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inferInsta
| Author | SHA1 | Date | |
|---|---|---|---|
|
dd1303b64c | ||
|
|
57f13c89f2 |
15
.github/workflows/ci.yml
vendored
15
.github/workflows/ci.yml
vendored
@@ -76,20 +76,9 @@ jobs:
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fi
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echo "nightly=$LEAN_VERSION_STRING" >> "$GITHUB_OUTPUT"
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else
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# Scheduled: do nothing if commit already has a different tag (e.g. a release tag)
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# Scheduled: do nothing if commit already has a different tag
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LEAN_VERSION_STRING="nightly-$(date -u +%F)"
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HEAD_TAG="$(git name-rev --name-only --tags --no-undefined HEAD 2> /dev/null || true)"
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if [[ -n "$HEAD_TAG" && "$HEAD_TAG" != "$LEAN_VERSION_STRING" ]]; then
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echo "HEAD already tagged as ${HEAD_TAG}, skipping nightly"
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elif git rev-parse "refs/tags/${LEAN_VERSION_STRING}" >/dev/null 2>&1; then
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# Today's nightly already exists (e.g. from a manual release), create a revision
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REV=1
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while git rev-parse "refs/tags/${LEAN_VERSION_STRING}-rev${REV}" >/dev/null 2>&1; do
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REV=$((REV + 1))
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done
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LEAN_VERSION_STRING="${LEAN_VERSION_STRING}-rev${REV}"
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echo "nightly=$LEAN_VERSION_STRING" >> "$GITHUB_OUTPUT"
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else
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if [[ "$(git name-rev --name-only --tags --no-undefined HEAD 2> /dev/null || echo "$LEAN_VERSION_STRING")" == "$LEAN_VERSION_STRING" ]]; then
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echo "nightly=$LEAN_VERSION_STRING" >> "$GITHUB_OUTPUT"
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fi
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fi
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@@ -14,6 +14,13 @@ repositories:
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bump-branch: true
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dependencies: []
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- name: lean4checker
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url: https://github.com/leanprover/lean4checker
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toolchain-tag: true
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stable-branch: true
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branch: master
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dependencies: []
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- name: quote4
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url: https://github.com/leanprover-community/quote4
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toolchain-tag: true
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@@ -37,7 +37,7 @@ set_option linter.unusedVariables false in -- `s` unused
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Use a monadic action that may throw an exception by providing explicit success and failure
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continuations.
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-/
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@[always_inline, inline, expose]
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@[always_inline, inline]
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def runK {ε α : Type u} (x : ExceptCpsT ε m α) (s : ε) (ok : α → m β) (error : ε → m β) : m β :=
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x _ ok error
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@@ -83,8 +83,6 @@ of `True`.
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-/
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instance : MonadAttach (ExceptCpsT ε m) := .trivial
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@[simp] theorem throw_bind [Monad m] (e : ε) (f : α → ExceptCpsT ε m β) : (throw e >>= f : ExceptCpsT ε m β) = throw e := rfl
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@[simp] theorem run_pure [Monad m] : run (pure x : ExceptCpsT ε m α) = pure (Except.ok x) := rfl
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@[simp] theorem run_lift {α ε : Type u} [Monad m] (x : m α) : run (ExceptCpsT.lift x : ExceptCpsT ε m α) = (x >>= fun a => pure (Except.ok a) : m (Except ε α)) := rfl
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@@ -93,20 +91,7 @@ instance : MonadAttach (ExceptCpsT ε m) := .trivial
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@[simp] theorem run_bind_lift [Monad m] (x : m α) (f : α → ExceptCpsT ε m β) : run (ExceptCpsT.lift x >>= f : ExceptCpsT ε m β) = x >>= fun a => run (f a) := rfl
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@[deprecated throw_bind (since := "2026-03-13")]
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theorem run_bind_throw [Monad m] (e : ε) (f : α → ExceptCpsT ε m β) : run (throw e >>= f : ExceptCpsT ε m β) = run (throw e) := rfl
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@[simp] theorem runK_pure :
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runK (pure x : ExceptCpsT ε m α) s ok error = ok x := rfl
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@[simp] theorem runK_lift {α ε : Type u} [Monad m] (x : m α) (s : ε) (ok : α → m β) (error : ε → m β) :
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runK (ExceptCpsT.lift x : ExceptCpsT ε m α) s ok error = x >>= ok := rfl
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@[simp] theorem runK_throw [Monad m] :
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runK (throw e : ExceptCpsT ε m β) s ok error = error e := rfl
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@[simp] theorem runK_bind_lift [Monad m] (x : m α) (f : α → ExceptCpsT ε m β) :
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runK (ExceptCpsT.lift x >>= f : ExceptCpsT ε m β) s ok error = x >>= fun a => runK (f a) s ok error := rfl
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@[simp] theorem run_bind_throw [Monad m] (e : ε) (f : α → ExceptCpsT ε m β) : run (throw e >>= f : ExceptCpsT ε m β) = run (throw e) := rfl
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@[simp] theorem runCatch_pure [Monad m] : runCatch (pure x : ExceptCpsT α m α) = pure x := rfl
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@@ -117,7 +102,6 @@ theorem run_bind_throw [Monad m] (e : ε) (f : α → ExceptCpsT ε m β) : run
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@[simp] theorem runCatch_bind_lift [Monad m] (x : m α) (f : α → ExceptCpsT β m β) : runCatch (ExceptCpsT.lift x >>= f : ExceptCpsT β m β) = x >>= fun a => runCatch (f a) := rfl
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@[deprecated throw_bind (since := "2026-03-13")]
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theorem runCatch_bind_throw [Monad m] (e : β) (f : α → ExceptCpsT β m β) : runCatch (throw e >>= f : ExceptCpsT β m β) = pure e := rfl
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@[simp] theorem runCatch_bind_throw [Monad m] (e : β) (f : α → ExceptCpsT β m β) : runCatch (throw e >>= f : ExceptCpsT β m β) = pure e := rfl
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end ExceptCpsT
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@@ -201,10 +201,6 @@ theorem Pos.prev_eq_iff {s : Slice} {p q : s.Pos} {h} :
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theorem Pos.prev_lt {s : Slice} {p : s.Pos} {h} : p.prev h < p := by
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simp
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@[simp]
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theorem Pos.prev_le {s : Slice} {p : s.Pos} {h} : p.prev h ≤ p :=
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Std.le_of_lt (by simp)
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@[simp]
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theorem Pos.prev_ne_endPos {s : Slice} {p : s.Pos} {h} : p.prev h ≠ s.endPos :=
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ne_endPos_of_lt prev_lt
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@@ -215,29 +211,6 @@ theorem Pos.prevn_le {s : Slice} {p : s.Pos} {n : Nat} : p.prevn n ≤ p := by
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| case2 p n h ih => exact Std.le_of_lt (by simpa using ih)
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| case3 => simp
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theorem Pos.ofSliceTo_prev {s : Slice} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos} {h} :
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Pos.ofSliceTo (p.prev h) = (Pos.ofSliceTo p).prev (by simpa [← Pos.ofSliceTo_inj] using h) := by
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rw [eq_comm, Pos.prev_eq_iff]
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simp only [Pos.ofSliceTo_lt_ofSliceTo_iff, Pos.le_ofSliceTo_iff]
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simp [Pos.lt_ofSliceTo_iff]
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theorem Pos.prev_ofSliceTo {s : Slice} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos} {h} :
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(Pos.ofSliceTo p).prev h = Pos.ofSliceTo (p.prev (by simpa [← Pos.ofSliceTo_inj])) := by
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simp [ofSliceTo_prev]
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theorem Pos.ofSliceFrom_prev {s : Slice} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos} {h} :
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Pos.ofSliceFrom (p.prev h) = (Pos.ofSliceFrom p).prev (by exact ofSliceFrom_ne_startPos h) := by
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rw [eq_comm, Pos.prev_eq_iff]
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simp only [Pos.ofSliceFrom_lt_ofSliceFrom_iff, Pos.le_ofSliceFrom_iff]
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simp [Pos.lt_ofSliceFrom_iff]
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theorem Pos.ofSlice_prev {s : Slice} {p₀ p₁ : s.Pos} {h}
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{p : (s.slice p₀ p₁ h).Pos} {h'} :
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Pos.ofSlice (p.prev h') = (Pos.ofSlice p).prev (by exact ofSlice_ne_startPos h') := by
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rw [eq_comm, Pos.prev_eq_iff]
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simp only [ofSlice_lt_ofSlice_iff, le_ofSlice_iff]
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simpa +contextual [← ofSlice_lt_ofSlice_iff] using fun q hq => Std.le_of_lt (Std.lt_of_lt_of_le hq ofSlice_le)
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@[simp]
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theorem Pos.prev_next {s : Slice} {p : s.Pos} {h} : (p.next h).prev (by simp) = p :=
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prev_eq_iff.2 (by simp)
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@@ -466,10 +439,6 @@ theorem Pos.prev_eq_iff {s : String} {p q : s.Pos} {h} :
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theorem Pos.prev_lt {s : String} {p : s.Pos} {h} : p.prev h < p := by
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simp
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@[simp]
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theorem Pos.prev_le {s : String} {p : s.Pos} {h} : p.prev h ≤ p :=
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Std.le_of_lt (by simp)
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@[simp]
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theorem Pos.prev_ne_endPos {s : String} {p : s.Pos} {h} : p.prev h ≠ s.endPos :=
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ne_endPos_of_lt prev_lt
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@@ -494,29 +463,6 @@ theorem Pos.prevn_le {s : String} {p : s.Pos} {n : Nat} :
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p.prevn n ≤ p := by
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simpa [Pos.le_iff, ← offset_toSlice] using Slice.Pos.prevn_le
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theorem Pos.ofSliceTo_prev {s : String} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos} {h} :
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Pos.ofSliceTo (p.prev h) = (Pos.ofSliceTo p).prev (by simpa [← Pos.ofSliceTo_inj] using h) := by
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rw [eq_comm, Pos.prev_eq_iff]
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simp only [Pos.ofSliceTo_lt_ofSliceTo_iff, Pos.le_ofSliceTo_iff]
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simp [Pos.lt_ofSliceTo_iff]
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theorem Pos.prev_ofSliceTo {s : String} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos} {h} :
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(Pos.ofSliceTo p).prev h = Pos.ofSliceTo (p.prev (by simpa [← Pos.ofSliceTo_inj])) := by
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simp [ofSliceTo_prev]
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theorem Pos.ofSliceFrom_prev {s : String} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos} {h} :
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Pos.ofSliceFrom (p.prev h) = (Pos.ofSliceFrom p).prev (by exact ofSliceFrom_ne_startPos h) := by
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rw [eq_comm, Pos.prev_eq_iff]
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simp only [Pos.ofSliceFrom_lt_ofSliceFrom_iff, Pos.le_ofSliceFrom_iff]
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simp [Pos.lt_ofSliceFrom_iff]
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theorem Pos.ofSlice_prev {s : String} {p₀ p₁ : s.Pos} {h}
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{p : (s.slice p₀ p₁ h).Pos} {h'} :
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Pos.ofSlice (p.prev h') = (Pos.ofSlice p).prev (by exact ofSlice_ne_startPos h') := by
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rw [eq_comm, Pos.prev_eq_iff]
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simp only [ofSlice_lt_ofSlice_iff, le_ofSlice_iff]
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simpa +contextual [← ofSlice_lt_ofSlice_iff] using fun q hq => Std.le_of_lt (Std.lt_of_lt_of_le hq ofSlice_le)
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@[simp]
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theorem Pos.prev_next {s : String} {p : s.Pos} {h} : (p.next h).prev (by simp) = p :=
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prev_eq_iff.2 (by simp)
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@@ -204,7 +204,7 @@ theorem Slice.copy_sliceTo_startPos {s : Slice} : (s.sliceTo s.startPos).copy =
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simp
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@[simp]
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theorem Slice.copy_sliceFrom_endPos {s : Slice} : (s.sliceFrom s.endPos).copy = "" := by
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theorem Slice.copy_sliceFrom_startPos {s : Slice} : (s.sliceFrom s.endPos).copy = "" := by
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simp
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end CopyEqEmpty
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@@ -11,7 +11,6 @@ import Init.Data.String.OrderInstances
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import Init.Data.String.Lemmas.Basic
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import Init.Data.Order.Lemmas
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import Init.Omega
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import Init.ByCases
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public section
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@@ -71,7 +70,7 @@ theorem Pos.le_startPos {s : String} (p : s.Pos) : p ≤ s.startPos ↔ p = s.st
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⟨fun h => Std.le_antisymm h (startPos_le _), by simp +contextual⟩
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@[simp]
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theorem Pos.startPos_lt_iff {s : String} (p : s.Pos) : s.startPos < p ↔ p ≠ s.startPos := by
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theorem Pos.startPos_lt_iff {s : String} {p : s.Pos} : s.startPos < p ↔ p ≠ s.startPos := by
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simp [← le_startPos, Std.not_le]
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|
||||
@[simp]
|
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@@ -236,10 +235,6 @@ theorem Slice.Pos.ofSliceFrom_next {s : Slice} {p₀ : s.Pos} {p : (s.sliceFrom
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Pos.next_le_iff_lt, true_and]
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simp [Pos.ofSliceFrom_lt_iff]
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|
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theorem Slice.Pos.next_ofSliceFrom {s : Slice} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos} {h} :
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(Pos.ofSliceFrom p).next h = Pos.ofSliceFrom (p.next (by simpa [← Pos.ofSliceFrom_inj])) := by
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simp [ofSliceFrom_next]
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|
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theorem Pos.ofSliceFrom_next {s : String} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos} {h} :
|
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Pos.ofSliceFrom (p.next h) = (Pos.ofSliceFrom p).next (by simpa [← Pos.ofSliceFrom_inj] using h) := by
|
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rw [eq_comm, Pos.next_eq_iff]
|
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@@ -247,10 +242,6 @@ theorem Pos.ofSliceFrom_next {s : String} {p₀ : s.Pos} {p : (s.sliceFrom p₀)
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Slice.Pos.next_le_iff_lt, true_and]
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simp [Pos.ofSliceFrom_lt_iff]
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|
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theorem Pos.next_ofSliceFrom {s : String} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos} {h} :
|
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(Pos.ofSliceFrom p).next h = Pos.ofSliceFrom (p.next (by simpa [← Pos.ofSliceFrom_inj])) := by
|
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simp [Pos.ofSliceFrom_next]
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|
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theorem Slice.Pos.le_ofSliceTo_iff {s : Slice} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos} {q : s.Pos} :
|
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q ≤ Pos.ofSliceTo p ↔ ∃ h, Slice.Pos.sliceTo p₀ q h ≤ p := by
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refine ⟨fun h => ⟨Slice.Pos.le_trans h Pos.ofSliceTo_le, ?_⟩, fun ⟨h, h'⟩ => ?_⟩
|
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@@ -368,21 +359,11 @@ theorem Slice.Pos.ofSliceTo_ne_endPos {s : Slice} {p₀ : s.Pos} {p : (s.sliceTo
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refine (lt_endPos_iff _).1 (Std.lt_of_lt_of_le ?_ (le_endPos p₀))
|
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simpa [← lt_endPos_iff, ← ofSliceTo_lt_ofSliceTo_iff] using h
|
||||
|
||||
theorem Slice.Pos.ofSliceFrom_ne_startPos {s : Slice} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos}
|
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(h : p ≠ (s.sliceFrom p₀).startPos) : Pos.ofSliceFrom p ≠ s.startPos := by
|
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refine (startPos_lt_iff _).1 (Std.lt_of_le_of_lt (startPos_le p₀) ?_)
|
||||
simpa [← startPos_lt_iff, ← ofSliceFrom_lt_ofSliceFrom_iff] using h
|
||||
|
||||
theorem Pos.ofSliceTo_ne_endPos {s : String} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos}
|
||||
(h : p ≠ (s.sliceTo p₀).endPos) : Pos.ofSliceTo p ≠ s.endPos := by
|
||||
refine (lt_endPos_iff _).1 (Std.lt_of_lt_of_le ?_ (le_endPos p₀))
|
||||
simpa [← Slice.Pos.lt_endPos_iff, ← ofSliceTo_lt_ofSliceTo_iff] using h
|
||||
|
||||
theorem Pos.ofSliceFrom_ne_startPos {s : String} {p₀ : s.Pos} {p : (s.sliceFrom p₀).Pos}
|
||||
(h : p ≠ (s.sliceFrom p₀).startPos) : Pos.ofSliceFrom p ≠ s.startPos := by
|
||||
refine (startPos_lt_iff _).1 (Std.lt_of_le_of_lt (startPos_le p₀) ?_)
|
||||
simpa [← Slice.Pos.startPos_lt_iff, ← ofSliceFrom_lt_ofSliceFrom_iff] using h
|
||||
|
||||
theorem Slice.Pos.ofSliceTo_next {s : Slice} {p₀ : s.Pos} {p : (s.sliceTo p₀).Pos} {h} :
|
||||
Pos.ofSliceTo (p.next h) = (Pos.ofSliceTo p).next (ofSliceTo_ne_endPos h) := by
|
||||
rw [eq_comm, Pos.next_eq_iff]
|
||||
@@ -425,110 +406,16 @@ theorem Pos.slice_le_slice_iff {s : String} {p₀ p₁ : s.Pos} {q r : s.Pos}
|
||||
simp [Slice.Pos.le_iff, Pos.le_iff, Pos.Raw.le_iff] at h₁ h₁' ⊢
|
||||
omega
|
||||
|
||||
theorem Slice.Pos.le_ofSlice_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
q ≤ Pos.ofSlice p ↔ ∃ h₁, ∀ h₀, Slice.Pos.slice q p₀ p₁ h₀ h₁ ≤ p := by
|
||||
refine ⟨fun h => ⟨Std.le_trans h ofSlice_le, fun h' => ?_⟩, fun ⟨h₁, h⟩ => ?_⟩
|
||||
· simp only [← Slice.Pos.slice_ofSlice (pos := p), slice_le_slice_iff]
|
||||
simpa
|
||||
· by_cases h₀ : p₀ ≤ q
|
||||
· simpa only [← Slice.Pos.ofSlice_slice (h₁ := h₀) (h₂ := h₁), ofSlice_le_ofSlice_iff] using h h₀
|
||||
· exact Std.le_of_lt (Std.lt_of_lt_of_le (Std.not_le.1 h₀) le_ofSlice)
|
||||
|
||||
theorem Slice.Pos.ofSlice_lt_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
Pos.ofSlice p < q ↔ ∀ h₁, ∃ h₀, p < Slice.Pos.slice q p₀ p₁ h₀ h₁ := by
|
||||
simp [← Std.not_le, le_ofSlice_iff]
|
||||
|
||||
theorem Slice.Pos.lt_ofSlice_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
q < Pos.ofSlice p ↔ ∃ h₁, ∀ h₀, Slice.Pos.slice q p₀ p₁ h₀ h₁ < p := by
|
||||
refine ⟨fun h => ⟨Std.le_of_lt (Std.lt_of_lt_of_le h ofSlice_le), fun h' => ?_⟩, fun ⟨h₁, h⟩ => ?_⟩
|
||||
· simp only [← Slice.Pos.slice_ofSlice (pos := p), slice_lt_slice_iff]
|
||||
simpa
|
||||
· by_cases h₀ : p₀ ≤ q
|
||||
· simpa only [← Slice.Pos.ofSlice_slice (h₁ := h₀) (h₂ := h₁), ofSlice_lt_ofSlice_iff] using h h₀
|
||||
· exact Std.lt_of_lt_of_le (Std.not_le.1 h₀) le_ofSlice
|
||||
|
||||
theorem Slice.Pos.ofSlice_le_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
Pos.ofSlice p ≤ q ↔ ∀ h₁, ∃ h₀, p ≤ Slice.Pos.slice q p₀ p₁ h₀ h₁ := by
|
||||
simp [← Std.not_lt, lt_ofSlice_iff]
|
||||
|
||||
theorem Pos.le_ofSlice_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
q ≤ Pos.ofSlice p ↔ ∃ h₁, ∀ h₀, Pos.slice q p₀ p₁ h₀ h₁ ≤ p := by
|
||||
refine ⟨fun h => ⟨Std.le_trans h ofSlice_le, fun h' => ?_⟩, fun ⟨h₁, h⟩ => ?_⟩
|
||||
· simp only [← Pos.slice_ofSlice (pos := p), slice_le_slice_iff]
|
||||
simpa
|
||||
· by_cases h₀ : p₀ ≤ q
|
||||
· simpa only [← Pos.ofSlice_slice (h₁ := h₀) (h₂ := h₁), ofSlice_le_ofSlice_iff] using h h₀
|
||||
· exact Std.le_of_lt (Std.lt_of_lt_of_le (Std.not_le.1 h₀) le_ofSlice)
|
||||
|
||||
theorem Pos.ofSlice_lt_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
Pos.ofSlice p < q ↔ ∀ h₁, ∃ h₀, p < Pos.slice q p₀ p₁ h₀ h₁ := by
|
||||
simp [← Std.not_le, le_ofSlice_iff]
|
||||
|
||||
theorem Pos.lt_ofSlice_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
q < Pos.ofSlice p ↔ ∃ h₁, ∀ h₀, Pos.slice q p₀ p₁ h₀ h₁ < p := by
|
||||
refine ⟨fun h => ⟨Std.le_of_lt (Std.lt_of_lt_of_le h ofSlice_le), fun h' => ?_⟩, fun ⟨h₁, h⟩ => ?_⟩
|
||||
· simp only [← Pos.slice_ofSlice (pos := p), slice_lt_slice_iff]
|
||||
simpa
|
||||
· by_cases h₀ : p₀ ≤ q
|
||||
· simpa only [← Pos.ofSlice_slice (h₁ := h₀) (h₂ := h₁), ofSlice_lt_ofSlice_iff] using h h₀
|
||||
· exact Std.lt_of_lt_of_le (Std.not_le.1 h₀) le_ofSlice
|
||||
|
||||
theorem Pos.ofSlice_le_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} :
|
||||
Pos.ofSlice p ≤ q ↔ ∀ h₁, ∃ h₀, p ≤ Pos.slice q p₀ p₁ h₀ h₁ := by
|
||||
simp [← Std.not_lt, lt_ofSlice_iff]
|
||||
|
||||
theorem Slice.Pos.slice_le_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
Slice.Pos.slice q p₀ p₁ h₀ h₁ ≤ p ↔ q ≤ Pos.ofSlice p := by
|
||||
simp [le_ofSlice_iff, h₀, h₁]
|
||||
|
||||
theorem Slice.Pos.lt_slice_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
p < Slice.Pos.slice q p₀ p₁ h₀ h₁ ↔ Pos.ofSlice p < q := by
|
||||
simp [ofSlice_lt_iff, h₀, h₁]
|
||||
|
||||
theorem Slice.Pos.slice_lt_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
Slice.Pos.slice q p₀ p₁ h₀ h₁ < p ↔ q < Pos.ofSlice p := by
|
||||
simp [lt_ofSlice_iff, h₀, h₁]
|
||||
|
||||
theorem Slice.Pos.le_slice_iff {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
p ≤ Slice.Pos.slice q p₀ p₁ h₀ h₁ ↔ Pos.ofSlice p ≤ q := by
|
||||
simp [ofSlice_le_iff, h₀, h₁]
|
||||
|
||||
theorem Pos.slice_le_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
Pos.slice q p₀ p₁ h₀ h₁ ≤ p ↔ q ≤ Pos.ofSlice p := by
|
||||
simp [le_ofSlice_iff, h₀, h₁]
|
||||
|
||||
theorem Pos.lt_slice_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
p < Pos.slice q p₀ p₁ h₀ h₁ ↔ Pos.ofSlice p < q := by
|
||||
simp [ofSlice_lt_iff, h₀, h₁]
|
||||
|
||||
theorem Pos.slice_lt_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
Pos.slice q p₀ p₁ h₀ h₁ < p ↔ q < Pos.ofSlice p := by
|
||||
simp [lt_ofSlice_iff, h₀, h₁]
|
||||
|
||||
theorem Pos.le_slice_iff {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos} {q : s.Pos} {h₀ h₁} :
|
||||
p ≤ Pos.slice q p₀ p₁ h₀ h₁ ↔ Pos.ofSlice p ≤ q := by
|
||||
simp [ofSlice_le_iff, h₀, h₁]
|
||||
|
||||
theorem Slice.Pos.ofSlice_ne_endPos {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos}
|
||||
(h : p ≠ (s.slice p₀ p₁ h).endPos) : Pos.ofSlice p ≠ s.endPos := by
|
||||
refine (lt_endPos_iff _).1 (Std.lt_of_lt_of_le ?_ (le_endPos p₁))
|
||||
simpa [← lt_endPos_iff, ← ofSlice_lt_ofSlice_iff] using h
|
||||
|
||||
theorem Slice.Pos.ofSlice_ne_startPos {s : Slice} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos}
|
||||
(h : p ≠ (s.slice p₀ p₁ h).startPos) : Pos.ofSlice p ≠ s.startPos := by
|
||||
refine (startPos_lt_iff _).1 (Std.lt_of_le_of_lt (startPos_le p₀) ?_)
|
||||
simpa [← startPos_lt_iff, ← ofSlice_lt_ofSlice_iff] using h
|
||||
|
||||
theorem Pos.ofSlice_ne_endPos {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos}
|
||||
(h : p ≠ (s.slice p₀ p₁ h).endPos) : Pos.ofSlice p ≠ s.endPos := by
|
||||
refine (lt_endPos_iff _).1 (Std.lt_of_lt_of_le ?_ (le_endPos p₁))
|
||||
simpa [← Slice.Pos.lt_endPos_iff, ← ofSlice_lt_ofSlice_iff] using h
|
||||
|
||||
theorem Pos.ofSlice_ne_startPos {s : String} {p₀ p₁ : s.Pos} {h} {p : (s.slice p₀ p₁ h).Pos}
|
||||
(h : p ≠ (s.slice p₀ p₁ h).startPos) : Pos.ofSlice p ≠ s.startPos := by
|
||||
refine (startPos_lt_iff _).1 (Std.lt_of_le_of_lt (startPos_le p₀) ?_)
|
||||
simpa [← Slice.Pos.startPos_lt_iff, ← ofSlice_lt_ofSlice_iff] using h
|
||||
|
||||
@[simp]
|
||||
theorem Slice.Pos.offset_le_rawEndPos {s : Slice} {p : s.Pos} :
|
||||
p.offset ≤ s.rawEndPos :=
|
||||
|
||||
@@ -19,7 +19,6 @@ import Init.Data.Order.Lemmas
|
||||
import Init.ByCases
|
||||
import Init.Data.Option.Lemmas
|
||||
import Init.Data.Iterators.Lemmas.Consumers.Collect
|
||||
import Init.Data.String.Lemmas.FindPos
|
||||
|
||||
set_option doc.verso true
|
||||
|
||||
@@ -32,20 +31,19 @@ This file develops basic theory around searching in strings.
|
||||
|
||||
We provide a typeclass for providing semantics to a pattern and then define the relevant notions
|
||||
of matching a pattern that let us state compatibility typeclasses for {name}`ForwardPattern` and
|
||||
{name}`ToForwardSearcher` as well as their backwards variants. These typeclasses can then be
|
||||
required by correctness results for string functions which are implemented using the pattern
|
||||
framework.
|
||||
{name}`ToForwardSearcher`. These typeclasses can then be required by correctness results for
|
||||
string functions which are implemented using the pattern framework.
|
||||
-/
|
||||
|
||||
/--
|
||||
This data-carrying typeclass is used to give semantics to a pattern type that implements
|
||||
{name}`ForwardPattern` and/or {name}`ToForwardSearcher` by providing an abstract, not necessarily
|
||||
decidable {name}`PatternModel.Matches` predicate that implementates of {name}`ForwardPattern`
|
||||
decidable {name}`ForwardPatternModel.Matches` predicate that implementates of {name}`ForwardPattern`
|
||||
and {name}`ToForwardSearcher` can be validated against.
|
||||
|
||||
Correctness results for generic functions relying on the pattern infrastructure, for example the
|
||||
correctness result for {name (scope := "Init.Data.String.Slice")}`String.Slice.split`, are then
|
||||
stated in terms of {name}`PatternModel.Matches`, and can be specialized to specific patterns
|
||||
stated in terms of {name}`ForwardPatternModel.Matches`, and can be specialized to specific patterns
|
||||
from there.
|
||||
|
||||
The corresponding compatibility typeclasses are
|
||||
@@ -61,7 +59,7 @@ searching.
|
||||
This means that pattern types that allow searching for the empty string will have to special-case
|
||||
the empty string in their correctness statements.
|
||||
-/
|
||||
class PatternModel {ρ : Type} (pat : ρ) : Type where
|
||||
class ForwardPatternModel {ρ : Type} (pat : ρ) : Type where
|
||||
/-- The predicate that says which strings match the pattern. -/
|
||||
Matches : String → Prop
|
||||
not_matches_empty : ¬ Matches ""
|
||||
@@ -71,72 +69,49 @@ Predicate stating that the region between the start of the slice {name}`s` and t
|
||||
{name}`endPos` matches the pattern {name}`pat`. Note that there might be a longer match, see
|
||||
{name (scope := "Init.Data.String.Lemmas.Pattern.Basic")}`String.Slice.Pattern.IsLongestMatch`.
|
||||
-/
|
||||
structure IsMatch (pat : ρ) [PatternModel pat] {s : Slice} (endPos : s.Pos) : Prop where
|
||||
matches_copy : PatternModel.Matches pat (s.sliceTo endPos).copy
|
||||
structure IsMatch (pat : ρ) [ForwardPatternModel pat] {s : Slice} (endPos : s.Pos) : Prop where
|
||||
matches_copy : ForwardPatternModel.Matches pat (s.sliceTo endPos).copy
|
||||
|
||||
theorem IsMatch.ne_startPos {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos}
|
||||
theorem IsMatch.ne_startPos {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos : s.Pos}
|
||||
(h : IsMatch pat pos) : pos ≠ s.startPos := by
|
||||
intro hc
|
||||
apply PatternModel.not_matches_empty (pat := pat)
|
||||
apply ForwardPatternModel.not_matches_empty (pat := pat)
|
||||
simpa [hc] using h.matches_copy
|
||||
|
||||
theorem isMatch_iff {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch pat pos ↔ PatternModel.Matches pat (s.sliceTo pos).copy :=
|
||||
theorem isMatch_iff {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch pat pos ↔ ForwardPatternModel.Matches pat (s.sliceTo pos).copy :=
|
||||
⟨fun ⟨h⟩ => h, fun h => ⟨h⟩⟩
|
||||
|
||||
theorem isMatch_iff_exists_splits {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch pat pos ↔ ∃ t₁ t₂, pos.Splits t₁ t₂ ∧ PatternModel.Matches pat t₁ := by
|
||||
theorem isMatch_iff_exists_splits {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch pat pos ↔ ∃ t₁ t₂, pos.Splits t₁ t₂ ∧ ForwardPatternModel.Matches pat t₁ := by
|
||||
rw [isMatch_iff]
|
||||
refine ⟨fun h => ⟨_, _, pos.splits, h⟩, fun ⟨t₁, t₂, h₁, h₂⟩ => ?_⟩
|
||||
rwa [h₁.eq_left pos.splits] at h₂
|
||||
|
||||
/--
|
||||
Predicate stating that the region between the position {name}`startPos` and the end of the slice
|
||||
{name}`s` matches the pattern {name}`pat`. Note that there might be a longer match.
