LZ4 compression for Java, based on Yann Collet's work available at http://code.google.com/p/lz4/.
This library provides access to two compression methods that both generate a valid LZ4 stream:
- fast scan (LZ4):
- low memory footprint (~ 16 KB),
- very fast (fast scan with skipping heuristics in case the input looks incompressible),
- reasonable compression ratio (depending on the redundancy of the input).
- high compression (LZ4 HC):
- medium memory footprint (~ 256 KB),
- rather slow (~ 10 times slower than LZ4),
- good compression ratio (depending on the size and the redundancy of the input).
The streams produced by those 2 compression algorithms use the same compression format, are very fast to decompress and can be decompressed by the same decompressor instance.
For LZ4 compressors, LZ4 HC compressors and decompressors, 3 implementations are available:
- JNI bindings to the original C implementation by Yann Collet,
- a pure Java port of the compression and decompression algorithms,
- a Java port that uses the sun.misc.Unsafe API in order to achieve compression and decompression speeds close to the C implementation.
Have a look at LZ4Factory for more information.
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Compressors and decompressors are interchangeable: it is perfectly correct to compress with the JNI bindings and to decompress with a Java port, or the other way around.
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Compressors might not generate the same compressed streams on all platforms, especially if CPU endianness differs, but the compressed streams can be safely decompressed by any decompressor implementation on any platform.
LZ4Factory factory = LZ4Factory.fastestInstance();
byte[] data = "12345345234572".getBytes("UTF-8");
final int decompressedLength = data.length;
// compress data
LZ4Compressor compressor = factory.fastCompressor();
int maxCompressedLength = compressor.maxCompressedLength(decompressedLength);
byte[] compressed = new byte[maxCompressedLength];
int compressedLength = compressor.compress(data, 0, decompressedLength, compressed, 0, maxCompressedLength);
// decompress data
// - method 1: when the decompressed length is known
LZ4FastDecompressor decompressor = factory.fastDecompressor();
byte[] restored = new byte[decompressedLength];
int compressedLength2 = decompressor.decompress(compressed, 0, restored, 0, decompressedLength);
// compressedLength == compressedLength2
// - method 2: when the compressed length is known (a little slower)
// the destination buffer needs to be over-sized
LZ4SafeDecompressor decompressor2 = factory.safeDecompressor();
int decompressedLength2 = decompressor2.decompress(compressed, 0, compressedLength, restored, 0);
// decompressedLength == decompressedLength2byte[] data = "12345345234572".getBytes("UTF-8");
final int decompressedLength = data.length;
LZ4FrameOutputStream outStream = new LZ4FrameOutputStream(new FileOutputStream(new File("test.lz4")));
outStream.write(data);
outStream.close();
byte[] restored = new byte[decompressedLength];
LZ4FrameInputStream inStream = new LZ4FrameInputStream(new FileInputStream(new File("test.lz4")));
inStream.read(restored);
inStream.close();xxhash hashing for Java, based on Yann Collet's work available at https://github.com/Cyan4973/xxHash (old version http://code.google.com/p/xxhash/). xxhash is a non-cryptographic, extremly fast and high-quality (SMHasher score of 10) hash function.
Similarly to LZ4, 3 implementations are available: JNI bindings, pure Java port and pure Java port that uses sun.misc.Unsafe.
Have a look at XXHashFactory for more information.
- All implementation return the same hash for the same input bytes:
- on any JVM,
- on any platform (even if the endianness or integer size differs).
XXHashFactory factory = XXHashFactory.fastestInstance();
byte[] data = "12345345234572".getBytes("UTF-8");
ByteArrayInputStream in = new ByteArrayInputStream(data);
int seed = 0x9747b28c; // used to initialize the hash value, use whatever
// value you want, but always the same
StreamingXXHash32 hash32 = factory.newStreamingHash32(seed);
byte[] buf = new byte[8]; // for real-world usage, use a larger buffer, like 8192 bytes
for (;;) {
int read = in.read(buf);
if (read == -1) {
break;
}
hash32.update(buf, 0, read);
}
int hash = hash32.getValue();You can download released artifacts from Maven Central.
You can download pure-Java lz4-java from Maven Central. These artifacts include the Safe and Unsafe Java versions but not JNI bindings. (Experimental)
Both lz4 and xxhash focus on speed. Although compression, decompression and hashing performance can depend a lot on the input (there are lies, damn lies and benchmarks), here are some benchmarks that try to give a sense of the speed at which they compress/decompress/hash bytes.
- JDK version 7 or newer,
- ant version 1.10.2 or newer,
- ivy.
If ivy is not installed yet, ant can take care of it for you, just run
ant ivy-bootstrap. The library will be installed under ${user.home}/.ant/lib.
You might hit an error like the following when the ivy in ${user.home}/.ant/lib is old. You can delete it and then run ant ivy-bootstrap again to install the latest version.
[ivy:resolve] ::::::::::::::::::::::::::::::::::::::::::::::
[ivy:resolve] :: UNRESOLVED DEPENDENCIES ::
[ivy:resolve] ::::::::::::::::::::::::::::::::::::::::::::::
For lz4-java 1.5.0 or newer, first run git submodule init and then git submodule update
to initialize the lz4 submodule in src/lz4.
Then run ant. It will:
- generate some Java source files in
build/javafrom the templates that are located undersrc/build, - compile the lz4 and xxhash libraries and their JNI (Java Native Interface) bindings,
- compile Java sources in
src/java(normal sources),src/java-unsafe(sources that make use ofsun.misc.Unsafe) andbuild/java(auto-generated sources) tobuild/classes,build/unsafe-classesandbuild/generated-classes, - generate a JAR file called lz4-${version}.jar under the
distdirectory.
The JAR file that is generated contains Java class files, the native library and the JNI bindings. If you add this JAR to your classpath, the native library will be copied to a temporary directory and dynamically linked to your Java application.