{-# OPTIONS_GHC -fwarn-missing-signatures #-} module Agda.Syntax.Translation.ReflectedToAbstract where import Control.Arrow ( (***) ) import Control.Monad ( foldM ) import Control.Monad.Except ( MonadError ) import Control.Monad.Reader ( MonadReader(..), asks, reader, runReaderT ) import Data.Maybe import Data.Set (Set) import qualified Data.Set as Set import Data.Text (Text) import qualified Data.Text as Text import Agda.Syntax.Literal import Agda.Syntax.Position import Agda.Syntax.Info import Agda.Syntax.Common import Agda.Syntax.Abstract ( Name, QName, QNamed(QNamed) , isNoName, nameConcrete, nextName, qualify, unambiguous ) import qualified Agda.Syntax.Abstract as A import Agda.Syntax.Abstract.Pattern import Agda.Syntax.Reflected as R import Agda.Syntax.Internal (Dom,Dom'(..)) import Agda.Interaction.Options (optUseUnicode, UnicodeOrAscii(..)) import Agda.TypeChecking.Monad as M hiding (MetaInfo) import Agda.Syntax.Scope.Monad (getCurrentModule) import Agda.Utils.Impossible import Agda.Utils.Maybe import Agda.Utils.Monad import Agda.Utils.List import Agda.Utils.List1 (List1, pattern (:|)) import qualified Agda.Utils.List1 as List1 import Agda.Utils.Null import Agda.Syntax.Common.Pretty import Agda.Utils.Functor import Agda.Utils.Singleton import Agda.Utils.Size type Vars = [(Name,R.Type)] type MonadReflectedToAbstract m = ( MonadReader Vars m , MonadFresh NameId m , MonadError TCErr m , MonadTCEnv m , ReadTCState m , HasOptions m , HasBuiltins m , HasConstInfo m ) -- | Adds a new unique name to the current context. -- NOTE: See @chooseName@ in @Agda.Syntax.Translation.AbstractToConcrete@ for similar logic. -- NOTE: See @freshConcreteName@ in @Agda.Syntax.Scope.Monad@ also for similar logic. withName :: MonadReflectedToAbstract m => String -> (Name -> m a) -> m a withName s = withVar s R.Unknown withVar :: MonadReflectedToAbstract m => String -> R.Type -> (Name -> m a) -> m a withVar s t f = do name <- freshName_ s ctx <- asks $ map $ nameConcrete . fst glyphMode <- optUseUnicode <$> M.pragmaOptions let freshNameMode = case glyphMode of UnicodeOk -> A.UnicodeSubscript AsciiOnly -> A.AsciiCounter let name' = headWithDefault __IMPOSSIBLE__ $ filter (notTaken ctx) $ iterate (nextName freshNameMode) name local ((name,t):) $ f name' where notTaken xs x = isNoName x || nameConcrete x `notElem` xs withNames :: MonadReflectedToAbstract m => [String] -> ([Name] -> m a) -> m a withNames ss = withVars $ zip ss $ repeat R.Unknown withVars :: MonadReflectedToAbstract m => [(String, R.Type)] -> ([Name] -> m a) -> m a withVars ss f = case ss of [] -> f [] ((s,t):ss) -> withVar s t $ \n -> withVars ss $ \ns -> f (n:ns) -- | Returns the name and type of the variable with the given de Bruijn index. askVar :: MonadReflectedToAbstract m => Int -> m (Maybe (Name,R.Type)) askVar i = reader (!!! i) askName :: MonadReflectedToAbstract m => Int -> m (Maybe Name) askName i = fmap fst <$> askVar i class ToAbstract r where type AbsOfRef r toAbstract :: MonadReflectedToAbstract m => r -> m (AbsOfRef r) default toAbstract :: (Traversable t, ToAbstract s, t s ~ r, t (AbsOfRef s) ~ (AbsOfRef r)) => MonadReflectedToAbstract m => r -> m (AbsOfRef r) toAbstract = traverse toAbstract -- | Translate reflected syntax to abstract, using the names from the current typechecking context. toAbstract_ :: (ToAbstract r , MonadFresh NameId m , MonadError TCErr m , MonadTCEnv m , ReadTCState m , HasOptions m , HasBuiltins m , HasConstInfo m ) => r -> m (AbsOfRef r) toAbstract_ = withShowAllArguments . toAbstractWithoutImplicit -- | Drop implicit arguments unless --show-implicit is on. toAbstractWithoutImplicit :: (ToAbstract r , MonadFresh NameId m , MonadError