/* boot.c - Read and analyze ia PC/MS-DOS boot sector Copyright (C) 1993 Werner Almesberger Copyright (C) 1998 Roman Hodek Copyright (C) 2008-2014 Daniel Baumann Copyright (C) 2015 Andreas Bombe This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . The complete text of the GNU General Public License can be found in /usr/share/common-licenses/GPL-3 file. */ /* FAT32, VFAT, Atari format support, and various fixes additions May 1998 * by Roman Hodek */ #include #include #include #include #include #include #include "common.h" #include "fsck.fat.h" #include "fat.h" #include "io.h" #include "boot.h" #include "check.h" #define ROUND_TO_MULTIPLE(n,m) ((n) && (m) ? (n)+(m)-1-((n)-1)%(m) : 0) /* don't divide by zero */ /* cut-over cluster counts for FAT12 and FAT16 */ #define FAT12_THRESHOLD 4085 #define FAT16_THRESHOLD 65525 static struct { uint8_t media; const char *descr; } mediabytes[] = { { 0xf0, "5.25\" or 3.5\" HD floppy"}, { 0xf8, "hard disk"}, { 0xf9, "3,5\" 720k floppy 2s/80tr/9sec or " "5.25\" 1.2M floppy 2s/80tr/15sec"}, { 0xfa, "5.25\" 320k floppy 1s/80tr/8sec"}, { 0xfb, "3.5\" 640k floppy 2s/80tr/8sec"}, { 0xfc, "5.25\" 180k floppy 1s/40tr/9sec"}, { 0xfd, "5.25\" 360k floppy 2s/40tr/9sec"}, { 0xfe, "5.25\" 160k floppy 1s/40tr/8sec"}, { 0xff, "5.25\" 320k floppy 2s/40tr/8sec"},}; /* Unaligned fields must first be accessed byte-wise */ #define GET_UNALIGNED_W(f) \ ( (uint16_t)f[0] | ((uint16_t)f[1]<<8) ) static const char *get_media_descr(unsigned char media) { int i; for (i = 0; i < sizeof(mediabytes) / sizeof(*mediabytes); ++i) { if (mediabytes[i].media == media) return (mediabytes[i].descr); } return ("undefined"); } static void dump_boot(DOS_FS * fs, struct boot_sector *b, unsigned lss) { unsigned short sectors; printf("Boot sector contents:\n"); if (!atari_format) { char id[9]; strncpy(id, (const char *)b->system_id, 8); id[8] = 0; printf("System ID \"%s\"\n", id); } else { /* On Atari, a 24 bit serial number is stored at offset 8 of the boot * sector */ printf("Serial number 0x%x\n", b->system_id[5] | (b->system_id[6] << 8) | (b-> system_id[7] << 16)); } printf("Media byte 0x%02x (%s)\n", b->media, get_media_descr(b->media)); printf("%10d bytes per logical sector\n", GET_UNALIGNED_W(b->sector_size)); printf("%10d bytes per cluster\n", fs->cluster_size); printf("%10d reserved sector%s\n", le16toh(b->reserved), le16toh(b->reserved) == 1 ? "" : "s"); printf("First FAT starts at byte %llu (sector %llu)\n", (unsigned long long)fs->fat_start, (unsigned long long)fs->fat_start / lss); printf("%10d FATs, %d bit entries\n", b->fats, fs->fat_bits); printf("%10lld bytes per FAT (= %llu sectors)\n", (long long)fs->fat_size, (long long)fs->fat_size / lss); if (!fs->root_cluster) { printf("Root directory starts at byte %llu (sector %llu)\n", (unsigned long long)fs->root_start, (unsigned long long)fs->root_start / lss); printf("%10d root directory entries\n", fs->root_entries); } else { printf("Root directory start at cluster %lu (arbitrary size)\n", (unsigned long)fs->root_cluster); } printf("Data area starts at byte %llu (sector %llu)\n", (unsigned long long)fs->data_start, (unsigned long long)fs->data_start / lss); printf("%10lu data clusters (%llu bytes)\n", (unsigned long)fs->data_clusters, (unsigned long long)fs->data_clusters * fs->cluster_size); printf("%u sectors/track, %u