/*- * Copyright (c) 1998 Robert Nordier * All rights reserved. * * Redistribution and use in source and binary forms are freely * permitted provided that the above copyright notice and this * paragraph and the following disclaimer are duplicated in all * such forms. * * This software is provided "AS IS" and without any express or * implied warranties, including, without limitation, the implied * warranties of merchantability and fitness for a particular * purpose. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #ifdef GPT #include #endif #include #include #include #include #include #include #include #include #include "bootstrap.h" #include "libi386.h" #include #include "lib.h" #include "rbx.h" #include "cons.h" #include "bootargs.h" #include "disk.h" #include "part.h" #include "paths.h" #include "libzfs.h" #define ARGS 0x900 #define NOPT 14 #define NDEV 3 #define BIOS_NUMDRIVES 0x475 #define DRV_HARD 0x80 #define DRV_MASK 0x7f #define TYPE_AD 0 #define TYPE_DA 1 #define TYPE_MAXHARD TYPE_DA #define TYPE_FD 2 extern uint32_t _end; static const char optstr[NOPT] = "DhaCcdgmnpqrsv"; /* Also 'P', 'S' */ static const unsigned char flags[NOPT] = { RBX_DUAL, RBX_SERIAL, RBX_ASKNAME, RBX_CDROM, RBX_CONFIG, RBX_KDB, RBX_GDB, RBX_MUTE, RBX_NOINTR, RBX_PAUSE, RBX_QUIET, RBX_DFLTROOT, RBX_SINGLE, RBX_VERBOSE }; uint32_t opts; /* * Paths to try loading before falling back to the boot2 prompt. * * /boot/zfsloader must be tried before /boot/loader in order to remain * backward compatible with ZFS boot environments where /boot/loader exists * but does not have ZFS support, which was the case before FreeBSD 12. * * If no loader is found, try to load a kernel directly instead. */ static const struct string { const char *p; size_t len; } loadpath[] = { { PATH_LOADER_ZFS, sizeof(PATH_LOADER_ZFS) }, { PATH_LOADER, sizeof(PATH_LOADER) }, { PATH_KERNEL, sizeof(PATH_KERNEL) }, }; static const unsigned char dev_maj[NDEV] = {30, 4, 2}; static struct i386_devdesc *bdev; static char cmd[512]; static char cmddup[512]; static char kname[1024]; static int comspeed = SIOSPD; static struct bootinfo bootinfo; static uint32_t bootdev; static struct zfs_boot_args zfsargs; #ifdef LOADER_GELI_SUPPORT static struct geli_boot_args geliargs; #endif extern vm_offset_t high_heap_base; extern uint32_t bios_basemem, bios_extmem, high_heap_size; static char *heap_top; static char *heap_bottom; void exit(int); static void i386_zfs_probe(void); static void load(void); static int parse_cmd(void); #ifdef LOADER_GELI_SUPPORT #include "geliboot.h" static char gelipw[GELI_PW_MAXLEN]; #endif struct arch_switch archsw; /* MI/MD interface boundary */ static char boot_devname[2 * ZFS_MAXNAMELEN + 8]; /* disk or pool:dataset */ struct devsw *devsw[] = { &bioshd, #if defined(LOADER_ZFS_SUPPORT) &zfs_dev, #endif NULL }; struct fs_ops *file_system[] = { #if defined(LOADER_ZFS_SUPPORT) &zfs_fsops, #endif #if defined(LOADER_UFS_SUPPORT) &ufs_fsops, #endif NULL }; caddr_t ptov(uintptr_t x) { return (PTOV(x)); } int main(void) { unsigned i; int auto_boot, fd, nextboot = 0; struct disk_devdesc devdesc; bios_getmem(); if (high_heap_size > 0) { heap_top = PTOV(high_heap_base + high_heap_size); heap_bottom = PTOV(high_heap_base); } else { heap_bottom = (char *) (roundup2(__base + (int32_t)&_end, 0x10000) - __base); heap_top = (char *)PTOV(bios_basemem); } setheap(heap_bottom, heap_top); /* * Initialise the block cache. Set the upper limit. */ bcache_init(32768, 512); archsw.arch_autoload = NULL; archsw.arch_getdev = i386_getdev; archsw.arch_copyin = NULL; archsw.arch_copyout = NULL; archsw.arch_readin = NULL; archsw.arch_isainb = NULL; archsw.arch_isaoutb = NULL; archsw.arch_zfs_probe = i386_zfs_probe; bootinfo.bi_version = BOOTINFO_VERSION; bootinfo.bi_size = sizeof(bootinfo); bootinfo.bi_basemem = bios_basemem / 1024; bootinfo.bi_extmem = bios_extmem / 1024; bootinfo.bi_memsizes_valid++; bootinfo.bi_bios_dev = *(uint8_t *)PTOV(ARGS); /* Set up fall back device name. */ snprintf(boot_devname, sizeof (boot_devname), "disk%d:", bd_bios2unit(bootinfo.bi_bios_dev)); for (i = 0; devsw[i] != NULL; i++) if (devsw[i]->dv_init != NULL) (devsw[i]->dv_init)(); disk_parsedev(&devdesc, boot_devname + 4, NULL); bootdev = MAKEBOOTDEV(dev_maj[DEVT_DISK], devdesc.d_slice + 1, devdesc.dd.d_unit, devdesc.d_partition >= 0 ? devdesc.d_partition : 0xff); /* * zfs_fmtdev() can be called only after dv_init */ if (bdev != NULL && bdev->dd.d_dev->dv_type == DEVT_ZFS) { /* set up proper device name string for ZFS */ strncpy(boot_devname, zfs_fmtdev(bdev), sizeof (boot_devname)); if (zfs_nextboot(bdev, cmd, sizeof(cmd)) == 0) { nextboot = 1; memcpy(cmddup, cmd, sizeof(cmd)); if (parse_cmd()) { if (!OPT_CHECK(RBX_QUIET)) printf("failed to parse pad2 area\n"); exit(0); } if (!OPT_CHECK(RBX_QUIET)) printf("zfs nextboot: %s\n", cmddup); /* Do not process this command twice */ *cmd = 0; } } /* now make sure we have bdev on all cases */ free(bdev); i386_getdev((void **)&bdev, boot_devname, NULL); env_setenv("currdev", EV_VOLATILE, boot_devname, i386_setcurrdev, env_nounset); /* Process configuration file */ auto_boot = 1; fd = open(PATH_CONFIG, O_RDONLY); if (fd == -1) fd = open(PATH_DOTCONFIG, O_RDONLY); if (fd != -1) { read(fd, cmd, sizeof (cmd)); close(fd); } if (*cmd) { /* * Note that parse_cmd() is destructive to cmd[] and we also * want to honor RBX_QUIET option that could be present in * cmd[]. */ memcpy(cmddup, cmd, sizeof(cmd)); if (parse_cmd()) auto_boot = 0; if (!OPT_CHECK(RBX_QUIET)) printf("%s: %s\n", PATH_CONFIG, cmddup); /* Do not process this command twice */ *cmd = 0; } /* Do not risk waiting at the prompt forever. */ if (nextboot && !auto_boot) exit(0); if (auto_boot && !*kname) { /* * Iterate through the list of loader and kernel paths, * trying to load. If interrupted by a keypress, or in case of * failure, drop the user to the boot2 prompt. */ for (i = 0; i < nitems(loadpath); i++) { memcpy(kname, loadpath[i].p, loadpath[i].len); if (keyhit(3)) break; load(); } } /* Present the user with the boot2 prompt. */ for (;;) { if (!auto_boot || !OPT_CHECK(RBX_QUIET)) { printf("\nFreeBSD/x86 boot\n"); printf("Default: %s%s\nboot: ", boot_devname, kname); } if (ioctrl & IO_SERIAL) sio_flush(); if (!auto_boot || keyhit(5)) getstr(cmd, sizeof(cmd)); else if (!auto_boot || !OPT_CHECK(RBX_QUIET)) putchar('\n'); auto_boot = 0; if (parse_cmd()) putchar('\a'); else load(); } } /* XXX - Needed for btxld to link the boot2 binary; do not remove. */ void exit(int x) { __exit(x); } static void load(void) { union { struct exec ex; Elf32_Ehdr eh; } hdr; static Elf32_Phdr ep[2]; static Elf32_Shdr es[2]; caddr_t p; uint32_t addr, x; int fd, fmt, i, j; ssize_t size; if ((fd = open(kname, O_RDONLY)) == -1) { printf("\nCan't find %s\n", kname); return; } size = sizeof(hdr); if (read(fd, &hdr, sizeof (hdr)) != size) { close(fd); return; } if (N_GETMAGIC(hdr.ex) == ZMAGIC) { fmt = 0; } else if (IS_ELF(hdr.eh)) { fmt = 1; } else { printf("Invalid %s\n", "format"); close(fd); return; } if (fmt == 0) { addr = hdr.ex.a_entry & 0xffffff; p = PTOV(addr); lseek(fd, PAGE_SIZE, SEEK_SET); size = hdr.ex.a_text; if (read(fd, p, hdr.ex.a_text) != size) { close(fd); return; } p += roundup2(hdr.ex.a_text, PAGE_SIZE); size = hdr.ex.a_data; if (read(fd, p, hdr.ex.a_data) != size) { close(fd); return; } p += hdr.ex.a_data + roundup2(hdr.ex.a_bss, PAGE_SIZE); bootinfo.bi_symtab = VTOP(p); memcpy(p, &hdr.ex.a_syms, sizeof(hdr.ex.a_syms)); p += sizeof(hdr.ex.a_syms); if (hdr.ex.a_syms) { size = hdr.ex.a_syms; if (read(fd, p, hdr.ex.a_syms) != size) { close(fd); return; } p += hdr.ex.a_syms; size = sizeof (int); if (read(fd, p, sizeof (int)) != size) { close(fd); return; } x = *(uint32_t *)p; p += sizeof(int); x -= sizeof(int); size = x; if (read(fd, p, x) != size) { close(fd); return; } p += x; } } else { lseek(fd, hdr.eh.e_phoff, SEEK_SET); for (j = i = 0; i < hdr.eh.e_phnum && j < 2; i++) { size = sizeof (ep[0]); if (read(fd, ep + j, sizeof (ep[0])) != size) { close(fd); return; } if (ep[j].p_type == PT_LOAD) j++; } for (i = 0; i < 2; i++) { p = PTOV(ep[i].p_paddr & 0xffffff); lseek(fd, ep[i].p_offset, SEEK_SET); size = ep[i].p_filesz; if (read(fd, p, ep[i].p_filesz) != size) { close(fd); return; } } p += roundup2(ep[1].p_memsz, PAGE_SIZE); bootinfo.bi_symtab = VTOP(p); if (hdr.eh.e_shnum == hdr.eh.e_shstrndx + 3) { lseek(fd, hdr.eh.e_shoff + sizeof (es[0]) * (hdr.eh.e_shstrndx + 1), SEEK_SET); size = sizeof(es); if (read(fd, &es, sizeof (es)) != size) { close(fd); return; } for (i = 0; i < 2; i++) { memcpy(p, &es[i].sh_size, sizeof(es[i].sh_size)); p += sizeof(es[i].sh_size); lseek(fd, es[i].sh_offset, SEEK_SET); size = es[i].sh_size; if (read(fd, p, es[i].sh_size) != size) { close(fd); return; } p += es[i].sh_size; } } addr = hdr.eh.e_entry & 0xffffff; } close(fd); bootinfo.bi_esymtab = VTOP(p); bootinfo.bi_kernelname = VTOP(kname); #ifdef LOADER_GELI_SUPPORT explicit_bzero(gelipw, sizeof(gelipw)); #endif if (bdev->dd.d_dev->dv_type == DEVT_ZFS) { zfsargs.size = sizeof(zfsargs); zfsargs.pool = bdev->d_kind.zfs.pool_guid; zfsargs.root = bdev->d_kind.zfs.root_guid; #ifdef LOADER_GELI_SUPPORT export_geli_boot_data(&zfsargs.gelidata); #endif /* * Note that the zfsargs struct is passed by value, not by * pointer. Code in btxldr.S copies the values from the entry * stack to a fixed location within loader(8) at startup due * to the presence of KARGS_FLAGS_EXTARG. */ __exec((caddr_t)addr, RB_BOOTINFO | (opts & RBX_MASK), bootdev, KARGS_FLAGS_ZFS | KARGS_FLAGS_EXTARG, (uint32_t)bdev->d_kind.zfs.pool_guid, (uint32_t)(bdev->d_kind.zfs.pool_guid >> 32), VTOP(&bootinfo), zfsargs); } else { #ifdef LOADER_GELI_SUPPORT geliargs.size = sizeof(geliargs); export_geli_boot_data(&geliargs.gelidata); #endif /* * Note that the geliargs struct is passed by value, not by * pointer. Code in btxldr.S copies the values from the entry * stack to a fixed location within loader(8) at startup due * to the presence of the KARGS_FLAGS_EXTARG flag. */ __exec((caddr_t)addr, RB_BOOTINFO | (opts & RBX_MASK), bootdev, #ifdef LOADER_GELI_SUPPORT KARGS_FLAGS_GELI | KARGS_FLAGS_EXTARG, 0, 0, VTOP(&bootinfo), geliargs #else 0, 0, 0, VTOP(&bootinfo) #endif ); } } static int mount_root(char *arg) { char *root; struct i386_devdesc *ddesc; uint8_t part; if (asprintf(&root, "%s:", arg) < 0) return (1); if (i386_getdev((void **)&ddesc, root, NULL)) { free(root); return (1); } /* we should have new device descriptor, free old and replace it. */ free(bdev); bdev = ddesc; if (bdev->dd.d_dev->dv_type == DEVT_DISK) { if (bdev->d_kind.biosdisk.partition == -1) part = 0xff; else part = bdev->d_kind.biosdisk.partition; bootdev = MAKEBOOTDEV(dev_maj[bdev->dd.d_dev->dv_type], bdev->d_kind.biosdisk.slice + 1, bdev->dd.d_unit, part); bootinfo.bi_bios_dev = bd_unit2bios(bdev); } strncpy(boot_devname, root, sizeof (boot_devname)); setenv("currdev", root, 1); free(root); return (0); } static void fs_list(char *arg) { int fd; struct dirent *d; char line[80]; fd = open(arg, O_RDONLY); if (fd < 0) return; pager_open(); while ((d = readdirfd(fd)) != NULL) { sprintf(line, "%s\n", d->d_name); if (pager_output(line)) break; } pager_close(); close(fd); } static int parse_cmd(void) { char *arg = cmd; char *ep, *p, *q; const char *cp; char line[80]; int c, i, j; while ((c = *arg++)) { if (c == ' ' || c == '\t' || c == '\n') continue; for (p = arg; *p && *p != '\n' && *p != ' ' && *p != '\t'; p++) ; ep = p; if (*p) *p++ = 0; if (c == '-') { while ((c = *arg++)) { if (c == 'P') { if (*(uint8_t *)PTOV(0x496) & 0x10) { cp = "yes"; } else { opts |= OPT_SET(RBX_DUAL); opts |= OPT_SET(RBX_SERIAL); cp = "no"; } printf("Keyboard: %s\n", cp); continue; } else if (c == 'S') { j = 0; while ((unsigned int) (i = *arg++ - '0') <= 9) j = j * 10 + i; if (j > 0 && i == -'0') { comspeed = j; break; } /* * Fall through to error below * ('S' not in optstr[]). */ } for (i = 0; c != optstr[i]; i++) if (i == NOPT - 1) return (-1); opts ^= OPT_SET(flags[i]); } ioctrl = OPT_CHECK(RBX_DUAL) ? (IO_SERIAL|IO_KEYBOARD) : OPT_CHECK(RBX_SERIAL) ? IO_SERIAL : IO_KEYBOARD; if (ioctrl & IO_SERIAL) { if (sio_init(115200 / comspeed) != 0) ioctrl &= ~IO_SERIAL; } } if (c == '?') { printf("\n"); if (*arg == '\0') arg = (char *)"/"; fs_list(arg); zfs_list(arg); return (-1); } else { char *ptr; printf("\n"); arg--; /* * Report pool status if the comment is 'status'. Lets * hope no-one wants to load /status as a kernel. */ if (strcmp(arg, "status") == 0) { pager_open(); for (i = 0; devsw[i] != NULL; i++) { if (devsw[i]->dv_print != NULL) { if (devsw[i]->dv_print(1)) break; } else { snprintf(line, sizeof(line), "%s: (unknown)\n", devsw[i]->dv_name); if (pager_output(line)) break; } } pager_close(); return (-1); } /* * If there is "zfs:" prefix simply ignore it. */ ptr = arg; if (strncmp(ptr, "zfs:", 4) == 0) ptr += 4; /* * If there is a colon, switch pools. */ q = strchr(ptr, ':'); if (q) { *q++ = '\0'; if (mount_root(arg) != 0) { return (-1); } arg = q; } if ((i = ep - arg)) { if ((size_t)i >= sizeof(kname)) return (-1); memcpy(kname, arg, i + 1); } } arg = p; } return (0); } /* * Probe all disks to discover ZFS pools. The idea is to walk all possible * disk devices, however, we also need to identify possible boot pool. * For boot pool detection we have boot disk passed us from BIOS, recorded * in bootinfo.bi_bios_dev. */ static void i386_zfs_probe(void) { char devname[32]; int boot_unit; struct i386_devdesc dev; uint64_t pool_guid = 0; dev.dd.d_dev = &bioshd; /* Translate bios dev to our unit number. */ boot_unit = bd_bios2unit(bootinfo.bi_bios_dev); /* * Open all the disks we can find and see if we can reconstruct * ZFS pools from them. */ for (dev.dd.d_unit = 0; bd_unit2bios(&dev) >= 0; dev.dd.d_unit++) { snprintf(devname, sizeof (devname), "%s%d:", bioshd.dv_name, dev.dd.d_unit); /* If this is not boot disk, use generic probe. */ if (dev.dd.d_unit != boot_unit) zfs_probe_dev(devname, NULL); else zfs_probe_dev(devname, &pool_guid); if (pool_guid != 0 && bdev == NULL) { bdev = malloc(sizeof (struct i386_devdesc)); bzero(bdev, sizeof (struct i386_devdesc)); bdev->dd.d_dev = &zfs_dev; bdev->d_kind.zfs.pool_guid = pool_guid; } } }