This PR adds adds union operation on `DHashMap`/`HashMap`/`HashSet` and
their raw variants and provides lemmas about union operations.
---------
Co-authored-by: Paul-Lez <paul.lezeau@gmail.com>
Co-authored-by: Markus Himmel <markus@lean-fro.org>
Co-authored-by: Markus Himmel <markus@himmel-villmar.de>
This PR introduces a no-op version of `Shrink`, a type that should allow
shrinking small types into smaller universes given a proof that the type
is small enough, and uses it in the iterator library. Because this type
would require special compiler support, the current version is just a
wrapper around the inner type so that the wrapper is equivalent, but not
definitionally equivalent.
While `Shrink` is unable to shrink universes right now, but introducing
it now will allow us to generalize the universes in the iterator library
with fewer breaking changes as soon as an actual `Shrink` is possible.
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 cuts some edges from the import graph.
Specifically:
- `TreeMap` and `HashMap` no longer depend on `String`, so now the
expensive things are all in parallel instead of partially in sequence
- `Omega` no longer relies on `List` lemmas
- The section of the import graph between `Init.Omega` and
`Init.Data.Bitvec.Lemmas` is cleaned up a bit
This PR refines and clarifies the `meta` phase distinction in the module
system.
* `meta import A` without `public` now has the clarified meaning of
"enable compile-time evaluation of declarations in or above `A` in the
current module, but not downstream". This is now checked statically by
enforcing that public meta defs, which therefore may be referenced from
outside, can only use public meta imports, and that global evaluating
attributes such as `@[term_parser]` can only be applied to public meta
defs.
* `meta def`s may no longer reference non-meta defs even when in the
same module. This clarifies the meta distinction as well as improves
locality of (new) error messages.
* parser references in `syntax` are now also properly tracked as meta
references.
* A `meta import` of an `import` now properly loads only the `.ir` of
the nested module for the purposes of execution instead of also making
its declarations available for general elaboration.
* `initialize` is now no longer being run on import under the module
system, which is now covered by `meta initialize`.
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 the type `Std.Internal.Parsec.Error`, which contains the
constructors `.eof` (useful for checking if parsing failed due to not
having enough input and then retrying when more input arrives that is
useful in the HTTP server) and `.other`, which describes other errors.
It also adds documentation to many functions, along with some new
functions to the `ByteArray` Parsec, such as `peekWhen?`, `octDigit`,
`takeWhile`, `takeUntil`, `skipWhile`, and `skipUntil`.
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 adds missing the lemmas `ofList_eq_insertMany_empty`,
`get?_eq_some_iff`, `getElem?_eq_some_iff` and `getKey?_eq_some_iff` to
all container types.
This PR generalizes the monadic operations for `HashMap`, `TreeMap`, and
`HashSet` to work for `m : Type u → Type v`.
This upstreams [a workaround from
Aesop](66a992130e/Aesop/Util/Basic.lean (L57-L66)),
and seems to continue a pattern already established in other files, such
as:
```lean
Array.forM.{u, v, w} {α : Type u} {m : Type v → Type w} [Monad m] (f : α → m PUnit) (as : Array α) (start : Nat := 0)
(stop : Nat := as.size) : m PUnit
```
This PR adds useful declarations to the `LawfulOrderMin/Max` and
`LawfulOrderLeftLeaningMin/Max` API. In particular, it introduces
`.leftLeaningOfLE` factories for `Min` and `Max`. It also renames
`LawfulOrderMin/Max.of_le` to .of_le_min_iff` and `.of_max_le_iff` and
introduces a second variant with different arguments.
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 adds lemmas for the `TreeMap` operations `filter`, `map` and
`filterMap`. These lemmas existed already for hash maps and are simply
ported over from there.
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.
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]`.
(Almost) only typos in constant names and doc-strings were considered;
grammar was not considered. Also, along others,
`mkDefinitionValInferrringUnsafe` has been fixed :-)
This PR improves the `congr` tactic so that it can handle function
applications with fewer arguments than the arity of the head function.
