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/*
* The MIT License (MIT)
*
* Copyright (c) 2023-2024 Daniel Alievsky, AlgART Laboratory (http://algart.net)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
package net.algart.matrices.tiff;
import net.algart.arrays.*;
import net.algart.matrices.tiff.codecs.TiffCodec;
import net.algart.matrices.tiff.data.TiffJPEGDecodingHelper;
import net.algart.matrices.tiff.data.TiffUnpacking;
import net.algart.matrices.tiff.data.TiffPrediction;
import net.algart.matrices.tiff.data.TiffUnusualPrecisions;
import net.algart.matrices.tiff.tags.TagCompression;
import net.algart.matrices.tiff.tags.TagRational;
import net.algart.matrices.tiff.tags.TagTypes;
import net.algart.matrices.tiff.tags.Tags;
import net.algart.matrices.tiff.tiles.TiffMap;
import net.algart.matrices.tiff.tiles.TiffTile;
import net.algart.matrices.tiff.tiles.TiffTileIO;
import net.algart.matrices.tiff.tiles.TiffTileIndex;
import org.scijava.Context;
import org.scijava.io.handle.BytesHandle;
import org.scijava.io.handle.DataHandle;
import org.scijava.io.handle.FileHandle;
import org.scijava.io.handle.ReadBufferDataHandle;
import org.scijava.io.location.BytesLocation;
import org.scijava.io.location.FileLocation;
import org.scijava.io.location.Location;
import java.io.Closeable;
import java.io.FileNotFoundException;
import java.io.IOException;
import java.lang.reflect.InvocationTargetException;
import java.net.URI;
import java.nio.ByteOrder;
import java.nio.charset.StandardCharsets;
import java.nio.file.Files;
import java.nio.file.Path;
import java.util.Arrays;
import java.util.*;
import java.util.concurrent.atomic.AtomicBoolean;
import java.util.function.Consumer;
import java.util.stream.Collectors;
/**
* Reads TIFF format.
*
* This object is internally synchronized and thread-safe when used in multi-threaded environment.
* However, you should not modify objects, passed to the methods of this class from a parallel thread;
* first of all, it concerns the {@link TiffIFD} arguments of many methods.
* The same is true for the result of {@link #stream()} method.
*/
public class TiffReader implements Closeable {
// Creating this class started from reworking SCIFIO TiffParser class.
// Below is a copy of list of its authors and of the SCIFIO license for that class.
// (It is placed here to avoid autocorrection by IntelliJ IDEA)
/*
* @author Curtis Rueden
* @author Eric Kjellman
* @author Melissa Linkert
* @author Chris Allan
*
* #%L
* SCIFIO library for reading and converting scientific file formats.
* %%
* Copyright (C) 2011 - 2023 SCIFIO developers.
* %%
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
* #L%
*/
/**
* IFD with number of entries, greater than this limit, is not allowed:
* it is mostly probable that it is corrupted file.
*/
public static final int MAX_NUMBER_OF_IFD_ENTRIES = 1_000_000;
/**
* The number of bytes in each IFD entry.
*/
public static final int BYTES_PER_ENTRY = 12;
/**
* The number of bytes in each IFD entry of a BigTIFF file.
*/
public static final int BIG_TIFF_BYTES_PER_ENTRY = 20;
// TIFF header constants
public static final int FILE_USUAL_MAGIC_NUMBER = 42;
public static final int FILE_BIG_TIFF_MAGIC_NUMBER = 43;
public static final int FILE_PREFIX_LITTLE_ENDIAN = 0x49;
public static final int FILE_PREFIX_BIG_ENDIAN = 0x4d;
private static final boolean OPTIMIZE_READING_IFD_ARRAYS = true;
// - Note: this optimization allows to speed up reading large array of offsets.
// If we use simple FileHandle for reading file (based on RandomAccessFile),
// acceleration is up to 100 and more times:
// on my computer, 23220 int32 values were loaded in 0.2 ms instead of 570 ms.
// Since scijava-common 2.95.1, we use optimized ReadBufferDataHandle for reading file;
// now acceleration for 23220 int32 values is 0.2 ms instead of 0.4 ms.
static final boolean USE_LEGACY_UNPACK_BYTES = false;
// - Should be false for better performance; necessary for debugging needs only
// (together with uncommenting unpackBytesLegacy call)
static final boolean BUILT_IN_TIMING = getBooleanProperty("net.algart.matrices.tiff.timing");
private static final int MINIMAL_ALLOWED_TIFF_FILE_LENGTH = 8 + 2 + 12 + 4;
// - 8 bytes header + at least 1 IFD entry (usually at least 2 entries required: ImageWidth + ImageLength);
// this constant should be > 16 to detect "dummy" BigTIFF file, containing header only
private static final System.Logger LOG = System.getLogger(TiffReader.class.getName());
private static final boolean LOGGABLE_DEBUG = LOG.isLoggable(System.Logger.Level.DEBUG);
private boolean requireValidTiff;
private boolean interleaveResults = false;
private boolean autoUnpackBitsToBytes = false;
private boolean autoUnpackUnusualPrecisions = true;
private boolean autoScaleWhenIncreasingBitDepth = true;
private boolean autoCorrectInvertedBrightness = false;
private boolean enforceUseExternalCodec = false;
private boolean cropTilesToImageBoundaries = true;
private boolean cachingIFDs = true;
private boolean missingTilesAllowed = false;
private byte byteFiller = 0;
private volatile Context context = null;
private final Exception openingException;
private final DataHandle in;
private final boolean valid;
private final boolean bigTiff;
/**
* Cached list of IFDs in the current file.
*/
private volatile List ifds;
/**
* Cached first IFD in the current file.
*/
private volatile TiffIFD firstIFD;
private volatile Object scifio = null;
private final Object fileLock = new Object();
private TiffCodec.Options codecOptions = new TiffCodec.Options();
private volatile long positionOfLastIFDOffset = -1;
private long timeReading = 0;
private long timeCustomizingDecoding = 0;
private long timeDecoding = 0;
private long timeDecodingMain = 0;
private long timeDecodingBridge = 0;
private long timeDecodingAdditional = 0;
private long timeCompleteDecoding = 0;
public TiffReader(Path file) throws IOException {
this(file, true);
}
public TiffReader(Path file, boolean requireValidTiff) throws IOException {
this(getExistingFileHandle(file), requireValidTiff, true);
}
/**
* Equivalent to {@link #TiffReader(DataHandle, boolean, boolean)} with false last argument.
* Note that you should not call this constructor from another constructor, creating this
* DataHandle: in this case, the handle will never be closed!
*
* @param inputStream input stream; automatically replaced (wrapped) with {@link ReadBufferDataHandle},
* if this stream is still not an instance of this class.
* @param requireValidTiff whether the input file must exist and be a readable TIFF-file
* with a correct header.
* @throws TiffException if the file is not a correct TIFF file
* @throws IOException in a case of any problems with the input file
*/
public TiffReader(DataHandle inputStream, boolean requireValidTiff) throws IOException {
this(inputStream, requireValidTiff, false);
}
/**
* Constructs new reader.
*
* If requireValidTiff is true (standard variant), it will throw an exception
* in a case of incorrect TIFF header or some other I/O errors.
* In this case, closeStreamOnException flag specifies, whether this function
* must close the input stream or no. It should be true when you call this constructor
* from another constructor, which creates DataHandle: it is the only way to close
* an invalid file. In other situation this flag may be false, then you must close
* the input stream yourself.
*
*
If requireValidTiff is false, all exceptions are caught and not thrown,
* and {@link #isValid()} method will return false.
* In this case, you can know the occurred exception by {@link #openingException()} method.
*
* @param inputStream input stream; automatically replaced (wrapped) with {@link ReadBufferDataHandle},
* if this stream is still not an instance of this class.
* @param requireValidTiff whether the input file must exist and be a readable TIFF-file
* with a correct header.
* @param closeStreamOnException if true, the input stream is closed in a case of any exception;
* ignored if requireValidTiff is false.
* @throws TiffException if the file is not a correct TIFF file.
* @throws IOException in a case of any problems with the input file.
*/
public TiffReader(DataHandle inputStream, boolean requireValidTiff, boolean closeStreamOnException)
throws IOException {
this(inputStream, null);
this.requireValidTiff = requireValidTiff;
if (requireValidTiff && openingException != null) {
if (closeStreamOnException) {
try {
inputStream.close();
} catch (Exception ignored) {
}
}
if (openingException instanceof IOException e) {
throw e;
}
if (openingException instanceof RuntimeException e) {
throw e;
}
throw new TiffException(openingException);
}
}
/**
* Universal constructor, called from other constructors.
*
* Unlike other constructors, this one never throws an exception. This is helpful, because allows
* to make constructors in subclasses, which do not declare any exceptions to be thrown.
*
*
If the file is not a correct TIFF or in a case of any other I/O problem,
* the information about the problem is stored in an exception, which can be retrieved later
* by {@link #openingException()} method and which is passed to exceptionHandler
* (if it is not {@code null}).
*
* @param inputStream input stream; automatically replaced (wrapped) with {@link ReadBufferDataHandle},
* if this stream is still not an instance of this class.
* @param exceptionHandler if not {@code null}, it will be called in a case of some checked exception;
* for example, it may log it. But usually it is better idea to use the main
* constructor {@link #TiffReader(DataHandle, boolean, boolean)} with catching exception.
*/
public TiffReader(DataHandle inputStream, Consumer exceptionHandler) {
Objects.requireNonNull(inputStream, "Null in stream");
this.requireValidTiff = false;
this.in = inputStream instanceof ReadBufferDataHandle ?
inputStream :
new ReadBufferDataHandle<>(inputStream);
AtomicBoolean bigTiff = new AtomicBoolean(false);
this.openingException = startReading(bigTiff);
this.valid = openingException == null;
this.bigTiff = bigTiff.get();
if (exceptionHandler != null) {
exceptionHandler.accept(openingException);
}
}
public boolean isRequireValidTiff() {
return requireValidTiff;
}
/**
* Sets whether the parser should always require valid TIFF format.
* Default value is specified in the constructor or is false
* when using a constructor without such argument.
*
* @param requireValidTiff whether TIFF file should be correct.
