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| Author | SHA1 | Date | |
|---|---|---|---|
|
1e046db407 |
11
.github/workflows/pr-release.yml
vendored
11
.github/workflows/pr-release.yml
vendored
@@ -164,10 +164,10 @@ jobs:
|
||||
|
||||
# Use GitHub API to check if a comment already exists
|
||||
existing_comment="$(curl --retry 3 --location --silent \
|
||||
-H "Authorization: token ${{ secrets.MATHLIB4_COMMENT_BOT }}" \
|
||||
-H "Authorization: token ${{ secrets.MATHLIB4_BOT }}" \
|
||||
-H "Accept: application/vnd.github.v3+json" \
|
||||
"https://api.github.com/repos/leanprover/lean4/issues/${{ steps.workflow-info.outputs.pullRequestNumber }}/comments" \
|
||||
| jq 'first(.[] | select(.body | test("^- . Mathlib") or startswith("Mathlib CI status")) | select(.user.login == "leanprover-community-bot"))')"
|
||||
| jq 'first(.[] | select(.body | test("^- . Mathlib") or startswith("Mathlib CI status")) | select(.user.login == "leanprover-community-mathlib4-bot"))')"
|
||||
existing_comment_id="$(echo "$existing_comment" | jq -r .id)"
|
||||
existing_comment_body="$(echo "$existing_comment" | jq -r .body)"
|
||||
|
||||
@@ -177,14 +177,14 @@ jobs:
|
||||
echo "Posting message to the comments: $MESSAGE"
|
||||
|
||||
# Append new result to the existing comment or post a new comment
|
||||
# It's essential we use the MATHLIB4_COMMENT_BOT token here, so that Mathlib CI can subsequently edit the comment.
|
||||
# It's essential we use the MATHLIB4_BOT token here, so that Mathlib CI can subsequently edit the comment.
|
||||
if [ -z "$existing_comment_id" ]; then
|
||||
INTRO="Mathlib CI status ([docs](https://leanprover-community.github.io/contribute/tags_and_branches.html)):"
|
||||
# Post new comment with a bullet point
|
||||
echo "Posting as new comment at leanprover/lean4/issues/${{ steps.workflow-info.outputs.pullRequestNumber }}/comments"
|
||||
curl -L -s \
|
||||
-X POST \
|
||||
-H "Authorization: token ${{ secrets.MATHLIB4_COMMENT_BOT }}" \
|
||||
-H "Authorization: token ${{ secrets.MATHLIB4_BOT }}" \
|
||||
-H "Accept: application/vnd.github.v3+json" \
|
||||
-d "$(jq --null-input --arg intro "$INTRO" --arg val "$MESSAGE" '{"body":($intro + "\n" + $val)}')" \
|
||||
"https://api.github.com/repos/leanprover/lean4/issues/${{ steps.workflow-info.outputs.pullRequestNumber }}/comments"
|
||||
@@ -193,7 +193,7 @@ jobs:
|
||||
echo "Appending to existing comment at leanprover/lean4/issues/${{ steps.workflow-info.outputs.pullRequestNumber }}/comments"
|
||||
curl -L -s \
|
||||
-X PATCH \
|
||||
-H "Authorization: token ${{ secrets.MATHLIB4_COMMENT_BOT }}" \
|
||||
-H "Authorization: token ${{ secrets.MATHLIB4_BOT }}" \
|
||||
-H "Accept: application/vnd.github.v3+json" \
|
||||
-d "$(jq --null-input --arg existing "$existing_comment_body" --arg message "$MESSAGE" '{"body":($existing + "\n" + $message)}')" \
|
||||
"https://api.github.com/repos/leanprover/lean4/issues/comments/$existing_comment_id"
|
||||
@@ -340,7 +340,6 @@ jobs:
|
||||
# (This should no longer be possible once `nightly-testing-YYYY-MM-DD` is a tag, but it is still safe to merge.)
|
||||
git merge "$BASE" --strategy-option ours --no-commit --allow-unrelated-histories
|
||||
lake update batteries
|
||||
get add lake-manifest.json
|
||||
git commit --allow-empty -m "Trigger CI for https://github.com/leanprover/lean4/pull/${{ steps.workflow-info.outputs.pullRequestNumber }}"
|
||||
fi
|
||||
|
||||
|
||||
314
RELEASES.md
314
RELEASES.md
@@ -10,317 +10,7 @@ of each version.
|
||||
|
||||
v4.12.0
|
||||
----------
|
||||
|
||||
### Language features, tactics, and metaprograms
|
||||
|
||||
* `bv_decide` tactic. This release introduces a new tactic for proving goals involving `BitVec` and `Bool`. It reduces the goal to a SAT instance that is refuted by an external solver, and the resulting LRAT proof is checked in Lean. This is used to synthesize a proof of the goal by reflection. As this process uses verified algorithms, proofs generated by this tactic use `Lean.ofReduceBool`, so this tactic includes the Lean compiler as part of the trusted code base. The external solver CaDiCaL is included with Lean and does not need to be installed separately to make use of `bv_decide`.
|
||||
|
||||
For example, we can use `bv_decide` to verify that a bit twiddling formula leaves at most one bit set:
|
||||
```lean
|
||||
def popcount (x : BitVec 64) : BitVec 64 :=
|
||||
let rec go (x pop : BitVec 64) : Nat → BitVec 64
|
||||
| 0 => pop
|
||||
| n + 1 => go (x >>> 2) (pop + (x &&& 1)) n
|
||||
go x 0 64
|
||||
|
||||
example (x : BitVec 64) : popcount ((x &&& (x - 1)) ^^^ x) ≤ 1 := by
|
||||
simp only [popcount, popcount.go]
|
||||
bv_decide
|
||||
```
|
||||
When the external solver fails to refute the SAT instance generated by `bv_decide`, it can report a counterexample:
|
||||
```lean
|
||||
/--
|
||||
error: The prover found a counterexample, consider the following assignment:
|
||||
x = 0xffffffffffffffff#64
|
||||
-/
|
||||
#guard_msgs in
|
||||
example (x : BitVec 64) : x < x + 1 := by
|
||||
bv_decide
|
||||
```
|
||||
|
||||
See `Lean.Elab.Tactic.BVDecide` for a more detailed overview, and look in `tests/lean/run/bv_*` for examples.
|
||||
|
||||
[#5013](https://github.com/leanprover/lean4/pull/5013), [#5074](https://github.com/leanprover/lean4/pull/5074), [#5100](https://github.com/leanprover/lean4/pull/5100), [#5113](https://github.com/leanprover/lean4/pull/5113), [#5137](https://github.com/leanprover/lean4/pull/5137), [#5203](https://github.com/leanprover/lean4/pull/5203), [#5212](https://github.com/leanprover/lean4/pull/5212), [#5220](https://github.com/leanprover/lean4/pull/5220).
|
||||
|
||||
* `simp` tactic
|
||||
* [#4988](https://github.com/leanprover/lean4/pull/4988) fixes a panic in the `reducePow` simproc.
|
||||
* [#5071](https://github.com/leanprover/lean4/pull/5071) exposes the `index` option to the `dsimp` tactic, introduced to `simp` in [#4202](https://github.com/leanprover/lean4/pull/4202).
|
||||
* [#5159](https://github.com/leanprover/lean4/pull/5159) fixes a panic at `Fin.isValue` simproc.
|
||||
* [#5167](https://github.com/leanprover/lean4/pull/5167) and [#5175](https://github.com/leanprover/lean4/pull/5175) rename the `simpCtorEq` simproc to `reduceCtorEq` and makes it optional. (See breaking changes.)
|
||||
* [#5187](https://github.com/leanprover/lean4/pull/5187) ensures `reduceCtorEq` is enabled in the `norm_cast` tactic.
|
||||
* [#5073](https://github.com/leanprover/lean4/pull/5073) modifies the simp debug trace messages to tag with "dpre" and "dpost" instead of "pre" and "post" when in definitional rewrite mode. [#5054](https://github.com/leanprover/lean4/pull/5054) explains the `reduce` steps for `trace.Debug.Meta.Tactic.simp` trace messages.
|
||||
* `ext` tactic
|
||||
* [#4996](https://github.com/leanprover/lean4/pull/4996) reduces default maximum iteration depth from 1000000 to 100.
|
||||
* `induction` tactic
|
||||
* [#5117](https://github.com/leanprover/lean4/pull/5117) fixes a bug where `let` bindings in minor premises wouldn't be counted correctly.
|
||||
|
||||
* `omega` tactic
|
||||
* [#5157](https://github.com/leanprover/lean4/pull/5157) fixes a panic.
|
||||
|
||||
* `conv` tactic
|
||||
* [#5149](https://github.com/leanprover/lean4/pull/5149) improves `arg n` to handle subsingleton instance arguments.
|
||||
|
||||
* [#5044](https://github.com/leanprover/lean4/pull/5044) upstreams the `#time` command.
|
||||
* [#5079](https://github.com/leanprover/lean4/pull/5079) makes `#check` and `#reduce` typecheck the elaborated terms.
|
||||
|
||||
* **Incrementality**
|
||||
* [#4974](https://github.com/leanprover/lean4/pull/4974) fixes regression where we would not interrupt elaboration of previous document versions.
|
||||
* [#5004](https://github.com/leanprover/lean4/pull/5004) fixes a performance regression.
|
||||
* [#5001](https://github.com/leanprover/lean4/pull/5001) disables incremental body elaboration in presence of `where` clauses in declarations.
|
||||
* [#5018](https://github.com/leanprover/lean4/pull/5018) enables infotrees on the command line for ilean generation.
|
||||
* [#5040](https://github.com/leanprover/lean4/pull/5040) and [#5056](https://github.com/leanprover/lean4/pull/5056) improve performance of info trees.
|
||||
* [#5090](https://github.com/leanprover/lean4/pull/5090) disables incrementality in the `case .. | ..` tactic.
|
||||
* [#5312](https://github.com/leanprover/lean4/pull/5312) fixes a bug where changing whitespace after the module header could break subsequent commands.
|
||||
|
||||
* **Definitions**
|
||||
* [#5016](https://github.com/leanprover/lean4/pull/5016) and [#5066](https://github.com/leanprover/lean4/pull/5066) add `clean_wf` tactic to clean up tactic state in `decreasing_by`. This can be disabled with `set_option debug.rawDecreasingByGoal false`.
|
||||
* [#5055](https://github.com/leanprover/lean4/pull/5055) unifies equational theorems between structural and well-founded recursion.
|
||||
* [#5041](https://github.com/leanprover/lean4/pull/5041) allows mutually recursive functions to use different parameter names among the “fixed parameter prefix”
|
||||
* [#4154](https://github.com/leanprover/lean4/pull/4154) and [#5109](https://github.com/leanprover/lean4/pull/5109) add fine-grained equational lemmas for non-recursive functions. See breaking changes.
|
||||
* [#5129](https://github.com/leanprover/lean4/pull/5129) unifies equation lemmas for recursive and non-recursive definitions. The `backward.eqns.deepRecursiveSplit` option can be set to `false` to get the old behavior. See breaking changes.
|
||||
* [#5141](https://github.com/leanprover/lean4/pull/5141) adds `f.eq_unfold` lemmas. Now Lean produces the following zoo of rewrite rules:
|
||||
```
|
||||
Option.map.eq_1 : Option.map f none = none
|
||||
Option.map.eq_2 : Option.map f (some x) = some (f x)
|
||||
Option.map.eq_def : Option.map f p = match o with | none => none | (some x) => some (f x)
|
||||
Option.map.eq_unfold : Option.map = fun f p => match o with | none => none | (some x) => some (f x)
|
||||
```
|
||||
The `f.eq_unfold` variant is especially useful to rewrite with `rw` under binders.
|
||||
* [#5136](https://github.com/leanprover/lean4/pull/5136) fixes bugs in recursion over predicates.
|
||||
|
||||
* **Variable inclusion**
|
||||
* [#5206](https://github.com/leanprover/lean4/pull/5206) documents that `include` currently only applies to theorems.
|
||||
|
||||
* **Elaboration**
|
||||
* [#4926](https://github.com/leanprover/lean4/pull/4926) fixes a bug where autoparam errors were associated to an incorrect source position.
|
||||
* [#4833](https://github.com/leanprover/lean4/pull/4833) fixes an issue where cdot anonymous functions (e.g. `(· + ·)`) would not handle ambiguous notation correctly. Numbers the parameters, making this example expand as `fun x1 x2 => x1 + x2` rather than `fun x x_1 => x + x_1`.
|
||||
* [#5037](https://github.com/leanprover/lean4/pull/5037) improves strength of the tactic that proves array indexing is in bounds.
|
||||
* [#5119](https://github.com/leanprover/lean4/pull/5119) fixes a bug in the tactic that proves indexing is in bounds where it could loop in the presence of mvars.
|
||||
* [#5072](https://github.com/leanprover/lean4/pull/5072) makes the structure type clickable in "not a field of structure" errors for structure instance notation.
|
||||
* [#4717](https://github.com/leanprover/lean4/pull/4717) fixes a bug where mutual `inductive` commands could create terms that the kernel rejects.
|
||||
* [#5142](https://github.com/leanprover/lean4/pull/5142) fixes a bug where `variable` could fail when mixing binder updates and declarations.
|
||||
|
||||
* **Other fixes or improvements**
|
||||
* [#5118](https://github.com/leanprover/lean4/pull/5118) changes the definition of the `syntheticHole` parser so that hovering over `_` in `?_` gives the docstring for synthetic holes.
|
||||
* [#5173](https://github.com/leanprover/lean4/pull/5173) uses the emoji variant selector for ✅️,❌️,💥️ in messages, improving fonts selection.
|
||||
* [#5183](https://github.com/leanprover/lean4/pull/5183) fixes a bug in `rename_i` where implementation detail hypotheses could be renamed.
|
||||
|
||||
### Language server, widgets, and IDE extensions
|
||||
|
||||
* [#4821](https://github.com/leanprover/lean4/pull/4821) resolves two language server bugs that especially affect Windows users. (1) Editing the header could result in the watchdog not correctly restarting the file worker, which would lead to the file seemingly being processed forever. (2) On an especially slow Windows machine, we found that starting the language server would sometimes not succeed at all. This PR also resolves an issue where we would not correctly emit messages that we received while the file worker is being restarted to the corresponding file worker after the restart.
|
||||
* [#5006](https://github.com/leanprover/lean4/pull/5006) updates the user widget manual.
|
||||
* [#5193](https://github.com/leanprover/lean4/pull/5193) updates the quickstart guide with the new display name for the Lean 4 extension ("Lean 4").
|
||||
* [#5185](https://github.com/leanprover/lean4/pull/5185) fixes a bug where over time "import out of date" messages would accumulate.
|
||||
* [#4900](https://github.com/leanprover/lean4/pull/4900) improves ilean loading performance by about a factor of two. Optimizes the JSON parser and the conversion from JSON to Lean data structures; see PR description for details.
|
||||
* **Other fixes or improvements**
|
||||
* [#5031](https://github.com/leanprover/lean4/pull/5031) localizes an instance in `Lsp.Diagnostics`.
|
||||
|
||||
### Pretty printing
|
||||
|
||||
* [#4976](https://github.com/leanprover/lean4/pull/4976) introduces `@[app_delab]`, a macro for creating delaborators for particular constants. The `@[app_delab ident]` syntax resolves `ident` to its constant name `name` and then expands to `@[delab app.name]`.
|
||||
* [#4982](https://github.com/leanprover/lean4/pull/4982) fixes a bug where the pretty printer assumed structure projections were type correct (such terms can appear in type mismatch errors). Improves hoverability of `#print` output for structures.
|
||||
* [#5218](https://github.com/leanprover/lean4/pull/5218) and [#5239](https://github.com/leanprover/lean4/pull/5239) add `pp.exprSizes` debugging option. When true, each pretty printed expression is prefixed with `[size a/b/c]`, where `a` is the size without sharing, `b` is the actual size, and `c` is the size with the maximum possible sharing.
|
||||
|
||||
### Library
|
||||
|
||||
* [#5020](https://github.com/leanprover/lean4/pull/5020) swaps the parameters to `Membership.mem`. A purpose of this change is to make set-like `CoeSort` coercions to refer to the eta-expanded function `fun x => Membership.mem s x`, which can reduce in many computations. Another is that having the `s` argument first leads to better discrimination tree keys. (See breaking changes.)
|
||||
* `Array`
|
||||
* [#4970](https://github.com/leanprover/lean4/pull/4970) adds `@[ext]` attribute to `Array.ext`.
|
||||
* [#4957](https://github.com/leanprover/lean4/pull/4957) deprecates `Array.get_modify`.
|
||||
* `List`
|
||||
* [#4995](https://github.com/leanprover/lean4/pull/4995) upstreams `List.findIdx` lemmas.
|
||||
* [#5029](https://github.com/leanprover/lean4/pull/5029), [#5048](https://github.com/leanprover/lean4/pull/5048) and [#5132](https://github.com/leanprover/lean4/pull/5132) add `List.Sublist` lemmas, some upstreamed. [#5077](https://github.com/leanprover/lean4/pull/5077) fixes implicitness in refl/rfl lemma binders. add `List.Sublist` theorems.
|
||||
* [#5047](https://github.com/leanprover/lean4/pull/5047) upstreams `List.Pairwise` lemmas.
|
||||
* [#5053](https://github.com/leanprover/lean4/pull/5053), [#5124](https://github.com/leanprover/lean4/pull/5124), and [#5161](https://github.com/leanprover/lean4/pull/5161) add `List.find?/findSome?/findIdx?` theorems.
|
||||
* [#5039](https://github.com/leanprover/lean4/pull/5039) adds `List.foldlRecOn` and `List.foldrRecOn` recursion principles to prove things about `List.foldl` and `List.foldr`.
|
||||
* [#5069](https://github.com/leanprover/lean4/pull/5069) upstreams `List.Perm`.
|
||||
* [#5092](https://github.com/leanprover/lean4/pull/5092) and [#5107](https://github.com/leanprover/lean4/pull/5107) add `List.mergeSort` and a fast `@[csimp]` implementation.
|
||||
* [#5103](https://github.com/leanprover/lean4/pull/5103) makes the simp lemmas for `List.subset` more aggressive.
|
||||
* [#5106](https://github.com/leanprover/lean4/pull/5106) changes the statement of `List.getLast?_cons`.
|
||||
* [#5123](https://github.com/leanprover/lean4/pull/5123) and [#5158](https://github.com/leanprover/lean4/pull/5158) add `List.range` and `List.iota` lemmas.
|
||||
* [#5130](https://github.com/leanprover/lean4/pull/5130) adds `List.join` lemmas.
|
||||
* [#5131](https://github.com/leanprover/lean4/pull/5131) adds `List.append` lemmas.
|
||||
* [#5152](https://github.com/leanprover/lean4/pull/5152) adds `List.erase(|P|Idx)` lemmas.
|
||||
* [#5127](https://github.com/leanprover/lean4/pull/5127) makes miscellaneous lemma updates.
|
||||
* [#5153](https://github.com/leanprover/lean4/pull/5153) and [#5160](https://github.com/leanprover/lean4/pull/5160) add lemmas about `List.attach` and `List.pmap`.
|
||||
* [#5164](https://github.com/leanprover/lean4/pull/5164), [#5177](https://github.com/leanprover/lean4/pull/5177), and [#5215](https://github.com/leanprover/lean4/pull/5215) add `List.find?` and `List.range'/range/iota` lemmas.
|
||||
* [#5196](https://github.com/leanprover/lean4/pull/5196) adds `List.Pairwise_erase` and related lemmas.
|
||||
* [#5151](https://github.com/leanprover/lean4/pull/5151) and [#5163](https://github.com/leanprover/lean4/pull/5163) improve confluence of `List` simp lemmas. [#5105](https://github.com/leanprover/lean4/pull/5105) and [#5102](https://github.com/leanprover/lean4/pull/5102) adjust `List` simp lemmas.
|
||||
* [#5178](https://github.com/leanprover/lean4/pull/5178) removes `List.getLast_eq_iff_getLast_eq_some` as a simp lemma.
|
||||
* [#5210](https://github.com/leanprover/lean4/pull/5210) reverses the meaning of `List.getElem_drop` and `List.getElem_drop'`.
|
||||
* [#5214](https://github.com/leanprover/lean4/pull/5214) moves `@[csimp]` lemmas earlier where possible.
|
||||
* `Nat` and `Int`
|
||||
* [#5104](https://github.com/leanprover/lean4/pull/5104) adds `Nat.add_left_eq_self` and relatives.
|
||||
* [#5146](https://github.com/leanprover/lean4/pull/5146) adds missing `Nat.and_xor_distrib_(left|right)`.
|
||||
* [#5148](https://github.com/leanprover/lean4/pull/5148) and [#5190](https://github.com/leanprover/lean4/pull/5190) improve `Nat` and `Int` simp lemma confluence.
|
||||
* [#5165](https://github.com/leanprover/lean4/pull/5165) adjusts `Int` simp lemmas.
|
||||
* [#5166](https://github.com/leanprover/lean4/pull/5166) adds `Int` lemmas relating `neg` and `emod`/`mod`.
|
||||
* [#5208](https://github.com/leanprover/lean4/pull/5208) reverses the direction of the `Int.toNat_sub` simp lemma.
|
||||
* [#5209](https://github.com/leanprover/lean4/pull/5209) adds `Nat.bitwise` lemmas.
|
||||
* [#5230](https://github.com/leanprover/lean4/pull/5230) corrects the docstrings for integer division and modulus.
|
||||
* `Option`
|
||||
* [#5128](https://github.com/leanprover/lean4/pull/5128) and [#5154](https://github.com/leanprover/lean4/pull/5154) add `Option` lemmas.
|
||||
* `BitVec`
|
||||
* [#4889](https://github.com/leanprover/lean4/pull/4889) adds `sshiftRight` bitblasting.
|
||||
* [#4981](https://github.com/leanprover/lean4/pull/4981) adds `Std.Associative` and `Std.Commutative` instances for `BitVec.[and|or|xor]`.
|
||||
* [#4913](https://github.com/leanprover/lean4/pull/4913) enables `missingDocs` error for `BitVec` modules.
|
||||
* [#4930](https://github.com/leanprover/lean4/pull/4930) makes parameter names for `BitVec` more consistent.
|
||||
* [#5098](https://github.com/leanprover/lean4/pull/5098) adds `BitVec.intMin`. Introduces `boolToPropSimps` simp set for converting from boolean to propositional expressions.
|
||||
* [#5200](https://github.com/leanprover/lean4/pull/5200) and [#5217](https://github.com/leanprover/lean4/pull/5217) rename `BitVec.getLsb` to `BitVec.getLsbD`, etc., to bring naming in line with `List`/`Array`/etc.
|
||||
* **Theorems:** [#4977](https://github.com/leanprover/lean4/pull/4977), [#4951](https://github.com/leanprover/lean4/pull/4951), [#4667](https://github.com/leanprover/lean4/pull/4667), [#5007](https://github.com/leanprover/lean4/pull/5007), [#4997](https://github.com/leanprover/lean4/pull/4997), [#5083](https://github.com/leanprover/lean4/pull/5083), [#5081](https://github.com/leanprover/lean4/pull/5081), [#4392](https://github.com/leanprover/lean4/pull/4392)
|
||||
* `UInt`
|
||||
* [#4514](https://github.com/leanprover/lean4/pull/4514) fixes naming convention for `UInt` lemmas.
|
||||
* `Std.HashMap` and `Std.HashSet`
|
||||
* [#4943](https://github.com/leanprover/lean4/pull/4943) deprecates variants of hash map query methods. (See breaking changes.)
|
||||
* [#4917](https://github.com/leanprover/lean4/pull/4917) switches the library and Lean to `Std.HashMap` and `Std.HashSet` almost everywhere.
|
||||
* [#4954](https://github.com/leanprover/lean4/pull/4954) deprecates `Lean.HashMap` and `Lean.HashSet`.
|
||||
* [#5023](https://github.com/leanprover/lean4/pull/5023) cleans up lemma parameters.
|
||||
|
||||
* `Std.Sat` (for `bv_decide`)
|
||||
* [#4933](https://github.com/leanprover/lean4/pull/4933) adds definitions of SAT and CNF.
|
||||
* [#4953](https://github.com/leanprover/lean4/pull/4953) defines "and-inverter graphs" (AIGs) as described in section 3 of [Davis-Swords 2013](https://arxiv.org/pdf/1304.7861.pdf).
|
||||
|
||||
* **Parsec**
|
||||
* [#4774](https://github.com/leanprover/lean4/pull/4774) generalizes the `Parsec` library, allowing parsing of iterable data beyong `String` such as `ByteArray`. (See breaking changes.)
|
||||
* [#5115](https://github.com/leanprover/lean4/pull/5115) moves `Lean.Data.Parsec` to `Std.Internal.Parsec` for bootstrappng reasons.
|
||||
|
||||
* `Thunk`
|
||||
* [#4969](https://github.com/leanprover/lean4/pull/4969) upstreams `Thunk.ext`.
|
||||
|
||||
* **IO**
|
||||
* [#4973](https://github.com/leanprover/lean4/pull/4973) modifies `IO.FS.lines` to handle `\r\n` on all operating systems instead of just on Windows.
|
||||
* [#5125](https://github.com/leanprover/lean4/pull/5125) adds `createTempFile` and `withTempFile` for creating temporary files that can only be read and written by the current user.
|
||||
|
||||
* **Other fixes or improvements**
|
||||
* [#4945](https://github.com/leanprover/lean4/pull/4945) adds `Array`, `Bool` and `Prod` utilities from LeanSAT.
|
||||
* [#4960](https://github.com/leanprover/lean4/pull/4960) adds `Relation.TransGen.trans`.
|
||||
* [#5012](https://github.com/leanprover/lean4/pull/5012) states `WellFoundedRelation Nat` using `<`, not `Nat.lt`.
|
||||
* [#5011](https://github.com/leanprover/lean4/pull/5011) uses `≠` instead of `Not (Eq ...)` in `Fin.ne_of_val_ne`.
|
||||
* [#5197](https://github.com/leanprover/lean4/pull/5197) upstreams `Fin.le_antisymm`.
|
||||
* [#5042](https://github.com/leanprover/lean4/pull/5042) reduces usage of `refine'`.
|
||||
* [#5101](https://github.com/leanprover/lean4/pull/5101) adds about `if-then-else` and `Option`.
|
||||
* [#5112](https://github.com/leanprover/lean4/pull/5112) adds basic instances for `ULift` and `PLift`.
|
||||
* [#5133](https://github.com/leanprover/lean4/pull/5133) and [#5168](https://github.com/leanprover/lean4/pull/5168) make fixes from running the simpNF linter over Lean.
|
||||
* [#5156](https://github.com/leanprover/lean4/pull/5156) removes a bad simp lemma in `omega` theory.
|
||||
* [#5155](https://github.com/leanprover/lean4/pull/5155) improves confluence of `Bool` simp lemmas.
|
||||
* [#5162](https://github.com/leanprover/lean4/pull/5162) improves confluence of `Function.comp` simp lemmas.
|
||||
* [#5191](https://github.com/leanprover/lean4/pull/5191) improves confluence of `if-then-else` simp lemmas.
|
||||
* [#5147](https://github.com/leanprover/lean4/pull/5147) adds `@[elab_as_elim]` to `Quot.rec`, `Nat.strongInductionOn` and `Nat.casesStrongInductionOn`, and also renames the latter two to `Nat.strongRecOn` and `Nat.casesStrongRecOn` (deprecated in [#5179](https://github.com/leanprover/lean4/pull/5179)).
|
||||
* [#5180](https://github.com/leanprover/lean4/pull/5180) disables some simp lemmas with bad discrimination tree keys.
|
||||
* [#5189](https://github.com/leanprover/lean4/pull/5189) cleans up internal simp lemmas that had leaked.
|
||||
* [#5198](https://github.com/leanprover/lean4/pull/5198) cleans up `allowUnsafeReducibility`.
|
||||
* [#5229](https://github.com/leanprover/lean4/pull/5229) removes unused lemmas from some `simp` tactics.
|
||||
* [#5199](https://github.com/leanprover/lean4/pull/5199) removes >6 month deprecations.
|
||||
|
||||
### Lean internals
|
||||
|
||||
* **Performance**
|
||||
* Some core algorithms have been rewritten in C++ for performance.
|
||||
* [#4910](https://github.com/leanprover/lean4/pull/4910) and [#4912](https://github.com/leanprover/lean4/pull/4912) reimplement `instantiateLevelMVars`.
|
||||
* [#4915](https://github.com/leanprover/lean4/pull/4915), [#4922](https://github.com/leanprover/lean4/pull/4922), and [#4931](https://github.com/leanprover/lean4/pull/4931) reimplement `instantiateExprMVars`, 30% faster on a benchmark.
|
||||
* [#4934](https://github.com/leanprover/lean4/pull/4934) has optimizations for the kernel's `Expr` equality test.
|
||||
* [#4990](https://github.com/leanprover/lean4/pull/4990) fixes bug in hashing for the kernel's `Expr` equality test.
|
||||
* [#4935](https://github.com/leanprover/lean4/pull/4935) and [#4936](https://github.com/leanprover/lean4/pull/4936) skip some `PreDefinition` transformations if they are not needed.
|
||||
* [#5225](https://github.com/leanprover/lean4/pull/5225) adds caching for visited exprs at `CheckAssignmentQuick` in `ExprDefEq`.
|
||||
* [#5226](https://github.com/leanprover/lean4/pull/5226) maximizes term sharing at `instantiateMVarDeclMVars`, used by `runTactic`.
|
||||
* **Diagnostics and profiling**
|
||||
* [#4923](https://github.com/leanprover/lean4/pull/4923) adds profiling for `instantiateMVars` in `Lean.Elab.MutualDef`, which can be a bottleneck there.
|
||||
* [#4924](https://github.com/leanprover/lean4/pull/4924) adds diagnostics for large theorems, controlled by the `diagnostics.threshold.proofSize` option.
|
||||
* [#4897](https://github.com/leanprover/lean4/pull/4897) improves display of diagnostic results.
|
||||
* **Other fixes or improvements**
|
||||
* [#4921](https://github.com/leanprover/lean4/pull/4921) cleans up `Expr.betaRev`.
|
||||
* [#4940](https://github.com/leanprover/lean4/pull/4940) fixes tests by not writing directly to stdout, which is unreliable now that elaboration and reporting are executed in separate threads.
|
||||
* [#4955](https://github.com/leanprover/lean4/pull/4955) documents that `stderrAsMessages` is now the default on the command line as well.
|
||||
* [#4647](https://github.com/leanprover/lean4/pull/4647) adjusts documentation for building on macOS.
|
||||
* [#4987](https://github.com/leanprover/lean4/pull/4987) makes regular mvar assignments take precedence over delayed ones in `instantiateMVars`. Normally delayed assignment metavariables are never directly assigned, but on errors Lean assigns `sorry` to unassigned metavariables.
|
||||
* [#4967](https://github.com/leanprover/lean4/pull/4967) adds linter name to errors when a linter crashes.
|
||||
* [#5043](https://github.com/leanprover/lean4/pull/5043) cleans up command line snapshots logic.
|
||||
* [#5067](https://github.com/leanprover/lean4/pull/5067) minimizes some imports.
|
||||
* [#5068](https://github.com/leanprover/lean4/pull/5068) generalizes the monad for `addMatcherInfo`.
|
||||
* [f71a1f](https://github.com/leanprover/lean4/commit/f71a1fb4ae958fccb3ad4d48786a8f47ced05c15) adds missing test for [#5126](https://github.com/leanprover/lean4/issues/5126).
|
||||
* [#5201](https://github.com/leanprover/lean4/pull/5201) restores a test.
|
||||
* [#3698](https://github.com/leanprover/lean4/pull/3698) fixes a bug where label attributes did not pass on the attribute kind.
|
||||
* Typos: [#5080](https://github.com/leanprover/lean4/pull/5080), [#5150](https://github.com/leanprover/lean4/pull/5150), [#5202](https://github.com/leanprover/lean4/pull/5202)
|
||||
|
||||
### Compiler, runtime, and FFI
|
||||
|
||||
* [#3106](https://github.com/leanprover/lean4/pull/3106) moves frontend to new snapshot architecture. Note that `Frontend.processCommand` and `FrontendM` are no longer used by Lean core, but they will be preserved.
|
||||
* [#4919](https://github.com/leanprover/lean4/pull/4919) adds missing include in runtime for `AUTO_THREAD_FINALIZATION` feature on Windows.
|
||||
* [#4941](https://github.com/leanprover/lean4/pull/4941) adds more `LEAN_EXPORT`s for Windows.
|
||||
* [#4911](https://github.com/leanprover/lean4/pull/4911) improves formatting of CLI help text for the frontend.
|
||||
* [#4950](https://github.com/leanprover/lean4/pull/4950) improves file reading and writing.
|
||||
* `readBinFile` and `readFile` now only require two system calls (`stat` + `read`) instead of one `read` per 1024 byte chunk.
|
||||
* `Handle.getLine` and `Handle.putStr` no longer get tripped up by NUL characters.
|
||||
* [#4971](https://github.com/leanprover/lean4/pull/4971) handles the SIGBUS signal when detecting stack overflows.
|
||||
* [#5062](https://github.com/leanprover/lean4/pull/5062) avoids overwriting existing signal handlers, like in [rust-lang/rust#69685](https://github.com/rust-lang/rust/pull/69685).
|
||||
* [#4860](https://github.com/leanprover/lean4/pull/4860) improves workarounds for building on Windows. Splits `libleanshared` on Windows to avoid symbol limit, removes the `LEAN_EXPORT` denylist workaround, adds missing `LEAN_EXPORT`s.
|
||||
* [#4952](https://github.com/leanprover/lean4/pull/4952) output panics into Lean's redirected stderr, ensuring panics ARE visible as regular messages in the language server and properly ordered in relation to other messages on the command line.
|
||||
* [#4963](https://github.com/leanprover/lean4/pull/4963) links LibUV.
|
||||
|
||||
### Lake
|
||||
|
||||
* [#5030](https://github.com/leanprover/lean4/pull/5030) removes dead code.
|
||||
* [#4770](https://github.com/leanprover/lean4/pull/4770) adds additional fields to the package configuration which will be used by Reservoir. See the PR description for details.
|
||||
|
||||
|
||||
### DevOps/CI
|
||||
* [#4914](https://github.com/leanprover/lean4/pull/4914) and [#4937](https://github.com/leanprover/lean4/pull/4937) improve the release checklist.
|
||||
* [#4925](https://github.com/leanprover/lean4/pull/4925) ignores stale leanpkg tests.
|
||||
* [#5003](https://github.com/leanprover/lean4/pull/5003) upgrades `actions/cache` in CI.
|
||||
* [#5010](https://github.com/leanprover/lean4/pull/5010) sets `save-always` in cache actions in CI.
|
||||
* [#5008](https://github.com/leanprover/lean4/pull/5008) adds more libuv search patterns for the speedcenter.
|
||||
* [#5009](https://github.com/leanprover/lean4/pull/5009) reduce number of runs in the speedcenter for "fast" benchmarks from 10 to 3.
|
||||
* [#5014](https://github.com/leanprover/lean4/pull/5014) adjusts lakefile editing to use new `git` syntax in `pr-release` workflow.
|
||||
* [#5025](https://github.com/leanprover/lean4/pull/5025) has `pr-release` workflow pass `--retry` to `curl`.
|
||||
* [#5022](https://github.com/leanprover/lean4/pull/5022) builds MacOS Aarch64 release for PRs by default.
|
||||
* [#5045](https://github.com/leanprover/lean4/pull/5045) adds libuv to the required packages heading in macos docs.
|
||||
* [#5034](https://github.com/leanprover/lean4/pull/5034) fixes the install name of `libleanshared_1` on macOS.
|
||||
* [#5051](https://github.com/leanprover/lean4/pull/5051) fixes Windows stage 0.
|
||||
* [#5052](https://github.com/leanprover/lean4/pull/5052) fixes 32bit stage 0 builds in CI.
|
||||
* [#5057](https://github.com/leanprover/lean4/pull/5057) avoids rebuilding `leanmanifest` in each build.
|
||||
* [#5099](https://github.com/leanprover/lean4/pull/5099) makes `restart-on-label` workflow also filter by commit SHA.
|
||||
* [#4325](https://github.com/leanprover/lean4/pull/4325) adds CaDiCaL.
|
||||
|
||||
### Breaking changes
|
||||
|
||||
* [LibUV](https://libuv.org/) is now required to build Lean. This change only affects developers who compile Lean themselves instead of obtaining toolchains via `elan`. We have updated the official build instructions with information on how to obtain LibUV on our supported platforms. ([#4963](https://github.com/leanprover/lean4/pull/4963))
|
||||
|
||||
* Recursive definitions with a `decreasing_by` clause that begins with `simp_wf` may break. Try removing `simp_wf` or replacing it with `simp`. ([#5016](https://github.com/leanprover/lean4/pull/5016))
|
||||
|
||||
* The behavior of `rw [f]` where `f` is a non-recursive function defined by pattern matching changed.
|
||||
|
||||
For example, preciously, `rw [Option.map]` would rewrite `Option.map f o` to `match o with … `. Now this rewrite fails because it will use the equational lemmas, and these require constructors – just like for `List.map`.
|
||||
|
||||
Remedies:
|
||||
* Split on `o` before rewriting.
|
||||
* Use `rw [Option.map.eq_def]`, which rewrites any (saturated) application of `Option.map`.
|
||||
* Use `set_option backward.eqns.nonrecursive false` when *defining* the function in question.
|
||||
([#4154](https://github.com/leanprover/lean4/pull/4154))
|
||||
|
||||
* The unified handling of equation lemmas for recursive and non-recursive functions can break existing code, as there now can be extra equational lemmas:
|
||||
|
||||
* Explicit uses of `f.eq_2` might have to be adjusted if the numbering changed.
|
||||
|
||||
* Uses of `rw [f]` or `simp [f]` may no longer apply if they previously matched (and introduced a `match` statement), when the equational lemmas got more fine-grained.
|
||||
|
||||
In this case either case analysis on the parameters before rewriting helps, or setting the option `backward.eqns.deepRecursiveSplit false` while *defining* the function.
|
||||
|
||||
([#5129](https://github.com/leanprover/lean4/pull/5129), [#5207](https://github.com/leanprover/lean4/pull/5207))
|
||||
|
||||
* The `reduceCtorEq` simproc is now optional, and it might need to be included in lists of simp lemmas, like `simp only [reduceCtorEq]`. This simproc is responsible for reducing equalities of constructors. ([#5167](https://github.com/leanprover/lean4/pull/5167))
|
||||
|
||||
* `Nat.strongInductionOn` is now `Nat.strongRecOn` and `Nat.caseStrongInductionOn` to `Nat.caseStrongRecOn`. ([#5147](https://github.com/leanprover/lean4/pull/5147))
|
||||
|
||||
* The parameters to `Membership.mem` have been swapped, which affects all `Membership` instances. ([#5020](https://github.com/leanprover/lean4/pull/5020))
|
||||
|
||||
* The meanings of `List.getElem_drop` and `List.getElem_drop'` have been reversed and the first is now a simp lemma. ([#5210](https://github.com/leanprover/lean4/pull/5210))
|
||||
|
||||
* The `Parsec` library has moved from `Lean.Data.Parsec` to `Std.Internal.Parsec`. The `Parsec` type is now more general with a parameter for an iterable. Users parsing strings can migrate to `Parser` in the `Std.Internal.Parsec.String` namespace, which also includes string-focused parsing combinators. ([#4774](https://github.com/leanprover/lean4/pull/4774))
|
||||
|
||||
* The `Lean` module has switched from `Lean.HashMap` and `Lean.HashSet` to `Std.HashMap` and `Std.HashSet` ([#4943](https://github.com/leanprover/lean4/pull/4943)). `Lean.HashMap` and `Lean.HashSet` are now deprecated ([#4954](https://github.com/leanprover/lean4/pull/4954)) and will be removed in a future release. Users of `Lean` APIs that interact with hash maps, for example `Lean.Environment.const2ModIdx`, might encounter minor breakage due to the following changes from `Lean.HashMap` to `Std.HashMap`:
|
||||
* query functions use the term `get` instead of `find`, ([#4943](https://github.com/leanprover/lean4/pull/4943))
|
||||
* the notation `map[key]` no longer returns an optional value but instead expects a proof that the key is present in the map. The previous behavior is available via the `map[key]?` notation.
|
||||
|
||||
Development in progress.
|
||||
|
||||
v4.11.0
|
||||
----------
|
||||
@@ -331,7 +21,7 @@ v4.11.0
|
||||
|
||||
See breaking changes below.
|
||||
|
||||
PRs: [#4883](https://github.com/leanprover/lean4/pull/4883), [#4814](https://github.com/leanprover/lean4/pull/4814), [#5000](https://github.com/leanprover/lean4/pull/5000), [#5036](https://github.com/leanprover/lean4/pull/5036), [#5138](https://github.com/leanprover/lean4/pull/5138), [0edf1b](https://github.com/leanprover/lean4/commit/0edf1bac392f7e2fe0266b28b51c498306363a84).
|
||||
PRs: [#4883](https://github.com/leanprover/lean4/pull/4883), [1242ff](https://github.com/leanprover/lean4/commit/1242ffbfb5a79296041683682268e770fc3cf820), [#5000](https://github.com/leanprover/lean4/pull/5000), [#5036](https://github.com/leanprover/lean4/pull/5036), [#5138](https://github.com/leanprover/lean4/pull/5138), [0edf1b](https://github.com/leanprover/lean4/commit/0edf1bac392f7e2fe0266b28b51c498306363a84).
|
||||
|
||||
* **Recursive definitions**
|
||||
* Structural recursion can now be explicitly requested using
|
||||
|
||||
3
releases_drafts/hashmap.md
Normal file
3
releases_drafts/hashmap.md
Normal file
@@ -0,0 +1,3 @@
|
||||
* The `Lean` module has switched from `Lean.HashMap` and `Lean.HashSet` to `Std.HashMap` and `Std.HashSet`. `Lean.HashMap` and `Lean.HashSet` are now deprecated and will be removed in a future release. Users of `Lean` APIs that interact with hash maps, for example `Lean.Environment.const2ModIdx`, might encounter minor breakage due to the following breaking changes from `Lean.HashMap` to `Std.HashMap`:
|
||||
* query functions use the term `get` instead of `find`,
|
||||
* the notation `map[key]` no longer returns an optional value but expects a proof that the key is present in the map instead. The previous behavior is available via the `map[key]?` notation.
|
||||
1
releases_drafts/libuv.md
Normal file
1
releases_drafts/libuv.md
Normal file
@@ -0,0 +1 @@
|
||||
* #4963 [LibUV](https://libuv.org/) is now required to build Lean. This change only affects developers who compile Lean themselves instead of obtaining toolchains via `elan`. We have updated the official build instructions with information on how to obtain LibUV on our supported platforms.
|
||||
@@ -80,8 +80,6 @@ noncomputable scoped instance (priority := low) propDecidable (a : Prop) : Decid
|
||||
noncomputable def decidableInhabited (a : Prop) : Inhabited (Decidable a) where
|
||||
default := inferInstance
|
||||
|
||||
instance (a : Prop) : Nonempty (Decidable a) := ⟨propDecidable a⟩
|
||||
|
||||
noncomputable def typeDecidableEq (α : Sort u) : DecidableEq α :=
|
||||
fun _ _ => inferInstance
|
||||
|
||||
|
||||
@@ -133,9 +133,6 @@ theorem seqLeft_eq_bind [Monad m] [LawfulMonad m] (x : m α) (y : m β) : x <* y
|
||||
rw [← bind_pure_comp]
|
||||
simp only [bind_assoc, pure_bind]
|
||||
|
||||
@[simp] theorem Functor.map_unit [Monad m] [LawfulMonad m] {a : m PUnit} : (fun _ => PUnit.unit) <$> a = a := by
|
||||
simp [map]
|
||||
|
||||
/--
|
||||
An alternative constructor for `LawfulMonad` which has more
|
||||
defaultable fields in the common case.
|
||||
@@ -183,9 +180,9 @@ end Id
|
||||
|
||||
instance : LawfulMonad Option := LawfulMonad.mk'
|
||||
(id_map := fun x => by cases x <;> rfl)
|
||||
(pure_bind := fun _ _ => rfl)
|
||||
(bind_assoc := fun x _ _ => by cases x <;> rfl)
|
||||
(bind_pure_comp := fun _ x => by cases x <;> rfl)
|
||||
(pure_bind := fun x f => rfl)
|
||||
(bind_assoc := fun x f g => by cases x <;> rfl)
|
||||
(bind_pure_comp := fun f x => by cases x <;> rfl)
|
||||
|
||||
instance : LawfulApplicative Option := inferInstance
|
||||
instance : LawfulFunctor Option := inferInstance
|
||||
|
||||
@@ -84,19 +84,14 @@ instance [Monad m] [LawfulMonad m] : LawfulMonad (ExceptT ε m) where
|
||||
pure_bind := by intros; apply ext; simp [run_bind]
|
||||
bind_assoc := by intros; apply ext; simp [run_bind]; apply bind_congr; intro a; cases a <;> simp
|
||||
|
||||
@[simp] theorem map_throw [Monad m] [LawfulMonad m] {α β : Type _} (f : α → β) (e : ε) :
|
||||
f <$> (throw e : ExceptT ε m α) = (throw e : ExceptT ε m β) := by
|
||||
simp only [ExceptT.instMonad, ExceptT.map, ExceptT.mk, throw, throwThe, MonadExceptOf.throw,
|
||||
pure_bind]
|
||||
|
||||
end ExceptT
|
||||
|
||||
/-! # Except -/
|
||||
|
||||
instance : LawfulMonad (Except ε) := LawfulMonad.mk'
|
||||
(id_map := fun x => by cases x <;> rfl)
|
||||
(pure_bind := fun _ _ => rfl)
|
||||
(bind_assoc := fun a _ _ => by cases a <;> rfl)
|
||||
(pure_bind := fun a f => rfl)
|
||||
(bind_assoc := fun a f g => by cases a <;> rfl)
|
||||
|
||||
instance : LawfulApplicative (Except ε) := inferInstance
|
||||
instance : LawfulFunctor (Except ε) := inferInstance
|
||||
|
||||
@@ -5,7 +5,6 @@ Authors: Joachim Breitner, Mario Carneiro
|
||||
-/
|
||||
prelude
|
||||
import Init.Data.Array.Mem
|
||||
import Init.Data.Array.Lemmas
|
||||
import Init.Data.List.Attach
|
||||
|
||||
namespace Array
|
||||
@@ -27,154 +26,4 @@ Unsafe implementation of `attachWith`, taking advantage of the fact that the rep
|
||||
with the same elements but in the type `{x // x ∈ xs}`. -/
|
||||
@[inline] def attach (xs : Array α) : Array {x // x ∈ xs} := xs.attachWith _ fun _ => id
|
||||
|
||||
@[simp] theorem _root_.List.attachWith_toArray {l : List α} {P : α → Prop} {H : ∀ x ∈ l.toArray, P x} :
|
||||
l.toArray.attachWith P H = (l.attachWith P (by simpa using H)).toArray := by
|
||||
simp [attachWith]
|
||||
|
||||
@[simp] theorem _root_.List.attach_toArray {l : List α} :
|
||||
l.toArray.attach = (l.attachWith (· ∈ l.toArray) (by simp)).toArray := by
|
||||
simp [attach]
|
||||
|
||||
@[simp] theorem toList_attachWith {l : Array α} {P : α → Prop} {H : ∀ x ∈ l, P x} :
|
||||
(l.attachWith P H).toList = l.toList.attachWith P (by simpa [mem_toList] using H) := by
|
||||
simp [attachWith]
|
||||
|
||||
@[simp] theorem toList_attach {α : Type _} {l : Array α} :
|
||||
l.attach.toList = l.toList.attachWith (· ∈ l) (by simp [mem_toList]) := by
|
||||
simp [attach]
|
||||
|
||||
/-! ## unattach
|
||||
|
||||
`Array.unattach` is the (one-sided) inverse of `Array.attach`. It is a synonym for `Array.map Subtype.val`.
|
||||
|
||||
We use it by providing a simp lemma `l.attach.unattach = l`, and simp lemmas which recognize higher order
|
||||
functions applied to `l : Array { x // p x }` which only depend on the value, not the predicate, and rewrite these
|
||||
in terms of a simpler function applied to `l.unattach`.
|
||||
|
||||
Further, we provide simp lemmas that push `unattach` inwards.
|
||||
-/
|
||||
|
||||
/--
|
||||
A synonym for `l.map (·.val)`. Mostly this should not be needed by users.
|
||||
It is introduced as in intermediate step by lemmas such as `map_subtype`,
|
||||
and is ideally subsequently simplified away by `unattach_attach`.
|
||||
|
||||
If not, usually the right approach is `simp [Array.unattach, -Array.map_subtype]` to unfold.
