chore: Version 0.3 #136

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@ -1,4 +1,4 @@
/- Adapted from lean-training-data by semorrison -/
import Pantograph.Frontend.Basic import Pantograph.Frontend.Basic
import Pantograph.Frontend.Elab import Pantograph.Frontend.Elab
import Pantograph.Frontend.InfoTree
import Pantograph.Frontend.MetaTranslate import Pantograph.Frontend.MetaTranslate

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@ -30,6 +30,13 @@ end Lean.PersistentArray
namespace Pantograph.Frontend namespace Pantograph.Frontend
@[export pantograph_frontend_stx_byte_range]
def stxByteRange (stx : Syntax) : String.Pos × String.Pos :=
let pos := stx.getPos?.getD 0
let endPos := stx.getTailPos?.getD 0
(pos, endPos)
abbrev FrontendM := Elab.Frontend.FrontendM abbrev FrontendM := Elab.Frontend.FrontendM
structure CompilationStep where structure CompilationStep where

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@ -1,87 +1,21 @@
/- Adapted from https://github.com/semorrison/lean-training-data -/
import Lean.Elab.Import import Lean.Elab.Import
import Lean.Elab.Command import Lean.Elab.Command
import Lean.Elab.InfoTree import Lean.Elab.InfoTree
import Lean.DeclarationRange
import Pantograph.Frontend.Basic import Pantograph.Frontend.Basic
import Pantograph.Frontend.MetaTranslate import Pantograph.Frontend.MetaTranslate
import Pantograph.Goal import Pantograph.Goal
import Pantograph.Protocol import Pantograph.Protocol
import Pantograph.Frontend.InfoTree
open Lean open Lean
namespace Lean.Elab.Info
/-- The `Syntax` for a `Lean.Elab.Info`, if there is one. -/
protected def stx? : Info → Option Syntax
| .ofTacticInfo info => info.stx
| .ofTermInfo info => info.stx
| .ofCommandInfo info => info.stx
| .ofMacroExpansionInfo info => info.stx
| .ofOptionInfo info => info.stx
| .ofFieldInfo info => info.stx
| .ofCompletionInfo info => info.stx
| .ofUserWidgetInfo info => info.stx
| .ofCustomInfo info => info.stx
| .ofFVarAliasInfo _ => none
| .ofFieldRedeclInfo info => info.stx
| .ofOmissionInfo info => info.stx
/-- Is the `Syntax` for this `Lean.Elab.Info` original, or synthetic? -/
protected def isOriginal (i : Info) : Bool :=
match i.stx? with
| none => true -- Somewhat unclear what to do with `FVarAliasInfo`, so be conservative.
| some stx => match stx.getHeadInfo with
| .original .. => true
| _ => false
end Lean.Elab.Info
namespace Lean.Elab.TacticInfo
/-- Find the name for the outermost `Syntax` in this `TacticInfo`. -/
def name? (t : TacticInfo) : Option Name :=
match t.stx with
| Syntax.node _ n _ => some n
| _ => none
/-- Decide whether a tactic is "substantive",
or is merely a tactic combinator (e.g. `by`, `;`, multiline tactics, parenthesized tactics). -/
def isSubstantive (t : TacticInfo) : Bool :=
match t.name? with
| none => false
| some `null => false
| some ``cdot => false
| some ``cdotTk => false
| some ``Lean.Parser.Term.byTactic => false
| some ``Lean.Parser.Tactic.tacticSeq => false
| some ``Lean.Parser.Tactic.tacticSeq1Indented => false
| some ``Lean.Parser.Tactic.«tactic_<;>_» => false
| some ``Lean.Parser.Tactic.paren => false
| _ => true
end Lean.Elab.TacticInfo
namespace Lean.Elab.InfoTree
/--
Keep `.node` nodes and `.hole` nodes satisfying predicates.
Returns a `List InfoTree`, although in most situations this will be a singleton.
