* This class deflates sequences of bytes into ZLIB compressed data format. * The input byte sequence is provided in either byte array or byte buffer, * via one of the {@code setInput()} methods. The output byte sequence is * written to the output byte array or byte buffer passed to the * {@code deflate()} methods. *
* The following code fragment demonstrates a trivial compression * and decompression of a string using {@code Deflater} and * {@code Inflater}. * *
* try {
* // Encode a String into bytes
* String inputString = "blahblahblah";
* byte[] input = inputString.getBytes("UTF-8");
*
* // Compress the bytes
* byte[] output = new byte[100];
* Deflater compresser = new Deflater();
* compresser.setInput(input);
* compresser.finish();
* int compressedDataLength = compresser.deflate(output);
* compresser.end();
*
* // Decompress the bytes
* Inflater decompresser = new Inflater();
* decompresser.setInput(output, 0, compressedDataLength);
* byte[] result = new byte[100];
* int resultLength = decompresser.inflate(result);
* decompresser.end();
*
* // Decode the bytes into a String
* String outputString = new String(result, 0, resultLength, "UTF-8");
* } catch (java.io.UnsupportedEncodingException ex) {
* // handle
* } catch (java.util.zip.DataFormatException ex) {
* // handle
* }
* * One of the {@code setInput()} methods should be called whenever * {@code needsInput()} returns true indicating that more input data * is required. *
* @param input the input data bytes * @param off the start offset of the data * @param len the length of the data * @see Deflater#needsInput */ public void setInput(byte[] input, int off, int len) { if (off < 0 || len < 0 || off > input.length - len) { throw new ArrayIndexOutOfBoundsException(); } synchronized (zsRef) { this.input = null; this.inputArray = input; this.inputPos = off; this.inputLim = off + len; } } /** * Sets input data for compression. *
* One of the {@code setInput()} methods should be called whenever * {@code needsInput()} returns true indicating that more input data * is required. *
* @param input the input data bytes * @see Deflater#needsInput */ public void setInput(byte[] input) { setInput(input, 0, input.length); } /** * Sets input data for compression. *
* One of the {@code setInput()} methods should be called whenever * {@code needsInput()} returns true indicating that more input data * is required. *
* The given buffer's position will be advanced as deflate * operations are performed, up to the buffer's limit. * The input buffer may be modified (refilled) between deflate * operations; doing so is equivalent to creating a new buffer * and setting it with this method. *
* Modifying the input buffer's contents, position, or limit * concurrently with an deflate operation will result in * undefined behavior, which may include incorrect operation * results or operation failure. * * @param input the input data bytes * @see Deflater#needsInput * @since 11 */ public void setInput(ByteBuffer input) { Objects.requireNonNull(input); synchronized (zsRef) { this.input = input; this.inputArray = null; } } /** * Sets preset dictionary for compression. A preset dictionary is used * when the history buffer can be predetermined. When the data is later * uncompressed with Inflater.inflate(), Inflater.getAdler() can be called * in order to get the Adler-32 value of the dictionary required for * decompression. * @param dictionary the dictionary data bytes * @param off the start offset of the data * @param len the length of the data * @see Inflater#inflate * @see Inflater#getAdler */ public void setDictionary(byte[] dictionary, int off, int len) { if (off < 0 || len < 0 || off > dictionary.length - len) { throw new ArrayIndexOutOfBoundsException(); } synchronized (zsRef) { ensureOpen(); setDictionary(zsRef.address(), dictionary, off, len); } } /** * Sets preset dictionary for compression. A preset dictionary is used * when the history buffer can be predetermined. When the data is later * uncompressed with Inflater.inflate(), Inflater.getAdler() can be called * in order to get the Adler-32 value of the dictionary required for * decompression. * @param dictionary the dictionary data bytes * @see Inflater#inflate * @see Inflater#getAdler */ public void setDictionary(byte[] dictionary) { setDictionary(dictionary, 0, dictionary.length); } /** * Sets preset dictionary for compression. A preset dictionary is used * when the history buffer can be predetermined. When the data is later * uncompressed with Inflater.inflate(), Inflater.getAdler() can be called * in order to get the Adler-32 value of the dictionary required for * decompression. *