|
||||
-/
|
||||
def unattach {α : Type _} {p : α → Prop} (l : Array { x // p x }) := l.map (·.val)
|
||||
|
||||
@[simp] theorem unattach_nil {α : Type _} {p : α → Prop} : (#[] : Array { x // p x }).unattach = #[] := rfl
|
||||
@[simp] theorem unattach_push {α : Type _} {p : α → Prop} {a : { x // p x }} {l : Array { x // p x }} :
|
||||
(l.push a).unattach = l.unattach.push a.1 := by
|
||||
simp [unattach]
|
||||
|
||||
@[simp] theorem size_unattach {α : Type _} {p : α → Prop} {l : Array { x // p x }} :
|
||||
l.unattach.size = l.size := by
|
||||
unfold unattach
|
||||
simp
|
||||
|
||||
@[simp] theorem _root_.List.unattach_toArray {α : Type _} {p : α → Prop} {l : List { x // p x }} :
|
||||
l.toArray.unattach = l.unattach.toArray := by
|
||||
simp [unattach, List.unattach]
|
||||
|
||||
@[simp] theorem toList_unattach {α : Type _} {p : α → Prop} {l : Array { x // p x }} :
|
||||
l.unattach.toList = l.toList.unattach := by
|
||||
simp [unattach, List.unattach]
|
||||
|
||||
@[simp] theorem unattach_attach {α : Type _} (l : Array α) : l.attach.unattach = l := by
|
||||
cases l
|
||||
simp
|
||||
|
||||
@[simp] theorem unattach_attachWith {α : Type _} {p : α → Prop} {l : Array α}
|
||||
{H : ∀ a ∈ l, p a} :
|
||||
(l.attachWith p H).unattach = l := by
|
||||
cases l
|
||||
simp
|
||||
|
||||
/-! ### Recognizing higher order functions using a function that only depends on the value. -/
|
||||
|
||||
/--
|
||||
This lemma identifies folds over arrays of subtypes, where the function only depends on the value, not the proposition,
|
||||
and simplifies these to the function directly taking the value.
|
||||
-/
|
||||
theorem foldl_subtype {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : β → { x // p x } → β} {g : β → α → β} {x : β}
|
||||
{hf : ∀ b x h, f b ⟨x, h⟩ = g b x} :
|
||||
l.foldl f x = l.unattach.foldl g x := by
|
||||
cases l
|
||||
simp only [List.foldl_toArray', List.unattach_toArray]
|
||||
rw [List.foldl_subtype] -- Why can't simp do this?
|
||||
simp [hf]
|
||||
|
||||
/-- Variant of `foldl_subtype` with side condition to check `stop = l.size`. -/
|
||||
@[simp] theorem foldl_subtype' {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : β → { x // p x } → β} {g : β → α → β} {x : β}
|
||||
{hf : ∀ b x h, f b ⟨x, h⟩ = g b x} (h : stop = l.size) :
|
||||
l.foldl f x 0 stop = l.unattach.foldl g x := by
|
||||
subst h
|
||||
rwa [foldl_subtype]
|
||||
|
||||
/--
|
||||
This lemma identifies folds over arrays of subtypes, where the function only depends on the value, not the proposition,
|
||||
and simplifies these to the function directly taking the value.
|
||||
-/
|
||||
theorem foldr_subtype {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : { x // p x } → β → β} {g : α → β → β} {x : β}
|
||||
{hf : ∀ x h b, f ⟨x, h⟩ b = g x b} :
|
||||
l.foldr f x = l.unattach.foldr g x := by
|
||||
cases l
|
||||
simp only [List.foldr_toArray', List.unattach_toArray]
|
||||
rw [List.foldr_subtype]
|
||||
simp [hf]
|
||||
|
||||
/-- Variant of `foldr_subtype` with side condition to check `stop = l.size`. -/
|
||||
@[simp] theorem foldr_subtype' {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : { x // p x } → β → β} {g : α → β → β} {x : β}
|
||||
{hf : ∀ x h b, f ⟨x, h⟩ b = g x b} (h : start = l.size) :
|
||||
l.foldr f x start 0 = l.unattach.foldr g x := by
|
||||
subst h
|
||||
rwa [foldr_subtype]
|
||||
|
||||
/--
|
||||
This lemma identifies maps over arrays of subtypes, where the function only depends on the value, not the proposition,
|
||||
and simplifies these to the function directly taking the value.
|
||||
-/
|
||||
@[simp] theorem map_subtype {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : { x // p x } → β} {g : α → β} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
l.map f = l.unattach.map g := by
|
||||
cases l
|
||||
simp only [List.map_toArray, List.unattach_toArray]
|
||||
rw [List.map_subtype]
|
||||
simp [hf]
|
||||
|
||||
@[simp] theorem filterMap_subtype {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : { x // p x } → Option β} {g : α → Option β} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
l.filterMap f = l.unattach.filterMap g := by
|
||||
cases l
|
||||
simp only [size_toArray, List.filterMap_toArray', List.unattach_toArray, List.length_unattach,
|
||||
mk.injEq]
|
||||
rw [List.filterMap_subtype]
|
||||
simp [hf]
|
||||
|
||||
@[simp] theorem unattach_filter {p : α → Prop} {l : Array { x // p x }}
|
||||
{f : { x // p x } → Bool} {g : α → Bool} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
(l.filter f).unattach = l.unattach.filter g := by
|
||||
cases l
|
||||
simp [hf]
|
||||
rw [List.unattach_filter]
|
||||
simp [hf]
|
||||
|
||||
/-! ### Simp lemmas pushing `unattach` inwards. -/
|
||||
|
||||
@[simp] theorem unattach_reverse {p : α → Prop} {l : Array { x // p x }} :
|
||||
l.reverse.unattach = l.unattach.reverse := by
|
||||
cases l
|
||||
simp
|
||||
|
||||
@[simp] theorem unattach_append {p : α → Prop} {l₁ l₂ : Array { x // p x }} :
|
||||
(l₁ ++ l₂).unattach = l₁.unattach ++ l₂.unattach := by
|
||||
cases l₁
|
||||
cases l₂
|
||||
simp
|
||||
|
||||
end Array
|
||||
|
||||
@@ -617,7 +617,7 @@ def concatMap (f : α → Array β) (as : Array α) : Array β :=
|
||||
|
||||
`flatten #[#[a₁, a₂, ⋯], #[b₁, b₂, ⋯], ⋯]` = `#[a₁, a₂, ⋯, b₁, b₂, ⋯]`
|
||||
-/
|
||||
@[inline] def flatten (as : Array (Array α)) : Array α :=
|
||||
def flatten (as : Array (Array α)) : Array α :=
|
||||
as.foldl (init := empty) fun r a => r ++ a
|
||||
|
||||
@[inline]
|
||||
@@ -720,7 +720,7 @@ termination_by a.size - i.val
|
||||
decreasing_by simp_wf; exact Nat.sub_succ_lt_self _ _ i.isLt
|
||||
|
||||
-- This is required in `Lean.Data.PersistentHashMap`.
|
||||
@[simp] theorem size_feraseIdx (a : Array α) (i : Fin a.size) : (a.feraseIdx i).size = a.size - 1 := by
|
||||
theorem size_feraseIdx (a : Array α) (i : Fin a.size) : (a.feraseIdx i).size = a.size - 1 := by
|
||||
induction a, i using Array.feraseIdx.induct with
|
||||
| @case1 a i h a' _ ih =>
|
||||
unfold feraseIdx
|
||||
@@ -810,27 +810,11 @@ def split (as : Array α) (p : α → Bool) : Array α × Array α :=
|
||||
as.foldl (init := (#[], #[])) fun (as, bs) a =>
|
||||
if p a then (as.push a, bs) else (as, bs.push a)
|
||||
|
||||
/-! ## Auxiliary functions used in metaprogramming.
|
||||
/-! ### Auxiliary functions used in metaprogramming.
|
||||
|
||||
We do not intend to provide verification theorems for these functions.
|
||||
-/
|
||||
|
||||
/-! ### eraseReps -/
|
||||
|
||||
/--
|
||||
`O(|l|)`. Erase repeated adjacent elements. Keeps the first occurrence of each run.
|
||||
* `eraseReps #[1, 3, 2, 2, 2, 3, 5] = #[1, 3, 2, 3, 5]`
|
||||
-/
|
||||
def eraseReps {α} [BEq α] (as : Array α) : Array α :=
|
||||
if h : 0 < as.size then
|
||||
let ⟨last, r⟩ := as.foldl (init := (as[0], #[])) fun ⟨last, r⟩ a =>
|
||||
if a == last then ⟨last, r⟩ else ⟨a, r.push last⟩
|
||||
r.push last
|
||||
else
|
||||
#[]
|
||||
|
||||
/-! ### allDiff -/
|
||||
|
||||
private def allDiffAuxAux [BEq α] (as : Array α) (a : α) : forall (i : Nat), i < as.size → Bool
|
||||
| 0, _ => true
|
||||
| i+1, h =>
|
||||
@@ -848,8 +832,6 @@ decreasing_by simp_wf; decreasing_trivial_pre_omega
|
||||
def allDiff [BEq α] (as : Array α) : Bool :=
|
||||
allDiffAux as 0
|
||||
|
||||
/-! ### getEvenElems -/
|
||||
|
||||
@[inline] def getEvenElems (as : Array α) : Array α :=
|
||||
(·.2) <| as.foldl (init := (true, Array.empty)) fun (even, r) a =>
|
||||
if even then
|
||||
|
||||
@@ -73,7 +73,7 @@ theorem foldr_eq_foldr_toList (f : α → β → β) (init : β) (arr : Array α
|
||||
|
||||
@[simp] theorem append_eq_append (arr arr' : Array α) : arr.append arr' = arr ++ arr' := rfl
|
||||
|
||||
@[simp] theorem toList_append (arr arr' : Array α) :
|
||||
@[simp] theorem append_toList (arr arr' : Array α) :
|
||||
(arr ++ arr').toList = arr.toList ++ arr'.toList := by
|
||||
rw [← append_eq_append]; unfold Array.append
|
||||
rw [foldl_eq_foldl_toList]
|
||||
@@ -111,8 +111,8 @@ abbrev toList_eq := @toListImpl_eq
|
||||
@[deprecated pop_toList (since := "2024-09-09")]
|
||||
abbrev pop_data := @pop_toList
|
||||
|
||||
@[deprecated toList_append (since := "2024-09-09")]
|
||||
abbrev append_data := @toList_append
|
||||
@[deprecated append_toList (since := "2024-09-09")]
|
||||
abbrev append_data := @append_toList
|
||||
|
||||
@[deprecated appendList_toList (since := "2024-09-09")]
|
||||
abbrev appendList_data := @appendList_toList
|
||||
|
||||
@@ -91,74 +91,28 @@ abbrev toArray_data := @toArray_toList
|
||||
@[simp] theorem getElem_toArray {a : List α} {i : Nat} (h : i < a.toArray.size) :
|
||||
a.toArray[i] = a[i]'(by simpa using h) := rfl
|
||||
|
||||
@[simp] theorem getElem?_toArray {a : List α} {i : Nat} : a.toArray[i]? = a[i]? := rfl
|
||||
|
||||
@[deprecated "Use the reverse direction of `List.push_toArray`." (since := "2024-09-27")]
|
||||
theorem toArray_concat {as : List α} {x : α} :
|
||||
@[simp] theorem toArray_concat {as : List α} {x : α} :
|
||||
(as ++ [x]).toArray = as.toArray.push x := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem push_toArray (l : List α) (a : α) : l.toArray.push a = (l ++ [a]).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
/-- Unapplied variant of `push_toArray`, useful for monadic reasoning. -/
|
||||
@[simp] theorem push_toArray_fun (l : List α) : l.toArray.push = fun a => (l ++ [a]).toArray := by
|
||||
funext a
|
||||
simp
|
||||
|
||||
theorem foldrM_toArray [Monad m] (f : α → β → m β) (init : β) (l : List α) :
|
||||
@[simp] theorem foldrM_toArray [Monad m] (f : α → β → m β) (init : β) (l : List α) :
|
||||
l.toArray.foldrM f init = l.foldrM f init := by
|
||||
rw [foldrM_eq_reverse_foldlM_toList]
|
||||
simp
|
||||
|
||||
theorem foldlM_toArray [Monad m] (f : β → α → m β) (init : β) (l : List α) :
|
||||
@[simp] theorem foldlM_toArray [Monad m] (f : β → α → m β) (init : β) (l : List α) :
|
||||
l.toArray.foldlM f init = l.foldlM f init := by
|
||||
rw [foldlM_eq_foldlM_toList]
|
||||
|
||||
theorem foldr_toArray (f : α → β → β) (init : β) (l : List α) :
|
||||
@[simp] theorem foldr_toArray (f : α → β → β) (init : β) (l : List α) :
|
||||
l.toArray.foldr f init = l.foldr f init := by
|
||||
rw [foldr_eq_foldr_toList]
|
||||
|
||||
theorem foldl_toArray (f : β → α → β) (init : β) (l : List α) :
|
||||
@[simp] theorem foldl_toArray (f : β → α → β) (init : β) (l : List α) :
|
||||
l.toArray.foldl f init = l.foldl f init := by
|
||||
rw [foldl_eq_foldl_toList]
|
||||
|
||||
/-- Variant of `foldrM_toArray` with a side condition for the `start` argument. -/
|
||||
@[simp] theorem foldrM_toArray' [Monad m] (f : α → β → m β) (init : β) (l : List α)
|
||||
(h : start = l.toArray.size) :
|
||||
l.toArray.foldrM f init start 0 = l.foldrM f init := by
|
||||
subst h
|
||||
rw [foldrM_eq_reverse_foldlM_toList]
|
||||
simp
|
||||
|
||||
/-- Variant of `foldlM_toArray` with a side condition for the `stop` argument. -/
|
||||
@[simp] theorem foldlM_toArray' [Monad m] (f : β → α → m β) (init : β) (l : List α)
|
||||
(h : stop = l.toArray.size) :
|
||||
l.toArray.foldlM f init 0 stop = l.foldlM f init := by
|
||||
subst h
|
||||
rw [foldlM_eq_foldlM_toList]
|
||||
|
||||
/-- Variant of `foldr_toArray` with a side condition for the `start` argument. -/
|
||||
@[simp] theorem foldr_toArray' (f : α → β → β) (init : β) (l : List α)
|
||||
(h : start = l.toArray.size) :
|
||||
l.toArray.foldr f init start 0 = l.foldr f init := by
|
||||
subst h
|
||||
rw [foldr_eq_foldr_toList]
|
||||
|
||||
/-- Variant of `foldl_toArray` with a side condition for the `stop` argument. -/
|
||||
@[simp] theorem foldl_toArray' (f : β → α → β) (init : β) (l : List α)
|
||||
(h : stop = l.toArray.size) :
|
||||
l.toArray.foldl f init 0 stop = l.foldl f init := by
|
||||
subst h
|
||||
rw [foldl_eq_foldl_toList]
|
||||
|
||||
@[simp] theorem append_toArray (l₁ l₂ : List α) :
|
||||
l₁.toArray ++ l₂.toArray = (l₁ ++ l₂).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
end List
|
||||
|
||||
namespace Array
|
||||
@@ -172,10 +126,10 @@ attribute [simp] uset
|
||||
@[deprecated toArray_toList (since := "2024-09-09")]
|
||||
abbrev toArray_data := @toArray_toList
|
||||
|
||||
@[simp] theorem length_toList {l : Array α} : l.toList.length = l.size := rfl
|
||||
@[simp] theorem toList_length {l : Array α} : l.toList.length = l.size := rfl
|
||||
|
||||
@[deprecated length_toList (since := "2024-09-09")]
|
||||
abbrev data_length := @length_toList
|
||||
@[deprecated toList_length (since := "2024-09-09")]
|
||||
abbrev data_length := @toList_length
|
||||
|
||||
@[simp] theorem mkEmpty_eq (α n) : @mkEmpty α n = #[] := rfl
|
||||
|
||||
@@ -211,25 +165,25 @@ where
|
||||
mapM.map f arr i r = (arr.toList.drop i).foldlM (fun bs a => bs.push <$> f a) r := by
|
||||
unfold mapM.map; split
|
||||
· rw [← List.get_drop_eq_drop _ i ‹_›]
|
||||
simp only [aux (i + 1), map_eq_pure_bind, length_toList, List.foldlM_cons, bind_assoc,
|
||||
simp only [aux (i + 1), map_eq_pure_bind, toList_length, List.foldlM_cons, bind_assoc,
|
||||
pure_bind]
|
||||
rfl
|
||||
· rw [List.drop_of_length_le (Nat.ge_of_not_lt ‹_›)]; rfl
|
||||
termination_by arr.size - i
|
||||
decreasing_by decreasing_trivial_pre_omega
|
||||
|
||||
@[simp] theorem toList_map (f : α → β) (arr : Array α) : (arr.map f).toList = arr.toList.map f := by
|
||||
@[simp] theorem map_toList (f : α → β) (arr : Array α) : (arr.map f).toList = arr.toList.map f := by
|
||||
rw [map, mapM_eq_foldlM]
|
||||
apply congrArg toList (foldl_eq_foldl_toList (fun bs a => push bs (f a)) #[] arr) |>.trans
|
||||
have H (l arr) : List.foldl (fun bs a => push bs (f a)) arr l = ⟨arr.toList ++ l.map f⟩ := by
|
||||
induction l generalizing arr <;> simp [*]
|
||||
simp [H]
|
||||
|
||||
@[deprecated toList_map (since := "2024-09-09")]
|
||||
abbrev map_data := @toList_map
|
||||
@[deprecated map_toList (since := "2024-09-09")]
|
||||
abbrev map_data := @map_toList
|
||||
|
||||
@[simp] theorem size_map (f : α → β) (arr : Array α) : (arr.map f).size = arr.size := by
|
||||
simp only [← length_toList]
|
||||
simp only [← toList_length]
|
||||
simp
|
||||
|
||||
@[simp] theorem appendList_nil (arr : Array α) : arr ++ ([] : List α) = arr := Array.ext' (by simp)
|
||||
@@ -237,11 +191,6 @@ abbrev map_data := @toList_map
|
||||
@[simp] theorem appendList_cons (arr : Array α) (a : α) (l : List α) :
|
||||
arr ++ (a :: l) = arr.push a ++ l := Array.ext' (by simp)
|
||||
|
||||
@[simp] theorem toList_appendList (arr : Array α) (l : List α) :
|
||||
(arr ++ l).toList = arr.toList ++ l := by
|
||||
cases arr
|
||||
simp
|
||||
|
||||
theorem foldl_toList_eq_bind (l : List α) (acc : Array β)
|
||||
(F : Array β → α → Array β) (G : α → List β)
|
||||
(H : ∀ acc a, (F acc a).toList = acc.toList ++ G a) :
|
||||
@@ -333,14 +282,14 @@ theorem getElem_set (a : Array α) (i : Fin a.size) (v : α) (j : Nat)
|
||||
@[simp] theorem set!_is_setD : @set! = @setD := rfl
|
||||
|
||||
@[simp] theorem size_setD (a : Array α) (index : Nat) (val : α) :
|
||||
(Array.setD a index val).size = a.size := by
|
||||
(Array.setD a index val).size = a.size := by
|
||||
if h : index < a.size then
|
||||
simp [setD, h]
|
||||
else
|
||||
simp [setD, h]
|
||||
|
||||
@[simp] theorem getElem_setD_eq (a : Array α) {i : Nat} (v : α) (h : _) :
|
||||
(setD a i v)[i]'h = v := by
|
||||
(setD a i v)[i]'h = v := by
|
||||
simp at h
|
||||
simp only [setD, h, dite_true, getElem_set, ite_true]
|
||||
|
||||
@@ -350,7 +299,7 @@ theorem getElem?_setD_eq (a : Array α) {i : Nat} (p : i < a.size) (v : α) : (a
|
||||
|
||||
/-- Simplifies a normal form from `get!` -/
|
||||
@[simp] theorem getD_get?_setD (a : Array α) (i : Nat) (v d : α) :
|
||||
Option.getD (setD a i v)[i]? d = if i < a.size then v else d := by
|
||||
Option.getD (setD a i v)[i]? d = if i < a.size then v else d := by
|
||||
by_cases h : i < a.size <;>
|
||||
simp [setD, Nat.not_lt_of_le, h, getD_get?]
|
||||
|
||||
@@ -465,18 +414,12 @@ theorem getElem_mem_toList (a : Array α) (h : i < a.size) : a[i] ∈ a.toList :
|
||||
@[deprecated getElem_mem_toList (since := "2024-09-09")]
|
||||
abbrev getElem_mem_data := @getElem_mem_toList
|
||||
|
||||
theorem getElem?_eq_toList_getElem? (a : Array α) (i : Nat) : a[i]? = a.toList[i]? := by
|
||||
by_cases i < a.size <;> simp_all [getElem?_pos, getElem?_neg]
|
||||
|
||||
@[deprecated getElem?_eq_toList_getElem? (since := "2024-09-30")]
|
||||
theorem getElem?_eq_toList_get? (a : Array α) (i : Nat) : a[i]? = a.toList.get? i := by
|
||||
by_cases i < a.size <;> simp_all [getElem?_pos, getElem?_neg, List.get?_eq_get, eq_comm]
|
||||
|
||||
set_option linter.deprecated false in
|
||||
@[deprecated getElem?_eq_toList_getElem? (since := "2024-09-09")]
|
||||
@[deprecated getElem?_eq_toList_get? (since := "2024-09-09")]
|
||||
abbrev getElem?_eq_data_get? := @getElem?_eq_toList_get?
|
||||
|
||||
set_option linter.deprecated false in
|
||||
theorem get?_eq_toList_get? (a : Array α) (i : Nat) : a.get? i = a.toList.get? i :=
|
||||
getElem?_eq_toList_get? ..
|
||||
|
||||
@@ -486,15 +429,11 @@ abbrev get?_eq_data_get? := @get?_eq_toList_get?
|
||||
theorem get!_eq_get? [Inhabited α] (a : Array α) : a.get! n = (a.get? n).getD default := by
|
||||
simp [get!_eq_getD]
|
||||
|
||||
theorem getElem?_eq_some_iff {as : Array α} : as[n]? = some a ↔ ∃ h : n < as.size, as[n] = a := by
|
||||
cases as
|
||||
simp [List.getElem?_eq_some_iff]
|
||||
|
||||
@[simp] theorem back_eq_back? [Inhabited α] (a : Array α) : a.back = a.back?.getD default := by
|
||||
simp [back, back?]
|
||||
|
||||
@[simp] theorem back?_push (a : Array α) : (a.push x).back? = some x := by
|
||||
simp [back?, getElem?_eq_toList_getElem?]
|
||||
simp [back?, getElem?_eq_toList_get?]
|
||||
|
||||
theorem back_push [Inhabited α] (a : Array α) : (a.push x).back = x := by simp
|
||||
|
||||
@@ -552,7 +491,7 @@ theorem get_set (a : Array α) (i : Fin a.size) (j : Nat) (hj : j < a.size) (v :
|
||||
simp only [set, getElem_eq_getElem_toList, List.getElem_set_ne h]
|
||||
|
||||
theorem getElem_setD (a : Array α) (i : Nat) (v : α) (h : i < (setD a i v).size) :
|
||||
(setD a i v)[i] = v := by
|
||||
(setD a i v)[i] = v := by
|
||||
simp at h
|
||||
simp only [setD, h, dite_true, get_set, ite_true]
|
||||
|
||||
@@ -565,7 +504,7 @@ theorem swap_def (a : Array α) (i j : Fin a.size) :
|
||||
a.swap i j = (a.set i (a.get j)).set ⟨j.1, by simp [j.2]⟩ (a.get i) := by
|
||||
simp [swap, fin_cast_val]
|
||||
|
||||
@[simp] theorem toList_swap (a : Array α) (i j : Fin a.size) :
|
||||
theorem toList_swap (a : Array α) (i j : Fin a.size) :
|
||||
(a.swap i j).toList = (a.toList.set i (a.get j)).set j (a.get i) := by simp [swap_def]
|
||||
|
||||
@[deprecated toList_swap (since := "2024-09-09")]
|
||||
@@ -654,11 +593,11 @@ theorem getElem_range {n : Nat} {x : Nat} (h : x < (Array.range n).size) : (Arra
|
||||
simp [getElem_eq_getElem_toList]
|
||||
|
||||
set_option linter.deprecated false in
|
||||
@[simp] theorem toList_reverse (a : Array α) : a.reverse.toList = a.toList.reverse := by
|
||||
@[simp] theorem reverse_toList (a : Array α) : a.reverse.toList = a.toList.reverse := by
|
||||
let rec go (as : Array α) (i j hj)
|
||||
(h : i + j + 1 = a.size) (h₂ : as.size = a.size)
|
||||
(H : ∀ k, as.toList[k]? = if i ≤ k ∧ k ≤ j then a.toList[k]? else a.toList.reverse[k]?)
|
||||
(k : Nat) : (reverse.loop as i ⟨j, hj⟩).toList[k]? = a.toList.reverse[k]? := by
|
||||
(H : ∀ k, as.toList.get? k = if i ≤ k ∧ k ≤ j then a.toList.get? k else a.toList.reverse.get? k)
|
||||
(k) : (reverse.loop as i ⟨j, hj⟩).toList.get? k = a.toList.reverse.get? k := by
|
||||
rw [reverse.loop]; dsimp; split <;> rename_i h₁
|
||||
· match j with | j+1 => ?_
|
||||
simp only [Nat.add_sub_cancel]
|
||||
@@ -666,37 +605,34 @@ set_option linter.deprecated false in
|
||||
· rwa [Nat.add_right_comm i]
|
||||
· simp [size_swap, h₂]
|
||||
· intro k
|
||||
rw [← getElem?_eq_toList_getElem?, get?_swap]
|
||||
simp only [H, getElem_eq_getElem_toList, ← List.getElem?_eq_getElem, Nat.le_of_lt h₁,
|
||||
getElem?_eq_toList_getElem?]
|
||||
rw [← getElem?_eq_toList_get?, get?_swap]
|
||||
simp only [H, getElem_eq_toList_get, ← List.get?_eq_get, Nat.le_of_lt h₁,
|
||||
getElem?_eq_toList_get?]
|
||||
split <;> rename_i h₂
|
||||
· simp only [← h₂, Nat.not_le.2 (Nat.lt_succ_self _), Nat.le_refl, and_false]
|
||||
exact (List.getElem?_reverse' (j+1) i (Eq.trans (by simp_arith) h)).symm
|
||||
exact (List.get?_reverse' (j+1) i (Eq.trans (by simp_arith) h)).symm
|
||||
split <;> rename_i h₃
|
||||
· simp only [← h₃, Nat.not_le.2 (Nat.lt_succ_self _), Nat.le_refl, false_and]
|
||||
exact (List.getElem?_reverse' i (j+1) (Eq.trans (by simp_arith) h)).symm
|
||||
exact (List.get?_reverse' i (j+1) (Eq.trans (by simp_arith) h)).symm
|
||||
simp only [Nat.succ_le, Nat.lt_iff_le_and_ne.trans (and_iff_left h₃),
|
||||
Nat.lt_succ.symm.trans (Nat.lt_iff_le_and_ne.trans (and_iff_left (Ne.symm h₂)))]
|
||||
· rw [H]; split <;> rename_i h₂
|
||||
· cases Nat.le_antisymm (Nat.not_lt.1 h₁) (Nat.le_trans h₂.1 h₂.2)
|
||||
cases Nat.le_antisymm h₂.1 h₂.2
|
||||
exact (List.getElem?_reverse' _ _ h).symm
|
||||
exact (List.get?_reverse' _ _ h).symm
|
||||
· rfl
|
||||
termination_by j - i
|
||||
simp only [reverse]
|
||||
split
|
||||
· match a with | ⟨[]⟩ | ⟨[_]⟩ => rfl
|
||||
· have := Nat.sub_add_cancel (Nat.le_of_not_le ‹_›)
|
||||
refine List.ext_getElem? <| go _ _ _ _ (by simp [this]) rfl fun k => ?_
|
||||
refine List.ext_get? <| go _ _ _ _ (by simp [this]) rfl fun k => ?_
|
||||
split
|
||||
· rfl
|
||||
· rename_i h
|
||||
simp only [← show k < _ + 1 ↔ _ from Nat.lt_succ (n := a.size - 1), this, Nat.zero_le,
|
||||
true_and, Nat.not_lt] at h
|
||||
rw [List.getElem?_eq_none_iff.2 ‹_›, List.getElem?_eq_none_iff.2 (a.toList.length_reverse ▸ ‹_›)]
|
||||
|
||||
@[deprecated toList_reverse (since := "2024-09-30")]
|
||||
abbrev reverse_toList := @toList_reverse
|
||||
rw [List.get?_eq_none.2 ‹_›, List.get?_eq_none.2 (a.toList.length_reverse ▸ ‹_›)]
|
||||
|
||||
/-! ### foldl / foldr -/
|
||||
|
||||
@@ -759,35 +695,19 @@ theorem foldr_induction
|
||||
simp [foldr, foldrM]; split; {exact go _ h0}
|
||||
· next h => exact (Nat.eq_zero_of_not_pos h ▸ h0)
|
||||
|
||||
@[congr]
|
||||
theorem foldl_congr {as bs : Array α} (h₀ : as = bs) {f g : β → α → β} (h₁ : f = g)
|
||||
{a b : β} (h₂ : a = b) {start start' stop stop' : Nat} (h₃ : start = start') (h₄ : stop = stop') :
|
||||
as.foldl f a start stop = bs.foldl g b start' stop' := by
|
||||
congr
|
||||
|
||||
@[congr]
|
||||
theorem foldr_congr {as bs : Array α} (h₀ : as = bs) {f g : α → β → β} (h₁ : f = g)
|
||||
{a b : β} (h₂ : a = b) {start start' stop stop' : Nat} (h₃ : start = start') (h₄ : stop = stop') :
|
||||
as.foldr f a start stop = bs.foldr g b start' stop' := by
|
||||
congr
|
||||
|
||||
/-! ### map -/
|
||||
|
||||
@[simp] theorem mem_map {f : α → β} {l : Array α} : b ∈ l.map f ↔ ∃ a, a ∈ l ∧ f a = b := by
|
||||
simp only [mem_def, toList_map, List.mem_map]
|
||||
simp only [mem_def, map_toList, List.mem_map]
|
||||
|
||||
theorem mapM_eq_mapM_toList [Monad m] [LawfulMonad m] (f : α → m β) (arr : Array α) :
|
||||
arr.mapM f = List.toArray <$> (arr.toList.mapM f) := by
|
||||
arr.mapM f = return mk (← arr.toList.mapM f) := by
|
||||
rw [mapM_eq_foldlM, foldlM_eq_foldlM_toList, ← List.foldrM_reverse]
|
||||
conv => rhs; rw [← List.reverse_reverse arr.toList]
|
||||
induction arr.toList.reverse with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih]
|
||||
|
||||
@[simp] theorem toList_mapM [Monad m] [LawfulMonad m] (f : α → m β) (arr : Array α) :
|
||||
toList <$> arr.mapM f = arr.toList.mapM f := by
|
||||
simp [mapM_eq_mapM_toList]
|
||||
|
||||
@[deprecated mapM_eq_mapM_toList (since := "2024-09-09")]
|
||||
abbrev mapM_eq_mapM_data := @mapM_eq_mapM_toList
|
||||
|
||||
@@ -844,27 +764,16 @@ theorem map_spec (as : Array α) (f : α → β) (p : Fin as.size → β → Pro
|
||||
simpa using map_induction as f (fun _ => True) trivial p (by simp_all)
|
||||
|
||||
@[simp] theorem getElem_map (f : α → β) (as : Array α) (i : Nat) (h) :
|
||||
(as.map f)[i] = f (as[i]'(size_map .. ▸ h)) := by
|
||||
((as.map f)[i]) = f (as[i]'(size_map .. ▸ h)) := by
|
||||
have := map_spec as f (fun i b => b = f (as[i]))
|
||||
simp only [implies_true, true_implies] at this
|
||||
obtain ⟨eq, w⟩ := this
|
||||
apply w
|
||||
simp_all
|
||||
|
||||
@[simp] theorem getElem?_map (f : α → β) (as : Array α) (i : Nat) :
|
||||
(as.map f)[i]? = as[i]?.map f := by
|
||||
simp [getElem?_def]
|
||||
|
||||
@[simp] theorem map_push {f : α → β} {as : Array α} {x : α} :
|
||||
(as.push x).map f = (as.map f).push (f x) := by
|
||||
ext
|
||||
· simp
|
||||
· simp only [getElem_map, get_push, size_map]
|
||||
split <;> rfl
|
||||
|
||||
/-! ### mapIdx -/
|
||||
|
||||
-- This could also be proved from `SatisfiesM_mapIdxM` in Batteries.
|
||||
-- This could also be prove from `SatisfiesM_mapIdxM`.
|
||||
theorem mapIdx_induction (as : Array α) (f : Fin as.size → α → β)
|
||||
(motive : Nat → Prop) (h0 : motive 0)
|
||||
(p : Fin as.size → β → Prop)
|
||||
@@ -904,46 +813,41 @@ theorem mapIdx_spec (as : Array α) (f : Fin as.size → α → β)
|
||||
|
||||
@[simp] theorem getElem_mapIdx (a : Array α) (f : Fin a.size → α → β) (i : Nat)
|
||||
(h : i < (mapIdx a f).size) :
|
||||
(a.mapIdx f)[i] = f ⟨i, by simp_all⟩ (a[i]'(by simp_all)) :=
|
||||
haveI : i < a.size := by simp_all
|
||||
(a.mapIdx f)[i] = f ⟨i, this⟩ a[i] :=
|
||||
(mapIdx_spec _ _ (fun i b => b = f i a[i]) fun _ => rfl).2 i _
|
||||
|
||||
@[simp] theorem getElem?_mapIdx (a : Array α) (f : Fin a.size → α → β) (i : Nat) :
|
||||
(a.mapIdx f)[i]? =
|
||||
a[i]?.pbind fun b h => f ⟨i, (getElem?_eq_some_iff.1 h).1⟩ b := by
|
||||
simp only [getElem?_def, size_mapIdx, getElem_mapIdx]
|
||||
split <;> simp_all
|
||||
|
||||
/-! ### modify -/
|
||||
|
||||
@[simp] theorem size_modify (a : Array α) (i : Nat) (f : α → α) : (a.modify i f).size = a.size := by
|
||||
unfold modify modifyM Id.run
|
||||
split <;> simp
|
||||
|
||||
theorem getElem_modify {as : Array α} {x i} (h : i < (as.modify x f).size) :
|
||||
(as.modify x f)[i] = if x = i then f (as[i]'(by simpa using h)) else as[i]'(by simpa using h) := by
|
||||
theorem getElem_modify {as : Array α} {x i} (h : i < as.size) :
|
||||
(as.modify x f)[i]'(by simp [h]) = if x = i then f as[i] else as[i] := by
|
||||
simp only [modify, modifyM, get_eq_getElem, Id.run, Id.pure_eq]
|
||||
split
|
||||
· simp only [Id.bind_eq, get_set _ _ _ (by simpa using h)]; split <;> simp [*]
|
||||
· rw [if_neg (mt (by rintro rfl; exact h) (by simp_all))]
|
||||
· simp only [Id.bind_eq, get_set _ _ _ h]; split <;> simp [*]
|
||||
· rw [if_neg (mt (by rintro rfl; exact h) ‹_›)]
|
||||
|
||||
theorem getElem_modify_self {as : Array α} {i : Nat} (f : α → α) (h : i < (as.modify i f).size) :
|
||||
(as.modify i f)[i] = f (as[i]'(by simpa using h)) := by
|
||||
theorem getElem_modify_self {as : Array α} {i : Nat} (h : i < as.size) (f : α → α) :
|
||||
(as.modify i f)[i]'(by simp [h]) = f as[i] := by
|
||||
simp [getElem_modify h]
|
||||
|
||||
theorem getElem_modify_of_ne {as : Array α} {i : Nat} (h : i ≠ j)
|
||||
(f : α → α) (hj : j < (as.modify i f).size) :
|
||||
(as.modify i f)[j] = as[j]'(by simpa using hj) := by
|
||||
theorem getElem_modify_of_ne {as : Array α} {i : Nat} (hj : j < as.size)
|
||||
(f : α → α) (h : i ≠ j) :
|
||||
(as.modify i f)[j]'(by rwa [size_modify]) = as[j] := by
|
||||
simp [getElem_modify hj, h]
|
||||
|
||||
@[deprecated getElem_modify (since := "2024-08-08")]
|
||||
theorem get_modify {arr : Array α} {x i} (h : i < (arr.modify x f).size) :
|
||||
(arr.modify x f).get ⟨i, h⟩ =
|
||||
if x = i then f (arr.get ⟨i, by simpa using h⟩) else arr.get ⟨i, by simpa using h⟩ := by
|
||||
theorem get_modify {arr : Array α} {x i} (h : i < arr.size) :
|
||||
(arr.modify x f).get ⟨i, by simp [h]⟩ =
|
||||
if x = i then f (arr.get ⟨i, h⟩) else arr.get ⟨i, h⟩ := by
|
||||
simp [getElem_modify h]
|
||||
|
||||
/-! ### filter -/
|
||||
|
||||
@[simp] theorem toList_filter (p : α → Bool) (l : Array α) :
|
||||
@[simp] theorem filter_toList (p : α → Bool) (l : Array α) :
|
||||
(l.filter p).toList = l.toList.filter p := by
|
||||
dsimp only [filter]
|
||||
rw [foldl_eq_foldl_toList]
|
||||
@@ -954,30 +858,23 @@ theorem get_modify {arr : Array α} {x i} (h : i < (arr.modify x f).size) :
|
||||
induction l with simp
|
||||
| cons => split <;> simp [*]
|
||||
|
||||
@[deprecated toList_filter (since := "2024-09-09")]
|
||||
abbrev filter_data := @toList_filter
|
||||
@[deprecated filter_toList (since := "2024-09-09")]
|
||||
abbrev filter_data := @filter_toList
|
||||
|
||||
@[simp] theorem filter_filter (q) (l : Array α) :
|
||||
filter p (filter q l) = filter (fun a => p a && q a) l := by
|
||||
apply ext'
|
||||
simp only [toList_filter, List.filter_filter]
|
||||
simp only [filter_toList, List.filter_filter]
|
||||
|
||||
@[simp] theorem mem_filter : x ∈ filter p as ↔ x ∈ as ∧ p x := by
|
||||
simp only [mem_def, toList_filter, List.mem_filter]
|
||||
simp only [mem_def, filter_toList, List.mem_filter]
|
||||
|
||||
theorem mem_of_mem_filter {a : α} {l} (h : a ∈ filter p l) : a ∈ l :=
|
||||
(mem_filter.mp h).1
|
||||
|
||||
@[congr]
|
||||
theorem filter_congr {as bs : Array α} (h : as = bs)
|
||||
{f : α → Bool} {g : α → Bool} (h' : f = g) {start stop start' stop' : Nat}
|
||||
(h₁ : start = start') (h₂ : stop = stop') :
|
||||
filter f as start stop = filter g bs start' stop' := by
|
||||
congr
|
||||
|
||||
/-! ### filterMap -/
|
||||
|
||||
@[simp] theorem toList_filterMap (f : α → Option β) (l : Array α) :
|
||||
@[simp] theorem filterMap_toList (f : α → Option β) (l : Array α) :
|
||||
(l.filterMap f).toList = l.toList.filterMap f := by
|
||||
dsimp only [filterMap, filterMapM]
|
||||
rw [foldlM_eq_foldlM_toList]
|
||||
@@ -990,19 +887,12 @@ theorem filter_congr {as bs : Array α} (h : as = bs)
|
||||
· simp_all [Id.run, List.filterMap_cons]
|
||||
split <;> simp_all
|
||||
|
||||
@[deprecated toList_filterMap (since := "2024-09-09")]
|
||||
abbrev filterMap_data := @toList_filterMap
|
||||
@[deprecated filterMap_toList (since := "2024-09-09")]
|
||||
abbrev filterMap_data := @filterMap_toList
|
||||
|
||||
@[simp] theorem mem_filterMap {f : α → Option β} {l : Array α} {b : β} :
|
||||
b ∈ filterMap f l ↔ ∃ a, a ∈ l ∧ f a = some b := by
|
||||
simp only [mem_def, toList_filterMap, List.mem_filterMap]
|
||||
|
||||
@[congr]
|
||||
theorem filterMap_congr {as bs : Array α} (h : as = bs)
|
||||
{f : α → Option β} {g : α → Option β} (h' : f = g) {start stop start' stop' : Nat}
|
||||
(h₁ : start = start') (h₂ : stop = stop') :
|
||||
filterMap f as start stop = filterMap g bs start' stop' := by
|
||||
congr
|
||||
simp only [mem_def, filterMap_toList, List.mem_filterMap]
|
||||
|
||||
/-! ### empty -/
|
||||
|
||||
@@ -1018,66 +908,34 @@ abbrev empty_data := @toList_empty
|
||||
theorem push_eq_append_singleton (as : Array α) (x) : as.push x = as ++ #[x] := rfl
|
||||
|
||||
@[simp] theorem mem_append {a : α} {s t : Array α} : a ∈ s ++ t ↔ a ∈ s ∨ a ∈ t := by
|
||||
simp only [mem_def, toList_append, List.mem_append]
|
||||
simp only [mem_def, append_toList, List.mem_append]
|
||||
|
||||
@[simp] theorem size_append (as bs : Array α) : (as ++ bs).size = as.size + bs.size := by
|
||||
simp only [size, toList_append, List.length_append]
|
||||
theorem size_append (as bs : Array α) : (as ++ bs).size = as.size + bs.size := by
|
||||
simp only [size, append_toList, List.length_append]
|
||||
|
||||
theorem getElem_append {as bs : Array α} (h : i < (as ++ bs).size) :
|
||||
(as ++ bs)[i] = if h' : i < as.size then as[i] else bs[i - as.size]'(by simp at h; omega) := by
|
||||
cases as; cases bs
|
||||
simp [List.getElem_append]
|
||||
|
||||
theorem getElem_append_left {as bs : Array α} {h : i < (as ++ bs).size} (hlt : i < as.size) :
|
||||
theorem get_append_left {as bs : Array α} {h : i < (as ++ bs).size} (hlt : i < as.size) :
|
||||
(as ++ bs)[i] = as[i] := by
|
||||
simp only [getElem_eq_getElem_toList]
|
||||
have h' : i < (as.toList ++ bs.toList).length := by rwa [← length_toList, toList_append] at h
|
||||
have h' : i < (as.toList ++ bs.toList).length := by rwa [← toList_length, append_toList] at h
|
||||
conv => rhs; rw [← List.getElem_append_left (bs := bs.toList) (h' := h')]
|
||||
apply List.get_of_eq; rw [toList_append]
|
||||
apply List.get_of_eq; rw [append_toList]
|
||||
|
||||
@[deprecated getElem_append_left (since := "2024-09-30")]
|
||||
abbrev get_append_left := @getElem_append_left
|
||||
|
||||
theorem getElem_append_right {as bs : Array α} {h : i < (as ++ bs).size} (hle : as.size ≤ i)
|
||||
theorem get_append_right {as bs : Array α} {h : i < (as ++ bs).size} (hle : as.size ≤ i)
|
||||
(hlt : i - as.size < bs.size := Nat.sub_lt_left_of_lt_add hle (size_append .. ▸ h)) :
|
||||
(as ++ bs)[i] = bs[i - as.size] := by
|
||||
simp only [getElem_eq_getElem_toList]
|
||||
have h' : i < (as.toList ++ bs.toList).length := by rwa [← length_toList, toList_append] at h
|
||||
have h' : i < (as.toList ++ bs.toList).length := by rwa [← toList_length, append_toList] at h
|
||||
conv => rhs; rw [← List.getElem_append_right (h₁ := hle) (h₂ := h')]
|
||||
apply List.get_of_eq; rw [toList_append]
|
||||
|
||||
@[deprecated getElem_append_right (since := "2024-09-30")]
|
||||
abbrev get_append_right := @getElem_append_right
|
||||
apply List.get_of_eq; rw [append_toList]
|
||||
|
||||
@[simp] theorem append_nil (as : Array α) : as ++ #[] = as := by
|
||||
apply ext'; simp only [toList_append, toList_empty, List.append_nil]
|
||||
apply ext'; simp only [append_toList, toList_empty, List.append_nil]
|
||||
|
||||
@[simp] theorem nil_append (as : Array α) : #[] ++ as = as := by
|
||||
apply ext'; simp only [toList_append, toList_empty, List.nil_append]
|
||||
apply ext'; simp only [append_toList, toList_empty, List.nil_append]
|
||||
|
||||
theorem append_assoc (as bs cs : Array α) : as ++ bs ++ cs = as ++ (bs ++ cs) := by
|
||||
apply ext'; simp only [toList_append, List.append_assoc]
|
||||
|
||||
/-! ### flatten -/
|
||||
|
||||
@[simp] theorem toList_flatten {l : Array (Array α)} : l.flatten.toList = (l.toList.map toList).join := by
|
||||
dsimp [flatten]
|
||||
simp only [foldl_eq_foldl_toList]
|
||||
generalize l.toList = l
|
||||
have : ∀ a : Array α, (List.foldl ?_ a l).toList = a.toList ++ ?_ := ?_
|
||||
exact this #[]
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons h => induction h.toList <;> simp [*]
|
||||
|
||||
theorem mem_flatten : ∀ {L : Array (Array α)}, a ∈ L.flatten ↔ ∃ l, l ∈ L ∧ a ∈ l := by
|
||||
simp only [mem_def, toList_flatten, List.mem_join, List.mem_map]
|
||||
intro l
|
||||
constructor
|
||||
· rintro ⟨_, ⟨s, m, rfl⟩, h⟩
|
||||
exact ⟨s, m, h⟩
|
||||
· rintro ⟨s, h₁, h₂⟩
|
||||
refine ⟨s.toList, ⟨⟨s, h₁, rfl⟩, h₂⟩⟩
|
||||
apply ext'; simp only [append_toList, List.append_assoc]
|
||||
|
||||
/-! ### extract -/
|
||||
|
||||
@@ -1127,20 +985,20 @@ theorem size_extract_loop (as bs : Array α) (size start : Nat) :
|
||||
simp [extract]; rw [size_extract_loop, size_empty, Nat.zero_add, Nat.sub_min_sub_right,
|
||||
Nat.min_assoc, Nat.min_self]
|
||||
|
||||
theorem getElem_extract_loop_lt_aux (as bs : Array α) (size start : Nat) (hlt : i < bs.size) :
|
||||
theorem get_extract_loop_lt_aux (as bs : Array α) (size start : Nat) (hlt : i < bs.size) :
|
||||
i < (extract.loop as size start bs).size := by
|
||||
rw [size_extract_loop]
|
||||
apply Nat.lt_of_lt_of_le hlt
|
||||
exact Nat.le_add_right ..
|
||||
|
||||
theorem getElem_extract_loop_lt (as bs : Array α) (size start : Nat) (hlt : i < bs.size)
|
||||
(h := getElem_extract_loop_lt_aux as bs size start hlt) :
|
||||
theorem get_extract_loop_lt (as bs : Array α) (size start : Nat) (hlt : i < bs.size)
|
||||
(h := get_extract_loop_lt_aux as bs size start hlt) :
|
||||
(extract.loop as size start bs)[i] = bs[i] := by
|
||||
apply Eq.trans _ (getElem_append_left (bs:=extract.loop as size start #[]) hlt)
|
||||
apply Eq.trans _ (get_append_left (bs:=extract.loop as size start #[]) hlt)
|
||||
· rw [size_append]; exact Nat.lt_of_lt_of_le hlt (Nat.le_add_right ..)
|
||||
· congr; rw [extract_loop_eq_aux]
|
||||
|
||||
theorem getElem_extract_loop_ge_aux (as bs : Array α) (size start : Nat) (hge : i ≥ bs.size)
|
||||
theorem get_extract_loop_ge_aux (as bs : Array α) (size start : Nat) (hge : i ≥ bs.size)
|
||||
(h : i < (extract.loop as size start bs).size) : start + i - bs.size < as.size := by
|
||||
have h : i < bs.size + (as.size - start) := by
|
||||
apply Nat.lt_of_lt_of_le h
|
||||
@@ -1151,9 +1009,9 @@ theorem getElem_extract_loop_ge_aux (as bs : Array α) (size start : Nat) (hge :
|
||||
apply Nat.add_lt_of_lt_sub'
|
||||
exact Nat.sub_lt_left_of_lt_add hge h
|
||||
|
||||
theorem getElem_extract_loop_ge (as bs : Array α) (size start : Nat) (hge : i ≥ bs.size)
|
||||
theorem get_extract_loop_ge (as bs : Array α) (size start : Nat) (hge : i ≥ bs.size)
|
||||
(h : i < (extract.loop as size start bs).size)
|
||||
(h' := getElem_extract_loop_ge_aux as bs size start hge h) :
|
||||
(h' := get_extract_loop_ge_aux as bs size start hge h) :
|
||||
(extract.loop as size start bs)[i] = as[start + i - bs.size] := by
|
||||
induction size using Nat.recAux generalizing start bs with
|
||||
| zero =>
|
||||
@@ -1175,37 +1033,28 @@ theorem getElem_extract_loop_ge (as bs : Array α) (size start : Nat) (hge : i
|
||||
have h₂ : bs.size < (extract.loop as size (start+1) (bs.push as[start])).size := by
|
||||
rw [size_extract_loop]; apply Nat.lt_of_lt_of_le h₁; exact Nat.le_add_right ..
