import Pantograph.Goal import Pantograph.Library import Pantograph.Protocol import Lean import LSpec open Lean namespace Pantograph deriving instance Repr for Expr -- Use strict equality check for expressions instance : BEq Expr := ⟨Expr.equal⟩ def uniq (n: Nat): Name := .num (.str .anonymous "_uniq") n -- Auxiliary functions namespace Protocol def Goal.devolatilizeVars (goal: Goal): Goal := { goal with vars := goal.vars.map removeInternalAux, } where removeInternalAux (v: Variable): Variable := { v with name := "" } /-- Set internal names to "" -/ def Goal.devolatilize (goal: Goal): Goal := { goal.devolatilizeVars with name := "", } deriving instance DecidableEq, Repr for Name deriving instance DecidableEq, Repr for Expression deriving instance DecidableEq, Repr for Variable deriving instance DecidableEq, Repr for Goal deriving instance DecidableEq, Repr for ExprEchoResult deriving instance DecidableEq, Repr for InteractionError deriving instance DecidableEq, Repr for Option end Protocol namespace Condensed deriving instance BEq, Repr for LocalDecl deriving instance BEq, Repr for Goal protected def LocalDecl.devolatilize (decl: LocalDecl): LocalDecl := { decl with fvarId := { name := .anonymous } } protected def Goal.devolatilize (goal: Goal): Goal := { goal with mvarId := { name := .anonymous }, context := goal.context.map LocalDecl.devolatilize } end Condensed def GoalState.get! (state: GoalState) (i: Nat): MVarId := state.goals.get! i def GoalState.tacticOn (state: GoalState) (goalId: Nat) (tactic: String) := state.tryTactic (state.goals.get! goalId) tactic def TacticResult.toString : TacticResult → String | .success state => s!".success ({state.goals.length} goals)" | .failure messages => let messages := "\n".intercalate messages.toList s!".failure {messages}" | .parseError error => s!".parseError {error}" | .invalidAction error => s!".invalidAction {error}" namespace Test def expectationFailure (desc: String) (error: String): LSpec.TestSeq := LSpec.test desc (LSpec.ExpectationFailure "ok _" error) def assertUnreachable (message: String): LSpec.TestSeq := LSpec.check message false def parseFailure (error: String) := expectationFailure "parse" error def elabFailure (error: String) := expectationFailure "elab" error def runCoreMSeq (env: Environment) (coreM: CoreM LSpec.TestSeq) (options: Array String := #[]): IO LSpec.TestSeq := do let coreContext: Core.Context ← createCoreContext options match ← (coreM.run' coreContext { env := env }).toBaseIO with | .error exception => return LSpec.test "Exception" (s!"internal exception #{← exception.toMessageData.toString}" = "") | .ok a => return a def runMetaMSeq (env: Environment) (metaM: MetaM LSpec.TestSeq): IO LSpec.TestSeq := runCoreMSeq env metaM.run' def runTermElabMInMeta { α } (termElabM: Lean.Elab.TermElabM α): Lean.MetaM α := termElabM.run' (ctx := defaultElabContext) def runTermElabMSeq (env: Environment) (termElabM: Elab.TermElabM LSpec.TestSeq): IO LSpec.TestSeq := runMetaMSeq env $ termElabM.run' (ctx := defaultElabContext) def exprToStr (e: Expr): Lean.MetaM String := toString <$> Meta.ppExpr e def strToTermSyntax [Monad m] [MonadEnv m] (s: String): m Syntax := do let .ok stx := Parser.runParserCategory (env := ← MonadEnv.getEnv) (catName := `term) (input := s) (fileName := filename) | panic! s!"Failed to parse {s}" return stx def parseSentence (s: String): Elab.TermElabM Expr := do let stx ← match Parser.runParserCategory (env := ← MonadEnv.getEnv) (catName := `term) (input := s) (fileName := filename) with | .ok syn => pure syn | .error error => throwError "Failed to parse: {error}" Elab.Term.elabTerm (stx := stx) .none def runTacticOnMVar (tacticM: Elab.Tactic.TacticM Unit) (goal: MVarId): Elab.TermElabM (List MVarId) := do let (_, newGoals) ← tacticM { elaborator := .anonymous } |>.run { goals := [goal] } return newGoals.goals def mvarUserNameAndType (mvarId: MVarId): MetaM (Name × String) := do let name := (← mvarId.getDecl).userName let t ← exprToStr (← mvarId.getType) return (name, t) -- Monadic testing abbrev TestT := StateT LSpec.TestSeq def addTest [Monad m] (test: LSpec.TestSeq) : TestT m Unit := do set $ (← get) ++ test def checkEq [Monad m] [DecidableEq α] (desc : String) (lhs rhs : α) : TestT m Unit := do addTest $ LSpec.check desc (lhs == rhs) def checkTrue [Monad m] (desc : String) (flag : Bool) : TestT m Unit := do addTest $ LSpec.check desc flag def fail [Monad m] (desc : String) : TestT m Unit := do addTest $ LSpec.check desc false def runTest [Monad m] (t: TestT m Unit): m LSpec.TestSeq := Prod.snd <$> t.run LSpec.TestSeq.done def runTestWithResult { α } [Monad m] (t: TestT m α): m (α × LSpec.TestSeq) := t.run LSpec.TestSeq.done def runTestTermElabM (env: Environment) (t: TestT Elab.TermElabM Unit): IO LSpec.TestSeq := runTermElabMSeq env $ runTest t def cdeclOf (userName: Name) (type: Expr): Condensed.LocalDecl := { userName, type } def buildGoal (nameType: List (String × String)) (target: String) (userName?: Option String := .none): Protocol.Goal := { userName?, target := { pp? := .some target}, vars := (nameType.map fun x => ({ userName := x.fst, type? := .some { pp? := .some x.snd }, })).toArray } end Test end Pantograph