[pcsx_rearmed.git] / deps / libchdr / deps / zstd-1.5.5 / README.md

<p align="center"><img src="https://raw.githubusercontent.com/facebook/zstd/dev/doc/images/zstd_logo86.png" alt="Zstandard"></p>

__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](https://github.com/Cyan4973/FiniteStateEntropy).

Zstandard's format is stable and documented in [RFC8878](https://datatracker.ietf.org/doc/html/rfc8878). Multiple independent implementations are already available.
This repository represents the reference implementation, provided as an open-source dual [BSD](LICENSE) and [GPLv2](COPYING) 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](https://facebook.github.io/zstd/#other-languages).

**Development branch status:**

[![Build Status][travisDevBadge]][travisLink]
[![Build status][CircleDevBadge]][CircleLink]
[![Build status][CirrusDevBadge]][CirrusLink]
[![Fuzzing Status][OSSFuzzBadge]][OSSFuzzLink]

[travisDevBadge]: https://api.travis-ci.com/facebook/zstd.svg?branch=dev "Continuous Integration test suite"
[travisLink]: https://travis-ci.com/facebook/zstd
[CircleDevBadge]: https://circleci.com/gh/facebook/zstd/tree/dev.svg?style=shield "Short test suite"
[CircleLink]: https://circleci.com/gh/facebook/zstd
[CirrusDevBadge]: https://api.cirrus-ci.com/github/facebook/zstd.svg?branch=dev
[CirrusLink]: https://cirrus-ci.com/github/facebook/zstd
[OSSFuzzBadge]: https://oss-fuzz-build-logs.storage.googleapis.com/badges/zstd.svg
[OSSFuzzLink]: https://bugs.chromium.org/p/oss-fuzz/issues/list?sort=-opened&can=1&q=proj:zstd

## Benchmarks

For reference, several fast compression algorithms were tested and compared
on a desktop running Ubuntu 20.04 (`Linux 5.11.0-41-generic`),
with a Core i7-9700K CPU @ 4.9GHz,
using [lzbench], an open-source in-memory benchmark by @inikep
compiled with [gcc] 9.3.0,
on the [Silesia compression corpus].

[lzbench]: https://github.com/inikep/lzbench
[Silesia compression corpus]: https://sun.aei.polsl.pl//~sdeor/index.php?page=silesia
[gcc]: https://gcc.gnu.org/

| Compressor name         | Ratio | Compression| Decompress.|
| ---------------         | ------| -----------| ---------- |
| **zstd 1.5.1 -1**       | 2.887 |   530 MB/s |  1700 MB/s |
| [zlib] 1.2.11 -1        | 2.743 |    95 MB/s |   400 MB/s |
| brotli 1.0.9 -0         | 2.702 |   395 MB/s |   450 MB/s |
| **zstd 1.5.1 --fast=1** | 2.437 |   600 MB/s |  2150 MB/s |
| **zstd 1.5.1 --fast=3** | 2.239 |   670 MB/s |  2250 MB/s |
| quicklz 1.5.0 -1        | 2.238 |   540 MB/s |   760 MB/s |
| **zstd 1.5.1 --fast=4** | 2.148 |   710 MB/s |  2300 MB/s |
| lzo1x 2.10 -1           | 2.106 |   660 MB/s |   845 MB/s |
| [lz4] 1.9.3             | 2.101 |   740 MB/s |  4500 MB/s |
| lzf 3.6 -1              | 2.077 |   410 MB/s |   830 MB/s |
| snappy 1.1.9            | 2.073 |   550 MB/s |  1750 MB/s |

[zlib]: https://www.zlib.net/
[lz4]: https://lz4.github.io/lz4/

The negative compression levels, specified with `--fast=#`,
offer faster compression and decompression speed
at the cost of compression ratio (compared to level 1).

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](doc/images/CSpeed2.png "Compression Speed vs Ratio") | ![Decompression Speed](doc/images/DSpeed3.png "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](doc/images/DCspeed5.png).


## 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](https://github.com/facebook/zstd/releases/tag/v1.1.3), created from [github public API](https://developer.github.com/v3/users/#get-all-users).
It consists of roughly 10K records weighing about 1KB each.

Compression Ratio | Compression Speed | Decompression Speed
------------------|-------------------|--------------------
![Compression Ratio](doc/images/dict-cr.png "Compression Ratio") | ![Compression Speed](doc/images/dict-cs.png "Compression Speed") | ![Decompression Speed](doc/images/dict-ds.png "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

`make` is the officially maintained build system of this project.
All other build systems are "compatible" and 3rd-party maintained,
they may feature small differences in advanced options.
When your system allows it, prefer using `make` to build `zstd` and `libzstd`.

### Makefile

If your system is compatible with standard `make` (or `gmake`),
invoking `make` in root directory will generate `zstd` cli in root directory.
It will also create `libzstd` into `lib/`.

