PEP 103 – Collecting information about git
- Author:
- Oleg Broytman <phd at phdru.name>
- Status:
- Withdrawn
- Type:
- Informational
- Created:
- 01-Jun-2015
- Post-History:
- 12-Sep-2015
Table of Contents
- Withdrawal
- Abstract
- Documentation
- Quick start
- Examples in this PEP
- Branches and branches
- Remote repositories and remote branches
- Commit editing and caveats
- Undo
- Merge or rebase?
- Null-merges
- Branching models
- Advanced configuration
- Advanced topics
- Tips and tricks
- git on server
- From Mercurial to git
- Git and GitHub
- Copyright
Withdrawal
This PEP was withdrawn as it’s too generic and doesn’t really deals with Python development. It is no longer updated.
The content was moved to Python Wiki. Make further updates in the wiki.
Abstract
This Informational PEP collects information about git. There is, of course, a lot of documentation for git, so the PEP concentrates on more complex (and more related to Python development) issues, scenarios and examples.
The plan is to extend the PEP in the future collecting information about equivalence of Mercurial and git scenarios to help migrating Python development from Mercurial to git.
The author of the PEP doesn’t currently plan to write a Process PEP on migration Python development from Mercurial to git.
Documentation
Git is accompanied with a lot of documentation, both online and offline.
Documentation for starters
Git User’s manual. Everyday GIT With 20 Commands Or So. Git workflows.
Advanced documentation
Git Magic, with a number of translations.
Pro Git. The Book about git. Buy it at Amazon or download in PDF, mobi, or ePub form. It has translations to many different languages. Download Russian translation from GArik.
Git Buch (German).
Offline documentation
Git has builtin help: run git help $TOPIC
. For example, run
git help git
or git help help
.
Quick start
Download and installation
Unix users: download and install using your package manager.
Microsoft Windows: download git-for-windows.
MacOS X: use git installed with XCode or download from MacPorts or
git-osx-installer or
install git with Homebrew: brew install git
.
git-cola (repository) is a Git GUI written in Python and GPL licensed. Linux, Windows, MacOS X.
TortoiseGit is a Windows Shell Interface to Git based on TortoiseSVN; open source.
Initial configuration
This simple code is often appears in documentation, but it is important so let repeat it here. Git stores author and committer names/emails in every commit, so configure your real name and preferred email:
$ git config --global user.name "User Name"
$ git config --global user.email user.name@example.org
Examples in this PEP
Examples of git commands in this PEP use the following approach. It is
supposed that you, the user, works with a local repository named
python
that has an upstream remote repo named origin
. Your
local repo has two branches v1
and master
. For most examples
the currently checked out branch is master
. That is, it’s assumed
you have done something like that:
$ git clone https://git.python.org/python.git
$ cd python
$ git branch v1 origin/v1
The first command clones remote repository into local directory
python
, creates a new local branch master, sets
remotes/origin/master as its upstream remote-tracking branch and
checks it out into the working directory.
The last command creates a new local branch v1 and sets remotes/origin/v1 as its upstream remote-tracking branch.
The same result can be achieved with commands:
$ git clone -b v1 https://git.python.org/python.git
$ cd python
$ git checkout --track origin/master
The last command creates a new local branch master, sets remotes/origin/master as its upstream remote-tracking branch and checks it out into the working directory.
Branches and branches
Git terminology can be a bit misleading. Take, for example, the term “branch”. In git it has two meanings. A branch is a directed line of commits (possibly with merges). And a branch is a label or a pointer assigned to a line of commits. It is important to distinguish when you talk about commits and when about their labels. Lines of commits are by itself unnamed and are usually only lengthening and merging. Labels, on the other hand, can be created, moved, renamed and deleted freely.
Remote repositories and remote branches
Remote-tracking branches are branches (pointers to commits) in your
local repository. They are there for git (and for you) to remember
what branches and commits have been pulled from and pushed to what
remote repos (you can pull from and push to many remotes).
Remote-tracking branches live under remotes/$REMOTE
namespaces,
e.g. remotes/origin/master
.
