feat: `GoalState.tryHave` tactic (tests failing)
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@ -10,6 +10,8 @@ def Lean.MessageLog.getErrorMessages (log : MessageLog) : MessageLog :=
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namespace Pantograph
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open Lean
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def filename: String := "<pantograph>"
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structure GoalState where
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savedState : Elab.Tactic.SavedState
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@ -18,9 +20,6 @@ structure GoalState where
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-- New metavariables acquired in this state
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newMVars: SSet MVarId
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-- The id of the goal in the parent
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parentGoalId: Nat := 0
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-- Parent state metavariable source
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parentMVar: Option MVarId
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@ -56,7 +55,7 @@ private def GoalState.mvars (state: GoalState): SSet MVarId :=
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state.mctx.decls.foldl (init := .empty) fun acc k _ => acc.insert k
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private def GoalState.restoreElabM (state: GoalState): Elab.TermElabM Unit :=
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state.savedState.term.restore
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def GoalState.restoreMetaM (state: GoalState): MetaM Unit :=
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protected def GoalState.restoreMetaM (state: GoalState): MetaM Unit :=
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state.savedState.term.meta.restore
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/-- Inner function for executing tactic on goal state -/
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@ -89,7 +88,7 @@ inductive TacticResult where
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| indexError (goalId: Nat)
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/-- Execute tactic on given state -/
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protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String):
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protected def GoalState.tryTactic (state: GoalState) (goalId: Nat) (tactic: String):
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M TacticResult := do
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state.restoreElabM
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let goal ← match state.savedState.tactic.goals.get? goalId with
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@ -99,7 +98,7 @@ protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String
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(env := ← MonadEnv.getEnv)
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(catName := `tactic)
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(input := tactic)
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(fileName := "<stdin>") with
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(fileName := filename) with
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| .ok stx => pure $ stx
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| .error error => return .parseError error
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match (← executeTactic (state := state.savedState) (goal := goal) (tactic := tactic)) with
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@ -122,10 +121,48 @@ protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String
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root := state.root,
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savedState := nextSavedState
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newMVars,
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parentGoalId := goalId,
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parentMVar := .some goal,
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}
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/-- Assumes elabM has already been restored -/
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protected def GoalState.assign (state: GoalState) (goal: MVarId) (expr: Expr): M TacticResult := do
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let goalType ← goal.getType
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try
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let exprType ← Meta.inferType expr
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-- This elaboration is necessary
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if !(← Meta.isDefEq goalType exprType) then
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return .failure #["Type unification failed", toString (← Meta.ppExpr goalType), toString (← Meta.ppExpr exprType)]
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goal.checkNotAssigned `GoalState.tryAssign
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goal.assign expr
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if (← getThe Core.State).messages.hasErrors then
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let messages := (← getThe Core.State).messages.getErrorMessages |>.toList.toArray
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let errors ← (messages.map Message.data).mapM fun md => md.toString
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return .failure errors
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else
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let prevMCtx := state.savedState.term.meta.meta.mctx
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let nextMCtx ← getMCtx
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-- Generate a list of mvarIds that exist in the parent state; Also test the
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-- assertion that the types have not changed on any mvars.