* @return a reference to this object.
*/
public TiffReader setRequireValidTiff(boolean requireValidTiff) {
this.requireValidTiff = requireValidTiff;
return this;
}
public boolean isInterleaveResults() {
return interleaveResults;
}
/**
* Sets the interleave mode: the loaded samples will be returned in chunked form, for example, RGBRGBRGB...
* in a case of RGB image. If not set (default behaviour), the samples are returned in unpacked form:
* RRR...GGG...BBB...
*
* @param interleaveResults new interleaving mode.
* @return a reference to this object.
*/
public TiffReader setInterleaveResults(boolean interleaveResults) {
this.interleaveResults = interleaveResults;
return this;
}
public boolean isAutoUnpackBitsToBytes() {
return autoUnpackBitsToBytes;
}
/**
* Sets the flag, whether do we need to unpack binary images (1 bit/pixel, black-and-white images)
* into byte matrices: black pixels to the value 0, white pixels to the value 255.
*
* By default this flag is cleared. In this case, {@link #readMatrix(TiffMap)} and similar methods return
* binary AlgART matrices.
*
* Note that TIFF images, using m>1 bit per pixel where m is not divisible by 8,
* for example 4-bit indexed images with a palette or 15-bit RGB image, 5+5+5 bits/channel,
* are always unpacked to format with an integer number of bytes per channel (m=8*k).
* The only exception is 1-bit monochrome images: in this case, unpacking into bytes depends
* is controlled by this method.
*
* @param autoUnpackBitsToBytes whether do we need to unpack bit matrices to byte ones (0->0, 1->255).
* @return a reference to this object.
*/
public TiffReader setAutoUnpackBitsToBytes(boolean autoUnpackBitsToBytes) {
this.autoUnpackBitsToBytes = autoUnpackBitsToBytes;
return this;
}
public boolean isAutoUnpackUnusualPrecisions() {
return autoUnpackUnusualPrecisions;
}
/**
* Sets the flag, whether do we need to automatically unpack precisions (bits/sample), differ than all precisions
* supported by {@link TiffSampleType} class. These are 3-byte samples (17..24 bits/sample;
* this flag enforces unpacking them to 32 bit) and 16- or 24-bit floating-point formats
* (this flag enforces unpacking them to 32 bit {@code float} values).
*
* This flag is used after reading all tiles inside {@link #readSamples(TiffMap, int, int, int, int)}
* method. Note that the data in {@link TiffTile}, in the case of unusual precision, are never unpacked.
* On the other hand, all other precisions, like 4-bit or 12-bit (but not 1-channel 1-bit case),
* are always unpacked into the nearest bit depth divided by 8 while decoding tiles.
*
* If this flag is {@code false}, you cannot used high-level reading methods as
* {@link #readMatrix} and {@link #readJavaArray}; you must use {@link #readSamples} methods,
* which return pixels as a sequences of bytes.
*
* This flag is {@code true} by default. Usually there are not reasons to set it to {@code false},
* besides compatibility reasons or requirement to maximally save memory while processing 16/24-bit
* float values.
*
* @param autoUnpackUnusualPrecisions whether do we need to unpack unusual precisions.
* @return a reference to this object.
* @see #completeDecoding(TiffTile)
* @see TiffMap#bitsPerUnpackedSample()
*/
public TiffReader setAutoUnpackUnusualPrecisions(boolean autoUnpackUnusualPrecisions) {
this.autoUnpackUnusualPrecisions = autoUnpackUnusualPrecisions;
return this;
}
public boolean isAutoScaleWhenIncreasingBitDepth() {
return autoScaleWhenIncreasingBitDepth;
}
/**
* Sets the flag, whether do we need to scale pixel sample values when automatic increasing bit depths,
* for example, when we decode 12-bit grayscale image into 16-bit result.
*
* This class can successfully read TIFF with bit depths not divided by 8, such as 4-bit, 12-bit images or
* 5+5+5 "HiRes" RGB images. But the data returned by this class is always represented by 8-bit, 16-bit,
* 32-bit integer values (signed or unsigned) or by 32- or 64-bit floating-point values
* (these bit depths correspond to Java primitive types). If the source pixel values have another bit depth,
* they are automatically converted to the nearest "larger" type, for example, 4-bit integer is converted
* to 8-bit, 12-bit integer is converted to 16-bit, 24-bit to 32-bit.
*
* If this flag is false, this conversion is performed "as-is", so, values 0..15 in 4-bit source
* data will be converted to the same values 0..15 with 8-bit precision.
* This is good if you need to process these values using some kind of algorithm.
* However, if you need to show the real picture to the end user, then values 0..15 with 8-bit
* precisions (or 0..4095 with 16-bit precision) will look almost black. To avoid this,
* you can use true
* value of this flag, which causes automatic scaling returned values: multiplying by
* (2n−1)/(2k−1), where n is the result bit depth
* and k is the source one (for example, for 12-bit image k=12 and n=16).
* As the result, the returned picture will look alike the source one.
*
* Default value is true. However, the scaling is still not performed if
* PhotometricInterpretation TIFF tag is "Palette" (3) or "Transparency Mask" (4): in these cases
* scaling has no sense.
*
* @param autoScaleWhenIncreasingBitDepth whether do we need to scale pixel samples, represented with k
* bits/sample, k%8 ≠ 0, when increasing bit depth
* to nearest n bits/sample, where
* n > k and n is divided by 8.
* @return a reference to this object.
*/
public TiffReader setAutoScaleWhenIncreasingBitDepth(boolean autoScaleWhenIncreasingBitDepth) {
this.autoScaleWhenIncreasingBitDepth = autoScaleWhenIncreasingBitDepth;
return this;
}
public boolean isAutoCorrectInvertedBrightness() {
return autoCorrectInvertedBrightness;
}
/**
* Sets the flag, whether do we need to automatically correct (invert) pixel sample values in color spaces
* with inverted sense of pixel brightness, i.e. when PhotometricInterpretation TIFF tag is "WhiteIsZero" (0)
* or "Separated" (CMYK, 5). (In these color spaces, white color is encoded as zero, and black color is encoded
* as maximal allowed value like 255 for 8-bit samples.)
* Note that this flag do not provide correct processing CMYK color model
* and absolutely useless for more complex color spaces like CIELAB, but for PhotometricInterpretation=0 or 5
* it helps to provide RGB results more similar to the correct picture.
*
*
Default value is false. You may set it to true if the only goal of reading TIFF
* is to show the image to a user.
*
* @param autoCorrectInvertedBrightness whether do we need to invert samples for "WhiteIsZero" and "CMYK"
* photometric interpretations.
* @return a reference to this object.
*/
public TiffReader setAutoCorrectInvertedBrightness(boolean autoCorrectInvertedBrightness) {
this.autoCorrectInvertedBrightness = autoCorrectInvertedBrightness;
return this;
}
public boolean isEnforceUseExternalCodec() {
return enforceUseExternalCodec;
}
public TiffReader setEnforceUseExternalCodec(boolean enforceUseExternalCodec) {
this.enforceUseExternalCodec = enforceUseExternalCodec;
return this;
}
public boolean isCropTilesToImageBoundaries() {
return cropTilesToImageBoundaries;
}
public TiffReader setCropTilesToImageBoundaries(boolean cropTilesToImageBoundaries) {
this.cropTilesToImageBoundaries = cropTilesToImageBoundaries;
return this;
}
/**
* Retrieves the current set of codec options being used to decompress pixel
* data.
*
* @return See above.
*/
public TiffCodec.Options getCodecOptions() {
return codecOptions.clone();
}
/**
* Sets the codec options to be used when decompressing pixel data.
*
* @param codecOptions Codec options to use.
* @return a reference to this object.
*/
public TiffReader setCodecOptions(TiffCodec.Options codecOptions) {
this.codecOptions = Objects.requireNonNull(codecOptions, "Null codecOptions").clone();
return this;
}
public boolean isCachingIFDs() {
return cachingIFDs;
}
/**
* Sets whether IFD entries, returned by {@link #allIFDs()} method, should be cached.
*
*
Default value is true. Possible reason to set is to false
* is reading file which is dynamically modified.
* In other cases, usually it should be true, though false value
* also works well if you are not going to call {@link #allIFDs()} more than once.
*
* @param cachingIFDs whether caching IFD is enabled.
* @return a reference to this object.
*/
public TiffReader setCachingIFDs(final boolean cachingIFDs) {
this.cachingIFDs = cachingIFDs;
return this;
}
public boolean isMissingTilesAllowed() {
return missingTilesAllowed;
}
/**
* Sets the special mode, when TIFF file is allowed to contain "missing" tiles or strips,
* for which the offset (TileOffsets or StripOffsets tag) and/or
* byte count (TileByteCounts or StripByteCounts tag) contains zero value.
* In this mode, such tiles/strips will be successfully read as empty rectangles, filled by
* the {@link #setByteFiller(byte) default filler}.
*
*
Default value is false. In this case, such tiles/strips are not allowed,
* as the standard TIFF format requires.
*
* @param missingTilesAllowed whether "missing" tiles/strips are allowed.
* @return a reference to this object.
*/
public TiffReader setMissingTilesAllowed(boolean missingTilesAllowed) {
this.missingTilesAllowed = missingTilesAllowed;
return this;
}
public byte getByteFiller() {
return byteFiller;
}
/**
* Sets the filler byte for tiles, lying completely outside the image.
* Value 0 means black color, 0xFF usually means white color.
*
*
Warning! If you want to work with non-8-bit TIFF, especially float precision, you should
* preserve default 0 value, in another case results could be very strange.
*
* @param byteFiller new filler.
* @return a reference to this object.
*/
public TiffReader setByteFiller(byte byteFiller) {
this.byteFiller = byteFiller;
return this;
}
public Context getContext() {
return context;
}
public TiffReader setContext(Context context) {
this.scifio = null;
this.context = context;
return this;
}
/**
* Gets the stream from which TIFF data is being parsed.
*/
public DataHandle stream() {
synchronized (fileLock) {
// - we prefer not to return this stream in the middle of I/O operations
return in;
}
}
public boolean isValid() {
return valid;
}
public Exception openingException() {
return openingException;
}
/**
* Returns whether the current TIFF file contains BigTIFF data.