-/
partial def filter (p : Info → Bool) (m : MVarId → Bool := fun _ => false) :
InfoTree → List InfoTree
| .context ctx tree => tree.filter p m |>.map (.context ctx)
| .node info children =>
if p info then
[.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 []
end Lean.Elab.InfoTree
namespace Pantograph.Frontend namespace Pantograph.Frontend
-- Info tree filtering functions -- Info tree filtering functions
/- Adapted from lean-training-data -/
structure TacticInvocation where structure TacticInvocation where
info : Elab.TacticInfo info : Elab.TacticInfo
ctx : Elab.ContextInfo ctx : Elab.ContextInfo
@ -131,19 +65,10 @@ protected def usedConstants (t: TacticInvocation) : NameSet :=
end TacticInvocation end TacticInvocation
/-- Analogue of `Lean.Elab.InfoTree.findInfo?`, but that returns a list of all results. -/
partial def findAllInfo (t : Elab.InfoTree) (context?: Option Elab.ContextInfo) (pred : Elab.Info → Bool) :
List (Elab.Info × Option Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
match t with
| .context inner t => findAllInfo t (inner.mergeIntoOuter? context?) pred
| .node i children =>
(if pred i then [(i, context?, children)] else []) ++ children.toList.bind (fun t => findAllInfo t context? pred)
| _ => []
/-- Return all `TacticInfo` nodes in an `InfoTree` corresponding to tactics, /-- Return all `TacticInfo` nodes in an `InfoTree` corresponding to tactics,
each equipped with its relevant `ContextInfo`, and any children info trees. -/ each equipped with its relevant `ContextInfo`, and any children info trees. -/
private def collectTacticNodes (t : Elab.InfoTree) : List TacticInvocation := private def collectTacticNodes (t : Elab.InfoTree) : List TacticInvocation :=
let infos := findAllInfo t none fun i => match i with let infos := t.findAllInfo none false fun i => match i with
| .ofTacticInfo _ => true | .ofTacticInfo _ => true
| _ => false | _ => false
infos.filterMap fun p => match p with infos.filterMap fun p => match p with
@ -162,9 +87,11 @@ def collectTacticsFromCompilationStep (step : CompilationStep) : IO (List Protoc
tactics.mapM λ invocation => do tactics.mapM λ invocation => do
let goalBefore := (Format.joinSep (← invocation.goalState) "\n").pretty let goalBefore := (Format.joinSep (← invocation.goalState) "\n").pretty
let goalAfter := (Format.joinSep (← invocation.goalStateAfter) "\n").pretty let goalAfter := (Format.joinSep (← invocation.goalStateAfter) "\n").pretty
let tactic ← invocation.ctx.runMetaM {} do let tactic ← invocation.ctx.runMetaM {} <| Meta.withMCtx invocation.info.mctxBefore do
let t ← PrettyPrinter.ppTactic ⟨invocation.info.stx⟩ return (← invocation.ctx.ppSyntax {} invocation.info.stx).pretty
return t.pretty -- FIXME: Why does this not work? There are problems with `term.pseudo.antiquot`
--PrettyPrinter.ppTactic ⟨invocation.info.stx⟩
--return t.pretty
let usedConstants := invocation.usedConstants.toArray.map λ n => n.toString let usedConstants := invocation.usedConstants.toArray.map λ n => n.toString
return { return {
goalBefore, goalBefore,
@ -177,47 +104,79 @@ structure InfoWithContext where
info: Elab.Info info: Elab.Info
context?: Option Elab.ContextInfo := .none context?: Option Elab.ContextInfo := .none
private def collectSorrysInTree (t : Elab.InfoTree) : List InfoWithContext := private def collectSorrysInTree (t : Elab.InfoTree) : IO (List InfoWithContext) := do