* The bytes in given byte buffer will be fully consumed by this method. On * return, its position will equal its limit. * * @param dictionary the dictionary data bytes * @see Inflater#inflate * @see Inflater#getAdler */ public void setDictionary(ByteBuffer dictionary) { synchronized (zsRef) { int position = dictionary.position(); int remaining = Math.max(dictionary.limit() - position, 0); ensureOpen(); if (dictionary.isDirect()) { long address = ((DirectBuffer) dictionary).address(); try { setDictionaryBuffer(zsRef.address(), address + position, remaining); } finally { Reference.reachabilityFence(dictionary); } } else { byte[] array = ZipUtils.getBufferArray(dictionary); int offset = ZipUtils.getBufferOffset(dictionary); setDictionary(zsRef.address(), array, offset + position, remaining); } dictionary.position(position + remaining); } } /** * Sets the compression strategy to the specified value. * *
If the compression strategy is changed, the next invocation * of {@code deflate} will compress the input available so far with * the old strategy (and may be flushed); the new strategy will take * effect only after that invocation. * * @param strategy the new compression strategy * @exception IllegalArgumentException if the compression strategy is * invalid */ public void setStrategy(int strategy) { switch (strategy) { case DEFAULT_STRATEGY: case FILTERED: case HUFFMAN_ONLY: break; default: throw new IllegalArgumentException(); } synchronized (zsRef) { if (this.strategy != strategy) { this.strategy = strategy; setParams = true; } } } /** * Sets the compression level to the specified value. * *
If the compression level is changed, the next invocation * of {@code deflate} will compress the input available so far * with the old level (and may be flushed); the new level will * take effect only after that invocation. * * @param level the new compression level (0-9) * @exception IllegalArgumentException if the compression level is invalid */ public void setLevel(int level) { if ((level < 0 || level > 9) && level != DEFAULT_COMPRESSION) { throw new IllegalArgumentException("invalid compression level"); } synchronized (zsRef) { if (this.level != level) { this.level = level; setParams = true; } } } /** * Returns true if no data remains in the input buffer. This can * be used to determine if one of the {@code setInput()} methods should be * called in order to provide more input. * * @return true if the input data buffer is empty and setInput() * should be called in order to provide more input */ public boolean needsInput() { synchronized (zsRef) { ByteBuffer input = this.input; return input == null ? inputLim == inputPos : ! input.hasRemaining(); } } /** * When called, indicates that compression should end with the current * contents of the input buffer. */ public void finish() { synchronized (zsRef) { finish = true; } } /** * Returns true if the end of the compressed data output stream has * been reached. * @return true if the end of the compressed data output stream has * been reached */ public boolean finished() { synchronized (zsRef) { return finished; } } /** * Compresses the input data and fills specified buffer with compressed * data. Returns actual number of bytes of compressed data. A return value * of 0 indicates that {@link #needsInput() needsInput} should be called * in order to determine if more input data is required. * *
This method uses {@link #NO_FLUSH} as its compression flush mode. * An invocation of this method of the form {@code deflater.deflate(b, off, len)} * yields the same result as the invocation of * {@code deflater.deflate(b, off, len, Deflater.NO_FLUSH)}. * * @param output the buffer for the compressed data * @param off the start offset of the data * @param len the maximum number of bytes of compressed data * @return the actual number of bytes of compressed data written to the * output buffer */ public int deflate(byte[] output, int off, int len) { return deflate(output, off, len, NO_FLUSH); } /** * Compresses the input data and fills specified buffer with compressed * data. Returns actual number of bytes of compressed data. A return value * of 0 indicates that {@link #needsInput() needsInput} should be called * in order to determine if more input data is required. * *
