/* mkfs.fat.c - utility to create FAT/MS-DOS filesystems Copyright (C) 1991 Linus Torvalds Copyright (C) 1992-1993 Remy Card Copyright (C) 1993-1994 David Hudson Copyright (C) 1998 H. Peter Anvin Copyright (C) 1998-2005 Roman Hodek Copyright (C) 2008-2014 Daniel Baumann Copyright (C) 2015-2016 Andreas Bombe Copyright (C) 2018 Pali Rohár 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. */ /* Description: Utility to allow an MS-DOS filesystem to be created under Linux. A lot of the basic structure of this program has been borrowed from Remy Card's "mke2fs" code. As far as possible the aim here is to make the "mkfs.fat" command look almost identical to the other Linux filesystem make utilties, eg bad blocks are still specified as blocks, not sectors, but when it comes down to it, DOS is tied to the idea of a sector (512 bytes as a rule), and not the block. For example the boot block does not occupy a full cluster. Fixes/additions May 1998 by Roman Hodek : - Atari format support - New options -A, -S, -C - Support for filesystems > 2GB - FAT32 support */ /* Include the header files */ #include "version.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "endian_compat.h" #include "common.h" #include "msdos_fs.h" #include "device_info.h" #include "charconv.h" /* Constant definitions */ #define TRUE 1 /* Boolean constants */ #define FALSE 0 #define TEST_BUFFER_BLOCKS 16 #define BLOCK_SIZE 1024 #define HARD_SECTOR_SIZE 512 #define SECTORS_PER_BLOCK ( BLOCK_SIZE / HARD_SECTOR_SIZE ) #define NO_NAME "NO NAME " /* Macro definitions */ /* Mark a cluster in the FAT as bad */ #define mark_sector_bad( sector ) mark_FAT_sector( sector, FAT_BAD ) /* Compute ceil(a/b) */ static inline int cdiv(int a, int b) { return (a + b - 1) / b; } /* FAT values */ #define FAT_EOF (atari_format ? 0x0fffffff : 0x0ffffff8) #define FAT_BAD 0x0ffffff7 #define MSDOS_EXT_SIGN 0x29 /* extended boot sector signature */ #define MSDOS_FAT12_SIGN "FAT12 " /* FAT12 filesystem signature */ #define MSDOS_FAT16_SIGN "FAT16 " /* FAT16 filesystem signature */ #define MSDOS_FAT32_SIGN "FAT32 " /* FAT32 filesystem signature */ #define BOOT_SIGN 0xAA55 /* Boot sector magic number */ /* According to Microsoft FAT specification (fatgen103.doc) disk with * 4085 clusters (or more) is FAT16, but Microsoft Windows FAT driver * fastfat.sys detects disk with less then 4087 clusters as FAT12. * Linux FAT drivers msdos.ko and vfat.ko detect disk with at least * 4085 clusters as FAT16, therefore for compatibility reasons with * both systems disallow formatting disks to 4085 or 4086 clusters. */ #define MAX_CLUST_12 4084 #define MIN_CLUST_16 4087 /* According to Microsoft FAT specification (fatgen103.doc) disk with * 65525 clusters (or more) is FAT32, but Microsoft Windows FAT driver * fastfat.sys, Linux FAT drivers msdos.ko and vfat.ko detect disk as * FAT32 when Sectors Per FAT (fat_length) is set to zero. And not by * number of clusters. Still there is cluster upper limit for FAT16. */ #define MAX_CLUST_16 65524 #define MIN_CLUST_32 65525 /* M$ says the high 4 bits of a FAT32 FAT entry are reserved and don't belong * to the cluster number. So the max. cluster# is based on 2^28 */ #define MAX_CLUST_32 268435446 #define OLDGEMDOS_MAX_SECTORS 32765 #define GEMDOS_MAX_SECTORS 65531 #define GEMDOS_MAX_SECTOR_SIZE (16*1024) #define BOOTCODE_SIZE 448 #define BOOTCODE_FAT32_SIZE 420 /* __attribute__ ((packed)) is used on all structures to make gcc ignore any * alignments */ struct msdos_volume_info { uint8_t drive_number; /* BIOS drive number */ uint8_t boot_flags; /* bit 0: dirty, bit 1: need surface test */ uint8_t ext_boot_sign; /* 0x29 if fields below exist (DOS 3.3+) */ uint8_t volume_id[4]; /* Volume ID number */ uint8_t volume_label[11]; /* Volume label */ uint8_t fs_type[8]; /* Typically FAT12 or FAT16 */ } __attribute__ ((packed)); struct msdos_boot_sector { uint8_t boot_jump[3]; /* Boot strap short or near jump */ uint8_t system_id[8]; /* Name - can be used to special case partition manager volumes */ uint8_t sector_size[2]; /* bytes per logical sector */ uint8_t cluster_size; /* sectors/cluster */ uint16_t reserved; /* reserved sectors */ uint8_t fats; /* number of FATs */ uint8_t dir_entries[2]; /* root directory entries */ uint8_t sectors[2]; /* number of sectors */ uint8_t media; /* media code (unused) */ uint16_t fat_length; /* sectors/FAT */ uint16_t secs_track; /* sectors per track */ uint16_t heads; /* number of heads */ uint32_t hidden; /* hidden sectors (unused) */ uint32_t total_sect; /* number of sectors (if sectors == 0) */ union { struct { struct msdos_volume_info vi; uint8_t boot_code[BOOTCODE_SIZE]; } __attribute__ ((packed)) _oldfat; struct { uint32_t fat32_length; /* sectors/FAT */ uint16_t flags; /* bit 8: fat mirroring, low 4: active fat */ uint8_t version[2]; /* major, minor filesystem version */ uint32_t root_cluster; /* first cluster in root directory */ uint16_t info_sector; /* filesystem info sector */ uint16_t backup_boot; /* backup boot sector */ uint16_t reserved2[6]; /* Unused */ struct msdos_volume_info vi; uint8_t boot_code[BOOTCODE_FAT32_SIZE]; } __attribute__ ((packed)) _fat32; } __attribute__ ((packed)) fstype; uint16_t boot_sign; } __attribute__ ((packed)); #define fat32 fstype._fat32 #define oldfat fstype._oldfat struct fat32_fsinfo { uint32_t reserved1; /* Nothing as far as I can tell */ uint32_t signature; /* 0x61417272L */ uint32_t free_clusters; /* Free cluster count. -1 if unknown */ uint32_t next_cluster; /* Most recently allocated cluster. * Unused under Linux. */ uint32_t reserved2[4]; } __attribute__ ((packed)); /* The "boot code" we put into the filesystem... it writes a message and tells the user to try again. This "boot code" is in the public domain. */ unsigned char dummy_boot_jump[3] = { 0xeb, 0x3c, 0x90 }; unsigned char dummy_boot_jump_m68k[2] = { 0x60, 0x1c }; #define MSG_OFFSET_OFFSET 3 char dummy_boot_code[BOOTCODE_SIZE] = "\x0e" /* push cs */ "\x1f" /* pop ds */ "\xbe\x5b\x7c" /* mov si, offset message_txt */ /* write_msg: */ "\xac" /* lodsb */ "\x22\xc0" /* and al, al */ "\x74\x0b" /* jz key_press */ "\x56" /* push si */ "\xb4\x0e" /* mov ah, 0eh */ "\xbb\x07\x00" /* mov bx, 0007h */ "\xcd\x10" /* int 10h */ "\x5e" /* pop si */ "\xeb\xf0" /* jmp write_msg */ /* key_press: */ "\x32\xe4" /* xor ah, ah */ "\xcd\x16" /* int 16h */ "\xcd\x19" /* int 19h */ "\xeb\xfe" /* foo: jmp foo */ /* message_txt: */ "This is not a bootable disk. Please insert a bootable floppy and\r\n" "press any key to try again ... \r\n"; #define MESSAGE_OFFSET 29 /* Offset of message in above code */ static char initial_volume_name[] = NO_NAME; /* Initial volume name, make sure that is writable */ /* Global variables - the root of all evil :-) - see these and weep! */ static char *device_name = NULL; /* Name of the device on which to create the filesystem */ static int check = FALSE; /* Default to no readablity checking */ static int verbose = 0; /* Default to verbose mode off */ static long volume_id; /* Volume ID number */ static time_t create_time = -1; /* Creation time */ static char *volume_name = initial_volume_name; /* Volume name */ static unsigned long long blocks; /* Number of blocks in filesystem */ static unsigned sector_size = 512; /* Size of a logical sector */ static int sector_size_set = 0; /* User selected sector size */ static int backup_boot = 0; /* Sector# of backup boot sector */ static int backup_boot_set = 0; /* User selected backup boot sector */ static int