This PR fixes freeing memory accidentally retained for each document
version in the language server on certain elaboration workloads. The
issue must have existed since 4.18.0.
This PR adds an explicit normalization layer for ring constraints in the
`grind linarith` module. For example, it will be used to clean up
denominators when the ring is a field.
This PR renames the `cutsat` tactic to `lia` for better alignment with
standard terminology in the theorem proving community.
`cutsat` still works but now emits a deprecation warning and suggests
using `lia` instead via "Try this:". Both tactics have identical
behavior.
Co-authored-by: Claude <noreply@anthropic.com>
This PR cleans up the API around `String.find` and moves it uniformly to
the new position types `String.ValidPos` and `String.Slice.Pos`
Overview:
- To search for a character, character predicate, string or slice in a
string or slice `s`, use `s.find?` or `s.find`.
- To do the same, but starting at a position `p` of a string or slice,
use `p.find?` or `p.find`.
- To do the same but between two positions `p` and `q`, construct the
slice from `p` to `q` and then use `find?` or `find` on that.
- To search backwards, all of the above applies, except that the
function is called `revFind?`, there is no non-question-mark version
(use `getD` if there is a sane default return value in your specific
application), and that you can only search for characters and character
predicates, not strings or slices.
This PR ensures that users can provide `grind` proof parameters whose
types are not `forall`-quantified. Examples:
```lean
opaque f : Nat → Nat
axiom le_f (a : Nat) : a ≤ f a
example (a : Nat) : a ≤ f a := by
grind [le_f a]
example (a b : α) (h : ∀ x y : α, x = y) : a = b := by
grind [h a b]
```
This PR redefines `front` and `back` on `String` to go through
`String.Slice` and adds the new `String` functions `front?`, `back?`,
`positions`, `chars`, `revPositions`, `revChars`, `byteIterator`,
`revBytes`, `lines`.
This PR adds `CoreM.toIO'`, the analogue of `CoreM.toIO` dropping the
state from the return type, and similarly for `TermElabM.toIO'` and
`MetaM.toIO'`.
This PR introduces a new `grind` option, `funCC` (enabled by default),
which extends congruence closure to *function-valued* equalities. When
`funCC` is enabled, `grind` tracks equalities of **partially applied
functions**, allowing reasoning steps such as:
```lean
a : Nat → Nat
f : (Nat → Nat) → (Nat → Nat)
h : f a = a
⊢ (f a) m = a m
g : Nat → Nat
f : Nat → Nat → Nat
h : f a = g
⊢ f a b = g b
```
Given an application `f a₁ a₂ … aₙ`, when `funCC := true` and function
equality is enabled for `f`, `grind` generates and tracks equalities for
all partial applications:
* `f a₁`
* `f a₁ a₂`
* …
* `f a₁ a₂ … aₙ`
This allows equalities such as `f a₁ = g` to propagate through further
applications.
**When is function equality enabled for a symbol?**
Function equality is enabled for `f` in the following cases:
1. `f` is **not a constant** (e.g., a lambda, a local function, or a
function parameter).
2. `f` is a **structure field projection**, provided the structure is
**not a `class`**.
3. `f` is a constant marked with `@[grind funCC]`
Users can also enable function equality for specific constants in a
single call using:
```lean
grind [funCC f, funCC g]
```
**Examples:**
```lean
example (m : Nat) (a : Nat → Nat) (f : (Nat → Nat) → (Nat → Nat)) (h : f a = a) :
f a m = a m := by
grind
example (m : Nat) (a : Nat → Nat) (f : (Nat → Nat) → (Nat → Nat)) (h : f a = a) :
f a m = a m := by
fail_if_success grind -funCC -- fails if `funCC` is disabled
grind
```
```lean
example (a b : Nat) (g : Nat → Nat) (f : Nat → Nat → Nat) (h : f a = g) :
f a b = g b := by
grind
example (a b : Nat) (g : Nat → Nat) (f : Nat → Nat → Nat) (h : f a = g) :
f a b = g b := by
fail_if_success grind -funCC
grind
```
**Enabling per-symbol with parameters or attributes**
```lean
opaque f : Nat → Nat → Nat
opaque g : Nat → Nat
example (a b c : Nat) : f a = g → b = c → f a b = g c := by
grind [funCC f, funCC g]
attribute [grind funCC] f g
example (a b c : Nat) : f a = g → b = c → f a b = g c := by
grind
```
This feature substantially improves `grind`’s support for higher-order
and partially-applied function equalities, while preserving
compatibility with first-order SMT behavior when `funCC` is disabled.
