1 /* 2 * Copyright (c) 2000, 2018, Oracle and/or its affiliates. All rights reserved. 3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. 4 * 5 * This code is free software; you can redistribute it and/or modify it 6 * under the terms of the GNU General Public License version 2 only, as 7 * published by the Free Software Foundation. Oracle designates this 8 * particular file as subject to the "Classpath" exception as provided 9 * by Oracle in the LICENSE file that accompanied this code. 10 * 11 * This code is distributed in the hope that it will be useful, but WITHOUT 12 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 13 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 14 * version 2 for more details (a copy is included in the LICENSE file that 15 * accompanied this code). 16 * 17 * You should have received a copy of the GNU General Public License version 18 * 2 along with this work; if not, write to the Free Software Foundation, 19 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. 20 * 21 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA 22 * or visit www.oracle.com if you need additional information or have any 23 * questions. 24 */ 25 26 package com.sun.imageio.plugins.png; 27 28 import java.awt.Point; 29 import java.awt.Rectangle; 30 import java.awt.color.ColorSpace; 31 import java.awt.image.BufferedImage; 32 import java.awt.image.DataBuffer; 33 import java.awt.image.DataBufferByte; 34 import java.awt.image.DataBufferUShort; 35 import java.awt.image.Raster; 36 import java.awt.image.WritableRaster; 37 import java.io.BufferedInputStream; 38 import java.io.ByteArrayInputStream; 39 import java.io.DataInputStream; 40 import java.io.EOFException; 41 import java.io.InputStream; 42 import java.io.IOException; 43 import java.io.SequenceInputStream; 44 import java.util.ArrayList; 45 import java.util.Arrays; 46 import java.util.Enumeration; 47 import java.util.Iterator; 48 import java.util.zip.Inflater; 49 import java.util.zip.InflaterInputStream; 50 import javax.imageio.IIOException; 51 import javax.imageio.ImageReader; 52 import javax.imageio.ImageReadParam; 53 import javax.imageio.ImageTypeSpecifier; 54 import javax.imageio.metadata.IIOMetadata; 55 import javax.imageio.spi.ImageReaderSpi; 56 import javax.imageio.stream.ImageInputStream; 57 import com.sun.imageio.plugins.common.InputStreamAdapter; 58 import com.sun.imageio.plugins.common.ReaderUtil; 59 import com.sun.imageio.plugins.common.SubImageInputStream; 60 import java.io.ByteArrayOutputStream; 61 import sun.awt.image.ByteInterleavedRaster; 62 63 class PNGImageDataEnumeration implements Enumeration<InputStream> { 64 65 boolean firstTime = true; 66 ImageInputStream stream; 67 int length; 68 69 public PNGImageDataEnumeration(ImageInputStream stream) 70 throws IOException { 71 this.stream = stream; 72 this.length = stream.readInt(); 73 int type = stream.readInt(); // skip chunk type 74 } 75 76 public InputStream nextElement() { 77 try { 78 firstTime = false; 79 ImageInputStream iis = new SubImageInputStream(stream, length); 80 return new InputStreamAdapter(iis); 81 } catch (IOException e) { 82 return null; 83 } 84 } 85 86 public boolean hasMoreElements() { 87 if (firstTime) { 88 return true; 89 } 90 91 try { 92 int crc = stream.readInt(); 93 this.length = stream.readInt(); 94 int type = stream.readInt(); 95 if (type == PNGImageReader.IDAT_TYPE) { 96 return true; 97 } else { 98 return false; 99 } 100 } catch (IOException e) { 101 return false; 102 } 103 } 104 } 105 106 public class PNGImageReader extends ImageReader { 107 108 /* 109 * Note: The following chunk type constants are autogenerated. Each 110 * one is derived from the ASCII values of its 4-character name. For 111 * example, IHDR_TYPE is calculated as follows: 112 * ('I' << 24) | ('H' << 16) | ('D' << 8) | 'R' 113 */ 114 115 // Critical chunks 116 static final int IHDR_TYPE = 0x49484452; 117 static final int PLTE_TYPE = 0x504c5445; 118 static final int IDAT_TYPE = 0x49444154; 119 static final int IEND_TYPE = 0x49454e44; 120 121 // Ancillary chunks 122 static final int bKGD_TYPE = 0x624b4744; 123 static final int cHRM_TYPE = 0x6348524d; 124 static final int gAMA_TYPE = 0x67414d41; 125 static final int hIST_TYPE = 0x68495354; 126 static final int iCCP_TYPE = 0x69434350; 127 static final int iTXt_TYPE = 0x69545874; 128 static final int pHYs_TYPE = 0x70485973; 129 static final int sBIT_TYPE = 0x73424954; 130 static final int sPLT_TYPE = 0x73504c54; 131 static final int sRGB_TYPE = 0x73524742; 132 static final int tEXt_TYPE = 0x74455874; 133 static final int tIME_TYPE = 0x74494d45; 134 static final int tRNS_TYPE = 0x74524e53; 135 static final int zTXt_TYPE = 0x7a545874; 136 137 static final int PNG_COLOR_GRAY = 0; 138 static final int PNG_COLOR_RGB = 2; 139 static final int PNG_COLOR_PALETTE = 3; 140 static final int PNG_COLOR_GRAY_ALPHA = 4; 141 static final int PNG_COLOR_RGB_ALPHA = 6; 142 143 // The number of bands by PNG color type 144 static final int[] inputBandsForColorType = { 145 1, // gray 146 -1, // unused 147 3, // rgb 148 1, // palette 149 2, // gray + alpha 150 -1, // unused 151 4 // rgb + alpha 152 }; 153 154 static final int PNG_FILTER_NONE = 0; 155 static final int PNG_FILTER_SUB = 1; 156 static final int PNG_FILTER_UP = 2; 157 static final int PNG_FILTER_AVERAGE = 3; 158 static final int PNG_FILTER_PAETH = 4; 159 160 static final int[] adam7XOffset = { 0, 4, 0, 2, 0, 1, 0 }; 161 static final int[] adam7YOffset = { 0, 0, 4, 0, 2, 0, 1 }; 162 static final int[] adam7XSubsampling = { 8, 8, 4, 4, 2, 2, 1, 1 }; 163 static final int[] adam7YSubsampling = { 8, 8, 8, 4, 4, 2, 2, 1 }; 164 165 private static final boolean debug = true; 166 167 ImageInputStream stream = null; 168 169 boolean gotHeader = false; 170 boolean gotMetadata = false; 171 172 ImageReadParam lastParam = null; 173 174 long imageStartPosition = -1L; 175 176 Rectangle sourceRegion = null; 177 int sourceXSubsampling = -1; 178 int sourceYSubsampling = -1; 179 int sourceMinProgressivePass = 0; 180 int sourceMaxProgressivePass = 6; 181 int[] sourceBands = null; 182 int[] destinationBands = null; 183 Point destinationOffset = new Point(0, 0); 184 185 PNGMetadata metadata = new PNGMetadata(); 186 187 DataInputStream pixelStream = null; 188 189 BufferedImage theImage = null; 190 191 // The number of source pixels processed 192 int pixelsDone = 0; 193 194 // The total number of pixels in the source image 195 int totalPixels; 196 197 public PNGImageReader(ImageReaderSpi originatingProvider) { 198 super(originatingProvider); 199 } 200 201 public void setInput(Object input, 202 boolean seekForwardOnly, 203 boolean ignoreMetadata) { 204 super.setInput(input, seekForwardOnly, ignoreMetadata); 205 this.stream = (ImageInputStream)input; // Always works 206 207 // Clear all values based on the previous stream contents 208 resetStreamSettings(); 209 } 210 211 private String readNullTerminatedString(String charset, int maxLen) throws IOException { 212 ByteArrayOutputStream baos = new ByteArrayOutputStream(); 213 int b; 214 int count = 0; 215 while ((maxLen > count++) && ((b = stream.read()) != 0)) { 216 if (b == -1) throw new EOFException(); 217 baos.write(b); 218 } 219 return new String(baos.toByteArray(), charset); 220 } 221 222 private void readHeader() throws IIOException { 223 if (gotHeader) { 224 return; 225 } 226 if (stream == null) { 227 throw new IllegalStateException("Input source not set!"); 228 } 229 230 try { 231 byte[] signature = new byte[8]; 232 stream.readFully(signature); 233 234 if (signature[0] != (byte)137 || 235 signature[1] != (byte)80 || 236 signature[2] != (byte)78 || 237 signature[3] != (byte)71 || 238 signature[4] != (byte)13 || 239 signature[5] != (byte)10 || 240 signature[6] != (byte)26 || 241 signature[7] != (byte)10) { 242 throw new IIOException("Bad PNG signature!"); 243 } 244 245 int IHDR_length = stream.readInt(); 246 if (IHDR_length != 13) { 247 throw new IIOException("Bad length for IHDR chunk!"); 248 } 249 int IHDR_type = stream.readInt(); 250 if (IHDR_type != IHDR_TYPE) { 251 throw new IIOException("Bad type for IHDR chunk!"); 252 } 253 254 this.metadata = new PNGMetadata(); 255 256 int width = stream.readInt(); 257 int height = stream.readInt(); 258 259 // Re-use signature array to bulk-read these unsigned byte values 260 stream.readFully(signature, 0, 5); 261 int bitDepth = signature[0] & 0xff; 262 int colorType = signature[1] & 0xff; 263 int compressionMethod = signature[2] & 0xff; 264 int filterMethod = signature[3] & 0xff; 265 int interlaceMethod = signature[4] & 0xff; 266 267 // Skip IHDR CRC 268 stream.skipBytes(4); 269 270 stream.flushBefore(stream.getStreamPosition()); 271 272 if (width <= 0) { 273 throw new IIOException("Image width <= 0!"); 274 } 275 if (height <= 0) { 276 throw new IIOException("Image height <= 0!"); 277 } 278 if (bitDepth != 1 && bitDepth != 2 && bitDepth != 4 && 279 bitDepth != 8 && bitDepth != 16) { 280 throw new IIOException("Bit depth must be 1, 2, 4, 8, or 16!"); 281 } 282 if (colorType != 0 && colorType != 2 && colorType != 3 && 283 colorType != 4 && colorType != 6) { 284 throw new IIOException("Color type must be 0, 2, 3, 4, or 6!"); 285 } 286 if (colorType == PNG_COLOR_PALETTE && bitDepth == 16) { 287 throw new IIOException("Bad color type/bit depth combination!"); 288 } 289 if ((colorType == PNG_COLOR_RGB || 290 colorType == PNG_COLOR_RGB_ALPHA || 291 colorType == PNG_COLOR_GRAY_ALPHA) && 292 (bitDepth != 8 && bitDepth != 16)) { 293 throw new IIOException("Bad color type/bit depth combination!"); 294 } 295 if (compressionMethod != 0) { 296 throw new IIOException("Unknown compression method (not 0)!"); 297 } 298 if (filterMethod != 0) { 299 throw new IIOException("Unknown filter method (not 0)!"); 300 } 301 if (interlaceMethod != 0 && interlaceMethod != 1) { 302 throw new IIOException("Unknown interlace method (not 0 or 1)!"); 303 } 304 305 metadata.IHDR_present = true; 306 metadata.IHDR_width = width; 307 metadata.IHDR_height = height; 308 metadata.IHDR_bitDepth = bitDepth; 309 metadata.IHDR_colorType = colorType; 310 metadata.IHDR_compressionMethod = compressionMethod; 311 metadata.IHDR_filterMethod = filterMethod; 312 metadata.IHDR_interlaceMethod = interlaceMethod; 313 gotHeader = true; 314 } catch (IOException e) { 315 throw new IIOException("I/O error reading PNG header!", e); 316 } 317 } 318 319 private void parse_PLTE_chunk(int chunkLength) throws IOException { 320 if (metadata.PLTE_present) { 321 processWarningOccurred( 322 "A PNG image may not contain more than one PLTE chunk.\n" + 323 "The chunk wil be ignored."); 324 return; 325 } else if (metadata.IHDR_colorType == PNG_COLOR_GRAY || 326 metadata.IHDR_colorType == PNG_COLOR_GRAY_ALPHA) { 327 processWarningOccurred( 328 "A PNG gray or gray alpha image cannot have a PLTE chunk.\n" + 329 "The chunk wil be ignored."); 330 return; 331 } 332 333 byte[] palette = new byte[chunkLength]; 334 stream.readFully(palette); 335 336 int numEntries = chunkLength/3; 337 if (metadata.IHDR_colorType == PNG_COLOR_PALETTE) { 338 int maxEntries = 1 << metadata.IHDR_bitDepth; 339 if (numEntries > maxEntries) { 340 processWarningOccurred( 341 "PLTE chunk contains too many entries for bit depth, ignoring extras."); 342 numEntries = maxEntries; 343 } 344 numEntries = Math.min(numEntries, maxEntries); 345 } 346 347 // Round array sizes up to 2^2^n 348 int paletteEntries; 349 if (numEntries > 16) { 350 paletteEntries = 256; 351 } else if (numEntries > 4) { 352 paletteEntries = 16; 353 } else if (numEntries > 2) { 354 paletteEntries = 4; 355 } else { 356 paletteEntries = 2; 357 } 358 359 metadata.PLTE_present = true; 360 metadata.PLTE_red = new byte[paletteEntries]; 361 metadata.PLTE_green = new byte[paletteEntries]; 362 metadata.PLTE_blue = new byte[paletteEntries]; 363 364 int index = 0; 365 for (int i = 0; i < numEntries; i++) { 366 metadata.PLTE_red[i] = palette[index++]; 367 metadata.PLTE_green[i] = palette[index++]; 368 metadata.PLTE_blue[i] = palette[index++]; 369 } 370 } 371 372 private void parse_bKGD_chunk() throws IOException { 373 if (metadata.IHDR_colorType == PNG_COLOR_PALETTE) { 374 metadata.bKGD_colorType = PNG_COLOR_PALETTE; 375 metadata.bKGD_index = stream.readUnsignedByte(); 376 } else if (metadata.IHDR_colorType == PNG_COLOR_GRAY || 377 metadata.IHDR_colorType == PNG_COLOR_GRAY_ALPHA) { 378 metadata.bKGD_colorType = PNG_COLOR_GRAY; 379 metadata.bKGD_gray = stream.readUnsignedShort(); 380 } else { // RGB or RGB_ALPHA 381 metadata.bKGD_colorType = PNG_COLOR_RGB; 382 metadata.bKGD_red = stream.readUnsignedShort(); 383 metadata.bKGD_green = stream.readUnsignedShort(); 384 metadata.bKGD_blue = stream.readUnsignedShort(); 385 } 386 387 metadata.bKGD_present = true; 388 } 389 390 private void parse_cHRM_chunk() throws IOException { 391 metadata.cHRM_whitePointX = stream.readInt(); 392 metadata.cHRM_whitePointY = stream.readInt(); 393 metadata.cHRM_redX = stream.readInt(); 394 metadata.cHRM_redY = stream.readInt(); 395 metadata.cHRM_greenX = stream.readInt(); 396 metadata.cHRM_greenY = stream.readInt(); 397 metadata.cHRM_blueX = stream.readInt(); 398 metadata.cHRM_blueY = stream.readInt(); 399 400 metadata.cHRM_present = true; 401 } 402 403 private void parse_gAMA_chunk() throws IOException { 404 int gamma = stream.readInt(); 405 metadata.gAMA_gamma = gamma; 406 407 metadata.gAMA_present = true; 408 } 409 410 private void parse_hIST_chunk(int chunkLength) throws IOException, 411 IIOException 412 { 413 if (!metadata.PLTE_present) { 414 throw new IIOException("hIST chunk without prior PLTE chunk!"); 415 } 416 417 /* According to PNG specification length of 418 * hIST chunk is specified in bytes and 419 * hIST chunk consists of 2 byte elements 420 * (so we expect length is even). 