Table of Contents
Git is a fast distributed revision control system.
This manual is designed to be readable by someone with basic UNIX command-line skills, but no previous knowledge of Git.
Chapter 1, Repositories and Branches and Chapter 2, Exploring Git history explain how to fetch and study a project using git—read these chapters to learn how to build and test a particular version of a software project, search for regressions, and so on.
People needing to do actual development will also want to read Chapter 3, Developing with Git and Chapter 4, Sharing development with others.
Further chapters cover more specialized topics.
Comprehensive reference documentation is available through the man
pages, or git-help(1) command. For example, for the command
git clone <repo>
, you can either use:
$ man git-clone
or:
$ git help clone
With the latter, you can use the manual viewer of your choice; see git-help(1) for more information.
See also Appendix A, Git Quick Reference for a brief overview of Git commands, without any explanation.
Finally, see Appendix B, Notes and todo list for this manual for ways that you can help make this manual more complete.
Table of Contents
It will be useful to have a Git repository to experiment with as you read this manual.
The best way to get one is by using the git-clone(1) command to download a copy of an existing repository. If you don’t already have a project in mind, here are some interesting examples:
# Git itself (approx. 40MB download): $ git clone git://git.kernel.org/pub/scm/git/git.git # the Linux kernel (approx. 640MB download): $ git clone git://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
The initial clone may be time-consuming for a large project, but you will only need to clone once.
The clone command creates a new directory named after the project
(git
or linux
in the examples above). After you cd into this
directory, you will see that it contains a copy of the project files,
called the working tree, together with a special
top-level directory named .git
, which contains all the information
about the history of the project.
Git is best thought of as a tool for storing the history of a collection of files. It stores the history as a compressed collection of interrelated snapshots of the project’s contents. In Git each such version is called a commit.
Those snapshots aren’t necessarily all arranged in a single line from oldest to newest; instead, work may simultaneously proceed along parallel lines of development, called branches, which may merge and diverge.
A single Git repository can track development on multiple branches. It does this by keeping a list of heads which reference the latest commit on each branch; the git-branch(1) command shows you the list of branch heads:
$ git branch * master
A freshly cloned repository contains a single branch head, by default named "master", with the working directory initialized to the state of the project referred to by that branch head.
Most projects also use tags. Tags, like heads, are references into the project’s history, and can be listed using the git-tag(1) command:
$ git tag -l v2.6.11 v2.6.11-tree v2.6.12 v2.6.12-rc2 v2.6.12-rc3 v2.6.12-rc4 v2.6.12-rc5 v2.6.12-rc6 v2.6.13 ...
Tags are expected to always point at the same version of a project, while heads are expected to advance as development progresses.
Create a new branch head pointing to one of these versions and check it out using git-switch(1):
$ git switch -c new v2.6.13
The working directory then reflects the contents that the project had when it was tagged v2.6.13, and git-branch(1) shows two branches, with an asterisk marking the currently checked-out branch:
$ git branch master * new
If you decide that you’d rather see version 2.6.17, you can modify the current branch to point at v2.6.17 instead, with
$ git reset --hard v2.6.17
Note that if the current branch head was your only reference to a particular point in history, then resetting that branch may leave you with no way to find the history it used to point to; so use this command carefully.
Every change in the history of a project is represented by a commit. The git-show(1) command shows the most recent commit on the current branch:
$ git show commit 17cf781661e6d38f737f15f53ab552f1e95960d7 Author: Linus Torvalds <[email protected].(none)> Date: Tue Apr 19 14:11:06 2005 -0700 Remove duplicate getenv(DB_ENVIRONMENT) call Noted by Tony Luck. diff --git a/init-db.c b/init-db.c index 65898fa..b002dc6 100644 --- a/init-db.c +++ b/init-db.c @@ -7,7 +7,7 @@ int main(int argc, char **argv) { - char *sha1_dir = getenv(DB_ENVIRONMENT), *path; + char *sha1_dir, *path; int len, i; if (mkdir(".git", 0755) < 0) {
As you can see, a commit shows who made the latest change, what they did, and why.
Every commit has a 40-hexdigit id, sometimes called the "object name" or the
"SHA-1 id", shown on the first line of the git show
output. You can usually
refer to a commit by a shorter name, such as a tag or a branch name, but this
longer name can also be useful. Most importantly, it is a globally unique
name for this commit: so if you tell somebody else the object name (for
example in email), then you are guaranteed that name will refer to the same
commit in their repository that it does in yours (assuming their repository
has that commit at all). Since the object name is computed as a hash over the
contents of the commit, you are guaranteed that the commit can never change
without its name also changing.
In fact, in Chapter 7, Git concepts we shall see that everything stored in Git history, including file data and directory contents, is stored in an object with a name that is a hash of its contents.
Every commit (except the very first commit in a project) also has a parent commit which shows what happened before this commit. Following the chain of parents will eventually take you back to the beginning of the project.
However, the commits do not form a simple list; Git allows lines of development to diverge and then reconverge, and the point where two lines of development reconverge is called a "merge". The commit representing a merge can therefore have more than one parent, with each parent representing the most recent commit on one of the lines of development leading to that point.
The best way to see how this works is using the gitk(1) command; running gitk now on a Git repository and looking for merge commits will help understand how Git organizes history.
In the following, we say that commit X is "reachable" from commit Y if commit X is an ancestor of commit Y. Equivalently, you could say that Y is a descendant of X, or that there is a chain of parents leading from commit Y to commit X.
We will sometimes represent Git history using diagrams like the one below. Commits are shown as "o", and the links between them with lines drawn with - / and \. Time goes left to right:
o--o--o <-- Branch A / o--o--o <-- master \ o--o--o <-- Branch B
If we need to talk about a particular commit, the character "o" may be replaced with another letter or number.
When we need to be precise, we will use the word "branch" to mean a line of development, and "branch head" (or just "head") to mean a reference to the most recent commit on a branch. In the example above, the branch head named "A" is a pointer to one particular commit, but we refer to the line of three commits leading up to that point as all being part of "branch A".
However, when no confusion will result, we often just use the term "branch" both for branches and for branch heads.
Creating, deleting, and modifying branches is quick and easy; here’s a summary of the commands:
git branch
git branch <branch>
<branch>
, referencing the same
point in history as the current branch.
git branch <branch> <start-point>
<branch>
, referencing
<start-point>
, which may be specified any way you like,
including using a branch name or a tag name.
git branch -d <branch>
<branch>
; if the branch is not fully
merged in its upstream branch or contained in the current branch,
this command will fail with a warning.
git branch -D <branch>
<branch>
irrespective of its merged status.
git switch <branch>
<branch>
, updating the working
directory to reflect the version referenced by <branch>
.
git switch -c <new> <start-point>
<new>
referencing <start-point>
, and
check it out.
The special symbol "HEAD" can always be used to refer to the current
branch. In fact, Git uses a file named HEAD
in the .git
directory
to remember which branch is current:
$ cat .git/HEAD ref: refs/heads/master
The git switch
command normally expects a branch head, but will also
accept an arbitrary commit when invoked with --detach; for example,
you can check out the commit referenced by a tag:
$ git switch --detach v2.6.17 Note: checking out 'v2.6.17'. You are in 'detached HEAD' state. You can look around, make experimental changes and commit them, and you can discard any commits you make in this state without impacting any branches by performing another switch. If you want to create a new branch to retain commits you create, you may do so (now or later) by using -c with the switch command again. Example: git switch -c new_branch_name HEAD is now at 427abfa Linux v2.6.17
The HEAD then refers to the SHA-1 of the commit instead of to a branch, and git branch shows that you are no longer on a branch:
$ cat .git/HEAD 427abfa28afedffadfca9dd8b067eb6d36bac53f $ git branch * (detached from v2.6.17) master
In this case we say that the HEAD is "detached".
This is an easy way to check out a particular version without having to make up a name for the new branch. You can still create a new branch (or tag) for this version later if you decide to.
The "master" branch that was created at the time you cloned is a copy
of the HEAD in the repository that you cloned from. That repository
may also have had other branches, though, and your local repository
keeps branches which track each of those remote branches, called
remote-tracking branches, which you
can view using the -r
option to git-branch(1):
$ git branch -r origin/HEAD origin/html origin/maint origin/man origin/master origin/next origin/seen origin/todo
In this example, "origin" is called a remote repository, or "remote"
for short. The branches of this repository are called "remote
branches" from our point of view. The remote-tracking branches listed
above were created based on the remote branches at clone time and will
be updated by git fetch
(hence git pull
) and git push
. See
the section called “Updating a repository with git fetch” for details.
You might want to build on one of these remote-tracking branches on a branch of your own, just as you would for a tag:
$ git switch -c my-todo-copy origin/todo
You can also check out origin/todo
directly to examine it or
write a one-off patch. See detached head.
Note that the name "origin" is just the name that Git uses by default to refer to the repository that you cloned from.
Branches, remote-tracking branches, and tags are all references to
commits. All references are named with a slash-separated path name
starting with refs
; the names we’ve been using so far are actually
shorthand:
test
is short for refs/heads/test
.
v2.6.18
is short for refs/tags/v2.6.18
.
origin/master
is short for refs/remotes/origin/master
.
The full name is occasionally useful if, for example, there ever exists a tag and a branch with the same name.
(Newly created refs are actually stored in the .git/refs
directory,
under the path given by their name. However, for efficiency reasons
they may also be packed together in a single file; see
git-pack-refs(1)).
As another useful shortcut, the "HEAD" of a repository can be referred to just using the name of that repository. So, for example, "origin" is usually a shortcut for the HEAD branch in the repository "origin".
For the complete list of paths which Git checks for references, and the order it uses to decide which to choose when there are multiple references with the same shorthand name, see the "SPECIFYING REVISIONS" section of gitrevisions(7).
After you clone a repository and commit a few changes of your own, you may wish to check the original repository for updates.
The git-fetch
command, with no arguments, will update all of the
remote-tracking branches to the latest version found in the original
repository. It will not touch any of your own branches—not even the
"master" branch that was created for you on clone.
You can also track branches from repositories other than the one you cloned from, using git-remote(1):
$ git remote add staging git://git.kernel.org/.../gregkh/staging.git $ git fetch staging ... From git://git.kernel.org/pub/scm/linux/kernel/git/gregkh/staging * [new branch] master -> staging/master * [new branch] staging-linus -> staging/staging-linus * [new branch] staging-next -> staging/staging-next
New remote-tracking branches will be stored under the shorthand name
that you gave git remote add
, in this case staging
:
$ git branch -r origin/HEAD -> origin/master origin/master staging/master staging/staging-linus staging/staging-next
If you run git fetch <remote>
later, the remote-tracking branches
for the named <remote>
will be updated.
If you examine the file .git/config
, you will see that Git has added
a new stanza:
$ cat .git/config ... [remote "staging"] url = git://git.kernel.org/pub/scm/linux/kernel/git/gregkh/staging.git fetch = +refs/heads/*:refs/remotes/staging/* ...
This is what causes Git to track the remote’s branches; you may modify
or delete these configuration options by editing .git/config
with a
text editor. (See the "CONFIGURATION FILE" section of
git-config(1) for details.)
Table of Contents
Git is best thought of as a tool for storing the history of a collection of files. It does this by storing compressed snapshots of the contents of a file hierarchy, together with "commits" which show the relationships between these snapshots.
Git provides extremely flexible and fast tools for exploring the history of a project.
We start with one specialized tool that is useful for finding the commit that introduced a bug into a project.
Suppose version 2.6.18 of your project worked, but the version at "master" crashes. Sometimes the best way to find the cause of such a regression is to perform a brute-force search through the project’s history to find the particular commit that caused the problem. The git-bisect(1) command can help you do this:
$ git bisect start $ git bisect good v2.6.18 $ git bisect bad master Bisecting: 3537 revisions left to test after this [65934a9a028b88e83e2b0f8b36618fe503349f8e] BLOCK: Make USB storage depend on SCSI rather than selecting it [try #6]
If you run git branch
at this point, you’ll see that Git has
temporarily moved you in "(no branch)". HEAD is now detached from any
branch and points directly to a commit (with commit id 65934) that
is reachable from "master" but not from v2.6.18. Compile and test it,
and see whether it crashes. Assume it does crash. Then:
$ git bisect bad Bisecting: 1769 revisions left to test after this [7eff82c8b1511017ae605f0c99ac275a7e21b867] i2c-core: Drop useless bitmaskings
checks out an older version. Continue like this, telling Git at each stage whether the version it gives you is good or bad, and notice that the number of revisions left to test is cut approximately in half each time.
After about 13 tests (in this case), it will output the commit id of the guilty commit. You can then examine the commit with git-show(1), find out who wrote it, and mail them your bug report with the commit id. Finally, run
$ git bisect reset
to return you to the branch you were on before.
Note that the version which git bisect
checks out for you at each
point is just a suggestion, and you’re free to try a different
version if you think it would be a good idea. For example,
occasionally you may land on a commit that broke something unrelated;
run
$ git bisect visualize
which will run gitk and label the commit it chose with a marker that says "bisect". Choose a safe-looking commit nearby, note its commit id, and check it out with:
$ git reset --hard fb47ddb2db
then test, run bisect good
or bisect bad
as appropriate, and
continue.
Instead of git bisect visualize
and then git reset --hard
fb47ddb2db
, you might just want to tell Git that you want to skip
the current commit:
$ git bisect skip
In this case, though, Git may not eventually be able to tell the first bad one between some first skipped commits and a later bad commit.
There are also ways to automate the bisecting process if you have a
test script that can tell a good from a bad commit. See
git-bisect(1) for more information about this and other git
bisect
features.
We have seen several ways of naming commits already:
There are many more; see the "SPECIFYING REVISIONS" section of the gitrevisions(7) man page for the complete list of ways to name revisions. Some examples:
$ git show fb47ddb2 # the first few characters of the object name # are usually enough to specify it uniquely $ git show HEAD^ # the parent of the HEAD commit $ git show HEAD^^ # the grandparent $ git show HEAD~4 # the great-great-grandparent
Recall that merge commits may have more than one parent; by default,
^
and ~
follow the first parent listed in the commit, but you can
also choose:
$ git show HEAD^1 # show the first parent of HEAD $ git show HEAD^2 # show the second parent of HEAD
In addition to HEAD, there are several other special names for commits:
Merges (to be discussed later), as well as operations such as
git reset
, which change the currently checked-out commit, generally
set ORIG_HEAD to the value HEAD had before the current operation.