|
||||
-/
|
||||
structure IsRevMatch (pat : ρ) [PatternModel pat] {s : Slice} (startPos : s.Pos) : Prop where
|
||||
matches_copy : PatternModel.Matches pat (s.sliceFrom startPos).copy
|
||||
|
||||
theorem IsRevMatch.ne_endPos {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos}
|
||||
(h : IsRevMatch pat pos) : pos ≠ s.endPos := by
|
||||
intro hc
|
||||
apply PatternModel.not_matches_empty (pat := pat)
|
||||
simpa [hc] using h.matches_copy
|
||||
|
||||
theorem isRevMatch_iff {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch pat pos ↔ PatternModel.Matches pat (s.sliceFrom pos).copy :=
|
||||
⟨fun ⟨h⟩ => h, fun h => ⟨h⟩⟩
|
||||
|
||||
theorem isRevMatch_iff_exists_splits {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch pat pos ↔ ∃ t₁ t₂, pos.Splits t₁ t₂ ∧ PatternModel.Matches pat t₂ := by
|
||||
rw [isRevMatch_iff]
|
||||
refine ⟨fun h => ⟨_, _, pos.splits, h⟩, fun ⟨t₁, t₂, h₁, h₂⟩ => ?_⟩
|
||||
rwa [h₁.eq_right pos.splits] at h₂
|
||||
|
||||
/--
|
||||
Predicate stating that the region between the start of the slice {name}`s` and the position
|
||||
{name}`pos` matches the pattern {name}`pat`, and that there is no longer match starting at the
|
||||
{name}`endPos` matches that pattern {name}`pat`, and that there is no longer match starting at the
|
||||
beginning of the slice. This is what a correct matcher should match.
|
||||
|
||||
In some cases, being a match and being a longest match will coincide, see
|
||||
{name (scope := "Init.Data.String.Lemmas.Pattern.Basic")}`String.Slice.Pattern.Model.NoPrefixPatternModel`.
|
||||
{name (scope := "Init.Data.String.Lemmas.Pattern.Basic")}`String.Slice.Pattern.Model.NoPrefixForwardPatternModel`.
|
||||
-/
|
||||
structure IsLongestMatch (pat : ρ) [PatternModel pat] {s : Slice} (pos : s.Pos) where
|
||||
structure IsLongestMatch (pat : ρ) [ForwardPatternModel pat] {s : Slice} (pos : s.Pos) where
|
||||
isMatch : IsMatch pat pos
|
||||
not_isMatch : ∀ pos', pos < pos' → ¬ IsMatch pat pos'
|
||||
|
||||
theorem IsLongestMatch.ne_startPos {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos}
|
||||
theorem IsLongestMatch.ne_startPos {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos : s.Pos}
|
||||
(h : IsLongestMatch pat pos) : pos ≠ s.startPos :=
|
||||
h.isMatch.ne_startPos
|
||||
|
||||
theorem IsLongestMatch.eq {pat : ρ} [PatternModel pat] {s : Slice} {pos pos' : s.Pos}
|
||||
theorem IsLongestMatch.eq {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos pos' : s.Pos}
|
||||
(h : IsLongestMatch pat pos) (h' : IsLongestMatch pat pos') : pos = pos' := by
|
||||
apply Std.le_antisymm
|
||||
· exact Std.not_lt.1 (fun hlt => h'.not_isMatch _ hlt h.isMatch)
|
||||
· exact Std.not_lt.1 (fun hlt => h.not_isMatch _ hlt h'.isMatch)
|
||||
|
||||
open Classical in
|
||||
theorem IsMatch.exists_isLongestMatch {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
theorem IsMatch.exists_isLongestMatch {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch pat pos → ∃ (pos' : s.Pos), IsLongestMatch pat pos' := by
|
||||
induction pos using WellFounded.induction Pos.wellFounded_gt with | h pos ih
|
||||
intro h₁
|
||||
@@ -145,118 +120,61 @@ theorem IsMatch.exists_isLongestMatch {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
exact ih _ hp₁ hp₂
|
||||
· exact ⟨pos, ⟨h₁, fun p' hp₁ hp₂ => h₂ ⟨_, hp₁, hp₂⟩⟩⟩
|
||||
|
||||
theorem IsLongestMatch.le_of_isMatch {pat : ρ} [PatternModel pat] {s : Slice} {pos pos' : s.Pos}
|
||||
theorem IsLongestMatch.le_of_isMatch {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos pos' : s.Pos}
|
||||
(h : IsLongestMatch pat pos) (h' : IsMatch pat pos') : pos' ≤ pos :=
|
||||
Std.not_lt.1 (fun hlt => h.not_isMatch _ hlt h')
|
||||
|
||||
/--
|
||||
Predicate stating that the region between the start of the slice {name}`s` and the position
|
||||
{name}`pos` matches the patten {name}`pat`, and that there is no longer match starting at the
|
||||
beginning of the slice. This is what a correct matcher should match.
|
||||
|
||||
In some cases, being a match and being a longest match will coincide, see
|
||||
{name (scope := "Init.Data.String.Lemmas.Pattern.Basic")}`String.Slice.Pattern.Model.NoPrefixPatternModel`.
|
||||
-/
|
||||
structure IsLongestRevMatch (pat : ρ) [PatternModel pat] {s : Slice} (pos : s.Pos) where
|
||||
isRevMatch : IsRevMatch pat pos
|
||||
not_isRevMatch : ∀ pos', pos' < pos → ¬ IsRevMatch pat pos'
|
||||
|
||||
theorem IsLongestRevMatch.ne_endPos {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos}
|
||||
(h : IsLongestRevMatch pat pos) : pos ≠ s.endPos :=
|
||||
h.isRevMatch.ne_endPos
|
||||
|
||||
theorem IsLongestRevMatch.eq {pat : ρ} [PatternModel pat] {s : Slice} {pos pos' : s.Pos}
|
||||
(h : IsLongestRevMatch pat pos) (h' : IsLongestRevMatch pat pos') : pos = pos' := by
|
||||
apply Std.le_antisymm
|
||||
· exact Std.not_lt.1 (fun hlt => h.not_isRevMatch _ hlt h'.isRevMatch)
|
||||
· exact Std.not_lt.1 (fun hlt => h'.not_isRevMatch _ hlt h.isRevMatch)
|
||||
|
||||
open Classical in
|
||||
theorem IsRevMatch.exists_isLongestRevMatch {pat : ρ} [PatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch pat pos → ∃ (pos' : s.Pos), IsLongestRevMatch pat pos' := by
|
||||
induction pos using WellFounded.induction Pos.wellFounded_lt with | h pos ih
|
||||
intro h₁
|
||||
by_cases h₂ : ∃ pos', pos' < pos ∧ IsRevMatch pat pos'
|
||||
· obtain ⟨pos', hp₁, hp₂⟩ := h₂
|
||||
exact ih _ hp₁ hp₂
|
||||
· exact ⟨pos, ⟨h₁, fun p' hp₁ hp₂ => h₂ ⟨_, hp₁, hp₂⟩⟩⟩
|
||||
|
||||
theorem IsLongestRevMatch.le_of_isRevMatch {pat : ρ} [PatternModel pat] {s : Slice} {pos pos' : s.Pos}
|
||||
(h : IsLongestRevMatch pat pos) (h' : IsRevMatch pat pos') : pos ≤ pos' :=
|
||||
Std.not_lt.1 (fun hlt => h.not_isRevMatch _ hlt h')
|
||||
|
||||
/--
|
||||
Predicate stating that a match for a given pattern is never a proper prefix of another match.
|
||||
|
||||
This implies that the notion of match and longest match coincide.
|
||||
-/
|
||||
class NoPrefixPatternModel {ρ : Type} (pat : ρ) [PatternModel pat] : Prop where
|
||||
eq_empty (s t) : PatternModel.Matches pat s → PatternModel.Matches pat (s ++ t) → t = ""
|
||||
class NoPrefixForwardPatternModel {ρ : Type} (pat : ρ) [ForwardPatternModel pat] : Prop where
|
||||
eq_empty (s t) : ForwardPatternModel.Matches pat s → ForwardPatternModel.Matches pat (s ++ t) → t = ""
|
||||
|
||||
theorem NoPrefixPatternModel.of_length_eq {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
(h : ∀ s t, PatternModel.Matches pat s → PatternModel.Matches pat t → s.length = t.length) :
|
||||
NoPrefixPatternModel pat where
|
||||
theorem NoPrefixForwardPatternModel.of_length_eq {ρ : Type} {pat : ρ} [ForwardPatternModel pat]
|
||||
(h : ∀ s t, ForwardPatternModel.Matches pat s → ForwardPatternModel.Matches pat t → s.length = t.length) :
|
||||
NoPrefixForwardPatternModel pat where
|
||||
eq_empty s t hs ht := by simpa using h s _ hs ht
|
||||
|
||||
theorem isLongestMatch_iff_isMatch {ρ : Type} (pat : ρ) [PatternModel pat] [NoPrefixPatternModel pat]
|
||||
theorem isLongestMatch_iff_isMatch {ρ : Type} (pat : ρ) [ForwardPatternModel pat] [NoPrefixForwardPatternModel pat]
|
||||
{s : Slice} {pos : s.Pos} : IsLongestMatch pat pos ↔ IsMatch pat pos := by
|
||||
refine ⟨fun h => h.isMatch, fun h => ⟨h, fun pos' hpos' hm => ?_⟩⟩
|
||||
obtain ⟨t₁, t₂, ht₁, ht₂⟩ := isMatch_iff_exists_splits.1 h
|
||||
obtain ⟨t₁', t₂', ht₁', ht₂'⟩ := isMatch_iff_exists_splits.1 hm
|
||||
obtain ⟨t₅, ht₅, ht₅', ht₅''⟩ := (ht₁.lt_iff_exists_eq_append ht₁').1 hpos'
|
||||
exact ht₅ (NoPrefixPatternModel.eq_empty _ _ ht₂ (ht₅' ▸ ht₂'))
|
||||
|
||||
/--
|
||||
Predicate stating that a match for a given pattern is never a proper suffix of another match.
|
||||
|
||||
This implies that the notion of reverse match and longest reverse match coincide.
|
||||
-/
|
||||
class NoSuffixPatternModel {ρ : Type} (pat : ρ) [PatternModel pat] : Prop where
|
||||
eq_empty (s t) : PatternModel.Matches pat t → PatternModel.Matches pat (s ++ t) → s = ""
|
||||
|
||||
theorem NoSuffixPatternModel.of_length_eq {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
(h : ∀ s t, PatternModel.Matches pat s → PatternModel.Matches pat t → s.length = t.length) :
|
||||
NoSuffixPatternModel pat where
|
||||
eq_empty s t hs ht := by simpa using h t _ hs ht
|
||||
|
||||
theorem isLongestRevMatch_iff_isRevMatch {ρ : Type} (pat : ρ) [PatternModel pat] [NoSuffixPatternModel pat]
|
||||
{s : Slice} {pos : s.Pos} : IsLongestRevMatch pat pos ↔ IsRevMatch pat pos := by
|
||||
refine ⟨fun h => h.isRevMatch, fun h => ⟨h, fun pos' hpos' hm => ?_⟩⟩
|
||||
obtain ⟨t₁, t₂, ht₁, ht₂⟩ := isRevMatch_iff_exists_splits.1 h
|
||||
obtain ⟨t₁', t₂', ht₁', ht₂'⟩ := isRevMatch_iff_exists_splits.1 hm
|
||||
obtain ⟨t₅, ht₅, ht₅', ht₅''⟩ := (ht₁'.lt_iff_exists_eq_append ht₁).1 hpos'
|
||||
exact ht₅ (NoSuffixPatternModel.eq_empty _ _ ht₂ (ht₅'' ▸ ht₂'))
|
||||
exact ht₅ (NoPrefixForwardPatternModel.eq_empty _ _ ht₂ (ht₅' ▸ ht₂'))
|
||||
|
||||
/--
|
||||
Predicate stating that the slice formed by {name}`startPos` and {name}`endPos` contains is a match
|
||||
of {name}`pat` in {name}`s` and it is longest among matches starting at {name}`startPos`.
|
||||
-/
|
||||
structure IsLongestMatchAt (pat : ρ) [PatternModel pat] {s : Slice} (startPos endPos : s.Pos) : Prop where
|
||||
structure IsLongestMatchAt (pat : ρ) [ForwardPatternModel pat] {s : Slice} (startPos endPos : s.Pos) : Prop where
|
||||
le : startPos ≤ endPos
|
||||
isLongestMatch_sliceFrom : IsLongestMatch pat (Slice.Pos.sliceFrom _ _ le)
|
||||
|
||||
theorem isLongestMatchAt_iff {pat : ρ} [PatternModel pat] {s : Slice} {pos₁ pos₂ : s.Pos} :
|
||||
theorem isLongestMatchAt_iff {pat : ρ} [ForwardPatternModel pat] {s : Slice} {pos₁ pos₂ : s.Pos} :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔
|
||||
∃ (h : pos₁ ≤ pos₂), IsLongestMatch pat (Slice.Pos.sliceFrom _ _ h) :=
|
||||
⟨fun ⟨h, h'⟩ => ⟨h, h'⟩, fun ⟨h, h'⟩ => ⟨h, h'⟩⟩
|
||||
|
||||
theorem IsLongestMatchAt.lt {pat : ρ} [PatternModel pat] {s : Slice} {startPos endPos : s.Pos}
|
||||
theorem IsLongestMatchAt.lt {pat : ρ} [ForwardPatternModel pat] {s : Slice} {startPos endPos : s.Pos}
|
||||
(h : IsLongestMatchAt pat startPos endPos) : startPos < endPos := by
|
||||
have := h.isLongestMatch_sliceFrom.ne_startPos
|
||||
rw [← Pos.startPos_lt_iff, ← Slice.Pos.ofSliceFrom_lt_ofSliceFrom_iff] at this
|
||||
simpa
|
||||
|
||||
theorem IsLongestMatchAt.eq {pat : ρ} [PatternModel pat] {s : Slice} {startPos endPos endPos' : s.Pos}
|
||||
theorem IsLongestMatchAt.eq {pat : ρ} [ForwardPatternModel pat] {s : Slice} {startPos endPos endPos' : s.Pos}
|
||||
(h : IsLongestMatchAt pat startPos endPos) (h' : IsLongestMatchAt pat startPos endPos') :
|
||||
endPos = endPos' := by
|
||||
simpa using h.isLongestMatch_sliceFrom.eq h'.isLongestMatch_sliceFrom
|
||||
|
||||
private theorem isLongestMatch_of_eq {pat : ρ} [PatternModel pat] {s t : Slice}
|
||||
private theorem isLongestMatch_of_eq {pat : ρ} [ForwardPatternModel pat] {s t : Slice}
|
||||
{pos : s.Pos} {pos' : t.Pos} (h_eq : s = t) (h_pos : pos.offset = pos'.offset)
|
||||
(hm : IsLongestMatch pat pos) : IsLongestMatch pat pos' := by
|
||||
subst h_eq; exact (Slice.Pos.ext h_pos) ▸ hm
|
||||
|
||||
theorem isLongestMatchAt_iff_isLongestMatchAt_ofSliceFrom {pat : ρ} [PatternModel pat]
|
||||
theorem isLongestMatchAt_iff_isLongestMatchAt_ofSliceFrom {pat : ρ} [ForwardPatternModel pat]
|
||||
{s : Slice} {base : s.Pos} {startPos endPos : (s.sliceFrom base).Pos} :
|
||||
IsLongestMatchAt pat startPos endPos ↔ IsLongestMatchAt pat (Pos.ofSliceFrom startPos) (Pos.ofSliceFrom endPos) := by
|
||||
constructor
|
||||
@@ -269,88 +187,35 @@ theorem isLongestMatchAt_iff_isLongestMatchAt_ofSliceFrom {pat : ρ} [PatternMod
|
||||
exact isLongestMatch_of_eq Slice.sliceFrom_sliceFrom.symm
|
||||
(by simp [Pos.Raw.ext_iff]; omega) h.isLongestMatch_sliceFrom
|
||||
|
||||
theorem IsLongestMatch.isLongestMatchAt_ofSliceFrom {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem IsLongestMatch.isLongestMatchAt_ofSliceFrom {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{p₀ : s.Pos} {pos : (s.sliceFrom p₀).Pos} (h : IsLongestMatch pat pos) :
|
||||
IsLongestMatchAt pat p₀ (Slice.Pos.ofSliceFrom pos) where
|
||||
le := Slice.Pos.le_ofSliceFrom
|
||||
isLongestMatch_sliceFrom := by simpa
|
||||
|
||||
@[simp]
|
||||
theorem isLongestMatchAt_startPos_iff {pat : ρ} [PatternModel pat] {s : Slice} {endPos : s.Pos} :
|
||||
theorem isLongestMatchAt_startPos_iff {pat : ρ} [ForwardPatternModel pat] {s : Slice} {endPos : s.Pos} :
|
||||
IsLongestMatchAt pat s.startPos endPos ↔ IsLongestMatch pat endPos := by
|
||||
simpa [isLongestMatchAt_iff] using
|
||||
⟨fun h => isLongestMatch_of_eq (by simp) (by simp) h,
|
||||
fun h => isLongestMatch_of_eq (by simp) (by simp) h⟩
|
||||
|
||||
/--
|
||||
Predicate stating that the slice formed by {name}`startPos` and {name}`endPos` contains is a match
|
||||
of {name}`pat` in {name}`s` and it is longest among matches ending at {name}`endPos`.
|
||||
-/
|
||||
structure IsLongestRevMatchAt (pat : ρ) [PatternModel pat] {s : Slice} (startPos endPos : s.Pos) : Prop where
|
||||
le : startPos ≤ endPos
|
||||
isLongestRevMatch_sliceTo : IsLongestRevMatch pat (Slice.Pos.sliceTo _ _ le)
|
||||
|
||||
theorem isLongestRevMatchAt_iff {pat : ρ} [PatternModel pat] {s : Slice} {pos₁ pos₂ : s.Pos} :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔
|
||||
∃ (h : pos₁ ≤ pos₂), IsLongestRevMatch pat (Slice.Pos.sliceTo _ _ h) :=
|
||||
⟨fun ⟨h, h'⟩ => ⟨h, h'⟩, fun ⟨h, h'⟩ => ⟨h, h'⟩⟩
|
||||
|
||||
theorem IsLongestRevMatchAt.lt {pat : ρ} [PatternModel pat] {s : Slice} {startPos endPos : s.Pos}
|
||||
(h : IsLongestRevMatchAt pat startPos endPos) : startPos < endPos := by
|
||||
have := h.isLongestRevMatch_sliceTo.ne_endPos
|
||||
rw [← Pos.lt_endPos_iff, ← Slice.Pos.ofSliceTo_lt_ofSliceTo_iff] at this
|
||||
simpa
|
||||
|
||||
theorem IsLongestRevMatchAt.eq {pat : ρ} [PatternModel pat] {s : Slice} {startPos startPos' endPos : s.Pos}
|
||||
(h : IsLongestRevMatchAt pat startPos endPos) (h' : IsLongestRevMatchAt pat startPos' endPos) :
|
||||
startPos = startPos' := by
|
||||
simpa using h.isLongestRevMatch_sliceTo.eq h'.isLongestRevMatch_sliceTo
|
||||
|
||||
private theorem isLongestRevMatch_of_eq {pat : ρ} [PatternModel pat] {s t : Slice}
|
||||
{pos : s.Pos} {pos' : t.Pos} (h_eq : s = t) (h_pos : pos.offset = pos'.offset)
|
||||
(hm : IsLongestRevMatch pat pos) : IsLongestRevMatch pat pos' := by
|
||||
subst h_eq; exact (Slice.Pos.ext h_pos) ▸ hm
|
||||
|
||||
theorem isLongestRevMatchAt_iff_isLongestRevMatchAt_ofSliceTo {pat : ρ} [PatternModel pat]
|
||||
{s : Slice} {base : s.Pos} {startPos endPos : (s.sliceTo base).Pos} :
|
||||
IsLongestRevMatchAt pat startPos endPos ↔ IsLongestRevMatchAt pat (Pos.ofSliceTo startPos) (Pos.ofSliceTo endPos) := by
|
||||
constructor
|
||||
· intro h
|
||||
refine ⟨Slice.Pos.ofSliceTo_le_ofSliceTo_iff.mpr h.le, ?_⟩
|
||||
exact isLongestRevMatch_of_eq Slice.sliceTo_sliceTo (by simp) h.isLongestRevMatch_sliceTo
|
||||
· intro h
|
||||
refine ⟨Slice.Pos.ofSliceTo_le_ofSliceTo_iff.mp h.le, ?_⟩
|
||||
exact isLongestRevMatch_of_eq Slice.sliceTo_sliceTo.symm (by simp) h.isLongestRevMatch_sliceTo
|
||||
|
||||
theorem IsLongestRevMatch.isLongestRevMatchAt_ofSliceTo {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{p₀ : s.Pos} {pos : (s.sliceTo p₀).Pos} (h : IsLongestRevMatch pat pos) :
|
||||
IsLongestRevMatchAt pat (Slice.Pos.ofSliceTo pos) p₀ where
|
||||
le := Slice.Pos.ofSliceTo_le
|
||||
isLongestRevMatch_sliceTo := by simpa
|
||||
|
||||
@[simp]
|
||||
theorem isLongestRevMatchAt_endPos_iff {pat : ρ} [PatternModel pat] {s : Slice} {startPos : s.Pos} :
|
||||
IsLongestRevMatchAt pat startPos s.endPos ↔ IsLongestRevMatch pat startPos := by
|
||||
simpa [isLongestRevMatchAt_iff] using
|
||||
⟨fun h => isLongestRevMatch_of_eq (by simp) (by simp) h,
|
||||
fun h => isLongestRevMatch_of_eq (by simp) (by simp) h⟩
|
||||
|
||||
/--
|
||||
Predicate stating that there is a (longest) match starting at the given position.
|
||||
-/
|
||||
structure MatchesAt (pat : ρ) [PatternModel pat] {s : Slice} (pos : s.Pos) : Prop where
|
||||
structure MatchesAt (pat : ρ) [ForwardPatternModel pat] {s : Slice} (pos : s.Pos) : Prop where
|
||||
exists_isLongestMatchAt : ∃ endPos, IsLongestMatchAt pat pos endPos
|
||||
|
||||
theorem matchesAt_iff_exists_isLongestMatchAt {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem matchesAt_iff_exists_isLongestMatchAt {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{pos : s.Pos} : MatchesAt pat pos ↔ ∃ endPos, IsLongestMatchAt pat pos endPos :=
|
||||
⟨fun ⟨h⟩ => h, fun h => ⟨h⟩⟩
|
||||
|
||||
theorem matchesAt_iff_exists_isLongestMatch {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem matchesAt_iff_exists_isLongestMatch {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{pos : s.Pos} :
|
||||
MatchesAt pat pos ↔ ∃ (endPos : s.Pos), ∃ h, IsLongestMatch pat (pos.sliceFrom endPos h) :=
|
||||
⟨fun ⟨p, h⟩ => ⟨p, h.le, h.isLongestMatch_sliceFrom⟩, fun ⟨p, h₁, h₂⟩ => ⟨p, ⟨h₁, h₂⟩⟩⟩
|
||||
|
||||
theorem matchesAt_iff_exists_isMatch {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem matchesAt_iff_exists_isMatch {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{pos : s.Pos} :
|
||||
MatchesAt pat pos ↔ ∃ (endPos : s.Pos), ∃ h, IsMatch pat (pos.sliceFrom endPos h) := by
|
||||
refine ⟨fun ⟨p, h⟩ => ⟨p, h.le, h.isLongestMatch_sliceFrom.isMatch⟩, fun ⟨p, h₁, h₂⟩ => ?_⟩
|
||||
@@ -360,13 +225,13 @@ theorem matchesAt_iff_exists_isMatch {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
by simpa using hq⟩⟩
|
||||
|
||||
@[simp]
|
||||
theorem not_matchesAt_endPos {pat : ρ} [PatternModel pat] {s : Slice} :
|
||||
theorem not_matchesAt_endPos {pat : ρ} [ForwardPatternModel pat] {s : Slice} :
|
||||
¬ MatchesAt pat s.endPos := by
|
||||
simp only [matchesAt_iff_exists_isMatch, Pos.endPos_le, exists_prop_eq]
|
||||
intro h
|
||||
simpa [← Pos.ofSliceFrom_inj] using h.ne_startPos
|
||||
|
||||
theorem matchesAt_iff_matchesAt_ofSliceFrom {pat : ρ} [PatternModel pat] {s : Slice} {base : s.Pos}
|
||||
theorem matchesAt_iff_matchesAt_ofSliceFrom {pat : ρ} [ForwardPatternModel pat] {s : Slice} {base : s.Pos}
|
||||
{pos : (s.sliceFrom base).Pos} : MatchesAt pat pos ↔ MatchesAt pat (Pos.ofSliceFrom pos) := by
|
||||
simp only [matchesAt_iff_exists_isLongestMatchAt]
|
||||
constructor
|
||||
@@ -376,66 +241,21 @@ theorem matchesAt_iff_matchesAt_ofSliceFrom {pat : ρ} [PatternModel pat] {s : S
|
||||
exact ⟨base.sliceFrom endPos (Std.le_trans Slice.Pos.le_ofSliceFrom h.le),
|
||||
isLongestMatchAt_iff_isLongestMatchAt_ofSliceFrom.mpr (by simpa using h)⟩
|
||||
|
||||
theorem IsLongestMatchAt.matchesAt {pat : ρ} [PatternModel pat] {s : Slice} {startPos endPos : s.Pos}
|
||||
theorem IsLongestMatchAt.matchesAt {pat : ρ} [ForwardPatternModel pat] {s : Slice} {startPos endPos : s.Pos}
|
||||
(h : IsLongestMatchAt pat startPos endPos) : MatchesAt pat startPos where
|
||||
exists_isLongestMatchAt := ⟨_, h⟩
|
||||
|
||||
/--
|
||||
Predicate stating that there is a (longest) match ending at the given position.
|
||||
-/
|
||||
structure RevMatchesAt (pat : ρ) [PatternModel pat] {s : Slice} (pos : s.Pos) : Prop where
|
||||
exists_isLongestRevMatchAt : ∃ startPos, IsLongestRevMatchAt pat startPos pos
|
||||
|
||||
theorem revMatchesAt_iff_exists_isLongestRevMatchAt {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{pos : s.Pos} : RevMatchesAt pat pos ↔ ∃ startPos, IsLongestRevMatchAt pat startPos pos :=
|
||||
⟨fun ⟨h⟩ => h, fun h => ⟨h⟩⟩
|
||||
|
||||
theorem revMatchesAt_iff_exists_isLongestRevMatch {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{pos : s.Pos} :
|
||||
RevMatchesAt pat pos ↔ ∃ (startPos : s.Pos), ∃ h, IsLongestRevMatch pat (pos.sliceTo startPos h) :=
|
||||
⟨fun ⟨p, h⟩ => ⟨p, h.le, h.isLongestRevMatch_sliceTo⟩, fun ⟨p, h₁, h₂⟩ => ⟨p, ⟨h₁, h₂⟩⟩⟩
|
||||
|
||||
theorem revMatchesAt_iff_exists_isRevMatch {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{pos : s.Pos} :
|
||||
RevMatchesAt pat pos ↔ ∃ (startPos : s.Pos), ∃ h, IsRevMatch pat (pos.sliceTo startPos h) := by
|
||||
refine ⟨fun ⟨p, h⟩ => ⟨p, h.le, h.isLongestRevMatch_sliceTo.isRevMatch⟩, fun ⟨p, h₁, h₂⟩ => ?_⟩
|
||||
obtain ⟨q, hq⟩ := h₂.exists_isLongestRevMatch
|
||||
exact ⟨Pos.ofSliceTo q,
|
||||
⟨Std.le_trans (by simpa [← Pos.ofSliceTo_le_ofSliceTo_iff] using hq.le_of_isRevMatch h₂) h₁,
|
||||
by simpa using hq⟩⟩
|
||||
|
||||
@[simp]
|
||||
theorem not_revMatchesAt_startPos {pat : ρ} [PatternModel pat] {s : Slice} :
|
||||
¬ RevMatchesAt pat s.startPos := by
|
||||
simp only [revMatchesAt_iff_exists_isRevMatch, Pos.le_startPos, exists_prop_eq]
|
||||
intro h
|
||||
simpa [← Pos.ofSliceTo_inj] using h.ne_endPos
|
||||
|
||||
theorem revMatchesAt_iff_revMatchesAt_ofSliceto {pat : ρ} [PatternModel pat] {s : Slice} {base : s.Pos}
|
||||
{pos : (s.sliceTo base).Pos} : RevMatchesAt pat pos ↔ RevMatchesAt pat (Pos.ofSliceTo pos) := by
|
||||
simp only [revMatchesAt_iff_exists_isLongestRevMatchAt]
|
||||
constructor
|
||||
· rintro ⟨startPos, h⟩
|
||||
exact ⟨Pos.ofSliceTo startPos, isLongestRevMatchAt_iff_isLongestRevMatchAt_ofSliceTo.mp h⟩
|
||||
· rintro ⟨startPos, h⟩
|
||||
exact ⟨base.sliceTo startPos (Std.le_trans h.le Slice.Pos.ofSliceTo_le),
|
||||
isLongestRevMatchAt_iff_isLongestRevMatchAt_ofSliceTo.mpr (by simpa using h)⟩
|
||||
|
||||
theorem IsLongestRevMatchAt.revMatchesAt {pat : ρ} [PatternModel pat] {s : Slice} {startPos endPos : s.Pos}
|
||||
(h : IsLongestRevMatchAt pat startPos endPos) : RevMatchesAt pat endPos where
|
||||
exists_isLongestRevMatchAt := ⟨_, h⟩
|
||||
|
||||
open Classical in
|
||||
/--
|
||||
Noncomputable model function returning the end point of the longest match starting at the given
|
||||
position, or {lean}`none` if there is no match.
|
||||
-/
|
||||
noncomputable def matchAt? {ρ : Type} (pat : ρ) [PatternModel pat]
|
||||
noncomputable def matchAt? {ρ : Type} (pat : ρ) [ForwardPatternModel pat]
|
||||
{s : Slice} (startPos : s.Pos) : Option s.Pos :=
|
||||
if h : ∃ endPos, IsLongestMatchAt pat startPos endPos then some h.choose else none
|
||||
|
||||
@[simp]
|
||||
theorem matchAt?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
theorem matchAt?_eq_some_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat]
|
||||
{s : Slice} {startPos endPos : s.Pos} :
|
||||
matchAt? pat startPos = some endPos ↔ IsLongestMatchAt pat startPos endPos := by
|
||||
fun_cases matchAt? with
|
||||
@@ -443,92 +263,40 @@ theorem matchAt?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
| case2 => simp_all
|
||||
|
||||
@[simp]
|
||||
theorem matchAt?_eq_none_iff {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
theorem matchAt?_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat]
|
||||
{s : Slice} {startPos : s.Pos} :
|
||||
matchAt? pat startPos = none ↔ ¬ MatchesAt pat startPos := by
|
||||
fun_cases matchAt? with
|
||||
| case1 h => simpa using ⟨h⟩
|
||||
| case2 h => simpa using fun ⟨h'⟩ => h h'
|
||||
|
||||
open Classical in
|
||||
/--
|
||||
Noncomputable model function returning the start point of the longest match ending at the given
|
||||
position, or {lean}`none` if there is no match.