info_sector = 0; /* Sector# of FAT32 info sector */ static int reserved_sectors = 0; /* Number of reserved sectors */ static int badblocks = 0; /* Number of bad blocks in the filesystem */ static int nr_fats = 2; /* Default number of FATs to produce */ static int size_fat = 0; /* Size in bits of FAT entries */ static int size_fat_by_user = 0; /* 1 if FAT size user selected */ static int dev = -1; /* FS block device file handle */ static off_t part_sector = 0; /* partition offset in sector */ static int ignore_safety_checks = 0; /* Ignore safety checks */ static off_t currently_testing = 0; /* Block currently being tested (if autodetect bad blocks) */ static struct msdos_boot_sector bs; /* Boot sector data */ static int start_data_sector; /* Sector number for the start of the data area */ static int start_data_block; /* Block number for the start of the data area */ static unsigned char *fat; /* File allocation table */ static unsigned alloced_fat_length; /* # of FAT sectors we can keep in memory */ static unsigned fat_entries; /* total entries in FAT table (including reserved) */ static unsigned char *info_sector_buffer; /* FAT32 info sector */ static struct msdos_dir_entry *root_dir; /* Root directory */ static int size_root_dir; /* Size of the root directory in bytes */ static uint32_t num_sectors; /* Total number of sectors in device */ static int sectors_per_cluster = 0; /* Number of sectors per disk cluster */ static int root_dir_entries = 0; /* Number of root directory entries */ static int root_dir_entries_set = 0; /* User selected root directory size */ static char *blank_sector; /* Blank sector - all zeros */ static unsigned hidden_sectors = 0; /* Number of hidden sectors */ static int hidden_sectors_by_user = 0; /* -h option invoked */ static int drive_number_option = 0; /* drive number */ static int drive_number_by_user = 0; /* drive number option invoked */ static int fat_media_byte = 0; /* media byte in header and starting FAT */ static int malloc_entire_fat = FALSE; /* Whether we should malloc() the entire FAT or not */ static int align_structures = TRUE; /* Whether to enforce alignment */ static int orphaned_sectors = 0; /* Sectors that exist in the last block of filesystem */ static int invariant = 0; /* Whether to set normally randomized or current time based values to constants */ static int fill_mbr_partition = -1; /* Whether to fill MBR partition table or not */ /* Function prototype definitions */ static void mark_FAT_cluster(int cluster, unsigned int value); static void mark_FAT_sector(int sector, unsigned int value); static long do_check(char *buffer, int try, off_t current_block); static void alarm_intr(int alnum); static void check_blocks(void); static void get_list_blocks(char *filename); static void check_mount(char *device_name); static void establish_params(struct device_info *info); static void setup_tables(void); static void write_tables(void); /* The function implementations */ /* Mark the specified cluster as having a particular value */ static void mark_FAT_cluster(int cluster, unsigned int value) { if (cluster < 0 || cluster >= fat_entries) die("Internal error: out of range cluster number in mark_FAT_cluster"); switch (size_fat) { case 12: value &= 0x0fff; if (((cluster * 3) & 0x1) == 0) { fat[3 * cluster / 2] = (unsigned char)(value & 0x00ff); fat[(3 * cluster / 2) + 1] = (unsigned char)((fat[(3 * cluster / 2) + 1] & 0x00f0) | ((value & 0x0f00) >> 8)); } else { fat[3 * cluster / 2] = (unsigned char)((fat[3 * cluster / 2] & 0x000f) | ((value & 0x000f) << 4)); fat[(3 * cluster / 2) + 1] = (unsigned char)((value & 0x0ff0) >> 4); } break; case 16: value &= 0xffff; fat[2 * cluster] = (unsigned char)(value & 0x00ff); fat[(2 * cluster) + 1] = (unsigned char)(value >> 8); break; case 32: value &= 0xfffffff; fat[4 * cluster] = (unsigned char)(value & 0x000000ff); fat[(4 * cluster) + 1] = (unsigned char)((value & 0x0000ff00) >> 8); fat[(4 * cluster) + 2] = (unsigned char)((value & 0x00ff0000) >> 16); fat[(4 * cluster) + 3] = (unsigned char)((value & 0xff000000) >> 24); break; default: die("Bad FAT size (not 12, 16, or 32)"); } } /* Mark a specified sector as having a particular value in it's FAT entry */ static void mark_FAT_sector(int sector, unsigned int value) { int cluster = (sector - start_data_sector) / (int)(bs.cluster_size) / (sector_size / HARD_SECTOR_SIZE) + 2; if (sector < start_data_sector || sector >= num_sectors) die("Internal error: out of range sector number in mark_FAT_sector"); mark_FAT_cluster(cluster, value); } /* Perform a test on a block. Return the number of blocks that could be read successfully */ static long do_check(char *buffer, int try, off_t current_block) { long got; if (lseek(dev, part_sector * sector_size + current_block * BLOCK_SIZE, SEEK_SET) /* Seek to the correct location */ !=current_block * BLOCK_SIZE) die("seek failed during testing for blocks"); got = read(dev, buffer, try * BLOCK_SIZE); /* Try reading! */ if (got < 0) got = 0; if (got & (BLOCK_SIZE - 1)) printf("Unexpected values in do_check: probably bugs\n"); got /= BLOCK_SIZE; return got; } /* Alarm clock handler - display the status of the quest for bad blocks! Then retrigger the alarm for five senconds later (so we can come here again) */ static void alarm_intr(int alnum) { (void)alnum; if (currently_testing >= blocks) return; signal(SIGALRM, alarm_intr); alarm(5); if (!currently_testing) return; printf("%lld... ", (unsigned long long)currently_testing); fflush(stdout); } static void check_blocks(void) { int try, got; int i; static char blkbuf[BLOCK_SIZE * TEST_BUFFER_BLOCKS]; if (verbose) { printf("Searching for bad blocks "); fflush(stdout); } currently_testing = 0; if (verbose) { signal(SIGALRM, alarm_intr); alarm(5); } try = TEST_BUFFER_BLOCKS; while (currently_testing < blocks) { if (currently_testing + try > blocks) try = blocks - currently_testing; /* TODO: check overflow */ got = do_check(blkbuf, try, currently_testing); currently_testing += got; if (got == try) { try = TEST_BUFFER_BLOCKS; continue; } else try = 1; if (currently_testing < start_data_block) die("bad blocks before data-area: cannot make fs"); for (i = 0; i < SECTORS_PER_BLOCK; i++) /* Mark all of the sectors in the block as bad */ mark_sector_bad(currently_testing * SECTORS_PER_BLOCK + i); badblocks++; currently_testing++; } if (verbose) printf("\n"); if (badblocks) printf("%d bad block%s\n", badblocks, (badblocks > 1) ? "s" : ""); } static void get_list_blocks(char *filename) { int i; FILE *listfile; long long blockno; char *line = NULL; size_t linesize = 0; int lineno = 0; char *end, *check; listfile = fopen(filename, "r"); if (listfile == (FILE *) NULL) die("Can't open file of bad blocks"); while (1) { lineno++; ssize_t length = getline(&line, &linesize, listfile); if (length < 0) { if (errno == 0) /* end of file */ break; perror("getline"); die("Error while reading bad blocks file"); } errno = 0; blockno = strtoll(line, &end, 10); if (errno || blockno < 0) { fprintf(stderr, "While converting bad block number in line %d: %s\n", lineno, strerror(errno)); die("Error in bad blocks file"); } check = end; while (*check) { if (!isspace(*check)) { fprintf(stderr, "Badly formed number in bad blocks file line %d\n", lineno); die("Error in bad blocks file"); } check++; } /* ignore empty or white space only lines */ if (end == line) continue; /* Mark all of the sectors in the block as bad */ for (i = 0; i < SECTORS_PER_BLOCK; i++) { unsigned long long sector = blockno * SECTORS_PER_BLOCK + i; if (sector < start_data_sector) { fprintf(stderr, "Block number %lld is before data area\n", blockno); die("Error in bad blocks file"); } if (sector >= num_sectors) { fprintf(stderr, "Block number %lld is behind end of filesystem\n", blockno); die("Error in bad blocks file"); } mark_sector_bad(sector); } badblocks++; } fclose(listfile); free(line); if (badblocks) printf("%d bad block%s\n", badblocks, (badblocks > 1) ? "s" : ""); } /* Check to see if the specified device is currently mounted - abort if it is */ static void check_mount(char *device_name) { if (is_device_mounted(device_name)) die("%s contains a mounted filesystem.", device_name); } /* Establish the geometry and media parameters for the device */ static void establish_params(struct device_info *info) { unsigned int sec_per_track; unsigned int heads; unsigned int media = 0xf8; unsigned int cluster_size = 4; /* starting point for FAT12 and FAT16 */ int def_root_dir_entries = 512; if (info->geom_heads > 0) { heads = info->geom_heads; sec_per_track = info->geom_sectors; } else { unsigned long long int total_sectors; if (info->geom_size > 0) total_sectors = info->geom_size; else if (info->sector_size > 0) total_sectors = info->size / info->sector_size; else total_sectors = info->size / sector_size; if (total_sectors <= 524288) { /* For capacity below the 256MB (with 512b sectors) use CHS Recommendation from SD Card Part 2 File System Specification */ heads = total_sectors <= 32768 ? 2 : total_sectors <= 65536 ? 4 : total_sectors <= 262144 ? 8 : 16; sec_per_track = total_sectors <= 4096 ? 16 : 32; } else { /* Use LBA-Assist Translation for calculating CHS when disk geometry is not available */ heads = total_sectors <= 16*63*1024 ? 16 : total_sectors <= 32*63*1024 ? 32 : total_sectors <= 64*63*1024 ? 64 : total_sectors <= 128*63*1024 ? 128 : 255; sec_per_track = 63; } } if (info->type != TYPE_FIXED) { /* enter default parameters for floppy disks if the size matches */ switch (info->size / 1024) { case 360: sec_per_track = 9; heads = 2; media = 0xfd; cluster_size = 2; def_root_dir_entries = 112; break; case 720: sec_per_track = 9; heads = 2; media = 0xf9; cluster_size = 2; def_root_dir_entries = 112; break; case 1200: sec_per_track = 15; heads = 2; media = 0xf9; cluster_size = (atari_format ? 2 : 1); def_root_dir_entries = 224; break; case 1440: sec_per_track = 18; heads = 2; media = 0xf0; cluster_size = (atari_format ? 2 : 1); def_root_dir_entries = 224; break; case 2880: sec_per_track = 36; heads = 2; media = 0xf0; cluster_size = 2; def_root_dir_entries = 224; break; } } if (!size_fat && info->size >= 512 * 1024 * 1024) { if (verbose) printf("Auto-selecting FAT32 for large filesystem\n"); size_fat = 32; } if (size_fat == 32) { /* * For FAT32, try to do the same as M$'s format command * (see http://www.win.tue.nl/~aeb/linux/fs/fat/fatgen103.pdf p. 20): * fs size <= 260M: 0.5k clusters * fs size <= 8G: 4k clusters * fs size <= 16G: 8k clusters * fs size <= 32G: 16k clusters * fs size > 32G: 32k clusters */ unsigned long long int sectors = info->size / sector_size; cluster_size = sectors > 32*1024*1024*2 ? 64 : sectors > 16*1024*1024*2 ? 32 : sectors > 8*1024*1024*2 ? 16 : sectors > 260*1024*2 ? 8 : 1; } if (!hidden_sectors_by_user && info->geom_start >= 0 && info->geom_start + part_sector <= UINT32_MAX) hidden_sectors = info->geom_start + part_sector; if (!root_dir_entries) root_dir_entries = def_root_dir_entries; if (!bs.secs_track) bs.secs_track = htole16(sec_per_track); if (!bs.heads) bs.heads = htole16(heads); bs.media = media; bs.cluster_size = cluster_size; } /* * If alignment is enabled, round the first argument up to the second; the * latter must be a power of two. */ static unsigned int align_object(unsigned int sectors, unsigned int clustsize) { if (align_structures) return (sectors + clustsize - 1) & ~(clustsize - 1); else return sectors; } /* Create the filesystem data tables */ static void setup_tables(void) { unsigned cluster_count = 0, fat_length; struct tm *ctime; struct msdos_volume_info *vi = (size_fat == 32 ? &bs.fat32.vi : &bs.oldfat.vi); char label[12] = { 0 }; size_t len; int ret; int i; if (atari_format) { /* On Atari, the first few bytes of the boot sector are assigned * differently: The jump code is only 2 bytes (and m68k machine code * :-), then 6 bytes filler (ignored), then 3 byte serial number. */ bs.boot_jump[2] = 'm'; memcpy((char *)bs.system_id, "kdosf", strlen("kdosf")); } else memcpy((char *)bs.system_id, "mkfs.fat", strlen("mkfs.fat")); if (sectors_per_cluster) bs.cluster_size = (char)sectors_per_cluster; if (fat_media_byte) bs.media = (char) fat_media_byte; if (bs.media == 0xf8) vi->drive_number=0x80; else vi->drive_number=0x00; if (drive_number_by_user) vi->drive_number= (char) drive_number_option; if (size_fat == 32) { /* Under FAT32, the root dir is in a cluster chain, and this is * signalled by bs.dir_entries being 0. */ if (root_dir_entries_set) fprintf(stderr, "Warning: root directory entries specified with -r have no effect on FAT32\n"); root_dir_entries = 0; } if (atari_format) { bs.system_id[5] = (unsigned char)(volume_id & 0x000000ff); bs.system_id[6] = (unsigned char)((volume_id & 0x0000ff00) >> 8); bs.system_id[7] = (unsigned char)((volume_id & 0x00ff0000) >> 16); } else { vi->volume_id[0] = (unsigned char)(volume_id & 0x000000ff); vi->volume_id[1] = (unsigned char)((volume_id & 0x0000ff00) >> 8); vi->volume_id[2] = (unsigned char)((volume_id & 0x00ff0000) >> 16); vi->volume_id[3] = (unsigned char)(volume_id >> 24); } len = mbstowcs(NULL, volume_name, 0); if (len != (size_t)-1 && len > 11) die("Label can be no longer than 11 characters"); if (!local_string_to_dos_string(label, volume_name, 12)) die("Error when processing label"); for (i = strlen(label); i < 11; ++i) label[i] = ' '; label[11] = 0; if (memcmp(label, " ", MSDOS_NAME) == 0) memcpy(label, NO_NAME, MSDOS_NAME); ret = validate_volume_label(label); if (ret & 0x1) fprintf(stderr, "mkfs.fat: Warning: lowercase labels might not work properly on some systems\n"); if (ret & 0x2) die("Labels with characters below 0x20 are not allowed\n"); if (ret & 0x4) die("Labels with characters *?.,;:/\\|+=<>[]\" are not allowed\n"); if (ret & 0x10) die("Label can't start with a space character"); if (!atari_format) { memcpy(vi->volume_label, label, 11); memcpy(bs.boot_jump, dummy_boot_jump, 3); /* Patch in the correct offset to the boot code */ bs.boot_jump[1] = ((size_fat == 32 ? (char *)&bs.fat32.boot_code : (char *)&bs.oldfat.boot_code) - (char *)&bs) - 2; if (size_fat == 32) { int offset = (char *)&bs.fat32.boot_code - (char *)&bs + MESSAGE_OFFSET + 0x7c00; if (dummy_boot_code[BOOTCODE_FAT32_SIZE - 1]) printf("Warning: message too long; truncated\n"); dummy_boot_code[BOOTCODE_FAT32_SIZE - 1] = 0; memcpy(bs.fat32.boot_code, dummy_boot_code, BOOTCODE_FAT32_SIZE); bs.fat32.boot_code[MSG_OFFSET_OFFSET] = offset & 0xff; bs.fat32.boot_code[MSG_OFFSET_OFFSET + 1] = offset >> 8; } else { memcpy(bs.oldfat.boot_code, dummy_boot_code, BOOTCODE_SIZE); } bs.boot_sign = htole16(BOOT_SIGN); } else { memcpy(bs.boot_jump, dummy_boot_jump_m68k, 2); } if (verbose >= 2) printf("Boot jump code is %02x %02x\n", bs.boot_jump[0], bs.boot_jump[1]); if (!reserved_sectors) reserved_sectors = (size_fat == 32) ? 