{-# LANGUAGE CPP #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE ScopedTypeVariables #-} -- | Preprocess 'Agda.Syntax.Concrete.Declaration's, producing 'NiceDeclaration's. -- -- * Attach fixity and syntax declarations to the definition they refer to. -- -- * Distribute the following attributes to the individual definitions: -- @abstract@, -- @instance@, -- @postulate@, -- @primitive@, -- @private@, -- termination pragmas. -- -- * Gather the function clauses belonging to one function definition. -- -- * Expand ellipsis @...@ in function clauses following @with@. -- -- * Infer mutual blocks. -- A block starts when a lone signature is encountered, and ends when -- all lone signatures have seen their definition. -- -- * Report basic well-formedness error, -- when one of the above transformation fails. module Agda.Syntax.Concrete.Definitions ( NiceDeclaration(..) , NiceConstructor, NiceTypeSignature , Clause(..) , DeclarationException(..) , Nice, runNice , niceDeclarations , notSoNiceDeclarations , niceHasAbstract , Measure ) where import Prelude hiding (null) import Control.Arrow ((***)) import Control.Applicative hiding (empty) import Control.Monad.State #if __GLASGOW_HASKELL__ <= 708 import Data.Foldable ( foldMap ) #endif import qualified Data.Map as Map import Data.Map (Map) import Data.Maybe import Data.Semigroup ( Semigroup, Monoid, (<>), mempty, mappend ) import Data.List as List hiding (null) import qualified Data.Set as Set import Data.Traversable (Traversable, traverse) import Data.Typeable (Typeable) import Agda.Syntax.Concrete import Agda.Syntax.Common hiding (TerminationCheck()) import qualified Agda.Syntax.Common as Common import Agda.Syntax.Position import Agda.Syntax.Fixity import Agda.Syntax.Notation import Agda.Syntax.Concrete.Pretty () import Agda.TypeChecking.Positivity.Occurrence import Agda.Utils.Except ( Error(strMsg), MonadError(throwError) ) import Agda.Utils.Functor import Agda.Utils.Lens import Agda.Utils.List (caseList, headMaybe, isSublistOf) import Agda.Utils.Monad import Agda.Utils.Null import qualified Agda.Utils.Pretty as Pretty import Agda.Utils.Pretty hiding ((<>)) import Agda.Utils.Singleton import Agda.Utils.Tuple import Agda.Utils.Update #include "undefined.h" import Agda.Utils.Impossible {-------------------------------------------------------------------------- Types --------------------------------------------------------------------------} {-| The nice declarations. No fixity declarations and function definitions are contained in a single constructor instead of spread out between type signatures and clauses. The @private@, @postulate@, @abstract@ and @instance@ modifiers have been distributed to the individual declarations. Observe the order of components: Range Fixity' Access IsAbstract IsInstance TerminationCheck PositivityCheck further attributes (Q)Name content (Expr, Declaration ...) -} data NiceDeclaration = Axiom Range Fixity' Access IsAbstract IsInstance ArgInfo (Maybe [Occurrence]) Name Expr -- ^ 'IsAbstract' argument: We record whether a declaration was made in an @abstract@ block. -- -- 'ArgInfo' argument: Axioms and functions can be declared irrelevant. -- ('Hiding' should be 'NotHidden'.) -- -- @Maybe [Occurrence]@ argument: Polarities can be assigned to identifiers. | NiceField Range Fixity' Access IsAbstract IsInstance Name (Arg Expr) | PrimitiveFunction Range Fixity' Access IsAbstract Name Expr | NiceMutual Range TerminationCheck PositivityCheck [NiceDeclaration] | NiceModule Range Access IsAbstract QName Telescope [Declaration] | NiceModuleMacro Range Access Name ModuleApplication OpenShortHand ImportDirective | NiceOpen Range QName ImportDirective | NiceImport Range QName (Maybe AsName) OpenShortHand ImportDirective | NicePragma Range Pragma | NiceRecSig Range Fixity' Access IsAbstract PositivityCheck Name [LamBinding] Expr | NiceDataSig Range Fixity' Access IsAbstract PositivityCheck Name [LamBinding] Expr | NiceFunClause Range Access IsAbstract TerminationCheck Catchall Declaration -- ^ An uncategorized function clause, could be a function clause -- without type signature or a pattern lhs (e.g. for irrefutable let). -- The 'Declaration' is the actual 'FunClause'. | FunSig Range Fixity' Access IsAbstract IsInstance IsMacro ArgInfo TerminationCheck Name Expr | FunDef Range [Declaration] Fixity' IsAbstract TerminationCheck Name [Clause] -- ^ Block of function clauses (we have seen the type signature before). -- The 'Declaration's are the original declarations that were processed -- into this 'FunDef' and are only used in 'notSoNiceDeclaration'. | DataDef Range Fixity' IsAbstract PositivityCheck Name [LamBinding] [NiceConstructor] | RecDef Range Fixity' IsAbstract PositivityCheck Name (Maybe (Ranged Induction)) (Maybe Bool) (Maybe (ThingWithFixity Name, IsInstance)) [LamBinding] [NiceDeclaration] | NicePatternSyn Range Fixity' Name [Arg Name] Pattern | NiceUnquoteDecl Range [Fixity'] Access IsAbstract IsInstance TerminationCheck [Name] Expr | NiceUnquoteDef Range [Fixity'] Access IsAbstract TerminationCheck [Name] Expr deriving (Typeable, Show) type TerminationCheck = Common.TerminationCheck Measure -- | Termination measure is, for now, a variable name. type Measure = Name type Catchall = Bool -- | Only 'Axiom's. type NiceConstructor = NiceTypeSignature -- | Only 'Axiom's. type NiceTypeSignature = NiceDeclaration -- | One clause in a function definition. There is no guarantee that the 'LHS' -- actually declares the 'Name'. We will have to check that later. data Clause = Clause Name Catchall LHS RHS WhereClause [Clause] deriving (Typeable, Show) -- | The exception type. data DeclarationException = MultipleFixityDecls [(Name, [Fixity'])] | MultiplePolarityPragmas [Name] | InvalidName Name | DuplicateDefinition Name | MissingDefinition Name | MissingWithClauses Name | MissingTypeSignature LHS -- Andreas 2012-06-02: currently unused, remove after a while -- Fredrik 2012-09-20: now used, can we keep it? | MissingDataSignature Name | WrongDefinition Name DataRecOrFun DataRecOrFun | WrongParameters Name | NotAllowedInMutual NiceDeclaration | UnknownNamesInFixityDecl [Name] | UnknownNamesInPolarityPragmas [Name] | PolarityPragmasButNotPostulates [Name] | Codata Range | DeclarationPanic String | UselessPrivate Range | UselessAbstract Range | UselessInstance Range | WrongContentBlock KindOfBlock Range | AmbiguousFunClauses LHS [Name] -- ^ in a mutual block, a clause could belong to any of the @[Name]@ type signatures | InvalidTerminationCheckPragma Range | InvalidMeasureMutual Range -- ^ In a mutual block, all or none need a MEASURE pragma. -- Range is of mutual block. | PragmaNoTerminationCheck Range -- ^ Pragma @{-# NO_TERMINATION_CHECK #-}@ has been replaced -- by {-# TERMINATING #-} and {-# NON_TERMINATING #-}. | InvalidCatchallPragma Range | UnquoteDefRequiresSignature [Name] | BadMacroDef NiceDeclaration | InvalidNoPositivityCheckPragma Range deriving (Typeable) -- | Several declarations expect only type signatures as sub-declarations. These are: data KindOfBlock = PostulateBlock -- ^ @postulate@ | PrimitiveBlock -- ^ @primitive@. Ensured by parser. | InstanceBlock -- ^ @instance@. Actually, here all kinds of sub-declarations are allowed a priori. | FieldBlock -- ^ @field@. Ensured by parser. | DataBlock -- ^ @data ... where@. Here we got a bad error message for