chore: Version 0.3 #136

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aniva wants to merge 487 commits from dev into main
20 changed files with 682 additions and 201 deletions
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@ -1,16 +1,15 @@
import Lean.Data.Json
import Lean.Environment
import Pantograph.Version
import Pantograph.Library
import Pantograph
import Repl
-- Main IO functions
open Pantograph
open Pantograph.Repl
open Pantograph.Protocol
/-- Parse a command either in `{ "cmd": ..., "payload": ... }` form or `cmd { ... }` form. -/
def parseCommand (s: String): Except String Protocol.Command := do
def parseCommand (s: String): Except String Command := do
let s := s.trim
match s.get? 0 with
| .some '{' => -- Parse in Json mode
@ -30,7 +29,7 @@ partial def loop : MainM Unit := do
if command.trim.length = 0 then return ()
match parseCommand command with
| .error error =>
let error := Lean.toJson ({ error := "command", desc := error }: Protocol.InteractionError)
let error := Lean.toJson ({ error := "command", desc := error }: InteractionError)
-- Using `Lean.Json.compress` here to prevent newline
IO.println error.compress
| .ok command =>
@ -46,15 +45,15 @@ unsafe def main (args: List String): IO Unit := do
-- NOTE: A more sophisticated scheme of command line argument handling is needed.
-- Separate imports and options
if args == ["--version"] then do
println! s!"{version}"
println! s!"{Pantograph.version}"
return
initSearch ""
Pantograph.initSearch ""
let coreContext ← args.filterMap (λ s => if s.startsWith "--" then .some <| s.drop 2 else .none)
|>.toArray |> createCoreContext
|>.toArray |> Pantograph.createCoreContext
let imports:= args.filter (λ s => ¬ (s.startsWith "--"))
let coreState ← createCoreState imports.toArray
let coreState ← Pantograph.createCoreState imports.toArray
let context: Context := {
imports
}

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@ -1,6 +1,6 @@
import Pantograph.Compile
import Pantograph.Condensed
import Pantograph.Environment
import Pantograph.Frontend
import Pantograph.Goal
import Pantograph.Library
import Pantograph.Protocol

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@ -1,25 +0,0 @@
/- Adapted from lean-training-data by semorrison -/
import Pantograph.Protocol
import Pantograph.Compile.Frontend
import Pantograph.Compile.Elab
import Pantograph.Compile.Parse
open Lean
namespace Pantograph.Compile
def collectTacticsFromCompilation (steps : List CompilationStep) : IO (List Protocol.InvokedTactic) := do
let infoTrees := steps.bind (·.trees)
let tacticInfoTrees := infoTrees.bind λ tree => tree.filter λ
| info@(.ofTacticInfo _) => info.isOriginal
| _ => false
let tactics := tacticInfoTrees.bind collectTactics
tactics.mapM λ invocation => do
let goalBefore := (Format.joinSep (← invocation.goalState) "\n").pretty
let goalAfter := (Format.joinSep (← invocation.goalStateAfter) "\n").pretty
let tactic ← invocation.ctx.runMetaM {} do
let t ← Lean.PrettyPrinter.ppTactic ⟨invocation.info.stx⟩
return t.pretty
return { goalBefore, goalAfter, tactic }
end Pantograph.Compile

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@ -1,14 +0,0 @@
import Lean
open Lean
namespace Pantograph.Compile
def parseTermM [Monad m] [MonadEnv m] (s: String): m (Except String Syntax) := do
return Parser.runParserCategory
(env := ← MonadEnv.getEnv)
(catName := `term)
(input := s)
(fileName := "<stdin>")
end Pantograph.Compile

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@ -2,7 +2,6 @@
import Lean
import Pantograph.Goal
import Pantograph.Expr
import Pantograph.Protocol
open Lean

