chore: Version 0.3 #136
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@ -1,4 +1,4 @@
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/- Adapted from lean-training-data by semorrison -/
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import Pantograph.Frontend.Basic
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import Pantograph.Frontend.Elab
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import Pantograph.Frontend.InfoTree
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import Pantograph.Frontend.MetaTranslate
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@ -30,6 +30,13 @@ end Lean.PersistentArray
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namespace Pantograph.Frontend
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@[export pantograph_frontend_stx_byte_range]
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def stxByteRange (stx : Syntax) : String.Pos × String.Pos :=
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let pos := stx.getPos?.getD 0
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let endPos := stx.getTailPos?.getD 0
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(pos, endPos)
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abbrev FrontendM := Elab.Frontend.FrontendM
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structure CompilationStep where
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@ -1,87 +1,21 @@
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/- Adapted from https://github.com/semorrison/lean-training-data -/
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import Lean.Elab.Import
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import Lean.Elab.Command
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import Lean.Elab.InfoTree
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import Lean.DeclarationRange
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import Pantograph.Frontend.Basic
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import Pantograph.Frontend.MetaTranslate
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import Pantograph.Goal
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import Pantograph.Protocol
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import Pantograph.Frontend.InfoTree
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open Lean
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namespace Lean.Elab.Info
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/-- The `Syntax` for a `Lean.Elab.Info`, if there is one. -/
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protected def stx? : Info → Option Syntax
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| .ofTacticInfo info => info.stx
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| .ofTermInfo info => info.stx
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| .ofCommandInfo info => info.stx
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| .ofMacroExpansionInfo info => info.stx
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| .ofOptionInfo info => info.stx
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| .ofFieldInfo info => info.stx
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| .ofCompletionInfo info => info.stx
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| .ofUserWidgetInfo info => info.stx
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| .ofCustomInfo info => info.stx
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| .ofFVarAliasInfo _ => none
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| .ofFieldRedeclInfo info => info.stx
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| .ofOmissionInfo info => info.stx
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/-- Is the `Syntax` for this `Lean.Elab.Info` original, or synthetic? -/
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protected def isOriginal (i : Info) : Bool :=
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match i.stx? with
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| none => true -- Somewhat unclear what to do with `FVarAliasInfo`, so be conservative.
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| some stx => match stx.getHeadInfo with
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| .original .. => true
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| _ => false
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end Lean.Elab.Info
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namespace Lean.Elab.TacticInfo
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/-- Find the name for the outermost `Syntax` in this `TacticInfo`. -/
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def name? (t : TacticInfo) : Option Name :=
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match t.stx with
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| Syntax.node _ n _ => some n
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| _ => none
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/-- Decide whether a tactic is "substantive",
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or is merely a tactic combinator (e.g. `by`, `;`, multiline tactics, parenthesized tactics). -/
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def isSubstantive (t : TacticInfo) : Bool :=
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match t.name? with
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| none => false
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| some `null => false
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| some ``cdot => false
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| some ``cdotTk => false
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| some ``Lean.Parser.Term.byTactic => false
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| some ``Lean.Parser.Tactic.tacticSeq => false
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| some ``Lean.Parser.Tactic.tacticSeq1Indented => false
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| some ``Lean.Parser.Tactic.«tactic_<;>_» => false
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| some ``Lean.Parser.Tactic.paren => false
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| _ => true
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end Lean.Elab.TacticInfo
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namespace Lean.Elab.InfoTree
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/--
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Keep `.node` nodes and `.hole` nodes satisfying predicates.
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Returns a `List InfoTree`, although in most situations this will be a singleton.
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-/
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partial def filter (p : Info → Bool) (m : MVarId → Bool := fun _ => false) :
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InfoTree → List InfoTree
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| .context ctx tree => tree.filter p m |>.map (.context ctx)
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| .node info children =>
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if p info then
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[.node info (children.toList.map (filter p m)).join.toPArray']
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else
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(children.toList.map (filter p m)).join
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| .hole mvar => if m mvar then [.hole mvar] else []
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end Lean.Elab.InfoTree
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namespace Pantograph.Frontend
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-- Info tree filtering functions
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/- Adapted from lean-training-data -/
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structure TacticInvocation where
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info : Elab.TacticInfo
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ctx : Elab.ContextInfo
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@ -131,19 +65,10 @@ protected def usedConstants (t: TacticInvocation) : NameSet :=
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end TacticInvocation
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/-- Analogue of `Lean.Elab.InfoTree.findInfo?`, but that returns a list of all results. -/
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partial def findAllInfo (t : Elab.InfoTree) (context?: Option Elab.ContextInfo) (pred : Elab.Info → Bool) :
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List (Elab.Info × Option Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
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match t with
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| .context inner t => findAllInfo t (inner.mergeIntoOuter? context?) pred