let infos := findAllInfo t none fun i => match i with let infos ← t.findAllInfoM none fun i ctx? => match i with
| .ofTermInfo { expectedType?, expr, stx, .. } => | .ofTermInfo { expectedType?, expr, stx, lctx, .. } => do
expr.isSorry ∧ expectedType?.isSome ∧ stx.isOfKind `Lean.Parser.Term.sorry let .some ctx := ctx? | return (false, true)
if expr.isSorry ∧ stx.isOfKind `Lean.Parser.Term.sorry then
if expectedType?.isNone then
throw $ .userError "Sorry of indeterminant type is not allowed"
return (true, false)
let .some expectedType := expectedType? | return (false, true)
let typeMatch ← ctx.runMetaM lctx do
let type ← Meta.inferType expr
Meta.isExprDefEqGuarded type expectedType
return match typeMatch, expr.hasSorry with
| false, true => (true, false) -- Types mismatch but has sorry -> collect, halt
| false, false => (true, false) -- Types mistmatch but no sorry -> collect, halt
| true, true => (false, true) -- Types match but has sorry -> continue
| true, false => (false, false) -- Types match but no sorries -> halt
| .ofTacticInfo { stx, goalsBefore, .. } => | .ofTacticInfo { stx, goalsBefore, .. } =>
-- The `sorry` term is distinct from the `sorry` tactic -- The `sorry` term is distinct from the `sorry` tactic
let isSorry := stx.isOfKind `Lean.Parser.Tactic.tacticSorry let isSorry := stx.isOfKind `Lean.Parser.Tactic.tacticSorry
isSorry ∧ !goalsBefore.isEmpty return (isSorry ∧ !goalsBefore.isEmpty, ¬ isSorry)
| _ => false | _ => return (false, true)
infos.map fun (info, context?, _) => { info, context? } return infos.map fun (info, context?, _) => { info, context? }
-- NOTE: Plural deliberately not spelled "sorries" -- NOTE: Plural deliberately not spelled "sorries"
@[export pantograph_frontend_collect_sorrys_m] @[export pantograph_frontend_collect_sorrys_m]
def collectSorrys (step: CompilationStep) : List InfoWithContext := def collectSorrys (step: CompilationStep) : IO (List InfoWithContext) := do
step.trees.bind collectSorrysInTree return (← step.trees.mapM collectSorrysInTree).join
structure AnnotatedGoalState where
state : GoalState
srcBoundaries : List (String.Pos × String.Pos)
/-- /--
Since we cannot directly merge `MetavarContext`s, we have to get creative. This Since we cannot directly merge `MetavarContext`s, we have to get creative. This
function duplicates frozen mvars in term and tactic info nodes, and add them to function duplicates frozen mvars in term and tactic info nodes, and add them to
the current `MetavarContext`. the current `MetavarContext`.
-/ -/
@[export pantograph_frontend_sorrys_to_goal_state] @[export pantograph_frontend_sorrys_to_goal_state_m]
def sorrysToGoalState (sorrys : List InfoWithContext) : MetaM GoalState := do def sorrysToGoalState (sorrys : List InfoWithContext) : MetaM AnnotatedGoalState := do
assert! !sorrys.isEmpty assert! !sorrys.isEmpty
let goalsM := sorrys.mapM λ i => do let goalsM := sorrys.mapM λ i => do
match i.info with match i.info with
| .ofTermInfo termInfo => do | .ofTermInfo termInfo => do
let mvarId ← MetaTranslate.translateMVarFromTermInfo termInfo i.context? let mvarId ← MetaTranslate.translateMVarFromTermInfo termInfo i.context?
return [mvarId] return [(mvarId, stxByteRange termInfo.stx)]
| .ofTacticInfo tacticInfo => do | .ofTacticInfo tacticInfo => do
MetaTranslate.translateMVarFromTacticInfoBefore tacticInfo i.context? let mvarIds ← MetaTranslate.translateMVarFromTacticInfoBefore tacticInfo i.context?
