Index: head/sys/boot/efi/loader/main.c =================================================================== --- head/sys/boot/efi/loader/main.c (revision 307325) +++ head/sys/boot/efi/loader/main.c (revision 307326) @@ -1,1070 +1,1075 @@ /*- * Copyright (c) 2008-2010 Rui Paulo * Copyright (c) 2006 Marcel Moolenaar * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #ifdef EFI_ZFS_BOOT #include #endif #include "loader_efi.h" extern char bootprog_name[]; extern char bootprog_rev[]; extern char bootprog_date[]; extern char bootprog_maker[]; struct arch_switch archsw; /* MI/MD interface boundary */ EFI_GUID acpi = ACPI_TABLE_GUID; EFI_GUID acpi20 = ACPI_20_TABLE_GUID; EFI_GUID devid = DEVICE_PATH_PROTOCOL; EFI_GUID imgid = LOADED_IMAGE_PROTOCOL; EFI_GUID mps = MPS_TABLE_GUID; EFI_GUID netid = EFI_SIMPLE_NETWORK_PROTOCOL; EFI_GUID smbios = SMBIOS_TABLE_GUID; EFI_GUID dxe = DXE_SERVICES_TABLE_GUID; EFI_GUID hoblist = HOB_LIST_TABLE_GUID; EFI_GUID memtype = MEMORY_TYPE_INFORMATION_TABLE_GUID; EFI_GUID debugimg = DEBUG_IMAGE_INFO_TABLE_GUID; EFI_GUID fdtdtb = FDT_TABLE_GUID; EFI_GUID inputid = SIMPLE_TEXT_INPUT_PROTOCOL; #ifdef EFI_ZFS_BOOT static void efi_zfs_probe(void); #endif /* * cpy8to16 copies a traditional C string into a CHAR16 string and * 0 terminates it. len is the size of *dst in bytes. */ static void cpy8to16(const char *src, CHAR16 *dst, size_t len) { len <<= 1; /* Assume CHAR16 is 2 bytes */ while (len > 0 && *src) { *dst++ = *src++; len--; } *dst++ = (CHAR16)0; } static void cpy16to8(const CHAR16 *src, char *dst, size_t len) { size_t i; for (i = 0; i < len && src[i]; i++) dst[i] = (char)src[i]; if (i < len) dst[i] = '\0'; } static int has_keyboard(void) { EFI_STATUS status; EFI_DEVICE_PATH *path; EFI_HANDLE *hin, *hin_end, *walker; UINTN sz; int retval = 0; /* * Find all the handles that support the SIMPLE_TEXT_INPUT_PROTOCOL and * do the typical dance to get the right sized buffer. */ sz = 0; hin = NULL; status = BS->LocateHandle(ByProtocol, &inputid, 0, &sz, 0); if (status == EFI_BUFFER_TOO_SMALL) { hin = (EFI_HANDLE *)malloc(sz); status = BS->LocateHandle(ByProtocol, &inputid, 0, &sz, hin); if (EFI_ERROR(status)) free(hin); } if (EFI_ERROR(status)) return retval; /* * Look at each of the handles. If it supports the device path protocol, * use it to get the device path for this handle. Then see if that * device path matches either the USB device path for keyboards or the * legacy device path for keyboards. */ hin_end = &hin[sz / sizeof(*hin)]; for (walker = hin; walker < hin_end; walker++) { status = BS->HandleProtocol(*walker, &devid, (VOID **)&path); if (EFI_ERROR(status)) continue; while (!IsDevicePathEnd(path)) { /* * Check for the ACPI keyboard node. All PNP3xx nodes * are keyboards of different flavors. Note: It is * unclear of there's always a keyboard node when * there's a keyboard controller, or if there's only one * when a keyboard is detected at boot. */ if (DevicePathType(path) == ACPI_DEVICE_PATH && (DevicePathSubType(path) == ACPI_DP || DevicePathSubType(path) == ACPI_EXTENDED_DP)) { ACPI_HID_DEVICE_PATH *acpi; acpi = (ACPI_HID_DEVICE_PATH *)(void *)path; if ((EISA_ID_TO_NUM(acpi->HID) & 0xff00) == 0x300 && (acpi->HID & 0xffff) == PNP_EISA_ID_CONST) { retval = 1; goto out; } /* * Check for USB keyboard node, if present. Unlike a * PS/2 