The git fetch
operation always stores the head of the last fetched
branch in FETCH_HEAD. For example, if you run git fetch
without
specifying a local branch as the target of the operation
$ git fetch git://example.com/proj.git theirbranch
the fetched commits will still be available from FETCH_HEAD.
When we discuss merges we’ll also see the special name MERGE_HEAD, which refers to the other branch that we’re merging in to the current branch.
The git-rev-parse(1) command is a low-level command that is occasionally useful for translating some name for a commit to the object name for that commit:
$ git rev-parse origin e05db0fd4f31dde7005f075a84f96b360d05984b
We can also create a tag to refer to a particular commit; after running
$ git tag stable-1 1b2e1d63ff
You can use stable-1
to refer to the commit 1b2e1d63ff.
This creates a "lightweight" tag. If you would also like to include a comment with the tag, and possibly sign it cryptographically, then you should create a tag object instead; see the git-tag(1) man page for details.
The git-log(1) command can show lists of commits. On its own, it shows all commits reachable from the parent commit; but you can also make more specific requests:
$ git log v2.5.. # commits since (not reachable from) v2.5 $ git log test..master # commits reachable from master but not test $ git log master..test # ...reachable from test but not master $ git log master...test # ...reachable from either test or master, # but not both $ git log --since="2 weeks ago" # commits from the last 2 weeks $ git log Makefile # commits which modify Makefile $ git log fs/ # ... which modify any file under fs/ $ git log -S'foo()' # commits which add or remove any file data # matching the string 'foo()'
And of course you can combine all of these; the following finds
commits since v2.5 which touch the Makefile
or any file under fs
:
$ git log v2.5.. Makefile fs/
You can also ask git log to show patches:
$ git log -p
See the --pretty
option in the git-log(1) man page for more
display options.
Note that git log starts with the most recent commit and works backwards through the parents; however, since Git history can contain multiple independent lines of development, the particular order that commits are listed in may be somewhat arbitrary.
You can generate diffs between any two versions using git-diff(1):
$ git diff master..test
That will produce the diff between the tips of the two branches. If you’d prefer to find the diff from their common ancestor to test, you can use three dots instead of two:
$ git diff master...test
Sometimes what you want instead is a set of patches; for this you can use git-format-patch(1):
$ git format-patch master..test
will generate a file with a patch for each commit reachable from test but not from master.
You can always view an old version of a file by just checking out the correct revision first. But sometimes it is more convenient to be able to view an old version of a single file without checking anything out; this command does that:
$ git show v2.5:fs/locks.c
Before the colon may be anything that names a commit, and after it may be any path to a file tracked by Git.
Suppose you want to know how many commits you’ve made on mybranch
since it diverged from origin
:
$ git log --pretty=oneline origin..mybranch | wc -l
Alternatively, you may often see this sort of thing done with the lower-level command git-rev-list(1), which just lists the SHA-1’s of all the given commits:
$ git rev-list origin..mybranch | wc -l
Suppose you want to check whether two branches point at the same point in history.
$ git diff origin..master
will tell you whether the contents of the project are the same at the two branches; in theory, however, it’s possible that the same project contents could have been arrived at by two different historical routes. You could compare the object names:
$ git rev-list origin e05db0fd4f31dde7005f075a84f96b360d05984b $ git rev-list master e05db0fd4f31dde7005f075a84f96b360d05984b
Or you could recall that the ...
operator selects all commits
reachable from either one reference or the other but not
both; so
$ git log origin...master
will return no commits when the two branches are equal.
Suppose you know that the commit e05db0fd fixed a certain problem. You’d like to find the earliest tagged release that contains that fix.
Of course, there may be more than one answer—if the history branched after commit e05db0fd, then there could be multiple "earliest" tagged releases.
You could just visually inspect the commits since e05db0fd:
$ gitk e05db0fd..
or you can use git-name-rev(1), which will give the commit a name based on any tag it finds pointing to one of the commit’s descendants:
$ git name-rev --tags e05db0fd e05db0fd tags/v1.5.0-rc1^0~23
The git-describe(1) command does the opposite, naming the revision using a tag on which the given commit is based:
$ git describe e05db0fd v1.5.0-rc0-260-ge05db0f
but that may sometimes help you guess which tags might come after the given commit.
If you just want to verify whether a given tagged version contains a given commit, you could use git-merge-base(1):
$ git merge-base e05db0fd v1.5.0-rc1 e05db0fd4f31dde7005f075a84f96b360d05984b
The merge-base command finds a common ancestor of the given commits, and always returns one or the other in the case where one is a descendant of the other; so the above output shows that e05db0fd actually is an ancestor of v1.5.0-rc1.
Alternatively, note that
$ git log v1.5.0-rc1..e05db0fd
will produce empty output if and only if v1.5.0-rc1 includes e05db0fd, because it outputs only commits that are not reachable from v1.5.0-rc1.
As yet another alternative, the git-show-branch(1) command lists the commits reachable from its arguments with a display on the left-hand side that indicates which arguments that commit is reachable from. So, if you run something like
$ git show-branch e05db0fd v1.5.0-rc0 v1.5.0-rc1 v1.5.0-rc2 ! [e05db0fd] Fix warnings in sha1_file.c - use C99 printf format if available ! [v1.5.0-rc0] GIT v1.5.0 preview ! [v1.5.0-rc1] GIT v1.5.0-rc1 ! [v1.5.0-rc2] GIT v1.5.0-rc2 ...
then a line like
+ ++ [e05db0fd] Fix warnings in sha1_file.c - use C99 printf format if available
shows that e05db0fd is reachable from itself, from v1.5.0-rc1, and from v1.5.0-rc2, and not from v1.5.0-rc0.
Suppose you would like to see all the commits reachable from the branch
head named master
but not from any other head in your repository.
We can list all the heads in this repository with git-show-ref(1):
$ git show-ref --heads bf62196b5e363d73353a9dcf094c59595f3153b7 refs/heads/core-tutorial db768d5504c1bb46f63ee9d6e1772bd047e05bf9 refs/heads/maint a07157ac624b2524a059a3414e99f6f44bebc1e7 refs/heads/master 24dbc180ea14dc1aebe09f14c8ecf32010690627 refs/heads/tutorial-2 1e87486ae06626c2f31eaa63d26fc0fd646c8af2 refs/heads/tutorial-fixes
We can get just the branch-head names, and remove master
, with
the help of the standard utilities cut and grep:
$ git show-ref --heads | cut -d' ' -f2 | grep -v '^refs/heads/master' refs/heads/core-tutorial refs/heads/maint refs/heads/tutorial-2 refs/heads/tutorial-fixes
And then we can ask to see all the commits reachable from master but not from these other heads:
$ gitk master --not $( git show-ref --heads | cut -d' ' -f2 | grep -v '^refs/heads/master' )
Obviously, endless variations are possible; for example, to see all commits reachable from some head but not from any tag in the repository:
$ gitk $( git show-ref --heads ) --not $( git show-ref --tags )
(See gitrevisions(7) for explanations of commit-selecting
syntax such as --not
.)
The git-archive(1) command can create a tar or zip archive from any version of a project; for example:
$ git archive -o latest.tar.gz --prefix=project/ HEAD
will use HEAD to produce a gzipped tar archive in which each filename
is preceded by project/
. The output file format is inferred from
the output file extension if possible, see git-archive(1) for
details.
Versions of Git older than 1.7.7 don’t know about the tar.gz
format,
you’ll need to use gzip explicitly:
$ git archive --format=tar --prefix=project/ HEAD | gzip >latest.tar.gz
If you’re releasing a new version of a software project, you may want to simultaneously make a changelog to include in the release announcement.
Linus Torvalds, for example, makes new kernel releases by tagging them, then running:
$ release-script 2.6.12 2.6.13-rc6 2.6.13-rc7
where release-script is a shell script that looks like:
#!/bin/sh stable="$1" last="$2" new="$3" echo "# git tag v$new" echo "git archive --prefix=linux-$new/ v$new | gzip -9 > ../linux-$new.tar.gz" echo "git diff v$stable v$new | gzip -9 > ../patch-$new.gz" echo "git log --no-merges v$new ^v$last > ../ChangeLog-$new" echo "git shortlog --no-merges v$new ^v$last > ../ShortLog" echo "git diff --stat --summary -M v$last v$new > ../diffstat-$new"
and then he just cut-and-pastes the output commands after verifying that they look OK.
Somebody hands you a copy of a file, and asks which commits modified a file such that it contained the given content either before or after the commit. You can find out with this:
$ git log --raw --abbrev=40 --pretty=oneline | grep -B 1 `git hash-object filename`
Figuring out why this works is left as an exercise to the (advanced) student. The git-log(1), git-diff-tree(1), and git-hash-object(1) man pages may prove helpful.
Table of Contents
Before creating any commits, you should introduce yourself to Git. The easiest way to do so is to use git-config(1):
$ git config --global user.name 'Your Name Comes Here' $ git config --global user.email '[email protected]'
Which will add the following to a file named .gitconfig
in your
home directory:
[user] name = Your Name Comes Here email = [email protected]
See the "CONFIGURATION FILE" section of git-config(1) for details on the configuration file. The file is plain text, so you can also edit it with your favorite editor.
Creating a new repository from scratch is very easy:
$ mkdir project $ cd project $ git init
If you have some initial content (say, a tarball):
$ tar xzvf project.tar.gz $ cd project $ git init $ git add . # include everything below ./ in the first commit: $ git commit
Creating a new commit takes three steps:
In practice, you can interleave and repeat steps 1 and 2 as many times as you want: in order to keep track of what you want committed at step 3, Git maintains a snapshot of the tree’s contents in a special staging area called "the index."
At the beginning, the content of the index will be identical to
that of the HEAD. The command git diff --cached
, which shows
the difference between the HEAD and the index, should therefore
produce no output at that point.
Modifying the index is easy:
To update the index with the contents of a new or modified file, use
$ git add path/to/file
To remove a file from the index and from the working tree, use
$ git rm path/to/file
After each step you can verify that
$ git diff --cached
always shows the difference between the HEAD and the index file—this is what you’d commit if you created the commit now—and that
$ git diff
shows the difference between the working tree and the index file.
Note that git add
always adds just the current contents of a file
to the index; further changes to the same file will be ignored unless
you run git add
on the file again.
When you’re ready, just run
$ git commit
and Git will prompt you for a commit message and then create the new commit. Check to make sure it looks like what you expected with
$ git show
As a special shortcut,
$ git commit -a
will update the index with any files that you’ve modified or removed and create a commit, all in one step.
A number of commands are useful for keeping track of what you’re about to commit:
$ git diff --cached # difference between HEAD and the index; what # would be committed if you ran "commit" now. $ git diff # difference between the index file and your # working directory; changes that would not # be included if you ran "commit" now. $ git diff HEAD # difference between HEAD and working tree; what # would be committed if you ran "commit -a" now. $ git status # a brief per-file summary of the above.
You can also use git-gui(1) to create commits, view changes in the index and the working tree files, and individually select diff hunks for inclusion in the index (by right-clicking on the diff hunk and choosing "Stage Hunk For Commit").
Though not required, it’s a good idea to begin the commit message with a single short (less than 50 character) line summarizing the change, followed by a blank line and then a more thorough description. The text up to the first blank line in a commit message is treated as the commit title, and that title is used throughout Git. For example, git-format-patch(1) turns a commit into email, and it uses the title on the Subject line and the rest of the commit in the body.
A project will often generate files that you do not want to track with Git.
This typically includes files generated by a build process or temporary
backup files made by your editor. Of course, not tracking files with Git
is just a matter of not calling git add
on them. But it quickly becomes
annoying to have these untracked files lying around; e.g. they make
git add .
practically useless, and they keep showing up in the output of
git status
.
You can tell Git to ignore certain files by creating a file called
.gitignore
in the top level of your working directory, with contents
such as:
# Lines starting with '#' are considered comments. # Ignore any file named foo.txt. foo.txt # Ignore (generated) html files, *.html # except foo.html which is maintained by hand. !foo.html # Ignore objects and archives. *.[oa]
See gitignore(5) for a detailed explanation of the syntax. You can
also place .gitignore files in other directories in your working tree, and they
will apply to those directories and their subdirectories. The .gitignore
files can be added to your repository like any other files (just run git add
.gitignore
and git commit
, as usual), which is convenient when the exclude
patterns (such as patterns matching build output files) would also make sense
for other users who clone your repository.
If you wish the exclude patterns to affect only certain repositories
(instead of every repository for a given project), you may instead put
them in a file in your repository named .git/info/exclude
, or in any
file specified by the core.excludesFile
configuration variable.
Some Git commands can also take exclude patterns directly on the
command line. See gitignore(5) for the details.
You can rejoin two diverging branches of development using git-merge(1):
$ git merge branchname
merges the development in the branch branchname
into the current
branch.
A merge is made by combining the changes made in branchname
and the
changes made up to the latest commit in your current branch since
their histories forked. The work tree is overwritten by the result of
the merge when this combining is done cleanly, or overwritten by a
half-merged results when this combining results in conflicts.
Therefore, if you have uncommitted changes touching the same files as
the ones impacted by the merge, Git will refuse to proceed. Most of
the time, you will want to commit your changes before you can merge,
and if you don’t, then git-stash(1) can take these changes
away while you’re doing the merge, and reapply them afterwards.
If the changes are independent enough, Git will automatically complete the merge and commit the result (or reuse an existing commit in case of fast-forward, see below). On the other hand, if there are conflicts—for example, if the same file is modified in two different ways in the remote branch and the local branch—then you are warned; the output may look something like this:
$ git merge next 100% (4/4) done Auto-merged file.txt CONFLICT (content): Merge conflict in file.txt Automatic merge failed; fix conflicts and then commit the result.
Conflict markers are left in the problematic files, and after you resolve the conflicts manually, you can update the index with the contents and run Git commit, as you normally would when creating a new file.
If you examine the resulting commit using gitk, you will see that it has two parents, one pointing to the top of the current branch, and one to the top of the other branch.
When a merge isn’t resolved automatically, Git leaves the index and the working tree in a special state that gives you all the information you need to help resolve the merge.
