/* $NetBSD: ffs.c,v 1.32 2013/06/23 02:06:06 dholland Exp $ */ /*- * Copyright (c) 2002 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by Matt Fredette. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS * ``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 FOUNDATION OR CONTRIBUTORS * 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. */ #if HAVE_NBTOOL_CONFIG_H #include "nbtool_config.h" #endif #include #if !defined(__lint) __RCSID("$NetBSD: ffs.c,v 1.32 2013/06/23 02:06:06 dholland Exp $"); #endif /* !__lint */ #include #if !HAVE_NBTOOL_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include "installboot.h" /* From */ #define RF_PROTECTED_SECTORS 64L #undef DIRBLKSIZ #include #include #include #include #ifndef NO_FFS_SWAP #include #else #define ffs_sb_swap(fs_a, fs_b) #define ffs_dinode1_swap(inode_a, inode_b) #define ffs_dinode2_swap(inode_a, inode_b) #endif static int ffs_match_common(ib_params *, off_t); static int ffs_read_disk_block(ib_params *, uint64_t, int, char []); static int ffs_find_disk_blocks_ufs1(ib_params *, ino_t, int (*)(ib_params *, void *, uint64_t, uint32_t), void *); static int ffs_find_disk_blocks_ufs2(ib_params *, ino_t, int (*)(ib_params *, void *, uint64_t, uint32_t), void *); static int ffs_findstage2_ino(ib_params *, void *, uint64_t, uint32_t); static int ffs_findstage2_blocks(ib_params *, void *, uint64_t, uint32_t); static int is_ufs2; /* This reads a disk block from the filesystem. */ static int ffs_read_disk_block(ib_params *params, uint64_t blkno, int size, char blk[]) { int rv; assert(params != NULL); assert(params->filesystem != NULL); assert(params->fsfd != -1); assert(size > 0); assert(blk != NULL); rv = pread(params->fsfd, blk, size, blkno * params->sectorsize); if (rv == -1) { warn("Reading block %llu in `%s'", (unsigned long long)blkno, params->filesystem); return (0); } else if (rv != size) { warnx("Reading block %llu in `%s': short read", (unsigned long long)blkno, params->filesystem); return (0); } return (1); } /* * This iterates over the data blocks belonging to an inode, * making a callback each iteration with the disk block number * and the size. */ static int ffs_find_disk_blocks_ufs1(ib_params *params, ino_t ino, int (*callback)(ib_params *, void *, uint64_t, uint32_t), void *state) { char sbbuf[SBLOCKSIZE]; struct fs *fs; char inodebuf[MAXBSIZE]; struct ufs1_dinode *inode; int level_i; int32_t blk, lblk, nblk; int rv; #define LEVELS 4 struct { int32_t *blknums; unsigned long blkcount; char diskbuf[MAXBSIZE]; } level[LEVELS]; assert(params != NULL); assert(params->fstype != NULL); assert(callback != NULL); assert(state != NULL); /* Read the superblock. */ if (!ffs_read_disk_block(params, params->fstype->sblockloc, SBLOCKSIZE, sbbuf)) return (0); fs = (struct fs *)sbbuf; #ifndef NO_FFS_SWAP if (params->fstype->needswap) ffs_sb_swap(fs, fs); #endif if (fs->fs_inopb <= 0) { warnx("Bad inopb %d in superblock in `%s'", fs->fs_inopb, params->filesystem); return (0); } /* Read the inode. */ if (! ffs_read_disk_block(params, FFS_FSBTODB(fs, ino_to_fsba(fs, ino)) + params->fstype->offset, fs->fs_bsize, inodebuf)) return (0); inode = (struct ufs1_dinode *)inodebuf; inode += ino_to_fsbo(fs, ino); #ifndef NO_FFS_SWAP if (params->fstype->needswap) ffs_dinode1_swap(inode, inode); #endif /* Get the block count and initialize for our block walk. */ nblk = howmany(inode->di_size, fs->fs_bsize); lblk = 0; level_i = 0; level[0].blknums = &inode->di_db[0]; level[0].blkcount = UFS_NDADDR; level[1].blknums = &inode->di_ib[0]; level[1].blkcount = 1; level[2].blknums = &inode->di_ib[1]; level[2].blkcount = 1; level[3].blknums = &inode->di_ib[2]; level[3].blkcount = 1; /* Walk the data blocks. */ while (nblk > 0) { /* * If there are no more blocks at this indirection * level, move up one indirection level and loop. */ if (level[level_i].blkcount == 0) { if (++level_i == LEVELS) break; continue; } /* Get the next block at this level. */ blk = *(level[level_i].blknums++); level[level_i].blkcount--; if (params->fstype->needswap) blk = bswap32(blk); #if 0 fprintf(stderr, "ino %lu blk %lu level %d\n", ino, blk, level_i); #endif /* * If we're not at the direct level, descend one * level, read in that