// // partition_map.c - partition map routines // // Written by Eryk Vershen // /* * Copyright 1996,1997,1998 by Apple Computer, Inc. * All Rights Reserved * * Permission to use, copy, modify, and distribute this software and * its documentation for any purpose and without fee is hereby granted, * provided that the above copyright notice appears in all copies and * that both the copyright notice and this permission notice appear in * supporting documentation. * * APPLE COMPUTER DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE. * * IN NO EVENT SHALL APPLE COMPUTER BE LIABLE FOR ANY SPECIAL, INDIRECT, OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM * LOSS OF USE, DATA OR PROFITS, WHETHER IN ACTION OF CONTRACT, * NEGLIGENCE, OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION * WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ // for *printf() #include // for malloc(), calloc() & free() #ifndef __linux__ #include #else #include #endif // for strncpy() & strcmp() #include // for O_RDONLY & O_RDWR #include // for errno #include #include "partition_map.h" #include "pathname.h" #include "hfs_misc.h" #include "deblock_media.h" #include "io.h" #include "convert.h" #include "util.h" #include "errors.h" // // Defines // #define APPLE_HFS_FLAGS_VALUE 0x4000037f #define get_align_long(x) (*(x)) #define put_align_long(y, x) ((*(x)) = (y)) // #define TEST_COMPUTE // // Types // // // Global Constants // const char * kFreeType = "Apple_Free"; const char * kMapType = "Apple_partition_map"; const char * kUnixType = "Apple_UNIX_SVR2"; const char * kHFSType = "Apple_HFS"; const char * kPatchType = "Apple_Patches"; const char * kFreeName = "Extra"; enum add_action { kReplace = 0, kAdd = 1, kSplit = 2 }; // // Global Variables // extern int cflag; // // Forward declarations // int add_data_to_map(struct dpme *, long, partition_map_header *); int coerce_block0(partition_map_header *map); int contains_driver(partition_map *entry); void combine_entry(partition_map *entry); long compute_device_size(partition_map_header *map, partition_map_header *oldmap); DPME* create_data(const char *name, const char *dptype, u32 base, u32 length); void delete_entry(partition_map *entry); char *get_HFS_name(partition_map *entry, int *kind); void insert_in_base_order(partition_map *entry); void insert_in_disk_order(partition_map *entry); int read_block(partition_map_header *map, unsigned long num, char *buf); int read_partition_map(partition_map_header *map); void remove_driver(partition_map *entry); void remove_from_disk_order(partition_map *entry); void renumber_disk_addresses(partition_map_header *map); void sync_device_size(partition_map_header *map); int write_block(partition_map_header *map, unsigned long num, char *buf); // // Routines // partition_map_header * open_partition_map(char *name, int *valid_file, int ask_logical_size) { MEDIA m; partition_map_header * map; int writable; long size; m = open_pathname_as_media(name, (rflag)?O_RDONLY:O_RDWR); if (m == 0) { m = open_pathname_as_media(name, O_RDONLY); if (m == 0) { error(errno, "can't open file '%s'", name); *valid_file = 0; return NULL; } else { writable = 0; } } else { writable = 1; } *valid_file = 1; map = (partition_map_header *) malloc(sizeof(partition_map_header)); if (map == NULL) { error(errno, "can't allocate memory for open partition map"); close_media(m); return NULL; } map->name = name; map->writable = (rflag)?0:writable; map->changed = 0; map->written = 0; map->disk_order = NULL; map->base_order = NULL; map->physical_block = media_granularity(m); /* preflight */ m = open_deblock_media(PBLOCK_SIZE, m); map->m = m; map->misc = (Block0 *) malloc(PBLOCK_SIZE); if (map->misc == NULL) { error(errno, "can't allocate memory for block zero buffer"); close_media(map->m); free(map); return NULL; } else if (read_media(map->m, (long long) 0, PBLOCK_SIZE, (char *)map->misc) == 0 || convert_block0(map->misc, 1) || coerce_block0(map)) { // if I can't