heads\n", le16toh(b->secs_track), le16toh(b->heads)); printf("%10u hidden sectors\n", atari_format ? /* On Atari, the hidden field is only 16 bit wide and unused */ (((unsigned char *)&b->hidden)[0] | ((unsigned char *)&b->hidden)[1] << 8) : le32toh(b->hidden)); sectors = GET_UNALIGNED_W(b->sectors); printf("%10u sectors total\n", sectors ? sectors : le32toh(b->total_sect)); } static void check_backup_boot(DOS_FS * fs, struct boot_sector *b, unsigned int lss) { struct boot_sector b2; if (!fs->backupboot_start) { printf("There is no backup boot sector.\n"); if (le16toh(b->reserved) < 3) { printf("And there is no space for creating one!\n"); return; } if (interactive) printf("1) Create one\n2) Do without a backup\n"); else printf(" Auto-creating backup boot block.\n"); if (!interactive || get_key("12", "?") == '1') { unsigned int bbs; /* The usual place for the backup boot sector is sector 6. Choose * that or the last reserved sector. */ if (le16toh(b->reserved) >= 7 && le16toh(b->info_sector) != 6) bbs = 6; else { bbs = le16toh(b->reserved) - 1; if (bbs == le16toh(b->info_sector)) --bbs; /* this is never 0, as we checked reserved >= 3! */ } fs->backupboot_start = bbs * lss; b->backup_boot = htole16(bbs); fs_write(fs->backupboot_start, sizeof(*b), b); fs_write(offsetof(struct boot_sector, backup_boot), sizeof(b->backup_boot), &b->backup_boot); printf("Created backup of boot sector in sector %d\n", bbs); return; } else return; } fs_read(fs->backupboot_start, sizeof(b2), &b2); if (memcmp(b, &b2, sizeof(b2)) != 0) { /* there are any differences */ uint8_t *p, *q; int i, pos, first = 1; char buf[20]; printf("There are differences between boot sector and its backup.\n"); printf("This is mostly harmless. Differences: (offset:original/backup)\n "); pos = 2; for (p = (uint8_t *) b, q = (uint8_t *) & b2, i = 0; i < sizeof(b2); ++p, ++q, ++i) { if (*p != *q) { sprintf(buf, "%s%u:%02x/%02x", first ? "" : ", ", (unsigned)(p - (uint8_t *) b), *p, *q); if (pos + strlen(buf) > 78) printf("\n "), pos = 2; printf("%s", buf); pos += strlen(buf); first = 0; } } printf("\n"); if (interactive) printf("1) Copy original to backup\n" "2) Copy backup to original\n" "3) No action\n"); else printf(" Not automatically fixing this.\n"); switch (interactive ? get_key("123", "?") : '3') { case '1': fs_write(fs->backupboot_start, sizeof(*b), b); break; case '2': fs_write(0, sizeof(b2), &b2); break; default: break; } } } static void init_fsinfo(struct info_sector *i) { memset(i, 0, sizeof (struct info_sector)); i->magic = htole32(0x41615252); i->signature = htole32(0x61417272); i->free_clusters = htole32(-1); i->next_cluster = htole32(2); i->boot_sign = htole32(0xaa550000); } static void read_fsinfo(DOS_FS * fs, struct boot_sector *b, unsigned int lss) { struct info_sector i; if (!b->info_sector) { printf("No FSINFO sector\n"); if (interactive) printf("1) Create one\n2) Do without FSINFO\n"); else printf(" Not automatically creating it.\n"); if (interactive && get_key("12", "?") == '1') { /* search for a free reserved sector (not boot sector and not * backup boot sector) */ uint32_t s; for (s = 1; s < le16toh(b->reserved); ++s) if (s != le16toh(b->backup_boot)) break; if (s > 0 && s < le16toh(b->reserved)) { init_fsinfo(&i); fs_write((off_t)s * lss, sizeof(i), &i); b->info_sector = htole16(s); fs_write(offsetof(struct boot_sector, info_sector), sizeof(b->info_sector), &b->info_sector); if (fs->backupboot_start) fs_write(fs->backupboot_start + offsetof(struct boot_sector, info_sector), sizeof(b->info_sector), &b->info_sector); } else { printf("No free reserved sector found -- " "no space for FSINFO sector!