This text is a work in progress—highly subject to change—and may not accurately describe any released version of the Apache™ Subversion® software. Bookmarking or otherwise referring others to this page is probably not such a smart idea. Please visit http://www.svnbook.com/ for stable versions of this book.
Subversion's copy-modify-merge version control model lives and dies on its data merging algorithms—specifically on how well those algorithms perform when trying to resolve conflicts caused by multiple users modifying the same file concurrently. Subversion itself provides only one such algorithm: a three-way differencing algorithm that is smart enough to handle data at a granularity of a single line of text. Subversion also allows you to supplement its content merge processing with external differencing utilities (as described in the section called “External diff3” and the section called “External merge”), some of which may do an even better job, perhaps providing granularity of a word or a single character of text. But common among those algorithms is that they generally work only on text files. The landscape starts to look pretty grim when you start talking about content merges of nontextual file formats. And when you can't find a tool that can handle that type of merging, you begin to run into problems with the copy-modify-merge model.
Let's look at a real-life example of where this model runs aground. Harry and Sally are both graphic designers working on the same project, a bit of marketing collateral for an automobile mechanic. Central to the design of a particular poster is an image of a car in need of some bodywork, stored in a file using the PNG image format. The poster's layout is almost finished, and both Harry and Sally are pleased with the particular photo they chose for their damaged car—a baby blue 1967 Ford Mustang with an unfortunate bit of crumpling on the left front fender.
Now, as is common in graphic design work, there's a change
in plans, which causes the car's color to be a concern. So Sally
updates her working copy to HEAD
, fires up
her photo-editing software, and sets about tweaking the image so
that the car is now cherry red. Meanwhile, Harry, feeling
particularly inspired that day, decides that the image would
have greater impact if the car also appears to have suffered
greater impact. He, too, updates to HEAD
,
and then draws some cracks on the vehicle's windshield. He
manages to finish his work before Sally finishes hers, and after
admiring the fruits of his undeniable talent, he commits the
modified image. Shortly thereafter, Sally is finished with the
car's new finish and tries to commit her changes. But, as
expected, Subversion fails the commit, informing Sally that
her version of the image is now out of date.
Here's where the difficulty sets in. If Harry and Sally were making changes to a text file, Sally would simply update her working copy, receiving Harry's changes in the process. In the worst possible case, they would have modified the same region of the file, and Sally would have to work out by hand the proper resolution to the conflict. But these aren't text files—they are binary images. And while it's a simple matter to describe what one would expect the results of this content merge to be, there is precious little chance that any software exists that is smart enough to examine the common baseline image that each of these graphic artists worked against, the changes that Harry made, and the changes that Sally made, and then spit out an image of a busted-up red Mustang with a cracked windshield!
Of course, things would have gone more smoothly if Harry and Sally had serialized their modifications to the image—if, say, Harry had waited to draw his windshield cracks on Sally's now-red car, or if Sally had tweaked the color of a car whose windshield was already cracked. As is discussed in the section called “Giải pháp sao chép-sửa đổi-hợp nhất”, most of these types of problems go away entirely where perfect communication between Harry and Sally exists.[27] But as one's version control system is, in fact, one form of communication, it follows that having that software facilitate the serialization of nonparallelizable editing efforts is no bad thing. This is where Subversion's implementation of the lock-modify-unlock model steps into the spotlight. This is where we talk about Subversion's locking feature, which is similar to the “reserved checkouts” mechanisms of other version control systems.
Subversion's locking feature exists ultimately to minimize wasted time and effort. By allowing a user to programmatically claim the exclusive right to change a file in the repository, that user can be reasonably confident that any energy he invests on unmergeable changes won't be wasted—his commit of those changes will succeed. Also, because Subversion communicates to other users that serialization is in effect for a particular versioned object, those users can reasonably expect that the object is about to be changed by someone else. They, too, can then avoid wasting their time and energy on unmergeable changes that won't be committable due to eventual out-of-dateness.
When referring to Subversion's locking feature, one is actually talking about a fairly diverse collection of behaviors, which include the ability to lock a versioned file[28] (claiming the exclusive right to modify the file), to unlock that file (yielding that exclusive right to modify), to see reports about which files are locked and by whom, to annotate files for which locking before editing is strongly advised, and so on. In this section, we'll cover all of these facets of the larger locking feature.
