This PR changes the interface of the `ForIn`, `ForIn'`, and `ForM`
typeclasses to not take a `Monad m` parameter. This is a breaking change
for most downstream `instance`s, which will will now need to assume
`[Monad m]`.
The rationale is that if the provider of an instance requires `m` to be
a Monad, they should assume this up front. This makes it possible for
the instanve to assume `LawfulMonad m` or some other stronger
requirement, and also to provided a concrete instance for a particular
`m` without assuming a non-canonical `Monad` structure on it.
Zulip: [#lean4 > Monad assumptions in fields of other typeclasses @
💬](https://leanprover.zulipchat.com/#narrow/channel/270676-lean4/topic/Monad.20assumptions.20in.20fields.20of.20other.20typeclasses/near/537102158)
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 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 adds `Std.Tricho r`, a typeclass for relations which identifies
them as trichotomous. This is preferred to `Std.Antisymm (¬ r · ·)` in
all cases (which it is equivalent to).
This PR provides a polymorphic `ForIn` instance for slices and an MPL
`spec` lemma for the iteration over slices using `for ... in`. It also
provides a version specialized to `Subarray`.
This PR uses the new `grind_pattern` constraints to fix cases where an
unbounded number of theorem instantiations would be generated for
certain theorems in the standard library.
This PR replaces `Iter(M).size` with the `Iter(M).count`. While the
former used a special `IteratorSize` type class, the latter relies on
`IteratorLoop`. The `IteratorSize` class is deprecated. The PR also
renames lemmas about ranges be replacing `_Rcc` with `_rcc`, `_Rco` with
`_roo` (and so on) in names, in order to be more consistent with the
naming convention.
This PR fixes a typo in the doc string of `List.finIdxOf?`. The first
line of the doc string previously says the function returns the size of
the list if no element equal to `a`, but both the examples in the doc
string and real run-time behavior indicate it returns `none` in this
case.
Closes#11110
This PR removes support for reducible well-founded recursion, a Breaking
Change. Using `@[semireducible]` on a definition by well-founded
recursion prints a warning that this is no longer effective.
With the upcoming module system, proofs are often not available. With
this change, we remove a fringe use case hat may require proofs, and
that would not be supported under the module system anyways.
At least for now, direct use of `WellFounded.fix` is not affected.
This fixes: #5192
This PR "monomorphizes" the structure `Std.PRange shape α`, replacing it
with nine distinct structures `Std.Rcc`, `Std.Rco`, `Std.Rci` etc., one
for each possible shape of a range's bounds. This change was necessary
because the shape polymorphism is detrimental to attempts of automation.
**BREAKING CHANGE:** While range/slice notation itself is unchanged,
this essentially breaks the entire remaining (polymorphic) range and
slice API except for the dot-notation(`toList`, `iter`, ...). It is not
possible to deprecate old declarations that were formulated in a
shape-polymorphic way that is not available anymore.
This PR removes some `grind` annotations for `Array.attach` and related
functions. These lemmas introduce lambda on the right hand side which
`grind` can't do much with. I've added a test file that verifies that
the theorems with removed annotations can actually be proved already by
grind. Removing the annotations will help with excessive instantiation.
This PR resolves a potential bad interaction between the compiler and
the module system where references to declarations not imported are
brought into scope by inlining or specializing. We now proactively check
that declarations to be inlined/specialized only reference public
imports. The intention is to later resolve this limitation by moving out
compilation into a separate build step with its own import/incremental
system.
This PR fixes a few bugs in the `rw` tactic: it could "steal" goals
because they appear in the type of the rewrite, it did not do an occurs
check, and new proof goals would not be synthetic opaque. This PR also
lets the `rfl` tactic assign synthetic opaque metavariables so that it
is equivalent to `exact rfl`.
Implementation note: filtering old vs new is not sufficient. This PR
partially addresses the bug where the rw tactic creates natural
metavariables for each of the goals; now new proof goals are synthetic
opaque.
Metaprogramming API: Instead of `Lean.MVarId.rewrite` prefer
`Lean.Elab.Tactic.elabRewrite` for elaborating rewrite theorems and
applying rewrites to expressions.
Closes#10172
This PR adds more lemmas about the `toList` and `toArray` functions on
ranges and iterators. It also renames `Array.mem_toArray` into
`List.mem_toArray`.
This PR is followup to the change in grind pattern heuristics from
#10342, typically resolving the discrepancy by writing out an explicit
`grind_pattern` for the intended pattern. The new behaviour is more
aggressive, because it selects smaller patterns.
This PR completes the review of `@[grind]` annotations without a sigil
(e.g. `=` or `←`), replacing most of them with more specific annotations
or patterns.
---------
Co-authored-by: Leonardo de Moura <leomoura@amazon.com>
This PR updates `@[grind]` annotations which should be `@[grind =]`, for
robustness (and, presumably, in some fraction of cases the existing
heuristic for `@[grind]` is already too liberal).