keyboard, these definitely only appear when * connected to the system. */ } else if (DevicePathType(path) == MESSAGING_DEVICE_PATH && DevicePathSubType(path) == MSG_USB_CLASS_DP) { USB_CLASS_DEVICE_PATH *usb; usb = (USB_CLASS_DEVICE_PATH *)(void *)path; if (usb->DeviceClass == 3 && /* HID */ usb->DeviceSubClass == 1 && /* Boot devices */ usb->DeviceProtocol == 1) { /* Boot keyboards */ retval = 1; goto out; } } path = NextDevicePathNode(path); } } out: free(hin); return retval; } static int find_currdev(EFI_LOADED_IMAGE *img, struct devsw **dev, int *unit, uint64_t *extra) { EFI_DEVICE_PATH *devpath, *copy; EFI_HANDLE h; /* * Try the device handle from our loaded image first. If that * fails, use the device path from the loaded image and see if * any of the nodes in that path match one of the enumerated * handles. */ if (efi_handle_lookup(img->DeviceHandle, dev, unit, extra) == 0) return (0); copy = NULL; devpath = efi_lookup_image_devpath(IH); while (devpath != NULL) { h = efi_devpath_handle(devpath); if (h == NULL) break; if (efi_handle_lookup(h, dev, unit, extra) == 0) { if (copy != NULL) free(copy); return (0); } if (copy != NULL) free(copy); devpath = efi_lookup_devpath(h); if (devpath != NULL) { copy = efi_devpath_trim(devpath); devpath = copy; } } return (ENOENT); } EFI_STATUS main(int argc, CHAR16 *argv[]) { char var[128]; EFI_LOADED_IMAGE *img; EFI_GUID *guid; int i, j, vargood, unit, howto; struct devsw *dev; uint64_t pool_guid; UINTN k; int has_kbd; + char buf[40]; archsw.arch_autoload = efi_autoload; archsw.arch_getdev = efi_getdev; archsw.arch_copyin = efi_copyin; archsw.arch_copyout = efi_copyout; archsw.arch_readin = efi_readin; #ifdef EFI_ZFS_BOOT /* Note this needs to be set before ZFS init. */ archsw.arch_zfs_probe = efi_zfs_probe; #endif /* Init the time source */ efi_time_init(); has_kbd = has_keyboard(); /* * XXX Chicken-and-egg problem; we want to have console output * early, but some console attributes may depend on reading from * eg. the boot device, which we can't do yet. We can use * printf() etc. once this is done. */ cons_probe(); /* * Initialise the block cache. Set the upper limit. */ bcache_init(32768, 512); /* * Parse the args to set the console settings, etc * boot1.efi passes these in, if it can read /boot.config or /boot/config * or iPXE may be setup to pass these in. * * Loop through the args, and for each one that contains an '=' that is * not the first character, add it to the environment. This allows * loader and kernel env vars to be passed on the command line. Convert * args from UCS-2 to ASCII (16 to 8 bit) as they are copied. */ howto = 0; for (i = 1; i < argc; i++) { if (argv[i][0] == '-') { for (j = 1; argv[i][j] != 0; j++) { int ch; ch = argv[i][j]; switch (ch) { case 'a': howto |= RB_ASKNAME; break; case 'd': howto |= RB_KDB; break; case 'D': howto |= RB_MULTIPLE; break; case 'h': howto |= RB_SERIAL; break; case 'm': howto |= RB_MUTE; break; case 'p': howto |= RB_PAUSE; break; case 'P': if (!has_kbd) howto |= RB_SERIAL | RB_MULTIPLE; break; case 'r': howto |= RB_DFLTROOT; break; case 's': howto |= RB_SINGLE; break; case 'S': if (argv[i][j + 1] == 0) { if (i + 1 == argc) { setenv("comconsole_speed", "115200", 1); } else { cpy16to8(&argv[i + 1][0], var, sizeof(var)); setenv("comconsole_speedspeed", var, 