io.netty.handler.codec.compression.JZlibEncoder Maven / Gradle / Ivy
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This artifact provides a single jar that contains all classes required to use remote EJB and JMS, including
all dependencies. It is intended for use by those not using maven, maven users should just import the EJB and
JMS BOM's instead (shaded JAR's cause lots of problems with maven, as it is very easy to inadvertently end up
with different versions on classes on the class path).
/*
* Copyright 2012 The Netty Project
*
* The Netty Project licenses this file to you under the Apache License,
* version 2.0 (the "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at:
*
* https://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
* under the License.
*/
package io.netty.handler.codec.compression;
import com.jcraft.jzlib.Deflater;
import com.jcraft.jzlib.JZlib;
import io.netty.buffer.ByteBuf;
import io.netty.buffer.Unpooled;
import io.netty.channel.ChannelFuture;
import io.netty.channel.ChannelFutureListener;
import io.netty.channel.ChannelHandlerContext;
import io.netty.channel.ChannelPromise;
import io.netty.util.concurrent.EventExecutor;
import io.netty.util.concurrent.PromiseNotifier;
import io.netty.util.internal.EmptyArrays;
import io.netty.util.internal.ObjectUtil;
import java.util.concurrent.TimeUnit;
/**
* Compresses a {@link ByteBuf} using the deflate algorithm.
*/
public class JZlibEncoder extends ZlibEncoder {
private final int wrapperOverhead;
private final Deflater z = new Deflater();
private volatile boolean finished;
private volatile ChannelHandlerContext ctx;
private static final int THREAD_POOL_DELAY_SECONDS = 10;
/**
* Creates a new zlib encoder with the default compression level ({@code 6}),
* default window bits ({@code 15}), default memory level ({@code 8}),
* and the default wrapper ({@link ZlibWrapper#ZLIB}).
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder() {
this(6);
}
/**
* Creates a new zlib encoder with the specified {@code compressionLevel},
* default window bits ({@code 15}), default memory level ({@code 8}),
* and the default wrapper ({@link ZlibWrapper#ZLIB}).
*
* @param compressionLevel
* {@code 1} yields the fastest compression and {@code 9} yields the
* best compression. {@code 0} means no compression. The default
* compression level is {@code 6}.
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(int compressionLevel) {
this(ZlibWrapper.ZLIB, compressionLevel);
}
/**
* Creates a new zlib encoder with the default compression level ({@code 6}),
* default window bits ({@code 15}), default memory level ({@code 8}),
* and the specified wrapper.
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(ZlibWrapper wrapper) {
this(wrapper, 6);
}
/**
* Creates a new zlib encoder with the specified {@code compressionLevel},
* default window bits ({@code 15}), default memory level ({@code 8}),
* and the specified wrapper.
*
* @param compressionLevel
* {@code 1} yields the fastest compression and {@code 9} yields the
* best compression. {@code 0} means no compression. The default
* compression level is {@code 6}.
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(ZlibWrapper wrapper, int compressionLevel) {
this(wrapper, compressionLevel, 15, 8);
}
/**
* Creates a new zlib encoder with the specified {@code compressionLevel},
* the specified {@code windowBits}, the specified {@code memLevel}, and
* the specified wrapper.
*
* @param compressionLevel
* {@code 1} yields the fastest compression and {@code 9} yields the
* best compression. {@code 0} means no compression. The default
* compression level is {@code 6}.
* @param windowBits
* The base two logarithm of the size of the history buffer. The
* value should be in the range {@code 9} to {@code 15} inclusive.
* Larger values result in better compression at the expense of
* memory usage. The default value is {@code 15}.
