diff --git a/en_US.ISO8859-1/books/handbook/advanced-networking/chapter.sgml b/en_US.ISO8859-1/books/handbook/advanced-networking/chapter.sgml index bd0bef8b72..31b3e6b3bc 100644 --- a/en_US.ISO8859-1/books/handbook/advanced-networking/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/advanced-networking/chapter.sgml @@ -1,4696 +1,4696 @@ Advanced Networking Synopsis This chapter will cover some of the more frequently used network services on Unix systems. We will cover how to define, setup, test and maintain all of the network services that FreeBSD utilizes. In addition, there have been example configuration files included throughout this chapter for you to benefit from. After reading this chapter you will know: The basics of gateways and routes. How to make FreeBSD act as a bridge. How to setup a network file system. How to setup network booting on a diskless machine. How to setup a network information server for sharing user accounts. How to setup automatic network settings using DHCP. How to setup a domain name server. How to setup network address translation. How to manage the inetd daemon. Before reading this chapter you should: The basics of the /etc/rc scripts. Basic network terminology. Coranth Gryphon Contributed by Gateways and Routes routing gateway subnet For one machine to be able to find another, there must be a mechanism in place to describe how to get from one to the other. This is called Routing. A route is a defined pair of addresses: a destination and a gateway. The pair indicates that if you are trying to get to this destination, send along through this gateway. There are three types of destinations: individual hosts, subnets, and default. The default route is used if none of the other routes apply. We will talk a little bit more about default routes later on. There are also three types of gateways: individual hosts, interfaces (also called links), and Ethernet hardware addresses. An Example To illustrate different aspects of routing, we will use the following example which is the output of the command netstat -r: Destination Gateway Flags Refs Use Netif Expire default outside-gw UGSc 37 418 ppp0 localhost localhost UH 0 181 lo0 test0 0:e0:b5:36:cf:4f UHLW 5 63288 ed0 77 10.20.30.255 link#1 UHLW 1 2421 foobar.com link#1 UC 0 0 host1 0:e0:a8:37:8:1e UHLW 3 4601 lo0 host2 0:e0:a8:37:8:1e UHLW 0 5 lo0 => host2.foobar.com link#1 UC 0 0 224 link#1 UC 0 0 default route The first two lines specify the default route (which we will cover in the next section) and the localhost route. loopback device The interface (Netif column) that it specifies to use for localhost is lo0, also known as the loopback device. This says to keep all traffic for this destination internal, rather than sending it out over the LAN, since it will only end up back where it started anyway. Ethernet MAC address The next thing that stands out are the 0:e0:... addresses. These are Ethernet hardware addresses. FreeBSD will automatically identify any hosts (test0 in the example) on the local Ethernet and add a route for that host, directly to it over the Ethernet interface, ed0. There is also a timeout (Expire column) associated with this type of route, which is used if we fail to hear from the host in a specific amount of time. In this case the route will be automatically deleted. These hosts are identified using a mechanism known as RIP (Routing Information Protocol), which figures out routes to local hosts based upon a shortest path determination. subnet FreeBSD will also add subnet routes for the local subnet (10.20.30.255 is the broadcast address for the subnet 10.20.30, and foobar.com is the domain name associated with that subnet). The designation link#1 refers to the first Ethernet card in the machine. You will notice no additional interface is specified for those. Both of these groups (local network hosts and local subnets) have their routes automatically configured by a daemon called routed. If this is not run, then only routes which are statically defined (ie. entered explicitly) will exist. The host1 line refers to our host, which it knows by Ethernet address. Since we are the sending host, FreeBSD knows to use the loopback interface (lo0) rather than sending it out over the Ethernet interface. The two host2 lines are an example of what happens when we use an &man.ifconfig.8; alias (see the section of Ethernet for reasons why we would do this). The => symbol after the lo0 interface says that not only are we using the loopback (since this is address also refers to the local host), but specifically it is an alias. Such routes only show up on the host that supports the alias; all other hosts on the local network will simply have a link#1 line for such. The final line (destination subnet 224) deals with MultiCasting, which will be covered in a another section. The other column that we should talk about are the Flags. Each route has different attributes that are described in the column. Below is a short table of some of these flags and their meanings: U Up: The route is active. H Host: The route destination is a single host. G Gateway: Send anything for this destination on to this remote system, which will figure out from there where to send it. S Static: This route was configured manually, not automatically generated by the system. C Clone: Generates a new route based upon this route for machines we connect to. This type of route is normally used for local networks. W WasCloned: Indicated a route that was auto-configured based upon a local area network (Clone) route. L Link: Route involves references to Ethernet hardware. Default Routes default route When the local system needs to make a connection to remote host, it checks the routing table to determine if a known path exists. If the remote host falls into a subnet that we know how to reach (Cloned routes), then the system checks to see if it can connect along that interface. If all known paths fail, the system has one last option: the default route. This route is a special type of gateway route (usually the only one present in the system), and is always marked with a c in the flags field. For hosts on a local area network, this gateway is set to whatever machine has a direct connection to the outside world (whether via PPP link, or your hardware device attached to a dedicated data line). If you are configuring the default route for a machine which itself is functioning as the gateway to the outside world, then the default route will be the gateway machine at your Internet Service Provider's (ISP) site. Let us look at an example of default routes. This is a common configuration: [Local2] <--ether--> [Local1] <--PPP--> [ISP-Serv] <--ether--> [T1-GW] The hosts Local1 and Local2 are at your site, with the formed being your PPP connection to your ISP's Terminal Server. Your ISP has a local network at their site, which has, among other things, the server where you connect and a hardware device (T1-GW) attached to the ISP's Internet feed. The default routes for each of your machines will be: host default gateway interface Local2 Local1 Ethernet Local1 T1-GW PPP A common question is Why (or how) would we set the T1-GW to be the default gateway for Local1, rather than the ISP server it is connected to?. Remember, since the PPP interface is using an address on the ISP's local network for your side of the connection, routes for any other machines on the ISP's local network will be automatically generated. Hence, you will already know how to reach the T1-GW machine, so there is no need for the intermediate step of sending traffic to the ISP server. As a final note, it is common to use the address ...1 as the gateway address for your local network. So (using the same example), if your local class-C address space was 10.20.30 and your ISP was using 10.9.9 then the default routes would be: Local2 (10.20.30.2) --> Local1 (10.20.30.1) Local1 (10.20.30.1, 10.9.9.30) --> T1-GW (10.9.9.1) Dual Homed Hosts dual homed hosts There is one other type of configuration that we should cover, and that is a host that sits on two different networks. Technically, any machine functioning as a gateway (in the example above, using a PPP connection) counts as a dual-homed host. But the term is really only used to refer to a machine that sits on two local-area networks. In one case, the machine as two Ethernet cards, each having an address on the separate subnets. Alternately, the machine may only have one Ethernet card, and be using &man.ifconfig.8; aliasing. The former is used if two physically separate Ethernet networks are in use, the latter if there is one physical network segment, but two logically separate subnets. Either way, routing tables are set up so that each subnet knows that this machine is the defined gateway (inbound route) to the other subnet. This configuration, with the machine acting as a Bridge between the two subnets, is often used when we need to implement packet filtering or firewall security in either or both directions. Routing Propagation routing propagation We have already talked about how we define our routes to the outside world, but not about how the outside world finds us. We already know that routing tables can be set up so that all traffic for a particular address space (in our examples, a class-C subnet) can be sent to a particular host on that network, which will forward the packets inbound. When you get an address space assigned to your site, your service provider will set up their routing tables so that all traffic for your subnet will be sent down your PPP link to your site. But how do sites across the country know to send to your ISP? There is a system (much like the distributed DNS information) that keeps track of all assigned address-spaces, and defines their point of connection to the Internet Backbone. The Backbone are the main trunk lines that carry Internet traffic across the country, and around the world. Each backbone machine has a copy of a master set of tables, which direct traffic for a particular network to a specific backbone carrier, and from there down the chain of service providers until it reaches your network. It is the task of your service provider to advertise to the backbone sites that they are the point of connection (and thus the path inward) for your site. This is known as route propagation. Troubleshooting traceroute Sometimes, there is a problem with routing propagation, and some sites are unable to connect to you. Perhaps the most useful command for trying to figure out where a routing is breaking down is the &man.traceroute.8; command. It is equally useful if you cannot seem to make a connection to a remote machine (i.e. &man.ping.8; fails). The &man.traceroute.8; command is run with the name of the remote host you are trying to connect to. It will show the gateway hosts along the path of the attempt, eventually either reaching the target host, or terminating because of a lack of connection. For more information, see the manual page for &man.traceroute.8;. Steve Peterson Written by Bridging Introduction IP subnet bridge It is sometimes useful to divide one physical network (i.e., an Ethernet segment) into two separate network segments, without having to create IP subnets and use a router to connect the segments together. A device that connects two networks together in this fashion is called a bridge. and a FreeBSD system with two network interface cards can act as a bridge. The bridge works by learning the MAC layer addresses (i.e., Ethernet addresses) of the devices on each of its network interfaces. It forwards traffic between two networks only when its source and destination are on different networks. In many respects, a bridge is like an Ethernet switch with very few ports. Situations Where Bridging Is Appropriate There are two common situations in which a bridge is used today. High Traffic on a Segment Situation one is where your physical network segment is - overloaded with traffic, but you don't want for whatever reason to + overloaded with traffic, but you do not want for whatever reason to subnet the network and interconnect the subnets with a router. - Let's consider an example of a newspaper where the Editorial and + Let us consider an example of a newspaper where the Editorial and Production departments are on the same subnetwork. The Editorial users all use server A for file service, and the Production users are on server B. An Ethernet is used to connect all users together, and high loads on the network are slowing things down. If the Editorial users could be segregated on one network segment and the Production users on another, the two network segments could be connected with a bridge. Only the network traffic destined for interfaces on the "other" side of the bridge would be sent to the other network, reducing congestion on each network segment. Filtering/Traffic Shaping Firewall firewall IP Masquerading The second common situation is where firewall functionality is needed without IP Masquerading (NAT). An example is a small company that is connected via DSL or ISDN to their ISP. They have a 13 address global IP allocation for their ISP and have 10 PCs on their network. In this situation, using a router-based firewall is difficult because of subnetting issues. router DSL ISDN A bridge-based firewall can be configured and dropped into the path just downstream of their DSL/ISDN router without any IP numbering issues. Configuring a Bridge Network Interface Card Selection A bridge requires at least two network cards to function. Unfortunately, not all network interface cards as of FreeBSD 4.0 support bridging. Read &man.bridge.4; for details on the cards that are supported. Install and test the two network cards before continuing. Kernel Configuration Changes kernel configuration kernel configuration options BRIDGE To enable kernel support for bridging, add the options BRIDGE statement to your kernel configuration file, and rebuild your kernel. Firewall Support firewall If you are planning to use the bridge as a firewall, you will need to add the IPFIREWALL option as well. Read for general information on configuring the bridge as a firewall. If you need to allow non-IP packets (such as ARP) to flow through the bridge, there is an undocumented firewall option that must be set. This option is IPFIREWALL_DEFAULT_TO_ACCEPT. Note that this changes the default rule for the firewall to accept any packet. Make sure you know how this changes the meaning of your ruleset before you set it. Traffic Shaping Support If you want to use the bridge as a traffic shaper, you will need to add the DUMMYNET option to your kernel configuration. Read &man.dummynet.4; for further information. Enabling the Bridge Add the line net.link.ether.bridge=1 to /etc/sysctl.conf to enable the bridge at runtime. If you want the bridged packets to be filtered by &man.ipfw.8;, you should also add net.link.ether.bridge_ipfw=1 as well. Performance My bridge/firewall is a Pentium 90 with one 3Com 3C900B and one 3C905B. The protected side of the network runs at 10mbps half duplex and the connection between the bridge and my router (a Cisco 675) runs - at 100mbps full duplex. With no filtering enabled, I've found that + at 100mbps full duplex. With no filtering enabled, I have found that the bridge adds about 0.4 milliseconds of latency to pings from the protected 10mbps network to the Cisco 675. Other Information If you want to be able to telnet into the bridge from the network, it is OK to assign one of the network cards an IP address. The consensus is that assigning both cards an address is a bad idea. If you have multiple bridges on your network, there cannot be more than one path between any two workstations. Technically, this means that there is no support for spanning tree link management. Bill Swingle Written by NFS NFS Among the many different file systems that FreeBSD supports is the Network File System or NFS. NFS allows you to share directories and files on one machine with one or more other machines via the network they are attached to. Using NFS, users and programs can access files on remote systems as if they were local files. NFS has several benefits: - Local workstations don't need as much disk space because + Local workstations do not need as much disk space because commonly used data can be stored on a single machine and still remain accessible to everyone on the network. There is no need for users to have unique home directories on every machine on your network. Once they have an established directory that is available via NFS it can be accessed from anywhere. Storage devices such as floppies and CDROM drives can be used by other machines on the network eliminating the need for extra hardware. How It Works NFS is composed of two sides – a client side and a server side. Think of it as a want/have relationship. The client wants the data that the server side has. The server shares its data with the client. In order for this system to function properly a few processes have to be configured and running properly. The server has to be running the following daemons: NFS server portmap mountd nfsd nfsd - The NFS Daemon which services requests from NFS clients. mountd - The NFS Mount Daemon which actually carries out requests that &man.nfsd.8; passes on to it. portmap - The portmapper daemon which allows NFS clients to find out which port the NFS server is using. The client side only needs to run a single daemon: NFS client nfsiod nfsiod - The NFS async I/O Daemon which services requests from its NFS server. Configuring NFS NFS configuration Luckily for us, on a FreeBSD system this setup is a snap. The processes that need to be running can all be run at boot time with a few modifications to your /etc/rc.conf file. On the NFS server make sure you have: portmap_enable="YES" nfs_server_enable="YES" nfs_server_flags="-u -t -n 4" mountd_flags="-r" mountd is automatically run whenever the NFS server is enabled. The and flags to nfsd tell it to serve UDP and TCP clients. The flag tells nfsd to start 4 copies of itself. On the client, make sure you have: nfs_client_enable="YES" nfs_client_flags="-n 4" Like nfsd, the tells nfsiod to start 4 copies of itself. The last configuration step requires that you create a file called /etc/exports. The exports file specifies which file systems on your server will be shared (a.k.a., exported) and with what clients they will be shared. Each line in the file specifies a file system to be shared. There are a handful of options that can be used in this file but only a few will be mentioned here. You can find out about the rest in the &man.exports.5; manual page. Here are a few example /etc/exports entries: NFS exporting filesystems The following line exports /cdrom to three silly machines that have the same domain name as the server (hence the lack of a domain name for each) or have entries in your /etc/hosts file. The flag makes the shared file system read-only. With this flag, the remote system will not be able to make any changes to the shared file system. /cdrom -ro moe larry curly The following line exports /home to three hosts by IP address. This is a useful setup if you have a private network but do not have DNS running. The flag allows all the directories below the specified file system to be exported as well. /home -alldirs 10.0.0.2 10.0.0.3 10.0.0.4 The following line exports /a to two machines that have different domain names than the server. The flag allows the root user on the remote system to write to the shared file system as root. Without the -maproot=0 flag even if - someone has root access on the remote system they won't + someone has root access on the remote system they will not be able to modify files on the shared file system. /a -maproot=0 host.domain.com box.example.com In order for a client to share an exported file system it must have permission to do so. Make sure your client is listed in your /etc/exports file. - It's important to remember that you must restart mountd + It is important to remember that you must restart mountd whenever you modify /etc/exports so that your changes take effect. This can be accomplished by sending the hangup signal to the mountd process : &prompt.root; kill -HUP `cat /var/run/mountd.pid` Now that you have made all these changes you can just reboot and let FreeBSD start everything for you at boot time or you can run the following commands as root: On the NFS server: &prompt.root; portmap &prompt.root; nfsd -u -t -n 4 &prompt.root; mountd -r On the NFS client: &prompt.root; nfsiod -n 4 Now you should be ready to actually mount a remote file system. This can be done one of two ways. In these examples the server's name will be server and the client's name will be client. If you just want to temporarily mount a remote file system or just want to test out your configuration you can run a command like this as root on the client: NFS mounting filesystems &prompt.root; mount server:/home /mnt This will mount /home on the server on /mnt on the client. If everything is setup correctly you should be able to go into /mnt on the client and see all the files that are on the server. If you want to permanently (each time you reboot) mount a remote file system you need to add it to your /etc/fstab file. Here is an example line: server:/home /mnt nfs rw 0 0 Read the &man.fstab.5; manual page for more options. Practical Uses There are many very cool uses for NFS. Some of the more common ones are listed below. NFS uses Have several machines on a network and share a CDROM or floppy drive among them. This is cheaper and often more convenient. With so many machines on a network, it gets old having your personal files strewn all over the place. You can have a central NFS server that houses all user home directories and shares them with the rest of the machines on the LAN, so no matter where you log in you will have the same home directory. When you get to reinstalling FreeBSD on one of your machines, NFS is the way to go! Just pop your distribution CDROM into your file server and away you go! Have a common /usr/ports/distfiles directory that all your machines share. That way, when you go - to install a port that you've already installed on a different + to install a port that you have already installed on a different machine, you do not have to download the source all over again! Wylie Stilwell Contributed by Chern Lee Rewritten by amd amd automatic mounter daemon &man.amd.8;, which is also known as the automatic mounter daemon, is a useful utility used for automatically mounting a remote filesystem whenever a file or directory within that filesystem is accessed. Filesystems that are inactive for a period of time will also be automatically unmounted by amd. Using amd provides a simplistic alternative to static mounts. amd operates by attaching itself as an NFS server to the /host and /net directories. When a file is accessed within one of these directories, amd looks up the corresponding remote mount and automatically mounts it. /net is used to mount an exported filesystem from an IP address, while /host is used to mount an export from a remote hostname. An access to a file within /host/foobar/usr would tell amd to attempt to mount the /usr export on the host foobar. Mounting an Export with <application>amd</application> &prompt.user; showmount -e foobar Exports list on foobar: /usr 10.10.10.0 /a 10.10.10.0 &prompt.user; cd /host/foobar/usr As seen in the example, the showmount shows /usr as an export. When changing directories to /host/foobar/usr, amd attempts to resolve the hostname foobar and automatically mount the desired export. amd can be started through the rc.conf system by placing the following lines in /etc/rc.conf: amd_enable="YES" Additionally, custom flags can be passed to amd from the amd_flags option. By default, amd_flags is set to: amd_flags="-a /.amd_mnt -l syslog /host /etc/amd.map /net /etc/amd.map" The /etc/amd.map file defines the default options that exports are mounted with. The /etc/amd.conf file defines some of the more advanced features of amd. Consult the &man.amd.8; and &man.amd.conf.5; man pages for more information. John Lind Contributed by Problems Integrating with Other Systems Certain Ethernet adapters for ISA PC systems have limitations which can lead to serious network problems, particularly with NFS. This difficulty is not specific to FreeBSD, but FreeBSD systems are affected by it. The problem nearly always occurs when (FreeBSD) PC systems are networked with high-performance workstations, such as those made by Silicon Graphics, Inc., and Sun Microsystems, Inc. The NFS mount will work fine, and some operations may succeed, but suddenly the server will seem to become unresponsive to the client, even though requests to and from other systems continue to be processed. This happens to the client system, whether the client is the FreeBSD system or the workstation. On many systems, there is no way to shut down the client gracefully once this problem has manifested itself. The only solution is often to reset the client, because the NFS situation cannot be resolved. Though the correct solution is to get a higher performance and capacity Ethernet adapter for the FreeBSD system, there is a simple workaround that will allow satisfactory operation. If the FreeBSD system is the server, include the option on the mount from the client. If the FreeBSD system is the client, then mount the NFS file system with the option . These options may be specified using the fourth field of the fstab entry on the client for automatic mounts, or by using the parameter of the mount command for manual mounts. It should be noted that there is a different problem, sometimes mistaken for this one, when the NFS servers and clients are on different networks. If that is the case, make certain that your routers are routing the necessary UDP information, or you will not get anywhere, no matter what else you are doing. In the following examples, fastws is the host (interface) name of a high-performance workstation, and freebox is the host (interface) name of a FreeBSD system with a lower-performance Ethernet adapter. Also, /sharedfs will be the exported NFS filesystem (see man exports), and /project will be the mount point on the client for the exported file system. In all cases, note that additional options, such as or and may be desirable in your application. Examples for the FreeBSD system (freebox) as the client: in /etc/fstab on freebox: fastws:/sharedfs /project nfs rw,-r=1024 0 0 As a manual mount command on freebox: &prompt.root; mount -t nfs -o -r=1024 fastws:/sharedfs /project Examples for the FreeBSD system as the server: in /etc/fstab on fastws: freebox:/sharedfs /project nfs rw,-w=1024 0 0 As a manual mount command on fastws: &prompt.root; mount -t nfs -o -w=1024 freebox:/sharedfs /project Nearly any 16-bit Ethernet adapter will allow operation without the above restrictions on the read or write size. For anyone who cares, here is what happens when the failure occurs, which also explains why it is unrecoverable. NFS typically works with a block size of 8k (though it may do fragments of smaller sizes). Since the maximum Ethernet packet is around 1500 bytes, the NFS block gets split into multiple Ethernet packets, even though it is still a single unit to the upper-level code, and must be received, assembled, and acknowledged as a unit. The high-performance workstations can pump out the packets which comprise the NFS unit one right after the other, just as close together as the standard allows. On the smaller, lower capacity cards, the later packets overrun the earlier packets of the same unit before they can be transferred to the host and the unit as a whole cannot be reconstructed or acknowledged. As a result, the workstation will time out and try again, but it will try again with the entire 8K unit, and the process will be repeated, ad infinitum. By keeping the unit size below the Ethernet packet size limitation, we ensure that any complete Ethernet packet received can be acknowledged individually, avoiding the deadlock situation. Overruns may still occur when a high-performance workstations is slamming data out to a PC system, but with the better cards, such overruns are not guaranteed on NFS units. When an overrun occurs, the units affected will be retransmitted, and there will be a fair chance that they will be received, assembled, and acknowledged. Martin Renters Contributed by Diskless Operation diskless workstation netboot.com/netboot.rom allow you to boot your FreeBSD machine over the network and run FreeBSD without having a disk on your client. Under 2.0 it is now possible to have local swap. Swapping over NFS is also still supported. Supported Ethernet cards include: Western Digital/SMC 8003, 8013, 8216 and compatibles; NE1000/NE2000 and compatibles (requires recompile) Setup Instructions Find a machine that will be your server. This machine will require enough disk space to hold the FreeBSD 2.0 binaries and have bootp, tftp and NFS services available. Tested machines: HP-UX - HP9000/8xx running HP-UX 9.04 or later (pre 9.04 doesn't + HP9000/8xx running HP-UX 9.04 or later (pre 9.04 does not work) Solaris Sun/Solaris 2.3. (you may need to get bootp) Set up a bootp server to provide the client with IP address, gateway, netmask. diskless:\ :ht=ether:\ :ha=0000c01f848a:\ :sm=255.255.255.0:\ :hn:\ :ds=192.1.2.3:\ :ip=192.1.2.4:\ :gw=192.1.2.5:\ :vm=rfc1048: TFTP bootp Set up a TFTP server (on same machine as bootp server) to provide booting information to client. The name of this file is cfg.X.X.X.X (or /tftpboot/cfg.X.X.X.X, it will try both) where X.X.X.X is the IP address of the client. The contents of this file can be any valid netboot commands. Under 2.0, netboot has the following commands: help print help list ip print/set client's IP address server print/set bootp/tftp server address netmask print/set netmask hostname name print/set hostname kernel print/set kernel name rootfs print/set root filesystem swapfs print/set swap filesystem swapsize set diskless swapsize in KBytes diskboot boot from disk autoboot continue boot process trans | turn transceiver on|off flags set boot flags A typical completely diskless config file might contain: rootfs 192.1.2.3:/rootfs/myclient swapfs 192.1.2.3:/swapfs swapsize 20000 hostname myclient.mydomain A config file for a machine with local swap might contain: rootfs 192.1.2.3:/rootfs/myclient hostname myclient.mydomain Ensure that your NFS server has exported the root (and swap if applicable) filesystems to your client, and that the client has root access to these filesystems A typical /etc/exports file on FreeBSD might look like: /rootfs/myclient -maproot=0:0 myclient.mydomain /swapfs -maproot=0:0 myclient.mydomain And on HP-UX: /rootfs/myclient -root=myclient.mydomain /swapfs -root=myclient.mydomain NFS swapping over If you are swapping over NFS (completely diskless configuration) create a swap file for your client using dd. If your swapfs command has the arguments /swapfs and the size 20000 as in the example above, the swapfile for myclient will be called /swapfs/swap.X.X.X.X where X.X.X.X is the client's IP address, e.g.: &prompt.root; dd if=/dev/zero of=/swapfs/swap.192.1.2.4 bs=1k count=20000 Also, the client's swap space might contain sensitive information once swapping starts, so make sure to restrict read and write access to this file to prevent unauthorized access: &prompt.root; chmod 0600 /swapfs/swap.192.1.2.4 Unpack the root filesystem in the directory the client will use for its root filesystem (/rootfs/myclient in the example above). On HP-UX systems: The server should be running HP-UX 9.04 or later for HP9000/800 series machines. Prior versions do not allow the creation of device files over NFS. When extracting /dev in /rootfs/myclient, beware that some systems (HPUX) will not create device files that FreeBSD is happy with. You may have to go to single user mode on the first bootup (press control-c during the bootup phase), cd /dev and do a sh ./MAKEDEV all from the client to fix this. Run netboot.com on the client or make an EPROM from the netboot.rom file Using Shared <filename>/</filename> and <filename>/usr</filename> Filesystems Although this is not an officially sanctioned or supported way of doing this, some people report that it works quite well. If anyone has any suggestions on how to do this cleanly, please tell &a.doc;. Compiling Netboot for Specific Setups Netboot can be compiled to support NE1000/2000 cards by changing the configuration in /sys/i386/boot/netboot/Makefile. See the comments at the top of this file. ISDN A good resource for information on ISDN technology and hardware is Dan Kegel's ISDN Page. A quick simple road map to ISDN follows: If you live in Europe you might want to investigate the ISDN card section. If you are planning to use ISDN primarily to connect to the Internet with an Internet Provider on a dial-up non-dedicated basis, you might look into Terminal Adapters. This will give you the most flexibility, with the fewest problems, if you change providers. If you are connecting two LANs together, or connecting to the Internet with a dedicated ISDN connection, you might consider the stand alone router/bridge option. Cost is a significant factor in determining what solution you will choose. The following options are listed from least expensive to most expensive. Hellmuth Michaelis Contributed by ISDN Cards ISDN cards FreeBSD's ISDN implementation supports only the DSS1/Q.931 (or Euro-ISDN) standard using passive cards. Starting with FreeBSD 4.4, some active cards are supported where the firmware also supports other signalling protocols; this also includes the first supported Primary Rate (PRI) ISDN card. Isdn4bsd allows you to connect to other ISDN routers using either IP over raw HDLC or by using synchronous PPP: either by using kernel PPP with isppp, a modified sppp driver, or by using userland &man.ppp.8;. By using userland &man.ppp.8;, channel bonding of two or more ISDN B-channels is possible. A telephone answering machine application is also available as well as many utilities such as a software 300 Baud modem. Some growing number of PC ISDN cards are supported under FreeBSD and the reports show that it is successfully used all over Europe and in many other parts of the world. The passive ISDN cards supported are mostly the ones with the Infineon (formerly Siemens) ISAC/HSCX/IPAC ISDN chipsets, but also ISDN cards with chips from Cologne Chip (ISA bus only), PCI cards with Winbond W6692 chips, some cards with the Tiger300/320/ISAC chipset combinations and some vendor specific chipset based cards such as the AVM Fritz!Card PCI V.1.0 and the AVM Fritz!Card PnP. Currently the active supported ISDN cards are the AVM B1 (ISA and PCI) BRI cards and the AVM T1 PCI PRI cards. For documentation on isdn4bsd, have a look at /usr/share/examples/isdn/ directory on your FreeBSD system or at the homepage of isdn4bsd which also has pointers to hints, erratas and much more documentation such as the isdn4bsd handbook. In case you are interested in adding support for a different ISDN protocol, a currently unsupported ISDN PC card or otherwise enhancing isdn4bsd, please get in touch with hm@freebsd.org. For questions regarding the installation, configuration and troubleshooting isdn4bsd, a majordomo maintained mailing list is available. To join, send mail to majordomo@FreeBSD.org and specify: subscribe freebsd-isdn in the body of your message. ISDN Terminal Adapters Terminal adapters(TA), are to ISDN what modems are to regular phone lines. modem Most TA's use the standard hayes modem AT command set, and can be used as a drop in replacement for a modem. A TA will operate basically the same as a modem except connection and throughput speeds will be much faster than your old modem. You will need to configure PPP exactly the same as for a modem setup. Make sure you set your serial speed as high as possible. PPP The main advantage of using a TA to connect to an Internet Provider is that you can do Dynamic PPP. As IP address space becomes more and more scarce, most providers are not willing to provide you with a static IP anymore. Most stand-alone routers are not able to accommodate dynamic IP allocation. TA's completely rely on the PPP daemon that you are running for their features and stability of connection. This allows you to upgrade easily from using a modem to ISDN on a FreeBSD machine, if you already have PPP setup. However, at the same time any problems you experienced with the PPP program and are going to persist. If you want maximum stability, use the kernel PPP option, not the user-land iijPPP. The following TA's are know to work with FreeBSD. Motorola BitSurfer and Bitsurfer Pro Adtran Most other TA's will probably work as well, TA vendors try to make sure their product can accept most of the standard modem AT command set. The real problem with external TA's is like modems you need a good serial card in your computer. You should read the FreeBSD Serial Hardware tutorial for a detailed understanding of serial devices, and the differences between asynchronous and synchronous serial ports. A TA running off a standard PC serial port (asynchronous) limits you to 115.2Kbs, even though you have a 128Kbs connection. To fully utilize the 128Kbs that ISDN is capable of, you must move the TA to a synchronous serial card. Do not be fooled into buying an internal TA and thinking you have avoided the synchronous/asynchronous issue. Internal TA's simply have a standard PC serial port chip built into them. All this will do, is save you having to buy another serial cable, and find another empty electrical socket. A synchronous card with a TA is at least as fast as a stand-alone router, and with a simple 386 FreeBSD box driving it, probably more flexible. The choice of sync/TA v.s. stand-alone router is largely a religious issue. There has been some discussion of this in the mailing lists. I suggest you search the archives for the complete discussion. Stand-alone ISDN Bridges/Routers ISDN stand-alone bridges/routers ISDN bridges or routers are not at all specific to FreeBSD or any other operating system. For a more complete description of routing and bridging technology, please refer to a Networking reference book. In the context of this page, the terms router and bridge will be used interchangeably. As the cost of low end ISDN routers/bridges comes down, it will likely become a more and more popular choice. An ISDN router is a small box that plugs directly into your local Ethernet network(or card), and manages its own connection to the other bridge/router. It has all the software to do PPP and other protocols built in. A router will allow you much faster throughput that a standard TA, since it will be using a full synchronous ISDN connection. The main problem with ISDN routers and bridges is that interoperability between manufacturers can still be a problem. If you are planning to connect to an Internet provider, you should discuss your needs with them. If you are planning to connect two LAN segments together, ie: home LAN to the office LAN, this is the simplest lowest maintenance solution. Since you are buying the equipment for both sides of the connection you can be assured that the link will work. For example to connect a home computer or branch office network to a head office network the following setup could be used. Branch Office or Home Network 10 base 2 Network uses a bus based topology with 10 base 2 Ethernet ("thinnet"). Connect router to network cable with AUI/10BT transceiver, if necessary. ---Sun workstation | ---FreeBSD box | ---Windows 95 (Do not admit to owning it) | Stand-alone router | ISDN BRI line 10 Base 2 Ethernet If your home/branch office is only one computer you can use a twisted pair crossover cable to connect to the stand-alone router directly. Head Office or Other LAN 10 base T Network uses a star topology with 10 base T Ethernet ("Twisted Pair"). -------Novell Server | H | | ---Sun | | | U ---FreeBSD | | | ---Windows 95 | B | |___---Stand-alone router | ISDN BRI line ISDN Network Diagram One large advantage of most routers/bridges is that they allow you to have 2 separate independent PPP connections to 2 separate sites at the same time. This is not supported on most TA's, except for specific(expensive) models that have two serial ports. Do not confuse this with channel bonding, MPP etc. This can be very useful feature, for example if you have an dedicated ISDN connection at your office and would like to - tap into it, but don't want to get another ISDN line at work. A router + tap into it, but do not want to get another ISDN line at work. A router at the office location can manage a dedicated B channel connection (64Kbs) to the Internet, as well as a use the other B channel for a separate data connection. The second B channel can be used for dial-in, dial-out or dynamically bond(MPP etc.) with the first B channel for more bandwidth. IPX/SPX An Ethernet bridge will also allow you to transmit more than just IP traffic, you can also send IPX/SPX or whatever other protocols you use. Bill Swingle Written by Eric Ogren Enhanced by Udo Erdelhoff NIS/YP What Is It? NIS Solaris HP-UX AIX Linux NetBSD OpenBSD NIS, which stands for Network Information Services, was developed by Sun Microsystems to centralize administration of Unix (originally SunOS) systems. It has now essentially become an industry standard; all major Unix systems (Solaris, HP-UX, AIX, Linux, NetBSD, OpenBSD, FreeBSD, etc) support NIS. yellow pagesNIS NIS was formerly known as Yellow Pages, but because of trademark issues, Sun changed the name. The old term (and yp) is still often seen and used. NIS domains It is a RPC-based client/server system that allows a group of machines within an NIS domain to share a common set of configuration files. This permits a system administrator to set up NIS client systems with only minimal configuration data and add, remove or modify configuration data from a single location. Windows NT It is similar to Windows NT's domain system; although the - internal implementation of the two aren't at all similar, + internal implementation of the two are not at all similar, the basic functionality can be compared. Terms/Processes You Should Know There are several terms and several important user processes that you will come across when attempting to implement NIS on FreeBSD, whether you are trying to create an NIS server or act an NIS client: The NIS domainname. An NIS master server and all of its clients (including its slave servers) have a NIS domainname. Similar to an NT domain name, the NIS domainname does not have anything to do with DNS. portmap portmap. portmap must be running in order to enable RPC (Remote Procedure Call, a network protocol used by NIS). If portmap is not running, it will be impossible to run an NIS server, or to act as an NIS client. ypbind. ypbind “binds” an NIS client to its NIS server. It will take the NIS domainname from the system, and using RPC, connect to the server. ypbind is the core of client-server communication in an NIS environment; if ypbind dies on a client machine, it will not be able to access the NIS server. ypserv. ypserv, which should only be running on NIS servers, is the NIS server process itself. If &man.ypserv.8; dies, then the server will no longer be able to respond to NIS requests (hopefully, there is a slave server to take over for it). There are some implementations of NIS (but not the - FreeBSD one), that don't try to reconnect to another server + FreeBSD one), that do not try to reconnect to another server if the server it used before dies. Often, the only thing that helps in this case is to restart the server process (or even the whole server) or the ypbind process on the client. rpc.yppasswdd. rpc.yppasswdd, another process that should only be running on NIS master servers, is a daemon that will allow NIS clients to change their NIS passwords. If this daemon is not running, users will have to login to the NIS master server and change their passwords there. How Does It Work? There are three types of hosts in an NIS environment; master servers, slave servers, and clients. Servers act as a central repository for host configuration information. Master servers hold the authoritative copy of this information, while slave servers mirror this information for redundancy. Clients rely on the servers to provide this information to them. Information in many files can be shared in this manner. The master.passwd, group, and hosts files are commonly shared via NIS. Whenever a process on a client needs information that would normally be found in these files locally, it makes a query to the server it is bound to, to get this information. Machine Types NIS master server A NIS master server. This server, analogous to a Windows NT primary domain controller, maintains the files used by all of the NIS clients. The passwd, group, and other various files used by the NIS clients live on the master server. It is possible for one machine to be an NIS master server for more than one NIS domain. However, this will not be covered in this introduction, which assumes a relatively small-scale NIS environment. NIS slave server NIS slave servers. Similar to NT's backup domain controllers, NIS slave servers maintain copies of the NIS master's data files. NIS slave servers provide the redundancy, which is needed in important environments. They also help to balance the load of the master server: NIS Clients always attach to the NIS server whose response they get first, and this includes slave-server-replies. NIS client NIS clients. NIS clients, like most NT workstations, authenticate against the NIS server (or the NT domain controller in the NT Workstation case) to log on. Using NIS/YP This section will deal with setting up a sample NIS environment. This section assumes that you are running FreeBSD 3.3 or later. The instructions given here will probably work for any version of FreeBSD greater than 3.0, but there are no guarantees that this is true. Planning - Let's assume that you are the administrator of a small + Let us assume that you are the administrator of a small university lab. This lab, which consists of 15 FreeBSD machines, currently has no centralized point of administration; each machine has its own /etc/passwd and /etc/master.passwd. These files are kept in sync with each other only through manual intervention; currently, when you add a user to the lab, you must run adduser on all 15 machines. Clearly, this has to change, so you have decided to convert the lab to use NIS, using two of the machines as servers. Therefore, the configuration of the lab now looks something like: Machine name IP address Machine role ellington 10.0.0.2 NIS master coltrane 10.0.0.3 NIS slave basie 10.0.0.4 Faculty workstation bird 10.0.0.5 Client machine cli[1-11] 10.0.0.[6-17] Other client machines If you are setting up a NIS scheme for the first time, it is a good idea to think through how you want to go about it. No matter what the size of your network, there are a few decisions that need to be made. Choosing a NIS Domain Name NIS domainname This might not be the domainname that you are used to. It is more accurately called the NIS domainname. When a client broadcasts its requests for info, it includes the name of the NIS domain that it is part of. This is how multiple servers on one network can tell which server should answer which request. Think of the NIS domainname as the name for a group of hosts that are related in some way. Some organizations choose to use their Internet domainname for their NIS domainname. This is not recommended as it can cause confusion when trying to debug network problems. The NIS domainname should be unique within your network and it is helpful if it describes the group of machines it represents. For example, the Art department at Acme Inc. might be in the "acme-art" NIS domain. For this example, assume you have chosen the name test-domain. SunOS However, some operating systems (notably SunOS) use their NIS domain name as their Internet domain name. If one or more machines on your network have this restriction, you must use the Internet domain name as your NIS domain name. Physical Server Requirements There are several things to keep in mind when choosing a machine to use as a NIS server. One of the unfortunate things about NIS is the level of dependency the clients have on the server. If a client cannot contact the server for its NIS domain, very often the machine becomes unusable. The lack of user and group information causes most systems to temporarily freeze up. With this in mind you should make sure to choose a - machine that won't be prone to being rebooted regularly, or + machine that will not be prone to being rebooted regularly, or one that might be used for development. The NIS server should ideally be a stand alone machine whose sole purpose in life is to be an NIS server. If you have a network that is not very heavily used, it is acceptable to put the NIS server on a machine running other services, just keep in mind that if the NIS server becomes unavailable, it will affect all of your NIS clients adversely. NIS Servers The canonical copies of all NIS information are stored on a single machine called the NIS master server. The databases used to store the information are called NIS maps. In FreeBSD, these maps are stored in /var/yp/[domainname] where [domainname] is the name of the NIS domain being served. A single NIS server can support several domains at once, therefore it is possible to have several such directories, one for each supported domain. Each domain will have its own independent set of maps. NIS master and slave servers handle all NIS requests with the ypserv daemon. Ypserv is responsible for receiving incoming requests from NIS clients, translating the requested domain and map name to a path to the corresponding database file and transmitting data from the database back to the client. Setting Up a NIS Master Server NIS server configuration Setting up a master NIS server can be relatively straight forward, depending on your needs. FreeBSD comes with support for NIS out-of-the-box. All you need is to add the following lines to /etc/rc.conf, and FreeBSD will do the rest for you. nisdomainname="test-domain" This line will set the NIS domainname to test-domain upon network setup (e.g. after reboot). nis_server_enable="YES" This will tell FreeBSD to start up the NIS server processes when the networking is next brought up. nis_yppasswdd_enable="YES" This will enable the rpc.yppasswdd daemon, which, as mentioned above, will allow users to change their NIS password from a client machine. Now, all you have to do is to run the command /etc/netstart as superuser. It will setup everything for you, using the values you defined in /etc/rc.conf. Initializing the NIS Maps NIS maps The NIS maps are database files, that are kept in the /var/yp directory. They are generated from configuration files in the /etc directory of the NIS master, with one exception: the /etc/master.passwd file. - This is for a good reason; you don't want to propagate + This is for a good reason; you do not want to propagate passwords to your root and other administrative accounts to all the servers in the NIS domain. Therefore, before we initialize the NIS maps, you should: &prompt.root; cp /etc/master.passwd /var/yp/master.passwd &prompt.root; cd /var/yp &prompt.root; vi master.passwd You should remove all entries regarding system accounts (bin, tty, kmem, games, etc), as well as any accounts that you - don't want to be propagated to the NIS clients (for example + do not want to be propagated to the NIS clients (for example root and any other UID 0 (superuser) accounts). Make sure the /var/yp/master.passwd is neither group nor world readable (mode 600)! Use the chmod command, if appropriate. Tru64 Unix - When you have finished, it's time to initialize the NIS + When you have finished, it is time to initialize the NIS maps! FreeBSD includes a script named ypinit to do this for you (see its manual page for more information). Note that this script is available on most Unix Operating Systems, but not on all. On Digital Unix/Compaq Tru64 Unix it is called ypsetup. Because we are generating maps for an NIS master, we are going to pass the option to ypinit. To generate the NIS maps, assuming you already performed the steps above, run: ellington&prompt.root; ypinit -m test-domain Server Type: MASTER Domain: test-domain Creating an YP server will require that you answer a few questions. Questions will all be asked at the beginning of the procedure. Do you want this procedure to quit on non-fatal errors? [y/n: n] n Ok, please remember to go back and redo manually whatever fails. If you don't, something might not work. At this point, we have to construct a list of this domains YP servers. rod.darktech.org is already known as master server. Please continue to add any slave servers, one per line. When you are done with the list, type a <control D>. master server : ellington next host to add: coltrane next host to add: ^D The current list of NIS servers looks like this: ellington coltrane Is this correct? [y/n: y] y [..output from map generation..] NIS Map update completed. ellington has been setup as an YP master server without any errors. ypinit should have created /var/yp/Makefile from /var/yp/Makefile.dist. When created, this file assumes that you are operating in a single server NIS environment with only FreeBSD machines. Since test-domain has a slave server as well, you must edit /var/yp/Makefile: ellington&prompt.root; vi /var/yp/Makefile You should comment out the line that says `NOPUSH = "True"' (if it is not commented out already). Setting up a NIS Slave Server NIS configuring a slave server Setting up an NIS slave server is even more simple than setting up the master. Log on to the slave server and edit the file /etc/rc.conf as you did before. The only difference is that we now must use the option when running ypinit. The option requires the name of the NIS master be passed to it as well, so our command line looks like: coltrane&prompt.root; ypinit -s ellington test-domain Server Type: SLAVE Domain: test-domain Master: ellington Creating an YP server will require that you answer a few questions. Questions will all be asked at the beginning of the procedure. Do you want this procedure to quit on non-fatal errors? [y/n: n] n Ok, please remember to go back and redo manually whatever fails. If you don't, something might not work. There will be no further questions. The remainder of the procedure should take a few minutes, to copy the databases from ellington. Transferring netgroup... ypxfr: Exiting: Map successfully transferred Transferring netgroup.byuser... ypxfr: Exiting: Map successfully transferred Transferring netgroup.byhost... ypxfr: Exiting: Map successfully transferred Transferring master.passwd.byuid... ypxfr: Exiting: Map successfully transferred Transferring passwd.byuid... ypxfr: Exiting: Map successfully transferred Transferring passwd.byname... ypxfr: Exiting: Map successfully transferred Transferring group.bygid... ypxfr: Exiting: Map successfully transferred Transferring group.byname... ypxfr: Exiting: Map successfully transferred Transferring services.byname... ypxfr: Exiting: Map successfully transferred Transferring rpc.bynumber... ypxfr: Exiting: Map successfully transferred Transferring rpc.byname... ypxfr: Exiting: Map successfully transferred Transferring protocols.byname... ypxfr: Exiting: Map successfully transferred Transferring master.passwd.byname... ypxfr: Exiting: Map successfully transferred Transferring networks.byname... ypxfr: Exiting: Map successfully transferred Transferring networks.byaddr... ypxfr: Exiting: Map successfully transferred Transferring netid.byname... ypxfr: Exiting: Map successfully transferred Transferring hosts.byaddr... ypxfr: Exiting: Map successfully transferred Transferring protocols.bynumber... ypxfr: Exiting: Map successfully transferred Transferring ypservers... ypxfr: Exiting: Map successfully transferred Transferring hosts.byname... ypxfr: Exiting: Map successfully transferred coltrane has been setup as an YP slave server without any errors. Don't forget to update map ypservers on ellington. You should now have a directory called /var/yp/test-domain. Copies of the NIS master server's maps should be in this directory. You will need to make sure that these stay updated. The following /etc/crontab entries on your slave servers should do the job: 20 * * * * root /usr/libexec/ypxfr passwd.byname 21 * * * * root /usr/libexec/ypxfr passwd.byuid These two lines force the slave to sync its maps with the maps on the master server. Although this is not mandatory, because the master server tries to make sure any changes to its NIS maps are communicated to its slaves, the password information is so vital to systems that depend on the server, that it is a good idea to force the updates. This is more important on busy networks where map updates might not always complete. Now, run the command /etc/netstart on the slave server as well, which again starts the NIS server. NIS Clients An NIS client establishes what is called a binding to a particular NIS server using the ypbind daemon. ypbind checks the system's default domain (as set by the domainname command), and begins broadcasting RPC requests on the local network. These requests specify the name of the domain for which ypbind is attempting to establish a binding. If a server that has been configured to serve the requested domain receives one of the broadcasts, it will respond to ypbind, which will record the server's address. If there are several servers available (a master and several slaves, for example), ypbind will use the address of the first one to respond. From that point on, the client system will direct all of its NIS requests to that server. Ypbind will occasionally ping the server to make sure it is still up and running. If it fails to receive a reply to one of its pings within a reasonable amount of time, ypbind will mark the domain as unbound and begin broadcasting again in the hopes of locating another server. Setting Up an NIS Client NIS client configuration Setting up a FreeBSD machine to be a NIS client is fairly straightforward. Edit the file /etc/rc.conf and add the following lines in order to set the NIS domainname and start ypbind upon network startup: nisdomainname="test-domain" nis_client_enable="YES" To import all possible password entries from the NIS server, add this line to your /etc/master.passwd file, using vipw: +::::::::: This line will afford anyone with a valid account in the NIS server's password maps an account. There are many ways to configure your NIS client by changing this line. See the netgroups part below for more information. For more detailed reading see O'Reilly's book on Managing NFS and NIS. To import all possible group entries from the NIS server, add this line to your /etc/group file: +:*:: After completing these steps, you should be able to run ypcat passwd and see the NIS server's passwd map. NIS Security In general, any remote user can issue an RPC to &man.ypserv.8; and retrieve the contents of your NIS maps, provided the remote user knows your domainname. To prevent such unauthorized transactions, &man.ypserv.8; supports a feature called securenets which can be used to restrict access to a given set of hosts. At startup, &man.ypserv.8; will attempt to load the securenets information from a file called /var/yp/securenets. This path varies depending on the path specified with the option. This file contains entries that consist of a network specification and a network mask separated by white space. Lines starting with # are considered to be comments. A sample securenets file might look like this: # allow connections from local host -- mandatory 127.0.0.1 255.255.255.255 # allow connections from any host # on the 192.168.128.0 network 192.168.128.0 255.255.255.0 # allow connections from any host # between 10.0.0.0 to 10.0.15.255 # this includes the machines in the testlab 10.0.0.0 255.255.240.0 If &man.ypserv.8; receives a request from an address that matches one of these rules, it will process the request normally. If the address fails to match a rule, the request will be ignored and a warning message will be logged. If the /var/yp/securenets file does not exist, ypserv will allow connections from any host. The ypserv program also has support for Wietse Venema's tcpwrapper package. This allows the administrator to use the tcpwrapper configuration files for access control instead of /var/yp/securenets. While both of these access control mechanisms provide some security, they, like the privileged port test, are vulnerable to IP spoofing attacks. All NIS-related traffic should be blocked at your firewall. Servers using /var/yp/securenets may fail to serve legitimate NIS clients with archaic TCP/IP implementations. Some of these implementations set all host bits to zero when doing broadcasts and/or fail to observe the subnet mask when calculating the broadcast address. While some of these problems can be fixed by changing the client configuration, other problems may force the retirement of the client systems in question or the abandonment of /var/yp/securenets. Using /var/yp/securenets on a server with such an archaic implementation of TCP/IP is a really bad idea and will lead to loss of NIS functionality for large parts of your network. tcpwrapper The use of the tcpwrapper package increases the latency of your NIS server. The additional delay may be long enough to cause timeouts in client programs, especially in busy networks or with slow NIS servers. If one or more of your client systems suffers from these symptoms, you should convert the client systems in question into NIS slave servers and force them to bind to themselves. Barring Some Users from Logging On In our lab, there is a machine basie that is - supposed to be a faculty only workstation. We don't want to take this + supposed to be a faculty only workstation. We do not want to take this machine out of the NIS domain, yet the passwd file on the master NIS server contains accounts for both faculty and students. What can we do? There is a way to bar specific users from logging on to a machine, even if they are present in the NIS database. To do this, all you must do is add -username to the end of the /etc/master.passwd file on the client machine, where username is the username of the user you wish to bar from logging in. This should preferably be done using vipw, since vipw will sanity check your changes to /etc/master.passwd, as well as automatically rebuild the password database when you finish editing. For example, if we wanted to bar user bill from logging on to basie we would: basie&prompt.root; vipw [add -bill to the end, exit] vipw: rebuilding the database... vipw: done basie&prompt.root; cat /etc/master.passwd root:[password]:0:0::0:0:The super-user:/root:/bin/csh toor:[password]:0:0::0:0:The other super-user:/root:/bin/sh daemon:*:1:1::0:0:Owner of many system processes:/root:/sbin/nologin operator:*:2:5::0:0:System &:/:/sbin/nologin bin:*:3:7::0:0:Binaries Commands and Source,,,:/:/sbin/nologin tty:*:4:65533::0:0:Tty Sandbox:/:/sbin/nologin kmem:*:5:65533::0:0:KMem Sandbox:/:/sbin/nologin games:*:7:13::0:0:Games pseudo-user:/usr/games:/sbin/nologin news:*:8:8::0:0:News Subsystem:/:/sbin/nologin man:*:9:9::0:0:Mister Man Pages:/usr/share/man:/sbin/nologin bind:*:53:53::0:0:Bind Sandbox:/:/sbin/nologin uucp:*:66:66::0:0:UUCP pseudo-user:/var/spool/uucppublic:/usr/libexec/uucp/uucico xten:*:67:67::0:0:X-10 daemon:/usr/local/xten:/sbin/nologin pop:*:68:6::0:0:Post Office Owner:/nonexistent:/sbin/nologin nobody:*:65534:65534::0:0:Unprivileged user:/nonexistent:/sbin/nologin +::::::::: -bill basie&prompt.root; Udo Erdelhoff Contributed by Using Netgroups netgroups The method shown in the previous chapter works reasonably well if you need special rules for a very small number of users and/or machines. On larger networks, you will forget to bar some users from logging onto sensitive machines, or you may even have to modify each machine separately, thus losing the main benefit of NIS, centralized administration. The NIS developers' solution for this problem is called netgroups. Their purpose and semantics can be compared to the normal groups used by Unix file systems. The main differences are the lack of a numeric id and the ability to define a netgroup by including both user accounts and other netgroups. Netgroups were developed to handle large, complex networks with hundreds of users and machines. On one hand, this is a Good Thing if you are forced to deal with such a situation. On the other hand, this complexity makes it almost impossible to explain netgroups with really simple examples. The example used in the remainder of this chapter demonstrates this problem. Let us assume that your successful introduction of NIS in your laboratory caught your superiors' interest. Your next job is to extend your NIS domain to cover some of the other machines on campus. The two tables contain the names of the new users and new machines as well as brief descriptions of them. User Name(s) Description alpha, beta Normal employees of the IT department charlie, delta The new apprentices of the IT department echo, foxtrott, golf, ... Ordinary employees able, baker, ... The current interns Machine Name(s) Description war, death, famine, pollution Your most important servers. Only the IT employees are allowed to log onto these machines. pride, greed, envy, wrath, lust, sloth Less important servers. All members of the IT department are allowed to login onto these machines. one, two, three, four, ... Ordinary workstations. Only the real employees are allowed to use these machines. trashcan A very old machine without any critical data. Even the intern is allowed to use this box. If you tried to implement these restrictions by separately blocking each user, you would have to add one -user line to each system's passwd for each user who is not allowed to login onto that system. If you forget just one entry, you could be in trouble. It may be feasible to do this correctly during the initial setup, however you will eventually forget to add the lines for new users during day-to-day operations. After all, Murphy was an optimist. Handling this situation with netgroups offers several advantages. Each user need not be handled separately; you assign a user to one or more netgroups and allow or forbid logins for all members of the netgroup. If you add a new machine, you will only have to define login restrictions for netgroups. If a new user is added, you will only have to add the user to one or more netgroups. Those changes are independent of each other; no more for each combination of user and machine do... If your NIS setup is planned carefully, you will only have to modify exactly one central configuration file to grant or deny access to machines. The first step is the initialization of the NIS map netgroup. FreeBSD's &man.ypinit.8; does not create this map by default, but its NIS implementation will support it once it has been created. To create an empty map, simply type ellington&prompt.root; vi /var/yp/netgroup and start adding content. For our example, we need at least four netgroups: IT employees, IT apprentices, normal employees and interns. IT_EMP (,alpha,test-domain) (,beta,test-domain) IT_APP (,charlie,test-domain) (,delta,test-domain) USERS (,echo,test-domain) (,foxtrott,test-domain) \ (,golf,test-domain) INTERNS (,able,test-domain) (,baker,test-domain) IT_EMP, IT_APP etc. are the names of the netgroups. Each bracketed group adds one or more user accounts to it. The three fields inside a group are: The name of the host(s) where the following items are valid. If you do not specify a hostname, the entry is valid on all hosts. If you do specify a hostname, you will enter a realm of darkness, horror and utter confusion. The name of the account that belongs to this netgroup. The NIS domain for the account. You can import accounts from other NIS domains into your netgroup if you are one of unlucky fellows with more than one NIS domain. Each of these fields can contain wildcards. See &man.netgroup.5; for details. netgroups Netgroup names longer than 8 characters should not be used, especially if you have machines running other operating systems within your NIS domain. The names are case sensitive; using capital letters for your netgroup names is an easy way to distinguish between user, machine and netgroup names. Some NIS clients (other than FreeBSD) cannot handle netgroups with a large number of entries. For example, some older versions of SunOS start to cause trouble if a netgroup contains more than 15 entries. You can circumvent this limit by creating several sub-netgroups with 15 users or less and a real netgroup that consists of the sub-netgroups: BIGGRP1 (,joe1,domain) (,joe2,domain) (,joe3,domain) [...] BIGGRP2 (,joe16,domain) (,joe17,domain) [...] BIGGRP3 (,joe31,domain) (,joe32,domain) BIGGROUP BIGGRP1 BIGGRP2 BIGGRP3 You can repeat this process if you need more than 225 users within a single netgroup. Activating and distributing your new NIS map is easy: ellington&prompt.root; cd /var/yp ellington&prompt.root; make This will generate the three NIS maps netgroup, netgroup.byhost and netgroup.byuser. Use &man.ypcat.1; to check if your new NIS maps are available: ellington&prompt.user; ypcat -k netgroup ellington&prompt.user; ypcat -k netgroup.byhost ellington&prompt.user; ypcat -k netgroup.byuser The output of the first command should resemble the contents of /var/yp/netgroup. The second command will not produce output if you have not specified host-specific netgroups. The third command can be used to get the list of netgroups for a user. The client setup is quite simple. To configure the server war, you only have to start &man.vipw.8; and replace the line +::::::::: with +@IT_EMP::::::::: Now, only the data for the users defined in the netgroup IT_EMP is imported into war's password database and only these users are allowed to login. Unfortunately, this limitation also applies to the ~ function of the shell and all routines converting between user names and numerical user ids. In other words, cd ~user will not work, ls -l will show the numerical id instead of the username and find . -user joe -print will fail with No such user. To fix this, you will have to import all user entries without allowing them to login onto your servers. This can be achieved by adding another line to /etc/master.passwd. This line should contain +:::::::::/sbin/nologin, meaning Import all entries but replace the shell with /sbin/nologin in the imported entries. You can replace any field in the passwd entry by placing a default value in your /etc/master.passwd. Make sure that the line +:::::::::/sbin/nologin is placed after +@IT_EMP:::::::::. Otherwise, all user accounts imported from NIS will have /sbin/nologin as their login shell. After this change, you will only have to change one NIS map if a new employee joins the IT department. You could use a similar approach for the less important servers by replacing the old +::::::::: in their local version of /etc/master.passwd with something like this: +@IT_EMP::::::::: +@IT_APP::::::::: +:::::::::/sbin/nologin The corresponding lines for the normal workstations could be: +@IT_EMP::::::::: +@USERS::::::::: +:::::::::/sbin/nologin And everything would be fine until there is a policy change a few weeks later: The IT department starts hiring interns. The IT interns are allowed to use the normal workstations and the less important servers; and the IT apprentices are allowed to login onto the main servers. You add a new netgroup IT_INTERN, add the new IT interns to this netgroup and start to change the config on each and every machine... As the old saying goes: Errors in centralized planning lead to global mess. NIS' ability to create netgroups from other netgroups can be used to prevent situations like these. One possibility is the creation of role-based netgroups. For example, you could create a netgroup called BIGSRV to define the login restrictions for the important servers, another netgroup called SMALLSRV for the less important servers and a third netgroup called USERBOX for the normal workstations. Each of these netgroups contains the netgroups that are allowed to login onto these machines. The new entries for your NIS map netgroup should look like this: BIGSRV IT_EMP IT_APP SMALLSRV IT_EMP IT_APP ITINTERN USERBOX IT_EMP ITINTERN USERS This method of defining login restrictions works reasonably well if you can define groups of machines with identical restrictions. Unfortunately, this is the exception and not the rule. Most of the time, you will need the ability to define login restrictions on a per-machine basis. Machine-specific netgroup definitions are the other possibility to deal with the policy change outlined above. In this scenario, the /etc/master.passwd of each box contains two lines starting with ``+''. The first of them adds a netgroup with the accounts allowed to login onto this machine, the second one adds all other accounts with /sbin/nologin as shell. It is a good idea to use the ALL-CAPS version of the machine name as the name of the netgroup. In other words, the lines should look like this: +@BOXNAME::::::::: +:::::::::/sbin/nologin Once you have completed this task for all your machines, you will not have to modify the local versions of /etc/master.passwd ever again. All further changes can be handled by modifying the NIS map. Here is an example of a possible netgroup map for this scenario with some additional goodies. # Define groups of users first IT_EMP (,alpha,test-domain) (,beta,test-domain) IT_APP (,charlie,test-domain) (,delta,test-domain) DEPT1 (,echo,test-domain) (,foxtrott,test-domain) DEPT2 (,golf,test-domain) (,hotel,test-domain) DEPT3 (,india,test-domain) (,juliet,test-domain) ITINTERN (,kilo,test-domain) (,lima,test-domain) D_INTERNS (,able,test-domain) (,baker,test-domain) # # Now, define some groups based on roles USERS DEPT1 DEPT2 DEPT3 BIGSRV IT_EMP IT_APP SMALLSRV IT_EMP IT_APP ITINTERN USERBOX IT_EMP ITINTERN USERS # # And a groups for a special tasks # Allow echo and golf to access our anti-virus-machine SECURITY IT_EMP (,echo,test-domain) (,golf,test-domain) # # machine-based netgroups # Our main servers WAR BIGSRV FAMINE BIGSRV # User india needs access to this server POLLUTION BIGSRV (,india,test-domain) # # This one is really important and needs more access restrictions DEATH IT_EMP # # The anti-virus-machine mentioned above ONE SECURITY # # Restrict a machine to a single user TWO (,hotel,test-domain) # [...more groups to follow] If you are using some kind of database to manage your user accounts, you should be able to create the first part of the map with your database's report tools. This way, new users will automatically have access to the boxes. One last word of caution: It may not always be advisable to use machine-based netgroups. If you are deploying a couple dozen or even hundreds of identical machines for student labs, you should use role-based netgroups instead of machine-based netgroups to keep the size of the NIS map within reasonable limits. Important Things to Remember There are still a couple of things that you will need to do differently now that you are in an NIS environment. Every time you wish to add a user to the lab, you must add it to the master NIS server only, and you must remember to rebuild the NIS maps. If you forget to do this, the new user will not be able to login anywhere except on the NIS master. For example, if we needed to add a new user “jsmith” to the lab, we would: &prompt.root; pw useradd jsmith &prompt.root; cd /var/yp &prompt.root; make test-domain You could also run adduser jsmith instead of pw useradd jsmith. Keep the administration accounts out of the NIS - maps. You don't want to be propagating administrative + maps. You do not want to be propagating administrative accounts and passwords to machines that will have users that - shouldn't have access to those accounts. + should not have access to those accounts. Keep the NIS master and slave secure, and minimize their downtime. If somebody either hacks or simply turns off these machines, they have effectively rendered many people without the ability to login to the lab. This is the chief weakness of any centralized administration system, and it is probably the most important weakness. If you do not protect your NIS servers, you will have a lot of angry users! NIS v1 Compatibility FreeBSD's ypserv has some support for serving NIS v1 clients. FreeBSD's NIS implementation only uses the NIS v2 protocol, however other implementations include support for the v1 protocol for backwards compatibility with older systems. The ypbind daemons supplied with these systems will try to establish a binding to an NIS v1 server even though they may never actually need it (and they may persist in broadcasting in search of one even after they receive a response from a v2 server). Note that while support for normal client calls is provided, this version of ypserv does not handle v1 map transfer requests; consequently, it cannot be used as a master or slave in conjunction with older NIS servers that only support the v1 protocol. Fortunately, there probably are not any such servers still in use today. NIS Servers that are also NIS Clients Care must be taken when running ypserv in a multi-server domain where the server machines are also NIS clients. It is generally a good idea to force the servers to bind to themselves rather than allowing them to broadcast bind requests and possibly become bound to each other. Strange failure modes can result if one server goes down and others are dependent upon on it. Eventually all the clients will time out and attempt to bind to other servers, but the delay involved can be considerable and the failure mode is still present since the servers might bind to each other all over again. You can force a host to bind to a particular server by running ypbind with the flag. libscrypt v.s. libdescrypt NIS crypto library One of the most common issues that people run into when trying to implement NIS is crypt library compatibility. If your NIS server is using the DES crypt libraries, it will only support clients that are using DES as well. To check which one your server and clients are using look at the symlinks in /usr/lib. If the machine is configured to use the DES libraries, it will look something like this: &prompt.user; ls -l /usr/lib/*crypt* lrwxrwxrwx 1 root wheel 13 Jul 15 08:55 libcrypt.a@ -> libdescrypt.a lrwxrwxrwx 1 root wheel 14 Jul 15 08:55 libcrypt.so@ -> libdescrypt.so lrwxrwxrwx 1 root wheel 16 Jul 15 08:55 libcrypt.so.2@ -> libdescrypt.so.2 lrwxrwxrwx 1 root wheel 15 Jul 15 08:55 libcrypt_p.a@ -> libdescrypt_p.a -r--r--r-- 1 root wheel 13018 Nov 8 14:27 libdescrypt.a lrwxr-xr-x 1 root wheel 16 Nov 8 14:27 libdescrypt.so@ -> libdescrypt.so.2 -r--r--r-- 1 root wheel 12965 Nov 8 14:27 libdescrypt.so.2 -r--r--r-- 1 root wheel 14750 Nov 8 14:27 libdescrypt_p.a If the machine is configured to use the standard FreeBSD MD5 crypt libraries they will look something like this: &prompt.user; ls -l /usr/lib/*crypt* lrwxrwxrwx 1 root wheel 13 Jul 15 08:55 libcrypt.a@ -> libscrypt.a lrwxrwxrwx 1 root wheel 14 Jul 15 08:55 libcrypt.so@ -> libscrypt.so lrwxrwxrwx 1 root wheel 16 Jul 15 08:55 libcrypt.so.2@ -> libscrypt.so.2 lrwxrwxrwx 1 root wheel 15 Jul 15 08:55 libcrypt_p.a@ -> libscrypt_p.a -r--r--r-- 1 root wheel 6194 Nov 8 14:27 libscrypt.a lrwxr-xr-x 1 root wheel 14 Nov 8 14:27 libscrypt.so@ -> libscrypt.so.2 -r--r--r-- 1 root wheel 7579 Nov 8 14:27 libscrypt.so.2 -r--r--r-- 1 root wheel 6684 Nov 8 14:27 libscrypt_p.a If you have trouble authenticating on an NIS client, this is a pretty good place to start looking for possible problems. If you want to deploy an NIS server for a heterogenous network, you will probably have to use DES on all systems because it is the lowest common standard. Greg Sutter Written by DHCP What Is DHCP? Dynamic Host Configuration Protocol DHCP Internet Software Consortium (ISC) DHCP, the Dynamic Host Configuration Protocol, describes the means by which a system can connect to a network and obtain the necessary information for communication upon that network. FreeBSD uses the ISC (Internet Software Consortium) DHCP implementation, so all implementation-specific information here is for use with the ISC distribution. What this Section Covers This handbook section attempts to describe only the parts of the DHCP system that are integrated with FreeBSD; consequently, the server portions are not described. The DHCP manual pages, in addition to the references below, are useful resources. How It Works UDP When dhclient, the DHCP client, is executed on the client machine, it begins broadcasting requests for configuration information. By default, these requests are on UDP port 68. The server replies on UDP 67, giving the client an IP address and other relevant network information such as netmask, router, and DNS servers. All of this information comes in the form of a DHCP "lease" and is only valid for a certain time (configured by the DHCP server maintainer). In this manner, stale IP addresses for clients no longer connected to the network can be automatically reclaimed. DHCP clients can obtain a great deal of information from the server. An exhaustive list may be found in &man.dhcp-options.5;. FreeBSD Integration FreeBSD fully integrates the ISC DHCP client, dhclient. DHCP client support is provided within both the installer and the base system, obviating the need for detailed knowledge of network configurations on any network that runs a DHCP server. dhclient has been included in all FreeBSD distributions since 3.2. sysinstall DHCP is supported by sysinstall. When configuring a network interface within sysinstall, the first question asked is, "Do you want to try DHCP configuration of this interface?" Answering affirmatively will execute dhclient, and if successful, will fill in the network configuration information automatically. There are two things you must do to have your system use DHCP upon startup: DHCP requirements Make sure that the bpf device is compiled into your kernel. To do this, add pseudo-device bpf to your kernel configuration file, and rebuild the kernel. For more information about building kernels, see . The bpf device is already part of the GENERIC kernel that is - supplied with FreeBSD, so if you don't have a custom - kernel, you shouldn't need to create one in order to get + supplied with FreeBSD, so if you do not have a custom + kernel, you should not need to create one in order to get DHCP working. For those who are particularly security conscious, you should be warned that bpf is also the device that allows packet sniffers to work correctly (although they still have to be run as root). bpf is required to use DHCP, but if you are very sensitive about security, you probably - shouldn't add bpf to your + should not add bpf to your kernel in the expectation that at some point in the future you will be using DHCP. Edit your /etc/rc.conf to include the following: ifconfig_fxp0="DHCP" Be sure to replace fxp0 with the designation for the interface that you wish to dynamically configure. If you are using a different location for dhclient, or if you wish to pass additional flags to dhclient, also include the following (editing as necessary): dhcp_program="/sbin/dhclient" dhcp_flags="" DHCP server The DHCP server, dhcpd, is included as part of the isc-dhcp2 port in the ports collection. This port contains the full ISC DHCP distribution, consisting of client, server, relay agent and documentation. Files DHCP configuration files /etc/dhclient.conf dhclient requires a configuration file, /etc/dhclient.conf. Typically the file contains only comments, the defaults being reasonably sane. This configuration file is described by the &man.dhclient.conf.5; manual page. /sbin/dhclient dhclient is statically linked and resides in /sbin. The &man.dhclient.8; manual page gives more information about dhclient. /sbin/dhclient-script dhclient-script is the FreeBSD-specific DHCP client configuration script. It is described in &man.dhclient-script.8;, but should not need any user modification to function properly. /var/db/dhclient.leases The DHCP client keeps a database of valid leases in this file, which is written as a log. &man.dhclient.leases.5; gives a slightly longer description. Further Reading The DHCP protocol is fully described in RFC 2131. An informational resource has also been set up at dhcp.org. Chern Lee Contributed by DNS Overview BIND FreeBSD utilizes, by default, a version of BIND (Berkeley Internet Name Domain), which is the most common implementation of the DNS protocol. DNS is the protocol through which names are mapped to IP addresses, and vice versa. For example, a query for www.FreeBSD.org will receive a reply with the IP address of The FreeBSD Project's web server, whereas, a query for ftp.FreeBSD.org will return the IP address of the corresponding FTP machine. Likewise, the opposite can happen. A query for an IP address can resolve its hostname. It is not necessary to run a name server to perform DNS lookups on a system. DNS DNS is coordinated across the Internet through a somewhat complex system of authoritative root name servers, and other smaller-scale name servers who host and cache individual domain information. This document refers to BIND 8.x, as it is the stable version used in FreeBSD. BIND 9.x in FreeBSD can be installed through the net/bind9 port. RFC1034 and RFC1035 dictates the DNS protocol. Currently, BIND is maintained by the Internet Software Consortium (www.isc.org) Terminology To understand this document, some terms related to DNS must be understood. Term Definition forward DNS mapping of hostnames to IP addresses origin refers to the domain covered for the particular zone file named, bind, name server common names for the BIND name server package within FreeBSD resolver resolver a system process through which a machine queries a name server for zone information reverse DNS reverse DNS the opposite of forward DNS, mapping of IP addresses to hostnames root zone root zone literally, a ., refers to the root, or beginning zone. All zones fall under this, as do all files in fall under the root directory. It is the beginning of the Internet zone hierarchy. zone Each individual domain, subdomain, or area dictated by DNS zones examples Examples of zones: . is the root zone org. is a zone under the root zone foobardomain.org is a zone under the org. zone foo.foobardomain.org. is a subdomain, a zone under the foobardomain.org. zone 1.2.3.in-addr.arpa is a zone referencing all IP addresses which fall under the 3.2.1.* IP space. As one can see, the more specific part of a hostname appears to its left. For example, foobardomain.org. is more specific than org., as org. is more specific than the root zone. The layout of each part of a hostname is much like a filesystem: the /dev directory falls within the root, and so on. Reasons to Run a Name Server Name servers usually come in two forms: an authoritative name server, and a caching name server. An authoritative name server is needed when: one wants to serve DNS information to the world, replying authoritatively to queries. a domain, such as foobardomain.org, is registered and IP addresses need to be assigned to hostnames under it. an IP address block requires reverse DNS entries (IP to hostname). a backup name server, called a slave, must reply to queries when the primary is down or inaccessible. A caching name server is needed when: a local DNS server may cache and respond more quickly then querying an outside name server. a reduction in overall network traffic is desired. (DNS traffic has been measured to account for 5% or more of total Internet traffic) When one queries for www.FreeBSD.org, the resolver usually queries the uplink ISP's name server, and retrieves the reply. With a local, caching DNS server, the query only has to be made once to the outside world by the caching DNS server. Every additional query will not have to look to the outside of the local network, since the information is cached locally. How It Works In FreeBSD, the BIND daemon is called named for obvious reasons. File Description named the BIND daemon ndc name daemon control program /etc/namedb directory where BIND zone information resides /etc/namedb/named.conf daemon configuration file Zone files are usually contained within the /etc/namedb directory, and contain the DNS zone information served by the name server. Starting BIND BIND starting Since BIND is installed by default, configuring it all is relatively simple. To ensure the named daemon is started at boot, put the following modifications in /etc/rc.conf: named_enable="YES" To start the daemon manually (after configuring it) &prompt.root; ndc start Configuration Files BIND configuration files make-localhost Be sure to: &prompt.root; cd /etc/namedb &prompt.root; sh make-localhost to properly create the local reverse DNS zone file in /etc/namedb/localhost.rev. <filename>/etc/namedb/named.conf</filename> // $FreeBSD$ // // Refer to the named(8) manual page for details. If you are ever going // to setup a primary server, make sure you've understood the hairy // details of how DNS is working. Even with simple mistakes, you can // break connectivity for affected parties, or cause huge amount of // useless Internet traffic. options { directory "/etc/namedb"; // In addition to the "forwarders" clause, you can force your name // server to never initiate queries of its own, but always ask its // forwarders only, by enabling the following line: // // forward only; // If you've got a DNS server around at your upstream provider, enter // its IP address here, and enable the line below. This will make you // benefit from its cache, thus reduce overall DNS traffic in the Internet. /* forwarders { 127.0.0.1; }; */ Just as the comment says, to benefit from an uplink's cache, forwarders can be enabled here. Under normal circumstances, a name server will recursively query the Internet looking at certain name servers until it finds the answer it is looking for. Having this enabled will have it query the uplink's name server (or name server provided) first, taking advantage of its cache. If the uplink name server in question is a heavily trafficked, fast name server, enabling this may be worthwhile. 127.0.0.1 will not work here. Change this IP address to a name server at your uplink. /* * If there is a firewall between you and name servers you want * to talk to, you might need to uncomment the query-source * directive below. Previous versions of BIND always asked * questions using port 53, but BIND 8.1 uses an unprivileged * port by default. */ // query-source address * port 53; /* * If running in a sandbox, you may have to specify a different * location for the dumpfile. */ // dump-file "s/named_dump.db"; }; // Note: the following will be supported in a future release. /* host { any; } { topology { 127.0.0.0/8; }; }; */ // Setting up secondaries is way easier and the rough picture for this // is explained below. // // If you enable a local name server, don't forget to enter 127.0.0.1 // into your /etc/resolv.conf so this server will be queried first. // Also, make sure to enable it in /etc/rc.conf. zone "." { type hint; file "named.root"; }; zone "0.0.127.IN-ADDR.ARPA" { type master; file "localhost.rev"; }; zone "0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.IP6.INT" { type master; file "localhost.rev"; }; // NB: Do not use the IP addresses below, they are faked, and only // serve demonstration/documentation purposes! // // Example secondary config entries. It can be convenient to become // a secondary at least for the zone where your own domain is in. Ask // your network administrator for the IP address of the responsible // primary. // // Never forget to include the reverse lookup (IN-ADDR.ARPA) zone! // (This is the first bytes of the respective IP address, in reverse // order, with ".IN-ADDR.ARPA" appended.) // // Before starting to setup a primary zone, better make sure you fully // understand how DNS and BIND works, however. There are sometimes // unobvious pitfalls. Setting up a secondary is comparably simpler. // // NB: Don't blindly enable the examples below. :-) Use actual names // and addresses instead. // // NOTE!!! FreeBSD runs bind in a sandbox (see named_flags in rc.conf). // The directory containing the secondary zones must be write accessible // to bind. The following sequence is suggested: // // mkdir /etc/namedb/s // chown bind:bind /etc/namedb/s // chmod 750 /etc/namedb/s For more information on running BIND in a sandbox, see Running named in a sandbox. /* zone "domain.com" { type slave; file "s/domain.com.bak"; masters { 192.168.1.1; }; }; zone "0.168.192.in-addr.arpa" { type slave; file "s/0.168.192.in-addr.arpa.bak"; masters { 192.168.1.1; }; }; */ In named.conf, these are examples of slave entries for a forward and reverse zone. For each new zone served, a new zone entry must be added to named.conf For example, the simplest zone entry for foobardomain.org can look like: zone "foobardomain.org" { type master; file "foobardomain.org"; }; The zone is a master, as indicated by the statement, holding its zone information in /etc/namedb/foobardomain.org indicated by the statement. zone "foobardomain.org" { type slave; file "foobardomain.org"; }; In the slave case, the zone information is transferred from the master name server for the particular zone, and saved in the file specified. If and when the master server dies or is unreachable, the slave name server will have the transferred zone information and will be able to serve it. Zone Files An example master zone file for foobardomain.org (existing within /etc/namedb/foobardomain.org) is as follows: $TTL 3600 foobardomain.org. IN SOA ns1.foobardomain.org. admin.foobardomain.org. ( 5 ; Serial 10800 ; Refresh 3600 ; Retry 604800 ; Expire 86400 ) ; Minimum TTL ; DNS Servers @ IN NS ns1.foobardomain.org. @ IN NS ns2.foobardomain.org. ; Machine Names localhost IN A 127.0.0.1 ns1 IN A 3.2.1.2 ns2 IN A 3.2.1.3 mail IN A 3.2.1.10 @ IN A 3.2.1.30 ; Aliases www IN CNAME @ ; MX Record @ IN MX 10 mail.foobardomain.org. Note that every hostname ending in a . is an exact hostname, whereas everything without a trailing . is referenced to the origin. For example, www is translated into www + origin. In our fictitious zone file, our origin is foobardomain.org., so www would translate to www.foobardomain.org. The format of a zone file follows: recordname IN recordtype value DNS records The most commonly used DNS records: SOA start of zone authority NS an authoritative name server A A host address CNAME the canonical name for an alias MX mail exchange PTR a domain name pointer (used in reverse DNS) foobardomain.org. IN SOA ns1.foobardomain.org. admin.foobardomain.org. ( 5 ; Serial 10800 ; Refresh after 3 hours 3600 ; Retry after 1 hour 604800 ; Expire after 1 week 86400 ) ; Minimum TTL of 1 day foobardomain.org. the domain name, also the origin for this zone file. ns1.foobardomain.org. the primary/authoritative name server for this zone admin.foobardomain.org. the responsible person for this zone, email address with @ replaced. (admin@foobardomain.org becomes admin.foobardomain.org) 5 the serial number of the file. this must be incremented each time the zone file is modified. Nowadays, many admins prefer a yyyymmddrr format for the serial number. 2001041002 would mean last modified 04/10/2001, the latter 02 being the second time the zone file has been modified this day. The serial number is important as it alerts slave name servers for a zone when it is updated. @ IN NS ns1.foobardomain.org. This is an NS entry. Every name server that is going to reply authoritatively for the zone must have one of these entries. The @ as seen here could have been foobardomain.org. The @ translates to the origin. localhost IN A 127.0.0.1 ns1 IN A 3.2.1.2 ns2 IN A 3.2.1.3 mail IN A 3.2.1.10 @ IN A 3.2.1.30 The A record indicates machine names. As seen above, ns1.foobardomain.org would resolve to 3.2.1.2. Again, the origin symbol, @, is used here, thus meaning foobardomain.org would resolve to 3.2.1.30. www IN CNAME @ The canonical name record is usually used for giving aliases to a machine. In the example, www is aliased to the machine addressed to the origin, or foobardomain.org (3.2.1.30). CNAMEs can be used to provide alias hostnames, or round robin one hostname among multiple machines. @ IN MX 10 mail.foobardomain.org. The MX record indicates which mail servers are responsible for handling incoming mail for the zone. mail.foobardomain.org is the hostname of the mail server, and 10 being the priority of that mail server. One can have several mail servers, with priorities of 3, 2, 1. A mail server attempting to deliver to foobardomain.org would first try the highest priority MX, then the second highest, etc, until the mail can be properly delivered. For in-addr.arpa zone files (reverse DNS), the same format is used, except with PTR entries instead of A or CNAME. $TTL 3600 1.2.3.in-addr.arpa. IN SOA ns1.foobardomain.org. admin.foobardomain.org. ( 5 ; Serial 10800 ; Refresh 3600 ; Retry 604800 ; Expire 3600 ) ; Minimum @ IN NS ns1.foobardomain.org. @ IN NS ns2.foobardomain.org. 2 IN PTR ns1.foobardomain.org. 3 IN PTR ns2.foobardomain.org. 10 IN PTR mail.foobardomain.org. 30 IN PTR foobardomain.org. This file gives the proper IP address to hostname mappings of our above fictitious domain. Caching Name Server BIND caching name server A caching name server is a name server that is not authoritative for any zones. It simply asks queries of its own, and remembers them for later use. To set one up, just configure the name server as usual, omitting any inclusions of zones. Mike Makonnen Contributed by Running named in a Sandbox BIND running in a sandbox chroot For added security you may want to run &man.named.8; in a sandbox. This will reduce the potential damage should it be compromised. If you include a sandbox directory in its command line, named will &man.chroot.8; into that directory immediately upon finishing processing its command line. It is also a good idea to have named run as a non-privileged user in the sandbox. The default FreeBSD install contains a user bind with group bind. If we wanted the sandbox in the /etc/namedb/sandbox directory the command line for named would look like this: &prompt.root; /usr/sbin/named -u bind -g bind -t /etc/namedb/sandbox <path_to_named.conf> The following steps should be taken in order to successfully run named in a sandbox. Throughout the following discussion we will assume the path to your sandbox is /etc/namedb/sandbox Create the sandbox directory: /etc/namedb/sandbox Create other necessary directories off of the sandbox directory: etc and var/run copy /etc/localtime to sandbox/etc make bind:bind the owner of all files and directories in the sandbox: &prompt.root; chown -R bind:bind /etc/namedb/sandbox &prompt.root; chmod -R 750 /etc/namedb/sandbox There are some issues you need to be aware of when running named in a sandbox. Your &man.named.conf.5; file and all your zone files must be in the sandbox sandbox/etc/localtime is needed in order to have the correct time for your time zone in log messages. &man.named.8; will write its process id to a file in sandbox/var/run The Unix socket used for communication by the &man.ndc.8; utility will be created in sandbox/var/run When using the &man.ndc.8; utility you need to specify the location of the Unix socket created in the sandbox, by &man.named.8;, by using the -c switch: &prompt.root; ndc -c /etc/namedb/sandbox/var/run/ndc If you enable logging to file, the log files must be in the sandbox &man.named.8; can be started in a sandbox properly, if the following is in /etc/rc.conf: named_flags="-u bind -g bind -t /etc/namedb/sandbox <path_to_named.conf>" How to Use the Name Server If setup properly, the name server should be accessible through the network and locally. /etc/resolv.conf must contain a name server entry with the local IP address so it will query the local name server first. To access it over the network, the machine must have the name server's IP address set properly in its own name server configuration options. Security Although BIND is the most common implementation of DNS, there is always the issue of security. Possible and exploitable security holes are sometimes found. It is a good idea to subscribe to CERT and freebsd-announce to stay up to date with the current Internet and FreeBSD security issues. If a problem arises, keeping sources up to date and having a fresh build of named would not hurt. Further Reading BIND/named manual pages: &man.ndc.8; &man.named.8; &man.named.conf.5; Official ISC Bind Page BIND FAQ O'Reilly DNS and BIND 4th Edition RFC1034 - Domain Names - Concepts and Facilities RFC1035 - Domain Names - Implementation and Specification Chern Lee Contributed by Network Address Translation Overview natd FreeBSD's Network Address Translation daemon, commonly known as &man.natd.8; is a daemon that accepts incoming raw IP packets, changes the source to the local machine and re-injects these packets back into the outgoing IP packet stream. natd does this by changing the source IP address and port such that when data is received back, it is able to determine the original location of the data and forward it back to its original requester. Internet connection sharing IP masquerading The most common use of NAT is to perform what is commonly known as Internet Connection Sharing. Setup Due to the diminishing IP space in IPv4, and the increased number of users on high-speed consumer lines such as cable or DSL, people are in more and more need of an Internet Connection Sharing solution. The ability to connect several computers online through one connection and IP address makes &man.natd.8; a reasonable choice. Most commonly, a user has a machine connected to a cable or DSL line with one IP address and wishes to use this one connected computer to provide Internet access to several more over a LAN. To do this, the FreeBSD machine on the Internet must act as a gateway. This gateway machine must have two NICs--one for connecting to the Internet router, the other connecting to a LAN. All the machines on the LAN are connected through a hub or switch. _______ __________ ________ | | | | | | | Hub |-----| Client B |-----| Router |----- Internet |_______| |__________| |________| | ____|_____ | | | Client A | |__________| Network Layout With this setup, the machine without Internet access can use the machine with access as a gateway to access the outside world. kernel configuration Configuration The following options must be in the kernel configuration file: options IPFIREWALL options IPDIVERT Additionally, at choice, the following may also be suitable: options IPFIREWALL_DEFAULT_TO_ACCEPT options IPFIREWALL_VERBOSE The following must be in /etc/rc.conf: gateway_enable="YES" firewall_enable="YES" firewall_type="OPEN" natd_enable="YES" natd_interface="fxp0" natd_flags="" gateway_enable="YES" Sets up the machine to act as a gateway. Running sysctl -w net.inet.ip.forwarding=1 would have the same effect. firewall_enable="YES" Enables the firewall rules in /etc/rc.firewall at boot. firewall_type="OPEN" This specifies a predefined firewall ruleset that allows anything in. See /etc/rc.firewall for additional types. natd_interface="fxp0" Indicates which interface to forward packets through. (the interface connected to the Internet) natd_flags="" Any additional configuration options passed to &man.natd.8; on boot. Having the previous options defined in /etc/rc.conf would run natd -interface fxp0 at boot. This can also be run manually. Each machine and interface behind the LAN should be assigned IP address numbers in the private network space as defined by RFC 1918 and have a default gateway of the natd machine's internal IP address. For example, client a and b behind the LAN have IP addresses of 192.168.0.2 and 192.168.0.3, while the natd machine's LAN interface has an IP address of 192.168.0.1. Client a and b's default gateway must be set to that of the natd machine, 192.168.0.1. The natd machine's external, or Internet interface does not require any special modification for natd to work. Port Redirection The drawback with natd is that the LAN clients are not accessible from the Internet. Clients on the LAN can make outgoing connections to the world but cannot receive incoming ones. This presents a problem if trying to run Internet services on one of the LAN client machines. A simple way around this is to redirect selected Internet ports on the natd machine to a LAN client. For example, an IRC server runs on Client A, and a web server runs on Client B. For this to work properly, connections received on ports 6667 (irc) and 80 (web) must be redirected to the respective machines. The -redirect_port must be passed to &man.natd.8; with the proper options. The syntax is as follows: -redirect_port proto targetIP:targetPORT[-targetPORT] [aliasIP:]aliasPORT[-aliasPORT] [remoteIP[:remotePORT[-remotePORT]]] In the above example, the argument should be: -redirect_port tcp 192.168.0.2:6667 6667 -redirect_port tcp 192.168.0.3:80 80 This will redirect the proper tcp ports to the LAN client machines. The -redirect_port argument can be used to indicate port ranges over individual ports. For example, tcp 192.168.0.2:2000-3000 2000-3000 would redirect all connections received on ports 2000 to 3000 to ports 2000 to 3000 on Client A. These options can be used when directly running &man.natd.8; or placed within the natd_flags="" option in /etc/rc.conf. For further configuration options, consult &man.natd.8; Address Redirection address redirection Address redirection is useful if several IP addresses are available, yet they must be on one machine. With this, &man.natd.8; can assign each LAN client its own external IP address. &man.natd.8; then rewrites outgoing packets from the LAN clients with the proper external IP address and redirects all traffic incoming on that particular IP address back to the specific LAN client. This is also known as static NAT. For example, the IP addresses 128.1.1.1, 128.1.1.2, and 128.1.1.3 belong to the natd gateway machine. 128.1.1.1 can be used as the natd gateway machine's external IP address, while 128.1.1.2 and 128.1.1.3 are forwarded back to LAN clients A and B. The -redirect_address syntax is as follows: localIP The internal IP address of the LAN client. publicIP The external IP address corresponding to the LAN client. In the example, this argument would read: Like -redirect_port, these arguments are also placed within natd_flags of /etc/rc.conf. With address redirection, there is no need for port redirection since all data received on a particular IP address is redirected. The external IP addresses on the natd machine must be active and aliased to the external interface. Look at &man.rc.conf.5; to do so. Chern Lee Contributed by inetd <quote>Super-Server</quote> Overview &man.inetd.8; is referred to as the Internet Super-Server because it manages connections for several daemons. Programs that provide network service are commonly known as daemons. inetd serves as a managing server for other daemons. When a connection is received by inetd, it determines which daemon the connection is destined for, spawns the particular daemon and delegates the socket to it. Running one instance of inetd reduces the overall system load as compared to running each daemon individually in stand-alone mode. Primarily, inetd is used to spawn other daemons, but several trivial protocols are handled directly, such as chargen, auth, and daytime. This section will cover the basics in configuring inetd through its command-line - options and it's configuration file, + options and its configuration file, /etc/inetd.conf. Settings inetd is initialized through the /etc/rc.conf system. The inetd_enable option is set to NO by default, but is often times turned on by sysinstall with the medium security profile. Placing: inetd_enable="YES" or inetd_enable="NO" into /etc/rc.conf can enable or disable inetd starting at boot time. Additionally, different command-line options can be passed to inetd via the inetd_flags option. Command-Line Options inetd sypnosis: -d Turn on debugging. -l Turn on logging of successful connections. -w Turn on TCP Wrapping for external services. (on by default) -W Turn on TCP Wrapping for internal services which are built in to inetd. (on by default) -c maximum Specify the default maximum number of simultaneous invocations of each service; the default is unlimited. May be overridden on a per-service basis with the parameter. -C rate Specify the default maximum number of times a service can be invoked from a single IP address in one minute; the default is unlimited. May be overridden on a per-service basis with the parameter. -R rate Specify the maximum number of times a service can be invoked in one minute; the default is 256. A rate of 0 allows an unlimited number of invocations. -a Specify one specific IP address to bind to. Alternatively, a hostname can be specified, in which case the IPv4 or IPv6 address which corresponds to that hostname is used. Usually a hostname is specified when inetd is run inside a &man.jail.8;, in which case the hostname corresponds to the &man.jail.8; environment. When hostname specification is used and both IPv4 and IPv6 bindings are desired, one entry with the appropriate protocol type for each binding is required for each service in /etc/inetd.conf. For example, a TCP-based service would need two entries, one using ``tcp4'' for the protocol and the other using ``tcp6''. -p Specify an alternate file in which to store the process ID. These options can be passed to inetd using the inetd_flags option in /etc/rc.conf. By default, inetd_flags is set to -wW, which turns on TCP wrapping for inetd's internal and external services. For novice users, these parameters usually do not need to be modified or even entered in /etc/rc.conf An external service is a daemon outside of inetd, which is invoked when a connection is received for it. On the other hand, an internal service is one that inetd has the facility of offering within itself. <filename>inetd.conf</filename> Configuration of inetd is controlled through the /etc/inetd.conf file. When a modification is made to /etc/inetd.conf, inetd can be forced to re-read its configuration file by sending a HangUP signal to the inetd process as shown: Sending <application>inetd</application> a HangUP Signal &prompt.root kill -HUP `cat /var/run/inetd.pid` Each line of the configuration file specifies an individual daemon. Comments in the file are preceded by a #. The format of /etc/inetd.conf is as follows: service-name socket-type protocol {wait|nowait}[/max-child[/max-connections-per-ip-per-minute]] user[:group][/login-class] server-program server-program-arguments An example entry for the ftpd daemon using IPv4: ftp stream tcp nowait root /usr/libexec/ftpd ftpd -l service-name This is the service name of the particular daemon. It must correspond to a service listed in /etc/services. This determines which port inetd must listen to. If a new service is being created, it must be placed in /etc/services first. socket-type Either stream, dgram, raw, or seqpacket. stream must be used for connection-based, TCP daemons, while dgram is used for daemons utilizing the UDP transport protocol. protocol One of the following: Protocol Explanation tcp, tcp4 TCP IPv4 udp, udp4 UDP IPv4 tcp6 TCP IPv6 udp6 UDP IPv6 tcp46 Both TCP IPv4 and v6 udp46 Both UDP IPv4 and v6 {wait|nowait}[/max-child[/max-connections-per-ip-per-minute]] indicates whether the daemon invoked from inetd is able to handle its own socket or not. socket types must use the wait option, while stream socket daemons, which are usually multi-threaded, should use . usually hands off multiple sockets to a single daemon, while spawns a child daemon for each new socket. The maximum number of child daemons inetd may spawn can be set using the option. If a limit of ten instances of a particular daemon is needed, a /10 would be placed after . In addition to another option limiting the maximum connections from a single place to a particular daemon can be enabled. does just this. A value of ten here would limit any particular IP address connecting to a particular service to ten attempts per minute. This is useful to prevent intentional or unintentional resource consumption and Denial of Service (DoS) attacks to a machine. In this field, or is mandatory. and are optional. A stream-type multi-threaded daemon without any or limits would simply be: nowait The same daemon with a maximum limit of ten daemons would read: nowait/10 Additionally, the same setup with a limit of twenty connections per IP address per minute and a maximum total limit of ten child daemons would read: nowait/10/20 These options are all utilized by the default settings of the fingerd daemon, as seen here: finger stream tcp nowait/3/10 nobody /usr/libexec/fingerd fingerd -s user The user is the username that the particular daemon should run as. Most commonly, daemons run as the root user. For security purposes, it is common to find some servers running as the daemon user, or the least privileged nobody user. server-program The full path of the daemon to be executed when a connection is received. If the daemon is a service provided by inetd internally, then should be used. server-program-arguments This works in conjunction with by specifying the arguments, starting with argv[0], passed to the daemon on invocation. If mydaemon -d is the command line, mydaemon -d would be the value of . Again, if the daemon is an internal service, use here. Security Depending on the security profile chosen at install, many of inetd's daemons may be enabled by default. If there is no apparent need for a particular daemon, disable it! Place a # in front of the daemon in question, and send a hangup signal to inetd. Some daemons, such as fingerd, may not be desired at all because they provide an attacker with too much information. Some daemons are not security-conscious and have long, or non-existent timeouts for connection attempts. This allows an attacker to slowly send connections to a particular daemon, thus saturating available resources. It may be a good idea to place and limitations on certain daemons. By default, TCP wrapping is turned on. Consult the &man.hosts.access.5; manual page for more information on placing TCP restrictions on various inetd invoked daemons. Miscellaneous daytime, time, echo, discard, chargen, and auth are all internally provided services of inetd. The auth service provides identity (ident, identd) network services, and is configurable to a certain degree. Consult the &man.inetd.8; manual page for more in-depth information. diff --git a/en_US.ISO8859-1/books/handbook/backups/chapter.sgml b/en_US.ISO8859-1/books/handbook/backups/chapter.sgml index d79c73d45e..7414f9fc09 100644 --- a/en_US.ISO8859-1/books/handbook/backups/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/backups/chapter.sgml @@ -1,850 +1,850 @@ Backups Synopsis The following chapter will cover methods of backing up data, and the programs used to create those backups. Tape Media tape media The major tape media are the 4mm, 8mm, QIC, mini-cartridge and DLT. 4mm (DDS: Digital Data Storage) tape media DDS (4mm) tapes tape media QIC tapes 4mm tapes are replacing QIC as the workstation backup media of choice. This trend accelerated greatly when Conner purchased Archive, a leading manufacturer of QIC drives, and then stopped production of QIC drives. 4mm drives are small and quiet but do not have the reputation for reliability that is enjoyed by 8mm drives. The cartridges are less expensive and smaller (3 x 2 x 0.5 inches, 76 x 51 x 12 mm) than 8mm cartridges. 4mm, like 8mm, has comparatively short head life for the same reason, both use helical scan. Data throughput on these drives starts ~150kB/s, peaking at ~500kB/s. Data capacity starts at 1.3 GB and ends at 2.0 GB. Hardware compression, available with most of these drives, approximately doubles the capacity. Multi-drive tape library units can have 6 drives in a single cabinet with automatic tape changing. Library capacities reach 240 GB. The DDS-3 standard now supports tape capacities up to 12 GB (or 24 GB compressed). 4mm drives, like 8mm drives, use helical-scan. All the benefits and drawbacks of helical-scan apply to both 4mm and 8mm drives. Tapes should be retired from use after 2,000 passes or 100 full backups. 8mm (Exabyte) tape media Exabyte (8mm) tapes 8mm tapes are the most common SCSI tape drives; they are the best choice of exchanging tapes. Nearly every site has an Exabyte 2 GB 8mm tape drive. 8mm drives are reliable, convenient and quiet. Cartridges are inexpensive and small (4.8 x 3.3 x 0.6 inches; 122 x 84 x 15 mm). One downside of 8mm tape is relatively short head and tape life due to the high rate of relative motion of the tape across the heads. Data throughput ranges from ~250kB/s to ~500kB/s. Data sizes start at 300 MB and go up to 7 GB. Hardware compression, available with most of these drives, approximately doubles the capacity. These drives are available as single units or multi-drive tape libraries with 6 drives and 120 tapes in a single cabinet. Tapes are changed automatically by the unit. Library capacities reach 840+ GB. The Exabyte Mammoth model supports 12 GB on one tape (24 GB with compression) and costs approximately twice as much as conventional tape drives. Data is recorded onto the tape using helical-scan, the heads are positioned at an angle to the media (approximately 6 degrees). The tape wraps around 270 degrees of the spool that holds the heads. The spool spins while the tape slides over the spool. The result is a high density of data and closely packed tracks that angle across the tape from one edge to the other. QIC tape media QIC-150 QIC-150 tapes and drives are, perhaps, the most common tape drive and media around. QIC tape drives are the least expensive "serious" backup drives. The downside is the cost of media. QIC tapes are expensive compared to 8mm or 4mm tapes, up to 5 times the price per GB data storage. But, if your needs can be satisfied with a half-dozen tapes, QIC may be the correct choice. QIC is the most common tape drive. Every site has a QIC drive of some density or another. Therein lies the rub, QIC has a large number of densities on physically similar (sometimes identical) tapes. QIC drives are not quiet. These drives audibly seek before they begin to record data and are clearly audible whenever reading, writing or seeking. QIC tapes measure (6 x 4 x 0.7 inches; 15.2 x 10.2 x 1.7 mm). Mini-cartridges, which also use 1/4" wide tape are discussed separately. Tape libraries and changers are not available. Data throughput ranges from ~150kB/s to ~500kB/s. Data capacity ranges from 40 MB to 15 GB. Hardware compression is available on many of the newer QIC drives. QIC drives are less frequently installed; they are being supplanted by DAT drives. Data is recorded onto the tape in tracks. The tracks run along the long axis of the tape media from one end to the other. The number of tracks, and therefore the width of a track, varies with the tape's capacity. Most if not all newer drives provide backward-compatibility at least for reading (but often also for writing). QIC has a good reputation regarding the safety of the data (the mechanics are simpler and more robust than for helical scan drives). Tapes should be retired from use after 5,000 backups. XXX* Mini-Cartridge DLT tape media DLT DLT has the fastest data transfer rate of all the drive types listed here. The 1/2" (12.5mm) tape is contained in a single spool cartridge (4 x 4 x 1 inches; 100 x 100 x 25 mm). The cartridge has a swinging gate along one entire side of the cartridge. The drive mechanism opens this gate to extract the tape leader. The tape leader has an oval hole in it which the drive uses to "hook" the tape. The take-up spool is located inside the tape drive. All the other tape cartridges listed here (9 track tapes are the only exception) have both the supply and take-up spools located inside the tape cartridge itself. Data throughput is approximately 1.5MB/s, three times the throughput of 4mm, 8mm, or QIC tape drives. Data capacities range from 10 GB to 20 GB for a single drive. Drives are available in both multi-tape changers and multi-tape, multi-drive tape libraries containing from 5 to 900 tapes over 1 to 20 drives, providing from 50 GB to 9 TB of storage. With compression, DLT Type IV format supports up to 70 GB capacity. Data is recorded onto the tape in tracks parallel to the direction of travel (just like QIC tapes). Two tracks are written at once. Read/write head lifetimes are relatively long; once the tape stops moving, there is no relative motion between the heads and the tape. AIT tape media AIT AIT is a new format from Sony, and can hold up to 50 GB (with compression) per tape. The tapes contain memory chips which retain an index of the tape's contents. This index can be rapidly read by the tape drive to determine the position of files on the tape, instead of the several minutes that would be required for other tapes. Software such as SAMS:Alexandria can operate forty or more AIT tape libraries, communicating directly with the tape's memory chip to display the contents on screen, determine what files where backed up to which tape, locate the correct tape, load it, and restore the data from the tape. Libraries like this cost in the region of $20,000, pricing them a little out of the hobbyist market. Using a New Tape for the First Time The first time that you try to read or write a new, completely blank tape, the operation will fail. The console messages should be similar to: sa0(ncr1:4:0): NOT READY asc:4,1 sa0(ncr1:4:0): Logical unit is in process of becoming ready The tape does not contain an Identifier Block (block number 0). All QIC tape drives since the adoption of QIC-525 standard write an Identifier Block to the tape. There are two solutions: mt fsf 1 causes the tape drive to write an Identifier Block to the tape. Use the front panel button to eject the tape. Re-insert the tape and &man.dump.8; data to the tape. &man.dump.8; will report DUMP: End of tape detected and the console will show: HARDWARE FAILURE info:280 asc:80,96. rewind the tape using: mt rewind. Subsequent tape operations are successful. Backup Programs backup software The three major programs are &man.dump.8;, &man.tar.1;, and &man.cpio.1;. Dump and Restore backup software dump / restore dump restore The traditional Unix backup programs are &man.dump.8; and &man.restore.8;. They operate on the drive as a collection of disk blocks, below the abstractions of files, links and directories that are created by the filesystems. &man.dump.8; backs up an entire filesystem on a device. It is unable to backup only part of a filesystem or a directory tree that spans more than one filesystem. &man.dump.8; does not write files and directories to tape, but rather writes the raw data blocks that comprise files and directories. If you use &man.dump.8; on your root directory, you would not back up /home, /usr or many other directories since these are typically mount points for other filesystems or symbolic links into those filesystems. &man.dump.8; has quirks that remain from its early days in Version 6 of AT&T Unix (circa 1975). The default parameters are suitable for 9-track tapes (6250 bpi), not the high-density media available today (up to 62,182 ftpi). These defaults must be overridden on the command line to utilize the capacity of current tape drives. rhosts It is also possible to backup data across the network to a tape drive attached to another computer with &man.rdump.8; and &man.rrestore.8;. Both programs rely upon &man.rcmd.3; and &man.ruserok.3; to access the remote tape drive. Therefore, the user performing the backup must have rhosts access to the remote computer. The arguments to &man.rdump.8; and &man.rrestore.8; must be suitable to use on the remote computer. (e.g. When rdumping from a FreeBSD computer to an Exabyte tape drive connected to a Sun called komodo, use: /sbin/rdump 0dsbfu 54000 13000 126 komodo:/dev/nrsa8 /dev/rda0a 2>&1) Beware: there are security implications to allowing rhosts commands. Evaluate your situation carefully. It is also possible to use &man.rdump.8; and &man.rrestore.8; in a more secure fashion over &man.ssh.1;. Using <command>rdump</command> over <application>ssh</application> &prompt.root; /sbin/dump -0uan -f - /usr | gzip -2 | ssh1 -c blowfish \ targetuser@targetmachine.example.com dd of=/mybigfiles/dump-usr-l0.gz <command>tar</command> backup software tar &man.tar.1; also dates back to Version 6 of AT&T Unix (circa 1975). &man.tar.1; operates in cooperation with the filesystem; &man.tar.1; writes files and directories to tape. &man.tar.1; does not support the full range of options that are available from &man.cpio.1;, but &man.tar.1; does not require the unusual command pipeline that &man.cpio.1; uses. tar Most versions of &man.tar.1; do not support backups across the network. The GNU version of &man.tar.1;, which FreeBSD utilizes, supports remote devices using the same syntax as &man.rdump.8;. To &man.tar.1; to an Exabyte tape drive connected to a Sun called komodo, use: /usr/bin/tar cf komodo:/dev/nrsa8 . 