let range := stxByteRange tacticInfo.stx
return mvarIds.map (·, range)
| _ => panic! "Invalid info" | _ => panic! "Invalid info"
let goals := List.join (← goalsM.run {} |>.run' {}) let annotatedGoals := List.join (← goalsM.run {} |>.run' {})
let goals := annotatedGoals.map Prod.fst
let srcBoundaries := annotatedGoals.map Prod.snd
let root := match goals with let root := match goals with
| [] => panic! "No MVars generated" | [] => panic! "No MVars generated"
| [g] => g | [g] => g
| _ => { name := .anonymous } | _ => { name := .anonymous }
GoalState.createFromMVars goals root let state ← GoalState.createFromMVars goals root
return { state, srcBoundaries }
@[export pantograph_frontend_collect_new_defined_constants_m]
def collectNewDefinedConstants (step : CompilationStep) : IO (List Name) := do
step.after.constants.map₂.foldlM (λ acc name _ => do
if step.before.contains name then
return acc
let coreM : CoreM Bool := Option.isSome <$> findDeclarationRanges? name
let hasRange ← coreM.run' { fileName := step.fileName, fileMap := step.fileMap } { env := step.after } |>.toBaseIO
match hasRange with
| .ok true => return name :: acc
| .ok false => return acc
| .error e => throw $ IO.userError (← e.toMessageData.toString)
) []
end Pantograph.Frontend end Pantograph.Frontend

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@ -0,0 +1,153 @@
/- Adapted from lean-training-data -/
import Lean.Elab.InfoTree
import Lean.Parser.Term
import Lean.PrettyPrinter
open Lean
namespace Lean.Elab
private def elaboratorToString : Name → String
| .anonymous => ""
| n => s!"⟨{n}⟩ "
private def indent (s : String) : String := "\n".intercalate $ s.splitOn "\n" |>.map ("\t" ++ .)
/-- The `Syntax` for a `Lean.Elab.Info`, if there is one. -/
protected def Info.stx? : Info → Option Syntax
| .ofTacticInfo info => info.stx
| .ofTermInfo info => info.stx
| .ofCommandInfo info => info.stx
| .ofMacroExpansionInfo info => info.stx
| .ofOptionInfo info => info.stx
| .ofFieldInfo info => info.stx
| .ofCompletionInfo info => info.stx
| .ofUserWidgetInfo info => info.stx
| .ofCustomInfo info => info.stx
| .ofFVarAliasInfo _ => none
| .ofFieldRedeclInfo info => info.stx
| .ofOmissionInfo info => info.stx
/-- Is the `Syntax` for this `Lean.Elab.Info` original, or synthetic? -/
protected def Info.isOriginal (i : Info) : Bool :=
match i.stx? with
| none => true -- Somewhat unclear what to do with `FVarAliasInfo`, so be conservative.
