chore: Version 0.3 #136

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aniva wants to merge 487 commits from dev into main
4 changed files with 142 additions and 89 deletions
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@ -31,14 +31,20 @@ protected def GoalState.create (expr: Expr): M GoalState := do
--let expr ← instantiateMVars expr
let goal := (← Meta.mkFreshExprMVar expr (kind := MetavarKind.synthetic) (userName := .anonymous))
let savedStateMonad: Elab.Tactic.TacticM Elab.Tactic.SavedState := MonadBacktrack.saveState
let savedState ← savedStateMonad { elaborator := .anonymous } |>.run' { goals := [goal.mvarId!]}
let root := goal.mvarId!
let savedState ← savedStateMonad { elaborator := .anonymous } |>.run' { goals := [root]}
return {
savedState,
root := goal.mvarId!,
newMVars := SSet.empty,
root,
newMVars := SSet.insert .empty root,
}
protected def GoalState.goals (goalState: GoalState): List MVarId := goalState.savedState.tactic.goals
private def GoalState.mctx (state: GoalState): MetavarContext :=
state.savedState.term.meta.meta.mctx
private def GoalState.mvars (state: GoalState): SSet MVarId :=
state.mctx.decls.foldl (init := .empty) fun acc k _ => acc.insert k
def executeTactic (state: Elab.Tactic.SavedState) (goal: MVarId) (tactic: Syntax) :
M (Except (Array String) (Elab.Tactic.SavedState × List MVarId)):= do
let tacticM (stx: Syntax): Elab.Tactic.TacticM (Except (Array String) (Elab.Tactic.SavedState × List MVarId)) := do
@ -93,13 +99,13 @@ protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String
let prevMCtx := state.savedState.term.meta.meta.mctx
-- 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
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
) []).toSSet
return acc.insert mvarId
) SSet.empty
let nextState: GoalState := {
savedState := nextSavedState
root := state.root,
@ -115,38 +121,70 @@ protected def GoalState.execute (state: GoalState) (goalId: Nat) (tactic: String
| .none => throwError s!"Parent mvar id does not exist {nextGoal.name}"
return .success nextState goals.toArray
/-- 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 :=
if target.root != graftee.root then
.error s!"Roots of two continued goal states do not match: {target.root.name} != {graftee.root.name}"
-- Ensure goals are not dangling
else if ¬ (target.goals.all (λ goal => graftee.mvars.contains goal)) then
.error s!"Some goals in target are not present in the graftee"
else
-- Set goals to the goals that have not been assigned yet, similar to the `focus` tactic.
let unassigned := target.goals.filter (λ goal =>
let mctx := graftee.mctx
¬(mctx.eAssignment.contains goal || mctx.dAssignment.contains goal))
.ok {
savedState := {
term := graftee.savedState.term,
tactic := { goals := unassigned },
},
root := target.root,
newMVars := graftee.newMVars,
}
protected def GoalState.rootExpr (goalState: GoalState): Option Expr :=
goalState.mctx.eAssignment.find? goalState.root |>.filter (λ e => ¬ e.hasMVar)
-- Diagnostics functions
/-- Print the metavariables in a readable format -/
protected def GoalState.print (goalState: GoalState) (options: Protocol.GoalPrint := {}): Elab.TermElabM Unit := do
protected def GoalState.print (goalState: GoalState) (options: Protocol.GoalPrint := {}): M Unit := do
let savedState := goalState.savedState
savedState.term.restore
let goals := savedState.tactic.goals
let mctx ← getMCtx
let root := goalState.root
-- Print the root
match mctx.decls.find? root with
| .some decl => printMVar ">" root decl
| .none => IO.println s!">{root.name}: ??"
goals.forM (fun mvarId => do
let pref := "⊢"
if mvarId != root then
match mctx.decls.find? mvarId with
| .some decl => printMVar pref mvarId decl
| .none => IO.println s!"{pref}{mvarId.name}: ??"
| .some decl => printMVar "⊢" mvarId decl
| .none => IO.println s!"⊢{mvarId.name}: ??"