|
||||
-/
|
||||
noncomputable def revMatchAt? {ρ : Type} (pat : ρ) [PatternModel pat]
|
||||
{s : Slice} (endPos : s.Pos) : Option s.Pos :=
|
||||
if h : ∃ startPos, IsLongestRevMatchAt pat startPos endPos then some h.choose else none
|
||||
|
||||
@[simp]
|
||||
theorem revMatchAt?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
{s : Slice} {startPos endPos : s.Pos} :
|
||||
revMatchAt? pat endPos = some startPos ↔ IsLongestRevMatchAt pat startPos endPos := by
|
||||
fun_cases revMatchAt? with
|
||||
| case1 h => simpa using ⟨by rintro rfl; exact h.choose_spec, fun h' => h.choose_spec.eq h'⟩
|
||||
| case2 => simp_all
|
||||
|
||||
@[simp]
|
||||
theorem revMatchAt?_eq_none_iff {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
{s : Slice} {endPos : s.Pos} :
|
||||
revMatchAt? pat endPos = none ↔ ¬ RevMatchesAt pat endPos := by
|
||||
fun_cases revMatchAt? with
|
||||
| case1 h => simpa using ⟨h⟩
|
||||
| case2 h => simpa using fun ⟨h'⟩ => h h'
|
||||
|
||||
/--
|
||||
Predicate stating compatibility between {name}`PatternModel` and {name}`ForwardPattern`.
|
||||
Predicate stating compatibility between {name}`ForwardPatternModel` and {name}`ForwardPattern`.
|
||||
|
||||
This extends {name}`LawfulForwardPattern`, but it is much stronger because it forces the
|
||||
{name}`ForwardPattern` to match the longest prefix of the given slice that matches the property
|
||||
supplied by the {name}`PatternModel` instance.
|
||||
supplied by the {name}`ForwardPatternModel` instance.
|
||||
-/
|
||||
class LawfulForwardPatternModel {ρ : Type} (pat : ρ) [ForwardPattern pat]
|
||||
[PatternModel pat] : Prop extends LawfulForwardPattern pat where
|
||||
[ForwardPatternModel pat] : Prop extends LawfulForwardPattern pat where
|
||||
skipPrefix?_eq_some_iff (pos) : ForwardPattern.skipPrefix? pat s = some pos ↔ IsLongestMatch pat pos
|
||||
|
||||
theorem LawfulForwardPatternModel.skipPrefix?_sliceFrom_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPattern pat] [PatternModel pat]
|
||||
open Classical in
|
||||
theorem LawfulForwardPatternModel.skipPrefix?_sliceFrom_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPattern pat] [ForwardPatternModel pat]
|
||||
[LawfulForwardPatternModel pat] {s : Slice} {p₀ : s.Pos} :
|
||||
ForwardPattern.skipPrefix? pat (s.sliceFrom p₀) = none ↔ ¬ MatchesAt pat p₀ := by
|
||||
classical
|
||||
rw [← Decidable.not_iff_not]
|
||||
simp [Option.ne_none_iff_exists', LawfulForwardPatternModel.skipPrefix?_eq_some_iff]
|
||||
refine ⟨fun ⟨p, hp⟩ => ?_, fun ⟨p, hp⟩ => ?_⟩
|
||||
· exact ⟨Slice.Pos.ofSliceFrom p, hp.isLongestMatchAt_ofSliceFrom⟩
|
||||
· exact ⟨p₀.sliceFrom p hp.le, hp.isLongestMatch_sliceFrom⟩
|
||||
|
||||
theorem LawfulForwardPatternModel.skipPrefix?_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPattern pat] [PatternModel pat]
|
||||
theorem LawfulForwardPatternModel.skipPrefix?_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPattern pat] [ForwardPatternModel pat]
|
||||
[LawfulForwardPatternModel pat] {s : Slice} :
|
||||
ForwardPattern.skipPrefix? pat s = none ↔ ¬ MatchesAt pat s.startPos := by
|
||||
conv => lhs; rw [← sliceFrom_startPos (s := s)]
|
||||
simp [skipPrefix?_sliceFrom_eq_none_iff]
|
||||
|
||||
/--
|
||||
Predicate stating compatibility between {name}`PatternModel` and {name}`BackwardPattern`.
|
||||
|
||||
This extends {name}`LawfulForwardPattern`, but it is much stronger because it forces the
|
||||
{name}`ForwardPattern` to match the longest prefix of the given slice that matches the property
|
||||
supplied by the {name}`PatternModel` instance.
|
||||
-/
|
||||
class LawfulBackwardPatternModel {ρ : Type} (pat : ρ) [BackwardPattern pat]
|
||||
[PatternModel pat] : Prop extends LawfulBackwardPattern pat where
|
||||
skipSuffix?_eq_some_iff (pos) : BackwardPattern.skipSuffix? pat s = some pos ↔ IsLongestRevMatch pat pos
|
||||
|
||||
theorem LawfulBackwardPatternModel.skipSuffix?_sliceTo_eq_none_iff {ρ : Type} {pat : ρ} [BackwardPattern pat] [PatternModel pat]
|
||||
[LawfulBackwardPatternModel pat] {s : Slice} {p₀ : s.Pos} :
|
||||
BackwardPattern.skipSuffix? pat (s.sliceTo p₀) = none ↔ ¬ RevMatchesAt pat p₀ := by
|
||||
classical
|
||||
rw [← Decidable.not_iff_not]
|
||||
simp [Option.ne_none_iff_exists', LawfulBackwardPatternModel.skipSuffix?_eq_some_iff]
|
||||
refine ⟨fun ⟨p, hp⟩ => ?_, fun ⟨p, hp⟩ => ?_⟩
|
||||
· exact ⟨Slice.Pos.ofSliceTo p, hp.isLongestRevMatchAt_ofSliceTo⟩
|
||||
· exact ⟨p₀.sliceTo p hp.le, hp.isLongestRevMatch_sliceTo⟩
|
||||
|
||||
theorem LawfulBackwardPatternModel.skipSuffix?_eq_none_iff {ρ : Type} {pat : ρ} [BackwardPattern pat] [PatternModel pat]
|
||||
[LawfulBackwardPatternModel pat] {s : Slice} :
|
||||
BackwardPattern.skipSuffix? pat s = none ↔ ¬ RevMatchesAt pat s.endPos := by
|
||||
conv => lhs; rw [← sliceTo_endPos (s := s)]
|
||||
simp [skipSuffix?_sliceTo_eq_none_iff]
|
||||
|
||||
/--
|
||||
Inductive predicate stating that a list of search steps represents a valid search from a given
|
||||
position in a slice.
|
||||
@@ -538,7 +306,7 @@ matches.
|
||||
|
||||
Hence, this predicate determines the list of search steps up to grouping of rejections.
|
||||
-/
|
||||
inductive IsValidSearchFrom (pat : ρ) [PatternModel pat] {s : Slice} :
|
||||
inductive IsValidSearchFrom (pat : ρ) [ForwardPatternModel pat] {s : Slice} :
|
||||
s.Pos → List (SearchStep s) → Prop where
|
||||
| endPos : IsValidSearchFrom pat s.endPos []
|
||||
| matched {startPos endPos : s.Pos} :
|
||||
@@ -548,14 +316,14 @@ inductive IsValidSearchFrom (pat : ρ) [PatternModel pat] {s : Slice} :
|
||||
(∀ pos, startPos ≤ pos → pos < endPos → ¬ MatchesAt pat pos) →
|
||||
IsValidSearchFrom pat endPos l → IsValidSearchFrom pat startPos (.rejected startPos endPos :: l)
|
||||
|
||||
theorem IsValidSearchFrom.matched_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem IsValidSearchFrom.matched_of_eq {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{startPos startPos' endPos : s.Pos} {l : List (SearchStep s)} (h₁ : IsValidSearchFrom pat endPos l)
|
||||
(h₂ : IsLongestMatchAt pat startPos' endPos)
|
||||
(h₃ : startPos = startPos') : IsValidSearchFrom pat startPos' (.matched startPos endPos :: l) := by
|
||||
cases h₃
|
||||
exact IsValidSearchFrom.matched h₂ h₁
|
||||
|
||||
theorem IsValidSearchFrom.mismatched_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem IsValidSearchFrom.mismatched_of_eq {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{startPos startPos' endPos : s.Pos} {l : List (SearchStep s)} (h₁ : IsValidSearchFrom pat endPos l)
|
||||
(h₀ : startPos' < endPos)
|
||||
(h₂ : ∀ pos, startPos' ≤ pos → pos < endPos → ¬ MatchesAt pat pos) (h₃ : startPos = startPos') :
|
||||
@@ -563,7 +331,7 @@ theorem IsValidSearchFrom.mismatched_of_eq {pat : ρ} [PatternModel pat] {s : Sl
|
||||
cases h₃
|
||||
exact IsValidSearchFrom.mismatched h₀ h₂ h₁
|
||||
|
||||
theorem IsValidSearchFrom.endPos_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
theorem IsValidSearchFrom.endPos_of_eq {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{p : s.Pos} {l : List (SearchStep s)} (hp : p = s.endPos) (hl : l = []) :
|
||||
IsValidSearchFrom pat p l := by
|
||||
cases hp
|
||||
@@ -571,18 +339,18 @@ theorem IsValidSearchFrom.endPos_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
exact IsValidSearchFrom.endPos
|
||||
|
||||
/--
|
||||
Predicate stating compatibility between {name}`PatternModel` and {name}`ToForwardSearcher`.
|
||||
Predicate stating compatibility between {name}`ForwardPatternModel` and {name}`ToForwardSearcher`.
|
||||
|
||||
We require the searcher to always match the longest match at the first position where the pattern
|
||||
matches; see {name}`IsValidSearchFrom`.
|
||||
-/
|
||||
class LawfulToForwardSearcherModel {ρ : Type} (pat : ρ) [PatternModel pat] {σ : Slice → Type}
|
||||
class LawfulToForwardSearcherModel {ρ : Type} (pat : ρ) [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[ToForwardSearcher pat σ] [∀ s, Std.Iterator (σ s) Id (SearchStep s)]
|
||||
[∀ s, Std.Iterators.Finite (σ s) Id] : Prop where
|
||||
isValidSearchFrom_toList (s) : IsValidSearchFrom pat s.startPos (ToForwardSearcher.toSearcher pat s).toList
|
||||
|
||||
theorem LawfulToForwardSearcherModel.defaultImplementation {pat : ρ} [ForwardPattern pat] [StrictForwardPattern pat]
|
||||
[PatternModel pat] [LawfulForwardPatternModel pat] :
|
||||
[ForwardPatternModel pat] [LawfulForwardPatternModel pat] :
|
||||
letI : ToForwardSearcher pat (ToForwardSearcher.DefaultForwardSearcher pat) := .defaultImplementation
|
||||
LawfulToForwardSearcherModel pat := by
|
||||
let inst : ToForwardSearcher pat (ToForwardSearcher.DefaultForwardSearcher pat) := .defaultImplementation
|
||||
@@ -622,97 +390,4 @@ theorem LawfulToForwardSearcherModel.defaultImplementation {pat : ρ} [ForwardPa
|
||||
· split at heq <;> simp at heq
|
||||
· split at heq <;> simp at heq
|
||||
|
||||
/--
|
||||
Inductive predicate stating that a list of search steps represents a valid backwards search from a
|
||||
given position in a slice.
|
||||
|
||||
"Searching" here means always taking the longest match at the first position where the pattern
|
||||
matches.
|
||||
|
||||
Hence, this predicate determines the list of search steps up to grouping of rejections.
|
||||
-/
|
||||
inductive IsValidRevSearchFrom (pat : ρ) [PatternModel pat] {s : Slice} :
|
||||
s.Pos → List (SearchStep s) → Prop where
|
||||
| startPos : IsValidRevSearchFrom pat s.startPos []
|
||||
| matched {startPos endPos : s.Pos} :
|
||||
IsLongestRevMatchAt pat startPos endPos → IsValidRevSearchFrom pat startPos l →
|
||||
IsValidRevSearchFrom pat endPos (.matched startPos endPos :: l)
|
||||
| mismatched {startPos endPos : s.Pos} : startPos < endPos →
|
||||
(∀ pos, startPos < pos → pos ≤ endPos → ¬ RevMatchesAt pat pos) →
|
||||
IsValidRevSearchFrom pat startPos l → IsValidRevSearchFrom pat endPos (.rejected startPos endPos :: l)
|
||||
|
||||
theorem IsValidRevSearchFrom.matched_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{startPos endPos endPos' : s.Pos} {l : List (SearchStep s)} (h₁ : IsValidRevSearchFrom pat startPos l)
|
||||
(h₂ : IsLongestRevMatchAt pat startPos endPos')
|
||||
(h₃ : endPos = endPos') : IsValidRevSearchFrom pat endPos' (.matched startPos endPos :: l) := by
|
||||
cases h₃
|
||||
exact IsValidRevSearchFrom.matched h₂ h₁
|
||||
|
||||
theorem IsValidRevSearchFrom.mismatched_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{startPos endPos endPos' : s.Pos} {l : List (SearchStep s)} (h₁ : IsValidRevSearchFrom pat startPos l)
|
||||
(h₀ : startPos < endPos')
|
||||
(h₂ : ∀ pos, startPos < pos → pos ≤ endPos' → ¬ RevMatchesAt pat pos) (h₃ : endPos = endPos') :
|
||||
IsValidRevSearchFrom pat endPos' (.rejected startPos endPos :: l) := by
|
||||
cases h₃
|
||||
exact IsValidRevSearchFrom.mismatched h₀ h₂ h₁
|
||||
|
||||
theorem IsValidRevSearchFrom.startPos_of_eq {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
{p : s.Pos} {l : List (SearchStep s)} (hp : p = s.startPos) (hl : l = []) :
|
||||
IsValidRevSearchFrom pat p l := by
|
||||
cases hp
|
||||
cases hl
|
||||
exact IsValidRevSearchFrom.startPos
|
||||
|
||||
/--
|
||||
Predicate stating compatibility between {name}`PatternModel` and {name}`ToBackwardSearcher`.
|
||||
|
||||
We require the searcher to always match the longest match at the first position where the pattern
|
||||
matches; see {name}`IsValidRevSearchFrom`.
|
||||
-/
|
||||
class LawfulToBackwardSearcherModel {ρ : Type} (pat : ρ) [PatternModel pat] {σ : Slice → Type}
|
||||
[ToBackwardSearcher pat σ] [∀ s, Std.Iterator (σ s) Id (SearchStep s)]
|
||||
[∀ s, Std.Iterators.Finite (σ s) Id] : Prop where
|
||||
isValidRevSearchFrom_toList (s) : IsValidRevSearchFrom pat s.endPos (ToBackwardSearcher.toSearcher pat s).toList
|
||||
|
||||
theorem LawfulToBackwardSearcherModel.defaultImplementation {pat : ρ} [BackwardPattern pat] [StrictBackwardPattern pat]
|
||||
[PatternModel pat] [LawfulBackwardPatternModel pat] :
|
||||
letI : ToBackwardSearcher pat (ToBackwardSearcher.DefaultBackwardSearcher pat) := .defaultImplementation
|
||||
LawfulToBackwardSearcherModel pat := by
|
||||
let inst : ToBackwardSearcher pat (ToBackwardSearcher.DefaultBackwardSearcher pat) := .defaultImplementation
|
||||
refine ⟨fun s => ?_⟩
|
||||
suffices ∀ (pos : s.Pos),
|
||||
IsValidRevSearchFrom pat pos (Std.Iter.mk (α := ToBackwardSearcher.DefaultBackwardSearcher pat s) ⟨pos⟩).toList from
|
||||
this s.endPos
|
||||
intro pos
|
||||
induction pos using WellFounded.induction Slice.Pos.wellFounded_lt with | h pos ih
|
||||
rw [Std.Iter.toList_eq_match_step, Std.Iter.step_eq]
|
||||
simp only [Std.Iter.toIterM, ne_eq]
|
||||
by_cases h : pos = s.startPos
|
||||
· simpa [h] using IsValidRevSearchFrom.startPos
|
||||
· simp only [h, ↓reduceDIte]
|
||||
split <;> rename_i heq
|
||||
· split at heq <;> rename_i pos' heq'
|
||||
· simp only [Id.run_pure, Std.Shrink.inflate_deflate, Std.IterM.Step.toPure_yield,
|
||||
Std.PlausibleIterStep.yield, Std.IterStep.yield.injEq] at heq
|
||||
rw [← heq.1, ← heq.2]
|
||||
apply IsValidRevSearchFrom.matched
|
||||
· rw [LawfulBackwardPattern.skipSuffixOfNonempty?_eq,
|
||||
LawfulBackwardPatternModel.skipSuffix?_eq_some_iff] at heq'
|
||||
exact heq'.isLongestRevMatchAt_ofSliceTo
|
||||
· simp only [Std.IterM.toIter]
|
||||
apply ih
|
||||
refine Std.lt_of_lt_of_le (Slice.Pos.ofSliceTo_lt_ofSliceTo_iff.2 ?_)
|
||||
(Slice.Pos.ofSliceTo_le (pos := Slice.endPos _))
|
||||
simpa using StrictBackwardPattern.ne_endPos _ _ heq'
|
||||
· simp only [Id.run_pure, Std.Shrink.inflate_deflate, Std.IterM.Step.toPure_yield,
|
||||
Std.PlausibleIterStep.yield, Std.IterStep.yield.injEq] at heq
|
||||
rw [← heq.1, ← heq.2]
|
||||
apply IsValidRevSearchFrom.mismatched (by simp) _ (ih _ (by simp))
|
||||
intro p' hp' hp''
|
||||
obtain rfl : pos = p' := Std.le_antisymm (by simpa using hp') hp''
|
||||
rwa [LawfulBackwardPattern.skipSuffixOfNonempty?_eq,
|
||||
LawfulBackwardPatternModel.skipSuffix?_sliceTo_eq_none_iff] at heq'
|
||||
· split at heq <;> simp at heq
|
||||
· split at heq <;> simp at heq
|
||||
|
||||
end String.Slice.Pattern.Model
|
||||
|
||||
@@ -20,42 +20,28 @@ import Init.Data.String.Lemmas.Order
|
||||
import Init.Data.Order.Lemmas
|
||||
import Init.Data.String.OrderInstances
|
||||
import Init.Omega
|
||||
import Init.Data.String.Lemmas.FindPos
|
||||
|
||||
public section
|
||||
|
||||
namespace String.Slice.Pattern.Model.Char
|
||||
|
||||
instance {c : Char} : PatternModel c where
|
||||
instance {c : Char} : ForwardPatternModel c where
|
||||
Matches s := s = String.singleton c
|
||||
not_matches_empty := by simp
|
||||
|
||||
instance {c : Char} : NoPrefixPatternModel c :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
|
||||
instance {c : Char} : NoSuffixPatternModel c :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
instance {c : Char} : NoPrefixForwardPatternModel c :=
|
||||
.of_length_eq (by simp +contextual [ForwardPatternModel.Matches])
|
||||
|
||||
theorem isMatch_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsMatch c pos ↔
|
||||
∃ (h : s.startPos ≠ s.endPos), pos = s.startPos.next h ∧ s.startPos.get h = c := by
|
||||
simp only [Model.isMatch_iff, PatternModel.Matches, copy_sliceTo_eq_iff_exists_splits]
|
||||
simp only [Model.isMatch_iff, ForwardPatternModel.Matches, sliceTo_copy_eq_iff_exists_splits]
|
||||
refine ⟨?_, ?_⟩
|
||||
· simp only [splits_singleton_iff]
|
||||
exact fun ⟨t₂, h, h₁, h₂, h₃⟩ => ⟨h, h₁, h₂⟩
|
||||
· rintro ⟨h, rfl, rfl⟩
|
||||
exact ⟨_, Slice.splits_next_startPos⟩
|
||||
|
||||
theorem isRevMatch_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch c pos ↔
|
||||
∃ (h : s.endPos ≠ s.startPos), pos = s.endPos.prev h ∧ (s.endPos.prev h).get (by simp) = c := by
|
||||
simp only [Model.isRevMatch_iff, PatternModel.Matches, copy_sliceFrom_eq_iff_exists_splits]
|
||||
refine ⟨?_, ?_⟩
|
||||
· simp only [splits_singleton_right_iff]
|
||||
exact fun ⟨t₂, h, h₁, h₂, h₃⟩ => ⟨h, h₁, h₂⟩
|
||||
· rintro ⟨h, rfl, rfl⟩
|
||||
exact ⟨_, Slice.splits_prev_endPos⟩
|
||||
|
||||
theorem isLongestMatch_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestMatch c pos ↔
|
||||
∃ (h : s.startPos ≠ s.endPos), pos = s.startPos.next h ∧ s.startPos.get h = c := by
|
||||
@@ -66,46 +52,21 @@ theorem isLongestMatchAt_iff {c : Char} {s : Slice} {pos pos' : s.Pos} :
|
||||
simp +contextual [Model.isLongestMatchAt_iff, isLongestMatch_iff, ← Pos.ofSliceFrom_inj,
|
||||
Pos.get_eq_get_ofSliceFrom, Pos.ofSliceFrom_next]
|
||||
|
||||
theorem isLongestRevMatch_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestRevMatch c pos ↔
|
||||
∃ (h : s.endPos ≠ s.startPos), pos = s.endPos.prev h ∧ (s.endPos.prev h).get (by simp) = c := by
|
||||
rw [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff]
|
||||
|
||||
theorem isLongestRevMatchAt_iff {c : Char} {s : Slice} {pos pos' : s.Pos} :
|
||||
IsLongestRevMatchAt c pos pos' ↔ ∃ h, pos = pos'.prev h ∧ (pos'.prev h).get (by simp) = c := by
|
||||
simp +contextual [Model.isLongestRevMatchAt_iff, isLongestRevMatch_iff, ← Pos.ofSliceTo_inj,
|
||||
Pos.get_eq_get_ofSliceTo, Pos.ofSliceTo_prev]
|
||||
|
||||
theorem isLongestMatchAt_of_get_eq {c : Char} {s : Slice} {pos : s.Pos} {h : pos ≠ s.endPos}
|
||||
(hc : pos.get h = c) : IsLongestMatchAt c pos (pos.next h) :=
|
||||
isLongestMatchAt_iff.2 ⟨h, by simp [hc]⟩
|
||||
|
||||
theorem isLongestRevMatchAt_of_get_eq {c : Char} {s : Slice} {pos : s.Pos} {h : pos ≠ s.startPos}
|
||||
(hc : (pos.prev h).get (by simp) = c) : IsLongestRevMatchAt c (pos.prev h) pos :=
|
||||
isLongestRevMatchAt_iff.2 ⟨h, by simp [hc]⟩
|
||||
|
||||
instance {c : Char} : LawfulForwardPatternModel c where
|
||||
skipPrefix?_eq_some_iff {s} pos := by
|
||||
simp [isLongestMatch_iff, ForwardPattern.skipPrefix?, and_comm, eq_comm (b := pos)]
|
||||
|
||||
instance {c : Char} : LawfulBackwardPatternModel c where
|
||||
skipSuffix?_eq_some_iff {s} pos := by
|
||||
simp [isLongestRevMatch_iff, BackwardPattern.skipSuffix?, and_comm, eq_comm (b := pos)]
|
||||
|
||||
theorem toSearcher_eq {c : Char} {s : Slice} :
|
||||
ToForwardSearcher.toSearcher c s = ToForwardSearcher.toSearcher (· == c) s := (rfl)
|
||||
|
||||
theorem toBackwardSearcher_eq {c : Char} {s : Slice} :
|
||||
ToBackwardSearcher.toSearcher c s = ToBackwardSearcher.toSearcher (· == c) s := (rfl)
|
||||
|
||||
theorem matchesAt_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
MatchesAt c pos ↔ ∃ (h : pos ≠ s.endPos), pos.get h = c := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff, exists_comm]
|
||||
|
||||
theorem revMatchesAt_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
RevMatchesAt c pos ↔ ∃ (h : pos ≠ s.startPos), (pos.prev h).get (by simp) = c := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt, isLongestRevMatchAt_iff, exists_comm]
|
||||
|
||||
theorem matchesAt_iff_splits {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
MatchesAt c pos ↔ ∃ t₁ t₂, pos.Splits t₁ (singleton c ++ t₂) := by
|
||||
rw [matchesAt_iff]
|
||||
@@ -116,81 +77,37 @@ theorem matchesAt_iff_splits {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
have hne := hs.ne_endPos_of_singleton
|
||||
exact ⟨hne, (singleton_append_inj.mp (hs.eq_right (pos.splits_next_right hne))).1.symm⟩
|
||||
|
||||
theorem revMatchesAt_iff_splits {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
RevMatchesAt c pos ↔ ∃ t₁ t₂, pos.Splits (t₁ ++ singleton c) t₂ := by
|
||||
rw [revMatchesAt_iff]
|
||||
refine ⟨?_, ?_⟩
|
||||
· rintro ⟨h, rfl⟩
|
||||
exact ⟨_, _, pos.splits_prev_right h⟩
|
||||
· rintro ⟨t₁, t₂, hs⟩
|
||||
have hne := hs.ne_startPos_of_singleton
|
||||
refine ⟨hne, ?_⟩
|
||||
have := hs.eq_left (pos.splits_prev_right hne)
|
||||
simp only [append_singleton, push_inj] at this
|
||||
exact this.2.symm
|
||||
|
||||
theorem not_matchesAt_of_get_ne {c : Char} {s : Slice} {pos : s.Pos} {h : pos ≠ s.endPos}
|
||||
(hc : pos.get h ≠ c) : ¬ MatchesAt c pos := by
|
||||
simp [matchesAt_iff, hc]
|
||||
|
||||
theorem not_revMatchesAt_of_get_ne {c : Char} {s : Slice} {pos : s.Pos} {h : pos ≠ s.startPos}
|
||||
(hc : (pos.prev h).get (by simp) ≠ c) : ¬ RevMatchesAt c pos := by
|
||||
simp [revMatchesAt_iff, hc]
|
||||
|
||||
theorem matchAt?_eq {s : Slice} {pos : s.Pos} {c : Char} :
|
||||
matchAt? c pos =
|
||||
if h₀ : ∃ (h : pos ≠ s.endPos), pos.get h = c then some (pos.next h₀.1) else none := by
|
||||
split <;> simp_all [isLongestMatchAt_iff, matchesAt_iff]
|
||||
|
||||
theorem revMatchAt?_eq {s : Slice} {pos : s.Pos} {c : Char} :
|
||||
revMatchAt? c pos =
|
||||
if h₀ : ∃ (h : pos ≠ s.startPos), (pos.prev h).get (by simp) = c then some (pos.prev h₀.1) else none := by
|
||||
split <;> simp_all [isLongestRevMatchAt_iff, revMatchesAt_iff]
|
||||
|
||||
theorem isMatch_iff_isMatch_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsMatch c pos ↔ IsMatch (· == c) pos := by
|
||||
simp [isMatch_iff, CharPred.isMatch_iff, beq_iff_eq]
|
||||
|
||||
theorem isRevMatch_iff_isRevMatch_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch c pos ↔ IsRevMatch (· == c) pos := by
|
||||
simp [isRevMatch_iff, CharPred.isRevMatch_iff, beq_iff_eq]
|
||||
|
||||
theorem isLongestMatch_iff_isLongestMatch_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestMatch c pos ↔ IsLongestMatch (· == c) pos := by
|
||||
simp [isLongestMatch_iff_isMatch, isMatch_iff_isMatch_beq]
|
||||
|
||||
theorem isLongestRevMatch_iff_isLongestRevMatch_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestRevMatch c pos ↔ IsLongestRevMatch (· == c) pos := by
|
||||
simp [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff_isRevMatch_beq]
|
||||
|
||||
theorem isLongestMatchAt_iff_isLongestMatchAt_beq {c : Char} {s : Slice}
|
||||
{pos pos' : s.Pos} :
|
||||
IsLongestMatchAt c pos pos' ↔ IsLongestMatchAt (· == c) pos pos' := by
|
||||
simp [Model.isLongestMatchAt_iff, isLongestMatch_iff_isLongestMatch_beq]
|
||||
|
||||
theorem isLongestRevMatchAt_iff_isLongestRevMatchAt_beq {c : Char} {s : Slice}
|
||||
{pos pos' : s.Pos} :
|
||||
IsLongestRevMatchAt c pos pos' ↔ IsLongestRevMatchAt (· == c) pos pos' := by
|
||||
simp [Model.isLongestRevMatchAt_iff, isLongestRevMatch_iff_isLongestRevMatch_beq]
|
||||
|
||||
theorem matchesAt_iff_matchesAt_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
MatchesAt c pos ↔ MatchesAt (· == c) pos := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff_isLongestMatchAt_beq]
|
||||
|
||||
theorem revMatchesAt_iff_revMatchesAt_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
RevMatchesAt c pos ↔ RevMatchesAt (· == c) pos := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt, isLongestRevMatchAt_iff_isLongestRevMatchAt_beq]
|
||||
|
||||
theorem matchAt?_eq_matchAt?_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
matchAt? c pos = matchAt? (· == c) pos := by
|
||||
refine Option.ext (fun pos' => ?_)
|
||||
simp [matchAt?_eq_some_iff, isLongestMatchAt_iff_isLongestMatchAt_beq]
|
||||
|
||||
theorem revMatchAt?_eq_revMatchAt?_beq {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
revMatchAt? c pos = revMatchAt? (· == c) pos := by
|
||||
refine Option.ext (fun pos' => ?_)
|
||||
simp [revMatchAt?_eq_some_iff, isLongestRevMatchAt_iff_isLongestRevMatchAt_beq]
|
||||
|
||||
theorem isValidSearchFrom_iff_isValidSearchFrom_beq {c : Char} {s : Slice} {p : s.Pos}
|
||||
{l : List (SearchStep s)} : IsValidSearchFrom c p l ↔ IsValidSearchFrom (· == c) p l := by
|
||||
refine ⟨fun h => ?_, fun h => ?_⟩
|
||||
@@ -203,28 +120,11 @@ theorem isValidSearchFrom_iff_isValidSearchFrom_beq {c : Char} {s : Slice} {p :
|
||||
| matched => simp_all [IsValidSearchFrom.matched, isLongestMatchAt_iff_isLongestMatchAt_beq]
|
||||
| mismatched => simp_all [IsValidSearchFrom.mismatched, matchesAt_iff_matchesAt_beq]
|
||||
|
||||
theorem isValidRevSearchFrom_iff_isValidRevSearchFrom_beq {c : Char} {s : Slice} {p : s.Pos}
|
||||
{l : List (SearchStep s)} : IsValidRevSearchFrom c p l ↔ IsValidRevSearchFrom (· == c) p l := by
|
||||
refine ⟨fun h => ?_, fun h => ?_⟩
|
||||
· induction h with
|
||||
| startPos => simpa using IsValidRevSearchFrom.startPos
|
||||
| matched => simp_all [IsValidRevSearchFrom.matched, isLongestRevMatchAt_iff_isLongestRevMatchAt_beq]
|
||||
| mismatched => simp_all [IsValidRevSearchFrom.mismatched, revMatchesAt_iff_revMatchesAt_beq]
|
||||
· induction h with
|
||||
| startPos => simpa using IsValidRevSearchFrom.startPos
|
||||
| matched => simp_all [IsValidRevSearchFrom.matched, isLongestRevMatchAt_iff_isLongestRevMatchAt_beq]
|
||||
| mismatched => simp_all [IsValidRevSearchFrom.mismatched, revMatchesAt_iff_revMatchesAt_beq]
|
||||
|
||||
instance {c : Char} : LawfulToForwardSearcherModel c where
|
||||
isValidSearchFrom_toList s := by
|
||||
simpa [toSearcher_eq, isValidSearchFrom_iff_isValidSearchFrom_beq] using
|
||||
LawfulToForwardSearcherModel.isValidSearchFrom_toList (pat := (· == c)) (s := s)
|
||||
|
||||
instance {c : Char} : LawfulToBackwardSearcherModel c where
|
||||
isValidRevSearchFrom_toList s := by
|
||||
simpa [toBackwardSearcher_eq, isValidRevSearchFrom_iff_isValidRevSearchFrom_beq] using
|
||||
LawfulToBackwardSearcherModel.isValidRevSearchFrom_toList (pat := (· == c)) (s := s)
|
||||
|
||||
end Pattern.Model.Char
|
||||
|
||||
theorem startsWith_char_eq_startsWith_beq {c : Char} {s : Slice} :
|
||||
|
||||
@@ -23,7 +23,7 @@ open Std String.Slice Pattern Pattern.Model
|
||||
|
||||
namespace String.Slice
|
||||
|
||||
theorem Pattern.Model.find?_eq_some_iff {ρ : Type} (pat : ρ) [PatternModel pat] {σ : Slice → Type}
|
||||
theorem Pattern.Model.find?_eq_some_iff {ρ : Type} (pat : ρ) [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[∀ s, Iterator (σ s) Id (SearchStep s)] [∀ s, Iterators.Finite (σ s) Id]
|
||||
[∀ s, IteratorLoop (σ s) Id Id] [∀ s, LawfulIteratorLoop (σ s) Id Id]
|
||||
[ToForwardSearcher pat σ] [LawfulToForwardSearcherModel pat] {s : Slice} {pos : s.Pos} :
|
||||
@@ -40,7 +40,7 @@ theorem Pattern.Model.find?_eq_some_iff {ρ : Type} (pat : ρ) [PatternModel pat
|
||||
| matched h₁ _ _ => have := h₁.matchesAt; grind
|
||||
| mismatched => grind
|
||||
|
||||
theorem Pattern.Model.find?_eq_none_iff {ρ : Type} (pat : ρ) [PatternModel pat] {σ : Slice → Type}
|
||||
theorem Pattern.Model.find?_eq_none_iff {ρ : Type} (pat : ρ) [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[∀ s, Iterator (σ s) Id (SearchStep s)] [∀ s, Iterators.Finite (σ s) Id]
|
||||
[∀ s, IteratorLoop (σ s) Id Id] [∀ s, LawfulIteratorLoop (σ s) Id Id]
|
||||
[ToForwardSearcher pat σ] [LawfulToForwardSearcherModel pat] {s : Slice} :
|
||||
@@ -65,14 +65,14 @@ theorem find?_eq_none_iff {ρ : Type} (pat : ρ) {σ : Slice → Type}
|
||||
[ToForwardSearcher pat σ] {s : Slice} : s.find? pat = none ↔ s.contains pat = false := by
|
||||
rw [← Option.isNone_iff_eq_none, ← Option.isSome_eq_false_iff, isSome_find?]