To see the status of remote-tracking branches run:
$ git branch -rv
To see local and remote-tracking branches (and tags) pointing to commits:
$ git log --decorate
You never do your own development on remote-tracking branches. You create a local branch that has a remote branch as upstream and do development on that local branch. On push git pushes commits to the remote repo and updates remote-tracking branches, on pull git fetches commits from the remote repo, updates remote-tracking branches and fast-forwards, merges or rebases local branches.
When you do an initial clone like this:
$ git clone -b v1 https://git.python.org/python.git
git clones remote repository https://git.python.org/python.git
to
directory python
, creates a remote named origin
, creates
remote-tracking branches, creates a local branch v1
, configure it
to track upstream remotes/origin/v1 branch and checks out v1
into
the working directory.
Some commands, like git status --branch
and git branch --verbose
,
report the difference between local and remote branches.
Please remember they only do comparison with remote-tracking branches
in your local repository, and the state of those remote-tracking
branches can be outdated. To update remote-tracking branches you
either fetch and merge (or rebase) commits from the remote repository
or update remote-tracking branches without updating local branches.
Updating local and remote-tracking branches
To update remote-tracking branches without updating local branches run
git remote update [$REMOTE...]
. For example:
$ git remote update
$ git remote update origin
Fetch and pull
There is a major difference between
$ git fetch $REMOTE $BRANCH
and
$ git fetch $REMOTE $BRANCH:$BRANCH
The first command fetches commits from the named $BRANCH in the $REMOTE repository that are not in your repository, updates remote-tracking branch and leaves the id (the hash) of the head commit in file .git/FETCH_HEAD.
The second command fetches commits from the named $BRANCH in the $REMOTE repository that are not in your repository and updates both the local branch $BRANCH and its upstream remote-tracking branch. But it refuses to update branches in case of non-fast-forward. And it refuses to update the current branch (currently checked out branch, where HEAD is pointing to).
The first command is used internally by git pull
.
$ git pull $REMOTE $BRANCH
is equivalent to
$ git fetch $REMOTE $BRANCH
$ git merge FETCH_HEAD
Certainly, $BRANCH in that case should be your current branch. If you want to merge a different branch into your current branch first update that non-current branch and then merge:
$ git fetch origin v1:v1 # Update v1
$ git pull --rebase origin master # Update the current branch master
# using rebase instead of merge
$ git merge v1
If you have not yet pushed commits on v1
, though, the scenario has
to become a bit more complex. Git refuses to update
non-fast-forwardable branch, and you don’t want to do force-pull
because that would remove your non-pushed commits and you would need
to recover. So you want to rebase v1
but you cannot rebase
non-current branch. Hence, checkout v1
and rebase it before
merging:
$ git checkout v1
$ git pull --rebase origin v1
$ git checkout master
$ git pull --rebase origin master
$ git merge v1
It is possible to configure git to make it fetch/pull a few branches or all branches at once, so you can simply run
$ git pull origin
or even
$ git pull
Default remote repository for fetching/pulling is origin
. Default
set of references to fetch is calculated using matching algorithm: git
fetches all branches having the same name on both ends.
Push
Pushing is a bit simpler. There is only one command push
. When you
run
$ git push origin v1 master
git pushes local v1 to remote v1 and local master to remote master. The same as:
$ git push origin v1:v1 master:master
Git pushes commits to the remote repo and updates remote-tracking branches. Git refuses to push commits that aren’t fast-forwardable. You can force-push anyway, but please remember - you can force-push to your own repositories but don’t force-push to public or shared repos. If you find git refuses to push commits that aren’t fast-forwardable, better fetch and merge commits from the remote repo (or rebase your commits on top of the fetched commits), then push. Only force-push if you know what you do and why you do it. See the section Commit editing and caveats below.
It is possible to configure git to make it push a few branches or all branches at once, so you can simply run
$ git push origin
or even
$ git push
Default remote repository for pushing is origin
. Default set of
references to push in git before 2.0 is calculated using matching
algorithm: git pushes all branches having the same name on both ends.
Default set of references to push in git 2.0+ is calculated using
simple algorithm: git pushes the current branch back to its
@{upstream}.