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@ -60,53 +60,54 @@ partial def instantiateDelayedMVars (eOrig: Expr) : MetaM Expr := do
-- nested mvars.
mvarId.setKind .syntheticOpaque
let lctx ← MonadLCtx.getLCtx
if mvarDecl.lctx.any (λ decl => !lctx.contains decl.fvarId) then
let violations := mvarDecl.lctx.decls.foldl (λ acc decl? => match decl? with
| .some decl => if lctx.contains decl.fvarId then acc else acc ++ [decl.fvarId.name]
| .none => acc) []
panic! s!"Local context variable violation: {violations}"
mvarId.withContext do
let lctx ← MonadLCtx.getLCtx
if mvarDecl.lctx.any (λ decl => !lctx.contains decl.fvarId) then
let violations := mvarDecl.lctx.decls.foldl (λ acc decl? => match decl? with
| .some decl => if lctx.contains decl.fvarId then acc else acc ++ [decl.fvarId.name]
| .none => acc) []
panic! s!"In the context of {mvarId.name}, there are local context variable violations: {violations}"
if let .some assign ← getExprMVarAssignment? mvarId then
--IO.println s!"{padding}├A ?{mvarId.name}"
assert! !(← mvarId.isDelayedAssigned)
return .visit (mkAppN assign args)
else if let some { fvars, mvarIdPending } ← getDelayedMVarAssignment? mvarId then
--let substTableStr := String.intercalate ", " $ Array.zipWith fvars args (λ fvar assign => s!"{fvar.fvarId!.name} := {assign}") |>.toList
--IO.println s!"{padding}├MD ?{mvarId.name} := ?{mvarIdPending.name} [{substTableStr}]"
if let .some assign ← getExprMVarAssignment? mvarId then
--IO.println s!"{padding}├A ?{mvarId.name}"
assert! !(← mvarId.isDelayedAssigned)
return .visit (mkAppN assign args)
else if let some { fvars, mvarIdPending } ← getDelayedMVarAssignment? mvarId then
--let substTableStr := String.intercalate ", " $ Array.zipWith fvars args (λ fvar assign => s!"{fvar.fvarId!.name} := {assign}") |>.toList
--IO.println s!"{padding}├MD ?{mvarId.name} := ?{mvarIdPending.name} [{substTableStr}]"
if args.size < fvars.size then
throwError "Not enough arguments to instantiate a delay assigned mvar. This is due to bad implementations of a tactic: {args.size} < {fvars.size}. Expr: {toString e}; Origin: {toString eOrig}"
--if !args.isEmpty then
--IO.println s!"{padding}├── Arguments Begin"
let args ← args.mapM self
--if !args.isEmpty then
--IO.println s!"{padding}├── Arguments End"
if !(← mvarIdPending.isAssignedOrDelayedAssigned) then
--IO.println s!"{padding}├T1"
let result := mkAppN f args
if args.size < fvars.size then
throwError "Not enough arguments to instantiate a delay assigned mvar. This is due to bad implementations of a tactic: {args.size} < {fvars.size}. Expr: {toString e}; Origin: {toString eOrig}"
--if !args.isEmpty then
--IO.println s!"{padding}├── Arguments Begin"
let args ← args.mapM self
--if !args.isEmpty then
--IO.println s!"{padding}├── Arguments End"
if !(← mvarIdPending.isAssignedOrDelayedAssigned) then
--IO.println s!"{padding}├T1"
let result := mkAppN f args
return .done result
let pending ← mvarIdPending.withContext do
let inner ← instantiateDelayedMVars (.mvar mvarIdPending) --(level := level + 1)
--IO.println s!"{padding}├Pre: {inner}"
pure <| (← inner.abstractM fvars).instantiateRev args
-- Tail arguments
let result := mkAppRange pending fvars.size args.size args
--IO.println s!"{padding}├MD {result}"
return .done result
else
assert! !(← mvarId.isAssigned)
assert! !(← mvarId.isDelayedAssigned)
--if !args.isEmpty then
-- IO.println s!"{padding}├── Arguments Begin"
let args ← args.mapM self
--if !args.isEmpty then
-- IO.println s!"{padding}├── Arguments End"
let pending ← mvarIdPending.withContext do
let inner ← instantiateDelayedMVars (.mvar mvarIdPending) --(level := level + 1)
--IO.println s!"{padding}├Pre: {inner}"
pure <| (← inner.abstractM fvars).instantiateRev args
-- Tail arguments
let result := mkAppRange pending fvars.size args.size args
--IO.println s!"{padding}├MD {result}"
return .done result
else
assert! !(← mvarId.isAssigned)
assert! !(← mvarId.isDelayedAssigned)
--if !args.isEmpty then
-- IO.println s!"{padding}├── Arguments Begin"
let args ← args.mapM self
--if !args.isEmpty then
-- IO.println s!"{padding}├── Arguments End"
--IO.println s!"{padding}├M ?{mvarId.name}"
return .done (mkAppN f args))
--IO.println s!"{padding}├M ?{mvarId.name}"
return .done (mkAppN f args))
--IO.println s!"{padding}└Result {result}"
return result
where

4
Pantograph/Frontend.lean Normal file
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@ -0,0 +1,4 @@
/- Adapted from lean-training-data by semorrison -/
import Pantograph.Frontend.Basic
import Pantograph.Frontend.Elab
import Pantograph.Frontend.MetaTranslate

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@ -8,6 +8,7 @@ namespace Lean.FileMap
/-- Extract the range of a `Syntax` expressed as lines and columns. -/
-- Extracted from the private declaration `Lean.Elab.formatStxRange`,
-- in `Lean.Elab.InfoTree.Main`.
@[export pantograph_frontend_stx_range]
protected def stxRange (fileMap : FileMap) (stx : Syntax) : Position × Position :=
let pos := stx.getPos?.getD 0
let endPos := stx.getTailPos?.getD pos
@ -27,7 +28,9 @@ protected def drop [Inhabited α] (t : PersistentArray α) (n : Nat) : List α :
end Lean.PersistentArray
namespace Pantograph.Compile
namespace Pantograph.Frontend
abbrev FrontendM := Elab.Frontend.FrontendM
structure CompilationStep where
fileName : String
@ -44,7 +47,8 @@ structure CompilationStep where
Process one command, returning a `CompilationStep` and
`done : Bool`, indicating whether this was the last command.
-/
def processOneCommand: Elab.Frontend.FrontendM (CompilationStep × Bool) := do
@[export pantograph_frontend_process_one_command_m]
def processOneCommand: FrontendM (CompilationStep × Bool) := do
let s := (← get).commandState
let before := s.env
let done ← Elab.Frontend.processCommand
@ -57,30 +61,52 @@ def processOneCommand: Elab.Frontend.FrontendM (CompilationStep × Bool) := do
let ⟨_, fileName, fileMap⟩ := (← read).inputCtx
return ({ fileName, fileMap, src, stx, before, after, msgs, trees }, done)
partial def processFile : Elab.Frontend.FrontendM (List CompilationStep) := do
partial def mapCompilationSteps { α } (f: CompilationStep → IO α) : FrontendM (List α) := do
let (cmd, done) ← processOneCommand
if done then
return [cmd]
if cmd.src.isEmpty then
return []
else
return [← f cmd]
else
return cmd :: (← processFile)
return (← f cmd) :: (← mapCompilationSteps f)
@[export pantograph_frontend_find_source_path_m]
def findSourcePath (module : Name) : IO System.FilePath := do
return System.FilePath.mk ((← findOLean module).toString.replace ".lake/build/lib/" "") |>.withExtension "lean"
def processSource (module : Name) (opts : Options := {}) : IO (List CompilationStep) := unsafe do
let file ← IO.FS.readFile (← findSourcePath module)
let inputCtx := Parser.mkInputContext file module.toString
/--
Use with
```lean
let m: FrontendM α := ...
let (context, state) ← createContextStateFromFile ...
m.run context |>.run' state
```
-/
@[export pantograph_frontend_create_context_state_from_file_m]
def createContextStateFromFile
(file : String) -- Content of the file
(fileName : String := "<anonymous>")
(env? : Option Lean.Environment := .none) -- If set to true, assume there's no header.
(opts : Options := {})
: IO (Elab.Frontend.Context × Elab.Frontend.State) := unsafe do
--let file ← IO.FS.readFile (← findSourcePath module)
let inputCtx := Parser.mkInputContext file fileName
let (header, parserState, messages) ← Parser.parseHeader inputCtx
let (env, messages) ← Elab.processHeader header opts messages inputCtx
let (env, parserState, messages) ← match env? with
| .some env => pure (env, {}, .empty)
| .none =>
let (header, parserState, messages) ← Parser.parseHeader inputCtx
let (env, messages) ← Elab.processHeader header opts messages inputCtx
pure (env, parserState, messages)
let commandState := Elab.Command.mkState env messages opts
processFile.run { inputCtx }
|>.run' {
let context: Elab.Frontend.Context := { inputCtx }
let state: Elab.Frontend.State := {
commandState := { commandState with infoState.enabled := true },
parserState,
cmdPos := parserState.pos
}
return (context, state)
end Pantograph.Compile
end Pantograph.Frontend