TCErr m , MonadTCEnv m , ReadTCState m , HasOptions m , HasBuiltins m , HasConstInfo m ) => r -> m (AbsOfRef r) toAbstractWithoutImplicit x = do xs <- killRange <$> getContextNames let ctx = zip xs $ repeat R.Unknown runReaderT (toAbstract x) ctx instance ToAbstract r => ToAbstract (Named name r) where type AbsOfRef (Named name r) = Named name (AbsOfRef r) instance ToAbstract r => ToAbstract (Arg r) where type AbsOfRef (Arg r) = NamedArg (AbsOfRef r) toAbstract (Arg i x) = Arg i <$> toAbstract (unnamed x) instance ToAbstract r => ToAbstract [Arg r] where type AbsOfRef [Arg r] = [NamedArg (AbsOfRef r)] -- instance ToAbstract r A.Expr => ToAbstract (Dom r, Name) (A.TypedBinding) where instance (ToAbstract r, AbsOfRef r ~ A.Expr) => ToAbstract (Dom r, Name) where type AbsOfRef (Dom r, Name) = A.TypedBinding toAbstract (Dom{domInfo = i, domIsFinite = isfin, unDom = x, domTactic = tac}, name) = do dom <- toAbstract x -- TODO(Amy): Anyone know why this discards the tactic? It was like -- that when I got here! return $ A.TBind noRange (A.TypedBindingInfo empty isfin) (singleton $ unnamedArg i $ A.mkBinder_ name) dom instance ToAbstract (A.Expr, Elim) where type AbsOfRef (A.Expr, Elim) = A.Expr toAbstract (f, Apply arg) = do arg <- toAbstract arg showImp <- showImplicitArguments return $ if showImp || visible arg then A.App (setOrigin Reflected defaultAppInfo_) f arg else f instance ToAbstract (A.Expr, Elims) where type AbsOfRef (A.Expr, Elims) = A.Expr toAbstract (f, elims) = foldM (curry toAbstract) f elims instance ToAbstract r => ToAbstract (R.Abs r) where type AbsOfRef (R.Abs r) = (AbsOfRef r, Name) toAbstract (Abs s x) = withName s' $ \name -> (,name) <$> toAbstract x where s' = if (isNoName s) then "z" else s -- TODO: only do this when var is free instance ToAbstract Literal where type AbsOfRef Literal = A.Expr toAbstract l = return $ A.Lit empty l instance ToAbstract Term where type AbsOfRef Term = A.Expr toAbstract = \case R.Var i es -> do name <- mkVarName i toAbstract (A.Var name, es) R.Con c es -> toAbstract (A.Con (unambiguous $ killRange c), es) R.Def f es -> do af <- mkDef (killRange f) toAbstract (af, es) R.Lam h t -> do (e, name) <- toAbstract t let info = setHiding h $ setOrigin Reflected defaultArgInfo return $ A.Lam exprNoRange (A.mkDomainFree $ unnamedArg info $ A.mkBinder_ name) e R.ExtLam cs es -> do name <- freshName_ extendedLambdaName m <- getCurrentModule let qname = qualify m name cname = nameConcrete name defInfo = mkDefInfo cname noFixity' PublicAccess ConcreteDef noRange cs <- toAbstract $ fmap (QNamed qname) cs toAbstract (A.ExtendedLam exprNoRange defInfo defaultErased qname cs, es) R.Pi a b -> do (b, name) <- toAbstract b a <- toAbstract (a, name) return $ A.Pi exprNoRange (singleton a) b R.Sort s -> toAbstract s R.Lit l -> toAbstract l R.Meta x es -> do info <- mkMetaInfo let info' = info{ metaNumber = Just x } toAbstract (A.Underscore info', es) R.Unknown -> A.Underscore <$> mkMetaInfo mkMetaInfo :: ReadTCState m => m MetaInfo mkMetaInfo = do scope <- getScope return $ emptyMetaInfo { metaScope = scope } mkDef :: HasConstInfo m => QName -> m A.Expr mkDef f = getConstInfo f <&> theDef <&> \case Constructor{} -> A.Con $ unambiguous f Function{ funProjection = Right Projection{ projProper = Just{} } } -> A.Proj ProjSystem $ unambiguous f d@Function{} | isMacro d -> A.Macro f _ -> A.Def f mkApp :: A.Expr -> A.Expr -> A.Expr mkApp e1 e2 = A.App (setOrigin Reflected defaultAppInfo_) e1 $ defaultNamedArg e2 mkVar :: MonadReflectedToAbstract m => Int -> m (Name, R.Type) mkVar i = ifJustM (askVar i) return $ do cxt <- getContextTelescope names <- asks $ drop (size cxt) . reverse . map fst