Agda-2.5 (Issue 1698). deriving (Typeable, Eq, Ord, Show) instance HasRange DeclarationException where getRange (MultipleFixityDecls xs) = getRange (fst $ head xs) getRange (MultiplePolarityPragmas xs) = getRange (head xs) getRange (InvalidName x) = getRange x getRange (DuplicateDefinition x) = getRange x getRange (MissingDefinition x) = getRange x getRange (MissingWithClauses x) = getRange x getRange (MissingTypeSignature x) = getRange x getRange (MissingDataSignature x) = getRange x getRange (WrongDefinition x k k') = getRange x getRange (WrongParameters x) = getRange x getRange (AmbiguousFunClauses lhs xs) = getRange lhs getRange (NotAllowedInMutual x) = getRange x getRange (UnknownNamesInFixityDecl xs) = getRange . head $ xs getRange (UnknownNamesInPolarityPragmas xs) = getRange . head $ xs getRange (PolarityPragmasButNotPostulates xs) = getRange . head $ xs getRange (Codata r) = r getRange (DeclarationPanic _) = noRange getRange (UselessPrivate r) = r getRange (UselessAbstract r) = r getRange (UselessInstance r) = r getRange (WrongContentBlock _ r) = r getRange (InvalidTerminationCheckPragma r) = r getRange (InvalidMeasureMutual r) = r getRange (PragmaNoTerminationCheck r) = r getRange (InvalidCatchallPragma r) = r getRange (UnquoteDefRequiresSignature x) = getRange x getRange (BadMacroDef d) = getRange d getRange (InvalidNoPositivityCheckPragma r) = r instance HasRange NiceDeclaration where getRange (Axiom r _ _ _ _ _ _ _ _) = r getRange (NiceField r _ _ _ _ _ _) = r getRange (NiceMutual r _ _ _) = r getRange (NiceModule r _ _ _ _ _ ) = r getRange (NiceModuleMacro r _ _ _ _ _) = r getRange (NiceOpen r _ _) = r getRange (NiceImport r _ _ _ _) = r getRange (NicePragma r _) = r getRange (PrimitiveFunction r _ _ _ _ _) = r getRange (FunSig r _ _ _ _ _ _ _ _ _) = r getRange (FunDef r _ _ _ _ _ _) = r getRange (DataDef r _ _ _ _ _ _) = r getRange (RecDef r _ _ _ _ _ _ _ _ _) = r getRange (NiceRecSig r _ _ _ _ _ _ _) = r getRange (NiceDataSig r _ _ _ _ _ _ _) = r getRange (NicePatternSyn r _ _ _ _) = r getRange (NiceFunClause r _ _ _ _ _) = r getRange (NiceUnquoteDecl r _ _ _ _ _ _ _) = r getRange (NiceUnquoteDef r _ _ _ _ _ _) = r instance Error DeclarationException where strMsg = DeclarationPanic -- These error messages can (should) be terminated by a dot ".", -- there is no error context printed after them. instance Pretty DeclarationException where pretty (MultipleFixityDecls xs) = sep [ fsep $ pwords "Multiple fixity or syntax declarations for" , vcat $ map f xs ] where f (x, fs) = pretty x Pretty.<> text ": " <+> fsep (map pretty fs) pretty (MultiplePolarityPragmas xs) = fsep $ pwords "Multiple polarity pragmas for" ++ map pretty xs pretty (InvalidName x) = fsep $ pwords "Invalid name:" ++ [pretty x] pretty (DuplicateDefinition x) = fsep $ pwords "Duplicate definition of" ++ [pretty x] pretty (MissingDefinition x) = fsep $ pwords "Missing definition for" ++ [pretty x] pretty (MissingWithClauses x) = fsep $ pwords "Missing with-clauses for function" ++ [pretty x] pretty (MissingTypeSignature x) = fsep $ pwords "Missing type signature for left hand side" ++ [pretty x] pretty (MissingDataSignature x) = fsep $ pwords "Missing type signature for " ++ [pretty x] pretty (WrongDefinition x k k') = fsep $ pretty x : pwords ("has been declared as a " ++ show k ++ ", but is being defined as a " ++ show k') pretty (WrongParameters x) = fsep $ pwords "List of parameters does not match previous signature for" ++ [pretty x] pretty (AmbiguousFunClauses lhs xs) = sep [ fsep $ pwords "More than one matching type signature for left hand side " ++ [pretty lhs] ++ pwords "it could belong to any of:" , vcat $ map (pretty . PrintRange) xs ] pretty (UnknownNamesInFixityDecl xs) = fsep $ pwords "The following names are not declared in the same scope as their syntax or fixity declaration (i.e., either not in scope at all, imported from another module, or declared in a super module):" ++ map pretty xs pretty (UnknownNamesInPolarityPragmas xs) = fsep $ pwords "The following names are not declared in the same scope as their polarity pragmas (they could for instance be out of scope, imported from another module, or declared in a super module):" ++ map pretty xs pretty (PolarityPragmasButNotPostulates xs) = fsep $ pwords "Polarity pragmas have been given for the following identifiers which are not postulates:" ++ map pretty xs pretty (UselessPrivate _) = fsep $ pwords "Using private here has no effect. Private applies only to declarations that introduce new identifiers into the module, like type signatures and data, record, and module declarations." pretty (UselessAbstract _) = fsep $ pwords "Using abstract here has no effect. Abstract applies only definitions like data definitions, record type definitions and function clauses." pretty (UselessInstance _) = fsep $ pwords "Using instance here has no effect. Instance applies only to declarations that introduce new identifiers into the module, like type signatures and axioms." pretty (WrongContentBlock b _) = fsep . pwords $ case b of PostulateBlock -> "A postulate block can only contain type signatures, possibly under keyword instance" DataBlock -> "A data definition can only contain type signatures, possibly under keyword instance" _ -> __IMPOSSIBLE__ pretty (PragmaNoTerminationCheck _) = fsep $ pwords "Pragma {-# NO_TERMINATION_CHECK #-} has been removed. To skip the termination check, label your definitions either as {-# TERMINATING #-} or {-# NON_TERMINATING #-}." pretty (InvalidTerminationCheckPragma _) = fsep $ pwords "Termination checking pragmas can only precede a mutual block or a function definition." pretty (InvalidMeasureMutual _) = fsep $ pwords "In a mutual block, either all functions must have the same (or no) termination checking pragma." pretty (InvalidCatchallPragma _) = fsep $ pwords "The CATCHALL pragma can only preceed a function clause." pretty (UnquoteDefRequiresSignature xs) = fsep $ pwords "Missing type signatures for unquoteDef" ++ map pretty xs pretty (BadMacroDef nd) = fsep $ [text $ declName nd] ++ pwords "are not allowed in macro blocks" pretty (NotAllowedInMutual nd) = fsep $ [text $ declName nd] ++ pwords "are not allowed in mutual blocks" pretty (Codata _) = text $ "The codata construction has been removed. " ++ "Use the INFINITY builtin instead." pretty (DeclarationPanic s) = text s pretty (InvalidNoPositivityCheckPragma _) = fsep $ pwords "No positivity checking pragmas can only precede a mutual block or a data/record definition." declName :: NiceDeclaration -> String declName Axiom{} = "Postulates" declName NiceField{} = "Fields" declName NiceMutual{} = "Mutual blocks" declName NiceModule{} = "Modules" declName NiceModuleMacro{} = "Modules" declName NiceOpen{} = "Open declarations" declName NiceImport{} = "Import statements" declName NicePragma{} = "Pragmas" declName PrimitiveFunction{} = "Primitive declarations" declName NicePatternSyn{} = "Pattern synonyms" declName NiceUnquoteDecl{} = "Unquoted declarations" declName NiceUnquoteDef{} = "Unquoted definitions" declName NiceRecSig{} = "Records" declName NiceDataSig{} = "Data types" declName NiceFunClause{} = "Functions without a type signature" declName FunSig{} = "Type signatures" declName FunDef{} = "Function definitions" declName RecDef{} = "Records" declName DataDef{} = "Data