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@ -1,9 +1,12 @@
/- Adapted from https://github.com/semorrison/lean-training-data -/
import Lean.Elab.Import
import Lean.Elab.Command
import Lean.Elab.InfoTree
import Pantograph.Compile.Frontend
import Pantograph.Frontend.Basic
import Pantograph.Frontend.MetaTranslate
import Pantograph.Goal
import Pantograph.Protocol
open Lean
@ -75,7 +78,7 @@ partial def filter (p : Info → Bool) (m : MVarId → Bool := fun _ => false) :
end Lean.Elab.InfoTree
namespace Pantograph.Compile
namespace Pantograph.Frontend
-- Info tree filtering functions
@ -86,6 +89,7 @@ structure TacticInvocation where
namespace TacticInvocation
/-- Return the range of the tactic, as a pair of file positions. -/
@[export pantograph_frontend_tactic_invocation_range]
protected def range (t : TacticInvocation) : Position × Position := t.ctx.fileMap.stxRange t.info.stx
/-- Pretty print a tactic. -/
@ -121,17 +125,17 @@ protected def ppExpr (t : TacticInvocation) (e : Expr) : IO Format :=
end TacticInvocation
/-- Analogue of `Lean.Elab.InfoTree.findInfo?`, but that returns a list of all results. -/
partial def findAllInfo (t : Elab.InfoTree) (ctx : Option Elab.ContextInfo) (pred : Elab.Info → Bool) :
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? ctx) pred
| .context inner t => findAllInfo t (inner.mergeIntoOuter? context?) pred
| .node i children =>
(if pred i then [(i, ctx, children)] else []) ++ children.toList.bind (fun t => findAllInfo t ctx pred)
(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,
each equipped with its relevant `ContextInfo`, and any children info trees. -/
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
| .ofTacticInfo _ => true
| _ => false
@ -142,5 +146,64 @@ def collectTacticNodes (t : Elab.InfoTree) : List TacticInvocation :=
def collectTactics (t : Elab.InfoTree) : List TacticInvocation :=
collectTacticNodes t |>.filter fun i => i.info.isSubstantive
@[export pantograph_frontend_collect_tactics_from_compilation_step_m]
def collectTacticsFromCompilationStep (step : CompilationStep) : IO (List Protocol.InvokedTactic) := do
let tacticInfoTrees := step.trees.bind λ tree => tree.filter λ
| info@(.ofTacticInfo _) => info.isOriginal
| _ => false
let tactics := tacticInfoTrees.bind collectTactics
tactics.mapM λ invocation => do
let goalBefore := (Format.joinSep (← invocation.goalState) "\n").pretty
let goalAfter := (Format.joinSep (← invocation.goalStateAfter) "\n").pretty
let tactic ← invocation.ctx.runMetaM {} do
let t ← PrettyPrinter.ppTactic ⟨invocation.info.stx⟩
return t.pretty
return { goalBefore, goalAfter, tactic }
end Pantograph.Compile
structure InfoWithContext where
info: Elab.Info
context?: Option Elab.ContextInfo := .none
private def collectSorrysInTree (t : Elab.InfoTree) : List InfoWithContext :=
let infos := findAllInfo t none fun i => match i with
| .ofTermInfo { expectedType?, expr, stx, .. } =>
expr.isSorry ∧ expectedType?.isSome ∧ stx.isOfKind `Lean.Parser.Term.sorry
| .ofTacticInfo { stx, .. } =>
-- The `sorry` term is distinct from the `sorry` tactic
stx.isOfKind `Lean.Parser.Tactic.tacticSorry
| _ => false
infos.map fun (info, context?, _) => { info, context? }
-- NOTE: Plural deliberately not spelled "sorries"
@[export pantograph_frontend_collect_sorrys_m]
def collectSorrys (step: CompilationStep) : List InfoWithContext :=
step.trees.bind collectSorrysInTree
/--
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
the current `MetavarContext`.
-/
@[export pantograph_frontend_sorrys_to_goal_state]
def sorrysToGoalState (sorrys : List InfoWithContext) : MetaM GoalState := do
assert! !sorrys.isEmpty
let goalsM := sorrys.mapM λ i => do
match i.info with
| .ofTermInfo termInfo => do
let mvarId ← MetaTranslate.translateMVarFromTermInfo termInfo i.context?
return [mvarId]
| .ofTacticInfo tacticInfo => do
MetaTranslate.translateMVarFromTacticInfoBefore tacticInfo i.context?
| _ => panic! "Invalid info"
let goals := (← goalsM.run {} |>.run' {}).bind id
let root := match goals with
| [] => panic! "This function cannot be called on an empty list"
| [g] => g
| _ => { name := .anonymous }
GoalState.createFromMVars goals root
end Pantograph.Frontend