|
||||
have h : (extract.loop as size (start + 1) (push bs as[start]))[bs.size] = as[start] := by
|
||||
rw [getElem_extract_loop_lt as (bs.push as[start]) size (start+1) h₁ h₂, get_push_eq]
|
||||
rw [get_extract_loop_lt as (bs.push as[start]) size (start+1) h₁ h₂, get_push_eq]
|
||||
rw [h]; congr; rw [Nat.add_sub_cancel]
|
||||
else
|
||||
have hge : bs.size + 1 ≤ i := Nat.lt_of_le_of_ne hge hi
|
||||
rw [ih (bs.push as[start]) (start+1) ((size_push ..).symm ▸ hge)]
|
||||
congr 1; rw [size_push, Nat.add_right_comm, Nat.add_sub_add_right]
|
||||
|
||||
theorem getElem_extract_aux {as : Array α} {start stop : Nat} (h : i < (as.extract start stop).size) :
|
||||
theorem get_extract_aux {as : Array α} {start stop : Nat} (h : i < (as.extract start stop).size) :
|
||||
start + i < as.size := by
|
||||
rw [size_extract] at h; apply Nat.add_lt_of_lt_sub'; apply Nat.lt_of_lt_of_le h
|
||||
apply Nat.sub_le_sub_right; apply Nat.min_le_right
|
||||
|
||||
@[simp] theorem getElem_extract {as : Array α} {start stop : Nat}
|
||||
@[simp] theorem get_extract {as : Array α} {start stop : Nat}
|
||||
(h : i < (as.extract start stop).size) :
|
||||
(as.extract start stop)[i] = as[start + i]'(getElem_extract_aux h) :=
|
||||
(as.extract start stop)[i] = as[start + i]'(get_extract_aux h) :=
|
||||
show (extract.loop as (min stop as.size - start) start #[])[i]
|
||||
= as[start + i]'(getElem_extract_aux h) by rw [getElem_extract_loop_ge]; rfl; exact Nat.zero_le _
|
||||
|
||||
theorem getElem?_extract {as : Array α} {start stop : Nat} :
|
||||
(as.extract start stop)[i]? = if i < min stop as.size - start then as[start + i]? else none := by
|
||||
simp only [getElem?_def, size_extract, getElem_extract]
|
||||
split
|
||||
· split
|
||||
· rfl
|
||||
· omega
|
||||
· rfl
|
||||
= as[start + i]'(get_extract_aux h) by rw [get_extract_loop_ge]; rfl; exact Nat.zero_le _
|
||||
|
||||
@[simp] theorem extract_all (as : Array α) : as.extract 0 as.size = as := by
|
||||
apply ext
|
||||
· rw [size_extract, Nat.min_self, Nat.sub_zero]
|
||||
· intros; rw [getElem_extract]; congr; rw [Nat.zero_add]
|
||||
· intros; rw [get_extract]; congr; rw [Nat.zero_add]
|
||||
|
||||
theorem extract_empty_of_stop_le_start (as : Array α) {start stop : Nat} (h : stop ≤ start) :
|
||||
as.extract start stop = #[] := by
|
||||
@@ -1222,33 +1071,6 @@ theorem extract_empty_of_size_le_start (as : Array α) {start stop : Nat} (h : a
|
||||
|
||||
/-! ### any -/
|
||||
|
||||
theorem anyM_loop_cons [Monad m] (p : α → m Bool) (a : α) (as : List α) (stop start : Nat) (h : stop + 1 ≤ (a :: as).length) :
|
||||
anyM.loop p ⟨a :: as⟩ (stop + 1) h (start + 1) = anyM.loop p ⟨as⟩ stop (by simpa using h) start := by
|
||||
rw [anyM.loop]
|
||||
conv => rhs; rw [anyM.loop]
|
||||
split <;> rename_i h'
|
||||
· simp only [Nat.add_lt_add_iff_right] at h'
|
||||
rw [dif_pos h']
|
||||
rw [anyM_loop_cons]
|
||||
simp
|
||||
· rw [dif_neg]
|
||||
omega
|
||||
|
||||
@[simp] theorem anyM_toList [Monad m] (p : α → m Bool) (as : Array α) :
|
||||
as.toList.anyM p = as.anyM p :=
|
||||
match as with
|
||||
| ⟨[]⟩ => rfl
|
||||
| ⟨a :: as⟩ => by
|
||||
simp only [List.anyM, anyM, size_toArray, List.length_cons, Nat.le_refl, ↓reduceDIte]
|
||||
rw [anyM.loop, dif_pos (by omega)]
|
||||
congr 1
|
||||
funext b
|
||||
split
|
||||
· simp
|
||||
· simp only [Bool.false_eq_true, ↓reduceIte]
|
||||
rw [anyM_loop_cons]
|
||||
simpa [anyM] using anyM_toList p ⟨as⟩
|
||||
|
||||
-- Auxiliary for `any_iff_exists`.
|
||||
theorem anyM_loop_iff_exists {p : α → Bool} {as : Array α} {start stop} (h : stop ≤ as.size) :
|
||||
anyM.loop (m := Id) p as stop h start = true ↔
|
||||
@@ -1287,26 +1109,12 @@ theorem any_iff_exists {p : α → Bool} {as : Array α} {start stop} :
|
||||
theorem any_eq_true {p : α → Bool} {as : Array α} :
|
||||
any as p ↔ ∃ i : Fin as.size, p as[i] := by simp [any_iff_exists, Fin.isLt]
|
||||
|
||||
theorem any_toList {p : α → Bool} (as : Array α) : as.toList.any p = as.any p := by
|
||||
theorem any_def {p : α → Bool} (as : Array α) : as.any p = as.toList.any p := by
|
||||
rw [Bool.eq_iff_iff, any_eq_true, List.any_eq_true]; simp only [List.mem_iff_get]
|
||||
exact ⟨fun ⟨_, ⟨i, rfl⟩, h⟩ => ⟨i, h⟩, fun ⟨i, h⟩ => ⟨_, ⟨i, rfl⟩, h⟩⟩
|
||||
|
||||
@[deprecated "Use the reverse direction of `Array.any_toList`" (since := "2024-09-30")]
|
||||
abbrev any_def := @any_toList
|
||||
exact ⟨fun ⟨i, h⟩ => ⟨_, ⟨i, rfl⟩, h⟩, fun ⟨_, ⟨i, rfl⟩, h⟩ => ⟨i, h⟩⟩
|
||||
|
||||
/-! ### all -/
|
||||
|
||||
theorem allM_eq_not_anyM_not [Monad m] [LawfulMonad m] (p : α → m Bool) (as : Array α) :
|
||||
allM p as = (! ·) <$> anyM ((! ·) <$> p ·) as := by
|
||||
dsimp [allM, anyM]
|
||||
simp
|
||||
|
||||
@[simp] theorem allM_toList [Monad m] [LawfulMonad m] (p : α → m Bool) (as : Array α) :
|
||||
as.toList.allM p = as.allM p := by
|
||||
rw [allM_eq_not_anyM_not]
|
||||
rw [← anyM_toList]
|
||||
rw [List.allM_eq_not_anyM_not]
|
||||
|
||||
theorem all_eq_not_any_not (p : α → Bool) (as : Array α) (start stop) :
|
||||
all as p start stop = !(any as (!p ·) start stop) := by
|
||||
dsimp [all, allM]
|
||||
@@ -1324,25 +1132,22 @@ theorem all_iff_forall {p : α → Bool} {as : Array α} {start stop} :
|
||||
theorem all_eq_true {p : α → Bool} {as : Array α} : all as p ↔ ∀ i : Fin as.size, p as[i] := by
|
||||
simp [all_iff_forall, Fin.isLt]
|
||||
|
||||
theorem all_toList {p : α → Bool} (as : Array α) : as.toList.all p = as.all p := by
|
||||
theorem all_def {p : α → Bool} (as : Array α) : as.all p = as.toList.all p := by
|
||||
rw [Bool.eq_iff_iff, all_eq_true, List.all_eq_true]; simp only [List.mem_iff_getElem]
|
||||
constructor
|
||||
· intro w i
|
||||
exact w as[i] ⟨i, i.2, (getElem_eq_getElem_toList i.2).symm⟩
|
||||
· rintro w x ⟨r, h, rfl⟩
|
||||
rw [← getElem_eq_getElem_toList]
|
||||
exact w ⟨r, h⟩
|
||||
|
||||
@[deprecated "Use the reverse direction of `Array.all_toList`" (since := "2024-09-30")]
|
||||
abbrev all_def := @all_toList
|
||||
· intro w i
|
||||
exact w as[i] ⟨i, i.2, (getElem_eq_getElem_toList i.2).symm⟩
|
||||
|
||||
theorem all_eq_true_iff_forall_mem {l : Array α} : l.all p ↔ ∀ x, x ∈ l → p x := by
|
||||
simp only [← all_toList, List.all_eq_true, mem_def]
|
||||
simp only [all_def, List.all_eq_true, mem_def]
|
||||
|
||||
/-! ### contains -/
|
||||
|
||||
theorem contains_def [DecidableEq α] {a : α} {as : Array α} : as.contains a ↔ a ∈ as := by
|
||||
rw [mem_def, contains, ← any_toList, List.any_eq_true]; simp [and_comm]
|
||||
rw [mem_def, contains, any_def, List.any_eq_true]; simp [and_comm]
|
||||
|
||||
instance [DecidableEq α] (a : α) (as : Array α) : Decidable (a ∈ as) :=
|
||||
decidable_of_iff _ contains_def
|
||||
@@ -1351,12 +1156,12 @@ instance [DecidableEq α] (a : α) (as : Array α) : Decidable (a ∈ as) :=
|
||||
|
||||
open Fin
|
||||
|
||||
@[simp] theorem getElem_swap_right (a : Array α) {i j : Fin a.size} : (a.swap i j)[j.val] = a[i] :=
|
||||
@[simp] theorem get_swap_right (a : Array α) {i j : Fin a.size} : (a.swap i j)[j.val] = a[i] :=
|
||||
by simp only [swap, fin_cast_val, get_eq_getElem, getElem_set_eq, getElem_fin]
|
||||
|
||||
@[simp] theorem getElem_swap_left (a : Array α) {i j : Fin a.size} : (a.swap i j)[i.val] = a[j] :=
|
||||
@[simp] theorem get_swap_left (a : Array α) {i j : Fin a.size} : (a.swap i j)[i.val] = a[j] :=
|
||||
if he : ((Array.size_set _ _ _).symm ▸ j).val = i.val then by
|
||||
simp only [←he, fin_cast_val, getElem_swap_right, getElem_fin]
|
||||
simp only [←he, fin_cast_val, get_swap_right, getElem_fin]
|
||||
else by
|
||||
apply Eq.trans
|
||||
· apply Array.get_set_ne
|
||||
@@ -1364,7 +1169,7 @@ open Fin
|
||||
· assumption
|
||||
· simp [get_set_ne]
|
||||
|
||||
@[simp] theorem getElem_swap_of_ne (a : Array α) {i j : Fin a.size} (hp : p < a.size)
|
||||
@[simp] theorem get_swap_of_ne (a : Array α) {i j : Fin a.size} (hp : p < a.size)
|
||||
(hi : p ≠ i) (hj : p ≠ j) : (a.swap i j)[p]'(a.size_swap .. |>.symm ▸ hp) = a[p] := by
|
||||
apply Eq.trans
|
||||
· have : ((a.size_set i (a.get j)).symm ▸ j).val = j.val := by simp only [fin_cast_val]
|
||||
@@ -1376,22 +1181,22 @@ open Fin
|
||||
· apply Ne.symm
|
||||
· assumption
|
||||
|
||||
theorem getElem_swap' (a : Array α) (i j : Fin a.size) (k : Nat) (hk : k < a.size) :
|
||||
theorem get_swap (a : Array α) (i j : Fin a.size) (k : Nat) (hk: k < a.size) :
|
||||
(a.swap i j)[k]'(by simp_all) = if k = i then a[j] else if k = j then a[i] else a[k] := by
|
||||
split
|
||||
· simp_all only [getElem_swap_left]
|
||||
· simp_all only [get_swap_left]
|
||||
· split <;> simp_all
|
||||
|
||||
theorem getElem_swap (a : Array α) (i j : Fin a.size) (k : Nat) (hk : k < (a.swap i j).size) :
|
||||
theorem get_swap' (a : Array α) (i j : Fin a.size) (k : Nat) (hk' : k < (a.swap i j).size) :
|
||||
(a.swap i j)[k] = if k = i then a[j] else if k = j then a[i] else a[k]'(by simp_all) := by
|
||||
apply getElem_swap'
|
||||
apply get_swap
|
||||
|
||||
@[simp] theorem swap_swap (a : Array α) {i j : Fin a.size} :
|
||||
(a.swap i j).swap ⟨i.1, (a.size_swap ..).symm ▸i.2⟩ ⟨j.1, (a.size_swap ..).symm ▸j.2⟩ = a := by
|
||||
apply ext
|
||||
· simp only [size_swap]
|
||||
· intros
|
||||
simp only [getElem_swap]
|
||||
simp only [get_swap']
|
||||
split
|
||||
· simp_all
|
||||
· split <;> simp_all
|
||||
@@ -1400,179 +1205,9 @@ theorem swap_comm (a : Array α) {i j : Fin a.size} : a.swap i j = a.swap j i :=
|
||||
apply ext
|
||||
· simp only [size_swap]
|
||||
· intros
|
||||
simp only [getElem_swap]
|
||||
simp only [get_swap']
|
||||
split
|
||||
· split <;> simp_all
|
||||
· split <;> simp_all
|
||||
|
||||
@[deprecated getElem_extract_loop_lt_aux (since := "2024-09-30")]
|
||||
abbrev get_extract_loop_lt_aux := @getElem_extract_loop_lt_aux
|
||||
@[deprecated getElem_extract_loop_lt (since := "2024-09-30")]
|
||||
abbrev get_extract_loop_lt := @getElem_extract_loop_lt
|
||||
@[deprecated getElem_extract_loop_ge_aux (since := "2024-09-30")]
|
||||
abbrev get_extract_loop_ge_aux := @getElem_extract_loop_ge_aux
|
||||
@[deprecated getElem_extract_loop_ge (since := "2024-09-30")]
|
||||
abbrev get_extract_loop_ge := @getElem_extract_loop_ge
|
||||
@[deprecated getElem_extract_aux (since := "2024-09-30")]
|
||||
abbrev get_extract_aux := @getElem_extract_aux
|
||||
@[deprecated getElem_extract (since := "2024-09-30")]
|
||||
abbrev get_extract := @getElem_extract
|
||||
|
||||
@[deprecated getElem_swap_right (since := "2024-09-30")]
|
||||
abbrev get_swap_right := @getElem_swap_right
|
||||
@[deprecated getElem_swap_left (since := "2024-09-30")]
|
||||
abbrev get_swap_left := @getElem_swap_left
|
||||
@[deprecated getElem_swap_of_ne (since := "2024-09-30")]
|
||||
abbrev get_swap_of_ne := @getElem_swap_of_ne
|
||||
@[deprecated getElem_swap (since := "2024-09-30")]
|
||||
abbrev get_swap := @getElem_swap
|
||||
@[deprecated getElem_swap' (since := "2024-09-30")]
|
||||
abbrev get_swap' := @getElem_swap'
|
||||
|
||||
end Array
|
||||
|
||||
|
||||
open Array
|
||||
|
||||
namespace List
|
||||
|
||||
/-!
|
||||
### More theorems about `List.toArray`, followed by an `Array` operation.
|
||||
|
||||
Our goal is to have `simp` "pull `List.toArray` outwards" as much as possible.
|
||||
-/
|
||||
|
||||
@[simp] theorem mem_toArray {a : α} {l : List α} : a ∈ l.toArray ↔ a ∈ l := by
|
||||
simp [mem_def]
|
||||
|
||||
@[simp] theorem toListRev_toArray (l : List α) : l.toArray.toListRev = l.reverse := by
|
||||
simp
|
||||
|
||||
@[simp] theorem push_append_toArray (as : Array α) (a : α) (l : List α) :
|
||||
as.push a ++ l.toArray = as ++ (a :: l).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem mapM_toArray [Monad m] [LawfulMonad m] (f : α → m β) (l : List α) :
|
||||
l.toArray.mapM f = List.toArray <$> l.mapM f := by
|
||||
simp only [← mapM'_eq_mapM, mapM_eq_foldlM]
|
||||
suffices ∀ init : Array β,
|
||||
foldlM (fun bs a => bs.push <$> f a) init l.toArray = (init ++ toArray ·) <$> mapM' f l by
|
||||
simpa using this #[]
|
||||
intro init
|
||||
induction l generalizing init with
|
||||
| nil => simp
|
||||
| cons a l ih =>
|
||||
simp only [foldlM_toArray] at ih
|
||||
rw [size_toArray, mapM'_cons, foldlM_toArray]
|
||||
simp [ih]
|
||||
|
||||
@[simp] theorem map_toArray (f : α → β) (l : List α) : l.toArray.map f = (l.map f).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem toArray_appendList (l₁ l₂ : List α) :
|
||||
l₁.toArray ++ l₂ = (l₁ ++ l₂).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem set_toArray (l : List α) (i : Fin l.toArray.size) (a : α) :
|
||||
l.toArray.set i a = (l.set i a).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem uset_toArray (l : List α) (i : USize) (a : α) (h : i.toNat < l.toArray.size) :
|
||||
l.toArray.uset i a h = (l.set i.toNat a).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem setD_toArray (l : List α) (i : Nat) (a : α) :
|
||||
l.toArray.setD i a = (l.set i a).toArray := by
|
||||
apply ext'
|
||||
simp only [setD]
|
||||
split
|
||||
· simp
|
||||
· simp_all [List.set_eq_of_length_le]
|
||||
|
||||
theorem anyM_toArray [Monad m] [LawfulMonad m] (p : α → m Bool) (l : List α) :
|
||||
l.toArray.anyM p = l.anyM p := by
|
||||
rw [← anyM_toList]
|
||||
|
||||
theorem any_toArray (p : α → Bool) (l : List α) : l.toArray.any p = l.any p := by
|
||||
rw [any_toList]
|
||||
|
||||
theorem allM_toArray [Monad m] [LawfulMonad m] (p : α → m Bool) (l : List α) :
|
||||
l.toArray.allM p = l.allM p := by
|
||||
rw [← allM_toList]
|
||||
|
||||
theorem all_toArray (p : α → Bool) (l : List α) : l.toArray.all p = l.all p := by
|
||||
rw [all_toList]
|
||||
|
||||
/-- Variant of `anyM_toArray` with a side condition on `stop`. -/
|
||||
@[simp] theorem anyM_toArray' [Monad m] [LawfulMonad m] (p : α → m Bool) (l : List α)
|
||||
(h : stop = l.toArray.size) :
|
||||
l.toArray.anyM p 0 stop = l.anyM p := by
|
||||
subst h
|
||||
rw [← anyM_toList]
|
||||
|
||||
/-- Variant of `any_toArray` with a side condition on `stop`. -/
|
||||
@[simp] theorem any_toArray' (p : α → Bool) (l : List α) (h : stop = l.toArray.size) :
|
||||
l.toArray.any p 0 stop = l.any p := by
|
||||
subst h
|
||||
rw [any_toList]
|
||||
|
||||
/-- Variant of `allM_toArray` with a side condition on `stop`. -/
|
||||
@[simp] theorem allM_toArray' [Monad m] [LawfulMonad m] (p : α → m Bool) (l : List α)
|
||||
(h : stop = l.toArray.size) :
|
||||
l.toArray.allM p 0 stop = l.allM p := by
|
||||
subst h
|
||||
rw [← allM_toList]
|
||||
|
||||
/-- Variant of `all_toArray` with a side condition on `stop`. -/
|
||||
@[simp] theorem all_toArray' (p : α → Bool) (l : List α) (h : stop = l.toArray.size) :
|
||||
l.toArray.all p 0 stop = l.all p := by
|
||||
subst h
|
||||
rw [all_toList]
|
||||
|
||||
@[simp] theorem swap_toArray (l : List α) (i j : Fin l.toArray.size) :
|
||||
l.toArray.swap i j = ((l.set i l[j]).set j l[i]).toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem pop_toArray (l : List α) : l.toArray.pop = l.dropLast.toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem reverse_toArray (l : List α) : l.toArray.reverse = l.reverse.toArray := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
@[simp] theorem filter_toArray' (p : α → Bool) (l : List α) (h : stop = l.toArray.size) :
|
||||
l.toArray.filter p 0 stop = (l.filter p).toArray := by
|
||||
subst h
|
||||
apply ext'
|
||||
rw [toList_filter]
|
||||
|
||||
@[simp] theorem filterMap_toArray' (f : α → Option β) (l : List α) (h : stop = l.toArray.size) :
|
||||
l.toArray.filterMap f 0 stop = (l.filterMap f).toArray := by
|
||||
subst h
|
||||
apply ext'
|
||||
rw [toList_filterMap]
|
||||
|
||||
theorem filter_toArray (p : α → Bool) (l : List α) :
|
||||
l.toArray.filter p = (l.filter p).toArray := by
|
||||
simp
|
||||
|
||||
theorem filterMap_toArray (f : α → Option β) (l : List α) :
|
||||
l.toArray.filterMap f = (l.filterMap f).toArray := by
|
||||
simp
|
||||
|
||||
@[simp] theorem flatten_toArray (l : List (List α)) : (l.toArray.map List.toArray).flatten = l.join.toArray := by
|
||||
apply ext'
|
||||
simp [Function.comp_def]
|
||||
|
||||
@[simp] theorem toArray_range (n : Nat) : (range n).toArray = Array.range n := by
|
||||
apply ext'
|
||||
simp
|
||||
|
||||
end List
|
||||
|
||||
@@ -5,7 +5,6 @@ Authors: Leonardo de Moura
|
||||
-/
|
||||
prelude
|
||||
import Init.Data.Array.Basic
|
||||
import Init.Data.Ord
|
||||
|
||||
namespace Array
|
||||
-- TODO: remove the [Inhabited α] parameters as soon as we have the tactic framework for automating proof generation and using Array.fget
|
||||
@@ -45,11 +44,4 @@ def qpartition (as : Array α) (lt : α → α → Bool) (lo hi : Nat) : Nat ×
|
||||
else as
|
||||
sort as low high
|
||||
|
||||
set_option linter.unusedVariables.funArgs false in
|
||||
/--
|
||||
Sort an array using `compare` to compare elements.
|
||||
-/
|
||||
def qsortOrd [ord : Ord α] (xs : Array α) : Array α :=
|
||||
xs.qsort fun x y => compare x y |>.isLT
|
||||
|
||||
end Array
|
||||
|
||||
@@ -59,22 +59,6 @@ def popFront (s : Subarray α) : Subarray α :=
|
||||
else
|
||||
s
|
||||
|
||||
/--
|
||||
The empty subarray.
|
||||
-/
|
||||
protected def empty : Subarray α where
|
||||
array := #[]
|
||||
start := 0
|
||||
stop := 0
|
||||
start_le_stop := Nat.le_refl 0
|
||||
stop_le_array_size := Nat.le_refl 0
|
||||
|
||||
instance : EmptyCollection (Subarray α) :=
|
||||
⟨Subarray.empty⟩
|
||||
|
||||
instance : Inhabited (Subarray α) :=
|
||||
⟨{}⟩
|
||||
|
||||
@[inline] unsafe def forInUnsafe {α : Type u} {β : Type v} {m : Type v → Type w} [Monad m] (s : Subarray α) (b : β) (f : α → β → m (ForInStep β)) : m β :=
|
||||
let sz := USize.ofNat s.stop
|
||||
let rec @[specialize] loop (i : USize) (b : β) : m β := do
|
||||
|
||||
@@ -269,8 +269,8 @@ Return the absolute value of a signed bitvector.
|
||||
protected def abs (x : BitVec n) : BitVec n := if x.msb then .neg x else x
|
||||
|
||||
/--
|
||||
Multiplication for bit vectors. This can be interpreted as either signed or unsigned
|
||||
multiplication modulo `2^n`.
|
||||
Multiplication for bit vectors. This can be interpreted as either signed or unsigned negation
|
||||
modulo `2^n`.
|
||||
|
||||
SMT-Lib name: `bvmul`.
|
||||
-/
|
||||
@@ -676,13 +676,6 @@ result of appending a single bit to the front in the naive implementation).
|
||||
That is, the new bit is the least significant bit. -/
|
||||
def concat {n} (msbs : BitVec n) (lsb : Bool) : BitVec (n+1) := msbs ++ (ofBool lsb)
|
||||
|
||||
/--
|
||||
`x.shiftConcat b` shifts all bits of `x` to the left by `1` and sets the least significant bit to `b`.
|
||||
It is a non-dependent version of `concat` that does not change the total bitwidth.
|
||||
-/
|
||||
def shiftConcat (x : BitVec n) (b : Bool) : BitVec n :=
|
||||
(x.concat b).truncate n
|
||||
|
||||
/-- Prepend a single bit to the front of a bitvector, using big endian order (see `append`).
|
||||
That is, the new bit is the most significant bit. -/
|
||||
def cons {n} (msb : Bool) (lsbs : BitVec n) : BitVec (n+1) :=
|
||||
|
||||
@@ -164,17 +164,6 @@ theorem getLsbD_add {i : Nat} (i_lt : i < w) (x y : BitVec w) :
|
||||
(getLsbD x i ^^ (getLsbD y i ^^ carry i x y false)) := by
|
||||
simpa using getLsbD_add_add_bool i_lt x y false
|
||||
|
||||
theorem getElem_add_add_bool {i : Nat} (i_lt : i < w) (x y : BitVec w) (c : Bool) :
|
||||
(x + y + setWidth w (ofBool c))[i] =
|
||||
(x[i] ^^ (y[i] ^^ carry i x y c)) := by
|
||||
simp only [← getLsbD_eq_getElem]
|
||||
rw [getLsbD_add_add_bool]
|
||||
omega
|
||||
|
||||
theorem getElem_add {i : Nat} (i_lt : i < w) (x y : BitVec w) :
|
||||
(x + y)[i] = (x[i] ^^ (y[i] ^^ carry i x y false)) := by
|
||||
simpa using getElem_add_add_bool i_lt x y false
|
||||
|
||||
theorem adc_spec (x y : BitVec w) (c : Bool) :
|
||||
adc x y c = (carry w x y c, x + y + setWidth w (ofBool c)) := by
|
||||
simp only [adc]
|
||||
@@ -379,10 +368,6 @@ theorem getLsbD_mul (x y : BitVec w) (i : Nat) :
|
||||
· simp
|
||||
· omega
|
||||
|
||||
theorem getElem_mul {x y : BitVec w} {i : Nat} (h : i < w) :
|
||||
(x * y)[i] = (mulRec x y w)[i] := by
|
||||
simp [mulRec_eq_mul_signExtend_setWidth]
|
||||
|
||||
/-! ## shiftLeft recurrence for bitblasting -/
|
||||
|
||||
/--
|
||||
@@ -453,385 +438,6 @@ theorem shiftLeft_eq_shiftLeftRec (x : BitVec w₁) (y : BitVec w₂) :
|
||||
· simp [of_length_zero]
|
||||
· simp [shiftLeftRec_eq]
|
||||
|
||||
/-! # udiv/urem recurrence for bitblasting
|
||||
|
||||
In order to prove the correctness of the division algorithm on the integers,
|
||||
one shows that `n.div d = q` and `n.mod d = r` iff `n = d * q + r` and `0 ≤ r < d`.
|
||||
Mnemonic: `n` is the numerator, `d` is the denominator, `q` is the quotient, and `r` the remainder.
|
||||
|
||||
This *uniqueness of decomposition* is not true for bitvectors.
|
||||
For `n = 0, d = 3, w = 3`, we can write:
|
||||
- `0 = 0 * 3 + 0` (`q = 0`, `r = 0 < 3`.)
|
||||
- `0 = 2 * 3 + 2 = 6 + 2 ≃ 0 (mod 8)` (`q = 2`, `r = 2 < 3`).
|
||||
|
||||
Such examples can be created by choosing different `(q, r)` for a fixed `(d, n)`
|
||||
such that `(d * q + r)` overflows and wraps around to equal `n`.
|
||||
|
||||
This tells us that the division algorithm must have more restrictions than just the ones
|
||||
we have for integers. These restrictions are captured in `DivModState.Lawful`.
|
||||
The key idea is to state the relationship in terms of the toNat values of {n, d, q, r}.
|
||||
If the division equation `d.toNat * q.toNat + r.toNat = n.toNat` holds,
|
||||
then `n.udiv d = q` and `n.umod d = r`.
|
||||
|
||||
Following this, we implement the division algorithm by repeated shift-subtract.
|
||||
|
||||
References:
|
||||
- Fast 32-bit Division on the DSP56800E: Minimized nonrestoring division algorithm by David Baca
|
||||
- Bitwuzla sources for bitblasting.h
|
||||
-/
|
||||
|
||||
private theorem Nat.div_add_eq_left_of_lt {x y z : Nat} (hx : z ∣ x) (hy : y < z) (hz : 0 < z) :
|
||||
(x + y) / z = x / z := by
|
||||
refine Nat.div_eq_of_lt_le ?lo ?hi
|
||||
· apply Nat.le_trans
|
||||
· exact div_mul_le_self x z
|
||||
· omega
|
||||
· simp only [succ_eq_add_one, Nat.add_mul, Nat.one_mul]
|
||||
apply Nat.add_lt_add_of_le_of_lt
|
||||
· apply Nat.le_of_eq
|
||||
exact (Nat.div_eq_iff_eq_mul_left hz hx).mp rfl
|
||||
· exact hy
|
||||
|
||||
/-- If the division equation `d.toNat * q.toNat + r.toNat = n.toNat` holds,
|
||||
then `n.udiv d = q`. -/
|
||||
theorem udiv_eq_of_mul_add_toNat {d n q r : BitVec w} (hd : 0 < d)
|
||||
(hrd : r < d)
|
||||
(hdqnr : d.toNat * q.toNat + r.toNat = n.toNat) :
|
||||
n.udiv d = q := by
|
||||
apply BitVec.eq_of_toNat_eq
|
||||
rw [toNat_udiv]
|
||||
replace hdqnr : (d.toNat * q.toNat + r.toNat) / d.toNat = n.toNat / d.toNat := by
|
||||
simp [hdqnr]
|
||||
rw [Nat.div_add_eq_left_of_lt] at hdqnr
|
||||
· rw [← hdqnr]
|
||||
exact mul_div_right q.toNat hd
|
||||
· exact Nat.dvd_mul_right d.toNat q.toNat
|
||||
· exact hrd
|
||||
· exact hd
|
||||
|
||||
/-- If the division equation `d.toNat * q.toNat + r.toNat = n.toNat` holds,
|
||||
then `n.umod d = r`. -/
|
||||
theorem umod_eq_of_mul_add_toNat {d n q r : BitVec w} (hrd : r < d)
|
||||
(hdqnr : d.toNat * q.toNat + r.toNat = n.toNat) :
|
||||
n.umod d = r := by
|
||||
apply BitVec.eq_of_toNat_eq
|
||||
rw [toNat_umod]
|
||||
replace hdqnr : (d.toNat * q.toNat + r.toNat) % d.toNat = n.toNat % d.toNat := by
|
||||
simp [hdqnr]
|
||||
rw [Nat.add_mod, Nat.mul_mod_right] at hdqnr
|
||||
simp only [Nat.zero_add, mod_mod] at hdqnr
|
||||
replace hrd : r.toNat < d.toNat := by
|
||||
simpa [BitVec.lt_def] using hrd
|
||||
rw [Nat.mod_eq_of_lt hrd] at hdqnr
|
||||
simp [hdqnr]
|
||||
|
||||
/-! ### DivModState -/
|
||||
|
||||
/-- `DivModState` is a structure that maintains the state of recursive `divrem` calls. -/
|
||||
structure DivModState (w : Nat) : Type where
|
||||
/-- The number of bits in the numerator that are not yet processed -/
|
||||
wn : Nat
|
||||
/-- The number of bits in the remainder (and quotient) -/
|
||||
wr : Nat
|
||||
/-- The current quotient. -/
|
||||
q : BitVec w
|
||||
/-- The current remainder. -/
|
||||
r : BitVec w
|
||||
|
||||
|
||||
/-- `DivModArgs` contains the arguments to a `divrem` call which remain constant throughout
|
||||
execution. -/
|
||||
structure DivModArgs (w : Nat) where
|
||||
/-- the numerator (aka, dividend) -/
|
||||
n : BitVec w
|
||||
/-- the denumerator (aka, divisor)-/
|
||||
d : BitVec w
|
||||
|
||||
/-- A `DivModState` is lawful if the remainder width `wr` plus the numerator width `wn` equals `w`,
|
||||
and the bitvectors `r` and `n` have values in the bounds given by bitwidths `wr`, resp. `wn`.
|
||||
|
||||
This is a proof engineering choice: an alternative world could have been
|
||||
`r : BitVec wr` and `n : BitVec wn`, but this required much more dependent typing coercions.
|
||||
|
||||
Instead, we choose to declare all involved bitvectors as length `w`, and then prove that
|
||||
the values are within their respective bounds.
|
||||
|
||||
We start with `wn = w` and `wr = 0`, and then in each step, we decrement `wn` and increment `wr`.
|
||||
In this way, we grow a legal remainder in each loop iteration.
|
||||
-/
|
||||
structure DivModState.Lawful {w : Nat} (args : DivModArgs w) (qr : DivModState w) : Prop where
|
||||
/-- The sum of widths of the dividend and remainder is `w`. -/
|
||||
hwrn : qr.wr + qr.wn = w
|
||||
/-- The denominator is positive. -/
|
||||
hdPos : 0 < args.d
|
||||
/-- The remainder is strictly less than the denominator. -/
|
||||
hrLtDivisor : qr.r.toNat < args.d.toNat
|
||||
/-- The remainder is morally a `Bitvec wr`, and so has value less than `2^wr`. -/
|
||||
hrWidth : qr.r.toNat < 2^qr.wr
|
||||
/-- The quotient is morally a `Bitvec wr`, and so has value less than `2^wr`. -/
|
||||
hqWidth : qr.q.toNat < 2^qr.wr
|
||||
/-- The low `(w - wn)` bits of `n` obey the invariant for division. -/
|
||||
hdiv : args.n.toNat >>> qr.wn = args.d.toNat * qr.q.toNat + qr.r.toNat
|
||||
|
||||
/-- A lawful DivModState implies `w > 0`. -/
|
||||
def DivModState.Lawful.hw {args : DivModArgs w} {qr : DivModState w}
|
||||
{h : DivModState.Lawful args qr} : 0 < w := by
|
||||
have hd := h.hdPos
|
||||
rcases w with rfl | w
|
||||
· have hcontra : args.d = 0#0 := by apply Subsingleton.elim
|
||||
rw [hcontra] at hd
|
||||
simp at hd
|
||||
· omega
|
||||
|
||||
/-- An initial value with both `q, r = 0`. -/
|
||||
def DivModState.init (w : Nat) : DivModState w := {
|
||||
wn := w
|
||||
wr := 0
|
||||
q := 0#w
|
||||
r := 0#w
|
||||
}
|
||||
|
||||
/-- The initial state is lawful. -/
|
||||
def DivModState.lawful_init {w : Nat} (args : DivModArgs w) (hd : 0#w < args.d) :
|
||||
DivModState.Lawful args (DivModState.init w) := by
|
||||
simp only [BitVec.DivModState.init]
|
||||
exact {
|
||||
hwrn := by simp only; omega,
|
||||
hdPos := by assumption
|
||||
hrLtDivisor := by simp [BitVec.lt_def] at hd ⊢; assumption
|
||||
hrWidth := by simp [DivModState.init],
|
||||
hqWidth := by simp [DivModState.init],
|
||||
hdiv := by
|
||||
simp only [DivModState.init, toNat_ofNat, zero_mod, Nat.mul_zero, Nat.add_zero];
|
||||
rw [Nat.shiftRight_eq_div_pow]
|
||||
apply Nat.div_eq_of_lt args.n.isLt
|
||||
}
|
||||
|
||||
/--
|
||||
A lawful DivModState with a fully consumed dividend (`wn = 0`) witnesses that the
|
||||
quotient has been correctly computed.
|
||||
-/
|
||||
theorem DivModState.udiv_eq_of_lawful {n d : BitVec w} {qr : DivModState w}
|
||||
(h_lawful : DivModState.Lawful {n, d} qr)
|
||||
(h_final : qr.wn = 0) :
|
||||
n.udiv d = qr.q := by
|
||||
apply udiv_eq_of_mul_add_toNat h_lawful.hdPos h_lawful.hrLtDivisor
|
||||
have hdiv := h_lawful.hdiv
|
||||
simp only [h_final] at *
|
||||
omega
|
||||
|
||||
/--
|
||||
A lawful DivModState with a fully consumed dividend (`wn = 0`) witnesses that the
|
||||
remainder has been correctly computed.
|
||||
-/
|
||||
theorem DivModState.umod_eq_of_lawful {qr : DivModState w}
|
||||
(h : DivModState.Lawful {n, d} qr)
|
||||
(h_final : qr.wn = 0) :
|
||||
n.umod d = qr.r := by
|
||||
apply umod_eq_of_mul_add_toNat h.hrLtDivisor
|
||||
have hdiv := h.hdiv
|
||||
simp only [shiftRight_zero] at hdiv
|
||||
simp only [h_final] at *
|
||||
exact hdiv.symm
|
||||
|
||||
/-! ### DivModState.Poised -/
|
||||
|
||||
/--
|
||||
A `Poised` DivModState is a state which is `Lawful` and furthermore, has at least
|
||||
one numerator bit left to process `(0 < wn)`
|
||||
|
||||
The input to the shift subtractor is a legal input to `divrem`, and we also need to have an
|
||||
input bit to perform shift subtraction on, and thus we need `0 < wn`.
|
||||
-/
|
||||
structure DivModState.Poised {w : Nat} (args : DivModArgs w) (qr : DivModState w)
|
||||
extends DivModState.Lawful args qr : Type where
|
||||
/-- Only perform a round of shift-subtract if we have dividend bits. -/
|
||||
hwn_lt : 0 < qr.wn
|
||||
|
||||
/--
|
||||
In the shift subtract input, the dividend is at least one bit long (`wn > 0`), so
|
||||
the remainder has bits to be computed (`wr < w`).
|
||||
-/
|
||||
def DivModState.wr_lt_w {qr : DivModState w} (h : qr.Poised args) : qr.wr < w := by
|
||||
have hwrn := h.hwrn
|
||||
have hwn_lt := h.hwn_lt
|
||||
omega
|
||||
|
||||
/-! ### Division shift subtractor -/
|
||||
|
||||
/--
|
||||
One round of the division algorithm, that tries to perform a subtract shift.
|
||||
Note that this should only be called when `r.msb = false`, so we will not overflow.
|
||||
-/
|
||||
def divSubtractShift (args : DivModArgs w) (qr : DivModState w) : DivModState w :=
|
||||
let {n, d} := args
|
||||
let wn := qr.wn - 1
|
||||
let wr := qr.wr + 1
|
||||
let r' := shiftConcat qr.r (n.getLsbD wn)
|
||||
if r' < d then {
|
||||
q := qr.q.shiftConcat false, -- If `r' < d`, then we do not have a quotient bit.
|
||||
r := r'
|
||||
wn, wr
|
||||
} else {
|
||||
q := qr.q.shiftConcat true, -- Otherwise, `r' ≥ d`, and we have a quotient bit.
|
||||
r := r' - d -- we subtract to maintain the invariant that `r < d`.
|
||||
wn, wr
|
||||
}
|
||||
|
||||
/-- The value of shifting right by `wn - 1` equals shifting by `wn` and grabbing the lsb at `(wn - 1)`. -/
|
||||
theorem DivModState.toNat_shiftRight_sub_one_eq
|
||||
{args : DivModArgs w} {qr : DivModState w} (h : qr.Poised args) :
|
||||
args.n.toNat >>> (qr.wn - 1)
|
||||
= (args.n.toNat >>> qr.wn) * 2 + (args.n.getLsbD (qr.wn - 1)).toNat := by
|
||||
show BitVec.toNat (args.n >>> (qr.wn - 1)) = _
|
||||
have {..} := h -- break the structure down for `omega`
|
||||
rw [shiftRight_sub_one_eq_shiftConcat args.n h.hwn_lt]
|
||||
rw [toNat_shiftConcat_eq_of_lt (k := w - qr.wn)]
|
||||
· simp
|
||||
· omega
|
||||
· apply BitVec.toNat_ushiftRight_lt
|
||||
omega
|
||||
|
||||
/--
|
||||
This is used when proving the correctness of the divison algorithm,
|
||||
where we know that `r < d`.
|
||||
We then want to show that `((r.shiftConcat b) - d) < d` as the loop invariant.
|
||||
In arithmetic, this is the same as showing that
|
||||
`r * 2 + 1 - d < d`, which this theorem establishes.
|
||||
-/
|
||||
private theorem two_mul_add_sub_lt_of_lt_of_lt_two (h : a < x) (hy : y < 2) :
|
||||
2 * a + y - x < x := by omega
|
||||
|
||||
/-- We show that the output of `divSubtractShift` is lawful, which tells us that it
|
||||
obeys the division equation. -/
|
||||
theorem lawful_divSubtractShift (qr : DivModState w) (h : qr.Poised args) :
|
||||
DivModState.Lawful args (divSubtractShift args qr) := by
|
||||
rcases args with ⟨n, d⟩
|
||||
simp only [divSubtractShift, decide_eq_true_eq]
|
||||
-- We add these hypotheses for `omega` to find them later.
|
||||
have ⟨⟨hrwn, hd, hrd, hr, hn, hrnd⟩, hwn_lt⟩ := h
|
||||
have : d.toNat * (qr.q.toNat * 2) = d.toNat * qr.q.toNat * 2 := by rw [Nat.mul_assoc]
|
||||
by_cases rltd : shiftConcat qr.r (n.getLsbD (qr.wn - 1)) < d
|
||||
· simp only [rltd, ↓reduceIte]
|
||||
constructor <;> try bv_omega
|
||||
case pos.hrWidth => apply toNat_shiftConcat_lt_of_lt <;> omega
|
||||
case pos.hqWidth => apply toNat_shiftConcat_lt_of_lt <;> omega
|
||||
case pos.hdiv =>
|
||||
simp [qr.toNat_shiftRight_sub_one_eq h, h.hdiv, this,
|
||||
toNat_shiftConcat_eq_of_lt (qr.wr_lt_w h) h.hrWidth,
|
||||
toNat_shiftConcat_eq_of_lt (qr.wr_lt_w h) h.hqWidth]
|
||||
omega
|
||||
· simp only [rltd, ↓reduceIte]
|
||||
constructor <;> try bv_omega
|
||||
case neg.hrLtDivisor =>
|
||||
simp only [lt_def, Nat.not_lt] at rltd
|
||||
rw [BitVec.toNat_sub_of_le rltd,
|
||||
toNat_shiftConcat_eq_of_lt (hk := qr.wr_lt_w h) (hx := h.hrWidth),
|
||||
Nat.mul_comm]
|
||||
apply two_mul_add_sub_lt_of_lt_of_lt_two <;> bv_omega
|
||||
case neg.hrWidth =>
|
||||
simp only
|
||||
have hdr' : d ≤ (qr.r.shiftConcat (n.getLsbD (qr.wn - 1))) :=
|
||||
BitVec.not_lt_iff_le.mp rltd
|
||||
have hr' : ((qr.r.shiftConcat (n.getLsbD (qr.wn - 1)))).toNat < 2 ^ (qr.wr + 1) := by
|
||||
apply toNat_shiftConcat_lt_of_lt <;> bv_omega
|
||||
rw [BitVec.toNat_sub_of_le hdr']
|
||||
omega
|
||||
case neg.hqWidth =>
|
||||
apply toNat_shiftConcat_lt_of_lt <;> omega
|
||||
case neg.hdiv =>
|
||||
have rltd' := (BitVec.not_lt_iff_le.mp rltd)
|
||||
simp only [qr.toNat_shiftRight_sub_one_eq h,
|
||||
BitVec.toNat_sub_of_le rltd',
|
||||
toNat_shiftConcat_eq_of_lt (qr.wr_lt_w h) h.hrWidth]
|
||||
simp only [BitVec.le_def,
|
||||
toNat_shiftConcat_eq_of_lt (qr.wr_lt_w h) h.hrWidth] at rltd'
|
||||
simp only [toNat_shiftConcat_eq_of_lt (qr.wr_lt_w h) h.hqWidth, h.hdiv, Nat.mul_add]
|
||||
bv_omega
|
||||
|
||||
/-! ### Core division algorithm circuit -/
|
||||
|
||||
/-- A recursive definition of division for bitblasting, in terms of a shift-subtraction circuit. -/
|
||||
def divRec {w : Nat} (m : Nat) (args : DivModArgs w) (qr : DivModState w) :
|
||||
DivModState w :=
|
||||
match m with
|
||||
| 0 => qr
|
||||
| m + 1 => divRec m args <| divSubtractShift args qr
|
||||
|
||||
@[simp]
|
||||
theorem divRec_zero (qr : DivModState w) :
|
||||
divRec 0 args qr = qr := rfl
|
||||
|
||||
@[simp]
|
||||
theorem divRec_succ (m : Nat) (args : DivModArgs w) (qr : DivModState w) :
|
||||
divRec (m + 1) args qr =
|
||||
divRec m args (divSubtractShift args qr) := rfl
|
||||
|
||||
/-- The output of `divRec` is a lawful state -/
|
||||
theorem lawful_divRec {args : DivModArgs w} {qr : DivModState w}
|
||||
(h : DivModState.Lawful args qr) :
|
||||
DivModState.Lawful args (divRec qr.wn args qr) := by
|
||||
generalize hm : qr.wn = m
|
||||
induction m generalizing qr
|
||||
case zero =>
|
||||
exact h
|
||||
case succ wn' ih =>
|
||||
simp only [divRec_succ]
|
||||
apply ih
|
||||
· apply lawful_divSubtractShift
|
||||
constructor
|
||||
· assumption
|
||||
· omega
|
||||
· simp only [divSubtractShift, hm]
|
||||
split <;> rfl
|
||||
|
||||
/-- The output of `divRec` has no more bits left to process (i.e., `wn = 0`) -/
|
||||
@[simp]
|
||||
theorem wn_divRec (args : DivModArgs w) (qr : DivModState w) :
|
||||
(divRec qr.wn args qr).wn = 0 := by
|
||||
generalize hm : qr.wn = m
|
||||
induction m generalizing qr
|
||||
case zero =>
|
||||
assumption
|
||||
case succ wn' ih =>
|
||||
apply ih
|
||||
simp only [divSubtractShift, hm]
|
||||
split <;> rfl
|
||||
|
||||
/-- The result of `udiv` agrees with the result of the division recurrence. -/
|
||||
theorem udiv_eq_divRec (hd : 0#w < d) :
|
||||
let out := divRec w {n, d} (DivModState.init w)
|
||||
n.udiv d = out.q := by
|
||||
have := DivModState.lawful_init {n, d} hd
|
||||
have := lawful_divRec this
|
||||
apply DivModState.udiv_eq_of_lawful this (wn_divRec ..)
|
||||
|
||||
/-- The result of `umod` agrees with the result of the division recurrence. -/
|
||||
theorem umod_eq_divRec (hd : 0#w < d) :
|
||||
let out := divRec w {n, d} (DivModState.init w)
|
||||
n.umod d = out.r := by
|
||||
have := DivModState.lawful_init {n, d} hd
|
||||
have := lawful_divRec this
|
||||
apply DivModState.umod_eq_of_lawful this (wn_divRec ..)
|
||||
|
||||
theorem divRec_succ' (m : Nat) (args : DivModArgs w) (qr : DivModState w) :
|
||||
divRec (m+1) args qr =
|
||||
let wn := qr.wn - 1
|
||||
let wr := qr.wr + 1
|
||||
let r' := shiftConcat qr.r (args.n.getLsbD wn)
|
||||
let input : DivModState _ :=
|
||||
if r' < args.d then {
|
||||
q := qr.q.shiftConcat false,
|
||||
r := r'
|
||||
wn, wr
|
||||
} else {
|
||||
q := qr.q.shiftConcat true,
|
||||
r := r' - args.d
|
||||
wn, wr
|
||||
}
|
||||
divRec m args input := by
|
||||
simp [divRec_succ, divSubtractShift]
|
||||
|
||||
/- ### Arithmetic shift right (sshiftRight) recurrence -/
|
||||
|
||||
/--
|
||||
|
||||
@@ -165,8 +165,7 @@ theorem getMsbD_eq_getMsb?_getD (x : BitVec w) (i : Nat) :
|
||||
· simp [getMsb?, h]
|
||||
· rw [getLsbD_eq_getElem?_getD, getMsb?_eq_getLsb?]
|
||||
split <;>
|
||||
· simp only [getLsb?_eq_getElem?, Bool.and_iff_right_iff_imp, decide_eq_true_eq,
|
||||
Option.getD_none, Bool.and_eq_false_imp]
|
||||
· simp
|
||||
intros
|
||||
omega
|
||||
|
||||
@@ -304,7 +303,7 @@ theorem getElem?_zero_ofNat_one : (BitVec.ofNat (w+1) 1)[0]? = some true := by
|
||||
|
||||
-- This does not need to be a `@[simp]` theorem as it is already handled by `getElem?_eq_getElem`.
