Here is my problem, I have a set of big gz log files, the very first info in the line is a datetime text, e.g.: 2014-03-20 05:32:00.

I need to check what set of log files holds a specific data. For the init I simply do a:

zgrep -m 1 '^20140320-04' 20140320-0{3,4}*gz

BUT HOW to do the same with the last line without process the whole file as would be done with zcat (too heavy):

zcat foo.gz | tail -1

Additional info, those logs are created with the data time of it's initial record, so if I want to query logs at 14:00:00 I have to search, also, in files created BEFORE 14:00:00, as a file would be created at 13:50:00 and closed at 14:10:00.

  • 5
    Because of the way compression works, it's not possible to read the end of a file without decompressing everything before it.
    – Barmar
    Mar 20, 2014 at 12:36
  • is there a pattern on grep to mach end of file, as it does for end of line $ Mar 20, 2014 at 13:02
  • 1
    The problem is that compressed data is hard to process backwards. Stream compression algorithms like LZW are based on adaptive algorithms, and the reader has to process the compressed data in order to learn the compressions as it goes.
    – Barmar
    Mar 20, 2014 at 20:00
  • 1
    Can you increase the frequency on logrotate (or whatever compresses the log files) so that you have smaller compressed files to search? That'll reduce the overhead of decompressing the file, which is a given.
    – zanerock
    Mar 21, 2014 at 4:44
  • 2
    Thanks, but I don't think it is a sufficiently good answer. In the meantime I would like to direct you to these pages stackoverflow.com/questions/429987/… stackoverflow.com/questions/236414/… lh3.github.io/2014/07/05/random-access-to-zlib-compressed-files Jan 30, 2015 at 14:07

2 Answers 2


The easiest solution would be to alter your log rotation to create smaller files.

The second easiest solution would be to use a compression tool that supports random access.

Projects like dictzip, BGZF, and csio each add sync flush points at various intervals within gzip-compressed data that allow you to seek to in a program aware of that extra information. While it exists in the standard, the vanilla gzip does not add such markers either by default or by option.

Files compressed by these random-access-friendly utilities are slightly larger (by perhaps 2-20%) due to the markers themselves, but fully support decompression with gzip or another utility that is unaware of these markers.

You can learn more at this question about random access in various compression formats.

There's also a "Blasted Bioinformatics" blog by Peter Cock with several posts on this topic, including:

Experiments with xz

xz (an LZMA compression format) actually has random access support on a per-block level, but you will only get a single block with the defaults.

File creation

xz can concatenate multiple archives together, in which case each archive would have its own block. The GNU split can do this easily:

split -b 50M --filter 'xz -c' big.log > big.log.sp.xz

This tells split to break big.log into 50MB chunks (before compression) and run each one through xz -c, which outputs the compressed chunk to standard output. We then collect that standard output into a single file named big.log.sp.xz.

To do this without GNU, you'd need a loop:

split -b 50M big.log big.log-part
for p in big.log-part*; do xz -c $p; done > big.log.sp.xz
rm big.log-part*


You can get the list of block offsets with xz --verbose --list FILE.xz. If you want the last block, you need its compressed size (column 5) plus 36 bytes for overhead (found by comparing the size to hd big.log.sp0.xz |grep 7zXZ). Fetch that block using tail -c and pipe that through xz. Since the above question wants the last line of the file, I then pipe that through tail -n1:

SIZE=$(xz --verbose --list big.log.sp.xz |awk 'END { print $5 + 36 }')
tail -c $SIZE big.log.sp.xz |unxz -c |tail -n1

Side note

Version 5.1.1 introduced support for the --block-size flag:

xz --block-size=50M big.log

However, I have not been able to extract a specific block since it doesn't include full headers between blocks. I suspect this is nontrivial to do from the command line.

Experiments with gzip

gzip also supports concatenation. I (briefly) tried mimicking this process for gzip without any luck. gzip --verbose --list doesn't give enough information and it appears the headers are too variable to find.