1); } i++; break; } else { cpy16to8(&argv[i][j + 1], var, sizeof(var)); setenv("comconsole_speed", var, 1); break; } case 'v': howto |= RB_VERBOSE; break; } } } else { vargood = 0; for (j = 0; argv[i][j] != 0; j++) { if (j == sizeof(var)) { vargood = 0; break; } if (j > 0 && argv[i][j] == '=') vargood = 1; var[j] = (char)argv[i][j]; } if (vargood) { var[j] = 0; putenv(var); } } } for (i = 0; howto_names[i].ev != NULL; i++) if (howto & howto_names[i].mask) setenv(howto_names[i].ev, "YES", 1); if (howto & RB_MULTIPLE) { if (howto & RB_SERIAL) setenv("console", "comconsole efi" , 1); else setenv("console", "efi comconsole" , 1); } else if (howto & RB_SERIAL) { setenv("console", "comconsole" , 1); } if (efi_copy_init()) { printf("failed to allocate staging area\n"); return (EFI_BUFFER_TOO_SMALL); } /* * March through the device switch probing for things. */ for (i = 0; devsw[i] != NULL; i++) if (devsw[i]->dv_init != NULL) (devsw[i]->dv_init)(); /* Get our loaded image protocol interface structure. */ BS->HandleProtocol(IH, &imgid, (VOID**)&img); printf("Command line arguments:"); for (i = 0; i < argc; i++) printf(" %S", argv[i]); printf("\n"); printf("Image base: 0x%lx\n", (u_long)img->ImageBase); printf("EFI version: %d.%02d\n", ST->Hdr.Revision >> 16, ST->Hdr.Revision & 0xffff); printf("EFI Firmware: %S (rev %d.%02d)\n", ST->FirmwareVendor, ST->FirmwareRevision >> 16, ST->FirmwareRevision & 0xffff); printf("\n"); printf("%s, Revision %s\n", bootprog_name, bootprog_rev); printf("(%s, %s)\n", bootprog_maker, bootprog_date); /* * Disable the watchdog timer. By default the boot manager sets * the timer to 5 minutes before invoking a boot option. If we * want to return to the boot manager, we have to disable the * watchdog timer and since we're an interactive program, we don't * want to wait until the user types "quit". The timer may have * fired by then. We don't care if this fails. It does not prevent * normal functioning in any way... */ BS->SetWatchdogTimer(0, 0, 0, NULL); if (find_currdev(img, &dev, &unit, &pool_guid) != 0) return (EFI_NOT_FOUND); switch (dev->dv_type) { #ifdef EFI_ZFS_BOOT case DEVT_ZFS: { struct zfs_devdesc currdev; currdev.d_dev = dev; currdev.d_unit = unit; currdev.d_type = currdev.d_dev->dv_type; currdev.d_opendata = NULL; currdev.pool_guid = pool_guid; currdev.root_guid = 0; env_setenv("currdev", EV_VOLATILE, efi_fmtdev(&currdev), efi_setcurrdev, env_nounset); env_setenv("loaddev", EV_VOLATILE, efi_fmtdev(&currdev), env_noset, env_nounset); init_zfs_bootenv(zfs_fmtdev(&currdev)); break; } #endif default: { struct devdesc currdev; currdev.d_dev = dev; currdev.d_unit = unit; currdev.d_opendata = NULL; currdev.d_type = currdev.d_dev->dv_type; env_setenv("currdev", EV_VOLATILE, efi_fmtdev(&currdev), efi_setcurrdev, env_nounset); env_setenv("loaddev", EV_VOLATILE, efi_fmtdev(&currdev), env_noset, env_nounset); break; } } snprintf(var, sizeof(var), "%d.