cmserr.c revision 4d3acf4ec42bf6e838f9060103aff98fbf170794
1//--------------------------------------------------------------------------------- 2// 3// Little Color Management System 4// Copyright (c) 1998-2012 Marti Maria Saguer 5// 6// Permission is hereby granted, free of charge, to any person obtaining 7// a copy of this software and associated documentation files (the "Software"), 8// to deal in the Software without restriction, including without limitation 9// the rights to use, copy, modify, merge, publish, distribute, sublicense, 10// and/or sell copies of the Software, and to permit persons to whom the Software 11// is furnished to do so, subject to the following conditions: 12// 13// The above copyright notice and this permission notice shall be included in 14// all copies or substantial portions of the Software. 15// 16// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, 17// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO 18// THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND 19// NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE 20// LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION 21// OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION 22// WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. 23// 24//--------------------------------------------------------------------------------- 25 26#include "lcms2_internal.h" 27 28// I am so tired about incompatibilities on those functions that here are some replacements 29// that hopefully would be fully portable. 30 31// compare two strings ignoring case 32int CMSEXPORT cmsstrcasecmp(const char* s1, const char* s2) 33{ 34 register const unsigned char *us1 = (const unsigned char *)s1, 35 *us2 = (const unsigned char *)s2; 36 37 while (toupper(*us1) == toupper(*us2++)) 38 if (*us1++ == '\0') 39 return 0; 40 41 return (toupper(*us1) - toupper(*--us2)); 42} 43 44// long int because C99 specifies ftell in such way (7.19.9.2) 45long int CMSEXPORT cmsfilelength(FILE* f) 46{ 47 long int p , n; 48 49 p = ftell(f); // register current file position 50 51 if (fseek(f, 0, SEEK_END) != 0) { 52 return -1; 53 } 54 55 n = ftell(f); 56 fseek(f, p, SEEK_SET); // file position restored 57 58 return n; 59} 60 61#if 0 62// Memory handling ------------------------------------------------------------------ 63// 64// This is the interface to low-level memory management routines. By default a simple 65// wrapping to malloc/free/realloc is provided, although there is a limit on the max 66// amount of memoy that can be reclaimed. This is mostly as a safety feature to prevent 67// bogus or evil code to allocate huge blocks that otherwise lcms would never need. 68 69#define MAX_MEMORY_FOR_ALLOC ((cmsUInt32Number)(1024U*1024U*512U)) 70 71// User may override this behaviour by using a memory plug-in, which basically replaces 72// the default memory management functions. In this case, no check is performed and it 73// is up to the plug-in writter to keep in the safe side. There are only three functions 74// required to be implemented: malloc, realloc and free, although the user may want to 75// replace the optional mallocZero, calloc and dup as well. 76 77cmsBool _cmsRegisterMemHandlerPlugin(cmsContext ContextID, cmsPluginBase* Plugin); 78 79// ********************************************************************************* 80 81// This is the default memory allocation function. It does a very coarse 82// check of amout of memory, just to prevent exploits 83static 84void* _cmsMallocDefaultFn(cmsContext ContextID, cmsUInt32Number size) 85{ 86 if (size > MAX_MEMORY_FOR_ALLOC) return NULL; // Never allow over maximum 87 88 return (void*) malloc(size); 89 90 cmsUNUSED_PARAMETER(ContextID); 91} 92 93// Generic allocate & zero 94static 95void* _cmsMallocZeroDefaultFn(cmsContext ContextID, cmsUInt32Number size) 96{ 97 void *pt = _cmsMalloc(ContextID, size); 98 if (pt == NULL) return NULL; 99 100 memset(pt, 0, size); 101 return pt; 102} 103 104 105// The default free function. The only check proformed is against NULL pointers 106static 107void _cmsFreeDefaultFn(cmsContext ContextID, void *Ptr) 108{ 109 // free(NULL) is defined a no-op by C99, therefore it is safe to 110 // avoid the check, but it is here just in case... 111 112 if (Ptr) free(Ptr); 113 114 cmsUNUSED_PARAMETER(ContextID); 115} 116 117// The default realloc function. Again it checks for exploits. If Ptr is NULL, 118// realloc behaves the same way as malloc and allocates a new block of size bytes. 119static 120void* _cmsReallocDefaultFn(cmsContext ContextID, void* Ptr, cmsUInt32Number size) 121{ 122 123 if (size > MAX_MEMORY_FOR_ALLOC) return NULL; // Never realloc over 512Mb 124 125 return realloc(Ptr, size); 126 127 cmsUNUSED_PARAMETER(ContextID); 128} 129 130 131// The default calloc function. Allocates an array of num elements, each one of size bytes 132// all memory is initialized to zero. 133static 134void* _cmsCallocDefaultFn(cmsContext ContextID, cmsUInt32Number num, cmsUInt32Number size) 135{ 136 cmsUInt32Number Total = num * size; 137 138 // Preserve calloc behaviour 139 if (Total == 0) return NULL; 140 141 // Safe check for overflow. 142 if (num >= UINT_MAX / size) return NULL; 143 144 // Check for overflow 145 if (Total < num || Total < size) { 146 return NULL; 147 } 148 149 if (Total > MAX_MEMORY_FOR_ALLOC) return NULL; // Never alloc over 512Mb 150 151 return _cmsMallocZero(ContextID, Total); 152} 153 154// Generic block duplication 155static 156void* _cmsDupDefaultFn(cmsContext ContextID, const void* Org, cmsUInt32Number size) 157{ 158 void* mem; 159 160 if (size > MAX_MEMORY_FOR_ALLOC) return NULL; // Never dup over 512Mb 161 162 mem = _cmsMalloc(ContextID, size); 163 164 if (mem != NULL && Org != NULL) 165 memmove(mem, Org, size); 166 167 return mem; 168} 169 170 171// Pointers to memory manager functions in Context0 172_cmsMemPluginChunkType _cmsMemPluginChunk = { _cmsMallocDefaultFn, _cmsMallocZeroDefaultFn, _cmsFreeDefaultFn, 173 _cmsReallocDefaultFn, _cmsCallocDefaultFn, _cmsDupDefaultFn 174 }; 175 176 177// Reset and duplicate memory manager 178void _cmsAllocMemPluginChunk(struct _cmsContext_struct* ctx, const struct _cmsContext_struct* src) 179{ 180 _cmsAssert(ctx != NULL); 181 182 if (src != NULL) { 183 184 // Duplicate 185 ctx ->chunks[MemPlugin] = _cmsSubAllocDup(ctx ->MemPool, src ->chunks[MemPlugin], sizeof(_cmsMemPluginChunkType)); 