421 */ 422 metadata.hIST_histogram = new char[chunkLength/2]; 423 stream.readFully(metadata.hIST_histogram, 424 0, metadata.hIST_histogram.length); 425 426 metadata.hIST_present = true; 427 } 428 429 private void parse_iCCP_chunk(int chunkLength) throws IOException { 430 String keyword = readNullTerminatedString("ISO-8859-1", 80); 431 int compressedProfileLength = chunkLength - keyword.length() - 2; 432 if (compressedProfileLength <= 0) { 433 throw new IIOException("iCCP chunk length is not proper"); 434 } 435 metadata.iCCP_profileName = keyword; 436 437 metadata.iCCP_compressionMethod = stream.readUnsignedByte(); 438 439 byte[] compressedProfile = 440 new byte[compressedProfileLength]; 441 stream.readFully(compressedProfile); 442 metadata.iCCP_compressedProfile = compressedProfile; 443 444 metadata.iCCP_present = true; 445 } 446 447 private void parse_iTXt_chunk(int chunkLength) throws IOException { 448 long chunkStart = stream.getStreamPosition(); 449 450 String keyword = readNullTerminatedString("ISO-8859-1", 80); 451 metadata.iTXt_keyword.add(keyword); 452 453 int compressionFlag = stream.readUnsignedByte(); 454 metadata.iTXt_compressionFlag.add(Boolean.valueOf(compressionFlag == 1)); 455 456 int compressionMethod = stream.readUnsignedByte(); 457 metadata.iTXt_compressionMethod.add(Integer.valueOf(compressionMethod)); 458 459 String languageTag = readNullTerminatedString("UTF8", 80); 460 metadata.iTXt_languageTag.add(languageTag); 461 462 long pos = stream.getStreamPosition(); 463 int maxLen = (int)(chunkStart + chunkLength - pos); 464 String translatedKeyword = 465 readNullTerminatedString("UTF8", maxLen); 466 metadata.iTXt_translatedKeyword.add(translatedKeyword); 467 468 String text; 469 pos = stream.getStreamPosition(); 470 int textLength = (int)(chunkStart + chunkLength - pos); 471 if (textLength <= 0) { 472 throw new IIOException("iTXt chunk length is not proper"); 473 } 474 byte[] b = new byte[textLength]; 475 stream.readFully(b); 476 477 if (compressionFlag == 1) { // Decompress the text 478 text = new String(inflate(b), "UTF8"); 479 } else { 480 text = new String(b, "UTF8"); 481 } 482 metadata.iTXt_text.add(text); 483 484 // Check if the text chunk contains image creation time 485 if (keyword.equals(PNGMetadata.tEXt_creationTimeKey)) { 486 // Update Standard/Document/ImageCreationTime from text chunk 487 int index = metadata.iTXt_text.size() - 1; 488 metadata.decodeImageCreationTimeFromTextChunk( 489 metadata.iTXt_text.listIterator(index)); 490 } 491 } 492 493 private void parse_pHYs_chunk() throws IOException { 494 metadata.pHYs_pixelsPerUnitXAxis = stream.readInt(); 495 metadata.pHYs_pixelsPerUnitYAxis = stream.readInt(); 496 metadata.pHYs_unitSpecifier = stream.readUnsignedByte(); 497 498 metadata.pHYs_present = true; 499 } 500 501 private void parse_sBIT_chunk() throws IOException { 502 int colorType = metadata.IHDR_colorType; 503 if (colorType == PNG_COLOR_GRAY || 504 colorType == PNG_COLOR_GRAY_ALPHA) { 505 metadata.sBIT_grayBits = stream.readUnsignedByte(); 506 } else if (colorType == PNG_COLOR_RGB || 507 colorType == PNG_COLOR_PALETTE || 508 colorType == PNG_COLOR_RGB_ALPHA) { 509 metadata.sBIT_redBits = stream.readUnsignedByte(); 510 metadata.sBIT_greenBits = stream.readUnsignedByte(); 511 metadata.sBIT_blueBits = stream.readUnsignedByte(); 512 } 513 514 if (colorType == PNG_COLOR_GRAY_ALPHA || 515 colorType == PNG_COLOR_RGB_ALPHA) { 516 metadata.sBIT_alphaBits = stream.readUnsignedByte(); 517 } 518 519 metadata.sBIT_colorType = colorType; 520 metadata.sBIT_present = true; 521 } 522 523 private void parse_sPLT_chunk(int chunkLength) 524 throws IOException, IIOException { 525 metadata.sPLT_paletteName = readNullTerminatedString("ISO-8859-1", 80); 526 int remainingChunkLength = chunkLength - 527 (metadata.sPLT_paletteName.length() + 1); 528 if (remainingChunkLength <= 0) { 529 throw new IIOException("sPLT chunk length is not proper"); 530 } 531 532 int sampleDepth = stream.readUnsignedByte(); 533 metadata.sPLT_sampleDepth = sampleDepth; 534 535 int numEntries = remainingChunkLength/(4*(sampleDepth/8) + 2); 536 metadata.sPLT_red = new int[numEntries]; 537 metadata.sPLT_green = new int[numEntries]; 538 metadata.sPLT_blue = new int[numEntries]; 539 metadata.sPLT_alpha = new int[numEntries]; 540 metadata.sPLT_frequency = new int[numEntries]; 541 542 if (sampleDepth == 8) { 543 for (int i = 0; i < numEntries; i++) { 544 metadata.sPLT_red[i] = stream.readUnsignedByte(); 545 metadata.sPLT_green[i] = stream.readUnsignedByte(); 546 metadata.sPLT_blue[i] = stream.readUnsignedByte(); 547 metadata.sPLT_alpha[i] = stream.readUnsignedByte(); 548 metadata.sPLT_frequency[i] = stream.readUnsignedShort(); 549 } 550 } else if (sampleDepth == 16) { 551 for (int i = 0; i < numEntries; i++) { 552 metadata.sPLT_red[i] = stream.readUnsignedShort(); 553 metadata.sPLT_green[i] = stream.readUnsignedShort(); 554 metadata.sPLT_blue[i] = stream.readUnsignedShort(); 555 metadata.sPLT_alpha[i] = stream.readUnsignedShort(); 556 metadata.sPLT_frequency[i] = stream.readUnsignedShort(); 557 } 558 } else { 559 throw new IIOException("sPLT sample depth not 8 or 16!"); 560 } 561 562 metadata.sPLT_present = true; 563 } 564 565 private void parse_sRGB_chunk() throws IOException { 566 metadata.sRGB_renderingIntent = stream.readUnsignedByte(); 567 568 metadata.sRGB_present = true; 569 } 570 571 private void parse_tEXt_chunk(int chunkLength) throws IOException { 572 String keyword = readNullTerminatedString("ISO-8859-1", 80); 573 int textLength = chunkLength - keyword.length() - 1; 574 if (textLength <= 0) { 575 throw new IIOException("tEXt chunk length is not proper"); 576 } 577 metadata.tEXt_keyword.add(keyword); 578 579 byte[] b = new byte[textLength]; 580 stream.readFully(b); 581 metadata.tEXt_text.add(new String(b, "ISO-8859-1")); 582 583 // Check if the text chunk contains image creation time 584 if (keyword.equals(PNGMetadata.tEXt_creationTimeKey)) { 585 // Update Standard/Document/ImageCreationTime from text chunk 586 int index = metadata.tEXt_text.size() - 1; 587 metadata.decodeImageCreationTimeFromTextChunk( 588 metadata.tEXt_text.listIterator(index)); 589 } 590 } 591 592 private void parse_tIME_chunk() throws IOException { 593 metadata.tIME_year = stream.readUnsignedShort(); 594 metadata.tIME_month = stream.readUnsignedByte(); 595 metadata.tIME_day = stream.readUnsignedByte(); 596 metadata.tIME_hour = stream.readUnsignedByte(); 597 metadata.tIME_minute = stream.readUnsignedByte(); 598 metadata.tIME_second = stream.readUnsignedByte(); 599 600 metadata.tIME_present = true; 601 } 602 603 private void parse_tRNS_chunk(int chunkLength) throws IOException { 604 int colorType = metadata.IHDR_colorType; 605 if (colorType == PNG_COLOR_PALETTE) { 606 if (!metadata.PLTE_present) { 607 processWarningOccurred( 608 "tRNS chunk without prior PLTE chunk, ignoring it."); 609 return; 610 } 611 612 // Alpha table may have fewer entries than RGB palette 613 int maxEntries = metadata.PLTE_red.length; 614 int numEntries = chunkLength; 615 if (numEntries > maxEntries && maxEntries > 0) { 616 processWarningOccurred( 617 "tRNS chunk has more entries than prior PLTE chunk, ignoring extras."); 618 numEntries = maxEntries; 619 } 620 metadata.tRNS_alpha = new byte[numEntries]; 621 metadata.tRNS_colorType = PNG_COLOR_PALETTE; 622 stream.read(metadata.tRNS_alpha, 0, numEntries); 623 stream.skipBytes(chunkLength - numEntries); 624 } else if (colorType == PNG_COLOR_GRAY) { 625 if (chunkLength != 2) { 626 processWarningOccurred( 627 "tRNS chunk for gray image must have length 2, ignoring chunk."); 628 stream.skipBytes(chunkLength); 629 return; 630 } 631 metadata.tRNS_gray = stream.readUnsignedShort(); 632 metadata.tRNS_colorType = PNG_COLOR_GRAY; 633 } else if (colorType == PNG_COLOR_RGB) { 634 if (chunkLength != 6) { 635 processWarningOccurred( 636 "tRNS chunk for RGB image must have length 6, ignoring chunk."); 637 stream.skipBytes(chunkLength); 638 return; 639 } 640 metadata.tRNS_red = stream.readUnsignedShort(); 641 metadata.tRNS_green = stream.readUnsignedShort(); 642 metadata.tRNS_blue = stream.readUnsignedShort(); 643 metadata.tRNS_colorType = PNG_COLOR_RGB; 644 } else { 645 processWarningOccurred( 646 "Gray+Alpha and RGBS images may not have a tRNS chunk, ignoring it."); 647 return; 648 } 649 650 metadata.tRNS_present = true; 651 } 652 653 private static byte[] inflate(byte[] b) throws IOException { 654 InputStream bais = new ByteArrayInputStream(b); 655 InputStream iis = new InflaterInputStream(bais); 656 ByteArrayOutputStream baos = new ByteArrayOutputStream(); 657 658 int c; 659 try { 660 while ((c = iis.read()) != -1) { 661 baos.write(c); 662 } 663 } finally { 664 iis.close(); 665 } 666 return baos.toByteArray(); 667 } 668 669 private void parse_zTXt_chunk(int chunkLength) throws IOException { 670 String keyword = readNullTerminatedString("ISO-8859-1", 80); 671 int textLength = chunkLength - keyword.length() - 2; 672 if (textLength <= 0) { 673 throw new IIOException("zTXt chunk length is not proper"); 674 } 675 metadata.zTXt_keyword.add(keyword); 676 677 int method = stream.readUnsignedByte(); 678 metadata.zTXt_compressionMethod.add(method); 679 680 byte[] b = new byte[textLength]; 681 stream.readFully(b); 682 metadata.zTXt_text.add(new String(inflate(b), "ISO-8859-1")); 683 684 // Check if the text chunk contains image creation time 685 if (keyword.equals(PNGMetadata.tEXt_creationTimeKey)) { 686 // Update Standard/Document/ImageCreationTime from text chunk 687 int index = metadata.zTXt_text.size() - 1; 688 metadata.decodeImageCreationTimeFromTextChunk( 689 metadata.zTXt_text.listIterator(index)); 690 } 691 } 692 693 private void readMetadata() throws IIOException { 694 if (gotMetadata) { 695 return; 696 } 697 698 readHeader(); 699 700 /* 701 * Optimization: We can skip reading metadata if ignoreMetadata 702 * flag is set and colorType is not PNG_COLOR_PALETTE. However, 703 * we parse tRNS chunk to retrieve the transparent color from the 704 * metadata. Doing so, helps PNGImageReader to appropriately 705 * identify and set transparent pixels in the decoded image for 706 * colorType PNG_COLOR_RGB and PNG_COLOR_GRAY. 707 */ 708 int colorType = metadata.IHDR_colorType; 709 if (ignoreMetadata && colorType != PNG_COLOR_PALETTE) { 710 try { 711 while (true) { 712 int chunkLength = stream.readInt(); 713 714 // verify the chunk length first 715 if (chunkLength < 0 || chunkLength + 4 < 0) { 716 throw new IIOException("Invalid chunk length " + chunkLength); 717 } 718 719 int chunkType = stream.readInt(); 720 721 if (chunkType == IDAT_TYPE) { 722 // We've reached the first IDAT chunk position 723 stream.skipBytes(-8); 724 imageStartPosition = stream.getStreamPosition(); 725 /* 726 * According to PNG specification tRNS chunk must 727 * precede the first IDAT chunk. So we can stop 728 * reading metadata. 729 */ 730 break; 731 } else if (chunkType == tRNS_TYPE) { 732 parse_tRNS_chunk(chunkLength); 733 // After parsing tRNS chunk we will skip 4 CRC bytes 734 stream.skipBytes(4); 735 } else { 736 // Skip the chunk plus the 4 CRC bytes that follow 737 stream.skipBytes(chunkLength + 4); 738 } 739 } 740 } catch (IOException e) { 741 throw new IIOException("Error skipping PNG metadata", e); 742 } 743 744 gotMetadata = true; 745 return; 746 } 747 748 try { 749 loop: while (true) { 750 int chunkLength = stream.readInt(); 751 int chunkType = stream.readInt(); 752 int chunkCRC; 753 754 // verify the chunk length 755 if (chunkLength < 0) { 756 throw new IIOException("Invalid chunk length " + chunkLength); 757 }; 758 759 try { 760 stream.mark(); 761 stream.seek(stream.getStreamPosition() + chunkLength); 762 chunkCRC = stream.readInt(); 763 stream.reset(); 764 } catch (IOException e) { 765 throw new IIOException("Invalid chunk length " + chunkLength); 766 } 767 768 switch (chunkType) { 769 case IDAT_TYPE: 770 // If chunk type is 'IDAT', we've reached the image data. 771 if (imageStartPosition == -1L) { 772 /* 773 * The PNG specification mandates that if colorType is 774 * PNG_COLOR_PALETTE then the PLTE chunk should appear 775 * before the first IDAT chunk. 776 */ 777 if (colorType == PNG_COLOR_PALETTE && 778 !(metadata.PLTE_present)) 779 { 780 throw new IIOException("Required PLTE chunk" 781 + " missing"); 782 } 783 /* 784 * PNGs may contain multiple IDAT chunks containing 785 * a portion of image data. We store the position of 786 * the first IDAT chunk and continue with iteration 787 * of other chunks that follow image data. 788 */ 789 imageStartPosition = stream.getStreamPosition() - 8; 790 } 791 // Move to the CRC byte location. 792 stream.skipBytes(chunkLength); 793 break; 794 case IEND_TYPE: 795 /* 796 * If the chunk type is 'IEND', we've reached end of image. 797 * Seek to the first IDAT chunk for subsequent decoding. 798 */ 799 stream.seek(imageStartPosition); 800 801 /* 802 * flushBefore discards the portion of the stream before 803 * the indicated position. Hence this should be used after 804 * we complete iteration over available chunks including 805 * those that appear after the IDAT. 806 */ 807 stream.flushBefore(stream.getStreamPosition()); 808 break loop; 809 case PLTE_TYPE: 810 parse_PLTE_chunk(chunkLength); 811 break; 812 case bKGD_TYPE: 813 parse_bKGD_chunk(); 814 break; 815 case cHRM_TYPE: 816 parse_cHRM_chunk(); 817 break; 818 case gAMA_TYPE: 819 parse_gAMA_chunk(); 820 break; 821 case hIST_TYPE: 822 parse_hIST_chunk(chunkLength); 823 break; 824 case iCCP_TYPE: 825 parse_iCCP_chunk(chunkLength); 826 break; 827 case iTXt_TYPE: 828 if (ignoreMetadata) { 829 stream.skipBytes(chunkLength); 830 } else { 831 parse_iTXt_chunk(chunkLength); 832 } 833 break; 834 case pHYs_TYPE: 835 parse_pHYs_chunk(); 836 break; 837 case sBIT_TYPE: 838 parse_sBIT_chunk(); 839 break; 840 case sPLT_TYPE: 841 parse_sPLT_chunk(chunkLength); 842 break; 843 case sRGB_TYPE: 844 parse_sRGB_chunk(); 845 break; 846 case tEXt_TYPE: 847 parse_tEXt_chunk(chunkLength); 848 break; 849 case tIME_TYPE: 850 parse_tIME_chunk(); 851 break; 852 case tRNS_TYPE: 853 parse_tRNS_chunk(chunkLength); 854 break; 855 case zTXt_TYPE: 856 if (ignoreMetadata) { 857 stream.skipBytes(chunkLength); 858 } else { 859 parse_zTXt_chunk(chunkLength); 860 } 861 break; 862 default: 863 // Read an unknown chunk 864 byte[] b = new byte[chunkLength]; 865 stream.readFully(b); 866 867 StringBuilder chunkName = new StringBuilder(4); 868 chunkName.append((char)(chunkType >>> 24)); 869 chunkName.append((char)((chunkType >> 16) & 0xff)); 870 chunkName.append((char)((chunkType >> 8) & 0xff)); 871 chunkName.append((char)(chunkType & 0xff)); 872 873 int