/* $OpenBSD: i386_installboot.c,v 1.25 2015/12/24 20:14:07 krw Exp $ */ /* $NetBSD: installboot.c,v 1.5 1995/11/17 23:23:50 gwr Exp $ */ /* * Copyright (c) 2011 Joel Sing * Copyright (c) 2010 Otto Moerbeek * Copyright (c) 2003 Tom Cosgrove * Copyright (c) 1997 Michael Shalayeff * Copyright (c) 1994 Paul Kranenburg * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Paul Kranenburg. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #define ELFSIZE 32 #include /* DEV_BSIZE */ #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 "installboot.h" #include "i386_installboot.h" char *bootldr; char *blkstore; size_t blksize; struct sym_data pbr_symbols[] = { {"_fs_bsize_p", 2}, {"_fs_bsize_s", 2}, {"_fsbtodb", 1}, {"_p_offset", 4}, {"_inodeblk", 4}, {"_inodedbl", 4}, {"_nblocks", 2}, {NULL} }; static void devread(int, void *, daddr_t, size_t, char *); static u_int findopenbsd(int, struct disklabel *); static int getbootparams(char *, int, struct disklabel *); static char *loadproto(char *, long *); static int gpt_chk_mbr(struct dos_partition *, u_int64_t); /* * Read information about /boot's inode and filesystem parameters, then * put biosboot (partition boot record) on the target drive with these * parameters patched in. */ void md_init(void) { stages = 2; stage1 = "/usr/mdec/biosboot"; stage2 = "/usr/mdec/boot"; bootldr = "/boot"; } void md_loadboot(void) { /* Load prototype boot blocks. */ if ((blkstore = loadproto(stage1, &blksize)) == NULL) exit(1); /* XXX - Paranoia: Make sure size is aligned! */ if (blksize & (DEV_BSIZE - 1)) errx(1, "proto %s bad size=%ld", stage1, blksize); if (blksize > SBSIZE - DEV_BSIZE) errx(1, "proto bootblocks too big"); } void md_installboot(int devfd, char *dev) { struct disklabel dl; int part; /* Get and check disklabel. */ if (ioctl(devfd, DIOCGDINFO, &dl) != 0) err(1, "disklabel: %s", dev); if (dl.d_magic != DISKMAGIC) errx(1, "bad disklabel magic=0x%08x", dl.d_magic); /* Warn on unknown disklabel types. */ if (dl.d_type == 0) warnx("disklabel type unknown"); part = findgptefisys(devfd, &dl); if (part != -1) { write_efisystem(&dl, (char)part); return; } bootldr = fileprefix(root, bootldr); if (bootldr == NULL) exit(1); if (verbose) fprintf(stderr, "%s %s to %s\n", (nowrite ? "would copy" : "copying"), stage2, bootldr); if (!nowrite) if (filecopy(stage2, bootldr) == -1) exit(1); /* Get bootstrap parameters to patch into proto. */ if (getbootparams(bootldr, devfd, &dl) != 0) exit(1); /* Write boot blocks to device. */ write_bootblocks(devfd, dev, &dl); } void write_bootblocks(int devfd, char *dev, struct disklabel *dl) { struct stat sb; u_int8_t *secbuf; u_int start = 0; /* Write patched proto bootblock(s) into the superblock. */ if (fstat(devfd, &sb) < 0) err(1, "fstat: %s", dev); if (!S_ISCHR(sb.st_mode)) errx(1, "%s: not a character device", dev); /* Patch the parameters into the proto bootstrap sector. */ pbr_set_symbols(stage1, blkstore, pbr_symbols); if (!nowrite) { /* Sync filesystems (to clean in-memory superblock?). */ sync(); sleep(1); } /* * Find OpenBSD partition. Floppies are special, getting an * everything-in-one /boot starting at sector 0. */ if (dl->d_type != DTYPE_FLOPPY) { start = findopenbsd(devfd, dl); if (start == (u_int)-1) errx(1, "no OpenBSD partition"); } if (verbose) fprintf(stderr, "%s will be written at sector %u\n", stage1, start); if (start + (blksize / dl->d_secsize) > BOOTBIOS_MAXSEC) warnx("%s extends beyond sector %u. OpenBSD might not boot.", stage1, BOOTBIOS_MAXSEC); if (!nowrite) { if (lseek(devfd, (off_t)start * dl->d_secsize, SEEK_SET) < 0) err(1, "seek boot sector"); secbuf = calloc(1, dl->d_secsize); if (read(devfd, secbuf, dl->d_secsize) != dl->d_secsize) err(1, "read boot sector"); bcopy(blkstore, secbuf, blksize); if (lseek(devfd, (off_t)start * dl->d_secsize, SEEK_SET) < 0) err(1, "seek bootstrap"); if (write(devfd, secbuf, dl->d_secsize) != dl->d_secsize) err(1, "write bootstrap"); free(secbuf); } } void write_efisystem(struct disklabel *dl, char part) { static char *fsckfmt = "/sbin/fsck_msdos %s >/dev/null"; static char *newfsfmt ="/sbin/newfs_msdos %s >/dev/null"; struct msdosfs_args args; char cmd[60]; char dst[50]; /* /tmp/installboot.XXXXXXXXXX/efi/BOOT/BOOTIA32.EFI */ char *src; size_t mntlen, pathlen, srclen; int rslt; src = NULL; /* Create directory for temporary mount point. */ strlcpy(dst, "/tmp/installboot.XXXXXXXXXX", sizeof(dst)); if (mkdtemp(dst) == NULL) err(1, "mkdtemp('%s') failed", dst); mntlen = strlen(dst); /* Mount . as msdos filesystem. */ memset(&args, 0, sizeof(args)); rslt = asprintf(&args.fspec, "%02hhx%02hhx%02hhx%02hhx%02hhx%02hhx%02hhx%02hhx.%c", dl->d_uid[0], dl->d_uid[1], dl->d_uid[2], dl->d_uid[3], dl->d_uid[4], dl->d_uid[5], dl->d_uid[6], dl->d_uid[7], part); if (rslt == -1) { warn("bad special device"); goto rmdir; } args.export_info.ex_root = -2; /* unchecked anyway on DOS fs */ args.export_info.ex_flags = 0; if (mount(MOUNT_MSDOS, dst, 0, &args) == -1) { /* Try fsck'ing it. */ rslt = snprintf(cmd, sizeof(cmd), fsckfmt, args.fspec); if (rslt >= sizeof(cmd)) { warnx("can't build for fsck command"); rslt = -1; goto rmdir; } rslt = system(cmd); if (rslt == -1) { warn("system('%s') failed", cmd); goto rmdir; } if (mount(MOUNT_MSDOS, dst, 0, &args) == -1) { /* Try newfs'ing it. */ rslt = snprintf(cmd, sizeof(cmd), newfsfmt, args.fspec); if (rslt >= sizeof(cmd)) { warnx("can't build newfs command"); rslt = -1; goto rmdir; } rslt = system(cmd); if (rslt == -1) { warn("system('%s') failed", cmd); goto rmdir; } rslt = mount(MOUNT_MSDOS, dst, 0, &args); if (rslt == -1) { warn("unable to mount EFI System partition"); goto rmdir; } } } /* Create "/efi/BOOT" directory in .. */ if (strlcat(dst, "/efi", sizeof(dst)) >= sizeof(dst)) { rslt = -1; warn("unable to build /efi directory"); goto umount; } rslt = mkdir(dst, 0); if (rslt == -1 && errno != EEXIST) { warn("mkdir('%s') failed", dst); goto umount; } if (strlcat(dst, "/BOOT", sizeof(dst)) >= sizeof(dst)) { rslt = -1; warn("unable to build /BOOT directory"); goto umount; } rslt = mkdir(dst, 0); if (rslt == -1 && errno != EEXIST) { warn("mkdir('%s') failed", dst); goto umount; } /* * Copy BOOTIA32.EFI and BOOTX64.EFI to /efi/BOOT/. * * N.B.: BOOTIA32.EFI is longer than BOOTX64.EFI, so src can be reused! */ pathlen = strlen(dst); if (strlcat(dst, "/BOOTIA32.EFI", sizeof(dst)) >= sizeof(dst)) { rslt = -1; warn("unable to build /BOOTIA32.EFI path"); goto umount; } src = fileprefix(root, "/usr/mdec/BOOTIA32.EFI"); if (src == NULL) { rslt = -1; goto umount; } srclen = strlen(src); if (verbose) fprintf(stderr, "%s %s to %s\n", (nowrite ? "would copy" : "copying"), src, dst); if (!nowrite) { rslt = filecopy(src, dst); if (rslt == -1) goto umount; } src[srclen - strlen("/BOOTIA32.EFI")] = '\0'; dst[pathlen] = '\0'; if (strlcat(dst, "/BOOTX64.EFI", sizeof(dst)) >= sizeof(dst)) { rslt = -1; warn("unable to build /BOOTX64.EFI dst path"); goto umount; } if (strlcat(src, "/BOOTX64.EFI", srclen+1) >= srclen+1) { rslt = -1; warn("unable to build /BOOTX64.EFI src path"); goto umount; } if (verbose) fprintf(stderr, "%s %s to %s\n", (nowrite ? "would copy" : "copying"), src, dst); if (!nowrite) { rslt = filecopy(src, dst); if (rslt == -1) goto umount; } rslt = 0; umount: dst[mntlen] = '\0'; if (unmount(dst, MNT_FORCE) == -1) err(1, "unmount('%s') failed", dst); rmdir: free(args.fspec); dst[mntlen] = '\0'; if (rmdir(dst) == -1) err(1, "rmdir('%s') failed", dst); free(src); if (rslt == -1) exit(1); } u_int findopenbsd(int devfd, struct disklabel *dl) { struct dos_mbr mbr; u_int mbroff = DOSBBSECTOR; u_int mbr_eoff = DOSBBSECTOR; /* Offset of extended part. */ struct dos_partition *dp; u_int8_t *secbuf; u_int maxebr = DOS_MAXEBR, nextebr; int i; again: if (!maxebr--) { if (verbose) fprintf(stderr, "Traversed more than %d Extended Boot " "Records (EBRs)\n", DOS_MAXEBR); return ((u_int)-1); } if (verbose) fprintf(stderr, "%s boot record (%cBR) at sector %u\n", (mbroff == DOSBBSECTOR) ? "master" : "extended", (mbroff == DOSBBSECTOR) ? 'M' : 'E', mbroff); if ((secbuf = malloc(dl->d_secsize)) == NULL) err(1, NULL); if (lseek(devfd, (off_t)mbroff * dl->d_secsize, SEEK_SET) < 0 || read(devfd, secbuf, dl->d_secsize) < (ssize_t)sizeof(mbr)) err(4, "can't read boot record"); bcopy(secbuf, &mbr, sizeof(mbr)); free(secbuf); if (mbr.dmbr_sign != DOSMBR_SIGNATURE) errx(1, "invalid boot record signature (0x%04X) @ sector %u", mbr.dmbr_sign, mbroff); nextebr = 0; for (i = 0; i < NDOSPART; i++) { dp = &mbr.dmbr_parts[i]; if (!dp->dp_size) continue; if (verbose) fprintf(stderr, "\tpartition %d: type 0x%02X offset %u size %u\n", i, dp->dp_typ, dp->dp_start, dp->dp_size); if (dp->dp_typ == DOSPTYP_OPENBSD) { if (dp->dp_start > (dp->dp_start + mbroff)) continue; return (dp->dp_start + mbroff); } if (!nextebr && (dp->dp_typ == DOSPTYP_EXTEND || dp->dp_typ == DOSPTYP_EXTENDL)) { nextebr = dp->dp_start + mbr_eoff; if (nextebr < dp->dp_start) nextebr = (u_int)-1; if (mbr_eoff == DOSBBSECTOR) mbr_eoff = dp->dp_start; } } if (nextebr && nextebr != (u_int)-1) { mbroff = nextebr; goto again; } return ((u_int)-1); } /* * Returns 0 if the MBR with the provided partition array is a GPT protective * MBR, and returns 1 otherwise. A GPT protective MBR would have one and only * one MBR partition, an EFI partition that either covers the whole disk or as * much of it as is possible with a 32bit size field. * * NOTE: MS always uses a size of UINT32_MAX for the EFI partition!