read block 0 I might as well give up error(-1, "Can't read block 0 from '%s'", name); close_partition_map(map); return NULL; } map->physical_block = map->misc->sbBlkSize; //printf("physical block size is %d\n", map->physical_block); if (ask_logical_size && interactive) { size = PBLOCK_SIZE; printf("A logical block is %ld bytes: ", size); flush_to_newline(0); get_number_argument("what should be the logical block size? ", &size, size); size = (size / PBLOCK_SIZE) * PBLOCK_SIZE; if (size < PBLOCK_SIZE) { size = PBLOCK_SIZE; } map->logical_block = size; } else { map->logical_block = PBLOCK_SIZE; } if (map->logical_block > MAXIOSIZE) { map->logical_block = MAXIOSIZE; } if (map->logical_block > map->physical_block) { map->physical_block = map->logical_block; } map->blocks_in_map = 0; map->maximum_in_map = -1; map->media_size = compute_device_size(map, map); sync_device_size(map); if (read_partition_map(map) < 0) { // some sort of failure reading the map } else { // got it! ; return map; } close_partition_map(map); return NULL; } void close_partition_map(partition_map_header *map) { partition_map * entry; partition_map * next; if (map == NULL) { return; } free(map->misc); for (entry = map->disk_order; entry != NULL; entry = next) { next = entry->next_on_disk; free(entry->data); free(entry->HFS_name); free(entry); } close_media(map->m); free(map); } int read_partition_map(partition_map_header *map) { DPME *data; u32 limit; unsigned int ix; int old_logical; double d; //printf("called read_partition_map\n"); //printf("logical = %d, physical = %d\n", map->logical_block, map->physical_block); data = (DPME *) malloc(PBLOCK_SIZE); if (data == NULL) { error(errno, "can't allocate memory for disk buffers"); return -1; } if (read_block(map, 1, (char *)data) == 0) { error(-1, "Can't read block 1 from '%s'", map->name); free(data); return -1; } else if (convert_dpme(data, 1) || data->dpme_signature != DPME_SIGNATURE) { old_logical = map->logical_block; map->logical_block = 512; while (map->logical_block <= map->physical_block) { if (read_block(map, 1, (char *)data) == 0) { error(-1, "Can't read block 1 from '%s'", map->name); free(data); return -1; } else if (convert_dpme(data, 1) == 0 && data->dpme_signature == DPME_SIGNATURE) { d = map->media_size; map->media_size = (d * old_logical) / map->logical_block; break; } map->logical_block *= 2; } if (map->logical_block > map->physical_block) { error(-1, "No valid block 1 on '%s'", map->name); free(data); return -1; } } //printf("logical = %d, physical = %d\n", map->logical_block, map->physical_block); limit = data->dpme_map_entries; ix = 1; while (1) { if (add_data_to_map(data, ix, map) == 0) { free(data); return -1; } if (ix >= limit) { break; } else { ix++; } data = (DPME *) malloc(PBLOCK_SIZE); if (data == NULL) { error(errno, "can't allocate memory for disk buffers"); return -1; } if (read_block(map, ix, (char *)data) == 0) { error(-1, "Can't read block %u from '%s'", ix, map->name); free(data); return -1; } else if (convert_dpme(data, 1) || (data->dpme_signature != DPME_SIGNATURE && dflag == 0) || (data->dpme_map_entries != limit && dflag == 0)) { error(-1, "Bad data in block %u from '%s'", ix, map->name); free(data); return -1; } } return 0; } void write_partition_map(partition_map_header *map) { MEDIA m; char *block; partition_map * entry; int i = 0; int result = 0; m = map->m; if (map->misc != NULL) { convert_block0(map->misc, 0); result = write_block(map, 0, (char *)map->misc); convert_block0(map->misc, 1); } else { block = (char *) calloc(1, PBLOCK_SIZE); if (block != NULL) { result = write_block(map, 0, block); free(block); } } if (result == 0) { error(errno, "Unable to write block zero"); } for (entry = map->disk_order; entry != NULL; entry = entry->next_on_disk) { convert_dpme(entry->data, 0); result = write_block(map, entry->disk_address, (char *)entry->data); convert_dpme(entry->data, 1); i = entry->disk_address; if (result == 0) { error(errno, "Unable to write block %d", i); } } #ifdef __linux__ // zap the block after the map (if possible) to get around a bug. if (map->maximum_in_map > 0 && i < map->maximum_in_map) { i += 1; block = (char *) malloc(PBLOCK_SIZE); if (block != NULL) { if (read_block(map, i, block)) { block[0] = 0; write_block(map, i, block); } free(block); } } #endif if (interactive) printf("The partition table has been altered!