This PR addresses an outstanding feature in the module system to
automatically mark `let rec` and `where` helper declarations as private
unless they are defined in a public context such as under `@[expose]`.
This PR removes an error which implicitly assumes that the sort of type
dependency between erased types present in the test being added can not
occur. It would be difficult to refine the error using only the
information present in LCNF types, and it is of very little ongoing
value (I don't recall it ever finding an actual problem), so it makes
more sense to delete it.
Fixes#9692.
This PR changes the LCNF `elimDeadBranches` pass so that it considers
all non-`Nat` literal types to be `⊤`. It turns out that fixing this to
correctly handle all of these types with the current abstract value
representation is surprisingly nontrivial, and it's better to just land
the fix first.
This PR adds a version of `CommRing.Expr.toPoly` optimized for kernel
reduction. We use this function not only to implement `grind ring`, but
also to interface the ring module with `grind cutsat`.
This PR updates `release_repos.yml` to reflect that `import-graph` no
longer depends on `batteries`, and reorders the repositories to better
reflect dependencies.
This PR adds propagation rules for functions that take singleton types.
This feature is useful for discharging verification conditions produced
by `mvcgen`. For example:
```lean
example (h : (fun (_ : Unit) => x + 1) = (fun _ => 1 + y)) : x = y := by
grind
```
This removes the early call to `contradiction` from `simpH`, and
replaces it with a quick check if the pattern start with different
constructors.
We already call `simpH` quadratically often (unavoidable), so we want it
to be quick. Most common contradictions are found later on, so maybe we
don't want to the expensive `contradiction` tactic to be run early.
May help with #9598.
This PR adjusts the formatting type classes for `lake query` to no
longer require both a text and JSON form and instead work with any
combination of the two. The classes have also been renamed. In addition,
the query formatting of a text module header has been improved to only
produce valid headers.
This PR restricts Lake's production of thin archives to only the Windows
core build (i.e., `bootstrap = true`). The unbundled `ar` usually used
for core builds on macOS does not support `--thin`, so we avoid using it
unless necessary.
* Have asynchronous environment extensions specify whether they are
manipulate data for declarations from the "outside"/main branch (e.g.
attributes) or from the "inside"/async branch (e.g. data collected from
body elaboration) in order to avoid unnecessary waiting.
* Merge `findStateAsync?` into `getState` via a new, optional
`asyncDecl` parameter.
* Make `mayContainAsync` check an automatic part of `modifyState`.
This PR uses a more simple approach to proving the unfolding theorem for
a function defined by well-founded recursion. Instead of looping a bunch
of tactics, it uses simp in single-pass mode to (try to) exactly undo
the changes done in `WF.Fix`, using a dedicated theorem that pushes the
extra argument in for each matcher (or `casesOn`).
Improves performance for recursive functions with large `match`
statements, as in #9598.
This PR fixes a regression introduced by an optimization in the
`unfoldReducible` step used by the `grind` normalizer. It also ensures
that projection functions are not reduced, as they are folded in a later
step.
This PR adds build times to each build step of the build monitor (under
`-v` or in CI) and delays exiting on a `--no-build` until after the
build monitor finishes. Thus, a `--no-build` failure will now report
which targets blocked Lake by needing a rebuild.
This PR adds normalizers for nonstandard arithmetic instances. The types
`Nat` and `Int` have built-in support in `grind`, which uses the
standard instances for these types and assumes they are the ones in use.
However, users may define their own alternative instances that are
definitionally equal to the standard ones. This PR normalizes such
instances using simprocs. This situation actually occurs in Mathlib.
Example:
```lean
class Distrib (R : Type _) extends Mul R where
namespace Nat
instance instDistrib : Distrib Nat where
mul := (· * ·)
theorem odd_iff.extracted_1_4 {n : Nat} (m : Nat)
(hm : n =
@HMul.hMul _ _ _ (@instHMul Nat instDistrib.toMul)
2 m + 1) :
n % 2 = 1 := by
grind
end Nat
```
This PR adds support for `Fin.val` in `grind cutsat`. Examples:
```lean
example (a b : Fin 2) (n : Nat) : n = 1 → ↑(a + b) ≠ n → a ≠ 0 → b = 0 → False := by
grind
example (m n : Nat) (i : Fin (m + n)) (hi : m ≤ ↑i) : ↑i - m < n := by
grind
example {n : Nat} (m : Nat) (i : Fin n) ⦃j : Fin (n + m)⦄
(this : ↑i + m ≤ ↑j) : ↑j - m < n := by
grind
example {n : Nat} (i : Fin n) (j : Nat) (hj : j < ↑i) : j < n := by
grind
```
This PR ensures that `grind cutsat` processes `ToInt.toInt` applications
provided by the user. Example:
```lean
open Lean Grind
example (x : Fin 3) : ToInt.toInt x ≠ 0 → ToInt.toInt x ≠ 1 → ToInt.toInt x ≠ 2 → False := by
grind -ring
example (x y z : Fin 5) : ToInt.toInt (x + z) = ToInt.toInt y → z = 0 → x = y := by
grind -ring
```
