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This file contains reference information for the core git commands.
The README contains much useful definition and clarification
info - read that first. And of the commands, I suggest reading
'git-update-cache' and 'git-read-tree' first - I wish I had!
David Greaves <david@dgreaves.com>
24/4/05
Updated by Junio C Hamano <junkio@cox.net> on 2005-05-05 to
reflect recent changes.
Identifier terminology used:
<object>
Indicates any object sha1 identifier
<blob>
Indicates a blob object sha1 identifier
<tree>
Indicates a tree object sha1 identifier
<commit>
Indicates a commit object sha1 identifier
<tree-ish>
Indicates a tree, commit or tag object sha1 identifier.
A command that takes a <tree-ish> argument ultimately
wants to operate on a <tree> object but automatically
dereferences <commit> and <tag> that points at a
<tree>.
<type>
Indicates that an object type is required.
Currently one of: blob/tree/commit/tag
<file>
Indicates a filename - always relative to the root of
the tree structure GIT_INDEX_FILE describes.
################################################################
git-apply-patch-script
This is a sample script to be used as GIT_EXTERNAL_DIFF to apply
differences git-diff-* family of commands reports to the current
work tree.
################################################################
git-cat-file
git-cat-file (-t | <type>) <object>
Provides contents or type of objects in the repository. The type
is required if -t is not being used to find the object type.
<object>
The sha1 identifier of the object.
-t
Instead of the content, show the object type identified
by <object>.
<type>
Typically this matches the real type of <object> but
asking for type that can trivially dereferenced from the
given <object> is also permitted. An example is to ask
"tree" with <object> for a commit object that contains
it, or to ask "blob" with <object> for a tag object that
points at it.
Output
If -t is specified, one of the <type>.
Otherwise the raw (though uncompressed) contents of the <object> will
be returned.
################################################################
git-check-files
git-check-files <file>...
Check that a list of files are up-to-date between the filesystem and
the cache. Used to verify a patch target before doing a patch.
Files that do not exist on the filesystem are considered up-to-date
(whether or not they are in the cache).
Emits an error message on failure.
preparing to update existing file <file> not in cache
<file> exists but is not in the cache
preparing to update file <file> not uptodate in cache
<file> on disk is not up-to-date with the cache
Exits with a status code indicating success if all files are
up-to-date.
see also: git-update-cache
################################################################
git-checkout-cache
git-checkout-cache [-q] [-a] [-f] [-n] [--prefix=<string>]
[--] <file>...
Will copy all files listed from the cache to the working directory
(not overwriting existing files).
-q
be quiet if files exist or are not in the cache
-f
forces overwrite of existing files
-a
checks out all files in the cache (will then continue to
process listed files).
-n
Don't checkout new files, only refresh files already checked
out.
--prefix=<string>
When creating files, prepend <string> (usually a directory
including a trailing /)
--
Do not interpret any more arguments as options.
Note that the order of the flags matters:
git-checkout-cache -a -f file.c
will first check out all files listed in the cache (but not overwrite
any old ones), and then force-checkout file.c a second time (ie that
one _will_ overwrite any old contents with the same filename).
Also, just doing "git-checkout-cache" does nothing. You probably meant
"git-checkout-cache -a". And if you want to force it, you want
"git-checkout-cache -f -a".
Intuitiveness is not the goal here. Repeatability is. The reason for
the "no arguments means no work" thing is that from scripts you are
supposed to be able to do things like
find . -name '*.h' -print0 | xargs -0 git-checkout-cache -f --
which will force all existing *.h files to be replaced with their
cached copies. If an empty command line implied "all", then this would
force-refresh everything in the cache, which was not the point.
To update and refresh only the files already checked out:
git-checkout-cache -n -f -a && git-update-cache --ignore-missing --refresh
Oh, and the "--" is just a good idea when you know the rest will be
filenames. Just so that you wouldn't have a filename of "-a" causing
problems (not possible in the above example, but get used to it in
scripting!).
The prefix ability basically makes it trivial to use git-checkout-cache as
a "git-export as tree" function. Just read the desired tree into the
index, and do a
git-checkout-cache --prefix=git-export-dir/ -a
and git-checkout-cache will "git-export" the cache into the specified
directory.
