libhfs.c revision 1.13
1 1.13 maxv /* $NetBSD: libhfs.c,v 1.13 2014/12/29 17:02:39 maxv Exp $ */ 2 1.1 dillo 3 1.1 dillo /*- 4 1.1 dillo * Copyright (c) 2005, 2007 The NetBSD Foundation, Inc. 5 1.1 dillo * All rights reserved. 6 1.1 dillo * 7 1.1 dillo * This code is derived from software contributed to The NetBSD Foundation 8 1.4 dillo * by Yevgeny Binder, Dieter Baron, and Pelle Johansson. 9 1.1 dillo * 10 1.1 dillo * Redistribution and use in source and binary forms, with or without 11 1.1 dillo * modification, are permitted provided that the following conditions 12 1.1 dillo * are met: 13 1.1 dillo * 1. Redistributions of source code must retain the above copyright 14 1.1 dillo * notice, this list of conditions and the following disclaimer. 15 1.1 dillo * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 dillo * notice, this list of conditions and the following disclaimer in the 17 1.1 dillo * documentation and/or other materials provided with the distribution. 18 1.1 dillo * 19 1.1 dillo * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.1 dillo * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.1 dillo * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.1 dillo * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.1 dillo * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.1 dillo * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.1 dillo * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.1 dillo * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.1 dillo * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.1 dillo * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.1 dillo * POSSIBILITY OF SUCH DAMAGE. 30 1.1 dillo */ 31 1.1 dillo 32 1.1 dillo /* 33 1.2 dillo * All functions and variable types have the prefix "hfs_". All constants 34 1.2 dillo * have the prefix "HFS_". 35 1.1 dillo * 36 1.1 dillo * Naming convention for functions which read/write raw, linear data 37 1.1 dillo * into/from a structured form: 38 1.1 dillo * 39 1.2 dillo * hfs_read/write[d][a]_foo_bar 40 1.1 dillo * [d] - read/write from/to [d]isk instead of a memory buffer 41 1.1 dillo * [a] - [a]llocate output buffer instead of using an existing one 42 1.1 dillo * (not applicable for writing functions) 43 1.1 dillo * 44 1.1 dillo * Most functions do not have either of these options, so they will read from 45 1.1 dillo * or write to a memory buffer, which has been previously allocated by the 46 1.1 dillo * caller. 47 1.1 dillo */ 48 1.1 dillo 49 1.5 lukem #include <sys/cdefs.h> 50 1.13 maxv __KERNEL_RCSID(0, "$NetBSD: libhfs.c,v 1.13 2014/12/29 17:02:39 maxv Exp $"); 51 1.5 lukem 52 1.2 dillo #include "libhfs.h" 53 1.1 dillo 54 1.1 dillo /* global private file/folder keys */ 55 1.2 dillo hfs_catalog_key_t hfs_gMetadataDirectoryKey; /* contains HFS+ inodes */ 56 1.2 dillo hfs_catalog_key_t hfs_gJournalInfoBlockFileKey; 57 1.2 dillo hfs_catalog_key_t hfs_gJournalBufferFileKey; 58 1.2 dillo hfs_catalog_key_t* hfs_gPrivateObjectKeys[4] = { 59 1.2 dillo &hfs_gMetadataDirectoryKey, 60 1.2 dillo &hfs_gJournalInfoBlockFileKey, 61 1.2 dillo &hfs_gJournalBufferFileKey, 62 1.13 maxv NULL 63 1.13 maxv }; 64 1.1 dillo 65 1.1 dillo 66 1.1 dillo extern uint16_t be16tohp(void** inout_ptr); 67 1.1 dillo extern uint32_t be32tohp(void** inout_ptr); 68 1.1 dillo extern uint64_t be64tohp(void** inout_ptr); 69 1.1 dillo 70 1.12 matt hfs_callbacks hfs_gcb; /* global callbacks */ 71 1.12 matt 72 1.12 matt /* 73 1.12 matt * global case folding table 74 1.12 matt * (lazily initialized; see comments at bottom of hfs_open_volume()) 75 1.12 matt */ 76 1.12 matt unichar_t* hfs_gcft; 77 1.12 matt 78 1.12 matt 79 1.2 dillo int hfslib_create_casefolding_table(void); 80 1.1 dillo 81 1.1 dillo #ifdef DLO_DEBUG 82 1.1 dillo #include <stdio.h> 83 1.1 dillo void 84 1.2 dillo dlo_print_key(hfs_catalog_key_t *key) 85 1.1 dillo { 86 1.1 dillo int i; 87 1.1 dillo 88 1.1 dillo printf("%ld:[", (long)key->parent_cnid); 89 1.1 dillo for (i=0; i<key->name.length; i++) { 90 1.1 dillo if (key->name.unicode[i] < 256 91 1.1 dillo && isprint(key->name.unicode[i])) 92 1.1 dillo putchar(key->name.unicode[i]); 93 1.1 dillo else 94 1.1 dillo printf("<%04x>", key->name.unicode[i]); 95 1.1 dillo } 96 1.1 dillo printf("]"); 97 1.1 dillo } 98 1.1 dillo #endif 99 1.1 dillo 100 1.1 dillo void 101 1.2 dillo hfslib_init(hfs_callbacks* in_callbacks) 102 1.1 dillo { 103 1.1 dillo unichar_t temp[256]; 104 1.13 maxv 105 1.13 maxv if (in_callbacks != NULL) 106 1.2 dillo memcpy(&hfs_gcb, in_callbacks, sizeof(hfs_callbacks)); 107 1.13 maxv 108 1.2 dillo hfs_gcft = NULL; 109 1.13 maxv 110 1.1 dillo /* 111 1.1 dillo * Create keys for the HFS+ "private" files so we can reuse them whenever 112 1.1 dillo * we perform a user-visible operation, such as listing directory contents. 113 1.1 dillo */ 114 1.13 maxv 115 1.1 dillo #define ATOU(str, len) /* quick & dirty ascii-to-unicode conversion */ \ 116 1.1 dillo do{ int i; for(i=0; i<len; i++) temp[i]=str[i]; } \ 117 1.1 dillo while( /*CONSTCOND*/ 0) 118 1.13 maxv 119 1.1 dillo ATOU("\0\0\0\0HFS+ Private Data", 21); 120 1.2 dillo hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 21, temp, 121 1.2 dillo &hfs_gMetadataDirectoryKey); 122 1.1 dillo 123 1.1 dillo ATOU(".journal_info_block", 19); 124 1.2 dillo hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 19, temp, 125 1.2 dillo &hfs_gJournalInfoBlockFileKey); 126 1.1 dillo 127 1.1 dillo ATOU(".journal", 8); 128 1.2 dillo hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 8, temp, 129 1.2 dillo &hfs_gJournalBufferFileKey); 130 1.1 dillo 131 1.1 dillo #undef ATOU 132 1.1 dillo } 133 1.1 dillo 134 1.1 dillo void 135 1.2 dillo hfslib_done(void) 136 1.1 dillo { 137 1.2 dillo hfs_callback_args cbargs; 138 1.13 maxv 139 1.13 maxv if (hfs_gcft != NULL) { 140 1.2 dillo hfslib_init_cbargs(&cbargs); 141 1.2 dillo hfslib_free(hfs_gcft, &cbargs); 142 1.2 dillo hfs_gcft = NULL; 143 1.1 dillo } 144 1.1 dillo 145 1.1 dillo return; 146 1.1 dillo } 147 1.1 dillo 148 1.1 dillo void 149 1.2 dillo hfslib_init_cbargs(hfs_callback_args* ptr) 150 1.1 dillo { 151 1.2 dillo memset(ptr, 0, sizeof(hfs_callback_args)); 152 1.1 dillo } 153 1.1 dillo 154 1.1 dillo #if 0 155 1.1 dillo #pragma mark - 156 1.1 dillo #pragma mark High-Level Routines 157 1.1 dillo #endif 158 1.1 dillo 159 1.1 dillo int 160 1.2 dillo hfslib_open_volume( 161 1.1 dillo const char* in_device, 162 1.1 dillo int in_readonly, 163 1.2 dillo hfs_volume* out_vol, 164 1.2 dillo hfs_callback_args* cbargs) 165 1.1 dillo { 166 1.2 dillo hfs_catalog_key_t rootkey; 167 1.2 dillo hfs_thread_record_t rootthread; 168 1.4 dillo hfs_hfs_master_directory_block_t mdb; 169 1.3 dillo uint16_t node_rec_sizes[1]; 170 1.3 dillo void* node_recs[1]; 171 1.1 dillo void* buffer; 172 1.1 dillo void* buffer2; /* used as temporary pointer for realloc() */ 173 1.1 dillo int result; 174 1.6 pooka int isopen = 0; 175 1.1 dillo 176 1.1 dillo result = 1; 177 1.1 dillo buffer = NULL; 178 1.1 dillo 179 1.13 maxv if (in_device == NULL || out_vol == NULL) 180 1.1 dillo return 1; 181 1.1 dillo 182 1.1 dillo out_vol->readonly = in_readonly; 183 1.4 dillo out_vol->offset = 0; 184 1.4 dillo 185 1.13 maxv if (hfslib_openvoldevice(out_vol, in_device, cbargs) != 0) 186 1.2 dillo HFS_LIBERR("could not open device"); 187 1.6 pooka isopen = 1; 188 1.1 dillo 189 1.1 dillo /* 190 1.13 maxv * Read the volume header. 191 1.1 dillo */ 192 1.4 dillo buffer = hfslib_malloc(max(sizeof(hfs_volume_header_t), 193 1.4 dillo sizeof(hfs_hfs_master_directory_block_t)), cbargs); 194 1.13 maxv if (buffer == NULL) 195 1.2 dillo HFS_LIBERR("could not allocate volume header"); 196 1.13 maxv if (hfslib_readd(out_vol, buffer, max(sizeof(hfs_volume_header_t), 197 1.13 maxv sizeof(hfs_hfs_master_directory_block_t)), 198 1.13 maxv HFS_VOLUME_HEAD_RESERVE_SIZE, cbargs) != 0) 199 1.2 dillo HFS_LIBERR("could not read volume header"); 200 1.4 dillo 201 1.4 dillo if (be16toh(*((uint16_t *)buffer)) == HFS_SIG_HFS) { 202 1.4 dillo if (hfslib_read_master_directory_block(buffer, &mdb) == 0) 203 1.4 dillo HFS_LIBERR("could not parse master directory block"); 204 1.13 maxv if (mdb.embedded_signature == HFS_SIG_HFSP) { 205 1.4 dillo /* XXX: is 512 always correct? */ 206 1.4 dillo out_vol->offset = 207 1.4 dillo mdb.first_block * 512 208 1.4 dillo + mdb.embedded_extent.start_block 209 1.4 dillo * (uint64_t)mdb.block_size; 210 1.4 dillo 211 1.13 maxv if (hfslib_readd(out_vol, buffer, 212 1.13 maxv sizeof(hfs_volume_header_t), 213 1.13 maxv HFS_VOLUME_HEAD_RESERVE_SIZE, cbargs) != 0) 214 1.4 dillo HFS_LIBERR("could not read volume header"); 215 1.13 maxv } else 216 1.4 dillo HFS_LIBERR("Plain HFS volumes not currently supported"); 217 1.4 dillo } 218 1.4 dillo 219 1.13 maxv if (hfslib_read_volume_header(buffer, &(out_vol->vh)) == 0) 220 1.2 dillo HFS_LIBERR("could not parse volume header"); 221 1.13 maxv 222 1.1 dillo /* 223 1.1 dillo * Check the volume signature to see if this is a legitimate HFS+ or HFSX 224 1.1 dillo * volume. If so, set the key comparison function pointers appropriately. 225 1.1 dillo */ 226 1.13 maxv switch(out_vol->vh.signature) { 227 1.2 dillo case HFS_SIG_HFSP: 228 1.2 dillo out_vol->keycmp = hfslib_compare_catalog_keys_cf; 229 1.1 dillo break; 230 1.2 dillo case HFS_SIG_HFSX: 231 1.1 dillo out_vol->keycmp = NULL; /* will be set below */ 232 1.1 dillo break; 233 1.1 dillo default: 234 1.9 pooka /* HFS_LIBERR("unrecognized volume format"); */ 235 1.9 pooka goto error; 236 1.9 pooka break; 237 1.1 dillo } 238 1.1 dillo 239 1.1 dillo /* 240 1.13 maxv * Read the catalog header. 241 1.1 dillo */ 242 1.3 dillo buffer2 = hfslib_realloc(buffer, 512, cbargs); 243 1.13 maxv if (buffer2 == NULL) 244 1.2 dillo HFS_LIBERR("could not allocate catalog header node"); 245 1.1 dillo buffer = buffer2; 246 1.13 maxv 247 1.3 dillo /* 248 1.13 maxv * We are only interested in the node header, so read the first 249 1.13 maxv * 512 bytes and construct the node descriptor by hand. 250 1.13 maxv */ 251 1.13 maxv if (hfslib_readd(out_vol, buffer, 512, 252 1.13 maxv out_vol->vh.catalog_file.extents[0].start_block * 253 1.13 maxv (uint64_t)out_vol->vh.block_size, cbargs) != 0) 254 1.2 dillo HFS_LIBERR("could not read catalog header node"); 255 1.3 dillo node_recs[0] = (char *)buffer+14; 256 1.3 dillo node_rec_sizes[0] = 120; 257 1.13 maxv if (hfslib_read_header_node(node_recs, node_rec_sizes, 1, 258 1.13 maxv &out_vol->chr, NULL, NULL) == 0) 259 1.2 dillo HFS_LIBERR("could not parse catalog header node"); 260 1.13 maxv 261 1.13 maxv /* 262 1.13 maxv * If this is an HFSX volume, the catalog header specifies the type of 263 1.13 maxv * key comparison method (case-folding or binary compare) we should 264 1.13 maxv * use. 265 1.13 maxv */ 266 1.13 maxv if (out_vol->keycmp == NULL) { 267 1.13 maxv if (out_vol->chr.keycomp_type == HFS_KEY_CASEFOLD) 268 1.2 dillo out_vol->keycmp = hfslib_compare_catalog_keys_cf; 269 1.13 maxv else if (out_vol->chr.keycomp_type == HFS_KEY_BINARY) 270 1.2 dillo out_vol->keycmp = hfslib_compare_catalog_keys_bc; 271 1.1 dillo else 272 1.2 dillo HFS_LIBERR("undefined key compare method"); 273 1.1 dillo } 274 1.3 dillo 275 1.3 dillo out_vol->catkeysizefieldsize 276 1.3 dillo = (out_vol->chr.attributes & HFS_BIG_KEYS_MASK) ? 277 1.3 dillo sizeof(uint16_t) : sizeof(uint8_t); 278 1.3 dillo 279 1.1 dillo /* 280 1.13 maxv * Read the extent overflow header. 281 1.1 dillo */ 282 1.3 dillo /* 283 1.13 maxv * We are only interested in the node header, so read the first 284 1.13 maxv * 512 bytes and construct the node descriptor by hand. 285 1.13 maxv * buffer is already 512 bytes long. 286 1.13 maxv */ 287 1.13 maxv if (hfslib_readd(out_vol, buffer, 512, 288 1.13 maxv out_vol->vh.extents_file.extents[0].start_block * 289 1.13 maxv (uint64_t)out_vol->vh.block_size, cbargs) != 0) 290 1.2 dillo HFS_LIBERR("could not read extent header node"); 291 1.13 maxv 292 1.3 dillo node_recs[0] = (char *)buffer+14; 293 1.3 dillo node_rec_sizes[0] = 120; 294 1.13 maxv if (hfslib_read_header_node(node_recs, node_rec_sizes, 1, 295 1.13 maxv &out_vol->ehr, NULL, NULL) == 0) 296 1.2 dillo HFS_LIBERR("could not parse extent header node"); 297 1.3 dillo out_vol->extkeysizefieldsize 298 1.3 dillo = (out_vol->ehr.attributes & HFS_BIG_KEYS_MASK) ? 299 1.3 dillo sizeof(uint16_t):sizeof(uint8_t); 300 1.1 dillo /* 301 1.1 dillo * Read the journal info block and journal header (if volume journaled). 