freebsd-dev/sys/contrib/zstd
Conrad Meyer a0483764f3 Update to Zstandard 1.3.8
This merge brings in a couple new files, which needed to be attached to the
build; a new dependency on <limits.h>, which must be stubbed; and a name
change in the Context parameter constants, from ZSTD_p_foo to ZSTD_c_foo.

Significantly, it fixes a kernel build error with GCC where floating-point
functions were included in the kernel build, by hiding them under the same
compile-time #ifdef that already covered their invocation.  That issue was
introduced to FreeBSD in the 1.3.7 update and tracked upstream here:

  https://github.com/facebook/zstd/issues/1386

The full 1.3.8 release notes can be found on Github:

  https://github.com/facebook/zstd/releases/tag/v1.3.8

Relnotes:	yes
2018-12-29 21:18:01 +00:00
..
contrib Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
doc Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
lib Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
programs Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
tests Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
zlibWrapper Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
.buckconfig
.buckversion
.gitattributes Update to Zstandard 1.3.7 2018-10-22 18:29:12 +00:00
appveyor.yml Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
CONTRIBUTING.md
COPYING
LICENSE
Makefile Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
README.md Update to Zstandard 1.3.8 2018-12-29 21:18:01 +00:00
TESTING.md Update to Zstandard 1.3.7 2018-10-22 18:29:12 +00:00

Zstandard

Zstandard, or zstd as short version, is a fast lossless compression algorithm, targeting real-time compression scenarios at zlib-level and better compression ratios. It's backed by a very fast entropy stage, provided by Huff0 and FSE library.

The project is provided as an open-source dual BSD and GPLv2 licensed C library, and a command line utility producing and decoding .zst, .gz, .xz and .lz4 files. Should your project require another programming language, a list of known ports and bindings is provided on Zstandard homepage.

Development branch status:

Build Status Build status Build status

Benchmarks

For reference, several fast compression algorithms were tested and compared on a server running Linux Debian (Linux version 4.14.0-3-amd64), with a Core i7-6700K CPU @ 4.0GHz, using lzbench, an open-source in-memory benchmark by @inikep compiled with gcc 7.3.0, on the Silesia compression corpus.

Compressor name Ratio Compression Decompress.
zstd 1.3.4 -1 2.877 470 MB/s 1380 MB/s
zlib 1.2.11 -1 2.743 110 MB/s 400 MB/s
brotli 1.0.2 -0 2.701 410 MB/s 430 MB/s
quicklz 1.5.0 -1 2.238 550 MB/s 710 MB/s
lzo1x 2.09 -1 2.108 650 MB/s 830 MB/s
lz4 1.8.1 2.101 750 MB/s 3700 MB/s
snappy 1.1.4 2.091 530 MB/s 1800 MB/s
lzf 3.6 -1 2.077 400 MB/s 860 MB/s

Zstd can also offer stronger compression ratios at the cost of compression speed. Speed vs Compression trade-off is configurable by small increments. Decompression speed is preserved and remains roughly the same at all settings, a property shared by most LZ compression algorithms, such as zlib or lzma.

The following tests were run on a server running Linux Debian (Linux version 4.14.0-3-amd64) with a Core i7-6700K CPU @ 4.0GHz, using lzbench, an open-source in-memory benchmark by @inikep compiled with gcc 7.3.0, on the Silesia compression corpus.

Compression Speed vs Ratio Decompression Speed
Compression Speed vs Ratio Decompression Speed

A few other algorithms can produce higher compression ratios at slower speeds, falling outside of the graph. For a larger picture including slow modes, click on this link.

The case for Small Data compression

Previous charts provide results applicable to typical file and stream scenarios (several MB). Small data comes with different perspectives.

The smaller the amount of data to compress, the more difficult it is to compress. This problem is common to all compression algorithms, and reason is, compression algorithms learn from past data how to compress future data. But at the beginning of a new data set, there is no "past" to build upon.

To solve this situation, Zstd offers a training mode, which can be used to tune the algorithm for a selected type of data. Training Zstandard is achieved by providing it with a few samples (one file per sample). The result of this training is stored in a file called "dictionary", which must be loaded before compression and decompression. Using this dictionary, the compression ratio achievable on small data improves dramatically.

The following example uses the github-users sample set, created from github public API. It consists of roughly 10K records weighing about 1KB each.

Compression Ratio Compression Speed Decompression Speed
Compression Ratio Compression Speed Decompression Speed

These compression gains are achieved while simultaneously providing faster compression and decompression speeds.

Training works if there is some correlation in a family of small data samples. The more data-specific a dictionary is, the more efficient it is (there is no universal dictionary). Hence, deploying one dictionary per type of data will provide the greatest benefits. Dictionary gains are mostly effective in the first few KB. Then, the compression algorithm will gradually use previously decoded content to better compress the rest of the file.

Dictionary compression How To:

  1. Create the dictionary

    zstd --train FullPathToTrainingSet/* -o dictionaryName

  2. Compress with dictionary

    zstd -D dictionaryName FILE

  3. Decompress with dictionary

    zstd -D dictionaryName --decompress FILE.zst

Build instructions

Makefile

If your system is compatible with standard make (or gmake), invoking make in root directory will generate zstd cli in root directory.

Other available options include:

  • make install : create and install zstd cli, library and man pages
  • make check : create and run zstd, tests its behavior on local platform

cmake

A cmake project generator is provided within build/cmake. It can generate Makefiles or other build scripts to create zstd binary, and libzstd dynamic and static libraries.

By default, CMAKE_BUILD_TYPE is set to Release.

Meson

A Meson project is provided within build/meson. Follow build instructions in that directory.

You can also take a look at .travis.yml file for an example about how Meson is used to build this project.

Note that default build type is release.

Visual Studio (Windows)

Going into build directory, you will find additional possibilities:

  • Projects for Visual Studio 2005, 2008 and 2010.
    • VS2010 project is compatible with VS2012, VS2013, VS2015 and VS2017.
  • Automated build scripts for Visual compiler by @KrzysFR, in build/VS_scripts, which will build zstd cli and libzstd library without any need to open Visual Studio solution.

Buck

You can build the zstd binary via buck by executing: buck build programs:zstd from the root of the repo. The output binary will be in buck-out/gen/programs/.

Status

Zstandard is currently deployed within Facebook. It is used continuously to compress large amounts of data in multiple formats and use cases. Zstandard is considered safe for production environments.

License

Zstandard is dual-licensed under BSD and GPLv2.

Contributing

The "dev" branch is the one where all contributions are merged before reaching "master". If you plan to propose a patch, please commit into the "dev" branch, or its own feature branch. Direct commit to "master" are not permitted. For more information, please read CONTRIBUTING.