chore: Version 0.3 #136
4
Makefile
4
Makefile
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@ -1,9 +1,9 @@
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LIB := ./.lake/build/lib/Pantograph.olean
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LIB := ./.lake/build/lib/Pantograph.olean
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EXE := ./.lake/build/bin/pantograph
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EXE := ./.lake/build/bin/pantograph
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SOURCE := $(wildcard Pantograph/*.lean) $(wildcard *.lean) lean-toolchain
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SOURCE := $(wildcard *.lean Pantograph/*.lean Pantograph/**/*.lean) lean-toolchain
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TEST_EXE := ./.lake/build/bin/test
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TEST_EXE := ./.lake/build/bin/test
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TEST_SOURCE := $(wildcard Test/*.lean)
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TEST_SOURCE := $(wildcard Test/*.lean Test/**/*.lean)
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$(LIB) $(EXE): $(SOURCE)
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$(LIB) $(EXE): $(SOURCE)
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lake build pantograph
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lake build pantograph
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@ -126,7 +126,7 @@ protected def GoalState.continue (target: GoalState) (branch: GoalState): Except
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protected def GoalState.rootExpr? (goalState: GoalState): Option Expr := do
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protected def GoalState.rootExpr? (goalState: GoalState): Option Expr := do
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let expr ← goalState.mctx.eAssignment.find? goalState.root
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let expr ← goalState.mctx.eAssignment.find? goalState.root
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let (expr, _) := instantiateMVarsCore (mctx := goalState.mctx) (e := expr)
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let (expr, _) := instantiateMVarsCore (mctx := goalState.mctx) (e := expr)
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if expr.hasMVar then
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if expr.hasExprMVar then
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-- Must not assert that the goal state is empty here. We could be in a branch goal.
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-- Must not assert that the goal state is empty here. We could be in a branch goal.
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--assert! ¬goalState.goals.isEmpty
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--assert! ¬goalState.goals.isEmpty
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.none
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.none
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@ -9,6 +9,54 @@ def getForallArgsBody: Expr → List Expr × Expr
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let (innerArgs, innerBody) := getForallArgsBody b
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let (innerArgs, innerBody) := getForallArgsBody b
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(d :: innerArgs, innerBody)
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(d :: innerArgs, innerBody)
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| e => ([], e)
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| e => ([], e)
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def replaceForallBody: Expr → Expr → Expr
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| .forallE param domain body binderInfo, target =>
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let body := replaceForallBody body target
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.forallE param domain body binderInfo
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| _, target => target
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structure RecursorWithMotive where
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args: List Expr
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body: Expr
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-- .bvar index for the motive and major from the body
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iMotive: Nat
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iMajor: Nat
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namespace RecursorWithMotive
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protected def nArgs (info: RecursorWithMotive): Nat := info.args.length
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protected def getMotiveType (info: RecursorWithMotive): Expr :=
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let level := info.nArgs - info.iMotive - 1
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let a := info.args.get! level
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a
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protected def surrogateMotiveType (info: RecursorWithMotive) (resultant: Expr): MetaM Expr := do
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let motiveType := info.getMotiveType
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let resultantType ← Meta.inferType resultant
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return replaceForallBody motiveType resultantType
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protected def phantomType (info: RecursorWithMotive) (mvars: Array Expr) (resultant: Expr): MetaM Expr := do
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let goalMotive := mvars.get! (info.nArgs - info.iMotive - 1)
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let goalMajor := mvars.get! (info.nArgs - info.iMajor - 1)
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Meta.mkEq (.app goalMotive goalMajor) resultant
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end RecursorWithMotive
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def getRecursorInformation (recursorType: Expr): Option RecursorWithMotive := do
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let (args, body) := getForallArgsBody recursorType
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let (iMotive, iMajor) ← match body with
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| .app (.bvar iMotive) (.bvar iMajor) => pure (iMotive, iMajor)
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| _ => .none
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return {
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args,
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body,
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iMotive,
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iMajor,
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}
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def collectMotiveArguments (forallBody: Expr): SSet Nat :=
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def collectMotiveArguments (forallBody: Expr): SSet Nat :=
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match forallBody with
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match forallBody with
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| .app (.bvar i) _ => SSet.empty.insert i
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| .app (.bvar i) _ => SSet.empty.insert i
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@ -21,38 +69,38 @@ def motivatedApply: Elab.Tactic.Tactic := λ stx => do
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let recursor ← Elab.Term.elabTerm (stx := stx) .none
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let recursor ← Elab.Term.elabTerm (stx := stx) .none
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let recursorType ← Meta.inferType recursor
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let recursorType ← Meta.inferType recursor
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let (forallArgs, forallBody) := getForallArgsBody recursorType
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let resultant ← goal.getType