302 1.1 dillo */ 303 1.13 maxv if (out_vol->vh.attributes & (1<<HFS_VOL_JOURNALED)) { 304 1.1 dillo /* journal info block */ 305 1.2 dillo buffer2 = hfslib_realloc(buffer, sizeof(hfs_journal_info_t), cbargs); 306 1.13 maxv if (buffer2 == NULL) 307 1.2 dillo HFS_LIBERR("could not allocate journal info block"); 308 1.1 dillo buffer = buffer2; 309 1.13 maxv 310 1.13 maxv if (hfslib_readd(out_vol, buffer, sizeof(hfs_journal_info_t), 311 1.13 maxv out_vol->vh.journal_info_block * out_vol->vh.block_size, 312 1.13 maxv cbargs) != 0) 313 1.2 dillo HFS_LIBERR("could not read journal info block"); 314 1.13 maxv 315 1.13 maxv if (hfslib_read_journal_info(buffer, &out_vol->jib) == 0) 316 1.2 dillo HFS_LIBERR("could not parse journal info block"); 317 1.13 maxv 318 1.1 dillo /* journal header */ 319 1.13 maxv buffer2 = hfslib_realloc(buffer, sizeof(hfs_journal_header_t), cbargs); 320 1.13 maxv if (buffer2 == NULL) 321 1.2 dillo HFS_LIBERR("could not allocate journal header"); 322 1.1 dillo buffer = buffer2; 323 1.13 maxv 324 1.13 maxv if (hfslib_readd(out_vol, buffer, sizeof(hfs_journal_header_t), 325 1.13 maxv out_vol->jib.offset, cbargs) != 0) 326 1.2 dillo HFS_LIBERR("could not read journal header"); 327 1.13 maxv 328 1.13 maxv if (hfslib_read_journal_header(buffer, &out_vol->jh) == 0) 329 1.2 dillo HFS_LIBERR("could not parse journal header"); 330 1.1 dillo 331 1.1 dillo out_vol->journaled = 1; 332 1.13 maxv } else { 333 1.1 dillo out_vol->journaled = 0; 334 1.1 dillo } 335 1.13 maxv 336 1.1 dillo /* 337 1.1 dillo * If this volume uses case-folding comparison and the folding table hasn't 338 1.2 dillo * been created yet, do that here. (We don't do this in hfslib_init() 339 1.1 dillo * because the table is large and we might never even need to use it.) 340 1.1 dillo */ 341 1.13 maxv if (out_vol->keycmp == hfslib_compare_catalog_keys_cf && hfs_gcft == NULL) 342 1.2 dillo result = hfslib_create_casefolding_table(); 343 1.1 dillo else 344 1.1 dillo result = 0; 345 1.1 dillo 346 1.1 dillo /* 347 1.1 dillo * Find and store the volume name. 348 1.1 dillo */ 349 1.13 maxv if (hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 0, NULL, &rootkey) == 0) 350 1.2 dillo HFS_LIBERR("could not make root search key"); 351 1.13 maxv 352 1.13 maxv if (hfslib_find_catalog_record_with_key(out_vol, &rootkey, 353 1.13 maxv (hfs_catalog_keyed_record_t*)&rootthread, cbargs)!=0) 354 1.2 dillo HFS_LIBERR("could not find root parent"); 355 1.1 dillo 356 1.2 dillo memcpy(&out_vol->name, &rootthread.name, sizeof(hfs_unistr255_t)); 357 1.1 dillo 358 1.1 dillo /* FALLTHROUGH */ 359 1.1 dillo error: 360 1.7 pooka if (result != 0 && isopen) 361 1.6 pooka hfslib_close_volume(out_vol, cbargs); 362 1.1 dillo if(buffer!=NULL) 363 1.2 dillo hfslib_free(buffer, cbargs); 364 1.1 dillo return result; 365 1.1 dillo } 366 1.1 dillo 367 1.1 dillo void 368 1.2 dillo hfslib_close_volume(hfs_volume* in_vol, hfs_callback_args* cbargs) 369 1.1 dillo { 370 1.13 maxv if (in_vol == NULL) 371 1.1 dillo return; 372 1.2 dillo hfslib_closevoldevice(in_vol, cbargs); 373 1.1 dillo } 374 1.1 dillo 375 1.1 dillo int 376 1.2 dillo hfslib_path_to_cnid(hfs_volume* in_vol, 377 1.2 dillo hfs_cnid_t in_cnid, 378 1.1 dillo char** out_unicode, 379 1.1 dillo uint16_t* out_length, 380 1.2 dillo hfs_callback_args* cbargs) 381 1.1 dillo { 382 1.2 dillo hfs_thread_record_t parent_thread; 383 1.2 dillo hfs_cnid_t parent_cnid, child_cnid; 384 1.1 dillo char* newpath; 385 1.1 dillo char* path; 386 1.1 dillo int path_offset = 0; 387 1.1 dillo int result; 388 1.1 dillo uint16_t* ptr; /* dummy var */ 389 1.1 dillo uint16_t uchar; /* dummy var */ 390 1.1 dillo uint16_t total_path_length; 391 1.1 dillo 392 1.13 maxv if (in_vol == NULL || in_cnid == 0 || out_unicode == NULL || 393 1.13 maxv out_length == NULL) 394 1.1 dillo return 1; 395 1.13 maxv 396 1.1 dillo result = 1; 397 1.1 dillo *out_unicode = NULL; 398 1.1 dillo *out_length = 0; 399 1.1 dillo path = NULL; 400 1.1 dillo total_path_length = 0; 401 1.13 maxv 402 1.2 dillo path = hfslib_malloc(514, cbargs); /* 256 unichars plus a forward slash */ 403 1.13 maxv if (path == NULL) 404 1.1 dillo return 1; 405 1.1 dillo 406 1.1 dillo child_cnid = in_cnid; 407 1.1 dillo parent_cnid = child_cnid; /* skips loop in case in_cnid is root id */ 408 1.13 maxv while (parent_cnid != HFS_CNID_ROOT_FOLDER && 409 1.13 maxv parent_cnid != HFS_CNID_ROOT_PARENT) 410 1.1 dillo { 411 1.13 maxv if (child_cnid != in_cnid) { 412 1.2 dillo newpath = hfslib_realloc(path, 514 + total_path_length*2, cbargs); 413 1.13 maxv if (newpath == NULL) 414 1.1 dillo goto exit; 415 1.1 dillo path = newpath; 416 1.1 dillo memmove(path + 514, path + path_offset, total_path_length*2); 417 1.1 dillo } 418 1.1 dillo 419 1.2 dillo parent_cnid = hfslib_find_parent_thread(in_vol, child_cnid, 420 1.13 maxv &parent_thread, cbargs); 421 1.13 maxv if (parent_cnid == 0) 422 1.1 dillo goto exit; 423 1.1 dillo 424 1.1 dillo path_offset = 512 - parent_thread.name.length*2; 425 1.1 dillo 426 1.1 dillo memcpy(path + path_offset, parent_thread.name.unicode, 427 1.1 dillo parent_thread.name.length*2); 428 1.1 dillo 429 1.1 dillo /* Add a forward slash. The unicode string was specified in big endian 430 1.1 dillo * format, so convert to core format if necessary. */ 431 1.1 dillo path[512]=0x00; 432 1.1 dillo path[513]=0x2F; 433 1.1 dillo 434 1.1 dillo ptr = (uint16_t*)path + 256; 435 1.1 dillo uchar = be16tohp((void*)&ptr); 436 1.1 dillo *(ptr-1) = uchar; 437 1.1 dillo 438 1.1 dillo total_path_length += parent_thread.name.length + 1; 439 1.1 dillo 440 1.1 dillo child_cnid = parent_cnid; 441 1.1 dillo } 442 1.1 dillo 443 1.1 dillo /* 444 1.1 dillo * At this point, 'path' holds a sequence of unicode characters which 445 1.1 dillo * represent the absolute path to the given cnid. This string is missing 446 1.1 dillo * a terminating null char and an initial forward slash that represents 447 1.1 dillo * the root of the filesystem. It most likely also has extra space in 448 1.1 dillo * the beginning, due to the fact that we reserve 512 bytes for each path 449 1.1 dillo * component and won't usually use all that space. So, we allocate the 450 1.1 dillo * final string based on the actual length of the absolute path, plus four 451 1.1 dillo * additional bytes (two unichars) for the forward slash and the null char. 452 1.1 dillo */ 453 1.1 dillo 454 1.2 dillo *out_unicode = hfslib_malloc((total_path_length+2)*2, cbargs); 455 1.1 dillo if(*out_unicode == NULL) 456 1.1 dillo goto exit; 457 1.1 dillo 458 1.1 dillo /* copy only the bytes that are actually used */ 459 1.10 christos memcpy(*out_unicode + 2, path + path_offset, total_path_length*2); 460 1.1 dillo 461 1.1 dillo /* insert forward slash at start */ 462 1.10 christos uchar = be16toh(0x2F); 463 1.10 christos memcpy(*out_unicode, &uchar, sizeof(uchar)); 464 1.1 dillo 465 1.1 dillo /* insert null char at end */ 466 1.1 dillo (*out_unicode)[total_path_length*2+2] = 0x00; 467 1.1 dillo (*out_unicode)[total_path_length*2+3] = 0x00; 468 1.1 dillo 469 1.1 dillo *out_length = total_path_length + 1 /* extra for forward slash */ ; 470 1.1 dillo 471 1.1 dillo result = 0; 472 1.1 dillo 473 1.1 dillo exit: 474 1.1 dillo if(path!=NULL) 475 1.2 dillo hfslib_free(path, cbargs); 476 1.1 dillo 477 1.1 dillo return result; 478 1.1 dillo } 479 1.1 dillo 480 1.2 dillo hfs_cnid_t 481 1.2 dillo hfslib_find_parent_thread( 482 1.2 dillo hfs_volume* in_vol, 483 1.2 dillo hfs_cnid_t in_child, 484 1.2 dillo hfs_thread_record_t* out_thread, 485 1.2 dillo hfs_callback_args* cbargs) 486 1.1 dillo { 487 1.2 dillo hfs_catalog_key_t childkey; 488 1.1 dillo 489 1.1 dillo if(in_vol==NULL || in_child==0 || out_thread==NULL) 490 1.1 dillo return 0; 491 1.1 dillo 492 1.2 dillo if(hfslib_make_catalog_key(in_child, 0, NULL, &childkey)==0) 493 1.1 dillo return 0; 494 1.1 dillo 495 1.2 dillo if(hfslib_find_catalog_record_with_key(in_vol, &childkey, 496 1.2 dillo (hfs_catalog_keyed_record_t*)out_thread, cbargs)!=0) 497 1.1 dillo return 0; 498 1.1 dillo 499 1.1 dillo return out_thread->parent_cnid; 500 1.1 dillo } 501 1.1 dillo 502 1.1 dillo /* 503 1.2 dillo * hfslib_find_catalog_record_with_cnid() 504 1.1 dillo * 505 1.2 dillo * Looks up a catalog record by calling hfslib_find_parent_thread() and 506 1.2 dillo * hfslib_find_catalog_record_with_key(). out_key may be NULL; if not, the key 507 1.1 dillo * corresponding to this cnid is stuffed in it. Returns 0 on success. 508 1.1 dillo */ 509 1.1 dillo int 510 1.2 dillo hfslib_find_catalog_record_with_cnid( 511 1.2 dillo hfs_volume* in_vol, 512 1.2 dillo hfs_cnid_t in_cnid, 513 1.2 dillo hfs_catalog_keyed_record_t* out_rec, 514 1.2 dillo hfs_catalog_key_t* out_key, 515 1.2 dillo hfs_callback_args* cbargs) 516 1.2 dillo { 517 1.2 dillo hfs_cnid_t parentcnid; 518 1.2 dillo hfs_thread_record_t parentthread; 519 1.2 dillo hfs_catalog_key_t key; 520 1.1 dillo 521 1.1 dillo if(in_vol==NULL || in_cnid==0 || out_rec==NULL) 522 1.1 dillo return 0; 523 1.1 dillo 524 1.1 dillo parentcnid = 525 1.2 dillo hfslib_find_parent_thread(in_vol, in_cnid, &parentthread, cbargs); 526 1.1 dillo if(parentcnid == 0) 527 1.2 dillo HFS_LIBERR("could not find parent thread for cnid %i", in_cnid); 528 1.1 dillo 529 1.2 dillo if(hfslib_make_catalog_key(parentthread.parent_cnid, 530 1.1 dillo parentthread.name.length, parentthread.name.unicode, &key) == 0) 531 1.2 dillo HFS_LIBERR("could not make catalog search key"); 532 1.1 dillo 533 1.1 dillo if(out_key!=NULL) 534 1.1 dillo memcpy(out_key, &key, sizeof(key)); 535 1.1 dillo 536 1.2 dillo return hfslib_find_catalog_record_with_key(in_vol, &key, out_rec, cbargs); 537 1.1 dillo 538 1.1 dillo error: 539 1.1 dillo return 1; 540 1.1 dillo } 541 1.1 dillo 542 1.1 dillo /* Returns 0 on success, 1 on error, and -1 if record was not found. */ 543 1.1 dillo int 544 1.2 dillo hfslib_find_catalog_record_with_key( 545 1.2 dillo hfs_volume* in_vol, 546 1.2 dillo hfs_catalog_key_t* in_key, 547 1.2 dillo hfs_catalog_keyed_record_t* out_rec, 548 1.2 dillo hfs_callback_args* cbargs) 549 1.2 dillo { 550 1.2 dillo hfs_node_descriptor_t nd; 551 1.2 dillo hfs_extent_descriptor_t* extents; 552 1.2 dillo hfs_catalog_keyed_record_t lastrec; 553 1.2 dillo hfs_catalog_key_t* curkey; 554 1.1 dillo void** recs; 555 1.1 dillo void* buffer; 556 1.1 dillo uint64_t bytesread; 557 1.1 dillo uint32_t curnode; 558 1.1 dillo uint16_t* recsizes; 559 1.1 dillo uint16_t numextents; 560 1.1 dillo uint16_t recnum; 561 1.1 dillo int16_t leaftype; 562 1.1 dillo int keycompare; 563 1.1 dillo int result; 564 1.1 dillo 565 1.1 dillo if(in_key==NULL || out_rec==NULL || in_vol==NULL) 566 1.1 dillo return 1; 567 1.1 dillo 568 1.1 dillo result = 1; 569 1.1 dillo buffer = NULL; 570 1.1 dillo curkey = NULL; 571 1.1 dillo extents = NULL; 572 1.1 dillo recs = NULL; 573 1.1 dillo recsizes = NULL; 574 1.1 dillo 575 1.1 dillo /* The key takes up over half a kb of ram, which is a lot for the BSD 576 1.1 dillo * kernel stack. So allocate it in the heap instead to play it safe. */ 577 1.2 dillo curkey = hfslib_malloc(sizeof(hfs_catalog_key_t), cbargs); 578 1.1 dillo if(curkey==NULL) 579 1.2 dillo HFS_LIBERR("could not allocate catalog search key"); 580 1.1 dillo 581 1.2 dillo buffer = hfslib_malloc(in_vol->chr.node_size, cbargs); 582 1.1 dillo if(buffer==NULL) 583 1.2 dillo HFS_LIBERR("could not allocate node buffer"); 584 1.1 dillo 585 1.2 dillo numextents = hfslib_get_file_extents(in_vol, HFS_CNID_CATALOG, 586 1.2 dillo HFS_DATAFORK, &extents, cbargs); 587 1.1 dillo if(numextents==0) 588 1.2 dillo HFS_LIBERR("could not locate fork extents"); 589 1.1 dillo 590 1.1 dillo nd.num_recs = 0; 591 1.1 dillo curnode = in_vol->chr.root_node; 592 1.1 dillo 593 1.1 dillo #ifdef DLO_DEBUG 594 1.1 dillo printf("-> key "); 595 1.1 dillo dlo_print_key(in_key); 596 1.1 dillo printf("\n"); 597 1.1 dillo #endif 598 1.1 dillo 599 1.1 dillo do 600 1.1 dillo { 601 1.1 dillo #ifdef DLO_DEBUG 602 1.1 dillo printf("--> node %d\n", curnode); 603 1.1 dillo #endif 604 1.1 dillo 605 1.2 dillo if(hfslib_readd_with_extents(in_vol, buffer, 606 1.1 dillo &bytesread,in_vol->chr.node_size, curnode * in_vol->chr.node_size, 607 1.1 dillo extents, numextents, cbargs)!=0) 608 1.2 dillo HFS_LIBERR("could not read catalog node #%i", curnode); 609 1.1 dillo 610 1.2 dillo if(hfslib_reada_node(buffer, &nd, &recs, &recsizes, HFS_CATALOG_FILE, 611 1.1 dillo in_vol, cbargs)==0) 612 1.2 dillo HFS_LIBERR("could not parse catalog node #%i", curnode); 613 1.1 dillo 614 1.1 dillo for(recnum=0; recnum<nd.num_recs; recnum++) 615 1.1 dillo { 616 1.1 dillo leaftype = nd.kind; 617 1.2 dillo if(hfslib_read_catalog_keyed_record(recs[recnum], out_rec, 618 1.1 dillo &leaftype, curkey, in_vol)==0) 619 1.2 dillo HFS_LIBERR("could not read catalog record #%i",recnum); 620 1.1 dillo 621 1.1 dillo #ifdef DLO_DEBUG 622 1.1 dillo printf("---> record %d: ", recnum); 623 1.1 dillo dlo_print_key(curkey); 624 1.1 dillo fflush(stdout); 625 1.1 dillo #endif 626 1.1 dillo keycompare = in_vol->keycmp(in_key, curkey); 627 1.1 dillo #ifdef DLO_DEBUG 628 1.1 dillo printf(" %c\n", 629 1.1 dillo keycompare < 0 ? '<' 630 1.1 dillo : keycompare == 0 ? '=' : '>'); 631 1.1 dillo #endif 632 1.1 dillo 633 1.1 dillo if(keycompare < 0) 634 1.1 dillo { 635 1.1 dillo /* Check if key is less than *every* record, which should never 636 1.1 dillo * happen if the volume is consistent and the key legit. */ 637 1.1 dillo if(recnum==0) 638 1.2 dillo HFS_LIBERR("all records greater than key"); 639 1.1 dillo 640 1.1 dillo /* Otherwise, we've found the first record that exceeds our key, 641 1.1 dillo * so retrieve the previous record, which is still less... */ 642 1.1 dillo memcpy(out_rec, &lastrec, 643 1.2 dillo sizeof(hfs_catalog_keyed_record_t)); 644 1.1 dillo 645 1.1 dillo /* ...unless this is a leaf node, which means we've gone from 646 1.1 dillo * a key which is smaller than the search key, in the previous 647 1.1 dillo * loop, to a key which is larger, in this loop, and that 648 1.1 dillo * implies that our search key does not exist on the volume. */ 649 1.2 dillo if(nd.kind==HFS_LEAFNODE) 650 1.1 dillo result = -1; 651 1.1 dillo 652 1.1 dillo break; 653 1.1 dillo } 654 1.1 dillo else if(keycompare == 0) 655 1.1 dillo { 656 1.1 dillo /* If leaf node, found an exact match. */ 657 1.1 dillo result = 0; 658 1.1 dillo break; 659 1.1 dillo } 660 1.1 dillo else if(recnum==nd.num_recs-1 && keycompare > 0) 661 1.1 dillo { 662 1.1 dillo /* If leaf node, we've reached the last record with no match, 663 1.1 dillo * which means this key is not present on the volume. */ 664 1.1 dillo result = -1; 665 1.1 dillo break; 666 1.1 dillo } 667 1.1 dillo 668 1.2 dillo memcpy(&lastrec, out_rec, sizeof(hfs_catalog_keyed_record_t)); 669 1.1 dillo } 670 1.1 dillo 671 1.2 dillo if(nd.kind==HFS_INDEXNODE) 672 1.1 dillo curnode = out_rec->child; 673 1.2 dillo else if(nd.kind==HFS_LEAFNODE) 674 1.1 dillo break; 675 1.1 dillo 676 1.2 dillo hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs); 677 1.1 dillo } 678 1.2 dillo while(nd.kind!