\n"); return; } } else return; } fs->fsinfo_start = le16toh(b->info_sector) * lss; fs_read(fs->fsinfo_start, sizeof(i), &i); if (i.magic != htole32(0x41615252) || i.signature != htole32(0x61417272) || i.boot_sign != htole32(0xaa550000)) { printf("FSINFO sector has bad magic number(s):\n"); if (i.magic != htole32(0x41615252)) printf(" Offset %llu: 0x%08x != expected 0x%08x\n", (unsigned long long)offsetof(struct info_sector, magic), le32toh(i.magic), 0x41615252); if (i.signature != htole32(0x61417272)) printf(" Offset %llu: 0x%08x != expected 0x%08x\n", (unsigned long long)offsetof(struct info_sector, signature), le32toh(i.signature), 0x61417272); if (i.boot_sign != htole32(0xaa550000)) printf(" Offset %llu: 0x%08x != expected 0x%08x\n", (unsigned long long)offsetof(struct info_sector, boot_sign), le32toh(i.boot_sign), 0xaa550000); if (interactive) printf("1) Correct\n2) Don't correct (FSINFO invalid then)\n"); else printf(" Auto-correcting it.\n"); if (!interactive || get_key("12", "?") == '1') { init_fsinfo(&i); fs_write(fs->fsinfo_start, sizeof(i), &i); } else fs->fsinfo_start = 0; } if (fs->fsinfo_start) fs->free_clusters = le32toh(i.free_clusters); } static char print_fat_dirty_state(void) { printf("Dirty bit is set. Fs was not properly unmounted and" " some data may be corrupt.\n"); if (interactive) { printf("1) Remove dirty bit\n" "2) No action\n"); return get_key("12", "?"); } else printf(" Automatically removing dirty bit.\n"); return '1'; } static void check_fat_state_bit(DOS_FS * fs, void *b) { if (fs->fat_bits == 32) { struct boot_sector *b32 = b; if (b32->reserved3 & FAT_STATE_DIRTY) { printf("0x41: "); if (print_fat_dirty_state() == '1') { b32->reserved3 &= ~FAT_STATE_DIRTY; fs_write(0, sizeof(*b32), b32); } } } else { struct boot_sector_16 *b16 = b; if (b16->reserved2 & FAT_STATE_DIRTY) { printf("0x25: "); if (print_fat_dirty_state() == '1') { b16->reserved2 &= ~FAT_STATE_DIRTY; fs_write(0, sizeof(*b16), b16); } } } } void read_boot(DOS_FS * fs) { struct boot_sector b; unsigned total_sectors; unsigned int logical_sector_size, sectors; off_t fat_length; unsigned total_fat_entries; off_t data_size; fs_read(0, sizeof(b), &b); logical_sector_size = GET_UNALIGNED_W(b.sector_size); if (!logical_sector_size) die("Logical sector size is zero."); /* This was moved up because it's the first thing that will fail */ /* if the platform needs special handling of unaligned multibyte accesses */ /* but such handling isn't being provided. See GET_UNALIGNED_W() above. */ if (logical_sector_size & (SECTOR_SIZE - 1)) die("Logical sector size (%d bytes) is not a multiple of the physical " "sector size.", logical_sector_size); fs->cluster_size = b.cluster_size * logical_sector_size; if (!fs->cluster_size) die("Cluster size is zero."); if (b.fats != 2 && b.fats != 1) die("Currently, only 1 or 2 FATs are supported, not %d.