This also fixes a bug where `congr` could not make progress with
`Set`-valued functions in Mathlib, since `Set` was being unfolded and
making such functions have an apparently higher arity.
This addresses issue #2128 for the `congr` tactic, but not `simp` and
others.
This PR moves the construction of the `Option.SomeLtNone.lt` (and `le`)
relation, in which `some` is less than `none`, to
`Init.Data.Option.Basic` and moves well-foundedness proofs for
`Option.lt` and `Option.SomeLtNone.lt` into `Init.Data.Option.Lemmas`.
This PR proves that the default `toList`, `toListRev` and `toArray`
functions on slices can be described in terms of the slice iterator.
Relying on new lemmas for the `uLift` and `attachWith` iterator
combinators, a more concrete description of said functions is given for
`Subarray`.
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 introduces polymorphic slices in their most basic form. They
come with a notation similar to the new range notation. `Subarray` is
now also a slice and can produce an iterator now. It is intended to
migrate more operations of `Subarray` to the `Slice` wrapper type to
make them available for slices of other types, too.
The PR also moves the `filterMap` combinators into `Init` because they
are used internally to implement iterators on array slices.
This PR adds the types `Std.ExtDTreeMap`, `Std.ExtTreeMap` and
`Std.ExtTreeSet` of extensional tree maps and sets. These are very
similar in construction to the existing extensional hash maps with one
exception: extensional tree maps and sets provide all functions from
regular tree maps and sets. This is possible because in contrast to hash
maps, tree maps are always ordered.
This PR introduces ranges that are polymorphic, in contrast to the
existing `Std.Range` which only supports natural numbers.
Breakdown of core changes:
* `Lean.Parser.Basic`: Modified the number parser (`Lean.Parser.Basic`)
so that it will only consider a *single* dot to be part of a decimal
number. `1..` will no longer be parsed as `1.` followed by `.`, but as
`1` followed by `..`.
* The test `ellipsisProjIssue` ensures that `#check Nat.add ...succ`
produces a syntax error. After introducing the new range notation (see
below), it returns a different (less nice) error message. I updated the
test to reflect the new error message. (The error message will become
nicer as soon as a delaborator for the ranges is implemented. This is
out of scope for this PR.)
Breakdown of standard library changes:
Modified modules: `Init.Data.Range.Polymorphic` (added),
`Init.Data.Iterators`, `Std.Data.Iterators`
* Introduced the type `Std.PRange` that is parameterized over the type
in which the range operates and the shapes of the lower and upper bound.
* Introduced a new notation for ranges. Examples for this notation are:
`1...*`, `1...=3`, `1...<3`, `1<...=2`, `*...=3`.
* Defined lots of typeclasses for different capabilities of ranges,
depending on their shape and underlying type.
* Introduced `Iter(M).size`.
* Introduced the `Iter(M).stepSize n` combinator, which iterates over an
iterator with the given step size `n`. It will drop `n - 1` values
between every value it emits.
* Replaced `LawfulPureIterator` with a new and better typeclass
`LawfulDeterministicIterator`.
* Simplified some lemma statements in the iterator library such as
`IterM.toList_eq_match`, which unnecessarily matched over a `Subtype`,
hindering rewrites due to type dependencies.
Reasons for the concrete choice of notation:
* `lean4-cli` uses `...`-based notation for the `Cmd` notation and it
clashes with `...a` range notation.
* test `2461` fails when using two-dot-based notation because of the
existing `{ a.. }` notation.
This PR adds a generic `MonadLiftT Id m` instance. We do not implement a
`MonadLift Id m` instance because it would slow down instance resolution
and because it would create more non-canonical instances. This change
makes it possible to iterate over a pure iterator, such as `[1, 2,
3].iter`, in arbitrary monads.