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| .node i children =>
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(if pred i then [(i, context?, children)] else []) ++ children.toList.bind (fun t => findAllInfo t context? pred)
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| _ => []
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/-- Return all `TacticInfo` nodes in an `InfoTree` corresponding to tactics,
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each equipped with its relevant `ContextInfo`, and any children info trees. -/
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private def collectTacticNodes (t : Elab.InfoTree) : List TacticInvocation :=
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let infos := findAllInfo t none fun i => match i with
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let infos := t.findAllInfo none false fun i => match i with
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| .ofTacticInfo _ => true
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| _ => false
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infos.filterMap fun p => match p with
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@ -162,9 +87,11 @@ def collectTacticsFromCompilationStep (step : CompilationStep) : IO (List Protoc
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tactics.mapM λ invocation => do
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let goalBefore := (Format.joinSep (← invocation.goalState) "\n").pretty
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let goalAfter := (Format.joinSep (← invocation.goalStateAfter) "\n").pretty
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let tactic ← invocation.ctx.runMetaM {} do
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let t ← PrettyPrinter.ppTactic ⟨invocation.info.stx⟩
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return t.pretty
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let tactic ← invocation.ctx.runMetaM {} <| Meta.withMCtx invocation.info.mctxBefore do
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return (← invocation.ctx.ppSyntax {} invocation.info.stx).pretty
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-- FIXME: Why does this not work? There are problems with `term.pseudo.antiquot`
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--PrettyPrinter.ppTactic ⟨invocation.info.stx⟩
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--return t.pretty
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let usedConstants := invocation.usedConstants.toArray.map λ n => n.toString
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return {
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goalBefore,
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@ -177,47 +104,79 @@ structure InfoWithContext where
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info: Elab.Info
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context?: Option Elab.ContextInfo := .none
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private def collectSorrysInTree (t : Elab.InfoTree) : List InfoWithContext :=
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let infos := findAllInfo t none fun i => match i with
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| .ofTermInfo { expectedType?, expr, stx, .. } =>
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expr.isSorry ∧ expectedType?.isSome ∧ stx.isOfKind `Lean.Parser.Term.sorry
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private def collectSorrysInTree (t : Elab.InfoTree) : IO (List InfoWithContext) := do
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let infos ← t.findAllInfoM none fun i ctx? => match i with
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| .ofTermInfo { expectedType?, expr, stx, lctx, .. } => do
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let .some ctx := ctx? | return (false, true)
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if expr.isSorry ∧ stx.isOfKind `Lean.Parser.Term.sorry then
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if expectedType?.isNone then
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throw $ .userError "Sorry of indeterminant type is not allowed"
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return (true, false)
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let .some expectedType := expectedType? | return (false, true)
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let typeMatch ← ctx.runMetaM lctx do
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let type ← Meta.inferType expr
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Meta.isExprDefEqGuarded type expectedType
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return match typeMatch, expr.hasSorry with
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| false, true => (true, false) -- Types mismatch but has sorry -> collect, halt
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| false, false => (true, false) -- Types mistmatch but no sorry -> collect, halt
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| true, true => (false, true) -- Types match but has sorry -> continue
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| true, false => (false, false) -- Types match but no sorries -> halt
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| .ofTacticInfo { stx, goalsBefore, .. } =>
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-- The `sorry` term is distinct from the `sorry` tactic
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let isSorry := stx.isOfKind `Lean.Parser.Tactic.tacticSorry
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isSorry ∧ !goalsBefore.isEmpty
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| _ => false
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infos.map fun (info, context?, _) => { info, context? }
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return (isSorry ∧ !goalsBefore.isEmpty, ¬ isSorry)
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| _ => return (false, true)
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return infos.map fun (info, context?, _) => { info, context? }
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-- NOTE: Plural deliberately not spelled "sorries"
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@[export pantograph_frontend_collect_sorrys_m]
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def collectSorrys (step: CompilationStep) : List InfoWithContext :=
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step.trees.bind collectSorrysInTree
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def collectSorrys (step: CompilationStep) : IO (List InfoWithContext) := do
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return (← step.trees.mapM collectSorrysInTree).join
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structure AnnotatedGoalState where
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state : GoalState
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srcBoundaries : List (String.Pos × String.Pos)
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/--
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Since we cannot directly merge `MetavarContext`s, we have to get creative. This
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function duplicates frozen mvars in term and tactic info nodes, and add them to
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the current `MetavarContext`.
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-/
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@[export pantograph_frontend_sorrys_to_goal_state]
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def sorrysToGoalState (sorrys : List InfoWithContext) : MetaM GoalState := do
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@[export pantograph_frontend_sorrys_to_goal_state_m]
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def sorrysToGoalState (sorrys : List InfoWithContext) : MetaM AnnotatedGoalState := do
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assert! !sorrys.isEmpty
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let goalsM := sorrys.mapM λ i => do
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match i.info with
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| .ofTermInfo termInfo => do
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let mvarId ← MetaTranslate.translateMVarFromTermInfo termInfo i.context?
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return [mvarId]
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return [(mvarId, stxByteRange termInfo.stx)]
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| .ofTacticInfo tacticInfo => do
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MetaTranslate.translateMVarFromTacticInfoBefore tacticInfo i.context?
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let mvarIds ← MetaTranslate.translateMVarFromTacticInfoBefore tacticInfo i.context?
