1 // Copyright 2014 PDFium Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style license that can be 3 // found in the LICENSE file. 4 5 // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com 6 7 #include <algorithm> 8 #include <limits> 9 #include <memory> 10 #include <vector> 11 12 #include "core/fpdfapi/page/cpdf_colorspace.h" 13 #include "core/fxcodec/codec/codec_int.h" 14 #include "core/fxcodec/fx_codec.h" 15 #include "core/fxcrt/fx_safe_types.h" 16 #include "third_party/lcms2-2.6/include/lcms2.h" 17 #include "third_party/libopenjpeg20/openjpeg.h" 18 19 static void fx_error_callback(const char* msg, void* client_data) { 20 (void)client_data; 21 } 22 static void fx_warning_callback(const char* msg, void* client_data) { 23 (void)client_data; 24 } 25 static void fx_info_callback(const char* msg, void* client_data) { 26 (void)client_data; 27 } 28 29 OPJ_SIZE_T opj_read_from_memory(void* p_buffer, 30 OPJ_SIZE_T nb_bytes, 31 void* p_user_data) { 32 DecodeData* srcData = static_cast<DecodeData*>(p_user_data); 33 if (!srcData || !srcData->src_data || srcData->src_size == 0) { 34 return static_cast<OPJ_SIZE_T>(-1); 35 } 36 // Reads at EOF return an error code. 37 if (srcData->offset >= srcData->src_size) { 38 return static_cast<OPJ_SIZE_T>(-1); 39 } 40 OPJ_SIZE_T bufferLength = srcData->src_size - srcData->offset; 41 OPJ_SIZE_T readlength = nb_bytes < bufferLength ? nb_bytes : bufferLength; 42 memcpy(p_buffer, &srcData->src_data[srcData->offset], readlength); 43 srcData->offset += readlength; 44 return readlength; 45 } 46 47 OPJ_SIZE_T opj_write_from_memory(void* p_buffer, 48 OPJ_SIZE_T nb_bytes, 49 void* p_user_data) { 50 DecodeData* srcData = static_cast<DecodeData*>(p_user_data); 51 if (!srcData || !srcData->src_data || srcData->src_size == 0) { 52 return static_cast<OPJ_SIZE_T>(-1); 53 } 54 // Writes at EOF return an error code. 55 if (srcData->offset >= srcData->src_size) { 56 return static_cast<OPJ_SIZE_T>(-1); 57 } 58 OPJ_SIZE_T bufferLength = srcData->src_size - srcData->offset; 59 OPJ_SIZE_T writeLength = nb_bytes < bufferLength ? nb_bytes : bufferLength; 60 memcpy(&srcData->src_data[srcData->offset], p_buffer, writeLength); 61 srcData->offset += writeLength; 62 return writeLength; 63 } 64 65 OPJ_OFF_T opj_skip_from_memory(OPJ_OFF_T nb_bytes, void* p_user_data) { 66 DecodeData* srcData = static_cast<DecodeData*>(p_user_data); 67 if (!srcData || !srcData->src_data || srcData->src_size == 0) { 68 return static_cast<OPJ_OFF_T>(-1); 69 } 70 // Offsets are signed and may indicate a negative skip. Do not support this 71 // because of the strange return convention where either bytes skipped or 72 // -1 is returned. Following that convention, a successful relative seek of 73 // -1 bytes would be required to to give the same result as the error case. 74 if (nb_bytes < 0) { 75 return static_cast<OPJ_OFF_T>(-1); 76 } 77 // FIXME: use std::make_unsigned<OPJ_OFF_T>::type once c++11 lib is OK'd. 78 uint64_t unsignedNbBytes = static_cast<uint64_t>(nb_bytes); 79 // Additionally, the offset may take us beyond the range of a size_t (e.g. 80 // 32-bit platforms). If so, just clamp at EOF. 81 if (unsignedNbBytes > 82 std::numeric_limits<OPJ_SIZE_T>::max() - srcData->offset) { 83 srcData->offset = srcData->src_size; 84 } else { 85 OPJ_SIZE_T checkedNbBytes = static_cast<OPJ_SIZE_T>(unsignedNbBytes); 86 // Otherwise, mimic fseek() semantics to always succeed, even past EOF, 87 // clamping at EOF. We can get away with this since we don't actually 88 // provide negative relative skips from beyond EOF back to inside the 89 // data, which would be the only reason to need to know exactly how far 90 // beyond EOF we are. 91 srcData->offset = 92 std::min(srcData->offset + checkedNbBytes, srcData->src_size); 93 } 94 return nb_bytes; 95 } 96 97 OPJ_BOOL opj_seek_from_memory(OPJ_OFF_T nb_bytes, void* p_user_data) { 98 DecodeData* srcData = static_cast<DecodeData*>(p_user_data); 99 if (!srcData || !srcData->src_data || srcData->src_size == 0) { 100 return OPJ_FALSE; 101 } 102 // Offsets are signed and may indicate a negative position, which would 103 // be before the start of the file. Do not support this. 104 if (nb_bytes < 0) { 105 return OPJ_FALSE; 106 } 107 // FIXME: use std::make_unsigned<OPJ_OFF_T>::type once c++11 lib is OK'd. 108 uint64_t unsignedNbBytes = static_cast<uint64_t>(nb_bytes); 109 // Additionally, the offset may take us beyond the range of a size_t (e.g. 110 // 32-bit platforms). If so, just clamp at EOF. 111 if (unsignedNbBytes > std::numeric_limits<OPJ_SIZE_T>::max()) { 112 srcData->offset = srcData->src_size; 113 } else { 114 OPJ_SIZE_T checkedNbBytes = static_cast<OPJ_SIZE_T>(nb_bytes); 115 // Otherwise, mimic fseek() semantics to always succeed, even past EOF, 116 // again clamping at EOF. 117 srcData->offset = std::min(checkedNbBytes, srcData->src_size); 118 } 119 return OPJ_TRUE; 120 } 121 opj_stream_t* fx_opj_stream_create_memory_stream(DecodeData* data, 122 OPJ_SIZE_T p_size, 123 OPJ_BOOL p_is_read_stream) { 124 opj_stream_t* l_stream = 00; 125 if (!data || !data->src_data || data->src_size <= 0) { 126 return nullptr; 127 } 128 l_stream = opj_stream_create(p_size, p_is_read_stream); 129 if (!l_stream) { 130 return nullptr; 131 } 132 opj_stream_set_user_data(l_stream, data, nullptr); 133 opj_stream_set_user_data_length(l_stream, data->src_size); 134 opj_stream_set_read_function(l_stream, opj_read_from_memory); 135 opj_stream_set_write_function(l_stream, opj_write_from_memory); 136 opj_stream_set_skip_function(l_stream, opj_skip_from_memory); 137 opj_stream_set_seek_function(l_stream, opj_seek_from_memory); 138 return l_stream; 139 } 140 static void sycc_to_rgb(int offset, 141 int upb, 142 int y, 143 int cb, 144 int cr, 145 int* out_r, 146 int* out_g, 147 int* out_b) { 148 int r, g, b; 149 cb -= offset; 150 cr -= offset; 151 r = y + (int)(1.402 * (float)cr); 152 if (r < 0) { 153 r = 0; 154 } else if (r > upb) { 155 r = upb; 156 } 157 *out_r = r; 158 g = y - (int)(0.344 * (float)cb + 0.714 * (float)cr); 159 if (g < 0) { 160 g = 0; 161 } else if (g > upb) { 162 g = upb; 163 } 164 *out_g = g; 165 b = y + (int)(1.772 * (float)cb); 166 if (b < 0) { 167 b = 0; 168 } else if (b > upb) { 169 b = upb; 170 } 171 *out_b = b; 172 } 173 174 static void sycc444_to_rgb(opj_image_t* img) { 175 int prec = img->comps[0].prec; 176 int offset = 1 << (prec - 1); 177 int upb = (1 << prec) - 1; 178 OPJ_UINT32 maxw = 179 std::min({img->comps[0].w, img->comps[1].w, img->comps[2].w}); 180 OPJ_UINT32 maxh = 181 std::min({img->comps[0].h, img->comps[1].h, img->comps[2].h}); 182 FX_SAFE_SIZE_T max_size = maxw; 183 max_size *= maxh; 184 if (!max_size.IsValid()) 185 return; 186 187 const int* y = img->comps[0].data; 188 const int* cb = img->comps[1].data; 189 const int* cr = img->comps[2].data; 190 if (!y || !cb || !cr) 191 return; 192 193 int* r = FX_Alloc(int, max_size.ValueOrDie()); 194 int* g = FX_Alloc(int, max_size.ValueOrDie()); 195 int* b = FX_Alloc(int, max_size.ValueOrDie()); 196 int* d0 = r; 197 int* d1 = g; 198 int* d2 = b; 199 for (size_t i = 0; i < max_size.ValueOrDie(); ++i) { 200 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 201 ++y; 202 ++cb; 203 ++cr; 204 ++r; 205 ++g; 206 ++b; 207 } 208 FX_Free(img->comps[0].data); 209 FX_Free(img->comps[1].data); 210 FX_Free(img->comps[2].data); 211 img->comps[0].data = d0; 212 img->comps[1].data = d1; 213 img->comps[2].data = d2; 214 } 215 216 static bool sycc420_422_size_is_valid(opj_image_t* img) { 217 return (img && img->comps[0].w != std::numeric_limits<OPJ_UINT32>::max() && 218 (img->comps[0].w + 1) / 2 == img->comps[1].w && 219 img->comps[1].w == img->comps[2].w && 220 img->comps[1].h == img->comps[2].h); 221 } 222 static bool sycc420_size_is_valid(opj_image_t* img) { 223 return (sycc420_422_size_is_valid(img) && 224 img->comps[0].h != std::numeric_limits<OPJ_UINT32>::max() && 225 (img->comps[0].h + 1) / 2 == img->comps[1].h); 226 } 227 static bool sycc422_size_is_valid(opj_image_t* img) { 228 return (sycc420_422_size_is_valid(img) && img->comps[0].h == img->comps[1].h); 229 } 230 static void sycc422_to_rgb(opj_image_t* img) { 231 if (!sycc422_size_is_valid(img)) 232 return; 233 234 int prec = img->comps[0].prec; 235 if (prec <= 0 || prec >= 32) 236 return; 237 238 int offset = 1 << (prec - 1); 239 int upb = (1 << prec) - 1; 240 241 OPJ_UINT32 maxw = img->comps[0].w; 242 OPJ_UINT32 maxh = img->comps[0].h; 243 FX_SAFE_SIZE_T max_size = maxw; 244 max_size *= maxh; 245 if (!max_size.IsValid()) 246 return; 247 248 const int* y = img->comps[0].data; 249 const int* cb = img->comps[1].data; 250 const int* cr = img->comps[2].data; 251 if (!y || !cb || !cr) 252 return; 253 254 int *d0, *d1, *d2, *r, *g, *b; 255 d0 = r = FX_Alloc(int, max_size.ValueOrDie()); 256 d1 = g = FX_Alloc(int, max_size.ValueOrDie()); 257 d2 = b = FX_Alloc(int, max_size.ValueOrDie()); 258 for (uint32_t i = 0; i < maxh; ++i) { 259 OPJ_UINT32 j; 260 for (j = 0; j < (maxw & ~static_cast<OPJ_UINT32>(1)); j += 2) { 261 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 262 ++y; 263 ++r; 264 ++g; 265 ++b; 266 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 267 ++y; 268 ++r; 269 ++g; 270 ++b; 271 ++cb; 272 ++cr; 273 } 274 if (j < maxw) { 275 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 276 ++y; 277 ++r; 278 ++g; 279 ++b; 280 ++cb; 281 ++cr; 282 } 283 } 284 FX_Free(img->comps[0].data); 285 img->comps[0].data = d0; 286 FX_Free(img->comps[1].data); 287 img->comps[1].data = d1; 288 FX_Free(img->comps[2].data); 289 img->comps[2].data = d2; 290 img->comps[1].w = maxw; 291 img->comps[1].h = maxh; 292 img->comps[2].w = maxw; 293 img->comps[2].h = maxh; 294 img->comps[1].dx = img->comps[0].dx; 295 img->comps[2].dx = img->comps[0].dx; 296 img->comps[1].dy = img->comps[0].dy; 297 img->comps[2].dy = img->comps[0].dy; 298 } 299 static bool sycc420_must_extend_cbcr(OPJ_UINT32 y, OPJ_UINT32 cbcr) { 300 return (y & 1) && (cbcr == y / 2); 301 } 302 void sycc420_to_rgb(opj_image_t* img) { 303 if (!sycc420_size_is_valid(img)) 304 return; 305 306 OPJ_UINT32 prec = img->comps[0].prec; 307 if (!prec) 308 return; 309 OPJ_UINT32 offset = 1 << (prec - 1); 310 OPJ_UINT32 upb = (1 << prec) - 1; 311 OPJ_UINT32 yw = img->comps[0].w; 312 OPJ_UINT32 yh = img->comps[0].h; 313 OPJ_UINT32 cbw = img->comps[1].w; 314 OPJ_UINT32 cbh = img->comps[1].h; 315 OPJ_UINT32 crw = img->comps[2].w; 316 bool extw = sycc420_must_extend_cbcr(yw, cbw); 317 bool exth = sycc420_must_extend_cbcr(yh, cbh); 318 FX_SAFE_UINT32 safeSize = yw; 