This PR adds a `sym =>` tactic that enters an interactive symbolic
simulation
mode built on `grind`. Unlike `grind =>`, it does not eagerly introduce
hypotheses or apply by-contradiction, giving users explicit control over
`intro`, `apply`, and `internalize` steps.
New tactics available in `sym =>` mode:
- `intro` / `intros`: introduce binders and internalize into the E-graph
by
default. Use `intro~` or `intro (internalize := false)` to skip
internalization.
- `apply t`: apply backward rules with caching for `repeat`.
- `internalize` / `internalize_all`: internalize hypotheses into the
E-graph.
- `by_contra`: apply proof by contradiction, negating the target.
Satellite solvers (`lia`, `ring`, `linarith`) automatically introduce
remaining
binders and apply by-contradiction in `sym =>` mode, matching their
behavior in
default tactic mode. All existing `grind =>` tactics (`finish`,
`instantiate`,
`cases`, etc.) also work in `sym =>` mode. The sym-specific tactics are
guarded
and rejected in regular `grind =>` mode.
```lean
example (x : Nat) : myP x → myQ x := by
sym [myP_myQ] =>
intro h
finish
example (x y z : Nat) : x > 1 → x + y + z > 0 := by
sym =>
lia
```
This PR fixes a regression introduced in Lean 4.29.0-rc2 where `simp` no
longer simplifies inside type class instance arguments due to the
`backward.isDefEq.respectTransparency` change. This breaks proofs where
a term like `(a :: l).length` appears both in the main expression and
inside implicit instance arguments (e.g., determining a `BitVec` width).
**The problem:** After `simp only [List.length_cons]`, the main
expression has `l.length + 1` but instances still have `(a ::
l).length`. Since `simp` no longer simplifies inside instances, and
`isDefEq` won't unfold `List.length` at the default transparency,
subsequent lemma applications fail.
**Reproducer** (from Son Ho, reported by Sebastian Ullrich):
```lean
theorem BitVec.getElem!_eq_testBit_toNat {w : Nat} (x : BitVec w) (i : Nat) :
x[i]! = x.toNat.testBit i := by sorry
example (l : List Nat) (a : Nat) (j : Nat) :
(0#((a :: l).length))[j]! = (0#((a :: l).length)).toNat.testBit j := by
simp only [List.length_cons]
simp only [BitVec.getElem!_eq_testBit_toNat] -- works in 4.28.0-rc1, fails in 4.29.0-rc6
```
**The fix:** Mark `List.length` as `@[implicit_reducible]`, allowing
`isDefEq` to unfold it when checking implicit arguments. Several proofs
that previously needed a trailing `rfl` after `simp` now close directly,
since `simp` can see through `List.length` in more positions.
**Longer term:** The root cause is that `GetElem` carries complex proof
obligations in its type class instances, making implicit arguments
sensitive to definitional equality of collection sizes. We are
considering a redesign with a noncomputable `GetElemV` variant based on
`Nonempty` that avoids these casts entirely, but that is a larger change
planned for a future release.
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR changes the interaction between `@[cbv_opaque]` and
`@[cbv_eval]`
attributes in the `cbv` tactic. Previously, `@[cbv_opaque]` completely
blocked
all reduction including `@[cbv_eval]` rewrite rules. Now, `@[cbv_eval]`
rules
can fire on `@[cbv_opaque]` constants, allowing users to provide custom
rewrite
rules without exposing the full definition. Equation theorems, unfold
theorems,
and kernel reduction remain suppressed for opaque constants.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR introduces the `Headers` data type, that provides a good and
convenient abstraction for parsing, querying, and encoding HTTP/1.1
headers.
This contains the same code as #10478, divided into separate pieces to
facilitate easier review.