Other available options include:
- `make install` : create and install zstd cli, library and man pages
- `make check` : create and run `zstd`, test its behavior on local platform

The `Makefile` follows the [GNU Standard Makefile conventions](https://www.gnu.org/prep/standards/html_node/Makefile-Conventions.html),
allowing staged install, standard flags, directory variables and command variables.

For advanced use cases, specialized compilation flags which control binary generation
are documented in [`lib/README.md`](lib/README.md#modular-build) for the `libzstd` library
and in [`programs/README.md`](programs/README.md#compilation-variables) for the `zstd` CLI.

### 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`.

#### Support for Fat (Universal2) Output

`zstd` can be built and installed with support for both Apple Silicon (M1/M2) as well as Intel by using CMake's Universal2 support.
To perform a Fat/Universal2 build and install use the following commands:

```bash
cmake -B build-cmake-debug -S build/cmake -G Ninja -DCMAKE_OSX_ARCHITECTURES="x86_64;x86_64h;arm64"
cd build-cmake-debug
ninja
sudo ninja install
```

### Meson

A Meson project is provided within [`build/meson`](build/meson). Follow
build instructions in that directory.

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

Note that default build type is **release**.

### VCPKG
You can build and install zstd [vcpkg](https://github.com/Microsoft/vcpkg/) dependency manager:

    git clone https://github.com/Microsoft/vcpkg.git
    cd vcpkg
    ./bootstrap-vcpkg.sh
    ./vcpkg integrate install
    ./vcpkg install zstd

The zstd port in vcpkg is kept up to date by Microsoft team members and community contributors.
If the version is out of date, please [create an issue or pull request](https://github.com/Microsoft/vcpkg) on the vcpkg repository.

### 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](https://github.com/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/`.

## Testing

You can run quick local smoke tests by running `make check`.
If you can't use `make`, execute the `playTest.sh` script from the `src/tests` directory.
Two env variables `$ZSTD_BIN` and `$DATAGEN_BIN` are needed for the test script to locate the `zstd` and `datagen` binary.
For information on CI testing, please refer to `TESTING.md`.

## Status

Zstandard is currently deployed within Facebook and many other large cloud infrastructures.
It is run 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](LICENSE) and [GPLv2](COPYING).