2>&1. For versions without remote device support, you can use a pipeline and &man.rsh.1; to send the data to a remote tape drive. &prompt.root; tar cf - . | rsh hostname dd of=tape-device obs=20b - If you're worried about the security of backing over a network + If you are worried about the security of backing over a network you should use the &man.ssh.1; command instead of &man.rsh.1;. <command>cpio</command> backup software cpio &man.cpio.1; is the original Unix file interchange tape program for magnetic media. &man.cpio.1; has options (among many others) to perform byte-swapping, write a number of different archives format, and pipe the data to other programs. This last feature makes &man.cpio.1; and excellent choice for installation media. &man.cpio.1; does not know how to walk the directory tree and a list of files must be provided through stdin. cpio &man.cpio.1; does not support backups across the network. You can use a pipeline and &man.rsh.1; to send the data to a remote tape drive. &prompt.root; for f in directory_list; do find $f >> backup.list done &prompt.root; cpio -v -o --format=newc < backup.list | ssh user@host "cat > backup_device Where directory_list is the list of directories you want to back up, user@host is the user/hostname combination that will be performing the backups, and backup_device is where the backups should be written to (e.g., /dev/nrsa0). <command>pax</command> backup software pax pax POSIX IEEE &man.pax.1; is IEEE/POSIX's answer to &man.tar.1; and &man.cpio.1;. Over the years the various versions of &man.tar.1; and &man.cpio.1; have gotten slightly incompatible. So rather than fight it out to fully standardize them, POSIX created a new archive utility. &man.pax.1; attempts to read and write many of the various &man.cpio.1; and &man.tar.1; formats, plus new formats of its own. Its command set more resembles &man.cpio.1; than &man.tar.1;. <application>Amanda</application> backup software Amanda Amanda Amanda (Advanced Maryland Network Disk Archiver) is a client/server backup system, rather than a single program. An Amanda server will backup to a single tape drive any number of computers that have Amanda clients and a network connection to the Amanda server. A common problem at locations with a number of large disks is the length of time required to backup to data directly to tape exceeds the amount of time available for the task. Amanda solves this problem. Amanda can use a "holding disk" to backup several filesystems at the same time. Amanda creates "archive sets": a group of tapes used over a period of time to create full backups of all the filesystems listed in Amanda's configuration file. The "archive set" also contains nightly incremental (or differential) backups of all the filesystems. Restoring a damaged filesystem requires the most recent full backup and the incremental backups. The configuration file provides fine control backups and the network traffic that Amanda generates. Amanda will use any of the above backup programs to write the data to tape. Amanda is available as either a port or a package, it is not installed by default. Do Nothing Do nothing is not a computer program, but it is the most widely used backup strategy. There are no initial costs. There is no backup schedule to follow. Just say no. If something happens to your data, grin and bear it! If your time and your data is worth little to nothing, then Do nothing is the most suitable backup program for your computer. But beware, Unix is a useful tool, you may find that within six months you have a collection of files that are valuable to you. Do nothing is the correct backup method for /usr/obj and other directory trees that can be exactly recreated by your computer. An example is the files that comprise the HTML or Postscript version of this Handbook. These document formats have been created from SGML input files. Creating backups of the HTML or PostScript files is not necessary. The SGML files are backed up regularly. Which Backup Program Is Best? LISA &man.dump.8; Period. Elizabeth D. Zwicky torture tested all the backup programs discussed here. The clear choice for preserving all your data and all the peculiarities of Unix filesystems is &man.dump.8;. Elizabeth created filesystems containing a large variety of unusual conditions (and some not so unusual ones) and tested each program by doing a backup and restore of that filesystems. The peculiarities included: files with holes, files with holes and a block of nulls, files with funny characters in their names, unreadable and unwritable files, devices, files that change size during the backup, files that are created/deleted during the backup and more. She presented the results at LISA V in Oct. 1991. See torture-testing Backup and Archive Programs. Emergency Restore Procedure Before the Disaster There are only four steps that you need to perform in preparation for any disaster that may occur. disklabel First, print the disklabel from each of your disks (e.g. disklabel da0 | lpr), your filesystem table (/etc/fstab) and all boot messages, two copies of each. fix-it floppies Second, determine that the boot and fix-it floppies (boot.flp and fixit.flp) have all your devices. The easiest way to check is to reboot your machine with the boot floppy in the floppy drive and check the boot messages. If all your devices are listed and functional, skip on to step three. Otherwise, you have to create two custom bootable floppies which has a kernel that can mount all of your disks and access your tape drive. These floppies must contain: &man.fdisk.8;, &man.disklabel.8;, &man.newfs.8;, &man.mount.8;, and whichever backup program you use. These programs must be statically linked. If you use &man.dump.8;, the floppy must contain &man.restore.8;. Third, create backup tapes regularly. Any changes that you make after your last backup may be irretrievably lost. Write-protect the backup tapes. Fourth, test the floppies (either boot.flp and fixit.flp or the two custom bootable floppies you made in step two.) and backup tapes. Make notes of the procedure. Store these notes with the bootable floppy, the printouts and the backup tapes. You will be so distraught when restoring that the notes may prevent you from destroying your backup tapes (How? In place of tar xvf /dev/rsa0, you might accidently type tar cvf /dev/rsa0 and over-write your backup tape). For an added measure of security, make bootable floppies and two backup tapes each time. Store one of each at a remote location. A remote location is NOT the basement of the same office building. A number of firms in the World Trade Center learned this lesson the hard way. A remote location should be physically separated from your computers and disk drives by a significant distance. A Script for Creating a Bootable Floppy /mnt/sbin/init gzip -c -best /sbin/fsck > /mnt/sbin/fsck gzip -c -best /sbin/mount > /mnt/sbin/mount gzip -c -best /sbin/halt > /mnt/sbin/halt gzip -c -best /sbin/restore > /mnt/sbin/restore gzip -c -best /bin/sh > /mnt/bin/sh gzip -c -best /bin/sync > /mnt/bin/sync cp /root/.profile /mnt/root cp -f /dev/MAKEDEV /mnt/dev chmod 755 /mnt/dev/MAKEDEV chmod 500 /mnt/sbin/init chmod 555 /mnt/sbin/fsck /mnt/sbin/mount /mnt/sbin/halt chmod 555 /mnt/bin/sh /mnt/bin/sync chmod 6555 /mnt/sbin/restore # # create the devices nodes # cd /mnt/dev ./MAKEDEV std ./MAKEDEV da0 ./MAKEDEV da1 ./MAKEDEV da2 ./MAKEDEV sa0 ./MAKEDEV pty0 cd / # # create minimum filesystem table # cat > /mnt/etc/fstab < /mnt/etc/passwd < /mnt/etc/master.passwd < After the Disaster The key question is: did your hardware survive? You have been doing regular backups so there is no need to worry about the software. If the hardware has been damaged. First, replace those parts that have been damaged. If your hardware is okay, check your floppies. If you are using a custom boot floppy, boot single-user (type -s at the boot: prompt). Skip the following paragraph. If you are using the boot.flp and fixit.flp floppies, keep reading. Insert the boot.flp floppy in the first floppy drive and boot the computer. The original install menu will be displayed on the screen. Select the Fixit--Repair mode with CDROM or floppy. option. Insert the fixit.flp when prompted. restore and the other programs that you need are located in /mnt2/stand. Recover each filesystem separately. mount root partition disklabel newfs Try to &man.mount.8; (e.g. mount /dev/da0a /mnt) the root partition of your first disk. If the disklabel was damaged, use &man.disklabel.8; to re-partition and label the disk to match the label that you printed and saved. Use &man.newfs.8; to re-create the filesystems. Re-mount the root partition of the floppy read-write (mount -u -o rw /mnt). Use your backup program and backup tapes to recover the data for this filesystem (e.g. restore vrf /dev/sa0). Unmount the filesystem (e.g. umount /mnt) Repeat for each filesystem that was damaged. Once your system is running, backup your data onto new tapes. Whatever caused the crash or data loss may strike again. Another hour spent now may save you from further distress later. * I did not prepare for the Disaster, What Now? ]]> What About Backups to Floppies? Can I Use floppies for Backing Up My Data? backup floppies floppy disks Floppy disks are not really a suitable media for making backups as: The media is unreliable, especially over long periods of time Backing up and restoring is very slow They have a very limited capacity (the days of backing up an entire hard disk onto a dozen or so floppies has long since passed). However, if you have no other method of backing up your data then floppy disks are better than no backup at all. If you do have to use floppy disks then ensure that you use good quality ones. Floppies that have been lying around the office for a couple of years are a bad choice. Ideally use new ones from a reputable manufacturer. So How Do I Backup My Data to Floppies? The best way to backup to floppy disk is to use &man.tar.1; with the (multi volume) option, which allows backups to span multiple floppies. To backup all the files in the current directory and sub-directory use this (as root): &prompt.root; tar Mcvf /dev/fd0 * When the first floppy is full &man.tar.1; will prompt you to insert the next volume (because &man.tar.1; is media independent it refers to volumes. In this context it means floppy disk) Prepare volume #2 for /dev/fd0 and hit return: This is repeated (with the volume number incrementing) until all the specified files have been archived. Can I Compress My Backups? tar gzip compression Unfortunately, &man.tar.1; will not allow the option to be used for multi-volume archives. You could, of course, &man.gzip.1; all the files, &man.tar.1; them to the floppies, then &man.gunzip.1; the files again! How Do I Restore My Backups? To restore the entire archive use: &prompt.root; tar Mxvf /dev/fd0 There are two ways that you can use to restore only specific files. First, you can start with the first floppy and use: &prompt.root; tar Mxvf /dev/fd0 filename &man.tar.1; will prompt you to insert subsequent floppies until it finds the required file. Alternatively, if you know which floppy the file is on then you can simply insert that floppy and use the same command as above. Note that if the first file on the floppy is a continuation from the previous one then &man.tar.1; will warn you that it cannot restore it, even if you have not asked it to! diff --git a/en_US.ISO8859-1/books/handbook/basics/chapter.sgml b/en_US.ISO8859-1/books/handbook/basics/chapter.sgml index 8d9a525d9b..2594afe39f 100644 --- a/en_US.ISO8859-1/books/handbook/basics/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/basics/chapter.sgml @@ -1,885 +1,885 @@ Chris Shumway Rewritten by Unix Basics Synopsis basics The following chapter will cover the basic commands and functionality of the FreeBSD operating system. If you are new to FreeBSD, you will definitely want to read through this chapter before asking for help. Permissions Unix FreeBSD, having its history rooted in BSD Unix, has its fundamentals based on several key Unix concepts. The first, and most pronounced, is that FreeBSD is a multi-user operating system. The system can handle several users all working simultaneously on completely unrelated tasks. The system is responsible for properly sharing and managing requests for hardware devices, peripherals, memory, and CPU time evenly to each user. Because the system is capable of supporting multiple users, everything the system manages has a set of permissions governing who can read, write, and execute the resource. These permissions are stored as two octets broken into three pieces, one for the owner of the file, one for the group that the file belongs to, and one for everyone else. This numerical representation works like this: permissions file permissions Value Permission Directory Listing 0 No read, no write, no execute --- 1 No read, no write, execute --x 2 No read, write, no execute -w- 3 No read, write, execute -wx 4 Read, no write, no execute r-- 5 Read, no write, execute r-x 6 Read, write, no execute rw- 7 Read, write, execute rwx ls directories For the long directory listing by ls -l, a column will show a file's permissions for the owner, group, and everyone else. Here's how it is broken up: -rw-r--r-- The first character, from left to right, is a special character that tells if this is a regular file, a directory, a special character or block device, a socket, or any other special pseudo-file device. The next three characters, designated as rw- gives the permissions for the owner of the file. The next three characters, r-- gives the permissions for the group that the file belongs to. The final three characters, r--, gives the permissions for the rest of the world. A dash means that the permission is turned off. In the case of this file, the permissions are set so the owner can read and write to the file, the group can read the file, and the rest of the world can only read the file. According to the table above, the permissions for this file would be 644, where each digit represents the three parts of the file's permission. This is all well and good, but how does the system control permissions on devices? FreeBSD actually treats most hardware devices as a file that programs can open, read, and write data to just like any other file. These special device files are stored on the /dev directory. Directories are also treated as files. They have read, write, and execute permissions. The executable bit for a directory has a slightly different meaning than that of files. When a directory is marked executable, it means it can be searched into, for example, a directory listing can be done in that directory. There are more to permissions, but they are primarily used in special circumstances such as setuid binaries and sticky directories. If you want more information on file permissions and how to set them, be sure to look at the &man.chmod.1; man page. Directory Structures directory hierarchy Since FreeBSD uses its file systems to determine many fundamental system operations, the hierarchy of the file system is extremely important. Due to the fact that the &man.hier.7; manual page provides a complete description of the directory structure, it will not be duplicated here. Please read &man.hier.7; for more information. Of significant importance is the root of all directories, the / directory. This directory is the first directory mounted at boot time and it contains the base system necessary at boot time. The root directory also contains mount points for every other file system that you want to mount. A mount point is a directory where additional file systems can be grafted onto the root file system. Standard mount points include /usr, /var, /mnt, and /cdrom. These directories are usually referenced to entries in the file /etc/fstab. /etc/fstab is a table of various file systems and mount points for reference by the system. Most of the file systems in /etc/fstab are mounted automatically at boot time from the script &man.rc.8; unless they contain the option. Consult the &man.fstab.5; manual page for more information on the format of the /etc/fstab file and the options it contains. Processes FreeBSD is a multi-tasking operating system. This means that it seems as though more than one program is running at once. Each program running at any one time is called a process. Every command you run will start at least one new process, and there are a number of system processes that run all the time, keeping the system functional. Each process is uniquely identified by a number called a process ID, or PID, and, like files, each process also has one owner and group. The owner and group information is used to determine what files and devices the process can open, using the file permissions discussed earlier. Most processes also have a parent process. The parent process is the process that started them. For example, if you are typing commands to the shell then the shell is a process, and any commands you run are also processes. Each process you run in this way will have your shell as its parent process. The exception to this is a special process called init. init is always the first process, so its PID is always 1. init is started automatically by the kernel when FreeBSD starts. Two commands are particularly useful to see the processes on the system, &man.ps.1; and &man.top.1;. The &man.ps.1; command is used to show a static list of the currently running processes, and can show their PID, how much memory they are using, the command line they were started with, and so on. The &man.top.1; command displays all the running processes, and updates the display every few seconds, so that you can interactively see what your computer is doing. By default, &man.ps.1; only shows you the commands that are running and are owned by you. For example; &prompt.user; ps PID TT STAT TIME COMMAND 298 p0 Ss 0:01.10 tcsh 7078 p0 S 2:40.88 xemacs mdoc.xsl (xemacs-21.1.14) 37393 p0 I 0:03.11 xemacs freebsd.dsl (xemacs-21.1.14) 48630 p0 S 2:50.89 /usr/local/lib/netscape-linux/navigator-linux-4.77.bi 48730 p0 IW 0:00.00 (dns helper) (navigator-linux-) 72210 p0 R+ 0:00.00 ps 390 p1 Is 0:01.14 tcsh 7059 p2 Is+ 1:36.18 /usr/local/bin/mutt -y 6688 p3 IWs 0:00.00 tcsh 10735 p4 IWs 0:00.00 tcsh 20256 p5 IWs 0:00.00 tcsh 262 v0 IWs 0:00.00 -tcsh (tcsh) 270 v0 IW+ 0:00.00 /bin/sh /usr/X11R6/bin/startx -- -bpp 16 280 v0 IW+ 0:00.00 xinit /home/nik/.xinitrc -- -bpp 16 284 v0 IW 0:00.00 /bin/sh /home/nik/.xinitrc 285 v0 S 0:38.45 /usr/X11R6/bin/sawfish As you can see in this example, the output from &man.ps.1; is organized in to a number of columns. PID is the process ID discussed earlier. PIDs are assigned starting from 1, go up to 65536, and wrap around back to the beginning when you run out. TT shows the tty the program is running on, and can safely be ignore for the moment. STAT shows the program's state, and again, can be safely ignored. TIME is the amount of time the program has been running on the CPU—this is not necessarily the elapsed time since you started the program, as some programs spend a lot of time waiting for things to happen before they need to spend time on the CPU. Finally, COMMAND is the command line that was used to run the program. &man.ps.1; supports a number of different options to change the information that is displayed. One of the most useful sets is auxww. displays information about all the running processes, not just your own. displays the username of the process' owner, as well as memory usage. displays information about daemon processes, and causes &man.ps.1; to display the full command line, rather than truncating it once it gets too long to fit on the screen. The output from &man.top.1; is similar. A sample session looks like this; &prompt.user; top last pid: 72257; load averages: 0.13, 0.09, 0.03 up 0+13:38:33 22:39:10 47 processes: 1 running, 46 sleeping CPU states: 12.6% user, 0.0% nice, 7.8% system, 0.0% interrupt, 79.7% idle Mem: 36M Active, 5256K Inact, 13M Wired, 6312K Cache, 15M Buf, 408K Free Swap: 256M Total, 38M Used, 217M Free, 15% Inuse PID USERNAME PRI NICE SIZE RES STATE TIME WCPU CPU COMMAND 72257 nik 28 0 1960K 1044K RUN 0:00 14.86% 1.42% top 7078 nik 2 0 15280K 10960K select 2:54 0.88% 0.88% xemacs-21.1.14 281 nik 2 0 18636K 7112K select 5:36 0.73% 0.73% XF86_SVGA 296 nik 2 0 3240K 1644K select 0:12 0.05% 0.05% xterm 48630 nik 2 0 29816K 9148K select 3:18 0.00% 0.00% navigator-linu 175 root 2 0 924K 252K select 1:41 0.00% 0.00% syslogd 7059 nik 2 0 7260K 4644K poll 1:38 0.00% 0.00% mutt ... The output is split in to two sections. The header (the first five lines) shows the PID of the last process to run, the system load averages (which are a measure of how busy the system is), the system uptime (time since the last reboot) and the current time. The other figures in the header relate to how many processes are running (47 in this case), how much memory and swap space has been taken up, and how much time the system is spending in different CPU states. Below that are a series of columns containing similar information to the output from &man.ps.1;. As before you can see the PID, the username, the amount of CPU time taken, and the command that was run. &man.top.1; also defaults to showing you the amount of memory space taken by the process. This is split in to two columns, one for total size, and one for resident size—total size is how much memory the application has needed, and the resident size is how much it is actually using at the moment. In this example you can see that Netscape has needed almost 30 MB of RAM, and is currently only needing 9 MB. &man.top.1; automatically updates this display every two seconds; this can be changed with the option. Daemons, Signals, and Killing Processes When you run an editor it is easy to control the editor, tell it to load files, and so on. You can do this because the editor provides facilities to do so, and because the editor is attached to a terminal. Some programs are not designed to be run with continuous user input, and so they disconnect from the terminal at the first opportunity. For example, a web server spends all day responding to web requests, it normally does not need any input from you. Programs that transport email from site to site are another example of this class of application. We call these programs daemons. Daemons were characters in Greek mythology; neither good or evil, they were little attendant spirits that, by and large, did useful things for mankind. Much like the web servers and mail servers of today do useful things. This is why the BSD mascot has, for a long time, been the cheerful looking daemon with sneakers and a pitchfork. There is a convention to name programs that normally run as daemons with a trailing d. BIND is the Berkeley Internet Name Daemon (and the program you can is called named), the Apache web server program is called httpd, the line printer spooling daemon is lpd and so on. This is a convention, not a hard and fast rule; for example, the main mail daemon for the Sendmail application is called sendmail, and not maild, as you might imagine. Sometimes you will need to communicate with a daemon process. These communications are called signals, and you can communicate with daemons (or with any running process) by sending it a signal. There are a number if different signals that you can send—some of them have a specific meaning, others are interpreted by the application, and the application's documentation will tell you how that application interprets signals. You can only send a signal to a process that you own. If you try and send a signal to someone else's process it will be ignored. The exception to this is the root user, who can send signals to everyone's processes. FreeBSD will also send applications signals in some cases. If an application is badly written, and tries to access memory that it is not supposed to, FreeBSD sends the process the Segmentation Violation signal (SIGSEGV). If an application has used the &man.alarm.3; system call to be alerted after a period of time has elapsed then it will be sent the Alarm signal (SIGALRM), and so on. Two signals can be used to stop a process, SIGTERM and SIGKILL. SIGTERM is the polite way to kill a process; the process can catch the signal, realize that you want it to shut down, close any log files it may have open, and generally finish whatever it is doing at the time before shutting down. In some cases a process may even ignore SIGTERM if it is in the middle of some task that can not be interrupted. SIGKILL can not be ignored by a process. This is - the I don't care what you are doing, stop right now + the I do not care what you are doing, stop right now signal. If you send SIGKILL to a process then FreeBSD will stop that process there and then Not quite true—there are a few things that can not be interrupted. For example, if the process is trying to read from a file that is on another computer on the network, and the other computer has gone away for some reason (been turned off, or the network has a fault), then the process is said to be uninterruptible. Eventually the process will time out, typically after two minutes. As soon as this time out occurs the process will be killed. . The other signals you might want to use are SIGHUP, SIGUSR1, and SIGUSR2. These are general purpose signals, and different applications will do different things when they are sent. Suppose that you have changed your web server's configuration file—you would like to tell the web server to re-read its configuration. You could stop and restart httpd, but this would result in a brief outage period on your web server, which may be undesirable. Most daemons are written to respond to the SIGHUP signal by re-reading their configuration file. So instead of killing and restarting httpd you would send it the SIGHUP signal. Because there is no standard way to respond to these signals, different daemons will have different behavior, so be sure and read the documentation for the daemon in question. Signals are sent using the &man.kill.1; command, as this example shows. Sending a Signal to a Process This example shows how to send a signal to &man.inetd.8;. The &man.inetd.8; configuration file is /etc/inetd.conf, and &man.inetd.8; will re-read this configuration file when it is sent SIGHUP. Find the process ID of the process you want to send the signal to. Do this using &man.ps.1; and &man.grep.1;. The &man.grep.1; command is used to search through output, looking for the string you specify. This command is run as a normal user, and &man.inetd.8; is run as root, so the options must be given to &man.ps.1;. &prompt.user; ps -ax | grep inetd 198 ?? IWs 0:00.00 inetd -wW So the &man.inetd.8; PID is 198. In some cases the grep inetd command might also occur in this output. This is because of the way &man.ps.1; has to find the list of running processes. Use &man.kill.1; to send the signal. Because &man.inetd.8; is being run by root you must use &man.su.1; to become root first. &prompt.user; su Password: &prompt.root; /bin/kill -s HUP 198 As is common with Unix commands, &man.kill.1; will not print any output if it is successfully. If you try and send a signal to a process that you do not own then you will see kill: PID: Operation not permitted. If you mistype the PID you will either send the signal to the wrong process, which could be bad, or, if you are lucky, you will have sent the signal to a PID that is not currently in use, and you will see kill: PID: No such process. Why Use <command>/bin/kill</command>? Many shells provide the kill command as a built in command; that is, the shell will send the signal directly, rather than running /bin/kill. This can be very useful, but different shells have a different syntax for specifying the name of the signal to send. Rather than try to learn all of them, it can be simpler just to use the /bin/kill ... command directly. Sending other signals is very similar, just substitute TERM or KILL in the command line as necessary. Killing random process on the system can be a bad idea. In particular, &man.init.8;, process ID 1, is very special. Running /bin/kill -s KILL 1 is a quick way to shutdown your system. Always double check the arguments you run &man.kill.1; with before you press RETURN. Shells shells command-line In FreeBSD, a lot of everyday work is done in a command line interface called a shell. A shell's main job is to take commands from the input channel and execute them. A lot of shells also have built in functions to help everyday tasks such a file management, file globing, command line editing, command macros, and environment variables. FreeBSD comes with a set of shells, such as sh, the Bourne Shell, and csh, the C-shell. Many other shells are available from the FreeBSD Ports Collection that have much more power, such as tcsh and bash. Which shell do you use? It is really a matter of taste. If you are a C programmer you might feel more comfortable with a C-like shell - such as tcsh. If you've come from Linux or are new + such as tcsh. If you have come from Linux or are new to a Unix command line interface you might try bash. The point is that each shell has unique properties that may or may not work with your preferred working environment, and that you have a choice of what shell to use. One common feature in a shell is file-name completion. Given the typing of the first few letters of a command or filename, you can usually have the shell automatically complete the rest of the command or filename by hitting the TAB key on the keyboard. Here is an example. Suppose you have two files called foobar and foo.bar. You want to delete foo.bar. So what you would type on the keyboard is: rm fo[TAB].[TAB]. The shell would print out rm foo[BEEP].bar. The [BEEP] is the console bell, which is the shell telling me it was unable to totally complete the filename because there is more than one match. Both foobar and foo.bar start with fo, but it was able to complete to foo. If you type in ., then hit TAB again, the shell would be able to fill in the rest of the filename for you. environment variables Another function of the shell is environment variables. Environment variables are a variable key pair stored in the shell's environment space. This space can be read by any program invoked by the shell, and thus contains a lot of program configuration. Here is a list of common environment variables and what they mean: environment variables Variable Description USER Current logged in user's name. PATH Colon separated list of directories to search for binaries. DISPLAY Network name of the X11 display to connect to, if available. SHELL The current shell. TERM The name of the user's terminal. Used to determine the capabilities of the terminal. TERMCAP Database entry of the terminal escape codes to perform various terminal functions. OSTYPE Type of operating system. E.g., FreeBSD. MACHTYPE The CPU architecture that the system is running on. EDITOR The user's preferred text editor. PAGER The user's preferred text pager. MANPATH Colon separated list of directories to search for manual pages. Bourne shells To view or set an environment variable differs somewhat from shell to shell. For example, in the C-Style shells such as tcsh and csh, you would use setenv to set and view environment variables. Under Bourne shells such as sh and bash, you would use set and export to view and set your current environment variables. For example, to set or modify the EDITOR environment variable, under csh or tcsh a command like this would set EDITOR to /usr/local/bin/emacs: &prompt.user; setenv EDITOR /usr/local/bin/emacs Under Bourne shells: &prompt.user; export EDITOR="/usr/local/bin/emacs" You can also make most shells expand the environment variable by placing a $ character in front of it on the command line. For example, echo $TERM would print out whatever $TERM is set to, because the shell expands $TERM and passes it on to echo. Shells treat a lot of special characters, called meta-characters as special representations of data. The most common one is the * character, which represents any number of characters in a filename. These special meta-characters can be used to do file name globing. For example, typing in echo * is almost the same as typing in ls because the shell takes all the files that match * and puts them on the command line for echo to see. To prevent the shell from interpreting these special characters, they can be escaped from the shell by putting a backslash (\) character in front of them. echo $TERM prints whatever your terminal is set to. echo \$TERM prints $TERM as is. Changing Your Shell The easiest way to change your shell is to use the chsh command. Running chsh will place you into the editor that is in your EDITOR environment variable; if it is not set, you will be placed in vi. Change the Shell: line accordingly. You can also give chsh the option; this will set your shell for you, without requiring you to enter an editor. For example, if you wanted to change your shell to bash, the following should do the trick: &prompt.user; chsh -s /usr/local/bin/bash Running chsh with no parameters and editing the shell from there would work also. The shell that you wish to use must be present in the /etc/shells file. If you have installed a shell from the ports collection, then this should have been done for you already. If you installed the shell by hand, you must do this. For example, if you installed bash by hand and placed it into /usr/local/bin, you would want to: &prompt.root; echo "/usr/local/bin/bash" >> /etc/shells Then rerun chsh. Text Editors text editors editors A lot of configuration in FreeBSD is done by editing a text file. Because of this, it would be a good idea to become familiar with a text editor. FreeBSD comes with a few as part of the base system, and many more are available in the ports collection. ee The easiest and simplest editor to learn is an editor called ee, which stands for easy editor. To start ee, one would type at the command line ee filename where filename is the name of the file to be edited. For example, to edit /etc/rc.conf, type in ee /etc/rc.conf. Once inside of ee, all of the commands for manipulating the editor's functions are listed at the top of the display. The caret ^ character means the control key on the keyboard, so ^e expands to pressing the control key plus the letter e. To leave ee, hit the escape key, then choose leave editor. The editor will prompt you to save any changes if the file has been modified. vi editors vi emacs editors emacs FreeBSD also comes with more powerful text editors such as vi as part of the base system, and emacs and vim as part of the FreeBSD Ports Collection. These editors offer much more functionality and power at the expense of being a little more complicated to learn. However if you plan on doing a lot of text editing, learning a more powerful editor such as vim or emacs will save you much more time in the long run. For More Information... Manual Pages manual pages The most comprehensive documentation on FreeBSD is in the form of manual pages. Nearly every program on the system comes with a short reference manual explaining the basic operation and various arguments. These manuals can be viewed with the man command. Use of the man command is simple: &prompt.user; man command command is the name of the command you wish to learn about. For example, to learn more about ls command type: &prompt.user; man ls The online manual is divided up into numbered sections: User commands. System calls and error numbers. Functions in the C libraries. Device drivers. File formats. Games and other diversions. Miscellaneous information. System maintenance and operation commands. Kernel developers. In some cases, the same topic may appear in more than one section of the online manual. For example, there is a chmod user command and a chmod() system call. In this case, you can tell the man command which one you want by specifying the section: &prompt.user; man 1 chmod This will display the manual page for the user command chmod. References to a particular section of the online manual are traditionally placed in parenthesis in written documentation, so &man.chmod.1; refers to the chmod user command and &man.chmod.2; refers to the system call. This is fine if you know the name of the command and simply wish to know how to use it, but what if you cannot recall the command name? You can use man to search for keywords in the command descriptions by using the switch: &prompt.user; man -k mail With this command you will be presented with a list of commands that have the keyword mail in their descriptions. This is actually functionally equivalent to using the apropos command. So, you are looking at all those fancy commands in /usr/bin but do not have the faintest idea what most of them actually do? Simply do: &prompt.user; cd /usr/bin &prompt.user; man -f * or &prompt.user; cd /usr/bin &prompt.user; whatis * which does the same thing. GNU Info Files Free Software Foundation FreeBSD includes many applications and utilities produced by the Free Software Foundation (FSF). In addition to manual pages, these programs come with more extensive hypertext documents called info files which can be viewed with the info command or, if you installed emacs, the info mode of emacs. To use the &man.info.1; command, simply type: &prompt.user; info For a brief introduction, type h. For a quick command reference, type ?. diff --git a/en_US.ISO8859-1/books/handbook/boot/chapter.sgml b/en_US.ISO8859-1/books/handbook/boot/chapter.sgml index 9b4be12e51..4fa6c7c0d7 100644 --- a/en_US.ISO8859-1/books/handbook/boot/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/boot/chapter.sgml @@ -1,664 +1,664 @@ The FreeBSD Booting Process Synopsis booting bootstrap The process of starting a computer and loading the operating system is referred to as the bootstrap process, or simply booting. FreeBSD's boot process provides a great deal of flexibility in customizing what happens when you start the system, allowing you to select from different operating systems installed on the same computer, or even different versions of the same operating system or installed kernel. This chapter details the configuration options you can set and how to customize the FreeBSD boot process. This includes everything that happens until the FreeBSD kernel has started, probed for devices, and started &man.init.8;. If you are not quite sure when this happens, it occurs when the text color changes from bright white to grey. After reading this chapter you will know: What the components of the FreeBSD bootstrap system are, and how they interact. The options you can give to the components in the FreeBSD bootstrap to control the boot process. x86 only This chapter only describes the boot process for FreeBSD running on Intel x86 systems. The Booting Problem Turning on a computer and starting the operating system poses an interesting dilemma. By definition, the computer does not know how to do anything until the operating system is started. This includes running programs from the disk. So if the computer can not run a program from the disk without the operating system, and the operating system programs are on the disk, how is the operating system started? This problem parallels one in the book The Adventures of Baron Munchausen. A character had fallen part way down a manhole, and pulled himself out by grabbing his bootstraps, and lifting. In the early days of computing the term bootstrap was applied to the mechanism used to load the operating system, which has become shortened to booting. On x86 hardware the Basic Input/Output System (BIOS) is responsible for loading the operating system. To do this, the BIOS looks on the hard disk for the Master Boot Record (MBR), which must be located on a specific place on the disk. The BIOS has enough knowledge to load and run the MBR, and assumes that the MBR can then carry out the rest of the tasks involved in loading the operating system. BIOS Basic Input/Output System If you only have one operating system installed on your disks then the standard MBR will suffice. This MBR searches for the first bootable slice on the disk, and then runs the code on that slice to load the remainder of the operating system. If you have installed multiple operating systems on your disks then you can install a different MBR, one that can display a list of different operating systems, and allows you to choose the one to boot from. FreeBSD comes with one such MBR which can be installed, and other operating system vendors also provide alternative MBRs. The remainder of the FreeBSD bootstrap system is divided into three stages. The first stage is run by the MBR, which knows just enough to get the computer into a specific state and run the second stage. The second stage can do a little bit more, before running the third stage. The third stage finishes the task of loading the operating system. The work is split into these three stages because the PC standards put limits on the size of the programs that can be run at stages one and two. Chaining the tasks together allows FreeBSD to provide a more flexible loader. kernel init The kernel is then started, which will then probe for devices and initialize them for use. Once the kernel boot process is finished, the kernel passes control to the user process &man.init.8;, which then makes sure the disks are in a usable state. &man.init.8; then starts the user-level resource configuration which then mounts filesystems, sets up network cards to act on the network, and generally starts all the processes that usually are run on a FreeBSD system at startup. The MBR, and Boot Stages One, Two, and Three MBR, <filename>/boot/boot0</filename> Master Boot Record (MBR) The FreeBSD MBR is located in /boot/boot0. This is a copy of the MBR, as the real MBR must be placed on a special part of the disk, outside the FreeBSD area. boot0 is very simple, since the program in the MBR can only be 512 bytes in size. If you have installed the FreeBSD MBR and have installed multiple operating systems on your hard disks then you will see a display similar to this one at boot time. <filename>boot0</filename> Screenshot F1 DOS F2 FreeBSD F3 Linux F4 ?? F5 Drive 1 Default: F2 Other operating systems, in particular Windows 95, have been known to overwrite an existing MBR with their own. If this happens to you, or you want to replace your existing MBR with the FreeBSD MBR then use the following command. &prompt.root; fdisk -B -b /boot/boot0 device Where device is the device that you boot from, such as ad0 for the first IDE disk, ad4 for the first IDE disk on a second IDE controller, da0 for the first SCSI disk, and so on. Stage One, <filename>/boot/boot1</filename>, and Stage Two, <filename>/boot/boot2</filename> Conceptually the first and second stages are part of the same program, on the same area of the disk. Because of space constraints they have been split into two, but you would always install them together. They are found on the boot sector of the boot slice, which is where boot0, or any other program on the MBR expects to find the program to run to continue the boot process. The files in the /boot directory are copies of the real files, which are stored outside of the FreeBSD filesystem. boot1 is very simple, since it too can only be 512 bytes in size, and knows just enough about the FreeBSD disklabel, which stores information about the slice, to find and execute boot2. boot2 is slightly more sophisticated, and understands the FreeBSD filesystem enough to find files on it, and can provide a simple interface to choose the kernel or loader to run. Since the loader is much more sophisticated, and provides a nice easy-to-use boot configuration, boot2 usually runs it, but previously it was tasked to run the kernel directly. <filename>boot2</filename> Screenshot >> FreeBSD/i386 BOOT Default: 0:ad(0,a)/kernel boot: If you ever need to replace the installed boot1 and boot2 use &man.disklabel.8;. &prompt.root; disklabel -B diskslice Where diskslice is the disk and slice you boot from, such as ad0s1 for the first slice on the first IDE disk. Dangerously Dedicated Mode If you use just the disk name, such as ad0, in the &man.disklabel.8; command you will create a dangerously dedicated disk, without slices. This is almost certainly not what you want to do, so make sure you double check the &man.disklabel.8; command before you press RETURN. Stage Three, <filename>/boot/loader</filename> boot-loader The loader is the final stage of the three-stage bootstrap, and is located on the filesystem, usually as /boot/loader. The loader is intended as a user-friendly method for configuration, using an easy-to-use built-in command set, backed up by a more powerful interpreter, with a more complex command set. Loader Program Flow During initialization, the loader will probe for a console and for disks, and figure out what disk it is booting from. It will set variables accordingly, and then the interpreter is started, and the easy-to-use commands are passed to it. loader loader configuration The loader will then read /boot/loader.rc, which by default reads in /boot/defaults/loader.conf which sets reasonable defaults for variables and reads /boot/loader.conf for local changes to those variables. loader.rc then acts on these variables, loading whichever modules and kernel are selected. Finally, by default, the loader issues a 10 second wait for key presses, and boots the kernel if it is not interrupted. If interrupted, the user is presented with a prompt which understands the easy-to-use command set, where the user may adjust variables, unload all modules, load modules, and then finally boot or reboot. A more technical discussion of the process is available in &man.loader.8; Loader Built-In Commands The easy-to-use command set comprises of: autoboot seconds Proceeds to boot the kernel if not interrupted within the time span given, in seconds. It displays a countdown, and the default time span is 10 seconds. boot -options kernelname Immediately proceeds to boot the kernel, with the given options, if any, and with the kernel name given, if it is. boot-conf Goes through the same automatic configuration of modules based on variables as what happens at boot. This only makes sense if you use unload first, and change some variables, most commonly kernel. help topic Shows help messages read from /boot/loader.help. If the topic given is index, then the list of available topics is given. include filename Processes the file with the given filename. The file is read in, and interpreted line by line. An error immediately stops the include command. load type filename Loads the kernel, kernel module, or file of the type given, with the filename given. Any arguments after filename are passed to the file. ls path Displays a listing of files in the given path, or the root directory, if the path is not specified. If is specified, file sizes will be shown too. lsdev Lists all of the devices from which it may be possible to load modules. If is specified, more details are printed. lsmod Displays loaded modules. If is specified, more details are shown. more filename Display the files specified, with a pause at each LINES displayed. reboot Immediately reboots the system. set variable set variable=value Set loader's environment variables. unload Removes all loaded modules. Loader Examples Here are some practical examples of loader usage. single-user mode To simply boot your usual kernel, but in single-user mode: boot -s To unload your usual kernel and modules, and then load just your old (or another) kernel: kernel.old unload load kernel.old You can use kernel.GENERIC to refer to the generic kernel that comes on the install disk, or kernel.old to refer to - your previously installed kernel (when you've upgraded + your previously installed kernel (when you have upgraded or configured your own kernel, for example). Use the following to load your usual modules with another kernel: unload set kernel="kernel.old" boot-conf To load a kernel configuration script (an automated - script which does the things you'd normally do in the + script which does the things you would normally do in the kernel boot-time configurator): load -t userconfig_script /boot/kernel.conf Kernel Interaction During Boot kernel boot interaction Once the kernel is loaded by either loader (as usual) or boot2 (bypassing the loader), it examines its boot flags, if any, and adjusts its behavior as necessary. kernel bootflags Kernel Boot Flags Here are the more common boot flags: during kernel initialization, ask for the device to mount as the root file system. boot from CDROM. run UserConfig, the boot-time kernel configurator boot into single-user mode be more verbose during kernel startup There are other boot flags, read &man.boot.8; for more information on them. init Init: Process Control Initialization Once the kernel has finished booting, it passes control to the user process init, which is located at /sbin/init, or the program path specified in the init_path variable in loader. Automatic Reboot Sequence The automatic reboot sequence makes sure that the filesystems available on the system are consistent. If they are not, and fsck cannot fix the inconsistencies, init drops the system into single-user mode for the system administrator to take care of the problems directly. Single-User Mode single-user mode console This mode can be reached through the automatic reboot sequence, or by the user booting with the option or setting the boot_single variable in loader. It can also be reached by calling shutdown without the reboot () or halt () options, from multi-user mode. If the system console is set to insecure in /etc/ttys, then the system prompts for the root password before initiating single-user mode. An Insecure Console in /etc/ttys # name getty type status comments # # This entry needed for asking password when init goes to single-user mode # If you want to be asked for password, change "secure" to "insecure" here console none unknown off insecure An insecure console means that you consider your physical security to the console to be insecure, and want to make sure only someone who knows the root password may use single-user mode, and it does not mean that you want to run your console insecurely. Thus, if you want security, choose insecure, not secure. Multi-User Mode multi-user mode If init finds your filesystems to be in order, or once the user has finished in single-user mode, the system enters multi-user mode, in which it starts the resource configuration of the system. rc files Resource Configuration (rc) The resource configuration system reads in configuration defaults from /etc/defaults/rc.conf, and system-specific details from /etc/rc.conf, and then proceeds to mount the system filesystems mentioned in /etc/fstab, start up networking services, start up miscellaneous system daemons, and finally runs the startup scripts of locally installed packages. The &man.rc.8; manual page is a good reference to the resource configuration system, as is examining the scripts themselves. Shutdown Sequence shutdown Upon controlled shutdown, via shutdown, init will attempt to run the script /etc/rc.shutdown, and then proceed to send all processes the TERM signal, and subsequently - the KILL signal to any that don't terminate + the KILL signal to any that do not terminate timely. diff --git a/en_US.ISO8859-1/books/handbook/config/chapter.sgml b/en_US.ISO8859-1/books/handbook/config/chapter.sgml index 788a0b391a..0e01b2d0c9 100644 --- a/en_US.ISO8859-1/books/handbook/config/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/config/chapter.sgml @@ -1,940 +1,940 @@ Chern Lee Written by Mike Smith Based on a tutorial written by Matt Dillon Also based on tuning(7) written by Configuration and Tuning Synopsis system configuration/optimization Configuring a system correctly can substantially reduce the amount of work involved in maintaining and upgrading it in the future. This chapter describes some of the aspects of administrative configuration of FreeBSD systems. This chapter will also describe some of the parameters that can be set to tune a FreeBSD system for optimum performance. After reading this chapter you will know: Why and how to efficiently size, layout, and place filesystems and swap partition on your hard drive. The basics of the rc.conf configuration and /usr/local/etc/rc.d startup systems. How to configure virtual hosts on your network device. How to use the various configuration files in /etc. How to tune FreeBSD using sysctl variables. How to tune disk performance and modify kernel limitations. Before reading this chapter you should: Understand the basics of Unix and FreeBSD () Initial Configuration Partition Layout Partition layout /etc /var /usr Base Partitions When laying out your filesystem with &man.disklabel.8; or &man.sysinstall.8;, it is important to remember that hard drives can transfer data at a faster rate from the outer tracks than the inner. Knowing this, you should place your smaller, heavily-accessed filesystems, such as root and swap, closer to the outside of the drive, while placing larger partitions, such as /usr, towards the inner. To do so, it is a good idea to create partitions in a similar order: root, swap, /var, /usr. The size of your /var partition reflects the intended use of your machine. /var is primarily used to hold: mailboxes, print spool and log files. Mail boxes and log files, in particular, can grow to unexpected sizes based upon how many users are on your system and how long your log files are kept. If you intend to run a mail server, a /var partition of over a gigabyte can be suitable. Additionally, /var/tmp must be large enough to contain any packages you may wish to add. The /usr partition holds the bulk of the files required to support the system and a subdirectory within it called /usr/local holds the bulk of the files installed from the &man.ports.7; hierarchy. If you do not use ports all that much and do not intend to keep system source (/usr/src) on the machine, you can get away with a 1 gigabyte /usr partition. However, if you install a lot of ports (especially window managers and Linux binaries), we recommend at least a two gigabyte /usr and if you also intend to keep system source on the machine, we recommend a three gigabyte /usr. Do not underestimate the amount of space you will need in this partition, it can creep up and surprise you! When sizing your partitions, keep in mind the space requirements for your system to grow. Running out of space in one partition while having plenty in another can lead to much frustration. Some users who have used &man.sysinstall.8;'s Auto-defaults partition sizer have found either their root or /var partitions too small later on. Partition wisely and generously. Swap Partition swap sizing swap partition As a rule of thumb, your swap space should typically be double the amount of main memory. For example, if the machine has 128 megabytes of memory, the swap file should be 256 megabytes. Systems with lesser memory may perform better with a lot more swap. It is not recommended that you configure any less than 256 megabytes of swap on a system and you should keep in mind future memory expansion when sizing the swap partition. The kernel's VM paging algorithms are tuned to perform best when the swap partition is at least two times the size of main memory. Configuring too little swap can lead to inefficiencies in the VM page scanning code as well as create issues later on if you add more memory to your machine. Finally, on larger systems with multiple SCSI disks (or multiple IDE disks operating on different controllers), it is strongly recommend that you configure swap on each drive (up to four drives). The swap partitions on the drives should be approximately the same size. The kernel can handle arbitrary sizes but internal data structures scale to 4 times the largest swap partition. Keeping the swap partitions near the same size will allow the kernel to optimally stripe swap space across the disks. Do not worry about overdoing it a little, - swap space is the saving grace of Unix. Even if you don't + swap space is the saving grace of Unix. Even if you do not normally use much swap, it can give you more time to recover from a runaway program before being forced to reboot. Why Partition? Why partition at all? Why not create one big root - partition and be done with it? Then I don't have to worry + partition and be done with it? Then I do not have to worry about undersizing things! There are several reasons this is not a good idea. First, each partition has different operational characteristics and separating them allows the filesystem to tune itself to those characteristics. For example, the root and /usr partitions are read-mostly, with very little writing, while a lot of reading and writing could occur in /var and /var/tmp. By properly partitioning your system, fragmentation introduced in the smaller more heavily write-loaded partitions will not bleed over into the mostly-read partitions. Additionally, keeping the write-loaded partitions closer to the edge of the disk, for example before the really big partition instead of after in the partition table, will increase I/O performance in the partitions where you need it the most. Now it is true that you might also need I/O performance in the larger partitions, but they are so large that shifting them more towards the edge of the disk will not lead to a significant performance improvement whereas moving /var to the edge can have a huge impact. Finally, there are safety concerns. Having a small neat root partition that is essentially read-only gives it a greater chance of surviving a bad crash intact. Core Configuration rc files rc.conf The principal location for system configuration information is within /etc/rc.conf. This file contains a wide range of configuration information, principally used at system startup to configure the system. Its name directly implies this; it is configuration information for the rc* files. An administrator should make entries in the rc.conf file to override the default settings from /etc/defaults/rc.conf. The defaults file should not be copied verbatim to /etc - it contains default values, not examples. All system-specific changes should be made in the rc.conf file itself. A number of strategies may be applied in clustered applications to separate site-wide configuration from system-specific configuration in order to keep administration overheads down. The recommended approach is to place site-wide configuration into another file, such as /etc/rc.conf.site, and then include this file into /etc/rc.conf, which will contain only system-specific information. As rc.conf is read by &man.sh.1; it is trivial to achieve this. For example: rc.conf: . rc.conf.site hostname="node15.webcompany.com" network_interfaces="fxp0 lo0" ifconfig_fxp0="inet 10.1.1.1" rc.conf.site: defaultrouter="10.1.1.254" saver="daemon" blanktime="100" The rc.conf.site file can then be distributed to every system using rsync or similar program, whilst the rc.conf file remains unique. Upgrading the system using &man.sysinstall.8; or make world will not overwrite the rc.conf file, so system configuration information will not be lost. Application Configuration Typically, installed applications have their own configuration files, with their own syntax, etc. It is important that these files be kept separate from the base system, so that they may be easily located and managed by the package management tools. /usr/local/etc Typically, these files are installed in /usr/local/etc. In the case where an application has a large number of configuration files, a subdirectory will be created to hold them. Normally, when a port or package is installed, sample configuration files are also installed. These are usually identified with a .default suffix. If there are no existing configuration files for the application, they will be created by copying the .default files. For example, here is /usr/local/etc/apache: -rw-r--r-- 1 root wheel 2184 May 20 1998 access.conf -rw-r--r-- 1 root wheel 2184 May 20 1998 access.conf.default -rw-r--r-- 1 root wheel 9555 May 20 1998 httpd.conf -rw-r--r-- 1 root wheel 9555 May 20 1998 httpd.conf.default -rw-r--r-- 1 root wheel 12205 May 20 1998 magic -rw-r--r-- 1 root wheel 12205 May 20 1998 magic.default -rw-r--r-- 1 root wheel 2700 May 20 1998 mime.types -rw-r--r-- 1 root wheel 2700 May 20 1998 mime.types.default -rw-r--r-- 1 root wheel 7980 May 20 1998 srm.conf -rw-r--r-- 1 root wheel 7933 May 20 1998 srm.conf.default It can be quickly seen that only the srm.conf file has been changed. A later update of the apache port would not overwrite this changed file. Starting Services services It is common for a system to host a number of services. These may be started in several different fashions, each having different advantages. /usr/local/etc/rc.d Software installed from a port or the packages collection will often place a script in /usr/local/etc/rc.d which is invoked at system startup with a argument, and at system shutdown with a argument. This is the recommended way for starting system-wide services that are to be run as root, or that expect to be started as root. These scripts are registered as part of the installation of the package, and will be removed when the package is removed. A generic startup script in /usr/local/etc/rc.d looks like: #!/bin/sh echo -n ' FooBar' case "$1" in start) /usr/local/bin/foobar ;; stop) kill -9 `cat /var/run/foobar.pid` ;; *) echo "Usage: `basename $0` {start|stop}" >&2 exit 64 ;; esac exit 0 This script is called with at startup, and the at shutdown to allow it to carry out its purpose. Some services expect to be invoked by &man.inetd.8; when a connection is received on a suitable port. This is common for mail reader servers (POP and IMAP, etc.). These services are enabled by editing the file /etc/inetd.conf. See &man.inetd.8; for details on editing this file. Some additional system services may not be covered by the toggles in /etc/rc.conf. These are traditionally enabled by placing the command(s) to invoke them in /etc/rc.local. As of FreeBSD 3.1 there is no default /etc/rc.local; if it is created by the administrator it will however be honored in the normal fashion. Note that rc.local is generally regarded as the location of last resort; if there is a better place to start a service, do it there. Do not place any commands in /etc/rc.conf. To start daemons, or run any commands at boot time, place a script in /usr/local/etc/rc.d instead. It is also possible to use the &man.cron.8; daemon to start system services. This approach has a number of advantages, not least being that because &man.cron.8; runs these processes as the owner of the crontab, services may be started and maintained by non-root users. This takes advantage of an undocumented feature of &man.cron.8; the time specification may be replaced by @reboot, which will cause the job to be run when &man.cron.8; is started shortly after system boot. Virtual Hosts virtual hosts ip aliases A very common use of FreeBSD is virtual site hosting, where one server appears to the network as many servers. This is achieved by assigning multiple network addresses to a single interface. A given network interface has one real address, and may have any number of alias addresses. These aliases are normally added by placing alias entries in /etc/rc.conf. An alias entry for the interface fxp0 looks like: ifconfig_fxp0_alias0="inet xxx.xxx.xxx.xxx netmask xxx.xxx.xxx.xxx" Note that alias entries must start with alias0 and proceed upwards in order, (for example, _alias1, _alias2, and so on). The configuration process will stop at the first missing number. The calculation of alias netmasks is important, but fortunately quite simple. For a given interface, there must be one address which correctly represents the network's netmask. Any other addresses which fall within this network must have a netmask of all 1's. For example, consider the case where the fxp0 interface is connected to two networks, the 10.1.1.0 network with a netmask of 255.255.255.0 and the 202.0.75.16 network with a netmask of 255.255.255.240. We want the system to appear at 10.1.1.1 through 10.1.1.5 and at 202.0.75.17 through 202.0.75.20. The following entries configure the adapter correctly for this arrangement: ifconfig_fxp0="inet 10.1.1.1 netmask 255.255.255.0" ifconfig_fxp0_alias0="inet 10.1.1.2 netmask 255.255.255.255" ifconfig_fxp0_alias1="inet 10.1.1.3 netmask 255.255.255.255" ifconfig_fxp0_alias2="inet 10.1.1.4 netmask 255.255.255.255" ifconfig_fxp0_alias3="inet 10.1.1.5 netmask 255.255.255.255" ifconfig_fxp0_alias4="inet 202.0.75.17 netmask 255.255.255.240" ifconfig_fxp0_alias5="inet 202.0.75.18 netmask 255.255.255.255" ifconfig_fxp0_alias6="inet 202.0.75.19 netmask 255.255.255.255" ifconfig_fxp0_alias7="inet 202.0.75.20 netmask 255.255.255.255" Configuration Files <filename>/etc</filename> Layout There are a number of directories in which configuration information is kept. These include: /etc Generic system configuration information; data here is system-specific. /etc/defaults Default versions of system configuration files. /etc/mail Extra &man.sendmail.8; configuration, other MTA configuration files. /etc/ppp Configuration for both user- and kernel-ppp programs. /etc/namedb Default location for &man.named.8; data. Normally the boot file is located here, and contains a directive to refer to other data in /var/db. /usr/local/etc Configuration files for installed applications. May contain per-application subdirectories. /usr/local/etc/rc.d Start/stop scripts for installed applications. /var/db Persistent system-specific data files, such as &man.named.8; zone files, database files, and so on. Hostnames hostname DNS <filename>/etc/resolv.conf</filename> resolv.conf /etc/resolv.conf dictates how FreeBSD's resolver accesses the Internet Domain Name System (DNS). The most common entries to resolv.conf are: name server The IP address of a name server the resolver should query. The servers are queried in the order listed with a maximum of three. search Search list hostname lookup. This is normally determined by the domain of the local hostname. domain The local domain name. A typical resolv.conf: search foobar.com nameserver 147.11.1.11 nameserver 147.11.100.30 If you are using DHCP, &man.dhclient.8; usually rewrites resolv.conf with information received from the DHCP server. <filename>/etc/hosts</filename> hosts /etc/hosts is a simple text database reminiscent of the old Internet. It works in conjunction with DNS and NIS providing name to IP address mappings. Local computers connected via a LAN can be placed in here for simplistic naming purposes instead of setting up a &man.named.8; server. Additionally, /etc/hosts can be used to provide a local record of Internet names, reducing the need to query externally for commonly accessed names. # $FreeBSD$ # # Host Database # This file should contain the addresses and aliases # for local hosts that share this file. # In the presence of the domain name service or NIS, this file may # not be consulted at all; see /etc/nsswitch.conf for the resolution order. # # ::1 localhost localhost.my.domain myname.my.domain 127.0.0.1 localhost localhost.my.domain myname.my.domain # # Imaginary network. #10.0.0.2 myname.my.domain myname #10.0.0.3 myfriend.my.domain myfriend # # According to RFC 1918, you can use the following IP networks for # private nets which will never be connected to the Internet: # # 10.0.0.0 - 10.255.255.255 # 172.16.0.0 - 172.31.255.255 # 192.168.0.0 - 192.168.255.255 # # In case you want to be able to connect to the Internet, you need # real official assigned numbers. PLEASE PLEASE PLEASE do not try # to invent your own network numbers but instead get one from your # network provider (if any) or from the Internet Registry (ftp to # rs.internic.net, directory `/templates'). # /etc/hosts takes on the simple format of: [Internet address] [official hostname] [alias1] [alias2] ... For example: 10.0.0.1 myRealHostname.foobar.com myRealHostname foobar1 foobar2 Consult &man.hosts.5; for more information. Log File Configuration log files <filename>syslog.conf</filename> syslog.conf syslog.conf is the configuration file for the &man.syslogd.8; program. It indicates which types of syslog messages are logged to particular log files. # $FreeBSD$ # # Spaces ARE valid field separators in this file. However, # other *nix-like systems still insist on using tabs as field # separators. If you are sharing this file between systems, you # may want to use only tabs as field separators here. # Consult the syslog.conf(5) manual page. *.err;kern.debug;auth.notice;mail.crit /dev/console *.notice;kern.debug;lpr.info;mail.crit;news.err /var/log/messages security.* /var/log/security mail.info /var/log/maillog lpr.info /var/log/lpd-errs cron.* /var/log/cron *.err root *.notice;news.err root *.alert root *.emerg * # uncomment this to log all writes to /dev/console to /var/log/console.log #console.info /var/log/console.log # uncomment this to enable logging of all log messages to /var/log/all.log #*.* /var/log/all.log # uncomment this to enable logging to a remote log host named loghost #*.* @loghost # uncomment these if you're running inn # news.crit /var/log/news/news.crit # news.err /var/log/news/news.err # news.notice /var/log/news/news.notice !startslip *.* /var/log/slip.log !ppp *.* /var/log/ppp.log Consult the &man.syslog.conf.5; manual page for more information. <filename>newsyslog.conf</filename> newsyslog.conf newsyslog.conf is the configuration file for &man.newsyslog.8;, a program that is scheduled to run normally by &man.cron.8; &man.newsyslog.8; determines when log files require archiving or rearranging. logfile is moved to logfile.1, logfile.1 is moved to logfile.2, and so on. Additionally, the log files may be archived in &man.gzip.1; format causing them to be named: logfile.0.gz, logfile.1.gz, and so on. newsyslog.conf indicates which log files are to be managed, how many are to be kept, and when they are to be touched. Log files can be rearranged and/or archived when they have either reached a certain size, or at a certain periodic time/date. # configuration file for newsyslog # $FreeBSD$ # # filename [owner:group] mode count size when [ZB] [/pid_file] [sig_num] /var/log/cron 600 3 100 * Z /var/log/amd.log 644 7 100 * Z /var/log/kerberos.log 644 7 100 * Z /var/log/lpd-errs 644 7 100 * Z /var/log/maillog 644 7 * @T00 Z /var/log/sendmail.st 644 10 * 168 B /var/log/messages 644 5 100 * Z /var/log/all.log 600 7 * @T00 Z /var/log/slip.log 600 3 100 * Z /var/log/ppp.log 600 3 100 * Z /var/log/security 600 10 100 * Z /var/log/wtmp 644 3 * @01T05 B /var/log/daily.log 640 7 * @T00 Z /var/log/weekly.log 640 5 1 $W6D0 Z /var/log/monthly.log 640 12 * $M1D0 Z /var/log/console.log 640 5 100 * Z Consult the &man.newsyslog.8; manual page for more information. <filename>sysctl.conf</filename> sysctl.conf sysctl sysctl.conf looks much like rc.conf. Values are set in a variable=value form. The specified values are set after the system goes into multi-user mode. Not all variables are settable in this mode. A sample sysctl.conf turning off logging of fatal signal exits and letting Linux programs know they are really running under FreeBSD. kern.logsigexit=0 # Do not log fatal signal exits (e.g. sig 11) compat.linux.osname=FreeBSD compat.linux.osrelease=4.3-STABLE Tuning with sysctl sysctl Tuning with sysctl &man.sysctl.8; is an interface that allows you to make changes to a running FreeBSD system. This includes many advanced options of the TCP/IP stack and virtual memory system that can dramatically improve performance for an experienced system administrator. Over five hundred system variables can be read and set using &man.sysctl.8;. At its core, &man.sysctl.8; serves to do two functions: read and modify system settings. To view all readable variables: &prompt.user; sysctl -a To read a particular variable, for example, kern.maxproc: &prompt.user; sysctl kern.maxproc kern.maxproc: 1044 To set a particular variable, use the = option: &prompt.root; sysctl kern.maxfiles=5000 kern.maxfiles: 2088 -> 5000 Settings of sysctl variables are usually either strings, numbers, or booleans. A boolean being 1 for yes or a 0 for no. Tuning Disks Sysctl Variables <varname>vfs.vmiodirenable</varname> vfs.vmiodirenable The vfs.vmiodirenable sysctl variable defaults to 0 (off) (though soon it will default to 1) and may be set to 0 (off) or 1 (on). This parameter controls how directories are cached by the system. Most directories are small and use but a single fragment (typically 1K) in the filesystem and even less (typically 512 bytes) in the buffer cache. However, when operating in the default mode the buffer cache will only cache a fixed number of directories even if you have a huge amount of memory. Turning on this sysctl allows the buffer cache to use the VM Page Cache to cache the directories. The advantage is that all of memory is now available for caching directories. The disadvantage is that the minimum in-core memory used to cache a directory is the physical page size (typically 4K) rather than 512 bytes. We recommend turning this option on if you are running any services which manipulate large numbers of files. Such services can include web caches, large mail systems, and news systems. Turning on this option will generally not reduce performance even with the wasted memory but you should experiment to find out. <varname>hw.ata.wc</varname> hw.ata.wc FreeBSD 4.3 flirted with turning off IDE write caching. This reduced write bandwidth to IDE disks but was considered necessary due to serious data consistency issues introduced by hard drive vendors. Basically the problem is that IDE drives lie about when a write completes. With IDE write caching turned on, IDE hard drives will not only write data to disk out of order, they will sometimes delay some of the blocks indefinitely when under heavy disk loads. A crash or power failure can result in serious filesystem corruption. So our default was changed to be safe. Unfortunately, the result was such a huge loss in performance that we caved in and changed the default back to on after the release. You should check the default on your system by observing the hw.ata.wc sysctl variable. If IDE write caching is turned off, you can turn it back on by setting the kernel variable back to 1. This must be done from the boot loader at boot time. Attempting to do it after the kernel boots will have no effect. For more information, please see &man.ata.4;. Soft Updates Soft Updates tunefs The &man.tunefs.8; program can be used to fine-tune a filesystem. This program has many different options, but for now we are only concerned with toggling Soft Updates on and off, which is done by : &prompt.root; tunefs -n enable /filesystem &prompt.root; tunefs -n disable /filesystem A filesystem cannot be modified with &man.tunefs.8; while it is mounted. A good time to enable Soft Updates is before any partitions have been mounted, in single-user mode. Soft Updates drastically improves meta-data performance, mainly file creation and deletion, through the use of a memory cache. We recommend turning Soft Updates on on all of your filesystems. There are two downsides to Soft Updates that you should be aware of: First, Soft Updates guarantees filesystem consistency in the case of a crash but could very easily be several seconds (even a minute!) behind updating the physical disk. If you crash you may lose more work than otherwise. Secondly, Soft Updates delays the freeing of filesystem blocks. If you have a filesystem (such as the root filesystem) which is close to full, doing a major update of it, e.g. make installworld, can run it out of space and cause the update to fail. Tuning Kernel Limits Tuning kernel limits File/Process Limits <varname>kern.maxfiles</varname> kern.maxfiles kern.maxfiles can be raised or lowered based upon your system requirements. This variable indicates the maximum number of file descriptors on your system. When the file descriptor table is full, file: table is full will show up repeatedly in the system message buffer, which can be viewed with the dmesg command. Each open file, socket, or fifo uses one file descriptor. A large-scale production server may easily require many thousands of file descriptors, depending on the kind and number of services running concurrently. kern.maxfile's default value is dictated by the option in your kernel configuration file. kern.maxfiles grows proportionally to the value of . diff --git a/en_US.ISO8859-1/books/handbook/cutting-edge/chapter.sgml b/en_US.ISO8859-1/books/handbook/cutting-edge/chapter.sgml index bca5456c4a..c3f6e03e0c 100644 --- a/en_US.ISO8859-1/books/handbook/cutting-edge/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/cutting-edge/chapter.sgml @@ -1,1535 +1,1535 @@ The Cutting Edge Restructured, reorganized, and parts updated by &a.jim; March 2000. Original work by &a.jkh;, &a.phk;, &a.jdp;, and &a.nik; with feedback from various others. Synopsis &os; is under constant development between releases. For people who want to be on the cutting edge, there are several easy mechanisms for keeping your system in sync with the latest developments. Be warned—the cutting edge is not for everyone! This chapter will help you decide if you want to track the development system, or stick with one of the released versions. &os.current; vs. &os.stable; -CURRENT -STABLE There are two development branches to FreeBSD; &os.current; and &os.stable;. This section will explain a bit about each and describe how to keep your system up-to-date with each respective tree. &os.current; will be discussed first, then &os.stable;. Staying Current with &os; As you are reading this, keep in mind that &os.current; is the bleeding edge of &os; development and that if you are new to &os;, you are most likely going to want to think twice about running it. What Is &os.current;? snapshot &os.current; is, quite literally, nothing more than a daily snapshot of the working sources for &os;. These include work in progress, experimental changes and transitional mechanisms that may or may not be present in the next official release of the software. While many of us compile almost daily from &os.current; sources, there are periods of time when the sources are literally un-compilable. These problems are generally resolved as expeditiously as possible, but whether or not &os.current; sources bring disaster or greatly desired functionality can literally be a matter of which part of any given 24 hour period you grabbed them in! Who Needs &os.current;? &os.current; is made generally available for 3 primary interest groups: Members of the &os; group who are actively working on some part of the source tree and for whom keeping current is an absolute requirement. Members of the &os; group who are active testers, willing to spend time working through problems in order to ensure that &os.current; remains as sane as possible. These are also people who wish to make topical suggestions on changes and the general direction of &os;. Peripheral members of the &os; (or some other) group who merely wish to keep an eye on things and use the current sources for reference purposes (e.g. for reading, not running). These people also make the occasional comment or contribute code. What Is &os.current; <emphasis>Not</emphasis>? A fast-track to getting pre-release bits because you heard there is some cool new feature in there and you want to be the first on your block to have it. A quick way of getting bug fixes. In any way officially supported by us. We do our best to help people genuinely in one of the 3 legitimate &os.current; categories, but we simply do not have the time to provide tech support for it. This is not because we are mean and nasty people who do not like helping people out (we would not even be doing &os; if we were), it is literally because we cannot answer 400 messages a day and actually work on FreeBSD! Given the choice between improving &os; and answering lots of questions, most developers, and users, would probably opt for the former. Using &os.current; Join the &a.current; and the &a.cvsall; . This is not just a good idea, it is essential. If you are not on the &a.current;, you will not see the comments that people are making about the current state of the system and thus will probably end up stumbling over a lot of problems that others have already found and solved. Even more importantly, you will miss out on important bulletins which may be critical to your system's continued health. The &a.cvsall; mailing list will allow you to see the commit log entry for each change as it is made along with any pertinent information on possible side-effects. To join these lists, send mail to &a.majordomo; and specify the following in the body of your message: subscribe freebsd-current subscribe cvs-all majordomo Optionally, you can also say help and Majordomo will send you full help on how to subscribe and unsubscribe to the various other mailing lists we support. Grab the sources from ftp.FreeBSD.org. You can do this in one of three ways: cvsup cron -CURRENT Syncing with CVSup Use the cvsup program with this supfile. This is the second most recommended method, since it allows you to grab the entire collection once and then only what has changed from then on. Many people run cvsup from cron and keep their sources up-to-date automatically. For a fairly easy interface to this, simply type:
&prompt.root; pkg_add -f ftp://ftp.FreeBSD.org/pub/FreeBSD/development/CVSup/cvsupit.tgz
-CURRENT Downloading with ftp Use ftp. The source tree for &os.current; is always exported on: ftp://ftp.FreeBSD.org/pub/FreeBSD/FreeBSD-current/. Our FTP server server also allows compressed/tarred grabbing of whole trees. e.g. you see: usr.bin/lex You can do the following to get the whole directory as a tar file: ftp> cd usr.bin ftp> get lex.tar -CURRENT Syncing with CTM Use the CTM facility. If you have very bad connectivity (high price connections or only email access) CTM is an option. However, it is a lot of hassle and can give you broken files. This leads to it being rarely used, which again increases the chance of it not working for fairly long periods of time. We recommend using CVSup for anybody with a 9600bps modem or faster connection.
If you are grabbing the sources to run, and not just look at, then grab all of &os.current;, not just selected portions. The reason for this is that various parts of the source depend on updates elsewhere, and trying to compile just a subset is almost guaranteed to get you into trouble. Before compiling &os.current;, read the Makefilein /usr/src carefully. You should at least run a make world the first time through as part of the upgrading process. Reading the &a.current; will keep you up-to-date on other bootstrapping procedures that sometimes become necessary as we move towards the next release. Be active! If you are running &os.current;, we want to know what you have to say about it, especially if you have suggestions for enhancements or bug fixes. Suggestions with accompanying code are received most enthusiastically!
Staying Stable with &os; What Is &os.stable;? -STABLE &os.stable; is our development branch from which major releases are made. Changes go into this branch at a different pace, and - with the general assumption that they've first gone into + with the general assumption that they have first gone into &os.current; first for testing. This is still a development branch, however, and this means that at any given time, the sources for &os.stable; may or may not be suitable for any particular purpose. It is simply another engineering development track, not a resource for end-users. Who Needs &os.stable;? If you are interested in tracking or contributing to the FreeBSD development process, especially as it relates to the next point release of FreeBSD, then you should consider following &os.stable;. While it is true that security fixes also go into the &os.stable; branch, you do not need to track &os.stable; to do this. Every security advisory for FreeBSD explains how to fix the problem for the releases it affects, and tracking an entire development branch just for security reasons is likely to bring in a lot of unwanted changes as well. Although we endeavor to ensure that the &os.stable; branch compiles and runs at all times, this cannot be guaranteed. In addition, while code is developed in &os.current; before including it in &os.stable;, more people run &os.stable; than &os.current;, so it is inevitable that bugs and corner cases will sometimes be found in &os.stable; that were not apparent in &os.current;. For these reasons, we do not recommend that you blindly track &os.stable;, and it is particularly important that you do not update any production servers to &os.stable; without first thoroughly testing the code in your development environment. If you do not have the resources to do this then we recommend that you run the most recent release of FreeBSD, and use the binary update mechanism to move from release to release. Using &os.stable; -STABLE using Join the &a.stable;. This will keep you informed of build-dependencies that may appear in &os.stable; or any other issues requiring special attention. Developers will also make announcements in this mailing list when they are contemplating some controversial fix or update, giving the users a chance to respond if they have any issues to raise concerning the proposed change. The &a.cvsall; mailing list will allow you to see the commit log entry for each change as it is made along with any pertinent information on possible side-effects. To join these lists, send mail to &a.majordomo; and specify the following in the body of your message: subscribe freebsd-stable subscribe cvs-all majordomo Optionally, you can also say help and Majordomo will send you full help on how to subscribe and unsubscribe to the various other mailing lists we support. If you are installing a new system and want it to be as stable as possible, you can simply grab the latest dated branch snapshot from ftp://releng4.FreeBSD.org/pub/FreeBSD/ and install it like any other release. If you are already running a previous release of &os; and wish to upgrade via sources then you can easily do so from ftp.FreeBSD.org. This can be done in one of three ways: CTM -STABLE syncing with CTM Use the CTM facility. Unless you have a good TCP/IP connection at a flat rate, this is the way to do it. -STABLE syncing with CVSup Use the cvsup program with this supfile. This is the second most recommended method, since it allows you to grab the entire collection once and then only what has changed from then on. Many people run cvsup from cron to keep their sources up-to-date automatically. For a fairly easy interface to this, simply type:
&prompt.root; pkg_add -f ftp://ftp.FreeBSD.org/pub/FreeBSD/development/CVSup/cvsupit.tgz
-STABLE downloading with FTP Use ftp. The source tree for &os.stable; is always exported on: ftp://ftp.FreeBSD.org/pub/FreeBSD/FreeBSD-stable/ We also use wu-ftpd which allows compressed/tarred grabbing of whole trees. e.g. you see: usr.bin/lex You can do the following to get the whole directory for you as a tar file: ftp> cd usr.bin ftp> get lex.tar
Essentially, if you need rapid on-demand access to the source and communications bandwidth is not a consideration, use cvsup or ftp. Otherwise, use CTM. -STABLE compiling Before compiling &os.stable;, read the Makefile in /usr/src carefully. You should at least run a make world the first time through as part of the upgrading process. Reading the &a.stable; will keep you up-to-date on other bootstrapping procedures that sometimes become necessary as we move towards the next release.
Synchronizing Your Source There are various ways of using an Internet (or email) connection to stay up-to-date with any given area of the &os; project sources, or all areas, depending on what interests you. The primary services we offer are Anonymous CVS, CVSup, and CTM. While it is possible to update only parts of your source tree, the only supported update procedure is to update the entire tree and recompile both userland (i.e., all the programs that run in user space, such as those in /bin and /sbin) and kernel sources. Updating only part of your source tree, only the kernel, or only userland will often result in problems. These problems may range from compile errors to kernel panics or data corruption. anonymous CVS Anonymous CVS and CVSup use the pull model of updating sources. In the case of CVSup the user (or a cron script) invokes the cvsup program, and it interacts with a cvsupd server somewhere to bring your files up-to-date. The updates you receive are up-to-the-minute and you get them when, and only when, you want them. You can easily restrict your updates to the specific files or directories that are of interest to you. Updates are generated on the fly by the server, according to what you have and what you want to have. Anonymous CVS is quite a bit more - simplistic than CVSup in that it's just an extension to + simplistic than CVSup in that it is just an extension to CVS which allows it to pull changes directly from a remote CVS repository. CVSup can do this far more efficiently, but Anonymous CVS is easier to use. CTM CTM, on the other hand, does not interactively compare the sources you have with those on the master archive or otherwise pull them across.. Instead, a script which identifies changes in files since its previous run is executed several times a day on the master CTM machine, any detected changes being compressed, stamped with a sequence-number and encoded for transmission over email (in printable ASCII only). Once received, these CTM deltas can then be handed to the &man.ctm.rmail.1; utility which will automatically decode, verify and apply the changes to the user's copy of the sources. This process is far more efficient than CVSup, and places less strain on our server resources since it is a push rather than a pull model. There are other trade-offs, of course. If you inadvertently wipe out portions of your archive, CVSup will detect and rebuild the damaged portions for you. - CTM won't do this, and if you wipe some - portion of your source tree out (and don't have it backed up) then + CTM will not do this, and if you wipe some + portion of your source tree out (and do not have it backed up) then you will have to start from scratch (from the most recent CVS base delta) and rebuild it all with CTM or, with anoncvs, simply delete the bad bits and resync. More information about Anonymous CVS, CTM, and CVSup is available further down in this section. Using <command>make world</command> make world Once you have synchronized your local source tree against a particular version of &os; (&os.stable;, &os.current;, and so on) you can then use the source tree to rebuild the system. Take a Backup It cannot be stressed enough how important it is to take a backup of your system before you do this. While rebuilding the world is (as long as you follow these instructions) an easy task to do, there will inevitably be times when you make mistakes, or when mistakes made by others in the source tree render your system unbootable. Make sure you have taken a backup. And have a fix-it floppy to hand. You will probably never have to use it, but it is better to be safe than sorry! Subscribe to the Right Mailing List mailing list The &os.stable; and &os.current; branches are, by their nature, in development. People that contribute to &os; are human, and mistakes occasionally happen. Sometimes these mistakes can be quite harmless, just causing your system to print a new diagnostic warning. Or the change may be catastrophic, and render your system unbootable or destroy your filesystems (or worse). If problems like these occur, a heads up is posted to the appropriate mailing list, explaining the nature of the problem and which systems it affects. And an all clear announcement is posted when the problem has been solved. If you try and track &os.stable; or &os.current; and do not read the stable@FreeBSD.org or current@FreeBSD.org mailing lists then you are asking for trouble. Read <filename>/usr/src/UPDATING</filename> Before you do anything else, read /usr/src/UPDATING (or the equivalent file wherever you have a copy of the source code). This file should contain important information about problems you might encounter, or specify the order in which you might have to run certain commands. If UPDATING contradicts something you read here, UPDATING takes precedence. Reading UPDATING is not an acceptable substitute for subscribing to the correct mailing list, as described previously. The two requirements are complementary, not exclusive. Check <filename>/etc/make.conf</filename> make.conf Examine the files /etc/defaults/make.conf and /etc/make.conf. The first contains some default defines – most of which are commented out. To make use of them when you rebuild your system from source, add them to /etc/make.conf. Keep in mind that anything you add to /etc/make.conf is also used every time you run make, so it is a good idea to set them to something sensible for your system. A typical user will probably want to copy the CFLAGS and NOPROFILE lines found in /etc/defaults/make.conf to /etc/make.conf and uncomment them. Examine the other definitions (COPTFLAGS, NOPORTDOCS and so on) and decide if they are relevant to you. Update <filename>/etc/group</filename> The /etc directory contains a large part of your system's configuration information, as well as scripts that are run at system startup. Some of these scripts change from version to version of FreeBSD. Some of the configuration files are also used in the day to day running of the system. In particular, /etc/group. There have been occasions when the installation part of make world has expected certain usernames or groups to exist. When performing an upgrade it is likely that these groups did not exist. This caused problems when upgrading. The most recent example of this is when the ppp subsystem were installed using a non-existent (for them) group name. The solution is to examine /usr/src/etc/group and compare its list of groups with your own. If there are any groups in the new file that are not in your file then copy them over. Similarly, you should rename any groups in /etc/group which have the same GID but a different name to those in /usr/src/etc/group. If you are feeling particularly paranoid, you can check your system to see which files are owned by the group you are renaming or deleting. &prompt.root; find / -group GID -print will show all files owned by group GID (which can be either a group name or a numeric group ID). Drop to Single User Mode single-user mode You may want to compile the system in single user mode. Apart from the obvious benefit of making things go slightly faster, reinstalling the system will touch a lot of important system files, all the standard system binaries, libraries, include files and so on. Changing these on a running system (particularly if you have active users on the system at the time) is asking for trouble. multi-user mode Another method is to compile the system in multi-user mode, and then drop into single user mode for the installation. If you would like to do it this way, simply hold off on the following steps until the build has completed. As the superuser, you can execute &prompt.root; from a running system, which will drop it to single user mode. Alternatively, reboot the system, and at the boot prompt, enter the flag. The system will then boot single user. At the shell prompt you should then run: &prompt.root; fsck -p &prompt.root; mount -u / &prompt.root; mount -a -t ufs &prompt.root; swapon -a This checks the filesystems, remounts / read/write, mounts all the other UFS filesystems referenced in /etc/fstab and then turns swapping on. Remove <filename>/usr/obj</filename> As parts of the system are rebuilt they are placed in directories which (by default) go under /usr/obj. The directories shadow those under /usr/src. You can speed up the make world process, and possibly save yourself some dependency headaches by removing this directory as well. Some files below /usr/obj may have the immutable flag set (see &man.chflags.1; for more information) which must be removed first. &prompt.root; cd /usr/obj &prompt.root; chflags -R noschg * &prompt.root; rm -rf * Recompile the Source Saving the Output It is a good idea to save the output you get from running &man.make.1; to another file. If something goes wrong you will have a copy of the error message. While this might not help you in diagnosing what has gone wrong, it can help others if you post your problem to one of the &os; mailing lists. The easiest way to do this is to use the &man.script.1; command, with a parameter that specifies the name of the file to save all output to. You would do this immediately before rebuilding the world, and then type exit when the process has finished. &prompt.root; script /var/tmp/mw.out Script started, output file is /var/tmp/mw.out &prompt.root; make TARGET … compile, compile, compile … &prompt.root; exit Script done, … If you do this, do not save the output in /tmp. This directory may be cleared next time you reboot. A better place to store it is in /var/tmp (as in the previous example) or in root's home directory. Compile and Install the Base System You must be in the /usr/src directory... &prompt.root; cd /usr/src (unless, of course, your source code is elsewhere, in which case change to that directory instead). make To rebuild the world you use the &man.make.1; command. This command reads instructions from the Makefile, which describes how the programs that comprise &os; should be rebuilt, the order in which they should be built, and so on. The general format of the command line you will type is as follows: &prompt.root; make In this example, is an option that you would pass to &man.make.1;. See the &man.make.1; manual page for an example of the options you can pass. passes a variable to the Makefile. The behavior of the Makefile is controlled by these variables. These are the same variables as are set in /etc/make.conf, and this provides another way of setting them. &prompt.root; make -DNOPROFILE=true target is another way of specifying that profiled libraries should not be built, and corresponds with the NOPROFILE= true # Avoid compiling profiled libraries lines in /etc/make.conf. target tells &man.make.1; what you want to do. Each Makefile defines a number of different targets, and your choice of target determines what happens. Some targets are listed in the Makefile, but are not meant for you to run. Instead, they are used by the build process to break out the steps necessary to rebuild the system into a number of sub-steps. - Most of the time you won't need to pass any parameters to + Most of the time you will not need to pass any parameters to &man.make.1;, and so your command like will look like this: &prompt.root; make target Beginning with version 2.2.5 of &os; (actually, it was first created on the &os.current; branch, and then retrofitted to &os.stable; midway between 2.2.2 and 2.2.5) the world target has been split in two. buildworld and installworld. As the names imply, buildworld builds a complete new tree under /usr/obj, and installworld installs this tree on the current machine. This is very useful for 2 reasons. First, it allows you to do the build safe in the knowledge that no components of your running system will be affected. The build is self hosted. Because of this, you can safely run buildworld on a machine running in multi-user mode with no fear of ill-effects. It is still recommended that you run the installworld part in single user mode, though. Secondly, it allows you to use NFS mounts to upgrade multiple machines on your network. If you have three machines, A, B and C that you want to upgrade, run make buildworld and make installworld on A. B and C should then NFS mount /usr/src and /usr/obj from A, and you can then run make installworld to install the results of the build on B and C. Although the world target still exists, you are strongly encouraged not to use it. Run &prompt.root; make buildworld It is now possible to specify a -j option to make which will cause it to spawn several simultaneous processes. This is most useful on multi-CPU machines. However, since much of the compiling process is IO bound rather than CPU bound it is also useful on single CPU machines. On a typical single-CPU machine you would run: &prompt.root; make -j4 buildworld &man.make.1; will then have up to 4 processes running at any one time. Empirical evidence posted to the mailing lists shows this generally gives the best performance benefit. If you have a multi-CPU machine and you are using an SMP configured kernel try values between 6 and 10 and see how they speed things up. Be aware that this is still somewhat experimental, and commits to the source tree may occasionally break this feature. If the world fails to compile using this parameter try again without it before you report any problems. Timings make world timings Many factors influence the build time, but currently a 500 MHz Pentium 3 with 128 MB of RAM takes about 3 and a half hours to build the &os.current; tree, with no tricks or shortcuts used during the process. A &os.stable; tree will build somewhat faster. Compile and Install a New Kernel kernel compiling To take full advantage of your new system you should recompile the kernel. This is practically a necessity, as certain memory structures may have changed, and programs like &man.ps.1; and &man.top.1; will fail to work until the kernel and source code versions are the same. The simplest, safest way to do this is to build and install a kernel based on GENERIC. While GENERIC may not have all the necessary devices for your system, it should contain everything necessary to boot your system back to single user mode. This is a good test that the new system works properly. After booting from GENERIC and verifying that your system works you can then build a new kernel based on your normal kernel configuration file. If you are upgrading to &os; 4.0 or above then the standard kernel build procedure (as described in ) is deprecated. Instead, you should run these commands. &prompt.root; cd /usr/src &prompt.root; make buildkernel &prompt.root; make installkernel If you are upgrading to a version of &os; below 4.0 you should use the standard kernel build procedure. However, it is recommended that you use the new version of &man.config.8;, using a command line like this. &prompt.root; /usr/obj/usr/src/usr.sbin/config/config KERNELNAME Reboot into Single User Mode single-user mode You should reboot in to single user mode to test the new kernel works. Do this by following the instructions in . Install the New System Binaries If you were building a version of &os; recent enough to have used make buildworld then you should now use the installworld to install the new system binaries. Run &prompt.root; make installworld If you specified variables on the make buildworld command line, you must specify the same variables in the make installworld command line. This does not necessarily hold true for other options; for example, must never be used with installworld. For example, if you ran: &prompt.root; make -DNOPROFILE=true buildworld you must install the results with: &prompt.root; make -DNOPROFILE=true installworld otherwise it would try and install profiled libraries that had not been built during the make buildworld phase. Update Files Not Updated by <command>make world</command> Remaking the world will not update certain directories (in particular, /etc, /var and /usr) with new or changed configuration files. mergemaster The simplest way to update these files is to use &man.mergemaster.8;, though it is possible to do it manually if you would prefer to do that. We strongly recommend you use &man.mergemaster.8;, however, and if you do then you can skip forward to the next section, since &man.mergemaster.8; is very simple to use. You should read the manual page first, and make a backup of /etc in case anything goes wrong. If you wish to do the update manually, you cannot just copy over the files from /usr/src/etc to /etc and have it work. Some of these files must be installed first. This is because the /usr/src/etc directory is not a copy of what your /etc directory should look like. In addition, there are files that should be in /etc that are not in /usr/src/etc. The simplest way to do this by hand is to install the files into a new directory, and then work through them looking for differences. Backup Your Existing <filename>/etc</filename> Although, in theory, nothing is going to touch this directory automatically, it is always better to be sure. So copy your existing /etc directory somewhere safe. Something like: &prompt.root; cp -Rp /etc /etc.old does a recursive copy, preserves times, ownerships on files and suchlike. You need to build a dummy set of directories to install the new /etc and other files into. /var/tmp/root is a reasonable choice, and there are a number of subdirectories required under this as well. &prompt.root; mkdir /var/tmp/root &prompt.root; cd /usr/src/etc &prompt.root; make DESTDIR=/var/tmp/root distrib-dirs distribution This will build the necessary directory structure and install the files. A lot of the subdirectories that have been created under /var/tmp/root are empty and should be deleted. The simplest way to do this is to: &prompt.root; cd /var/tmp/root &prompt.root; find -d . -type d | xargs rmdir 2>/dev/null This will remove all empty directories. (Standard error is redirected to /dev/null to prevent the warnings about the directories that are not empty.) /var/tmp/root now contains all the files that should be placed in appropriate locations below /. You now have to go through each of these files, determining how they differ with your existing files. Note that some of the files that will have been installed in /var/tmp/root have a leading /var/tmp/root/ and /var/tmp/root/root/, although there may be others (depending on when you are reading this. Make sure you use The simplest way to do this is to use &man.diff.1; to compare the two files. &prompt.root; diff /etc/shells /var/tmp/root/etc/shells This will show you the differences between your /etc/shells file and the new /etc/shells file. Use these to decide whether to merge in changes that you have made or whether to copy over your old file. Name the New Root Directory (<filename>/var/tmp/root</filename>) with a Time Stamp, So You Can Easily Compare Differences Between Versions Frequently rebuilding the world means that you have to update /etc frequently as well, which can be a bit of a chore. You can speed this process up by keeping a copy of the last set of changed files that you merged into /etc. The following procedure gives one idea of how to do this. Make the world as normal. When you want to update /etc and the other directories, give the target directory a name based on the current date. If you were doing this on the 14th of February 1998 you could do the following. &prompt.root; mkdir /var/tmp/root-19980214 &prompt.root; cd /usr/src/etc &prompt.root; make DESTDIR=/var/tmp/root-19980214 \ distrib-dirs distribution Merge in the changes from this directory as outlined above. Do not remove the /var/tmp/root-19980214 directory when you have finished. When you have downloaded the latest version of the source and remade it, follow step 1. This will give you a new directory, which might be called /var/tmp/root-19980221 (if you wait a week between doing updates). You can now see the differences that have been made in the intervening week using &man.diff.1; to create a recursive diff between the two directories. &prompt.root; cd /var/tmp &prompt.root; diff -r root-19980214 root-19980221 Typically, this will be a much smaller set of differences than those between /var/tmp/root-19980221/etc and /etc. Because the set of differences is smaller, it is easier to migrate those changes across into your /etc directory. You can now remove the older of the two /var/tmp/root-* directories. &prompt.root; rm -rf /var/tmp/root-19980214 Repeat this process every time you need to merge in changes to /etc. You can use &man.date.1; to automate the generation of the directory names. &prompt.root; mkdir /var/tmp/root-`date "+%Y%m%d"` Update <filename>/dev</filename> DEVFS DEVFS If you are using DEVFS this is unnecessary. In most cases, the &man.mergemaster.8 tool will realize when it is necessary to update the devices, and offer to complete it automatically. These instructions tell how to update the devices manually. For safety's sake, this is a multi-step process. Copy /var/tmp/root/dev/MAKEDEV to /dev. &prompt.root; cp /var/tmp/root/dev/MAKEDEV /dev MAKEDEV If you used &man.mergemaster.8; to update /etc, then your MAKEDEV script should have been updated - already, though it can't hurt to check (with &man.diff.1;) + already, though it cannot hurt to check (with &man.diff.1;) and copy it manually if necessary. Now, take a snapshot of your current /dev. This snapshot needs to contain the permissions, ownerships, major and minor numbers of each filename, but it should not contain the time stamps. The easiest way to do this is to use &man.awk.1; to strip out some of the information. &prompt.root; cd /dev &prompt.root; ls -l | awk '{print $1, $2, $3, $4, $5, $6, $NF}' > /var/tmp/dev.out Remake all the devices. &prompt.root; Write another snapshot of the directory, this time to /var/tmp/dev2.out. Now look through these two files for any devices that you missed creating. There should not be any, but it is better to be safe than sorry. &prompt.root; diff /var/tmp/dev.out /var/tmp/dev2.out You are most likely to notice disk slice discrepancies which will involve commands such as &prompt.root; sh MAKEDEV sd0s1 to recreate the slice entries. Your precise circumstances may vary. Update <filename>/stand</filename> This step is included only for completeness. It can safely be omitted. For the sake of completeness, you may want to update the files in /stand as well. These files consist of hard links to the /stand/sysinstall binary. This binary should be statically linked, so that it can work when no other filesystems (and in particular /usr) have been mounted. &prompt.root; cd /usr/src/release/sysinstall &prompt.root; make all install Rebooting You are now done. After you have verified that everything appears to be in the right place you can reboot the system. A simple &man.fastboot.8; should do it. &prompt.root; fastboot Finished You should now have successfully upgraded your &os; system. Congratulations. If things went slightly wrong, it is easy to rebuild a particular piece of the system. For example, if you accidently deleted /etc/magic as part of the upgrade or merge of /etc, the &man.file.1; command will stop working. In this case, the fix would be to run: &prompt.root; cd /usr/src/usr.bin/file &prompt.root; Questions Do I need to re-make the world for every change? There is no easy answer to this one, as it depends on the nature of the change. For example, if you just ran CVSup, and it has shown the following files as being updated, src/games/cribbage/instr.c src/games/sail/pl_main.c src/release/sysinstall/config.c src/release/sysinstall/media.c src/share/mk/bsd.port.mk it probably is not worth rebuilding the entire world. You could just go to the appropriate sub-directories and make all install, and that's about it. But if something major changed, for example src/lib/libc/stdlib then you should either re-make the world, or at least those parts of it that are statically linked (as well as anything else you might have added that is statically linked). At the end of the day, it is your call. You might be happy re-making the world every fortnight say, and let changes accumulate over that fortnight. Or you might want to re-make just those things that have changed, and are confident you can spot all the dependencies. And, of course, this all depends on how often you want to upgrade, and whether you are tracking &os.stable; or &os.current;. My compile failed with lots of signal 11 (or other signal number) errors. What has happened? signal 11 This is normally indicative of hardware problems. (Re)making the world is an effective way to stress test your hardware, and will frequently throw up memory problems. These normally manifest themselves as the compiler mysteriously dying on receipt of strange signals. A sure indicator of this is if you can restart the make and it dies at a different point in the process. In this instance there is little you can do except start swapping around the components in your machine to determine which one is failing. Can I remove /usr/obj when I have finished? The short answer is yes. /usr/obj contains all the object files that were produced during the compilation phase. Normally, one of the first steps in the /usr/obj around after you have finished makes little sense, and will free up a large chunk of disk space (currently about 340MB). However, if you know what you are doing you can have If you want to live dangerously then make the world, passing the NOCLEAN definition to make, like this: &prompt.root; make -DNOCLEAN world Can interrupted builds be resumed? This depends on how far through the process you got before you found a problem. In general (and this is not a hard and fast rule) the make world process builds new copies of essential tools (such as &man.gcc.1;, and &man.make.1;) and the system libraries. These tools and libraries are then installed. The new tools and libraries are then used to rebuild themselves, and are installed again. The entire system (now including regular user programs, such as &man.ls.1; or &man.grep.1;) is then rebuilt with the new system files. If you are at the last stage, and you know it (because you have looked through the output that you were storing) then you can (fairly safely) do … fix the problem … &prompt.root; cd /usr/src &prompt.root; make -DNOCLEAN all This will not undo the work of the previous make world. If you see the message -------------------------------------------------------------- Building everything.. -------------------------------------------------------------- in the make world output then it is probably fairly safe to do so. If you do not see that message, or you are not sure, then it is always better to be safe than sorry, and restart the build from scratch. NFS Can I use one machine as a This is a fairly easy task, and can save hours of compile time for many machines. Simply run the buildworld on a central machine, and then NFS mount /usr/src and /usr/obj on the remote machine and installworld there. How can I speed up making the world? Run in single user mode. Put the /usr/src and /usr/obj directories on separate filesystems held on separate disks. If possible, put these disks on separate disk controllers. Better still, put these filesystems across multiple disks using the &man.ccd.4 (concatenated disk driver) device. Turn off profiling (set NOPROFILE=true in /etc/make.conf). You almost certainly do not need it. Also in /etc/make.conf, set CFLAGS to something like -O -pipe. The optimization -O2 is much slower, and the optimization difference between -O and -O2 is normally negligible. -pipe lets the compiler use pipes rather than temporary files for communication, which saves disk access (at the expense of memory). Pass the option to make to run multiple processes in parallel. This usually helps regardless of whether you have a single or a multi processor machine. The filesystem holding /usr/src can be mounted (or remounted) with the option. This prevents the filesystem from recording the file access time. You probably do not need this information anyway. &prompt.root; mount -u -o noatime /usr/src The example assumes /usr/src is on its own filesystem. If it is not (if it is a part of /usr for example) then you will need to use that filesystem mount point, and not /usr/src. The filesystem holding /usr/obj can be mounted (or remounted) with the async option. This causes disk writes to happen asynchronously. In other words, the write completes immediately, and the data is written to the disk a few seconds later. This allows writes to be clustered together, and can be a dramatic performance boost. Keep in mind that this option makes your filesystem more fragile. With this option there is an increased chance that, should power fail, the filesystem will be in an unrecoverable state when the machine restarts. If /usr/obj is the only thing on this filesystem then it is not a problem. If you have other, valuable data on the same filesystem then ensure your backups are fresh before you enable this option. &prompt.root; mount -u -o async /usr/obj As above, if /usr/obj is not on its own filesystem, replace it in the example with the name of the appropriate mount point.
diff --git a/en_US.ISO8859-1/books/handbook/disks/chapter.sgml b/en_US.ISO8859-1/books/handbook/disks/chapter.sgml index c4e508727e..e58897b45a 100644 --- a/en_US.ISO8859-1/books/handbook/disks/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/disks/chapter.sgml @@ -1,1285 +1,1285 @@ Disks Synopsis This chapter covers how to use disks, whether physical, memory, or networked, on FreeBSD. BIOS Drive Numbering Before you install and configure FreeBSD on your system, there is an important subject that you should be aware of, especially if you have multiple hard drives. DOS Microsoft Windows In a PC running DOS or any of the BIOS-dependent operating systems (WINxxx), the BIOS is able to abstract the normal disk drive order, and the operating system goes along with the change. This allows the user to boot from a disk drive other than the so-called primary master. This is especially convenient for some users who have found that the simplest and cheapest way to keep a system backup is to buy an identical second hard drive, and perform routine copies of the first drive to the second drive using Ghost or XCOPY . Then, if the first drive fails, or is attacked by a virus, or is scribbled upon by an operating system defect, he can easily recover by instructing the BIOS - to logically swap the drives. It's like switching the cables on the + to logically swap the drives. It is like switching the cables on the drives, but without having to open the case. SCSI BIOS More expensive systems with SCSI controllers often include BIOS extensions which allow the SCSI drives to be re-ordered in a similar fashion for up to seven drives. A user who is accustomed to taking advantage of these features may become surprised when the results with FreeBSD are not as expected. FreeBSD does not use the BIOS, and does not know the logical BIOS drive mapping. This can lead to very perplexing situations, especially when drives are physically identical in geometry, and have also been made as data clones of one another. When using FreeBSD, always restore the BIOS to natural drive numbering before installing FreeBSD, and then leave it that way. If you need to switch drives around, then do so, but do it the hard way, and open the case and move the jumpers and cables. An Illustration from the Files of Bill and Fred's Exceptional Adventures: Bill breaks-down an older Wintel box to make another FreeBSD box for Fred. Bill installs a single SCSI drive as SCSI unit zero, and installs FreeBSD on it. Fred begins using the system, but after several days notices that the older SCSI drive is reporting numerous soft errors, and reports this fact to Bill. - After several more days, Bill decides it's time to address the + After several more days, Bill decides it is time to address the situation, so he grabs an identical SCSI drive from the disk drive "archive" in the back room. An initial surface scan indicates that this drive is functioning well, so Bill installs this drive as SCSI unit four, and makes an image copy from drive zero to drive four. Now that the new drive is installed and functioning nicely, Bill decides - that it's a good idea to start using it, so he uses features in the + that it is a good idea to start using it, so he uses features in the SCSI BIOS to re-order the disk drives so that the system boots from SCSI unit four. FreeBSD boots and runs just fine. Fred continues his work for several days, and soon Bill and Fred - decide that it's time for a new adventure -- time to upgrade to a + decide that it is time for a new adventure -- time to upgrade to a newer version of FreeBSD. Bill removes SCSI unit zero because it was a bit flaky, and replaces it with another identical disk drive from the "archive." Bill then installs the new version of FreeBSD onto the new SCSI unit zero using Fred's magic Internet FTP floppies. The installation goes well. Fred uses the new version of FreeBSD for a few days, and certifies - that it is good enough for use in the engineering department...it's + that it is good enough for use in the engineering department...it is time to copy all of his work from the old version. So Fred mounts SCSI unit four (the latest copy of the older FreeBSD version). Fred is dismayed to find that none of his precious work is present on SCSI unit four. Where did the data go? When Bill made an image copy of the original SCSI unit zero onto SCSI unit four, unit four became the "new clone," When Bill re-ordered the SCSI BIOS so that he could boot from SCSI unit four, he was only fooling himself. FreeBSD was still running on SCSI unit zero. Making this kind of BIOS change will cause some or all of the Boot and Loader code to be fetched from the selected BIOS drive, but when the FreeBSD kernel drivers take-over, the BIOS drive numbering will be ignored, and FreeBSD will transition back to normal drive numbering. In the illustration at hand, the system continued to operate on the original SCSI unit zero, and all of Fred's data was there, not on SCSI unit four. The fact that the system appeared to be running on SCSI unit four was simply an artifact of human expectations. We are delighted to mention that no data bytes were killed or harmed in any way by our discovery of this phenomenon. The older SCSI unit zero was retrieved from the bone pile, and all of Fred's work was returned to him, (and now Bill knows that he can count as high as zero). Although SCSI drives were used in this illustration, the concepts apply equally to IDE drives. Disk Naming IDE SCSI RAID fash memory Physical drives come in two main flavors, IDE, or SCSI; but there are also drives backed by RAID controllers, flash memory, and so forth. Since these behave quite differently, they have their own drivers and devices. Physical Disk Naming Conventions Drive type Drive device name IDE hard drives ad in 4.0-RELEASE, wd before 4.0-RELEASE. IDE CDROM drives acd from 4.1-RELEASE, wcd before 4.0-RELEASE. SCSI hard drives da from 3.0-RELEASE, sd before 3.0-RELEASE. SCSI CDROM drives cd Assorted non-standard CDROM drives mcd for Mitsumi CD-ROM, scd for Sony CD-ROM, matcd for Matsushita/Panasonic CD-ROM Floppy drives fd SCSI tape drives sa from 3.0-RELEASE, st before 3.0-RELEASE. IDE tape drives ast from 4.0-RELEASE, wst before 4.0-RELEASE. Flash drives fla for DiskOnChip Flash device from 3.3-RELEASE. RAID drives myxd for Mylex, and amrd for AMI MegaRAID, idad for Compaq Smart RAID. from 4.0-RELEASE. id between 3.2-RELEASE and 4.0-RELEASE.