This method uses {@link #NO_FLUSH} as its compression flush mode. * An invocation of this method of the form {@code deflater.deflate(b)} * yields the same result as the invocation of * {@code deflater.deflate(b, 0, b.length, Deflater.NO_FLUSH)}. * * @param output the buffer for the compressed data * @return the actual number of bytes of compressed data written to the * output buffer */ public int deflate(byte[] output) { return deflate(output, 0, output.length, NO_FLUSH); } /** * Compresses the input data and fills specified buffer with compressed * data. Returns actual number of bytes of compressed data. A return value * of 0 indicates that {@link #needsInput() needsInput} should be called * in order to determine if more input data is required. * *
This method uses {@link #NO_FLUSH} as its compression flush mode. * An invocation of this method of the form {@code deflater.deflate(output)} * yields the same result as the invocation of * {@code deflater.deflate(output, Deflater.NO_FLUSH)}. * * @param output the buffer for the compressed data * @return the actual number of bytes of compressed data written to the * output buffer * @since 11 */ public int deflate(ByteBuffer output) { return deflate(output, NO_FLUSH); } /** * Compresses the input data and fills the specified buffer with compressed * data. Returns actual number of bytes of data compressed. * *
Compression flush mode is one of the following three modes: * *
In the case of {@link #FULL_FLUSH} or {@link #SYNC_FLUSH}, if * the return value is {@code len}, the space available in output * buffer {@code b}, this method should be invoked again with the same * {@code flush} parameter and more output space. Make sure that * {@code len} is greater than 6 to avoid flush marker (5 bytes) being * repeatedly output to the output buffer every time this method is * invoked. * *
If the {@link #setInput(ByteBuffer)} method was called to provide a buffer * for input, the input buffer's position will be advanced by the number of bytes * consumed by this operation. * * @param output the buffer for the compressed data * @param off the start offset of the data * @param len the maximum number of bytes of compressed data * @param flush the compression flush mode * @return the actual number of bytes of compressed data written to * the output buffer * * @throws IllegalArgumentException if the flush mode is invalid * @since 1.7 */ public int deflate(byte[] output, int off, int len, int flush) { if (off < 0 || len < 0 || off > output.length - len) { throw new ArrayIndexOutOfBoundsException(); } if (flush != NO_FLUSH && flush != SYNC_FLUSH && flush != FULL_FLUSH) { throw new IllegalArgumentException(); } synchronized (zsRef) { ensureOpen(); ByteBuffer input = this.input; if (finish) { // disregard given flush mode in this case flush = FINISH; } int params; if (setParams) { // bit 0: true to set params // bit 1-2: strategy (0, 1, or 2) // bit 3-31: level (0..9 or -1) params = 1 | strategy << 1 | level << 3; } else { params = 0; } int inputPos; long result; if (input == null) { inputPos = this.inputPos; result = deflateBytesBytes(zsRef.address(), inputArray, inputPos, inputLim - inputPos, output, off, len, flush, params); } else { inputPos = input.position(); int inputRem = Math.max(input.limit() - inputPos, 0); if (input.isDirect()) { try { long inputAddress = ((DirectBuffer) input).address(); result = deflateBufferBytes(zsRef.address(), inputAddress + inputPos, inputRem, output, off, len, flush, params); } finally { Reference.reachabilityFence(input); } } else { byte[] inputArray = ZipUtils.getBufferArray(input); int inputOffset = ZipUtils.getBufferOffset(input); result = deflateBytesBytes(zsRef.address(), inputArray, inputOffset + inputPos, inputRem, output, off, len, flush, params); } } int read = (int) (result & 0x7fff_ffffL); int written = (int) (result >>> 31 & 0x7fff_ffffL); if ((result >>> 62 & 1) != 0) { finished = true; } if (params != 0 && (result >>> 63 & 1) == 0) { setParams = false; } if (input != null) { input.position(inputPos + read); } else { this.inputPos = inputPos + read; } bytesWritten += written; bytesRead += read; return written; } } /** * Compresses the input data and fills the specified buffer with compressed * data. Returns actual number of bytes of data compressed. * *
Compression flush mode is one of the following three modes: * *
In the case of {@link #FULL_FLUSH} or {@link #SYNC_FLUSH}, if * the return value is equal to the {@linkplain ByteBuffer#remaining() remaining space} * of the buffer, this method should be invoked again with the same * {@code flush} parameter and more output space. Make sure that * the buffer has at least 6 bytes of remaining space to avoid the * flush marker (5 bytes) being repeatedly output to the output buffer * every time this method is invoked. * *
On success, the position of the given {@code output} byte buffer will be * advanced by as many bytes as were produced by the operation, which is equal * to the number returned by this method. * *