%02d", ST->Hdr.Revision >> 16, ST->Hdr.Revision & 0xffff); env_setenv("efi-version", EV_VOLATILE, var, env_noset, env_nounset); setenv("LINES", "24", 1); /* optional */ for (k = 0; k < ST->NumberOfTableEntries; k++) { guid = &ST->ConfigurationTable[k].VendorGuid; if (!memcmp(guid, &smbios, sizeof(EFI_GUID))) { + snprintf(buf, sizeof(buf), "%p", + ST->ConfigurationTable[k].VendorTable); + setenv("hint.smbios.0.mem", buf, 1); smbios_detect(ST->ConfigurationTable[k].VendorTable); break; } } interact(NULL); /* doesn't return */ return (EFI_SUCCESS); /* keep compiler happy */ } /* XXX move to lib stand ? */ static int wcscmp(CHAR16 *a, CHAR16 *b) { while (*a && *b && *a == *b) { a++; b++; } return *a - *b; } COMMAND_SET(reboot, "reboot", "reboot the system", command_reboot); static int command_reboot(int argc, char *argv[]) { int i; for (i = 0; devsw[i] != NULL; ++i) if (devsw[i]->dv_cleanup != NULL) (devsw[i]->dv_cleanup)(); RS->ResetSystem(EfiResetCold, EFI_SUCCESS, 23, (CHAR16 *)"Reboot from the loader"); /* NOTREACHED */ return (CMD_ERROR); } COMMAND_SET(quit, "quit", "exit the loader", command_quit); static int command_quit(int argc, char *argv[]) { exit(0); return (CMD_OK); } COMMAND_SET(memmap, "memmap", "print memory map", command_memmap); static int command_memmap(int argc, char *argv[]) { UINTN sz; EFI_MEMORY_DESCRIPTOR *map, *p; UINTN key, dsz; UINT32 dver; EFI_STATUS status; int i, ndesc; static char *types[] = { "Reserved", "LoaderCode", "LoaderData", "BootServicesCode", "BootServicesData", "RuntimeServicesCode", "RuntimeServicesData", "ConventionalMemory", "UnusableMemory", "ACPIReclaimMemory", "ACPIMemoryNVS", "MemoryMappedIO", "MemoryMappedIOPortSpace", "PalCode" }; sz = 0; status = BS->GetMemoryMap(&sz, 0, &key, &dsz, &dver); if (status != EFI_BUFFER_TOO_SMALL) { printf("Can't determine memory map size\n"); return (CMD_ERROR); } map = malloc(sz); status = BS->GetMemoryMap(&sz, map, &key, &dsz, &dver); if (EFI_ERROR(status)) { printf("Can't read memory map\n"); return (CMD_ERROR); } ndesc = sz / dsz; printf("%23s %12s %12s %8s %4s\n", "Type", "Physical", "Virtual", "#Pages", "Attr"); for (i = 0, p = map; i < ndesc; i++, p = NextMemoryDescriptor(p, dsz)) { printf("%23s %012jx %012jx %08jx ", types[p->Type], (uintmax_t)p->PhysicalStart, (uintmax_t)p->VirtualStart, (uintmax_t)p->NumberOfPages); if (p->Attribute & EFI_MEMORY_UC) printf("UC "); if (p->Attribute & EFI_MEMORY_WC) printf("WC "); if (p->Attribute & EFI_MEMORY_WT) printf("WT "); if (p->Attribute & EFI_MEMORY_WB) printf("WB "); if (p->Attribute & EFI_MEMORY_UCE) printf("UCE "); if (p->Attribute & EFI_MEMORY_WP) printf("WP "); if (p->Attribute & EFI_MEMORY_RP) printf("RP "); if (p->Attribute & EFI_MEMORY_XP) printf("XP "); printf("\n"); } return (CMD_OK); } COMMAND_SET(configuration, "configuration", "print configuration tables", command_configuration); static const char * guid_to_string(EFI_GUID *guid) { static char buf[40]; sprintf(buf, "%08x-%04x-%04x-%02x%02x-%02x%02x%02x%02x%02x%02x", guid->Data1, guid->Data2, guid->Data3, guid->Data4[0], guid->Data4[1], guid->Data4[2], guid->Data4[3], guid->Data4[4], guid->Data4[5], guid->Data4[6], guid->Data4[7]); return (buf); } static int command_configuration(int argc, char *argv[]) { UINTN i; printf("NumberOfTableEntries=%lu\n", (unsigned long)ST->NumberOfTableEntries); for (i = 0; i < ST->NumberOfTableEntries; i++) { EFI_GUID *guid; printf(" "); guid = &ST->ConfigurationTable[i].VendorGuid; if (!memcmp(guid, &mps, sizeof(EFI_GUID))) printf("MPS Table"); else if (!memcmp(guid, &acpi, sizeof(EFI_GUID))) printf("ACPI Table"); else if (!memcmp(guid, &acpi20, sizeof(EFI_GUID))) printf("ACPI 2.0 Table"); else if (!memcmp(guid, &smbios, sizeof(EFI_GUID))) - printf("SMBIOS