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let newMVars ← nextMCtx.decls.foldlM (fun acc mvarId mvarDecl => do
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if let .some prevMVarDecl := prevMCtx.decls.find? mvarId then
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assert! prevMVarDecl.type == mvarDecl.type
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return acc
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else
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return mvarId :: acc
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) []
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let nextGoals ← newMVars.filterM (λ mvar => do pure !(← mvar.isAssigned))
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return .success {
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root := state.root,
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savedState := {
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term := ← MonadBacktrack.saveState,
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tactic := { goals := nextGoals }
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},
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newMVars := newMVars.toSSet,
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parentMVar := .some goal,
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}
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catch exception =>
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return .failure #[← exception.toMessageData.toString]
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protected def GoalState.tryAssign (state: GoalState) (goalId: Nat) (expr: String): M TacticResult := do
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state.restoreElabM
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let goal ← match state.savedState.tactic.goals.get? goalId with
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@ -135,50 +172,43 @@ protected def GoalState.tryAssign (state: GoalState) (goalId: Nat) (expr: String
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(env := state.env)
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(catName := `term)
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(input := expr)
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(fileName := "<stdin>") with
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(fileName := filename) with
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| .ok syn => pure syn
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| .error error => return .parseError error
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let tacticM: Elab.Tactic.TacticM TacticResult := do
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state.savedState.restore
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Elab.Tactic.setGoals [goal]
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try
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let expr ← Elab.Term.elabTerm (stx := expr) (expectedType? := .none)
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-- Attempt to unify the expression
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let goalType ← goal.getType
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let exprType ← Meta.inferType expr
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if !(← Meta.isDefEq goalType exprType) then
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return .failure #["Type unification failed", toString (← Meta.ppExpr goalType), toString (← Meta.ppExpr exprType)]
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goal.checkNotAssigned `GoalState.tryAssign
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goal.assign expr
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if (← getThe Core.State).messages.hasErrors then
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let messages := (← getThe Core.State).messages.getErrorMessages |>.toList.toArray
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let errors ← (messages.map Message.data).mapM fun md => md.toString
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return .failure errors
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else
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let prevMCtx := state.savedState.term.meta.meta.mctx
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let nextMCtx ← getMCtx
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-- Generate a list of mvarIds that exist in the parent state; Also test the
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-- assertion that the types have not changed on any mvars.
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let newMVars ← nextMCtx.decls.foldlM (fun acc mvarId mvarDecl => do
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if let .some prevMVarDecl := prevMCtx.decls.find? mvarId then
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assert! prevMVarDecl.type == mvarDecl.type
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return acc
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else
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return mvarId :: acc
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) []
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-- The new goals are the newMVars that lack an assignment
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Elab.Tactic.setGoals (← newMVars.filterM (λ mvar => do pure !(← mvar.isAssigned)))
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let nextSavedState ← MonadBacktrack.saveState
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return .success {
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root := state.root,
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savedState := nextSavedState,
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newMVars := newMVars.toSSet,
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parentGoalId := goalId,
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parentMVar := .some goal,
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}
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catch exception =>
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return .failure #[← exception.toMessageData.toString]
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tacticM { elaborator := .anonymous } |>.run' state.savedState.tactic
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let goalType ← goal.getType
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try
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let expr ← Elab.Term.elabTermAndSynthesize (stx := expr) (expectedType? := .some goalType)
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state.assign goal expr
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catch exception =>
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return .failure #[← exception.toMessageData.toString]
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-- Specialized Tactics
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protected def GoalState.tryHave (state: GoalState) (goalId: Nat) (binderName: String) (type: String): M TacticResult := do
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state.restoreElabM
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let goal ← match state.savedState.tactic.goals.get? goalId with
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| .some goal => pure goal
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| .none => return .indexError goalId
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let type ← match Parser.runParserCategory
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(env := state.env)
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(catName := `term)
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(input := type)
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(fileName := filename) with
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| .ok syn => pure syn
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| .error error => return .parseError error
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try
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let type ← Elab.Term.elabType (stx := type)
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-- The branch created by "have"
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let mvarBranch ← Meta.mkFreshExprSyntheticOpaqueMVar type
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-- The main branch
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let mvarUpstream ← Meta.mkFreshExprSyntheticOpaqueMVar (← goal.getType)
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let expr := Expr.app (.lam binderName.toName type mvarBranch .default) mvarUpstream
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state.assign goal expr
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catch exception =>
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return .failure #[← exception.toMessageData.toString]
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/--
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Brings into scope a list of goals
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@ -160,7 +160,7 @@ def goalStartExpr (expr: String): Lean.CoreM (Protocol.CR GoalState) :=
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@[export pantograph_goal_tactic_m]
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def goalTactic (state: GoalState) (goalId: Nat) (tactic: String): Lean.CoreM TacticResult :=
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runTermElabM <| GoalState.execute state goalId tactic
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runTermElabM <| GoalState.tryTactic state goalId tactic
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@[export pantograph_goal_try_assign_m]
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def goalTryAssign (state: GoalState) (goalId: Nat) (expr: String): Lean.CoreM TacticResult :=
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@ -251,9 +251,7 @@ protected def GoalState.serializeGoals
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MetaM (Array Protocol.Goal):= do
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state.restoreMetaM
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let goals := state.goals.toArray
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let parentDecl? := parent.bind (λ parentState =>
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let parentGoal := parentState.goals.get! state.parentGoalId
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parentState.mctx.findDecl? parentGoal)
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let parentDecl? := parent.bind (λ parentState => parentState.mctx.findDecl? state.parentMVar.get!)
