/- Copyright (c) 2020 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Authors: Leonardo de Moura -/ module prelude public import Lean.Elab.Term public import Lean.Elab.BindersUtil public import Lean.Elab.PatternVar public import Lean.Elab.Quotation.Util meta import Lean.Parser.Do public section -- HACK: avoid code explosion until heuristics are improved set_option compiler.reuse false namespace Lean.Elab.Term open Lean.Parser.Term open Meta open TSyntax.Compat private def getDoSeqElems (doSeq : Syntax) : List Syntax := if doSeq.getKind == ``Parser.Term.doSeqBracketed then doSeq[1].getArgs.toList.map fun arg => arg[0] else if doSeq.getKind == ``Parser.Term.doSeqIndent then doSeq[0].getArgs.toList.map fun arg => arg[0] else [] private def getDoSeq (doStx : Syntax) : Syntax := doStx[1] @[builtin_term_elab liftMethod] def elabLiftMethod : TermElab := fun stx _ => throwErrorAt stx "invalid use of `(<- ...)`, must be nested inside a 'do' expression" /-- Return true if we should not lift `(<- ...)` actions nested in the syntax nodes with the given kind. -/ private def liftMethodDelimiter (k : SyntaxNodeKind) : Bool := k == ``Parser.Term.do || k == ``Parser.Term.doSeqIndent || k == ``Parser.Term.doSeqBracketed || k == ``Parser.Term.termReturn || k == ``Parser.Term.termUnless || k == ``Parser.Term.termTry || k == ``Parser.Term.termFor /-- Given `stx` which is a `letPatDecl`, `letEqnsDecl`, or `letIdDecl`, return true if it has binders. -/ private def letDeclArgHasBinders (letDeclArg : Syntax) : Bool := let k := letDeclArg.getKind if k == ``Parser.Term.letPatDecl then false else if k == ``Parser.Term.letEqnsDecl then true else if k == ``Parser.Term.letIdDecl then -- letIdLhs := binderIdent >> checkWsBefore "expected space before binders" >> many (ppSpace >> letIdBinder)) >> optType let binders := letDeclArg[1] binders.getNumArgs > 0 else false /-- Return `true` if the given `letDecl` contains binders. -/ private def letDeclHasBinders (letDecl : Syntax) : Bool := letDeclArgHasBinders letDecl[0] /-- Return true if we should generate an error message when lifting a method over this kind of syntax. -/ private def liftMethodForbiddenBinder (stx : Syntax) : Bool := let k := stx.getKind -- TODO: make this extensible in the future. if k == ``Parser.Term.fun || k == ``Parser.Term.matchAlts || k == ``Parser.Term.doLetRec || k == ``Parser.Term.letrec then -- It is never ok to lift over this kind of binder true -- The following kinds of `let`-expressions require extra checks to decide whether they contain binders or not else if k == ``Parser.Term.let then letDeclHasBinders stx[1] else if k == ``Parser.Term.doLet then letDeclHasBinders stx[2] else if k == ``Parser.Term.doLetArrow then letDeclArgHasBinders stx[2] else false -- TODO: we must track whether we are inside a quotation or not. private partial def hasLiftMethod : Syntax → Bool | Syntax.node _ k args => if liftMethodDelimiter k then false -- NOTE: We don't check for lifts in quotations here, which doesn't break anything but merely makes this rare case a -- bit slower else if k == ``Parser.Term.liftMethod then true -- For `pure` if-then-else, we only lift `(<- ...)` occurring in the condition. else if k == ``termDepIfThenElse || k == ``termIfThenElse then args.size >= 2 && hasLiftMethod args[1]! else args.any hasLiftMethod | _ => false structure ExtractMonadResult where m : Expr returnType : Expr expectedType : Expr private def mkUnknownMonadResult : MetaM ExtractMonadResult := do let u ← mkFreshLevelMVar let v ← mkFreshLevelMVar let m ← mkFreshExprMVar (← mkArrow (mkSort (mkLevelSucc u)) (mkSort (mkLevelSucc v))) let returnType ← mkFreshExprMVar (mkSort (mkLevelSucc u)) return { m, returnType, expectedType := mkApp m returnType } private partial def extractBind (expectedType? : Option Expr) : TermElabM ExtractMonadResult := do let some expectedType := expectedType? | mkUnknownMonadResult let extractStep? (type : Expr) : MetaM (Option ExtractMonadResult) := do let .app m returnType := type | return none try let bindInstType ← mkAppM ``Bind #[m] discard <| Meta.synthInstance bindInstType return some { m, returnType, expectedType } catch _ => return none let rec extract? (type : Expr) : MetaM (Option ExtractMonadResult) := do match (← extractStep? type) with | some r => return r | none => let typeNew ← whnfCore type if typeNew != type then extract? typeNew else if typeNew.getAppFn.isMVar then mkUnknownMonadResult else match (← unfoldDefinition? typeNew) with | some typeNew => extract? typeNew | none => return none match (← extract? expectedType) with | some r => return r | none => throwError "invalid `do` notation, expected type is not a monad application{indentExpr expectedType}\nYou can use the `do` notation in pure code by writing `Id.run do` instead of `do`, where `Id` is the identity monad." namespace Do abbrev Var := Syntax -- TODO: should be `Ident` /-- A `doMatch` alternative. `vars` is the array of variables declared by `patterns`. -/ structure Alt (σ : Type) where ref : Syntax vars : Array Var patterns : Syntax rhs : σ deriving Inhabited /-- A `doMatchExpr` alternative. -/ structure AltExpr (σ : Type) where ref : Syntax var? : Option Var funName : Syntax pvars : Array Syntax rhs : σ deriving Inhabited def AltExpr.vars (alt : AltExpr σ) : Array Var := Id.run do let mut vars := #[] if let some var := alt.var? then vars := vars.push var for pvar in alt.pvars do match pvar with | `(_) => pure () | _ => vars := vars.push pvar return vars /-- Auxiliary datastructure for representing a `do` code block, and compiling "reassignments" (e.g., `x := x + 1`). We convert `Code` into a `Syntax` term representing the: - `do`-block, or - the visitor argument for the `forIn` combinator. We say the following constructors are terminals: - `break`: for interrupting a `for x in s` - `continue`: for interrupting the current iteration of a `for x in s` - `return e`: for returning `e` as the result for the whole `do` computation block - `action a`: for executing action `a` as a terminal - `ite`: if-then-else - `match`: pattern matching - `jmp` a goto to a join-point We say the terminals `break`, `continue`, `action`, and `return` are "exit points" Note that, `return e` is not equivalent to `action (pure e)`. Here is an example: ``` def f (x : Nat) : IO Unit := do if x == 0 then return () IO.println "hello" ``` Executing `#eval f 0` will not print "hello". Now, consider ``` def g (x : Nat) : IO Unit := do if x == 0 then pure () IO.println "hello" ``` The `if` statement is essentially a noop, and "hello" is printed when we execute `g 0`. - `decl` represents all declaration-like `doElem`s (e.g., `let`, `have`, `let rec`). The field `stx` is the actual `doElem`, `vars` is the array of variables declared by it, and `cont` is the next instruction in the `do` code block. `vars` is an array since we have declarations such as `let (a, b) := s`. - `reassign` is an reassignment-like `doElem` (e.g., `x := x + 1`). - `joinpoint` is a join point declaration: an auxiliary `let`-declaration used to represent the control-flow. - `seq a k` executes action `a`, ignores its result, and then executes `k`. We also store the do-elements `dbg_trace` and `assert!` as actions in a `seq`. A code block `C` is well-formed if - For every `jmp ref j as` in `C`, there is a `joinpoint j ps b k` and `jmp ref j as` is in `k`, and `ps.size == as.size` -/ inductive Code where | decl (xs : Array Var) (doElem : Syntax) (k : Code) | reassign (xs : Array Var) (doElem : Syntax) (k : Code) /-- The Boolean value in `params` indicates whether we should use `(x : typeof! x)` when generating term Syntax or not -/ | joinpoint (name : Name) (params : Array (Var × Bool)) (body : Code) (k : Code) | seq (action : Syntax) (k : Code) | action (action : Syntax) | break (ref : Syntax) | continue (ref : Syntax) | return (ref : Syntax) (val : Syntax) /-- Recall that an if-then-else may declare a variable using `optIdent` for the branches `thenBranch` and `elseBranch`. We store the variable name at `var?`. -/ | ite (ref : Syntax) (h? : Option Var) (optIdent : Syntax) (cond : Syntax) (thenBranch : Code) (elseBranch : Code) | match (ref : Syntax) (gen : Syntax) (discrs : Syntax) (optMotive : Syntax) (alts : Array (Alt Code)) | matchExpr (ref : Syntax) («meta» : Bool) (discr : Syntax) (alts : Array (AltExpr Code)) (elseBranch : Code) | jmp (ref : Syntax) (jpName : Name) (args : Array Syntax) deriving Inhabited def Code.getRef? : Code → Option Syntax | .decl _ doElem _ => doElem | .reassign _ doElem _ => doElem | .joinpoint .. => none | .seq a _ => a | .action a => a | .break ref => ref | .continue ref => ref | .return ref _ => ref | .ite ref .. => ref | .match ref .. => ref | .matchExpr ref .. => ref | .jmp ref .. => ref abbrev VarSet := Std.TreeMap Name Syntax Name.cmp /-- A code block, and the collection of variables updated by it. -/ structure CodeBlock where code : Code uvars : VarSet := {} -- set of variables updated by `code` private def varSetToArray (s : VarSet) : Array Var := s.foldl (fun xs _ x => xs.push x) #[] private def varsToMessageData (vars : Array Var) : MessageData := MessageData.joinSep (vars.toList.map fun n => MessageData.ofName (n.getId.simpMacroScopes)) " " partial def CodeBlock.toMessageData (codeBlock : CodeBlock) : MessageData := let us := MessageData.ofList <| (varSetToArray codeBlock.uvars).toList.map MessageData.ofSyntax let rec loop : Code → MessageData | .decl xs _ k => m!"let {varsToMessageData xs} := ...