|
||||
theorem getElem?_zero_ofBool (b : Bool) : (ofBool b)[0]? = some b := by
|
||||
simp only [ofBool, ofNat_eq_ofNat, cond_eq_if]
|
||||
simp [ofBool, cond_eq_if]
|
||||
split <;> simp_all
|
||||
|
||||
@[simp] theorem getElem_zero_ofBool (b : Bool) : (ofBool b)[0] = b := by
|
||||
@@ -333,7 +332,7 @@ theorem getElem_ofBool {b : Bool} {i : Nat} : (ofBool b)[0] = b := by
|
||||
|
||||
theorem msb_eq_getLsbD_last (x : BitVec w) :
|
||||
x.msb = x.getLsbD (w - 1) := by
|
||||
simp only [BitVec.msb, getMsbD]
|
||||
simp [BitVec.msb, getMsbD, getLsbD]
|
||||
rcases w with rfl | w
|
||||
· simp [BitVec.eq_nil x]
|
||||
· simp
|
||||
@@ -361,7 +360,7 @@ theorem toNat_ge_of_msb_true {x : BitVec n} (p : BitVec.msb x = true) : x.toNat
|
||||
| 0 =>
|
||||
simp [BitVec.msb, BitVec.getMsbD] at p
|
||||
| n + 1 =>
|
||||
simp only [msb_eq_decide, Nat.add_one_sub_one, decide_eq_true_eq] at p
|
||||
simp [BitVec.msb_eq_decide] at p
|
||||
simp only [Nat.add_sub_cancel]
|
||||
exact p
|
||||
|
||||
@@ -421,7 +420,7 @@ theorem toInt_eq_toNat_bmod (x : BitVec n) : x.toInt = Int.bmod x.toNat (2^n) :=
|
||||
/-- Prove equality of bitvectors in terms of nat operations. -/
|
||||
theorem eq_of_toInt_eq {x y : BitVec n} : x.toInt = y.toInt → x = y := by
|
||||
intro eq
|
||||
simp only [toInt_eq_toNat_cond] at eq
|
||||
simp [toInt_eq_toNat_cond] at eq
|
||||
apply eq_of_toNat_eq
|
||||
revert eq
|
||||
have _xlt := x.isLt
|
||||
@@ -463,16 +462,6 @@ theorem toInt_pos_iff {w : Nat} {x : BitVec w} :
|
||||
0 ≤ BitVec.toInt x ↔ 2 * x.toNat < 2 ^ w := by
|
||||
simp [toInt_eq_toNat_cond]; omega
|
||||
|
||||
theorem eq_zero_or_eq_one (a : BitVec 1) : a = 0#1 ∨ a = 1#1 := by
|
||||
obtain ⟨a, ha⟩ := a
|
||||
simp only [Nat.reducePow]
|
||||
have acases : a = 0 ∨ a = 1 := by omega
|
||||
rcases acases with ⟨rfl | rfl⟩
|
||||
· simp
|
||||
· case inr h =>
|
||||
subst h
|
||||
simp
|
||||
|
||||
/-! ### setWidth, zeroExtend and truncate -/
|
||||
|
||||
@[simp]
|
||||
@@ -535,7 +524,6 @@ theorem getElem_setWidth' (x : BitVec w) (i : Nat) (h : w ≤ v) (hi : i < v) :
|
||||
(setWidth' h x)[i] = x.getLsbD i := by
|
||||
rw [getElem_eq_testBit_toNat, toNat_setWidth', getLsbD]
|
||||
|
||||
@[simp]
|
||||
theorem getElem_setWidth (m : Nat) (x : BitVec n) (i : Nat) (h : i < m) :
|
||||
(setWidth m x)[i] = x.getLsbD i := by
|
||||
rw [setWidth]
|
||||
@@ -912,8 +900,8 @@ theorem not_def {x : BitVec v} : ~~~x = allOnes v ^^^ x := rfl
|
||||
rw [← h]
|
||||
rw [Nat.testBit_two_pow_sub_succ (isLt _)]
|
||||
· cases w : decide (i < v)
|
||||
· simp only [decide_eq_false_iff_not, Nat.not_lt] at w
|
||||
simp only [Bool.false_bne, Bool.false_and]
|
||||
· simp at w
|
||||
simp [w]
|
||||
rw [Nat.testBit_lt_two_pow]
|
||||
calc BitVec.toNat x < 2 ^ v := isLt _
|
||||
_ ≤ 2 ^ i := Nat.pow_le_pow_of_le_right Nat.zero_lt_two w
|
||||
@@ -961,16 +949,6 @@ theorem not_not {b : BitVec w} : ~~~(~~~b) = b := by
|
||||
ext i
|
||||
simp
|
||||
|
||||
@[simp] theorem getMsb_not {x : BitVec w} :
|
||||
(~~~x).getMsbD i = (decide (i < w) && !(x.getMsbD i)) := by
|
||||
simp only [getMsbD]
|
||||
by_cases h : i < w
|
||||
· simp [h]; omega
|
||||
· simp [h];
|
||||
|
||||
@[simp] theorem msb_not {x : BitVec w} : (~~~x).msb = (decide (0 < w) && !x.msb) := by
|
||||
simp [BitVec.msb]
|
||||
|
||||
/-! ### cast -/
|
||||
|
||||
@[simp] theorem not_cast {x : BitVec w} (h : w = w') : ~~~(cast h x) = cast h (~~~x) := by
|
||||
@@ -1053,8 +1031,7 @@ theorem shiftLeft_or_distrib (x y : BitVec w) (n : Nat) :
|
||||
simp only [t]
|
||||
simp only [decide_True, Nat.sub_sub, Bool.true_and, Nat.add_assoc]
|
||||
by_cases h₁ : k < w <;> by_cases h₂ : w - (1 + k) < i <;> by_cases h₃ : k + i < w
|
||||
<;> simp only [h₁, h₂, h₃, decide_False, h₂, decide_True, Bool.not_true, Bool.false_and, Bool.and_self,
|
||||
Bool.true_and, Bool.false_eq, Bool.false_and, Bool.not_false]
|
||||
<;> simp [h₁, h₂, h₃]
|
||||
<;> (first | apply getLsbD_ge | apply Eq.symm; apply getLsbD_ge)
|
||||
<;> omega
|
||||
|
||||
@@ -1172,17 +1149,6 @@ theorem ushiftRight_or_distrib (x y : BitVec w) (n : Nat) :
|
||||
theorem ushiftRight_zero_eq (x : BitVec w) : x >>> 0 = x := by
|
||||
simp [bv_toNat]
|
||||
|
||||
/--
|
||||
Shifting right by `n < w` yields a bitvector whose value is less than `2 ^ (w - n)`.
|
||||
-/
|
||||
theorem toNat_ushiftRight_lt (x : BitVec w) (n : Nat) (hn : n ≤ w) :
|
||||
(x >>> n).toNat < 2 ^ (w - n) := by
|
||||
rw [toNat_ushiftRight, Nat.shiftRight_eq_div_pow, Nat.div_lt_iff_lt_mul]
|
||||
· rw [Nat.pow_sub_mul_pow]
|
||||
· apply x.isLt
|
||||
· apply hn
|
||||
· apply Nat.pow_pos (by decide)
|
||||
|
||||
/-! ### ushiftRight reductions from BitVec to Nat -/
|
||||
|
||||
@[simp]
|
||||
@@ -1316,22 +1282,6 @@ theorem sshiftRight_add {x : BitVec w} {m n : Nat} :
|
||||
omega
|
||||
· simp [h₃, sshiftRight_msb_eq_msb]
|
||||
|
||||
theorem not_sshiftRight {b : BitVec w} :
|
||||
~~~b.sshiftRight n = (~~~b).sshiftRight n := by
|
||||
ext i
|
||||
simp only [getLsbD_not, Fin.is_lt, decide_True, getLsbD_sshiftRight, Bool.not_and, Bool.not_not,
|
||||
Bool.true_and, msb_not]
|
||||
by_cases h : w ≤ i
|
||||
<;> by_cases h' : n + i < w
|
||||
<;> by_cases h'' : 0 < w
|
||||
<;> simp [h, h', h'']
|
||||
<;> omega
|
||||
|
||||
@[simp]
|
||||
theorem not_sshiftRight_not {x : BitVec w} {n : Nat} :
|
||||
~~~((~~~x).sshiftRight n) = x.sshiftRight n := by
|
||||
simp [not_sshiftRight]
|
||||
|
||||
/-! ### sshiftRight reductions from BitVec to Nat -/
|
||||
|
||||
@[simp]
|
||||
@@ -1362,69 +1312,6 @@ theorem umod_eq {x y : BitVec n} :
|
||||
theorem toNat_umod {x y : BitVec n} :
|
||||
(x.umod y).toNat = x.toNat % y.toNat := rfl
|
||||
|
||||
/-! ### sdiv -/
|
||||
|
||||
/-- Equation theorem for `sdiv` in terms of `udiv`. -/
|
||||
theorem sdiv_eq (x y : BitVec w) : x.sdiv y =
|
||||
match x.msb, y.msb with
|
||||
| false, false => udiv x y
|
||||
| false, true => - (x.udiv (- y))
|
||||
| true, false => - ((- x).udiv y)
|
||||
| true, true => (- x).udiv (- y) := by
|
||||
rw [BitVec.sdiv]
|
||||
rcases x.msb <;> rcases y.msb <;> simp
|
||||
|
||||
@[bv_toNat]
|
||||
theorem toNat_sdiv {x y : BitVec w} : (x.sdiv y).toNat =
|
||||
match x.msb, y.msb with
|
||||
| false, false => (udiv x y).toNat
|
||||
| false, true => (- (x.udiv (- y))).toNat
|
||||
| true, false => (- ((- x).udiv y)).toNat
|
||||
| true, true => ((- x).udiv (- y)).toNat := by
|
||||
simp only [sdiv_eq, toNat_udiv]
|
||||
by_cases h : x.msb <;> by_cases h' : y.msb <;> simp [h, h']
|
||||
|
||||
theorem sdiv_eq_and (x y : BitVec 1) : x.sdiv y = x &&& y := by
|
||||
have hx : x = 0#1 ∨ x = 1#1 := by bv_omega
|
||||
have hy : y = 0#1 ∨ y = 1#1 := by bv_omega
|
||||
rcases hx with rfl | rfl <;>
|
||||
rcases hy with rfl | rfl <;>
|
||||
rfl
|
||||
|
||||
/-! ### smod -/
|
||||
|
||||
/-- Equation theorem for `smod` in terms of `umod`. -/
|
||||
theorem smod_eq (x y : BitVec w) : x.smod y =
|
||||
match x.msb, y.msb with
|
||||
| false, false => x.umod y
|
||||
| false, true =>
|
||||
let u := x.umod (- y)
|
||||
(if u = 0#w then u else u + y)
|
||||
| true, false =>
|
||||
let u := umod (- x) y
|
||||
(if u = 0#w then u else y - u)
|
||||
| true, true => - ((- x).umod (- y)) := by
|
||||
rw [BitVec.smod]
|
||||
rcases x.msb <;> rcases y.msb <;> simp
|
||||
|
||||
@[bv_toNat]
|
||||
theorem toNat_smod {x y : BitVec w} : (x.smod y).toNat =
|
||||
match x.msb, y.msb with
|
||||
| false, false => (x.umod y).toNat
|
||||
| false, true =>
|
||||
let u := x.umod (- y)
|
||||
(if u = 0#w then u.toNat else (u + y).toNat)
|
||||
| true, false =>
|
||||
let u := (-x).umod y
|
||||
(if u = 0#w then u.toNat else (y - u).toNat)
|
||||
| true, true => (- ((- x).umod (- y))).toNat := by
|
||||
simp only [smod_eq, toNat_umod]
|
||||
by_cases h : x.msb <;> by_cases h' : y.msb
|
||||
<;> by_cases h'' : (-x).umod y = 0#w <;> by_cases h''' : x.umod (-y) = 0#w
|
||||
<;> simp only [h, h', h'', h''']
|
||||
<;> simp only [umod, toNat_eq, toNat_ofNatLt, toNat_ofNat, Nat.zero_mod] at h'' h'''
|
||||
<;> simp [h'', h''']
|
||||
|
||||
/-! ### signExtend -/
|
||||
|
||||
/-- Equation theorem for `Int.sub` when both arguments are `Int.ofNat` -/
|
||||
@@ -1509,18 +1396,18 @@ theorem getLsbD_append {x : BitVec n} {y : BitVec m} :
|
||||
simp only [append_def, getLsbD_or, getLsbD_shiftLeftZeroExtend, getLsbD_setWidth']
|
||||
by_cases h : i < m
|
||||
· simp [h]
|
||||
· simp_all [h]
|
||||
· simp [h]; simp_all
|
||||
|
||||
theorem getElem_append {x : BitVec n} {y : BitVec m} (h : i < n + m) :
|
||||
(x ++ y)[i] = bif i < m then getLsbD y i else getLsbD x (i - m) := by
|
||||
simp only [append_def, getElem_or, getElem_shiftLeftZeroExtend, getElem_setWidth']
|
||||
by_cases h' : i < m
|
||||
· simp [h']
|
||||
· simp_all [h']
|
||||
· simp [h']; simp_all
|
||||
|
||||
@[simp] theorem getMsbD_append {x : BitVec n} {y : BitVec m} :
|
||||
getMsbD (x ++ y) i = bif n ≤ i then getMsbD y (i - n) else getMsbD x i := by
|
||||
simp only [append_def]
|
||||
simp [append_def]
|
||||
by_cases h : n ≤ i
|
||||
· simp [h]
|
||||
· simp [h]
|
||||
@@ -1528,7 +1415,7 @@ theorem getElem_append {x : BitVec n} {y : BitVec m} (h : i < n + m) :
|
||||
theorem msb_append {x : BitVec w} {y : BitVec v} :
|
||||
(x ++ y).msb = bif (w == 0) then (y.msb) else (x.msb) := by
|
||||
rw [← append_eq, append]
|
||||
simp only [msb_or, msb_shiftLeftZeroExtend, msb_setWidth']
|
||||
simp [msb_setWidth']
|
||||
by_cases h : w = 0
|
||||
· subst h
|
||||
simp [BitVec.msb, getMsbD]
|
||||
@@ -1625,21 +1512,6 @@ theorem shiftRight_add {w : Nat} (x : BitVec w) (n m : Nat) :
|
||||
ext i
|
||||
simp [Nat.add_assoc n m i]
|
||||
|
||||
theorem shiftLeft_ushiftRight {x : BitVec w} {n : Nat}:
|
||||
x >>> n <<< n = x &&& BitVec.allOnes w <<< n := by
|
||||
induction n generalizing x
|
||||
case zero =>
|
||||
ext; simp
|
||||
case succ n ih =>
|
||||
rw [BitVec.shiftLeft_add, Nat.add_comm, BitVec.shiftRight_add, ih,
|
||||
Nat.add_comm, BitVec.shiftLeft_add, BitVec.shiftLeft_and_distrib]
|
||||
ext i
|
||||
by_cases hw : w = 0
|
||||
· simp [hw]
|
||||
· by_cases hi₂ : i.val = 0
|
||||
· simp [hi₂]
|
||||
· simp [Nat.lt_one_iff, hi₂, show 1 + (i.val - 1) = i by omega]
|
||||
|
||||
@[deprecated shiftRight_add (since := "2024-06-02")]
|
||||
theorem shiftRight_shiftRight {w : Nat} (x : BitVec w) (n m : Nat) :
|
||||
(x >>> n) >>> m = x >>> (n + m) := by
|
||||
@@ -1649,13 +1521,13 @@ theorem shiftRight_shiftRight {w : Nat} (x : BitVec w) (n m : Nat) :
|
||||
|
||||
theorem getLsbD_rev (x : BitVec w) (i : Fin w) :
|
||||
x.getLsbD i.rev = x.getMsbD i := by
|
||||
simp only [getLsbD, Fin.val_rev, getMsbD, Fin.is_lt, decide_True, Bool.true_and]
|
||||
simp [getLsbD, getMsbD]
|
||||
congr 1
|
||||
omega
|
||||
|
||||
theorem getElem_rev {x : BitVec w} {i : Fin w}:
|
||||
x[i.rev] = x.getMsbD i := by
|
||||
simp only [Fin.getElem_fin, Fin.val_rev, getMsbD, Fin.is_lt, decide_True, Bool.true_and]
|
||||
simp [getMsbD]
|
||||
congr 1
|
||||
omega
|
||||
|
||||
@@ -1680,13 +1552,13 @@ theorem toNat_cons' {x : BitVec w} :
|
||||
|
||||
theorem getLsbD_cons (b : Bool) {n} (x : BitVec n) (i : Nat) :
|
||||
getLsbD (cons b x) i = if i = n then b else getLsbD x i := by
|
||||
simp only [getLsbD, toNat_cons, Nat.testBit_or, Nat.testBit_shiftLeft, ge_iff_le]
|
||||
simp only [getLsbD, toNat_cons, Nat.testBit_or]
|
||||
rw [Nat.testBit_shiftLeft]
|
||||
rcases Nat.lt_trichotomy i n with i_lt_n | i_eq_n | n_lt_i
|
||||
· have p1 : ¬(n ≤ i) := by omega
|
||||
have p2 : i ≠ n := by omega
|
||||
simp [p1, p2]
|
||||
· simp only [i_eq_n, ge_iff_le, Nat.le_refl, decide_True, Nat.sub_self, Nat.testBit_zero,
|
||||
Bool.true_and, testBit_toNat, getLsbD_ge, Bool.or_false, ↓reduceIte]
|
||||
· simp [i_eq_n, testBit_toNat]
|
||||
cases b <;> trivial
|
||||
· have p1 : i ≠ n := by omega
|
||||
have p2 : i - n ≠ 0 := by omega
|
||||
@@ -1700,8 +1572,7 @@ theorem getElem_cons {b : Bool} {n} {x : BitVec n} {i : Nat} (h : i < n + 1) :
|
||||
· have p1 : ¬(n ≤ i) := by omega
|
||||
have p2 : i ≠ n := by omega
|
||||
simp [p1, p2]
|
||||
· simp only [i_eq_n, ge_iff_le, Nat.le_refl, decide_True, Nat.sub_self, Nat.testBit_zero,
|
||||
Bool.true_and, testBit_toNat, getLsbD_ge, Bool.or_false, ↓reduceIte]
|
||||
· simp [i_eq_n, testBit_toNat]
|
||||
cases b <;> trivial
|
||||
· have p1 : i ≠ n := by omega
|
||||
have p2 : i - n ≠ 0 := by omega
|
||||
@@ -1812,51 +1683,6 @@ theorem getElem_concat (x : BitVec w) (b : Bool) (i : Nat) (h : i < w + 1) :
|
||||
(concat x a) ^^^ (concat y b) = concat (x ^^^ y) (a ^^ b) := by
|
||||
ext i; cases i using Fin.succRecOn <;> simp
|
||||
|
||||
/-! ### shiftConcat -/
|
||||
|
||||
theorem getLsbD_shiftConcat (x : BitVec w) (b : Bool) (i : Nat) :
|
||||
(shiftConcat x b).getLsbD i
|
||||
= (decide (i < w) && (if (i = 0) then b else x.getLsbD (i - 1))) := by
|
||||
simp only [shiftConcat, getLsbD_setWidth, getLsbD_concat]
|
||||
|
||||
theorem getLsbD_shiftConcat_eq_decide (x : BitVec w) (b : Bool) (i : Nat) :
|
||||
(shiftConcat x b).getLsbD i
|
||||
= (decide (i < w) && ((decide (i = 0) && b) || (decide (0 < i) && x.getLsbD (i - 1)))) := by
|
||||
simp only [getLsbD_shiftConcat]
|
||||
split <;> simp [*, show ((0 < i) ↔ ¬(i = 0)) by omega]
|
||||
|
||||
theorem shiftRight_sub_one_eq_shiftConcat (n : BitVec w) (hwn : 0 < wn) :
|
||||
n >>> (wn - 1) = (n >>> wn).shiftConcat (n.getLsbD (wn - 1)) := by
|
||||
ext i
|
||||
simp only [getLsbD_ushiftRight, getLsbD_shiftConcat, Fin.is_lt, decide_True, Bool.true_and]
|
||||
split
|
||||
· simp [*]
|
||||
· congr 1; omega
|
||||
|
||||
@[simp, bv_toNat]
|
||||
theorem toNat_shiftConcat {x : BitVec w} {b : Bool} :
|
||||
(x.shiftConcat b).toNat
|
||||
= (x.toNat <<< 1 + b.toNat) % 2 ^ w := by
|
||||
simp [shiftConcat, Nat.shiftLeft_eq]
|
||||
|
||||
/-- `x.shiftConcat b` does not overflow if `x < 2^k` for `k < w`, and so
|
||||
`x.shiftConcat b |>.toNat = x.toNat * 2 + b.toNat`. -/
|
||||
theorem toNat_shiftConcat_eq_of_lt {x : BitVec w} {b : Bool} {k : Nat}
|
||||
(hk : k < w) (hx : x.toNat < 2 ^ k) :
|
||||
(x.shiftConcat b).toNat = x.toNat * 2 + b.toNat := by
|
||||
simp only [toNat_shiftConcat, Nat.shiftLeft_eq, Nat.pow_one]
|
||||
have : 2 ^ k < 2 ^ w := Nat.pow_lt_pow_of_lt (by omega) (by omega)
|
||||
have : 2 ^ k * 2 ≤ 2 ^ w := (Nat.pow_lt_pow_iff_pow_mul_le_pow (by omega)).mp this
|
||||
rw [Nat.mod_eq_of_lt (by cases b <;> simp [bv_toNat] <;> omega)]
|
||||
|
||||
theorem toNat_shiftConcat_lt_of_lt {x : BitVec w} {b : Bool} {k : Nat}
|
||||
(hk : k < w) (hx : x.toNat < 2 ^ k) :
|
||||
(x.shiftConcat b).toNat < 2 ^ (k + 1) := by
|
||||
rw [toNat_shiftConcat_eq_of_lt hk hx]
|
||||
have : 2 ^ (k + 1) ≤ 2 ^ w := Nat.pow_le_pow_of_le_right (by decide) (by assumption)
|
||||
have := Bool.toNat_lt b
|
||||
omega
|
||||
|
||||
@[simp] theorem zero_concat_false : concat 0#w false = 0#(w + 1) := by
|
||||
ext
|
||||
simp [getLsbD_concat]
|
||||
@@ -1911,20 +1737,6 @@ theorem ofInt_add {n} (x y : Int) : BitVec.ofInt n (x + y) =
|
||||
apply eq_of_toInt_eq
|
||||
simp
|
||||
|
||||
@[simp]
|
||||
theorem shiftLeft_add_distrib {x y : BitVec w} {n : Nat} :
|
||||
(x + y) <<< n = x <<< n + y <<< n := by
|
||||
induction n
|
||||
case zero =>
|
||||
simp
|
||||
case succ n ih =>
|
||||
simp [ih, toNat_eq, Nat.shiftLeft_eq, ← Nat.add_mul]
|
||||
|
||||
theorem add_eq_xor {a b : BitVec 1} : a + b = a ^^^ b := by
|
||||
have ha : a = 0 ∨ a = 1 := eq_zero_or_eq_one _
|
||||
have hb : b = 0 ∨ b = 1 := eq_zero_or_eq_one _
|
||||
rcases ha with h | h <;> (rcases hb with h' | h' <;> (simp [h, h']))
|
||||
|
||||
/-! ### sub/neg -/
|
||||
|
||||
theorem sub_def {n} (x y : BitVec n) : x - y = .ofNat n ((2^n - y.toNat) + x.toNat) := by rfl
|
||||
@@ -1971,7 +1783,7 @@ theorem toInt_neg {x : BitVec w} :
|
||||
Int.bmod_add_cancel]
|
||||
by_cases h : x.toNat < ((2 ^ w) + 1) / 2
|
||||
· rw [Int.bmod_pos (x := x.toNat)]
|
||||
all_goals simp only [toNat_mod_cancel']
|
||||
all_goals simp [toNat_mod_cancel', h]
|
||||
norm_cast
|
||||
· rw [Int.bmod_neg (x := x.toNat)]
|
||||
· simp only [toNat_mod_cancel']
|
||||
@@ -1985,7 +1797,7 @@ theorem toInt_neg {x : BitVec w} :
|
||||
|
||||
theorem sub_toAdd {n} (x y : BitVec n) : x - y = x + - y := by
|
||||
apply eq_of_toNat_eq
|
||||
simp only [toNat_sub, toNat_add, toNat_neg, Nat.add_mod_mod]
|
||||
simp
|
||||
rw [Nat.add_comm]
|
||||
|
||||
@[simp] theorem neg_zero (n:Nat) : -BitVec.ofNat n 0 = BitVec.ofNat n 0 := by apply eq_of_toNat_eq ; simp
|
||||
@@ -2034,22 +1846,6 @@ theorem neg_ne_iff_ne_neg {x y : BitVec w} : -x ≠ y ↔ x ≠ -y := by
|
||||
subst h'
|
||||
simp at h
|
||||
|
||||
theorem sub_eq_xor {a b : BitVec 1} : a - b = a ^^^ b := by
|
||||
have ha : a = 0 ∨ a = 1 := eq_zero_or_eq_one _
|
||||
have hb : b = 0 ∨ b = 1 := eq_zero_or_eq_one _
|
||||
rcases ha with h | h <;> (rcases hb with h' | h' <;> (simp [h, h']))
|
||||
|
||||
/-! ### abs -/
|
||||
|
||||
@[simp, bv_toNat]
|
||||
theorem toNat_abs {x : BitVec w} : x.abs.toNat = if x.msb then 2^w - x.toNat else x.toNat := by
|
||||
simp only [BitVec.abs, neg_eq]
|
||||
by_cases h : x.msb = true
|
||||
· simp only [h, ↓reduceIte, toNat_neg]
|
||||
have : 2 * x.toNat ≥ 2 ^ w := BitVec.msb_eq_true_iff_two_mul_ge.mp h
|
||||
rw [Nat.mod_eq_of_lt (by omega)]
|
||||
· simp [h]
|
||||
|
||||
/-! ### mul -/
|
||||
|
||||
theorem mul_def {n} {x y : BitVec n} : x * y = (ofFin <| x.toFin * y.toFin) := by rfl
|
||||
@@ -2106,11 +1902,6 @@ theorem ofInt_mul {n} (x y : Int) : BitVec.ofInt n (x * y) =
|
||||
apply eq_of_toInt_eq
|
||||
simp
|
||||
|
||||
theorem mul_eq_and {a b : BitVec 1} : a * b = a &&& b := by
|
||||
have ha : a = 0 ∨ a = 1 := eq_zero_or_eq_one _
|
||||
have hb : b = 0 ∨ b = 1 := eq_zero_or_eq_one _
|
||||
rcases ha with h | h <;> (rcases hb with h' | h' <;> (simp [h, h']))
|
||||
|
||||
/-! ### le and lt -/
|
||||
|
||||
@[bv_toNat] theorem le_def {x y : BitVec n} :
|
||||
@@ -2177,10 +1968,6 @@ protected theorem umod_lt (x : BitVec n) {y : BitVec n} : 0 < y → x.umod y < y
|
||||
simp only [ofNat_eq_ofNat, lt_def, toNat_ofNat, Nat.zero_mod, umod, toNat_ofNatLt]
|
||||
apply Nat.mod_lt
|
||||
|
||||
theorem not_lt_iff_le {x y : BitVec w} : (¬ x < y) ↔ y ≤ x := by
|
||||
constructor <;>
|
||||
(intro h; simp only [lt_def, Nat.not_lt, le_def] at h ⊢; omega)
|
||||
|
||||
/-! ### ofBoolList -/
|
||||
|
||||
@[simp] theorem getMsbD_ofBoolListBE : (ofBoolListBE bs).getMsbD i = bs.getD i false := by
|
||||
@@ -2286,12 +2073,6 @@ theorem getLsbD_rotateLeft {x : BitVec w} {r i : Nat} :
|
||||
· simp
|
||||
· rw [← rotateLeft_mod_eq_rotateLeft, getLsbD_rotateLeft_of_le (Nat.mod_lt _ (by omega))]
|
||||
|
||||
@[simp]
|
||||
theorem getElem_rotateLeft {x : BitVec w} {r i : Nat} (h : i < w) :
|
||||
(x.rotateLeft r)[i] =
|
||||
if h' : i < r % w then x[(w - (r % w) + i)] else x[i - (r % w)] := by
|
||||
simp [← BitVec.getLsbD_eq_getElem, h]
|
||||
|
||||
/-! ## Rotate Right -/
|
||||
|
||||
/--
|
||||
@@ -2373,12 +2154,6 @@ theorem getLsbD_rotateRight {x : BitVec w} {r i : Nat} :
|
||||
· simp
|
||||
· rw [← rotateRight_mod_eq_rotateRight, getLsbD_rotateRight_of_le (Nat.mod_lt _ (by omega))]
|
||||
|
||||
@[simp]
|
||||
theorem getElem_rotateRight {x : BitVec w} {r i : Nat} (h : i < w) :
|
||||
(x.rotateRight r)[i] = if h' : i < w - (r % w) then x[(r % w) + i] else x[(i - (w - (r % w)))] := by
|
||||
simp only [← BitVec.getLsbD_eq_getElem]
|
||||
simp [getLsbD_rotateRight, h]
|
||||
|
||||
/- ## twoPow -/
|
||||
|
||||
@[simp, bv_toNat]
|
||||
@@ -2407,12 +2182,6 @@ theorem getLsbD_twoPow (i j : Nat) : (twoPow w i).getLsbD j = ((i < w) && (i = j
|
||||
simp at hi
|
||||
simp_all
|
||||
|
||||
@[simp]
|
||||
theorem getElem_twoPow {i j : Nat} (h : j < w) : (twoPow w i)[j] = decide (j = i) := by
|
||||
rw [←getLsbD_eq_getElem, getLsbD_twoPow]
|
||||
simp [eq_comm]
|
||||
omega
|
||||
|
||||
theorem and_twoPow (x : BitVec w) (i : Nat) :
|
||||
x &&& (twoPow w i) = if x.getLsbD i then twoPow w i else 0#w := by
|
||||
ext j
|
||||
@@ -2444,17 +2213,6 @@ theorem twoPow_zero {w : Nat} : twoPow w 0 = 1#w := by
|
||||
theorem getLsbD_one {w i : Nat} : (1#w).getLsbD i = (decide (0 < w) && decide (0 = i)) := by
|
||||
rw [← twoPow_zero, getLsbD_twoPow]
|
||||
|
||||
@[simp]
|
||||
theorem getElem_one {w i : Nat} (h : i < w) : (1#w)[i] = decide (i = 0) := by
|
||||
rw [← twoPow_zero, getElem_twoPow]
|
||||
|
||||
theorem shiftLeft_eq_mul_twoPow (x : BitVec w) (n : Nat) :
|
||||
x <<< n = x * (BitVec.twoPow w n) := by
|
||||
ext i
|
||||
simp [getLsbD_shiftLeft, Fin.is_lt, decide_True, Bool.true_and, mul_twoPow_eq_shiftLeft]
|
||||
|
||||
/- ### cons -/
|
||||
|
||||
@[simp] theorem true_cons_zero : cons true 0#w = twoPow (w + 1) w := by
|
||||
ext
|
||||
simp [getLsbD_cons]
|
||||
@@ -2552,12 +2310,6 @@ theorem getLsbD_replicate {n w : Nat} (x : BitVec w) :
|
||||
simp only [show ¬i < w * n by omega, decide_False, cond_false, hi, Bool.false_and]
|
||||
apply BitVec.getLsbD_ge (x := x) (i := i - w * n) (ge := by omega)
|
||||
|
||||
@[simp]
|
||||
theorem getElem_replicate {n w : Nat} (x : BitVec w) (h : i < w * n) :
|
||||
(x.replicate n)[i] = if h' : w = 0 then false else x[i % w]'(@Nat.mod_lt i w (by omega)) := by
|
||||
simp only [← getLsbD_eq_getElem, getLsbD_replicate]
|
||||
by_cases h' : w = 0 <;> simp [h'] <;> omega
|
||||
|
||||
/-! ### intMin -/
|
||||
|
||||
/-- The bitvector of width `w` that has the smallest value when interpreted as an integer. -/
|
||||
|
||||
@@ -368,14 +368,13 @@ theorem and_or_inj_left_iff :
|
||||
/-- convert a `Bool` to a `Nat`, `false -> 0`, `true -> 1` -/
|
||||
def toNat (b : Bool) : Nat := cond b 1 0
|
||||
|
||||
@[simp, bv_toNat] theorem toNat_false : false.toNat = 0 := rfl
|
||||
@[simp] theorem toNat_false : false.toNat = 0 := rfl
|
||||
|
||||
@[simp, bv_toNat] theorem toNat_true : true.toNat = 1 := rfl
|
||||
@[simp] theorem toNat_true : true.toNat = 1 := rfl
|
||||
|
||||
theorem toNat_le (c : Bool) : c.toNat ≤ 1 := by
|
||||
cases c <;> trivial
|
||||
|
||||
@[bv_toNat]
|
||||
theorem toNat_lt (b : Bool) : b.toNat < 2 :=
|
||||
Nat.lt_succ_of_le (toNat_le _)
|
||||
|
||||
|
||||
@@ -245,7 +245,7 @@ On an invalid position, returns `(default : UInt8)`. -/
|
||||
@[inline]
|
||||
def curr : Iterator → UInt8
|
||||
| ⟨arr, i⟩ =>
|
||||
if h : i < arr.size then
|
||||
if h:i < arr.size then
|
||||
arr[i]'h
|
||||
else
|
||||
default
|
||||
|
||||
@@ -582,8 +582,8 @@ theorem rev_succ (k : Fin n) : rev (succ k) = castSucc (rev k) := k.rev_addNat 1
|
||||
@[simp] theorem coe_pred (j : Fin (n + 1)) (h : j ≠ 0) : (j.pred h : Nat) = j - 1 := rfl
|
||||
|
||||
@[simp] theorem succ_pred : ∀ (i : Fin (n + 1)) (h : i ≠ 0), (i.pred h).succ = i
|
||||
| ⟨0, _⟩, hi => by simp only [mk_zero, ne_eq, not_true] at hi
|
||||
| ⟨_ + 1, _⟩, _ => rfl
|
||||
| ⟨0, h⟩, hi => by simp only [mk_zero, ne_eq, not_true] at hi
|
||||
| ⟨n + 1, h⟩, hi => rfl
|
||||
|
||||
@[simp]
|
||||
theorem pred_succ (i : Fin n) {h : i.succ ≠ 0} : i.succ.pred h = i := by
|
||||
|
||||
@@ -72,35 +72,21 @@ instance floatDecLt (a b : Float) : Decidable (a < b) := Float.decLt a b
|
||||
instance floatDecLe (a b : Float) : Decidable (a ≤ b) := Float.decLe a b
|
||||
|
||||
@[extern "lean_float_to_string"] opaque Float.toString : Float → String
|
||||
/-- If the given float is non-negative, truncates the value to the nearest non-negative integer.
|
||||
If negative or NaN, returns `0`.
|
||||
If larger than the maximum value for `UInt8` (including Inf), returns the maximum value of `UInt8`
|
||||
(i.e. `UInt8.size - 1`).
|
||||
-/
|
||||
|
||||
/-- If the given float is positive, truncates the value to the nearest positive integer.
|
||||
If negative or larger than the maximum value for UInt8, returns 0. -/
|
||||
@[extern "lean_float_to_uint8"] opaque Float.toUInt8 : Float → UInt8
|
||||
/-- If the given float is non-negative, truncates the value to the nearest non-negative integer.
|
||||
If negative or NaN, returns `0`.
|
||||
If larger than the maximum value for `UInt16` (including Inf), returns the maximum value of `UInt16`
|
||||
(i.e. `UInt16.size - 1`).
|
||||
-/
|
||||
/-- If the given float is positive, truncates the value to the nearest positive integer.
|
||||
If negative or larger than the maximum value for UInt16, returns 0. -/
|
||||
@[extern "lean_float_to_uint16"] opaque Float.toUInt16 : Float → UInt16
|
||||
/-- If the given float is non-negative, truncates the value to the nearest non-negative integer.
|
||||
If negative or NaN, returns `0`.
|
||||
If larger than the maximum value for `UInt32` (including Inf), returns the maximum value of `UInt32`
|
||||
(i.e. `UInt32.size - 1`).
|
||||
-/
|
||||
/-- If the given float is positive, truncates the value to the nearest positive integer.
|
||||
If negative or larger than the maximum value for UInt32, returns 0. -/
|
||||
@[extern "lean_float_to_uint32"] opaque Float.toUInt32 : Float → UInt32
|
||||
/-- If the given float is non-negative, truncates the value to the nearest non-negative integer.
|
||||
If negative or NaN, returns `0`.
|
||||
If larger than the maximum value for `UInt64` (including Inf), returns the maximum value of `UInt64`
|
||||
(i.e. `UInt64.size - 1`).
|
||||
-/
|
||||
/-- If the given float is positive, truncates the value to the nearest positive integer.
|
||||
If negative or larger than the maximum value for UInt64, returns 0. -/
|
||||
@[extern "lean_float_to_uint64"] opaque Float.toUInt64 : Float → UInt64
|
||||
/-- If the given float is non-negative, truncates the value to the nearest non-negative integer.
|
||||
If negative or NaN, returns `0`.
|
||||
If larger than the maximum value for `USize` (including Inf), returns the maximum value of `USize`
|
||||
(i.e. `USize.size - 1`). This value is platform dependent).
|
||||
-/
|
||||
/-- If the given float is positive, truncates the value to the nearest positive integer.
|
||||
If negative or larger than the maximum value for USize, returns 0. -/
|
||||
@[extern "lean_float_to_usize"] opaque Float.toUSize : Float → USize
|
||||
|
||||
@[extern "lean_float_isnan"] opaque Float.isNaN : Float → Bool
|
||||
|
||||
@@ -253,7 +253,7 @@ theorem tmod_def (a b : Int) : tmod a b = a - b * a.tdiv b := by
|
||||
|
||||
theorem fmod_add_fdiv : ∀ a b : Int, a.fmod b + b * a.fdiv b = a
|
||||
| 0, ofNat _ | 0, -[_+1] => congrArg ofNat <| by simp
|
||||
| succ _, ofNat _ => congrArg ofNat <| Nat.mod_add_div ..
|
||||
| succ m, ofNat n => congrArg ofNat <| Nat.mod_add_div ..
|
||||
| succ m, -[n+1] => by
|
||||
show subNatNat (m % succ n) n + (↑(succ n * (m / succ n)) + n + 1) = (m + 1)
|
||||
rw [Int.add_comm _ n, ← Int.add_assoc, ← Int.add_assoc,
|
||||
@@ -289,8 +289,8 @@ theorem fmod_eq_tmod {a b : Int} (Ha : 0 ≤ a) (Hb : 0 ≤ b) : fmod a b = tmod
|
||||
|
||||
@[simp] protected theorem ediv_neg : ∀ a b : Int, a / (-b) = -(a / b)
|
||||
| ofNat m, 0 => show ofNat (m / 0) = -↑(m / 0) by rw [Nat.div_zero]; rfl
|
||||
| ofNat _, -[_+1] => (Int.neg_neg _).symm
|
||||
| ofNat _, succ _ | -[_+1], 0 | -[_+1], succ _ | -[_+1], -[_+1] => rfl
|
||||
| ofNat m, -[n+1] => (Int.neg_neg _).symm
|
||||
| ofNat m, succ n | -[m+1], 0 | -[m+1], succ n | -[m+1], -[n+1] => rfl
|
||||
|
||||
theorem ediv_neg' {a b : Int} (Ha : a < 0) (Hb : 0 < b) : a / b < 0 :=
|
||||
match a, b, eq_negSucc_of_lt_zero Ha, eq_succ_of_zero_lt Hb with
|
||||
@@ -339,7 +339,7 @@ theorem add_mul_ediv_right (a b : Int) {c : Int} (H : c ≠ 0) : (a + b * c) / c
|
||||
| _, ⟨k, rfl⟩, -[n+1] => show (a - n.succ * k.succ).ediv k.succ = a.ediv k.succ - n.succ by
|
||||
rw [← Int.add_sub_cancel (ediv ..), ← this, Int.sub_add_cancel]
|
||||
fun {k n} => @fun
|
||||
| ofNat _ => congrArg ofNat <| Nat.add_mul_div_right _ _ k.succ_pos
|
||||
| ofNat m => congrArg ofNat <| Nat.add_mul_div_right _ _ k.succ_pos
|
||||
| -[m+1] => by
|
||||
show ((n * k.succ : Nat) - m.succ : Int).ediv k.succ = n - (m / k.succ + 1 : Nat)
|
||||
by_cases h : m < n * k.succ
|
||||
@@ -396,7 +396,7 @@ theorem add_mul_ediv_left (a : Int) {b : Int}
|
||||
rw [Int.mul_neg, Int.ediv_neg, Int.ediv_neg]; apply congrArg Neg.neg; apply this
|
||||
fun m k b =>
|
||||
match b, k with
|
||||
| ofNat _, _ => congrArg ofNat (Nat.mul_div_mul_left _ _ m.succ_pos)
|
||||
| ofNat n, k => congrArg ofNat (Nat.mul_div_mul_left _ _ m.succ_pos)
|
||||
| -[n+1], 0 => by
|
||||
rw [Int.ofNat_zero, Int.mul_zero, Int.ediv_zero, Int.ediv_zero]
|
||||
| -[n+1], succ k => congrArg negSucc <|
|
||||
@@ -822,14 +822,14 @@ theorem ediv_eq_ediv_of_mul_eq_mul {a b c d : Int}
|
||||
unseal Nat.div in
|
||||
@[simp] protected theorem tdiv_neg : ∀ a b : Int, a.tdiv (-b) = -(a.tdiv b)
|
||||
| ofNat m, 0 => show ofNat (m / 0) = -↑(m / 0) by rw [Nat.div_zero]; rfl
|
||||
| ofNat _, -[_+1] | -[_+1], succ _ => (Int.neg_neg _).symm
|
||||
| ofNat _, succ _ | -[_+1], 0 | -[_+1], -[_+1] => rfl
|
||||
| ofNat m, -[n+1] | -[m+1], succ n => (Int.neg_neg _).symm
|
||||
| ofNat m, succ n | -[m+1], 0 | -[m+1], -[n+1] => rfl
|
||||
|
||||
unseal Nat.div in
|
||||
@[simp] protected theorem neg_tdiv : ∀ a b : Int, (-a).tdiv b = -(a.tdiv b)
|
||||
| 0, n => by simp [Int.neg_zero]
|
||||
| succ _, (n:Nat) | -[_+1], 0 | -[_+1], -[_+1] => rfl
|
||||
| succ _, -[_+1] | -[_+1], succ _ => (Int.neg_neg _).symm
|
||||
| succ m, (n:Nat) | -[m+1], 0 | -[m+1], -[n+1] => rfl
|
||||
| succ m, -[n+1] | -[m+1], succ n => (Int.neg_neg _).symm
|
||||
|
||||
protected theorem neg_tdiv_neg (a b : Int) : (-a).tdiv (-b) = a.tdiv b := by
|
||||
simp [Int.tdiv_neg, Int.neg_tdiv, Int.neg_neg]
|
||||
|
||||
@@ -181,12 +181,12 @@ theorem subNatNat_add_negSucc (m n k : Nat) :
|
||||
Nat.add_comm]
|
||||
|
||||
protected theorem add_assoc : ∀ a b c : Int, a + b + c = a + (b + c)
|
||||
| (m:Nat), (n:Nat), _ => aux1 ..
|
||||
| (m:Nat), (n:Nat), c => aux1 ..
|
||||
| Nat.cast m, b, Nat.cast k => by
|
||||
rw [Int.add_comm, ← aux1, Int.add_comm k, aux1, Int.add_comm b]
|
||||
| a, (n:Nat), (k:Nat) => by
|
||||
rw [Int.add_comm, Int.add_comm a, ← aux1, Int.add_comm a, Int.add_comm k]
|
||||
| -[_+1], -[_+1], (k:Nat) => aux2 ..
|
||||
| -[m+1], -[n+1], (k:Nat) => aux2 ..
|
||||
| -[m+1], (n:Nat), -[k+1] => by
|
||||
rw [Int.add_comm, ← aux2, Int.add_comm n, ← aux2, Int.add_comm -[m+1]]
|
||||
| (m:Nat), -[n+1], -[k+1] => by
|
||||
|
||||
@@ -512,8 +512,8 @@ theorem toNat_add_nat {a : Int} (ha : 0 ≤ a) (n : Nat) : (a + n).toNat = a.toN
|
||||
|
||||
@[simp] theorem pred_toNat : ∀ i : Int, (i - 1).toNat = i.toNat - 1
|
||||
| 0 => rfl
|
||||
| (_+1:Nat) => by simp [ofNat_add]
|
||||
| -[_+1] => rfl
|
||||
| (n+1:Nat) => by simp [ofNat_add]
|
||||
| -[n+1] => rfl
|
||||
|
||||
theorem toNat_sub_toNat_neg : ∀ n : Int, ↑n.toNat - ↑(-n).toNat = n
|
||||
| 0 => rfl
|
||||
|
||||
@@ -73,7 +73,7 @@ theorem map_pmap {p : α → Prop} (g : β → γ) (f : ∀ a, p a → β) (l H)
|
||||
· simp only [*, pmap, map]
|
||||
|
||||
theorem pmap_map {p : β → Prop} (g : ∀ b, p b → γ) (f : α → β) (l H) :
|
||||
pmap g (map f l) H = pmap (fun a h => g (f a) h) l fun _ h => H _ (mem_map_of_mem _ h) := by
|
||||
pmap g (map f l) H = pmap (fun a h => g (f a) h) l fun a h => H _ (mem_map_of_mem _ h) := by
|
||||
induction l
|
||||
· rfl
|
||||
· simp only [*, pmap, map]
|
||||
@@ -84,7 +84,7 @@ theorem attach_congr {l₁ l₂ : List α} (h : l₁ = l₂) :
|
||||
simp
|
||||
|
||||
theorem attachWith_congr {l₁ l₂ : List α} (w : l₁ = l₂) {P : α → Prop} {H : ∀ x ∈ l₁, P x} :
|
||||
l₁.attachWith P H = l₂.attachWith P fun _ h => H _ (w ▸ h) := by
|
||||
l₁.attachWith P H = l₂.attachWith P fun x h => H _ (w ▸ h) := by
|
||||
subst w
|
||||
simp
|
||||
|
||||
@@ -353,7 +353,7 @@ theorem attach_map {l : List α} (f : α → β) :
|
||||
induction l <;> simp [*]
|
||||
|
||||
theorem attachWith_map {l : List α} (f : α → β) {P : β → Prop} {H : ∀ (b : β), b ∈ l.map f → P b} :
|
||||
(l.map f).attachWith P H = (l.attachWith (P ∘ f) (fun _ h => H _ (mem_map_of_mem f h))).map
|
||||
(l.map f).attachWith P H = (l.attachWith (P ∘ f) (fun a h => H _ (mem_map_of_mem f h))).map
|
||||
fun ⟨x, h⟩ => ⟨f x, h⟩ := by
|
||||
induction l <;> simp [*]
|
||||
|
||||
@@ -548,131 +548,12 @@ theorem count_attachWith [DecidableEq α] {p : α → Prop} (l : List α) (H :
|
||||
(l.attachWith p H).count a = l.count ↑a :=
|
||||
Eq.trans (countP_congr fun _ _ => by simp [Subtype.ext_iff]) <| countP_attachWith _ _ _
|
||||
|
||||
/-! ## unattach
|
||||
@[simp] theorem map_attach_comp_subtype_val {l : List α} :
|
||||
l.attach.map (f ∘ Subtype.val) = l.map f := by
|
||||
simp [map_attach]
|
||||
|
||||
`List.unattach` is the (one-sided) inverse of `List.attach`. It is a synonym for `List.map Subtype.val`.
|
||||
|
||||
We use it by providing a simp lemma `l.attach.unattach = l`, and simp lemmas which recognize higher order
|
||||
functions applied to `l : List { x // p x }` which only depend on the value, not the predicate, and rewrite these
|
||||
in terms of a simpler function applied to `l.unattach`.
|
||||
|
||||
Further, we provide simp lemmas that push `unattach` inwards.
|
||||
-/
|
||||
|
||||
/--
|
||||
A synonym for `l.map (·.val)`. Mostly this should not be needed by users.
|
||||
It is introduced as an intermediate step by lemmas such as `map_subtype`,
|
||||
and is ideally subsequently simplified away by `unattach_attach`.
|
||||
|
||||
If not, usually the right approach is `simp [List.unattach, -List.map_subtype]` to unfold.
|
||||
-/
|
||||
def unattach {α : Type _} {p : α → Prop} (l : List { x // p x }) := l.map (·.val)
|
||||
|
||||
@[simp] theorem unattach_nil {α : Type _} {p : α → Prop} : ([] : List { x // p x }).unattach = [] := rfl
|
||||
@[simp] theorem unattach_cons {α : Type _} {p : α → Prop} {a : { x // p x }} {l : List { x // p x }} :
|
||||
(a :: l).unattach = a.val :: l.unattach := rfl
|
||||
|
||||
@[simp] theorem length_unattach {α : Type _} {p : α → Prop} {l : List { x // p x }} :
|
||||
l.unattach.length = l.length := by
|
||||
unfold unattach
|
||||
simp
|
||||
|
||||
@[simp] theorem unattach_attach {α : Type _} (l : List α) : l.attach.unattach = l := by
|
||||
unfold unattach
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, Function.comp_def]
|
||||
|
||||
@[simp] theorem unattach_attachWith {α : Type _} {p : α → Prop} {l : List α}
|
||||
{H : ∀ a ∈ l, p a} :
|
||||
(l.attachWith p H).unattach = l := by
|
||||
unfold unattach
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, Function.comp_def]
|
||||
|
||||
/-! ### Recognizing higher order functions on subtypes using a function that only depends on the value. -/
|
||||
|
||||
/--
|
||||
This lemma identifies folds over lists of subtypes, where the function only depends on the value, not the proposition,
|
||||
and simplifies these to the function directly taking the value.
