I don't get all the effort people spend in perfectly curating git history. No one is ever going back and reading individual commits. Just squash everything before merging and call it a day.
> scary rebase -i commands that can leave your tree in a half-broken state if you so much as sneeze
`git rebase --abort` exists. One can also set a tag or something before doing the rebase, do whatever, then `git reset --hard $set_tag` to go back. Nothing to be scared of. Not like the prior state is lost.
I have so many branches named `temp` or `before-rebase` for exactly that reason; I'm using them effectively as tags, but branches can be moved around with less ceremony than tags (since tags are designed to be for things like v1.2.3, placed once and then almost never moved again), so I usually just do `git branch before-rebase/some-feature` before running a big `rebase -i`.
I've almost never needed to run `get reset before-rebase`. But I have often done `git log -p before-rebase` and compared that to the post-rebase state of the branch, to ensure that the merge-conflict resolution(s) that came up during the rebase haven't accidentally introduced an unintended change.
> but branches can be moved around with less ceremony than tags
`git tag -f` to move a tag.
Personally, I just do `git show` when I'm feeling cautious, but I can generally just scroll up to find the last `git commit` I did with the hash in the output. `git reflog` should also have record of it, so everything else is kind of extra.
Good point, that's no more ceremony than moving a branch. I guess I've just gotten "branches are movable tags" so deep into my hindbrain that I absorbed "tags are hard to move". But that's not actually true, and for what I'm doing (save this point in history for a while) a tag makes slightly more sense, semantically, than a branch.
I don’t consider myself a coder or programmer, but learning git was like an organizational superpower for my particular brain wiring. I use it for websites, design projects, electronics engineering, music composition, personal knowledge bases, remote administration scripts, config management, snippets, so many applications and so many features for one system. It’s not always perfect, but I tell everyone I work with they should learn it.
> That last part goes further than git rebase --update-refs, which only moves refs sitting inside the range you’re actively rebasing. git history instead finds and rewrites every local branch descended from the commit (while also having an option to limit it to only the current branch).
I'm reading that to mean that when I use `git rebase --update-refs` in this situation, where I've currently checked out `D` and update `B` to `B'`:
A ──► B ──► C ──► D
│
└───► E
I'll end up with this state, where `E` remains untouched?
A ──► B' ─► C' ─► D'
│
└───► B ──► E
(EDIT: Originally I had `E` point to `B'`, which doesn't make sense)
If I use `git history fixup`, it would also update `E` and end up with this?
A ──► B' ─► C' ─► D'
│
└───► E'
If that's the case, is there a way to get `git rebase` to have the same behavior? I've got decades of `git rebase` burned into my fingers at this point.
Huh.. That's a shame :(. Maybe what it refers to is if you had a branch on B rather than D, it might update that.
EDIT: Yeah, this seems to be it. `git branch b` on b, then `git rebase -i --update-ref @~3` from main caused branch ref `b` to move from d86229e to 02fcaf7:
* 1e354fb (HEAD -> main) fix b
* 40e6f70 c
* 02fcaf7 (b) b
| * f4188e0 (branched-feature) d
| * d86229e b
|/
* 5fe78fa a
Unless E remained untouched because it was not rewritten, and ended up staying parented on B instead of getting reparented onto B'.
Which is usually not what you want; most of the time you want E', which is E reparented onto B'. But sometimes you want E to remain untouched and stay parented on the original B. Depends on the situation.
> when I use `git rebase --update-refs` [...] I'll end up with this state, where `E` remains untouched?
would be backwards. The second graph would be what you'd get if you don't use --update-refs. The third graph would be what you'd get when you do use it. At least, according to my reading:
> --update-refs Automatically force-update any branches that point to commits that are being rebased. Any branches that are checked out in a worktree are not updated in this way.
I'm not sure that answers my question. That shows a linear set of branches (my-feature-v3 depends on my-feature-v2 depends on my-feature-v1 depends on main). I'm asking about the case where two or more branches fork from a common ancestor and you want to fix the common ancestor.
`git history split` is really going to help me help juniors break up their large PRs into smaller more concise changes. If only it had the option to split an entire branch in two easily.
Probably to take a series of commits and decide "this one goes on branch A, this one on branch B", e.g. if you intermingled fixing bug A and B in the same branch, you could more easily go through and assign each commit to a new branch.
