/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * bootadm(1M) is a new utility for managing bootability of * Solaris *Newboot* environments. It has two primary tasks: * - Allow end users to manage bootability of Newboot Solaris instances * - Provide services to other subsystems in Solaris (primarily Install) */ /* Headers */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "message.h" #include "bootadm.h" #ifndef TEXT_DOMAIN #define TEXT_DOMAIN "SUNW_OST_OSCMD" #endif /* TEXT_DOMAIN */ /* Type definitions */ /* Primary subcmds */ typedef enum { BAM_MENU = 3, BAM_ARCHIVE } subcmd_t; typedef enum { OPT_ABSENT = 0, /* No option */ OPT_REQ, /* option required */ OPT_OPTIONAL /* option may or may not be present */ } option_t; typedef struct { char *subcmd; option_t option; error_t (*handler)(); int unpriv; /* is this an unprivileged command */ } subcmd_defn_t; #define LINE_INIT 0 /* lineNum initial value */ #define ENTRY_INIT -1 /* entryNum initial value */ #define ALL_ENTRIES -2 /* selects all boot entries */ #define GRUB_DIR "/boot/grub" #define GRUB_MENU "/boot/grub/menu.lst" #define MENU_TMP "/boot/grub/menu.lst.tmp" #define RAMDISK_SPECIAL "/ramdisk" #define STUBBOOT "/stubboot" /* lock related */ #define BAM_LOCK_FILE "/var/run/bootadm.lock" #define LOCK_FILE_PERMS (S_IRUSR|S_IWUSR|S_IRGRP|S_IROTH) #define CREATE_RAMDISK "/boot/solaris/bin/create_ramdisk" #define CREATE_DISKMAP "/boot/solaris/bin/create_diskmap" #define GRUBDISK_MAP "/var/run/solaris_grubdisk.map" #define GRUB_slice "/etc/lu/GRUB_slice" #define GRUB_root "/etc/lu/GRUB_root" #define GRUB_backup_menu "/etc/lu/GRUB_backup_menu" #define GRUB_slice_mntpt "/tmp/GRUB_slice_mntpt" #define LU_ACTIVATE_FILE "/etc/lu/DelayUpdate/activate.sh" #define GRUB_fdisk "/etc/lu/GRUB_fdisk" #define GRUB_fdisk_target "/etc/lu/GRUB_fdisk_target" #define INSTALLGRUB "/sbin/installgrub" #define STAGE1 "/boot/grub/stage1" #define STAGE2 "/boot/grub/stage2" /* * The following two defines are used to detect and create the correct * boot archive when safemode patching is underway. LOFS_PATCH_FILE is a * contracted private interface between bootadm and the install * consolidation. It is set by pdo.c when a patch with SUNW_PATCH_SAFEMODE * is applied. */ #define LOFS_PATCH_FILE "/var/run/.patch_loopback_mode" #define LOFS_PATCH_MNT "/var/run/.patch_root_loopbackmnt" /* * Default file attributes */ #define DEFAULT_DEV_MODE 0644 /* default permissions */ #define DEFAULT_DEV_UID 0 /* user root */ #define DEFAULT_DEV_GID 3 /* group sys */ /* * Menu related * menu_cmd_t and menu_cmds must be kept in sync */ char *menu_cmds[] = { "default", /* DEFAULT_CMD */ "timeout", /* TIMEOUT_CMD */ "title", /* TITLE_CMD */ "root", /* ROOT_CMD */ "kernel", /* KERNEL_CMD */ "kernel$", /* KERNEL_DOLLAR_CMD */ "module", /* MODULE_CMD */ "module$", /* MODULE_DOLLAR_CMD */ " ", /* SEP_CMD */ "#", /* COMMENT_CMD */ "chainloader", /* CHAINLOADER_CMD */ "args", /* ARGS_CMD */ NULL }; #define OPT_ENTRY_NUM "entry" /* * archive related */ typedef struct { line_t *head; line_t *tail; } filelist_t; #define BOOT_FILE_LIST "boot/solaris/filelist.ramdisk" #define ETC_FILE_LIST "etc/boot/solaris/filelist.ramdisk" #define FILE_STAT "boot/solaris/filestat.ramdisk" #define FILE_STAT_TMP "boot/solaris/filestat.ramdisk.tmp" #define DIR_PERMS (S_IRWXU|S_IRGRP|S_IXGRP|S_IROTH|S_IXOTH) #define FILE_STAT_MODE (S_IRUSR|S_IWUSR|S_IRGRP|S_IROTH) /* Globals */ int bam_verbose; int bam_force; static char *prog; static subcmd_t bam_cmd; static char *bam_root; static int bam_rootlen; static int bam_root_readonly; static int bam_alt_root; static char *bam_subcmd; static char *bam_opt; static int bam_debug; static char **bam_argv; static int bam_argc; static int bam_check; static int bam_smf_check; static int bam_lock_fd = -1; static char rootbuf[PATH_MAX] = "/"; static int bam_update_all; /* function prototypes */ static void parse_args_internal(int argc, char *argv[]); static void parse_args(int argc, char *argv[]); static error_t bam_menu(char *subcmd, char *opt, int argc, char *argv[]); static error_t bam_archive(char *subcmd, char *opt); static void bam_print(char *format, ...); static void bam_exit(int excode); static void bam_lock(void); static void bam_unlock(void); static int exec_cmd(char *cmdline, char *output, int64_t osize); static error_t read_globals(menu_t *mp, char *menu_path, char *globalcmd, int quiet); static menu_t *menu_read(char *menu_path); static error_t menu_write(char *root, menu_t *mp); static void linelist_free(line_t *start); static void menu_free(menu_t *mp); static void line_free(line_t *lp); static void filelist_free(filelist_t *flistp); static error_t list2file(char *root, char *tmp, char *final, line_t *start); static error_t list_entry(menu_t *mp, char *menu_path, char *opt); static error_t delete_all_entries(menu_t *mp, char *menu_path, char *opt); static error_t update_entry(menu_t *mp, char *root, char *opt); static error_t update_temp(menu_t *mp, char *root, char *opt); static error_t update_archive(char *root, char *opt); static error_t list_archive(char *root, char *opt); static error_t update_all(char *root, char *opt); static error_t read_list(char *root, filelist_t *flistp); static error_t set_global(menu_t *mp, char *globalcmd, int val); static error_t set_option(menu_t *mp, char *globalcmd, char *opt); static error_t set_kernel(menu_t *mp, menu_cmd_t optnum, char *path, char *buf, size_t bufsize); static char *expand_path(const char *partial_path); static long s_strtol(char *str); static int s_fputs(char *str, FILE *fp); static char *s_strdup(char *str); static int is_readonly(char *); static int is_amd64(void); static void append_to_flist(filelist_t *, char *); #if defined(__sparc) static void sparc_abort(void); #endif /* Menu related sub commands */ static subcmd_defn_t menu_subcmds[] = { "set_option", OPT_OPTIONAL, set_option, 0, /* PUB */ "list_entry", OPT_OPTIONAL, list_entry, 1, /* PUB */ "delete_all_entries", OPT_ABSENT, delete_all_entries, 0, /* PVT */ "update_entry", OPT_REQ, update_entry, 0, /* menu */ "update_temp", OPT_OPTIONAL, update_temp, 0, /* reboot */ "upgrade", OPT_ABSENT, upgrade_menu, 0, /* menu */ NULL, 0, NULL, 0 /* must be last */ }; /* Archive related sub commands */ static subcmd_defn_t arch_subcmds[] = { "update", OPT_ABSENT, update_archive, 0, /* PUB */ "update_all", OPT_ABSENT, update_all, 0, /* PVT */ "list", OPT_OPTIONAL, list_archive, 1, /* PUB */ NULL, 0, NULL, 0 /* must be last */ }; static struct { nvlist_t *new_nvlp; nvlist_t *old_nvlp; int need_update; } walk_arg; struct safefile { char *name; struct safefile *next; }; static struct safefile *safefiles = NULL; #define NEED_UPDATE_FILE "/etc/svc/volatile/boot_archive_needs_update" static void usage(void) { (void) fprintf(stderr, "USAGE:\n"); /* archive usage */ (void) fprintf(stderr, "\t%s update-archive [-vn] [-R altroot]\n", prog); (void) fprintf(stderr, "\t%s list-archive [-R altroot]\n", prog); #ifndef __sparc /* x86 only */ (void) fprintf(stderr, "\t%s set-menu [-R altroot] key=value\n", prog); (void) fprintf(stderr, "\t%s list-menu [-R altroot]\n", prog); #endif } int main(int argc, char *argv[]) { error_t ret; (void) setlocale(LC_ALL, ""); (void) textdomain(TEXT_DOMAIN); if ((prog = strrchr(argv[0], '/')) == NULL) { prog = argv[0]; } else { prog++; } /* * Don't depend on caller's umask */ (void) umask(0022); parse_args(argc, argv); #if defined(__sparc) /* * There are only two valid invocations of bootadm * on SPARC: * * - SPARC diskless server creating boot_archive for i386 clients * - archive creation call during reboot of a SPARC system * * The latter should be a NOP */ if (bam_cmd != BAM_ARCHIVE) { sparc_abort(); } #endif switch (bam_cmd) { case BAM_MENU: ret = bam_menu(bam_subcmd, bam_opt, bam_argc, bam_argv); break; case BAM_ARCHIVE: ret = bam_archive(bam_subcmd, bam_opt); break; default: usage(); bam_exit(1); } if (ret != BAM_SUCCESS) bam_exit(1); bam_unlock(); return (0); } #if defined(__sparc) static void sparc_abort(void) { bam_error(NOT_ON_SPARC); bam_exit(1); } #endif /* * Equivalence of public and internal commands: * update-archive -- -a update * list-archive -- -a list * set-menu -- -m set_option * list-menu -- -m list_entry * update-menu -- -m update_entry */ static struct cmd_map { char *bam_cmdname; int bam_cmd; char *bam_subcmd; } cmd_map[] = { { "update-archive", BAM_ARCHIVE, "update"}, { "list-archive", BAM_ARCHIVE, "list"}, { "set-menu", BAM_MENU, "set_option"}, { "list-menu", BAM_MENU, "list_entry"}, { "update-menu", BAM_MENU, "update_entry"}, { NULL, 0, NULL} }; /* * Commands syntax published in bootadm(1M) are parsed here */ static void parse_args(int argc, char *argv[]) { struct cmd_map *cmp = cmd_map; /* command conforming to the final spec */ if (argc > 1 && argv[1][0] != '-') { /* * Map commands to internal table. */ while (cmp->bam_cmdname) { if (strcmp(argv[1], cmp->bam_cmdname) == 0) { bam_cmd = cmp->bam_cmd; bam_subcmd = cmp->bam_subcmd; break; } cmp++; } if (cmp->bam_cmdname == NULL) { usage(); bam_exit(1); } argc--; argv++; } parse_args_internal(argc, argv); } /* * A combination of public and private commands are parsed here. * The internal syntax and the corresponding functionality are: * -a update -- update-archive * -a list -- list-archive * -a update-all -- (reboot to sync all mounted OS archive) * -m update_entry -- update-menu * -m list_entry -- list-menu * -m update_temp -- (reboot -- [boot-args]) * -m delete_all_entries -- (called from install) */ static void parse_args_internal(int argc, char *argv[]) { int c, error; extern char *optarg; extern int optind, opterr; /* Suppress error message from getopt */ opterr = 0; error = 0; while ((c = getopt(argc, argv, "a:d:fm:no:vCR:")) != -1) { switch (c) { case 'a': if (bam_cmd) { error = 1; bam_error(MULT_CMDS, c); } bam_cmd = BAM_ARCHIVE; bam_subcmd = optarg; break; case 'd': if (bam_debug) { error = 1; bam_error(DUP_OPT, c); } bam_debug = s_strtol(optarg); break; case 'f': if (bam_force) { error = 1; bam_error(DUP_OPT, c); } bam_force = 1; break; case 'm': if (bam_cmd) { error = 1; bam_error(MULT_CMDS, c); } bam_cmd = BAM_MENU; bam_subcmd = optarg; break; case 'n': if (bam_check) { error = 1; bam_error(DUP_OPT, c); } bam_check = 1; break; case 'o': if (bam_opt) { error = 1; bam_error(DUP_OPT, c); } bam_opt = optarg; break; case 'v': if (bam_verbose) { error = 1; bam_error(DUP_OPT, c); } bam_verbose = 1; break; case 'C': bam_smf_check = 1; break; case 'R': if (bam_root) { error = 1; bam_error(DUP_OPT, c); break; } else if (realpath(optarg, rootbuf) == NULL) { error = 1; bam_error(CANT_RESOLVE, optarg, strerror(errno)); break; } bam_alt_root = 1; bam_root = rootbuf; bam_rootlen = strlen(rootbuf); break; case '?': error = 1; bam_error(BAD_OPT, optopt); break; default : error = 1; bam_error(BAD_OPT, c); break; } } /* * A command option must be specfied */ if (!bam_cmd) { if (bam_opt && strcmp(bam_opt, "all") == 0) { usage(); bam_exit(0); } bam_error(NEED_CMD); error = 1; } if (error) { usage(); bam_exit(1); } if (optind > argc) { bam_error(INT_ERROR, "parse_args"); bam_exit(1); } else if (optind < argc) { bam_argv = &argv[optind]; bam_argc = argc - optind; } /* * -n implies verbose mode */ if (bam_check) bam_verbose = 1; } static error_t check_subcmd_and_options( char *subcmd, char *opt, subcmd_defn_t *table, error_t (**fp)()) { int i; if (subcmd == NULL) { bam_error(NEED_SUBCMD); return (BAM_ERROR); } if (bam_argc != 0 || bam_argv) { if (strcmp(subcmd, "set_option") != 0 || bam_argc != 1) { bam_error(TRAILING_ARGS); usage(); return (BAM_ERROR); } } if (bam_root == NULL) { bam_root = rootbuf; bam_rootlen = 1; } /* verify that subcmd is valid */ for (i = 0; table[i].subcmd != NULL; i++) { if (strcmp(table[i].subcmd, subcmd) == 0) break; } if (table[i].subcmd == NULL) { bam_error(INVALID_SUBCMD, subcmd); return (BAM_ERROR); } if (table[i].unpriv == 0 && geteuid() != 0) { bam_error(MUST_BE_ROOT); return (BAM_ERROR); } /* * Currently only privileged commands need a lock */ if (table[i].unpriv == 0) bam_lock(); /* subcmd verifies that opt is appropriate */ if (table[i].option != OPT_OPTIONAL) { if ((table[i].option == OPT_REQ) ^ (opt != NULL)) { if (opt) bam_error(NO_OPT_REQ, subcmd); else bam_error(MISS_OPT, subcmd); return (BAM_ERROR); } } *fp = table[i].handler; return (BAM_SUCCESS); } static char * mount_grub_slice(int *mnted, char **physlice, char **logslice, char **fs_type) { struct extmnttab mnt; struct stat sb; char buf[BAM_MAXLINE], dev[PATH_MAX], phys[PATH_MAX], fstype[32]; char cmd[PATH_MAX]; char *mntpt; int p, l, f; FILE *fp; assert(mnted); *mnted = 0; /* * physlice, logslice, fs_type args may be NULL */ if (physlice) *physlice = NULL; if (logslice) *logslice = NULL; if (fs_type) *fs_type = NULL; if (stat(GRUB_slice, &sb) != 0) { bam_error(MISSING_SLICE_FILE, GRUB_slice, strerror(errno)); return (NULL); } fp = fopen(GRUB_slice, "r"); if (fp == NULL) { bam_error(OPEN_FAIL, GRUB_slice, strerror(errno)); return (NULL); } dev[0] = fstype[0] = phys[0] = '\0'; p = sizeof ("PHYS_SLICE=") - 1; l = sizeof ("LOG_SLICE=") - 1; f = sizeof ("LOG_FSTYP=") - 1; while (s_fgets(buf, sizeof (buf), fp) != NULL) { if (strncmp(buf, "PHYS_SLICE=", p) == 0) { (void) strlcpy(phys, buf + p, sizeof (phys)); continue; } if (strncmp(buf, "LOG_SLICE=", l) == 0) { (void) strlcpy(dev, buf + l, sizeof (dev)); continue; } if (strncmp(buf, "LOG_FSTYP=", f) == 0) { (void) strlcpy(fstype, buf + f, sizeof (fstype)); continue; } } (void) fclose(fp); if (dev[0] == '\0' || fstype[0] == '\0' || phys[0] == '\0') { bam_error(BAD_SLICE_FILE, GRUB_slice); return (NULL); } if (physlice) { *physlice = s_strdup(phys); } if (logslice) { *logslice = s_strdup(dev); } if (fs_type) { *fs_type = s_strdup(fstype); } /* * Check if the slice is already mounted */ fp = fopen(MNTTAB, "r"); if (fp == NULL) { bam_error(OPEN_FAIL, MNTTAB, strerror(errno)); goto error; } resetmnttab(fp); mntpt = NULL; while (getextmntent(fp, &mnt, sizeof (mnt)) == 0) { if (strcmp(mnt.mnt_special, dev) == 0) { mntpt = s_strdup(mnt.mnt_mountp); break; } } (void) fclose(fp); if (mntpt) { return (mntpt); } /* * GRUB slice is not mounted, we need to mount it now. * First create the mountpoint */ mntpt = s_calloc(1, PATH_MAX); (void) snprintf(mntpt, PATH_MAX, "%s.%d", GRUB_slice_mntpt, getpid()); if (mkdir(mntpt, 0755) == -1 && errno != EEXIST) { bam_error(MKDIR_FAILED, mntpt, strerror(errno)); free(mntpt); goto error; } (void) snprintf(cmd, sizeof (cmd), "/sbin/mount -F %s %s %s", fstype, dev, mntpt); if (exec_cmd(cmd, NULL, 0) != 0) { bam_error(MOUNT_FAILED, dev, fstype); if (rmdir(mntpt) != 0) { bam_error(RMDIR_FAILED, mntpt, strerror(errno)); } free(mntpt); goto error; } *mnted = 1; return (mntpt); error: if (physlice) { free(*physlice); *physlice = NULL; } if (logslice) { free(*logslice); *logslice = NULL; } if (fs_type) { free(*fs_type); *fs_type = NULL; } return (NULL); } static void umount_grub_slice( int mnted, char *mntpt, char *physlice, char *logslice, char *fs_type) { char cmd[PATH_MAX]; /* * If we have not dealt with GRUB slice * we have nothing to do - just return. */ if (mntpt == NULL) return; /* * If we mounted the filesystem earlier in mount_grub_slice() * unmount it now. */ if (mnted) { (void) snprintf(cmd, sizeof (cmd), "/sbin/umount %s", mntpt); if (exec_cmd(cmd, NULL, 0) != 0) { bam_error(UMOUNT_FAILED, mntpt); } if (rmdir(mntpt) != 0) { bam_error(RMDIR_FAILED, mntpt, strerror(errno)); } } if (physlice) free(physlice); if (logslice) free(logslice); if (fs_type) free(fs_type); free(mntpt); } static char * use_stubboot(void) { int mnted; struct stat sb; struct extmnttab mnt; FILE *fp; char cmd[PATH_MAX]; if (stat(STUBBOOT, &sb) != 0) { bam_error(STUBBOOT_DIR_NOT_FOUND); return (NULL); } /* * Check if stubboot is mounted. If not, mount it */ fp = fopen(MNTTAB, "r"); if (fp == NULL) { bam_error(OPEN_FAIL, MNTTAB, strerror(errno)); return (NULL); } resetmnttab(fp); mnted = 0; while (getextmntent(fp, &mnt, sizeof (mnt)) == 0) { if (strcmp(mnt.mnt_mountp, STUBBOOT) == 0) { mnted = 1; break; } } (void) fclose(fp); if (mnted) return (STUBBOOT); /* * Stubboot is not mounted, mount it now. * It should exist in /etc/vfstab */ (void) snprintf(cmd, sizeof (cmd), "/sbin/mount %s", STUBBOOT); if (exec_cmd(cmd, NULL, 0) != 0) { bam_error(MOUNT_MNTPT_FAILED, STUBBOOT); return (NULL); } return (STUBBOOT); } static void disp_active_menu_locn(char *menu_path, char *logslice, char *fstype, int mnted) { /* * Check if we did a temp mount of an unmounted device. * If yes, print the block device and fstype for that device * else it is already mounted, so we print the path to the GRUB menu. */ if (mnted) { bam_print(GRUB_MENU_DEVICE, logslice); bam_print(GRUB_MENU_FSTYPE, fstype); } else { bam_print(GRUB_MENU_PATH, menu_path); } } /* * NOTE: A single "/" is also considered a trailing slash and will * be deleted. */ static void elide_trailing_slash(const char *src, char *dst, size_t dstsize) { size_t dstlen; assert(src); assert(dst); (void) strlcpy(dst, src, dstsize); dstlen = strlen(dst); if (dst[dstlen - 1] == '/') { dst[dstlen - 1] = '\0'; } } static error_t bam_menu(char *subcmd, char *opt, int largc, char *largv[]) { error_t ret; char menu_path[PATH_MAX]; char path[PATH_MAX]; menu_t *menu; char *mntpt, *menu_root, *logslice, *fstype; struct stat sb; int mnted; /* set if we did a mount */ error_t (*f)(menu_t *mp, char *menu_path, char *opt); /* * Check arguments */ ret = check_subcmd_and_options(subcmd, opt, menu_subcmds, &f); if (ret == BAM_ERROR) { return (BAM_ERROR); } mntpt = NULL; mnted = 0; logslice = fstype = NULL; /* * Check for the menu.list file: * * 1. Check for a GRUB_slice file, be it on / or * on the user-provided alternate root. * 2. Use the alternate root, if given. * 3. Check /stubboot * 4. Use / */ if (bam_alt_root) { (void) snprintf(path, sizeof (path), "%s%s", bam_root, GRUB_slice); } else { (void) snprintf(path, sizeof (path), "%s", GRUB_slice); } if (stat(path, &sb) == 0) { mntpt = mount_grub_slice(&mnted, NULL, &logslice, &fstype); menu_root = mntpt; } else if (bam_alt_root) { menu_root = bam_root; } else if (stat(STUBBOOT, &sb) == 0) { menu_root = use_stubboot(); } else { menu_root = bam_root; } if (menu_root == NULL) { bam_error(CANNOT_LOCATE_GRUB_MENU); return (BAM_ERROR); } elide_trailing_slash(menu_root, menu_path, sizeof (menu_path)); (void) strlcat(menu_path, GRUB_MENU, sizeof (menu_path)); /* * If listing the menu, display the active menu * location */ if (strcmp(subcmd, "list_entry") == 0) { disp_active_menu_locn(menu_path, logslice, fstype, mnted); } menu = menu_read(menu_path); assert(menu); /* * Special handling for setting timeout and default */ if (strcmp(subcmd, "set_option") == 0) { if (largc != 1 || largv[0] == NULL) { usage(); menu_free(menu); umount_grub_slice(mnted, mntpt, NULL, logslice, fstype); return (BAM_ERROR); } opt = largv[0]; } else if (largc != 0) { usage(); menu_free(menu); umount_grub_slice(mnted, mntpt, NULL, logslice, fstype); return (BAM_ERROR); } ret = dboot_or_multiboot(bam_root); if (ret != BAM_SUCCESS) return (ret); /* * Once the sub-cmd handler has run * only the line field is guaranteed to have valid values */ if ((strcmp(subcmd, "update_entry") == 0) || (strcmp(subcmd, "upgrade") == 0)) ret = f(menu, bam_root, opt); else ret = f(menu, menu_path, opt); if (ret == BAM_WRITE) { ret = menu_write(menu_root, menu); } menu_free(menu); umount_grub_slice(mnted, mntpt, NULL, logslice, fstype); return (ret); } static error_t bam_archive( char *subcmd, char *opt) { error_t ret; error_t (*f)(char *root, char *opt); /* * Add trailing / for archive subcommands */ if (rootbuf[strlen(rootbuf) - 1] != '/') (void) strcat(rootbuf, "/"); bam_rootlen = strlen(rootbuf); /* * Check arguments */ ret = check_subcmd_and_options(subcmd, opt, arch_subcmds, &f); if (ret != BAM_SUCCESS) { return (BAM_ERROR); } #if defined(__sparc) /* * A NOP if called on SPARC during reboot */ if (strcmp(subcmd, "update_all") == 0) return (BAM_SUCCESS); else if (strcmp(subcmd, "update") != 0) sparc_abort(); #endif ret = dboot_or_multiboot(rootbuf); if (ret != BAM_SUCCESS) return (ret); /* * Check archive not supported with update_all * since it is awkward to display out-of-sync * information for each BE. */ if (bam_check && strcmp(subcmd, "update_all") == 0) { bam_error(CHECK_NOT_SUPPORTED, subcmd); return (BAM_ERROR); } if (strcmp(subcmd, "update_all") == 0) bam_update_all = 1; ret = f(bam_root, opt); bam_update_all = 0; return (ret); } /*PRINTFLIKE1*/ void bam_error(char *format, ...) { va_list ap; va_start(ap, format); (void) fprintf(stderr, "%s: ", prog); (void) vfprintf(stderr, format, ap); va_end(ap); } /*PRINTFLIKE1*/ static void bam_print(char *format, ...) { va_list ap; va_start(ap, format); (void) vfprintf(stdout, format, ap); va_end(ap); } /*PRINTFLIKE1*/ void bam_print_stderr(char *format, ...) { va_list ap; va_start(ap, format); (void) vfprintf(stderr, format, ap); va_end(ap); } static void bam_exit(int excode) { bam_unlock(); exit(excode); } static void bam_lock(void) { struct flock lock; pid_t pid; bam_lock_fd = open(BAM_LOCK_FILE, O_CREAT|O_RDWR, LOCK_FILE_PERMS); if (bam_lock_fd < 0) { /* * We may be invoked early in boot for archive verification. * In this case, root is readonly and /var/run may not exist. * Proceed without the lock */ if (errno == EROFS || errno == ENOENT) { bam_root_readonly = 1; return; } bam_error(OPEN_FAIL, BAM_LOCK_FILE, strerror(errno)); bam_exit(1); } lock.l_type = F_WRLCK; lock.l_whence = SEEK_SET; lock.l_start = 0; lock.l_len = 0; if (fcntl(bam_lock_fd, F_SETLK, &lock) == -1) { if (errno != EACCES && errno != EAGAIN) { bam_error(LOCK_FAIL, BAM_LOCK_FILE, strerror(errno)); (void) close(bam_lock_fd); bam_lock_fd = -1; bam_exit(1); } pid = 0; (void) pread(bam_lock_fd, &pid, sizeof (pid_t), 0); bam_print(FILE_LOCKED, pid); lock.l_type = F_WRLCK; lock.l_whence = SEEK_SET; lock.l_start = 0; lock.l_len = 0; if (fcntl(bam_lock_fd, F_SETLKW, &lock) == -1) { bam_error(LOCK_FAIL, BAM_LOCK_FILE, strerror(errno)); (void) close(bam_lock_fd); bam_lock_fd = -1; bam_exit(1); } } /* We own the lock now */ pid = getpid(); (void) write(bam_lock_fd, &pid, sizeof (pid)); } static void bam_unlock(void) { struct flock unlock; /* * NOP if we don't hold the lock */ if (bam_lock_fd < 0) { return; } unlock.l_type = F_UNLCK; unlock.l_whence = SEEK_SET; unlock.l_start = 0; unlock.l_len = 0; if (fcntl(bam_lock_fd, F_SETLK, &unlock) == -1) { bam_error(UNLOCK_FAIL, BAM_LOCK_FILE, strerror(errno)); } if (close(bam_lock_fd) == -1) { bam_error(CLOSE_FAIL, BAM_LOCK_FILE, strerror(errno)); } bam_lock_fd = -1; } static error_t list_archive(char *root, char *opt) { filelist_t flist; filelist_t *flistp = &flist; line_t *lp; assert(root); assert(opt == NULL); flistp->head = flistp->tail = NULL; if (read_list(root, flistp) != BAM_SUCCESS) { return (BAM_ERROR); } assert(flistp->head && flistp->tail); for (lp = flistp->head; lp; lp = lp->next) { bam_print(PRINT, lp->line); } filelist_free(flistp); return (BAM_SUCCESS); } /* * This routine writes a list of lines to a file. * The list is *not* freed */ static error_t list2file(char *root, char *tmp, char *final, line_t *start) { char tmpfile[PATH_MAX]; char path[PATH_MAX]; FILE *fp; int ret; struct stat sb; mode_t mode; uid_t root_uid; gid_t sys_gid; struct passwd *pw; struct group *gp; (void) snprintf(path, sizeof (path), "%s%s", root, final); if (start == NULL) { if (stat(path, &sb) != -1) { bam_print(UNLINK_EMPTY, path); if (unlink(path) != 0) { bam_error(UNLINK_FAIL, path, strerror(errno)); return (BAM_ERROR); } else { return (BAM_SUCCESS); } } } /* * Preserve attributes of existing file if possible, * otherwise ask the system for uid/gid of root/sys. * If all fails, fall back on hard-coded defaults. */ if (stat(path, &sb) != -1) { mode = sb.st_mode; root_uid = sb.st_uid; sys_gid = sb.st_gid; } else { mode = DEFAULT_DEV_MODE; if ((pw = getpwnam(DEFAULT_DEV_USER)) != NULL) { root_uid = pw->pw_uid; } else { if (bam_verbose) bam_error(CANT_FIND_USER, DEFAULT_DEV_USER, DEFAULT_DEV_UID); root_uid = (uid_t)DEFAULT_DEV_UID; } if ((gp = getgrnam(DEFAULT_DEV_GROUP)) != NULL) { sys_gid = gp->gr_gid; } else { if (bam_verbose) bam_error(CANT_FIND_GROUP, DEFAULT_DEV_GROUP, DEFAULT_DEV_GID); sys_gid = (gid_t)DEFAULT_DEV_GID; } } (void) snprintf(tmpfile, sizeof (tmpfile), "%s%s", root, tmp); /* Truncate tmpfile first */ fp = fopen(tmpfile, "w"); if (fp == NULL) { bam_error(OPEN_FAIL, tmpfile, strerror(errno)); return (BAM_ERROR); } ret = fclose(fp); if (ret == EOF) { bam_error(CLOSE_FAIL, tmpfile, strerror(errno)); return (BAM_ERROR); } /* Now open it in append mode */ fp = fopen(tmpfile, "a"); if (fp == NULL) { bam_error(OPEN_FAIL, tmpfile, strerror(errno)); return (BAM_ERROR); } for (; start; start = start->next) { ret = s_fputs(start->line, fp); if (ret == EOF) { bam_error(WRITE_FAIL, tmpfile, strerror(errno)); (void) fclose(fp); return (BAM_ERROR); } } ret = fclose(fp); if (ret == EOF) { bam_error(CLOSE_FAIL, tmpfile, strerror(errno)); return (BAM_ERROR); } /* * Set up desired attributes. Ignore failures on filesystems * not supporting these operations - pcfs reports unsupported * operations as EINVAL. */ ret = chmod(tmpfile, mode); if (ret == -1 && errno != EINVAL && errno != ENOTSUP) { bam_error(CHMOD_FAIL, tmpfile, strerror(errno)); return (BAM_ERROR); } ret = chown(tmpfile, root_uid, sys_gid); if (ret == -1 && errno != EINVAL && errno != ENOTSUP) { bam_error(CHOWN_FAIL, tmpfile, strerror(errno)); return (BAM_ERROR); } /* * Do an atomic rename */ ret = rename(tmpfile, path); if (ret != 0) { bam_error(RENAME_FAIL, path, strerror(errno)); return (BAM_ERROR); } return (BAM_SUCCESS); } /* * This function should always return 0 - since we want * to create stat data for *all* files in the list. */ /*ARGSUSED*/ static int cmpstat( const char *file, const struct stat *stat, int flags, struct FTW *ftw) { uint_t sz; uint64_t *value; uint64_t filestat[2]; int error; struct safefile *safefilep; FILE *fp; /* * We only want regular files */ if (!S_ISREG(stat->st_mode)) return (0); /* * new_nvlp may be NULL if there were errors earlier * but this is not fatal to update determination. */ if (walk_arg.new_nvlp) { filestat[0] = stat->st_size; filestat[1] = stat->st_mtime; error = nvlist_add_uint64_array(walk_arg.new_nvlp, file + bam_rootlen, filestat, 2); if (error) bam_error(NVADD_FAIL, file, strerror(error)); } /* * The remaining steps are only required if we haven't made a * decision about update or if we are checking (-n) */ if (walk_arg.need_update && !bam_check) return (0); /* * If we are invoked as part of system/filesyste/boot-archive, then * there are a number of things we should not worry about */ if (bam_smf_check) { /* ignore amd64 modules unless we are booted amd64. */ if (!is_amd64() && strstr(file, "/amd64/") != 0) return (0); /* read in list of safe files */ if (safefiles == NULL) if (fp = fopen("/boot/solaris/filelist.safe", "r")) { safefiles = s_calloc(1, sizeof (struct safefile)); safefilep = safefiles; safefilep->name = s_calloc(1, MAXPATHLEN + MAXNAMELEN); safefilep->next = NULL; while (s_fgets(safefilep->name, MAXPATHLEN + MAXNAMELEN, fp) != NULL) { safefilep->next = s_calloc(1, sizeof (struct safefile)); safefilep = safefilep->next; safefilep->name = s_calloc(1, MAXPATHLEN + MAXNAMELEN); safefilep->next = NULL; } (void) fclose(fp); } } /* * We need an update if file doesn't exist in old archive */ if (walk_arg.old_nvlp == NULL || nvlist_lookup_uint64_array(walk_arg.old_nvlp, file + bam_rootlen, &value, &sz) != 0) { if (bam_smf_check) /* ignore new during smf check */ return (0); walk_arg.need_update = 1; if (bam_verbose) bam_print(PARSEABLE_NEW_FILE, file); return (0); } /* * File exists in old archive. Check if file has changed */ assert(sz == 2); bcopy(value, filestat, sizeof (filestat)); if (filestat[0] != stat->st_size || filestat[1] != stat->st_mtime) { if (bam_smf_check) { safefilep = safefiles; while (safefilep != NULL) { if (strcmp(file + bam_rootlen, safefilep->name) == 0) { (void) creat(NEED_UPDATE_FILE, 0644); return (0); } safefilep = safefilep->next; } } walk_arg.need_update = 1; if (bam_verbose) if (bam_smf_check) bam_print(" %s\n", file); else bam_print(PARSEABLE_OUT_DATE, file); } return (0); } /* * Check flags and presence of required files. * The force flag and/or absence of files should * trigger an update. * Suppress stdout output if check (-n) option is set * (as -n should only produce parseable output.) */ static void check_flags_and_files(char *root) { char path[PATH_MAX]; struct stat sb; /* * if force, create archive unconditionally */ if (bam_force) { walk_arg.need_update = 1; if (bam_verbose && !bam_check) bam_print(UPDATE_FORCE); return; } /* * If archive is missing, create archive */ (void) snprintf(path, sizeof (path), "%s%s", root, DIRECT_BOOT_ARCHIVE_32); if (stat(path, &sb) != 0) { if (bam_verbose && !bam_check) bam_print(UPDATE_ARCH_MISS, path); walk_arg.need_update = 1; return; } if (bam_direct == BAM_DIRECT_DBOOT) { (void) snprintf(path, sizeof (path), "%s%s", root, DIRECT_BOOT_ARCHIVE_64); if (stat(path, &sb) != 0) { if (bam_verbose && !bam_check) bam_print(UPDATE_ARCH_MISS, path); walk_arg.need_update = 1; return; } } } static error_t read_one_list(char *root, filelist_t *flistp, char *filelist) { char path[PATH_MAX]; FILE *fp; char buf[BAM_MAXLINE]; (void) snprintf(path, sizeof (path), "%s%s", root, filelist); fp = fopen(path, "r"); if (fp == NULL) { if (bam_debug) bam_error(FLIST_FAIL, path, strerror(errno)); return (BAM_ERROR); } while (s_fgets(buf, sizeof (buf), fp) != NULL) { /* skip blank lines */ if (strspn(buf, " \t") == strlen(buf)) continue; append_to_flist(flistp, buf); } if (fclose(fp) != 0) { bam_error(CLOSE_FAIL, path, strerror(errno)); return (BAM_ERROR); } return (BAM_SUCCESS); } static error_t read_list(char *root, filelist_t *flistp) { int rval; flistp->head = flistp->tail = NULL; /* * Read current lists of files - only the first is mandatory */ rval = read_one_list(root, flistp, BOOT_FILE_LIST); if (rval != BAM_SUCCESS) return (rval); (void) read_one_list(root, flistp, ETC_FILE_LIST); if (flistp->head == NULL) { bam_error(NO_FLIST); return (BAM_ERROR); } return (BAM_SUCCESS); } static void getoldstat(char *root) { char path[PATH_MAX]; int fd, error; struct stat sb; char *ostat; (void) snprintf(path, sizeof (path), "%s%s", root, FILE_STAT); fd = open(path, O_RDONLY); if (fd == -1) { if (bam_verbose) bam_print(OPEN_FAIL, path, strerror(errno)); walk_arg.need_update = 1; return; } if (fstat(fd, &sb) != 0) { bam_error(STAT_FAIL, path, strerror(errno)); (void) close(fd); walk_arg.need_update = 1; return; } ostat = s_calloc(1, sb.st_size); if (read(fd, ostat, sb.st_size) != sb.st_size) { bam_error(READ_FAIL, path, strerror(errno)); (void) close(fd); free(ostat); walk_arg.need_update = 1; return; } (void) close(fd); walk_arg.old_nvlp = NULL; error = nvlist_unpack(ostat, sb.st_size, &walk_arg.old_nvlp, 0); free(ostat); if (error) { bam_error(UNPACK_FAIL, path, strerror(error)); walk_arg.old_nvlp = NULL; walk_arg.need_update = 1; return; } } /* * Checks if a file in the current (old) archive has * been deleted from the root filesystem. This is needed for * software like Trusted Extensions (TX) that switch early * in boot based on presence/absence of a kernel module. */ static void check4stale(char *root) { nvpair_t *nvp; nvlist_t *nvlp; char *file; char path[PATH_MAX]; struct stat sb; /* * Skip stale file check during smf check */ if (bam_smf_check) return; /* Nothing to do if no old stats */ if ((nvlp = walk_arg.old_nvlp) == NULL) return; for (nvp = nvlist_next_nvpair(nvlp, NULL); nvp; nvp = nvlist_next_nvpair(nvlp, nvp)) { file = nvpair_name(nvp); if (file == NULL) continue; (void) snprintf(path, sizeof (path), "%s/%s", root, file); if (stat(path, &sb) == -1) { walk_arg.need_update = 1; if (bam_verbose) bam_print(PARSEABLE_STALE_FILE, path); } } } static void create_newstat(void) { int error; error = nvlist_alloc(&walk_arg.new_nvlp, NV_UNIQUE_NAME, 0); if (error) { /* * Not fatal - we can still create archive */ walk_arg.new_nvlp = NULL; bam_error(NVALLOC_FAIL, strerror(error)); } } static void walk_list(char *root, filelist_t *flistp) { char path[PATH_MAX]; line_t *lp; for (lp = flistp->head; lp; lp = lp->next) { (void) snprintf(path, sizeof (path), "%s%s", root, lp->line); /* XXX shouldn't we use FTW_MOUNT ? */ if (nftw(path, cmpstat, 20, 0) == -1) { /* * Some files may not exist. * For example: etc/rtc_config on a x86 diskless system * Emit verbose message only */ if (bam_verbose) bam_print(NFTW_FAIL, path, strerror(errno)); } } } static void savenew(char *root) { char path[PATH_MAX]; char path2[PATH_MAX]; size_t sz; char *nstat; int fd, wrote, error; nstat = NULL; sz = 0; error = nvlist_pack(walk_arg.new_nvlp, &nstat, &sz, NV_ENCODE_XDR, 0); if (error) { bam_error(PACK_FAIL, strerror(error)); return; } (void) snprintf(path, sizeof (path), "%s%s", root, FILE_STAT_TMP); fd = open(path, O_RDWR|O_CREAT|O_TRUNC, FILE_STAT_MODE); if (fd == -1) { bam_error(OPEN_FAIL, path, strerror(errno)); free(nstat); return; } wrote = write(fd, nstat, sz); if (wrote != sz) { bam_error(WRITE_FAIL, path, strerror(errno)); (void) close(fd); free(nstat); return; } (void) close(fd); free(nstat); (void) snprintf(path2, sizeof (path2), "%s%s", root, FILE_STAT); if (rename(path, path2) != 0) { bam_error(RENAME_FAIL, path2, strerror(errno)); } } static void clear_walk_args(void) { if (walk_arg.old_nvlp) nvlist_free(walk_arg.old_nvlp); if (walk_arg.new_nvlp) nvlist_free(walk_arg.new_nvlp); walk_arg.need_update = 0; walk_arg.old_nvlp = NULL; walk_arg.new_nvlp = NULL; } /* * Returns: * 0 - no update necessary * 1 - update required. * BAM_ERROR (-1) - An error occurred * * Special handling for check (-n): * ================================ * The check (-n) option produces parseable output. * To do this, we suppress all stdout messages unrelated * to out of sync files. * All stderr messages are still printed though. * */ static int update_required(char *root) { struct stat sb; char path[PATH_MAX]; filelist_t flist; filelist_t *flistp = &flist; int need_update; flistp->head = flistp->tail = NULL; walk_arg.need_update = 0; /* * Without consulting stat data, check if we need update */ check_flags_and_files(root); /* * In certain deployment scenarios, filestat may not * exist. Ignore it during boot-archive SMF check. */ if (bam_smf_check) { (void) snprintf(path, sizeof (path), "%s%s", root, FILE_STAT); if (stat(path, &sb) != 0) return (0); } /* * consult stat data only if we haven't made a decision * about update. If checking (-n) however, we always * need stat data (since we want to compare old and new) */ if (!walk_arg.need_update || bam_check) getoldstat(root); /* * Check if the archive contains files that are no longer * present on the root filesystem. */ if (!walk_arg.need_update || bam_check) check4stale(root); /* * read list of files */ if (read_list(root, flistp) != BAM_SUCCESS) { clear_walk_args(); return (BAM_ERROR); } assert(flistp->head && flistp->tail); /* * At this point either the update is required * or the decision is pending. In either case * we need to create new stat nvlist */ create_newstat(); /* * This walk does 2 things: * - gets new stat data for every file * - (optional) compare old and new stat data */ walk_list(root, &flist); /* done with the file list */ filelist_free(flistp); /* * if we didn't succeed in creating new stat data above * just return result of update check so that archive is built. */ if (walk_arg.new_nvlp == NULL) { bam_error(NO_NEW_STAT); need_update = walk_arg.need_update; clear_walk_args(); return (need_update ? 