The pieces of this feature are:
- Core data structures: #12126
- Headers: #12127
- URI: #12128
- Body: #12144
- H1: #12146
- Server: #12151
- Client:
---------
Co-authored-by: Rob23oba <152706811+Rob23oba@users.noreply.github.com>
This PR fixes a segfault when running `idbgClientLoop`. `@[extern]`
expects that the function doesn't include erased arguments in the
signature; however, `@[export]` exports the function with all arguments,
including erased ones. This causes a function signature mismatch between
`idbgClientLoopImpl` and `idbgClientLoop`, causing segfaults. However,
instead of solving the deeper problem that `@[extern]` - `@[export]`
pairs can cause such problems, this PR removes the erased arguments from
`idbgClientLoopImpl` and replaces occurrences of `α` with `NonScalar`.
The tests need to run with certain environment variables set that only
cmake really knows and that differ between stages. Cmake could just set
the variables directly when running the tests and benchmarks, but that
would leave no good way to manually run a single benchmark. So cmake
generates some stage-specific scripts instead that set the required
environment variables.
Previously, those scripts were sourced directly by the individual
`run_*` scripts, so the env scripts of different stages would overwrite
each other. This PR changes the setup so they can instead be generated
next to each other. This also simplifies the `run_*` scripts themselves
a bit, and makes `tests/bench/build` less of a hack.
This PR fixes the `HSub PlainTime Duration` instance, which had its
operands reversed: it computed `duration - time` instead of `time -
duration`. For example, subtracting 2 minutes from `time("13:02:01")`
would give `time("10:57:59")` rather than the expected
`time("13:00:01")`. We also noticed that `HSub PlainDateTime
Millisecond.Offset` is similarly affected.
Closes#12918
This PR fixes a bug where `max u v` and `max v u` fail to match in
SymM's pattern matching. Both `processLevel` (Phase 1) and
`isLevelDefEqS` (Phase 2) treated `max` positionally, so `max u v ≠ max
v u` structurally even though they are semantically equal.
The fix has three parts:
- Eagerly normalize universe levels in patterns at creation time
(`preprocessDeclPattern`, `preprocessExprPattern`,
`mkSimprocPatternFromExpr`)
- Normalize the target level in `processLevel` before matching, using a
`where go` refactor
- Add `tryApproxMaxMax` to `processLevel` and `isLevelDefEqS`: when
positional `max/max` matching would fail, check if one argument from
each side matches structurally and match the remaining pair
Also moves `normalizeLevels` from `Grind.Util` to `Sym.Util` to avoid
code duplication, since both Sym and Grind need it.
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds eta reduction to the sym discrimination tree lookup
functions (`getMatch`, `getMatchWithExtra`, `getMatchLoop`). Without
this, expressions like `StateM Nat` that unfold to eta-expanded forms
`(fun α => StateT Nat Id α)` fail to match discrimination tree entries
for the eta-reduced form `(StateT Nat Id)`.
Also optimizes `etaReduce` with an early exit for non-lambda expressions
and removes a redundant `n == 0` check.
Includes a test verifying that `P (StateM Nat)` matches a disc tree
entry for `P (StateT Nat Id)`.
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR optimizes the `String.reduceEq`, `String.reduceNe`, and
`Sym.Simp` string equality simprocs to produce kernel-efficient proofs.
Previously, these used `String.decEq` which forced the kernel to run
UTF-8 encoding/decoding and byte array comparison, causing 86+ kernel
unfoldings on short strings.
The new approach reduces string inequality to `List Char` via
`String.ofList_injective`, then uses two strategies depending on the
difference:
- **Different characters at position `i`**: Projects to `Nat` via
`congrArg (fun l => (List.get!Internal l i).toNat)`, then uses
`Nat.ne_of_beq_eq_false rfl`. This avoids `Decidable` instances entirely
— the kernel only evaluates `Nat.beq` on two concrete natural numbers.
- **One string is a prefix of the other**: Uses `congrArg (List.drop n
·)` with `List.cons_ne_nil`, which is a definitional proof requiring no
`decide` step at all.
For equal strings, `eq_true rfl` avoids kernel evaluation entirely.
The shared proof construction is in `Lean.Meta.mkStringLitNeProof`
(`Lean/Meta/StringLitProof.lean`), used by both the standard simprocs
and the `Sym.Simp` ground evaluator.
Kernel max unfolds for `"hello" ≠ "foo"`: 86+ → 6.