*/
public boolean isBigTiff() {
return bigTiff;
}
/**
* Returns whether we are reading little-endian data.
*/
public boolean isLittleEndian() {
return in.isLittleEndian();
}
/**
* Returns {@link #isLittleEndian()} ? ByteOrder.LITTLE_ENDIAN : ByteOrder.BIG_ENDIAN.
*/
public ByteOrder byteOrder() {
return isLittleEndian() ? ByteOrder.LITTLE_ENDIAN : ByteOrder.BIG_ENDIAN;
}
/**
* Returns position in the file of the last IFD offset, loaded by {@link #readIFDOffsets()},
* {@link #readSingleIFDOffset(int)} or {@link #readFirstIFDOffset()} methods.
* Usually it is just a position of the offset of the last IFD, because
* popular {@link #allIFDs()} method calls {@link #readIFDOffsets()} inside.
*
* Immediately after creating new object this position is -1.
*
* @return file position of the last IFD offset.
*/
public long positionOfLastIFDOffset() {
return positionOfLastIFDOffset;
}
/**
* Returns {@link #allIFDs()}.size().
*
* @return number of existing IFDs.
* @throws TiffException if the file is not a correct TIFF file.
* @throws IOException in a case of any problems with the input file.
*/
public int numberOfIFDs() throws IOException {
return allIFDs().size();
}
/**
* Equivalent to {@link #newMap(TiffIFD) newMap}({@link #ifd(int) ifd}(ifdIndex)).
*
* @param ifdIndex index of IFD.
* @return TIFF map, allowing to read this IFD
* @throws TiffException if ifdIndex is too large,
* or if the file is not a correct TIFF file
* and this was not detected while opening it.
* @throws IOException in a case of any problems with the input file.
* @throws IllegalArgumentException if ifdIndex<0.
*/
public TiffMap map(int ifdIndex) throws IOException {
return newMap(ifd(ifdIndex));
}
/**
* Calls {@link #allIFDs()} and returns IFD with the specified index.
* If ifdIndex is too big (≥{@link #numberOfIFDs()}), this method throws
* {@link TiffException}.
*
* @param ifdIndex index of IFD.
* @return the IFD with the specified index.
* @throws TiffException if ifdIndex is too large,
* or if the file is not a correct TIFF file
* and this was not detected while opening it.
* @throws IOException in a case of any problems with the input file.
* @throws IllegalArgumentException if ifdIndex<0.
*/
public TiffIFD ifd(int ifdIndex) throws IOException {
List ifdList = allIFDs();
if (ifdIndex < 0) {
throw new IllegalArgumentException("Negative IFD index " + ifdIndex);
}
if (ifdIndex >= ifdList.size()) {
throw new TiffException(
"IFD index " + ifdIndex + " is out of bounds 0 <= index < " + ifdList.size());
}
return ifdList.get(ifdIndex);
}
/**
* Reads 1st IFD (#0).
*
* Note: this method does not use {@link #allIFDs()} method.
* If you really needs access only to 1st IFD,
* this method may work faster than {@link #ifd(int)}.
*/
public TiffIFD firstIFD() throws IOException {
TiffIFD firstIFD = this.firstIFD;
if (cachingIFDs && firstIFD != null) {
return this.firstIFD;
}
final long offset = readFirstIFDOffset();
firstIFD = readIFDAt(offset);
if (cachingIFDs) {
this.firstIFD = firstIFD;
}
return firstIFD;
}
public List allMaps() throws IOException {
return allIFDs().stream().map(this::newMap).toList();
}
/**
* Returns all IFDs in the file in unmodifiable list.
* When first called, reads all IFD from the file
* (but this can be disabled using {@link #setCachingIFDs(boolean)} method).
*
* Note: if this TIFF file is not valid ({@link #isValid()} returns false), this method
* returns an empty list and does not throw an exception. For valid TIFF, result cannot be empty.
*
* @throws TiffException if the file is not a correct TIFF file, but this was not detected while opening it.
* @throws IOException in a case of any problems with the input file.
*/
public List allIFDs() throws IOException {
long t1 = debugTime();
List ifds;
synchronized (fileLock) {
// - this synchronization is not necessary, but helps
// to be sure that the client will not try to read TIFF images
// when all IFD are not fully loaded and checked
ifds = this.ifds;
if (cachingIFDs && ifds != null) {
return ifds;
}
final long[] offsets = readIFDOffsets();
ifds = new ArrayList<>();
for (final long offset : offsets) {
final TiffIFD ifd = readIFDAt(offset);
assert ifd != null;
ifds.add(ifd);
long[] subOffsets = null;
try {
// Deprecated solution: "fillInIFD" technique is no longer used
// if (!cachingIFDs && ifd.containsKey(IFD.SUB_IFD)) {
// fillInIFD(ifd);
// }
subOffsets = ifd.getLongArray(Tags.SUB_IFD);
} catch (final TiffException ignored) {
}
if (subOffsets != null) {
for (final long subOffset : subOffsets) {
final TiffIFD sub = readIFDAt(subOffset, Tags.SUB_IFD, false);
if (sub != null) {
ifds.add(sub);
}
}
}
}
if (cachingIFDs) {
this.ifds = Collections.unmodifiableList(ifds);
}
}
if (BUILT_IN_TIMING && LOGGABLE_DEBUG) {
long t2 = debugTime();
LOG.log(System.Logger.Level.DEBUG, String.format(Locale.US,
"%s read %d IFDs: %.3f ms",
getClass().getSimpleName(), ifds.size(),
(t2 - t1) * 1e-6));
}
return ifds;
}
/**
* Returns EXIF IFDs.
*/
public List exifIFDs() throws IOException {
final List ifds = allIFDs();
final List result = new ArrayList<>();
for (final TiffIFD ifd : ifds) {
final long offset = ifd.getLong(Tags.EXIF, 0);
if (offset != 0) {
final TiffIFD exifIFD = readIFDAt(offset, Tags.EXIF, false);
if (exifIFD != null) {
result.add(exifIFD);
}
}
}
return result;
}
/**
* Gets offset to the first IFD.
* Updates {@link #positionOfLastIFDOffset()} to the position of first offset (4, for Bit-TIFF 8).
*/
public long readFirstIFDOffset() throws IOException {
synchronized (fileLock) {
in.seek(bigTiff ? 8 : 4);
return readFirstOffsetFromCurrentPosition(true, this.bigTiff);
}
}
/**
* Returns the file offset of IFD with given index or -1 if the index is too high.
* Updates {@link #positionOfLastIFDOffset()} to position of this offset.
*
* @param ifdIndex index of IFD (0, 1, ...).
* @return offset of this IFD in the file or -1 if the index is too high.
*/
public long readSingleIFDOffset(int ifdIndex) throws IOException {
if (ifdIndex < 0) {
throw new IllegalArgumentException("Negative ifdIndex = " + ifdIndex);
}
synchronized (fileLock) {
final long fileLength = in.length();
long offset = readFirstIFDOffset();
while (offset > 0 && offset < fileLength) {
if (ifdIndex-- <= 0) {
return offset;
}
in.seek(offset);
skipIFDEntries(fileLength);
final long newOffset = readNextOffset(true);
if (newOffset == offset) {
throw new TiffException("TIFF file is broken - infinite loop of IFD offsets is detected " +
"for offset " + offset);
}
offset = newOffset;
}
return -1;
}
}
/**
* Gets the offsets to every IFD in the file.
*
* Note: if this TIFF file is not valid ({@link #isValid()} returns false), this method
* returns an empty array and does not throw an exception. For valid TIFF, result cannot be empty.
*/
public long[] readIFDOffsets() throws IOException {
synchronized (fileLock) {
if (!requireValidTiff && !valid) {
return new long[0];
}
final long fileLength = in.length();
final LinkedHashSet ifdOffsets = new LinkedHashSet<>();
long offset = readFirstIFDOffset();
while (offset > 0 && offset < fileLength) {
in.seek(offset);
final boolean wasNotPresent = ifdOffsets.add(offset);
if (!wasNotPresent) {
throw new TiffException("TIFF file is broken - infinite loop of IFD offsets is detected " +
"for offset " + offset + " (the stored ifdOffsets sequence is " +
ifdOffsets.stream().map(Object::toString).collect(Collectors.joining(", ")) +
", " + offset + ", ...)");
}
skipIFDEntries(fileLength);
offset = readNextOffset(true);
}
if (requireValidTiff && ifdOffsets.isEmpty()) {
throw new AssertionError("No IFDs, but it was not checked in readFirstIFDOffset");
}
return ifdOffsets.stream().mapToLong(v -> v).toArray();
}
}
public TiffIFD readSingleIFD(int ifdIndex) throws IOException, NoSuchElementException {
long startOffset = readSingleIFDOffset(ifdIndex);
if (startOffset < 0) {
throw new NoSuchElementException("No IFD #" + ifdIndex + " in TIFF" + prettyInName()
+ ": too large index");
}
return readIFDAt(startOffset);
}
/**
* Reads the IFD stored at the given offset.
* Never returns {@code null}.