To configure git before 2.0 to the new behaviour run:
$ git config push.default simple
To configure git 2.0+ to the old behaviour run:
$ git config push.default matching
Git doesn’t allow to push a branch if it’s the current branch in the remote non-bare repository: git refuses to update remote working directory. You really should push only to bare repositories. For non-bare repositories git prefers pull-based workflow.
When you want to deploy code on a remote host and can only use push (because your workstation is behind a firewall and you cannot pull from it) you do that in two steps using two repositories: you push from the workstation to a bare repo on the remote host, ssh to the remote host and pull from the bare repo to a non-bare deployment repo.
That changed in git 2.3, but see the blog post for caveats; in 2.4 the push-to-deploy feature was further improved.
Private information
When cloning/fetching/pulling/pushing git copies only database objects (commits, trees, files and tags) and symbolic references (branches and lightweight tags). Everything else is private to the repository and never cloned, updated or pushed. It’s your config, your hooks, your private exclude file.
If you want to distribute hooks, copy them to the working tree, add, commit, push and instruct the team to update and install the hooks manually.
Commit editing and caveats
A warning not to edit published (pushed) commits also appears in documentation but it’s repeated here anyway as it’s very important.
It is possible to recover from a forced push but it’s PITA for the entire team. Please avoid it.
To see what commits have not been published yet compare the head of the branch with its upstream remote-tracking branch:
$ git log origin/master.. # from origin/master to HEAD (of master)
$ git log origin/v1..v1 # from origin/v1 to the head of v1
For every branch that has an upstream remote-tracking branch git maintains an alias @{upstream} (short version @{u}), so the commands above can be given as:
$ git log @{u}..
$ git log v1@{u}..v1
To see the status of all branches:
$ git branch -avv
To compare the status of local branches with a remote repo:
$ git remote show origin
Read how to recover from upstream rebase.
It is in git help rebase
.
On the other hand, don’t be too afraid about commit editing. You can safely edit, reorder, remove, combine and split commits that haven’t been pushed yet. You can even push commits to your own (backup) repo, edit them later and force-push edited commits to replace what have already been pushed. Not a problem until commits are in a public or shared repository.
Undo
Whatever you do, don’t panic. Almost anything in git can be undone.
git checkout: restore file’s content
git checkout
, for example, can be used to restore the content of
file(s) to that one of a commit. Like this:
git checkout HEAD~ README
The commands restores the contents of README file to the last but one
commit in the current branch. By default the commit ID is simply HEAD;
i.e. git checkout README
restores README to the latest commit.
(Do not use git checkout
to view a content of a file in a commit,
use git cat-file -p
; e.g. git cat-file -p HEAD~:path/to/README
).
git reset: remove (non-pushed) commits
git reset
moves the head of the current branch. The head can be
moved to point to any commit but it’s often used to remove a commit or
a few (preferably, non-pushed ones) from the top of the branch - that
is, to move the branch backward in order to undo a few (non-pushed)
commits.
git reset
has three modes of operation - soft, hard and mixed.
Default is mixed. ProGit explains the
difference very clearly. Bare repositories don’t have indices or
working trees so in a bare repo only soft reset is possible.
Unstaging
Mixed mode reset with a path or paths can be used to unstage changes -
that is, to remove from index changes added with git add
for
committing. See The Book for details
about unstaging and other undo tricks.
git reflog: reference log
Removing commits with git reset
or moving the head of a branch
sounds dangerous and it is. But there is a way to undo: another
reset back to the original commit. Git doesn’t remove commits
immediately; unreferenced commits (in git terminology they are called
“dangling commits”) stay in the database for some time (default is two
weeks) so you can reset back to it or create a new branch pointing to
the original commit.
For every move of a branch’s head - with git commit
, git
checkout
, git fetch
, git pull
, git rebase
, git reset
and so on - git stores a reference log (reflog for short). For every
move git stores where the head was. Command git reflog
can be used
to view (and manipulate) the log.
In addition to the moves of the head of every branch git stores the
moves of the HEAD - a symbolic reference that (usually) names the
current branch. HEAD is changed with git checkout $BRANCH
.