ancillaryBit = chunkType >>> 28; 874 if (ancillaryBit == 0) { 875 processWarningOccurred( 876 "Encountered unknown chunk with critical bit set!"); 877 } 878 879 metadata.unknownChunkType.add(chunkName.toString()); 880 metadata.unknownChunkData.add(b); 881 break; 882 } 883 884 // double check whether all chunk data were consumed 885 if (chunkCRC != stream.readInt()) { 886 throw new IIOException("Failed to read a chunk of type " + 887 chunkType); 888 } 889 } 890 } catch (IOException e) { 891 throw new IIOException("Error reading PNG metadata", e); 892 } 893 894 gotMetadata = true; 895 } 896 897 // Data filtering methods 898 899 private static void decodeSubFilter(byte[] curr, int coff, int count, 900 int bpp) { 901 for (int i = bpp; i < count; i++) { 902 int val; 903 904 val = curr[i + coff] & 0xff; 905 val += curr[i + coff - bpp] & 0xff; 906 907 curr[i + coff] = (byte)val; 908 } 909 } 910 911 private static void decodeUpFilter(byte[] curr, int coff, 912 byte[] prev, int poff, 913 int count) { 914 for (int i = 0; i < count; i++) { 915 int raw = curr[i + coff] & 0xff; 916 int prior = prev[i + poff] & 0xff; 917 918 curr[i + coff] = (byte)(raw + prior); 919 } 920 } 921 922 private static void decodeAverageFilter(byte[] curr, int coff, 923 byte[] prev, int poff, 924 int count, int bpp) { 925 int raw, priorPixel, priorRow; 926 927 for (int i = 0; i < bpp; i++) { 928 raw = curr[i + coff] & 0xff; 929 priorRow = prev[i + poff] & 0xff; 930 931 curr[i + coff] = (byte)(raw + priorRow/2); 932 } 933 934 for (int i = bpp; i < count; i++) { 935 raw = curr[i + coff] & 0xff; 936 priorPixel = curr[i + coff - bpp] & 0xff; 937 priorRow = prev[i + poff] & 0xff; 938 939 curr[i + coff] = (byte)(raw + (priorPixel + priorRow)/2); 940 } 941 } 942 943 private static int paethPredictor(int a, int b, int c) { 944 int p = a + b - c; 945 int pa = Math.abs(p - a); 946 int pb = Math.abs(p - b); 947 int pc = Math.abs(p - c); 948 949 if ((pa <= pb) && (pa <= pc)) { 950 return a; 951 } else if (pb <= pc) { 952 return b; 953 } else { 954 return c; 955 } 956 } 957 958 private static void decodePaethFilter(byte[] curr, int coff, 959 byte[] prev, int poff, 960 int count, int bpp) { 961 int raw, priorPixel, priorRow, priorRowPixel; 962 963 for (int i = 0; i < bpp; i++) { 964 raw = curr[i + coff] & 0xff; 965 priorRow = prev[i + poff] & 0xff; 966 967 curr[i + coff] = (byte)(raw + priorRow); 968 } 969 970 for (int i = bpp; i < count; i++) { 971 raw = curr[i + coff] & 0xff; 972 priorPixel = curr[i + coff - bpp] & 0xff; 973 priorRow = prev[i + poff] & 0xff; 974 priorRowPixel = prev[i + poff - bpp] & 0xff; 975 976 curr[i + coff] = (byte)(raw + paethPredictor(priorPixel, 977 priorRow, 978 priorRowPixel)); 979 } 980 } 981 982 private static final int[][] bandOffsets = { 983 null, 984 { 0 }, // G 985 { 0, 1 }, // GA in GA order 986 { 0, 1, 2 }, // RGB in RGB order 987 { 0, 1, 2, 3 } // RGBA in RGBA order 988 }; 989 990 private WritableRaster createRaster(int width, int height, int bands, 991 int scanlineStride, 992 int bitDepth) { 993 994 DataBuffer dataBuffer; 995 WritableRaster ras = null; 996 Point origin = new Point(0, 0); 997 if ((bitDepth < 8) && (bands == 1)) { 998 dataBuffer = new DataBufferByte(height*scanlineStride); 999 ras = Raster.createPackedRaster(dataBuffer, 1000 width, height, 1001 bitDepth, 1002 origin); 1003 } else if (bitDepth <= 8) { 1004 dataBuffer = new DataBufferByte(height*scanlineStride); 1005 ras = Raster.createInterleavedRaster(dataBuffer, 1006 width, height, 1007 scanlineStride, 1008 bands, 1009 bandOffsets[bands], 1010 origin); 1011 } else { 1012 dataBuffer = new DataBufferUShort(height*scanlineStride); 1013 ras = Raster.createInterleavedRaster(dataBuffer, 1014 width, height, 1015 scanlineStride, 1016 bands, 1017 bandOffsets[bands], 1018 origin); 1019 } 1020 1021 return ras; 1022 } 1023 1024 private void skipPass(int passWidth, int passHeight) 1025 throws IOException, IIOException { 1026 if ((passWidth == 0) || (passHeight == 0)) { 1027 return; 1028 } 1029 1030 int inputBands = inputBandsForColorType[metadata.IHDR_colorType]; 1031 int bitsPerRow = Math. 1032 multiplyExact((inputBands * metadata.IHDR_bitDepth), passWidth); 1033 int bytesPerRow = (bitsPerRow + 7) / 8; 1034 1035 // Read the image row-by-row 1036 for (int srcY = 0; srcY < passHeight; srcY++) { 1037 // Skip filter byte and the remaining row bytes 1038 pixelStream.skipBytes(1 + bytesPerRow); 1039 } 1040 } 1041 1042 private void updateImageProgress(int newPixels) { 1043 pixelsDone += newPixels; 1044 processImageProgress(100.0F*pixelsDone/totalPixels); 1045 } 1046 1047 private void decodePass(int passNum, 1048 int xStart, int yStart, 1049 int xStep, int yStep, 1050 int passWidth, int passHeight) throws IOException { 1051 1052 if ((passWidth == 0) || (passHeight == 0)) { 1053 return; 1054 } 1055 1056 WritableRaster imRas = theImage.getWritableTile(0, 0); 1057 int dstMinX = imRas.getMinX(); 1058 int dstMaxX = dstMinX + imRas.getWidth() - 1; 1059 int dstMinY = imRas.getMinY(); 1060 int dstMaxY = dstMinY + imRas.getHeight() - 1; 1061 1062 // Determine which pixels will be updated in this pass 1063 int[] vals = 1064 ReaderUtil.computeUpdatedPixels(sourceRegion, 1065 destinationOffset, 1066 dstMinX, dstMinY, 1067 dstMaxX, dstMaxY, 1068 sourceXSubsampling, 1069 sourceYSubsampling, 1070 xStart, yStart, 1071 passWidth, passHeight, 1072 xStep, yStep); 1073 int updateMinX = vals[0]; 1074 int updateMinY = vals[1]; 1075 int updateWidth = vals[2]; 1076 int updateXStep = vals[4]; 1077 int updateYStep = vals[5]; 1078 1079 int bitDepth = metadata.IHDR_bitDepth; 1080 int inputBands = inputBandsForColorType[metadata.IHDR_colorType]; 1081 int bytesPerPixel = (bitDepth == 16) ? 2 : 1; 1082 bytesPerPixel *= inputBands; 1083 1084 int bitsPerRow = Math.multiplyExact((inputBands * bitDepth), passWidth); 1085 int bytesPerRow = (bitsPerRow + 7) / 8; 1086 int eltsPerRow = (bitDepth == 16) ? bytesPerRow/2 : bytesPerRow; 1087 1088 // If no pixels need updating, just skip the input data 1089 if (updateWidth == 0) { 1090 for (int srcY = 0; srcY < passHeight; srcY++) { 1091 // Update count of pixels read 1092 updateImageProgress(passWidth); 1093 /* 1094 * If read has been aborted, just return 1095 * processReadAborted will be called later 1096 */ 1097 if (abortRequested()) { 1098 return; 1099 } 1100 // Skip filter byte and the remaining row bytes 1101 pixelStream.skipBytes(1 + bytesPerRow); 1102 } 1103 return; 1104 } 1105 1106 // Backwards map from destination pixels 1107 // (dstX = updateMinX + k*updateXStep) 1108 // to source pixels (sourceX), and then 1109 // to offset and skip in passRow (srcX and srcXStep) 1110 int sourceX = 1111 (updateMinX - destinationOffset.x)*sourceXSubsampling + 1112 sourceRegion.x; 1113 int srcX = (sourceX - xStart)/xStep; 1114 1115 // Compute the step factor in the source 1116 int srcXStep = updateXStep*sourceXSubsampling/xStep; 1117 1118 byte[] byteData = null; 1119 short[] shortData = null; 1120 byte[] curr = new byte[bytesPerRow]; 1121 byte[] prior = new byte[bytesPerRow]; 1122 1123 // Create a 1-row tall Raster to hold the