\n", b.fats); fs->nfats = b.fats; sectors = GET_UNALIGNED_W(b.sectors); total_sectors = sectors ? sectors : le32toh(b.total_sect); if (verbose) printf("Checking we can access the last sector of the filesystem\n"); /* Can't access last odd sector anyway, so round down */ fs_test((off_t)((total_sectors & ~1) - 1) * logical_sector_size, logical_sector_size); fat_length = le16toh(b.fat_length) ? le16toh(b.fat_length) : le32toh(b.fat32_length); if (!fat_length) die("FAT size is zero."); fs->fat_start = (off_t)le16toh(b.reserved) * logical_sector_size; fs->root_start = ((off_t)le16toh(b.reserved) + b.fats * fat_length) * logical_sector_size; fs->root_entries = GET_UNALIGNED_W(b.dir_entries); fs->data_start = fs->root_start + ROUND_TO_MULTIPLE(fs->root_entries << MSDOS_DIR_BITS, logical_sector_size); data_size = (off_t)total_sectors * logical_sector_size - fs->data_start; if (data_size < fs->cluster_size) die("Filesystem has no space for any data clusters"); fs->data_clusters = data_size / fs->cluster_size; fs->root_cluster = 0; /* indicates standard, pre-FAT32 root dir */ fs->fsinfo_start = 0; /* no FSINFO structure */ fs->free_clusters = -1; /* unknown */ if (!b.fat_length && b.fat32_length) { fs->fat_bits = 32; fs->root_cluster = le32toh(b.root_cluster); if (!fs->root_cluster && fs->root_entries) /* M$ hasn't specified this, but it looks reasonable: If * root_cluster is 0 but there is a separate root dir * (root_entries != 0), we handle the root dir the old way. Give a * warning, but convertig to a root dir in a cluster chain seems * to complex for now... */ printf("Warning: FAT32 root dir not in cluster chain! " "Compatibility mode...\n"); else if (!fs->root_cluster && !fs->root_entries) die("No root directory!"); else if (fs->root_cluster && fs->root_entries) printf("Warning: FAT32 root dir is in a cluster chain, but " "a separate root dir\n" " area is defined. Cannot fix this easily.\n"); if (fs->data_clusters < FAT16_THRESHOLD) printf("Warning: Filesystem is FAT32 according to fat_length " "and fat32_length fields,\n" " but has only %lu clusters, less than the required " "minimum of %d.\n" " This may lead to problems on some systems.\n", (unsigned long)fs->data_clusters, FAT16_THRESHOLD); check_fat_state_bit(fs, &b); fs->backupboot_start = le16toh(b.backup_boot) * logical_sector_size; check_backup_boot(fs, &b, logical_sector_size); read_fsinfo(fs, &b, logical_sector_size); } else if (!atari_format) { /* On real MS-DOS, a 16 bit FAT is used whenever there would be too * much clusers otherwise. */ fs->fat_bits = (fs->data_clusters >= FAT12_THRESHOLD) ? 16 : 12; if (fs->data_clusters >= FAT16_THRESHOLD) die("Too many clusters (%lu) for FAT16 filesystem.", (unsigned long)fs->data_clusters); check_fat_state_bit(fs, &b); } else { /* On Atari, things are more difficult: GEMDOS always uses 12bit FATs * on floppies, and always 16 bit on harddisks. */ fs->fat_bits = 16; /* assume 16 bit FAT for now */ /* If more clusters than fat entries in 16-bit fat, we assume * it's a real MSDOS FS with 12-bit fat. */ if (fs->data_clusters + 2 > fat_length * logical_sector_size * 8 / 16 || /* if it has one of the usual floppy sizes -> 12bit FAT */ (total_sectors == 720 || total_sectors == 1440 || total_sectors == 2880)) fs->fat_bits = 12; } /* On FAT32, the high 4 bits of a FAT entry are reserved */ fs->eff_fat_bits = (fs->fat_bits == 32) ? 