This PR makes `IO.RealWorld` opaque. It also adds a new compiler -only
`lcRealWorld` constant to represent this type within the compiler. By
default, an opaque type definition is treated like `lcAny`, whereas we
want a more efficient representation. At the moment, this isn't a big
difference, but in the future we would like to completely erase
`IO.RealWorld` at runtime.
This PR offers an alternative `noConfusion` construction for the
off-diagonal use (i.e. for different constructors), based on comparing
the `.ctorIdx`. This should lead to faster type checking, as the kernel
only has to reduce `.ctorIdx` twice, instead of the complicate
`noConfusionType` construction.
This PR changes the "declaration uses 'sorry'" error to pretty print an
actual `sorry` expression in the message. The effect is that the `sorry`
is hoverable and, if it's labeled, you can "go to definition" to see
where it came from.
The implementation prefers reporting synthetic sorries. These can appear
even if there are no error messages if a declaration refers to a
declaration that has elaboration errors. Users should focus on
elaboration errors before worrying about user-written `sorry`s.
In the future we could have some more precise logic for sorry reporting.
All the sorries in a declaration should be considered to be reported,
and we should not re-report sorries in later declarations. Some
elaborators use `warn.sorry` to avoid re-reporting sorries in auxiliary
declarations.
This PR changes the implementation of a function `unfoldPredRel` used in
(co)inductive predicate machinery, that unfolds pointwise order on
predicates to quantifications and implications. Previous implementation
relied on `withDeclsDND` that could not deal with types which depend on
each other. This caused the following example to fail:
```lean4
inductive infSeq_functor1.{u} {α : Type u} (r : α → α → Prop) (call : {α : Type u} → (r : α → α → Prop) → α → Prop) : α → Prop where
| step : r a b → infSeq_functor1 r call b → infSeq_functor1 r call a
def infSeq1 (r : α → α → Prop) : α → Prop := infSeq_functor1 r (infSeq1)
coinductive_fixpoint monotonicity by sorry
#check infSeq1.coinduct
```
Closes#10234.
This PR completes the `grind` solver extension design and ports the
`grind ac` solver to the new framework. Future PRs will document the API
and port the remaining solvers. An additional benefit of the new design
is faster build times.
The proof of the instWPMonad instance relies on the equality of any two
terms of type `IO.RealWorld`, which is only a side effect of the current
transparent definition. Ignoring the questions around the utility of
proving things about programs in `IO`, the semantic validity of this
instance in the intended model of the IO monad is also unclear.
I tried a few things to axiomatize this instance so it could be put into
the test file to preserve the one test section that relies on it, but I
was unsuccessful; everything I attempted caused errors.
This PR adds infrastructure for registering new `grind` solvers. `grind`
already includes many solvers, and this PR is the first step toward
modularizing the design and supporting user-defined solvers.
This PR prepares for a future reorganization of the import hierarchy so
that `Init.Data.String.Basic` can import `Init.Data.UInt.Bitwise` and
`Init.Data.Array.Lemmas`.
This PR moves `String.utf8EncodeChar` to the prelude to prepare for the
imminent redefinition of `String`.
The definition in the prelude uses modulo and division operations on
natural numbers. In `String.Extra`, a `csimp` lemma is provided, showing
that the new definition is equal to the previous one (which is now
called `utf8EncodeCharFast`) which uses bitwise operations on `UInt8`.
This PR implements diagnostic information for the `grind ac` module. It
now displays the basis, normalized disequalities, and additional
properties detected for each associative operator.
This PR improves the counterexamples produced by `grind linarith` for
`NatModule`s. `grind` now hides occurrences of the auxiliary function
`Grind.IntModule.OfNatModule.toQ`.
This PR implements `NatModule` normalization when the `AddRightCancel`
instance is not available. Note that in this case, the embedding into
`IntModule` is not injective. Therefore, we use a custom normalizer,
similar to the `CommSemiring` normalizer used in the `grind ring`
module. Example:
```lean
open Lean Grind
example [NatModule α] (a b c : α)
: 2•a + 2•(b + 2•c) + 3•a = 4•a + c + 2•b + 3•c + a := by
grind
```
This PR adds the auxiliary theorem `Lean.Grind.Linarith.eq_normN` for
normalizing `NatModule` equations when the instance `AddRightCancel` is
not available.
This PR changes the implementation of the linear `DecidableEq`
implementation to use `match decEq` rather than `if h : ` to compare the
constructor tags. Otherwise, the “smart unfolding” machinery will not
let `rfl` decide that different constructors are different.
This PR adds support for `NatModule` equalities and inequalities in
`grind linarith`. Examples:
```lean
open Lean Grind Std
example [NatModule α] [LE α] [LT α]
[LawfulOrderLT α] [IsLinearOrder α] [OrderedAdd α]
(x y : α) : x ≤ y → 2 • x + y ≤ 3 • y := by
grind
example [NatModule α] [AddRightCancel α] [LE α] [LT α]
[LawfulOrderLT α] [IsLinearOrder α] [OrderedAdd α]
(a b c d : α) : a ≤ b → a ≥ c + d → d ≤ 0 → d ≥ 0 → b = c → a = b := by
grind
```
This PR changes the naming of the internal functions in deriving
instances like BEq to use accessible names. This is necessary to
reasonably easily prove things about these functions. For example after
`deriving BEq` for a type `T`, the implementation of `instBEqT` is in
`instBEqT.beq`.
This PR adds a new option `maxErrors` that limits the number of errors
printed from a single `lean` run, defaulting to 100. Processing is
aborted when the limit is reached, but this is tracked only on a
per-command level.
Smaller values can be useful when making changes that break a lot of
files and would otherwise scroll the actual root failures out of the
terminal view.
This PR implements the infrastructure for supporting `NatModule` in
`grind linarith` and uses it to handle disequalities. Another PR will
add support for equalities and inequalities. Example:
```lean
open Lean Grind
variable (M : Type) [NatModule M] [AddRightCancel M]
example (x y : M) : 2 • x + 3 • y + x = 3 • (x + y) := by
grind
```
This PR fixes a panic in `grind ring` exposed by #10242. `grind ring`
should not assume that all normalizations have been applied, because
some subterms cannot be rewritten by `simp` due to typing constraints.
Moreover, `grind` uses `preprocessLight` in a few places, and it skips
the simplifier/normalizer.
Closes#10242
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 moves the `PackageConfig` definition from `Lake.Config.Package`
into its own module. This enables a significant reduction in the `meta
import` tree of the `Lake.CLI.Translate` modules.
This PR fixes a bug in the `LinearOrderPackage.ofOrd` factory. If there
is a `LawfulEqOrd` instance available, it should automatically use it
instead of requiring the user to provide the `eq_of_compare` argument to
the factory. The PR also solves a hygiene-related problem making the
factories fail when `Std` is not open.
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 fixes the E-matching procedure for theorems that contain
universe parameters not referenced by any regular parameter. This kind
of theorem seldom happens in practice, but we do have instances in the
standard library. Example:
```
@[simp, grind =] theorem Std.Do.SPred.down_pure {φ : Prop} : (⌜φ⌝ : SPred []).down = φ := rfl
```
closes#10233
This PR fixes a missing case in the `grind` canonicalizer. Some types
may include terms or propositions that are internalized later in the
`grind` state.
closes#10232