=HFS_LEAFNODE); 679 1.1 dillo 680 1.1 dillo /* FALLTHROUGH */ 681 1.1 dillo error: 682 1.1 dillo if(extents!=NULL) 683 1.2 dillo hfslib_free(extents, cbargs); 684 1.2 dillo hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs); 685 1.1 dillo if(curkey!=NULL) 686 1.2 dillo hfslib_free(curkey, cbargs); 687 1.1 dillo if(buffer!=NULL) 688 1.2 dillo hfslib_free(buffer, cbargs); 689 1.1 dillo 690 1.1 dillo return result; 691 1.1 dillo } 692 1.1 dillo 693 1.1 dillo /* returns 0 on success */ 694 1.1 dillo /* XXX Need to look this over and make sure it gracefully handles cases where 695 1.1 dillo * XXX the key is not found. */ 696 1.1 dillo int 697 1.2 dillo hfslib_find_extent_record_with_key(hfs_volume* in_vol, 698 1.2 dillo hfs_extent_key_t* in_key, 699 1.2 dillo hfs_extent_record_t* out_rec, 700 1.2 dillo hfs_callback_args* cbargs) 701 1.2 dillo { 702 1.2 dillo hfs_node_descriptor_t nd; 703 1.2 dillo hfs_extent_descriptor_t* extents; 704 1.2 dillo hfs_extent_record_t lastrec; 705 1.2 dillo hfs_extent_key_t curkey; 706 1.1 dillo void** recs; 707 1.1 dillo void* buffer; 708 1.1 dillo uint64_t bytesread; 709 1.1 dillo uint32_t curnode; 710 1.1 dillo uint16_t* recsizes; 711 1.1 dillo uint16_t numextents; 712 1.1 dillo uint16_t recnum; 713 1.1 dillo int keycompare; 714 1.1 dillo int result; 715 1.1 dillo 716 1.1 dillo if(in_vol==NULL || in_key==NULL || out_rec==NULL) 717 1.1 dillo return 1; 718 1.1 dillo 719 1.1 dillo result = 1; 720 1.1 dillo buffer = NULL; 721 1.1 dillo extents = NULL; 722 1.1 dillo recs = NULL; 723 1.1 dillo recsizes = NULL; 724 1.1 dillo 725 1.2 dillo buffer = hfslib_malloc(in_vol->ehr.node_size, cbargs); 726 1.1 dillo if(buffer==NULL) 727 1.2 dillo HFS_LIBERR("could not allocate node buffer"); 728 1.1 dillo 729 1.2 dillo numextents = hfslib_get_file_extents(in_vol, HFS_CNID_EXTENTS, 730 1.2 dillo HFS_DATAFORK, &extents, cbargs); 731 1.1 dillo if(numextents==0) 732 1.2 dillo HFS_LIBERR("could not locate fork extents"); 733 1.1 dillo 734 1.1 dillo nd.num_recs = 0; 735 1.1 dillo curnode = in_vol->ehr.root_node; 736 1.1 dillo 737 1.1 dillo do 738 1.1 dillo { 739 1.2 dillo hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs); 740 1.1 dillo recnum = 0; 741 1.1 dillo 742 1.2 dillo if(hfslib_readd_with_extents(in_vol, buffer, &bytesread, 743 1.1 dillo in_vol->ehr.node_size, curnode * in_vol->ehr.node_size, extents, 744 1.1 dillo numextents, cbargs)!=0) 745 1.2 dillo HFS_LIBERR("could not read extents overflow node #%i", curnode); 746 1.1 dillo 747 1.2 dillo if(hfslib_reada_node(buffer, &nd, &recs, &recsizes, HFS_EXTENTS_FILE, 748 1.1 dillo in_vol, cbargs)==0) 749 1.2 dillo HFS_LIBERR("could not parse extents overflow node #%i",curnode); 750 1.1 dillo 751 1.1 dillo for(recnum=0; recnum<nd.num_recs; recnum++) 752 1.1 dillo { 753 1.2 dillo memcpy(&lastrec, out_rec, sizeof(hfs_extent_record_t)); 754 1.1 dillo 755 1.2 dillo if(hfslib_read_extent_record(recs[recnum], out_rec, nd.kind, 756 1.1 dillo &curkey, in_vol)==0) 757 1.2 dillo HFS_LIBERR("could not read extents record #%i",recnum); 758 1.1 dillo 759 1.2 dillo keycompare = hfslib_compare_extent_keys(in_key, &curkey); 760 1.1 dillo if(keycompare < 0) 761 1.1 dillo { 762 1.1 dillo /* this should never happen for any legitimate key */ 763 1.1 dillo if(recnum==0) 764 1.1 dillo return 1; 765 1.1 dillo 766 1.2 dillo memcpy(out_rec, &lastrec, sizeof(hfs_extent_record_t)); 767 1.1 dillo 768 1.1 dillo break; 769 1.1 dillo } 770 1.1 dillo else if(keycompare == 0 || 771 1.1 dillo (recnum==nd.num_recs-1 && keycompare > 0)) 772 1.1 dillo break; 773 1.1 dillo } 774 1.1 dillo 775 1.2 dillo if(nd.kind==HFS_INDEXNODE) 776 1.1 dillo curnode = *((uint32_t *)out_rec); /* out_rec is a node ptr in this case */ 777 1.2 dillo else if(nd.kind==HFS_LEAFNODE) 778 1.1 dillo break; 779 1.1 dillo else 780 1.2 dillo HFS_LIBERR("unknwon node type for extents overflow node #%i",curnode); 781 1.1 dillo } 782 1.2 dillo while(nd.kind!=HFS_LEAFNODE); 783 1.1 dillo 784 1.1 dillo result = 0; 785 1.1 dillo 786 1.1 dillo /* FALLTHROUGH */ 787 1.1 dillo 788 1.1 dillo error: 789 1.1 dillo if(buffer!=NULL) 790 1.2 dillo hfslib_free(buffer, cbargs); 791 1.1 dillo if(extents!=NULL) 792 1.2 dillo hfslib_free(extents, cbargs); 793 1.2 dillo hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs); 794 1.1 dillo 795 1.1 dillo return result; 796 1.1 dillo } 797 1.1 dillo 798 1.1 dillo /* out_extents may be NULL. */ 799 1.1 dillo uint16_t 800 1.2 dillo hfslib_get_file_extents(hfs_volume* in_vol, 801 1.2 dillo hfs_cnid_t in_cnid, 802 1.1 dillo uint8_t in_forktype, 803 1.2 dillo hfs_extent_descriptor_t** out_extents, 804 1.2 dillo hfs_callback_args* cbargs) 805 1.1 dillo { 806 1.2 dillo hfs_extent_descriptor_t* dummy; 807 1.2 dillo hfs_extent_key_t extentkey; 808 1.2 dillo hfs_file_record_t file; 809 1.2 dillo hfs_catalog_key_t filekey; 810 1.2 dillo hfs_thread_record_t fileparent; 811 1.8 apb hfs_fork_t fork = {.logical_size = 0}; 812 1.2 dillo hfs_extent_record_t nextextentrec; 813 1.1 dillo uint32_t numblocks; 814 1.1 dillo uint16_t numextents, n; 815 1.1 dillo 816 1.1 dillo if(in_vol==NULL || in_cnid==0) 817 1.1 dillo return 0; 818 1.1 dillo 819 1.1 dillo if(out_extents!=NULL) 820 1.1 dillo { 821 1.2 dillo *out_extents = hfslib_malloc(sizeof(hfs_extent_descriptor_t), cbargs); 822 1.1 dillo if(*out_extents==NULL) 823 1.1 dillo return 0; 824 1.1 dillo } 825 1.1 dillo 826 1.1 dillo switch(in_cnid) 827 1.1 dillo { 828 1.2 dillo case HFS_CNID_CATALOG: 829 1.1 dillo fork = in_vol->vh.catalog_file; 830 1.1 dillo break; 831 1.1 dillo 832 1.2 dillo case HFS_CNID_EXTENTS: 833 1.1 dillo fork = in_vol->vh.extents_file; 834 1.1 dillo break; 835 1.1 dillo 836 1.2 dillo case HFS_CNID_ALLOCATION: 837 1.1 dillo fork = in_vol->vh.allocation_file; 838 1.1 dillo break; 839 1.1 dillo 840 1.2 dillo case HFS_CNID_ATTRIBUTES: 841 1.1 dillo fork = in_vol->vh.attributes_file; 842 1.1 dillo break; 843 1.1 dillo 844 1.2 dillo case HFS_CNID_STARTUP: 845 1.1 dillo fork = in_vol->vh.startup_file; 846 1.1 dillo break; 847 1.1 dillo 848 1.1 dillo default: 849 1.2 dillo if(hfslib_find_parent_thread(in_vol, in_cnid, &fileparent, 850 1.1 dillo cbargs)==0) 851 1.1 dillo goto error; 852 1.1 dillo 853 1.2 dillo if(hfslib_make_catalog_key(fileparent.parent_cnid, 854 1.1 dillo fileparent.name.length, fileparent.name.unicode, &filekey)==0) 855 1.1 dillo goto error; 856 1.1 dillo 857 1.2 dillo if(hfslib_find_catalog_record_with_key(in_vol, &filekey, 858 1.2 dillo (hfs_catalog_keyed_record_t*)&file, cbargs)!=0) 859 1.1 dillo goto error; 860 1.1 dillo 861 1.1 dillo /* only files have extents, not folders or threads */ 862 1.2 dillo if(file.rec_type!=HFS_REC_FILE) 863 1.1 dillo goto error; 864 1.1 dillo 865 1.2 dillo if(in_forktype==HFS_DATAFORK) 866 1.1 dillo fork = file.data_fork; 867 1.2 dillo else if(in_forktype==HFS_RSRCFORK) 868 1.1 dillo fork = file.rsrc_fork; 869 1.1 dillo } 870 1.1 dillo 871 1.1 dillo numextents = 0; 872 1.1 dillo numblocks = 0; 873 1.2 dillo memcpy(&nextextentrec, &fork.extents, sizeof(hfs_extent_record_t)); 874 1.1 dillo 875 1.1 dillo while(1) 876 1.1 dillo { 877 1.1 dillo for(n=0; n<8; n++) 878 1.1 dillo { 879 1.1 dillo if(nextextentrec[n].block_count==0) 880 1.1 dillo break; 881 1.1 dillo 882 1.1 dillo numblocks += nextextentrec[n].block_count; 883 1.1 dillo } 884 1.1 dillo 885 1.1 dillo if(out_extents!=NULL) 886 1.1 dillo { 887 1.2 dillo dummy = hfslib_realloc(*out_extents, 888 1.2 dillo (numextents+n) * sizeof(hfs_extent_descriptor_t), 889 1.1 dillo cbargs); 890 1.1 dillo if(dummy==NULL) 891 1.1 dillo goto error; 892 1.1 dillo *out_extents = dummy; 893 1.1 dillo 894 1.1 dillo memcpy(*out_extents + numextents, 895 1.2 dillo &nextextentrec, n*sizeof(hfs_extent_descriptor_t)); 896 1.1 dillo } 897 1.1 dillo numextents += n; 898 1.1 dillo 899 1.1 dillo if(numblocks >= fork.total_blocks) 900 1.1 dillo break; 901 1.1 dillo 902 1.2 dillo if(hfslib_make_extent_key(in_cnid, in_forktype, numblocks, 903 1.1 dillo &extentkey)==0) 904 1.1 dillo goto error; 905 1.1 dillo 906 1.2 dillo if(hfslib_find_extent_record_with_key(in_vol, &extentkey, 907 1.1 dillo &nextextentrec, cbargs)!=0) 908 1.1 dillo goto error; 909 1.1 dillo } 910 1.1 dillo 911 1.1 dillo goto exit; 912 1.1 dillo 913 1.1 dillo error: 914 1.1 dillo if(out_extents!=NULL && *out_extents!=NULL) 915 1.1 dillo { 916 1.2 dillo hfslib_free(*out_extents, cbargs); 917 1.1 dillo *out_extents = NULL; 918 1.1 dillo } 919 1.1 dillo return 0; 920 1.1 dillo 921 1.1 dillo exit: 922 1.1 dillo return numextents; 923 1.1 dillo } 924 1.1 dillo 925 1.1 dillo /* 926 1.2 dillo * hfslib_get_directory_contents() 927 1.1 dillo * 928 1.1 dillo * Finds the immediate children of a given directory CNID and places their 929 1.1 dillo * CNIDs in an array allocated here. The first child is found by doing a 930 1.1 dillo * catalog search that only compares parent CNIDs (ignoring file/folder names) 931 1.1 dillo * and skips over thread records. Then the remaining children are listed in 932 1.1 dillo * ascending order by name, according to the HFS+ spec, so just read off each 933 1.1 dillo * successive leaf node until a different parent CNID is found. 934 1.1 dillo * 935 1.1 dillo * If out_childnames is not NULL, it will be allocated and set to an array of 936 1.2 dillo * hfs_unistr255_t's which correspond to the name of the child with that same 937 1.1 dillo * index. 938 1.1 dillo * 939 1.1 dillo * out_children may be NULL. 940 1.1 dillo * 941 1.1 dillo * Returns 0 on success. 942 1.1 dillo */ 943 1.1 dillo int 944 1.2 dillo hfslib_get_directory_contents( 945 1.2 dillo hfs_volume* in_vol, 946 1.2 dillo hfs_cnid_t in_dir, 947 1.2 dillo hfs_catalog_keyed_record_t** out_children, 948 1.2 dillo hfs_unistr255_t** out_childnames, 949 1.1 dillo uint32_t* out_numchildren, 950 1.2 dillo hfs_callback_args* cbargs) 951 1.1 dillo { 952 1.2 dillo hfs_node_descriptor_t nd; 953 1.2 dillo hfs_extent_descriptor_t* extents; 954 1.2 dillo hfs_catalog_keyed_record_t currec; 955 1.2 dillo hfs_catalog_key_t curkey; 956 1.1 dillo void** recs; 957 1.1 dillo void* buffer; 958 1.1 dillo void* ptr; /* temporary pointer for realloc() */ 959 1.1 dillo uint64_t bytesread; 960 1.1 dillo uint32_t curnode; 961 1.1 dillo uint32_t lastnode; 962 1.1 dillo uint16_t* recsizes; 963 1.1 dillo uint16_t numextents; 964 1.1 dillo uint16_t recnum; 965 1.1 dillo int16_t leaftype; 966 1.1 dillo int keycompare; 967 1.1 dillo int result; 968 1.1 dillo 969 1.1 dillo if(in_vol==NULL || in_dir==0 || out_numchildren==NULL) 970 1.1 dillo return 1; 971 1.1 dillo 972 1.1 dillo result = 1; 973 1.1 dillo buffer = NULL; 974 1.1 dillo extents = NULL; 975 1.1 dillo lastnode = 0; 976 1.1 dillo recs = NULL; 977 1.1 dillo recsizes = NULL; 978 1.1 dillo *out_numchildren = 0; 979 1.1 dillo if(out_children!=NULL) 980 1.1 dillo *out_children = NULL; 981 1.1 dillo if(out_childnames!=NULL) 982 1.1 dillo *out_childnames = NULL; 983 1.1 dillo 984 1.2 dillo buffer = hfslib_malloc(in_vol->chr.node_size, cbargs); 985 1.1 dillo if(buffer==NULL) 986 1.2 dillo HFS_LIBERR("could not allocate node buffer"); 987 1.1 dillo 988 1.2 dillo numextents = hfslib_get_file_extents(in_vol, HFS_CNID_CATALOG, 989 1.2 dillo HFS_DATAFORK, &extents, cbargs); 990 1.1 dillo if(numextents==0) 991 1.2 dillo HFS_LIBERR("could not locate fork extents"); 992 1.1 dillo 993 1.1 dillo nd.num_recs = 0; 994 1.1 dillo curnode = in_vol->chr.root_node; 995 1.1 dillo 996 1.1 dillo while(1) 997 1.1 dillo { 998 1.2 dillo hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs); 999 1.1 dillo recnum = 0; 1000 1.1 dillo 1001 1.2 dillo if(hfslib_readd_with_extents(in_vol, buffer, &bytesread, 1002 1.1 dillo in_vol->chr.node_size, curnode * in_vol->chr.node_size, extents, 1003 1.1 dillo numextents, cbargs)!