* @param memLevel
* How much memory should be allocated for the internal compression
* state. {@code 1} uses minimum memory and {@code 9} uses maximum
* memory. Larger values result in better and faster compression
* at the expense of memory usage. The default value is {@code 8}
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(ZlibWrapper wrapper, int compressionLevel, int windowBits, int memLevel) {
ObjectUtil.checkInRange(compressionLevel, 0, 9, "compressionLevel");
ObjectUtil.checkInRange(windowBits, 9, 15, "windowBits");
ObjectUtil.checkInRange(memLevel, 1, 9, "memLevel");
ObjectUtil.checkNotNull(wrapper, "wrapper");
if (wrapper == ZlibWrapper.ZLIB_OR_NONE) {
throw new IllegalArgumentException(
"wrapper '" + ZlibWrapper.ZLIB_OR_NONE + "' is not " +
"allowed for compression.");
}
int resultCode = z.init(
compressionLevel, windowBits, memLevel,
ZlibUtil.convertWrapperType(wrapper));
if (resultCode != JZlib.Z_OK) {
ZlibUtil.fail(z, "initialization failure", resultCode);
}
wrapperOverhead = ZlibUtil.wrapperOverhead(wrapper);
}
/**
* Creates a new zlib encoder with the default compression level ({@code 6}),
* default window bits ({@code 15}), default memory level ({@code 8}),
* and the specified preset dictionary. The wrapper is always
* {@link ZlibWrapper#ZLIB} because it is the only format that supports
* the preset dictionary.
*
* @param dictionary the preset dictionary
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(byte[] dictionary) {
this(6, dictionary);
}
/**
* Creates a new zlib encoder with the specified {@code compressionLevel},
* default window bits ({@code 15}), default memory level ({@code 8}),
* and the specified preset dictionary. The wrapper is always
* {@link ZlibWrapper#ZLIB} because it is the only format that supports
* the preset dictionary.
*
* @param compressionLevel
* {@code 1} yields the fastest compression and {@code 9} yields the
* best compression. {@code 0} means no compression. The default
* compression level is {@code 6}.
* @param dictionary the preset dictionary
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(int compressionLevel, byte[] dictionary) {
this(compressionLevel, 15, 8, dictionary);
}
/**
* Creates a new zlib encoder with the specified {@code compressionLevel},
* the specified {@code windowBits}, the specified {@code memLevel},
* and the specified preset dictionary. The wrapper is always
* {@link ZlibWrapper#ZLIB} because it is the only format that supports
* the preset dictionary.
*
* @param compressionLevel
* {@code 1} yields the fastest compression and {@code 9} yields the
* best compression. {@code 0} means no compression. The default
* compression level is {@code 6}.
* @param windowBits
* The base two logarithm of the size of the history buffer. The
* value should be in the range {@code 9} to {@code 15} inclusive.
* Larger values result in better compression at the expense of
* memory usage. The default value is {@code 15}.
* @param memLevel
* How much memory should be allocated for the internal compression
* state. {@code 1} uses minimum memory and {@code 9} uses maximum
* memory. Larger values result in better and faster compression
* at the expense of memory usage. The default value is {@code 8}
* @param dictionary the preset dictionary
*
* @throws CompressionException if failed to initialize zlib
*/
public JZlibEncoder(int compressionLevel, int windowBits, int memLevel, byte[] dictionary) {
ObjectUtil.checkInRange(compressionLevel, 0, 9, "compressionLevel");
ObjectUtil.checkInRange(windowBits, 9, 15, "windowBits");
ObjectUtil.checkInRange(memLevel, 1, 9, "memLevel");
ObjectUtil.checkNotNull(dictionary, "dictionary");
int resultCode;
resultCode = z.deflateInit(
compressionLevel, windowBits, memLevel,
JZlib.W_ZLIB); // Default: ZLIB format
if (resultCode != JZlib.Z_OK) {
ZlibUtil.fail(z, "initialization failure", resultCode);
} else {
resultCode = z.deflateSetDictionary(dictionary, dictionary.length);
if (resultCode != JZlib.Z_OK) {
ZlibUtil.fail(z, "failed to set the dictionary", resultCode);
}
}
wrapperOverhead = ZlibUtil.wrapperOverhead(ZlibWrapper.ZLIB);
}
@Override
public ChannelFuture close() {
return close(ctx().channel().newPromise());
}
@Override
public ChannelFuture close(final ChannelPromise promise) {
ChannelHandlerContext ctx = ctx();
EventExecutor executor = ctx.executor();
if (executor.inEventLoop()) {
return finishEncode(ctx, promise);
} else {
final ChannelPromise p = ctx.newPromise();
executor.execute(new Runnable() {
@Override
public void run() {
ChannelFuture f = finishEncode(ctx(), p);
PromiseNotifier.cascade(f, promise);
}
});
return p;
}
}
private ChannelHandlerContext ctx() {
ChannelHandlerContext ctx = this.ctx;
if (ctx == null) {
throw new IllegalStateException("not added to a pipeline");
}
return ctx;
}
@Override
public boolean isClosed() {
return finished;
}
@Override
protected void encode(ChannelHandlerContext ctx, ByteBuf in, ByteBuf out) throws Exception {
if (finished) {
out.writeBytes(in);
return;
}
int inputLength = in.readableBytes();
if (inputLength == 0) {
return;
}
try {
// Configure input.