NOTE! The final "/" is important. The git-exported name is literally just
prefixed with the specified string, so you can also do something like
git-checkout-cache --prefix=.merged- Makefile
to check out the currently cached copy of "Makefile" into the file
".merged-Makefile".
################################################################
git-commit-tree
git-commit-tree <tree> [-p <parent commit>]* < changelog
Creates a new commit object based on the provided tree object and
emits the new commit object id on stdout. If no parent is given then
it is considered to be an initial tree.
A commit object usually has 1 parent (a commit after a change) or up
to 16 parents. More than one parent represents a merge of branches
that led to them.
While a tree represents a particular directory state of a working
directory, a commit represents that state in "time", and explains how
to get there.
Normally a commit would identify a new "HEAD" state, and while git
doesn't care where you save the note about that state, in practice we
tend to just write the result to the file ".git/HEAD", so that we can
always see what the last committed state was.
Options
<tree>
An existing tree object
-p <parent commit>
Each -p indicates a the id of a parent commit object.
Commit Information
A commit encapsulates:
all parent object ids
author name, email and date
committer name and email and the commit time.
If not provided, git-commit-tree uses your name, hostname and domain to
provide author and committer info. This can be overridden using the
following environment variables.
AUTHOR_NAME
AUTHOR_EMAIL
AUTHOR_DATE
COMMIT_AUTHOR_NAME
COMMIT_AUTHOR_EMAIL
(nb <,> and '\n's are stripped)
A commit comment is read from stdin (max 999 chars). If a changelog
entry is not provided via '<' redirection, git-commit-tree will just wait
for one to be entered and terminated with ^D
see also: git-write-tree
################################################################
git-convert-cache
Converts old-style GIT repository to the latest.
################################################################
git-diff-cache
git-diff-cache [-p] [-r] [-z] [--cached] <tree-ish>
Compares the content and mode of the blobs found via a tree object
with the content of the current cache and, optionally ignoring the
stat state of the file on disk.
<tree-ish>
The id of a tree object to diff against.
-p
Generate patch (see section on generating patches)
-r
This flag does not mean anything. It is there only to match
git-diff-tree. Unlike git-diff-tree, git-diff-cache always looks
at all the subdirectories.
-z
\0 line termination on output
--cached
do not consider the on-disk file at all
Output format:
See "Output format from git-diff-cache, git-diff-tree and git-diff-files"
section.
Operating Modes
You can choose whether you want to trust the index file entirely
(using the "--cached" flag) or ask the diff logic to show any files
that don't match the stat state as being "tentatively changed". Both
of these operations are very useful indeed.
Cached Mode
If --cached is specified, it allows you to ask:
show me the differences between HEAD and the current index
contents (the ones I'd write with a "git-write-tree")
For example, let's say that you have worked on your index file, and are
ready to commit. You want to see eactly _what_ you are going to commit is
without having to write a new tree object and compare it that way, and to
do that, you just do
git-diff-cache --cached $(cat .git/HEAD)
Example: let's say I had renamed "commit.c" to "git-commit.c", and I had
done an "git-update-cache" to make that effective in the index file.
"git-diff-files" wouldn't show anything at all, since the index file
matches my working directory. But doing a git-diff-cache does:
torvalds@ppc970:~/git> git-diff-cache --cached $(cat .git/HEAD)
-100644 blob 4161aecc6700a2eb579e842af0b7f22b98443f74 commit.c
+100644 blob 4161aecc6700a2eb579e842af0b7f22b98443f74 git-commit.c
You can trivially see that the above is a rename.
In fact, "git-diff-cache --cached" _should_ always be entirely equivalent to
actually doing a "git-write-tree" and comparing that. Except this one is much
nicer for the case where you just want to check where you are.
So doing a "git-diff-cache --cached" is basically very useful when you are
asking yourself "what have I already marked for being committed, and
what's the difference to a previous tree".
Non-cached Mode
The "non-cached" mode takes a different approach, and is potentially the
even more useful of the two in that what it does can't be emulated with a
"git-write-tree + git-diff-tree". Thus that's the default mode. The
non-cached version asks the question
"show me the differences between HEAD and the currently checked out
tree - index contents _and_ files that aren't up-to-date"
which is obviously a very useful question too, since that tells you what
you _could_ commit. Again, the output matches the "git-diff-tree -r"
output to a tee, but with a twist.