By default git reflog
shows the moves of the HEAD, i.e. the
command is equivalent to git reflog HEAD
. To show the moves of the
head of a branch use the command git reflog $BRANCH
.
So to undo a git reset
lookup the original commit in git
reflog
, verify it with git show
or git log
and run git
reset $COMMIT_ID
. Git stores the move of the branch’s head in
reflog, so you can undo that undo later again.
In a more complex situation you’d want to move some commits along with
resetting the head of the branch. Cherry-pick them to the new branch.
For example, if you want to reset the branch master
back to the
original commit but preserve two commits created in the current branch
do something like:
$ git branch save-master # create a new branch saving master
$ git reflog # find the original place of master
$ git reset $COMMIT_ID
$ git cherry-pick save-master~ save-master
$ git branch -D save-master # remove temporary branch
git revert: revert a commit
git revert
reverts a commit or commits, that is, it creates a new
commit or commits that revert(s) the effects of the given commits.
It’s the only way to undo published commits (git commit --amend
,
git rebase
and git reset
change the branch in
non-fast-forwardable ways so they should only be used for non-pushed
commits.)
There is a problem with reverting a merge commit. git revert
can
undo the code created by the merge commit but it cannot undo the fact
of merge. See the discussion How to revert a faulty merge.
One thing that cannot be undone
Whatever you undo, there is one thing that cannot be undone - overwritten uncommitted changes. Uncommitted changes don’t belong to git so git cannot help preserving them.
Most of the time git warns you when you’re going to execute a command
that overwrites uncommitted changes. Git doesn’t allow you to switch
branches with git checkout
. It stops you when you’re going to
rebase with non-clean working tree. It refuses to pull new commits
over non-committed files.
But there are commands that do exactly that - overwrite files in the
working tree. Commands like git checkout $PATHs
or git reset
--hard
silently overwrite files including your uncommitted changes.
With that in mind you can understand the stance “commit early, commit
often”. Commit as often as possible. Commit on every save in your
editor or IDE. You can edit your commits before pushing - edit commit
messages, change commits, reorder, combine, split, remove. But save
your changes in git database, either commit changes or at least stash
them with git stash
.
Merge or rebase?
Internet is full of heated discussions on the topic: “merge or rebase?” Most of them are meaningless. When a DVCS is being used in a big team with a big and complex project with many branches there is simply no way to avoid merges. So the question’s diminished to “whether to use rebase, and if yes - when to use rebase?” Considering that it is very much recommended not to rebase published commits the question’s diminished even further: “whether to use rebase on non-pushed commits?”
That small question is for the team to decide. To preserve the beauty
of linear history it’s recommended to use rebase when pulling, i.e. do
git pull --rebase
or even configure automatic setup of rebase for
every new branch:
$ git config branch.autosetuprebase always
and configure rebase for existing branches:
$ git config branch.$NAME.rebase true
For example:
$ git config branch.v1.rebase true
$ git config branch.master.rebase true
After that git pull origin master
becomes equivalent to git pull
--rebase origin master
.
It is recommended to create new commits in a separate feature or topic branch while using rebase to update the mainline branch. When the topic branch is ready merge it into mainline. To avoid a tedious task of resolving large number of conflicts at once you can merge the topic branch to the mainline from time to time and switch back to the topic branch to continue working on it. The entire workflow would be something like:
$ git checkout -b issue-42 # create a new issue branch and switch to it
...edit/test/commit...
$ git checkout master
$ git pull --rebase origin master # update master from the upstream
$ git merge issue-42
$ git branch -d issue-42 # delete the topic branch
$ git push origin master
When the topic branch is deleted only the label is removed, commits are stayed in the database, they are now merged into master:
o--o--o--o--o--M--< master - the mainline branch
\ /
--*--*--* - the topic branch, now unnamed
The topic branch is deleted to avoid cluttering branch namespace with small topic branches. Information on what issue was fixed or what feature was implemented should be in the commit messages.
But even that small amount of rebasing could be too big in case of
long-lived merged branches. Imagine you’re doing work in both v1
and master
branches, regularly merging v1
into master
.