Files with conflicts are marked specially in the index, so until you resolve the problem and update the index, git-commit(1) will fail:
$ git commit file.txt: needs merge
Also, git-status(1) will list those files as "unmerged", and the files with conflicts will have conflict markers added, like this:
<<<<<<< HEAD:file.txt Hello world ======= Goodbye >>>>>>> 77976da35a11db4580b80ae27e8d65caf5208086:file.txt
All you need to do is edit the files to resolve the conflicts, and then
$ git add file.txt $ git commit
Note that the commit message will already be filled in for you with some information about the merge. Normally you can just use this default message unchanged, but you may add additional commentary of your own if desired.
The above is all you need to know to resolve a simple merge. But Git also provides more information to help resolve conflicts:
All of the changes that Git was able to merge automatically are already added to the index file, so git-diff(1) shows only the conflicts. It uses an unusual syntax:
$ git diff diff --cc file.txt index 802992c,2b60207..0000000 --- a/file.txt +++ b/file.txt @@@ -1,1 -1,1 +1,5 @@@ ++<<<<<<< HEAD:file.txt +Hello world ++======= + Goodbye ++>>>>>>> 77976da35a11db4580b80ae27e8d65caf5208086:file.txt
Recall that the commit which will be committed after we resolve this conflict will have two parents instead of the usual one: one parent will be HEAD, the tip of the current branch; the other will be the tip of the other branch, which is stored temporarily in MERGE_HEAD.
During the merge, the index holds three versions of each file. Each of these three "file stages" represents a different version of the file:
$ git show :1:file.txt # the file in a common ancestor of both branches $ git show :2:file.txt # the version from HEAD. $ git show :3:file.txt # the version from MERGE_HEAD.
When you ask git-diff(1) to show the conflicts, it runs a three-way diff between the conflicted merge results in the work tree with stages 2 and 3 to show only hunks whose contents come from both sides, mixed (in other words, when a hunk’s merge results come only from stage 2, that part is not conflicting and is not shown. Same for stage 3).
The diff above shows the differences between the working-tree version of
file.txt and the stage 2 and stage 3 versions. So instead of preceding
each line by a single +
or -
, it now uses two columns: the first
column is used for differences between the first parent and the working
directory copy, and the second for differences between the second parent
and the working directory copy. (See the "COMBINED DIFF FORMAT" section
of git-diff-files(1) for a details of the format.)
After resolving the conflict in the obvious way (but before updating the index), the diff will look like:
$ git diff diff --cc file.txt index 802992c,2b60207..0000000 --- a/file.txt +++ b/file.txt @@@ -1,1 -1,1 +1,1 @@@ - Hello world -Goodbye ++Goodbye world
This shows that our resolved version deleted "Hello world" from the first parent, deleted "Goodbye" from the second parent, and added "Goodbye world", which was previously absent from both.
Some special diff options allow diffing the working directory against any of these stages:
$ git diff -1 file.txt # diff against stage 1 $ git diff --base file.txt # same as the above $ git diff -2 file.txt # diff against stage 2 $ git diff --ours file.txt # same as the above $ git diff -3 file.txt # diff against stage 3 $ git diff --theirs file.txt # same as the above.
The git-log(1) and gitk(1) commands also provide special help for merges:
$ git log --merge $ gitk --merge
These will display all commits which exist only on HEAD or on MERGE_HEAD, and which touch an unmerged file.
You may also use git-mergetool(1), which lets you merge the unmerged files using external tools such as Emacs or kdiff3.
Each time you resolve the conflicts in a file and update the index:
$ git add file.txt
the different stages of that file will be "collapsed", after which
git diff
will (by default) no longer show diffs for that file.
If you get stuck and decide to just give up and throw the whole mess away, you can always return to the pre-merge state with
$ git merge --abort
Or, if you’ve already committed the merge that you want to throw away,
$ git reset --hard ORIG_HEAD
However, this last command can be dangerous in some cases—never throw away a commit you have already committed if that commit may itself have been merged into another branch, as doing so may confuse further merges.
There is one special case not mentioned above, which is treated differently. Normally, a merge results in a merge commit, with two parents, one pointing at each of the two lines of development that were merged.
However, if the current branch is an ancestor of the other—so every commit present in the current branch is already contained in the other branch—then Git just performs a "fast-forward"; the head of the current branch is moved forward to point at the head of the merged-in branch, without any new commits being created.
If you’ve messed up the working tree, but haven’t yet committed your mistake, you can return the entire working tree to the last committed state with
$ git restore --staged --worktree :/
If you make a commit that you later wish you hadn’t, there are two fundamentally different ways to fix the problem:
Creating a new commit that reverts an earlier change is very easy; just pass the git-revert(1) command a reference to the bad commit; for example, to revert the most recent commit:
$ git revert HEAD
This will create a new commit which undoes the change in HEAD. You will be given a chance to edit the commit message for the new commit.
You can also revert an earlier change, for example, the next-to-last:
$ git revert HEAD^
In this case Git will attempt to undo the old change while leaving intact any changes made since then. If more recent changes overlap with the changes to be reverted, then you will be asked to fix conflicts manually, just as in the case of resolving a merge.
If the problematic commit is the most recent commit, and you have not
yet made that commit public, then you may just
destroy it using git reset
.
Alternatively, you can edit the working directory and update the index to fix your mistake, just as if you were going to create a new commit, then run
$ git commit --amend
which will replace the old commit by a new commit incorporating your changes, giving you a chance to edit the old commit message first.
Again, you should never do this to a commit that may already have been merged into another branch; use git-revert(1) instead in that case.
It is also possible to replace commits further back in the history, but this is an advanced topic to be left for another chapter.
In the process of undoing a previous bad change, you may find it useful to check out an older version of a particular file using git-restore(1). The command
$ git restore --source=HEAD^ path/to/file
replaces path/to/file by the contents it had in the commit HEAD^, and also updates the index to match. It does not change branches.
If you just want to look at an old version of the file, without modifying the working directory, you can do that with git-show(1):
$ git show HEAD^:path/to/file
which will display the given version of the file.
While you are in the middle of working on something complicated, you find an unrelated but obvious and trivial bug. You would like to fix it before continuing. You can use git-stash(1) to save the current state of your work, and after fixing the bug (or, optionally after doing so on a different branch and then coming back), unstash the work-in-progress changes.
$ git stash push -m "work in progress for foo feature"
This command will save your changes away to the stash
, and
reset your working tree and the index to match the tip of your
current branch. Then you can make your fix as usual.
... edit and test ... $ git commit -a -m "blorpl: typofix"
After that, you can go back to what you were working on with
git stash pop
:
$ git stash pop
On large repositories, Git depends on compression to keep the history
information from taking up too much space on disk or in memory. Some
Git commands may automatically run git-gc(1), so you don’t
have to worry about running it manually. However, compressing a large
repository may take a while, so you may want to call gc
explicitly
to avoid automatic compression kicking in when it is not convenient.
The git-fsck(1) command runs a number of self-consistency checks on the repository, and reports on any problems. This may take some time.
$ git fsck dangling commit 7281251ddd2a61e38657c827739c57015671a6b3 dangling commit 2706a059f258c6b245f298dc4ff2ccd30ec21a63 dangling commit 13472b7c4b80851a1bc551779171dcb03655e9b5 dangling blob 218761f9d90712d37a9c5e36f406f92202db07eb dangling commit bf093535a34a4d35731aa2bd90fe6b176302f14f dangling commit 8e4bec7f2ddaa268bef999853c25755452100f8e dangling tree d50bb86186bf27b681d25af89d3b5b68382e4085 dangling tree b24c2473f1fd3d91352a624795be026d64c8841f ...
You will see informational messages on dangling objects. They are objects
that still exist in the repository but are no longer referenced by any of
your branches, and can (and will) be removed after a while with gc
.
You can run git fsck --no-dangling
to suppress these messages, and still
view real errors.
Say you modify a branch with git reset --hard
,
and then realize that the branch was the only reference you had to
that point in history.
Fortunately, Git also keeps a log, called a "reflog", of all the previous values of each branch. So in this case you can still find the old history using, for example,
$ git log master@{1}
This lists the commits reachable from the previous version of the
master
branch head. This syntax can be used with any Git command
that accepts a commit, not just with git log
. Some other examples:
$ git show master@{2} # See where the branch pointed 2, $ git show master@{3} # 3, ... changes ago. $ gitk master@{yesterday} # See where it pointed yesterday, $ gitk master@{"1 week ago"} # ... or last week $ git log --walk-reflogs master # show reflog entries for master
A separate reflog is kept for the HEAD, so
$ git show HEAD@{"1 week ago"}
will show what HEAD pointed to one week ago, not what the current branch pointed to one week ago. This allows you to see the history of what you’ve checked out.
The reflogs are kept by default for 30 days, after which they may be pruned. See git-reflog(1) and git-gc(1) to learn how to control this pruning, and see the "SPECIFYING REVISIONS" section of gitrevisions(7) for details.
Note that the reflog history is very different from normal Git history. While normal history is shared by every repository that works on the same project, the reflog history is not shared: it tells you only about how the branches in your local repository have changed over time.
In some situations the reflog may not be able to save you. For example,
suppose you delete a branch, then realize you need the history it
contained. The reflog is also deleted; however, if you have not yet
pruned the repository, then you may still be able to find the lost
commits in the dangling objects that git fsck
reports. See
the section called “Dangling objects” for the details.
$ git fsck dangling commit 7281251ddd2a61e38657c827739c57015671a6b3 dangling commit 2706a059f258c6b245f298dc4ff2ccd30ec21a63 dangling commit 13472b7c4b80851a1bc551779171dcb03655e9b5 ...
You can examine one of those dangling commits with, for example,
$ gitk 7281251ddd --not --all
which does what it sounds like: it says that you want to see the commit history that is described by the dangling commit(s), but not the history that is described by all your existing branches and tags. Thus you get exactly the history reachable from that commit that is lost. (And notice that it might not be just one commit: we only report the "tip of the line" as being dangling, but there might be a whole deep and complex commit history that was dropped.)
If you decide you want the history back, you can always create a new reference pointing to it, for example, a new branch:
$ git branch recovered-branch 7281251ddd
Other types of dangling objects (blobs and trees) are also possible, and dangling objects can arise in other situations.
Table of Contents
After you clone a repository and commit a few changes of your own, you may wish to check the original repository for updates and merge them into your own work.
We have already seen how to keep remote-tracking branches up to date with git-fetch(1), and how to merge two branches. So you can merge in changes from the original repository’s master branch with:
$ git fetch $ git merge origin/master
However, the git-pull(1) command provides a way to do this in one step:
$ git pull origin master
In fact, if you have master
checked out, then this branch has been
configured by git clone
to get changes from the HEAD branch of the
origin repository. So often you can
accomplish the above with just a simple
$ git pull
This command will fetch changes from the remote branches to your
remote-tracking branches origin/*
, and merge the default branch into
the current branch.
More generally, a branch that is created from a remote-tracking branch
will pull
by default from that branch. See the descriptions of the
branch.<name>.remote
and branch.<name>.merge
options in
git-config(1), and the discussion of the --track
option in
git-checkout(1), to learn how to control these defaults.
In addition to saving you keystrokes, git pull
also helps you by
producing a default commit message documenting the branch and
repository that you pulled from.
(But note that no such commit will be created in the case of a fast-forward; instead, your branch will just be updated to point to the latest commit from the upstream branch.)
The git pull
command can also be given .
as the "remote" repository,
in which case it just merges in a branch from the current repository; so
the commands
$ git pull . branch $ git merge branch
are roughly equivalent.
If you just have a few changes, the simplest way to submit them may just be to send them as patches in email:
First, use git-format-patch(1); for example:
$ git format-patch origin
will produce a numbered series of files in the current directory, one
for each patch in the current branch but not in origin/HEAD
.
git format-patch
can include an initial "cover letter". You can insert
commentary on individual patches after the three dash line which
format-patch
places after the commit message but before the patch
itself. If you use git notes
to track your cover letter material,
git format-patch --notes
will include the commit’s notes in a similar
manner.
You can then import these into your mail client and send them by hand. However, if you have a lot to send at once, you may prefer to use the git-send-email(1) script to automate the process. Consult the mailing list for your project first to determine their requirements for submitting patches.
Git also provides a tool called git-am(1) (am stands for
"apply mailbox"), for importing such an emailed series of patches.
Just save all of the patch-containing messages, in order, into a
single mailbox file, say patches.mbox
, then run
$ git am -3 patches.mbox
Git will apply each patch in order; if any conflicts are found, it
will stop, and you can fix the conflicts as described in
"Resolving a merge". (The -3
option tells
Git to perform a merge; if you would prefer it just to abort and
leave your tree and index untouched, you may omit that option.)
Once the index is updated with the results of the conflict resolution, instead of creating a new commit, just run
$ git am --continue
and Git will create the commit for you and continue applying the remaining patches from the mailbox.
The final result will be a series of commits, one for each patch in the original mailbox, with authorship and commit log message each taken from the message containing each patch.
Another way to submit changes to a project is to tell the maintainer
of that project to pull the changes from your repository using
git-pull(1). In the section "Getting updates with git pull
" we described this as a way to get
updates from the "main" repository, but it works just as well in the
other direction.
If you and the maintainer both have accounts on the same machine, then you can just pull changes from each other’s repositories directly; commands that accept repository URLs as arguments will also accept a local directory name:
$ git clone /path/to/repository $ git pull /path/to/other/repository
or an ssh URL:
$ git clone ssh://yourhost/~you/repository
For projects with few developers, or for synchronizing a few private repositories, this may be all you need.
However, the more common way to do this is to maintain a separate public repository (usually on a different host) for others to pull changes from. This is usually more convenient, and allows you to cleanly separate private work in progress from publicly visible work.
You will continue to do your day-to-day work in your personal repository, but periodically "push" changes from your personal repository into your public repository, allowing other developers to pull from that repository. So the flow of changes, in a situation where there is one other developer with a public repository, looks like this:
you push your personal repo ------------------> your public repo ^ | | | | you pull | they pull | | | | | they push V their public repo <------------------- their repo
We explain how to do this in the following sections.
Assume your personal repository is in the directory ~/proj
. We
first create a new clone of the repository and tell git daemon
that it
is meant to be public:
$ git clone --bare ~/proj proj.git $ touch proj.git/git-daemon-export-ok
The resulting directory proj.git contains a "bare" git repository—it is
just the contents of the .git
directory, without any files checked out
around it.