*/
public TiffIFD readIFDAt(long startOffset) throws IOException {
return readIFDAt(startOffset, null, true);
}
public TiffIFD readIFDAt(final long startOffset, Integer subIFDType, boolean readNextOffset) throws IOException {
if (startOffset < 0) {
throw new IllegalArgumentException("Negative file offset = " + startOffset);
}
if (startOffset < (bigTiff ? 16 : 8)) {
throw new IllegalArgumentException("Attempt to read IFD from too small start offset " + startOffset);
}
long t1 = debugTime();
long timeEntries = 0;
long timeArrays = 0;
final TiffIFD ifd;
synchronized (fileLock) {
if (startOffset >= in.length()) {
throw new TiffException("TIFF IFD offset " + startOffset + " is outside the file");
}
final Map map = new LinkedHashMap<>();
final Map detailedEntries = new LinkedHashMap<>();
// read in directory entries for this IFD
in.seek(startOffset);
final long numberOfEntries = bigTiff ? in.readLong() : in.readUnsignedShort();
if (numberOfEntries < 0 || numberOfEntries > MAX_NUMBER_OF_IFD_ENTRIES) {
throw new TiffException("Too large number of IFD entries: " +
(numberOfEntries < 0 ? ">= 2^63" : numberOfEntries + " > " + MAX_NUMBER_OF_IFD_ENTRIES));
// - theoretically BigTIFF allows to have more entries, but we prefer to make some restriction;
// in any case, billions if detailedEntries will probably lead to OutOfMemoryError or integer overflow
}
final int bytesPerEntry = bigTiff ? BIG_TIFF_BYTES_PER_ENTRY : BYTES_PER_ENTRY;
final int baseOffset = bigTiff ? 8 : 2;
for (long i = 0; i < numberOfEntries; i++) {
long tEntry1 = debugTime();
in.seek(startOffset + baseOffset + bytesPerEntry * i);
final TiffIFD.TiffEntry entry = readIFDEntry();
final int tag = entry.tag();
long tEntry2 = debugTime();
timeEntries += tEntry2 - tEntry1;
final Object value = readIFDValueAtEntryOffset(in, entry);
long tEntry3 = debugTime();
timeArrays += tEntry3 - tEntry2;
// System.err.printf("%d values from %d: %.6f ms%n", valueCount, valueOffset, (tEntry3 - tEntry2) * 1e-6);
if (value != null && !map.containsKey(tag)) {
// - null value should not occur in current version;
// if this tag is present twice (strange mistake if TIFF file),
// we do not throw exception and just use the 1st entry
map.put(tag, value);
detailedEntries.put(tag, entry);
}
}
final long positionOfNextOffset = startOffset + baseOffset + bytesPerEntry * numberOfEntries;
in.seek(positionOfNextOffset);
ifd = new TiffIFD(map, detailedEntries);
ifd.setLittleEndian(in.isLittleEndian());
ifd.setBigTiff(bigTiff);
ifd.setFileOffsetForReading(startOffset);
ifd.setSubIFDType(subIFDType);
if (readNextOffset) {
final long nextOffset = readNextOffset(false);
ifd.setNextIFDOffset(nextOffset);
in.seek(positionOfNextOffset);
// - this "in.seek" provides maximal compatibility with old code (which did not read next IFD offset)
// and also with behaviour of this method, when readNextOffset is not requested
}
}
if (BUILT_IN_TIMING && LOGGABLE_DEBUG) {
long t2 = debugTime();
LOG.log(System.Logger.Level.TRACE, String.format(Locale.US,
"%s read IFD at offset %d: %.3f ms, including %.6f entries + %.6f arrays",
getClass().getSimpleName(), startOffset,
(t2 - t1) * 1e-6, timeEntries * 1e-6, timeArrays * 1e-6));
}
return ifd;
}
/**
* Reads and decodes the tile at the specified position.
* Note: the loaded tile is always {@link TiffTile#isSeparated() separated}.
*
* @param tileIndex position of the file
* @return loaded tile.
*/
public TiffTile readTile(TiffTileIndex tileIndex) throws IOException {
TiffTile tile = readEncodedTile(tileIndex);
if (tile.isEmpty()) {
return tile;
}
decode(tile);
return tile;
}
public TiffTile readEncodedTile(TiffTileIndex tileIndex) throws IOException {
Objects.requireNonNull(tileIndex, "Null tileIndex");
long t1 = debugTime();
final TiffIFD ifd = tileIndex.ifd();
final int index = tileIndex.linearIndex();
// - also checks that tile index is not out of image bounds
final long offset = ifd.cachedTileOrStripOffset(index);
assert offset >= 0 : "offset " + offset + " was not checked in TiffIFD";
final int byteCount = cachedByteCountWithCompatibilityTrick(ifd, index);
/*
// Some strange old code, seems to be useless
final int rowsPerStrip = ifd.cachedStripSizeY();
final int bytesPerSample = ifd.getBytesPerSampleBasedOnBits();
if (byteCount == ((long) rowsPerStrip * tileSizeX) && bytesPerSample > 1) {
byteCount *= bytesPerSample;
}
if (byteCount >= Integer.MAX_VALUE) {
throw new FormatException("Too large tile/strip #" + index + ": " + byteCount + " bytes > 2^31-1");
}
*/
final TiffTile result = new TiffTile(tileIndex);
// - No reasons to put it into the map: this class do not provide access to temporary created map.
if (cropTilesToImageBoundaries) {
result.cropToMap();
}
// If cropping is disabled, we should not avoid reading extra content of the last strip.
// Note the last encoded strip can have actually full strip sizes,
// i.e. larger than necessary; this situation is quite possible.
if (byteCount == 0 || offset == 0) {
if (missingTilesAllowed) {
return result;
} else {
throw new TiffException("Zero tile/strip " + (byteCount == 0 ? "byte-count" : "offset")
+ " is not allowed in a valid TIFF file (tile " + tileIndex + ")");
}
}
synchronized (fileLock) {
if (offset >= in.length()) {
throw new TiffException("Offset of TIFF tile/strip " + offset + " is out of file length (tile " +
tileIndex + ")");
// - note: old SCIFIO code allowed such offsets and returned zero-filled tile
}
TiffTileIO.read(result, in, offset, byteCount);
}
long t2 = debugTime();
timeReading += t2 - t1;
return result;
}
// Note: result is usually interleaved (RGBRGB...) or monochrome; it is always so in UNCOMPRESSED, LZW, DEFLATE
public void decode(TiffTile tile) throws TiffException {
Objects.requireNonNull(tile, "Null tile");
long t1 = debugTime();
prepareTileForDecoding(tile);
final TagCompression compression = TagCompression.valueOfCodeOrNull(tile.ifd().getCompressionCode());
TiffCodec codec = null;
if (!enforceUseExternalCodec && compression != null) {
codec = compression.codec();
// - we are sure that this codec does not require SCIFIO context
}
TiffCodec.Options options = buildOptions(tile);
long t2 = debugTime();
if (codec != null) {
options = compression.customizeReading(tile, options);
if (USE_LEGACY_UNPACK_BYTES) {
options.setInterleaved(true);
// - old-style unpackBytes does not "understand" already-separated tiles
}
if (codec instanceof TiffCodec.Timing timing) {
timing.setTiming(BUILT_IN_TIMING && LOGGABLE_DEBUG);
timing.clearTiming();
}
final byte[] decodedData = codec.decompress(tile.getEncodedData(), options);
tile.setPartiallyDecodedData(decodedData);
} else {
final Optional decodedData = decodeByExternalCodec(tile, tile.getEncodedData(), options);
if (decodedData.isEmpty()) {
throw new UnsupportedTiffFormatException("TIFF compression with code " +
tile.ifd().getCompressionCode() + " cannot be decoded: " + tile.ifd());
}
tile.setPartiallyDecodedData(decodedData.get());
}
tile.setInterleaved(options.isInterleaved());
long t3 = debugTime();
completeDecoding(tile);
long t4 = debugTime();
timeCustomizingDecoding += t2 - t1;
timeDecoding += t3 - t2;
if (codec instanceof TiffCodec.Timing timing) {
timeDecodingMain += timing.timeMain();
timeDecodingBridge += timing.timeBridge();
timeDecodingAdditional += timing.timeAdditional();
} else {
timeDecodingMain += t3 - t2;
}
timeCompleteDecoding += t4 - t3;
}
public void prepareTileForDecoding(TiffTile tile) throws TiffException {
Objects.requireNonNull(tile, "Null tile");
if (tile.isEmpty()) {
// - unlike full decoding, here it is better not to throw exception for empty tile
return;
}
if (tile.ifd().isReversedFillOrder()) {
PackedBitArraysPer8.reverseBitOrderInPlace(tile.getData());
}
boolean throwExceptionForStrangeDataStream = context != null;
// - if context == null, there are no available external codecs; later we will throw a correct exception
TiffJPEGDecodingHelper.embedJPEGTableInDataIfRequested(tile, throwExceptionForStrangeDataStream);
}
/**
* Completes decoding tile after decoding by some {@link TiffCodec}. This method is automatically called
* at the end of {@link #decode(TiffTile)} method.
*
* First of all, this method always rearranges data in the file: if the codec returned
* {@link TiffTile#isInterleaved() interleaved} data, this method
* {@link TiffTile#separateSamplesIfNecessary() separates} them.
* Interleaved data are the standard for internal pixel storage for simple formats like
* {@link TagCompression#LZW} and may be returned by complex codecs like {@link TagCompression#JPEG_2000_LOSSLESS}.
*
*
This method does 3 other corrections for some standard compression algorithms:
*
* - {@link TagCompression#UNCOMPRESSED},
* - {@link TagCompression#LZW},
* - {@link TagCompression#DEFLATE},
* - {@link TagCompression#PACK_BITS}.
*
*
* 1st correction: unpacking. TIFF supports storing pixel samples in any number of bits,
* not always divisible by 8, in other words, one pixel sample can occupy non-integer number of bytes.
* Most useful from these cases is 1-bit monochrome picture, where 8 pixels are packed into 1 byte.
* Sometimes the pictures with 4 bits/pixels (monochrome or with palette) or 3*4=12 bits/pixels (RGB) appear.
* You can also meet old RGB 32-bit images with 5+5+5 or 5+6+5 bits/channel.
*
* However, the API of this class represents any image as a sequence of bytes. This method performs
* all necessary unpacking so that the result image use an integer number of bytes per each pixel sample (channel).
* For example, 1-bit binary image is converted to 8-bit: 0 transformed to 0, 1 to 255;
* 4-bit grayscale image is converted by multiplying by 17 (so that maximal possible 4-bit value, 15,
* will become maximal possible 8-bit value 255=17*15); 12-bit RGB image is converted to 16-bit
* by multiplying each channel by (216−1)/(212−1), etc.
*
* 2nd correction: inversion. Some TIFF files use CMYK color space or WhiteIsZero interpretation of grayscale
* images, where dark colors are represented by smaller values and bright colors by higher, in particular,
* 0 is white, maximal value (255 for 8-bit) is black.
*
* However, the API of this class suppose that all returned images are RGB, RGBA or usual monochrome.
* Complex codecs like JPEG perform necessary conversion themselves, but the simple codecs like
* {@link TagCompression#UNCOMPRESSED} do not this correction. This is performed by this method.