data 1124 WritableRaster passRow = createRaster(passWidth, 1, inputBands, 1125 eltsPerRow, 1126 bitDepth); 1127 1128 // Create an array suitable for holding one pixel 1129 int[] ps = passRow.getPixel(0, 0, (int[])null); 1130 1131 DataBuffer dataBuffer = passRow.getDataBuffer(); 1132 int type = dataBuffer.getDataType(); 1133 if (type == DataBuffer.TYPE_BYTE) { 1134 byteData = ((DataBufferByte)dataBuffer).getData(); 1135 } else { 1136 shortData = ((DataBufferUShort)dataBuffer).getData(); 1137 } 1138 1139 processPassStarted(theImage, 1140 passNum, 1141 sourceMinProgressivePass, 1142 sourceMaxProgressivePass, 1143 updateMinX, updateMinY, 1144 updateXStep, updateYStep, 1145 destinationBands); 1146 1147 // Handle source and destination bands 1148 if (sourceBands != null) { 1149 passRow = passRow.createWritableChild(0, 0, 1150 passRow.getWidth(), 1, 1151 0, 0, 1152 sourceBands); 1153 } 1154 if (destinationBands != null) { 1155 imRas = imRas.createWritableChild(0, 0, 1156 imRas.getWidth(), 1157 imRas.getHeight(), 1158 0, 0, 1159 destinationBands); 1160 } 1161 1162 // Determine if all of the relevant output bands have the 1163 // same bit depth as the source data 1164 boolean adjustBitDepths = false; 1165 int[] outputSampleSize = imRas.getSampleModel().getSampleSize(); 1166 int numBands = outputSampleSize.length; 1167 for (int b = 0; b < numBands; b++) { 1168 if (outputSampleSize[b] != bitDepth) { 1169 adjustBitDepths = true; 1170 break; 1171 } 1172 } 1173 1174 // If the bit depths differ, create a lookup table per band to perform 1175 // the conversion 1176 int[][] scale = null; 1177 if (adjustBitDepths) { 1178 int maxInSample = (1 << bitDepth) - 1; 1179 int halfMaxInSample = maxInSample/2; 1180 scale = new int[numBands][]; 1181 for (int b = 0; b < numBands; b++) { 1182 int maxOutSample = (1 << outputSampleSize[b]) - 1; 1183 scale[b] = new int[maxInSample + 1]; 1184 for (int s = 0; s <= maxInSample; s++) { 1185 scale[b][s] = 1186 (s*maxOutSample + halfMaxInSample)/maxInSample; 1187 } 1188 } 1189 } 1190 1191 // Limit passRow to relevant area for the case where we 1192 // will can setRect to copy a contiguous span 1193 boolean useSetRect = srcXStep == 1 && 1194 updateXStep == 1 && 1195 !adjustBitDepths && 1196 (imRas instanceof ByteInterleavedRaster); 1197 1198 if (useSetRect) { 1199 passRow = passRow.createWritableChild(srcX, 0, 1200 updateWidth, 1, 1201 0, 0, 1202 null); 1203 } 1204 1205 // Decode the (sub)image row-by-row 1206 for (int srcY = 0; srcY < passHeight; srcY++) { 1207 // Update count of pixels read 1208 updateImageProgress(passWidth); 1209 /* 1210 * If read has been aborted, just return 1211 * processReadAborted will be called later 1212 */ 1213 if (abortRequested()) { 1214 return; 1215 } 1216 // Read the filter type byte and a row of data 1217 int filter = pixelStream.read(); 1218 try { 1219 // Swap curr and prior 1220 byte[] tmp = prior; 1221 prior = curr; 1222 curr = tmp; 1223 1224 pixelStream.readFully(curr, 0, bytesPerRow); 1225 } catch (java.util.zip.ZipException ze) { 1226 // TODO - throw a more meaningful exception 1227 throw ze; 1228 } 1229 1230 switch (filter) { 1231 case PNG_FILTER_NONE: 1232 break; 1233 case PNG_FILTER_SUB: 1234 decodeSubFilter(curr, 0, bytesPerRow, bytesPerPixel); 1235 break; 1236 case PNG_FILTER_UP: 1237 decodeUpFilter(curr, 0, prior, 0, bytesPerRow); 1238 break; 1239 case PNG_FILTER_AVERAGE: 1240 decodeAverageFilter(curr, 0, prior, 0, bytesPerRow, 1241 bytesPerPixel); 1242 break; 1243 case PNG_FILTER_PAETH: 1244 decodePaethFilter(curr, 0, prior, 0, bytesPerRow, 1245 bytesPerPixel); 1246 break; 1247 default: 1248 throw new IIOException("Unknown row filter type (= " + 1249 filter + ")!"); 1250 } 1251 1252 // Copy data into passRow byte by byte 1253 if (bitDepth < 16) { 1254 System.arraycopy(curr, 0, byteData, 0, bytesPerRow); 1255 } else { 1256 int idx = 0; 1257 for (int j = 0; j < eltsPerRow; j++) { 1258 shortData[j] = 1259 (short)((curr[idx] << 8) | (curr[idx + 1] & 0xff)); 1260 idx += 2; 1261 } 1262 } 1263 1264 // True Y position in source 1265 int sourceY = srcY*yStep + yStart; 1266 if ((sourceY >= sourceRegion.y) && 1267 (sourceY < sourceRegion.y + sourceRegion.height) && 1268 (((sourceY - sourceRegion.y) % 1269 sourceYSubsampling) == 0)) { 1270 1271 int dstY = destinationOffset.y + 1272 (sourceY - sourceRegion.y)/sourceYSubsampling; 1273 if (dstY < dstMinY) { 1274 continue; 1275 } 1276 if (dstY > dstMaxY) { 1277 break; 1278 } 1279 1280 /* 1281 * In case of colortype PNG_COLOR_RGB or PNG_COLOR_GRAY 1282 * if we have transparent pixel information from tRNS chunk 1283 * we need to consider that also and store proper information 1284 * in alpha channel. 1285 * 1286 * Also we create destination image with extra alpha channel 1287 * in getImageTypes() when we have tRNS chunk for colorType 1288 * PNG_COLOR_RGB or PNG_COLOR_GRAY. 1289 */ 1290 boolean tRNSTransparentPixelPresent = 1291 theImage.getSampleModel().getNumBands() == inputBands + 1 && 1292 metadata.tRNS_present && 1293 (metadata.tRNS_colorType == PNG_COLOR_RGB || 1294 metadata.tRNS_colorType == PNG_COLOR_GRAY); 1295 if (useSetRect && 1296 !tRNSTransparentPixelPresent) 1297 { 1298 imRas.setRect(updateMinX, dstY, passRow); 1299 } else { 1300 int newSrcX = srcX; 1301 1302 for (int dstX = updateMinX; 1303 dstX < updateMinX + updateWidth; 1304 dstX += updateXStep) { 1305 1306 passRow.getPixel(newSrcX, 0, ps); 1307 if (adjustBitDepths) { 1308 for (int b = 0; b < numBands; b++) { 1309 ps[b] = scale[b][ps[b]]; 1310 } 1311 } 1312 if (tRNSTransparentPixelPresent) 1313 { 1314 /* 1315 * Create intermediate array to fill the extra 1316 * alpha channel for each pixel. 1317 */ 1318 int[] temp = new int[inputBands + 1]; 1319 if (metadata.tRNS_colorType == PNG_COLOR_RGB) { 1320 temp[0] = ps[0]; 1321 temp[1] = ps[1]; 1322 temp[2] = ps[2]; 1323 if (ps[0] == metadata.tRNS_red && 1324 ps[1] == metadata.tRNS_green && 1325 ps[2] == metadata.tRNS_blue) 1326 { 1327 temp[3] = 0; 1328 } else { 1329 if (bitDepth < 16) { 1330 temp[3] = 255; 1331 } else { 1332 temp[3] = 65535; 1333 } 1334 } 1335 } else { 1336 // when tRNS_colorType is PNG_COLOR_GRAY 1337 temp[0] = ps[0]; 1338 if (ps[0] == metadata.tRNS_gray) 1339 { 1340 temp[1] = 0; 1341 } else { 1342 if (bitDepth < 16) { 1343 temp[1] = 255; 1344 } else { 1345 temp[1] = 65535; 1346 } 1347 } 1348 } 1349 imRas.setPixel(dstX, dstY, temp); 1350 } else { 1351 imRas.setPixel(dstX, dstY, ps); 1352 } 1353 newSrcX += srcXStep; 1354 } 1355 } 1356 1357 processImageUpdate(theImage, 1358 updateMinX, dstY, 1359 updateWidth, 1, 1360 updateXStep, updateYStep, 1361 destinationBands); 1362 } 1363 } 1364 1365 processPassComplete(theImage); 1366 } 1367 1368 private void decodeImage() 1369 throws IOException, IIOException { 1370 int width = metadata.IHDR_width; 1371 int height = metadata.IHDR_height; 1372 1373 this.pixelsDone = 0; 1374 this.totalPixels = width*height; 1375 1376 if (metadata.IHDR_interlaceMethod == 0) { 1377 decodePass(0, 0, 0, 1, 1, width, height); 1378 } else { 1379 for (int i = 0; i <= sourceMaxProgressivePass; i++) { 1380 int XOffset = adam7XOffset[i]; 