refactor: Code cleanup

2024-05-28 20:24:23 -07:00 · 2024-05-28 20:24:23 -07:00 · b9b16ba0e9
parent 09628309a9
commit b9b16ba0e9
3 changed files with 242 additions and 226 deletions
--- a/Pantograph/Compile.lean
+++ b/Pantograph/Compile.lean
@ -1,241 +1,18 @@
 /- Adapted from lean-training-data by semorrison -/
 import Lean.Parser
 import Lean.Elab.Import
 import Lean.Elab.Command
 import Lean.Elab.Frontend
 import Lean.Elab.InfoTree
 import Lean.Util.Path
 import Pantograph.Protocol
 import Pantograph.Compile.Frontend
 import Pantograph.Compile.Elab
 open Lean
 namespace Lean.PersistentArray
 /--
 Drop the first `n` elements of a `PersistentArray`, returning the results as a `List`.
 -/
 -- We can't remove the `[Inhabited α]` hypotheses here until
 -- `PersistentArray`'s `GetElem` instance also does.
 def drop [Inhabited α] (t : PersistentArray α) (n : Nat) : List α :=
  List.range (t.size - n) |>.map fun i => t.get! (n + i)
 end Lean.PersistentArray
 namespace Lean.Elab.Info
 /-- The `Syntax` for a `Lean.Elab.Info`, if there is one. -/
 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? -/
 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 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`.
 def stxRange (fileMap : FileMap) (stx : Syntax) : Position × Position :=
  let pos    := stx.getPos?.getD 0
  let endPos := stx.getTailPos?.getD pos
  (fileMap.toPosition pos, fileMap.toPosition endPos)
 end Lean.FileMap
 -- Main
 namespace Pantograph.Compile
 structure CompilationStep where
  fileName : String
  fileMap : FileMap
  src : Substring
  stx : Syntax
  before : Environment
  after : Environment
  msgs : List Message
  trees : List Elab.InfoTree
 /--
 Process one command, returning a `CompilationStep` and
 `done : Bool`, indicating whether this was the last command.
 -/
 def processOneCommand: Elab.Frontend.FrontendM (CompilationStep × Bool) := do
  let s := (← get).commandState
  let before := s.env
  let done ← Elab.Frontend.processCommand
  let stx := (← get).commands.back
  let src := (← read).inputCtx.input.toSubstring.extract (← get).cmdPos (← get).parserState.pos
  let s' := (← get).commandState
  let after := s'.env
  let msgs := s'.messages.msgs.drop s.messages.msgs.size
  let trees := s'.infoState.trees.drop s.infoState.trees.size
  let ⟨_, fileName, fileMap⟩  := (← read).inputCtx
  return ({ fileName, fileMap, src, stx, before, after, msgs, trees }, done)
 partial def processFile : Elab.Frontend.FrontendM (List CompilationStep) := do
  let (cmd, done) ← processOneCommand
  if done then
    return [cmd]
  else
    return cmd :: (← processFile)
 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
  let (header, parserState, messages) ← Parser.parseHeader inputCtx
  let (env, messages) ← Elab.processHeader header opts messages inputCtx
  let commandState := Elab.Command.mkState env messages opts
  processFile.run { inputCtx }
    |>.run' {
    commandState := { commandState with infoState.enabled := true },
    parserState,
    cmdPos := parserState.pos
  }
 -- Info tree filtering functions
 structure TacticInvocation where
  info : Elab.TacticInfo
  ctx : Elab.ContextInfo
  children : PersistentArray Elab.InfoTree
 namespace TacticInvocation
 /-- Return the range of the tactic, as a pair of file positions. -/
 def range (t : TacticInvocation) : Position × Position := t.ctx.fileMap.stxRange t.info.stx
 /-- Pretty print a tactic. -/
 def pp (t : TacticInvocation) : IO Format :=
  t.ctx.runMetaM {} try
    Lean.PrettyPrinter.ppTactic ⟨t.info.stx⟩
  catch _ =>
    pure "<failed to pretty print>"
 open Meta
 /-- Run a tactic on the goals stored in a `TacticInvocation`. -/
 def runMetaMGoalsBefore (t : TacticInvocation) (x : List MVarId → MetaM α) : IO α := do
  t.ctx.runMetaM {} <| Meta.withMCtx t.info.mctxBefore <| x t.info.goalsBefore
 /-- Run a tactic on the after goals stored in a `TacticInvocation`. -/
 def runMetaMGoalsAfter (t : TacticInvocation) (x : List MVarId → MetaM α) : IO α := do
  t.ctx.runMetaM {} <| Meta.withMCtx t.info.mctxAfter <| x t.info.goalsAfter