\n{loop k}" | .reassign xs _ k => m!"{varsToMessageData xs} := ...\n{loop k}" | .joinpoint n ps body k => m!"let {n.simpMacroScopes} {varsToMessageData (ps.map Prod.fst)} := {indentD (loop body)}\n{loop k}" | .seq e k => m!"{e}\n{loop k}" | .action e => e | .ite _ _ _ c t e => m!"if {c} then {indentD (loop t)}\nelse{loop e}" | .jmp _ j xs => m!"jmp {j.simpMacroScopes} {xs.toList}" | .break _ => m!"break {us}" | .continue _ => m!"continue {us}" | .return _ v => m!"return {v} {us}" | .match _ _ ds _ alts => m!"match {ds} with" ++ alts.foldl (init := m!"") fun acc alt => acc ++ m!"\n| {alt.patterns} => {loop alt.rhs}" | .matchExpr _ «meta» d alts elseCode => let r := m!"match_expr {if «meta» then "" else "(meta := false)"} {d} with" let r := r ++ alts.foldl (init := m!"") fun acc alt => let acc := acc ++ m!"\n| {if let some var := alt.var? then m!"{var}@" else ""}" let acc := acc ++ m!"{alt.funName}" let acc := acc ++ alt.pvars.foldl (init := m!"") fun acc pvar => acc ++ m!" {pvar}" acc ++ m!" => {loop alt.rhs}" r ++ m!"| _ => {loop elseCode}" loop codeBlock.code /-- Return true if the give code contains an exit point that satisfies `p` -/ partial def hasExitPointPred (c : Code) (p : Code → Bool) : Bool := let rec loop : Code → Bool | .decl _ _ k => loop k | .reassign _ _ k => loop k | .joinpoint _ _ b k => loop b || loop k | .seq _ k => loop k | .ite _ _ _ _ t e => loop t || loop e | .match _ _ _ _ alts => alts.any (loop ·.rhs) | .matchExpr _ _ _ alts e => alts.any (loop ·.rhs) || loop e | .jmp .. => false | c => p c loop c def hasExitPoint (c : Code) : Bool := hasExitPointPred c fun _ => true def hasReturn (c : Code) : Bool := hasExitPointPred c fun | .return .. => true | _ => false def hasTerminalAction (c : Code) : Bool := hasExitPointPred c fun | .action _ => true | _ => false def hasBreakContinue (c : Code) : Bool := hasExitPointPred c fun | .break _ => true | .continue _ => true | _ => false def hasBreakContinueReturn (c : Code) : Bool := hasExitPointPred c fun | .break _ => true | .continue _ => true | .return _ _ => true | _ => false def mkAuxDeclFor {m} [Monad m] [MonadQuotation m] (e : Syntax) (mkCont : Syntax → m Code) : m Code := withRef e <| withFreshMacroScope do let y ← `(y) let doElem ← `(doElem| let y ← $e:term) -- Add elaboration hint for producing sane error message let y ← `(ensure_expected_type% "type mismatch, result value" $y) let k ← mkCont y return .decl #[y] doElem k /-- Convert `action _ e` instructions in `c` into `let y ← e; jmp _ jp (xs y)`. -/ partial def convertTerminalActionIntoJmp (code : Code) (jp : Name) (xs : Array Var) : MacroM Code := let rec loop : Code → MacroM Code | .decl xs stx k => return .decl xs stx (← loop k) | .reassign xs stx k => return .reassign xs stx (← loop k) | .joinpoint n ps b k => return .joinpoint n ps (← loop b) (← loop k) | .seq e k => return .seq e (← loop k) | .ite ref x? h c t e => return .ite ref x? h c (← loop t) (← loop e) | .action e => mkAuxDeclFor e fun y => let ref := e -- We jump to `jp` with xs **and** y let jmpArgs := xs.push y return Code.jmp ref jp jmpArgs | .match ref g ds t alts => return .match ref g ds t (← alts.mapM fun alt => do pure { alt with rhs := (← loop alt.rhs) }) | .matchExpr ref «meta» d alts e => do let alts ← alts.mapM fun alt => do pure { alt with rhs := (← loop alt.rhs) } let e ← loop e return .matchExpr ref «meta» d alts e | c => return c loop code structure JPDecl where name : Name params : Array (Var × Bool) body : Code def attachJP (jpDecl : JPDecl) (k : Code) : Code := Code.joinpoint jpDecl.name jpDecl.params jpDecl.body k def attachJPs (jpDecls : Array JPDecl) (k : Code) : Code := jpDecls.foldr attachJP k def mkFreshJP (ps : Array (Var × Bool)) (body : Code) : TermElabM JPDecl := do let ps ← if ps.isEmpty then let y ← `(y) pure #[(y.raw, false)] else pure ps -- Remark: the compiler frontend implemented in C++ currently detects join points created by -- the "do" notation by testing the name. See hack at method `visit_let` at `lcnf.cpp` -- We will remove this hack when we re-implement the compiler frontend in Lean. let name ← mkFreshUserName `__do_jp pure { name := name, params := ps, body := body } def addFreshJP (ps : Array (Var × Bool)) (body : Code) : StateRefT (Array JPDecl) TermElabM Name := do let jp ← mkFreshJP ps body modify fun (jps : Array JPDecl) => jps.push jp pure jp.name def insertVars (rs : VarSet) (xs : Array Var) : VarSet := xs.foldl (fun rs x => rs.insert x.getId x) rs def eraseVars (rs : VarSet) (xs : Array Var) : VarSet := xs.foldl (·.erase ·.getId) rs def eraseOptVar (rs : VarSet) (x? : Option Var) : VarSet := match x? with | none => rs | some x => rs.insert x.getId x /-- Create a new join point for `c`, and jump to it with the variables `rs` -/ def mkSimpleJmp (ref : Syntax) (rs : VarSet) (c : Code) : StateRefT (Array JPDecl) TermElabM Code := do let xs := varSetToArray rs let jp ← addFreshJP (xs.map fun x => (x, true)) c if xs.isEmpty then let unit ← ``(Unit.unit) return Code.jmp ref jp #[unit] else return Code.jmp ref jp xs /-- Create a new join point that takes `rs` and `val` as arguments. `val` must be syntax representing a pure value. The body of the join point is created using `mkJPBody yFresh`, where `yFresh` is a fresh variable created by this method. -/ def mkJmp (ref : Syntax) (rs : VarSet) (val : Syntax) (mkJPBody : Syntax → MacroM Code) : StateRefT (Array JPDecl) TermElabM Code := do let xs := varSetToArray rs let args := xs.push val let yFresh ← withRef ref `(y) let ps := xs.map fun x => (x, true) let ps := ps.push (yFresh, false) let jpBody ← liftMacroM <| mkJPBody yFresh let jp ← addFreshJP ps jpBody return Code.jmp ref jp args /-- `pullExitPointsAux rs c` auxiliary method for `pullExitPoints`, `rs` is the set of update variable in the current path. -/ partial def pullExitPointsAux (rs : VarSet) (c : Code) : StateRefT (Array JPDecl) TermElabM Code := do match c with | .decl xs stx k => return .decl xs stx (← pullExitPointsAux (eraseVars rs xs) k) | .reassign xs stx k => return .reassign xs stx (← pullExitPointsAux (insertVars rs xs) k) | .joinpoint j ps b k => return .joinpoint j ps (← pullExitPointsAux rs b) (← pullExitPointsAux rs k) | .seq e k => return .seq e (← pullExitPointsAux rs k) | .ite ref x? o c t e => return .ite ref x? o c (← pullExitPointsAux (eraseOptVar rs x?) t) (← pullExitPointsAux (eraseOptVar rs x?) e) | .jmp .. => return c | .break ref => mkSimpleJmp ref rs (.break ref) | .continue ref => mkSimpleJmp ref rs (.continue ref) | .return ref val => mkJmp ref rs val (fun y => return .return ref y) | .action e => -- We use `mkAuxDeclFor` because `e` is not pure. mkAuxDeclFor e fun y => let ref := e mkJmp ref rs y (fun yFresh => return .action (← ``(Pure.pure $yFresh))) | .match ref g ds t alts => let alts ← alts.mapM fun alt => do pure { alt with rhs := (← pullExitPointsAux (eraseVars rs alt.vars) alt.rhs) } return .match ref g ds t alts | .matchExpr ref «meta» d alts e => let alts ← alts.mapM fun alt => do pure { alt with rhs := (← pullExitPointsAux (eraseVars rs alt.vars) alt.rhs) } let e ← pullExitPointsAux rs e return .matchExpr ref «meta» d alts e /-- Auxiliary operation for adding new variables to the collection of updated variables in a CodeBlock. When a new variable is not already in the collection, but is shadowed by some declaration in `c`, we create auxiliary join points to make sure we preserve the semantics of the code block. Example: suppose we have the code block `print x; let x := 10; return x`. And we want to extend it with the reassignment `x := x + 1`. We first use `pullExitPoints` to create ``` let jp (x!1) := return x!1; print x; let x := 10; jmp jp x ``` and then we add the reassignment ``` x := x + 1 let jp (x!1) := return x!1; print x; let x := 10; jmp jp x ``` Note that we created a fresh variable `x!1` to avoid accidental name capture. As another example, consider ``` print x; let x := 10 y := y + 1; return x; ``` We transform it into ``` let jp (y x!1) := return x!1; print x; let x := 10 y := y + 1; jmp jp y x ``` and then we add the reassignment as in the previous example. We need to include `y` in the jump, because each exit point is implicitly returning the set of update variables. We implement the method as follows. Let `us` be `c.uvars`, then 1- for each `return _ y` in `c`, we create a join point `let j (us y!1) := return y!1` and replace the `return _ y` with `jmp us y` 2- for each `break`, we create a join point `let j (us) := break` and replace the `break` with `jmp us`. 