)
let goals := goals.toSSet
mctx.decls.forM (fun mvarId decl => do
if goals.contains mvarId then
if goals.contains mvarId || mvarId == root then
pure ()
-- Always print the root goal
else if mvarId == goalState.root then
printMVar (pref := ">") mvarId decl
else if ¬(goalState.newMVars.contains mvarId) then
printMVar (pref := " ") mvarId decl
-- Print the remainig ones that users don't see in Lean
else if options.printNonVisible then
printMVar (pref := "~") mvarId decl
let pref := if goalState.newMVars.contains mvarId then "~" else " "
printMVar pref mvarId decl
else
IO.println s!" {mvarId.name}{userNameToString decl.userName}"
pure ()
--IO.println s!" {mvarId.name}{userNameToString decl.userName}"
)
where
printMVar (pref: String) (mvarId: MVarId) (decl: MetavarDecl): Elab.TermElabM Unit := do
if options.printContext then
decl.lctx.fvarIdToDecl.forM printFVar
IO.println s!"{pref}{mvarId.name}{userNameToString decl.userName}: {← Meta.ppExpr decl.type} {← serialize_expression_ast decl.type}"
let type_sexp ← serialize_expression_ast (← instantiateMVars decl.type) (sanitize := false)
IO.println s!"{pref}{mvarId.name}{userNameToString decl.userName}: {← Meta.ppExpr decl.type} {type_sexp}"
if options.printValue then
if let Option.some value := (← getMCtx).eAssignment.find? mvarId then
IO.println s!" = {← Meta.ppExpr value}"

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@ -167,7 +167,8 @@ structure GoalDeleteResult where
structure GoalPrint where
printContext: Bool := true
printValue: Bool := true
printNonVisible: Bool := true
printNewMVars: Bool := false
printNonVisible: Bool := false
end Pantograph.Protocol

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@ -45,9 +45,11 @@ def type_expr_to_bound (expr: Expr): MetaM Protocol.BoundExpression := do
return (toString (← fvar.fvarId!.getUserName), toString (← Meta.ppExpr (← fvar.fvarId!.getType)))
return { binders, target := toString (← Meta.ppExpr body) }
private def name_to_ast: Lean.Name → String
| .anonymous
| .num _ _ => ":anon"
private def name_to_ast (name: Lean.Name) (sanitize: Bool := true): String := match name with
| .anonymous => ":anon"
| .num n i => match sanitize with
| false => s!"{toString n} {i}"
| true => ":anon"
| n@(.str _ _) => toString n
private def level_depth: Level → Nat
@ -100,71 +102,73 @@ def serialize_sort_level_ast (level: Level): String :=
/--
Completely serializes an expression tree. Json not used due to compactness
-/
def serialize_expression_ast (expr: Expr): MetaM String := do
match expr with
def serialize_expression_ast (expr: Expr) (sanitize: Bool := true): MetaM String := do
return self expr
where
self (e: Expr): String :=
match e with
| .bvar deBruijnIndex =>
-- This is very common so the index alone is shown. Literals are handled below.
-- The raw de Bruijn index should never appear in an unbound setting. In
-- Lean these are handled using a `#` prefix.
