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 the unnecessary requirement of `BEq α` for
`Array.any_push`, `Array.any_push'`, `Array.all_push`, `Array.all_push'`
as well as `Vector.any_push` and `Vector.all_push`.
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 extends the `Eq` simproc used in `grind`. It covers more cases
now. It also adds 3 reducible declarations to the list of declarations
to unfold.
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 removes a rather ugly hack in the module system, exposing the
bodies of theorems whose type mention `WellFounded`.
The original motivation was that reducing well-founded definitions (e.g.
in `by rfl`) requires reducing proofs, so they need to be available.
But reducing proofs is generally fraught with peril, and we have been
nudging our users away from using it for a while, e.g. in #5182. Since
the module system is opt-in and users will gradually migrate to it, it
may be reasonable to expect them to avoid reducing well-founded
recursion in the process
This way we don't need hacks like this (which, without evidence, I
believe would be incomplete anyways) and we get the nice guarantee that
within the module system, theorems bodies are always private.
This PR removes some unnecessary `Decidable*` instance arguments by
using lemmas in the `Classical` namespace instead of the `Decidable`
namespace.
This might lead to some additional dependency on classical axioms, but
large parts of the standard library are relying on them either way.
This PR adjusts the experimental module system to make `private` the
default visibility modifier in `module`s, introducing `public` as a new
modifier instead. `public section` can be used to revert the default for
an entire section, though this is more intended to ease gradual adoption
of the new semantics such as in `Init` (and soon `Std`) where they
should be replaced by a future decl-by-decl re-review of visibilities.
This PR replaces all usages of `[:]` slice notation in `src` with the
new `[...]` notation in production code, tests and comments. The
underlying implementation of the `Subarray` functions stays the same.
Notation cheat sheet:
* `*...*` is the doubly-unbounded range.
* `*...a` or `*...<a` contains all elements that are less than `a`.
* `*...=a` contains all elements that are less than or equal to `a`.
* `a...*` contains all elements that are greater than or equal to `a`.
* `a...b` or `a...<b` contains all elements that are greater than or
equal to `a` and less than `b`.
* `a...=b` contains all elements that are greater than or equal to `a`
and less than or equal to `b`.
* `a<...*` contains all elements that are greater than `a`.
* `a<...b` or `a<...<b` contains all elements that are greater than `a`
and less than `b`.
* `a<...=b` contains all elements that are greater than `a` and less
than or equal to `b`.
Benchmarks have shown that importing the iterator-backed parts of the
polymorphic slice library in `Init` impacts build performance. This PR
avoids this problem by separating those parts of the library that do not
rely on iterators from those those that do. Whereever the new slice
notation is used, only the iterator-independent files are imported.
This PR adds grind annotations for `List/Array/Vector.ofFn` theorems and
additional `List.Impl` find operations.
The annotations are added to theorems that correspond to those already
annotated in the List implementation, ensuring consistency across all
three container types (List, Array, Vector) for ofFn operations and
related functionality.
Key theorems annotated include:
- Element access theorems (`getElem_ofFn`, `getElem?_ofFn`)
- Construction and conversion theorems (`ofFn_zero`, `toList_ofFn`,
`toArray_ofFn`)
- Membership theorems (`mem_ofFn`)
- Head/tail operations (`back_ofFn`)
- Monadic operations (`ofFnM_zero`, `toList_ofFnM`, `toArray_ofFnM`,
`idRun_ofFnM`)
- List.Impl find operations (`find?_singleton`, `find?_append`,
`findSome?_singleton`, `findSome?_append`)
This PR adds grind annotations for `Array/Vector.mapIdx` and `mapFinIdx`
theorems.
The annotations are added to theorems that correspond to those already
annotated in the List implementation, ensuring consistency across all
three container types (List, Array, Vector) for indexed mapping
operations.
Key theorems annotated include:
- Size and element access theorems (`size_mapIdx`, `getElem_mapIdx`,
`getElem?_mapIdx`)
- Construction theorems (`mapIdx_empty`, `mapIdx_push`, `mapIdx_append`)
- Membership and equality theorems (`mem_mapIdx`, `mapIdx_mapIdx`)
- Conversion theorems (`toList_mapIdx`, `mapIdx_toArray`, etc.)
- Reverse and composition operations
- Similar annotations for `mapFinIdx` variants
This PR adds an equivalence relation to tree maps akin to the existing
one for hash maps. In order to get many congruence lemmas to eventually
use for defining functions on extensional tree maps, almost all of the
remaining tree map functions have also been given lemmas to relate them
to list functions, although these aren't currently used to prove lemmas
other than congruence lemmas.
This PR removes the `@[reducible]` annotation on `Array.size`. This is
probably best gone anyway in order to keep separation between the `List`
and `Array` APIs, but it also helps avoid uselessly instantiating
`Array` theorems when `grind` is working on `List` problems.
This PR adds the `@[expose]` attribute to many functions (and changes
some theorems to be by `:= (rfl)`) in preparation for the `@[defeq]`
attribute change in #8419.
This PR adds a `@[simp]` lemma, and comments explaining that there is
intentionally no verification API for `Vector.take`, `Vector.drop`, or
`Vector.tail`, which should all be rewritten in terms of
`Vector.extract`.
This PR reworks the `simp` set around the `Id` monad, to not elide or
unfold `pure` and `Id.run`
In particular, it stops encoding the "defeq abuse" of `Id X = X` in the
statements of theorems, instead using `Id.run` and `pure` to pass back
and forth between these two spellings. Often when writing these with
`pure`, they generalize to other lawful monads; though such changes were
split off to other PRs.
This fixes the problem with the current simp set where `Id.run (pure x)`
is simplified to `Id.run x`, instead of the desirable `x`.
This is particularly bad because the` x` is sometimes inferred with type
`Id X` instead of `X`, which prevents other `simp` lemmas about `X` from
firing.
Making `Id` reducible instead is not an option, as then the `Monad`
instances would have nothing to key on.
---------
Co-authored-by: Sebastian Graf <sg@lean-fro.org>
Co-authored-by: Kim Morrison <kim@tqft.net>
Co-authored-by: Paul Reichert <6992158+datokrat@users.noreply.github.com>
This PR adds the `List/Array/Vector.ofFnM`, the monadic analogues of
`ofFn`, along with basic theory.
At the same time we pave some potholes in nearby API.
---------
Co-authored-by: Eric Wieser <wieser.eric@gmail.com>
This PR adjusts the experimental module system to not export the bodies
of `def`s unless opted out by the new attribute `@[expose]` on the `def`
or on a surrounding `section`.
---------
Co-authored-by: Markus Himmel <markus@lean-fro.org>