In the Subversion repository, a lock is a piece of metadata that grants exclusive access to one user to change a file. This user is said to be the lock owner. Each lock also has a unique identifier, typically a long string of characters, known as the lock token. The repository manages locks, ultimately handling their creation, enforcement, and removal. If any commit transaction attempts to modify or delete a locked file (or delete one of the parent directories of the file), the repository will demand two pieces of information—that the client performing the commit be authenticated as the lock owner, and that the lock token has been provided as part of the commit process as a form of proof that the client knows which lock it is using.
To demonstrate lock creation, let's refer back to our example of multiple graphic designers working on the same binary image files. Harry has decided to change a JPEG image. To prevent other people from committing changes to the file while he is modifying it (as well as alerting them that he is about to change it), he locks the file in the repository using the svn lock command.
$ svn lock banana.jpg -m "Editing file for tomorrow's release." 'banana.jpg' locked by user 'harry'. $
The preceding example demonstrates a number of new things.
First, notice that Harry passed the
--message
(-m
) option to
svn lock. Similar to svn
commit, the svn lock command can
take comments—via either --message
(-m
) or --file
(-F
)—to describe the reason for locking the
file. Unlike svn commit, however,
svn lock will not demand a message by
launching your preferred text editor. Lock comments are
optional, but still recommended to aid communication.
Second, the lock attempt succeeded. This means that the file wasn't already locked, and that Harry had the latest version of the file. If Harry's working copy of the file had been out of date, the repository would have rejected the request, forcing Harry to svn update and reattempt the locking command. The locking command would also have failed if the file had already been locked by someone else.
As you can see, the svn lock command prints confirmation of the successful lock. At this point, the fact that the file is locked becomes apparent in the output of the svn status and svn info reporting subcommands.
$ svn status K banana.jpg $ svn info banana.jpg Path: banana.jpg Name: banana.jpg Working Copy Root Path: /home/harry/project URL: http://svn.example.com/repos/project/banana.jpg Relative URL: ^/banana.jpg Repository Root: http://svn.example.com/repos/project Repository UUID: edb2f264-5ef2-0310-a47a-87b0ce17a8ec Revision: 2198 Node Kind: file Schedule: normal Last Changed Author: frank Last Changed Rev: 1950 Last Changed Date: 2006-03-15 12:43:04 -0600 (Wed, 15 Mar 2006) Text Last Updated: 2006-06-08 19:23:07 -0500 (Thu, 08 Jun 2006) Properties Last Updated: 2006-06-08 19:23:07 -0500 (Thu, 08 Jun 2006) Checksum: 3b110d3b10638f5d1f4fe0f436a5a2a5 Lock Token: opaquelocktoken:0c0f600b-88f9-0310-9e48-355b44d4a58e Lock Owner: harry Lock Created: 2006-06-14 17:20:31 -0500 (Wed, 14 Jun 2006) Lock Comment (1 line): Editing file for tomorrow's release. $
The fact that the svn info command,
which does not contact the repository when run against working
copy paths, can display the lock token reveals an important
piece of information about those tokens: they are cached in
the working copy. The presence of the lock token is critical.
It gives the working copy authorization to make use of the
lock later on. Also, the svn status
command shows a K
next to the file (short
for locKed), indicating that the lock token is present.
Now that Harry has locked banana.jpg
,
Sally is unable to change or delete that file:
$ svn delete banana.jpg D banana.jpg $ svn commit -m "Delete useless file." Deleting banana.jpg svn: E175002: Commit failed (details follow): svn: E175002: Server sent unexpected return value (423 Locked) in response to DELETE request for '/repos/project/!svn/wrk/64bad3a9-96f9-0310-818a-df4224ddc 35d/banana.jpg' $
But Harry, after touching up the banana's shade of yellow, is able to commit his changes to the file. That's because he authenticates as the lock owner and also because his working copy holds the correct lock token:
$ svn status M K banana.jpg $ svn commit -m "Make banana more yellow" Sending banana.jpg Transmitting file data . Committed revision 2201. $ svn status $
Notice that after the commit is finished, svn
status shows that the lock token is no longer
present in the working copy. This is the standard behavior of
svn commit—it searches the working
copy (or list of targets, if you provide such a list) for
local modifications and sends all the lock tokens it
encounters during this walk to the server as part of the
commit transaction. After the commit completes successfully,
all of the repository locks that were mentioned are
released—even on files that weren't
committed. This is meant to discourage users from
being sloppy about locking or from holding locks for too long.
If Harry haphazardly locks 30 files in a directory named
images
because he's unsure of which files
he needs to change, yet changes only four of those files, when he
runs svn commit images
, the process will
still release all 30 locks.