* For CMYK or WhiteIsZero it means inversion of the pixel samples: v is transformed to MAX−v,
* where MAX is the maximal possible value (255 for 8-bit).
*
* 3rd correction: conversion of YCbCr color space to usual RGB. It is a rare situation, when
* the image is stored as YCbCr, however not in JPEG format, but uncompressed or, for example, as LZW.
* This method performs necessary conversion to RGB (but only if the image is exactly 8-bit).
*
* Note: this method never increase number of bytes, necessary for representing a single pixel sample.
* It can increase the number of bits per sample, but only to the nearest greater integer number of
* bytes: 1..7 bits are transformed to 8 bits/sample, 9..15 to 16 bits/sample, 17..23 to 24 bits/sample etc.
* Thus, this method does not unpack 3-byte samples (to 4-byte) and
* does not unpack 16- or 24-bit floating-point formats. These cases
* are processed after reading all tiles inside {@link #readSamples(TiffMap, int, int, int, int)}
* method, if {@link #isAutoUnpackUnusualPrecisions()} flag is set, or may be performed by external
* code with help of {@link TiffUnusualPrecisions#unpackUnusualPrecisions(byte[], TiffIFD, int, long, boolean)}
* method.
* See {@link TiffReader#setAutoUnpackUnusualPrecisions(boolean)}.
*
*
This method does not allow 5, 6, 7 or greater than 8 bytes/sample
* (but 8 bytes/sample is allowed: it is probably double precision).
*
* @param tile the tile that should be corrected.
*/
public void completeDecoding(TiffTile tile) throws TiffException {
// scifio.tiff().undifference(tile.getDecodedData(), tile.ifd());
// - this solution requires using SCIFIO context class; it is better to avoid this
TiffPrediction.unsubtractPredictionIfRequested(tile);
if (USE_LEGACY_UNPACK_BYTES) {
byte[] samples = new byte[tile.map().tileSizeInBytes()];
// TiffTools.unpackBytesLegacy(samples, 0, tile.getDecodedData(), tile.ifd());
// - uncomment this to perform debugging
tile.setDecodedData(samples);
tile.setInterleaved(false);
} else {
if (!TiffUnpacking.separateUnpackedSamples(tile)) {
if (!TiffUnpacking.separateYCbCrToRGB(tile)) {
TiffUnpacking.unpackTiffBitsAndInvertValues(tile,
autoScaleWhenIncreasingBitDepth,
autoCorrectInvertedBrightness);
}
}
}
tile.checkDataLengthAlignment();
// - Fully unpacked and separated data must be correctly aligned
/*
// The following code is equivalent to the analogous code from SCIFIO 0.46.0 and earlier version,
// which performed correction of channels with different precision in a rare case PLANAR_CONFIG_SEPARATE.
// But it is deprecated: we do not support different number of BYTES in different samples,
// and it is checked inside getBytesPerSampleBasedOnBits() method.
byte[] samples = tile.getDecodedData();
final TiffTileIndex tileIndex = tile.tileIndex();
final int tileSizeX = tileIndex.tileSizeX();
final int tileSizeY = tileIndex.tileSizeY();
TiffIFD ifd = tile.ifd();
final int samplesPerPixel = ifd.getSamplesPerPixel();
final int planarConfig = ifd.getPlanarConfiguration();
final int bytesPerSample = ifd.getBytesPerSampleBasedOnBits();
final int effectiveChannels = planarConfig == TiffIFD.PLANAR_CONFIG_SEPARATE ? 1 : samplesPerPixel;
assert samples.length == ((long) tileSizeX * (long) tileSizeY * bytesPerSample * effectiveChannels);
if (planarConfig == TiffIFD.PLANAR_CONFIG_SEPARATE && !ifd.isTiled() && ifd.getSamplesPerPixel() > 1) {
final OnDemandLongArray onDemandOffsets = ifd.getOnDemandStripOffsets();
final long[] offsets = onDemandOffsets != null ? null : ifd.getStripOffsets();
final long numberOfStrips = onDemandOffsets != null ? onDemandOffsets.size() : offsets.length;
final int channel = (int) (tileIndex.y() % numberOfStrips);
int[] differentBytesPerSample = ifd.getBytesPerSample();
if (channel < differentBytesPerSample.length) {
final int realBytes = differentBytesPerSample[channel];
if (realBytes != bytesPerSample) {
// re-pack pixels to account for differing bits per sample
final boolean littleEndian = ifd.isLittleEndian();
final int[] newSamples = new int[samples.length / bytesPerSample];
for (int i = 0; i < newSamples.length; i++) {
newSamples[i] = Bytes.toInt(samples, i * realBytes, realBytes,
littleEndian);
}
for (int i = 0; i < newSamples.length; i++) {
Bytes.unpack(newSamples[i], samples, i * bytesPerSample, bytesPerSample, littleEndian);
}
}
}
}
tile.setDecodedData(samples);
*/
}
public TiffMap newMap(TiffIFD ifd) {
return TiffMap.newFixed(ifd).buildTileGrid();
// - building grid is useful to perform loops on all tiles
}
public byte[] readSamples(TiffMap map) throws IOException {
return readSamples(map, false);
}
public byte[] readSamples(TiffMap map, boolean storeTilesInMap) throws IOException {
return readSamples(map, 0, 0, map.dimX(), map.dimY(), storeTilesInMap);
}
/**
* Reads samples in byte[] array.
*
* Note: you should not change IFD in a parallel thread while calling this method.
*
* @return loaded samples in a normalized form of byte sequence.
*/
public byte[] readSamples(TiffMap map, int fromX, int fromY, int sizeX, int sizeY) throws IOException {
return readSamples(map, fromX, fromY, sizeX, sizeY, false);
}
public byte[] readSamples(TiffMap map, int fromX, int fromY, int sizeX, int sizeY, boolean storeTilesInMap)
throws IOException {
Objects.requireNonNull(map, "Null TIFF map");
long t1 = debugTime();
clearTiming();
checkRequestedArea(fromX, fromY, sizeX, sizeY);
// - note: we allow this area to be outside the image
final int numberOfChannels = map.numberOfChannels();
final TiffIFD ifd = map.ifd();
final long sizeInPixels = (long) sizeX * (long) sizeY;
// - can be >2^31 for bits
final int sizeInBytes = map.sizeOfRegionWithPossibleNonStandardPrecisions(sizeX, sizeY);
assert sizeX >= 0 && sizeY >= 0 :
"sizeOfRegionWithPossibleUnusualPrecisions didn't check sizes accurately: " + sizeX + "fromX" + sizeY;
byte[] samples = new byte[sizeInBytes];
if (byteFiller != 0) {
// - samples array is already zero-filled by Java
Arrays.fill(samples, 0, sizeInBytes, byteFiller);
}
// - important for a case when the requested area is outside the image;
// old SCIFIO code did not check this and could return undefined results
long t2 = debugTime();
readTiles(map, samples, fromX, fromY, sizeX, sizeY, storeTilesInMap);
long t3 = debugTime();
boolean interleave = false;
if (interleaveResults) {
byte[] newSamples = map.toInterleavedSamples(samples, numberOfChannels, sizeInPixels);
interleave = newSamples != samples;
samples = newSamples;
}
long t4 = debugTime();
boolean unpackingPrecision = false;
if (autoUnpackUnusualPrecisions) {
byte[] newSamples = TiffUnusualPrecisions.unpackUnusualPrecisions(
samples, ifd, numberOfChannels, sizeInPixels, autoScaleWhenIncreasingBitDepth);
unpackingPrecision = newSamples != samples;
samples = newSamples;
// - note: the size of sample array can be increased here!
}
if (autoUnpackBitsToBytes && map.isBinary()) {
unpackingPrecision = true;
samples = PackedBitArraysPer8.unpackBitsToBytes(samples, 0, sizeInPixels, (byte) 0, (byte) 255);
}
if (BUILT_IN_TIMING && LOGGABLE_DEBUG) {
long t5 = debugTime();
LOG.log(System.Logger.Level.DEBUG, String.format(Locale.US,
"%s read %dx%dx%d samples (%.3f MB) in %.3f ms = " +
"%.3f initializing + %.3f read/decode " +
"(%.3f read, %.3f customize/bit-order, %.3f decode: " +
"%.3f decode-main%s, " +
"%.3f complete)" +
"%s%s, %.3f MB/s",
getClass().getSimpleName(),
sizeX, sizeY, numberOfChannels, sizeInBytes / 1048576.0,
(t5 - t1) * 1e-6,
(t2 - t1) * 1e-6,
(t3 - t2) * 1e-6,
timeReading * 1e-6,
timeCustomizingDecoding * 1e-6,
timeDecoding * 1e-6,
timeDecodingMain * 1e-6,
timeDecodingBridge + timeDecodingAdditional > 0 ?
String.format(Locale.US, " + %.3f decode-bridge + %.3f decode-additional",
timeDecodingBridge * 1e-6,
timeDecodingAdditional * 1e-6) :
"",
timeCompleteDecoding * 1e-6,
interleave ?
String.format(Locale.US, " + %.3f interleave", (t4 - t3) * 1e-6) : "",
unpackingPrecision ?
String.format(Locale.US, " + %.3f unpacking %d-bit %s",
(t5 - t4) * 1e-6,
map.alignedBitsPerSample(),
map.sampleType().isFloatingPoint() ? "float values" : "integer values") :
"",
sizeInBytes / 1048576.0 / ((t5 - t1) * 1e-9)));
}
return samples;
}
public Object readJavaArray(TiffMap map) throws IOException {
Objects.requireNonNull(map, "Null TIFF map");
return readJavaArray(map, 0, 0, map.dimX(), map.dimY());
}
public Object readJavaArray(TiffMap map, int fromX, int fromY, int sizeX, int sizeY) throws IOException {
return readJavaArray(map, fromX, fromY, sizeX, sizeY, false);
}
public Object readJavaArray(TiffMap map, int fromX, int fromY, int sizeX, int sizeY, boolean storeTilesInMap)
throws IOException {
Objects.requireNonNull(map, "Null TIFF map");
final byte[] samples = readSamples(map, fromX, fromY, sizeX, sizeY, storeTilesInMap);
long t1 = debugTime();
final TiffSampleType sampleType = map.sampleType();
if (!autoUnpackUnusualPrecisions && map.alignedBitsPerSample() != sampleType.bitsPerSample()) {
throw new IllegalStateException("Cannot convert TIFF pixels, " + map.alignedBitsPerSample() +
" bits/sample, to \"" + sampleType.elementType() + "\" " + sampleType.bitsPerSample() +
"-bit Java type: unpacking unusual prevision mode is disabled");
}
final Object samplesArray = autoUnpackBitsToBytes && map.isBinary() ?
samples :
sampleType.javaArray(samples, byteOrder());
if (BUILT_IN_TIMING && LOGGABLE_DEBUG) {
long t2 = debugTime();
LOG.log(System.Logger.Level.DEBUG, String.format(Locale.US,
"%s converted %d bytes (%.3f MB) to %s[] in %.3f ms%s",
getClass().getSimpleName(),
samples.length, samples.length / 1048576.0,
samplesArray.getClass().getComponentType().getSimpleName(),
(t2 - t1) * 1e-6,
samples == samplesArray ?