** */ static int gpt_chk_mbr(struct dos_partition *dp, u_int64_t dsize) { struct dos_partition *dp2; int efi, found, i; u_int32_t psize; found = efi = 0; for (dp2=dp, i=0; i < NDOSPART; i++, dp2++) { if (dp2->dp_typ == DOSPTYP_UNUSED) continue; found++; if (dp2->dp_typ != DOSPTYP_EFI) continue; psize = letoh32(dp2->dp_size); if (psize == (dsize - 1) || psize == UINT32_MAX) { if (letoh32(dp2->dp_start) == 1) efi++; } } if (found == 1 && efi == 1) return (0); return (1); } int findgptefisys(int devfd, struct disklabel *dl) { struct gpt_partition gp[NGPTPARTITIONS]; struct gpt_header gh; struct dos_partition dp[NDOSPART]; struct uuid efisys_uuid; const char efisys_uuid_code[] = GPT_UUID_EFI_SYSTEM; off_t off; ssize_t len; u_int64_t start; int i; uint32_t orig_csum, new_csum; uint32_t ghsize, ghpartsize, ghpartnum, ghpartspersec; u_int8_t *secbuf; /* Prepare EFI System UUID */ uuid_dec_be(efisys_uuid_code, &efisys_uuid); if ((secbuf = malloc(dl->d_secsize)) == NULL) err(1, NULL); /* Check that there is a protective MBR. */ len = pread(devfd, secbuf, dl->d_secsize, 0); if (len != dl->d_secsize) err(4, "can't read mbr"); memcpy(dp, &secbuf[DOSPARTOFF], sizeof(dp)); if (gpt_chk_mbr(dp, DL_GETDSIZE(dl))) { free(secbuf); return (-1); } /* Check GPT Header. */ off = dl->d_secsize; /* Read header from sector 1. */ len = pread(devfd, secbuf, dl->d_secsize, off); if (len != dl->d_secsize) err(4, "can't read gpt header"); memcpy(&gh, secbuf, sizeof(gh)); free(secbuf); /* Check signature */ if (letoh64(gh.gh_sig) != GPTSIGNATURE) return (-1); if (letoh32(gh.gh_rev) != GPTREVISION) return (-1); ghsize = letoh32(gh.gh_size); if (ghsize < GPTMINHDRSIZE || ghsize > sizeof(struct gpt_header)) return (-1); /* Check checksum */ orig_csum = gh.gh_csum; gh.gh_csum = 0; new_csum = crc32((unsigned char *)&gh, ghsize); gh.gh_csum = orig_csum; if (letoh32(orig_csum) != new_csum) return (-1); off = letoh64(gh.gh_part_lba) * dl->d_secsize; ghpartsize = letoh32(gh.gh_part_size); ghpartspersec = dl->d_secsize / ghpartsize; ghpartnum = letoh32(gh.gh_part_num); if ((secbuf = malloc(dl->d_secsize)) == NULL) err(1, NULL); for (i = 0; i < (ghpartnum + ghpartspersec - 1) / ghpartspersec; i++) { len = pread(devfd, secbuf, dl->d_secsize, off); if (len != dl->d_secsize) { free(secbuf); return (-1); } memcpy(gp + i * ghpartspersec, secbuf, ghpartspersec * sizeof(struct gpt_partition)); off += dl->d_secsize; } free(secbuf); new_csum = crc32((unsigned char *)&gp, ghpartnum * ghpartsize); if (new_csum != letoh32(gh.gh_part_csum)) return (-1); start = 0; for (i = 0; i < ghpartnum && start == 0; i++) { if (memcmp(&gp[i].gp_type, &efisys_uuid, sizeof(struct uuid)) == 0) start = letoh64(gp[i].gp_lba_start); } if (start) { for (i = 0; i < MAXPARTITIONS; i++) { if (DL_GETPSIZE(&dl->d_partitions[i]) > 0 && DL_GETPOFFSET(&dl->d_partitions[i]) == start) return ('a' + i); } } return (-1); } /* * Load the prototype boot sector (biosboot) into memory. */ static char * loadproto(char *fname, long *size) { int fd; size_t tdsize; /* text+data size */ char *bp; Elf_Ehdr eh; Elf_Word phsize; Elf_Phdr *ph; if ((fd = open(fname, O_RDONLY)) < 0) err(1, "%s", fname); if (read(fd, &eh, sizeof(eh)) != sizeof(eh)) errx(1, "%s: read failed", fname); if (!IS_ELF(eh)) errx(1, "%s: bad magic: 0x%02x%02x%02x%02x", fname, eh.e_ident[EI_MAG0], eh.e_ident[EI_MAG1], eh.e_ident[EI_MAG2], eh.e_ident[EI_MAG3]); /* * We have to include the exec header in the beginning of * the buffer, and leave extra space at the end in case * the actual write to disk wants to skip the header. */ /* Program load header. */ if (eh.e_phnum != 1) errx(1, "%s: %u ELF