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@ -0,0 +1,133 @@
import Lean.Meta
open Lean
namespace Pantograph.Frontend
namespace MetaTranslate
structure Context where
sourceMCtx : MetavarContext := {}
sourceLCtx : LocalContext := {}
abbrev FVarMap := HashMap FVarId FVarId
structure State where
-- Stores mapping from old to new mvar/fvars
mvarMap: HashMap MVarId MVarId := {}
fvarMap: HashMap FVarId FVarId := {}
/-
Monadic state for translating a frozen meta state. The underlying `MetaM`
operates in the "target" context and state.
-/
abbrev MetaTranslateM := ReaderT Context StateRefT State MetaM
def getSourceLCtx : MetaTranslateM LocalContext := do pure (← read).sourceLCtx
def getSourceMCtx : MetaTranslateM MetavarContext := do pure (← read).sourceMCtx
def addTranslatedFVar (src dst: FVarId) : MetaTranslateM Unit := do
modifyGet λ state => ((), { state with fvarMap := state.fvarMap.insert src dst })
def addTranslatedMVar (src dst: MVarId) : MetaTranslateM Unit := do
modifyGet λ state => ((), { state with mvarMap := state.mvarMap.insert src dst })
def saveFVarMap : MetaTranslateM FVarMap := do
return (← get).fvarMap
def restoreFVarMap (map: FVarMap) : MetaTranslateM Unit := do
modifyGet λ state => ((), { state with fvarMap := map })
def resetFVarMap : MetaTranslateM Unit := do
modifyGet λ state => ((), { state with fvarMap := {} })
mutual
private partial def translateExpr (srcExpr: Expr) : MetaTranslateM Expr := do
let sourceMCtx ← getSourceMCtx
let (srcExpr, _) := instantiateMVarsCore (mctx := sourceMCtx) srcExpr
--IO.println s!"Transform src: {srcExpr}"
let result ← Core.transform srcExpr λ e => do
let state ← get
match e with
| .fvar fvarId =>
let .some fvarId' := state.fvarMap.find? fvarId | panic! s!"FVar id not registered: {fvarId.name}"
assert! (← getLCtx).contains fvarId'
return .done $ .fvar fvarId'
| .mvar mvarId => do
assert! !(sourceMCtx.dAssignment.contains mvarId)
assert! !(sourceMCtx.eAssignment.contains mvarId)
match state.mvarMap.find? mvarId with
| .some mvarId' => do
return .done $ .mvar mvarId'
| .none => do
-- Entering another LCtx, must save the current one
let fvarMap ← saveFVarMap
let mvarId' ← translateMVarId mvarId
restoreFVarMap fvarMap
return .done $ .mvar mvarId'
| _ => return .continue
Meta.check result
return result
partial def translateLocalInstance (srcInstance: LocalInstance) : MetaTranslateM LocalInstance := do
return {
className := srcInstance.className,
fvar := ← translateExpr srcInstance.fvar
}
partial def translateLocalDecl (srcLocalDecl: LocalDecl) : MetaTranslateM LocalDecl := do
let fvarId ← mkFreshFVarId
addTranslatedFVar srcLocalDecl.fvarId fvarId
match srcLocalDecl with
| .cdecl index _ userName type bi kind => do
--IO.println s!"[CD] {userName} {toString type}"
return .cdecl index fvarId userName (← translateExpr type) bi kind
| .ldecl index _ userName type value nonDep kind => do
--IO.println s!"[LD] {toString type} := {toString value}"
return .ldecl index fvarId userName (← translateExpr type) (← translateExpr value) nonDep kind
partial def translateLCtx : MetaTranslateM LocalContext := do
resetFVarMap
let lctx ← MonadLCtx.getLCtx
assert! lctx.isEmpty
(← getSourceLCtx).foldlM (λ lctx srcLocalDecl => do
let localDecl ← Meta.withLCtx lctx #[] do
translateLocalDecl srcLocalDecl
pure $ lctx.addDecl localDecl
) lctx
partial def translateMVarId (srcMVarId: MVarId) : MetaTranslateM MVarId := do
if let .some mvarId' := (← get).mvarMap.find? srcMVarId then
return mvarId'
let mvar ← Meta.withLCtx .empty #[] do
let srcDecl := (← getSourceMCtx).findDecl? srcMVarId |>.get!
withTheReader Context (λ ctx => { ctx with sourceLCtx := srcDecl.lctx }) do
let lctx' ← translateLCtx
let localInstances' ← srcDecl.localInstances.mapM translateLocalInstance
Meta.withLCtx lctx' localInstances' do
let target' ← translateExpr srcDecl.type
Meta.mkFreshExprMVar target' srcDecl.kind srcDecl.userName
addTranslatedMVar srcMVarId mvar.mvarId!
return mvar.mvarId!
end
def translateMVarFromTermInfo (termInfo : Elab.TermInfo) (context? : Option Elab.ContextInfo)
: MetaTranslateM MVarId := do
withTheReader Context (λ ctx => { ctx with
sourceMCtx := context?.map (·.mctx) |>.getD {},
sourceLCtx := termInfo.lctx,
}) do
let type := termInfo.expectedType?.get!
let lctx' ← translateLCtx
let mvar ← Meta.withLCtx lctx' #[] do
let type' ← translateExpr type
Meta.mkFreshExprSyntheticOpaqueMVar type'
return mvar.mvarId!
def translateMVarFromTacticInfoBefore (tacticInfo : Elab.TacticInfo) (_context? : Option Elab.ContextInfo)
: MetaTranslateM (List MVarId) := do
withTheReader Context (λ ctx => { ctx with sourceMCtx := tacticInfo.mctxBefore }) do
tacticInfo.goalsBefore.mapM translateMVarId
end MetaTranslate
export MetaTranslate (MetaTranslateM)
end Pantograph.Frontend