|
||||
|
||||
theorem Pattern.Model.contains_eq_false_iff {ρ : Type} (pat : ρ) [PatternModel pat] {σ : Slice → Type}
|
||||
theorem Pattern.Model.contains_eq_false_iff {ρ : Type} (pat : ρ) [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[∀ s, Iterator (σ s) Id (SearchStep s)] [∀ s, Iterators.Finite (σ s) Id]
|
||||
[∀ s, IteratorLoop (σ s) Id Id] [∀ s, LawfulIteratorLoop (σ s) Id Id]
|
||||
[ToForwardSearcher pat σ] [LawfulToForwardSearcherModel pat] {s : Slice} :
|
||||
s.contains pat = false ↔ ∀ (pos : s.Pos), ¬ MatchesAt pat pos := by
|
||||
rw [← find?_eq_none_iff, Slice.find?_eq_none_iff]
|
||||
|
||||
theorem Pattern.Model.contains_eq_true_iff {ρ : Type} (pat : ρ) [PatternModel pat] {σ : Slice → Type}
|
||||
theorem Pattern.Model.contains_eq_true_iff {ρ : Type} (pat : ρ) [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[∀ s, Iterator (σ s) Id (SearchStep s)] [∀ s, Iterators.Finite (σ s) Id]
|
||||
[∀ s, IteratorLoop (σ s) Id Id] [∀ s, LawfulIteratorLoop (σ s) Id Id]
|
||||
[ToForwardSearcher pat σ] [LawfulToForwardSearcherModel pat] {s : Slice} :
|
||||
@@ -85,7 +85,7 @@ theorem Pos.find?_eq_find?_sliceFrom {ρ : Type} {pat : ρ} {σ : Slice → Type
|
||||
p.find? pat = ((s.sliceFrom p).find? pat).map Pos.ofSliceFrom :=
|
||||
(rfl)
|
||||
|
||||
theorem Pattern.Model.posFind?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel pat] {σ : Slice → Type}
|
||||
theorem Pattern.Model.posFind?_eq_some_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[∀ s, Iterator (σ s) Id (SearchStep s)] [∀ s, Iterators.Finite (σ s) Id]
|
||||
[∀ s, IteratorLoop (σ s) Id Id] [∀ s, LawfulIteratorLoop (σ s) Id Id]
|
||||
[ToForwardSearcher pat σ] [LawfulToForwardSearcherModel pat] {s : Slice} {pos pos' : s.Pos} :
|
||||
@@ -100,7 +100,7 @@ theorem Pattern.Model.posFind?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel
|
||||
refine ⟨Pos.sliceFrom _ _ h₁, ⟨by simpa using h₂, fun p hp₁ hp₂ => ?_⟩, by simp⟩
|
||||
exact h₃ (Pos.ofSliceFrom p) Slice.Pos.le_ofSliceFrom (Pos.lt_sliceFrom_iff.1 hp₁) hp₂
|
||||
|
||||
theorem Pattern.Model.posFind?_eq_none_iff {ρ : Type} {pat : ρ} [PatternModel pat] {σ : Slice → Type}
|
||||
theorem Pattern.Model.posFind?_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[∀ s, Iterator (σ s) Id (SearchStep s)] [∀ s, Iterators.Finite (σ s) Id]
|
||||
[∀ s, IteratorLoop (σ s) Id Id] [∀ s, LawfulIteratorLoop (σ s) Id Id]
|
||||
[ToForwardSearcher pat σ] [LawfulToForwardSearcherModel pat] {s : Slice} {pos : s.Pos} :
|
||||
|
||||
@@ -19,228 +19,124 @@ import Init.Data.String.Lemmas.Order
|
||||
import Init.Data.Order.Lemmas
|
||||
import Init.Data.String.OrderInstances
|
||||
import Init.Omega
|
||||
import Init.Data.String.Lemmas.FindPos
|
||||
|
||||
public section
|
||||
|
||||
namespace String.Slice.Pattern.Model.CharPred
|
||||
|
||||
instance {p : Char → Bool} : PatternModel p where
|
||||
instance {p : Char → Bool} : ForwardPatternModel p where
|
||||
Matches s := ∃ c, s = singleton c ∧ p c
|
||||
not_matches_empty := by
|
||||
simp
|
||||
|
||||
instance {p : Char → Bool} : NoPrefixPatternModel p :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
|
||||
instance {p : Char → Bool} : NoSuffixPatternModel p :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
instance {p : Char → Bool} : NoPrefixForwardPatternModel p :=
|
||||
.of_length_eq (by simp +contextual [ForwardPatternModel.Matches])
|
||||
|
||||
theorem isMatch_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
IsMatch p pos ↔
|
||||
∃ (h : s.startPos ≠ s.endPos), pos = s.startPos.next h ∧ p (s.startPos.get h) := by
|
||||
simp only [Model.isMatch_iff, PatternModel.Matches, copy_sliceTo_eq_iff_exists_splits]
|
||||
simp only [Model.isMatch_iff, ForwardPatternModel.Matches, sliceTo_copy_eq_iff_exists_splits]
|
||||
refine ⟨?_, ?_⟩
|
||||
· simp only [splits_singleton_iff]
|
||||
refine fun ⟨c, ⟨t₂, h, h₁, h₂, h₃⟩, hc⟩ => ⟨h, h₁, h₂ ▸ hc⟩
|
||||
· rintro ⟨h, rfl, h'⟩
|
||||
exact ⟨s.startPos.get h, ⟨_, Slice.splits_next_startPos⟩, h'⟩
|
||||
|
||||
theorem isRevMatch_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch p pos ↔
|
||||
∃ (h : s.endPos ≠ s.startPos), pos = s.endPos.prev h ∧ p ((s.endPos.prev h).get (by simp)) := by
|
||||
simp only [Model.isRevMatch_iff, PatternModel.Matches, copy_sliceFrom_eq_iff_exists_splits]
|
||||
refine ⟨?_, ?_⟩
|
||||
· simp only [splits_singleton_right_iff]
|
||||
refine fun ⟨c, ⟨t₂, h, h₁, h₂, h₃⟩, hc⟩ => ⟨h, h₁, h₂ ▸ hc⟩
|
||||
· rintro ⟨h, rfl, h'⟩
|
||||
exact ⟨(s.endPos.prev h).get (by simp), ⟨_, Slice.splits_prev_endPos⟩, h'⟩
|
||||
|
||||
theorem isLongestMatch_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestMatch p pos ↔
|
||||
∃ (h : s.startPos ≠ s.endPos), pos = s.startPos.next h ∧ p (s.startPos.get h) := by
|
||||
rw [isLongestMatch_iff_isMatch, isMatch_iff]
|
||||
|
||||
theorem isLongestRevMatch_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestRevMatch p pos ↔
|
||||
∃ (h : s.endPos ≠ s.startPos), pos = s.endPos.prev h ∧ p ((s.endPos.prev h).get (by simp)) := by
|
||||
rw [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff]
|
||||
|
||||
theorem isLongestMatchAt_iff {p : Char → Bool} {s : Slice} {pos pos' : s.Pos} :
|
||||
IsLongestMatchAt p pos pos' ↔ ∃ h, pos' = pos.next h ∧ p (pos.get h) := by
|
||||
simp +contextual [Model.isLongestMatchAt_iff, isLongestMatch_iff, ← Pos.ofSliceFrom_inj,
|
||||
Pos.get_eq_get_ofSliceFrom, Pos.ofSliceFrom_next]
|
||||
|
||||
theorem isLongestRevMatchAt_iff {p : Char → Bool} {s : Slice} {pos pos' : s.Pos} :
|
||||
IsLongestRevMatchAt p pos pos' ↔ ∃ h, pos = pos'.prev h ∧ p ((pos'.prev h).get (by simp)) := by
|
||||
simp +contextual [Model.isLongestRevMatchAt_iff, isLongestRevMatch_iff, ← Pos.ofSliceTo_inj,
|
||||
Pos.get_eq_get_ofSliceTo, Pos.ofSliceTo_prev]
|
||||
|
||||
theorem isLongestMatchAt_of_get {p : Char → Bool} {s : Slice} {pos : s.Pos} {h : pos ≠ s.endPos}
|
||||
(hc : p (pos.get h)) : IsLongestMatchAt p pos (pos.next h) :=
|
||||
isLongestMatchAt_iff.2 ⟨h, by simp [hc]⟩
|
||||
|
||||
theorem isLongestRevMatchAt_of_get {p : Char → Bool} {s : Slice} {pos : s.Pos} {h : pos ≠ s.startPos}
|
||||
(hc : p ((pos.prev h).get (by simp))) : IsLongestRevMatchAt p (pos.prev h) pos :=
|
||||
isLongestRevMatchAt_iff.2 ⟨h, by simp [hc]⟩
|
||||
|
||||
instance {p : Char → Bool} : LawfulForwardPatternModel p where
|
||||
skipPrefix?_eq_some_iff {s} pos := by
|
||||
simp [isLongestMatch_iff, ForwardPattern.skipPrefix?, and_comm, eq_comm (b := pos)]
|
||||
|
||||
instance {p : Char → Bool} : LawfulBackwardPatternModel p where
|
||||
skipSuffix?_eq_some_iff {s} pos := by
|
||||
simp [isLongestRevMatch_iff, BackwardPattern.skipSuffix?, and_comm, eq_comm (b := pos)]
|
||||
|
||||
instance {p : Char → Bool} : LawfulToForwardSearcherModel p :=
|
||||
.defaultImplementation
|
||||
|
||||
instance {p : Char → Bool} : LawfulToBackwardSearcherModel p :=
|
||||
.defaultImplementation
|
||||
|
||||
theorem matchesAt_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
MatchesAt p pos ↔ ∃ (h : pos ≠ s.endPos), p (pos.get h) := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff, exists_comm]
|
||||
|
||||
theorem revMatchesAt_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
RevMatchesAt p pos ↔ ∃ (h : pos ≠ s.startPos), p ((pos.prev h).get (by simp)) := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt, isLongestRevMatchAt_iff, exists_comm]
|
||||
|
||||
theorem not_matchesAt_of_get {p : Char → Bool} {s : Slice} {pos : s.Pos} {h : pos ≠ s.endPos}
|
||||
(hc : p (pos.get h) = false) : ¬ MatchesAt p pos := by
|
||||
simp [matchesAt_iff, hc]
|
||||
|
||||
theorem not_revMatchesAt_of_get {p : Char → Bool} {s : Slice} {pos : s.Pos} {h : pos ≠ s.startPos}
|
||||
(hc : p ((pos.prev h).get (by simp)) = false) : ¬ RevMatchesAt p pos := by
|
||||
simp [revMatchesAt_iff, hc]
|
||||
|
||||
theorem matchAt?_eq {s : Slice} {pos : s.Pos} {p : Char → Bool} :
|
||||
matchAt? p pos =
|
||||
if h₀ : ∃ (h : pos ≠ s.endPos), p (pos.get h) then some (pos.next h₀.1) else none := by
|
||||
split <;> simp_all [isLongestMatchAt_iff, matchesAt_iff]
|
||||
|
||||
theorem revMatchAt?_eq {s : Slice} {pos : s.Pos} {p : Char → Bool} :
|
||||
revMatchAt? p pos =
|
||||
if h₀ : ∃ (h : pos ≠ s.startPos), p ((pos.prev h).get (by simp)) then some (pos.prev h₀.1) else none := by
|
||||
split <;> simp_all [isLongestRevMatchAt_iff, revMatchesAt_iff]
|
||||
|
||||
namespace Decidable
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : PatternModel p where
|
||||
Matches := PatternModel.Matches (decide <| p ·)
|
||||
not_matches_empty := PatternModel.not_matches_empty (pat := (decide <| p ·))
|
||||
instance {p : Char → Prop} [DecidablePred p] : ForwardPatternModel p where
|
||||
Matches := ForwardPatternModel.Matches (decide <| p ·)
|
||||
not_matches_empty := ForwardPatternModel.not_matches_empty (pat := (decide <| p ·))
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : NoPrefixPatternModel p where
|
||||
eq_empty := NoPrefixPatternModel.eq_empty (pat := (decide <| p ·))
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : NoSuffixPatternModel p where
|
||||
eq_empty := NoSuffixPatternModel.eq_empty (pat := (decide <| p ·))
|
||||
instance {p : Char → Prop} [DecidablePred p] : NoPrefixForwardPatternModel p where
|
||||
eq_empty := NoPrefixForwardPatternModel.eq_empty (pat := (decide <| p ·))
|
||||
|
||||
theorem isMatch_iff_isMatch_decide {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch p pos ↔ IsMatch (decide <| p ·) pos :=
|
||||
⟨fun ⟨h⟩ => ⟨h⟩, fun ⟨h⟩ => ⟨h⟩⟩
|
||||
|
||||
theorem isRevMatch_iff_isRevMatch_decide {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch p pos ↔ IsRevMatch (decide <| p ·) pos :=
|
||||
⟨fun ⟨h⟩ => ⟨h⟩, fun ⟨h⟩ => ⟨h⟩⟩
|
||||
|
||||
theorem isMatch_iff {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
IsMatch p pos ↔
|
||||
∃ (h : s.startPos ≠ s.endPos), pos = s.startPos.next h ∧ p (s.startPos.get h) := by
|
||||
simp [isMatch_iff_isMatch_decide, CharPred.isMatch_iff]
|
||||
|
||||
theorem isRevMatch_iff {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch p pos ↔
|
||||
∃ (h : s.endPos ≠ s.startPos), pos = s.endPos.prev h ∧ p ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [isRevMatch_iff_isRevMatch_decide, CharPred.isRevMatch_iff]
|
||||
|
||||
theorem isLongestMatch_iff {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
IsLongestMatch p pos ↔
|
||||
∃ (h : s.startPos ≠ s.endPos), pos = s.startPos.next h ∧ p (s.startPos.get h) := by
|
||||
rw [isLongestMatch_iff_isMatch, isMatch_iff]
|
||||
|
||||
theorem isLongestRevMatch_iff {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
IsLongestRevMatch p pos ↔
|
||||
∃ (h : s.endPos ≠ s.startPos), pos = s.endPos.prev h ∧ p ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff]
|
||||
|
||||
theorem isLongestMatch_iff_isLongestMatch_decide {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos : s.Pos} : IsLongestMatch p pos ↔ IsLongestMatch (decide <| p ·) pos := by
|
||||
simp [isLongestMatch_iff_isMatch, isMatch_iff_isMatch_decide]
|
||||
|
||||
theorem isLongestRevMatch_iff_isLongestRevMatch_decide {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos : s.Pos} : IsLongestRevMatch p pos ↔ IsLongestRevMatch (decide <| p ·) pos := by
|
||||
simp [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff_isRevMatch_decide]
|
||||
|
||||
theorem isLongestMatchAt_iff_isLongestMatchAt_decide {p : Char → Prop} [DecidablePred p]
|
||||
{s : Slice} {pos pos' : s.Pos} :
|
||||
IsLongestMatchAt p pos pos' ↔ IsLongestMatchAt (decide <| p ·) pos pos' := by
|
||||
simp [Model.isLongestMatchAt_iff, isLongestMatch_iff_isLongestMatch_decide]
|
||||
|
||||
theorem isLongestRevMatchAt_iff_isLongestRevMatchAt_decide {p : Char → Prop} [DecidablePred p]
|
||||
{s : Slice} {pos pos' : s.Pos} :
|
||||
IsLongestRevMatchAt p pos pos' ↔ IsLongestRevMatchAt (decide <| p ·) pos pos' := by
|
||||
simp [Model.isLongestRevMatchAt_iff, isLongestRevMatch_iff_isLongestRevMatch_decide]
|
||||
|
||||
theorem isLongestMatchAt_iff {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos pos' : s.Pos} :
|
||||
IsLongestMatchAt p pos pos' ↔ ∃ h, pos' = pos.next h ∧ p (pos.get h) := by
|
||||
simp [isLongestMatchAt_iff_isLongestMatchAt_decide, CharPred.isLongestMatchAt_iff]
|
||||
|
||||
theorem isLongestRevMatchAt_iff {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos pos' : s.Pos} :
|
||||
IsLongestRevMatchAt p pos pos' ↔ ∃ h, pos = pos'.prev h ∧ p ((pos'.prev h).get (by simp)) := by
|
||||
simp [isLongestRevMatchAt_iff_isLongestRevMatchAt_decide, CharPred.isLongestRevMatchAt_iff]
|
||||
|
||||
theorem isLongestMatchAt_of_get {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos}
|
||||
{h : pos ≠ s.endPos} (hc : p (pos.get h)) : IsLongestMatchAt p pos (pos.next h) :=
|
||||
isLongestMatchAt_iff.2 ⟨h, by simp [hc]⟩
|
||||
|
||||
theorem isLongestRevMatchAt_of_get {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos}
|
||||
{h : pos ≠ s.startPos} (hc : p ((pos.prev h).get (by simp))) :
|
||||
IsLongestRevMatchAt p (pos.prev h) pos :=
|
||||
isLongestRevMatchAt_iff.2 ⟨h, by simp [hc]⟩
|
||||
|
||||
theorem matchesAt_iff_matchesAt_decide {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos : s.Pos} : MatchesAt p pos ↔ MatchesAt (decide <| p ·) pos := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff_isLongestMatchAt_decide]
|
||||
|
||||
theorem revMatchesAt_iff_revMatchesAt_decide {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos : s.Pos} : RevMatchesAt p pos ↔ RevMatchesAt (decide <| p ·) pos := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt, isLongestRevMatchAt_iff_isLongestRevMatchAt_decide]
|
||||
|
||||
theorem matchAt?_eq_matchAt?_decide {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos : s.Pos} : matchAt? p pos = matchAt? (decide <| p ·) pos := by
|
||||
ext endPos
|
||||
simp [isLongestMatchAt_iff_isLongestMatchAt_decide]
|
||||
|
||||
theorem revMatchAt?_eq_revMatchAt?_decide {p : Char → Prop} [DecidablePred p] {s : Slice}
|
||||
{pos : s.Pos} : revMatchAt? p pos = revMatchAt? (decide <| p ·) pos := by
|
||||
ext startPos
|
||||
simp [isLongestRevMatchAt_iff_isLongestRevMatchAt_decide]
|
||||
|
||||
theorem skipPrefix?_eq_skipPrefix?_decide {p : Char → Prop} [DecidablePred p] :
|
||||
ForwardPattern.skipPrefix? p = ForwardPattern.skipPrefix? (decide <| p ·) := rfl
|
||||
|
||||
theorem skipSuffix?_eq_skipSuffix?_decide {p : Char → Prop} [DecidablePred p] :
|
||||
BackwardPattern.skipSuffix? p = BackwardPattern.skipSuffix? (decide <| p ·) := rfl
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : LawfulForwardPatternModel p where
|
||||
skipPrefix?_eq_some_iff {s} pos := by
|
||||
rw [skipPrefix?_eq_skipPrefix?_decide, isLongestMatch_iff_isLongestMatch_decide]
|
||||
exact LawfulForwardPatternModel.skipPrefix?_eq_some_iff ..
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : LawfulBackwardPatternModel p where
|
||||
skipSuffix?_eq_some_iff {s} pos := by
|
||||
rw [skipSuffix?_eq_skipSuffix?_decide, isLongestRevMatch_iff_isLongestRevMatch_decide]
|
||||
exact LawfulBackwardPatternModel.skipSuffix?_eq_some_iff ..
|
||||
|
||||
theorem toSearcher_eq {p : Char → Prop} [DecidablePred p] {s : Slice} :
|
||||
ToForwardSearcher.toSearcher p s = ToForwardSearcher.toSearcher (decide <| p ·) s := (rfl)
|
||||
|
||||
theorem toBackwardSearcher_eq {p : Char → Prop} [DecidablePred p] {s : Slice} :
|
||||
ToBackwardSearcher.toSearcher p s = ToBackwardSearcher.toSearcher (decide <| p ·) s := (rfl)
|
||||
|
||||
theorem isValidSearchFrom_iff_isValidSearchFrom_decide {p : Char → Prop} [DecidablePred p]
|
||||
{s : Slice} {pos : s.Pos} {l : List (SearchStep s)} :
|
||||
IsValidSearchFrom p pos l ↔ IsValidSearchFrom (decide <| p ·) pos l := by
|
||||
@@ -254,55 +150,24 @@ theorem isValidSearchFrom_iff_isValidSearchFrom_decide {p : Char → Prop} [Deci
|
||||
| matched => simp_all [IsValidSearchFrom.matched, isLongestMatchAt_iff_isLongestMatchAt_decide]
|
||||
| mismatched => simp_all [IsValidSearchFrom.mismatched, matchesAt_iff_matchesAt_decide]
|
||||
|
||||
theorem isValidRevSearchFrom_iff_isValidRevSearchFrom_decide {p : Char → Prop} [DecidablePred p]
|
||||
{s : Slice} {pos : s.Pos} {l : List (SearchStep s)} :
|
||||
IsValidRevSearchFrom p pos l ↔ IsValidRevSearchFrom (decide <| p ·) pos l := by
|
||||
refine ⟨fun h => ?_, fun h => ?_⟩
|
||||
· induction h with
|
||||
| startPos => simpa using IsValidRevSearchFrom.startPos
|
||||
| matched => simp_all [IsValidRevSearchFrom.matched, isLongestRevMatchAt_iff_isLongestRevMatchAt_decide]
|
||||
| mismatched => simp_all [IsValidRevSearchFrom.mismatched, revMatchesAt_iff_revMatchesAt_decide]
|
||||
· induction h with
|
||||
| startPos => simpa using IsValidRevSearchFrom.startPos
|
||||
| matched => simp_all [IsValidRevSearchFrom.matched, isLongestRevMatchAt_iff_isLongestRevMatchAt_decide]
|
||||
| mismatched => simp_all [IsValidRevSearchFrom.mismatched, revMatchesAt_iff_revMatchesAt_decide]
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : LawfulToForwardSearcherModel p where
|
||||
isValidSearchFrom_toList s := by
|
||||
simpa [toSearcher_eq, isValidSearchFrom_iff_isValidSearchFrom_decide] using
|
||||
LawfulToForwardSearcherModel.isValidSearchFrom_toList (pat := (decide <| p ·)) (s := s)
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] : LawfulToBackwardSearcherModel p where
|
||||
isValidRevSearchFrom_toList s := by
|
||||
simpa [toBackwardSearcher_eq, isValidRevSearchFrom_iff_isValidRevSearchFrom_decide] using
|
||||
LawfulToBackwardSearcherModel.isValidRevSearchFrom_toList (pat := (decide <| p ·)) (s := s)
|
||||
|
||||
theorem matchesAt_iff {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
MatchesAt p pos ↔ ∃ (h : pos ≠ s.endPos), p (pos.get h) := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff, exists_comm]
|
||||
|
||||
theorem revMatchesAt_iff {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos} :
|
||||
RevMatchesAt p pos ↔ ∃ (h : pos ≠ s.startPos), p ((pos.prev h).get (by simp)) := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt, isLongestRevMatchAt_iff, exists_comm]
|
||||
|
||||
theorem not_matchesAt_of_get {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos}
|
||||
{h : pos ≠ s.endPos} (hc : ¬ p (pos.get h)) : ¬ MatchesAt p pos := by
|
||||
simp [matchesAt_iff, hc]
|
||||
|
||||
theorem not_revMatchesAt_of_get {p : Char → Prop} [DecidablePred p] {s : Slice} {pos : s.Pos}
|
||||
{h : pos ≠ s.startPos} (hc : ¬ p ((pos.prev h).get (by simp))) : ¬ RevMatchesAt p pos := by
|
||||
simp [revMatchesAt_iff, hc]
|
||||
|
||||
theorem matchAt?_eq {s : Slice} {pos : s.Pos} {p : Char → Prop} [DecidablePred p] :
|
||||
matchAt? p pos =
|
||||
if h₀ : ∃ (h : pos ≠ s.endPos), p (pos.get h) then some (pos.next h₀.1) else none := by
|
||||
split <;> simp_all [isLongestMatchAt_iff, matchesAt_iff]
|
||||
|
||||
theorem revMatchAt?_eq {s : Slice} {pos : s.Pos} {p : Char → Prop} [DecidablePred p] :
|
||||
revMatchAt? p pos =
|
||||
if h₀ : ∃ (h : pos ≠ s.startPos), p ((pos.prev h).get (by simp)) then some (pos.prev h₀.1) else none := by
|
||||
split <;> simp_all [isLongestRevMatchAt_iff, revMatchesAt_iff]
|
||||
|
||||
end Decidable
|
||||
|
||||
end Pattern.Model.CharPred
|
||||
|
||||
@@ -28,7 +28,7 @@ set_option doc.verso true
|
||||
# Verification of {name}`String.Slice.splitToSubslice`
|
||||
|
||||
This PR verifies the {name}`String.Slice.splitToSubslice` function by relating it to a model
|
||||
implementation based on the {name}`String.Slice.Pattern.Model.PatternModel` class.
|
||||
implementation based on the {name}`String.Slice.Pattern.Model.ForwardPatternModel` class.
|
||||
|
||||
This gives a low-level correctness proof from which higher-level API lemmas can be derived.