=0) 1004 1.2 dillo HFS_LIBERR("could not read catalog node #%i", curnode); 1005 1.1 dillo 1006 1.2 dillo if(hfslib_reada_node(buffer, &nd, &recs, &recsizes, HFS_CATALOG_FILE, 1007 1.1 dillo in_vol, cbargs)==0) 1008 1.2 dillo HFS_LIBERR("could not parse catalog node #%i", curnode); 1009 1.1 dillo 1010 1.1 dillo for(recnum=0; recnum<nd.num_recs; recnum++) 1011 1.1 dillo { 1012 1.1 dillo leaftype = nd.kind; /* needed b/c leaftype might be modified now */ 1013 1.2 dillo if(hfslib_read_catalog_keyed_record(recs[recnum], &currec, 1014 1.1 dillo &leaftype, &curkey, in_vol)==0) 1015 1.2 dillo HFS_LIBERR("could not read cat record %i:%i", curnode, recnum); 1016 1.1 dillo 1017 1.2 dillo if(nd.kind==HFS_INDEXNODE) 1018 1.1 dillo { 1019 1.1 dillo keycompare = in_dir - curkey.parent_cnid; 1020 1.1 dillo if(keycompare < 0) 1021 1.1 dillo { 1022 1.1 dillo /* Check if key is less than *every* record, which should 1023 1.1 dillo * never happen if the volume and key are good. */ 1024 1.1 dillo if(recnum==0) 1025 1.2 dillo HFS_LIBERR("all records greater than key"); 1026 1.1 dillo 1027 1.1 dillo /* Otherwise, we've found the first record that exceeds our 1028 1.1 dillo * key, so retrieve the previous, lesser record. */ 1029 1.1 dillo curnode = lastnode; 1030 1.1 dillo break; 1031 1.1 dillo } 1032 1.1 dillo else if(keycompare == 0) 1033 1.1 dillo { 1034 1.1 dillo /* 1035 1.1 dillo * Normally, if we were doing a typical catalog lookup with 1036 1.1 dillo * both a parent cnid AND a name, keycompare==0 would be an 1037 1.1 dillo * exact match. However, since we are ignoring object names 1038 1.1 dillo * in this case and only comparing parent cnids, a direct 1039 1.1 dillo * match on only a parent cnid could mean that we've found 1040 1.1 dillo * an object with that parent cnid BUT which is NOT the 1041 1.1 dillo * first object (according to the HFS+ spec) with that 1042 1.1 dillo * parent cnid. Thus, when we find a parent cnid match, we 1043 1.1 dillo * still go back to the previously found leaf node and start 1044 1.1 dillo * checking it for a possible prior instance of an object 1045 1.1 dillo * with our desired parent cnid. 1046 1.1 dillo */ 1047 1.1 dillo curnode = lastnode; 1048 1.1 dillo break; 1049 1.1 dillo } 1050 1.1 dillo else if (recnum==nd.num_recs-1 && keycompare > 0) 1051 1.1 dillo { 1052 1.1 dillo /* Descend to child node if we found an exact match, or if 1053 1.1 dillo * this is the last pointer record. */ 1054 1.1 dillo curnode = currec.child; 1055 1.1 dillo break; 1056 1.1 dillo } 1057 1.1 dillo 1058 1.1 dillo lastnode = currec.child; 1059 1.1 dillo } 1060 1.1 dillo else 1061 1.1 dillo { 1062 1.1 dillo /* 1063 1.1 dillo * We have now descended down the hierarchy of index nodes into 1064 1.1 dillo * the leaf node that contains the first catalog record with a 1065 1.1 dillo * matching parent CNID. Since all leaf nodes are chained 1066 1.1 dillo * through their flink/blink, we can simply walk forward through 1067 1.1 dillo * this chain, copying every matching non-thread record, until 1068 1.1 dillo * we hit a record with a different parent CNID. At that point, 1069 1.1 dillo * we've retrieved all of our directory's items, if any. 1070 1.1 dillo */ 1071 1.1 dillo curnode = nd.flink; 1072 1.1 dillo 1073 1.1 dillo if(curkey.parent_cnid<in_dir) 1074 1.1 dillo continue; 1075 1.1 dillo else if(curkey.parent_cnid==in_dir) 1076 1.1 dillo { 1077 1.1 dillo /* Hide files/folders which are supposed to be invisible 1078 1.1 dillo * to users, according to the hfs+ spec. */ 1079 1.2 dillo if(hfslib_is_private_file(&curkey)) 1080 1.1 dillo continue; 1081 1.1 dillo 1082 1.1 dillo /* leaftype has now been set to the catalog record type */ 1083 1.2 dillo if(leaftype==HFS_REC_FLDR || leaftype==HFS_REC_FILE) 1084 1.1 dillo { 1085 1.1 dillo (*out_numchildren)++; 1086 1.1 dillo 1087 1.1 dillo if(out_children!=NULL) 1088 1.1 dillo { 1089 1.2 dillo ptr = hfslib_realloc(*out_children, 1090 1.1 dillo *out_numchildren * 1091 1.2 dillo sizeof(hfs_catalog_keyed_record_t), cbargs); 1092 1.1 dillo if(ptr==NULL) 1093 1.2 dillo HFS_LIBERR("could not allocate child record"); 1094 1.1 dillo *out_children = ptr; 1095 1.1 dillo 1096 1.1 dillo memcpy(&((*out_children)[*out_numchildren-1]), 1097 1.2 dillo &currec, sizeof(hfs_catalog_keyed_record_t)); 1098 1.1 dillo } 1099 1.1 dillo 1100 1.1 dillo if(out_childnames!=NULL) 1101 1.1 dillo { 1102 1.2 dillo ptr = hfslib_realloc(*out_childnames, 1103 1.2 dillo *out_numchildren * sizeof(hfs_unistr255_t), 1104 1.1 dillo cbargs); 1105 1.1 dillo if(ptr==NULL) 1106 1.2 dillo HFS_LIBERR("could not allocate child name"); 1107 1.1 dillo *out_childnames = ptr; 1108 1.1 dillo 1109 1.1 dillo memcpy(&((*out_childnames)[*out_numchildren-1]), 1110 1.2 dillo &curkey.name, sizeof(hfs_unistr255_t)); 1111 1.1 dillo } 1112 1.1 dillo } 1113 1.1 dillo } else { 1114 1.1 dillo result = 0; 1115 1.1 dillo /* We have just now passed the last item in the desired 1116 1.1 dillo * folder (or the folder was empty), so exit. */ 1117 1.1 dillo goto exit; 1118 1.1 dillo } 1119 1.1 dillo } 1120 1.1 dillo } 1121 1.1 dillo } 1122 1.1 dillo 1123 1.1 dillo result = 0; 1124 1.1 dillo 1125 1.1 dillo goto exit; 1126 1.1 dillo 1127 1.1 dillo error: 1128 1.1 dillo if(out_children!=NULL && *out_children!=NULL) 1129 1.2 dillo hfslib_free(*out_children, cbargs); 1130 1.1 dillo if(out_childnames!=NULL && *out_childnames!=NULL) 1131 1.2 dillo hfslib_free(*out_childnames, cbargs); 1132 1.1 dillo 1133 1.1 dillo /* FALLTHROUGH */ 1134 1.1 dillo 1135 1.1 dillo exit: 1136 1.1 dillo if(extents!=NULL) 1137 1.2 dillo hfslib_free(extents, cbargs); 1138 1.2 dillo hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs); 1139 1.1 dillo if(buffer!=NULL) 1140 1.2 dillo hfslib_free(buffer, cbargs); 1141 1.1 dillo 1142 1.1 dillo return result; 1143 1.1 dillo } 1144 1.1 dillo 1145 1.1 dillo int 1146 1.2 dillo hfslib_is_journal_clean(hfs_volume* in_vol) 1147 1.1 dillo { 1148 1.1 dillo if(in_vol==NULL) 1149 1.1 dillo return 0; 1150 1.1 dillo 1151 1.1 dillo /* return true if no journal */ 1152 1.2 dillo if(!(in_vol->vh.attributes & (1<<HFS_VOL_JOURNALED))) 1153 1.1 dillo return 1; 1154 1.1 dillo 1155 1.1 dillo return (in_vol->jh.start == in_vol->jh.end); 1156 1.1 dillo } 1157 1.1 dillo 1158 1.1 dillo /* 1159 1.2 dillo * hfslib_is_private_file() 1160 1.1 dillo * 1161 1.1 dillo * Given a file/folder's key and parent CNID, determines if it should be hidden 1162 1.1 dillo * from the user (e.g., the journal header file or the HFS+ Private Data folder) 1163 1.1 dillo */ 1164 1.1 dillo int 1165 1.2 dillo hfslib_is_private_file(hfs_catalog_key_t *filekey) 1166 1.1 dillo { 1167 1.2 dillo hfs_catalog_key_t* curkey = NULL; 1168 1.1 dillo int i = 0; 1169 1.1 dillo 1170 1.1 dillo /* 1171 1.1 dillo * According to the HFS+ spec to date, all special objects are located in 1172 1.1 dillo * the root directory of the volume, so don't bother going further if the 1173 1.1 dillo * requested object is not. 1174 1.1 dillo */ 1175 1.2 dillo if(filekey->parent_cnid != HFS_CNID_ROOT_FOLDER) 1176 1.1 dillo return 0; 1177 1.1 dillo 1178 1.2 dillo while((curkey = hfs_gPrivateObjectKeys[i]) != NULL) 1179 1.1 dillo { 1180 1.1 dillo /* XXX Always use binary compare here, or use volume's specific key 1181 1.1 dillo * XXX comparison routine? */ 1182 1.1 dillo if(filekey->name.length == curkey->name.length 1183 1.1 dillo && memcmp(filekey->name.unicode, curkey->name.unicode, 1184 1.1 dillo 2 * curkey->name.length)==0) 1185 1.1 dillo return 1; 1186 1.1 dillo 1187 1.1 dillo i++; 1188 1.1 dillo } 1189 1.1 dillo 1190 1.1 dillo return 0; 1191 1.1 dillo } 1192 1.1 dillo 1193 1.1 dillo 1194 1.1 dillo /* bool 1195 1.2 dillo hfslib_is_journal_valid(hfs_volume* in_vol) 1196 1.1 dillo { 1197 1.1 dillo - check magic numbers 1198 1.1 dillo - check Other Things 1199 1.1 dillo }*/ 1200 1.1 dillo 1201 1.1 dillo #if 0 1202 1.1 dillo #pragma mark - 1203 1.1 dillo #pragma mark Major Structures 1204 1.1 dillo #endif 1205 1.1 dillo 1206 1.1 dillo /* 1207 1.2 dillo * hfslib_read_volume_header() 1208 1.1 dillo * 1209 1.1 dillo * Reads in_bytes, formats the data appropriately, and places the result 1210 1.1 dillo * in out_header, which is assumed to be previously allocated. Returns number 1211 1.1 dillo * of bytes read, 0 if failed. 1212 1.1 dillo */ 1213 1.1 dillo 1214 1.1 dillo size_t 1215 1.2 dillo hfslib_read_volume_header(void* in_bytes, hfs_volume_header_t* out_header) 1216 1.1 dillo { 1217 1.1 dillo void* ptr; 1218 1.1 dillo size_t last_bytes_read; 1219 1.1 dillo int i; 1220 1.1 dillo 1221 1.1 dillo if(in_bytes==NULL || out_header==NULL) 1222 1.1 dillo return 0; 1223 1.1 dillo 1224 1.1 dillo ptr = in_bytes; 1225 1.1 dillo 1226 1.1 dillo out_header->signature = be16tohp(&ptr); 1227 1.1 dillo out_header->version = be16tohp(&ptr); 1228 1.1 dillo out_header->attributes = be32tohp(&ptr); 1229 1.1 dillo out_header->last_mounting_version = be32tohp(&ptr); 1230 1.1 dillo out_header->journal_info_block = be32tohp(&ptr); 1231 1.1 dillo 1232 1.1 dillo out_header->date_created = be32tohp(&ptr); 1233 1.1 dillo out_header->date_modified = be32tohp(&ptr); 1234 1.1 dillo out_header->date_backedup = be32tohp(&ptr); 1235 1.1 dillo out_header->date_checked = be32tohp(&ptr); 1236 1.1 dillo 1237 1.1 dillo out_header->file_count = be32tohp(&ptr); 1238 1.1 dillo out_header->folder_count = be32tohp(&ptr); 1239 1.1 dillo 1240 1.1 dillo out_header->block_size = be32tohp(&ptr); 1241 1.1 dillo out_header->total_blocks = be32tohp(&ptr); 1242 1.1 dillo out_header->free_blocks = be32tohp(&ptr); 1243 1.1 dillo out_header->next_alloc_block = be32tohp(&ptr); 1244 1.1 dillo out_header->rsrc_clump_size = be32tohp(&ptr); 1245 1.1 dillo out_header->data_clump_size = be32tohp(&ptr); 1246 1.1 dillo out_header->next_cnid = be32tohp(&ptr); 1247 1.1 dillo 1248 1.1 dillo out_header->write_count = be32tohp(&ptr); 1249 1.1 dillo out_header->encodings = be64tohp(&ptr); 1250 1.1 dillo 1251 1.1 dillo for(i=0;i<8;i++) 1252 1.1 dillo out_header->finder_info[i] = be32tohp(&ptr); 1253 1.1 dillo 1254 1.2 dillo if((last_bytes_read = hfslib_read_fork_descriptor(ptr, 1255 1.1 dillo &out_header->allocation_file))==0) 1256 1.1 dillo return 0; 1257 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1258 1.1 dillo 1259 1.2 dillo if((last_bytes_read = hfslib_read_fork_descriptor(ptr, 1260 1.1 dillo &out_header->extents_file))==0) 1261 1.1 dillo return 0; 1262 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1263 1.1 dillo 1264 1.2 dillo if((last_bytes_read = hfslib_read_fork_descriptor(ptr, 1265 1.1 dillo &out_header->catalog_file))==0) 1266 1.1 dillo return 0; 1267 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1268 1.1 dillo 1269 1.2 dillo if((last_bytes_read = hfslib_read_fork_descriptor(ptr, 1270 1.1 dillo &out_header->attributes_file))==0) 1271 1.1 dillo return 0; 1272 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1273 1.1 dillo 1274 1.2 dillo if((last_bytes_read = hfslib_read_fork_descriptor(ptr, 1275 1.1 dillo &out_header->startup_file))==0) 1276 1.1 dillo return 0; 1277 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1278 1.1 dillo 1279 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1280 1.1 dillo } 1281 1.1 dillo 1282 1.1 dillo /* 1283 1.4 dillo * hfsplib_read_master_directory_block() 1284 1.4 dillo * 1285 1.4 dillo * Reads in_bytes, formats the data appropriately, and places the result 1286 1.4 dillo * in out_header, which is assumed to be previously allocated. Returns numb 1287 1.4 dillo er 1288 1.4 dillo * of bytes read, 0 if failed. 1289 1.4 dillo */ 1290 1.4 dillo 1291 1.4 dillo size_t 1292 1.4 dillo hfslib_read_master_directory_block(void* in_bytes, 1293 1.4 dillo hfs_hfs_master_directory_block_t* out_mdr) 1294 1.4 dillo { 1295 1.4 dillo void* ptr; 1296 1.4 dillo int i; 1297 1.4 dillo 1298 1.4 dillo if(in_bytes==NULL || out_mdr==NULL) 1299 1.4 dillo return 0; 1300 1.4 dillo 1301 1.4 dillo ptr = in_bytes; 1302 1.4 dillo 1303 1.4 dillo out_mdr->signature = be16tohp(&ptr); 1304 1.4 dillo 1305 1.4 dillo out_mdr->date_created = be32tohp(&ptr); 1306 1.4 dillo out_mdr->date_modified = be32tohp(&ptr); 1307 1.4 dillo 1308 1.4 dillo out_mdr->attributes = be16tohp(&ptr); 1309 1.4 dillo out_mdr->root_file_count = be16tohp(&ptr); 1310 1.4 dillo out_mdr->volume_bitmap = be16tohp(&ptr); 1311 1.4 dillo 1312 1.4 dillo out_mdr->next_alloc_block = be16tohp(&ptr); 1313 1.4 dillo out_mdr->total_blocks = be16tohp(&ptr); 1314 1.4 dillo out_mdr->block_size = be32tohp(&ptr); 1315 1.4 dillo 1316 1.4 dillo out_mdr->clump_size = be32tohp(&ptr); 1317 1.4 dillo out_mdr->first_block = be16tohp(&ptr); 1318 1.4 dillo out_mdr->next_cnid = be32tohp(&ptr); 1319 1.4 dillo out_mdr->free_blocks = be16tohp(&ptr); 1320 1.4 dillo 1321 1.4 dillo memcpy(out_mdr->volume_name, ptr, 28); 1322 1.4 dillo ptr = (char *)ptr + 28; 1323 1.4 dillo 1324 1.4 dillo out_mdr->date_backedup = be32tohp(&ptr); 1325 1.4 dillo out_mdr->backup_seqnum = be16tohp(&ptr); 1326 1.4 dillo 1327 1.4 dillo out_mdr->write_count = be32tohp(&ptr); 1328 1.4 dillo 1329 1.4 dillo out_mdr->extents_clump_size = be32tohp(&ptr); 1330 1.4 dillo out_mdr->catalog_clump_size = be32tohp(&ptr); 1331 1.4 dillo 1332 1.4 dillo out_mdr->root_folder_count = be16tohp(&ptr); 1333 1.4 dillo out_mdr->file_count = be32tohp(&ptr); 1334 1.4 dillo out_mdr->folder_count = be32tohp(&ptr); 1335 1.4 dillo 1336 1.4 dillo for(i=0;i<8;i++) 1337 1.4 dillo out_mdr->finder_info[i] = be32tohp(&ptr); 1338 1.4 dillo 1339 1.4 dillo out_mdr->embedded_signature = be16tohp(&ptr); 1340 1.4 dillo out_mdr->embedded_extent.start_block = be16tohp(&ptr); 1341 1.4 dillo out_mdr->embedded_extent.block_count = be16tohp(&ptr); 1342 1.4 dillo 1343 1.4 dillo out_mdr->extents_size = be32tohp(&ptr); 1344 1.4 dillo for (i = 0; i < 3; i++) 1345 1.4 dillo { 1346 1.4 dillo out_mdr->extents_extents[i].start_block = be16tohp(&ptr); 1347 1.4 dillo out_mdr->extents_extents[i].block_count = be16tohp(&ptr); 1348 1.4 dillo } 1349 1.4 dillo 1350 1.4 dillo out_mdr->catalog_size = be32tohp(&ptr); 1351 1.4 dillo for (i = 0; i < 3; i++) 1352 1.4 dillo { 1353 1.4 dillo out_mdr->catalog_extents[i].start_block = be16tohp(&ptr); 1354 1.4 dillo out_mdr->catalog_extents[i].block_count = be16tohp(&ptr); 1355 1.4 dillo } 1356 1.4 dillo 1357 1.4 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1358 1.4 dillo } 1359 1.4 dillo 1360 1.4 dillo /* 1361 1.2 dillo * hfslib_reada_node() 1362 1.1 dillo * 1363 1.1 dillo * Given the pointer to and size of a buffer containing the entire, raw 1364 1.1 dillo * contents of any b-tree node from the disk, this function will: 1365 1.1 dillo * 1366 1.1 dillo * 1. determine the type of node and read its contents 1367 1.1 dillo * 2. allocate memory for each record and fill it appropriately 1368 1.1 dillo * 3. set out_record_ptrs_array to point to an array (which it allocates) 1369 1.1 dillo * which has out_node_descriptor->num_recs many pointers to the 1370 1.1 dillo * records themselves 1371 1.1 dillo * 4. allocate out_record_ptr_sizes_array and fill it with the sizes of 1372 1.1 dillo * each record 1373 1.1 dillo * 5. return the number of bytes read (i.e., the size of the node) 1374 1.1 dillo * or 0 on failure 1375 1.1 dillo * 1376 1.1 dillo * out_node_descriptor must be allocated by the caller and may not be NULL. 1377 1.1 dillo * 1378 1.1 dillo * out_record_ptrs_array and out_record_ptr_sizes_array must both be specified, 1379 1.1 dillo * or both be NULL if the caller is not interested in reading the records. 