If I were to AES-encrypt a file, and then ZLIB-compress it, would the compression be less efficient than if I first compressed and then encrypted?

In other words, should I compress first or encrypt first, or does it matter?

  • 1
    They are not the same question at all. This question asks about efficiency, the other is about security.
    – Ferruccio
    Commented Jun 28, 2016 at 18:02
  • I feel like this question was never fully answered, as the answers all seem to discuss efficiency from the standpoint of "compressed data size" (or compression ratio, or whatever you want to call it). Another aspect to consider is the total CPU time needed to process the data, and by this measure for a compressible (i.e. text, not binary) payload of nontrivial size (i.e. anything over a few kB) it's more computationally efficient to compress and then encrypt (even versus just encrypting the uncompressed data and performing no compression at all).
    – aroth
    Commented Jun 25, 2020 at 7:46

6 Answers 6


Compress first. Once you encrypt the file you will generate a stream of seemingly random data, which will be not be compressible. The compression process depends on finding compressible patterns in the data.

  • 12
    It's not really random. It's just that no compression algorithm will be able to spot the pattern anymore after it's encrypted.
    – finnw
    Commented Jan 13, 2011 at 2:04
  • 1
    True enough. It looks random. The process is deterministic, so given the same data and key you will get the same random looking result.
    – Ferruccio
    Commented Jan 13, 2011 at 11:46
  • 2
    @finnw Supposing the encryption algorithm takes steps to remove patterns (such as using a block cipher in CBC mode with a random IV), encrypted data is indistinguishable from random data.
    – yfeldblum
    Commented Jan 13, 2011 at 14:06
  • @Ferruccio If you use, for example, a block cipher in CBC mode with a random IV, then, given the same data and the same key, you will get a different random-looking result.
    – yfeldblum
    Commented Jan 13, 2011 at 14:07
  • 3
    Does any practical (finite-time) compression algorithm fully randomize the message? Isn't there always a residual pattern to the compressed data that can then be used to break the encryption (theoretically)? Don't many compression algorithms add header/footer signatures in the compressed file? The nature/pattern of that residual will be the same across multiple different compressed messages (assuming they used the same compression algorithm), and that gives the cracker statistical information about the unencrypted (but compressed) message that he can potentially exploit.
    – hobs
    Commented Jan 7, 2014 at 0:19

Compression before encryption is surely more space efficient but in the same time less secure. That's why I would disagree with other answers.

Most compression algorithms use "magic" file headers and that could be used for statistical attacks.

For example, there is a CRIME SSL/TLS attack.

  • So, is it a trade-off, then? Looks like the two choices are: 1) Encrypt, then compress for greater security but less effective compression. 2) Compress, then encrypt for more effective compression but introduce a vulnerability. Commented Jan 8, 2018 at 23:07
  • 2
    Doesn't this require a known-plaintext attack to be viable against your chosen cryptographic primitive?
    – Awn
    Commented May 31, 2018 at 21:27
  • If you want the better file size and security, compress, encrypt, then compress again. The final compression won't be able to compress anything but it will randomize the data.
    – Zintom
    Commented Jan 23, 2021 at 18:05

If your encryption algorithm is any good (and AES, with a proper chaining mode, is good), then no compressor will be able to shrink the encrypted text. Or, if you prefer it the other way round: if you succeed in compressing some encrypted text, then it is high time to question the quality of the encryption algorithm…

That is because the output of an encryption system should be indistinguishable from purely random data, even by a determined attacker. A compressor is not a malicious attacker, but it works by trying to find non-random patterns which it can represent with fewer bits. The compressor should not be able to find any such pattern in encrypted text.

So you should compress data first, then encrypt the result, not the other way round. This is what is done in, e.g., the OpenPGP format.


Compress first. If you encrypt then your data turns into (essentially) a stream of random bits. Random bits are incompressable because compression looks for patterns in the data and a random stream, by definition, has no patterns.


Of course it matters. It's generally better to compress first and then to encrypt.

ZLib uses Huffman coding and LZ77 compression. The Huffman tree will be more balanced and optimum if it's performed on plain text for instance and so the compression rate will be better.

Encryption can follow after compression even if the compression result appear to be "encrypted" but can easily be detected to be compressed because the file usually starts with PK.

ZLib don't provide encryption natively. That's why I've implemented ZeusProtection. The source code is also available at github.


From a practical perspective, I think you should compress first simply because many files are pre-compressed. For example, video encoding usually involves heavy compression. If you encrypt this video file then compress it, it has now been compressed twice. Not only will the second compression get a dismal compression ratio, but compressing again will take a great deal of resources to compress large files or streams. As Thomas Pornin and Ferruccio stated, compression of encrypted files may have little effect anyway because of the randomness of the encrypted files.

I think the best, and simplest, policy may be to compress files only-as-needed beforehand (using a whitelist or blacklist), then encrypt them regardless.

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