This PR introduces a new annotation that allows definitions to describe
plausible-but-wrong name variants for the purpose of improving error
messages.
This PR just adds the notation and extra functionality; a stage0 update
will allow standard Lean functions to have suggestion annotations.
(Hence the changelog-no tag: this should go in the changelog when some
preliminary annotations are actually added.)
## Example
```lean4
inductive MyBool where | tt | ff
attribute [suggest_for MyBool.true] MyBool.tt
attribute [suggest_for MyBool.false] MyBool.ff
@[suggest_for MyBool.not]
def MyBool.swap : MyBool → MyBool
| tt => ff
| ff => tt
/--
error: Unknown constant `MyBool.true`
Hint: Perhaps you meant `MyBool.tt` in place of `MyBool.true`:
M̵y̵B̵o̵o̵l̵.̵t̵r̵u̵e̵M̲y̲B̲o̲o̲l̲.̲t̲t̲
-/
#guard_msgs in
example := MyBool.true
/--
error: Invalid field `not`: The environment does not contain `MyBool.not`, so it is not possible to project the field `not` from an expression
MyBool.tt
of type `MyBool`
Hint: Perhaps you meant one of these in place of `MyBool.not`:
[apply] `MyBool.swap`: MyBool.tt.swap
-/
#guard_msgs in
example := MyBool.tt.not
```
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 simplifies the `grind order` module, and internalizes the order
constraints. It removes the `Offset` type class because it introduced
too much complexity. We now cover the same use cases with a simpler
approach:
- Any type that implements at least `Std.IsPreorder`
- Arbitrary ordered rings.
- `Nat` by the `Nat.ToInt` adapter.
This PR fixes an issue where the "eta feature" in the app elaborator,
which is invoked when positional arguments are skipped due to named
arguments, results in variables that can be captured by those named
arguments. Now the temporary local variables that implement this feature
get fresh names. The names used for the closed lambda expression still
use the original parameter names.
Closes#6373
This PR makes `mvcgen` aggressively eta-expand before trying to apply a
spec. This ensures that `mspec` will be able to frame hypotheses
involving uninstantiated loop invariants in goals for the inductive step
of a loop instead of losing them in a destructive world update.
This PR adds improved support for proof-by-reflection to the kernel type
checker. It addresses the performance issue exposed by #9854. With this
PR, whenever the kernel type-checks an argument of the form `eagerReduce
_`, it enters "eager-reduction" mode. In this mode, the kernel is more
eager to reduce terms. The new `eagerReduce _` hint is often used to
wrap `Eq.refl true`. The new hint should not negatively impact any
existing Lean package.
---------
Co-authored-by: Joachim Breitner <mail@joachim-breitner.de>
This PR modifies dot identifier notation so that `(.a : T)` resolves
`T.a` with respect to the root namespace, like for generalized field
notation. This lets the notation refer to private names, follow aliases,
and also use open namespaces. The LSP completions are improved to follow
how dot ident notation is resolved, but it doesn't yet take into account
aliases or open namespaces.
Closes#9629
(Almost) only typos in constant names and doc-strings were considered;
grammar was not considered. Also, along others,
`mkDefinitionValInferrringUnsafe` has been fixed :-)
This PR removes uses of `Lean.RBMap` in Lean itself.
Furthermore some massaging of the import graph is done in order to avoid
having `Std.Data.TreeMap.AdditionalOperations` (which is quite
expensive) be the critical path for a large chunk of Lean. In particular
we can build `Lean.Meta.Simp` and `Lean.Meta.Grind` without it thanks to
these changes.
We did previously not conduct this change as `Std.TreeMap` was not
outperforming `Lean.RBMap` yet, however this has changed with the new
code generator.
This PR modifies the encoding from `Nat` to `Int` used in `grind
cutsat`. It is simpler, more extensible, and similar to the generic
`ToInt`. After update stage0, we will be able to delete the leftovers.
This PR implements support for (commutative) semirings in `grind`. It
uses the Grothendieck completion to construct a (commutative) ring
`Lean.Grind.Ring.OfSemiring.Q α` from a (commutative) semiring `α`. This
construction is mostly useful for semirings that implement
`AddRightCancel α`. Otherwise, the function `toQ` is not injective.
Examples:
```lean
example (x y : Nat) : x^2*y = 1 → x*y^2 = y → y*x = 1 := by
grind
example [CommSemiring α] [AddRightCancel α] (x y : α) : x^2*y = 1 → x*y^2 = y → y*x = 1 := by
grind
example (a b : Nat) : 3 * a * b = a * b * 3 := by grind
example (k z : Nat) : k * (z * 2 * (z * 2 + 1)) = z * (k * (2 * (z * 2 + 1))) := by grind
example [CommSemiring α] [AddRightCancel α] [IsCharP α 0] (x y : α)
: x^2*y = 1 → x*y^2 = y → x + y = 1 → False := by
grind
```
This PR adds the `nondep` field of `Expr.letE` to the C++ data model.
Previously this field has been unused, and in followup PRs the
elaborator will use it to encode `have` expressions (non-dependent
`let`s). The kernel does not verify that `nondep` is correctly applied
during typechecking. The `letE` delaborator now prints `have`s when
`nondep` is true, though `have` still elaborates as `letFun` for now.
Breaking change: `Expr.updateLet!` is renamed to `Expr.updateLetE!`.
This PR also fixes a bug in `Expr.letFun?` and `Expr.letFunAppArgs?`
when the body is not a lambda. In any case, these functions will be
removed once the `Expr.letE (nondep := true)` encoding of `have`
expressions is complete.
This PR implements disequality splitting and non-chronological
backtracking for the `grind` linarith procedure.