types" {-------------------------------------------------------------------------- The niceifier --------------------------------------------------------------------------} data InMutual = InMutual -- ^ we are nicifying a mutual block | NotInMutual -- ^ we are nicifying decls not in a mutual block deriving (Eq, Show) -- | The kind of the forward declaration, remembering the parameters. data DataRecOrFun = DataName PositivityCheck Params -- ^ name of a data with parameters | RecName PositivityCheck Params -- ^ name of a record with parameters | FunName TerminationCheck -- ^ name of a function -- Ignore pragmas when checking equality instance Eq DataRecOrFun where DataName _ p == DataName _ q = p == q RecName _ p == RecName _ q = p == q FunName _ == FunName _ = True _ == _ = False type Params = [Hiding] instance Show DataRecOrFun where show (DataName _ n) = "data type" -- "with " ++ show n ++ " visible parameters" show (RecName _ n) = "record type" -- "with " ++ show n ++ " visible parameters" show (FunName{}) = "function" isFunName :: DataRecOrFun -> Bool isFunName (FunName{}) = True isFunName _ = False sameKind :: DataRecOrFun -> DataRecOrFun -> Bool sameKind DataName{} DataName{} = True sameKind RecName{} RecName{} = True sameKind FunName{} FunName{} = True sameKind _ _ = False terminationCheck :: DataRecOrFun -> TerminationCheck terminationCheck (FunName tc) = tc terminationCheck _ = TerminationCheck positivityCheck :: DataRecOrFun -> PositivityCheck positivityCheck (DataName pc _) = pc positivityCheck (RecName pc _) = pc positivityCheck _ = True -- | Check that declarations in a mutual block are consistently -- equipped with MEASURE pragmas, or whether there is a -- NO_TERMINATION_CHECK pragma. combineTermChecks :: Range -> [TerminationCheck] -> Nice TerminationCheck combineTermChecks r tcs = loop tcs where loop [] = return TerminationCheck loop (tc : tcs) = do let failure r = throwError $ InvalidMeasureMutual r tc' <- loop tcs case (tc, tc') of (TerminationCheck , tc' ) -> return tc' (tc , TerminationCheck ) -> return tc (NonTerminating , NonTerminating ) -> return NonTerminating (NoTerminationCheck , NoTerminationCheck ) -> return NoTerminationCheck (NoTerminationCheck , Terminating ) -> return Terminating (Terminating , NoTerminationCheck ) -> return Terminating (Terminating , Terminating ) -> return Terminating (TerminationMeasure{} , TerminationMeasure{} ) -> return tc (TerminationMeasure r _, NoTerminationCheck ) -> failure r (TerminationMeasure r _, Terminating ) -> failure r (NoTerminationCheck , TerminationMeasure r _) -> failure r (Terminating , TerminationMeasure r _) -> failure r (TerminationMeasure r _, NonTerminating ) -> failure r (NonTerminating , TerminationMeasure r _) -> failure r (NoTerminationCheck , NonTerminating ) -> failure r (Terminating , NonTerminating ) -> failure r (NonTerminating , NoTerminationCheck ) -> failure r (NonTerminating , Terminating ) -> failure r -- | Nicifier monad. type Nice = StateT NiceEnv (Either DeclarationException) -- | Nicifier state. data NiceEnv = NiceEnv { _loneSigs :: LoneSigs -- ^ Lone type signatures that wait for their definition. , _termChk :: TerminationCheck -- ^ Termination checking pragma waiting for a definition. , _posChk :: PositivityCheck -- ^ Positivity checking pragma waiting for a definition. , _catchall :: Catchall -- ^ Catchall pragma waiting for a function clause. , fixs :: Fixities , pols :: Polarities } type LoneSigs = Map Name DataRecOrFun type Fixities = Map Name Fixity' type Polarities = Map Name [Occurrence] -- | Initial nicifier state. initNiceEnv :: NiceEnv initNiceEnv = NiceEnv { _loneSigs = empty , _termChk = TerminationCheck , _posChk = True , _catchall = False , fixs = empty , pols = empty } -- * Handling the lone signatures, stored to infer mutual blocks. -- | Lens for field '_loneSigs'. loneSigs :: Lens' LoneSigs NiceEnv loneSigs f e = f (_loneSigs e) <&> \ s -> e { _loneSigs = s } -- | Adding a lone signature to the state. addLoneSig :: Name -> DataRecOrFun -> Nice () addLoneSig x k = loneSigs %== \ s -> do let (mr, s') = Map.insertLookupWithKey (\ k new old -> new) x k s case mr of Nothing -> return s' Just{} -> throwError $ DuplicateDefinition x -- | Remove a lone signature from the state. removeLoneSig :: Name -> Nice () removeLoneSig x = loneSigs %= Map.delete x -- | Search for forward type signature. getSig :: Name -> Nice (Maybe DataRecOrFun) getSig x = Map.lookup x <$> use loneSigs -- | Check that no lone signatures are left in the state. noLoneSigs :: Nice Bool noLoneSigs = null <$> use loneSigs -- | Ensure that all forward declarations have been given a definition. checkLoneSigs :: [(Name, a)] -> Nice () checkLoneSigs xs = case xs of [] -> return () (x, _):_ -> throwError $ MissingDefinition x -- | Lens for field '_termChk'. terminationCheckPragma :: Lens' TerminationCheck NiceEnv terminationCheckPragma f e = f (_termChk e) <&> \ s -> e { _termChk = s } withTerminationCheckPragma :: TerminationCheck -> Nice a -> Nice a withTerminationCheckPragma tc f = do tc_old <- use terminationCheckPragma terminationCheckPragma .= tc result <- f terminationCheckPragma .= tc_old return result -- | Lens for field '_posChk'. positivityCheckPragma :: Lens' PositivityCheck NiceEnv positivityCheckPragma f e = f (_posChk e) <&> \ s -> e { _posChk = s } withPositivityCheckPragma :: PositivityCheck -> Nice a -> Nice a withPositivityCheckPragma pc f = do pc_old <- use positivityCheckPragma positivityCheckPragma .= pc result <- f positivityCheckPragma .= pc_old return result -- | Lens for field '_catchall'. catchallPragma :: Lens' Catchall NiceEnv catchallPragma f e = f (_catchall e) <&> \ s -> e { _catchall = s } -- | Get current catchall pragma, and reset it for the next clause. popCatchallPragma :: Nice Catchall popCatchallPragma = do ca <- use catchallPragma catchallPragma .= False return ca withCatchallPragma :: Catchall -> Nice a -> Nice a withCatchallPragma ca f = do ca_old <- use catchallPragma catchallPragma .= ca result <- f catchallPragma .= ca_old return result -- | Check whether name is not "_" and return its fixity. getFixity :: Name -> Nice Fixity' getFixity x = Map.findWithDefault noFixity' x <$> gets fixs -- WAS: defaultFixity' -- | Fail if the name is @_@. Otherwise the name's polarity, if any, -- is removed from the state and returned. getPolarity :: Name -> Nice (Maybe [Occurrence]) getPolarity x = do p <- gets (Map.lookup x . pols) modify (\s -> s { pols = Map.delete x (pols s) }) return p runNice :: Nice a -> Either DeclarationException a runNice nice = nice `evalStateT` initNiceEnv data DeclKind = LoneSig DataRecOrFun Name | LoneDefs DataRecOrFun [Name] | OtherDecl deriving (Eq, Show) declKind :: NiceDeclaration -> DeclKind declKind (FunSig _ _ _ _ _ _ _ tc x _) = LoneSig (FunName tc) x declKind (NiceRecSig _ _ _ _ pc x pars _) = LoneSig (RecName pc $ parameters pars) x declKind (NiceDataSig _ _ _ _ pc x pars _)= LoneSig (DataName pc $ parameters pars) x declKind (FunDef _ _ _ _ tc x _) = LoneDefs (FunName tc) [x] declKind (DataDef _ _ _ pc x pars _) = LoneDefs (DataName pc $ parameters pars) [x] declKind (RecDef _ _ _ pc x _ _ _ pars _) = LoneDefs (RecName pc $ parameters pars) [x] declKind (NiceUnquoteDef _ _ _ _ tc xs _) = LoneDefs (FunName tc) xs declKind Axiom{} = OtherDecl declKind NiceField{} = OtherDecl declKind PrimitiveFunction{} = OtherDecl declKind NiceMutual{} = OtherDecl declKind NiceModule{} = OtherDecl declKind NiceModuleMacro{} = OtherDecl declKind NiceOpen{} = OtherDecl declKind NiceImport{} = OtherDecl declKind NicePragma{} = OtherDecl declKind NiceFunClause{} = OtherDecl declKind NicePatternSyn{} = OtherDecl declKind NiceUnquoteDecl{} = OtherDecl -- | Compute visible parameters of a data or record signature or definition. parameters :: [LamBinding] -> Params parameters = List.concat . List.map numP where numP (DomainFree i _) = [argInfoHiding i] numP (DomainFull (TypedBindings _ (Arg i (TBind _ xs _)))) = List.replicate (length xs) $ argInfoHiding i numP (DomainFull (TypedBindings _ (Arg _ TLet{}))) = [] -- | Main. niceDeclarations :: [Declaration] -> Nice [NiceDeclaration] niceDeclarations ds = do -- Get fixity and syntax declarations. (fixs, polarities) <- fixitiesAndPolarities ds let declared = Set.fromList (concatMap declaredNames ds) unknownFixs = Map.keysSet fixs Set.