The twist is that if some file doesn't match the cache, we don't have a
backing store thing for it, and we use the magic "all-zero" sha1 to show
that. So let's say that you have edited "kernel/sched.c", but have not
actually done an git-update-cache on it yet - there is no "object" associated
with the new state, and you get:
torvalds@ppc970:~/v2.6/linux> git-diff-cache $(cat .git/HEAD )
*100644->100664 blob 7476bb......->000000...... kernel/sched.c
ie it shows that the tree has changed, and that "kernel/sched.c" has is
not up-to-date and may contain new stuff. The all-zero sha1 means that to
get the real diff, you need to look at the object in the working directory
directly rather than do an object-to-object diff.
NOTE! As with other commands of this type, "git-diff-cache" does not
actually look at the contents of the file at all. So maybe
"kernel/sched.c" hasn't actually changed, and it's just that you touched
it. In either case, it's a note that you need to upate-cache it to make
the cache be in sync.
NOTE 2! You can have a mixture of files show up as "has been updated" and
"is still dirty in the working directory" together. You can always tell
which file is in which state, since the "has been updated" ones show a
valid sha1, and the "not in sync with the index" ones will always have the
special all-zero sha1.
################################################################
git-diff-tree
git-diff-tree [-p] [-r] [-z] <tree-ish> <tree-ish> [<pattern>]*
Compares the content and mode of the blobs found via two tree objects.
Note that git-diff-tree can use the tree encapsulated in a commit object.
<tree-ish>
The id of a tree object.
<pattern>
If provided, the results are limited to a subset of files
matching one of these prefix strings.
ie file matches /^<pattern1>|<pattern2>|.../
Note that pattern does not provide any wildcard or regexp
features.
-p
generate patch (see section on generating patches). For
git-diff-tree, this flag implies -r as well.
-r
recurse
-z
\0 line termination on output
Limiting Output
If you're only interested in differences in a subset of files, for
example some architecture-specific files, you might do:
git-diff-tree -r <tree-ish> <tree-ish> arch/ia64 include/asm-ia64
and it will only show you what changed in those two directories.
Or if you are searching for what changed in just kernel/sched.c, just do
git-diff-tree -r <tree-ish> <tree-ish> kernel/sched.c
and it will ignore all differences to other files.
The pattern is always the prefix, and is matched exactly. There are no
wildcards. Even stricter, it has to match complete path comonent.
I.e. "foo" does not pick up "foobar.h". "foo" does match "foo/bar.h"
so it can be used to name subdirectories.
Output format:
See "Output format from git-diff-cache, git-diff-tree and git-diff-files"
section.
An example of normal usage is:
torvalds@ppc970:~/git> git-diff-tree 5319e4......
*100664->100664 blob ac348b.......->a01513....... git-fsck-cache.c
which tells you that the last commit changed just one file (it's from
this one:
commit 3c6f7ca19ad4043e9e72fa94106f352897e651a8
tree 5319e4d609cdd282069cc4dce33c1db559539b03
parent b4e628ea30d5ab3606119d2ea5caeab141d38df7
author Linus Torvalds <torvalds@ppc970.osdl.org> Sat Apr 9 12:02:30 2005
committer Linus Torvalds <torvalds@ppc970.osdl.org> Sat Apr 9 12:02:30 2005
Make "git-fsck-cache" print out all the root commits it finds.
Once I do the reference tracking, I'll also make it print out all the
HEAD commits it finds, which is even more interesting.
in case you care).
################################################################
git-diff-tree-helper
git-diff-tree-helper [-z] [-R]
Reads output from git-diff-cache, git-diff-tree and git-diff-files and
generates patch format output.
-z
\0 line termination on input
-R
Output diff in reverse. This is useful for displaying output from
git-diff-cache which always compares tree with cache or working
file. E.g.
git-diff-cache <tree> | git-diff-tree-helper -R file.c
would show a diff to bring the working file back to what is in the
<tree>.
See also the section on generating patches.
################################################################
git-fsck-cache
git-fsck-cache [--tags] [--root] [[--unreachable] [--cache] <object>*]
Verifies the connectivity and validity of the objects in the database.
<object>
An object to treat as the head of an unreachability trace.