|
||||
-/
|
||||
@@ -36,7 +36,7 @@ This gives a low-level correctness proof from which higher-level API lemmas can
|
||||
namespace String.Slice.Pattern.Model
|
||||
|
||||
@[cbv_opaque]
|
||||
public protected noncomputable def split {ρ : Type} (pat : ρ) [PatternModel pat] {s : Slice}
|
||||
public protected noncomputable def split {ρ : Type} (pat : ρ) [ForwardPatternModel pat] {s : Slice}
|
||||
(firstRejected curr : s.Pos) (hle : firstRejected ≤ curr) : List s.Subslice :=
|
||||
if h : curr = s.endPos then
|
||||
[s.subslice _ _ hle]
|
||||
@@ -49,12 +49,12 @@ public protected noncomputable def split {ρ : Type} (pat : ρ) [PatternModel pa
|
||||
termination_by curr
|
||||
|
||||
@[simp]
|
||||
public theorem split_endPos {ρ : Type} {pat : ρ} [PatternModel pat] {s : Slice}
|
||||
public theorem split_endPos {ρ : Type} {pat : ρ} [ForwardPatternModel pat] {s : Slice}
|
||||
{firstRejected : s.Pos} :
|
||||
Model.split (s := s) pat firstRejected s.endPos (by simp) = [s.subslice firstRejected s.endPos (by simp)] := by
|
||||
simp [Model.split]
|
||||
|
||||
public theorem split_eq_of_isLongestMatchAt {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
public theorem split_eq_of_isLongestMatchAt {ρ : Type} {pat : ρ} [ForwardPatternModel pat]
|
||||
{s : Slice} {firstRejected start stop : s.Pos} {hle} (h : IsLongestMatchAt pat start stop) :
|
||||
Model.split pat firstRejected start hle =
|
||||
s.subslice _ _ hle :: Model.split pat stop stop (by exact Std.le_refl _) := by
|
||||
@@ -63,7 +63,7 @@ public theorem split_eq_of_isLongestMatchAt {ρ : Type} {pat : ρ} [PatternModel
|
||||
· congr <;> exact (matchAt?_eq_some_iff.1 ‹_›).eq h
|
||||
· simp [matchAt?_eq_some_iff.2 ‹_›] at *
|
||||
|
||||
public theorem split_eq_of_not_matchesAt {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
public theorem split_eq_of_not_matchesAt {ρ : Type} {pat : ρ} [ForwardPatternModel pat]
|
||||
{s : Slice} {firstRejected start} (stop : s.Pos) (h₀ : start ≤ stop) {hle}
|
||||
(h : ∀ p, start ≤ p → p < stop → ¬ MatchesAt pat p) :
|
||||
Model.split pat firstRejected start hle =
|
||||
@@ -80,7 +80,7 @@ public theorem split_eq_of_not_matchesAt {ρ : Type} {pat : ρ} [PatternModel pa
|
||||
· obtain rfl : start = stop := Std.le_antisymm h₀ (Std.not_lt.1 h')
|
||||
simp
|
||||
|
||||
public theorem split_eq_next_of_not_matchesAt {ρ : Type} {pat : ρ} [PatternModel pat]
|
||||
public theorem split_eq_next_of_not_matchesAt {ρ : Type} {pat : ρ} [ForwardPatternModel pat]
|
||||
{s : Slice} {firstRejected start} {hle} (hs : start ≠ s.endPos) (h : ¬ MatchesAt pat start) :
|
||||
Model.split pat firstRejected start hle =
|
||||
Model.split pat firstRejected (start.next hs) (by exact Std.le_trans hle (by simp)) := by
|
||||
@@ -103,7 +103,7 @@ def splitFromSteps {s : Slice} (currPos : s.Pos) (l : List (SearchStep s)) : Lis
|
||||
| .matched p q :: l => s.subslice! currPos p :: splitFromSteps q l
|
||||
|
||||
theorem IsValidSearchFrom.splitFromSteps_eq_extend_split {ρ : Type} (pat : ρ)
|
||||
[PatternModel pat] (l : List (SearchStep s)) (pos pos' : s.Pos) (h₀ : pos ≤ pos')
|
||||
[ForwardPatternModel pat] (l : List (SearchStep s)) (pos pos' : s.Pos) (h₀ : pos ≤ pos')
|
||||
(h' : ∀ p, pos ≤ p → p < pos' → ¬ MatchesAt pat p)
|
||||
(h : IsValidSearchFrom pat pos' l) :
|
||||
splitFromSteps pos l = Model.split pat pos pos' h₀ := by
|
||||
@@ -155,7 +155,7 @@ end Model
|
||||
open Model
|
||||
|
||||
@[cbv_eval]
|
||||
public theorem toList_splitToSubslice_eq_modelSplit {ρ : Type} (pat : ρ) [PatternModel pat]
|
||||
public theorem toList_splitToSubslice_eq_modelSplit {ρ : Type} (pat : ρ) [ForwardPatternModel pat]
|
||||
{σ : Slice → Type} [ToForwardSearcher pat σ] [∀ s, Std.Iterator (σ s) Id (SearchStep s)]
|
||||
[∀ s, Std.Iterators.Finite (σ s) Id] [LawfulToForwardSearcherModel pat] (s : Slice) :
|
||||
(s.splitToSubslice pat).toList = Model.split pat s.startPos s.startPos (by exact Std.le_refl _) := by
|
||||
@@ -168,7 +168,7 @@ end Pattern
|
||||
open Pattern
|
||||
|
||||
public theorem toList_splitToSubslice_of_isEmpty {ρ : Type} (pat : ρ)
|
||||
[Model.PatternModel pat] {σ : Slice → Type}
|
||||
[Model.ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[ToForwardSearcher pat σ] [∀ s, Std.Iterator (σ s) Id (SearchStep s)]
|
||||
[∀ s, Std.Iterators.Finite (σ s) Id] [Model.LawfulToForwardSearcherModel pat] {s : Slice}
|
||||
(h : s.isEmpty = true) :
|
||||
@@ -182,7 +182,7 @@ public theorem toList_split_eq_splitToSubslice {ρ : Type} (pat : ρ) {σ : Slic
|
||||
simp [split, Std.Iter.toList_map]
|
||||
|
||||
public theorem toList_split_of_isEmpty {ρ : Type} (pat : ρ)
|
||||
[Model.PatternModel pat] {σ : Slice → Type}
|
||||
[Model.ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[ToForwardSearcher pat σ] [∀ s, Std.Iterator (σ s) Id (SearchStep s)]
|
||||
[∀ s, Std.Iterators.Finite (σ s) Id] [Model.LawfulToForwardSearcherModel pat] {s : Slice}
|
||||
(h : s.isEmpty = true) :
|
||||
@@ -200,7 +200,7 @@ public theorem split_eq_split_toSlice {ρ : Type} {pat : ρ} {σ : Slice → Typ
|
||||
|
||||
@[simp]
|
||||
public theorem toList_split_empty {ρ : Type} (pat : ρ)
|
||||
[Model.PatternModel pat] {σ : Slice → Type}
|
||||
[Model.ForwardPatternModel pat] {σ : Slice → Type}
|
||||
[ToForwardSearcher pat σ] [∀ s, Std.Iterator (σ s) Id (SearchStep s)]
|
||||
[∀ s, Std.Iterators.Finite (σ s) Id] [Model.LawfulToForwardSearcherModel pat] :
|
||||
("".split pat).toList.map Slice.copy = [""] := by
|
||||
|
||||
@@ -19,12 +19,12 @@ namespace String.Slice.Pattern.Model
|
||||
|
||||
namespace ForwardSliceSearcher
|
||||
|
||||
instance {pat : Slice} : PatternModel pat where
|
||||
instance {pat : Slice} : ForwardPatternModel pat where
|
||||
/-
|
||||
See the docstring of `PatternModel` for an explanation about why we disallow matching the
|
||||
See the docstring of `ForwardPatternModel` for an explanation about why we disallow matching the
|
||||
empty string.
|
||||
|
||||
Requiring `s ≠ ""` is a trick that allows us to give a `PatternModel` instance
|
||||
Requiring `s ≠ ""` is a trick that allows us to give a `ForwardPatternModel` instance
|
||||
unconditionally, without forcing `pat.copy` to be non-empty (which would make it very awkward
|
||||
to state theorems about the instance). It does not change anything about the fact that all lemmas
|
||||
about this instance require `pat.isEmpty = false`.
|
||||
@@ -32,60 +32,34 @@ instance {pat : Slice} : PatternModel pat where
|
||||
Matches s := s ≠ "" ∧ s = pat.copy
|
||||
not_matches_empty := by simp
|
||||
|
||||
instance {pat : Slice} : NoPrefixPatternModel pat :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
|
||||
instance {pat : Slice} : NoSuffixPatternModel pat :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
instance {pat : Slice} : NoPrefixForwardPatternModel pat :=
|
||||
.of_length_eq (by simp +contextual [ForwardPatternModel.Matches])
|
||||
|
||||
theorem isMatch_iff {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsMatch pat pos ↔ (s.sliceTo pos).copy = pat.copy := by
|
||||
simp only [Model.isMatch_iff, PatternModel.Matches, ne_eq, copy_eq_empty_iff,
|
||||
simp only [Model.isMatch_iff, ForwardPatternModel.Matches, ne_eq, copy_eq_empty_iff,
|
||||
Bool.not_eq_true, and_iff_right_iff_imp]
|
||||
intro h'
|
||||
rw [← isEmpty_copy (s := s.sliceTo pos), h', isEmpty_copy, h]
|
||||
|
||||
theorem isRevMatch_iff {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsRevMatch pat pos ↔ (s.sliceFrom pos).copy = pat.copy := by
|
||||
simp only [Model.isRevMatch_iff, PatternModel.Matches, ne_eq, copy_eq_empty_iff,
|
||||
Bool.not_eq_true, and_iff_right_iff_imp]
|
||||
intro h'
|
||||
rw [← isEmpty_copy (s := s.sliceFrom pos), h', isEmpty_copy, h]
|
||||
|
||||
theorem isLongestMatch_iff {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestMatch pat pos ↔ (s.sliceTo pos).copy = pat.copy := by
|
||||
rw [isLongestMatch_iff_isMatch, isMatch_iff h]
|
||||
|
||||
theorem isLongestRevMatch_iff {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestRevMatch pat pos ↔ (s.sliceFrom pos).copy = pat.copy := by
|
||||
rw [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff h]
|
||||
|
||||
theorem isLongestMatchAt_iff {pat s : Slice} {pos₁ pos₂ : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔ ∃ h, (s.slice pos₁ pos₂ h).copy = pat.copy := by
|
||||
simp [Model.isLongestMatchAt_iff, isLongestMatch_iff h]
|
||||
|
||||
theorem isLongestRevMatchAt_iff {pat s : Slice} {pos₁ pos₂ : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔ ∃ h, (s.slice pos₁ pos₂ h).copy = pat.copy := by
|
||||
simp [Model.isLongestRevMatchAt_iff, isLongestRevMatch_iff h]
|
||||
|
||||
theorem isLongestMatchAt_iff_splits {pat s : Slice} {pos₁ pos₂ : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔ ∃ t₁ t₂, pos₁.Splits t₁ (pat.copy ++ t₂) ∧
|
||||
pos₂.Splits (t₁ ++ pat.copy) t₂ := by
|
||||
simp only [isLongestMatchAt_iff h, copy_slice_eq_iff_splits]
|
||||
|
||||
theorem isLongestRevMatchAt_iff_splits {pat s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat.isEmpty = false) :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔ ∃ t₁ t₂, pos₁.Splits t₁ (pat.copy ++ t₂) ∧
|
||||
pos₂.Splits (t₁ ++ pat.copy) t₂ := by
|
||||
simp only [isLongestRevMatchAt_iff h, copy_slice_eq_iff_splits]
|
||||
|
||||
theorem isLongestMatch_iff_splits {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestMatch pat pos ↔ ∃ t, pos.Splits pat.copy t := by
|
||||
rw [isLongestMatch_iff h, copy_sliceTo_eq_iff_exists_splits]
|
||||
|
||||
theorem isLongestRevMatch_iff_splits {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestRevMatch pat pos ↔ ∃ t, pos.Splits t pat.copy := by
|
||||
rw [isLongestRevMatch_iff h, copy_sliceFrom_eq_iff_exists_splits]
|
||||
simp only [← isLongestMatchAt_startPos_iff, isLongestMatchAt_iff_splits h, splits_startPos_iff,
|
||||
and_assoc, exists_and_left, exists_eq_left, empty_append]
|
||||
exact ⟨fun ⟨h, _, h'⟩ => ⟨h, h'⟩, fun ⟨h, h'⟩ => ⟨h, h'.eq_append.symm, h'⟩⟩
|
||||
|
||||
theorem isLongestMatchAt_iff_extract {pat s : Slice} {pos₁ pos₂ : s.Pos} (h : pat.isEmpty = false) :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔
|
||||
@@ -97,18 +71,6 @@ theorem isLongestMatchAt_iff_extract {pat s : Slice} {pos₁ pos₂ : s.Pos} (h
|
||||
exact ⟨by simp [Pos.le_iff, Pos.Raw.le_iff]; omega,
|
||||
by simp [← h', ← toByteArray_inj, toByteArray_copy_slice]⟩
|
||||
|
||||
theorem isLongestRevMatchAt_iff_extract {pat s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat.isEmpty = false) :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔
|
||||
s.copy.toByteArray.extract pos₁.offset.byteIdx pos₂.offset.byteIdx =
|
||||
pat.copy.toByteArray := by
|
||||
rw [isLongestRevMatchAt_iff h]
|
||||
refine ⟨fun ⟨h, h'⟩ => ?_, fun h' => ?_⟩
|
||||
· simp [← h', toByteArray_copy_slice]
|
||||
· rw [← Slice.toByteArray_copy_ne_empty_iff, ← h', ne_eq, ByteArray.extract_eq_empty_iff] at h
|
||||
exact ⟨by simp [Pos.le_iff, Pos.Raw.le_iff]; omega,
|
||||
by simp [← h', ← toByteArray_inj, toByteArray_copy_slice]⟩
|
||||
|
||||
theorem offset_of_isLongestMatchAt {pat s : Slice} {pos₁ pos₂ : s.Pos} (h : pat.isEmpty = false)
|
||||
(h' : IsLongestMatchAt pat pos₁ pos₂) : pos₂.offset = pos₁.offset.increaseBy pat.utf8ByteSize := by
|
||||
simp only [Pos.Raw.ext_iff, Pos.Raw.byteIdx_increaseBy]
|
||||
@@ -119,29 +81,12 @@ theorem offset_of_isLongestMatchAt {pat s : Slice} {pos₁ pos₂ : s.Pos} (h :
|
||||
suffices pos₂.offset.byteIdx ≤ s.utf8ByteSize by omega
|
||||
simpa [Pos.le_iff, Pos.Raw.le_iff] using pos₂.le_endPos
|
||||
|
||||
theorem offset_of_isLongestRevMatchAt {pat s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat.isEmpty = false) (h' : IsLongestRevMatchAt pat pos₁ pos₂) :
|
||||
pos₂.offset = pos₁.offset.increaseBy pat.utf8ByteSize := by
|
||||
simp only [Pos.Raw.ext_iff, Pos.Raw.byteIdx_increaseBy]
|
||||
rw [isLongestRevMatchAt_iff_extract h] at h'
|
||||
rw [← Slice.toByteArray_copy_ne_empty_iff, ← h', ne_eq, ByteArray.extract_eq_empty_iff] at h
|
||||
replace h' := congrArg ByteArray.size h'
|
||||
simp only [ByteArray.size_extract, size_toByteArray, utf8ByteSize_copy] at h'
|
||||
suffices pos₂.offset.byteIdx ≤ s.utf8ByteSize by omega
|
||||
simpa [Pos.le_iff, Pos.Raw.le_iff] using pos₂.le_endPos
|
||||
|
||||
theorem matchesAt_iff_splits {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
MatchesAt pat pos ↔ ∃ t₁ t₂, pos.Splits t₁ (pat.copy ++ t₂) := by
|
||||
simp only [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff_splits h]
|
||||
exact ⟨fun ⟨e, t₁, t₂, ht₁, ht₂⟩ => ⟨t₁, t₂, ht₁⟩,
|
||||
fun ⟨t₁, t₂, ht⟩ => ⟨ht.rotateRight, t₁, t₂, ht, ht.splits_rotateRight⟩⟩
|
||||
|
||||
theorem revMatchesAt_iff_splits {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
RevMatchesAt pat pos ↔ ∃ t₁ t₂, pos.Splits (t₁ ++ pat.copy) t₂ := by
|
||||
simp only [revMatchesAt_iff_exists_isLongestRevMatchAt, isLongestRevMatchAt_iff_splits h]
|
||||
exact ⟨fun ⟨e, t₁, t₂, ht₁, ht₂⟩ => ⟨t₁, t₂, ht₂⟩,
|
||||
fun ⟨t₁, t₂, ht⟩ => ⟨ht.rotateLeft, t₁, t₂, ht.splits_rotateLeft, ht⟩⟩
|
||||
|
||||
theorem exists_matchesAt_iff_eq_append {pat s : Slice} (h : pat.isEmpty = false) :
|
||||
(∃ (pos : s.Pos), MatchesAt pat pos) ↔ ∃ t₁ t₂, s.copy = t₁ ++ pat.copy ++ t₂ := by
|
||||
simp only [matchesAt_iff_splits h]
|
||||
@@ -154,18 +99,6 @@ theorem exists_matchesAt_iff_eq_append {pat s : Slice} (h : pat.isEmpty = false)
|
||||
⟨t₁, pat.copy ++ t₂, by rw [← append_assoc]; exact heq, rfl⟩
|
||||
exact ⟨s.pos _ hvalid, t₁, t₂, ⟨by rw [← append_assoc]; exact heq, by simp⟩⟩
|
||||
|
||||
theorem exists_revMatchesAt_iff_eq_append {pat s : Slice} (h : pat.isEmpty = false) :
|
||||
(∃ (pos : s.Pos), RevMatchesAt pat pos) ↔ ∃ t₁ t₂, s.copy = t₁ ++ pat.copy ++ t₂ := by
|
||||
simp only [revMatchesAt_iff_splits h]
|
||||
constructor
|
||||
· rintro ⟨pos, t₁, t₂, hsplit⟩
|
||||
exact ⟨t₁, t₂, by rw [hsplit.eq_append, append_assoc]⟩
|
||||
· rintro ⟨t₁, t₂, heq⟩
|
||||
have hvalid : (t₁ ++ pat.copy).rawEndPos.IsValidForSlice s :=
|
||||
Pos.Raw.isValidForSlice_iff_exists_append.mpr
|
||||
⟨t₁ ++ pat.copy, t₂, heq, rfl⟩
|
||||
exact ⟨s.pos _ hvalid, t₁, t₂, ⟨heq, by simp⟩⟩
|
||||
|
||||
theorem matchesAt_iff_isLongestMatchAt {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
MatchesAt pat pos ↔ ∃ (h : (pos.offset.increaseBy pat.utf8ByteSize).IsValidForSlice s),
|
||||
IsLongestMatchAt pat pos (s.pos _ h) := by
|
||||
@@ -175,25 +108,6 @@ theorem matchesAt_iff_isLongestMatchAt {pat s : Slice} {pos : s.Pos} (h : pat.is
|
||||
obtain rfl : p = s.pos _ this := by simpa [Pos.ext_iff] using offset_of_isLongestMatchAt h h'
|
||||
exact h'
|
||||
|
||||
theorem revMatchesAt_iff_isLongestRevMatchAt {pat s : Slice} {pos : s.Pos}
|
||||
(h : pat.isEmpty = false) :
|
||||
RevMatchesAt pat pos ↔
|
||||
∃ (h : (pos.offset.decreaseBy pat.utf8ByteSize).IsValidForSlice s),
|
||||
IsLongestRevMatchAt pat (s.pos _ h) pos := by
|
||||
refine ⟨fun ⟨⟨p, h'⟩⟩ => ?_, fun ⟨_, h⟩ => ⟨⟨_, h⟩⟩⟩
|
||||
have hoff := offset_of_isLongestRevMatchAt h h'
|
||||
have hvalid : (pos.offset.decreaseBy pat.utf8ByteSize).IsValidForSlice s := by
|
||||
rw [show pos.offset.decreaseBy pat.utf8ByteSize = p.offset from by
|
||||
simp [Pos.Raw.ext_iff, Pos.Raw.byteIdx_decreaseBy, Pos.Raw.byteIdx_increaseBy] at hoff ⊢
|
||||
omega]
|
||||
exact p.isValidForSlice
|
||||
refine ⟨hvalid, ?_⟩
|
||||
obtain rfl : p = s.pos _ hvalid := by
|
||||
simp only [Pos.ext_iff, offset_pos]
|
||||
simp [Pos.Raw.ext_iff, Pos.Raw.byteIdx_decreaseBy, Pos.Raw.byteIdx_increaseBy] at hoff ⊢
|
||||
omega
|
||||
exact h'
|
||||
|
||||
theorem matchesAt_iff_getElem {pat s : Slice} {pos : s.Pos} (h : pat.isEmpty = false) :
|
||||
MatchesAt pat pos ↔
|
||||
∃ (h : pos.offset.byteIdx + pat.copy.toByteArray.size ≤ s.copy.toByteArray.size),
|
||||
@@ -232,56 +146,31 @@ end ForwardSliceSearcher
|
||||
|
||||
namespace ForwardStringSearcher
|
||||
|
||||
instance {pat : String} : PatternModel pat where
|
||||
instance {pat : String} : ForwardPatternModel pat where
|
||||
Matches s := s ≠ "" ∧ s = pat
|
||||
not_matches_empty := by simp
|
||||
|
||||
instance {pat : String} : NoPrefixPatternModel pat :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
|
||||
instance {pat : String} : NoSuffixPatternModel pat :=
|
||||
.of_length_eq (by simp +contextual [PatternModel.Matches])
|
||||
instance {pat : String} : NoPrefixForwardPatternModel pat :=
|
||||
.of_length_eq (by simp +contextual [ForwardPatternModel.Matches])
|
||||
|
||||
theorem isMatch_iff_slice {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
IsMatch (ρ := String) pat pos ↔ IsMatch (ρ := Slice) pat.toSlice pos := by
|
||||
simp only [Model.isMatch_iff, PatternModel.Matches, copy_toSlice]
|
||||
|
||||
theorem isRevMatch_iff_slice {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
IsRevMatch (ρ := String) pat pos ↔ IsRevMatch (ρ := Slice) pat.toSlice pos := by
|
||||
simp only [Model.isRevMatch_iff, PatternModel.Matches, copy_toSlice]
|
||||
simp only [Model.isMatch_iff, ForwardPatternModel.Matches, copy_toSlice]
|
||||
|
||||
theorem isLongestMatch_iff_isLongestMatch_toSlice {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestMatch (ρ := String) pat pos ↔ IsLongestMatch (ρ := Slice) pat.toSlice pos where
|
||||
mp h := ⟨isMatch_iff_slice.1 h.isMatch, fun p hp hm => h.not_isMatch p hp (isMatch_iff_slice.2 hm)⟩
|
||||
mpr h := ⟨isMatch_iff_slice.2 h.isMatch, fun p hp hm => h.not_isMatch p hp (isMatch_iff_slice.1 hm)⟩
|
||||
|
||||
theorem isLongestRevMatch_iff_isLongestRevMatch_toSlice {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
IsLongestRevMatch (ρ := String) pat pos ↔ IsLongestRevMatch (ρ := Slice) pat.toSlice pos where
|
||||
mp h := ⟨isRevMatch_iff_slice.1 h.isRevMatch,
|
||||
fun p hp hm => h.not_isRevMatch p hp (isRevMatch_iff_slice.2 hm)⟩
|
||||
mpr h := ⟨isRevMatch_iff_slice.2 h.isRevMatch,
|
||||
fun p hp hm => h.not_isRevMatch p hp (isRevMatch_iff_slice.1 hm)⟩
|
||||
|
||||
theorem isLongestMatchAt_iff_isLongestMatchAt_toSlice {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos} :
|
||||
IsLongestMatchAt (ρ := String) pat pos₁ pos₂ ↔
|
||||
IsLongestMatchAt (ρ := Slice) pat.toSlice pos₁ pos₂ := by
|
||||
simp [Model.isLongestMatchAt_iff, isLongestMatch_iff_isLongestMatch_toSlice]
|
||||
|
||||
theorem isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice {pat : String} {s : Slice}
|
||||
{pos₁ pos₂ : s.Pos} :
|
||||
IsLongestRevMatchAt (ρ := String) pat pos₁ pos₂ ↔
|
||||
IsLongestRevMatchAt (ρ := Slice) pat.toSlice pos₁ pos₂ := by
|
||||
simp [Model.isLongestRevMatchAt_iff, isLongestRevMatch_iff_isLongestRevMatch_toSlice]
|
||||
|
||||
theorem matchesAt_iff_toSlice {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
MatchesAt (ρ := String) pat pos ↔ MatchesAt (ρ := Slice) pat.toSlice pos := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff_isLongestMatchAt_toSlice]
|
||||
|
||||
theorem revMatchesAt_iff_toSlice {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
RevMatchesAt (ρ := String) pat pos ↔ RevMatchesAt (ρ := Slice) pat.toSlice pos := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt,
|
||||
isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice]
|
||||
|
||||
private theorem toSlice_isEmpty (h : pat ≠ "") : pat.toSlice.isEmpty = false := by
|
||||
rwa [isEmpty_toSlice, isEmpty_eq_false_iff]
|
||||
|
||||
@@ -290,31 +179,16 @@ theorem isMatch_iff {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
rw [isMatch_iff_slice, ForwardSliceSearcher.isMatch_iff (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isRevMatch_iff {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
IsRevMatch pat pos ↔ (s.sliceFrom pos).copy = pat := by
|
||||
rw [isRevMatch_iff_slice, ForwardSliceSearcher.isRevMatch_iff (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isLongestMatch_iff {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
IsLongestMatch pat pos ↔ (s.sliceTo pos).copy = pat := by
|
||||
rw [isLongestMatch_iff_isMatch, isMatch_iff h]
|
||||
|
||||
theorem isLongestRevMatch_iff {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
IsLongestRevMatch pat pos ↔ (s.sliceFrom pos).copy = pat := by
|
||||
rw [isLongestRevMatch_iff_isRevMatch, isRevMatch_iff h]
|
||||
|
||||
theorem isLongestMatchAt_iff {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos} (h : pat ≠ "") :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔ ∃ h, (s.slice pos₁ pos₂ h).copy = pat := by
|
||||
rw [isLongestMatchAt_iff_isLongestMatchAt_toSlice,
|
||||
ForwardSliceSearcher.isLongestMatchAt_iff (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isLongestRevMatchAt_iff {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos} (h : pat ≠ "") :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔ ∃ h, (s.slice pos₁ pos₂ h).copy = pat := by
|
||||
rw [isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice,
|
||||
ForwardSliceSearcher.isLongestRevMatchAt_iff (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isLongestMatchAt_iff_splits {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat ≠ "") :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔
|
||||
@@ -323,14 +197,6 @@ theorem isLongestMatchAt_iff_splits {pat : String} {s : Slice} {pos₁ pos₂ :
|
||||
ForwardSliceSearcher.isLongestMatchAt_iff_splits (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isLongestRevMatchAt_iff_splits {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat ≠ "") :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔
|
||||
∃ t₁ t₂, pos₁.Splits t₁ (pat ++ t₂) ∧ pos₂.Splits (t₁ ++ pat) t₂ := by
|
||||
rw [isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice,
|
||||
ForwardSliceSearcher.isLongestRevMatchAt_iff_splits (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isLongestMatchAt_iff_extract {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat ≠ "") :
|
||||
IsLongestMatchAt pat pos₁ pos₂ ↔
|
||||
@@ -339,14 +205,6 @@ theorem isLongestMatchAt_iff_extract {pat : String} {s : Slice} {pos₁ pos₂ :
|
||||
ForwardSliceSearcher.isLongestMatchAt_iff_extract (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem isLongestRevMatchAt_iff_extract {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat ≠ "") :
|
||||
IsLongestRevMatchAt pat pos₁ pos₂ ↔
|
||||
s.copy.toByteArray.extract pos₁.offset.byteIdx pos₂.offset.byteIdx = pat.toByteArray := by
|
||||
rw [isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice,
|
||||
ForwardSliceSearcher.isLongestRevMatchAt_iff_extract (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem offset_of_isLongestMatchAt {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat ≠ "") (h' : IsLongestMatchAt pat pos₁ pos₂) :
|
||||
pos₂.offset = pos₁.offset.increaseBy pat.utf8ByteSize := by
|
||||
@@ -354,25 +212,12 @@ theorem offset_of_isLongestMatchAt {pat : String} {s : Slice} {pos₁ pos₂ : s
|
||||
exact ForwardSliceSearcher.offset_of_isLongestMatchAt (toSlice_isEmpty h)
|
||||
(isLongestMatchAt_iff_isLongestMatchAt_toSlice.1 h')
|
||||
|
||||
