so that the pretty-printed origin is clickable, and avoid the
unnecessary `@`.
Particularly nice is this fix:
```diff
/--
-info: [Meta.Tactic.simp.discharge] @bar discharge ✅
+info: [Meta.Tactic.simp.discharge] bar discharge ✅
autoParam T _auto✝
- [Meta.Tactic.simp.rewrite] { }:1000, T ==> True
-[Meta.Tactic.simp.rewrite] @bar:1000, U ==> True
+ [Meta.Tactic.simp.rewrite] T.mk:1000, T ==> True
+[Meta.Tactic.simp.rewrite] bar:1000, U ==> True
-/
```
this is an amendment to #4177, after @kmill pointed out an issue:
Users might expect that within a tactic combinator like `first`, `simp
[h]` fails if `h` does not exist. Therefore the behavior introduced in
PR #4177, which is really most useful in mormal interactive use of
`skip`, is restricted to when `recover := true`.
types like
```
inductive Many (α : Type u) where
| none : Many α
| more : α → (Unit → Many α) → Many α
```
have a `.brecOn` only supports motives producing `Type u`, but not `Sort
u`, but our induction principles produce `Prop`. So the previous
implementation of functional induction would fail for functions that
structurally recurse over such types.
We recognize this case now and, rather hazardously, replace `.brecOn`
with `.binductionOn` (and thus `.below ` with `.ibelow` and `PProd` with
`And`). This assumes that these definitions are highly analogous.
This also improves the error message when realizing a reserved name
fails with an exception, by prepending
```
Failed to realize constant {id}:
```
to the error message.
Fixes#4320
Remark: when splitting an `if-then-else` term, the subgoals now have
tags `isTrue` and `isFalse` instead of `inl` and `inr`.
closes#4313
---------
Co-authored-by: Mario Carneiro <di.gama@gmail.com>
The `save` happened in a slightly different context from the restore,
which a refinement of the `saveOrRestoreFull` signature now makes
impossible.
Fixes#4328
this fixes a usability paper cut that just annoyed me. When editing a
larger simp proof, I usually want to see the goal state after the simp,
and this is what I see while the `simp` command is complete. But then,
when I start typing, and necessarily type incomplete lemma names, that
error makes `simp` do nothing again and I see the original goal state.
In fact, if a prefix of the simp theorem name I am typing is a valid
identifier, it jumps even more around.
With this PR, using `logException`, I still get the red squiggly lines
for the unknown identifer, but `simp` just ignores that argument and
still shows me the final goal. Much nicer.
I also demoted the message for `[-foo]` when `foo` isn’t `simp` to a
warning and gave it the correct `ref`.
See it in action here: (in the middle, when you suddenly see the
terminal,
I am switching lean versions.)
https://github.com/leanprover/lean4/assets/148037/8cb3c563-1354-4c2d-bcee-26dfa1005ae0
Without this, it would not easy but perhaps be feasible to break
incrementality when editing command prefixes such as `set_option ... in
theorem` or also `theorem namesp.name ...` (which is a macro),
especially if at some later point we support incrementality in input
shifted by an edit. Explicit, sound support for these common cases will
be brought back soon.
Extends Lean's incremental reporting and reuse between commands into
various steps inside declarations:
* headers and bodies of each (mutual) definition/theorem
* `theorem ... := by` for each contained tactic step, including
recursively inside supported combinators currently consisting of
* `·` (cdot), `case`, `next`
* `induction`, `cases`
* macros such as `next` unfolding to the above
*Incremental reuse* means not recomputing any such steps if they are not
affected by a document change. *Incremental reporting* includes the
parts seen in the recording above: the progress bar and messages. Other
language server features such as hover etc. are *not yet* supported
incrementally, i.e. they are shown only when the declaration has been
fully processed as before.
---------
Co-authored-by: Scott Morrison <scott.morrison@gmail.com>
this fixes#4078. It is an alternative fix to the one in #4137,
suggested
by @kmill.
Incidentially, it makes the unused variable linter better. My theory is
that
if we don’t reset the info when backtracking, the binder shows up more
than
once in the info tree, and then it is considered “used”, although there
are
just multiple binders.
Add docstrings, usage examples, and doc tests for `String.prev`,
`.front`, `.back`, `.atEnd`.
Improve docstring examples for `String.next` based on discussion
examples for `String.prev`.