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adjusts the JSON encoding of RPC references from `{"p": "n"}` to
`{"__rpcref": "n"}`. Existing clients will continue to work unchanged,
but should eventually move to the new format by advertising the
`rpcWireFormat` client capability.
- This came up in leanprover/vscode-lean4#712.
- The new encoding is far less likely to clash with real-world names,
and is now documented as a "reserved internal name".
- At 8 bytes vs. 1 byte, it incurs a ~5% size increase on the JSON size
of interactive terms, e.g. from 868KiB to 903KiB on the
leanprover/vscode-lean4#500 test.
- Make `deriving RpcEncodable` throw an error when it encounters the
reserved name. We cannot easily guard against clashes in user-provided
JSON, however, so we just assume it does not clash.
- Add a notion of *RPC wire format* with corresponding `rpcWireFormat`
client and server capabilities. The format before this PR is now called
`v0`, whereas here we implement `v1`. Existing clients should eventually
implement compatibility with `v1` (because doing so fixes the above
bug), but will continue to work in the meantime. The format may be
revised again in the future (but we don't expect to revise it so often
that semver would be useful).
- Document everything.
## Alternative designs (abandoned for now)
- Option 1. Add a method `$/lean/rpc/metadata` which, given the name of
an RPC method `foo`, returns metadata containing a description of where
the RPC refs in any return value of `foo` would be (essentially a
description of the structure of the return type).
- Option 2. Wrap every response to `$/lean/rpc/call` in such metadata.
This would be a different change to the wire format.
- To implement this in an extensible way, we extend `RpcEncodable` by a
`refPaths` field. But how does `refPaths` describe where the refs are?
- Option A. Emit the code of a JS method that extracts the refs. This is
maybe simplest, but it would leave non-JS clients (e.g. `lean.nvim`)
behind.
- Option B. Give the description in some query language. The query
language must be able to describe paths into arbitrary inductive types.
- The most popular option,
[JSONPath](https://www.rfc-editor.org/rfc/rfc9535), seemingly cannot
describe non-uniform paths (e.g. both the `a`s in `{a: 1, {b: {a:
2}}}`).
- [JMESPath](https://jmespath.org/) can describe non-uniform paths, and
has 'fully compliant' implementations in many languages, but doesn't
seem to handle recursive paths.
- The most expressive option is [jq](https://github.com/jqlang/jq), but
the most popular way to run it is via an Emscripten WASM blob in
[jq-web](https://github.com/fiatjaf/jq-web) which seems heavy. There is
[jqjs](https://github.com/mwh/jqjs) as well; I'm not sure how
production-ready that is.
This PR makes `@[cbv_opaque]` unconditionally block all evaluation of a
constant
by `cbv`, including `@[cbv_eval]` rewrite rules. Previously,
`@[cbv_eval]` could
bypass `@[cbv_opaque]`, and for bare constants (not applications),
`isOpaqueConst`
could fall through to `handleConst` which would unfold the definition
body.
The intended usage pattern is now: mark subterm-producing functions
(like
`DHashMap.insert`) as `@[cbv_opaque]` to prevent unfolding, and provide
`@[cbv_eval]` theorems on the *consuming* function (like
`DHashMap.contains`)
which pattern-matches against the opaque subterms.
This PR adds support for ignoring user defined borrow annotations. This
can be useful when defining
`extern`/`export` pairs as the `extern` might be infected by borrow
annotations while in `export`
they are already ignored.
This PR adds an `@[mvcgen_witness_type]` tag attribute, analogous to
`@[mvcgen_invariant_type]`, that allows users to mark types as witness
types. Goals whose type is an application of a tagged type are
classified as witnesses rather than verification conditions, and appear
in a new `witnesses` section in the `mvcgen` tactic syntax (before
`invariants`).
Witnesses are concrete values the prover supplies (inspired by
zero-knowledge proofs), as opposed to invariants (predicates maintained
across iterations) or verification conditions (propositions to prove).
The test uses a ZK-inspired example where a `SquareRootWitness` value
must be provided by the prover, with the resulting constraint
auto-discharged.