Slices and Partitions slices partitions dangerously dedicated Physical disks usually contain slices, unless they are dangerously dedicated. Slice numbers follow the device name, prefixed with an s: da0s1. Slices, dangerously dedicated physical drives, and other drives contain partitions, which are represented as letters from a to h. b is reserved for swap partitions, and c is an unused partition the size of the entire slice or drive. This is explained in .
Mounting and Unmounting Filesystems The filesystem is best visualized as a tree, rooted, as it were, at /. /dev, /usr, and the other directories in the root directory are branches, which may have their own branches, such as /usr/local, and so on. root filesystem There are various reasons to house some of these directories on separate filesystems. /var contains the directories log/, spool/, and various types of temporary files, and as such, may get filled up. Filling up the root filesystem - isn't a good idea, so splitting /var from + is not a good idea, so splitting /var from / is often favorable. Another common reason to contain certain directory trees on other filesystems is if they are to be housed on separate physical disks, or are separate virtual disks, such as Network File System mounts, or CDROM drives. The <filename>fstab</filename> File filesystems mounted with fstab During the boot process, filesystems listed in /etc/fstab are automatically mounted (unless they are listed with ). The /etc/fstab file contains a list of lines of the following format: device /mount-point fstype options dumpfreq passno device A device name (which should exist), as explained in the Disk naming conventions above. mount-point A directory (which should exist), on which to mount the filesystem. fstype The filesystem type to pass to &man.mount.8;. The default FreeBSD filesystem is ufs. options Either for read-write filesystems, or for read-only filesystems, followed by any other options that may be needed. A common option is for filesystems not normally mounted during the boot sequence. Other options are listed in the &man.mount.8; manual page. dumpfreq The number of days the filesystem should be dumped, and passno is the pass number during which the filesystem is checked during the boot sequence. The mount Command filesystems mounting The &man.mount.8; command is what is ultimately used to mount filesystems. In its most basic form, you use: &prompt.root; mount device mountpoint There are plenty of options, as mentioned in the &man.mount.8; manual page, but the most common are: Mount Options Mount all the filesystems listed in /etc/fstab. Exceptions are those marked as noauto, excluded by the flag, or those that are already mounted. Do everything except for the actual system call. This option is useful in conjunction with the flag to determine what the mount is actually trying to do. Force the mount of an unclean filesystem (dangerous), or forces the revocation of write access when downgrading a filesystem's mount status from read-write to read-only. Mount the filesystem read-only. This is identical to using the argument to the option. fstype Mount the given filesystem as the given filesystem type, or mount only filesystems of the given type, if given the option. ufs is the default filesystem type. Update mount options on the filesystem. Be verbose. Mount the filesystem read-write. The option takes a comma-separated list of the options, including the following: nodev Do not interpret special devices on the filesystem. This is a useful security option. noexec Do not allow execution of binaries on this filesystem. This is also a useful security option. nosuid Do not interpret setuid or setgid flags on the filesystem. This is also a useful security option. The <command>umount</command> Command filesystems unmounting The &man.umount.8; command takes, as a parameter, one of a mountpoint, a device name, or the or option. All forms take to force unmounting, and for verbosity. and are used to unmount all mounted filesystems, possibly modified by the filesystem types listed after . - , however, doesn't attempt to unmount the + , however, does not attempt to unmount the root filesystem. David O'Brien Originally contributed by Adding Disks disks adding Lets say we want to add a new SCSI disk to a machine that currently only has a single drive. First turn off the computer and install the drive in the computer following the instructions of the computer, controller, and drive manufacturer. Due the wide variations of procedures to do this, the details are beyond the scope of this document. - Login as user root. After you've installed the + Login as user root. After you have installed the drive, inspect /var/run/dmesg.boot to ensure the new disk was found. Continuing with our example, the newly added drive will be da1 and we want to mount it on /1 (if you are adding an IDE drive, the device name will be wd1 in pre-4.0 systems, or ad1 in most 4.X systems). partitions slices fdisk Because FreeBSD runs on IBM-PC compatible computers, it must take into account the PC BIOS partitions. These are different from the traditional BSD partitions. A PC disk has up to four BIOS partition entries. If the disk is going to be truly dedicated to FreeBSD, you can use the dedicated mode. Otherwise, FreeBSD will have to live within one of the PC BIOS partitions. FreeBSD calls the PC BIOS partitions slices so as not to confuse them with traditional BSD partitions. You may also use slices on a disk that is dedicated to FreeBSD, but used in a computer that also has another operating system installed. This is to not confuse the fdisk utility of the other operating system. In the slice case the drive will be added as /dev/da1s1e. This is read as: SCSI disk, unit number 1 (second SCSI disk), slice 1 (PC BIOS partition 1), and e BSD partition. In the dedicated case, the drive will be added simply as /dev/da1e. Using &man.sysinstall.8; sysinstall adding disks su Navigating <application>Sysinstall</application> You may use /stand/sysinstall to partition and label a new disk using its easy to use menus. Either login as user root or use the su command. Run /stand/sysinstall and enter the Configure menu. Within the FreeBSD Configuration Menu, scroll down and select the Partition item. Next you should be presented with a list of hard drives installed in your system. If you do not see da1 listed, you need to recheck your physical installation and dmesg output in the file /var/run/dmesg.boot. FDISK Partition Editor Select da1 to enter the FDISK Partition Editor. Type A to use the entire disk for FreeBSD. When asked if you want to remain cooperative with any future possible operating systems, answer YES. Write the changes to the disk using W. Now exit the FDISK editor by typing q. Next you will be asked about the Master Boot Record. Since you are adding a disk to an already running system, choose None. Disk Label Editor BSD partitions Next, Sysinstall will enter the Disk Label Editor. This is where you will create the traditional BSD partitions. A disk can have up to eight partitions, labeled a-h. A few of the partition labels have special uses. The a partition is used for the root partition (/). Thus only your system disk (e.g, the disk you boot from) should have an a partition. The b partition is used for swap partitions, and you may have many disks with swap partitions. The c partition addresses the entire disk in dedicated mode, or the entire FreeBSD slice in slice mode. The other partitions are for general use. Sysinstall's Label editor favors the e partition for non-root, non-swap partitions. Within the Label editor, create a single file system by typing C. When prompted if this will be a FS (file system) or swap, choose FS and type in a mount point (e.g, /mnt). When adding a disk in post-install mode, Sysinstall will not create entries in /etc/fstab for you, so the mount point - you specify isn't important. + you specify is not important. You are now ready to write the new label to the disk and create a file system on it. Do this by typing W. Ignore any errors from Sysinstall that it could not mount the new partition. Exit the Label Editor and Sysinstall completely. Finish The last step is to edit /etc/fstab to add an entry for your new disk. Using Command Line Utilities Using Slices This setup will allow your disk to work correctly with other operating systems that might be installed on your computer and will not confuse other operating systems' fdisk utilities. It is recommended to use this method for new disk installs. Only use dedicated mode if you have a good reason to do so! &prompt.root; dd if=/dev/zero of=/dev/rda1 bs=1k count=1 &prompt.root; fdisk -BI da1 #Initialize your new disk &prompt.root; disklabel -B -w -r da1s1 auto #Label it. &prompt.root; disklabel -e da1s1 # Edit the disklabel just created and add any partitions. &prompt.root; mkdir -p /1 &prompt.root; newfs /dev/da1s1e # Repeat this for every partition you created. &prompt.root; mount -t ufs /dev/da1s1e /1 # Mount the partition(s) &prompt.root; vi /etc/fstab # Add the appropriate entry/entries to your /etc/fstab. If you have an IDE disk, substitute ad for da. On pre-4.X systems use wd. Dedicated OS/2 If you will not be sharing the new drive with another operating system, you may use the dedicated mode. Remember this mode can confuse Microsoft operating systems; however, no damage will be done by them. IBM's OS/2 however, will appropriate any partition it finds which it doesn't understand. &prompt.root; dd if=/dev/zero of=/dev/rda1 bs=1k count=1 &prompt.root; disklabel -Brw da1 auto &prompt.root; disklabel -e da1 # create the `e' partition &prompt.root; newfs -d0 /dev/rda1e &prompt.root; mkdir -p /1 &prompt.root; vi /etc/fstab # add an entry for /dev/da1e &prompt.root; mount /1 An alternate method is: &prompt.root; dd if=/dev/zero of=/dev/rda1 count=2 &prompt.root; disklabel /dev/rda1 | disklabel -BrR da1 /dev/stdin &prompt.root; newfs /dev/rda1e &prompt.root; mkdir -p /1 &prompt.root; vi /etc/fstab # add an entry for /dev/da1e &prompt.root; mount /1 Virtual Disks: Network, Memory, and File-Based Filesystems virtual disks disks virtual Aside from the disks you physically insert into your computer: floppies, CDs, hard drives, and so forth; other forms of disks are understood by FreeBSD - the virtual disks. NFS Coda disks memory These include network filesystems such as the Network Filesystem and Coda, memory-based filesystems such as md and file-backed filesystems created by vnconfig or mdconfig. vnconfig: File-Backed Filesystem disks file-backed &man.vnconfig.8; configures and enables vnode pseudo-disk devices. A vnode is a representation of a file, and is the focus of file activity. This means that &man.vnconfig.8; uses files to create and operate a filesystem. One possible use is the mounting of floppy or CD images kept in files. To mount an existing filesystem image: Using vnconfig to mount an Existing Filesystem Image &prompt.root; vnconfig vn0 diskimage &prompt.root; mount /dev/vn0c /mnt To create a new filesystem image with vnconfig: Creating a New File-Backed Disk with vnconfig &prompt.root; dd if=/dev/zero of=newimage bs=1k count=5k 5120+0 records in 5120+0 records out &prompt.root; vnconfig -s labels -c vn0 newimage &prompt.root; disklabel -r -w vn0 auto &prompt.root; newfs vn0c Warning: 2048 sector(s) in last cylinder unallocated /dev/rvn0c: 10240 sectors in 3 cylinders of 1 tracks, 4096 sectors 5.0MB in 1 cyl groups (16 c/g, 32.00MB/g, 1280 i/g) super-block backups (for fsck -b #) at: 32 &prompt.root; mount /dev/vn0c /mnt &prompt.root; df /mnt Filesystem 1K-blocks Used Avail Capacity Mounted on /dev/vn0c 4927 1 4532 0% /mnt md: Memory Filesystem disks memory filesystem md is a simple, efficient means to create memory filesystems. - Simply take a filesystem you've prepared with, for + Simply take a filesystem you have prepared with, for example, &man.vnconfig.8;, and: md Memory Disk &prompt.root; dd if=newimage of=/dev/md0 5120+0 records in 5120+0 records out &prompt.root; mount /dev/md0c /mnt &prompt.root; df /mnt Filesystem 1K-blocks Used Avail Capacity Mounted on /dev/md0c 4927 1 4532 0% /mnt Disk Quotas accounting disk space disk quotas Quotas are an optional feature of the operating system that allow you to limit the amount of disk space and/or the number of files a user, or members of a group, may allocate on a per-file system basis. This is used most often on timesharing systems where it is desirable to limit the amount of resources any one user or group of users may allocate. This will prevent one user from consuming all of the available disk space. Configuring Your System to Enable Disk Quotas Before attempting to use disk quotas it is necessary to make sure that quotas are configured in your kernel. This is done by adding the following line to your kernel configuration file: options QUOTA The stock GENERIC kernel does not have this enabled by default, so you will have to configure, build and install a custom kernel in order to use disk quotas. Please refer to for more information on kernel configuration. Next you will need to enable disk quotas in /etc/rc.conf. This is done by adding the line: enable_quotas=YES disk quotas checking For finer control over your quota startup, there is an additional configuration variable available. Normally on bootup, the quota integrity of each file system is checked by the quotacheck program. The quotacheck facility insures that the data in the quota database properly reflects the data on the file system. This is a very time consuming process that will significantly affect the time your system takes to boot. If you would like to skip this step, a variable in /etc/rc.conf is made available for the purpose: check_quotas=NO If you are running FreeBSD prior to 3.2-RELEASE, the configuration is simpler, and consists of only one variable. Set the following in your /etc/rc.conf: check_quotas=YES Finally you will need to edit /etc/fstab to enable disk quotas on a per-file system basis. This is where you can either enable user or group quotas or both for all of your file systems. To enable per-user quotas on a file system, add the userquota option to the options field in the /etc/fstab entry for the file system you want to enable quotas on. For example: /dev/da1s2g /home ufs rw,userquota 1 2 Similarly, to enable group quotas, use the groupquota option instead of the userquota keyword. To enable both user and group quotas, change the entry as follows: /dev/da1s2g /home ufs rw,userquota,groupquota 1 2 By default the quota files are stored in the root directory of the file system with the names quota.user and quota.group for user and group quotas respectively. See &man.fstab.5; for more information. Even though the &man.fstab.5; manual page says that you can specify an alternate location for the quota files, this is not recommended because the various quota utilities do not seem to handle this properly. At this point you should reboot your system with your new kernel. /etc/rc will automatically run the appropriate commands to create the initial quota files for all of the quotas you enabled in /etc/fstab, so there is no need to manually create any zero length quota files. In the normal course of operations you should not be required to run the quotacheck, quotaon, or quotaoff commands manually. However, you may want to read their manual pages just to be familiar with their operation. Setting Quota Limits disk quotas limits Once you have configured your system to enable quotas, verify that they really are enabled. An easy way to do this is to run: &prompt.root; quota -v You should see a one line summary of disk usage and current quota limits for each file system that quotas are enabled on. You are now ready to start assigning quota limits with the edquota command. You have several options on how to enforce limits on the amount of disk space a user or group may allocate, and how many files they may create. You may limit allocations based on disk space (block quotas) or number of files (inode quotas) or a combination of both. Each of these limits are further broken down into two categories; hard and soft limits. hard limit A hard limit may not be exceeded. Once a user reaches his hard limit he may not make any further allocations on the file system in question. For example, if the user has a hard limit of 500 blocks on a file system and is currently using 490 blocks, the user can only allocate an additional 10 blocks. Attempting to allocate an additional 11 blocks will fail. soft limit Soft limits, on the other hand, can be exceeded for a limited amount of time. This period of time is known as the grace period, which is one week by default. If a user stays over his or her soft limit longer than the grace period, the soft limit will turn into a hard limit and no further allocations will be allowed. When the user drops back below the soft limit, the grace period will be reset. The following is an example of what you might see when you run the edquota command. When the edquota command is invoked, you are placed into the editor specified by the EDITOR environment variable, or in the vi editor if the EDITOR variable is not set, to allow you to edit the quota limits. &prompt.root; edquota -u test Quotas for user test: /usr: blocks in use: 65, limits (soft = 50, hard = 75) inodes in use: 7, limits (soft = 50, hard = 60) /usr/var: blocks in use: 0, limits (soft = 50, hard = 75) inodes in use: 0, limits (soft = 50, hard = 60) You will normally see two lines for each file system that has quotas enabled. One line for the block limits, and one line for inode limits. Simply change the value you want updated to modify the quota limit. For example, to raise this users block limit from a soft limit of 50 and a hard limit of 75 to a soft limit of 500 and a hard limit of 600, change: /usr: blocks in use: 65, limits (soft = 50, hard = 75) to: /usr: blocks in use: 65, limits (soft = 500, hard = 600) The new quota limits will be in place when you exit the editor. Sometimes it is desirable to set quota limits on a range of uids. This can be done by use of the option on the edquota command. First, assign the desired quota limit to a user, and then run edquota -p protouser startuid-enduid. For example, if user test has the desired quota limits, the following command can be used to duplicate those quota limits for uids 10,000 through 19,999: &prompt.root; edquota -p test 10000-19999 For more information see &man.edquota.8;. Checking Quota Limits and Disk Usage disk quotas checking You can use either the quota or the repquota commands to check quota limits and disk usage. The quota command can be used to check individual user and group quotas and disk usage. Only the super-user may examine quotas and usage for other users, or for groups that they are not a member of. The repquota command can be used to get a summary of all quotas and disk usage for file systems with quotas enabled. The following is some sample output from the quota -v command for a user that has quota limits on two file systems. Disk quotas for user test (uid 1002): Filesystem blocks quota limit grace files quota limit grace /usr 65* 50 75 5days 7 50 60 /usr/var 0 50 75 0 50 60 grace period On the /usr file system in the above example this user is currently 15 blocks over the soft limit of 50 blocks and has 5 days of the grace period left. Note the asterisk * which indicates that the user is currently over his quota limit. Normally file systems that the user is not using any disk space on will not show up in the output from the quota command, even if he has a quota limit assigned for that file system. The option will display those file systems, such as the /usr/var file system in the above example. Quotas over NFS NFS Quotas are enforced by the quota subsystem on the NFS server. The &man.rpc.rquotad.8; daemon makes quota information available to the &man.quota.1; command on NFS clients, allowing users on those machines to see their quota statistics. Enable rpc.rquotad in /etc/inetd.conf like so: rquotad/1 dgram rpc/udp wait root /usr/libexec/rpc.rquotad rpc.rquotad Now restart inetd: &prompt.root; kill -HUP `cat /var/run/inetd.pid` Mike Meyer Contributed by Creating CDs CDROMs creating Introduction CDs have a number of features that differentiate them from - conventional disks. Initially, they weren't writable by the + conventional disks. Initially, they were not writable by the user. They are designed so that they can be read continuously without delays to move the head between tracks. They are also much easier to transport between systems than similarly sized media were at the time. CDs do have tracks, but this refers to a section of data to be read continuously and not a physical property of the disk. To produce a CD on FreeBSD, you prepare the data files that are going to make up the tracks on the CD, then write the tracks to the CD. ISO 9660 filesystems ISO-9660 The ISO 9660 file system was designed to deal with these differences. It unfortunately codifies file system limits that were common then. Fortunately, it provides an extension mechanism that allows properly written CDs to exceed those limits while still working with systems that do not support those extensions. mkisofs The mkisofs program is used to produce a data file containing an ISO 9660 file system. It has options that support various extensions, and is described below. You can install it with the sysutils/mkisofs port. CD burner ATAPI Which tool to use to burn the CD depends on whether your CD burner is ATAPI or something else. ATAPI CD burners use the burncd program that is part of the base system. SCSI and USB CD burners should use the cdrecord from the sysutils/cdrtools port. burncd has a limited number of supported drives. To find out if a drive is supported, see CD-R/RW supported drives. mkisofs mkisofs produces an ISO 9660 file system that is an image of a directory tree in the Unix file system name space. The simplest usage is: &prompt.root; mkisofs imagefile.iso /path/to/tree filesystems ISO-9660 This command will create an imagefile containing an ISO 9660 file system that is a copy of the tree at /path/to/tree. In the process, it will map the file names to names that fit the limitations of the standard ISO 9660 file system, and will exclude files that have names uncharacteristic of ISO file systems. filesystems HFS filesystems Joliet A number of options are available to overcome those restrictions. In particular, enables the Rock Ridge extensions common to Unix systems, enables Joliet extensions used by Microsoft systems, and can be used to create HFS file systems used by MacOS. For CDs that are going to be used only on FreeBSD systems, can be used to disable all filename restrictions. When used with , it produces a file system image that is identical to the FreeBSD tree you started from, though it may violate the ISO 9660 standard in a number of ways. CDROMs creating bootable The last option of general use is . This is used to specify the location of the boot image for use in producing an El Torito bootable CD. This option takes an argument which is the path to a boot image from the top of the tree being written to the CD. So, given that /tmp/myboot holds a bootable FreeBSD system with the boot image in /tmp/myboot/boot/cdboot, you could produce the image of an ISO 9660 file system in /tmp/bootable.iso like so: &prompt.root; mkisofs boot/cdboot /tmp/bootable.iso /tmp/myboot Having done that, if you have vn configured in your kernel, you can mount the file system with: &prompt.root; vnconfig vn0c /tmp/bootable.iso &prompt.root; mount cd9660 /dev/vn0c /mnt At which point you can verify that /mnt and /tmp/myboot are identical. There are many other options you can use with mkisofs to fine-tune its behavior. In particular: modifications to an ISO 9660 layout and the creation of Joilet and HFS discs. See the &man.mkisofs.8; manual page for details. burncd CDROMs burning If you have an ATAPI CD burner, you can use the burncd command to burn an ISO image onto a CD. burncd is part of the base system, installed as /usr/sbin/burncd. Usage is very simple, as it has few options: &prompt.root; burncd cddevice data imagefile.iso fixate Will burn a copy of imagefile.iso on cddevice. The default device is /dev/acd0c. See &man.burncd.8; for options to set the write speed, eject the CD after burning, and write audio data. cdrecord If you do not have an ATAPI CD burner, you will have to use cdrecord to burn your CDs. cdrecord is not part of the base system; you must install it from either the port at sysutils/cdrtools or the appropriate package. Changes to the base system can cause binary versions of this program to fail, possibly resulting in a coaster. You should therefore either upgrade the port when you upgrade your system, or if you are tracking -STABLE, upgrade the port when a new version becomes available. While cdrecord has many options, basic usage is even simpler than burncd. Burning an ISO 9660 image is done with: &prompt.root; cdrecord device imagefile.iso The tricky part of using cdrecord is finding the to use. To find the proper setting, use the flag of cdrecord, which might produce results like this: CDROMs burning &prompt.root; cdrecord Cdrecord 1.9 (i386-unknown-freebsd4.2) Copyright (C) 1995-2000 Jörg Schilling Using libscg version 'schily-0.1' scsibus0: 0,0,0 0) 'SEAGATE ' 'ST39236LW ' '0004' Disk 0,1,0 1) 'SEAGATE ' 'ST39173W ' '5958' Disk 0,2,0 2) * 0,3,0 3) 'iomega ' 'jaz 1GB ' 'J.86' Removable Disk 0,4,0 4) 'NEC ' 'CD-ROM DRIVE:466' '1.26' Removable CD-ROM 0,5,0 5) * 0,6,0 6) * 0,7,0 7) * scsibus1: 1,0,0 100) * 1,1,0 101) * 1,2,0 102) * 1,3,0 103) * 1,4,0 104) * 1,5,0 105) 'YAMAHA ' 'CRW4260 ' '1.0q' Removable CD-ROM 1,6,0 106) 'ARTEC ' 'AM12S ' '1.06' Scanner 1,7,0 107) * This lists the appropriate value for the devices on the list. Locate your CD burner, and use the three numbers separated by commas as the value for . In this case, the CRW device is 1,5,0, so the appropriate input would be =1,5,0. There are easier ways to specify this value; see &man.cdrecord.1; for details. That is also the place to look for information on writing audio tracks, controlling the speed, and other things.
diff --git a/en_US.ISO8859-1/books/handbook/eresources/chapter.sgml b/en_US.ISO8859-1/books/handbook/eresources/chapter.sgml index be6b0d2f27..70784ba74e 100644 --- a/en_US.ISO8859-1/books/handbook/eresources/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/eresources/chapter.sgml @@ -1,1639 +1,1639 @@ Resources on the Internet The rapid pace of FreeBSD progress makes print media impractical as a means of following the latest developments. Electronic resources are the best, if not often the only, way stay informed of the latest advances. Since FreeBSD is a volunteer effort, the user community itself also generally serves as a technical support department of sorts, with electronic mail and USENET news being the most effective way of reaching that community. The most important points of contact with the FreeBSD user community are outlined below. If you are aware of other resources not mentioned here, please send them to the &a.doc;so that they may also be included. Mailing Lists Though many of the FreeBSD development members read USENET, we cannot always guarantee that we will get to your questions in a timely fashion (or at all) if you post them only to one of the comp.unix.bsd.freebsd.* groups. By addressing your questions to the appropriate mailing list you will reach both us and a concentrated FreeBSD audience, invariably assuring a better (or at least faster) response. The charters for the various lists are given at the bottom of this document. Please read the charter before joining or sending mail to any list. Most of our list subscribers now receive many hundreds of FreeBSD related messages every day, and by setting down charters and rules for proper use we are striving to keep the signal-to-noise ratio of the lists high. To do less would see the mailing lists ultimately fail as an effective communications medium for the project. Archives are kept for all of the mailing lists and can be searched using the FreeBSD World Wide Web server. The keyword searchable archive offers an excellent way of finding answers to frequently asked questions and should be consulted before posting a question. List Summary General lists: The following are general lists which anyone is free (and encouraged) to join: List Purpose cvs-all Changes made to the FreeBSD source tree freebsd-advocacy FreeBSD Evangelism freebsd-announce Important events and project milestones freebsd-arch Architecture and design discussions freebsd-bugs Bug reports freebsd-chat Non-technical items related to the FreeBSD community freebsd-config Development of FreeBSD installation and configuration tools freebsd-current Discussion concerning the use of FreeBSD-current freebsd-isp Issues for Internet Service Providers using FreeBSD freebsd-jobs FreeBSD employment and consulting opportunities freebsd-newbies New FreeBSD users activities and discussions freebsd-policy FreeBSD Core team policy decisions. Low volume, and read-only freebsd-questions User questions and technical support freebsd-stable Discussion concerning the use of FreeBSD-stable freebsd-test Where to send your test messages instead of one of the actual lists Technical lists: The following lists are for technical discussion. You should read the charter for each list carefully before joining or sending mail to one as there are firm guidelines for their use and content. List Purpose freebsd-afs Porting AFS to FreeBSD freebsd-alpha Porting FreeBSD to the Alpha freebsd-arm Porting FreeBSD to ARM processors freebsd-atm Using ATM networking with FreeBSD freebsd-audit Source code audit project freebsd-cluster Using FreeBSD in a clustered environment freebsd-database Discussing database use and development under FreeBSD freebsd-doc Creating FreeBSD related documents freebsd-emulation Emulation of other systems such as Linux/DOS/Windows freebsd-fs Filesystems freebsd-hackers General technical discussion freebsd-hardware General discussion of hardware for running FreeBSD freebsd-i18n FreeBSD Internationalization freebsd-ia64 Porting FreeBSD to Intel's upcoming IA64 systems freebsd-ircops Discussion of IRC servers on FreeBSD freebsd-ipfw Technical discussion concerning the redesign of the IP firewall code freebsd-isdn ISDN developers freebsd-java Java developers and people porting JDKs to FreeBSD freebsd-libh The second generation installation and package system freebsd-mobile Discussions about mobile computing freebsd-mozilla Porting mozilla to FreeBSD freebsd-multimedia Multimedia applications freebsd-new-bus Technical discussions about bus architecture freebsd-net Networking discussion and TCP/IP source code freebsd-platforms Concerning ports to non-Intel architecture platforms freebsd-ports Discussion of the ports collection freebsd-ppc Porting FreeBSD to the PowerPC freebsd-qa Discussion of Quality Assurance, usually pending a release freebsd-realtime Development of realtime extensions to FreeBSD freebsd-scsi The SCSI subsystem freebsd-security Security issues freebsd-security-notifications Security notifications freebsd-small Using FreeBSD in embedded applications freebsd-smp Design discussions for [A]Symmetric MultiProcessing freebsd-sparc Porting FreeBSD to Sparc systems freebsd-tokenring Support Token Ring in FreeBSD Limited lists: The following lists are for more specialized (and demanding) audiences and are probably not of interest to the general public. It is also a good idea to establish a presence in the technical lists before joining one of these limited - lists so that you'll understand the communications etiquette involved. + lists so that you will understand the communications etiquette involved. List Purpose freebsd-core FreeBSD core team freebsd-hubs People running mirror sites (infrastructural support) freebsd-install Installation development freebsd-user-groups User group coordination freebsd-www Maintainers of www.freebsd.org Digest lists: Many of the above lists are also available as digests. New messages posted to the list are collected and sent out as a single email when the sizes goes over 100KB. The lists available in digest form are: List freebsd-afs-digest freebsd-alpha-digest freebsd-chat-digest freebsd-current-digest freebsd-cvs-all-digest freebsd-database-digest freebsd-hackers-digest freebsd-ia64-digest freebsd-isdn-digest freebsd-java-digest freebsd-questions-digest freebsd-security-digest freebsd-sparc-digest freebsd-stable-digest freebsd-test-digest CVS lists: The following lists are for people interested in seeing the log messages for changes to various areas of the source tree. They are Read-Only lists and should not have mail sent to them. List Source area Area Description (source for) cvs-all /usr/src All changes to the tree (superset) How to Subscribe All mailing lists live on FreeBSD.org, so to post to a given list you simply mail to <listname@FreeBSD.org>. It will then be redistributed to mailing list members world-wide. To subscribe to a list, send mail to &a.majordomo; and include subscribe <listname> [<optional address>] in the body of your message. For example, to subscribe yourself to - freebsd-announce, you'd do: + freebsd-announce, you would do: &prompt.user; mail majordomo@FreeBSD.org subscribe freebsd-announce ^D If you want to subscribe yourself under a different name, or submit a subscription request for a local mailing list (this is more efficient if you have several interested parties at one site, and highly appreciated by us!), you would do something like: &prompt.user; mail majordomo@FreeBSD.org subscribe freebsd-announce local-announce@somesite.com ^D Finally, it is also possible to unsubscribe yourself from a list, get a list of other list members or see the list of mailing lists again by sending other types of control messages to majordomo. For a complete list of available commands, do this: &prompt.user; mail majordomo@FreeBSD.org help ^D Again, we would like to request that you keep discussion in the technical mailing lists on a technical track. If you are only interested in important announcements then it is suggested that you join freebsd-announce, which is intended only for infrequent traffic. List Charters All FreeBSD mailing lists have certain basic rules which must be adhered to by anyone using them. Failure to comply with these guidelines will result in two (2) written warnings from the FreeBSD Postmaster postmaster@FreeBSD.org, after which, on a third offense, the poster will removed from all FreeBSD mailing lists and filtered from further posting to them. We regret that such rules and measures are necessary at all, but today's Internet is a pretty harsh environment, it would seem, and many fail to appreciate just how fragile some of its mechanisms are. Rules of the road: The topic of any posting should adhere to the basic charter of the list it is posted to, e.g. if the list is about technical issues then your posting should contain technical discussion. Ongoing irrelevant chatter or flaming only detracts from the value of the mailing list for everyone on it and will not be tolerated. For free-form discussion on no particular topic, the freebsd-chat freebsd-chat@FreeBSD.org mailing list is freely available and should be used instead. No posting should be made to more than 2 mailing lists, and only to 2 when a clear and obvious need to post to both lists exists. For most lists, there is already a great deal of subscriber overlap and except for the most esoteric mixes (say "-stable & -scsi"), there really is no reason to post to more than one list at a time. If a message is sent to you in such a way that multiple mailing lists appear on the Cc line then the Cc line should also be trimmed before sending it out again. You are still responsible for your own cross-postings, no matter who the originator might have been. Personal attacks and profanity (in the context of an argument) are not allowed, and that includes users and developers alike. Gross breaches of netiquette, like excerpting or reposting private mail when permission to do so was not and would not be forthcoming, are frowned upon but not specifically enforced. However, there are also very few cases where such content would fit within the charter of a list and it would therefore probably rate a warning (or ban) on that basis alone. Advertising of non-FreeBSD related products or services is strictly prohibited and will result in an immediate ban if it is clear that the offender is advertising by spam. Individual list charters: FREEBSD-AFS Andrew File System This list is for discussion on porting and using AFS from CMU/Transarc FREEBSD-ANNOUNCE Important events / milestones This is the mailing list for people interested only in occasional announcements of significant FreeBSD events. This includes announcements about snapshots and other releases. It contains announcements of new FreeBSD capabilities. It may contain calls for volunteers etc. This is a low volume, strictly moderated mailing list. FREEBSD-ARCH Architecture and design discussions This list is for discussion of the FreeBSD architecture. Messages will mostly be kept strictly technical in nature. Examples of suitable topics are: How to re-vamp the build system to have several customized builds running at the same time. What needs to be fixed with VFS to make Heidemann layers work. How do we change the device driver interface to be able to use the same drivers cleanly on many buses and architectures. How to write a network driver. FREEBSD-AUDIT Source code audit project This is the mailing list for the FreeBSD source code audit project. Although this was originally intended for security-related changes, its charter has been expanded to review any code changes. This list is very heavy on patches, and is probably of no interest to the average FreeBSD user. Security discussions not related to a particular code change are held on freebsd-security. Conversely, all developers are encouraged to send their patches here for review, especially if they touch a part of the system where a bug may adversely affect the integrity of the system. FREEBSD-BUGS Bug reports This is the mailing list for reporting bugs in FreeBSD Whenever possible, bugs should be submitted using the &man.send-pr.1; command or the WEB interface to it. FREEBSD-CHAT Non technical items related to the FreeBSD community This list contains the overflow from the other lists about non-technical, social information. It includes discussion about whether Jordan looks like a toon ferret or not, whether or not to type in capitals, who is drinking too much coffee, where the best beer is brewed, who is brewing beer in their basement, and so on. Occasional announcements of important events (such as upcoming parties, weddings, births, new jobs, etc) can be made to the technical lists, but the follow ups should be directed to this -chat list. FREEBSD-CORE FreeBSD core team This is an internal mailing list for use by the core members. Messages can be sent to it when a serious FreeBSD-related matter requires arbitration or high-level scrutiny. FREEBSD-CURRENT Discussions about the use of FreeBSD-current This is the mailing list for users of freebsd-current. It includes warnings about new features coming out in -current that will affect the users, and instructions on steps that must be taken to remain -current. Anyone running current must subscribe to this list. This is a technical mailing list for which strictly technical content is expected. FREEBSD-CURRENT-DIGEST Discussions about the use of FreeBSD-current This is the digest version of the freebsd-current mailing list. The digest consists of all messages sent to freebsd-current bundled together and mailed out as a single message. This list is Read-Only and should not be posted to. FREEBSD-DOC Documentation project This mailing list is for the discussion of issues and projects related to the creation of documentation for FreeBSD. The members of this mailing list are collectively referred to as The FreeBSD Documentation Project. It is an open list; feel free to join and contribute! FREEBSD-FS Filesystems Discussions concerning FreeBSD filesystems. This is a technical mailing list for which strictly technical content is expected. FREEBSD-IPFW IP Firewall This is the forum for technical discussions concerning the redesign of the IP firewall code in FreeBSD. This is a technical mailing list for which strictly technical content is expected. FREEBSD-IA64 Porting FreeBSD to IA64 This is a technical mailing list for individuals actively working on porting FreeBSD to the IA-64 platform from Intel, to bring up problems or discuss alternative solutions. Individuals interested in following the technical discussion are also welcome. FREEBSD-ISDN ISDN Communications This is the mailing list for people discussing the development of ISDN support for FreeBSD. FREEBSD-JAVA Java Development This is the mailing list for people discussing the development of significant Java applications for FreeBSD and the porting and maintenance of JDKs. FREEBSD-HACKERS Technical discussions This is a forum for technical discussions related to FreeBSD. This is the primary technical mailing list. It is for individuals actively working on FreeBSD, to bring up problems or discuss alternative solutions. Individuals interested in following the technical discussion are also welcome. This is a technical mailing list for which strictly technical content is expected. FREEBSD-HACKERS-DIGEST Technical discussions This is the digest version of the freebsd-hackers mailing list. The digest consists of all messages sent to freebsd-hackers bundled together and mailed out as a single message. This list is Read-Only and should not be posted to. FREEBSD-HARDWARE General discussion of FreeBSD hardware General discussion about the types of hardware that FreeBSD runs on, various problems and suggestions concerning what to buy or avoid. FREEBSD-HUBS Mirror sites Announcements and discussion for people who run FreeBSD mirror sites. FREEBSD-INSTALL Installation discussion This mailing list is for discussing FreeBSD installation development for the future releases. FREEBSD-ISP Issues for Internet Service Providers This mailing list is for discussing topics relevant to Internet Service Providers (ISPs) using FreeBSD. This is a technical mailing list for which strictly technical content is expected. FREEBSD-NEWBIES Newbies activities discussion We cover any of the activities of newbies that are not already dealt with elsewhere, including: independent learning and problem solving techniques, finding and using resources and asking for help elsewhere, how to use mailing lists and which lists to use, general chat, making mistakes, boasting, sharing ideas, stories, moral (but not technical) support, and taking an active part in the FreeBSD community. We take our problems and support questions to freebsd-questions, and use freebsd-newbies to meet others who are doing the same things that we do as newbies. FREEBSD-PLATFORMS Porting to Non-Intel platforms Cross-platform FreeBSD issues, general discussion and proposals for non-Intel FreeBSD ports. This is a technical mailing list for which strictly technical content is expected. FREEBSD-POLICY Core team policy decisions This is a low volume, read-only mailing list for FreeBSD Core Team Policy decisions. FREEBSD-PORTS Discussion of ports Discussions concerning FreeBSD's ports collection (/usr/ports), proposed ports, modifications to ports collection infrastructure and general coordination efforts. This is a technical mailing list for which strictly technical content is expected. FREEBSD-QUESTIONS User questions This is the mailing list for questions about FreeBSD. You should not send how to questions to the technical lists unless you consider the question to be pretty technical. FREEBSD-QUESTIONS-DIGEST User questions This is the digest version of the freebsd-questions mailing list. The digest consists of all messages sent to freebsd-questions bundled together and mailed out as a single message. FREEBSD-SCSI SCSI subsystem This is the mailing list for people working on the scsi subsystem for FreeBSD. This is a technical mailing list for which strictly technical content is expected. FREEBSD-SECURITY Security issues FreeBSD computer security issues (DES, Kerberos, known security holes and fixes, etc). This is a technical mailing list for which strictly technical content is expected. FREEBSD-SECURITY-NOTIFICATIONS Security Notifications Notifications of FreeBSD security problems and fixes. This is not a discussion list. The discussion list is FreeBSD-security. FREEBSD-SMALL Using FreeBSD in embedded applications This list discusses topics related to unusually small and embedded FreeBSD installations. This is a technical mailing list for which strictly technical content is expected. FREEBSD-STABLE Discussions about the use of FreeBSD-stable This is the mailing list for users of freebsd-stable. It includes warnings about new features coming out in -stable that will affect the users, and instructions on steps that must be taken to remain -stable. Anyone running stable should subscribe to this list. This is a technical mailing list for which strictly technical content is expected. FREEBSD-USER-GROUPS User Group Coordination List This is the mailing list for the coordinators from each of the local area Users Groups to discuss matters with each other and a designated individual from the Core Team. This mail list should be limited to meeting synopsis and coordination of projects that span User Groups. Usenet Newsgroups In addition to two FreeBSD specific newsgroups, there are many others in which FreeBSD is discussed or are otherwise relevant to FreeBSD users. Keyword searchable archives are available for some of these newsgroups from courtesy of Warren Toomey wkt@cs.adfa.edu.au. BSD Specific Newsgroups comp.unix.bsd.freebsd.announce comp.unix.bsd.freebsd.misc Other Unix Newsgroups of Interest comp.unix comp.unix.questions comp.unix.admin comp.unix.programmer comp.unix.shell comp.unix.user-friendly comp.security.unix comp.sources.unix comp.unix.advocacy comp.unix.misc comp.bugs.4bsd comp.bugs.4bsd.ucb-fixes comp.unix.bsd X Window System comp.windows.x.i386unix comp.windows.x comp.windows.x.apps comp.windows.x.announce comp.windows.x.intrinsics comp.windows.x.motif comp.windows.x.pex comp.emulators.ms-windows.wine World Wide Web Servers http://www.FreeBSD.org/ — Central Server. http://www.au.FreeBSD.org/ — Australia/1. http://www2.au.FreeBSD.org/ — Australia/2. http://www3.au.FreeBSD.org/ — Australia/3. http://freebsd.itworks.com.au/ — Australia/4. http://www.br.FreeBSD.org/www.freebsd.org/ — Brazil/1. http://www2.br.FreeBSD.org/www.freebsd.org/ — Brazil/2. http://www3.br.FreeBSD.org/ — Brazil/3. http://www.bg.FreeBSD.org/ — Bulgaria. http://www.ca.FreeBSD.org/ — Canada/1. http://www2.ca.FreeBSD.org/ — Canada/2. http://www3.ca.FreeBSD.org/ — Canada/3. http://www.cn.FreeBSD.org/ — China. http://www.cz.FreeBSD.org/ — Czech Republic. http://www.dk.FreeBSD.org/ — Denmark. http://www.ee.FreeBSD.org/ — Estonia. http://www.fi.FreeBSD.org/ — Finland. http://www.fr.FreeBSD.org/ — France. http://www.de.FreeBSD.org/ — Germany/1. http://www1.de.FreeBSD.org/ — Germany/2. http://www2.de.FreeBSD.org/ — Germany/3. http://www.gr.FreeBSD.org/ — Greece. http://www.hu.FreeBSD.org/ — Hungary. http://www.is.FreeBSD.org/ — Iceland. http://www.ie.FreeBSD.org/ — Ireland. http://www.jp.FreeBSD.org/www.FreeBSD.org/ — Japan. http://www.kr.FreeBSD.org/ — Korea/1. http://www2.kr.FreeBSD.org/ — Korea/2. http://www.lv.FreeBSD.org/ — Latvia. http://rama.asiapac.net/freebsd/ — Malaysia. http://www.nl.FreeBSD.org/ — Netherlands/1. http://www2.nl.FreeBSD.org/ — Netherlands/2. http://www.no.FreeBSD.org/ — Norway. http://www.nz.FreeBSD.org/ — New Zealand. http://www.pl.FreeBSD.org/ — Poland/1. http://www2.pl.FreeBSD.org/ — Poland/2. http://www.pt.FreeBSD.org/ — Portugal/1. http://www2.pt.FreeBSD.org/ — Portugal/2. http://www3.pt.FreeBSD.org/ — Portugal/3. http://www.ro.FreeBSD.org/ — Romania. http://www.ru.FreeBSD.org/ — Russia/1. http://www2.ru.FreeBSD.org/ — Russia/2. http://www3.ru.FreeBSD.org/ — Russia/3. http://www4.ru.FreeBSD.org/ — Russia/4. http://freebsd.s1web.com/ — Singapore. http://www.sk.FreeBSD.org/ — Slovak Republic. http://www.si.FreeBSD.org/ — Slovenia. http://www.es.FreeBSD.org/ — Spain. http://www.za.FreeBSD.org/ — South Africa/1. http://www2.za.FreeBSD.org/ — South Africa/2. http://www.se.FreeBSD.org/ — Sweden. http://www.ch.FreeBSD.org/ — Switzerland. http://www.tw.FreeBSD.org/www.freebsd.org/data/ — Taiwan. http://www.tr.FreeBSD.org/ — Turkey. http://www.ua.FreeBSD.org/www.freebsd.org/ — Ukraine/1. http://www2.ua.FreeBSD.org/ — Ukraine/2. http://www4.ua.FreeBSD.org/ — Ukraine/Crimea. http://www.uk.FreeBSD.org/ — United Kingdom/1. http://www2.uk.FreeBSD.org/ — United Kingdom/2. http://www3.uk.FreeBSD.org/ — United Kingdom/3. http://www6.FreeBSD.org/ — USA/Oregon. http://www2.FreeBSD.org/ — USA/Texas. Email Addresses The following user groups provide FreeBSD related email addresses for their members. The listed administrator reserves the right to revoke the address if it is abused in any way. Domain Facilities User Group Administrator ukug.uk.FreeBSD.org Forwarding only freebsd-users@uk.FreeBSD.org Lee Johnston lee@uk.FreeBSD.org Shell Accounts The following user groups provide shell accounts for people who are actively supporting the FreeBSD project. The listed administrator reserves the right to cancel the account if it is abused in any way. Host Access Facilities Administrator storm.uk.FreeBSD.org SSH only Read-only cvs, personal web space, email &a.brian dogma.freebsd-uk.eu.org Telnet/FTP/SSH Email, Web space, Anonymous FTP Lee Johnston lee@uk.FreeBSD.org diff --git a/en_US.ISO8859-1/books/handbook/install/chapter.sgml b/en_US.ISO8859-1/books/handbook/install/chapter.sgml index b8b998e1bd..ba2cb70658 100644 --- a/en_US.ISO8859-1/books/handbook/install/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/install/chapter.sgml @@ -1,3624 +1,3624 @@ Jim Mock Restructured, reorganized, and parts rewritten by Randy Pratt The sysinstall walkthrough, screenshots, and general copy Installing FreeBSD Synopsis installation FreeBSD is provided with a text-based, easy to use installation program called SysInstall. This is the default installation program for FreeBSD, although vendors are free to provide their own installation suite if they wish. This chapter describes how to use SysInstall to install FreeBSD. After reading this chapter you will know: How to create the FreeBSD installation disks. How FreeBSD refers to, and subdivides, your hard disks. How to start SysInstall. The questions SysInstall will ask you, what they mean, and how to answer them. Before reading this chapter you should: Read the supported hardware list that shipped with the version of FreeBSD you are installing, and verify that your hardware is supported. Pre-installation Tasks Inventory Your Computer Before installing FreeBSD you should attempt to inventory the components in your computer. The FreeBSD installation routines will show you the components (hard disks, network cards, CDROM drives, and so forth) with their model number and manufacturer. FreeBSD will also attempt to determine the correct configuration for these devices, which includes information about IRQ and memory usage. Due to the vagaries of PC hardware this process is not always completely successful, and you may need to correct FreeBSD's determination of your configuration. If you already have another operating system installed, such as Windows, or Linux, it is a good idea to use the facilities provided by those operating systems to see how your hardware is already configured. We recommend you print or write down this information before installing FreeBSD. Backup Your Data If the computer you will be installing FreeBSD on contains valuable data then ensure you have it backed up, and that you have tested the backups before installing FreeBSD. The FreeBSD installation routine will prompt you several times before writing any data to your disk, but once that process has started it can not be undone. Decide Where to Install FreeBSD If you want FreeBSD to use all your disk then there is nothing more to concern yourself with at this point, and you can skip to the next section.. However, if you need FreeBSD to co-exist with other operating systems then you need to have a rough understanding of how data is laid out on the disk, and how this affects you. A PC disk can be divided in to up to four discrete chunks. These chunks are called partitions. One partition on each disk will be the primary partition, the others are extended partitions. A disk does not need to be configured with all four partitions. You might only have one partition on your disk at the moment, and that partition is taking up the whole space of the disk. Each partition has a partition ID, which is a number, used to identify the type of data on the partition. FreeBSD partitions have the partition ID 165. In general, each operating system that you use will identify partitions in a particular way. For example, DOS, and its descendants, like Windows, assign each partition a drive letter, starting with C:. FreeBSD keeps all your data in one partition, so you need to have one partition available when you install FreeBSD. This might be a blank partition that you have prepared, or it might be an existing partition that contains data that you no longer care about. If you are already using all the partitions on all your disks then you will have to free one of them for FreeBSD to use, using the tools provided by the other operating systems you use (e.g., fdisk on DOS or Windows). If you have a spare partition then you can use that. However, you may need to shrink one or more of your existing partitions first. A minimal installation of FreeBSD takes as little as 35MB of disk space. However, that is a very minimal install, leaving almost no space for your own files. A more realistic minimum is 250MB without a graphical environment, and 350MB or more if you want a graphical user interface. If you intend to install a lot of third party software as well then you will need more space. You can use a commercial tool such as Partition Magic to resize your partitions to make space for FreeBSD. The tools directory on the CDROM contains two free software tools which can carry out this task, FIPS and PResizer. Documentation for both of these is in the same directory. Incorrect use of these tools can delete the data on your disk. Be sure that you have recent, working backups before using them. Although FreeBSD will be installed in to the part of your disk that is currently D:, that drive letter will no longer be available in Windows. FreeBSD can read and write to DOS and Windows drives, but the reverse is not true. Using an existing partition unchanged Suppose that you have a computer with a single 4GB disk, that already has a version of Windows installed, and you have split the disk in to two drive letters, C: and D:, each of which is 2GB in size. You have 1GB of data on C:, and 0.5GB of data on D:. This means that your disk has two partitions on it, one per drive letter. You can copy all your existing data from D: to C:, which will free up the second partition, ready for FreeBSD. Shrinking an existing partition Suppose that you have a computer with a single 4GB disk, that already has a version of Windows installed. When you installed Windows you created one large partition, giving you a C: drive that is 4GB in size. You are currently using 1.5GB of space, and want FreeBSD to have 2GB of space. In order to install FreeBSD you will need to either: Back up your Windows data, and then reinstall Windows, asking for a 2GB partition at install time. Use one of the tools such as Partition Magic, described above, to shrink your Windows partition. Check for FreeBSD Errata Although the FreeBSD project strives to ensure that each release of FreeBSD is as stable as possible, bugs do occasionally creep in to the process. On very rare occasions those bugs affect the installation process. As these problems are discovered and fixed they are noted in the FreeBSD Errata, posted on the FreeBSD web site. You should check the errata before installing to make sure that there are no late-breaking problems which you should be aware of. Prepare the Boot Discs FreeBSD can be installed from a number of different media; CDROM, DVD, FTP (both anonymous and non-anonymous), NFS, tape, or an existing MS-DOS partition. If you have FreeBSD on CDROM or DVD, and your computer allows you to boot from the CDROM or DVD (typically a BIOS option called Boot Order or similar) then you can skip this section. The FreeBSD CDROM and DVD images are bootable, and can be used to install FreeBSD without any other special preparation. The FreeBSD installation process is started by booting your computer in to the FreeBSD installer—it is not a program you run from within another operating system. To do this you must create some floppy disks that can be booted from, and then boot from them. If you are not installing directly from CDROM or DVD then you are probably preparing your own installation media (e.g., FTP, or an MS-DOS partition), which must be prepared before you install FreeBSD. This is a slightly more advanced, and infrequent activity, and is documented in . Acquire the Boot Floppy Images The boot discs are available on your installation media, and can also be downloaded from the ftp://ftp.FreeBSD.org/pub/FreeBSD/releases/i386/&rel.current;-RELEASE/floppies/ directory. The floppy images have a .flp extension. The floppies/ directory contains a number of different images, and the ones you will need to use depends on the version of FreeBSD you are installing, and in some cases, the hardware you are installing to. In most cases you will need two files, kern.flp and mfsroot.flp, but check README.TXT in the same directory to be sure. Prepare the Floppy Disks You must prepare one floppy disk per image file you had to download. It is imperative that these disks are free from defects. The easiest way to test this is to format the disks for yourself. Do not trust pre-formatted floppies. If you try to install FreeBSD and the installation program crashes, freezes, or otherwise misbehaves one of the first things to suspect is the floppies. Try writing the floppy image files to some other disks, and try again. Write the Image Files to the Floppy Disks. The .flp files are not regular files you copy to the disk. Instead, they are images of the complete contents of the disk. This means that you can not use commands like DOS' copy to write the files. Instead, you must use specific tools to write the images directly to the disk. DOS If you are creating the floppies on a computer running DOS then we provide a tool to do this called fdimage. If you are using the floppies from the CDROM, and your CDROM is the E: drive then you would run this: E:\> tools\fdimage floppies\kern.flp A: Repeat this command for each .flp file, replacing the floppy disk each time, and being sure to label the disks with the name of the file that you copied to them. Adjust the command line as necessary, depending on where you have placed the .flp files. If you do not have the CDROM then fdimage can be downloaded from the tools directory on the FreeBSD FTP site. If you are writing the floppies on a Unix system (such as another FreeBSD system) you can use the &man.dd.1; command to write the image files directly to disk. On FreeBSD you would run: &prompt.root; dd if=kern.flp of=/dev/fd0 On FreeBSD /dev/fd0 refers to the first floppy disk (the A: drive). /dev/fd1 would be the B: drive, and so on. Other Unix variants might have different names for the floppy disk devices, and you will need to check the documentation for the system as necessary. You are now ready to start installing FreeBSD. Starting the Installation Once you have completed the pre-installation step relevant to your situation, you are ready to install FreeBSD! Although you should not experience any difficulty, there is always the chance that you may, no matter how slight it is. If this is the case in your situation, then you may wish to go back and re-read the relevant preparation section or sections. Perhaps you will come across something you missed the first time. If you are having hardware problems, or FreeBSD refuses to boot at all, read the Hardware Guide for a list of possible solutions. sysinstall The FreeBSD boot floppies contain all of the online documentation you should need to be able to navigate through an installation. If it does not, please let us know what you found to be the most confusing or most lacking. Send your comments to the &a.doc;. It is the objective of the installation program (sysinstall) to be self-documenting enough that painful step-by-step guides are no longer necessary. It may take us a little while to reach that objective, but nonetheless, it is still our objective. Meanwhile, you may also find the following typical installation sequence to be helpful: Boot the kern.flp floppy and when asked, remove it and insert the mfsroot.flp and hit return. After a boot sequence which can take anywhere from 30 seconds to 3 minutes, depending on your hardware, you should be presented with a menu of initial choices. If the kern.flp floppy does not boot at all or the boot hangs at some stage, read the Q&A section of the Hardware Guide for possible causes. Press F1. You should see some basic usage instructions on the menu screen and general navigation. If you have not used this menu system before then please read this thoroughly. Select the Options item and set any special preferences you may have. installation standard installation express installation custom Select a Standard, Express, or Custom install, depending on whether or not you would like the installation to help you through a typical installation, give you a high degree of control over each step, or simply whiz through it (using reasonable defaults when possible) as fast as possible. If you have never used FreeBSD before, the Standard installation method is most recommended. The final configuration menu choice allows you to further configure your FreeBSD installation by giving you menu-driven access to various system defaults. Some items, like networking, may be especially important if you did a CDROM, tape, or floppy install and have not yet configured your network interfaces (assuming you have any). Properly configuring such interfaces here will allow FreeBSD to come up on the network when you first reboot from the hard disk. Starting the installation will not make any changes to the system until this warning message appears : Last Chance: Are you SURE your want continue the installation? If you're running this on a disk with data you wish to save then WE STRONGLY ENCOURAGE YOU TO MAKE PROPER BACKUPS before proceeding! We can take no responsibility for lost disk contents! The install can be exited at any time prior to the final warning without changing the contents of the hard drive. Starting The Installation Process If booting from floppies, put the kern.flp disk in the floppy drive before booting the system. If the CDROM drive is a bootable type, it is not necessary to make the boot floppies. The CD must be in the drive before you boot in order to be sure it is found by the hardware probe. BIOS settings may need to be adjusted. It may be necessary to enter the BIOS setup and set it to use the CDROM or the floppy drive as the appropriate boot option. Be sure to change it back after installation to boot from the appropriate drive. It might also be necessary to turn off the BIOS Plug and Play (PnP) option so that some hardware will be detected correctly. Power down and restart the system. The normal BIOS startup screens display until it starts booting from the floppy or CDROM. If you are booting from floppies, it will ask for the mfsroot.flp floppy disk next, after which the installation will proceed. The "twirling baton" that is seen indicates that the installation program is loading. Typical booting from CDROM Verifying DMI Pool Data ........ Boot from ATAPI CD-ROM : 1. FD 2.88MB System Type-(00) /boot.config: -P Keyboard: yes BTX loader 1.00& BTX version is 1.01 Console: internal video/keyboard BIOS drive A: is disk0 BIOS drive B: is disk1 BIOS drive C: is disk2 BIOS drive C: is disk3 BIOS 639kB/64512kB available memory FreeBSD/i386 bootstrap loader, Revision 0.8 (jkh@bento.freebsd.org, Mon Nov 20 11:41:23 GMT 2000) | Hit [Enter] to boot immediately, or any other key for command prompt. Booting [kernel] in 9 seconds... _ Typical booting from floppies Verifying DMI Pool Data ........ BTX loader 1.00 BTX version is 1.01 Console: internal video/keyboard BIOS drive A: is disk0 BIOS drive C: is disk1 BIOS 639kB/261120kB available memory FreeBSD/i386 bootstrap loader, Revision 0.8 (jkh@narf.osd.bsdi.com, Sat Apr 21 08:46:19 GMT 2001) /kernel text=0x24f1bb data=0x307ac+0x2062c | Please insert MFS root floppy and press enter: A beep will sound and a screen message will say to remove the kern.flp disk, insert the mfsroot.flp disk and press ENTER. The loading of the installation program will then continue. Hit [Enter] to boot immediately, or any other key for command prompt. Booting [kernel] in 9 seconds... _ Regardless of how the installation program is started, the boot prompt will appear with a countdown to boot. Do nothing and in about 10 seconds, it will continue to boot or press ENTER to continue immediately. Starting UserConfig This starts the UserConfig program which is used to tell the system what hardware to probe and where to look. The best way to learn the UserConfig is to practice a few times. The method recommended for new users is "Start kernel configuration in full screen Visual mode". Press the down arrow key to highlight the item and then press ENTER.
Start Kernel Configuration Menu
Layout of UserConfig The first screen shows the layout of UserConfig and indicates the number of hardware conflicts present. The categories of device drivers (Storage, Network, etc.) are initially shown as a collapsed lists and can be expanded.
UserConfig
As the menu at the bottom indicates, pressing ? will display information about screen layout, moving around, altering the list/parameters, and saving changes. When finished reviewing the instructions, press Q to return to the UserConfig kernel settings editor. Resolve Hardware Conflicts The first operating system kernel installed is a "GENERIC" kernel. It includes a wide variety of hardware probes for different system hardware configurations. Probing is the name used for the process of detecting the presence of particular hardware. The drivers included in the GENERIC kernel often have the same IRQ/Port information and will be indicated as "Conflicts". The UserConfig utility is used to disable the unnecessary hardware probes and eliminate the conflicts. The objective is to specify the hardware probes to be "Active" in the system and have no conflicts between them. Certain situations will have "permitted conflicts" and will be indicated at the bottom of the Editor screen. Pressing X will expand all of the collapsed fields so the conflicts can be examined in detail.
Typical Hardware Conflicts
Most of the conflicts are generated by hardware that is not present and should be eliminated first. In general, do not disable the Keyboard (atkbd0) or the Syscons console driver (sc0). You need these. If a USB keyboard is being used, it may be necessary to disable the atkbd0 keyboard driver. Disable unused drivers by highlighting and pressing DELETE. This will move the driver to the Inactive Driver list and reduce the total number of conflicts if one had existed. Eliminate all the unused drivers first. The conflicts that are left need to be examined. If they do not have the indication of an "allowed conflict" in the message area, then either the IRQ/address for device probe will need to be changed - or - the IRQ/address on the hardware will need to be changed.
Start Hardware Probe When the hardware conflicts have been resolved, the probe is started. In this example, moving all the unused device probes to the "Inactive" list left no conflicts.
User Config Completed
The actual probing can now be started by pressing Q to quit. A message will appear : Save these parameters before exiting? ([Y]es/[N]o/[C]ancel) Answer Y to save the parameters and the probing will start. The results will scroll off the screen and the Main Installation screen will display.
Viewing Probe Results
Sysinstall Main Menu
The results of the probing can be viewed by pressing the SCROLL LOCK and using PageUp and PageDown to view the results. Pressing SCROLL LOCK again will return to the Main Installation screen. Typical hardware probe results: avail memory = 58880000 (57500K bytes) Preloaded elf kernel "kernel" at 0xc065d000. md1: Malloc disk npx0: <math processor> on motherboard npx0: INT 16 interface pcib0: <Host to PCI bridge> on motherboard pci0: <PCI bus> on pcib0 pcib1: <VIA 82C598MVP (Apollo MVP3) PCI-PCI (AGP bridge> at device 1.0 on pci0 pci1: <PCI bus> on pcib1 pci1: <Matrox MGA G200 AGP graphics accelerator> at 0.0 irq 11 isab0: <VIA 82C586 PCI-ISA bridge> at device 7.0 on pci0 isa0: <ISA bus> on isab0 atapci0: <VIA 82C586 ATA33 controller> port 0xe000-0xe00f at device 7.1 on pci0 ata0: at 0x1f0 irq 14 on atapci0 uhci0: <VIA 83C572 USB controller> port 0xe400-0xe41f irq 10 at device 7.2 on pci0 usb0: <VIA 83C572 USB controller> on uhci0 usb0: USB revision 1.0 uhub0: VIA UHCI root hub, class 9/0, rev 1.00/1.00, addr 1 uhub0: 2 ports with 2 removable, self powered chip1: <VIA 82C586B ACPI interface> at device 7.3 on pci0 isa0: too many dependant configs (8) isa0: unexpected small tag 14 fdc0: <NEC 72065B or clone> at port 0x3f0-0x3f5,0x3f7 irq6 drq2 on isa0 fdc0: FIFO enabled, 8 bytes threshold fd0: <1440-KB 3.5" drive> on fdc0 drive 0 atkbdc0: <keyboard controller (i8042)> at port 0x60-0x6f on isa0 atkbd0: <AT Keyboard> flags 0x1 irq 1 on atkbdc0 kbd0 at atkbd0 psm0: <PS/2 Mouse> irq 12 on atkbdc0 psm0: model Generic PS/2 mouse, device ID 0 vga0: <Generic ISA VGA> at port 0x3c0-0c3df iomem 0xa0000-0xbffff on isa0 sc0: <System console> at flags 0x100 on isa0 sc0: VGA <16 virtual consoles, flags-0x300> sio0 at port 0x3f8-0x3ff irq 4 flags 0x10 on isa0 sio0: type 16550A sio1: at port 0x2f8-0x2ff irq3 on isa0 sio1: type 16550A ppc0: <Parallel port> at port 0x378-0x37f irq 7 on isa0 ppc0: SMC-like chipset (ECP/EPP/PS2/NIBBLE) in COMPATIBLE mode ppc0: FIFO with 16/16/15 bytes threshold ppi0: <Parallel I/O> on ppbus0 plip0: <PLIP network interface> on ppbus0 ad0: 8063MB <IBM-DHEA-38451> [16383/16/63] at ata0-master using UDMA33 acd0: CDROM <DELTA OTC-H101/ST3 F/W by OIPD> at ata0-slave using PIO4 Mounting root from ufs:/dev/md0c /stand/sysinstall running as init on vty0 The results of the hardware probing will depend on the system hardware. Check it carefully to confirm it found the hardware. Hardware problems should be corrected before continuing with the installation. It might be useful to record the probe results until the system is up and running. This installation produced messages which needed checking. Information regarding these messages were found by searching the mailing lists (questions and bugs). The unexpected tag 14 or unexpected small tag 14 indication can be ignored. This should disappear in future releases. An ISA-device (AWE64 sound card) gave too many proposals for possible PnP-Configurations and produced isa0: too many dependant configs (8). This should be harmless. Support for the sound card can be added after installation by building a new kernel with the sound driver or by loading the sound modules dynamically.
Changing UserConfig Device Probing If you need to make changes to the UserConfig device probing, its easy to exit the sysinstall program and start over again. Its also a good way to become more familiar with the process.
Select Sysinstall Exit
Use the arrow keys to select "Exit Install" from the Main Install Screen menu. The following message will display: User Confirmation Requested Are you sure you wish to exit? The system will reboot (be sure to remove any floppies from the drives). [ Yes ] No The install program will start again if the CDROM is left in the drive and [Yes] is selected. If booting from floppies, to restart the installation it will be necessary to remove the mfs.root floppy and replace it with kern.flp before rebooting. This will allow trying the device probing a few times and fine-tune it before continuing with the installation process.
How To Use Sysinstall
Select Usage From Main Menu
To learn how to use the menu system, use the arrow keys to select "Usage" and press ENTER. The instructions for using the menu system will display. After reviewing, pressing ENTER will return to the Main Menu.
Selecting The Documentation Menu From the Main Menu, select "Doc" with the arrow keys and press ENTER.
Selecting Documentation Menu
This will display the Documentation Menu.
Sysinstall Documentation Menu
It is important to read the documents provided. To view a document, select it with the arrow keys and press ENTER. When finished reading a document, pressing ENTER will return to the Documentation Menu. To return to the Main Installation Menu, select "Exit" with the arrow keys and press ENTER.
Selecting The Keymap Menu To change the keyboard mapping, use the arrow keys to select "Keymap" from the menu and press ENTER
Sysinstall Main Menu
A different keyboard mapping may be chosen by selecting the menu item using up/down arrow keys and pressing SPACE. Pressing SPACE again will unselect the item. When finished, choose the [OK] item using the arrow keys and press ENTER. Only a partial list is shown in this screen representation. Selecting [CANCEL] will use the default keymap and return to the Main Install Menu.
Sysinstall Keymap Menu
Installation Options Screen Select "Options" and press ENTER
Sysinstall Main Menu
Sysinstall Options
The default values are usually fine for most users and do not need to be changed. The description of the selected item will appear at the bottom of the screen highlighted in blue. Notice that one of the options is "Use Defaults" to reset all values to startup defaults. Press F1 to read the help screen about the various options. Pressing Q will return to the Main Install menu.
Installation Begin A Standard Installation The "Standard" installation is the option recommended for those new to Unix or FreeBSD. Use the arrow keys to select "Standard" and then press ENTER to start the installation.
Begin Standard Installation
FDISK Partition Editor Message In the next menu, you will need to set up a DOS-style ("fdisk") partitioning scheme for your hard disk. If you simply wish to devote all disk space to FreeBSD (overwriting anything else that might be on the disk(s) selected) then use the (A)ll command to select the default partitioning scheme followed by a (Quit. If you wish to allocate only free space to FreeBSD, move to a partition marked "unused" and use the (C)reate command. [ OK ] [ Press enter to continue ]
Select Drive for FDISK
The following instructions for FDISK are for using the entire hard disk for the FreeBSD installation. If you want to use multiple operating systems, please refer to the tutorials at http://www.freebsd.org/tutorials
FDISK Partition Editor The FDISK Partition Editor will display the current hard disk settings. The appearance of the screen will vary depending on the size of the hard disk installed and how it was set up previously. The following screen representation would be similar to a system which had DOS/Windows installed. Pressing F1 will display important information about using the FDISK Partition Editor.
Typical Fdisk Partitions Before Editing
Creating a FreeBSD Slice using the Entire Disk The tutorial Installing and Using FreeBSD With Other Operating Systems provides information on multi-os installations. For this particular system, A was selected to use the entire disk for the FreeBSD installation. Remember, all data currently on the hard disk will be lost using this method. The following illustrates how a FDISK Partition Editor screen will appear after choosing to use the entire hard disk and to remain compatible with future operating systems. The first line indicates the space allocated for the master boot record. The FreeBSD slice was created as shown on the second line. The next step is to set the freebsd slice as bootable.
Fdisk Partition Using Entire Disk
Use the arrow keys to highlight the FreeBSD slice and press S to set the slice as bootable. The illustration below shows the FreeBSD Slice as set as bootable. The flags should indicate "CA" before you leave this screen. When finished, press Q to save the changes and quit and continue with the installation.
Install a Boot Manager First, highlight the boot manager option desired using the arrow keys, then press SPACE. An asterisk "*" will indicate the selection chosen. This installation was solely FreeBSD so a boot manager was not needed. When finished, select [OK] and press ENTER.
Sysinstall Boot Manager Menu
The help screen discusses the problems that can be encountered when trying to share the hard disk between operating systems. If there is more than one drive, it will return to the Select Drives screen after the boot manager selection.
Exit Select Drive
Make sure [OK] is highlighted, then press ENTER to continue with the installation.
Initial Disklabel Screen Message Now, you need to create BSD partitions inside of the fdisk partition(s) just created. If you have a reasonable amount of disk space (200MB or more) and don't have any special requirements, simply use the (A)uto command to allocate space automatically. If you have more specific needs or just don't care for the layout chosen by (A)uto, press F1 for more information on manual layout. [ OK ] [ Press enter to continue ] There are no partitions shown when you first enter the editor.
Sysinstall Disklabel Editor
Pressing F1 will give instructions for using the DiskLabel Editor. Press Q to continue.
Auto Defaults for Partitions Pressing A displayed the suggested disklabels for this particular disk size. If a small hard disk is being used, the default values may be appropriate.
Sysinstall Disklabel Editor With Auto Defaults
Creating Custom Partitions Write down the auto defaults for all the file systems (/, swap, /var, /usr). Using the arrow keys, select the first partition ( / ) and press D to delete the partition. Delete all the partitions in the same manner. It is easiest to create the partitions in the same order shown by the auto default. Example Custom Partition To create the root partition, first press C and a dialog box will appear showing the total space available in blocks :
Free Space For Root Partition
This example will set the root partition to 100M. First, delete the entry using the BACKSPACE and enter the desired value :
Edit Root Partition Size
With [OK] highlighted, then press ENTER. The following dialog box will display :
Choose The Root Partition Type
The root partition needs to be a file system. With "FS" and [OK] highlighted, press ENTER. The next dialog box to appear is to enter the mount point for the root partition. Enter "/" for the root partition mount point. With the [OK] highlighted, press ENTER.
Choose The Root Mount Point
The swap, /var and /usr partitions are created in the same way. Be sure to choose "swap" as the filesystem type for the swap partition. Generally the swap value is twice the amount of RAM in the system. For this system, the "swap" partition will be set to 516M. The "/var" partition will be set to 100M and the "/usr" partition will get the remaining amount of disk space. Your final FreeBSD DiskLabel Editor screen will appear similar although your values chosen may be different. Press Q to finish.
Sysinstall Disklabel Editor
Select The Distribution Set I chose to install everything using the "All" option since I - had the hard drive space. If you're concerned about space, + had the hard drive space. If you are concerned about space, consider the other distribution options. Select "All" using the arrow keys to highlight the item and press the SPACEBAR. Notice that the instructions below give pressing [ENTER] as a means to exit.
Choose Distributions
Installing The Ports Collection User Confirmation Requested Would you like to install the FreeBSD ports collection? This will give you ready access to over 5000 ported software packages, at a cost of around 70MB of disk space when "clean" and possibly much more than that if a lot of the distribution tarballs are loaded (unless you have the extra CDs from a FreeBSD CDROM distribution available and can mount it on /cdrom, in which case this is far less of a problem). The ports collection is a very valuable resource and well worth having on your /usr partition, so it is advisable to say Yes to this option. For more information on the ports collection & the latest ports, visit: http://www.freebsd.org/ports [ Yes ] No The installation program does not check to see if you have adequate space. Select this option only if you have adequate hard disk space. The ports can be added as needed later. The install program returns to the Choose Distributions screen. Select "EXIT" with the arrow keys and press ENTER to continue with the installation.
Confirm Distributions
Installation Media If Installing from a CDROM, use the arrow keys to highlight the "Install from a FreeBSD CDROM" option. Make sure [OK] is highlighted, then press ENTER to proceed with installation.
Choose Installation Media
Press F1 to display the Online Help for installation media. Press ENTER to return to the media selection menu.
Final Warning The installation can now proceed if desired. This is also the last chance for aborting the installation to prevent changes to the hard drive. This is the point of no return. User Confirmation Requested Last Chance! Are you SURE you want to continue the installation? If you're running this on a disk with data you wish to save then WE STRONGLY ENCOURAGE YOU TO MAKE PROPER BACKUPS before proceeding! We can take no responsibility for lost disk contents! [ Yes ] No Continuing The Installation Select "Yes" and Press ENTER to proceed. The installation time will vary according to the distribution chosen and installation media used. There will be a series of messages displayed indicating the status. When the installation is complete when the following message is displayed : Message Congratulations! You now have FreeBSD installed on your system. We will now move on to the final configuration questions. For any option you do not wish to configure, simply select No. If you wish to re-enter this utility after the system is up, you may do so by typing: /stand/sysinstall . [ OK ] [ Press enter to continue ] Press ENTER to proceed with post-installation configurations. Aborting The Installation Selecting [No] and pressing ENTER will abort the installation so no changes will be made to your system. The following message will appear : Message Installation complete with some errors. You may wish to scroll through the debugging messages on VTY1 with the scroll-lock feature. You can also choose "No" at the next prompt and go back into the installation menus to try and retry whichever operations have failed. [ OK ] Pressing ENTER will return to the Main Installation Menu to exit the installation.
Post-installation Configuration of various options follows the successful installation. A option can be configured by re-entering the configuration options before booting the new FreeBSD system or after installation using /stand/sysinstall. Network Device Configuration If you previously configured PPP for an FTP install, this screen will not re-appear. For detailed information on Local Area Networks and configuring FreeBSD as a gateway/router refer to the tutorial PPP- Pendantic PPP Primer. User Confirmation Requested Would you like to configure Ethernet or SLIP/PPP network devices? [ Yes ] No This option allows configuration of network devices by selecting [Yes] and pressing ENTER
Selecting An Ethernet Device
Select the appropriate interface and press ENTER. User Confirmation Requested Do you want to try IPv6 configuration of the interface? Yes [ No ] In this private local area network the current Internet type protocol (IPv4) was sufficient and "No" was selected with the arrow keys and ENTER pressed. If you want to try the new Internet protocol (IPv6), choose [Yes] and press ENTER. If yes is chosen, it will take several seconds for scanning RA servers. User Confirmation Requested Do you want to try DHCP configuration of the interface? Yes [ No ] There is no DHCP (Dynamic Host Configuration Protocol) so "No" was selected with the arrow keys and ENTER pressed. Answering [Yes] will execute dhclient, and if successful, will fill in the network configuration information automatically. Refer to the FreeBSD Handbook for more information. The following Network Configuration screen shows the configuration of the Ethernet device for a system that will act as the gateway for a Local Area Network.
Set Network Configuration For ed0
Use TAB to select the information fields and fill in appropriate information: Host The fully-qualified hostname, e.g. k6-2.weeble.com in this case. Domain The name of the domain that your machine is in, e.g. weeble.com for this case. IPv4 Gateway IP address of host forwarding packets to non-local destinations. Fill this in only if the machine is a node on the network. Leave this field blank if the machine is the gateway to the Internet for the network. Name server IP address of your local DNS server. There is no local DNS server on this private local area network so the IP address of the provider's DNS server (208.163.10.2) was used. IPv4 address The IP address to be used for this interface was (192.168.0.1). Netmask The address block being used for this local area network is a Class C block (192.168.0.0 - 192.168.255.255). The default netmask is for a Class C network (255.255.255.0). Extra options to ifconfig Any interface-specific options to ifconfig you would like to add. There were none in this case. Use TAB to select [OK] when finished and press ENTER. User Confirmation Requested Would you like to Bring Up the ed0 interface right now? [ Yes ] No Choosing [Yes] and pressing ENTER will bring the machine up on the network and be ready for use after leaving leaving the installation.
Configure Gateway User Confirmation Requested Do you want this machine to function as a network gateway? [ Yes ] No [Yes] was selected and ENTER pressed since this machine will be acting as the gateway for a local area network and forwarding packets between other machines. Anonymous FTP Deny Anonymous FTP Selecting [No] and pressing ENTER will still allow users who have accounts with passwords to use ftp. User Confirmation Requested Do you want to have anonymous FTP access to this machine? Yes [ No ] With [No] highlighted, press ENTER to continue with post-installation configuration. Allow Anonymous FTP User Confirmation Requested Do you want to have anonymous FTP access to this machine? [ Yes ] No If you select [Yes] and press ENTER you would be allowing anonymous ftp connections. Be aware of the security considerations if you elect to allow this. To allow anonymous FTP, use the arrow keys to select [Yes] and press ENTER. The following screens (or similar) will appear :
Default Anonymous FTP Configuration
Pressing F1 will display the help : This screen allows you to configure the anonymous FTP user. The following configuration values are editable: UID: The user ID you wish to assign to the anonymous FTP user. All files uploaded will be owned by this ID. Group: Which group you wish the anonymous FTP user to be in. Comment: String describing this user in /etc/passwd FTP Root Directory: Where files available for anonymous FTP will be kept. Upload subdirectory: Where files uploaded by anonymous FTP users will go. The ftp root directory will be put in /var by default. If you do not have enough room there for the anticipated FTP needs, the /usr directory could be used by setting the FTP Root Directory to /usr/ftp. When you are satisfied with the values, press ENTER to continue. User Confirmation Requested Create a welcome message file for anonymous FTP users? [ Yes ] No If you select [Yes] and press ENTER, an editor will automatically start allowing you to edit the message.
Edit The FTP Welcome Message
This is a text editor called ee. Use the instructions to change the message or change the message later using a text editor of your choice. Note the file name/location at the bottom. Press ESC and a pop-up menu will default to "a) leave editor". Press ENTER to exit and continue.
Configure Network File Services NFS Server User Confirmation Requested Do you want to configure this machine as an NFS server? Yes [ No ] If there is no need for a Network File System server or client, select [No] and press ENTER. If [Yes] is chosen, a message will pop-up indicating that the the exports file must be created. Press Enter to continue. Message Operating as an NFS server means that you must first configure an /etc/exports file to indicate which hosts are allowed certain kinds of access to your local file systems. Press [ENTER] now to invoke an editor on /etc/exports [ OK ] A text editor will start allowing the exports file to be created and edited.
Editing the Exports File
Use the instructions to add the actual exported filesystems now or later using a text editor of your choice. Note the filename/location at the bottom. Press ESC and a pop-up menu will default to "a) leave editor". Press ENTER to exit and continue.
NFS Client With the arrow keys, select [Yes] or [No] as appropriate and press ENTER. This example shows the NFS client option as [No]. User Confirmation Requested Do you want to configure this machine as an NFS client? Yes [ No ]
Security Profile A "security profile" is a set of configuration options that attempts to achieve the desired ratio of security to convenience by enabling and disabling certain programs and other settings. Refer to the FAQ for more information. Selecting [No] and pressing ENTER will set the security profile to "medium" (recommended for new users) and continue the installation. User Confirmation Requested Do you want to select a default security profile for this host (select No for "medium" security)? [ Yes ] No Selecting [Yes] and pressing ENTER will allow selecting a different security profile.
Security Profile Options
Press F1 to display the help. Press ENTER to return to selection menu. Use the arrow keys to choose the medium level [DEFAULT] unless your are sure that another level is required for your needs. With [OK] highlighted, press ENTER. Message Moderate security settings have been selected. This means that most "popular" network services and mechanisms like inetd(8) have been enabled by default for a comfortable user experience but with possible trade-offs in system security. If this bothers you and you know exactly what your are doing, select the high high security profile instead. To change any of these settings later, edit /etc/rc.conf. [ OK ] [ Press enter to continue ] Press ENTER to continue with the post-installation configuration.
System Console Settings There are several options available to customize the system console. To view and configure the options, select [Yes] and press ENTER. User Confirmation Requested Would you like to customize your system console settings? [ Yes ] No A commonly used option is the screensaver. Use the arrow keys to select "Saver" and then press ENTER.
Screensaver Options
First, select the desired screen saver using the arrow keys and then press SPACE. The "X" will indicate the selected screensaver.
Screensaver Options
The default time interval is 300 seconds. To change the time interval, select "Timeout" using the arrow keys and press SPACE. A pop-up menu will appear :
Screensaver Timeout
The value can be changed, then select [OK] and press ENTER to return to the System Screensaver options menu. At the Screensaver Menu, select [OK] and press ENTER again to return to the System Console options menu.
System Console Configuration Exit
Selecting [EXIT] and pressing ENTER will continue with the post-installation configurations.
Setting The Time Zone Setting the timezone for your machine will allow it to automatically correct for any regional time changes and perform other timezone related functions properly. The selection menus will vary according to your geographical selections. User Confirmation Requested Would you like to set this machine's time zone now? [ Yes ] No Select [Yes] and press ENTER to set the time zone. User Confirmation Requested Is this machine's CMOS clock set to UTC? If it is set to local time please choose NO here! Yes [ No ] If the machine's CMOS clock is set to local time select [No] with the arrow keys and then press ENTER. If the CMOS clock is set to GMT or UTC, select [Yes] and press ENTER.
Select Your Region
The appropriate region is selected using the arrow keys and then press ENTER.
Select Your Country
Select the appropriate country using the arrow keys and press ENTER. This is a partial chart of the country selection menu.
Select Your Timezone
The appropriate time zone is selected using the arrow keys and pressing ENTER. Again, this is a partial chart. Confirmation Does the abbreviation 'EDT' look reasonable? [ Yes ] No Confirm the abbreviation for the time zone is correct. If it looks okay, press ENTER to continue with the post-installation configuration.
Linux Compatibility User Confirmation Requested Would you like to enable Linux binary compatibility? [ Yes ] No Selecting [Yes] and pressing ENTER will allow running Linux software on FreeBSD. The install will proceed to add the appropriate packages for Linux compatibility. If installing by FTP, the machine will need to be connected to the Internet. Sometimes a remote ftp site will not have all the distributions like the Linux binary compatibility. This can be installed later if necessary. Mouse Settings This option will allow you to cut and past text in the console and user programs with a 3-button mouse. If using a 2-button mouse, refer to manual page, &man.moused.8;, after installation for details on emulating the 3-button style. This example depicts a non-USB mouse. User Confirmation Requested Does this system have a non-USB mouse attached to it? [ Yes ] No Select [Yes] for a non-USB mouse or [No] for a USB mouse and press ENTER.
Select Mouse Protocol Type
Use the arrow keys to select "Type" and press ENTER
Set Mouse Protocol
The mouse in this example is a PS/2 type, so the default "Auto" was appropriate. To change protocol, use the arrow keys and then press SPACE. Select [OK] and press ENTER to exit this menu.
Configure Mouse Port
Use the arrow keys to select "Port" and press ENTER.
Setting The Mouse Port
This system had a PS/2 mouse, so the default "PS/2" was appropriate. To change the port, use the arrow keys and then press the space bar. Select [OK] and press ENTER to exit this menu.
Enable The Mouse Daemon
Last, the mouse daemon is enabled and tested.
Test The Mouse Daemon
The cursor moved around the screen so the mouse daemon is running: Select [YES] to return to the previous menu then select "Exit" with the arrow keys and press ENTER to return to continue with the post-installation configuration.
Configure X-Server User Confirmation Requested Would you like to configure your X server at this time? [ Yes ] No - This can be done later using /stand/sysinstall if you don't + This can be done later using /stand/sysinstall if you do not have graphics card and monitor information handy. Equipment damage can occur if settings are incorrect. Select [Yes] and press ENTER to proceed with configuring the X server. Select Configuration Method
Select Configuration Method Menu
There are several ways to configure the X server. XF86Setup is fully graphical and probably the easiest. Use the arrow keys to select the "XF86Setup" option and press ENTER. Message You have configured and been running the mouse daemon. Choose "/dev/sysmouse" as the mouse port and "SysMouse" or "MouseSystems" as the mouse protocol in the X configuration utility. [ OK ] [ Press enter to continue ] The mouse daemon previously configured has been detected. Press ENTER to continue. Press [Enter] to switch to graphics mode. This may take a while... [ OK ] Press ENTER to switch to the graphics mode and continue. It will not try to switch to the graphics mode until ENTER is pressed. The screen will go black and then shortly a screen with a large "X" in the center will appear. Be patient and wait. After a few more moments, the XF86 Setup Introduction will appear. Read all instructions carefully. Press ENTER to continue.