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let motiveIndices := collectMotiveArguments forallBody
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--IO.println s!"{motiveIndices.toList} from {← Meta.ppExpr forallBody}"
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let numArgs ← Meta.getExpectedNumArgs recursorType
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let info ← match getRecursorInformation recursorType with
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| .some info => pure info
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| .none => throwError "Recursor return type does not correspond with the invocation of a motive: {← Meta.ppExpr recursorType}"
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let rec go (i: Nat) (prev: Array Expr): MetaM (Array Expr) := do
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let rec go (i: Nat) (prev: Array Expr): MetaM (Array Expr) := do
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if i ≥ numArgs then
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if i ≥ info.nArgs then
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return prev
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return prev
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else
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else
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let argType := forallArgs.get! i
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let argType := info.args.get! i
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-- If `argType` has motive references, its goal needs to be placed in it
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-- If `argType` has motive references, its goal needs to be placed in it
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let argType := argType.instantiateRev prev
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let argType := argType.instantiateRev prev
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-- Create the goal
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let bvarIndex := info.nArgs - i - 1
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let userName := if motiveIndices.contains (numArgs - i - 1) then `motive else .anonymous
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let argGoal ← if bvarIndex = info.iMotive then
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let argGoal ← Meta.mkFreshExprMVar argType .syntheticOpaque (userName := userName)
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let surrogateMotiveType ← info.surrogateMotiveType resultant
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IO.println s!"Creating [{i}] {← Meta.ppExpr argGoal}"
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Meta.mkFreshExprMVar surrogateMotiveType .syntheticOpaque (userName := `motive)
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else if bvarIndex = info.iMajor then
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Meta.mkFreshExprMVar argType .syntheticOpaque (userName := `major)
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else
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Meta.mkFreshExprMVar argType .syntheticOpaque (userName := .anonymous)
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let prev := prev ++ [argGoal]
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let prev := prev ++ [argGoal]
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go (i + 1) prev
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go (i + 1) prev
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termination_by numArgs - i
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termination_by info.nArgs - i
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let newMVars ← go 0 #[]
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let mut newMVars ← go 0 #[]
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-- FIXME: Add an `Eq` target and swap out the motive type
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--let sourceType := forallBody.instantiateRev newMVars
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--unless ← withTheReader Meta.Context (λ ctx => { ctx with config := { ctx.config with } }) $
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-- Meta.isDefEq sourceType (← goal.getType) do
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-- throwError "invalid mapply: The resultant type {← Meta.ppExpr sourceType} cannot be unified with {← Meta.ppExpr $ ← goal.getType}"
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-- Create the main goal for the return type of the recursor
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goal.assign (mkAppN recursor newMVars)
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goal.assign (mkAppN recursor newMVars)
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let phantomType ← info.phantomType newMVars resultant
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let goalPhantom ← Meta.mkFreshExprMVar phantomType .syntheticOpaque (userName := `phantom)
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newMVars := newMVars ++ [goalPhantom]
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let nextGoals ← newMVars.toList.map (·.mvarId!) |>.filterM (not <$> ·.isAssigned)
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let nextGoals ← newMVars.toList.map (·.mvarId!) |>.filterM (not <$> ·.isAssigned)
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pure nextGoals
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pure nextGoals
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Elab.Tactic.setGoals nextGoals
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Elab.Tactic.setGoals nextGoals
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@ -63,6 +63,12 @@ def runMetaMSeq (env: Environment) (metaM: MetaM LSpec.TestSeq): IO LSpec.TestSe
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def runTermElabMInMeta { α } (termElabM: Lean.Elab.TermElabM α): Lean.MetaM α :=
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def runTermElabMInMeta { α } (termElabM: Lean.Elab.TermElabM α): Lean.MetaM α :=
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termElabM.run' (ctx := Pantograph.defaultTermElabMContext)
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termElabM.run' (ctx := Pantograph.defaultTermElabMContext)
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def exprToStr (e: Expr): Lean.MetaM String := toString <$> Meta.ppExpr e
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def runTacticOnMVar (tacticM: Elab.Tactic.TacticM Unit) (goal: MVarId): Elab.TermElabM (List MVarId) := do
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let (_, newGoals) ← tacticM { elaborator := .anonymous } |>.run { goals := [goal] }
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return newGoals.goals
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end Test
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end Test
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end Pantograph
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end Pantograph
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@ -661,9 +661,10 @@ def test_nat_zero_add: TestM Unit := do
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return ()
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return ()
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addTest $ LSpec.check s!"mapply {recursor}" ((← state2.serializeGoals (options := ← read)).map (·.devolatilizeVars) =
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addTest $ LSpec.check s!"mapply {recursor}" ((← state2.serializeGoals (options := ← read)).map (·.devolatilizeVars) =
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#[
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#[
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buildNamedGoal "_uniq.70" [("n", "Nat")] "Nat → Sort ?u.66" (.some "motive"),
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buildNamedGoal "_uniq.67" [("n", "Nat")] "Nat → Prop" (.some "motive"),
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buildNamedGoal "_uniq.71" [("n", "Nat")] "Nat",
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buildNamedGoal "_uniq.68" [("n", "Nat")] "Nat" (.some "major"),
