Joshua Levy
2012-11-06 (covers Zinc version 0.3.16)
Kazuyuki Tanimura
Update on 2013-05-14 (covers Zinc version 0.3.27)
Zinc is a simple, versioned store for files. It operates much like a revision control system for source code, but with an emphasis on scalability and simplicity in managing large or numerous data or configuration files.
The key goals are:
-
Revision control for data: The goal is to manage revisions of data files, including support for atomic commits and metadata such as commit history, commit messages, and tags.
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Cloud storage: Direct support for S3 (and potentially any other file storage layer).
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Efficiency and scalability: The ability to manage numerous (millions) and large (multi-gigabyte) files. Support sharding of data to avoid excessive copying.
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Simplicity: A simple implementation and an easy-to-understand internal storage structure for files, so you have a good understanding of how your data is kept safe.
So why would you use Zinc over other existing systems? What are the alternatives?
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Revision control systems (such as Subversion, Mercurial, or Git) give a great set of features for versioning but tend to fail with even moderately large files. They also become unmanageable when there are many files. Distributed systems copy the entire repository to every clone, which is prohibitively expensive if you don't have enough bandwidth.
-
Storage systems (such as S3 with versioning support enabled, or enterprise solutions like JCR) do support versioning and larger files, but they do not support the same versioning features, especially atomic commits of many files in a transaction.
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The closest alternatives are extensions to existing revision control systems to store file contents externally, such as git-annex or Bigfiles. Also Boar has a similar goal. These vary in their features and approach, and may be a better fit for some applications; however, we're not aware of one that has the same emphasis of support for S3, terabyte scale, and some of the additional features below.
Zinc supports both scale and transactionality, making it well suited for managing potentially large sets of data and configuration files. It also does this fairly simply via direct support for S3. Some other nice features:
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For read-only use, you can copy or access any file or set of files directly, without "checking out" a whole repository. This is key for large repositories, to minimize the amount of data downloaded or copied.
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You can access the underlying content directly. For example, you may look up the location of a particular file, then point another piece of software, such as Hadoop, to the underlying compressed blobs in S3. (LZO compression is used for compatibility with Hadoop.)
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Data is broken into "scopes" to better scale to big data problems. With any large data set, it helps to split your data into shards that can be stored or updated independently. Zinc scopes offer a way to do this. Potentially, you can have thousands of scopes, each with thousands of files, operating independently.
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Transactionality is flexible -- and not global. Scopes also delineate transactionality. This means you can easily support commits to different parts of your repository in parallel (without the numerous trivial merge operations common to systems like Git or Mercurial).
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For write use, you need only check out the scope in the repository you are interested in and modify and commit those files. This reduces data copying.
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The internal format is transparent, consisting of simple text files for metadata, and unmodified or LZO compressed blobs for all files. It's also designed in a way that it is robust to interrupted transactions; an interruption or other failure cannot leave the shared repository in a state that will ever confuse another client.
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The full implementation is fairly simple -- just one Python file. Scalability is left to S3 (or any other backing storage layer). Dependencies are minimal: Python, Boto, and lzop.
However, before we get too excited here, there are a number of key limitations:
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Zinc is a small and basic piece of software, without a lot of the comforts of a mature and complex system like Git or Mercurial. Nor does it support any of the more advanced features of a revision control system, like branching or merging. (The reasoning for this is that with large data files, and especially binary ones, you rarely want automated merge support at this layer.)
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Zinc does not support delta compression. Files are compressed individually, not delta compressed, for simplicity and to allow direct access to underlying files from other programs.
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There are a number of other caveats, notably to do with the need for a locking service (see below).
A central repository (on disk or in S3) holds all versions of all files. Versions of some or all of the files can be checked out or directly copied. Items stored are just files and may be of any size (limited only by the backing store, such as S3). They are stored in a global folder hierarchy, just like the filesystem. With a large or distributed filesystem like S3, the set of files could be very large.