319 safeSize *= yh; 320 if (!safeSize.IsValid()) 321 return; 322 int* r = FX_Alloc(int, safeSize.ValueOrDie()); 323 int* g = FX_Alloc(int, safeSize.ValueOrDie()); 324 int* b = FX_Alloc(int, safeSize.ValueOrDie()); 325 int* d0 = r; 326 int* d1 = g; 327 int* d2 = b; 328 const int* y = img->comps[0].data; 329 const int* cb = img->comps[1].data; 330 const int* cr = img->comps[2].data; 331 if (!y || !cb || !cr) 332 return; 333 334 const int* ny = nullptr; 335 int* nr = nullptr; 336 int* ng = nullptr; 337 int* nb = nullptr; 338 OPJ_UINT32 i = 0; 339 OPJ_UINT32 j = 0; 340 for (i = 0; i < (yh & ~(OPJ_UINT32)1); i += 2) { 341 ny = y + yw; 342 nr = r + yw; 343 ng = g + yw; 344 nb = b + yw; 345 for (j = 0; j < (yw & ~(OPJ_UINT32)1); j += 2) { 346 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 347 ++y; 348 ++r; 349 ++g; 350 ++b; 351 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 352 ++y; 353 ++r; 354 ++g; 355 ++b; 356 sycc_to_rgb(offset, upb, *ny, *cb, *cr, nr, ng, nb); 357 ++ny; 358 ++nr; 359 ++ng; 360 ++nb; 361 sycc_to_rgb(offset, upb, *ny, *cb, *cr, nr, ng, nb); 362 ++ny; 363 ++nr; 364 ++ng; 365 ++nb; 366 ++cb; 367 ++cr; 368 } 369 if (j < yw) { 370 if (extw) { 371 --cb; 372 --cr; 373 } 374 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 375 ++y; 376 ++r; 377 ++g; 378 ++b; 379 sycc_to_rgb(offset, upb, *ny, *cb, *cr, nr, ng, nb); 380 ++ny; 381 ++nr; 382 ++ng; 383 ++nb; 384 ++cb; 385 ++cr; 386 } 387 y += yw; 388 r += yw; 389 g += yw; 390 b += yw; 391 } 392 if (i < yh) { 393 if (exth) { 394 cb -= cbw; 395 cr -= crw; 396 } 397 for (j = 0; j < (yw & ~(OPJ_UINT32)1); j += 2) { 398 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 399 ++y; 400 ++r; 401 ++g; 402 ++b; 403 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 404 ++y; 405 ++r; 406 ++g; 407 ++b; 408 ++cb; 409 ++cr; 410 } 411 if (j < yw) { 412 if (extw) { 413 --cb; 414 --cr; 415 } 416 sycc_to_rgb(offset, upb, *y, *cb, *cr, r, g, b); 417 } 418 } 419 420 FX_Free(img->comps[0].data); 421 img->comps[0].data = d0; 422 FX_Free(img->comps[1].data); 423 img->comps[1].data = d1; 424 FX_Free(img->comps[2].data); 425 img->comps[2].data = d2; 426 img->comps[1].w = yw; 427 img->comps[1].h = yh; 428 img->comps[2].w = yw; 429 img->comps[2].h = yh; 430 img->comps[1].w = yw; 431 img->comps[1].h = yh; 432 img->comps[2].w = yw; 433 img->comps[2].h = yh; 434 img->comps[1].dx = img->comps[0].dx; 435 img->comps[2].dx = img->comps[0].dx; 436 img->comps[1].dy = img->comps[0].dy; 437 img->comps[2].dy = img->comps[0].dy; 438 } 439 void color_sycc_to_rgb(opj_image_t* img) { 440 if (img->numcomps < 3) { 441 img->color_space = OPJ_CLRSPC_GRAY; 442 return; 443 } 444 if ((img->comps[0].dx == 1) && (img->comps[1].dx == 2) && 445 (img->comps[2].dx == 2) && (img->comps[0].dy == 1) && 446 (img->comps[1].dy == 2) && (img->comps[2].dy == 2)) { 447 sycc420_to_rgb(img); 448 } else if ((img->comps[0].dx == 1) && (img->comps[1].dx == 2) && 449 (img->comps[2].dx == 2) && (img->comps[0].dy == 1) && 450 (img->comps[1].dy == 1) && (img->comps[2].dy == 1)) { 451 sycc422_to_rgb(img); 452 } else if ((img->comps[0].dx == 1) && (img->comps[1].dx == 1) && 453 (img->comps[2].dx == 1) && (img->comps[0].dy == 1) && 454 (img->comps[1].dy == 1) && (img->comps[2].dy == 1)) { 455 sycc444_to_rgb(img); 456 } else { 457 return; 458 } 459 img->color_space = OPJ_CLRSPC_SRGB; 460 } 461 void color_apply_icc_profile(opj_image_t* image) { 462 cmsHPROFILE out_prof; 463 cmsUInt32Number in_type; 464 cmsUInt32Number out_type; 465 int* r; 466 