chore: Version 0.3 #136

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aniva wants to merge 487 commits from dev into main
4 changed files with 112 additions and 24 deletions
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@ -47,13 +47,15 @@ protected def GoalState.runM {α: Type} (state: GoalState) (m: Elab.TermElabM α
protected def GoalState.mctx (state: GoalState): MetavarContext := protected def GoalState.mctx (state: GoalState): MetavarContext :=
state.savedState.term.meta.meta.mctx state.savedState.term.meta.meta.mctx
protected def GoalState.env (state: GoalState): Environment :=
state.savedState.term.meta.core.env
private def GoalState.mvars (state: GoalState): SSet MVarId := private def GoalState.mvars (state: GoalState): SSet MVarId :=
state.mctx.decls.foldl (init := .empty) fun acc k _ => acc.insert k state.mctx.decls.foldl (init := .empty) fun acc k _ => acc.insert k
/-- Inner function for executing tactic on goal state -/ /-- Inner function for executing tactic on goal state -/
def executeTactic (state: Elab.Tactic.SavedState) (goal: MVarId) (tactic: Syntax) : def executeTactic (state: Elab.Tactic.SavedState) (goal: MVarId) (tactic: Syntax) :
M (Except (Array String) (Elab.Tactic.SavedState × List MVarId)):= do M (Except (Array String) Elab.Tactic.SavedState):= do
let tacticM (stx: Syntax): Elab.Tactic.TacticM (Except (Array String) (Elab.Tactic.SavedState × List MVarId)) := do let tacticM (stx: Syntax): Elab.Tactic.TacticM (Except (Array String) Elab.Tactic.SavedState) := do
state.restore state.restore
Elab.Tactic.setGoals [goal] Elab.Tactic.setGoals [goal]
try try
@ -63,9 +65,7 @@ def executeTactic (state: Elab.Tactic.SavedState) (goal: MVarId) (tactic: Syntax
let errors ← (messages.map Message.data).mapM fun md => md.toString let errors ← (messages.map Message.data).mapM fun md => md.toString
return .error errors return .error errors
else else
let unsolved ← Elab.Tactic.getUnsolvedGoals return .ok (← MonadBacktrack.saveState)
-- The order of evaluation is important here, since `getUnsolvedGoals` prunes the goals set
return .ok (← MonadBacktrack.saveState, unsolved)
catch exception => catch exception =>
return .error #[← exception.toMessageData.toString] return .error #[← exception.toMessageData.toString]
tacticM tactic { elaborator := .anonymous } |>.run' state.tactic tacticM tactic { elaborator := .anonymous } |>.run' state.tactic
@ -97,8 +97,7 @@ protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String
match (← executeTactic (state := state.savedState) (goal := goal) (tactic := tactic)) with match (← executeTactic (state := state.savedState) (goal := goal) (tactic := tactic)) with
| .error errors => | .error errors =>
return .failure errors return .failure errors
| .ok (nextSavedState, nextGoals) => | .ok nextSavedState =>
assert! nextSavedState.tactic.goals.length == nextGoals.length
-- Assert that the definition of metavariables are the same -- Assert that the definition of metavariables are the same
let nextMCtx := nextSavedState.term.meta.meta.mctx let nextMCtx := nextSavedState.term.meta.meta.mctx
let prevMCtx := state.savedState.term.meta.meta.mctx let prevMCtx := state.savedState.term.meta.meta.mctx
@ -112,12 +111,64 @@ protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String
return acc.insert mvarId return acc.insert mvarId
) SSet.empty ) SSet.empty
return .success { return .success {
state with
savedState := nextSavedState savedState := nextSavedState
root := state.root,
newMVars, newMVars,
parentGoalId := goalId, parentGoalId := goalId,
} }
protected def GoalState.tryAssign (state: GoalState) (goalId: Nat) (expr: String): M TacticResult := do
let goal ← match state.savedState.tactic.goals.get? goalId with
| .some goal => pure goal
| .none => return .indexError goalId
let expr ← match Parser.runParserCategory
(env := state.env)
(catName := `term)
(input := expr)
(fileName := "<stdin>") with
| .ok syn => pure syn
| .error error => return .parseError error
let tacticM: Elab.Tactic.TacticM TacticResult := do
state.savedState.restore
Elab.Tactic.setGoals [goal]
try
let expr ← Elab.Term.elabTerm (stx := expr) (expectedType? := .none)
-- Attempt to unify the expression
let goalType ← goal.getType
let exprType ← Meta.inferType expr
if !(← Meta.isDefEq goalType exprType) then
return .failure #["Type unification failed", toString (← Meta.ppExpr goalType), toString (← Meta.ppExpr exprType)]
goal.checkNotAssigned `GoalState.tryAssign
goal.assign expr
if (← getThe Core.State).messages.hasErrors then
let messages := (← getThe Core.State).messages.getErrorMessages |>.toList.toArray
let errors ← (messages.map Message.data).mapM fun md => md.toString
return .failure errors
else
let prevMCtx := state.savedState.term.meta.meta.mctx
let nextMCtx ← getMCtx
-- Generate a list of mvarIds that exist in the parent state; Also test the
-- assertion that the types have not changed on any mvars.