---------
Co-authored-by: Kim Morrison <kim@tqft.net>
To eliminate parsing differences between Windows and other platforms,
the frontend now normalizes all CRLF line endings to LF, like [in
Rust](https://github.com/rust-lang/rust/issues/62865).
Effects:
- This makes Lake hashes be faithful to what Lean sees (Lake already
normalizes line endings before computing hashes).
- Docstrings now have normalized line endings. In particular, this fixes
`#guard_msgs` failing multiline tests for Windows users using CRLF.
- Now strings don't have different lengths depending on the platform.
Before this PR, the following theorem is true for LF and false for CRLF
files.
```lean
example : "
".length = 1 := rfl
```
Note: the normalization will take `\r\r\n` and turn it into `\r\n`. In
the elaborator, we reject loose `\r`'s that appear in whitespace. Rust
instead takes the approach of making the normalization routine fail.
They do this so that there's no downstream confusion about any `\r\n`
that appears.
Implementation note: the LSP maintains its own copy of a source file
that it updates when edit operations are applied. We are assuming that
edit operations never split or join CRLFs. If this assumption is not
correct, then the LSP copy of a source file can become slightly out of
sync. If this is an issue, there is some discussion
[here](https://github.com/leanprover/lean4/pull/3903#discussion_r1592930085).
Given `h` with type `x + k = y + k'` (or `h : k = k')`, `cases h`
produced a proof of size linear in `min k k'`. `isDefEq` has support for
offset, but `unifyEq?` did not have it, and a stack overflow occurred
while processing the resulting proof. This PR fixes this issue.
closes#4219
### Explanation
In the case that `assignSyntheticOpaque := true` and the given
metavariable is `syntheticOpaque` and the depth of the metavariable is
not the current depth, `isReadOnlyOrSyntheticOpaque` returns false, even
though the metavariable is read-only because of being declared at a
smaller depth. This causes the metavariable to (wrongly) be able to be
instantiated by `isDefEq`.
This bug was found at the proof of
[RingHom.PropertyIsLocal.sourceAffineLocally_of_source_openCover](https://leanprover-community.github.io/mathlib4_docs/Mathlib/AlgebraicGeometry/Morphisms/RingHomProperties.html#RingHom.PropertyIsLocal.sourceAffineLocally_of_source_openCover),
which involves a type class synthesis for `CommRing ?m.2404`, and the
synthesis manages to instantiate this metavariable into different
values, even though `synthInstance?` increases the metavariable depth.
This synthesis fails after 1 second.
I found the bug while modifying the instance synthesis code: the
modified code spent several minutes on this failed synthesis.
### Test
The problem can be verified with the test:
```
run_meta do
let m ← mkFreshExprMVar (Expr.sort levelOne) MetavarKind.syntheticOpaque
withAssignableSyntheticOpaque do
withNewMCtxDepth do
let eq ← isDefEq m (.const ``Nat [])
Lean.logInfo m! "{eq}"
```
this unification used to succeed, giving `true`, and this fix makes it
return `false`.
### Impact on Mathlib
This fix causes a change in the behaviour of `congr`, `convert` and
friends, which breaks a couple of proofs in mathlib. Most of these are
fixed by supplying more arguments.
I fixed these proofs, and
[benched](http://speed.lean-fro.org/mathlib4/compare/b821bfd9-3769-4930-b77f-0adc6f9d218f/to/e7b27246-a3e6-496a-b552-ff4b45c7236e?hash2=4f3c460cc1668820c9af8418a87a23db44c7acab)
mathlib. The result is that most files are unaffected, but some files
are significantly improved. This is most prominent in
Mathlib.RingTheory.Jacobson, where the number of instructions has
decreased by 28%. The overall improvement is a 0.3% reduction in
instructions.
[Zulip
message](https://leanprover.zulipchat.com/#narrow/stream/287929-mathlib4/topic/Ways.20to.20speed.20up.20Mathlib/near/439218960)
The expression tree elaborator computes a "maxType" that every leaf term
can be coerced to, but the elaborator was not ensuring that the entire
expression tree would have maxType as its type. This led to unexpected
errors in examples such as
```lean
example (a : Nat) (b : Int) :
a = id (a * b^2) := sorry
```
where it would say it could not synthesize an `HMul Int Int Nat`
instance (the `Nat` would propagate from the `a` on the LHS of the
equality). The issue in this case is that `HPow` uses default instances,
so while the expression tree elaborator decides that `a * b^2` should be
referring to an `Int`, the actual elaborated type is temporarily a
metavariable. Then, when the binrel elaborator is looking at both sides
of the equality, it decides that `Nat` will work and coercions don't
need to be inserted.