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let range := stxByteRange tacticInfo.stx
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return mvarIds.map (·, range)
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| _ => panic! "Invalid info"
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let goals := List.join (← goalsM.run {} |>.run' {})
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let annotatedGoals := List.join (← goalsM.run {} |>.run' {})
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let goals := annotatedGoals.map Prod.fst
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let srcBoundaries := annotatedGoals.map Prod.snd
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let root := match goals with
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| [] => panic! "No MVars generated"
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| [g] => g
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| _ => { name := .anonymous }
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GoalState.createFromMVars goals root
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let state ← GoalState.createFromMVars goals root
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return { state, srcBoundaries }
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@[export pantograph_frontend_collect_new_defined_constants_m]
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def collectNewDefinedConstants (step : CompilationStep) : IO (List Name) := do
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step.after.constants.map₂.foldlM (λ acc name _ => do
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if step.before.contains name then
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return acc
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let coreM : CoreM Bool := Option.isSome <$> findDeclarationRanges? name
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let hasRange ← coreM.run' { fileName := step.fileName, fileMap := step.fileMap } { env := step.after } |>.toBaseIO
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match hasRange with
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| .ok true => return name :: acc
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| .ok false => return acc
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| .error e => throw $ IO.userError (← e.toMessageData.toString)
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) []
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end Pantograph.Frontend
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@ -0,0 +1,153 @@
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/- Adapted from lean-training-data -/
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import Lean.Elab.InfoTree
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import Lean.Parser.Term
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import Lean.PrettyPrinter
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open Lean
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namespace Lean.Elab
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private def elaboratorToString : Name → String
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| .anonymous => ""
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| n => s!"⟨{n}⟩ "
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private def indent (s : String) : String := "\n".intercalate $ s.splitOn "\n" |>.map ("\t" ++ .)
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/-- The `Syntax` for a `Lean.Elab.Info`, if there is one. -/
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protected def Info.stx? : Info → Option Syntax
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| .ofTacticInfo info => info.stx
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| .ofTermInfo info => info.stx
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| .ofCommandInfo info => info.stx
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| .ofMacroExpansionInfo info => info.stx
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| .ofOptionInfo info => info.stx
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| .ofFieldInfo info => info.stx
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| .ofCompletionInfo info => info.stx
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| .ofUserWidgetInfo info => info.stx
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| .ofCustomInfo info => info.stx
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| .ofFVarAliasInfo _ => none
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| .ofFieldRedeclInfo info => info.stx
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| .ofOmissionInfo info => info.stx
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/-- Is the `Syntax` for this `Lean.Elab.Info` original, or synthetic? -/
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protected def Info.isOriginal (i : Info) : Bool :=
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match i.stx? with
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| none => true -- Somewhat unclear what to do with `FVarAliasInfo`, so be conservative.
|
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| some stx => match stx.getHeadInfo with
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| .original .. => true
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| _ => false
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def ContextInfo.ppExpr (ctx : ContextInfo) (lctx : LocalContext) (e : Expr) : IO Format :=
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ctx.runMetaM lctx (do Meta.ppExpr (← instantiateMVars e))
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def CommandInfo.toString (info : CommandInfo) (ctx : ContextInfo) : IO String := do
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let stx := (← ctx.ppSyntax {} info.stx).pretty
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return s!"{elaboratorToString info.elaborator}\n{stx}"
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def TermInfo.toString (info : TermInfo) (ctx : ContextInfo) : IO String := do
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let stx := (← ctx.ppSyntax info.lctx info.stx).pretty
|
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let expectedType := (← info.expectedType?.mapM fun ty => do
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pure s!": {(← ctx.ppExpr info.lctx ty).pretty}").getD ""
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let expr := (← ctx.ppExpr info.lctx info.expr).pretty
|
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return s!"{elaboratorToString info.elaborator}{expr}{expectedType}\n{stx}"
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/-- Find the name for the outermost `Syntax` in this `TacticInfo`. -/
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def TacticInfo.name? (t : TacticInfo) : Option Name :=
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match t.stx with
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| Syntax.node _ n _ => some n
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| _ => none
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/-- Decide whether a tactic is "substantive",
|
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or is merely a tactic combinator (e.g. `by`, `;`, multiline tactics, parenthesized tactics). -/
|
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def TacticInfo.isSubstantive (t : TacticInfo) : Bool :=
|
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match t.name? with
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| none => false
|
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| some `null => false
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| some ``cdot => false
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| some ``cdotTk => false
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| some ``Lean.Parser.Term.byTactic => false
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| some ``Lean.Parser.Tactic.tacticSeq => false
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| some ``Lean.Parser.Tactic.tacticSeq1Indented => false
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| some ``Lean.Parser.Tactic.«tactic_<;>_» => false
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| some ``Lean.Parser.Tactic.paren => false
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| _ => true
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def TacticInfo.pp (info : TacticInfo) (ctx : ContextInfo) : IO Format :=
|
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ctx.runMetaM {} try
|
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Lean.PrettyPrinter.ppTactic ⟨info.stx⟩
|
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catch _ =>
|
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pure "<failed to pretty print>"
|
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def TacticInfo.toString (i : TacticInfo) (ctx : ContextInfo) : IO String := do
|
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let name := i.name?
|
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let stx := Format.pretty (← i.pp ctx)
|
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return s!"{name}\n{stx}"
|
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|
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/--
|
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Keep `.node` nodes and `.hole` nodes satisfying predicates.
