{-# LANGUAGE CPP #-} {-# LANGUAGE ConstraintKinds #-} {-# LANGUAGE ExistentialQuantification #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE RecordWildCards #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TemplateHaskell #-} {-# LANGUAGE TupleSections #-} {-# LANGUAGE TypeOperators #-} {-# LANGUAGE CPP #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE MonoLocalBinds #-} module Language.C.Inline.Internal ( -- * Context handling setContext , getContext -- * Substitution , Substitutions(..) , substitute , getHaskellType -- * Emitting and invoking C code -- -- | The functions in this section let us access more the C file -- associated with the current module. They can be used to build -- additional features on top of the basic machinery. All of -- @inline-c@ is based upon the functions defined here. -- ** Emitting C code , emitVerbatim -- ** Inlining C code -- $embedding , Code(..) , inlineCode , inlineExp , inlineItems -- * Parsing -- -- | These functions are used to parse the anti-quotations. They're -- exposed for testing purposes, you really should not use them. , SomeEq , toSomeEq , fromSomeEq , ParameterType(..) , ParseTypedC(..) , parseTypedC , runParserInQ , splitTypedC -- * Utility functions for writing quasiquoters , genericQuote , funPtrQuote ) where import Control.Applicative import Control.Monad (forM, void, msum) import Control.Monad.State (evalStateT, StateT, get, put) import Control.Monad.Trans.Class (lift) import Data.Foldable (forM_) import qualified Data.Map as Map import Data.Maybe (fromMaybe) import Data.Traversable (for) import Data.Typeable (Typeable, cast) import qualified Language.Haskell.TH as TH import qualified Language.Haskell.TH.Quote as TH import qualified Language.Haskell.TH.Syntax as TH import System.IO.Unsafe (unsafePerformIO) import qualified Text.Parsec as Parsec import qualified Text.Parsec.Pos as Parsec import qualified Text.Parser.Char as Parser import qualified Text.Parser.Combinators as Parser import qualified Text.Parser.LookAhead as Parser import qualified Text.Parser.Token as Parser import Text.PrettyPrint.ANSI.Leijen ((<+>)) import qualified Text.PrettyPrint.ANSI.Leijen as PP import qualified Data.List as L import qualified Data.Char as C import Data.Hashable (Hashable) import Foreign.Ptr (FunPtr) import qualified Data.Map as M -- We cannot use getQ/putQ before 7.10.3 because of #define USE_GETQ (__GLASGOW_HASKELL__ > 710 || (__GLASGOW_HASKELL__ == 710 && __GLASGOW_HASKELL_PATCHLEVEL1__ >= 3)) #if !USE_GETQ import Control.Concurrent.MVar (MVar, newMVar, modifyMVar_, readMVar) #endif import Language.C.Inline.Context import Language.C.Inline.FunPtr import Language.C.Inline.HaskellIdentifier import qualified Language.C.Types as C data ModuleState = ModuleState { msContext :: Context , msGeneratedNames :: Int , msFileChunks :: [String] } deriving (Typeable) getModuleState :: TH.Q (Maybe ModuleState) putModuleState :: ModuleState -> TH.Q () #if USE_GETQ getModuleState = TH.getQ putModuleState = TH.putQ #else -- | Identifier for the current module. Currently we use the file name. -- Since we're pairing Haskell files with C files, it makes more sense -- to use the file name. I'm not sure if it's possible to compile two -- modules with the same name in one run of GHC, but in this way we make -- sure that we don't run into trouble even it is. type ModuleId = String getModuleId :: TH.Q ModuleId getModuleId = TH.loc_filename <$> TH.location -- | 'MVar' storing the state for all the modules we visited. Note