X-Mouse The mouse is the first item to be configured. The mouse daemon was already running and "Emulate3Buttons" was added for my mouse type. Click on "Apply" and check the mouse actions are working properly. X-Keyboard Click on the "Keyboard" menu item. The default settings were fine for my keyboard. Select the options appropriate for your situation then click on "Apply". Video Card Click on the "Card" menu item. Select the appropriate video card from the list using the scrollbar. Clicking on your card will show as "Card selected:" above the list box. Next, the "Detailed Setup" was selected just to check any details. Monitor Click on the "Monitor" menu item. There are two ways to proceed. One method requires that you enter the horizontal and vertical sweep capabilities of your monitor. Choosing one of the options listed that the monitor is the method used in the illustration. Do not exceed the ratings of your monitor. Damage could occur. If you have doubts select "ABORT" and get the information. The remainder of the installation process will be unaffected and configuring the X-Server can be done later using /stand/sysinstall. After selecting a listed option, the screen will display the horizontal and vertical sweep rates that will be used. Compare those to the monitor specifications. The monitor must be capable of using those ranges. Video Mode Selection Click on the "Modeselection" menu item. Selected the modes and color depth appropriate for the system. Other These are generally reasonable values. Verify all the settings once again and select "Done". It will then attempt to switch to x-mode to verify the settings. If nothing appears or appears wrong, kill the x-server using CTRLALTBACKSPACE and adjust the settings or revisit them after installation. Saving Configuration After selecting [DONE] the following message will display: If you've finished configuring everything press the Okay button to start the X server using the configuration you've selected. If you still wish to configure some things, press one of the buttons at the top and then press "Done" again, when you've finished. After selecting [OKAY], some messages will briefly appear advising to wait and attempting to start the x-server. This process takes a few moments, so be patient. The screen will go blank for a short period of time and then the following should appear: "Congratulations, you've got a running server! The configuration can now be saved in the location indicated and continue with the installation. If the monitor display needs adjusted, xvidtune can be ran to adjust them. There are warnings that improper settings can - damage your equipment. Heed them. If in doubt, don't do + damage your equipment. Heed them. If in doubt, do not do it. Instead, use the monitor controls to adjust the display for x-windows. There may be some display differences when switching - back to text mode, but it's better than damaging equipment. The + back to text mode, but it is better than damaging equipment. The xvidtune can be ran later using /stand/sysinstall. - If it doesn't appear or is distorted, kill the server with + If it does not appear or is distorted, kill the server with CTRLALTBACKSPACE to continue and configure the x-server after installation using /stand/sysinstall. The installation program will create the 'X' link to the server by selecting [Yes]: Do you want to create an 'X' link to the SVGA server? (the link will be created in the directory: /usr/X11R6/bin) Okay? [ Yes ] No Link created successfully. [ OK ] Press [ENTER] to continue configuration.
Select Default X Desktop I selected the K Desktop Environment with the arrow keys and then pressed ENTER to set it as my default window manager.
Select Default Desktop
The selected desktop package will then be loaded on they system.
Install Packages Only one package is shown being added for purposes of illustration. Additional packages can also be added at this time if desired. After installation /stand/sysinstall can be used to add additional packages. User Confirmation Requested The FreeBSD package collection is a collection of hundreds of ready-to-run applications, from text editors to games to WEB servers and more. Would you like to browse the collection now? [ Yes ] No Selecting [Yes] and pressing ENTER will be followed by the Package Selection screens:
Select Package Category
All packages available will be displayed if "All" is chosen. Additional packages may be on other CDs. These can also be added later using /stand/sysinstall. The bash shell is shown selected. Select as many as desired by highlighting the item and pressing the SPACE. A short description of each package will appear in the lower left corner of the screen.
Select Packages
When the package(s) are selected, select [OK] and then press ENTER to return to the Package Selection menu.
Install Packages
Use the arrow keys to select [INSTALL] and pressing ENTER will ask for confirmation.
Confirm Package Installation
Selecting [OK] and pressing ENTER will start the package installation. Installing messages will appear until completed. Make note if there are any error messages. The final configuration continues after packages are installed.
Add User/Groups User Confirmation Requested Would you like to add any initial user accounts to the system? Adding at least one account for yourself at this stage is suggested since working as the "root" user is dangerous (it is easy to do things which adversely affect the entire system). [ Yes ] No Select "Add User" with the arrow keys then and press ENTER.
Select Add User
Add User Information
The following descriptions will appear in the lower part of the screen as the items are selected with TAB Login ID The login name of the new user (mandatory) UID The numerical ID for this user (leave blank for automatic choice) Group The login group name for this user (leave blank for automatic choice) Password The password for this user (enter this field with care!) Full name The user's full name (comment) Member groups The groups this user belongs to (i.e. gets access rights for) Home directory The user's home directory (leave blank for default) Login shell The user's login shell (leave blank for default). (/bin/sh) The login shell was changed from /bin/sh to /usr/local/bin/bash to use the bash shell that was previously installed as a package. The user was also added to the group "wheel" to be able to become a superuser with root privileges. Groups could also be added at this time if specific needs are known. Otherwise, this may be accessed through using /stand/sysinstall after installation is completed.
Exit User and Group Management
I selected [Exit] with the arrow keys then [OK] and pressed ENTER to continue the installation.
Set Root Password Message Now you must set the system manager's password. This is the password you'll use to log in as "root". [ OK ] [ Press enter to continue ] The password will need to be typed in twice correctly. Needless to say, make sure you have a way of finding the password if you forget. Changing local password for root. New password : Retype new password : The installation will continue after the password is successfully entered. Exiting Install User Confirmation Requested Visit the general configuration menu for a chance to set any last options? Yes [ No ] Selecting [No] with the arrow keys and pressing ENTER returns to the Main Installation Menu
Exit Install
Select [EXIT INSTALL] with the arrow keys and press ENTER. User Confirmation Requested Are you sure you wish to exit? The system will reboot (be sure to remove any floppies from the drives). [ Yes ] No Select [Yes] and remove floppy if booting from floppy. The CDROM drive is locked until you select yes to exit and press ENTER. The CDROM drive is then unlocked and can be removed from drive (quickly). The system will reboot so watch for any error messages that may appear.
FreeBSD Bootup If everything goes well, you will see similar messages scroll - off the screen and you'll arrive at a login prompt. You can view + off the screen and you will arrive at a login prompt. You can view the content of the messages by pressing SCROLL-LOCK and using PgUp and PgDn. Pressing SCROLL-LOCK again will return to the prompt. The entire message may not display (buffer limitation) but can be viewed from the command line after logging in by typing dmesg at the prompt will get similar information. Login using the user/password you set during installation (rpratt, in this example). Avoid logging in as root except when necessary. Typical boot messages : Copyright (c) 1992-2001 The FreeBSD Project. Copyright (c) 1982, 1986, 1989, 1991, 1993, 1994 The Regents of the University of California. All rights reserved. FreeBSD 4.3-RELEASE #0: Sat Apr 21 10:54:49 GMT 2001 jkh@narf.osd.bsdi.com:/usr/src/sys/compile/GENERIC Timecounter "i8254" frequency 1193182 Hz CPU: AMD-K6(tm) 3D processor (300.68-MHz 586-class CPU) Origin = "AuthenticAMD" Id = 0x580 Stepping = 0 Features=0x8001bf<FPU,VME,DE,PSE,TSC,MSR,MCE,CX8,MMX> AMD Features=0x80000800<SYSCALL,3DNow!> real memory = 268435456 (262144K bytes) config> di sn0 config> di lnc0 config> di le0 config> di ie0 config> di fe0 config> di cs0 config> di bt0 config> di ata1 config> di aic0 config> di aha0 config> di adv0 config> q avail memory = 256983040 (250960K bytes) Preloaded elf kernel "kernel" at 0xc044d000. Preloaded userconfig_script "/boot/kernel.conf" at 0xc044d09c. md0: Malloc disk npx0: <math processor> on motherboard npx0: INT 16 interface pcib0: <Host to PCI bridge> on motherboard pci0: <PCI bus> on pcib0 pcib1: <VIA 82C598MVP (Apollo MVP3) PCI-PCI (AGP) bridge> at device 1.0 on pci0 pci1: <PCI bus> on pcib1 pci1: <Matrox MGA G200 AGP graphics accelerator> at 0.0 irq 11 isab0: <VIA 82C586 PCI-ISA bridge> at device 7.0 on pci0 isa0: <ISA bus> on isab0 atapci0: <VIA 82C586 ATA33 controller> port 0xe000-0xe00f at device 7.1 on pci0 ata0: at 0x1f0 irq 14 on atapci0 ata1: at 0x170 irq 15 on atapci0 uhci0: <VIA 83C572 USB controller> port 0xe400-0xe41f irq 10 at device 7.2 on pci0 usb0: <VIA 83C572 USB controller> on uhci0 usb0: USB revision 1.0 uhub0: VIA UHCI root hub, class 9/0, rev 1.00/1.00, addr 1 uhub0: 2 ports with 2 removable, self powered chip1: <VIA 82C586B ACPI interface> at device 7.3 on pci0 ed0: <NE2000 PCI Ethernet (RealTek 8029)> port 0xe800-0xe81f irq 9 at device 10.0 on pci0 ed0: address 52:54:05:de:73:1b, type NE2000 (16 bit) isa0: too many dependant configs (8) isa0: unexpected small tag 14 fdc0: <NEC 72065B or clone> at port 0x3f0-0x3f5,0x3f7 irq 6 drq 2 on isa0 fdc0: FIFO enabled, 8 bytes threshold fd0: <1440-KB 3.5" drive> on fdc0 drive 0 atkbdc0: <keyboard controller (i8042)> at port 0x60-0x6f on isa0 atkbd0: <AT Keyboard> flags 0x1 irq 1 on atkbdc0 kbd0 at atkbd0 psm0: <PS/2 Mouse> irq 12 on atkbdc0 psm0: model Generic PS/2 mouse, device ID 0 vga0: <Generic ISA VGA> at port 0x3c0-0x3df iomem 0xa0000-0xbffff on isa0 sc0: <System console> at flags 0x1 on isa0 sc0: VGA <16 virtual consoles, flags=0x300> sio0 at port 0x3f8-0x3ff irq 4 flags 0x10 on isa0 sio0: type 16550A sio1 at port 0x2f8-0x2ff irq 3 on isa0 sio1: type 16550A ppc0: <Parallel port> at port 0x378-0x37f irq 7 on isa0 ppc0: SMC-like chipset (ECP/EPP/PS2/NIBBLE) in COMPATIBLE mode ppc0: FIFO with 16/16/15 bytes threshold ppi0: <Parallel I/O> on ppbus0 lpt0: <Printer> on ppbus0 lpt0: Interrupt-driven port plip0: <PLIP network interface> on ppbus0 ad0: 8063MB <IBM-DHEA-38451> [16383/16/63] at ata0-master using UDMA33 ad2: 8063MB <IBM-DHEA-38451> [16383/16/63] at ata1-master using UDMA33 acd0: CDROM <DELTA OTC-H101/ST3 F/W by OIPD> at ata0-slave using PIO4 Mounting root from ufs:/dev/ad0s1a swapon: adding /dev/ad0s1b as swap device Automatic boot in progress... /dev/ad0s1a: FILESYSTEM CLEAN; SKIPPING CHECKS /dev/ad0s1a: clean, 70119 free (655 frags, 8683 blocks, 0.7% fragmentation) /dev/ad0s1f: FILESYSTEM CLEAN; SKIPPING CHECKS /dev/ad0s1f: clean, 6976313 free (51774 frags, 829297 blocks, 0.7% fragmentation) /dev/ad0s1e: filesystem CLEAN; SKIPPING CHECKS /dev/ad0s1e: clean, 97952 free (9 frags, 12381 blocks, 0.0% fragmentation) Doing initial network setup: hostname. lo0: flags=8049<UP,LOOPBACK,RUNNING,MULTICAST> mtu 16384 inet6 fe80::1%lo0 prefixlen 64 scopeid 0x8 inet6 ::1 prefixlen 128 inet 127.0.0.1 netmask 0xff000000 Additional routing options: tcp extensions=NO IP gateway=YES TCP keepalive=YES routing daemons:. additional daemons: syslogd. Doing additional network setup: portmap. Starting final network daemons: creating ssh RSA host key Generating RSA keys: Key generation complete. Your identification has been saved in /etc/ssh/ssh_host_key. Your public key has been saved in /etc/ssh/ssh_host_key.pub. The key fingerprint is: 2d:02:37:d2:0e:68:93:8f:9c:46:de:92:f4:be:60:0a root@k6-2.weeble.com creating ssh DSA host key Generating DSA parameter and key. Your identification has been saved in /etc/ssh/ssh_host_dsa_key. Your public key has been saved in /etc/ssh/ssh_host_dsa_key.pub. The key fingerprint is: 38:af:d2:1f:63:14:00:d8:83:fd:dd:4b:97:1c:43:6d root@k6-2.weeble.com. setting ELF ldconfig path: /usr/lib /usr/lib/compat /usr/X11R6/lib /usr/local/lib setting a.out ldconfig path: /usr/lib/aout /usr/lib/compat/aout /usr/X11R6/lib/aout starting standard daemons: inetd cron sendmail sshd usbd. Initial rc.i386 initialization: linux. rc.i386 configuring syscons: blank_time screensaver moused. Additional ABI support: linux. Local package initilization:. Additional TCP options:. login: rpratt Password: Generating the RSA and DSA keys may take some time on slower machines. This happens only on the initial boot-up of a new installation. Subsequent boots will be faster. If the X server has been configured and a Default Desktop chosen, it can be started by typing startx at the command line. FreeBSD Shutdown It is important to properly shutdown the operating system. Do not just turn off power. First, become a superuser by typing su at the command line and entering the root password. This will work only if the user is a member of the group wheel. Otherwise, login as root and use shutdown -h now. The operating system has halted. Please press any key to reboot. It is safe to turn off the power after the shutdown command has been issued and the message "Please press any key to reboot" appears. If any key is pressed instead of turning off the power switch, the system will reboot.
Supported Hardware hardware FreeBSD currently runs on a wide variety of ISA, VLB, EISA, and PCI bus-based PCs with Intel, AMD, Cyrix, or NexGen x86 processors, as well as a number of machines based on the Compaq Alpha processor. Support for generic IDE or ESDI drive configurations, various SCSI controllers, PCMCIA cards, USB devices, and network and serial cards is also provided. FreeBSD also supports IBM's microchannel (MCA) bus. A list of supported hardware is provided with each FreeBSD release in the FreeBSD Hardware Notes. This document can usually be found in a file named HARDWARE.TXT, in the top-level directory of a CDROM or FTP distribution or in sysinstall's documentation menu. It lists, for a given architecture, what hardware devices are known to be supported by each release of FreeBSD. Troubleshooting installation troubleshooting The following section covers basic installation troubleshooting, such as common problems people have reported. There are also a few questions and answers for people wishing to dual-boot FreeBSD with MS-DOS. What to Do If Something Goes Wrong... Due to various limitations of the PC architecture, it is impossible for probing to be 100% reliable, however, there are a few things you can do if it fails. Check the Hardware Notes document for your version of FreeBSD to make sure your hardware is supported. If your hardware is supported and you still experience lock-ups or other problems, reset your computer, and when the visual kernel configuration option is given, choose it. This will allow you to go through your hardware and supply information to the system about it. The kernel on the boot disks is configured assuming that most hardware devices are in their factory default configuration in terms of IRQs, IO addresses, and DMA channels. If your hardware has been reconfigured, you will most likely need to use the configuration editor to tell FreeBSD where to find things. It is also possible that a probe for a device not present will cause a later probe for another device that is present to fail. In that case, the probes for the conflicting driver(s) should be disabled. Do not disable any drivers you will need during the installation, such as your screen (sc0). If the installation wedges or fails mysteriously after leaving the configuration editor, you have probably removed or changed something you should not have. Reboot and try again. In configuration mode, you can: List the device drivers installed in the kernel. Change device drivers for hardware that is not present in your system. Change IRQs, DRQs, and IO port addresses used by a device driver. After adjusting the kernel to match your hardware configuration, type Q to boot with the new settings. Once the installation has completed, any changes you made in the configuration mode will be permanent so you do not have to reconfigure every time you boot. It is still highly likely that you will eventually want to build a custom kernel. MS-DOS User's Questions and Answers DOS Many users wish to install FreeBSD on PCs inhabited by MS-DOS. Here are some commonly asked questions about installing FreeBSD on such systems. Help, I have no space! Do I need to delete everything first? If your machine is already running MS-DOS and has little or no free space available for the FreeBSD installation, all hope is not lost! You may find the FIPS utility, provided in the tools directory on the FreeBSD CDROM or various FreeBSD FTP sites to be quite useful. FIPS FIPS allows you to split an existing MS-DOS partition into two pieces, preserving the original partition and allowing you to install onto the second free piece. You first defragment your MS-DOS partition using the Windows DEFRAG utility (go into Explorer, right-click on the hard drive, and choose to defrag your hard drive), or Norton Disk Tools. You then must run FIPS. It will prompt you for the rest of the information it needs. Afterwards, you can reboot and install FreeBSD on the new free slice. See the Distributions menu for an estimate of how much free space you will need for the kind of installation you want. Partition Magic There is also a very useful product from PowerQuest called Partition Magic. This application has far more functionality than FIPS, and is highly recommended if you plan to often add/remove operating systems (like me). However, it does cost money, and if you plan to install FreeBSD once and then leave it there, FIPS will probably be fine for you. Can I use compressed MS-DOS filesystems from FreeBSD? No. If you are using a utility such as Stacker(tm) or DoubleSpace(tm), FreeBSD will only be able to use whatever portion of the filesystem you leave uncompressed. The rest of the filesystem will show up as one large file (the stacked/double spaced file!). Do not remove that file or you will probably regret it greatly! It is probably better to create another uncompressed primary MS-DOS partition and use this for communications between MS-DOS and FreeBSD. Can I mount my extended MS-DOS partition? partitions slices Yes. DOS extended partitions are mapped in at the end of the other slices in FreeBSD, e.g., your D: drive might be /dev/da0s5, your E: drive, /dev/da0s6, and so on. This example assumes, of course, that your extended partition is on SCSI drive 0. For IDE drives, substitute ad for da appropriately if installing 4.0-RELEASE or later, and substitute wd for da if you are installing a version of FreeBSD prior to 4.0. You otherwise mount extended partitions exactly like you would any other DOS drive, for example: &prompt.root; mount -t msdos /dev/ad0s5 /dos_d Valentino Vaschetto Contributed by Advanced Installation Guide This section describes how to install FreeBSD in exceptional cases. Installing FreeBSD on a System without a Monitor or Keyboard installation headless (serial console) serial console This type of installation is called a "headless install", because the machine that you are trying to install FreeBSD on either doesnt have a monitor attached to it, or doesnt even have a VGA output. How is this possible you ask? Using a serial console. A serial console is basically using another machine to act as the main display and keyboard for a system. To do this, just follow these steps: Fetch the Right Boot Floppy Images First you will need to get the right disk images so that you can boot into the install program. The secret with using a serial console is that you tell the boot loader to send I/O through a serial port instead of displaying console output to the VGA device and trying to read input from a local keyboard. Enough of that now, let's get back to getting these disk images. You will need to get kern.flp and mfsroot.flp from the floppies directory. Write the Image Files to the Floppy Disks. The image files, such as kern.flp, are not regular files that you copy to the disk. Instead, they are images of the complete contents of the disk. This means that you can not use commands like DOS' copy to write the files. Instead, you must use specific tools to write the images directly to the disk. fdimage If you are creating the floppies on a computer running DOS then we provide a tool to do this called fdimage. If you are using the floppies from the CDROM, and your CDROM is the E: drive then you would run this: E:\> tools\fdimage floppies\kern.flp A: Repeat this command for each .flp file, replacing the floppy disk each time. Adjust the command line as necessary, depending on where you have placed the .flp files. If you do not have the CDROM then fdimage can be downloaded from the tools directory on the FreeBSD FTP site. If you are writing the floppies on a Unix system (such as another FreeBSD system) you can use the &man.dd.1; command to write the image files directly to disk. On FreeBSD you would run: &prompt.root; dd if=kern.flp of=/dev/fd0 On FreeBSD /dev/fd0 refers to the first floppy disk (the A: drive). /dev/fd1 would be the B: drive, and so on. Other Unix variants might have different names for the floppy disk devices, and you will need to check the documentation for the system as necessary. Enabling the Boot Floppies to Boot into a Serial Console Do not try to mount the floppy if it is write-protected mount If you were to boot into the floppies that you just made, FreeBSD would boot into its normal install mode. We want FreeBSD to boot into a serial console for our install. To do this, you have to mount the kern.flp floppy onto your FreeBSD system using the &man.mount.8; command. &prompt.root; mount /dev/fd0 /mnt Now that you have the floppy mounted, you must change into the floppy directory &prompt.root; cd /mnt Here is where you must set the floppy to boot into a serial console. You have to make a file called boot.config containing "/boot/loader -h". All this does is pass a flag to the bootloader to boot into a serial console. &prompt.root; echo "/boot/loader -h" > boot.config Now that you have your floppy configured correctly, you must unmount the floppy using the &man.umount.8; command &prompt.root; cd / &prompt.root; umount /mnt Now you can remove the floppy from the floppy drive Connecting Your Null Modem Cable null-modem cable You now need to connect a null modem cable between the two machines. Just connect the cable to the serial ports of the 2 machines. A normal serial cable will not work here, you need a null modem cable because it has some of the wires inside crossed over. Booting Up for the Install - It's now time to go ahead and start the install. Put + It is now time to go ahead and start the install. Put the kern.flp floppy in the floppy - drive of the machine you're doing the headless install + drive of the machine you are doing the headless install on, and power on the machine. Connecting to Your Headless Machine cu Now you have to connect to that machine with &man.cu.1;: &prompt.root; cu -l /dev/cuaa0 That's it! You should be able to control the headless machine through your cu session now. It will ask you to put in the mfsroot.flp, and then it will come up with a selection of what kind of terminal to use. Just select the FreeBSD color console and proceed with your install! Preparing Installation Media If you are Placeholder Before Installing from CDROM If your CDROM is of an unsupported type, please skip ahead to the MS-DOS Preparation section. Unix If you are creating the boot floppies from a Unix machine, see the Creating the Boot Floppies section of this guide for examples. Once you have booted from DOS or floppy, you should then be able to select CDROM as the media type during the install process and load the entire distribution from CDROM. No other types of installation media should be required. After your system is fully installed and you have rebooted (from the hard disk), you can mount the CDROM at any time by typing: &prompt.root; mount /cdrom Before removing the CD from the drive again, you must first unmount it. This is done with the following command: &prompt.root; umount /cdrom Do not just remove it from the drive! Before invoking the installation, be sure that the CDROM is in the drive so that the install probe can find it. This is also true if you wish the CDROM to be added to the default system configuration automatically during the installation (whether or not you actually use it as the installation media). installation network FTP Finally, if you would like people to be able to FTP install FreeBSD directly from the CDROM in your machine, you will find it quite easy. After the machine is fully installed, you simply need to add the following line to the password file (using the vipw command): ftp:*:99:99::0:0:FTP:/cdrom:/nonexistent Anyone with network connectivity to your machine can now chose a media type of FTP and type in ftp://your machine after picking Other in the FTP sites menu during the install. If you choose to enable anonymous FTP during the installation of your system, the installation program will do the above for you. Before Installing from Floppies installation floppies If you must install from floppy disk (which we suggest you do NOT do), either due to unsupported hardware or simply because you insist on doing things the hard way, you must first prepare some floppies for the installation. At a minimum, you will need as many 1.44MB or 1.2MB floppies as it takes to hold all the files in the bin (binary distribution) directory. If you are preparing the floppies from DOS, then they MUST be formatted using the MS-DOS FORMAT command. If you are using Windows, use Explorer to format the disks (right-click on the A: drive, and select "Format". Do NOT trust factory pre-formatted floppies! Format them again yourself, just to be sure. Many problems reported by our users in the past have resulted from the use of improperly formatted media, which is why we are making a point of it now. If you are creating the floppies on another FreeBSD machine, a format is still not a bad idea, though you do not need to put a DOS filesystem on each floppy. You can use the disklabel and newfs commands to put a UFS filesystem on them instead, as the following sequence of commands (for a 3.5" 1.44MB floppy) illustrates: &prompt.root; fdformat -f 1440 fd0.1440 &prompt.root; disklabel -w -r fd0.1440 floppy3 &prompt.root; newfs -t 2 -u 18 -l 1 -i 65536 /dev/fd0 Use fd0.1200 and floppy5 for 5.25" 1.2MB disks. Then you can mount and write to them like any other filesystem. After you have formatted the floppies, you will need to copy the files to them. The distribution files are split into chunks conveniently sized so that 5 of them will fit on a conventional 1.44MB floppy. Go through all your floppies, packing as many files as will fit on each one, until you have all of the distributions you want packed up in this fashion. Each distribution should go into a subdirectory on the floppy, e.g.: a:\bin\bin.aa, a:\bin\bin.ab, and so on. Once you come to the Media screen during the install process, select Floppy and you will be prompted for the rest. Before Installing from MS-DOS installation from MS-DOS To prepare for an installation from an MS-DOS partition, copy the files from the distribution into a directory named, for example, c:\FreeBSD. The directory structure of the CDROM or FTP site must be partially reproduced within this directory, so we suggest using the DOS xcopy command if you are copying it from a CD. For example, to prepare for a minimal installation of FreeBSD: C:\> md c:\FreeBSD C:\> xcopy e:\bin c:\FreeBSD\bin\ /s C:\> xcopy e:\manpages c:\FreeBSD\manpages\ /s Assuming that C: is where you have free space and E: is where your CDROM is mounted. If you do not have a CDROM drive, you can download the distribution from ftp.FreeBSD.org. Each distribution is in its own directory; for example, the bin distribution can be found in the &rel.current;/bin directory. For as many distributions you wish to install from an MS-DOS partition (and you have the free space for), install each one under c:\FreeBSD — the BIN distribution is the only one required for a minimum installation. Before Installing from QIC/SCSI Tape installation from QIC/SCSI Tape Installing from tape is probably the easiest method, short of an online FTP install or CDROM install. The installation program expects the files to be simply tarred onto the tape, so after getting all of the distribution files you are interested in, simply tar them onto the tape like so: &prompt.root; cd /freebsd/distdir &prompt.root; tar cvf /dev/rwt0 dist1 ... dist2 When you go to do the installation, you should also make sure that you leave enough room in some temporary directory (which you will be allowed to choose) to accommodate the full contents of the tape you have created. Due to the non-random access nature of tapes, this method of installation requires quite a bit of temporary storage. You should expect to require as much temporary storage as you have stuff written on tape. When starting the installation, the tape must be in the drive before booting from the boot floppy. The installation probe may otherwise fail to find it. Before Installing over a Network installation network serial (SLIP or PPP) installation network parallel (PLIP) installation network Ethernet There are three types of network installations you can do. Serial port (SLIP or PPP), Parallel port (PLIP (laplink cable)), or Ethernet (a standard Ethernet controller (includes some PCMCIA)). The SLIP support is rather primitive, and limited primarily to hard-wired links, such as a serial cable running between a laptop computer and another computer. The link should be hard-wired as the SLIP installation does not currently offer a dialing capability; that facility is provided with the PPP utility, which should be used in preference to SLIP whenever possible. If you are using a modem, then PPP is almost certainly your only choice. Make sure that you have your service provider's information handy as you will need to know it fairly early in the installation process. If you use PAP or CHAP to connect your ISP (in other words, if you can connect to the ISP in Windows without using a script), then all you will need to do is type in dial at the ppp prompt. Otherwise, you will need to know how to dial your ISP using the AT commands specific to your modem, as the PPP dialer provides only a very simple terminal emulator. Please refer to the user-ppp handbook and FAQ entries for further information. If you have problems, logging can be directed to the screen using the command set log local .... If a hard-wired connection to another FreeBSD (2.0-R or later) machine is available, you might also consider installing over a laplink parallel port cable. The data rate over the parallel port is much higher than what is typically possible over a serial line (up to 50kbytes/sec), thus resulting in a quicker installation. Finally, for the fastest possible network installation, an Ethernet adapter is always a good choice! FreeBSD supports most common PC Ethernet cards; a table of supported cards (and their required settings) is provided in the Hardware Notes for each release of FreeBSD. If you are using one of the supported PCMCIA Ethernet cards, also be sure that it is plugged in before the laptop is powered on! FreeBSD does not, unfortunately, currently support hot insertion of PCMCIA cards during installation. You will also need to know your IP address on the network, the netmask value for your address class, and the name of your machine. If you are installing over a PPP connection and do not have a static IP, fear not, the IP address can be dynamically assigned by your ISP. Your system administrator can tell you which values to use for your particular network setup. If you will be referring to other hosts by name rather than IP address, you will also need a name server and possibly the address of a gateway (if you are using PPP, it is your provider's IP address) to use in talking to it. If you want to install by FTP via a HTTP proxy (see below), you will also need the proxy's address. If you do not know the answers to all or most of these questions, then you should really probably talk to your system administrator or ISP before trying this type of installation. Before Installing via NFS installation network NFS The NFS installation is fairly straight-forward. Simply copy the FreeBSD distribution files you want onto a server somewhere and then point the NFS media selection at it. If this server supports only privileged port (as is generally the default for Sun workstations), you will need to set this option in the Options menu before installation can proceed. If you have a poor quality Ethernet card which suffers from very slow transfer rates, you may also wish to toggle the appropriate Options flag. In order for NFS installation to work, the server must support subdir mounts, e.g., if your FreeBSD 3.4 distribution directory lives on:ziggy:/usr/archive/stuff/FreeBSD, then ziggy will have to allow the direct mounting of /usr/archive/stuff/FreeBSD, not just /usr or /usr/archive/stuff. In FreeBSD's /etc/exports file, this is controlled by the . Other NFS servers may have different conventions. If you are getting permission denied messages from the server, then it is likely that you do not have this enabled properly. Before Installing via FTP installation network FTP FTP installation may be done from any FreeBSD mirror site containing a reasonably up-to-date version of FreeBSD. A full list of FTP mirrors located all over the world is provided during the install process. If you are installing from an FTP site not listed in this menu, or are having trouble getting your name server configured properly, you can also specify a URL to use by selecting the choice labeled Other in that menu. You can also use the IP address of a machine you wish to install from, so the following would work in the absence of a name server: ftp://209.55.82.20/pub/FreeBSD/&rel.current;-RELEASE There are three FTP installation modes you can choose from: active or passive FTP or via a HTTP proxy. FTP Active This option will make all FTP transfers use Active mode. This will not work through firewalls, but will often work with older FTP servers that do not support passive mode. If your connection hangs with passive mode (the default), try active! FTP Passive FTP Passive mode This option instructs FreeBSD to use Passive mode for all FTP operations. This allows the user to pass through firewalls that do not allow incoming connections on random port addresses. FTP via a HTTP proxy FTP via a HTTP proxy This option instructs FreeBSD to use the HTTP protocol (like a web browser) to connect to a proxy for all FTP operations. The proxy will translate the requests and send them to the FTP server. This allows the user to pass through firewalls that do not allow FTP at all, but offer a HTTP proxy. In this case, you have to specify the proxy in addition to the FTP server. There is another type of FTP proxy other tha HTTP proxies. This type is very uncommon, though. If you are not absolutely certain, you can assume that you have a HTTP proxy as described above. For a proxy FTP server, you should usually give the name of the server you really want as a part of the username, after an @ sign. The proxy server then fakes the real server. For example, assuming you want to install from ftp.FreeBSD.org, using the proxy FTP server foo.bar.com, listening on port 1024. In this case, you go to the options menu, set the FTP username to ftp@ftp.FreeBSD.org, and the password to your email address. As your installation media, you specify FTP (or passive FTP, if the proxy supports it), and the URL ftp://foo.bar.com:1234/pub/FreeBSD. Since /pub/FreeBSD from ftp.FreeBSD.org is proxied under foo.bar.com, you are able to install from that machine (which will fetch the files from ftp.FreeBSD.org as your installation requests them. Check Your BIOS Drive Numbering If you have used features in your BIOS to renumber your disk drives without re-cabling them then you should read first to avoid confusion.
diff --git a/en_US.ISO8859-1/books/handbook/introduction/chapter.sgml b/en_US.ISO8859-1/books/handbook/introduction/chapter.sgml index 5e88f843f5..c4b8b02501 100644 --- a/en_US.ISO8859-1/books/handbook/introduction/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/introduction/chapter.sgml @@ -1,890 +1,890 @@ Jim Mock Restructured, reorganized, and parts rewritten by Introduction Synopsis Thank you for your interest in FreeBSD! The following chapter covers various items about the FreeBSD Project, such as its history, goals, development model, and so on. 4.4BSD-Lite FreeBSD is a 4.4BSD-Lite based operating system for the Intel architecture (x86) and DEC Alpha based systems. Ports to other architectures are also underway. For a brief overview of FreeBSD, see the next section. You can also read about the history of FreeBSD, or the current release. If you are interested in contributing something to the Project (code, hardware, unmarked bills), see the contributing to FreeBSD section. Welcome to FreeBSD! Since you are still here reading this, you most likely have some idea as to what FreeBSD is and what it can do for you. If you are new to FreeBSD, read on for more information. What is FreeBSD? Intel architecture (x86) DEC Alpha architecture In general, FreeBSD is a state-of-the-art operating system based on 4.4BSD-Lite. It runs on computer systems based on the Intel architecture (x86), and also the DEC Alpha architecture. FreeBSD is used to power some of the biggest sites on the Internet, including: Yahoo! Yahoo! Apache Apache Be, Inc. Be, Inc. Blue Mountain Arts Blue Mountain Arts Pair Networks Pair Networks Whistle Communications Whistle Communications Microsoft Microsoft Hotmail Hotmail Sony Japan Sony Japan and many more. What Can FreeBSD Do? FreeBSD has many noteworthy features. Some of these are: preemptive multitasking Preemptive multitasking with dynamic priority adjustment to ensure smooth and fair sharing of the computer between applications and users, even under the heaviest of loads. multi-user facilities Multi-user facilities which allow many people to use a FreeBSD system simultaneously for a variety of things. This means, for example, that system peripherals such as printers and tape drives are properly shared between all users on the system or the network and that individual resource limits can be placed on users or groups of users, protecting critical system resources from over-use. TCP/IP networking Strong TCP/IP networking with support for industry standards such as SLIP, PPP, NFS, DHCP, and NIS. This means that your FreeBSD machine can interoperate easily with other systems as well as act as an enterprise server, providing vital functions such as NFS (remote file access) and email services or putting your organization on the Internet with WWW, FTP, routing and firewall (security) services. memory protection Memory protection ensures that applications (or users) cannot interfere with each other. One application crashing will not affect others in any way. FreeBSD is a 32-bit operating system (64-bit on the Alpha) and was designed as such from the ground up. X Window System XFree86 The industry standard X Window System (X11R6) provides a graphical user interface (GUI) for the cost of a common VGA card and monitor and comes with full sources. binary compatibility Linux binary compatibility SCO binary compatibility SVR4 binary compatibility BSD/OS binary compatibility NetBSD Binary compatibility with many programs built for Linux, SCO, SVR4, BSDI and NetBSD. Thousands of ready-to-run applications are available from the FreeBSD ports and packages collection. Why search the net when you can find it all right here? Thousands of additional and easy-to-port applications are available on the Internet. FreeBSD is source code compatible with most popular commercial Unix systems and thus most applications require few, if any, changes to compile. virtual memory Demand paged virtual memory and merged VM/buffer cache design efficiently satisfies applications with large appetites for memory while still maintaining interactive response to other users. Symetric Multi-Processing (SMP) SMP support for machines with multiple CPUs. compilers C compilers C++ compilers Fortran A full complement of C, C++, Fortran, and Perl development tools. Many additional languages for advanced research and development are also available in the ports and packages collection. source code Source code for the entire system means you have the greatest degree of control over your environment. Why be locked into a proprietary solution at the mercy of your vendor when you can have a truly open system? Extensive online documentation. And many more! 4.4BSD-Lite Computer Systems Resarch Group (CSRG) U.C. Berkeley FreeBSD is based on the 4.4BSD-Lite release from Computer Systems Research Group (CSRG) at the University of California at Berkeley, and carries on the distinguished tradition of BSD systems development. In addition to the fine work provided by CSRG, the FreeBSD Project has put in many thousands of hours in fine tuning the system for maximum performance and reliability in real-life load situations. As many of the commercial giants struggle to field PC operating systems with such features, performance and reliability, FreeBSD can offer them now! The applications to which FreeBSD can be put are truly limited only by your own imagination. From software development to factory automation, inventory control to azimuth correction of remote satellite antennae; if it can be done with a commercial Unix product then it is more than likely that you can do it with FreeBSD too! FreeBSD also benefits significantly from the literally thousands of high quality applications developed by research centers and universities around the world, often available at little to no cost. Commercial applications are also available and appearing in greater numbers every day. Because the source code for FreeBSD itself is generally available, the system can also be customized to an almost unheard of degree for special applications or projects, and in ways not generally possible with operating systems from most major commercial vendors. Here is just a sampling of some of the applications in which people are currently using FreeBSD: Internet Services: The robust TCP/IP networking built into FreeBSD makes it an ideal platform for a variety of Internet services such as: FTP servers FTP servers web servers World Wide Web servers (standard or secure [SSL]) firewall IP masquerading Firewalls and NAT (IP masquerading) gateways electronic mail Electronic Mail servers USENET USENET News or Bulletin Board Systems And more... With FreeBSD, you can easily start out small with an inexpensive 386 class PC and upgrade all the way up to a quad-processor Xeon with RAID storage as your enterprise grows. Education: Are you a student of computer science or a related engineering field? There is no better way of learning about operating systems, computer architecture and networking than the hands on, under the hood experience that FreeBSD can provide. A number of freely available CAD, mathematical and graphic design packages also make it highly useful to those whose primary interest in a computer is to get other work done! Research: With source code for the entire system available, FreeBSD is an excellent platform for research in operating systems as well as other branches of computer science. FreeBSD's freely available nature also makes it possible for remote groups to collaborate on ideas or shared development without having to worry about special licensing agreements or limitations on what may be discussed in open forums. router DNS Server Networking: Need a new router? A name server (DNS)? A firewall to keep people out of your internal network? FreeBSD can easily turn that unused 386 or 486 PC sitting in the corner into an advanced router with sophisticated packet-filtering capabilities. X Window System XFree86 X Window System Accellerated-X X Window workstation: FreeBSD is a fine choice for an inexpensive X terminal solution, either using the freely available XFree86 server or one of the excellent commercial servers provided by X Inside. Unlike an X terminal, FreeBSD allows many applications to be run locally, if desired, thus relieving the burden on a central server. FreeBSD can even boot diskless, making individual workstations even cheaper and easier to administer. GNU Compiler Collection Software Development: The basic FreeBSD system comes with a full complement of development tools including the renowned GNU C/C++ compiler and debugger. FreeBSD is available in both source and binary form on CDROM and via anonymous FTP. Please see for more information about obtaining FreeBSD. About the FreeBSD Project The following section provides some background information on the project, including a brief history, project goals, and the development model of the project. Jordan Hubbard Contributed by A Brief History of FreeBSD 386BSD Patchkit Hubbard, Jordan Williams, Nate Grimes, Rod FreeBSD Project History The FreeBSD project had its genesis in the early part of 1993, partially as an outgrowth of the Unofficial 386BSD Patchkit by the patchkit's last 3 coordinators: Nate Williams, Rod Grimes and myself. 386BSD Our original goal was to produce an intermediate snapshot of 386BSD in order to fix a number of problems with it that the patchkit mechanism just was not capable of solving. Some of you may remember the early working title for the project being 386BSD 0.5 or 386BSD Interim in reference to that fact. Jolitz, Bill 386BSD was Bill Jolitz's operating system, which had been up to that point suffering rather severely from almost a year's worth of neglect. As the patchkit swelled ever more uncomfortably with each passing day, we were in unanimous agreement that something had to be done and decided to try and assist Bill by providing this interim cleanup snapshot. Those plans came to a rude halt when Bill Jolitz suddenly decided to withdraw his sanction from the project without any clear indication of what would be done instead. Greenman, David Walnut Creek CDROM It did not take us long to decide that the goal remained worthwhile, even without Bill's support, and so we adopted the name FreeBSD, coined by David Greenman. Our initial objectives were set after consulting with the system's current users and, once it became clear that the project was on the road to perhaps even becoming a reality, I contacted Walnut Creek CDROM with an eye towards improving FreeBSD's distribution channels for those many unfortunates without easy access to the Internet. Walnut Creek CDROM not only supported the idea of distributing FreeBSD on CD but also went so far as to provide the project with a machine to work on and a fast Internet connection. Without Walnut Creek CDROM's almost unprecedented degree of faith in what was, at the time, a completely unknown project, it is quite unlikely that FreeBSD would have gotten as far, as fast, as it has today. 4.3BSD-Lite Net/2 U.C. Berkeley 386BSD Free Software Foundation The first CDROM (and general net-wide) distribution was FreeBSD 1.0, released in December of 1993. This was based on the 4.3BSD-Lite (Net/2) tape from U.C. Berkeley, with many components also provided by 386BSD and the Free Software Foundation. It was a fairly reasonable success for a first offering, and we followed it with the highly successful FreeBSD 1.1 release in May of 1994. Novell U.C. Berkeley Net/2 AT&amp;T Around this time, some rather unexpected storm clouds formed on the horizon as Novell and U.C. Berkeley settled their long-running lawsuit over the legal status of the Berkeley Net/2 tape. A condition of that settlement was U.C. Berkeley's concession that large parts of Net/2 were encumbered code and the property of Novell, who had in turn acquired it from AT&T some time previously. What Berkeley got in return was Novell's blessing that the 4.4BSD-Lite release, when it was finally released, would be declared unencumbered and all existing Net/2 users would be strongly encouraged to switch. This included FreeBSD, and the project was given until the end of July 1994 to stop shipping its own Net/2 based product. Under the terms of that agreement, the project was allowed one last release before the deadline, that release being FreeBSD 1.1.5.1. FreeBSD then set about the arduous task of literally re-inventing itself from a completely new and rather incomplete set of 4.4BSD-Lite bits. The Lite releases were light in part because Berkeley's CSRG had removed large chunks of code required for actually constructing a bootable running system (due to various legal requirements) and the fact that the Intel port of 4.4 was highly incomplete. It took the project until November of 1994 to make this transition, at which point it released FreeBSD 2.0 to the net and on CDROM (in late December). Despite being still more than a little rough around the edges, the release was a significant success and was followed by the more robust and easier to install FreeBSD 2.0.5 release in June of 1995. We released FreeBSD 2.1.5 in August of 1996, and it appeared to be popular enough among the ISP and commercial communities that another release along the 2.1-STABLE branch was merited. This was FreeBSD 2.1.7.1, released in February 1997 and capping the end of mainstream development on 2.1-STABLE. Now in maintenance mode, only security enhancements and other critical bug fixes will be done on this branch (RELENG_2_1_0). FreeBSD 2.2 was branched from the development mainline (-CURRENT) in November 1996 as the RELENG_2_2 branch, and the first full release (2.2.1) was released in April 1997. Further releases along the 2.2 branch were done in the summer and fall of '97, the last of which (2.2.8) appeared in November 1998. The first official 3.0 release appeared in October 1998 and spelled the beginning of the end for the 2.2 branch. The tree branched again on Jan 20, 1999, leading to the 4.0-CURRENT and 3.X-STABLE branches. From 3.X-STABLE, 3.1 was released on February 15, 1999, 3.2 on May 15, 1999, 3.3 on September 16, 1999, 3.4 on December 20, 1999, and 3.5 on June 24, 2000, which was followed a few days later by a minor point release update to 3.5.1, to incorporate some last-minute security fixes to Kerberos. This will be the final release in the 3.X branch. There was another branch on March 13, 2000, which saw the emergence of the 4.X-STABLE branch, now considered to be the "current -stable branch". There have been several releases from it so far: 4.0-RELEASE came out in March 2000, 4.1 was released in July 2000, 4.2 in November 2000, and 4.3 in April 2001. There will be more releases along the 4.X-stable (RELENG_4) branch throughout 2001. Long-term development projects continue to take place in the 5.0-CURRENT (trunk) branch, and SNAPshot releases of 5.0 on CDROM (and, of course, on the net) are continually made available from the snapshot server as work progresses. Jordan Hubbard Contributed by FreeBSD Project Goals FreeBSD Project Goals The goals of the FreeBSD Project are to provide software that may be used for any purpose and without strings attached. Many of us have a significant investment in the code (and project) and would certainly not mind a little financial compensation now and then, but we are definitely not prepared to insist on it. We believe that our first and foremost mission is to provide code to any and all comers, and for whatever purpose, so that the code gets the widest possible use and provides the widest possible benefit. This is, I believe, one of the most fundamental goals of Free Software and one that we enthusiastically support. GNU General Public License (GPL) GNU Lesser General Public License (LGPL) BSD Copyright That code in our source tree which falls under the GNU General Public License (GPL) or Library General Public License (LGPL) comes with slightly more strings attached, though at least on the side of enforced access rather than the usual opposite. Due to the additional complexities that can evolve in the commercial use of GPL software we do, however, prefer software submitted under the more relaxed BSD copyright when - it's a reasonable option to do so. + it is a reasonable option to do so. Satoshi Asami Contributed by The FreeBSD Development Model FreeBSD Project Development Model The development of FreeBSD is a very open and flexible process, FreeBSD being literally built from the contributions of hundreds of people around the world, as can be seen from our our list of contributors. We are constantly on the lookout for new developers and ideas, and those interested in becoming more closely involved with the project need simply contact us at the &a.hackers;. The &a.announce; is also available to those wishing to make other FreeBSD users aware of major areas of work. Useful things to know about the FreeBSD project and its development process, whether working independently or in close cooperation: The CVS repository CVS repository Concurrent Versions System CVS The central source tree for FreeBSD is maintained by CVS (Concurrent Versions System), a freely available source code control tool that comes bundled with FreeBSD. The primary CVS repository resides on a machine in Santa Clara CA, USA from where it is replicated to numerous mirror machines throughout the world. The CVS tree, as well as the -CURRENT and -STABLE trees which are checked out of it, can be easily replicated to your own machine as well. Please refer to the Synchronizing your source tree section for more information on doing this. The committers list committers The committers are the people who have write access to the CVS tree, and are thus authorized to make modifications to the FreeBSD source (the term committer comes from the &man.cvs.1; commit command, which is used to bring new changes into the CVS repository). The best way of making submissions for review by the committers list is to use the &man.send-pr.1; command, though if something appears to be jammed in the system then you may also reach them by sending mail to cvs-committers@FreeBSD.org. The FreeBSD core team core team The FreeBSD core team would be equivalent to the board of directors if the FreeBSD Project were a company. The primary task of the core team is to make sure the project, as a whole, is in good shape and is heading in the right directions. Inviting dedicated and responsible developers to join our group of committers is one of the functions of the core team, as is the recruitment of new core team members as others move on. The current core team was elected from a pool of committer candidates in October 2000. Elections are held every 2 years. Some core team members also have specific areas of responsibility, meaning that they are committed to ensuring that some large portion of the system works as advertised. For a complete list of FreeBSD developers and their areas of responsibility, please see the Contributors List Most members of the core team are volunteers when it comes to FreeBSD development and do not benefit from the project financially, so commitment should also not be misconstrued as meaning guaranteed support. The board of directors analogy above is not actually very accurate, and it may be more suitable to say that these are the people who gave up their lives in favor of FreeBSD against their better judgment! Outside contributors contributors Last, but definitely not least, the largest group of developers are the users themselves who provide feedback and bug fixes to us on an almost constant basis. The primary way of keeping in touch with FreeBSD's more non-centralized development is to subscribe to the &a.hackers; (see mailing list info) where such things are discussed. The FreeBSD Contributors List is a long and growing one, so why not join it by contributing something back to FreeBSD today? Providing code is not the only way of contributing to the project; for a more complete list of things that need doing, please refer to the how to contribute section in this handbook. In summary, our development model is organized as a loose set of concentric circles. The centralized model is designed for the convenience of the users of FreeBSD, who are thereby provided with an easy way of tracking one central code base, not to keep potential contributors out! Our desire is to present a stable operating system with a large set of coherent application programs that the users can easily install and use, and this model works very well in accomplishing that. All we ask of those who would join us as FreeBSD developers is some of the same dedication its current people have to its continued success! The Current FreeBSD Release NetBSD OpenBSD 386BSD Free Software Foundation U.C. Berkeley Computer Systems Resarch Group (CSRG) FreeBSD is a freely available, full source 4.4BSD-Lite based release for Intel i386, i486, Pentium, Pentium Pro, Celeron, Pentium II, Pentium III (or compatible) and DEC Alpha based computer systems. It is based primarily on software from U.C. Berkeley's CSRG group, with some enhancements from NetBSD, OpenBSD, 386BSD, and the Free Software Foundation. Since our release of FreeBSD 2.0 in late 94, the performance, feature set, and stability of FreeBSD has improved dramatically. The largest change is a revamped virtual memory system with a merged VM/file buffer cache that not only increases performance, but also reduces FreeBSD's memory footprint, making a 5MB configuration a more acceptable minimum. Other enhancements include full NIS client and server support, transaction TCP support, dial-on-demand PPP, integrated DHCP support, an improved SCSI subsystem, ISDN support, support for ATM, FDDI, Fast and Gigabit Ethernet (1000Mbit) adapters, improved support for the latest Adaptec controllers, and many hundreds of bug fixes. We have also taken the comments and suggestions of many of our users to heart and have attempted to provide what we hope is a more sane and easily understood installation process. Your feedback on this (constantly evolving) process is especially welcome! In addition to the base distributions, FreeBSD offers a ported software collection with thousands of commonly sought-after programs. At the time of this printing, there were over &os.numports; ports! The list of ports ranges from http (WWW) servers, to games, languages, editors, and almost everything in between. The entire ports collection requires approximately 100MB of storage, all ports being expressed as deltas to their original sources. This makes it much easier for us to update ports, and greatly reduces the disk space demands made by the older 1.0 ports collection. To compile a port, you simply change to the directory of the program you wish to install, type make install, and let the system do the rest. The full original distribution for each port you build is retrieved dynamically off the CDROM or a local FTP site, so you need only enough disk space to build the ports you want. Almost every port is also provided as a pre-compiled package, which can be installed with a simple command (pkg_add) by those who do not wish to compile their own ports from source. A number of additional documents which you may find very helpful in the process of installing and using FreeBSD may now also be found in the /usr/share/doc directory on any machine running FreeBSD 2.1 or later. You may view the locally installed manuals with any HTML capable browser using the following URLs: The FreeBSD Handbook /usr/share/doc/handbook/index.html The FreeBSD FAQ /usr/share/doc/faq/index.html You can also view the master (and most frequently updated) copies at http://www.FreeBSD.org/. diff --git a/en_US.ISO8859-1/books/handbook/kernelconfig/chapter.sgml b/en_US.ISO8859-1/books/handbook/kernelconfig/chapter.sgml index dce60bb7cf..c03fd5233d 100644 --- a/en_US.ISO8859-1/books/handbook/kernelconfig/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/kernelconfig/chapter.sgml @@ -1,1327 +1,1327 @@ Jim Mock Updated and restructured by Jake Hamby Originally contributed by Configuring the FreeBSD Kernel Synopsis kernel building a custom kernel The kernel is the core of the FreeBSD operating system. It is responsible for managing memory, enforcing security controls, networking, disk access, and much more. While more and more of FreeBSD becomes dynamically configurable it is still occasionally necessary to reconfigure and recompile your kernel. After reading this chapter you will know: Why you might need to build a custom kernel How to write a kernel configuration file, or alter an existing configuration file How to use the kernel configuration file to create and build a new kernel How to install the new kernel How to create any entries in /dev that may be required How to troubleshoot if things go wrong Why Build a Custom Kernel? Traditionally FreeBSD has had what is called a monolithic kernel. This means that the kernel was one large program, supported a fixed list of devices, and if you wanted to change the kernel's behavior then you had to compile a new kernel, and then reboot your computer with the new kernel. Today, FreeBSD is rapidly moving to a model where much of the kernel's functionality is contained in modules which can be dynamically loaded and unloaded from the kernel as necessary. This allows the kernel to adapt to new hardware suddenly becoming available (such as PCMCIA cards in a laptop), or for new functionality to be brought in to the kernel that was not necessary when the kernel was originally compiled. Colloquially these are called KLDs. Despite this, it is still necessary to carry out some static kernel configuration. In some cases this is because the functionality is so tied to the kernel that it can not be made dynamically loadable. In others it may simply be because no one has yet taken the time to write a dynamic loadable kernel module for that functionality yet. Building a custom kernel is one of the most important rites of passage nearly every Unix user must endure. This process, while time consuming, will provide many benefits to your FreeBSD system. Unlike the GENERIC kernel, which must support a wide range of hardware, a custom kernel only contains support for your PC's hardware. This has a number of benefits, such as: Faster boot time. Since the kernel will only probe the hardware you have on your system, the time it takes your system to boot will decrease dramatically. Less memory use. A custom kernel often uses less memory than the GENERIC kernel, which is important because the kernel is one process that must always be present in memory. For this reason, a custom kernel is especially useful on a system with a small amount of RAM. Additional hardware support. A custom kernel allows you to add in support for devices such as sound cards, which are not present in the GENERIC kernel. Building and Installing a Custom Kernel kernel building / installing First, let us take a quick tour of the kernel build directory. All directories mentioned will be relative to the main /usr/src/sys directory, which is also accessible through /sys. There are a number of subdirectories here representing different parts of the kernel, but the most important, for our purposes, are arch/conf, where you will edit your custom kernel configuration, and compile, which is the staging area where your kernel will be built. arch represents either i386, alpha, or pc98 (an alternative development branch of PC hardware, popular in Japan). Everything inside a particular architecture's directory deals with that architecture only; the rest of the code is common to all platforms to which FreeBSD could potentially be ported. Notice the logical organization of the directory structure, with each supported device, filesystem, and option in its own subdirectory. If there is not a /usr/src/sys directory on your system, then the kernel source has not been installed. The easiest way to do this is by running /stand/sysinstall as root, choosing Configure, then Distributions, then src, then sys. Next, move to the arch/conf directory and copy the GENERIC configuration file to the name you want to give your kernel. For example: &prompt.root; cd /usr/src/sys/i386/conf &prompt.root; cp GENERIC MYKERNEL Traditionally, this name is in all capital letters and, if you are maintaining multiple FreeBSD machines with different hardware, it is a good idea to name it after your machine's hostname. We will call it MYKERNEL for the purpose of this example. Storing your kernel config file directly under /usr/src can be a bad idea. If you are experiencing problems it can be tempting to just delete /usr/src and start again. Five seconds after you do that you realize that you have deleted your custom kernel config file. You might want to keep your kernel config file elsewhere, and then create a symbolic link to the file in the i386 directory. For example: &prompt.root; cd /usr/src/sys/i386/conf &prompt.root; mkdir /root/kernels &prompt.root; cp GENERIC /root/kernels/MYKERNEL &prompt.root; ln -s /root/kernels/MYKERNEL You must execute these and all of the following commands under the root account or you will get permission denied errors. Now, edit MYKERNEL with your favorite text editor. If you are just starting out, the only editor available will probably be vi, which is too complex to explain here, but is covered well in many books in the bibliography. However, FreeBSD does offer an easier editor called ee which, if you are a beginner, should be your editor of choice. Feel free to change the comment lines at the top to reflect your configuration or the changes you have made to differentiate it from GENERIC. SunOS If you have built a kernel under SunOS or some other BSD operating system, much of this file will be very familiar to you. If you are coming from some other operating system such as DOS, on the other hand, the GENERIC configuration file might seem overwhelming to you, so follow the descriptions in the Configuration File section slowly and carefully. Be sure to always check the file /usr/src/UPDATING, before you perform any update steps, in the case you sync your source-tree with the latest sources of the FreeBSD project. In this file all important issues with updating FreeBSD are written down. /usr/src/UPDATING always fits to your version of the FreeBSD source, and is therefore more accurate for those information than the handbook. You must now compile the source code for the kernel. There are two procedures you can use to do this, and the one you will use depends on why you are rebuilding the kernel, and the version of FreeBSD you are running. If you have installed only the kernel source code, use procedure 1. If you are running a FreeBSD version prior to 4.0, and you are not upgrading to FreeBSD 4.0 or higher using the make world procedure, use procedure 1. If you are building a new kernel without updating the source code (perhaps just to add a new option, such as IPFIREWALL) you can use either procedure. If you are rebuilding the kernel as part of a make world process, use procedure 2. Procedure 1. Building a kernel the <quote>traditional</quote> way Run &man.config.8; to generate the kernel source code. &prompt.root; /usr/sbin/config MYKERNEL Change in to the build directory. &prompt.root; cd ../../compile/MYKERNEL Compile the kernel. &prompt.root; make depend &prompt.root; make Install the new kernel. &prompt.root; make install Procedure 2. Building a kernel the <quote>new</quote> way Change to the /usr/src directory &prompt.root; cd /usr/src Compile the kernel. &prompt.root; make buildkernel KERNCONF=MYKERNEL Install the new kernel. &prompt.root; make installkernel KERNCONF=MYKERNEL In FreeBSD 4.2 and older you must replace KERNCONF= with KERNEL=. 4.2-STABLE that was fetched after Feb 2nd, 2001 does recognize KERNCONF= cvsup anonymous CVS CTM CVS anonymous If you have not upgraded your source tree in any way (you have not run CVSup, CTM, or used anoncvs), then you should use the config, make depend, make, make install sequence. kernel.old The new kernel will be copied to the root directory as /kernel and the old kernel will be moved to /kernel.old. Now, shutdown the system and reboot to use your kernel. In case something goes wrong, there are some troubleshooting instructions at the end of this document. Be sure to read the section which explains how to recover in case your new kernel does not boot. If you have added any new devices (such as sound cards) you may have to add some device nodes to your /dev directory before you can use them. The Configuration File kernel LINT LINT kernel config file The general format of a configuration file is quite simple. Each line contains a keyword and one or more arguments. For simplicity, most lines only contain one argument. Anything following a # is considered a comment and ignored. The following sections describe each keyword, generally in the order they are listed in GENERIC, although some related keywords have been grouped together in a single section (such as Networking) even though they are actually scattered throughout the GENERIC file. An exhaustive list of options and more detailed explanations of the device lines is present in the LINT configuration file, located in the same directory as GENERIC. If you are in doubt as to the purpose or necessity of a line, check first in LINT. Quoting numbers In all versions of FreeBSD up to and including 3.X, &man.config.8; required that any strings in the configuration file that contained numbers used as text had to be enclosed in double quotes. This requirement was removed in the 4.X branch, which this book covers, so if you are on a pre-4.X system, see the /usr/src/sys/i386/conf/LINT and /usr/src/sys/i386/conf/GENERIC files on your system for examples. kernel example config file The following is an example GENERIC kernel configuration file with various additional comments where needed for clarity. This example should match your copy in /usr/src/sys/i386/conf/GENERIC fairly closely. For details of all the possible kernel options, see /usr/src/sys/i386/conf/LINT. # # GENERIC -- Generic kernel configuration file for FreeBSD/i386 # # For more information on this file, please read the handbook section on # Kernel Configuration Files: # # http://www.freebsd.org/handbook/kernelconfig-config.html # # The handbook is also available locally in /usr/share/doc/handbook # if you've installed the doc distribution, otherwise always see the # FreeBSD World Wide Web server (http://www.FreeBSD.ORG/) for the # latest information. # # An exhaustive list of options and more detailed explanations of the # device lines is also present in the ./LINT configuration file. If you are # in doubt as to the purpose or necessity of a line, check first in LINT. # # $FreeBSD: src/sys/i386/conf/GENERIC,v 1.246 2000/03/09 16:32:55 jlemon Exp $ The following are the mandatory keywords required in every kernel you build: kernel options machine machine i386 This is the machine architecture. It must be either i386, alpha, or pc98. kernel options cpu cpu I386_CPU cpu I486_CPU cpu I586_CPU cpu I686_CPU The above specifies the type of CPU you have in your system. You may have multiple instances of the CPU line (i.e., you are not sure whether you should use I586_CPU or I686_CPU), however, for a custom kernel, it is best to specify only the CPU you have. If you are unsure of your CPU type, you can use the dmesg command to view your boot up messages. kernel options cpu type The Alpha architecture has different values for cpu_type. They include: cpu EV4 cpu EV5 If you are using an Alpha machine, you should be using one of the above CPU types. kernel options ident ident GENERIC This is the identification of the kernel. You should change this to whatever you named your kernel, in our previous example, MYKERNEL. The value you put in the ident string will print when you boot up the kernel, so it is useful to give a kernel a different name if you want to keep it separate from your usual kernel (i.e., you want to build an experimental kernel). kernel options maxusers maxusers 32 The maxusers option sets the size of a number of important system tables. This number is supposed to be roughly equal to the number of simultaneous users you expect to have on your machine. However, under normal circumstances, you will want to set maxusers to at least 4, especially if you are using the X Window System or compiling software. The reason is that the most important table set by maxusers is the maximum number of processes, which is set to 20 + 16 * maxusers, so if you set maxusers to 1, then you can only have 36 simultaneous processes, including the 18 or so that the system starts up at boot time, and the 15 or so you will probably create when you start the X Window System. Even a simple task like reading a manual page will start up nine processes to filter, decompress, and view it. Setting maxusers to 64 will allow you to have up to 1044 simultaneous processes, which should be enough for nearly all uses. If, however, you see the dreaded proc table full error when trying to start another program, or are running a server with a large number of simultaneous users (like ftp.FreeBSD.org), you can always increase the number and rebuild. maxusers does not limit the number of users which can log into your machine. It simply sets various table sizes to reasonable values considering the maximum number of users you will likely have on your system and how many processes each of them will be running. One keyword which does limit the number of simultaneous remote logins is pseudo-device pty 16. Everything that follows is more or less optional. See the notes underneath or next to each option for more information. #makeoptions DEBUG=-g #Build kernel with gdb(1) debug symbols options MATH_EMULATE #Support for x87 emulation This line allows the kernel to simulate a math co-processor if your computer does not have one (386 or 486SX). If you have a 486DX, or a 386 or 486SX (with a separate 387 or 487 chip), or higher (Pentium, Pentium II, etc.), you can comment this line out. The normal math co-processor emulation routines that come with FreeBSD are not very accurate. If you do not have a math co-processor, and you need the best accuracy, it is recommended that you change this option to GPL_MATH_EMULATION to use the GNU math support, which is not included by default for licensing reasons. options INET #InterNETworking Networking support. Leave this in, even if you do not plan to be connected to a network. Most programs require at least loopback networking (i.e., making network connections within your PC), so this is essentially mandatory. options INET6 #IPv6 communications protocols This enables the IPv6 communication protocols. options FFS #Berkeley Fast Filesystem options FFS_ROOT #FFS usable as root device [keep this!] This is the basic hard drive filesystem. Leave it in if you boot from the hard disk. options MFS #Memory Filesystem options MD_ROOT #MD is a potential root device This is the memory-mapped filesystem. This is basically a RAM disk for fast storage of temporary files, useful if you have a lot of swap space that you want to take advantage of. A perfect place to mount an MFS partition is on the /tmp directory, since many programs store temporary data here. To mount an MFS RAM disk on /tmp, add the following line to /etc/fstab: /dev/ad1s2b /tmp mfs rw 0 0 Now you simply need to either reboot, or run the command mount /tmp. kernel options NFS kernel options NFS_ROOT options NFS #Network Filesystem options NFS_ROOT #NFS usable as root device, NFS required The network filesystem. Unless you plan to mount partitions from a Unix file server over TCP/IP, you can comment these out. kernel options MSDOSFS options MSDOSFS #MSDOS Filesystem The MS-DOS filesystem. Unless you plan to mount a DOS formatted hard drive partition at boot time, you can safely comment this out. It will be automatically loaded the first time you mount a DOS partition, as described above. Also, the excellent mtools software (in the ports collection) allows you to access DOS floppies without having to mount and unmount them (and does not require MSDOSFS at all). options CD9660 #ISO 9660 Filesystem options CD9660_ROOT #CD-ROM usable as root, CD9660 required The ISO 9660 filesystem for CDROMs. Comment it out if you do not have a CDROM drive or only mount data CDs occasionally (since it will be dynamically loaded the first time you mount a data CD). Audio CDs do not need this filesystem. options PROCFS #Process filesystem The process filesystem. This is a pretend filesystem mounted on /proc which allows programs like &man.ps.1; to give you more information on what processes are running. options COMPAT_43 #Compatible with BSD 4.3 [KEEP THIS!] Compatibility with 4.3BSD. Leave this in; some programs will act strangely if you comment this out. options SCSI_DELAY=15000 #Delay (in ms) before probing SCSI This causes the kernel to pause for 15 seconds before probing each SCSI device in your system. If you only have IDE hard drives, you can ignore this, otherwise you will probably want to lower this number, perhaps to 5 seconds, to speed up booting. Of course, if you do this, and FreeBSD has trouble recognizing your SCSI devices, you will have to raise it back up. options UCONSOLE #Allow users to grab the console Allow users to grab the console, which is useful for X users. For example, you can create a console xterm by typing xterm -C, which will display any write, talk, and any other messages you receive, as well as any console messages sent by the kernel. options USERCONFIG #boot -c editor This option allows you to boot the configuration editor from the boot menu. options VISUAL_USERCONFIG #visual boot -c editor This option allows you to boot the visual configuration editor from the boot menu. options KTRACE #ktrace(1) support This enables kernel process tracing, which is useful in debugging. options SYSVSHM #SYSV-style shared memory This option provides for System V shared memory. The most common use of this is the XSHM extension in X, which many graphics-intensive programs will automatically take advantage of for - extra speed. If you use X, you'll definitely want to include + extra speed. If you use X, you will definitely want to include this. options SYSVSEM #SYSV-style semaphores Support for System V semaphores. Less commonly used but only adds a few hundred bytes to the kernel. options SYSVMSG #SYSV-style message queues Support for System V messages. Again, only adds a few hundred bytes to the kernel. The &man.ipcs.1; command will list any processes using each of these System V facilities. options P1003_1B #Posix P1003_1B real-time extensions options _KPOSIX_PRIORITY_SCHEDULING Real-time extensions added in the 1993 POSIX. Certain applications in the ports collection use these (such as Star Office). kernel options ICMP_BANDLIM options ICMP_BANDLIM #Rate limit bad replies This option enables ICMP error response bandwidth limiting. You typically want this option as it will help protect the machine from denial of service packet attacks. kernel options SMP # To make an SMP kernel, the next two are needed #options SMP # Symmetric MultiProcessor Kernel #options APIC_IO # Symmetric (APIC) I/O The above are both required for SMP support. device isa All PCs supported by FreeBSD have one of these. If you have an IBM PS/2 (Micro Channel Architecture), you cannot run FreeBSD at this time (support is being worked on). device eisa Include this if you have an EISA motherboard. This enables auto-detection and configuration support for all devices on the EISA bus. device pci Include this if you have a PCI motherboard. This enables auto-detection of PCI cards and gatewaying from the PCI to ISA bus. # Floppy drives device fdc0 at isa? port IO_FD1 irq 6 drq 2 device fd0 at fdc0 drive 0 device fd1 at fdc0 drive 1 This is the floppy drive controller. fd0 is the A: floppy drive, and fd1 is the B: drive. device ata This driver supports all ATA and ATAPI devices. You only need one device ata line for the kernel to detect all PCI ATA/ATAPI devices on modern machines. device atadisk # ATA disk drives This is needed along with device ata for ATAPI disk drives. device atapicd # ATAPI CDROM drives This is needed along with device ata for ATAPI CDROM drives. device atapifd # ATAPI floppy drives This is needed along with device ata for ATAPI floppy drives. device atapist # ATAPI tape drives This is needed along with device ata for ATAPI tape drives. options ATA_STATIC_ID #Static device numbering This makes the controller number static (like the old driver) or else the device numbers are dynamically allocated. # ATA and ATAPI devices device ata0 at isa? port IO_WD1 irq 14 device ata1 at isa? port IO_WD2 irq 15 Use the above for older, non-PCI systems. # SCSI Controllers device ahb # EISA AHA1742 family device ahc # AHA2940 and onboard AIC7xxx devices device amd # AMD 53C974 (Teckram DC-390(T)) device dpt # DPT Smartcache - See LINT for options! device isp # Qlogic family device ncr # NCR/Symbios Logic device sym # NCR/Symbios Logic (newer chipsets) device adv0 at isa? device adw device bt0 at isa? device aha0 at isa? device aic0 at isa? SCSI controllers. Comment out any you do not have in your system. If you have an IDE only system, you can remove these altogether. # SCSI peripherals device scbus # SCSI bus (required) device da # Direct Access (disks) device sa # Sequential Access (tape etc) device cd # CD device pass # Passthrough device (direct SCSI access) SCSI peripherals. Again, comment out any you do not have, or if you have only IDE hardware, you can remove them completely. # RAID controllers device ida # Compaq Smart RAID device amr # AMI MegaRAID device mlx # Mylex DAC960 family Supported RAID controllers. If you do not have any of these, you can comment them out or remove them. # atkbdc0 controls both the keyboard and the PS/2 mouse device atkbdc0 at isa? port IO_KBD The keyboard controller (atkbdc) provides I/O services for the AT keyboard and PS/2 style pointing devices. This controller is required by the keyboard driver (atkbd) and the PS/2 pointing device driver (psm). device atkbd0 at atkbdc? irq 1 The atkbd driver, together with atkbdc controller, provides access to the AT 84 keyboard or the AT enhanced keyboard which is connected to the AT keyboard controller. device psm0 at atkbdc? irq 12 Use this device if your mouse plugs into the PS/2 mouse port. device vga0 at isa? The video card driver. # splash screen/screen saver pseudo-device splash Splash screen at start up! Screen savers require this too. # syscons is the default console driver, resembling an SCO console device sc0 at isa? sc0 is the default console driver, which resembles a SCO console. Since most full-screen programs access the console through a terminal database library like termcap, it should not matter whether you use this or vt0, the VT220 compatible console driver. When you log in, set your TERM variable to scoansi if full-screen programs have trouble running under this console. # Enable this and PCVT_FREEBSD for pcvt vt220 compatible console driver #device vt0 at isa? #options XSERVER # support for X server on a vt console #options FAT_CURSOR # start with block cursor # If you have a ThinkPAD, uncomment this along with the rest of the PCVT lines #options PCVT_SCANSET=2 # IBM keyboards are non-std This is a VT220-compatible console driver, backward compatible to VT100/102. It works well on some laptops which have hardware incompatibilities with sc0. Also set your TERM variable to vt100 or vt220 when you log in. This driver might also prove useful when connecting to a large number of different machines over the network, where termcap or terminfo entries for the sc0 device are often not available — vt100 should be available on virtually any platform. # Floating point support - do not disable. device npx0 at nexus? port IO_NPX irq 13 npx0 is the interface to the floating point math unit in FreeBSD, which is either the hardware co-processor or the software math emulator. This is not optional. # Power management support (see LINT for more options) device apm0 at nexus? disable flags 0x20 # Advanced Power Management Advanced Power Management support. Useful for laptops. # PCCARD (PCMCIA) support device card device pcic0 at isa? irq 10 port 0x3e0 iomem 0xd0000 device pcic1 at isa? irq 11 port 0x3e2 iomem 0xd4000 disable PCMCIA support. You need this if you are installing on a laptop. # Serial (COM) ports device sio0 at isa? port IO_COM1 flags 0x10 irq 4 device sio1 at isa? port IO_COM2 irq 3 device sio2 at isa? disable port IO_COM3 irq 5 device sio3 at isa? disable port IO_COM4 irq 9 These are the four serial ports referred to as COM1 through COM4 in the MS-DOS/Windows world. If you have an internal modem on COM4 and a serial port at COM2, you will have to change the IRQ of the modem to 2 (for obscure technical reasons, IRQ2 = IRQ 9) in order to access it from FreeBSD. If you have a multiport serial card, check the manual page for &man.sio.4; for more information on the proper values for these lines. Some video cards (notably those based on S3 chips) use IO addresses in the form of 0x*2e8, and since many cheap serial cards do not fully decode the 16-bit IO address space, they clash with these cards making the COM4 port practically unavailable. Each serial port is required to have a unique IRQ (unless you are using one of the multiport cards where shared interrupts are supported), so the default IRQs for COM3 and COM4 cannot be used. # Parallel port device ppc0 at isa? irq 7 This is the ISA-bus parallel port interface. device ppbus # Parallel port bus (required) Provides support for the parallel port bus. device lpt # Printer Support for parallel port printers. All three of the above are required to enable parallel printer support. device plip # TCP/IP over parallel This is the driver for the parallel network interface. device ppi # Parallel port interface device The general-purpose I/O (geek port) + IEEE1284 I/O. #device vpo # Requires scbus and da zip drive This is for an Iomega Zip drive. It requires scbus and da support. Best performance is achieved with ports in EPP 1.9 mode. # PCI Ethernet NICs. device de # DEC/Intel DC21x4x (Tulip) device fxp # Intel EtherExpress PRO/100B (82557, 82558) device tx # SMC 9432TX (83c170 EPIC) device vx # 3Com 3c590, 3c595 (Vortex) device wx # Intel Gigabit Ethernet Card (Wiseman) Various PCI network card drivers. Comment out or remove any of these not present in your system. # PCI Ethernet NICs that use the common MII bus controller code. device miibus # MII bus support MII bus support is required for some PCI 10/100 Ethernet NICs, namely those which use MII-compliant transceivers or implement transceiver control interfaces that operate like an MII. Adding device miibus to the kernel config pulls in support for the generic miibus API and all of the PHY drivers, including a generic one for PHYs that are not specifically handled by an individual driver device dc # DEC/Intel 21143 and various workalikes device rl # RealTek 8129/8139 device sf # Adaptec AIC-6915 (Starfire) device sis # Silicon Integrated Systems SiS 900/SiS 7016 device ste # Sundance ST201 (D-Link DFE-550TX) device tl # Texas Instruments ThunderLAN device vr # VIA Rhine, Rhine II device wb # Winbond W89C840F device xl # 3Com 3c90x (Boomerang, Cyclone) Drivers that use the MII bus controller code. # ISA Ethernet NICs. device ed0 at isa? port 0x280 irq 10 iomem 0xd8000 device ex device ep # WaveLAN/IEEE 802.11 wireless NICs. Note: the WaveLAN/IEEE really # exists only as a PCMCIA device, so there is no ISA attachment needed # and resources will always be dynamically assigned by the pccard code. device wi # Aironet 4500/4800 802.11 wireless NICs. Note: the declaration below will # work for PCMCIA and PCI cards, as well as ISA cards set to ISA PnP # mode (the factory default). If you set the switches on your ISA # card for a manually chosen I/O address and IRQ, you must specify # those parameters here. device an # The probe order of these is presently determined by i386/isa/isa_compat.c. device ie0 at isa? port 0x300 irq 10 iomem 0xd0000 device fe0 at isa? port 0x300 device le0 at isa? port 0x300 irq 5 iomem 0xd0000 device lnc0 at isa? port 0x280 irq 10 drq 0 device cs0 at isa? port 0x300 device sn0 at isa? port 0x300 irq 10 # requires PCCARD (PCMCIA) support to be activated #device xe0 at isa? ISA Ethernet drivers. See /usr/src/sys/i386/conf/LINT for which cards are supported by which driver. # Pseudo devices - the number indicates how many units to allocate. pseudo-device loop # Network loopback This is the generic loopback device for TCP/IP. If you telnet or FTP to localhost (a.k.a., 127.0.0.1) it will come back at you through this pseudo-device. This is mandatory. pseudo-device ether # Ethernet support ether is only needed if you have an Ethernet card. It includes generic Ethernet protocol code. pseudo-device sl 1 # Kernel SLIP sl is for SLIP support. This has been almost entirely supplanted by PPP, which is easier to set up, better suited for modem-to-modem connection, and more powerful. The number after sl specifies how many simultaneous SLIP sessions to support. pseudo-device ppp 1 # Kernel PPP This is for kernel PPP support for dial-up connections. There is also a version of PPP implemented as a userland application that uses tun and offers more flexibility and features such as demand dialing. The number after ppp specifies how many simultaneous PPP connections to support. pseudo-device tun # Packet tunnel. This is used by the userland PPP software. A number after tun specifies the number of simultaneous PPP sessions to support. See the PPP section of this book for more information. pseudo-device pty # Pseudo-ttys (telnet etc) This is a pseudo-terminal or simulated login port. It is used by incoming telnet and rlogin sessions, xterm, and some other applications such as emacs. A number after pty indicates the number of ptys to create. If you need more than the default of 16 simultaneous xterm windows and/or remote logins, be sure to increase this number accordingly, up to a maximum of 256. pseudo-device md # Memory disks Memory disk pseudo-devices. pseudo-device gif 4 # IPv6 and IPv4 tunneling This implements IPv6 over IPv4 tunneling, IPv4 over IPv6 tunneling, IPv4 over IPv4 tunneling, and IPv6 over IPv6 tunneling. pseudo-device faith 1 # IPv6-to-IPv4 relaying (translation) This pseudo-device captures packets that are sent to it and diverts them to the IPv4/IPv6 translation daemon. # The `bpf' pseudo-device enables the Berkeley Packet Filter. # Be aware of the administrative consequences of enabling this! pseudo-device bpf # Berkeley packet filter This is the Berkeley Packet Filter. This pseudo-device allows network interfaces to be placed in promiscuous mode, capturing every packet on a broadcast network (e.g., an Ethernet). These packets can be captured to disk and or examined with the &man.tcpdump.1; program. The bpf pseudo-device is also used by &man.dhclient.8; to obtain the IP address of the default router (gateway) and so on. If you use DHCP, leave this uncommented. # USB support #device uhci # UHCI PCI->USB interface #device ohci # OHCI PCI->USB interface #device usb # USB Bus (required) #device ugen # Generic #device uhid # Human Interface Devices #device ukbd # Keyboard #device ulpt # Printer #device umass # Disks/Mass storage - Requires scbus and da #device ums # Mouse # USB Ethernet, requires mii #device aue # ADMtek USB ethernet #device cue # CATC USB ethernet #device kue # Kawasaki LSI USB ethernet Support for various USB devices. For more information and additional devices supported by FreeBSD, see /usr/src/sys/i386/conf/LINT. Making Device Nodes device nodes MAKEDEV Almost every device in the kernel has a corresponding node entry in the /dev directory. These nodes look like regular files, but are actually special entries into the kernel which programs use to access the device. The shell script /dev/MAKEDEV, which is executed when you first install the operating system, creates nearly all of the device nodes supported. However, it does not create all of them, so when you add support for a new device, it pays to make sure that the appropriate entries are in this directory, and if not, add them. Here is a simple example: Suppose you add the IDE CD-ROM support to the kernel. The line to add is: device acd0 This means that you should look for some entries that start with acd0 in the /dev directory, possibly followed by a letter, such as c, or preceded by the letter r, which means a raw device. It turns out that those files are not there, so you must change to the /dev directory and type: MAKEDEV &prompt.root; sh MAKEDEV acd0 When this script finishes, you will find that there are now acd0c and racd0c entries in /dev so you know that it executed correctly. For sound cards, the following command creates the appropriate entries: &prompt.root; sh MAKEDEV snd0 When creating device nodes for devices such as sound cards, if other people have access to your machine, it may be desirable to protect the devices from outside access by adding them to the /etc/fbtab file. See &man.fbtab.5; for more information. Follow this simple procedure for any other non-GENERIC devices which do not have entries. All SCSI controllers use the same set of /dev entries, so you do not need to create these. Also, network cards and SLIP/PPP pseudo-devices do not have entries in /dev at all, so you do not have to worry about these either. If Something Goes Wrong There are four categories of trouble that can occur when building a custom kernel. They are: config fails If the config command fails when you give it your kernel description, you have probably made a simple error somewhere. Fortunately, config will print the line number that it had trouble with, so you can quickly skip to it with vi. For example, if you see: config: line 17: syntax error You can skip to the problem in vi by typing 17G in command mode. Make sure the keyword is typed correctly, by comparing it to the GENERIC kernel or another reference. make fails If the make command fails, it usually signals an error in your kernel description, but not severe enough for config to catch it. Again, look over your configuration, and if you still cannot resolve the problem, send mail to the &a.questions; with your kernel configuration, and it should be diagnosed very quickly. The kernel will not boot If your new kernel does not boot, or fails to recognize your devices, do not panic! Fortunately, BSD has an excellent mechanism for recovering from incompatible kernels. Simply choose the kernel you want to boot from at the FreeBSD boot loader (i.e., boot kernel.old). When reconfiguring a kernel, it is always a good idea to keep a kernel that is known to work on hand. After booting with a good kernel you can check over your configuration file and try to build it again. One helpful resource is the /var/log/messages file which records, among other things, all of the kernel messages from every successful boot. Also, the &man.dmesg.8; command will print the kernel messages from the current boot. If you are having trouble building a kernel, make sure to keep a GENERIC, or some other kernel that is known to work on hand as a different name that will not get erased on the next build. You cannot rely on kernel.old because when installing a new kernel, kernel.old is overwritten with the last installed kernel which may be non-functional. Also, as soon as possible, move the working kernel to the proper kernel location or commands such as &man.ps.1; will not work properly. The proper command to unlock the kernel file that make installs (in order to move another kernel back permanently) is: &prompt.root; chflags noschg /kernel If you find you cannot do this, you are probably running at a &man.securelevel.8; greater than zero. Edit kern_securelevel in /etc/rc.conf and set it to -1, then reboot. You can change it back to its previous setting when you are happy with your new kernel. And, if you want to lock your new kernel into place, or any file for that matter, so that it cannot be moved or tampered with: &prompt.root; chflags schg /kernel The kernel works, but ps does not work any more! If you have installed a different version of the kernel from the one that the system utilities have been built with, for example, a 4.X kernel on a 3.X system, many system-status commands like &man.ps.1; and &man.vmstat.8; will not work any more. You must recompile the libkvm library as well as these utilities. This is one reason it is not normally a good idea to use a different version of the kernel from the rest of the operating system. diff --git a/en_US.ISO8859-1/books/handbook/kernelopts/chapter.sgml b/en_US.ISO8859-1/books/handbook/kernelopts/chapter.sgml index c1cb46746a..1e3df5452d 100644 --- a/en_US.ISO8859-1/books/handbook/kernelopts/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/kernelopts/chapter.sgml @@ -1,168 +1,168 @@ Jörg Wunsch Contributed by Adding New Kernel Configuration Options You should be familiar with the section about kernel configuration before reading here. What's a <emphasis>Kernel Option</emphasis>, Anyway? The use of kernel options is basically described in the kernel configuration section. There's also an explanation of historic and new-style options. The ultimate goal is to eventually turn all the supported options in the kernel into new-style ones, so for people who correctly did a make depend in their kernel compile directory after running &man.config.8;, the build process will automatically pick up modified options, and only recompile those files where it is necessary. Wiping out the old compile directory on each run of &man.config.8; as it is still done now can then be eliminated again. Basically, a kernel option is nothing else than the definition of a C preprocessor macro for the kernel compilation process. To make the build truly optional, the corresponding part of the kernel source (or kernel .h file) must be written with the option concept in mind, i.e., the default can be overridden by the config option. This is usually done with something like: #ifndef THIS_OPTION #define THIS_OPTION (some_default_value) #endif /* THIS_OPTION */ This way, an administrator mentioning another value for the option in his config file will take the default out of effect, and replace it with his new value. Clearly, the new value will be substituted into the source code during the preprocessor run, so it must be a valid C expression in whatever context the default value would have been used. It is also possible to create value-less options that simply enable or disable a particular piece of code by embracing it in #ifdef THAT_OPTION [your code here] #endif Simply mentioning THAT_OPTION in the config file (with or without any value) will then turn on the corresponding piece of code. People familiar with the C language will immediately recognize that everything could be counted as a config option where there is at least a single #ifdef referencing it... - However, it's unlikely that many people would put + However, it is unlikely that many people would put options notyet,notdef in their config file, and then wonder why the kernel compilation falls over. Clearly, using arbitrary names for the options makes it very hard to track their usage throughout the kernel source tree. That is the rationale behind the new-style option scheme, where each option goes into a separate .h file in the kernel compile directory, which is by convention named opt_foo.h. This way, the usual Makefile dependencies could be applied, and make can determine what needs to be recompiled once an option has been changed. The old-style option mechanism still has one advantage for local options or maybe experimental options that have a short anticipated lifetime: since it is easy to add a new #ifdef to the kernel source, this has already made it a kernel config option. In this case, the administrator using such an option is responsible himself for knowing about its implications (and maybe manually forcing the recompilation of parts of his kernel). Once the transition of all supported options has been done, &man.config.8; will warn whenever an unsupported option appears in the config file, but it will nevertheless include it into the kernel Makefile. Now What Do I Have to Do for It? First, edit sys/conf/options (or sys/<arch>/conf/options.<arch>, e. g. sys/i386/conf/options.i386), and select an opt_foo.h file where your new option would best go into. If there is already something that comes close to the purpose of the new option, pick this. For example, options modifying the overall behavior of the SCSI subsystem can go into opt_scsi.h. By default, simply mentioning an option in the appropriate option file, say FOO, implies its value will go into the corresponding file opt_foo.h. This can be overridden on the right-hand side of a rule by specifying another filename. If there is no opt_foo.h already available for the intended new option, invent a new name. Make it meaningful, and comment the new section in the options[.<arch>] file. &man.config.8; will automagically pick up the change, and create that file next time it is run. Most options should go in a header file by themselves.. Packing too many options into a single opt_foo.h will cause too many kernel files to be rebuilt when one of the options has been changed in the config file. Finally, find out which kernel files depend on the new option. Unless you have just invented your option, and it does not exist anywhere yet, &prompt.user; find /usr/src/sys -type f | xargs fgrep NEW_OPTION is your friend in finding them. Go and edit all those files, and add #include "opt_foo.h" on top before all the #include <xxx.h> stuff. This sequence is most important as the options could override defaults from the regular include files, if the defaults are of the form #ifndef NEW_OPTION #define NEW_OPTION (something) #endif in the regular header. Adding an option that overrides something in a system header file (i.e., a file sitting in /usr/include/sys/) is almost always a mistake. opt_foo.h cannot be included into those files since it would break the headers more seriously, but if it is not included, then places that include it may get an inconsistent value for the option. Yes, there are precedents for this right now, but that does not make them more correct. diff --git a/en_US.ISO8859-1/books/handbook/linuxemu/chapter.sgml b/en_US.ISO8859-1/books/handbook/linuxemu/chapter.sgml index 57f6b37341..e5946af2ef 100644 --- a/en_US.ISO8859-1/books/handbook/linuxemu/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/linuxemu/chapter.sgml @@ -1,2344 +1,2344 @@ Jim Mock Restructured and parts updated by Brian N. Handy Originally contributed by Rich Murphey Linux Binary Compatibility Synopsis Linux binary compatibility binary compatibility Linux FreeBSD provides binary compatibility with several other Unix-like operating systems, including Linux. At this point, you may be asking yourself why exactly, does FreeBSD need to be able to run Linux binaries? The answer to that question is quite simple. Many companies and developers develop only for Linux, since it is the latest hot thing in the computing world. That leaves the rest of us FreeBSD users bugging these same companies and developers to put out native FreeBSD versions of their applications. The problem is, that most of these companies do not really realize how many people would use their product if there were FreeBSD versions too, and most continue to only develop for Linux. So what is a FreeBSD user to do? This is where the Linux binary compatibility of FreeBSD comes into play. In a nutshell, the compatibility allows FreeBSD users to run about 90% of all Linux applications without modification. This includes applications such as Star Office, the Linux version of Netscape, Adobe Acrobat, RealPlayer 5 and 7, VMWare, Oracle, WordPerfect, Doom, Quake, and more. It is also reported that in some situations, Linux binaries perform better on FreeBSD than they do under Linux. Linux /proc filesystem There are, however, some Linux-specific operating system features that are not supported under FreeBSD. Linux binaries will not work on FreeBSD if they overly use the Linux /proc filesystem (which is different from FreeBSD's /proc filesystem), or i386-specific calls, such as enabling virtual 8086 mode. After reading this chapter you will know: How to enable Linux binary compatibility on your system. How to install additional Linux shared libraries. How to install Linux applications on your FreeBSD system. The implementation details of Linux compatibility in FreeBSD. Before reading this chapter you should: Know how to install additional third-party software () Installation KLD (kernel loadable object) Linux binary compatibility is not turned on by default. The easiest way to enable this functionality is to load the linux KLD object (Kernel LoaDable object). You can load this module by simply typing linux at the command prompt. If you would like Linux compatibility to always be enabled, then you should add the following line to /etc/rc.conf: linux_enable=YES This, in turn, triggers the following action in /etc/rc.i386: # Start the Linux binary compatibility if requested. # case ${linux_enable} in [Yy][Ee][Ss]) echo -n ' linux'; linux > /dev/null 2>&1 ;; esac The &man.kldstat.8; command can be used to verify that the KLD is loaded: &prompt.user; kldstat Id Refs Address Size Name 1 2 0xc0100000 16bdb8 kernel 7 1 0xc24db000 d000 linux.ko kernel options LINUX If for some reason you do not want to or cannot load the KLD, then you may statically link Linux binary compatibility into the kernel by adding options LINUX to your kernel configuration file. Then install your new kernel as described in . Installing Linux Runtime Libraries Linux installing Linux libraries This can be done one of two ways, either by using the linux_base port, or by installing them manually. Installing Using the linux_base Port ports collection This is by far the easiest method to use when installing the runtime libraries. It is just like installing any other port from the ports collection. Simply do the following: &prompt.root; cd /usr/ports/emulators/linux_base &prompt.root; make install distclean You should now have working Linux binary compatibility. Some programs may complain about incorrect minor versions of the system libraries. In general, however, this does not seem to be a problem. Installing Libraries Manually If you do not have the ports collection installed, you can install the libraries by hand instead. You will need the Linux shared libraries that the program depends on and the runtime linker. Also, you will need to create a shadow root directory, /compat/linux, for Linux libraries on your FreeBSD system. Any shared libraries opened by Linux programs run under FreeBSD will look in this tree first. So, if a Linux program loads, for example, /lib/libc.so, FreeBSD will first try to open /compat/linux/lib/libc.so, and if that does not exist, it will then try /lib/libc.so. Shared libraries should be installed in the shadow tree /compat/linux/lib rather than the paths that the Linux ld.so reports. Generally, you will need to look for the shared libraries that Linux binaries depend on only the first few times that you install a Linux program on your FreeBSD system. After a while, you will have a sufficient set of Linux shared libraries on your system to be able to run newly imported Linux binaries without any extra work. How to Install Additional Shared Libraries shared libraries What if you install the linux_base port and your application still complains about missing shared libraries? How do you know which shared libraries Linux binaries need, and where to get them? Basically, there are 2 possibilities (when following these instructions you will need to be root on your FreeBSD system). If you have access to a Linux system, see what shared libraries the application needs, and copy them to your FreeBSD system. Look at the following example: Let us assume you used FTP to get the Linux binary of Doom, and put it on a Linux system you have access to. You then can check which shared libraries it needs by running ldd linuxdoom, like so: &prompt.user; ldd linuxdoom libXt.so.3 (DLL Jump 3.1) => /usr/X11/lib/libXt.so.3.1.0 libX11.so.3 (DLL Jump 3.1) => /usr/X11/lib/libX11.so.3.1.0 libc.so.4 (DLL Jump 4.5pl26) => /lib/libc.so.4.6.29 symbolic links You would need to get all the files from the last column, and put them under /compat/linux, with the names in the first column as symbolic links pointing to them. This means you eventually have these files on your FreeBSD system: /compat/linux/usr/X11/lib/libXt.so.3.1.0 /compat/linux/usr/X11/lib/libXt.so.3 -> libXt.so.3.1.0 /compat/linux/usr/X11/lib/libX11.so.3.1.0 /compat/linux/usr/X11/lib/libX11.so.3 -> libX11.so.3.1.0 /compat/linux/lib/libc.so.4.6.29 /compat/linux/lib/libc.so.4 -> libc.so.4.6.29
Note that if you already have a Linux shared library with a matching major revision number to the first column of the ldd output, you will not need to copy the file named in the last column to your system, the one you already have should work. It is advisable to copy the shared library anyway if it is a newer version, though. You can remove the old one, as long as you make the symbolic link point to the new one. So, if you have these libraries on your system: /compat/linux/lib/libc.so.4.6.27 /compat/linux/lib/libc.so.4 -> libc.so.4.6.27 and you find a new binary that claims to require a later version according to the output of ldd: libc.so.4 (DLL Jump 4.5pl26) -> libc.so.4.6.29 If it is only one or two versions out of date in the in the trailing digit then do not worry about copying /lib/libc.so.4.6.29 too, because the program should work fine with the slightly older version. However, if you like, you can decide to replace the libc.so anyway, and that should leave you with: /compat/linux/lib/libc.so.4.6.29 /compat/linux/lib/libc.so.4 -> libc.so.4.6.29
The symbolic link mechanism is only needed for Linux binaries. The FreeBSD runtime linker takes care of looking for matching major revision numbers itself and you do not need to worry about it.
Installing Linux ELF Binaries Linux ELF binaries ELF binaries sometimes require an extra step of branding. If you attempt to run an unbranded ELF binary, you will get an error message like the following; &prompt.user; ./my-linux-elf-binary ELF binary type not known Abort To help the FreeBSD kernel distinguish between a FreeBSD ELF binary from a Linux binary, use the &man.brandelf.1; utility. &prompt.user; brandelf -t Linux my-linux-elf-binary GNU toolchain The GNU toolchain now places the appropriate branding information into ELF binaries automatically, so you this step should become increasingly more rare in the future. Configuring the Hostname Resolver If DNS does not work or you get this message: resolv+: "bind" is an invalid keyword resolv+: "hosts" is an invalid keyword You will need to configure a /compat/linux/etc/host.conf file containing: order hosts, bind multi on The order here specifies that /etc/hosts is searched first and DNS is searched second. When /compat/linux/etc/host.conf is not installed, Linux applications find FreeBSD's /etc/host.conf and complain about the incompatible FreeBSD syntax. You should remove bind if you have not configured a name server using the /etc/resolv.conf file.