theorem offset_of_isLongestRevMatchAt {pat : String} {s : Slice} {pos₁ pos₂ : s.Pos}
|
||||
(h : pat ≠ "") (h' : IsLongestRevMatchAt pat pos₁ pos₂) :
|
||||
pos₂.offset = pos₁.offset.increaseBy pat.utf8ByteSize := by
|
||||
rw [show pat.utf8ByteSize = pat.toSlice.utf8ByteSize from utf8ByteSize_toSlice.symm]
|
||||
exact ForwardSliceSearcher.offset_of_isLongestRevMatchAt (toSlice_isEmpty h)
|
||||
(isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice.1 h')
|
||||
|
||||
theorem matchesAt_iff_splits {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
MatchesAt pat pos ↔ ∃ t₁ t₂, pos.Splits t₁ (pat ++ t₂) := by
|
||||
rw [matchesAt_iff_toSlice,
|
||||
ForwardSliceSearcher.matchesAt_iff_splits (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem revMatchesAt_iff_splits {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
RevMatchesAt pat pos ↔ ∃ t₁ t₂, pos.Splits (t₁ ++ pat) t₂ := by
|
||||
rw [revMatchesAt_iff_toSlice,
|
||||
ForwardSliceSearcher.revMatchesAt_iff_splits (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem exists_matchesAt_iff_eq_append {pat : String} {s : Slice} (h : pat ≠ "") :
|
||||
(∃ (pos : s.Pos), MatchesAt pat pos) ↔ ∃ t₁ t₂, s.copy = t₁ ++ pat ++ t₂ := by
|
||||
simp only [matchesAt_iff_splits h]
|
||||
@@ -385,14 +230,6 @@ theorem exists_matchesAt_iff_eq_append {pat : String} {s : Slice} (h : pat ≠ "
|
||||
⟨t₁, pat ++ t₂, by rw [← append_assoc]; exact heq, rfl⟩
|
||||
exact ⟨s.pos _ hvalid, t₁, t₂, ⟨by rw [← append_assoc]; exact heq, by simp⟩⟩
|
||||
|
||||
theorem exists_revMatchesAt_iff_eq_append {pat : String} {s : Slice} (h : pat ≠ "") :
|
||||
(∃ (pos : s.Pos), RevMatchesAt pat pos) ↔ ∃ t₁ t₂, s.copy = t₁ ++ pat ++ t₂ := by
|
||||
rw [show (∃ (pos : s.Pos), RevMatchesAt (ρ := String) pat pos) ↔
|
||||
(∃ (pos : s.Pos), RevMatchesAt (ρ := Slice) pat.toSlice pos) from by
|
||||
simp [revMatchesAt_iff_toSlice],
|
||||
ForwardSliceSearcher.exists_revMatchesAt_iff_eq_append (toSlice_isEmpty h)]
|
||||
simp
|
||||
|
||||
theorem matchesAt_iff_isLongestMatchAt {pat : String} {s : Slice} {pos : s.Pos}
|
||||
(h : pat ≠ "") :
|
||||
MatchesAt pat pos ↔ ∃ (h : (pos.offset.increaseBy pat.utf8ByteSize).IsValidForSlice s),
|
||||
@@ -402,16 +239,6 @@ theorem matchesAt_iff_isLongestMatchAt {pat : String} {s : Slice} {pos : s.Pos}
|
||||
simp only [utf8ByteSize_toSlice, ← isLongestMatchAt_iff_isLongestMatchAt_toSlice] at key
|
||||
rwa [matchesAt_iff_toSlice]
|
||||
|
||||
theorem revMatchesAt_iff_isLongestRevMatchAt {pat : String} {s : Slice} {pos : s.Pos}
|
||||
(h : pat ≠ "") :
|
||||
RevMatchesAt pat pos ↔
|
||||
∃ (h : (pos.offset.decreaseBy pat.utf8ByteSize).IsValidForSlice s),
|
||||
IsLongestRevMatchAt pat (s.pos _ h) pos := by
|
||||
have key := ForwardSliceSearcher.revMatchesAt_iff_isLongestRevMatchAt (pat := pat.toSlice)
|
||||
(toSlice_isEmpty h) (pos := pos)
|
||||
simp only [utf8ByteSize_toSlice, ← isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice] at key
|
||||
rwa [revMatchesAt_iff_toSlice]
|
||||
|
||||
theorem matchesAt_iff_getElem {pat : String} {s : Slice} {pos : s.Pos} (h : pat ≠ "") :
|
||||
MatchesAt pat pos ↔
|
||||
∃ (h : pos.offset.byteIdx + pat.toByteArray.size ≤ s.copy.toByteArray.size),
|
||||
@@ -432,11 +259,6 @@ theorem matchesAt_iff_matchesAt_toSlice {pat : String} {s : Slice}
|
||||
{pos : s.Pos} : MatchesAt pat pos ↔ MatchesAt pat.toSlice pos := by
|
||||
simp [matchesAt_iff_exists_isLongestMatchAt, isLongestMatchAt_iff_isLongestMatchAt_toSlice]
|
||||
|
||||
theorem revMatchesAt_iff_revMatchesAt_toSlice {pat : String} {s : Slice}
|
||||
{pos : s.Pos} : RevMatchesAt pat pos ↔ RevMatchesAt pat.toSlice pos := by
|
||||
simp [revMatchesAt_iff_exists_isLongestRevMatchAt,
|
||||
isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice]
|
||||
|
||||
theorem toSearcher_eq {pat : String} {s : Slice} :
|
||||
ToForwardSearcher.toSearcher pat s = ToForwardSearcher.toSearcher pat.toSlice s := (rfl)
|
||||
|
||||
@@ -453,21 +275,6 @@ theorem isValidSearchFrom_iff_isValidSearchFrom_toSlice {pat : String}
|
||||
| matched => simp_all [IsValidSearchFrom.matched, isLongestMatchAt_iff_isLongestMatchAt_toSlice]
|
||||
| mismatched => simp_all [IsValidSearchFrom.mismatched, matchesAt_iff_matchesAt_toSlice]
|
||||
|
||||
theorem isValidRevSearchFrom_iff_isValidRevSearchFrom_toSlice {pat : String}
|
||||
{s : Slice} {pos : s.Pos} {l : List (SearchStep s)} :
|
||||
IsValidRevSearchFrom pat pos l ↔ IsValidRevSearchFrom pat.toSlice pos l := by
|
||||
refine ⟨fun h => ?_, fun h => ?_⟩
|
||||
· induction h with
|
||||
| startPos => simpa using IsValidRevSearchFrom.startPos
|
||||
| matched => simp_all [IsValidRevSearchFrom.matched,
|
||||
isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice]
|
||||
| mismatched => simp_all [IsValidRevSearchFrom.mismatched, revMatchesAt_iff_revMatchesAt_toSlice]
|
||||
· induction h with
|
||||
| startPos => simpa using IsValidRevSearchFrom.startPos
|
||||
| matched => simp_all [IsValidRevSearchFrom.matched,
|
||||
isLongestRevMatchAt_iff_isLongestRevMatchAt_toSlice]
|
||||
| mismatched => simp_all [IsValidRevSearchFrom.mismatched, revMatchesAt_iff_revMatchesAt_toSlice]
|
||||
|
||||
end ForwardStringSearcher
|
||||
|
||||
end String.Slice.Pattern.Model
|
||||
|
||||
@@ -76,12 +76,10 @@ namespace Model.ForwardSliceSearcher
|
||||
|
||||
open Pattern.ForwardSliceSearcher
|
||||
|
||||
public instance {pat : Slice} : LawfulForwardPattern pat where
|
||||
skipPrefixOfNonempty?_eq _ := rfl
|
||||
startsWith_eq _ := isSome_skipPrefix?.symm
|
||||
|
||||
public theorem lawfulForwardPatternModel {pat : Slice} (hpat : pat.isEmpty = false) :
|
||||
LawfulForwardPatternModel pat where
|
||||
skipPrefixOfNonempty?_eq h := rfl
|
||||
startsWith_eq s := isSome_skipPrefix?.symm
|
||||
skipPrefix?_eq_some_iff pos := by
|
||||
simp [ForwardPattern.skipPrefix?, skipPrefix?_eq_some_iff, isLongestMatch_iff hpat]
|
||||
|
||||
@@ -91,116 +89,15 @@ namespace Model.ForwardStringSearcher
|
||||
|
||||
open Pattern.ForwardSliceSearcher
|
||||
|
||||
public instance {pat : String} : LawfulForwardPattern pat where
|
||||
skipPrefixOfNonempty?_eq _ := rfl
|
||||
startsWith_eq _ := isSome_skipPrefix?.symm
|
||||
|
||||
public theorem lawfulForwardPatternModel {pat : String} (hpat : pat ≠ "") :
|
||||
LawfulForwardPatternModel pat where
|
||||
skipPrefixOfNonempty?_eq h := rfl
|
||||
startsWith_eq s := isSome_skipPrefix?.symm
|
||||
skipPrefix?_eq_some_iff pos := by
|
||||
simp [ForwardPattern.skipPrefix?, skipPrefix?_eq_some_iff, isLongestMatch_iff hpat]
|
||||
|
||||
end Model.ForwardStringSearcher
|
||||
|
||||
namespace BackwardSliceSearcher
|
||||
|
||||
theorem endsWith_iff {pat s : Slice} : endsWith pat s ↔ ∃ t, s.copy = t ++ pat.copy := by
|
||||
rw [endsWith]
|
||||
simp [Internal.memcmpSlice_eq_true_iff, utf8ByteSize_eq_size_toByteArray_copy, -size_toByteArray]
|
||||
generalize pat.copy = pat
|
||||
generalize s.copy = s
|
||||
refine ⟨fun ⟨h₁, h₂⟩ => ?_, ?_⟩
|
||||
· rw [Nat.sub_add_cancel h₁] at h₂
|
||||
suffices (s.rawEndPos.unoffsetBy pat.rawEndPos).IsValid s by
|
||||
have h₃ : (s.sliceFrom (s.pos _ this)).copy = pat := by
|
||||
rw [← toByteArray_inj, (s.pos _ this).splits.toByteArray_right_eq]
|
||||
simpa [offset_pos, Pos.Raw.byteIdx_unoffsetBy, byteIdx_rawEndPos]
|
||||
have := (s.pos _ this).splits
|
||||
rw [h₃] at this
|
||||
exact ⟨_, this.eq_append⟩
|
||||
rw [Pos.Raw.isValid_iff_isValidUTF8_extract_utf8ByteSize]
|
||||
refine ⟨by simp [Pos.Raw.le_iff, Pos.Raw.byteIdx_unoffsetBy], ?_⟩
|
||||
simp only [size_toByteArray] at h₂
|
||||
simpa [Pos.Raw.byteIdx_unoffsetBy, byteIdx_rawEndPos, h₂] using pat.isValidUTF8
|
||||
· rintro ⟨t, rfl⟩
|
||||
exact ⟨by simp, by rw [Nat.sub_add_cancel (by simp)]; exact
|
||||
ByteArray.extract_append_eq_right (by simp) (by simp)⟩
|
||||
|
||||
theorem skipSuffix?_eq_some_iff {pat s : Slice} {pos : s.Pos} :
|
||||
skipSuffix? pat s = some pos ↔ (s.sliceFrom pos).copy = pat.copy := by
|
||||
fun_cases skipSuffix? with
|
||||
| case1 h =>
|
||||
simp only [Option.some.injEq]
|
||||
obtain ⟨t, ht⟩ := endsWith_iff.1 h
|
||||
have hpc : pat.copy.utf8ByteSize = pat.utf8ByteSize := Slice.utf8ByteSize_copy
|
||||
have hsz : s.utf8ByteSize = t.utf8ByteSize + pat.utf8ByteSize := by
|
||||
have := congrArg String.utf8ByteSize ht
|
||||
simp only [utf8ByteSize_append, Slice.utf8ByteSize_copy] at this
|
||||
exact this
|
||||
have hoff : (s.endPos.offset.unoffsetBy pat.rawEndPos) = t.rawEndPos := by
|
||||
ext
|
||||
simp only [offset_endPos, Pos.Raw.byteIdx_unoffsetBy, byteIdx_rawEndPos,
|
||||
String.byteIdx_rawEndPos]
|
||||
omega
|
||||
have hval : (s.endPos.offset.unoffsetBy pat.rawEndPos).IsValidForSlice s :=
|
||||
Pos.Raw.isValidForSlice_iff_exists_append.mpr ⟨t, pat.copy, ht, hoff⟩
|
||||
have hsp : (s.pos _ hval).Splits t pat.copy := ⟨ht, hoff⟩
|
||||
rw [Slice.pos!_eq_pos hval]
|
||||
exact ⟨(· ▸ hsp.copy_sliceFrom_eq),
|
||||
fun h => hsp.pos_eq_of_eq_right (h ▸ pos.splits)⟩
|
||||
| case2 h =>
|
||||
simp only [endsWith_iff, not_exists] at h
|
||||
simp only [reduceCtorEq, false_iff]
|
||||
intro heq
|
||||
have := h (s.sliceTo pos).copy
|
||||
simp [← heq, pos.splits.eq_append] at this
|
||||
|
||||
theorem isSome_skipSuffix? {pat s : Slice} : (skipSuffix? pat s).isSome = endsWith pat s := by
|
||||
fun_cases skipSuffix? <;> simp_all
|
||||
|
||||
public theorem endsWith_of_isEmpty {pat s : Slice} (hpat : pat.isEmpty = true) :
|
||||
BackwardPattern.endsWith pat s = true := by
|
||||
suffices pat.copy = "" by simp [BackwardPattern.endsWith, endsWith_iff, this]
|
||||
simpa
|
||||
|
||||
public theorem skipSuffix?_of_isEmpty {pat s : Slice} (hpat : pat.isEmpty = true) :
|
||||
BackwardPattern.skipSuffix? pat s = some s.endPos := by
|
||||
simpa [BackwardPattern.skipSuffix?, skipSuffix?_eq_some_iff]
|
||||
|
||||
end BackwardSliceSearcher
|
||||
|
||||
namespace Model.BackwardSliceSearcher
|
||||
|
||||
open Pattern.BackwardSliceSearcher
|
||||
|
||||
public instance {pat : Slice} : LawfulBackwardPattern pat where
|
||||
skipSuffixOfNonempty?_eq _ := rfl
|
||||
endsWith_eq _ := isSome_skipSuffix?.symm
|
||||
|
||||
public theorem lawfulBackwardPatternModel {pat : Slice} (hpat : pat.isEmpty = false) :
|
||||
LawfulBackwardPatternModel pat where
|
||||
skipSuffix?_eq_some_iff pos := by
|
||||
simp [BackwardPattern.skipSuffix?, skipSuffix?_eq_some_iff,
|
||||
ForwardSliceSearcher.isLongestRevMatch_iff hpat]
|
||||
|
||||
end Model.BackwardSliceSearcher
|
||||
|
||||
namespace Model.BackwardStringSearcher
|
||||
|
||||
open Pattern.BackwardSliceSearcher
|
||||
|
||||
public instance {pat : String} : LawfulBackwardPattern pat where
|
||||
skipSuffixOfNonempty?_eq _ := rfl
|
||||
endsWith_eq _ := isSome_skipSuffix?.symm
|
||||
|
||||
public theorem lawfulBackwardPatternModel {pat : String} (hpat : pat ≠ "") :
|
||||
LawfulBackwardPatternModel pat where
|
||||
skipSuffix?_eq_some_iff pos := by
|
||||
simp [BackwardPattern.skipSuffix?, skipSuffix?_eq_some_iff,
|
||||
ForwardStringSearcher.isLongestRevMatch_iff hpat]
|
||||
|
||||
end Model.BackwardStringSearcher
|
||||
|
||||
end Pattern
|
||||
|
||||
public theorem startsWith_string_eq_startsWith_toSlice {pat : String} {s : Slice} :
|
||||
|
||||
@@ -29,12 +29,12 @@ theorem startsWith_eq_forwardPatternStartsWith {ρ : Type} {pat : ρ} [ForwardPa
|
||||
theorem dropPrefix?_eq_map_skipPrefix? {ρ : Type} {pat : ρ} [ForwardPattern pat] {s : Slice} :
|
||||
s.dropPrefix? pat = (s.skipPrefix? pat).map s.sliceFrom := (rfl)
|
||||
|
||||
theorem Pattern.Model.skipPrefix?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel pat] [ForwardPattern pat]
|
||||
theorem Pattern.Model.skipPrefix?_eq_some_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat] [ForwardPattern pat]
|
||||
[LawfulForwardPatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
s.skipPrefix? pat = some pos ↔ IsLongestMatch pat pos := by
|
||||
rw [skipPrefix?_eq_forwardPatternSkipPrefix?, LawfulForwardPatternModel.skipPrefix?_eq_some_iff]
|
||||
|
||||
theorem Pattern.Model.skipPrefix?_eq_none_iff {ρ : Type} {pat : ρ} [PatternModel pat] [ForwardPattern pat]
|
||||
theorem Pattern.Model.skipPrefix?_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat] [ForwardPattern pat]
|
||||
[LawfulForwardPatternModel pat] {s : Slice} :
|
||||
s.skipPrefix? pat = none ↔ ¬ MatchesAt pat s.startPos := by
|
||||
rw [skipPrefix?_eq_forwardPatternSkipPrefix?, LawfulForwardPatternModel.skipPrefix?_eq_none_iff]
|
||||
@@ -44,13 +44,13 @@ theorem isSome_skipPrefix? {ρ : Type} {pat : ρ} [ForwardPattern pat] [LawfulFo
|
||||
(s.skipPrefix? pat).isSome = s.startsWith pat := by
|
||||
rw [startsWith_eq_forwardPatternStartsWith, skipPrefix?, LawfulForwardPattern.startsWith_eq]
|
||||
|
||||
theorem Pattern.Model.startsWith_eq_false_iff {ρ : Type} {pat : ρ} [PatternModel pat] [ForwardPattern pat]
|
||||
theorem Pattern.Model.startsWith_eq_false_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat] [ForwardPattern pat]
|
||||
[LawfulForwardPatternModel pat] {s : Slice} :
|
||||
s.startsWith pat = false ↔ ¬ MatchesAt pat s.startPos := by
|
||||
rw [← Pattern.Model.skipPrefix?_eq_none_iff, ← Option.isNone_iff_eq_none,
|
||||
← isSome_skipPrefix?, Option.isSome_eq_false_iff]
|
||||
|
||||
theorem Pattern.Model.startsWith_iff {ρ : Type} {pat : ρ} [PatternModel pat] [ForwardPattern pat]
|
||||
theorem Pattern.Model.startsWith_iff {ρ : Type} {pat : ρ} [ForwardPatternModel pat] [ForwardPattern pat]
|
||||
[LawfulForwardPatternModel pat] {s : Slice} :
|
||||
s.startsWith pat = true ↔ MatchesAt pat s.startPos := by
|
||||
rw [← Bool.not_eq_false, startsWith_eq_false_iff, Classical.not_not]
|
||||
@@ -65,65 +65,13 @@ theorem dropPrefix?_eq_none_iff {ρ : Type} {pat : ρ} [ForwardPattern pat] [Law
|
||||
{s : Slice} : s.dropPrefix? pat = none ↔ s.startsWith pat = false := by
|
||||
simp [dropPrefix?_eq_map_skipPrefix?]
|
||||
|
||||
theorem Pattern.Model.eq_append_of_dropPrefix?_eq_some {ρ : Type} {pat : ρ} [PatternModel pat] [ForwardPattern pat]
|
||||
theorem Pattern.Model.eq_append_of_dropPrefix?_eq_some {ρ : Type} {pat : ρ} [ForwardPatternModel pat] [ForwardPattern pat]
|
||||
[LawfulForwardPatternModel pat] {s res : Slice} (h : s.dropPrefix? pat = some res) :
|
||||
∃ t, PatternModel.Matches pat t ∧ s.copy = t ++ res.copy := by
|
||||
∃ t, ForwardPatternModel.Matches pat t ∧ s.copy = t ++ res.copy := by
|
||||
simp only [dropPrefix?_eq_map_skipPrefix?, Option.map_eq_some_iff, skipPrefix?_eq_some_iff] at h
|
||||
obtain ⟨pos, h₁, h₂⟩ := h
|
||||
exact ⟨(s.sliceTo pos).copy, h₁.isMatch.matches_copy, by simp [← h₂, ← copy_eq_copy_sliceTo]⟩
|
||||
|
||||
theorem skipSuffix?_eq_backwardPatternSkipSuffix? {ρ : Type} {pat : ρ} [BackwardPattern pat] {s : Slice} :
|
||||
s.skipSuffix? pat = BackwardPattern.skipSuffix? pat s := (rfl)
|
||||
|
||||
theorem endsWith_eq_backwardPatternEndsWith {ρ : Type} {pat : ρ} [BackwardPattern pat] {s : Slice} :
|
||||
s.endsWith pat = BackwardPattern.endsWith pat s := (rfl)
|
||||
|
||||
theorem dropSuffix?_eq_map_skipSuffix? {ρ : Type} {pat : ρ} [BackwardPattern pat] {s : Slice} :
|
||||
s.dropSuffix? pat = (s.skipSuffix? pat).map s.sliceTo := (rfl)
|
||||
|
||||
theorem Pattern.Model.skipSuffix?_eq_some_iff {ρ : Type} {pat : ρ} [PatternModel pat] [BackwardPattern pat]
|
||||
[LawfulBackwardPatternModel pat] {s : Slice} {pos : s.Pos} :
|
||||
s.skipSuffix? pat = some pos ↔ IsLongestRevMatch pat pos := by
|
||||
rw [skipSuffix?_eq_backwardPatternSkipSuffix?, LawfulBackwardPatternModel.skipSuffix?_eq_some_iff]
|
||||
|
||||
theorem Pattern.Model.skipSuffix?_eq_none_iff {ρ : Type} {pat : ρ} [PatternModel pat] [BackwardPattern pat]
|
||||
[LawfulBackwardPatternModel pat] {s : Slice} :
|
||||
s.skipSuffix? pat = none ↔ ¬ RevMatchesAt pat s.endPos := by
|
||||
rw [skipSuffix?_eq_backwardPatternSkipSuffix?, LawfulBackwardPatternModel.skipSuffix?_eq_none_iff]
|
||||
|
||||
@[simp]
|
||||
theorem isSome_skipSuffix? {ρ : Type} {pat : ρ} [BackwardPattern pat] [LawfulBackwardPattern pat] {s : Slice} :
|
||||
(s.skipSuffix? pat).isSome = s.endsWith pat := by
|
||||
rw [endsWith_eq_backwardPatternEndsWith, skipSuffix?, LawfulBackwardPattern.endsWith_eq]
|
||||
|
||||
theorem Pattern.Model.endsWith_eq_false_iff {ρ : Type} {pat : ρ} [PatternModel pat] [BackwardPattern pat]
|
||||
[LawfulBackwardPatternModel pat] {s : Slice} :
|
||||
s.endsWith pat = false ↔ ¬ RevMatchesAt pat s.endPos := by
|
||||
rw [← Pattern.Model.skipSuffix?_eq_none_iff, ← Option.isNone_iff_eq_none,
|
||||
← isSome_skipSuffix?, Option.isSome_eq_false_iff]
|
||||
|
||||
theorem Pattern.Model.endsWith_iff {ρ : Type} {pat : ρ} [PatternModel pat] [BackwardPattern pat]
|
||||
[LawfulBackwardPatternModel pat] {s : Slice} :
|
||||
s.endsWith pat = true ↔ RevMatchesAt pat s.endPos := by
|
||||
rw [← Bool.not_eq_false, endsWith_eq_false_iff, Classical.not_not]
|
||||
|
||||
@[simp]
|
||||
theorem skipSuffix?_eq_none_iff {ρ : Type} {pat : ρ} [BackwardPattern pat] [LawfulBackwardPattern pat]
|
||||
{s : Slice} : s.skipSuffix? pat = none ↔ s.endsWith pat = false := by
|
||||
rw [← Option.isNone_iff_eq_none, ← Option.isSome_eq_false_iff, isSome_skipSuffix?]
|
||||
|
||||
@[simp]
|
||||
theorem dropSuffix?_eq_none_iff {ρ : Type} {pat : ρ} [BackwardPattern pat] [LawfulBackwardPattern pat]
|
||||
{s : Slice} : s.dropSuffix? pat = none ↔ s.endsWith pat = false := by
|
||||
simp [dropSuffix?_eq_map_skipSuffix?]
|
||||
|
||||
theorem Pattern.Model.eq_append_of_dropSuffix?_eq_some {ρ : Type} {pat : ρ} [PatternModel pat] [BackwardPattern pat]
|
||||
[LawfulBackwardPatternModel pat] {s res : Slice} (h : s.dropSuffix? pat = some res) :
|
||||
∃ t, PatternModel.Matches pat t ∧ s.copy = res.copy ++ t := by
|
||||
simp only [dropSuffix?_eq_map_skipSuffix?, Option.map_eq_some_iff, skipSuffix?_eq_some_iff] at h
|
||||
obtain ⟨pos, h₁, h₂⟩ := h
|
||||
exact ⟨(s.sliceFrom pos).copy, h₁.isRevMatch.matches_copy, by simp [← h₂, ← copy_eq_copy_sliceTo]⟩
|
||||
|
||||
end Slice
|
||||
|
||||
theorem skipPrefix?_eq_skipPrefix?_toSlice {ρ : Type} {pat : ρ} [ForwardPattern pat] {s : String} :
|
||||
@@ -135,13 +83,4 @@ theorem startsWith_eq_startsWith_toSlice {ρ : Type} {pat : ρ} [ForwardPattern
|
||||
theorem dropPrefix?_eq_dropPrefix?_toSlice {ρ : Type} {pat : ρ} [ForwardPattern pat] {s : String} :
|
||||
s.dropPrefix? pat = s.toSlice.dropPrefix? pat := (rfl)
|
||||
|
||||
theorem skipSuffix?_eq_skipSuffix?_toSlice {ρ : Type} {pat : ρ} [BackwardPattern pat] {s : String} :
|
||||
s.skipSuffix? pat = (s.toSlice.skipSuffix? pat).map Pos.ofToSlice := (rfl)
|
||||
|
||||
theorem endsWith_eq_endsWith_toSlice {ρ : Type} {pat : ρ} [BackwardPattern pat] {s : String} :
|
||||
s.endsWith pat = s.toSlice.endsWith pat := (rfl)
|
||||
|
||||
theorem dropSuffix?_eq_dropSuffix?_toSlice {ρ : Type} {pat : ρ} [BackwardPattern pat] {s : String} :
|
||||
s.dropSuffix? pat = s.toSlice.dropSuffix? pat := (rfl)
|
||||
|
||||
end String
|
||||
|
||||
@@ -11,8 +11,6 @@ public import Init.Data.String.TakeDrop
|
||||
import Init.Data.String.Lemmas.Pattern.TakeDrop.Basic
|
||||
import Init.Data.String.Lemmas.Pattern.Char
|
||||
import Init.Data.Option.Lemmas
|
||||
import Init.Data.String.Lemmas.FindPos
|
||||
import Init.Data.List.Sublist
|
||||
|
||||
public section
|
||||
|
||||
@@ -54,42 +52,7 @@ theorem startsWith_char_eq_false_iff_forall_append {c : Char} {s : Slice} :
|
||||
|
||||
theorem eq_append_of_dropPrefix?_char_eq_some {c : Char} {s res : Slice} (h : s.dropPrefix? c = some res) :
|
||||
s.copy = singleton c ++ res.copy := by
|
||||
simpa [PatternModel.Matches] using Pattern.Model.eq_append_of_dropPrefix?_eq_some h
|
||||
|
||||
theorem skipSuffix?_char_eq_some_iff {c : Char} {s : Slice} {pos : s.Pos} :
|
||||
s.skipSuffix? c = some pos ↔ ∃ h, pos = s.endPos.prev h ∧ (s.endPos.prev h).get (by simp) = c := by
|
||||
rw [Pattern.Model.skipSuffix?_eq_some_iff, Char.isLongestRevMatch_iff]
|
||||
|
||||
theorem endsWith_char_iff_get {c : Char} {s : Slice} :
|
||||
s.endsWith c ↔ ∃ h, (s.endPos.prev h).get (by simp) = c := by
|
||||
simp [Pattern.Model.endsWith_iff, Char.revMatchesAt_iff]
|
||||
|
||||
theorem endsWith_char_eq_false_iff_get {c : Char} {s : Slice} :
|
||||
s.endsWith c = false ↔ ∀ h, (s.endPos.prev h).get (by simp) ≠ c := by
|
||||
simp [Pattern.Model.endsWith_eq_false_iff, Char.revMatchesAt_iff]
|
||||
|
||||
theorem endsWith_char_iff_exists_append {c : Char} {s : Slice} :
|
||||
s.endsWith c ↔ ∃ t, s.copy = t ++ singleton c := by
|
||||
rw [Pattern.Model.endsWith_iff, Char.revMatchesAt_iff_splits]
|
||||
simp only [splits_endPos_iff, exists_eq_right, eq_comm (a := s.copy)]
|
||||
|
||||
theorem endsWith_char_eq_getLast? {c : Char} {s : Slice} :
|
||||
s.endsWith c = (s.copy.toList.getLast? == some c) := by
|
||||
rw [Bool.eq_iff_iff, endsWith_char_iff_exists_append, beq_iff_eq,
|
||||
← List.singleton_suffix_iff_getLast?_eq_some, List.suffix_iff_exists_eq_append]
|
||||
constructor
|
||||
· rintro ⟨t, ht⟩
|
||||
exact ⟨t.toList, by rw [ht, toList_append, toList_singleton]⟩
|
||||
· rintro ⟨l, hl⟩
|
||||
exact ⟨ofList l, by rw [← toList_inj, toList_append, toList_singleton, toList_ofList]; exact hl⟩
|
||||
|
||||
theorem endsWith_char_eq_false_iff_forall_append {c : Char} {s : Slice} :
|
||||
s.endsWith c = false ↔ ∀ t, s.copy ≠ t ++ singleton c := by
|
||||
simp [← Bool.not_eq_true, endsWith_char_iff_exists_append]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_char_eq_some {c : Char} {s res : Slice} (h : s.dropSuffix? c = some res) :
|
||||
s.copy = res.copy ++ singleton c := by
|
||||
simpa [PatternModel.Matches] using Pattern.Model.eq_append_of_dropSuffix?_eq_some h
|
||||
simpa [ForwardPatternModel.Matches] using Pattern.Model.eq_append_of_dropPrefix?_eq_some h
|
||||
|
||||
end Slice
|
||||
|
||||
@@ -123,34 +86,4 @@ theorem eq_append_of_dropPrefix?_char_eq_some {c : Char} {s : String} {res : Sli
|
||||
rw [dropPrefix?_eq_dropPrefix?_toSlice] at h
|
||||
simpa using Slice.eq_append_of_dropPrefix?_char_eq_some h
|
||||
|
||||
theorem skipSuffix?_char_eq_some_iff {c : Char} {s : String} {pos : s.Pos} :
|
||||
s.skipSuffix? c = some pos ↔ ∃ h, pos = s.endPos.prev h ∧ (s.endPos.prev h).get (by simp) = c := by
|
||||
simp [skipSuffix?_eq_skipSuffix?_toSlice, Slice.skipSuffix?_char_eq_some_iff, ← Pos.toSlice_inj,
|
||||
Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_char_iff_get {c : Char} {s : String} :
|
||||
s.endsWith c ↔ ∃ h, (s.endPos.prev h).get (by simp) = c := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_char_iff_get, Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_char_eq_false_iff_get {c : Char} {s : String} :
|
||||
s.endsWith c = false ↔ ∀ h, (s.endPos.prev h).get (by simp) ≠ c := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_char_eq_false_iff_get, Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_char_eq_getLast? {c : Char} {s : String} :
|
||||
s.endsWith c = (s.toList.getLast? == some c) := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_char_eq_getLast?]