int* g; 467 int* b; 468 int max; 469 cmsHPROFILE in_prof = 470 cmsOpenProfileFromMem(image->icc_profile_buf, image->icc_profile_len); 471 if (!in_prof) { 472 return; 473 } 474 cmsColorSpaceSignature out_space = cmsGetColorSpace(in_prof); 475 cmsUInt32Number intent = cmsGetHeaderRenderingIntent(in_prof); 476 int max_w = (int)image->comps[0].w; 477 int max_h = (int)image->comps[0].h; 478 int prec = (int)image->comps[0].prec; 479 OPJ_COLOR_SPACE oldspace = image->color_space; 480 if (out_space == cmsSigRgbData) { 481 if (prec <= 8) { 482 in_type = TYPE_RGB_8; 483 out_type = TYPE_RGB_8; 484 } else { 485 in_type = TYPE_RGB_16; 486 out_type = TYPE_RGB_16; 487 } 488 out_prof = cmsCreate_sRGBProfile(); 489 image->color_space = OPJ_CLRSPC_SRGB; 490 } else if (out_space == cmsSigGrayData) { 491 if (prec <= 8) { 492 in_type = TYPE_GRAY_8; 493 out_type = TYPE_RGB_8; 494 } else { 495 in_type = TYPE_GRAY_16; 496 out_type = TYPE_RGB_16; 497 } 498 out_prof = cmsCreate_sRGBProfile(); 499 image->color_space = OPJ_CLRSPC_SRGB; 500 } else if (out_space == cmsSigYCbCrData) { 501 in_type = TYPE_YCbCr_16; 502 out_type = TYPE_RGB_16; 503 out_prof = cmsCreate_sRGBProfile(); 504 image->color_space = OPJ_CLRSPC_SRGB; 505 } else { 506 return; 507 } 508 cmsHTRANSFORM transform = 509 cmsCreateTransform(in_prof, in_type, out_prof, out_type, intent, 0); 510 cmsCloseProfile(in_prof); 511 cmsCloseProfile(out_prof); 512 if (!transform) { 513 image->color_space = oldspace; 514 return; 515 } 516 if (image->numcomps > 2) { 517 if (prec <= 8) { 518 unsigned char *inbuf, *outbuf, *in, *out; 519 max = max_w * max_h; 520 cmsUInt32Number nr_samples = max * 3 * sizeof(unsigned char); 521 in = inbuf = FX_Alloc(unsigned char, nr_samples); 522 out = outbuf = FX_Alloc(unsigned char, nr_samples); 523 r = image->comps[0].data; 524 g = image->comps[1].data; 525 b = image->comps[2].data; 526 for (int i = 0; i < max; ++i) { 527 *in++ = (unsigned char)*r++; 528 *in++ = (unsigned char)*g++; 529 *in++ = (unsigned char)*b++; 530 } 531 cmsDoTransform(transform, inbuf, outbuf, (cmsUInt32Number)max); 532 r = image->comps[0].data; 533 g = image->comps[1].data; 534 b = image->comps[2].data; 535 for (int i = 0; i < max; ++i) { 536 *r++ = (int)*out++; 537 *g++ = (int)*out++; 538 *b++ = (int)*out++; 539 } 540 FX_Free(inbuf); 541 FX_Free(outbuf); 542 } else { 543 unsigned short *inbuf, *outbuf, *in, *out; 544 max = max_w * max_h; 545 cmsUInt32Number nr_samples = max * 3 * sizeof(unsigned short); 546 in = inbuf = FX_Alloc(unsigned short, nr_samples); 547 out = outbuf = FX_Alloc(unsigned short, nr_samples); 548 r = image->comps[0].data; 549 g = image->comps[1].data; 550 b = image->comps[2].data; 551 for (int i = 0; i < max; ++i) { 552 *in++ = (unsigned short)*r++; 553 *in++ = (unsigned short)*g++; 554 *in++ = (unsigned short)*b++; 555 } 556 cmsDoTransform(transform, inbuf, outbuf, (cmsUInt32Number)max); 557 r = image->comps[0].data; 558 g = image->comps[1].data; 559 b = image->comps[2].data; 560 for (int i = 0; i < max; ++i) { 561 *r++ = (int)*out++; 562 *g++ = (int)*out++; 563 *b++ = (int)*out++; 564 } 565 FX_Free(inbuf); 566 FX_Free(outbuf); 567 } 568 } else { 569 unsigned char *in, *inbuf, *out, *outbuf; 570 max = max_w * max_h; 571 cmsUInt32Number nr_samples = 572 (cmsUInt32Number)max * 3 * sizeof(unsigned char); 573 in = inbuf = FX_Alloc(unsigned char, nr_samples); 574 out = outbuf = FX_Alloc(unsigned char, nr_samples); 575 image->comps = (opj_image_comp_t*)realloc( 576 image->comps, (image->numcomps + 2) * sizeof(opj_image_comp_t)); 577 if (image->numcomps == 2) { 578 image->comps[3] = image->comps[1]; 579 } 580 image->comps[1] = image->comps[0]; 581 image->comps[2] = image->comps[0]; 582 image->comps[1].data = FX_Alloc(int, (size_t)max); 583 FXSYS_memset(image->comps[1].data, 0, sizeof(int) * (size_t)max); 584 image->comps[2].data = FX_Alloc(int, (size_t)max); 585 FXSYS_memset(image->comps[2].data, 0, sizeof(int) * (size_t)max); 586 image->numcomps += 2; 587 r = image->comps[0].data; 588 for (int i = 0; i < max; ++i) { 589 *in++ = (unsigned char)*r++; 590 } 591 cmsDoTransform(transform, inbuf, outbuf, (cmsUInt32Number)max); 592 r = image->comps[0].data; 593 g = image->comps[1].data; 594 b = image->comps[2].data; 595 for (int i = 0; i < max; ++i) { 596 *r++ = (int)*out++; 597 *g++ = (int)*out++; 598 *b++ = (int)*out++; 599 } 600 FX_Free(inbuf); 601 FX_Free(outbuf); 602 } 603 cmsDeleteTransform(transform); 604 } 605 void color_apply_conversion(opj_image_t* image) { 606 int* row; 607 int enumcs, numcomps; 608 numcomps = image->numcomps; 609 if (numcomps < 3) { 610 return; 611 } 612 row = (int*)image->icc_profile_buf; 613 enumcs = row[0]; 614 if (enumcs == 14) { 615 int *L, *a, *b, *red, *green, *blue, *src0, *src1, *src2; 616 double rl, ol, ra, oa, rb, ob, prec0, prec1, prec2; 617 double minL, maxL, mina, maxa, minb, maxb; 618 unsigned int default_type; 619 unsigned int i, max; 620 cmsHPROFILE in, out; 621 cmsHTRANSFORM transform; 622 cmsUInt16Number RGB[3]; 623 cmsCIELab Lab; 624 in = cmsCreateLab4Profile(nullptr); 625 out = cmsCreate_sRGBProfile(); 626 transform = cmsCreateTransform(in, TYPE_Lab_DBL, out, TYPE_RGB_16, 627 INTENT_PERCEPTUAL, 0); 628 cmsCloseProfile(in); 629 cmsCloseProfile(out); 630 if (!transform) { 631 return; 632 } 633 prec0 = (double)image->comps[0].prec; 634 prec1 = (double)image->comps[1].prec; 635 prec2 = (double)image->comps[2].prec; 636 default_type = row[1]; 637 if (default_type == 0x44454600) { 638 rl = 100; 639 ra = 170; 640 rb = 200; 641 ol = 0; 642 oa = pow(2, prec1 - 1); 643 ob = pow(2, prec2 - 2) + pow(2, prec2 - 3); 644 } else { 645 rl = row[2]; 646 ra = row[4]; 647 rb = row[6]; 648 ol = row[3]; 649 oa = row[5]; 650 ob = row[7]; 651 } 652 L = src0 = image->comps[0].data; 653 a = src1 = image->comps[1].data; 654 b = src2 = image->comps[2].data; 655 max = image->comps[0].w * image->comps[0].h; 656 red = FX_Alloc(int, max); 657 image->comps[0].data = red; 658 green = FX_Alloc(int, max); 659 image->comps[1].data = green; 660 blue = FX_Alloc(int, max); 661 image->comps[2].data = blue; 662 minL = -(rl * ol) / (pow(2, prec0) - 1); 663 maxL = minL + rl; 664 mina = -(ra * oa) / (pow(2, prec1) - 1); 665 maxa = mina + ra; 666 minb = -(rb * ob) / (pow(2, prec2) - 1); 667 maxb = minb + rb; 668 for (i = 0; i < max; ++i) { 669 Lab.L = minL + (double)(*L) * (maxL - minL) / (pow(2, prec0) - 1); 670 ++L; 671 Lab.a = mina + (double)(*a) * (maxa - mina) / (pow(2, prec1) - 1); 672 ++a; 673 Lab.b = minb + (double)(*b) * (maxb - minb) / (pow(2, prec2) - 1); 674 ++b; 675 cmsDoTransform(transform, &Lab, RGB, 1); 676 *red++ = RGB[0]; 677 *green++ = RGB[1]; 678 *blue++ = RGB[2]; 679 } 680 cmsDeleteTransform(transform); 681 FX_Free(src0); 682 FX_Free(src1); 683 FX_Free(src2); 684 image->color_space = OPJ_CLRSPC_SRGB; 685 image->comps[0].prec = 16; 686 image->comps[1].prec = 16; 687 image->comps[2].prec = 16; 688 return; 689 } 690 } 691 class CJPX_Decoder { 692 public: 693 explicit CJPX_Decoder(CPDF_ColorSpace* cs); 694 ~CJPX_Decoder(); 695 bool Init(const unsigned char* src_data, uint32_t src_size); 696 void GetInfo(uint32_t* width, uint32_t* height, uint32_t* components); 697 bool Decode(uint8_t* dest_buf, 698 int pitch, 699 const std::vector<uint8_t>& offsets); 700 701 private: 702 const uint8_t* m_SrcData; 703 uint32_t m_SrcSize; 704 opj_image_t* image; 705 opj_codec_t* l_codec; 706 opj_stream_t* l_stream; 707 const CPDF_ColorSpace* const m_ColorSpace; 708 }; 709 710 CJPX_Decoder::CJPX_Decoder(CPDF_ColorSpace* cs) 711 : image(nullptr), l_codec(nullptr), l_stream(nullptr), m_ColorSpace(cs) {} 712 713 CJPX_Decoder::~CJPX_Decoder() { 714 if (l_codec) { 715 opj_destroy_codec(l_codec); 716 } 717 if (l_stream) { 718 opj_stream_destroy(l_stream); 719 } 720 if (image) { 721 opj_image_destroy(image); 722 } 723 } 724 725 bool CJPX_Decoder::Init(const unsigned char* src_data, uint32_t src_size) { 726 static const unsigned char szJP2Header[] = { 727 0x00, 0x00, 0x00, 0x0c, 0x6a, 0x50, 0x20, 0x20, 0x0d, 0x0a, 0x87, 0x0a}; 728 if (!src_data || src_size < sizeof(szJP2Header)) 729 return false; 730 731 image = nullptr; 732 m_SrcData = src_data; 733 m_SrcSize = src_size; 734 DecodeData srcData(const_cast<unsigned char*>(src_data), src_size); 735 l_stream = fx_opj_stream_create_memory_stream(&srcData, 736 OPJ_J2K_STREAM_CHUNK_SIZE, 1); 737 if (!l_stream) { 738 return false; 739 } 740 opj_dparameters_t parameters; 741 opj_set_default_decoder_parameters(¶meters); 742 parameters.decod_format = 0; 743 parameters.cod_format = 3; 744 if (FXSYS_memcmp(m_SrcData, szJP2Header, sizeof(szJP2Header)) == 0) { 745 l_codec = opj_create_decompress(OPJ_CODEC_JP2); 746 parameters.decod_format = 1; 747 } else { 748 l_codec = opj_create_decompress(OPJ_CODEC_J2K); 749 } 750 if (!l_codec) { 751 return false; 752 } 753 if (m_ColorSpace && m_ColorSpace->GetFamily() == PDFCS_INDEXED) 754 parameters.flags |= OPJ_DPARAMETERS_IGNORE_PCLR_CMAP_CDEF_FLAG; 755 opj_set_info_handler(l_codec, fx_info_callback, 00); 756 opj_set_warning_handler(l_codec, fx_warning_callback, 00); 757 opj_set_error_handler(l_codec, fx_error_callback, 00); 758 if (!opj_setup_decoder(l_codec, ¶meters)) { 759 return false; 760 } 761 if (!opj_read_header(l_stream, l_codec, &image)) { 762 image = nullptr; 763 return false; 764 } 765 image->pdfium_use_colorspace = !!m_ColorSpace; 766 767 if (!parameters.nb_tile_to_decode) { 768 if (!opj_set_decode_area(l_codec, image, parameters.DA_x0, parameters.DA_y0, 769 parameters.DA_x1, parameters.DA_y1)) { 770 opj_image_destroy(image); 771 image = nullptr; 772 return false; 773 } 774 if (!(opj_decode(l_codec, l_stream, image) && 775 opj_end_decompress(l_codec, l_stream))) { 776 opj_image_destroy(image); 777 image = nullptr; 778 return false; 779 } 780 } else { 781 if (!opj_get_decoded_tile(l_codec, l_stream, image, 782 parameters.tile_index)) { 783 return false; 784 } 785 } 786 opj_stream_destroy(l_stream); 787 l_stream = nullptr; 788 if (image->color_space != OPJ_CLRSPC_SYCC && image->numcomps == 3 && 789 image->comps[0].dx == image->comps[0].dy && image->comps[1].dx != 1) { 790 image->color_space = OPJ_CLRSPC_SYCC; 791 } else if (image->numcomps <= 2) { 792 image->color_space = OPJ_CLRSPC_GRAY; 793 } 794 if (image->color_space == OPJ_CLRSPC_SYCC) { 795 color_sycc_to_rgb(image); 796 } 797 if (image->icc_profile_buf) { 798 FX_Free(image->icc_profile_buf); 799 image->icc_profile_buf = nullptr; 800 image->icc_profile_len = 0; 801 } 802 if (!image) { 803 return false; 804 } 805 return true; 806 } 