## Contributing

The `dev` branch is the one where all contributions are merged before reaching `release`.
If you plan to propose a patch, please commit into the `dev` branch, or its own feature branch.
Direct commit to `release` are not permitted.
For more information, please read [CONTRIBUTING](CONTRIBUTING.md).
Commit	Line	Data
648db22b	1	<p align="center"><img src="https://raw.githubusercontent.com/facebook/zstd/dev/doc/images/zstd_logo86.png" alt="Zstandard"></p>
	2
	3	__Zstandard__, or `zstd` as short version, is a fast lossless compression algorithm,
	4	targeting real-time compression scenarios at zlib-level and better compression ratios.
	5	It's backed by a very fast entropy stage, provided by [Huff0 and FSE library](https://github.com/Cyan4973/FiniteStateEntropy).
	6
	7	Zstandard's format is stable and documented in [RFC8878](https://datatracker.ietf.org/doc/html/rfc8878). Multiple independent implementations are already available.
	8	This repository represents the reference implementation, provided as an open-source dual [BSD](LICENSE) and [GPLv2](COPYING) licensed C library,
	9	and a command line utility producing and decoding `.zst`, `.gz`, `.xz` and `.lz4` files.
	10	Should your project require another programming language,
	11	a list of known ports and bindings is provided on [Zstandard homepage](https://facebook.github.io/zstd/#other-languages).
	12
	13	Development branch status:
	14
	15	[![Build Status][travisDevBadge]][travisLink]
	16	[![Build status][CircleDevBadge]][CircleLink]
	17	[![Build status][CirrusDevBadge]][CirrusLink]
	18	[![Fuzzing Status][OSSFuzzBadge]][OSSFuzzLink]
	19
	20	[travisDevBadge]: https://api.travis-ci.com/facebook/zstd.svg?branch=dev "Continuous Integration test suite"
	21	[travisLink]: https://travis-ci.com/facebook/zstd
	22	[CircleDevBadge]: https://circleci.com/gh/facebook/zstd/tree/dev.svg?style=shield "Short test suite"
	23	[CircleLink]: https://circleci.com/gh/facebook/zstd
	24	[CirrusDevBadge]: https://api.cirrus-ci.com/github/facebook/zstd.svg?branch=dev
	25	[CirrusLink]: https://cirrus-ci.com/github/facebook/zstd
	26	[OSSFuzzBadge]: https://oss-fuzz-build-logs.storage.googleapis.com/badges/zstd.svg
	27	[OSSFuzzLink]: https://bugs.chromium.org/p/oss-fuzz/issues/list?sort=-opened&can=1&q=proj:zstd
	28
	29	## Benchmarks
	30
	31	For reference, several fast compression algorithms were tested and compared
	32	on a desktop running Ubuntu 20.04 (`Linux 5.11.0-41-generic`),
	33	with a Core i7-9700K CPU @ 4.9GHz,
	34	using [lzbench], an open-source in-memory benchmark by @inikep
	35	compiled with [gcc] 9.3.0,
	36	on the [Silesia compression corpus].
	37
	38	[lzbench]: https://github.com/inikep/lzbench
	39	[Silesia compression corpus]: https://sun.aei.polsl.pl//~sdeor/index.php?page=silesia
	40	[gcc]: https://gcc.gnu.org/
	41
	42	\| Compressor name \| Ratio \| Compression\| Decompress.\|
	43	\| --------------- \| ------\| -----------\| ---------- \|
	44	\| zstd 1.5.1 -1 \| 2.887 \| 530 MB/s \| 1700 MB/s \|
	45	\| [zlib] 1.2.11 -1 \| 2.743 \| 95 MB/s \| 400 MB/s \|
	46	\| brotli 1.0.9 -0 \| 2.702 \| 395 MB/s \| 450 MB/s \|
	47	\| zstd 1.5.1 --fast=1 \| 2.437 \| 600 MB/s \| 2150 MB/s \|
	48	\| zstd 1.5.1 --fast=3 \| 2.239 \| 670 MB/s \| 2250 MB/s \|
	49	\| quicklz 1.5.0 -1 \| 2.238 \| 540 MB/s \| 760 MB/s \|
	50	\| zstd 1.5.1 --fast=4 \| 2.148 \| 710 MB/s \| 2300 MB/s \|
	51	\| lzo1x 2.10 -1 \| 2.106 \| 660 MB/s \| 845 MB/s \|
	52	\| [lz4] 1.9.3 \| 2.101 \| 740 MB/s \| 4500 MB/s \|
	53	\| lzf 3.6 -1 \| 2.077 \| 410 MB/s \| 830 MB/s \|
	54	\| snappy 1.1.9 \| 2.073 \| 550 MB/s \| 1750 MB/s \|
	55
	56	[zlib]: https://www.zlib.net/
	57	[lz4]: https://lz4.github.io/lz4/
	58
	59	The negative compression levels, specified with `--fast=#`,
	60	offer faster compression and decompression speed
	61	at the cost of compression ratio (compared to level 1).
	62
	63	Zstd can also offer stronger compression ratios at the cost of compression speed.
	64	Speed vs Compression trade-off is configurable by small increments.
65	Decompression speed is preserved and remains roughly the same at all settings,
66	a property shared by most LZ compression algorithms, such as [zlib] or lzma.
67
68	The following tests were run
69	on a server running Linux Debian (`Linux version 4.14.0-3-amd64`)
70	with a Core i7-6700K CPU @ 4.0GHz,
71	using [lzbench], an open-source in-memory benchmark by @inikep
72	compiled with [gcc] 7.3.0,
73	on the [Silesia compression corpus].
74
75	Compression Speed vs Ratio \| Decompression Speed
76	---------------------------\|--------------------
77	![Compression Speed vs Ratio](doc/images/CSpeed2.png "Compression Speed vs Ratio") \| ![Decompression Speed](doc/images/DSpeed3.png "Decompression Speed")
78
79	A few other algorithms can produce higher compression ratios at slower speeds, falling outside of the graph.
80	For a larger picture including slow modes, [click on this link](doc/images/DCspeed5.png).
81
82
83	## The case for Small Data compression
84
85	Previous charts provide results applicable to typical file and stream scenarios (several MB). Small data comes with different perspectives.
86
87	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.
88
89	To solve this situation, Zstd offers a __training mode__, which can be used to tune the algorithm for a selected type of data.
90	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.
91	Using this dictionary, the compression ratio achievable on small data improves dramatically.
92
93	The following example uses the `github-users` [sample set](https://github.com/facebook/zstd/releases/tag/v1.1.3), created from [github public API](https://developer.github.com/v3/users/#get-all-users).