1380 1.1 dillo * 1381 1.1 dillo * out_record_ptr_sizes_array may be NULL if the caller is not interested in 1382 1.1 dillo * reading the records, but must not be NULL if out_record_ptrs_array is not. 1383 1.1 dillo * 1384 1.2 dillo * in_parent_file is HFS_CATALOG_FILE, HFS_EXTENTS_FILE, or 1385 1.2 dillo * HFS_ATTRIBUTES_FILE, depending on the special file in which this node 1386 1.1 dillo * resides. 1387 1.1 dillo * 1388 1.1 dillo * inout_volume must have its catnodesize or extnodesize field (depending on 1389 1.1 dillo * the parent file) set to the correct value if this is an index, leaf, or map 1390 1.1 dillo * node. If this is a header node, the field will be set to its correct value. 1391 1.1 dillo */ 1392 1.1 dillo size_t 1393 1.2 dillo hfslib_reada_node(void* in_bytes, 1394 1.2 dillo hfs_node_descriptor_t* out_node_descriptor, 1395 1.1 dillo void** out_record_ptrs_array[], 1396 1.1 dillo uint16_t* out_record_ptr_sizes_array[], 1397 1.2 dillo hfs_btree_file_type in_parent_file, 1398 1.2 dillo hfs_volume* inout_volume, 1399 1.2 dillo hfs_callback_args* cbargs) 1400 1.1 dillo { 1401 1.1 dillo void* ptr; 1402 1.1 dillo uint16_t* rec_offsets; 1403 1.1 dillo size_t last_bytes_read; 1404 1.1 dillo uint16_t nodesize; 1405 1.1 dillo uint16_t numrecords; 1406 1.1 dillo uint16_t free_space_offset; /* offset to free space in node */ 1407 1.1 dillo int keysizefieldsize; 1408 1.1 dillo int i; 1409 1.1 dillo 1410 1.1 dillo numrecords = 0; 1411 1.1 dillo rec_offsets = NULL; 1412 1.1 dillo if(out_record_ptrs_array!=NULL) 1413 1.1 dillo *out_record_ptrs_array = NULL; 1414 1.1 dillo if(out_record_ptr_sizes_array!=NULL) 1415 1.1 dillo *out_record_ptr_sizes_array = NULL; 1416 1.1 dillo 1417 1.1 dillo if(in_bytes==NULL || inout_volume==NULL || out_node_descriptor==NULL 1418 1.1 dillo || (out_record_ptrs_array==NULL && out_record_ptr_sizes_array!=NULL) 1419 1.1 dillo || (out_record_ptrs_array!=NULL && out_record_ptr_sizes_array==NULL) ) 1420 1.1 dillo goto error; 1421 1.1 dillo 1422 1.1 dillo ptr = in_bytes; 1423 1.1 dillo 1424 1.1 dillo out_node_descriptor->flink = be32tohp(&ptr); 1425 1.1 dillo out_node_descriptor->blink = be32tohp(&ptr); 1426 1.1 dillo out_node_descriptor->kind = *(((int8_t*)ptr)); 1427 1.1 dillo ptr = (uint8_t*)ptr + 1; 1428 1.1 dillo out_node_descriptor->height = *(((uint8_t*)ptr)); 1429 1.1 dillo ptr = (uint8_t*)ptr + 1; 1430 1.1 dillo out_node_descriptor->num_recs = be16tohp(&ptr); 1431 1.1 dillo out_node_descriptor->reserved = be16tohp(&ptr); 1432 1.1 dillo 1433 1.1 dillo numrecords = out_node_descriptor->num_recs; 1434 1.1 dillo 1435 1.1 dillo /* 1436 1.1 dillo * To go any further, we will need to know the size of this node, as well 1437 1.1 dillo * as the width of keyed records' key_len parameters for this btree. If 1438 1.1 dillo * this is an index, leaf, or map node, inout_volume already has the node 1439 1.1 dillo * size set in its catnodesize or extnodesize field and the key length set 1440 1.1 dillo * in the catkeysizefieldsize or extkeysizefieldsize for catalog files and 1441 1.1 dillo * extent files, respectively. However, if this is a header node, this 1442 1.1 dillo * information has not yet been determined, so this is the place to do it. 1443 1.1 dillo */ 1444 1.2 dillo if(out_node_descriptor->kind == HFS_HEADERNODE) 1445 1.1 dillo { 1446 1.2 dillo hfs_header_record_t hr; 1447 1.1 dillo void* header_rec_offset[1]; 1448 1.1 dillo uint16_t header_rec_size[1]; 1449 1.1 dillo 1450 1.1 dillo /* sanity check to ensure this is a good header node */ 1451 1.1 dillo if(numrecords!=3) 1452 1.2 dillo HFS_LIBERR("header node does not have exactly 3 records"); 1453 1.1 dillo 1454 1.1 dillo header_rec_offset[0] = ptr; 1455 1.2 dillo header_rec_size[0] = sizeof(hfs_header_record_t); 1456 1.1 dillo 1457 1.2 dillo last_bytes_read = hfslib_read_header_node(header_rec_offset, 1458 1.1 dillo header_rec_size, 1, &hr, NULL, NULL); 1459 1.1 dillo if(last_bytes_read==0) 1460 1.2 dillo HFS_LIBERR("could not read header node"); 1461 1.1 dillo 1462 1.1 dillo switch(in_parent_file) 1463 1.1 dillo { 1464 1.2 dillo case HFS_CATALOG_FILE: 1465 1.1 dillo inout_volume->chr.node_size = hr.node_size; 1466 1.1 dillo inout_volume->catkeysizefieldsize = 1467 1.2 dillo (hr.attributes & HFS_BIG_KEYS_MASK) ? 1468 1.1 dillo sizeof(uint16_t):sizeof(uint8_t); 1469 1.1 dillo break; 1470 1.1 dillo 1471 1.2 dillo case HFS_EXTENTS_FILE: 1472 1.1 dillo inout_volume->ehr.node_size = hr.node_size; 1473 1.1 dillo inout_volume->extkeysizefieldsize = 1474 1.2 dillo (hr.attributes & HFS_BIG_KEYS_MASK) ? 1475 1.1 dillo sizeof(uint16_t):sizeof(uint8_t); 1476 1.1 dillo break; 1477 1.1 dillo 1478 1.2 dillo case HFS_ATTRIBUTES_FILE: 1479 1.1 dillo default: 1480 1.2 dillo HFS_LIBERR("invalid parent file type specified"); 1481 1.1 dillo /* NOTREACHED */ 1482 1.1 dillo } 1483 1.1 dillo } 1484 1.1 dillo 1485 1.1 dillo switch(in_parent_file) 1486 1.1 dillo { 1487 1.2 dillo case HFS_CATALOG_FILE: 1488 1.1 dillo nodesize = inout_volume->chr.node_size; 1489 1.1 dillo keysizefieldsize = inout_volume->catkeysizefieldsize; 1490 1.1 dillo break; 1491 1.1 dillo 1492 1.2 dillo case HFS_EXTENTS_FILE: 1493 1.1 dillo nodesize = inout_volume->ehr.node_size; 1494 1.1 dillo keysizefieldsize = inout_volume->extkeysizefieldsize; 1495 1.1 dillo break; 1496 1.1 dillo 1497 1.2 dillo case HFS_ATTRIBUTES_FILE: 1498 1.1 dillo default: 1499 1.2 dillo HFS_LIBERR("invalid parent file type specified"); 1500 1.1 dillo /* NOTREACHED */ 1501 1.1 dillo } 1502 1.1 dillo 1503 1.1 dillo /* 1504 1.1 dillo * Don't care about records so just exit after getting the node descriptor. 1505 1.1 dillo * Note: This happens after the header node code, and not before it, in 1506 1.1 dillo * case the caller calls this function and ignores the record data just to 1507 1.1 dillo * get at the node descriptor, but then tries to call it again on a non- 1508 1.1 dillo * header node without first setting inout_volume->cat/extnodesize. 1509 1.1 dillo */ 1510 1.1 dillo if(out_record_ptrs_array==NULL) 1511 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1512 1.1 dillo 1513 1.2 dillo rec_offsets = hfslib_malloc(numrecords * sizeof(uint16_t), cbargs); 1514 1.1 dillo *out_record_ptr_sizes_array = 1515 1.2 dillo hfslib_malloc(numrecords * sizeof(uint16_t), cbargs); 1516 1.1 dillo if(rec_offsets==NULL || *out_record_ptr_sizes_array==NULL) 1517 1.2 dillo HFS_LIBERR("could not allocate node record offsets"); 1518 1.1 dillo 1519 1.2 dillo *out_record_ptrs_array = hfslib_malloc(numrecords * sizeof(void*), cbargs); 1520 1.1 dillo if(*out_record_ptrs_array==NULL) 1521 1.2 dillo HFS_LIBERR("could not allocate node records"); 1522 1.1 dillo 1523 1.2 dillo last_bytes_read = hfslib_reada_node_offsets((uint8_t*)in_bytes + nodesize - 1524 1.1 dillo numrecords * sizeof(uint16_t), rec_offsets); 1525 1.1 dillo if(last_bytes_read==0) 1526 1.2 dillo HFS_LIBERR("could not read node record offsets"); 1527 1.1 dillo 1528 1.1 dillo /* The size of the last record (i.e. the first one listed in the offsets) 1529 1.1 dillo * must be determined using the offset to the node's free space. */ 1530 1.1 dillo free_space_offset = be16toh(*(uint16_t*)((uint8_t*)in_bytes + nodesize - 1531 1.1 dillo (numrecords+1) * sizeof(uint16_t))); 1532 1.1 dillo 1533 1.1 dillo (*out_record_ptr_sizes_array)[numrecords-1] = 1534 1.1 dillo free_space_offset - rec_offsets[0]; 1535 1.1 dillo for(i=1;i<numrecords;i++) 1536 1.1 dillo { 1537 1.1 dillo (*out_record_ptr_sizes_array)[numrecords-i-1] = 1538 1.1 dillo rec_offsets[i-1] - rec_offsets[i]; 1539 1.1 dillo } 1540 1.1 dillo 1541 1.1 dillo for(i=0;i<numrecords;i++) 1542 1.1 dillo { 1543 1.1 dillo (*out_record_ptrs_array)[i] = 1544 1.2 dillo hfslib_malloc((*out_record_ptr_sizes_array)[i], cbargs); 1545 1.1 dillo 1546 1.1 dillo if((*out_record_ptrs_array)[i]==NULL) 1547 1.2 dillo HFS_LIBERR("could not allocate node record #%i",i); 1548 1.1 dillo 1549 1.1 dillo /* 1550 1.1 dillo * If this is a keyed node (i.e., a leaf or index node), there are two 1551 1.1 dillo * boundary rules that each record must obey: 1552 1.1 dillo * 1553 1.1 dillo * 1. A pad byte must be placed between the key and data if the 1554 1.1 dillo * size of the key plus the size of the key_len field is odd. 1555 1.1 dillo * 1556 1.1 dillo * 2. A pad byte must be placed after the data if the data size 1557 1.1 dillo * is odd. 1558 1.1 dillo * 1559 1.1 dillo * So in the first case we increment the starting point of the data 1560 1.1 dillo * and correspondingly decrement the record size. In the second case 1561 1.1 dillo * we decrement the record size. 1562 1.1 dillo */ 1563 1.2 dillo if(out_node_descriptor->kind == HFS_LEAFNODE || 1564 1.2 dillo out_node_descriptor->kind == HFS_INDEXNODE) 1565 1.1 dillo { 1566 1.2 dillo hfs_catalog_key_t reckey; 1567 1.1 dillo uint16_t rectype; 1568 1.1 dillo 1569 1.1 dillo rectype = out_node_descriptor->kind; 1570 1.2 dillo last_bytes_read = hfslib_read_catalog_keyed_record(ptr, NULL, 1571 1.1 dillo &rectype, &reckey, inout_volume); 1572 1.1 dillo if(last_bytes_read==0) 1573 1.2 dillo HFS_LIBERR("could not read node record"); 1574 1.1 dillo 1575 1.1 dillo if((reckey.key_len + keysizefieldsize) % 2 == 1) 1576 1.1 dillo { 1577 1.1 dillo ptr = (uint8_t*)ptr + 1; 1578 1.1 dillo (*out_record_ptr_sizes_array)[i]--; 1579 1.1 dillo } 1580 1.1 dillo 1581 1.1 dillo if((*out_record_ptr_sizes_array)[i] % 2 == 1) 1582 1.1 dillo (*out_record_ptr_sizes_array)[i]--; 1583 1.1 dillo } 1584 1.1 dillo 1585 1.1 dillo memcpy((*out_record_ptrs_array)[i], ptr, 1586 1.1 dillo (*out_record_ptr_sizes_array)[i]); 1587 1.1 dillo ptr = (uint8_t*)ptr + (*out_record_ptr_sizes_array)[i]; 1588 1.1 dillo } 1589 1.1 dillo 1590 1.1 dillo goto exit; 1591 1.1 dillo 1592 1.1 dillo error: 1593 1.2 dillo hfslib_free_recs(out_record_ptrs_array, out_record_ptr_sizes_array, 1594 1.1 dillo &numrecords, cbargs); 1595 1.1 dillo 1596 1.1 dillo ptr = in_bytes; 1597 1.1 dillo 1598 1.2 dillo /* warn("error occurred in hfslib_reada_node()"); */ 1599 1.1 dillo 1600 1.1 dillo /* FALLTHROUGH */ 1601 1.1 dillo 1602 1.1 dillo exit: 1603 1.1 dillo if(rec_offsets!=NULL) 1604 1.2 dillo hfslib_free(rec_offsets, cbargs); 1605 1.1 dillo 1606 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1607 1.1 dillo } 1608 1.1 dillo 1609 1.1 dillo /* 1610 1.2 dillo * hfslib_reada_node_offsets() 1611 1.1 dillo * 1612 1.1 dillo * Sets out_offset_array to contain the offsets to each record in the node, 1613 1.1 dillo * in reverse order. Does not read the free space offset. 1614 1.1 dillo */ 1615 1.1 dillo size_t 1616 1.2 dillo hfslib_reada_node_offsets(void* in_bytes, uint16_t* out_offset_array) 1617 1.1 dillo { 1618 1.1 dillo void* ptr; 1619 1.1 dillo 1620 1.1 dillo if(in_bytes==NULL || out_offset_array==NULL) 1621 1.1 dillo return 0; 1622 1.1 dillo 1623 1.1 dillo ptr = in_bytes; 1624 1.1 dillo 1625 1.1 dillo /* 1626 1.1 dillo * The offset for record 0 (which is the very last offset in the node) is 1627 1.1 dillo * always equal to 14, the size of the node descriptor. So, once we hit 1628 1.1 dillo * offset=14, we know this is the last offset. In this way, we don't need 1629 1.1 dillo * to know the number of records beforehand. 1630 1.1 dillo */ 1631 1.1 dillo out_offset_array--; 1632 1.1 dillo do 1633 1.1 dillo { 1634 1.1 dillo out_offset_array++; 1635 1.1 dillo *out_offset_array = be16tohp(&ptr); 1636 1.1 dillo } 1637 1.1 dillo while(*out_offset_array != (uint16_t)14); 1638 1.1 dillo 1639 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1640 1.1 dillo } 1641 1.1 dillo 1642 1.2 dillo /* hfslib_read_header_node() 1643 1.1 dillo * 1644 1.1 dillo * out_header_record and/or out_map_record may be NULL if the caller doesn't 1645 1.1 dillo * care about their contents. 