level's new block list, * and loop. */ if (level_i > 0) { level_i--; if (blk == 0) memset(level[level_i].diskbuf, 0, MAXBSIZE); else if (! ffs_read_disk_block(params, FFS_FSBTODB(fs, blk) + params->fstype->offset, fs->fs_bsize, level[level_i].diskbuf)) return (0); /* XXX ondisk32 */ level[level_i].blknums = (int32_t *)level[level_i].diskbuf; level[level_i].blkcount = FFS_NINDIR(fs); continue; } /* blk is the next direct level block. */ #if 0 fprintf(stderr, "ino %lu db %lu blksize %lu\n", ino, FFS_FSBTODB(fs, blk), ffs_sblksize(fs, inode->di_size, lblk)); #endif rv = (*callback)(params, state, FFS_FSBTODB(fs, blk) + params->fstype->offset, ffs_sblksize(fs, (int64_t)inode->di_size, lblk)); lblk++; nblk--; if (rv != 1) return (rv); } if (nblk != 0) { warnx("Inode %llu in `%s' ran out of blocks?", (unsigned long long)ino, params->filesystem); return (0); } return (1); } /* * This iterates over the data blocks belonging to an inode, * making a callback each iteration with the disk block number * and the size. */ static int ffs_find_disk_blocks_ufs2(ib_params *params, ino_t ino, int (*callback)(ib_params *, void *, uint64_t, uint32_t), void *state) { char sbbuf[SBLOCKSIZE]; struct fs *fs; char inodebuf[MAXBSIZE]; struct ufs2_dinode *inode; int level_i; int64_t blk, lblk, nblk; int rv; #define LEVELS 4 struct { int64_t *blknums; unsigned long blkcount; char diskbuf[MAXBSIZE]; } level[LEVELS]; assert(params != NULL); assert(params->fstype != NULL); assert(callback != NULL); assert(state != NULL); /* Read the superblock. */ if (!ffs_read_disk_block(params, params->fstype->sblockloc, SBLOCKSIZE, sbbuf)) return (0); fs = (struct fs *)sbbuf; #ifndef NO_FFS_SWAP if (params->fstype->needswap) ffs_sb_swap(fs, fs); #endif if (fs->fs_inopb <= 0) { warnx("Bad inopb %d in superblock in `%s'", fs->fs_inopb, params->filesystem); return (0); } /* Read the inode. */ if (! ffs_read_disk_block(params, FFS_FSBTODB(fs, ino_to_fsba(fs, ino)) + params->fstype->offset, fs->fs_bsize, inodebuf)) return (0); inode = (struct ufs2_dinode *)inodebuf; inode += ino_to_fsbo(fs, ino); #ifndef NO_FFS_SWAP if (params->fstype->needswap) ffs_dinode2_swap(inode, inode); #endif /* Get the block count and initialize for our block walk. */ nblk = howmany(inode->di_size, fs->fs_bsize); lblk = 0; level_i = 0; level[0].blknums = &inode->di_db[0]; level[0].blkcount = UFS_NDADDR; level[1].blknums = &inode->di_ib[0]; level[1].blkcount = 1; level[2].blknums = &inode->di_ib[1]; level[2].blkcount = 1; level[3].blknums = &inode->di_ib[2]; level[3].blkcount = 1; /* Walk the data blocks. */ while (nblk > 0) { /* * If there are no more blocks at this indirection * level, move up one indirection level and loop. */ if (level[level_i].blkcount == 0) { if (++level_i == LEVELS) break; continue; } /* Get the next block at this level. */ blk = *(level[level_i].blknums++); level[level_i].blkcount--; if (params->fstype->needswap) blk = bswap64(blk); #if 0 fprintf(stderr, "ino %lu blk %llu level %d\n", ino, (unsigned long long)blk, level_i); #endif /* * If we're not at the direct level, descend one * level, read in that level's new block list, * and loop. */ if (level_i > 0) { level_i--; if (blk == 0) memset(level[level_i].diskbuf, 0, MAXBSIZE); else if (! ffs_read_disk_block(params, FFS_FSBTODB(fs, blk) + params->fstype->offset, fs->fs_bsize, level[level_i].diskbuf)) return (0); level[level_i].blknums = (int64_t *)level[level_i].diskbuf; level[level_i].blkcount = FFS_NINDIR(fs); continue; } /* blk is the next direct level block. */ #if 0 fprintf(stderr, "ino %lu db %llu blksize %lu\n", ino, FFS_FSBTODB(fs, blk), ffs_sblksize(fs, inode->di_size, lblk)); #endif rv = (*callback)(params, state, FFS_FSBTODB(fs, blk) + params->fstype->offset, ffs_sblksize(fs, (int64_t)inode->di_size, lblk)); lblk++; nblk--; if (rv != 1) return (rv); } if (nblk != 0) { warnx("Inode %llu in `%s' ran out of blocks?", (unsigned long long)ino, params->filesystem); return (0); } return (1); } /* * This callback reads a block of the root directory, * searches for an entry for the secondary bootstrap, * and saves the inode number if one is found. */ static int ffs_findstage2_ino(ib_params *params, void *_ino, uint64_t blk, uint32_t