Next, copy proj.git
to the server where you plan to host the
public repository. You can use scp, rsync, or whatever is most
convenient.
This is the preferred method.
If someone else administers the server, they should tell you what
directory to put the repository in, and what git://
URL it will
appear at. You can then skip to the section
"Pushing changes to a public repository", below.
Otherwise, all you need to do is start git-daemon(1); it will
listen on port 9418. By default, it will allow access to any directory
that looks like a Git directory and contains the magic file
git-daemon-export-ok. Passing some directory paths as git daemon
arguments will further restrict the exports to those paths.
You can also run git daemon
as an inetd service; see the
git-daemon(1) man page for details. (See especially the
examples section.)
The Git protocol gives better performance and reliability, but on a host with a web server set up, HTTP exports may be simpler to set up.
All you need to do is place the newly created bare Git repository in a directory that is exported by the web server, and make some adjustments to give web clients some extra information they need:
$ mv proj.git /home/you/public_html/proj.git $ cd proj.git $ git --bare update-server-info $ mv hooks/post-update.sample hooks/post-update
(For an explanation of the last two lines, see git-update-server-info(1) and githooks(5).)
Advertise the URL of proj.git
. Anybody else should then be able to
clone or pull from that URL, for example with a command line like:
$ git clone http://yourserver.com/~you/proj.git
(See also setup-git-server-over-http for a slightly more sophisticated setup using WebDAV which also allows pushing over HTTP.)
Note that the two techniques outlined above (exporting via http or git) allow other maintainers to fetch your latest changes, but they do not allow write access, which you will need to update the public repository with the latest changes created in your private repository.
The simplest way to do this is using git-push(1) and ssh; to
update the remote branch named master
with the latest state of your
branch named master
, run
$ git push ssh://yourserver.com/~you/proj.git master:master
or just
$ git push ssh://yourserver.com/~you/proj.git master
As with git fetch
, git push
will complain if this does not result in a
fast-forward; see the following section for details on
handling this case.
Note that the target of a push
is normally a
bare repository. You can also push to a
repository that has a checked-out working tree, but a push to update the
currently checked-out branch is denied by default to prevent confusion.
See the description of the receive.denyCurrentBranch option
in git-config(1) for details.
As with git fetch
, you may also set up configuration options to
save typing; so, for example:
$ git remote add public-repo ssh://yourserver.com/~you/proj.git
adds the following to .git/config
:
[remote "public-repo"] url = yourserver.com:proj.git fetch = +refs/heads/*:refs/remotes/example/*
which lets you do the same push with just
$ git push public-repo master
See the explanations of the remote.<name>.url
,
branch.<name>.remote
, and remote.<name>.push
options in
git-config(1) for details.
If a push would not result in a fast-forward of the remote branch, then it will fail with an error like:
! [rejected] master -> master (non-fast-forward) error: failed to push some refs to '...' hint: Updates were rejected because the tip of your current branch is behind hint: its remote counterpart. Integrate the remote changes (e.g. hint: 'git pull ...') before pushing again. hint: See the 'Note about fast-forwards' in 'git push --help' for details.
This can happen, for example, if you:
git reset --hard
to remove already-published commits, or
git commit --amend
to replace already-published commits
(as in the section called “Fixing a mistake by rewriting history”), or
git rebase
to rebase any already-published commits (as
in the section called “Keeping a patch series up to date using git rebase”).
You may force git push
to perform the update anyway by preceding the
branch name with a plus sign:
$ git push ssh://yourserver.com/~you/proj.git +master
Note the addition of the +
sign. Alternatively, you can use the
-f
flag to force the remote update, as in:
$ git push -f ssh://yourserver.com/~you/proj.git master
Normally whenever a branch head in a public repository is modified, it is modified to point to a descendant of the commit that it pointed to before. By forcing a push in this situation, you break that convention. (See the section called “Problems with rewriting history”.)
Nevertheless, this is a common practice for people that need a simple way to publish a work-in-progress patch series, and it is an acceptable compromise as long as you warn other developers that this is how you intend to manage the branch.
It’s also possible for a push to fail in this way when other people have the right to push to the same repository. In that case, the correct solution is to retry the push after first updating your work: either by a pull, or by a fetch followed by a rebase; see the next section and gitcvs-migration(7) for more.
Another way to collaborate is by using a model similar to that commonly used in CVS, where several developers with special rights all push to and pull from a single shared repository. See gitcvs-migration(7) for instructions on how to set this up.
However, while there is nothing wrong with Git’s support for shared repositories, this mode of operation is not generally recommended, simply because the mode of collaboration that Git supports—by exchanging patches and pulling from public repositories—has so many advantages over the central shared repository:
git pull
provides
an easy way for that maintainer to delegate this job to other
maintainers while still allowing optional review of incoming
changes.
The gitweb cgi script provides users an easy way to browse your project’s revisions, file contents and logs without having to install Git. Features like RSS/Atom feeds and blame/annotation details may optionally be enabled.
The git-instaweb(1) command provides a simple way to start browsing the repository using gitweb. The default server when using instaweb is lighttpd.
See the file gitweb/INSTALL in the Git source tree and gitweb(1) for instructions on details setting up a permanent installation with a CGI or Perl capable server.
A shallow clone, with its truncated history, is useful when one is interested only in recent history of a project and getting full history from the upstream is expensive.
A shallow clone is created by specifying
the git-clone(1) --depth
switch. The depth can later be
changed with the git-fetch(1) --depth
switch, or full
history restored with --unshallow
.
Merging inside a shallow clone will work as long as a merge base is in the recent history. Otherwise, it will be like merging unrelated histories and may have to result in huge conflicts. This limitation may make such a repository unsuitable to be used in merge based workflows.
This describes how Tony Luck uses Git in his role as maintainer of the IA64 architecture for the Linux kernel.
He uses two public branches:
He also uses a set of temporary branches ("topic branches"), each containing a logical grouping of patches.
To set this up, first create your work tree by cloning Linus’s public tree:
$ git clone git://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git work $ cd work
Linus’s tree will be stored in the remote-tracking branch named origin/master, and can be updated using git-fetch(1); you can track other public trees using git-remote(1) to set up a "remote" and git-fetch(1) to keep them up to date; see Chapter 1, Repositories and Branches.
Now create the branches in which you are going to work; these start out
at the current tip of origin/master branch, and should be set up (using
the --track
option to git-branch(1)) to merge changes in from
Linus by default.
$ git branch --track test origin/master $ git branch --track release origin/master
These can be easily kept up to date using git-pull(1).
$ git switch test && git pull $ git switch release && git pull
Important note! If you have any local changes in these branches, then
this merge will create a commit object in the history (with no local
changes Git will simply do a "fast-forward" merge). Many people dislike
the "noise" that this creates in the Linux history, so you should avoid
doing this capriciously in the release
branch, as these noisy commits
will become part of the permanent history when you ask Linus to pull
from the release branch.
A few configuration variables (see git-config(1)) can make it easy to push both branches to your public tree. (See the section called “Setting up a public repository”.)
$ cat >> .git/config <<EOF [remote "mytree"] url = master.kernel.org:/pub/scm/linux/kernel/git/aegl/linux.git push = release push = test EOF
Then you can push both the test and release trees using git-push(1):
$ git push mytree
or push just one of the test and release branches using:
$ git push mytree test
or
$ git push mytree release
Now to apply some patches from the community. Think of a short
snappy name for a branch to hold this patch (or related group of
patches), and create a new branch from a recent stable tag of
Linus’s branch. Picking a stable base for your branch will:
1) help you: by avoiding inclusion of unrelated and perhaps lightly
tested changes
2) help future bug hunters that use git bisect
to find problems
$ git switch -c speed-up-spinlocks v2.6.35
Now you apply the patch(es), run some tests, and commit the change(s). If the patch is a multi-part series, then you should apply each as a separate commit to this branch.
$ ... patch ... test ... commit [ ... patch ... test ... commit ]*
When you are happy with the state of this change, you can merge it into the "test" branch in preparation to make it public:
$ git switch test && git merge speed-up-spinlocks
It is unlikely that you would have any conflicts here … but you might if you spent a while on this step and had also pulled new versions from upstream.
Sometime later when enough time has passed and testing done, you can pull the
same branch into the release
tree ready to go upstream. This is where you
see the value of keeping each patch (or patch series) in its own branch. It
means that the patches can be moved into the release
tree in any order.
$ git switch release && git merge speed-up-spinlocks
After a while, you will have a number of branches, and despite the well chosen names you picked for each of them, you may forget what they are for, or what status they are in. To get a reminder of what changes are in a specific branch, use:
$ git log linux..branchname | git shortlog
To see whether it has already been merged into the test or release branches, use:
$ git log test..branchname
or
$ git log release..branchname
(If this branch has not yet been merged, you will see some log entries. If it has been merged, then there will be no output.)
Once a patch completes the great cycle (moving from test to release,
then pulled by Linus, and finally coming back into your local
origin/master
branch), the branch for this change is no longer needed.
You detect this when the output from:
$ git log origin..branchname
is empty. At this point the branch can be deleted:
$ git branch -d branchname
Some changes are so trivial that it is not necessary to create a separate
branch and then merge into each of the test and release branches. For
these changes, just apply directly to the release
branch, and then
merge that into the test
branch.
After pushing your work to mytree
, you can use
git-request-pull(1) to prepare a "please pull" request message
to send to Linus:
$ git push mytree $ git request-pull origin mytree release
Here are some of the scripts that simplify all this even further.
==== update script ==== # Update a branch in my Git tree. If the branch to be updated # is origin, then pull from kernel.org. Otherwise merge # origin/master branch into test|release branch case "$1" in test|release) git checkout $1 && git pull . origin ;; origin) before=$(git rev-parse refs/remotes/origin/master) git fetch origin after=$(git rev-parse refs/remotes/origin/master) if [ $before != $after ] then git log $before..$after | git shortlog fi ;; *) echo "usage: $0 origin|test|release" 1>&2 exit 1 ;; esac
==== merge script ==== # Merge a branch into either the test or release branch pname=$0 usage() { echo "usage: $pname branch test|release" 1>&2 exit 1 } git show-ref -q --verify -- refs/heads/"$1" || { echo "Can't see branch <$1>" 1>&2 usage } case "$2" in test|release) if [ $(git log $2..$1 | wc -c) -eq 0 ] then echo $1 already merged into $2 1>&2 exit 1 fi git checkout $2 && git pull . $1 ;; *) usage ;; esac
==== status script ==== # report on status of my ia64 Git tree gb=$(tput setab 2) rb=$(tput setab 1) restore=$(tput setab 9) if [ `git rev-list test..release | wc -c` -gt 0 ] then echo $rb Warning: commits in release that are not in test $restore git log test..release fi for branch in `git show-ref --heads | sed 's|^.*/||'` do if [ $branch = test -o $branch = release ] then continue fi echo -n $gb ======= $branch ====== $restore " " status= for ref in test release origin/master do if [ `git rev-list $ref..$branch | wc -c` -gt 0 ] then status=$status${ref:0:1} fi done case $status in trl) echo $rb Need to pull into test $restore ;; rl) echo "In test" ;; l) echo "Waiting for linus" ;; "") echo $rb All done $restore ;; *) echo $rb "<$status>" $restore ;; esac git log origin/master..$branch | git shortlog done
Table of Contents
Normally commits are only added to a project, never taken away or replaced. Git is designed with this assumption, and violating it will cause Git’s merge machinery (for example) to do the wrong thing.
However, there is a situation in which it can be useful to violate this assumption.
Suppose you are a contributor to a large project, and you want to add a complicated feature, and to present it to the other developers in a way that makes it easy for them to read your changes, verify that they are correct, and understand why you made each change.
If you present all of your changes as a single patch (or commit), they may find that it is too much to digest all at once.
If you present them with the entire history of your work, complete with mistakes, corrections, and dead ends, they may be overwhelmed.
So the ideal is usually to produce a series of patches such that:
We will introduce some tools that can help you do this, explain how to use them, and then explain some of the problems that can arise because you are rewriting history.
Suppose that you create a branch mywork
on a remote-tracking branch
origin
, and create some commits on top of it:
$ git switch -c mywork origin $ vi file.txt $ git commit $ vi otherfile.txt $ git commit ...
You have performed no merges into mywork, so it is just a simple linear
sequence of patches on top of origin
:
o--o--O <-- origin \ a--b--c <-- mywork
Some more interesting work has been done in the upstream project, and
origin
has advanced:
o--o--O--o--o--o <-- origin \ a--b--c <-- mywork
At this point, you could use pull
to merge your changes back in;
the result would create a new merge commit, like this:
o--o--O--o--o--o <-- origin \ \ a--b--c--m <-- mywork
However, if you prefer to keep the history in mywork a simple series of commits without any merges, you may instead choose to use git-rebase(1):
$ git switch mywork $ git rebase origin
This will remove each of your commits from mywork, temporarily saving
them as patches (in a directory named .git/rebase-apply
), update mywork to
point at the latest version of origin, then apply each of the saved
patches to the new mywork. The result will look like:
o--o--O--o--o--o <-- origin \ a'--b'--c' <-- mywork
In the process, it may discover conflicts. In that case it will stop
and allow you to fix the conflicts; after fixing conflicts, use git add
to update the index with those contents, and then, instead of
running git commit
, just run
$ git rebase --continue
and Git will continue applying the rest of the patches.
At any point you may use the --abort
option to abort this process and
return mywork to the state it had before you started the rebase:
$ git rebase --abort
If you need to reorder or edit a number of commits in a branch, it may
be easier to use git rebase -i
, which allows you to reorder and
squash commits, as well as marking them for individual editing during
the rebase. See the section called “Using interactive rebases” for details, and
the section called “Reordering or selecting from a patch series” for alternatives.
We saw in the section called “Fixing a mistake by rewriting history” that you can replace the most recent commit using
$ git commit --amend
which will replace the old commit by a new commit incorporating your changes, giving you a chance to edit the old commit message first. This is useful for fixing typos in your last commit, or for adjusting the patch contents of a poorly staged commit.
If you need to amend commits from deeper in your history, you can
use interactive rebase’s edit
instruction.
Sometimes you want to edit a commit deeper in your history. One
approach is to use git format-patch
to create a series of patches
and then reset the state to before the patches:
$ git format-patch origin $ git reset --hard origin
Then modify, reorder, or eliminate patches as needed before applying them again with git-am(1):
$ git am *.patch
You can also edit a patch series with an interactive rebase. This is
the same as reordering a patch series using format-patch
, so use whichever interface you like best.