1646 1.1 dillo */ 1647 1.1 dillo size_t 1648 1.2 dillo hfslib_read_header_node(void** in_recs, 1649 1.1 dillo uint16_t* in_rec_sizes, 1650 1.1 dillo uint16_t in_num_recs, 1651 1.2 dillo hfs_header_record_t* out_hr, 1652 1.1 dillo void* out_userdata, 1653 1.1 dillo void* out_map) 1654 1.1 dillo { 1655 1.1 dillo void* ptr; 1656 1.1 dillo int i; 1657 1.11 joerg 1658 1.11 joerg KASSERT(out_hr != NULL); 1659 1.11 joerg 1660 1.1 dillo if(in_recs==NULL || in_rec_sizes==NULL) 1661 1.1 dillo return 0; 1662 1.1 dillo 1663 1.11 joerg ptr = in_recs[0]; 1664 1.11 joerg out_hr->tree_depth = be16tohp(&ptr); 1665 1.11 joerg out_hr->root_node = be32tohp(&ptr); 1666 1.11 joerg out_hr->leaf_recs = be32tohp(&ptr); 1667 1.11 joerg out_hr->first_leaf = be32tohp(&ptr); 1668 1.11 joerg out_hr->last_leaf = be32tohp(&ptr); 1669 1.11 joerg out_hr->node_size = be16tohp(&ptr); 1670 1.11 joerg out_hr->max_key_len = be16tohp(&ptr); 1671 1.11 joerg out_hr->total_nodes = be32tohp(&ptr); 1672 1.11 joerg out_hr->free_nodes = be32tohp(&ptr); 1673 1.11 joerg out_hr->reserved = be16tohp(&ptr); 1674 1.11 joerg out_hr->clump_size = be32tohp(&ptr); 1675 1.11 joerg out_hr->btree_type = *(((uint8_t*)ptr)); 1676 1.11 joerg ptr = (uint8_t*)ptr + 1; 1677 1.11 joerg out_hr->keycomp_type = *(((uint8_t*)ptr)); 1678 1.11 joerg ptr = (uint8_t*)ptr + 1; 1679 1.11 joerg out_hr->attributes = be32tohp(&ptr); 1680 1.11 joerg for(i=0;i<16;i++) 1681 1.11 joerg out_hr->reserved2[i] = be32tohp(&ptr); 1682 1.11 joerg 1683 1.1 dillo if(out_userdata!=NULL) 1684 1.1 dillo { 1685 1.1 dillo memcpy(out_userdata, in_recs[1], in_rec_sizes[1]); 1686 1.1 dillo } 1687 1.1 dillo ptr = (uint8_t*)ptr + in_rec_sizes[1]; /* size of user data record */ 1688 1.1 dillo 1689 1.1 dillo if(out_map!=NULL) 1690 1.1 dillo { 1691 1.1 dillo memcpy(out_map, in_recs[2], in_rec_sizes[2]); 1692 1.1 dillo } 1693 1.1 dillo ptr = (uint8_t*)ptr + in_rec_sizes[2]; /* size of map record */ 1694 1.1 dillo 1695 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_recs[0]); 1696 1.1 dillo } 1697 1.1 dillo 1698 1.1 dillo /* 1699 1.2 dillo * hfslib_read_catalog_keyed_record() 1700 1.1 dillo * 1701 1.2 dillo * out_recdata can be NULL. inout_rectype must be set to either HFS_LEAFNODE 1702 1.2 dillo * or HFS_INDEXNODE upon calling this function, and will be set by the 1703 1.2 dillo * function to one of HFS_REC_FLDR, HFS_REC_FILE, HFS_REC_FLDR_THREAD, or 1704 1.2 dillo * HFS_REC_FLDR_THREAD upon return if the node is a leaf node. If it is an 1705 1.1 dillo * index node, inout_rectype will not be changed. 1706 1.1 dillo */ 1707 1.1 dillo size_t 1708 1.2 dillo hfslib_read_catalog_keyed_record( 1709 1.1 dillo void* in_bytes, 1710 1.2 dillo hfs_catalog_keyed_record_t* out_recdata, 1711 1.1 dillo int16_t* inout_rectype, 1712 1.2 dillo hfs_catalog_key_t* out_key, 1713 1.2 dillo hfs_volume* in_volume) 1714 1.1 dillo { 1715 1.1 dillo void* ptr; 1716 1.1 dillo size_t last_bytes_read; 1717 1.1 dillo 1718 1.1 dillo if(in_bytes==NULL || out_key==NULL || inout_rectype==NULL) 1719 1.1 dillo return 0; 1720 1.1 dillo 1721 1.1 dillo ptr = in_bytes; 1722 1.1 dillo 1723 1.1 dillo /* For HFS+, the key length is always a 2-byte number. This is indicated 1724 1.2 dillo * by the HFS_BIG_KEYS_MASK bit in the attributes field of the catalog 1725 1.1 dillo * header record. However, we just assume this bit is set, since all HFS+ 1726 1.1 dillo * volumes should have it set anyway. */ 1727 1.1 dillo if(in_volume->catkeysizefieldsize == sizeof(uint16_t)) 1728 1.1 dillo out_key->key_len = be16tohp(&ptr); 1729 1.1 dillo else if (in_volume->catkeysizefieldsize == sizeof(uint8_t)) { 1730 1.1 dillo out_key->key_len = *(((uint8_t*)ptr)); 1731 1.1 dillo ptr = (uint8_t*)ptr + 1; 1732 1.1 dillo } 1733 1.1 dillo 1734 1.1 dillo out_key->parent_cnid = be32tohp(&ptr); 1735 1.1 dillo 1736 1.2 dillo last_bytes_read = hfslib_read_unistr255(ptr, &out_key->name); 1737 1.1 dillo if(last_bytes_read==0) 1738 1.1 dillo return 0; 1739 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1740 1.1 dillo 1741 1.1 dillo /* don't waste time if the user just wanted the key and/or record type */ 1742 1.1 dillo if(out_recdata==NULL) 1743 1.1 dillo { 1744 1.2 dillo if(*inout_rectype == HFS_LEAFNODE) 1745 1.1 dillo *inout_rectype = be16tohp(&ptr); 1746 1.2 dillo else if(*inout_rectype != HFS_INDEXNODE) 1747 1.1 dillo return 0; /* should not happen if we were given valid arguments */ 1748 1.1 dillo 1749 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1750 1.1 dillo } 1751 1.1 dillo 1752 1.2 dillo if(*inout_rectype == HFS_INDEXNODE) 1753 1.1 dillo { 1754 1.1 dillo out_recdata->child = be32tohp(&ptr); 1755 1.1 dillo } 1756 1.1 dillo else 1757 1.1 dillo { 1758 1.1 dillo /* first need to determine what kind of record this is */ 1759 1.1 dillo *inout_rectype = be16tohp(&ptr); 1760 1.1 dillo out_recdata->type = *inout_rectype; 1761 1.1 dillo 1762 1.1 dillo switch(out_recdata->type) 1763 1.1 dillo { 1764 1.2 dillo case HFS_REC_FLDR: 1765 1.1 dillo { 1766 1.1 dillo out_recdata->folder.flags = be16tohp(&ptr); 1767 1.1 dillo out_recdata->folder.valence = be32tohp(&ptr); 1768 1.1 dillo out_recdata->folder.cnid = be32tohp(&ptr); 1769 1.1 dillo out_recdata->folder.date_created = be32tohp(&ptr); 1770 1.1 dillo out_recdata->folder.date_content_mod = be32tohp(&ptr); 1771 1.1 dillo out_recdata->folder.date_attrib_mod = be32tohp(&ptr); 1772 1.1 dillo out_recdata->folder.date_accessed = be32tohp(&ptr); 1773 1.1 dillo out_recdata->folder.date_backedup = be32tohp(&ptr); 1774 1.1 dillo 1775 1.2 dillo last_bytes_read = hfslib_read_bsd_data(ptr, 1776 1.1 dillo &out_recdata->folder.bsd); 1777 1.1 dillo if(last_bytes_read==0) 1778 1.1 dillo return 0; 1779 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1780 1.1 dillo 1781 1.2 dillo last_bytes_read = hfslib_read_folder_userinfo(ptr, 1782 1.1 dillo &out_recdata->folder.user_info); 1783 1.1 dillo if(last_bytes_read==0) 1784 1.1 dillo return 0; 1785 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1786 1.1 dillo 1787 1.2 dillo last_bytes_read = hfslib_read_folder_finderinfo(ptr, 1788 1.1 dillo &out_recdata->folder.finder_info); 1789 1.1 dillo if(last_bytes_read==0) 1790 1.1 dillo return 0; 1791 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1792 1.1 dillo 1793 1.1 dillo out_recdata->folder.text_encoding = be32tohp(&ptr); 1794 1.1 dillo out_recdata->folder.reserved = be32tohp(&ptr); 1795 1.1 dillo } 1796 1.1 dillo break; 1797 1.1 dillo 1798 1.2 dillo case HFS_REC_FILE: 1799 1.1 dillo { 1800 1.1 dillo out_recdata->file.flags = be16tohp(&ptr); 1801 1.1 dillo out_recdata->file.reserved = be32tohp(&ptr); 1802 1.1 dillo out_recdata->file.cnid = be32tohp(&ptr); 1803 1.1 dillo out_recdata->file.date_created = be32tohp(&ptr); 1804 1.1 dillo out_recdata->file.date_content_mod = be32tohp(&ptr); 1805 1.1 dillo out_recdata->file.date_attrib_mod = be32tohp(&ptr); 1806 1.1 dillo out_recdata->file.date_accessed = be32tohp(&ptr); 1807 1.1 dillo out_recdata->file.date_backedup = be32tohp(&ptr); 1808 1.1 dillo 1809 1.2 dillo last_bytes_read = hfslib_read_bsd_data(ptr, 1810 1.1 dillo &out_recdata->file.bsd); 1811 1.1 dillo if(last_bytes_read==0) 1812 1.1 dillo return 0; 1813 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1814 1.1 dillo 1815 1.2 dillo last_bytes_read = hfslib_read_file_userinfo(ptr, 1816 1.1 dillo &out_recdata->file.user_info); 1817 1.1 dillo if(last_bytes_read==0) 1818 1.1 dillo return 0; 1819 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1820 1.1 dillo 1821 1.2 dillo last_bytes_read = hfslib_read_file_finderinfo(ptr, 1822 1.1 dillo &out_recdata->file.finder_info); 1823 1.1 dillo if(last_bytes_read==0) 1824 1.1 dillo return 0; 1825 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1826 1.1 dillo 1827 1.1 dillo out_recdata->file.text_encoding = be32tohp(&ptr); 1828 1.1 dillo out_recdata->file.reserved2 = be32tohp(&ptr); 1829 1.1 dillo 1830 1.2 dillo last_bytes_read = hfslib_read_fork_descriptor(ptr, 1831 1.1 dillo &out_recdata->file.data_fork); 1832 1.1 dillo if(last_bytes_read==0) 1833 1.1 dillo return 0; 1834 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1835 1.1 dillo 1836 1.2 dillo last_bytes_read = hfslib_read_fork_descriptor(ptr, 1837 1.1 dillo &out_recdata->file.rsrc_fork); 1838 1.1 dillo if(last_bytes_read==0) 1839 1.1 dillo return 0; 1840 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1841 1.1 dillo } 1842 1.1 dillo break; 1843 1.1 dillo 1844 1.2 dillo case HFS_REC_FLDR_THREAD: 1845 1.2 dillo case HFS_REC_FILE_THREAD: 1846 1.1 dillo { 1847 1.1 dillo out_recdata->thread.reserved = be16tohp(&ptr); 1848 1.1 dillo out_recdata->thread.parent_cnid = be32tohp(&ptr); 1849 1.1 dillo 1850 1.2 dillo last_bytes_read = hfslib_read_unistr255(ptr, 1851 1.1 dillo &out_recdata->thread.name); 1852 1.1 dillo if(last_bytes_read==0) 1853 1.1 dillo return 0; 1854 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1855 1.1 dillo } 1856 1.1 dillo break; 1857 1.1 dillo 1858 1.1 dillo default: 1859 1.1 dillo return 1; 1860 1.1 dillo /* NOTREACHED */ 1861 1.1 dillo } 1862 1.1 dillo } 1863 1.1 dillo 1864 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1865 1.1 dillo } 1866 1.1 dillo 1867 1.1 dillo /* out_rec may be NULL */ 1868 1.1 dillo size_t 1869 1.2 dillo hfslib_read_extent_record( 1870 1.1 dillo void* in_bytes, 1871 1.2 dillo hfs_extent_record_t* out_rec, 1872 1.2 dillo hfs_node_kind in_nodekind, 1873 1.2 dillo hfs_extent_key_t* out_key, 1874 1.2 dillo hfs_volume* in_volume) 1875 1.1 dillo { 1876 1.1 dillo void* ptr; 1877 1.1 dillo size_t last_bytes_read; 1878 1.1 dillo 1879 1.1 dillo if(in_bytes==NULL || out_key==NULL 1880 1.2 dillo || (in_nodekind!=HFS_LEAFNODE && in_nodekind!=HFS_INDEXNODE)) 1881 1.1 dillo return 0; 1882 1.1 dillo 1883 1.1 dillo ptr = in_bytes; 1884 1.1 dillo 1885 1.1 dillo /* For HFS+, the key length is always a 2-byte number. This is indicated 1886 1.2 dillo * by the HFS_BIG_KEYS_MASK bit in the attributes field of the extent 1887 1.1 dillo * overflow header record. However, we just assume this bit is set, since 1888 1.1 dillo * all HFS+ volumes should have it set anyway. */ 1889 1.1 dillo if(in_volume->extkeysizefieldsize == sizeof(uint16_t)) 1890 1.1 dillo out_key->key_length = be16tohp(&ptr); 1891 1.1 dillo else if (in_volume->extkeysizefieldsize == sizeof(uint8_t)) { 1892 1.1 dillo out_key->key_length = *(((uint8_t*)ptr)); 1893 1.1 dillo ptr = (uint8_t*)ptr + 1; 1894 1.1 dillo } 1895 1.1 dillo 1896 1.1 dillo out_key->fork_type = *(((uint8_t*)ptr)); 1897 1.1 dillo ptr = (uint8_t*)ptr + 1; 1898 1.1 dillo out_key->padding = *(((uint8_t*)ptr)); 1899 1.1 dillo ptr = (uint8_t*)ptr + 1; 1900 1.1 dillo out_key->file_cnid = be32tohp(&ptr); 1901 1.1 dillo out_key->start_block = be32tohp(&ptr); 1902 1.1 dillo 1903 1.1 dillo /* don't waste time if the user just wanted the key */ 1904 1.1 dillo if(out_rec==NULL) 1905 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1906 1.1 dillo 1907 1.2 dillo if(in_nodekind==HFS_LEAFNODE) 1908 1.1 dillo { 1909 1.2 dillo last_bytes_read = hfslib_read_extent_descriptors(ptr, out_rec); 1910 1.1 dillo if(last_bytes_read==0) 1911 1.1 dillo return 0; 1912 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1913 1.1 dillo } 1914 1.1 dillo else 1915 1.1 dillo { 1916 1.1 dillo /* XXX: this is completely bogus */ 1917 1.1 dillo /* (uint32_t*)*out_rec = be32tohp(&ptr); */ 1918 1.1 dillo uint32_t *ptr_32 = (uint32_t *)out_rec; 1919 1.1 dillo *ptr_32 = be32tohp(&ptr); 1920 1.1 dillo /* (*out_rec)[0].start_block = be32tohp(&ptr); */ 1921 1.1 dillo } 1922 1.1 dillo 1923 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1924 1.1 dillo } 1925 1.1 dillo 1926 1.1 dillo void 1927 1.2 dillo hfslib_free_recs( 1928 1.1 dillo void*** inout_node_recs, 1929 1.1 dillo uint16_t** inout_rec_sizes, 1930 1.1 dillo uint16_t* inout_num_recs, 1931 1.2 dillo hfs_callback_args* cbargs) 1932 1.1 dillo { 1933 1.1 dillo uint16_t i; 1934 1.1 dillo 1935 1.1 dillo if(inout_num_recs==NULL || *inout_num_recs==0) 1936 1.1 dillo return; 1937 1.1 dillo 1938 1.1 dillo if(inout_node_recs!=NULL && *inout_node_recs!=NULL) 1939 1.1 dillo { 1940 1.1 dillo for(i=0;i<*inout_num_recs;i++) 1941 1.1 dillo { 1942 1.1 dillo if((*inout_node_recs)[i]!=NULL) 1943 1.1 dillo { 1944 1.2 dillo hfslib_free((*inout_node_recs)[i], cbargs); 1945 1.1 dillo (*inout_node_recs)[i] = NULL; 1946 1.1 dillo } 1947 1.1 dillo } 1948 1.1 dillo 1949 1.2 dillo hfslib_free(*inout_node_recs, cbargs); 1950 1.1 dillo *inout_node_recs = NULL; 1951 1.1 dillo } 1952 1.1 dillo 1953 1.1 dillo if(inout_rec_sizes!=NULL && *inout_rec_sizes!