If the {@link #setInput(ByteBuffer)} method was called to provide a buffer * for input, the input buffer's position will be advanced by the number of bytes * consumed by this operation. * * @param output the buffer for the compressed data * @param flush the compression flush mode * @return the actual number of bytes of compressed data written to * the output buffer * * @throws IllegalArgumentException if the flush mode is invalid * @since 11 */ public int deflate(ByteBuffer output, int flush) { if (output.isReadOnly()) { throw new ReadOnlyBufferException(); } if (flush != NO_FLUSH && flush != SYNC_FLUSH && flush != FULL_FLUSH) { throw new IllegalArgumentException(); } synchronized (zsRef) { ensureOpen(); ByteBuffer input = this.input; if (finish) { // disregard given flush mode in this case flush = FINISH; } int params; if (setParams) { // bit 0: true to set params // bit 1-2: strategy (0, 1, or 2) // bit 3-31: level (0..9 or -1) params = 1 | strategy << 1 | level << 3; } else { params = 0; } int outputPos = output.position(); int outputRem = Math.max(output.limit() - outputPos, 0); int inputPos; long result; if (input == null) { inputPos = this.inputPos; if (output.isDirect()) { long outputAddress = ((DirectBuffer) output).address(); try { result = deflateBytesBuffer(zsRef.address(), inputArray, inputPos, inputLim - inputPos, outputAddress + outputPos, outputRem, flush, params); } finally { Reference.reachabilityFence(output); } } else { byte[] outputArray = ZipUtils.getBufferArray(output); int outputOffset = ZipUtils.getBufferOffset(output); result = deflateBytesBytes(zsRef.address(), inputArray, inputPos, inputLim - inputPos, outputArray, outputOffset + outputPos, outputRem, flush, params); } } else { inputPos = input.position(); int inputRem = Math.max(input.limit() - inputPos, 0); if (input.isDirect()) { long inputAddress = ((DirectBuffer) input).address(); try { if (output.isDirect()) { long outputAddress = outputPos + ((DirectBuffer) output).address(); try { result = deflateBufferBuffer(zsRef.address(), inputAddress + inputPos, inputRem, outputAddress, outputRem, flush, params); } finally { Reference.reachabilityFence(output); } } else { byte[] outputArray = ZipUtils.getBufferArray(output); int outputOffset = ZipUtils.getBufferOffset(output); result = deflateBufferBytes(zsRef.address(), inputAddress + inputPos, inputRem, outputArray, outputOffset + outputPos, outputRem, flush, params); } } finally { Reference.reachabilityFence(input); } } else { byte[] inputArray = ZipUtils.getBufferArray(input); int inputOffset = ZipUtils.getBufferOffset(input); if (output.isDirect()) { long outputAddress = ((DirectBuffer) output).address(); try { result = deflateBytesBuffer(zsRef.address(), inputArray, inputOffset + inputPos, inputRem, outputAddress + outputPos, outputRem, flush, params); } finally { Reference.reachabilityFence(output); } } else { byte[] outputArray = ZipUtils.getBufferArray(output); int outputOffset = ZipUtils.getBufferOffset(output); result = deflateBytesBytes(zsRef.address(), inputArray, inputOffset + inputPos, inputRem, outputArray, outputOffset + outputPos, outputRem, flush, params); } } } int read = (int) (result & 0x7fff_ffffL); int written = (int) (result >>> 31 & 0x7fff_ffffL); if ((result >>> 62 & 1) != 0) { finished = true; } if (params != 0 && (result >>> 63 & 1) == 0) { setParams = false; } if (input != null) { input.position(inputPos + read); } else { this.inputPos = inputPos + read; } output.position(outputPos + written); bytesWritten += written; bytesRead += read; return written; } } /** * Returns the ADLER-32 value of the uncompressed data. * @return the ADLER-32 value of the uncompressed data */ public int getAdler() { synchronized (zsRef) { ensureOpen(); return getAdler(zsRef.address()); } } /** * Returns the total number of uncompressed bytes input so far. * *
Since the number of bytes may be greater than * Integer.MAX_VALUE, the {@link #getBytesRead()} method is now * the preferred means of obtaining this information.
* * @return the total number of uncompressed bytes input so far */ public int getTotalIn() { return (int) getBytesRead(); } /** * Returns the total number of uncompressed bytes input so far. * * @return the total (non-negative) number of uncompressed bytes input so far * @since 1.5 */ public long getBytesRead() { synchronized (zsRef) { ensureOpen(); return bytesRead; } } /** * Returns the total number of compressed bytes output so far. * *Since the number of bytes may be greater than * Integer.MAX_VALUE, the {@link #getBytesWritten()} method is now * the preferred means of obtaining this information.