Changes:
- `src/Lean/Elab/Tactic/Do/Attr.lean`: register `@[mvcgen_witness_type]`
tag attribute and `isMVCGenWitnessType` helper
- `src/Lean/Elab/Tactic/Do/VCGen/Basic.lean`: add `witnesses` field to
`State`, three-way classification in `addSubGoalAsVC`
- `src/Std/Tactic/Do/Syntax.lean`: add `witnesses` section syntax
(before `invariants`), extract shared `goalDotAlt`/`goalCaseAlt` syntax
kinds
- `src/Lean/Elab/Tactic/Do/VCGen.lean`: extract shared
`elabGoalSection`, add `elabWitnesses`, wire up witness labeling and
elaboration
- `tests/elab/mvcgenWitnessType.lean`: end-to-end tests for
witness-only, witness with `-leave`, and combined witness+invariant
scenarios
🤖 Generated with [Claude Code](https://claude.com/claude-code)
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds `Invariant.withEarlyReturnNewDo`,
`StringInvariant.withEarlyReturnNewDo`, and
`StringSliceInvariant.withEarlyReturnNewDo` which use `Prod` instead of
`MProd` for the state tuple, matching the new do elaborator's output.
The existing `withEarlyReturn` definitions are reverted to `MProd` for
backwards compatibility with the legacy do elaborator. Tests and
invariant suggestions are updated to use the `NewDo` variants.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds an `@[mvcgen_invariant_type]` tag attribute so that users
can mark
custom types as invariant types for the `mvcgen` tactic. Goals whose
type is an
application of a tagged type are classified as invariants rather than
verification
conditions. The hard-coded check for `Std.Do.Invariant` is kept as a
fallback
until a stage0 update allows applying the attribute directly.
A follow-up PR (after a stage0 update) will apply
`@[mvcgen_invariant_type]` to
`Std.Do.Invariant` and remove the hard-coded fallback.
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds `optType` support to the `doPatDecl` parser, allowing
`let ⟨width, height⟩ : Nat × Nat ← action` in do-notation. Previously,
only
the less ergonomic `let ⟨width, height⟩ : Nat × Nat := ← action`
workaround
was available. The type annotation is propagated to the monadic action
as an
expected type, matching `doIdDecl`'s existing behavior.
Both the legacy and new (BuiltinDo) elaborators are updated.
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds a `cbv_simproc` system for the `cbv` tactic, mirroring
simp's `simproc` infrastructure but tailored to cbv's three-phase
pipeline (`↓` pre, `cbv_eval` eval, `↑` post). User-defined
simplification procedures are indexed by discrimination tree patterns
and dispatched during cbv normalization.
New syntax:
- `cbv_simproc [↓|↑|cbv_eval] name (pattern) := body` — define and
register a cbv simproc
- `cbv_simproc_decl name (pattern) := body` — define without registering
- `attribute [cbv_simproc [↓|↑|cbv_eval]] name` — register an existing
declaration
- `builtin_cbv_simproc` variants for the internal use
New files:
- `src/Init/CbvSimproc.lean` — syntax and macros
- `src/Lean/Meta/Tactic/Cbv/CbvSimproc.lean` — types, env extensions,
registration, dispatch
- `src/Lean/Elab/Tactic/CbvSimproc.lean` — pattern elaboration and
command elaborators
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR add support for erasing `@[cbv_eval]` annotations using
`attribute [-cbv_eval]`, mirroring the existing `@[-simp]` mechanism for
simp lemmas.
The `CbvEvalEntry` now tracks the original declaration name (`origin`)
so that inverted theorems (`@[cbv_eval ←]`) can be erased by their
original name. The `CbvEvalState` stores individual entries alongside
the composed `Theorems` discrimination tree, allowing the tree to be
rebuilt from remaining entries after erasure. Erasure is properly scoped
via `modifyState`, so `attribute [-cbv_eval]` inside a `section` is
reverted when the section ends.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
This PR adds a `set_option grind.unusedLemmaThreshold` that, when set to
N > 0
and `grind` succeeds, reports E-matching lemmas that were activated at
least N
times but do not appear in the final proof term. This helps identify
`@[grind]`
annotations that fire frequently without contributing to proofs.