\n\n"); os_reload_media(map->m); } int add_data_to_map(struct dpme *data, long ix, partition_map_header *map) { partition_map *entry; //printf("add data %d to map\n", ix); entry = (partition_map *) malloc(sizeof(partition_map)); if (entry == NULL) { error(errno, "can't allocate memory for map entries"); return 0; } entry->next_on_disk = NULL; entry->prev_on_disk = NULL; entry->next_by_base = NULL; entry->prev_by_base = NULL; entry->disk_address = ix; entry->the_map = map; entry->data = data; entry->contains_driver = contains_driver(entry); entry->HFS_name = get_HFS_name(entry, &entry->HFS_kind); insert_in_disk_order(entry); insert_in_base_order(entry); map->blocks_in_map++; if (map->maximum_in_map < 0) { if (istrncmp(data->dpme_type, kMapType, DPISTRLEN) == 0) { map->maximum_in_map = data->dpme_pblocks; } } return 1; } partition_map_header * init_partition_map(char *name, partition_map_header* oldmap) { partition_map_header *map; if (oldmap != NULL) { printf("map already exists\n"); if (get_okay("do you want to reinit? [n/y]: ", 0) != 1) { return oldmap; } } map = create_partition_map(name, oldmap); if (map == NULL) { return oldmap; } close_partition_map(oldmap); add_partition_to_map("Apple", kMapType, 1, (map->media_size <= 128? 2: 63), map); return map; } partition_map_header * create_partition_map(char *name, partition_map_header *oldmap) { MEDIA m; partition_map_header * map; DPME *data; unsigned long default_number; unsigned long number; long size; unsigned long multiple; m = open_pathname_as_media(name, (rflag)?O_RDONLY:O_RDWR); if (m == 0) { error(errno, "can't open file '%s' for %sing", name, (rflag)?"read":"writ"); return NULL; } map = (partition_map_header *) malloc(sizeof(partition_map_header)); if (map == NULL) { error(errno, "can't allocate memory for open partition map"); close_media(m); return NULL; } map->name = name; map->writable = (rflag)?0:1; map->changed = 1; map->disk_order = NULL; map->base_order = NULL; if (oldmap != NULL) { size = oldmap->physical_block; } else { size = media_granularity(m); } m = open_deblock_media(PBLOCK_SIZE, m); map->m = m; if (interactive) { printf("A physical block is %ld bytes: ", size); flush_to_newline(0); get_number_argument("what should be the physical block size? ", &size, size); size = (size / PBLOCK_SIZE) * PBLOCK_SIZE; if (size < PBLOCK_SIZE) { size = PBLOCK_SIZE; } } if (map->physical_block > MAXIOSIZE) { map->physical_block = MAXIOSIZE; } map->physical_block = size; // printf("block size is %d\n", map->physical_block); if (oldmap != NULL) { size = oldmap->logical_block; } else { size = PBLOCK_SIZE; } if (interactive) { printf("A logical block is %ld bytes: ", size); flush_to_newline(0); get_number_argument("what should be the logical block size? ", &size, size); size = (size / PBLOCK_SIZE) * PBLOCK_SIZE; if (size < PBLOCK_SIZE) { size = PBLOCK_SIZE; } } #if 0 if (size > map->physical_block) { size = map->physical_block; } #endif map->logical_block = size; map->blocks_in_map = 0; map->maximum_in_map = -1; number = compute_device_size(map, oldmap); if (interactive) { printf("size of 'device' is %lu blocks (%d byte blocks): ", number, map->logical_block); default_number = number; flush_to_newline(0); do { if (get_number_argument("what should be the size? ", (long *)&number, default_number) == 0) { printf("Not a number\n"); flush_to_newline(1); number = 0; } else { multiple = get_multiplier(map->logical_block); if (multiple == 0) { printf("Bad multiplier\n"); number = 0; } else if (multiple != 1) { if (0xFFFFFFFF/multiple < number) { printf("Number