blksize) { char dirbuf[MAXBSIZE]; struct direct *de, *ede; uint32_t ino; assert(params != NULL); assert(params->fstype != NULL); assert(params->stage2 != NULL); assert(_ino != NULL); /* Skip directory holes. */ if (blk == 0) return (1); /* Read the directory block. */ if (! ffs_read_disk_block(params, blk, blksize, dirbuf)) return (0); /* Loop over the directory entries. */ de = (struct direct *)&dirbuf[0]; ede = (struct direct *)&dirbuf[blksize]; while (de < ede) { ino = de->d_fileno; if (params->fstype->needswap) { ino = bswap32(ino); de->d_reclen = bswap16(de->d_reclen); } if (ino != 0 && strcmp(de->d_name, params->stage2) == 0) { *((uint32_t *)_ino) = ino; return (2); } if (de->d_reclen == 0) break; de = (struct direct *)((char *)de + de->d_reclen); } return (1); } struct findblks_state { uint32_t maxblk; uint32_t nblk; ib_block *blocks; }; /* This callback records the blocks of the secondary bootstrap. */ static int ffs_findstage2_blocks(ib_params *params, void *_state, uint64_t blk, uint32_t blksize) { struct findblks_state *state = _state; assert(params != NULL); assert(params->stage2 != NULL); assert(_state != NULL); if (state->nblk == state->maxblk) { warnx("Secondary bootstrap `%s' has too many blocks (max %d)", params->stage2, state->maxblk); return (0); } state->blocks[state->nblk].block = blk; state->blocks[state->nblk].blocksize = blksize; state->nblk++; return (1); } /* * publicly visible functions */ static off_t sblock_try[] = SBLOCKSEARCH; int ffs_match(ib_params *params) { return ffs_match_common(params, (off_t) 0); } int raid_match(ib_params *params) { /* XXX Assumes 512 bytes / sector */ if (params->sectorsize != 512) { warnx("Media is %d bytes/sector." " RAID is only supported on 512 bytes/sector media.", params->sectorsize); return 0; } return ffs_match_common(params, (off_t) RF_PROTECTED_SECTORS); } int ffs_match_common(ib_params *params, off_t offset) { char sbbuf[SBLOCKSIZE]; struct fs *fs; int i; off_t loc; assert(params != NULL); assert(params->fstype != NULL); fs = (struct fs *)sbbuf; for (i = 0; sblock_try[i] != -1; i++) { loc = sblock_try[i] / params->sectorsize + offset; if (!ffs_read_disk_block(params, loc, SBLOCKSIZE, sbbuf)) continue; switch (fs->fs_magic) { case FS_UFS2_MAGIC: is_ufs2 = 1; /* FALLTHROUGH */ case FS_UFS1_MAGIC: params->fstype->needswap = 0; params->fstype->blocksize = fs->fs_bsize; params->fstype->sblockloc = loc; params->fstype->offset = offset; break; #ifndef FFS_NO_SWAP case FS_UFS2_MAGIC_SWAPPED: is_ufs2 = 1; /* FALLTHROUGH */ case FS_UFS1_MAGIC_SWAPPED: params->fstype->needswap = 1; params->fstype->blocksize = bswap32(fs->fs_bsize); params->fstype->sblockloc = loc; params->fstype->offset = offset; break; #endif default: continue; } if (!is_ufs2 && sblock_try[i] == SBLOCK_UFS2) continue; return 1; } return (0); } int ffs_findstage2(ib_params *params, uint32_t *maxblk, ib_block *blocks) { int rv; uint32_t ino; struct findblks_state state; assert(params != NULL); assert(params->stage2 != NULL); assert(maxblk != NULL); assert(blocks != NULL); if (params->flags & IB_STAGE2START) return (hardcode_stage2(params, maxblk, blocks)); /* The secondary bootstrap must be clearly in /. */ if (params->stage2[0] == '/') params->stage2++; if (strchr(params->stage2, '/') != NULL) { warnx("The secondary bootstrap `%s' must be in /", params->stage2); warnx("(Path must be relative to the file system in `%s')", params->filesystem); return (0); } /* Get the inode number of the secondary bootstrap. */ if (is_ufs2) rv = ffs_find_disk_blocks_ufs2(params, UFS_ROOTINO, ffs_findstage2_ino, &ino); else rv = ffs_find_disk_blocks_ufs1(params, UFS_ROOTINO, ffs_findstage2_ino, &ino); if (rv != 2) { warnx("Could not find secondary bootstrap `%s' in `%s'", params->stage2, params->filesystem); warnx("(Path must be relative to the file system in `%s')", params->filesystem); return (0); } /* Record the disk blocks of the secondary bootstrap. */ state.maxblk = *maxblk; state.nblk = 0; state.blocks = blocks; if (is_ufs2) rv = ffs_find_disk_blocks_ufs2(params, ino, ffs_findstage2_blocks, &state); else rv = ffs_find_disk_blocks_ufs1(params, ino, ffs_findstage2_blocks, &state); if (! rv) { return (0); } *maxblk = state.nblk; return (1); }