Scopes are a way to keep the number of files users deal with routinely to a manageable number and total size, considering that the whole repository may be large. Folders may be specially marked as scopes. Every item has a unique scope, which is the smallest enclosing folder marked as a scope. As with other versioning systems, items are changed via atomic commits that add, remove, or modify files. What is different from other versioning systems is that the files and the transactionality guarantees of a commit are limited to one scope. The reason for this is that with large data sets, it's important to reduce centralized bookkeeping: working in separate scopes reduces synchronization and merging challenges when many files are in the repository. Effectively, Zinc encourages you to partition your data into small pieces that require more limited transactionality, which means fewer merges and less global contention.
Data for any file or folder can be read or copied from the repository directly. To modify data, you must check out a working directory, then modify files, and make a commit.
To use, make sure zinc.py is in your path as zinc
(copy or symlink it
-- it's just one file).
If you plan to use Zinc with S3, you should put your S3 credentials in your
environment variables S3_ACCESS_KEY
and S3_SECRET_KEY
. Alternately, as a
convenience for folks who already use s3cmd, Zinc will by default "borrow" your
access keys from s3cmd's configuration file in ~/.s3cfg
, if it is present and
readable.
Some commands work directly with the repository, with no local state on the filesystem. Others require a working directory.
Below is a quick summary of sample commands and what they do. For illustration,
we'll assume you have a repository in S3 at s3://my-bucket/zinc/my-repo
and that this holds lots of data. In these examples we'll assume data is
sharded by customer, each within paths like customer/acme
.
These are setup commands you'd only run occasionally:
# Create a new repository -- do this only once ever:
zinc init s3://my-bucket/zinc/my-repo
# Create a new scope (log message username is supplied) -- do this for each new scope (customer in this case):
zinc newscope -R s3://my-bucket/zinc/my-repo -u levy customer/acme
Now some routine commands:
# Get help:
zinc -h
# Make our own working copy:
zinc checkout -s customer/acme s3://my-bucket/zinc/my-repo
# (Or, can use --all option to check out all scopes at once, though this may be way too much data, for large repositories.)
cd customer/acme
# (Now add some files to this directory.)
# View what files have changed:
zinc status
# Now commit them; all files will be added:
zinc commit -u levy -s customer/acme -m "Changed some stuff."
# View history:
zinc log -s customer/acme
# Add a tag for this scope, operating directly on repository:
zinc tag -s customer/acme deploy-20110806
# View tags:
zinc tags -s customer/acme
# For this scope, or each scope we have checked out, remember what revision we have:
zinc id
zinc ids
# Update our working copy, in case someone else has made changes:
zinc update -s customer/acme
# Or, update all scopes
zinc update --all
# Update to a particular revision or tag
zinc update -r l9q43b51f2kht -s customer/acme
zinc update -r my-tag -s customer/acme
(Once you're done, if you're curious, you can see the actual internal structure
of the repository within s3://my-bucket/zinc/my-repo
at any time. It's very
simple and holds all version of all the files along with various pieces of
metadata.)
You can also work directly on the repository, without a working directory. This is good for scripts or situations where you only want to examine a few files.
# List recursively (-a) all files within a scope, for current tip:
zinc list -a -R s3://my-bucket/zinc/my-repo -s customer/acme
# Or for a previous revision:
zinc list -a -R s3://my-bucket/zinc/my-repo -s customer/acme -r l9q43b51f2kht
# Tag names work for this too:
zinc list -a -R s3://my-bucket/zinc/my-repo -s customer/acme -r deploy-20110806
# Copy recursively (-a) all files within a scope:
zinc copy -a -R s3://my-bucket/zinc/my-repo -s customer/acme related my-acme/related
# Other commands work directly on the repository too:
zinc tags -R s3://my-bucket/zinc/my-repo -s customer/acme my-acme
zinc log -R s3://my-bucket/zinc/my-repo -s customer/acme my-acme
zinc locate -R s3://my-bucket/zinc/my-repo -s customer/acme related
zinc locate -a -R s3://my-bucket/zinc/my-repo -s customer/acme subdir1
Checking out an entire scope sometimes requires GB order of file transfer in total. The new version of zinc allows partial checkouts
Here, we will have an idea of partial tracking mode v.s. auto tracking mode (i.e. current behavior, all local changes will be picked up). In partial tracking mode, only tracked files will show up in status or be allowed to be committed. Zinc checkout command with "--mode partial" option puts the checked-out scope in partial tracking mode. The default is "--mode auto" We can also switch between these two modes using track/untrack commands. Moreover, we can track/untrack only specific files as well.