Installing Mathematica Updated for Mathematica version 4.X by &a.murray and merged with work by Bojan Bistrovic bojanb@physics.odu.edu. applications Mathematica This document describes the process of installing the Linux version of Mathematica 4.X onto a FreeBSD system. The Linux version of Mathematica runs perfectly under FreeBSD however the binaries shipped by Wolfram need to be branded so that FreeBSD knows to use the Linux ABI to execute them. The Linux version of Mathematica or Mathematica for Students can be ordered directly from Wolfram at http://www.wolfram.com/. Branding the Linux Binaries The Linux binaries are located in the Unix directory of the Mathematica CDROM distributed by Wolfram. You need to copy this directory tree to your local hard drive so that you can brand the Linux binaries with &man.brandelf.1; before running the installer: &prompt.root; mount /cdrom &prompt.root; cp -rp /cdrom/Unix/ /localdir/ &prompt.root; brandelf -t Linux /localdir/Files/SystemFiles/Kernel/Binaries/Linux/* &prompt.root; brandelf -t Linux /localdir/Files/SystemFiles/FrontEnd/Binaries/Linux/* &prompt.root; brandelf -t Linux /localdir/Files/SystemFiles/Installation/Binaries/Linux/* &prompt.root; brandelf -t Linux /localdir/Files/SystemFiles/Graphics/Binaries/Linux/* &prompt.root; brandelf -t Linux /localdir/Files/SystemFiles/Converters/Binaries/Linux/* &prompt.root; brandelf -t Linux /localdir/Files/SystemFiles/LicenseManager/Binaries/Linux/mathlm &prompt.root; cd /localdir/Installers/Linux/ &prompt.root; ./MathInstaller Alternatively, you can simply set the default ELF brand to Linux for all unbranded binaries with the command: &prompt.root; sysctl -w kern.fallback_elf_brand=3 This will make FreeBSD assume that unbranded ELF binaries use the Linux ABI and so you should be able to run the installer straight from the CDROM. Obtaining Your Mathematica Password Before you can run Mathematica you will have to obtain a password from Wolfram that corresponds to your machine ID. Ethernet MAC address Once you have installed the Linux compatibility runtime libraries and unpacked Mathematica you can obtain the machine ID by running the program mathinfo in the Install directory. This machine ID is based solely on the MAC address of your first Ethernet card. &prompt.root; cd /localdir/Files/SystemFiles/Installation/Binaries/Linux &prompt.root; mathinfo disco.example.com 7115-70839-20412 When you register with Wolfram, either by email, phone or fax, you will give them the machine ID and they will respond with a corresponding password consisting of groups of numbers. You can then enter this information when you attempt to run Mathematica for the first time exactly as you would for any other Mathematica platform. Running the Mathematica Frontend over a Network Mathematica uses some special fonts to display characters not present in any of the standard font sets (integrals, sums, Greek letters, etc.). The X protocol requires these fonts to be install locally. This means you will have to copy these fonts from the CDROM or from a host with Mathematica installed to your local machine. These fonts are normally stored in /cdrom/Unix/Files/SystemFiles/Fonts on the CDROM, or /usr/local/mathematica/SystemFiles/Fonts on your hard drive. The actual fonts are in the subdirectories Type1 and X. There are several ways to use them, as described below. The first way is to copy them into one of the existing font directories in /usr/X11R6/lib/X11/fonts. This will require editing the fonts.dir file, adding the font names to it, and changing the number of fonts on the first line. Alternatively, you should also just be able to run mkfontdir in the directory you have copied them to. The second way to do this is to copy the directories to /usr/X11R6/lib/X11/fonts: &prompt.root; cd /usr/X11R6/lib/X11/fonts &prompt.root; mkdir X &prompt.root; mkdir MathType1 &prompt.root; cd /cdrom/Unix/Files/SystemFiles/Fonts &prompt.root; cp X/* /usr/X11R6/lib/X11/fonts/X &prompt.root; cp Type1/* /usr/X11R6/lib/X11/fonts/MathType1 &prompt.root; cd /usr/X11R6/lib/X11/fonts/X &prompt.root; mkfontdir &prompt.root; cd ../MathType1 &prompt.root; mkfontdir Now add the new font directories to your font path: &prompt.root; xset fp+ /usr/X11R6/lib/X11/fonts/X &prompt.root; xset fp+ /usr/X11R6/lib/X11/fonts/MathType1 &prompt.root; xset fp rehash If you are using the XFree86 server, you can have these font directories loaded automatically by adding them to your XF86Config file. fonts If you do not already have a directory called /usr/X11R6/lib/X11/fonts/Type1, you can change the name of the MathType1 directory in the example above to Type1. Marcel Moolenaar Contributed by Installing Oracle applications Oracle Preface This document describes the process of installing Oracle 8.0.5 and Oracle 8.0.5.1 Enterprise Edition for Linux onto a FreeBSD machine Installing the Linux Environment Make sure you have both linux_base and linux_devtools from the ports collection installed. These ports are added to the collection after the release of FreeBSD 3.2. If you are using FreeBSD 3.2 or an older version for that matter, update your ports collection. You may want to consider updating your FreeBSD version too. If you run into difficulties with linux_base-6.1 or linux_devtools-6.1 you may have to use version 5.2 of these packages. - If you want to run the intelligent agent, you'll + If you want to run the intelligent agent, you will also need to install the Red Hat Tcl package: tcl-8.0.3-20.i386.rpm. The general command for installing packages with the official RPM port is : &prompt.root; rpm -i --ignoreos --root /compat/linux --dbpath /var/lib/rpm package Installation of the package should not generate any errors. Creating the Oracle Environment Before you can install Oracle, you need to set up a proper environment. This document only describes what to do specially to run Oracle for Linux on FreeBSD, not what has been described in the Oracle installation guide. Kernel Tuning kernel tuning As described in the Oracle installation guide, you need to set - the maximum size of shared memory. Don't use + the maximum size of shared memory. Do not use SHMMAX under FreeBSD. SHMMAX is merely calculated out of SHMMAXPGS and PGSIZE. Therefore define SHMMAXPGS. All other options can be used as described in the guide. For example: options SHMMAXPGS=10000 options SHMMNI=100 options SHMSEG=10 options SEMMNS=200 options SEMMNI=70 options SEMMSL=61 Set these options to suit your intended use of Oracle. Also, make sure you have the following options in your kernel config-file: options SYSVSHM #SysV shared memory options SYSVSEM #SysV semaphores options SYSVMSG #SysV interprocess communication Oracle Account Create an Oracle account just as you would create any other account. The Oracle account is special only that you need to give it a Linux shell. Add /compat/linux/bin/bash to /etc/shells and set the shell for the Oracle account to /compat/linux/bin/bash. Environment Besides the normal Oracle variables, such as ORACLE_HOME and ORACLE_SID you must set the following environment variables: Variable Value LD_LIBRARY_PATH $ORACLE_HOME/lib CLASSPATH $ORACLE_HOME/jdbc/lib/classes111.zip PATH /compat/linux/bin /compat/linux/sbin /compat/linux/usr/bin /compat/linux/usr/sbin /bin /sbin /usr/bin /usr/sbin /usr/local/bin $ORACLE_HOME/bin It is advised to set all the environment variables in .profile. A complete example is: ORACLE_BASE=/oracle; export ORACLE_BASE ORACLE_HOME=/oracle; export ORACLE_HOME LD_LIBRARY_PATH=$ORACLE_HOME/lib export LD_LIBRARY_PATH ORACLE_SID=ORCL; export ORACLE_SID ORACLE_TERM=386x; export ORACLE_TERM CLASSPATH=$ORACLE_HOME/jdbc/lib/classes111.zip export CLASSPATH PATH=/compat/linux/bin:/compat/linux/sbin:/compat/linux/usr/bin:/compat/linux/usr/sbin:/bin:/sbin:/usr/bin:/usr/sbin:/usr/local/bin:$ORACLE_HOME/bin export PATH Installing Oracle Due to a slight inconsistency in the Linux emulator, you need to create a directory named .oracle in /var/tmp before you start the installer. Either make it world writable or let it be owner by the oracle user. You should be able to install Oracle without any problems. If you have problems, check your Oracle distribution and/or configuration first! After you have installed Oracle, apply the patches described in the next two subsections. A frequent problem is that the TCP protocol adapter is not installed right. As a consequence, you cannot start any TCP listeners. The following actions help solve this problem: &prompt.root; cd $ORACLE_HOME/network/lib &prompt.root; make -f ins_network.mk ntcontab.o &prompt.root; cd $ORACLE_HOME/lib &prompt.root; ar r libnetwork.a ntcontab.o &prompt.root; cd $ORACLE_HOME/network/lib &prompt.root; make -f ins_network.mk install - Don't forget to run root.sh again! + Do not forget to run root.sh again! Patching root.sh When installing Oracle, some actions, which need to be performed as root, are recorded in a shell script called root.sh. root.sh is written in the orainst directory. Apply the following patch to root.sh, to have it use to proper location of chown or alternatively run the script under a Linux native shell. *** orainst/root.sh.orig Tue Oct 6 21:57:33 1998 --- orainst/root.sh Mon Dec 28 15:58:53 1998 *************** *** 31,37 **** # This is the default value for CHOWN # It will redefined later in this script for those ports # which have it conditionally defined in ss_install.h ! CHOWN=/bin/chown # # Define variables to be used in this script --- 31,37 ---- # This is the default value for CHOWN # It will redefined later in this script for those ports # which have it conditionally defined in ss_install.h ! CHOWN=/usr/sbin/chown # # Define variables to be used in this script - When you don't install Oracle from CD, you can patch the source + When you do not install Oracle from CD, you can patch the source for root.sh. It is called rthd.sh and is located in the orainst directory in the source tree. Patching genclntsh The script genclntsh is used to create a single shared client library. It is used when building the demos. Apply the following patch to comment out the definition of PATH: *** bin/genclntsh.orig Wed Sep 30 07:37:19 1998 --- bin/genclntsh Tue Dec 22 15:36:49 1998 *************** *** 32,38 **** # # Explicit path to ensure that we're using the correct commands #PATH=/usr/bin:/usr/ccs/bin export PATH ! PATH=/usr/local/bin:/bin:/usr/bin:/usr/X11R6/bin export PATH # # each product MUST provide a $PRODUCT/admin/shrept.lst --- 32,38 ---- # # Explicit path to ensure that we're using the correct commands #PATH=/usr/bin:/usr/ccs/bin export PATH ! #PATH=/usr/local/bin:/bin:/usr/bin:/usr/X11R6/bin export PATH # # each product MUST provide a $PRODUCT/admin/shrept.lst Running Oracle When you have followed the instructions, you should be able to run Oracle as if it was run on Linux itself. Holger Kill Contributed by Valentino Vaschetto Converted to SGML by Installing SAP R/3 (4.6B - IDES) applications SAP R/3 Preface This document describes a possible way of installing a SAP R/3 4.6B IDES-System with Oracle 8.0.5 for Linux onto a FreeBSD 4.3 machine, including the installation of FreeBSD 4.3-STABLE and Oracle 8.0.5. Even though this document tries to describe all important steps in a greater detail, it is not intended as a replacement for the Oracle and SAP R/3 installation guides. Please see the documentation that comes with the SAP R/3 Linux edition for SAP- and Oracle-specific questions, as well as resources from Oracle and SAP OSS. Software The following CDROMs have been used for SAP-installation: Name Number Description KERNEL 51009113 SAP Kernel Oracle / Installation / AIX, Linux, Solaris RDBMS 51007558 Oracle / RDBMS 8.0.5.X / Linux EXPORT1 51010208 IDES / DB-Export / Disc 1 of 6 EXPORT2 51010209 IDES / DB-Export / Disc 2 of 6 EXPORT3 51010210 IDES / DB-Export / Disc3 of 6 EXPORT4 51010211 IDES / DB-Export / Disc4 of 6 EXPORT5 51010212 IDES / DB-Export / Disc5 of 6 EXPORT6 51010213 IDES / DB-Export / Disc6 of 6 Additionally, I used the Oracle 8 Server (Pre-production version 8.0.5 for Linux, Kernel Version 2.0.33) CD which is not really necessary, and of course FreeBSD 4.3 stable (it was only a few days past 4.3 RELEASE). SAP-Notes The following notes should be read before installing SAP R/3 or proved to be useful during installation: Number Title 0171356 SAP Software auf Linux: grundlegenden Anmerkungen 0201147 INST: 4.6C R/3 Inst. on UNIX - Oracle 0373203 Update / Migration Oracle 8.0.5 --> 8.0.6/8.1.6 LINUX 0072984 Release of Digital UNIX 4.0B for Oracle 0130581 R3SETUP step DIPGNTAB terminates 0144978 Your system has not been installed correctly 0162266 Questions and tips for R3SETUP on Windows NT / W2K Hardware-Requirements The following equipment is sufficient for a SAP R/3 System (4.6B): Component 4.6B 4.6C Processor 2 x 800MHz Pentium III 2 x 800MHz Pentium III Memory 1GB ECC 2GB ECC Hard Disc Space 50-60GB (IDES) 50-60GB (IDES) For use in production, Xeon-Processors with large cache, high-speed disc access (SCSI, RAID hardware controller), USV and ECC-RAM is recommended. The large amount of Hard disc space is due to the preconfigured IDES System, which creates 27 GB of database files during installation. Usually after installation it is then necessary to extend some tablespaces. I used a dual processor board with 2 800MHz Pentium III processors, Adaptec 29160 Ultra160 SCSI adapter (for accessing a 40/80 GB DLT tape drive and CDROM), Mylex AcelleRAID (2 channels, firmware 6.00-1-00 with 32MB RAM). To the Mylex Raid-controller are attached two 17GB hard discs (mirrored) and four 36GB hard discs (RAID level 5). Installation of FreeBSD 4.3-STABLE First I installed FreeBSD 4.3 stable. I did the default-installation via FTP. Installation via FTP Get the diskimages kern.flp and mfsroot.flp and put them on floppy disks (I got mine from ftp7.de.freebsd.org. Please choose the appropriate mirror). &prompt.root; dd if=kern.flp of=/dev/fd0 &prompt.root; dd if=mfsroot.flp of=/dev/fd0 - Don't forget to use different disks for the two images, + Do not forget to use different disks for the two images, then boot from the floppy with the kern.flp-image on it and follow instructions. I used the following disk layout: Filesystem Size (1k-blocks) Size (GB) Mounted on /dev/da0s1a 1.016.303 1 / /dev/da0s1b 6 <swap> /dev/da0s1e 2.032.623 2 /var /dev/da0s1f 8.205.339 8 /usr /dev/da1s1e 45.734.361 45 /compat/linux/oracle /dev/da1s1f 2.032.623 2 /compat/linux/sapmnt /dev/da1s1g 2.032.623 2 /compat/linux/usr/sap I had to configure and initialize the two logical drives with the Mylex software beforehand. It is located on the board itself and can be started during the boot phase of the PC. Please note that this disk layout differs slightly from the SAP recommendations, as SAP suggests mounting the oracle-subdirectories (and some others) separately - I decided to just create them as real subdirectories for simplicity. Get the Latest STABLE Sources For FreeBSD 4.3 stable onwards, it is quite easy to get the latest stable sources. With the older versions of FreeBSD, I had my own script located in /etc/cvsup. Setting up CVSup for FreeBSD 4.3 is quite easy. As user root do the following: &prompt.root; cp /etc/defaults/make.conf /etc/make.conf &prompt.root; vi /etc/make.conf The file /etc/make.conf requires the following entries to be active: SUP_UPDATE= yes SUP= /usr/local/bin/cvsup SUPFLAGS= -g -L 2 SUPHOST= cvsup8.FreeBSD.org SUPFILE= /usr/share/examples/cvsup/stable-supfile PORTSSUPFILE= /usr/share/examples/cvsup/ports-supfile DOCSUPFILE= /usr/share/examples/cvsup/doc-supfile Change the SUPHOST-value appropriately. The supfiles in /usr/share/examples/cvsup should be - fine. If you don't want to load all the docfiles, leave the + fine. If you do not want to load all the docfiles, leave the corresponding DOCSUPFILE-entry inactive. Starting cvsup to get the latest stable-sources is then very easy: &prompt.root; cd /usr/src &prompt.root; make update <command>make world</command> and a New Kernel The first thing to do is to install the sources. As user root, do the following: &prompt.root; cd /usr/src &prompt.root; make world If this goes through, one can then continue creating and configuring the new kernel. Usually this is where to customize the kernel configuration file. As the computer is named troubadix, the natural name for the config file also is troubadix: &prompt.root; cd /usr/src/sys/i386/conf &prompt.root; cp GENERIC TROUBADIX &prompt.root; vi TROUBADIX At this stage one can define the drivers to use and not to use, etc. See the appropriate documentation or have a look at file LINT for some additional explanations. One can then also include the parameters as described below Creating the new kernel then requires: &prompt.root; cd /usr/src/sys/i386/conf &prompt.root; config TROUBADIX &prompt.root; cd /usr/src/sys/compile/TROUBADIX &prompt.root; make depend &prompt.root; make &prompt.root; make install After make install finished successfully, one should reboot the computer to have the new kernel available. Installing the Linux Environment I had some trouble downloading the required RPM-files (for 4.3 stable, 2nd May 2001), so you might try one of the following locations (if all the others fail and the following - aren't out of date): + are not out of date): ftp7.de.freebsd.org/pub/FreeBSD/distfiles/rpm ftp.redhat.com/pub/redhat/linux/6.1/en/os/i386/RedHat/RPMS Installing Linux Base-system First the Linux base-system needs to be installed (as root): &prompt.root; cd /usr/ports/emulators/linux_base &prompt.root; make package Installing Linux Development Next, the Linux development is needed: &prompt.root; cd /usr/ports/devel/linux_devtools &prompt.root; make package Installing Necessary RPMs RPMs To start the R3SETUP-Program, pam support is needed. As this also requires some other packages, I ended up installing several packages. After that, pam still complained about a missing package, so I forced the installation and it worked. I wonder if the other packages are really needed or if it would have been sufficient to install the pam-package. Anyway, here is the list of packages I installed: cracklib-2.7-5.i386.rpm cracklib-dicts-2.7-5.i386.rpm pwdb-0.60-1.i386.rpm pam-0.68-7.i386.rpm I installed these packages with the following command: &prompt.root; rpm -i --ignoreos --root /compat/linux --dbpath /var/lib/rpm <package_name> except for the pam package, which I forced with &prompt.root; rpm -i --ignoreos --nodeps --root /compat/linux --dbpath /var/lib/rpm pam-0.68-7.i386.rpm For Oracle to run the intelligent agent, I also had to install the following RedHat Tcl package (as is stated in the FreeBSD Handbook): tcl-8.0.5-30.i386.rpm (otherwise the relinking during Oracle install - won't work). There are some other issues regarding + will not work). There are some other issues regarding relinking of Oracle, but that is a Oracle-Linux issue, not FreeBSD specific as far as I understand it. Creating the SAP/R3 Environment Creating the Necessary Filesystems and Mountpoints For a simple installation, it is sufficient to create the following filesystems: mountpoint size in GB /compat/linux/oracle 45 GB /compat/linux/sapmnt 2 GB /compat/linux/usr/sap 2 GB I also created some links, so FreeBSD will also find the correct path: &prompt.root; ln -s /compat/linux/oracle /oracle &prompt.root; ln -s /compat/linux/sapmnt /sapmnt &prompt.root; ln -s /compat/linux/usr/sap /usr/sap Creating Users and Directories SAP R/3 needs two users and three groups. The usernames depend on the SAP system id (SID) which consists of three letters. Some of these SIDs are reserved by SAP (for example SAP and NIX. For a complete list please see the SAP documentation). For the IDES installation I used IDS. We have therefore the following groups (group ids might differ, these are just the values I used with my installation): group id group name description 100 dba Data Base Administrator 101 sapsys SAP System 102 oper Data Base Operator For a default Oracle-Installation, only group dba is used. As oper-group, one also uses group dba (see Oracle- and SAP-documentation for further information). We also need the following users: user id username generic name group additional groups description 1000 idsadm <sid>adm sapsys oper SAP Administrator 1002 oraids ora<sid> dba oper DB Administrator Adding the users with adduser requires the following (please note shell and home directory) entries for SAP-Administrator: Name: idsadm <sid>adm Password: ****** Fullname: SAP IDES Administrator Uid: 1000 Gid: 101 (sapsys) Class: Groups: sapsys dba HOME: /home/idsadm /home/<sid>adm Shell: /bin/sh and for Database-Administrator: Name: oraids ora<sid> Password: ****** Fullname: Oracle IDES Administrator Uid: 1002 Gid: 100 (dba) Class: Groups: dba HOME: /oracle/IDS /oracle/<sid> Shell: /bin/sh This should also include group oper in case you are using both groups dba and oper. Creating Directories These directories are usually created as separate filesystems. This depends entirely on your requirements. I choose to create them as simple directories, as they are all located on the same RAID 5 anyway: - First we'll set owners and right of some directories (as + First we will set owners and right of some directories (as user root): &prompt.root; chmod 775 /oracle &prompt.root; chmod 777 /sapmnt &prompt.root; chown root:dba /oracle &prompt.root; chown idsadm:sapsys /compat/linux/usr/sap &prompt.root; chmow 775 /compat/linux/usr/sap - Second we'll create directories as user ora<sid>. These + Second we will create directories as user ora<sid>. These will all be subdirectories of /oracle/IDS: &prompt.root; su - oraids &prompt.root; mkdir mirrlogA mirrlogB origlogA origlogB &prompt.root; mkdir sapdata1 sapdata2 sapdata3 sapdata4 sapdata5 sapdata6 &prompt.root; mkdir saparch sapreorg &prompt.root; exit In the third step we create directories as user idsadm (<sid>adm): &prompt.root; su - idsadm &prompt.root; cd /usr/sap &prompt.root; mkdir IDS &prompt.root; mkdir trans &prompt.root; exit Entries in /etc/services SAP R/3 requires some entries in file /etc/services , which will not be set correctly during installation under FreeBSD. Please add the following entries (you need at least those entries corresponding to the instance number - in this case, 00. It'll do no harm adding all entries from 00 to 99 for dp, gw, sp and ms); sapdp00 3200/tcp # SAP Dispatcher. 3200 + Instance-Number sapgw00 3300/tcp # SAP Gateway. 3300 + Instance-Number sapsp00 3400/tcp # 3400 + Instance-Number sapms00 3500/tcp # 3500 + Instance-Number sapmsIDS 3600/tcp # SAP Message Server. 3600 + Instance-Number Necessary Locales locale - SAP requires at least two locales that aren't part of + SAP requires at least two locales that are not part of the default RedHat installation. SAP offers the required RPMs as download from their FTP-server (which is only accessible if you are a customer with OSS-access). See note 0171356 for a list of RPMs you need. It is also possible to just create appropriate links (for example from de_DE and - en_US ), but I wouldn't recommend this + en_US ), but I would not recommend this for a production system (so far it worked with the IDES system without any problems, though). The following locales are needed: de_DE.ISO-8859-1 en_US.ISO-8859-1 If they are not present, there will be some problems during the installation. If these are then subsequently ignored (eg by setting the status of the offending steps to OK in file CENTRDB.R3S), it will be impossible to log onto the SAP-system without some additional effort. Kernel Tuning kernel tuning SAP R/3 Systems need a lot of resources. I therefore added the following parameters to my kernel config-file: # Set these for memory pigs (SAP and Oracle): options MAXDSIZ="(1024*1024*1024)" options DFLDSIZ="(1024*1024*1024)" # System V options needed. options SYSVSHM #SYSV-style shared memory options SHMMAXPGS=262144 #max amount of shared mem. pages options SHMMNI=256 #max number of shared memory ident if. options SHMSEG=100 #max shared mem.segs per process options SYSVMSG #SYSV-style message queues options MSGSEG=32767 #max num. of mes.segments in system options MSGSSZ=32 #size of msg-seg. MUST be power of 2 options MSGMNB=65535 #max char. per message queue options MSGTQL=2046 #max amount of msgs in system options SYSVSEM #SYSV-style semaphores options SEMMNU=256 #number of semaphore UNDO structures options SEMMNS=1024 #number of semaphores in system options SEMMNI=520 #number of semaphore indentifiers options SEMUME=100 #number of UNDO keys The minimum values are specified in the documentation that comes from SAP. As there is no description for Linux, see the HP-UX-section (32-bit) for further information. Installing SAP R/3 Preparing SAP CDROMs There are lots of CDROMs to mount and unmount during installation. Assuming you have enough CDROM-drives, you can just mount them all. I decided to copy the CDROM contents to corresponding directories: /oracle/IDS/sapreorg/<cd-name> where <cd-name> was one of KERNEL, RDBMS, EXPORT1, EXPORT2, EXPORT3, EXPORT4, EXPORT5 and EXPORT6. All the filenames should be in capital letters, otherwise use the -g option for mounting. So use the following commands: &prompt.root; mount_cd9660 -g /dev/cd0a /mnt &prompt.root; cp -R /mnt/* /oracle/IDS/sapreorg/<cd-name> &prompt.root; umount /mnt Running the install-script First we need to prepare an install-directory: &prompt.root; cd /oracle/IDS/sapreorg &prompt.root; mkdir install &prompt.root; cd install Then the install-script is started, which will copy nearly all the relevant files into the install-directory: /oracle/IDS/sapreorg/KERNEL/UNIX/INSTTOOL.SH As this is an IDES-Installation with a fully customized SAP R/3 Demo-System, we have six instead of just three EXPORT-CDs. At this point the installation template CENTRDB.R3S is for installing a standard central instance (R/3 and Database), not an IDES central instance, so copy the corresponding CENTRDB.R3S from the EXPORT1 directory, otherwise R3SETUP will only ask for three EXPORT-CDs. Start R3SETUP Make sure LD_LIBRARY_PATH is set correctly: &prompt.root; export LD_LIBRARY_PATH=/oracle/IDS/lib:/sapmnt/IDS/exe:/oracle/805_32/lib Start R3SETUP as user root from installation directory: &prompt.root; cd /oracle/IDS/sapreorg/install &prompt.root; ./R3SETUP -f CENTRDB.R3S The script then asks some questions (defaults in brackets, followed by actual input): Question Default Input Enter SAP System ID [C11] IDS<ret> Enter SAP Instance Number [00] <ret> Enter SAPMOUNT Directory [/sapmnt] <ret> Enter name of SAP central host [troubadix.domain.de] <ret> Enter name of SAP db host [troubadix] <ret> Select character set [1] (WE8DEC) <ret> Enter Oracle server version (1) Oracle 8.0.5, (2) Oracle 8.0.6, (3) Oracle 8.1.5, (4) Oracle 8.1.6 1<ret> Extract Oracle Client archive [1] (Yes, extract) <ret> Enter path to KERNEL CD [/sapcd] /oracle/IDS/sapreorg/KERNEL Enter path to RDBMS CD [/sapcd] /oracle/IDS/sapreorg/RDBMS Enter path to EXPORT1 CD [/sapcd] /oracle/IDS/sapreorg/EXPORT1 Directory to copy EXPORT1 CD [/oracle/IDS/sapreorg/CD4_DIR] <ret> Enter path to EXPORT2 CD [/sapcd] /oracle/IDS/sapreorg/EXPORT2 Directory to copy EXPORT2 CD [/oracle/IDS/sapreorg/CD5_DIR] <ret> Enter path to EXPORT3 CD [/sapcd] /oracle/IDS/sapreorg/EXPORT3 Directory to copy EXPORT3 CD [/oracle/IDS/sapreorg/CD6_DIR] <ret> Enter path to EXPORT4 CD [/sapcd] /oracle/IDS/sapreorg/EXPORT4 Directory to copy EXPORT4 CD [/oracle/IDS/sapreorg/CD7_DIR] <ret> Enter path to EXPORT5 CD [/sapcd] /oracle/IDS/sapreorg/EXPORT5 Directory to copy EXPORT5 CD [/oracle/IDS/sapreorg/CD8_DIR] <ret> Enter path to EXPORT6 CD [/sapcd] /oracle/IDS/sapreorg/EXPORT6 Directory to copy EXPORT6 CD [/oracle/IDS/sapreorg/CD9_DIR] <ret> Enter amount of RAM for SAP + DB 850<ret> (in Megabytes) Service Entry Message Server [3600] <ret> Enter Group-ID of sapsys [101] <ret> Enter Group-ID of oper [102] <ret> Enter Group-ID of dba [100] <ret> Enter User-ID of <sid>adm [1000] <ret> Enter User-ID of ora<sid> [1002] <ret> Number of parallel procs [2] <ret> If I had not copied the CDs to the different locations, - then the SAP-Installer can't find the CD needed (identified + then the SAP-Installer cannot find the CD needed (identified by the LABEL.ASC-File on CD) and would then ask you to insert / mount the CD and confirm or enter the mount path. The CENTRDB.R3S might not be error-free. In my case, it requested EXPORT4 again (but indicated the correct key (6_LOCATI ON, then 7_LOCATION etc.), so one can just continue with entering the correct - values. Don't get irritated. + values. Do not get irritated. Apart from some problems mentioned below, everything should go straight through up to the point where the Oracle database software needs to be installed. Installing Oracle 8.0.5 Please see the corresponding SAP-Notes and Oracle Readmes regarding Linux and Oracle DB for possible problems. Most if not all problems stem from incompatible libraries For more information on installing Oracle, refer to the Installing Oracle chapter. Installing the Oracle 8.0.5 with orainst If Oracle 8.0.5 is to be used, some additional libraries are needed for successfully relinking, as Oracle 8.0.5 was linked with an old glibc (RedHat 6.0), but RedHat 6.1 already uses a new glibc. So you have to install the following additional packages to ensure that linking will work: compat-libs-5.2-2.i386.rpm compat-glibc-5.2-2.0.7.2.i386.rpm compat-egcs-5.2-1.0.3a.1.i386.rpm compat-egcs-c++-5.2-1.0.3a.1.i386.rpm compat-binutils-5.2-2.9.1.0.23.1.i386.rpm See the corresponding SAP-Notes or Oracle Readmes for further information. If this is no option (at the time of - installation I didn't have enough time to check this), one + installation I did not have enough time to check this), one could use the original binaries, or use the relinked binaries from an original RedHat System. For compiling the intelligent agent, the RedHat Tcl - package must be installed. If you can't get + package must be installed. If you cannot get tcl-8.0.3-20.i386.rpm, a newer one like tcl-8.0.5-30.i386.rpm for RedHat 6.1 should also do. Apart from relinking, the installation is straightforward: &prompt.root; su - oraids &prompt.root; export TERM=xterm &prompt.root; export ORACLE_TERM=xterm &prompt.root; export ORACLE_HOME=/oracle/IDS &prompt.root; cd /ORACLE_HOME/orainst_sap &prompt.root; ./orainst Confirm all Screens with Enter until the software is installed, except that one has to deselect the Oracle On-Line Text Viewer , as this is not currently available for Linux. Oracle then wants to relink with i386-glibc20-linux-gcc instead of the available gcc, egcs or i386-redhat-linux-gcc . Due to time constrains I decided to use the binaries from an Oracle 8.0.5 PreProduction release, after the first attempt at getting the version from the RDBMS-CD working, failed, and finding / accessing the correct RPMs was a nightmare at that time. Installing the Oracle 8.0.5 Pre-Production release for Linux (Kernel 2.0.33) This installation is quite easy. Mount the CD, start the installer. It will then ask for the location of the Oracle home directory, and copy all binaries there. I did not delete the remains of my previous RDBMS-installation tries, though. Afterwards, Oracle Database could be started with no problems. Continue with SAP R/3 Installation First check the environment settings of users idsamd (<sid>adm) and oraids (ora<sid>). They should now both have the files .profile , .login and .cshrc which are all using hostname. In case the system's hostname is the fully qualified name, you need to change hostname to hostname -s within all three files. Database Load Afterwards, R3SETUP can either be restarted or continued (depending on whether exit was chosen or not). R3SETUP then creates the tablespaces and loads the data from EXPORT1 to EXPORT6 (remember, it is an IDES system, otherwise it would only be EXPORT1 to EXPORT3) with R3load into the database. When the database load is finished (might take a few hours), some passwords are requested. For test installations, one can use the well known default passwords (use different ones if security is an issue!): Question Input Enter Password for sapr3 sap<ret> Confirum Password for sapr3 sap<ret> Enter Password for sys change_on_install<ret> Confirm Password for sys change_on_install<ret> Enter Password for system manager<ret> Confirm Password for system manager<ret> At this point I had a few problems with dipgntab. Listener Start the Oracle-Listener as user oraids (ora<sid>) as follows: umask 0; lsnrctl start - Otherwise you might get ORA-12546 as the sockets won't + Otherwise you might get ORA-12546 as the sockets will not have the correct permissions. See SAP note 072984. Post-installation Steps Request SAP R/3 License Key This is needed, as the temporary license is only valid for - four weeks. Don't forget to enter the correct Operating System: + four weeks. Do not forget to enter the correct Operating System: (X) Other: FreeBSD 4.3 Stable. First get the hardware key. Log on as user idsadm and call saplicense: &prompt.root; /sapmnt/IDS/exe/saplicense -get Calling saplicense without options gives a list of options. Upon receiving the license key, it can be installed using &prompt.root; /sapmnt/IDS/exe/saplicense -install You are then required to enter the following values: SAP SYSTEM ID = <SID, 3 chars> CUSTOMER KEY = <hardware key, 11 chars> INSTALLATION NO = <installation, 10 digits> EXPIRATION DATE = <yyyymmdd, usually "99991231"> LICENSE KEY = <license key, 24 chars> Creating Users Create a user within client 000 (for some tasks required to be done within client 000, but with a user different from users sap* and ddic). As a username, I usually choose wartung (or service in English). Profiles required are sap_new and sap_all. For additional safety the passwords of default users within all clients should be changed (this includes users sap* and ddic). Configure Transport System, Profile, Operation Modes, Etc. Within client 000, user different from ddic and sap*, do at least the following: Task Transaction Configure Transport System, eg as Stand-Alone Transport Domain Entity STMS Create / Edit Profile for System RZ10 Maintain Operation Modes and Instances RZ04 These and all the other post-installation steps are thoroughly described in SAP installation guides. Edit init<sid>.sap (initIDS.sap) The file /oracle/IDS/dbs/initIDS.sap contains the SAP backup profile. Here the size of the tape to be used, type of compression and so on need to be defined. To get this running with sapdba / brbackup, I changed the following values: compress = hardware archive_function = copy_delete_save cpio_flags = "-ov --format=newc --block-size=128 --quiet" cpio_in_flags = "-iuv --block-size=128 --quiet" tape_size = 38000M tape_address = /dev/nsa0 tape_address_rew = /dev/sa0 Explanations: compress The tape I use is a HP DLT1 which does hardware compression. archive_function This defines the default behavior for saving Oracle archive logs: New logfiles are saved to tape, already saved logfiles are saved again and are then deleted. This prevents lots of trouble if one needs to recover the database, and one of the archive-tapes has gone bad. cpio_flags Default is to use -B which sets blocksize to 5120 Bytes. For DLT-Tapes, HP recommends at least 32K blocksize, so I used --block-size=128 for 64K. --format=newc is needed I have inode numbers greater than 65535. The last option --quiet is needed as otherwise brbackup complains as soon as cpio outputs the numbers of blocks saved. cpio_in_flags Flags needed for loading data back from tape. Format is recognized automagically. tape_size This usually gives the raw storage capability of the tape. For security reason (we use hardware compression), the value is slightly lower than the actual value. tape_address The non-rewindable device to be used with cpio. tape_address_rew The rewindable device to be used with cpio. Problems During Installation OSUSERSIDADM_IND_ORA During R3SETUP If R3SETUP complains at this stage, edit file CENTRDB.R3S. Locate [OSUSERSIDADM_IND_ORA] and edit the following values: HOME=/home/idsadm (was empty) STATUS=OK (had status ERROR) Then you can restart R3SETUP with: &prompt.root; ./R3SETUP -f CENTRDB.R3S OSUSERDBSID_IND_ORA During R3SETUP Possibly R3SETUP also complains at this stage. Just edit CENTRDB.R3S. Locate [OSUSERDBSID_IND_ORA] and edit the following value in that section: STATUS=OK Then just restart R3SETUP again: &prompt.root; ./R3SETUP -f CENTRDB.R3S oraview.vrf FILE NOT FOUND During Oracle Installation - You haven't deselected Oracle On-Line Text Viewer + You have not deselected Oracle On-Line Text Viewer before starting the installation. This is marked for installation even though this option is currently not available for Linux. Deselect this product inside the Oracle installation menu and restart installation. TEXTENV_INVALID During R3SETUP, RFC or SAPGUI Start If this error is encountered, the correct locale is missing. SAP note 0171356 lists the necessary RPMs that need be installed (eg saplocales-1.0-3, saposcheck-1.0-1 for RedHat 6.1). In case you ignored all the related errors and set the corresponding status from ERROR to OK (in CENTRDB.R3S) every time R3SETUP complained and just restarted R3SETUP, the SAP-System will not be properly configured and you will then not be able to connect to the system with a sapgui, even though the system can be started. Trying to connect with the old Linux sapgui gave the following messages: Sat May 5 14:23:14 2001 *** ERROR => no valid userarea given [trgmsgo. 0401] Sat May 5 14:23:22 2001 *** ERROR => ERROR NR 24 occured [trgmsgi. 0410] *** ERROR => Error when generating text environment. [trgmsgi. 0435] *** ERROR => function failed [trgmsgi. 0447] *** ERROR => no socket operation allowed [trxio.c 3363] Speicherzugriffsfehler This behavior is due to SAP R/3 being unable to correctly assign a locale and also not being properly configured itself (missing entries in some database tables). To be able to connect to SAP, add the following entries to file DEFAULT.PFL (see note 0043288): abap/set_etct_env_at_new_mode =0 install/collate/active =0 rscp/TCP0B =TCP0B Restart the SAP system. Now one can connect to the system, even though country-specific language settings might not work as expected. After correcting country-settings (and providing the correct locales), these entries can be removed from DEFAULT.PFL and the SAP system can be restarted. ORA-12546. Start Listener with Correct Permissions Start the Oracle Listener as user oraids with the following commands: &prompt.root; umask 0; lsnrctl start - Otherwise one might get ORA-12546 as the sockets won't + Otherwise one might get ORA-12546 as the sockets will not have the correct permissions. See SAP note 0072984. [DIPGNTAB_IND_IND] During R3SETUP In general, see SAP note 0130581 (R3SETUP step DIPGNTAB terminates). During this specific installation, for some reasons the installation process was not using the proper SAP system name "IDS", but the empty string "" instead. This lead to some minor problems with accessing directories, as the paths are generated dynamically using <sid> (in this case IDS). So instead of accessing: /usr/sap/IDS/SYS/... /usr/sap/IDS/DVMGS00 the following path were used: /usr/sap//SYS/... /usr/sap/D00i To continue with the installation, I created a link and an additional directory: &prompt.root; pwd /compat/linux/usr/sap &prompt.root; ls -l total 4 drwxr-xr-x 3 idsadm sapsys 512 May 5 11:20 D00 drwxr-x--x 5 idsadm sapsys 512 May 5 11:35 IDS lrwxr-xr-x 1 root sapsys 7 May 5 11:35 SYS -> IDS/SYS drwxrwxr-x 2 idsadm sapsys 512 May 5 13:00 tmp drwxrwxr-x 11 idsadm sapsys 512 May 4 14:20 trans I also found SAP notes (0029227 and 0008401) describing this behavior. [RFCRSWBOINI_IND_IND] During R3SETUP Set STATUS of the offending step from ERROR to OK (file CENTRDB.R3S) and restart R3SETUP. After installation, you have to execute the report RSWBOINS from transaction SE38. See SAP note 0162266 for additional information about phase RFCRSWBOINI and RFCRADDBDIF. [RFCRADDBDIF_IND_IND] During R3SETUP Set STATUS of the offending step from ERROR to OK (file CENTRDB.R3S) and restart R3SETUP. After installation, you have to execute the report RADDBDIF from transaction SE38. See SAP note 0162266 for further information. Advanced Topics If you are curious as to how the Linux binary compatibility works, this is the section you want to read. Most of what follows is based heavily on an email written to &a.chat; by Terry Lambert tlambert@primenet.com (Message ID: <199906020108.SAA07001@usr09.primenet.com>). How Does It Work? execution class loader FreeBSD has an abstraction called an execution class loader. This is a wedge into the &man.execve.2; system call. What happens is that FreeBSD has a list of loaders, instead of a single loader with a fallback to the #! loader for running any shell interpreters or shell scripts. Historically, the only loader on the Unix platform examined the magic number (generally the first 4 or 8 bytes of the file) to see if it was a binary known to the system, and if so, invoked the binary loader. If it was not the binary type for the system, the &man.execve.2; call returned a failure, and the shell attempted to start executing it as shell commands. The assumption was a default of whatever the current shell is. Later, a hack was made for &man.sh.1; to examine the first two characters, and if they were :\n, then it invoked the &man.csh.1; shell instead (we believe SCO first made this hack). What FreeBSD does now is go through a list of loaders, with a generic #! loader that knows about interpreters as the characters which follow to the next whitespace next to last, followed by a fallback to /bin/sh. ELF For the Linux ABI support, FreeBSD sees the magic number as an ELF binary (it makes no distinction between FreeBSD, Solaris, Linux, or any other OS which has an ELF image type, at this point). Solaris The ELF loader looks for a specialized brand, which is a comment section in the ELF image, and which is not present on SVR4/Solaris ELF binaries. For Linux binaries to function, they must be branded as type Linux; from &man.brandelf.1;: &prompt.root; brandelf -t Linux file When this is done, the ELF loader will see the Linux brand on the file. ELF branding When the ELF loader sees the Linux brand, the loader replaces a pointer in the proc structure. All system calls are indexed through this pointer (in a traditional Unix system, this would be the sysent[] structure array, containing the system calls). In addition, the process flagged for special handling of the trap vector for the signal trampoline code, and sever other (minor) fix-ups that are handled by the Linux kernel module. The Linux system call vector contains, among other things, a list of sysent[] entries whose addresses reside in the kernel module. When a system call is called by the Linux binary, the trap code dereferences the system call function pointer off the proc structure, and gets the Linux, not the FreeBSD, system call entry points. In addition, the Linux mode dynamically reroots lookups; this is, in effect, what the union option to FS mounts (not the unionfs!) does. First, an attempt is made to lookup the file in the /compat/linux/original-path directory, then only if that fails, the lookup is done in the /original-path directory. This makes sure that binaries that require other binaries can run (e.g., the Linux toolchain can all run under Linux ABI support). It also means that the Linux binaries can load and exec FreeBSD binaries, if there are no corresponding Linux binaries present, and that you could place a &man.uname.1; command in the /compat/linux directory tree to ensure that the Linux binaries could not tell they were not running on Linux. In effect, there is a Linux kernel in the FreeBSD kernel; the various underlying functions that implement all of the services provided by the kernel are identical to both the FreeBSD system call table entries, and the Linux system call table entries: file system operations, virtual memory operations, signal delivery, System V IPC, etc… The only difference is that FreeBSD binaries get the FreeBSD glue functions, and Linux binaries get the Linux glue functions (most older OS's only had their own glue functions: addresses of functions in a static global sysent[] structure array, instead of addresses of functions dereferenced off a dynamically initialized pointer in the proc structure of the process making the call). Which one is the native FreeBSD ABI? It does not matter. Basically the only difference is that (currently; this could easily be changed in a future release, and probably will be after this) the FreeBSD glue functions are statically linked into the kernel, and the Linux glue functions can be statically linked, or they can be accessed via a kernel module. Yeah, but is this really emulation? No. It is an ABI implementation, not an emulation. There is no emulator (or simulator, to cut off the next question) involved. So why is it sometimes called Linux emulation? To make it hard to sell FreeBSD! Really, it is because the historical implementation was done at a time when there was really no word other than that to describe what was going on; saying that FreeBSD ran Linux binaries was not true, if you did not compile the code in or load a module, and there needed to be a word to describe what was being loaded—hence the Linux emulator.
diff --git a/en_US.ISO8859-1/books/handbook/mail/chapter.sgml b/en_US.ISO8859-1/books/handbook/mail/chapter.sgml index 0f5255d7aa..73d949af38 100644 --- a/en_US.ISO8859-1/books/handbook/mail/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/mail/chapter.sgml @@ -1,819 +1,819 @@ Bill Lloyd Original work by Jim Mock Rewritten by Electronic Mail Synopsis email electronic mail Electronic Mail, better known as email, is one of the most widely used forms of communication today. Millions of people use email every day, and chances are if you are reading this online, you fall into that category and probably even have more than one email address. Electronic Mail configuration is the subject of many System Administration books. If you plan on doing anything beyond setting up one mailhost for your network, you need industrial strength help. DNS Some parts of email configuration are controlled in the Domain Name System (DNS). If you are going to run your own DNS server, be sure to read through the files in /etc/namedb and man -k named. Using Electronic Mail POP IMAP There are five major parts involved in an email exchange. They are: the user program, the server daemon, DNS, a pop or IMAP daemon, and of course, the mailhost itself. The User Program This includes command line programs such as mutt, pine, elm, and mail, and GUI programs such as balsa, xfmail to name a few, and something more sophisticated like a WWW browser. These programs simply pass off the email transactions to the local mailhost, either by calling one of the server daemons available or delivering it over TCP. Mailhost Server Daemon mail server daemons sendmail mail server daemons postfix mail server daemons qmail mail server daemons exim This is usually sendmail (by default with FreeBSD) or one of the other mail server daemons such as qmail, postfix, or exim. There are others, but those are the most widely used. The server daemon usually has two functions—it looks after receiving incoming mail and delivers outgoing mail. It does not allow you to connect to it via POP or IMAP to read your mail. You need an additional daemon for that. Be aware that some older versions of sendmail have some serious security problems, however as long as you run a current version of it you should not have any problems. As always, it is a good idea to stay up-to-date with any software you run. Email and DNS The Domain Name System (DNS) and its daemon named play a large role in the delivery of email. In order to deliver mail from your site to another, the server daemon will look up the site in the DNS to determine the host that will receive mail for the destination. It works the same way when you have mail sent to you. The DNS contains the database mapping hostname to an IP address, and a hostname to mailhost. The IP address is specified in an A record. The MX (Mail eXchanger) record specifies the mailhost that will receive mail for you. If you do not have an MX record for your hostname, the mail will be delivered directly to your host. Receiving Mail email receiving Receiving mail for your domain is done by the mail host. It will collect mail sent to you and store it for reading or pickup. In order to pick the stored mail up, you will need to connect to the mail host. This is done by either using POP or IMAP. If you want to read mail directly on the mail host, then a POP or IMAP server is not needed. POP IMAP If you want to run a POP or IMAP server, there are two things you need to do: Get a POP or IMAP daemon from the ports collection and install it on your system. Modify /etc/inetd.conf to load the POP or IMAP server. The Mail Host mail host The mail host is the name given to a server that is responsible for delivering and receiving mail for your host, and possibly your network. Christopher Shumway Contributed by <application>sendmail</application> Configuration sendmail &man.sendmail.8; is the default Mail Transfer Agent (MTA) in FreeBSD. sendmail's job is to accept mail from Mail User Agents (MUA) and deliver it to the appropriate mailer as defined by its configuration file. sendmail can also accept network connections and deliver mail to local mailboxes or deliver it to another program. sendmail uses the following configuration files: /etc/mail/access /etc/mail/aliases /etc/mail/local-host-names /etc/mail/mailer.conf /etc/mail/mailertable /etc/mail/sendmail.cf /etc/mail/virtusertable Filename Function /etc/mail/access sendmail access database file /etc/mail/aliases Mailbox aliases /etc/mail/local-host-names Lists of hosts sendmail accepts mail for /etc/mail/mailer.conf Mailer program configuration /etc/mail/mailertable Mailer delivery table /etc/mail/sendmail.cf sendmail master configuration file /etc/mail/virtusertable Virtual users and domain tables <filename>/etc/mail/access</filename> The access database defines what host(s) or IP addresses have access to the local mail server and what kind of access they have. Hosts can be listed as , , or simply passed to sendmail's error handling routine with a given mailer error. Hosts that are listed as , which is the default, are allowed to send mail to this host as long as the mail's final destination is the local machine. Hosts that are listed as are rejected for all mail connections. Hosts that have the option for their hostname are allowed to send mail for any destination through this mail server. Configuring the <application>sendmail</application> Access Database cyberspammer.com 550 We don't accept mail from spammers FREE.STEALTH.MAILER@ 550 We don't accept mail from spammers another.source.of.spam REJECT okay.cyberspammer.com OK 128.32 RELAY In this example we have five entries. Mail senders that match the left hand side of the table are affected by the action on the right side of the table. The first two examples give an error code to sendmail's error handling routine. The message is printed to the remote host when a mail matches the left hand side of the table. The next entry rejects mail from a specific host on the Internet, another.source.of.spam. The next entry accepts mail connections from a host okay.cyberspammer.com, which is more exact than the cyberspamer.com line above. More specific matches override less exact matches. The last entry allows relaying of electronic mail from hosts with an IP address that begins with 128.32. These hosts would be able to send mail through this mail server that are destined for other mail servers. When this file is updated, you need to run make in /etc/mail/ to update the database. <filename>/etc/mail/aliases</filename> The aliases database contains a list of virtual mailboxes that are expanded to other user(s), files, programs or other aliases. Here is a few examples that can be used in /etc/mail/aliases: Mail Aliases root: localuser ftp-bugs: joe,eric,paul bit.bucket: /dev/null procmail: "|/usr/local/bin/procmail" The aliases update matches the mailbox name on the left of the colon, and will expand it to the target(s) on the right. The first example simply expands the mailbox root to the mailbox localuser , which is then looked up again in the aliases database. If no match is found, then the message is delivered to the local user localuser. The next example shows a mail list. Mail to the mailbox ftp-bugs is expanded to the three local mailboxes joe, eric, and paul. Note that a remote mailbox could be specified as user@domain.com. The next example shows writing mail to a file, in this case /dev/null. The last example shows sending mail to a program, in this case the mail message is written to the standard input of /usr/local/bin/procmail through a Unix pipe. When this file is updated, you need to run make in /etc/mail/ to update the database. <filename>/etc/mail/local-host-names</filename> This is a list of hostnames &man.sendmail.8; is to accept as the local host name. Place any domains or hosts that sendmail is to be receiving mail for. For example, if this mail server was to accept mail for the domain example.com and the host mail.example.com, its local-host-names might look something like this: example.com mail.example.com When this file is updated, &man.sendmail.8; needs to be restarted for it to read the changes. <filename>/etc/mail/mailer.conf</filename> The mailer.conf configuration file holds a table containing the real mailer that is used for the given action. Very old software programs would hard-code in the name and path to the mailer, /usr/sbin/sendmail, which meant they where incompatible with other mailers such as postfix. Today, /usr/sbin/sendmail is a wrapper that looks at /etc/mail/mailer.conf and executes the correct binary. When another mail transfer agent is installed on the system, mailer.conf should be updated to reflect the correct programs to execute. <filename>/etc/mail/sendmail.cf</filename> sendmail's master configuration file, sendmail.cf controls the overall behavior of sendmail. Everything from rewriting e-mail addresses to printing reject messages for remote mail servers. Naturally, with such a diverse role, this configuration file is quite complex and its details are a bit out of the scope of this chapter. Fortunately, this file rarely needs to be changed for standard mail servers. The master sendmail configuration file can be built from &man.m4.1; macros that define features and behavior of sendmail. Please see /usr/src/contrib/sendmail/cf/README for some of the details. When changes to this file are made, sendmail needs to be restarted for the changes to take effect. <filename>/etc/mail/virtusertable</filename> The virtualusertable maps mail for virtual domains and mailboxes to real mailboxes. These mail boxes can be local, remote, point to an alias defined in /etc/mail/aliases or to a file. Example Virtual Domain Mail Map root@example.com root postmaster@example.com postmaster@noc.example.net @example.com joe In the above example, we have a mapping for a domain example.com. This file is processed in a first match order down the file. The first item, maps root@example.com to the local mailbox root. The next entry maps postmaster@example.com to the mailbox postmaster on the host noc.example.net. Finally, if nothing from example.com has matched so far, it will match the last mapping, which matches every other mail message addressed to someone at example.com. This will be mapped to the local mail box joe. Troubleshooting email troubleshooting Why do I have to use the FQDN for hosts on my site? You will probably find that the host is actually in a different domain; for example, if you are in foo.bar.edu and you wish to reach a host called mumble in the bar.edu domain, you will have to refer to it by the fully-qualified domain name, mumble.bar.edu, instead of just mumble. BIND Traditionally, this was allowed by BSD BIND resolvers. However the current version of BIND that ships with FreeBSD no longer provides default abbreviations for non-fully qualified domain names other than the domain you are in. So an unqualified host mumble must either be found as mumble.foo.bar.edu, or it will be searched for in the root domain. This is different from the previous behavior, where the search continued across mumble.bar.edu, and mumble.edu. Have a look at RFC 1535 for why this was considered bad practice, or even a security hole. As a good workaround, you can place the line: search foo.bar.edu bar.edu instead of the previous: domain foo.bar.edu into your /etc/resolv.conf. However, make sure that the search order does not go beyond the boundary between local and public administration, as RFC 1535 calls it. sendmail says mail loops back to myself This is answered in the sendmail FAQ as follows: * I am getting Local configuration error messages, such as: 553 relay.domain.net config error: mail loops back to myself 554 <user@domain.net>... Local configuration error How can I solve this problem? You have asked mail to the domain (e.g., domain.net) to be forwarded to a specific host (in this case, relay.domain.net) by using an MX record, but the relay machine does not recognize itself as domain.net. Add domain.net to /etc/sendmail.cw (if you are using FEATURE(use_cw_file)) or add Cw domain.net to /etc/sendmail.cf. The sendmail FAQ is in /usr/src/usr.sbin/sendmail and is recommended reading if you want to do any tweaking of your mail setup. PPP How can I do email with a dial-up PPP host? You want to connect a FreeBSD box on a lan, to the Internet. The FreeBSD box will be a mail gateway for the lan. The PPP connection is non-dedicated. There are at least two ways to do this. UUCP The other is to use UUCP. The key is to get a Internet site to provide secondary MX service for your domain. For example: bigco.com. MX 10 bigco.com. MX 20 smalliap.com. Only one host should be specified as the final recipient (add Cw bigco.com in /etc/sendmail.cf on bigco.com). When the senders' sendmail is trying to deliver the mail it will try to connect to you over the modem link. It will most likely time out because you are not online. sendmail will automatically deliver it to the secondary MX site, i.e., your Internet provider. The secondary MX site will try every (sendmail_flags = -bd -q15m in /etc/rc.conf) 15 minutes to connect to your host to deliver the mail to the primary MX site. You might want to use something like this as a login script. #!/bin/sh # Put me in /usr/local/bin/pppbigco ( sleep 60 ; /usr/sbin/sendmail -q ) & /usr/sbin/ppp -direct pppbigco If you are going to create a separate login script for a user you could use sendmail -qRbigco.com instead in the script above. This will force all mail in your queue for bigco.com to be processed immediately. A further refinement of the situation is as follows. Message stolen from the &a.isp;. > we provide the secondary MX for a customer. The customer connects to > our services several times a day automatically to get the mails to > his primary MX (We do not call his site when a mail for his domains > arrived). Our sendmail sends the mailqueue every 30 minutes. At the > moment he has to stay 30 minutes online to be sure that all mail is > gone to the primary MX. > > Is there a command that would initiate sendmail to send all the mails > now? The user has not root-privileges on our machine of course. In the privacy flags section of sendmail.cf, there is a definition Opgoaway,restrictqrun Remove restrictqrun to allow non-root users to start the queue processing. You might also like to rearrange the MXs. We are the 1st MX for our customers like this, and we have defined: # If we are the best MX for a host, try directly instead of generating # local config error. OwTrue That way a remote site will deliver straight to you, without trying the customer connection. You then send to your customer. Only works for hosts, so you need to get your customer to name their mail machine customer.com as well as hostname.customer.com in the DNS. Just put an A record in the DNS for customer.com. Advanced Topics The following section covers more involved topics such as mail configuration and setting up mail for your entire domain. Basic Configuration email configuration Out of the box, you should be able to send email to external hosts as long as you have set up /etc/resolv.conf or are running your own name server. If you would like to have mail for your host delivered to that specific host, there are two methods: Run your own name server and have your own domain. For example, FreeBSD.org Get mail delivered directly to your host. This is done by delivering mail directly to the current DNS name for your machine. For example, example.FreeBSD.org. SMTP Regardless of which of the above you choose, in order to have mail delivered directly to your host, you must have a permanent (static) IP address (no dynamic PPP dial-up). If you are behind a firewall, it must pass SMTP traffic on to you. If you want to receive mail at your host itself, you need to be sure of one of two things: MX record Make sure that the MX record in your DNS points to your host's IP address. Make sure there is no MX entry in your DNS for your host. Either of the above will allow you to receive mail directly at your host. Try this: &prompt.root; hostname example.FreeBSD.org &prompt.root; host example.FreeBSD.org example.FreeBSD.org has address 204.216.27.XX If that is what you see, mail directly to yourlogin@example.FreeBSD.org should work without problems. If instead you see something like this: &prompt.root; host example.FreeBSD.org example.FreeBSD.org has address 204.216.27.XX example.FreeBSD.org mail is handled (pri=10) by hub.FreeBSD.org All mail sent to your host (example.FreeBSD.org) will end up being collected on hub under the same username instead of being sent directly to your host. The above information is handled by your DNS server. The DNS record that carries mail routing information is the Mail eXchange entry. If no MX record exists, mail will be delivered directly to the host by way of its IP address. The MX entry for freefall.FreeBSD.org at one time looked like this: freefall MX 30 mail.crl.net freefall MX 40 agora.rdrop.com freefall MX 10 freefall.FreeBSD.org freefall MX 20 who.cdrom.com As you can see, freefall had many MX entries. The lowest MX number is the host that ends up receiving the mail in the end while the others will queue mail temporarily if freefall is busy or down. Alternate MX sites should have separate Internet connections from your own in order to be the most useful. Your ISP or other friendly site should have no problem providing this service for you. Mail for Your Domain In order to set up a mailhost (a.k.a., mail server) you need to have any mail sent to various workstations directed to it. Basically, you want to hijack any mail for your domain (in this case *.FreeBSD.org) and divert it to your mail server so your users can check their mail via POP or directly on the server. DNS To make life easiest, a user account with the same username should exist on both machines. Use adduser to do this. The mailhost you will be using must be the designated mail exchange for each workstation on the network. This is done in your DNS configuration like so: example.FreeBSD.org A 204.216.27.XX ; Workstation MX 10 hub.FreeBSD.org ; Mailhost This will redirect mail for the workstation to the mailhost no matter where the A record points. The mail is sent to the MX host. You cannot do this yourself unless you are running a DNS server. If you are not, or cannot, run your own DNS server, talk to your ISP or whoever does your DNS for you. - If you're doing virtual email hosting, the following + If you are doing virtual email hosting, the following information will come in handy. For the sake of an example, we will assume you have a customer with their own domain, in this case customer1.org and you want all the mail for customer1.org sent to your mailhost, which is named mail.myhost.com. The entry in your DNS should look like this: customer1.org MX 10 mail.myhost.com You do not need an A record if you only want to handle email for the domain. Be aware that this means pinging customer1.org will not work unless an A record exists for it. The last thing that you must do is tell sendmail on your mailhost what domains and/or hostnames it should be accepting mail for. There are a few different ways this can be done. Either of the following will work: Add the hosts to your /etc/sendmail.cw file if you are using the FEATURE(use_cw_file). If you are using sendmail 8.10 or higher, the file is /etc/mail/local-host-names. Add a Cwyour.host.com line to your /etc/sendmail.cf or /etc/mail/sendmail.cf if you are using sendmail 8.10 or higher. diff --git a/en_US.ISO8859-1/books/handbook/mirrors/chapter.sgml b/en_US.ISO8859-1/books/handbook/mirrors/chapter.sgml index 3154a98df7..e0354722e4 100644 --- a/en_US.ISO8859-1/books/handbook/mirrors/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/mirrors/chapter.sgml @@ -1,3948 +1,3948 @@ Obtaining FreeBSD CDROM Publishers Retail Boxed Products FreeBSD is available as a boxed product (FreeBSD CDs, additional software, and documentation) from several retailers:
CompUSA WWW: http://www.compusa.com/
Frys Electronics WWW: http://www.frys.com/
Micro Center WWW: http://www.microcenter.com/
CD Sets FreeBSD CD sets are available from many online retailers:
Daemon News 2680 Bayshore Parkway, Suite 307 Mountain View, CA 94043 USA Phone: +1 650 694-4949 Email: sales@daemonnews.org WWW: http://www.bsdmall.com/
Wind River Systems 500 Wind River Way Alameda, CA 94501 USA Phone: +1 510 749-2872 WWW: http://www.freebsdmall.com/
Distributors If you are a reseller and want to carry FreeBSD CDROM products, please contact a distributor :
Cylogistics 2680 Bayshore Parkway, Suite 307 Mountain View, CA 94043 USA Phone: +1 650 694-4949 Fax: +1 650 694-4953 Email: sales@cylogistics.com WWW: http://www.cylogistics.com/
Ingram Micro WWW: http://www.ingrammicro.com/
Navarre WWW: http://www.navarre.com/
DVD Publishers FreeBSD is available on DVD from:
FreeBSD Services Ltd 11 Lapwing Close Bicester OX26 6XR United Kingdom WWW: http://www.freebsd-services.com/
FTP Sites The official sources for FreeBSD are available via anonymous FTP from:
ftp://ftp.FreeBSD.org/pub/FreeBSD/.
The FreeBSD mirror sites database is more accurate than the mirror listing in the handbook, as it gets its information from the DNS rather than relying on static lists of hosts. Additionally, FreeBSD is available via anonymous FTP from the following mirror sites. If you choose to obtain FreeBSD via anonymous FTP, please try to use a site near you. Argentina, Australia, Brazil, Canada, China, Czech Republic, Denmark, Estonia, Finland, France, Germany, Hong Kong, Hungary, Ireland, Israel, Japan, Korea, Lithuania, Netherlands, New Zealand, Poland, Portugal, Romania, Russia, Saudi Arabia, South Africa, Spain, Slovak Republic, Slovenia, Sweden, Taiwan, Thailand, UK, Ukraine, USA. Argentina In case of problems, please contact the hostmaster hostmaster@ar.FreeBSD.org for this domain. ftp://ftp.ar.FreeBSD.org/pub/FreeBSD/ Australia In case of problems, please contact the hostmaster hostmaster@au.FreeBSD.org for this domain. ftp://ftp.au.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.au.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.au.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.au.FreeBSD.org/pub/FreeBSD/ Brazil In case of problems, please contact the hostmaster hostmaster@br.FreeBSD.org for this domain. ftp://ftp.br.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.br.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.br.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.br.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.br.FreeBSD.org/pub/FreeBSD/ ftp://ftp6.br.FreeBSD.org/pub/FreeBSD/ ftp://ftp7.br.FreeBSD.org/pub/FreeBSD/ Canada In case of problems, please contact the hostmaster hostmaster@ca.FreeBSD.org for this domain. ftp://ftp.ca.FreeBSD.org/pub/FreeBSD/ China In case of problems, please contact the hostmaster phj@cn.FreeBSD.org for this domain. ftp://ftp.cn.FreeBSD.org/pub/FreeBSD/ Czech Republic In case of problems, please contact the hostmaster hostmaster@cz.FreeBSD.org for this domain. ftp://ftp.cz.FreeBSD.org/pub/FreeBSD/ Contact: calda@dzungle.ms.mff.cuni.cz Denmark In case of problems, please contact the hostmaster hostmaster@dk.FreeBSD.org for this domain. ftp://ftp.dk.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.dk.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.dk.FreeBSD.org/pub/FreeBSD/ Estonia In case of problems, please contact the hostmaster hostmaster@ee.FreeBSD.org for this domain. ftp://ftp.ee.FreeBSD.org/pub/FreeBSD/ Finland In case of problems, please contact the hostmaster hostmaster@fi.FreeBSD.org for this domain. ftp://ftp.fi.FreeBSD.org/pub/FreeBSD/ France In case of problems, please contact the hostmaster hostmaster@fr.FreeBSD.org for this domain. ftp://ftp.fr.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.fr.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.fr.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.fr.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.fr.FreeBSD.org/pub/FreeBSD/ ftp://ftp6.fr.FreeBSD.org/pub/FreeBSD/ Germany In case of problems, please contact the mirror admins de-bsd-hubs@de.FreeBSD.org for this domain. ftp://ftp.de.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.de.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.de.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.de.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.de.FreeBSD.org/pub/FreeBSD/ ftp://ftp6.de.FreeBSD.org/pub/FreeBSD/ ftp://ftp7.de.FreeBSD.org/pub/FreeBSD/ Hong Kong ftp://ftp.hk.super.net/pub/FreeBSD/ Contact: ftp-admin@HK.Super.NET. Hungary In case of problems, please contact the hostmaster mohacsi@ik.bme.hu for this domain. ftp://ftp.hu.FreeBSD.org/pub/FreeBSD/ Ireland In case of problems, please contact the hostmaster hostmaster@ie.FreeBSD.org for this domain. ftp://ftp.ie.FreeBSD.org/pub/FreeBSD/ Israel In case of problems, please contact the hostmaster hostmaster@il.FreeBSD.org for this domain. ftp://ftp.il.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.il.FreeBSD.org/pub/FreeBSD/ Japan In case of problems, please contact the hostmaster hostmaster@jp.FreeBSD.org for this domain. ftp://ftp.jp.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.jp.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.jp.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.jp.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.jp.FreeBSD.org/pub/FreeBSD/ ftp://ftp6.jp.FreeBSD.org/pub/FreeBSD/ Korea In case of problems, please contact the hostmaster hostmaster@kr.FreeBSD.org for this domain. ftp://ftp.kr.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.kr.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.kr.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.kr.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.kr.FreeBSD.org/pub/FreeBSD/ ftp://ftp6.kr.FreeBSD.org/pub/FreeBSD/ Lithuania In case of problems, please contact the hostmaster hostmaster@lt.FreeBSD.org for this domain. ftp://ftp.lt.FreeBSD.org/pub/FreeBSD/ Netherlands In case of problems, please contact the hostmaster hostmaster@nl.FreeBSD.org for this domain. ftp://ftp.nl.FreeBSD.org/pub/FreeBSD/ New Zealand In case of problems, please contact the hostmaster hostmaster@nz.FreeBSD.org for this domain. ftp://ftp.nz.FreeBSD.org/pub/FreeBSD/ Poland In case of problems, please contact the hostmaster hostmaster@pl.FreeBSD.org for this domain. ftp://ftp.pl.FreeBSD.org/pub/FreeBSD/ Portugal In case of problems, please contact the hostmaster hostmaster@pt.FreeBSD.org for this domain. ftp://ftp.pt.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.pt.FreeBSD.org/pub/FreeBSD/ Romania In case of problems, please contact the hostmaster hostmaster@ro.FreeBSD.org for this domain. ftp://ftp.ro.FreeBSD.org/pub/FreeBSD/ Russia In case of problems, please contact the hostmaster hostmaster@ru.FreeBSD.org for this domain. ftp://ftp.ru.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.ru.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.ru.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.ru.FreeBSD.org/pub/FreeBSD/ Saudi Arabia In case of problems, please contact ftpadmin@isu.net.sa ftp://ftp.isu.net.sa/pub/mirrors/ftp.freebsd.org/ South Africa In case of problems, please contact the hostmaster hostmaster@za.FreeBSD.org for this domain. ftp://ftp.za.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.za.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.za.FreeBSD.org/FreeBSD/ Slovak Republic In case of problems, please contact the hostmaster hostmaster@sk.FreeBSD.org for this domain. ftp://ftp.sk.FreeBSD.org/pub/FreeBSD/ Slovenia In case of problems, please contact the hostmaster hostmaster@si.FreeBSD.org for this domain. ftp://ftp.si.FreeBSD.org/pub/FreeBSD/ Spain In case of problems, please contact the hostmaster hostmaster@es.FreeBSD.org for this domain. ftp://ftp.es.FreeBSD.org/pub/FreeBSD/ Sweden In case of problems, please contact the hostmaster hostmaster@se.FreeBSD.org for this domain. ftp://ftp.se.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.se.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.se.FreeBSD.org/pub/FreeBSD/ Taiwan In case of problems, please contact the hostmaster hostmaster@tw.FreeBSD.org for this domain. ftp://ftp.tw.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.tw.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.tw.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.tw.FreeBSD.org/pub/FreeBSD/ Thailand ftp://ftp.nectec.or.th/pub/FreeBSD/ Contact: ftpadmin@ftp.nectec.or.th. Ukraine ftp://ftp.ua.FreeBSD.org/pub/FreeBSD/ Contact: freebsd-mnt@lucky.net. UK In case of problems, please contact the hostmaster hostmaster@uk.FreeBSD.org for this domain. ftp://ftp.uk.FreeBSD.org/pub/FreeBSD/ ftp://ftp2.uk.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.uk.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.uk.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.uk.FreeBSD.org/pub/FreeBSD/ USA In case of problems, please contact the hostmaster hostmaster@FreeBSD.org for this domain. ftp://ftp2.FreeBSD.org/pub/FreeBSD/ ftp://ftp3.FreeBSD.org/pub/FreeBSD/ ftp://ftp4.FreeBSD.org/pub/FreeBSD/ ftp://ftp5.FreeBSD.org/pub/FreeBSD/ ftp://ftp6.FreeBSD.org/pub/FreeBSD/ ftp://ftp7.FreeBSD.org/pub/FreeBSD/ ftp://ftp8.FreeBSD.org/pub/FreeBSD/ ftp://ftp9.FreeBSD.org/pub/os/FreeBSD/ ftp://ftp10.FreeBSD.org/pub/FreeBSD/
Anonymous CVS <anchor id="anoncvs-intro">Introduction Anonymous CVS (or, as it is otherwise known, anoncvs) is a feature provided by the CVS utilities bundled with FreeBSD for synchronizing with a remote CVS repository. Among other things, it allows users of FreeBSD to perform, with no special privileges, read-only CVS operations against one of the FreeBSD project's official anoncvs servers. To use it, one simply sets the CVSROOT environment variable to point at the appropriate anoncvs server, provides the well-known password anoncvs with the cvs login command, and then uses the &man.cvs.1; command to access it like any local repository. While it can also be said that the CVSup and anoncvs services both perform essentially the same function, there are various trade-offs which can influence the user's choice of synchronization methods. In a nutshell, CVSup is much more efficient in its usage of network resources and is by far the most technically sophisticated of the two, but at a price. To use CVSup, a special client must first be installed and configured before any bits can be grabbed, and then only in the fairly large chunks which CVSup calls collections. Anoncvs, by contrast, can be used to examine anything from an individual file to a specific program (like ls or grep) by referencing the CVS module name. Of course, anoncvs is also only good for - read-only operations on the CVS repository, so if it's your + read-only operations on the CVS repository, so if it is your intention to support local development in one repository shared with the FreeBSD project bits then CVSup is really your only option. <anchor id="anoncvs-usage">Using Anonymous CVS Configuring &man.cvs.1; to use an Anonymous CVS repository is a simple matter of setting the CVSROOT environment variable to point to one of the FreeBSD project's anoncvs servers. At the time of this writing, the following servers are available: USA: :pserver:anoncvs@anoncvs.FreeBSD.org:/home/ncvs (Use cvs login and enter the password anoncvs when prompted.) Since CVS allows one to check out virtually any version of the FreeBSD sources that ever existed (or, in some cases, will exist, you need to be familiar with the revision () flag to &man.cvs.1; and what some of the permissible values for it in the FreeBSD Project repository are. There are two kinds of tags, revision tags and branch tags. A revision tag refers to a specific revision. Its meaning stays the same from day to day. A branch tag, on the other hand, refers to the latest revision on a given line of development, at any given time. Because a branch tag does not refer to a specific revision, it may mean something different tomorrow than it means today. Here are the branch tags that users might be interested in (keep in mind that the only tags valid for the ports collection is HEAD). HEAD Symbolic name for the main line, or FreeBSD-CURRENT. Also the default when no revision is specified. RELENG_4 The line of development for FreeBSD-4.X, also known as FreeBSD-STABLE. RELENG_4_3 The release branch for FreeBSD-4.3, used only for security advisories and other seriously critical fixes. RELENG_3 The line of development for FreeBSD-3.X, also known as 3.X-STABLE. RELENG_2_2 The line of development for FreeBSD-2.2.X, also known as 2.2-STABLE. This branch is mostly obsolete. Here are the revision tags that users might be interested in. Again, none of these are valid for the ports collection since the ports collection does not have multiple revisions. RELENG_4_3_0_RELEASE FreeBSD 4.3. RELENG_4_2_0_RELEASE FreeBSD 4.2. RELENG_4_1_1_RELEASE FreeBSD 4.1.1. RELENG_4_1_0_RELEASE FreeBSD 4.1. RELENG_4_0_0_RELEASE FreeBSD 4.0. RELENG_3_5_0_RELEASE FreeBSD-3.5. RELENG_3_4_0_RELEASE FreeBSD-3.4. RELENG_3_3_0_RELEASE FreeBSD-3.3. RELENG_3_2_0_RELEASE FreeBSD-3.2. RELENG_3_1_0_RELEASE FreeBSD-3.1. RELENG_3_0_0_RELEASE FreeBSD-3.0. RELENG_2_2_8_RELEASE FreeBSD-2.2.8. RELENG_2_2_7_RELEASE FreeBSD-2.2.7. RELENG_2_2_6_RELEASE FreeBSD-2.2.6. RELENG_2_2_5_RELEASE FreeBSD-2.2.5. RELENG_2_2_2_RELEASE FreeBSD-2.2.2. RELENG_2_2_1_RELEASE FreeBSD-2.2.1. RELENG_2_2_0_RELEASE FreeBSD-2.2.0. When you specify a branch tag, you normally receive the latest versions of the files on that line of development. If you wish to receive some past version, you can do so by specifying a date with the flag. See the &man.cvs.1; manual page for more details. Examples While it really is recommended that you read the manual page for &man.cvs.1; thoroughly before doing anything, here are some quick examples which essentially show how to use Anonymous CVS: Checking Out Something from -CURRENT (&man.ls.1;) and Deleting It Again: &prompt.user; setenv CVSROOT :pserver:anoncvs@anoncvs.FreeBSD.org:/home/ncvs &prompt.user; cvs login At the prompt, enter the password anoncvs. &prompt.user; cvs co ls &prompt.user; cvs release -d ls &prompt.user; cvs logout Checking Out the Version of &man.ls.1; in the 3.X-STABLE Branch: &prompt.user; setenv CVSROOT :pserver:anoncvs@anoncvs.FreeBSD.org:/home/ncvs &prompt.user; cvs login At the prompt, enter the password anoncvs. &prompt.user; cvs co -rRELENG_3 ls &prompt.user; cvs release -d ls &prompt.user; cvs logout Creating a List of Changes (as unified diffs) to &man.ls.1; &prompt.user; setenv CVSROOT :pserver:anoncvs@anoncvs.FreeBSD.org:/home/ncvs &prompt.user; cvs login At the prompt, enter the password anoncvs. &prompt.user; cvs rdiff -u -rRELENG_3_0_0_RELEASE -rRELENG_3_4_0_RELEASE ls &prompt.user; cvs logout Finding Out What Other Module Names Can Be Used: &prompt.user; setenv CVSROOT :pserver:anoncvs@anoncvs.FreeBSD.org:/home/ncvs &prompt.user; cvs login At the prompt, enter the password anoncvs. &prompt.user; cvs co modules &prompt.user; more modules/modules &prompt.user; cvs release -d modules &prompt.user; cvs logout Other Resources The following additional resources may be helpful in learning CVS: CVS Tutorial from Cal Poly. Cyclic Software, commercial maintainers of CVS. CVSWeb is the FreeBSD Project web interface for CVS. Using CTM CTM is a method for keeping a remote directory tree in sync with a central one. It has been developed for usage with FreeBSD's source trees, though other people may find it useful for other purposes as time goes by. Little, if any, documentation currently exists at this time on the process of creating deltas, so talk to &a.phk; for more information should you wish to use CTM for other things. Why Should I Use <application>CTM</application>? CTM will give you a local copy of the FreeBSD source trees. There are a number of “flavors” of the tree available. Whether you wish to track the entire CVS tree or just one of the branches, CTM can provide you the information. If you are an active developer on FreeBSD, but have lousy or non-existent TCP/IP connectivity, or simply wish to have the changes automatically sent to you, CTM was made for you. You will need to obtain up to three deltas per day for the most active branches. However, you should consider having them sent by automatic email. The sizes of the updates are always kept as small as possible. This is typically less than 5K, with an occasional (one in ten) being 10-50K and every now and then a large 100K+ or more coming around. You will also need to make yourself aware of the various caveats related to working directly from the development sources rather than a pre-packaged release. This is particularly true if you choose the “current” sources. It is recommended that you read Staying current with FreeBSD. What Do I Need to Use <application>CTM</application>? You will need two things: The CTM program, and the initial deltas to feed it (to get up to “current” levels). The CTM program has been part of FreeBSD ever since version 2.0 was released, and lives in /usr/src/usr.sbin/CTM if you have a copy of the source available. If you are running a pre-2.0 version of FreeBSD, you can fetch the current CTM sources directly from: ftp://ftp.FreeBSD.org/pub/FreeBSD/FreeBSD-current/src/usr.sbin/ctm/ The “deltas” you feed CTM can be had two ways, FTP or email. If you have general FTP access to the Internet then the following FTP sites support access to CTM: ftp://ftp.FreeBSD.org/pub/FreeBSD/CTM/ or see section mirrors. FTP the relevant directory and fetch the README file, starting from there. If you wish to get your deltas via email: Send email to &a.majordomo; to subscribe to one of the CTM distribution lists. “ctm-cvs-cur” supports the entire CVS tree. “ctm-src-cur” supports the head of the development branch. “ctm-src-2_2” supports the 2.2 release branch, etc.. (If you do not know how to subscribe yourself using majordomo, send a message first containing the word help — it will send you back usage instructions.) When you begin receiving your CTM updates in the mail, you may use the ctm_rmail program to unpack and apply them. You can actually use the ctm_rmail program directly from a entry in /etc/aliases if you want to have the process run in a fully automated fashion. Check the ctm_rmail manual page for more details. No matter what method you use to get the CTM deltas, you should subscribe to the ctm-announce@FreeBSD.org mailing list. In the future, this will be the only place where announcements concerning the operations of the CTM system will be posted. Send an email to &a.majordomo; with a single line of subscribe ctm-announce to get added to the list. Using <application>CTM</application> for the First Time Before you can start using CTM deltas, you will need to get to a starting point for the deltas produced subsequently to it. First you should determine what you already have. Everyone can start from an “empty” directory. You must use an initial “Empty” delta to start off your CTM supported tree. At some point it is intended that one of these “started” deltas be distributed on the CD for your convenience, however, this does not currently happen. Since the trees are many tens of megabytes, you should prefer to start from something already at hand. If you have a -RELEASE CD, you can copy or extract an initial source from it. This will save a significant transfer of data. You can recognize these “starter” deltas by the X appended to the number (src-cur.3210XEmpty.gz for instance). The designation following the X corresponds to the origin of your initial “seed”. Empty is an empty directory. As a rule a base transition from Empty is produced every 100 deltas. By the way, they are large! 25 to 30 Megabytes of gzip'd data is common for the XEmpty deltas. - Once you've picked a base delta to start from, you will also + Once you have picked a base delta to start from, you will also need all deltas with higher numbers following it. Using <application>CTM</application> in Your Daily Life To apply the deltas, simply say: &prompt.root; cd /where/ever/you/want/the/stuff &prompt.root; ctm -v -v /where/you/store/your/deltas/src-xxx.* CTM understands deltas which have been put through gzip, so you do not need to gunzip them first, this saves disk space. Unless it feels very secure about the entire process, CTM will not touch your tree. To verify a delta you can also use the flag and CTM will not actually touch your tree; it will merely verify the integrity of the delta and see if it would apply cleanly to your current tree. There are other options to CTM as well, see the manual pages or look in the sources for more information. That is really all there is to it. Every time you get a new delta, just run it through CTM to keep your sources up to date. Do not remove the deltas if they are hard to download again. You just might want to keep them around in case something bad happens. Even if you only have floppy disks, consider using fdwrite to make a copy. Keeping Your Local Changes As a developer one would like to experiment with and change files in the source tree. CTM supports local modifications in a limited way: before checking for the presence of a file foo, it first looks for foo.ctm. If this file exists, CTM will operate on it instead of foo. This behavior gives us a simple way to maintain local changes: simply copy the files you plan to modify to the corresponding file names with a .ctm suffix. Then you can freely hack the code, while CTM keeps the .ctm file up-to-date. Other Interesting <application>CTM</application> Options Finding Out Exactly What Would Be Touched by an Update You can determine the list of changes that CTM will make on your source repository using the option to CTM. This is useful if you would like to keep logs of the changes, pre- or post- process the modified files in any manner, or just are feeling a tad paranoid. Making Backups Before Updating Sometimes you may want to backup all the files that would be changed by a CTM update. Specifying the option causes CTM to backup all files that would be touched by a given CTM delta to backup-file. Restricting the Files Touched by an Update Sometimes you would be interested in restricting the scope of a given CTM update, or may be interested in extracting just a few files from a sequence of deltas. You can control the list of files that CTM would operate on by specifying filtering regular expressions using the and options. For example, to extract an up-to-date copy of lib/libc/Makefile from your collection of saved CTM deltas, run the commands: &prompt.root; cd /where/ever/you/want/to/extract/it/ &prompt.root; ctm -e '^lib/libc/Makefile' ~ctm/src-xxx.* For every file specified in a CTM delta, the and options are applied in the order given on the command line. The file is processed by CTM only if it is marked as eligible after all the and options are applied to it. Future Plans for <application>CTM</application> Tons of them: Use some kind of authentication into the CTM system, so as to allow detection of spoofed CTM updates. Clean up the options to CTM, they became confusing and counter intuitive. Miscellaneous Stuff There is a sequence of deltas for the ports collection too, but interest has not been all that high yet. Tell me if you want an email list for that too and we will consider setting it up. CTM Mirrors CTM/FreeBSD is available via anonymous FTP from the following mirror sites. If you choose to obtain CTM via anonymous FTP, please try to use a site near you. In case of problems, please contact &a.phk;. California, Bay Area, official source ftp://ftp.FreeBSD.org/pub/FreeBSD/development/CTM/ Germany, Trier ftp://ftp.uni-trier.de/pub/unix/systems/BSD/FreeBSD/CTM/ South Africa, backup server for old deltas ftp://ftp.za.FreeBSD.org/pub/FreeBSD/CTM/ Taiwan/R.O.C, Chiayi ftp://ctm.tw.FreeBSD.org/pub/FreeBSD/CTM/ ftp://ctm2.tw.FreeBSD.org/pub/FreeBSD/CTM/ ftp://ctm3.tw.FreeBSD.org/pub/freebsd/CTM/ If you did not find a mirror near to you or the mirror is incomplete, try FTP search at http://ftpsearch.ntnu.no/ftpsearch. FTP search is a great free archie server in Trondheim, Norway. Using CVSup Introduction CVSup is a software package for distributing and updating source trees from a master CVS repository on a remote server host. The FreeBSD sources are maintained in a CVS repository on a central development machine in California. With CVSup, FreeBSD users can easily keep their own source trees up to date. CVSup uses the so-called pull model of updating. Under the pull model, each client asks the server for updates, if and when they are wanted. The server waits passively for update requests from its clients. Thus all updates are instigated by the client. The server never sends unsolicited updates. Users must either run the CVSup client manually to get an update, or they must set up a cron job to run it automatically on a regular basis. The term CVSup, capitalized just so, refers to the entire software package. Its main components are the client cvsup which runs on each user's machine, and the server cvsupd which runs at each of the FreeBSD mirror sites. As you read the FreeBSD documentation and mailing lists, you may see references to sup. Sup was the predecessor of CVSup, and it served a similar purpose.CVSup is in used in much the same way as sup and, in fact, uses configuration files which are backward-compatible with sup's. Sup is no longer used in the FreeBSD project, because CVSup is both faster and more flexible. Installation The easiest way to install CVSup is to use the precompiled net/cvsup package from the FreeBSD packages collection. If you prefer to build CVSup from source, you can use the net/cvsup port instead. But be forewarned: the net/cvsup port depends on the Modula-3 system, which takes a substantial amount of time and disk space to download and build. If you do not know anything about CVSup at all and want a single package which will install it, set up the configuration file and start the transfer via a pointy-clicky type of interface, then get the cvsupit package. Just hand it to &man.pkg.add.1; and it will lead you through the configuration process in a menu-oriented fashion. CVSup Configuration CVSup's operation is controlled by a configuration file called the supfile. There are some sample supfiles in the directory /usr/share/examples/cvsup/. The information in a supfile answers the following questions for cvsup: Which files do you want to receive? Which versions of them do you want? Where do you want to get them from? Where do you want to put them on your own machine? Where do you want to put your status files? In the following sections, we will construct a typical supfile by answering each of these questions in turn. First, we describe the overall structure of a supfile. A supfile is a text file. Comments begin with # and extend to the end of the line. Lines that are blank and lines that contain only comments are ignored. Each remaining line describes a set of files that the user wishes to receive. The line begins with the name of a collection, a logical grouping of files defined by the server. The name of the collection tells the server which files you want. After the collection name come zero or more fields, separated by white space. These fields answer the questions listed above. There are two types of fields: flag fields and value fields. A flag field consists of a keyword standing alone, e.g., delete or compress. A value field also begins with a keyword, but the keyword is followed without intervening white space by = and a second word. For example, release=cvs is a value field. A supfile typically specifies more than one collection to receive. One way to structure a supfile is to specify all of the relevant fields explicitly for each collection. However, that tends to make the supfile lines quite long, and it is inconvenient because most fields are the same for all of the collections in a supfile. CVSup provides a defaulting mechanism to avoid these problems. Lines beginning with the special pseudo-collection name *default can be used to set flags and values which will be used as defaults for the subsequent collections in the supfile. A default value can be overridden for an individual collection, by specifying a different value with the collection itself. Defaults can also be changed or augmented in mid-supfile by additional *default lines. With this background, we will now proceed to construct a supfile for receiving and updating the main source tree of FreeBSD-CURRENT. Which files do you want to receive? The files available via CVSup are organized into named groups called collections. The collections that are available are described here. In this example, we wish to receive the entire main source tree for the FreeBSD system. There is a single large collection src-all which will give us all of that. As a first step toward constructing our supfile, we simply list the collections, one per line (in this case, only one line): src-all Which version(s) of them do you want? With CVSup, you can receive virtually any version of the sources that ever existed. That is possible because the cvsupd server works directly from the CVS repository, which contains all of the versions. You specify which one of them you want using the tag= and value fields. Be very careful to specify any tag= fields correctly. Some tags are valid only for certain collections of files. If you specify an incorrect or misspelled tag, CVSup will delete files which you probably do not want deleted. In particular, use only tag=. for the ports-* collections. The tag= field names a symbolic tag in the repository. There are two kinds of tags, revision tags and branch tags. A revision tag refers to a specific revision. Its meaning stays the same from day to day. A branch tag, on the other hand, refers to the latest revision on a given line of development, at any given time. Because a branch tag does not refer to a specific revision, it may mean something different tomorrow than it means today. Here are the branch tags that users might be interested in. Keep in mind that only the tag=. is relevant for the ports collection. tag=. The main line of development, also known as FreeBSD-CURRENT. The . is not punctuation; it is the name of the tag. Valid for all collections. tag=RELENG_4 The line of development for FreeBSD-4.X, also known as FreeBSD-STABLE. tag=RELENG_4_3 The release branch for FreeBSD-4.3, used only for security advisories and other seriously critical fixes. tag=RELENG_3 The line of development for FreeBSD-3.X tag=RELENG_2_2 The line of development for FreeBSD-2.2.X, also known as 2.2-STABLE. Here are the revision tags that users might be interested in. Again, these are not valid for the ports collection. tag=RELENG_4_3_0_RELEASE FreeBSD 4.3. tag=RELENG_4_2_0_RELEASE FreeBSD-4.2. tag=RELENG_4_1_1_RELEASE FreeBSD-4.1.1. tag=RELENG_4_1_0_RELEASE FreeBSD-4.1. tag=RELENG_4_0_0_RELEASE FreeBSD-4.0. tag=RELENG_3_5_0_RELEASE FreeBSD-3.5. tag=RELENG_3_4_0_RELEASE FreeBSD-3.4. tag=RELENG_3_3_0_RELEASE FreeBSD-3.3. tag=RELENG_3_2_0_RELEASE FreeBSD-3.2. tag=RELENG_3_1_0_RELEASE FreeBSD-3.1. tag=RELENG_3_0_0_RELEASE FreeBSD-3.0. tag=RELENG_2_2_8_RELEASE FreeBSD-2.2.8. tag=RELENG_2_2_7_RELEASE FreeBSD-2.2.7. tag=RELENG_2_2_6_RELEASE FreeBSD-2.2.6. tag=RELENG_2_2_5_RELEASE FreeBSD-2.2.5. tag=RELENG_2_2_2_RELEASE FreeBSD-2.2.2. tag=RELENG_2_2_1_RELEASE FreeBSD-2.2.1. tag=RELENG_2_2_0_RELEASE FreeBSD-2.2.0. Be very careful to type the tag name exactly as shown. CVSup cannot distinguish between valid and invalid tags. If you misspell the tag, CVSup will behave as though you had specified a valid tag which happens to refer to no files at all. It will delete your existing sources in that case. When you specify a branch tag, you normally receive the latest versions of the files on that line of development. If you wish to receive some past version, you can do so by specifying a date with the value field. The &man.cvsup.1; manual page explains how to do that. For our example, we wish to receive FreeBSD-CURRENT. We add this line at the beginning of our supfile: *default tag=. There is an important special case that comes into play if you specify neither a tag= field nor a date= field. In that case, you receive the actual RCS files directly from the server's CVS repository, rather than receiving a particular version. Developers generally prefer this mode of operation. By maintaining a copy of the repository itself on their systems, they gain the ability to browse the revision histories and examine past versions of files. This gain is achieved at a large cost in terms of disk space, however. Where do you want to get them from? We use the host= field to tell cvsup where to obtain its updates. Any of the CVSup mirror sites will do, though you should try to select one that is close to you in cyberspace. In this example we will use a fictional FreeBSD distribution site, cvsup666.FreeBSD.org: *default host=cvsup666.FreeBSD.org You will need to change the host to one that actually exists before running CVSup. On any particular run of cvsup, you can override the host setting on the command line, with . Where do you want to put them on your own machine? The prefix= field tells cvsup where to put the files it receives. In this example, we will put the source files directly into our main source tree, /usr/src. The src directory is already implicit in the collections we have chosen to receive, so this is the correct specification: *default prefix=/usr Where should cvsup maintain its status files? The CVSup client maintains certain status files in what is called the base directory. These files help CVSup to work more efficiently, by keeping track of which updates you have already received. We will use the standard base directory, /usr/local/etc/cvsup: *default base=/usr/local/etc/cvsup This setting is used by default if it is not specified in the supfile, so we actually do not need the above line. If your base directory does not already exist, now would be a good time to create it. The cvsup client will refuse to run if the base directory does not exist. Miscellaneous supfile settings: There is one more line of boiler plate that normally needs to be present in the supfile: *default release=cvs delete use-rel-suffix compress release=cvs indicates that the server should get its information out of the main FreeBSD CVS repository. This is virtually always the case, but there are other possibilities which are beyond the scope of this discussion. delete gives CVSup permission to delete files. You should always specify this, so that CVSup can keep your source tree fully up-to-date. CVSup is careful to delete only those files for which it is responsible. Any extra files you happen to have will be left strictly alone. use-rel-suffix is ... arcane. If you really want to know about it, see the &man.cvsup.1; manual page. Otherwise, just specify it and do not worry about it. compress enables the use of gzip-style compression on the communication channel. If your network link is T1 speed or faster, you probably should not use compression. Otherwise, it helps substantially. Putting it all together: Here is the entire supfile for our example: *default tag=. *default host=cvsup666.FreeBSD.org *default prefix=/usr *default base=/usr/local/etc/cvsup *default release=cvs delete use-rel-suffix compress src-all The refuse File As mentioned above, CVSup uses a pull method. Basically, this means that you connect to the CVSup server, and it says, Here's what you can download from me..., and your client responds OK, I'll take this, this, this, and this. In the default configuration, the CVSup client will take every file associated with the collection and tag you chose in the configuration file. However, this is not always what you want, especially if you are synching the doc, ports, or - www trees — most people can't read four or five - languages, and therefore they don't need to download the + www trees — most people cannot read four or five + languages, and therefore they do not need to download the language-specific files. If you are CVSuping the ports collection, you can get around this by specifying each collection individually (e.g., ports-astrology, ports-biology, etc instead of simply saying ports-all). However, since the doc and www trees do not have language-specific collections, you must use one of CVSup's many nifty features; the refuse file. The refuse file essentially tells CVSup that it should not take every single file from a collection; in other words, it tells the client to refuse certain files from the server. The refuse file can be found (or, if you do not yet have one, should be placed) in base/sup/refuse. base is defined in your supfile; by default, base is /usr/local/etc/cvsup, which means that by default the refuse file is in /usr/local/etc/cvsup/sup/refuse. The refuse file has a very simple format; it simply contains the names of files or directories that you do not wish to download. For example, if you cannot speak any languages other than English and some German, and you do not feel the need to use the German applications, you can put the following in your refuse file: ports/chinese ports/german ports/japanese ports/korean ports/russian ports/vietnamese doc/es_ES.ISO8859-1 doc/ja_JP.eucJP and so forth for the other languages. Note that the name of the repository is the first directory in the refuse file. With this very useful feature, those users who are on slow links or pay by the minute for their Internet connection will be able to save valuable time as they will no longer need to download files that they will never use. For more information on refuse files and other neat features of CVSup, please view its manual page. Running <application>CVSup</application> You are now ready to try an update. The command line for doing this is quite simple: &prompt.root; cvsup supfile where supfile is of course the name of the supfile you have just created. Assuming you are running under X11, cvsup will display a GUI window with some buttons to do the usual things. Press the go button, and watch it run. Since you are updating your actual /usr/src tree in this example, you will need to run the program as root so that cvsup has the permissions it needs to update your files. Having just created your configuration file, and having never used this program before, that might understandably make you nervous. There is an easy way to do a trial run without touching your precious files. Just create an empty directory somewhere convenient, and name it as an extra argument on the command line: &prompt.root; mkdir /var/tmp/dest &prompt.root; cvsup supfile /var/tmp/dest The directory you specify will be used as the destination directory for all file updates. CVSup will examine your usual files in /usr/src, but it will not modify or delete any of them. Any file updates will instead land in /var/tmp/dest/usr/src. CVSup will also leave its base directory status files untouched when run this way. The new versions of those files will be written into the specified directory. As long as you have read access to /usr/src, you do not even need to be root to perform this kind of trial run. If you are not running X11 or if you just do not like GUIs, you should add a couple of options to the command line when you run cvsup: &prompt.root; cvsup -g -L 2 supfile The tells CVSup not to use its GUI. This is automatic if you are not running X11, but otherwise you have to specify it. The tells CVSup to print out the details of all the file updates it is doing. There are three levels of verbosity, from to . The default is 0, which means total silence except for error messages. There are plenty of other options available. For a brief list of them, type cvsup -H. For more detailed descriptions, see the manual page. Once you are satisfied with the way updates are working, you can arrange for regular runs of CVSup using &man.cron.8;. Obviously, you should not let CVSup use its GUI when running it from &man.cron.8;. <application>CVSup</application> File Collections The file collections available via CVSup are organized hierarchically. There are a few large collections, and they are divided into smaller sub-collections. Receiving a large collection is equivalent to receiving each of its sub-collections. The hierarchical relationships among collections are reflected by the use of indentation in the list below. The most commonly used collections are src-all, and ports-all. The other collections are used only by small groups of people for specialized purposes, and some mirror sites may not carry all of them. cvs-all release=cvs The main FreeBSD CVS repository, including the cryptography code. distrib release=cvs Files related to the distribution and mirroring of FreeBSD. doc-all release=cvs Sources for the FreeBSD handbook and other documentation. ports-all release=cvs The FreeBSD Ports Collection. ports-archivers release=cvs Archiving tools. ports-astro release=cvs Astronomical ports. ports-audio release=cvs Sound support. ports-base release=cvs Miscellaneous files at the top of /usr/ports. ports-benchmarks release=cvs Benchmarks. ports-biology release=cvs Biology. ports-cad release=cvs Computer aided design tools. ports-chinese release=cvs Chinese language support. ports-comms release=cvs Communication software. ports-converters release=cvs character code converters. ports-databases release=cvs Databases. ports-deskutils release=cvs Things that used to be on the desktop before computers were invented. ports-devel release=cvs Development utilities. ports-editors release=cvs Editors. ports-emulators release=cvs Emulators for other operating systems. ports-ftp release=cvs FTP client and server utilities. ports-games release=cvs Games. ports-german release=cvs German language support. ports-graphics release=cvs Graphics utilities. ports-irc release=cvs Internet Relay Chat utilities. ports-japanese release=cvs Japanese language support. ports-java release=cvs Java utilities. ports-korean release=cvs Korean language support. ports-lang release=cvs Programming languages. ports-mail release=cvs Mail software. ports-math release=cvs Numerical computation software. ports-mbone release=cvs MBone applications. ports-misc release=cvs Miscellaneous utilities. ports-net release=cvs Networking software. ports-news release=cvs USENET news software. ports-palm release=cvs Software support for 3Com Palm(tm) series. ports-print release=cvs Printing software. ports-russian release=cvs Russian language support. ports-security release=cvs Security utilities. ports-shells release=cvs Command line shells. ports-sysutils release=cvs System utilities. ports-textproc release=cvs text processing utilities (does not include desktop publishing). ports-vietnamese release=cvs Vietnamese language support. ports-www release=cvs Software related to the World Wide Web. ports-x11 release=cvs Ports to support the X window system. ports-x11-clocks release=cvs X11 clocks. ports-x11-fm release=cvs X11 file managers. ports-x11-fonts release=cvs X11 fonts and font utilities. ports-x11-toolkits release=cvs X11 toolkits. ports-x11-servers X11 servers. ports-x11-wm X11 window managers. src-all release=cvs The main FreeBSD sources, including the cryptography code. src-base release=cvs Miscellaneous files at the top of /usr/src. src-bin release=cvs User utilities that may be needed in single-user mode (/usr/src/bin). src-contrib release=cvs Utilities and libraries from outside the FreeBSD project, used relatively unmodified (/usr/src/contrib). src-crypto release=cvs Cryptography utilities and libraries from outside the FreeBSD project, used relatively unmodified (/usr/src/crypto). src-eBones release=cvs Kerberos and DES (/usr/src/eBones). Not used in current releases of FreeBSD. src-etc release=cvs System configuration files (/usr/src/etc). src-games release=cvs Games (/usr/src/games). src-gnu release=cvs Utilities covered by the GNU Public License (/usr/src/gnu). src-include release=cvs Header files (/usr/src/include). src-kerberos5 release=cvs Kerberos5 security package (/usr/src/kerberos5). src-kerberosIV release=cvs KerberosIV security package (/usr/src/kerberosIV). src-lib release=cvs Libraries (/usr/src/lib). src-libexec release=cvs System programs normally executed by other programs (/usr/src/libexec). src-release release=cvs Files required to produce a FreeBSD release (/usr/src/release). src-secure release=cvs DES (/usr/src/secure). src-sbin release=cvs System utilities for single-user mode (/usr/src/sbin). src-share release=cvs Files that can be shared across multiple systems (/usr/src/share). src-sys release=cvs The kernel (/usr/src/sys). src-sys-crypto release=cvs Kernel cryptography code (/usr/src/sys/crypto). src-tools release=cvs Various tools for the maintenance of FreeBSD (/usr/src/tools). src-usrbin release=cvs User utilities (/usr/src/usr.bin). src-usrsbin release=cvs System utilities (/usr/src/usr.sbin). www release=cvs The sources for the World Wide Web data. distrib release=self The CVSup server's own configuration files. Used by CVSup mirror sites. gnats release=current The GNATS bug-tracking database. mail-archive release=current FreeBSD mailing list archive. www release=current The installed World Wide Web data. Used by WWW mirror sites. For More Information For the CVSup FAQ and other information about CVSup, see The CVSup Home Page. Most FreeBSD-related discussion of CVSup takes place on the &a.hackers;. New versions of the software are announced there, as well as on the &a.announce;. Questions and bug reports should be addressed to the author of the program at cvsup-bugs@polstra.com. CVSup Sites CVSup servers for FreeBSD are running at the following sites: Argentina cvsup.ar.FreeBSD.org (maintainer msagre@cactus.fi.uba.ar) Australia cvsup.au.FreeBSD.org (maintainer dawes@xfree86.org) cvsup3.au.FreeBSD.org (maintainer FreeBSD@admin.gil.com.au) Austria cvsup.at.FreeBSD.org (maintainer postmaster@wu-wien.ac.at) Brazil cvsup.br.FreeBSD.org (maintainer cvsup@cvsup.br.FreeBSD.org) cvsup2.br.FreeBSD.org (maintainer tps@ti.sk) cvsup3.br.FreeBSD.org (maintainer camposr@matrix.com.br) Canada cvsup.ca.FreeBSD.org (maintainer dan@jaded.net) cvsup2.ca.FreeBSD.org (maintainer hostmaster@ca.freebsd.org) China cvsup.cn.FreeBSD.org (maintainer phj@cn.FreeBSD.org) Czech Republic cvsup.cz.FreeBSD.org (maintainer cejkar@dcse.fee.vutbr.cz) Denmark cvsup.dk.FreeBSD.org (maintainer jesper@skriver.dk) Estonia cvsup.ee.FreeBSD.org (maintainer taavi@uninet.ee) Finland cvsup.fi.FreeBSD.org (maintainer count@key.sms.fi) cvsup2.fi.FreeBSD.org (maintainer count@key.sms.fi) France cvsup.fr.FreeBSD.org (maintainer hostmaster@fr.FreeBSD.org) cvsup2.fr.FreeBSD.org (maintainer ftpmaint@uvsq.fr) Germany cvsup.de.FreeBSD.org (maintainer rse@freebsd.org) cvsup1.de.FreeBSD.org (maintainer wosch@FreeBSD.org) cvsup2.de.FreeBSD.org (maintainer cvsup@nikoma.de) cvsup3.de.FreeBSD.org (maintainer ag@leo.org) cvsup4.de.FreeBSD.org (maintainer cvsup@cosmo-project.de) cvsup5.de.FreeBSD.org (maintainer rse@freebsd.org) Greece cvsup.gr.FreeBSD.org (maintainer ftpadm@duth.gr) cvsup2.gr.FreeBSD.org (maintainer paschos@cs.uoi.gr) Iceland cvsup.is.FreeBSD.org (maintainer adam@veda.is) Ireland cvsup.ie.FreeBSD.org (maintainer dwmalone@maths.tcd.ie), Trinity College, Dublin. Japan cvsup.jp.FreeBSD.org (maintainer cvsupadm@jp.FreeBSD.org) cvsup2.jp.FreeBSD.org (maintainer max@FreeBSD.org) cvsup3.jp.FreeBSD.org (maintainer shige@cin.nihon-u.ac.jp) cvsup4.jp.FreeBSD.org (maintainer cvsup-admin@ftp.media.kyoto-u.ac.jp) cvsup5.jp.FreeBSD.org (maintainer cvsup@imasy.or.jp) cvsup6.jp.FreeBSD.org (maintainer cvsupadm@jp.FreeBSD.org) Korea cvsup.kr.FreeBSD.org (maintainer cjh@kr.FreeBSD.org) cvsup2.kr.FreeBSD.org (maintainer holywar@mail.holywar.net) Lithuania cvsup.lt.FreeBSD.org (maintainer domas.mituzas@delfi.lt) Netherlands cvsup.nl.FreeBSD.org (maintainer xaa@xaa.iae.nl) cvsup2.nl.FreeBSD.org (maintainer cvsup@nl.uu.net) Norway cvsup.no.FreeBSD.org (maintainer Per.Hove@math.ntnu.no) Poland cvsup.pl.FreeBSD.org (maintainer Mariusz@kam.pl) Portugal cvsup.pt.FreeBSD.org (maintainer jpedras@webvolution.net) Russia cvsup.ru.FreeBSD.org (maintainer ache@nagual.pp.ru) cvsup2.ru.FreeBSD.org (maintainer dv@dv.ru) cvsup3.ru.FreeBSD.org (maintainer fjoe@iclub.nsu.ru) cvsup4.ru.FreeBSD.org (maintainer zhecka@klondike.ru) cvsup5.ru.FreeBSD.org (maintainer maxim@macomnet.ru) cvsup6.ru.FreeBSD.org (maintainer pvr@corbina.net) Slovak Republic cvsup.sk.FreeBSD.org (maintainer tps@tps.sk) cvsup2.sk.FreeBSD.org (maintainer tps@tps.sk) Slovenia cvsup.si.FreeBSD.org (maintainer blaz@si.FreeBSD.org) South Africa cvsup.za.FreeBSD.org (maintainer markm@FreeBSD.org) cvsup2.za.FreeBSD.org (maintainer markm@FreeBSD.org) Spain cvsup.es.FreeBSD.org (maintainer jesusr@FreeBSD.org) cvsup2.es.FreeBSD.org (maintainer jesusr@FreeBSD.org) cvsup3.es.FreeBSD.org (maintainer jose@we.lc.ehu.es) Sweden cvsup.se.FreeBSD.org (maintainer pantzer@ludd.luth.se) cvsup2.se.FreeBSD.org (maintainer cvsup@dataphone.net) Taiwan cvsup.tw.FreeBSD.org (maintainer jdli@freebsd.csie.nctu.edu.tw) cvsup2.tw.FreeBSD.org (maintainer ycheng@sinica.edu.tw) cvsup3.tw.FreeBSD.org (maintainer foxfair@FreeBSD.org) Ukraine cvsup2.ua.FreeBSD.org (maintainer freebsd-mnt@lucky.net) cvsup3.ua.FreeBSD.org (maintainer ftpmaster@ukr.net), Kiev cvsup4.ua.FreeBSD.org (maintainer phantom@cris.net) United Kingdom cvsup.uk.FreeBSD.org (maintainer joe@pavilion.net) cvsup2.uk.FreeBSD.org (maintainer brian@FreeBSD.org) cvsup3.uk.FreeBSD.org (maintainer ftp-admin@plig.net) USA cvsup1.FreeBSD.org (maintainer skynyrd@opus.cts.cwu.edu), Washington state cvsup2.FreeBSD.org (maintainer jdp@FreeBSD.org), California cvsup3.FreeBSD.org (maintainer wollman@FreeBSD.org), Massachusetts cvsup4.FreeBSD.org (maintainer rgrimes@FreeBSD.org), Oregon cvsup5.FreeBSD.org (maintainer mjr@blackened.com), Arizona cvsup6.FreeBSD.org (maintainer jdp@FreeBSD.org), Florida cvsup7.FreeBSD.org (maintainer jdp@FreeBSD.org), Washington state cvsup8.FreeBSD.org (maintainer hostmaster@bigmirror.com), Washington state cvsup9.FreeBSD.org (maintainer qbsd@uswest.net), Minnesota cvsup10.FreeBSD.org (maintainer jdp@FreeBSD.org), California cvsup11.FreeBSD.org (maintainer cvsup@research.uu.net), Virginia cvsup12.FreeBSD.org (maintainer will@FreeBSD.org), Indiana cvsup13.FreeBSD.org (maintainer dima@valueclick.com), California cvsup14.FreeBSD.org (maintainer freebsd-cvsup@mfnx.net), California cvsup15.FreeBSD.org (maintainer cvsup@math.uic.edu), Illinois cvsup16.FreeBSD.org (maintainer pth3k@virginia.edu), Virginia cvsup17.FreeBSD.org (maintainer cvsup@mirrortree.com), Washington state AFS Sites AFS servers for FreeBSD are running at the following sites; Sweden The path to the files are: /afs/stacken.kth.se/ftp/pub/FreeBSD/ stacken.kth.se # Stacken Computer Club, KTH, Sweden 130.237.234.43 #hot.stacken.kth.se 130.237.237.230 #fishburger.stacken.kth.se 130.237.234.3 #milko.stacken.kth.se Maintainer ftp@stacken.kth.se
