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This is similar to a previous question, but the answers there don't satisfy my needs and my question is slightly different:

I currently use gzip compression for some very large files which contain sorted data. When the files are not compressed, binary search is a handy and efficient way to support seeking to a location in the sorted data.

But when the files are compressed, things get tricky. I recently found out about zlib's Z_FULL_FLUSH option, which can be used during compression to insert "sync points" in the compressed output (inflateSync() can then begin reading from various points in the file). This is OK, though files I already have would have to be recompressed to add this feature (and strangely gzip doesn't have an option for this, but I'm willing to write my own compression program if I must).

It seems from one source that even Z_FULL_FLUSH is not a perfect solution...not only is it not supported by all gzip archives, but the very idea of detecting sync points in archives may produce false positives (either by coincidence with the magic number for sync points, or due to the fact that Z_SYNC_FLUSH also produces sync points but they are not usable for random access).

Is there a better solution? I'd like to avoid having auxiliary files for indexing if possible, and explicit, default support for quasi-random access would be helpful (even if it's large-grained--like being able to start reading at each 10 MB interval). Is there another compression format with better support for random reads than gzip?

Edit: As I mentioned, I wish to do binary search in the compressed data. I don't need to seek to a specific (uncompressed) position--only to seek with some coarse granularity within the compressed file. I just want support for something like "Decompress the data starting roughly 50% (25%, 12.5%, etc.) of the way into this compressed file."

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11 Answers 11

up vote 13 down vote accepted

I don't know of any compressed file format which would support random access to a specific location in the uncompressed data (well, except for multimedia formats), but you can brew your own.

For example, bzip2 compressed files are composed of independent compressed blocks of size <1MB uncompressed, which are delimited by sequences of magic bytes, so you could parse the bzip2 file, get the block boundaries and then just uncompress the right block. This would need some indexing to remember where do the blocks start.

Still, I think the best solution would be to split your file into chunks of your choice, and then compressing it with some archiver, like zip or rar, which support random access to individual files in the archive.

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I don't need to seek to a specific uncompressed position--only to seek somewhat randomly with some coarse granularity within the compressed file. I don't mind at all if all I can do is say "uncompess the data starting here, about 700MB into this file." – John Zwinck Jan 9 '09 at 23:53
@John Zwinck: Add your comment to your question as an update. Note that given the variable compression of data (some stuff I compress shrinks by 94% or so - usually, except when it only shrinks by about 50% or so), your estimate of where to start decompressing might be very hit and miss. – Jonathan Leffler Jan 10 '09 at 6:54
Just a note that is complicated by bzip2 block boundaries being within a byte, so it is doable, but there is more bookkeeping required. – Alex Reynolds Jan 29 at 21:23

Take a look at dictzip. It is compatible with gzip and allows coarse random access.

An excerpt from its man page:

dictzip compresses files using the gzip(1) algorithm (LZ77) in a manner which is completely compatible with the gzip file format. An extension to the gzip file format (Extra Field, described in of RFC 1952) allows extra data to be stored in the header of a compressed file. Programs like gzip and zcat will ignore this extra data. However, [dictzcat --start] will make use of this data to perform pseudo-random access on the file.

I have the package dictzip in Ubuntu. Or its source code is in a dictd-*.tar.gz. Its license is GPL. You are free to study it.


I improved dictzip to have no file size limit. My implementation is under MIT license.

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I solved my problem through the use of gzip sync/flush points, which allow me to scan through the file (doing binary search) just fine. I had to write my own gzip-like program on top of libz, because the standard gzip for whatever reason doesn't include a facility to write sync points. Anyway, this works great in my case, because I do not care about being able to "read starting at byte 10000", only to "read starting about 50% of the way through the file." The dictzip approach does look very interesting, and solves a perhaps more general problem than mine. – John Zwinck Nov 6 '10 at 16:52
Do I understand correctly that you've used GPL licenced source code as a base for yours MIT licenced program? Its violation of GPL licence! – Jacek Kaniuk Apr 15 '14 at 12:12
@JacekKaniuk Sorry for confusing you. The dictzip file format specification was used and reimplemented from scratch in Python. – Ivo Danihelka Apr 16 '14 at 12:35
@JohnZwinck You mentioned "false positives" being a potential problem. Did you solve that? I assume your solution was in c? Sounds like I need exactly the same functionality, any tips or code would be appreciated. – TJez Sep 5 '14 at 13:08
@TroyJ: if you control the writing of the files, false positives are not going to happen often, and when they do you may know it because decompression from those points will fail (and you can try again). If you do not control the writing, things are trickier: standard gzip-writing programs will emit lots of false positives and no true positives. You could retry N times before giving up; in my experience N will only need to be a small number (less than 10) for the system to be reasonably accurate. – John Zwinck Sep 5 '14 at 15:00