|
||||
|
||||
Returns a `List InfoTree`, although in most situations this will be a singleton.
|
||||
-/
|
||||
partial def InfoTree.filter (p : Info → Bool) (m : MVarId → Bool := fun _ => false) :
|
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InfoTree → List InfoTree
|
||||
| .context ctx tree => tree.filter p m |>.map (.context ctx)
|
||||
| .node info children =>
|
||||
if p info then
|
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[.node info (children.toList.map (filter p m)).join.toPArray']
|
||||
else
|
||||
(children.toList.map (filter p m)).join
|
||||
| .hole mvar => if m mvar then [.hole mvar] else []
|
||||
|
||||
/-- Analogue of `Lean.Elab.InfoTree.findInfo?`, but that returns a list of all results. -/
|
||||
partial def InfoTree.findAllInfo
|
||||
(t : InfoTree)
|
||||
(context?: Option Elab.ContextInfo)
|
||||
(haltOnMatch : Bool := false)
|
||||
(pred : Elab.Info → Bool)
|
||||
: List (Elab.Info × Option Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
|
||||
match t with
|
||||
| .context inner t => findAllInfo t (inner.mergeIntoOuter? context?) haltOnMatch pred
|
||||
| .node i children =>
|
||||
let head := if pred i then [(i, context?, children)] else []
|
||||
let tail := if haltOnMatch ∧ !head.isEmpty then [] else children.toList.bind (fun t => findAllInfo t context? haltOnMatch pred)
|
||||
head ++ tail
|
||||
| _ => []
|
||||
|
||||
/-- Monadic analogue of `findAllInfo`, but predicate controls whether to recurse. -/
|
||||
partial def InfoTree.findAllInfoM [Monad m]
|
||||
(t : InfoTree)
|
||||
(context?: Option Elab.ContextInfo)
|
||||
(pred : Elab.Info → Option Elab.ContextInfo → m (Bool × Bool))
|
||||
: m (List (Elab.Info × Option Elab.ContextInfo × PersistentArray Elab.InfoTree)) := do
|
||||
match t with
|
||||
| .context inner t => t.findAllInfoM (inner.mergeIntoOuter? context?) pred
|
||||
| .node i children =>
|
||||
let (flagCollect, flagRecurse) ← pred i context?
|
||||
let head := if flagCollect then [(i, context?, children)] else []
|
||||
let tail := if ¬ flagRecurse then pure [] else children.toList.mapM (fun t => t.findAllInfoM context? pred)
|
||||
return head ++ (← tail).join
|
||||
| _ => return []
|
||||
|
||||
@[export pantograph_infotree_to_string_m]
|
||||
partial def InfoTree.toString (t : InfoTree) (ctx?: Option Elab.ContextInfo := .none) : IO String := do
|
||||
match t with
|
||||
| .context ctx t => t.toString (ctx.mergeIntoOuter? ctx?)
|
||||
| .node info children =>
|
||||
if let some ctx := ctx? then
|
||||
let node : String ← match info with
|
||||
| .ofTermInfo info => pure s!"[term] {(← info.toString ctx)}"
|
||||
| .ofCommandInfo info => pure s!"[command] {(← info.toString ctx)}"
|
||||
| .ofTacticInfo info => pure s!"[tactic] {(← info.toString ctx)}"
|
||||
| .ofMacroExpansionInfo _ => pure "[macro_exp]"
|
||||
| .ofOptionInfo _ => pure "[option]"
|
||||
| .ofFieldInfo _ => pure "[field]"
|
||||
| .ofCompletionInfo _ => pure "[completion]"
|
||||
| .ofUserWidgetInfo _ => pure "[user_widget]"
|
||||
| .ofCustomInfo _ => pure "[custom]"
|
||||
| .ofFVarAliasInfo _ => pure "[fvar]"
|
||||
| .ofFieldRedeclInfo _ => pure "[field_redecl]"
|
||||
| .ofOmissionInfo _ => pure "[omission]"
|
||||
let children := "\n".intercalate (← children.toList.mapM λ t' => do pure $ indent $ ← t'.toString ctx)
|
||||
return s!"{node}\n{children}"
|
||||
else throw <| IO.userError "No `ContextInfo` available."
|
||||
| .hole mvarId =>
|
||||
if let some ctx := ctx? then
|
||||
let payload := (← ctx.runMetaM {} (do Meta.ppGoal mvarId)).pretty
|
||||
return s!"[hole] {payload}"
|
||||
else throw <| IO.userError "No `ContextInfo` available."
|
||||
|
||||
end Lean.Elab
|
|
@ -177,16 +177,51 @@ protected def GoalState.getMVarEAssignment (goalState: GoalState) (mvarId: MVarI
|
|||
|
||||
--- Tactic execution functions ---
|
||||
|
||||
protected def GoalState.step (state: GoalState) (goal: MVarId) (tacticM: Elab.Tactic.TacticM Unit)
|
||||
-- Mimics `Elab.Term.logUnassignedUsingErrorInfos`
|
||||
private def collectAllErroredMVars (src : MVarId) : Elab.TermElabM (List MVarId) := do
|
||||
-- These descendants serve as "seed" mvars. If a MVarError's mvar is related
|
||||
-- to one of these seed mvars, it means an error has occurred when a tactic
|
||||
-- was executing on `src`. `evalTactic`, will not capture these mvars, so we
|
||||
-- need to manually find them and save them into the goal list.