too large\n"); number = 0; } else { number *= multiple; } } } default_number = kDefault; } while (number == 0); if (number < 4) { number = 4; } printf("new size of 'device' is %lu blocks (%d byte blocks)\n", number, map->logical_block); } map->media_size = number; map->misc = (Block0 *) calloc(1, PBLOCK_SIZE); if (map->misc == NULL) { error(errno, "can't allocate memory for block zero buffer"); } else { // got it! coerce_block0(map); sync_device_size(map); data = (DPME *) calloc(1, PBLOCK_SIZE); if (data == NULL) { error(errno, "can't allocate memory for disk buffers"); } else { // set data into entry data->dpme_signature = DPME_SIGNATURE; data->dpme_map_entries = 1; data->dpme_pblock_start = 1; data->dpme_pblocks = map->media_size - 1; strncpy(data->dpme_name, kFreeName, DPISTRLEN); strncpy(data->dpme_type, kFreeType, DPISTRLEN); data->dpme_lblock_start = 0; data->dpme_lblocks = data->dpme_pblocks; dpme_writable_set(data, 1); dpme_readable_set(data, 1); dpme_bootable_set(data, 0); dpme_in_use_set(data, 0); dpme_allocated_set(data, 0); dpme_valid_set(data, 1); if (add_data_to_map(data, 1, map) == 0) { free(data); } else { return map; } } } close_partition_map(map); return NULL; } int coerce_block0(partition_map_header *map) { Block0 *p; p = map->misc; if (p == NULL) { return 1; } if (p->sbSig != BLOCK0_SIGNATURE) { p->sbSig = BLOCK0_SIGNATURE; if (map->physical_block == 1) { p->sbBlkSize = PBLOCK_SIZE; } else { p->sbBlkSize = map->physical_block; } p->sbBlkCount = 0; p->sbDevType = 0; p->sbDevId = 0; p->sbData = 0; p->sbDrvrCount = 0; } return 0; // we do this simply to make it easier to call this function } int add_partition_to_map(const char *name, const char *dptype, u32 base, u32 length, partition_map_header *map) { partition_map * cur; DPME *data; enum add_action act; int limit; u32 adjusted_base = 0; u32 adjusted_length = 0; u32 new_base = 0; u32 new_length = 0; // find a block that starts includes base and length cur = map->base_order; while (cur != NULL) { if (cur->data->dpme_pblock_start <= base && (base + length) <= (cur->data->dpme_pblock_start + cur->data->dpme_pblocks)) { break; } else { // check if request is past end of existing partitions, but on disk if ((cur->next_by_base == NULL) && (base + length <= map->media_size)) { // Expand final free partition if ((istrncmp(cur->data->dpme_type, kFreeType, DPISTRLEN) == 0) && base >= cur->data->dpme_pblock_start) { cur->data->dpme_pblocks = map->media_size - cur->data->dpme_pblock_start; break; } // create an extra free partition if (base >= cur->data->dpme_pblock_start + cur->data->dpme_pblocks) { if (map->maximum_in_map < 0) { limit = map->media_size; } else { limit = map->maximum_in_map; } if (map->blocks_in_map + 1 > limit) { printf("the map is not big enough\n"); return 0; } data = create_data(kFreeName, kFreeType, cur->data->dpme_pblock_start + cur->data->dpme_pblocks, map->media_size - (cur->data->dpme_pblock_start + cur->data->dpme_pblocks)); if (data != NULL) { if (add_data_to_map(data, cur->disk_address, map) == 0) { free(data); } } } } cur = cur->next_by_base; } } // if it is not Extra then punt if (cur == NULL || istrncmp(cur->data->dpme_type, kFreeType, DPISTRLEN) != 0) { printf("requested base and length is not " "within an existing free partition\n"); return 0; } // figure out what to do and sizes data = cur->data; if (data->dpme_pblock_start == base) { // replace or add if (data->dpme_pblocks == length) { act = kReplace; } else { act = kAdd; adjusted_base = base + length; adjusted_length = data->dpme_pblocks - length; } } else { // split or add if (data->dpme_pblock_start + data->dpme_pblocks == base + length) { act = kAdd; adjusted_base = data->dpme_pblock_start; adjusted_length = base - adjusted_base; } else { act = kSplit; new_base = data->dpme_pblock_start; new_length = base - new_base; adjusted_base = base + length; adjusted_length = data->dpme_pblocks - (length + new_length); } } // if the map will overflow then