"" :
String.format(Locale.US, " %.3f MB/s",
samples.length / 1048576.0 / ((t2 - t1) * 1e-9))));
}
return samplesArray;
}
/**
* Reads the full image with the specified index.
* The result is a 3-dimensional matrix, where each 3-dimensional layer contain one of color channels.
* However, if {@link #setInterleaveResults interleave results} flag is cleared, the result will an interleaved
* 3D matrix, which can be separated to channels by {@link Matrices#separate(ArrayContext, Matrix)} method.
* Equivalent to {@link #readMatrix(TiffMap) readMatrix}({@link #map(int) map}(ifdIndex)).
*
* @param ifdIndex index of IFD.
* @return content of the IFD image.
* @throws TiffException if ifdIndex is too large,
* or if the file is not a correct TIFF file
* and this was not detected while opening it.
* @throws IOException in a case of any problems with the input file.
* @throws IllegalArgumentException if ifdIndex<0.
*/
public Matrix readMatrix(int ifdIndex) throws IOException {
return readMatrix(map(ifdIndex));
}
public Matrix readMatrix(TiffMap map) throws IOException {
Objects.requireNonNull(map, "Null TIFF map");
return readMatrix(map, 0, 0, map.dimX(), map.dimY());
}
public Matrix readMatrix(TiffMap map, int fromX, int fromY, int sizeX, int sizeY)
throws IOException {
return readMatrix(map, fromX, fromY, sizeX, sizeY, false);
}
public Matrix readMatrix(
TiffMap map,
int fromX,
int fromY,
int sizeX,
int sizeY,
boolean storeTilesInMap)
throws IOException {
final Object samplesArray = readJavaArray(map, fromX, fromY, sizeX, sizeY, storeTilesInMap);
return TiffSampleType.asMatrix(samplesArray, sizeX, sizeY, map.numberOfChannels(), interleaveResults);
}
/**
* Reads the full image with the specified index as a list of 2-dimensional matrices containing color channels.
* For example, for RGB image the result will be a list of 3 matrices R, G, B.
* Equivalent to
* {@link #readChannels(TiffMap) readChannels}({@link #map(int) map}(ifdIndex)).
*
* @param ifdIndex index of IFD.
* @return content of the IFD image.
* @throws TiffException if ifdIndex is too large,
* or if the file is not a correct TIFF file
* and this was not detected while opening it.
* @throws IOException in a case of any problems with the input file.
* @throws IllegalArgumentException if ifdIndex<0.
*/
public List> readChannels(int ifdIndex) throws IOException {
return readChannels(map(ifdIndex));
}
public List> readChannels(TiffMap map) throws IOException {
Objects.requireNonNull(map, "Null TIFF map");
return readChannels(map, 0, 0, map.dimX(), map.dimY());
}
public List> readChannels(TiffMap map, int fromX, int fromY, int sizeX, int sizeY)
throws IOException {
return readChannels(map, fromX, fromY, sizeX, sizeY, false);
}
public List> readChannels(
TiffMap map,
int fromX,
int fromY,
int sizeX,
int sizeY,
boolean storeTilesInMap)
throws IOException {
Matrix mergedChannels = readMatrix(map, fromX, fromY, sizeX, sizeY, storeTilesInMap);
return interleaveResults ?
Matrices.separate(null, mergedChannels, TiffIFD.MAX_NUMBER_OF_CHANNELS) :
Matrices.asLayers(mergedChannels, TiffIFD.MAX_NUMBER_OF_CHANNELS);
}
public final byte[] decompressByScifioCodec(TiffIFD ifd, byte[] encodedData, Object scifioCodecOptions)
throws TiffException {
final Object scifio = requireScifio(ifd);
final int compressionCode = ifd.getCompressionCode();
final Object compression;
try {
compression = SCIFIOBridge.createTiffCompression(compressionCode);
} catch (InvocationTargetException e) {
throw new UnsupportedTiffFormatException("TIFF compression code " + compressionCode +
" is unknown and is not correctly recognized by the external SCIFIO subsystem", e);
}
try {
return SCIFIOBridge.callDecompress(scifio, compression, encodedData, scifioCodecOptions);
} catch (InvocationTargetException e) {
throw new TiffException(e.getMessage(), e.getCause());
}
}
@Override
public void close() throws IOException {
synchronized (fileLock) {
in.close();
}
}
public static long checkRequestedArea(long fromX, long fromY, long sizeX, long sizeY) {
final long result = TiffIFD.multiplySizes(sizeX, sizeY);
if (fromX != (int) fromX || fromY != (int) fromY) {
throw new IllegalArgumentException("Too large absolute values of fromX = " + fromX +
" or fromY = " + fromY + " (out of -2^31..2^31-1 ranges)");
}
if (sizeX >= Integer.MAX_VALUE - fromX || sizeY >= Integer.MAX_VALUE - fromY) {
// - Note: >= instead of > ! This allows to use "toX = fromX + sizeX" without overflow
throw new IllegalArgumentException("Requested area [" + fromX + ".." + (fromX + sizeX - 1) +
" x " + fromY + ".." + (fromY + sizeY - 1) + " is out of 0..2^31-2 ranges");
}
return result;
}
public static Context newSCIFIOContext() {
return SCIFIOBridge.getDefaultScifioContext();
}
public static DataHandle getExistingFileHandle(Path file) throws FileNotFoundException {
if (!Files.isRegularFile(file)) {
throw new FileNotFoundException("File " + file
+ (Files.exists(file) ? " is not a regular file" : " does not exist"));
}
return getFileHandle(file);
}
protected Optional decodeByExternalCodec(TiffTile tile, byte[] encodedData, TiffCodec.Options options)
throws TiffException {
Objects.requireNonNull(tile, "Null tile");
Objects.requireNonNull(encodedData, "Null encoded data");
Objects.requireNonNull(options, "Null options");
if (!SCIFIOBridge.isScifioInstalled()) {
return Optional.empty();
}
final Object scifioCodecOptions = options.toScifioStyleOptions(SCIFIOBridge.codecOptionsClass());
final byte[] decodedData = decompressByScifioCodec(tile.ifd(), encodedData, scifioCodecOptions);
return Optional.of(decodedData);
}
static DataHandle getFileHandle(Path file) {
Objects.requireNonNull(file, "Null file");
return getFileHandle(new FileLocation(file.toFile()));
}
/**
* Warning: you should never call {@link DataHandle#set(Object)} method of the returned result!
* It can lead to unpredictable ClassCastException.
*/
@SuppressWarnings("rawtypes, unchecked")
static DataHandle getBytesHandle(BytesLocation bytesLocation) {
Objects.requireNonNull(bytesLocation, "Null bytesLocation");
BytesHandle bytesHandle = new BytesHandle(bytesLocation);
return (DataHandle) bytesHandle;
}
/**
* Warning: you should never call {@link DataHandle#set(Object)} method of the returned result!
* It can lead to unpredictable ClassCastException.
*/
@SuppressWarnings("rawtypes, unchecked")
static DataHandle getFileHandle(FileLocation fileLocation) {
Objects.requireNonNull(fileLocation, "Null fileLocation");
FileHandle fileHandle = new FileHandle(fileLocation);
fileHandle.setLittleEndian(false);
// - in current implementation it is an extra operator: BigEndian is default in scijava;
// but we want to be sure that this behaviour will be the same in all future versions
return (DataHandle) fileHandle;
}
Object scifio() {
Object scifio = this.scifio;
if (scifio == null) {
this.scifio = scifio = SCIFIOBridge.createScifioFromContext(context);
}
return scifio;
}
private Object requireScifio(TiffIFD ifd) throws UnsupportedTiffFormatException {
Object scifio = scifio();
if (scifio == null) {
// - in other words, this.context is not set
throw new UnsupportedTiffFormatException("TIFF compression " +
TagCompression.toPrettyString(ifd.optInt(Tags.COMPRESSION, TagCompression.UNCOMPRESSED.code())) +
" is not supported without external codecs");
}
return scifio;
}
private void clearTiming() {
timeReading = 0;
timeCustomizingDecoding = 0;
timeDecoding = 0;
timeDecodingMain = 0;
timeDecodingBridge = 0;
timeDecodingAdditional = 0;
timeCompleteDecoding = 0;
}
// We prefer make this.bigTiff a final field, so we cannot set it outside the constructor
private Exception startReading(AtomicBoolean bigTiffReference) {
try {
synchronized (fileLock) {
// - this synchronization is extra, but may become useful
// if we will decide to make this method public and called not only from the constructor
if (!in.exists()) {
return new FileNotFoundException("Input TIFF file" + prettyInName() + " does not exist");
}
testHeader(bigTiffReference);
return null;
}
} catch (IOException e) {
return e;
}
}
private void testHeader(AtomicBoolean bigTiffReference) throws IOException {
final long savedOffset = in.offset();
try {
in.seek(0);
final long length = in.length();
if (length < MINIMAL_ALLOWED_TIFF_FILE_LENGTH) {
// - sometimes we can meet 8-byte "TIFF-files" (or 16-byte "Big-TIFF"), containing only header
// and no actual data (for example, results of debugging writing algorithm)
throw new TiffException("Too short TIFF file" + prettyInName() + ": only " + length +
" bytes (minimum " + MINIMAL_ALLOWED_TIFF_FILE_LENGTH + " bytes are required for valid TIFF)");
}
final int endianOne = in.read();
final int endianTwo = in.read();
// byte order must be II or MM
final boolean littleEndian = endianOne == FILE_PREFIX_LITTLE_ENDIAN &&
endianTwo == FILE_PREFIX_LITTLE_ENDIAN; // II
final boolean bigEndian = endianOne == FILE_PREFIX_BIG_ENDIAN &&
endianTwo == FILE_PREFIX_BIG_ENDIAN; // MM
if (!littleEndian && !bigEndian) {
throw new TiffException("The file" + prettyInName() + " is not TIFF");
}
// check magic number (42)
in.setLittleEndian(littleEndian);
final short magic = in.readShort();
final boolean bigTiff = magic == FILE_BIG_TIFF_MAGIC_NUMBER;
bigTiffReference.set(bigTiff);
if (magic != FILE_USUAL_MAGIC_NUMBER && magic != FILE_BIG_TIFF_MAGIC_NUMBER) {
throw new TiffException("The file" + prettyInName() + " is not TIFF");
}
if (bigTiff) {
in.seek(8);
}
readFirstOffsetFromCurrentPosition(false, bigTiff);
// - additional check, filling positionOfLastOffset
} finally {
in.seek(savedOffset);
// - for maximal compatibility: in old versions, constructor of this class
// guaranteed that file position in the input stream will not change
// (that is illogical, because "little-endian" mode was still changed)
}
}
private TiffCodec.Options buildOptions(TiffTile tile) throws TiffException {
TiffCodec.Options options = this.codecOptions.clone();
options.setByteOrder(tile.byteOrder());
options.setMaxSizeInBytes(tile.getSizeInBytes());
// - Note: this may be LESS than a usual number of samples in the tile/strip.