3- Same as 2 for `continue`. -/ def pullExitPoints (c : Code) : TermElabM Code := do if hasExitPoint c then let (c, jpDecls) ← (pullExitPointsAux {} c).run #[] return attachJPs jpDecls c else return c partial def extendUpdatedVarsAux (c : Code) (ws : VarSet) : TermElabM Code := let rec update (c : Code) : TermElabM Code := do match c with | .joinpoint j ps b k => return .joinpoint j ps (← update b) (← update k) | .seq e k => return .seq e (← update k) | .match ref g ds t alts => if alts.any fun alt => alt.vars.any fun x => ws.contains x.getId then -- If a pattern variable is shadowing a variable in ws, we `pullExitPoints` pullExitPoints c else return .match ref g ds t (← alts.mapM fun alt => do pure { alt with rhs := (← update alt.rhs) }) | .matchExpr ref «meta» d alts e => if alts.any fun alt => alt.vars.any fun x => ws.contains x.getId then -- If a pattern variable is shadowing a variable in ws, we `pullExitPoints` pullExitPoints c else let alts ← alts.mapM fun alt => do pure { alt with rhs := (← update alt.rhs) } let e ← update e return .matchExpr ref «meta» d alts e | .ite ref none o c t e => return .ite ref none o c (← update t) (← update e) | .ite ref (some h) o cond t e => if ws.contains h.getId then -- if the `h` at `if h : c then t else e` shadows a variable in `ws`, we `pullExitPoints` pullExitPoints c else return Code.ite ref (some h) o cond (← update t) (← update e) | .reassign xs stx k => return .reassign xs stx (← update k) | .decl xs stx k => do if xs.any fun x => ws.contains x.getId then -- One the declared variables is shadowing a variable in `ws` pullExitPoints c else return .decl xs stx (← update k) | c => return c update c /-- Extend the set of updated variables. It assumes `ws` is a super set of `c.uvars`. We **cannot** simply update the field `c.uvars`, because `c` may have shadowed some variable in `ws`. See discussion at `pullExitPoints`. -/ partial def extendUpdatedVars (c : CodeBlock) (ws : VarSet) : TermElabM CodeBlock := do if ws.any fun x _ => !c.uvars.contains x then -- `ws` contains a variable that is not in `c.uvars`, but in `c.dvars` (i.e., it has been shadowed) pure { code := (← extendUpdatedVarsAux c.code ws), uvars := ws } else pure { c with uvars := ws } private def union (s₁ s₂ : VarSet) : VarSet := s₁.foldl (·.insert ·) s₂ /-- Given two code blocks `c₁` and `c₂`, make sure they have the same set of updated variables. Let `ws` the union of the updated variables in `c₁‵ and ‵c₂`. We use `extendUpdatedVars c₁ ws` and `extendUpdatedVars c₂ ws` -/ def homogenize (c₁ c₂ : CodeBlock) : TermElabM (CodeBlock × CodeBlock) := do let ws := union c₁.uvars c₂.uvars let c₁ ← extendUpdatedVars c₁ ws let c₂ ← extendUpdatedVars c₂ ws pure (c₁, c₂) /-- Extending code blocks with variable declarations: `let x : t := v` and `let x : t ← v`. We remove `x` from the collection of updated variables. Remark: `stx` is the syntax for the declaration (e.g., `letDecl`), and `xs` are the variables declared by it. It is an array because we have let-declarations that declare multiple variables. Example: `let (x, y) := t` -/ def mkVarDeclCore (xs : Array Var) (stx : Syntax) (c : CodeBlock) : CodeBlock := { code := Code.decl xs stx c.code, uvars := eraseVars c.uvars xs } /-- Extending code blocks with reassignments: `x : t := v` and `x : t ← v`. Remark: `stx` is the syntax for the declaration (e.g., `letDecl`), and `xs` are the variables declared by it. It is an array because we have let-declarations that declare multiple variables. Example: `(x, y) ← t` -/ def mkReassignCore (xs : Array Var) (stx : Syntax) (c : CodeBlock) : TermElabM CodeBlock := do let us := c.uvars let ws := insertVars us xs -- If `xs` contains a new updated variable, then we must use `extendUpdatedVars`. -- See discussion at `pullExitPoints` let code ← if xs.any fun x => !us.contains x.getId then extendUpdatedVarsAux c.code ws else pure c.code pure { code := .reassign xs stx code, uvars := ws } def mkSeq (action : Syntax) (c : CodeBlock) : CodeBlock := { c with code := .seq action c.code } def mkTerminalAction (action : Syntax) : CodeBlock := { code := .action action } def mkReturn (ref : Syntax) (val : Syntax) : CodeBlock := { code := .return ref val } def mkBreak (ref : Syntax) : CodeBlock := { code := .break ref } def mkContinue (ref : Syntax) : CodeBlock := { code := .continue ref } def mkIte (ref : Syntax) (optIdent : Syntax) (cond : Syntax) (thenBranch : CodeBlock) (elseBranch : CodeBlock) : TermElabM CodeBlock := do let x? := optIdent.getOptional? let (thenBranch, elseBranch) ← homogenize thenBranch elseBranch return { code := .ite ref x? optIdent cond thenBranch.code elseBranch.code, uvars := thenBranch.uvars, } private def mkUnit : MacroM Syntax := ``((⟨⟩ : PUnit)) private def mkPureUnit : MacroM Syntax := ``(pure PUnit.unit) def mkPureUnitAction : MacroM CodeBlock := do return mkTerminalAction (← mkPureUnit) def mkUnless (cond : Syntax) (c : CodeBlock) : MacroM CodeBlock := do let thenBranch ← mkPureUnitAction return { c with code := .ite (← getRef) none mkNullNode cond thenBranch.code c.code } def mkMatch (ref : Syntax) (genParam : Syntax) (discrs : Syntax) (optMotive : Syntax) (alts : Array (Alt CodeBlock)) : TermElabM CodeBlock := do -- nary version of homogenize let ws := alts.foldl (union · ·.rhs.uvars) {} let alts ← alts.mapM fun alt => do let rhs ← extendUpdatedVars alt.rhs ws return { ref := alt.ref, vars := alt.vars, patterns := alt.patterns, rhs := rhs.code : Alt Code } return { code := .match ref genParam discrs optMotive alts, uvars := ws } def mkMatchExpr (ref : Syntax) («meta» : Bool) (discr : Syntax) (alts : Array (AltExpr CodeBlock)) (elseBranch : CodeBlock) : TermElabM CodeBlock := do -- nary version of homogenize let ws := alts.foldl (union · ·.rhs.uvars) {} let ws := union ws elseBranch.uvars let alts ← alts.mapM fun alt => do let rhs ← extendUpdatedVars alt.rhs ws return { alt with rhs := rhs.code : AltExpr Code } let elseBranch ← extendUpdatedVars elseBranch ws return { code := .matchExpr ref «meta» discr alts elseBranch.code, uvars := ws } /-- Return a code block that executes `terminal` and then `k` with the value produced by `terminal`. This method assumes `terminal` is a terminal -/ def concat (terminal : CodeBlock) (kRef : Syntax) (y? : Option Var) (k : CodeBlock) : TermElabM CodeBlock := do unless hasTerminalAction terminal.code do throwErrorAt kRef "`do` element is unreachable" let (terminal, k) ← homogenize terminal k let xs := varSetToArray k.uvars let y ← match y? with | some y => pure y | none => `(y) let ps := xs.map fun x => (x, true) let ps := ps.push (y, false) let jpDecl ← mkFreshJP ps k.code let jp := jpDecl.name let terminal ← liftMacroM <| convertTerminalActionIntoJmp terminal.code jp xs return { code := attachJP jpDecl terminal, uvars := k.uvars } def getLetIdVars (letId : Syntax) : Array Var := assert! letId.isOfKind ``Parser.Term.letId -- def letId := leading_parser binderIdent <|> hygieneInfo if letId[0].isIdent then #[letId[0]] else if letId[0].isOfKind hygieneInfoKind then #[HygieneInfo.mkIdent letId[0] `this (canonical := true)] else #[] def getLetIdDeclVars (letIdDecl : Syntax) : Array Var := assert! letIdDecl.isOfKind ``Parser.Term.letIdDecl -- def letIdLhs : Parser := letId >> many (ppSpace >> letIdBinder) >> optType -- def letIdDecl := leading_parser letIdLhs >> " := " >> termParser getLetIdVars letIdDecl[0] -- support both regular and syntax match def getPatternVarsEx (pattern : Syntax) : TermElabM (Array Var) := getPatternVars pattern <|> Quotation.getPatternVars pattern def getPatternsVarsEx (patterns : Array Syntax) : TermElabM (Array Var) := getPatternsVars patterns <|> Quotation.getPatternsVars patterns def getLetPatDeclVars (letPatDecl : Syntax) : TermElabM (Array Var) := do -- def letPatDecl := leading_parser termParser >> pushNone >> optType >> " := " >> termParser let pattern := letPatDecl[0] getPatternVarsEx pattern def getLetEqnsDeclVars (letEqnsDecl : Syntax) : Array Var := assert! letEqnsDecl.isOfKind ``Parser.Term.letEqnsDecl -- def letIdLhs : Parser := letId >> many (ppSpace >> letIdBinder) >> optType -- def letEqnsDecl := leading_parser letIdLhs >> matchAlts getLetIdVars letEqnsDecl[0] def getLetDeclVars (letDecl : Syntax) : TermElabM (Array Var) := do -- def letDecl := leading_parser letIdDecl <|> letPatDecl <|> letEqnsDecl let arg := letDecl[0] if arg.getKind == ``Parser.Term.letIdDecl then return getLetIdDeclVars arg else if arg.getKind == ``Parser.Term.letPatDecl then getLetPatDeclVars arg else if arg.getKind == ``Parser.Term.letEqnsDecl then return getLetEqnsDeclVars arg else throwError "unexpected kind of let declaration" def getDoLetVars (doLet : Syntax) : TermElabM (Array