punt if (map->maximum_in_map < 0) { limit = map->media_size; } else { limit = map->maximum_in_map; } if (map->blocks_in_map + (int)act > limit) { printf("the map is not big enough\n"); return 0; } data = create_data(name, dptype, base, length); if (data == NULL) { return 0; } if (act == kReplace) { free(cur->data); cur->data = data; } else { // adjust this block's size cur->data->dpme_pblock_start = adjusted_base; cur->data->dpme_pblocks = adjusted_length; cur->data->dpme_lblocks = adjusted_length; // insert new with block address equal to this one if (add_data_to_map(data, cur->disk_address, map) == 0) { free(data); } else if (act == kSplit) { data = create_data(kFreeName, kFreeType, new_base, new_length); if (data != NULL) { // insert new with block address equal to this one if (add_data_to_map(data, cur->disk_address, map) == 0) { free(data); } } } } // renumber disk addresses renumber_disk_addresses(map); // mark changed map->changed = 1; return 1; } DPME * create_data(const char *name, const char *dptype, u32 base, u32 length) { DPME *data; data = (DPME *) calloc(1, PBLOCK_SIZE); if (data == NULL) { error(errno, "can't allocate memory for disk buffers"); } else { // set data into entry data->dpme_signature = DPME_SIGNATURE; data->dpme_map_entries = 1; data->dpme_pblock_start = base; data->dpme_pblocks = length; strncpy(data->dpme_name, name, DPISTRLEN); strncpy(data->dpme_type, dptype, DPISTRLEN); data->dpme_lblock_start = 0; data->dpme_lblocks = data->dpme_pblocks; dpme_init_flags(data); } return data; } void dpme_init_flags(DPME *data) { if (istrncmp(data->dpme_type, kHFSType, DPISTRLEN) == 0) { /* XXX this is gross, fix it! */ data->dpme_flags = APPLE_HFS_FLAGS_VALUE; } else { dpme_writable_set(data, 1); dpme_readable_set(data, 1); dpme_bootable_set(data, 0); dpme_in_use_set(data, 0); dpme_allocated_set(data, 1); dpme_valid_set(data, 1); } } /* These bits are appropriate for Apple_UNIX_SVR2 partitions * used by NetBSD. They may be ok for A/UX, but have not been * tested. */ void bzb_init_slice(BZB *bp, int slice) { memset(bp,0,sizeof(BZB)); if ((slice >= 'A') && (slice <= 'Z')) { slice += 'a' - 'A'; } if ((slice != 0) && ((slice < 'a') || (slice > 'z'))) { error(-1,"Bad bzb slice"); slice = 0; } switch (slice) { case 0: case 'c': return; case 'a': bp->bzb_type = FST; strlcpy((char *)bp->bzb_mount_point, "/", sizeof(bp->bzb_mount_point)); bp->bzb_inode = 1; bzb_root_set(bp,1); bzb_usr_set(bp,1); break; case 'b': bp->bzb_type = FSTSFS; strlcpy((char *)bp->bzb_mount_point, "(swap)", sizeof(bp->bzb_mount_point)); break; case 'g': strlcpy((char *)bp->bzb_mount_point, "/usr", sizeof(bp->bzb_mount_point)); /* Fall through */ default: bp->bzb_type = FST; bp->bzb_inode = 1; bzb_usr_set(bp,1); break; } bzb_slice_set(bp,0); // XXX NetBSD disksubr.c ignores slice // bzb_slice_set(bp,slice-'a'+1); bp->bzb_magic = BZBMAGIC; } void renumber_disk_addresses(partition_map_header *map) { partition_map * cur; long ix; // reset disk addresses cur = map->disk_order; ix = 1; while (cur != NULL) { cur->disk_address = ix++; cur->data->dpme_map_entries = map->blocks_in_map; cur = cur->next_on_disk; } } long compute_device_size(partition_map_header *map, partition_map_header *oldmap) { #ifdef TEST_COMPUTE unsigned long length; struct hd_geometry geometry; struct stat info; loff_t pos; #endif char* data; unsigned long l, r, x = 0; long long size; int valid = 0; #ifdef TEST_COMPUTE int fd; fd = map->fd->fd; printf("\n"); if (fstat(fd, &info) < 0) { printf("stat of device failed\n"); } else { printf("stat: mode = 0%o, type=%s\n", info.st_mode, (S_ISREG(info.st_mode)? "Regular": (S_ISBLK(info.st_mode)?"Block":"Other"))); printf("size = %d, blocks = %d\n", info.st_size, info.st_size/map->logical_block); } if (ioctl(fd, BLKGETSIZE, &length) < 0) { printf("get device size failed\n"); } else { printf("BLKGETSIZE:size in blocks = %u\n", length); } if (ioctl(fd, HDIO_GETGEO, &geometry) < 0) { printf("get device geometry