```lean
example [IntModule α] [LinearOrder α] [IntModule.IsOrdered α] (a b c d : α)
: a ≤ b → a - c ≥ 0 + d → d ≤ 0 → d ≥ 0 → b = c → a ≠ b → False := by
grind
```
The termination prover has gotten stronger since these definitions were
written, and now they can be proved terminating automatically. (One
definition had to be changed slightly because it wasn't actually
terminating before.)
This PR adds variants of `HashMap.getElem?_filter` that assume
`LawfulBEq` and have a simpler right-hand-side. `simp` can already
achieve these, via rewriting with `getKey_eq` under the lambda. However
`grind` can not, and these lemmas help `grind` work with `HashMap`
goals. There are variants for all variants of `HashMap`,
`getElem?/getElem/getElem!/getD`, and for `filter` and `filterMap`.
This PR fixes the `grind +splitImp` and the arrow propagator. Given `p :
Prop`, the propagator was incorrectly assuming `A` was always a
proposition in an arrow `A -> p`. This PR also adds a missing
normalization rule to `grind`.
This PR ensures that `set_option grind.debug true` works properly when
using `grind +ring`. It also adds the helper functions `mkPropEq` and
`mkExpectedPropHint`.
This PR adds a feature to `structure`/`class` where binders without
types on a field definition are interpreted as overriding the type's
parameters binder kinds in that field's projection function. The rules
are (1) only a prefix of the binders are interpreted this way, (2)
multi-identifier binders are allowed but they must all be for
parameters, (3) only parameters that appear in the declaration itself
(not from `variables`) can be overridden and (4) the updates will be
applied after parameter binder kind inference is done. Binder updates
are not allowed in default value redefinitions. Example application: In
the following, `(R p)` causes the `R` and `p` parameters to be explicit,
where normally they would be implicit.
```
class CharP (R : Type u) [AddMonoidWithOne R] (p : Nat) : Prop where
cast_eq_zero_iff (R p) : ∀ x : Nat, (x : R) = 0 ↔ p ∣ x
#guard_msgs in #check CharP.cast_eq_zero_iff
/-
info: CharP.cast_eq_zero_iff.{u} (R : Type u) {inst✝ : AddMonoidWithOne R} (p : Nat) [self : CharP R p] (x : Nat) :
↑x = 0 ↔ p ∣ x
-/
```
The rationale for (3) is that there are cases where a module starts with
a large `variables` list and a field only incidentally uses the binder.
Without the restriction, the field ends up depending on that variable,
counterintuitively causing it to be introduced as an additional
parameter for the type. Instead, there is an explicit error. The easy
fix is to add `: _`, which is the bare minimum to make the binder have a
type.
We should consider warning when binders shadow parameters.
Closes#3574
[Zulip
discussion](https://leanprover.zulipchat.com/#narrow/channel/270676-lean4/topic/RFC.3A.20adjust.20argument.20explicitness.20on.20typeclass.20projections/near/508584627)
Mathlib fixes:
https://github.com/leanprover-community/mathlib4/pull/23469
This PR translates `lean::mk_projections` into Lean, adding
`Lean.Meta.mkProjections`. It also puts `hasLooseBVarInExplicitDomain`
back in sync with the kernel version. Deletes
`src/library/constructions/projection.{h,cpp}`.
This PR tries to remove from functional induction principles hypotheses
that have been matched, as we expect the corresponding pattern to be
more useful. This avoids duplicate hypotheses due to the way `match`
refines hypotheses. Fixes#6281.
This PR moves away from using `List.get` / `List.get?` / `List.get!` and
`Array.get!`, in favour of using the `GetElem` mediated getters. In
particular it deprecates `List.get?`, `List.get!` and `Array.get?`. Also
adds `Array.back`, taking a proof, matching `List.getLast`.
This PR implements the normalizer for linear integer arithmetic
expressions. It is not connect to `simp +arith` yet because of some
spurious `[simp]` attributes.
This PR adds support for constructors to the (WIP) `grind` tactic. When
merging equivalence classes, `grind` checks for equalities between
constructors. If they are distinct, it closes the goal; if they are the
same, it applies injectivity.
This PR adds support for detecting congruent terms in the (WIP) `grind`
tactic. It also introduces the `grind.debug` option, which, when set to
`true`, checks many invariants after each equivalence class is merged.
This option is intended solely for debugging purposes.
This PR adds docstrings to `Expr.hasLooseBVars` and `Expr.hasLooseBVar`,
to clarify the difference between these functions, and to document that
the former traverses the expression, while the latter is constant-time,
using cached information.
---------
Co-authored-by: Joachim Breitner <mail@joachim-breitner.de>
Example: Normally subtype notation pretty prints as `{ x // x > 0 }`,
but now the difference in domains is exposed:
```lean
example (h : {x : Int // x > 0}) : {x : Nat // x > 0} := h
/-
error: type mismatch
h
has type
{ x : Int // x > 0 } : Type
but is expected to have type
{ x : Nat // x > 0 } : Type
-/
```
Example:
```lean
example : 0 = (0 : Nat) := by
exact Eq.refl (0 : Int)
/-
error: type mismatch
Eq.refl 0
has type
(0 : Int) = 0 : Prop
but is expected to have type
(0 : Nat) = 0 : Prop
-/
```
`getNumHeadForalls` and `getNumHeadLambdas` were both duplicated
downstream with different names; I'll clean up those next.
Also adds `getAppNumArgs'`.
Remark: declarations like `sizeWithSharing` must be in `IO` since they
are not functions.
The commit also uses the more efficient `ShareCommon.shareCommon'`.