|
||||
let descendants ← Meta.getMVars $ ← instantiateMVars (.mvar src)
|
||||
--let _ ← Elab.Term.logUnassignedUsingErrorInfos descendants
|
||||
let mut alreadyVisited : MVarIdSet := {}
|
||||
let mut result : MVarIdSet := {}
|
||||
for { mvarId, .. } in (← get).mvarErrorInfos do
|
||||
unless alreadyVisited.contains mvarId do
|
||||
alreadyVisited := alreadyVisited.insert mvarId
|
||||
/- The metavariable `mvarErrorInfo.mvarId` may have been assigned or
|
||||
delayed assigned to another metavariable that is unassigned. -/
|
||||
let mvarDeps ← Meta.getMVars (.mvar mvarId)
|
||||
if mvarDeps.any descendants.contains then do
|
||||
result := mvarDeps.foldl (·.insert ·) result
|
||||
return result.toList
|
||||
|
||||
private def mergeMVarLists (li1 li2 : List MVarId) : List MVarId :=
|
||||
let li2' := li2.filter (¬ li1.contains ·)
|
||||
li1 ++ li2'
|
||||
|
||||
/--
|
||||
Set `guardMVarErrors` to true to capture mvar errors. Lean will not
|
||||
automatically collect mvars from text tactics (vide
|
||||
`test_tactic_failure_synthesize_placeholder`)
|
||||
-/
|
||||
protected def GoalState.step (state: GoalState) (goal: MVarId) (tacticM: Elab.Tactic.TacticM Unit) (guardMVarErrors : Bool := false)
|
||||
: Elab.TermElabM GoalState := do
|
||||
unless (← getMCtx).decls.contains goal do
|
||||
throwError s!"Goal is not in context: {goal.name}"
|
||||
goal.checkNotAssigned `GoalState.step
|
||||
let (_, newGoals) ← tacticM { elaborator := .anonymous } |>.run { goals := [goal] }
|
||||
let (_, { goals }) ← tacticM { elaborator := .anonymous } |>.run { goals := [goal] }
|
||||
let nextElabState ← MonadBacktrack.saveState
|
||||
Elab.Term.synthesizeSyntheticMVarsNoPostponing
|
||||
|
||||
let goals ← if guardMVarErrors then
|
||||
pure $ mergeMVarLists goals (← collectAllErroredMVars goal)
|
||||
else
|
||||
pure goals
|
||||
return {
|
||||
state with
|
||||
savedState := { term := nextElabState, tactic := newGoals },
|
||||
savedState := { term := nextElabState, tactic := { goals }, },
|
||||
parentMVar? := .some goal,
|
||||
calcPrevRhs? := .none,
|
||||
}
|
||||
|
@ -203,10 +238,10 @@ inductive TacticResult where
|
|||
| invalidAction (message: String)
|
||||
|
||||
/-- Executes a `TacticM` monad on this `GoalState`, collecting the errors as necessary -/
|
||||
protected def GoalState.tryTacticM (state: GoalState) (goal: MVarId) (tacticM: Elab.Tactic.TacticM Unit):
|
||||
protected def GoalState.tryTacticM (state: GoalState) (goal: MVarId) (tacticM: Elab.Tactic.TacticM Unit) (guardMVarErrors : Bool := false):
|
||||
Elab.TermElabM TacticResult := do
|
||||
try
|
||||
let nextState ← state.step goal tacticM
|
||||
let nextState ← state.step goal tacticM guardMVarErrors
|
||||
|
||||
-- Check if error messages have been generated in the core.
|
||||
let newMessages ← (← Core.getMessageLog).toList.drop state.coreState.messages.toList.length
|
||||
|
@ -215,6 +250,7 @@ protected def GoalState.tryTacticM (state: GoalState) (goal: MVarId) (tacticM: E
|
|||
return .some $ ← m.toString
|
||||
else
|
||||
return .none
|
||||
Core.resetMessageLog
|
||||
if ¬ newMessages.isEmpty then
|
||||
return .failure newMessages.toArray
|
||||
return .success nextState
|
||||
|
@ -233,7 +269,7 @@ protected def GoalState.tryTactic (state: GoalState) (goal: MVarId) (tactic: Str
|
|||
(fileName := ← getFileName) with
|
||||
| .ok stx => pure $ stx
|
||||
| .error error => return .parseError error
|
||||
state.tryTacticM goal $ Elab.Tactic.evalTactic tactic
|
||||
state.tryTacticM goal (Elab.Tactic.evalTactic tactic) true
|
||||
|
||||
protected def GoalState.tryAssign (state: GoalState) (goal: MVarId) (expr: String):
|
||||
Elab.TermElabM TacticResult := do
|
||||
|
|
|
@ -316,6 +316,8 @@ structure FrontendProcess where
|
|||
invocations: Bool := false
|
||||
-- If set to true, collect `sorry`s
|
||||
sorrys: Bool := false
|
||||
-- If set to true, extract new constants
|
||||
newConstants: Bool := false
|
||||
deriving Lean.FromJson
|
||||
structure InvokedTactic where
|
||||
goalBefore: String
|
||||
|
@ -329,11 +331,16 @@ structure InvokedTactic where
|
|||
structure CompilationUnit where
|
||||
-- String boundaries of compilation units
|
||||
boundary: (Nat × Nat)
|
||||
messages: Array String := #[]
|
||||
-- Tactic invocations
|
||||
invocations?: Option (List InvokedTactic) := .none
|
||||
goalStateId?: Option Nat := .none
|
||||
goals: Array Goal := #[]
|
||||
messages: Array String := #[]
|
||||
goals?: Option (Array Goal) := .none
|
||||
-- Code segments which generated the goals
|
||||
goalSrcBoundaries?: Option (Array (Nat × Nat)) := .none
|
||||
|
||||
-- New constants defined in compilation unit
|
||||
newConstants?: Option (Array String) := .none
|
||||
deriving Lean.ToJson
|
||||
structure FrontendProcessResult where
|
||||
units: List CompilationUnit
|
||||
|
|
|
@ -7,7 +7,7 @@ A Machine-to-Machine interaction system for Lean 4.