The existing workflow for that would be (there are several possible workflows, but this is what I would do):
git checkout intermingled-branch
git branch bugfix-A
git branch bugfix-B
git checkout bugfix-A
git rebase -i
# Edit the file, keep commits that fix bug A, drop commits that fix bug B
git push origin bugfix-A:bugfix-A
git checkout bugfix-B
git rebase -i
# Edit the file, keep commits that fix bug B, drop commits that fix bug A
git push origin bugfix-B:bugfix-B
Commit graph is just a data structure. Sometimes it represents a "history", sometimes other things.
Personally, I like it when project's repository represents the history of the project rather than the history of random things developers do on their machines, but you do you.
Remotes aren't equal either. Sometimes the remote is my other machine, sometimes it's a fork on a forge used for producing CI artifacts.
It's a good rule of thumb to consider shared branches to be append-only, but not every remote branch is "shared" and, as with any proper rule of thumb, you can always find exceptions.
With tools like GitHub Actions and some added constraints, it's not always possible. You literally need a commit to trigger the CI workflow and it starts to trash your branch. Besides, aren't we all familiar with git commit -m "typo"?
In short, newer versions of git implemented three really frequent use cases of `git rebase --interactive` as separate lower-friction commands. Apparently they only work when there are no conflicts.
Granted, I have a perspective of a game dev, but this kind of repo defiling just gives me the willies. IMO instead of finding a common ancestor and altering it, just make the desired change upstream and merge it to where it’s needed. If you can’t do that then you have already made a deal with the devil and might reconsider your approach. KISS
> Working with lots of changes in parallel on git can be painful. You end up juggling branches and commits, and running scary rebase -i commands that can leave your tree in a half-broken state if you so much as sneeze.
I think that only happens when you work on code as text files (i.e character streams) instead of code (i.e structured content with meaning). Like you have commit A and commit B that is in conflict, you should be glad because that's a rough signal that the intent of A and B differs. Your goal should be to think about how to compose A and B so that both intent survives (unless one supersedes the other). Which means you should be at least familiar with A and B.
The issue I found with people that fears conflict is that they often don't understand either A or B (or both). So they are a bad candidate to actually do the operation. It's not a matter of git's cli interface, it's a matter of codebase comprehension and how well you're familiar with the changes in question.
Git store whole files. The diff and the merge algorithm works by line by default, but that's because line is a rough unit of code (statement, expression, and definition happens mostly within one line).
When you merge a commit in that changed a file that has been already changed since the common ancestor, Git runs a tool of your choice on this file. If the tool fails, it marks the file as needing a merge and doesn't let you commit it until you unmark it to confirm that you have merged it manually. In case of octopus merges, it will just abort early. That's basically its whole behavior when it comes to conflicts.
Such as moving down a fixup during interactive rebase when it's going to conflict with parents, or I've added more commits mid-rebase, or the rebase started in a tool and now I need to think about the tool's command and understand how many times the rebase point is view is backwards to interpret which is "ours" and which is "theirs" and whether it's the tool, my editor, or my own experience I should ignore because it's going to mislead me.
None of that word salad should matter, but it does. Git will ruin everything with glee and there is always an excuse for why that's fine and it's the user's fault.
There's nothing "backwards" in "rebase point of view". It's just automated cherry-picking - it's like applying patches, it's as forwards as it gets. People who think it's "backwards" usually just have holes in their mental model of the repository. And yes, I find tools doing what you're asking them to do to be rather fine. In fact, Git makes it easy to notice when you're adding commits mid-rebase, which is something I often do intentionally, as it tells you what the HEAD is (and even shows a detailed state of the in-progress rebase) while authoring the commit message.
"ours" is always HEAD, usually meaning the state of the working_tree, "theirs" is always the commit that is going to change the working_tree.
When merging, you are taking change from another branch (theirs) to create a new commit on the current branch (ours) that ties the two together. When rebasing interactively, you switch to the new base (ours) and replay the changes of the branch (theirs) according to the edit file.
Etymology matters. The conceptual model of git is simple, but people only focus on the operations. That's like trying to learn algorithm and data structures and focusing on the words "insert", "remove", "find", without trying to learn "list", "stack", "tree",... first.
Instead learn about Git's glossary [0], then how the operations use and modify those concepts.
`git rebase --abort` exists. One can also set a tag or something before doing the rebase, do whatever, then `git reset --hard $set_tag` to go back. Nothing to be scared of. Not like the prior state is lost.