🤖 Prepared with Claude Code
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds a `result? : Option TraceResult` field to `TraceData` and
populates it in `withTraceNode` and `withTraceNodeBefore`, so that
metaprograms walking trace trees can determine success/failure
structurally instead of string-matching on emoji.
`TraceResult` has three cases: `.success` (checkEmoji), `.failure`
(crossEmoji), and `.error` (bombEmoji, exception thrown). An
`ExceptToTraceResult` typeclass converts `Except` results to
`TraceResult` directly, with instances for `Bool` and `Option`.
`TraceResult.toEmoji` converts back to emoji for display. This replaces
the previous `ExceptToEmoji` typeclass — `TraceResult` is now the
primary representation rather than being derived from emoji strings.
`withTraceNodeBefore` (used by `isDefEq`) uses
`ExceptToTraceResult.toTraceResult` directly, correctly handling `Bool`
(`.ok false` = failure) and `Option` (`.ok none` = failure), with
`Except.error` mapping to `.error`.
For `withTraceNode`, `result?` defaults to `none`. Callers can pass
`mkResult?` to provide structured results; when set, the corresponding
emoji is auto-prepended to the message.
Motivated by mathlib's `#defeq_abuse` diagnostic tactic
(https://github.com/leanprover-community/mathlib4/pull/35750) which
currently string-matches on emoji to determine trace node outcomes. See
https://leanprover.zulipchat.com/#narrow/channel/113488-general/topic/backward.2EisDefEq.2ErespectTransparency🤖 Prepared with Claude Code
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR makes notations such as `∨`, `∧`, `≤`, and `≥` pretty print
using ASCII versions when `pp.unicode` is false.
Continuation of #10373. Closes#1056.
This will require followup with a stage0 update and removal of the
ASCII-only `<=` and `>=` syntaxes from `Init.Notation`, for cleanup.
This PR optimizes the handling of `match_same_ctor.het` to make it emit
nice match trees as opposed to unoptimized CPS style code.
`match_same_ctor.het` is essentially a specialized kind of matcher where
we know that two objects are built from the same constructor and we wish
to call a continuation on their data. This means for every constructor
that contains data `het` takes one closure as an argument. Then after
matching on one of the objects every closure but the one relevant for
the match is released in every match arm, causing quadratic code
generation. This PR ensures that the `het` declarations get inlined and
then further processed by ordinary matcher and casesOn compilation,
thereby removing all of the continuations from the compiled code.
This PR replaces the default `instantiateMVars` implementation with a
two-pass variant that fuses fvar substitution into the traversal,
avoiding separate `replace_fvars` calls for delayed-assigned MVars and
preserving sharing. The old single-pass implementation is removed
entirely.
The previous implementation had quadratic complexity when instantiating
expressions with long chains of nested delayed-assigned MVars. Such
chains arise naturally from repeated `intro`/`apply` tactic sequences,
where each step creates a new delayed assignment wrapping the previous
one. The new two-pass approach resolves the entire chain in a single
traversal with a fused fvar substitution, reducing this to linear
complexity.
### Terminology (used in this PR and in the source)
* **Direct MVar**: an MVar that is not delayed-assigned.
* **Pending MVar**: the direct MVar stored in a
`DelayedMetavarAssignment`.
* **Assigned MVar**: a direct MVar with an assignment, or a
delayed-assigned MVar with an assigned pending MVar.
* **MVar DAG**: the directed acyclic graph of MVars reachable from the
expression.
* **Resolvable MVar**: an MVar where all MVars reachable from it
(including itself) are assigned.
* **Updateable MVar**: an assigned direct MVar, or a delayed-assigned
MVar that is resolvable but not reachable from any other resolvable
delayed-assigned MVar.
In the MVar DAG, the updateable delayed-assigned MVars form a cut (the
**updateable-MVar cut**) with only assigned MVars behind it and no
resolvable delayed-assigned MVars before it.