1381 int YOffset = adam7YOffset[i]; 1382 int XSubsampling = adam7XSubsampling[i]; 1383 int YSubsampling = adam7YSubsampling[i]; 1384 int xbump = adam7XSubsampling[i + 1] - 1; 1385 int ybump = adam7YSubsampling[i + 1] - 1; 1386 1387 if (i >= sourceMinProgressivePass) { 1388 decodePass(i, 1389 XOffset, 1390 YOffset, 1391 XSubsampling, 1392 YSubsampling, 1393 (width + xbump)/XSubsampling, 1394 (height + ybump)/YSubsampling); 1395 } else { 1396 skipPass((width + xbump)/XSubsampling, 1397 (height + ybump)/YSubsampling); 1398 } 1399 1400 /* 1401 * If read has been aborted, just return 1402 * processReadAborted will be called later 1403 */ 1404 if (abortRequested()) { 1405 return; 1406 } 1407 } 1408 } 1409 } 1410 1411 private void readImage(ImageReadParam param) throws IIOException { 1412 readMetadata(); 1413 1414 int width = metadata.IHDR_width; 1415 int height = metadata.IHDR_height; 1416 1417 // Init default values 1418 sourceXSubsampling = 1; 1419 sourceYSubsampling = 1; 1420 sourceMinProgressivePass = 0; 1421 sourceMaxProgressivePass = 6; 1422 sourceBands = null; 1423 destinationBands = null; 1424 destinationOffset = new Point(0, 0); 1425 1426 // If an ImageReadParam is available, get values from it 1427 if (param != null) { 1428 sourceXSubsampling = param.getSourceXSubsampling(); 1429 sourceYSubsampling = param.getSourceYSubsampling(); 1430 1431 sourceMinProgressivePass = 1432 Math.max(param.getSourceMinProgressivePass(), 0); 1433 sourceMaxProgressivePass = 1434 Math.min(param.getSourceMaxProgressivePass(), 6); 1435 1436 sourceBands = param.getSourceBands(); 1437 destinationBands = param.getDestinationBands(); 1438 destinationOffset = param.getDestinationOffset(); 1439 } 1440 Inflater inf = null; 1441 try { 1442 stream.seek(imageStartPosition); 1443 1444 Enumeration<InputStream> e = new PNGImageDataEnumeration(stream); 1445 InputStream is = new SequenceInputStream(e); 1446 1447 /* InflaterInputStream uses an Inflater instance which consumes 1448 * native (non-GC visible) resources. This is normally implicitly 1449 * freed when the stream is closed. However since the 1450 * InflaterInputStream wraps a client-supplied input stream, 1451 * we cannot close it. 1452 * But the app may depend on GC finalization to close the stream. 1453 * Therefore to ensure timely freeing of native resources we 1454 * explicitly create the Inflater instance and free its resources 1455 * when we are done with the InflaterInputStream by calling 1456 * inf.end(); 1457 */ 1458 inf = new Inflater(); 1459 is = new InflaterInputStream(is, inf); 1460 is = new BufferedInputStream(is); 1461 this.pixelStream = new DataInputStream(is); 1462 1463 /* 1464 * PNG spec declares that valid range for width 1465 * and height is [1, 2^31-1], so here we may fail to allocate 1466 * a buffer for destination image due to memory limitation. 1467 * 1468 * If the read operation triggers OutOfMemoryError, the same 1469 * will be wrapped in an IIOException at PNGImageReader.read 1470 * method. 1471 * 1472 * The recovery strategy for this case should be defined at 1473 * the level of application, so we will not try to estimate 1474 * the required amount of the memory and/or handle OOM in 1475 * any way. 1476 */ 1477 theImage = getDestination(param, 1478 getImageTypes(0), 1479 width, 1480 height); 1481 1482 Rectangle destRegion = new Rectangle(0, 0, 0, 0); 1483 sourceRegion = new Rectangle(0, 0, 0, 0); 1484 computeRegions(param, width, height, 1485 theImage, 1486 sourceRegion, destRegion); 1487 destinationOffset.setLocation(destRegion.getLocation()); 1488 1489 // At this point the header has been read and we know 1490 // how many bands are in the image, so perform checking 1491 // of the read param. 1492 int colorType = metadata.IHDR_colorType; 1493 if (theImage.getSampleModel().getNumBands() == 1494 inputBandsForColorType[colorType] + 1 && 1495 metadata.tRNS_present && 1496 (metadata.tRNS_colorType == PNG_COLOR_RGB || 1497 metadata.tRNS_colorType == PNG_COLOR_GRAY)) 1498 { 1499 checkReadParamBandSettings(param, 1500 inputBandsForColorType[colorType] + 1, 1501 theImage.getSampleModel().getNumBands()); 1502 } else { 1503 checkReadParamBandSettings(param, 1504 inputBandsForColorType[colorType], 1505 theImage.getSampleModel().getNumBands()); 1506 } 1507 1508 clearAbortRequest(); 1509 processImageStarted(0); 1510 if (abortRequested()) { 1511 processReadAborted(); 1512 } else { 1513 decodeImage(); 1514 if (abortRequested()) { 1515 processReadAborted(); 1516 } else { 1517 processImageComplete(); 1518 } 1519 } 1520 1521 } catch (IOException e) { 1522 throw new IIOException("Error reading PNG image data", e); 1523 } finally { 1524 if (inf != null) { 1525 inf.end(); 1526 } 1527 } 1528 } 1529 1530 public int getNumImages(boolean allowSearch) throws IIOException { 1531 if (stream == null) { 1532 throw new IllegalStateException("No input source set!"); 1533 } 1534 if (seekForwardOnly && allowSearch) { 1535 throw new IllegalStateException 1536 ("seekForwardOnly and allowSearch can't both be true!"); 1537 } 1538 return 1; 1539 } 1540 1541 public int getWidth(int imageIndex) throws IIOException { 1542 if (imageIndex != 0) { 1543 throw new IndexOutOfBoundsException("imageIndex != 0!"); 1544 } 1545 1546 readHeader(); 1547 1548 return metadata.IHDR_width; 1549 } 1550 1551 public int getHeight(int imageIndex) throws IIOException { 1552 if (imageIndex != 0) { 1553 throw new IndexOutOfBoundsException("imageIndex != 0!"); 1554 } 1555 1556 readHeader(); 1557 1558 return metadata.IHDR_height; 1559 } 1560 1561 public Iterator<ImageTypeSpecifier> getImageTypes(int imageIndex) 1562 throws IIOException 1563 { 1564 if (imageIndex != 0) { 1565 throw new IndexOutOfBoundsException("imageIndex != 0!"); 1566 } 1567 1568 readHeader(); 1569 1570 ArrayList<ImageTypeSpecifier> l = 1571 new ArrayList<ImageTypeSpecifier>(1); 1572 1573 ColorSpace rgb; 1574 ColorSpace gray; 1575 int[] bandOffsets; 1576 1577 int bitDepth = metadata.IHDR_bitDepth; 1578 int colorType = metadata.IHDR_colorType; 1579 1580 int dataType; 1581 if (bitDepth <= 8) { 1582 dataType = DataBuffer.TYPE_BYTE; 1583 } else { 1584 dataType = DataBuffer.TYPE_USHORT; 1585 } 1586 1587 switch (colorType) { 1588 /* 1589 * In case of PNG_COLOR_RGB or PNG_COLOR_GRAY, if we 1590 * have transparent pixel information in tRNS chunk 1591 * we create destination image having alpha channel. 