I've almost never needed to run `get reset before-rebase`. But I have often done `git log -p before-rebase` and compared that to the post-rebase state of the branch, to ensure that the merge-conflict resolution(s) that came up during the rebase haven't accidentally introduced an unintended change.
`git tag -f` to move a tag.
Personally, I just do `git show` when I'm feeling cautious, but I can generally just scroll up to find the last `git commit` I did with the hash in the output. `git reflog` should also have record of it, so everything else is kind of extra.
It sounds like there was probably an equivalent using an existing command but this is easier for me to understand. Thanks for sharing!
I'm reading that to mean that when I use `git rebase --update-refs` in this situation, where I've currently checked out `D` and update `B` to `B'`:
I'll end up with this state, where `E` remains untouched? (EDIT: Originally I had `E` point to `B'`, which doesn't make sense)If I use `git history fixup`, it would also update `E` and end up with this?
If that's the case, is there a way to get `git rebase` to have the same behavior? I've got decades of `git rebase` burned into my fingers at this point.Can't, because a commit's hash takes into account the parent hashes.
Haven't used --update-refs, but reading it, it should result in your third graph. So,
> is there a way to get `git rebase` to have the same behavior?
is already the case.
I don't think it does. I tried locally:
And ended up with this graph (`git log --graph --all`) Replacing the `git commit -m 'fix b'; git rebase -i --root --update-refs` with `git history fixup HEAD~` produces what I'd like:EDIT: Yeah, this seems to be it. `git branch b` on b, then `git rebase -i --update-ref @~3` from main caused branch ref `b` to move from d86229e to 02fcaf7:
Which is usually not what you want; most of the time you want E', which is E reparented onto B'. But sometimes you want E to remain untouched and stay parented on the original B. Depends on the situation.
> when I use `git rebase --update-refs` [...] I'll end up with this state, where `E` remains untouched?
would be backwards. The second graph would be what you'd get if you don't use --update-refs. The third graph would be what you'd get when you do use it. At least, according to my reading:
> --update-refs Automatically force-update any branches that point to commits that are being rebased. Any branches that are checked out in a worktree are not updated in this way.
EDIT: This is wrong. Actual behavior in https://news.ycombinator.com/item?id=48901607
The existing workflow for that would be (there are several possible workflows, but this is what I would do):
Personally, I like it when project's repository represents the history of the project rather than the history of random things developers do on their machines, but you do you.
It's a good rule of thumb to consider shared branches to be append-only, but not every remote branch is "shared" and, as with any proper rule of thumb, you can always find exceptions.
I prefer the interactive rebase and use it frequently.
Would much rather “visually” move commits around than accidentally aim “git history” at an orphaned commit hash no longer in my local branch.
I think that only happens when you work on code as text files (i.e character streams) instead of code (i.e structured content with meaning). Like you have commit A and commit B that is in conflict, you should be glad because that's a rough signal that the intent of A and B differs. Your goal should be to think about how to compose A and B so that both intent survives (unless one supersedes the other). Which means you should be at least familiar with A and B.
The issue I found with people that fears conflict is that they often don't understand either A or B (or both). So they are a bad candidate to actually do the operation. It's not a matter of git's cli interface, it's a matter of codebase comprehension and how well you're familiar with the changes in question.
When you merge a commit in that changed a file that has been already changed since the common ancestor, Git runs a tool of your choice on this file. If the tool fails, it marks the file as needing a merge and doesn't let you commit it until you unmark it to confirm that you have merged it manually. In case of octopus merges, it will just abort early. That's basically its whole behavior when it comes to conflicts.
None of that word salad should matter, but it does. Git will ruin everything with glee and there is always an excuse for why that's fine and it's the user's fault.
"ours" is always HEAD, usually meaning the state of the working_tree, "theirs" is always the commit that is going to change the working_tree.
When merging, you are taking change from another branch (theirs) to create a new commit on the current branch (ours) that ties the two together. When rebasing interactively, you switch to the new base (ours) and replay the changes of the branch (theirs) according to the edit file.
Etymology matters. The conceptual model of git is simple, but people only focus on the operations. That's like trying to learn algorithm and data structures and focusing on the words "insert", "remove", "find", without trying to learn "list", "stack", "tree",... first.
Instead learn about Git's glossary [0], then how the operations use and modify those concepts.
[0] https://git-scm.com/docs/gitglossary