|
||||
|
||||
theorem endsWith_char_iff_exists_append {c : Char} {s : String} :
|
||||
s.endsWith c ↔ ∃ t, s = t ++ singleton c := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_char_iff_exists_append]
|
||||
|
||||
theorem endsWith_char_eq_false_iff_forall_append {c : Char} {s : String} :
|
||||
s.endsWith c = false ↔ ∀ t, s ≠ t ++ singleton c := by
|
||||
simp [← Bool.not_eq_true, endsWith_char_iff_exists_append]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_char_eq_some {c : Char} {s : String} {res : Slice} (h : s.dropSuffix? c = some res) :
|
||||
s = res.copy ++ singleton c := by
|
||||
rw [dropSuffix?_eq_dropSuffix?_toSlice] at h
|
||||
simpa using Slice.eq_append_of_dropSuffix?_char_eq_some h
|
||||
|
||||
end String
|
||||
|
||||
@@ -11,7 +11,6 @@ public import Init.Data.String.TakeDrop
|
||||
import Init.Data.String.Lemmas.Pattern.TakeDrop.Basic
|
||||
import Init.Data.String.Lemmas.Pattern.Pred
|
||||
import Init.Data.Option.Lemmas
|
||||
import Init.Data.String.Lemmas.FindPos
|
||||
import Init.ByCases
|
||||
|
||||
public section
|
||||
@@ -46,7 +45,7 @@ theorem startsWith_bool_eq_head? {p : Char → Bool} {s : Slice} :
|
||||
|
||||
theorem eq_append_of_dropPrefix?_bool_eq_some {p : Char → Bool} {s res : Slice} (h : s.dropPrefix? p = some res) :
|
||||
∃ c, s.copy = singleton c ++ res.copy ∧ p c = true := by
|
||||
obtain ⟨_, ⟨c, ⟨rfl, h₁⟩⟩, h₂⟩ := by simpa [PatternModel.Matches] using Pattern.Model.eq_append_of_dropPrefix?_eq_some h
|
||||
obtain ⟨_, ⟨c, ⟨rfl, h₁⟩⟩, h₂⟩ := by simpa [ForwardPatternModel.Matches] using Pattern.Model.eq_append_of_dropPrefix?_eq_some h
|
||||
exact ⟨_, h₂, h₁⟩
|
||||
|
||||
theorem skipPrefix?_prop_eq_some_iff {P : Char → Prop} [DecidablePred P] {s : Slice} {pos : s.Pos} :
|
||||
@@ -70,54 +69,6 @@ theorem eq_append_of_dropPrefix_prop_eq_some {P : Char → Prop} [DecidablePred
|
||||
rw [dropPrefix?_prop_eq_dropPrefix?_decide] at h
|
||||
simpa using eq_append_of_dropPrefix?_bool_eq_some h
|
||||
|
||||
theorem skipSuffix?_bool_eq_some_iff {p : Char → Bool} {s : Slice} {pos : s.Pos} :
|
||||
s.skipSuffix? p = some pos ↔ ∃ h, pos = s.endPos.prev h ∧ p ((s.endPos.prev h).get (by simp)) = true := by
|
||||
rw [Pattern.Model.skipSuffix?_eq_some_iff, CharPred.isLongestRevMatch_iff]
|
||||
|
||||
theorem endsWith_bool_iff_get {p : Char → Bool} {s : Slice} :
|
||||
s.endsWith p ↔ ∃ h, p ((s.endPos.prev h).get (by simp)) = true := by
|
||||
simp [Pattern.Model.endsWith_iff, CharPred.revMatchesAt_iff]
|
||||
|
||||
theorem endsWith_bool_eq_false_iff_get {p : Char → Bool} {s : Slice} :
|
||||
s.endsWith p = false ↔ ∀ h, p ((s.endPos.prev h).get (by simp)) = false := by
|
||||
simp [Pattern.Model.endsWith_eq_false_iff, CharPred.revMatchesAt_iff]
|
||||
|
||||
theorem endsWith_bool_eq_getLast? {p : Char → Bool} {s : Slice} :
|
||||
s.endsWith p = s.copy.toList.getLast?.any p := by
|
||||
rw [Bool.eq_iff_iff, Pattern.Model.endsWith_iff, CharPred.revMatchesAt_iff]
|
||||
by_cases h : s.endPos = s.startPos
|
||||
· refine ⟨fun ⟨h', _⟩ => by simp_all, ?_⟩
|
||||
have : s.copy = "" := by simp_all [Slice.startPos_eq_endPos_iff.mp h.symm]
|
||||
simp [this]
|
||||
· obtain ⟨t, ht⟩ := s.splits_endPos.exists_eq_append_singleton_of_ne_startPos h
|
||||
simp [h, ht]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_bool_eq_some {p : Char → Bool} {s res : Slice} (h : s.dropSuffix? p = some res) :
|
||||
∃ c, s.copy = res.copy ++ singleton c ∧ p c = true := by
|
||||
obtain ⟨_, ⟨c, ⟨rfl, h₁⟩⟩, h₂⟩ := by simpa [PatternModel.Matches] using Pattern.Model.eq_append_of_dropSuffix?_eq_some h
|
||||
exact ⟨_, h₂, h₁⟩
|
||||
|
||||
theorem skipSuffix?_prop_eq_some_iff {P : Char → Prop} [DecidablePred P] {s : Slice} {pos : s.Pos} :
|
||||
s.skipSuffix? P = some pos ↔ ∃ h, pos = s.endPos.prev h ∧ P ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [skipSuffix?_prop_eq_skipSuffix?_decide, skipSuffix?_bool_eq_some_iff]
|
||||
|
||||
theorem endsWith_prop_iff_get {P : Char → Prop} [DecidablePred P] {s : Slice} :
|
||||
s.endsWith P ↔ ∃ h, P ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [endsWith_prop_eq_endsWith_decide, endsWith_bool_iff_get]
|
||||
|
||||
theorem endsWith_prop_eq_false_iff_get {P : Char → Prop} [DecidablePred P] {s : Slice} :
|
||||
s.endsWith P = false ↔ ∀ h, ¬ P ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [endsWith_prop_eq_endsWith_decide, endsWith_bool_eq_false_iff_get]
|
||||
|
||||
theorem endsWith_prop_eq_getLast? {P : Char → Prop} [DecidablePred P] {s : Slice} :
|
||||
s.endsWith P = s.copy.toList.getLast?.any (decide <| P ·) := by
|
||||
simp [endsWith_prop_eq_endsWith_decide, endsWith_bool_eq_getLast?]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_prop_eq_some {P : Char → Prop} [DecidablePred P] {s res : Slice} (h : s.dropSuffix? P = some res) :
|
||||
∃ c, s.copy = res.copy ++ singleton c ∧ P c := by
|
||||
rw [dropSuffix?_prop_eq_dropSuffix?_decide] at h
|
||||
simpa using eq_append_of_dropSuffix?_bool_eq_some h
|
||||
|
||||
end Slice
|
||||
|
||||
theorem skipPrefix?_bool_eq_some_iff {p : Char → Bool} {s : String} {pos : s.Pos} :
|
||||
@@ -164,48 +115,4 @@ theorem eq_append_of_dropPrefix?_prop_eq_some {P : Char → Prop} [DecidablePred
|
||||
rw [dropPrefix?_eq_dropPrefix?_toSlice] at h
|
||||
simpa using Slice.eq_append_of_dropPrefix_prop_eq_some h
|
||||
|
||||
theorem skipSuffix?_bool_eq_some_iff {p : Char → Bool} {s : String} {pos : s.Pos} :
|
||||
s.skipSuffix? p = some pos ↔ ∃ h, pos = s.endPos.prev h ∧ p ((s.endPos.prev h).get (by simp)) = true := by
|
||||
simp [skipSuffix?_eq_skipSuffix?_toSlice, Slice.skipSuffix?_bool_eq_some_iff, ← Pos.toSlice_inj,
|
||||
Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_bool_iff_get {p : Char → Bool} {s : String} :
|
||||
s.endsWith p ↔ ∃ h, p ((s.endPos.prev h).get (by simp)) = true := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_bool_iff_get, Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_bool_eq_false_iff_get {p : Char → Bool} {s : String} :
|
||||
s.endsWith p = false ↔ ∀ h, p ((s.endPos.prev h).get (by simp)) = false := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_bool_eq_false_iff_get, Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_bool_eq_getLast? {p : Char → Bool} {s : String} :
|
||||
s.endsWith p = s.toList.getLast?.any p := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_bool_eq_getLast?]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_bool_eq_some {p : Char → Bool} {s : String} {res : Slice} (h : s.dropSuffix? p = some res) :
|
||||
∃ c, s = res.copy ++ singleton c ∧ p c = true := by
|
||||
rw [dropSuffix?_eq_dropSuffix?_toSlice] at h
|
||||
simpa using Slice.eq_append_of_dropSuffix?_bool_eq_some h
|
||||
|
||||
theorem skipSuffix?_prop_eq_some_iff {P : Char → Prop} [DecidablePred P] {s : String} {pos : s.Pos} :
|
||||
s.skipSuffix? P = some pos ↔ ∃ h, pos = s.endPos.prev h ∧ P ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [skipSuffix?_eq_skipSuffix?_toSlice, Slice.skipSuffix?_prop_eq_some_iff, ← Pos.toSlice_inj,
|
||||
Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_prop_iff_get {P : Char → Prop} [DecidablePred P] {s : String} :
|
||||
s.endsWith P ↔ ∃ h, P ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_prop_iff_get, Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_prop_eq_false_iff_get {P : Char → Prop} [DecidablePred P] {s : String} :
|
||||
s.endsWith P = false ↔ ∀ h, ¬ P ((s.endPos.prev h).get (by simp)) := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_prop_eq_false_iff_get, Pos.prev_toSlice]
|
||||
|
||||
theorem endsWith_prop_eq_getLast? {P : Char → Prop} [DecidablePred P] {s : String} :
|
||||
s.endsWith P = s.toList.getLast?.any (decide <| P ·) := by
|
||||
simp [endsWith_eq_endsWith_toSlice, Slice.endsWith_prop_eq_getLast?]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_prop_eq_some {P : Char → Prop} [DecidablePred P] {s : String} {res : Slice}
|
||||
(h : s.dropSuffix? P = some res) : ∃ c, s = res.copy ++ singleton c ∧ P c := by
|
||||
rw [dropSuffix?_eq_dropSuffix?_toSlice] at h
|
||||
simpa using Slice.eq_append_of_dropSuffix?_prop_eq_some h
|
||||
|
||||
end String
|
||||
|
||||
@@ -67,7 +67,7 @@ theorem eq_append_of_dropPrefix?_slice_eq_some {pat s res : Slice} (h : s.dropPr
|
||||
| false =>
|
||||
have := ForwardSliceSearcher.lawfulForwardPatternModel hpat
|
||||
have := Pattern.Model.eq_append_of_dropPrefix?_eq_some h
|
||||
simp only [PatternModel.Matches] at this
|
||||
simp only [ForwardPatternModel.Matches] at this
|
||||
obtain ⟨_, ⟨-, rfl⟩, h⟩ := this
|
||||
exact h
|
||||
| true => simp [Option.some.inj (h ▸ dropPrefix?_slice_of_isEmpty hpat), (show pat.copy = "" by simpa)]
|
||||
@@ -104,87 +104,6 @@ theorem eq_append_of_dropPrefix?_string_eq_some {pat : String} {s res : Slice} (
|
||||
rw [dropPrefix?_string_eq_dropPrefix?_toSlice] at h
|
||||
simpa using eq_append_of_dropPrefix?_slice_eq_some h
|
||||
|
||||
theorem skipSuffix?_slice_of_isEmpty {pat s : Slice} (hpat : pat.isEmpty = true) :
|
||||
s.skipSuffix? pat = some s.endPos := by
|
||||
rw [skipSuffix?_eq_backwardPatternSkipSuffix?, BackwardSliceSearcher.skipSuffix?_of_isEmpty hpat]
|
||||
|
||||
@[simp]
|
||||
theorem skipSuffix?_slice_eq_some_iff {pat s : Slice} {pos : s.Pos} :
|
||||
s.skipSuffix? pat = some pos ↔ ∃ t, pos.Splits t pat.copy := by
|
||||
match h : pat.isEmpty with
|
||||
| false =>
|
||||
have := BackwardSliceSearcher.lawfulBackwardPatternModel h
|
||||
rw [Pattern.Model.skipSuffix?_eq_some_iff, ForwardSliceSearcher.isLongestRevMatch_iff_splits h]
|
||||
| true => simp [skipSuffix?_slice_of_isEmpty h, (show pat.copy = "" by simpa), eq_comm]
|
||||
|
||||
theorem endsWith_slice_of_isEmpty {pat s : Slice} (hpat : pat.isEmpty = true) :
|
||||
s.endsWith pat = true := by
|
||||
rw [endsWith_eq_backwardPatternEndsWith, BackwardSliceSearcher.endsWith_of_isEmpty hpat]
|
||||
|
||||
@[simp]
|
||||
theorem endsWith_slice_iff {pat s : Slice} :
|
||||
s.endsWith pat ↔ pat.copy.toList <:+ s.copy.toList := by
|
||||
match h : pat.isEmpty with
|
||||
| false =>
|
||||
have := BackwardSliceSearcher.lawfulBackwardPatternModel h
|
||||
simp only [Model.endsWith_iff, ForwardSliceSearcher.revMatchesAt_iff_splits h,
|
||||
splits_endPos_iff, exists_eq_right]
|
||||
simp only [← toList_inj, toList_append, List.suffix_iff_exists_append_eq]
|
||||
exact ⟨fun ⟨t, ht⟩ => ⟨t.toList, by simp [ht]⟩, fun ⟨t, ht⟩ => ⟨String.ofList t, by simp [← ht]⟩⟩
|
||||
| true => simp [endsWith_slice_of_isEmpty h, (show pat.copy = "" by simpa)]
|
||||
|
||||
@[simp]
|
||||
theorem endsWith_slice_eq_false_iff {pat s : Slice} :
|
||||
s.endsWith pat = false ↔ ¬ (pat.copy.toList <:+ s.copy.toList) := by
|
||||
simp [← Bool.not_eq_true, endsWith_slice_iff]
|
||||
|
||||
theorem dropSuffix?_slice_of_isEmpty {pat s : Slice} (hpat : pat.isEmpty = true) :
|
||||
s.dropSuffix? pat = some s := by
|
||||
simp [dropSuffix?_eq_map_skipSuffix?, skipSuffix?_slice_of_isEmpty hpat]
|
||||
|
||||
theorem eq_append_of_dropSuffix?_slice_eq_some {pat s res : Slice} (h : s.dropSuffix? pat = some res) :
|
||||
s.copy = res.copy ++ pat.copy := by
|
||||
match hpat : pat.isEmpty with
|
||||
| false =>
|
||||
have := BackwardSliceSearcher.lawfulBackwardPatternModel hpat
|
||||
have := Pattern.Model.eq_append_of_dropSuffix?_eq_some h
|
||||
simp only [PatternModel.Matches] at this
|
||||
obtain ⟨_, ⟨-, rfl⟩, h⟩ := this
|
||||
exact h
|
||||
| true => simp [Option.some.inj (h ▸ dropSuffix?_slice_of_isEmpty hpat), (show pat.copy = "" by simpa)]
|
||||
|
||||
@[simp]
|
||||
theorem skipSuffix?_string_eq_some_iff' {pat : String} {s : Slice} {pos : s.Pos} :
|
||||
s.skipSuffix? pat = some pos ↔ ∃ t, pos.Splits t pat := by
|
||||
simp [skipSuffix?_string_eq_skipSuffix?_toSlice]
|
||||
|
||||
@[simp]
|
||||
theorem skipSuffix?_string_empty {s : Slice} : s.skipSuffix? "" = some s.endPos := by
|
||||
simp
|
||||
|
||||
@[simp]
|
||||
theorem endsWith_string_iff {pat : String} {s : Slice} :
|
||||
s.endsWith pat ↔ pat.toList <:+ s.copy.toList := by
|
||||
simp [endsWith_string_eq_endsWith_toSlice]
|
||||
|
||||
@[simp]
|
||||
theorem endsWith_string_empty {s : Slice} : s.endsWith "" = true := by
|
||||
simp
|
||||
|
||||
@[simp]
|
||||
theorem endsWith_string_eq_false_iff {pat : String} {s : Slice} :
|
||||
s.endsWith pat = false ↔ ¬ (pat.toList <:+ s.copy.toList) := by
|
||||
simp [endsWith_string_eq_endsWith_toSlice]
|
||||
|
||||
@[simp]
|
||||
theorem dropSuffix?_string_empty {s : Slice} : s.dropSuffix? "" = some s := by
|
||||
simpa [dropSuffix?_string_eq_dropSuffix?_toSlice] using dropSuffix?_slice_of_isEmpty (by simp)
|
||||
|
||||
theorem eq_append_of_dropSuffix?_string_eq_some {pat : String} {s res : Slice} (h : s.dropSuffix? pat = some res) :
|
||||
s.copy = res.copy ++ pat := by
|
||||
rw [dropSuffix?_string_eq_dropSuffix?_toSlice] at h
|
||||
simpa using eq_append_of_dropSuffix?_slice_eq_some h
|
||||
|
||||
end Slice
|
||||
|
||||
theorem skipPrefix?_slice_of_isEmpty {pat : Slice} {s : String} (hpat : pat.isEmpty = true) :
|
||||
|
||||
@@ -367,7 +367,7 @@ theorem Slice.Pos.Splits.of_prev {s : Slice} {p : s.Pos} {hp}
|
||||
obtain ⟨rfl, rfl, rfl⟩ := by simpa using h.eq (splits_prev p hp)
|
||||
exact splits_prev_right p hp
|
||||
|
||||
theorem Slice.copy_sliceTo_eq_iff_exists_splits {s : Slice} {p : s.Pos} {t₁ : String} :
|
||||
theorem Slice.sliceTo_copy_eq_iff_exists_splits {s : Slice} {p : s.Pos} {t₁ : String} :
|
||||
(s.sliceTo p).copy = t₁ ↔ ∃ t₂, p.Splits t₁ t₂ := by
|
||||
refine ⟨?_, ?_⟩
|
||||
· rintro rfl
|
||||
@@ -375,21 +375,13 @@ theorem Slice.copy_sliceTo_eq_iff_exists_splits {s : Slice} {p : s.Pos} {t₁ :
|
||||
· rintro ⟨t₂, h⟩
|
||||
exact p.splits.eq_left h
|
||||
|
||||
theorem Slice.copy_sliceFrom_eq_iff_exists_splits {s : Slice} {p : s.Pos} {t₂ : String} :
|
||||
(s.sliceFrom p).copy = t₂ ↔ ∃ t₁, p.Splits t₁ t₂ := by
|
||||
theorem sliceTo_copy_eq_iff_exists_splits {s : String} {p : s.Pos} {t₁ : String} :
|
||||
(s.sliceTo p).copy = t₁ ↔ ∃ t₂, p.Splits t₁ t₂ := by
|
||||
refine ⟨?_, ?_⟩
|
||||
· rintro rfl
|
||||
exact ⟨_, p.splits⟩
|
||||
· rintro ⟨t₂, h⟩
|
||||
exact p.splits.eq_right h
|
||||
|
||||
theorem copy_sliceTo_eq_iff_exists_splits {s : String} {p : s.Pos} {t₁ : String} :
|
||||
(s.sliceTo p).copy = t₁ ↔ ∃ t₂, p.Splits t₁ t₂ := by
|
||||
simp [← Pos.splits_toSlice_iff, ← Slice.copy_sliceTo_eq_iff_exists_splits]
|
||||
|
||||
theorem copy_sliceFrom_eq_iff_exists_splits {s : String} {p : s.Pos} {t₂ : String} :
|
||||
(s.sliceFrom p).copy = t₂ ↔ ∃ t₁, p.Splits t₁ t₂ := by
|
||||
simp [← Pos.splits_toSlice_iff, ← Slice.copy_sliceFrom_eq_iff_exists_splits]
|
||||
exact p.splits.eq_left h
|
||||
|
||||
theorem Pos.Splits.offset_eq_decreaseBy {s : String} {p : s.Pos} (h : p.Splits t₁ t₂) :
|
||||
p.offset = s.rawEndPos.decreaseBy t₂.utf8ByteSize := by
|
||||
@@ -435,7 +427,8 @@ theorem Slice.splits_singleton_iff {s : Slice} {p : s.Pos} {c : Char} {t : Strin
|
||||
simp [startPos_ne_endPos_iff, ← copy_ne_empty_iff, h.eq_append]
|
||||
have spl : (s.startPos.next this).Splits (singleton c) t := by
|
||||
rw [← empty_append (s := singleton c)]
|
||||
exact Pos.Splits.next (by simp [h.eq_append])
|
||||
apply Pos.Splits.next
|
||||
simp [h.eq_append]
|
||||
refine ⟨this, ⟨h.pos_eq spl, ?_, h.eq_append⟩⟩
|
||||
rw [← empty_append (s := singleton c)] at spl
|
||||
exact spl.get_eq_of_singleton
|
||||
@@ -449,27 +442,6 @@ theorem splits_singleton_iff {s : String} {p : s.Pos} {c : Char} {t : String} :
|
||||
rw [← Pos.splits_toSlice_iff, Slice.splits_singleton_iff]
|
||||
simp [← Pos.ofToSlice_inj]
|
||||
|
||||
theorem Slice.splits_singleton_right_iff {s : Slice} {p : s.Pos} {c : Char} {t : String} :
|
||||
p.Splits t (singleton c) ↔
|
||||
∃ h, p = s.endPos.prev h ∧ (s.endPos.prev h).get (by simp) = c ∧ s.copy = t ++ singleton c := by
|
||||
refine ⟨fun h => ?_, ?_⟩
|
||||
· have : s.endPos ≠ s.startPos := by
|
||||
simp [ne_comm (a := s.endPos), startPos_ne_endPos_iff, ← copy_ne_empty_iff, h.eq_append]
|
||||
have spl : (s.endPos.prev this).Splits t (singleton c) := by
|
||||
rw [← append_empty (s := singleton c)]
|
||||
exact Pos.Splits.prev (by simp [h.eq_append])
|
||||
refine ⟨this, ⟨h.pos_eq spl, ?_, h.eq_append⟩⟩
|
||||
exact (h.eq_append ▸ Pos.next_prev (h := this) ▸ s.splits_endPos).get_eq_of_singleton
|
||||
· rintro ⟨h, ⟨rfl, rfl, h'⟩⟩
|
||||
rw [← String.append_empty (s := singleton _)]
|
||||
exact Pos.Splits.prev (by simp [h'])
|
||||
|
||||
theorem splits_singleton_right_iff {s : String} {p : s.Pos} {c : Char} {t : String} :
|
||||
p.Splits t (singleton c) ↔
|
||||
∃ h, p = s.endPos.prev h ∧ (s.endPos.prev h).get (by simp) = c ∧ s = t ++ singleton c := by
|
||||
rw [← Pos.splits_toSlice_iff, Slice.splits_singleton_right_iff]
|
||||
simp [← Pos.ofToSlice_inj, Pos.prev_toSlice]
|
||||
|
||||
theorem Slice.splits_next_startPos {s : Slice} {h : s.startPos ≠ s.endPos} :
|
||||
(s.startPos.next h).Splits
|
||||
(singleton (s.startPos.get h)) (s.sliceFrom (s.startPos.next h)).copy := by
|
||||
@@ -484,20 +456,6 @@ theorem splits_next_startPos {s : String} {h : s.startPos ≠ s.endPos} :
|
||||
rw [← Pos.splits_toSlice_iff]
|
||||
apply (Slice.splits_next_startPos).of_eq <;> simp [String.Pos.next_toSlice]
|
||||
|
||||
theorem Slice.splits_prev_endPos {s : Slice} {h : s.endPos ≠ s.startPos} :
|
||||
(s.endPos.prev h).Splits
|
||||
(s.sliceTo (s.endPos.prev h)).copy (singleton ((s.endPos.prev h).get (by simp))) := by
|
||||
rw [← String.append_empty (s := singleton _)]
|
||||
apply Slice.Pos.Splits.prev
|
||||
have := Slice.Pos.splits_prev_right s.endPos h
|
||||
rwa [copy_sliceFrom_endPos] at this
|
||||
|
||||
theorem splits_prev_endPos {s : String} {h : s.endPos ≠ s.startPos} :
|
||||
(s.endPos.prev h).Splits
|
||||
(s.sliceTo (s.endPos.prev h)).copy (singleton ((s.endPos.prev h).get (by simp))) := by
|
||||
rw [← Pos.splits_toSlice_iff]
|
||||
apply (Slice.splits_prev_endPos).of_eq <;> simp [String.Pos.prev_toSlice, h]
|
||||
|
||||
theorem Slice.Pos.Splits.toByteArray_eq_left {s : Slice} {p : s.Pos} {t₁ t₂ : String} (h : p.Splits t₁ t₂) :
|
||||
t₁.toByteArray = s.copy.toByteArray.extract 0 p.offset.byteIdx := by
|
||||
rw [h.eq_left p.splits]
|
||||
|
||||
@@ -117,7 +117,7 @@ class ForwardPattern {ρ : Type} (pat : ρ) where
|
||||
-/
|
||||
startsWith : (s : Slice) → Bool := fun s => (skipPrefix? s).isSome
|
||||
|
||||
@[deprecated ForwardPattern.skipPrefix? (since := "2026-03-19")]
|
||||
@[deprecated ForwardPattern.dropPrefix? (since := "2026-03-19")]
|
||||
def ForwardPattern.dropPrefix? {ρ : Type} (pat : ρ) [ForwardPattern pat] (s : Slice) : Option s.Pos :=
|
||||
ForwardPattern.skipPrefix? pat s
|
||||
|
||||
|
||||
@@ -47,8 +47,8 @@ instance {c : Char} : LawfulBackwardPattern c where
|
||||
skipSuffixOfNonempty?_eq h := LawfulBackwardPattern.skipSuffixOfNonempty?_eq (pat := (· == c)) h
|
||||
endsWith_eq s := LawfulBackwardPattern.endsWith_eq (pat := (· == c)) s
|
||||
|
||||
instance {c : Char} : ToBackwardSearcher c (ToBackwardSearcher.DefaultBackwardSearcher (· == c)) where
|
||||
toSearcher s := ToBackwardSearcher.toSearcher (· == c) s
|
||||
instance {c : Char} : ToBackwardSearcher c (ToBackwardSearcher.DefaultBackwardSearcher c) :=
|
||||
.defaultImplementation
|
||||
|
||||
end Char
|
||||
|
||||
|
||||
@@ -139,9 +139,8 @@ instance {p : Char → Prop} [DecidablePred p] : LawfulBackwardPattern p where
|
||||
skipSuffixOfNonempty?_eq h := LawfulBackwardPattern.skipSuffixOfNonempty?_eq (pat := (decide <| p ·)) h
|
||||
endsWith_eq s := LawfulBackwardPattern.endsWith_eq (pat := (decide <| p ·)) s
|
||||
|
||||
instance {p : Char → Prop} [DecidablePred p] :
|
||||
ToBackwardSearcher p (ToBackwardSearcher.DefaultBackwardSearcher (decide <| p ·)) where
|
||||
toSearcher s := ToBackwardSearcher.toSearcher (decide <| p ·) s
|
||||
instance {p : Char → Prop} [DecidablePred p] : ToBackwardSearcher p (ToBackwardSearcher.DefaultBackwardSearcher p) :=
|
||||
.defaultImplementation
|
||||
|
||||
end Decidable
|
||||
|
||||
|
||||
@@ -2259,6 +2259,42 @@ with grind
|
||||
```
|
||||
This is more convenient than the equivalent `· by rename_i _ acc _; exact I1 acc`.
|
||||
|
||||
### Witnesses
|
||||
|
||||
When a specification has a parameter whose type is tagged with `@[mvcgen_witness_type]`, `mvcgen`
|
||||
classifies the corresponding goal as a *witness* rather than a verification condition.
|
||||
Witnesses are concrete values that the user must provide (inspired by zero-knowledge proofs),
|
||||
as opposed to invariants (predicates maintained across loop iterations) or verification conditions
|
||||
(propositions to prove).
|
||||
|
||||
Witness goals are labelled `witness1`, `witness2`, etc. and can be provided in a `witnesses` section
|
||||
that appears before the `invariants` section:
|
||||
```
|
||||
mvcgen [...] witnesses
|
||||
· W1
|
||||
· W2
|
||||
invariants
|
||||
· I1
|
||||
with grind
|
||||
```
|
||||
Like invariants, witnesses support case label syntax:
|
||||
```
|
||||
mvcgen [...] witnesses
|
||||
| witness1 => W1
|
||||
```
|
||||
|
||||
See the `@[mvcgen_witness_type]` attribute for how to register custom witness types.
|
||||
|
||||
### Invariant and witness type attributes
|
||||
|
||||
The `@[mvcgen_invariant_type]` and `@[mvcgen_witness_type]` tag attributes control how `mvcgen`
|
||||
classifies subgoals:
|
||||
* A goal whose type is an application of a type tagged with `@[mvcgen_invariant_type]` is classified
|
||||
as an invariant (`inv<n>`).
|
||||
* A goal whose type is an application of a type tagged with `@[mvcgen_witness_type]` is classified
|
||||
as a witness (`witness<n>`).
|
||||
* All other goals are classified as verification conditions (`vc<n>`).
|
||||
|
||||
### Invariant suggestions
|
||||
|
||||
`mvcgen` will suggest invariants for you if you use the `invariants?` keyword.
|
||||
|
||||
@@ -10,7 +10,6 @@ public import Lean.Compiler.IR.Format
|
||||
public import Lean.Compiler.ExportAttr
|
||||
public import Lean.Compiler.LCNF.PublicDeclsExt
|
||||
import Lean.Compiler.InitAttr
|
||||
import all Lean.Compiler.ModPkgExt
|
||||
import Init.Data.Format.Macro
|
||||
import Lean.Compiler.LCNF.Basic
|
||||
|
||||
@@ -130,14 +129,8 @@ private def exportIREntries (env : Environment) : Array (Name × Array EnvExtens
|
||||
-- safety: cast to erased type
|
||||
let initDecls : Array EnvExtensionEntry := unsafe unsafeCast initDecls
|
||||
|
||||
-- needed during initialization via interpreter
|
||||
let modPkg : Array (Option PkgId) := modPkgExt.exportEntriesFn env (modPkgExt.getState env) .private
|
||||
-- safety: cast to erased type
|
||||
let modPkg : Array EnvExtensionEntry := unsafe unsafeCast modPkg
|
||||
|
||||
#[(declMapExt.name, irEntries),
|
||||
(Lean.regularInitAttr.ext.name, initDecls),
|
||||
(modPkgExt.name, modPkg)]
|
||||
(Lean.regularInitAttr.ext.name, initDecls)]
|
||||
|
||||
def findEnvDecl (env : Environment) (declName : Name) : Option Decl :=
|
||||
Compiler.LCNF.findExtEntry? env declMapExt declName findAtSorted? (·.2.find?)
|
||||
|
||||
@@ -342,11 +342,6 @@ def LetValue.toExpr (e : LetValue pu) : Expr :=
|
||||
| .unbox var _ => mkApp (.const `unbox []) (.fvar var)
|
||||
| .isShared fvarId _ => mkApp (.const `isShared []) (.fvar fvarId)
|
||||
|
||||
def LetValue.isPersistent (val : LetValue .impure) : Bool :=
|
||||
match val with
|
||||
| .fap _ xs => xs.isEmpty -- all global constants are persistent
|
||||
| _ => false
|
||||
|
||||
structure LetDecl (pu : Purity) where
|
||||
fvarId : FVarId
|
||||
binderName : Name
|
||||
|
||||
@@ -235,6 +235,11 @@ def withParams (ps : Array (Param .impure)) (x : RcM α) : RcM α := do
|
||||
{ ctx with idx := ctx.idx + 1, varMap }
|
||||
withReader update x
|
||||
|
||||
def LetValue.isPersistent (val : LetValue .impure) : Bool :=
|
||||
match val with
|
||||
| .fap _ xs => xs.isEmpty -- all global constants are persistent
|
||||
| _ => false
|
||||
|
||||
@[inline]
|
||||
def withLetDecl (decl : LetDecl .impure) (x : RcM α) : RcM α := do
|
||||
let update := fun ctx =>
|
||||
|
||||
@@ -390,12 +390,9 @@ where
|
||||
if let .fvar parent := args[1]! then
|
||||
if ← isOwned parent then ownFVar z (.forwardProjectionProp z)
|
||||
| .fap f args =>
|
||||
-- Constants remain alive at least until the end of execution and can thus effectively be seen
|
||||
-- as a "borrowed" read.
|
||||
if args.size > 0 then
|
||||
let ps ← getParamInfo (.decl f)
|
||||
ownFVar z (.functionCallResult z)
|
||||
ownArgsUsingParams args ps (.functionCallArg z)
|
||||
let ps ← getParamInfo (.decl f)
|
||||
ownFVar z (.functionCallResult z)
|
||||
ownArgsUsingParams args ps (.functionCallArg z)
|
||||
| .fvar x args =>
|
||||
ownFVar z (.functionCallResult z); ownFVar x (.fvarCall z); ownArgs (.fvarCall z) args
|
||||
| .pap _ args => ownFVar z (.functionCallResult z); ownArgs (.partialApplication z) args
|
||||
|
||||
@@ -121,10 +121,7 @@ where
|
||||
if let .fvar parent := args[1]! then
|
||||
let parentVal ← getOwnedness parent
|
||||
join z parentVal
|
||||
| .fap _ args =>
|
||||
let value := if args.isEmpty then .borrow else .own
|
||||
join z value
|
||||
| .ctor .. | .fvar .. | .pap .. | .sproj .. | .uproj .. | .erased .. | .lit .. =>
|
||||
| .ctor .. | .fap .. | .fvar .. | .pap .. | .sproj .. | .uproj .. | .erased .. | .lit .. =>
|
||||
join z .own
|
||||
| _ => unreachable!
|
||||
|
||||
|
||||
@@ -268,3 +268,24 @@ def isMVCGenInvariantType (env : Environment) (ty : Expr) : Bool :=
|
||||
mvcgenInvariantAttr.hasTag env name
|
||||
else
|
||||
false
|
||||
|
||||
/--
|
||||
Marks a type as a witness type for the `mvcgen` tactic.
|
||||
Goals whose type is an application of a tagged type will be classified
|
||||
as witnesses rather than verification conditions.
|
||||
In the spirit of zero-knowledge proofs, witnesses are concrete values that the user
|
||||
must provide, as opposed to invariants (predicates maintained across iterations)
|
||||
or verification conditions (propositions to prove).
|
||||
-/
|
||||
builtin_initialize mvcgenWitnessTypeAttr : TagAttribute ←
|
||||
registerTagAttribute `mvcgen_witness_type
|
||||
"marks a type as a witness type for the `mvcgen` tactic"
|
||||
|
||||
/--
|
||||
Returns `true` if `ty` is an application of a type tagged with `@[mvcgen_witness_type]`.