### Two-pass architecture
**Pass 1** (`instantiate_direct_fn`): Traverses all MVars and
expressions reachable from the initial expression and instantiates all
updateable direct MVars (updating their assignment with the result),
instantiates all level MVars, and determines if there are any updateable
delayed-assigned MVars.
**Pass 2** (`instantiate_delayed_fn`): Only run if pass 1 found
updateable delayed-assigned MVars. Has an **outer** and an **inner**
mode, depending on whether it has crossed the updateable-MVar cut.
In outer mode (empty fvar substitution), all MVars are either unassigned
direct MVars (left alone), non-updateable delayed-assigned MVars
(pending MVar traversed in outer mode and updated with the result), or
updateable delayed-assigned MVars. When a delayed-assigned MVar is
encountered, its MVar DAG is explored (via `is_resolvable_pending`) to
determine if it is resolvable (and thus updateable). Results are cached
across invocations.
If it is updateable, the substitution is initialized from its arguments
and traversal continues with the value of its pending MVar in inner
mode. In inner mode (non-empty substitution), all encountered
delayed-assigned MVars are, by construction, resolvable but not
updateable. The substitution is carried along and extended as we cross
such MVars. Pending MVars of these delayed-assigned MVars are NOT
updated with the result (as the result is valid only for this
substitution, not in general).
Applying the substitution in one go, rather than instantiating each
delayed-assigned MVar on its own from inside out, avoids the quadratic
overhead of that approach when there are long chains of delayed-assigned
MVars.
**Write-back behavior**: Pass 2 writes back the normalized pending MVar
values of delayed-assigned MVars above the updateable-MVar cut (the
non-resolvable ones whose children may have been resolved). This is
exactly the right set: these MVars are visited in outer mode, so their
normalized values are suitable for storing in the mctx. MVars below the
cut are visited in inner mode, so their intermediate values cannot be
written back.
### Pass 2 scope-tracked caching
A `scope_cache` data structure ensures that sharing is preserved even
across different delayed-assigned MVars (and hence with different
substitutions), when possible. Each `visit_delayed` call pushes a new
scope with fresh fvar bindings. The cache correctly handles cross-scope
reuse, fvar shadowing, and late-binding via generation counters and
scope-level tracking.
The `scope_cache` has been formally verified:
`tests/elab/scopeCacheProofs.lean` contains a complete Lean proof that
the lazy generation-based implementation refines the eager
specification, covering all operations (push, pop, lookup, insert)
including the rewind lazy cleanup with scope re-entry and degradation.
The key correctness invariant is inter-entry gen list consistency
(GensConsistent), which, unlike per-entry alignment with `currentGens`,
survives pop+push cycles.
### Behavioral differences from original `instantiateMVars`
The implementation matches the original single-pass `instantiateMVars`
behavior with one cosmetic difference: the new implementation
substitutes fvars inline during traversal rather than constructing
intermediate beta-redexes, producing more beta-reduced terms in some
edge cases. This changes the pretty-printed output for two elab tests
(`1179b`, `depElim1`) but all terms remain definitionally equal.
### Tests
Correctness and performance tests for the new implementation were added
in #12808.
### Files
- `src/library/instantiate_mvars.cpp` — C++ implementation of both
passes (replaces `src/kernel/instantiate_mvars.cpp`)
- `src/library/scope_cache.h` — scope-aware cache data structure
- `src/Lean/MetavarContext.lean` — exported accessors for
`DelayedMetavarAssignment` fields
- `tests/elab/scopeCacheProofs.lean` — formal verification of
`scope_cache` correctness
- `tests/elab/1179b.lean.out.expected`,
`tests/elab/depElim1.lean.out.expected` — updated expected output
Co-authored-by: Claude <noreply@anthropic.com>
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR changes the way the linting for `linter.unusedSimpArgs` gets the
value from the environment. This is achieved by using the appropriate
helper functions defined in `Lean.Linter.Basic`.