186 } 187 else { 188 189 // To reset it, we use the default allocators, which cannot be overriden 190 ctx ->chunks[MemPlugin] = &ctx ->DefaultMemoryManager; 191 } 192} 193 194// Auxiliar to fill memory management functions from plugin (or context 0 defaults) 195void _cmsInstallAllocFunctions(cmsPluginMemHandler* Plugin, _cmsMemPluginChunkType* ptr) 196{ 197 if (Plugin == NULL) { 198 199 memcpy(ptr, &_cmsMemPluginChunk, sizeof(_cmsMemPluginChunk)); 200 } 201 else { 202 203 ptr ->MallocPtr = Plugin -> MallocPtr; 204 ptr ->FreePtr = Plugin -> FreePtr; 205 ptr ->ReallocPtr = Plugin -> ReallocPtr; 206 207 // Make sure we revert to defaults 208 ptr ->MallocZeroPtr= _cmsMallocZeroDefaultFn; 209 ptr ->CallocPtr = _cmsCallocDefaultFn; 210 ptr ->DupPtr = _cmsDupDefaultFn; 211 212 if (Plugin ->MallocZeroPtr != NULL) ptr ->MallocZeroPtr = Plugin -> MallocZeroPtr; 213 if (Plugin ->CallocPtr != NULL) ptr ->CallocPtr = Plugin -> CallocPtr; 214 if (Plugin ->DupPtr != NULL) ptr ->DupPtr = Plugin -> DupPtr; 215 216 } 217} 218 219 220// Plug-in replacement entry 221cmsBool _cmsRegisterMemHandlerPlugin(cmsContext ContextID, cmsPluginBase *Data) 222{ 223 cmsPluginMemHandler* Plugin = (cmsPluginMemHandler*) Data; 224 _cmsMemPluginChunkType* ptr; 225 226 // NULL forces to reset to defaults. In this special case, the defaults are stored in the context structure. 227 // Remaining plug-ins does NOT have any copy in the context structure, but this is somehow special as the 228 // context internal data should be malloce'd by using those functions. 229 if (Data == NULL) { 230 231 struct _cmsContext_struct* ctx = ( struct _cmsContext_struct*) ContextID; 232 233 // Return to the default allocators 234 if (ContextID != NULL) { 235 ctx->chunks[MemPlugin] = (void*) &ctx->DefaultMemoryManager; 236 } 237 return TRUE; 238 } 239 240 // Check for required callbacks 241 if (Plugin -> MallocPtr == NULL || 242 Plugin -> FreePtr == NULL || 243 Plugin -> ReallocPtr == NULL) return FALSE; 244 245 // Set replacement functions 246 ptr = (_cmsMemPluginChunkType*) _cmsContextGetClientChunk(ContextID, MemPlugin); 247 if (ptr == NULL) 248 return FALSE; 249 250 _cmsInstallAllocFunctions(Plugin, ptr); 251 return TRUE; 252} 253#else 254#include "core/fxcrt/fx_memory.h" 255#include "core/fxcrt/fx_system.h" 256 257cmsBool _cmsRegisterMemHandlerPlugin(cmsContext ContextID, cmsPluginBase* Plugin) 258{ 259 return TRUE; 260} 261 262// Generic allocate 263void* CMSEXPORT _cmsMalloc(cmsContext ContextID, cmsUInt32Number size) 264{ 265 return FXMEM_DefaultAlloc(size, 1); 266} 267 268// Generic allocate & zero 269void* CMSEXPORT _cmsMallocZero(cmsContext ContextID, cmsUInt32Number size) 270{ 271 void* p = FXMEM_DefaultAlloc(size, 1); 272 if (p) FXSYS_memset(p, 0, size); 273 return p; 274} 275 276// Generic calloc 277void* CMSEXPORT _cmsCalloc(cmsContext ContextID, cmsUInt32Number num, cmsUInt32Number size) 278{ 279 cmsUInt32Number total = num * size; 280 if (total == 0 || total / size != num || total >= 512 * 1024 * 1024) 281 return NULL; 282 283 return _cmsMallocZero(ContextID, num * size); 284} 285 286// Generic reallocate 287void* CMSEXPORT _cmsRealloc(cmsContext