Rebase your current HEAD on the last commit you want to retain as-is. For example, if you want to reorder the last 5 commits, use:
$ git rebase -i HEAD~5
This will open your editor with a list of steps to be taken to perform your rebase.
pick deadbee The oneline of this commit pick fa1afe1 The oneline of the next commit ... # Rebase c0ffeee..deadbee onto c0ffeee # # Commands: # p, pick = use commit # r, reword = use commit, but edit the commit message # e, edit = use commit, but stop for amending # s, squash = use commit, but meld into previous commit # f, fixup = like "squash", but discard this commit's log message # x, exec = run command (the rest of the line) using shell # # These lines can be re-ordered; they are executed from top to bottom. # # If you remove a line here THAT COMMIT WILL BE LOST. # # However, if you remove everything, the rebase will be aborted. # # Note that empty commits are commented out
As explained in the comments, you can reorder commits, squash them together, edit commit messages, etc. by editing the list. Once you are satisfied, save the list and close your editor, and the rebase will begin.
The rebase will stop where pick
has been replaced with edit
or
when a step in the list fails to mechanically resolve conflicts and
needs your help. When you are done editing and/or resolving conflicts
you can continue with git rebase --continue
. If you decide that
things are getting too hairy, you can always bail out with git rebase
--abort
. Even after the rebase is complete, you can still recover
the original branch by using the reflog.
For a more detailed discussion of the procedure and additional tips, see the "INTERACTIVE MODE" section of git-rebase(1).
There are numerous other tools, such as StGit, which exist for the purpose of maintaining a patch series. These are outside of the scope of this manual.
The primary problem with rewriting the history of a branch has to do with merging. Suppose somebody fetches your branch and merges it into their branch, with a result something like this:
o--o--O--o--o--o <-- origin \ \ t--t--t--m <-- their branch:
Then suppose you modify the last three commits:
o--o--o <-- new head of origin / o--o--O--o--o--o <-- old head of origin
If we examined all this history together in one repository, it will look like:
o--o--o <-- new head of origin / o--o--O--o--o--o <-- old head of origin \ \ t--t--t--m <-- their branch:
Git has no way of knowing that the new head is an updated version of the old head; it treats this situation exactly the same as it would if two developers had independently done the work on the old and new heads in parallel. At this point, if someone attempts to merge the new head in to their branch, Git will attempt to merge together the two (old and new) lines of development, instead of trying to replace the old by the new. The results are likely to be unexpected.
You may still choose to publish branches whose history is rewritten, and it may be useful for others to be able to fetch those branches in order to examine or test them, but they should not attempt to pull such branches into their own work.
For true distributed development that supports proper merging, published branches should never be rewritten.
The git-bisect(1) command correctly handles history that includes merge commits. However, when the commit that it finds is a merge commit, the user may need to work harder than usual to figure out why that commit introduced a problem.
Imagine this history:
---Z---o---X---...---o---A---C---D \ / o---o---Y---...---o---B
Suppose that on the upper line of development, the meaning of one of the functions that exists at Z is changed at commit X. The commits from Z leading to A change both the function’s implementation and all calling sites that exist at Z, as well as new calling sites they add, to be consistent. There is no bug at A.
Suppose that in the meantime on the lower line of development somebody adds a new calling site for that function at commit Y. The commits from Z leading to B all assume the old semantics of that function and the callers and the callee are consistent with each other. There is no bug at B, either.
Suppose further that the two development lines merge cleanly at C, so no conflict resolution is required.
Nevertheless, the code at C is broken, because the callers added on the lower line of development have not been converted to the new semantics introduced on the upper line of development. So if all you know is that D is bad, that Z is good, and that git-bisect(1) identifies C as the culprit, how will you figure out that the problem is due to this change in semantics?
When the result of a git bisect
is a non-merge commit, you should
normally be able to discover the problem by examining just that commit.
Developers can make this easy by breaking their changes into small
self-contained commits. That won’t help in the case above, however,
because the problem isn’t obvious from examination of any single
commit; instead, a global view of the development is required. To
make matters worse, the change in semantics in the problematic
function may be just one small part of the changes in the upper
line of development.
On the other hand, if instead of merging at C you had rebased the history between Z to B on top of A, you would have gotten this linear history:
---Z---o---X--...---o---A---o---o---Y*--...---o---B*--D*
Bisecting between Z and D* would hit a single culprit commit Y*, and understanding why Y* was broken would probably be easier.
Partly for this reason, many experienced Git users, even when working on an otherwise merge-heavy project, keep the history linear by rebasing against the latest upstream version before publishing.
Table of Contents
Instead of using git-remote(1), you can also choose just to update one branch at a time, and to store it locally under an arbitrary name:
$ git fetch origin todo:my-todo-work
The first argument, origin
, just tells Git to fetch from the
repository you originally cloned from. The second argument tells Git
to fetch the branch named todo
from the remote repository, and to
store it locally under the name refs/heads/my-todo-work
.
You can also fetch branches from other repositories; so
$ git fetch git://example.com/proj.git master:example-master
will create a new branch named example-master
and store in it the
branch named master
from the repository at the given URL. If you
already have a branch named example-master, it will attempt to
fast-forward to the commit given by example.com’s
master branch. In more detail:
In the previous example, when updating an existing branch, git fetch
checks to make sure that the most recent commit on the remote
branch is a descendant of the most recent commit on your copy of the
branch before updating your copy of the branch to point at the new
commit. Git calls this process a fast-forward.
A fast-forward looks something like this:
o--o--o--o <-- old head of the branch \ o--o--o <-- new head of the branch
In some cases it is possible that the new head will not actually be a descendant of the old head. For example, the developer may have realized she made a serious mistake, and decided to backtrack, resulting in a situation like:
o--o--o--o--a--b <-- old head of the branch \ o--o--o <-- new head of the branch
In this case, git fetch
will fail, and print out a warning.
In that case, you can still force Git to update to the new head, as
described in the following section. However, note that in the
situation above this may mean losing the commits labeled a
and b
,
unless you’ve already created a reference of your own pointing to
them.
If git fetch fails because the new head of a branch is not a descendant of the old head, you may force the update with:
$ git fetch git://example.com/proj.git +master:refs/remotes/example/master
Note the addition of the +
sign. Alternatively, you can use the -f
flag to force updates of all the fetched branches, as in:
$ git fetch -f origin
Be aware that commits that the old version of example/master pointed at may be lost, as we saw in the previous section.
We saw above that origin
is just a shortcut to refer to the
repository that you originally cloned from. This information is
stored in Git configuration variables, which you can see using
git-config(1):
$ git config -l core.repositoryformatversion=0 core.filemode=true core.logallrefupdates=true remote.origin.url=git://git.kernel.org/pub/scm/git/git.git remote.origin.fetch=+refs/heads/*:refs/remotes/origin/* branch.master.remote=origin branch.master.merge=refs/heads/master
If there are other repositories that you also use frequently, you can create similar configuration options to save typing; for example,
$ git remote add example git://example.com/proj.git
adds the following to .git/config
:
[remote "example"] url = git://example.com/proj.git fetch = +refs/heads/*:refs/remotes/example/*
Also note that the above configuration can be performed by directly
editing the file .git/config
instead of using git-remote(1).
After configuring the remote, the following three commands will do the same thing:
$ git fetch git://example.com/proj.git +refs/heads/*:refs/remotes/example/* $ git fetch example +refs/heads/*:refs/remotes/example/* $ git fetch example
See git-config(1) for more details on the configuration options mentioned above and git-fetch(1) for more details on the refspec syntax.
Table of Contents
Git is built on a small number of simple but powerful ideas. While it is possible to get things done without understanding them, you will find Git much more intuitive if you do.
We start with the most important, the object database and the index.
We already saw in the section called “Understanding History: Commits” that all commits are stored under a 40-digit "object name". In fact, all the information needed to represent the history of a project is stored in objects with such names. In each case the name is calculated by taking the SHA-1 hash of the contents of the object. The SHA-1 hash is a cryptographic hash function. What that means to us is that it is impossible to find two different objects with the same name. This has a number of advantages; among others:
(See the section called “Object storage format” for the details of the object formatting and SHA-1 calculation.)
There are four different types of objects: "blob", "tree", "commit", and "tag".
The object types in some more detail:
The "commit" object links a physical state of a tree with a description
of how we got there and why. Use the --pretty=raw
option to
git-show(1) or git-log(1) to examine your favorite
commit:
$ git show -s --pretty=raw 2be7fcb476 commit 2be7fcb4764f2dbcee52635b91fedb1b3dcf7ab4 tree fb3a8bdd0ceddd019615af4d57a53f43d8cee2bf parent 257a84d9d02e90447b149af58b271c19405edb6a author Dave Watson <[email protected]> 1187576872 -0400 committer Junio C Hamano <[email protected]> 1187591163 -0700 Fix misspelling of 'suppress' in docs Signed-off-by: Junio C Hamano <[email protected]>
As you can see, a commit is defined by:
Note that a commit does not itself contain any information about what
actually changed; all changes are calculated by comparing the contents
of the tree referred to by this commit with the trees associated with
its parents. In particular, Git does not attempt to record file renames
explicitly, though it can identify cases where the existence of the same
file data at changing paths suggests a rename. (See, for example, the
-M
option to git-diff(1)).
A commit is usually created by git-commit(1), which creates a commit whose parent is normally the current HEAD, and whose tree is taken from the content currently stored in the index.
The ever-versatile git-show(1) command can also be used to examine tree objects, but git-ls-tree(1) will give you more details:
$ git ls-tree fb3a8bdd0ce 100644 blob 63c918c667fa005ff12ad89437f2fdc80926e21c .gitignore 100644 blob 5529b198e8d14decbe4ad99db3f7fb632de0439d .mailmap 100644 blob 6ff87c4664981e4397625791c8ea3bbb5f2279a3 COPYING 040000 tree 2fb783e477100ce076f6bf57e4a6f026013dc745 Documentation 100755 blob 3c0032cec592a765692234f1cba47dfdcc3a9200 GIT-VERSION-GEN 100644 blob 289b046a443c0647624607d471289b2c7dcd470b INSTALL 100644 blob 4eb463797adc693dc168b926b6932ff53f17d0b1 Makefile 100644 blob 548142c327a6790ff8821d67c2ee1eff7a656b52 README ...
As you can see, a tree object contains a list of entries, each with a mode, object type, SHA-1 name, and name, sorted by name. It represents the contents of a single directory tree.
The object type may be a blob, representing the contents of a file, or another tree, representing the contents of a subdirectory. Since trees and blobs, like all other objects, are named by the SHA-1 hash of their contents, two trees have the same SHA-1 name if and only if their contents (including, recursively, the contents of all subdirectories) are identical. This allows Git to quickly determine the differences between two related tree objects, since it can ignore any entries with identical object names.
(Note: in the presence of submodules, trees may also have commits as entries. See Chapter 8, Submodules for documentation.)
Note that the files all have mode 644 or 755: Git actually only pays attention to the executable bit.
You can use git-show(1) to examine the contents of a blob; take,
for example, the blob in the entry for COPYING
from the tree above:
$ git show 6ff87c4664 Note that the only valid version of the GPL as far as this project is concerned is _this_ particular version of the license (ie v2, not v2.2 or v3.x or whatever), unless explicitly otherwise stated. ...
A "blob" object is nothing but a binary blob of data. It doesn’t refer to anything else or have attributes of any kind.
Since the blob is entirely defined by its data, if two files in a directory tree (or in multiple different versions of the repository) have the same contents, they will share the same blob object. The object is totally independent of its location in the directory tree, and renaming a file does not change the object that file is associated with.
Note that any tree or blob object can be examined using git-show(1) with the <revision>:<path> syntax. This can sometimes be useful for browsing the contents of a tree that is not currently checked out.
If you receive the SHA-1 name of a blob from one source, and its contents from another (possibly untrusted) source, you can still trust that those contents are correct as long as the SHA-1 name agrees. This is because the SHA-1 is designed so that it is infeasible to find different contents that produce the same hash.
Similarly, you need only trust the SHA-1 name of a top-level tree object to trust the contents of the entire directory that it refers to, and if you receive the SHA-1 name of a commit from a trusted source, then you can easily verify the entire history of commits reachable through parents of that commit, and all of those contents of the trees referred to by those commits.
So to introduce some real trust in the system, the only thing you need to do is to digitally sign just one special note, which includes the name of a top-level commit. Your digital signature shows others that you trust that commit, and the immutability of the history of commits tells others that they can trust the whole history.
In other words, you can easily validate a whole archive by just sending out a single email that tells the people the name (SHA-1 hash) of the top commit, and digitally sign that email using something like GPG/PGP.
To assist in this, Git also provides the tag object…
A tag object contains an object, object type, tag name, the name of the person ("tagger") who created the tag, and a message, which may contain a signature, as can be seen using git-cat-file(1):
$ git cat-file tag v1.5.0 object 437b1b20df4b356c9342dac8d38849f24ef44f27 type commit tag v1.5.0 tagger Junio C Hamano <[email protected]> 1171411200 +0000 GIT 1.5.0 -----BEGIN PGP SIGNATURE----- Version: GnuPG v1.4.6 (GNU/Linux) iD8DBQBF0lGqwMbZpPMRm5oRAuRiAJ9ohBLd7s2kqjkKlq1qqC57SbnmzQCdG4ui nLE/L9aUXdWeTFPron96DLA= =2E+0 -----END PGP SIGNATURE-----
See the git-tag(1) command to learn how to create and verify tag
objects. (Note that git-tag(1) can also be used to create
"lightweight tags", which are not tag objects at all, but just simple
references whose names begin with refs/tags/
).
Newly created objects are initially created in a file named after the
object’s SHA-1 hash (stored in .git/objects
).
Unfortunately this system becomes inefficient once a project has a lot of objects. Try this on an old project:
$ git count-objects 6930 objects, 47620 kilobytes
The first number is the number of objects which are kept in individual files. The second is the amount of space taken up by those "loose" objects.
You can save space and make Git faster by moving these loose objects in to a "pack file", which stores a group of objects in an efficient compressed format; the details of how pack files are formatted can be found in pack format.