| some stx => match stx.getHeadInfo with
| .original .. => true
| _ => false
def ContextInfo.ppExpr (ctx : ContextInfo) (lctx : LocalContext) (e : Expr) : IO Format :=
ctx.runMetaM lctx (do Meta.ppExpr (← instantiateMVars e))
def CommandInfo.toString (info : CommandInfo) (ctx : ContextInfo) : IO String := do
let stx := (← ctx.ppSyntax {} info.stx).pretty
return s!"{elaboratorToString info.elaborator}\n{stx}"
def TermInfo.toString (info : TermInfo) (ctx : ContextInfo) : IO String := do
let stx := (← ctx.ppSyntax info.lctx info.stx).pretty
let expectedType := (← info.expectedType?.mapM fun ty => do
pure s!": {(← ctx.ppExpr info.lctx ty).pretty}").getD ""
let expr := (← ctx.ppExpr info.lctx info.expr).pretty
return s!"{elaboratorToString info.elaborator}{expr}{expectedType}\n{stx}"
/-- Find the name for the outermost `Syntax` in this `TacticInfo`. -/
def TacticInfo.name? (t : TacticInfo) : Option Name :=
match t.stx with
| Syntax.node _ n _ => some n
| _ => none
/-- Decide whether a tactic is "substantive",
or is merely a tactic combinator (e.g. `by`, `;`, multiline tactics, parenthesized tactics). -/
def TacticInfo.isSubstantive (t : TacticInfo) : Bool :=
match t.name? with
| none => false
| some `null => false
| some ``cdot => false
| some ``cdotTk => false
| some ``Lean.Parser.Term.byTactic => false
| some ``Lean.Parser.Tactic.tacticSeq => false
| some ``Lean.Parser.Tactic.tacticSeq1Indented => false
| some ``Lean.Parser.Tactic.«tactic_<;>_» => false
| some ``Lean.Parser.Tactic.paren => false
| _ => true
def TacticInfo.pp (info : TacticInfo) (ctx : ContextInfo) : IO Format :=
ctx.runMetaM {} try
Lean.PrettyPrinter.ppTactic ⟨info.stx⟩
catch _ =>
pure "<failed to pretty print>"
def TacticInfo.toString (i : TacticInfo) (ctx : ContextInfo) : IO String := do
let name := i.name?
let stx := Format.pretty (← i.pp ctx)
return s!"{name}\n{stx}"
/--
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) :
InfoTree → List InfoTree
| .context ctx tree => tree.filter p m |>.map (.context ctx)
| .node info children =>
if p info then
[.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

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@ -312,6 +312,8 @@ structure FrontendProcess where
invocations: Bool := false invocations: Bool := false
-- If set to true, collect `sorry`s -- If set to true, collect `sorry`s
sorrys: Bool := false sorrys: Bool := false
-- If set to true, extract new constants
newConstants: Bool := false
deriving Lean.FromJson deriving Lean.FromJson
structure InvokedTactic where structure InvokedTactic where
goalBefore: String goalBefore: String
@ -325,11 +327,16 @@ structure InvokedTactic where
structure CompilationUnit where structure CompilationUnit where
-- String boundaries of compilation units -- String boundaries of compilation units
boundary: (Nat × Nat) boundary: (Nat × Nat)
messages: Array String := #[]
-- Tactic invocations -- Tactic invocations
invocations?: Option (List InvokedTactic) := .none invocations?: Option (List InvokedTactic) := .none
goalStateId?: Option Nat := .none goalStateId?: Option Nat := .none
goals: Array Goal := #[] goals?: Option (Array Goal) := .none
messages: Array String := #[] -- 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 deriving Lean.ToJson
structure FrontendProcessResult where structure FrontendProcessResult where
units: List CompilationUnit units: List CompilationUnit

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@ -257,27 +257,38 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
pure $ .some invocations pure $ .some invocations
else else
pure .none pure .none
let sorrys := if args.sorrys then let sorrys if args.sorrys then
Frontend.collectSorrys step Frontend.collectSorrys step
else else
[] pure []
let messages ← step.messageStrings 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 li ← frontendM.run context |>.run' state
let units ← li.mapM λ (env, boundary, invocations?, sorrys, messages) => Lean.withEnv env do let units ← li.mapM λ (env, boundary, invocations?, sorrys, messages, newConstants) => Lean.withEnv env do
let (goalStateId?, goals) ← if sorrys.isEmpty then do let newConstants? := if args.newConstants then
pure (.none, #[]) .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 else do