that -- currently we do not bother with cleaning up the state after we're -- done compiling a module. TODO if there is an easy way, clean up the -- state. {-# NOINLINE moduleStatesVar #-} moduleStatesVar :: MVar (Map.Map ModuleId ModuleState) moduleStatesVar = unsafePerformIO $ newMVar Map.empty getModuleState = do moduleStates <- TH.runIO (readMVar moduleStatesVar) moduleId <- getModuleId return (Map.lookup moduleId moduleStates) putModuleState ms = do moduleId <- getModuleId TH.runIO (modifyMVar_ moduleStatesVar (return . Map.insert moduleId ms)) #endif -- | Make sure that 'moduleStatesVar' and the respective C file are up -- to date. initialiseModuleState :: Maybe Context -- ^ The 'Context' to use if we initialise the module. If 'Nothing', -- 'baseCtx' will be used. -> TH.Q Context initialiseModuleState mbContext = do mbModuleState <- getModuleState case mbModuleState of Just moduleState -> return (msContext moduleState) Nothing -> do -- Add hook to add the file TH.addModFinalizer $ do mbMs <- getModuleState ms <- case mbMs of Nothing -> fail "inline-c: ModuleState not present (initialiseModuleState)" Just ms -> return ms let lang = fromMaybe TH.LangC (ctxForeignSrcLang context) #if MIN_VERSION_base(4,12,0) TH.addForeignSource lang (concat (reverse (msFileChunks ms))) #else TH.addForeignFile lang (concat (reverse (msFileChunks ms))) #endif let moduleState = ModuleState { msContext = context , msGeneratedNames = 0 , msFileChunks = mempty } putModuleState moduleState return context where context = fromMaybe baseCtx mbContext -- | Gets the current 'Context'. Also makes sure that the current -- module is initialised. getContext :: TH.Q Context getContext = initialiseModuleState Nothing modifyModuleState :: (ModuleState -> (ModuleState, a)) -> TH.Q a modifyModuleState f = do mbModuleState <- getModuleState case mbModuleState of Nothing -> fail "inline-c: ModuleState not present (modifyModuleState)" Just ms -> do let (ms', x) = f ms putModuleState ms' return x -- $context -- -- The inline C functions ('cexp', 'c', etc.) need a 'Context' to -- operate. Said context can be explicitely set with 'setContext'. -- Otherwise, at the first usage of one of the TH functions in this -- module the 'Context' is implicitely set to 'baseCtx'. -- | Sets the 'Context' for the current module. This function, if -- called, must be called before any of the other TH functions in this -- module. Fails if that's not the case. setContext :: Context -> TH.Q () setContext ctx = do mbModuleState <- getModuleState forM_ mbModuleState $ \_ms -> fail "inline-c: The module has already been initialised (setContext)." void $ initialiseModuleState $ Just ctx bumpGeneratedNames :: TH.Q Int bumpGeneratedNames = do modifyModuleState $ \ms -> let c' = msGeneratedNames ms in (ms{msGeneratedNames = c' + 1}, c') ------------------------------------------------------------------------ -- Emitting -- | Simply appends some string to the module's C file. Use with care. emitVerbatim :: String -> TH.DecsQ emitVerbatim s = do -- Make sure that the 'ModuleState' is initialized void (initialiseModuleState Nothing) let chunk = "\n" ++ s ++ "\n" modifyModuleState $ \ms -> (ms{msFileChunks = chunk : msFileChunks ms}, ()) return [] ------------------------------------------------------------------------ -- Inlining -- $embedding -- -- We use the 'Code' data structure to represent some C code that we -- want to emit to the module's C file and immediately generate a -- foreign call to. For this reason, 