807 808 void CJPX_Decoder::GetInfo(uint32_t* width, 809 uint32_t* height, 810 uint32_t* components) { 811 *width = (uint32_t)image->x1; 812 *height = (uint32_t)image->y1; 813 *components = (uint32_t)image->numcomps; 814 } 815 816 bool CJPX_Decoder::Decode(uint8_t* dest_buf, 817 int pitch, 818 const std::vector<uint8_t>& offsets) { 819 if (image->comps[0].w != image->x1 || image->comps[0].h != image->y1) 820 return false; 821 822 if (pitch<(int)(image->comps[0].w * 8 * image->numcomps + 31)>> 5 << 2) 823 return false; 824 825 FXSYS_memset(dest_buf, 0xff, image->y1 * pitch); 826 std::vector<uint8_t*> channel_bufs(image->numcomps); 827 std::vector<int> adjust_comps(image->numcomps); 828 for (uint32_t i = 0; i < image->numcomps; i++) { 829 channel_bufs[i] = dest_buf + offsets[i]; 830 adjust_comps[i] = image->comps[i].prec - 8; 831 if (i > 0) { 832 if (image->comps[i].dx != image->comps[i - 1].dx || 833 image->comps[i].dy != image->comps[i - 1].dy || 834 image->comps[i].prec != image->comps[i - 1].prec) { 835 return false; 836 } 837 } 838 } 839 int width = image->comps[0].w; 840 int height = image->comps[0].h; 841 for (uint32_t channel = 0; channel < image->numcomps; ++channel) { 842 uint8_t* pChannel = channel_bufs[channel]; 843 if (adjust_comps[channel] < 0) { 844 for (int row = 0; row < height; ++row) { 845 uint8_t* pScanline = pChannel + row * pitch; 846 for (int col = 0; col < width; ++col) { 847 uint8_t* pPixel = pScanline + col * image->numcomps; 848 if (!image->comps[channel].data) 849 continue; 850 851 int src = image->comps[channel].data[row * width + col]; 852 src += image->comps[channel].sgnd 853 ? 1 << (image->comps[channel].prec - 1) 854 : 0; 855 if (adjust_comps[channel] > 0) { 856 *pPixel = 0; 857 } else { 858 *pPixel = (uint8_t)(src << -adjust_comps[channel]); 859 } 860 } 861 } 862 } else { 863 for (int row = 0; row < height; ++row) { 864 uint8_t* pScanline = pChannel + row * pitch; 865 for (int col = 0; col < width; ++col) { 866 uint8_t* pPixel = pScanline + col * image->numcomps; 867 if (!image->comps[channel].data) 868 continue; 869 870 int src = image->comps[channel].data[row * width + col]; 871 src += image->comps[channel].sgnd 872 ? 1 << (image->comps[channel].prec - 1) 873 : 0; 874 if (adjust_comps[channel] - 1 < 0) { 875 *pPixel = (uint8_t)((src >> adjust_comps[channel])); 876 } else { 877 int tmpPixel = (src >> adjust_comps[channel]) + 878 ((src >> (adjust_comps[channel] - 1)) % 2); 879 if (tmpPixel > 255) { 880 tmpPixel = 255; 881 } else if (tmpPixel < 0) { 882 tmpPixel = 0; 883 } 884 *pPixel = (uint8_t)tmpPixel; 885 } 886 } 887 } 888 } 889 } 890 return true; 891 } 892 893 CCodec_JpxModule::CCodec_JpxModule() {} 894 CCodec_JpxModule::~CCodec_JpxModule() {} 895 896 CJPX_Decoder* CCodec_JpxModule::CreateDecoder(const uint8_t* src_buf, 897 uint32_t src_size, 898 CPDF_ColorSpace* cs) { 899 std::unique_ptr<CJPX_Decoder> decoder(new CJPX_Decoder(cs)); 900 return decoder->Init(src_buf, src_size) ? decoder.release() : nullptr; 901 } 902 903 void CCodec_JpxModule::GetImageInfo(CJPX_Decoder* pDecoder, 904 uint32_t* width, 905 uint32_t* height, 906 uint32_t* components) { 907 pDecoder->GetInfo(width, height, components); 908 } 909 910 bool CCodec_JpxModule::Decode(CJPX_Decoder* pDecoder, 911 uint8_t* dest_data, 912 int pitch, 913 const std::vector<uint8_t>& offsets) { 914 return pDecoder->Decode(dest_data, pitch, offsets); 915 } 916 917 void CCodec_JpxModule::DestroyDecoder(CJPX_Decoder* pDecoder) { 918 delete pDecoder; 919 } 920