Commit graph

6 commits

Author SHA1 Message Date
Leonardo de Moura
2652cc18b8
chore: error messages consistency (#10143)
This PR standardizes error messages by quoting names with backticks. The
changes were automated, so some cases may still be missing.
2025-08-26 17:55:43 +00:00
jrr6
62f14514da
refactor: update built-in tactic error messages (#9633)
This PR updates various error messages produced by or associated with
built-in tactics and adapts their formatting to current conventions.
2025-07-31 14:16:57 +00:00
jrr6
d1ec806834
feat: improve error messages in invalid match alternatives (#8368)
This PR improves the error messages produced by invalid pattern-match
alternatives and improves parity in error placement between
pattern-matching tactics and elaborators.

Closes #7170
2025-05-19 17:40:41 +00:00
Joachim Breitner
e575736cae
feat: fun_induction to unfold function application in the goal (#8104)
This PR makes `fun_induction` and `fun_cases` (try to) unfold the
function application of interest in the goal. The old behavior can be
enabled with `set_option tactic.fun_induction.unfolding false`. For
`fun_cases` this does not work yet when the function’s result type
depends on one of the arguments, see issue #8296.
2025-05-13 09:37:39 +00:00
Joachim Breitner
f45c19b428
feat: identify more fixed parameters (#7166)
This PR extends the notion of “fixed parameter” of a recursive function
also to parameters that come after varying function. The main benefit is
that we get nicer induction principles.


Before the definition

```lean
def app (as : List α) (bs : List α) : List α :=
  match as with
  | [] => bs
  | a::as => a :: app as bs
```

produced

```lean
app.induct.{u_1} {α : Type u_1} (motive : List α → List α → Prop) (case1 : ∀ (bs : List α), motive [] bs)
  (case2 : ∀ (bs : List α) (a : α) (as : List α), motive as bs → motive (a :: as) bs) (as bs : List α) : motive as bs
```
and now you get
```lean
app.induct.{u_1} {α : Type u_1} (motive : List α → Prop) (case1 : motive [])
  (case2 : ∀ (a : α) (as : List α), motive as → motive (a :: as)) (as : List α) : motive as
```
because `bs` is fixed throughout the recursion (and can completely be
dropped from the principle).

This is a breaking change when such an induction principle is used
explicitly. Using `fun_induction` makes proof tactics robust against
this change.

The rules for when a parameter is fixed are now:

1. A parameter is fixed if it is reducibly defq to the the corresponding
argument in each recursive call, so we have to look at each such call.
2. With mutual recursion, it is not clear a-priori which arguments of
another function correspond to the parameter. This requires an analysis
with some graph algorithms to determine.
3. A parameter can only be fixed if all parameters occurring in its type
are fixed as well.
This dependency graph on parameters can be different for the different
functions in a recursive group, even leading to cycles.
4. For structural recursion, we kinda want to know the fixed parameters
before investigating which argument to actually recurs on. But once we
have that we may find that we fixed an index of the recursive
parameter’s type, and these cannot be fixed. So we have to un-fix them
5. … and all other fixed parameters that have dependencies on them.

Lean tries to identify the largest set of parameters that satisfies
these criteria.

Note that in a definition like
```lean
def app : List α → List α → List α
  | [], bs => bs
  | a::as, bs => a :: app as bs
```
the `bs` is not considered fixes, as it goes through the matcher
machinery.


Fixes #7027
Fixes #2113
2025-03-04 22:26:20 +00:00
Joachim Breitner
a3b76aa825
feat: fun_induction foo (no arguments) (#7101)
This PR implements `fun_induction foo`, which is like `fun_induction foo
x y z`, only that it picks the arguments to use from a unique suitable
call to `foo` in the goal.
2025-02-18 12:27:21 +00:00