=NULL) 1954 1.1 dillo { 1955 1.2 dillo hfslib_free(*inout_rec_sizes, cbargs); 1956 1.1 dillo *inout_rec_sizes = NULL; 1957 1.1 dillo } 1958 1.1 dillo 1959 1.1 dillo *inout_num_recs = 0; 1960 1.1 dillo } 1961 1.1 dillo 1962 1.1 dillo #if 0 1963 1.1 dillo #pragma mark - 1964 1.1 dillo #pragma mark Individual Fields 1965 1.1 dillo #endif 1966 1.1 dillo 1967 1.1 dillo size_t 1968 1.2 dillo hfslib_read_fork_descriptor(void* in_bytes, hfs_fork_t* out_forkdata) 1969 1.1 dillo { 1970 1.1 dillo void* ptr; 1971 1.1 dillo size_t last_bytes_read; 1972 1.1 dillo 1973 1.1 dillo if(in_bytes==NULL || out_forkdata==NULL) 1974 1.1 dillo return 0; 1975 1.1 dillo 1976 1.1 dillo ptr = in_bytes; 1977 1.1 dillo 1978 1.1 dillo out_forkdata->logical_size = be64tohp(&ptr); 1979 1.1 dillo out_forkdata->clump_size = be32tohp(&ptr); 1980 1.1 dillo out_forkdata->total_blocks = be32tohp(&ptr); 1981 1.1 dillo 1982 1.2 dillo if((last_bytes_read = hfslib_read_extent_descriptors(ptr, 1983 1.1 dillo &out_forkdata->extents))==0) 1984 1.1 dillo return 0; 1985 1.1 dillo ptr = (uint8_t*)ptr + last_bytes_read; 1986 1.1 dillo 1987 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 1988 1.1 dillo } 1989 1.1 dillo 1990 1.1 dillo size_t 1991 1.2 dillo hfslib_read_extent_descriptors( 1992 1.1 dillo void* in_bytes, 1993 1.2 dillo hfs_extent_record_t* out_extentrecord) 1994 1.1 dillo { 1995 1.1 dillo void* ptr; 1996 1.1 dillo int i; 1997 1.1 dillo 1998 1.1 dillo if(in_bytes==NULL || out_extentrecord==NULL) 1999 1.1 dillo return 0; 2000 1.1 dillo 2001 1.1 dillo ptr = in_bytes; 2002 1.1 dillo 2003 1.1 dillo for(i=0;i<8;i++) 2004 1.1 dillo { 2005 1.2 dillo (((hfs_extent_descriptor_t*)*out_extentrecord)[i]).start_block = 2006 1.1 dillo be32tohp(&ptr); 2007 1.2 dillo (((hfs_extent_descriptor_t*)*out_extentrecord)[i]).block_count = 2008 1.1 dillo be32tohp(&ptr); 2009 1.1 dillo } 2010 1.1 dillo 2011 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2012 1.1 dillo } 2013 1.1 dillo 2014 1.1 dillo size_t 2015 1.2 dillo hfslib_read_unistr255(void* in_bytes, hfs_unistr255_t* out_string) 2016 1.1 dillo { 2017 1.1 dillo void* ptr; 2018 1.1 dillo uint16_t i, length; 2019 1.1 dillo 2020 1.1 dillo if(in_bytes==NULL || out_string==NULL) 2021 1.1 dillo return 0; 2022 1.1 dillo 2023 1.1 dillo ptr = in_bytes; 2024 1.1 dillo 2025 1.1 dillo length = be16tohp(&ptr); 2026 1.1 dillo if(length>255) 2027 1.1 dillo length = 255; /* hfs+ folder/file names have a limit of 255 chars */ 2028 1.1 dillo out_string->length = length; 2029 1.1 dillo 2030 1.1 dillo for(i=0; i<length; i++) 2031 1.1 dillo { 2032 1.1 dillo out_string->unicode[i] = be16tohp(&ptr); 2033 1.1 dillo } 2034 1.1 dillo 2035 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2036 1.1 dillo } 2037 1.1 dillo 2038 1.1 dillo size_t 2039 1.2 dillo hfslib_read_bsd_data(void* in_bytes, hfs_bsd_data_t* out_perms) 2040 1.1 dillo { 2041 1.1 dillo void* ptr; 2042 1.1 dillo 2043 1.1 dillo if(in_bytes==NULL || out_perms==NULL) 2044 1.1 dillo return 0; 2045 1.1 dillo 2046 1.1 dillo ptr = in_bytes; 2047 1.1 dillo 2048 1.1 dillo out_perms->owner_id = be32tohp(&ptr); 2049 1.1 dillo out_perms->group_id = be32tohp(&ptr); 2050 1.1 dillo out_perms->admin_flags = *(((uint8_t*)ptr)); 2051 1.1 dillo ptr = (uint8_t*)ptr + 1; 2052 1.1 dillo out_perms->owner_flags = *(((uint8_t*)ptr)); 2053 1.1 dillo ptr = (uint8_t*)ptr + 1; 2054 1.1 dillo out_perms->file_mode = be16tohp(&ptr); 2055 1.1 dillo out_perms->special.inode_num = be32tohp(&ptr); /* this field is a union */ 2056 1.1 dillo 2057 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2058 1.1 dillo } 2059 1.1 dillo 2060 1.1 dillo size_t 2061 1.2 dillo hfslib_read_file_userinfo(void* in_bytes, hfs_macos_file_info_t* out_info) 2062 1.1 dillo { 2063 1.1 dillo void* ptr; 2064 1.1 dillo 2065 1.1 dillo if(in_bytes==NULL || out_info==NULL) 2066 1.1 dillo return 0; 2067 1.1 dillo 2068 1.1 dillo ptr = in_bytes; 2069 1.1 dillo 2070 1.1 dillo out_info->file_type = be32tohp(&ptr); 2071 1.1 dillo out_info->file_creator = be32tohp(&ptr); 2072 1.1 dillo out_info->finder_flags = be16tohp(&ptr); 2073 1.1 dillo out_info->location.v = be16tohp(&ptr); 2074 1.1 dillo out_info->location.h = be16tohp(&ptr); 2075 1.1 dillo out_info->reserved = be16tohp(&ptr); 2076 1.1 dillo 2077 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2078 1.1 dillo } 2079 1.1 dillo 2080 1.1 dillo size_t 2081 1.2 dillo hfslib_read_file_finderinfo( 2082 1.1 dillo void* in_bytes, 2083 1.2 dillo hfs_macos_extended_file_info_t* out_info) 2084 1.1 dillo { 2085 1.1 dillo void* ptr; 2086 1.1 dillo 2087 1.1 dillo if(in_bytes==NULL || out_info==NULL) 2088 1.1 dillo return 0; 2089 1.1 dillo 2090 1.1 dillo ptr = in_bytes; 2091 1.1 dillo 2092 1.1 dillo #if 0 2093 1.1 dillo #pragma warn Fill in with real code! 2094 1.1 dillo #endif 2095 1.1 dillo /* FIXME: Fill in with real code! */ 2096 1.1 dillo memset(out_info, 0, sizeof(*out_info)); 2097 1.2 dillo ptr = (uint8_t*)ptr + sizeof(hfs_macos_extended_file_info_t); 2098 1.1 dillo 2099 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2100 1.1 dillo } 2101 1.1 dillo 2102 1.1 dillo size_t 2103 1.2 dillo hfslib_read_folder_userinfo(void* in_bytes, hfs_macos_folder_info_t* out_info) 2104 1.1 dillo { 2105 1.1 dillo void* ptr; 2106 1.1 dillo 2107 1.1 dillo if(in_bytes==NULL || out_info==NULL) 2108 1.1 dillo return 0; 2109 1.1 dillo 2110 1.1 dillo ptr = in_bytes; 2111 1.1 dillo 2112 1.1 dillo #if 0 2113 1.1 dillo #pragma warn Fill in with real code! 2114 1.1 dillo #endif 2115 1.1 dillo /* FIXME: Fill in with real code! */ 2116 1.1 dillo memset(out_info, 0, sizeof(*out_info)); 2117 1.2 dillo ptr = (uint8_t*)ptr + sizeof(hfs_macos_folder_info_t); 2118 1.1 dillo 2119 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2120 1.1 dillo } 2121 1.1 dillo 2122 1.1 dillo size_t 2123 1.2 dillo hfslib_read_folder_finderinfo( 2124 1.1 dillo void* in_bytes, 2125 1.2 dillo hfs_macos_extended_folder_info_t* out_info) 2126 1.1 dillo { 2127 1.1 dillo void* ptr; 2128 1.1 dillo 2129 1.1 dillo if(in_bytes==NULL || out_info==NULL) 2130 1.1 dillo return 0; 2131 1.1 dillo 2132 1.1 dillo ptr = in_bytes; 2133 1.1 dillo 2134 1.1 dillo #if 0 2135 1.1 dillo #pragma warn Fill in with real code! 2136 1.1 dillo #endif 2137 1.1 dillo /* FIXME: Fill in with real code! */ 2138 1.1 dillo memset(out_info, 0, sizeof(*out_info)); 2139 1.2 dillo ptr = (uint8_t*)ptr + sizeof(hfs_macos_extended_folder_info_t); 2140 1.1 dillo 2141 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2142 1.1 dillo } 2143 1.1 dillo 2144 1.1 dillo size_t 2145 1.2 dillo hfslib_read_journal_info(void* in_bytes, hfs_journal_info_t* out_info) 2146 1.1 dillo { 2147 1.1 dillo void* ptr; 2148 1.1 dillo int i; 2149 1.1 dillo 2150 1.1 dillo if(in_bytes==NULL || out_info==NULL) 2151 1.1 dillo return 0; 2152 1.1 dillo 2153 1.1 dillo ptr = in_bytes; 2154 1.1 dillo 2155 1.1 dillo out_info->flags = be32tohp(&ptr); 2156 1.1 dillo for(i=0; i<8; i++) 2157 1.1 dillo { 2158 1.1 dillo out_info->device_signature[i] = be32tohp(&ptr); 2159 1.1 dillo } 2160 1.1 dillo out_info->offset = be64tohp(&ptr); 2161 1.1 dillo out_info->size = be64tohp(&ptr); 2162 1.1 dillo for(i=0; i<32; i++) 2163 1.1 dillo { 2164 1.1 dillo out_info->reserved[i] = be64tohp(&ptr); 2165 1.1 dillo } 2166 1.1 dillo 2167 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2168 1.1 dillo } 2169 1.1 dillo 2170 1.1 dillo size_t 2171 1.2 dillo hfslib_read_journal_header(void* in_bytes, hfs_journal_header_t* out_header) 2172 1.1 dillo { 2173 1.1 dillo void* ptr; 2174 1.1 dillo 2175 1.1 dillo if(in_bytes==NULL || out_header==NULL) 2176 1.1 dillo return 0; 2177 1.1 dillo 2178 1.1 dillo ptr = in_bytes; 2179 1.1 dillo 2180 1.1 dillo out_header->magic = be32tohp(&ptr); 2181 1.1 dillo out_header->endian = be32tohp(&ptr); 2182 1.1 dillo out_header->start = be64tohp(&ptr); 2183 1.1 dillo out_header->end = be64tohp(&ptr); 2184 1.1 dillo out_header->size = be64tohp(&ptr); 2185 1.1 dillo out_header->blocklist_header_size = be32tohp(&ptr); 2186 1.1 dillo out_header->checksum = be32tohp(&ptr); 2187 1.1 dillo out_header->journal_header_size = be32tohp(&ptr); 2188 1.1 dillo 2189 1.1 dillo return ((uint8_t*)ptr - (uint8_t*)in_bytes); 2190 1.1 dillo } 2191 1.1 dillo 2192 1.1 dillo #if 0 2193 1.1 dillo #pragma mark - 2194 1.1 dillo #pragma mark Disk Access 2195 1.1 dillo #endif 2196 1.1 dillo 2197 1.1 dillo /* 2198 1.2 dillo * hfslib_readd_with_extents() 2199 1.1 dillo * 2200 1.1 dillo * This function reads the contents of a file from the volume, given an array 2201 1.1 dillo * of extent descriptors which specify where every extent of the file is 2202 1.1 dillo * located (in addition to the usual pread() arguments). out_bytes is presumed 2203 1.1 dillo * to exist and be large enough to hold in_length number of bytes. Returns 0 2204 1.1 dillo * on success. 2205 1.1 dillo */ 2206 1.1 dillo int 2207 1.2 dillo hfslib_readd_with_extents( 2208 1.2 dillo hfs_volume* in_vol, 2209 1.1 dillo void* out_bytes, 2210 1.1 dillo uint64_t* out_bytesread, 2211 1.1 dillo uint64_t in_length, 2212 1.1 dillo uint64_t in_offset, 2213 1.2 dillo hfs_extent_descriptor_t in_extents[], 2214 1.1 dillo uint16_t in_numextents, 2215 1.2 dillo hfs_callback_args* cbargs) 2216 1.1 dillo { 2217 1.1 dillo uint64_t ext_length, last_offset; 2218 1.1 dillo uint16_t i; 2219 1.1 dillo int error; 2220 1.1 dillo 2221 1.1 dillo if(in_vol==NULL || out_bytes==NULL || in_extents==NULL || in_numextents==0 2222 1.1 dillo || out_bytesread==NULL) 2223 1.1 dillo return -1; 2224 1.1 dillo 2225 1.1 dillo *out_bytesread = 0; 2226 1.1 dillo last_offset = 0; 2227 1.1 dillo 2228 1.1 dillo for(i=0; i<in_numextents; i++) 2229 1.1 dillo { 2230 1.1 dillo if(in_extents[i].block_count==0) 2231 1.1 dillo continue; 2232 1.1 dillo 2233 1.1 dillo ext_length = in_extents[i].block_count * in_vol->vh.block_size; 2234 1.1 dillo 2235 1.1 dillo if(in_offset < last_offset+ext_length 2236 1.1 dillo && in_offset+in_length >= last_offset) 2237 1.1 dillo { 2238 1.1 dillo uint64_t isect_start, isect_end; 2239 1.1 dillo 2240 1.1 dillo isect_start = max(in_offset, last_offset); 2241 1.1 dillo isect_end = min(in_offset+in_length, last_offset+ext_length); 2242 1.2 dillo error = hfslib_readd(in_vol, out_bytes, isect_end-isect_start, 2243 1.1 dillo isect_start - last_offset + (uint64_t)in_extents[i].start_block 2244 1.1 dillo * in_vol->vh.block_size, cbargs); 2245 1.1 dillo 2246 1.1 dillo if(error!=0) 2247 1.1 dillo return error; 2248 1.1 dillo 2249 1.1 dillo *out_bytesread += isect_end-isect_start; 2250 1.1 dillo out_bytes = (uint8_t*)out_bytes + isect_end-isect_start; 2251 1.1 dillo } 2252 1.1 dillo 2253 1.1 dillo last_offset += ext_length; 2254 1.1 dillo } 2255 1.1 dillo 2256 1.1 dillo 2257 1.1 dillo return 0; 2258 1.1 dillo } 2259 1.1 dillo 2260 1.1 dillo #if 0 2261 1.1 dillo #pragma mark - 2262 1.1 dillo #pragma mark Callback Wrappers 2263 1.1 dillo #endif 2264 1.1 dillo 2265 1.1 dillo void 2266 1.2 dillo hfslib_error(const char* in_format, const char* in_file, int in_line, ...) 2267 1.1 dillo { 2268 1.1 dillo va_list ap; 2269 1.1 dillo 2270 1.1 dillo if(in_format==NULL) 2271 1.1 dillo return; 2272 1.1 dillo 2273 1.2 dillo if(hfs_gcb.error!=NULL) 2274 1.1 dillo { 2275 1.1 dillo va_start(ap, in_line); 2276 1.1 dillo 2277 1.2 dillo hfs_gcb.error(in_format, in_file, in_line, ap); 2278 1.1 dillo 2279 1.1 dillo va_end(ap); 2280 1.1 dillo } 2281 1.1 dillo } 2282 1.1 dillo 2283 1.1 dillo void* 2284 1.2 dillo hfslib_malloc(size_t size, hfs_callback_args* cbargs) 2285 1.1 dillo { 2286 1.2 dillo if(hfs_gcb.allocmem!=NULL) 2287 1.2 dillo return hfs_gcb.allocmem(size, cbargs); 2288 1.1 dillo 2289 1.1 dillo return NULL; 2290 1.1 dillo } 2291 1.1 dillo 2292 1.1 dillo void* 2293 1.2 dillo hfslib_realloc(void* ptr, size_t size, hfs_callback_args* cbargs) 2294 1.1 dillo { 2295 1.2 dillo if(hfs_gcb.reallocmem!=NULL) 2296 1.2 dillo return hfs_gcb.reallocmem(ptr, size, cbargs); 2297 1.1 dillo 2298 1.1 dillo return NULL; 2299 1.1 dillo } 2300 1.1 dillo 2301 1.1 dillo void 2302 1.2 dillo hfslib_free(void* ptr, hfs_callback_args* cbargs) 2303 1.1 dillo { 2304 1.2 dillo if(hfs_gcb.freemem!=NULL && ptr!=NULL) 2305 1.2 dillo hfs_gcb.freemem(ptr, cbargs); 2306 1.1 dillo } 2307 1.1 dillo 2308 1.1 dillo int 2309 1.2 dillo hfslib_openvoldevice( 2310 1.2 dillo hfs_volume* in_vol, 2311 1.1 dillo const char* in_device, 2312 1.2 dillo hfs_callback_args* cbargs) 2313 1.1 dillo { 2314 1.2 dillo if(hfs_gcb.openvol!=NULL && in_device!=NULL) 2315 1.4 dillo return hfs_gcb.openvol(in_vol, in_device, cbargs); 2316 1.1 dillo 2317 1.1 dillo return 1; 2318 1.1 dillo } 2319 1.1 dillo 2320 1.1 dillo void 2321 1.2 dillo hfslib_closevoldevice(hfs_volume* in_vol, hfs_callback_args* cbargs) 2322 1.1 dillo { 2323 1.2 dillo if(hfs_gcb.closevol!=NULL) 2324 1.2 dillo hfs_gcb.closevol(in_vol, cbargs); 2325 1.1 dillo } 2326 1.1 dillo 2327 1.1 dillo int 2328 1.2 dillo hfslib_readd( 2329 1.2 dillo hfs_volume* in_vol, 2330 1.1 dillo void* out_bytes, 2331 1.1 dillo uint64_t in_length, 2332 1.1 dillo uint64_t in_offset, 2333 1.2 dillo hfs_callback_args* cbargs) 2334 1.1 dillo { 2335 1.1 dillo if(in_vol==NULL || out_bytes==NULL) 2336 1.1 dillo return -1; 2337 1.1 dillo 2338 1.2 dillo if(hfs_gcb.read!=NULL) 2339 1.2 dillo return hfs_gcb.read(in_vol, out_bytes, in_length, in_offset, cbargs); 2340 1.1 dillo 2341 1.1 dillo return -1; 2342 1.1 dillo } 2343 1.1 dillo 2344 1.1 dillo #if 0 2345 1.1 dillo #pragma mark - 2346 1.1 dillo #pragma mark Other 2347 1.1 dillo #endif 2348 1.1 dillo 2349 1.1 dillo /* returns key length */ 2350 1.1 dillo uint16_t 2351 1.2 dillo hfslib_make_catalog_key( 2352 1.2 dillo hfs_cnid_t in_parent_cnid, 2353 1.1 dillo uint16_t in_name_len, 2354 1.1 dillo unichar_t* in_unicode, 2355 1.2 dillo hfs_catalog_key_t* out_key) 2356 1.1 dillo { 2357 1.1 dillo if(in_parent_cnid==0 || (in_name_len>0 && in_unicode==NULL) || out_key==0) 2358 1.1 dillo return 0; 2359 1.1 dillo 2360 1.1 dillo if(in_name_len>255) 2361 1.1 dillo in_name_len = 255; 2362 1.1 dillo 2363 1.1 dillo out_key->key_len = 6 + 2 * in_name_len; 2364 1.1 dillo out_key->parent_cnid = in_parent_cnid; 2365 1.1 dillo out_key->name.length = in_name_len; 2366 1.1 dillo if(in_name_len>0) 2367 1.1 dillo memcpy(&out_key->name.unicode, in_unicode, in_name_len*2); 2368 1.1 dillo 2369 1.1 dillo return out_key->key_len; 2370 1.1 dillo } 2371 1.1 dillo 2372 1.1 dillo /* returns key length */ 2373 1.1 dillo uint16_t 2374 1.2 dillo hfslib_make_extent_key( 2375 1.2 dillo hfs_cnid_t in_cnid, 2376 1.1 dillo uint8_t in_forktype, 2377 1.1 dillo uint32_t in_startblock, 2378 1.2 dillo hfs_extent_key_t* out_key) 2379 1.1 dillo { 2380 1.1 dillo if(in_cnid==0 || out_key==0) 2381 1.1 dillo return 0; 2382 1.1 dillo 2383 1.2 dillo out_key->key_length = HFS_MAX_EXT_KEY_LEN; 2384 1.1 dillo out_key->fork_type = in_forktype; 2385 1.1 dillo out_key->padding = 0; 2386 1.1 dillo out_key->file_cnid = in_cnid; 2387 1.1 dillo out_key->start_block = in_startblock; 2388 1.1 dillo 2389 1.1 dillo return out_key->key_length; 2390 1.1 dillo } 2391 1.1 dillo 2392 1.1 dillo /* case-folding */ 2393 1.1 dillo int 2394 1.2 dillo hfslib_compare_catalog_keys_cf ( 2395 1.1 dillo const void *ap, 2396 1.1 dillo const void *bp) 2397 1.1 dillo { 2398 1.2 dillo const hfs_catalog_key_t *a, *b; 2399 1.1 dillo unichar_t ac, bc; /* current character from a, b */ 2400 1.1 dillo unichar_t lc; /* lowercase version of current character */ 2401 1.1 dillo uint8_t apos, bpos; /* current character indices */ 2402 1.1 dillo 2403 1.2 dillo a = (const hfs_catalog_key_t*)ap; 2404 1.2 dillo b = (const hfs_catalog_key_t*)bp; 2405 1.1 dillo 2406 1.1 dillo if(a->parent_cnid != b->parent_cnid) 2407 1.1 dillo { 2408 1.1 dillo return (a->parent_cnid - b->parent_cnid); 2409 1.1 dillo } 2410 1.1 dillo else 2411 1.1 dillo { 2412 1.1 dillo /* 2413 1.1 dillo * The following code implements the pseudocode suggested by 2414 1.1 dillo * the HFS+ technote. 