1 : 0); } /* * If no update required, discard newstat */ if (!walk_arg.need_update) { clear_walk_args(); return (0); } /* * At this point we need an update - so save new stat data * However, if only checking (-n), don't save new stat data. */ if (!bam_check) savenew(root); clear_walk_args(); return (1); } static error_t create_ramdisk(char *root) { char *cmdline, path[PATH_MAX]; size_t len; struct stat sb; /* * Setup command args for create_ramdisk.ksh */ (void) snprintf(path, sizeof (path), "%s%s", root, CREATE_RAMDISK); if (stat(path, &sb) != 0) { bam_error(ARCH_EXEC_MISS, path, strerror(errno)); return (BAM_ERROR); } len = strlen(path) + strlen(root) + 10; /* room for space + -R */ cmdline = s_calloc(1, len); if (strlen(root) > 1) { (void) snprintf(cmdline, len, "%s -R %s", path, root); /* chop off / at the end */ cmdline[strlen(cmdline) - 1] = '\0'; } else (void) snprintf(cmdline, len, "%s", path); if (exec_cmd(cmdline, NULL, 0) != 0) { bam_error(ARCHIVE_FAIL, cmdline); free(cmdline); return (BAM_ERROR); } free(cmdline); /* * Verify that the archive has been created */ (void) snprintf(path, sizeof (path), "%s%s", root, DIRECT_BOOT_ARCHIVE_32); if (stat(path, &sb) != 0) { bam_error(ARCHIVE_NOT_CREATED, path); return (BAM_ERROR); } if (bam_direct == BAM_DIRECT_DBOOT) { (void) snprintf(path, sizeof (path), "%s%s", root, DIRECT_BOOT_ARCHIVE_64); if (stat(path, &sb) != 0) { bam_error(ARCHIVE_NOT_CREATED, path); return (BAM_ERROR); } } return (BAM_SUCCESS); } /* * Checks if target filesystem is on a ramdisk * 1 - is miniroot * 0 - is not * When in doubt assume it is not a ramdisk. */ static int is_ramdisk(char *root) { struct extmnttab mnt; FILE *fp; int found; char mntpt[PATH_MAX]; char *cp; /* * There are 3 situations where creating archive is * of dubious value: * - create boot_archive on a lofi-mounted boot_archive * - create it on a ramdisk which is the root filesystem * - create it on a ramdisk mounted somewhere else * The first is not easy to detect and checking for it is not * worth it. * The other two conditions are handled here */ fp = fopen(MNTTAB, "r"); if (fp == NULL) { bam_error(OPEN_FAIL, MNTTAB, strerror(errno)); return (0); } resetmnttab(fp); /* * Remove any trailing / from the mount point */ (void) strlcpy(mntpt, root, sizeof (mntpt)); if (strcmp(root, "/") != 0) { cp = mntpt + strlen(mntpt) - 1; if (*cp == '/') *cp = '\0'; } found = 0; while (getextmntent(fp, &mnt, sizeof (mnt)) == 0) { if (strcmp(mnt.mnt_mountp, mntpt) == 0) { found = 1; break; } } if (!found) { if (bam_verbose) bam_error(NOT_IN_MNTTAB, mntpt); (void) fclose(fp); return (0); } if (strstr(mnt.mnt_special, RAMDISK_SPECIAL) != NULL) { if (bam_verbose) bam_error(IS_RAMDISK, bam_root); (void) fclose(fp); return (1); } (void) fclose(fp); return (0); } static int is_newboot(char *root) { char path[PATH_MAX]; struct stat sb; /* * We can't boot without MULTI_BOOT */ (void) snprintf(path, sizeof (path), "%s%s", root, MULTI_BOOT); if (stat(path, &sb) == -1) { if (bam_verbose) bam_print(FILE_MISS, path); return (0); } /* * We can't generate archive without GRUB_DIR */ (void) snprintf(path, sizeof (path), "%s%s", root, GRUB_DIR); if (stat(path, &sb) == -1) { if (bam_verbose) bam_print(DIR_MISS, path); return (0); } return (1); } static int is_readonly(char *root) { struct statvfs vfs; /* * Check for RDONLY filesystem * When in doubt assume it is not readonly */ if (statvfs(root, &vfs) != 0) { if (bam_verbose) bam_error(STATVFS_FAIL, root, strerror(errno)); return (0); } if (vfs.f_flag & ST_RDONLY) { return (1); } return (0); } static error_t update_archive(char *root, char *opt) { error_t ret; assert(root); assert(opt == NULL); /* * root must belong to a GRUB boot OS, * don't care on sparc except for diskless clients */ if (!is_newboot(root)) { /* * Emit message only if not in context of update_all. * If in update_all, emit only if verbose flag is set. */ if (!bam_update_all || bam_verbose) bam_print(NOT_GRUB_BOOT, root); return (BAM_SUCCESS); } /* * If smf check is requested when / is writable (can happen * on first reboot following an upgrade because service * dependency is messed up), skip the check. */ if (bam_smf_check && !bam_root_readonly) return (BAM_SUCCESS); /* * root must be writable. This check applies to alternate * root (-R option); bam_root_readonly applies to '/' only. * Note: statvfs() does not always report the truth */ if (!bam_smf_check && !bam_check && is_readonly(root)) { if (bam_verbose) bam_print(RDONLY_FS, root); return (BAM_SUCCESS); } /* * Don't generate archive on ramdisk */ if (is_ramdisk(root)) { if (bam_verbose) bam_print(SKIP_RAMDISK); return (BAM_SUCCESS); } /* * Now check if updated is really needed */ ret = update_required(root); /* * The check command (-n) is *not* a dry run * It only checks if the archive is in sync. */ if (bam_check) { bam_exit((ret != 0) ? 1 : 0); } if (ret == 1) { /* create the ramdisk */ ret = create_ramdisk(root); } return (ret); } static void update_fdisk(void) { struct stat sb; char cmd[PATH_MAX]; int ret1, ret2; assert(stat(GRUB_fdisk, &sb) == 0); assert(stat(GRUB_fdisk_target, &sb) == 0); (void) snprintf(cmd, sizeof (cmd), "/sbin/fdisk -F %s `/bin/cat %s`", GRUB_fdisk, GRUB_fdisk_target); bam_print(UPDATING_FDISK); if (exec_cmd(cmd, NULL, 0) != 0) { bam_error(FDISK_UPDATE_FAILED); } /* * We are done, remove the files. */ ret1 = unlink(GRUB_fdisk); ret2 = unlink(GRUB_fdisk_target); if (ret1 != 0 || ret2 != 0) { bam_error(FILE_REMOVE_FAILED, GRUB_fdisk, GRUB_fdisk_target); } } static void restore_grub_slice(void) { struct stat sb; char *mntpt, *physlice; int mnted; /* set if we did a mount */ char menupath[PATH_MAX], cmd[PATH_MAX]; if (stat(GRUB_slice, &sb) != 0) { bam_error(MISSING_SLICE_FILE, GRUB_slice, strerror(errno)); return; } /* * If we are doing an luactivate, don't attempt to restore GRUB or else * we may not be able to get to DCA boot environments. Let luactivate * handle GRUB/DCA installation */ if (stat(LU_ACTIVATE_FILE, &sb) == 0) { return; } mnted = 0; physlice = NULL; mntpt = mount_grub_slice(&mnted, &physlice, NULL, NULL); if (mntpt == NULL) { bam_error(CANNOT_RESTORE_GRUB_SLICE); return; } (void) snprintf(menupath, sizeof (menupath), "%s%s", mntpt, GRUB_MENU); if (stat(menupath, &sb) == 0) { umount_grub_slice(mnted, mntpt, physlice, NULL, NULL); return; } /* * The menu is missing - we need to do a restore */ bam_print(RESTORING_GRUB); (void) snprintf(cmd, sizeof (cmd), "%s %s %s %s", INSTALLGRUB, STAGE1, STAGE2, physlice); if (exec_cmd(cmd, NULL, 0) != 0) { bam_error(RESTORE_GRUB_FAILED); umount_grub_slice(mnted, mntpt, physlice, NULL, NULL); return; } if (stat(GRUB_backup_menu, &sb) != 0) { bam_error(MISSING_BACKUP_MENU, GRUB_backup_menu, strerror(errno)); umount_grub_slice(mnted, mntpt, physlice, NULL, NULL); return; } (void) snprintf(cmd, sizeof (cmd), "/bin/cp %s %s", GRUB_backup_menu, menupath); if (exec_cmd(cmd, NULL, 0) != 0) { bam_error(RESTORE_MENU_FAILED, menupath); umount_grub_slice(mnted, mntpt, physlice, NULL, NULL); return; } /* Success */ umount_grub_slice(mnted, mntpt, physlice, NULL, NULL); } static error_t update_all(char *root, char *opt) { struct extmnttab mnt; struct stat sb; FILE *fp; char multibt[PATH_MAX]; error_t ret = BAM_SUCCESS; int ret1, ret2; assert(root); assert(opt == NULL); if (bam_rootlen != 1 || *root != '/') { elide_trailing_slash(root, multibt, sizeof (multibt)); bam_error(ALT_ROOT_INVALID, multibt); return (BAM_ERROR); } /* * Check to see if we are in the midst of safemode patching * If so skip building the archive for /. Instead build it * against the latest bits obtained by creating a fresh lofs * mount of root. */ if (stat(LOFS_PATCH_FILE, &sb) == 0) { if (mkdir(LOFS_PATCH_MNT, 0755) == -1 && errno != EEXIST) { bam_error(MKDIR_FAILED, "%s", LOFS_PATCH_MNT, strerror(errno)); ret = BAM_ERROR; goto out; } (void) snprintf(multibt, sizeof (multibt), "/sbin/mount -F lofs -o nosub / %s", LOFS_PATCH_MNT); if (exec_cmd(multibt, NULL, 0) != 0) { bam_error(MOUNT_FAILED, LOFS_PATCH_MNT, "lofs"); ret = BAM_ERROR; } if (ret != BAM_ERROR) { (void) snprintf(rootbuf, sizeof (rootbuf), "%s/", LOFS_PATCH_MNT); bam_rootlen = strlen(rootbuf); if (update_archive(rootbuf, opt) != BAM_SUCCESS) ret = BAM_ERROR; } } else { /* * First update archive for current root */ if (update_archive(root, opt) != BAM_SUCCESS) ret = BAM_ERROR; } if (ret == BAM_ERROR) goto out; /* * Now walk the mount table, performing archive update * for all mounted Newboot root filesystems */ fp = fopen(MNTTAB, "r"); if (fp == NULL) { bam_error(OPEN_FAIL, MNTTAB, strerror(errno)); ret = BAM_ERROR; goto out; } resetmnttab(fp); while (getextmntent(fp, &mnt, sizeof (mnt)) == 0) { if (mnt.mnt_special == NULL) continue; if (strncmp(mnt.mnt_special, "/dev/", strlen("/dev/")) != 0) continue; if (strcmp(mnt.mnt_mountp, "/") == 0) continue; (void) snprintf(multibt, sizeof (multibt), "%s%s", mnt.mnt_mountp, MULTI_BOOT); if (stat(multibt, &sb) == -1) continue; /* * We put a trailing slash to be consistent with root = "/" * case, such that we don't have to print // in some cases. */ (void) snprintf(rootbuf, sizeof (rootbuf), "%s/", mnt.mnt_mountp); bam_rootlen = strlen(rootbuf); /* * It's possible that other mounts may be an alternate boot * architecture, so check it again. */ if ((dboot_or_multiboot(rootbuf) != BAM_SUCCESS) || (update_archive(rootbuf, opt) != BAM_SUCCESS)) ret = BAM_ERROR; } (void) fclose(fp); out: if (stat(GRUB_slice, &sb) == 0) { restore_grub_slice(); } /* * Update fdisk table as we go down. Updating it when * the system is running will confuse biosdev. */ ret1 = stat(GRUB_fdisk, &sb); ret2 = stat(GRUB_fdisk_target, &sb); if ((ret1 == 0) && (ret2 == 0)) { update_fdisk(); } else if ((ret1 == 0) ^ (ret2 == 0)) { /* * It