'Code' includes both some C -- definition, and enough information to be able to generate a foreign -- call -- specifically the name of the function to call and the Haskell -- type. -- -- All the quasi-quoters work by constructing a 'Code' and calling -- 'inlineCode'. -- | Data type representing a list of C definitions with a typed and named entry -- function. -- -- We use it as a basis to inline and call C code. data Code = Code { codeCallSafety :: TH.Safety -- ^ Safety of the foreign call. , codeLoc :: Maybe TH.Loc -- ^ The haskell source location used for the #line directive , codeType :: TH.TypeQ -- ^ Type of the foreign call. , codeFunName :: String -- ^ Name of the function to call in the code below. , codeDefs :: String -- ^ The C code. , codeFunPtr :: Bool -- ^ If 'True', the type will be wrapped in 'FunPtr', and -- the call will be static (e.g. prefixed by &). } -- TODO use the #line CPP macro to have the functions in the C file -- refer to the source location in the Haskell file they come from. -- -- See . -- | Inlines a piece of code inline. The resulting 'TH.Exp' will have -- the type specified in the 'codeType'. -- -- In practice, this function outputs the C code to the module's C file, -- and then inserts a foreign call of type 'codeType' calling the -- provided 'codeFunName'. -- -- Example: -- -- @ -- c_add :: Int -> Int -> Int -- c_add = $(do -- here <- TH.location -- inlineCode $ Code -- TH.Unsafe -- Call safety -- (Just here) -- [t| Int -> Int -> Int |] -- Call type -- "francescos_add" -- Call name -- -- C Code -- \"int francescos_add(int x, int y) { int z = x + y; return z; }\") -- @ inlineCode :: Code -> TH.ExpQ inlineCode Code{..} = do -- Write out definitions ctx <- getContext let out = fromMaybe id $ ctxOutput ctx let directive = maybe "" (\l -> "#line " ++ show (fst $ TH.loc_start l) ++ " " ++ show (TH.loc_filename l ) ++ "\n") codeLoc void $ emitVerbatim $ out $ directive ++ codeDefs -- Create and add the FFI declaration. ffiImportName <- uniqueFfiImportName dec <- if codeFunPtr then TH.forImpD TH.CCall codeCallSafety ("&" ++ codeFunName) ffiImportName [t| FunPtr $(codeType) |] else TH.forImpD TH.CCall codeCallSafety codeFunName ffiImportName codeType TH.addTopDecls [dec] TH.varE ffiImportName uniqueCName :: Maybe String -> TH.Q String uniqueCName mbPostfix = do -- The name looks like this: -- inline_c_MODULE_INDEX_POSTFIX -- -- Where: -- * MODULE is the module name but with _s instead of .s; -- * INDEX is a counter that keeps track of how many names we're generating -- for each module. -- * POSTFIX is an optional postfix to ease debuggability -- -- we previously also generated a hash from the contents of the -- C code because of problems when cabal recompiled but now this -- is not needed anymore since we use 'addDependentFile' to compile -- the C code. c' <- bumpGeneratedNames module_ <- TH.loc_module <$> TH.location let replaceDot '.' = '_' replaceDot c = c let postfix = case mbPostfix of Nothing -> "" Just s -> "_" ++ s ++ "_" return $ "inline_c_" ++ map replaceDot module_ ++ "_" ++ show c' ++ postfix -- | Same as 'inlineCItems', but with a single expression. -- -- @ -- c_cos :: Double -> Double -- c_cos = $(do -- here <- TH.location -- inlineExp -- TH.Unsafe -- here -- [t| Double -> Double |] -- (quickCParser_ \"double\" parseType) -- [("x", quickCParser_ \"double\" parseType)] -- "cos(x)") -- @ inlineExp :: TH.Safety -- ^ Safety of the foreign call -> TH.Loc -- ^ The location to report -> TH.TypeQ -- ^ Type of the foreign