git/Documentation/git-read-tree.txt

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git-read-tree(1)
================
v0.1, May 2005
NAME
----
git-read-tree - Reads tree information into the directory cache
SYNOPSIS
--------
'git-read-tree' (<tree-ish> | -m <tree-ish1> [<tree-ish2> <tree-ish3>])"
DESCRIPTION
-----------
Reads the tree information given by <tree> into the directory cache,
but does not actually *update* any of the files it "caches". (see:
git-checkout-cache)
Optionally, it can merge a tree into the cache or perform a 3-way
merge.
Trivial merges are done by "git-read-tree" itself. Only conflicting paths
will be in unmerged state when "git-read-tree" returns.
OPTIONS
-------
-m::
Perform a merge, not just a read
<tree-ish#>::
The id of the tree object(s) to be read/merged.
Merging
-------
If '-m' is specified, "git-read-tree" performs 2 kinds of merge, a single tree
merge if only 1 tree is given or a 3-way merge if 3 trees are
provided.
Single Tree Merge
~~~~~~~~~~~~~~~~~
If only 1 tree is specified, git-read-tree operates as if the user did not
specify '-m', except that if the original cache has an entry for a
given pathname; and the contents of the path matches with the tree
being read, the stat info from the cache is used. (In other words, the
cache's stat()s take precedence over the merged tree's)
That means that if you do a "git-read-tree -m <newtree>" followed by a
"git-checkout-cache -f -a", the "git-checkout-cache" only checks out
the stuff that really changed.
This is used to avoid unnecessary false hits when "git-diff-files" is
run after git-read-tree.
Two Tree Merge
~~~~~~~~~~~~~~
Typically, this is invoked as "git-read-tree -m $H $M", where $H
is the head commit of the current repository, and $M is the head
of a foreign tree, which is simply ahead of $H (i.e. we are in a
fast forward situation).
When two trees are specified, the user is telling git-read-tree
the following:
(1) The current index and work tree is derived from $H, but
the user may have local changes in them since $H;
(2) The user wants to fast-forward to $M.
In this case, the "git-read-tree -m $H $M" command makes sure
that no local change is lost as the result of this "merge".
Here are the "carry forward" rules:
I (index) H M Result
-------------------------------------------------------
0 nothing nothing nothing (does not happen)
1 nothing nothing exists use M
2 nothing exists nothing remove path from cache
3 nothing exists exists use M
clean I==H I==M
------------------
4 yes N/A N/A nothing nothing keep index
5 no N/A N/A nothing nothing keep index
6 yes N/A yes nothing exists keep index
7 no N/A yes nothing exists keep index
8 yes N/A no nothing exists fail
9 no N/A no nothing exists fail
10 yes yes N/A exists nothing remove path from cache
11 no yes N/A exists nothing fail
12 yes no N/A exists nothing fail
13 no no N/A exists nothing fail
clean (H=M)
------
14 yes exists exists keep index
15 no exists exists keep index
clean I==H I==M (H!=M)
------------------
16 yes no no exists exists fail
17 no no no exists exists fail
18 yes no yes exists exists keep index
19 no no yes exists exists keep index
20 yes yes no exists exists use M
21 no yes no exists exists fail
In all "keep index" cases, the cache entry stays as in the
original index file. If the entry were not up to date,
git-read-tree keeps the copy in the work tree intact when
operating under the -u flag.
When this form of git-read-tree returns successfully, you can
see what "local changes" you made are carried forward by running
"git-diff-cache --cached $M". Note that this does not
necessarily match "git-diff-cache --cached $H" would have
produced before such a two tree merge. This is because of cases
18 and 19 --- if you already had the changes in $M (e.g. maybe
you picked it up via e-mail in a patch form), "git-diff-cache
--cached $H" would have told you about the change before this
merge, but it would not show in "git-diff-cache --cached $M"
output after two-tree merge.
3-Way Merge
~~~~~~~~~~~
Each "index" entry has two bits worth of "stage" state. stage 0 is the
normal one, and is the only one you'd see in any kind of normal use.
However, when you do "git-read-tree" with three trees, the "stage"
starts out at 1.
This means that you can do
git-read-tree -m <tree1> <tree2> <tree3>
and you will end up with an index with all of the <tree1> entries in
"stage1", all of the <tree2> entries in "stage2" and all of the
<tree3> entries in "stage3".
Furthermore, "git-read-tree" has special-case logic that says: if you see
a file that matches in all respects in the following states, it
"collapses" back to "stage0":
- stage 2 and 3 are the same; take one or the other (it makes no
difference - the same work has been done on stage 2 and 3)
- stage 1 and stage 2 are the same and stage 3 is different; take
stage 3 (some work has been done on stage 3)
- stage 1 and stage 3 are the same and stage 2 is different take
stage 2 (some work has been done on stage 2)
The "git-write-tree" command refuses to write a nonsensical tree, and it
will complain about unmerged entries if it sees a single entry that is not
stage 0.
Ok, this all sounds like a collection of totally nonsensical rules,
but it's actually exactly what you want in order to do a fast
merge. The different stages represent the "result tree" (stage 0, aka
"merged"), the original tree (stage 1, aka "orig"), and the two trees
you are trying to merge (stage 2 and 3 respectively).
In fact, the way "git-read-tree" works, it's entirely agnostic about how
you assign the stages, and you could really assign them any which way,
and the above is just a suggested way to do it (except since
"git-write-tree" refuses to write anything but stage0 entries, it makes
sense to always consider stage 0 to be the "full merge" state).
So what happens? Try it out. Select the original tree, and two trees
to merge, and look how it works:
- if a file exists in identical format in all three trees, it will
automatically collapse to "merged" state by the new git-read-tree.
- a file that has _any_ difference what-so-ever in the three trees
will stay as separate entries in the index. It's up to "script
policy" to determine how to remove the non-0 stages, and insert a
merged version. But since the index is always sorted, they're easy
to find: they'll be clustered together.
- the index file saves and restores with all this information, so you
can merge things incrementally, but as long as it has entries in
stages 1/2/3 (ie "unmerged entries") you can't write the result. So
now the merge algorithm ends up being really simple:
* you walk the index in order, and ignore all entries of stage 0,
since they've already been done.
* if you find a "stage1", but no matching "stage2" or "stage3", you
know it's been removed from both trees (it only existed in the
original tree), and you remove that entry.
* if you find a matching "stage2" and "stage3" tree, you remove one
of them, and turn the other into a "stage0" entry. Remove any
matching "stage1" entry if it exists too. .. all the normal
trivial rules ..
Incidentally - it also means that you don't even have to have a
separate subdirectory for this. All the information literally is in
the index file, which is a temporary thing anyway. There is no need to
worry about what is in the working directory, since it is never shown
and never used.
See Also
--------
link:git-write-tree.html[git-write-tree]; link:git-ls-files.html[git-ls-files]
Author
------
Written by Linus Torvalds <torvalds@osdl.org>
Documentation
--------------
Documentation by David Greaves, Junio C Hamano and the git-list <git@vger.kernel.org>.
GIT
---
Part of the link:git.html[git] suite