Var) := -- leading_parser "let " >> optional "mut " >> letDecl getLetDeclVars doLet[2] def getDoHaveVars (doHave : Syntax) : TermElabM (Array Var) := -- leading_parser "have" >> letDecl getLetDeclVars doHave[1] def getDoLetRecVars (doLetRec : Syntax) : TermElabM (Array Var) := do -- letRecDecls is an array of `(group (optional attributes >> letDecl))` let letRecDecls := doLetRec[1][0].getSepArgs let letDecls := letRecDecls.map fun p => p[2] let mut allVars := #[] for letDecl in letDecls do let vars ← getLetDeclVars letDecl allVars := allVars ++ vars return allVars -- ident >> optType >> leftArrow >> termParser def getDoIdDeclVar (doIdDecl : Syntax) : Var := doIdDecl[0] -- termParser >> leftArrow >> termParser >> optional (" | " >> termParser) def getDoPatDeclVars (doPatDecl : Syntax) : TermElabM (Array Var) := do let pattern := doPatDecl[0] getPatternVarsEx pattern -- leading_parser "let " >> optional "mut " >> (doIdDecl <|> doPatDecl) def getDoLetArrowVars (doLetArrow : Syntax) : TermElabM (Array Var) := do let decl := doLetArrow[2] if decl.getKind == ``Parser.Term.doIdDecl then return #[getDoIdDeclVar decl] else if decl.getKind == ``Parser.Term.doPatDecl then getDoPatDeclVars decl else throwError "unexpected kind of `do` declaration" def getDoReassignVars (doReassign : Syntax) : TermElabM (Array Var) := do let arg := doReassign[0] if arg.getKind == ``Parser.Term.letIdDecl then return getLetIdDeclVars arg else if arg.getKind == ``Parser.Term.letPatDecl then getLetPatDeclVars arg else throwError "unexpected kind of reassignment" def mkDoSeq (doElems : Array Syntax) : Syntax := mkNode `Lean.Parser.Term.doSeqIndent #[mkNullNode <| doElems.map fun doElem => mkNullNode #[doElem, mkNullNode]] /-- If the given syntax is a `doIf`, return an equivalent `doIf` that has an `else` but no `else if`s or `if let`s. -/ private def expandDoIf? (stx : Syntax) : MacroM (Option Syntax) := match stx with | `(doElem|if $_:doIfProp then $_ else $_) => pure none | `(doElem|if $cond:doIfCond then $t $[else if $conds:doIfCond then $ts]* $[else $e?]?) => withRef stx do let mut e := e?.getD (← `(doSeq|pure PUnit.unit)) let mut eIsSeq := true for (cond, t) in Array.zip (conds.reverse.push cond) (ts.reverse.push t) do e ← if eIsSeq then pure e else `(doSeq|$e:doElem) e ← match cond with | `(doIfCond|let $pat := $d) => `(doElem| match $d:term with | $pat:term => $t | _ => $e) | `(doIfCond|let $pat ← $d) => `(doElem| match ← $d with | $pat:term => $t | _ => $e) | `(doIfCond|$cond:doIfProp) => `(doElem| if $cond:doIfProp then $t else $e) | _ => `(doElem| if $(Syntax.missing) then $t else $e) eIsSeq := false return some e | _ => pure none /-- If the given syntax is a `doLetExpr` or `doLetMetaExpr`, return an equivalent `doIf` that has an `else` but no `else if`s or `if let`s. -/ private def expandDoLetExpr? (stx : Syntax) (doElems : List Syntax) : MacroM (Option Syntax) := match stx with | `(doElem| let_expr $pat:matchExprPat := $discr:term | $elseBranch:doSeq) => return some (← `(doElem| match_expr (meta := false) $discr:term with | $pat:matchExprPat => $(mkDoSeq doElems.toArray) | _ => $elseBranch)) | `(doElem| let_expr $pat:matchExprPat ← $discr:term | $elseBranch:doSeq) => return some (← `(doElem| match_expr $discr:term with | $pat:matchExprPat => $(mkDoSeq doElems.toArray) | _ => $elseBranch)) | _ => return none structure DoIfView where ref : Syntax optIdent : Syntax cond : Syntax thenBranch : Syntax elseBranch : Syntax /-- This method assumes `expandDoIf?` is not applicable. -/ private def mkDoIfView (doIf : Syntax) : DoIfView := { ref := doIf optIdent := doIf[1][0] cond := doIf[1][1] thenBranch := doIf[3] elseBranch := doIf[5][1] } /-- We use `MProd` instead of `Prod` to group values when expanding the `do` notation. `MProd` is a universe monomorphic product. The motivation is to generate simpler universe constraints in code that was not written by the user. Note that we are not restricting the macro power since the `Bind.bind` combinator already forces values computed by monadic actions to be in the same universe. -/ private def mkTuple (elems : Array Syntax) : MacroM Syntax := do if elems.size = 0 then mkUnit else if h : elems.size = 1 then return elems[0] else elems.extract 0 (elems.size - 1) |>.foldrM (init := elems.back!) fun elem tuple => ``(MProd.mk $elem $tuple) /-- Return `some action` if `doElem` is a `doExpr `-/ def isDoExpr? (doElem : Syntax) : Option Syntax := if doElem.getKind == ``Parser.Term.doExpr then some doElem[0] else none /-- Given `uvars := #[a_1, ..., a_n, a_{n+1}]` construct term ``` let a_1 := x.1 let x := x.2 let a_2 := x.1 let x := x.2 ... let a_n := x.1 let a_{n+1} := x.2 body ``` Special cases - `uvars := #[]` => `body` - `uvars := #[a]` => `let a := x; body` We use this method when expanding the `for-in` notation. -/ private def destructTuple (uvars : Array Var) (x : Syntax) (body : Syntax) : MacroM Syntax := do if uvars.size = 0 then return body else if h : uvars.size = 1 then `(let $(uvars[0]):ident := $x; $body) else destruct uvars.toList x body where destruct (as : List Var) (x : Syntax) (body : Syntax) : MacroM Syntax := do match as with | [a, b] => `(let $a:ident := $x.1; let $b:ident := $x.2; $body) | a :: as => withFreshMacroScope do let rest ← destruct as (← `(x)) body `(let $a:ident := $x.1; let x := $x.2; $rest) | _ => unreachable! /-! The procedure `ToTerm.run` converts a `CodeBlock` into a `Syntax` term. We use this method to convert 1- The `CodeBlock` for a root `do ...` term into a `Syntax` term. This kind of `CodeBlock` never contains `break` nor `continue`. Moreover, the collection of updated variables is not packed into the result. Thus, we have two kinds of exit points - `Code.action e` which is converted into `e` - `Code.return _ e` which is converted into `pure e` We use `Kind.regular` for this case. 2- The `CodeBlock` for `b` at `for x in xs do b`. In this case, we need to generate a `Syntax` term representing a function for the `xs.forIn` combinator. a) If `b` contain a `Code.return _ a` exit point. The generated `Syntax` term has type `m (ForInStep (Option α × σ))`, where `a : α`, and the `σ` is the type of the tuple of variables reassigned by `b`. We use `Kind.forInWithReturn` for this case b) If `b` does not contain a `Code.return _ a` exit point. Then, the generated `Syntax` term has type `m (ForInStep σ)`. We use `Kind.forIn` for this case. 3- The `CodeBlock` `c` for a `do` sequence nested in a monadic combinator (e.g., `MonadExcept.tryCatch`). The generated `Syntax` term for `c` must inform whether `c` "exited" using `Code.action`, `Code.return`, `Code.break` or `Code.continue`. We use the auxiliary types `DoResult`s for storing this information. For example, the auxiliary type `DoResultPBC α σ` is used for a code block that exits with `Code.action`, **and** `Code.break`/`Code.continue`, `α` is the type of values produced by the exit `action`, and `σ` is the type of the tuple of reassigned variables. The type `DoResult α β σ` is usedf for code blocks that exit with `Code.action`, `Code.return`, **and** `Code.break`/`Code.continue`, `β` is the type of the returned values. We don't use `DoResult α β σ` for all cases because: a) The elaborator would not be able to infer all type parameters without extra annotations. For example, if the code block does not contain `Code.return _ _`, the elaborator will not be able to infer `β`. b) We need to pattern match on the result produced by the combinator (e.g., `MonadExcept.tryCatch`), but we don't want to consider "unreachable" cases. We do not distinguish between cases that contain `break`, but not `continue`, and vice versa. When listing all cases, we use `a` to indicate the code block contains `Code.action _`, `r` for `Code.return _ _`, and `b/c` for a code block that contains `Code.break _` or `Code.continue _`. - `a`: `Kind.regular`, type `m (α × σ)` - `r`: `Kind.regular`, type `m (α × σ)` Note that the code that pattern matches on the result will behave differently in this case. It produces `return a` for this case, and `pure a` for the previous one. - `b/c`: `Kind.nestedBC`, type `m (DoResultBC σ)` - `a` and `r`: `Kind.nestedPR`, type `m (DoResultPR α β σ)` - `a` and `bc`: `Kind.nestedSBC`, type `m (DoResultSBC α σ)` - `r` and `bc`: `Kind.nestedSBC`, type `m (DoResultSBC α σ)` Again the code that pattern matches on the result will behave differently in this case and the previous one. It produces `return a` for the constructor `DoResultSPR.pureReturn a u` for this case, and `pure a` for the previous case. - `a`, `r`, `b/c`: `Kind.nestedPRBC`, type type `m (DoResultPRBC α β σ)` Here is the recipe for adding new combinators with nested `do`s. Example: suppose we want to support `repeat doSeq`. Assuming we have `repeat : m α → m α` 1- Convert `doSeq` into `codeBlock : CodeBlock` 2- Create term `term` using `mkNestedTerm code m uvars a r bc` where `code` is `codeBlock.code`, `uvars` is an array containing `codeBlock.uvars`, `m` is a `Syntax` representing the Monad, and `a` is true if `code` contains `Code.action _`, `r` is true if `code` contains `Code.return _ _`, `bc` is true if `code` contains `Code.break _` or `Code.continue _`. Remark: for combinators such as `repeat` that take a single `doSeq`, all arguments, but `m`, are extracted from `codeBlock`. 