|
|||
Pantograph provides interfaces to execute proofs, construct expressions, and
|
||||
examine the symbol list of a Lean project for machine learning.
|
||||
|
||||
See [documentations](doc/) for design rationale and references.
|
||||
See [documentations](doc/rationale.md) for design rationale and references.
|
||||
|
||||
## Installation
|
||||
|
||||
|
|
36
Repl.lean
36
Repl.lean
|
@ -79,6 +79,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
|
|||
let state ← get
|
||||
let nGoals := state.goalStates.size
|
||||
set { state with nextId := 0, goalStates := .empty }
|
||||
Lean.Core.resetMessageLog
|
||||
return .ok { nGoals }
|
||||
stat (_: Protocol.Stat): MainM (CR Protocol.StatResult) := do
|
||||
let state ← get
|
||||
|
@ -258,27 +259,38 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
|
|||
pure $ .some invocations
|
||||
else
|
||||
pure .none
|
||||
let sorrys := if args.sorrys then
|
||||
let sorrys ← if args.sorrys then
|
||||
Frontend.collectSorrys step
|
||||
else
|
||||
[]
|
||||
pure []
|
||||
let messages ← step.messageStrings
|
||||
return (step.before, boundary, invocations?, sorrys, messages)
|
||||
let newConstants ← if args.newConstants then
|
||||
Frontend.collectNewDefinedConstants step
|
||||
else
|
||||
pure []
|
||||
return (step.before, boundary, invocations?, sorrys, messages, newConstants)
|
||||
let li ← frontendM.run context |>.run' state
|
||||
let units ← li.mapM λ (env, boundary, invocations?, sorrys, messages) => Lean.withEnv env do
|
||||
let (goalStateId?, goals) ← if sorrys.isEmpty then do
|
||||
pure (.none, #[])
|
||||
let units ← li.mapM λ (env, boundary, invocations?, sorrys, messages, newConstants) => Lean.withEnv env do
|
||||
let newConstants? := if args.newConstants then
|
||||
.some $ newConstants.toArray.map λ name => name.toString
|
||||
else
|
||||
.none
|
||||
let (goalStateId?, goals?, goalSrcBoundaries?) ← if sorrys.isEmpty then do
|
||||
pure (.none, .none, .none)
|
||||
else do
|
||||
let goalState ← runMetaInMainM $ Frontend.sorrysToGoalState sorrys
|
||||
let stateId ← newGoalState goalState
|
||||
let goals ← goalSerialize goalState options
|
||||
pure (.some stateId, goals)
|
||||
let { state, srcBoundaries } ← runMetaInMainM $ Frontend.sorrysToGoalState sorrys
|
||||
let stateId ← newGoalState state
|
||||
let goals ← goalSerialize state options
|
||||
let srcBoundaries := srcBoundaries.toArray.map (λ (b, e) => (b.byteIdx, e.byteIdx))
|
||||
pure (.some stateId, .some goals, .some srcBoundaries)
|
||||
return {
|
||||
boundary,
|
||||
messages,
|
||||
invocations?,
|
||||
goalStateId?,
|
||||
goals,
|
||||
messages,
|
||||
goals?,
|
||||
goalSrcBoundaries?,
|
||||
newConstants?,
|
||||
}
|
||||
return .ok { units }
|
||||
catch e =>
|
||||
|
|
|
@ -10,13 +10,13 @@ def collectSorrysFromSource (source: String) : MetaM (List GoalState) := do
|
|||
let filename := "<anonymous>"
|
||||
let (context, state) ← do Frontend.createContextStateFromFile source filename (← getEnv) {}
|
||||
let m := Frontend.mapCompilationSteps λ step => do
|
||||
return (step.before, Frontend.collectSorrys step)
|
||||
return (step.before, ← Frontend.collectSorrys step)
|
||||
let li ← m.run context |>.run' state
|
||||
let goalStates ← li.filterMapM λ (env, sorrys) => withEnv env do
|
||||
if sorrys.isEmpty then
|
||||
return .none
|
||||
let goalState ← Frontend.sorrysToGoalState sorrys
|
||||
return .some goalState
|
||||
let { state, .. } ← Frontend.sorrysToGoalState sorrys
|
||||
return .some state
|
||||
return goalStates
|
||||
|
||||
def test_multiple_sorrys_in_proof : TestT MetaM Unit := do
|
||||
|
@ -177,6 +177,47 @@ example (n: Nat) : mystery n + 1 = n + 2 := sorry
|
|||
}
|
||||
])
|
||||
|
||||
def test_capture_type_mismatch : TestT MetaM Unit := do
|
||||
let input := "
|
||||
def mystery (k: Nat) : Nat := true
|
||||
"
|
||||
let goalStates ← (collectSorrysFromSource input).run' {}
|
