Pantograph/Pantograph.lean

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import Pantograph.Commands
import Pantograph.Serial
import Pantograph.Symbols
import Pantograph.Tactic
import Pantograph.SemihashMap
namespace Pantograph
structure Context where
imports: List String
/-- Stores state of the REPL -/
structure State where
options: Commands.Options := {}
goalStates: SemihashMap GoalState := SemihashMap.empty
-- State monad
abbrev MainM := ReaderT Context (StateT State Lean.Elab.TermElabM)
-- For some reason writing `CommandM α := MainM (Except ... α)` disables certain
-- monadic features in `MainM`
abbrev CR α := Except Commands.InteractionError α
def execute (command: Commands.Command): MainM Lean.Json := do
let run { α β: Type } [Lean.FromJson α] [Lean.ToJson β] (comm: α → MainM (CR β)): MainM Lean.Json :=
match Lean.fromJson? command.payload with
| .ok args => do
match (← comm args) with
| .ok result => return Lean.toJson result
| .error ierror => return Lean.toJson ierror
| .error error => return Lean.toJson $ errorCommand s!"Unable to parse json: {error}"
match command.cmd with
| "reset" => run reset
| "expr.echo" => run expr_echo
| "lib.catalog" => run lib_catalog
| "lib.inspect" => run lib_inspect
| "options.set" => run options_set
| "options.print" => run options_print
| "proof.start" => run proof_start
| "proof.tactic" => run proof_tactic
| "proof.printTree" => run proof_print_tree
| cmd =>
let error: Commands.InteractionError :=
errorCommand s!"Unknown command {cmd}"
return Lean.toJson error
where
errorI (type desc: String): Commands.InteractionError := { error := type, desc := desc }
errorCommand := errorI "command"
errorIndex := errorI "index"
-- Command Functions
reset (_: Commands.Reset): MainM (CR Commands.ResetResult) := do
let state ← get
let nStates := state.goalStates.size
set { state with goalStates := SemihashMap.empty }
return .ok { nStates := nStates }
lib_catalog (_: Commands.LibCatalog): MainM (CR Commands.LibCatalogResult) := do
let env ← Lean.MonadEnv.getEnv
let names := env.constants.fold (init := #[]) (λ acc name info =>
match to_filtered_symbol name info with
| .some x => acc.push x
| .none => acc)
return .ok { symbols := names }
lib_inspect (args: Commands.LibInspect): MainM (CR Commands.LibInspectResult) := do
let state ← get
let env ← Lean.MonadEnv.getEnv
let name := str_to_name args.name
let info? := env.find? name
match info? with
| none => return .error $ errorIndex s!"Symbol not found {args.name}"
| some info =>
let module? := env.getModuleIdxFor? name >>=
(λ idx => env.allImportedModuleNames.get? idx.toNat) |>.map toString
let value? := match args.value?, info with
| .some true, _ => info.value?
| .some false, _ => .none
| .none, .defnInfo _ => info.value?
| .none, _ => .none
return .ok {
type := ← serialize_expression state.options info.type,
value? := ← value?.mapM (λ v => serialize_expression state.options v),
module? := module?
}
expr_echo (args: Commands.ExprEcho): MainM (CR Commands.ExprEchoResult) := do
let state ← get
let env ← Lean.MonadEnv.getEnv
match syntax_from_str env args.expr with
| .error str => return .error $ errorI "parsing" str
| .ok syn => do
match (← syntax_to_expr syn) with
| .error str => return .error $ errorI "elab" str
| .ok expr => do
try
let type ← Lean.Meta.inferType expr
return .ok {
type := (← serialize_expression (options := state.options) type),
expr := (← serialize_expression (options := state.options) expr)
}
catch exception =>
return .error $ errorI "typing" (← exception.toMessageData.toString)
options_set (args: Commands.OptionsSet): MainM (CR Commands.OptionsSetResult) := do
let state ← get
let options := state.options
set { state with
options := {
-- FIXME: This should be replaced with something more elegant
printJsonPretty := args.printJsonPretty?.getD options.printJsonPretty,
printExprPretty := args.printExprPretty?.getD options.printExprPretty,
printExprAST := args.printExprAST?.getD options.printExprAST,
proofVariableDelta := args.proofVariableDelta?.getD options.proofVariableDelta,
printAuxDecls := args.printAuxDecls?.getD options.printAuxDecls,
printImplementationDetailHyps := args.printImplementationDetailHyps?.getD options.printImplementationDetailHyps
}
}
return .ok { }
options_print (_: Commands.OptionsPrint): MainM (CR Commands.OptionsPrintResult) := do
return .ok (← get).options
proof_start (args: Commands.ProofStart): MainM (CR Commands.ProofStartResult) := do
let state ← get
let env ← Lean.MonadEnv.getEnv
let expr?: Except _ Lean.Expr ← (match args.expr, args.copyFrom with
| .some expr, .none =>
(match syntax_from_str env expr with
| .error str => return .error <| errorI "parsing" str
| .ok syn => do
(match (← syntax_to_expr syn) with
| .error str => return .error <| errorI "elab" str
| .ok expr => return .ok expr))
| .none, .some copyFrom =>
(match env.find? <| str_to_name copyFrom with
| .none => return .error <| errorIndex s!"Symbol not found: {copyFrom}"
| .some cInfo => return .ok cInfo.type)
| .none, .none =>
return .error <| errorI "arguments" "At least one of {expr, copyFrom} must be supplied"
| _, _ => return .error <| errorI "arguments" "Cannot populate both of {expr, copyFrom}")
match expr? with
| .error error => return .error error
| .ok expr =>
let goalState ← GoalState.create expr
let (goalStates, goalId) := state.goalStates.insert goalState
set { state with goalStates }
return .ok { goalId }
proof_tactic (args: Commands.ProofTactic): MainM (CR Commands.ProofTacticResult) := do
let state ← get
match state.goalStates.get? args.goalId with
| .none => return .error $ errorIndex "Invalid goal index {args.goalId}"
| .some goalState =>
let result ← GoalState.execute goalState args.tactic |>.run state.options
match result with
| .success goals =>
if goals.isEmpty then
return .ok {}
else
-- Append all goals
let (goalStates, goalIds, sGoals) := Array.foldl (λ acc itr =>
let (map, indices, serializedGoals) := acc
let (goalState, sGoal) := itr
let (map, index) := map.insert goalState
(map, index :: indices, sGoal :: serializedGoals)
) (state.goalStates, [], []) goals
set { state with goalStates }
return .ok { goals? := .some sGoals.reverse.toArray, goalIds? := .some goalIds.reverse.toArray }
| .failure messages =>
return .ok { tacticErrors? := .some messages }
proof_print_tree (_: Commands.ProofPrintTree): MainM (CR Commands.ProofPrintTreeResult) := do
let state ← get
return .ok { nGoals := state.goalStates.size }
end Pantograph