The following now compiles without warning
```lean4
set_option linter.all false in
example : True := by simp [False]
```
Fixes#12559
This PR makes the `omit`, `unusedSectionVars` and `loopingSimpArgs`
linters respect the `linter.all` option:
when `linter.all` is set to false (and the respective linter option is
unset), the linter should not report errors.
Similarly to #12559, these linters should honour the linter.all flag
being set to false. These are all remaining occurrences of this pattern.
This fixes an issue analogous to #12559.
This PR and #12560 fix all occurrences of this pattern. (The only
question is around `RCases.linter.unusedRCasesPattern`: should this also
respect this? I have left this alone for now.)
Co-authored-by: fiforeach <249703130+fiforeach@users.noreply.github.com>
This PR modifies `#eval e` to elaborate `e` with section variables in
scope. While evaluating expressions with free variables is not possible,
this lets `#eval` give a better error message than "unknown identifier."
Example:
```lean
section
variable (n : Nat)
/-- error: Cannot evaluate, contains free variable `n` -/
#guard_msgs in #eval n
end
```
The error is localized to `#eval`. It would be more friendly if the
error were to be placed on uses of free variables.
[Zulip
discussion](https://leanprover.zulipchat.com/#narrow/channel/270676-lean4/topic/Unknown.20identifier.20error.20messages.20for.20.60.23eval.60/near/560864544)
This PR changes the elaboration of the `structure`/`class` commands so
that default values have later fields in context as well. This allows
field defaults to depend on fields that come both before and after them.
While this was already the case for inherited fields to some degree, it
now applies uniformly to all fields. Additionally, when elaborating the
default value for a field, all fields that depend on it are cleared from
the context to avoid situations where the default value depends on
itself.
This addresses an issue reported by Aaron Liu [on
Zulip](https://leanprover.zulipchat.com/#narrow/channel/270676-lean4/topic/default.20structure.20values.20can.20depend.20on.20themselves/near/578014370).
This PR changes "structure-like" terminology to "non-recursive
structure" across internal documentation, error messages, the
metaprogramming API, and the kernel, to clarify Lean's type theory. A
*structure* is a one-constructor inductive type with no indices — these
can be created by either the `structure` or `inductive` commands — and
are supported by the primitive `Expr.proj` projections. Only
*non-recursive* structures have an eta conversion rule. The PR
description contains the APIs that were renamed.
Addresses RFC #5891, which proposed this rename. The change is motivated
by the need to distinguish between `structure`-defined structures,
structures, and non-recursive structures. Especially since #5783, which
enabled the `structure` command to define recursive structures,
"structure-like" has been easy to misunderstand.
Changes:
- Kernel: `is_structure_like()` -> `is_non_rec_structure()`
- `Lean.isStructureLike` -> `Lean.isNonRecStructure`
- `Lean.matchConstStructLike` -> `Lean.matchConstNonRecStructure`
- `Lean.getStructureLikeCtor?` -> `Lean.getNonRecStructureCtor?`
- `Lean.getStructureLikeNumFields` -> `Lean.getNonRecStructureNumFields`
- `Lean.Expr.proj`: extended and corrected documentation (note: despite
the fact that not every projection can be written as a recursor
application, I left in this claim since it seems good to document a
more-restrictive specification, and some users have requested the kernel
be more restrictive in this way)
Closes#5891
This PR migrates most remaining tests to the new test suite. It also
completes the migration of directories like `tests/lean/run`, meaning
that PRs trying to add tests to those old directories will now fail.
This PR solves three distinct issues with the handling of
`ite`/`dite`,`decide`.
1) We prevent the simprocs from picking up `noncomputable`, `Classical`
instances, such as `Classical.propDecidable`, when simplifying the
proposition in `ite`/`dite`/`decide`.
2) We fix a type mismatch occurring when the condition/proposition is
unchanged but the `Decidable` instance is simplified.
3) If we rewrite the proposition from `c` to `c'` and the evaluation of
the original instance `Decidable c` gets stuck we try fallback path of
of obtaining `Decidable c'` instance and evaluating it. This matters
when the instance is evaluated via `cbv_eval` lemmas.