--unreachable
Print out objects that exist but that aren't readable from any
of the specified head nodes.
--root
Report root nodes.
--tags
Report tags.
--cache
Consider any object recorded in the cache also as a head node for
an unreachability trace.
It tests SHA1 and general object sanity, and it does full tracking of
the resulting reachability and everything else. It prints out any
corruption it finds (missing or bad objects), and if you use the
"--unreachable" flag it will also print out objects that exist but
that aren't readable from any of the specified head nodes.
So for example
git-fsck-cache --unreachable $(cat .git/HEAD)
or, for Cogito users:
git-fsck-cache --unreachable $(cat .git/refs/heads/*)
will do quite a _lot_ of verification on the tree. There are a few
extra validity tests to be added (make sure that tree objects are
sorted properly etc), but on the whole if "git-fsck-cache" is happy, you
do have a valid tree.
Any corrupt objects you will have to find in backups or other archives
(ie you can just remove them and do an "rsync" with some other site in
the hopes that somebody else has the object you have corrupted).
Of course, "valid tree" doesn't mean that it wasn't generated by some
evil person, and the end result might be crap. Git is a revision
tracking system, not a quality assurance system ;)
Extracted Diagnostics
expect dangling commits - potential heads - due to lack of head information
You haven't specified any nodes as heads so it won't be
possible to differentiate between un-parented commits and
root nodes.
missing sha1 directory '<dir>'
The directory holding the sha1 objects is missing.
unreachable <type> <object>
The <type> object <object>, isn't actually referred to directly
or indirectly in any of the trees or commits seen. This can
mean that there's another root na SHA1_ode that you're not specifying
or that the tree is corrupt. If you haven't missed a root node
then you might as well delete unreachable nodes since they
can't be used.
missing <type> <object>
The <type> object <object>, is referred to but isn't present in
the database.
dangling <type> <object>
The <type> object <object>, is present in the database but never
_directly_ used. A dangling commit could be a root node.
warning: git-fsck-cache: tree <tree> has full pathnames in it
And it shouldn't...
sha1 mismatch <object>
The database has an object who's sha1 doesn't match the
database value.
This indicates a ??serious?? data integrity problem.
(note: this error occured during early git development when
the database format changed.)
Environment Variables
SHA1_FILE_DIRECTORY
used to specify the object database root (usually .git/objects)
GIT_INDEX_FILE
used to specify the cache
################################################################
git-export
git-export top [base]
Exports each commit and diff against each of its parents, between
top and base. If base is not specified it exports everything.
################################################################
git-init-db
git-init-db
This simply creates an empty git object database - basically a .git
directory and .git/object/??/ directories.
If the object storage directory is specified via the SHA1_FILE_DIRECTORY
environment variable then the sha1 directories are created underneath -
otherwise the default .git/objects directory is used.
git-init-db won't hurt an existing repository.
################################################################
git-http-pull
git-http-pull [-c] [-t] [-a] [-v] commit-id url
Downloads a remote GIT repository via HTTP protocol.
-c
Get the commit objects.
-t
Get trees associated with the commit objects.
-a
Get all the objects.
-v
Report what is downloaded.
################################################################
git-local-pull
git-local-pull [-c] [-t] [-a] [-l] [-s] [-n] [-v] commit-id path
Downloads another GIT repository on a local system.
-c
Get the commit objects.
-t
Get trees associated with the commit objects.
-a
Get all the objects.
-v
Report what is downloaded.
################################################################
git-ls-tree
git-ls-tree [-r] [-z] <tree-ish>
Converts the tree object to a human readable (and script processable)
form.
<tree-ish>
Id of a tree.
-r
recurse into sub-trees
-z
\0 line termination on output
Output Format
<mode>\t <type>\t <object>\t <file>
################################################################
git-merge-base
git-merge-base <commit> <commit>
git-merge-base finds as good a common ancestor as possible. Given a
selection of equally good common ancestors it should not be relied on
to decide in any particular way.
The git-merge-base algorithm is still in flux - use the source...
################################################################
git-merge-cache
git-merge-cache <merge-program> (-a | -- | <file>*)
This looks up the <file>(s) in the cache and, if there are any merge
entries, passes the SHA1 hash for those files as arguments 1, 2, 3 (empty
argument if no file), and <file> as argument 4. File modes for the three
files are passed as arguments 5, 6 and 7.