To put the loose objects into a pack, just run git repack:
$ git repack Counting objects: 6020, done. Delta compression using up to 4 threads. Compressing objects: 100% (6020/6020), done. Writing objects: 100% (6020/6020), done. Total 6020 (delta 4070), reused 0 (delta 0)
This creates a single "pack file" in .git/objects/pack/ containing all currently unpacked objects. You can then run
$ git prune
to remove any of the "loose" objects that are now contained in the
pack. This will also remove any unreferenced objects (which may be
created when, for example, you use git reset
to remove a commit).
You can verify that the loose objects are gone by looking at the
.git/objects
directory or by running
$ git count-objects 0 objects, 0 kilobytes
Although the object files are gone, any commands that refer to those objects will work exactly as they did before.
The git-gc(1) command performs packing, pruning, and more for you, so is normally the only high-level command you need.
The git-fsck(1) command will sometimes complain about dangling objects. They are not a problem.
The most common cause of dangling objects is that you’ve rebased a branch, or you have pulled from somebody else who rebased a branch—see Chapter 5, Rewriting history and maintaining patch series. In that case, the old head of the original branch still exists, as does everything it pointed to. The branch pointer itself just doesn’t, since you replaced it with another one.
There are also other situations that cause dangling objects. For
example, a "dangling blob" may arise because you did a git add
of a
file, but then, before you actually committed it and made it part of the
bigger picture, you changed something else in that file and committed
that updated thing—the old state that you added originally ends up
not being pointed to by any commit or tree, so it’s now a dangling blob
object.
Similarly, when the "recursive" merge strategy runs, and finds that there are criss-cross merges and thus more than one merge base (which is fairly unusual, but it does happen), it will generate one temporary midway tree (or possibly even more, if you had lots of criss-crossing merges and more than two merge bases) as a temporary internal merge base, and again, those are real objects, but the end result will not end up pointing to them, so they end up "dangling" in your repository.
Generally, dangling objects aren’t anything to worry about. They can even be very useful: if you screw something up, the dangling objects can be how you recover your old tree (say, you did a rebase, and realized that you really didn’t want to—you can look at what dangling objects you have, and decide to reset your head to some old dangling state).
For commits, you can just use:
$ gitk <dangling-commit-sha-goes-here> --not --all
This asks for all the history reachable from the given commit but not from any branch, tag, or other reference. If you decide it’s something you want, you can always create a new reference to it, e.g.,
$ git branch recovered-branch <dangling-commit-sha-goes-here>
For blobs and trees, you can’t do the same, but you can still examine them. You can just do
$ git show <dangling-blob/tree-sha-goes-here>
to show what the contents of the blob were (or, for a tree, basically
what the ls
for that directory was), and that may give you some idea
of what the operation was that left that dangling object.
Usually, dangling blobs and trees aren’t very interesting. They’re
almost always the result of either being a half-way mergebase (the blob
will often even have the conflict markers from a merge in it, if you
have had conflicting merges that you fixed up by hand), or simply
because you interrupted a git fetch
with ^C or something like that,
leaving some of the new objects in the object database, but just
dangling and useless.
Anyway, once you are sure that you’re not interested in any dangling state, you can just prune all unreachable objects:
$ git prune
and they’ll be gone. (You should only run git prune
on a quiescent
repository—it’s kind of like doing a filesystem fsck recovery: you
don’t want to do that while the filesystem is mounted.
git prune
is designed not to cause any harm in such cases of concurrent
accesses to a repository but you might receive confusing or scary messages.)
By design, Git treats data trusted to it with caution. However, even in the absence of bugs in Git itself, it is still possible that hardware or operating system errors could corrupt data.
The first defense against such problems is backups. You can back up a Git directory using clone, or just using cp, tar, or any other backup mechanism.
As a last resort, you can search for the corrupted objects and attempt to replace them by hand. Back up your repository before attempting this in case you corrupt things even more in the process.
We’ll assume that the problem is a single missing or corrupted blob, which is sometimes a solvable problem. (Recovering missing trees and especially commits is much harder).
Before starting, verify that there is corruption, and figure out where it is with git-fsck(1); this may be time-consuming.
Assume the output looks like this:
$ git fsck --full --no-dangling broken link from tree 2d9263c6d23595e7cb2a21e5ebbb53655278dff8 to blob 4b9458b3786228369c63936db65827de3cc06200 missing blob 4b9458b3786228369c63936db65827de3cc06200
Now you know that blob 4b9458b3 is missing, and that the tree 2d9263c6
points to it. If you could find just one copy of that missing blob
object, possibly in some other repository, you could move it into
.git/objects/4b/9458b3...
and be done. Suppose you can’t. You can
still examine the tree that pointed to it with git-ls-tree(1),
which might output something like:
$ git ls-tree 2d9263c6d23595e7cb2a21e5ebbb53655278dff8 100644 blob 8d14531846b95bfa3564b58ccfb7913a034323b8 .gitignore 100644 blob ebf9bf84da0aab5ed944264a5db2a65fe3a3e883 .mailmap 100644 blob ca442d313d86dc67e0a2e5d584b465bd382cbf5c COPYING ... 100644 blob 4b9458b3786228369c63936db65827de3cc06200 myfile ...
So now you know that the missing blob was the data for a file named
myfile
. And chances are you can also identify the directory—let’s
say it’s in somedirectory
. If you’re lucky the missing copy might be
the same as the copy you have checked out in your working tree at
somedirectory/myfile
; you can test whether that’s right with
git-hash-object(1):
$ git hash-object -w somedirectory/myfile
which will create and store a blob object with the contents of somedirectory/myfile, and output the SHA-1 of that object. if you’re extremely lucky it might be 4b9458b3786228369c63936db65827de3cc06200, in which case you’ve guessed right, and the corruption is fixed!
Otherwise, you need more information. How do you tell which version of the file has been lost?
The easiest way to do this is with:
$ git log --raw --all --full-history -- somedirectory/myfile
Because you’re asking for raw output, you’ll now get something like
commit abc Author: Date: ... :100644 100644 4b9458b newsha M somedirectory/myfile commit xyz Author: Date: ... :100644 100644 oldsha 4b9458b M somedirectory/myfile
This tells you that the immediately following version of the file was "newsha", and that the immediately preceding version was "oldsha". You also know the commit messages that went with the change from oldsha to 4b9458b and with the change from 4b9458b to newsha.
If you’ve been committing small enough changes, you may now have a good shot at reconstructing the contents of the in-between state 4b9458b.
If you can do that, you can now recreate the missing object with
$ git hash-object -w <recreated-file>
and your repository is good again!
(Btw, you could have ignored the fsck
, and started with doing a
$ git log --raw --all
and just looked for the sha of the missing object (4b9458b) in that whole thing. It’s up to you—Git does have a lot of information, it is just missing one particular blob version.
The index is a binary file (generally kept in .git/index
) containing a
sorted list of path names, each with permissions and the SHA-1 of a blob
object; git-ls-files(1) can show you the contents of the index:
$ git ls-files --stage 100644 63c918c667fa005ff12ad89437f2fdc80926e21c 0 .gitignore 100644 5529b198e8d14decbe4ad99db3f7fb632de0439d 0 .mailmap 100644 6ff87c4664981e4397625791c8ea3bbb5f2279a3 0 COPYING 100644 a37b2152bd26be2c2289e1f57a292534a51a93c7 0 Documentation/.gitignore 100644 fbefe9a45b00a54b58d94d06eca48b03d40a50e0 0 Documentation/Makefile ... 100644 2511aef8d89ab52be5ec6a5e46236b4b6bcd07ea 0 xdiff/xtypes.h 100644 2ade97b2574a9f77e7ae4002a4e07a6a38e46d07 0 xdiff/xutils.c 100644 d5de8292e05e7c36c4b68857c1cf9855e3d2f70a 0 xdiff/xutils.h
Note that in older documentation you may see the index called the "current directory cache" or just the "cache". It has three important properties:
The index contains all the information necessary to generate a single (uniquely determined) tree object.
For example, running git-commit(1) generates this tree object from the index, stores it in the object database, and uses it as the tree object associated with the new commit.
The index enables fast comparisons between the tree object it defines and the working tree.
It does this by storing some additional data for each entry (such as the last modified time). This data is not displayed above, and is not stored in the created tree object, but it can be used to determine quickly which files in the working directory differ from what was stored in the index, and thus save Git from having to read all of the data from such files to look for changes.
It can efficiently represent information about merge conflicts between different tree objects, allowing each pathname to be associated with sufficient information about the trees involved that you can create a three-way merge between them.
We saw in the section called “Getting conflict-resolution help during a merge” that during a merge the index can store multiple versions of a single file (called "stages"). The third column in the git-ls-files(1) output above is the stage number, and will take on values other than 0 for files with merge conflicts.
The index is thus a sort of temporary staging area, which is filled with a tree which you are in the process of working on.
If you blow the index away entirely, you generally haven’t lost any information as long as you have the name of the tree that it described.
Table of Contents
Large projects are often composed of smaller, self-contained modules. For example, an embedded Linux distribution’s source tree would include every piece of software in the distribution with some local modifications; a movie player might need to build against a specific, known-working version of a decompression library; several independent programs might all share the same build scripts.
With centralized revision control systems this is often accomplished by including every module in one single repository. Developers can check out all modules or only the modules they need to work with. They can even modify files across several modules in a single commit while moving things around or updating APIs and translations.
Git does not allow partial checkouts, so duplicating this approach in Git would force developers to keep a local copy of modules they are not interested in touching. Commits in an enormous checkout would be slower than you’d expect as Git would have to scan every directory for changes. If modules have a lot of local history, clones would take forever.
On the plus side, distributed revision control systems can much better integrate with external sources. In a centralized model, a single arbitrary snapshot of the external project is exported from its own revision control and then imported into the local revision control on a vendor branch. All the history is hidden. With distributed revision control you can clone the entire external history and much more easily follow development and re-merge local changes.
Git’s submodule support allows a repository to contain, as a subdirectory, a checkout of an external project. Submodules maintain their own identity; the submodule support just stores the submodule repository location and commit ID, so other developers who clone the containing project ("superproject") can easily clone all the submodules at the same revision. Partial checkouts of the superproject are possible: you can tell Git to clone none, some or all of the submodules.
The git-submodule(1) command is available since Git 1.5.3. Users with Git 1.5.2 can look up the submodule commits in the repository and manually check them out; earlier versions won’t recognize the submodules at all.
To see how submodule support works, create four example repositories that can be used later as a submodule:
$ mkdir ~/git $ cd ~/git $ for i in a b c d do mkdir $i cd $i git init echo "module $i" > $i.txt git add $i.txt git commit -m "Initial commit, submodule $i" cd .. done
Now create the superproject and add all the submodules:
$ mkdir super $ cd super $ git init $ for i in a b c d do git submodule add ~/git/$i $i done
Do not use local URLs here if you plan to publish your superproject!
See what files git submodule
created:
$ ls -a . .. .git .gitmodules a b c d
The git submodule add <repo> <path>
command does a couple of things:
<repo>
to the given <path>
under the
current directory and by default checks out the master branch.
Commit the superproject:
$ git commit -m "Add submodules a, b, c and d."
Now clone the superproject:
$ cd .. $ git clone super cloned $ cd cloned
The submodule directories are there, but they’re empty:
$ ls -a a . .. $ git submodule status -d266b9873ad50488163457f025db7cdd9683d88b a -e81d457da15309b4fef4249aba9b50187999670d b -c1536a972b9affea0f16e0680ba87332dc059146 c -d96249ff5d57de5de093e6baff9e0aafa5276a74 d
The commit object names shown above would be different for you, but they
should match the HEAD commit object names of your repositories. You can check
it by running git ls-remote ../a
.
Pulling down the submodules is a two-step process. First run git submodule
init
to add the submodule repository URLs to .git/config
:
$ git submodule init
Now use git submodule update
to clone the repositories and check out the
commits specified in the superproject:
$ git submodule update $ cd a $ ls -a . .. .git a.txt
One major difference between git submodule update
and git submodule add
is
that git submodule update
checks out a specific commit, rather than the tip
of a branch. It’s like checking out a tag: the head is detached, so you’re not
working on a branch.
$ git branch * (detached from d266b98) master
If you want to make a change within a submodule and you have a detached head, then you should create or checkout a branch, make your changes, publish the change within the submodule, and then update the superproject to reference the new commit:
$ git switch master
or
$ git switch -c fix-up
then
$ echo "adding a line again" >> a.txt $ git commit -a -m "Updated the submodule from within the superproject." $ git push $ cd .. $ git diff diff --git a/a b/a index d266b98..261dfac 160000 --- a/a +++ b/a @@ -1 +1 @@ -Subproject commit d266b9873ad50488163457f025db7cdd9683d88b +Subproject commit 261dfac35cb99d380eb966e102c1197139f7fa24 $ git add a $ git commit -m "Updated submodule a." $ git push
You have to run git submodule update
after git pull
if you want to update
submodules, too.
Always publish the submodule change before publishing the change to the superproject that references it. If you forget to publish the submodule change, others won’t be able to clone the repository:
$ cd ~/git/super/a $ echo i added another line to this file >> a.txt $ git commit -a -m "doing it wrong this time" $ cd .. $ git add a $ git commit -m "Updated submodule a again." $ git push $ cd ~/git/cloned $ git pull $ git submodule update error: pathspec '261dfac35cb99d380eb966e102c1197139f7fa24' did not match any file(s) known to git. Did you forget to 'git add'? Unable to checkout '261dfac35cb99d380eb966e102c1197139f7fa24' in submodule path 'a'
In older Git versions it could be easily forgotten to commit new or modified
files in a submodule, which silently leads to similar problems as not pushing
the submodule changes. Starting with Git 1.7.0 both git status
and git diff
in the superproject show submodules as modified when they contain new or
modified files to protect against accidentally committing such a state. git
diff
will also add a -dirty
to the work tree side when generating patch
output or used with the --submodule
option:
$ git diff diff --git a/sub b/sub --- a/sub +++ b/sub @@ -1 +1 @@ -Subproject commit 3f356705649b5d566d97ff843cf193359229a453 +Subproject commit 3f356705649b5d566d97ff843cf193359229a453-dirty $ git diff --submodule Submodule sub 3f35670..3f35670-dirty:
You also should not rewind branches in a submodule beyond commits that were ever recorded in any superproject.