failed\n"); } else { printf("HDIO_GETGEO: heads=%d, sectors=%d, cylinders=%d, start=%d, total=%d\n", geometry.heads, geometry.sectors, geometry.cylinders, geometry.start, geometry.heads*geometry.sectors*geometry.cylinders); } if ((pos = llseek(fd, (loff_t)0, SEEK_END)) < 0) { printf("llseek to end of device failed\n"); } else if ((pos = llseek(fd, (loff_t)0, SEEK_CUR)) < 0) { printf("llseek to end of device failed on second try\n"); } else { printf("llseek: pos = %d, blocks=%d\n", pos, pos/map->logical_block); } #endif if (cflag == 0 && oldmap != NULL && oldmap->misc->sbBlkCount != 0) { return (oldmap->misc->sbBlkCount * (oldmap->physical_block / map->logical_block)); } size = media_total_size(map->m); if (size != 0) { return (long)(size / map->logical_block); } // else case data = (char *) malloc(PBLOCK_SIZE); if (data == NULL) { error(errno, "can't allocate memory for try buffer"); x = 0; } else { // double till off end l = 0; r = 1024; while (read_block(map, r, data) != 0) { l = r; if (r <= 1024) { r = r * 1024; } else { r = r * 2; } if (r >= 0x80000000) { r = 0xFFFFFFFE; break; } } // binary search for end while (l <= r) { x = (r - l) / 2 + l; if ((valid = read_block(map, x, data)) != 0) { l = x + 1; } else { if (x > 0) { r = x - 1; } else { break; } } } if (valid != 0) { x = x + 1; } // printf("size in blocks = %d\n", x); free(data); } return x; } void sync_device_size(partition_map_header *map) { Block0 *p; unsigned long size; double d; p = map->misc; if (p == NULL) { return; } d = map->media_size; size = (d * map->logical_block) / p->sbBlkSize; if (p->sbBlkCount != size) { p->sbBlkCount = size; } } void delete_partition_from_map(partition_map *entry) { partition_map_header *map; DPME *data; if (istrncmp(entry->data->dpme_type, kMapType, DPISTRLEN) == 0) { printf("Can't delete entry for the map itself\n"); return; } if (entry->contains_driver) { printf("This program can't install drivers\n"); if (get_okay("are you sure you want to delete this driver? [n/y]: ", 0) != 1) { return; } } // if past end of disk, delete it completely if (entry->next_by_base == NULL && entry->data->dpme_pblock_start >= entry->the_map->media_size) { if (entry->contains_driver) { remove_driver(entry); // update block0 if necessary } delete_entry(entry); return; } // If at end of disk, incorporate extra disk space to partition if (entry->next_by_base == NULL) { entry->data->dpme_pblocks = entry->the_map->media_size - entry->data->dpme_pblock_start; } data = create_data(kFreeName, kFreeType, entry->data->dpme_pblock_start, entry->data->dpme_pblocks); if (data == NULL) { return; } if (entry->contains_driver) { remove_driver(entry); // update block0 if necessary } free(entry->data); free(entry->HFS_name); entry->HFS_kind = kHFS_not; entry->HFS_name = 0; entry->data = data; combine_entry(entry); map = entry->the_map; renumber_disk_addresses(map); map->changed = 1; } int contains_driver(partition_map *entry) { partition_map_header *map; Block0 *p; DDMap *m; int i; int f; u32 start; map = entry->the_map; p = map->misc; if (p == NULL) { return 0; } if (p->sbSig != BLOCK0_SIGNATURE) { return 0; } if (map->logical_block > p->sbBlkSize) { return 0; } else { f = p->sbBlkSize / map->logical_block; } if (p->sbDrvrCount > 0) { m = (DDMap *) p->sbMap; for (i = 0; i < p->sbDrvrCount; i++) { start = get_align_long(&m[i].ddBlock); if (entry->data->dpme_pblock_start <= f*start && f*(start + m[i].ddSize) <= (entry->data->dpme_pblock_start + entry->data->dpme_pblocks)) { return 1; } } } return 0; } void combine_entry(partition_map *entry) { partition_map *p; u32 end; if (entry == NULL || istrncmp(entry->data->dpme_type, kFreeType, DPISTRLEN) != 0) { return; } if (entry->next_by_base != NULL) { p = entry->next_by_base; if (istrncmp(p->data->dpme_type, kFreeType, DPISTRLEN) != 0) { // next is not free } else if (entry->data->dpme_pblock_start + entry->data->dpme_pblocks != p->data->dpme_pblock_start) { // next is not contiguous (XXX this is