call -> C.Type C.CIdentifier -- ^ Return type of the C expr -> [(C.CIdentifier, C.Type C.CIdentifier)] -- ^ Parameters of the C expr -> String -- ^ The C expression -> TH.ExpQ inlineExp callSafety loc type_ cRetType cParams cExp = inlineItems callSafety False Nothing loc type_ cRetType cParams cItems where cItems = case cRetType of C.TypeSpecifier _quals C.Void -> cExp ++ ";" _ -> "return (" ++ cExp ++ ");" -- | Same as 'inlineCode', but accepts a string containing a list of C -- statements instead instead than a full-blown 'Code'. A function -- containing the provided statement will be automatically generated. -- -- @ -- c_cos :: Double -> Double -- c_cos = $(do -- here <- TH.location -- inlineItems -- TH.Unsafe -- False -- Nothing -- here -- [t| Double -> Double |] -- (quickCParser_ \"double\" parseType) -- [("x", quickCParser_ \"double\" parseType)] -- "return cos(x);") -- @ inlineItems :: TH.Safety -- ^ Safety of the foreign call -> Bool -- ^ Whether to return as a FunPtr or not -> Maybe String -- ^ Optional postfix for the generated name -> TH.Loc -- ^ The location to report -> TH.TypeQ -- ^ Type of the foreign call -> C.Type C.CIdentifier -- ^ Return type of the C expr -> [(C.CIdentifier, C.Type C.CIdentifier)] -- ^ Parameters of the C expr -> String -- ^ The C items -> TH.ExpQ inlineItems callSafety funPtr mbPostfix loc type_ cRetType cParams cItems = do let mkParam (id', paramTy) = C.ParameterDeclaration (Just id') paramTy let proto = C.Proto cRetType (map mkParam cParams) ctx <- getContext funName <- uniqueCName mbPostfix cFunName <- case C.cIdentifierFromString (ctxEnableCpp ctx) funName of Left err -> fail $ "inlineItems: impossible, generated bad C identifier " ++ "funName:\n" ++ err Right x -> return x let decl = C.ParameterDeclaration (Just cFunName) proto let defs = prettyOneLine decl ++ " { " ++ cItems ++ " }\n" inlineCode $ Code { codeCallSafety = callSafety , codeLoc = Just loc , codeType = type_ , codeFunName = funName , codeDefs = defs , codeFunPtr = funPtr } ------------------------------------------------------------------------ -- Parsing runParserInQ :: (Hashable ident) => String -> C.CParserContext ident -> (forall m. C.CParser ident m => m a) -> TH.Q a runParserInQ s ctx p = do loc <- TH.location let (line, col) = TH.loc_start loc let parsecLoc = Parsec.newPos (TH.loc_filename loc) line col let p' = lift (Parsec.setPosition parsecLoc) *> p <* lift Parser.eof case C.runCParser ctx (TH.loc_filename loc) s p' of Left err -> do -- TODO consider prefixing with "error while parsing C" or similar fail $ show err Right res -> do return res data SomeEq = forall a. (Typeable a, Eq a) => SomeEq a instance Eq SomeEq where SomeEq x == SomeEq y = case cast x of Nothing -> False Just x' -> x' == y instance Show SomeEq where show _ = "<>" toSomeEq :: (Eq a, Typeable a) => a -> SomeEq toSomeEq x = SomeEq x fromSomeEq :: (Eq a, Typeable a) => SomeEq -> Maybe a fromSomeEq (SomeEq x) = cast x data ParameterType = Plain HaskellIdentifier -- The name of the captured variable | AntiQuote AntiQuoterId SomeEq deriving (Show, Eq) data ParseTypedC = ParseTypedC { ptcReturnType :: C.Type C.CIdentifier , ptcParameters :: [(C.CIdentifier, C.Type C.CIdentifier, ParameterType)] , ptcBody :: String } newtype Substitutions = Substitutions { unSubstitutions :: M.Map String (String -> String) } applySubstitutions :: String -> TH.Q String applySubstitutions str = do subs <- maybe mempty unSubstitutions <$> TH.getQ let substitution = msum $ flip map (M.toList