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For example, when you tar -zcvf a directory, you can see a list of files being added sequentially to the final gzip file.

But how does that happen?

Any compression algorithm at the very basic level uses the redundancy in data to represent it in a better way and hence save space.

But when file n is being added, there is already a way chosen to represent the first n - 1 files which might not be the optimal one because until file n came across we never knew what the best way was.

Am I missing something? If not, does this mean that all these compression algorithms choose some sub-optimal representation of data?

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How would you define what a optimal representation of data is? Because I don't there is any reasonable definition. –  svick Apr 24 '11 at 19:38
optimal = whatever representation compresses the data most –  Lazer Apr 24 '11 at 19:43
given that different compression algorithms/programs produce different-sized output for the same input, you know for sure that all but one of them are "sub-optimal". Seems reasonable to me to suspect that the other one is too ;-) –  Steve Jessop Apr 24 '11 at 20:05
Also, there's a theorem in information theory about this - Kolmogorov complexity is not a computable function. Therefore if your compression algorithm creates a self-extracting archive, or any other compressed format which is in reality bytecodes that are interpreted on some virtual machine to decompress, then it's generally not possible to write an algorithm that produces optimal output. Restricted models admit proofs of optimal compression (e.g. Huffman encoding is optimal within its constraints), but the constraints make the actual compression results worse than unconstrained competitors. –  Steve Jessop Apr 24 '11 at 22:08
given specific input, I can easily write a program that will compress it to 0 bytes, but it will make any other input longer by 1 byte. On the other hand, it's impossible to write a program that will compress any input at least by one byte. All compression algorithms are just trade-offs between these two exteremes. –  svick Apr 25 '11 at 0:37

3 Answers 3

In gzip, the redundancy is restricted to a specific window size (by default 32k if I remember right). That means that after you process uncompressed data past that window, you can start writing compressed output.

You could call that "suboptimal", but the benefits provided, such as the ability to stream, and possibly error recovery (if there are synchronisation marks between windows; not sure how gzip works here), are worth it.

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The short answer is that it doesn't -- gzip works incrementally, so the first part of a file generally is not compressed quite as much as later parts of the file.

The good point of this is that the compressed data itself contains what's necessary to build a "dictionary" to decompress the data, so you never have to explicitly transmit the dictionary with the data.

There are methods of compression (e.g., two-pass Huffmany compression) where you scan through the data to find an ideal "dictionary" for that particular data, and then use it compress the data. When you do this, however, you generally have to transmit the dictionary along with the data to be able to decompress it on the receiving end.

That can be a reasonable tradeoff -- if you have a reasonably high level of certainty that you'll be compressing enough data with the same dictionary, you might gain more from the improved compression than you lose by transmitting the dictionary. There is one problem though: the "character" of the data in a file often changes within the same file, so the dictionary that works best in one part of the file may not be very good at all for a different part of the file. This is particularly relevant for compressing a tar file that contains a number of constituent files, each of which may (and probably will) have differing redundancy.

The incremental/dynamic compression that gzip uses deals with that fairly well, because the dictionary it uses is automatically/constantly "adjusting" itself based on a window of the most recently-seen data. The primary disadvantage is that there's a bit of a "lag" built in, so right where the "character" of the data changes, the compression will temporarily drop until the dictionary has had a chance to "adjust" to the change.

A two-pass algorithm can improve compression for data that remains similar throughout the entire stream you're compressing. An incremental algorithm tends to do a better job of adjusting to more variable data.

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When you say tar -zcvf X, that is equivalent to saying:

tar -cvf X | gzip 

So all gzip sees is bunch of bytes that it compresses, tar and gzip don't have a conversation about how tar should order the files for gzip to optimially compress the entire stream. And gzip doesn't know the tar data format so it cannot rearrange things for better compression.

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