This patch teaches the `View` object to keep track of the checkout in
each workspace. It serializes that information into the `OpStore`. For
compatibility with existing repos, the existing field for a single
workspace's checkout is interpreted as being for the workspace called
"default".
This is just an early step towards support for multiple
workspaces. Remaining things to do:
* Record the workspace ID somewhere in `.jj/` (maybe in
`.jj/working_copy/`)
* Update existing code to use the workspace ID instead of assuming
it's always "default" as we do after this patch
* Add a way of indicating in `.jj/` that the repo lives elsewhere and
make it possible to load a repo from such workspaces
* Add a command for creating additional workspaces
* Show each workspace's checkout in log output
The `.jj/` directory contains information about two distinct parts:
the repo and the working copy. Most subdirectories are related to the
repo; only `.jj/working_copy/` is about the working copy. Let's move
the repo-related bits into a new `.jj/repo/` subdirectory. That makes
it clearer that they're related to the repo. It will probably also be
easier to manage when we have support for multiple workspaces backed
by a single repo.
This adds a `jj move [--from <rev>] [--to <rev>] [-i]` command, which
lets you move some changes from one commit into another. `jj
squash/amend` is just a special case of this new command. Except for
that command's more specialized help text, instructions, etc., it
could be implemented as simply `jj move --to @-`.
I thought it was a bit unclear which part of the process was
interactive (it's only choosing parts of the diffs that is
interactive, not choosing destination or anything else).
The `DescendantRebaser` was designed to help with rebasing in two
different use cases: 1) after regular rewriting of commits where the
change ID is preserved, and 2) after importing moved branches from
other repo (e.g. backing Git repo or remote). Many of the tests are
for the second use case, such as where a branch was moved
forward. However, I just noticed that there's a pretty common scenario
from the first use case that is not supported.
Let's say you have this history:
```
D
|
C C'
|/
B B'
|/
A
```
Here we want C' to be rebased onto B' and then D to be rebased onto
C''. However, because of the support for moving branches forward, we
would not rebase commits that were already rewritten, such as C' here
(see affected tests for details), which resulted in D getting rebased
onto C', and both B and B' remaining visible.
I think I was thinking when I designed it that it would be nice if you
could just tell `DescendantRebaser` that any descendants of a commit
should be moved forward. That may be useful, but I don't think we'll
want that for the general case of a branch moving forward. Perhaps
we'll want to make it configurable which branches it should happen
for. Either way, the way it was coded by not rebasing already
rewritten commits did not work for the case above. We may be able to
handle both cases better by considering each rewrite separately
instead of all destinations at once. For now, however, I've decided to
keep it simple, so I'm fixing the case above by sacrificing some of
the potentially useful functionality for moving branches forward.
Another fix necessary for the scenario shown above was to make sure we
always rebase C' before D. Before this patch, that depended on the
order in the index. This patch fixes that by modifying the topological
order to take rewrites into account, making D depend not only on C but
also on C'. (I suppose you could instead say that C depends on both B
and C'; I don't know if that'd make a difference.)
Despite what the documentation said, we don't clear the record of
rewritten and abandoned commits at the end. This change fixes that,
and adds a test showing that it's possible to call
`MutableRepo::rebase_descendants()` multiple times.
We allow rebasing to a descendant, but that causes divergence because
the old commit remains visible. You could imagine making it work so
`jj rebase -r B -d D` on a linear chain "A-B-C-D" reorders it to
"A-C-D-B", but we don't do that yet, so let's just prevent the
divergence for now.
Now that we have the operation ID recorded in the working copy state,
we can tell if the working copy is stale. When it is, we update it to
the repo view's checkout.
When there are concurrent operations that want to update the working
copy, it's useful to know which operation was the last to successfully
update the working copy. That can help use decide how to resolve a
mismatch between the repo view's record and the working copy's
record. If we detect such a difference, we can look at the working
copy's operation ID to see if it was updated by an operation before or
after we loaded the repo.
If the working copy's record says that it was updated at operation A
and we have loaded the repo at operation B (after A), we know that the
working copy is stale, so we can automatically update it (or tell the
user to run some command to update it if we think that's more
user-friendly).