3- Create the term `repeat $term` 4- and then, convert it into a `doSeq` using `matchNestedTermResult ref (repeat $term) uvsar a r bc` -/ /-- Helper method for annotating `term` with the raw syntax `ref`. We use this method to implement finer-grained term infos for `do`-blocks. We use `withRef term` to make sure the synthetic position for the `with_annotate_term` is equal to the one for `term`. This is important for producing error messages when there is a type mismatch. Consider the following example: ``` opaque f : IO Nat def g : IO String := do f ``` There is at type mismatch at `f`, but it is detected when elaborating the expanded term containing the `with_annotate_term .. f`. The current `getRef` when this `annotate` is invoked is not necessarily `f`. Actually, it is the whole `do`-block. By using `withRef` we ensure the synthetic position for the `with_annotate_term ..` is equal to `term`. Recall that synthetic positions are used when generating error messages. -/ def annotate [Monad m] [MonadRef m] [MonadQuotation m] (ref : Syntax) (term : Syntax) : m Syntax := withRef term <| `(with_annotate_term $ref $term) namespace ToTerm inductive Kind where | regular | forIn | forInWithReturn | nestedBC | nestedPR | nestedSBC | nestedPRBC instance : Inhabited Kind := ⟨Kind.regular⟩ def Kind.isRegular : Kind → Bool | .regular => true | _ => false structure Context where /-- Syntax to reference the monad associated with the do notation. -/ m : Syntax /-- Syntax to reference the result of the monadic computation performed by the do notation. -/ returnType : Syntax uvars : Array Var kind : Kind abbrev M := ReaderT Context MacroM def mkUVarTuple : M Syntax := do let ctx ← read mkTuple ctx.uvars def returnToTerm (val : Syntax) : M Syntax := do let ctx ← read let u ← mkUVarTuple match ctx.kind with | .regular => if ctx.uvars.isEmpty then ``(Pure.pure $val) else ``(Pure.pure (MProd.mk $val $u)) | .forIn => ``(Pure.pure (ForInStep.done $u)) | .forInWithReturn => ``(Pure.pure (ForInStep.done (MProd.mk (some $val) $u))) | .nestedBC => unreachable! | .nestedPR => ``(Pure.pure (DoResultPR.«return» $val $u)) | .nestedSBC => ``(Pure.pure (DoResultSBC.«pureReturn» $val $u)) | .nestedPRBC => ``(Pure.pure (DoResultPRBC.«return» $val $u)) def continueToTerm : M Syntax := do let ctx ← read let u ← mkUVarTuple match ctx.kind with | .regular => unreachable! | .forIn => ``(Pure.pure (ForInStep.yield $u)) | .forInWithReturn => ``(Pure.pure (ForInStep.yield (MProd.mk none $u))) | .nestedBC => ``(Pure.pure (DoResultBC.«continue» $u)) | .nestedPR => unreachable! | .nestedSBC => ``(Pure.pure (DoResultSBC.«continue» $u)) | .nestedPRBC => ``(Pure.pure (DoResultPRBC.«continue» $u)) def breakToTerm : M Syntax := do let ctx ← read let u ← mkUVarTuple match ctx.kind with | .regular => unreachable! | .forIn => ``(Pure.pure (ForInStep.done $u)) | .forInWithReturn => ``(Pure.pure (ForInStep.done (MProd.mk none $u))) | .nestedBC => ``(Pure.pure (DoResultBC.«break» $u)) | .nestedPR => unreachable! | .nestedSBC => ``(Pure.pure (DoResultSBC.«break» $u)) | .nestedPRBC => ``(Pure.pure (DoResultPRBC.«break» $u)) def actionTerminalToTerm (action : Syntax) : M Syntax := withRef action <| withFreshMacroScope do let ctx ← read let u ← mkUVarTuple match ctx.kind with | .regular => if ctx.uvars.isEmpty then pure action else ``(Bind.bind $action fun y => Pure.pure (MProd.mk y $u)) | .forIn => ``(Bind.bind $action fun (_ : PUnit) => Pure.pure (ForInStep.yield $u)) | .forInWithReturn => ``(Bind.bind $action fun (_ : PUnit) => Pure.pure (ForInStep.yield (MProd.mk none $u))) | .nestedBC => unreachable! | .nestedPR => ``(Bind.bind $action fun y => (Pure.pure (DoResultPR.«pure» y $u))) | .nestedSBC => ``(Bind.bind $action fun y => (Pure.pure (DoResultSBC.«pureReturn» y $u))) | .nestedPRBC => ``(Bind.bind $action fun y => (Pure.pure (DoResultPRBC.«pure» y $u))) def seqToTerm (action : Syntax) (k : Syntax) : M Syntax := withRef action <| withFreshMacroScope do if action.getKind == ``Parser.Term.doDbgTrace then let msg := action[1] `(dbg_trace $msg; $k) else if action.getKind == ``Parser.Term.doAssert then let cond := action[1] `(assert! $cond; $k) else if action.getKind == ``Parser.Term.doDebugAssert then let cond := action[1] `(debugAssert| debug_assert! $cond; $k) else let action ← withRef action ``(($action : $((←read).m) PUnit)) ``(Bind.bind $action (fun (_ : PUnit) => $k)) def declToTerm (decl : Syntax) (k : Syntax) : M Syntax := withRef decl <| withFreshMacroScope do let kind := decl.getKind if kind == ``Parser.Term.doLet then let letDecl := decl[2] `(let $letDecl:letDecl; $k) else if kind == ``Parser.Term.doLetRec then let letRecToken := decl[0] let letRecDecls := decl[1] return mkNode ``Parser.Term.letrec #[letRecToken, letRecDecls, mkNullNode, k] else if kind == ``Parser.Term.doLetArrow then let arg := decl[2] if arg.getKind == ``Parser.Term.doIdDecl then let id := arg[0] let type := expandOptType id arg[1] let doElem := arg[3] -- `doElem` must be a `doExpr action`. See `doLetArrowToCode` match isDoExpr? doElem with | some action => let action ← withRef action `(($action : $((← read).m) $type)) ``(Bind.bind $action (fun ($id:ident : $type) => $k)) | none => Macro.throwErrorAt decl "unexpected kind of `do` declaration" else Macro.throwErrorAt decl "unexpected kind of `do` declaration" else if kind == ``Parser.Term.doHave then -- The `have` term is of the form `"have " >> letDecl >> optSemicolon termParser` let args := decl.getArgs let args := args ++ #[mkNullNode /- optional ';' -/, k] return mkNode `Lean.Parser.Term.«have» args else Macro.throwErrorAt decl "unexpected kind of `do` declaration" def reassignToTerm (reassign : Syntax) (k : Syntax) : MacroM Syntax := withRef reassign <| withFreshMacroScope do match reassign with | `(doElem| $x:ident := $rhs) => `(let $x:ident := ensure_type_of% $x $(quote "invalid reassignment, value") $rhs; $k) | `(doElem| $e:term := $rhs) => `(let $e:term := ensure_type_of% $e $(quote "invalid reassignment, value") $rhs; $k) | _ => -- Note that `doReassignArrow` is expanded by `doReassignArrowToCode Macro.throwErrorAt reassign "unexpected kind of `do` reassignment" def mkIte (optIdent : Syntax) (cond : Syntax) (thenBranch : Syntax) (elseBranch : Syntax) : MacroM Syntax := do if optIdent.isNone then ``(if $cond then $thenBranch else $elseBranch) else let h := optIdent[0] ``(if $h:ident : $cond then $thenBranch else $elseBranch) def mkJoinPoint (j : Name) (ps : Array (Syntax × Bool)) (body : Syntax) (k : Syntax) : M Syntax := withRef body <| withFreshMacroScope do let pTypes ← ps.mapM fun ⟨id, useTypeOf⟩ => do if useTypeOf then `(type_of% $id) else `(_) let ps := ps.map (·.1) /- We use `let_delayed` instead of `let` for join points to make sure `$k` is elaborated before `$body`. By elaborating `$k` first, we "learn" more about `$body`'s type. For example, consider the following example `do` expression ``` def f (x : Nat) : IO Unit := do if x > 0 then IO.println "x is not zero" -- Error is here IO.mkRef true ``` it is expanded into ``` def f (x : Nat) : IO Unit := do let jp (u : Unit) : IO _ := IO.mkRef true; if x > 0 then IO.println "not zero" jp () else jp () ``` If we use the regular `let` instead of `let_delayed`, the join point `jp` will be elaborated and its type will be inferred to be `Unit → IO (IO.Ref Bool)`. Then, we get a typing error at `jp ()`. By using `let_delayed`, we first elaborate `if x > 0 ...` and learn that `jp` has type `Unit → IO Unit`. Then, we get the expected type mismatch error at `IO.mkRef true`. -/ `(let_delayed $(← mkIdentFromRef j):ident $[($ps : $pTypes)]* : $((← read).m) _ := $body; $k) def mkJmp (ref : Syntax) (j : Name) (args : Array Syntax) : Syntax := Syntax.mkApp (mkIdentFrom ref j) args partial def toTerm (c : Code) : M Syntax := do let term ← go c if let some ref := c.getRef? then annotate ref term else return term where go (c : Code) : M Syntax := do match c with | .return ref val => withRef ref <| returnToTerm val | .continue ref => withRef ref continueToTerm | .break ref => withRef ref breakToTerm | .action e => actionTerminalToTerm e | .joinpoint j ps b k => mkJoinPoint j ps (← toTerm b) (← toTerm k) | .jmp ref j args => return mkJmp ref j args | .decl _ stx k => declToTerm stx (← toTerm k) | .reassign _ stx k => reassignToTerm stx (← toTerm k) | .seq stx k => seqToTerm stx (← toTerm k) | .ite ref _ o c t e => withRef ref <| do mkIte o c (← toTerm t) (← toTerm e) | .match ref genParam discrs optMotive alts => let mut termAlts := #[] for alt in alts do let rhs ← toTerm alt.rhs let termAlt := mkNode ``Parser.Term.matchAlt #[mkAtomFrom alt.ref "|", mkNullNode #[alt.patterns], mkAtomFrom alt.ref "=>", rhs] termAlts := termAlts.push termAlt let termMatchAlts := mkNode ``Parser.Term.matchAlts #[mkNullNode termAlts] return mkNode ``Parser.Term.