return s!"{deBruijnIndex}"
s!"{deBruijnIndex}"
| .fvar fvarId =>
let name := name_to_ast fvarId.name
return s!"(:fv {name})"
let name := of_name fvarId.name
s!"(:fv {name})"
| .mvar mvarId =>
let name := name_to_ast mvarId.name
return s!"(:mv {name})"
let name := of_name mvarId.name
s!"(:mv {name})"
| .sort level =>
let level := serialize_sort_level_ast level
return s!"(:sort {level})"
s!"(:sort {level})"
| .const declName _ =>
-- The universe level of the const expression is elided since it should be
-- inferrable from surrounding expression
return s!"(:c {declName})"
s!"(:c {declName})"
| .app fn arg =>
let fn' ← serialize_expression_ast fn
let arg' ← serialize_expression_ast arg
return s!"({fn'} {arg'})"
let fn' := self fn
let arg' := self arg
s!"({fn'} {arg'})"
| .lam binderName binderType body binderInfo =>
let binderName' := name_to_ast binderName
let binderType' ← serialize_expression_ast binderType
let body' ← serialize_expression_ast body
let binderName' := of_name binderName
let binderType' := self binderType
let body' := self body
let binderInfo' := binder_info_to_ast binderInfo
return s!"(:lambda {binderName'} {binderType'} {body'}{binderInfo'})"
s!"(:lambda {binderName'} {binderType'} {body'}{binderInfo'})"
| .forallE binderName binderType body binderInfo =>
let binderName' := name_to_ast binderName
let binderType' ← serialize_expression_ast binderType
let body' ← serialize_expression_ast body
let binderName' := of_name binderName
let binderType' := self binderType
let body' := self body
let binderInfo' := binder_info_to_ast binderInfo
return s!"(:forall {binderName'} {binderType'} {body'}{binderInfo'})"
s!"(:forall {binderName'} {binderType'} {body'}{binderInfo'})"
| .letE name type value body _ =>
-- Dependent boolean flag diacarded
let name' := name_to_ast name
let type' ← serialize_expression_ast type
let value' ← serialize_expression_ast value
let body' ← serialize_expression_ast body
return s!"(:let {name'} {type'} {value'} {body'})"
let type' := self type
let value' := self value
let body' := self body
s!"(:let {name'} {type'} {value'} {body'})"
| .lit v =>
-- To not burden the downstream parser who needs to handle this, the literal
-- is wrapped in a :lit sexp.
let v' := match v with
| .natVal val => toString val
| .strVal val => s!"\"{val}\""
return s!"(:lit {v'})"
| .mdata _ expr =>
s!"(:lit {v'})"
| .mdata _ inner =>
-- NOTE: Equivalent to expr itself, but mdata influences the prettyprinter
-- It may become necessary to incorporate the metadata.
return (← serialize_expression_ast expr)
self inner
| .proj typeName idx struct =>
let struct' ← serialize_expression_ast struct
return s!"(:proj {typeName} {idx} {struct'})"
where
let struct' := self struct
s!"(:proj {typeName} {idx} {struct'})"
-- Elides all unhygenic names
binder_info_to_ast : Lean.BinderInfo → String
| .default => ""
| .implicit => " :implicit"
| .strictImplicit => " :strictImplicit"
| .instImplicit => " :instImplicit"
of_name (name: Name) := name_to_ast name sanitize
def serialize_expression (options: Protocol.Options) (e: Expr): MetaM Protocol.Expression := do
let pp := toString (← Meta.ppExpr e)

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@ -189,26 +189,36 @@ def proof_or_comm: TestM Unit := do
| other => do
addTest $ assertUnreachable $ other.toString
return ()
IO.println "===== 1 ====="
state1.print
IO.println "===== 2 ====="
state2.print
IO.println "===== 4_1 ====="
state4_1.print
let (state3_2, _goal) ← match ← state2.execute (goalId := 1) (tactic := "apply Or.inl") with
| .success state #[goal] => pure (state, goal)
| other => do
addTest $ assertUnreachable $ other.toString
return ()
IO.println "===== 3_2 ====="
state3_2.print
let state4_2 ← match ← state3_2.execute (goalId := 0) (tactic := "assumption") with
| .success state #[] => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
IO.println "===== 4_2 ====="
state4_2.print
-- Ensure the proof can continue from `state4_2`.
let state2b ← match state2.continue state4_2 with
| .error msg => do
addTest $ assertUnreachable $ msg
return ()
| .ok state => pure state
addTest $ LSpec.test "state2b" (state2b.goals == [state2.goals.get! 0])
let (state3_1, _goal) ← match ← state2b.execute (goalId := 0) (tactic := "apply Or.inr") with
| .success state #[goal] => pure (state, goal)
| other => do
addTest $ assertUnreachable $ other.toString
return ()
let state4_1 ← match ← state3_1.execute (goalId := 0) (tactic := "assumption") with
| .success state #[] => pure state
| other => do
addTest $ assertUnreachable $ other.toString
return ()
IO.println "===== 4_1 ====="
state4_1.print ({ printNonVisible := false })
return ()
where