|
||||
-/
|
||||
@[simp] theorem foldl_subtype {p : α → Prop} {l : List { x // p x }}
|
||||
{f : β → { x // p x } → β} {g : β → α → β} {x : β}
|
||||
{hf : ∀ b x h, f b ⟨x, h⟩ = g b x} :
|
||||
l.foldl f x = l.unattach.foldl g x := by
|
||||
unfold unattach
|
||||
induction l generalizing x with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, hf]
|
||||
|
||||
/--
|
||||
This lemma identifies folds over lists of subtypes, where the function only depends on the value, not the proposition,
|
||||
and simplifies these to the function directly taking the value.
|
||||
-/
|
||||
@[simp] theorem foldr_subtype {p : α → Prop} {l : List { x // p x }}
|
||||
{f : { x // p x } → β → β} {g : α → β → β} {x : β}
|
||||
{hf : ∀ x h b, f ⟨x, h⟩ b = g x b} :
|
||||
l.foldr f x = l.unattach.foldr g x := by
|
||||
unfold unattach
|
||||
induction l generalizing x with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, hf]
|
||||
|
||||
/--
|
||||
This lemma identifies maps over lists of subtypes, where the function only depends on the value, not the proposition,
|
||||
and simplifies these to the function directly taking the value.
|
||||
-/
|
||||
@[simp] theorem map_subtype {p : α → Prop} {l : List { x // p x }}
|
||||
{f : { x // p x } → β} {g : α → β} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
l.map f = l.unattach.map g := by
|
||||
unfold unattach
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, hf]
|
||||
|
||||
@[simp] theorem filterMap_subtype {p : α → Prop} {l : List { x // p x }}
|
||||
{f : { x // p x } → Option β} {g : α → Option β} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
l.filterMap f = l.unattach.filterMap g := by
|
||||
unfold unattach
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, hf, filterMap_cons]
|
||||
|
||||
@[simp] theorem bind_subtype {p : α → Prop} {l : List { x // p x }}
|
||||
{f : { x // p x } → List β} {g : α → List β} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
(l.bind f) = l.unattach.bind g := by
|
||||
unfold unattach
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a l ih => simp [ih, hf]
|
||||
|
||||
@[simp] theorem unattach_filter {p : α → Prop} {l : List { x // p x }}
|
||||
{f : { x // p x } → Bool} {g : α → Bool} {hf : ∀ x h, f ⟨x, h⟩ = g x} :
|
||||
(l.filter f).unattach = l.unattach.filter g := by
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a l ih =>
|
||||
simp only [filter_cons, hf, unattach_cons]
|
||||
split <;> simp [ih]
|
||||
|
||||
/-! ### Simp lemmas pushing `unattach` inwards. -/
|
||||
|
||||
@[simp] theorem unattach_reverse {p : α → Prop} {l : List { x // p x }} :
|
||||
l.reverse.unattach = l.unattach.reverse := by
|
||||
simp [unattach, -map_subtype]
|
||||
|
||||
@[simp] theorem unattach_append {p : α → Prop} {l₁ l₂ : List { x // p x }} :
|
||||
(l₁ ++ l₂).unattach = l₁.unattach ++ l₂.unattach := by
|
||||
simp [unattach, -map_subtype]
|
||||
|
||||
@[simp] theorem unattach_join {p : α → Prop} {l : List (List { x // p x })} :
|
||||
l.join.unattach = (l.map unattach).join := by
|
||||
unfold unattach
|
||||
induction l <;> simp_all
|
||||
|
||||
@[simp] theorem unattach_replicate {p : α → Prop} {n : Nat} {x : { x // p x }} :
|
||||
(List.replicate n x).unattach = List.replicate n x.1 := by
|
||||
simp [unattach, -map_subtype]
|
||||
@[simp] theorem map_attachWith_comp_subtype_val {l : List α} {P : α → Prop} {H} :
|
||||
(l.attachWith P H).map (f ∘ Subtype.val) = l.map f := by
|
||||
simp [map_attachWith]
|
||||
|
||||
end List
|
||||
|
||||
@@ -43,7 +43,7 @@ The operations are organized as follow:
|
||||
* Logic: `any`, `all`, `or`, and `and`.
|
||||
* Zippers: `zipWith`, `zip`, `zipWithAll`, and `unzip`.
|
||||
* Ranges and enumeration: `range`, `iota`, `enumFrom`, and `enum`.
|
||||
* Minima and maxima: `min?` and `max?`.
|
||||
* Minima and maxima: `minimum?` and `maximum?`.
|
||||
* Other functions: `intersperse`, `intercalate`, `eraseDups`, `eraseReps`, `span`, `groupBy`,
|
||||
`removeAll`
|
||||
(currently these functions are mostly only used in meta code,
|
||||
@@ -218,8 +218,8 @@ def get? : (as : List α) → (i : Nat) → Option α
|
||||
|
||||
theorem ext_get? : ∀ {l₁ l₂ : List α}, (∀ n, l₁.get? n = l₂.get? n) → l₁ = l₂
|
||||
| [], [], _ => rfl
|
||||
| _ :: _, [], h => nomatch h 0
|
||||
| [], _ :: _, h => nomatch h 0
|
||||
| a :: l₁, [], h => nomatch h 0
|
||||
| [], a' :: l₂, h => nomatch h 0
|
||||
| a :: l₁, a' :: l₂, h => by
|
||||
have h0 : some a = some a' := h 0
|
||||
injection h0 with aa; simp only [aa, ext_get? fun n => h (n+1)]
|
||||
@@ -1464,34 +1464,30 @@ def enum : List α → List (Nat × α) := enumFrom 0
|
||||
|
||||
/-! ## Minima and maxima -/
|
||||
|
||||
/-! ### min? -/
|
||||
/-! ### minimum? -/
|
||||
|
||||
/--
|
||||
Returns the smallest element of the list, if it is not empty.
|
||||
* `[].min? = none`
|
||||
* `[4].min? = some 4`
|
||||
* `[1, 4, 2, 10, 6].min? = some 1`
|
||||
* `[].minimum? = none`
|
||||
* `[4].minimum? = some 4`
|
||||
* `[1, 4, 2, 10, 6].minimum? = some 1`
|
||||
-/
|
||||
def min? [Min α] : List α → Option α
|
||||
def minimum? [Min α] : List α → Option α
|
||||
| [] => none
|
||||
| a::as => some <| as.foldl min a
|
||||
|
||||
@[inherit_doc min?, deprecated min? (since := "2024-09-29")] abbrev minimum? := @min?
|
||||
|
||||
/-! ### max? -/
|
||||
/-! ### maximum? -/
|
||||
|
||||
/--
|
||||
Returns the largest element of the list, if it is not empty.
|
||||
* `[].max? = none`
|
||||
* `[4].max? = some 4`
|
||||
* `[1, 4, 2, 10, 6].max? = some 10`
|
||||
* `[].maximum? = none`
|
||||
* `[4].maximum? = some 4`
|
||||
* `[1, 4, 2, 10, 6].maximum? = some 10`
|
||||
-/
|
||||
def max? [Max α] : List α → Option α
|
||||
def maximum? [Max α] : List α → Option α
|
||||
| [] => none
|
||||
| a::as => some <| as.foldl max a
|
||||
|
||||
@[inherit_doc max?, deprecated max? (since := "2024-09-29")] abbrev maximum? := @max?
|
||||
|
||||
/-! ## Other list operations
|
||||
|
||||
The functions are currently mostly used in meta code,
|
||||
|
||||
@@ -235,8 +235,8 @@ theorem sizeOf_get [SizeOf α] (as : List α) (i : Fin as.length) : sizeOf (as.g
|
||||
theorem le_antisymm [LT α] [s : Antisymm (¬ · < · : α → α → Prop)] {as bs : List α} (h₁ : as ≤ bs) (h₂ : bs ≤ as) : as = bs :=
|
||||
match as, bs with
|
||||
| [], [] => rfl
|
||||
| [], _::_ => False.elim <| h₂ (List.lt.nil ..)
|
||||
| _::_, [] => False.elim <| h₁ (List.lt.nil ..)
|
||||
| [], b::bs => False.elim <| h₂ (List.lt.nil ..)
|
||||
| a::as, [] => False.elim <| h₁ (List.lt.nil ..)
|
||||
| a::as, b::bs => by
|
||||
by_cases hab : a < b
|
||||
· exact False.elim <| h₂ (List.lt.head _ _ hab)
|
||||
|
||||
@@ -52,9 +52,9 @@ theorem eraseP_of_forall_not {l : List α} (h : ∀ a, a ∈ l → ¬p a) : l.er
|
||||
theorem eraseP_ne_nil {xs : List α} {p : α → Bool} : xs.eraseP p ≠ [] ↔ xs ≠ [] ∧ ∀ x, p x → xs ≠ [x] := by
|
||||
simp
|
||||
|
||||
theorem exists_of_eraseP : ∀ {l : List α} {a} (_ : a ∈ l) (_ : p a),
|
||||
theorem exists_of_eraseP : ∀ {l : List α} {a} (al : a ∈ l) (pa : p a),
|
||||
∃ a l₁ l₂, (∀ b ∈ l₁, ¬p b) ∧ p a ∧ l = l₁ ++ a :: l₂ ∧ l.eraseP p = l₁ ++ l₂
|
||||
| b :: l, _, al, pa =>
|
||||
| b :: l, a, al, pa =>
|
||||
if pb : p b then
|
||||
⟨b, [], l, forall_mem_nil _, pb, by simp [pb]⟩
|
||||
else
|
||||
@@ -168,8 +168,8 @@ theorem eraseP_append_left {a : α} (pa : p a) :
|
||||
|
||||
theorem eraseP_append_right :
|
||||
∀ {l₁ : List α} l₂, (∀ b ∈ l₁, ¬p b) → eraseP p (l₁++l₂) = l₁ ++ l₂.eraseP p
|
||||
| [], _, _ => rfl
|
||||
| _ :: _, _, h => by
|
||||
| [], l₂, _ => rfl
|
||||
| x :: xs, l₂, h => by
|
||||
simp [(forall_mem_cons.1 h).1, eraseP_append_right _ (forall_mem_cons.1 h).2]
|
||||
|
||||
theorem eraseP_append (l₁ l₂ : List α) :
|
||||
|
||||
@@ -31,7 +31,7 @@ The following operations are still missing `@[csimp]` replacements:
|
||||
The following operations are not recursive to begin with
|
||||
(or are defined in terms of recursive primitives):
|
||||
`isEmpty`, `isSuffixOf`, `isSuffixOf?`, `rotateLeft`, `rotateRight`, `insert`, `zip`, `enum`,
|
||||
`min?`, `max?`, and `removeAll`.
|
||||
`minimum?`, `maximum?`, and `removeAll`.
|
||||
|
||||
The following operations were already given `@[csimp]` replacements in `Init/Data/List/Basic.lean`:
|
||||
`length`, `map`, `filter`, `replicate`, `leftPad`, `unzip`, `range'`, `iota`, `intersperse`.
|
||||
|
||||
@@ -55,7 +55,7 @@ See also
|
||||
* `Init.Data.List.Erase` for lemmas about `List.eraseP` and `List.erase`.
|
||||
* `Init.Data.List.Find` for lemmas about `List.find?`, `List.findSome?`, `List.findIdx`,
|
||||
`List.findIdx?`, and `List.indexOf`
|
||||
* `Init.Data.List.MinMax` for lemmas about `List.min?` and `List.max?`.
|
||||
* `Init.Data.List.MinMax` for lemmas about `List.minimum?` and `List.maximum?`.
|
||||
* `Init.Data.List.Pairwise` for lemmas about `List.Pairwise` and `List.Nodup`.
|
||||
* `Init.Data.List.Sublist` for lemmas about `List.Subset`, `List.Sublist`, `List.IsPrefix`,
|
||||
`List.IsSuffix`, and `List.IsInfix`.
|
||||
@@ -191,7 +191,7 @@ theorem get?_eq_some : l.get? n = some a ↔ ∃ h, get l ⟨n, h⟩ = a :=
|
||||
⟨fun e =>
|
||||
have : n < length l := Nat.gt_of_not_le fun hn => by cases get?_len_le hn ▸ e
|
||||
⟨this, by rwa [get?_eq_get this, Option.some.injEq] at e⟩,
|
||||
fun ⟨_, e⟩ => e ▸ get?_eq_get _⟩
|
||||
fun ⟨h, e⟩ => e ▸ get?_eq_get _⟩
|
||||
|
||||
theorem get?_eq_none : l.get? n = none ↔ length l ≤ n :=
|
||||
⟨fun e => Nat.ge_of_not_lt (fun h' => by cases e ▸ get?_eq_some.2 ⟨h', rfl⟩), get?_len_le⟩
|
||||
@@ -203,9 +203,6 @@ theorem get?_eq_none : l.get? n = none ↔ length l ≤ n :=
|
||||
|
||||
@[simp] theorem get_eq_getElem (l : List α) (i : Fin l.length) : l.get i = l[i.1]'i.2 := rfl
|
||||
|
||||
theorem getElem?_eq_some {l : List α} : l[i]? = some a ↔ ∃ h : i < l.length, l[i]'h = a := by
|
||||
simpa using get?_eq_some
|
||||
|
||||
/--
|
||||
If one has `l.get i` in an expression (with `i : Fin l.length`) and `h : l = l'`,
|
||||
`rw [h]` will give a "motive it not type correct" error, as it cannot rewrite the
|
||||
@@ -492,7 +489,7 @@ theorem getElem?_of_mem {a} {l : List α} (h : a ∈ l) : ∃ n : Nat, l[n]? = s
|
||||
theorem get?_of_mem {a} {l : List α} (h : a ∈ l) : ∃ n, l.get? n = some a :=
|
||||
let ⟨⟨n, _⟩, e⟩ := get_of_mem h; ⟨n, e ▸ get?_eq_get _⟩
|
||||
|
||||
@[simp] theorem getElem_mem : ∀ {l : List α} {n} (h : n < l.length), l[n]'h ∈ l
|
||||
theorem getElem_mem : ∀ {l : List α} {n} (h : n < l.length), l[n]'h ∈ l
|
||||
| _ :: _, 0, _ => .head ..
|
||||
| _ :: l, _+1, _ => .tail _ (getElem_mem (l := l) ..)
|
||||
|
||||
@@ -718,9 +715,9 @@ theorem set_eq_of_length_le {l : List α} {n : Nat} (h : l.length ≤ n) {a : α
|
||||
theorem set_comm (a b : α) : ∀ {n m : Nat} (l : List α), n ≠ m →
|
||||
(l.set n a).set m b = (l.set m b).set n a
|
||||
| _, _, [], _ => by simp
|
||||
| _+1, 0, _ :: _, _ => by simp [set]
|
||||
| 0, _+1, _ :: _, _ => by simp [set]
|
||||
| _+1, _+1, _ :: t, h =>
|
||||
| n+1, 0, _ :: _, _ => by simp [set]
|
||||
| 0, m+1, _ :: _, _ => by simp [set]
|
||||
| n+1, m+1, x :: t, h =>
|
||||
congrArg _ <| set_comm a b t fun h' => h <| Nat.succ_inj'.mpr h'
|
||||
|
||||
@[simp]
|
||||
@@ -881,20 +878,6 @@ theorem foldr_map' {α β : Type u} (g : α → β) (f : α → α → α) (f' :
|
||||
· simp
|
||||
· simp [*, h]
|
||||
|
||||
theorem foldl_assoc {op : α → α → α} [ha : Std.Associative op] :
|
||||
∀ {l : List α} {a₁ a₂}, l.foldl op (op a₁ a₂) = op a₁ (l.foldl op a₂)
|
||||
| [], a₁, a₂ => rfl
|
||||
| a :: l, a₁, a₂ => by
|
||||
simp only [foldl_cons, ha.assoc]
|
||||
rw [foldl_assoc]
|
||||
|
||||
theorem foldr_assoc {op : α → α → α} [ha : Std.Associative op] :
|
||||
∀ {l : List α} {a₁ a₂}, l.foldr op (op a₁ a₂) = op (l.foldr op a₁) a₂
|
||||
| [], a₁, a₂ => rfl
|
||||
| a :: l, a₁, a₂ => by
|
||||
simp only [foldr_cons, ha.assoc]
|
||||
rw [foldr_assoc]
|
||||
|
||||
theorem foldl_hom (f : α₁ → α₂) (g₁ : α₁ → β → α₁) (g₂ : α₂ → β → α₂) (l : List β) (init : α₁)
|
||||
(H : ∀ x y, g₂ (f x) y = f (g₁ x y)) : l.foldl g₂ (f init) = f (l.foldl g₁ init) := by
|
||||
induction l generalizing init <;> simp [*, H]
|
||||
@@ -994,8 +977,8 @@ theorem getLast_eq_getElem : ∀ (l : List α) (h : l ≠ []),
|
||||
match l with
|
||||
| [] => contradiction
|
||||
| a :: l => exact Nat.le_refl _)
|
||||
| [_], _ => rfl
|
||||
| _ :: _ :: _, _ => by
|
||||
| [a], h => rfl
|
||||
| a :: b :: l, h => by
|
||||
simp [getLast, get, Nat.succ_sub_succ, getLast_eq_getElem]
|
||||
|
||||
@[deprecated getLast_eq_getElem (since := "2024-07-15")]
|
||||
@@ -1021,14 +1004,14 @@ theorem getLast_eq_getLastD (a l h) : @getLast α (a::l) h = getLastD l a := by
|
||||
theorem getLast!_cons [Inhabited α] : @getLast! α _ (a::l) = getLastD l a := by
|
||||
simp [getLast!, getLast_eq_getLastD]
|
||||
|
||||
@[simp] theorem getLast_mem : ∀ {l : List α} (h : l ≠ []), getLast l h ∈ l
|
||||
theorem getLast_mem : ∀ {l : List α} (h : l ≠ []), getLast l h ∈ l
|
||||
| [], h => absurd rfl h
|
||||
| [_], _ => .head ..
|
||||
| _::a::l, _ => .tail _ <| getLast_mem (cons_ne_nil a l)
|
||||
|
||||
theorem getLast_mem_getLast? : ∀ {l : List α} (h : l ≠ []), getLast l h ∈ getLast? l
|
||||
| [], h => by contradiction
|
||||
| _ :: _, _ => rfl
|
||||
| a :: l, _ => rfl
|
||||
|
||||
theorem getLastD_mem_cons : ∀ (l : List α) (a : α), getLastD l a ∈ a::l
|
||||
| [], _ => .head ..
|
||||
@@ -1119,7 +1102,7 @@ theorem head?_eq_some_iff {xs : List α} {a : α} : xs.head? = some a ↔ ∃ ys
|
||||
@[simp] theorem head?_isSome : l.head?.isSome ↔ l ≠ [] := by
|
||||
cases l <;> simp
|
||||
|
||||
@[simp] theorem head_mem : ∀ {l : List α} (h : l ≠ []), head l h ∈ l
|
||||
theorem head_mem : ∀ {l : List α} (h : l ≠ []), head l h ∈ l
|
||||
| [], h => absurd rfl h
|
||||
| _::_, _ => .head ..
|
||||
|
||||
@@ -1134,7 +1117,7 @@ theorem mem_of_mem_head? : ∀ {l : List α} {a : α}, a ∈ l.head? → a ∈ l
|
||||
|
||||
theorem head_mem_head? : ∀ {l : List α} (h : l ≠ []), head l h ∈ head? l
|
||||
| [], h => by contradiction
|
||||
| _ :: _, _ => rfl
|
||||
| a :: l, _ => rfl
|
||||
|
||||
theorem head?_concat {a : α} : (l ++ [a]).head? = l.head?.getD a := by
|
||||
cases l <;> simp
|
||||
@@ -1466,7 +1449,7 @@ theorem map_filter_eq_foldr (f : α → β) (p : α → Bool) (as : List α) :
|
||||
|
||||
@[simp] theorem filter_append {p : α → Bool} :
|
||||
∀ (l₁ l₂ : List α), filter p (l₁ ++ l₂) = filter p l₁ ++ filter p l₂
|
||||
| [], _ => rfl
|
||||
| [], l₂ => rfl
|
||||
| a :: l₁, l₂ => by simp [filter]; split <;> simp [filter_append l₁]
|
||||
|
||||
theorem filter_eq_cons_iff {l} {a} {as} :
|
||||
@@ -1690,7 +1673,7 @@ theorem getElem?_append_left {l₁ l₂ : List α} {n : Nat} (hn : n < l₁.leng
|
||||
|
||||
theorem getElem?_append_right : ∀ {l₁ l₂ : List α} {n : Nat}, l₁.length ≤ n →
|
||||
(l₁ ++ l₂)[n]? = l₂[n - l₁.length]?
|
||||
| [], _, _, _ => rfl
|
||||
| [], _, n, _ => rfl
|
||||
| a :: l, _, n+1, h₁ => by
|
||||
rw [cons_append]
|
||||
simp [Nat.succ_sub_succ_eq_sub, getElem?_append_right (Nat.lt_succ.1 h₁)]
|
||||
@@ -1755,8 +1738,8 @@ theorem append_of_mem {a : α} {l : List α} : a ∈ l → ∃ s t : List α, l
|
||||
|
||||
theorem append_inj :
|
||||
∀ {s₁ s₂ t₁ t₂ : List α}, s₁ ++ t₁ = s₂ ++ t₂ → length s₁ = length s₂ → s₁ = s₂ ∧ t₁ = t₂
|
||||
| [], [], _, _, h, _ => ⟨rfl, h⟩
|
||||
| _ :: _, _ :: _, _, _, h, hl => by
|
||||
| [], [], t₁, t₂, h, _ => ⟨rfl, h⟩
|
||||
| a :: s₁, b :: s₂, t₁, t₂, h, hl => by
|
||||
simp [append_inj (cons.inj h).2 (Nat.succ.inj hl)] at h ⊢; exact h
|
||||
|
||||
theorem append_inj_right (h : s₁ ++ t₁ = s₂ ++ t₂) (hl : length s₁ = length s₂) : t₁ = t₂ :=
|
||||
@@ -2409,10 +2392,6 @@ theorem map_eq_replicate_iff {l : List α} {f : α → β} {b : β} :
|
||||
@[simp] theorem map_const (l : List α) (b : β) : map (Function.const α b) l = replicate l.length b :=
|
||||
map_eq_replicate_iff.mpr fun _ _ => rfl
|
||||
|
||||
@[simp] theorem map_const_fun (x : β) : map (Function.const α x) = (replicate ·.length x) := by
|
||||
funext l
|
||||
simp
|
||||
|
||||
/-- Variant of `map_const` using a lambda rather than `Function.const`. -/
|
||||
-- This can not be a `@[simp]` lemma because it would fire on every `List.map`.
|
||||
theorem map_const' (l : List α) (b : β) : map (fun _ => b) l = replicate l.length b :=
|
||||
@@ -2707,7 +2686,7 @@ theorem bind_reverse {β} (l : List α) (f : α → List β) : (l.reverse.bind f
|
||||
@[simp] theorem reverse_replicate (n) (a : α) : reverse (replicate n a) = replicate n a :=
|
||||
eq_replicate_iff.2
|
||||
⟨by rw [length_reverse, length_replicate],
|
||||
fun _ h => eq_of_mem_replicate (mem_reverse.1 h)⟩
|
||||
fun b h => eq_of_mem_replicate (mem_reverse.1 h)⟩
|
||||
|
||||
/-! #### Further results about `getLast` and `getLast?` -/
|
||||
|
||||
@@ -2912,7 +2891,7 @@ theorem head?_dropLast (xs : List α) : xs.dropLast.head? = if 1 < xs.length the
|
||||
|
||||
theorem getLast_dropLast {xs : List α} (h) :
|
||||
xs.dropLast.getLast h =
|
||||
xs[xs.length - 2]'(match xs, h with | (_ :: _ :: _), _ => Nat.lt_trans (Nat.lt_add_one _) (Nat.lt_add_one _)) := by
|
||||
xs[xs.length - 2]'(match xs, h with | (a :: b :: xs), _ => Nat.lt_trans (Nat.lt_add_one _) (Nat.lt_add_one _)) := by
|
||||
rw [getLast_eq_getElem, getElem_dropLast]
|
||||
congr 1
|
||||
simp; rfl
|
||||
@@ -2936,8 +2915,8 @@ theorem dropLast_cons_of_ne_nil {α : Type u} {x : α}
|
||||
|
||||
theorem dropLast_concat_getLast : ∀ {l : List α} (h : l ≠ []), dropLast l ++ [getLast l h] = l
|
||||
| [], h => absurd rfl h
|
||||
| [_], _ => rfl
|
||||
| _ :: b :: l, _ => by
|
||||
| [a], h => rfl
|
||||
| a :: b :: l, h => by
|
||||
rw [dropLast_cons₂, cons_append, getLast_cons (cons_ne_nil _ _)]
|
||||
congr
|
||||
exact dropLast_concat_getLast (cons_ne_nil b l)
|
||||
|
||||
@@ -7,7 +7,7 @@ prelude
|
||||
import Init.Data.List.Lemmas
|
||||
|
||||
/-!
|
||||
# Lemmas about `List.min?` and `List.max?.
|
||||
# Lemmas about `List.minimum?` and `List.maximum?.
|
||||
-/
|
||||
|
||||
namespace List
|
||||
@@ -16,24 +16,24 @@ open Nat
|
||||
|
||||
/-! ## Minima and maxima -/
|
||||
|
||||
/-! ### min? -/
|
||||
/-! ### minimum? -/
|
||||
|
||||
@[simp] theorem min?_nil [Min α] : ([] : List α).min? = none := rfl
|
||||
@[simp] theorem minimum?_nil [Min α] : ([] : List α).minimum? = none := rfl
|
||||
|
||||
-- We don't put `@[simp]` on `min?_cons`,
|
||||
-- We don't put `@[simp]` on `minimum?_cons`,
|
||||
-- because the definition in terms of `foldl` is not useful for proofs.
|
||||
theorem min?_cons [Min α] {xs : List α} : (x :: xs).min? = foldl min x xs := rfl
|
||||
theorem minimum?_cons [Min α] {xs : List α} : (x :: xs).minimum? = foldl min x xs := rfl
|
||||
|
||||
@[simp] theorem min?_eq_none_iff {xs : List α} [Min α] : xs.min? = none ↔ xs = [] := by
|
||||
cases xs <;> simp [min?]
|
||||
@[simp] theorem minimum?_eq_none_iff {xs : List α} [Min α] : xs.minimum? = none ↔ xs = [] := by
|
||||
cases xs <;> simp [minimum?]
|
||||
|
||||
theorem min?_mem [Min α] (min_eq_or : ∀ a b : α, min a b = a ∨ min a b = b) :
|
||||
{xs : List α} → xs.min? = some a → a ∈ xs := by
|
||||
theorem minimum?_mem [Min α] (min_eq_or : ∀ a b : α, min a b = a ∨ min a b = b) :
|
||||
{xs : List α} → xs.minimum? = some a → a ∈ xs := by
|
||||
intro xs
|
||||
match xs with
|
||||
| nil => simp
|
||||
| x :: xs =>
|
||||
simp only [min?_cons, Option.some.injEq, List.mem_cons]
|
||||
simp only [minimum?_cons, Option.some.injEq, List.mem_cons]
|
||||
intro eq
|
||||
induction xs generalizing x with
|
||||
| nil =>
|
||||
@@ -49,12 +49,12 @@ theorem min?_mem [Min α] (min_eq_or : ∀ a b : α, min a b = a ∨ min a b = b
|
||||
|
||||
-- See also `Init.Data.List.Nat.Basic` for specialisations of the next two results to `Nat`.
|
||||
|
||||
theorem le_min?_iff [Min α] [LE α]
|
||||
theorem le_minimum?_iff [Min α] [LE α]
|
||||
(le_min_iff : ∀ a b c : α, a ≤ min b c ↔ a ≤ b ∧ a ≤ c) :
|
||||
{xs : List α} → xs.min? = some a → ∀ {x}, x ≤ a ↔ ∀ b, b ∈ xs → x ≤ b
|
||||
{xs : List α} → xs.minimum? = some a → ∀ {x}, x ≤ a ↔ ∀ b, b ∈ xs → x ≤ b
|
||||
| nil => by simp
|
||||
| cons x xs => by
|
||||
rw [min?]
|
||||
rw [minimum?]
|
||||
intro eq y
|
||||
simp only [Option.some.injEq] at eq
|
||||
induction xs generalizing x with
|
||||
@@ -67,46 +67,46 @@ theorem le_min?_iff [Min α] [LE α]
|
||||
|
||||
-- This could be refactored by designing appropriate typeclasses to replace `le_refl`, `min_eq_or`,
|
||||
-- and `le_min_iff`.
|
||||
theorem min?_eq_some_iff [Min α] [LE α] [anti : Antisymm ((· : α) ≤ ·)]
|
||||
theorem minimum?_eq_some_iff [Min α] [LE α] [anti : Antisymm ((· : α) ≤ ·)]
|
||||
(le_refl : ∀ a : α, a ≤ a)
|
||||
(min_eq_or : ∀ a b : α, min a b = a ∨ min a b = b)
|
||||
(le_min_iff : ∀ a b c : α, a ≤ min b c ↔ a ≤ b ∧ a ≤ c) {xs : List α} :
|
||||
xs.min? = some a ↔ a ∈ xs ∧ ∀ b, b ∈ xs → a ≤ b := by
|
||||
refine ⟨fun h => ⟨min?_mem min_eq_or h, (le_min?_iff le_min_iff h).1 (le_refl _)⟩, ?_⟩
|
||||
xs.minimum? = some a ↔ a ∈ xs ∧ ∀ b, b ∈ xs → a ≤ b := by
|
||||
refine ⟨fun h => ⟨minimum?_mem min_eq_or h, (le_minimum?_iff le_min_iff h).1 (le_refl _)⟩, ?_⟩
|
||||
intro ⟨h₁, h₂⟩
|
||||
cases xs with
|
||||
| nil => simp at h₁
|
||||
| cons x xs =>
|
||||
exact congrArg some <| anti.1
|
||||
((le_min?_iff le_min_iff (xs := x::xs) rfl).1 (le_refl _) _ h₁)
|
||||
(h₂ _ (min?_mem min_eq_or (xs := x::xs) rfl))
|
||||
((le_minimum?_iff le_min_iff (xs := x::xs) rfl).1 (le_refl _) _ h₁)
|
||||
(h₂ _ (minimum?_mem min_eq_or (xs := x::xs) rfl))
|
||||
|
||||
theorem min?_replicate [Min α] {n : Nat} {a : α} (w : min a a = a) :
|
||||
(replicate n a).min? = if n = 0 then none else some a := by
|
||||
theorem minimum?_replicate [Min α] {n : Nat} {a : α} (w : min a a = a) :
|
||||
(replicate n a).minimum? = if n = 0 then none else some a := by
|
||||
induction n with
|
||||
| zero => rfl
|
||||
| succ n ih => cases n <;> simp_all [replicate_succ, min?_cons]
|
||||
| succ n ih => cases n <;> simp_all [replicate_succ, minimum?_cons]
|
||||
|
||||
@[simp] theorem min?_replicate_of_pos [Min α] {n : Nat} {a : α} (w : min a a = a) (h : 0 < n) :
|
||||
(replicate n a).min? = some a := by
|
||||
simp [min?_replicate, Nat.ne_of_gt h, w]
|
||||
@[simp] theorem minimum?_replicate_of_pos [Min α] {n : Nat} {a : α} (w : min a a = a) (h : 0 < n) :
|
||||
(replicate n a).minimum? = some a := by
|
||||
simp [minimum?_replicate, Nat.ne_of_gt h, w]
|
||||
|
||||
/-! ### max? -/
|
||||
/-! ### maximum? -/
|
||||
|
||||
@[simp] theorem max?_nil [Max α] : ([] : List α).max? = none := rfl
|
||||
@[simp] theorem maximum?_nil [Max α] : ([] : List α).maximum? = none := rfl
|
||||
|
||||
-- We don't put `@[simp]` on `max?_cons`,
|
||||
-- We don't put `@[simp]` on `maximum?_cons`,
|
||||
-- because the definition in terms of `foldl` is not useful for proofs.
|
||||
theorem max?_cons [Max α] {xs : List α} : (x :: xs).max? = foldl max x xs := rfl
|
||||
theorem maximum?_cons [Max α] {xs : List α} : (x :: xs).maximum? = foldl max x xs := rfl
|
||||
|
||||
@[simp] theorem max?_eq_none_iff {xs : List α} [Max α] : xs.max? = none ↔ xs = [] := by
|
||||
cases xs <;> simp [max?]
|
||||
@[simp] theorem maximum?_eq_none_iff {xs : List α} [Max α] : xs.maximum? = none ↔ xs = [] := by
|
||||
cases xs <;> simp [maximum?]
|
||||
|
||||
theorem max?_mem [Max α] (min_eq_or : ∀ a b : α, max a b = a ∨ max a b = b) :
|
||||
{xs : List α} → xs.max? = some a → a ∈ xs
|
||||
theorem maximum?_mem [Max α] (min_eq_or : ∀ a b : α, max a b = a ∨ max a b = b) :
|
||||
{xs : List α} → xs.maximum? = some a → a ∈ xs
|
||||
| nil => by simp
|
||||
| cons x xs => by
|
||||
rw [max?]; rintro ⟨⟩
|
||||
rw [maximum?]; rintro ⟨⟩
|
||||
induction xs generalizing x with simp at *
|
||||
| cons y xs ih =>
|
||||
rcases ih (max x y) with h | h <;> simp [h]
|
||||
@@ -114,57 +114,40 @@ theorem max?_mem [Max α] (min_eq_or : ∀ a b : α, max a b = a ∨ max a b = b
|
||||
|
||||
-- See also `Init.Data.List.Nat.Basic` for specialisations of the next two results to `Nat`.
|
||||
|
||||
theorem max?_le_iff [Max α] [LE α]
|
||||
theorem maximum?_le_iff [Max α] [LE α]
|
||||
(max_le_iff : ∀ a b c : α, max b c ≤ a ↔ b ≤ a ∧ c ≤ a) :
|
||||
{xs : List α} → xs.max? = some a → ∀ {x}, a ≤ x ↔ ∀ b ∈ xs, b ≤ x
|
||||
{xs : List α} → xs.maximum? = some a → ∀ {x}, a ≤ x ↔ ∀ b ∈ xs, b ≤ x
|
||||
| nil => by simp
|
||||
| cons x xs => by
|
||||
rw [max?]; rintro ⟨⟩ y
|
||||
rw [maximum?]; rintro ⟨⟩ y
|
||||
induction xs generalizing x with
|
||||
| nil => simp
|
||||
| cons y xs ih => simp [ih, max_le_iff, and_assoc]
|
||||
|
||||
-- This could be refactored by designing appropriate typeclasses to replace `le_refl`, `max_eq_or`,
|
||||
-- and `le_min_iff`.
|
||||
theorem max?_eq_some_iff [Max α] [LE α] [anti : Antisymm ((· : α) ≤ ·)]
|
||||
theorem maximum?_eq_some_iff [Max α] [LE α] [anti : Antisymm ((· : α) ≤ ·)]
|
||||
(le_refl : ∀ a : α, a ≤ a)
|
||||
(max_eq_or : ∀ a b : α, max a b = a ∨ max a b = b)
|
||||
(max_le_iff : ∀ a b c : α, max b c ≤ a ↔ b ≤ a ∧ c ≤ a) {xs : List α} :
|
||||
xs.max? = some a ↔ a ∈ xs ∧ ∀ b ∈ xs, b ≤ a := by
|
||||
refine ⟨fun h => ⟨max?_mem max_eq_or h, (max?_le_iff max_le_iff h).1 (le_refl _)⟩, ?_⟩
|
||||
xs.maximum? = some a ↔ a ∈ xs ∧ ∀ b ∈ xs, b ≤ a := by
|
||||
refine ⟨fun h => ⟨maximum?_mem max_eq_or h, (maximum?_le_iff max_le_iff h).1 (le_refl _)⟩, ?_⟩
|
||||
intro ⟨h₁, h₂⟩
|
||||
cases xs with
|
||||
| nil => simp at h₁
|
||||
| cons x xs =>
|
||||
exact congrArg some <| anti.1
|
||||
(h₂ _ (max?_mem max_eq_or (xs := x::xs) rfl))
|
||||
((max?_le_iff max_le_iff (xs := x::xs) rfl).1 (le_refl _) _ h₁)
|
||||
(h₂ _ (maximum?_mem max_eq_or (xs := x::xs) rfl))
|
||||
((maximum?_le_iff max_le_iff (xs := x::xs) rfl).1 (le_refl _) _ h₁)
|
||||
|
||||
theorem max?_replicate [Max α] {n : Nat} {a : α} (w : max a a = a) :
|
||||
(replicate n a).max? = if n = 0 then none else some a := by
|
||||
theorem maximum?_replicate [Max α] {n : Nat} {a : α} (w : max a a = a) :
|
||||
(replicate n a).maximum? = if n = 0 then none else some a := by
|
||||
induction n with
|
||||
| zero => rfl
|
||||
| succ n ih => cases n <;> simp_all [replicate_succ, max?_cons]
|
||||
| succ n ih => cases n <;> simp_all [replicate_succ, maximum?_cons]
|
||||
|
||||
@[simp] theorem max?_replicate_of_pos [Max α] {n : Nat} {a : α} (w : max a a = a) (h : 0 < n) :
|
||||
(replicate n a).max? = some a := by
|
||||
simp [max?_replicate, Nat.ne_of_gt h, w]
|
||||
|
||||
@[deprecated min?_nil (since := "2024-09-29")] abbrev minimum?_nil := @min?_nil
|
||||
@[deprecated min?_cons (since := "2024-09-29")] abbrev minimum?_cons := @min?_cons
|
||||
@[deprecated min?_eq_none_iff (since := "2024-09-29")] abbrev mininmum?_eq_none_iff := @min?_eq_none_iff
|
||||
@[deprecated min?_mem (since := "2024-09-29")] abbrev minimum?_mem := @min?_mem
|
||||
@[deprecated le_min?_iff (since := "2024-09-29")] abbrev le_minimum?_iff := @le_min?_iff
|
||||
@[deprecated min?_eq_some_iff (since := "2024-09-29")] abbrev minimum?_eq_some_iff := @min?_eq_some_iff
|
||||
@[deprecated min?_replicate (since := "2024-09-29")] abbrev minimum?_replicate := @min?_replicate
|
||||
@[deprecated min?_replicate_of_pos (since := "2024-09-29")] abbrev minimum?_replicate_of_pos := @min?_replicate_of_pos
|
||||
@[deprecated max?_nil (since := "2024-09-29")] abbrev maximum?_nil := @max?_nil
|
||||
@[deprecated max?_cons (since := "2024-09-29")] abbrev maximum?_cons := @max?_cons
|
||||
@[deprecated max?_eq_none_iff (since := "2024-09-29")] abbrev maximum?_eq_none_iff := @max?_eq_none_iff
|
||||
@[deprecated max?_mem (since := "2024-09-29")] abbrev maximum?_mem := @max?_mem
|
||||
@[deprecated max?_le_iff (since := "2024-09-29")] abbrev maximum?_le_iff := @max?_le_iff
|
||||
@[deprecated max?_eq_some_iff (since := "2024-09-29")] abbrev maximum?_eq_some_iff := @max?_eq_some_iff
|
||||
@[deprecated max?_replicate (since := "2024-09-29")] abbrev maximum?_replicate := @max?_replicate
|
||||
@[deprecated max?_replicate_of_pos (since := "2024-09-29")] abbrev maximum?_replicate_of_pos := @max?_replicate_of_pos
|
||||
@[simp] theorem maximum?_replicate_of_pos [Max α] {n : Nat} {a : α} (w : max a a = a) (h : 0 < n) :
|
||||
(replicate n a).maximum? = some a := by
|
||||
simp [maximum?_replicate, Nat.ne_of_gt h, w]
|
||||
|
||||
end List
|
||||
|
||||
@@ -51,27 +51,6 @@ theorem mapM'_eq_mapM [Monad m] [LawfulMonad m] (f : α → m β) (l : List α)
|
||||
@[simp] theorem mapM_append [Monad m] [LawfulMonad m] (f : α → m β) {l₁ l₂ : List α} :
|
||||
(l₁ ++ l₂).mapM f = (return (← l₁.mapM f) ++ (← l₂.mapM f)) := by induction l₁ <;> simp [*]
|
||||
|
||||
/-- Auxiliary lemma for `mapM_eq_reverse_foldlM_cons`. -/
|
||||
theorem foldlM_cons_eq_append [Monad m] [LawfulMonad m] (f : α → m β) (as : List α) (b : β) (bs : List β) :
|
||||
(as.foldlM (init := b :: bs) fun acc a => return ((← f a) :: acc)) =
|
||||
(· ++ b :: bs) <$> as.foldlM (init := []) fun acc a => return ((← f a) :: acc) := by
|
||||
induction as generalizing b bs with
|
||||
| nil => simp
|
||||
| cons a as ih =>
|
||||
simp only [bind_pure_comp] at ih
|
||||
simp [ih, _root_.map_bind, Functor.map_map, Function.comp_def]
|
||||
|
||||
theorem mapM_eq_reverse_foldlM_cons [Monad m] [LawfulMonad m] (f : α → m β) (l : List α) :
|
||||
mapM f l = reverse <$> (l.foldlM (fun acc a => return ((← f a) :: acc)) []) := by
|
||||
rw [← mapM'_eq_mapM]
|
||||
induction l with
|
||||
| nil => simp
|
||||
| cons a as ih =>
|
||||
simp only [mapM'_cons, ih, bind_map_left, foldlM_cons, LawfulMonad.bind_assoc, pure_bind,
|
||||
foldlM_cons_eq_append, _root_.map_bind, Functor.map_map, Function.comp_def, reverse_append,
|
||||
reverse_cons, reverse_nil, nil_append, singleton_append]
|
||||
simp [bind_pure_comp]
|
||||
|
||||
/-! ### forM -/
|
||||
|
||||
-- We use `List.forM` as the simp normal form, rather that `ForM.forM`.
|
||||
@@ -87,16 +66,4 @@ theorem mapM_eq_reverse_foldlM_cons [Monad m] [LawfulMonad m] (f : α → m β)
|
||||
(l₁ ++ l₂).forM f = (do l₁.forM f; l₂.forM f) := by
|
||||
induction l₁ <;> simp [*]
|
||||
|
||||
/-! ### allM -/
|
||||
|
||||
theorem allM_eq_not_anyM_not [Monad m] [LawfulMonad m] (p : α → m Bool) (as : List α) :
|
||||
allM p as = (! ·) <$> anyM ((! ·) <$> p ·) as := by
|
||||
induction as with
|
||||
| nil => simp
|
||||
| cons a as ih =>
|
||||
simp only [allM, anyM, bind_map_left, _root_.map_bind]
|
||||
congr
|
||||
funext b
|
||||
split <;> simp_all
|
||||
|
||||
end List
|
||||
|
||||
@@ -86,26 +86,26 @@ theorem mem_eraseIdx_iff_getElem? {x : α} {l} {k} : x ∈ eraseIdx l k ↔ ∃
|
||||
obtain ⟨h', -⟩ := getElem?_eq_some_iff.1 h
|
||||
exact ⟨h', h⟩
|
||||
|
||||
/-! ### min? -/
|
||||
/-! ### minimum? -/
|
||||
|
||||
-- A specialization of `min?_eq_some_iff` to Nat.
|
||||
theorem min?_eq_some_iff' {xs : List Nat} :
|
||||
xs.min? = some a ↔ (a ∈ xs ∧ ∀ b ∈ xs, a ≤ b) :=
|
||||
min?_eq_some_iff
|
||||
-- A specialization of `minimum?_eq_some_iff` to Nat.
|
||||
theorem minimum?_eq_some_iff' {xs : List Nat} :
|
||||
xs.minimum? = some a ↔ (a ∈ xs ∧ ∀ b ∈ xs, a ≤ b) :=
|
||||
minimum?_eq_some_iff
|
||||
(le_refl := Nat.le_refl)
|
||||
(min_eq_or := fun _ _ => Nat.min_def .. ▸ by split <;> simp)
|
||||
(le_min_iff := fun _ _ _ => Nat.le_min)
|
||||
(min_eq_or := fun _ _ => by omega)
|
||||
(le_min_iff := fun _ _ _ => by omega)
|
||||
|
||||
-- This could be generalized,
|
||||
-- but will first require further work on order typeclasses in the core repository.
|
||||
theorem min?_cons' {a : Nat} {l : List Nat} :
|
||||
(a :: l).min? = some (match l.min? with
|
||||
theorem minimum?_cons' {a : Nat} {l : List Nat} :
|
||||
(a :: l).minimum? = some (match l.minimum? with
|
||||
| none => a
|
||||
| some m => min a m) := by
|
||||
rw [min?_eq_some_iff']
|
||||
rw [minimum?_eq_some_iff']
|
||||
split <;> rename_i h m
|
||||
· simp_all
|
||||
· rw [min?_eq_some_iff'] at m
|
||||
· rw [minimum?_eq_some_iff'] at m
|
||||
obtain ⟨m, le⟩ := m
|
||||
rw [Nat.min_def]
|
||||
constructor
|
||||
@@ -122,11 +122,11 @@ theorem min?_cons' {a : Nat} {l : List Nat} :
|
||||
theorem foldl_min
|
||||
{α : Type _} [Min α] [Std.IdempotentOp (min : α → α → α)] [Std.Associative (min : α → α → α)]
|
||||
{l : List α} {a : α} :
|
||||
l.foldl (init := a) min = min a (l.min?.getD a) := by
|
||||
l.foldl (init := a) min = min a (l.minimum?.getD a) := by
|
||||
cases l with
|
||||
| nil => simp [Std.IdempotentOp.idempotent]
|
||||
| cons b l =>
|
||||
simp only [min?]
|
||||
simp only [minimum?]
|
||||
induction l generalizing a b with
|
||||
| nil => simp
|
||||
| cons c l ih => simp [ih, Std.Associative.assoc]
|
||||
@@ -134,7 +134,7 @@ theorem foldl_min
|
||||
theorem foldl_min_right {α β : Type _}
|
||||
[Min β] [Std.IdempotentOp (min : β → β → β)] [Std.Associative (min : β → β → β)]
|
||||
{l : List α} {b : β} {f : α → β} :
|
||||
(l.foldl (init := b) fun acc a => min acc (f a)) = min b ((l.map f).min?.getD b) := by
|
||||
(l.foldl (init := b) fun acc a => min acc (f a)) = min b ((l.map f).minimum?.getD b) := by
|
||||
rw [← foldl_map, foldl_min]
|
||||
|
||||
theorem foldl_min_le {l : List Nat} {a : Nat} : l.foldl (init := a) min ≤ a := by
|
||||
@@ -148,12 +148,12 @@ theorem foldl_min_min_of_le {l : List Nat} {a b : Nat} (h : a ≤ b) :
|
||||
l.foldl (init := a) min ≤ b :=
|
||||
Nat.le_trans (foldl_min_le) h
|
||||
|
||||
theorem min?_getD_le_of_mem {l : List Nat} {a k : Nat} (h : a ∈ l) :
|
||||
l.min?.getD k ≤ a := by
|
||||
theorem minimum?_getD_le_of_mem {l : List Nat} {a k : Nat} (h : a ∈ l) :
|
||||
l.minimum?.getD k ≤ a := by
|
||||
cases l with
|
||||
| nil => simp at h
|
||||
| cons b l =>
|
||||
simp [min?_cons]
|
||||
simp [minimum?_cons]
|
||||
simp at h
|
||||
rcases h with (rfl | h)
|
||||
· exact foldl_min_le
|
||||
@@ -166,26 +166,26 @@ theorem min?_getD_le_of_mem {l : List Nat} {a k : Nat} (h : a ∈ l) :
|
||||
· exact foldl_min_min_of_le (Nat.min_le_right _ _)
|
||||
· exact ih _ h
|
||||
|
||||
/-! ### max? -/
|
||||
/-! ### maximum? -/
|
||||
|
||||
-- A specialization of `max?_eq_some_iff` to Nat.
|
||||
theorem max?_eq_some_iff' {xs : List Nat} :
|
||||
xs.max? = some a ↔ (a ∈ xs ∧ ∀ b ∈ xs, b ≤ a) :=
|
||||
max?_eq_some_iff
|
||||
-- A specialization of `maximum?_eq_some_iff` to Nat.
|
||||
theorem maximum?_eq_some_iff' {xs : List Nat} :
|
||||
xs.maximum? = some a ↔ (a ∈ xs ∧ ∀ b ∈ xs, b ≤ a) :=
|
||||
maximum?_eq_some_iff
|
||||
(le_refl := Nat.le_refl)
|
||||
(max_eq_or := fun _ _ => Nat.max_def .. ▸ by split <;> simp)
|
||||
(max_le_iff := fun _ _ _ => Nat.max_le)
|
||||
(max_eq_or := fun _ _ => by omega)
|
||||
(max_le_iff := fun _ _ _ => by omega)
|
||||
|
||||
-- This could be generalized,
|
||||
-- but will first require further work on order typeclasses in the core repository.