\\ declared unknownPols = Map.keysSet polarities Set.\\ declared case (Set.null unknownFixs, Set.null unknownPols) of -- If we have fixity/syntax decls for names not declared -- in the current scope, fail. (False, _) -> throwError $ UnknownNamesInFixityDecl (Set.toList unknownFixs) -- Fail if there are polarity pragmas with undeclared names. (_, False) -> throwError $ UnknownNamesInPolarityPragmas (Set.toList unknownPols) (True, True) -> localState $ do -- Run the nicifier in an initial environment of fixity decls -- and polarities. put $ initNiceEnv { fixs = fixs, pols = polarities } ds <- nice ds -- Check that every polarity pragma was used. unusedPolarities <- gets (Map.keys . pols) unless (null unusedPolarities) $ do throwError $ PolarityPragmasButNotPostulates unusedPolarities -- Check that every signature got its definition. checkLoneSigs . Map.toList =<< use loneSigs -- Note that loneSigs is ensured to be empty. -- (Important, since inferMutualBlocks also uses loneSigs state). inferMutualBlocks ds where -- Compute the names defined in a declaration. -- We stay in the current scope, i.e., do not go into modules. declaredNames :: Declaration -> [Name] declaredNames d = case d of TypeSig _ x _ -> [x] Field _ x _ -> [x] FunClause (LHS p [] [] []) _ _ _ | IdentP (QName x) <- removeSingletonRawAppP p -> [x] FunClause{} -> [] DataSig _ _ x _ _ -> [x] Data _ _ x _ _ cs -> x : concatMap declaredNames cs RecordSig _ x _ _ -> [x] Record _ x _ _ c _ _ _ -> x : foldMap (:[]) (fst <$> c) Infix _ _ -> [] Syntax _ _ -> [] PatternSyn _ x _ _ -> [x] Mutual _ ds -> concatMap declaredNames ds Abstract _ ds -> concatMap declaredNames ds Private _ _ ds -> concatMap declaredNames ds InstanceB _ ds -> concatMap declaredNames ds Macro _ ds -> concatMap declaredNames ds Postulate _ ds -> concatMap declaredNames ds Primitive _ ds -> concatMap declaredNames ds Open{} -> [] Import{} -> [] ModuleMacro{} -> [] Module{} -> [] UnquoteDecl _ xs _ -> xs UnquoteDef{} -> [] Pragma{} -> [] inferMutualBlocks :: [NiceDeclaration] -> Nice [NiceDeclaration] inferMutualBlocks [] = return [] inferMutualBlocks (d : ds) = case declKind d of OtherDecl -> (d :) <$> inferMutualBlocks ds LoneDefs _ xs -> __IMPOSSIBLE__ LoneSig k x -> do addLoneSig x k ((tcs, pcs), (ds0, ds1)) <- untilAllDefined ([terminationCheck k], [positivityCheck k]) ds tc <- combineTermChecks (getRange d) tcs -- Record modules are, for performance reasons, not always -- placed in mutual blocks. -- ASR (01 January 2016): If the record module has a -- NO_POSITIVITY_CHECK pragma, it is placed in a mutual -- block. See Issue 1760. let prefix :: [NiceDeclaration] -> [NiceDeclaration] prefix = case (d, ds0) of (NiceRecSig{}, [r@(RecDef _ _ _ True _ _ _ _ _ _)]) -> ([d, r] ++) _ -> (NiceMutual (getRange (d : ds0)) tc (and pcs) (d : ds0) :) prefix <$> inferMutualBlocks ds1 where untilAllDefined :: ([TerminationCheck], [PositivityCheck]) -> [NiceDeclaration] -> Nice (([TerminationCheck], [PositivityCheck]), ([NiceDeclaration], [NiceDeclaration])) untilAllDefined (tc, pc) ds = do done <- noLoneSigs if done then return ((tc, pc), ([], ds)) else case ds of [] -> __IMPOSSIBLE__ <$ (checkLoneSigs . Map.toList =<< use loneSigs) d : ds -> case declKind d of LoneSig k x -> addLoneSig x k >> cons d (untilAllDefined (terminationCheck k : tc, positivityCheck k : pc) ds) LoneDefs k xs -> do mapM_ removeLoneSig xs cons d (untilAllDefined (terminationCheck k : tc, positivityCheck k : pc) ds) OtherDecl -> cons d (untilAllDefined (tc, pc) ds) where -- ASR (26 December 2015): Type annotated version of the @cons@ function. -- cons d = fmap $ -- (id :: (([TerminationCheck], [PositivityCheck]) -> ([TerminationCheck], [PositivityCheck]))) -- *** (d :) -- *** (id :: [NiceDeclaration] -> [NiceDeclaration]) cons d = fmap (id *** (d :) *** id) notMeasure TerminationMeasure{} = False notMeasure _ = True nice :: [Declaration] -> Nice [NiceDeclaration] nice [] = return [] nice ds = do (xs , ys) <- nice1 ds (xs ++) <$> nice ys nice1 :: [Declaration] -> Nice ([NiceDeclaration], [Declaration]) nice1 [] = __IMPOSSIBLE__ nice1 (d:ds) = case d of (TypeSig info x t) -> do termCheck <- use terminationCheckPragma fx <- getFixity x -- register x as lone type signature, to recognize clauses later addLoneSig x (FunName termCheck) return ([FunSig (getRange d) fx PublicAccess ConcreteDef NotInstanceDef NotMacroDef info termCheck x t] , ds) (FunClause lhs _ _ _) -> do termCheck <- use terminationCheckPragma catchall <- popCatchallPragma xs <- map fst . filter (isFunName . snd) . Map.toList <$> use loneSigs -- for each type signature 'x' waiting for clauses, we try -- if we have some clauses for 'x' fixs <- gets fixs case [ (x, (fits, rest)) | x <- xs , let (fits, rest) = -- Anonymous declarations only have 1 clause each! if isNoName x then ([d], ds) else span (couldBeFunClauseOf (Map.lookup x fixs) x) (d : ds) , not (null fits) ] of -- case: clauses match none of the sigs [] -> case lhs of -- Subcase: The lhs is single identifier (potentially anonymous). -- Treat it as a function clause without a type signature. LHS p [] [] [] | Just x <- isSingleIdentifierP p -> do d <- mkFunDef defaultArgInfo termCheck x Nothing [d] -- fun def without type signature is relevant return (d , ds) -- Subcase: The lhs is a proper pattern. -- This could be a let-pattern binding. Pass it on. -- A missing type signature error might be raise in ConcreteToAbstract _ -> do return ([NiceFunClause (getRange d) PublicAccess ConcreteDef termCheck catchall d] , ds) -- case: clauses match exactly one of the sigs [(x,(fits,rest))] -> do removeLoneSig x cs <- mkClauses x (expandEllipsis fits) False fx <- getFixity x return ([FunDef (getRange fits) fits fx ConcreteDef termCheck x cs] , rest) -- case: clauses match more than one sigs (ambiguity) l -> throwError $ AmbiguousFunClauses lhs $ reverse $ map fst l -- "ambiguous function clause; cannot assign it uniquely to one type signature" Field{} -> (,ds) <$> niceAxioms FieldBlock [ d ] DataSig r CoInductive _ _ _ -> throwError (Codata r) Data r CoInductive _ _ _ _ -> throwError (Codata r) (DataSig r Inductive x tel t) -> do pc <- use positivityCheckPragma addLoneSig x (DataName pc $ parameters tel) (,) <$> dataOrRec pc DataDef NiceDataSig (niceAxioms DataBlock) r x tel (Just t) Nothing <*> return ds (Data r Inductive x tel t cs) -> do pc <- use positivityCheckPragma t <- defaultTypeSig (DataName pc $ parameters tel) x t (,) <$> dataOrRec pc DataDef NiceDataSig (niceAxioms DataBlock) r x tel t (Just cs) <*> return ds (RecordSig r x tel t) -> do pc <- use positivityCheckPragma addLoneSig x (RecName pc $ parameters tel) fx <- getFixity x return ([NiceRecSig r fx PublicAccess ConcreteDef pc x tel t] , ds) (Record r x i e c tel t cs) -> do pc <- use positivityCheckPragma t <- defaultTypeSig (RecName pc $ parameters tel) x t c <- traverse (\(cname, cinst) -> do fix <- getFixity cname; return (ThingWithFixity cname fix, cinst)) c (,) <$> dataOrRec pc (\ r f a pc x tel cs -> RecDef r f a pc x i e c tel cs) NiceRecSig niceDeclarations r x tel t (Just cs) <*> return ds Mutual r ds' -> (,ds) <$> (singleton <$> (mkOldMutual r =<< nice ds')) Abstract r ds' -> (,ds) <$> (abstractBlock r =<< nice ds') Private r o ds' -> (,ds) <$> (privateBlock r o =<< nice ds') InstanceB r ds' -> (,ds) <$> (instanceBlock r =<< nice ds') Macro r ds' -> (,ds) <$> (macroBlock r =<< nice ds') Postulate _ ds' -> (,ds) <$> (mapM setPolarity =<< niceAxioms PostulateBlock ds') where setPolarity (Axiom r f acc a i arg Nothing x e) = do mp <- getPolarity x return (Axiom r f acc a i arg mp x e) setPolarity (Axiom _ _ _ _ _ _ (Just _) _ _) = __IMPOSSIBLE__ setPolarity d = return d Primitive _ ds' -> (,ds) <$> (map toPrim <$> niceAxioms PrimitiveBlock ds') Module r x tel ds' -> return $ ([NiceModule r PublicAccess ConcreteDef x tel ds'] , ds) ModuleMacro r x modapp op is -> return $ ([NiceModuleMacro r PublicAccess x modapp op is] , ds) -- Fixity and syntax declarations and polarity pragmas have -- already been processed. Infix _ _ -> return ([], ds) Syntax _ _ -> return ([], ds) PatternSyn r n as p -> do fx <- getFixity n return ([NicePatternSyn r fx n as p] , ds) Open r x is -> return ([NiceOpen r x is] , ds) Import r x as op is -> return ([NiceImport r x as op is] , ds) UnquoteDecl r xs e -> do fxs <- mapM getFixity xs tc <- use terminationCheckPragma return ([NiceUnquoteDecl r fxs PublicAccess ConcreteDef NotInstanceDef tc xs e] , ds) UnquoteDef r xs e -> do fxs <- mapM getFixity xs sigs <- map fst . filter (isFunName . snd) . Map.toList <$> use loneSigs let missing = filter (`notElem` sigs) xs if null missing then do mapM_ removeLoneSig xs return ([NiceUnquoteDef r fxs PublicAccess ConcreteDef TerminationCheck xs e] , ds) else throwError $ UnquoteDefRequiresSignature missing Pragma p -> nicePragma p ds nicePragma :: Pragma -> [Declaration] -> Nice ([NiceDeclaration], [Declaration]) nicePragma (TerminationCheckPragma r (TerminationMeasure _ x)) ds = if canHaveTerminationMeasure ds then withTerminationCheckPragma (TerminationMeasure r x) $ nice1 ds else throwError $ InvalidTerminationCheckPragma r nicePragma (TerminationCheckPragma r NoTerminationCheck) ds = throwError $ PragmaNoTerminationCheck r nicePragma (TerminationCheckPragma r tc) ds = if canHaveTerminationCheckPragma ds then withTerminationCheckPragma tc $ nice1 ds else throwError $ InvalidTerminationCheckPragma r nicePragma (CatchallPragma r) ds = if canHaveCatchallPragma ds then withCatchallPragma True $ nice1 ds else throwError $ InvalidCatchallPragma r nicePragma (NoPositivityCheckPragma r) ds = if canHaveNoPositivityCheckPragma ds then withPositivityCheckPragma False $ nice1 ds else throwError $ InvalidNoPositivityCheckPragma r nicePragma (PolarityPragma{}) ds = return ([], ds) nicePragma p ds = return ([NicePragma (getRange p) p], ds) canHaveTerminationMeasure :: [Declaration] -> Bool canHaveTerminationMeasure [] = False canHaveTerminationMeasure (d:ds) = case d of TypeSig{} -> True (Pragma p) | isAttachedPragma p -> canHaveTerminationMeasure ds _ -> False canHaveTerminationCheckPragma :: [Declaration] -> Bool canHaveTerminationCheckPragma [] = False canHaveTerminationCheckPragma (d:ds) = case d of Mutual{} -> True TypeSig{} -> True FunClause{} -> True UnquoteDecl{} -> True (Pragma p) | isAttachedPragma p -> canHaveTerminationCheckPragma ds _ -> False canHaveCatchallPragma :: [Declaration] -> Bool canHaveCatchallPragma [] = False canHaveCatchallPragma (d:ds) = case d of FunClause{} -> True (Pragma p) | isAttachedPragma p -> canHaveCatchallPragma ds _ -> False canHaveNoPositivityCheckPragma :: [Declaration] -> Bool canHaveNoPositivityCheckPragma [] = False canHaveNoPositivityCheckPragma (d:ds) = case d of Mutual{} -> True (Data _ Inductive _ _ _ _) -> True (DataSig _ Inductive _ _ _) -> True Record{} -> True RecordSig{} -> True (Pragma p) | isAttachedPragma p -> canHaveNoPositivityCheckPragma ds _ -> False isAttachedPragma :: Pragma -> Bool isAttachedPragma p = case p of TerminationCheckPragma{} -> True CatchallPragma{} -> True NoPositivityCheckPragma{} -> True _ -> False -- We could add a default type signature here, but at the moment we can't -- infer the type of a record or datatype, so better to just fail here. defaultTypeSig :: DataRecOrFun -> Name -> Maybe Expr -> Nice (Maybe Expr) defaultTypeSig k x t@Just{} = return t defaultTypeSig k x Nothing = do mk <- getSig x case mk of Nothing -> throwError $ MissingDataSignature x Just k' | k == k' -> Nothing <$ removeLoneSig x | sameKind k k' -> throwError $ WrongParameters x | otherwise -> throwError $ WrongDefinition x k' k dataOrRec :: forall a . PositivityCheck -> (Range -> Fixity' -> IsAbstract -> PositivityCheck -> Name -> [LamBinding] -> [NiceConstructor] -> NiceDeclaration) -> (Range -> Fixity' -> Access -> IsAbstract -> PositivityCheck -> Name -> [LamBinding] -> Expr -> NiceDeclaration) -> ([a] -> Nice [NiceDeclaration]) -> Range -> Name -> [LamBinding] -> Maybe Expr -> Maybe [a] -> Nice [NiceDeclaration] dataOrRec pc mkDef mkSig niceD r x tel mt mcs = do mds <- traverse niceD mcs f <- getFixity x return $ catMaybes $ [ mt <&> \ t -> mkSig (fuseRange x t) f PublicAccess ConcreteDef pc x tel t , mkDef r f ConcreteDef pc x (concatMap dropType tel) <$> mds ] where dropType :: LamBinding -> [LamBinding] dropType (DomainFull (TypedBindings _r (Arg ai (TBind _ xs _)))) = map (mergeHiding . fmap (DomainFree ai)) xs dropType (DomainFull (TypedBindings _r (Arg _ TLet{}))) = [] dropType b@DomainFree{} = [b] -- Translate axioms niceAxioms :: KindOfBlock -> [TypeSignatureOrInstanceBlock] -> Nice [NiceDeclaration] niceAxioms b ds = liftM List.concat $ mapM (niceAxiom b) ds niceAxiom :: KindOfBlock -> TypeSignatureOrInstanceBlock -> Nice [NiceDeclaration] niceAxiom b d = case d of TypeSig rel x t -> do fx <- getFixity x return [ Axiom (getRange d) fx PublicAccess ConcreteDef NotInstanceDef rel Nothing x t ] Field i x argt -> do fx <- getFixity x return [ NiceField (getRange d) fx PublicAccess ConcreteDef i x argt ] InstanceB r decls -> do instanceBlock r =<< niceAxioms InstanceBlock decls Pragma p@(RewritePragma r _) -> do return [ NicePragma r p ] _ -> throwError $ WrongContentBlock b $ getRange d toPrim :: NiceDeclaration -> NiceDeclaration toPrim (Axiom r f p a i rel Nothing x t) = PrimitiveFunction r f p a x t toPrim _ = __IMPOSSIBLE__ -- Create a function definition. mkFunDef info termCheck x mt ds0 = do cs <- mkClauses x (expandEllipsis ds0) False f <- getFixity x return [ FunSig (fuseRange x t) f PublicAccess ConcreteDef NotInstanceDef NotMacroDef info termCheck x t , FunDef (getRange ds0) ds0 f ConcreteDef termCheck x cs ] where t = case mt of Just t -> t Nothing -> underscore (getRange x) underscore r = Underscore r Nothing expandEllipsis :: [Declaration] -> [Declaration] expandEllipsis [] = [] expandEllipsis (d@(FunClause Ellipsis{} _ _ _) : ds) = d : expandEllipsis ds expandEllipsis (d@(FunClause lhs@(LHS p ps _ _) _ _ _) : ds) = d : expand (setInserted p) (map setInserted ps) ds where expand _ _ [] = [] expand p ps (d@(Pragma (CatchallPragma r)) : ds) = d : expand p ps ds expand p ps (FunClause (Ellipsis r ps' eqs []) rhs wh ca : ds) = FunClause (LHS (setRange r p) ((setRange r ps) ++ ps') eqs []) rhs wh ca : expand p ps ds expand p ps (FunClause (Ellipsis r ps' eqs es) rhs wh ca : ds) = FunClause (LHS (setRange r p) ((setRange r ps) ++ ps') eqs es) rhs wh ca : expand p (ps ++ ps') ds expand p ps (d@(FunClause (LHS _ _ _ []) _ _ _) : ds) = d : expand p ps ds expand _ _ (d@(FunClause (LHS p ps _ (_ : _)) _ _ _) : ds) = d : expand p ps ds expand _ _ (_ : ds) = __IMPOSSIBLE__ expandEllipsis (_ : ds) = __IMPOSSIBLE__ setInserted :: Pattern -> Pattern setInserted p = case p of IdentP{} -> p QuoteP{} -> p AppP p q -> AppP (setInserted p) (fmap (fmap setInserted) q) RawAppP r ps -> RawAppP r (map setInserted ps) OpAppP r c ns ps -> OpAppP r c ns (map (fmap $ fmap setInserted) ps) HiddenP r p -> HiddenP r (fmap setInserted p) InstanceP r p -> InstanceP r (fmap setInserted p) ParenP r p -> ParenP r (setInserted p) WildP{} -> p AbsurdP{} -> p AsP r n p -> AsP r n (setInserted p) DotP r _ e -> DotP r Inserted e LitP{} -> p RecP r fs -> RecP r (map (fmap setInserted) fs) -- Turn function clauses into nice function clauses. mkClauses :: Name -> [Declaration] -> Catchall -> Nice [Clause] mkClauses _ [] _ = return [] mkClauses x (Pragma (CatchallPragma r) : cs) True = throwError $ InvalidCatchallPragma r mkClauses x (Pragma (CatchallPragma r) : cs) False = do when (null cs) $ throwError $ InvalidCatchallPragma r mkClauses x cs True mkClauses x (FunClause lhs@(LHS _ _ _ []) rhs wh ca : cs) catchall = (Clause x (ca || catchall) lhs rhs wh [] :) <$> mkClauses x cs False mkClauses x (FunClause lhs@(LHS _ ps _ es) rhs wh ca : cs) catchall = do when (null with) $ throwError $ MissingWithClauses x wcs <- mkClauses x with False (Clause x (ca || catchall) lhs rhs wh wcs :) <$> mkClauses x cs' False where (with, cs') = subClauses cs -- A clause is a subclause if the number of with-patterns is -- greater or equal to the current number of with-patterns plus the -- number of with arguments. subClauses :: [Declaration] -> ([Declaration],[Declaration]) subClauses (c@(FunClause (LHS _ ps' _ _) _ _ _) : cs) | length ps' >= length ps + length es = mapFst (c:) (subClauses cs) | otherwise = ([], c:cs) subClauses (c@(FunClause (Ellipsis _ ps' _ _) _ _ _) : cs) = mapFst (c:) (subClauses cs) subClauses (c@(Pragma (CatchallPragma r)) : cs) = case subClauses cs of ([], cs') -> ([], c:cs') (cs, cs') -> (c:cs, cs') subClauses [] = ([],[]) subClauses _ = __IMPOSSIBLE__ mkClauses x (FunClause lhs@Ellipsis{} rhs wh ca : cs) catchall = (Clause x (ca || catchall) lhs rhs wh [] :) <$> mkClauses x cs False -- Will result in an error later. mkClauses _ _ _ = __IMPOSSIBLE__ -- for finding clauses for a type sig in mutual blocks couldBeFunClauseOf :: Maybe Fixity' -> Name -> Declaration -> Bool couldBeFunClauseOf mFixity x (Pragma (CatchallPragma{})) = True couldBeFunClauseOf mFixity x (FunClause Ellipsis{} _ _ _) = True couldBeFunClauseOf mFixity x (FunClause (LHS p _ _ _) _ _ _) = let pns = patternNames p xStrings = nameStringParts x patStrings = concatMap nameStringParts pns in -- trace ("x = " ++ show x) $ -- trace ("pns = " ++ show pns) $ -- trace ("xStrings = " ++ show xStrings) $ -- trace ("patStrings = " ++ show patStrings) $ -- trace ("mFixity = " ++ show mFixity) $ case (headMaybe pns, mFixity) of -- first identifier in the patterns is the fun.symbol? (Just y, _) | x == y -> True -- trace ("couldBe since y = " ++ show y) $ True -- are the parts of x contained in p _ | xStrings `isSublistOf` patStrings -> True -- trace ("couldBe since isSublistOf") $ True -- looking for a mixfix fun.symb (_, Just fix) -> -- also matches in case of a postfix let notStrings = stringParts (theNotation fix) in -- trace ("notStrings = " ++ show notStrings) $ -- trace ("patStrings = " ++ show patStrings) $ (not $ null notStrings) && (notStrings `isSublistOf` patStrings) -- not a notation, not first id: give up _ -> False -- trace ("couldBe not (case default)") $ False couldBeFunClauseOf _ _ _ = False -- trace ("couldBe not (fun default)") $ False -- ASR (27 May 2014). Commented out unused code. -- @isFunClauseOf@ is for non-mutual blocks where clauses must follow the -- type sig immediately -- isFunClauseOf :: Name -> Declaration -> Bool -- isFunClauseOf x (FunClause Ellipsis{} _ _) = True -- isFunClauseOf x (FunClause (LHS p _ _ _) _ _) = -- -- p is the whole left hand side, excluding "with" patterns and clauses -- case removeSingletonRawAppP p of -- IdentP (QName q) -> x == q -- lhs is just an identifier -- _ -> True -- -- more complicated lhss must come with type signatures, so we just assume -- -- it's part of the current definition -- isFunClauseOf _ _ = False isSingleIdentifierP :: Pattern -> Maybe Name isSingleIdentifierP p = case removeSingletonRawAppP p of IdentP (QName x) -> Just x WildP r -> Just $ noName r _ -> Nothing removeSingletonRawAppP :: Pattern -> Pattern removeSingletonRawAppP p = case p of RawAppP _ [p'] -> removeSingletonRawAppP p' ParenP _ p' -> removeSingletonRawAppP p' _ -> p -- Make an old style mutual block from a list of mutual declarations mkOldMutual :: Range -> [NiceDeclaration] -> Nice NiceDeclaration mkOldMutual r ds = do -- Check that there aren't any missing definitions checkLoneSigs loneNames -- Check that there are no declarations that aren't allowed in old style mutual blocks case filter notAllowedInMutual ds of [] -> return () (NiceFunClause _ _ _ _ s_ (FunClause lhs _ _ _)):_ -> throwError $ MissingTypeSignature lhs d:_ -> throwError $ NotAllowedInMutual d tc0 <- use terminationCheckPragma let tcs = map termCheck ds tc <- combineTermChecks r (tc0:tcs) pc0 <- use positivityCheckPragma let pc :: PositivityCheck pc = pc0 && all positivityCheckOldMutual ds return $ NiceMutual r tc pc $ sigs ++ other where -- Andreas, 2013-11-23 allow postulates in mutual blocks notAllowedInMutual Axiom{} = False notAllowedInMutual d = declKind d == OtherDecl -- Pull type signatures to the top (sigs, other) = partition isTypeSig ds isTypeSig Axiom{} = True isTypeSig d | LoneSig{} <- declKind d = True isTypeSig _ = False sigNames = [ (x, k) | LoneSig k x <- map declKind ds ] defNames = [ (x, k) | LoneDefs k xs <- map declKind ds, x <- xs ] -- compute the set difference with equality just on names loneNames = [ (x, k) | (x, k) <- sigNames, List.all ((x /=) . fst) defNames ] -- Andreas, 2013-02-28 (issue 804): -- do not termination check a mutual block if any of its -- inner declarations comes with a {-# NO_TERMINATION_CHECK #-} termCheck (FunSig _ _ _ _ _ _ _ tc _ _) = tc termCheck (FunDef _ _ _ _ tc _ _) = tc -- ASR (28 December 2015): Is this equation necessary? termCheck (NiceMutual _ tc _ _) = __IMPOSSIBLE__ termCheck (NiceUnquoteDecl _ _ _ _ _ tc _ _) = tc termCheck (NiceUnquoteDef _ _ _ _ tc _ _) = tc termCheck Axiom{} = TerminationCheck termCheck NiceField{} = TerminationCheck termCheck PrimitiveFunction{} = TerminationCheck termCheck NiceModule{} = TerminationCheck termCheck NiceModuleMacro{} = TerminationCheck