subs) $ \( subName, subFunc ) -> Parsec.try $ do _ <- Parsec.string ('@' : subName ++ "(") subArg <- Parsec.manyTill Parsec.anyChar (Parsec.char ')') return (subFunc subArg) let someChar = (:[]) <$> Parsec.anyChar case Parsec.parse (many (substitution <|> someChar)) "" str of Left _ -> fail "Substitution failed (should be impossible)" Right chunks -> return (concat chunks) -- | Define macros that can be used in the nested Template Haskell expression. -- Macros can be used as @\@MACRO_NAME(input)@ in inline-c quotes, and will transform their input with the given function. -- They can be useful for passing in types when defining Haskell instances for C++ template types. substitute :: [ ( String, String -> String ) ] -> TH.Q a -> TH.Q a substitute subsList cont = do oldSubs <- maybe mempty unSubstitutions <$> TH.getQ let subs = M.fromList subsList let conflicting = M.intersection subs oldSubs newSubs <- if M.null conflicting then return (Substitutions (M.union oldSubs subs)) else fail ("Conflicting substitutions `" ++ show (M.keys conflicting) ++ "`") TH.putQ newSubs *> cont <* TH.putQ (Substitutions oldSubs) -- | Given a C type name, return the Haskell type in Template Haskell. The first parameter controls whether function pointers -- should be mapped as pure or IO functions. getHaskellType :: Bool -> String -> TH.TypeQ getHaskellType pureFunctions cTypeStr = do ctx <- getContext let cParseCtx = C.cCParserContext (ctxEnableCpp ctx) (typeNamesFromTypesTable (ctxTypesTable ctx)) cType <- runParserInQ cTypeStr cParseCtx C.parseType cToHs ctx (if pureFunctions then Pure else IO) cType -- To parse C declarations, we're faced with a bit of a problem: we want -- to parse the anti-quotations so that Haskell identifiers are -- accepted, but we want them to appear only as the root of -- declarations. For this reason, we parse allowing Haskell identifiers -- everywhere, and then we "purge" Haskell identifiers everywhere but at -- the root. parseTypedC :: forall m. C.CParser HaskellIdentifier m => Bool -> AntiQuoters -> m ParseTypedC -- ^ Returns the return type, the captured variables, and the body. parseTypedC useCpp antiQs = do -- Parse return type (consume spaces first) Parser.spaces cRetType <- purgeHaskellIdentifiers =<< C.parseType -- Parse the body void $ Parser.char '{' (cParams, cBody) <- evalStateT parseBody 0 return $ ParseTypedC cRetType cParams cBody where parseBody :: StateT Int m ([(C.CIdentifier, C.Type C.CIdentifier, ParameterType)], String) parseBody = do -- Note that this code does not use "lexing" combinators (apart -- when appropriate) because we want to make sure to preserve -- whitespace after we substitute things. s <- Parser.manyTill Parser.anyChar $ Parser.lookAhead (Parser.char '}' <|> Parser.char '$') (decls, s') <- msum [ do Parser.try $ do -- Try because we might fail to parse the 'eof' -- 'symbolic' because we want to consume whitespace void $ Parser.symbolic '}' Parser.eof return ([], "") , do void $ Parser.char '}' (decls, s') <- parseBody return (decls, "}" ++ s') , do void $ Parser.char '$' (decls1, s1) <- parseEscapedDollar <|> parseAntiQuote <|> parseTypedCapture (decls2, s2) <- parseBody return (decls1 ++ decls2, s1 ++ s2) ] return (decls, s ++ s') where parseAntiQuote :: StateT Int m ([(C.CIdentifier, C.Type C.CIdentifier, ParameterType)], String) parseAntiQuote = msum [ do void $ Parser.try (Parser.string $ antiQId ++ ":") Parser. "anti quoter id" (s, cTy, x) <- aqParser antiQ id' <- freshId s return ([(id', cTy, AntiQuote