After some time you will have a lot of merge and non-merge commits in
master
. Then you want to push your finished work to a shared
repository and find someone has pushed a few commits to v1
. Now
you have a choice of two equally bad alternatives: either you fetch
and rebase v1
and then have to recreate all you work in master
(reset master
to the origin, merge v1
and cherry-pick all
non-merge commits from the old master); or merge the new v1
and
loose the beauty of linear history.
Null-merges
Git has a builtin merge strategy for what Python core developers call “null-merge”:
$ git merge -s ours v1 # null-merge v1 into master
Branching models
Git doesn’t assume any particular development model regarding branching and merging. Some projects prefer to graduate patches from the oldest branch to the newest, some prefer to cherry-pick commits backwards, some use squashing (combining a number of commits into one). Anything is possible.
There are a few examples to start with. git help workflows describes how the very git authors develop git.
ProGit book has a few chapters devoted to branch management in different projects: Git Branching - Branching Workflows and Distributed Git - Contributing to a Project.
There is also a well-known article A successful Git branching model by Vincent Driessen. It recommends a set of very detailed rules on creating and managing mainline, topic and bugfix branches. To support the model the author implemented git flow extension.
Advanced configuration
Line endings
Git has builtin mechanisms to handle line endings between platforms
with different end-of-line styles. To allow git to do CRLF conversion
assign text
attribute to files using .gitattributes.
For files that have to have specific line endings assign eol
attribute. For binary files the attribute is, naturally, binary
.
For example:
$ cat .gitattributes
*.py text
*.txt text
*.png binary
/readme.txt eol=CRLF
To check what attributes git uses for files use git check-attr
command. For example:
$ git check-attr -a -- \*.py
Useful assets
GitAlias (repository) is a big collection of aliases. A careful selection of aliases for frequently used commands could save you a lot of keystrokes!
GitIgnore and
https://github.com/github/gitignore are collections of .gitignore
files for all kinds of IDEs and programming languages. Python
included!
pre-commit (repositories) is a framework for managing and maintaining multi-language pre-commit hooks. The framework is written in Python and has a lot of plugins for many programming languages.
Advanced topics
Staging area
Staging area aka index aka cache is a distinguishing feature of git. Staging area is where git collects patches before committing them. Separation between collecting patches and commit phases provides a very useful feature of git: you can review collected patches before commit and even edit them - remove some hunks, add new hunks and review again.
To add files to the index use git add
. Collecting patches before
committing means you need to do that for every change, not only to add
new (untracked) files. To simplify committing in case you just want to
commit everything without reviewing run git commit --all
(or just
-a
) - the command adds every changed tracked file to the index and
then commit. To commit a file or files regardless of patches collected
in the index run git commit [--only|-o] -- $FILE...
.
To add hunks of patches to the index use git add --patch
(or just
-p
). To remove collected files from the index use git reset HEAD
-- $FILE...
To add/inspect/remove collected hunks use git add
--interactive
(-i
).
To see the diff between the index and the last commit (i.e., collected
patches) use git diff --cached
. To see the diff between the
working tree and the index (i.e., uncollected patches) use just git
diff
. To see the diff between the working tree and the last commit
(i.e., both collected and uncollected patches) run git diff HEAD
.
See WhatIsTheIndex and IndexCommandQuickref in Git Wiki.
Root
Git switches to the root (top-level directory of the project where
.git
subdirectory exists) before running any command. Git
remembers though the directory that was current before the switch.
Some programs take into account the current directory. E.g., git
status
shows file paths of changed and unknown files relative to the
current directory; git grep
searches below the current directory;
git apply
applies only those hunks from the patch that touch files
below the current directory.
But most commands run from the root and ignore the current directory.
Imagine, for example, that you have two work trees, one for the branch
v1
and the other for master
. If you want to merge v1
from
a subdirectory inside the second work tree you must write commands as
if you’re in the top-level dir. Let take two work trees,
project-v1
and project
, for example:
$ cd project/subdirectory
$ git fetch ../project-v1 v1:v1
$ git merge v1
Please note the path in git fetch ../project-v1 v1:v1
is
../project-v1
and not ../../project-v1
despite the fact that
we run the commands from a subdirectory, not from the root.