«match» #[mkAtomFrom ref "match", genParam, optMotive, discrs, mkAtomFrom ref "with", termMatchAlts] | .matchExpr ref «meta» d alts elseBranch => withFreshMacroScope do let d' ← `(discr) let mut termAlts := #[] for alt in alts do let rhs ← `(($(← toTerm alt.rhs) : $((← read).m) _)) let optVar := if let some var := alt.var? then mkNullNode #[var, mkAtomFrom var "@"] else mkNullNode #[] let pat := mkNode ``Parser.Term.matchExprPat #[optVar, alt.funName, mkNullNode alt.pvars] let termAlt := mkNode ``Parser.Term.matchExprAlt #[mkAtomFrom alt.ref "|", pat, mkAtomFrom alt.ref "=>", rhs] termAlts := termAlts.push termAlt let elseBranch := mkNode ``Parser.Term.matchExprElseAlt #[mkAtomFrom ref "|", mkHole ref, mkAtomFrom ref "=>", (← toTerm elseBranch)] let termMatchExprAlts := mkNode ``Parser.Term.matchExprAlts #[mkNullNode termAlts, elseBranch] let body := mkNode ``Parser.Term.matchExpr #[mkAtomFrom ref "match_expr", d', mkAtomFrom ref "with", termMatchExprAlts] if «meta» then `(Bind.bind (instantiateMVarsIfMVarApp $d) fun discr => $body) else `(let discr := $d; $body) def run (code : Code) (m : Syntax) (returnType : Syntax) (uvars : Array Var := #[]) (kind := Kind.regular) : MacroM Syntax := toTerm code { m, returnType, kind, uvars } /-- Given - `a` is true if the code block has a `Code.action _` exit point - `r` is true if the code block has a `Code.return _ _` exit point - `bc` is true if the code block has a `Code.break _` or `Code.continue _` exit point generate Kind. See comment at the beginning of the `ToTerm` namespace. -/ def mkNestedKind (a r bc : Bool) : Kind := match a, r, bc with | true, false, false => .regular | false, true, false => .regular | false, false, true => .nestedBC | true, true, false => .nestedPR | true, false, true => .nestedSBC | false, true, true => .nestedSBC | true, true, true => .nestedPRBC | false, false, false => unreachable! def mkNestedTerm (code : Code) (m : Syntax) (returnType : Syntax) (uvars : Array Var) (a r bc : Bool) : MacroM Syntax := do ToTerm.run code m returnType uvars (mkNestedKind a r bc) /-- Given a term `term` produced by `ToTerm.run`, pattern match on its result. See comment at the beginning of the `ToTerm` namespace. - `a` is true if the code block has a `Code.action _` exit point - `r` is true if the code block has a `Code.return _ _` exit point - `bc` is true if the code block has a `Code.break _` or `Code.continue _` exit point The result is a sequence of `doElem` -/ def matchNestedTermResult (term : Syntax) (uvars : Array Var) (a r bc : Bool) : MacroM (List Syntax) := do let toDoElems (auxDo : Syntax) : List Syntax := getDoSeqElems (getDoSeq auxDo) let u ← mkTuple uvars match a, r, bc with | true, false, false => if uvars.isEmpty then return toDoElems (← `(do $term:term)) else return toDoElems (← `(do let r ← $term:term; $u:term := r.2; pure r.1)) | false, true, false => if uvars.isEmpty then return toDoElems (← `(do let r ← $term:term; return r)) else return toDoElems (← `(do let r ← $term:term; $u:term := r.2; return r.1)) | false, false, true => toDoElems <$> `(do let r ← $term:term; match r with | .break u => $u:term := u; break | .continue u => $u:term := u; continue) | true, true, false => toDoElems <$> `(do let r ← $term:term; match r with | .pure a u => $u:term := u; pure a | .return b u => $u:term := u; return b) | true, false, true => toDoElems <$> `(do let r ← $term:term; match r with | .pureReturn a u => $u:term := u; pure a | .break u => $u:term := u; break | .continue u => $u:term := u; continue) | false, true, true => toDoElems <$> `(do let r ← $term:term; match r with | .pureReturn a u => $u:term := u; return a | .break u => $u:term := u; break | .continue u => $u:term := u; continue) | true, true, true => toDoElems <$> `(do let r ← $term:term; match r with | .pure a u => $u:term := u; pure a | .return a u => $u:term := u; return a | .break u => $u:term := u; break | .continue u => $u:term := u; continue) | false, false, false => unreachable! end ToTerm def isMutableLet (doElem : Syntax) : Bool := let kind := doElem.getKind (kind == ``doLetArrow || kind == ``doLet || kind == ``doLetElse) && !doElem[1].isNone namespace ToCodeBlock structure Context where ref : Syntax /-- Syntax representing the monad associated with the do notation. -/ m : Syntax /-- Syntax to reference the result of the monadic computation performed by the do notation. -/ returnType : Syntax mutableVars : VarSet := {} insideFor : Bool := false abbrev M := ReaderT Context TermElabM def withNewMutableVars {α} (newVars : Array Var) (mutable : Bool) (x : M α) : M α := withReader (fun ctx => if mutable then { ctx with mutableVars := insertVars ctx.mutableVars newVars } else ctx) x def checkReassignable (xs : Array Var) : M Unit := do let throwInvalidReassignment (x : Name) : M Unit := throwError "`{x.simpMacroScopes}` cannot be mutated, only variables declared using `let mut` can be mutated. If you did not intend to mutate but define `{x.simpMacroScopes}`, consider using `let {x.simpMacroScopes}` instead" let ctx ← read for x in xs do unless ctx.mutableVars.contains x.getId do throwInvalidReassignment x.getId def checkNotShadowingMutable (xs : Array Var) : M Unit := do let throwInvalidShadowing (x : Name) : M Unit := throwError "mutable variable `{x.simpMacroScopes}` cannot be shadowed" let ctx ← read for x in xs do if ctx.mutableVars.contains x.getId then withRef x <| throwInvalidShadowing x.getId def withFor {α} (x : M α) : M α := withReader (fun ctx => { ctx with insideFor := true }) x structure ToForInTermResult where uvars : Array Var term : Syntax def mkForInBody (_ : Syntax) (forInBody : CodeBlock) : M ToForInTermResult := do let ctx ← read let uvars := forInBody.uvars let uvars := varSetToArray uvars let term ← liftMacroM <| ToTerm.run forInBody.code ctx.m ctx.returnType uvars (if hasReturn forInBody.code then ToTerm.Kind.forInWithReturn else ToTerm.Kind.forIn) return ⟨uvars, term⟩ def ensureInsideFor : M Unit := unless (← read).insideFor do throwError "invalid `do` element, it must be inside `for`" def ensureEOS (doElems : List Syntax) : M Unit := unless doElems.isEmpty do throwError "must be last element in a `do` sequence" variable (baseId : Name) in private partial def expandLiftMethodAux (inQuot : Bool) (inBinder : Bool) : Syntax → StateT (List Syntax) M Syntax | stx@(Syntax.node i k args) => if k == choiceKind then do -- choice node: check that lifts are consistent let alts ← stx.getArgs.mapM (expandLiftMethodAux inQuot inBinder · |>.run []) let (_, lifts) := alts[0]! unless alts.all (·.2 == lifts) do throwErrorAt stx "cannot lift `(<- ...)` over inconsistent syntax variants, consider lifting out the binding manually" modify (· ++ lifts) return .node i k (alts.map (·.1)) else if liftMethodDelimiter k then return stx -- For `pure` if-then-else, we only lift `(<- ...)` occurring in the condition. else if h : args.size >= 2 ∧ (k == ``termDepIfThenElse || k == ``termIfThenElse) then do let inAntiquot := stx.isAntiquot && !stx.isEscapedAntiquot let arg1 ← expandLiftMethodAux (inQuot && !inAntiquot || stx.isQuot) inBinder args[1] let args := args.set! 1 arg1 return Syntax.node i k args else if k == ``Parser.Term.liftMethod && !inQuot then withFreshMacroScope do if inBinder then throwErrorAt stx "cannot lift `(<- ...)