* * @return the total number of compressed bytes output so far */ public int getTotalOut() { return (int) getBytesWritten(); } /** * Returns the total number of compressed bytes output so far. * * @return the total (non-negative) number of compressed bytes output so far * @since 1.5 */ public long getBytesWritten() { synchronized (zsRef) { ensureOpen(); return bytesWritten; } } /** * Resets deflater so that a new set of input data can be processed. * Keeps current compression level and strategy settings. */ public void reset() { synchronized (zsRef) { ensureOpen(); reset(zsRef.address()); finish = false; finished = false; input = ZipUtils.defaultBuf; inputArray = null; bytesRead = bytesWritten = 0; } } /** * Closes the compressor and discards any unprocessed input. * * This method should be called when the compressor is no longer * being used. Once this method is called, the behavior of the * Deflater object is undefined. */ public void end() { synchronized (zsRef) { zsRef.clean(); input = ZipUtils.defaultBuf; } } /** * Closes the compressor when garbage is collected. * * @deprecated The {@code finalize} method has been deprecated and will be * removed. It is implemented as a no-op. Subclasses that override * {@code finalize} in order to perform cleanup should be modified to use * alternative cleanup mechanisms and to remove the overriding {@code finalize} * method. The recommended cleanup for compressor is to explicitly call * {@code end} method when it is no longer in use. If the {@code end} is * not invoked explicitly the resource of the compressor will be released * when the instance becomes unreachable. */ @Deprecated(since="9", forRemoval=true) protected void finalize() {} private void ensureOpen() { assert Thread.holdsLock(zsRef); if (zsRef.address() == 0) throw new NullPointerException("Deflater has been closed"); } private static native long init(int level, int strategy, boolean nowrap); private static native void setDictionary(long addr, byte[] b, int off, int len); private static native void setDictionaryBuffer(long addr, long bufAddress, int len); private native long deflateBytesBytes(long addr, byte[] inputArray, int inputOff, int inputLen, byte[] outputArray, int outputOff, int outputLen, int flush, int params); private native long deflateBytesBuffer(long addr, byte[] inputArray, int inputOff, int inputLen, long outputAddress, int outputLen, int flush, int params); private native long deflateBufferBytes(long addr, long inputAddress, int inputLen, byte[] outputArray, int outputOff, int outputLen, int flush, int params); private native long deflateBufferBuffer(long addr, long inputAddress, int inputLen, long outputAddress, int outputLen, int flush, int params); private static native int getAdler(long addr); private static native void reset(long addr); private static native void end(long addr); /** * A reference to the native zlib's z_stream structure. It also * serves as the "cleaner" to clean up the native resource when * the Deflater is ended, closed or cleaned. */ static class DeflaterZStreamRef implements Runnable { private long address; private final Cleanable cleanable; private DeflaterZStreamRef(Deflater owner, long addr) { this.cleanable = (owner != null) ? CleanerFactory.cleaner().register(owner, this) : null; this.address = addr; } long address() { return address; } void clean() { cleanable.clean(); } public synchronized void run() { long addr = address; address = 0; if (addr != 0) { end(addr); } } /* * If {@code Deflater} has been subclassed and the {@code end} method is * overridden, uses {@code finalizer} mechanism for resource cleanup. So * {@code end} method can be called when the {@code Deflater} is unreachable. * This mechanism will be removed when the {@code finalize} method is * removed from {@code Deflater}. */ static DeflaterZStreamRef get(Deflater owner, long addr) { Class clz = owner.getClass(); while (clz != Deflater.class) { try { clz.getDeclaredMethod("end"); return new FinalizableZStreamRef(owner, addr); } catch (NoSuchMethodException nsme) {} clz = clz.getSuperclass(); } return new DeflaterZStreamRef(owner, addr); } private static class FinalizableZStreamRef extends DeflaterZStreamRef { final Deflater owner; FinalizableZStreamRef (Deflater owner, long addr) { super(null, addr); this.owner = owner; } @Override void clean() { run(); } @Override @SuppressWarnings("deprecation") protected void finalize() { owner.end(); } } } }