It’s not safe to run git submodule update
if you’ve made and committed
changes within a submodule without checking out a branch first. They will be
silently overwritten:
$ cat a.txt module a $ echo line added from private2 >> a.txt $ git commit -a -m "line added inside private2" $ cd .. $ git submodule update Submodule path 'a': checked out 'd266b9873ad50488163457f025db7cdd9683d88b' $ cd a $ cat a.txt module a
The changes are still visible in the submodule’s reflog.
If you have uncommitted changes in your submodule working tree, git
submodule update
will not overwrite them. Instead, you get the usual
warning about not being able switch from a dirty branch.
Table of Contents
Many of the higher-level commands were originally implemented as shell scripts using a smaller core of low-level Git commands. These can still be useful when doing unusual things with Git, or just as a way to understand its inner workings.
The git-cat-file(1) command can show the contents of any object, though the higher-level git-show(1) is usually more useful.
The git-commit-tree(1) command allows constructing commits with arbitrary parents and trees.
A tree can be created with git-write-tree(1) and its data can be accessed by git-ls-tree(1). Two trees can be compared with git-diff-tree(1).
A tag is created with git-mktag(1), and the signature can be verified by git-verify-tag(1), though it is normally simpler to use git-tag(1) for both.
High-level operations such as git-commit(1) and git-restore(1) work by moving data between the working tree, the index, and the object database. Git provides low-level operations which perform each of these steps individually.
Generally, all Git operations work on the index file. Some operations work purely on the index file (showing the current state of the index), but most operations move data between the index file and either the database or the working directory. Thus there are four main combinations:
The git-update-index(1) command updates the index with information from the working directory. You generally update the index information by just specifying the filename you want to update, like so:
$ git update-index filename
but to avoid common mistakes with filename globbing etc., the command will not normally add totally new entries or remove old entries, i.e. it will normally just update existing cache entries.
To tell Git that yes, you really do realize that certain files no
longer exist, or that new files should be added, you
should use the --remove
and --add
flags respectively.
NOTE! A --remove
flag does not mean that subsequent filenames will
necessarily be removed: if the files still exist in your directory
structure, the index will be updated with their new status, not
removed. The only thing --remove
means is that update-index will be
considering a removed file to be a valid thing, and if the file really
does not exist any more, it will update the index accordingly.
As a special case, you can also do git update-index --refresh
, which
will refresh the "stat" information of each index to match the current
stat information. It will not update the object status itself, and
it will only update the fields that are used to quickly test whether
an object still matches its old backing store object.
The previously introduced git-add(1) is just a wrapper for git-update-index(1).
You write your current index file to a "tree" object with the program
$ git write-tree
that doesn’t come with any options—it will just write out the current index into the set of tree objects that describe that state, and it will return the name of the resulting top-level tree. You can use that tree to re-generate the index at any time by going in the other direction:
You read a "tree" file from the object database, and use that to populate (and overwrite—don’t do this if your index contains any unsaved state that you might want to restore later!) your current index. Normal operation is just
$ git read-tree <SHA-1 of tree>
and your index file will now be equivalent to the tree that you saved earlier. However, that is only your index file: your working directory contents have not been modified.
You update your working directory from the index by "checking out"
files. This is not a very common operation, since normally you’d just
keep your files updated, and rather than write to your working
directory, you’d tell the index files about the changes in your
working directory (i.e. git update-index
).
However, if you decide to jump to a new version, or check out somebody else’s version, or just restore a previous tree, you’d populate your index file with read-tree, and then you need to check out the result with
$ git checkout-index filename
or, if you want to check out all of the index, use -a
.
NOTE! git checkout-index
normally refuses to overwrite old files, so
if you have an old version of the tree already checked out, you will
need to use the -f
flag (before the -a
flag or the filename) to
force the checkout.
Finally, there are a few odds and ends which are not purely moving from one representation to the other:
To commit a tree you have instantiated with git write-tree
, you’d
create a "commit" object that refers to that tree and the history
behind it—most notably the "parent" commits that preceded it in
history.
Normally a "commit" has one parent: the previous state of the tree before a certain change was made. However, sometimes it can have two or more parent commits, in which case we call it a "merge", due to the fact that such a commit brings together ("merges") two or more previous states represented by other commits.
In other words, while a "tree" represents a particular directory state of a working directory, a "commit" represents that state in time, and explains how we got there.
You create a commit object by giving it the tree that describes the state at the time of the commit, and a list of parents:
$ git commit-tree <tree> -p <parent> [(-p <parent2>)...]
and then giving the reason for the commit on stdin (either through redirection from a pipe or file, or by just typing it at the tty).
git commit-tree
will return the name of the object that represents
that commit, and you should save it away for later use. Normally,
you’d commit 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 pointed at by .git/HEAD
, so that we can always see
what the last committed state was.
Here is a picture that illustrates how various pieces fit together:
commit-tree commit obj +----+ | | | | V V +-----------+ | Object DB | | Backing | | Store | +-----------+ ^ write-tree | | tree obj | | | | read-tree | | tree obj V +-----------+ | Index | | "cache" | +-----------+ update-index ^ blob obj | | | | checkout-index -u | | checkout-index stat | | blob obj V +-----------+ | Working | | Directory | +-----------+
You can examine the data represented in the object database and the index with various helper tools. For every object, you can use git-cat-file(1) to examine details about the object:
$ git cat-file -t <objectname>
shows the type of the object, and once you have the type (which is usually implicit in where you find the object), you can use
$ git cat-file blob|tree|commit|tag <objectname>
to show its contents. NOTE! Trees have binary content, and as a result
there is a special helper for showing that content, called
git ls-tree
, which turns the binary content into a more easily
readable form.
It’s especially instructive to look at "commit" objects, since those
tend to be small and fairly self-explanatory. In particular, if you
follow the convention of having the top commit name in .git/HEAD
,
you can do
$ git cat-file commit HEAD
to see what the top commit was.
Git can help you perform a three-way merge, which can in turn be used for a many-way merge by repeating the merge procedure several times. The usual situation is that you only do one three-way merge (reconciling two lines of history) and commit the result, but if you like to, you can merge several branches in one go.
To perform a three-way merge, you start with the two commits you want to merge, find their closest common parent (a third commit), and compare the trees corresponding to these three commits.
To get the "base" for the merge, look up the common parent of two commits:
$ git merge-base <commit1> <commit2>
This prints the name of a commit they are both based on. You should now look up the tree objects of those commits, which you can easily do with
$ git cat-file commit <commitname> | head -1
since the tree object information is always the first line in a commit object.
Once you know the three trees you are going to merge (the one "original" tree, aka the common tree, and the two "result" trees, aka the branches you want to merge), you do a "merge" read into the index. This will complain if it has to throw away your old index contents, so you should make sure that you’ve committed those—in fact you would normally always do a merge against your last commit (which should thus match what you have in your current index anyway).
To do the merge, do
$ git read-tree -m -u <origtree> <yourtree> <targettree>
which will do all trivial merge operations for you directly in the
index file, and you can just write the result out with
git write-tree
.
Sadly, many merges aren’t trivial. If there are files that have been added, moved or removed, or if both branches have modified the same file, you will be left with an index tree that contains "merge entries" in it. Such an index tree can NOT be written out to a tree object, and you will have to resolve any such merge clashes using other tools before you can write out the result.
You can examine such index state with git ls-files --unmerged
command. An example:
$ git read-tree -m $orig HEAD $target $ git ls-files --unmerged 100644 263414f423d0e4d70dae8fe53fa34614ff3e2860 1 hello.c 100644 06fa6a24256dc7e560efa5687fa84b51f0263c3a 2 hello.c 100644 cc44c73eb783565da5831b4d820c962954019b69 3 hello.c
Each line of the git ls-files --unmerged
output begins with
the blob mode bits, blob SHA-1, stage number, and the
filename. The stage number is Git’s way to say which tree it
came from: stage 1 corresponds to the $orig
tree, stage 2 to
the HEAD
tree, and stage 3 to the $target
tree.
Earlier we said that trivial merges are done inside
git read-tree -m
. For example, if the file did not change
from $orig
to HEAD
or $target
, or if the file changed
from $orig
to HEAD
and $orig
to $target
the same way,
obviously the final outcome is what is in HEAD
. What the
above example shows is that file hello.c
was changed from
$orig
to HEAD
and $orig
to $target
in a different way.
You could resolve this by running your favorite 3-way merge
program, e.g. diff3
, merge
, or Git’s own merge-file, on
the blob objects from these three stages yourself, like this:
$ git cat-file blob 263414f >hello.c~1 $ git cat-file blob 06fa6a2 >hello.c~2 $ git cat-file blob cc44c73 >hello.c~3 $ git merge-file hello.c~2 hello.c~1 hello.c~3
This would leave the merge result in hello.c~2
file, along
with conflict markers if there are conflicts. After verifying
the merge result makes sense, you can tell Git what the final
merge result for this file is by:
$ mv -f hello.c~2 hello.c $ git update-index hello.c
When a path is in the "unmerged" state, running git update-index
for
that path tells Git to mark the path resolved.
The above is the description of a Git merge at the lowest level,
to help you understand what conceptually happens under the hood.
In practice, nobody, not even Git itself, runs git cat-file
three times
for this. There is a git merge-index
program that extracts the
stages to temporary files and calls a "merge" script on it:
$ git merge-index git-merge-one-file hello.c
and that is what higher level git merge -s resolve
is implemented with.
Table of Contents
This chapter covers internal details of the Git implementation which probably only Git developers need to understand.
All objects have a statically determined "type" which identifies the format of the object (i.e. how it is used, and how it can refer to other objects). There are currently four different object types: "blob", "tree", "commit", and "tag".
Regardless of object type, all objects share the following
characteristics: they are all deflated with zlib, and have a header
that not only specifies their type, but also provides size information
about the data in the object. It’s worth noting that the SHA-1 hash
that is used to name the object is the hash of the original data
plus this header, so sha1sum
file does not match the object name
for file.
As a result, the general consistency of an object can always be tested
independently of the contents or the type of the object: all objects can
be validated by verifying that (a) their hashes match the content of the
file and (b) the object successfully inflates to a stream of bytes that
forms a sequence of
<ascii type without space> + <space> + <ascii decimal size> +
<byte\0> + <binary object data>
.
The structured objects can further have their structure and
connectivity to other objects verified. This is generally done with
the git fsck
program, which generates a full dependency graph
of all objects, and verifies their internal consistency (in addition
to just verifying their superficial consistency through the hash).
It is not always easy for new developers to find their way through Git’s source code. This section gives you a little guidance to show where to start.
A good place to start is with the contents of the initial commit, with:
$ git switch --detach e83c5163
The initial revision lays the foundation for almost everything Git has today, but is small enough to read in one sitting.
Note that terminology has changed since that revision. For example, the README in that revision uses the word "changeset" to describe what we now call a commit.
Also, we do not call it "cache" any more, but rather "index"; however, the
file is still called cache.h
. Remark: Not much reason to change it now,
especially since there is no good single name for it anyway, because it is
basically the header file which is included by all of Git’s C sources.
If you grasp the ideas in that initial commit, you should check out a
more recent version and skim cache.h
, object.h
and commit.h
.
In the early days, Git (in the tradition of UNIX) was a bunch of programs which were extremely simple, and which you used in scripts, piping the output of one into another. This turned out to be good for initial development, since it was easier to test new things. However, recently many of these parts have become builtins, and some of the core has been "libified", i.e. put into libgit.a for performance, portability reasons, and to avoid code duplication.
By now, you know what the index is (and find the corresponding data
structures in cache.h
), and that there are just a couple of object types
(blobs, trees, commits and tags) which inherit their common structure from
struct object
, which is their first member (and thus, you can cast e.g.
(struct object *)commit
to achieve the same as &commit->object
, i.e.
get at the object name and flags).
Now is a good point to take a break to let this information sink in.
Next step: get familiar with the object naming. Read the section called “Naming commits”.
There are quite a few ways to name an object (and not only revisions!).
All of these are handled in sha1_name.c
. Just have a quick look at
the function get_sha1()
. A lot of the special handling is done by
functions like get_sha1_basic()
or the likes.
This is just to get you into the groove for the most libified part of Git: the revision walker.
Basically, the initial version of git log
was a shell script:
$ git-rev-list --pretty $(git-rev-parse --default HEAD "$@") | \ LESS=-S ${PAGER:-less}
What does this mean?
git rev-list
is the original version of the revision walker, which
always printed a list of revisions to stdout. It is still functional,
and needs to, since most new Git commands start out as scripts using
git rev-list
.
git rev-parse
is not as important any more; it was only used to filter out
options that were relevant for the different plumbing commands that were
called by the script.
Most of what git rev-list
did is contained in revision.c
and
revision.h
. It wraps the options in a struct named rev_info
, which
controls how and what revisions are walked, and more.
The original job of git rev-parse
is now taken by the function
setup_revisions()
, which parses the revisions and the common command-line
options for the revision walker. This information is stored in the struct
rev_info
for later consumption. You can do your own command-line option
parsing after calling setup_revisions()
. After that, you have to call
prepare_revision_walk()
for initialization, and then you can get the
commits one by one with the function get_revision()
.
If you are interested in more details of the revision walking process,
just have a look at the first implementation of cmd_log()
; call
git show v1.3.0~155^2~4
and scroll down to that function (note that you
no longer need to call setup_pager()
directly).
Nowadays, git log
is a builtin, which means that it is contained in the
command git
. The source side of a builtin is
cmd_<bla>
, typically defined in builtin/<bla.c>
(note that older versions of Git used to have it in builtin-<bla>.c
instead), and declared in builtin.h
.
commands[]
array in git.c
, and
BUILTIN_OBJECTS
in the Makefile
.
Sometimes, more than one builtin is contained in one source file. For
example, cmd_whatchanged()
and cmd_log()
both reside in builtin/log.c
,
since they share quite a bit of code. In that case, the commands which are
not named like the .c
file in which they live have to be listed in
BUILT_INS
in the Makefile
.
git log
looks more complicated in C than it does in the original script,
but that allows for a much greater flexibility and performance.
Here again it is a good point to take a pause.
Lesson three is: study the code. Really, it is the best way to learn about the organization of Git (after you know the basic concepts).
So, think about something which you are interested in, say, "how can I
access a blob just knowing the object name of it?". The first step is to
find a Git command with which you can do it. In this example, it is either
git show
or git cat-file
.