// Current readEncodedTile() can return full-size tile without cropping
// (see comments inside that method), but usually it CROPS the last tile/strip.
// Old SCIFIO code did not detect this situation, in particular, did not distinguish between
// last and usual strips in stripped image, and its behaviour could be described by the following assignment:
// final int samplesLength = tile.map().tileSizeInBytes();
// For many codecs (like DEFLATE or JPEG) this is not important, but at least
// LZWCodec creates result array on the base of options.maxSizeInBytes.
// If it is invalid (too large value), the returned decoded data will be too large,
// and that is not too good: this class could throw an exception "data may be lost" in further
// tile.adjustNumberOfPixels() call if it called it without allowDecreasing=true argument.
options.setInterleaved(true);
// - Value "true" is necessary for most codecs, that work with high-level classes (like JPEG or JPEG-2000) and
// need to be instructed to interleave results (unlike LZW or DECOMPRESSED, which work with data "as-is"
// and suppose that data are interleaved according TIFF format specification).
// For JPEG, TagCompression overrides this value to false, because it works faster in this mode.
return options;
}
// Note: this method does not store tile in the tile map.
private void readTiles(
TiffMap map,
byte[] resultSamples,
int fromX,
int fromY,
int sizeX,
int sizeY,
boolean storeTilesInMap)
throws IOException {
Objects.requireNonNull(map, "Null TIFF map");
Objects.requireNonNull(resultSamples, "Null result samples");
assert sizeX >= 0 && sizeY >= 0;
// Note: we cannot process image larger than 2^31 x 2^31 pixels,
// though TIFF supports maximal sizes 2^32 x 2^32
// (IFD.getImageWidth/getImageLength do not allow so large results)
if (sizeX == 0 || sizeY == 0) {
// - if no pixels are updated, no need to expand the map and to check correct expansion
return;
}
final int mapTileSizeX = map.tileSizeX();
final int mapTileSizeY = map.tileSizeY();
final long bitsPerSample = map.alignedBitsPerSample();
// - "long" here leads to stricter requirements later on
final int numberOfSeparatedPlanes = map.numberOfSeparatedPlanes();
final int samplesPerPixel = map.tileSamplesPerPixel();
final int toX = Math.min(fromX + sizeX, cropTilesToImageBoundaries ? map.dimX() : Integer.MAX_VALUE);
final int toY = Math.min(fromY + sizeY, cropTilesToImageBoundaries ? map.dimY() : Integer.MAX_VALUE);
// - crop by image sizes to avoid reading unpredictable content of the boundary tiles outside the image
final int minXIndex = Math.max(0, divFloor(fromX, mapTileSizeX));
final int minYIndex = Math.max(0, divFloor(fromY, mapTileSizeY));
if (minXIndex >= map.gridCountX() || minYIndex >= map.gridCountY() || toX < fromX || toY < fromY) {
return;
}
final int maxXIndex = Math.min(map.gridCountX() - 1, divFloor(toX - 1, mapTileSizeX));
final int maxYIndex = Math.min(map.gridCountY() - 1, divFloor(toY - 1, mapTileSizeY));
if (minYIndex > maxYIndex || minXIndex > maxXIndex) {
// - possible when fromX < 0 or fromY < 0
return;
}
final long tileOneChannelRowSizeInBits = (long) mapTileSizeX * bitsPerSample;
final long samplesOneChannelRowSizeInBits = (long) sizeX * bitsPerSample;
for (int p = 0; p < numberOfSeparatedPlanes; p++) {
// - for a rare case PlanarConfiguration=2 (RRR...GGG...BBB...)
for (int yIndex = minYIndex; yIndex <= maxYIndex; yIndex++) {
final int tileStartY = Math.max(yIndex * mapTileSizeY, fromY);
final int fromYInTile = tileStartY % mapTileSizeY;
final int yDiff = tileStartY - fromY;
for (int xIndex = minXIndex; xIndex <= maxXIndex; xIndex++) {
final int tileStartX = Math.max(xIndex * mapTileSizeX, fromX);
final int fromXInTile = tileStartX % mapTileSizeX;
final int xDiff = tileStartX - fromX;
final TiffTile tile = readTile(map.multiPlaneIndex(p, xIndex, yIndex));
if (storeTilesInMap) {
map.put(tile);
}
if (tile.isEmpty()) {
continue;
}
if (!tile.isSeparated()) {
throw new AssertionError("Illegal behavior of readTile: it returned interleaved tile!");
// - theoretically possible in subclasses
}
byte[] data = tile.getDecodedData();
final int tileSizeX = tile.getSizeX();
final int tileSizeY = tile.getSizeY();
final int sizeXInTile = Math.min(toX - tileStartX, tileSizeX - fromXInTile);
assert sizeXInTile > 0 : "sizeXInTile=" + sizeXInTile;
final int sizeYInTile = Math.min(toY - tileStartY, tileSizeY - fromYInTile);
assert sizeYInTile > 0 : "sizeYInTile=" + sizeYInTile;
final long partSizeXInBits = (long) sizeXInTile * bitsPerSample;
for (int s = 0; s < samplesPerPixel; s++) {
long tOffset = (((s * (long) tileSizeY) + fromYInTile)
* (long) tileSizeX + fromXInTile) * bitsPerSample;
long sOffset = (((p + s) * (long) sizeY + yDiff) * (long) sizeX + xDiff) * bitsPerSample;
// (long) cast is important for processing large bit matrices!
for (int i = 0; i < sizeYInTile; i++) {
assert sOffset >= 0 && tOffset >= 0 : "possibly int instead of long";
PackedBitArraysPer8.copyBitsNoSync(resultSamples, sOffset, data, tOffset, partSizeXInBits);
tOffset += tileOneChannelRowSizeInBits;
sOffset += samplesOneChannelRowSizeInBits;
}
}
}
}
}
}
private static int cachedByteCountWithCompatibilityTrick(TiffIFD ifd, int index) throws TiffException {
final boolean tiled = ifd.hasTileInformation();
final int tag = tiled ? Tags.TILE_BYTE_COUNTS : Tags.STRIP_BYTE_COUNTS;
Object value = ifd.get(tag);
if (value instanceof long[] byteCounts &&
byteCounts.length == 1 &&
byteCounts[0] == (int) byteCounts[0]) {
// - possible in a rare case:
// we use TiffParser.getIFD to read this IFD,
// and this file is Big-TIFF,
// and if we set "equal-strip" mode by TiffParser.setAssumeEqualStrips
return (int) byteCounts[0];
}
return ifd.cachedTileOrStripByteCount(index);
}
// Unlike AbstractCodec.decompress, this method does not require using "handles" field, annotated as @Parameter
// This function is not universal, it cannot be applied to any codec!
private String prettyInName() {
return prettyFileName(" %s", in);
}
private long readFirstOffsetFromCurrentPosition(boolean updatePositionOfLastOffset, boolean bigTiff)
throws IOException {
final long offset = readNextOffset(updatePositionOfLastOffset, true, bigTiff);
if (offset == 0) {
throw new TiffException("Invalid TIFF" + prettyInName() +
": zero first offset (TIFF must contain at least one IFD!)");
}
return offset;
}
private void skipIFDEntries(long fileLength) throws IOException {
final long offset = in.offset();
final int bytesPerEntry = bigTiff ? BIG_TIFF_BYTES_PER_ENTRY : BYTES_PER_ENTRY;
final long numberOfEntries = bigTiff ? in.readLong() : in.readUnsignedShort();
if (numberOfEntries < 0 || numberOfEntries > Integer.MAX_VALUE / bytesPerEntry) {
throw new TiffException(
"Too large number of IFD entries in Big TIFF: " +
(numberOfEntries < 0 ? ">= 2^63" : numberOfEntries + "") +
" (it is not supported, probably file is broken)");
}
final long skippedIFDBytes = numberOfEntries * bytesPerEntry;
if (offset + skippedIFDBytes >= fileLength) {
throw new TiffException(
"Invalid TIFF" + prettyInName() + ": position of next IFD offset " +
(offset + skippedIFDBytes) + " after " + numberOfEntries +
" entries is outside the file (probably file is broken)");
}
in.skipBytes((int) skippedIFDBytes);
}
private long readNextOffset(boolean updatePositionOfLastOffset) throws IOException {
return readNextOffset(updatePositionOfLastOffset, this.requireValidTiff, this.bigTiff);
}
/**
* Read a file offset. For bigTiff, a 64-bit number is read. For other Tiffs,
* a 32-bit number is read and possibly adjusted for a possible carry-over
* from the previous offset.