--
Interpret all future arguments as filenames.
-a
Run merge against all files in the cache that need merging.
If git-merge-cache is called with multiple <file>s (or -a) then it
processes them in turn only stopping if merge returns a non-zero exit
code.
Typically this is run with the a script calling the merge command from
the RCS package.
A sample script called git-merge-one-file-script is included in the
ditribution.
ALERT ALERT ALERT! The git "merge object order" is different from the
RCS "merge" program merge object order. In the above ordering, the
original is first. But the argument order to the 3-way merge program
"merge" is to have the original in the middle. Don't ask me why.
Examples:
torvalds@ppc970:~/merge-test> git-merge-cache cat MM
This is MM from the original tree. # original
This is modified MM in the branch A. # merge1
This is modified MM in the branch B. # merge2
This is modified MM in the branch B. # current contents
or
torvalds@ppc970:~/merge-test> git-merge-cache cat AA MM
cat: : No such file or directory
This is added AA in the branch A.
This is added AA in the branch B.
This is added AA in the branch B.
fatal: merge program failed
where the latter example shows how "git-merge-cache" will stop trying to
merge once anything has returned an error (ie "cat" returned an error
for the AA file, because it didn't exist in the original, and thus
"git-merge-cache" didn't even try to merge the MM thing).
################################################################
git-merge-one-file-script
This is the standard helper program to use with git-merge-cache
to resolve a merge after the trivial merge done with git-read-tree -m.
################################################################
git-mktag
Reads a tag contents from its standard input and creates a tag object.
The input must be a well formed tag object.
################################################################
git-prune-script
This runs git-fsck-cache --unreachable program using the heads specified
on the command line (or .git/refs/heads/* and .git/refs/tags/* if none is
specified), and prunes all unreachable objects from the object database.
################################################################
git-pull-script
This script is used by Linus to pull from a remote repository and perform
a merge.
################################################################
git-read-tree
git-read-tree (<tree-ish> | -m <tree-ish1> [<tree-ish2> <tree-ish3>])"
Reads the tree information given by <tree> into the directory cache,
but does not actually _update_ any of the files it "caches". (see:
git-checkout-cache)
Optionally, it can merge a tree into the cache or perform a 3-way
merge.
Trivial merges are done by git-read-tree itself. Only conflicting paths
will be in unmerged state when git-read-tree returns.
-m
Perform a merge, not just a read
<tree-ish#>
The id of the tree object(s) to be read/merged.
Merging
If -m is specified, git-read-tree performs 2 kinds of merge, a single tree
merge if only 1 tree is given or a 3-way merge if 3 trees are
provided.
Single Tree Merge
If only 1 tree is specified, git-read-tree operates as if the user did not
specify "-m", except that if the original cache has an entry for a
given pathname; and the contents of the path matches with the tree
being read, the stat info from the cache is used. (In other words, the
cache's stat()s take precedence over the merged tree's)
That means that if you do a "git-read-tree -m <newtree>" followed by a
"git-checkout-cache -f -a", the git-checkout-cache only checks out the stuff
that really changed.
This is used to avoid unnecessary false hits when git-diff-files is
run after git-read-tree.
3-Way Merge
Each "index" entry has two bits worth of "stage" state. stage 0 is the
normal one, and is the only one you'd see in any kind of normal use.
However, when you do "git-read-tree" with three trees, the "stage"
starts out at 1.
This means that you can do
git-read-tree -m <tree1> <tree2> <tree3>
and you will end up with an index with all of the <tree1> entries in
"stage1", all of the <tree2> entries in "stage2" and all of the
<tree3> entries in "stage3".
Furthermore, "git-read-tree" has special-case logic that says: if you see
a file that matches in all respects in the following states, it
"collapses" back to "stage0":
- stage 2 and 3 are the same; take one or the other (it makes no
difference - the same work has been done on stage 2 and 3)
- stage 1 and stage 2 are the same and stage 3 is different; take
stage 3 (some work has been done on stage 3)
- stage 1 and stage 3 are the same and stage 2 is different take
stage 2 (some work has been done on stage 2)
The git-write-tree command refuses to write a nonsensical tree, and it
will complain about unmerged entries if it sees a single entry that is not
stage 0.
