I got a sparse file of 1TB which stores actually 32MB data on Linux.

Is it possible to "efficiently" make a package to store the sparse file? The package should be unpacked to be a 1TB sparse file on another computer. Ideally, the "package" should be around 32MB.

Note: On possible solution is to use 'tar': https://wiki.archlinux.org/index.php/Sparse_file#Archiving_with_.60tar.27

However, for a 1TB sparse file, although the tar ball may be small, archiving the sparse file will take too long a time.

Edit 1

I tested the tar and gzip and the results are as follows (Note that this sparse file contains data of 0 byte).

$ du -hs sparse-1
0   sparse-1

$ ls -lha sparse-1
-rw-rw-r-- 1 user1 user1 1.0T 2012-11-03 11:17 sparse-1

$ time tar cSf sparse-1.tar sparse-1

real    96m19.847s
user    22m3.314s
sys     52m32.272s

$ time gzip sparse-1

real    200m18.714s
user    164m33.835s
sys     10m39.971s

$ ls -lha sparse-1*
-rw-rw-r-- 1 user1 user1 1018M 2012-11-03 11:17 sparse-1.gz
-rw-rw-r-- 1 user1 user1   10K 2012-11-06 23:13 sparse-1.tar

The 1TB file sparse-1 which contains 0 byte data can be archived by 'tar' to a 10KB tar ball or compressed by gzip to a ~1GB file. gzip takes around 2 times of the time than the time tar uses.

From the comparison, 'tar' seems better than gzip.

However, 96 minutes are too long for a sparse file that contains data of 0 byte.

Edit 2

rsync seems finish copying the file in more time than tar but less than gzip:

$ time rsync --sparse sparse-1 sparse-1-copy

real    124m46.321s
user    107m15.084s
sys     83m8.323s

$ du -hs sparse-1-copy 
4.0K    sparse-1-copy

Hence, tar + cp or scp should be faster than directly rsync for this extremely sparse file.

Edit 3

Thanks to @mvp for pointing out the SEEK_HOLE functionality in newer kernel. (I previously work on a 2.6.32 Linux kernel).

Note: bsdtar version >=3.0.4 is required (check here: http://ask.fclose.com/4/how-to-efficiently-archive-a-very-large-sparse-file?show=299#c299 ).

On a newer kernel and Fedora release (17), tar and cp handles the sparse file very efficiently.

[zma@office tmp]$ ls -lh pmem-1 

-rw-rw-r-- 1 zma zma 1.0T Nov  7 20:14 pmem-1
[zma@office tmp]$ time tar cSf pmem-1.tar pmem-1

real    0m0.003s
user    0m0.003s
sys 0m0.000s
[zma@office tmp]$ time cp pmem-1 pmem-1-copy

real    0m0.020s
user    0m0.000s
sys 0m0.003s
[zma@office tmp]$ ls -lh pmem*
-rw-rw-r-- 1 zma zma 1.0T Nov  7 20:14 pmem-1
-rw-rw-r-- 1 zma zma 1.0T Nov  7 20:15 pmem-1-copy
-rw-rw-r-- 1 zma zma  10K Nov  7 20:15 pmem-1.tar
[zma@office tmp]$ mkdir t
[zma@office tmp]$ cd t
[zma@office t]$ time tar xSf ../pmem-1.tar 

real    0m0.003s
user    0m0.000s
sys 0m0.002s
[zma@office t]$ ls -lha
total 8.0K
drwxrwxr-x   2 zma  zma  4.0K Nov  7 20:16 .
drwxrwxrwt. 35 root root 4.0K Nov  7 20:16 ..
-rw-rw-r--   1 zma  zma  1.0T Nov  7 20:14 pmem-1

I am using a 3.6.5 kernel:

[zma@office t]$ uname -a
Linux office.zhiqiangma.com 3.6.5-1.fc17.x86_64 #1 SMP Wed Oct 31 19:37:18 UTC 2012 x86_64 x86_64 x86_64 GNU/Linux
  • gzip or bzip2 should do a beautiful job compressing it. pigz and pbzip2 are their respective modern equivalents that utilize all the cores. You'll be pleasantly surprised how quickly they run.
    – Marcin
    Nov 6, 2012 at 14:13
  • 1
    @Marcin compression by gzip seems worse than tar. Please find the updated question with the results of gzip and tar.
    – ericzma
    Nov 7, 2012 at 8:34
  • When you say "a sparse file of 0 byte" do you mean every byte is 0? That's a different question. Nov 7, 2012 at 8:43
  • @MatthewStrawbridge I meant that the sparse file contains data of 0 byte (no data).
    – ericzma
    Nov 7, 2012 at 8:46
  • 1
    gzip performs ridiculously poorly for data that has long strings of repeated characters. LZMA is not much better. long stretches of 0's 1's or anything else get spectacularly compressed by bzip. I had a 1.8GB file with mostly (90%) zeros and the rest random integers. it got compressed to around 800kB. the speed sucks though.
    – staticd
    Oct 7, 2013 at 7:27

4 Answers 4


Short answer: Use bsdtar or GNU tar (version 1.29 or later) to create archives, and GNU tar (version 1.26 or later) to extract them on another box.

Long answer: There are some requirements for this to work.

First, Linux must be at least kernel 3.1 (Ubuntu 12.04 or later would do), so it supports SEEK_HOLE functionality.

Then, you need tar utility that can support this syscall. GNU tar supports it since version 1.29 (released on 2016/05/16, it should be present by default since Ubuntu 18.04), or bsdtar since version 3.0.4 (available since Ubuntu 12.04) - install it using sudo apt-get install bsdtar.

While bsdtar (which uses libarchive) is awesome, unfortunately, it is not very smart when it comes to untarring - it stupidly requires to have at least as much free space on target drive as untarred file size, without regard to holes. GNU tar will untar such sparse archives efficiently and will not check this condition.

This is log from Ubuntu 12.10 (Linux kernel 3.5):

$ dd if=/dev/zero of=1tb seek=1T bs=1 count=1
1+0 records in
1+0 records out
1 byte (1 B) copied, 0.000143113 s, 7.0 kB/s

$ time bsdtar cvfz sparse.tar.gz 1tb 
a 1tb

real    0m0.362s
user    0m0.336s
sys 0m0.020s

# Or, use gnu tar if version is later than 1.29:
$ time tar cSvfz sparse-gnutar.tar.gz 1tb

real    0m0.005s
user    0m0.006s
sys 0m0.000s

$ ls -l
-rw-rw-r-- 1 autouser autouser 1099511627777 Nov  7 01:43 1tb
-rw-rw-r-- 1 autouser autouser           257 Nov  7 01:43 sparse.tar.gz
-rw-rw-r-- 1 autouser autouser           134 Nov  7 01:43 sparse-gnutar.tar.gz

Like I said above, unfortunately, untarring with bsdtar will not work unless you have 1TB free space. However, any version of GNU tar works just fine to untar such sparse.tar:

$ rm 1tb 
$ time tar -xvSf sparse.tar.gz 

real    0m0.031s
user    0m0.016s
sys 0m0.016s
$ ls -l
total 8
-rw-rw-r-- 1 autouser autouser 1099511627777 Nov  7 01:43 1tb
-rw-rw-r-- 1 autouser autouser           257 Nov  7 01:43 sparse.tar.gz
  • 2
    Awesome! I guess the SEEK_HOLE plays the trick! I tried the tar and cp on a 3.6.5 Linux kernel and both are very fast. Thanks!
    – ericzma
    Nov 7, 2012 at 12:22
  • Is the requirement of Linux kernel 3.1 or later the case even if using a later version of libarchive? It looks like there's code which makes use of FIEMAP ioctl in versions 3.x of libarchive. github.com/libarchive/libarchive/blob/master/libarchive/…
    – bockmabe
    Oct 21, 2013 at 21:54
  • 2
    Sadly, 1.5 years since I wrote this, GNU tar still has not learned to parse holes effectively, so this recipe is still very much relevant! :(...
    – mvp
    May 22, 2014 at 8:44
  • I tried this with a 1MB empty sparse file and found that bsdtar handled this like a non-sparse file. For a 2tb sparse file with something in between it worked like as described above. Maybe it only works for very large files?
    – Alfe
    Sep 8, 2017 at 12:05
  • 1
    Finally, GNU tar supports this properly since version 1.29 ;-)
    – mvp
    Sep 19, 2019 at 0:59

I realize this question is very old, but here's an update that may be helpful to others who find their way here the same way I did.