withShowAllArguments' False $ typeError $ DeBruijnIndexOutOfScope i cxt names mkVarName :: MonadReflectedToAbstract m => Int -> m Name mkVarName i = fst <$> mkVar i annotatePattern :: MonadReflectedToAbstract m => Int -> R.Type -> A.Pattern -> m A.Pattern annotatePattern _ R.Unknown p = return p annotatePattern i t p = local (drop $ i + 1) $ do t <- toAbstract t -- go into the right context for translating the type return $ A.AnnP patNoRange t p instance ToAbstract Sort where type AbsOfRef Sort = A.Expr toAbstract s = do setName <- fromMaybe __IMPOSSIBLE__ <$> getBuiltinName' builtinSet propName <- fromMaybe __IMPOSSIBLE__ <$> getBuiltinName' builtinProp infName <- fromMaybe __IMPOSSIBLE__ <$> getBuiltinName' builtinSetOmega case s of SetS x -> mkApp (A.Def setName) <$> toAbstract x LitS x -> return $ A.Def' setName $ A.Suffix x PropS x -> mkApp (A.Def propName) <$> toAbstract x PropLitS x -> return $ A.Def' propName $ A.Suffix x InfS x -> return $ A.Def' infName $ A.Suffix x UnknownS -> mkApp (A.Def setName) . A.Underscore <$> mkMetaInfo instance ToAbstract R.Pattern where type AbsOfRef R.Pattern = A.Pattern toAbstract pat = case pat of R.ConP c args -> do args <- toAbstract args return $ A.ConP (ConPatInfo ConOCon patNoRange ConPatEager) (unambiguous $ killRange c) args R.DotP t -> A.DotP patNoRange <$> toAbstract t R.VarP i -> do (x, t) <- mkVar i annotatePattern i t $ A.VarP $ A.mkBindName x R.LitP l -> return $ A.LitP patNoRange l R.AbsurdP i -> do (_, t) <- mkVar i annotatePattern i t $ A.AbsurdP patNoRange R.ProjP d -> return $ A.ProjP patNoRange ProjSystem $ unambiguous $ killRange d instance ToAbstract (QNamed R.Clause) where type AbsOfRef (QNamed R.Clause) = A.Clause toAbstract (QNamed name (R.Clause tel pats rhs)) = withVars (map (Text.unpack *** unArg) tel) $ \_ -> do checkClauseTelescopeBindings tel pats pats <- toAbstract pats rhs <- toAbstract rhs let lhs = spineToLhs $ A.SpineLHS empty name pats return $ A.Clause lhs [] (A.RHS rhs Nothing) A.noWhereDecls False toAbstract (QNamed name (R.AbsurdClause tel pats)) = withVars (map (Text.unpack *** unArg) tel) $ \_ -> do checkClauseTelescopeBindings tel pats pats <- toAbstract pats let lhs = spineToLhs $ A.SpineLHS empty name pats return $ A.Clause lhs [] A.AbsurdRHS A.noWhereDecls False instance ToAbstract [QNamed R.Clause] where type AbsOfRef [QNamed R.Clause] = [A.Clause] toAbstract = traverse toAbstract instance ToAbstract (List1 (QNamed R.Clause)) where type AbsOfRef (List1 (QNamed R.Clause)) = List1 A.Clause toAbstract = traverse toAbstract -- | Check that all variables in the telescope are bound in the left-hand side. Since we check the -- telescope by attaching type annotations to the pattern variables there needs to be somewhere to -- put the annotation. Also, since the lhs is where the variables are actually bound, missing a -- binding for a variable that's used later in the telescope causes unbound variable panic -- (see #5044). checkClauseTelescopeBindings :: MonadReflectedToAbstract m => [(Text, Arg R.Type)] -> [Arg R.Pattern] -> m () checkClauseTelescopeBindings tel pats = case reverse [ x | ((x, _), i) <- zip (reverse tel) [0..], not $ Set.member i bs ] of [] -> return () xs -> genericDocError $ (singPlural xs id (<> "s") "Missing bindings for telescope variable") (fsep (punctuate ", " $ map (text . Text.unpack) xs) <> ".") $$ "All variables in the clause telescope must be bound in the left-hand side." where bs = boundVars pats boundVars = Set.unions . map (bound . unArg) bound (R.VarP i) = Set.singleton i bound (R.ConP _ ps) = boundVars ps bound R.DotP{} = Set.empty bound R.LitP{} = Set.empty bound (R.AbsurdP i) = Set.singleton i bound R.ProjP{} = Set.empty