 /-- Run a tactic on the main goal stored in a `TacticInvocation`. -/
 def runMetaM (t : TacticInvocation) (x : MVarId → MetaM α) : IO α := do
  match t.info.goalsBefore.head? with
  | none => throw <| IO.userError s!"No goals at {← t.pp}"
  | some g => t.runMetaMGoalsBefore fun _ => do g.withContext <| x g
 def mainGoal (t : TacticInvocation) : IO Expr :=
  t.runMetaM (fun g => do instantiateMVars (← g.getType))
 def formatMainGoal (t : TacticInvocation) : IO Format :=
  t.runMetaM (fun g => do ppExpr (← instantiateMVars (← g.getType)))
 def goalState (t : TacticInvocation) : IO (List Format) := do
  t.runMetaMGoalsBefore (fun gs => gs.mapM fun g => do Meta.ppGoal g)
 def goalStateAfter (t : TacticInvocation) : IO (List Format) := do
  t.runMetaMGoalsAfter (fun gs => gs.mapM fun g => do Meta.ppGoal g)
 def ppExpr (t : TacticInvocation) (e : Expr) : IO Format :=
  t.runMetaM (fun _ => do Meta.ppExpr (← instantiateMVars e))
 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) :
    List (Elab.Info × Option Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
  match t with
  | .context inner t => findAllInfo t (inner.mergeIntoOuter? ctx) pred
  | .node i children  =>
      (if pred i then [(i, ctx, children)] else []) ++ children.toList.bind (fun t => findAllInfo t ctx 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 (Elab.TacticInfo × Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
  let infos := findAllInfo t none fun i => match i with
    | .ofTacticInfo _ => true
    | _ => false
  infos.filterMap fun p => match p with
    | (.ofTacticInfo i, some ctx, children) => (i, ctx, children)
    | _ => none
 def collectTactics (t : Elab.InfoTree) : List TacticInvocation :=
  collectTacticNodes t |>.map (fun ⟨i, ctx, children⟩ => ⟨i, ctx, children⟩)
    |>.filter fun i => i.info.isSubstantive
 def compileAndCollectTacticInvocations (module : Name) : IO Protocol.CompileTacticsResult := do
  let steps ← processSource module
  let infoTrees := steps.bind (·.trees)
  let tacticInfoTrees := infoTrees.bind λ tree => tree.filter λ
-    | info@(.ofTacticInfo _) => true --info.isOriginal
+    | info@(.ofTacticInfo _) => info.isOriginal
    | _ => false
  let tactics := tacticInfoTrees.bind collectTactics
  IO.println s!"{steps.length} compilation steps, {infoTrees.length} trees found, {tacticInfoTrees.length} tactic trees, {tactics.length} tactics found"
--- a/Pantograph/Compile/Elab.lean
+++ b/Pantograph/Compile/Elab.lean
@ -0,0 +1,153 @@
 import Lean.Elab.Import
 import Lean.Elab.Command
 import Lean.Elab.InfoTree
 import Pantograph.Compile.Frontend
 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.Compile
 -- Info tree filtering functions
 structure TacticInvocation where
  info : Elab.TacticInfo
  ctx : Elab.ContextInfo
  children : PersistentArray Elab.InfoTree
 namespace TacticInvocation
 /-- Return the range of the tactic, as a pair of file positions. -/
 protected def range (t : TacticInvocation) : Position × Position := t.ctx.fileMap.stxRange t.info.stx
 /-- Pretty print a tactic. -/
 protected def pp (t : TacticInvocation) : IO Format :=
  t.ctx.runMetaM {} try
    Lean.PrettyPrinter.ppTactic ⟨t.info.stx⟩
  catch _ =>
    pure "<failed to pretty print>"
 /-- Run a tactic on the goals stored in a `TacticInvocation`. -/
 protected def runMetaMGoalsBefore (t : TacticInvocation) (x : List MVarId → MetaM α) : IO α := do
  t.ctx.runMetaM {} <| Meta.withMCtx t.info.mctxBefore <| x t.info.goalsBefore
 /-- Run a tactic on the after goals stored in a `TacticInvocation`. -/
 protected def runMetaMGoalsAfter (t : TacticInvocation) (x : List MVarId → MetaM α) : IO α := do
  t.ctx.runMetaM {} <| Meta.withMCtx t.info.mctxAfter <| x t.info.goalsAfter
 /-- Run a tactic on the main goal stored in a `TacticInvocation`. -/
 protected def runMetaM (t : TacticInvocation) (x : MVarId → MetaM α) : IO α := do
  match t.info.goalsBefore.head? with
  | none => throw <| IO.userError s!"No goals at {← t.pp}"
  | some g => t.runMetaMGoalsBefore fun _ => do g.withContext <| x g