32 : 1; else { if (size_fat == 32 && reserved_sectors < 2) die("On FAT32 at least 2 reserved sectors are needed."); } bs.reserved = htole16(reserved_sectors); if (verbose >= 2) printf("Using %d reserved sectors\n", reserved_sectors); bs.fats = (char)nr_fats; if (!atari_format || size_fat == 32) bs.hidden = htole32(hidden_sectors); else { /* In Atari format, hidden is a 16 bit field */ uint16_t hidden = htole16(hidden_sectors); if (hidden_sectors & ~0xffff) die("#hidden doesn't fit in 16bit field of Atari format\n"); memcpy(&bs.hidden, &hidden, 2); } if ((long long)(blocks * BLOCK_SIZE / sector_size) + orphaned_sectors > UINT32_MAX) { printf("Warning: target too large, space at end will be left unused\n"); num_sectors = UINT32_MAX; blocks = (unsigned long long)UINT32_MAX * sector_size / BLOCK_SIZE; } else { num_sectors = (long long)(blocks * BLOCK_SIZE / sector_size) + orphaned_sectors; } if (align_structures) { /* Align number of sectors to be multiple of sectors per track, needed by DOS and mtools */ num_sectors = num_sectors / le16toh(bs.secs_track) * le16toh(bs.secs_track); } if (!atari_format) { unsigned fatdata1216; /* Sectors for FATs + data area (FAT12/16) */ unsigned fatdata32; /* Sectors for FATs + data area (FAT32) */ unsigned fatlength12, fatlength16, fatlength32; unsigned maxclust12, maxclust16, maxclust32; unsigned clust12, clust16, clust32; int maxclustsize; unsigned root_dir_sectors = cdiv(root_dir_entries * 32, sector_size); /* * If the filesystem is 8192 sectors or less (4 MB with 512-byte * sectors, i.e. floppy size), don't align the data structures. */ if (num_sectors <= 8192) { if (align_structures && verbose >= 2) printf("Disabling alignment due to tiny filesystem\n"); align_structures = FALSE; } if (sectors_per_cluster) bs.cluster_size = maxclustsize = sectors_per_cluster; else /* An initial guess for bs.cluster_size should already be set */ maxclustsize = 128; do { fatdata32 = num_sectors - align_object(reserved_sectors, bs.cluster_size); fatdata1216 = fatdata32 - align_object(root_dir_sectors, bs.cluster_size); if (verbose >= 2) printf("Trying with %d sectors/cluster:\n", bs.cluster_size); /* The factor 2 below avoids cut-off errors for nr_fats == 1. * The "nr_fats*3" is for the reserved first two FAT entries */ clust12 = 2 * ((long long)fatdata1216 * sector_size + nr_fats * 3) / (2 * (int)bs.cluster_size * sector_size + nr_fats * 3); fatlength12 = cdiv(((clust12 + 2) * 3 + 1) >> 1, sector_size); fatlength12 = align_object(fatlength12, bs.cluster_size); /* Need to recalculate number of clusters, since the unused parts of the * FATS and data area together could make up space for an additional, * not really present cluster. */ clust12 = (fatdata1216 - nr_fats * fatlength12) / bs.cluster_size; maxclust12 = (fatlength12 * 2 * sector_size) / 3; if (maxclust12 > MAX_CLUST_12) maxclust12 = MAX_CLUST_12; if (verbose >= 2 && (size_fat == 0 || size_fat == 12)) printf("Trying FAT12: #clu=%u, fatlen=%u, maxclu=%u, limit=%u\n", clust12, fatlength12, maxclust12, MAX_CLUST_12); if (clust12 > maxclust12) { clust12 = 0; if (verbose >= 2 && (size_fat == 0 || size_fat == 12)) printf("Trying FAT12: too much clusters\n"); } clust16 = ((long long)fatdata1216 * sector_size + nr_fats * 4) / ((int)bs.cluster_size * sector_size + nr_fats * 2); fatlength16 = cdiv((clust16 + 2) * 2, sector_size); fatlength16 = align_object(fatlength16, bs.cluster_size); /* Need to recalculate number of clusters, since the unused parts of the * FATS and data area together could make up space for an additional, * not really present cluster. */ clust16 = (fatdata1216 - nr_fats * fatlength16) / bs.cluster_size; maxclust16 = (fatlength16 * sector_size) / 2; if (maxclust16 > MAX_CLUST_16) maxclust16 = MAX_CLUST_16; if (verbose >= 2 && (size_fat == 0 || size_fat == 16)) printf("Trying FAT16: #clu=%u, fatlen=%u, maxclu=%u, limit=%u/%u\n", clust16, fatlength16, maxclust16, MIN_CLUST_16, MAX_CLUST_16); if (clust16 > maxclust16) { if (verbose >= 2 && (size_fat == 0 || size_fat == 16)) printf("Trying FAT16: too much clusters\n"); clust16 = 0; } /* This avoids that the filesystem will be misdetected as having a * 12 bit FAT. */ if (clust16 && clust16 < MIN_CLUST_16) { if (verbose >= 2 && (size_fat == 0 || size_fat == 16)) printf("Trying FAT16: not enough clusters, would be misdetected as FAT12\n"); clust16 = 0; } clust32 = ((long long)fatdata32 * sector_size + nr_fats * 8) / ((int)bs.cluster_size * sector_size + nr_fats * 4); fatlength32 = cdiv((clust32 + 2) * 4, sector_size); fatlength32 = align_object(fatlength32, bs.cluster_size); /* Need to recalculate number of clusters, since the unused parts of the * FATS and data area together could make up space for an additional, * not really present cluster. */ clust32 = (fatdata32 - nr_fats * fatlength32) / bs.cluster_size; maxclust32 = (fatlength32 * sector_size) / 4; if (maxclust32 > MAX_CLUST_32) maxclust32 = MAX_CLUST_32; if (verbose >= 2 && (size_fat == 0 || size_fat == 32)) printf("Trying FAT32: #clu=%u, fatlen=%u, maxclu=%u, limit=%u/%u\n", clust32, fatlength32, maxclust32, MIN_CLUST_32, MAX_CLUST_32); if (clust32 > maxclust32) { if (verbose >= 2 && (size_fat == 0 || size_fat == 32)) printf("Trying FAT32: too much clusters\n"); clust32 = 0; } /* When explicitely asked, allow to create FAT32 with less then MIN_CLUST_32 */ if (clust32 && clust32 < MIN_CLUST_32 && !(size_fat_by_user && size_fat == 32)) { if (verbose >= 2 && (size_fat == 0 || size_fat == 32)) printf("Trying FAT32: not enough clusters\n"); clust32 = 0; } if ((clust12 && (size_fat == 0 || size_fat == 12)) || (clust16 && (size_fat == 0 || size_fat == 16)) || (clust32 && size_fat == 32)) break; bs.cluster_size <<= 1; } while (bs.cluster_size && bs.cluster_size <= maxclustsize); /* Use the optimal FAT size if not specified; * establish_params() will have already set size_fat to 32 if it is not * specified and the filesystem size is over a specific threshold */ if (!size_fat) { size_fat = (clust16 > clust12) ? 16 : 12; if (verbose >= 2) printf("Choosing %d bits for FAT\n", size_fat); } switch (size_fat) { case 12: cluster_count = clust12; fat_length = fatlength12; bs.fat_length = htole16(fatlength12); memcpy(vi->fs_type, MSDOS_FAT12_SIGN, 8); break; case 16: cluster_count = clust16; fat_length = fatlength16; bs.fat_length = htole16(fatlength16); memcpy(vi->fs_type, MSDOS_FAT16_SIGN, 8); break; case 32: if (clust32 < MIN_CLUST_32) fprintf(stderr, "WARNING: Number of clusters for 32 bit FAT is less then suggested minimum.\n"); cluster_count = clust32; fat_length = fatlength32; bs.fat_length = htole16(0); bs.fat32.fat32_length = htole32(fatlength32); memcpy(vi->fs_type, MSDOS_FAT32_SIGN, 8); root_dir_entries = 0; break; default: die("FAT not 12, 16 or 32 bits"); } /* Adjust the reserved number of sectors for alignment */ reserved_sectors = align_object(reserved_sectors, bs.cluster_size); bs.reserved = htole16(reserved_sectors); /* Adjust the number of root directory entries to help enforce alignment */ if (align_structures) { root_dir_entries = align_object(root_dir_sectors, bs.cluster_size) * (sector_size >> 5); } } else { unsigned clusters, maxclust, fatdata; /* GEMDOS always uses a 12 bit FAT on floppies, and always a 16 bit FAT on * hard disks. So use 12 bit if the size of the filesystem suggests that * this fs is for a floppy disk, if the user hasn't explicitly requested a * size. */ if (!size_fat) size_fat = (num_sectors == 1440 || num_sectors == 2400 || num_sectors == 2880 || num_sectors == 5760) ? 