diff --git a/en_US.ISO8859-1/books/handbook/multimedia/chapter.sgml b/en_US.ISO8859-1/books/handbook/multimedia/chapter.sgml index b2f186cfae..3b4f8a3e32 100644 --- a/en_US.ISO8859-1/books/handbook/multimedia/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/multimedia/chapter.sgml @@ -1,368 +1,368 @@ Moses Moore Contributed by Sound Synopsis FreeBSD supports a wide variety of sound cards, allowing you to enjoy high fidelity output from your computer. This includes the ability to record and playback audio in the MPEG Audio Layer 3 (MP3), WAV, and Ogg Vorbis formats as well as many other formats. The FreeBSD Ports Collection also contains applications allowing you to edit your recorded audio, add sound effects, and control attached MIDI devices. After reading this chapter you will know: How to locate your sound card. How to configure your system so that your sound card is recognized. Methods to test that your card is working using sample applications. How to troubleshoot your sound setup. Before reading this chapter you should: Know how to configure and install a new kernel () Locating the Correct Device PCI ISA sound cards Before you begin, you should know the model of the card you have, the chip it uses, and whether it is a PCI or ISA card. FreeBSD supports a wide variety of both PCI and ISA cards. If you do not see your card in the following list, check the &man.pcm.4; manual page. This is not a complete list; however, it does list some of the most common cards. Crystal 4237, 4236, 4232, 4231 Yamaha OPL-SAx OPTi931 Ensoniq AudioPCI 1370/1371 ESS Solo-1/1E NeoMagic 256AV/ZX Sound Blaster Pro, 16, 32, AWE64, AWE128, Live Creative ViBRA16 Advanced Asound 100, 110, and Logic ALS120 ES 1868, 1869, 1879, 1888 Gravis UltraSound Aureal Vortex 1 or 2 kernel configuration The driver you use in your kernel depends on the kind of card you have. The sections below provide more information and what you will need to add to your kernel configuration. Creative, Advance, and ESS Sound Cards If you have one of the above cards, you will need to add device pcm to your kernel. If you have a PnP ISA card, you will also need to add device sbc to your kernel. For a non-PnP ISA card, add device pcm and device sbc0 at isa? port0x220 irq 5 drq 1 flags 0x15 to your kernel. Those are the default settings. You may need to change the IRQ, etc. See the &man.sbc.4; manual page for more information. The Sound Blaster Live is not supported under FreeBSD 4.0 without a patch, which this document will not cover. It is recommended that you update to the latest -STABLE before trying to use this card. Gravis UltraSound Cards For a PnP ISA card, you will need to add device pcm and device gusc to your kernel. If you have a non-PnP ISA card, you will need to add device pcm and device gus0 at isa? port 0x220 irq 5 drq 1 flags 0x13 to your kernel. You may need to change the IRQ, etc. See the &man.gusc.4; manual page for more information. Crystal Sound Cards For Crystal cards, you will need both device pcm and device csa in your kernel. Generic Support For PnP ISA or PCI cards, you will need to add device pcm to your kernel configuration. If you have a non-PnP ISA sound card that does not have a bridge driver, you will need to add device pcm0 at isa? irq 10 drq 1 flags 0x0 to your kernel configuration. You may need to change the IRQ, etc., to match your hardware configuration. Recompiling the Kernel After adding the driver(s) you need to your kernel configuration, you will need to recompile your kernel. Please see of the handbook for more information. Creating and Testing the Device Nodes device nodes After you reboot, log in and run cat /dev/sndstat. You should see output similar to the following: FreeBSD Audio Driver (newpcm) Sep 21 2000 18:29:53 Installed devices: pcm0: <Aureal Vortex 8830> at memory 0xfeb40000 irq 5 (4p/1r +channels duplex) If you see an error message, something went wrong earlier. If that happens, go through your kernel configuration file again and make sure you chose the correct device. If it reported no errors and returned pcm0, su to root and do the following: &prompt.root; cd /dev &prompt.root; sh MAKEDEV snd0 If it reported no errors and returned pcm1, su to root and do the following: &prompt.root; cd /dev &prompt.root; sh MAKEDEV snd1 Please note that either of the above commands will not create a /dev/snd device! Instead it creates a group of device nodes including: Device Description /dev/audio SPARC-compatible audio device /dev/dsp Digitized voice device /dev/dspW Like /dev/dsp, but 16 bits per sample /dev/midi Raw midi access device /dev/mixer Control port mixer device /dev/music Level 2 sequencer interface /dev/sequencer Sequencer device /dev/pss Programmable device interface If all goes well, you should now have a functioning sound card. If you do not, see the next section. Common Problems device node I get an unsupported subdevice XX error! - One or more of the device nodes wasn't created + One or more of the device nodes was not created correctly. Repeat the steps above. I/O port I get a sb_dspwr(XX) timed out error! The I/O port is not set correctly. IRQ I get a bad irq XX error! The IRQ is set incorrectly. Make sure that the set IRQ and the sound IRQ are the same. I get a xxx: gus pcm not attached, out of memory error. What causes that? If this happens, it is because there is not enough available memory to use the device. diff --git a/en_US.ISO8859-1/books/handbook/policies/chapter.sgml b/en_US.ISO8859-1/books/handbook/policies/chapter.sgml index f9fcbba896..2cb0d8060c 100644 --- a/en_US.ISO8859-1/books/handbook/policies/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/policies/chapter.sgml @@ -1,437 +1,437 @@ Poul-Henning Kamp Contributed by Source Tree Guidelines and Policies This chapter documents various guidelines and policies in force for the FreeBSD source tree. <makevar>MAINTAINER</makevar> on Makefiles ports maintainer June 1996. If a particular portion of the FreeBSD distribution is being maintained by a person or group of persons, they can communicate this fact to the world by adding a MAINTAINER= email-addresses line to the Makefiles covering this portion of the source tree. The semantics of this are as follows: The maintainer owns and is responsible for that code. This means that he is responsible for fixing bugs and answer problem reports pertaining to that piece of the code, and in the case of contributed software, for tracking new versions, as appropriate. Changes to directories which have a maintainer defined shall be sent to the maintainer for review before being committed. Only if the maintainer does not respond for an unacceptable period of time, to several emails, will it be acceptable to commit changes without review by the maintainer. However, it is suggested that you try and have the changes reviewed by someone else if at all possible. It is of course not acceptable to add a person or group as maintainer unless they agree to assume this duty. On the other hand it - doesn't have to be a committer and it can easily be a group of + does not have to be a committer and it can easily be a group of people. Poul-Henning Kamp Contributed by David O'Brien Contributed Software contributed software Some parts of the FreeBSD distribution consist of software that is actively being maintained outside the FreeBSD project. For historical reasons, we call this contributed software. Some examples are perl, gcc and patch. Over the last couple of years, various methods have been used in dealing with this type of software and all have some number of advantages and drawbacks. No clear winner has emerged. Since this is the case, after some debate one of these methods has been selected as the official method and will be required for future imports of software of this kind. Furthermore, it is strongly suggested that existing contributed software converge on this model over time, as it has significant advantages over the old method, including the ability to easily obtain diffs relative to the official versions of the source by everyone (even without cvs access). This will make it significantly easier to return changes to the primary developers of the contributed software. Ultimately, however, it comes down to the people actually doing the work. If using this model is particularly unsuited to the package being dealt with, exceptions to these rules may be granted only with the approval of the core team and with the general consensus of the other developers. The ability to maintain the package in the future will be a key issue in the decisions. Because of some unfortunate design limitations with the RCS file format and CVS's use of vendor branches, minor, trivial and/or cosmetic changes are strongly discouraged on files that are still tracking the vendor branch. Spelling fixes are explicitly included here under the cosmetic category and are to be avoided for files with revision 1.1.x.x. The repository bloat impact from a single character change can be rather dramatic. The Tcl embedded programming language will be used as example of how this model works: src/contrib/tcl contains the source as distributed by the maintainers of this package. Parts that are entirely not applicable for FreeBSD can be removed. In the case of Tcl, the mac, win and compat subdirectories were eliminated before the import src/lib/libtcl contains only a "bmake style" Makefile that uses the standard bsd.lib.mk makefile rules to produce the library and install the documentation. src/usr.bin/tclsh contains only a bmake style Makefile which will produce and install the tclsh program and its associated man-pages using the standard bsd.prog.mk rules. src/tools/tools/tcl_bmake contains a couple of shell-scripts that can be of help when the Tcl software needs updating. These are not part of the built or installed software. The important thing here is that the src/contrib/tcl directory is created according to the rules: It is supposed to contain the sources as distributed (on a proper CVS vendor-branch and without RCS keyword expansion) with as few FreeBSD-specific changes as possible. The 'easy-import' tool on freefall will assist in doing the import, but if there are any doubts on how to go about it, it is imperative that you ask first and not blunder ahead and hope it works out. CVS is not forgiving of import accidents and a fair amount of effort is required to back out major mistakes. Because of the previously mentioned design limitations with CVS's vendor branches, it is required that official patches from the vendor be applied to the original distributed sources and the result re-imported onto the vendor branch again. Official patches should never be patched into the FreeBSD checked out version and "committed", as this destroys the vendor branch coherency and makes importing future versions rather difficult as there will be conflicts. Since many packages contain files that are meant for compatibility with other architectures and environments that FreeBSD, it is permissible to remove parts of the distribution tree that are of no interest to FreeBSD in order to save space. Files containing copyright notices and release-note kind of information applicable to the remaining files shall not be removed. If it seems easier, the bmake Makefiles can be produced from the dist tree automatically by some utility, something which would hopefully make it even easier to upgrade to a new version. If this is done, be sure to check in such utilities (as necessary) in the src/tools directory along with the port itself so that it is available to future maintainers. In the src/contrib/tcl level directory, a file called FREEBSD-upgrade should be added and it should states things like: Which files have been left out Where the original distribution was obtained from and/or the official master site. Where to send patches back to the original authors Perhaps an overview of the FreeBSD-specific changes that have been made. However, please do not import FREEBSD-upgrade with the contributed source. Rather you should cvs add FREEBSD-upgrade ; cvs ci after the initial import. Example wording from src/contrib/cpio is below: This directory contains virgin sources of the original distribution files on a "vendor" branch. Do not, under any circumstances, attempt to upgrade the files in this directory via patches and a cvs commit. New versions or official-patch versions must be imported. Please remember to import with "-ko" to prevent CVS from corrupting any vendor RCS Ids. For the import of GNU cpio 2.4.2, the following files were removed: INSTALL cpio.info mkdir.c Makefile.in cpio.texi mkinstalldirs To upgrade to a newer version of cpio, when it is available: 1. Unpack the new version into an empty directory. [Do not make ANY changes to the files.] 2. Remove the files listed above and any others that don't apply to FreeBSD. 3. Use the command: cvs import -ko -m 'Virgin import of GNU cpio v<version>' \ src/contrib/cpio GNU cpio_<version> For example, to do the import of version 2.4.2, I typed: cvs import -ko -m 'Virgin import of GNU v2.4.2' \ src/contrib/cpio GNU cpio_2_4_2 4. Follow the instructions printed out in step 3 to resolve any conflicts between local FreeBSD changes and the newer version. Do not, under any circumstances, deviate from this procedure. To make local changes to cpio, simply patch and commit to the main branch (aka HEAD). Never make local changes on the GNU branch. All local changes should be submitted to "cpio@gnu.ai.mit.edu" for inclusion in the next vendor release. obrien@FreeBSD.org - 30 March 1997 Encumbered Files It might occasionally be necessary to include an encumbered file in the FreeBSD source tree. For example, if a device requires a small piece of binary code to be loaded to it before the device will operate, and we do not have the source to that code, then the binary file is said to be encumbered. The following policies apply to including encumbered files in the FreeBSD source tree. Any file which is interpreted or executed by the system CPU(s) and not in source format is encumbered. Any file with a license more restrictive than BSD or GNU is encumbered. A file which contains downloadable binary data for use by the hardware is not encumbered, unless (1) or (2) apply to it. It must be stored in an architecture neutral ASCII format (file2c or uuencoding is recommended). Any encumbered file requires specific approval from the Core team before it is added to the CVS repository. Encumbered files go in src/contrib or src/sys/contrib. The entire module should be kept together. There is no point in splitting it, unless there is code-sharing with non-encumbered code. Object files are named arch/filename.o.uu>. Kernel files; Should always be referenced in conf/files.* (for build simplicity). Should always be in LINT, but the Core team decides per case if it should be commented out or not. The Core team can, of course, change their minds later on. The Release Engineer decides whether or not it goes in to the release. User-land files; core team The Core team decides if the code should be part of make world. release engineer The Release Engineer decides if it goes in to the release. Satoshi Asami Contributed by Peter Wemm David O'Brien Shared Libraries If you are adding shared library support to a port or other piece of - software that doesn't have one, the version numbers should follow these + software that does not have one, the version numbers should follow these rules. Generally, the resulting numbers will have nothing to do with the release version of the software. The three principles of shared library building are: Start from 1.0 If there is a change that is backwards compatible, bump minor number (note that ELF systems ignore the minor number) If there is an incompatible change, bump major number For instance, added functions and bugfixes result in the minor version number being bumped, while deleted functions, changed function call syntax etc. will force the major version number to change. Stick to version numbers of the form major.minor (x.y). Our a.out dynamic linker does not handle version numbers of the form x.y.z well. Any version number after the y (ie. the third digit) is totally ignored when comparing shared lib version numbers to decide which library to link with. Given two shared libraries that differ only in the micro revision, ld.so will link with the higher one. Ie: if you link with libfoo.so.3.3.3, the linker only records 3.3 in the headers, and will link with anything starting with libfoo.so.3.(anything >= 3).(highest available). ld.so will always use the highest minor revision. Ie: it will use libc.so.2.2 in preference to libc.so.2.0, even if the program was initially linked with libc.so.2.0. In addition, our ELF dynamic linker does not handle minor version numbers at all. However, one should still specify a major and minor version number as our Makefiles "do the right thing" based on the type of system. For non-port libraries, it is also our policy to change the shared library version number only once between releases. In addition, it is our policy to change the major shared library version number only once between major OS releases. Ie: X.0 to (X+1).0. When you make a change to a system library that requires the version number to be bumped, check the Makefile's commit logs. It is the responsibility of the committer to ensure that the first such change since the release will result in the shared library version number in the Makefile to be updated, and any subsequent changes will not. diff --git a/en_US.ISO8859-1/books/handbook/ports/chapter.sgml b/en_US.ISO8859-1/books/handbook/ports/chapter.sgml index 3c1e3122cf..4ea5e3c82b 100644 --- a/en_US.ISO8859-1/books/handbook/ports/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/ports/chapter.sgml @@ -1,1314 +1,1314 @@ Installing Applications: Packages and Ports Synopsis ports packages There is only so much you can do with FreeBSD. If you are an operating systems developer then the base system likely contains everything you need. If that is not what you are planning to do with FreeBSD then you will probably want to install additional software—perhaps a web server, or a mail reader, or a graphical environment such as KDE or GNOME. If you have used a Unix system before you will know that the typical procedure for installing third party software goes something like this: Download the software, which might be distributed in source code format, or as a binary. Unpack the software from its distribution format (typically a tarball compressed with either &man.compress.1; or &man.gzip.1;). Locate the documentation (perhaps a README file, or some files in a doc/ subdirectory) and read up on how to install the software. If the software was distributed in source format, compile it. This may involve editing a Makefile, or running a configure script, and other work. Test and install the software. And that is only if everything goes well. If you are installing a software package that was not deliberately ported to FreeBSD you may even have to go in and edit the code to make it work properly. Should you want to, you can continue to install software the traditional way with FreeBSD. However, FreeBSD provides two technologies which can save you a lot of effort; packages and ports. At the time of writing, over &os.numports; third party applications have been made available in this way. For any given application, the FreeBSD package for that application is a single file which you must download. The package contains pre-compiled copies of all the commands for the application, as well as any configuration files or documentation. A downloaded package file can be manipulated with FreeBSD package management commands, such as &man.pkg.add.1;, &man.pkg.delete.1;, &man.pkg.info.1;, and so on. Installing a new application can be carried out with a single command. A FreeBSD port for an application is a collection of files designed to automate the process of compiling an application from source code. Remember that there are a number of steps you would normally carry out if you compiled a program yourself (unpacking, patching, compiling, installing). The files that make up a port contain all the necessary information to allow the system to do this for you. You run a handful of simple commands and the source code for the application is automatically downloaded, extracted, patched, compiled, and installed for you. In fact, the ports system can also be used to generate packages which can later be manipulated with the pkg_add and friends commands. Both packages and ports understand dependencies. Suppose you want to install an application that depends on a specific library being installed. Both the application and the library have been made available as FreeBSD ports and packages. If you use the pkg_add command or the ports system to add the application, both will notice that the library has not been installed, and the commands will install the library first. Given that the two technologies are quite similar, you might be wondering why FreeBSD bothers with both. Packages and ports both have their own strengths, and which one you use will depend on your own preference. Package Benefits A compressed package tarball is typically smaller than the compressed tarball containing the source code for the application. Packages do not require any additional compilation. For large applications, such as Mozilla, KDE, or GNOME this can be important, particularly if you are on a slow system. Packages do not require you to understand the process involved in compiling software on FreeBSD. Ports Benefits Packages are normally compiled with conservative options, because they have to run on the maximum number of systems. By installing from the port, you can tweak the compilation options to (for example) generate code that is specific to a 686 processor. Some packages have compile time options relating to what they - can and can't do. For example, Apache + can and cannot do. For example, Apache can be configured with a wide variety of different builtin options. By building from the port you do not have to accept the default options, and can set them yourself. In some cases, multiple packages will exist for the same application to specify certain settings. For example, Ghostscript is available as a ghostscript package and a ghostscript-nox11 package, depending on whether or not you have installed an X11 server. This sort of rough tweaking is possible with packages, but rapidly becomes impossible if an application has more than one or two different compile time options. The licensing conditions of some software distributions forbid binary distribution. They must be distributed as source code. Some people do not trust binary distributions. At least with source code, you can (in theory) read through it and look for potential problems yourself. If you have local patches, you will need the source in order to apply them. Some people like having code around, so they can read it if they get bored, hack it, borrow from it (license permitting, of course), and so on. To keep track of updated ports, subscribe to the freebsd-ports@freebsd.org mailing list. The remainder of this chapter will explain how to use packages and ports to install and manage third party software on FreeBSD. Finding Your Application Before you can install any applications you need to know what you want, and what the application is called. FreeBSD's list of available applications is growing all the time. Currently there are over &os.numports; applications available as packages or ports. There are a number of ways to find what you want. The FreeBSD web site maintains an up-to-date searchable list of all the available applications, at http://www.FreeBSD.org/ports/. The name space is divided in to categories, and you may either search for an application by name (if you know it), or you can list all the applications available in a category. FreshPorts Dan Langille maintains FreshPorts, at http://www.freshports.org/. FreshPorts tracks changes to the applications in the ports tree as they happen, and allows you to watch one or more ports, and will send you an email when they are updated. FreshMeat If you do not know the name of the application you want, try using a site like FreshMeat (http://www.freshmeat.net/) or AppWatch (http://www.appwatch.com/) to find an application, then check back at the FreeBSD site to see if the application has been ported yet. Chern Lee Contributed by Using the Packages System Installing a Package packages installing pkg_add You can use the &man.pkg.add.1; utility to install a FreeBSD software package from a local file or from a server on the network. Downloading a Package and then Installing It Locally &prompt.root; ftp -a ftp2.freebsd.org Connected to ftp2.freebsd.org. 220 ftp2.freebsd.org FTP server (Version 6.00LS) ready. 331 Guest login ok, send your email address as password. 230- 230- This machine is in Vienna, VA, USA, hosted by Verio. 230- Questions? E-mail freebsd@vienna.verio.net. 230- 230- 230 Guest login ok, access restrictions apply. Remote system type is UNIX. Using binary mode to transfer files. ftp> cd /pub/FreeBSD/ports/packages/sysutils/ 250 CWD command successful. ftp> get lsof-4.56.4.tgz local: lsof-4.56.4.tgz remote: lsof-4.56.4.tgz 200 PORT command successful. 150 Opening BINARY mode data connection for 'lsof-4.56.4.tgz' (92375 bytes). 100% |**************************************************| 92375 00:00 ETA 226 Transfer complete. 92375 bytes received in 5.60 seconds (16.11 KB/s) ftp> exit &prompt.root; pkg_add lsof-4.56.4.tgz - If you don't have a source of local packages (such as a + If you do not have a source of local packages (such as a FreeBSD CDROM set) then it will probably be easier to use the -r option to &man.pkg.add.1;. This will cause the utility to automatically determine the correct object format and release and then to fetch and install the package from an FTP site. pkg_add &prompt.root; pkg_add -r lsof-4.56.4 This would download the correct package and add it without any further user intervention. Package files are distributed in .tgz format. You can find them at ftp://ftp.freebsd.org/pub/FreeBSD/ports/packages/, or on the FreeBSD CDROM distribution. Every CD on the FreeBSD 4-CD set (and PowerPak, etc) contains packages in the /packages directory. The layout of the packages is similar to that of the /usr/ports tree. Each category has its own directory, and every package can be found within the All directory. The directory structure of the package system is homologous to that of the ports; they work with each other to form the entire package/port system. Deleting a Package pkg_delete packages deleting To remove a previously installed software package, use the &man.pkg.delete.1; utility. &prompt.root pkg_delete xchat-1.7.1 Managing Packages packages managing &man.pkg.info.1; a utility that lists and describes the various packages installed. pkg_info &prompt.root pkg_info cvsup-16.1 A general network file distribution system optimized for CV docbook-1.2 Meta-port for the different versions of the DocBook DTD ... &man.pkg.version.1; a utility that summarizes the versions of all installed packages. It compares the package version to the current version found in the ports tree. &prompt.root pkg_version cvsup = docbook = ... The symbols in the second column indicate the relative age of the installed version and the version available in the local ports tree. Symbol Meaning = The version of the installed package matches that of the one found in the local ports tree. < The installed version is older then the one available in the ports tree. >The installed version is newer than the one found in the local ports tree. (local ports tree is probably out of date) ?The installed package cannot be found in the ports index. *There are multiple versions of the package. Miscellaneous All package information is stored within the /var/db/pkg directory. The listing of contents and descriptions of each package can be found within files in this directory. Using the Ports Collection The following sections provide basic instructions on using the ports collection to install or remove programs from your system. Installing Ports ports installing The first thing that should be explained when it comes to the ports collection is what is actually meant by a skeleton. In a nutshell, a port skeleton is a minimal set of files that are needed for a program to compile and install cleanly on FreeBSD. Each port skeleton includes: A Makefile. The Makefile contains various statements that specify how the application should be compiled and where it should be installed on your system A distinfo file. This file contains information about the files that must be downloaded to build the port, and checksums, to ensure that those files have not been corrupted during the download. A files directory. This directory contains patches to make the program compile and install on your FreeBSD system. Patches are basically small files that specify changes to particular files. They are in plain text format, and basically say Remove line 10 or Change line 26 to this .... Patches are also known as diffs because they are generated by the diff program. This directory may also contain other files used in building the port. A pkg-comment file. This is a one-line description of the program. A pkg-descr file. This is a more detailed, often multiple-line, description of the program. A pkg-plist file. This is a list of all the files that will be installed by the port. It also tells the ports system what files to remove upon deinstallation. Now that you have enough background information to know what the ports collection is used for, you are ready to install your first port. There are two ways this can be done, and each is explained below. Before we get into that however, you will need to choose a port to install. There are a few ways to do this, with the easiest method being the ports listing on the FreeBSD web site. You can browse through the ports listed there or use the search function on the site. Each port also includes a description so you can read a bit about each port before deciding to install it. Another method is to use the whereis command. To use whereis, simply type whereis <program you want to install> at the prompt, and if it is found on your system, you will be told where it is, like so: &prompt.root; whereis lsof lsof: /usr/ports/sysutils/lsof This tells us that lsof (a system utility) can be found in the /usr/ports/sysutils/lsof directory. Yet another way of finding a particular port is by using the ports collection's built-in search mechanism. To use the search feature, you will need to be in the /usr/ports directory. Once in that directory, run make search key=program-name where program-name is the name of the program you want to find. For example, if you were looking for lsof: &prompt.root; cd /usr/ports &prompt.root; make search key=lsof Port: lsof-4.56.4 Path: /usr/ports/sysutils/lsof Info: Lists information about open files (similar to fstat(1)) Maint: obrien@FreeBSD.org Index: sysutils B-deps: R-deps: The part of the output you want to pay particular attention to is the Path: line, since that tells you where to find it. The other information provided is not needed in order to install the port directly, so it will not be covered here. You must be the root user to install ports. Now that you have found a port you would like to install, you are ready to do the actual installation. Installing Ports from a CDROM ports installing from CDROM As you may have guessed from the title, everything described in this section assumes you have a FreeBSD CDROM set. If you do not, you can order one from the FreeBSD Mall. Assuming that your FreeBSD CDROM is in the drive and is mounted on /cdrom (and the mount point must be /cdrom), you are ready to install the port. To begin, change to the directory where the port you want to install lives: &prompt.root; cd /usr/ports/sysutils/lsof Once inside the lsof directory, you will see the port skeleton. The next step is to compile (also called build) the port. This is done by simply typing make at the prompt. Once you have done so, you should see something like this: &prompt.root; make >> lsof_4.57D.freebsd.tar.gz doesn't seem to exist in /usr/ports/distfiles/. >> Attempting to fetch from file:/cdrom/ports/distfiles/. ===> Extracting for lsof-4.57 ... [extraction output snipped] ... >> Checksum OK for lsof_4.57D.freebsd.tar.gz. ===> Patching for lsof-4.57 ===> Applying FreeBSD patches for lsof-4.57 ===> Configuring for lsof-4.57 ... [configure output snipped] ... ===> Building for lsof-4.57 ... [compilation snipped] ... &prompt.root; Take notice that once the compile is complete you are returned to your prompt. The next step is to install the port. In order to install it, you simply need to tack one word onto the make command, and that word is install: &prompt.root; make install ===> Installing for lsof-4.57 ... [install routines snipped] ... ===> Generating temporary packing list ===> Compressing manual pages for lsof-4.57 ===> Registering installation for lsof-4.57 ===> SECURITY NOTE: This port has installed the following binaries which execute with increased privileges. &prompt.root; Once you are returned to your prompt, you should be able to run the application you just installed. Since lsof is a program that runs with increased privileges, a security warning is shown. During the building and installation of ports, you should take heed of any other warnings that may appear. You can save an extra step by just running make install instead of make and make install as two separate steps. Please be aware that the licenses of a few ports do not allow for inclusion on the CDROM. This could be for various reasons, including things such as registration form needs to be filled out before downloading, if redistribution is not allowed, and so on. If you wish to install a port not included on the CDROM, you will need to be online in order to do so (see the next section). Installing Ports from the Internet As with the last section, this section makes an assumption that you have a working Internet connection. If you do not, you will need to do the CDROM installation. Installing a port from the Internet is done exactly the same way as it would be if you were installing from a CDROM. The only difference between the two is that the program's source code is downloaded from the Internet instead of pulled from the CDROM. The steps involved are identical: &prompt.root; make install >> lsof_4.57D.freebsd.tar.gz doesn't seem to exist in /usr/ports/distfiles/. >> Attempting to fetch from ftp://ftp.FreeBSD.org/pub/FreeBSD/ports/distfiles/. Receiving lsof_4.57D.freebsd.tar.gz (439860 bytes): 100% 439860 bytes transferred in 18.0 seconds (23.90 kBps) ===> Extracting for lsof-4.57 ... [extraction output snipped] ... >> Checksum OK for lsof_4.57D.freebsd.tar.gz. ===> Patching for lsof-4.57 ===> Applying FreeBSD patches for lsof-4.57 ===> Configuring for lsof-4.57 ... [configure output snipped] ... ===> Building for lsof-4.57 ... [compilation snipped] ... ===> Installing for lsof-4.57 ... [install routines snipped] ... ===> Generating temporary packing list ===> Compressing manual pages for lsof-4.57 ===> Registering installation for lsof-4.57 ===> SECURITY NOTE: This port has installed the following binaries which execute with increased privileges. &prompt.root; As you can see, the only difference is the line that tells you where the system is fetching the port from. That about does it for installing ports onto your system. In the next section you will learn how to remove a port from your system. Removing Installed Ports ports removing Now that you know how to install ports, you are probably wondering how to remove them, just in case you install one and later on you decide that you installed the wrong port. The next few paragraphs will cover just that. Now we will remove our previous example (which was lsof for those of you not paying attention). As with installing ports, the first thing you must do is change to the port directory, which if you remember was /usr/ports/irc/lsof. After you change directories, you are ready to uninstall lsof. This is done with the make deinstall command: &prompt.root; cd /usr/ports/irc/lsof &prompt.root; make deinstall ===> Deinstalling for lsof-4.57 That was easy enough. You have now managed to remove lsof from your system. If you would like to reinstall it, you can do so by running make reinstall from the /usr/ports/irc/lsof directory. Troubleshooting The following sections cover some of the more frequently asked questions about the ports collection and some basic troubleshooting techniques, and what do to if a port is broken. Some Questions and Answers I thought this was going to be a discussion about modems??! Ah, you must be thinking of the serial ports on the back of your computer. We are using port here to mean the result of porting a program from one version of Unix to another. What is a patch? A patch is a small file that specifies how to go from one version of a file to another. It contains plain text, and basically says things like delete line 23, add these two lines after line 468, or change line 197 to this. They are also known as diffs because they are generated by the diff program. tarball What is all this about tarballs? It is a file ending in .tar, or with variations such as .tar.gz, .tar.Z, .tar.bz2, and even .tgz. Basically, it is a directory tree that has been archived into a single file (.tar) and optionally compressed (.gz). This technique was originally used for Tape ARchives (hence the name tar), but it is a widely used way of distributing program source code around the Internet. You can see what files are in them, or even extract them yourself by using the standard Unix tar program, which comes with the base FreeBSD system, like this: &prompt.user; tar tvzf foobar.tar.gz &prompt.user; tar xzvf foobar.tar.gz &prompt.user; tar tvf foobar.tar &prompt.user; tar xvf foobar.tar checksum And a checksum? It is a number generated by adding up all the data in the file you want to check. If any of the characters change, the checksum will no longer be equal to the total, so a simple comparison will allow you to spot the difference. I did what you said for compiling ports from a CDROM and it worked great until I tried to install the kermit port. &prompt.root; make install >> cku190.tar.gz doesn't seem to exist on this system. >> Attempting to fetch from ftp://kermit.columbia.edu/kermit/archives/. Why can it not be found? Have I got a dud CDROM? As was explained in the compiling ports from CDROM section, some ports cannot be put on the CDROM set due to licensing restrictions. Kermit is an example of that. The licensing terms for kermit do not allow us to put the tarball for it on the CDROM, so you will have to fetch it by hand—sorry! The reason why you got all those error messages was because you were not connected to the Internet at the time. Once you have downloaded it from any of the MASTER_SITES (listed in the Makefile), you can restart the install process. I did that, but when I tried to put it into /usr/ports/distfiles I got some error about not having permission. The ports mechanism looks for the tarball in /usr/ports/distfiles, but you will not be able to copy anything there because it is symlinked to the CDROM, which is read-only. You can tell it to look somewhere else by doing: &prompt.root; make DISTDIR=/where/you/put/it install Does the ports scheme only work if you have everything in /usr/ports? My system administrator says I must put everything under /u/people/guests/wurzburger, but it does not seem to work. You can use the PORTSDIR and PREFIX variables to tell the ports mechanism to use different directories. For instance, &prompt.root; make PORTSDIR=/u/people/guests/wurzburger/ports install will compile the port in /u/people/guests/wurzburger/ports and install everything under /usr/local. &prompt.root; make PREFIX=/u/people/guests/wurzburger/local install will compile it in /usr/ports and install it in /u/people/guests/wurzburger/local. And of course, &prompt.root; make PORTSDIR=../ports PREFIX=../local install will combine the two (it is too long to write fully on the page, but it should give you the general idea). imake Some ports that use &man.imake.1; (a part of the X Windows - System) don't work well with PREFIX, and will insist on + System) do not work well with PREFIX, and will insist on installing under /usr/X11R6. Similarly, some Perl ports ignore PREFIX and install in the Perl tree. Making these ports respect PREFIX is a difficult or impossible job. If you do not fancy typing all that in every time you install a port, it is a good idea to put these variables into your environment. Read the manual page for your shell for instructions on doing so. I do not have a FreeBSD CDROM, but I would like to have all the tarballs handy on my system so I do not have to wait for a download every time I install a port. Is there any way to get them all at once? To get every single tarball for the ports collection, do: &prompt.root; cd /usr/ports &prompt.root; make fetch For all the tarballs for a single ports directory, do: &prompt.root; cd /usr/ports/directory &prompt.root; make fetch and for just one port—well, you have probably guessed already. I know it is probably faster to fetch the tarballs from one of the FreeBSD mirror sites close by. Is there any way to tell the port to fetch them from servers other than the ones listed in the MASTER_SITES? Yes. If you know, for example, that ftp.FreeBSD.org is much closer to you than the sites listed in MASTER_SITES, do as follows: &prompt.root; cd /usr/ports/directory &prompt.root; make MASTER_SITE_OVERRIDE= \ ftp://ftp.FreeBSD.org/pub/FreeBSD/ports/distfiles/ fetch I want to know what files make is going to need before it tries to pull them down. make fetch-list will display a list of the files needed for a port. Is there any way to stop the port from compiling? I want to do some hacking on the source before I install it, but it is a bit tiresome to watch it and hit control-C every time. Doing make extract will stop it after it has fetched and extracted the source code. I am trying to make my own port and I want to be able to stop it compiling until I have had a chance to see if my patches worked properly. Is there something like make extract, but for patches? Yep, make patch is what you want. You will probably find the PATCH_DEBUG option useful as well. And by the way, thank you for your efforts! I have heard that some compiler options can cause bugs. Is this true? How can I make sure that I compile ports with the right settings? Yes, with version 2.6.3 of gcc (the version shipped with FreeBSD 2.1.0 and 2.1.5), the option could result in buggy code unless you used the option as well. (Most of the ports do not use ). You should be able to specify the compiler options used by something like: &prompt.root; make CFLAGS='-O2 -fno-strength-reduce' install or by editing /etc/make.conf, but unfortunately not all ports respect this. The surest way is to do make configure, then go into the source directory and inspect the Makefiles by hand, but this can get tedious if the source has lots of sub-directories, each with their own Makefiles. The default FreeBSD compiler options are quite conservative, so if you have not changed them you should not have any problems. There are so many ports it is hard to find the one I want. Is there a list anywhere of what ports are available? Look in the INDEX file in /usr/ports. If you would like to search the ports collection for a keyword, you can do that too. For example, you can find ports relevant to the LISP programming language using: &prompt.user; cd /usr/ports &prompt.user; make search key=lisp I went to install the foo port but the system suddenly stopped compiling it and starting compiling the bar port. What is going on? The foo port needs something that is supplied with bar — for instance, if foo uses graphics, bar might have a library with useful graphics processing routines. Or bar might be a tool that is needed to compile the foo port. I installed the grizzle program from the ports and frankly it is a complete waste of disk space. I want to delete it but I do not know where it put all the files. Any clues? No problem, just type: &prompt.root; pkg_delete grizzle-6.5 Alternatively, you can type: &prompt.root; cd /usr/ports/somewhere/grizzle &prompt.root; make deinstall Hang on a minute, you have to know the version number to use that command. You do not seriously expect me to remember that, do you? Not at all, you can find it out by doing: &prompt.root; pkg_info -I 'grizzle*' Information for grizzle-6.5: grizzle-6.5 - the combined piano tutorial, LOGO interpreter and shoot 'em up arcade game. The version number can also be found using the pkg_info or by typing: ls /var/db/pkg Talking of disk space, the ports directory seems to be taking up an awful lot of room. Is it safe to go in there and delete things? Yes, if you have installed the program and are fairly certain you will not need the source again, there is no point in keeping it hanging around. The best way to do this is: &prompt.root; cd /usr/ports &prompt.root; make clean which will go through all the ports subdirectories and delete everything except the skeletons for each port. I tried that and it still left all those tarballs or whatever you called them in the distfiles directory. Can I delete those as well? Yes, if you are sure you have finished with them, those can go as well. They can be removed manually, or by using make distclean. I like having lots and lots of programs to play with. Is there any way of installing all the ports in one go? Just do: &prompt.root; cd /usr/ports &prompt.root; make install Be careful, as some ports may install files with the same name. If you install two graphics ports and they both install /usr/local/bin/plot then you will obviously have problems. OK, I tried that, but I thought it would take a very long time so I went to bed and left it to get on with it. When I looked at the computer this morning, it had only done three and a half ports. Did something go wrong? No, the problem is that some of the ports need to ask you questions that we cannot answer for you (e.g., Do you want to print on A4 or US letter sized paper?) and they need to have someone on hand to answer them. I really do not want to spend all day staring at the monitor. Any better ideas? OK, do this before you go to bed/work/the local park: &prompt.root cd /usr/ports &prompt.root; make -DBATCH install This will install every port that does not require user input. Then, when you come back, do: &prompt.root; cd /usr/ports &prompt.root; make -DINTERACTIVE install to finish the job. At work, we are using frobble, which is in your ports collection, but we have altered it quite a bit to get it to do what we need. Is there any way of making our own packages, so we can distribute it more easily around our sites? No problem, assuming you know how to make patches for your changes: &prompt.root; cd /usr/ports/somewhere/frobble &prompt.root; make extract &prompt.root; cd work/frobble-2.8 [Apply your patches] &prompt.root; cd ../.. &prompt.root; make package This ports stuff is really clever. I am desperate to find out how you did it. What is the secret? Nothing secret about it at all, just look at the bsd.port.mk and bsd.port.subdir.mk files in your makefiles directory. (Readers with an aversion to intricate shell-scripts are advised not to look at the files in this directory.) Help! This Port Is Broken! - If you come across a port that doesn't work for you, there are + If you come across a port that does not work for you, there are a few things you can do, including: Fix it! The Porter's Handbook should help you do this. Gripe—by email only! Send email to the maintainer of the port first. Type make maintainer or read the Makefile to find the maintainer's email address. Remember to include the name and version of the port (send the $FreeBSD: line from the Makefile) and the output leading up to the error when you email the maintainer. If you do not get a response from the maintainer, you can use send-pr to submit a bug report. Grab the package from an ftp site near you. The master package collection is on ftp.FreeBSD.org in the packages directory, but be sure to check your local mirror first! These are more likely to work than trying to compile from source and are a lot faster as well. Use the &man.pkg.add.1; program to install the package on your system. Advanced Topics The documentation that was here has been moved to its own Porter's Handbook for ease of reference. Please go there if you wish to create and submit your own ports. diff --git a/en_US.ISO8859-1/books/handbook/ppp-and-slip/chapter.sgml b/en_US.ISO8859-1/books/handbook/ppp-and-slip/chapter.sgml index 1f52f77c59..ce6eacc707 100644 --- a/en_US.ISO8859-1/books/handbook/ppp-and-slip/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/ppp-and-slip/chapter.sgml @@ -1,2984 +1,2984 @@ Jim Mock Restructured, reorganized, and updated by PPP and SLIP Synopsis PPP SLIP If you are connecting to the Internet via modem, or wish to provide dial-up connections to the Internet for others using FreeBSD, you have the option of using PPP or SLIP. PPP user PPP PPP kernel PPP PPP over Ethernet This chapter covers three varieties of PPP; user, kernel, and PPPoE (PPP over Ethernet). It also covers setting up a SLIP client and server. The first variety of PPP that will be covered is User PPP. User PPP was introduced into FreeBSD in 2.0.5-RELEASE as an addition to the already existing kernel implementation of PPP. You may be wondering what the main difference is between User PPP and kernel PPP. The answer is simple; user PPP processes the inbound and outbound data in userland rather than in the kernel. This is expensive in terms of copying the data between the kernel and userland, but allows a far more feature-rich ppp implementation. User PPP uses the tun device to communicate with the outside world whereas kernel-ppp uses the ppp device. From here on out in this chapter, user ppp will simply be referred to as ppp unless a distinction needs to be made between it and any other PPP software such as pppd. Unless otherwise stated, all of the commands explained in this section should be executed as root. Brian Somers Originally contributed by Nik Clayton With input from Dirk Frömberg Peter Childs Using User PPP User PPP Assumptions This document assumes you have the following: ISP PPP An account with an Internet Service Provider (ISP) which you connect to using PPP. Further, you have a modem or other device connected to your system and configured correctly, which allows you to connect to your ISP. The dial-up number(s) of your ISP. PAP CHAP Unix login name password Your login name and password. This can be either a regular Unix-style login and password pair, or a PAP or CHAP login and password pair. nameserver The IP address(es) of one or more name servers. Normally, you will be given two IP addresses by your ISP to use for this. If they have not given you at least one, then you can use the enable dns command in your ppp.conf file to tell ppp to set the name servers for you. This feature depends on your ISPs PPP implementation supporting DNS negotiation. The following information may be supplied by your ISP, but is not completely necessary: The IP address of your ISP's gateway. The gateway is the machine to which you will connect and will be set up as your default route. If you do not have this information, we can make one up and your ISP's PPP server will tell us the correct value when we connect. This IP number is referred to as HISADDR by ppp. The netmask you should use. If your ISP has not provided you with one, you can safely use 255.255.255.255. static IP address If your ISP provides you with a static IP address and hostname, you can enter it. Otherwise, we simply let the peer assign whatever IP address it sees fit. If you do not have any of the required information, contact your ISP and make sure they provide it to you. Preparing the Kernel As previously mentioned, ppp uses the tun device. If this device has not been compiled into your kernel, ppp will load it on demand as a module. The tunnel driver is dynamic, so any number of devices may be created (you are not limited by any kernel configuration values). It should be noted that the tunnel driver creates devices - on demand, so ifconfig -a won't necessarily + on demand, so ifconfig -a will not necessarily show up with any tun devices. Check the <devicename>tun</devicename> Device Under normal circumstances, most users will only use one tun device (/dev/tun0). References to tun0 below may be changed to tunN where N is any unit number. For FreeBSD installations that do not have DEVFS enabled, the existence of the tun0 device should be verified (this is not necessary if DEVFS is enabled as device nodes will be created on demand). The easiest way to make sure that the tun0 device is configured correctly, is to remake the device. To remake the device, do the following: &prompt.root; cd /dev &prompt.root; ./MAKEDEV tun0 If you need 16 tunnel devices in your kernel, you will need to create them. This can be done by executing the following commands: &prompt.root; cd /dev &prompt.root; ./MAKEDEV tun15 Name Resolution Configuration resolver hostname hosts The resolver is the part of the system that turns IP addresses into hostnames and vice versa. It can be configured to look for maps that describe IP to hostname mappings in one of two places. The first is a file called /etc/hosts. Read &man.hosts.5; for more information. The second is the Internet Domain Name Service (DNS), a distributed data base, the discussion of which is beyond the scope of this document. The resolver is a set of system calls that do the name mappings, but you have to tell it where to find the information. For versions of FreeBSD prior to 5.0, you do this by first editing the file /etc/host.conf. FreeBSD 5.0 uses the /etc/nsswitch.conf file. Edit <filename>/etc/host.conf</filename> For versions of FreeBSD prior to 5.0, this file should contain the following two lines (in this order): hosts bind This instructs the resolver to first look in the file /etc/hosts, and then to consult the DNS if the name was not found. Edit <filename>/etc/nsswitch.conf</filename> For FreeBSD version 5.0 or above, this file should contain at least the following line: hosts: files, dns This instructs the resolver to first look in the file /etc/hosts, and then to consult the DNS if the name was not found. Edit <filename>/etc/hosts</filename> This file may contain the IP addresses and names of machines on your network. At a bare minimum it should contain entries for the machine which will be running ppp. Assuming that your machine is called foo.bar.com with the IP address 10.0.0.1, /etc/hosts should contain: 127.0.0.1 localhost.bar.com localhost ::1 localhost.bar.com localhost 10.0.0.1 foo.bar.com foo The first two lines define the alias localhost as a synonym for the current machine. Regardless of your own IP address, the IP addresses for these lines should always be 127.0.0.1 and ::1. The last line maps the name foo.bar.com (and the shorthand foo) to the IP address 10.0.0.1. If your provider allocates you a static IP address and name, and you are not using that as your host name, add this to the /etc/hosts too. Edit <filename>/etc/resolv.conf</filename> The /etc/resolv.conf file tells the resolver how to behave. Normally, you will need to enter the following line(s): domain bar.com nameserver x.x.x.x nameserver y.y.y.y The x.x.x.x and y.y.y.y addresses are those given to you by your ISP. Add as many nameserver lines as your ISP provides. The domain line is set to your hosts domain name. Refer to the &man.resolv.conf.5; manual page for details of other possible entries in this file. If you are running a local name server, replace the above nameserver lines with: nameserver 0.0.0.0 PPP ISP The enable dns command (entered in the /etc/ppp/ppp.conf file - see below) will tell PPP to request that your ISP confirms the nameserver values. If your ISP supplies different addresses (or if there are no nameserver lines in /etc/resolv.conf), PPP will rewrite the file with the ISP-supplied values. <application>PPP</application> Configuration PPPconfiguration Both ppp and pppd (the kernel level implementation of PPP) use the configuration files located in the /etc/ppp directory. Examples for user ppp can be found in /usr/share/examples/ppp/. Configuring ppp requires that you edit a number of files, depending on your requirements. What you put in them depends to some extent on whether your ISP allocates IP addresses statically (i.e., you get given one IP address, and always use that one) or dynamically (i.e., your IP address changes each time you connect to your ISP). PPP and Static IP Addresses PPPwith static IP addresses You will need to edit the /etc/ppp/ppp.conf configuration file. It should look similar to the example below. Lines that end in a : start in the first column, all other lines should be indented as shown using spaces or tabs. 1 default: 2 set log Phase Chat LCP IPCP CCP tun command 3 ident user-ppp VERSION (built COMPILATIONDATE) 4 set device /dev/cuaa0 5 set speed 115200 6 set dial "ABORT BUSY ABORT NO\\sCARRIER TIMEOUT 5 \ 7 \"\" AT OK-AT-OK ATE1Q0 OK \\dATDT\\TTIMEOUT 40 CONNECT" 8 set timeout 180 9 enable dns 10 11 provider: 12 set phone "(123) 456 7890" 13 set authname foo 14 set authkey bar 15 set login "TIMEOUT 10 \"\" \"\" gin:--gin: \\U word: \\P col: ppp" 16 set timeout 300 17 set ifaddr x.x.x.x y.y.y.y 255.255.255.255 0.0.0.0 18 add default HISADDR Do not include the line numbers, they are just for reference in this discussion. Line 1: Identifies the default entry. Commands in this entry are executed automatically when ppp is run. Line 2: Enables logging parameters. When the configuration is working satisfactorily, this line should be reduced to saying set log phase tun in order to avoid excessive log file sizes. Line 3: Tells PPP how to identify itself to the peer. PPP identifies itself to the peer if it has any trouble negotiating and setting up the link, providing information that the peers administrator may find useful when investigating such problems. Line 4: Identifies the device to which the modem is connected. COM1 is /dev/cuaa0 and COM2 is /dev/cuaa1. Line 5: Sets the speed you want to connect at. If 115200 does not work (it should with any reasonably new modem), try 38400 instead. Line 6 & 7: PPPuser PPP The dial string. User PPP uses an expect-send syntax similar to the &man.chat.8; program. Refer to the manual page for information on the features of this language. Note that this command continues onto the next line for readability. Any command in ppp.conf may do this if the last character on the line is a ``\'' character. Line 8: Sets the idle timeout for the link. 180 seconds is the default, so this line is purely cosmetic. Line 9: Tells PPP to ask the peer to confirm the local resolver settings. If you run a local name server, this line should be commented out or removed. Line 10: A blank line for readability. Blank lines are ignored by PPP. Line 11: Identifies an entry for a provider called provider. Line 12: Sets the phone number for this provider. Multiple phone numbers may be specified using the colon (:) or pipe character (|)as a separator. The difference between the two separators is described in &man.ppp.8;. To summarize, if you want to rotate through the numbers, use a colon. If you want to always attempt to dial the first number first and only use the other numbers if the first number fails, use the pipe character. Always quote the entire set of phone numbers as shown. Line 13 & 14: Identifies the user name and password. When connecting using a unix-style login prompt, these values are referred to by the set login command using the \U and \P variables. When connecting using PAP or CHAP, these values are used at authentication time. Line 15: PAP CHAP If you are using PAP or CHAP, there will be no login at this point, and this line should be commented out or removed. See PAP and CHAP authentication for further details. The login string is of the same chat-like syntax as the dial string. In this example, the string works for a service whose login session looks like this: J. Random Provider login: foo password: bar protocol: ppp You will need to alter this script to suit your own needs. When you write this script for the first time, you should ensure that you have enabled chat logging so you can determine if the conversation is going as expected. Line 16: timeout Sets the default idle timeout (in seconds) for the connection. Here, the connection will be closed automatically after 300 seconds of inactivity. If you never want to timeout, set this value to zero or use the command line switch. Line 17: ISP Sets the interface addresses. The string x.x.x.x should be replaced by the IP address that your provider has allocated to you. The string y.y.y.y should be replaced by the IP address that your ISP indicated for their gateway (the machine to which you connect). If - your ISP hasn't given you a gateway address, use 10.0.0.2/0. If you need to use a guessed address, make sure that you create an entry in /etc/ppp/ppp.linkup as per the instructions for PPP and Dynamic IP addresses. If this line is omitted, ppp cannot run in mode. Line 18: Adds a default route to your ISP's gateway. The special word HISADDR is replaced with the gateway address specified on line 9. It is important that this line appears after line 9, otherwise HISADDR will not yet be initialized. If you do not wish to run ppp in , this line should be moved to the ppp.linkup file. It is not necessary to add an entry to ppp.linkup when you have a static IP address and are running ppp in mode as your routing table entries are already correct before you connect. You may however wish to create an entry to invoke programs after connection. This is explained later with the sendmail example. Example configuration files can be found in the /usr/share/examples/ppp/ directory. PPP and Dynamic IP Addresses PPPwith dynamic IP addresses IPCP If your service provider does not assign static IP addresses, ppp can be configured to negotiate the local and remote addresses. This is done by guessing an IP address and allowing ppp to set it up correctly using the IP Configuration Protocol (IPCP) after connecting. The ppp.conf configuration is the same as PPP and Static IP Addresses, with the following change: 17 set ifaddr 10.0.0.1/0 10.0.0.2/0 255.255.255.255 Again, do not include the line number, it is just for reference. Indentation of at least one space is required. Line 17: The number after the / character is the number of bits of the address that ppp will insist on. You may wish to use IP numbers more appropriate to your circumstances, but the above example will always work. The last argument (0.0.0.0) tells PPP to start negotiations using address 0.0.0.0 rather than 10.0.0.1 and is necessary for some ISPs. Do not use 0.0.0.0 as the first argument to set ifaddr as it prevents PPP from setting up an initial route in mode. If you are not running in mode, you will need to create an entry in /etc/ppp/ppp.linkup. ppp.linkup is used after a connection has been established. At this point, ppp will have assigned the interface addresses and it will now be possible to add the routing table entries: 1 provider: 2 add default HISADDR Line 1: On establishing a connection, ppp will look for an entry in ppp.linkup according to the following rules: First, try to match the same label as we used in ppp.conf. If that fails, look for an entry for the IP address of our gateway. This entry is a four-octet IP style label. If we still have not found an entry, look for the MYADDR entry. Line 2: This line tells ppp to add a default route that points to HISADDR. HISADDR will be replaced with the IP number of the gateway as negotiated by the IPCP. See the pmdemand entry in the files /usr/share/examples/ppp/ppp.conf.sample and /usr/share/examples/ppp/ppp.linkup.sample for a detailed example. Receiving Incoming Calls PPPreceiving incoming calls When you configure ppp to receive incoming calls on a machine connected to a LAN, you must decide if you wish to forward packets to the LAN. If you do, you should allocate the peer an IP number from your LAN's subnet, and use the command enable proxy in your /etc/ppp/ppp.conf file. You should also confirm that the /etc/rc.conf file contains the following: gateway="YES" Which getty? Configuring FreeBSD for Dial-up Services provides a good description on enabling dial-up services using &man.getty.8;. An alternative to getty is mgetty, a smarter version of getty designed with dial-up lines in mind. The advantages of using mgetty is that it actively talks to modems, meaning if port is turned off in /etc/ttys then your modem will not answer the phone. Later versions of mgetty (from 0.99beta onwards) also support the automatic detection of PPP streams, allowing your clients script-less access to your server. Refer to Mgetty and AutoPPP for more information on mgetty. <application>PPP</application> Permissions The ppp command must normally be run as user id 0. If however, you wish to allow ppp to run in server mode as a normal user by executing ppp as described below, that user must be given permission to run ppp by adding them to the network group in /etc/group. You will also need to give them access to one or more sections of the configuration file using the allow command: allow users fred mary If this command is used in the default section, it gives the specified users access to everything. PPP Shells for Dynamic-IP Users PPP shells Create a file called /etc/ppp/ppp-shell containing the following: #!/bin/sh IDENT=`echo $0 | sed -e 's/^.*-\(.*\)$/\1/'` CALLEDAS="$IDENT" TTY=`tty` if [ x$IDENT = xdialup ]; then IDENT=`basename $TTY` fi echo "PPP for $CALLEDAS on $TTY" echo "Starting PPP for $IDENT" exec /usr/sbin/ppp -direct $IDENT This script should be executable. Now make a symbolic link called ppp-dialup to this script using the following commands: &prompt.root; ln -s ppp-shell /etc/ppp/ppp-dialup You should use this script as the shell for all of your dialup users. This is an example from /etc/password for a dialup PPP user with username - pchilds (remember don't directly edit + pchilds (remember do not directly edit the password file, use vipw). pchilds:*:1011:300:Peter Childs PPP:/home/ppp:/etc/ppp/ppp-dialup Create a /home/ppp directory that is world readable containing the following 0 byte files: -r--r--r-- 1 root wheel 0 May 27 02:23 .hushlogin -r--r--r-- 1 root wheel 0 May 27 02:22 .rhosts which prevents /etc/motd from being displayed. PPP Shells for Static-IP Users PPP shells Create the ppp-shell file as above and for each account with statically assigned IPs create a symbolic link to ppp-shell. For example, if you have three dialup customers fred, sam, and mary, that you route class C networks for, you would type the following: &prompt.root; ln -s /etc/ppp/ppp-shell /etc/ppp/ppp-fred &prompt.root; ln -s /etc/ppp/ppp-shell /etc/ppp/ppp-sam &prompt.root; ln -s /etc/ppp/ppp-shell /etc/ppp/ppp-mary Each of these users dialup accounts should have their shell set to the symbolic link created above (i.e., mary's shell should be /etc/ppp/ppp-mary). Setting up ppp.conf for Dynamic-IP Users The /etc/ppp/ppp.conf file should contain something along the lines of: default: set debug phase lcp chat set timeout 0 ttyd0: set ifaddr 203.14.100.1 203.14.100.20 255.255.255.255 enable proxy ttyd1: set ifaddr 203.14.100.1 203.14.100.21 255.255.255.255 enable proxy The indenting is important. The default: section is loaded for each session. For each dialup line enabled in /etc/ttys create an entry similar to the one for ttyd0: above. Each line should get a unique IP address from your pool of IP addresses for dynamic users. Setting up <filename>ppp.conf</filename> for Static-IP Users Along with the contents of the sample /usr/share/examples/ppp/ppp.conf above you should add a section for each of the statically assigned dialup users. We will continue with our fred, sam, and mary example. fred: set ifaddr 203.14.100.1 203.14.101.1 255.255.255.255 sam: set ifaddr 203.14.100.1 203.14.102.1 255.255.255.255 mary: set ifaddr 203.14.100.1 203.14.103.1 255.255.255.255 The file /etc/ppp/ppp.linkup should also contain routing information for each static IP user if required. The line below would add a route for the 203.14.101.0 class C via the client's ppp link. fred: add 203.14.101.0 netmask 255.255.255.0 HISADDR sam: add 203.14.102.0 netmask 255.255.255.0 HISADDR mary: add 203.14.103.0 netmask 255.255.255.0 HISADDR More on <command>mgetty</command>, AutoPPP, and MS Extensions <command>mgetty</command> and AutoPPP mgetty AutoPPP LCP Configuring and compiling mgetty with the AUTO_PPP option enabled allows mgetty to detect the LCP phase of PPP connections and automatically spawn off a ppp shell. However, since the default login/password sequence does not occur it is necessary to authenticate users using either PAP or CHAP. This section assumes the user has successfully configured, compiled, and installed a version of mgetty with the AUTO_PPP option (v0.99beta or later). Make sure your /usr/local/etc/mgetty+sendfax/login.config file has the following in it: /AutoPPP/ - - /etc/ppp/ppp-pap-dialup This will tell mgetty to run the ppp-pap-dialup script for detected PPP connections. Create a file called /etc/ppp/ppp-pap-dialup containing the following (the file should be executable): #!/bin/sh exec /usr/sbin/ppp -direct pap$IDENT For each dialup line enabled in /etc/ttys, create a corresponding entry in /etc/ppp/ppp.conf. This will happily co-exist with the definitions we created above. pap: enable pap set ifaddr 203.14.100.1 203.14.100.20-203.14.100.40 enable proxy Each user logging in with this method will need to have a username/password in /etc/ppp/ppp.secret file, or alternatively add the following option to authenticate users via PAP from /etc/password file. enable passwdauth If you wish to assign some users a static IP number, you can specify the number as the third argument in /etc/ppp/ppp.secret. See /usr/share/examples/ppp/ppp.secret.sample for examples. MS Extensions DNS NetBIOS PPPMicrosoft extensions It is possible to configure PPP to supply DNS and NetBIOS nameserver addresses on demand. To enable these extensions with PPP version 1.x, the following lines might be added to the relevant section of /etc/ppp/ppp.conf. enable msext set ns 203.14.100.1 203.14.100.2 set nbns 203.14.100.5 And for PPP version 2 and above: accept dns set dns 203.14.100.1 203.14.100.2 set nbns 203.14.100.5 This will tell the clients the primary and secondary name server addresses, and a netbios nameserver host. In version 2 and above, if the set dns line is omitted, PPP will use the values found in /etc/resolv.conf. PAP and CHAP Authentication PAP CHAP Some ISPs set their system up so that the authentication part of your connection is done using either of the PAP or CHAP authentication mechanisms. If this is the case, your ISP will not give a login: prompt when you connect, but will start talking PPP immediately. PAP is less secure than CHAP, but security is not normally an issue here as passwords, although being sent as plain text with PAP, are being transmitted down a serial line only. There's not much room for crackers to eavesdrop. Referring back to the PPP and Static IP addresses or PPP and Dynamic IP addresses sections, the following alterations must be made: 7 set login … 12 set authname MyUserName 13 set authkey MyPassword As always, do not include the line numbers, they are just for reference in this discussion. Indentation of at least one space is required. Line 7: Your ISP will not normally require that you log into - the server if you're using PAP or CHAP. You must + the server if you are using PAP or CHAP. You must therefore disable your set login string. Line 12: This line specifies your PAP/CHAP user name. You will need to insert the correct value for MyUserName. Line 13: password This line specifies your PAP/CHAP password. You will need to insert the correct value for MyPassword. You may want to add an additional line, such as: 15 accept PAP or 15 accept CHAP to make it obvious that this is the intention, but PAP and CHAP are both accepted by default. Changing Your <command>ppp</command> Configuration on the Fly It is possible to talk to the ppp program while it is running in the background, but only if a suitable diagnostic port has been set up. To do this, add the following line to your configuration: set server /var/run/ppp-tun%d DiagnosticPassword 0177 This will tell PPP to listen to the specified unix-domain socket, asking clients for the specified password before allowing access. The %d in the name is replaced with the tun device number that is in use. Once a socket has been set up, the &man.pppctl.8; program may be used in scripts that wish to manipulate the running program. Final System Configuration PPPconfiguration You now have ppp configured, but there are a few more things to do before it is ready to work. They all involve editing the /etc/rc.conf file. Working from the top down in this file, make sure the hostname= line is set, e.g.: hostname="foo.bar.com" If your ISP has supplied you with a static IP address and - name, it's probably best that you use this name as your host + name, it is probably best that you use this name as your host name. Look for the network_interfaces variable. If you want to configure your system to dial your ISP on demand, make sure the tun0 device is added to the list, otherwise remove it. network_interfaces="lo0 tun0" ifconfig_tun0= The ifconfig_tun0 variable should be empty, and a file called /etc/start_if.tun0 should be created. This file should contain the line: ppp -auto mysystem This script is executed at network configuration time, starting your ppp daemon in automatic mode. If you have a LAN for which this machine is a gateway, you may also wish to use the switch. Refer to the manual page for further details. Set the router program to NO with following line in your /etc/rc.conf: router_enable="NO" routed It is important that the routed daemon is not started (it is started by default), as it routed tends to delete the default routing table entries created by ppp. It is probably worth your while ensuring that the sendmail_flags line does not include the option, otherwise sendmail will attempt to do a network lookup every now and then, possibly causing your machine to dial out. You may try: sendmail_flags="-bd" sendmail The downside of this is that you must force sendmail to re-examine the mail queue whenever the ppp link is up by typing: &prompt.root; /usr/sbin/sendmail -q You may wish to use the !bg command in ppp.linkup to do this automatically: 1 provider: 2 delete ALL 3 add 0 0 HISADDR 4 !bg sendmail -bd -q30m SMTP - If you don't like this, it is possible to set up a + If you do not like this, it is possible to set up a dfilter to block SMTP traffic. Refer to the sample files for further details. Now the only thing left to do is reboot the machine. All that is left is to reboot the machine. After rebooting, you can now either type: &prompt.root; ppp and then dial provider to start the PPP session, or, if you want ppp to establish sessions automatically when there is outbound traffic (and you have not created the start_if.tun0 script), type: &prompt.root; ppp -auto provider Summary To recap, the following steps are necessary when setting up ppp for the first time: Client side: Ensure that the tun device is built into your kernel. Ensure that the tunX device file is available in the /dev directory. Create an entry in /etc/ppp/ppp.conf. The pmdemand example should suffice for most ISPs. If you have a dynamic IP address, create an entry in /etc/ppp/ppp.linkup. Update your /etc/rc.conf file. Create a start_if.tun0 script if you require demand dialing. Server side: Ensure that the tun device is built into your kernel. Ensure that the tunX device file is available in the /dev directory. Create an entry in /etc/passwd (using the &man.vipw.8; program). Create a profile in this users home directory that runs ppp -direct direct-server or similar. Create an entry in /etc/ppp/ppp.conf. The direct-server example should suffice. Create an entry in /etc/ppp/ppp.linkup. Update your /etc/rc.conf file. Gennady B. Sorokopud Parts originally contributed by Robert Huff Using Kernel PPP Setting up Kernel PPP PPPkernel PPP Before you start setting up PPP on your machine make sure that pppd is located in /usr/sbin and the directory /etc/ppp exists. pppd can work in two modes: As a client, i.e., you want to connect your machine to the outside world via a PPP serial connection or modem line. PPPserver as a server, i.e. your machine is located on the network and used to connect other computers using PPP. In both cases you will need to set up an options file (/etc/ppp/options or ~/.ppprc if you have more than one user on your machine that uses PPP). You also will need some modem/serial software (preferably kermit) so you can dial and establish a connection with the remote host. Using <command>pppd</command> as a Client PPPclient Cisco The following /etc/ppp/options might be used to connect to a CISCO terminal server PPP line. crtscts # enable hardware flow control modem # modem control line noipdefault # remote PPP server must supply your IP address. # if the remote host doesn't send your IP during IPCP # negotiation , remove this option passive # wait for LCP packets domain ppp.foo.com # put your domain name here :<remote_ip> # put the IP of remote PPP host here # it will be used to route packets via PPP link # if you didn't specified the noipdefault option # change this line to <local_ip>:<remote_ip> defaultroute # put this if you want that PPP server will be your # default router To connect: kermit modem Dial to the remote host using kermit (or some other modem program), and enter your user name and password (or whatever is needed to enable PPP on the remote host). Exit kermit (without hanging up the line). Enter the following: &prompt.root; /usr/src/usr.sbin/pppd.new/pppd /dev/tty01 19200 Be sure to use the appropriate speed and device name. Now your computer is connected with PPP. If the connection fails, you can add the option to the /etc/ppp/options file and check messages on the console to track the problem. Following /etc/ppp/pppup script will make all 3 stages automatically: #!/bin/sh ps ax |grep pppd |grep -v grep pid=`ps ax |grep pppd |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing pppd, PID=' ${pid} kill ${pid} fi ps ax |grep kermit |grep -v grep pid=`ps ax |grep kermit |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing kermit, PID=' ${pid} kill -9 ${pid} fi ifconfig ppp0 down ifconfig ppp0 delete kermit -y /etc/ppp/kermit.dial pppd /dev/tty01 19200 kermit /etc/ppp/kermit.dial is a kermit script that dials and makes all necessary authorization on the remote host (an example of such a script is attached to the end of this document). Use the following /etc/ppp/pppdown script to disconnect the PPP line: #!/bin/sh pid=`ps ax |grep pppd |grep -v grep|awk '{print $1;}'` if [ X${pid} != "X" ] ; then echo 'killing pppd, PID=' ${pid} kill -TERM ${pid} fi ps ax |grep kermit |grep -v grep pid=`ps ax |grep kermit |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing kermit, PID=' ${pid} kill -9 ${pid} fi /sbin/ifconfig ppp0 down /sbin/ifconfig ppp0 delete kermit -y /etc/ppp/kermit.hup /etc/ppp/ppptest Check to see if PPP is still running by executing /usr/etc/ppp/ppptest, which should look like this: #!/bin/sh pid=`ps ax| grep pppd |grep -v grep|awk '{print $1;}'` if [ X${pid} != "X" ] ; then echo 'pppd running: PID=' ${pid-NONE} else echo 'No pppd running.' fi set -x netstat -n -I ppp0 ifconfig ppp0 To hang up the modem, execute /etc/ppp/kermit.hup, which should contain: set line /dev/tty01 ; put your modem device here set speed 19200 set file type binary set file names literal set win 8 set rec pack 1024 set send pack 1024 set block 3 set term bytesize 8 set command bytesize 8 set flow none pau 1 out +++ inp 5 OK out ATH0\13 echo \13 exit Here is an alternate method using chat instead of kermit. The following two files are sufficient to accomplish a pppd connection. /etc/ppp/options: /dev/cuaa1 115200 crtscts # enable hardware flow control modem # modem control line connect "/usr/bin/chat -f /etc/ppp/login.chat.script" noipdefault # remote PPP serve must supply your IP address. # if the remote host doesn't send your IP during # IPCP negotiation, remove this option passive # wait for LCP packets domain <your.domain> # put your domain name here : # put the IP of remote PPP host here # it will be used to route packets via PPP link # if you didn't specified the noipdefault option # change this line to <local_ip>:<remote_ip> defaultroute # put this if you want that PPP server will be # your default router /etc/ppp/login.chat.script: The following should go on a single line. ABORT BUSY ABORT 'NO CARRIER' "" AT OK ATDT<phone.number> CONNECT "" TIMEOUT 10 ogin:-\\r-ogin: <login-id> TIMEOUT 5 sword: <password> Once these are installed and modified correctly, all you need to do is run pppd, like so: &prompt.root; pppd This sample is based primarily on information provided by: Trev Roydhouse <Trev.Roydhouse@f401.n711.z3.fidonet.org> and used with permission. Using <command>pppd</command> as a Server /etc/ppp/options should contain something similar to the following: crtscts # Hardware flow control netmask 255.255.255.0 # netmask ( not required ) 192.114.208.20:192.114.208.165 # ip's of local and remote hosts # local ip must be different from one # you assigned to the ethernet ( or other ) # interface on your machine. # remote IP is ip address that will be # assigned to the remote machine domain ppp.foo.com # your domain passive # wait for LCP modem # modem line The following /etc/ppp/pppserv script will enable tell pppd to behave as a server: #!/bin/sh ps ax |grep pppd |grep -v grep pid=`ps ax |grep pppd |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing pppd, PID=' ${pid} kill ${pid} fi ps ax |grep kermit |grep -v grep pid=`ps ax |grep kermit |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing kermit, PID=' ${pid} kill -9 ${pid} fi # reset ppp interface ifconfig ppp0 down ifconfig ppp0 delete # enable autoanswer mode kermit -y /etc/ppp/kermit.ans # run ppp pppd /dev/tty01 19200 Use this /etc/ppp/pppservdown script to stop the server: #!/bin/sh ps ax |grep pppd |grep -v grep pid=`ps ax |grep pppd |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing pppd, PID=' ${pid} kill ${pid} fi ps ax |grep kermit |grep -v grep pid=`ps ax |grep kermit |grep -v grep|awk '{print $1;}'` if [ "X${pid}" != "X" ] ; then echo 'killing kermit, PID=' ${pid} kill -9 ${pid} fi ifconfig ppp0 down ifconfig ppp0 delete kermit -y /etc/ppp/kermit.noans The following kermit script (/etc/ppp/kermit.ans) will enable/disable autoanswer mode on your modem. It should look like this: set line /dev/tty01 set speed 19200 set file type binary set file names literal set win 8 set rec pack 1024 set send pack 1024 set block 3 set term bytesize 8 set command bytesize 8 set flow none pau 1 out +++ inp 5 OK out ATH0\13 inp 5 OK echo \13 out ATS0=1\13 ; change this to out ATS0=0\13 if you want to disable ; autoanswer mod inp 5 OK echo \13 exit A script named /etc/ppp/kermit.dial is used for dialing and authenticating on the remote host. You will need to customize it for your needs. Put your login and password in this script; you will also need to change the input statement depending on responses from your modem and remote host. ; ; put the com line attached to the modem here: ; set line /dev/tty01 ; ; put the modem speed here: ; set speed 19200 set file type binary ; full 8 bit file xfer set file names literal set win 8 set rec pack 1024 set send pack 1024 set block 3 set term bytesize 8 set command bytesize 8 set flow none set modem hayes set dial hangup off set carrier auto ; Then SET CARRIER if necessary, set dial display on ; Then SET DIAL if necessary, set input echo on set input timeout proceed set input case ignore def \%x 0 ; login prompt counter goto slhup :slcmd ; put the modem in command mode echo Put the modem in command mode. clear ; Clear unread characters from input buffer pause 1 output +++ ; hayes escape sequence input 1 OK\13\10 ; wait for OK if success goto slhup output \13 pause 1 output at\13 input 1 OK\13\10 if fail goto slcmd ; if modem doesn't answer OK, try again :slhup ; hang up the phone clear ; Clear unread characters from input buffer pause 1 echo Hanging up the phone. output ath0\13 ; hayes command for on hook input 2 OK\13\10 if fail goto slcmd ; if no OK answer, put modem in command mode :sldial ; dial the number pause 1 echo Dialing. output atdt9,550311\13\10 ; put phone number here assign \%x 0 ; zero the time counter :look clear ; Clear unread characters from input buffer increment \%x ; Count the seconds input 1 {CONNECT } if success goto sllogin reinput 1 {NO CARRIER\13\10} if success goto sldial reinput 1 {NO DIALTONE\13\10} if success goto slnodial reinput 1 {\255} if success goto slhup reinput 1 {\127} if success goto slhup if < \%x 60 goto look else goto slhup :sllogin ; login assign \%x 0 ; zero the time counter pause 1 echo Looking for login prompt. :slloop increment \%x ; Count the seconds clear ; Clear unread characters from input buffer output \13 ; ; put your expected login prompt here: ; input 1 {Username: } if success goto sluid reinput 1 {\255} if success goto slhup reinput 1 {\127} if success goto slhup if < \%x 10 goto slloop ; try 10 times to get a login prompt else goto slhup ; hang up and start again if 10 failures :sluid ; ; put your userid here: ; output ppp-login\13 input 1 {Password: } ; ; put your password here: ; output ppp-password\13 input 1 {Entering SLIP mode.} echo quit :slnodial echo \7No dialtone. Check the telephone line!\7 exit 1 ; local variables: ; mode: csh ; comment-start: "; " ; comment-start-skip: "; " ; end: Jim Mock Contributed (from http://node.to/freebsd/how-tos/how-to-freebsd-pppoe.html) by Using <application>PPP</application> over Ethernet (PPPoE) PPPover Ethernet PPPoE PPP, over Ethernet The following describes how to set up PPP over Ethernet, a.k.a, PPPoE. Prerequisites There are a few requirements that your system will need to meet in order for PPPoE to function properly. They are: Kernel source for FreeBSD 3.4 or later ppp from FreeBSD 3.4 or later Kernel Configuration kernelconfiguration You will need to set the following options in your kernel configuration file and then compile a new kernel. Optionally, you can add although if this functionality is not available at runtime, ppp will load the relevant modules on demand Setting up <filename>ppp.conf</filename> Here is an example of a working ppp.conf: default: # or name_of_service_provider set device PPPoE:xl1 # replace xl1 with your ethernet device set mru 1492 set mtu 1492 set authname YOURLOGINNAME set authkey YOURPASSWORD set log Phase tun command # you can add more detailed logging if you wish set dial set login set ifaddr 10.0.0.1/0 10.0.0.2/0 add default HISADDR nat enable yes # if you want to enable nat for your local net papchap: set authname YOURLOGINNAME set authkey YOURPASSWORD Care should be taken when running PPPoE with the option. Running <application>PPP</application> As root, you can run: &prompt.root; ppp -ddial name_of_service_provider Starting <application>PPP</application> at Boot Add the following to your /etc/rc.conf file: ppp_enable="YES" ppp_mode="ddial" ppp_nat="YES" ppp_profile="default" # or your provider Mário Sérgio Fujikawa Ferreira Contributed by PPPoE with a 3Com HomeConnect ADSL Modem Dual Link In short, it does not work. It should, but unfortunately, that is not the case. For whatever reason, this modem does not follow RFC 2516 (A Method for transmitting PPP over Ethernet (PPPoE), written by L. Mamakos, K. Lidl, J. Evarts, D. Carrel, D. Simone, and R. Wheeler). Since it does not follow the specification, FreeBSD's PPPoE implementation will not talk to it. It is very likely that it will not work under other Unix systems for that same reason. Complain to 3Com if you think it should comply with the PPPoE specification. ADSL If you absolutely want to use your ADSL connection with FreeBSD and are stuck with this modem, you can either: DSL Try replacing the modem with a different brand or model if your DSL provider permits you to do so. If you are not sure which brand(s) will work, the &a.questions; is a good place to ask. Try to get it working. Keep in mind that there is no guarantee it will work, your mileage may vary. If you want to try to make it work, you can do the following, but please keep in mind that you do this at your own risk! Just because it worked for me does not mean it will work for you. There are three steps to the process. They are: Make sure you already have ppp.conf set up. See the beginning of this chapter for more details on doing so. Since the modem does not speak the correct protocol, we need to learn how to speak its variant of the protocol. This information was obtained from a DSLreports forum message. The modem speaks 0x3c12 for DISCOVERY, and 0x3c13 for PAYLOAD identifiers instead of 0x8863 and 0x8864 respectively, as mandated by the PPPoE specification. Code RFC's Code Dual Link Modem's Code PAYLOAD 0x8863 0x3c12 PAYLOAD 0x8864 0x3c13 So, now what? You need to recompile the NETGRAPH_PPPOE code with the modem's codes. For this, you should have installed the full kernel sources. Find the /usr/src/sys/netgraph/ng_pppoe.h file. Be careful while editing this file. You have to modify both the little and the big endian entries. For big endian, find the line with 0x8863 in it, and replace the number with 0x3c12. Do the same with 0x8864, replacing it with 0x3c13. For little endian, find the line with 0x6388in it, and replace the number with 0x123c. Do the same with 0x6488, replacing it with 0x133c. Here is a diff of how the new file should look: &prompt.user; diff -u ng_pppoe.h.orig ng_pppoe.h --- ng_pppoe.h.orig Thu Apr 12 13:42:46 2001 +++ ng_pppoe.h Thu Apr 12 13:44:47 2001 @@ -148,8 +148,8 @@ #define PTT_SYS_ERR (0x0202) #define PTT_GEN_ERR (0x0203) -#define ETHERTYPE_PPPOE_DISC 0x8863 /* pppoe discovery packets */ -#define ETHERTYPE_PPPOE_SESS 0x8864 /* pppoe session packets */ +#define ETHERTYPE_PPPOE_DISC 0x3c12 /* pppoe discovery packets */ +#define ETHERTYPE_PPPOE_SESS 0x3c13 /* pppoe session packets */ #else #define PTT_EOL (0x0000) #define PTT_SRV_NAME (0x0101) @@ -162,8 +162,8 @@ #define PTT_SYS_ERR (0x0202) #define PTT_GEN_ERR (0x0302) -#define ETHERTYPE_PPPOE_DISC 0x6388 /* pppoe discovery packets */ -#define ETHERTYPE_PPPOE_SESS 0x6488 /* pppoe session packets */ +#define ETHERTYPE_PPPOE_DISC 0x123c /* pppoe discovery packets */ +#define ETHERTYPE_PPPOE_SESS 0x133c /* pppoe session packets */ #endif struct pppoe_tag { Then do the following as root: &prompt.root; cd /usr/src/sys/modules/netgraph/pppoe &prompt.root; make clean depend all install &prompt.root; make clean Now you can speak the modem's variant of the PPPoE specification. The third step is to figure out the name of the profile your ISP assigned to the modem. The information for this step was obtained from the Roaring Penguin PPPoE program which can be found in the ports collection. If you still are not able to find it, ask your ISP's tech support. If they do not know it either, and you are feeling bold (this may de-program your modem and render it useless, so think twice about doing it). Install the program shipped with the modem by your provider. Then, access the System menu from the program. The name of your profile should be listed there. It is usually ISP. The profile name will be used in the PPPoE configuration inside ppp.conf as the provider parameter. See the &man.ppp.8; manual page for more information. The PPPoE line in your ppp.conf should look like this: set device PPPoE:xl1:ISP Do not forget to change xl1 to the proper device for your Ethernet card. Do not forget to change ISP to the profile you have just found above. For additional information, you can try: Cheaper Broadband with FreeBSD on DSL by Renaud Waldura in Daemon News. Another PPPoE tutorial by Sympatico Users Group. Satoshi Asami Originally contributed by Guy Helmer With input from Piero Serini Using SLIP SLIP Setting up a SLIP Client SLIPclient The following is one way to set up a FreeBSD machine for SLIP on a static host network. For dynamic hostname assignments (i.e., your address changes each time you dial up), you probably need to do something much fancier. First, determine which serial port your modem is connected to. I have a symbolic link to /dev/modem from /dev/cuaa1, and only use the modem name in my configuration files. It can become quite cumbersome when you need to fix a bunch of files in /etc and .kermrc's all over the system! /dev/cuaa0 is COM1, cuaa1 is COM2, etc. Make sure you have the following in your kernel configuration file: pseudo-device sl 1 It is included in the GENERIC kernel, so this should not be a problem unless you have deleted it. Things You Have to Do Only Once Add your home machine, the gateway and nameservers to your /etc/hosts file. Mine looks like this: 127.0.0.1 localhost loghost 136.152.64.181 silvia.HIP.Berkeley.EDU silvia.HIP silvia 136.152.64.1 inr-3.Berkeley.EDU inr-3 slip-gateway 128.32.136.9 ns1.Berkeley.edu ns1 128.32.136.12 ns2.Berkeley.edu ns2 Make sure you have before in your /etc/host.conf. Otherwise, funny things may happen. Edit the /etc/rc.conf file. Set your hostname by editing the line that says: hostname=myname.my.domain You should give it your full Internet hostname. Add sl0 to the list of network interfaces by changing the line that says: network_interfaces="lo0" to: network_interfaces=lo0 sl0 Set the startup flags of sl0 by adding a line: ifconfig_sl0="inet ${hostname} slip-gateway netmask 0xffffff00 up" default route Designate the default router by changing the line: defaultrouter=NO to: defaultrouter=slip-gateway Make a file /etc/resolv.conf which contains: domain HIP.Berkeley.EDU nameserver 128.32.136.9 nameserver 128.32.136.12 nameserver domain name As you can see, these set up the nameserver hosts. Of course, the actual domain names and addresses depend on your environment. Set the password for root and toor (and any other accounts that do not have a password). Use passwd or &man.vipw.8;, do not edit the /etc/passwd or /etc/master.passwd files! Reboot your machine and make sure it comes up with the correct hostname. Making a SLIP Connection SLIPconnecting with Dial up, type slip at the prompt, enter your machine name and password. The things you need to enter depends on your environment. If you use kermit, you can try a script like this: # kermit setup set modem hayes set line /dev/modem set speed 115200 set parity none set flow rts/cts set terminal bytesize 8 set file type binary # The next macro will dial up and login define slip dial 643-9600, input 10 =>, if failure stop, - output slip\x0d, input 10 Username:, if failure stop, - output silvia\x0d, input 10 Password:, if failure stop, - output ***\x0d, echo \x0aCONNECTED\x0a Of course, you have to change the hostname and password to fit yours. After doing so, you can just type slip from the kermit prompt to get connected. Leaving your password in plain text anywhere in the filesystem is generally a BAD idea. Do it at your own risk. Leave the kermit there (you can suspend it by z) and as root, type: &prompt.root; slattach -h -c -s 115200 /dev/modem If you are able to ping hosts on the other side of the router, you are connected! If it does not work, you might want to try instead of as an argument to slattach. How to Shutdown the Connection Do the following: &prompt.root; kill -INT `cat /var/run/slattach.modem.pid` to kill slattach. Keep in mind you must be root to do the above. Then go back to kermit (fg if you suspended it) and exit from it (q). The slattach manual page says you have to use ifconfig sl0 down to mark the interface down, but this does not seem to make any difference for me. (ifconfig sl0 reports the same thing.) Some times, your modem might refuse to drop the carrier (mine often does). In that case, simply start kermit and quit it again. It usually goes out on the second try. Troubleshooting If it does not work, feel free to ask me. The things that people tripped over so far: Not using or in slattach (I have no idea why this can be fatal, but adding this flag solved the problem for at least one person). Using instead of (might be hard to see the difference on some fonts). Try ifconfig sl0 to see your interface status. For example, you might get: &prompt.root; ifconfig sl0 sl0: flags=10<POINTOPOINT> inet 136.152.64.181 --> 136.152.64.1 netmask ffffff00 Also, netstat -r will give the routing table, in case you get the no route to host messages from ping. Mine looks like: &prompt.root; netstat -r Routing tables Destination Gateway Flags Refs Use IfaceMTU Rtt Netmasks: (root node) (root node) Route Tree for Protocol Family inet: (root node) => default inr-3.Berkeley.EDU UG 8 224515 sl0 - - localhost.Berkel localhost.Berkeley UH 5 42127 lo0 - 0.438 inr-3.Berkeley.E silvia.HIP.Berkele UH 1 0 sl0 - - silvia.HIP.Berke localhost.Berkeley UGH 34 47641234 lo0 - 0.438 (root node) This is after transferring a bunch of files, your numbers should be smaller). Setting up a SLIP Server SLIPserver This document provides suggestions for setting up SLIP Server services on a FreeBSD system, which typically means configuring your system to automatically startup connections upon login for remote SLIP clients. The author has written this document based on his experience; however, as your system and needs may be different, this document may not answer all of your questions, and the author cannot be responsible if you damage your system or lose data due to attempting to follow the suggestions here. Prerequisites TCP/IP networking This document is very technical in nature, so background knowledge is required. It is assumed that you are familiar with the TCP/IP network protocol, and in particular, network and node addressing, network address masks, subnetting, routing, and routing protocols, such as RIP. Configuring SLIP services on a dial-up server requires a knowledge of these concepts, and if you are not familiar with them, please read a copy of either Craig Hunt's TCP/IP Network Administration published by O'Reilly & Associates, Inc. (ISBN Number 0-937175-82-X), or Douglas Comer's books on the TCP/IP protocol. modem It is further assumed that you have already setup your modem(s) and configured the appropriate system files to allow logins through your modems. If you have not prepared your system for this yet, please see the tutorial for configuring dialup services; if you have a World-Wide Web browser available, browse the list of tutorials at http://www.FreeBSD.org/. You may also want to check the manual pages for &man.sio.4; for information on the serial port device driver and &man.ttys.5;, &man.gettytab.5;, &man.getty.8;, & &man.init.8; for information relevant to configuring the system to accept logins on modems, and perhaps &man.stty.1; for information on setting serial port parameters (such as clocal for directly-connected serial interfaces). Quick Overview In its typical configuration, using FreeBSD as a SLIP server works as follows: a SLIP user dials up your FreeBSD SLIP Server system and logs in with a special SLIP login ID that uses /usr/sbin/sliplogin as the special user's shell. The sliplogin program browses the file /etc/sliphome/slip.hosts to find a matching line for the special user, and if it finds a match, connects the serial line to an available SLIP interface and then runs the shell script /etc/sliphome/slip.login to configure the SLIP interface. An Example of a SLIP Server Login For example, if a SLIP user ID were Shelmerg, Shelmerg's entry in /etc/master.passwd would look something like this (except it would be all on one line): Shelmerg:password:1964:89::0:0:Guy Helmer - SLIP:/usr/users/Shelmerg:/usr/sbin/sliplogin When Shelmerg logs in, sliplogin will search /etc/sliphome/slip.hosts for a line that had a matching user ID; for example, there may be a line in /etc/sliphome/slip.hosts that reads: Shelmerg dc-slip sl-helmer 0xfffffc00 autocomp sliplogin will find that matching line, hook the serial line into the next available SLIP interface, and then execute /etc/sliphome/slip.login like this: /etc/sliphome/slip.login 0 19200 Shelmerg dc-slip sl-helmer 0xfffffc00 autocomp If all goes well, /etc/sliphome/slip.login will issue an ifconfig for the SLIP interface to which sliplogin attached itself (slip interface 0,in the above example, which was the first parameter in the list given to slip.login) to set the local IP address (dc-slip), remote IP address (sl-helmer), network mask for the SLIP interface (0xfffffc00), and any additional flags (autocomp). If something goes wrong, sliplogin usually logs good informational messages via the daemon syslog facility, which usually goes into /var/log/messages (see the manual pages for &man.syslogd.8; and &man.syslog.conf.5; and perhaps check /etc/syslog.conf to see to which files syslogd is logging). OK, enough of the examples — let us dive into setting up the system. Kernel Configuration kernelconfiguration FreeBSD's default kernels usually come with two SLIP interfaces defined (sl0 and sl1); you can use netstat -i to see whether these interfaces are defined in your kernel. Sample output from netstat -i: Name Mtu Network Address Ipkts Ierrs Opkts Oerrs Coll ed0 1500 <Link>0.0.c0.2c.5f.4a 291311 0 174209 0 133 ed0 1500 138.247.224 ivory 291311 0 174209 0 133 lo0 65535 <Link> 79 0 79 0 0 lo0 65535 loop localhost 79 0 79 0 0 sl0* 296 <Link> 0 0 0 0 0 sl1* 296 <Link> 0 0 0 0 0 The sl0 and sl1 interfaces shown in netstat -i's output indicate that there are two SLIP interfaces built into the kernel. (The asterisks after the sl0 and sl1 indicate that the interfaces are down.) However, FreeBSD's default kernels do not come configured to forward packets (ie, your FreeBSD machine will not act as a router) due to Internet RFC requirements for Internet hosts (see RFCs 1009 [Requirements for Internet Gateways], 1122 [Requirements for Internet Hosts — Communication Layers], and perhaps 1127 [A Perspective on the Host Requirements RFCs]), so if you want your FreeBSD SLIP Server to act as a router, you will have to edit the /etc/rc.conf file and change the setting of the gateway_enable variable to . You will then need to reboot for the new settings to take effect. You will notice that near the end of the default kernel configuration file (/sys/i386/conf/GENERIC) is a line that reads: pseudo-device sl 2 SLIP This is the line that defines the number of SLIP devices available in the kernel; the number at the end of the line is the maximum number of SLIP connections that may be operating simultaneously. Please refer to Configuring the FreeBSD Kernel for help in reconfiguring your kernel. Sliplogin Configuration As mentioned earlier, there are three files in the /etc/sliphome directory that are part of the configuration for /usr/sbin/sliplogin (see &man.sliplogin.8; for the actual manual page for sliplogin): slip.hosts, which defines the SLIP users & their associated IP addresses; slip.login, which usually just configures the SLIP interface; and (optionally) slip.logout, which undoes slip.login's effects when the serial connection is terminated. <filename>slip.hosts</filename> Configuration /etc/sliphome/slip.hosts contains lines which have at least four items, separated by whitespace: SLIP user's login ID Local address (local to the SLIP server) of the SLIP link Remote address of the SLIP link Network mask The local and remote addresses may be host names (resolved to IP addresses by /etc/hosts or by the domain name service, depending on your specifications in /etc/host.conf), and the network mask may be a name that can be resolved by a lookup into /etc/networks. On a sample system, /etc/sliphome/slip.hosts looks like this: # # login local-addr remote-addr mask opt1 opt2 # (normal,compress,noicmp) # Shelmerg dc-slip sl-helmerg 0xfffffc00 autocomp At the end of the line is one or more of the options. — no header compression — compress headers — compress headers if the remote end allows it — disable ICMP packets (so any ping packets will be dropped instead of using up your bandwidth) Note that sliplogin under early releases of FreeBSD 2 ignored the options that FreeBSD 1.x recognized, so the options , , , and had no effect until support was added in FreeBSD 2.2 (unless your slip.login script included code to make use of the flags). SLIP TCP/IP networking Your choice of local and remote addresses for your SLIP links depends on whether you are going to dedicate a TCP/IP subnet or if you are going to use proxy ARP on your SLIP server (it is not true proxy ARP, but that is the terminology used in this document to describe it). If you are not sure which method to select or how to assign IP addresses, please refer to the TCP/IP books referenced in the slips-prereqs section and/or consult your IP network manager. gated If you are going to use a separate subnet for your SLIP clients, you will need to allocate the subnet number out of your assigned IP network number and assign each of your SLIP client's IP numbers out of that subnet. Then, you will probably either need to configure a static route to the SLIP subnet via your SLIP server on your nearest IP router, or install gated on your FreeBSD SLIP server and configure it to talk the appropriate routing protocols to your other routers to inform them about your SLIP server's route to the SLIP subnet. Ethernet Otherwise, if you will use the proxy ARP method, you will need to assign your SLIP client's IP addresses out of your SLIP server's Ethernet subnet, and you will also need to adjust your /etc/sliphome/slip.login and /etc/sliphome/slip.logout scripts to use &man.arp.8; to manage the proxy-ARP entries in the SLIP server's ARP table. <filename>slip.login</filename> Configuration The typical /etc/sliphome/slip.login file looks like this: #!/bin/sh - # # @(#)slip.login 5.1 (Berkeley) 7/1/90 # # generic login file for a slip line. sliplogin invokes this with # the parameters: # 1 2 3 4 5 6 7-n # slipunit ttyspeed loginname local-addr remote-addr mask opt-args # /sbin/ifconfig sl$1 inet $4 $5 netmask $6 This slip.login file merely ifconfig's the appropriate SLIP interface with the local and remote addresses and network mask of the SLIP interface. If you have decided to use the proxy ARP method (instead of using a separate subnet for your SLIP clients), your /etc/sliphome/slip.login file will need to look something like this: #!/bin/sh - # # @(#)slip.login 5.1 (Berkeley) 7/1/90 # # generic login file for a slip line. sliplogin invokes this with # the parameters: # 1 2 3 4 5 6 7-n # slipunit ttyspeed loginname local-addr remote-addr mask opt-args # /sbin/ifconfig sl$1 inet $4 $5 netmask $6 # Answer ARP requests for the SLIP client with our Ethernet addr /usr/sbin/arp -s $5 00:11:22:33:44:55 pub The additional line in this slip.login, arp -s $5 00:11:22:33:44:55 pub, creates an ARP entry in the SLIP server's ARP table. This ARP entry causes the SLIP server to respond with the SLIP server's Ethernet MAC address whenever a another IP node on the Ethernet asks to speak to the SLIP client's IP address. EthernetMAC address When using the example above, be sure to replace the Ethernet MAC address (00:11:22:33:44:55) with the MAC address of your system's Ethernet card, or your proxy ARP will definitely not work! You can discover your SLIP server's Ethernet MAC address by looking at the results of running netstat -i; the second line of the output should look something like: ed0 1500 <Link>0.2.c1.28.5f.4a 191923 0 129457 0 116 This indicates that this particular system's Ethernet MAC address is 00:02:c1:28:5f:4a — the periods in the Ethernet MAC address given by netstat -i must be changed to colons and leading zeros should be added to each single-digit hexadecimal number to convert the address into the form that &man.arp.8; desires; see the manual page on &man.arp.8; for complete information on usage. When you create /etc/sliphome/slip.login and /etc/sliphome/slip.logout, the execute bit (ie, chmod 755 /etc/sliphome/slip.login /etc/sliphome/slip.logout) must be set, or sliplogin will be unable to execute it. <filename>slip.logout</filename> Configuration /etc/sliphome/slip.logout is not strictly needed (unless you are implementing proxy ARP), but if you decide to create it, this is an example of a basic slip.logout script: #!/bin/sh - # # slip.logout # # logout file for a slip line. sliplogin invokes this with # the parameters: # 1 2 3 4 5 6 7-n # slipunit ttyspeed loginname local-addr remote-addr mask opt-args # /sbin/ifconfig sl$1 down If you are using proxy ARP, you will want to have /etc/sliphome/slip.logout remove the ARP entry for the SLIP client: #!