I have a large file of size 500 mb to compress in a minute with the best possible compression ratio. I have found out these algorithms to be suitable for my use.

  1. lz4
  2. lz4_hc
  3. snappy
  4. quicklz
  5. blosc

Can someone give a comparison of speed and compression ratios between these algorithms?

  • Have you found a comparison between lz4 and fastlz?
    – roalz
    Sep 15, 2017 at 9:21
  • I'm interested too, it seems lz4 is more efficient than fastlz but I couldn't find stats proving that fact.
    – rraallvv
    Apr 22, 2018 at 18:48

4 Answers 4


Yann Collet's lz4, hands down.

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  • 1
    What is you recommendation for embedded systems? which is the efficient compression and decompression algorithm regarding and space and time. Jan 19, 2018 at 4:21
  • 1
    Often people don't know about the large-window brotli and perform large corpus benchmarking with the small-window brotli. Brotli's HTTP content encoding variant is small-window to allow decompression on cheap mobile phones. Other compressors (particularly so lzma and zstd) don't do that limitation and should be compared with large-window brotli, not small-window brotli. Typically you can see 10 % density improvements (within 0.6 % of lzma) using the large-window brotli, while keeping the high decompression speed. Mar 27, 2019 at 15:25

This migth help you: (lz4 vs snappy) http://java-performance.info/performance-general-compression/ (benchmarks for lz4, snappy, lz4hc, blosc) https://web.archive.org/web/20170706065303/http://blosc.org:80/synthetic-benchmarks.html (now not available on http://www.blosc.org/synthetic-benchmarks.html)


If you are only aiming for high compression density, you want to look at LZMA and large-window Brotli. These two algorithms give the best compression density from the widely available open-sourced algorithms. Brotli is slower at compression, but ~5x faster at decompression.


Like most questions, the answer usually ends up being: It depends :)

The other answers gave you good pointers, but another thing to take into account is RAM usage in both compression and decompression stages, as well as decompression speed in MB/s.

Decompression speed is typically inversely proportional to the compression ratio, so you may think you chose the perfect algorithm to save some bandwidth/disk storage, but then whatever is consuming that data downstream now has to spend much more time, CPU cycles and/or RAM to decompress. And RAM usage might seem inconsequential, but maybe the downstream system is an embedded/low-voltage system? Maybe RAM is plentiful, but CPU is limited? All those things need to be taken into account.

Here's an example of a suite of benchmarks done on various algorithms, taking a lot of these considerations into account:


  • That was one of the interesting things about H265 vs H264 as well. H264 encodes faster, but results in a larger size. H265 results in a smaller result, and the decoder, while more complex, actually runs at similar speeds because the resulting data it needs to work on is significantly less.
    – Pyro
    Nov 27, 2020 at 16:20

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