Thankfully, mvp's excellent answer is now obsolete. According to the GNU tar release notes, SEEK_HOLE/SEEK_DATA was added in v. 1.29, released 2016-05-16. (And with GNU tar v. 1.30 being standard in Debian stable now, it's safe to assume that tar version ≥ 1.29 is available almost everywhere.)

So the way to handle sparse files now is to archive them with whichever tar (GNU or BSD) is installed on your system, and same for extracting.

Additionally, for sparse files that actually contain some data, if it's worthwhile to use compression (ie the data is compressible enough to save substantial disk space, and the disk space savings are worth the likely-substantial time and CPU resources required to compress it):

  • tar -cSjf <archive>.tar.bz2 /path/to/sparse/file will both take advantage of tar's SEEK_HOLE functionality to quickly & efficiently archive the sparse file, and use bzip2 to compress the actual data.
  • tar --use-compress-program=pbzip2 -cSf <archive>.tar.bz2 /path/to/sparse/file, as alluded to in marcin's comment, will do the same while also using multiple cores for the compression task.

On my little home server with a quad-core Atom CPU, using pbzip2 vs bzip2 reduced the time by around 25 or 30%.

With or without compression, this will give you an archive that doesn't need any special sparse-file handling, takes up approximately the 'real' size of the original sparse file (or less if compressed), and can be moved around without worrying about inconsistency between different utilities' sparse file capabilities. For example: cp will automatically detect sparse files and do the right thing, rsync will handle sparse files properly if you use the -S flag, and scp has no option for sparse files (it will consume bandwidth copying zeros for all the holes and the resulting copy will be a non-sparse file whose size is the 'apparent' size of the original); but all of them will of course handle a tar archive just fine—whether it contains sparse files or not—without any special flags.

Additional Notes

  1. When extracting, tar will automatically detect an archive created with -S so there's no need to specify it.
  2. An archive created with pbzip2 is stored in chunks. This results in the archive being marginally bigger than if bzip2 is used, but also means that the extraction can be multithreaded, unlike an archive created with bzip2.
  3. pbzip2 and bzip2 will reliably extract each other's archives without error or corruption.
  • Thanks for notifying regarding tar 1.29 - this is great news! Btw, modern cp utility is automatically taking advantage of this and copying sparse files efficiently.
    – mvp
    Sep 19, 2019 at 1:01
  • Good point, @mvp I have edited my answer to clarify that part.
    – Askeli
    Sep 20, 2019 at 11:34
  • Wonderful answer! Especially the last paragraph regarding cp and scp and alluding to how to efficiently move large images from remote locations, etc. Great points, and adjusting backup scripts now!
    – oemb1905
    Nov 3, 2021 at 16:47

From a related question, maybe rsync will work:

rsync --sparse sparse-1 sparse-1-copy
  • I tried this and after several minutes I killed it since it seems very busy there (two rsync processes that took ~89% and ~62% CPU). I do not expect that rsync works better than tar for this purpose. But I am giving it another try since the server is idle currently.
    – ericzma
    Nov 7, 2012 at 9:00
  • rsync seems finish copying the file in more time than tar but less than gzip. The results are in Edit 2 of the question.
    – ericzma
    Nov 7, 2012 at 11:58
  • 1
    rsync is not a fast or efficient program for copying files disk-to-disk, but it does have a lot of options you may not find elsewhere. You can use rsync -S ... to copy sparse files over a LAN, e.g over ssh. For copy disk-to-disk, just use cp --sparse=<option>, for maximum sparse, use the option always Nov 12, 2020 at 14:58
  • 1
    @James: Thanks! It is amazing how these utilities have evolved.
    – wallyk
    Nov 12, 2020 at 18:08

You're definitely looking for a compression tool such as tar, lzma, bzip2, zip or rar. According to this site, lzma is quite fast while still having quite a good compression ratio:


You can also adjust the speed/quality ratio of the compression by setting the compression level to something low, experiment a bit to find a level that works best


  • Compression by gzip seems worse than simply archiving the file using tar. Please find the updated question with the results of gzip and tar. Archiving seems still too slow for handling a file that contains 0 byte.
    – ericzma
    Nov 7, 2012 at 8:35
  • Bzip has the slowest decompression speed among gz and LZMA for all compression ratios
    – staticd
    Oct 7, 2013 at 7:22
  • Thanks @staticd, I misread the graph. I removed that recommendation from my answer.
    – LukeGT
    Feb 18, 2017 at 3:05

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