load sections (only support 1)", fname, eh.e_phnum); ph = reallocarray(NULL, eh.e_phnum, sizeof(Elf_Phdr)); if (ph == NULL) err(1, NULL); phsize = eh.e_phnum * sizeof(Elf_Phdr); lseek(fd, eh.e_phoff, SEEK_SET); if (read(fd, ph, phsize) != phsize) errx(1, "%s: can't read header", fname); tdsize = ph->p_filesz; /* * Allocate extra space here because the caller may copy * the boot block starting at the end of the exec header. * This prevents reading beyond the end of the buffer. */ if ((bp = calloc(tdsize, 1)) == NULL) err(1, NULL); /* Read the rest of the file. */ lseek(fd, ph->p_offset, SEEK_SET); if (read(fd, bp, tdsize) != (ssize_t)tdsize) errx(1, "%s: read failed", fname); *size = tdsize; /* not aligned to DEV_BSIZE */ close(fd); return bp; } static void devread(int fd, void *buf, daddr_t blk, size_t size, char *msg) { if (lseek(fd, dbtob((off_t)blk), SEEK_SET) != dbtob((off_t)blk)) err(1, "%s: devread: lseek", msg); if (read(fd, buf, size) != (ssize_t)size) err(1, "%s: devread: read", msg); } static char sblock[SBSIZE]; /* * Read information about /boot's inode, then put this and filesystem * parameters from the superblock into pbr_symbols. */ static int getbootparams(char *boot, int devfd, struct disklabel *dl) { int fd; struct stat dsb, fsb; struct statfs fssb; struct partition *pp; struct fs *fs; char *buf; u_int blk, *ap; struct ufs1_dinode *ip; int ndb; int mib[3]; size_t size; dev_t dev; /* * Open 2nd-level boot program and record enough details about * where it is on the filesystem represented by `devfd' * (inode block, offset within that block, and various filesystem * parameters essentially taken from the superblock) for biosboot * to be able to load it later. */ /* Make sure the (probably new) boot file is on disk. */ sync(); sleep(1); if ((fd = open(boot, O_RDONLY)) < 0) err(1, "open: %s", boot); if (fstatfs(fd, &fssb) != 0) err(1, "statfs: %s", boot); if (strncmp(fssb.f_fstypename, "ffs", MFSNAMELEN) && strncmp(fssb.f_fstypename, "ufs", MFSNAMELEN) ) errx(1, "%s: not on an FFS filesystem", boot); #if 0 if (read(fd, &eh, sizeof(eh)) != sizeof(eh)) errx(1, "read: %s", boot); if (!IS_ELF(eh)) { errx(1, "%s: bad magic: 0x%02x%02x%02x%02x", boot, eh.e_ident[EI_MAG0], eh.e_ident[EI_MAG1], eh.e_ident[EI_MAG2], eh.e_ident[EI_MAG3]); } #endif if (fsync(fd) != 0) err(1, "fsync: %s", boot); if (fstat(fd, &fsb) != 0) err(1, "fstat: %s", boot); if (fstat(devfd, &dsb) != 0) err(1, "fstat: %d", devfd); /* Check devices. */ mib[0] = CTL_MACHDEP; mib[1] = CPU_CHR2BLK; mib[2] = dsb.st_rdev; size = sizeof(dev); if (sysctl(mib, 3, &dev, &size, NULL, 0) >= 0) { if (fsb.st_dev / MAXPARTITIONS != dev / MAXPARTITIONS) errx(1, "cross-device install"); } pp = &dl->d_partitions[DISKPART(fsb.st_dev)]; close(fd); /* Read superblock. */ devread(devfd, sblock, DL_SECTOBLK(dl, pp->p_offset) + SBLOCK, SBSIZE, "superblock"); fs = (struct fs *)sblock; /* Sanity-check super-block. */ if (fs->fs_magic != FS_MAGIC) errx(1, "Bad magic number in superblock"); if (fs->fs_inopb <= 0) err(1, "Bad inopb=%d in superblock", fs->fs_inopb); /* Read inode. */ if ((buf = malloc(fs->fs_bsize)) == NULL) err(1, NULL); blk = fsbtodb(fs, ino_to_fsba(fs, fsb.st_ino)); devread(devfd, buf, DL_SECTOBLK(dl, pp->p_offset) + blk, fs->fs_bsize, "inode"); ip = (struct ufs1_dinode *)(buf) + ino_to_fsbo(fs, fsb.st_ino); /* * Have the inode. Figure out how many filesystem blocks (not disk * sectors) there are for biosboot to load. */ ndb = howmany(ip->di_size, fs->fs_bsize); if (ndb <= 0) errx(1, "No blocks to load"); /* * Now set the values that will need to go into biosboot * (the partition boot record, a.k.a. the PBR). */ sym_set_value(pbr_symbols, "_fs_bsize_p", (fs->fs_bsize / 16)); sym_set_value(pbr_symbols, "_fs_bsize_s", (fs->fs_bsize / dl->d_secsize)); /* * fs_fsbtodb is the shift to convert fs_fsize to DEV_BSIZE. The * ino_to_fsba() return value is the number of fs_fsize units. * Calculate the shift to convert fs_fsize into physical sectors, * which are added to p_offset to get the sector address BIOS * will use. * * N.B.: ASSUMES fs_fsize is a power of 2 of d_secsize. */ sym_set_value(pbr_symbols, "_fsbtodb", ffs(fs->fs_fsize / dl->d_secsize) - 1); sym_set_value(pbr_symbols, "_p_offset", pp->p_offset); sym_set_value(pbr_symbols, "_inodeblk", ino_to_fsba(fs, fsb.st_ino)); ap = ip->di_db; sym_set_value(pbr_symbols, "_inodedbl", ((((char *)ap) - buf) + INODEOFF)); sym_set_value(pbr_symbols, "_nblocks", ndb); if (verbose) { fprintf(stderr, "%s is %d blocks x %d bytes\n", boot, ndb, fs->fs_bsize); fprintf(stderr, "fs block shift %u; part offset %u; " "inode block %lld, offset %u\n", ffs(fs->fs_fsize / dl->d_secsize) - 1, pp->p_offset, ino_to_fsba(fs, fsb.st_ino), (unsigned int)((((char *)ap) - buf) + INODEOFF)); } return 0; } void sym_set_value(struct sym_data *sym_list, char *sym, u_int32_t value) { struct sym_data *p; for (p = sym_list; p->sym_name != NULL; p++) { if (strcmp(p->sym_name, sym) == 0) break; } if (p->sym_name == NULL) errx(1, "%s: no such symbol", sym); p->sym_value = value; p->sym_set = 1; } /* * Write the parameters stored in sym_list into the in-memory copy of * the prototype biosboot (proto), ready for it to be written to disk. */ void pbr_set_symbols(char *fname, char *proto, struct sym_data *sym_list) { struct sym_data *sym; struct nlist *nl; char *vp; u_int32_t *lp; u_int16_t *wp; u_int8_t *bp; for (sym = sym_list; sym->sym_name != NULL; sym++) { if (!sym->sym_set) errx(1, "%s not set", sym->sym_name); /* Allocate space for 2; second is null-terminator for list. */ nl = calloc(2, sizeof(struct nlist)); if (nl == NULL) err(1, NULL); nl->n_name = sym->sym_name; if (nlist_elf32(fname, nl) != 0) errx(1, "%s: symbol %s not found", fname, sym->sym_name); if (nl->n_type != (N_TEXT)) errx(1, "%s: %s: wrong type (%x)", fname, sym->sym_name, nl->n_type); /* Get a pointer to where the symbol's value needs to go. */ vp = proto + nl->n_value; switch (sym->sym_size) { case 4: /* u_int32_t */ lp = (u_int32_t *) vp; *lp = sym->sym_value; break; case 2: /* u_int16_t */ if (sym->sym_value >= 0x10000) /* out of range */ errx(1, "%s: symbol out of range (%u)", sym->sym_name, sym->sym_value); wp = (u_int16_t *) vp; *wp = (u_int16_t) sym->sym_value; break; case 1: /* u_int16_t */ if (sym->sym_value >= 0x100) /* out of range */ errx(1, "%s: symbol out of range (%u)", sym->sym_name, sym->sym_value); bp = (u_int8_t *) vp; *bp = (u_int8_t) sym->sym_value; break; default: errx(1, "%s: bad symbol size %d", sym->sym_name, sym->sym_size); /* NOTREACHED */ } free(nl); } }