ReReRe
Rerere is a mechanism that helps to resolve repeated merge conflicts. The most frequent source of recurring merge conflicts are topic branches that are merged into mainline and then the merge commits are removed; that’s often performed to test the topic branches and train rerere; merge commits are removed to have clean linear history and finish the topic branch with only one last merge commit.
Rerere works by remembering the states of tree before and after a successful commit. That way rerere can automatically resolve conflicts if they appear in the same files.
Rerere can be used manually with git rerere
command but most often
it’s used automatically. Enable rerere with these commands in a
working tree:
$ git config rerere.enabled true
$ git config rerere.autoupdate true
You don’t need to turn rerere on globally - you don’t want rerere in bare repositories or single-branch repositories; you only need rerere in repos where you often perform merges and resolve merge conflicts.
See Rerere in The Book.
Database maintenance
Git object database and other files/directories under .git
require
periodic maintenance and cleanup. For example, commit editing left
unreferenced objects (dangling objects, in git terminology) and these
objects should be pruned to avoid collecting cruft in the DB. The
command git gc
is used for maintenance. Git automatically runs
git gc --auto
as a part of some commands to do quick maintenance.
Users are recommended to run git gc --aggressive
from time to
time; git help gc
recommends to run it every few hundred
changesets; for more intensive projects it should be something like
once a week and less frequently (biweekly or monthly) for lesser
active projects.
git gc --aggressive
not only removes dangling objects, it also
repacks object database into indexed and better optimized pack(s); it
also packs symbolic references (branches and tags). Another way to do
it is to run git repack
.
There is a well-known message from Linus
Torvalds regarding “stupidity” of git gc --aggressive
. The message
can safely be ignored now. It is old and outdated, git gc
--aggressive
became much better since that time.
For those who still prefer git repack
over git gc --aggressive
the recommended parameters are git repack -a -d -f --depth=20
--window=250
. See this detailed experiment
for explanation of the effects of these parameters.
From time to time run git fsck [--strict]
to verify integrity of
the database. git fsck
may produce a list of dangling objects;
that’s not an error, just a reminder to perform regular maintenance.
Tips and tricks
Command-line options and arguments
git help cli
recommends not to combine short options/flags. Most of the times
combining works: git commit -av
works perfectly, but there are
situations when it doesn’t. E.g., git log -p -5
cannot be combined
as git log -p5
.
Some options have arguments, some even have default arguments. In that
case the argument for such option must be spelled in a sticky way:
-Oarg
, never -O arg
because for an option that has a default
argument the latter means “use default value for option -O
and
pass arg
further to the option parser”. For example, git grep
has an option -O
that passes a list of names of the found files to
a program; default program for -O
is a pager (usually less
),
but you can use your editor:
$ git grep -Ovim # but not -O vim
BTW, if git is instructed to use less
as the pager (i.e., if pager
is not configured in git at all it uses less
by default, or if it
gets less
from GIT_PAGER or PAGER environment variables, or if it
was configured with git config [--global] core.pager less
, or
less
is used in the command git grep -Oless
) git grep
passes +/$pattern
option to less
which is quite convenient.
Unfortunately, git grep
doesn’t pass the pattern if the pager is
not exactly less
, even if it’s less
with parameters (something
like git config [--global] core.pager less -FRSXgimq
); fortunately,
git grep -Oless
always passes the pattern.
bash/zsh completion
It’s a bit hard to type git rebase --interactive --preserve-merges
HEAD~5
manually even for those who are happy to use command-line,
and this is where shell completion is of great help. Bash/zsh come
with programmable completion, often automatically installed and
enabled, so if you have bash/zsh and git installed, chances are you
are already done - just go and use it at the command-line.
If you don’t have necessary bits installed, install and enable bash_completion package. If you want to upgrade your git completion to the latest and greatest download necessary file from git contrib.
Git-for-windows comes with git-bash for which bash completion is installed and enabled.
bash/zsh prompt
For command-line lovers shell prompt can carry a lot of useful information. To include git information in the prompt use git-prompt.sh. Read the detailed instructions in the file.