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@ -3,9 +3,7 @@ Functions for handling metavariables
All the functions starting with `try` resume their inner monadic state.
-/
import Pantograph.Protocol
import Pantograph.Tactic
import Pantograph.Compile.Parse
import Lean
@ -48,6 +46,15 @@ protected def GoalState.create (expr: Expr): Elab.TermElabM GoalState := do
savedState,
parentMVar? := .none,
}
@[export pantograph_goal_state_create_from_mvars_m]
protected def GoalState.createFromMVars (goals: List MVarId) (root: MVarId): MetaM GoalState := do
let savedStateMonad: Elab.Tactic.TacticM Elab.Tactic.SavedState := MonadBacktrack.saveState
let savedState ← savedStateMonad { elaborator := .anonymous } |>.run' { goals } |>.run' {}
return {
root,
savedState,
parentMVar? := .none,
}
@[export pantograph_goal_state_is_conv]
protected def GoalState.isConv (state: GoalState): Bool :=
state.convMVar?.isSome
@ -145,6 +152,8 @@ protected def GoalState.continue (target: GoalState) (branch: GoalState): Except
@[export pantograph_goal_state_root_expr]
protected def GoalState.rootExpr? (goalState: GoalState): Option Expr := do
if goalState.root.name == .anonymous then
.none
let expr ← goalState.mctx.eAssignment.find? goalState.root
let (expr, _) := instantiateMVarsCore (mctx := goalState.mctx) (e := expr)
if expr.hasExprMVar then
@ -385,20 +394,4 @@ protected def GoalState.tryCalc (state: GoalState) (goal: MVarId) (pred: String)
catch exception =>
return .failure #[← exception.toMessageData.toString]
protected def GoalState.tryMotivatedApply (state: GoalState) (goal: MVarId) (recursor: String):
Elab.TermElabM TacticResult := do
state.restoreElabM
let recursor ← match (← Compile.parseTermM recursor) with
| .ok syn => pure syn
| .error error => return .parseError error
state.tryTacticM goal (tacticM := Tactic.evalMotivatedApply recursor)
protected def GoalState.tryNoConfuse (state: GoalState) (goal: MVarId) (eq: String):
Elab.TermElabM TacticResult := do
state.restoreElabM
let eq ← match (← Compile.parseTermM eq) with
| .ok syn => pure syn
| .error error => return .parseError error
state.tryTacticM goal (tacticM := Tactic.evalNoConfuse eq)
end Pantograph

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@ -159,7 +159,7 @@ def goalAssign (state: GoalState) (goal: MVarId) (expr: String): CoreM TacticRes
runTermElabM <| state.tryAssign goal expr
@[export pantograph_goal_have_m]
protected def GoalState.tryHave (state: GoalState) (goal: MVarId) (binderName: String) (type: String): CoreM TacticResult := do
let type ← match (← Compile.parseTermM type) with
let type ← match (← parseTermM type) with
| .ok syn => pure syn
| .error error => return .parseError error
runTermElabM do
@ -167,12 +167,28 @@ protected def GoalState.tryHave (state: GoalState) (goal: MVarId) (binderName: S
state.tryTacticM goal $ Tactic.evalHave binderName.toName type
@[export pantograph_goal_try_define_m]
protected def GoalState.tryDefine (state: GoalState) (goal: MVarId) (binderName: String) (expr: String): CoreM TacticResult := do
let expr ← match (← Compile.parseTermM expr) with
let expr ← match (← parseTermM expr) with
| .ok syn => pure syn
| .error error => return .parseError error
runTermElabM do
state.restoreElabM
state.tryTacticM goal (Tactic.evalDefine binderName.toName expr)
@[export pantograph_goal_try_motivated_apply_m]
protected def GoalState.tryMotivatedApply (state: GoalState) (goal: MVarId) (recursor: String):
Elab.TermElabM TacticResult := do
state.restoreElabM
let recursor ← match (← parseTermM recursor) with
| .ok syn => pure syn
| .error error => return .parseError error
state.tryTacticM goal (tacticM := Tactic.evalMotivatedApply recursor)
@[export pantograph_goal_try_no_confuse_m]
protected def GoalState.tryNoConfuse (state: GoalState) (goal: MVarId) (eq: String):
Elab.TermElabM TacticResult := do
state.restoreElabM
let eq ← match (← parseTermM eq) with
| .ok syn => pure syn
| .error error => return .parseError error
state.tryTacticM goal (tacticM := Tactic.evalNoConfuse eq)
@[export pantograph_goal_let_m]
def goalLet (state: GoalState) (goal: MVarId) (binderName: String) (type: String): CoreM TacticResult :=
runTermElabM <| state.tryLet goal binderName type

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@ -284,21 +284,25 @@ structure GoalDiag where
/-- Executes the Lean compiler on a single file -/
structure CompileUnit where
module: String
-- If set to true, query the string boundaries of compilation units
compilationUnits: Bool := false
structure FrontendProcess where
-- One of these two must be supplied: Either supply the file name or the content.
fileName?: Option String := .none
file?: Option String := .none
-- If set to true, collect tactic invocations
invocations: Bool := false
-- If set to true, collect `sorry`s
sorrys: Bool := false
deriving Lean.FromJson
structure InvokedTactic where
goalBefore: String
goalAfter: String
tactic: String
deriving Lean.ToJson
structure CompileUnitResult where
units?: Option $ List (Nat × Nat)
invocations?: Option $ List InvokedTactic
structure FrontendProcessResult where
-- String boundaries of compilation units
units: List (Nat × Nat)
invocations?: Option (List InvokedTactic) := .none
goalStates?: Option (List (Nat × Array Goal)) := .none
deriving Lean.ToJson
abbrev CR α := Except InteractionError α

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@ -26,6 +26,13 @@ def parseTerm (env: Environment) (s: String): Except String Syntax :=
(input := s)
(fileName := "<stdin>")
def parseTermM [Monad m] [MonadEnv m] (s: String): m (Except String Syntax) := do
return Parser.runParserCategory
(env := ← MonadEnv.getEnv)
(catName := `term)
(input := s)
(fileName := "<stdin>")
/-- Parse a syntax object. May generate additional metavariables! -/
def elabType (syn: Syntax): Elab.TermElabM (Except String Expr) := do
try