` over a binder, this error usually happens when you are trying to lift a method nested in a `fun`, `let`, or `match`-alternative, and it can often be fixed by adding a missing `do`" let term := args[1]! let term ← expandLiftMethodAux inQuot inBinder term -- keep name deterministic across choice branches let id ← mkIdentFromRef (.num baseId (← get).length) let auxDoElem : Syntax ← `(doElem| let $id:ident ← $term:term) modify fun s => s ++ [auxDoElem] return id else do let inAntiquot := stx.isAntiquot && !stx.isEscapedAntiquot let inBinder := inBinder || (!inQuot && liftMethodForbiddenBinder stx) let args ← args.mapM (expandLiftMethodAux (inQuot && !inAntiquot || stx.isQuot) inBinder) return Syntax.node i k args | stx => return stx def expandLiftMethod (doElem : Syntax) : M (List Syntax × Syntax) := do if !hasLiftMethod doElem then return ([], doElem) else let baseId ← withFreshMacroScope (MonadQuotation.addMacroScope `__do_lift) let (doElem, doElemsNew) ← (expandLiftMethodAux baseId false false doElem).run [] return (doElemsNew, doElem) def checkLetArrowRHS (doElem : Syntax) : M Unit := do let kind := doElem.getKind if kind == ``Parser.Term.doLetArrow || kind == ``Parser.Term.doLet || kind == ``Parser.Term.doLetRec || kind == ``Parser.Term.doHave || kind == ``Parser.Term.doReassign || kind == ``Parser.Term.doReassignArrow then throwErrorAt doElem "invalid kind of value `{kind}` in an assignment" /-- Generate `CodeBlock` for `doReturn` which is of the form ``` "return " >> optional termParser ``` `doElems` is only used for sanity checking. -/ def doReturnToCode (doReturn : Syntax) (doElems: List Syntax) : M CodeBlock := withRef doReturn do ensureEOS doElems let argOpt := doReturn[1] let arg ← if argOpt.isNone then liftMacroM mkUnit else pure argOpt[0] return mkReturn (← getRef) arg structure Catch where x : Syntax optType : Syntax codeBlock : CodeBlock def getTryCatchUpdatedVars (tryCode : CodeBlock) (catches : Array Catch) (finallyCode? : Option CodeBlock) : VarSet := let ws := tryCode.uvars let ws := catches.foldl (init := ws) fun ws alt => union alt.codeBlock.uvars ws let ws := match finallyCode? with | none => ws | some c => union c.uvars ws ws def tryCatchPred (tryCode : CodeBlock) (catches : Array Catch) (finallyCode? : Option CodeBlock) (p : Code → Bool) : Bool := p tryCode.code || catches.any (fun «catch» => p «catch».codeBlock.code) || match finallyCode? with | none => false | some finallyCode => p finallyCode.code mutual /-- "Concatenate" `c` with `doSeqToCode doElems` -/ partial def concatWith (c : CodeBlock) (doElems : List Syntax) : M CodeBlock := match doElems with | [] => pure c | nextDoElem :: _ => do let k ← doSeqToCode doElems let ref := nextDoElem concat c ref none k /-- Generate `CodeBlock` for `doLetArrow; doElems` `doLetArrow` is of the form ``` "let " >> optional "mut " >> (doIdDecl <|> doPatDecl) ``` where ``` def doIdDecl := leading_parser ident >> optType >> leftArrow >> doElemParser def doPatDecl := leading_parser termParser >> leftArrow >> doElemParser >> optional (" | " >> doSeq) ``` -/ partial def doLetArrowToCode (doLetArrow : Syntax) (doElems : List Syntax) : M CodeBlock := do let decl := doLetArrow[2] if decl.getKind == ``Parser.Term.doIdDecl then let y := decl[0] checkNotShadowingMutable #[y] let doElem := decl[3] let k ← withNewMutableVars #[y] (isMutableLet doLetArrow) (doSeqToCode doElems) match isDoExpr? doElem with | some _ => return mkVarDeclCore #[y] doLetArrow k | none => checkLetArrowRHS doElem let c ← doSeqToCode [doElem] match doElems with | [] => pure c | kRef::_ => concat c kRef y k else if decl.getKind == ``Parser.Term.doPatDecl then let pattern := decl[0] let doElem := decl[2] let optElse := decl[3] if optElse.isNone then withFreshMacroScope do let auxDo ← if isMutableLet doLetArrow then `(do let%$doLetArrow __discr ← $doElem; let%$doLetArrow mut $pattern:term := __discr) else `(do let%$doLetArrow __discr ← $doElem; let%$doLetArrow $pattern:term := __discr) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) ++ doElems else let contSeq ← if isMutableLet doLetArrow then let vars ← (← getPatternVarsEx pattern).mapM fun var => `(doElem| let mut $var := $var) pure (vars ++ doElems.toArray) else pure doElems.toArray let contSeq := mkDoSeq contSeq let elseSeq := optElse[1] let auxDo ← `(do let%$doLetArrow __discr ← $doElem; match%$doLetArrow __discr with | $pattern:term => $contSeq | _ => $elseSeq) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) else throwError "unexpected kind of `do` declaration" partial def doLetElseToCode (doLetElse : Syntax) (doElems : List Syntax) : M CodeBlock := do -- "let " >> optional "mut " >> termParser >> " := " >> termParser >> checkColGt >> " | " >> doSeq let pattern := doLetElse[2] let val := doLetElse[4] let elseSeq := doLetElse[6] let contSeq ← if isMutableLet doLetElse then let vars ← (← getPatternVarsEx pattern).mapM fun var => `(doElem| let mut $var := $var) pure (vars ++ doElems.toArray) else pure doElems.toArray let contSeq := mkDoSeq contSeq let auxDo ← `(do match $val:term with | $pattern:term => $contSeq | _ => $elseSeq) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) /-- Generate `CodeBlock` for `doReassignArrow; doElems` `doReassignArrow` is of the form ``` (doIdDecl <|> doPatDecl) ``` -/ partial def doReassignArrowToCode (doReassignArrow : Syntax) (doElems : List Syntax) : M CodeBlock := do let decl := doReassignArrow[0] if decl.getKind == ``Parser.Term.doIdDecl then let doElem := decl[3] let y := decl[0] let auxDo ← `(do let r ← $doElem; $y:ident := r) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) ++ doElems else if decl.getKind == ``Parser.Term.doPatDecl then let pattern := decl[0] let doElem := decl[2] let optElse := decl[3] if optElse.isNone then withFreshMacroScope do let auxDo ← `(do let __discr ← $doElem; $pattern:term := __discr) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) ++ doElems else throwError "reassignment with `|` (i.e., \"else clause\") is not currently supported" else throwError "unexpected kind of `do` reassignment" /-- Generate `CodeBlock` for `doIf; doElems` `doIf` is of the form ``` "if " >> optIdent >> termParser >> " then " >> doSeq >> many (group (try (group (" else " >> " if ")) >> optIdent >> termParser >> " then " >> doSeq)) >> optional (" else " >> doSeq) ``` -/ partial def doIfToCode (doIf : Syntax) (doElems : List Syntax) : M CodeBlock := do let view := mkDoIfView doIf let thenBranch ← doSeqToCode (getDoSeqElems view.thenBranch) let elseBranch ← doSeqToCode (getDoSeqElems view.elseBranch) let ite ← mkIte view.ref view.optIdent view.cond thenBranch elseBranch concatWith ite doElems /-- Generate `CodeBlock` for `doUnless; doElems` `doUnless` is of the form ``` "unless " >> termParser >> "do " >> doSeq ``` -/ partial def doUnlessToCode (doUnless : Syntax) (doElems : List Syntax) : M CodeBlock := withRef doUnless do let cond := doUnless[1] let doSeq := doUnless[3] let body ← doSeqToCode (getDoSeqElems doSeq) let unlessCode ← liftMacroM <| mkUnless cond body concatWith unlessCode doElems /-- Generate `CodeBlock` for `doFor; doElems` `doFor` is of the form ``` def doForDecl := leading_parser termParser >> " in " >> withForbidden "do" termParser def doFor := leading_parser "for " >> sepBy1 doForDecl ", " >> "do " >> doSeq ``` -/ partial def doForToCode (doFor : Syntax) (doElems : List Syntax) : M CodeBlock := do let doForDecls := doFor[1].getSepArgs if h : doForDecls.size > 1 then /- Expand ``` for x in xs, y in ys do body ``` into ``` let s := toStream ys for x in xs do match Stream.next? s with | none => break | some (y, s') => s := s' body ``` -/ -- Extract second element let doForDecl := doForDecls[1]! unless doForDecl[0].isNone do throwErrorAt doForDecl[0] "the proof annotation here has not been implemented yet" let y := doForDecl[1] let ys := doForDecl[3] let doForDecls := doForDecls.eraseIdx 1 let body := doFor[3] withFreshMacroScope do /- Recall that `@` (explicit) disables `coeAtOutParam`. We used `@` at `Stream` functions to make sure `resultIsOutParamSupport` is not used. -/ let toStreamApp ← withRef ys `(@toStream _ _ _ $ys) let auxDo ← `(do let mut s := $toStreamApp:term for $doForDecls:doForDecl,* do match @Stream.next? _ _ _ s with | none => break | some ($y, s') => s := s' do $body) doSeqToCode (getDoSeqElems (getDoSeq auxDo) ++ doElems) else withRef doFor do let h? := if doForDecls[0]![0].isNone then none else some doForDecls[0]![0][0] let x := doForDecls[0]![1] withRef x <| checkNotShadowingMutable (← getPatternVarsEx x) let xs := doForDecls[0]![3] let forElems := getDoSeqElems doFor[3] let forInBodyCodeBlock ← withFor (doSeqToCode forElems) let ⟨uvars, forInBody⟩ ← mkForInBody x forInBodyCodeBlock let ctx ← read -- semantic no-op that replaces the `uvars`' position information (which all point inside the loop) -- with that of the respective mutable declarations outside the loop, which allows the language -- server to identify them as conceptually identical variables let uvars := uvars.map fun v => ctx.mutableVars.getD v.getId v let uvarsTuple ← liftMacroM do mkTuple uvars if hasReturn forInBodyCodeBlock.code then let forInBody ← liftMacroM <| destructTuple uvars (← `(r)) forInBody let optType ← `(Option $((← read).returnType)) let forInTerm ← if let some h := h? then annotate doFor (← `(for_in'% $(xs) (MProd.mk (none : $optType) $uvarsTuple) fun $x $h (r : MProd $optType _) => let r := r.2; $forInBody)) else annotate doFor (← `(for_in% $(xs) (MProd.mk (none : $optType) $uvarsTuple) fun $x (r : MProd $optType _) => let r := r.2; $forInBody)) let auxDo ← `(do let r ← $forInTerm:term; $uvarsTuple:term := r.2; match r.1 with | none => Pure.pure (ensure_expected_type% "type mismatch, `for`" PUnit.unit) | some a => return ensure_expected_type% "type mismatch, `for`" a) doSeqToCode (getDoSeqElems (getDoSeq auxDo) ++ doElems) else let forInBody ← liftMacroM <| destructTuple uvars (← `(r)) forInBody let forInTerm ← if let some h := h? then annotate doFor (← `(for_in'% $(xs) $uvarsTuple fun $x $h r => $forInBody)) else annotate doFor (← `(for_in% $(xs) $uvarsTuple fun $x r => $forInBody)) if doElems.isEmpty then let auxDo ← `(do let