28 : fs->fat_bits; fs->fat_size = fat_length * logical_sector_size; fs->label = calloc(12, sizeof(uint8_t)); if (fs->fat_bits == 12 || fs->fat_bits == 16) { struct boot_sector_16 *b16 = (struct boot_sector_16 *)&b; if (b16->extended_sig == 0x29) memmove(fs->label, b16->label, 11); else fs->label = NULL; } else if (fs->fat_bits == 32) { if (b.extended_sig == 0x29) memmove(fs->label, &b.label, 11); else fs->label = NULL; } total_fat_entries = (uint64_t)fs->fat_size * 8 / fs->fat_bits; if (fs->data_clusters > total_fat_entries - 2) die("Filesystem has %u clusters but only space for %u FAT entries.", fs->data_clusters, total_fat_entries - 2); if (!fs->root_entries && !fs->root_cluster) die("Root directory has zero size."); if (fs->root_entries & (MSDOS_DPS - 1)) die("Root directory (%d entries) doesn't span an integral number of " "sectors.", fs->root_entries); if (logical_sector_size & (SECTOR_SIZE - 1)) die("Logical sector size (%u bytes) is not a multiple of the physical " "sector size.", logical_sector_size); #if 0 /* linux kernel doesn't check that either */ /* ++roman: On Atari, these two fields are often left uninitialized */ if (!atari_format && (!b.secs_track || !b.heads)) die("Invalid disk format in boot sector."); #endif if (verbose) dump_boot(fs, &b, logical_sector_size); } static void write_boot_label(DOS_FS * fs, char *label) { if (fs->fat_bits == 12 || fs->fat_bits == 16) { struct boot_sector_16 b16; fs_read(0, sizeof(b16), &b16); if (b16.extended_sig != 0x29) { b16.extended_sig = 0x29; b16.serial = 0; memmove(b16.fs_type, fs->fat_bits == 12 ? "FAT12 " : "FAT16 ", 8); } memmove(b16.label, label, 11); fs_write(0, sizeof(b16), &b16); } else if (fs->fat_bits == 32) { struct boot_sector b; fs_read(0, sizeof(b), &b); if (b.extended_sig != 0x29) { b.extended_sig = 0x29; b.serial = 0; memmove(b.fs_type, "FAT32 ", 8); } memmove(b.label, label, 11); fs_write(0, sizeof(b), &b); if (fs->backupboot_start) fs_write(fs->backupboot_start, sizeof(b), &b); } } off_t find_volume_de(DOS_FS * fs, DIR_ENT * de) { uint32_t cluster; off_t offset; int i; if (fs->root_cluster) { for (cluster = fs->root_cluster; cluster != 0 && cluster != -1; cluster = next_cluster(fs, cluster)) { offset = cluster_start(fs, cluster); for (i = 0; i * sizeof(DIR_ENT) < fs->cluster_size; i++) { fs_read(offset, sizeof(DIR_ENT), de); if (de->attr != VFAT_LN_ATTR && de->attr & ATTR_VOLUME) return offset; offset += sizeof(DIR_ENT); } } } else { for (i = 0; i < fs->root_entries; i++) { offset = fs->root_start + i * sizeof(DIR_ENT); fs_read(offset, sizeof(DIR_ENT), de); if (de->attr != VFAT_LN_ATTR && de->attr & ATTR_VOLUME) return offset; } } return 0; } static void write_volume_label(DOS_FS * fs, char *label) { time_t now = time(NULL); struct tm *mtime = localtime(&now); off_t offset; int created; DIR_ENT de; created = 0; offset = find_volume_de(fs, &de); if (offset == 0) { created = 1; offset = alloc_rootdir_entry(fs, &de, label, 0); } memcpy(de.name, label, 11); de.time = htole16((unsigned short)((mtime->tm_sec >> 1) + (mtime->tm_min << 5) + (mtime->tm_hour << 11))); de.date = htole16((unsigned short)(mtime->tm_mday + ((mtime->tm_mon + 1) << 5) + ((mtime->tm_year - 80) << 9))); if (created) { de.attr = ATTR_VOLUME; de.ctime_ms = 0; de.ctime = de.time; de.cdate = de.date; de.adate = de.date; de.starthi = 0; de.start = 0; de.size = 0; } fs_write(offset, sizeof(DIR_ENT), &de); } void write_label(DOS_FS * fs, char *label) { int l = strlen(label); while (l < 11) label[l++] = ' '; write_boot_label(fs, label); write_volume_label(fs, label); }