This would require adding sync flush points, and since their size varies on the size of the last buffer in the previous compression, that's too hard to do on the command line (use dictzip or another of the previously discussed tools).

I did apt-get install dictzip and played with dictzip, but just a little. It doesn't work without arguments, creating a (massive!) .dz archive that neither dictunzip nor gunzip could understand.

Experiments with bzip2

bzip2 has headers we can find. This is still a bit messy, but it works.


This is just like the xz procedure above:

split -b 50M --filter 'bzip2 -c' big.log > big.log.sp.bz2

I should note that this is considerably slower than xz (48 min for bzip2 vs 17 min for xz vs 1 min for xz -0) as well as considerably larger (97M for bzip2 vs 25M for xz -0 vs 15M for xz), at least for my test log file.


This is a little harder because we don't have the nice index. We have to guess at where to go, and we have to err on the side of scanning too much, but with a massive file, we'd still save I/O.

My guess for this test was 50000000 (out of the original 52428800, a pessimistic guess that isn't pessimistic enough for e.g. an H.264 movie.)

LAST=$(tail -c$GUESS big.log.sp.bz2 \
         |grep -abo 'BZh91AY&SY' |awk -F: 'END { print '$GUESS'-$1 }')
tail -c $LAST big.log.sp.bz2 |bunzip2 -c |tail -n1

This takes just the last 50 million bytes, finds the binary offset of the last BZIP2 header, subtracts that from the guess size, and pulls that many bytes off of the end of the file. Just that part is decompressed and thrown into tail.

Because this has to query the compressed file twice and has an extra scan (the grep call seeking the header, which examines the whole guessed space), this is a suboptimal solution. See also the below section on how slow bzip2 really is.



Given how fast xz is, it's easily the best bet; using its fastest option (xz -0) is quite fast to compress or decompress and creates a smaller file than gzip or bzip2 on the log file I was testing with. Other tests (as well as various sources online) suggest that xz -0 is preferable to bzip2 in all scenarios.

            ————— No Random Access ——————     ——————— Random Access ———————
—————————   —————————————————————————————     —————————————————————————————
(original)  7211M   1.0000       -   0:06     7211M   1.0000       -   0:00
bzip2         96M   0.0133   48:31   3:15       97M   0.0134   47:39   0:00
gzip          79M   0.0109    0:59   0:22                                  
dictzip                                        605M   0.0839    1:36  (fail)
xz -0         25M   0.0034    1:14   0:12       25M   0.0035    1:08   0:00
xz            14M   0.0019   16:32   0:11       14M   0.0020   16:44   0:00

Timing tests were not comprehensive, I did not average anything and disk caching was in use. Still, they look correct; there is a very small amount of overhead from split plus launching 145 compression instances rather than just one (this may even be a net gain if it allows an otherwise non-multithreaded utility to consume multiple threads).

  • 1
    Thanks for the research. I would add that dictzip didn't work in your case because of the awkward "silent" limitation of 1.8 GB (see e.g. linux.die.net/man/1/dictzip). If only one file is to be compressed, simple concatenation of dictzip files (as allowed by the gzip standard) won't work. The only way to deal with the situation seems to be running dictzip -t file.dz (simple header checking): it either immediately fails or immediately succeeds. May 1, 2017 at 19:26

Well, you can access randomly a gzipped file if you previously create an index for each file ...

I've developed a command line tool which creates indexes for gzip files which allow for very quick random access inside them: https://github.com/circulosmeos/gztool

The tool has two options that may be of interest for you:

  • -S option supervise a still-growing file and creates an index for it as it is growing - this can be useful for gzipped rsyslog files as reduces to zero in the practice the time of index creation.
  • -t tails a gzip file: this way you can do: $ gztool -t foo.gz | tail -1 Please, note that if the index doesn't exists, this will consume the same time as a complete decompression: but as the index is reusable, next searches will be greatly reduced in time!

This tool is based on zran.c demonstration code from original zlib, so there's no out-of-the-rules magic!

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