This PR removes `grind →` annotations that fire too often, unhelpfully.
It would be nice for `grind` to instantiate these lemmas, but only if
they already see `xs ++ ys` and `#[]` in the same equivalence class, not
just as soon as it sees `xs ++ ys`.
In the meantime, let's see what is using these.
This PR improves the names of definitions and lemmas in the polymorphic
range API. It also introduces a recommended spelling. For example, a
left-closed, right-open range is spelled `Rco` in analogy with Mathlib's
`Ico` intervals.
This PR speeds up auto-completion by a factor of ~3.5x through various
performance improvements in the language server. On one machine, with
`import Mathlib`, completing `i` used to take 3200ms and now instead
yields a result in 920ms.
Specifically, the following improvements are made:
- The watchdog process no longer de-serializes and re-serializes most
messages from the file worker before passing them on to the user - a
fast partial de-serialization procedure is now used to determine whether
the message needs to be de-serialized in full or not.
- `escapePart` is optimized to perform better on ASCII strings that do
not need escaping.
- `Json.compress` is optimized to allocate fewer objects.
- A faster JSON compression specifically for completion responses is
implemented that skips allocating `Json` altogether.
- The JSON compression has been moved to the task where we convert a
request response to `Json` so that converting to a string won't block
the output task of the FileWorker and so the `Json` value is not marked
as multi-threaded when we compress is, which drastically increases the
cost of reference-counting.
- The JSON representation of the `data?` field of each completion item
is optimized.
- Both the completion kind and the set of completion tags for each
imported completion item is now cached.
- The filtering of duplicate completion items is optimized.
Other adjustments:
- `LT UInt8` and `LE UInt8` are moved to Prelude so that they can be
used in `Init.Meta` for the name part escaping fast path.
- `Array.usize` is exposed since it was marked as `@[simp]`.
This PR adds some test cases for `grind` working with `Fin`. There are
many still failing tests in `tests/lean/grind/grind_fin.lean` which I'm
intending to triage and work on.
This PR makes `IsPreorder`, `IsPartialOrder`, `IsLinearPreorder` and
`IsLinearOrder` extend `BEq` and `Ord` as appropriate, adds the
`LawfulOrderBEq` and `LawfulOrderOrd` typeclasses relating `BEq` and
`Ord` to `LE`, and adds many lemmas and instances.
Note: This PR contains a refactoring where `Init.Data.Ord` is moved to
`Init.Data.Ord.Basic`. If I added `Init.Data.Ord` simply importing all
submodules, git would not be able to determine that `Init.Data.Ord` was
renamed to `Init.Data.Ord.Basic`. This could lead to unnecessary merge
conflicts in the future. Hence, I chose the name `Init.Data.OrdRoot`
instead of `Init.Data.Ord` temporarily. After this PR, I will rename
this module back to `Init.Data.Ord` in a separate PR.
(This is a copy of #9430: I will not touch that PR because it currently
allows to debug a CI problem and pushing commits might break the
reproducibility.)
This PR eliminates uses of `intros x y z` (with arguments) and updates
the `intros` docstring to suggest that `intro x y z` should be used
instead. The `intros` tactic is historical, and can be traced all the
way back to Lean 2, when `intro` could only introduce a single
hypothesis. Since 2020, the `intro` tactic has superceded it. The
`intros` tactic (without arguments) is currently still useful.
This PR cleans up `optParam`/`autoParam`/etc. annotations before
elaborating definition bodies, theorem bodies, `fun` bodies, and `let`
function bodies. Both `variable`s and binders in declaration headers are
supported.
There are no changes to `inductive`/`structure`/`axiom`/etc. processing,
just `def`/`theorem`/`example`/`instance`.
This PR introduces a canonical way to endow a type with an order
structure. The basic operations (`LE`, `LT`, `Min`, `Max`, and in later
PRs `BEq`, `Ord`, ...) and any higher-level property (a preorder, a
partial order, a linear order etc.) are then put in relation to `LE` as
necessary. The PR provides `IsLinearOrder` instances for many core types
and updates the signatures of some lemmas.
**BREAKING CHANGES:**
* The requirements of the `lt_of_le_of_lt`/`le_trans` lemmas for
`Vector`, `List` and `Array` are simplified. They now require an
`IsLinearOrder` instance. The new requirements are logically equivalent
to the old ones, but the `IsLinearOrder` instance is not automatically
inferred from the smaller typeclasses.
* Hypotheses of type `Std.Total (¬ · < · : α → α → Prop)` are replaced
with the equivalent class `Std.Asymm (· < · : α → α → Prop)`. Breakage
should be limited because there is now an instance that derives the
latter from the former.
* In `Init.Data.List.MinMax`, multiple theorem signatures are modified,
replacing explicit parameters for antisymmetry, totality, `min_ex_or`
etc. with corresponding instance parameters.