antiQId (toSomeEq x))], C.unCIdentifier id') | (antiQId, SomeAntiQuoter antiQ) <- Map.toList antiQs ] parseEscapedDollar :: StateT Int m ([a], String) parseEscapedDollar = do void $ Parser.char '$' return ([], "$") parseTypedCapture :: StateT Int m ([(C.CIdentifier, C.Type C.CIdentifier, ParameterType)], String) parseTypedCapture = do void $ Parser.symbolic '(' decl <- C.parseParameterDeclaration declType <- purgeHaskellIdentifiers $ C.parameterDeclarationType decl -- Purge the declaration type of all the Haskell identifiers. hId <- case C.parameterDeclarationId decl of Nothing -> fail $ pretty80 $ "Un-named captured variable in decl" <+> PP.pretty decl Just hId -> return hId id' <- freshId $ mangleHaskellIdentifier useCpp hId void $ Parser.char ')' return ([(id', declType, Plain hId)], C.unCIdentifier id') freshId s = do c <- get put $ c + 1 case C.cIdentifierFromString useCpp (C.unCIdentifier s ++ "_inline_c_" ++ show c) of Left _err -> error "freshId: The impossible happened" Right x -> return x -- The @m@ is polymorphic because we use this both for the plain -- parser and the StateT parser we use above. We only need 'fail'. purgeHaskellIdentifiers #if MIN_VERSION_base(4,13,0) :: forall n. MonadFail n #else :: forall n. (Applicative n, Monad n) #endif => C.Type HaskellIdentifier -> n (C.Type C.CIdentifier) purgeHaskellIdentifiers cTy = for cTy $ \hsIdent -> do let hsIdentS = unHaskellIdentifier hsIdent case C.cIdentifierFromString useCpp hsIdentS of Left err -> fail $ "Haskell identifier " ++ hsIdentS ++ " in illegal position" ++ "in C type\n" ++ pretty80 cTy ++ "\n" ++ "A C identifier was expected, but:\n" ++ err Right cIdent -> return cIdent quoteCode :: (String -> TH.ExpQ) -- ^ The parser -> TH.QuasiQuoter quoteCode p = TH.QuasiQuoter { TH.quoteExp = p , TH.quotePat = const $ fail "inline-c: quotePat not implemented (quoteCode)" , TH.quoteType = const $ fail "inline-c: quoteType not implemented (quoteCode)" , TH.quoteDec = const $ fail "inline-c: quoteDec not implemented (quoteCode)" } cToHs :: Context -> Purity -> C.Type C.CIdentifier -> TH.TypeQ cToHs ctx purity cTy = do mbHsTy <- convertType purity (ctxTypesTable ctx) cTy case mbHsTy of Nothing -> fail $ "Could not resolve Haskell type for C type " ++ pretty80 cTy Just hsTy -> return hsTy genericQuote :: Purity -> (TH.Loc -> TH.TypeQ -> C.Type C.CIdentifier -> [(C.CIdentifier, C.Type C.CIdentifier)] -> String -> TH.ExpQ) -- ^ Function building an Haskell expression, see 'inlineExp' for -- guidance on the other args. -> TH.QuasiQuoter genericQuote purity build = quoteCode $ \rawStr -> do ctx <- getContext here <- TH.location s <- applySubstitutions rawStr ParseTypedC cType cParams cExp <- runParserInQ s (haskellCParserContext (ctxEnableCpp ctx) (typeNamesFromTypesTable (ctxTypesTable ctx))) (parseTypedC (ctxEnableCpp ctx) (ctxAntiQuoters ctx)) hsType <- cToHs ctx purity cType hsParams <- forM cParams $ \(_cId, cTy, parTy) -> do case parTy of Plain s' -> do hsTy <- cToHs ctx purity cTy let hsName = TH.mkName (unHaskellIdentifier s') hsExp <- [| \cont -> cont ($(TH.varE hsName) :: $(return hsTy)) |] return (hsTy, hsExp) AntiQuote antiId dyn -> do case Map.lookup antiId (ctxAntiQuoters ctx) of Nothing -> fail $ "IMPOSSIBLE: could not find anti-quoter " ++ show antiId ++ ". (genericQuote)" Just (SomeAntiQuoter antiQ) -> case fromSomeEq dyn of Nothing -> fail $ "IMPOSSIBLE: could not cast value for anti-quoter " ++ show antiId ++ ". (genericQuote)" Just x -> aqMarshaller antiQ purity (ctxTypesTable