ContextID, void* Ptr, cmsUInt32Number size) 288{ 289 return FXMEM_DefaultRealloc(Ptr, size, 1); 290} 291 292// Generic free memory 293void CMSEXPORT _cmsFree(cmsContext ContextID, void* Ptr) 294{ 295 if (Ptr != NULL) FXMEM_DefaultFree(Ptr, 0); 296} 297 298// Generic block duplication 299void* CMSEXPORT _cmsDupMem(cmsContext ContextID, const void* Org, cmsUInt32Number size) 300{ 301 void* p = FXMEM_DefaultAlloc(size, 1); 302 FXSYS_memmove(p, Org, size); 303 return p; 304} 305 306_cmsMemPluginChunkType _cmsMemPluginChunk = {_cmsMalloc, _cmsMallocZero, _cmsFree, 307 _cmsRealloc, _cmsCalloc, _cmsDupMem 308 }; 309 310void _cmsAllocMemPluginChunk(struct _cmsContext_struct* ctx, const struct _cmsContext_struct* src) 311{ 312 _cmsAssert(ctx != NULL); 313 314 if (src != NULL) { 315 316 // Duplicate 317 ctx ->chunks[MemPlugin] = _cmsSubAllocDup(ctx ->MemPool, src ->chunks[MemPlugin], sizeof(_cmsMemPluginChunkType)); 318 } 319 else { 320 321 // To reset it, we use the default allocators, which cannot be overriden 322 ctx ->chunks[MemPlugin] = &ctx ->DefaultMemoryManager; 323 } 324} 325 326void _cmsInstallAllocFunctions(cmsPluginMemHandler* Plugin, _cmsMemPluginChunkType* ptr) 327{ 328 if (Plugin == NULL) { 329 330 memcpy(ptr, &_cmsMemPluginChunk, sizeof(_cmsMemPluginChunk)); 331 } 332 else { 333 334 ptr ->MallocPtr = Plugin -> MallocPtr; 335 ptr ->FreePtr = Plugin -> FreePtr; 336 ptr ->ReallocPtr = Plugin -> ReallocPtr; 337 338 // Make sure we revert to defaults 339 ptr ->MallocZeroPtr= _cmsMallocZero; 340 ptr ->CallocPtr = _cmsCalloc; 341 ptr ->DupPtr = _cmsDupMem; 342 343 if (Plugin ->MallocZeroPtr != NULL) ptr ->MallocZeroPtr = Plugin -> MallocZeroPtr; 344 if (Plugin ->CallocPtr != NULL) ptr ->CallocPtr = Plugin -> CallocPtr; 345 if (Plugin ->DupPtr != NULL) ptr ->DupPtr = Plugin -> DupPtr; 346 347 } 348} 349#endif 350 351// ******************************************************************************************** 352 353// Sub allocation takes care of many pointers of small size. The memory allocated in 354// this way have be freed at once. Next function allocates a single chunk for linked list 355// I prefer this method over realloc due to the big inpact on xput realloc may have if 356// memory is being swapped to disk. This approach is safer (although that may not be true on all platforms) 357static 358_cmsSubAllocator_chunk* _cmsCreateSubAllocChunk(cmsContext ContextID, cmsUInt32Number Initial) 359{ 360 _cmsSubAllocator_chunk* chunk; 361 362 // 20K by default 363 if (Initial == 0) 364 Initial = 20*1024; 365 366 // Create the container 367 chunk = (_cmsSubAllocator_chunk*) _cmsMallocZero(ContextID, sizeof(_cmsSubAllocator_chunk)); 368 if (chunk == NULL) return NULL; 369 370 // Initialize values 371 chunk ->Block = (cmsUInt8Number*) _cmsMalloc(ContextID, Initial); 372 if (chunk ->Block == NULL) { 373 374 // Something went wrong 375 _cmsFree(ContextID, chunk); 376 return NULL; 377 } 378 379 chunk ->BlockSize = Initial; 380 chunk ->Used = 0; 381 chunk ->next = NULL; 382 383 return chunk; 384} 385 386// The suballocated is nothing but a pointer to the first element in the list. We also keep 387// the thread ID in this structure. 