94	It consists of roughly 10K records weighing about 1KB each.
95
96	Compression Ratio \| Compression Speed \| Decompression Speed
97	------------------\|-------------------\|--------------------
98	![Compression Ratio](doc/images/dict-cr.png "Compression Ratio") \| ![Compression Speed](doc/images/dict-cs.png "Compression Speed") \| ![Decompression Speed](doc/images/dict-ds.png "Decompression Speed")
99
100
101	These compression gains are achieved while simultaneously providing _faster_ compression and decompression speeds.
102
103	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_).
104	Hence, deploying one dictionary per type of data will provide the greatest benefits.
105	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.
106
107	### Dictionary compression How To:
108
109	1. Create the dictionary
110
111	`zstd --train FullPathToTrainingSet/* -o dictionaryName`
112
113	2. Compress with dictionary
114
115	`zstd -D dictionaryName FILE`
116
117	3. Decompress with dictionary
118
119	`zstd -D dictionaryName --decompress FILE.zst`
120
121
122	## Build instructions
123
124	`make` is the officially maintained build system of this project.
125	All other build systems are "compatible" and 3rd-party maintained,
126	they may feature small differences in advanced options.
127	When your system allows it, prefer using `make` to build `zstd` and `libzstd`.
128
129	### Makefile
130
131	If your system is compatible with standard `make` (or `gmake`),
132	invoking `make` in root directory will generate `zstd` cli in root directory.
133	It will also create `libzstd` into `lib/`.
134
135	Other available options include:
136	- `make install` : create and install zstd cli, library and man pages
137	- `make check` : create and run `zstd`, test its behavior on local platform
138
139	The `Makefile` follows the [GNU Standard Makefile conventions](https://www.gnu.org/prep/standards/html_node/Makefile-Conventions.html),
140	allowing staged install, standard flags, directory variables and command variables.
141
142	For advanced use cases, specialized compilation flags which control binary generation
143	are documented in [`lib/README.md`](lib/README.md#modular-build) for the `libzstd` library
144	and in [`programs/README.md`](programs/README.md#compilation-variables) for the `zstd` CLI.
145
146	### cmake
147
148	A `cmake` project generator is provided within `build/cmake`.
149	It can generate Makefiles or other build scripts
150	to create `zstd` binary, and `libzstd` dynamic and static libraries.
151
152	By default, `CMAKE_BUILD_TYPE` is set to `Release`.
153
154	#### Support for Fat (Universal2) Output
155
156	`zstd` can be built and installed with support for both Apple Silicon (M1/M2) as well as Intel by using CMake's Universal2 support.
157	To perform a Fat/Universal2 build and install use the following commands:
158
159	```bash
160	cmake -B build-cmake-debug -S build/cmake -G Ninja -DCMAKE_OSX_ARCHITECTURES="x86_64;x86_64h;arm64"
161	cd build-cmake-debug
162	ninja
163	sudo ninja install
164	```
165
166	### Meson
167
168	A Meson project is provided within [`build/meson`](build/meson). Follow
169	build instructions in that directory.
170
171	You can also take a look at [`.travis.yml`](.travis.yml) file for an
172	example about how Meson is used to build this project.
173
174	Note that default build type is release.
175
176	### VCPKG
177	You can build and install zstd [vcpkg](https://github.com/Microsoft/vcpkg/) dependency manager:
178
179	git clone https://github.com/Microsoft/vcpkg.git
180	cd vcpkg
181	./bootstrap-vcpkg.sh
182	./vcpkg integrate install
183	./vcpkg install zstd
184
185	The zstd port in vcpkg is kept up to date by Microsoft team members and community contributors.
186	If the version is out of date, please [create an issue or pull request](https://github.com/Microsoft/vcpkg) on the vcpkg repository.
187
188	### Visual Studio (Windows)
189
190	Going into `build` directory, you will find additional possibilities:
191	- Projects for Visual Studio 2005, 2008 and 2010.
192	+ VS2010 project is compatible with VS2012, VS2013, VS2015 and VS2017.
193	- Automated build scripts for Visual compiler by [@KrzysFR](https://github.com/KrzysFR), in `build/VS_scripts`,
194	which will build `zstd` cli and `libzstd` library without any need to open Visual Studio solution.
195
196	### Buck
197
198	You can build the zstd binary via buck by executing: `buck build programs:zstd` from the root of the repo.
199	The output binary will be in `buck-out/gen/programs/`.
200
201	## Testing
202
203	You can run quick local smoke tests by running `make check`.
204	If you can't use `make`, execute the `playTest.sh` script from the `src/tests` directory.
205	Two env variables `$ZSTD_BIN` and `$DATAGEN_BIN` are needed for the test script to locate the `zstd` and `datagen` binary.
206	For information on CI testing, please refer to `TESTING.md`.
207
208	## Status
209
210	Zstandard is currently deployed within Facebook and many other large cloud infrastructures.
211	It is run continuously to compress large amounts of data in multiple formats and use cases.
212	Zstandard is considered safe for production environments.
213
214	## License
215
216	Zstandard is dual-licensed under [BSD](LICENSE) and [GPLv2](COPYING).
217
218	## Contributing
219
220	The `dev` branch is the one where all contributions are merged before reaching `release`.
221	If you plan to propose a patch, please commit into the `dev` branch, or its own feature branch.
222	Direct commit to `release` are not permitted.
223	For more information, please read [CONTRIBUTING](CONTRIBUTING.md).