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@ -1,6 +1,6 @@
namespace Pantograph
@[export pantograph_version]
def version := "0.2.18"
def version := "0.2.19"
end Pantograph

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@ -9,30 +9,17 @@ examine the symbol list of a Lean project for machine learning.
## Installation
For Nix based workflow, see below.
For Nix users, run
``` sh
nix build .#{sharedLib,executable}
```
to build either the shared library or executable.
Install `elan` and `lake`, and run
``` sh
lake build
```
This builds the executable in `.lake/build/bin/pantograph`.
To use Pantograph in a project environment, setup the `LEAN_PATH` environment
variable so it contains the library path of lean libraries. The libraries must
be built in advance. For example, if `mathlib4` is stored at `../lib/mathlib4`,
the environment might be setup like this:
``` sh
LIB="../lib"
LIB_MATHLIB="$LIB/mathlib4/lake-packages"
export LEAN_PATH="$LIB/mathlib4/build/lib:$LIB_MATHLIB/aesop/build/lib:$LIB_MATHLIB/Qq/build/lib:$LIB_MATHLIB/std/build/lib"
LEAN_PATH=$LEAN_PATH build/bin/pantograph $@
```
The `$LEAN_PATH` executable of any project can be extracted by
``` sh
lake env printenv LEAN_PATH
```
This builds the executable in `.lake/build/bin/pantograph-repl`.
## Executable Usage
@ -114,6 +101,10 @@ See `Pantograph/Protocol.lean` for a description of the parameters and return va
- `{ "goals": <names> }`: Resume the given goals
* `goal.remove {"stateIds": [<id>]}"`: Drop the goal states specified in the list
* `goal.print {"stateId": <id>}"`: Print a goal state
* `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`)
### Errors
@ -130,6 +121,25 @@ Common error forms:
input of another is broken. For example, attempting to query a symbol not
existing in the library or indexing into a non-existent proof state.
### Project Environment
To use Pantograph in a project environment, setup the `LEAN_PATH` environment
variable so it contains the library path of lean libraries. The libraries must
be built in advance. For example, if `mathlib4` is stored at `../lib/mathlib4`,
the environment might be setup like this:
``` sh
LIB="../lib"
LIB_MATHLIB="$LIB/mathlib4/lake-packages"
export LEAN_PATH="$LIB/mathlib4/build/lib:$LIB_MATHLIB/aesop/build/lib:$LIB_MATHLIB/Qq/build/lib:$LIB_MATHLIB/std/build/lib"
LEAN_PATH=$LEAN_PATH build/bin/pantograph $@
```
The `$LEAN_PATH` executable of any project can be extracted by
``` sh
lake env printenv LEAN_PATH
```
### Troubleshooting
If lean encounters stack overflow problems when printing catalog, execute this before running lean:
@ -143,8 +153,11 @@ ulimit -s unlimited
with `Pantograph` which mirrors the REPL commands above. It is recommended to
call Pantograph via this FFI since it provides a tremendous speed up.
Note that there isn't a 1-1 correspondence between executable (REPL) commands
and library functions.
The executable can be used as-is, but linking against the shared library
requires the presence of `lean-all`. Note that there isn't a 1-1 correspondence
between executable (REPL) commands and library functions.
Inject any project path via the `pantograph_init_search` function.
## Developing
@ -152,7 +165,11 @@ A Lean development shell is provided in the Nix flake.
### Testing
The tests are based on `LSpec`. To run tests,
The tests are based on `LSpec`. To run tests, use either
``` sh
nix flake check
```
or
``` sh
lake test
```
@ -161,14 +178,3 @@ You can run an individual test by specifying a prefix
``` sh
lake test -- "Tactic/No Confuse"
```
## Nix based workflow
The included Nix flake provides build targets for `sharedLib` and `executable`.
The executable can be used as-is, but linking against the shared library
requires the presence of `lean-all`.
To run tests:
``` sh
nix flake check
```