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buildNamedGoal "_uniq.72" [("n", "Nat")] "(t : Nat) → Nat.below t → ?motive t"
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buildNamedGoal "_uniq.69" [("n", "Nat")] "∀ (t : Nat), Nat.below t → ?motive t",
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buildNamedGoal "_uniq.70" [("n", "Nat")] "?motive ?major = (n + 0 = n)" (.some "phantom")
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])
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])
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let tactic := "exact n"
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let tactic := "exact n"
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@ -710,6 +711,8 @@ def test_nat_zero_add: TestM Unit := do
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addTest $ LSpec.check tactic ((← stateF.serializeGoals (options := ← read)) =
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addTest $ LSpec.check tactic ((← stateF.serializeGoals (options := ← read)) =
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#[])
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#[])
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let expr := stateF.mctx.eAssignment.find! stateF.root
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let (expr, _) := instantiateMVarsCore (mctx := stateF.mctx) (e := expr)
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addTest $ LSpec.check "(F root)" stateF.rootExpr?.isSome
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addTest $ LSpec.check "(F root)" stateF.rootExpr?.isSome
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def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
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def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
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@ -1,11 +1,74 @@
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import LSpec
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import LSpec
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import Lean
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import Lean
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import Test.Common
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open Lean
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open Lean
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open Pantograph
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namespace Pantograph.Test.Tactic.MotivatedApply
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namespace Pantograph.Test.Tactic.MotivatedApply
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def valueAndType (recursor: String): MetaM (Expr × Expr) := do
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let recursor ← match Parser.runParserCategory
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(env := ← MonadEnv.getEnv)
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(catName := `term)
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(input := recursor)
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(fileName := filename) with
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| .ok syn => pure syn
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| .error error => throwError "Failed to parse: {error}"
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runTermElabMInMeta do
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let recursor ← Elab.Term.elabTerm (stx := recursor) .none
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let recursorType ← Meta.inferType recursor
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return (recursor, recursorType)
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def test_type_extract (env: Environment): IO LSpec.TestSeq :=
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runMetaMSeq env do
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let mut tests := LSpec.TestSeq.done
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let (recursor, recursorType) ← valueAndType "@Nat.brecOn"
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tests := tests ++ LSpec.check "recursorType" ("{motive : Nat → Sort ?u.1} → (t : Nat) → ((t : Nat) → Nat.below t → motive t) → motive t" =
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(← exprToStr recursorType))
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let info ← match Tactic.getRecursorInformation recursorType with
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| .some info => pure info
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| .none => throwError "Failed to extract recursor info"
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tests := tests ++ LSpec.check "iMotive" (info.iMotive = 2)
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tests := tests ++ LSpec.check "iMajor" (info.iMajor = 1)
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let motiveType := info.getMotiveType
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tests := tests ++ LSpec.check "motiveType" ("Nat → Sort ?u.1" =
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(← exprToStr motiveType))
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return tests
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def test_execute (env: Environment): IO LSpec.TestSeq :=
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let expr := "λ (n t: Nat) => n + 0 = n"
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runMetaMSeq env do
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let (expr, exprType) ← valueAndType expr
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Meta.lambdaTelescope expr $ λ _ body => do
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let recursor ← match Parser.runParserCategory
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(env := ← MonadEnv.getEnv)
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(catName := `term)
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(input := "@Nat.brecOn")
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(fileName := filename) with
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| .ok syn => pure syn
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| .error error => throwError "Failed to parse: {error}"
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|
let mut tests := LSpec.TestSeq.done
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-- Apply the tactic
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let target ← Meta.mkFreshExprSyntheticOpaqueMVar body
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let tactic := Tactic.motivatedApply recursor
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let test ← runTermElabMInMeta do
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let newGoals ← runTacticOnMVar tactic target.mvarId!
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pure $ LSpec.check "goals" ((← newGoals.mapM (λ g => do exprToStr (← g.getType))) =
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[
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"Nat → Prop",
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"Nat",
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"∀ (t : Nat), Nat.below t → ?motive t",
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"?motive ?major = (n + 0 = n)",
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|
])
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tests := tests ++ test
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return tests
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|
|
||||||
def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
|
def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
|
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[]
|
[
|
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|
("type_extract", test_type_extract env),
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("execute", test_execute env),
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|
]
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|
|
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end Pantograph.Test.Tactic.MotivatedApply
|
end Pantograph.Test.Tactic.MotivatedApply
|
||||||
|
|
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