|
||||
theorem max?_cons' {a : Nat} {l : List Nat} :
|
||||
(a :: l).max? = some (match l.max? with
|
||||
theorem maximum?_cons' {a : Nat} {l : List Nat} :
|
||||
(a :: l).maximum? = some (match l.maximum? with
|
||||
| none => a
|
||||
| some m => max a m) := by
|
||||
rw [max?_eq_some_iff']
|
||||
rw [maximum?_eq_some_iff']
|
||||
split <;> rename_i h m
|
||||
· simp_all
|
||||
· rw [max?_eq_some_iff'] at m
|
||||
· rw [maximum?_eq_some_iff'] at m
|
||||
obtain ⟨m, le⟩ := m
|
||||
rw [Nat.max_def]
|
||||
constructor
|
||||
@@ -202,11 +202,11 @@ theorem max?_cons' {a : Nat} {l : List Nat} :
|
||||
theorem foldl_max
|
||||
{α : Type _} [Max α] [Std.IdempotentOp (max : α → α → α)] [Std.Associative (max : α → α → α)]
|
||||
{l : List α} {a : α} :
|
||||
l.foldl (init := a) max = max a (l.max?.getD a) := by
|
||||
l.foldl (init := a) max = max a (l.maximum?.getD a) := by
|
||||
cases l with
|
||||
| nil => simp [Std.IdempotentOp.idempotent]
|
||||
| cons b l =>
|
||||
simp only [max?]
|
||||
simp only [maximum?]
|
||||
induction l generalizing a b with
|
||||
| nil => simp
|
||||
| cons c l ih => simp [ih, Std.Associative.assoc]
|
||||
@@ -214,7 +214,7 @@ theorem foldl_max
|
||||
theorem foldl_max_right {α β : Type _}
|
||||
[Max β] [Std.IdempotentOp (max : β → β → β)] [Std.Associative (max : β → β → β)]
|
||||
{l : List α} {b : β} {f : α → β} :
|
||||
(l.foldl (init := b) fun acc a => max acc (f a)) = max b ((l.map f).max?.getD b) := by
|
||||
(l.foldl (init := b) fun acc a => max acc (f a)) = max b ((l.map f).maximum?.getD b) := by
|
||||
rw [← foldl_map, foldl_max]
|
||||
|
||||
theorem le_foldl_max {l : List Nat} {a : Nat} : a ≤ l.foldl (init := a) max := by
|
||||
@@ -228,12 +228,12 @@ theorem le_foldl_max_of_le {l : List Nat} {a b : Nat} (h : a ≤ b) :
|
||||
a ≤ l.foldl (init := b) max :=
|
||||
Nat.le_trans h (le_foldl_max)
|
||||
|
||||
theorem le_max?_getD_of_mem {l : List Nat} {a k : Nat} (h : a ∈ l) :
|
||||
a ≤ l.max?.getD k := by
|
||||
theorem le_maximum?_getD_of_mem {l : List Nat} {a k : Nat} (h : a ∈ l) :
|
||||
a ≤ l.maximum?.getD k := by
|
||||
cases l with
|
||||
| nil => simp at h
|
||||
| cons b l =>
|
||||
simp [max?_cons]
|
||||
simp [maximum?_cons]
|
||||
simp at h
|
||||
rcases h with (rfl | h)
|
||||
· exact le_foldl_max
|
||||
@@ -246,11 +246,4 @@ theorem le_max?_getD_of_mem {l : List Nat} {a k : Nat} (h : a ∈ l) :
|
||||
· exact le_foldl_max_of_le (Nat.le_max_right b a)
|
||||
· exact ih _ h
|
||||
|
||||
@[deprecated min?_eq_some_iff' (since := "2024-09-29")] abbrev minimum?_eq_some_iff' := @min?_eq_some_iff'
|
||||
@[deprecated min?_cons' (since := "2024-09-29")] abbrev minimum?_cons' := @min?_cons'
|
||||
@[deprecated min?_getD_le_of_mem (since := "2024-09-29")] abbrev minimum?_getD_le_of_mem := @min?_getD_le_of_mem
|
||||
@[deprecated max?_eq_some_iff' (since := "2024-09-29")] abbrev maximum?_eq_some_iff' := @max?_eq_some_iff'
|
||||
@[deprecated max?_cons' (since := "2024-09-29")] abbrev maximum?_cons' := @max?_cons'
|
||||
@[deprecated le_max?_getD_of_mem (since := "2024-09-29")] abbrev le_maximum?_getD_of_mem := @le_max?_getD_of_mem
|
||||
|
||||
end List
|
||||
|
||||
@@ -10,7 +10,7 @@ import Init.Data.List.Erase
|
||||
namespace List
|
||||
|
||||
theorem getElem?_eraseIdx (l : List α) (i : Nat) (j : Nat) :
|
||||
(l.eraseIdx i)[j]? = if j < i then l[j]? else l[j + 1]? := by
|
||||
(l.eraseIdx i)[j]? = if h : j < i then l[j]? else l[j + 1]? := by
|
||||
rw [eraseIdx_eq_take_drop_succ, getElem?_append]
|
||||
split <;> rename_i h
|
||||
· rw [getElem?_take]
|
||||
|
||||
@@ -154,7 +154,7 @@ theorem erase_range' :
|
||||
/-! ### range -/
|
||||
|
||||
theorem reverse_range' : ∀ s n : Nat, reverse (range' s n) = map (s + n - 1 - ·) (range n)
|
||||
| _, 0 => rfl
|
||||
| s, 0 => rfl
|
||||
| s, n + 1 => by
|
||||
rw [range'_1_concat, reverse_append, range_succ_eq_map,
|
||||
show s + (n + 1) - 1 = s + n from rfl, map, map_map]
|
||||
|
||||
@@ -42,7 +42,7 @@ theorem getElem_take' (L : List α) {i j : Nat} (hi : i < L.length) (hj : i < j)
|
||||
|
||||
/-- The `i`-th element of a list coincides with the `i`-th element of any of its prefixes of
|
||||
length `> i`. Version designed to rewrite from the small list to the big list. -/
|
||||
@[simp] theorem getElem_take (L : List α) {j i : Nat} {h : i < (L.take j).length} :
|
||||
theorem getElem_take (L : List α) {j i : Nat} {h : i < (L.take j).length} :
|
||||
(L.take j)[i] =
|
||||
L[i]'(Nat.lt_of_lt_of_le h (length_take_le' _ _)) := by
|
||||
rw [length_take, Nat.lt_min] at h; rw [getElem_take' L _ h.1]
|
||||
@@ -52,7 +52,7 @@ length `> i`. Version designed to rewrite from the big list to the small list. -
|
||||
@[deprecated getElem_take' (since := "2024-06-12")]
|
||||
theorem get_take (L : List α) {i j : Nat} (hi : i < L.length) (hj : i < j) :
|
||||
get L ⟨i, hi⟩ = get (L.take j) ⟨i, length_take .. ▸ Nat.lt_min.mpr ⟨hj, hi⟩⟩ := by
|
||||
simp
|
||||
simp [getElem_take' _ hi hj]
|
||||
|
||||
/-- The `i`-th element of a list coincides with the `i`-th element of any of its prefixes of
|
||||
length `> i`. Version designed to rewrite from the small list to the big list. -/
|
||||
|
||||
@@ -98,8 +98,8 @@ theorem Perm.append_cons (a : α) {h₁ h₂ t₁ t₂ : List α} (p₁ : h₁ ~
|
||||
perm_middle.trans <| by rw [append_nil]
|
||||
|
||||
theorem perm_append_comm : ∀ {l₁ l₂ : List α}, l₁ ++ l₂ ~ l₂ ++ l₁
|
||||
| [], _ => by simp
|
||||
| _ :: _, _ => (perm_append_comm.cons _).trans perm_middle.symm
|
||||
| [], l₂ => by simp
|
||||
| a :: t, l₂ => (perm_append_comm.cons _).trans perm_middle.symm
|
||||
|
||||
theorem perm_append_comm_assoc (l₁ l₂ l₃ : List α) :
|
||||
Perm (l₁ ++ (l₂ ++ l₃)) (l₂ ++ (l₁ ++ l₃)) := by
|
||||
@@ -248,10 +248,6 @@ theorem countP_eq_countP_filter_add (l : List α) (p q : α → Bool) :
|
||||
theorem Perm.count_eq [DecidableEq α] {l₁ l₂ : List α} (p : l₁ ~ l₂) (a) :
|
||||
count a l₁ = count a l₂ := p.countP_eq _
|
||||
|
||||
/-
|
||||
This theorem is a variant of `Perm.foldl_eq` defined in Mathlib which uses typeclasses rather
|
||||
than the explicit `comm` argument.
|
||||
-/
|
||||
theorem Perm.foldl_eq' {f : β → α → β} {l₁ l₂ : List α} (p : l₁ ~ l₂)
|
||||
(comm : ∀ x ∈ l₁, ∀ y ∈ l₁, ∀ (z), f (f z x) y = f (f z y) x)
|
||||
(init) : foldl f init l₁ = foldl f init l₂ := by
|
||||
@@ -268,28 +264,6 @@ theorem Perm.foldl_eq' {f : β → α → β} {l₁ l₂ : List α} (p : l₁ ~
|
||||
refine (IH₁ comm init).trans (IH₂ ?_ _)
|
||||
intros; apply comm <;> apply p₁.symm.subset <;> assumption
|
||||
|
||||
/-
|
||||
This theorem is a variant of `Perm.foldr_eq` defined in Mathlib which uses typeclasses rather
|
||||
than the explicit `comm` argument.
|
||||
-/
|
||||
theorem Perm.foldr_eq' {f : α → β → β} {l₁ l₂ : List α} (p : l₁ ~ l₂)
|
||||
(comm : ∀ x ∈ l₁, ∀ y ∈ l₁, ∀ (z), f y (f x z) = f x (f y z))
|
||||
(init) : foldr f init l₁ = foldr f init l₂ := by
|
||||
induction p using recOnSwap' generalizing init with
|
||||
| nil => simp
|
||||
| cons x _p IH =>
|
||||
simp only [foldr]
|
||||
congr 1
|
||||
apply IH; intros; apply comm <;> exact .tail _ ‹_›
|
||||
| swap' x y _p IH =>
|
||||
simp only [foldr]
|
||||
rw [comm x (.tail _ <| .head _) y (.head _)]
|
||||
congr 2
|
||||
apply IH; intros; apply comm <;> exact .tail _ (.tail _ ‹_›)
|
||||
| trans p₁ _p₂ IH₁ IH₂ =>
|
||||
refine (IH₁ comm init).trans (IH₂ ?_ _)
|
||||
intros; apply comm <;> apply p₁.symm.subset <;> assumption
|
||||
|
||||
theorem Perm.rec_heq {β : List α → Sort _} {f : ∀ a l, β l → β (a :: l)} {b : β []} {l l' : List α}
|
||||
(hl : l ~ l') (f_congr : ∀ {a l l' b b'}, l ~ l' → HEq b b' → HEq (f a l b) (f a l' b'))
|
||||
(f_swap : ∀ {a a' l b}, HEq (f a (a' :: l) (f a' l b)) (f a' (a :: l) (f a l b))) :
|
||||
|
||||
@@ -92,7 +92,7 @@ theorem map_add_range' (a) : ∀ s n step, map (a + ·) (range' s n step) = rang
|
||||
|
||||
theorem range'_append : ∀ s m n step : Nat,
|
||||
range' s m step ++ range' (s + step * m) n step = range' s (n + m) step
|
||||
| _, 0, _, _ => rfl
|
||||
| s, 0, n, step => rfl
|
||||
| s, m + 1, n, step => by
|
||||
simpa [range', Nat.mul_succ, Nat.add_assoc, Nat.add_comm]
|
||||
using range'_append (s + step) m n step
|
||||
@@ -131,7 +131,7 @@ theorem range'_eq_cons_iff : range' s n = a :: xs ↔ s = a ∧ 0 < n ∧ xs = r
|
||||
/-! ### range -/
|
||||
|
||||
theorem range_loop_range' : ∀ s n : Nat, range.loop s (range' s n) = range' 0 (n + s)
|
||||
| 0, _ => rfl
|
||||
| 0, n => rfl
|
||||
| s + 1, n => by rw [← Nat.add_assoc, Nat.add_right_comm n s 1]; exact range_loop_range' s (n + 1)
|
||||
|
||||
theorem range_eq_range' (n : Nat) : range n = range' 0 n :=
|
||||
@@ -214,9 +214,9 @@ theorem enumFrom_eq_nil {n : Nat} {l : List α} : List.enumFrom n l = [] ↔ l =
|
||||
@[simp]
|
||||
theorem getElem?_enumFrom :
|
||||
∀ n (l : List α) m, (enumFrom n l)[m]? = l[m]?.map fun a => (n + m, a)
|
||||
| _, [], _ => rfl
|
||||
| _, _ :: _, 0 => by simp
|
||||
| n, _ :: l, m + 1 => by
|
||||
| n, [], m => rfl
|
||||
| n, a :: l, 0 => by simp
|
||||
| n, a :: l, m + 1 => by
|
||||
simp only [enumFrom_cons, getElem?_cons_succ]
|
||||
exact (getElem?_enumFrom (n + 1) l m).trans <| by rw [Nat.add_right_comm]; rfl
|
||||
|
||||
|
||||
@@ -102,7 +102,7 @@ def mergeSortTR (l : List α) (le : α → α → Bool := by exact fun a b => a
|
||||
where run : {n : Nat} → { l : List α // l.length = n } → List α
|
||||
| 0, ⟨[], _⟩ => []
|
||||
| 1, ⟨[a], _⟩ => [a]
|
||||
| _+2, xs =>
|
||||
| n+2, xs =>
|
||||
let (l, r) := splitInTwo xs
|
||||
mergeTR (run l) (run r) le
|
||||
|
||||
@@ -136,13 +136,13 @@ where
|
||||
run : {n : Nat} → { l : List α // l.length = n } → List α
|
||||
| 0, ⟨[], _⟩ => []
|
||||
| 1, ⟨[a], _⟩ => [a]
|
||||
| _+2, xs =>
|
||||
| n+2, xs =>
|
||||
let (l, r) := splitRevInTwo xs
|
||||
mergeTR (run' l) (run r) le
|
||||
run' : {n : Nat} → { l : List α // l.length = n } → List α
|
||||
| 0, ⟨[], _⟩ => []
|
||||
| 1, ⟨[a], _⟩ => [a]
|
||||
| _+2, xs =>
|
||||
| n+2, xs =>
|
||||
let (l, r) := splitRevInTwo' xs
|
||||
mergeTR (run' r) (run l) le
|
||||
|
||||
|
||||
@@ -725,25 +725,16 @@ theorem infix_iff_suffix_prefix {l₁ l₂ : List α} : l₁ <:+: l₂ ↔ ∃ t
|
||||
theorem IsInfix.eq_of_length (h : l₁ <:+: l₂) : l₁.length = l₂.length → l₁ = l₂ :=
|
||||
h.sublist.eq_of_length
|
||||
|
||||
theorem IsInfix.eq_of_length_le (h : l₁ <:+: l₂) : l₂.length ≤ l₁.length → l₁ = l₂ :=
|
||||
h.sublist.eq_of_length_le
|
||||
|
||||
theorem IsPrefix.eq_of_length (h : l₁ <+: l₂) : l₁.length = l₂.length → l₁ = l₂ :=
|
||||
h.sublist.eq_of_length
|
||||
|
||||
theorem IsPrefix.eq_of_length_le (h : l₁ <+: l₂) : l₂.length ≤ l₁.length → l₁ = l₂ :=
|
||||
h.sublist.eq_of_length_le
|
||||
|
||||
theorem IsSuffix.eq_of_length (h : l₁ <:+ l₂) : l₁.length = l₂.length → l₁ = l₂ :=
|
||||
h.sublist.eq_of_length
|
||||
|
||||
theorem IsSuffix.eq_of_length_le (h : l₁ <:+ l₂) : l₂.length ≤ l₁.length → l₁ = l₂ :=
|
||||
h.sublist.eq_of_length_le
|
||||
|
||||
theorem prefix_of_prefix_length_le :
|
||||
∀ {l₁ l₂ l₃ : List α}, l₁ <+: l₃ → l₂ <+: l₃ → length l₁ ≤ length l₂ → l₁ <+: l₂
|
||||
| [], _, _, _, _, _ => nil_prefix
|
||||
| _ :: _, b :: _, _, ⟨_, rfl⟩, ⟨_, e⟩, ll => by
|
||||
| [], l₂, _, _, _, _ => nil_prefix
|
||||
| a :: l₁, b :: l₂, _, ⟨r₁, rfl⟩, ⟨r₂, e⟩, ll => by
|
||||
injection e with _ e'; subst b
|
||||
rcases prefix_of_prefix_length_le ⟨_, rfl⟩ ⟨_, e'⟩ (le_of_succ_le_succ ll) with ⟨r₃, rfl⟩
|
||||
exact ⟨r₃, rfl⟩
|
||||
@@ -838,24 +829,6 @@ theorem isPrefix_iff : l₁ <+: l₂ ↔ ∀ i (h : i < l₁.length), l₂[i]? =
|
||||
rw (config := {occs := .pos [2]}) [← Nat.and_forall_add_one]
|
||||
simp [Nat.succ_lt_succ_iff, eq_comm]
|
||||
|
||||
theorem isPrefix_iff_getElem {l₁ l₂ : List α} :
|
||||
l₁ <+: l₂ ↔ ∃ (h : l₁.length ≤ l₂.length), ∀ x (hx : x < l₁.length),
|
||||
l₁[x] = l₂[x]'(Nat.lt_of_lt_of_le hx h) where
|
||||
mp h := ⟨h.length_le, fun _ _ ↦ h.getElem _⟩
|
||||
mpr h := by
|
||||
obtain ⟨hl, h⟩ := h
|
||||
induction l₂ generalizing l₁ with
|
||||
| nil =>
|
||||
simpa using hl
|
||||
| cons _ _ tail_ih =>
|
||||
cases l₁ with
|
||||
| nil =>
|
||||
exact nil_prefix
|
||||
| cons _ _ =>
|
||||
simp only [length_cons, Nat.add_le_add_iff_right, Fin.getElem_fin] at hl h
|
||||
simp only [cons_prefix_cons]
|
||||
exact ⟨h 0 (zero_lt_succ _), tail_ih hl fun a ha ↦ h a.succ (succ_lt_succ ha)⟩
|
||||
|
||||
-- See `Init.Data.List.Nat.Sublist` for `isSuffix_iff` and `ifInfix_iff`.
|
||||
|
||||
theorem isPrefix_filterMap_iff {β} {f : α → Option β} {l₁ : List α} {l₂ : List β} :
|
||||
|
||||
@@ -247,9 +247,9 @@ theorem zip_eq_zipWith : ∀ (l₁ : List α) (l₂ : List β), zip l₁ l₂ =
|
||||
|
||||
theorem zip_map (f : α → γ) (g : β → δ) :
|
||||
∀ (l₁ : List α) (l₂ : List β), zip (l₁.map f) (l₂.map g) = (zip l₁ l₂).map (Prod.map f g)
|
||||
| [], _ => rfl
|
||||
| _, [] => by simp only [map, zip_nil_right]
|
||||
| _ :: _, _ :: _ => by
|
||||
| [], l₂ => rfl
|
||||
| l₁, [] => by simp only [map, zip_nil_right]
|
||||
| a :: l₁, b :: l₂ => by
|
||||
simp only [map, zip_cons_cons, zip_map, Prod.map]; constructor
|
||||
|
||||
theorem zip_map_left (f : α → γ) (l₁ : List α) (l₂ : List β) :
|
||||
@@ -287,12 +287,12 @@ theorem of_mem_zip {a b} : ∀ {l₁ : List α} {l₂ : List β}, (a, b) ∈ zip
|
||||
|
||||
theorem map_fst_zip :
|
||||
∀ (l₁ : List α) (l₂ : List β), l₁.length ≤ l₂.length → map Prod.fst (zip l₁ l₂) = l₁
|
||||
| [], _, _ => rfl
|
||||
| [], bs, _ => rfl
|
||||
| _ :: as, _ :: bs, h => by
|
||||
simp [Nat.succ_le_succ_iff] at h
|
||||
show _ :: map Prod.fst (zip as bs) = _ :: as
|
||||
rw [map_fst_zip as bs h]
|
||||
| _ :: _, [], h => by simp at h
|
||||
| a :: as, [], h => by simp at h
|
||||
|
||||
theorem map_snd_zip :
|
||||
∀ (l₁ : List α) (l₂ : List β), l₂.length ≤ l₁.length → map Prod.snd (zip l₁ l₂) = l₂
|
||||
@@ -430,9 +430,9 @@ theorem zip_unzip : ∀ l : List (α × β), zip (unzip l).1 (unzip l).2 = l
|
||||
|
||||
theorem unzip_zip_left :
|
||||
∀ {l₁ : List α} {l₂ : List β}, length l₁ ≤ length l₂ → (unzip (zip l₁ l₂)).1 = l₁
|
||||
| [], _, _ => rfl
|
||||
| _, [], h => by rw [eq_nil_of_length_eq_zero (Nat.eq_zero_of_le_zero h)]; rfl
|
||||
| _ :: _, _ :: _, h => by
|
||||
| [], l₂, _ => rfl
|
||||
| l₁, [], h => by rw [eq_nil_of_length_eq_zero (Nat.eq_zero_of_le_zero h)]; rfl
|
||||
| a :: l₁, b :: l₂, h => by
|
||||
simp only [zip_cons_cons, unzip_cons, unzip_zip_left (le_of_succ_le_succ h)]
|
||||
|
||||
theorem unzip_zip_right :
|
||||
|
||||
@@ -248,7 +248,7 @@ protected theorem add_mul (n m k : Nat) : (n + m) * k = n * k + m * k :=
|
||||
Nat.right_distrib n m k
|
||||
|
||||
protected theorem mul_assoc : ∀ (n m k : Nat), (n * m) * k = n * (m * k)
|
||||
| _, _, 0 => rfl
|
||||
| n, m, 0 => rfl
|
||||
| n, m, succ k => by simp [mul_succ, Nat.mul_assoc n m k, Nat.left_distrib]
|
||||
instance : Std.Associative (α := Nat) (· * ·) := ⟨Nat.mul_assoc⟩
|
||||
|
||||
@@ -634,8 +634,6 @@ theorem lt_succ_of_lt (h : a < b) : a < succ b := le_succ_of_le h
|
||||
|
||||
theorem lt_add_one_of_lt (h : a < b) : a < b + 1 := le_succ_of_le h
|
||||
|
||||
@[simp] theorem lt_one_iff : n < 1 ↔ n = 0 := Nat.lt_succ_iff.trans <| by rw [le_zero_eq]
|
||||
|
||||
theorem succ_pred_eq_of_ne_zero : ∀ {n}, n ≠ 0 → succ (pred n) = n
|
||||
| _+1, _ => rfl
|
||||
|
||||
|
||||
@@ -269,7 +269,7 @@ protected theorem div_div_eq_div_mul (m n k : Nat) : m / n / k = m / (n * k) :=
|
||||
|
||||
theorem div_mul_le_self : ∀ (m n : Nat), m / n * n ≤ m
|
||||
| m, 0 => by simp
|
||||
| _, _+1 => (le_div_iff_mul_le (Nat.succ_pos _)).1 (Nat.le_refl _)
|
||||
| m, n+1 => (le_div_iff_mul_le (Nat.succ_pos _)).1 (Nat.le_refl _)
|
||||
|
||||
theorem div_lt_iff_lt_mul (Hk : 0 < k) : x / k < y ↔ x < y * k := by
|
||||
rw [← Nat.not_le, ← Nat.not_le]; exact not_congr (le_div_iff_mul_le Hk)
|
||||
|
||||
@@ -605,9 +605,6 @@ theorem add_mod (a b n : Nat) : (a + b) % n = ((a % n) + (b % n)) % n := by
|
||||
| zero => simp_all
|
||||
| succ k => omega
|
||||
|
||||
@[simp] theorem mod_mul_mod {a b c : Nat} : (a % c * b) % c = a * b % c := by
|
||||
rw [mul_mod, mod_mod, ← mul_mod]
|
||||
|
||||
/-! ### pow -/
|
||||
|
||||
theorem pow_succ' {m n : Nat} : m ^ n.succ = m * m ^ n := by
|
||||
@@ -770,11 +767,6 @@ protected theorem two_pow_pred_mod_two_pow (h : 0 < w) :
|
||||
rw [mod_eq_of_lt]
|
||||
apply Nat.pow_pred_lt_pow (by omega) h
|
||||
|
||||
protected theorem pow_lt_pow_iff_pow_mul_le_pow {a n m : Nat} (h : 1 < a) :
|
||||
a ^ n < a ^ m ↔ a ^ n * a ≤ a ^ m := by
|
||||
rw [←Nat.pow_add_one, Nat.pow_le_pow_iff_right (by omega), Nat.pow_lt_pow_iff_right (by omega)]
|
||||
omega
|
||||
|
||||
@[simp]
|
||||
theorem two_pow_pred_mul_two (h : 0 < w) :
|
||||
2 ^ (w - 1) * 2 = 2 ^ w := by
|
||||
@@ -874,15 +866,15 @@ theorem shiftLeft_succ_inside (m n : Nat) : m <<< (n+1) = (2*m) <<< n := rfl
|
||||
|
||||
/-- Shiftleft on successor with multiple moved to outside. -/
|
||||
theorem shiftLeft_succ : ∀(m n), m <<< (n + 1) = 2 * (m <<< n)
|
||||
| _, 0 => rfl
|
||||
| _, k + 1 => by
|
||||
| m, 0 => rfl
|
||||
| m, k + 1 => by
|
||||
rw [shiftLeft_succ_inside _ (k+1)]
|
||||
rw [shiftLeft_succ _ k, shiftLeft_succ_inside]
|
||||
|
||||
/-- Shiftright on successor with division moved inside. -/
|
||||
theorem shiftRight_succ_inside : ∀m n, m >>> (n+1) = (m/2) >>> n
|
||||
| _, 0 => rfl
|
||||
| _, k + 1 => by
|
||||
| m, 0 => rfl
|
||||
| m, k + 1 => by
|
||||
rw [shiftRight_succ _ (k+1)]
|
||||
rw [shiftRight_succ_inside _ k, shiftRight_succ]
|
||||
|
||||
|
||||
@@ -35,4 +35,4 @@ theorem neZero_iff {n : R} : NeZero n ↔ n ≠ 0 :=
|
||||
⟨fun h ↦ h.out, NeZero.mk⟩
|
||||
|
||||
@[simp] theorem neZero_zero_iff_false {α : Type _} [Zero α] : NeZero (0 : α) ↔ False :=
|
||||
⟨fun _ ↦ NeZero.ne (0 : α) rfl, fun h ↦ h.elim⟩
|
||||
⟨fun h ↦ h.ne rfl, fun h ↦ h.elim⟩
|
||||
|
||||
@@ -8,5 +8,3 @@ import Init.Data.Option.Basic
|
||||
import Init.Data.Option.BasicAux
|
||||
import Init.Data.Option.Instances
|
||||
import Init.Data.Option.Lemmas
|
||||
import Init.Data.Option.Attach
|
||||
import Init.Data.Option.List
|
||||
|
||||
@@ -1,178 +0,0 @@
|
||||
/-
|
||||
Copyright (c) 2024 Lean FRO. All rights reserved.
|
||||
Released under Apache 2.0 license as described in the file LICENSE.
|
||||
Authors: Kim Morrison
|
||||
-/
|
||||
prelude
|
||||
import Init.Data.Option.Basic
|
||||
import Init.Data.Option.List
|
||||
import Init.Data.List.Attach
|
||||
import Init.BinderPredicates
|
||||
|
||||
namespace Option
|
||||
|
||||
/--
|
||||
Unsafe implementation of `attachWith`, taking advantage of the fact that the representation of
|
||||
`Option {x // P x}` is the same as the input `Option α`.
|
||||
-/
|
||||
@[inline] private unsafe def attachWithImpl
|
||||
(o : Option α) (P : α → Prop) (_ : ∀ x ∈ o, P x) : Option {x // P x} := unsafeCast o
|
||||
|
||||
/-- "Attach" a proof `P x` that holds for the element of `o`, if present,
|
||||
to produce a new option with the same element but in the type `{x // P x}`. -/
|
||||
@[implemented_by attachWithImpl] def attachWith
|
||||
(xs : Option α) (P : α → Prop) (H : ∀ x ∈ xs, P x) : Option {x // P x} :=
|
||||
match xs with
|
||||
| none => none
|
||||
| some x => some ⟨x, H x (mem_some_self x)⟩
|
||||
|
||||
/-- "Attach" the proof that the element of `xs`, if present, is in `xs`
|
||||
to produce a new option with the same elements but in the type `{x // x ∈ xs}`. -/
|
||||
@[inline] def attach (xs : Option α) : Option {x // x ∈ xs} := xs.attachWith _ fun _ => id
|
||||
|
||||
@[simp] theorem attach_none : (none : Option α).attach = none := rfl
|
||||
@[simp] theorem attachWith_none : (none : Option α).attachWith P H = none := rfl
|
||||
|
||||
@[simp] theorem attach_some {x : α} :
|
||||
(some x).attach = some ⟨x, rfl⟩ := rfl
|
||||
@[simp] theorem attachWith_some {x : α} {P : α → Prop} (h : ∀ (b : α), b ∈ some x → P b) :
|
||||
(some x).attachWith P h = some ⟨x, by simpa using h⟩ := rfl
|
||||
|
||||
theorem attach_congr {o₁ o₂ : Option α} (h : o₁ = o₂) :
|
||||
o₁.attach = o₂.attach.map (fun x => ⟨x.1, h ▸ x.2⟩) := by
|
||||
subst h
|
||||
simp
|
||||
|
||||
theorem attachWith_congr {o₁ o₂ : Option α} (w : o₁ = o₂) {P : α → Prop} {H : ∀ x ∈ o₁, P x} :
|
||||
o₁.attachWith P H = o₂.attachWith P fun x h => H _ (w ▸ h) := by
|
||||
subst w
|
||||
simp
|
||||
|
||||
theorem attach_map_coe (o : Option α) (f : α → β) :
|
||||
(o.attach.map fun (i : {i // i ∈ o}) => f i) = o.map f := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem attach_map_val (o : Option α) (f : α → β) :
|
||||
(o.attach.map fun i => f i.val) = o.map f :=
|
||||
attach_map_coe _ _
|
||||
|
||||
@[simp]
|
||||
theorem attach_map_subtype_val (o : Option α) :
|
||||
o.attach.map Subtype.val = o :=
|
||||
(attach_map_coe _ _).trans (congrFun Option.map_id _)
|
||||
|
||||
theorem attachWith_map_coe {p : α → Prop} (f : α → β) (o : Option α) (H : ∀ a ∈ o, p a) :
|
||||
((o.attachWith p H).map fun (i : { i // p i}) => f i.val) = o.map f := by
|
||||
cases o <;> simp [H]
|
||||
|
||||
theorem attachWith_map_val {p : α → Prop} (f : α → β) (o : Option α) (H : ∀ a ∈ o, p a) :
|
||||
((o.attachWith p H).map fun i => f i.val) = o.map f :=
|
||||
attachWith_map_coe _ _ _
|
||||
|
||||
@[simp]
|
||||
theorem attachWith_map_subtype_val {p : α → Prop} (o : Option α) (H : ∀ a ∈ o, p a) :
|
||||
(o.attachWith p H).map Subtype.val = o :=
|
||||
(attachWith_map_coe _ _ _).trans (congrFun Option.map_id _)
|
||||
|
||||
@[simp] theorem mem_attach : ∀ (o : Option α) (x : {x // x ∈ o}), x ∈ o.attach
|
||||
| none, ⟨x, h⟩ => by simp at h
|
||||
| some a, ⟨x, h⟩ => by simpa using h
|
||||
|
||||
@[simp] theorem isNone_attach (o : Option α) : o.attach.isNone = o.isNone := by
|
||||
cases o <;> simp
|
||||
|
||||
@[simp] theorem isNone_attachWith {p : α → Prop} (o : Option α) (H : ∀ a ∈ o, p a) :
|
||||
(o.attachWith p H).isNone = o.isNone := by
|
||||
cases o <;> simp
|
||||
|
||||
@[simp] theorem isSome_attach (o : Option α) : o.attach.isSome = o.isSome := by
|
||||
cases o <;> simp
|
||||
|
||||
@[simp] theorem isSome_attachWith {p : α → Prop} (o : Option α) (H : ∀ a ∈ o, p a) :
|
||||
(o.attachWith p H).isSome = o.isSome := by
|
||||
cases o <;> simp
|
||||
|
||||
@[simp] theorem attach_eq_none_iff (o : Option α) : o.attach = none ↔ o = none := by
|
||||
cases o <;> simp
|
||||
|
||||
@[simp] theorem attach_eq_some_iff {o : Option α} {x : {x // x ∈ o}} :
|
||||
o.attach = some x ↔ o = some x.val := by
|
||||
cases o <;> cases x <;> simp
|
||||
|
||||
@[simp] theorem attachWith_eq_none_iff {p : α → Prop} (o : Option α) (H : ∀ a ∈ o, p a) :
|
||||
o.attachWith p H = none ↔ o = none := by
|
||||
cases o <;> simp
|
||||
|
||||
@[simp] theorem attachWith_eq_some_iff {p : α → Prop} {o : Option α} (H : ∀ a ∈ o, p a) {x : {x // p x}} :
|
||||
o.attachWith p H = some x ↔ o = some x.val := by
|
||||
cases o <;> cases x <;> simp
|
||||
|
||||
@[simp] theorem get_attach {o : Option α} (h : o.attach.isSome = true) :
|
||||
o.attach.get h = ⟨o.get (by simpa using h), by simp⟩ := by
|
||||
cases o
|
||||
· simp at h
|
||||
· simp [get_some]
|
||||
|
||||
@[simp] theorem get_attachWith {p : α → Prop} {o : Option α} (H : ∀ a ∈ o, p a) (h : (o.attachWith p H).isSome) :
|
||||
(o.attachWith p H).get h = ⟨o.get (by simpa using h), H _ (by simp)⟩ := by
|
||||
cases o
|
||||
· simp at h
|
||||
· simp [get_some]
|
||||
|
||||
@[simp] theorem toList_attach (o : Option α) :
|
||||
o.attach.toList = o.toList.attach.map fun ⟨x, h⟩ => ⟨x, by simpa using h⟩ := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem attach_map {o : Option α} (f : α → β) :
|
||||
(o.map f).attach = o.attach.map (fun ⟨x, h⟩ => ⟨f x, mem_map_of_mem f h⟩) := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem attachWith_map {o : Option α} (f : α → β) {P : β → Prop} {H : ∀ (b : β), b ∈ o.map f → P b} :
|
||||
(o.map f).attachWith P H = (o.attachWith (P ∘ f) (fun a h => H _ (mem_map_of_mem f h))).map
|
||||
fun ⟨x, h⟩ => ⟨f x, h⟩ := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem map_attach {o : Option α} (f : { x // x ∈ o } → β) :
|
||||
o.attach.map f = o.pmap (fun a (h : a ∈ o) => f ⟨a, h⟩) (fun a h => h) := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem map_attachWith {o : Option α} {P : α → Prop} {H : ∀ (a : α), a ∈ o → P a}
|
||||
(f : { x // P x } → β) :
|
||||
(o.attachWith P H).map f =
|
||||
o.pmap (fun a (h : a ∈ o ∧ P a) => f ⟨a, h.2⟩) (fun a h => ⟨h, H a h⟩) := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem attach_bind {o : Option α} {f : α → Option β} :
|
||||
(o.bind f).attach =
|
||||
o.attach.bind fun ⟨x, h⟩ => (f x).attach.map fun ⟨y, h'⟩ => ⟨y, mem_bind_iff.mpr ⟨x, h, h'⟩⟩ := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem bind_attach {o : Option α} {f : {x // x ∈ o} → Option β} :
|
||||
o.attach.bind f = o.pbind fun a h => f ⟨a, h⟩ := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem pbind_eq_bind_attach {o : Option α} {f : (a : α) → a ∈ o → Option β} :
|
||||
o.pbind f = o.attach.bind fun ⟨x, h⟩ => f x h := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem attach_filter {o : Option α} {p : α → Bool} :
|
||||
(o.filter p).attach =
|
||||
o.attach.bind fun ⟨x, h⟩ => if h' : p x then some ⟨x, by simp_all⟩ else none := by
|
||||
cases o with
|
||||
| none => simp
|
||||
| some a =>
|
||||
simp only [filter_some, attach_some]
|
||||
ext
|
||||
simp only [mem_def, attach_eq_some_iff, ite_none_right_eq_some, some.injEq, some_bind,
|
||||
dite_none_right_eq_some]
|
||||
constructor
|
||||
· rintro ⟨h, w⟩
|
||||
refine ⟨h, by ext; simpa using w⟩
|
||||
· rintro ⟨h, rfl⟩
|
||||
simp [h]
|
||||
|
||||
theorem filter_attach {o : Option α} {p : {x // x ∈ o} → Bool} :
|
||||
o.attach.filter p = o.pbind fun a h => if p ⟨a, h⟩ then some ⟨a, h⟩ else none := by
|
||||
cases o <;> simp [filter_some]
|
||||
|
||||
end Option
|
||||
@@ -202,7 +202,7 @@ result.
|
||||
instance (α) [BEq α] [LawfulBEq α] : LawfulBEq (Option α) where
|
||||
rfl {x} :=
|
||||
match x with
|
||||
| some _ => LawfulBEq.rfl (α := α)
|
||||
| some x => LawfulBEq.rfl (α := α)
|
||||
| none => rfl
|
||||
eq_of_beq {x y h} := by
|
||||
match x, y with
|
||||
|
||||
@@ -138,10 +138,6 @@ theorem bind_eq_none' {o : Option α} {f : α → Option β} :
|
||||
o.bind f = none ↔ ∀ b a, a ∈ o → b ∉ f a := by
|
||||
simp only [eq_none_iff_forall_not_mem, not_exists, not_and, mem_def, bind_eq_some]
|
||||
|
||||
theorem mem_bind_iff {o : Option α} {f : α → Option β} :
|
||||
b ∈ o.bind f ↔ ∃ a, a ∈ o ∧ b ∈ f a := by
|
||||
cases o <;> simp
|
||||
|
||||
theorem bind_comm {f : α → β → Option γ} (a : Option α) (b : Option β) :
|
||||
(a.bind fun x => b.bind (f x)) = b.bind fun y => a.bind fun x => f x y := by
|
||||
cases a <;> cases b <;> rfl
|
||||
@@ -236,27 +232,9 @@ theorem isSome_filter_of_isSome (p : α → Bool) (o : Option α) (h : (o.filter
|
||||
cases o <;> simp at h ⊢
|
||||
|
||||
@[simp] theorem filter_eq_none {p : α → Bool} :
|
||||
o.filter p = none ↔ o = none ∨ ∀ a, a ∈ o → ¬ p a := by
|
||||
Option.filter p o = none ↔ o = none ∨ ∀ a, a ∈ o → ¬ p a := by
|
||||
cases o <;> simp [filter_some]
|
||||
|
||||
@[simp] theorem filter_eq_some {o : Option α} {p : α → Bool} :
|
||||
o.filter p = some a ↔ a ∈ o ∧ p a := by
|
||||
cases o with
|
||||
| none => simp
|
||||
| some a =>
|
||||
simp [filter_some]
|
||||
split <;> rename_i h
|
||||
· simp only [some.injEq, iff_self_and]
|
||||
rintro rfl
|
||||
exact h
|
||||
· simp only [reduceCtorEq, false_iff, not_and, Bool.not_eq_true]
|
||||
rintro rfl
|
||||
simpa using h
|
||||
|
||||
theorem mem_filter_iff {p : α → Bool} {a : α} {o : Option α} :
|
||||
a ∈ o.filter p ↔ a ∈ o ∧ p a := by
|
||||
simp
|
||||
|
||||
@[simp] theorem all_guard (p : α → Prop) [DecidablePred p] (a : α) :
|
||||
Option.all q (guard p a) = (!p a || q a) := by
|
||||
simp only [guard]
|
||||
@@ -330,8 +308,8 @@ theorem guard_comp {p : α → Prop} [DecidablePred p] {f : β → α} :
|
||||
theorem liftOrGet_eq_or_eq {f : α → α → α} (h : ∀ a b, f a b = a ∨ f a b = b) :
|
||||
∀ o₁ o₂, liftOrGet f o₁ o₂ = o₁ ∨ liftOrGet f o₁ o₂ = o₂
|
||||
| none, none => .inl rfl
|
||||
| some _, none => .inl rfl
|
||||
| none, some _ => .inr rfl
|
||||
| some a, none => .inl rfl
|
||||
| none, some b => .inr rfl
|
||||
| some a, some b => by have := h a b; simp [liftOrGet] at this ⊢; exact this
|
||||
|
||||
@[simp] theorem liftOrGet_none_left {f} {b : Option α} : liftOrGet f none b = b := by
|
||||
@@ -372,8 +350,6 @@ end choice
|
||||
|
||||
@[simp] theorem toList_none (α : Type _) : (none : Option α).toList = [] := rfl
|
||||
|
||||
-- See `Init.Data.Option.List` for lemmas about `toList`.
|
||||
|
||||
@[simp] theorem or_some : (some a).or o = some a := rfl
|
||||
@[simp] theorem none_or : none.or o = o := rfl
|
||||
|
||||
|
||||
@@ -1,14 +0,0 @@
|
||||
/-
|
||||
Copyright (c) 2024 Lean FRO. All rights reserved.
|
||||
Released under Apache 2.0 license as described in the file LICENSE.
|
||||
Authors: Kim Morrison
|
||||
-/
|
||||
prelude
|
||||
import Init.Data.List.Lemmas
|
||||
|
||||
namespace Option
|
||||
|
||||
@[simp] theorem mem_toList {a : α} {o : Option α} : a ∈ o.toList ↔ a ∈ o := by
|
||||
cases o <;> simp [eq_comm]
|
||||
|
||||
end Option
|
||||
@@ -322,7 +322,7 @@ theorem lt_next (s : String) (i : Pos) : i.1 < (s.next i).1 :=
|
||||
|
||||
theorem utf8PrevAux_lt_of_pos : ∀ (cs : List Char) (i p : Pos), p ≠ 0 →
|
||||
(utf8PrevAux cs i p).1 < p.1
|
||||
| [], _, _, h =>
|
||||
| [], i, p, h =>
|
||||
Nat.lt_of_le_of_lt (Nat.zero_le _)
|
||||
(Nat.zero_lt_of_ne_zero (mt (congrArg Pos.mk) h))
|
||||
| c::cs, i, p, h => by
|
||||
|
||||
@@ -352,10 +352,10 @@ theorem not_forall_of_exists_not {p : α → Prop} : (∃ x, ¬p x) → ¬∀ x,
|
||||
@[simp] theorem exists_or_eq_left' (y : α) (p : α → Prop) : ∃ x : α, y = x ∨ p x := ⟨y, .inl rfl⟩
|
||||
@[simp] theorem exists_or_eq_right' (y : α) (p : α → Prop) : ∃ x : α, p x ∨ y = x := ⟨y, .inr rfl⟩
|
||||
|
||||
theorem exists_prop' {p : Prop} : (∃ _ : α, p) ↔ Nonempty α ∧ p :=
|
||||
@[simp] theorem exists_prop' {p : Prop} : (∃ _ : α, p) ↔ Nonempty α ∧ p :=
|
||||
⟨fun ⟨a, h⟩ => ⟨⟨a⟩, h⟩, fun ⟨⟨a⟩, h⟩ => ⟨a, h⟩⟩
|
||||
|
||||
@[simp] theorem exists_prop : (∃ _h : a, b) ↔ a ∧ b :=
|
||||
theorem exists_prop : (∃ _h : a, b) ↔ a ∧ b :=
|
||||
⟨fun ⟨hp, hq⟩ => ⟨hp, hq⟩, fun ⟨hp, hq⟩ => ⟨hp, hq⟩⟩
|
||||
|
||||
@[simp] theorem exists_apply_eq_apply (f : α → β) (a' : α) : ∃ a, f a = f a' := ⟨a', rfl⟩
|
||||
@@ -458,7 +458,7 @@ theorem Decidable.imp_iff_not_or [Decidable a] : (a → b) ↔ (¬a ∨ b) :=
|
||||
theorem Decidable.imp_iff_or_not [Decidable b] : b → a ↔ a ∨ ¬b :=
|
||||
Decidable.imp_iff_not_or.trans or_comm
|
||||
|
||||
theorem Decidable.imp_or [Decidable a] : (a → b ∨ c) ↔ (a → b) ∨ (a → c) :=
|
||||
theorem Decidable.imp_or [h : Decidable a] : (a → b ∨ c) ↔ (a → b) ∨ (a → c) :=
|
||||
if h : a then by
|
||||
rw [imp_iff_right h, imp_iff_right h, imp_iff_right h]
|
||||
else by
|
||||
|
||||
@@ -399,19 +399,6 @@ example (a b c d : Nat) : a + b + c + d = d + (b + c) + a := by ac_rfl
|
||||
-/
|
||||
syntax (name := acRfl) "ac_rfl" : tactic
|
||||
|
||||
/--
|
||||
`ac_nf` normalizes equalities up to application of an associative and commutative operator.
|
||||
```
|
||||
instance : Associative (α := Nat) (.+.) := ⟨Nat.add_assoc⟩
|
||||
instance : Commutative (α := Nat) (.+.) := ⟨Nat.add_comm⟩
|
||||
|
||||
example (a b c d : Nat) : a + b + c + d = d + (b + c) + a := by
|
||||
ac_nf
|
||||
-- goal: a + (b + (c + d)) = a + (b + (c + d))
|
||||
```
|
||||
-/
|
||||
syntax (name := acNf) "ac_nf" : tactic
|
||||
|
||||
/--
|
||||
The `sorry` tactic closes the goal using `sorryAx`. This is intended for stubbing out incomplete
|
||||
parts of a proof while still having a syntactically correct proof skeleton. Lean will give
|
||||
@@ -801,7 +788,7 @@ syntax inductionAlt := ppDedent(ppLine) inductionAltLHS+ " => " (hole <|> synth
|
||||
After `with`, there is an optional tactic that runs on all branches, and
|
||||
then a list of alternatives.
|
||||
-/
|
||||
syntax inductionAlts := " with" (ppSpace colGt tactic)? withPosition((colGe inductionAlt)+)
|
||||
syntax inductionAlts := " with" (ppSpace tactic)? withPosition((colGe inductionAlt)+)
|
||||
|
||||
/--
|
||||
Assuming `x` is a variable in the local context with an inductive type,
|
||||
|
||||
@@ -249,8 +249,8 @@ theorem lex_def {r : α → α → Prop} {s : β → β → Prop} {p q : α ×
|
||||
Prod.Lex r s p q ↔ r p.1 q.1 ∨ p.1 = q.1 ∧ s p.2 q.2 :=
|
||||
⟨fun h => by cases h <;> simp [*], fun h =>
|
||||
match p, q, h with
|
||||
| _, _, Or.inl h => Lex.left _ _ h
|
||||
| (_, _), (_, _), Or.inr ⟨e, h⟩ => by subst e; exact Lex.right _ h⟩
|
||||
| (a, b), (c, d), Or.inl h => Lex.left _ _ h
|
||||
| (a, b), (c, d), Or.inr ⟨e, h⟩ => by subst e; exact Lex.right _ h⟩
|
||||
|
||||
namespace Lex
|
||||
|
||||
|
||||
@@ -305,16 +305,15 @@ def registerAttributeImplBuilder (builderId : Name) (builder : AttributeImplBuil
|
||||
if table.contains builderId then throw (IO.userError ("attribute implementation builder '" ++ toString builderId ++ "' has already been declared"))
|
||||
attributeImplBuilderTableRef.modify fun table => table.insert builderId builder
|
||||
|
||||
structure AttributeExtensionOLeanEntry where
|
||||
builderId : Name
|
||||
ref : Name
|
||||
args : List DataValue
|
||||
|
||||
def mkAttributeImplOfEntry (e : AttributeExtensionOLeanEntry) : IO AttributeImpl := do
|
||||
def mkAttributeImplOfBuilder (builderId ref : Name) (args : List DataValue) : IO AttributeImpl := do
|
||||
let table ← attributeImplBuilderTableRef.get
|
||||
match table[e.builderId]? with
|
||||
| none => throw (IO.userError ("unknown attribute implementation builder '" ++ toString e.builderId ++ "'"))
|
||||
| some builder => IO.ofExcept <| builder e.ref e.args
|
||||
match table[builderId]? with
|
||||
| none => throw (IO.userError ("unknown attribute implementation builder '" ++ toString builderId ++ "'"))
|
||||
| some builder => IO.ofExcept <| builder ref args
|
||||
|
||||
inductive AttributeExtensionOLeanEntry where
|
||||
| decl (declName : Name) -- `declName` has type `AttributeImpl`
|
||||
| builder (builderId ref : Name) (args : List DataValue)
|
||||
|
||||
structure AttributeExtensionState where
|
||||
newEntries : List AttributeExtensionOLeanEntry := []
|
||||
@@ -338,13 +337,19 @@ unsafe def mkAttributeImplOfConstantUnsafe (env : Environment) (opts : Options)
|
||||
@[implemented_by mkAttributeImplOfConstantUnsafe]
|
||||
opaque mkAttributeImplOfConstant (env : Environment) (opts : Options) (declName : Name) : Except String AttributeImpl
|
||||
|
||||
def mkAttributeImplOfEntry (env : Environment) (opts : Options) (e : AttributeExtensionOLeanEntry) : IO AttributeImpl :=
|
||||
match e with
|
||||
| .decl declName => IO.ofExcept <| mkAttributeImplOfConstant env opts declName
|
||||
| .builder builderId ref args => mkAttributeImplOfBuilder builderId ref args
|
||||
|
||||
private def AttributeExtension.addImported (es : Array (Array AttributeExtensionOLeanEntry)) : ImportM AttributeExtensionState := do
|
||||
let ctx ← read
|
||||
let map ← attributeMapRef.get
|
||||
let map ← es.foldlM
|
||||
(fun map entries =>
|
||||
entries.foldlM
|
||||
(fun (map : Std.HashMap Name AttributeImpl) entry => do
|
||||
let attrImpl ← mkAttributeImplOfEntry entry
|
||||
let attrImpl ← mkAttributeImplOfEntry ctx.env ctx.opts entry
|
||||
return map.insert attrImpl.name attrImpl)
|
||||
map)
|
||||
map
|
||||
@@ -395,13 +400,19 @@ def getAttributeImpl (env : Environment) (attrName : Name) : Except String Attri
|
||||
| some attr => pure attr
|
||||
| none => throw ("unknown attribute '" ++ toString attrName ++ "'")
|
||||
|
||||
def registerAttributeOfDecl (env : Environment) (opts : Options) (attrDeclName : Name) : Except String Environment := do
|
||||
let attrImpl ← mkAttributeImplOfConstant env opts attrDeclName
|
||||
if isAttribute env attrImpl.name then
|
||||
throw ("invalid builtin attribute declaration, '" ++ toString attrImpl.name ++ "' has already been used")
|
||||
else
|
||||
return attributeExtension.addEntry env (.decl attrDeclName, attrImpl)
|
||||
|
||||
def registerAttributeOfBuilder (env : Environment) (builderId ref : Name) (args : List DataValue) : IO Environment := do
|
||||
let entry := {builderId, ref, args}
|
||||
let attrImpl ← mkAttributeImplOfEntry entry
|
||||
let attrImpl ← mkAttributeImplOfBuilder builderId ref args
|
||||
if isAttribute env attrImpl.name then
|
||||
throw (IO.userError ("invalid builtin attribute declaration, '" ++ toString attrImpl.name ++ "' has already been used"))
|
||||
else
|
||||
return attributeExtension.addEntry env (entry, attrImpl)
|
||||
return attributeExtension.addEntry env (.builder builderId ref args, attrImpl)
|
||||
|
||||
def Attribute.add (declName : Name) (attrName : Name) (stx : Syntax) (kind := AttributeKind.global) : AttrM Unit := do
|
||||
let attr ← ofExcept <| getAttributeImpl (← getEnv) attrName
|
||||
|
||||
@@ -20,18 +20,18 @@ def ensureHasDefault (alts : Array Alt) : Array Alt :=
|
||||
private def getOccsOf (alts : Array Alt) (i : Nat) : Nat := Id.run do
|
||||
let aBody := (alts.get! i).body
|
||||
let mut n := 1
|
||||
for h : j in [i+1:alts.size] do
|
||||
if alts[j].body == aBody then
|
||||
for j in [i+1:alts.size] do
|
||||
if alts[j]!.body == aBody then
|
||||
n := n+1
|
||||
return n
|
||||
|
||||
private def maxOccs (alts : Array Alt) : Alt × Nat := Id.run do
|
||||
let mut maxAlt := alts[0]!