||||
let [goalState] := goalStates | panic! s!"Incorrect number of states: {goalStates.length}"
|
||||
checkEq "goals" ((← goalState.serializeGoals (options := {})).map (·.devolatilize)) #[
|
||||
{
|
||||
target := { pp? := "Nat" },
|
||||
vars := #[{
|
||||
userName := "k",
|
||||
type? := .some { pp? := "Nat" },
|
||||
}],
|
||||
}
|
||||
]
|
||||
|
||||
def collectNewConstants (source: String) : MetaM (List (List Name)) := do
|
||||
let filename := "<anonymous>"
|
||||
let (context, state) ← do Frontend.createContextStateFromFile source filename (← getEnv) {}
|
||||
let m := Frontend.mapCompilationSteps λ step => do
|
||||
Frontend.collectNewDefinedConstants step
|
||||
m.run context |>.run' state
|
||||
|
||||
def test_collect_one_constant : TestT MetaM Unit := do
|
||||
let input := "
|
||||
def mystery : Nat := 123
|
||||
"
|
||||
let names ← collectNewConstants input
|
||||
checkEq "constants" names [[`mystery]]
|
||||
def test_collect_one_theorem : TestT MetaM Unit := do
|
||||
let input := "
|
||||
theorem mystery [SizeOf α] (as : List α) (i : Fin as.length) : sizeOf (as.get i) < sizeOf as := by
|
||||
match as, i with
|
||||
| a::as, ⟨0, _⟩ => simp_arith [get]
|
||||
| a::as, ⟨i+1, h⟩ =>
|
||||
have ih := sizeOf_get as ⟨i, Nat.le_of_succ_le_succ h⟩
|
||||
apply Nat.lt_trans ih
|
||||
simp_arith
|
||||
"
|
||||
let names ← collectNewConstants input
|
||||
checkEq "constants" names [[`mystery]]
|
||||
|
||||
def suite (env : Environment): List (String × IO LSpec.TestSeq) :=
|
||||
let tests := [
|
||||
|
@ -185,6 +226,9 @@ def suite (env : Environment): List (String × IO LSpec.TestSeq) :=
|
|||
("sorry_in_induction", test_sorry_in_induction),
|
||||
("sorry_in_coupled", test_sorry_in_coupled),
|
||||
("environment_capture", test_environment_capture),
|
||||
("capture_type_mismatch", test_capture_type_mismatch),
|
||||
("collect_one_constant", test_collect_one_constant),
|
||||
("collect_one_theorem", test_collect_one_theorem),
|
||||
]
|
||||
tests.map (fun (name, test) => (name, runMetaMSeq env $ runTest test))
|
||||
|
||||
|
|
|
@ -174,6 +174,7 @@ def test_frontend_process : Test :=
|
|||
("file", .str file),
|
||||
("invocations", .bool true),
|
||||
("sorrys", .bool false),
|
||||
("newConstants", .bool false),
|
||||
]
|
||||
({
|
||||
units := [{
|
||||
|
@ -214,6 +215,7 @@ def test_frontend_process_sorry : Test :=
|
|||
("file", .str file),
|
||||
("invocations", .bool false),
|
||||
("sorrys", .bool true),
|
||||
("newConstants", .bool false),
|
||||
]
|
||||
({
|
||||
units := [{
|
||||
|
@ -221,7 +223,8 @@ def test_frontend_process_sorry : Test :=
|
|||
}, {
|
||||
boundary := (solved.utf8ByteSize, solved.utf8ByteSize + withSorry.utf8ByteSize),
|
||||
goalStateId? := .some 0,
|
||||
goals := #[goal1],
|
||||
goals? := .some #[goal1],
|
||||
goalSrcBoundaries? := .some #[(57, 62)],
|
||||
messages := #["<anonymous>:2:0: warning: declaration uses 'sorry'\n"],
|
||||
}],
|
||||
}: Protocol.FrontendProcessResult),
|
||||
|
|
|
@ -701,7 +701,7 @@ def test_nat_zero_add_alt: TestM Unit := do
|
|||
}
|
||||
])
|
||||
|
||||
def test_composite_tactic_failure: TestM Unit := do
|
||||
def test_tactic_failure_unresolved_goals : TestM Unit := do
|
||||
let state? ← startProof (.expr "∀ (p : Nat → Prop), ∃ (x : Nat), p (0 + x + 0)")
|
||||
let state0 ← match state? with
|
||||
| .some state => pure state
|
||||
|
@ -720,6 +720,37 @@ def test_composite_tactic_failure: TestM Unit := do
|
|||
let .failure messages ← state1.tacticOn 0 tactic | addTest $ assertUnreachable s!"{tactic} should fail"
|
||||
checkEq s!"{tactic} fails" messages #[s!"{← getFileName}:0:12: error: unsolved goals\np : Nat → Prop\n⊢ p 0\n"]
|
||||
|
||||
|
||||
def test_tactic_failure_synthesize_placeholder : TestM Unit := do
|
||||
let state? ← startProof (.expr "∀ (p q r : Prop) (h : p → q), q ∧ r")
|
||||
let state0 ← match state? with
|
||||
| .some state => pure state
