This currently relies on the encoding pun of Nat.zero as the first
tagged constructor of Nat. Since Nat.succ is lowered to addition, it
makes sense to also lower Nat.zero to a zero literal. This might also
expose more optimization opportunities in the future.
This PR fixes IR constructor argument lowering to correctly handle an
irrelevant argument being passed for a relevant parameter in all cases.
This happened because constructor argument lowering (incompletely)
reimplemented general LCNF-to-IR argument lowering, and the fix is to
just adopt the generic helper functions. This is probably due to an
incomplete refactoring when the new compiler was still on a branch.
This PR fixes `toISO8601String` to produce a string that conforms to the
ISO 8601 format specification. The previous implementation separated the
minutes and seconds fragments with a `.` instead of a `:` and included
timezone offsets without the hour and minute fragments separated by a
`:`.
Closes#9235
This PR optimizes support for `Decidable` instances in `grind`. Because
`Decidable` is a subsingleton, the canonicalizer no longer wastes time
normalizing such instances, a significant performance bottleneck in
benchmarks like `grind_bitvec2.lean`. In addition, the
congruence-closure module now handles `Decidable` instances, and can
solve examples such as:
```lean
example (p q : Prop) (h₁ : Decidable p) (h₂ : Decidable (p ∧ q)) : (p ↔ q) → h₁ ≍ h₂ := by
grind
```
This PR fixes the bug that `collectAxioms` didn't collect axioms
referenced by other axioms. One of the results of this bug is that
axioms collected from a theorem proved by `native_decide` may not
include `Lean.trustCompiler`.
Closes#8840.
This PR makes `isDefEq` detect more stuck definitional equalities
involving smart unfoldings. Specifically, if `t =?= defn ?m` and `defn`
matches on its argument, then this equality is stuck on `?m`. Prior to
this change, we would not see this dependency and simply return `false`.
Fixes#8766.
Co-authored-by: Kyle Miller <kmill31415@gmail.com>
This PR improves the `congr` tactic so that it can handle function
applications with fewer arguments than the arity of the head function.
This also fixes a bug where `congr` could not make progress with
`Set`-valued functions in Mathlib, since `Set` was being unfolded and
making such functions have an apparently higher arity.
This addresses issue #2128 for the `congr` tactic, but not `simp` and
others.
This PR makes the logic and tactics of `Std.Do` universe polymorphic, at
the cost of a few definitional properties arising from the switch from
`Prop` to `ULift Prop` in the base case `SPred []`.
Co-authored-by: Sebastian Graf <sg@lean-fro.org>
This PR migrates usages of `Std.Range` to the new polymorphic ranges.
This PR unfortunately increases the transitive imports for
frequently-used parts of `Init` because the ranges now rely on iterators
in order to provide their functionality for types other than `Nat`.
However, iteration over ranges in compiled code is as efficient as
before in the examples I checked. This is because of a special
`IteratorLoop` implementation provided in the PR for this purpose.
There were two issues that were uncovered during migration:
* In `IndPredBelow.lean`, migrating the last remaining range causes
`compilerTest1.lean` to break. I have minimized the issue and came to
the conclusion it's a compiler bug. Therefore, I have not replaced said
old range usage yet (see #9186).
* In `BRecOn.lean`, we are publicly importing the ranges. Making this
import private should theoretically work, but there seems to be a
problem with the module system, causing the build to panic later in
`Init.Data.Grind.Poly` (see #9185).
* In `FuzzyMatching.lean`, inlining fails with the new ranges, which
would have led to significant slowdown. Therefore, I have not migrated
this file either.
This PR adds a benchmark for the rewriting engine of bv_decide, based on
a problem extracted from
SMT-LIB. Note that this problem has significant elaboration time itself
due to its sheer size though
the overall execution time is split approximately 50:50 between
elaboration and rewriting.
This PR improves the startup time for `grind ring` by generating the
required type classes on demand. This optimization is particularly
relevant for files that make hundreds of calls to `grind`, such as
`tests/lean/run/grind_bitvec2.lean`. For example, before this change,
`grind` spent 6.87 seconds synthesizing type classes, compared to 3.92
seconds after this PR.
This PR changes the `getLiteral` helper function of `elimDeadBranches`
to correctly handle inductives with constructors. This function is not
used as often as it could be, which makes this issue rare to hit outside
of targeted test cases.
This PR changes the compiler's specialization analysis to consider
higher-order params that are rebundled in a way that only changes their
`Prop` arguments to be fixed. This means that they get specialized with
a mere `@[specialize]`, rather than the compiler having to opt-in to
more aggressive parameter-specific specialization.
This PR tries to improve the E-matching pattern inference for `grind`.
That said, we still need better tools for annotating and maintaining
`grind` annotations in libraries.
closes#9125
This PR makes the `pullInstances` pass avoid pulling any instance
expressions containing erased propositions, because we don't correctly
represent the dependencies that remain after erasure.
This PR makes `mvcgen` split ifs rather than applying specifications.
Doing so fixes a bug reported by Rish.
Co-authored-by: Sebastian Graf <sg@lean-fro.org>
This PR resolves a defeq diamond, which caused a problem in Mathlib:
```
import Mathlib
example (R : Type) [I : Ring R] :
@AddCommGroup.toGrindIntModule R (@Ring.toAddCommGroup R I) =
@Lean.Grind.Ring.instIntModule R (@Ring.toGrindRing R I) := rfl -- fails
```
This test was originally checked in for a panic in the pretty printer,
but at some point the output of every LCNF simp pass was added to
#guard_msgs output. Since this is printing LCNF built by the stage0
compiler, this causes a lot of unnecessary churn.
This PR wraps `simpLemma` and `grindLemma` in `ppGroup` to make sure
that the modifiers aren't printed separately from the term / identifier.
Example:
```
simp only [very_long_lemma_oh_no_can_you_please_stop_we're_getting_to_the_limit, ←
wait_this_is_rewritten_backwards_oh_uhh_where's_the_arrow_you_ask?_oh_wait_it's_up_there!]
==>
simp only [very_long_lemma_oh_no_can_you_please_stop_we're_getting_to_the_limit,
← wait_this_is_rewritten_backwards_and_wow_it's_very_clear_and_obvious]
```
This PR generalizes the `a^(m+n)` grind normalizer to any semirings.
Example:
```
variable [Field R]
example (M : R) (h₀ : M ≠ 0) {n : Nat} (hn : n > 0) : M ^ n / M = M ^ (n - 1) := by
cases n <;> grind
```
This PR adds support for representing more inductive as enums,
summarized up as extending support to those that fail to be enums
because of parameters or irrelevant fields. While this is nice to have,
it is actually motivated by correctness of a future desired
optimization. The existing type representation is unsound if we
implement `object`/`tobject` distinction between values guaranteed to be
an object pointer and those that may also be a tagged scalar. In
particular, types like the ones added in this PR's tests would have all
of their constructors encoded via tagged values, but under the natural
extension of the existing rules of type representation they would be
considered `object` rather than `tobject`.
This PR changes ToIR to call `lowerEnumToScalarType?` with
`ConstructorVal.induct` rather than the name of the constructor itself.
This was an oversight in some refactoring of code in the new compiler
before landing it. It should not affect runtime of compiled code (due to
the extra tagging/untagging being optimized by LLVM), but it does make
IR for the interpreter slightly more efficient.
This PR fixes spacing in the `grind` attribute and tactic syntax.
Previously `@[grind]` was incorrectly pretty-printed as `@[grind ]`, and
`grind [...] on_failure ...` was pretty-printed `grind [...]on_failure
...`. Fixes that `on_failure` was reserved as keyword.