let newMVars ← nextMCtx.decls.foldlM (fun acc mvarId mvarDecl => do
if let .some prevMVarDecl := prevMCtx.decls.find? mvarId then
assert! prevMVarDecl.type == mvarDecl.type
return acc
else
return mvarId :: acc
) []
-- The new goals are the newMVars that lack an assignment
Elab.Tactic.setGoals (← newMVars.filterM (λ mvar => do pure !(← mvar.isAssigned)))
let nextSavedState ← MonadBacktrack.saveState
return .success {
state with
savedState := nextSavedState,
newMVars := newMVars.toSSet,
parentGoalId := goalId,
}
catch exception =>
return .failure #[← exception.toMessageData.toString]
tacticM { elaborator := .anonymous } |>.run' state.savedState.tactic
/-- After finishing one branch of a proof (`graftee`), pick up from the point where the proof was left off (`target`) -/ /-- After finishing one branch of a proof (`graftee`), pick up from the point where the proof was left off (`target`) -/
protected def GoalState.continue (target: GoalState) (graftee: GoalState): Except String GoalState := protected def GoalState.continue (target: GoalState) (graftee: GoalState): Except String GoalState :=
if target.root != graftee.root then if target.root != graftee.root then

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@ -172,7 +172,8 @@ structure GoalPrint where
printContext: Bool := true printContext: Bool := true
printValue: Bool := true printValue: Bool := true
printNewMVars: Bool := false printNewMVars: Bool := false
printNonVisible: Bool := false -- Print all mvars
printAll: Bool := false
end Pantograph.Protocol end Pantograph.Protocol

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@ -262,9 +262,6 @@ protected def GoalState.serializeGoals (state: GoalState) (parent: Option GoalSt
let parentGoal := parentState.goals.get! state.parentGoalId let parentGoal := parentState.goals.get! state.parentGoalId
parentState.mctx.findDecl? parentGoal) parentState.mctx.findDecl? parentGoal)
goals.mapM fun goal => do goals.mapM fun goal => do
if options.noRepeat then
let key := if parentDecl?.isSome then "is some" else "is none"
IO.println s!"goal: {goal.name}, {key}"
match state.mctx.findDecl? goal with match state.mctx.findDecl? goal with
| .some mvarDecl => | .some mvarDecl =>
let serializedGoal ← serialize_goal options mvarDecl (parentDecl? := parentDecl?) let serializedGoal ← serialize_goal options mvarDecl (parentDecl? := parentDecl?)
@ -296,7 +293,7 @@ protected def GoalState.print (goalState: GoalState) (options: Protocol.GoalPrin
else if mvarId == goalState.root then else if mvarId == goalState.root then
printMVar (pref := ">") mvarId decl printMVar (pref := ">") mvarId decl
-- Print the remainig ones that users don't see in Lean -- Print the remainig ones that users don't see in Lean
else if options.printNonVisible then else if options.printAll then
let pref := if goalState.newMVars.contains mvarId then "~" else " " let pref := if goalState.newMVars.contains mvarId then "~" else " "
printMVar pref mvarId decl printMVar pref mvarId decl
else else

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@ -66,8 +66,9 @@ def startProof (start: Start): TestM (Option GoalState) := do
def assertUnreachable (message: String): LSpec.TestSeq := LSpec.check message false def assertUnreachable (message: String): LSpec.TestSeq := LSpec.check message false
def buildGoal (nameType: List (String × String)) (target: String): Protocol.Goal := def buildGoal (nameType: List (String × String)) (target: String) (caseName?: Option String := .none): Protocol.Goal :=
{ {
caseName?,
target := { pp? := .some target}, target := { pp? := .some target},
vars := (nameType.map fun x => ({ vars := (nameType.map fun x => ({
userName := x.fst, userName := x.fst,
@ -187,21 +188,21 @@ def proof_arith: TestM Unit := do
addTest $ assertUnreachable $ other.toString addTest $ assertUnreachable $ other.toString
return () return ()
addTest $ LSpec.check "intros" (state1.goals.length = 1) addTest $ LSpec.check "intros" (state1.goals.length = 1)
addTest $ LSpec.test "1 root" state1.rootExpr.isNone 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.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
| .success state => pure state | .success state => pure state
| other => do | other => do
addTest $ assertUnreachable $ other.toString addTest $ assertUnreachable $ other.toString
return () return ()
addTest $ LSpec.check "simp ..." (state2.goals.length = 1) addTest $ LSpec.check "simp ..." (state2.goals.length = 1)
addTest $ LSpec.check "2 root" state2.rootExpr.isNone addTest $ LSpec.check "(2 root)" state2.rootExpr.isNone
let state3 ← match ← state2.execute (goalId := 0) (tactic := "assumption") with let state3 ← match ← state2.execute (goalId := 0) (tactic := "assumption") with