Ok, this all sounds like a collection of totally nonsensical rules,
but it's actually exactly what you want in order to do a fast
merge. The different stages represent the "result tree" (stage 0, aka
"merged"), the original tree (stage 1, aka "orig"), and the two trees
you are trying to merge (stage 2 and 3 respectively).
In fact, the way "git-read-tree" works, it's entirely agnostic about how
you assign the stages, and you could really assign them any which way,
and the above is just a suggested way to do it (except since
"git-write-tree" refuses to write anything but stage0 entries, it makes
sense to always consider stage 0 to be the "full merge" state).
So what happens? Try it out. Select the original tree, and two trees
to merge, and look how it works:
- if a file exists in identical format in all three trees, it will
automatically collapse to "merged" state by the new git-read-tree.
- a file that has _any_ difference what-so-ever in the three trees
will stay as separate entries in the index. It's up to "script
policy" to determine how to remove the non-0 stages, and insert a
merged version. But since the index is always sorted, they're easy
to find: they'll be clustered together.
- the index file saves and restores with all this information, so you
can merge things incrementally, but as long as it has entries in
stages 1/2/3 (ie "unmerged entries") you can't write the result.
So now the merge algorithm ends up being really simple:
- you walk the index in order, and ignore all entries of stage 0,
since they've already been done.
- if you find a "stage1", but no matching "stage2" or "stage3", you
know it's been removed from both trees (it only existed in the
original tree), and you remove that entry. - if you find a
matching "stage2" and "stage3" tree, you remove one of them, and
turn the other into a "stage0" entry. Remove any matching "stage1"
entry if it exists too. .. all the normal trivial rules ..
Incidentally - it also means that you don't even have to have a separate
subdirectory for this. All the information literally is in the index file,
which is a temporary thing anyway. There is no need to worry about what is
in the working directory, since it is never shown and never used.
see also:
git-write-tree
git-ls-files
################################################################
git-resolve-script
This script is used by Linus to merge two trees.
################################################################
git-rev-list <commit>
Lists commit objects in reverse chronological order starting at the
given commit, taking ancestry relationship into account. This is
useful to produce human-readable log output.
################################################################
git-rev-tree
git-rev-tree [--edges] [--cache <cache-file>] [^]<commit> [[^]<commit>]
Provides the revision tree for one or more commits.
--edges
Show edges (ie places where the marking changes between parent
and child)
--cache <cache-file>
Use the specified file as a cache from a previous git-rev-list run
to speed things up. Note that this "cache" is totally different
concept from the directory index. Also this option is not
implemented yet.
[^]<commit>
The commit id to trace (a leading caret means to ignore this
commit-id and below)
Output:
<date> <commit>:<flags> [<parent-commit>:<flags> ]*
<date>
Date in 'seconds since epoch'
<commit>
id of commit object
<parent-commit>
id of each parent commit object (>1 indicates a merge)
<flags>
The flags are read as a bitmask representing each commit
provided on the commandline. eg: given the command:
$ git-rev-tree <com1> <com2> <com3>
The output:
<date> <commit>:5
means that <commit> is reachable from <com1>(1) and <com3>(4)
A revtree can get quite large. git-rev-tree will eventually allow you to
cache previous state so that you don't have to follow the whole thing
down.
So the change difference between two commits is literally
git-rev-tree [commit-id1] > commit1-revtree
git-rev-tree [commit-id2] > commit2-revtree
join -t : commit1-revtree commit2-revtree > common-revisions
(this is also how to find the most common parent - you'd look at just
the head revisions - the ones that aren't referred to by other
revisions - in "common-revision", and figure out the best one. I
think.)
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git-rpull
git-rpull [-c] [-t] [-a] [-v] commit-id url
Pulls from a remote repository over ssh connection, invoking git-rpush on
the other end.
-c
Get the commit objects.
-t
Get trees associated with the commit objects.
-a
Get all the objects.
-v
Report what is downloaded.
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git-rpush
Helper "server-side" program used by git-rpull.
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git-diff-files
git-diff-files [-p] [-q] [-r] [-z] [<pattern>...]
Compares the files in the working tree and the cache. When paths
are specified, compares only those named paths. Otherwise all
entries in the cache are compared. The output format is the
same as git-diff-cache and git-diff-tree.