This behavior of automatically releasing locks can be
overridden with the --no-unlock
option to
svn commit. This is best used for those
times when you want to commit changes, but still plan to make
more changes and thus need to retain existing locks. You can
also make this your default behavior by setting the
no-unlock
runtime configuration option (see
the section called “Runtime Configuration Area”).
Of course, locking a file doesn't oblige one to commit a change to it. The lock can be released at any time with a simple svn unlock command:
$ svn unlock banana.c 'banana.c' unlocked.
When a commit fails due to someone else's locks, it's
fairly easy to learn about them. The easiest way is to run
svn status -u
:
$ svn status -u M 23 bar.c M O 32 raisin.jpg * 72 foo.h Status against revision: 105 $
In this example, Sally can see not only that her copy of
foo.h
is out of date, but also that one of the
two modified files she plans to commit is locked in the
repository. The O
symbol stands for
“Other,” meaning that a lock exists on the file
and was created by somebody else. If she were to attempt a
commit, the lock on raisin.jpg
would
prevent it. Sally is left wondering who made the lock, when,
and why. Once again, svn info has the
answers:
$ svn info ^/raisin.jpg Path: raisin.jpg Name: raisin.jpg URL: http://svn.example.com/repos/project/raisin.jpg Relative URL: ^/raisin.jpg Repository Root: http://svn.example.com/repos/project Repository UUID: edb2f264-5ef2-0310-a47a-87b0ce17a8ec Revision: 105 Node Kind: file Last Changed Author: sally Last Changed Rev: 32 Last Changed Date: 2006-01-25 12:43:04 -0600 (Sun, 25 Jan 2006) Lock Token: opaquelocktoken:fc2b4dee-98f9-0310-abf3-653ff3226e6b Lock Owner: harry Lock Created: 2006-02-16 13:29:18 -0500 (Thu, 16 Feb 2006) Lock Comment (1 line): Need to make a quick tweak to this image. $
Just as you can use svn info to examine objects in the working copy, you can also use it to examine objects in the repository. If the main argument to svn info is a working copy path, then all of the working copy's cached information is displayed; any mention of a lock means that the working copy is holding a lock token (if a file is locked by another user or in another working copy, svn info on a working copy path will show no lock information at all). If the main argument to svn info is a URL, the information reflects the latest version of an object in the repository, and any mention of a lock describes the current lock on the object.
So in this particular example, Sally can see that Harry locked the file on February 16 to “make a quick tweak.” It being June, she suspects that he probably forgot all about the lock. She might phone Harry to complain and ask him to release the lock. If he's unavailable, she might try to forcibly break the lock herself or ask an administrator to do so.
A repository lock isn't sacred—in Subversion's default configuration state, locks can be released not only by the person who created them, but by anyone. When somebody other than the original lock creator destroys a lock, we refer to this as breaking the lock.
From the administrator's chair, it's simple to break locks. The svnlook and svnadmin programs have the ability to display and remove locks directly from the repository. (For more information about these tools, see the section called “An Administrator's Toolkit”.)
$ svnadmin lslocks /var/svn/repos Path: /project2/images/banana.jpg UUID Token: opaquelocktoken:c32b4d88-e8fb-2310-abb3-153ff1236923 Owner: frank Created: 2006-06-15 13:29:18 -0500 (Thu, 15 Jun 2006) Expires: Comment (1 line): Still improving the yellow color. Path: /project/raisin.jpg UUID Token: opaquelocktoken:fc2b4dee-98f9-0310-abf3-653ff3226e6b Owner: harry Created: 2006-02-16 13:29:18 -0500 (Thu, 16 Feb 2006) Expires: Comment (1 line): Need to make a quick tweak to this image. $ svnadmin rmlocks /var/svn/repos /project/raisin.jpg Removed lock on '/project/raisin.jpg'. $
The more interesting option is to allow users to break
each other's locks over the network. To do this, Sally simply
needs to pass the --force
option to the
svn unlock command:
$ svn status -u M 23 bar.c M O 32 raisin.jpg * 72 foo.h Status against revision: 105 $ svn unlock raisin.jpg svn: E195013: 'raisin.jpg' is not locked in this working copy $ svn info raisin.jpg | grep ^URL URL: http://svn.example.com/repos/project/raisin.jpg $ svn unlock http://svn.example.com/repos/project/raisin.jpg svn: warning: W160039: Unlock failed on 'raisin.jpg' (403 Forbidden) $ svn unlock --force http://svn.example.com/repos/project/raisin.jpg 'raisin.jpg' unlocked. $
Now, Sally's initial attempt to unlock failed because she
ran svn unlock directly on her working copy
of the file, and no lock token was present. To remove the
lock directly from the repository, she needs to pass a URL
to svn unlock. Her first attempt to unlock
the URL fails, because she can't authenticate as the lock
owner (nor does she have the lock token). But when she
passes --force
, the authentication and
authorization requirements are ignored, and the remote lock is
broken.