| .success state => pure state | .success state => pure state
| other => do | other => do
addTest $ assertUnreachable $ other.toString addTest $ assertUnreachable $ other.toString
return () return ()
addTest $ LSpec.test "assumption" state3.goals.isEmpty addTest $ LSpec.test "assumption" state3.goals.isEmpty
addTest $ LSpec.check "3 root" state3.rootExpr.isSome addTest $ LSpec.check "(3 root)" state3.rootExpr.isSome
return () return ()
-- Two ways to write the same theorem -- Two ways to write the same theorem
@ -253,7 +254,7 @@ def proof_or_comm: TestM Unit := do
| other => do | other => do
addTest $ assertUnreachable $ other.toString addTest $ assertUnreachable $ other.toString
return () return ()
addTest $ LSpec.check "· assumption" state4_1.goals.isEmpty addTest $ LSpec.check " assumption" state4_1.goals.isEmpty
addTest $ LSpec.check "(4_1 root)" state4_1.rootExpr.isNone 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.execute (goalId := 1) (tactic := "apply Or.inl") with
| .success state => pure state | .success state => pure state
@ -266,7 +267,7 @@ def proof_or_comm: TestM Unit := do
| other => do | other => do
addTest $ assertUnreachable $ other.toString addTest $ assertUnreachable $ other.toString
return () return ()
addTest $ LSpec.check "· assumption" state4_2.goals.isEmpty addTest $ LSpec.check " assumption" state4_2.goals.isEmpty
addTest $ LSpec.check "(4_2 root)" state4_2.rootExpr.isNone addTest $ LSpec.check "(4_2 root)" state4_2.rootExpr.isNone
-- Ensure the proof can continue from `state4_2`. -- Ensure the proof can continue from `state4_2`.
let state2b ← match state2.continue state4_2 with let state2b ← match state2.continue state4_2 with
@ -286,8 +287,8 @@ def proof_or_comm: TestM Unit := do
| other => do | other => do
addTest $ assertUnreachable $ other.toString addTest $ assertUnreachable $ other.toString
return () return ()
addTest $ LSpec.check "· assumption" state4_1.goals.isEmpty addTest $ LSpec.check " assumption" state4_1.goals.isEmpty
addTest $ LSpec.check "4_1 root" state4_1.rootExpr.isSome addTest $ LSpec.check "(4_1 root)" state4_1.rootExpr.isSome
return () return ()
where where
@ -336,7 +337,45 @@ def proof_m_couple: TestM Unit := do
addTest $ LSpec.test "(2 root)" state1b.rootExpr.isNone addTest $ LSpec.test "(2 root)" state1b.rootExpr.isNone
return () return ()
/-- Tests the most basic form of proofs whose goals do not relate to each other -/ def proof_proposition_generation: TestM Unit := do
let state? ← startProof (.expr "Σ' p:Prop, p")
let state0 ← match state? with
| .some state => pure state
| .none => do
addTest $ assertUnreachable "Goal could not parse"
return ()
let state1 ← match ← state0.execute (goalId := 0) (tactic := "apply PSigma.mk") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check "apply PSigma.mk" ((← state1.serializeGoals (options := ← read)).map (·.devolatilize) =
#[
buildGoal [] "?fst" (caseName? := .some "snd"),
buildGoal [] "Prop" (caseName? := .some "fst")
])
addTest $ LSpec.test "(1 root)" state1.rootExpr.isNone
let state2 ← match ← state1.tryAssign (goalId := 0) (expr := "λ (x: Nat) => _") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check ":= λ (x: Nat), _" ((← state2.serializeGoals (options := ← read)).map (·.target.pp?) =
#[.some "Nat → Prop", .some "∀ (x : Nat), ?m.29 x"])
addTest $ LSpec.test "(2 root)" state2.rootExpr.isNone
let state3 ← match ← state2.tryAssign (goalId := 1) (expr := "fun x => Eq.refl x") with
| .success state => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
addTest $ LSpec.check ":= Eq.refl" ((← state3.serializeGoals (options := ← read)).map (·.target.pp?) =
#[])
addTest $ LSpec.test "(3 root)" state3.rootExpr.isSome
return ()
def suite: IO LSpec.TestSeq := do def suite: IO LSpec.TestSeq := do
let env: Lean.Environment ← Lean.importModules let env: Lean.Environment ← Lean.importModules
(imports := #[{ module := Name.append .anonymous "Init", runtimeOnly := false}]) (imports := #[{ module := Name.append .anonymous "Init", runtimeOnly := false}])
@ -348,8 +387,8 @@ def suite: IO LSpec.TestSeq := do
("Nat.add_comm delta", proof_delta_variable), ("Nat.add_comm delta", proof_delta_variable),
("arithmetic", proof_arith), ("arithmetic", proof_arith),
("Or.comm", proof_or_comm), ("Or.comm", proof_or_comm),
("2 < 5", proof_m_couple) ("2 < 5", proof_m_couple),
--("delta variable", proof_delta_variable) ("Proposition Generation", proof_proposition_generation)
] ]
let tests ← tests.foldlM (fun acc tests => do let tests ← tests.foldlM (fun acc tests => do
let (name, tests) := tests let (name, tests) := tests