|
||||
| .none => do
|
||||
addTest $ assertUnreachable "Goal could not parse"
|
||||
return ()
|
||||
|
||||
let tactic := "intro p q r h"
|
||||
let state1 ← match ← state0.tacticOn 0 tactic with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
|
||||
let tactic := "simpa [h] using And.imp_left h _"
|
||||
let state2 ← match ← state1.tacticOn 0 tactic with
|
||||
| .success state => pure state
|
||||
| other => do
|
||||
addTest $ assertUnreachable $ other.toString
|
||||
return ()
|
||||
|
||||
checkEq tactic ((← state2.serializeGoals).map (·.devolatilize)) #[
|
||||
buildGoal [("p", "Prop"), ("q", "Prop"), ("r", "Prop"), ("h", "p → q")] "p ∧ r"
|
||||
]
|
||||
|
||||
--let .failure messages ← state1.tacticOn 0 tactic | addTest $ assertUnreachable s!"{tactic} should fail"
|
||||
--let message := s!"<Pantograph>:0:31: error: don't know how to synthesize placeholder\ncontext:\np q r : Prop\nh : p → q\n⊢ p ∧ r\n"
|
||||
--checkEq s!"{tactic} fails" messages #[message]
|
||||
|
||||
def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
|
||||
let tests := [
|
||||
("identity", test_identity),
|
||||
|
@ -732,7 +763,8 @@ def suite (env: Environment): List (String × IO LSpec.TestSeq) :=
|
|||
("calc", test_calc),
|
||||
("Nat.zero_add", test_nat_zero_add),
|
||||
("Nat.zero_add alt", test_nat_zero_add_alt),
|
||||
("composite tactic failure", test_composite_tactic_failure),
|
||||
("tactic failure with unresolved goals", test_tactic_failure_unresolved_goals),
|
||||
("tactic failure with synthesize placeholder", test_tactic_failure_synthesize_placeholder),
|
||||
]
|
||||
tests.map (fun (name, test) => (name, proofRunner env test))
|
||||
|
||||
|
|
|
@ -24,6 +24,22 @@ The name Pantograph is a pun. It means two things
|
|||
a locomotive. In comparison the (relatively) simple Pantograph software powers
|
||||
theorem proving projects.
|
||||
|
||||
## Caveats
|
||||
|
||||
Pantograph does not exactly mimic Lean LSP's behaviour. That would not grant the
|
||||
flexibility it offers. To support tree search means Pantograph has to act
|
||||
differently from Lean in some times, but never at the sacrifice of soundness.
|
||||
|
||||
- When Lean LSP says "don't know how to synthesize placeholder", this indicates
|
||||
the human operator needs to manually move the cursor to the placeholder and
|
||||
type in the correct expression. This error therefore should not halt the proof
|
||||
process, and the placeholder should be turned into a goal.
|
||||
- When Lean LSP says "unresolved goals", that means a proof cannot finish where
|
||||
it is supposed to finish at the end of a `by` block. Pantograph will raise the
|
||||
error in this case, since it indicates the termination of a proof search branch.
|
||||
- `pick_goal` or `swap` will not work since they run contrary to tree search
|
||||
paradigms.
|
||||
|
||||
## References
|
||||
|
||||
* [Pantograph Paper](https://arxiv.org/abs/2410.16429)
|
||||
|
|
|
@ -44,9 +44,11 @@ See `Pantograph/Protocol.lean` for a description of the parameters and return va
|
|||
state. The user is responsible to ensure the sender/receiver instances share
|
||||
the same environment.
|
||||
* `frontend.process { ["fileName": <fileName>,] ["file": <str>], invocations:
|
||||
<bool>, sorrys: <bool> }`: Executes the Lean frontend on a file, collecting
|
||||
either the tactic invocations (`"invocations": true`) or the sorrys into goal
|
||||
states (`"sorrys": true`)
|
||||
<bool>, sorrys: <bool>, newConstants: <bool> }`: Executes the Lean frontend on
|
||||
a file, collecting the tactic invocations (`"invocations": true`), the
|
||||
sorrys and type errors into goal states (`"sorrys": true`), and new constants
|
||||
(`"newConstants": true`). In the case of `sorrys`, this command additionally
|
||||
outputs the position of each captured `sorry`.
|
||||
|
||||
## Errors
|
||||
|
||||
|
|
Loading…
Reference in New Issue