-p
generate patch (see section on generating patches).
-q
Remain silent even on nonexisting files
-r
This flag does not mean anything. It is there only to match
git-diff-tree. Unlike git-diff-tree, git-diff-files always looks
at all the subdirectories.
Output format:
See "Output format from git-diff-cache, git-diff-tree and git-diff-files"
section.
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git-tag-script
This is an example script that uses git-mktag to create a tag object
signed with GPG.
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git-tar-tree
git-tar-tree <tree-ish> [ <base> ]
Creates a tar archive containing the tree structure for the named tree.
When <base> is specified it is added as a leading path as the files in the
generated tar archive.
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git-ls-files
git-ls-files [-z] [-t]
(--[cached|deleted|others|ignored|stage|unmerged])*
(-[c|d|o|i|s|u])*
[-x <pattern>|--exclude=<pattern>]
[-X <file>|--exclude-from=<file>]
This merges the file listing in the directory cache index with the
actual working directory list, and shows different combinations of the
two.
One or more of the options below may be used to determine the files
shown:
-c|--cached
Show cached files in the output (default)
-d|--deleted
Show deleted files in the output
-o|--others
Show other files in the output
-i|--ignored
Show ignored files in the output
Note the this also reverses any exclude list present.
-s|--stage
Show stage files in the output
-u|--unmerged
Show unmerged files in the output (forces --stage)
-z
\0 line termination on output
-x|--exclude=<pattern>
Skips files matching pattern.
Note that pattern is a shell wildcard pattern.
-X|--exclude-from=<file>
exclude patterns are read from <file>; 1 per line.
Allows the use of the famous dontdiff file as follows to find
out about uncommitted files just as dontdiff is used with
the diff command:
git-ls-files --others --exclude-from=dontdiff
-t
Identify the file status with the following tags (followed by
a space) at the start of each line:
H cached
M unmerged
R removed/deleted
? other
Output
show files just outputs the filename unless --stage is specified in
which case it outputs:
[<tag> ]<mode> <object> <stage> <file>
git-ls-files --unmerged" and "git-ls-files --stage " can be used to examine
detailed information on unmerged paths.
For an unmerged path, instead of recording a single mode/SHA1 pair,
the dircache records up to three such pairs; one from tree O in stage
1, A in stage 2, and B in stage 3. This information can be used by
the user (or Cogito) to see what should eventually be recorded at the
path. (see read-cache for more information on state)
see also:
read-cache
################################################################
git-unpack-file
git-unpack-file <blob>
Creates a file holding the contents of the blob specified by sha1. It
returns the name of the temporary file in the following format:
.merge_file_XXXXX
<blob>
Must be a blob id
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git-update-cache
git-update-cache
[--add] [--remove] [--refresh]
[--ignore-missing]
[--force-remove <file>]
[--cacheinfo <mode> <object> <file>]*
[--] [<file>]*
Modifies the index or directory cache. Each file mentioned is updated
into the cache and any 'unmerged' or 'needs updating' state is
cleared.
The way git-update-cache handles files it is told about can be modified
using the various options:
--add
If a specified file isn't in the cache already then it's
added.
Default behaviour is to ignore new files.
--remove
If a specified file is in the cache but is missing then it's
removed.
Default behaviour is to ignore removed file.
--refresh
Looks at the current cache and checks to see if merges or
updates are needed by checking stat() information.
--ignore-missing
Ignores missing files during a --refresh
--cacheinfo <mode> <object> <path>
Directly insert the specified info into the cache.
--force-remove
Remove the file from the index even when the working directory
still has such a file.
--
Do not interpret any more arguments as options.
<file>
Files to act on.
Note that files begining with '.' are discarded. This includes
"./file" and "dir/./file". If you don't want this, then use
cleaner names.
The same applies to directories ending '/' and paths with '//'
Using --refresh
--refresh does not calculate a new sha1 file or bring the cache
up-to-date for mode/content changes. But what it _does_ do is to
"re-match" the stat information of a file with the cache, so that you
can refresh the cache for a file that hasn't been changed but where
the stat entry is out of date.
For example, you'd want to do this after doing a "git-read-tree", to link
up the stat cache details with the proper files.
Using --cacheinfo
--cacheinfo is used to register a file that is not in the current
working directory. This is useful for minimum-checkout merging.
