This happens because Git doesn't know that the squash merge is "equivalent to" the various branch-specific commits. You must forcibly delete the branch, with git branch -D
instead of git branch -d
.
(The rest of this is merely about why this is the case.)
Draw the commit graph
Let's draw (part of) the commit graph (this step is appropriate for so many things in Git...). In fact, let's step back one more step, so that we start before your git rebase
, with something like this:
...--o--o--o <-- mainline
A--B--C <-- feature1
A branch name, like mainline
or feature1
, points only to one specific commit. That commit points back (leftward) to a previous commit, and so on, and it's these backward pointers that form the actual branches.
The top row of commits, all just called o
here, are kind of boring, so we didn't give them letter-names. The bottom row of commits, A-B-C
, are only on branch feature1
. C
is the newest such commit; it leads back to B
, which leads back to A
, which leads back to one of the boring o
commits. (As an aside: the leftmost o
commit, along with all earlier commits in the ...
section, is on both branches.)
When you ran git rebase
, the three A-B-C
commits were copied to new commits appended to the tip of mainline
, giving us:
...--o--o--o <-- mainline
A'-B'-C' <-- feature1
A--B--C [old feature1, now abandoned]
The new A'-B'-C'
commits are mostly the same as the original three, but they are moved in the graph. (Note that all three boring o
commits are on both branches now.) Abandoning the original three means that Git usually doesn't have to compare the copies to the originals. (If the originals had been reachable by some other name—a branch that appended to the old feature1
, for instance—Git can figure this out, at least in most cases. The precise details of how Git figures this out are not particularly important here.)
Anyway, now you go on to run git checkout mainline; git merge --squash feature1
. This makes one new commit that is a "squash copy" of the three—or however many—commits that are on feature1
. I will stop drawing the old abandoned ones, and call the new squash-commit S
for Squash:
...--o--o--o--S <-- mainline
A'-B'-C' <-- feature1
"Delete safety" is determined entirely by commit history
When you ask Git to delete feature1
, it performs a safety check: "is feature1
merged into mainline
?" This "is merged into" test is based purely on the graph connectivity. The name mainline
points to commit S
; commit S
points back to the first boring o
commit, which leads back to more boring o
commits. Commit C'
, the tip of feature1
, is not reachable from S
: we're not allowed to move rightward, only leftward.
Contrast this with making a "normal" merge M
:
...--o--o--o---------M <-- mainline
/
A'-B'-C' <-- feature1
Using the same test—"is the tip commit of feature1
reachable from the tip commit of mainline
?"—the answer is now yes, because commit M
has a down-and-left link to commit C'
. (Commit C'
is, in Git internal parlance, the second parent of merge commit M
.)
Since squash merges are not actually merges, though, there is no connection from S
back to C'
.
Again, Git doesn't even try to see if S
is "the same as" A'
, B'
, or C'
. If it did, though, it would say "not the same", because S
is only the same as the sum of all three commits. The only way to get S
to match the squashed commits is to have only one such commit (and in this case, there's no need to squash in the first place).