12 : 16; if (verbose >= 2) printf("Choosing %d bits for FAT\n", size_fat); /* Atari format: cluster size should be 2, except explicitly requested by * the user, since GEMDOS doesn't like other cluster sizes very much. * Instead, tune the sector size for the FS to fit. */ bs.cluster_size = sectors_per_cluster ? sectors_per_cluster : 2; if (!sector_size_set) { while (num_sectors > GEMDOS_MAX_SECTORS) { num_sectors >>= 1; sector_size <<= 1; } } if (verbose >= 2) printf("Sector size must be %d to have less than %d log. sectors\n", sector_size, GEMDOS_MAX_SECTORS); /* Check if there are enough FAT indices for how much clusters we have */ do { fatdata = num_sectors - cdiv(root_dir_entries * 32, sector_size) - reserved_sectors; /* The factor 2 below avoids cut-off errors for nr_fats == 1 and * size_fat == 12 * The "2*nr_fats*size_fat/8" is for the reserved first two FAT entries */ clusters = (2 * ((long long)fatdata * sector_size - 2 * nr_fats * size_fat / 8)) / (2 * ((int)bs.cluster_size * sector_size + nr_fats * size_fat / 8)); fat_length = cdiv((clusters + 2) * size_fat / 8, sector_size); /* Need to recalculate number of clusters, since the unused parts of the * FATS and data area together could make up space for an additional, * not really present cluster. */ clusters = (fatdata - nr_fats * fat_length) / bs.cluster_size; maxclust = (fat_length * sector_size * 8) / size_fat; if (verbose >= 2) printf("ss=%d: #clu=%d, fat_len=%d, maxclu=%d\n", sector_size, clusters, fat_length, maxclust); /* last 10 cluster numbers are special (except FAT32: 4 high bits rsvd); * first two numbers are reserved */ if (maxclust <= (size_fat == 32 ? MAX_CLUST_32 : (1 << size_fat) - 0x10) && clusters <= maxclust - 2) break; if (verbose >= 2) printf(clusters > maxclust - 2 ? "Too many clusters\n" : "FAT too big\n"); /* need to increment sector_size once more to */ if (sector_size_set) die("With this sector size, the maximum number of FAT entries " "would be exceeded."); num_sectors >>= 1; sector_size <<= 1; } while (sector_size <= GEMDOS_MAX_SECTOR_SIZE); if (sector_size > GEMDOS_MAX_SECTOR_SIZE) die("Would need a sector size > 16k, which GEMDOS can't work with"); cluster_count = clusters; if (size_fat != 32) bs.fat_length = htole16(fat_length); else { bs.fat_length = 0; bs.fat32.fat32_length = htole32(fat_length); } } if (fill_mbr_partition) { uint8_t *partition; uint8_t *disk_sig_ptr; uint32_t disk_sig; uint8_t buf[512]; int fd; if (verbose) printf("Adding MBR table\n"); if (size_fat == 32) disk_sig_ptr = bs.fat32.boot_code + BOOTCODE_FAT32_SIZE - 16*4 - 6; else disk_sig_ptr = bs.oldfat.boot_code + BOOTCODE_SIZE - 16*4 - 6; if (*(disk_sig_ptr-1)) { printf("Warning: message too long; truncated\n"); *(disk_sig_ptr-1) = 0; } disk_sig = 0; memset(disk_sig_ptr, 0, 16*4 + 6); /* Try to read existing 32 bit disk signature */ fd = open(device_name, O_RDONLY); if (fd >= 0) { if (read(fd, buf, sizeof(buf)) == sizeof(buf) && buf[510] == 0x55 && buf[511] == 0xAA) disk_sig = (uint32_t)buf[440] | ((uint32_t)buf[441] << 8) | ((uint32_t)buf[442] << 16) | ((uint32_t)buf[443] << 24); close(fd); } /* If is not available then generate random 32 bit disk signature */ if (invariant || getenv("SOURCE_DATE_EPOCH")) disk_sig = volume_id; else if (!disk_sig) disk_sig = generate_volume_id(); disk_sig_ptr[0] = (disk_sig >> 0) & 0xFF; disk_sig_ptr[1] = (disk_sig >> 8) & 0xFF; disk_sig_ptr[2] = (disk_sig >> 16) & 0xFF; disk_sig_ptr[3] = (disk_sig >> 24) & 0xFF; partition = disk_sig_ptr + 6; /* Active flag */ partition[0] = 0x80; /* CHS address of the first sector */ partition[1] = 0; partition[2] = 1; partition[3] = 0; /* Partition type */ if (le16toh(bs.heads) > 254 || le16toh(bs.secs_track) > 63) { /* CHS values are out of range for MBR, use LBA */ if (size_fat != 32) partition[4] = 0x0E; /* BIG FAT16 (LBA) */ else partition[4] = 0x0C; /* FAT32 (LBA) */ } else if (size_fat == 12 && num_sectors < 65536) partition[4] = 0x01; /* FAT12 (CHS) */ else if (size_fat == 16 && num_sectors < 65536) partition[4] = 0x04; /* FAT16 (CHS) */ else if (size_fat != 32 && num_sectors < le16toh(bs.secs_track) * le16toh(bs.heads) * 1024) partition[4] = 0x06; /* BIG FAT16 or FAT12 (CHS) */ else if (size_fat != 32) partition[4] = 0x0E; /* BIG FAT16 (LBA) */ else partition[4] = 0x0C; /* FAT32 (LBA) */ /* CHS address of the last sector */ if (le16toh(bs.heads) > 254 || le16toh(bs.secs_track) > 63 || num_sectors >= le16toh(bs.secs_track) * le16toh(bs.heads) * 1024) { /* If CHS address is too large use tuple (1023, 254, 63) */ partition[5] = 254; partition[6] = 255; partition[7] = 255; } else { partition[5] = (num_sectors / le16toh(bs.secs_track)) % le16toh(bs.heads); partition[6] = ((1 + num_sectors % le16toh(bs.secs_track)) & 63) | (((num_sectors / (le16toh(bs.heads) * le16toh(bs.secs_track))) >> 8) * 64); partition[7] = (num_sectors / (le16toh(bs.heads) * le16toh(bs.secs_track))) & 255; } /* LBA of the first sector */ partition[ 8] = 0; partition[ 9] = 0; partition[10] = 0; partition[11] = 0; /* Number of sectors */ partition[12] = (num_sectors >> 0) & 0xFF; partition[13] = (num_sectors >> 8) & 0xFF; partition[14] = (num_sectors >> 16) & 0xFF; partition[15] = (num_sectors >> 24) & 0xFF; } bs.sector_size[0] = (char)(sector_size & 0x00ff); bs.sector_size[1] = (char)((sector_size & 0xff00) >> 8); bs.dir_entries[0] = (char)(root_dir_entries & 0x00ff); bs.dir_entries[1] = (char)((root_dir_entries & 0xff00) >> 8); if (size_fat == 32) { /* set up additional FAT32 fields */ bs.fat32.flags = htole16(0); bs.fat32.version[0] = 0; bs.fat32.version[1] = 0; bs.fat32.root_cluster = htole32(2); if (!info_sector) info_sector = 1; bs.fat32.info_sector = htole16(info_sector); if (!backup_boot_set) backup_boot = (reserved_sectors >= 7 && info_sector != 6) ? 6 : (reserved_sectors >= 3 + info_sector && info_sector != reserved_sectors - 2 && info_sector != reserved_sectors - 1) ? reserved_sectors - 2 : (reserved_sectors >= 3 && info_sector != reserved_sectors - 1) ? reserved_sectors - 1 : 0; if (backup_boot) { if (backup_boot == info_sector) die("Backup boot sector must not be same as info sector (%d)", info_sector); else if (backup_boot >= reserved_sectors) die("Backup boot sector must be a reserved sector"); } if (verbose >= 2) printf("Using sector %d as backup boot sector (0 = none)\n", backup_boot); bs.fat32.backup_boot = htole16(backup_boot); memset(&bs.fat32.reserved2, 0, sizeof(bs.fat32.reserved2)); } if (atari_format) { /* Just some consistency checks */ if (num_sectors >= GEMDOS_MAX_SECTORS) die("GEMDOS can't handle more than 65531 sectors"); else if (num_sectors >= OLDGEMDOS_MAX_SECTORS) printf("Warning: More than 32765 sector need TOS 1.04 " "or higher.\n"); } if (num_sectors >= 65536) { bs.sectors[0] = (char)0; bs.sectors[1] = (char)0; bs.total_sect = htole32(num_sectors); } else { bs.sectors[0] = (char)(num_sectors & 0x00ff); bs.sectors[1] = (char)((num_sectors & 0xff00) >> 8); if (!atari_format) bs.total_sect = htole32(0); } if (!atari_format) vi->ext_boot_sign = MSDOS_EXT_SIGN; if (!cluster_count) { if (sectors_per_cluster) /* If yes, die if we'd spec'd sectors per cluster */ die("Not enough or too many clusters for filesystem - try less or more sectors per cluster"); else die("Attempting to create a too small or a too large filesystem"); } fat_entries = cluster_count + 2; /* The two following vars are in hard sectors, i.e. 512 byte sectors! */ start_data_sector = (reserved_sectors + nr_fats * fat_length + cdiv(root_dir_entries * 32, sector_size)) * (sector_size / HARD_SECTOR_SIZE); start_data_block = (start_data_sector + SECTORS_PER_BLOCK - 1) / SECTORS_PER_BLOCK; if (blocks < start_data_block + 32) /* Arbitrary undersize filesystem! */ die("Too few blocks for viable filesystem"); if (verbose) { printf("%s has %d head%s and %d sector%s per track,\n", device_name, le16toh(bs.heads), (le16toh(bs.heads) != 1) ? "s" : "", le16toh(bs.secs_track), (le16toh(bs.secs_track) != 1) ? "s" : ""); printf("hidden sectors 0x%04x;\n", hidden_sectors); printf("logical sector size is %d,\n", sector_size); printf("using 0x%02x media descriptor, with %u sectors;\n", (int)(bs.media), (unsigned)num_sectors); printf("drive number 0x%02x;\n", (int) (vi->drive_number)); printf("filesystem has %d %d-bit FAT%s and %d sector%s per cluster.