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goals.mapM fun goal => do
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match state.mctx.findDecl? goal with
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| .some mvarDecl =>
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@ -84,7 +84,7 @@ def test_m_couple: TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply Nat.le_trans") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "apply Nat.le_trans") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -93,7 +93,7 @@ def test_m_couple: TestM Unit := do
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#[.some "2 ≤ ?m", .some "?m ≤ 5", .some "Nat"])
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addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
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-- Set m to 3
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let state2 ← match ← state1.execute (goalId := 2) (tactic := "exact 3") with
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let state2 ← match ← state1.tryTactic (goalId := 2) (tactic := "exact 3") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -116,14 +116,14 @@ def test_m_couple_simp: TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply Nat.le_trans") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "apply Nat.le_trans") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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return ()
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addTest $ LSpec.check "apply Nat.le_trans" ((← state1.serializeGoals (options := ← read)).map (·.target.pp?) =
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#[.some "2 ≤ ?m", .some "?m ≤ 5", .some "Nat"])
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let state2 ← match ← state1.execute (goalId := 2) (tactic := "exact 2") with
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let state2 ← match ← state1.tryTactic (goalId := 2) (tactic := "exact 2") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -137,7 +137,7 @@ def test_m_couple_simp: TestM Unit := do
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addTest $ LSpec.check "exact 2" ((← state1b.serializeGoals (options := ← read)).map (·.target.pp?) =
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#[.some "2 ≤ 2", .some "2 ≤ 5"])
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addTest $ LSpec.test "(2 root)" state1b.rootExpr?.isNone
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let state3 ← match ← state1b.execute (goalId := 0) (tactic := "simp") with
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let state3 ← match ← state1b.tryTactic (goalId := 0) (tactic := "simp") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -147,7 +147,7 @@ def test_m_couple_simp: TestM Unit := do
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addTest $ assertUnreachable $ msg
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return ()
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| .ok state => pure state
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let state5 ← match ← state4.execute (goalId := 0) (tactic := "simp") with
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let state5 ← match ← state4.tryTactic (goalId := 0) (tactic := "simp") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -174,7 +174,7 @@ def test_proposition_generation: TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply PSigma.mk") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "apply PSigma.mk") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -216,7 +216,7 @@ def test_partial_continuation: TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply Nat.le_trans") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "apply Nat.le_trans") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -224,7 +224,7 @@ def test_partial_continuation: TestM Unit := do
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addTest $ LSpec.check "apply Nat.le_trans" ((← state1.serializeGoals (options := ← read)).map (·.target.pp?) =
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#[.some "2 ≤ ?m", .some "?m ≤ 5", .some "Nat"])
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let state2 ← match ← state1.execute (goalId := 2) (tactic := "apply Nat.succ") with