/bin/sh - # # @(#)slip.logout # # logout file for a slip line. sliplogin invokes this with # the parameters: # 1 2 3 4 5 6 7-n # slipunit ttyspeed loginname local-addr remote-addr mask opt-args # /sbin/ifconfig sl$1 down # Quit answering ARP requests for the SLIP client /usr/sbin/arp -d $5 The arp -d $5 removes the ARP entry that the proxy ARP slip.login added when the SLIP client logged in. It bears repeating: make sure /etc/sliphome/slip.logout has the execute bit set for after you create it (ie, chmod 755 /etc/sliphome/slip.logout). Routing Considerations SLIP routing If you are not using the proxy ARP method for routing packets between your SLIP clients and the rest of your network (and perhaps the Internet), you will probably either have to add static routes to your closest default router(s) to route your SLIP client subnet via your SLIP server, or you will probably need to install and configure gated on your FreeBSD SLIP server so that it will tell your routers via appropriate routing protocols about your SLIP subnet. Static Routes static routes Adding static routes to your nearest default routers can be troublesome (or impossible, if you do not have authority to do so...). If you have a multiple-router network in your organization, some routers, such as Cisco and Proteon, may not only need to be configured with the static route to the SLIP subnet, but also need to be told which static routes to tell other routers about, so some expertise and troubleshooting/tweaking may be necessary to get static-route-based routing to work. Running <command>gated</command> gated An alternative to the headaches of static routes is to install gated on your FreeBSD SLIP server and configure it to use the appropriate routing protocols (RIP/OSPF/BGP/EGP) to tell other routers about your SLIP subnet. You can use gated from the ports collection or retrieve and build it yourself from the GateD anonymous FTP site; the current version as of this writing is gated-R3_5Alpha_8.tar.Z, which includes support for FreeBSD out-of-the-box. Complete information and documentation on gated is available on the Web starting at the Merit GateD Consortium. Compile and install it, and then write a /etc/gated.conf file to configure your gated; here is a sample, similar to what the author used on a FreeBSD SLIP server: # # gated configuration file for dc.dsu.edu; for gated version 3.5alpha5 # Only broadcast RIP information for xxx.xxx.yy out the ed Ethernet interface # # # tracing options # traceoptions "/var/tmp/gated.output" replace size 100k files 2 general ; rip yes { interface sl noripout noripin ; interface ed ripin ripout version 1 ; traceoptions route ; } ; # # Turn on a bunch of tracing info for the interface to the kernel: kernel { traceoptions remnants request routes info interface ; } ; # # Propagate the route to xxx.xxx.yy out the Ethernet interface via RIP # export proto rip interface ed { proto direct { xxx.xxx.yy mask 255.255.252.0 metric 1; # SLIP connections } ; } ; # # Accept routes from RIP via ed Ethernet interfaces import proto rip interface ed { all ; } ; RIP The above sample gated.conf file broadcasts routing information regarding the SLIP subnet xxx.xxx.yy via RIP onto the Ethernet; if you are using a different Ethernet driver than the ed driver, you will need to change the references to the ed interface appropriately. This sample file also sets up tracing to /var/tmp/gated.output for debugging gated's activity; you can certainly turn off the tracing options if gated works OK for you. You will need to change the xxx.xxx.yy's into the network address of your own SLIP subnet (be sure to change the net mask in the proto direct clause as well). When you get gated built and installed and create a configuration file for it, you will need to run gated in place of routed on your FreeBSD system; change the routed/gated startup parameters in /etc/netstart as appropriate for your system. Please see the manual page for gated for information on gated's command-line parameters. diff --git a/en_US.ISO8859-1/books/handbook/security/chapter.sgml b/en_US.ISO8859-1/books/handbook/security/chapter.sgml index b9385d687c..3eecd27ad2 100644 --- a/en_US.ISO8859-1/books/handbook/security/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/security/chapter.sgml @@ -1,3122 +1,3122 @@ Matthew Dillon Much of this chapter has been taken from the security(7) manual page by Security security Synopsis The following chapter will provide a basic introduction to system security concepts, some general good rules of thumb, and some advanced topics such as S/Key, OpenSSL, Kerberos, and others. Introduction Security is a function that begins and ends with the system administrator. While all BSD Unix multi-user systems have some inherent security, the job of building and maintaining additional security mechanisms to keep those users honest is probably one of the single largest undertakings of the sysadmin. Machines are only as secure as you make them, and security concerns are ever competing with the human necessity for convenience. Unix systems, in general, are capable of running a huge number of simultaneous processes and many of these processes operate as servers – meaning that external entities can connect and talk to them. As yesterday's mini-computers and mainframes become today's desktops, and as computers become networked and internetworked, security becomes an ever bigger issue. Security is best implemented through a layered onion approach. In a nutshell, what you want to do is to create as many layers of security as are convenient and then carefully monitor the system for intrusions. You do not want to overbuild your security or you will interfere with the detection side, and detection is one of the single most important aspects of any security mechanism. For example, it makes little sense to set the schg flags (see &man.chflags.1;) on every system binary because while this may temporarily protect the binaries, it prevents an attacker who has broken in from making an easily detectable change that may result in your security mechanisms not detecting the attacker at all. System security also pertains to dealing with various forms of attack, including attacks that attempt to crash, or otherwise make a system unusable, but do not attempt to break root. Security concerns can be split up into several categories: Denial of service attacks. User account compromises. Root compromise through accessible servers. Root compromise via user accounts. Backdoor creation. DoS attacks Denial of Service (DoS) security DoS attacks Denial of Service (DoS) Denial of Service (DoS) A denial of service attack is an action that deprives the machine of needed resources. Typically, D.O.S. attacks are brute-force mechanisms that attempt to crash or otherwise make a machine unusable by overwhelming its servers or network stack. Some D.O.S. attacks try to take advantage of bugs in the networking stack to crash a machine with a single packet. The latter can only be fixed by applying a bug fix to the kernel. Attacks on servers can often be fixed by properly specifying options to limit the load the servers incur on the system under adverse conditions. Brute-force network attacks are harder to deal with. A spoofed-packet attack, for example, is nearly impossible to stop, short of cutting your system off from the Internet. It may not be able to take your machine down, but it can saturate your Internet connection. security account compromises A user account compromise is even more common than a DoS attack. Many sysadmins still run standard telnetd, rlogind, rshd, and ftpd servers on their machines. These servers, by default, do not operate over encrypted connections. The result is that if you have any moderate-sized user base, one or more of your users logging into your system from a remote location (which is the most common and convenient way to login to a system) will have his or her password sniffed. The attentive system admin will analyze his remote access logs looking for suspicious source addresses even for successful logins. One must always assume that once an attacker has access to a user account, the attacker can break root. However, the reality is that in a well secured and maintained system, access to a user account does not necessarily give the attacker access to root. The distinction is important because without access to root the attacker cannot generally hide his tracks and may, at best, be able to do nothing more than mess with the user's files, or crash the machine. User account compromises are very common because users tend not to take the precautions that sysadmins take. security backdoors System administrators must keep in mind that there are potentially many ways to break root on a machine. The attacker may know the root password, the attacker may find a bug in a root-run server and be able to break root over a network connection to that server, or the attacker may know of a bug in an suid-root program that allows the attacker to break root once he has broken into a user's account. If an attacker has found a way to break root on a machine, the attacker may not have a need to install a backdoor. Many of the root holes found and closed to date involve a considerable amount of work by the attacker to cleanup after himself, so most attackers install backdoors. A backdoor provides the attacker with a way to easily regain root access to the system, but it also gives the smart system administrator a convenient way to detect the intrusion. Making it impossible for an attacker to install a backdoor may actually be detrimental to your security, because it will not close off the hole the attacker found to break in the first place. Security remedies should always be implemented with a multi-layered onion peel approach and can be categorized as follows: Securing root and staff accounts. Securing root – root-run servers and suid/sgid binaries. Securing user accounts. Securing the password file. Securing the kernel core, raw devices, and filesystems. Quick detection of inappropriate changes made to the system. Paranoia. The next section of this chapter will cover the above bullet items in greater depth. security securing Securing FreeBSD The sections that follow will cover the methods of securing your FreeBSD system that were mentioned in the last section of this chapter. Securing the <username>root</username> Account and Staff Accounts su First off, do not bother securing staff accounts if you have not secured the root account. Most systems have a password assigned to the root account. The first thing you do is assume that the password is always compromised. This does not mean that you should remove the password. The password is almost always necessary for console access to the machine. What it does mean is that you should not make it possible to use the password outside of the console or possibly even with the &man.su.1; command. For example, make sure that your pty's are specified as being unsecure in the /etc/ttys file so that direct root logins via telnet or rlogin are disallowed. If using other login services such as sshd, make sure that direct root logins are disabled there as well. Consider every access method – services such as FTP often fall through the cracks. Direct root logins should only be allowed via the system console. wheel Of course, as a sysadmin you have to be able to get to root, so we open up a few holes. But we make sure these holes require additional password verification to operate. One way to make root accessible is to add appropriate staff accounts to the wheel group (in /etc/group). The staff members placed in the wheel group are allowed to su to root. You should never give staff members native wheel access by putting them in the wheel group in their password entry. Staff accounts should be placed in a staff group, and then added to the wheel group via the /etc/group file. Only those staff members who actually need to have root access should be placed in the wheel group. It is also possible, when using an authentication method such as kerberos, to use kerberos' .k5login file in the root account to allow a &man.ksu.1; to root without having to place anyone at all in the wheel group. This may be the better solution since the wheel mechanism still allows an intruder to break root if the intruder has gotten hold of your password file and can break into a staff account. While having the wheel mechanism is better than having nothing at all, it is not necessarily the safest option. An indirect way to secure staff accounts, and ultimately root access is to use an alternative login access method and do what is known as *'ing out the crypted password for the staff accounts. Using the &man.vipw.8; command, one can replace each instance of a crypted password with a single * character. This command will update the /etc/master.passwd file and user/password database to disable password-authenticated logins. A staff account entry such as: foobar:R9DT/Fa1/LV9U:1000:1000::0:0:Foo Bar:/home/foobar:/usr/local/bin/tcsh Should be changed to this : foobar:*:1000:1000::0:0:Foo Bar:/home/foobar:/usr/local/bin/tcsh This change will prevent normal logins from occurring, since the encrypted password will never match *. With this done, staff members must use another mechanism to authenticate themselves such as &man.kerberos.1; or &man.ssh.1; using a public/private key pair. When using something like kerberos, one generally must secure the machines which run the kerberos servers and your desktop workstation. When using a public/private key pair with ssh, one must generally secure the machine used to login from (typically one's workstation). An additional layer of protection can be added to the key pair by password protecting the key pair when creating it with &man.ssh-keygen.1;. Being able to * out the passwords for staff accounts also guarantees that staff members can only login through secure access methods that you have setup. This forces all staff members to use secure, encrypted connections for all of their sessions, which closes an important hole used by many intruders: That of sniffing the network from an unrelated, less secure machine. The more indirect security mechanisms also assume that you are logging in from a more restrictive server to a less restrictive server. For example, if your main box is running all sorts of servers, your workstation should not be running any. In order for your workstation to be reasonably secure you should run as few servers as possible, up to and including no servers at all, and you should run a password-protected screen blanker. Of course, given physical access to a workstation an attacker can break any sort of security you put on it. This is definitely a problem that you should consider, but you should also consider the fact that the vast majority of break-ins occur remotely, over a network, from people who do not have physical access to your workstation or servers. Kerberos Using something like kerberos also gives you the ability to disable or change the password for a staff account in one place, and have it immediately effect all the machines on which the staff member may have an account. If a staff member's account gets compromised, the ability to instantly change his password on all machines should not be underrated. With discrete passwords, changing a password on N machines can be a mess. You can also impose re-passwording restrictions with kerberos: not only can a kerberos ticket be made to timeout after a while, but the kerberos system can require that the user choose a new password after a certain period of time (say, once a month). Securing Root-run Servers and SUID/SGID Binaries ntalk comsat finger sandboxes sshd telnetd rshd rlogind The prudent sysadmin only runs the servers he needs to, no more, no less. Be aware that third party servers are often the most bug-prone. For example, running an old version of imapd or popper is like giving a universal root ticket out to the entire world. Never run a server that you have not checked out carefully. Many servers do not need to be run as root. For example, the ntalk, comsat, and finger daemons can be run in special user sandboxes. A sandbox is not perfect, unless you go to a large amount of trouble, but the onion approach to security still stands: If someone is able to break in through a server running in a sandbox, they still have to break out of the sandbox. The more layers the attacker must break through, the lower the likelihood of his success. Root holes have historically been found in virtually every server ever run as root, including basic system servers. If you are running a machine through which people only login via sshd and never login via telnetd or rshd or rlogind, then turn off those services! FreeBSD now defaults to running ntalkd, comsat, and finger in a sandbox. Another program which may be a candidate for running in a sandbox is &man.named.8;. /etc/defaults/rc.conf includes the arguments necessary to run named in a sandbox in a commented-out form. Depending on whether you are installing a new system or upgrading an existing system, the special user accounts used by these sandboxes may not be installed. The prudent sysadmin would research and implement sandboxes for servers whenever possible. sendmail There are a number of other servers that typically do not run in sandboxes: sendmail, popper, imapd, ftpd, and others. There are alternatives to some of these, but installing them may require more work than you are willing to perform (the convenience factor strikes again). You may have to run these servers as root and rely on other mechanisms to detect break-ins that might occur through them. The other big potential root holes in a system are the suid-root and sgid binaries installed on the system. Most of these binaries, such as rlogin, reside in /bin, /sbin, /usr/bin, or /usr/sbin. While nothing is 100% safe, the system-default suid and sgid binaries can be considered reasonably safe. Still, root holes are occasionally found in these binaries. A root hole was found in Xlib in 1998 that made xterm (which is typically suid) vulnerable. It is better to be safe than sorry and the prudent sysadmin will restrict suid binaries, that only staff should run, to a special group that only staff can access, and get rid of (chmod 000) any suid binaries that nobody uses. A server with no display generally does not need an xterm binary. Sgid binaries can be almost as dangerous. If an intruder can break an sgid-kmem binary, the intruder might be able to read /dev/kmem and thus read the crypted password file, potentially compromising any passworded account. Alternatively an intruder who breaks group kmem can monitor keystrokes sent through pty's, including pty's used by users who login through secure methods. An intruder that breaks the tty group can write to almost any user's tty. If a user is running a terminal program or emulator with a keyboard-simulation feature, the intruder can potentially generate a data stream that causes the user's terminal to echo a command, which is then run as that user. Securing User Accounts User accounts are usually the most difficult to secure. While you can impose Draconian access restrictions on your staff and * out their passwords, you may not be able to do so with any general user accounts you might have. If you do have sufficient control, then you may win out and be able to secure the user accounts properly. If not, you simply have to be more vigilant in your monitoring of those accounts. Use of ssh and kerberos for user accounts is more problematic, due to the extra administration and technical support required, but still a very good solution compared to a crypted password file. Securing the Password File The only sure fire way is to * out as many passwords as you can and use ssh or kerberos for access to those accounts. Even though the crypted password file (/etc/spwd.db) can only be read by root, it may be possible for an intruder to obtain read access to that file even if the attacker cannot obtain root-write access. Your security scripts should always check for and report changes to the password file (see Checking file integrity below). Securing the Kernel Core, Raw Devices, and Filesystems If an attacker breaks root he can do just about anything, but there are certain conveniences. For example, most modern kernels have a packet sniffing device driver built in. Under FreeBSD it is called the bpf device. An intruder will commonly attempt to run a packet sniffer on a compromised machine. You do not need to give the intruder the capability and most systems should not have the bpf device compiled in. sysctl But even if you turn off the bpf device, you still have /dev/mem and /dev/kmem to worry about. For that matter, the intruder can still write to raw disk devices. Also, there is another kernel feature called the module loader, &man.kldload.8;. An enterprising intruder can use a KLD module to install his own bpf device, or other sniffing device, on a running kernel. To avoid these problems you have to run the kernel at a higher secure level, at least securelevel 1. The securelevel can be set with a sysctl on the kern.securelevel variable. Once you have set the securelevel to 1, write access to raw devices will be denied and special chflags flags, such as schg, will be enforced. You must also ensure that the schg flag is set on critical startup binaries, directories, and script files – everything that gets run up to the point where the securelevel is set. This might be overdoing it, and upgrading the system is much more difficult when you operate at a higher secure level. You may compromise and run the system at a higher secure level but not set the schg flag for every system file and directory under the sun. Another possibility is to simply mount / and /usr read-only. It should be noted that being too Draconian in what you attempt to protect may prevent the all-important detection of an intrusion. Checking File Integrity: Binaries, Configuration Files, Etc. When it comes right down to it, you can only protect your core system configuration and control files so much before the convenience factor rears its ugly head. For example, using chflags to set the schg bit on most of the files in / and /usr is probably counterproductive, because while it may protect the files, it also closes a detection window. The last layer of your security onion is perhaps the most important – detection. The rest of your security is pretty much useless (or, worse, presents you with a false sense of safety) if you cannot detect potential incursions. Half the job of the onion is to slow down the attacker, rather than stop him, in order to give the detection side of the equation a chance to catch him in the act. The best way to detect an incursion is to look for modified, missing, or unexpected files. The best way to look for modified files is from another (often centralized) limited-access system. Writing your security scripts on the extra-secure limited-access system makes them mostly invisible to potential attackers, and this is important. In order to take maximum advantage you generally have to give the limited-access box significant access to the other machines in the business, usually either by doing a read-only NFS export of the other machines to the limited-access box, or by setting up ssh key-pairs to allow the limited-access box to ssh to the other machines. Except for its network traffic, NFS is the least visible method – allowing you to monitor the filesystems on each client box virtually undetected. If your limited-access server is connected to the client boxes through a switch, the NFS method is often the better choice. If your limited-access server is connected to the client boxes through a hub, or through several layers of routing, the NFS method may be too insecure (network-wise) and using ssh may be the better choice even with the audit-trail tracks that ssh lays. Once you give a limited-access box, at least read access to the client systems it is supposed to monitor, you must write scripts to do the actual monitoring. Given an NFS mount, you can write scripts out of simple system utilities such as &man.find.1; and &man.md5.1;. It is best to physically md5 the client-box files at least once a day, and to test control files such as those found in /etc and /usr/local/etc even more often. When mismatches are found, relative to the base md5 information the limited-access machine knows is valid, it should scream at a sysadmin to go check it out. A good security script will also check for inappropriate suid binaries and for new or deleted files on system partitions such as / and /usr. When using ssh rather than NFS, writing the security script is much more difficult. You essentially have to scp the scripts to the client box in order to run them, making them visible, and for safety you also need to scp the binaries (such as find) that those scripts use. The ssh daemon on the client box may already be compromised. All in all, using ssh may be necessary when running over unsecure links, but it is also a lot harder to deal with. A good security script will also check for changes to user and staff members access configuration files: .rhosts, .shosts, .ssh/authorized_keys and so forth… files that might fall outside the purview of the MD5 check. If you have a huge amount of user disk space, it may take too long to run through every file on those partitions. In this case, setting mount flags to disallow suid binaries and devices on those partitions is a good idea. The nodev and nosuid options (see &man.mount.8;) are what you want to look into. You should probably scan them anyway, at least once a week, since the object of this layer is to detect a break-in whether or not the break-in is effective. Process accounting (see &man.accton.8;) is a relatively low-overhead feature of the operating system which might help as a post-break-in evaluation mechanism. It is especially useful in tracking down how an intruder has actually broken into a system, assuming the file is still intact after the break-in occurs. Finally, security scripts should process the log files, and the logs themselves should be generated in as secure a manner as possible – remote syslog can be very useful. An intruder tries to cover his tracks, and log files are critical to the sysadmin trying to track down the time and method of the initial break-in. One way to keep a permanent record of the log files is to run the system console to a serial port and collect the information on a continuing basis through a secure machine monitoring the consoles. Paranoia A little paranoia never hurts. As a rule, a sysadmin can add any number of security features, as long as they do not effect convenience, and can add security features that do effect convenience with some added thought. Even more importantly, a security administrator should mix it up a bit – if you use recommendations such as those given by this document verbatim, you give away your methodologies to the prospective attacker who also has access to this document. Denial of Service Attacks Denial of Service (DoS) This section covers Denial of Service attacks. A DoS attack is typically a packet attack. While there is not much you can do about modern spoofed packet attacks that saturate your network, you can generally limit the damage by ensuring that the attacks cannot take down your servers. Limiting server forks. Limiting springboard attacks (ICMP response attacks, ping broadcast, etc.). Kernel Route Cache. A common DoS attack is against a forking server that attempts to cause the server to eat processes, file descriptors, and memory, until the machine dies. inetd (see &man.inetd.8;) has several options to limit this sort of attack. It should be noted that while it is possible to prevent a machine from going down, it is not generally possible to prevent a service from being disrupted by the attack. Read the inetd manual page carefully and pay specific attention to the , , and options. Note that spoofed-IP attacks will circumvent the option to inetd, so typically a combination of options must be used. Some standalone servers have self-fork-limitation parameters. Sendmail has its option, which tends to work much better than trying to use sendmail's load limiting options due to the load lag. You should specify a MaxDaemonChildren parameter, when you start sendmail, high enough to handle your expected load, but not so high that the computer cannot handle that number of sendmails without falling on its face. It is also prudent to run sendmail in queued mode () and to run the daemon (sendmail -bd) separate from the queue-runs (sendmail -q15m). If you still want real-time delivery you can run the queue at a much lower interval, such as , but be sure to specify a reasonable MaxDaemonChildren option for that sendmail to prevent cascade failures. Syslogd can be attacked directly and it is strongly recommended that you use the option whenever possible, and the option otherwise. You should also be fairly careful with connect-back services such as tcpwrapper's reverse-identd, which can be attacked directly. You generally do not want to use the reverse-ident feature of tcpwrappers for this reason. It is a very good idea to protect internal services from external access by firewalling them off at your border routers. The idea here is to prevent saturation attacks from outside your LAN, not so much to protect internal services from network-based root compromise. Always configure an exclusive firewall, i.e., firewall everything except ports A, B, C, D, and M-Z. This way you can firewall off all of your low ports except for certain specific services such as named (if you are primary for a zone), ntalkd, sendmail, and other Internet-accessible services. If you try to configure the firewall the other way – as an inclusive or permissive firewall, there is a good chance that you will forget to close a couple of services, or that you will add a new internal service and forget to update the firewall. You can still open up the high-numbered port range on the firewall, to allow permissive-like operation, without compromising your low ports. Also take note that FreeBSD allows you to control the range of port numbers used for dynamic binding, via the various net.inet.ip.portrange sysctl's (sysctl -a | fgrep portrange), which can also ease the complexity of your firewall's configuration. For example, you might use a normal first/last range of 4000 to 5000, and a hiport range of 49152 to 65535, then block off everything under 4000 in your firewall (except for certain specific Internet-accessible ports, of course). ICMP_BANDLIM Another common DoS attack is called a springboard attack – to attack a server in a manner that causes the server to generate responses which then overload the server, the local network, or some other machine. The most common attack of this nature is the ICMP ping broadcast attack. The attacker spoofs ping packets sent to your LAN's broadcast address with the source IP address set to the actual machine they wish to attack. If your border routers are not configured to stomp on ping's to broadcast addresses, your LAN winds up generating sufficient responses to the spoofed source address to saturate the victim, especially when the attacker uses the same trick on several dozen broadcast addresses over several dozen different networks at once. Broadcast attacks of over a hundred and twenty megabits have been measured. A second common springboard attack is against the ICMP error reporting system. By constructing packets that generate ICMP error responses, an attacker can saturate a server's incoming network and cause the server to saturate its outgoing network with ICMP responses. This type of attack can also crash the server by running it out of mbuf's, especially if the server cannot drain the ICMP responses it generates fast enough. The FreeBSD kernel has a new kernel compile option called ICMP_BANDLIM which limits the effectiveness of these sorts of attacks. The last major class of springboard attacks is related to certain internal inetd services such as the udp echo service. An attacker simply spoofs a UDP packet with the source address being server A's echo port, and the destination address being server B's echo port, where server A and B are both on your LAN. The two servers then bounce this one packet back and forth between each other. The attacker can overload both servers and their LANs simply by injecting a few packets in this manner. Similar problems exist with the internal chargen port. A competent sysadmin will turn off all of these inetd-internal test services. Spoofed packet attacks may also be used to overload the kernel route cache. Refer to the net.inet.ip.rtexpire, rtminexpire, and rtmaxcache sysctl parameters. A spoofed packet attack that uses a random source IP will cause the kernel to generate a temporary cached route in the route table, viewable with netstat -rna | fgrep W3. These routes typically timeout in 1600 seconds or so. If the kernel detects that the cached route table has gotten too big it will dynamically reduce the rtexpire but will never decrease it to less than rtminexpire. There are two problems: The kernel does not react quickly enough when a lightly loaded server is suddenly attacked. The rtminexpire is not low enough for the kernel to survive a sustained attack. If your servers are connected to the Internet via a T3 or better, it may be prudent to manually override both rtexpire and rtminexpire via &man.sysctl.8;. Never set either parameter to zero (unless you want to crash the machine). Setting both parameters to 2 seconds should be sufficient to protect the route table from attack. Access Issues with Kerberos and SSH ssh Kerberos There are a few issues with both kerberos and ssh that need to be addressed if you intend to use them. Kerberos V is an excellent authentication protocol, but there are bugs in the kerberized telnet and rlogin applications that make them unsuitable for dealing with binary streams. Also, by default kerberos does not encrypt a session unless you use the option. ssh encrypts everything by default. ssh works quite well in every respect except that it forwards encryption keys by default. What this means is that if you have a secure workstation holding keys that give you access to the rest of the system, and you ssh to an unsecure machine, your keys becomes exposed. The actual keys themselves are not exposed, but ssh installs a forwarding port for the duration of your login, and if an attacker has broken root on the unsecure machine he can utilize that port to use your keys to gain access to any other machine that your keys unlock. We recommend that you use ssh in combination with kerberos whenever possible for staff logins. ssh can be compiled with kerberos support. This reduces your reliance on potentially exposable ssh keys while at the same time protecting passwords via kerberos. ssh keys should only be used for automated tasks from secure machines (something that kerberos is unsuited to). We also recommend that you either turn off key-forwarding in the ssh configuration, or that you make use of the from=IP/DOMAIN option that ssh allows in its authorized_keys file to make the key only usable to entities logging in from specific machines. Bill Swingle Parts rewritten and updated by DES, MD5, and Crypt security crypt crypt DES MD5 Every user on a Unix system has a password associated with their account. It seems obvious that these passwords need to be known only to the user and the actual operating system. In order to keep these passwords secret, they are encrypted with what is known as a one-way hash, that is, they can only be easily encrypted but not decrypted. In other words, what we told you a moment ago was obvious is not even true: the operating system itself does not really know the password. It only knows the encrypted form of the password. The only way to get the plain-text password is by a brute force search of the space of possible passwords. Unfortunately the only secure way to encrypt passwords when Unix came into being was based on DES, the Data Encryption Standard. This was not such a problem for users resident in the US, but since the source code for DES could not be exported outside the US, FreeBSD had to find a way to both comply with US law and retain compatibility with all the other Unix variants that still used DES. The solution was to divide up the encryption libraries so that US users could install the DES libraries and use DES but international users still had an encryption method that could be exported abroad. This is how FreeBSD came to use MD5 as its default encryption method. MD5 is believed to be more secure than DES, so installing DES is offered primarily for compatibility reasons. Recognizing Your Crypt Mechanism It is pretty easy to identify which encryption method FreeBSD is set up to use. Examining the encrypted passwords in the /etc/master.passwd file is one way. Passwords encrypted with the MD5 hash are longer than those encrypted with the DES hash and also begin with the characters $1$. DES password strings do not have any particular identifying characteristics, but they are shorter than MD5 passwords, and are coded in a 64-character alphabet which does not include the $ character, so a relatively short string which does not begin with a dollar sign is very likely a DES password. The libraries can identify the passwords this way as well. As a result, the DES libraries are able to identify MD5 passwords, and use MD5 to check passwords that were encrypted that way, and DES for the rest. They are able to do this because the DES libraries also contain MD5. Unfortunately, the reverse is not true, so the MD5 libraries cannot authenticate passwords that were encrypted with DES. Identifying which library is being used by the programs on your system is easy as well. Any program that uses crypt is linked against libcrypt, which for each type of library is a symbolic link to the appropriate implementation. For example, on a system using the DES versions: &prompt.user; ls -l /usr/lib/libcrypt* lrwxr-xr-x 1 root wheel 13 Mar 19 06:56 libcrypt.a -> libdescrypt.a lrwxr-xr-x 1 root wheel 18 Mar 19 06:56 libcrypt.so.2.0 -> libdescrypt.so.2.0 lrwxr-xr-x 1 root wheel 15 Mar 19 06:56 libcrypt_p.a -> libdescrypt_p.a On a system using the MD5-based libraries, the same links will be present, but the target will be libscrypt rather than libdescrypt. If you have installed the DES-capable crypt library libdescrypt (e.g. by installing the "crypto" distribution), then which password format will be used for new passwords is controlled by the passwd_format login capability in /etc/login.conf, which takes values of either des or md5. See the &man.login.conf.5; manual page for more information about login capabilities. S/Key S/Key security S/Key S/Key is a one-time password scheme based on a one-way hash function. FreeBSD uses the MD4 hash for compatibility but other systems have used MD5 and DES-MAC. S/Key has been part of the FreeBSD base system since version 1.1.5 and is also used on a growing number of other operating systems. S/Key is a registered trademark of Bell Communications Research, Inc. There are three different sorts of passwords which we will talk about in the discussion below. The first is your usual Unix-style or Kerberos password; we will call this a Unix password. The second sort is the one-time password which is generated by the S/Key key program and accepted by the keyinit program and the login prompt; we will call this a one-time password. The final sort of password is the secret password which you give to the key program (and sometimes the keyinit program) which it uses to generate one-time passwords; we will call it a secret password or just unqualified password. The secret password does not have anything to do with your Unix password; they can be the same but this is not recommended. S/Key secret passwords are not limited to 8 characters like Unix passwords, they can be as long as you like. Passwords of six or seven word long phrases are fairly common. For the most part, the S/Key system operates completely independently of the Unix password system. Besides the password, there are two other pieces of data that are important to S/Key. One is what is known as the seed or key and consists of two letters and five digits. The other is what is called the iteration count and is a number between 1 and 100. S/Key creates the one-time password by concatenating the seed and the secret password, then applying the MD4 hash as many times as specified by the iteration count and turning the result into six short English words. These six English words are your one-time password. The login and su programs keep track of the last one-time password used, and the user is authenticated if the hash of the user-provided password is equal to the previous password. Because a one-way hash is used it is impossible to generate future one-time passwords if a successfully used password is captured; the iteration count is decremented after each successful login to keep the user and the login program in sync. When the iteration count gets down to 1 S/Key must be reinitialized. There are four programs involved in the S/Key system which we will discuss below. The key program accepts an iteration count, a seed, and a secret password, and generates a one-time password. The keyinit program is used to initialize S/Key, and to change passwords, iteration counts, or seeds; it takes either a secret password, or an iteration count, seed, and one-time password. The keyinfo program examines the /etc/skeykeys file and prints out the invoking user's current iteration count and seed. Finally, the login and su programs contain the necessary logic to accept S/Key one-time passwords for authentication. The login program is also capable of disallowing the use of Unix passwords on connections coming from specified addresses. There are four different sorts of operations we will cover. The first is using the keyinit program over a secure connection to set up S/Key for the first time, or to change your password or seed. The second operation is using the keyinit program over an insecure connection, in conjunction with the key program over a secure connection, to do the same. The third is using the key program to log in over an insecure connection. The fourth is using the key program to generate a number of keys which can be written down or printed out to carry with you when going to some location without secure connections to anywhere. Secure Connection Initialization To initialize S/Key for the first time, change your password, or change your seed while logged in over a secure connection (e.g., on the console of a machine or via ssh), use the keyinit command without any parameters while logged in as yourself: &prompt.user; keyinit Adding unfurl: Reminder - Only use this method if you are directly connected. If you are using telnet or rlogin exit with no password and use keyinit -s. Enter secret password: Again secret password: ID unfurl s/key is 99 to17757 DEFY CLUB PRO NASH LACE SOFT At the Enter secret password: prompt you should enter a password or phrase. Remember, this is not the password that you will use to login with, this is used to generate your one-time login keys. The ID line gives the parameters of your particular S/Key instance; your login name, the iteration count, and seed. When logging in with S/Key, the system will remember these parameters and present them back to you so you do not have to remember them. The last line gives the particular one-time password which corresponds to those parameters and your secret password; if you were to re-login immediately, this one-time password is the one you would use. Insecure Connection Initialization To initialize S/Key or change your secret password over an insecure connection, you will need to already have a secure connection to some place where you can run the key program; this might be in the form of a desk accessory on a Macintosh, or a shell prompt on a machine you trust. You will also need to make up an iteration count (100 is probably a good value), and you may make up your own seed or use a randomly-generated one. Over on the insecure connection (to the machine you are initializing), use the keyinit -s command: &prompt.user; keyinit -s Updating unfurl: Old key: to17758 Reminder you need the 6 English words from the key command. Enter sequence count from 1 to 9999: 100 Enter new key [default to17759]: s/key 100 to 17759 s/key access password: To accept the default seed (which the keyinit program confusingly calls a key), press return. Then before entering an access password, move over to your secure connection or S/Key desk accessory, and give it the same parameters: &prompt.user; key 100 to17759 Reminder - Do not use this program while logged in via telnet or rlogin. Enter secret password: <secret password> CURE MIKE BANE HIM RACY GORE Now switch back over to the insecure connection, and copy the one-time password generated by key over to the keyinit program: s/key access password:CURE MIKE BANE HIM RACY GORE ID unfurl s/key is 100 to17759 CURE MIKE BANE HIM RACY GORE The rest of the description from the previous section applies here as well. Generating a Single one-time Password - Once you've initialized S/Key, when you login you will be + Once you have initialized S/Key, when you login you will be presented with a prompt like this: &prompt.user; telnet example.com Trying 10.0.0.1... Connected to example.com Escape character is '^]'. FreeBSD/i386 (example.com) (ttypa) login: <username> s/key 97 fw13894 Password: As a side note, the S/Key prompt has a useful feature (not shown here): if you press return at the password prompt, the login program will turn echo on, so you can see what you are typing. This can be extremely useful if you are attempting to type in an S/Key by hand, such as from a printout. Also, if this machine were configured to disallow Unix passwords over a connection from the source machine, the prompt would have also included the annotation (s/key required), indicating that only S/Key one-time passwords will be accepted. MS-DOS Windows MacOS At this point you need to generate your one-time password to answer this login prompt. This must be done on a trusted system that you can run the key command on. (There are versions of the key program for MS-DOS, Windows and MacOS as well.) The key program needs both the iteration count and the seed as command line options. You can cut-and-paste these right from the login prompt on the machine that you are logging in to. On the trusted system: &prompt.user; key 97 fw13894 Reminder - Do not use this program while logged in via telnet or rlogin. Enter secret password: WELD LIP ACTS ENDS ME HAAG Now that you have your one-time password you can continue logging in: login: <username> s/key 97 fw13894 Password: <return to enable echo> s/key 97 fw13894 Password [echo on]: WELD LIP ACTS ENDS ME HAAG Last login: Tue Mar 21 11:56:41 from 10.0.0.2 ... This is the easiest mechanism if you have a trusted machine. There is a Java S/Key key applet, The Java OTP Calculator, that you can download and run locally on any Java supporting browser. Generating Multiple one-time Passwords Sometimes you have to go places where you do not have access to a trusted machine or secure connection. In this case, it is possible to use the key command to generate a number of one-time passwords before hand to be printed out and taken with you. For example: &prompt.user; key -n 5 30 zz99999 Reminder - Do not use this program while logged in via telnet or rlogin. Enter secret password: <secret password> 26: SODA RUDE LEA LIND BUDD SILT 27: JILT SPY DUTY GLOW COWL ROT 28: THEM OW COLA RUNT BONG SCOT 29: COT MASH BARR BRIM NAN FLAG 30: CAN KNEE CAST NAME FOLK BILK The requests five keys in sequence, the specifies what the last iteration number should be. Note that these are printed out in reverse order of eventual use. If you are really paranoid, you might want to write the results down by hand; otherwise you can cut-and-paste into lpr. Note that each line shows both the iteration count and the one-time password; you may still find it handy to scratch off passwords as you use them. Restricting Use of Unix Passwords Restrictions can be placed on the use of Unix passwords based on the host name, user name, terminal port, or IP address of a login session. These restrictions can be found in the configuration file /etc/skey.access. The &man.skey.access.5; manual page has more info on the complete format of the file and also details some security cautions to be aware of before depending on this file for security. If there is no /etc/skey.access file (this is the FreeBSD default), then all users will be allowed to use Unix passwords. If the file exists, however, then all users will be required to use S/Key unless explicitly permitted to do otherwise by configuration statements in the skey.access file. In all cases, Unix passwords are permitted on the console. Here is a sample configuration file which illustrates the three most common sorts of configuration statements: permit internet 192.168.0.0 255.255.0.0 permit user fnord permit port ttyd0 The first line (permit internet) allows users whose IP source address (which is vulnerable to spoofing) matches the specified value and mask, to use Unix passwords. This should not be considered a security mechanism, but rather, a means to remind authorized users that they are using an insecure network and need to use S/Key for authentication. The second line (permit user) allows the specified username, in this case fnord, to use Unix passwords at any time. Generally speaking, this should only be used for people who are either unable to use the key program, like those with dumb terminals, or those who are uneducable. The third line (permit port) allows all users logging in on the specified terminal line to use Unix passwords; this would be used for dial-ups. Mark Murray Contributed by Mark Dapoz Based on a contribution by Kerberos Kerberos Kerberos is a network add-on system/protocol that allows users to authenticate themselves through the services of a secure server. Services such as remote login, remote copy, secure inter-system file copying and other high-risk tasks are made considerably safer and more controllable. The following instructions can be used as a guide on how to set up Kerberos as distributed for FreeBSD. However, you should refer to the relevant manual pages for a complete description. 4.4BSD-Lite In FreeBSD, the Kerberos is not that from the original 4.4BSD-Lite, distribution, but eBones, which had been previously ported to FreeBSD 1.1.5.1, and was sourced from outside the USA/Canada, and was thus available to system owners outside those countries during the era of restrictive export controls on cryptographic code from the USA. Creating the Initial Database This is done on the Kerberos server only. First make sure that you do not have any old Kerberos databases around. You should change to the directory /etc/kerberosIV and check that only the following files are present: &prompt.root; cd /etc/kerberosIV &prompt.root; ls README krb.conf krb.realms If any additional files (such as principal.* or master_key) exist, then use the kdb_destroy command to destroy the old Kerberos database, or if Kerberos is not running, simply delete the extra files. You should now edit the krb.conf and krb.realms files to define your Kerberos realm. In this case the realm will be GRONDAR.ZA and the server is grunt.grondar.za. We edit or create the krb.conf file: &prompt.root; cat krb.conf GRONDAR.ZA GRONDAR.ZA grunt.grondar.za admin server CS.BERKELEY.EDU okeeffe.berkeley.edu ATHENA.MIT.EDU kerberos.mit.edu ATHENA.MIT.EDU kerberos-1.mit.edu ATHENA.MIT.EDU kerberos-2.mit.edu ATHENA.MIT.EDU kerberos-3.mit.edu LCS.MIT.EDU kerberos.lcs.mit.edu TELECOM.MIT.EDU bitsy.mit.edu ARC.NASA.GOV trident.arc.nasa.gov In this case, the other realms do not need to be there. They are here as an example of how a machine may be made aware of multiple realms. You may wish to not include them for simplicity. The first line names the realm in which this system works. The other lines contain realm/host entries. The first item on a line is a realm, and the second is a host in that realm that is acting as a key distribution center. The words admin server following a hosts name means that host also provides an administrative database server. For further explanation of these terms, please consult the Kerberos manual pages. Now we have to add grunt.grondar.za to the GRONDAR.ZA realm and also add an entry to put all hosts in the .grondar.za domain in the GRONDAR.ZA realm. The krb.realms file would be updated as follows: &prompt.root; cat krb.realms grunt.grondar.za GRONDAR.ZA .grondar.za GRONDAR.ZA .berkeley.edu CS.BERKELEY.EDU .MIT.EDU ATHENA.MIT.EDU .mit.edu ATHENA.MIT.EDU Again, the other realms do not need to be there. They are here as an example of how a machine may be made aware of multiple realms. You may wish to remove them to simplify things. The first line puts the specific system into the named realm. The rest of the lines show how to default systems of a particular subdomain to a named realm. Now we are ready to create the database. This only needs to run on the Kerberos server (or Key Distribution Center). Issue the kdb_init command to do this: &prompt.root; kdb_init Realm name [default ATHENA.MIT.EDU ]: GRONDAR.ZA You will be prompted for the database Master Password. It is important that you NOT FORGET this password. Enter Kerberos master key: Now we have to save the key so that servers on the local machine can pick it up. Use the kstash command to do this. &prompt.root; kstash Enter Kerberos master key: Current Kerberos master key version is 1. Master key entered. BEWARE! This saves the encrypted master password in /etc/kerberosIV/master_key. Making It All Run Two principals need to be added to the database for each system that will be secured with Kerberos. Their names are kpasswd and rcmd These two principals are made for each system, with the instance being the name of the individual system. These daemons, kpasswd and rcmd allow other systems to change Kerberos passwords and run commands like rcp, rlogin and rsh. Now let's add these entries: &prompt.root; kdb_edit Opening database... Enter Kerberos master key: Current Kerberos master key version is 1. Master key entered. BEWARE! Previous or default values are in [brackets] , enter return to leave the same, or new value. Principal name: passwd Instance: grunt <Not found>, Create [y] ? y Principal: passwd, Instance: grunt, kdc_key_ver: 1 New Password: <---- enter RANDOM here Verifying password New Password: <---- enter RANDOM here Random password [y] ? y Principal's new key version = 1 Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ? Max ticket lifetime (*5 minutes) [ 255 ] ? Attributes [ 0 ] ? Edit O.K. Principal name: rcmd Instance: grunt <Not found>, Create [y] ? Principal: rcmd, Instance: grunt, kdc_key_ver: 1 New Password: <---- enter RANDOM here Verifying password New Password: <---- enter RANDOM here Random password [y] ? Principal's new key version = 1 Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ? Max ticket lifetime (*5 minutes) [ 255 ] ? Attributes [ 0 ] ? Edit O.K. Principal name: <---- null entry here will cause an exit Creating the Server File We now have to extract all the instances which define the services on each machine. For this we use the ext_srvtab command. This will create a file which must be copied or moved by secure means to each Kerberos client's /etc/kerberosIV directory. This file must be present on each server and client, and is crucial to the operation of Kerberos. &prompt.root; ext_srvtab grunt Enter Kerberos master key: Current Kerberos master key version is 1. Master key entered. BEWARE! Generating 'grunt-new-srvtab'.... Now, this command only generates a temporary file which must be renamed to srvtab so that all the servers can pick it up. Use the mv command to move it into place on the original system: &prompt.root; mv grunt-new-srvtab srvtab If the file is for a client system, and the network is not deemed safe, then copy the client-new-srvtab to removable media and transport it by secure physical means. Be sure to rename it to srvtab in the client's /etc/kerberosIV directory, and make sure it is mode 600: &prompt.root; mv grumble-new-srvtab srvtab &prompt.root; chmod 600 srvtab Populating the Database We now have to add some user entries into the database. First let's create an entry for the user jane. Use the kdb_edit command to do this: &prompt.root; kdb_edit Opening database... Enter Kerberos master key: Current Kerberos master key version is 1. Master key entered. BEWARE! Previous or default values are in [brackets] , enter return to leave the same, or new value. Principal name: jane Instance: <Not found>, Create [y] ? y Principal: jane, Instance: , kdc_key_ver: 1 New Password: <---- enter a secure password here Verifying password New Password: <---- re-enter the password here Principal's new key version = 1 Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ? Max ticket lifetime (*5 minutes) [ 255 ] ? Attributes [ 0 ] ? Edit O.K. Principal name: <---- null entry here will cause an exit Testing It All Out First we have to start the Kerberos daemons. NOTE that if you have correctly edited your /etc/rc.conf then this will happen automatically when you reboot. This is only necessary on the Kerberos server. Kerberos clients will automagically get what they need from the /etc/kerberosIV directory. &prompt.root; kerberos & Kerberos server starting Sleep forever on error Log file is /var/log/kerberos.log Current Kerberos master key version is 1. Master key entered. BEWARE! Current Kerberos master key version is 1 Local realm: GRONDAR.ZA &prompt.root; kadmind -n & KADM Server KADM0.0A initializing Please do not use 'kill -9' to kill this job, use a regular kill instead Current Kerberos master key version is 1. Master key entered. BEWARE! Now we can try using the kinit command to get a ticket for the id jane that we created above: &prompt.user; kinit jane MIT Project Athena (grunt.grondar.za) Kerberos Initialization for "jane" Password: Try listing the tokens using klist to see if we really have them: &prompt.user; klist Ticket file: /tmp/tkt245 Principal: jane@GRONDAR.ZA Issued Expires Principal Apr 30 11:23:22 Apr 30 19:23:22 krbtgt.GRONDAR.ZA@GRONDAR.ZA Now try changing the password using passwd to check if the kpasswd daemon can get authorization to the Kerberos database: &prompt.user; passwd realm GRONDAR.ZA Old password for jane: New Password for jane: Verifying password New Password for jane: Password changed. Adding <command>su</command> Privileges Kerberos allows us to give each user who needs root privileges their own separate supassword. We could now add an id which is authorized to su to root. This is controlled by having an instance of root associated with a principal. Using kdb_edit we can create the entry jane.root in the Kerberos database: &prompt.root; kdb_edit Opening database... Enter Kerberos master key: Current Kerberos master key version is 1. Master key entered. BEWARE! Previous or default values are in [brackets] , enter return to leave the same, or new value. Principal name: jane Instance: root <Not found>, Create [y] ? y Principal: jane, Instance: root, kdc_key_ver: 1 New Password: <---- enter a SECURE password here Verifying password New Password: <---- re-enter the password here Principal's new key version = 1 Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ? Max ticket lifetime (*5 minutes) [ 255 ] ? 12 <--- Keep this short! Attributes [ 0 ] ? Edit O.K. Principal name: <---- null entry here will cause an exit Now try getting tokens for it to make sure it works: &prompt.root; kinit jane.root MIT Project Athena (grunt.grondar.za) Kerberos Initialization for "jane.root" Password: Now we need to add the user to root's .klogin file: &prompt.root; cat /root/.klogin jane.root@GRONDAR.ZA Now try doing the su: &prompt.user; su Password: and take a look at what tokens we have: &prompt.root; klist Ticket file: /tmp/tkt_root_245 Principal: jane.root@GRONDAR.ZA Issued Expires Principal May 2 20:43:12 May 3 04:43:12 krbtgt.GRONDAR.ZA@GRONDAR.ZA Using Other Commands In an earlier example, we created a principal called jane with an instance root. This was based on a user with the same name as the principal, and this is a Kerberos default; that a <principal>.<instance> of the form <username>.root will allow that <username> to su to root if the necessary entries are in the .klogin file in root's home directory: &prompt.root; cat /root/.klogin jane.root@GRONDAR.ZA Likewise, if a user has in their own home directory lines of the form: &prompt.user; cat ~/.klogin jane@GRONDAR.ZA jack@GRONDAR.ZA This allows anyone in the GRONDAR.ZA realm who has authenticated themselves to jane or jack (via kinit, see above) access to rlogin to jane's account or files on this system (grunt) via rlogin, rsh or rcp. For example, Jane now logs into another system, using Kerberos: &prompt.user; kinit MIT Project Athena (grunt.grondar.za) Password: &prompt.user; rlogin grunt Last login: Mon May 1 21:14:47 from grumble Copyright (c) 1980, 1983, 1986, 1988, 1990, 1991, 1993, 1994 The Regents of the University of California. All rights reserved. FreeBSD BUILT-19950429 (GR386) #0: Sat Apr 29 17:50:09 SAT 1995 Or Jack logs into Jane's account on the same machine (Jane having set up the .klogin file as above, and the person in charge of Kerberos having set up principal jack with a null instance: &prompt.user; kinit &prompt.user; rlogin grunt -l jane MIT Project Athena (grunt.grondar.za) Password: Last login: Mon May 1 21:16:55 from grumble Copyright (c) 1980, 1983, 1986, 1988, 1990, 1991, 1993, 1994 The Regents of the University of California. All rights reserved. FreeBSD BUILT-19950429 (GR386) #0: Sat Apr 29 17:50:09 SAT 1995 Gary Palmer Contributed by Alex Nash Firewalls firewall security firewalls Firewalls are an area of increasing interest for people who are connected to the Internet, and are even finding applications on private networks to provide enhanced security. This section will hopefully explain what firewalls are, how to use them, and how to use the facilities provided in the FreeBSD kernel to implement them. People often think that having a firewall between your internal network and the Big Bad Internet will solve all your security problems. It may help, but a poorly setup firewall system is more of a security risk than not having one at all. A firewall can add another layer of security to your systems, but it cannot stop a really determined cracker from penetrating your internal network. If you let internal security lapse because you believe your firewall to be impenetrable, you have just made the crackers job that much easier. What Is a Firewall? There are currently two distinct types of firewalls in common use on the Internet today. The first type is more properly called a packet filtering router, where the kernel on a multi-homed machine chooses whether to forward or block packets based on a set of rules. The second type, known as a proxy server, relies on daemons to provide authentication and to forward packets, possibly on a multi-homed machine which has kernel packet forwarding disabled. Sometimes sites combine the two types of firewalls, so that only a certain machine (known as a bastion host) is allowed to send packets through a packet filtering router onto an internal network. Proxy services are run on the bastion host, which are generally more secure than normal authentication mechanisms. FreeBSD comes with a kernel packet filter (known as IPFW), which is what the rest of this section will concentrate on. Proxy servers can be built on FreeBSD from third party software, but there is such a variety of proxy servers available that it would be impossible to cover them in this document. Packet Filtering Routers A router is a machine which forwards packets between two or more networks. A packet filtering router has an extra piece of code in its kernel which compares each packet to a list of rules before deciding if it should be forwarded or not. Most modern IP routing software has packet filtering code within it that defaults to forwarding all packets. To enable the filters, you need to define a set of rules for the filtering code so it can decide if the packet should be allowed to pass or not. To decide whether a packet should be passed on, the code looks through its set of rules for a rule which matches the contents of this packets headers. Once a match is found, the rule action is obeyed. The rule action could be to drop the packet, to forward the packet, or even to send an ICMP message back to the originator. Only the first match counts, as the rules are searched in order. Hence, the list of rules can be referred to as a rule chain. The packet matching criteria varies depending on the software used, but typically you can specify rules which depend on the source IP address of the packet, the destination IP address, the source port number, the destination port number (for protocols which support ports), or even the packet type (UDP, TCP, ICMP, etc). Proxy Servers Proxy servers are machines which have had the normal system daemons (telnetd, ftpd, etc) replaced with special servers. These servers are called proxy servers as they normally only allow onward connections to be made. This enables you to run (for example) a proxy telnet server on your firewall host, and people can telnet in to your firewall from the outside, go through some authentication mechanism, and then gain access to the internal network (alternatively, proxy servers can be used for signals coming from the internal network and heading out). Proxy servers are normally more secure than normal servers, and often have a wider variety of authentication mechanisms available, including one-shot password systems so that even if someone manages to discover what password you used, they will not be able to use it to gain access to your systems as the password instantly expires. As they do not actually give users access to the host machine, it becomes a lot more difficult for someone to install backdoors around your security system. Proxy servers often have ways of restricting access further, so that only certain hosts can gain access to the servers, and often they can be set up so that you can limit which users can talk to which destination machine. Again, what facilities are available depends largely on what proxy software you choose. What Does IPFW Allow Me to Do? ipfw IPFW, the software supplied with FreeBSD, is a packet filtering and accounting system which resides in the kernel, and has a user-land control utility, &man.ipfw.8;. Together, they allow you to define and query the rules currently used by the kernel in its routing decisions. There are two related parts to IPFW. The firewall section allows you to perform packet filtering. There is also an IP accounting section which allows you to track usage of your router, based on similar rules to the firewall section. This allows you to see (for example) how much traffic your router is getting from a certain machine, or how much WWW (World Wide Web) traffic it is forwarding. As a result of the way that IPFW is designed, you can use IPFW on non-router machines to perform packet filtering on incoming and outgoing connections. This is a special case of the more general use of IPFW, and the same commands and techniques should be used in this situation. Enabling IPFW on FreeBSD ipfw enabling As the main part of the IPFW system lives in the kernel, you will need to add one or more options to your kernel configuration file, depending on what facilities you want, and recompile your kernel. See reconfiguring the kernel for more details on how to recompile your kernel. There are currently three kernel configuration options relevant to IPFW: options IPFIREWALL Compiles into the kernel the code for packet filtering. options IPFIREWALL_VERBOSE Enables code to allow logging of packets through &man.syslogd.8;. Without this option, even if you specify that packets should be logged in the filter rules, nothing will happen. options IPFIREWALL_VERBOSE_LIMIT=10 Limits the number of packets logged through &man.syslogd.8; on a per entry basis. You may wish to use this option in hostile environments in which you want to log firewall activity, but do not want to be open to a denial of service attack via syslog flooding. When a chain entry reaches the packet limit specified, logging is turned off for that particular entry. To resume logging, you will need to reset the associated counter using the &man.ipfw.8; utility: &prompt.root; ipfw zero 4500 Where 4500 is the chain entry you wish to continue logging. Previous versions of FreeBSD contained an IPFIREWALL_ACCT option. This is now obsolete as the firewall code automatically includes accounting facilities. Configuring IPFW ipfw configuring The configuration of the IPFW software is done through the &man.ipfw.8; utility. The syntax for this command looks quite complicated, but it is relatively simple once you understand its structure. There are currently four different command categories used by the utility: addition/deletion, listing, flushing, and clearing. Addition/deletion is used to build the rules that control how packets are accepted, rejected, and logged. Listing is used to examine the contents of your rule set (otherwise known as the chain) and packet counters (accounting). Flushing is used to remove all entries from the chain. Clearing is used to zero out one or more accounting entries. Altering the IPFW Rules The syntax for this form of the command is: ipfw -N command index action log protocol addresses options There is one valid flag when using this form of the command: -N Resolve addresses and service names in output. The command given can be shortened to the shortest unique form. The valid commands are: add Add an entry to the firewall/accounting rule list delete Delete an entry from the firewall/accounting rule list Previous versions of IPFW used separate firewall and accounting entries. The present version provides packet accounting with each firewall entry. If an index value is supplied, it is used to place the entry at a specific point in the chain. Otherwise, the entry is placed at the end of the chain at an index 100 greater than the last chain entry (this does not include the default policy, rule 65535, deny). The log option causes matching rules to be output to the system console if the kernel was compiled with IPFIREWALL_VERBOSE. Valid actions are: reject Drop the packet, and send an ICMP host or port unreachable (as appropriate) packet to the source. allow Pass the packet on as normal. (aliases: pass and accept) deny Drop the packet. The source is not notified via an ICMP message (thus it appears that the packet never arrived at the destination). count Update packet counters but do not allow/deny the packet based on this rule. The search continues with the next chain entry. Each action will be recognized by the shortest unambiguous prefix. The protocols which can be specified are: all Matches any IP packet icmp Matches ICMP packets tcp Matches TCP packets udp Matches UDP packets The address specification is: from address/maskport to address/maskport via interface You can only specify port in conjunction with protocols which support ports (UDP and TCP). The is optional and may specify the IP address or domain name of a local IP interface, or an interface name (e.g. ed0) to match only packets coming through this interface. Interface unit numbers can be specified with an optional wildcard. For example, ppp* would match all kernel PPP interfaces. The syntax used to specify an address/mask is: address or address/mask-bits or address:mask-pattern A valid hostname may be specified in place of the IP address. is a decimal number representing how many bits in the address mask should be set. e.g. specifying 192.216.222.1/24 will create a mask which will allow any address in a class C subnet (in this case, 192.216.222) to be matched. is an IP address which will be logically AND'ed with the address given. The keyword any may be used to specify any IP address. The port numbers to be blocked are specified as: port,port,port to specify either a single port or a list of ports, or port-port to specify a range of ports. You may also combine a single range with a list, but the range must always be specified first. The options available are: frag Matches if the packet is not the first fragment of the datagram. in Matches if the packet is on the way in. out Matches if the packet is on the way out. ipoptions spec Matches if the IP header contains the comma separated list of options specified in spec. The supported list of IP options are: ssrr (strict source route), lsrr (loose source route), rr (record packet route), and ts (time stamp). The absence of a particular option may be denoted with a leading !. established Matches if the packet is part of an already established TCP connection (i.e. it has the RST or ACK bits set). You can optimize the performance of the firewall by placing established rules early in the chain. setup Matches if the packet is an attempt to establish a TCP connection (the SYN bit is set but the ACK bit is not). tcpflags flags Matches if the TCP header contains the comma separated list of flags. The supported flags are fin, syn, rst, psh, ack, and urg. The absence of a particular flag may be indicated by a leading !. icmptypes types Matches if the ICMP type is present in the list types. The list may be specified as any combination of ranges and/or individual types separated by commas. Commonly used ICMP types are: 0 echo reply (ping reply), 3 destination unreachable, 5 redirect, 8 echo request (ping request), and 11 time exceeded (used to indicate TTL expiration as with &man.traceroute.8;). Listing the IPFW Rules The syntax for this form of the command is: ipfw -a -t -N l There are three valid flags when using this form of the command: -a While listing, show counter values. This option is the only way to see accounting counters. -t Display the last match times for each chain entry. The time listing is incompatible with the input syntax used by the &man.ipfw.8; utility. -N Attempt to resolve given addresses and service names. Flushing the IPFW Rules The syntax for flushing the chain is: ipfw flush This causes all entries in the firewall chain to be removed except the fixed default policy enforced by the kernel (index 65535). Use caution when flushing rules, the default deny policy will leave your system cut off from the network until allow entries are added to the chain. Clearing the IPFW Packet Counters The syntax for clearing one or more packet counters is: ipfw zero index When used without an index argument, all packet counters are cleared. If an index is supplied, the clearing operation only affects a specific chain entry. Example Commands for ipfw This command will deny all packets from the host evil.crackers.org to the telnet port of the host nice.people.org: &prompt.root ipfw add deny tcp from evil.crackers.org to nice.people.org 23 The next example denies and logs any TCP traffic from the entire crackers.org network (a class C) to the nice.people.org machine (any port). &prompt.root; ipfw add deny log tcp from evil.crackers.org/24 to nice.people.org If you do not want people sending X sessions to your internal network (a subnet of a class C), the following command will do the necessary filtering: &prompt.root; ipfw add deny tcp from any to my.org/28 6000 setup To see the accounting records: &prompt.root; ipfw -a list or in the short form &prompt.root; ipfw -a l You can also see the last time a chain entry was matched with: &prompt.root; ipfw -at l Building a Packet Filtering Firewall The following suggestions are just that: suggestions. The requirements of each firewall are different and we cannot tell you how to build a firewall to meet your particular requirements. When initially setting up your firewall, unless you have a test bench setup where you can configure your firewall host in a controlled environment, it is strongly recommend you use the logging version of the commands and enable logging in the kernel. This will allow you to quickly identify problem areas and cure them without too much disruption. Even after the initial setup phase is complete, I recommend using the logging for `deny' as it allows tracing of possible attacks and also modification of the firewall rules if your requirements alter. If you use the logging versions of the accept command, it can generate large amounts of log data as one log line will be generated for every packet that passes through the firewall, so large FTP/http transfers, etc, will really slow the system down. It also increases the latencies on those packets as it requires more work to be done by the kernel before the packet can be passed on. syslogd will also start using up a lot more processor time as it logs all the extra data to disk, and it could quite easily fill the partition /var/log is located on. You should enable your firewall from /etc/rc.conf.local or /etc/rc.conf. The associated manual page explains which knobs to fiddle and lists some preset firewall configurations. If you do not use a preset configuration, ipfw list will output the current ruleset into a file that you can pass to rc.conf. If you do not use /etc/rc.conf.local or /etc/rc.conf to enable your firewall, it is important to make sure your firewall is enabled before any IP interfaces are configured. The next problem is what your firewall should actually do! This is largely dependent on what access to your network you want to allow from the outside, and how much access to the outside world you want to allow from the inside. Some general rules are: Block all incoming access to ports below 1024 for TCP. This is where most of the security sensitive services are, like finger, SMTP (mail) and telnet. Block all incoming UDP traffic. There are very few useful services that travel over UDP, and what useful traffic there is, is normally a security threat (e.g. Suns RPC and NFS protocols). This has its disadvantages also, since UDP is a connectionless protocol, denying incoming UDP traffic also blocks the replies to outgoing UDP traffic. This can cause a problem for people (on the inside) using external archie (prospero) servers. If you want to allow access to archie, you will have to allow packets coming from ports 191 and 1525 to any internal UDP port through the firewall. ntp is another service you may consider allowing through, which comes from port 123. Block traffic to port 6000 from the outside. Port 6000 is the port used for access to X11 servers, and can be a security threat (especially if people are in the habit of doing xhost + on their workstations). X11 can actually use a range of ports starting at 6000, the upper limit being how many X displays you can run on the machine. The upper limit as defined by RFC 1700 (Assigned Numbers) is 6063. Check what ports any internal servers use (e.g. SQL servers, etc). It is probably a good idea to block those as well, as they normally fall outside the 1-1024 range specified above. Another checklist for firewall configuration is available from CERT at http://www.cert.org/tech_tips/packet_filtering.html As stated above, these are only guidelines. You will have to decide what filter rules you want to use on your firewall yourself. We cannot accept ANY responsibility if someone breaks into your network, even if you follow the advice given above. OpenSSL security OpenSSL OpenSSL As of FreeBSD 4.0, the OpenSSL toolkit is a part of the base system. OpenSSL provides a general-purpose cryptography library, as well as the Secure Sockets Layer v2/v3 (SSLv2/SSLv3) and Transport Layer Security v1 (TLSv1) network security protocols. However, one of the algorithms (specifically IDEA) included in OpenSSL is protected by patents in the USA and elsewhere, and is not available for unrestricted use. IDEA is included in the OpenSSL sources in FreeBSD, but it is not built by default. If you wish to use it, and you comply with the license terms, enable the MAKE_IDEA switch in /etc/make.conf and rebuild your sources using 'make world'. Today, the RSA algorithm is free for use in USA and other countries. In the past it was protected by a patent. OpenSSL install Source Code Installations OpenSSL is part of the src-crypto and src-secure cvsup collections. See the Obtaining FreeBSD section for more information about obtaining and updating FreeBSD source code. Yoshinobu Inoue Contributed by IPsec IPsec security IPsec The IPsec mechanism provides secure communication for IP layer and socket layer communication. This section should explain how to use them. For implementation details, please refer to The Developers' Handbook. The current IPsec implementation supports both transport mode and tunnel mode. However, tunnel mode comes with some restrictions. http://www.kame.net/newsletter/ has more comprehensive examples. Please be aware that in order to use this functionality, you must have the following options compiled into your kernel: options IPSEC #IP security options IPSEC_ESP #IP security (crypto; define w/IPSEC) Transport Mode Example with IPv4 Let us setup security association to deploy a secure channel between HOST A (10.2.3.4) and HOST B (10.6.7.8). Here we show a little complicated example. From HOST A to HOST B, only old AH is used. From HOST B to HOST A, new AH and new ESP are combined. Now we should choose an algorithm to be used corresponding to "AH"/"new AH"/"ESP"/"new ESP". Please refer to the &man.setkey.8; man page to know algorithm names. Our choice is MD5 for AH, new-HMAC-SHA1 for new AH, and new-DES-expIV with 8 byte IV for new ESP. Key length highly depends on each algorithm. For example, key length must be equal to 16 bytes for MD5, 20 for new-HMAC-SHA1, and 8 for new-DES-expIV. Now we choose "MYSECRETMYSECRET", "KAMEKAMEKAMEKAMEKAME", "PASSWORD", respectively. OK, let us assign SPI (Security Parameter Index) for each protocol. Please note that we need 3 SPIs for this secure channel since three security headers are produced (one for from HOST A to HOST B, two for from HOST B to HOST A). Please also note that SPI MUST be greater than or equal to 256. We choose, 1000, 2000, and 3000, respectively. (1) HOST A ------> HOST B (1)PROTO=AH ALG=MD5(RFC1826) KEY=MYSECRETMYSECRET SPI=1000 (2.1) HOST A <------ HOST B <------ (2.2) (2.1) PROTO=AH ALG=new-HMAC-SHA1(new AH) KEY=KAMEKAMEKAMEKAMEKAME SPI=2000 (2.2) PROTO=ESP ALG=new-DES-expIV(new ESP) IV length = 8 KEY=PASSWORD SPI=3000 Now, let us setup security association. Execute &man.setkey.8; on both HOST A and B: &prompt.root; setkey -c add 10.2.3.4 10.6.7.8 ah-old 1000 -m transport -A keyed-md5 "MYSECRETMYSECRET" ; add 10.6.7.8 10.2.3.4 ah 2000 -m transport -A hmac-sha1 "KAMEKAMEKAMEKAMEKAME" ; add 10.6.7.8 10.2.3.4 esp 3000 -m transport -E des-cbc "PASSWORD" ; ^D Actually, IPsec communication does not process until security policy entries are defined. In this case, you must setup each host. At A: &prompt.root; setkey -c spdadd 10.2.3.4 10.6.7.8 any -P out ipsec ah/transport/10.2.3.4-10.6.7.8/require ; ^D At B: &prompt.root; setkey -c spdadd 10.6.7.8 10.2.3.4 any -P out ipsec esp/transport/10.6.7.8-10.2.3.4/require ; spdadd 10.6.7.8 10.2.3.4 any -P out ipsec ah/transport/10.6.7.8-10.2.3.4/require ; ^D HOST A --------------------------------------> HOST E 10.2.3.4 10.6.7.8 | | ========== old AH keyed-md5 ==========> <========= new AH hmac-sha1 =========== <========= new ESP des-cbc ============ Transport Mode Example with IPv6 Another example using IPv6. ESP transport mode is recommended for TCP port number 110 between Host-A and Host-B. ============ ESP ============ | | Host-A Host-B fec0::10 -------------------- fec0::11 Encryption algorithm is blowfish-cbc whose key is "kamekame", and authentication algorithm is hmac-sha1 whose key is "this is the test key". Configuration at Host-A: &prompt.root; setkey -c <<EOF spdadd fec0::10[any] fec0::11[110] tcp -P out ipsec esp/transport/fec0::10-fec0::11/use ; spdadd fec0::11[110] fec0::10[any] tcp -P in ipsec esp/transport/fec0::11-fec0::10/use ; add fec0::10 fec0::11 esp 0x10001 -m transport -E blowfish-cbc "kamekame" -A hmac-sha1 "this is the test key" ; add fec0::11 fec0::10 esp 0x10002 -m transport -E blowfish-cbc "kamekame" -A hmac-sha1 "this is the test key" ; EOF and at Host-B: &prompt.root; setkey -c <<EOF spdadd fec0::11[110] fec0::10[any] tcp -P out ipsec esp/transport/fec0::11-fec0::10/use ; spdadd fec0::10[any] fec0::11[110] tcp -P in ipsec esp/transport/fec0::10-fec0::11/use ; add fec0::10 fec0::11 esp 0x10001 -m transport -E blowfish-cbc "kamekame" -A hmac-sha1 "this is the test key" ; add fec0::11 fec0::10 esp 0x10002 -m transport -E blowfish-cbc "kamekame" -A hmac-sha1 "this is the test key" ; EOF Note the direction of SP. Tunnel Mode Example with IPv4 Tunnel mode between two security gateways Security protocol is old AH tunnel mode, i.e. specified by RFC1826, with keyed-md5 whose key is "this is the test" as authentication algorithm. ======= AH ======= | | Network-A Gateway-A Gateway-B Network-B 10.0.1.0/24 ---- 172.16.0.1 ----- 172.16.0.2 ---- 10.0.2.0/24 Configuration at Gateway-A: &prompt.root; setkey -c <<EOF spdadd 10.0.1.0/24 10.0.2.0/24 any -P out ipsec ah/tunnel/172.16.0.1-172.16.0.2/require ; spdadd 10.0.2.0/24 10.0.1.0/24 any -P in ipsec ah/tunnel/172.16.0.2-172.16.0.1/require ; add 172.16.0.1 172.16.0.2 ah-old 0x10003 -m any -A keyed-md5 "this is the test" ; add 172.16.0.2 172.16.0.1 ah-old 0x10004 -m any -A keyed-md5 "this is the test" ; EOF If the port number field is omitted such as above then "[any]" is employed. `-m' specifies the mode of SA to be used. "-m any" means wild-card of mode of security protocol. You can use this SA for both tunnel and transport mode. and at Gateway-B: &prompt.root; setkey -c <<EOF spdadd 10.0.2.0/24 10.0.1.0/24 any -P out ipsec ah/tunnel/172.16.0.2-172.16.0.1/require ; spdadd 10.0.1.0/24 10.0.2.0/24 any -P in ipsec ah/tunnel/172.16.0.1-172.16.0.2/require ; add 172.16.0.1 172.16.0.2 ah-old 0x10003 -m any -A keyed-md5 "this is the test" ; add 172.16.0.2 172.16.0.1 ah-old 0x10004 -m any -A keyed-md5 "this is the test" ; EOF Making SA bundle between two security gateways AH transport mode and ESP tunnel mode is required between Gateway-A and Gateway-B. In this case, ESP tunnel mode is applied first, and AH transport mode is next. ========== AH ========= | ======= ESP ===== | | | | | Network-A Gateway-A Gateway-B Network-B fec0:0:0:1::/64 --- fec0:0:0:1::1 ---- fec0:0:0:2::1 --- fec0:0:0:2::/64 Tunnel Mode Example with IPv6 Encryption algorithm is 3des-cbc, and authentication algorithm for ESP is hmac-sha1. Authentication algorithm for AH is hmac-md5. Configuration at Gateway-A: &prompt.root; setkey -c <<EOF spdadd fec0:0:0:1::/64 fec0:0:0:2::/64 any -P out ipsec esp/tunnel/fec0:0:0:1::1-fec0:0:0:2::1/require ah/transport/fec0:0:0:1::1-fec0:0:0:2::1/require ; spdadd fec0:0:0:2::/64 fec0:0:0:1::/64 any -P in ipsec esp/tunnel/fec0:0:0:2::1-fec0:0:0:1::1/require ah/transport/fec0:0:0:2::1-fec0:0:0:1::1/require ; add fec0:0:0:1::1 fec0:0:0:2::1 esp 0x10001 -m tunnel -E 3des-cbc "kamekame12341234kame1234" -A hmac-sha1 "this is the test key" ; add fec0:0:0:1::1 fec0:0:0:2::1 ah 0x10001 -m transport -A hmac-md5 "this is the test" ; add fec0:0:0:2::1 fec0:0:0:1::1 esp 0x10001 -m tunnel -E 3des-cbc "kamekame12341234kame1234" -A hmac-sha1 "this is the test key" ; add fec0:0:0:2::1 fec0:0:0:1::1 ah 0x10001 -m transport -A hmac-md5 "this is the test" ; EOF Making SAs with the different end ESP tunnel mode is required between Host-A and Gateway-A. Encryption algorithm is cast128-cbc, and authentication algorithm for ESP is hmac-sha1. ESP transport mode is recommended between Host-A and Host-B. Encryption algorithm is rc5-cbc, and authentication algorithm for ESP is hmac-md5. ================== ESP ================= | ======= ESP ======= | | | | | Host-A Gateway-A Host-B fec0:0:0:1::1 ---- fec0:0:0:2::1 ---- fec0:0:0:2::2 Configuration at Host-A: &prompt.root; setkey -c <<EOF spdadd fec0:0:0:1::1[any] fec0:0:0:2::2[80] tcp -P out ipsec esp/transport/fec0:0:0:1::1-fec0:0:0:2::2/use esp/tunnel/fec0:0:0:1::1-fec0:0:0:2::1/require ; spdadd fec0:0:0:2::1[80] fec0:0:0:1::1[any] tcp -P in ipsec esp/transport/fec0:0:0:2::2-fec0:0:0:l::1/use esp/tunnel/fec0:0:0:2::1-fec0:0:0:1::1/require ; add fec0:0:0:1::1 fec0:0:0:2::2 esp 0x10001 -m transport -E cast128-cbc "12341234" -A hmac-sha1 "this is the test key" ; add fec0:0:0:1::1 fec0:0:0:2::1 esp 0x10002 -E rc5-cbc "kamekame" -A hmac-md5 "this is the test" ; add fec0:0:0:2::2 fec0:0:0:1::1 esp 0x10003 -m transport -E cast128-cbc "12341234" -A hmac-sha1 "this is the test key" ; add fec0:0:0:2::1 fec0:0:0:1::1 esp 0x10004 -E rc5-cbc "kamekame" -A hmac-md5 "this is the test" ; EOF Chern Lee Contributed by OpenSSH OpenSSH security OpenSSH Secure shell is a set of network connectivity tools used to access remote machines securely. It can be used as a direct replacement for rlogin, rsh, rcp, and telnet. Additionally, any other TCP/IP connections can be tunneled/forwarded securely through ssh. ssh encrypts all traffic to effectively eliminate eavesdropping, connection hijacking, and other network-level attacks. OpenSSH is maintained by the OpenBSD project, and is based upon SSH v1.2.12 with all the recent bug fixes and updates. It is compatible with both SSH protocols 1 and 2. OpenSSH has been in the base system since FreeBSD 4.0. Advantages of Using OpenSSH Normally, when using &man.telnet.1; or &man.rlogin.1;, data is sent over the network in an clear, un-encrypted form. Network sniffers anywhere in between the client and server can steal your user/password information or data transferred in your session. OpenSSH offers a variety of authentication and encryption methods to prevent this from happening. Enabling sshd OpenSSH enabling Be sure to make the following additions to your rc.conf file: sshd_enable="YES" This will load the ssh daemon the next time your system initializes. Alternatively, you can simply run the sshd daemon. SSH Client OpenSSH client The &man.ssh.1; utility works similarly to &man.rlogin.1;. &prompt.root ssh user@foobardomain.com Host key not found from the list of known hosts. Are you sure you want to continue connecting (yes/no)? yes Host 'foobardomain.com' added to the list of known hosts. user@foobardomain.com's password: ******* The login will continue just as it would have if a session was created using rlogin or telnet. SSH utilizes a key fingerprint system for verifying the authenticity of the server when the client connects. The user is prompted to enter 'yes' only when connecting for the first time. Future attempts to login are all verified against the saved fingerprint key. The SSH client will alert you if the saved fingerprint differs from the received fingerprint on future login attempts. The fingerprints are saved in ~/.ssh/known_hosts Secure Copy OpenSSH secure copy scp The scp command works similarly to rcp; it copies a file to or from a remote machine, except in a secure fashion. &prompt.root scp user@foobardomain.com:/COPYRIGHT COPYRIGHT user@foobardomain.com's password: COPYRIGHT 100% |*****************************| 4735 00:00 &prompt.root Since the fingerprint was already saved for this host in the previous example, it is verified when using scp here. Configuration OpenSSH configuration The system-wide configuration files for both the OpenSSH daemon and client reside within the /etc/ssh directory. ssh_config configures the client settings, while sshd_config configures the daemon. ssh-keygen Instead of using passwords, &man.ssh-keygen.1; can be used to generate RSA keys to authenticate a user. &prompt.user ssh-keygen Initializing random number generator... Generating p: .++ (distance 66) Generating q: ..............................++ (distance 498) Computing the keys... Key generation complete. Enter file in which to save the key (/home/user/.ssh/identity): Enter passphrase: Enter the same passphrase again: Your identification has been saved in /home/user/.ssh/identity. ... &man.ssh-keygen.1; will create a public and private key pair for use in authentication. The private key is stored in ~/.ssh/identity, whereas the public key is stored in ~/.ssh/identity.pub. The public key must be placed in ~/.ssh/authorized_keys of the remote machine in order for the setup to work. This will allow connection to the remote machine based upon RSA authentication instead of passwords. If a passphrase is used in &man.ssh-keygen.1;, the user will be prompted for a password each time in order to use the private key. &man.ssh-agent.1; and &man.ssh-add.1; are utilities used in managing multiple passworded private keys. SSH Tunneling OpenSSH tunneling OpenSSH has the ability to create a tunnel to encapsulate another protocol in an encrypted session. The following command tells &man.ssh.1; to create a tunnel for telnet. &prompt.user; ssh -2 -N -f -L 5023:localhost:23 user@foo.bar.com &prompt.user; -2 this forces &man.ssh.1 to use version 2 of the protocol. (Do not use if you are working with older ssh servers) -N indicates no command, or tunnel only. If omitted, &man.ssh.1; would initiate a normal session. -f forces &man.ssh.1; to run in the background. -L indicates a local tunnel in localport:localhost:remoteport fashion. foo.bar.com is the remote/target SSH server. An SSH tunnel works by creating a listen socket on the specified local host and port. It then forwards any connection to the local host/port via the SSH connection to the remote machine on the specified remote port. In the example, port 5023 on localhost is being forwarded to port 23 on the remote machine. Since 23 is telnet, this would create a secure telnet session through an SSH tunnel. This can be used to wrap any number of insecure TCP protocols such as smtp, pop3, ftp, etc. A typical SSH Tunnel &prompt.user; ssh -2 -N -f -L 5025:localhost:25 user@mailserver.foobar.com user@mailserver.foobar.com's password: ***** &prompt.user; telnet localhost 5025 Trying 127.0.0.1... Connected to localhost. Escape character is '^]'. 220 mailserver.foobar.com ESMTP This can be used in conjunction with an &man.ssh-keygen.1; and additional user accounts to create a more seamless/hassle-free SSH tunneling environment. Keys can be used in place of typing a password, and the tunnels can be run as a separate user. Further Reading OpenSSH &man.ssh.1; &man.scp.1; &man.ssh-keygen.1; &man.ssh-agent.1; &man.ssh-add.1; &man.sshd.8; &man.sftp-server.8; diff --git a/en_US.ISO8859-1/books/handbook/serialcomms/chapter.sgml b/en_US.ISO8859-1/books/handbook/serialcomms/chapter.sgml index d63c8e6079..2f1afb17d2 100644 --- a/en_US.ISO8859-1/books/handbook/serialcomms/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/serialcomms/chapter.sgml @@ -1,2593 +1,2593 @@ Serial Communications Synopsis serial communications Unix has always had support for serial communications. In fact, the very first Unix machines relied on serial lines for user input and output. Things have changed a lot from the days when the average terminal consisted of a 10-character-per-second serial printer and a keyboard. This chapter will cover some of the ways in which FreeBSD uses serial communications. After reading this chapter you will know: How to connect terminals to your FreeBSD system. How to use a modem to dial out to remote hosts. How to allow remote users to login to your system with a modem. How to boot your system from a serial console. Before reading this chapter you should: Know how to configure and install a new kernel () Understand Unix permissions and processes () Have access to the technical manual for the serial hardware (modem or multi-port card) that you would like to use with FreeBSD. Introduction Terminology bits-per-second bps Bits per Second — the rate at which data is transmitted DTE DTE Data Terminal Equipment — for example, your computer DCE DCE Data Communications Equipment — your modem RS-232 RS-232C cables EIA standard for hardware serial communications When talking about communications data rates, the authors do not use the term baud. Baud refers to the number of electrical state transitions that may be made in a period of time, while bps (bits per second) is the correct term to use (at least it does not seem to bother the curmudgeons quite a much). Cables and Ports To connect a modem or terminal to your FreeBSD system, you will need a serial port on your computer and the proper cable to connect to your serial device. If you are already familiar with your hardware and the cable it requires, you can safely skip this section. Cables There are several different kinds of serial cables. The two most common types for our purposes are null-modem cables and standard ("straight") RS-232 cables. The documentation for your hardware should describe the type of cable required. Null-modem Cables null-modem cable A null-modem cable passes some signals straight through, like signal ground, but switches other signals. For example, the send data pin on one end goes to the receive data pin on the other end. If you like making your own cables, you can construct a null-modem cable for use with terminals. This table shows the RS-232C signal names and the pin numbers on a DB-25 connector. Signal Pin # Pin # Signal TxD 2 connects to 3 RxD RxD 3 connects to 2 TxD DTR 20 connects to 6 DSR DSR 6 connects to 20 DTR SG 7 connects to 7 SG DCD 8 connects to 4 RTS RTS 4 5 CTS CTS 5 connects to 8 DCD For DCD to RTS, connect pins 4 to 5 internally in the connector hood, and then to pin 8 in the remote hood. Standard RS-232C Cables RS-232C cables A standard serial cable passes all the RS-232C signals straight-through. That is, the send data pin on one end of the cable goes to the send data pin on the other end. This is the type of cable to connect a modem to your FreeBSD system, and the type of cable needed for some terminals. Ports Serial ports are the devices through which data is transferred between the FreeBSD host computer and the terminal. This section describes the kinds of ports that exist and how they are addressed in FreeBSD. Kinds of Ports Several kinds of serial ports exist. Before you purchase or construct a cable, you need to make sure it will fit the ports on your terminal and on the FreeBSD system. Most terminals will have DB25 ports. Personal computers, including PCs running FreeBSD, will have DB25 or DB9 ports. If you have a multiport serial card for your PC, you may have RJ-12 or RJ-45 ports. See the documentation that accompanied the hardware for specifications on the kind of port in use. A visual inspection of the port often works, too. Port Names In FreeBSD, you access each serial port through an entry in the /dev directory. There are two different kinds of entries: Call-in ports are named /dev/ttydN where N is the port number, starting from zero. Generally, you use the call-in port for terminals. Call-in ports require that the serial line assert the data carrier detect (DCD) signal to work. Call-out ports are named /dev/cuaaN. You usually do not use the call-out port for terminals, just for modems. You may use the call-out port if the serial cable or the terminal does not support the carrier detect signal. If you have connected a terminal to the first serial port (COM1 in MS-DOS parlance), then you want to use /dev/ttyd0 to refer to the terminal. If it is on the second serial port (also known as COM2), it is /dev/ttyd1, and so forth. Kernel Configuration FreeBSD supports four serial ports by default. In the MS-DOS world, these are known as COM1:, COM2:, COM3:, and COM4:. FreeBSD currently supports dumb multiport serial interface cards, such as the BocaBoard 1008 and 2016, as well as more intelligent multi-port cards such as those made by Digiboard and Stallion Technologies. The default kernel only looks for the standard COM ports, though. To see if your kernel recognizes any of your serial ports, watch for messages while the kernel is booting, or use the /sbin/dmesg command to replay the kernel's boot messages. In particular, look for messages that start with the characters sio. To view just the messages that have the word sio, use the command: &prompt.root; /sbin/dmesg | grep 'sio' For example, on a system with four serial ports, these are the serial-port specific kernel boot messages: sio0 at 0x3f8-0x3ff irq 4 on isa sio0: type 16550A sio1 at 0x2f8-0x2ff irq 3 on isa sio1: type 16550A sio2 at 0x3e8-0x3ef irq 5 on isa sio2: type 16550A sio3 at 0x2e8-0x2ef irq 9 on isa sio3: type 16550A If your kernel does not recognize all of your serial ports, you will probably need to configure a custom FreeBSD kernel for your system. For detailed information on configuring your kernel, please see . The relevant device lines for your kernel configuration file would look like this: device sio0 at isa? port "IO_COM1" tty irq 4 vector siointr device sio1 at isa? port "IO_COM2" tty irq 3 vector siointr device sio2 at isa? port "IO_COM3" tty irq 5 vector siointr device sio3 at isa? port "IO_COM4" tty irq 9 vector siointr You can comment-out or completely remove lines for devices you do not have. Please see the &man.sio.4; manual page for complete information on how to write configuration lines for multiport boards. Be careful if you are using a configuration file that was previously used for a different version of FreeBSD because the device flags have changed between versions. port "IO_COM1" is a substitution for port 0x3f8, IO_COM2 is 0x2f8, IO_COM3 is 0x3e8, and IO_COM4 is 0x2e8, which are fairly common port addresses for their respective serial ports; interrupts 4, 3, 5, and 9 are fairly common interrupt request lines. Also note that regular serial ports cannot share interrupts on ISA-bus PCs (multiport boards have on-board electronics that allow all the 16550A's on the board to share one or two interrupt request lines). Device Special Files Most devices in the kernel are accessed through device special files, which are located in the /dev directory. The sio devices are accessed through the /dev/ttydN (dial-in) and /dev/cuaaN (call-out) devices. FreeBSD also provides initialization devices (/dev/ttyidN and /dev/cuai0N) and locking devices (/dev/ttyldN and /dev/cual0N). The initialization devices are used to initialize communications port parameters each time a port is opened, such as crtscts for modems which use CTS/RTS signaling for flow control. The locking devices are used to lock flags on ports to prevent users or programs changing certain parameters; see the manual pages &man.termios.4;, &man.sio.4;, and &man.stty.1; for information on the terminal settings, locking and initializing devices, and setting terminal options, respectively. Making Device Special Files FreeBSD 5.0 includes the devfs filesystem which automatically creates device nodes as needed. If you are running a version of FreeBSD with devfs enabled then you can safely skip this section. A shell script called MAKEDEV in the /dev directory manages the device special files. To use MAKEDEV to make dial-up device special files for COM1: (port 0), cd to /dev and issue the command MAKEDEV ttyd0. Likewise, to make dial-up device special files for COM2: (port 1), use MAKEDEV ttyd1. MAKEDEV not only creates the /dev/ttydN device special files, but also creates the /dev/cuaaN, /dev/cuaiaN, /dev/cualaN, /dev/ttyldN, and /dev/ttyidN nodes. After making new device special files, be sure to check the permissions on the files (especially the /dev/cua* files) to make sure that only users who should have access to those device special files can read and write on them — you probably do not want to allow your average user to use your modems to dial-out. The default permissions on the /dev/cua* files should be sufficient: crw-rw---- 1 uucp dialer 28, 129 Feb 15 14:38 /dev/cuaa1 crw-rw---- 1 uucp dialer 28, 161 Feb 15 14:38 /dev/cuaia1 crw-rw---- 1 uucp dialer 28, 193 Feb 15 14:38 /dev/cuala1 These permissions allow the user uucp and users in the group dialer to use the call-out devices. Serial Port Configuration ttyd cuaa The ttydN (or cuaaN) device is the regular device you will want to open for your applications. When a process opens the device, it will have a default set of terminal I/O settings. You can see these settings with the command &prompt.root; stty -a -f /dev/ttyd1 When you change the settings to this device, the settings are in effect until the device is closed. When it is reopened, it goes back to the default set. To make changes to the default set, you can open and adjust the settings of the initial state device. For example, to turn on mode, 8 bit communication, and flow control by default for ttyd5, type: &prompt.root; stty -f /dev/ttyid5 clocal cs8 ixon ixoff rc files rc.serial System-wide initialization of the serial devices is controlled in /etc/rc.serial. This file affects the default settings of serial devices. To prevent certain settings from being changed by an application, make adjustments to the lock state device. For example, to lock the speed of ttyd5 to 57600 bps, type: &prompt.root; stty -f /dev/ttyld5 57600 Now, an application that opens ttyd5 and tries to change the speed of the port will be stuck with 57600 bps. MAKEDEV Naturally, you should make the initial state and lock state devices writable only by the root account. Sean Kelly Contributed by Terminals terminals Terminals provide a convenient and low-cost way to access the power of your FreeBSD system when you are not at the computer's console or on a connected network. This section describes how to use terminals with FreeBSD. Uses and Types of Terminals The original Unix systems did not have consoles. Instead, people logged in and ran programs through terminals that were connected to the computer's serial ports. It is quite similar to using a modem and some terminal software to dial into a remote system to do text-only work. Today's PCs have consoles capable of high quality graphics, but the ability to establish a login session on a serial port still exists in nearly every Unix-style operating system today; FreeBSD is no exception. By using a terminal attached to a unused serial port, you can log in and run any text program that you would normally run on the console or in an xterm window in the X Window System. For the business user, you can attach many terminals to a FreeBSD system and place them on your employees' desktops. For a home user, a spare computer such as an older IBM PC or a Macintosh can be a terminal wired into a more powerful computer running FreeBSD. You can turn what might otherwise be a single-user computer into a powerful multiple user system. For FreeBSD, there are three kinds of terminals: Dumb terminals PCs acting as terminals X terminals The remaining subsections describe each kind. Dumb Terminals Dumb terminals are specialized pieces of hardware that let you connect to computers over serial lines. They are called dumb because they have only enough computational power to display, send, and receive text. You cannot run any programs on them. It is the computer to which you connect them that has all the power to run text editors, compilers, email, games, and so forth. There are hundreds of kinds of dumb terminals made by many manufacturers, including Digital Equipment Corporation's VT-100 and Wyse's WY-75. Just about any kind will work with FreeBSD. Some high-end terminals can even display graphics, but only certain software packages can take advantage of these advanced features. Dumb terminals are popular in work environments where workers do not need access to graphic applications such as those provided by the X Window System. PCs Acting As Terminals If a dumb terminal has just enough ability to display, send, and receive text, then certainly any spare personal computer can be a dumb terminal. All you need is the proper cable and some terminal emulation software to run on the computer. Such a configuration is popular in homes. For example, if your spouse is busy working on your FreeBSD system's console, you can do some text-only work at the same time from a less powerful personal computer hooked up as a terminal to the FreeBSD system. X Terminals X terminals are the most sophisticated kind of terminal available. Instead of connecting to a serial port, they usually connect to a network like Ethernet. Instead of being relegated to text-only applications, they can display any X application. We introduce X terminals just for the sake of completeness. However, this chapter does not cover setup, configuration, or use of X terminals. Configuration This section describes what you need to configure on your FreeBSD system to enable a login session on a terminal. It assumes you have already configured your kernel to support the serial port to which the terminal is connected—and that you have connected it. Recall from that the init process is responsible for all process control and initialization at system startup. One of the tasks performed by init is to read the /etc/ttys file and start a getty process on the available terminals. The getty process is responsible for reading a login name and starting the login program. Thus, to configure terminals for your FreeBSD system the following steps should be taken as root : Add a line to /etc/ttys for the entry in the /dev directory for the serial port if it is not already there. Specify that /usr/libexec/getty be run on the port, and specify the appropriate getty type from the /etc/gettytab file. Specify the default terminal type. Set the port to on. Specify whether the port should be secure. Force init to reread the /etc/ttys file. As an optional step, you may wish to create a custom getty type for use in step 2 by making an entry in /etc/gettytab. This chapter does not explain how to do so; you are encouraged to see the &man.gettytab.5; and the &man.getty.8; manual pages for more information. Adding an Entry to <filename>/etc/ttys</filename> The /etc/ttys file lists all of the ports on your FreeBSD system where you want to allow logins. For example, the first virtual console ttyv0 has an entry in this file. You can log in on the console using this entry. This file also contains entries for the other virtual consoles, serial ports, and pseudo-ttys. For a hardwired terminal, just list the serial port's /dev entry without the /dev part. A default FreeBSD install includes a /etc/ttys file with support for the first four serial ports: ttyd0 through ttyd3. If you are attaching a terminal to one of those ports, you do not need to add another entry. Adding Terminal Entries to <filename>/etc/ttys</filename> Suppose we would like to connect two terminals to the system: a Wyse-50 and an old 286 IBM PC running Procomm terminal software emulating a VT-100 terminal. We connect the Wyse to the second serial port and the 286 to the sixth serial port (a port on a multiport serial card). The corresponding entries in the /etc/ttys file would look like this: ttyd1 "/usr/libexec/getty std.38400" wy50 on insecure ttyd5 "/usr/libexec/getty std.19200" vt100 on insecure The first field normally specifies the name of the terminal special file as it is found in /dev. The second field is the command to execute for this line, which is usually &man.getty.8;. getty initializes and opens the line, sets the speed, prompts for a user name and then executes the &man.login.1; program. The getty program accepts one (optional) parameter on its command line, the getty type. A getty type tells about characteristics on the terminal line, like bps rate and parity. The getty program reads these characteristics from the file /etc/gettytab. The file /etc/gettytab contains lots of entries for terminal lines both old and new. In almost all cases, the entries that start with the text std will work for hardwired terminals. These entries ignore parity. There is a std entry for each bps rate from 110 to 115200. Of course, you can add your own entries to this file. The &man.gettytab.5; manual page provides more information. When setting the getty type in the /etc/ttys file, make sure that the communications settings on the terminal match. For our example, the Wyse-50 uses no parity and connects at 38400 bps. The 286 PC uses no parity and connects at 19200 bps. The third field is the type of terminal usually connected to that tty line. For dial-up ports, unknown or dialup is typically used in this field since users may dial up with practically any type of terminal or software. For hardwired terminals, the terminal type does not change, so you can put a real terminal type from the &man.termcap.5; database file in this field. For our example, the Wyse-50 uses the real terminal type while the 286 PC running Procomm will be set to emulate at VT-100. The fourth field specifies if the port should be enabled. Putting on here will have the init process start the program in the second field, getty. If you put off in this field, there will be no getty, and hence no logins on the port. The final field is used to specify whether the port is secure. Marking a port as secure means that you trust it enough to allow the root account (or any account with a user ID of 0) to login from that port. Insecure ports do not allow root logins. On an insecure port, users must login from unprivileged accounts and then use &man.su.1; or a similar mechanism to gain superuser privileges. It is highly recommended that you use "insecure" even