is an error for one file to be * present and the other absent. * It is normal for both files to be * absent - it indicates that no fdisk * update is required. */ bam_error(MISSING_FDISK_FILE, ret1 ? GRUB_fdisk : GRUB_fdisk_target); ret = BAM_ERROR; } return (ret); } static void append_line(menu_t *mp, line_t *lp) { if (mp->start == NULL) { mp->start = lp; } else { mp->end->next = lp; lp->prev = mp->end; } mp->end = lp; } static void unlink_line(menu_t *mp, line_t *lp) { /* unlink from list */ if (lp->prev) lp->prev->next = lp->next; else mp->start = lp->next; if (lp->next) lp->next->prev = lp->prev; else mp->end = lp->prev; } static entry_t * boot_entry_new(menu_t *mp, line_t *start, line_t *end) { entry_t *ent, *prev; ent = s_calloc(1, sizeof (entry_t)); ent->start = start; ent->end = end; if (mp->entries == NULL) { mp->entries = ent; return (ent); } prev = mp->entries; while (prev->next) prev = prev-> next; prev->next = ent; ent->prev = prev; return (ent); } static void boot_entry_addline(entry_t *ent, line_t *lp) { if (ent) ent->end = lp; } /* * A line in menu.lst looks like * [ ]*[ \t=]** */ static void line_parser(menu_t *mp, char *str, int *lineNum, int *entryNum) { /* * save state across calls. This is so that * header gets the right entry# after title has * been processed */ static line_t *prev = NULL; static entry_t *curr_ent = NULL; static int in_liveupgrade = 0; line_t *lp; char *cmd, *sep, *arg; char save, *cp, *line; menu_flag_t flag = BAM_INVALID; if (str == NULL) { return; } /* * First save a copy of the entire line. * We use this later to set the line field. */ line = s_strdup(str); /* Eat up leading whitespace */ while (*str == ' ' || *str == '\t') str++; if (*str == '#') { /* comment */ cmd = s_strdup("#"); sep = NULL; arg = s_strdup(str + 1); flag = BAM_COMMENT; if (strstr(arg, BAM_LU_HDR) != NULL) { in_liveupgrade = 1; } else if (strstr(arg, BAM_LU_FTR) != NULL) { in_liveupgrade = 0; } } else if (*str == '\0') { /* blank line */ cmd = sep = arg = NULL; flag = BAM_EMPTY; } else { /* * '=' is not a documented separator in grub syntax. * However various development bits use '=' as a * separator. In addition, external users also * use = as a separator. So we will allow that usage. */ cp = str; while (*str != ' ' && *str != '\t' && *str != '=') { if (*str == '\0') { cmd = s_strdup(cp); sep = arg = NULL; break; } str++; } if (*str != '\0') { save = *str; *str = '\0'; cmd = s_strdup(cp); *str = save; str++; save = *str; *str = '\0'; sep = s_strdup(str - 1); *str = save; while (*str == ' ' || *str == '\t') str++; if (*str == '\0') arg = NULL; else arg = s_strdup(str); } } lp = s_calloc(1, sizeof (line_t)); lp->cmd = cmd; lp->sep = sep; lp->arg = arg; lp->line = line; lp->lineNum = ++(*lineNum); if (cmd && strcmp(cmd, menu_cmds[TITLE_CMD]) == 0) { lp->entryNum = ++(*entryNum); lp->flags = BAM_TITLE; if (prev && prev->flags == BAM_COMMENT && prev->arg && strcmp(prev->arg, BAM_BOOTADM_HDR) == 0) { prev->entryNum = lp->entryNum; curr_ent = boot_entry_new(mp, prev, lp); curr_ent->flags = BAM_ENTRY_BOOTADM; } else { curr_ent = boot_entry_new(mp, lp, lp); if (in_liveupgrade) { curr_ent->flags = BAM_ENTRY_LU; } } curr_ent->entryNum = *entryNum; } else if (flag != BAM_INVALID) { /* * For header comments, the entry# is "fixed up" * by the subsequent title */ lp->entryNum = *entryNum; lp->flags = flag; } else { lp->entryNum = *entryNum; if (*entryNum == ENTRY_INIT) { lp->flags = BAM_GLOBAL; } else { lp->flags = BAM_ENTRY; if (cmd && arg) { /* * We only compare for the length of "module" * so that "module$" will also match. */ if ((strncmp(cmd, menu_cmds[MODULE_CMD], strlen(menu_cmds[MODULE_CMD])) == 0) && (strcmp(arg, MINIROOT) == 0)) curr_ent->flags |= BAM_ENTRY_MINIROOT; else if (strcmp(cmd, menu_cmds[ROOT_CMD]) == 0) curr_ent->flags |= BAM_ENTRY_ROOT; else if (strcmp(cmd, menu_cmds[CHAINLOADER_CMD]) == 0) curr_ent->flags |= BAM_ENTRY_CHAINLOADER; } } } /* record default, old default, and entry line ranges */ if (lp->flags == BAM_GLOBAL && strcmp(lp->cmd, menu_cmds[DEFAULT_CMD]) == 0) { mp->curdefault = lp; } else if (lp->flags == BAM_COMMENT && strncmp(lp->arg, BAM_OLDDEF, strlen(BAM_OLDDEF)) == 0) { mp->olddefault = lp; } else if (lp->flags == BAM_COMMENT && strncmp(lp->arg, BAM_OLD_RC_DEF, strlen(BAM_OLD_RC_DEF)) == 0) { mp->old_rc_default = lp; } else if (lp->flags == BAM_ENTRY || (lp->flags == BAM_COMMENT && strcmp(lp->arg, BAM_BOOTADM_FTR) == 0)) { boot_entry_addline(curr_ent, lp); } append_line(mp, lp); prev = lp; } static void update_numbering(menu_t *mp) { int lineNum; int entryNum; int old_default_value; line_t *lp, *prev, *default_lp, *default_entry; char buf[PATH_MAX]; if (mp->start == NULL) { return; } lineNum = LINE_INIT; entryNum = ENTRY_INIT; old_default_value = ENTRY_INIT; lp = default_lp = default_entry = NULL; prev = NULL; for (lp = mp->start; lp; prev = lp, lp = lp->next) { lp->lineNum = ++lineNum; /* * Get the value of the default command */ if (lp->entryNum == ENTRY_INIT && lp->cmd && strcmp(lp->cmd, menu_cmds[DEFAULT_CMD]) == 0 && lp->arg) { old_default_value = atoi(lp->arg); default_lp = lp; } /* * If not boot entry, nothing else to fix for this * entry */ if (lp->entryNum == ENTRY_INIT) continue; /* * Record the position of the default entry. * The following works because global * commands like default and timeout should precede * actual boot entries, so old_default_value * is already known (or default cmd is missing). */ if (default_entry == NULL && old_default_value != ENTRY_INIT && lp->entryNum == old_default_value) { default_entry = lp; } /* * Now fixup the entry number */ if (lp->cmd && strcmp(lp->cmd, menu_cmds[TITLE_CMD]) == 0) { lp->entryNum = ++entryNum; /* fixup the bootadm header */ if (prev && prev->flags == BAM_COMMENT && prev->arg && strcmp(prev->arg, BAM_BOOTADM_HDR) == 0) { prev->entryNum = lp->entryNum; } } else { lp->entryNum = entryNum; } } /* * No default command in menu, simply return */ if (default_lp == NULL) { return; } free(default_lp->arg); free(default_lp->line); if (default_entry == NULL) { default_lp->arg = s_strdup("0"); } else { (void) snprintf(buf, sizeof (buf), "%d", default_entry->entryNum); default_lp->arg = s_strdup(buf); } /* * The following is required since only the line field gets * written back to menu.lst */ (void) snprintf(buf, sizeof (buf), "%s%s%s", menu_cmds[DEFAULT_CMD], menu_cmds[SEP_CMD], default_lp->arg); default_lp->line = s_strdup(buf); } static menu_t * menu_read(char *menu_path) { FILE *fp; char buf[BAM_MAXLINE], *cp; menu_t *mp; int line, entry, len, n; mp = s_calloc(1, sizeof (menu_t)); fp = fopen(menu_path, "r"); if (fp == NULL) { /* Let the caller handle this error */ return (mp); } /* Note: GRUB boot entry number starts with 0 */ line = LINE_INIT; entry = ENTRY_INIT; cp = buf; len = sizeof (buf); while (s_fgets(cp, len, fp) != NULL) { n = strlen(cp); if (cp[n - 1] == '\\') { len -= n - 1; assert(len >= 2); cp += n - 1; continue; } line_parser(mp, buf, &line, &entry); cp = buf; len = sizeof (buf); } if (fclose(fp) == EOF) { bam_error(CLOSE_FAIL, menu_path, strerror(errno)); } return (mp); } static error_t selector(menu_t *mp, char *opt, int *entry, char **title) { char *eq; char *opt_dup; int entryNum; assert(mp); assert(mp->start); assert(opt); opt_dup = s_strdup(opt); if (entry) *entry = ENTRY_INIT; if (title) *title = NULL; eq = strchr(opt_dup, '='); if (eq == NULL) { bam_error(INVALID_OPT, opt); free(opt_dup); return (BAM_ERROR); } *eq = '\0'; if (entry && strcmp(opt_dup, OPT_ENTRY_NUM) == 0) { assert(mp->end); entryNum = s_strtol(eq + 1); if (entryNum < 0 || entryNum > mp->end->entryNum) { bam_error(INVALID_ENTRY, eq + 1); free(opt_dup); return (BAM_ERROR); } *entry = entryNum; } else if (title && strcmp(opt_dup, menu_cmds[TITLE_CMD]) == 0) { *title = opt + (eq - opt_dup) + 1; } else { bam_error(INVALID_OPT, opt); free(opt_dup); return (BAM_ERROR); } free(opt_dup); return (BAM_SUCCESS); } /* * If invoked with no titles/entries (opt == NULL) * only title lines in file are printed. * * If invoked with a title or entry #, all * lines in *every* matching entry are listed */ static error_t list_entry(menu_t *mp, char *menu_path, char *opt) { line_t *lp; int entry = ENTRY_INIT; int found; char *title = NULL; assert(mp); assert(menu_path); if (mp->start == NULL) { bam_error(NO_MENU, menu_path); return (BAM_ERROR); } if (opt != NULL) { if (selector(mp, opt, &entry, &title) != BAM_SUCCESS) { return (BAM_ERROR); } assert((entry != ENTRY_INIT) ^ (title != NULL)); } else { (void) read_globals(mp, menu_path, menu_cmds[DEFAULT_CMD], 0); (void) read_globals(mp, menu_path, menu_cmds[TIMEOUT_CMD], 0); } found = 0; for (lp = mp->start; lp; lp = lp->next) { if (lp->flags == BAM_COMMENT || lp->flags == BAM_EMPTY) continue; if (opt == NULL && lp->flags == BAM_TITLE) { bam_print(PRINT_TITLE, lp->entryNum, lp->arg); found = 1; continue; } if (entry != ENTRY_INIT && lp->entryNum == entry) { bam_print(PRINT, lp->line); found = 1; continue; } /* * We set the entry value here so that all lines * in entry get printed. If we subsequently match * title in other entries, all lines in those * entries get printed as well. */ if (title && lp->flags == BAM_TITLE && lp->arg && strncmp(title, lp->arg, strlen(title)) == 0) { bam_print(PRINT, lp->line); entry = lp->entryNum; found = 1; continue; } } if (!found) { bam_error(NO_MATCH_ENTRY); return (BAM_ERROR); } return (BAM_SUCCESS); } static int add_boot_entry(menu_t *mp, char *title, char *root, char *kernel, char *module) { int lineNum, entryNum; char linebuf[BAM_MAXLINE]; menu_cmd_t k_cmd, m_cmd; assert(mp); if (title == NULL) { title = "Solaris"; /* default to Solaris */ } if (kernel == NULL) { bam_error(SUBOPT_MISS, menu_cmds[KERNEL_CMD]); return (BAM_ERROR); } if (module == NULL) { if (bam_direct != BAM_DIRECT_DBOOT) { bam_error(SUBOPT_MISS, menu_cmds[MODULE_CMD]); return (BAM_ERROR); } /* Figure the commands out from the kernel line */ if (strstr(kernel, "$ISADIR") != NULL) { module = DIRECT_BOOT_ARCHIVE; k_cmd = KERNEL_DOLLAR_CMD; m_cmd = MODULE_DOLLAR_CMD; } else if (strstr(kernel, "amd64") != NULL) { module = DIRECT_BOOT_ARCHIVE_64; k_cmd = KERNEL_CMD; m_cmd = MODULE_CMD; } else { module = DIRECT_BOOT_ARCHIVE_32; k_cmd = KERNEL_CMD; m_cmd = MODULE_CMD; } } else if ((bam_direct == BAM_DIRECT_DBOOT) && (strstr(kernel, "$ISADIR") != NULL)) { /* * If it's a non-failsafe dboot kernel, use the "kernel$" * command. Otherwise, use "kernel". */ k_cmd = KERNEL_DOLLAR_CMD; m_cmd = MODULE_DOLLAR_CMD; } else { k_cmd = KERNEL_CMD; m_cmd = MODULE_CMD; } if (mp->start) { lineNum = mp->end->lineNum; entryNum = mp->end->entryNum; } else { lineNum = LINE_INIT; entryNum = ENTRY_INIT; } /* * No separator for comment (HDR/FTR) commands * The syntax for comments is # */ (void) snprintf(linebuf, sizeof (linebuf), "%s%s", menu_cmds[COMMENT_CMD], BAM_BOOTADM_HDR); line_parser(mp, linebuf, &lineNum, &entryNum); (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[TITLE_CMD], menu_cmds[SEP_CMD], title); line_parser(mp, linebuf, &lineNum, &entryNum); if (root) { (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[ROOT_CMD], menu_cmds[SEP_CMD], root); line_parser(mp, linebuf, &lineNum, &entryNum); } (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[k_cmd], menu_cmds[SEP_CMD], kernel); line_parser(mp, linebuf, &lineNum, &entryNum); (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[m_cmd], menu_cmds[SEP_CMD], module); line_parser(mp, linebuf, &lineNum, &entryNum); (void) snprintf(linebuf, sizeof (linebuf), "%s%s", menu_cmds[COMMENT_CMD], BAM_BOOTADM_FTR); line_parser(mp, linebuf, &lineNum, &entryNum); return (entryNum); } static error_t do_delete(menu_t *mp, int entryNum) { line_t *lp, *freed; entry_t *ent, *tmp; int deleted; assert(entryNum != ENTRY_INIT); ent = mp->entries; while (ent) { lp = ent->start; /* check entry number and make sure it's a bootadm entry */ if (lp->flags != BAM_COMMENT || strcmp(lp->arg, BAM_BOOTADM_HDR) != 0 || (entryNum != ALL_ENTRIES && lp->entryNum != entryNum)) { ent = ent->next; continue; } /* free the entry content */ do { freed = lp; lp = lp->next; /* prev stays the same */ unlink_line(mp, freed); line_free(freed); } while (freed != ent->end); /* free the entry_t structure */ tmp = ent; ent = ent->next; if (tmp->prev) tmp->prev->next = ent; else mp->entries = ent; if (ent) ent->prev = tmp->prev; deleted = 1; } if (!deleted && entryNum != ALL_ENTRIES) { bam_error(NO_BOOTADM_MATCH); return (BAM_ERROR); } /* * Now that we have deleted an entry, update * the entry numbering and the default cmd. */ update_numbering(mp); return (BAM_SUCCESS); } static error_t delete_all_entries(menu_t *mp, char *menu_path, char *opt) { assert(mp); assert(opt == NULL); if (mp->start == NULL) { bam_print(EMPTY_FILE, menu_path); return (BAM_SUCCESS); } if (do_delete(mp, ALL_ENTRIES) != BAM_SUCCESS) { return (BAM_ERROR); } return (BAM_WRITE); } static FILE * open_diskmap(char *root) { FILE *fp; char cmd[PATH_MAX]; /* make sure we have a map file */ fp = fopen(GRUBDISK_MAP, "r"); if (fp == NULL) { (void) snprintf(cmd, sizeof (cmd), "%s%s > /dev/null", root, CREATE_DISKMAP); (void) system(cmd); fp = fopen(GRUBDISK_MAP, "r"); } return (fp); } #define SECTOR_SIZE 512 static int get_partition(char *device) { int i, fd, is_pcfs, partno = -1; struct mboot *mboot; char boot_sect[SECTOR_SIZE]; char *wholedisk, *slice; /* form whole disk (p0) */ slice = device + strlen(device) - 2; is_pcfs = (*slice != 's'); if (!is_pcfs) *slice = '\0'; wholedisk = s_calloc(1, strlen(device) + 3); (void) snprintf(wholedisk, strlen(device) + 3, "%sp0", device); if (!is_pcfs) *slice = 's'; /* read boot sector */ fd = open(wholedisk, O_RDONLY); free(wholedisk); if (fd == -1 || read(fd, boot_sect, SECTOR_SIZE) != SECTOR_SIZE) { return (partno); } (void) close(fd); /* parse fdisk table */ mboot = (struct mboot *)((void *)boot_sect); for (i = 0; i < FD_NUMPART; i++) { struct ipart *part = (struct ipart *)(uintptr_t)mboot->parts + i; if (is_pcfs) { /* looking for solaris boot part */ if (part->systid == 0xbe) { partno = i; break; } } else { /* look for solaris partition, old and new */ if (part->systid == SUNIXOS || part->systid == SUNIXOS2) { partno = i; break; } } } return (partno); } static char * get_grubdisk(char *rootdev, FILE *fp, int on_bootdev) { char *grubdisk; /* (hd#,#,#) */ char *slice; char *grubhd; int fdiskpart; int found = 0; char *devname, *ctdname = strstr(rootdev, "dsk/"); char linebuf[PATH_MAX]; if (ctdname == NULL) return (NULL); ctdname += strlen("dsk/"); slice = strrchr(ctdname, 's'); if (slice) *slice = '\0'; rewind(fp); while (s_fgets(linebuf, sizeof (linebuf), fp) != NULL) { grubhd = strtok(linebuf, " \t\n"); if (grubhd) devname = strtok(NULL, " \t\n"); else devname = NULL; if (devname && strcmp(devname, ctdname) == 0) { found = 1; break; } } if (slice) *slice = 's'; if (found == 0) { if (bam_verbose) bam_print(DISKMAP_FAIL_NONFATAL, rootdev); grubhd = "0"; /* assume disk 0 if can't match */ } fdiskpart = get_partition(rootdev); if (fdiskpart == -1) return (NULL); grubdisk = s_calloc(1, 10); if (slice) { (void) snprintf(grubdisk, 10, "(hd%s,%d,%c)", grubhd, fdiskpart, slice[1] + 'a' - '0'); } else (void) snprintf(grubdisk, 10, "(hd%s,%d)", grubhd, fdiskpart); /* if root not on bootdev, change GRUB disk to 0 */ if (!on_bootdev) grubdisk[3] = '0'; return (grubdisk); } static char * get_title(char *rootdir) { static char title[80]; /* from /etc/release */ char *cp = NULL, release[PATH_MAX]; FILE *fp; /* open the /etc/release file */ (void) snprintf(release, sizeof (release), "%s/etc/release", rootdir); fp = fopen(release, "r"); if (fp == NULL) return (NULL); while (s_fgets(title, sizeof (title), fp) != NULL) { cp = strstr(title, "Solaris"); if (cp) break; } (void) fclose(fp); return (cp == NULL ? "Solaris" : cp); } char * get_special(char *mountp) { FILE *mntfp; struct mnttab mp = {0}, mpref = {0}; mntfp = fopen(MNTTAB, "r"); if (mntfp == NULL) { return (0); } if (*mountp == '\0') mpref.mnt_mountp = "/"; else mpref.mnt_mountp = mountp; if (getmntany(mntfp, &mp, &mpref) != 0) { (void) fclose(mntfp); return (NULL); } (void) fclose(mntfp); return (s_strdup(mp.mnt_special)); } char * os_to_grubdisk(char *osdisk, int on_bootdev) { FILE *fp; char *grubdisk; /* translate /dev/dsk name to grub disk name */ fp = open_diskmap(""); if (fp == NULL) { bam_error(DISKMAP_FAIL, osdisk); return (NULL); } grubdisk = get_grubdisk(osdisk, fp, on_bootdev); (void) fclose(fp); return (grubdisk); } /* * Check if root is on the boot device * Return 0 (false) on error */ static int menu_on_bootdev(char *menu_root, FILE *fp) { int ret; char *grubhd, *bootp, *special; special = get_special(menu_root); if (special == NULL) return (0); bootp = strstr(special, "p0:boot"); if (bootp) *bootp = '\0'; grubhd = get_grubdisk(special, fp, 1); free(special); if (grubhd == NULL) return (0); ret = grubhd[3] == '0'; free(grubhd); return (ret); } /* * look for matching bootadm entry with specified parameters * Here are the rules (based on existing usage): * - If title is specified, match on title only * - Else, match on grubdisk and module (don't care about kernel line). * note that, if root_opt is non-zero, the absence of root line is * considered a match. */ static entry_t * find_boot_entry(menu_t *mp, char *title, char *root, char *module, int root_opt, int *entry_num) { int i; line_t *lp; entry_t *ent; /* find matching entry */ for (i = 0, ent = mp->entries; ent; i++, ent = ent->next) { lp = ent->start; /* first line of entry must be bootadm comment */ lp = ent->start; if (lp->flags != BAM_COMMENT || strcmp(lp->arg, BAM_BOOTADM_HDR) != 0) { continue; } /* advance to title line */ lp = lp->next; if (title) { if (lp->flags == BAM_TITLE && lp->arg && strcmp(lp->arg, title) == 0) break; continue; /* check title only */ } lp = lp->next; /* advance to root line */ if (lp == NULL || strcmp(lp->cmd, menu_cmds[ROOT_CMD]) == 0) { /* root command found, match grub disk */ if (strcmp(lp->arg, root) != 0) { continue; } lp = lp->next; /* advance to kernel line */ } else { /* no root command, see if root is optional */ if (root_opt == 0) { continue; } } if (lp == NULL || lp->next == NULL) { continue; } /* * Check for matching module entry (failsafe or normal). We * use a strncmp to match "module" or "module$", since we * don't know which one it should be. If it fails to match, * we go around the loop again. */ lp = lp->next; /* advance to module line */ if ((strncmp(lp->cmd, menu_cmds[MODULE_CMD], strlen(menu_cmds[MODULE_CMD])) != 0) || (strcmp(lp->arg, module) != 0)) { continue; } break; /* match found */ } *entry_num = i; return (ent); } static int update_boot_entry(menu_t *mp, char *title, char *root, char *kernel, char *module, int root_opt) { int i, change_kernel = 0; entry_t *ent; line_t *lp; char linebuf[BAM_MAXLINE]; /* note: don't match on title, it's updated on upgrade */ ent = find_boot_entry(mp, NULL, root, module, root_opt, &i); if ((ent == NULL) && (bam_direct == BAM_DIRECT_DBOOT)) { /* * We may be upgrading a kernel from multiboot to * directboot. Look for a multiboot entry. */ ent = find_boot_entry(mp, NULL, root, MULTI_BOOT_ARCHIVE, root_opt, &i); if (ent != NULL) { change_kernel = 1; } } if (ent == NULL) return (add_boot_entry(mp, title, root_opt ? NULL : root, kernel, module)); /* replace title of exiting entry and delete root line */ lp = ent->start; lp = lp->next; /* title line */ (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[TITLE_CMD], menu_cmds[SEP_CMD], title); free(lp->arg); free(lp->line); lp->arg = s_strdup(title); lp->line = s_strdup(linebuf); lp = lp->next; /* root line */ if (strcmp(lp->cmd, menu_cmds[ROOT_CMD]) == 0) { if (root_opt) { /* root line not needed */ line_t *tmp = lp; lp = lp->next; unlink_line(mp, tmp); line_free(tmp); } else lp = lp->next; } if (change_kernel) { /* * We're upgrading from multiboot to directboot. */ if (strcmp(lp->cmd, menu_cmds[KERNEL_CMD]) == 0) { (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[KERNEL_DOLLAR_CMD], menu_cmds[SEP_CMD], kernel); free(lp->arg); free(lp->line); lp->arg = s_strdup(kernel); lp->line = s_strdup(linebuf); lp = lp->next; } if (strcmp(lp->cmd, menu_cmds[MODULE_CMD]) == 0) { (void) snprintf(linebuf, sizeof (linebuf), "%s%s%s", menu_cmds[MODULE_DOLLAR_CMD], menu_cmds[SEP_CMD], module); free(lp->arg); free(lp->line); lp->arg = s_strdup(module); lp->line = s_strdup(linebuf); lp = lp->next; } } return (i); } /*ARGSUSED*/ static error_t update_entry(menu_t *mp, char *menu_root, char *opt) { FILE *fp; int entry; char *grubdisk, *title, *osdev, *osroot, *failsafe_kernel = NULL; struct stat sbuf; char failsafe[256]; assert(mp); assert(opt); osdev = strtok(opt, ","); osroot = strtok(NULL, ","); if (osroot == NULL) osroot = menu_root; title = get_title(osroot); /* translate /dev/dsk name to grub disk name */ fp = open_diskmap(osroot); if (fp == NULL) { bam_error(DISKMAP_FAIL, osdev); return (BAM_ERROR); } grubdisk = get_grubdisk(osdev, fp, menu_on_bootdev(menu_root, fp)); (void) fclose(fp); if (grubdisk == NULL) { bam_error(DISKMAP_FAIL, osdev); return (BAM_ERROR); } /* add the entry for normal Solaris */ if (bam_direct == BAM_DIRECT_DBOOT) { entry = update_boot_entry(mp, title, grubdisk, DIRECT_BOOT_KERNEL, DIRECT_BOOT_ARCHIVE, osroot == menu_root); } else { entry = update_boot_entry(mp, title, grubdisk, MULTI_BOOT, MULTI_BOOT_ARCHIVE, osroot == menu_root); } /* add the entry for failsafe archive */ (void) snprintf(failsafe, sizeof (failsafe), "%s%s", osroot, MINIROOT); if (stat(failsafe, &sbuf) == 0) { /* Figure out where the kernel line should point */ (void) snprintf(failsafe, sizeof (failsafe), "%s%s", osroot, DIRECT_BOOT_FAILSAFE_KERNEL); if (stat(failsafe, &sbuf) == 0) { failsafe_kernel = DIRECT_BOOT_FAILSAFE_LINE; } else { (void) snprintf(failsafe, sizeof (failsafe), "%s%s", osroot, MULTI_BOOT_FAILSAFE); if (stat(failsafe, &sbuf) == 0) { failsafe_kernel = MULTI_BOOT_FAILSAFE_LINE; } } if (failsafe_kernel != NULL) { (void) update_boot_entry(mp, FAILSAFE_TITLE, grubdisk, failsafe_kernel, MINIROOT, osroot == menu_root); } else { bam_error(NO_FAILSAFE_KERNEL); } } free(grubdisk); if (entry == BAM_ERROR) { return (BAM_ERROR); } (void) set_global(mp, menu_cmds[DEFAULT_CMD], entry); return (BAM_WRITE); } static char * read_grub_root(void) { FILE *fp; struct stat sb; char buf[BAM_MAXLINE]; char *rootstr; if (stat(GRUB_slice, &sb) != 0) { bam_error(MISSING_SLICE_FILE, GRUB_slice, strerror(errno)); return (NULL); } if (stat(GRUB_root, &sb) != 0) { bam_error(MISSING_ROOT_FILE, GRUB_root, strerror(errno)); return (NULL); } fp = fopen(GRUB_root, "r"); if (fp == NULL) { bam_error(OPEN_FAIL, GRUB_root, strerror(errno)); return (NULL); } if (s_fgets(buf, sizeof (buf), fp) == NULL) { bam_error(EMPTY_FILE, GRUB_root, strerror(errno)); (void) fclose(fp); return (NULL); } /* * Copy buf here as check below may trash the buffer */ rootstr = s_strdup(buf); if (s_fgets(buf, sizeof (buf), fp) != NULL) { bam_error(BAD_ROOT_FILE, GRUB_root); free(rootstr); rootstr = NULL; } (void) fclose(fp); return (rootstr); } static void save_default_entry(menu_t *mp, const char *which) { int lineNum, entryNum; int entry = 0; /* default is 0 */ char linebuf[BAM_MAXLINE]; line_t *lp = mp->curdefault; if (mp->start) { lineNum = mp->end->lineNum; entryNum = mp->end->entryNum; } else { lineNum = LINE_INIT; entryNum = ENTRY_INIT; } if (lp) entry = s_strtol(lp->arg); (void) snprintf(linebuf, sizeof (linebuf), "#%s%d", which, entry); line_parser(mp, linebuf, &lineNum, &entryNum); } static void restore_default_entry(menu_t *mp, const char *which, line_t *lp) { int entry; char *str; if (lp == NULL) return; /* nothing to restore */ str = lp->arg + strlen(which); entry = s_strtol(str); (void) set_global(mp, menu_cmds[DEFAULT_CMD], entry); /* delete saved old default line */ unlink_line(mp, lp); line_free(lp); } /* * This function is for supporting reboot with args. * The opt value can be: * NULL delete temp entry, if present * entry=# switches default entry to 1 * else treated as boot-args and setup a temperary menu entry * and make it the default */ #define REBOOT_TITLE "Solaris_reboot_transient" /*ARGSUSED*/ static error_t update_temp(menu_t *mp, char *menupath, char *opt) { int entry; char *grubdisk, *rootdev, *path, *opt_ptr; char kernbuf[BUFSIZ]; char args_buf[BUFSIZ]; struct stat sb; assert(mp); /* If no option, delete exiting reboot menu entry */ if (opt == NULL) { entry_t *ent = find_boot_entry(mp, REBOOT_TITLE, NULL, NULL, 0, &entry); if (ent == NULL) /* not found is ok */ return (BAM_SUCCESS); (void) do_delete(mp, entry); restore_default_entry(mp, BAM_OLDDEF, mp->olddefault); mp->olddefault = NULL; return (BAM_WRITE); } /* if entry= is specified, set the default entry */ if (strncmp(opt, "entry=", strlen("entry=")) == 0 && selector(mp, opt, &entry, NULL) == BAM_SUCCESS) { /* this is entry=# option */ return (set_global(mp, menu_cmds[DEFAULT_CMD], entry)); } /* * add a new menu entry base on opt and make it the default */ grubdisk = NULL; if (stat(GRUB_slice, &sb) != 0) { /* * 1. First get root disk name from mnttab * 2. Translate disk name to grub name * 3. Add the new menu entry */ rootdev = get_special("/"); if (rootdev) { grubdisk = os_to_grubdisk(rootdev, 1); free(rootdev); } } else { /* * This is an LU BE. The GRUB_root file * contains entry for GRUB's "root" cmd. */ grubdisk = read_grub_root(); } if (grubdisk == NULL) { bam_error(REBOOT_WITH_ARGS_FAILED); return (BAM_ERROR); } /* add an entry for Solaris reboot */ if (bam_direct == BAM_DIRECT_DBOOT) { if (opt[0] == '-') { /* It's an option - first see if boot-file is set */ if (set_kernel(mp, KERNEL_CMD, NULL, kernbuf, BUFSIZ) != BAM_SUCCESS) return (BAM_ERROR); if (kernbuf[0] == '\0') (void) strncpy(kernbuf, DIRECT_BOOT_KERNEL, BUFSIZ); (void) strlcat(kernbuf, " ", BUFSIZ); (void) strlcat(kernbuf, opt, BUFSIZ); } else if (opt[0] == '/') { /* It's a full path, so write it out. */ (void) strlcpy(kernbuf, opt, BUFSIZ); /* * If someone runs: * * # eeprom boot-args='-kd' * # reboot /platform/i86pc/kernel/unix * * we want to use the boot-args as part of the boot * line. On the other hand, if someone runs: * * # reboot "/platform/i86pc/kernel/unix -kd" * * we don't need to mess with boot-args. If there's * no space in the options string, assume we're in the * first case. */ if (strchr(opt, ' ') == NULL) { if (set_kernel(mp, ARGS_CMD, NULL, args_buf, BUFSIZ) != BAM_SUCCESS) return (BAM_ERROR); if (args_buf[0] != '\0') { (void) strlcat(kernbuf, " ", BUFSIZ); (void) strlcat(kernbuf, args_buf, BUFSIZ); } } } else { /* * It may be a partial path, or it may be a partial * path followed by options. Assume that only options * follow a space. If someone sends us a kernel path * that includes a space, they deserve to be broken. */ opt_ptr = strchr(opt, ' '); if (opt_ptr != NULL) { *opt_ptr = '\0'; } path = expand_path(opt); if (path != NULL) { (void) strlcpy(kernbuf, path, BUFSIZ); free(path); /* * If there were options given, use those. * Otherwise, copy over the default options. */ if (opt_ptr != NULL) { /* Restore the space in opt string */ *opt_ptr = ' '; (void) strlcat(kernbuf, opt_ptr, BUFSIZ); } else { if (set_kernel(mp, ARGS_CMD, NULL, args_buf, BUFSIZ) != BAM_SUCCESS) return (BAM_ERROR); if (args_buf[0] != '\0') { (void) strlcat(kernbuf, " ", BUFSIZ); (void) strlcat(kernbuf, args_buf, BUFSIZ); } } } else { bam_error(UNKNOWN_KERNEL, opt); bam_print_stderr(UNKNOWN_KERNEL_REBOOT); return (BAM_ERROR); } } entry = add_boot_entry(mp, REBOOT_TITLE, grubdisk, kernbuf, NULL); } else { (void) snprintf(kernbuf, sizeof (kernbuf), "%s %s", MULTI_BOOT, opt); entry = add_boot_entry(mp, REBOOT_TITLE, grubdisk, kernbuf, MULTI_BOOT_ARCHIVE); } free(grubdisk); if (entry == BAM_ERROR) { bam_error(REBOOT_WITH_ARGS_FAILED); return (BAM_ERROR); } save_default_entry(mp, BAM_OLDDEF); (void) set_global(mp, menu_cmds[DEFAULT_CMD], entry); return (BAM_WRITE); } static error_t set_global(menu_t *mp, char *globalcmd, int val) { line_t *lp, *found, *last; char *cp, *str; char prefix[BAM_MAXLINE]; size_t len; assert(mp); assert(globalcmd); if (strcmp(globalcmd, menu_cmds[DEFAULT_CMD]) == 0) { if (val < 0 || mp->end == NULL || val > mp->end->entryNum) { (void) snprintf(prefix, sizeof (prefix), "%d", val); bam_error(INVALID_ENTRY, prefix); return (BAM_ERROR); } } found = last = NULL; for (lp = mp->start; lp; lp = lp->next) { if (lp->flags != BAM_GLOBAL) continue; last = lp; /* track the last global found */ if (lp->cmd == NULL) { bam_error(NO_CMD, lp->lineNum); continue; } if (strcmp(globalcmd, lp->cmd) != 0) continue; if (found) { bam_error(DUP_CMD, globalcmd, lp->lineNum, bam_root); } found = lp; } if (found == NULL) { lp = s_calloc(1, sizeof (line_t)); if (last == NULL) { lp->next = mp->start; mp->start = lp; mp->end = (mp->end) ? mp->end : lp; } else { lp->next = last->next; last->next = lp; if (lp->next == NULL) mp->end = lp; } lp->flags = BAM_GLOBAL; /* other fields not needed for writes */ len = strlen(globalcmd) + strlen(menu_cmds[SEP_CMD]); len += 10; /* val < 10 digits */ lp->line = s_calloc(1, len); (void) snprintf(lp->line, len, "%s%s%d", globalcmd, menu_cmds[SEP_CMD], val); return (BAM_WRITE); } /* * We are changing an existing entry. Retain any prefix whitespace, * but overwrite everything else. This preserves tabs added for * readability. */ str = found->line; cp = prefix; while (*str == ' ' || *str == '\t') *(cp++) = *(str++); *cp = '\0'; /* Terminate prefix */ len = strlen(prefix) + strlen(globalcmd); len += strlen(menu_cmds[SEP_CMD]) + 10; free(found->line); found->line = s_calloc(1, len); (void) snprintf(found->line, len, "%s%s%s%d", prefix, globalcmd, menu_cmds[SEP_CMD], val); return (BAM_WRITE); /* need a write to menu */ } /* * partial_path may be anything like "kernel/unix" or "kmdb". Try to * expand it to a full unix path. The calling function is expected to * output a message if an error occurs and NULL is returned. */ static char * expand_path(const char *partial_path) { int new_path_len; char *new_path, new_path2[PATH_MAX]; struct stat sb; new_path_len = strlen(partial_path) + 64; new_path = s_calloc(1, new_path_len); /* First, try the simplest case - something like "kernel/unix" */ (void) snprintf(new_path, new_path_len, "/platform/i86pc/%s", partial_path); if (stat(new_path, &sb) == 0) { return (new_path); } if (strcmp(partial_path, "kmdb") == 0) { (void) snprintf(new_path, new_path_len, "%s -k", DIRECT_BOOT_KERNEL); return (new_path); } /* * We've quickly reached unsupported usage. Try once more to * see if we were just given a glom name. */ (void) snprintf(new_path, new_path_len, "/platform/i86pc/%s/unix", partial_path); (void) snprintf(new_path2, PATH_MAX, "/platform/i86pc/%s/amd64/unix", partial_path); if (stat(new_path, &sb) == 0) { if (stat(new_path2, &sb) == 0) { /* * We matched both, so we actually * want to write the $ISADIR version. */ (void) snprintf(new_path, new_path_len, "/platform/i86pc/kernel/%s/$ISADIR/unix", partial_path); } return (new_path); } free(new_path); return (NULL); } /* * The kernel cmd and arg have been changed, so * check whether the archive line needs to change. */ static void set_archive_line(entry_t *entryp, line_t *kernelp) { line_t *lp = entryp->start; char *new_archive; menu_cmd_t m_cmd; for (; lp != NULL; lp = lp->next) { if (strncmp(lp->cmd, menu_cmds[MODULE_CMD], sizeof (menu_cmds[MODULE_CMD]) - 1) == 0) { break; } if (lp == entryp->end) return; } if (lp == NULL) return; if (strstr(kernelp->arg, "$ISADIR") != NULL) { new_archive = DIRECT_BOOT_ARCHIVE; m_cmd = MODULE_DOLLAR_CMD; } else if (strstr(kernelp->arg, "amd64") != NULL) { new_archive = DIRECT_BOOT_ARCHIVE_64; m_cmd = MODULE_CMD; } else { new_archive = DIRECT_BOOT_ARCHIVE_32; m_cmd = MODULE_CMD; } if (strcmp(lp->arg, new_archive) == 0) return; if (strcmp(lp->cmd, menu_cmds[m_cmd]) != 0) { free(lp->cmd); lp->cmd = s_strdup(menu_cmds[m_cmd]); } free(lp->arg); lp->arg = s_strdup(new_archive); update_line(lp); } /* * Title for an entry to set properties that once went in bootenv.rc. */ #define BOOTENV_RC_TITLE "Solaris bootenv rc" /* * If path is NULL, return the kernel (optnum == KERNEL_CMD) or arguments * (optnum == ARGS_CMD) in the argument buf. If path is a zero-length * string, reset the value to the default. If path is a non-zero-length * string, set the kernel or arguments. */ static error_t set_kernel(menu_t *mp, menu_cmd_t optnum, char *path, char *buf, size_t bufsize) { int entryNum, rv = BAM_SUCCESS, free_new_path = 0; entry_t *entryp; line_t *ptr, *kernelp; char *new_arg, *old_args, *space; char *grubdisk, *rootdev, *new_path; char old_space; size_t old_kernel_len, new_str_len; struct stat sb; assert(bufsize > 0); ptr = kernelp = NULL; new_arg = old_args = space = NULL; grubdisk = rootdev = new_path = NULL; buf[0] = '\0'; if (bam_direct != BAM_DIRECT_DBOOT) { bam_error(NOT_DBOOT, optnum == KERNEL_CMD ? "kernel" : "args"); return (BAM_ERROR); } /* * If a user changed the default entry to a non-bootadm controlled * one, we don't want to mess with it. Just print an error and * return. */ if (mp->curdefault) { entryNum = s_strtol(mp->curdefault->arg); for (entryp = mp->entries; entryp; entryp = entryp->next) { if (entryp->entryNum == entryNum) break; } if ((entryp != NULL) && ((entryp->flags & (BAM_ENTRY_BOOTADM|BAM_ENTRY_LU)) == 0)) { bam_error(DEFAULT_NOT_BAM); return (BAM_ERROR); } } entryNum = -1; entryp = find_boot_entry(mp, BOOTENV_RC_TITLE, NULL, NULL, 0, &entryNum); if (entryp != NULL) { for (ptr = entryp->start; ptr && ptr != entryp->end; ptr = ptr->next) { if (strncmp(ptr->cmd, menu_cmds[KERNEL_CMD], sizeof (menu_cmds[KERNEL_CMD]) - 1) == 0) { kernelp = ptr; break; } } if (kernelp == NULL) { bam_error(NO_KERNEL, entryNum); return (BAM_ERROR); } old_kernel_len = strcspn(kernelp->arg, " \t"); space = old_args = kernelp->arg + old_kernel_len; while ((*old_args == ' ') || (*old_args == '\t')) old_args++; } if (path == NULL) { /* Simply report what was found */ if (kernelp == NULL) return (BAM_SUCCESS); if (optnum == ARGS_CMD) { if (old_args[0] != '\0') (void) strlcpy(buf, old_args, bufsize); } else { /* * We need to print the kernel, so we just turn the * first space into a '\0' and print the beginning. * We don't print anything if it's the default kernel. */ old_space = *space; *space = '\0'; if (strcmp(kernelp->arg, DIRECT_BOOT_KERNEL) != 0) (void) strlcpy(buf, kernelp->arg, bufsize); *space = old_space; } return (BAM_SUCCESS); } /* * First, check if we're resetting an entry to the default. */ if ((path[0] == '\0') || ((optnum == KERNEL_CMD) && (strcmp(path, DIRECT_BOOT_KERNEL) == 0))) { if ((entryp == NULL) || (kernelp == NULL)) { /* No previous entry, it's already the default */ return (BAM_SUCCESS); } /* * Check if we can delete the entry. If we're resetting the * kernel command, and the args is already empty, or if we're * resetting the args command, and the kernel is already the * default, we can restore the old default and delete the entry. */ if (((optnum == KERNEL_CMD) && ((old_args == NULL) || (old_args[0] == '\0'))) || ((optnum == ARGS_CMD) && (strncmp(kernelp->arg, DIRECT_BOOT_KERNEL, sizeof (DIRECT_BOOT_KERNEL) - 1) == 0))) { kernelp = NULL; (void) do_delete(mp, entryNum); restore_default_entry(mp, BAM_OLD_RC_DEF, mp->old_rc_default); mp->old_rc_default = NULL; rv = BAM_WRITE; goto done; } if (optnum == KERNEL_CMD) { /* * At this point, we've already checked that old_args * and entryp are valid pointers. The "+ 2" is for * a space a the string termination character. */ new_str_len = (sizeof (DIRECT_BOOT_KERNEL) - 1) + strlen(old_args) + 2; new_arg = s_calloc(1, new_str_len); (void) snprintf(new_arg, new_str_len, "%s %s", DIRECT_BOOT_KERNEL, old_args); free(kernelp->arg); kernelp->arg = new_arg; /* * We have changed the kernel line, so we may need * to update the archive line as well. */ set_archive_line(entryp, kernelp); } else { /* * We're resetting the boot args to nothing, so * we only need to copy the kernel. We've already * checked that the kernel is not the default. */ new_arg = s_calloc(1, old_kernel_len + 1); (void) snprintf(new_arg, old_kernel_len + 1, "%s", kernelp->arg); free(kernelp->arg); kernelp->arg = new_arg; } rv = BAM_WRITE; goto done; } /* * Expand the kernel file to a full path, if necessary */ if ((optnum == KERNEL_CMD) && (path[0] != '/')) { new_path = expand_path(path); if (new_path == NULL) { bam_error(UNKNOWN_KERNEL, path); return (BAM_ERROR); } free_new_path = 1; } else { new_path = path; free_new_path = 0; } /* * At this point, we know we're setting a new value. First, take care * of the case where there was no previous entry. */ if (entryp == NULL) { /* Similar to code in update_temp */ if (stat(GRUB_slice, &sb) != 0) { /* * 1. First get root disk name from mnttab * 2. Translate disk name to grub name * 3. Add the new menu entry */ rootdev = get_special("/"); if (rootdev) { grubdisk = os_to_grubdisk(rootdev, 1); free(rootdev); } } else { /* * This is an LU BE. The GRUB_root file * contains entry for GRUB's "root" cmd. */ grubdisk = read_grub_root(); } if (grubdisk == NULL) { bam_error(REBOOT_WITH_ARGS_FAILED); rv = BAM_ERROR; goto done; } if (optnum == KERNEL_CMD) { entryNum = add_boot_entry(mp, BOOTENV_RC_TITLE, grubdisk, new_path, NULL); } else { new_str_len = strlen(DIRECT_BOOT_KERNEL) + strlen(path) + 8; new_arg = s_calloc(1, new_str_len); (void) snprintf(new_arg, new_str_len, "%s %s", DIRECT_BOOT_KERNEL, path); entryNum = add_boot_entry(mp, BOOTENV_RC_TITLE, grubdisk, new_arg, DIRECT_BOOT_ARCHIVE); } save_default_entry(mp, BAM_OLD_RC_DEF); (void) set_global(mp, menu_cmds[DEFAULT_CMD], entryNum); rv = BAM_WRITE; goto done; } /* * There was already an bootenv entry which we need to edit. */ if (optnum == KERNEL_CMD) { new_str_len = strlen(new_path) + strlen(old_args) + 2; new_arg = s_calloc(1, new_str_len); (void) snprintf(new_arg, new_str_len, "%s %s", new_path, old_args); free(kernelp->arg); kernelp->arg = new_arg; /* * If we have changed the kernel line, we may need to update * the archive line as well. */ set_archive_line(entryp, kernelp); } else { new_str_len = old_kernel_len + strlen(path) + 8; new_arg = s_calloc(1, new_str_len); (void) strncpy(new_arg, kernelp->arg, old_kernel_len); (void) strlcat(new_arg, " ", new_str_len); (void) strlcat(new_arg, path, new_str_len); free(kernelp->arg); kernelp->arg = new_arg; } rv = BAM_WRITE; done: if ((rv == BAM_WRITE) && kernelp) update_line(kernelp); if (free_new_path) free(new_path); return (rv); } /*ARGSUSED*/ static error_t set_option(menu_t *mp, char *menu_path, char *opt) { int optnum, optval; char *val; char buf[BUFSIZ] = ""; error_t rv; assert(mp); assert(opt); val = strchr(opt, '='); if (val != NULL) { *val = '\0'; } if (strcmp(opt, "default") == 0) { optnum = DEFAULT_CMD; } else if (strcmp(opt, "timeout") == 0) { optnum = TIMEOUT_CMD; } else if (strcmp(opt, menu_cmds[KERNEL_CMD]) == 0) { optnum = KERNEL_CMD; } else if (strcmp(opt, menu_cmds[ARGS_CMD]) == 0) { optnum = ARGS_CMD; } else { bam_error(INVALID_ENTRY, opt); return (BAM_ERROR); } /* * kernel and args are allowed without "=new_value" strings. All * others cause errors */ if ((val == NULL) && (optnum != KERNEL_CMD) && (optnum != ARGS_CMD)) { bam_error(INVALID_ENTRY, opt); return (BAM_ERROR); } else if (val != NULL) { *val = '='; } if ((optnum == KERNEL_CMD) || (optnum == ARGS_CMD)) { rv = set_kernel(mp, optnum, val ? val + 1 : NULL, buf, BUFSIZ); if ((rv == BAM_SUCCESS) && (buf[0] != '\0')) (void) printf("%s\n", buf); return (rv); } else { optval = s_strtol(val + 1); return (set_global(mp, menu_cmds[optnum], optval)); } } /* * The quiet argument suppresses messages. This is used * when invoked in the context of other commands (e.g. list_entry) */ static error_t read_globals(menu_t *mp, char *menu_path, char *globalcmd, int quiet) { line_t *lp; char *arg; int done, ret = BAM_SUCCESS; assert(mp); assert(menu_path); assert(globalcmd); if (mp->start == NULL) { if (!quiet) bam_error(NO_MENU, menu_path); return (BAM_ERROR); } done = 0; for (lp = mp->start; lp; lp = lp->next) { if (lp->flags != BAM_GLOBAL) continue; if (lp->cmd == NULL) { if (!quiet) bam_error(NO_CMD, lp->lineNum); continue; } if (strcmp(globalcmd, lp->cmd) != 0) continue; /* Found global. Check for duplicates */ if (done && !quiet) { bam_error(DUP_CMD, globalcmd, lp->lineNum, bam_root); ret = BAM_ERROR; } arg = lp->arg ? lp->arg : ""; bam_print(GLOBAL_CMD, globalcmd, arg); done = 1; } if (!done && bam_verbose) bam_print(NO_ENTRY, globalcmd); return (ret); } static error_t menu_write(char *root, menu_t *mp) { return (list2file(root, MENU_TMP, GRUB_MENU, mp->start)); } static void line_free(line_t *lp) { if (lp == NULL) return; if (lp->cmd) free(lp->cmd); if (lp->sep) free(lp->sep); if (lp->arg) free(lp->arg); if (lp->line) free(lp->line); free(lp); } static void linelist_free(line_t *start) { line_t *lp; while (start) { lp = start; start = start->next; line_free(lp); } } static void filelist_free(filelist_t *flistp) { linelist_free(flistp->head); flistp->head = NULL; flistp->tail = NULL; } static void menu_free(menu_t *mp) { entry_t *ent, *tmp; assert(mp); if (mp->start) linelist_free(mp->start); ent = mp->entries; while (ent) { tmp = ent; ent = tmp->next; free(tmp); } free(mp); } /* * Utility routines */ /* * Returns 0 on success * Any other value indicates an error */ static int exec_cmd(char *cmdline, char *output, int64_t osize) { char buf[BUFSIZ]; int ret; FILE *ptr; size_t len; sigset_t set; void (*disp)(int); /* * For security * - only absolute paths are allowed * - set IFS to space and tab */ if (*cmdline != '/') { bam_error(ABS_PATH_REQ, cmdline); return (-1); } (void) putenv("IFS= \t"); /* * We may have been exec'ed with SIGCHLD blocked * unblock it here */ (void) sigemptyset(&set); (void) sigaddset(&set, SIGCHLD); if (sigprocmask(SIG_UNBLOCK, &set, NULL) != 0) { bam_error(CANT_UNBLOCK_SIGCHLD, strerror(errno)); return (-1); } /* * Set SIGCHLD disposition to SIG_DFL for popen/pclose */ disp = sigset(SIGCHLD, SIG_DFL); if (disp == SIG_ERR) { bam_error(FAILED_SIG, strerror(errno)); return (-1); } if (disp == SIG_HOLD) { bam_error(BLOCKED_SIG, cmdline); return (-1); } ptr = popen(cmdline, "r"); if (ptr == NULL) { bam_error(POPEN_FAIL, cmdline, strerror(errno)); return (-1); } /* * If we simply do a pclose() following a popen(), pclose() * will close the reader end of the pipe immediately even * if the child process has not started/exited. pclose() * does wait for cmd to terminate before returning though. * When the executed command writes its output to the pipe * there is no reader process and the command dies with * SIGPIPE. To avoid this we read repeatedly until read * terminates with EOF. This indicates that the command * (writer) has closed the pipe and we can safely do a * pclose(). * * Since pclose() does wait for the command to exit, * we can safely reap the exit status of the command * from the value returned by pclose() */ while (fgets(buf, sizeof (buf), ptr) != NULL) { /* if (bam_verbose) XXX */ bam_print(PRINT_NO_NEWLINE, buf); if (output && osize > 0) { (void) snprintf(output, osize, "%s", buf); len = strlen(buf); output += len; osize -= len; } } ret = pclose(ptr); if (ret == -1) { bam_error(PCLOSE_FAIL, cmdline, strerror(errno)); return (-1); } if (WIFEXITED(ret)) { return (WEXITSTATUS(ret)); } else { bam_error(EXEC_FAIL, cmdline, ret); return (-1); } } /* * Since this function returns -1 on error * it cannot be used to convert -1. However, * that is sufficient for what we need. */ static long s_strtol(char *str) { long l; char *res = NULL; if (str == NULL) { return (-1); } errno = 0; l = strtol(str, &res, 10); if (errno || *res != '\0') { return (-1); } return (l); } /* * Wrapper around fputs, that adds a newline (since fputs doesn't) */ static int s_fputs(char *str, FILE *fp) { char linebuf[BAM_MAXLINE]; (void) snprintf(linebuf, sizeof (linebuf), "%s\n", str); return (fputs(linebuf, fp)); } /* * Wrapper around fgets, that strips newlines returned by fgets */ char * s_fgets(char *buf, int buflen, FILE *fp) { int n; buf = fgets(buf, buflen, fp); if (buf) { n = strlen(buf); if (n == buflen - 1 && buf[n-1] != '\n') bam_error(TOO_LONG, buflen - 1, buf); buf[n-1] = (buf[n-1] == '\n') ? '\0' : buf[n-1]; } return (buf); } void * s_calloc(size_t nelem, size_t sz) { void *ptr; ptr = calloc(nelem, sz); if (ptr == NULL) { bam_error(NO_MEM, nelem*sz); bam_exit(1); } return (ptr); } void * s_realloc(void *ptr, size_t sz) { ptr = realloc(ptr, sz); if (ptr == NULL) { bam_error(NO_MEM, sz); bam_exit(1); } return (ptr); } static char * s_strdup(char *str) { char *ptr; if (str == NULL) return (NULL); ptr = strdup(str); if (ptr == NULL) { bam_error(NO_MEM, strlen(str) + 1); bam_exit(1); } return (ptr); } /* * Returns 1 if amd64 (or sparc, for syncing x86 diskless clients) * Returns 0 otherwise */ static int is_amd64(void) { static int amd64 = -1; char isabuf[257]; /* from sysinfo(2) manpage */ if (amd64 != -1) return (amd64); if (sysinfo(SI_ISALIST, isabuf, sizeof (isabuf)) > 0 && strncmp(isabuf, "amd64 ", strlen("amd64 ")) == 0) amd64 = 1; else if (strstr(isabuf, "i386") == NULL) amd64 = 1; /* diskless server */ else amd64 = 0; return (amd64); } static void append_to_flist(filelist_t *flistp, char *s) { line_t *lp; lp = s_calloc(1, sizeof (line_t)); lp->line = s_strdup(s); if (flistp->head == NULL) flistp->head = lp; else flistp->tail->next = lp; flistp->tail = lp; }