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adjusts the module parser to set the leading whitespace of the
first token to the whitespace up to that token. If there are no actual
tokens in the file, the leading whitespace is set on the final (empty)
EOI token. This ensures that we do not lose the initial whitespace (e.g.
comments) of a file in `Syntax`.
(Tests generated/adjusted by Claude)
Co-authored-by: Claude Sonnet 4.6 <noreply@anthropic.com>
This PR adds tests and a benchmark exercising `instantiateMVars` on
metavariable assignment graphs with nested delayed assignments, in
preparation for optimizing the delayed mvar resolution path.
- `tests/elab/instantiateMVarsShadow.lean`: Two test cases for
correctness when the same fvar is bound to different values at different
scope levels (fvar shadowing and late-bind patterns). A buggy cache
could return a stale result from one scope level in another.
- `tests/elab/instantiateMVarsSharing.lean`: Verifies correct resolution
and object sharing on a graph with nested delayed mvars producing `∀ s,
(s = s → (s = s) ∧ (s = s)) ∧ (s = s)`.
- `tests/elab_bench/delayed_assign.lean`: Constructs an O(n²) delayed
mvar graph (n=700) and measures `instantiateMVars` resolution time,
calibrated to ~1s total elaboration.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR adds a warning to any `def` of class type that does not also
declare an appropriate reducibility.
The warning check runs after elaboration (checking the actual
reducibility status via `getReducibilityStatus`) rather than
syntactically checking modifiers before elaboration. This is necessary
to accommodate patterns like `@[to_additive (attr :=
implicit_reducible)]` in Mathlib, where the reducibility attribute is
applied during `.afterCompilation` by another attribute, and would be
missed by a purely syntactic check.
---------
Co-authored-by: Paul Reichert <6992158+datokrat@users.noreply.github.com>
Co-authored-by: Kim Morrison <kim@tqft.net>
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR moves the universe-level-count check from
`unfold_definition_core` into `is_delta`, establishing the invariant
that if `is_delta` succeeds then `unfold_definition` also succeeds. This
prevents a crash (SIGSEGV or garbled error) that occurred when call
sites in `lazy_delta_reduction_step` unconditionally dereferenced the
result of `unfold_definition` even on a level-parameter-count mismatch.
Additionally, moves the `is_prop` check for theorem types in
`add_theorem` to occur after `check_constant_val`, so the type is
verified to be well-formed before `is_prop` evaluates it. This prevents
`is_prop` from being called on an ill-typed term when a malformed
theorem declaration is supplied.
Fixes#10577.
---------
Co-authored-by: copilot-swe-agent[bot] <198982749+Copilot@users.noreply.github.com>
Co-authored-by: nomeata <148037+nomeata@users.noreply.github.com>
This PR adds a `set_option cbv.maxSteps N` option that controls the
maximum
number of simplification steps the `cbv` tactic performs. Previously the
limit
was hardcoded to the `Sym.Simp.Config` default of 100,000 with no way
for
users to override it. The option is threaded through `cbvCore`,
`cbvEntry`,
`cbvGoal`, and `cbvDecideGoal`.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
---------
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR moves cbv tests to the correct test directories. `cbv4.lean` is
a
straightforward elaboration test and is moved to `tests/elab/`. The AES
and ARM
load/store tests are performance-oriented stress tests and are moved to
`tests/elab_bench/`.
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
This PR makes the compiler removes arguments to join points that are
void, avoiding a bunch of dead
stores in the bytecode and the initial C (though LLVM was surely able to
optimize these away further
down the line already).
This PR skips the noncomputable pre-check in `processDefDeriving` when
the instance type is `Prop`. Since proofs are erased by the compiler,
computability is irrelevant for `Prop`-valued instances.
Previously (since https://github.com/leanprover/lean4/pull/12756),
`deriving instance` would reject instances that transitively depend on
noncomputable definitions, even when the class extends `Prop`. This came
up in mathlib where `Precoverage.IsStableUnderBaseChange` (a `Prop`
class) needs `deriving noncomputable instance` unnecessarily.
🤖 Prepared with Claude Code
Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