Simply breaking a lock may not be enough. In
the running example, Sally may not only want to break Harry's
long-forgotten lock, but relock the file for her own use.
She can accomplish this by using svn unlock
with --force
and then svn lock
back-to-back, but there's a small chance that somebody else
might lock the file between the two commands. The simpler thing
to do is to steal the lock, which involves
breaking and relocking the file all in one atomic step. To
do this, Sally passes the --force
option
to svn lock:
$ svn lock raisin.jpg svn: warning: W160035: Path '/project/raisin.jpg' is already locked by user 'h arry' in filesystem '/var/svn/repos/db' $ svn lock --force raisin.jpg 'raisin.jpg' locked by user 'sally'. $
In any case, whether the lock is broken or stolen, Harry may be in for a surprise. Harry's working copy still contains the original lock token, but that lock no longer exists. The lock token is said to be defunct. The lock represented by the lock token has either been broken (no longer in the repository) or stolen (replaced with a different lock). Either way, Harry can see this by asking svn status to contact the repository:
$ svn status K raisin.jpg $ svn status -u B 32 raisin.jpg Status against revision: 105 $ svn update Updating '.': B raisin.jpg Updated to revision 105. $ svn status $
If the repository lock was broken, then svn
status --show-updates
(-u
)
displays a B
(Broken) symbol next to the
file. If a new lock exists in place of the old one, then a
T
(sTolen) symbol is shown. Finally,
svn update notices any defunct lock tokens
and removes them from the working copy.
We've seen how svn lock and svn unlock can be used to create, release, break, and steal locks. This satisfies the goal of serializing commit access to a file. But what about the larger problem of preventing wasted time?
For example, suppose Harry locks an image file and then
begins editing it. Meanwhile, miles away, Sally wants to do
the same thing. She doesn't think to run svn status
-u
, so she has no idea that Harry has
already locked the file. She spends hours editing the file,
and when she tries to commit her change, she discovers that
either the file is locked or that she's out of date.
Regardless, her changes aren't mergeable with Harry's. One of
these two people has to throw away his or her work, and a lot of
time has been wasted.
Subversion's solution to this problem is to provide a
mechanism to remind users that a file ought to be locked
before the editing begins. The mechanism
is a special property: svn:needs-lock
. If
that property is attached to a file (regardless of its value,
which is irrelevant), Subversion will try to use
filesystem-level permissions to make the file read-only—unless,
of course, the user has explicitly locked the file.
When a lock token is present (as a result of using
svn lock), the file becomes read/write.
When the lock is released, the file becomes read-only
again.
The theory, then, is that if the image file has this property attached, Sally would immediately notice something is strange when she opens the file for editing: many applications alert users immediately when a read-only file is opened for editing, and nearly all would prevent her from saving changes to the file. This reminds her to lock the file before editing, whereby she discovers the preexisting lock:
$ /usr/local/bin/gimp raisin.jpg gimp: error: file is read-only! $ ls -l raisin.jpg -r--r--r-- 1 sally sally 215589 Jun 8 19:23 raisin.jpg $ svn lock raisin.jpg svn: warning: W160035: Path '/project/raisin.jpg' is already locked by user 'h arry' in filesystem '/var/svn/repos/db' $ svn info http://svn.example.com/repos/project/raisin.jpg | grep Lock Lock Token: opaquelocktoken:fc2b4dee-98f9-0310-abf3-653ff3226e6b Lock Owner: harry Lock Created: 2006-06-08 07:29:18 -0500 (Thu, 08 June 2006) Lock Comment (1 line): Making some tweaks. Locking for the next two hours. $
Tip | |
---|---|
Users and administrators alike are encouraged to attach
the |
Note that this property is a communication tool that works independently from the locking system. In other words, any file can be locked, whether or not this property is present. And conversely, the presence of this property doesn't make the repository require a lock when committing.
Unfortunately, the system isn't flawless. It's possible that even when a file has the property, the read-only reminder won't always work. Sometimes applications misbehave and “hijack” the read-only file, silently allowing users to edit and save the file anyway. There's not much that Subversion can do in this situation—at the end of the day, there's simply no substitution for good interpersonal communication.[29]