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@ -1,7 +1,7 @@
import Lean.Data.HashMap
import Pantograph
namespace Pantograph
namespace Pantograph.Repl
structure Context where
imports: List String
@ -46,7 +46,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
| "goal.continue" => run goal_continue
| "goal.delete" => run goal_delete
| "goal.print" => run goal_print
| "compile.unit" => run compile_unit
| "frontend.process" => run frontend_process
| cmd =>
let error: Protocol.InteractionError :=
errorCommand s!"Unknown command {cmd}"
@ -54,6 +54,14 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
where
errorCommand := errorI "command"
errorIndex := errorI "index"
newGoalState (goalState: GoalState) : MainM Nat := do
let state ← get
let stateId := state.nextId
set { state with
goalStates := state.goalStates.insert stateId goalState,
nextId := state.nextId + 1
}
return stateId
-- Command Functions
reset (_: Protocol.Reset): MainM (CR Protocol.StatResult) := do
let state ← get
@ -95,7 +103,6 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
options_print (_: Protocol.OptionsPrint): MainM (CR Protocol.Options) := do
return .ok (← get).options
goal_start (args: Protocol.GoalStart): MainM (CR Protocol.GoalStartResult) := do
let state ← get
let env ← Lean.MonadEnv.getEnv
let expr?: Except _ GoalState ← runTermElabInMainM (match args.expr, args.copyFrom with
| .some expr, .none => goalStartExpr expr (args.levels.getD #[])
@ -108,11 +115,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
match expr? with
| .error error => return .error error
| .ok goalState =>
let stateId := state.nextId
set { state with
goalStates := state.goalStates.insert stateId goalState,
nextId := state.nextId + 1
}
let stateId ← newGoalState goalState
return .ok { stateId, root := goalState.root.name.toString }
goal_tactic (args: Protocol.GoalTactic): MainM (CR Protocol.GoalTacticResult) := do
let state ← get
@ -151,11 +154,7 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
let .ok result := nextGoalState.resume (nextGoalState.goals ++ dormantGoals) | throwError "Resuming known goals"
pure result
| false, _ => pure nextGoalState
let nextStateId := state.nextId
set { state with
goalStates := state.goalStates.insert state.nextId nextGoalState,
nextId := state.nextId + 1,
}
let nextStateId ← newGoalState nextGoalState
let goals ← nextGoalState.serializeGoals (parent := .some goalState) (options := state.options) |>.run'
return .ok {
nextStateId? := .some nextStateId,
@ -201,20 +200,52 @@ def execute (command: Protocol.Command): MainM Lean.Json := do
let .some goalState := state.goalStates.find? args.stateId | return .error $ errorIndex s!"Invalid state index {args.stateId}"
let result ← runMetaInMainM <| goalPrint goalState state.options
return .ok result
compile_unit (args: Protocol.CompileUnit): MainM (CR Protocol.CompileUnitResult) := do
let module := args.module.toName
frontend_process (args: Protocol.FrontendProcess): MainM (CR Protocol.FrontendProcessResult) := do
let options := (← get).options
try
let steps ← Compile.processSource module
let units? := if args.compilationUnits then
.some $ steps.map λ step => (step.src.startPos.byteIdx, step.src.stopPos.byteIdx)
let (fileName, file) ← match args.fileName?, args.file? with
| .some fileName, .none => do
let file ← IO.FS.readFile fileName
pure (fileName, file)
| .none, .some file =>
pure ("<anonymous>", file)
| _, _ => return .error <| errorI "arguments" "Exactly one of {fileName, file} must be supplied"
let env?: Option Lean.Environment ← if args.fileName?.isSome then
pure .none
else do
let env ← Lean.MonadEnv.getEnv
pure <| .some env
let (context, state) ← do Frontend.createContextStateFromFile file fileName env? {}
let m := Frontend.mapCompilationSteps λ step => do
let unitBoundary := (step.src.startPos.byteIdx, step.src.stopPos.byteIdx)
let tacticInvocations ← if args.invocations then
Frontend.collectTacticsFromCompilationStep step
else
pure []
let sorrys := if args.sorrys then
Frontend.collectSorrys step
else
[]
return (unitBoundary, tacticInvocations, sorrys)
let li ← m.run context |>.run' state
let units := li.map λ (unit, _, _) => unit
let invocations? := if args.invocations then
.some $ li.bind λ (_, invocations, _) => invocations
else
.none
let invocations? ← if args.invocations then
pure $ .some (← Compile.collectTacticsFromCompilation steps)
let goalStates? ← if args.sorrys then do
let stateIds ← li.filterMapM λ (_, _, sorrys) => do
if sorrys.isEmpty then
return .none
let goalState ← runMetaInMainM $ Frontend.sorrysToGoalState sorrys
let stateId ← newGoalState goalState
let goals ← goalSerialize goalState options
return .some (stateId, goals)
pure $ .some stateIds
else
pure .none
return .ok { units?, invocations? }
return .ok { units, invocations?, goalStates? }
catch e =>
return .error $ errorI "compile" (← e.toMessageData.toString)
return .error $ errorI "frontend" (← e.toMessageData.toString)
end Pantograph
end Pantograph.Repl

172
Test/Frontend.lean Normal file
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@ -0,0 +1,172 @@
import LSpec
import Pantograph
import Repl
import Test.Common
open Lean Pantograph
namespace Pantograph.Test.Frontend
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 Frontend.collectSorrys step
let li ← m.run context |>.run' state
let goalStates ← li.filterMapM λ sorrys => do
if sorrys.isEmpty then
return .none
let goalState ← Frontend.sorrysToGoalState sorrys
return .some goalState
return goalStates
def test_multiple_sorrys_in_proof : TestT MetaM Unit := do
let sketch := "
theorem plus_n_Sm_proved_formal_sketch : ∀ n m : Nat, n + (m + 1) = (n + m) + 1 := by
have h_nat_add_succ: ∀ n m : Nat, n = m := sorry
sorry
"
let goalStates ← (collectSorrysFromSource sketch).run' {}
let [goalState] := goalStates | panic! "Incorrect number of states"
addTest $ LSpec.check "goals" ((← goalState.serializeGoals (options := {})).map (·.devolatilize) = #[
{
target := { pp? := "∀ (n m : Nat), n = m" },
vars := #[
]
},
{
target := { pp? := "∀ (n m : Nat), n + (m + 1) = n + m + 1" },
vars := #[{
userName := "h_nat_add_succ",
type? := .some { pp? := "∀ (n m : Nat), n = m" },
}],
}
])
def test_sorry_in_middle: TestT MetaM Unit := do
let sketch := "
example : ∀ (n m: Nat), n + m = m + n := by
intros n m
sorry
"
let goalStates ← (collectSorrysFromSource sketch).run' {}
let [goalState] := goalStates | panic! s!"Incorrect number of states: {goalStates.length}"
addTest $ LSpec.check "goals" ((← goalState.serializeGoals (options := {})).map (·.devolatilize) = #[
{
target := { pp? := "n + m = m + n" },
vars := #[{
userName := "n",
type? := .some { pp? := "Nat" },
}, {
userName := "m",
type? := .some { pp? := "Nat" },
}
],
}
])
def test_sorry_in_induction : TestT MetaM Unit := do
let sketch := "
example : ∀ (n m: Nat), n + m = m + n := by
intros n m
induction n with
| zero =>
have h1 : 0 + m = m := sorry
sorry
| succ n ih =>
have h2 : n + m = m := sorry
sorry
"
let goalStates ← (collectSorrysFromSource sketch).run' {}
let [goalState] := goalStates | panic! s!"Incorrect number of states: {goalStates.length}"
addTest $ LSpec.check "goals" ((← goalState.serializeGoals (options := {})).map (·.devolatilize) = #[
{
target := { pp? := "0 + m = m" },
vars := #[{
userName := "m",
type? := .some { pp? := "Nat" },
}]
},
{
userName? := .some "zero",
target := { pp? := "0 + m = m + 0" },
vars := #[{
userName := "m",
type? := .some { pp? := "Nat" },
}, {
userName := "h1",
type? := .some { pp? := "0 + m = m" },
}]
},
{
target := { pp? := "n + m = m" },
vars := #[{
userName := "m",
type? := .some { pp? := "Nat" },
}, {
userName := "n",
type? := .some { pp? := "Nat" },
}, {
userName := "ih",
type? := .some { pp? := "n + m = m + n" },
}]
},
{
userName? := .some "succ",
target := { pp? := "n + 1 + m = m + (n + 1)" },
vars := #[{
userName := "m",
type? := .some { pp? := "Nat" },
}, {
userName := "n",
type? := .some { pp? := "Nat" },
}, {
userName := "ih",
type? := .some { pp? := "n + m = m + n" },
}, {
userName := "h2",
type? := .some { pp? := "n + m = m" },
}]
}
])
def test_sorry_in_coupled: TestT MetaM Unit := do
let sketch := "
example : ∀ (y: Nat), ∃ (x: Nat), y + 1 = x := by
intro y
apply Exists.intro
case h => sorry
case w => sorry
"
let goalStates ← (collectSorrysFromSource sketch).run' {}
let [goalState] := goalStates | panic! s!"Incorrect number of states: {goalStates.length}"
addTest $ LSpec.check "goals" ((← goalState.serializeGoals (options := {})).map (·.devolatilize) = #[
{
target := { pp? := "y + 1 = ?w" },
vars := #[{
userName := "y",
type? := .some { pp? := "Nat" },
}
],
},
{
userName? := .some "w",
target := { pp? := "Nat" },
vars := #[{
userName := "y",
type? := .some { pp? := "Nat" },
}
],
}
])
def suite (env : Environment): List (String × IO LSpec.TestSeq) :=
let tests := [
("multiple_sorrys_in_proof", test_multiple_sorrys_in_proof),
("sorry_in_middle", test_sorry_in_middle),
("sorry_in_induction", test_sorry_in_induction),
("sorry_in_coupled", test_sorry_in_coupled),
]
tests.map (fun (name, test) => (name, runMetaMSeq env $ runTest test))
end Pantograph.Test.Frontend