To pretend you have a file with mode and sha1 at path, say:
$ git-update-cache --cacheinfo mode sha1 path
To update and refresh only the files already checked out:
git-checkout-cache -n -f -a && git-update-cache --ignore-missing --refresh
################################################################
git-write-blob
git-write-blob <any-file-on-the-filesystem>
Writes the contents of the named file (which can be outside of the work
tree) as a blob into the object database, and reports its object ID to its
standard output. This is used by git-merge-one-file-script to update the
cache without modifying files in the work tree.
################################################################
git-write-tree
git-write-tree
Creates a tree object using the current cache.
The cache must be merged.
Conceptually, git-write-tree sync()s the current directory cache contents
into a set of tree files.
In order to have that match what is actually in your directory right
now, you need to have done a "git-update-cache" phase before you did the
"git-write-tree".
################################################################
Output format from git-diff-cache, git-diff-tree and git-diff-files.
These commands all compare two sets of things; what are
compared are different:
git-diff-cache <tree-ish>
compares the <tree-ish> and the files on the filesystem.
git-diff-cache --cached <tree-ish>
compares the <tree-ish> and the cache.
git-diff-tree [-r] <tree-ish-1> <tree-ish-2> [<pattern>...]
compares the trees named by the two arguments.
git-diff-files [<pattern>...]
compares the cache and the files on the filesystem.
The following desription uses "old" and "new" to mean those
compared entities.
For files in old but not in new (i.e. removed):
-<mode> \t <type> \t <object> \t <path>
For files not in old but in new (i.e. added):
+<mode> \t <type> \t <object> \t <path>
For files that differ:
*<old-mode>-><new-mode> \t <type> \t <old-sha1>-><new-sha1> \t <path>
<new-sha1> is shown as all 0's if new is a file on the
filesystem and it is out of sync with the cache. Example:
*100644->100644 blob 5be4a4.......->000000....... file.c
################################################################
Generating patches
When git-diff-cache, git-diff-tree, or git-diff-files are run with a -p
option, they do not produce the output described in "Output format from
git-diff-cache, git-diff-tree and git-diff-files" section. It instead
produces a patch file.
The patch generation can be customized at two levels. This
customization also applies to git-diff-tree-helper.
1. When the environment variable GIT_EXTERNAL_DIFF is not set,
these commands internally invoke diff like this:
diff -L a/<path> -L a/<path> -pu <old> <new>
For added files, /dev/null is used for <old>. For removed
files, /dev/null is used for <new>
The diff formatting options can be customized via the
environment variable GIT_DIFF_OPTS. For example, if you
prefer context diff:
GIT_DIFF_OPTS=-c git-diff-cache -p $(cat .git/HEAD)
2. When the environment variable GIT_EXTERNAL_DIFF is set, the
program named by it is called, instead of the diff invocation
described above.
For a path that is added, removed, or modified,
GIT_EXTERNAL_DIFF is called with 7 parameters:
path old-file old-hex old-mode new-file new-hex new-mode
where
<old|new>-file are files GIT_EXTERNAL_DIFF can use to read the
contents of <old|ne>,
<old|new>-hex are the 40-hexdigit SHA1 hashes,
<old|new>-mode are the octal representation of the file modes.
The file parameters can point at the user's working file (e.g. new-file
in git-diff-files), /dev/null (e.g. old-file when a new file is added),
or a temporary file (e.g. old-file in the cache). GIT_EXTERNAL_DIFF
should not worry about unlinking the temporary file --- it is removed
when GIT_EXTERNAL_DIFF exits.
For a path that is unmerged, GIT_EXTERNAL_DIFF is called with
1 parameter, path.
################################################################
Terminology: - see README for description
Each line contains terms used interchangeably
object database, .git directory
directory cache, index
id, sha1, sha1-id, sha1 hash
type, tag
blob, blob object
tree, tree object
commit, commit object
parent
root object
changeset
git Environment Variables
AUTHOR_NAME
AUTHOR_EMAIL
AUTHOR_DATE
COMMIT_AUTHOR_NAME
COMMIT_AUTHOR_EMAIL
GIT_DIFF_OPTS
GIT_EXTERNAL_DIFF
GIT_INDEX_FILE
SHA1_FILE_DIRECTORY