388_cmsSubAllocator* _cmsCreateSubAlloc(cmsContext ContextID, cmsUInt32Number Initial) 389{ 390 _cmsSubAllocator* sub; 391 392 // Create the container 393 sub = (_cmsSubAllocator*) _cmsMallocZero(ContextID, sizeof(_cmsSubAllocator)); 394 if (sub == NULL) return NULL; 395 396 sub ->ContextID = ContextID; 397 398 sub ->h = _cmsCreateSubAllocChunk(ContextID, Initial); 399 if (sub ->h == NULL) { 400 _cmsFree(ContextID, sub); 401 return NULL; 402 } 403 404 return sub; 405} 406 407 408// Get rid of whole linked list 409void _cmsSubAllocDestroy(_cmsSubAllocator* sub) 410{ 411 _cmsSubAllocator_chunk *chunk, *n; 412 413 for (chunk = sub ->h; chunk != NULL; chunk = n) { 414 415 n = chunk->next; 416 if (chunk->Block != NULL) _cmsFree(sub ->ContextID, chunk->Block); 417 _cmsFree(sub ->ContextID, chunk); 418 } 419 420 // Free the header 421 _cmsFree(sub ->ContextID, sub); 422} 423 424 425// Get a pointer to small memory block. 426void* _cmsSubAlloc(_cmsSubAllocator* sub, cmsUInt32Number size) 427{ 428 cmsUInt32Number Free = sub -> h ->BlockSize - sub -> h -> Used; 429 cmsUInt8Number* ptr; 430 431 size = _cmsALIGNMEM(size); 432 433 // Check for memory. If there is no room, allocate a new chunk of double memory size. 434 if (size > Free) { 435 436 _cmsSubAllocator_chunk* chunk; 437 cmsUInt32Number newSize; 438 439 newSize = sub -> h ->BlockSize * 2; 440 if (newSize < size) newSize = size; 441 442 chunk = _cmsCreateSubAllocChunk(sub -> ContextID, newSize); 443 if (chunk == NULL) return NULL; 444 445 // Link list 446 chunk ->next = sub ->h; 447 sub ->h = chunk; 448 449 } 450 451 ptr = sub -> h ->Block + sub -> h ->Used; 452 sub -> h -> Used += size; 453 454 return (void*) ptr; 455} 456 457// Duplicate in pool 458void* _cmsSubAllocDup(_cmsSubAllocator* s, const void *ptr, cmsUInt32Number size) 459{ 460 void *NewPtr; 461 462 // Dup of null pointer is also NULL 463 if (ptr == NULL) 464 return NULL; 465 466 NewPtr = _cmsSubAlloc(s, size); 467 468 if (ptr != NULL && NewPtr != NULL) { 469 memcpy(NewPtr, ptr, size); 470 } 471 472 return NewPtr; 473} 474 475 476 477// Error logging ****************************************************************** 478 479// There is no error handling at all. When a funtion fails, it returns proper value. 480// For example, all create functions does return NULL on failure. Other return FALSE 481// It may be interesting, for the developer, to know why the function is failing. 482// for that reason, lcms2 does offer a logging function. This function does recive 483// a ENGLISH string with some clues on what is going wrong. You can show this 484// info to the end user, or just create some sort of log. 485// The logging function should NOT terminate the program, as this obviously can leave 486// resources. It is the programmer's responsability to check each function return code 487// to make sure it didn't fail. 488 489// Error messages are limited to MAX_ERROR_MESSAGE_LEN 490 491#define MAX_ERROR_MESSAGE_LEN 1024 492 493// --------------------------------------------------------------------------------------------------------- 494 495// This is our default log error 496static void DefaultLogErrorHandlerFunction(cmsContext