\n", (int)(bs.fats), size_fat, (bs.fats != 1) ? "s" : "", (int)(bs.cluster_size), (bs.cluster_size != 1) ? "s" : ""); printf("FAT size is %d sector%s, and provides %d cluster%s.\n", fat_length, (fat_length != 1) ? "s" : "", cluster_count, (cluster_count != 1) ? "s" : ""); printf("There %s %u reserved sector%s.\n", (reserved_sectors != 1) ? "are" : "is", reserved_sectors, (reserved_sectors != 1) ? "s" : ""); if (size_fat != 32) { unsigned root_dir_entries = bs.dir_entries[0] + ((bs.dir_entries[1]) * 256); unsigned root_dir_sectors = cdiv(root_dir_entries * 32, sector_size); printf("Root directory contains %u slots and uses %u sectors.\n", root_dir_entries, root_dir_sectors); } printf("Volume ID is %08lx, ", volume_id & (atari_format ? 0x00ffffff : 0xffffffff)); if (memcmp(label, NO_NAME, MSDOS_NAME)) printf("volume label %s.\n", volume_name); else printf("no volume label.\n"); } /* Make the file allocation tables! */ if (malloc_entire_fat) alloced_fat_length = fat_length; else alloced_fat_length = 1; if ((fat = (unsigned char *)malloc(alloced_fat_length * sector_size)) == NULL) die("unable to allocate space for FAT image in memory"); memset(fat, 0, alloced_fat_length * sector_size); mark_FAT_cluster(0, 0xffffffff); /* Initial fat entries */ mark_FAT_cluster(1, 0xffffffff); fat[0] = (unsigned char)bs.media; /* Put media type in first byte! */ if (size_fat == 32) { /* Mark cluster 2 as EOF (used for root dir) */ mark_FAT_cluster(2, FAT_EOF); } /* Make the root directory entries */ size_root_dir = (size_fat == 32) ? bs.cluster_size * sector_size : (((int)bs.dir_entries[1] * 256 + (int)bs.dir_entries[0]) * sizeof(struct msdos_dir_entry)); if ((root_dir = (struct msdos_dir_entry *)malloc(size_root_dir)) == NULL) { free(fat); /* Tidy up before we die! */ die("unable to allocate space for root directory in memory"); } memset(root_dir, 0, size_root_dir); if (memcmp(label, NO_NAME, MSDOS_NAME)) { struct msdos_dir_entry *de = &root_dir[0]; memcpy(de->name, label, MSDOS_NAME); if (de->name[0] == 0xe5) de->name[0] = 0x05; de->attr = ATTR_VOLUME; if (create_time != (time_t)-1) { if (!invariant && !getenv("SOURCE_DATE_EPOCH")) ctime = localtime(&create_time); else ctime = gmtime(&create_time); } else { ctime = NULL; } if (ctime && ctime->tm_year >= 80 && ctime->tm_year <= 207) { de->time = htole16((unsigned short)((ctime->tm_sec >> 1) + (ctime->tm_min << 5) + (ctime->tm_hour << 11))); de->date = htole16((unsigned short)(ctime->tm_mday + ((ctime->tm_mon + 1) << 5) + ((ctime->tm_year - 80) << 9))); } else { /* fallback to 1.1.1980 00:00:00 */ de->time = htole16(0); de->date = htole16(1 + (1 << 5)); } de->ctime_cs = 0; de->ctime = de->time; de->cdate = de->date; de->adate = de->date; de->starthi = htole16(0); de->start = htole16(0); de->size = htole32(0); } if (size_fat == 32) { /* For FAT32, create an info sector */ struct fat32_fsinfo *info; if (!(info_sector_buffer = malloc(sector_size))) die("Out of memory"); memset(info_sector_buffer, 0, sector_size); /* fsinfo structure is at offset 0x1e0 in info sector by observation */ info = (struct fat32_fsinfo *)(info_sector_buffer + 0x1e0); /* Info sector magic */ info_sector_buffer[0] = 'R'; info_sector_buffer[1] = 'R'; info_sector_buffer[2] = 'a'; info_sector_buffer[3] = 'A'; /* Magic for fsinfo structure */ info->signature = htole32(0x61417272); /* We've allocated cluster 2 for the root dir. */ info->free_clusters = htole32(cluster_count - 1); info->next_cluster = htole32(2); /* Info sector also must have boot sign */ *(uint16_t *) (info_sector_buffer + 0x1fe) = htole16(BOOT_SIGN); } if (!(blank_sector = malloc(sector_size))) die("Out of memory"); memset(blank_sector, 0, sector_size); } /* Write the new filesystem's data tables to wherever they're going to end up! */ #define error(str) \ do { \ free (fat); \ free (info_sector_buffer); \ free (root_dir); \ die (str); \ } while(0) #define seekto(pos,errstr) \ do { \ off_t __pos = (pos); \ if (lseek (dev, part_sector * sector_size + __pos, SEEK_SET) != part_sector * sector_size + __pos) \ error ("seek to " errstr " failed whilst writing tables"); \ } while(0) #define writebuf(buf,size,errstr) \ do { \ int __size = (size); \ if (write (dev, buf, __size) != __size) \ error ("failed whilst writing " errstr); \ } while(0) static void write_tables(void) { int x; int fat_length; fat_length = (size_fat == 32) ? le32toh(bs.fat32.fat32_length) : le16toh(bs.fat_length); seekto(0, "start of device"); /* clear all reserved sectors */ for (x = 0; x < reserved_sectors; ++x) writebuf(blank_sector, sector_size, "reserved sector"); /* seek back to sector 0 and write the boot sector */ seekto(0, "boot sector"); writebuf((char *)&bs, sizeof(struct msdos_boot_sector), "boot sector"); /* on FAT32, write the info sector and backup boot sector */ if (size_fat == 32) { seekto(le16toh(bs.fat32.info_sector) * sector_size, "info sector"); writebuf(info_sector_buffer, 512, "info sector"); if (backup_boot != 0) { seekto(backup_boot * sector_size, "backup boot sector"); writebuf((char *)&bs, sizeof(struct msdos_boot_sector), "backup boot sector"); if (backup_boot + le16toh(bs.fat32.info_sector) != le16toh(bs.fat32.info_sector) && backup_boot + le16toh(bs.fat32.info_sector) < reserved_sectors) { seekto((backup_boot + le16toh(bs.fat32.info_sector)) * sector_size, "backup info sector"); writebuf(info_sector_buffer, 512, "backup info sector"); } } } /* seek to start of FATS and write them all */ seekto(reserved_sectors * sector_size, "first FAT"); for (x = 1; x <= nr_fats; x++) { int y; int blank_fat_length = fat_length - alloced_fat_length; writebuf(fat, alloced_fat_length * sector_size, "FAT"); for (y = 0; y < blank_fat_length; y++) writebuf(blank_sector, sector_size, "FAT"); } /* Write the root directory directly after the last FAT. This is the root * dir area on FAT12/16, and the first cluster on FAT32. */ writebuf((char *)root_dir, size_root_dir, "root directory"); if (blank_sector) free(blank_sector); free(info_sector_buffer); free(root_dir); /* Free up the root directory space from setup_tables */ free(fat); /* Free up the fat table space reserved during setup_tables */ } /* Report the command usage and exit with the given error code */ static void usage(const char *name, int exitval) { fprintf(stderr, "Usage: %s [OPTIONS] TARGET [BLOCKS]\n", name); fprintf(stderr, "Create FAT filesystem in TARGET, which can be a block device or file. Use only\n"); fprintf(stderr, "up to BLOCKS 1024 byte blocks if specified. With the -C option, file TARGET will be\n"); fprintf(stderr, "created with a size of 1024 bytes times BLOCKS, which must be specified.