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@ -6,13 +6,13 @@ import Repl
import Test.Common
namespace Pantograph.Test.Integration
open Pantograph
open Pantograph.Repl
def step { α } [Lean.ToJson α] (cmd: String) (payload: List (String × Lean.Json))
(expected: α) (name? : Option String := .none): MainM LSpec.TestSeq := do
let payload := Lean.Json.mkObj payload
let name := name?.getD s!"{cmd} {payload.compress}"
let result ← execute { cmd, payload }
let result ← Repl.execute { cmd, payload }
return LSpec.test name (toString result = toString (Lean.toJson expected))
abbrev Test := List (MainM LSpec.TestSeq)
@ -161,6 +161,68 @@ def test_env_add_inspect : Test :=
Protocol.EnvInspectResult)
]
example : ∀ (p: Prop), p → p := by
intro p h
exact h
def test_frontend_process : Test :=
[
let file := "example : ∀ (p: Prop), p → p := by\n intro p h\n exact h"
let goal1 := "p : Prop\nh : p\n⊢ p"
step "frontend.process"
[
("file", .str file),
("invocations", .bool true),
("sorrys", .bool false),
]
({
units := [(0, file.utf8ByteSize)],
invocations? := .some [
{
goalBefore := "⊢ ∀ (p : Prop), p → p",
goalAfter := goal1,
tactic := "intro p h",
},
{
goalBefore := goal1 ,
goalAfter := "",
tactic := "exact h",
},
]
}: Protocol.FrontendProcessResult),
]
example : 1 + 2 = 3 := rfl
example (p: Prop): p → p := by simp
def test_frontend_process_sorry : Test :=
let solved := "example : 1 + 2 = 3 := rfl\n"
let withSorry := "example (p: Prop): p → p := sorry"
[
let file := s!"{solved}{withSorry}"
let goal1: Protocol.Goal := {
name := "_uniq.6",
target := { pp? := .some "p → p" },
vars := #[{ name := "_uniq.4", userName := "p", type? := .some { pp? := .some "Prop" }}],
}
step "frontend.process"
[
("file", .str file),
("invocations", .bool false),
("sorrys", .bool true),
]
({
units := [
(0, solved.utf8ByteSize),
(solved.utf8ByteSize, solved.utf8ByteSize + withSorry.utf8ByteSize),
],
goalStates? := [
(0, #[goal1]),
]
}: Protocol.FrontendProcessResult),
]
def runTest (env: Lean.Environment) (steps: Test): IO LSpec.TestSeq := do
-- Setup the environment for execution
let context: Context := {
@ -182,6 +244,8 @@ def suite (env : Lean.Environment): List (String × IO LSpec.TestSeq) :=
("Manual Mode", test_automatic_mode false),
("Automatic Mode", test_automatic_mode true),
("env.add env.inspect", test_env_add_inspect),
("frontend.process invocation", test_frontend_process),
("frontend.process sorry", test_frontend_process_sorry),
]
tests.map (fun (name, test) => (name, runTest env test))

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@ -1,5 +1,6 @@
import LSpec
import Test.Environment
import Test.Frontend
import Test.Integration
import Test.Library
import Test.Metavar
@ -44,6 +45,7 @@ def main (args: List String) := do
let suites: List (String × List (String × IO LSpec.TestSeq)) := [
("Environment", Environment.suite),
("Frontend", Frontend.suite env_default),
("Integration", Integration.suite env_default),
("Library", Library.suite env_default),
("Metavar", Metavar.suite env_default),