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let state2 ← match ← state1.tryTactic (goalId := 2) (tactic := "apply Nat.succ") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -75,7 +75,7 @@ def proofRunner (env: Lean.Environment) (tests: TestM Unit): IO LSpec.TestSeq :=
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example: ∀ (a b: Nat), a + b = b + a := by
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intro n m
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rw [Nat.add_comm]
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def proof_nat_add_comm (manual: Bool): TestM Unit := do
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def test_nat_add_comm (manual: Bool): TestM Unit := do
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let state? ← startProof <| match manual with
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| false => .copy "Nat.add_comm"
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| true => .expr "∀ (a b: Nat), a + b = b + a"
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@ -86,7 +86,7 @@ def proof_nat_add_comm (manual: Bool): TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "intro n m") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "intro n m") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -94,13 +94,13 @@ def proof_nat_add_comm (manual: Bool): TestM Unit := do
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addTest $ LSpec.check "intro n m" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
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#[buildGoal [("n", "Nat"), ("m", "Nat")] "n + m = m + n"])
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match ← state1.execute (goalId := 0) (tactic := "assumption") with
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match ← state1.tryTactic (goalId := 0) (tactic := "assumption") with
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| .failure #[message] =>
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addTest $ LSpec.check "assumption" (message = "tactic 'assumption' failed\nn m : Nat\n⊢ n + m = m + n")
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| other => do
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addTest $ assertUnreachable $ other.toString
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let state2 ← match ← state1.execute (goalId := 0) (tactic := "rw [Nat.add_comm]") with
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let state2 ← match ← state1.tryTactic (goalId := 0) (tactic := "rw [Nat.add_comm]") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -108,7 +108,7 @@ def proof_nat_add_comm (manual: Bool): TestM Unit := do
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addTest $ LSpec.test "rw [Nat.add_comm]" state2.goals.isEmpty
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return ()
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def proof_delta_variable: TestM Unit := do
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def test_delta_variable: TestM Unit := do
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let options: Protocol.Options := { noRepeat := true }
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let state? ← startProof <| .expr "∀ (a b: Nat), a + b = b + a"
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addTest $ LSpec.check "Start goal" state?.isSome
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@ -118,14 +118,14 @@ def proof_delta_variable: TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "intro n") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "intro n") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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return ()
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addTest $ LSpec.check "intro n" ((← state1.serializeGoals (parent := state0) options).map (·.devolatilize) =
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#[buildGoalSelective [("n", .some "Nat")] "∀ (b : Nat), n + b = b + n"])
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let state2 ← match ← state1.execute (goalId := 0) (tactic := "intro m") with
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let state2 ← match ← state1.tryTactic (goalId := 0) (tactic := "intro m") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