|
||||
-/
|
||||
def isMVCGenWitnessType (env : Environment) (ty : Expr) : Bool :=
|
||||
if let .const name .. := ty.getAppFn then
|
||||
mvcgenWitnessTypeAttr.hasTag env name
|
||||
else
|
||||
false
|
||||
|
||||
@@ -35,6 +35,7 @@ namespace VCGen
|
||||
|
||||
structure Result where
|
||||
invariants : Array MVarId
|
||||
witnesses : Array MVarId
|
||||
vcs : Array MVarId
|
||||
|
||||
partial def genVCs (goal : MVarId) (ctx : Context) (fuel : Fuel) : MetaM Result := do
|
||||
@@ -45,10 +46,13 @@ partial def genVCs (goal : MVarId) (ctx : Context) (fuel : Fuel) : MetaM Result
|
||||
for h : idx in *...state.invariants.size do
|
||||
let mv := state.invariants[idx]
|
||||
mv.setTag (Name.mkSimple ("inv" ++ toString (idx + 1)))
|
||||
for h : idx in *...state.witnesses.size do
|
||||
let mv := state.witnesses[idx]
|
||||
mv.setTag (Name.mkSimple ("witness" ++ toString (idx + 1)))
|
||||
for h : idx in *...state.vcs.size do
|
||||
let mv := state.vcs[idx]
|
||||
mv.setTag (Name.mkSimple ("vc" ++ toString (idx + 1)) ++ (← mv.getTag).eraseMacroScopes)
|
||||
return { invariants := state.invariants, vcs := state.vcs }
|
||||
return { invariants := state.invariants, witnesses := state.witnesses, vcs := state.vcs }
|
||||
where
|
||||
onFail (goal : MGoal) (name : Name) : VCGenM Expr := do
|
||||
-- trace[Elab.Tactic.Do.vcgen] "fail {goal.toExpr}"
|
||||
@@ -352,53 +356,70 @@ where
|
||||
|
||||
end VCGen
|
||||
|
||||
/-- Shared implementation for elaborating goal sections (invariants, witnesses).
|
||||
`tagPrefix` is `"inv"` or `"witness"`, used to parse labels like `inv1` or `witness2`.
|
||||
`label` is `"invariant"` or `"witness"`, used in error messages.
|
||||
When `requireAll` is true, an error is thrown if fewer alts are provided than goals. -/
|
||||
private def elabGoalSection (goals : Array MVarId) (alts : Array Syntax)
|
||||
(tagPrefix : String) (label : String) (requireAll := true) : TacticM Unit := do
|
||||
let goals ← goals.filterM (not <$> ·.isAssigned)
|
||||
let mut dotOrCase := LBool.undef -- .true => dot
|
||||
for h : n in 0...alts.size do
|
||||
let alt := alts[n]
|
||||
match alt with
|
||||
| `(goalDotAlt| · $rhs) =>
|
||||
if dotOrCase matches .false then
|
||||
logErrorAt alt m!"Alternation between labelled and bulleted {label}s is not supported."
|
||||
break
|
||||
dotOrCase := .true
|
||||
let some mv := goals[n]? | do
|
||||
logErrorAt alt m!"More {label}s have been defined ({alts.size}) than there were unassigned {label} goals `{tagPrefix}<n>` ({goals.size})."
|
||||
continue
|
||||
withRef rhs do
|
||||
discard <| evalTacticAt (← `(tactic| exact $rhs)) mv
|
||||
| `(goalCaseAlt| | $tag $args* => $rhs) =>
|
||||
if dotOrCase matches .true then
|
||||
logErrorAt alt m!"Alternation between labelled and bulleted {label}s is not supported."
|
||||
break
|
||||
dotOrCase := .false
|
||||
let n? : Option Nat := do
|
||||
let `(binderIdent| $tag:ident) := tag | some n -- fall back to ordinal
|
||||
let .str .anonymous s := tag.getId | none
|
||||
s.dropPrefix? tagPrefix >>= String.Slice.toNat?
|
||||
let some mv := do goals[(← n?) - 1]? | do
|
||||
logErrorAt alt m!"No {label} with label {tag} {repr tag}."
|
||||
continue
|
||||
if ← mv.isAssigned then
|
||||
logErrorAt alt m!"{label} {n?.get!} is already assigned."
|
||||
continue
|
||||
withRef rhs do
|
||||
discard <| evalTacticAt (← `(tactic| rename_i $args*; exact $rhs)) mv
|
||||
| _ => logErrorAt alt m!"Expected `goalDotAlt`, got {alt}"
|
||||
if requireAll && alts.size < goals.size then
|
||||
let missingTypes ← goals[alts.size:].toArray.mapM (·.getType)
|
||||
throwError "Lacking definitions for the following {label}s.\n{toMessageList missingTypes}"
|
||||
|
||||
def elabWitnesses (stx : Syntax) (witnesses : Array MVarId) : TacticM Unit := do
|
||||
let some stx := stx.getOptional? | return ()
|
||||
let stx : TSyntax ``witnessAlts := ⟨stx⟩
|
||||
withRef stx do
|
||||
match stx with
|
||||
| `(witnessAlts| witnesses $alts*) =>
|
||||
elabGoalSection witnesses alts "witness" "witness"
|
||||
| _ => logErrorAt stx m!"Expected witnessAlts, got {stx}"
|
||||
|
||||
def elabInvariants (stx : Syntax) (invariants : Array MVarId) (suggestInvariant : MVarId → TacticM Term) : TacticM Unit := do
|
||||
let some stx := stx.getOptional? | return ()
|
||||
let stx : TSyntax ``invariantAlts := ⟨stx⟩
|
||||
withRef stx do
|
||||
match stx with
|
||||
| `(invariantAlts| $invariantsKW $alts*) =>
|
||||
let invariants ← invariants.filterM (not <$> ·.isAssigned)
|
||||
|
||||
let mut dotOrCase := LBool.undef -- .true => dot
|
||||
for h : n in 0...alts.size do
|
||||
let alt := alts[n]
|
||||
match alt with
|
||||
| `(goalDotAlt| · $rhs) =>
|
||||
if dotOrCase matches .false then
|
||||
logErrorAt alt m!"Alternation between labelled and bulleted invariants is not supported."
|
||||
break
|
||||
dotOrCase := .true
|
||||
let some mv := invariants[n]? | do
|
||||
logErrorAt alt m!"More invariants have been defined ({alts.size}) than there were unassigned invariants goals `inv<n>` ({invariants.size})."
|
||||
continue
|
||||
withRef rhs do
|
||||
discard <| evalTacticAt (← `(tactic| exact $rhs)) mv
|
||||
| `(goalCaseAlt| | $tag $args* => $rhs) =>
|
||||
if dotOrCase matches .true then
|
||||
logErrorAt alt m!"Alternation between labelled and bulleted invariants is not supported."
|
||||
break
|
||||
dotOrCase := .false
|
||||
let n? : Option Nat := do
|
||||
let `(binderIdent| $tag:ident) := tag | some n -- fall back to ordinal
|
||||
let .str .anonymous s := tag.getId | none
|
||||
s.dropPrefix? "inv" >>= String.Slice.toNat?
|
||||
let some mv := do invariants[(← n?) - 1]? | do
|
||||
logErrorAt alt m!"No invariant with label {tag} {repr tag}."
|
||||
continue
|
||||
if ← mv.isAssigned then
|
||||
logErrorAt alt m!"Invariant {n?.get!} is already assigned."
|
||||
continue
|
||||
withRef rhs do
|
||||
discard <| evalTacticAt (← `(tactic| rename_i $args*; exact $rhs)) mv
|
||||
| _ => logErrorAt alt m!"Expected `goalDotAlt`, got {alt}"
|
||||
|
||||
if let `(invariantsKW| invariants) := invariantsKW then
|
||||
if alts.size < invariants.size then
|
||||
let missingTypes ← invariants[alts.size:].toArray.mapM (·.getType)
|
||||
throwErrorAt stx m!"Lacking definitions for the following invariants.\n{toMessageList missingTypes}"
|
||||
elabGoalSection invariants alts "inv" "invariant"
|
||||
else
|
||||
-- Otherwise, we have `invariants?`. Suggest missing invariants.
|
||||
-- We have `invariants?`. First elaborate any user-provided alts, then suggest the rest.
|
||||
elabGoalSection invariants alts "inv" "invariant" (requireAll := false)
|
||||
let invariants ← invariants.filterM (not <$> ·.isAssigned)
|
||||
let mut suggestions := #[]
|
||||
for i in 0...invariants.size do
|
||||
let mv := invariants[i]!
|
||||
@@ -457,8 +478,8 @@ def elabMVCGen : Tactic := fun stx => withMainContext do
|
||||
| none => .unlimited
|
||||
let goal ← getMainGoal
|
||||
let goal ← if ctx.config.elimLets then elimLets goal else pure goal
|
||||
let { invariants, vcs } ← VCGen.genVCs goal ctx fuel
|
||||
trace[Elab.Tactic.Do.vcgen] "after genVCs {← (invariants ++ vcs).mapM fun m => m.getTag}"
|
||||
let { invariants, witnesses, vcs } ← VCGen.genVCs goal ctx fuel
|
||||
trace[Elab.Tactic.Do.vcgen] "after genVCs {← (invariants ++ witnesses ++ vcs).mapM fun m => m.getTag}"
|
||||
let runOnVCs (tac : TSyntax `tactic) (extraMsg : MessageData) (vcs : Array MVarId) : TermElabM (Array MVarId) :=
|
||||
vcs.flatMapM fun vc =>
|
||||
tryCatchRuntimeEx
|
||||
@@ -467,10 +488,13 @@ def elabMVCGen : Tactic := fun stx => withMainContext do
|
||||
(fun ex => throwError "Error while running {tac} on {vc}Message: {indentD ex.toMessageData}\n{extraMsg}")
|
||||
let invariants ←
|
||||
if ctx.config.leave then runOnVCs (← `(tactic| try mleave)) "Try again with -leave." invariants else pure invariants
|
||||
trace[Elab.Tactic.Do.vcgen] "before elabInvariants {← (invariants ++ vcs).mapM fun m => m.getTag}"
|
||||
elabInvariants stx[3] invariants (suggestInvariant vcs)
|
||||
trace[Elab.Tactic.Do.vcgen] "before elabWitnesses {← (invariants ++ witnesses ++ vcs).mapM fun m => m.getTag}"
|
||||
elabWitnesses stx[3] witnesses
|
||||
let witnesses ← witnesses.filterM (not <$> ·.isAssigned)
|
||||
trace[Elab.Tactic.Do.vcgen] "before elabInvariants {← (invariants ++ witnesses ++ vcs).mapM fun m => m.getTag}"
|
||||
elabInvariants stx[4] invariants (suggestInvariant vcs)
|
||||
let invariants ← invariants.filterM (not <$> ·.isAssigned)
|
||||
trace[Elab.Tactic.Do.vcgen] "before trying trivial VCs {← (invariants ++ vcs).mapM fun m => m.getTag}"
|
||||
trace[Elab.Tactic.Do.vcgen] "before trying trivial VCs {← (invariants ++ witnesses ++ vcs).mapM fun m => m.getTag}"
|
||||
let vcs ← do
|
||||
let vcs ← if ctx.config.trivial then runOnVCs (← `(tactic| try mvcgen_trivial)) "Try again with -trivial." vcs else pure vcs
|
||||
let vcs ← if ctx.config.leave then runOnVCs (← `(tactic| try mleave)) "Try again with -leave." vcs else pure vcs
|
||||
@@ -478,17 +502,17 @@ def elabMVCGen : Tactic := fun stx => withMainContext do
|
||||
-- Eliminating lets here causes some metavariables in `mkFreshPair_triple` to become nonassignable
|
||||
-- so we don't do it. Presumably some weird delayed assignment thing is going on.
|
||||
-- let vcs ← if ctx.config.elimLets then liftMetaM <| vcs.mapM elimLets else pure vcs
|
||||
trace[Elab.Tactic.Do.vcgen] "before elabVCs {← (invariants ++ vcs).mapM fun m => m.getTag}"
|
||||
let vcs ← elabVCs stx[4] vcs
|
||||
trace[Elab.Tactic.Do.vcgen] "before replacing main goal {← (invariants ++ vcs).mapM fun m => m.getTag}"
|
||||
replaceMainGoal (invariants ++ vcs).toList
|
||||
trace[Elab.Tactic.Do.vcgen] "before elabVCs {← (invariants ++ witnesses ++ vcs).mapM fun m => m.getTag}"
|
||||
let vcs ← elabVCs stx[5] vcs
|
||||
trace[Elab.Tactic.Do.vcgen] "before replacing main goal {← (invariants ++ witnesses ++ vcs).mapM fun m => m.getTag}"
|
||||
replaceMainGoal (invariants ++ witnesses ++ vcs).toList
|
||||
-- trace[Elab.Tactic.Do.vcgen] "replaced main goal, new: {← getGoals}"
|
||||
|
||||
@[builtin_tactic Lean.Parser.Tactic.mvcgenHint]
|
||||
def elabMVCGenHint : Tactic := fun stx => withMainContext do
|
||||
let stx' : TSyntax ``mvcgen := TSyntax.mk <| stx
|
||||
|>.setKind ``Lean.Parser.Tactic.mvcgen
|
||||
|>.modifyArgs (·.set! 0 (mkAtom "mvcgen") |>.push (mkNullNode #[← `(invariantAlts| invariants?)]) |>.push mkNullNode)
|
||||
|>.modifyArgs (·.set! 0 (mkAtom "mvcgen") |>.push mkNullNode |>.push (mkNullNode #[← `(invariantAlts| invariants?)]) |>.push mkNullNode)
|
||||
-- logInfo m!"{stx}\n{toString stx}\n{repr stx}"
|
||||
-- logInfo m!"{stx'}\n{toString stx'}\n{repr stx'}"
|
||||
Lean.Meta.Tactic.TryThis.addSuggestion stx stx'
|
||||
|
||||
@@ -73,6 +73,10 @@ structure State where
|
||||
-/
|
||||
invariants : Array MVarId := #[]
|
||||
/--
|
||||
Holes of witness type that have been generated so far.
|
||||
-/
|
||||
witnesses : Array MVarId := #[]
|
||||
/--
|
||||
The verification conditions that have been generated so far.
|
||||
-/
|
||||
vcs : Array MVarId := #[]
|
||||
@@ -104,8 +108,11 @@ def addSubGoalAsVC (goal : MVarId) : VCGenM PUnit := do
|
||||
-- VC to the user as-is, without abstracting any variables in the local context.
|
||||
-- This only makes sense for synthetic opaque metavariables.
|
||||
goal.setKind .syntheticOpaque
|
||||
if isMVCGenInvariantType (← getEnv) ty then
|
||||
let env ← getEnv
|
||||
if isMVCGenInvariantType env ty then
|
||||
modify fun s => { s with invariants := s.invariants.push goal }
|
||||
else if isMVCGenWitnessType env ty then
|
||||
modify fun s => { s with witnesses := s.witnesses.push goal }
|
||||
else
|
||||
modify fun s => { s with vcs := s.vcs.push goal }
|
||||
|
||||
|
||||
@@ -15,8 +15,6 @@ register_builtin_option sym.debug : Bool := {
|
||||
descr := "check invariants"
|
||||
}
|
||||
|
||||
builtin_initialize registerTraceClass `sym.issues
|
||||
|
||||
/-!
|
||||
## Sym Extensions
|
||||
|
||||
@@ -136,16 +134,9 @@ structure SharedExprs where
|
||||
ordEqExpr : Expr
|
||||
intExpr : Expr
|
||||
|
||||
/-- Configuration options for the symbolic computation framework. -/
|
||||
structure Config where
|
||||
/-- When `true`, issues are collected during proof search and reported on failure. -/
|
||||
verbose : Bool := true
|
||||
deriving Inhabited
|
||||
|
||||
/-- Readonly context for the symbolic computation framework. -/
|
||||
structure Context where
|
||||
sharedExprs : SharedExprs
|
||||
config : Config := {}
|
||||
|
||||
/-- Mutable state for the symbolic computation framework. -/
|
||||
structure State where
|
||||
@@ -186,11 +177,6 @@ structure State where
|
||||
defEqI : PHashMap (ExprPtr × ExprPtr) Bool := {}
|
||||
/-- State for registered `SymExtension`s, indexed by extension id. -/
|
||||
extensions : Array SymExtensionState := #[]
|
||||
/--
|
||||
Issues found during symbolic computation. Accumulated across operations
|
||||
within a `sym =>` block and reported when a tactic fails.
|
||||
-/
|
||||
issues : List MessageData := []
|
||||
debug : Bool := false
|
||||
|
||||
abbrev SymM := ReaderT Context <| StateRefT State MetaM
|
||||
@@ -280,55 +266,6 @@ abbrev share (e : Expr) : SymM Expr :=
|
||||
@[inline] def isDebugEnabled : SymM Bool :=
|
||||
return (← get).debug
|
||||
|
||||
def getConfig : SymM Config :=
|
||||
return (← readThe Context).config
|
||||
|
||||
/-- Adds an issue message to the issue tracker. -/
|
||||
def reportIssue (msg : MessageData) : SymM Unit := do
|
||||
let msg ← addMessageContext msg
|
||||
modify fun s => { s with issues := .trace { cls := `issue } msg #[] :: s.issues }
|
||||
trace[sym.issues] msg
|
||||
|
||||
/-- Reports an issue if `verbose` mode is enabled. Does nothing if `verbose` is `false`. -/
|
||||
@[inline] def reportIssueIfVerbose (msg : MessageData) : SymM Unit := do
|
||||
if (← getConfig).verbose then
|
||||
reportIssue msg
|
||||
|
||||
private meta def expandReportIssueMacro (s : Syntax) : MacroM (TSyntax `doElem) := do
|
||||
let msg ← if s.getKind == interpolatedStrKind then `(m! $(⟨s⟩)) else `(($(⟨s⟩) : MessageData))
|
||||
`(doElem| Sym.reportIssueIfVerbose $msg)
|
||||
|
||||
/-- Reports an issue if `verbose` mode is enabled. -/
|
||||
macro "reportIssue!" s:(interpolatedStr(term) <|> term) : doElem => do
|
||||
expandReportIssueMacro s.raw
|
||||
|
||||
/-- Reports an issue if both `verbose` and `sym.debug` are enabled. Does nothing otherwise. -/
|
||||
@[inline] def reportDbgIssue (msg : MessageData) : SymM Unit := do
|
||||
if (← getConfig).verbose then
|
||||
if sym.debug.get (← getOptions) then
|
||||
reportIssue msg
|
||||
|
||||
meta def expandReportDbgIssueMacro (s : Syntax) : MacroM (TSyntax `doElem) := do
|
||||
let msg ← if s.getKind == interpolatedStrKind then `(m! $(⟨s⟩)) else `(($(⟨s⟩) : MessageData))
|
||||
`(doElem| Sym.reportDbgIssue $msg)
|
||||
|
||||
/-- Similar to `reportIssue!`, but only reports issue if `sym.debug` is set to `true`. -/
|
||||
macro "reportDbgIssue!" s:(interpolatedStr(term) <|> term) : doElem => do
|
||||
expandReportDbgIssueMacro s.raw
|
||||
|
||||
/-- Returns all accumulated issues without clearing them. -/
|
||||
def getIssues : SymM (List MessageData) :=
|
||||
return (← get).issues
|
||||
|
||||
/--
|
||||
Runs `x` with a fresh issue context. Issues reported during `x` are
|
||||
prepended to the issues that existed before the call.
|
||||
-/
|
||||
def withNewIssueContext (x : SymM α) : SymM α := do
|
||||
let saved := (← get).issues
|
||||
modify fun s => { s with issues := [] }
|
||||
try x finally modify fun s => { s with issues := s.issues ++ saved }
|
||||
|
||||
/-- Similar to `Meta.isDefEqI`, but the result is cache using pointer equality. -/
|
||||
def isDefEqI (s t : Expr) : SymM Bool := do
|
||||
let key := (⟨s⟩, ⟨t⟩)
|
||||
|
||||
@@ -206,7 +206,7 @@ def handleApp : Simproc := fun e => do
|
||||
match fn with
|
||||
| .const constName _ =>
|
||||
if (← isCbvOpaque constName) then
|
||||
return markAsDoneIfFailed <| ← tryCbvTheorems e
|
||||
return (← tryCbvTheorems e).markAsDone
|
||||
let info ← getConstInfo constName
|
||||
tryCbvTheorems <|> (guardSimproc (fun _ => info.hasValue) handleConstApp) <|> reduceRecMatcher <| e
|
||||
| .lam .. => betaReduce e
|
||||
@@ -215,7 +215,7 @@ def handleApp : Simproc := fun e => do
|
||||
def handleOpaqueConst : Simproc := fun e => do
|
||||
let .const constName _ := e | return .rfl
|
||||
if (← isCbvOpaque constName) then
|
||||
return markAsDoneIfFailed <| ← tryCbvTheorems e
|
||||
return (← tryCbvTheorems e).markAsDone
|
||||
return .rfl
|
||||
|
||||
def foldLit : Simproc := fun e => do
|
||||
|
||||
@@ -108,8 +108,4 @@ public partial def getListLitElems (e : Expr) (acc : Array Expr := #[]) : Option
|
||||
| List.cons _ a as => getListLitElems as <| acc.push a
|
||||
| _ => none
|
||||
|
||||
public def markAsDoneIfFailed : Result → Result
|
||||
| .rfl _ cd => .rfl true cd
|
||||
| .step e h d cd => .step e h d cd
|
||||
|
||||
end Lean.Meta.Tactic.Cbv
|
||||
|
||||
@@ -63,6 +63,7 @@ builtin_initialize registerTraceClass `grind.ematch.instance
|
||||
builtin_initialize registerTraceClass `grind.ematch.instance.assignment
|
||||
builtin_initialize registerTraceClass `grind.ematch.instance.delayed
|
||||
builtin_initialize registerTraceClass `grind.eqResolution
|
||||
builtin_initialize registerTraceClass `grind.issues
|
||||
builtin_initialize registerTraceClass `grind.simp
|
||||
builtin_initialize registerTraceClass `grind.split
|
||||
builtin_initialize registerTraceClass `grind.split.candidate
|
||||
|
||||
@@ -53,7 +53,7 @@ def mkEqCnstr (p : Poly) (h : EqCnstrProof) : RingM EqCnstr := do
|
||||
Returns the ring expression denoting the given Lean expression.
|
||||
Recall that we compute the ring expressions during internalization.
|
||||
-/
|
||||
private def toRingExpr? [Monad m] [MonadLiftT GrindM m] [MonadLiftT Sym.SymM m] [MonadRing m] (e : Expr) : m (Option RingExpr) := do
|
||||
private def toRingExpr? [Monad m] [MonadLiftT GrindM m] [MonadRing m] (e : Expr) : m (Option RingExpr) := do
|
||||
let ring ← getRing
|
||||
if let some re := ring.denote.find? { expr := e } then
|
||||
return some re
|
||||
@@ -67,7 +67,7 @@ private def toRingExpr? [Monad m] [MonadLiftT GrindM m] [MonadLiftT Sym.SymM m]
|
||||
Returns the semiring expression denoting the given Lean expression.
|
||||
Recall that we compute the semiring expressions during internalization.
|
||||
-/
|
||||
private def toSemiringExpr? [Monad m] [MonadLiftT GrindM m] [MonadLiftT Sym.SymM m] [MonadSemiring m] (e : Expr) : m (Option SemiringExpr) := do
|
||||
private def toSemiringExpr? [Monad m] [MonadLiftT GrindM m] [MonadSemiring m] (e : Expr) : m (Option SemiringExpr) := do
|
||||
let semiring ← getSemiring
|
||||
if let some re := semiring.denote.find? { expr := e } then
|
||||
return some re
|
||||
|
||||
@@ -456,7 +456,7 @@ private def getUnassignedLevelMVars (e : Expr) : MetaM (Array LMVarId) := do
|
||||
-- **Note**: issues reported by the E-matching module are too distractive. We only
|
||||
-- report them if `set_option grind.debug true`
|
||||
macro "reportEMatchIssue!" s:(interpolatedStr(term) <|> term) : doElem => do
|
||||
Sym.expandReportDbgIssueMacro s.raw
|
||||
expandReportDbgIssueMacro s.raw
|
||||
|
||||
/--
|
||||
Stores new theorem instance in the state.
|
||||
|
||||
@@ -104,8 +104,6 @@ private def discharge? (e : Expr) : SimpM (Option Expr) := do
|
||||
open Sym
|
||||
|
||||
def GrindM.run (x : GrindM α) (params : Params) (evalTactic? : Option EvalTactic := none) : MetaM α := Sym.SymM.run do
|
||||
withNewIssueContext do
|
||||
withReader (fun ctx => { ctx with config.verbose := params.config.verbose }) do
|
||||
/- **Note**: Consider using `Sym.simp` in the future. -/
|
||||
let simprocs := params.normProcs
|
||||
let simpMethods := Simp.mkMethods simprocs discharge? (wellBehavedDischarge := true)
|
||||
@@ -334,7 +332,7 @@ private def initCore (mvarId : MVarId) : GrindM Goal := do
|
||||
processHypotheses goal
|
||||
|
||||
def mkResult (params : Params) (failure? : Option Goal) : GrindM Result := do
|
||||
let issues ← Sym.getIssues
|
||||
let issues := (← get).issues
|
||||
let counters := (← get).counters
|
||||
let splitDiags := (← get).splitDiags
|
||||
let simp := { (← get).simp with }
|
||||
|
||||
@@ -214,6 +214,11 @@ structure State where
|
||||
and implement the macro `trace_goal`.
|
||||
-/
|
||||
lastTag : Name := .anonymous
|
||||
/--
|
||||
Issues found during the proof search. These issues are reported to
|
||||
users when `grind` fails.
|
||||
-/
|
||||
issues : List MessageData := []
|
||||
/-- Performance counters -/
|
||||
counters : Counters := {}
|
||||
/-- Split diagnostic information. This information is only collected when `set_option diagnostics true` -/
|
||||
@@ -396,6 +401,35 @@ def mkHCongrWithArity (f : Expr) (numArgs : Nat) : GrindM CongrTheorem := do
|
||||
modify fun s => { s with congrThms := s.congrThms.insert key result }
|
||||
return result
|
||||
|
||||
def reportIssue (msg : MessageData) : GrindM Unit := do
|
||||
let msg ← addMessageContext msg
|
||||
modify fun s => { s with issues := .trace { cls := `issue } msg #[] :: s.issues }
|
||||
/-
|
||||
We also add a trace message because we may want to know when
|
||||
an issue happened relative to other trace messages.
|
||||
-/
|
||||
trace[grind.issues] msg
|
||||
|
||||
private meta def expandReportIssueMacro (s : Syntax) : MacroM (TSyntax `doElem) := do
|
||||
let msg ← if s.getKind == interpolatedStrKind then `(m! $(⟨s⟩)) else `(($(⟨s⟩) : MessageData))
|
||||
`(doElem| do
|
||||
if (← getConfig).verbose then
|
||||
reportIssue $msg)
|
||||
|
||||
macro "reportIssue!" s:(interpolatedStr(term) <|> term) : doElem => do
|
||||
expandReportIssueMacro s.raw
|
||||
|
||||
/-- Similar to `expandReportIssueMacro`, but only reports issue if `grind.debug` is set to `true` -/
|
||||
meta def expandReportDbgIssueMacro (s : Syntax) : MacroM (TSyntax `doElem) := do
|
||||
let msg ← if s.getKind == interpolatedStrKind then `(m! $(⟨s⟩)) else `(($(⟨s⟩) : MessageData))
|
||||
`(doElem| do
|
||||
if (← getConfig).verbose then
|
||||
if grind.debug.get (← getOptions) then
|
||||
reportIssue $msg)
|
||||
|
||||
/-- Similar to `reportIssue!`, but only reports issue if `grind.debug` is set to `true` -/
|
||||
macro "reportDbgIssue!" s:(interpolatedStr(term) <|> term) : doElem => do
|
||||
expandReportDbgIssueMacro s.raw
|
||||
|
||||
/--
|
||||
Each E-node may have "solver terms" attached to them.
|
||||
|
||||
@@ -130,7 +130,7 @@ def foldProjs (e : Expr) : MetaM Expr := do
|
||||
let post (e : Expr) := do
|
||||
let .proj structName idx s := e | return .done e
|
||||
let some info := getStructureInfo? (← getEnv) structName |
|
||||
trace[sym.issues] "found `Expr.proj` but `{structName}` is not marked as structure{indentExpr e}"
|
||||
trace[grind.issues] "found `Expr.proj` but `{structName}` is not marked as structure{indentExpr e}"
|
||||
return .done e
|
||||
if h : idx < info.fieldNames.size then
|
||||
let fieldName := info.fieldNames[idx]
|
||||
@@ -149,7 +149,7 @@ def foldProjs (e : Expr) : MetaM Expr := do
|
||||
-/
|
||||
return .visit (← withDefault <| mkProjection s fieldName)
|
||||
else
|
||||
trace[sym.issues] "found `Expr.proj` with invalid field index `{idx}`{indentExpr e}"
|
||||
trace[grind.issues] "found `Expr.proj` with invalid field index `{idx}`{indentExpr e}"
|
||||
return .done e
|
||||
Meta.transform e (post := post)
|
||||
|
||||
|
||||
@@ -364,15 +364,30 @@ macro "mvcgen_trivial" : tactic =>
|
||||
)
|
||||
|
||||
/--
|
||||
An invariant alternative of the form `· term`, one per invariant goal.
|
||||
A goal section alternative of the form `· term`, one per goal.
|
||||
Used by both `invariants` and `witnesses` sections.
|
||||
-/
|
||||
syntax goalDotAlt := ppDedent(ppLine) cdotTk (colGe term)
|
||||
|
||||
/--
|
||||
An invariant alternative of the form `| inv<n> a b c => term`, one per invariant goal.
|
||||
A goal section alternative of the form `| label<n> a b c => term`, one per goal.
|
||||
Used by both `invariants` and `witnesses` sections.
|
||||
-/
|
||||
syntax goalCaseAlt := ppDedent(ppLine) "| " caseArg " => " (colGe term)
|
||||
|
||||
/--
|
||||
The contextual keyword ` witnesses `.
|
||||
-/
|
||||
syntax witnessesKW := &"witnesses "
|
||||
|
||||
/--
|
||||
After `mvcgen [...]`, there can be an optional `witnesses` followed by either
|
||||
* a bulleted list of witnesses `· term; · term`.
|
||||
* a labelled list of witnesses `| witness1 => term; witness2 a b c => term`, which is useful for
|
||||
naming inaccessibles.
|
||||
-/
|
||||
syntax witnessAlts := witnessesKW withPosition((colGe (goalDotAlt <|> goalCaseAlt))*)
|
||||
|
||||
/--
|
||||
Either the contextual keyword ` invariants ` or its tracing form ` invariants? ` which suggests
|
||||
skeletons for missing invariants as a hint.
|
||||
@@ -380,7 +395,7 @@ skeletons for missing invariants as a hint.
|
||||
syntax invariantsKW := &"invariants " <|> &"invariants? "
|
||||
|
||||
/--
|
||||
After `mvcgen [...]`, there can be an optional `invariants` followed by either
|
||||
After `mvcgen [...] witnesses ...`, there can be an optional `invariants` followed by either
|
||||
* a bulleted list of invariants `· term; · term`.
|
||||
* a labelled list of invariants `| inv1 => term; inv2 a b c => term`, which is useful for naming
|
||||
inaccessibles.
|
||||
@@ -404,7 +419,7 @@ syntax vcAlts := "with " (ppSpace colGt tactic)? withPosition((colGe vcAlt)*)
|
||||
@[tactic_alt Lean.Parser.Tactic.mvcgenMacro]
|
||||
syntax (name := mvcgen) "mvcgen" optConfig
|
||||
(" [" withoutPosition((simpStar <|> simpErase <|> simpLemma),*,?) "] ")?
|
||||
(invariantAlts)? (vcAlts)? : tactic
|
||||
(witnessAlts)? (invariantAlts)? (vcAlts)? : tactic
|
||||
|
||||
/--
|
||||
A hint tactic that expands to `mvcgen invariants?`.
|
||||
|
||||
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Some files were not shown because too many files have changed in this diff Show More
Reference in New Issue
Block a user