1592 */ 1593 case PNG_COLOR_GRAY: 1594 readMetadata(); // Need tRNS chunk 1595 1596 if (metadata.tRNS_present && 1597 metadata.tRNS_colorType == PNG_COLOR_GRAY) 1598 { 1599 gray = ColorSpace.getInstance(ColorSpace.CS_GRAY); 1600 bandOffsets = new int[2]; 1601 bandOffsets[0] = 0; 1602 bandOffsets[1] = 1; 1603 l.add(ImageTypeSpecifier.createInterleaved(gray, 1604 bandOffsets, 1605 dataType, 1606 true, 1607 false)); 1608 } 1609 // Packed grayscale 1610 l.add(ImageTypeSpecifier.createGrayscale(bitDepth, 1611 dataType, 1612 false)); 1613 break; 1614 1615 case PNG_COLOR_RGB: 1616 readMetadata(); // Need tRNS chunk 1617 1618 if (bitDepth == 8) { 1619 if (metadata.tRNS_present && 1620 metadata.tRNS_colorType == PNG_COLOR_RGB) 1621 { 1622 l.add(ImageTypeSpecifier.createFromBufferedImageType( 1623 BufferedImage.TYPE_4BYTE_ABGR)); 1624 } 1625 // some standard types of buffered images 1626 // which can be used as destination 1627 l.add(ImageTypeSpecifier.createFromBufferedImageType( 1628 BufferedImage.TYPE_3BYTE_BGR)); 1629 1630 l.add(ImageTypeSpecifier.createFromBufferedImageType( 1631 BufferedImage.TYPE_INT_RGB)); 1632 1633 l.add(ImageTypeSpecifier.createFromBufferedImageType( 1634 BufferedImage.TYPE_INT_BGR)); 1635 1636 } 1637 if (metadata.tRNS_present && 1638 metadata.tRNS_colorType == PNG_COLOR_RGB) 1639 { 1640 rgb = ColorSpace.getInstance(ColorSpace.CS_sRGB); 1641 bandOffsets = new int[4]; 1642 bandOffsets[0] = 0; 1643 bandOffsets[1] = 1; 1644 bandOffsets[2] = 2; 1645 bandOffsets[3] = 3; 1646 1647 l.add(ImageTypeSpecifier. 1648 createInterleaved(rgb, bandOffsets, 1649 dataType, true, false)); 1650 } 1651 // Component R, G, B 1652 rgb = ColorSpace.getInstance(ColorSpace.CS_sRGB); 1653 bandOffsets = new int[3]; 1654 bandOffsets[0] = 0; 1655 bandOffsets[1] = 1; 1656 bandOffsets[2] = 2; 1657 l.add(ImageTypeSpecifier.createInterleaved(rgb, 1658 bandOffsets, 1659 dataType, 1660 false, 1661 false)); 1662 break; 1663 1664 case PNG_COLOR_PALETTE: 1665 readMetadata(); // Need tRNS chunk 1666 1667 /* 1668 * The PLTE chunk spec says: 1669 * 1670 * The number of palette entries must not exceed the range that 1671 * can be represented in the image bit depth (for example, 2^4 = 16 1672 * for a bit depth of 4). It is permissible to have fewer entries 1673 * than the bit depth would allow. In that case, any out-of-range 1674 * pixel value found in the image data is an error. 1675 * 1676 * http://www.libpng.org/pub/png/spec/1.2/PNG-Chunks.html#C.PLTE 1677 * 1678 * Consequently, the case when the palette length is smaller than 1679 * 2^bitDepth is legal in the view of PNG spec. 1680 * 1681 * However the spec of createIndexed() method demands the exact 1682 * equality of the palette lengh and number of possible palette 1683 * entries (2^bitDepth). 1684 * 1685 * {@link javax.imageio.ImageTypeSpecifier.html#createIndexed} 1686 * 1687 * In order to avoid this contradiction we need to extend the 1688 * palette arrays to the limit defined by the bitDepth. 1689 */ 1690 1691 int plength = 1 << bitDepth; 1692 1693 byte[] red = metadata.PLTE_red; 1694 byte[] green = metadata.PLTE_green; 1695 byte[] blue = metadata.PLTE_blue; 1696 1697 if (metadata.PLTE_red.length < plength) { 1698 red = Arrays.copyOf(metadata.PLTE_red, plength); 1699 Arrays.fill(red, metadata.PLTE_red.length, plength, 1700 metadata.PLTE_red[metadata.PLTE_red.length - 1]); 1701 1702 green = Arrays.copyOf(metadata.PLTE_green, plength); 1703 Arrays.fill(green, metadata.PLTE_green.length, plength, 1704 metadata.PLTE_green[metadata.PLTE_green.length - 1]); 1705 1706 blue = Arrays.copyOf(metadata.PLTE_blue, plength); 1707 Arrays.fill(blue, metadata.PLTE_blue.length, plength, 1708 metadata.PLTE_blue[metadata.PLTE_blue.length - 1]); 1709 1710 } 1711 1712 // Alpha from tRNS chunk may have fewer entries than 1713 // the RGB LUTs from the PLTE chunk; if so, pad with 1714 // 255. 1715 byte[] alpha = null; 1716 if (metadata.tRNS_present && (metadata.tRNS_alpha != null)) { 1717 if (metadata.tRNS_alpha.length == red.length) { 1718 alpha = metadata.tRNS_alpha; 1719 } else { 1720 alpha = Arrays.copyOf(metadata.tRNS_alpha, red.length); 1721 Arrays.fill(alpha, 1722 metadata.tRNS_alpha.length, 1723 red.length, (byte)255); 1724 } 1725 } 1726 1727 l.add(ImageTypeSpecifier.createIndexed(red, green, 1728 blue, alpha, 1729 bitDepth, 1730 DataBuffer.TYPE_BYTE)); 1731 break; 1732 1733 case PNG_COLOR_GRAY_ALPHA: 1734 // Component G, A 1735 gray = ColorSpace.getInstance(ColorSpace.CS_GRAY); 1736 bandOffsets = new int[2]; 1737 bandOffsets[0] = 0; 1738 bandOffsets[1] = 1; 1739 l.add(ImageTypeSpecifier.createInterleaved(gray, 1740 bandOffsets, 1741 dataType, 1742 true, 1743 false)); 1744 break; 1745 1746 case PNG_COLOR_RGB_ALPHA: 1747 if (bitDepth == 8) { 1748 // some standard types of buffered images 1749 // wich can be used as destination 1750 l.add(ImageTypeSpecifier.createFromBufferedImageType( 1751 BufferedImage.TYPE_4BYTE_ABGR)); 1752 1753 l.add(ImageTypeSpecifier.createFromBufferedImageType( 1754 BufferedImage.TYPE_INT_ARGB)); 1755 } 1756 1757 // Component R, G, B, A (non-premultiplied) 1758 rgb = ColorSpace.getInstance(ColorSpace.CS_sRGB); 1759 bandOffsets = new int[4]; 1760 bandOffsets[0] = 0; 1761 bandOffsets[1] = 1; 1762 bandOffsets[2] = 2; 1763 bandOffsets[3] = 3; 1764 1765 l.add(ImageTypeSpecifier.createInterleaved(rgb, 1766 bandOffsets, 1767 dataType, 1768 true, 1769 false)); 1770 break; 1771 1772 default: 1773 break; 1774 } 1775 1776 return l.iterator(); 1777 } 1778 1779 /* 1780 * Super class implementation uses first element 1781 * of image types list as raw image type. 1782 * 1783 * Also, super implementation uses first element of this list 1784 * as default destination type image read param does not specify 1785 * anything other. 1786 * 1787 * However, in case of RGB and RGBA color types, raw image type 1788 * produces buffered image of custom type. It causes some 1789 * performance degradation of subsequent rendering operations. 1790 * 1791 * To resolve this contradiction we put standard image types 1792 * at the first positions of image types list (to produce standard 1793 * images by default) and put raw image type (which is custom) 1794 * at the last position of this list. 1795 * 1796 * After this changes we should override getRawImageType() 1797 * to return last element of image types list. 1798 */ 1799 public ImageTypeSpecifier getRawImageType(int imageIndex) 1800 throws IOException { 1801 1802 Iterator<ImageTypeSpecifier> types = getImageTypes(imageIndex); 1803 ImageTypeSpecifier raw = null; 1804 do { 1805 raw = types.next(); 1806 } while (types.hasNext()); 1807 return raw; 1808 } 1809 1810 public ImageReadParam getDefaultReadParam() { 1811 return new ImageReadParam(); 1812 } 1813 1814 public IIOMetadata getStreamMetadata() 1815 throws IIOException { 1816 return null; 1817 } 1818 1819 public IIOMetadata getImageMetadata(int imageIndex) throws IIOException { 1820 if (imageIndex != 0) { 1821 throw new IndexOutOfBoundsException("imageIndex != 0!"); 1822 } 1823 readMetadata(); 1824 return metadata; 1825 } 1826 1827 public BufferedImage read(int imageIndex, ImageReadParam param) 1828 throws IIOException { 1829 if (imageIndex != 0) { 1830 throw new IndexOutOfBoundsException("imageIndex != 0!"); 1831 } 1832 1833 try { 1834 readImage(param); 1835 } catch (IOException | 1836 IllegalStateException | 1837 IllegalArgumentException e) 1838 { 1839 throw e; 1840 } catch (Throwable e) { 1841 throw new IIOException("Caught exception during read: ", e); 1842 } 1843 return theImage; 1844 } 1845 1846 public void reset() { 1847 super.reset(); 1848 resetStreamSettings(); 1849 } 1850 1851 private void resetStreamSettings() { 1852 gotHeader = false; 1853 gotMetadata = false; 1854 metadata = null; 1855 pixelStream = null; 1856 imageStartPosition = -1L; 1857 } 1858 }