Solutions exist for providing random access to gzip and bzip2 archives:

(I'm looking for something for 7zip)

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I read the zran code with interest, especially considering it was written by Mark Adler. But it appears to be a convenience mechanism only: the comments say it first reads the entire file and builds an index which is later used to perform random access. This is probably great for GhostScript, where I imagine the input files are on the order of megabytes. But my input files are on the order of gigabytes, so reading them entirely before doing random access is not so great. Worse, my most common use case happens to be a single random access per opened file. – John Zwinck Dec 18 '10 at 16:11
Yes there's definitely associated costs. It's most effective when you want to use the same archive many times over a long period of time. – hippietrail Oct 1 '13 at 16:45

I'm not sure if this would be practical in your exact situation, but couldn't you just gzip each large file into smaller files, say 10 MB each? You would end up with a bunch of files: file0.gz, file1.gz, file2.gz, etc. Based on a given offset within the original large, you could search in the file named "file" + (offset / 10485760) + ".gz". The offset within the uncompressed archive would be offset % 10485760.

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Or you could TAR them all and end up with a .GZ.TAR. :) – Vilx- Jan 9 '09 at 22:48
That would definitely make things cleaner. I was just trying to go for simplicity here, but your suggestion is well taken :-) – William Brendel Jan 9 '09 at 22:49
.gz.tar is not really random access, since you must jump through all the headers to get to one file – jpalecek Jan 9 '09 at 23:03
Well, yes and no. With fixed size chunks (10 MB in this case), you would not have to walk through a list of headers. This relies on the assumption that the tar will order the files alphabetically (which happens to be the case in GNU-land). – William Brendel Jan 9 '09 at 23:13
Yes, but the files would not be compressed then (10 MB uncompressed for your indexing expression to work, 10 MB compressed for direct access in tar to work). It's hard to compress anything to a fixed size, although you could make that size sufficiently large and handle excess space with sparse files – jpalecek Jan 9 '09 at 23:30

The .xz file format (which uses LZMA compression) seems to support this:

Random-access reading: The data can be split into independently compressed blocks. Every .xz file contains an index of the blocks, which makes limited random-access reading possible when the block size is small enough.

This should be sufficient for your purpose. A drawback is that the API of liblzma (for interacting with these containers) does not seem that well-documented, so it may take some effort figuring out how to randomly access blocks.

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Because lossless compression works better on some areas than others, if you store compressed data into blocks of convenient length BLOCKSIZE, even though each block has exactly the same number of compressed bytes, some compressed blocks will expand to a much longer piece of plaintext than others.

You might look at "Compression: A Key for Next-Generation Text Retrieval Systems" by Nivio Ziviani, Edleno Silva de Moura, Gonzalo Navarro, and Ricardo Baeza-Yates in Computer magazine November 2000

Their decompressor takes 1, 2, or 3 whole bytes of compressed data and decompresses (using a vocabulary list) into a whole word. One can directly search the compressed text for words or phrases, which turns out to be even faster than searching uncompressed text.

Their decompressor lets you point to any word in the text with a normal (byte) pointer and start decompressing immediately from that point.

You can give every word a unique 2 byte code, since you probably have less than 65,000 unique words in your text. (There are almost 13,000 unique words in the KJV Bible). Even if there are more than 65,000 words, it's pretty simple to assign the first 256 two-byte code "words" to all possible bytes, so you can spell out words that aren't in the lexicon of the 65,000 or so "most frequent words and phrases". (The compression gained by packing frequent words and phrases into two bytes is usually worth the "expansion" of occasionally spelling out a word using two bytes per letter). There are a variety of ways to pick a lexicon of "frequent words and phrases" that will give adequate compression. For example, you could tweak a LZW compressor to dump "phrases" it uses more than once to a lexicon file, one line per phrase, and run it over all your data. Or you could arbitrarily chop up your uncompressed data into 5 byte phrases in a lexicon file, one line per phrase. Or you could chop up your uncompressed data into actual English words, and put each word -- including the space at the beginning of the word -- into the lexicon file. Then use "sort --unique" to eliminate duplicate words in that lexicon file. (Is picking the perfect "optimum" lexicon wordlist still considered NP-hard?)