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@ -149,7 +149,7 @@ example (w x y z : Nat) (p : Nat → Prop)
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(h : p (x * y + z * w * x)) : p (x * w * z + y * x) := by
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simp [Nat.add_assoc, Nat.add_comm, Nat.add_left_comm, Nat.mul_comm, Nat.mul_assoc, Nat.mul_left_comm] at *
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assumption
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def proof_arith: TestM Unit := do
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def test_arith: TestM Unit := do
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let state? ← startProof (.expr "∀ (w x y z : Nat) (p : Nat → Prop) (h : p (x * y + z * w * x)), p (x * w * z + y * x)")
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let state0 ← match state? with
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| .some state => pure state
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@ -157,21 +157,21 @@ def proof_arith: TestM Unit := do
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addTest $ assertUnreachable "Goal could not parse"
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return ()
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let state1 ← match ← state0.execute (goalId := 0) (tactic := "intros") with
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let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "intros") with
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| .success state => pure state
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| other => do
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addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "intros" (state1.goals.length = 1)
|
||||
addTest $ LSpec.test "(1 root)" state1.rootExpr?.isNone
|
||||
let state2 ← match ← state1.execute (goalId := 0) (tactic := "simp [Nat.add_assoc, Nat.add_comm, Nat.add_left_comm, Nat.mul_comm, Nat.mul_assoc, Nat.mul_left_comm] at *") with
|
||||
let state2 ← match ← state1.tryTactic (goalId := 0) (tactic := "simp [Nat.add_assoc, Nat.add_comm, Nat.add_left_comm, Nat.mul_comm, Nat.mul_assoc, Nat.mul_left_comm] at *") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "simp ..." (state2.goals.length = 1)
|
||||
addTest $ LSpec.check "(2 root)" state2.rootExpr?.isNone
|
||||
let state3 ← match ← state2.execute (goalId := 0) (tactic := "assumption") with
|
||||
let state3 ← match ← state2.tryTactic (goalId := 0) (tactic := "assumption") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
|
@ -195,7 +195,7 @@ example: ∀ (p q: Prop), p ∨ q → q ∨ p := by
|
|||
assumption
|
||||
. apply Or.inl
|
||||
assumption
|
||||
def proof_or_comm: TestM Unit := do
|
||||
def test_or_comm: TestM Unit := do
|
||||
let state? ← startProof (.expr "∀ (p q: Prop), p ∨ q → q ∨ p")
|
||||
let state0 ← match state? with
|
||||
| .some state => pure state
|
||||
|
@ -205,16 +205,16 @@ def proof_or_comm: TestM Unit := do
|
|||
addTest $ LSpec.check "(0 parent)" state0.parentExpr?.isNone
|
||||
addTest $ LSpec.check "(0 root)" state0.rootExpr?.isNone
|
||||
|
||||
let state1 ← match ← state0.execute (goalId := 0) (tactic := "intro p q h") with
|
||||
let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "intro p q h") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "intro n m" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
|
||||
addTest $ LSpec.check "intro p q h" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
|
||||
#[buildGoal [("p", "Prop"), ("q", "Prop"), ("h", "p ∨ q")] "q ∨ p"])
|
||||
addTest $ LSpec.check "(1 parent)" state1.parentExpr?.isSome
|
||||
addTest $ LSpec.check "(1 root)" state1.rootExpr?.isNone
|
||||
let state2 ← match ← state1.execute (goalId := 0) (tactic := "cases h") with
|
||||
let state2 ← match ← state1.tryTactic (goalId := 0) (tactic := "cases h") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
|
@ -229,7 +229,7 @@ def proof_or_comm: TestM Unit := do
|
|||
addTest $ LSpec.test "(2 parent)" (state2parent ==
|
||||
"((:mv _uniq.43) (:fv _uniq.16) ((:c Eq.refl) ((:c Or) (:fv _uniq.10) (:fv _uniq.13)) (:fv _uniq.16)))")
|
||||
|
||||
let state3_1 ← match ← state2.execute (goalId := 0) (tactic := "apply Or.inr") with
|
||||