Conversely, if we have loaded the repo at operation A and the working
copy's record says that it was updated at operation B, we know that
there was some concurrent operation that updated it. We can then
decide to print a warning telling the user that we skipped updating
because of the conflict. We already have logic for not updating the
working copy if the repo is loaded at an earlier operation, but maybe
we can drop that if we record the operation in the working copy (as
this patch does).
When importing git HEAD in a working copy shared with git, we reset
the working copy to the new commit at the end. If we fail to reset the
working copy, we shouldn't commit the operation. This patch mostly
fixes that by locking the working copy while we commit the
operation. There's still a small risk that the operation commits and
we fail to write the working copy state, but there's not much we can
do about that (or it's not worth the effort anyway).
Having the checkout functionality in `LockedWorkingCopy` makes it a
little more flexible (one could imagine using it for udating working
copy files and then discarding the state changes, for example). It
also lets us reuse a few lines of code for locking. I left
`WorkingCopy::check_out()` for convenience because that's what all
current users want.
`WorkingCopy::check_out()` currently fails if the commit recorded on
disk has changed since it was last read. It fails with a "concurrent
checkout" error. That usually works well in practice, but one can
imagine cases where it's not correct. For an example where the current
behavior is wrong, consider this sequence of events:
1. Process A loads the repo and working copy.
2. Process B loads the repo at operation A. It has not loaded the
working copy yet.
3. Process A writes an operation and updates the working copy.
4. Process B loads the working copy and sees that it is checked out
to the commit process B set it to. We don't currently have any
checks that the working copy commit matches the view's checkout
(though I plan to add that).
5. Process B finishes its operation (which is now divergent with the
operation written by process A). It updates the working copy to
the checkout set in the repo view by process B. There's no data
loss here, but the behavior is surprising because we would usually
tell the user that we detected a concurrent update to the working
copy.
We should instead check that the working copy's commit on disk matches
what the previous repo view said, i.e. the view at the start of the
operation we just committed. This patch does that by having the caller
pass in the expected old commit ID.
We already have two usecases that can be modeled as updating the
`TreeState` without touching the working copy:
1. `jj untrack` can be implemented as removing paths from the tree
object and then doing a reset of the working copy state.
2. Importing Git HEAD when sharing the working copy with a Git repo.
This patch adds that functionality to `TreeState`.
I was surprised that we save the `TreeState` before
`LockedWorkingCopy::finish()`. That means that even if the caller
instead decides to discard the changes, some changes will already have
been written.
This patch changes the interface for making changes to the working
copy by replacing `write_tree()` and `untrack()` by a single
`start_mutation()` method. The two functions now live on the returned
`LockedWorkingCopy` object instead. That is more flexible because the
caller can make multiple changes while the working copy is locked. It
also helps us reduce the risk of buggy callers that read the commit ID
before taking the lock, because we can now make it accessible only on
`LockedWorkingCopy`.
The working copy object knows the currently checked out commit ID. It
is set to `None` when the object is initialized. It is also set to
`None` when an existing working copy is loaded. In that case, it's
used only to facilitate lazy loading. However, that means that
`WorkingCopy::current_commit_id()` fails if the working copy has been
initalized but no checkout has been specified. I've never run into
that case, but it's ugly that it can happen. This patch fixes it by
having `WorkingCopy::init()` take a `CommitId`.
`WorkingCopy::current_commit()` has been there from the beginning. It
has made less sense since we made the repo view keep track of the
current checkout. Let's remove it.
Before this patch, we got the old commit ID before we took the lock on
the working copy, which means we might unnecessarily create divergence
if another process just committed the working copy.
If you create a `dir/.gitignore` file with pattern "dir" in it, it'll
currently match the parent directory, making e.g. the `dir/.gitignore`
file itself ignored. That was quite confusing, and it doesn't match
how Git behaves. This patch fixes the bug.
I ran into a tool that produced a `.gitignore` file with CRLF line
endings. I had not considered that case when implementing support for
`.gitignore`, so we interpreted the CR as part of the string, which of
course made the files not match.
This patch fixes the bug by ignoring a single CR at EOL. That seems to
be what Git does (I didn't see any information about it in the
documentation).
It turns out that the `--help` option is "global", so the description
we set on the top-level command already applies to subcommands (and
subsubcommands, etc.).