For the sake of clarity, let’s stay with git cat-file
, because it
cat-file.c
, was renamed to builtin/cat-file.c
when made a builtin, and then saw less than 10 versions).
So, look into builtin/cat-file.c
, search for cmd_cat_file()
and look what
it does.
git_config(git_default_config); if (argc != 3) usage("git cat-file [-t|-s|-e|-p|<type>] <sha1>"); if (get_sha1(argv[2], sha1)) die("Not a valid object name %s", argv[2]);
Let’s skip over the obvious details; the only really interesting part
here is the call to get_sha1()
. It tries to interpret argv[2]
as an
object name, and if it refers to an object which is present in the current
repository, it writes the resulting SHA-1 into the variable sha1
.
Two things are interesting here:
get_sha1()
returns 0 on success. This might surprise some new
Git hackers, but there is a long tradition in UNIX to return different
negative numbers in case of different errors—and 0 on success.
sha1
in the function signature of get_sha1()
is unsigned
char *
, but is actually expected to be a pointer to unsigned
char[20]
. This variable will contain the 160-bit SHA-1 of the given
commit. Note that whenever a SHA-1 is passed as unsigned char *
, it
is the binary representation, as opposed to the ASCII representation in
hex characters, which is passed as char *
.
You will see both of these things throughout the code.
Now, for the meat:
case 0: buf = read_object_with_reference(sha1, argv[1], &size, NULL);
This is how you read a blob (actually, not only a blob, but any type of
object). To know how the function read_object_with_reference()
actually
works, find the source code for it (something like git grep
read_object_with | grep ":[a-z]"
in the Git repository), and read
the source.
To find out how the result can be used, just read on in cmd_cat_file()
:
write_or_die(1, buf, size);
Sometimes, you do not know where to look for a feature. In many such cases,
it helps to search through the output of git log
, and then git show
the
corresponding commit.
Example: If you know that there was some test case for git bundle
, but
do not remember where it was (yes, you could git grep bundle t/
, but that
does not illustrate the point!):
$ git log --no-merges t/
In the pager (less
), just search for "bundle", go a few lines back,
and see that it is in commit 18449ab0. Now just copy this object name,
and paste it into the command line
$ git show 18449ab0
Voila.
Another example: Find out what to do in order to make some script a builtin:
$ git log --no-merges --diff-filter=A builtin/*.c
You see, Git is actually the best tool to find out about the source of Git itself!
Table of Contents
.git
suffix that does not
have a locally checked-out copy of any of the files under
revision control. That is, all of the Git
administrative and control files that would normally be present in the
hidden .git
sub-directory are directly present in the
repository.git
directory instead,
and no other files are present and checked out. Usually publishers of
public repositories make bare repositories available.
As a noun: A single point in the Git history; the entire history of a project is represented as a set of interrelated commits. The word "commit" is often used by Git in the same places other revision control systems use the words "revision" or "version". Also used as a short hand for commit object.
As a verb: The action of storing a new snapshot of the project’s state in the Git history, by creating a new commit representing the current state of the index and advancing HEAD to point at the new commit.
Normally the HEAD stores the name of a branch, and commands that operate on the history HEAD represents operate on the history leading to the tip of the branch the HEAD points at. However, Git also allows you to check out an arbitrary commit that isn’t necessarily the tip of any particular branch. The HEAD in such a state is called "detached".
Note that commands that operate on the history of the current branch
(e.g. git commit
to build a new history on top of it) still work
while the HEAD is detached. They update the HEAD to point at the tip
of the updated history without affecting any branch. Commands that
update or inquire information about the current branch (e.g. git
branch --set-upstream-to
that sets what remote-tracking branch the
current branch integrates with) obviously do not work, as there is no
(real) current branch to ask about in this state.
.git
at the root of a working tree that
points at the directory that is the real repository.
Grafts enables two otherwise different lines of development to be joined
together by recording fake ancestry information for commits. This way
you can make Git pretend the set of parents a commit has
is different from what was recorded when the commit was
created. Configured via the .git/info/grafts
file.
Note that the grafts mechanism is outdated and can lead to problems transferring objects between repositories; see git-replace(1) for a more flexible and robust system to do the same thing.
$GIT_DIR/refs/heads/
directory, except when using packed refs. (See
git-pack-refs(1).)
$GIT_DIR/hooks/
directory, and are enabled by simply
removing the .sample
suffix from the filename. In earlier versions
of Git you had to make them executable.
As a verb: To bring the contents of another branch (possibly from an external repository) into the current branch. In the case where the merged-in branch is from a different repository, this is done by first fetching the remote branch and then merging the result into the current branch. This combination of fetch and merge operations is called a pull. Merging is performed by an automatic process that identifies changes made since the branches diverged, and then applies all those changes together. In cases where changes conflict, manual intervention may be required to complete the merge.
As a noun: unless it is a fast-forward, a successful merge results in the creation of a new commit representing the result of the merge, and having as parents the tips of the merged branches. This commit is referred to as a "merge commit", or sometimes just a "merge".
$GIT_DIR/objects/
.
git branch -r
.
Pattern used to limit paths in Git commands.
Pathspecs are used on the command line of "git ls-files", "git ls-tree", "git add", "git grep", "git diff", "git checkout", and many other commands to limit the scope of operations to some subset of the tree or worktree. See the documentation of each command for whether paths are relative to the current directory or toplevel. The pathspec syntax is as follows:
For example, Documentation/*.jpg will match all .jpg files in the Documentation subtree, including Documentation/chapter_1/figure_1.jpg.
A pathspec that begins with a colon :
has special meaning. In the
short form, the leading colon :
is followed by zero or more "magic
signature" letters (which optionally is terminated by another colon :
),
and the remainder is the pattern to match against the path.
The "magic signature" consists of ASCII symbols that are neither
alphanumeric, glob, regex special characters nor colon.
The optional colon that terminates the "magic signature" can be
omitted if the pattern begins with a character that does not belong to
"magic signature" symbol set and is not a colon.
In the long form, the leading colon :
is followed by an open
parenthesis (
, a comma-separated list of zero or more "magic words",
and a close parentheses )
, and the remainder is the pattern to match
against the path.
A pathspec with only a colon means "there is no pathspec". This form should not be combined with other pathspec.
top
(magic signature: /
) makes the pattern
match from the root of the working tree, even when you are
running the command from inside a subdirectory.
*
or ?
are treated
as literal characters.
Git treats the pattern as a shell glob suitable for consumption by fnmatch(3) with the FNM_PATHNAME flag: wildcards in the pattern will not match a / in the pathname. For example, "Documentation/*.html" matches "Documentation/git.html" but not "Documentation/ppc/ppc.html" or "tools/perf/Documentation/perf.html".
Two consecutive asterisks ("**
") in patterns matched against
full pathname may have special meaning:
**
" followed by a slash means match in all
directories. For example, "**/foo
" matches file or directory
"foo
" anywhere, the same as pattern "foo
". "**/foo/bar
"
matches file or directory "bar
" anywhere that is directly
under directory "foo
".
/**
" matches everything inside. For example,
"abc/**
" matches all files inside directory "abc", relative
to the location of the .gitignore
file, with infinite depth.
a/**/b
"
matches "a/b
", "a/x/b
", "a/x/y/b
" and so on.
Other consecutive asterisks are considered invalid.
Glob magic is incompatible with literal magic.
After attr:
comes a space separated list of "attribute
requirements", all of which must be met in order for the
path to be considered a match; this is in addition to the
usual non-magic pathspec pattern matching.
See gitattributes(5).
Each of the attribute requirements for the path takes one of these forms:
ATTR
" requires that the attribute ATTR
be set.
-ATTR
" requires that the attribute ATTR
be unset.
ATTR=VALUE
" requires that the attribute ATTR
be
set to the string VALUE
.
"!ATTR
" requires that the attribute ATTR
be
unspecified.
Note that when matching against a tree object, attributes are still obtained from working tree, not from the given tree object.
!
or its
synonym ^
). If it matches, the path is ignored. When there
is no non-exclude pathspec, the exclusion is applied to the
result set as if invoked without any pathspec.
--pickaxe-all
option, it can be used to view the full
changeset that introduced or removed, say, a
particular line of text. See git-diff(1).
refs/bisect/
, but might later include other
unusual refs.
$GIT_DIR
which behave
like refs for the purposes of rev-parse, but which are treated
specially by git. Pseudorefs both have names that are all-caps,
and always start with a line consisting of a
SHA-1 followed by whitespace. So, HEAD is not a
pseudoref, because it is sometimes a symbolic ref. They might
optionally contain some additional data. MERGE_HEAD
and
CHERRY_PICK_HEAD
are examples. Unlike
per-worktree refs, these files cannot
be symbolic refs, and never have reflogs. They also cannot be
updated through the normal ref update machinery. Instead,
they are updated by directly writing to the files. However,
they can be read as if they were refs, so git rev-parse
MERGE_HEAD
will work.
A name that begins with refs/
(e.g. refs/heads/master
)
that points to an object name or another
ref (the latter is called a symbolic ref).
For convenience, a ref can sometimes be abbreviated when used
as an argument to a Git command; see gitrevisions(7)
for details.
Refs are stored in the repository.
The ref namespace is hierarchical.
Different subhierarchies are used for different purposes (e.g. the
refs/heads/
hierarchy is used to represent local branches).
There are a few special-purpose refs that do not begin with refs/
.
The most notable example is HEAD
.
git clone --depth=...
command.
--depth
option to git-clone(1), and
its history can be later deepened with git-fetch(1).
refs/tags/
namespace that points to an
object of an arbitrary type (typically a tag points to either a
tag or a commit object).
In contrast to a head, a tag is not updated by
the commit
command. A Git tag has nothing to do with a Lisp
tag (which would be called an object type
in Git’s context). A tag is most typically used to mark a particular
point in the commit ancestry chain.
Table of Contents
This is a quick summary of the major commands; the previous chapters explain how these work in more detail.
From a tarball:
$ tar xzf project.tar.gz $ cd project $ git init Initialized empty Git repository in .git/ $ git add . $ git commit
From a remote repository:
$ git clone git://example.com/pub/project.git $ cd project
$ git branch # list all local branches in this repo $ git switch test # switch working directory to branch "test" $ git branch new # create branch "new" starting at current HEAD $ git branch -d new # delete branch "new"
Instead of basing a new branch on current HEAD (the default), use:
$ git branch new test # branch named "test" $ git branch new v2.6.15 # tag named v2.6.15 $ git branch new HEAD^ # commit before the most recent $ git branch new HEAD^^ # commit before that $ git branch new test~10 # ten commits before tip of branch "test"
Create and switch to a new branch at the same time:
$ git switch -c new v2.6.15
Update and examine branches from the repository you cloned from:
$ git fetch # update $ git branch -r # list origin/master origin/next ... $ git switch -c masterwork origin/master
Fetch a branch from a different repository, and give it a new name in your repository:
$ git fetch git://example.com/project.git theirbranch:mybranch $ git fetch git://example.com/project.git v2.6.15:mybranch
Keep a list of repositories you work with regularly:
$ git remote add example git://example.com/project.git $ git remote # list remote repositories example origin $ git remote show example # get details * remote example URL: git://example.com/project.git Tracked remote branches master next ... $ git fetch example # update branches from example $ git branch -r # list all remote branches
$ gitk # visualize and browse history $ git log # list all commits $ git log src/ # ...modifying src/ $ git log v2.6.15..v2.6.16 # ...in v2.6.16, not in v2.6.15 $ git log master..test # ...in branch test, not in branch master $ git log test..master # ...in branch master, but not in test $ git log test...master # ...in one branch, not in both $ git log -S'foo()' # ...where difference contain "foo()" $ git log --since="2 weeks ago" $ git log -p # show patches as well $ git show # most recent commit $ git diff v2.6.15..v2.6.16 # diff between two tagged versions $ git diff v2.6.15..HEAD # diff with current head $ git grep "foo()" # search working directory for "foo()" $ git grep v2.6.15 "foo()" # search old tree for "foo()" $ git show v2.6.15:a.txt # look at old version of a.txt
Search for regressions:
$ git bisect start $ git bisect bad # current version is bad $ git bisect good v2.6.13-rc2 # last known good revision Bisecting: 675 revisions left to test after this # test here, then: $ git bisect good # if this revision is good, or $ git bisect bad # if this revision is bad. # repeat until done.
Make sure Git knows who to blame:
$ cat >>~/.gitconfig <<\EOF [user] name = Your Name Comes Here email = [email protected] EOF
Select file contents to include in the next commit, then make the commit:
$ git add a.txt # updated file $ git add b.txt # new file $ git rm c.txt # old file $ git commit
Or, prepare and create the commit in one step:
$ git commit d.txt # use latest content only of d.txt $ git commit -a # use latest content of all tracked files
$ git merge test # merge branch "test" into the current branch $ git pull git://example.com/project.git master # fetch and merge in remote branch $ git pull . test # equivalent to git merge test
Importing or exporting patches:
$ git format-patch origin..HEAD # format a patch for each commit # in HEAD but not in origin $ git am mbox # import patches from the mailbox "mbox"
Fetch a branch in a different Git repository, then merge into the current branch:
$ git pull git://example.com/project.git theirbranch
Store the fetched branch into a local branch before merging into the current branch:
$ git pull git://example.com/project.git theirbranch:mybranch
After creating commits on a local branch, update the remote branch with your commits:
$ git push ssh://example.com/project.git mybranch:theirbranch
When remote and local branch are both named "test":
$ git push ssh://example.com/project.git test
Shortcut version for a frequently used remote repository:
$ git remote add example ssh://example.com/project.git $ git push example test
Table of Contents
This is a work in progress.
The basic requirements:
git am
command"
Think about how to create a clear chapter dependency graph that will allow people to get to important topics without necessarily reading everything in between.
Scan Documentation/
for other stuff left out; in particular:
technical/
?
Scan email archives for other stuff left out
Scan man pages to see if any assume more background than this manual provides.
Add more good examples. Entire sections of just cookbook examples might be a good idea; maybe make an "advanced examples" section a standard end-of-chapter section?
Include cross-references to the glossary, where appropriate.
Add a section on working with other version control systems, including CVS, Subversion, and just imports of series of release tarballs.
Write a chapter on using plumbing and writing scripts.
Alternates, clone -reference, etc.
More on recovery from repository corruption. See: https://lore.kernel.org/git/[email protected]/ https://lore.kernel.org/git/[email protected]/