r ← $forInTerm:term; $uvarsTuple:term := r; Pure.pure (ensure_expected_type% "type mismatch, `for`" PUnit.unit)) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) else let auxDo ← `(do let r ← $forInTerm:term; $uvarsTuple:term := r) doSeqToCode <| getDoSeqElems (getDoSeq auxDo) ++ doElems /-- Generate `CodeBlock` for `doMatch; doElems` -/ partial def doMatchToCode (doMatch : Syntax) (doElems: List Syntax) : M CodeBlock := do let ref := doMatch let genParam := doMatch[1] let optMotive := doMatch[2] let discrs := doMatch[3] let matchAlts := doMatch[5][0].getArgs -- Array of `doMatchAlt` let matchAlts ← matchAlts.foldlM (init := #[]) fun result matchAlt => return result ++ (← liftMacroM <| expandMatchAlt matchAlt) let alts ← matchAlts.mapM fun matchAlt => do let patterns := matchAlt[1][0] let vars ← getPatternsVarsEx patterns.getSepArgs withRef patterns <| checkNotShadowingMutable vars let rhs := matchAlt[3] let rhs ← doSeqToCode (getDoSeqElems rhs) pure { ref := matchAlt, vars := vars, patterns := patterns, rhs := rhs : Alt CodeBlock } let matchCode ← mkMatch ref genParam discrs optMotive alts concatWith matchCode doElems /-- Generate `CodeBlock` for `doMatchExpr; doElems` -/ partial def doMatchExprToCode (doMatchExpr : Syntax) (doElems: List Syntax) : M CodeBlock := do let ref := doMatchExpr let «meta» := doMatchExpr[1].isNone let discr := doMatchExpr[2] let alts := doMatchExpr[4][0].getArgs -- Array of `doMatchExprAlt` let alts ← alts.mapM fun alt => do let pat := alt[1] let var? := if pat[0].isNone then none else some pat[0][0] let funName := pat[1] let pvars := pat[2].getArgs let rhs := alt[3] let rhs ← doSeqToCode (getDoSeqElems rhs) pure { ref, var?, funName, pvars, rhs } let elseBranch ← doSeqToCode (getDoSeqElems doMatchExpr[4][1][3]) let matchCode ← mkMatchExpr ref «meta» discr alts elseBranch concatWith matchCode doElems /-- Generate `CodeBlock` for `doTry; doElems` ``` def doTry := leading_parser "try " >> doSeq >> many (doCatch <|> doCatchMatch) >> optional doFinally def doCatch := leading_parser "catch " >> binderIdent >> optional (":" >> termParser) >> darrow >> doSeq def doCatchMatch := leading_parser "catch " >> doMatchAlts def doFinally := leading_parser "finally " >> doSeq ``` -/ partial def doTryToCode (doTry : Syntax) (doElems: List Syntax) : M CodeBlock := do let tryCode ← doSeqToCode (getDoSeqElems doTry[1]) let optFinally := doTry[3] let catches ← doTry[2].getArgs.mapM fun catchStx : Syntax => do if catchStx.getKind == ``Parser.Term.doCatch then let x := catchStx[1] if x.isIdent then withRef x <| checkNotShadowingMutable #[x] let optType := catchStx[2] let c ← doSeqToCode (getDoSeqElems catchStx[4]) return { x := x, optType := optType, codeBlock := c : Catch } else if catchStx.getKind == ``Parser.Term.doCatchMatch then let matchAlts := catchStx[1] let x ← `(ex) let auxDo ← `(do match ex with $matchAlts) let c ← doSeqToCode (getDoSeqElems (getDoSeq auxDo)) return { x := x, codeBlock := c, optType := mkNullNode : Catch } else throwError "unexpected kind of `catch`" let finallyCode? ← if optFinally.isNone then pure none else some <$> doSeqToCode (getDoSeqElems optFinally[0][1]) if catches.isEmpty && finallyCode?.isNone then throwError "invalid `try`, it must have a `catch` or `finally`" let ctx ← read let ws := getTryCatchUpdatedVars tryCode catches finallyCode? let uvars := varSetToArray ws let a := tryCatchPred tryCode catches finallyCode? hasTerminalAction let r := tryCatchPred tryCode catches finallyCode? hasReturn let bc := tryCatchPred tryCode catches finallyCode? hasBreakContinue let toTerm (codeBlock : CodeBlock) : M Syntax := do let codeBlock ← liftM $ extendUpdatedVars codeBlock ws liftMacroM <| ToTerm.mkNestedTerm codeBlock.code ctx.m ctx.returnType uvars a r bc let term ← toTerm tryCode let term ← catches.foldlM (init := term) fun term «catch» => do let catchTerm ← toTerm «catch».codeBlock if catch.optType.isNone then annotate doTry (← ``(MonadExcept.tryCatch $term (fun $(«catch».x):ident => $catchTerm))) else let type := «catch».optType[1] annotate doTry (← ``(tryCatchThe $type $term (fun $(«catch».x):ident => $catchTerm))) let term ← match finallyCode? with | none => pure term | some finallyCode => withRef optFinally do unless finallyCode.uvars.isEmpty do throwError "`finally` currently does not support reassignments" if hasBreakContinueReturn finallyCode.code then throwError "`finally` currently does `return`, `break`, nor `continue`" let finallyTerm ← liftMacroM <| ToTerm.run finallyCode.code ctx.m ctx.returnType {} ToTerm.Kind.regular annotate doTry (← ``(tryFinally $term $finallyTerm)) let doElemsNew ← liftMacroM <| ToTerm.matchNestedTermResult term uvars a r bc doSeqToCode (doElemsNew ++ doElems) partial def doSeqToCode : List Syntax → M CodeBlock | [] => do liftMacroM mkPureUnitAction | doElem::doElems => withIncRecDepth <| withRef doElem do checkSystem "`do`-expander" match (← liftMacroM <| expandMacro? doElem) with | some doElem => doSeqToCode (doElem::doElems) | none => match (← liftMacroM <| expandDoIf? doElem) with | some doElem => doSeqToCode (doElem::doElems) | none => match (← liftMacroM <| expandDoLetExpr? doElem doElems) with | some doElem => doSeqToCode [doElem] | none => let (liftedDoElems, doElem) ← expandLiftMethod doElem if !liftedDoElems.isEmpty then doSeqToCode (liftedDoElems ++ [doElem] ++ doElems) else let ref := doElem let k := doElem.getKind if k == ``Parser.Term.doLet then let vars ← getDoLetVars doElem checkNotShadowingMutable vars mkVarDeclCore vars doElem <$> withNewMutableVars vars (isMutableLet doElem) (doSeqToCode doElems) else if k == ``Parser.Term.doHave then let vars ← getDoHaveVars doElem checkNotShadowingMutable vars mkVarDeclCore vars doElem <$> (doSeqToCode doElems) else if k == ``Parser.Term.doLetRec then let vars ← getDoLetRecVars doElem checkNotShadowingMutable vars mkVarDeclCore vars doElem <$> (doSeqToCode doElems) else if k == ``Parser.Term.doReassign then let vars ← getDoReassignVars doElem checkReassignable vars let k ← doSeqToCode doElems mkReassignCore vars doElem k else if k == ``Parser.Term.doLetArrow then doLetArrowToCode doElem doElems else if k == ``Parser.Term.doLetElse then doLetElseToCode doElem doElems else if k == ``Parser.Term.doReassignArrow then doReassignArrowToCode doElem doElems else if k == ``Parser.Term.doIf then doIfToCode doElem doElems else if k == ``Parser.Term.doUnless then doUnlessToCode doElem doElems else if k == ``Parser.Term.doFor then withFreshMacroScope do doForToCode doElem doElems else if k == ``Parser.Term.doMatch then doMatchToCode doElem doElems else if k == ``Parser.Term.doMatchExpr then doMatchExprToCode doElem doElems else if k == ``Parser.Term.doTry then doTryToCode doElem doElems else if k == ``Parser.Term.doBreak then ensureInsideFor ensureEOS doElems return mkBreak ref else if k == ``Parser.Term.doContinue then ensureInsideFor ensureEOS doElems return mkContinue ref else if k == ``Parser.Term.doReturn then doReturnToCode doElem doElems else if k == ``Parser.Term.doDbgTrace then return mkSeq doElem (← doSeqToCode doElems) else if k == ``Parser.Term.doAssert then return mkSeq doElem (← doSeqToCode doElems) else if k == ``Parser.Term.doDebugAssert then return mkSeq doElem (← doSeqToCode doElems) else if k == ``Parser.Term.doNested then let nestedDoSeq := doElem[1] doSeqToCode (getDoSeqElems nestedDoSeq ++ doElems) else if k == ``Parser.Term.doExpr then let term := doElem[0] if doElems.isEmpty then return mkTerminalAction term else return mkSeq term (← doSeqToCode doElems) else throwError "unexpected do-element of kind {doElem.getKind}:\n{doElem}" end def run (doStx : Syntax) (m : Syntax) (returnType : Syntax) : TermElabM CodeBlock := (doSeqToCode <| getDoSeqElems <| getDoSeq doStx).run { ref := doStx, m, returnType } end ToCodeBlock @[builtin_term_elab «do»] def elabDo : TermElab := fun stx expectedType? => do tryPostponeIfNoneOrMVar expectedType? let bindInfo ← extractBind expectedType? let m ← Term.exprToSyntax bindInfo.m let returnType ← Term.exprToSyntax bindInfo.returnType let codeBlock ← ToCodeBlock.run stx m returnType let stxNew ← liftMacroM <| ToTerm.run codeBlock.code m returnType trace[Elab.do] stxNew withMacroExpansion stx stxNew <| elabTermEnsuringType stxNew bindInfo.expectedType end Do builtin_initialize registerTraceClass `Elab.do private def toDoElem (newKind : SyntaxNodeKind) : Macro := fun stx => do let stx := stx.setKind newKind withRef stx `(do $stx:doElem) @[builtin_macro Lean.Parser.Term.termFor] def expandTermFor : Macro := toDoElem ``Parser.Term.doFor @[builtin_macro Lean.Parser.Term.termTry] def expandTermTry : Macro := toDoElem ``Parser.Term.doTry @[builtin_macro Lean.Parser.Term.termUnless] def expandTermUnless : Macro := toDoElem ``Parser.Term.doUnless @[builtin_macro Lean.Parser.Term.termReturn] def expandTermReturn : Macro := toDoElem ``Parser.Term.doReturn end Lean.Elab.Term