bad) printf("next entry is not contiguous\n"); // start is already minimum // new end is maximum of two ends end = p->data->dpme_pblock_start + p->data->dpme_pblocks; if (end > entry->data->dpme_pblock_start + entry->data->dpme_pblocks) { entry->data->dpme_pblocks = end - entry->data->dpme_pblock_start; } entry->data->dpme_lblocks = entry->data->dpme_pblocks; delete_entry(p); } else { entry->data->dpme_pblocks += p->data->dpme_pblocks; entry->data->dpme_lblocks = entry->data->dpme_pblocks; delete_entry(p); } } if (entry->prev_by_base != NULL) { p = entry->prev_by_base; if (istrncmp(p->data->dpme_type, kFreeType, DPISTRLEN) != 0) { // previous is not free } else if (p->data->dpme_pblock_start + p->data->dpme_pblocks != entry->data->dpme_pblock_start) { // previous is not contiguous (XXX this is bad) printf("previous entry is not contiguous\n"); // new end is maximum of two ends end = p->data->dpme_pblock_start + p->data->dpme_pblocks; if (end < entry->data->dpme_pblock_start + entry->data->dpme_pblocks) { end = entry->data->dpme_pblock_start + entry->data->dpme_pblocks; } entry->data->dpme_pblocks = end - p->data->dpme_pblock_start; // new start is previous entry's start entry->data->dpme_pblock_start = p->data->dpme_pblock_start; entry->data->dpme_lblocks = entry->data->dpme_pblocks; delete_entry(p); } else { entry->data->dpme_pblock_start = p->data->dpme_pblock_start; entry->data->dpme_pblocks += p->data->dpme_pblocks; entry->data->dpme_lblocks = entry->data->dpme_pblocks; delete_entry(p); } } entry->contains_driver = contains_driver(entry); } void delete_entry(partition_map *entry) { partition_map_header *map; partition_map *p; map = entry->the_map; map->blocks_in_map--; remove_from_disk_order(entry); p = entry->next_by_base; if (map->base_order == entry) { map->base_order = p; } if (p != NULL) { p->prev_by_base = entry->prev_by_base; } if (entry->prev_by_base != NULL) { entry->prev_by_base->next_by_base = p; } free(entry->data); free(entry->HFS_name); free(entry); } partition_map * find_entry_by_disk_address(long ix, partition_map_header *map) { partition_map * cur; cur = map->disk_order; while (cur != NULL) { if (cur->disk_address == ix) { break; } cur = cur->next_on_disk; } return cur; } partition_map * find_entry_by_type(const char *type_name, partition_map_header *map) { partition_map * cur; cur = map->base_order; while (cur != NULL) { if (istrncmp(cur->data->dpme_type, type_name, DPISTRLEN) == 0) { break; } cur = cur->next_by_base; } return cur; } partition_map * find_entry_by_base(u32 base, partition_map_header *map) { partition_map * cur; cur = map->base_order; while (cur != NULL) { if (cur->data->dpme_pblock_start == base) { break; } cur = cur->next_by_base; } return cur; } void move_entry_in_map(long old_index, long ix, partition_map_header *map) { partition_map * cur; cur = find_entry_by_disk_address(old_index, map); if (cur == NULL) { printf("No such partition\n"); } else { remove_from_disk_order(cur); cur->disk_address = ix; insert_in_disk_order(cur); renumber_disk_addresses(map); map->changed = 1; } } void remove_from_disk_order(partition_map *entry) { partition_map_header *map; partition_map *p; map = entry->the_map; p = entry->next_on_disk; if (map->disk_order == entry) { map->disk_order = p; } if (p != NULL) { p->prev_on_disk = entry->prev_on_disk; } if (entry->prev_on_disk != NULL) { entry->prev_on_disk->next_on_disk = p; } entry->next_on_disk = NULL; entry->prev_on_disk = NULL; } void insert_in_disk_order(partition_map *entry) { partition_map_header *map; partition_map * cur; // find position in disk list & insert map = entry->the_map; cur = map->disk_order; if (cur == NULL || entry->disk_address <= cur->disk_address) { map->disk_order = entry; entry->next_on_disk = cur; if (cur != NULL) { cur->prev_on_disk = entry; } entry->prev_on_disk = NULL; } else { for (cur = map->disk_order; cur != NULL; cur = cur->next_on_disk) { if (cur->disk_address <= entry->disk_address && (cur->next_on_disk == NULL || entry->disk_address <= cur->next_on_disk->disk_address)) { entry->next_on_disk = cur->next_on_disk; cur->next_on_disk = entry; entry->prev_on_disk = cur; if (entry->next_on_disk != NULL) { entry->next_on_disk->prev_on_disk = entry; } break; } } } } void insert_in_base_order(partition_map *entry) { partition_map_header *map; partition_map * cur; // find position in base list & insert map = entry->the_map; cur = map->base_order; if (cur == NULL || entry->data->dpme_pblock_start <= cur->data->dpme_pblock_start) { map->base_order = entry; entry->next_by_base = cur; if (cur != NULL) { cur->prev_by_base = entry; } entry->prev_by_base = NULL; } else { for (cur = map->base_order; cur != NULL; cur = cur->next_by_base) { if (cur->data->dpme_pblock_start <= entry->data->dpme_pblock_start && (cur->next_by_base == NULL || entry->data->dpme_pblock_start <= cur->next_by_base->data->dpme_pblock_start)) { entry->next_by_base = cur->next_by_base; cur->next_by_base = entry; entry->prev_by_base = cur; if (entry->next_by_base != NULL) { entry->next_by_base->prev_by_base = entry; } break; } } } } void resize_map(unsigned long new_size, partition_map_header *map) { partition_map * entry; partition_map * next; unsigned int incr; // find map entry entry = find_entry_by_type(kMapType, map); if (entry == NULL) { printf("Couldn't find entry for map!\n"); return; } next = entry->next_by_base; // same size if (new_size == entry->data->dpme_pblocks) { // do nothing return; } // make it smaller if (new_size < entry->data->dpme_pblocks) { if (next == NULL || istrncmp(next->data->dpme_type, kFreeType, DPISTRLEN) != 0) { incr = 1; } else { incr = 0; } if (new_size < map->blocks_in_map + incr) { printf("New size would be too small\n"); return; } goto doit; } // make it larger if (next == NULL || istrncmp(next->data->dpme_type, kFreeType, DPISTRLEN) != 0) { printf("No free space to expand into\n"); return; } if (entry->data->dpme_pblock_start + entry->data->dpme_pblocks != next->data->dpme_pblock_start) { printf("No contiguous free space to expand into\n"); return; } if (new_size > entry->data->dpme_pblocks + next->data->dpme_pblocks) { printf("No enough free space\n"); return; } doit: entry->data->dpme_type[0] = 0; delete_partition_from_map(entry); add_partition_to_map("Apple", kMapType, 1, new_size, map); map->maximum_in_map = new_size; } void remove_driver(partition_map *entry) { partition_map_header *map; Block0 *p; DDMap *m; int i; int j; int f; u32 start; map = entry->the_map; p = map->misc; if (p == NULL) { return; } if (p->sbSig != BLOCK0_SIGNATURE) { return; } if (map->logical_block > p->sbBlkSize) { /* this is not supposed to happen, but let's just ignore it. */ return; } else { /* * compute the factor to convert the block numbers in block0 * into partition map block numbers. */ f = p->sbBlkSize / map->logical_block; } if (p->sbDrvrCount > 0) { m = (DDMap *) p->sbMap; for (i = 0; i < p->sbDrvrCount; i++) { start = get_align_long(&m[i].ddBlock); /* zap the driver if it is wholly contained in the partition */ if (entry->data->dpme_pblock_start <= f*start && f*(start + m[i].ddSize) <= (entry->data->dpme_pblock_start + entry->data->dpme_pblocks)) { // delete this driver // by copying down later ones and zapping the last for (j = i+1; j < p->sbDrvrCount; j++, i++) { put_align_long(get_align_long(&m[j].ddBlock), &m[i].ddBlock); m[i].ddSize = m[j].ddSize; m[i].ddType = m[j].ddType; } put_align_long(0, &m[i].ddBlock); m[i].ddSize = 0; m[i].ddType = 0; p->sbDrvrCount -= 1; return; /* XXX if we continue we will delete other drivers? */ } } } } int read_block(partition_map_header *map, unsigned long num, char *buf) { //printf("read block %d\n", num); return read_media(map->m, ((long long) num) * map->logical_block, PBLOCK_SIZE, (void *)buf); } int write_block(partition_map_header *map, unsigned long num, char *buf) { return write_media(map->m, ((long long) num) * map->logical_block, PBLOCK_SIZE, (void *)buf); }