Store the lexicon at the beginning of your huge compressed file, pad it out to some convenient BLOCKSIZE, and then store the compressed text -- a series of two byte "words" -- from there to the end of the file. Presumably the searcher will read this lexicon once and keep it in some quick-to-decode format in RAM during decompression, to speed up decompressing "two byte code" to "variable-length phrase". My first draft would start with a simple one line per phrase list, but you might later switch to storing the lexicon in a more compressed form using some sort of incremental coding or zlib.

You can pick any random even byte offset into the compressed text, and start decompressing from there. I don't think it's possible to make a finer-grained random access compressed file format.

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Two possible solutions:

  1. Let the OS deal with compression, create and mount a compressed file system (SquashFS, clicfs, cloop, cramfs, e2compr or whatever) containing all your text files and don't do anything about compression in your application program.

  2. Use clicfs directly on each text file (one clicfs per text file) instead of compressing a filesystem image. Think of "mkclicfs mytextfile mycompressedfile" being "gzip <mytextfile >mycompressedfile" and "clicfs mycompressedfile directory" as a way of getting random access to the data via the file "directory/mytextfile".

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Wow, interesting thoughts on an old question of mine. Your first suggestion (squashfs) is not entirely what I would want, because it has implications for remote storage: using a compressed filesystem and compressed SSH connections, you would manage to decompress the data and recompress it to send it over the network. What would be amazing would be something like a compressed filesystem that you could share via NFS. Which I guess is what your clicfs suggestion might yield. Documentation on clicfs seems quite hard to come by (at least by my quick search), but it's promising. Thank you. – John Zwinck Feb 11 '12 at 0:21

This is a very old question but it looks like zindex could provide a good solution (although I don't have much experience with it)

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razip supports random access with better performance than gzip/bzip2 which have to be tweaked for this support - reducing compression at the expense of "ok" random access:

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Have you used it? It looks like dead project from what I can see. – John Zwinck Aug 24 '11 at 2:07
I use it for bioinformatics stuff. Works fine so far. – Erik Aronesty Sep 6 '11 at 17:50

I dont know if its been mentioned yet, but the Kiwix project had done great work in this regard. Through their program Kiwix, they offer random access to ZIM file archives. Good compression, too. The project originated when there was a demand for offline copies of the Wikipedia (which has reached above 100 GB in uncompressed form, with all media included). They have successfully taken a 25 GB file (a single-file embodiment of the wikipedia without most of the media) and compressed it to a measly 8 GB zim file archive. And through the Kiwix program, you can call up any page of the Wikipedia, with all associated data, faster than you can surfing the net.

Even though Kiwix program is a technology based around the wikipedia database structure, it proves that you can have excellent compression ratios and random access simultaneously.

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I am the author of an open-source tool for compressing a particular type of biological data. This tool, called starch, splits the data by chromosome and uses those divisions as indices for fast access to compressed data units within the larger archive.

Per-chromosome data are transformed to remove redundancy in genomic coordinates, and the transformed data are compressed with either bzip2 or gzip algorithms. The offsets, metadata and compressed genomic data are concatenated into one file.

Source code is available from our GitHub site. We have compiled it under Linux and Mac OS X.

For your case, you could store (10 MB, or whatever) offsets in a header to a custom archive format. You parse the header, retrieve the offsets, and incrementally fseek through the file by current_offset_sum + header_size.

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Link is broken. – tommy.carstensen Jan 29 at 21:03
Updated link to Github site. – Alex Reynolds Jan 29 at 21:04
"BEDOPS also introduces a novel and lossless compression format called Starch that reduces whole-genome BED datasets to ~5% of their original size (and BAM datasets to roughly 35% of their original size)" <-- This is amazing. You should advertise your tool. – tommy.carstensen Jan 29 at 21:14
Samtools faidx doesn't compress near as well as Starch, and it requires keeping a second file with the genomic data, but it offers finer indexing and so is more popular. Starch works really well if you need to squeeze out space or you're doing whole-genome work and want to parallelize tasks by chromosome. I'm working on "Starch 2", which will offer base-level interval queries, but that may be a few months out. – Alex Reynolds Jan 29 at 21:20

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