let state3_1 ← match ← state2.tryTactic (goalId := 0) (tactic := "apply Or.inr") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
|
@ -237,7 +237,7 @@ def proof_or_comm: TestM Unit := do
|
|||
let state3_1parent ← serialize_expression_ast state3_1.parentExpr?.get! (sanitize := false)
|
||||
addTest $ LSpec.test "(3_1 parent)" (state3_1parent == "((:c Or.inr) (:fv _uniq.13) (:fv _uniq.10) (:mv _uniq.78))")
|
||||
addTest $ LSpec.check "· apply Or.inr" (state3_1.goals.length = 1)
|
||||
let state4_1 ← match ← state3_1.execute (goalId := 0) (tactic := "assumption") with
|
||||
let state4_1 ← match ← state3_1.tryTactic (goalId := 0) (tactic := "assumption") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
|
@ -246,13 +246,13 @@ def proof_or_comm: TestM Unit := do
|
|||
let state4_1parent ← serialize_expression_ast state4_1.parentExpr?.get! (sanitize := false)
|
||||
addTest $ LSpec.test "(4_1 parent)" (state4_1parent == "(:fv _uniq.47)")
|
||||
addTest $ LSpec.check "(4_1 root)" state4_1.rootExpr?.isNone
|
||||
let state3_2 ← match ← state2.execute (goalId := 1) (tactic := "apply Or.inl") with
|
||||
let state3_2 ← match ← state2.tryTactic (goalId := 1) (tactic := "apply Or.inl") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "· apply Or.inl" (state3_2.goals.length = 1)
|
||||
let state4_2 ← match ← state3_2.execute (goalId := 0) (tactic := "assumption") with
|
||||
let state4_2 ← match ← state3_2.tryTactic (goalId := 0) (tactic := "assumption") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
|
@ -266,13 +266,13 @@ def proof_or_comm: TestM Unit := do
|
|||
return ()
|
||||
| .ok state => pure state
|
||||
addTest $ LSpec.test "(resume)" (state2b.goals == [state2.goals.get! 0])
|
||||
let state3_1 ← match ← state2b.execute (goalId := 0) (tactic := "apply Or.inr") with
|
||||
let state3_1 ← match ← state2b.tryTactic (goalId := 0) (tactic := "apply Or.inr") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "· apply Or.inr" (state3_1.goals.length = 1)
|
||||
let state4_1 ← match ← state3_1.execute (goalId := 0) (tactic := "assumption") with
|
||||
let state4_1 ← match ← state3_1.tryTactic (goalId := 0) (tactic := "assumption") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
|
@ -292,14 +292,48 @@ def proof_or_comm: TestM Unit := do
|
|||
{ userName := "h✝", type? := .some { pp? := .some varName }, isInaccessible? := .some true }
|
||||
]
|
||||
}
|
||||
def test_have_tactic: TestM Unit := do
|
||||
let state? ← startProof (.expr "∀ (p q: Prop), p → ((p ∨ q) ∨ (p ∨ q))")
|
||||
let state0 ← match state? with
|
||||
| .some state => pure state
|
||||
| .none => do
|
||||
addTest $ assertUnreachable "Goal could not parse"
|
||||
return ()
|
||||
addTest $ LSpec.check "(0 parent)" state0.parentExpr?.isNone
|
||||
addTest $ LSpec.check "(0 root)" state0.rootExpr?.isNone
|
||||
|
||||
let state1 ← match ← state0.tryTactic (goalId := 0) (tactic := "intro p q h") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "intro p q h" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
|
||||
#[buildGoal [("p", "Prop"), ("q", "Prop"), ("h", "p")] "(p ∨ q) ∨ p ∨ q"])
|
||||
|
||||
let state2 ← match ← state1.tryAssign (goalId := 0) (expr := "Or.inl (Or.inl h)") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "have" ((← state2.serializeGoals (options := ← read)).map (·.devolatilize) =
|
||||
#[buildGoal [] ""])
|
||||
|
||||
let state2 ← match ← state1.tryHave (goalId := 0) (binderName := "y") (type := "p ∨ q") with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
addTest $ LSpec.check "have" ((← state2.serializeGoals (options := ← read)).map (·.devolatilize) =
|
||||
#[buildGoal [] ""])
|
||||
|
||||
def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
|
||||
let tests := [
|
||||
("Nat.add_comm", proof_nat_add_comm false),
|
||||
("Nat.add_comm manual", proof_nat_add_comm true),
|
||||
("Nat.add_comm delta", proof_delta_variable),
|
||||
("arithmetic", proof_arith),
|
||||
("Or.comm", proof_or_comm)
|
||||
("Nat.add_comm", test_nat_add_comm false),
|
||||
("Nat.add_comm manual", test_nat_add_comm true),
|
||||
("Nat.add_comm delta", test_delta_variable),
|
||||
("arithmetic", test_arith),
|
||||
("Or.comm", test_or_comm),
|
||||
("Have", test_have_tactic),
|
||||
]
|
||||
tests.map (fun (name, test) => (name, proofRunner env test))
|
||||
|
||||
|
|
Loading…
Reference in New Issue