\n"); fprintf(stderr, "\n"); fprintf(stderr, "Options:\n"); fprintf(stderr, " -a Disable alignment of data structures\n"); fprintf(stderr, " -A Toggle Atari variant of the filesystem\n"); fprintf(stderr, " -b SECTOR Select SECTOR as location of the FAT32 backup boot sector\n"); fprintf(stderr, " -c Check device for bad blocks before creating the filesystem\n"); fprintf(stderr, " -C Create file TARGET then create filesystem in it\n"); fprintf(stderr, " -D NUMBER Write BIOS drive number NUMBER to boot sector\n"); fprintf(stderr, " -f COUNT Create COUNT file allocation tables\n"); fprintf(stderr, " -F SIZE Select FAT size SIZE (12, 16 or 32)\n"); fprintf(stderr, " -g GEOM Select disk geometry: heads/sectors_per_track\n"); fprintf(stderr, " -h NUMBER Write hidden sectors NUMBER to boot sector\n"); fprintf(stderr, " -i VOLID Set volume ID to VOLID (a 32 bit hexadecimal number)\n"); fprintf(stderr, " -I Ignore and disable safety checks\n"); fprintf(stderr, " -l FILENAME Read bad blocks list from FILENAME\n"); fprintf(stderr, " -m FILENAME Replace default error message in boot block with contents of FILENAME\n"); fprintf(stderr, " -M TYPE Set media type in boot sector to TYPE\n"); fprintf(stderr, " --mbr[=y|n|a] Fill (fake) MBR table with one partition which spans whole disk\n"); fprintf(stderr, " -n LABEL Set volume name to LABEL (up to 11 characters long)\n"); fprintf(stderr, " --codepage=N use DOS codepage N to encode label (default: %d)\n", DEFAULT_DOS_CODEPAGE); fprintf(stderr, " -r COUNT Make room for at least COUNT entries in the root directory\n"); fprintf(stderr, " -R COUNT Set minimal number of reserved sectors to COUNT\n"); fprintf(stderr, " -s COUNT Set number of sectors per cluster to COUNT\n"); fprintf(stderr, " -S SIZE Select a sector size of SIZE (a power of two, at least 512)\n"); fprintf(stderr, " -v Verbose execution\n"); fprintf(stderr, " --variant=TYPE Select variant TYPE of filesystem (standard or Atari)\n"); fprintf(stderr, "\n"); fprintf(stderr, " --invariant Use constants for randomly generated or time based values\n"); fprintf(stderr, " --offset=SECTOR Write the filesystem at a specific sector into the device file.\n"); fprintf(stderr, " --help Show this help message and exit\n"); exit(exitval); } /* The "main" entry point into the utility - we pick up the options and attempt to process them in some sort of sensible way. In the event that some/all of the options are invalid we need to tell the user so that something can be done! */ int main(int argc, char **argv) { int c; char *tmp; char *listfile = NULL; FILE *msgfile; struct device_info devinfo; int i = 0, pos, ch; int create = 0; unsigned long long cblocks = 0; int blocks_specified = 0; struct timeval create_timeval; long long conversion; char *source_date_epoch = NULL; enum {OPT_HELP=1000, OPT_INVARIANT, OPT_MBR, OPT_VARIANT, OPT_CODEPAGE, OPT_OFFSET}; const struct option long_options[] = { {"codepage", required_argument, NULL, OPT_CODEPAGE}, {"invariant", no_argument, NULL, OPT_INVARIANT}, {"mbr", optional_argument, NULL, OPT_MBR}, {"variant", required_argument, NULL, OPT_VARIANT}, {"offset", required_argument, NULL, OPT_OFFSET}, {"help", no_argument, NULL, OPT_HELP}, {0,} }; program_name = "mkfs.fat"; if (argc && *argv) { /* What's the program name? */ char *p; program_name = *argv; if ((p = strrchr(program_name, '/'))) program_name = p + 1; } source_date_epoch = getenv("SOURCE_DATE_EPOCH"); if (source_date_epoch) { errno = 0; conversion = strtoll(source_date_epoch, &tmp, 10); create_time = conversion; if (!isdigit((unsigned char)*source_date_epoch) || *tmp != '\0' || errno != 0 || (long long)create_time != conversion) { die("SOURCE_DATE_EPOCH is too big or contains non-digits: \"%s\"", source_date_epoch); } } else if (gettimeofday(&create_timeval, NULL) == 0 && create_timeval.tv_sec != (time_t)-1) { create_time = create_timeval.tv_sec; } volume_id = generate_volume_id(); check_atari(); printf("mkfs.fat " VERSION " (" VERSION_DATE ")\n"); while ((c = getopt_long(argc, argv, "aAb:cCf:D:F:g:Ii:l:m:M:n:r:R:s:S:h:v", long_options, NULL)) != -1) /* Scan the command line for options */ switch (c) { case 'A': /* toggle Atari format */ atari_format = !atari_format; break; case 'a': /* a : skip alignment */ align_structures = FALSE; break; case 'b': /* b : location of backup boot sector */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 0 || conversion > 0xffff) { printf("Bad location for backup boot sector : %s\n", optarg); usage(argv[0], 1); } backup_boot = conversion; backup_boot_set = 1; break; case 'c': /* c : Check FS as we build it */ check = TRUE; malloc_entire_fat = TRUE; /* Need to be able to mark clusters bad */ break; case 'C': /* C : Create a new file */ create = TRUE; break; case 'D': /* D : Choose Drive Number */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 0x00 || conversion > 0xFF) { printf ("Bad drive number: %s\n", optarg); usage(argv[0], 1); } drive_number_option = conversion; drive_number_by_user=1; break; case 'f': /* f : Choose number of FATs */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 1 || conversion > 4) { printf("Bad number of FATs : %s\n", optarg); usage(argv[0], 1); } nr_fats = conversion; break; case 'F': /* F : Choose FAT size */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || (conversion != 12 && conversion != 16 && conversion != 32)) { printf("Bad FAT type : %s\n", optarg); usage(argv[0], 1); } size_fat = conversion; size_fat_by_user = 1; break; case 'g': /* g : geometry: heads and sectors per track */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || tmp[0] != '/' || !tmp[1] || isspace(tmp[1]) || errno || conversion <= 0 || conversion > UINT16_MAX) { printf("Bad format of geometry : %s\n", optarg); usage(argv[0], 1); } bs.heads = htole16(conversion); conversion = strtol(tmp+1, &tmp, 0); if (*tmp || errno || conversion <= 0 || conversion > UINT16_MAX) { printf("Bad format of geometry : %s\n", optarg); usage(argv[0], 1); } bs.secs_track = htole16(conversion); break; case 'h': /* h : number of hidden sectors */ errno = 0; conversion = strtoll(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 0 || conversion > UINT32_MAX) { printf("Bad number of hidden sectors : %s\n", optarg); usage(argv[0], 1); } hidden_sectors = conversion; hidden_sectors_by_user = 1; break; case 'I': ignore_safety_checks = 1; break; case 'i': /* i : specify volume ID */ errno = 0; conversion = strtoll(optarg, &tmp, 16); if (!*optarg || isspace(*optarg) || *tmp || conversion < 0) { printf("Volume ID must be a hexadecimal number\n"); usage(argv[0], 1); } if (conversion > UINT32_MAX) { printf("Volume ID does not fit in 32 bit\n"); usage(argv[0], 1); } if (errno) { printf("Parsing volume ID failed (%s)\n", strerror(errno)); usage(argv[0], 1); } volume_id = conversion; break; case 'l': /* l : Bad block filename */ listfile = optarg; malloc_entire_fat = TRUE; /* Need to be able to mark clusters bad */ break; case 'm': /* m : Set boot message */ if (strcmp(optarg, "-")) { msgfile = fopen(optarg, "r"); if (!msgfile) perror(optarg); } else msgfile = stdin; if (msgfile) { /* The boot code ends at offset 448 and needs a null terminator */ i = MESSAGE_OFFSET; pos = 0; /* We are at beginning of line */ do { ch = getc(msgfile); switch (ch) { case '\r': /* Ignore CRs */ case '\0': /* and nulls */ break; case '\n': /* LF -> CR+LF if necessary */ if (pos) { /* If not at beginning of line */ dummy_boot_code[i++] = '\r'; pos = 0; } dummy_boot_code[i++] = '\n'; break; case '\t': /* Expand tabs */ do { dummy_boot_code[i++] = ' '; pos++; } while (pos % 8 && i < BOOTCODE_SIZE - 1); break; case EOF: dummy_boot_code[i++] = '\0'; /* Null terminator */ break; default: dummy_boot_code[i++] = ch; /* Store character */ pos++; /* Advance position */ break; } } while (ch != EOF && i < BOOTCODE_SIZE - 1); /* Fill up with zeros */ while (i < BOOTCODE_SIZE - 1) dummy_boot_code[i++] = '\0'; dummy_boot_code[BOOTCODE_SIZE - 1] = '\0'; /* Just in case */ if (ch != EOF) printf("Warning: message too long; truncated\n"); if (msgfile != stdin) fclose(msgfile); } break; case 'M': /* M : FAT Media byte */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno) { printf("Bad number for media descriptor : %s\n", optarg); usage(argv[0], 1); } if (conversion != 0xf0 && (conversion < 0xf8 || conversion > 0xff)) { printf("FAT Media byte must either be between 0xF8 and 0xFF or be 0xF0 : %s\n", optarg); usage(argv[0], 1); } fat_media_byte = conversion; break; case 'n': /* n : Volume name */ volume_name = optarg; break; case OPT_CODEPAGE: /* --codepage : Code page */ errno = 0; conversion = strtol(optarg, &tmp, 10); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 0 || conversion > INT_MAX) { fprintf(stderr, "Invalid codepage : %s\n", optarg); usage(argv[0], 1); } if (!set_dos_codepage(conversion)) usage(argv[0], 1); break; case 'r': /* r : Root directory entries */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 16 || conversion > 32768) { printf("Bad number of root directory entries : %s\n", optarg); usage(argv[0], 1); } root_dir_entries = conversion; root_dir_entries_set = 1; break; case 'R': /* R : number of reserved sectors */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || conversion < 1 || conversion > 0xffff) { printf("Bad number of reserved sectors : %s\n", optarg); usage(argv[0], 1); } reserved_sectors = conversion; break; case 's': /* s : Sectors per cluster */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || (conversion != 1 && conversion != 2 && conversion != 4 && conversion != 8 && conversion != 16 && conversion != 32 && conversion != 64 && conversion != 128)) { printf("Bad number of sectors per cluster : %s\n", optarg); usage(argv[0], 1); } sectors_per_cluster = conversion; break; case 'S': /* S : Sector size */ errno = 0; conversion = strtol(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno || (conversion != 512 && conversion != 1024 && conversion != 2048 && conversion != 4096 && conversion != 8192 && conversion != 16384 && conversion != 32768)) { printf("Bad logical sector size : %s\n", optarg); usage(argv[0], 1); } sector_size = conversion; sector_size_set = 1; break; case 'v': /* v : Verbose execution */ ++verbose; break; case OPT_HELP: usage(argv[0], 0); break; case OPT_INVARIANT: invariant = 1; volume_id = 0x1234abcd; create_time = 1426325213; break; case OPT_MBR: if (!optarg || !strcasecmp(optarg, "y") || !strcasecmp(optarg, "yes")) fill_mbr_partition = 1; else if (!strcasecmp(optarg, "n") || !strcasecmp(optarg, "no")) fill_mbr_partition = 0; else if (!strcasecmp(optarg, "a") || !strcasecmp(optarg, "auto")) fill_mbr_partition = -1; else { printf("Unknown option for --mbr: '%s'\n", optarg); usage(argv[0], 1); } break; case OPT_VARIANT: if (!strcasecmp(optarg, "standard")) { atari_format = 0; } else if (!strcasecmp(optarg, "atari")) { atari_format = 1; } else { printf("Unknown variant: %s\n", optarg); usage(argv[0], 1); } break; case OPT_OFFSET: errno = 0; conversion = strtoll(optarg, &tmp, 0); if (!*optarg || isspace(*optarg) || *tmp || errno) { printf("Bad number for offset : %s\n", optarg); usage(argv[0], 1); } if (conversion < 0 || conversion > OFF_MAX) { printf("FAT offset must be between 0 and %lld: %s\n", (long long) OFF_MAX, optarg); usage(argv[0], 1); } part_sector = (off_t) conversion; break; case '?': usage(argv[0], 1); exit(1); default: fprintf(stderr, "Internal error: getopt_long() returned unexpected value %d\n", c); exit(2); } if (!set_dos_codepage(-1)) /* set default codepage if none was given in command line */ exit(1); if (optind == argc || !argv[optind]) { printf("No device specified.\n"); usage(argv[0], 1); } device_name = argv[optind++]; if (optind != argc) { blocks_specified = 1; errno = 0; conversion = strtoll(argv[optind], &tmp, 0); if (!*argv[optind] || isspace(*argv[optind]) || *tmp || errno || conversion < 0) { printf("Bad block count : %s\n", argv[optind]); usage(argv[0], 1); } blocks = conversion; optind++; } if (optind != argc) { fprintf(stderr, "Excess arguments on command line\n"); usage(argv[0], 1); } if (create && !blocks_specified) die("Need intended size with -C."); if (check && listfile) /* Auto and specified bad block handling are mutually */ die("-c and -l are incompatible"); /* exclusive of each other! */ if (!create) { check_mount(device_name); /* Is the device already mounted? */ dev = open(device_name, O_EXCL | O_RDWR); /* Is it a suitable device to build the FS on? */ if (dev < 0) { fprintf(stderr, "%s: unable to open %s: %s\n", program_name, device_name, strerror(errno)); exit(1); /* The error exit code is 1! */ } } else { /* create the file */ dev = open(device_name, O_EXCL | O_RDWR | O_CREAT, 0666); if (dev < 0) { if (errno == EEXIST) die("file %s already exists", device_name); else die("unable to create %s", device_name); } /* expand to desired size */ if (ftruncate(dev, part_sector * sector_size + blocks * BLOCK_SIZE)) /* TODO: check overflow */ die("unable to resize %s", device_name); } if (get_device_info(dev, &devinfo) < 0) die("error collecting information about %s", device_name); if (devinfo.size <= 0) die("unable to discover size of %s", device_name); if (devinfo.sector_size > 0) { if (sector_size_set) { if (sector_size < devinfo.sector_size) { sector_size = devinfo.sector_size; fprintf(stderr, "Warning: sector size was set to %d (minimal for this device)\n", sector_size); } } else { sector_size = devinfo.sector_size; sector_size_set = 1; } if (devinfo.size <= part_sector * sector_size) die("The device %s size %llu is less then the offset %llu", device_name, devinfo.size, (unsigned long long) part_sector * sector_size); } if (sector_size > 4096) fprintf(stderr, "Warning: sector size %d > 4096 is non-standard, filesystem may not be usable\n", sector_size); cblocks = (devinfo.size - part_sector * sector_size) / BLOCK_SIZE; orphaned_sectors = ((devinfo.size - part_sector * sector_size) % BLOCK_SIZE) / sector_size; if (blocks_specified) { if (blocks != cblocks) { fprintf(stderr, "Warning: block count mismatch: "); fprintf(stderr, "found %llu but assuming %llu.\n", cblocks, blocks); } } else { blocks = cblocks; } /* * Ignore any 'full' fixed disk devices, if -I is not given. */ if (!ignore_safety_checks && devinfo.has_children > 0) die("Partitions or virtual mappings on device '%s', not making filesystem (use -I to override)", device_name); /* * On non-removable fixed disk devices we need to create (fake) MBR partition * table so disk would be correctly recognized on MS Windows systems. */ if (fill_mbr_partition == -1) { if (devinfo.type == TYPE_FIXED && devinfo.partition == 0) fill_mbr_partition = 1; else fill_mbr_partition = 0; } establish_params(&devinfo); /* Establish the media parameters */ setup_tables(); /* Establish the filesystem tables */ if (check) /* Determine any bad block locations and mark them */ check_blocks(); else if (listfile) get_list_blocks(listfile); write_tables(); /* Write the filesystem tables away! */ /* Let's make sure to sync the block device. Otherwise, if we operate on a loop device and people issue * "losetup -d" right after this command finishes our in-flight writes might never hit the disk */ if (fsync(dev) < 0) pdie("unable to synchronize %s", device_name); exit(0); /* Terminate with no errors! */ }