ContextID, cmsUInt32Number ErrorCode, const char *Text); 497 498// Context0 storage, which is global 499_cmsLogErrorChunkType _cmsLogErrorChunk = { DefaultLogErrorHandlerFunction }; 500 501// Allocates and inits error logger container for a given context. If src is NULL, only initializes the value 502// to the default. Otherwise, it duplicates the value. The interface is standard across all context clients 503void _cmsAllocLogErrorChunk(struct _cmsContext_struct* ctx, 504 const struct _cmsContext_struct* src) 505{ 506 static _cmsLogErrorChunkType LogErrorChunk = { DefaultLogErrorHandlerFunction }; 507 void* from; 508 509 if (src != NULL) { 510 from = src ->chunks[Logger]; 511 } 512 else { 513 from = &LogErrorChunk; 514 } 515 516 ctx ->chunks[Logger] = _cmsSubAllocDup(ctx ->MemPool, from, sizeof(_cmsLogErrorChunkType)); 517} 518 519// The default error logger does nothing. 520static 521void DefaultLogErrorHandlerFunction(cmsContext ContextID, cmsUInt32Number ErrorCode, const char *Text) 522{ 523 // fprintf(stderr, "[lcms]: %s\n", Text); 524 // fflush(stderr); 525 526 cmsUNUSED_PARAMETER(ContextID); 527 cmsUNUSED_PARAMETER(ErrorCode); 528 cmsUNUSED_PARAMETER(Text); 529} 530 531// Change log error, context based 532void CMSEXPORT cmsSetLogErrorHandlerTHR(cmsContext ContextID, cmsLogErrorHandlerFunction Fn) 533{ 534 _cmsLogErrorChunkType* lhg = (_cmsLogErrorChunkType*) _cmsContextGetClientChunk(ContextID, Logger); 535 536 if (lhg != NULL) { 537 538 if (Fn == NULL) 539 lhg -> LogErrorHandler = DefaultLogErrorHandlerFunction; 540 else 541 lhg -> LogErrorHandler = Fn; 542 } 543} 544 545// Change log error, legacy 546void CMSEXPORT cmsSetLogErrorHandler(cmsLogErrorHandlerFunction Fn) 547{ 548 cmsSetLogErrorHandlerTHR(NULL, Fn); 549} 550 551// Log an error 552// ErrorText is a text holding an english description of error. 553void CMSEXPORT cmsSignalError(cmsContext ContextID, cmsUInt32Number ErrorCode, const char *ErrorText, ...) 554{ 555 va_list args; 556 char Buffer[MAX_ERROR_MESSAGE_LEN]; 557 _cmsLogErrorChunkType* lhg; 558 559 560 va_start(args, ErrorText); 561 vsnprintf(Buffer, MAX_ERROR_MESSAGE_LEN-1, ErrorText, args); 562 va_end(args); 563 564 // Check for the context, if specified go there. If not, go for the global 565 lhg = (_cmsLogErrorChunkType*) _cmsContextGetClientChunk(ContextID, Logger); 566 if (lhg ->LogErrorHandler) { 567 lhg ->LogErrorHandler(ContextID, ErrorCode, Buffer); 568 } 569} 570 571// Utility function to print signatures 572void _cmsTagSignature2String(char String[5], cmsTagSignature sig) 573{ 574 cmsUInt32Number be; 575 576 // Convert to big endian 577 be = _cmsAdjustEndianess32((cmsUInt32Number) sig); 578 579 // Move chars 580 memmove(String, &be, 4); 581 582 // Make sure of terminator 583 String[4] = 0; 584} 585 586//-------------------------------------------------------------------------------------------------- 587 588 589static 590void* defMtxCreate(cmsContext id) 591{ 592 _cmsMutex* ptr_mutex = (_cmsMutex*) _cmsMalloc(id, sizeof(_cmsMutex)); 593 _cmsInitMutexPrimitive(ptr_mutex); 594 return (void*) ptr_mutex; 595} 596 597static 598void defMtxDestroy(cmsContext id, void* mtx) 599{ 600 _cmsDestroyMutexPrimitive((_cmsMutex *) mtx); 601 _cmsFree(id, mtx); 602} 603 604static 605cmsBool defMtxLock(cmsContext id, void* mtx) 606{ 607 cmsUNUSED_PARAMETER(id); 608 return _cmsLockPrimitive((_cmsMutex *) mtx) == 0; 609} 610 611static 612void defMtxUnlock(cmsContext id, void* mtx) 613{ 614 cmsUNUSED_PARAMETER(id); 615 _cmsUnlockPrimitive((_cmsMutex *) mtx); 616} 617 618 619 620// Pointers to memory manager functions in Context0 621_cmsMutexPluginChunkType _cmsMutexPluginChunk = { defMtxCreate, defMtxDestroy, defMtxLock, defMtxUnlock }; 622 623// Allocate and init mutex container. 624void _cmsAllocMutexPluginChunk(struct _cmsContext_struct* ctx, 625 const struct _cmsContext_struct* src) 626{ 627 static _cmsMutexPluginChunkType MutexChunk = {defMtxCreate, defMtxDestroy, defMtxLock, defMtxUnlock }; 628 void* from; 629 630 if (src != NULL) { 631 from = src ->chunks[MutexPlugin]; 632 } 633 else { 634 from = &MutexChunk; 635 } 636 637 ctx ->chunks[MutexPlugin] = _cmsSubAllocDup(ctx ->MemPool, from, sizeof(_cmsMutexPluginChunkType)); 638} 639 640// Register new ways to transform 641cmsBool _cmsRegisterMutexPlugin(cmsContext ContextID, cmsPluginBase* Data) 642{ 643 cmsPluginMutex* Plugin = (cmsPluginMutex*) Data; 644 _cmsMutexPluginChunkType* ctx = ( _cmsMutexPluginChunkType*) _cmsContextGetClientChunk(ContextID, MutexPlugin); 645 646 if (Data == NULL) { 647 648 // No lock routines 649 ctx->CreateMutexPtr = NULL; 650 ctx->DestroyMutexPtr = NULL; 651 ctx->LockMutexPtr = NULL; 652 ctx ->UnlockMutexPtr = NULL; 653 return TRUE; 654 } 655 656 // Factory callback is required 657 if (Plugin ->CreateMutexPtr == NULL || Plugin ->DestroyMutexPtr == NULL || 658 Plugin ->LockMutexPtr == NULL || Plugin ->UnlockMutexPtr == NULL) return FALSE; 659 660 661 ctx->CreateMutexPtr = Plugin->CreateMutexPtr; 662 ctx->DestroyMutexPtr = Plugin ->DestroyMutexPtr; 663 ctx ->LockMutexPtr = Plugin ->LockMutexPtr; 664 ctx ->UnlockMutexPtr = Plugin ->UnlockMutexPtr; 665 666 // All is ok 667 return TRUE; 668} 669 670// Generic Mutex fns 671void* CMSEXPORT _cmsCreateMutex(cmsContext ContextID) 672{ 673 _cmsMutexPluginChunkType* ptr = (_cmsMutexPluginChunkType*) _cmsContextGetClientChunk(ContextID, MutexPlugin); 674 675 if (ptr ->CreateMutexPtr == NULL) return NULL; 676 677 return ptr ->CreateMutexPtr(ContextID); 678} 679 680void CMSEXPORT _cmsDestroyMutex(cmsContext ContextID, void* mtx) 681{ 682 _cmsMutexPluginChunkType* ptr = (_cmsMutexPluginChunkType*) _cmsContextGetClientChunk(ContextID, MutexPlugin); 683 684 if (ptr ->DestroyMutexPtr != NULL) { 685 686 ptr ->DestroyMutexPtr(ContextID, mtx); 687 } 688} 689 690cmsBool CMSEXPORT _cmsLockMutex(cmsContext ContextID, void* mtx) 691{ 692 _cmsMutexPluginChunkType* ptr = (_cmsMutexPluginChunkType*) _cmsContextGetClientChunk(ContextID, MutexPlugin); 693 694 if (ptr ->LockMutexPtr == NULL) return TRUE; 695 696 return ptr ->LockMutexPtr(ContextID, mtx); 697} 698 699void CMSEXPORT _cmsUnlockMutex(cmsContext ContextID, void* mtx) 700{ 701 _cmsMutexPluginChunkType* ptr = (_cmsMutexPluginChunkType*) _cmsContextGetClientChunk(ContextID, MutexPlugin); 702 703 if (ptr ->UnlockMutexPtr != NULL) { 704 705 ptr ->UnlockMutexPtr(ContextID, mtx); 706 } 707} 708