boolean inHasArray = in.hasArray();
z.avail_in = inputLength;
if (inHasArray) {
z.next_in = in.array();
z.next_in_index = in.arrayOffset() + in.readerIndex();
} else {
byte[] array = new byte[inputLength];
in.getBytes(in.readerIndex(), array);
z.next_in = array;
z.next_in_index = 0;
}
int oldNextInIndex = z.next_in_index;
// Configure output.
int maxOutputLength = (int) Math.ceil(inputLength * 1.001) + 12 + wrapperOverhead;
out.ensureWritable(maxOutputLength);
z.avail_out = maxOutputLength;
z.next_out = out.array();
z.next_out_index = out.arrayOffset() + out.writerIndex();
int oldNextOutIndex = z.next_out_index;
// Note that Z_PARTIAL_FLUSH has been deprecated.
int resultCode;
try {
resultCode = z.deflate(JZlib.Z_SYNC_FLUSH);
} finally {
in.skipBytes(z.next_in_index - oldNextInIndex);
}
if (resultCode != JZlib.Z_OK) {
ZlibUtil.fail(z, "compression failure", resultCode);
}
int outputLength = z.next_out_index - oldNextOutIndex;
if (outputLength > 0) {
out.writerIndex(out.writerIndex() + outputLength);
}
} finally {
// Deference the external references explicitly to tell the VM that
// the allocated byte arrays are temporary so that the call stack
// can be utilized.
// I'm not sure if the modern VMs do this optimization though.
z.next_in = null;
z.next_out = null;
}
}
@Override
public void close(
final ChannelHandlerContext ctx,
final ChannelPromise promise) {
ChannelFuture f = finishEncode(ctx, ctx.newPromise());
f.addListener(new ChannelFutureListener() {
@Override
public void operationComplete(ChannelFuture f) throws Exception {
ctx.close(promise);
}
});
if (!f.isDone()) {
// Ensure the channel is closed even if the write operation completes in time.
ctx.executor().schedule(new Runnable() {
@Override
public void run() {
ctx.close(promise);
}
}, THREAD_POOL_DELAY_SECONDS, TimeUnit.SECONDS);
}
}
private ChannelFuture finishEncode(ChannelHandlerContext ctx, ChannelPromise promise) {
if (finished) {
promise.setSuccess();
return promise;
}
finished = true;
ByteBuf footer;
try {
// Configure input.
z.next_in = EmptyArrays.EMPTY_BYTES;
z.next_in_index = 0;
z.avail_in = 0;
// Configure output.
byte[] out = new byte[32]; // room for ADLER32 + ZLIB / CRC32 + GZIP header
z.next_out = out;
z.next_out_index = 0;
z.avail_out = out.length;
// Write the ADLER32 checksum (stream footer).
int resultCode = z.deflate(JZlib.Z_FINISH);
if (resultCode != JZlib.Z_OK && resultCode != JZlib.Z_STREAM_END) {
promise.setFailure(ZlibUtil.deflaterException(z, "compression failure", resultCode));
return promise;
} else if (z.next_out_index != 0) { // lgtm[java/constant-comparison]
// Suppressed a warning above to be on the safe side
// even if z.next_out_index seems to be always 0 here
footer = Unpooled.wrappedBuffer(out, 0, z.next_out_index);
} else {
footer = Unpooled.EMPTY_BUFFER;
}
} finally {
z.deflateEnd();
// Deference the external references explicitly to tell the VM that
// the allocated byte arrays are temporary so that the call stack
// can be utilized.
// I'm not sure if the modern VMs do this optimization though.
z.next_in = null;
z.next_out = null;
}
return ctx.writeAndFlush(footer, promise);
}
@Override
public void handlerAdded(ChannelHandlerContext ctx) throws Exception {
this.ctx = ctx;
}
}