|
||||
let mut max := getOccsOf alts 0
|
||||
for h : i in [1:alts.size] do
|
||||
for i in [1:alts.size] do
|
||||
let curr := getOccsOf alts i
|
||||
if curr > max then
|
||||
maxAlt := alts[i]
|
||||
maxAlt := alts[i]!
|
||||
max := curr
|
||||
return (maxAlt, max)
|
||||
|
||||
|
||||
@@ -110,8 +110,8 @@ def isCtorParam (f : Expr) (i : Nat) : CoreM Bool := do
|
||||
def checkAppArgs (f : Expr) (args : Array Arg) : CheckM Unit := do
|
||||
let mut fType ← inferType f
|
||||
let mut j := 0
|
||||
for h : i in [:args.size] do
|
||||
let arg := args[i]
|
||||
for i in [:args.size] do
|
||||
let arg := args[i]!
|
||||
if fType.isErased then
|
||||
return ()
|
||||
fType := fType.headBeta
|
||||
|
||||
@@ -505,8 +505,8 @@ ones. Return whether any `Value` got updated in the process.
|
||||
-/
|
||||
def inferStep : InterpM Bool := do
|
||||
let ctx ← read
|
||||
for h : idx in [0:ctx.decls.size] do
|
||||
let decl := ctx.decls[idx]
|
||||
for idx in [0:ctx.decls.size] do
|
||||
let decl := ctx.decls[idx]!
|
||||
if !decl.safe then
|
||||
continue
|
||||
|
||||
|
||||
@@ -48,8 +48,8 @@ def hasTrivialStructure? (declName : Name) : CoreM (Option TrivialStructureInfo)
|
||||
let [ctorName] := info.ctors | return none
|
||||
let mask ← getRelevantCtorFields ctorName
|
||||
let mut result := none
|
||||
for h : i in [:mask.size] do
|
||||
if mask[i] then
|
||||
for i in [:mask.size] do
|
||||
if mask[i]! then
|
||||
if result.isSome then return none
|
||||
result := some { ctorName, fieldIdx := i, numParams := info.numParams }
|
||||
return result
|
||||
@@ -129,4 +129,4 @@ def getOtherDeclMonoType (declName : Name) : CoreM Expr := do
|
||||
modifyEnv fun env => monoTypeExt.modifyState env fun s => { s with mono := s.mono.insert declName type }
|
||||
return type
|
||||
|
||||
end Lean.Compiler.LCNF
|
||||
end Lean.Compiler.LCNF
|
||||
@@ -96,9 +96,9 @@ where
|
||||
unless (← visited i) do
|
||||
modify fun (k, visited) => (k, visited.set! i true)
|
||||
let pi := ps[i]!
|
||||
for h : j in [:ps.size] do
|
||||
for j in [:ps.size] do
|
||||
unless (← visited j) do
|
||||
let pj := ps[j]
|
||||
let pj := ps[j]!
|
||||
if pj.used.contains pi.decl.fvarId then
|
||||
visit j
|
||||
modify fun (k, visited) => (pi.attach k, visited)
|
||||
|
||||
@@ -18,10 +18,10 @@ or not.
|
||||
private def getMaxOccs (alts : Array Alt) : Alt × Nat := Id.run do
|
||||
let mut maxAlt := alts[0]!
|
||||
let mut max := getNumOccsOf alts 0
|
||||
for h : i in [1:alts.size] do
|
||||
for i in [1:alts.size] do
|
||||
let curr := getNumOccsOf alts i
|
||||
if curr > max then
|
||||
maxAlt := alts[i]
|
||||
maxAlt := alts[i]!
|
||||
max := curr
|
||||
return (maxAlt, max)
|
||||
where
|
||||
@@ -34,8 +34,8 @@ where
|
||||
getNumOccsOf (alts : Array Alt) (i : Nat) : Nat := Id.run do
|
||||
let code := alts[i]!.getCode
|
||||
let mut n := 1
|
||||
for h : j in [i+1:alts.size] do
|
||||
if Code.alphaEqv alts[j].getCode code then
|
||||
for j in [i+1:alts.size] do
|
||||
if Code.alphaEqv alts[j]!.getCode code then
|
||||
n := n+1
|
||||
return n
|
||||
|
||||
|
||||
@@ -121,8 +121,8 @@ where
|
||||
let mut paramsNew := #[]
|
||||
let singleton : FVarIdSet := ({} : FVarIdSet).insert params[targetParamIdx]!.fvarId
|
||||
let dependsOnDiscr := k.dependsOn singleton || decls.any (·.dependsOn singleton)
|
||||
for h : i in [:params.size] do
|
||||
let param := params[i]
|
||||
for i in [:params.size] do
|
||||
let param := params[i]!
|
||||
if targetParamIdx == i then
|
||||
if dependsOnDiscr then
|
||||
paramsNew := paramsNew.push (← internalizeParam param)
|
||||
@@ -300,3 +300,4 @@ builtin_initialize
|
||||
registerTraceClass `Compiler.simp.jpCases
|
||||
|
||||
end Lean.Compiler.LCNF
|
||||
|
||||
|
||||
@@ -129,9 +129,9 @@ See comment at `.fixedNeutral`.
|
||||
-/
|
||||
private def hasFwdDeps (decl : Decl) (paramsInfo : Array SpecParamInfo) (j : Nat) : Bool := Id.run do
|
||||
let param := decl.params[j]!
|
||||
for h : k in [j+1 : decl.params.size] do
|
||||
for k in [j+1 : decl.params.size] do
|
||||
if paramsInfo[k]! matches .user | .fixedHO | .fixedInst then
|
||||
let param' := decl.params[k]
|
||||
let param' := decl.params[k]!
|
||||
if param'.type.containsFVar param.fvarId then
|
||||
return true
|
||||
return false
|
||||
@@ -214,3 +214,4 @@ builtin_initialize
|
||||
registerTraceClass `Compiler.specialize.info
|
||||
|
||||
end Lean.Compiler.LCNF
|
||||
|
||||
|
||||
@@ -50,9 +50,9 @@ partial def inlineMatchers (e : Expr) : CoreM Expr :=
|
||||
let numAlts := info.numAlts
|
||||
let altNumParams := info.altNumParams
|
||||
let rec inlineMatcher (i : Nat) (args : Array Expr) (letFVars : Array Expr) : MetaM Expr := do
|
||||
if h : i < numAlts then
|
||||
if i < numAlts then
|
||||
let altIdx := i + info.getFirstAltPos
|
||||
let numParams := altNumParams[i]
|
||||
let numParams := altNumParams[i]!
|
||||
let alt ← normalizeAlt args[altIdx]! numParams
|
||||
Meta.withLetDecl (← mkFreshUserName `_alt) (← Meta.inferType alt) alt fun altFVar =>
|
||||
inlineMatcher (i+1) (args.set! altIdx altFVar) (letFVars.push altFVar)
|
||||
|
||||
@@ -411,23 +411,21 @@ private def finalize : M Expr := do
|
||||
synthesizeAppInstMVars
|
||||
return e
|
||||
|
||||
/--
|
||||
Returns a named argument that depends on the next argument, otherwise `none`.
|
||||
-/
|
||||
private def findNamedArgDependsOnCurrent? : M (Option NamedArg) := do
|
||||
/-- Return `true` if there is a named argument that depends on the next argument. -/
|
||||
private def anyNamedArgDependsOnCurrent : M Bool := do
|
||||
let s ← get
|
||||
if s.namedArgs.isEmpty then
|
||||
return none
|
||||
return false
|
||||
else
|
||||
forallTelescopeReducing s.fType fun xs _ => do
|
||||
let curr := xs[0]!
|
||||
for h : i in [1:xs.size] do
|
||||
let xDecl ← xs[i].fvarId!.getDecl
|
||||
if let some arg := s.namedArgs.find? fun arg => arg.name == xDecl.userName then
|
||||
for i in [1:xs.size] do
|
||||
let xDecl ← xs[i]!.fvarId!.getDecl
|
||||
if s.namedArgs.any fun arg => arg.name == xDecl.userName then
|
||||
/- Remark: a default value at `optParam` does not count as a dependency -/
|
||||
if (← exprDependsOn xDecl.type.cleanupAnnotations curr.fvarId!) then
|
||||
return arg
|
||||
return none
|
||||
return true
|
||||
return false
|
||||
|
||||
|
||||
/-- Return `true` if there are regular or named arguments to be processed. -/
|
||||
@@ -435,13 +433,11 @@ private def hasArgsToProcess : M Bool := do
|
||||
let s ← get
|
||||
return !s.args.isEmpty || !s.namedArgs.isEmpty
|
||||
|
||||
/--
|
||||
Returns the argument syntax if the next argument at `args` is of the form `_`.
|
||||
-/
|
||||
private def nextArgHole? : M (Option Syntax) := do
|
||||
/-- Return `true` if the next argument at `args` is of the form `_` -/
|
||||
private def isNextArgHole : M Bool := do
|
||||
match (← get).args with
|
||||
| Arg.stx stx@(Syntax.node _ ``Lean.Parser.Term.hole _) :: _ => pure stx
|
||||
| _ => pure none
|
||||
| Arg.stx (Syntax.node _ ``Lean.Parser.Term.hole _) :: _ => pure true
|
||||
| _ => pure false
|
||||
|
||||
/--
|
||||
Return `true` if the next argument to be processed is the outparam of a local instance, and it the result type
|
||||
@@ -516,9 +512,8 @@ where
|
||||
|
||||
mutual
|
||||
/--
|
||||
Create a fresh local variable with the current binder name and argument type, add it to `etaArgs` and `f`,
|
||||
and then execute the main loop.
|
||||
-/
|
||||
Create a fresh local variable with the current binder name and argument type, add it to `etaArgs` and `f`,
|
||||
and then execute the main loop.-/
|
||||
private partial def addEtaArg (argName : Name) : M Expr := do
|
||||
let n ← getBindingName
|
||||
let type ← getArgExpectedType
|
||||
@@ -527,9 +522,6 @@ mutual
|
||||
addNewArg argName x
|
||||
main
|
||||
|
||||
/--
|
||||
Create a fresh metavariable for the implicit argument, add it to `f`, and thn execute the main loop.
|
||||
-/
|
||||
private partial def addImplicitArg (argName : Name) : M Expr := do
|
||||
let argType ← getArgExpectedType
|
||||
let arg ← if (← isNextOutParamOfLocalInstanceAndResult) then
|
||||
@@ -547,47 +539,35 @@ mutual
|
||||
main
|
||||
|
||||
/--
|
||||
Process a `fType` of the form `(x : A) → B x`.
|
||||
This method assume `fType` is a function type.
|
||||
-/
|
||||
Process a `fType` of the form `(x : A) → B x`.
|
||||
This method assume `fType` is a function type -/
|
||||
private partial def processExplicitArg (argName : Name) : M Expr := do
|
||||
match (← get).args with
|
||||
| arg::args =>
|
||||
-- Note: currently the following test never succeeds in explicit mode since `@x.f` notation does not exist.
|
||||
if let some true := NamedArg.suppressDeps <$> (← findNamedArgDependsOnCurrent?) then
|
||||
if (← anyNamedArgDependsOnCurrent) then
|
||||
/-
|
||||
We treat the explicit argument `argName` as implicit
|
||||
if we have a named arguments that depends on it whose `suppressDeps` flag set to `true`.
|
||||
The motivation for this is class projections (issue #1851).
|
||||
In some cases, class projections can have explicit parameters. For example, in
|
||||
We treat the explicit argument `argName` as implicit if we have named arguments that depend on it.
|
||||
The idea is that this explicit argument can be inferred using the type of the named argument one.
|
||||
Note that we also use this approach in the branch where there are no explicit arguments left.
|
||||
This is important to make sure the system behaves in a uniform way.
|
||||
Moreover, users rely on this behavior. For example, consider the example on issue #1851
|
||||
```
|
||||
class Approx {α : Type} (a : α) (X : Type) : Type where
|
||||
val : X
|
||||
```
|
||||
the type of `Approx.val` is `{α : Type} → (a : α) → {X : Type} → [self : Approx a X] → X`.
|
||||
Note that the parameter `a` is explicit since there is no way to infer it from the expected
|
||||
type or from the types of other explicit parameters.
|
||||
Being a parameter of the class, `a` is determined by the type of `self`.
|
||||
|
||||
Consider
|
||||
```
|
||||
variable {α β X Y : Type} {f' : α → β} {x' : α} [f : Approx f' (X → Y)]
|
||||
```
|
||||
Recall that `f.val` is, to first approximation, sugar for `Approx.val (self := f)`.
|
||||
Without further refinement, this would expand to `fun f'' : α → β => Approx.val f'' f`,
|
||||
which is a type error, since `f''` must be defeq to `f'`.
|
||||
Furthermore, with projection notation, users expect all structure parameters
|
||||
to be uniformly implicit; after all, they are determined by `self`.
|
||||
To handle this, the `(self := f)` named argument is annotated with the `suppressDeps` flag.
|
||||
This causes the `a` parameter to become implicit, and `f.val` instead expands to `Approx.val f' f`.
|
||||
variable {α β X Y : Type} {f' : α → β} {x' : α} [f : Approx f' (X → Y)] [x : Approx x' X]
|
||||
|
||||
This feature previously was enabled for *all* explicit arguments, which confused users
|
||||
and was frequently reported as a bug (issue #1867).
|
||||
Now it is only enabled for the `self` argument in structure projections.
|
||||
|
||||
We used to do this only when `(← get).args` was empty,
|
||||
but it created an asymmetry because `f.val` worked as expected,
|
||||
yet one would have to write `f.val _ x` when there are further arguments.
|
||||
#check f.val
|
||||
#check f.val x.val
|
||||
```
|
||||
The type of `Approx.val` is `{α : Type} → (a : α) → {X : Type} → [self : Approx a X] → X`
|
||||
Note that the argument `a` is explicit since there is no way to infer it from the expected
|
||||
type or the type of other explicit arguments.
|
||||
Recall that `f.val` is sugar for `Approx.val (self := f)`. In both `#check` commands above
|
||||
the user assumed that `a` does not need to be provided since it can be inferred from the type
|
||||
of `self`.
|
||||
We used to that only in the branch where `(← get).args` was empty, but it created an asymmetry
|
||||
because `#check f.val` worked as expected, but one would have to write `#check f.val _ x.val`
|
||||
-/
|
||||
return (← addImplicitArg argName)
|
||||
propagateExpectedType arg
|
||||
@@ -604,6 +584,7 @@ mutual
|
||||
match evalSyntaxConstant env opts tacticDecl with
|
||||
| Except.error err => throwError err
|
||||
| Except.ok tacticSyntax =>
|
||||
-- TODO(Leo): does this work correctly for tactic sequences?
|
||||
let tacticBlock ← `(by $(⟨tacticSyntax⟩))
|
||||
/-
|
||||
We insert position information from the current ref into `stx` everywhere, simulating this being
|
||||
@@ -615,32 +596,24 @@ mutual
|
||||
-/
|
||||
let info := (← getRef).getHeadInfo
|
||||
let tacticBlock := tacticBlock.raw.rewriteBottomUp (·.setInfo info)
|
||||
let mvar ← mkTacticMVar argType.consumeTypeAnnotations tacticBlock (.autoParam argName)
|
||||
-- Note(kmill): We are adding terminfo to simulate a previous implementation that elaborated `tacticBlock`.
|
||||
-- We should look into removing this since terminfo for synthetic syntax is suspect,
|
||||
-- but we noted it was necessary to preserve the behavior of the unused variable linter.
|
||||
addTermInfo' tacticBlock mvar
|
||||
let argNew := Arg.expr mvar
|
||||
let argNew := Arg.stx tacticBlock
|
||||
propagateExpectedType argNew
|
||||
elabAndAddNewArg argName argNew
|
||||
main
|
||||
| false, _, some _ =>
|
||||
throwError "invalid autoParam, argument must be a constant"
|
||||
| _, _, _ =>
|
||||
if (← read).ellipsis then
|
||||
addImplicitArg argName
|
||||
else if !(← get).namedArgs.isEmpty then
|
||||
if let some _ ← findNamedArgDependsOnCurrent? then
|
||||
/-
|
||||
Dependencies of named arguments cannot be turned into eta arguments
|
||||
since they are determined by the named arguments.
|
||||
Instead we can turn them into implicit arguments.
|
||||
-/
|
||||
if !(← get).namedArgs.isEmpty then
|
||||
if (← anyNamedArgDependsOnCurrent) then
|
||||
addImplicitArg argName
|
||||
else if (← read).ellipsis then
|
||||
addImplicitArg argName
|
||||
else
|
||||
addEtaArg argName
|
||||
else if !(← read).explicit then
|
||||
if (← fTypeHasOptAutoParams) then
|
||||
if (← read).ellipsis then
|
||||
addImplicitArg argName
|
||||
else if (← fTypeHasOptAutoParams) then
|
||||
addEtaArg argName
|
||||
else
|
||||
finalize
|
||||
@@ -668,30 +641,24 @@ mutual
|
||||
finalize
|
||||
|
||||
/--
|
||||
Process a `fType` of the form `[x : A] → B x`.
|
||||
This method assume `fType` is a function type.
|
||||
-/
|
||||
Process a `fType` of the form `[x : A] → B x`.
|
||||
This method assume `fType` is a function type -/
|
||||
private partial def processInstImplicitArg (argName : Name) : M Expr := do
|
||||
if (← read).explicit then
|
||||
if let some stx ← nextArgHole? then
|
||||
-- We still use typeclass resolution for `_` arguments.
|
||||
-- This behavior can be suppressed with `(_)`.
|
||||
let ty ← getArgExpectedType
|
||||
let arg ← mkInstMVar ty
|
||||
addTermInfo' stx arg ty
|
||||
if (← isNextArgHole) then
|
||||
/- Recall that if '@' has been used, and the argument is '_', then we still use type class resolution -/
|
||||
let arg ← mkFreshExprMVar (← getArgExpectedType) MetavarKind.synthetic
|
||||
modify fun s => { s with args := s.args.tail! }
|
||||
addInstMVar arg.mvarId!
|
||||
addNewArg argName arg
|
||||
main
|
||||
else
|
||||
processExplicitArg argName
|
||||
else
|
||||
discard <| mkInstMVar (← getArgExpectedType)
|
||||
main
|
||||
where
|
||||
mkInstMVar (ty : Expr) : M Expr := do
|
||||
let arg ← mkFreshExprMVar ty MetavarKind.synthetic
|
||||
let arg ← mkFreshExprMVar (← getArgExpectedType) MetavarKind.synthetic
|
||||
addInstMVar arg.mvarId!
|
||||
addNewArg argName arg
|
||||
return arg
|
||||
main
|
||||
|
||||
/-- Elaborate function application arguments. -/
|
||||
partial def main : M Expr := do
|
||||
@@ -722,104 +689,6 @@ end
|
||||
|
||||
end ElabAppArgs
|
||||
|
||||
|
||||
/-! # Eliminator-like function application elaborator -/
|
||||
|
||||
/--
|
||||
Information about an eliminator used by the elab-as-elim elaborator.
|
||||
This is not to be confused with `Lean.Meta.ElimInfo`, which is for `induction` and `cases`.
|
||||
The elab-as-elim routine is less restrictive in what counts as an eliminator, and it doesn't need
|
||||
to have a strict notion of what is a "target" — all it cares about are
|
||||
1. that the return type of a function is of the form `m ...` where `m` is a parameter
|
||||
(unlike `induction` and `cases` eliminators, the arguments to `m`, known as "discriminants",
|
||||
can be any expressions, not just parameters), and
|
||||
2. which arguments should be eagerly elaborated, to make discriminants be as elaborated as
|
||||
possible for the expected type generalization procedure,
|
||||
and which should be postponed (since they are the "minor premises").
|
||||
|
||||
Note that the routine isn't doing induction/cases *on* particular expressions.
|
||||
The purpose of elab-as-elim is to successfully solve the higher-order unification problem
|
||||
between the return type of the function and the expected type.
|
||||
-/
|
||||
structure ElabElimInfo where
|
||||
/-- The eliminator. -/
|
||||
elimExpr : Expr
|
||||
/-- The type of the eliminator. -/
|
||||
elimType : Expr
|
||||
/-- The position of the motive parameter. -/
|
||||
motivePos : Nat
|
||||
/--
|
||||
Positions of "major" parameters (those that should be eagerly elaborated
|
||||
because they can contribute to the motive inference procedure).
|
||||
All parameters that are neither the motive nor a major parameter are "minor" parameters.
|
||||
The major parameters include all of the parameters that transitively appear in the motive's arguments,
|
||||
as well as "first-order" arguments that include such parameters,
|
||||
since they too can help with elaborating discriminants.
|
||||
|
||||
For example, in the following theorem the argument `h : a = b`
|
||||
should be elaborated eagerly because it contains `b`, which occurs in `motive b`.
|
||||
```
|
||||
theorem Eq.subst' {α} {motive : α → Prop} {a b : α} (h : a = b) : motive a → motive b
|
||||
```
|
||||
For another example, the term `isEmptyElim (α := α)` is an underapplied eliminator, and it needs
|
||||
argument `α` to be elaborated eagerly to create a type-correct motive.
|
||||
```
|
||||
def isEmptyElim [IsEmpty α] {p : α → Sort _} (a : α) : p a := ...
|
||||
example {α : Type _} [IsEmpty α] : id (α → False) := isEmptyElim (α := α)
|
||||
```
|
||||
-/
|
||||
majorsPos : Array Nat := #[]
|
||||
deriving Repr, Inhabited
|
||||
|
||||
def getElabElimExprInfo (elimExpr : Expr) : MetaM ElabElimInfo := do
|
||||
let elimType ← inferType elimExpr
|
||||
trace[Elab.app.elab_as_elim] "eliminator {indentExpr elimExpr}\nhas type{indentExpr elimType}"
|
||||
forallTelescopeReducing elimType fun xs type => do
|
||||
let motive := type.getAppFn
|
||||
let motiveArgs := type.getAppArgs
|
||||
unless motive.isFVar do
|
||||
throwError "unexpected eliminator resulting type{indentExpr type}"
|
||||
let motiveType ← inferType motive
|
||||
forallTelescopeReducing motiveType fun motiveParams motiveResultType => do
|
||||
unless motiveParams.size == motiveArgs.size do
|
||||
throwError "unexpected number of arguments at motive type{indentExpr motiveType}"
|
||||
unless motiveResultType.isSort do
|
||||
throwError "motive result type must be a sort{indentExpr motiveType}"
|
||||
let some motivePos ← pure (xs.indexOf? motive) |
|
||||
throwError "unexpected eliminator type{indentExpr elimType}"
|
||||
/-
|
||||
Compute transitive closure of fvars appearing in arguments to the motive.
|
||||
These are the primary set of major parameters.
|
||||
-/
|
||||
let initMotiveFVars : CollectFVars.State := motiveArgs.foldl (init := {}) collectFVars
|
||||
let motiveFVars ← xs.size.foldRevM (init := initMotiveFVars) fun i s => do
|
||||
let x := xs[i]!
|
||||
if s.fvarSet.contains x.fvarId! then
|
||||
return collectFVars s (← inferType x)
|
||||
else
|
||||
return s
|
||||
/- Collect the major parameter positions -/
|
||||
let mut majorsPos := #[]
|
||||
for h : i in [:xs.size] do
|
||||
let x := xs[i]
|
||||
unless motivePos == i do
|
||||
let xType ← x.fvarId!.getType
|
||||
/-
|
||||
We also consider "first-order" types because we can reliably "extract" information from them.
|
||||
We say a term is "first-order" if all applications are of the form `f ...` where `f` is a constant.
|
||||
-/
|
||||
let isFirstOrder (e : Expr) : Bool := Option.isNone <| e.find? fun e => e.isApp && !e.getAppFn.isConst
|
||||
if motiveFVars.fvarSet.contains x.fvarId!
|
||||
|| (isFirstOrder xType
|
||||
&& Option.isSome (xType.find? fun e => e.isFVar && motiveFVars.fvarSet.contains e.fvarId!)) then
|
||||
majorsPos := majorsPos.push i
|
||||
trace[Elab.app.elab_as_elim] "motivePos: {motivePos}"
|
||||
trace[Elab.app.elab_as_elim] "majorsPos: {majorsPos}"
|
||||
return { elimExpr, elimType, motivePos, majorsPos }
|
||||
|
||||
def getElabElimInfo (elimName : Name) : MetaM ElabElimInfo := do
|
||||
getElabElimExprInfo (← mkConstWithFreshMVarLevels elimName)
|
||||
|
||||
builtin_initialize elabAsElim : TagAttribute ←
|
||||
registerTagAttribute `elab_as_elim
|
||||
"instructs elaborator that the arguments of the function application should be elaborated as were an eliminator"
|
||||
@@ -834,15 +703,33 @@ builtin_initialize elabAsElim : TagAttribute ←
|
||||
let info ← getConstInfo declName
|
||||
if (← hasOptAutoParams info.type) then
|
||||
throwError "[elab_as_elim] attribute cannot be used in declarations containing optional and auto parameters"
|
||||
discard <| getElabElimInfo declName
|
||||
discard <| getElimInfo declName
|
||||
go.run' {} {}
|
||||
|
||||
/-! # Eliminator-like function application elaborator -/
|
||||
namespace ElabElim
|
||||
|
||||
/-- Context of the `elab_as_elim` elaboration procedure. -/
|
||||
structure Context where
|
||||
elimInfo : ElabElimInfo
|
||||
elimInfo : ElimInfo
|
||||
expectedType : Expr
|
||||
/--
|
||||
Position of additional arguments that should be elaborated eagerly
|
||||
because they can contribute to the motive inference procedure.
|
||||
For example, in the following theorem the argument `h : a = b`
|
||||
should be elaborated eagerly because it contains `b` which occurs
|
||||
in `motive b`.
|
||||
```
|
||||
theorem Eq.subst' {α} {motive : α → Prop} {a b : α} (h : a = b) : motive a → motive b
|
||||
```
|
||||
For another example, the term `isEmptyElim (α := α)` is an underapplied eliminator, and it needs
|
||||
argument `α` to be elaborated eagerly to create a type-correct motive.
|
||||
```
|
||||
def isEmptyElim [IsEmpty α] {p : α → Sort _} (a : α) : p a := ...
|
||||
example {α : Type _} [IsEmpty α] : id (α → False) := isEmptyElim (α := α)
|
||||
```
|
||||
-/
|
||||
extraArgsPos : Array Nat
|
||||
|
||||
/-- State of the `elab_as_elim` elaboration procedure. -/
|
||||
structure State where
|
||||
@@ -854,6 +741,8 @@ structure State where
|
||||
namedArgs : List NamedArg
|
||||
/-- User-provided arguments that still have to be processed. -/
|
||||
args : List Arg
|
||||
/-- Discriminants (targets) processed so far. -/
|
||||
discrs : Array (Option Expr)
|
||||
/-- Instance implicit arguments collected so far. -/
|
||||
instMVars : Array MVarId := #[]
|
||||
/-- Position of the next argument to be processed. We use it to decide whether the argument is the motive or a discriminant. -/
|
||||
@@ -899,7 +788,7 @@ def finalize : M Expr := do
|
||||
let some motive := (← get).motive?
|
||||
| throwError "failed to elaborate eliminator, insufficient number of arguments"
|
||||
trace[Elab.app.elab_as_elim] "motive: {motive}"
|
||||
forallTelescope (← get).fType fun xs fType => do
|
||||
forallTelescope (← get).fType fun xs _ => do
|
||||
trace[Elab.app.elab_as_elim] "xs: {xs}"
|
||||
let mut expectedType := (← read).expectedType
|
||||
trace[Elab.app.elab_as_elim] "expectedType:{indentD expectedType}"
|
||||
@@ -908,7 +797,6 @@ def finalize : M Expr := do
|
||||
let mut f := (← get).f
|
||||
if xs.size > 0 then
|
||||
-- under-application, specialize the expected type using `xs`
|
||||
-- Note: if we ever wanted to support optParams and autoParams, this is where it could be.
|
||||
assert! (← get).args.isEmpty
|
||||
for x in xs do
|
||||
let .forallE _ t b _ ← whnf expectedType | throwInsufficient
|
||||
@@ -925,11 +813,18 @@ def finalize : M Expr := do
|
||||
trace[Elab.app.elab_as_elim] "expectedType after processing:{indentD expectedType}"
|
||||
let result := mkAppN f xs
|
||||
trace[Elab.app.elab_as_elim] "result:{indentD result}"
|
||||
unless fType.getAppFn == (← get).motive? do
|
||||
throwError "Internal error, eliminator target type isn't an application of the motive"
|
||||
let discrs := fType.getAppArgs
|
||||
trace[Elab.app.elab_as_elim] "discrs: {discrs}"
|
||||
let motiveVal ← mkMotive discrs expectedType
|
||||
let mut discrs := (← get).discrs
|
||||
let idx := (← get).idx
|
||||
if discrs.any Option.isNone then
|
||||
for i in [idx:idx + xs.size], x in xs do
|
||||
if let some tidx := (← read).elimInfo.targetsPos.indexOf? i then
|
||||
discrs := discrs.set! tidx x
|
||||
if let some idx := discrs.findIdx? Option.isNone then
|
||||
-- This should not happen.
|
||||
trace[Elab.app.elab_as_elim] "Internal error, missing target with index {idx}"
|
||||
throwError "failed to elaborate eliminator, insufficient number of arguments"
|
||||
trace[Elab.app.elab_as_elim] "discrs: {discrs.map Option.get!}"
|
||||
let motiveVal ← mkMotive (discrs.map Option.get!) expectedType
|
||||
unless (← isTypeCorrect motiveVal) do
|
||||
throwError "failed to elaborate eliminator, motive is not type correct:{indentD motiveVal}"
|
||||
unless (← isDefEq motive motiveVal) do
|
||||
@@ -963,6 +858,10 @@ def getNextArg? (binderName : Name) (binderInfo : BinderInfo) : M (LOption Arg)
|
||||
def setMotive (motive : Expr) : M Unit :=
|
||||
modify fun s => { s with motive? := motive }
|
||||
|
||||
/-- Push the given expression into the `discrs` field in the state, where `i` is which target it is for. -/
|
||||
def addDiscr (i : Nat) (discr : Expr) : M Unit :=
|
||||
modify fun s => { s with discrs := s.discrs.set! i discr }
|
||||
|
||||
/-- Elaborate the given argument with the given expected type. -/
|
||||
private def elabArg (arg : Arg) (argExpectedType : Expr) : M Expr := do
|
||||
match arg with
|
||||
@@ -1005,13 +904,18 @@ partial def main : M Expr := do
|
||||
mkImplicitArg binderType binderInfo
|
||||
setMotive motive
|
||||
addArgAndContinue motive
|
||||
else if (← read).elimInfo.majorsPos.contains idx then
|
||||
else if let some tidx := (← read).elimInfo.targetsPos.indexOf? idx then
|
||||
match (← getNextArg? binderName binderInfo) with
|
||||
| .some arg => let discr ← elabArg arg binderType; addArgAndContinue discr
|
||||
| .some arg => let discr ← elabArg arg binderType; addDiscr tidx discr; addArgAndContinue discr
|
||||
| .undef => finalize
|
||||
| .none => let discr ← mkImplicitArg binderType binderInfo; addArgAndContinue discr
|
||||
| .none => let discr ← mkImplicitArg binderType binderInfo; addDiscr tidx discr; addArgAndContinue discr
|
||||
else match (← getNextArg? binderName binderInfo) with
|
||||
| .some (.stx stx) => addArgAndContinue (← postponeElabTerm stx binderType)
|
||||
| .some (.stx stx) =>
|
||||
if (← read).extraArgsPos.contains idx then
|
||||
let arg ← elabArg (.stx stx) binderType
|
||||
addArgAndContinue arg
|
||||
else
|
||||
addArgAndContinue (← postponeElabTerm stx binderType)
|
||||
| .some (.expr val) => addArgAndContinue (← ensureArgType (← get).f val binderType)
|
||||
| .undef => finalize
|
||||
| .none => addArgAndContinue (← mkImplicitArg binderType binderInfo)
|
||||
@@ -1065,10 +969,13 @@ def elabAppArgs (f : Expr) (namedArgs : Array NamedArg) (args : Array Arg)
|
||||
let some expectedType := expectedType? | throwError "failed to elaborate eliminator, expected type is not available"
|
||||
let expectedType ← instantiateMVars expectedType
|
||||
if expectedType.getAppFn.isMVar then throwError "failed to elaborate eliminator, expected type is not available"
|
||||
ElabElim.main.run { elimInfo, expectedType } |>.run' {
|
||||
let extraArgsPos ← getElabAsElimExtraArgsPos elimInfo
|
||||
trace[Elab.app.elab_as_elim] "extraArgsPos: {extraArgsPos}"
|
||||
ElabElim.main.run { elimInfo, expectedType, extraArgsPos } |>.run' {
|
||||
f, fType
|
||||
args := args.toList
|
||||
namedArgs := namedArgs.toList
|
||||
discrs := mkArray elimInfo.targetsPos.size none
|
||||
}
|
||||
else
|
||||
ElabAppArgs.main.run { explicit, ellipsis, resultIsOutParamSupport } |>.run' {
|
||||
@@ -1079,12 +986,12 @@ def elabAppArgs (f : Expr) (namedArgs : Array NamedArg) (args : Array Arg)
|
||||
}
|
||||
where
|
||||
/-- Return `some info` if we should elaborate as an eliminator. -/
|
||||
elabAsElim? : TermElabM (Option ElabElimInfo) := do
|
||||
elabAsElim? : TermElabM (Option ElimInfo) := do
|
||||
unless (← read).heedElabAsElim do return none
|
||||
if explicit || ellipsis then return none
|
||||
let .const declName _ := f | return none
|
||||
unless (← shouldElabAsElim declName) do return none
|
||||
let elimInfo ← getElabElimInfo declName
|
||||
let elimInfo ← getElimInfo declName
|
||||
forallTelescopeReducing (← inferType f) fun xs _ => do
|
||||
/- Process arguments similar to `Lean.Elab.Term.ElabElim.main` to see if the motive has been
|
||||
provided, in which case we use the standard app elaborator.
|
||||
@@ -1115,6 +1022,41 @@ where
|
||||
return none
|
||||
| _, _ => return some elimInfo
|
||||
|
||||
/--
|
||||
Collect extra argument positions that must be elaborated eagerly when using `elab_as_elim`.
|
||||
The idea is that they contribute to motive inference. See comment at `ElamElim.Context.extraArgsPos`.
|
||||
-/
|
||||
getElabAsElimExtraArgsPos (elimInfo : ElimInfo) : MetaM (Array Nat) := do
|
||||
forallTelescope elimInfo.elimType fun xs type => do
|
||||
let targets := type.getAppArgs
|
||||
/- Compute transitive closure of fvars appearing in the motive and the targets. -/
|
||||
let initMotiveFVars : CollectFVars.State := targets.foldl (init := {}) collectFVars
|
||||
let motiveFVars ← xs.size.foldRevM (init := initMotiveFVars) fun i s => do
|
||||
let x := xs[i]!
|
||||
if elimInfo.motivePos == i || elimInfo.targetsPos.contains i || s.fvarSet.contains x.fvarId! then
|
||||
return collectFVars s (← inferType x)
|
||||
else
|
||||
return s
|
||||
/- Collect the extra argument positions -/
|
||||
let mut extraArgsPos := #[]
|
||||
for i in [:xs.size] do
|
||||
let x := xs[i]!
|
||||
unless elimInfo.motivePos == i || elimInfo.targetsPos.contains i do
|
||||
let xType ← x.fvarId!.getType
|
||||
/- We only consider "first-order" types because we can reliably "extract" information from them. -/
|
||||
if motiveFVars.fvarSet.contains x.fvarId!
|
||||
|| (isFirstOrder xType
|
||||
&& Option.isSome (xType.find? fun e => e.isFVar && motiveFVars.fvarSet.contains e.fvarId!)) then
|
||||
extraArgsPos := extraArgsPos.push i
|
||||
return extraArgsPos
|
||||
|
||||
/-
|
||||
Helper function for implementing `elab_as_elim`.
|
||||
We say a term is "first-order" if all applications are of the form `f ...` where `f` is a constant.
|
||||
-/
|
||||
isFirstOrder (e : Expr) : Bool :=
|
||||
Option.isNone <| e.find? fun e =>
|
||||
e.isApp && !e.getAppFn.isConst
|
||||
|
||||
/-- Auxiliary inductive datatype that represents the resolution of an `LVal`. -/
|
||||
inductive LValResolution where
|
||||
@@ -1279,7 +1221,7 @@ private partial def mkBaseProjections (baseStructName : Name) (structName : Name
|
||||
let mut e := e
|
||||
for projFunName in path do
|
||||
let projFn ← mkConst projFunName
|
||||
e ← elabAppArgs projFn #[{ name := `self, val := Arg.expr e, suppressDeps := true }] (args := #[]) (expectedType? := none) (explicit := false) (ellipsis := false)
|
||||
e ← elabAppArgs projFn #[{ name := `self, val := Arg.expr e }] (args := #[]) (expectedType? := none) (explicit := false) (ellipsis := false)
|
||||
return e
|
||||
|
||||
private def typeMatchesBaseName (type : Expr) (baseName : Name) : MetaM Bool := do
|
||||
@@ -1301,8 +1243,8 @@ private def addLValArg (baseName : Name) (fullName : Name) (e : Expr) (args : Ar
|
||||
forallTelescopeReducing fType fun xs _ => do
|
||||
let mut argIdx := 0 -- position of the next explicit argument
|
||||
let mut remainingNamedArgs := namedArgs
|
||||
for h : i in [:xs.size] do
|
||||
let x := xs[i]
|
||||
for i in [:xs.size] do
|
||||
let x := xs[i]!
|
||||
let xDecl ← x.fvarId!.getDecl
|
||||
/- If there is named argument with name `xDecl.userName`, then we skip it. -/
|
||||
match remainingNamedArgs.findIdx? (fun namedArg => namedArg.name == xDecl.userName) with
|
||||
@@ -1363,10 +1305,10 @@ private def elabAppLValsAux (namedArgs : Array NamedArg) (args : Array Arg) (exp
|
||||
let projFn ← mkConst info.projFn
|
||||
let projFn ← addProjTermInfo lval.getRef projFn
|
||||
if lvals.isEmpty then
|
||||
let namedArgs ← addNamedArg namedArgs { name := `self, val := Arg.expr f, suppressDeps := true }
|
||||
let namedArgs ← addNamedArg namedArgs { name := `self, val := Arg.expr f }
|
||||
elabAppArgs projFn namedArgs args expectedType? explicit ellipsis
|
||||
else
|
||||
let f ← elabAppArgs projFn #[{ name := `self, val := Arg.expr f, suppressDeps := true }] #[] (expectedType? := none) (explicit := false) (ellipsis := false)
|
||||
let f ← elabAppArgs projFn #[{ name := `self, val := Arg.expr f }] #[] (expectedType? := none) (explicit := false) (ellipsis := false)
|
||||
loop f lvals
|
||||
else
|
||||
unreachable!
|
||||
|
||||
@@ -9,22 +9,18 @@ import Lean.Elab.Term
|
||||
namespace Lean.Elab.Term
|
||||
|
||||
/--
|
||||
Auxiliary inductive datatype for combining unelaborated syntax
|
||||
and already elaborated expressions. It is used to elaborate applications.
|
||||
-/
|
||||
Auxiliary inductive datatype for combining unelaborated syntax
|
||||
and already elaborated expressions. It is used to elaborate applications. -/
|
||||
inductive Arg where
|
||||
| stx (val : Syntax)
|
||||
| expr (val : Expr)
|
||||
deriving Inhabited
|
||||
|
||||
/-- Named arguments created using the notation `(x := val)`. -/
|
||||
/-- Named arguments created using the notation `(x := val)` -/
|
||||
structure NamedArg where
|
||||
ref : Syntax := Syntax.missing
|
||||
name : Name
|
||||
val : Arg
|
||||
/-- If `true`, then make all parameters that depend on this one become implicit.
|
||||
This is used for projection notation, since structure parameters might be explicit for classes. -/
|
||||
suppressDeps : Bool := false
|
||||
deriving Inhabited
|
||||
|
||||
/--
|
||||
|
||||
@@ -55,8 +55,8 @@ open Meta
|
||||
let cinfo ← getConstInfoCtor ctor
|
||||
let numExplicitFields ← forallTelescopeReducing cinfo.type fun xs _ => do
|
||||
let mut n := 0
|
||||
for h : i in [cinfo.numParams:xs.size] do
|
||||
if (← getFVarLocalDecl xs[i]).binderInfo.isExplicit then
|
||||
for i in [cinfo.numParams:xs.size] do
|
||||
if (← getFVarLocalDecl xs[i]!).binderInfo.isExplicit then
|
||||
n := n + 1
|
||||
return n
|
||||
let args := args.getElems
|
||||
|
||||
@@ -150,10 +150,26 @@ private def getMVarFromUserName (ident : Syntax) : MetaM Expr := do
|
||||
elabTerm b expectedType?
|
||||
| _ => throwUnsupportedSyntax
|
||||
|
||||
private def mkTacticMVar (type : Expr) (tacticCode : Syntax) : TermElabM Expr := do
|
||||
let mvar ← mkFreshExprMVar type MetavarKind.syntheticOpaque
|
||||
let mvarId := mvar.mvarId!
|
||||
let ref ← getRef
|
||||
registerSyntheticMVar ref mvarId <| SyntheticMVarKind.tactic tacticCode (← saveContext)
|
||||
return mvar
|
||||
|
||||
register_builtin_option debug.byAsSorry : Bool := {
|
||||
defValue := false
|
||||
group := "debug"
|
||||
descr := "replace `by ..` blocks with `sorry` IF the expected type is a proposition"
|
||||
}
|
||||
|
||||
@[builtin_term_elab byTactic] def elabByTactic : TermElab := fun stx expectedType? => do
|
||||
match expectedType? with
|
||||
| some expectedType =>
|
||||
mkTacticMVar expectedType stx .term
|
||||
if ← pure (debug.byAsSorry.get (← getOptions)) <&&> isProp expectedType then
|
||||
mkSorry expectedType false
|
||||
else
|
||||
mkTacticMVar expectedType stx
|
||||
| none =>
|
||||
tryPostpone
|
||||
throwError ("invalid 'by' tactic, expected type has not been provided")
|
||||
|
||||
@@ -64,13 +64,13 @@ private partial def winnowExpr (e : Expr) : MetaM Expr := do
|
||||
let mut fty ← inferType f
|
||||
let mut j := 0
|
||||
let mut e' ← visit f
|
||||
for h : i in [0:args.size] do
|
||||
for i in [0:args.size] do
|
||||
unless fty.isForall do
|
||||
fty ← withTransparency .all <| whnf <| fty.instantiateRevRange j i args
|
||||
j := i
|
||||
let .forallE _ _ fty' bi := fty | failure
|
||||
fty := fty'
|
||||
let arg := args[i]
|
||||
let arg := args[i]!
|
||||
if ← pure bi.isExplicit <||> (pure !arg.isSort <&&> isTypeFormer arg) then
|
||||
unless (← isProof arg) do
|
||||
e' := .app e' (← visit arg)
|
||||
@@ -206,11 +206,8 @@ Uses heuristics to generate an informative but terse base name for a term of the
|
||||
Makes use of the current namespace.
|
||||
It tries to make these names relatively unique ecosystem-wide,
|
||||
and it adds suffixes using the current module if the resulting name doesn't refer to anything defined in this module.
|
||||
|
||||
If any constant in `type` has a name with macro scopes, then the result will be a name with fresh macro scopes.
|
||||
While in this case we could skip the naming heuristics, we still want informative names for debugging purposes.
|
||||
-/
|
||||
def mkBaseNameWithSuffix (pre : String) (type : Expr) : MetaM Name := do
|
||||
def mkBaseNameWithSuffix (pre : String) (type : Expr) : MetaM String := do
|
||||
let (name, st) ← mkBaseName type |>.run {}
|
||||
let name := pre ++ name
|
||||
let project := (← getMainModule).getRoot
|
||||
@@ -220,13 +217,8 @@ def mkBaseNameWithSuffix (pre : String) (type : Expr) : MetaM Name := do
|
||||
let isModuleLocal := modules.any Option.isNone
|
||||
-- We can also avoid adding the full module suffix if the instance refers to "project"-local names.
|
||||
let isProjectLocal := isModuleLocal || modules.any fun mod? => mod?.map (·.getRoot) == project
|
||||
let name := Name.mkSimple <|
|
||||
if !isProjectLocal then
|
||||
s!"{name}{moduleToSuffix project}"
|
||||
else
|
||||
name
|
||||
if Option.isSome <| type.find? (fun e => if let .const n _ := e then n.hasMacroScopes else false) then
|
||||
mkFreshUserName name
|
||||
if !isProjectLocal then
|
||||
return s!"{name}{moduleToSuffix project}"
|
||||
else
|
||||
return name
|
||||
|
||||
@@ -241,8 +233,8 @@ def mkBaseNameWithSuffix' (pre : String) (binders : Array Syntax) (type : Syntax
|
||||
let ty ← mkForallFVars binds (← Term.elabType type)
|
||||
mkBaseNameWithSuffix pre ty
|
||||
catch _ =>
|
||||
mkFreshUserName <| Name.mkSimple pre
|
||||
liftMacroM <| mkUnusedBaseName name
|
||||
pure pre
|
||||
liftMacroM <| mkUnusedBaseName <| Name.mkSimple name
|
||||
|
||||
end NameGen
|
||||
|
||||
|
||||
@@ -86,8 +86,8 @@ where
|
||||
addLocalInstancesForParams xs[:ctorVal.numParams] fun localInst2Index => do
|
||||
let mut usedInstIdxs := {}
|
||||
let mut ok := true
|
||||
for h : i in [ctorVal.numParams:xs.size] do
|
||||
let x := xs[i]
|
||||
for i in [ctorVal.numParams:xs.size] do
|
||||
let x := xs[i]!
|
||||
let instType ← mkAppM `Inhabited #[(← inferType x)]
|
||||
trace[Elab.Deriving.inhabited] "checking {instType} for '{ctorName}'"
|
||||
match (← trySynthInstance instType) with
|
||||
|
||||
@@ -29,8 +29,8 @@ def mkBodyForStruct (header : Header) (indVal : InductiveVal) : TermElabM Term :
|
||||
let mut fields ← `(Format.nil)
|
||||
if xs.size != numParams + fieldNames.size then
|
||||
throwError "'deriving Repr' failed, unexpected number of fields in structure"
|
||||
for h : i in [:fieldNames.size] do
|
||||
let fieldName := fieldNames[i]
|
||||
for i in [:fieldNames.size] do
|
||||
let fieldName := fieldNames[i]!