for terminals that are behind locked doors. It is quite easy to login and use su if you need superuser privileges. Force <command>init</command> to Reread <filename>/etc/ttys</filename> After making the necessary changes to the /etc/ttys file you should send a SIGHUP (hangup) signal to the init process to force it to re-read its configuration file. For example : &prompt.root; kill -HUP 1 If everything is set up correctly, all cables are in place, and the terminals are powered up, then a getty process should be running on each terminal and you should see login prompts on your terminals at this point. Troubleshooting Your Connection Even with the most meticulous attention to detail, something could still go wrong while setting up a terminal. Here is a list of symptoms and some suggested fixes. No login prompt appears Make sure the terminal is plugged in and powered up. If it is a personal computer acting as a terminal, make sure it is running terminal emulation software on the correct serial port. Make sure the cable is connected firmly to both the terminal and the FreeBSD computer. Make sure it is the right kind of cable. Make sure the terminal and FreeBSD agree on the bps rate and parity settings. If you have a video display terminal, make sure the contrast and brightness controls are turned up. If it is a printing terminal, make sure paper and ink are in good supply. Make sure that a getty process is running and serving the terminal. For example, to get a list of running getty processes with ps, type: &prompt.root; ps -axww|grep getty You should see an entry for the terminal. For example, the following display shows that a getty is running on the second serial port ttyd1 and is using the std.38400 entry in /etc/gettytab: 22189 d1 Is+ 0:00.03 /usr/libexec/getty std.38400 ttyd1 If no getty process is running, make sure you have enabled the port in /etc/ttys. Also remember to run kill -HUP 1 after modifying the ttys file. Garbage appears instead of a login prompt Make sure the terminal and FreeBSD agree on the bps rate and parity settings. Check the getty processes to make sure the correct getty type is in use. If not, edit /etc/ttys and run kill -HUP 1. Characters appear doubled; the password appears when typed Switch the terminal (or the terminal emulation software) from half duplex or local echo to full duplex. Guy Helmer Contributed by Sean Kelly Additions by Dial-in Service dial-in service Configuring your FreeBSD system for dial-in service is very - similar to connecting terminals except that you're dealing with + similar to connecting terminals except that you are dealing with modems instead of terminals. External v.s. Internal Modems External modems seem to be more convenient for dial-up, because external modems often can be semi-permanently configured via parameters stored in non-volatile RAM and they usually provide lighted indicators that display the state of important RS-232 signals. Blinking lights impress visitors, but lights are also very useful to see whether a modem is operating properly. Internal modems usually lack non-volatile RAM, so their configuration may be limited only to setting DIP switches. If your internal modem has any signal indicator lights, it is probably difficult to view the lights when the system's cover is in place. Modems and Cables modem If you are using an external modem, then you will of course need the proper cable. A standard RS-232C serial cable should suffice as long as all of the normal signals are wired : Transmitted Data (SD) Received Data (RD) Request to Send (RTS) Clear to Send (CTS) Data Set Ready (DSR) Data Terminal Ready (DTR) Carrier Detect (CD) Signal Ground (SG) FreeBSD needs the RTS and CTS signals for flow-control at speeds above 2400bps, the CD signal to detect when a call has been answered or the line has been hung up, and the DTR signal to reset the modem after a session is complete. Some cables are wired without all of the needed signals, so if you have problems, such as a login session not going away when the line hangs up, you may have a problem with your cable. Like other Unix-like operating systems, FreeBSD uses the hardware signals to find out when a call has been answered or a line has been hung up and to hangup and reset the modem after a call. FreeBSD avoids sending commands to the modem or watching for status reports from the modem. If you are familiar with connecting modems to PC-based bulletin board systems, this may seem awkward. Serial Interface Considerations FreeBSD supports NS8250-, NS16450-, NS16550-, and NS16550A-based EIA RS-232C (CCITT V.24) communications interfaces. The 8250 and 16450 devices have single-character buffers. The 16550 device provides a 16-character buffer, which allows for better system performance. (Bugs in plain 16550's prevent the use of the 16-character buffer, so use 16550A's if possible). Because single-character-buffer devices require more work by the operating system than the 16-character-buffer devices, 16550A-based serial interface cards are much preferred. If the system has many active serial ports or will have a heavy load, 16550A-based cards are better for low-error-rate communications. Quick Overview getty As with terminals, init spawns a getty process for each configured serial port for dial-in connections. For example, if a modem is attached to /dev/ttyd0, the command ps ax might show this: 4850 ?? I 0:00.09 /usr/libexec/getty V19200 ttyd0 When a user dials the modem's line and the modems connect, the CD line is asserted by the modem. The kernel notices that carrier has been detected and completes getty's open of the port. getty sends a login: prompt at the specified initial line speed. getty watches to see if legitimate characters are received, and, in a typical configuration, if it finds junk (probably due to the modem's connection speed being different than getty's speed), getty tries adjusting the line speeds until it receives reasonable characters. /usr/bin/login After the user enters his/her login name, getty executes /usr/bin/login, which completes the login by asking for the user's password and then starting the user's shell. Configuration Files There are three system configuration files in the /etc directory that you will probably need to edit to allow dial-up access to your FreeBSD system. The first, /etc/gettytab, contains configuration information for the /usr/libexec/getty daemon. Second, /etc/ttys holds information that tells /sbin/init what tty devices should have getty processes running on them. Lastly, you can place port initialization commands in the /etc/rc.serial script. There are two schools of thought regarding dial-up modems on Unix. One group likes to configure their modems and systems so that no matter at what speed a remote user dials in, the local computer-to-modem RS-232 interface runs at a locked speed. The benefit of this configuration is that the remote user always sees a system login prompt immediately. The downside is that the system does not know what a user's true data rate is, so full-screen programs like Emacs will not adjust their screen-painting methods to make their response better for slower connections. The other school configures their modems' RS-232 interface to vary its speed based on the remote user's connection speed. For example, V.32bis (14.4 Kbps) connections to the modem might make the modem run its RS-232 interface at 19.2 Kbps, while 2400 bps connections make the modem's RS-232 interface run at 2400 bps. Because getty does not understand any particular modem's connection speed reporting, getty gives a login: message at an initial speed and watches the characters that come back in response. If the user sees junk, it is assumed that they know they should press the Enter key until they see a recognizable prompt. If the data rates do not match, getty sees anything the user types as junk, tries going to the next speed and gives the login: prompt again. This procedure can continue ad nauseam, but normally only takes a keystroke or two before the user sees a good prompt. Obviously, this login sequence does not look as clean as the former locked-speed method, but a user on a low-speed connection should receive better interactive response from full-screen programs. The authors will try to give balanced configuration information, but is biased towards having the modem's data rate follow the connection rate. <filename>/etc/gettytab</filename> /etc/gettytab /etc/gettytab is a &man.termcap.5;-style file of configuration information for &man.getty.8;. Please see the &man.gettytab.5; manual page for complete information on the format of the file and the list of capabilities. Locked-Speed Config If you are locking your modem's data communications rate at a particular speed, you probably will not need to make any changes to /etc/gettytab. Matching-Speed Config You will need to setup an entry in /etc/gettytab to give getty information about the speeds you wish to use for your modem. If you have a 2400 bps modem, you can probably use the existing D2400 entry. # # Fast dialup terminals, 2400/1200/300 rotary (can start either way) # D2400|d2400|Fast-Dial-2400:\ :nx=D1200:tc=2400-baud: 3|D1200|Fast-Dial-1200:\ :nx=D300:tc=1200-baud: 5|D300|Fast-Dial-300:\ :nx=D2400:tc=300-baud: If you have a higher speed modem, you will probably need to add an entry in /etc/gettytab; here is an entry you could use for a 14.4 Kbps modem with a top interface speed of 19.2 Kbps: # # Additions for a V.32bis Modem # um|V300|High Speed Modem at 300,8-bit:\ :nx=V19200:tc=std.300: un|V1200|High Speed Modem at 1200,8-bit:\ :nx=V300:tc=std.1200: uo|V2400|High Speed Modem at 2400,8-bit:\ :nx=V1200:tc=std.2400: up|V9600|High Speed Modem at 9600,8-bit:\ :nx=V2400:tc=std.9600: uq|V19200|High Speed Modem at 19200,8-bit:\ :nx=V9600:tc=std.19200: This will result in 8-bit, no parity connections. The example above starts the communications rate at 19.2 Kbps (for a V.32bis connection), then cycles through 9600 bps (for V.32), 2400 bps, 1200 bps, 300 bps, and back to 19.2 Kbps. Communications rate cycling is implemented with the nx= (next table) capability. Each of the lines uses a tc= (table continuation) entry to pick up the rest of the standard settings for a particular data rate. If you have a 28.8 Kbps modem and/or you want to take advantage of compression on a 14.4 Kbps modem, you need to use a higher communications rate than 19.2 Kbps. Here is an example of a gettytab entry starting a 57.6 Kbps: # # Additions for a V.32bis or V.34 Modem # Starting at 57.6 Kbps # vm|VH300|Very High Speed Modem at 300,8-bit:\ :nx=VH57600:tc=std.300: vn|VH1200|Very High Speed Modem at 1200,8-bit:\ :nx=VH300:tc=std.1200: vo|VH2400|Very High Speed Modem at 2400,8-bit:\ :nx=VH1200:tc=std.2400: vp|VH9600|Very High Speed Modem at 9600,8-bit:\ :nx=VH2400:tc=std.9600: vq|VH57600|Very High Speed Modem at 57600,8-bit:\ :nx=VH9600:tc=std.57600: If you have a slow CPU or a heavily loaded system and you do not have 16550A-based serial ports, you may receive sio silo errors at 57.6 Kbps. <filename>/etc/ttys</filename> /etc/ttys Configuration of the /etc/ttys file was covered in . Configuration for modems is similar but we must pass a different argument to getty and specify a different terminal type. The general format for both locked-speed and matching-speed configurations is: ttyd0 "/usr/libexec/getty xxx" dialup on The first item in the above line is the device special file for this entry — ttyd0 means /dev/ttyd0 is the file that this getty will be watching. The second item, "/usr/libexec/getty xxx" (xxx will be replaced by the initial gettytab capability) is the process init will run on the device. The third item, dialup, is the default terminal type. The fourth parameter, on, indicates to init that the line is operational. There can be a fifth parameter, secure, but it should only be used for terminals which are physically secure (such as the system console). The default terminal type (dialup in the example above) may depend on local preferences. dialup is the traditional default terminal type on dial-up lines so that users may customize their login scripts to notice when the terminal is dialup and automatically adjust their terminal type. However, the author finds it easier at his site to specify vt102 as the default terminal type, since the users just use VT102 emulation on their remote systems. After you have made changes to /etc/ttys, you may send the init process a HUP signal to re-read the file. You can use the command &prompt.root; kill -HUP 1 to send the signal. If this is your first time setting up the system, though, you may want to wait until your modem(s) are properly configured and connected before signaling init. Locked-Speed Config For a locked-speed configuration, your ttys entry needs to have a fixed-speed entry provided to getty. For a modem whose port speed is locked at 19.2 Kbps, the ttys entry might look like this: ttyd0 "/usr/libexec/getty std.19200" dialup on If your modem is locked at a different data rate, substitute the appropriate value for std.speed instead of std.19200. Make sure that you use a valid type listed in /etc/gettytab. Matching-Speed Config In a matching-speed configuration, your ttys entry needs to reference the appropriate beginning auto-baud (sic) entry in /etc/gettytab. For example, if you added the above suggested entry for a matching-speed modem that starts at 19.2 Kbps (the gettytab entry containing the V19200 starting point), your ttys entry might look like this: ttyd0 "/usr/libexec/getty V19200" dialup on <filename>/etc/rc.serial</filename> rc files rc.serial High-speed modems, like V.32, V.32bis, and V.34 modems, need to use hardware (RTS/CTS) flow control. You can add stty commands to /etc/rc.serial to set the hardware flow control flag in the FreeBSD kernel for the modem ports. For example to set the termios flag crtscts on serial port #1's (COM2:) dial-in and dial-out initialization devices, the following lines could be added to /etc/rc.serial : # Serial port initial configuration stty -f /dev/ttyid1 crtscts stty -f /dev/cuai01 crtscts Modem Settings If you have a modem whose parameters may be permanently set in non-volatile RAM, you will need to use a terminal program (such as Telix under MS-DOS or tip under FreeBSD) to set the parameters. Connect to the modem using the same communications speed as the initial speed getty will use and configure the modem's non-volatile RAM to match these requirements: CD asserted when connected DTR asserted for operation; dropping DTR hangs up line and resets modem CTS transmitted data flow control Disable XON/XOFF flow control RTS received data flow control Quiet mode (no result codes) No command echo Please read the documentation for your modem to find out what commands and/or DIP switch settings you need to give it. For example, to set the above parameters on a USRobotics Sportster 14,400 external modem, one could give these commands to the modem: ATZ AT&C1&D2&H1&I0&R2&W You might also want to take this opportunity to adjust other settings in the modem, such as whether it will use V.42bis and/or MNP5 compression. The USR Sportster 14,400 external modem also has some DIP switches that need to be set; for other modems, perhaps you can use these settings as an example: Switch 1: UP — DTR Normal Switch 2: Do not care (Verbal Result Codes/Numeric Result Codes) Switch 3: UP — Suppress Result Codes Switch 4: DOWN — No echo, offline commands Switch 5: UP — Auto Answer Switch 6: UP — Carrier Detect Normal Switch 7: UP — Load NVRAM Defaults Switch 8: Do not care (Smart Mode/Dumb Mode) Result codes should be disabled/suppressed for dial-up modems to avoid problems that can occur if getty mistakenly gives a login: prompt to a modem that is in command mode and the modem echoes the command or returns a result code. This sequence can result in a extended, silly conversation between getty and the modem. Locked-speed Config For a locked-speed configuration, you will need to configure the modem to maintain a constant modem-to-computer data rate independent of the communications rate. On a USR Sportster 14,400 external modem, these commands will lock the modem-to-computer data rate at the speed used to issue the commands: ATZ AT&B1&W Matching-speed Config For a variable-speed configuration, you will need to configure your modem to adjust its serial port data rate to match the incoming call rate. On a USR Sportster 14,400 external modem, these commands will lock the modem's error-corrected data rate to the speed used to issue the commands, but allow the serial port rate to vary for non-error-corrected connections: ATZ AT&B2&W Checking the Modem's Configuration Most high-speed modems provide commands to view the modem's current operating parameters in a somewhat human-readable fashion. On the USR Sportster 14,400 external modems, the command ATI5 displays the settings that are stored in the non-volatile RAM. To see the true operating parameters of the modem (as influenced by the USR's DIP switch settings), use the commands ATZ and then ATI4. If you have a different brand of modem, check your modem's manual to see how to double-check your modem's configuration parameters. Troubleshooting Here are a few steps you can follow to check out the dial-up modem on your system. Checking out the FreeBSD System Hook up your modem to your FreeBSD system, boot the system, and, if your modem has status indication lights, watch to see whether the modem's DTR indicator lights when the login: prompt appears on the system's console — if it lights up, that should mean that FreeBSD has started a getty process on the appropriate communications port and is waiting for the modem to accept a call. - If the DTR indicator doesn't light, login to + If the DTR indicator does not light, login to the FreeBSD system through the console and issue a ps ax to see if FreeBSD is trying to run a getty process on the correct port. You should see a lines like this among the processes displayed: 114 ?? I 0:00.10 /usr/libexec/getty V19200 ttyd0 115 ?? I 0:00.10 /usr/libexec/getty V19200 ttyd1 If you see something different, like this: 114 d0 I 0:00.10 /usr/libexec/getty V19200 ttyd0 and the modem has not accepted a call yet, this means that getty has completed its open on the communications port. This could indicate a problem with the cabling or a mis-configured modem, because getty should not be able to open the communications port until CD (carrier detect) has been asserted by the modem. If you do not see any getty processes waiting to open the desired ttydN port, double-check your entries in /etc/ttys to see if there are any mistakes there. Also, check the log file /var/log/messages to see if there are any log messages from init or getty regarding any problems. If there are any messages, triple-check the configuration files /etc/ttys and /etc/gettytab, as well as the appropriate device special files /dev/ttydN, for any mistakes, missing entries, or missing device special files. Try Dialing In Try dialing into the system; be sure to use 8 bits, no parity, 1 stop bit on the remote system. If you do not get a prompt right away, or get garbage, try pressing Enter about once per second. If you still do not see a login: prompt after a while, try sending a BREAK. If you are using a high-speed modem to do the dialing, try dialing again after locking the dialing modem's interface speed (via AT&B1 on a USR Sportster, for example). If you still cannot get a login: prompt, check /etc/gettytab again and double-check that The initial capability name specified in /etc/ttys for the line matches a name of a capability in /etc/gettytab Each nx= entry matches another gettytab capability name Each tc= entry matches another gettytab capability name If you dial but the modem on the FreeBSD system will not answer, make sure that the modem is configured to answer the phone when DTR is asserted. If the modem seems to be configured correctly, verify that the DTR line is asserted by checking the modem's indicator lights (if it has any). If you have gone over everything several times and it still does not work, take a break and come back to it later. If it still does not work, perhaps you can send an electronic mail message to the &a.questions;describing your modem and your problem, and the good folks on the list will try to help. Dial-out Service dial-out service The following are tips to getting your host to be able to connect over the modem to another computer. This is appropriate for establishing a terminal session with a remote host. This is useful to log onto a BBS. This kind of connection can be extremely helpful to get a file on the Internet if you have problems with PPP. If you need to FTP something and PPP is broken, use the terminal session to FTP it. Then use zmodem to transfer it to your machine. My Stock Hayes Modem Is Not Supported, What Can I Do? Actually, the manual page for tip is out of date. There is a generic Hayes dialer already built in. Just use at=hayes in your /etc/remote file. The Hayes driver is not smart enough to recognize some of the advanced features of newer modems—messages like BUSY, NO DIALTONE, or CONNECT 115200 will just confuse it. You should turn those messages off when you use tip (using ATX0&W). Also, the dial timeout for tip is 60 seconds. Your modem should use something less, or else tip will think there is a communication problem. Try ATS7=45&W. Actually, as shipped tip does not yet support it fully. The solution is to edit the file tipconf.h in the directory /usr/src/usr.bin/tip/tip Obviously you need the source distribution to do this. Edit the line #define HAYES 0 to #define HAYES 1. Then make and make install. Everything works nicely after that. How Am I Expected to Enter These AT Commands? /etc/remote Make what is called a direct entry in your /etc/remote file. For example, if your modem is hooked up to the first serial port, /dev/cuaa0, then put in the following line: cuaa0:dv=/dev/cuaa0:br#19200:pa=none Use the highest bps rate your modem supports in the br capability. Then, type tip cuaa0 and you will be connected to your modem. If there is no /dev/cuaa0 on your system, do this: &prompt.root; cd /dev &prompt.root; MAKEDEV cuaa0 Or use cu as root with the following command: &prompt.root; cu -lline -sspeed line is the serial port (e.g./dev/cuaa0) and speed is the speed (e.g.57600). When you are done entering the AT commands hit ~. to exit. The <literal>@</literal> Sign for the pn Capability Does Not Work! The @ sign in the phone number capability tells tip to look in /etc/phones for a phone number. But the @ sign is also a special character in capability files like /etc/remote. Escape it with a backslash: pn=\@ How Can I Dial a Phone Number on the Command Line? Put what is called a generic entry in your /etc/remote file. For example: tip115200|Dial any phone number at 115200 bps:\ :dv=/dev/cuaa0:br#115200:at=hayes:pa=none:du: tip57600|Dial any phone number at 57600 bps:\ :dv=/dev/cuaa0:br#57600:at=hayes:pa=none:du: Then you can things like: &prompt.root; tip -115200 5551234 If you prefer cu over tip, use a generic cu entry: cu115200|Use cu to dial any number at 115200bps:\ :dv=/dev/cuaa1:br#57600:at=hayes:pa=none:du: and type: &prompt.root; cu 5551234 -s 115200 Do I Have to Type in the bps Rate Every Time I Do That? Put in an entry for tip1200 or cu1200, but go ahead and use whatever bps rate is appropriate with the br capability. tip thinks a good default is 1200 bps which is why it looks for a tip1200 entry. You do not have to use 1200 bps, though. I Access a Number of Hosts through a Terminal Server. Rather than waiting until you are connected and typing CONNECT <host> each time, use tip's cm capability. For example, these entries in /etc/remote: pain|pain.deep13.com|Forrester's machine:\ :cm=CONNECT pain\n:tc=deep13: muffin|muffin.deep13.com|Frank's machine:\ :cm=CONNECT muffin\n:tc=deep13: deep13:Gizmonics Institute terminal server:\ :dv=/dev/cuaa2:br#38400:at=hayes:du:pa=none:pn=5551234: will let you type tip pain or tip muffin to connect to the hosts pain or muffin; and tip deep13 to get to the terminal server. Can Tip Try More Than one Line for each Site? This is often a problem where a university has several modem lines and several thousand students trying to use them... Make an entry for your university in /etc/remote and use @ for the pn capability: big-university:\ :pn=\@:tc=dialout dialout:\ :dv=/dev/cuaa3:br#9600:at=courier:du:pa=none: Then, list the phone numbers for the university in /etc/phones: big-university 5551111 big-university 5551112 big-university 5551113 big-university 5551114 tip will try each one in the listed order, then give up. If you want to keep retrying, run tip in a while loop. Why Do I Have to Hit <keycombo action="simul"> <keycap>Ctrl</keycap><keycap>P</keycap> </keycombo> Twice to Send <keycombo action="simul"> <keycap>Ctrl</keycap><keycap>P</keycap> </keycombo> Once? CtrlP is the default force character, used to tell tip that the next character is literal data. You can set the force character to any other character with the ~s escape, which means set a variable. Type ~sforce=single-char followed by a newline. single-char is any single character. If you leave out single-char, then the force character is the nul character, which you can get by typing Ctrl2 or CtrlSPACE . A pretty good value for single-char is Shift Ctrl 6 , which is only used on some terminal servers. You can have the force character be whatever you want by specifying the following in your $HOME/.tiprc file: force=<single-char> Suddenly Everything I Type Is in UPPER CASE?? You must have pressed Ctrl A , tip's raise character, specially designed for people with broken caps-lock keys. Use ~s as above and set the variable raisechar to something reasonable. In fact, you can set it to the same as the force character, if you never expect to use either of these features. Here is a sample .tiprc file perfect for Emacs users who need to type Ctrl2 and CtrlA a lot: force=^^ raisechar=^^ The ^^ is ShiftCtrl6 . How Can I Do File Transfers with <command>tip</command>? If you are talking to another Unix system, you can send and receive files with ~p (put) and ~t (take). These commands run cat and echo on the remote system to accept and send files. The syntax is: ~p local-file remote-file ~t remote-file local-file There is no error checking, so you probably should use another protocol, like zmodem. How Can I Run zmodem with <command>tip</command>? To receive files, start the sending program on the remote end. Then, type ~C rz to begin receiving them locally. To send files, start the receiving program on the remote end. Then, type ~C sz files to send them to the remote system. Kazutaka YOKOTA Contributed by Bill Paul Based on a document by Setting Up the Serial Console serial console Introduction FreeBSD boot on a system with only a dumb terminal on a serial port as a console. Such a configuration should be useful for two classes of people: system administrators who wish to install FreeBSD on machines that have no keyboard or monitor attached, and developers who want to debug the kernel or device drivers. As described in , FreeBSD employs a three stage bootstrap. The first two stages are in the boot block code which is stored at the beginning of the FreeBSD slice on the boot disk. The boot block will then load and run the boot loader (/boot/loader) as the third stage code. In order to set up the serial console you must configure the boot block code, the boot loader code and the kernel. Serial Console Configuration Prepare a serial cable. null-modem cable You will need either a null-modem cable or a standard serial cable and a null-modem adapter. See for a discussion on serial cables. Unplug your keyboard. Most PC systems probe for the keyboard during the Power-On Self-Test (POST) and will generate an error if the keyboard is not detected. Some machines complain loudly about the lack of a keyboard and will not continue to boot until it is plugged in. If your computer complains about the error, but boots anyway, then you do not have to do anything special. (Some machines with Phoenix BIOS installed merely say Keyboard failed and continue to boot normally.) If your computer refuses to boot without a keyboard attached then you will have to configure the BIOS so that it ignores this error (if it can). Consult your motherboard's manual for details on how to do this. Setting the keyboard to Not installed in the BIOS setup does not mean that you will not be able to use your keyboard. All this does is tell the BIOS not to probe for a keyboard at power-on so that it will not complain if the keyboard is not plugged in. You can leave the keyboard plugged in even with this flag set to Not installed and the keyboard will still work. If your system has a PS/2 mouse, chances are very good that you may have to unplug your mouse as well as your keyboard. This is because PS/2 mice share some hardware with the keyboard, and leaving the mouse plugged in can fool the keyboard probe into thinking the keyboard is still there. It is said that a Gateway 2000 Pentium 90MHz system with an AMI BIOS that behaves this way. In general this is not a problem since the mouse is not much good without the keyboard anyway. Plug a dumb terminal into COM1: (sio0). If you do not have a dumb terminal, you can use an old PC/XT with a modem program, or the serial port on another Unix box. If you do not have a COM1: (sio0), get one. At this time, there is no way to select a port other than COM1: for the boot blocks without recompiling the boot blocks. If you are already using COM1: for another device, you will have to temporarily remove that device and install a new boot block and kernel once you get FreeBSD up and running. (It is assumed that COM1: will be available on a file/compute/terminal server anyway; if you really need COM1: for something else (and you cannot switch that something else to COM2: (sio1)), then you probably should not even be bothering with all this in the first place.) Make sure the configuration file of your kernel has appropriate flags set for COM1: (sio0). Relevant flags are: 0x10 Enables console support for this unit. The other console flags are ignored unless this is set. Currently, at most one unit can have console support; the first one (in config file order) with this flag set is preferred. This option alone will not make the serial port the console. Set the following flag or use the option described below, together with this flag. 0x20 Forces this unit to be the console (unless there is another higher priority console), regardless of the option discussed below. This flag replaces the COMCONSOLE option in FreeBSD versions 2.X. The flag 0x20 must be used together with the flag. 0x40 Reserves this unit (in conjunction with 0x10) and makes the unit unavailable for normal access. You should not set this flag to the serial port unit which you want to use as the serial console. The only use of this flag is to designate the unit for kernel remote debugging. See The Developer's Handbook for more information on remote debugging. In FreeBSD 4.0-CURRENT or later the semantics of the flag 0x40 are slightly different and there is another flag to specify a serial port for remote debugging. Example: device sio0 at isa? port "IO_COM1" tty flags 0x10 irq 4 See the &man.sio.4; manual page for more details. If the flags were not set, you need to run UserConfig (on a different console) or recompile the kernel. Create boot.config in the root directory of the a partition on the boot drive. This file will instruct the boot block code how you would like to boot the system. In order to activate the serial console, you need one or more of the following options—if you want multiple options, include them all on the same line: Toggles internal and serial consoles. You can use this to switch console devices. For instance, if you boot from the internal (video) console, you can use to direct the boot loader and the kernel to use the serial port as its console device. Alternatively, if you boot from the serial port, you can use the to tell the boot loader and the kernel to use the video display as the console instead. Toggles single and dual console configurations. In the single configuration the console will be either the internal console (video display) or the serial port, depending on the state of the option above. In the dual console configuration, both the video display and the serial port will become the console at the same time, regardless of the state of the option. However, that the dual console configuration takes effect only during the boot block is running. Once the boot loader gets control, the console specified by the option becomes the only console. Makes the boot block probe the keyboard. If no keyboard is found, the and options are automatically set. Due to space constraints in the current version of the boot blocks, the option is capable of detecting extended keyboards only. Keyboards with less than 101 keys (and without F11 and F12 keys) may not be detected. Keyboards on some laptop computers may not be properly found because of this limitation. If this is to be the case with your system, you have to abandon using the option. Unfortunately there is no workaround for this problem. Use either the option to select the console automatically, or the option to activate the serial console. You may include other options described in &man.boot.8; as well. The options, except for , will be passed to the boot loader (/boot/loader). The boot loader will determine which of the internal video or the serial port should become the console by examining the state of the option alone. This means that if you specify the option but not the option in /boot.config, you can use the serial port as the console only during the boot block; the boot loader will use the internal video display as the console. Boot the machine. When you start your FreeBSD box, the boot blocks will echo the contents of /boot.config to the console. For example; /boot.config: -P Keyboard: no The second line appears only if you put in /boot.config and indicates presence/absence of the keyboard. These messages go to either serial or internal console, or both, depending on the option in /boot.config. Options Message goes to none internal console serial console serial and internal consoles serial and internal consoles , keyboard present internal console , keyboard absent serial console After the above messages, there will be a small pause before the boot blocks continue loading the boot loader and before any further messages printed to the console. Under normal circumstances, you do not need to interrupt the boot blocks, but you may want to do so in order to make sure things are set up correctly. Hit any key, other than Enter, at the console to interrupt the boot process. The boot blocks will then prompt you for further action. You should now see something like: >> FreeBSD/i386 BOOT Default: 0:wd(0,a)/boot/loader boot: Verify the above message appears on either the serial or internal console or both, according to the options you put in /boot.config. If the message appears in the correct console, hit Enter to continue the boot process. If you want the serial console but you do not see the prompt on the serial terminal, something is wrong with your settings. In the meantime, you enter and hit Enter/Return (if possible) to tell the boot block (and then the boot loader and the kernel) to choose the serial port for the console. Once the system is up, go back and check what went wrong. After the boot loader is loaded and you are in the third stage of the boot process you can still switch between the internal console and the serial console by setting appropriate environment variables in the boot loader. See . Summary Here is the summary of various settings discussed in this section and the console eventually selected. Case 1: You Set the flags to 0x10 for sio0 device sio0 at isa? port "IO_COM1" tty flags 0x10 irq 4 Options in /boot.config Console during boot blocks Console during boot loader Console in kernel nothing internal internal internal serial serial serial serial and internal internal internal serial and internal serial serial , keyboard present internal internal internal , keyboard absent serial and internal serial serial Case 2: You Set the flags to 0x30 for sio0 device sio0 at isa? port "IO_COM1" tty flags 0x30 irq 4 Options in /boot.config Console during boot blocks Console during boot loader Console in kernel nothing internal internal serial serial serial serial serial and internal internal serial serial and internal serial serial , keyboard present internal internal serial , keyboard absent serial and internal serial serial Tips for the Serial Console Setting a Faster Serial Port Speed By default the serial port settings are set to 9600 baud, 8 bits, no parity, 1 stop bit. If you wish to change the speed, you need to recompile at least the boot blocks. Add the following line to /etc/make.conf and compile new boot blocks: BOOT_COMCONSOLE_SPEED=19200 If the serial console is configured in some other way than by booting with , or if the serial console used by the kernel is different from the one used by the boot blocks, then you must also add the following option to the kernel configuration file and compile a new kernel: options CONSPEED=19200 Using Serial Port Other Than <devicename>sio0</devicename> for the Console Using a port other than sio0 as the console requires some recompiling. If you want to use another serial port for whatever reasons, recompile the boot blocks, the boot loader and the kernel as follows. Get the kernel source. Edit /etc/make.conf and set BOOT_COMCONSOLE_PORT to the address of the port you want to use (0x3F8, 0x2F8, 0x3E8 or 0x2E8). Only sio0 through sio3 (COM1: through COM4:) can be used; multiport serial cards will not work. No interrupt setting is needed. Create a custom kernel configuration file and add appropriate flags for the serial port you want to use. For example, if you want to make sio1 (COM2:) the console: device sio1 at isa? port "IO_COM2" tty flags 0x10 irq 3 or device sio1 at isa? port "IO_COM2" tty flags 0x30 irq 3 The console flags for the other serial ports should not be set. Recompile and install the boot blocks: &prompt.root; cd /sys/boot/i386/boot2 &prompt.root; make &prompt.root; make install Recompile and install the boot loader: &prompt.root; cd /sys/boot/i386/loader &prompt.root; make &prompt.root; make install Rebuild and install the kernel. Write the boot blocks to the boot disk with &man.disklabel.8; and boot from the new kernel. Entering the DDB Debugger from the Serial Line If you wish to drop into the kernel debugger from the serial console (useful for remote diagnostics, but also dangerous if you generate a spurious BREAK on the serial port!) then you should compile your kernel with the following options: options BREAK_TO_DEBUGGER options DDB Getting a Login Prompt on the Serial Console While this is not required, you may wish to get a login prompt over the serial line, now that you can see boot messages and can enter the kernel debugging session through the serial console. Here is how to do it. Open the file /etc/ttys with an editor and locate the lines: ttyd0 "/usr/libexec/getty std.9600" unknown off secure ttyd1 "/usr/libexec/getty std.9600" unknown off secure ttyd2 "/usr/libexec/getty std.9600" unknown off secure ttyd3 "/usr/libexec/getty std.9600" unknown off secure ttyd0 through ttyd3 corresponds to COM1 through COM4. Change off to on for the desired port. If you have changed the speed of the serial port, you need to change std.9600 to match the current setting, e.g. std.19200. You may also want to change the terminal type from unknown to the actual type of your serial terminal. After editing the file, you must kill -HUP 1 to make this change take effect. Changing Console from the Boot Loader Previous sections described how to set up the serial console by tweaking the boot block. This section shows that you can specify the console by entering some commands and environment variables in the boot loader. As the boot loader is invoked as the third stage of the boot process, after the boot block, the settings in the boot loader will override the settings in the boot block. Setting up the Serial Console You can easily specify the boot loader and the kernel to use the serial console by writing just one line in /boot/loader.rc: set console=comconsole This will take effect regardless of the settings in the boot block discussed in the previous section. You had better put the above line as the first line of /boot/loader.rc so as to see boot messages on the serial console as early as possible. Likewise, you can specify the internal console as: set console=vidconsole If you do not set the boot loader environment variable console, the boot loader, and subsequently the kernel, will use whichever console indicated by the option in the boot block. In versions 3.2 or later, you may specify the console in /boot/loader.conf.local or /boot/loader.conf, rather than in /boot/loader.rc. In this method your /boot/loader.rc should look like: include /boot/loader.4th start Then, create /boot/loader.conf.local and put the following line there. console=comconsole or console=vidconsole See &man.loader.conf.5; for more information. At the moment, the boot loader has no option equivalent to the option in the boot block, and there is no provision to automatically select the internal console and the serial console based on the presence of the keyboard. Using Serial Port Other than <devicename>sio0</devicename> for the Console You need to recompile the boot loader to use a serial port other than sio0 for the serial console. Follow the procedure described in . Caveats The idea here is to allow people to set up dedicated servers that require no graphics hardware or attached keyboards. Unfortunately, while most systems will let you boot without a keyboard, there are quite a few that will not let you boot without a graphics adapter. Machines with AMI BIOSes can be configured to boot with no graphics adapter installed simply by changing the `graphics adapter' setting in the CMOS configuration to `Not installed.' However, many machines do not support this option and will refuse to boot if you have no display hardware in the system. With these - machines, you'll have to leave some kind of graphics card plugged in, - (even if it's just a junky mono board) although you will not have to + machines, you will have to leave some kind of graphics card plugged in, + (even if it is just a junky mono board) although you will not have to attach a monitor into it. You might also try installing an AMI BIOS. diff --git a/en_US.ISO8859-1/books/handbook/sound/chapter.sgml b/en_US.ISO8859-1/books/handbook/sound/chapter.sgml index b2f186cfae..3b4f8a3e32 100644 --- a/en_US.ISO8859-1/books/handbook/sound/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/sound/chapter.sgml @@ -1,368 +1,368 @@ Moses Moore Contributed by Sound Synopsis FreeBSD supports a wide variety of sound cards, allowing you to enjoy high fidelity output from your computer. This includes the ability to record and playback audio in the MPEG Audio Layer 3 (MP3), WAV, and Ogg Vorbis formats as well as many other formats. The FreeBSD Ports Collection also contains applications allowing you to edit your recorded audio, add sound effects, and control attached MIDI devices. After reading this chapter you will know: How to locate your sound card. How to configure your system so that your sound card is recognized. Methods to test that your card is working using sample applications. How to troubleshoot your sound setup. Before reading this chapter you should: Know how to configure and install a new kernel () Locating the Correct Device PCI ISA sound cards Before you begin, you should know the model of the card you have, the chip it uses, and whether it is a PCI or ISA card. FreeBSD supports a wide variety of both PCI and ISA cards. If you do not see your card in the following list, check the &man.pcm.4; manual page. This is not a complete list; however, it does list some of the most common cards. Crystal 4237, 4236, 4232, 4231 Yamaha OPL-SAx OPTi931 Ensoniq AudioPCI 1370/1371 ESS Solo-1/1E NeoMagic 256AV/ZX Sound Blaster Pro, 16, 32, AWE64, AWE128, Live Creative ViBRA16 Advanced Asound 100, 110, and Logic ALS120 ES 1868, 1869, 1879, 1888 Gravis UltraSound Aureal Vortex 1 or 2 kernel configuration The driver you use in your kernel depends on the kind of card you have. The sections below provide more information and what you will need to add to your kernel configuration. Creative, Advance, and ESS Sound Cards If you have one of the above cards, you will need to add device pcm to your kernel. If you have a PnP ISA card, you will also need to add device sbc to your kernel. For a non-PnP ISA card, add device pcm and device sbc0 at isa? port0x220 irq 5 drq 1 flags 0x15 to your kernel. Those are the default settings. You may need to change the IRQ, etc. See the &man.sbc.4; manual page for more information. The Sound Blaster Live is not supported under FreeBSD 4.0 without a patch, which this document will not cover. It is recommended that you update to the latest -STABLE before trying to use this card. Gravis UltraSound Cards For a PnP ISA card, you will need to add device pcm and device gusc to your kernel. If you have a non-PnP ISA card, you will need to add device pcm and device gus0 at isa? port 0x220 irq 5 drq 1 flags 0x13 to your kernel. You may need to change the IRQ, etc. See the &man.gusc.4; manual page for more information. Crystal Sound Cards For Crystal cards, you will need both device pcm and device csa in your kernel. Generic Support For PnP ISA or PCI cards, you will need to add device pcm to your kernel configuration. If you have a non-PnP ISA sound card that does not have a bridge driver, you will need to add device pcm0 at isa? irq 10 drq 1 flags 0x0 to your kernel configuration. You may need to change the IRQ, etc., to match your hardware configuration. Recompiling the Kernel After adding the driver(s) you need to your kernel configuration, you will need to recompile your kernel. Please see of the handbook for more information. Creating and Testing the Device Nodes device nodes After you reboot, log in and run cat /dev/sndstat. You should see output similar to the following: FreeBSD Audio Driver (newpcm) Sep 21 2000 18:29:53 Installed devices: pcm0: <Aureal Vortex 8830> at memory 0xfeb40000 irq 5 (4p/1r +channels duplex) If you see an error message, something went wrong earlier. If that happens, go through your kernel configuration file again and make sure you chose the correct device. If it reported no errors and returned pcm0, su to root and do the following: &prompt.root; cd /dev &prompt.root; sh MAKEDEV snd0 If it reported no errors and returned pcm1, su to root and do the following: &prompt.root; cd /dev &prompt.root; sh MAKEDEV snd1 Please note that either of the above commands will not create a /dev/snd device! Instead it creates a group of device nodes including: Device Description /dev/audio SPARC-compatible audio device /dev/dsp Digitized voice device /dev/dspW Like /dev/dsp, but 16 bits per sample /dev/midi Raw midi access device /dev/mixer Control port mixer device /dev/music Level 2 sequencer interface /dev/sequencer Sequencer device /dev/pss Programmable device interface If all goes well, you should now have a functioning sound card. If you do not, see the next section. Common Problems device node I get an unsupported subdevice XX error! - One or more of the device nodes wasn't created + One or more of the device nodes was not created correctly. Repeat the steps above. I/O port I get a sb_dspwr(XX) timed out error! The I/O port is not set correctly. IRQ I get a bad irq XX error! The IRQ is set incorrectly. Make sure that the set IRQ and the sound IRQ are the same. I get a xxx: gus pcm not attached, out of memory error. What causes that? If this happens, it is because there is not enough available memory to use the device. diff --git a/en_US.ISO8859-1/books/handbook/users/chapter.sgml b/en_US.ISO8859-1/books/handbook/users/chapter.sgml index 021b692e28..0ccf88b880 100644 --- a/en_US.ISO8859-1/books/handbook/users/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/users/chapter.sgml @@ -1,1027 +1,1027 @@ Neil Blakey-Milner Contributed by Users and Basic Account Management Synopsis FreeBSD allows multiple users to use the computer at the same time. Obviously, only one of those users can be sat in front of the screen and keyboard at any one time, but any number of users can log in through the network to get their work done. To use the system every user must have an account. After reading this chapter you will know: The differences between the various user accounts on a FreeBSD system How to add user accounts How to remove user accounts How to change account details, such as the user's full name, or preferred shell How to set limits on a per-account basis, to control the resources such as memory and CPU time that accounts and groups of accounts are allowed to access How to use groups to make account management easier Before reading this chapter you should: Read Introduction All access to the system is achieved via accounts, and all processes are run by users, so user and account management are of integral importance on FreeBSD systems. Every account on a FreeBSD system has certain information associated with it to identify the account. User name The user name as it would be typed at the login: prompt. User names must be unique across the computer; you may not have two users with the same user name. There are a number of rules for creating valid user names, documented in &man.passwd.5;; you would typically use user names that consist of eight or fewer all lower case characters. Password Each account has a password associated with it. The password may be blank, in which case no password will be required to access the system. This is normally a very bad idea; every account should have a password. User ID (UID) The UID is a number from 0 to 65536 used to uniquely identify the user to the system. Internally FreeBSD uses the UID to identify users—any FreeBSD commands that allow you to specify a user name will convert it to the UID before working with it. This means that you can have several accounts with different user names but the same UID. As far as FreeBSD is concerned these accounts are one user. It is unlikely you will ever need to do this. Group ID (GID) The GID is a number from 0 to 65536 used to uniquely identify the primary group that the user belongs to. Groups are a mechanism for controlling access to resources based on a user's GID rather than their UID. This can significantly reduce the size of some configuration files. A user may also be in more than one group. Login class Login classes are an extension to the group mechanism that provide additional flexibility when tailoring the system to different users. Password change time By default FreeBSD does not force users to change their passwords periodically. You can enforce this on a per-user basis, forcing some or all of your users to change their passwords after a certain amount of time has elapsed. Account expiry time By default FreeBSD does not expire accounts. If you are creating accounts that you know have a limited lifespan, for example, in a school where you have accounts for the students, then you can specify when the account expires. After the expiry time has elapsed the account can not be used to log in to the system, although the account's directories and files will remain. User's full name The user name uniquely identifies the account to FreeBSD, but does not necessarily reflect the user's real name. This information can be associated with the account. Home directory The home directory is the full path to a directory on the system in which the user will start when logging on to the system. A common convention is to put all user home directories under /home/username. The user would store their personal files in their home directory, and any directories they may create in there. User shell The shell provides the default environment users use to interact with the system. There are many different kinds of shells, and experienced users will have their own preferences, which can be reflected in their account settings. There are three main types of accounts; the Superuser, system users, and user accounts. The Superuser account, usually called root, is used to manage the system with no limitations on privileges. System users run services. Finally, user accounts are used by real people, who log on, read mail, and so forth. The Superuser Account accounts superuser (root) The superuser account, usually called root, comes preconfigured to facilitate system administration, and should not be used for day-to-day tasks like sending and receiving mail, general exploration of the system, or programming. This is because the superuser, unlike normal user accounts, can operate without limits, and misuse of the superuser account may result in spectacular disasters. User accounts are unable to destroy the system by mistake, so it is generally best to use normal user accounts whenever possible, unless you especially need the extra privilege. You should always double and triple-check commands you issue as the superuser, since an extra space or missing character can mean irreparable data loss. So, the first thing you should do after reading this chapter, is to create an unprivileged user account for yourself - for general usage, if you haven't already. This applies equally - whether you're running a multi-user or single-user machine. + for general usage, if you have not already. This applies equally + whether you are running a multi-user or single-user machine. Later in this chapter, we discuss how to create additional accounts, and how to change between the normal user and superuser. System Accounts accounts system System users are those used to run services such as DNS, mail, web servers, and so forth. The reason for this is security; if all services ran as the superuser, they could act without restriction. accounts daemon accounts operator Examples of system users are daemon, operator, bind (for the Domain Name Service), and news. Often sysadmins create httpd to run web servers they install. accounts nobody nobody is the generic unprivileged - system user. However, it's important to keep in mind that the + system user. However, it is important to keep in mind that the more services that use nobody, the more files and processes that user will become associated with, and hence the more privileged that user becomes. User Accounts accounts user User accounts are the primary means of access for real people to the system, and these accounts insulate the user and the environment, preventing the users from damaging the system or other users, and allowing users to customize their environment without affecting others. Every person accessing your system should have a unique user account. This allows you to find out who is doing what, prevent people from clobbering each others' settings or reading each others' mail, and so forth. Each user can set up their own environment to accommodate their use of the system, by using alternate shells, editors, key bindings, and language. Modifying Accounts accounts modifying pw is a powerful and flexible tool to modify all aspects of user accounts. For most tasks however, adduser and rmuser are recommended to add and remove accounts respectively. chpass allows both the system administrator and normal users to adjust passwords, shells, and personal information. If you are only interested in changing a password then the passwd command is usually quicker. adduser accounts adding adduser /usr/share/skel skeleton directory adduser is a simple program for adding new users. It creates entries in the system passwd and group files. It will also create a home directory for the new user, copy in the default configuration files ("dotfiles") from /usr/share/skel, and can optionally mail the new user a welcome message. To create the initial configuration file, use adduser -s -config_create. The makes adduser default to quiet. We use later when we want to change defaults. Next, we configure adduser defaults, and create our first user account, since using root for normal usage is evil and nasty. Configuring adduser &prompt.root; adduser -v Use option ``-silent'' if you don't want to see all warnings and questions. Check /etc/shells Check /etc/master.passwd Check /etc/group Enter your default shell: csh date no sh tcsh zsh [sh]: zsh Your default shell is: zsh -> /usr/local/bin/zsh Enter your default HOME partition: [/home]: Copy dotfiles from: /usr/share/skel no [/usr/share/skel]: Send message from file: /etc/adduser.message no [/etc/adduser.message]: no Do not send message Use passwords (y/n) [y]: y Write your changes to /etc/adduser.conf? (y/n) [n]: y Ok, let's go. Don't worry about mistakes. I will give you the chance later to correct any input. Enter username [a-z0-9_-]: jru Enter full name []: J. Random User Enter shell csh date no sh tcsh zsh [zsh]: Enter home directory (full path) [/home/jru]: Uid [1001]: Enter login class: default []: Login group jru [jru]: Login group is ``jru''. Invite jru into other groups: guest no [no]: wheel Enter password []: Enter password again []: Name: jru Password: **** Fullname: J. Random User Uid: 1001 Gid: 1001 (jru) Class: Groups: jru wheel HOME: /home/jru Shell: /usr/local/bin/zsh OK? (y/n) [y]: y Added user ``jru'' Copy files from /usr/share/skel to /home/jru Add another user? (y/n) [y]: n Goodbye! &prompt.root; In summary, we changed the default shell to zsh (an additional shell found in packages), and turned off the sending of a welcome mail to added users. We then saved the configuration, and then created an account for jru, and we made sure jru is in wheel - group (which we'll see is important later). + group (which we will see is important later). - The password you type in isn't echoed, nor are asterisks - displayed. Make sure you don't mistype the password twice. + The password you type in is not echoed, nor are asterisks + displayed. Make sure you do not mistype the password twice. Just use adduser without arguments - from now on, and you won't have to go through changing the + from now on, and you will not have to go through changing the defaults. If the program asks you to change the defaults, exit the program, and try the option. <application>rmuser</application> rmuser accounts removing You can use rmuser to completely remove a user from the system. rmuser performs the following steps: Removes the user's &man.crontab.1; entry (if any). Removes any &man.at.1; jobs belonging to the user. Kills all processes owned by the user. Removes the user from the system's local password file. Removes the user's home directory (if it is owned by the user). Removes the incoming mail files belonging to the user from /var/mail. Removes all files owned by the user from temporary file storage areas such as /tmp. Finally, removes the username from all groups to which it belongs in /etc/group. If a group becomes empty and the group name is the same as the username, the group is removed; this complements the per-user unique groups created by &man.adduser.8;. - rmuser can't be used to remove + rmuser cannot be used to remove superuser accounts, since that is almost always an indication of massive destruction. By default, an interactive mode is used, which attempts to - make sure you know what you're doing. + make sure you know what you are doing. rmuser Interactive Account Removal &prompt.root; rmuser jru Matching password entry: jru:*:1001:1001::0:0:J. Random User:/home/jru:/usr/local/bin/tcsh Is this the entry you wish to remove? y Remove user's home directory (/home/jru)? y Updating password file, updating databases, done. Updating group file: trusted (removing group jru -- personal group is empty) done. Removing user's incoming mail file /var/mail/jru: done. Removing files belonging to jru from /tmp: done. Removing files belonging to jru from /var/tmp: done. Removing files belonging to jru from /var/tmp/vi.recover: done. &prompt.root; <application>pw</application> pw pw is a command line utility to create, remove, modify, and display users and groups, and functions as an editor of the system user and group files. This section describes its use for users. The Groups section below describes its use for groups. It is designed to be useful both as a directly executed command and for use from shell scripts. For detailed information, please see &man.pw.8;. <application>chpass</application> chpass chpass changes user database information such as passwords, shells, and personal information. Only system administrators, as the superuser, may change other users' information and passwords with chpass. When passed no options, aside from an optional username, chpass displays an editor containing user information. When the user exists from the editor, the user database is updated with the new information. Interactive chpass by Superuser #Changing user database information for jru. Login: jru Password: * Uid [#]: 1000 Gid [# or name]: 1000 Change [month day year]: Expire [month day year]: Class: Home directory: /home/jru Shell: /usr/local/bin/tcsh Full Name: J. Random User Office Location: Office Phone: Home Phone: Other information: The normal user can change only a small subsection of this information, and only for themselves. Interactive chpass by Normal User #Changing user database information for jru. Shell: /usr/local/bin/tcsh Full Name: J. Random User Office Location: Office Phone: Home Phone: Other information: chfn and chsh are just links to chpass, as are ypchpass, ypchfn, and ypchsh. NIS support is automatic, so specifying the yp before the command is not necessary. passwd passwd accounts changing password passwd is the usual way to change your own password as a user, or another user's password as the superuser. Users must type in their original password before changing their password, to prevent an unauthorized person from changing their password when the user is away from their console. Changing Your Password &prompt.user; passwd Changing local password for jru. Old password: New password: Retype new password: passwd: updating the database... passwd: done Changing Another User's Password as the Superuser &prompt.root; passwd jru Changing local password for jru. New password: Retype new password: passwd: updating the database... passwd: done yppasswd is just a link to passwd. NIS support is automatic, so specifying the yp before the command is not necessary. Limiting Users limiting users accounts limiting If you run a multi-user system, chances are that you do not trust all of your users not to damage your system. FreeBSD provides a number of ways a system administrator can limit the amount of system resources an individual user can use. These limits are generally divided into two sections: disk quotas, and other resource limits. quotas limiting users quotas disk quotas Disk quotas are a way for the system administrator to tell the filesystem the amount of disk space a user may use; moreover, they provide a way to quickly check on the disk usage of a user without having to calculate it every time. Quotas are discussed in . The other resource limits include ways to limit the amount of CPU, memory, and other resources a user may consume. These are defined using login classes and are discussed here. /etc/login.conf Login classes are defined in /etc/login.conf. The precise semantics are beyond the scope of this section, but are described in detail in the &man.login.conf.5; manual page. It is sufficient to say that each user is assigned to a login class (default by default), and that each login class has a set of login capabilities associated with it. A login capability is a name=value pair, where name is a well-known identifier and value is an arbitrary string processed accordingly depending on the name. Setting up login classes and capabilities is rather straight-forward, and is also described in &man.login.conf.5;. Resource limits are different from plain vanilla login capabilities in two ways. First, for every limit, there is a soft (current) and hard limit. A soft limit may be adjusted by the user or application, but may be no higher than the hard limit. The latter may be lowered by the user, but never raised. Second, most resource limits apply per process to a specific user, not the user as a whole. Note, however, that these differences are mandated by the specific handling of the limits, not by the implementation of the login capability framework (i.e., they are not really a special case of login capabilities). And so, without further ado, below are the most commonly used resource limits (the rest, along with all the other login capabilities, may be found in &man.login.conf.5;). coredumpsize coredumpsize limiting users coredumpsize The limit on the size of a core file generated by a program is, for obvious reasons, subordinate to other limits on disk usage (e.g., filesize, or disk quotas). Nevertheless, it is often used as a less-severe method of controlling disk space consumption: since users do not generate core files themselves, and often do not delete them, setting this may save them from running out of disk space should a large program (e.g., emacs) crash. cputime cputime limiting users cputime This is the maximum amount of CPU time a user's process may consume. Offending processes will be killed by the kernel. This is a limit on CPU time consumed, not percentage of the CPU as displayed in some fields by &man.top.1; and &man.ps.1;. A limit on the latter is, at the time of this writing, not possible, and would be rather useless: a compiler—probably a legitimate task—can easily use almost 100% of a CPU for some time. filesize filesize limiting users filesize This is the maximum size of a file the user may possess. Unlike disk quotas, this limit is enforced on individual files, not the set of all files a user owns. maxproc maxproc limiting users maxproc This is the maximum number of processes a user may be running. This includes foreground and background processes alike. For obvious reasons, this may not be larger than the system limit specified by the kern.maxproc sysctl. Also note that setting this too small may hinder a user's productivity: it is often useful to be logged in multiple times or execute pipelines. Some tasks, such as compiling a large program, also spawn multiple processes (e.g., &man.make.1;, &man.cc.1;, and other intermediate preprocessors). memorylocked memorylocked limiting users memorylocked This is the maximum amount a memory a process may have requested to be locked into main memory (e.g., see &man.mlock.2;). Some system-critical programs, such as &man.amd.8;, do this so that their getting swapped out does not contribute to a system's thrashing in time of trouble. memoryuse memoryuse limiting users memoryuse This is the maximum amount of memory a process may consume at any given time. It includes both core memory and swap usage. This is not a catch-all limit for restricting memory consumption, but it is a good start. openfiles openfiles limiting users openfiles This is the maximum amount of files a process may have open. In FreeBSD, files are also used to represent sockets and IPC channels; thus, be careful not to set this too low. The system-wide limit for this is defined by the kern.maxfiles sysctl. sbsize sbsize limiting users sbsize This is the limit on the amount of network memory, and thus mbufs, a user may consume. This originated as a response to an old DoS attack by creating a lot of sockets, but can be generally used to limit network communications. stacksize stacksize limiting users stacksize This is the maximum size a process' stack may grow to. This alone is not sufficient to limit the amount of memory a program may use; consequently, it should be used in conjunction with other limits. There are a few other things to remember when setting resource limits. Following are some general tips, suggestions, and miscellaneous comments. Processes started at system startup by /etc/rc are assigned to the daemon login class. Although the /etc/login.conf that comes with the system is a good source of reasonable values for most limits, only you, the administrator, can know what is appropriate for your system. Setting a limit too high may open your system up to abuse, while setting it too low may put a strain on productivity. Users of the X Window System (X11) should probably be granted more resources than other users. X11 by itself takes a lot of resources, but it also encourages users to run more programs simultaneously. Remember that many limits apply to individual processes, not the user as a whole. For example, setting openfiles to 50 means that each process the user runs may open up to 50 files. Thus, the gross amount of files a user may open is the value of openfiles multiplied by the value of maxproc. This also applies to memory consumption. For further information on resource limits and login classes and capabilities in general, please consult the relevant manual pages: &man.cap.mkdb.1;, &man.getrlimit.2;, &man.login.conf.5;. Personalizing Users Localization is an environment set up by the system administrator or user to accommodate different languages, character sets, date and time standards, and so on. This is discussed in the localization chapter. Groups groups /etc/groups accounts groups A group is simply a list of users. Groups are identified by their group name and gid (group ID). In FreeBSD (and most other Unix systems), the two factors the kernel uses to decide whether a process is allowed to do something is its user ID and list of groups it belongs to. Unlike a user ID, a process has a list of groups associated with it. You may hear some things refer to the "group ID" of a user or process; most of the time, this just means the first group in the list. The group name to group ID map is in /etc/group. This is a plain text file with four colon-delimited fields. The first field is the group name, the second is the encrypted password, the third the group ID, and the fourth the comma-delimited list of members. It can safely be edited - by hand (assuming, of course, that you don't make any syntax + by hand (assuming, of course, that you do not make any syntax errors!). For a more complete description of the syntax, see the &man.group.5; manual page. - If you don't want to edit /etc/group + If you do not want to edit /etc/group manually, you can use the &man.pw.8; command to add and edit groups. For example, to add a group called teamtwo and then confirm that it exists you can use: Adding a Group Using &man.pw.8; &prompt.root; pw groupadd teamtwo &prompt.root; pw groupshow teamtwo teamtwo:*:1100: The number 1100 above is the group ID of the group teamtwo. Right now, teamtwo has no members, and is thus rather useless. Let's change that by inviting jru to the teamtwo group. Adding Somebody to a Group Using &man.pw.8; &prompt.root; pw groupmod teamtwo jru &prompt.root; pw groupshow teamtwo teamtwo:*:1100:jru The argument to the option is a comma-delimited list of users who are members of the group. From the preceding sections, we know that the password file also contains a group for each user. The latter (the user) is automatically added to the group list by the system; the user will not show up as a member when using the groupshow command to &man.pw.8;, but will show up when the information is queried via &man.id.1; or similar tool. In other words, &man.pw.8; only manipulates the /etc/group file; it will never attempt to read additionally data from /etc/passwd. Using &man.id.1; to Determine Group Membership &prompt.user; id jru uid=1001(jru) gid=1001(jru) groups=1001(jru), 1100(teamtwo) As you can see, jru is a member of the groups jru and teamtwo. For more information about &man.pw.8;, see its manual page, and for more information on the format of /etc/group, consult the &man.group.5; manual page. diff --git a/en_US.ISO8859-1/books/handbook/x11/chapter.sgml b/en_US.ISO8859-1/books/handbook/x11/chapter.sgml index 8428cd7b6a..92c1390fcd 100644 --- a/en_US.ISO8859-1/books/handbook/x11/chapter.sgml +++ b/en_US.ISO8859-1/books/handbook/x11/chapter.sgml @@ -1,1394 +1,1394 @@ The X Window System Synopsis FreeBSD uses XFree86 to provide users with a powerful graphical user interface. XFree86 is a open-source implementation of the X Window System. The following chapter will cover installation and configuration of XFree86 on your FreeBSD system. For more information on X11 and to see whether your video card is supported, check the XFree86 web site. After reading this chapter you will know: How to install and configure XFree86. The various components of the X window system, and how they interoperate How to install and use different window managers How to use TrueType fonts in XFree86 How to setup your system for graphical logins (XDM). Before reading this chapter you should: Know how to install additional third-party software () Installing XFree86 XFree86 is available as a port and as a package, making it easy to install. You can also download the binaries directly from the XFree86 organization and install them by hand, following the instructions provided by the XFree86 group. Your only decision is which version of XFree86 to run. XFree86 3.X is the maintenance branch of XFree86 development. - It's very stable, and it supports a huge number of graphics + It is very stable, and it supports a huge number of graphics cards. However, no new development is happening there. XFree86 4.X is a redesign of XFree86. As well as introducing many new features (including much better support for fonts and anti-aliasing), XFree86 4.X supports slightly fewer graphics cards. If your card is supported we recommend you run 4.X. If it is not then run 3.X. The rest of this chapter will explain how to configure XFree86, and suggest various programs for X that you might want to try. Christopher Shumway Contributed by XFree86 Configuration Introduction This chapter will introduce the steps necessary to install and configure the XFree86 X Windows System under FreeBSD. Once the server is installed and configured properly. The user can read to setup their desktop environment. XFree86 4.X XFree86 Before You Start Before the user is to start configuration of XFree86-4, the the following information will need to be known about the target system: Monitor specifications Video Adapter chipset Video Adapter memory horizontal scan rate vertical scan rate The specifications for the target system's monitor are used by XFree86 to determine the resolution and refresh rate to run at. These specifications can usually be obtained from the documentation that came with the target system's monitor or from the manufacturer's website. There are two ranges of numbers that are needed, the horizontal scan rate and the vertical synchronization rate. The video adapter's chipset defines what driver module XFree86 uses to talk to the graphics hardware. With most chipsets, this can be automatically determined, but it is still useful to know in case the automatic - detection doesn't work correctly. + detection does not work correctly. Video memory on the graphic adapter determines the resolution and color depth the target system can run at. This is important to know so the user knows the limitations of the target system. Installing XFree86 4.X Software XFree86 4 can be installed using the FreeBSD ports system or using &man.pkg.add.1;. If the user is building XFree86-4 from source and has USA_RESIDENT set in /etc/make.conf, the user may first have to fetch Wraphelp.c if XDM-AUTHORIZATION-1 support is desired. This file is to be placed in the port's files/ sub-directory before the port is built. Configuring XFree86 4.X Configuration of XFree86 4.X is a several step process. The first step is to build an initial configuration file with the configure option to XFree86. As the super user, simply run: &prompt.root; XFree86 -configure This will generate a skeleton XFree86 configuration file in the current working directory called XF86Config.new. The XFree86 program will attempt to probe the graphics hardware on the system and will write a configuration file to load the proper drivers for the detected hardware on the target system. The next step is to test the currently existing configuration to verify that XFree86 can work with the graphics hardware on the target system. To preform this task, the user needs to run: &prompt.root; XFree86 -xf86config XF86Config.new If the user is presented with a black and grey grid and an X mouse cursor, then the configuration was successful. To exit the test, just press ctrl, alt and backspace simultaneously. XFree86 4 Tuning Next, the user needs to tune the XF86Config.new configuration file to their personal taste. Open up the file in a text editor such as &man.emacs.1; or &man.ee.1;. The first thing the user will want to do is add the frequencies for the target system's monitor. These are usually expressed as a horizontal and vertical synchronization rate. These values are added to the XF86Config.new file under the "Monitor" section as such: Section "Monitor" Identifier "Monitor0" VendorName "Monitor Vendor" ModelName "Monitor Model" Horizsync 30-107 VertRefresh 48-120 EndSection The Horizsync and VertRefresh keywords may not exist in the user's configuration file. If they do not, they need to be added, with the correct horizontal synchronization rate placed after the Horizsync keyword and the vertical synchronization rate after the VertRefresh keyword. In the example above the target monitor's rates where entered. XF86Config While the XF86Config.new configuration file is still open in an editor, next the user needs to select what the default resolution and color depth is desired. This is defined in the Screen section. Section "Screen" Identifier "Screen0" Device "Card0" Monitor "Monitor0" DefaultColorDepth 24 SubSection "Display" Depth 24 Modes "1024x768" EndSubSection EndSection The DefaultColorDepth keyword describes the color depth the user wishes to run at by default. This can be overridden with the -bpp command line switch to XFree86 1. The Modes keyword describes the resolution the user wishes to run at for the given color depth. In the example above, the default color depth is twenty four bits per pixel. At this color depth, the accepted resolution is one thousand twenty four pixels by seven hundred and sixty eight pixels. If a user wants to run at a resolution of one thousand twenty four pixels by seven hundred sixty eight pixels at twenty four bits per pixel, then the user needs to add the DefaultColorDepth keyword with the value of twenty four, and add to the "Display" subsection with the desired Depth the Modes keyword with the resolution the user wishes to run at. Note that only VESA standard modes are supported as defined by the target system's graphics hardware. Finally, the user can write out the configuration file and test it using the test mode given above. If all is well, then the configuration file needs to be installed in a common location where XFree86 1 can source it in the future. This is typically /etc/X11/XF86Config or /usr/X11R6/etc/X11/XF86Config. &prompt.root; cp XF86Config.new /etc/X11/XF86Config Once the configuration file has been placed in a common location, XFree86 can then be used through &man.xdm.1;. In order to use startx 1 the user will have to install the X11/wrapper port. Advanced Configuration Topics Configuration with Intel i810 Graphics Chipsets Intel i810 graphic chipset Configuration with Intel i810 integrated chipsets requires the agpgart AGP programming interface for XFree86 to be able to drive the card. To enable the agpgart programming interface, the agp.ko kernel loadable module needs to be loaded into the kernel with &man.kldload.8;. This can be done automatically with the &man.loader.8;. Simply add this line to /boot/loader.conf to have the loader load agp.ko at boot time: agp_load="YES" Next, a device node needs to be created for the programming interface. To create the AGP device node, run &man.MAKEDEV.8; in the /dev directory as such: &prompt.root; cd /dev &prompt.root; sh MAKEDEV agpgart This will allow the user to configure the graphics hardware as any other graphics board. Understanding X If you are familiar with using windowing systems that ship with other operating systems, such as Microsoft Windows, or MacOS, then you may find your first introduction to X to be something of a culture shock. Today, as Unix desktop environments such as KDE and GNOME become more prevalent it is less necessary to understand all the behind-the-scenes interaction between the various X components, or what those components actually are. However, one of X's strengths is its underlying design, which lends a great deal of flexibility, and makes it possible to do things with X that are impossible with other, more rigid, systems. Why X? X is not the first window system written for Unix, but it is the most popular. X's original development team had worked on another window system before writing X. That system's name was W (for Window, obviously). X is just the next letter in the Roman alphabet. X can be referred to variously as X, X Window System, X11, and other terms. X Windows is to be avoided wherever possible; see &man.X.1; for more information. The X Client/Server Model X was designed from the beginning to be network-centric, and adopts a client-server model. In the X model, the X server runs on the computer that has the keyboard, monitor, and mouse attached. The server is responsible for managing the display, handling input from the keyboard and mouse, and so on. Each X application (such as XTerm, or Netscape) is a client. A client sends messages to the server such as Please draw a window at these coordinates, and the server sends back messages such as The user just clicked on your OK button. If you are using FreeBSD in a home or small office environment where you only have one computer then you will be running the X server and the X clients on the same computer. However, if you have many machines running FreeBSD it is perfectly possible to run the X server on the computer by your desk (which might be quite a low specification machine) and run your X applications (the clients) on the powerful expensive server that serves your office. In this scenario the communication between the X client and server takes place over the network. This confuses a lot of people, because the X terminology is exactly backward to what they expect. They expect the X server to be the big powerful machine down the hall, and the X client to be the machine on their desk. As long as you remember that the X server is the machine with the monitor and keyboard, and the X clients are the programs that display the windows you will not get confused. There is an interesting side-effect to this design. There is nothing in the forces the client and server machines to be running the same operating system, or even to be running on the same type of computer. It is perfectly feasible to run an X server on Microsoft Windows or Apple's MacOS, and there are various free and commercial applications available that do exactly that. The X server that ships with FreeBSD is called XFree86, and is available for free, under a license very similar to the FreeBSD license. Commercial X servers for FreeBSD are also available, should you want one. The Window Manager The X design philosophy is much like the Unix design philosophy, tools, not policy. By this we mean that X (and Unix) does not try to dictate to the end user how they should accomplish whatever task they are trying to solve. Instead, they aim to provide the user tools to do the job, and it is the user's responsibility to decide how to use those tools. This philosophy extends to X not dictating what windows should look like on screen, how you move them around with your mouse, what keystrokes you should use to move between windows (i.e., Alt Tab , if you are familiar with Windows), what the title bars on each window should look like, whether or not they have close buttons on them, and so on. Instead, X delegates this responsibility to an application called the Window Manager. There are dozens of window managers available for X; AfterStep, Enlightenment, ctwm, ftwm, sawfish, twm, WindowMaker and more. Each of these window managers provides a different look and feel; some of them support virtual desktops some of them allow you to completely customize the keystrokes you can use to manage your desktop; some have a Start button, or similar device; some are themeable, allowing you to completely change the look-and-feel of your desktop by applying a new theme. These window managers, and many more, are available in the x11-wm category of the Ports Collection. In addition, the KDE and GNOME desktop environments both have their own window managers which integrate tightly with the desktop, although both of them allow you to replace the default window manager with your own choice. Each window manager also has a different configuration mechanism; some expect you to write a configuration file by hand; others feature GUI tools for carrying most of the configuration tasks; at least one (sawfish) has a configuration file written in a dialect of the Lisp language, which is very powerful (if you are in to that sort of thing). As you can imagine, this flexibility comes with a price. It can be very difficult for documents such as this one to guide you through choosing and configuring a window manager because the available choice is so wide. Focus Policy Another feature the window manager is responsible for is the mouse focus policy. Each windowing system, be it X, Microsoft Windows, or some other has an abstraction called the focus, and at any one time only one window can have the focus. The window that has the focus is the window that will receive all your keypresses and mouse clicks. You are probably familiar with a focus policy commonly called click-to-focus. This means that you must click on the window you want to have the focus. The window may then come to the top of the stack, and all your keypresses will now be directed to this window, even if you move the mouse outside the window. To give the focus to another window you must first click in it. X does not support any particular focus policy. Instead, the window manager controls which window has the focus at any one time. Different window managers will support different focus methods. All of them support click to focus, and the majority of them support several others. The two other most popular focus policies are: focus-follows-mouse With this policy, the window that is under the mouse pointer is the window that has the focus. This may not necessarily be the window that is on top of all the other windows. You can change the focus by pointing at another window, there is no need to click in it as well. After getting used to this policy it can be very disorientating going back to another system that uses click-to-focus. sloppy-focus This policy is a small extension to focus-follows-mouse. With focus-follows-mouse, if you move the mouse over the background (or desktop, also called the root window) then no window has the focus, and your keypresses go nowhere. If you use sloppy-focus and move the mouse pointer on the root window then the last window that had the focus will keep it. Your window manager will almost certainly support other policies, and variations on these two, so make sure you read the documentation it is supplied with. Widgets The X approach of providing tools and not policy extends to the widgets that you see on screen in each application. Widget is a GUI term for all the items in the user interface that you can click on and manipulate in some way; buttons, checkboxes, radio buttons, icons, lists, and so on. Microsoft Windows Developer documentation calls these things controls. Microsoft Windows and Apple's MacOS both have a very rigid widget policy. Application developers are supposed to ensure that their applications share a common look and feel. X was designed long before either of these windowing systems, when research into GUI systems was in its infancy, and it was felt that it would not be sensible to mandate a particular graphical style, or set of widgets that have to be adhered to. If you examine the evolution of the Windows or MacOS GUI over the past ten years you will see many examples of how the interfaces have been altered over time to reflect new thinking in the art of Human/Computer Interaction. The upshot of this is that you can not expect X applications to have a common look and feel. There are several popular widget sets (and variations), including the original Athena widget set (developed at MIT), Motif (on which the widget set in Microsoft Windows was modeled, all bevelled edges and three shades of grey), OpenLook, and others. Most newer X applications today will use a modern-looking widget set, probably either Qt, used by KDE, or GTK, used by the GNOME project. In this respect we are beginning to see a convergence in look-and-feel on the Unix desktop, which certainly makes things easier for the novice user. However, the sudden rise in popularity of theming, where window managers make it possible to dramatically personally your desktop and alter the look and feel of the widgets risks confusing the issue once more. Murray Stokely Contributed by Using Fonts in XFree86 Type1 Fonts The default fonts that ship with XFree86 are less than ideal for typical desktop publishing applications. Large presentation fonts show up jagged and unprofessional looking and small fonts in Netscape are almost completely unintelligible. However, there are several free, high quality Type1 (PostScript) fonts available which can be readily used with XFree86, either version 3.X or version 4.X. For instance, the URW font collection (x11-fonts/urwfonts) includes high quality versions of standard type1 fonts (Times Roman, Helvetica, Palatino and others). The Freefont collection (x11-fonts/freefont) includes many more fonts, but most of them are intended for use in graphics software such as the Gimp, and are not complete enough to serve as screen fonts. In addition, XFree86 can be configured to use TrueType fonts with a minimum of effort: see the section on TrueType fonts later. To install the above Type1 font collections from the ports collection you can run the following commands. &prompt.root; cd /usr/ports/x11-fonts/urwfonts &prompt.root; make install clean And likewise with the freefont or other collections. To tell the X server that these fonts exist, you can add an appropriate line to your XF86Config file (in /etc/ for XFree86 version 3, or in /etc/X11/ for version 4), which reads: FontPath "/usr/X11R6/lib/X11/fonts/URW/" Alternatively, at the command line in your X session you can write: &prompt.user; xset fp+ /usr/X11R6/lib/X11/fonts/URW &prompt.user; xset fp rehash This will work but will be lost when you log out from this session, unless you add it to your startup file (~/.xinitrc for a normal startx session, or ~/.xsession when logging in through a graphical login manager like XDM). A third way is to use the new XftConfig file: see the section on anti-aliasing, later. TrueType Fonts XFree86 4.0 has built in support for rendering TrueType fonts. There are two different modules that can enable this functionality. The "freetype" module is used in this example because it is more consistent with the other font rendering back-ends. To enable the freetype module just add the following line to the module section of your /etc/X11/XF86Config file. Load "freetype" For XFree86 3.3.X you will need to run a separate TrueType font server. Xfstt is commonly used for this purpose. To install x11-servers/Xfstt on your FreeBSD system simply install the port from /usr/ports/x11-servers/Xfstt You should now make a directory for your TrueType fonts (e.g. /usr/X11R6/lib/X11/fonts/TrueType) and copy all of your TrueType fonts into this directory. Keep in mind that you cannot take TrueType fonts directly from a Macintosh; they must be in Unix/DOS/Windows format for use by XFree86. Once you have copied the files into this directory you need to use ttmkfdir to create a fonts.dir file so that the X font renderer - knows that you've installed these new files. There is a FreeBSD + knows that you have installed these new files. There is a FreeBSD port for x11-fonts/ttmkfdir in /usr/ports/x11-fonts/ttmkfdir. &prompt.root; cd /usr/X11R6/lib/X11/fonts/TrueType &prompt.root; ttmkfdir > fonts.dir Now you need to add your TrueType directory to your fonts path. This is just the same as described above for Type1 fonts, that is, use &prompt.user; xset fp+ /usr/X11R6/lib/X11/fonts/TrueType &prompt.user; xset fp rehash or add a line to the XF86Config file. That's it. Now Netscape, Gimp, StarOffice, and all of your other X applications should now recognize your installed TrueType fonts. Extremely small fonts (as with text in a high resolution display on a web page) and extremely large fonts (within StarOffice) will look much better now. Anti-Aliasing Your Fonts Starting with version 4.0.2, XFree86 supports anti-aliased fonts. Currently, most software has not been updated to take advantage of this new functionality. However, Qt (the toolkit for the KDE desktop) does; so if you are running XFree86 4.0.2 (or higher), Qt 2.3 (or higher) and KDE, all your KDE/Qt applications can be made to use anti-aliased fonts. To configure anti-aliasing, you need to create (or edit, if it already exists) the file /usr/X11R6/lib/X11/XftConfig. Several advanced things can be done with this file; this section describes only the simplest possibilities. First, you need to tell the X server about the fonts which you want anti-aliased. To do that, for each font directory you have a line, which looks like this: dir "/usr/X11R6/lib/X11/Type1" And likewise for the other font directories (URW, truetype, etc) - containing fonts you'd like anti-aliased. Anti-aliasing makes + containing fonts you would like anti-aliased. Anti-aliasing makes sense only for scalable fonts (basically, Type1 and TrueType) so - don't include bitmap font directories here. The + do not include bitmap font directories here. The directories which you included here can now be commented out of your XF86Config file. Next, you may not want to anti-alias normal-sized text. (Antialiasing makes borders slightly fuzzy, which makes very small text more readable and removes "staircases" from large text, but can cause eyestrain if applied to normal text.) To exclude point sizes between 9 and 13 from anti-aliasing, include these lines: match any size > 8 any size < 14 edit antialias = false; You may also find that the spacing for some monospaced fonts gets messed up when you turn on anti-aliasing. This seems to be an issue with KDE, in particular. One possible fix for this is to force the spacing for such fonts to be 100: add the following lines: match any family == "fixed" edit family =+ "mono"; match any family == "console" edit family =+ "mono"; (this aliases the other common names for fixed fonts as "mono"), and then add: match any family == "mono" edit spacing = 100; Supposing you want to use the Lucidux fonts whenever - monospaced fonts are required (these look nice, and don't seem + monospaced fonts are required (these look nice, and do not seem to suffer from the spacing problem), you could replace that last line with these: match any family == "mono" edit family += "LuciduxMono"; match any family == "Lucidux Mono" edit family += "LuciduxMono"; match any family == "LuciduxMono" edit family =+ "Lucidux Mono"; (the last lines alias different equivalent family names). Finally, you want to allow users to add commands to this file, via their personal .xftconfig files. To do this, add a last line: includeif "~/.xftconfig" That's all; anti-aliasing should be enabled the next time you start the X server. However, note that your programs must know how to take advantage of it. At the present time, the toolkit Qt does, so the entire KDE environment can use anti-aliased fonts (see on KDE for details); there are patches for gtk+ to do the same, so if compiled against such a patched gtk+, the GNOME environment and Mozilla can also use anti-aliased fonts. Anti-aliasing is still new to FreeBSD and XFree86; configuring it should get easier with time, and it will soon be supported by many more applications. Seth Kingsley Contributed by The X Display Manager Overview The X Display Manager (XDM) is an optional part of the X Window System that is used for login session management. This is useful for several types of situations, including minimal X Terminals (see ), desktops, and large network display servers. Since the X Window System is network and protocol independent, there are a wide variety of possible configurations for running X clients and servers on different machines connected by a network. XDM provides a graphical interface for choosing which display server to connect to, and entering authorization information such as a login and password combination. You may think of XDM as providing the same functionality to the user as the &man.getty.8; utility (see for details). That is, it performs system logins to the display being connected to and then runs a session manager on behalf of the user (usually an X window manager). XDM then waits for this program to exit, signaling that the user is done and should be logged out of the display. At this point, XDM can display the login and display chooser screens for the next user to login. Using XDM The XDM daemon program is located in /usr/X11R6/bin/xdm. You can run this program at any time as root and it will start managing the X display on the local machine. If you want XDM to run in the background every time the machine boots up, a convenient way to do this is by adding an entry to /etc/ttys. For more information about the format and usage of this file, see . There is a line in the default /etc/ttys file for running the XDM daemon on a virtual terminal: ttyv8 "/usr/X11R6/bin/xdm -nodaemon" xterm off secure By default this entry is disabled, and in order to enable it you will need to change field 5 from off to on and then restart &man.init.8; using the directions in . The first field, the name of the terminal this program will manage, is ttyv8. This means that XDM will start running on the 9th virtual terminal. Configuring XDM The XDM configuration directory is located in /usr/X11R6/lib/X11/xdm. In this directory you will see several files used to change the behavior and appearance of XDM. Typically you will find these files: File Description Xaccess Client authorization ruleset. Xresources Default X resource values. Xservers List of remote and local displays to manage. Xsession Default session script for logins. Xsetup_* xdm-config Global configuration for all displays running on this machine. xdm-errors Errors generated by the server program. xdm-pid The process ID of the currently running XDM. Also in this directory are a few scripts and programs used to setup the desktop when XDM is running. In the next few sections I will briefly describe the purpose of each of these files. The exact syntax and usage of all of these files is described in &man.xdm.1; The default configuration is a simple rectangular login window with the hostname of the machine displayed at the top in a large font and Login: and Password: prompts below. This is a good starting point if you are planning to design your own look and feel for the XDM screens. Xaccess The protocol for connecting to XDM controlled displays is called the X Display Manager Connection Protocol (XDMCP). This file is basically just a ruleset for controlling XDMCP connections from remote machines. By default, it allows any client to connect, but you will see this will not matter because the default xdm-config file does not listen for remote connections. Xresources This is an application-defaults file for the display chooser and the login screens. This is where you can customize the appearance of the login program. The format is identical to the app-defaults file described in the XFree86 documentation. Xservers This is a list of the remote displays the chooser should provide as choices. Xsession This is the default session script for XDM to run after a user has logged in. Normally each user will have a customized session script in ~/.xsessionrc that overrides this script. Xsetup_* These files contain scripts that will be run automatically before displaying the chooser or login interfaces. There is a script for each display being used, named Xsetup_followed by the local display number (for instance Xsetup_0). Typically these scripts will run one or two programs in the background such as xconsole. xdm-config This file contains settings in the form of app-defaults that are applicable to every display that this installation manages. xdm-errors This file contains the output of the X servers that XDM is trying to run. If a display that XDM is trying to start hangs for some reason, this is a good place to look for error messages. These messages are also written to the user's ~/.xsession-errors file on a per-session basis Running a Network Display Server In order for other clients to connect to your display server, you will need to edit the access control rules, and enable the connection listener. By default these are set to conservative values, which is a good decision security-wise. To get XDM to listen for connections first comment out a line in the xdm-config file: ! SECURITY: do not listen for XDMCP or Chooser requests ! Comment out this line if you want to manage X terminals with xdm DisplayManager.requestPort: 0 and then restart XDM. Remember that comments in app-defaults files begin with a ! character, not a #. After this, you may need to put more strict access controls in place. Look at the example entries in Xaccess file, and refer to the &man.xdm.1; manual page. Replacements for XDM Several replacements for the default XDM program exist. One of them, KDM (bundled with KDE) is described in a later section. Apart from various visual improvements and cosmetic frills, it can be easily configured to let users choose their window manager of choice at the time they log in. Valentino Vaschetto Contributed by Desktop Environments This section describes the different desktop environments available for X-Windows on FreeBSD. For our purposes a "desktop environment" will mean anything ranging from a simple window manager, to a complete suite of desktop applications such as KDE or GNOME. GNOME About GNOME GNOME is a user-friendly desktop environment that enables users to easily use and configure their computers. GNOME includes a panel (for starting applications and displaying status), a desktop (where data and applications can be placed), a set of standard desktop tools and applications, and a set of conventions that make it easy for applications to cooperate and be consistent with each other. Users of other operating systems or environments should feel right at home using the powerful graphics-driven environment that GNOME provides. Installing GNOME To install GNOME from the network, simply type: &prompt.root; pkg_add -r gnome If you would rather build GNOME from source, then use the ports tree: &prompt.root; cd /usr/ports/x11/gnome &prompt.root; make install clean Once GNOME is installed, we must have the X server start GNOME instead of a default window manager. If you have already customized your .xinitrc file then you should simply replace the line that starts your current window manager with one that starts /usr/X11R6/bin/gnome-session instead. If you - haven't added anything special to your configuration file, + have not added anything special to your configuration file, then it is enough to simply type: &prompt.root; echo "/usr/X11R6/bin/gnome-session" > ~/.xinitrc That's it. Type startx and you will be in the GNOME desktop environment. - If you're running a display manager like + If you are running a display manager like XDM, this will not work. Instead, you should create an executable .xsession file with the same command in it. To do this, edit your file (if you already have one) and replace the existing window manager command with /usr/X11R6/bin/gnome-session; or else, &prompt.root; echo "#!/bin/sh" > ~/.xsession &prompt.root; echo "/usr/X11R6/bin/gnome-session" >> ~/.xsession &prompt.root; chmod +x ~/.xsession Another option is to configure your display manager to allow choosing the window manager at login time; the section on KDE2 details explains how to do this for kdm, the display manager of KDE. KDE2 About KDE2 KDE is an easy to use contemporary desktop environment. Some of the things that KDE brings to the user are: A beautiful contemporary desktop A desktop exhibiting complete network transparency An integrated help system allowing for convenient, consistent access to help on the use of the KDE desktop and its applications Consistent look and feel of all KDE applications Standardized menu and toolbars, keybindings, color-schemes, etc. Internationalization: KDE is available in more than 40 languages Centralized consisted dialog driven desktop configuration A great number of useful KDE applications KDE has an office application suite based on KDE's KParts technology consisting of a spread-sheet, a presentation application, an organizer, a news client and more. KDE is also comes with a web browser called Konqeuror, which represents already a solid competitor to other existing web browsers on Unix systems. More information on KDE can be found on the KDE website Installing KDE2 - At the time of writing, a package for kde2 doesn't + At the time of writing, a package for kde2 does not exist yet. No problem! The ports tree hides all the complexity of building a package from source. To install KDE2, do this : &prompt.root; cd /usr/ports/x11/kde2 &prompt.root; make install clean This command will fetch all the necessary files from the Internet, configure and compile KDE2, install the applications, and then clean up after itself. - Now you're going to have to tell the X server to launch + Now you are going to have to tell the X server to launch KDE2 instead of a default window manager. Do this by typing this: &prompt.root; echo "/usr/X11R6/bin/startkde" > ~/.xinitrc Now, whenever you go into X-Windows, KDE2 will be your - desktop. (Note: this will not work if you're logging in via + desktop. (Note: this will not work if you are logging in via a display manager like xdm. In that case you have two options: create an .xsession file as described in the section on GNOME, but with the /usr/X11R6/bin/startkde command instead of the gnome-session command; or, configure your display manager to allow choosing a desktop at login time. Below it is explained how to do this for kdm, KDE's display manager.) More Details on KDE2 Now that KDE2 is installed on - your system, you'll find that you can learn a lot from its + your system, you will find that you can learn a lot from its help pages, or just by pointing and clicking at various menus. Windows or Mac users will feel quite at home. The best reference for KDE is the on-line documentation. KDE comes with its own web browser, Konqueror, dozens of useful applications, and extensive documentation. This section only discusses somewhat technical things which are difficult to learn just by random exploration. The KDE display manager - If you're an administrator on a multi-user system, you + If you are an administrator on a multi-user system, you may like to have a graphical login screen to welcome users. You can use xdm, as described earlier. However, KDE includes an alternative, KDM, which is designed to look more attractive and include more login-time options. In particular, users can easily choose (via a menu) which desktop environment (KDE2, GNOME, or something else) to run - after logging on. If you're slightly adventurous and you want + after logging on. If you are slightly adventurous and you want this added flexibility and visual appeal, read on. To begin with, run the KDE2 control panel, kcontrol, as root. Note: it is generally considered unsafe to run your entire X environment as root. Instead, run your window manager as a normal user, open a terminal window (such as xterm or KDE's konsole, become root with su (you need to be in the wheel group in /etc/group for this), and then type kcontrol. Click on the icon on the left marked "System", then on - "Login manager". On the right you'll see various configurable + "Login manager". On the right you will see various configurable options, which the KDE manual will explain in greater detail. Click on "sessions" on the right. Depending on what window managers or desktop environments you have currently installed, you can type their names in "New type" and add them. (These are just labels so far, not commands, so you can write KDE and GNOME rather than startkde or gnome-session.) Include a label failsafe. Play with the other menus as you like (those are mainly - cosmetic and self-explanatory). When you're done, click on + cosmetic and self-explanatory). When you are done, click on "Apply" at the bottom, and quit the control center. To make sure kdm understands what your above labels (KDE, GNOME etc) mean, you need to edit some more files: the same ones used by xdm. In your terminal window, as root, edit the file /usr/X11R6/lib/X11/xdm/Xsession. You will come across a section in the middle looking like this (by default): case $# in 1) case $1 in failsafe) exec xterm -geometry 80x24-0-0 ;; esac esac You will need to add a few lines to this section. Assuming the labels you gave earlier were KDE2 and GNOME, the following will do: case $# in 1) case $1 in KDE2) exec /usr/X11R6/bin/startkde ;; GNOME) exec /usr/X11R6/bin/gnome-session ;; failsafe) exec xterm -geometry 80x24-0-0 ;; esac esac To make sure your KDE choice of a login-time desktop background is also honored, you will need to add the following line to /usr/X11R6/lib/X11/xdm/Xsetup_0: /usr/X11R6/bin/kdmdesktop Now, you need only to make sure kdm is started at the next bootup. To learn how to do this, read the section on xdm, and do the same thing replacing references to the xdm program by kdm. That's it. Your next login screen should have a pretty face and lots of menus. Anti-aliased Fonts Tired of blocky staircase edges to your fonts under X11? Tired of unreadable text in web browsers? Well, no more. Starting with version 4.0.2, XFree86 supports anti-aliasing via its "RENDER" extension, and starting with version 2.3, Qt (the toolkit used by KDE) supports this extension. Configuring this is described in on antialiasing X11 fonts. So if you're + linkend="antialias"> on antialiasing X11 fonts. So if you are running up-to-date software, anti-aliasing is possible on your KDE2 desktop. Just go to your KDE2 menu, go to Preferences -> Look and Feel -> Style, and click on the checkbox "Use Anti-Aliasing for Fonts and Icons". - That's all. If you're running a Qt application which is not + That's all. If you are running a Qt application which is not part of KDE, you may need to set the environment variable QT_XFT to true before starting your program. XFCE About XFCE XFCE is based on the gtk+ toolkit used by GNOME, but is much more lightweight and meant for those who want a simple, efficient desktop which is nevertheless easy to use and configure. Visually, it looks very much like CDE, found on commercial Unix systems. Some of XFCE's features are: A simple, easy-to-handle desktop Fully configurable via mouse, with drag and drop, etc Main panel similar to CDE, with menus, applets and app launchers Integrated window manager, file manager, sound manager, GNOME compliance module, and other things Themeable (since it uses gtk+) Fast, light and efficient: ideal for older/slower machines or machines with memory limitations More information on XFCE can be found on the XFCE website. Installing XFCE A binary package for xfce exists (at the time of writing). To install, simply do this: &prompt.root; pkg_add -r xfce Alternatively, you may prefer to build from source. The ports tree comes to the rescue again: &prompt.root; cd /usr/ports/x11-wm/xfce &prompt.root; make install clean All necessary source packages (including dependencies) will be automagically fetched, built and installed, and the build areas cleaned up afterwards. Now you want to tell the X server to launch XFCE the next time you start X. Simply type this: &prompt.root; echo "/usr/X11R6/bin/startxfce" > ~/.xinitrc The next time you start X, XFCE will be your desktop. (Note, as before: - if you're logging in via a display manager like + if you are logging in via a display manager like xdm, you should either create an .xsession, as described in the section on GNOME, but with the /usr/X11R6/bin/startxfce command; or, configure your display manager to allow choosing a desktop at login time, as explained in the section on kdm.)