*/
private long readNextOffset(boolean updatePositionOfLastOffset, boolean requireValidTiff, boolean bigTiff)
throws IOException {
final long fileLength = in.length();
final long filePosition = in.offset();
long offset;
if (bigTiff) {
offset = in.readLong();
} else {
// Below is a deprecated solution
// (this "trick" cannot help if a SINGLE image is very large (>2^32): for example,
// previous = 8 (1st IFD) and the next is 0x120000000; but it is the mostly typical
// problematic situation: for example, very large 1st IFD in SVS file).
//
// offset = (previous & ~0xffffffffL) | (in.readInt() & 0xffffffffL);
// Only adjust the offset if we know that the file is too large for
// 32-bit
// offsets to be accurate; otherwise, we're making the incorrect
// assumption
// that IFDs are stored sequentially.
// if (offset < previous && offset != 0 && in.length() > Integer.MAX_VALUE) {
// offset += 0x100000000L;
// }
// return offset;
offset = (long) in.readInt() & 0xffffffffL;
// - in usual TIFF format, offset if 32-bit UNSIGNED value
}
if (requireValidTiff) {
if (offset < 0) {
// - possibly in Big-TIFF only
throw new TiffException("Invalid TIFF" + prettyInName() +
": negative 64-bit offset " + offset + " at file position " + filePosition +
", probably the file is corrupted");
}
if (offset >= fileLength) {
throw new TiffException("Invalid TIFF" + prettyInName() + ": offset " + offset +
" at file position " + filePosition + " is outside the file, probably the is corrupted");
}
}
if (updatePositionOfLastOffset) {
this.positionOfLastIFDOffset = filePosition;
}
return offset;
}
private static Object readIFDValueAtEntryOffset(DataHandle in, TiffIFD.TiffEntry entry) throws IOException {
final int type = entry.type();
final int count = entry.valueCount();
final long offset = entry.valueOffset();
final ByteOrder byteOrder = in.isLittleEndian() ? ByteOrder.LITTLE_ENDIAN : ByteOrder.BIG_ENDIAN;
LOG.log(System.Logger.Level.TRACE, () ->
"Reading entry " + entry.tag() + " from " + offset + "; type=" + type + ", count=" + count);
in.seek(offset);
switch (type) {
case TagTypes.BYTE -> {
// 8-bit unsigned integer
if (count == 1) {
return (short) in.readByte();
}
final byte[] bytes = new byte[count];
in.readFully(bytes);
// bytes are unsigned, so use shorts
final short[] shorts = new short[count];
for (int j = 0; j < count; j++) {
shorts[j] = (short) (bytes[j] & 0xff);
}
return shorts;
}
case TagTypes.ASCII -> {
// 8-bit byte that contain a 7-bit ASCII code;
// the last byte must be NUL (binary zero)
final byte[] ascii = new byte[count];
in.read(ascii);
// count number of null terminators
int zeroCount = 0;
for (int j = 0; j < count; j++) {
if (ascii[j] == 0 || j == count - 1) {
zeroCount++;
}
}
// convert character array to array of strings
final String[] strings = zeroCount == 1 ? null : new String[zeroCount];
String s = null;
int c = 0, index = -1;
for (int j = 0; j < count; j++) {
if (ascii[j] == 0) {
s = new String(ascii, index + 1, j - index - 1, StandardCharsets.UTF_8);
index = j;
} else if (j == count - 1) {
// handle non-null-terminated strings
s = new String(ascii, index + 1, j - index, StandardCharsets.UTF_8);
} else {
s = null;
}
if (strings != null && s != null) {
strings[c++] = s;
}
}
return strings != null ? strings : s != null ? s : "";
}
case TagTypes.SHORT -> {
// 16-bit (2-byte) unsigned integer
if (count == 1) {
return in.readUnsignedShort();
}
if (OPTIMIZE_READING_IFD_ARRAYS) {
final byte[] bytes = readIFDBytes(in, 2 * (long) count);
final short[] shorts = JArrays.bytesToShortArray(bytes, byteOrder);
final int[] result = new int[count];
for (int j = 0; j < count; j++) {
result[j] = shorts[j] & 0xFFFF;
}
return result;
} else {
final int[] shorts = new int[count];
for (int j = 0; j < count; j++) {
shorts[j] = in.readUnsignedShort();
}
return shorts;
}
}
case TagTypes.LONG, TagTypes.IFD -> {
// 32-bit (4-byte) unsigned integer
if (count == 1) {
return in.readInt() & 0xFFFFFFFFL;
}
if (OPTIMIZE_READING_IFD_ARRAYS) {
final byte[] bytes = readIFDBytes(in, 4 * (long) count);
final int[] ints = JArrays.bytesToIntArray(bytes, byteOrder);
return Arrays.stream(ints).mapToLong(anInt -> anInt & 0xFFFFFFFFL).toArray();
// note: TIFF_LONG is UNSIGNED long
} else {
final long[] longs = new long[count];
for (int j = 0; j < count; j++) {
longs[j] = in.readInt() & 0xFFFFFFFFL;
}
return longs;
}
}
case TagTypes.LONG8, TagTypes.SLONG8, TagTypes.IFD8 -> {
if (count == 1) {
return in.readLong();
}
if (OPTIMIZE_READING_IFD_ARRAYS) {
final byte[] bytes = readIFDBytes(in, 8 * (long) count);
return JArrays.bytesToLongArray(bytes, byteOrder);
} else {
long[] longs = new long[count];
for (int j = 0; j < count; j++) {
longs[j] = in.readLong();
}
return longs;
}
}
case TagTypes.RATIONAL, TagTypes.SRATIONAL -> {
// Two LONGs or SLONGs: the first represents the numerator of a fraction; the second, the denominator
if (count == 1) {
return new TagRational(in.readInt(), in.readInt());
}
final TagRational[] rationals = new TagRational[count];
for (int j = 0; j < count; j++) {
rationals[j] = new TagRational(in.readInt(), in.readInt());
}
return rationals;
}
case TagTypes.SBYTE, TagTypes.UNDEFINED -> {
// SBYTE: An 8-bit signed (twos-complement) integer
// UNDEFINED: An 8-bit byte that may contain anything,
// depending on the definition of the field
if (count == 1) {
return in.readByte();
}
final byte[] sbytes = new byte[count];
in.read(sbytes);
return sbytes;
}
case TagTypes.SSHORT -> {
// A 16-bit (2-byte) signed (twos-complement) integer
if (count == 1) {
return in.readShort();
}
final short[] sshorts = new short[count];
for (int j = 0; j < count; j++) {
sshorts[j] = in.readShort();
}
return sshorts;
}
case TagTypes.SLONG -> {
// A 32-bit (4-byte) signed (twos-complement) integer
if (count == 1) {
return in.readInt();
}
final int[] slongs = new int[count];
for (int j = 0; j < count; j++) {
slongs[j] = in.readInt();
}
return slongs;
}
case TagTypes.FLOAT -> {
// Single precision (4-byte) IEEE format
if (count == 1) {
return in.readFloat();
}
final float[] floats = new float[count];
for (int j = 0; j < count; j++) {
floats[j] = in.readFloat();
}
return floats;
}
case TagTypes.DOUBLE -> {
// Double precision (8-byte) IEEE format
if (count == 1) {
return in.readDouble();
}
final double[] doubles = new double[count];
for (int j = 0; j < count; j++) {
doubles[j] = in.readDouble();
}
return doubles;
}
default -> {
final long valueOrOffset = in.readLong();
return new TiffIFD.UnsupportedTypeValue(type, count, valueOrOffset);
}
}
}
private static byte[] readIFDBytes(DataHandle in, long length) throws IOException {
if (length > Integer.MAX_VALUE) {
throw new TiffException("Too large IFD value: " + length + " >= 2^31 bytes");
}
byte[] bytes = new byte[(int) length];
in.readFully(bytes);
return bytes;
}
private TiffIFD.TiffEntry readIFDEntry() throws IOException {
final int entryTag = in.readUnsignedShort();
final int entryType = in.readUnsignedShort();
final long valueCount = bigTiff ? in.readLong() : ((long) in.readInt()) & 0xFFFFFFFFL;
if (valueCount < 0 || valueCount > Integer.MAX_VALUE) {
throw new TiffException("Invalid TIFF: very large number of IFD values in array " +
(valueCount < 0 ? " >= 2^63" : valueCount + " >= 2^31") + " is not supported");
}
final int bytesPerElement = TagTypes.sizeOfType(entryType);
// - will be zero for unknown type; in this case we will set valueOffset=in.offset() below
final long valueLength = valueCount * (long) bytesPerElement;
final int threshold = bigTiff ? 8 : 4;
final long valueOffset = valueLength > threshold ?
readNextOffset(false) :
in.offset();
if (valueOffset < 0) {
throw new TiffException("Invalid TIFF: negative offset of IFD values " + valueOffset);
}
if (valueOffset > in.length() - valueLength) {
throw new TiffException("Invalid TIFF: offset of IFD values " + valueOffset +
" + total lengths of values " + valueLength + " = " + valueCount + "*" + bytesPerElement +
" is outside the file length " + in.length());
}
final TiffIFD.TiffEntry result = new TiffIFD.TiffEntry(entryTag, entryType, (int) valueCount, valueOffset);
LOG.log(System.Logger.Level.TRACE, () -> String.format(
"Reading IFD entry: %s - %s", result, Tags.tiffTagName(result.tag(), true)));
return result;
}
static int divFloor(int a, int b) {
assert b > 0;
return a >= 0 ? a / b : (a - b + 1) / b;
}
static String prettyFileName(String format, DataHandle handle) {
if (handle == null) {
return "";
}
Location location = handle.get();
if (location == null) {
return "";
}
URI uri = location.getURI();
if (uri == null) {
return "";
}
return format.formatted(uri);
}
static boolean getBooleanProperty(String propertyName) {
try {
return Boolean.getBoolean(propertyName);
} catch (Exception e) {
return false;
}
}
private static long debugTime() {
return BUILT_IN_TIMING && LOGGABLE_DEBUG ? System.nanoTime() : 0;
}
}