This PR makes `realizeConst` to not set a `declPrefix`. This allows the
realization of both `foo.eq_def` and `bar.eq_def`, where `foo` and `bar`
are mutually recursive, all attached to the same function's environment.
This PR improves equality propagation (also known as theory combination)
and polynomial simplification for rings that do not implement the
`NoZeroNatDivisors` class. With these fixes, `grind` can now solve:
```lean
example [CommRing α] (a b c : α) (f : α → Nat)
: a + b + c = 3 →
a^2 + b^2 + c^2 = 5 →
a^3 + b^3 + c^3 = 7 →
f (a^4 + b^4) + f (9 - c^4) ≠ 1 := by
grind +ring
```
This example uses the commutative ring procedure, the linear integer
arithmetic solver, and congruence closure.
For rings that implement `NoZeroNatDivisors`, a polynomial is now also
divided by the greatest common divisor (gcd) of its coefficients when it
is inserted into the basis.
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 implements equality propagation in the new commutative ring
procedure in `grind`. The idea is to propagate implied equalities back
to the `grind` core module that does congruence closure. In the
following example, the equalities: `x^2*y = 1` and `x*y^2 - y = 0` imply
that `y*x` is equal to `y*x*y`, which implies by congruence that `f
(y*x) = f (y*x*y)`.
```lean
example [CommRing α] (x y : α) (f : α → Nat) : x^2*y = 1 → x*y^2 - y = 0 → f (y*x) = f (y*x*y) := by
grind +ring
```
This PR implements the main loop of the new commutative ring procedure
in `grind`. In the main loop, for each polynomial `p` in the todo queue,
the procedure:
- Simplifies it using the current basis.
- Computes critical pairs with polynomials already in the basis and adds
them to the queue.
After the queue is empty, the disequalities are re-simplified using the
new basis. `grind` can now solve examples such as:
```lean
example [CommRing α] (x y : α) : x*y*x = 1 → x*y*y = y → y = 1 := by
grind +ring
example [CommRing α] (x y : α) : x^2*y = 1 → x*y^2 = y → y*x = 1 := by
grind +ring
example (x y : BitVec 16) : x^2*y = 1 → x*y^2 = y → y*x = 1 := by
grind +ring
```
This PR correctly handles escaping functions in the LCNF
elimDeadBranches pass, by setting all params to top instead of
potentially leaving them at their default bottom value.
This PR implements the generation of compact proof terms for
Nullstellensatz certificates in the new commutative ring procedure in
`grind`. Some examples:
```lean
example [CommRing α] (x y : α) : x = 1 → y = 2 → 2*x + y = 4 := by
grind +ring
example [CommRing α] [IsCharP α 7] (x y : α) : 3*x = 1 → 3*y = 2 → x + y = 1 := by
grind +ring
example [CommRing α] [NoZeroNatDivisors α] (x y : α) : 3*x = 1 → 3*y = 2 → x + y = 1 := by
grind +ring
example (x y z : BitVec 8) : z = y → (x + 1)*(x - 1)*y + y = z*x^2 + 1 → False := by
grind +ring
```
This PR adds the helper type class `NoZeroNatDivisors` for the
commutative ring procedure in `grind`. Core only implements it for
`Int`. It can be instantiated in Mathlib for any type `A` that
implements `NoZeroSMulDivisors Nat A`.
See `findSimp?` and `PolyDerivation` for details on how this instance
impacts the commutative ring procedure.
This PR fixes a parallelism regression where linters that e.g. check for
errors in the command would no longer find such messages.
---------
Co-authored-by: damiano <adomani@gmail.com>
This PR reverts #8056 because the implementation there has a bug that is
best fixed with a different approach, and which we should preferably
only merge next release cycle.
This PR fixes the generation of functional induction principles for
functions with nested nested well-founded recursion and late fixed
parameters. This is a follow-up for #7166. Fixes#8093.
This PR makes sure that the functional induction priciples for mutually
recursive structural functions with extra parameters are split deeply,
as expected.
This PR ensures that for modules opted into the experimental module
system, we do not import module docstrings or declaration ranges.
Excluding declaration docstrings as well would require some more work to
make `[inherit_doc]` leave a mere reference to the other declaration
instead of copying its docstring eagerly.
This PR makes two improvements to the local context when there are
autobound implicits in `variable`s. First, the local context no longer
has two copies of every variable (the local context is rebuilt if the
types of autobound implicits have metavariables). Second, these
metavariables get names using the same algorithm used by binders that
appear in declarations (with `mkForallFVars'` instead of
`mkForallFVars`).
This removes the last use of `Term.addAutoBoundImplicits'`, which
inherently has this variable duplication issue.
This PR implements `EqCnstr.mkNullCertExt`. Given an implied polynomial
equation `p = 0`, it generates the certificate:
```
q₁ * h₁ + … + qₙ * hₙ
```
for `d * p = 0`, where each `qᵢ`s are polynomials and each `hᵢ` is an
equational hypothesis of the form `lhsᵢ = rhsᵢ`. `d` is a numeral.
This PR fixes a bug where the trace nodes in the InfoView would close
while the file was still being elaborated.
Closes#8053.
The cause of this bug was that we didn't memorize interactive
diagnostics correctly, so the server would generate new RPC pointers in
every single `getInteractiveDiagnostics` RPC request, which lead to the
client resetting the UI.
This PR makes `IntCast` a field of `Lean.Grind.CommRing`, along with
additional axioms relating it to negation of `OfNat`. This allows use to
use existing instances which are not definitionally equal to the
previously given construction.
---------
Co-authored-by: Leonardo de Moura <leomoura@amazon.com>
This PR implements tactics called `extract_lets` and `lift_lets` that
manipulate `let`/`let_fun` expressions. The `extract_lets` tactic
creates new local declarations extracted from any `let` and `let_fun`
expressions in the main goal. For top-level lets in the target, it is
like the `intros` tactic, but in general it can extract lets from deeper
subexpressions as well. The `lift_lets` tactic moves `let` and `let_fun`
expressions as far out of an expression as possible, but it does not
extract any new local declarations. The option `extract_lets +lift`
combines these behaviors.
This is a re-implementation of `extract_lets` and `lift_lets` from
mathlib. The new `extract_lets` is like doing `lift_lets; extract_lets`,
but it does not lift unextractable lets like `lift_lets`. The
`lift_lets; extract_lets` behavior is now handled by `extract_lets
+lift`. The new `lift_lets` tactic is a frontend to `extract_lets +lift`
machinery, which rather than creating new local definitions instead
represents the accumulated local declarations as top-level lets.
There are also conv tactics for both of these. The `extract_lets` has a
limitation due to the conv architecture; it can extract lets for a given
conv goal, but the local declarations don't survive outside conv. They
get zeta reduced immediately upon leaving conv.
This PR fixes the IR expand_reset_reuse pass to correctly handle
duplicate projections from the same base/index. This does not occur (at
least easily) with the old compiler, but it occurs when bootstrapping
Lean with the new compiler.