The fix is to unify the type of the resulting elaborated expression with
the computed maxType. One wrinkle is that `hasUncomparable` being false
is a valid test only if there are no leaf terms with unknown types (if
they become known, it could change `hasUncomparable` to true), so this
unification is only performed if the leaf terms all have known types.
Fixes issue described by Floris van Doorn on
[Zulip](https://leanprover.zulipchat.com/#narrow/stream/287929-mathlib4/topic/elaboration.20issue.20involving.20powers.20and.20sums/near/439243587).
luckily the necessary functionality already exists in the form of
`addPPExplicitToExposeDiff`. But it is not cheap, and we should not run
this code
when the error message isn’t shown, so we should do this lazily.
We already had `MessageData.ofPPFormat` to assemble the error message
lazily, but it
was restricted to returning `FormatWithInfo`, a data type that doesn’t
admit a nice
API to compose more complex messages (like `Format` or `MessageData`
has; an attempt to
fix that is in #3926).
Therefore we split the functionality of `.ofPPFormat` into
`.ofFormatWithInfo` and `.ofLazy`,
and use `.ofLazy` to compute the more complex error message of `apply`.
Fixes#3232.
---------
Co-authored-by: David Thrane Christiansen <david@davidchristiansen.dk>
Co-authored-by: Wojciech Nawrocki <wjnawrocki@protonmail.com>
The new Lake build monitor is now more selective, accurate, and prettier
in what it prints.
**Key Changes:**
* Poll jobs at a fixed frequency (100ms), updating the caption and
finished job count.
* Add `action` field to jobs to record information about what jobs do.
It enables distinguishing between jobs which build something, fetch from
a store, or reload logs from the cache.
* At standard verbosity, print build captions only when a job is know to
build or fetch something (i.e., `action >= .fetch`).
* Add an icon and color to job captions based on their log-level / build
status. Also add color to levels in logs.
* Add `--ansi`/`--no-ansi` to toggle Lake's use of ANSI escape codes.
* Fix some `v4.8.0-rc1` bugs and `--old`.
Closes#2822.
The `simp` tactic uses a discrimination tree to select candidate
theorems that will be used to rewrite an expression. This indexing data
structure minimizes the number of theorems that need to be tried and
improves performance. However, indexing modulo reducibility is
challenging, and a theorem that could be applied, when taking reduction
into account, may be missed. For example, suppose we have a `simp`
theorem `foo : forall x y, f x (x, y).2 = y`, and we are trying to
simplify the expression `f a b <= b`. `foo` will not be tried by `simp`
because the second argument of `f a b` is not a projection of a pair.
However, `f a b` is definitionally equal to `f a (a, b).2` since we can
reduce `(a, b).2`.
In Lean 3, we had a much simpler indexing data structure where only the
head symbol was taken into account. For the theorem `foo`, the head
symbol is `f`. Thus, the theorem would be considered by `simp`.
This commit adds the option `Simp.Config.index`. When `simp (config := {
index := false })`, only the head symbol is considered when retrieving
theorems, as in Lean 3. Moreover, if `set_option diagnostics true`,
`simp` will check whether every applied theorem would also have been
applied if `index := true`, and report them. This feature can help users
diagnose tricky issues in code that has been ported from libraries
developed using Lean 3 and then ported to Lean 4. In the following
example, it will report that `foo` is a problematic theorem.
```lean
opaque f : Nat → Nat → Nat
@[simp] theorem foo : f x (x, y).2 = y := by sorry
example : f a b ≤ b := by
set_option diagnostics true in
simp (config := { index := false })
```
In the example above, the following diagnostic message is produced.
```lean
[simp] theorems with bad keys
foo, key: [f, *, Prod.1, Prod.mk, Nat, Nat, *, *]
```
With the information above, users can annotate theorems such as `foo`
using `no_index` for problematic subterms.
Example:
```lean
opaque f : Nat → Nat → Nat
@[simp] theorem foo : f x (no_index (x, y).2) = y := by sorry
example : f a b ≤ b := by
simp -- `foo` is still applied
```
cc @semorrison
cc @PatrickMassot