ctx) cTy x let hsFunType = convertCFunSig hsType $ map fst hsParams let cParams' = [(cId, cTy) | (cId, cTy, _) <- cParams] ioCall <- buildFunCall ctx (build here hsFunType cType cParams' cExp) (map snd hsParams) [] -- If the user requested a pure function, make it so. case purity of Pure -> [| unsafePerformIO $(return ioCall) |] IO -> return ioCall where buildFunCall :: Context -> TH.ExpQ -> [TH.Exp] -> [TH.Name] -> TH.ExpQ buildFunCall _ctx f [] args = foldl (\f' arg -> [| $f' $(TH.varE arg) |]) f args buildFunCall ctx f (hsExp : params) args = [| $(return hsExp) $ \arg -> $(buildFunCall ctx f params (args ++ ['arg])) |] convertCFunSig :: TH.Type -> [TH.Type] -> TH.TypeQ convertCFunSig retType params0 = do go params0 where go [] = [t| IO $(return retType) |] go (paramType : params) = do [t| $(return paramType) -> $(go params) |] splitTypedC :: String -> (String, String) -- ^ Returns the type and the body separately splitTypedC s = (trim ty, case body of [] -> [] r -> r) where (ty, body) = span (/= '{') s trim x = L.dropWhileEnd C.isSpace (dropWhile C.isSpace x) -- | Data to parse for the 'funPtr' quasi-quoter. data FunPtrDecl = FunPtrDecl { funPtrReturnType :: C.Type C.CIdentifier , funPtrParameters :: [(C.CIdentifier, C.Type C.CIdentifier)] , funPtrBody :: String , funPtrName :: Maybe String } deriving (Eq, Show) funPtrQuote :: TH.Safety -> TH.QuasiQuoter funPtrQuote callSafety = quoteCode $ \rawCode -> do loc <- TH.location ctx <- getContext code <- applySubstitutions rawCode FunPtrDecl{..} <- runParserInQ code (C.cCParserContext (ctxEnableCpp ctx) (typeNamesFromTypesTable (ctxTypesTable ctx))) parse hsRetType <- cToHs ctx IO funPtrReturnType hsParams <- forM funPtrParameters (\(_ident, typ_) -> cToHs ctx IO typ_) let hsFunType = convertCFunSig hsRetType hsParams inlineItems callSafety True funPtrName loc hsFunType funPtrReturnType funPtrParameters funPtrBody where convertCFunSig :: TH.Type -> [TH.Type] -> TH.TypeQ convertCFunSig retType params0 = do go params0 where go [] = [t| IO $(return retType) |] go (paramType : params) = do [t| $(return paramType) -> $(go params) |] parse :: C.CParser C.CIdentifier m => m FunPtrDecl parse = do -- skip spaces Parser.spaces -- parse a proto C.ParameterDeclaration mbName protoTyp <- C.parseParameterDeclaration case protoTyp of C.Proto retType paramList -> do args <- forM paramList $ \decl -> case C.parameterDeclarationId decl of Nothing -> fail $ pretty80 $ "Un-named captured variable in decl" <+> PP.pretty decl Just declId -> return (declId, C.parameterDeclarationType decl) -- get the rest of the body void (Parser.symbolic '{') body <- parseBody return FunPtrDecl { funPtrReturnType = retType , funPtrParameters = args , funPtrBody = body , funPtrName = fmap C.unCIdentifier mbName } _ -> fail $ "Expecting function declaration" parseBody :: C.CParser C.CIdentifier m => m String parseBody = do s <- Parser.manyTill Parser.anyChar $ Parser.lookAhead (Parser.char '}') s' <- msum [ do Parser.try $ do -- Try because we might fail to parse the 'eof' -- 'symbolic' because we want to consume whitespace void $ Parser.symbolic '}' Parser.eof return "" , do void $ Parser.char '}' s' <- parseBody return ("}" ++ s') ] return (s ++ s') ------------------------------------------------------------------------ -- Utils pretty80 :: PP.Pretty a => a -> String pretty80 x = PP.displayS (PP.renderPretty 0.8 80 (PP.pretty x)) "" prettyOneLine :: PP.Pretty a => a -> String prettyOneLine x = PP.displayS (PP.renderCompact (PP.pretty x)) ""