termCheck NiceOpen{} = TerminationCheck termCheck NiceImport{} = TerminationCheck termCheck NicePragma{} = TerminationCheck termCheck NiceRecSig{} = TerminationCheck termCheck NiceDataSig{} = TerminationCheck termCheck NiceFunClause{} = TerminationCheck termCheck DataDef{} = TerminationCheck termCheck RecDef{} = TerminationCheck termCheck NicePatternSyn{} = TerminationCheck -- ASR (26 December 2015): Do not positivity check a mutual -- block if any of its inner declarations comes with a -- NO_POSITIVITY_CHECK pragma. See Issue 1614. positivityCheckOldMutual :: NiceDeclaration -> PositivityCheck positivityCheckOldMutual (DataDef _ _ _ pc _ _ _) = pc positivityCheckOldMutual (NiceDataSig _ _ _ _ pc _ _ _)= pc positivityCheckOldMutual (NiceMutual _ _ pc _) = __IMPOSSIBLE__ positivityCheckOldMutual (NiceRecSig _ _ _ _ pc _ _ _) = pc positivityCheckOldMutual (RecDef _ _ _ pc _ _ _ _ _ _) = pc positivityCheckOldMutual _ = True -- A mutual block cannot have a measure, -- but it can skip termination check. abstractBlock _ [] = return [] abstractBlock r ds = do let (ds', anyChange) = runChange $ mkAbstract ds inherited = r == noRange -- hack to avoid failing on inherited abstract blocks in where clauses if anyChange || inherited then return ds' else throwError $ UselessAbstract r privateBlock _ _ [] = return [] privateBlock r o ds = do let (ds', anyChange) = runChange $ mkPrivate o ds if anyChange then return ds' else if o == UserWritten then throwError $ UselessPrivate r else return ds -- no change! instanceBlock _ [] = return [] instanceBlock r ds = do let (ds', anyChange) = runChange $ mapM mkInstance ds if anyChange then return ds' else throwError $ UselessInstance r -- Make a declaration eligible for instance search. mkInstance :: Updater NiceDeclaration mkInstance d = case d of Axiom r f p a i rel mp x e -> (\ i -> Axiom r f p a i rel mp x e) <$> setInstance i FunSig r f p a i m rel tc x e -> (\ i -> FunSig r f p a i m rel tc x e) <$> setInstance i NiceUnquoteDecl r f p a i tc x e -> (\ i -> NiceUnquoteDecl r f p a i tc x e) <$> setInstance i NiceMutual{} -> return d NiceFunClause{} -> return d FunDef{} -> return d NiceField{} -> return d -- Field instance are handled by the parser PrimitiveFunction{} -> return d NiceUnquoteDef{} -> return d NiceRecSig{} -> return d NiceDataSig{} -> return d NiceModuleMacro{} -> return d NiceModule{} -> return d NicePragma{} -> return d NiceOpen{} -> return d NiceImport{} -> return d DataDef{} -> return d RecDef{} -> return d NicePatternSyn{} -> return d setInstance :: Updater IsInstance setInstance i = case i of InstanceDef -> return i _ -> dirty $ InstanceDef macroBlock r ds = mapM mkMacro ds mkMacro :: NiceDeclaration -> Nice NiceDeclaration mkMacro d = case d of FunSig r f p a i _ rel tc x e -> return $ FunSig r f p a i MacroDef rel tc x e FunDef{} -> return d _ -> throwError (BadMacroDef d) -- | Make a declaration abstract. -- -- Mark computation as 'dirty' if there was a declaration that could be made abstract. -- If no abstraction is taking place, we want to complain about 'UselessAbstract'. -- -- Alternatively, we could only flag 'dirty' if a non-abstract thing was abstracted. -- Then, nested @abstract@s would sometimes also be complained about. class MakeAbstract a where mkAbstract :: Updater a default mkAbstract :: (Traversable f, MakeAbstract a', a ~ f a') => Updater a mkAbstract = traverse mkAbstract instance MakeAbstract a => MakeAbstract [a] where -- Default definition kicks in here! -- But note that we still have to declare the instance! -- Leads to overlap with 'WhereClause': -- instance (Traversable f, MakeAbstract a) => MakeAbstract (f a) where -- mkAbstract = traverse mkAbstract instance MakeAbstract IsAbstract where mkAbstract a = case a of AbstractDef -> return a ConcreteDef -> dirty $ AbstractDef instance MakeAbstract NiceDeclaration where mkAbstract d = case d of NiceMutual r termCheck pc ds -> NiceMutual r termCheck pc <$> mkAbstract ds FunDef r ds f a tc x cs -> (\ a -> FunDef r ds f a tc x) <$> mkAbstract a <*> mkAbstract cs DataDef r f a pc x ps cs -> (\ a -> DataDef r f a pc x ps) <$> mkAbstract a <*> mkAbstract cs RecDef r f a pc x i e c ps cs -> (\ a -> RecDef r f a pc x i e c ps) <$> mkAbstract a <*> mkAbstract cs NiceFunClause r p a termCheck catchall d -> (\ a -> NiceFunClause r p a termCheck catchall d) <$> mkAbstract a -- The following declarations have an @InAbstract@ field -- but are not really definitions, so we do count them into -- the declarations which can be made abstract -- (thus, do not notify progress with @dirty@). Axiom r f p a i rel mp x e -> return $ Axiom r f p AbstractDef i rel mp x e FunSig r f p a i m rel tc x e -> return $ FunSig r f p AbstractDef i m rel tc x e NiceRecSig r f p a pc x ls t -> return $ NiceRecSig r f p AbstractDef pc x ls t NiceDataSig r f p a pc x ls t -> return $ NiceDataSig r f p AbstractDef pc x ls t NiceField r f p _ i x e -> return $ NiceField r f p AbstractDef i x e PrimitiveFunction r f p _ x e -> return $ PrimitiveFunction r f p AbstractDef x e -- Andreas, 2016-07-17 it does have effect on unquoted defs. -- Need to set updater state to dirty! NiceUnquoteDecl r f p _ i t x e -> dirty $ NiceUnquoteDecl r f p AbstractDef i t x e NiceUnquoteDef r f p _ t x e -> dirty $ NiceUnquoteDef r f p AbstractDef t x e NiceModule{} -> return d NiceModuleMacro{} -> return d NicePragma{} -> return d NiceOpen{} -> return d NiceImport{} -> return d NicePatternSyn{} -> return d instance MakeAbstract Clause where mkAbstract (Clause x catchall lhs rhs wh with) = do Clause x catchall lhs rhs <$> mkAbstract wh <*> mkAbstract with -- | Contents of a @where@ clause are abstract if the parent is. instance MakeAbstract WhereClause where mkAbstract NoWhere = return $ NoWhere mkAbstract (AnyWhere ds) = dirty $ AnyWhere [Abstract noRange ds] mkAbstract (SomeWhere m a ds) = dirty $ SomeWhere m a [Abstract noRange ds] -- | Make a declaration private. -- -- Andreas, 2012-11-17: -- Mark computation as 'dirty' if there was a declaration that could be privatized. -- If no privatization is taking place, we want to complain about 'UselessPrivate'. -- -- Alternatively, we could only flag 'dirty' if a non-private thing was privatized. -- Then, nested @private@s would sometimes also be complained about. class MakePrivate a where mkPrivate :: Origin -> Updater a default mkPrivate :: (Traversable f, MakePrivate a', a ~ f a') => Origin -> Updater a mkPrivate o = traverse $ mkPrivate o instance MakePrivate a => MakePrivate [a] where -- Default definition kicks in here! -- But note that we still have to declare the instance! -- Leads to overlap with 'WhereClause': -- instance (Traversable f, MakePrivate a) => MakePrivate (f a) where -- mkPrivate = traverse mkPrivate instance MakePrivate Access where mkPrivate o p = case p of PrivateAccess{} -> return p -- OR? return $ PrivateAccess o _ -> dirty $ PrivateAccess o instance MakePrivate NiceDeclaration where mkPrivate o d = case d of Axiom r f p a i rel mp x e -> (\ p -> Axiom r f p a i rel mp x e) <$> mkPrivate o p NiceField r f p a i x e -> (\ p -> NiceField r f p a i x e) <$> mkPrivate o p PrimitiveFunction r f p a x e -> (\ p -> PrimitiveFunction r f p a x e) <$> mkPrivate o p NiceMutual r termCheck pc ds -> (\ p -> NiceMutual r termCheck pc p) <$> mkPrivate o ds NiceModule r p a x tel ds -> (\ p -> NiceModule r p a x tel ds) <$> mkPrivate o p NiceModuleMacro r p x ma op is -> (\ p -> NiceModuleMacro r p x ma op is) <$> mkPrivate o p FunSig r f p a i m rel tc x e -> (\ p -> FunSig r f p a i m rel tc x e) <$> mkPrivate o p NiceRecSig r f p a pc x ls t -> (\ p -> NiceRecSig r f p a pc x ls t) <$> mkPrivate o p NiceDataSig r f p a pc x ls t -> (\ p -> NiceDataSig r f p a pc x ls t) <$> mkPrivate o p NiceFunClause r p a termCheck catchall d -> (\ p -> NiceFunClause r p a termCheck catchall d) <$> mkPrivate o p NiceUnquoteDecl r f p a i t x e -> (\ p -> NiceUnquoteDecl r f p a i t x e) <$> mkPrivate o p NiceUnquoteDef r f p a t x e -> (\ p -> NiceUnquoteDef r f p a t x e) <$> mkPrivate o p NicePragma _ _ -> return $ d NiceOpen _ _ _ -> return $ d NiceImport _ _ _ _ _ -> return $ d -- Andreas, 2016-07-08, issue #2089 -- we need to propagate 'private' to the named where modules FunDef r ds f a tc x cls -> FunDef r ds f a tc x <$> mkPrivate o cls DataDef{} -> return $ d RecDef{} -> return $ d NicePatternSyn _ _ _ _ _ -> return $ d instance MakePrivate Clause where mkPrivate o (Clause x catchall lhs rhs wh with) = do Clause x catchall lhs rhs <$> mkPrivate o wh <*> mkPrivate o with instance MakePrivate WhereClause where mkPrivate o NoWhere = return $ NoWhere -- @where@-declarations are protected behind an anonymous module, -- thus, they are effectively private by default. mkPrivate o (AnyWhere ds) = return $ AnyWhere ds -- Andreas, 2016-07-08 -- A @where@-module is private if the parent function is private. -- The contents of this module are not private, unless declared so! -- Thus, we do not recurse into the @ds@ (could not anyway). mkPrivate o (SomeWhere m a ds) = mkPrivate o a <&> \ a' -> SomeWhere m a' ds -- | Add more fixities. Throw an exception for multiple fixity declarations. -- OR: Disjoint union of fixity maps. Throws exception if not disjoint. plusFixities :: Fixities -> Fixities -> Nice Fixities plusFixities m1 m2 -- If maps are not disjoint, report conflicts as exception. | not (null isect) = throwError $ MultipleFixityDecls isect -- Otherwise, do the union. | otherwise = return $ Map.unionWithKey mergeFixites m1 m2 where -- Merge two fixities, assuming there is no conflict mergeFixites name (Fixity' f1 s1 r1) (Fixity' f2 s2 r2) = Fixity' f s $ fuseRange r1 r2 where f | f1 == noFixity = f2 | f2 == noFixity = f1 | otherwise = __IMPOSSIBLE__ s | s1 == noNotation = s2 | s2 == noNotation = s1 | otherwise = __IMPOSSIBLE__ -- Compute a list of conflicts in a format suitable for error reporting. isect = [ (x, map (Map.findWithDefault __IMPOSSIBLE__ x) [m1,m2]) | (x, False) <- Map.assocs $ Map.intersectionWith compatible m1 m2 ] -- Check for no conflict. compatible (Fixity' f1 s1 _) (Fixity' f2 s2 _) = (f1 == noFixity || f2 == noFixity ) && (s1 == noNotation || s2 == noNotation) -- | While 'Fixities' and Polarities are not semigroups under disjoint -- union (which might fail), we get a semigroup instance for the -- monadic @Nice (Fixities, Polarities)@ which propagates the first -- error. instance Semigroup (Nice (Fixities, Polarities)) where c1 <> c2 = do (f1, p1) <- c1 (f2, p2) <- c2 f <- plusFixities f1 f2 p <- mergePolarities p1 p2 return (f, p) where mergePolarities p1 p2 | Set.null i = return (Map.union p1 p2) | otherwise = throwError $ MultiplePolarityPragmas (Set.toList i) where i = Set.intersection (Map.keysSet p1) (Map.keysSet p2) instance Monoid (Nice (Fixities, Polarities)) where mempty = return (Map.empty, Map.empty) mappend = (<>) -- | Get the fixities and polarity pragmas from the current block. -- Doesn't go inside modules and where blocks. -- The reason for this is that these declarations have to appear at the same -- level (or possibly outside an abstract or mutual block) as their target -- declaration. fixitiesAndPolarities :: [Declaration] -> Nice (Fixities, Polarities) fixitiesAndPolarities = foldMap $ \ d -> case d of -- These declarations define polarities: Pragma (PolarityPragma _ x occs) -> return (Map.empty, Map.singleton x occs) -- These declarations define fixities: Syntax x syn -> return ( Map.singleton x (Fixity' noFixity syn $ getRange x) , Map.empty ) Infix f xs -> return ( Map.fromList $ for xs $ \ x -> (x, Fixity' f noNotation$ getRange x) , Map.empty ) -- We look into these blocks: Mutual _ ds' -> fixitiesAndPolarities ds' Abstract _ ds' -> fixitiesAndPolarities ds' Private _ _ ds' -> fixitiesAndPolarities ds' InstanceB _ ds' -> fixitiesAndPolarities ds' Macro _ ds' -> fixitiesAndPolarities ds' -- All other declarations are ignored. -- We expand these boring cases to trigger a revisit -- in case the @Declaration@ type is extended in the future. TypeSig {} -> mempty Field {} -> mempty FunClause {} -> mempty DataSig {} -> mempty Data {} -> mempty RecordSig {} -> mempty Record {} -> mempty PatternSyn {} -> mempty Postulate {} -> mempty Primitive {} -> mempty Open {} -> mempty Import {} -> mempty ModuleMacro {} -> mempty Module {} -> mempty UnquoteDecl {} -> mempty UnquoteDef {} -> mempty Pragma {} -> mempty -- The following function is (at the time of writing) only used three -- times: for building Lets, and for printing error messages. -- | (Approximately) convert a 'NiceDeclaration' back to a list of -- 'Declaration's. notSoNiceDeclarations :: NiceDeclaration -> [Declaration] notSoNiceDeclarations d = case d of Axiom _ _ _ _ i rel mp x e -> (case mp of Nothing -> [] Just occs -> [Pragma (PolarityPragma noRange x occs)]) ++ inst i [TypeSig rel x e] NiceField _ _ _ _ i x argt -> [Field i x argt] PrimitiveFunction r _ _ _ x e -> [Primitive r [TypeSig defaultArgInfo x e]] NiceMutual r _ _ ds -> [Mutual r $ concatMap notSoNiceDeclarations ds] NiceModule r _ _ x tel ds -> [Module r x tel ds] NiceModuleMacro r _ x ma o dir -> [ModuleMacro r x ma o dir] NiceOpen r x dir -> [Open r x dir] NiceImport r x as o dir -> [Import r x as o dir] NicePragma _ p -> [Pragma p] NiceRecSig r _ _ _ _ x bs e -> [RecordSig r x bs e] NiceDataSig r _ _ _ _ x bs e -> [DataSig r Inductive x bs e] NiceFunClause _ _ _ _ _ d -> [d] FunSig _ _ _ _ i _ rel tc x e -> inst i [TypeSig rel x e] FunDef _r ds _ _ _ _ _ -> ds DataDef r _ _ _ x bs cs -> [Data r Inductive x bs Nothing $ concatMap notSoNiceDeclarations cs] RecDef r _ _ _ x i e c bs ds -> [Record r x i e (unThing <$> c) bs Nothing $ concatMap notSoNiceDeclarations ds] where unThing (ThingWithFixity c _, inst) = (c, inst) NicePatternSyn r _ n as p -> [PatternSyn r n as p] NiceUnquoteDecl r _ _ _ i _ x e -> inst i [UnquoteDecl r x e] NiceUnquoteDef r _ _ _ _ x e -> [UnquoteDef r x e] where inst InstanceDef ds = [InstanceB (getRange ds) ds] inst NotInstanceDef ds = ds -- | Has the 'NiceDeclaration' a field of type 'IsAbstract'? niceHasAbstract :: NiceDeclaration -> Maybe IsAbstract niceHasAbstract d = case d of Axiom{} -> Nothing NiceField _ _ _ a _ _ _ -> Just a PrimitiveFunction _ _ _ a _ _ -> Just a NiceMutual{} -> Nothing NiceModule _ _ a _ _ _ -> Just a NiceModuleMacro{} -> Nothing NiceOpen{} -> Nothing NiceImport{} -> Nothing NicePragma{} -> Nothing NiceRecSig{} -> Nothing NiceDataSig{} -> Nothing NiceFunClause _ _ a _ _ _ -> Just a FunSig{} -> Nothing FunDef _ _ _ a _ _ _ -> Just a DataDef _ _ a _ _ _ _ -> Just a RecDef _ _ a _ _ _ _ _ _ _ -> Just a NicePatternSyn{} -> Nothing NiceUnquoteDecl _ _ _ a _ _ _ _ -> Just a NiceUnquoteDef _ _ _ a _ _ _ -> Just a