# checkout in tracking-mode
zinc checkout -s <scope> s3://my-bucket/zinc/my-repo --mode partial # => nothing will be downloaded
# we can track files after checking out using track command
zinc track -s <scope> dir1/file1 # => This path needs to be relative path(s) from scope dir
# even you add a random file, zinc status does not pick it up
touch scope/test.txt
zinc status -s <scope> # => will not show test.txt
zinc status -s <scope> --full # => the new --full option will show test.txt as an untracked file
# we can untrack files so that zinc update will ignore the files
zinc untrack -s <scope> dir1/file2
# "zinc commit" commits only tracked files and changed files
zinc commit -s <scope> -u <user> -m <message>
# when we track a file that already exists in local file, it preserve the file and your local change is safe.
zinc track -s <scope> dir1/file2 # => zinc assumes that your local change is ahead of repository
zinc status # => this should show that dir1/file2 is modified if it was modified
# we can delete it or rename it
rm scope/dir1/file2
zinc untrack -s <scope> dir1/file2 # => we can also untrack first before deleting it
# --no-download helps deleting files faster
zinc track -s <scope> dir1/file2 --no-download # => it does track file2; however, local copy won't be created (fast!)
zinc status -s <scope> # => status will show that file2 is removed
zinc commit -s <scope> # => commit it so that file2 will be removed from remote repository
# put all local checked out scopes with --work option
zinc track --work <maybe with filenames>
# Let's go back to auto tracking mode
zinc track -s <scope> --mode auto
# Now you see test.txt that we added earlier in the status
zinc status # => it picks up test.txt as a newly added file
# We also support wildcard
zinc untrack -s test_scope "subdir1/*"
zinc track -a -s test_scope "*file*"
- After updating Zinc, Zinc migrates its internal logging file "checkout-state" to a new format. After this migration, older version of Zinc cannot pick up the checked out states/files. Mixed usage of old version and new version of Zinc is prohibited!!
- If there is a local file with the same name as the file you are trying to track, Zinc assumes that the local copy in working directory is the newest. It does not do automatic rebase. The author is responsible to make sure that the change is on top of the current data.
- "Create a new file => track it => remove it" puts the file in an invalid state. Currently we can catch it only when we commit it (zinc status gives you a warning). The remote repo is safe and we leave this behavior for now.
Unfortunately, the program is really simple right now and has a lot of limitations, including:
-
There are no commands to explicitly add or remove files from within the working directory (like
git add
orgit rm
). All files are added or removed exactly as they appear, so use caution and checkzinc status
before committing. -
Merging of changes to the same file is not supported. If someone commits to the same scope as you and to the same file, between your last update and your current commit, you have to save your work somewhere, revert, merge manually yourself, and commit again.
-
There is a file cache at the top of any working directory, in
.zinc/cache
. This can grow large over time, and can be deleted withrm -rf .zinc/cache
at any time. Or use--no-cache
to avoid caching altogether. -
Simultaneous commits by different clients to different scopes is always handled correctly. And commits themselves are always transactional, so either succeed or fail in entirety. However, resolving conflicts between simultaneous commits to the same scope requires some sort of global locking service (see code). By default this is not enabled. What this means is that if two users commit to the same scope at once, and no locking service is used, one user's commit may be lost without an error.
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There is no support for deleting tags or removing or rolling back commits in the repository. (But you can always just make a new commit.)
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The working directory is not designed to be used by many clients at once (it does not use file locks). For multiple clients, use multiple working directories.
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It is worth being aware that S3's consistency model occasionally causes issues in rare situations where an one object may not appear for minutes or hours from some locations. This is most common in S3's Standard Region. These may cause an exception and abort during an update, but should never result in corrupt data being checked out.
For more details, see the long list of TODOs the end of zinc.py.
-
See
tests.sh
for example commands. -
Read pydocs on the Repo class in
zinc.py
for documentation on the internal repository format.