travis: test more go versions
|6 years ago|
|archive/tar||6 years ago|
|cmd/tar-split||6 years ago|
|concept||7 years ago|
|tar||6 years ago|
|version||6 years ago|
|.travis.yml||6 years ago|
|LICENSE||7 years ago|
|README.md||6 years ago|
|tar_benchmark_test.go||6 years ago|
Pristinely disassembling a tar archive, and stashing needed raw bytes and offsets to reassemble a validating original archive.
Code API for libraries provided by
The command line utilitiy is installable via:
go get github.com/vbatts/tar-split/cmd/tar-split
Basic disassembly and assembly
This demonstrates the
tar-split command and how to assemble a tar archive from the
Docker layer preservation
This demonstrates the tar-split integration for docker-1.8. Providing consistent tar archives for the image layer content.
Eventually this should detect TARs that this is not possible with.
For example stored sparse files that have "holes" in them, will be read as a contiguous file, though the archive contents may be recorded in sparse format. Therefore when adding the file payload to a reassembled tar, to achieve identical output, the file payload would need be precisely re-sparsified. This is not something I seek to fix imediately, but would rather have an alert that precise reassembly is not possible. (see more http://www.gnu.org/software/tar/manual/html_node/Sparse-Formats.html)
Other caveat, while tar archives support having multiple file entries for the
same path, we will not support this feature. If there are more than one entries
with the same path, expect an err (like
ErrDuplicatePath) or a resulting tar
stream that does not validate your original checksum/signature.
Do not break the API of stdlib
archive/tar in our fork (ideally find an upstream mergeable solution).
The version of golang stdlib
archive/tar is from go1.6
It is minimally extended to expose the raw bytes of the TAR, rather than just the marshalled headers and file stream.
See the design.
Since the raw bytes of the headers and padding are stored, you may be wondering what the size implications are. The headers are at least 512 bytes per file (sometimes more), at least 1024 null bytes on the end, and then various padding. This makes for a constant linear growth in the stored metadata, with a naive storage implementation.
First we'll get an archive to work with. For repeatability, we'll make an archive from what you've just cloned:
git archive --format=tar -o tar-split.tar HEAD .
$ go get github.com/vbatts/tar-split/cmd/tar-split $ tar-split checksize ./tar-split.tar inspecting "tar-split.tar" (size 210k) -- number of files: 50 -- size of metadata uncompressed: 53k -- size of gzip compressed metadata: 3k
So assuming you've managed the extraction of the archive yourself, for reuse of the file payloads from a relative path, then the only additional storage implications are as little as 3kb.
But let's look at a larger archive, with many files.
$ ls -sh ./d.tar 1.4G ./d.tar $ tar-split checksize ~/d.tar inspecting "/home/vbatts/d.tar" (size 1420749k) -- number of files: 38718 -- size of metadata uncompressed: 43261k -- size of gzip compressed metadata: 2251k
Here, an archive with 38,718 files has a compressed footprint of about 2mb.
Rolling the null bytes on the end of the archive, we will assume a bytes-per-file rate for the storage implications.
|~ 1kb per/file||0.06kb per/file|
- More implementations of storage Packer and Unpacker
- More implementations of FileGetter and FilePutter
- would be interesting to have an assembler stream that implements