Search the Net for “git prompt” to find other prompt variants.
SSH connection sharing
SSH connection sharing is a feature of OpenSSH and perhaps derivatives like PuTTY. SSH connection sharing is a way to decrease ssh client startup time by establishing one connection and reusing it for all subsequent clients connecting to the same server. SSH connection sharing can be used to speedup a lot of short ssh sessions like scp, sftp, rsync and of course git over ssh. If you regularly fetch/pull/push from/to remote repositories accessible over ssh then using ssh connection sharing is recommended.
To turn on ssh connection sharing add something like this to your ~/.ssh/config:
Host *
ControlMaster auto
ControlPath ~/.ssh/mux-%r@%h:%p
ControlPersist 600
See OpenSSH wikibook and search for more information.
SSH connection sharing can be used at GitHub, GitLab and SourceForge repositories, but please be advised that BitBucket doesn’t allow it and forcibly closes master connection after a short inactivity period so you will see errors like this from ssh: “Connection to bitbucket.org closed by remote host.”
git on server
The simplest way to publish a repository or a group of repositories is
git daemon
. The daemon provides anonymous access, by default it is
read-only. The repositories are accessible by git protocol (git://
URLs). Write access can be enabled but the protocol lacks any
authentication means, so it should be enabled only within a trusted
LAN. See git help daemon
for details.
Git over ssh provides authentication and repo-level authorisation as
repositories can be made user- or group-writeable (see parameter
core.sharedRepository
in git help config
). If that’s too
permissive or too restrictive for some project’s needs there is a
wrapper gitolite that can
be configured to allow access with great granularity; gitolite is
written in Perl and has a lot of documentation.
Web interface to browse repositories can be created using gitweb or cgit. Both are CGI scripts (written in Perl and C). In addition to web interface both provide read-only dumb http access for git (http(s):// URLs). Klaus is a small and simple WSGI web server that implements both web interface and git smart HTTP transport; supports Python 2 and Python 3, performs syntax highlighting.
There are also more advanced web-based development environments that include ability to manage users, groups and projects; private, group-accessible and public repositories; they often include issue trackers, wiki pages, pull requests and other tools for development and communication. Among these environments are Kallithea and pagure, both are written in Python; pagure was written by Fedora developers and is being used to develop some Fedora projects. GitPrep is yet another GitHub clone, written in Perl. Gogs is written in Go. GitBucket is written in Scala.
And last but not least, GitLab. It’s perhaps the most advanced web-based development environment for git. Written in Ruby, community edition is free and open source (MIT license).
From Mercurial to git
There are many tools to convert Mercurial repositories to git. The
most famous are, probably, hg-git and
fast-export (many years ago
it was known under the name hg2git
).
But a better tool, perhaps the best, is git-remote-hg. It provides transparent bidirectional (pull and push) access to Mercurial repositories from git. Its author wrote a comparison of alternatives that seems to be mostly objective.
To use git-remote-hg, install or clone it, add to your PATH (or copy
script git-remote-hg
to a directory that’s already in PATH) and
prepend hg::
to Mercurial URLs. For example:
$ git clone https://github.com/felipec/git-remote-hg.git
$ PATH=$PATH:"`pwd`"/git-remote-hg
$ git clone hg::https://hg.python.org/peps/ PEPs
To work with the repository just use regular git commands including
git fetch/pull/push
.
To start converting your Mercurial habits to git see the page Mercurial for Git users at Mercurial wiki. At the second half of the page there is a table that lists corresponding Mercurial and git commands. Should work perfectly in both directions.
Python Developer’s Guide also has a chapter Mercurial for git developers that documents a few differences between git and hg.
Git and GitHub
gitsome - Git/GitHub command line interface (CLI). Written in Python, work on MacOS, Unix, Windows. Git/GitHub CLI with autocomplete, includes many GitHub integrated commands that work with all shells, builtin xonsh with Python REPL to run Python commands alongside shell commands, command history, customizable highlighting, thoroughly documented.
Copyright
This document has been placed in the public domain.
Source: https://github.com/python/peps/blob/main/pep-0103.txt
Last modified: 2022-01-21 11:03:51 GMT