let goalState ← runMetaInMainM $ Frontend.sorrysToGoalState sorrys let { state, srcBoundaries } ← runMetaInMainM $ Frontend.sorrysToGoalState sorrys
let stateId ← newGoalState goalState let stateId ← newGoalState state
let goals ← goalSerialize goalState options let goals ← goalSerialize state options
pure (.some stateId, goals) let srcBoundaries := srcBoundaries.toArray.map (λ (b, e) => (b.byteIdx, e.byteIdx))
pure (.some stateId, .some goals, .some srcBoundaries)
return { return {
boundary, boundary,
messages,
invocations?, invocations?,
goalStateId?, goalStateId?,
goals, goals?,
messages, goalSrcBoundaries?,
newConstants?,
} }
return .ok { units } return .ok { units }
catch e => catch e =>

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@ -10,13 +10,13 @@ def collectSorrysFromSource (source: String) : MetaM (List GoalState) := do
let filename := "<anonymous>" let filename := "<anonymous>"
let (context, state) ← do Frontend.createContextStateFromFile source filename (← getEnv) {} let (context, state) ← do Frontend.createContextStateFromFile source filename (← getEnv) {}
let m := Frontend.mapCompilationSteps λ step => do 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 li ← m.run context |>.run' state
let goalStates ← li.filterMapM λ (env, sorrys) => withEnv env do let goalStates ← li.filterMapM λ (env, sorrys) => withEnv env do
if sorrys.isEmpty then if sorrys.isEmpty then
return .none return .none
let goalState ← Frontend.sorrysToGoalState sorrys let { state, .. } ← Frontend.sorrysToGoalState sorrys
return .some goalState return .some state
return goalStates return goalStates
def test_multiple_sorrys_in_proof : TestT MetaM Unit := do 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) := def suite (env : Environment): List (String × IO LSpec.TestSeq) :=
let tests := [ let tests := [
@ -185,6 +226,9 @@ def suite (env : Environment): List (String × IO LSpec.TestSeq) :=
("sorry_in_induction", test_sorry_in_induction), ("sorry_in_induction", test_sorry_in_induction),
("sorry_in_coupled", test_sorry_in_coupled), ("sorry_in_coupled", test_sorry_in_coupled),
("environment_capture", test_environment_capture), ("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)) tests.map (fun (name, test) => (name, runMetaMSeq env $ runTest test))

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@ -174,6 +174,7 @@ def test_frontend_process : Test :=
("file", .str file), ("file", .str file),
("invocations", .bool true), ("invocations", .bool true),
("sorrys", .bool false), ("sorrys", .bool false),
("newConstants", .bool false),
] ]
({ ({
units := [{ units := [{
@ -214,6 +215,7 @@ def test_frontend_process_sorry : Test :=
("file", .str file), ("file", .str file),
("invocations", .bool false), ("invocations", .bool false),
("sorrys", .bool true), ("sorrys", .bool true),
("newConstants", .bool false),
] ]
({ ({
units := [{ units := [{
@ -221,7 +223,8 @@ def test_frontend_process_sorry : Test :=
}, { }, {
boundary := (solved.utf8ByteSize, solved.utf8ByteSize + withSorry.utf8ByteSize), boundary := (solved.utf8ByteSize, solved.utf8ByteSize + withSorry.utf8ByteSize),
goalStateId? := .some 0, goalStateId? := .some 0,
goals := #[goal1], goals? := .some #[goal1],
goalSrcBoundaries? := .some #[(57, 62)],
messages := #["<anonymous>:2:0: warning: declaration uses 'sorry'\n"], messages := #["<anonymous>:2:0: warning: declaration uses 'sorry'\n"],
}], }],
}: Protocol.FrontendProcessResult), }: Protocol.FrontendProcessResult),

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@ -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 state. The user is responsible to ensure the sender/receiver instances share
the same environment. the same environment.
* `frontend.process { ["fileName": <fileName>,] ["file": <str>], invocations: * `frontend.process { ["fileName": <fileName>,] ["file": <str>], invocations:
<bool>, sorrys: <bool> }`: Executes the Lean frontend on a file, collecting <bool>, sorrys: <bool>, newConstants: <bool> }`: Executes the Lean frontend on
either the tactic invocations (`"invocations": true`) or the sorrys into goal a file, collecting the tactic invocations (`"invocations": true`), the
states (`"sorrys": true`) 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 ## Errors