 protected def mainGoal (t : TacticInvocation) : IO Expr :=
  t.runMetaM (fun g => do instantiateMVars (← g.getType))
 protected def formatMainGoal (t : TacticInvocation) : IO Format :=
  t.runMetaM (fun g => do Meta.ppExpr (← instantiateMVars (← g.getType)))
 protected def goalState (t : TacticInvocation) : IO (List Format) := do
  t.runMetaMGoalsBefore (fun gs => gs.mapM fun g => do Meta.ppGoal g)
 protected def goalStateAfter (t : TacticInvocation) : IO (List Format) := do
  t.runMetaMGoalsAfter (fun gs => gs.mapM fun g => do Meta.ppGoal g)
 protected def ppExpr (t : TacticInvocation) (e : Expr) : IO Format :=
  t.runMetaM (fun _ => do Meta.ppExpr (← instantiateMVars e))
 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) :
    List (Elab.Info × Option Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
  match t with
  | .context inner t => findAllInfo t (inner.mergeIntoOuter? ctx) pred
  | .node i children  =>
      (if pred i then [(i, ctx, children)] else []) ++ children.toList.bind (fun t => findAllInfo t ctx 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 (Elab.TacticInfo × Elab.ContextInfo × PersistentArray Elab.InfoTree) :=
  let infos := findAllInfo t none fun i => match i with
    | .ofTacticInfo _ => true
    | _ => false
  infos.filterMap fun p => match p with
    | (.ofTacticInfo i, some ctx, children) => (i, ctx, children)
    | _ => none
 def collectTactics (t : Elab.InfoTree) : List TacticInvocation :=
  collectTacticNodes t |>.map (fun ⟨i, ctx, children⟩ => ⟨i, ctx, children⟩)
    |>.filter fun i => i.info.isSubstantive
 end Pantograph.Compile
--- a/Pantograph/Compile/Frontend.lean
+++ b/Pantograph/Compile/Frontend.lean
@ -0,0 +1,86 @@
 import Lean.Parser
 import Lean.Elab.Frontend
 open Lean
 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`.
 protected def stxRange (fileMap : FileMap) (stx : Syntax) : Position × Position :=
  let pos    := stx.getPos?.getD 0
  let endPos := stx.getTailPos?.getD pos
  (fileMap.toPosition pos, fileMap.toPosition endPos)
 end Lean.FileMap
 namespace Lean.PersistentArray
 /--
 Drop the first `n` elements of a `PersistentArray`, returning the results as a `List`.
 -/
 -- We can't remove the `[Inhabited α]` hypotheses here until
 -- `PersistentArray`'s `GetElem` instance also does.
 protected def drop [Inhabited α] (t : PersistentArray α) (n : Nat) : List α :=
  List.range (t.size - n) |>.map fun i => t.get! (n + i)
 end Lean.PersistentArray
 namespace Pantograph.Compile
 structure CompilationStep where
  fileName : String
  fileMap : FileMap
  src : Substring
  stx : Syntax
  before : Environment
  after : Environment
  msgs : List Message
  trees : List Elab.InfoTree
 /--
 Process one command, returning a `CompilationStep` and
 `done : Bool`, indicating whether this was the last command.
 -/
 def processOneCommand: Elab.Frontend.FrontendM (CompilationStep × Bool) := do
  let s := (← get).commandState
  let before := s.env
  let done ← Elab.Frontend.processCommand
  let stx := (← get).commands.back
  let src := (← read).inputCtx.input.toSubstring.extract (← get).cmdPos (← get).parserState.pos
  let s' := (← get).commandState
  let after := s'.env
  let msgs := s'.messages.msgs.drop s.messages.msgs.size
  let trees := s'.infoState.trees.drop s.infoState.trees.size
  let ⟨_, fileName, fileMap⟩  := (← read).inputCtx
  return ({ fileName, fileMap, src, stx, before, after, msgs, trees }, done)
 partial def processFile : Elab.Frontend.FrontendM (List CompilationStep) := do
  let (cmd, done) ← processOneCommand
  if done then
    return [cmd]
  else
    return cmd :: (← processFile)
 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
  let (header, parserState, messages) ← Parser.parseHeader inputCtx
  let (env, messages) ← Elab.processHeader header opts messages inputCtx
  let commandState := Elab.Command.mkState env messages opts
  processFile.run { inputCtx }
    |>.run' {
    commandState := { commandState with infoState.enabled := true },
    parserState,
    cmdPos := parserState.pos
  }
 end Pantograph.Compile