Closes#11309
This PR significantly changes the signature of the `ToIterator` type
class. The obtained iterators' state is no longer dependently typed and
is an `outParam` instead of being bundled inside the class. Among other
benefits, `simp` can now rewrite inside of `Slice.toList` and
`Slice.toArray`. The downside is that we lose flexibility. For example,
the former combinator-based implementation of `Subarray`'s iterators is
no longer feasible because the states are dependently typed. Therefore,
this PR provides a hand-written iterator for `Subarray`, which does not
require a dependently typed state and is faster than the previous one.
Converting a family of dependently typed iterators into a simply typed
one using a `Sigma`-state iterator generates forbiddingly bad code, so
that we do provide such a combinator. This PR adds a benchmark for this
problem.
This PR improves the support for `Fin n` in `grind` when `n` is not a
numeral.
- `toInt (0 : Fin n) = 0` in `grind lia`.
- `Fin.mk`-applications are treated as interpreted terms in `grind lia`.
- `Fin.val` applications are suppressed from `grind lia`
counterexamples.
This PR fixes a breakage in Lake's TOML test caused by String API
changes. It also removes a JSON parser workaround that has since been
fixed, and it more generally polishes up the code.
This PR fixes an issue affecting `grind -revert`. In this mode, assigned
metavariables in hypotheses were not being instantiated. This issue was
affecting two files in Mathlib.
This PR fixes a local declaration internalization in `grind` that was
exposed when using `grind -revert`. This bug was affecting a `grind`
proof in Mathlib.
This PR makes the specializer (correctly) share more cache keys across
invocations, causing us to produce less code bloat.
We observed that in functions with lots of specialization, sometimes
cache keys are defeq but not BEq because one has unused let decls
(introduced by specialization) that the other doesn't. This PR resolves
this conflict by erasing unused let decls from specializer cache keys.
This PR improves the error message encountered in the case of a type
class instance resolution failure, and adds an error explanation that
discusses the common new-user case of binary operation overloading and
points to the `trace.Meta.synthInstance` option for advanced debugging.
## Example
```lean4
def f (x : String) := x + x
```
Before:
```
failed to synthesize
HAdd String String ?m.5
Hint: Additional diagnostic information may be available using the `set_option diagnostics true` command.
```
After:
```
failed to synthesize instance of type class
HAdd String String ?m.5
Hint: Type class instance resolution failures can be inspected with the `set_option trace.Meta.synthInstance true` command.
Error code: lean.failedToSynthesizeTypeclassInstance
[View explanation](https://lean-lang.org/doc/reference/latest/find/?domain=Manual.errorExplanation&name=lean.failedToSynthesizeTypeclassInstance)
```
The error message is changed in three important ways:
* Explains *what* failed to synthesize, using the "type class"
terminology that's more likely to be recognized than the "instance"
terminology
* Points to the `trace.Meta.synthInstance` option which is otherwise
nearly undiscoverable but is quite powerful (see also
leanprover/reference-manual#663 which is adding commentary on this
option)
* Gives an error explanation link (which won't actually work until the
next release after this is merged) which prioritizes the common-case
explanation of using the wrong binary operation
This PR removes all code that sets the `Option.Decl.group` field, which
is unused and has no clearly documented meaning.
The actual removal of the field would be #11305.
This PR renames the CTests tests to use filenames as test names. So
instead of
```
2080 - leanruntest_issue5767.lean (Failed)
```
we get
```
2080 - tests/lean/run/issue5767.lean (Failed)
```
which allows Ctrl-Click’ing on them in the VSCode terminal.
This PR renames congruence lemmas for union on
`DHashMap`/`HashMap`/`HashSet`/`DTreeMap`/`TreeMap`/`TreeSet` to fit the
convention of being in the `Equiv` namespace.
This PR fixes a bug in the propagation rules for `ite` and `dite` used
in `grind`. The bug prevented equalities from being propagated to the
satellite solvers. Here is an example affected by this issue.