|
||||
let fieldNameLit := Syntax.mkStrLit (toString fieldName)
|
||||
let x := xs[numParams + i]!
|
||||
if i != 0 then
|
||||
@@ -59,10 +59,10 @@ where
|
||||
let mut ctorArgs := #[]
|
||||
let mut rhs : Term := Syntax.mkStrLit (toString ctorInfo.name)
|
||||
rhs ← `(Format.text $rhs)
|
||||
for h : i in [:xs.size] do
|
||||
for i in [:xs.size] do
|
||||
-- Note: some inductive parameters are explicit if they were promoted from indices,
|
||||
-- so we process all constructor arguments in the same loop.
|
||||
let x := xs[i]
|
||||
let x := xs[i]!
|
||||
let a ← mkIdent <$> if i < indVal.numParams then pure header.argNames[i]! else mkFreshUserName `a
|
||||
if i < indVal.numParams then
|
||||
-- add `_` for inductive parameters, they are inaccessible
|
||||
|
||||
@@ -513,7 +513,7 @@ partial def extendUpdatedVarsAux (c : Code) (ws : VarSet) : TermElabM Code :=
|
||||
| .ite ref none o c t e => return .ite ref none o c (← update t) (← update e)
|
||||
| .ite ref (some h) o cond t e =>
|
||||
if ws.contains h.getId then
|
||||
-- if the `h` at `if h : c then t else e` shadows a variable in `ws`, we `pullExitPoints`
|
||||
-- if the `h` at `if h:c then t else e` shadows a variable in `ws`, we `pullExitPoints`
|
||||
pullExitPoints c
|
||||
else
|
||||
return Code.ite ref (some h) o cond (← update t) (← update e)
|
||||
|
||||
@@ -168,8 +168,8 @@ private def checkHeader (r : ElabHeaderResult) (numParams : Nat) (firstType? : O
|
||||
|
||||
-- Auxiliary function for checking whether the types in mutually inductive declaration are compatible.
|
||||
private partial def checkHeaders (rs : Array ElabHeaderResult) (numParams : Nat) (i : Nat) (firstType? : Option Expr) : TermElabM Unit := do
|
||||
if h : i < rs.size then
|
||||
let type ← checkHeader rs[i] numParams firstType?
|
||||
if i < rs.size then
|
||||
let type ← checkHeader rs[i]! numParams firstType?
|
||||
checkHeaders rs numParams (i+1) type
|
||||
|
||||
private def elabHeader (views : Array InductiveView) : TermElabM (Array ElabHeaderResult) := do
|
||||
@@ -222,11 +222,11 @@ private def replaceArrowBinderNames (type : Expr) (newNames : Array Name) : Expr
|
||||
go type 0
|
||||
where
|
||||
go (type : Expr) (i : Nat) : Expr :=
|
||||
if h : i < newNames.size then
|
||||
if i < newNames.size then
|
||||
match type with
|
||||
| .forallE n d b bi =>
|
||||
if n.hasMacroScopes then
|
||||
mkForall newNames[i] bi d (go b (i+1))
|
||||
mkForall newNames[i]! bi d (go b (i+1))
|
||||
else
|
||||
mkForall n bi d (go b (i+1))
|
||||
| _ => type
|
||||
|
||||
@@ -330,8 +330,8 @@ private def elabPatterns (patternStxs : Array Syntax) (matchType : Expr) : Excep
|
||||
withReader (fun ctx => { ctx with implicitLambda := false }) do
|
||||
let mut patterns := #[]
|
||||
let mut matchType := matchType
|
||||
for h : idx in [:patternStxs.size] do
|
||||
let patternStx := patternStxs[idx]
|
||||
for idx in [:patternStxs.size] do
|
||||
let patternStx := patternStxs[idx]!
|
||||
matchType ← whnf matchType
|
||||
match matchType with
|
||||
| Expr.forallE _ d b _ =>
|
||||
|
||||
@@ -406,9 +406,9 @@ private def elabFunValues (headers : Array DefViewElabHeader) (vars : Array Expr
|
||||
(if header.kind.isTheorem && !deprecated.oldSectionVars.get (← getOptions) then withHeaderSecVars vars sc #[header] else fun x => x #[]) fun vars => do
|
||||
forallBoundedTelescope header.type header.numParams fun xs type => do
|
||||
-- Add new info nodes for new fvars. The server will detect all fvars of a binder by the binder's source location.
|
||||
for h : i in [0:header.binderIds.size] do
|
||||
for i in [0:header.binderIds.size] do
|
||||
-- skip auto-bound prefix in `xs`
|
||||
addLocalVarInfo header.binderIds[i] xs[header.numParams - header.binderIds.size + i]!
|
||||
addLocalVarInfo header.binderIds[i]! xs[header.numParams - header.binderIds.size + i]!
|
||||
let val ← withReader ({ · with tacSnap? := header.tacSnap? }) do
|
||||
-- synthesize mvars here to force the top-level tactic block (if any) to run
|
||||
elabTermEnsuringType valStx type <* synthesizeSyntheticMVarsNoPostponing
|
||||
|
||||
@@ -77,9 +77,9 @@ def mkEqns (declName : Name) (info : DefinitionVal) : MetaM (Array Name) :=
|
||||
withReducible do
|
||||
mkEqnTypes #[] goal.mvarId!
|
||||
let mut thmNames := #[]
|
||||
for h : i in [: eqnTypes.size] do
|
||||
let type := eqnTypes[i]
|
||||
trace[Elab.definition.eqns] "eqnType[{i}]: {eqnTypes[i]}"
|
||||
for i in [: eqnTypes.size] do
|
||||
let type := eqnTypes[i]!
|
||||
trace[Elab.definition.eqns] "eqnType[{i}]: {eqnTypes[i]!}"
|
||||
let name := (Name.str baseName eqnThmSuffixBase).appendIndexAfter (i+1)
|
||||
thmNames := thmNames.push name
|
||||
let value ← mkProof declName type
|
||||
|
||||
@@ -67,8 +67,8 @@ def mkEqns (info : EqnInfo) : MetaM (Array Name) :=
|
||||
mkEqnTypes info.declNames goal.mvarId!
|
||||
let baseName := info.declName
|
||||
let mut thmNames := #[]
|
||||
for h : i in [: eqnTypes.size] do
|
||||
let type := eqnTypes[i]
|
||||
for i in [: eqnTypes.size] do
|
||||
let type := eqnTypes[i]!
|
||||
trace[Elab.definition.structural.eqns] "eqnType {i}: {type}"
|
||||
let name := (Name.str baseName eqnThmSuffixBase).appendIndexAfter (i+1)
|
||||
thmNames := thmNames.push name
|
||||
|
||||
@@ -83,9 +83,9 @@ def mkEqns (declName : Name) (info : EqnInfo) : MetaM (Array Name) :=
|
||||
withReducible do
|
||||
mkEqnTypes info.declNames goal.mvarId!
|
||||
let mut thmNames := #[]
|
||||
for h : i in [: eqnTypes.size] do
|
||||
let type := eqnTypes[i]
|
||||
trace[Elab.definition.wf.eqns] "{eqnTypes[i]}"
|
||||
for i in [: eqnTypes.size] do
|
||||
let type := eqnTypes[i]!
|
||||
trace[Elab.definition.wf.eqns] "{eqnTypes[i]!}"
|
||||
let name := (Name.str baseName eqnThmSuffixBase).appendIndexAfter (i+1)
|
||||
thmNames := thmNames.push name
|
||||
let value ← mkProof declName type
|
||||
|
||||
@@ -655,9 +655,9 @@ The parameter `alts` provides position information for alternatives.
|
||||
-/
|
||||
private def checkUnusedAlts (stx : Syntax) (alts : Array Syntax) (altIdxMap : NameMap Nat) (ignoreIfUnused : IdxSet) : TermElabM Syntax := do
|
||||
let (stx, used) ← findUsedAlts stx altIdxMap
|
||||
for h : i in [:alts.size] do
|
||||
for i in [:alts.size] do
|
||||
unless used.contains i || ignoreIfUnused.contains i do
|
||||
logErrorAt alts[i] s!"redundant alternative #{i+1}"
|
||||
logErrorAt alts[i]! s!"redundant alternative #{i+1}"
|
||||
return stx
|
||||
|
||||
def match_syntax.expand (stx : Syntax) : TermElabM Syntax := do
|
||||
|
||||
@@ -682,12 +682,7 @@ private partial def elabStruct (s : Struct) (expectedType? : Option Expr) : Term
|
||||
-- We add info to get reliable positions for messages from evaluating the tactic script.
|
||||
let info := field.ref.getHeadInfo
|
||||
let stx := stx.raw.rewriteBottomUp (·.setInfo info)
|
||||
let type := (d.getArg! 0).consumeTypeAnnotations
|
||||
let mvar ← mkTacticMVar type stx (.fieldAutoParam fieldName s.structName)
|
||||
-- Note(kmill): We are adding terminfo to simulate a previous implementation that elaborated `tacticBlock`.
|
||||
-- (See the aformentioned `processExplicitArg` for a comment about this.)
|
||||
addTermInfo' stx mvar
|
||||
cont mvar field
|
||||
cont (← elabTermEnsuringType stx (d.getArg! 0).consumeTypeAnnotations) field
|
||||
| _ =>
|
||||
if bi == .instImplicit then
|
||||
let val ← withRef field.ref <| mkFreshExprMVar d .synthetic
|
||||
|
||||
@@ -468,8 +468,7 @@ where
|
||||
if h : i < view.parents.size then
|
||||
let parentStx := view.parents.get ⟨i, h⟩
|
||||
withRef parentStx do
|
||||
let parentType ← Term.withSynthesize <| Term.elabType parentStx
|
||||
let parentType ← whnf parentType
|
||||
let parentType ← Term.elabType parentStx
|
||||
let parentStructName ← getStructureName parentType
|
||||
if let some existingFieldName ← findExistingField? infos parentStructName then
|
||||
if structureDiamondWarning.get (← getOptions) then
|
||||
@@ -733,8 +732,7 @@ private def addDefaults (lctx : LocalContext) (defaultAuxDecls : Array (Name ×
|
||||
throwError "invalid default value for field, it contains metavariables{indentExpr value}"
|
||||
/- The identity function is used as "marker". -/
|
||||
let value ← mkId value
|
||||
-- No need to compile the definition, since it is only used during elaboration.
|
||||
discard <| mkAuxDefinition declName type value (zetaDelta := true) (compile := false)
|
||||
discard <| mkAuxDefinition declName type value (zetaDelta := true)
|
||||
setReducibleAttribute declName
|
||||
|
||||
/--
|
||||
|
||||
@@ -257,8 +257,8 @@ private def throwStuckAtUniverseCnstr : TermElabM Unit := do
|
||||
unless found.contains (lhs, rhs) do
|
||||
found := found.insert (lhs, rhs)
|
||||
uniqueEntries := uniqueEntries.push entry
|
||||
for h : i in [1:uniqueEntries.size] do
|
||||
logErrorAt uniqueEntries[i].ref (← mkLevelStuckErrorMessage uniqueEntries[i]!)
|
||||
for i in [1:uniqueEntries.size] do
|
||||
logErrorAt uniqueEntries[i]!.ref (← mkLevelStuckErrorMessage uniqueEntries[i]!)
|
||||
throwErrorAt uniqueEntries[0]!.ref (← mkLevelStuckErrorMessage uniqueEntries[0]!)
|
||||
|
||||
/--
|
||||
@@ -316,18 +316,6 @@ def PostponeBehavior.ofBool : Bool → PostponeBehavior
|
||||
| true => .yes
|
||||
| false => .no
|
||||
|
||||
private def TacticMVarKind.logError (tacticCode : Syntax) (kind : TacticMVarKind) : TermElabM Unit := do
|
||||
match kind with
|
||||
| term => pure ()
|
||||
| autoParam argName => logErrorAt tacticCode m!"could not synthesize default value for parameter '{argName}' using tactics"
|
||||
| fieldAutoParam fieldName structName => logErrorAt tacticCode m!"could not synthesize default value for field '{fieldName}' of '{structName}' using tactics"
|
||||
|
||||
private def TacticMVarKind.maybeWithoutRecovery (kind : TacticMVarKind) (m : TacticM α) : TacticM α := do
|
||||
if kind matches .autoParam .. | .fieldAutoParam .. then
|
||||
withoutErrToSorry <| Tactic.withoutRecover <| m
|
||||
else
|
||||
m
|
||||
|
||||
mutual
|
||||
|
||||
/--
|
||||
@@ -337,7 +325,7 @@ mutual
|
||||
|
||||
If `report := false`, then `runTactic` will not capture exceptions nor will report unsolved goals. Unsolved goals become exceptions.
|
||||
-/
|
||||
partial def runTactic (mvarId : MVarId) (tacticCode : Syntax) (kind : TacticMVarKind) (report := true) : TermElabM Unit := withoutAutoBoundImplicit do
|
||||
partial def runTactic (mvarId : MVarId) (tacticCode : Syntax) (report := true) : TermElabM Unit := withoutAutoBoundImplicit do
|
||||
instantiateMVarDeclMVars mvarId
|
||||
/-
|
||||
TODO: consider using `runPendingTacticsAt` at `mvarId` local context and target type.
|
||||
@@ -354,7 +342,7 @@ mutual
|
||||
in more complicated scenarios.
|
||||
-/
|
||||
tryCatchRuntimeEx
|
||||
(do let remainingGoals ← withInfoHole mvarId <| Tactic.run mvarId <| kind.maybeWithoutRecovery do
|
||||
(do let remainingGoals ← withInfoHole mvarId <| Tactic.run mvarId do
|
||||
withTacticInfoContext tacticCode do
|
||||
-- also put an info node on the `by` keyword specifically -- the token may be `canonical` and thus shown in the info
|
||||
-- view even though it is synthetic while a node like `tacticCode` never is (#1990)
|
||||
@@ -366,13 +354,10 @@ mutual
|
||||
synthesizeSyntheticMVars (postpone := .no)
|
||||
unless remainingGoals.isEmpty do
|
||||
if report then
|
||||
kind.logError tacticCode
|
||||
reportUnsolvedGoals remainingGoals
|
||||
else
|
||||
throwError "unsolved goals\n{goalsToMessageData remainingGoals}")
|
||||
fun ex => do
|
||||
if report then
|
||||
kind.logError tacticCode
|
||||
if report && (← read).errToSorry then
|
||||
for mvarId in (← getMVars (mkMVar mvarId)) do
|
||||
mvarId.admit
|
||||
@@ -400,10 +385,10 @@ mutual
|
||||
return false
|
||||
-- NOTE: actual processing at `synthesizeSyntheticMVarsAux`
|
||||
| .postponed savedContext => resumePostponed savedContext mvarSyntheticDecl.stx mvarId postponeOnError
|
||||
| .tactic tacticCode savedContext kind =>
|
||||
| .tactic tacticCode savedContext =>
|
||||
withSavedContext savedContext do
|
||||
if runTactics then
|
||||
runTactic mvarId tacticCode kind
|
||||
runTactic mvarId tacticCode
|
||||
return true
|
||||
else
|
||||
return false
|
||||
@@ -544,9 +529,9 @@ the result of a tactic block.
|
||||
def runPendingTacticsAt (e : Expr) : TermElabM Unit := do
|
||||
for mvarId in (← getMVars e) do
|
||||
let mvarId ← getDelayedMVarRoot mvarId
|
||||
if let some { kind := .tactic tacticCode savedContext kind, .. } ← getSyntheticMVarDecl? mvarId then
|
||||
if let some { kind := .tactic tacticCode savedContext, .. } ← getSyntheticMVarDecl? mvarId then
|
||||
withSavedContext savedContext do
|
||||
runTactic mvarId tacticCode kind
|
||||
runTactic mvarId tacticCode
|
||||
markAsResolved mvarId
|
||||
|
||||
builtin_initialize
|
||||
|
||||
@@ -55,9 +55,9 @@ def evalBvCheck : Tactic := fun
|
||||
| `(tactic| bv_check%$tk $path:str) => do
|
||||
let cfg ← BVDecide.Frontend.BVCheck.mkContext path.getString
|
||||
liftMetaFinishingTactic fun g => do
|
||||
let g'? ← Normalize.bvNormalize g
|
||||
match g'? with
|
||||
| some g' => bvCheck g' cfg
|
||||
let res ← Normalize.bvNormalize g
|
||||
match res.goal with
|
||||
| some g => bvCheck g cfg
|
||||
| none =>
|
||||
let bvNormalizeStx ← `(tactic| bv_normalize)
|
||||
TryThis.addSuggestion tk bvNormalizeStx (origSpan? := ← getRef)
|
||||
|
||||
@@ -265,6 +265,10 @@ def bvUnsat (g : MVarId) (cfg : TacticContext) : MetaM (Except CounterExample Lr
|
||||
The result of calling `bv_decide`.
|
||||
-/
|
||||
structure Result where
|
||||
/--
|
||||
Trace of the `simp` used in `bv_decide`'s normalization procedure.
|
||||
-/
|
||||
simpTrace : Simp.Stats
|
||||
/--
|
||||
If the normalization step was not enough to solve the goal this contains the LRAT proof
|
||||
certificate.
|
||||
@@ -276,10 +280,10 @@ Try to close `g` using a bitblaster. Return either a `CounterExample` if one is
|
||||
if `g` is proven.
|
||||
-/
|
||||
def bvDecide' (g : MVarId) (cfg : TacticContext) : MetaM (Except CounterExample Result) := do
|
||||
let g? ← Normalize.bvNormalize g
|
||||
let some g := g? | return .ok ⟨none⟩
|
||||
let ⟨g?, simpTrace⟩ ← Normalize.bvNormalize g
|
||||
let some g := g? | return .ok ⟨simpTrace, none⟩
|
||||
match ← bvUnsat g cfg with
|
||||
| .ok lratCert => return .ok ⟨some lratCert⟩
|
||||
| .ok lratCert => return .ok ⟨simpTrace, some lratCert⟩
|
||||
| .error counterExample => return .error counterExample
|
||||
|
||||
/--
|
||||
|
||||
@@ -75,7 +75,9 @@ instance : ToExpr Gate where
|
||||
toExpr x :=
|
||||
match x with
|
||||
| .and => mkConst ``Gate.and
|
||||
| .or => mkConst ``Gate.or
|
||||
| .xor => mkConst ``Gate.xor
|
||||
| .imp => mkConst ``Gate.imp
|
||||
| .beq => mkConst ``Gate.beq
|
||||
toTypeExpr := mkConst ``Gate
|
||||
|
||||
|
||||
@@ -343,7 +343,7 @@ where
|
||||
return mkApp4 congrProof (toExpr inner.width) innerExpr innerEval innerProof
|
||||
|
||||
goBvLit (x : Expr) : M (Option ReifiedBVExpr) := do
|
||||
let some ⟨width, bvVal⟩ ← getBitVecValue? x | return ← ofAtom x
|
||||
let some ⟨width, bvVal⟩ ← getBitVecValue? x | return none
|
||||
let bvExpr : BVExpr width := .const bvVal
|
||||
let expr := mkApp2 (mkConst ``BVExpr.const) (toExpr width) (toExpr bvVal)
|
||||
let proof := do
|
||||
|
||||
@@ -65,6 +65,7 @@ partial def of (t : Expr) : M (Option ReifiedBVLogical) := do
|
||||
let subProof ← sub.evalsAtAtoms
|
||||
return mkApp3 (mkConst ``Std.Tactic.BVDecide.Reflect.Bool.not_congr) subExpr subEvalExpr subProof
|
||||
return some ⟨boolExpr, proof, expr⟩
|
||||
| Bool.or lhsExpr rhsExpr => gateReflection lhsExpr rhsExpr .or ``Std.Tactic.BVDecide.Reflect.Bool.or_congr
|
||||
| Bool.and lhsExpr rhsExpr => gateReflection lhsExpr rhsExpr .and ``Std.Tactic.BVDecide.Reflect.Bool.and_congr
|
||||
| Bool.xor lhsExpr rhsExpr => gateReflection lhsExpr rhsExpr .xor ``Std.Tactic.BVDecide.Reflect.Bool.xor_congr
|
||||
| BEq.beq α _ lhsExpr rhsExpr =>
|
||||
|
||||
@@ -89,7 +89,7 @@ where
|
||||
M (Option ReifiedBVPred) := do
|
||||
let some lhs ← ReifiedBVExpr.of lhsExpr | return none
|
||||
let some rhs ← ReifiedBVExpr.of rhsExpr | return none
|
||||
if h : lhs.width = rhs.width then
|
||||
if h:lhs.width = rhs.width then
|
||||
let bvExpr : BVPred := .bin (w := lhs.width) lhs.bvExpr pred (h ▸ rhs.bvExpr)
|
||||
let expr :=
|
||||
mkApp4
|
||||
|
||||
@@ -37,102 +37,40 @@ builtin_simproc [bv_normalize] eqToBEq (((_ : Bool) = (_ : Bool))) := fun e => d
|
||||
let proof := mkApp2 (mkConst ``Bool.eq_to_beq) lhs rhs
|
||||
return .done { expr := new, proof? := some proof }
|
||||
|
||||
builtin_simproc [bv_normalize] andOnes ((_ : BitVec _) &&& (_ : BitVec _)) := fun e => do
|
||||
let_expr HAnd.hAnd _ _ _ _ lhs rhs := e | return .continue
|
||||
let some ⟨w, rhsValue⟩ ← getBitVecValue? rhs | return .continue
|
||||
if rhsValue == -1#w then
|
||||
let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.and_ones) (toExpr w) lhs
|
||||
return .visit { expr := lhs, proof? := some proof }
|
||||
else
|
||||
return .continue
|
||||
structure Result where
|
||||
goal : Option MVarId := none
|
||||
stats : Simp.Stats := {}
|
||||
|
||||
builtin_simproc [bv_normalize] onesAnd ((_ : BitVec _) &&& (_ : BitVec _)) := fun e => do
|
||||
let_expr HAnd.hAnd _ _ _ _ lhs rhs := e | return .continue
|
||||
let some ⟨w, lhsValue⟩ ← getBitVecValue? lhs | return .continue
|
||||
if lhsValue == -1#w then
|
||||
let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.ones_and) (toExpr w) rhs
|
||||
return .visit { expr := rhs, proof? := some proof }
|
||||
else
|
||||
return .continue
|
||||
|
||||
builtin_simproc [bv_normalize] maxUlt (BitVec.ult (_ : BitVec _) (_ : BitVec _)) := fun e => do
|
||||
let_expr BitVec.ult _ lhs rhs := e | return .continue
|
||||
let some ⟨w, lhsValue⟩ ← getBitVecValue? lhs | return .continue
|
||||
if lhsValue == -1#w then
|
||||
let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.max_ult') (toExpr w) rhs
|
||||
return .visit { expr := toExpr Bool.false, proof? := some proof }
|
||||
else
|
||||
return .continue
|
||||
|
||||
/--
|
||||
A pass in the normalization pipeline. Takes the current goal and produces a refined one or closes
|
||||
the goal fully, indicated by returning `none`.
|
||||
-/
|
||||
abbrev Pass := MVarId → MetaM (Option MVarId)
|
||||
|
||||
namespace Pass
|
||||
|
||||
/--
|
||||
Repeatedly run a list of `Pass` until they either close the goal or an iteration doesn't change
|
||||
the goal anymore.
|
||||
-/
|
||||
partial def fixpointPipeline (passes : List Pass) (goal : MVarId) : MetaM (Option MVarId) := do
|
||||
let runPass (goal? : Option MVarId) (pass : Pass) : MetaM (Option MVarId) := do
|
||||
let some goal := goal? | return none
|
||||
pass goal
|
||||
|
||||
let some newGoal := ← passes.foldlM (init := some goal) runPass | return none
|
||||
if goal != newGoal then
|
||||
trace[Meta.Tactic.bv] m!"Rerunning pipeline on:\n{newGoal}"
|
||||
fixpointPipeline passes newGoal
|
||||
else
|
||||
trace[Meta.Tactic.bv] "Pipeline reached a fixpoint"
|
||||
return newGoal
|
||||
|
||||
/--
|
||||
Responsible for applying the Bitwuzla style rewrite rules.
|
||||
-/
|
||||
def rewriteRulesPass : Pass := fun goal => do
|
||||
let bvThms ← bvNormalizeExt.getTheorems
|
||||
let bvSimprocs ← bvNormalizeSimprocExt.getSimprocs
|
||||
let sevalThms ← getSEvalTheorems
|
||||
let sevalSimprocs ← Simp.getSEvalSimprocs
|
||||
|
||||
let simpCtx : Simp.Context := {
|
||||
config := { failIfUnchanged := false, zetaDelta := true }
|
||||
simpTheorems := #[bvThms, sevalThms]
|
||||
congrTheorems := (← getSimpCongrTheorems)
|
||||
}
|
||||
|
||||
let hyps ← goal.getNondepPropHyps
|
||||
let ⟨result?, _⟩ ← simpGoal goal
|
||||
(ctx := simpCtx)
|
||||
(simprocs := #[bvSimprocs, sevalSimprocs])
|
||||
(fvarIdsToSimp := hyps)
|
||||
let some (_, newGoal) := result? | return none
|
||||
return newGoal
|
||||
|
||||
/--
|
||||
The normalization passes used by `bv_normalize` and thus `bv_decide`.
|
||||
-/
|
||||
def defaultPipeline : List Pass := [rewriteRulesPass]
|
||||
|
||||
end Pass
|
||||
|
||||
def bvNormalize (g : MVarId) : MetaM (Option MVarId) := do
|
||||
def bvNormalize (g : MVarId) : MetaM Result := do
|
||||
withTraceNode `bv (fun _ => return "Normalizing goal") do
|
||||
-- Contradiction proof
|
||||
let some g ← g.falseOrByContra | return none
|
||||
trace[Meta.Tactic.bv] m!"Running preprocessing pipeline on:\n{g}"
|
||||
Pass.fixpointPipeline Pass.defaultPipeline g
|
||||
let some g ← g.falseOrByContra | return {}
|
||||
|
||||
-- Normalization by simp
|
||||
let bvThms ← bvNormalizeExt.getTheorems
|
||||
let bvSimprocs ← bvNormalizeSimprocExt.getSimprocs
|
||||
let sevalThms ← getSEvalTheorems
|
||||
let sevalSimprocs ← Simp.getSEvalSimprocs
|
||||
|
||||
let simpCtx : Simp.Context := {
|
||||
config := { failIfUnchanged := false, zetaDelta := true }
|
||||
simpTheorems := #[bvThms, sevalThms]
|
||||
congrTheorems := (← getSimpCongrTheorems)
|
||||
}
|
||||
|
||||
let hyps ← g.getNondepPropHyps
|
||||
let ⟨result?, stats⟩ ← simpGoal g
|
||||
(ctx := simpCtx)
|
||||
(simprocs := #[bvSimprocs, sevalSimprocs])
|
||||
(fvarIdsToSimp := hyps)
|
||||
let some (_, g) := result? | return ⟨none, stats⟩
|
||||
return ⟨some g, stats⟩
|
||||
|
||||
@[builtin_tactic Lean.Parser.Tactic.bvNormalize]
|
||||
def evalBVNormalize : Tactic := fun
|
||||
| `(tactic| bv_normalize) => do
|
||||
let g ← getMainGoal
|
||||
match ← bvNormalize g with
|
||||
| some newGoal => setGoals [newGoal]
|
||||
| none => setGoals []
|
||||
liftMetaFinishingTactic fun g => do
|
||||
discard <| bvNormalize g
|
||||
| _ => throwUnsupportedSyntax
|
||||
|
||||
end Frontend.Normalize
|
||||
|
||||
@@ -205,8 +205,8 @@ private def isWildcard (altStx : Syntax) : Bool :=
|
||||
getAltName altStx == `_
|
||||
|
||||
private def checkAltNames (alts : Array Alt) (altsSyntax : Array Syntax) : TacticM Unit :=
|
||||
for h : i in [:altsSyntax.size] do
|
||||
let altStx := altsSyntax[i]
|
||||
for i in [:altsSyntax.size] do
|
||||
let altStx := altsSyntax[i]!
|
||||
if getAltName altStx == `_ && i != altsSyntax.size - 1 then
|
||||
withRef altStx <| throwError "invalid occurrence of wildcard alternative, it must be the last alternative"
|
||||
let altName := getAltName altStx
|
||||
@@ -236,8 +236,8 @@ private def saveAltVarsInfo (altMVarId : MVarId) (altStx : Syntax) (fvarIds : Ar
|
||||
let altVars := getAltVars altStx
|
||||
for fvarId in fvarIds do
|
||||
if !useNamesForExplicitOnly || (← fvarId.getDecl).binderInfo.isExplicit then
|
||||
if h : i < altVars.size then
|
||||
Term.addLocalVarInfo altVars[i] (mkFVar fvarId)
|
||||
if i < altVars.size then
|
||||
Term.addLocalVarInfo altVars[i]! (mkFVar fvarId)
|
||||
i := i + 1
|
||||
|
||||
open Language in
|
||||
@@ -320,8 +320,8 @@ where
|
||||
2- The errors are produced in the same order the appear in the code above. This is not super
|
||||
important when using IDEs.
|
||||
-/
|
||||
for h : altStxIdx in [0:altStxs.size] do
|
||||
let altStx := altStxs[altStxIdx]
|
||||
for altStxIdx in [0:altStxs.size] do
|
||||
let altStx := altStxs[altStxIdx]!
|
||||
let altName := getAltName altStx
|
||||
if let some i := alts.findIdx? (·.1 == altName) then
|
||||
-- cover named alternative
|
||||
|
||||
@@ -513,13 +513,13 @@ def fourierMotzkinSelect (data : Array FourierMotzkinData) : MetaM FourierMotzki
|
||||
if bestSize = 0 then
|
||||
trace[omega] "Selected variable {data[0]!.var}."
|
||||
return data[0]!
|
||||
for h : i in [1:data.size] do
|
||||
let exact := data[i].exact
|
||||
let size := data[i].size
|
||||
for i in [1:data.size] do
|
||||
let exact := data[i]!.exact
|
||||
let size := data[i]!.size
|
||||
if size = 0 || !bestExact && exact || (bestExact == exact) && size < bestSize then
|
||||
if size = 0 then
|
||||
trace[omega] "Selected variable {data[i].var}"
|
||||
return data[i]
|
||||
trace[omega] "Selected variable {data[i]!.var}"
|
||||
return data[i]!
|
||||
bestIdx := i
|
||||
bestExact := exact
|
||||
bestSize := size
|
||||
|
||||
@@ -277,7 +277,6 @@ where
|
||||
| _ => mkAtomLinearCombo e
|
||||
| (``Min.min, #[_, _, a, b]) => rewrite e (mkApp2 (.const ``Int.ofNat_min []) a b)
|
||||
| (``Max.max, #[_, _, a, b]) => rewrite e (mkApp2 (.const ``Int.ofNat_max []) a b)
|
||||
| (``Int.toNat, #[n]) => rewrite e (mkApp (.const ``Int.toNat_eq_max []) n)
|
||||
| (``HShiftLeft.hShiftLeft, #[_, _, _, _, a, b]) =>
|
||||
rewrite e (mkApp2 (.const ``Int.ofNat_shiftLeft_eq []) a b)
|
||||
| (``HShiftRight.hShiftRight, #[_, _, _, _, a, b]) =>
|
||||
|
||||
@@ -29,14 +29,12 @@ The minimum non-zero entry in a list of natural numbers, or zero if all entries
|
||||
We completely characterize the function via
|
||||
`nonzeroMinimum_eq_zero_iff` and `nonzeroMinimum_eq_nonzero_iff` below.
|
||||
-/
|
||||
def nonzeroMinimum (xs : List Nat) : Nat := xs.filter (· ≠ 0) |>.min? |>.getD 0
|
||||
def nonzeroMinimum (xs : List Nat) : Nat := xs.filter (· ≠ 0) |>.minimum? |>.getD 0
|
||||
|
||||
-- A specialization of `minimum?_eq_some_iff` to Nat.
|
||||
-- This is a duplicate `min?_eq_some_iff'` proved in `Init.Data.List.Nat.Basic`,
|
||||
-- and could be deduplicated but the import hierarchy is awkward.
|
||||
theorem min?_eq_some_iff'' {xs : List Nat} :
|
||||
xs.min? = some a ↔ (a ∈ xs ∧ ∀ b ∈ xs, a ≤ b) :=
|
||||
min?_eq_some_iff
|
||||
theorem minimum?_eq_some_iff' {xs : List Nat} :
|
||||
xs.minimum? = some a ↔ (a ∈ xs ∧ ∀ b ∈ xs, a ≤ b) :=
|
||||
minimum?_eq_some_iff
|
||||
(le_refl := Nat.le_refl)
|
||||
(min_eq_or := fun _ _ => Nat.min_def .. ▸ by split <;> simp)
|
||||
(le_min_iff := fun _ _ _ => Nat.le_min)
|
||||
@@ -44,27 +42,27 @@ theorem min?_eq_some_iff'' {xs : List Nat} :
|
||||
open Classical in
|
||||
@[simp] theorem nonzeroMinimum_eq_zero_iff {xs : List Nat} :
|
||||
xs.nonzeroMinimum = 0 ↔ ∀ x ∈ xs, x = 0 := by
|
||||
simp [nonzeroMinimum, Option.getD_eq_iff, min?_eq_none_iff, min?_eq_some_iff'',
|
||||
simp [nonzeroMinimum, Option.getD_eq_iff, minimum?_eq_none_iff, minimum?_eq_some_iff',
|
||||
filter_eq_nil_iff, mem_filter]
|
||||
|
||||
theorem nonzeroMinimum_mem {xs : List Nat} (w : xs.nonzeroMinimum ≠ 0) :
|
||||
xs.nonzeroMinimum ∈ xs := by
|
||||
dsimp [nonzeroMinimum] at *
|
||||
generalize h : (xs.filter (· ≠ 0) |>.min?) = m at *
|
||||
generalize h : (xs.filter (· ≠ 0) |>.minimum?) = m at *
|
||||
match m, w with
|
||||
| some (m+1), _ => simp_all [min?_eq_some_iff'', mem_filter]
|
||||
| some (m+1), _ => simp_all [minimum?_eq_some_iff', mem_filter]
|
||||
|
||||
theorem nonzeroMinimum_pos {xs : List Nat} (m : a ∈ xs) (h : a ≠ 0) : 0 < xs.nonzeroMinimum :=
|
||||
Nat.pos_iff_ne_zero.mpr fun w => h (nonzeroMinimum_eq_zero_iff.mp w _ m)
|
||||
|
||||
theorem nonzeroMinimum_le {xs : List Nat} (m : a ∈ xs) (h : a ≠ 0) : xs.nonzeroMinimum ≤ a := by
|
||||
have : (xs.filter (· ≠ 0) |>.min?) = some xs.nonzeroMinimum := by
|
||||
have : (xs.filter (· ≠ 0) |>.minimum?) = some xs.nonzeroMinimum := by
|
||||
have w := nonzeroMinimum_pos m h
|
||||
dsimp [nonzeroMinimum] at *
|
||||
generalize h : (xs.filter (· ≠ 0) |>.min?) = m? at *
|
||||
generalize h : (xs.filter (· ≠ 0) |>.minimum?) = m? at *
|
||||
match m?, w with
|
||||
| some m?, _ => rfl
|
||||
rw [min?_eq_some_iff''] at this
|
||||
rw [minimum?_eq_some_iff'] at this
|
||||
apply this.2
|
||||
simp [List.mem_filter]
|
||||
exact ⟨m, h⟩
|
||||
@@ -144,4 +142,4 @@ theorem minNatAbs_eq_nonzero_iff (xs : List Int) (w : z ≠ 0) :
|
||||
@[simp] theorem minNatAbs_nil : ([] : List Int).minNatAbs = 0 := rfl
|
||||
|
||||
/-- The maximum absolute value in a list of integers. -/
|
||||
def maxNatAbs (xs : List Int) : Nat := xs.map Int.natAbs |>.max? |>.getD 0
|
||||
def maxNatAbs (xs : List Int) : Nat := xs.map Int.natAbs |>.maximum? |>.getD 0
|
||||
|
||||
@@ -47,7 +47,7 @@ def tacticToDischarge (tacticCode : Syntax) : TacticM (IO.Ref Term.State × Simp
|
||||
-/
|
||||
withoutModifyingStateWithInfoAndMessages do
|
||||
Term.withSynthesize (postpone := .no) do
|
||||
Term.runTactic (report := false) mvar.mvarId! tacticCode .term
|
||||
Term.runTactic (report := false) mvar.mvarId! tacticCode
|
||||
let result ← instantiateMVars mvar
|
||||
if result.hasExprMVar then
|
||||
return none
|
||||
|
||||
@@ -29,15 +29,6 @@ structure SavedContext where
|
||||
errToSorry : Bool
|
||||
levelNames : List Name
|
||||
|
||||
/-- The kind of a tactic metavariable, used for additional error reporting. -/
|
||||
inductive TacticMVarKind
|
||||
/-- Standard tactic metavariable, arising from `by ...` syntax. -/
|
||||
| term
|
||||
/-- Tactic metavariable arising from an autoparam for a function application. -/
|
||||
| autoParam (argName : Name)
|
||||
/-- Tactic metavariable arising from an autoparam for a structure field. -/
|
||||
| fieldAutoParam (fieldName structName : Name)
|
||||
|
||||
/-- We use synthetic metavariables as placeholders for pending elaboration steps. -/
|
||||
inductive SyntheticMVarKind where
|
||||
/--
|
||||
@@ -52,7 +43,7 @@ inductive SyntheticMVarKind where
|
||||
Otherwise, we generate the error `("type mismatch" ++ e ++ "has type" ++ eType ++ "but it is expected to have type" ++ expectedType)` -/
|
||||
| coe (header? : Option String) (expectedType : Expr) (e : Expr) (f? : Option Expr)
|
||||
/-- Use tactic to synthesize value for metavariable. -/
|
||||
| tactic (tacticCode : Syntax) (ctx : SavedContext) (kind : TacticMVarKind)
|
||||
| tactic (tacticCode : Syntax) (ctx : SavedContext)
|
||||
/-- Metavariable represents a hole whose elaboration has been postponed. -/
|
||||
| postponed (ctx : SavedContext)
|
||||
deriving Inhabited
|
||||
@@ -1200,26 +1191,6 @@ private def postponeElabTermCore (stx : Syntax) (expectedType? : Option Expr) :
|
||||
def getSyntheticMVarDecl? (mvarId : MVarId) : TermElabM (Option SyntheticMVarDecl) :=
|
||||
return (← get).syntheticMVars.find? mvarId
|
||||
|
||||
register_builtin_option debug.byAsSorry : Bool := {
|
||||
defValue := false
|
||||
group := "debug"
|
||||
descr := "replace `by ..` blocks with `sorry` IF the expected type is a proposition"
|
||||
}
|
||||
|
||||
/--
|
||||
Creates a new metavariable of type `type` that will be synthesized using the tactic code.
|
||||
The `tacticCode` syntax is the full `by ..` syntax.
|
||||
-/
|
||||
def mkTacticMVar (type : Expr) (tacticCode : Syntax) (kind : TacticMVarKind) : TermElabM Expr := do
|
||||
if ← pure (debug.byAsSorry.get (← getOptions)) <&&> isProp type then
|
||||
mkSorry type false
|
||||
else
|
||||
let mvar ← mkFreshExprMVar type MetavarKind.syntheticOpaque
|
||||
let mvarId := mvar.mvarId!
|
||||
let ref ← getRef
|
||||
registerSyntheticMVar ref mvarId <| SyntheticMVarKind.tactic tacticCode (← saveContext) kind
|
||||
return mvar
|
||||
|
||||
/--
|
||||
Create an auxiliary annotation to make sure we create an `Info` even if `e` is a metavariable.
|
||||
See `mkTermInfo`.
|
||||
|
||||
@@ -515,11 +515,11 @@ def addEntry {α β σ : Type} (ext : PersistentEnvExtension α β σ) (env : En
|
||||
def getState {α β σ : Type} [Inhabited σ] (ext : PersistentEnvExtension α β σ) (env : Environment) : σ :=
|
||||
(ext.toEnvExtension.getState env).state
|
||||
|
||||
/-- Set the current state of the given extension in the given environment. -/
|
||||
/-- Set the current state of the given extension in the given environment. This change is *not* persisted across files. -/
|
||||
def setState {α β σ : Type} (ext : PersistentEnvExtension α β σ) (env : Environment) (s : σ) : Environment :=
|
||||
ext.toEnvExtension.modifyState env fun ps => { ps with state := s }
|
||||
|
||||
/-- Modify the state of the given extension in the given environment by applying the given function. -/
|
||||
/-- Modify the state of the given extension in the given environment by applying the given function. This change is *not* persisted across files. -/
|
||||
def modifyState {α β σ : Type} (ext : PersistentEnvExtension α β σ) (env : Environment) (f : σ → σ) : Environment :=
|
||||
ext.toEnvExtension.modifyState env fun ps => { ps with state := f (ps.state) }
|
||||
|
||||
@@ -765,8 +765,8 @@ where
|
||||
loop (i : Nat) (env : Environment) : IO Environment := do
|
||||
-- Recall that the size of the array stored `persistentEnvExtensionRef` may increase when we import user-defined environment extensions.
|
||||
let pExtDescrs ← persistentEnvExtensionsRef.get
|
||||
if h : i < pExtDescrs.size then
|
||||
let extDescr := pExtDescrs[i]
|
||||
if i < pExtDescrs.size then
|
||||
let extDescr := pExtDescrs[i]!
|
||||
let s := extDescr.toEnvExtension.getState env
|
||||
let prevSize := (← persistentEnvExtensionsRef.get).size
|
||||
let prevAttrSize ← getNumBuiltinAttributes
|
||||
@@ -858,7 +858,7 @@ def finalizeImport (s : ImportState) (imports : Array Import) (opts : Options) (
|
||||
numConsts + mod.constants.size + mod.extraConstNames.size
|
||||
let mut const2ModIdx : Std.HashMap Name ModuleIdx := Std.HashMap.empty (capacity := numConsts)
|
||||
let mut constantMap : Std.HashMap Name ConstantInfo := Std.HashMap.empty (capacity := numConsts)
|
||||
for h : modIdx in [0:s.moduleData.size] do
|
||||
for h:modIdx in [0:s.moduleData.size] do
|
||||
let mod := s.moduleData[modIdx]'h.upper
|
||||
for cname in mod.constNames, cinfo in mod.constants do
|
||||
match constantMap.getThenInsertIfNew? cname cinfo with
|
||||
@@ -1096,13 +1096,6 @@ def isDefEqGuarded (env : Environment) (lctx : LocalContext) (a b : Expr) : Bool
|
||||
@[extern "lean_kernel_whnf"]
|
||||
opaque whnf (env : Environment) (lctx : LocalContext) (a : Expr) : Except KernelException Expr
|
||||
|
||||
/--
|
||||
Kernel typecheck function. We use it mainly for debugging purposes.
|
||||
Recall that the Kernel type checker does not support metavariables.
|
||||
When implementing automation, consider using the `MetaM` methods. -/
|
||||
@[extern "lean_kernel_check"]
|
||||
opaque check (env : Environment) (lctx : LocalContext) (a : Expr) : Except KernelException Expr
|
||||
|
||||
end Kernel
|
||||
|
||||
class MonadEnv (m : Type → Type) where
|
||||
|
||||
@@ -385,14 +385,14 @@ def size (lctx : LocalContext) : Nat :=
|
||||
Id.run <| lctx.findDeclRevM? f
|
||||
|
||||
partial def isSubPrefixOfAux (a₁ a₂ : PArray (Option LocalDecl)) (exceptFVars : Array Expr) (i j : Nat) : Bool :=
|
||||
if h : i < a₁.size then
|
||||
match a₁[i] with
|
||||
if i < a₁.size then
|
||||
match a₁[i]! with
|
||||
| none => isSubPrefixOfAux a₁ a₂ exceptFVars (i+1) j
|
||||
| some decl₁ =>
|
||||
if exceptFVars.any fun fvar => fvar.fvarId! == decl₁.fvarId then
|
||||
isSubPrefixOfAux a₁ a₂ exceptFVars (i+1) j
|
||||
else if h2 : j < a₂.size then
|
||||
match a₂[j] with
|
||||
else if j < a₂.size then
|
||||
match a₂[j]! with
|
||||
| none => isSubPrefixOfAux a₁ a₂ exceptFVars i (j+1)
|
||||
| some decl₂ => if decl₁.fvarId == decl₂.fvarId then isSubPrefixOfAux a₁ a₂ exceptFVars (i+1) (j+1) else isSubPrefixOfAux a₁ a₂ exceptFVars i (j+1)
|
||||
else false
|
||||
|
||||
@@ -155,8 +155,8 @@ where
|
||||
if !infos[i]!.isInstImplicit then
|
||||
if !(← lt args[i]! b) then
|
||||
return false
|
||||
for h : i in [infos.size:args.size] do
|
||||
if !(← lt args[i] b) then
|
||||
for i in [infos.size:args.size] do
|
||||
if !(← lt args[i]! b) then
|
||||
return false
|
||||
return true
|
||||
| .lam _ d e .. => lt d b <&&> lt e b
|
||||
|
||||
@@ -277,7 +277,7 @@ private def mkAppMFinal (methodName : Name) (f : Expr) (args : Array Expr) (inst
|
||||
|
||||
private partial def mkAppMArgs (f : Expr) (fType : Expr) (xs : Array Expr) : MetaM Expr :=
|
||||
let rec loop (type : Expr) (i : Nat) (j : Nat) (args : Array Expr) (instMVars : Array MVarId) : MetaM Expr := do
|
||||
if h : i >= xs.size then
|
||||
if i >= xs.size then
|
||||
mkAppMFinal `mkAppM f args instMVars
|
||||
else match type with
|
||||
| Expr.forallE n d b bi =>
|
||||
@@ -293,7 +293,7 @@ private partial def mkAppMArgs (f : Expr) (fType : Expr) (xs : Array Expr) : Met
|
||||
let mvar ← mkFreshExprMVar d MetavarKind.synthetic n
|
||||
loop b i j (args.push mvar) (instMVars.push mvar.mvarId!)
|
||||
| _ =>
|
||||
let x := xs[i]
|
||||
let x := xs[i]!
|
||||
let xType ← inferType x
|
||||
if (← isDefEq d xType) then
|
||||
loop b (i+1) j (args.push x) instMVars
|
||||
|
||||
@@ -69,8 +69,8 @@ The `type` should be the expected type of the packed argument, as created with `
|
||||
partial def pack (type : Expr) (args : Array Expr) : Expr := go 0 type
|
||||
where
|
||||
go (i : Nat) (type : Expr) : Expr :=
|
||||
if h : i < args.size - 1 then
|
||||
let arg := args[i]
|
||||
if i < args.size - 1 then
|
||||
let arg := args[i]!
|
||||
assert! type.isAppOfArity ``PSigma 2
|
||||
let us := type.getAppFn.constLevels!
|
||||
let α := type.appFn!.appArg!
|
||||
|
||||
@@ -77,7 +77,7 @@ partial def mkHCongrWithArity (f : Expr) (numArgs : Nat) : MetaM CongrTheorem :=
|
||||
where
|
||||
withNewEqs {α} (xs ys : Array Expr) (k : Array Expr → Array CongrArgKind → MetaM α) : MetaM α :=
|
||||
let rec loop (i : Nat) (eqs : Array Expr) (kinds : Array CongrArgKind) := do
|
||||
if i < xs.size then
|
||||
if i < xs.size then
|
||||
let x := xs[i]!
|
||||
let y := ys[i]!
|
||||
let xType := (← inferType x).cleanupAnnotations
|
||||
@@ -185,11 +185,11 @@ private def getClassSubobjectMask? (f : Expr) : MetaM (Option (Array Bool)) := d
|
||||
forallTelescopeReducing val.type (cleanupAnnotations := true) fun xs _ => do
|
||||
let env ← getEnv
|
||||
let mut mask := #[]
|
||||
for h : i in [:xs.size] do
|
||||
for i in [:xs.size] do
|
||||
if i < val.numParams then
|
||||
mask := mask.push false
|
||||
else
|
||||
let localDecl ← xs[i].fvarId!.getDecl
|
||||
let localDecl ← xs[i]!.fvarId!.getDecl
|
||||
mask := mask.push (isSubobjectField? env val.induct localDecl.userName).isSome
|
||||
return some mask
|
||||
|
||||
@@ -211,14 +211,14 @@ def getCongrSimpKinds (f : Expr) (info : FunInfo) : MetaM (Array CongrArgKind) :
|
||||
-/
|
||||
let mut result := #[]
|
||||
let mask? ← getClassSubobjectMask? f
|
||||
for h : i in [:info.paramInfo.size] do
|
||||
for i in [:info.paramInfo.size] do
|
||||
if info.resultDeps.contains i then
|
||||
result := result.push .fixed
|
||||
else if info.paramInfo[i].isProp then
|
||||
else if info.paramInfo[i]!.isProp then
|
||||
result := result.push .cast
|
||||
else if info.paramInfo[i].isInstImplicit then
|
||||
else if info.paramInfo[i]!.isInstImplicit then
|
||||
if let some mask := mask? then
|
||||
if h2 : i < mask.size then
|
||||
if h : i < mask.size then
|
||||
if mask[i] then
|
||||
-- Parameter is a subobect field of a class constructor. See comment above.
|
||||
result := result.push .eq
|
||||
|
||||
Some files were not shown because too many files have changed in this diff Show More
Reference in New Issue
Block a user