Table"); + printf("SMBIOS Table %p", + ST->ConfigurationTable[i].VendorTable); else if (!memcmp(guid, &dxe, sizeof(EFI_GUID))) printf("DXE Table"); else if (!memcmp(guid, &hoblist, sizeof(EFI_GUID))) printf("HOB List Table"); else if (!memcmp(guid, &memtype, sizeof(EFI_GUID))) printf("Memory Type Information Table"); else if (!memcmp(guid, &debugimg, sizeof(EFI_GUID))) printf("Debug Image Info Table"); else if (!memcmp(guid, &fdtdtb, sizeof(EFI_GUID))) printf("FDT Table"); else printf("Unknown Table (%s)", guid_to_string(guid)); printf(" at %p\n", ST->ConfigurationTable[i].VendorTable); } return (CMD_OK); } COMMAND_SET(mode, "mode", "change or display EFI text modes", command_mode); static int command_mode(int argc, char *argv[]) { UINTN cols, rows; unsigned int mode; int i; char *cp; char rowenv[8]; EFI_STATUS status; SIMPLE_TEXT_OUTPUT_INTERFACE *conout; extern void HO(void); conout = ST->ConOut; if (argc > 1) { mode = strtol(argv[1], &cp, 0); if (cp[0] != '\0') { printf("Invalid mode\n"); return (CMD_ERROR); } status = conout->QueryMode(conout, mode, &cols, &rows); if (EFI_ERROR(status)) { printf("invalid mode %d\n", mode); return (CMD_ERROR); } status = conout->SetMode(conout, mode); if (EFI_ERROR(status)) { printf("couldn't set mode %d\n", mode); return (CMD_ERROR); } sprintf(rowenv, "%u", (unsigned)rows); setenv("LINES", rowenv, 1); HO(); /* set cursor */ return (CMD_OK); } printf("Current mode: %d\n", conout->Mode->Mode); for (i = 0; i <= conout->Mode->MaxMode; i++) { status = conout->QueryMode(conout, i, &cols, &rows); if (EFI_ERROR(status)) continue; printf("Mode %d: %u columns, %u rows\n", i, (unsigned)cols, (unsigned)rows); } if (i != 0) printf("Select a mode with the command \"mode \"\n"); return (CMD_OK); } #ifdef EFI_ZFS_BOOT COMMAND_SET(lszfs, "lszfs", "list child datasets of a zfs dataset", command_lszfs); static int command_lszfs(int argc, char *argv[]) { int err; if (argc != 2) { command_errmsg = "wrong number of arguments"; return (CMD_ERROR); } err = zfs_list(argv[1]); if (err != 0) { command_errmsg = strerror(err); return (CMD_ERROR); } return (CMD_OK); } COMMAND_SET(reloadbe, "reloadbe", "refresh the list of ZFS Boot Environments", command_reloadbe); static int command_reloadbe(int argc, char *argv[]) { int err; char *root; if (argc > 2) { command_errmsg = "wrong number of arguments"; return (CMD_ERROR); } if (argc == 2) { err = zfs_bootenv(argv[1]); } else { root = getenv("zfs_be_root"); if (root == NULL) { return (CMD_OK); } err = zfs_bootenv(root); } if (err != 0) { command_errmsg = strerror(err); return (CMD_ERROR); } return (CMD_OK); } #endif COMMAND_SET(efishow, "efi-show", "print some or all EFI variables", command_efi_show); static int efi_print_var(CHAR16 *varnamearg, EFI_GUID *matchguid, int lflag) { UINTN datasz, i; EFI_STATUS status; UINT32 attr; CHAR16 *data; char *str; uint32_t uuid_status; int is_ascii; datasz = 0; status = RS->GetVariable(varnamearg, matchguid, &attr, &datasz, NULL); if (status != EFI_BUFFER_TOO_SMALL) { printf("Can't get the variable: error %#lx\n", status); return (CMD_ERROR); } data = malloc(datasz); status = RS->GetVariable(varnamearg, matchguid, &attr, &datasz, data); if (status != EFI_SUCCESS) { printf("Can't get the variable: error %#lx\n", status); return (CMD_ERROR); } uuid_to_string((uuid_t *)matchguid, &str, &uuid_status); if (lflag) { printf("%s 0x%x %S", str, attr, varnamearg); } else { printf("%s 0x%x %S=", str, attr, varnamearg); is_ascii = 1; free(str); str = (char *)data; for (i = 0; i < datasz - 1; i++) { /* Quick hack to see if this ascii-ish string printable range plus tab, cr and lf */ if ((str[i] < 32 || str[i] > 126) && str[i] != 9 && str[i] != 10 && str[i] != 13) { is_ascii = 0; break; } } if (str[datasz - 1] != '\0') is_ascii = 0; if (is_ascii) printf("%s", str); else { for (i = 0; i < datasz / 2; i++) { if (isalnum(data[i]) || isspace(data[i])) printf("%c", data[i]); else printf("\\x%02x", data[i]); } } } free(data); if (pager_output("\n")) return (CMD_WARN); return (CMD_OK); } static int command_efi_show(int argc, char *argv[]) { /* * efi-show [-a] * print all the env * efi-show -u UUID * print all the env vars tagged with UUID * efi-show -v var * search all the env vars and print the ones matching var * eif-show -u UUID -v var * eif-show UUID var * print all the env vars that match UUID and var */ /* NB: We assume EFI_GUID is the same as uuid_t */ int aflag = 0, gflag = 0, lflag = 0, vflag = 0; int ch, rv; unsigned i; EFI_STATUS status; EFI_GUID varguid = { 0,0,0,{0,0,0,0,0,0,0,0} }; EFI_GUID matchguid = { 0,0,0,{0,0,0,0,0,0,0,0} }; uint32_t uuid_status; CHAR16 *varname; CHAR16 *newnm; CHAR16 varnamearg[128]; UINTN varalloc; UINTN varsz; while ((ch = getopt(argc, argv, "ag:lv:")) != -1) { switch (ch) { case 'a': aflag = 1; break; case 'g': gflag = 1; uuid_from_string(optarg, (uuid_t *)&matchguid, &uuid_status); if (uuid_status != uuid_s_ok) { printf("uid %s could not be parsed\n", optarg); return (CMD_ERROR); } break; case 'l': lflag = 1; break; case 'v': vflag = 1; if (strlen(optarg) >= nitems(varnamearg)) { printf("Variable %s is longer than %zd characters\n", optarg, nitems(varnamearg)); return (CMD_ERROR); } for (i = 0; i < strlen(optarg); i++) varnamearg[i] = optarg[i]; varnamearg[i] = 0; break; default: printf("Invalid argument %c\n", ch); return (CMD_ERROR); } } if (aflag && (gflag || vflag)) { printf("-a isn't compatible with -v or -u\n"); return (CMD_ERROR); } if (aflag && optind < argc) { printf("-a doesn't take any args"); return (CMD_ERROR); } if (optind == argc) aflag = 1; argc -= optind; argv += optind; pager_open(); if (vflag && gflag) { rv = efi_print_var(varnamearg, &matchguid, lflag); pager_close(); return (rv); } if (argc == 2) { optarg = argv[0]; if (strlen(optarg) >= nitems(varnamearg)) { printf("Variable %s is longer than %zd characters\n", optarg, nitems(varnamearg)); pager_close(); return (CMD_ERROR); } for (i = 0; i < strlen(optarg); i++) varnamearg[i] = optarg[i]; varnamearg[i] = 0; optarg = argv[1]; uuid_from_string(optarg, (uuid_t *)&matchguid, &uuid_status); if (uuid_status != uuid_s_ok) { printf("uid %s could not be parsed\n", optarg); pager_close(); return (CMD_ERROR); } rv = efi_print_var(varnamearg, &matchguid, lflag); pager_close(); return (rv); } if (argc != 0) { printf("Too many args\n"); pager_close(); return (CMD_ERROR); } /* * Initiate the search -- note the standard takes pain * to specify the initial call must be a poiner to a NULL * character. */ varalloc = 1024; varname = malloc(varalloc); if (varname == NULL) { printf("Can't allocate memory to get variables\n"); pager_close(); return (CMD_ERROR); } varname[0] = 0; while (1) { varsz = varalloc; status = RS->GetNextVariableName(&varsz, varname, &varguid); if (status == EFI_BUFFER_TOO_SMALL) { varalloc = varsz; newnm = malloc(varalloc); if (newnm == NULL) { printf("Can't allocate memory to get variables\n"); free(varname); pager_close(); return (CMD_ERROR); } memcpy(newnm, varname, varsz); free(varname); varname = newnm; continue; /* Try again with bigger buffer */ } if (status != EFI_SUCCESS) break; if (aflag) { if (efi_print_var(varname, &varguid, lflag) != CMD_OK) break; continue; } if (vflag) { if (wcscmp(varnamearg, varname) == 0) { if (efi_print_var(varname, &varguid, lflag) != CMD_OK) break; continue; } } if (gflag) { if (memcmp(&varguid, &matchguid, sizeof(varguid)) == 0) { if (efi_print_var(varname, &varguid, lflag) != CMD_OK) break; continue; } } } free(varname); pager_close(); return (CMD_OK); } COMMAND_SET(efiset, "efi-set", "set EFI variables", command_efi_set); static int command_efi_set(int argc, char *argv[]) { char *uuid, *var, *val; CHAR16 wvar[128]; EFI_GUID guid; uint32_t status; EFI_STATUS err; if (argc != 4) { printf("efi-set uuid var new-value\n"); return (CMD_ERROR); } uuid = argv[1]; var = argv[2]; val = argv[3]; uuid_from_string(uuid, (uuid_t *)&guid, &status); if (status != uuid_s_ok) { printf("Invalid uuid %s %d\n", uuid, status); return (CMD_ERROR); } cpy8to16(var, wvar, sizeof(wvar)); err = RS->SetVariable(wvar, &guid, EFI_VARIABLE_NON_VOLATILE | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_BOOTSERVICE_ACCESS, strlen(val) + 1, val); if (EFI_ERROR(err)) { printf("Failed to set variable: error %lu\n", EFI_ERROR_CODE(err)); return (CMD_ERROR); } return (CMD_OK); } COMMAND_SET(efiunset, "efi-unset", "delete / unset EFI variables", command_efi_unset); static int command_efi_unset(int argc, char *argv[]) { char *uuid, *var; CHAR16 wvar[128]; EFI_GUID guid; uint32_t status; EFI_STATUS err; if (argc != 3) { printf("efi-unset uuid var\n"); return (CMD_ERROR); } uuid = argv[1]; var = argv[2]; uuid_from_string(uuid, (uuid_t *)&guid, &status); if (status != uuid_s_ok) { printf("Invalid uuid %s\n", uuid); return (CMD_ERROR); } cpy8to16(var, wvar, sizeof(wvar)); err = RS->SetVariable(wvar, &guid, 0, 0, NULL); if (EFI_ERROR(err)) { printf("Failed to unset variable: error %lu\n", EFI_ERROR_CODE(err)); return (CMD_ERROR); } return (CMD_OK); } #ifdef LOADER_FDT_SUPPORT extern int command_fdt_internal(int argc, char *argv[]); /* * Since proper fdt command handling function is defined in fdt_loader_cmd.c, * and declaring it as extern is in contradiction with COMMAND_SET() macro * (which uses static pointer), we're defining wrapper function, which * calls the proper fdt handling routine. */ static int command_fdt(int argc, char *argv[]) { return (command_fdt_internal(argc, argv)); } COMMAND_SET(fdt, "fdt", "flattened device tree handling", command_fdt); #endif #ifdef EFI_ZFS_BOOT static void efi_zfs_probe(void) { EFI_HANDLE h; u_int unit; int i; char dname[SPECNAMELEN + 1]; uint64_t guid; unit = 0; h = efi_find_handle(&efipart_dev, 0); for (i = 0; h != NULL; h = efi_find_handle(&efipart_dev, ++i)) { snprintf(dname, sizeof(dname), "%s%d:", efipart_dev.dv_name, i); if (zfs_probe_dev(dname, &guid) == 0) (void)efi_handle_update_dev(h, &zfs_dev, unit++, guid); } } #endif