```lean
example
[LE α] [LT α] [Std.IsLinearOrder α] [Std.LawfulOrderLT α]
[Lean.Grind.CommRing α] [DecidableLE α] [Lean.Grind.OrderedRing α]
(a b c : α) :
(if a - b ≤ -(a - b) then -(a - b) else a - b) ≤
((if a - c ≤ -(a - c) then -(a - c) else a - c) + if c - d ≤ -(c - d) then -(c - d) else c - d) +
if b - d ≤ -(b - d) then -(b - d) else b - d := by
grind
```
This PR adds support for decidable equality of empty lists and empty
arrays. Decidable equality for lists and arrays is suitably modified so
that all diamonds are definitionally equal.
Following #9302, the strong condition of definitionally equal under
`with_reducible_and_instances` is tested. This also moves some of the
comments added in #9302 out of docstrings.
---------
Co-authored-by: Aaron Liu <aaronliu2008@outlook.com>
Co-authored-by: Eric Wieser <wieser.eric@gmail.com>
This PR renames `String.replaceStartEnd` to `String.slice`,
`String.replaceStart` to `String.sliceFrom`, and `String.replaceEnd` to
`String.sliceTo`, and similar for the corresponding functions on
`String.Slice`.
This PR adds several lemmas that relate
`getMin`/`getMin?`/`getMin!`/`getMinD` and insertion to the empty
(D)TreeMap/TreeSet and their extensional variants.
---------
Co-authored-by: Markus Himmel <markus@himmel-villmar.de>
Global `attribute` commands on non-local declarations are impossible to
track granularly a priori and so should be preserved by `shake` by
default. A new `shake` option could be added to ignore these
dependencies for evaluation.
This PR adds `Std.Slice.Pattern` instances for `p : Char -> Prop` as
long as `DecidablePred p`, to allow things like `"hello".dropWhile (· =
'h')`.
To achieve this, we refactor `ForwardPattern` and friends to be
"non-uniform", i.e., the class is now `ForwardPattern pat`, not
`ForwardPattern ρ` (where `pat : ρ`).
This PR provides intersection operation for
`ExtDHashMap`/`ExtHashMap`/`ExtHashSet` and proves several lemmas about
it.
---------
Co-authored-by: Markus Himmel <markus@himmel-villmar.de>
This PR provides intersection on `DTreeMap`/`TreeMap`/`TreeSet`and
provides several lemmas about it.
---------
Co-authored-by: Markus Himmel <markus@himmel-villmar.de>
This PR adds a function `String.Slice.length`, with the following
deprecation string: There is no constant-time length function on slices.
Use `s.positions.count` instead, or `isEmpty` if you only need to know
whether the slice is empty.
This PR adds the alias `String.Slice.any` for `String.Slice.contains`.
It would probably be even better to only have one, but we don't have a
good mechanism for pointing people looking for one towards the other, so
an alias it is for now.
This PR splits the single grind_lint.lean test (50+ seconds) into 7
separate files that each run in under 7 seconds:
- grind_lint_list.lean (5.7s): List namespace with exceptions
- grind_lint_array.lean (4.6s): Array namespace
- grind_lint_bitvec.lean (3.9s): BitVec namespace with exceptions
- grind_lint_std_hashmap.lean (6.8s): Std hash map/set namespaces
- grind_lint_std_treemap.lean (~6s): Std tree map/set namespaces
- grind_lint_std_misc.lean (~5s): Std.Do, Std.Range, Std.Tactic
- grind_lint_misc.lean (5.5s): All other non-Lean namespaces
Each file maintains complete namespace coverage and preserves all
existing exceptions. The split enables better CI parallelization and
faster feedback.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-authored-by: Claude <noreply@anthropic.com>
This PR implements support for arbitrary `grind` parameters. The feature
is similar to the one available in `simp`, where a proof term is treated
as a local universe-polymorphic lemma. This feature relies on `grind
-revert` (see #11248). For example, users can now write:
```lean
def snd (p : α × β) : β := p.2
theorem snd_eq (a : α) (b : β) : snd (a, b) = b := rfl
/--
trace: [grind.ematch.instance] snd_eq (a + 1): snd (a + 1, Type) = Type
[grind.ematch.instance] snd_eq (a + 1): snd (a + 1, true) = true
-/
#guard_msgs (trace) in
set_option trace.grind.ematch.instance true in
example (a : Nat) : (snd (a + 1, true), snd (a + 1, Type), snd (2, 2)) = (true, Type, snd (2, 2)) := by
grind [snd_eq (a + 1)]
```
Note that in the example above, `snd_eq` is instantiated only twice, but
with different universe parameters.
As described in #11248, the new feature cannot be used with `grind
+revert`.