2415 1.1 dillo */ 2416 1.1 dillo 2417 1.1 dillo /* 2418 1.1 dillo * XXX These need to be revised to be endian-independent! 2419 1.1 dillo */ 2420 1.1 dillo #define hbyte(x) ((x) >> 8) 2421 1.1 dillo #define lbyte(x) ((x) & 0x00FF) 2422 1.1 dillo 2423 1.1 dillo apos = bpos = 0; 2424 1.1 dillo while(1) 2425 1.1 dillo { 2426 1.1 dillo /* get next valid character from a */ 2427 1.1 dillo for (lc=0; lc == 0 && apos < a->name.length; apos++) { 2428 1.1 dillo ac = a->name.unicode[apos]; 2429 1.2 dillo lc = hfs_gcft[hbyte(ac)]; 2430 1.1 dillo if(lc==0) 2431 1.1 dillo lc = ac; 2432 1.1 dillo else 2433 1.2 dillo lc = hfs_gcft[lc + lbyte(ac)]; 2434 1.1 dillo }; 2435 1.1 dillo ac=lc; 2436 1.1 dillo 2437 1.1 dillo /* get next valid character from b */ 2438 1.1 dillo for (lc=0; lc == 0 && bpos < b->name.length; bpos++) { 2439 1.1 dillo bc = b->name.unicode[bpos]; 2440 1.2 dillo lc = hfs_gcft[hbyte(bc)]; 2441 1.1 dillo if(lc==0) 2442 1.1 dillo lc = bc; 2443 1.1 dillo else 2444 1.2 dillo lc = hfs_gcft[lc + lbyte(bc)]; 2445 1.1 dillo }; 2446 1.1 dillo bc=lc; 2447 1.1 dillo 2448 1.1 dillo /* on end of string ac/bc are 0, otherwise > 0 */ 2449 1.1 dillo if (ac != bc || (ac == 0 && bc == 0)) 2450 1.1 dillo return ac - bc; 2451 1.1 dillo } 2452 1.1 dillo #undef hbyte 2453 1.1 dillo #undef lbyte 2454 1.1 dillo } 2455 1.1 dillo } 2456 1.1 dillo 2457 1.1 dillo /* binary compare (i.e., not case folding) */ 2458 1.1 dillo int 2459 1.2 dillo hfslib_compare_catalog_keys_bc ( 2460 1.1 dillo const void *a, 2461 1.1 dillo const void *b) 2462 1.1 dillo { 2463 1.2 dillo if(((const hfs_catalog_key_t*)a)->parent_cnid 2464 1.2 dillo == ((const hfs_catalog_key_t*)b)->parent_cnid) 2465 1.1 dillo { 2466 1.2 dillo if(((const hfs_catalog_key_t*)a)->name.length == 0 && 2467 1.2 dillo ((const hfs_catalog_key_t*)b)->name.length == 0) 2468 1.1 dillo return 0; 2469 1.1 dillo 2470 1.2 dillo if(((const hfs_catalog_key_t*)a)->name.length == 0) 2471 1.1 dillo return -1; 2472 1.2 dillo if(((const hfs_catalog_key_t*)b)->name.length == 0) 2473 1.1 dillo return 1; 2474 1.1 dillo 2475 1.1 dillo /* FIXME: This does a byte-per-byte comparison, whereas the HFS spec 2476 1.1 dillo * mandates a uint16_t chunk comparison. */ 2477 1.2 dillo return memcmp(((const hfs_catalog_key_t*)a)->name.unicode, 2478 1.2 dillo ((const hfs_catalog_key_t*)b)->name.unicode, 2479 1.2 dillo min(((const hfs_catalog_key_t*)a)->name.length, 2480 1.2 dillo ((const hfs_catalog_key_t*)b)->name.length)); 2481 1.1 dillo } 2482 1.1 dillo else 2483 1.1 dillo { 2484 1.2 dillo return (((const hfs_catalog_key_t*)a)->parent_cnid - 2485 1.2 dillo ((const hfs_catalog_key_t*)b)->parent_cnid); 2486 1.1 dillo } 2487 1.1 dillo } 2488 1.1 dillo 2489 1.1 dillo int 2490 1.2 dillo hfslib_compare_extent_keys ( 2491 1.1 dillo const void *a, 2492 1.1 dillo const void *b) 2493 1.1 dillo { 2494 1.1 dillo /* 2495 1.1 dillo * Comparison order, in descending importance: 2496 1.1 dillo * 2497 1.1 dillo * CNID -> fork type -> start block 2498 1.1 dillo */ 2499 1.1 dillo 2500 1.2 dillo if(((const hfs_extent_key_t*)a)->file_cnid 2501 1.2 dillo == ((const hfs_extent_key_t*)b)->file_cnid) 2502 1.1 dillo { 2503 1.2 dillo if(((const hfs_extent_key_t*)a)->fork_type 2504 1.2 dillo == ((const hfs_extent_key_t*)b)->fork_type) 2505 1.1 dillo { 2506 1.2 dillo if(((const hfs_extent_key_t*)a)->start_block 2507 1.2 dillo == ((const hfs_extent_key_t*)b)->start_block) 2508 1.1 dillo { 2509 1.1 dillo return 0; 2510 1.1 dillo } 2511 1.1 dillo else 2512 1.1 dillo { 2513 1.2 dillo return (((const hfs_extent_key_t*)a)->start_block - 2514 1.2 dillo ((const hfs_extent_key_t*)b)->start_block); 2515 1.1 dillo } 2516 1.1 dillo } 2517 1.1 dillo else 2518 1.1 dillo { 2519 1.2 dillo return (((const hfs_extent_key_t*)a)->fork_type - 2520 1.2 dillo ((const hfs_extent_key_t*)b)->fork_type); 2521 1.1 dillo } 2522 1.1 dillo } 2523 1.1 dillo else 2524 1.1 dillo { 2525 1.2 dillo return (((const hfs_extent_key_t*)a)->file_cnid - 2526 1.2 dillo ((const hfs_extent_key_t*)b)->file_cnid); 2527 1.1 dillo } 2528 1.1 dillo } 2529 1.1 dillo 2530 1.1 dillo /* 1+10 tables of 16 rows and 16 columns, each 2 bytes wide = 5632 bytes */ 2531 1.1 dillo int 2532 1.2 dillo hfslib_create_casefolding_table(void) 2533 1.1 dillo { 2534 1.2 dillo hfs_callback_args cbargs; 2535 1.1 dillo unichar_t* t; /* convenience */ 2536 1.1 dillo uint16_t s; /* current subtable * 256 */ 2537 1.1 dillo uint16_t i; /* current subtable index (0 to 255) */ 2538 1.1 dillo 2539 1.2 dillo if(hfs_gcft!=NULL) 2540 1.1 dillo return 0; /* no sweat, table already exists */ 2541 1.1 dillo 2542 1.2 dillo hfslib_init_cbargs(&cbargs); 2543 1.2 dillo hfs_gcft = hfslib_malloc(5632, &cbargs); 2544 1.2 dillo if(hfs_gcft==NULL) 2545 1.2 dillo HFS_LIBERR("could not allocate case folding table"); 2546 1.1 dillo 2547 1.2 dillo t = hfs_gcft; /* easier to type :) */ 2548 1.1 dillo 2549 1.1 dillo /* 2550 1.1 dillo * high byte indices 2551 1.1 dillo */ 2552 1.1 dillo s = 0 * 256; 2553 1.1 dillo memset(t, 0x00, 512); 2554 1.1 dillo t[s+ 0] = 0x0100; 2555 1.1 dillo t[s+ 1] = 0x0200; 2556 1.1 dillo t[s+ 3] = 0x0300; 2557 1.1 dillo t[s+ 4] = 0x0400; 2558 1.1 dillo t[s+ 5] = 0x0500; 2559 1.1 dillo t[s+ 16] = 0x0600; 2560 1.1 dillo t[s+ 32] = 0x0700; 2561 1.1 dillo t[s+ 33] = 0x0800; 2562 1.1 dillo t[s+254] = 0x0900; 2563 1.1 dillo t[s+255] = 0x0a00; 2564 1.1 dillo 2565 1.1 dillo /* 2566 1.1 dillo * table 1 (high byte 0x00) 2567 1.1 dillo */ 2568 1.1 dillo s = 1 * 256; 2569 1.1 dillo for(i=0; i<65; i++) 2570 1.1 dillo t[s+i] = i; 2571 1.1 dillo t[s+ 0] = 0xffff; 2572 1.1 dillo for(i=65; i<91; i++) 2573 1.1 dillo t[s+i] = i + 0x20; 2574 1.1 dillo for(i=91; i<256; i++) 2575 1.1 dillo t[s+i] = i; 2576 1.1 dillo t[s+198] = 0x00e6; 2577 1.1 dillo t[s+208] = 0x00f0; 2578 1.1 dillo t[s+216] = 0x00f8; 2579 1.1 dillo t[s+222] = 0x00fe; 2580 1.1 dillo 2581 1.1 dillo /* 2582 1.1 dillo * table 2 (high byte 0x01) 2583 1.1 dillo */ 2584 1.1 dillo s = 2 * 256; 2585 1.1 dillo for(i=0; i<256; i++) 2586 1.1 dillo t[s+i] = i + 0x0100; 2587 1.1 dillo t[s+ 16] = 0x0111; 2588 1.1 dillo t[s+ 38] = 0x0127; 2589 1.1 dillo t[s+ 50] = 0x0133; 2590 1.1 dillo t[s+ 63] = 0x0140; 2591 1.1 dillo t[s+ 65] = 0x0142; 2592 1.1 dillo t[s+ 74] = 0x014b; 2593 1.1 dillo t[s+ 82] = 0x0153; 2594 1.1 dillo t[s+102] = 0x0167; 2595 1.1 dillo t[s+129] = 0x0253; 2596 1.1 dillo t[s+130] = 0x0183; 2597 1.1 dillo t[s+132] = 0x0185; 2598 1.1 dillo t[s+134] = 0x0254; 2599 1.1 dillo t[s+135] = 0x0188; 2600 1.1 dillo t[s+137] = 0x0256; 2601 1.1 dillo t[s+138] = 0x0257; 2602 1.1 dillo t[s+139] = 0x018c; 2603 1.1 dillo t[s+142] = 0x01dd; 2604 1.1 dillo t[s+143] = 0x0259; 2605 1.1 dillo t[s+144] = 0x025b; 2606 1.1 dillo t[s+145] = 0x0192; 2607 1.1 dillo t[s+147] = 0x0260; 2608 1.1 dillo t[s+148] = 0x0263; 2609 1.1 dillo t[s+150] = 0x0269; 2610 1.1 dillo t[s+151] = 0x0268; 2611 1.1 dillo t[s+152] = 0x0199; 2612 1.1 dillo t[s+156] = 0x026f; 2613 1.1 dillo t[s+157] = 0x0272; 2614 1.1 dillo t[s+159] = 0x0275; 2615 1.1 dillo t[s+162] = 0x01a3; 2616 1.1 dillo t[s+164] = 0x01a5; 2617 1.1 dillo t[s+167] = 0x01a8; 2618 1.1 dillo t[s+169] = 0x0283; 2619 1.1 dillo t[s+172] = 0x01ad; 2620 1.1 dillo t[s+174] = 0x0288; 2621 1.1 dillo t[s+177] = 0x028a; 2622 1.1 dillo t[s+178] = 0x028b; 2623 1.1 dillo t[s+179] = 0x01b4; 2624 1.1 dillo t[s+181] = 0x01b6; 2625 1.1 dillo t[s+183] = 0x0292; 2626 1.1 dillo t[s+184] = 0x01b9; 2627 1.1 dillo t[s+188] = 0x01bd; 2628 1.1 dillo t[s+196] = 0x01c6; 2629 1.1 dillo t[s+197] = 0x01c6; 2630 1.1 dillo t[s+199] = 0x01c9; 2631 1.1 dillo t[s+200] = 0x01c9; 2632 1.1 dillo t[s+202] = 0x01cc; 2633 1.1 dillo t[s+203] = 0x01cc; 2634 1.1 dillo t[s+228] = 0x01e5; 2635 1.1 dillo t[s+241] = 0x01f3; 2636 1.1 dillo t[s+242] = 0x01f3; 2637 1.1 dillo 2638 1.1 dillo /* 2639 1.1 dillo * table 3 (high byte 0x03) 2640 1.1 dillo */ 2641 1.1 dillo s = 3 * 256; 2642 1.1 dillo for(i=0; i<145; i++) 2643 1.1 dillo t[s+i] = i + 0x0300; 2644 1.1 dillo for(i=145; i<170; i++) 2645 1.1 dillo t[s+i] = i + 0x0320; 2646 1.1 dillo t[s+162] = 0x03a2; 2647 1.1 dillo for(i=170; i<256; i++) 2648 1.1 dillo t[s+i] = i + 0x0300; 2649 1.1 dillo 2650 1.1 dillo for(i=226; i<239; i+=2) 2651 1.1 dillo t[s+i] = i + 0x0301; 2652 1.1 dillo 2653 1.1 dillo /* 2654 1.1 dillo * table 4 (high byte 0x04) 2655 1.1 dillo */ 2656 1.1 dillo s = 4 * 256; 2657 1.1 dillo for(i=0; i<16; i++) 2658 1.1 dillo t[s+i] = i + 0x0400; 2659 1.1 dillo t[s+ 2] = 0x0452; 2660 1.1 dillo t[s+ 4] = 0x0454; 2661 1.1 dillo t[s+ 5] = 0x0455; 2662 1.1 dillo t[s+ 6] = 0x0456; 2663 1.1 dillo t[s+ 8] = 0x0458; 2664 1.1 dillo t[s+ 9] = 0x0459; 2665 1.1 dillo t[s+ 10] = 0x045a; 2666 1.1 dillo t[s+ 11] = 0x045b; 2667 1.1 dillo t[s+ 15] = 0x045f; 2668 1.1 dillo 2669 1.1 dillo for(i=16; i<48; i++) 2670 1.1 dillo t[s+i] = i + 0x0420; 2671 1.1 dillo t[s+ 25] = 0x0419; 2672 1.1 dillo for(i=48; i<256; i++) 2673 1.1 dillo t[s+i] = i + 0x0400; 2674 1.1 dillo t[s+195] = 0x04c4; 2675 1.1 dillo t[s+199] = 0x04c8; 2676 1.1 dillo t[s+203] = 0x04cc; 2677 1.1 dillo 2678 1.1 dillo for(i=96; i<129; i+=2) 2679 1.1 dillo t[s+i] = i + 0x0401; 2680 1.1 dillo t[s+118] = 0x0476; 2681 1.1 dillo for(i=144; i<191; i+=2) 2682 1.1 dillo t[s+i] = i + 0x0401; 2683 1.1 dillo 2684 1.1 dillo /* 2685 1.1 dillo * table 5 (high byte 0x05) 2686 1.1 dillo */ 2687 1.1 dillo s = 5 * 256; 2688 1.1 dillo for(i=0; i<49; i++) 2689 1.1 dillo t[s+i] = i + 0x0500; 2690 1.1 dillo for(i=49; i<87; i++) 2691 1.1 dillo t[s+i] = i + 0x0530; 2692 1.1 dillo for(i=87; i<256; i++) 2693 1.1 dillo t[s+i] = i + 0x0500; 2694 1.1 dillo 2695 1.1 dillo /* 2696 1.1 dillo * table 6 (high byte 0x10) 2697 1.1 dillo */ 2698 1.1 dillo s = 6 * 256; 2699 1.1 dillo for(i=0; i<160; i++) 2700 1.1 dillo t[s+i] = i + 0x1000; 2701 1.1 dillo for(i=160; i<198; i++) 2702 1.1 dillo t[s+i] = i + 0x1030; 2703 1.1 dillo for(i=198; i<256; i++) 2704 1.1 dillo t[s+i] = i + 0x1000; 2705 1.1 dillo 2706 1.1 dillo /* 2707 1.1 dillo * table 7 (high byte 0x20) 2708 1.1 dillo */ 2709 1.1 dillo s = 7 * 256; 2710 1.1 dillo for(i=0; i<256; i++) 2711 1.1 dillo t[s+i] = i + 0x2000; 2712 1.1 dillo { 2713 1.1 dillo uint8_t zi[15] = { 12, 13, 14, 15, 2714 1.1 dillo 42, 43, 44, 45, 46, 2715 1.1 dillo 106, 107, 108, 109, 110, 111}; 2716 1.1 dillo 2717 1.1 dillo for(i=0; i<15; i++) 2718 1.1 dillo t[s+zi[i]] = 0x0000; 2719 1.1 dillo } 2720 1.1 dillo 2721 1.1 dillo /* 2722 1.1 dillo * table 8 (high byte 0x21) 2723 1.1 dillo */ 2724 1.1 dillo s = 8 * 256; 2725 1.1 dillo for(i=0; i<96; i++) 2726 1.1 dillo t[s+i] = i + 0x2100; 2727 1.1 dillo for(i=96; i<112; i++) 2728 1.1 dillo t[s+i] = i + 0x2110; 2729 1.1 dillo for(i=112; i<256; i++) 2730 1.1 dillo t[s+i] = i + 0x2100; 2731 1.1 dillo 2732 1.1 dillo /* 2733 1.1 dillo * table 9 (high byte 0xFE) 2734 1.1 dillo */ 2735 1.1 dillo s = 9 * 256; 2736 1.1 dillo for(i=0; i<256; i++) 2737 1.1 dillo t[s+i] = i + 0xFE00; 2738 1.1 dillo t[s+255] = 0x0000; 2739 1.1 dillo 2740 1.1 dillo /* 2741 1.1 dillo * table 10 (high byte 0xFF) 2742 1.1 dillo */ 2743 1.1 dillo s = 10 * 256; 2744 1.1 dillo for(i=0; i<33; i++) 2745 1.1 dillo t[s+i] = i + 0xFF00; 2746 1.1 dillo for(i=33; i<59; i++) 2747 1.1 dillo t[s+i] = i + 0xFF20; 2748 1.1 dillo for(i=59; i<256; i++) 2749 1.1 dillo t[s+i] = i + 0xFF00; 2750 1.1 dillo 2751 1.1 dillo return 0; 2752 1.1 dillo 2753 1.1 dillo error: 2754 1.1 dillo return 1; 2755 1.1 dillo } 2756 1.1 dillo 2757 1.1 dillo int 2758 1.2 dillo hfslib_get_hardlink(hfs_volume *vol, uint32_t inode_num, 2759 1.2 dillo hfs_catalog_keyed_record_t *rec, 2760 1.2 dillo hfs_callback_args *cbargs) 2761 1.1 dillo { 2762 1.2 dillo hfs_catalog_keyed_record_t metadata; 2763 1.2 dillo hfs_catalog_key_t key; 2764 1.1 dillo char name[16]; 2765 1.1 dillo unichar_t name_uni[16]; 2766 1.1 dillo int i, len; 2767 1.1 dillo 2768 1.1 dillo /* XXX: cache this */ 2769 1.2 dillo if (hfslib_find_catalog_record_with_key(vol, 2770 1.2 dillo &hfs_gMetadataDirectoryKey, 2771 1.1 dillo &metadata, cbargs) != 0 2772 1.2 dillo || metadata.type != HFS_REC_FLDR) 2773 1.1 dillo return -1; 2774 1.1 dillo 2775 1.1 dillo len = snprintf(name, sizeof(name), "iNode%d", inode_num); 2776 1.1 dillo for (i=0; i<len; i++) 2777 1.1 dillo name_uni[i] = name[i]; 2778 1.1 dillo 2779 1.2 dillo if (hfslib_make_catalog_key(metadata.folder.cnid, len, name_uni, 2780 1.1 dillo &key) == 0) 2781 1.1 dillo return -1; 2782 1.1 dillo 2783 1.2 dillo return hfslib_find_catalog_record_with_key(vol, &key, rec, cbargs); 2784 1.1 dillo } 2785
Indexes created Sun Sep 21 20:09:37 GMT 2025