{-# LANGUAGE CPP #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE NamedFieldPuns #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE RecordWildCards #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE ViewPatterns #-} ----------------------------------------------------------------------------- -- | -- Module : Language.Haskell.GHC.ExactPrint.Transform -- -- This module is currently under heavy development, and no promises are made -- about API stability. Use with care. -- -- We welcome any feedback / contributions on this, as it is the main point of -- the library. -- ----------------------------------------------------------------------------- module Language.Haskell.GHC.ExactPrint.Transform ( -- * The Transform Monad Transform , TransformT(..) , runTransform , runTransformFrom , runTransformFromT -- * Transform monad operations , logTr , logDataWithAnnsTr , getAnnsT, putAnnsT, modifyAnnsT , uniqueSrcSpanT , cloneT , getEntryDPT , setEntryDPT , transferEntryDPT , setPrecedingLinesDeclT , setPrecedingLinesT , addSimpleAnnT , addTrailingCommaT , removeTrailingCommaT -- ** Managing declarations, in Transform monad , HasTransform (..) , HasDecls (..) , hasDeclsSybTransform , hsDeclsGeneric , hsDeclsPatBind, hsDeclsPatBindD , replaceDeclsPatBind, replaceDeclsPatBindD , modifyDeclsT , modifyValD -- *** Utility, does not manage layout , hsDeclsValBinds, replaceDeclsValbinds -- ** Managing lists, Transform monad , insertAtStart , insertAtEnd , insertAfter , insertBefore -- *** Low level operations used in 'HasDecls' , balanceComments , balanceTrailingComments , moveTrailingComments -- ** Managing lists, pure functions , captureOrder , captureOrderAnnKey -- * Operations , isUniqueSrcSpan -- * Pure functions , mergeAnns , mergeAnnList , setPrecedingLinesDecl , setPrecedingLines , getEntryDP , setEntryDP , transferEntryDP , addTrailingComma , wrapSig, wrapDecl , decl2Sig, decl2Bind ) where import Language.Haskell.GHC.ExactPrint.Types import Language.Haskell.GHC.ExactPrint.Utils import Control.Monad.RWS import qualified Bag as GHC import qualified FastString as GHC import qualified GHC as GHC hiding (parseModule) import qualified Data.Generics as SYB import Data.Data import Data.List import Data.Maybe import qualified Data.Map as Map import Data.Functor.Identity -- import Control.Monad.Identity import Control.Monad.State import Control.Monad.Writer -- import Debug.Trace ------------------------------------------------------------------------------ -- Transformation of source elements -- | Monad type for updating the AST and managing the annotations at the same -- time. The W state is used to generate logging information if required. type Transform = TransformT Identity -- |Monad transformer version of 'Transform' monad newtype TransformT m a = TransformT { runTransformT :: RWST () [String] (Anns,Int) m a } deriving (Monad,Applicative,Functor ,MonadReader () ,MonadWriter [String] ,MonadState (Anns,Int) -- ,MonadTrans ) -- | Run a transformation in the 'Transform' monad, returning the updated -- annotations and any logging generated via 'logTr' runTransform :: Anns -> Transform a -> (a,(Anns,Int),[String]) runTransform ans f = runTransformFrom 0 ans f -- | Run a transformation in the 'Transform' monad, returning the updated -- annotations and any logging generated via 'logTr', allocating any new -- SrcSpans from the provided initial value. runTransformFrom :: Int -> Anns -> Transform a -> (a,(Anns,Int),[String]) runTransformFrom seed ans f = runRWS (runTransformT f) () (ans,seed) -- |Run a monad transformer stack for the 'TransformT' monad transformer runTransformFromT :: (Monad m) => Int -> Anns -> TransformT m a -> m (a,(Anns,Int),[String]) runTransformFromT seed ans f = runRWST (runTransformT f) () (ans,seed) -- |Log a string to the output of the Monad logTr :: (Monad m) => String -> TransformT m () logTr str = tell [str] -- |Log a representation of the given AST with annotations to the output of the -- Monad logDataWithAnnsTr :: (Monad m) => (SYB.Data a) => String -> a -> TransformT m () logDataWithAnnsTr str ast = do anns <- getAnnsT logTr $ str ++ showAnnData anns 0 ast -- |Access the 'Anns' being modified in this transformation getAnnsT :: (Monad m) => TransformT m Anns getAnnsT = gets fst -- |Replace the 'Anns' after any changes putAnnsT :: (Monad m) => Anns -> TransformT m () putAnnsT ans = do (_,col) <- get put (ans,col) -- |Change the stored 'Anns' modifyAnnsT :: (Monad m) => (Anns -> Anns) -> TransformT m () modifyAnnsT f = do ans <- getAnnsT putAnnsT (f ans) -- --------------------------------------------------------------------- -- |Once we have 'Anns', a 'GHC.SrcSpan' is used purely as part of an 'AnnKey' -- to index into the 'Anns'. If we need to add new elements to the AST, they -- need their own 'GHC.SrcSpan' for this. uniqueSrcSpanT :: Transform GHC.SrcSpan uniqueSrcSpanT = do (an,col) <- get put (an,col + 1 ) let pos = GHC.mkSrcLoc (GHC.mkFastString "ghc-exactprint") (-1) col return $ GHC.mkSrcSpan pos pos -- |Test whether a given 'GHC.SrcSpan' was generated by 'uniqueSrcSpanT' isUniqueSrcSpan :: GHC.SrcSpan -> Bool isUniqueSrcSpan ss = srcSpanStartLine ss == -1 -- --------------------------------------------------------------------- -- |Make a copy of an AST element, replacing the existing SrcSpans with new -- ones, and duplicating the matching annotations. cloneT :: (Data a,Typeable a) => a -> Transform (a, [(GHC.SrcSpan, GHC.SrcSpan)]) cloneT ast = do runWriterT $ SYB.everywhereM (return `SYB.ext2M` replaceLocated) ast where replaceLocated :: forall loc a. (Typeable loc,Typeable a, Data a) => (GHC.GenLocated loc a) -> WriterT [(GHC.SrcSpan, GHC.SrcSpan)] Transform (GHC.GenLocated loc a) replaceLocated (GHC.L l t) = do case cast l :: Maybe GHC.SrcSpan of Just ss -> do newSpan <- lift uniqueSrcSpanT lift $ modifyAnnsT (\anns -> case Map.lookup (mkAnnKey (GHC.L ss t)) anns of Nothing -> anns Just an -> Map.insert (mkAnnKey (GHC.L newSpan t)) an anns) tell [(ss, newSpan)] return $ fromJust . cast $ GHC.L newSpan t Nothing -> return (GHC.L l t) -- --------------------------------------------------------------------- -- |If a list has been re-ordered or had items added, capture the new order in -- the appropriate 'annSortKey' attached to the 'Annotation' for the first -- parameter. captureOrder :: (Data a) => GHC.Located a -> [GHC.Located b] -> Anns -> Anns captureOrder parent ls ans = captureOrderAnnKey (mkAnnKey parent) ls ans -- |If a list has been re-ordered or had items added, capture the new order in -- the appropriate 'annSortKey' item of the supplied 'AnnKey' captureOrderAnnKey :: AnnKey -> [GHC.Located b] -> Anns -> Anns captureOrderAnnKey parentKey ls ans = ans' where newList = map GHC.getLoc ls reList = Map.adjust (\an -> an {annSortKey = Just newList }) parentKey ans' = reList ans -- --------------------------------------------------------------------- -- |Pure function to convert a 'GHC.LHsDecl' to a 'GHC.LHsBind'. This does -- nothing to any annotations that may be attached to either of the elements. -- It is used as a utility function in 'replaceDecls' decl2Bind :: GHC.LHsDecl name -> [GHC.LHsBind name] decl2Bind (GHC.L l (GHC.ValD s)) = [GHC.L l s] decl2Bind _ = [] -- |Pure function to convert a 'GHC.LSig' to a 'GHC.LHsBind'. This does -- nothing to any annotations that may be attached to either of the elements. -- It is used as a utility function in 'replaceDecls' decl2Sig :: GHC.LHsDecl name -> [GHC.LSig name] decl2Sig (GHC.L l (GHC.SigD s)) = [GHC.L l s] decl2Sig _ = [] -- --------------------------------------------------------------------- -- |Convert a 'GHC.LSig' into a 'GHC.LHsDecl' wrapSig :: GHC.LSig GHC.RdrName -> GHC.LHsDecl GHC.RdrName wrapSig (GHC.L l s) = GHC.L l (GHC.SigD s) -- --------------------------------------------------------------------- -- |Convert a 'GHC.LHsBind' into a 'GHC.LHsDecl' wrapDecl :: GHC.LHsBind GHC.RdrName -> GHC.LHsDecl GHC.RdrName wrapDecl (GHC.L l s) = GHC.L l (GHC.ValD s) -- --------------------------------------------------------------------- -- |Create a simple 'Annotation' without comments, and attach it to the first -- parameter. addSimpleAnnT :: (Data a) => GHC.Located a -> DeltaPos -> [(KeywordId, DeltaPos)] -> Transform () addSimpleAnnT ast dp kds = do let ann = annNone { annEntryDelta = dp , annsDP = kds } modifyAnnsT (Map.insert (mkAnnKey ast) ann) -- --------------------------------------------------------------------- -- |Add a trailing comma annotation, unless there is already one addTrailingCommaT :: (Data a) => GHC.Located a -> Transform () addTrailingCommaT ast = do modifyAnnsT (addTrailingComma ast (DP (0,0))) -- --------------------------------------------------------------------- -- |Remove a trailing comma annotation, if there is one one removeTrailingCommaT :: (Data a) => GHC.Located a -> Transform () removeTrailingCommaT ast = do modifyAnnsT (removeTrailingComma ast) -- --------------------------------------------------------------------- -- |'Transform' monad version of 'getEntryDP' getEntryDPT :: (Data a) => GHC.Located a -> Transform DeltaPos getEntryDPT ast = do anns <- getAnnsT return (getEntryDP anns ast) -- --------------------------------------------------------------------- -- |'Transform' monad version of 'getEntryDP' setEntryDPT :: (Data a) => GHC.Located a -> DeltaPos -> Transform () setEntryDPT ast dp = do modifyAnnsT (setEntryDP ast dp) -- --------------------------------------------------------------------- -- |'Transform' monad version of 'transferEntryDP' transferEntryDPT :: (Data a,Data b) => GHC.Located a -> GHC.Located b -> Transform () transferEntryDPT a b = modifyAnnsT (transferEntryDP a b) -- --------------------------------------------------------------------- -- |'Transform' monad version of 'setPrecedingLinesDecl' setPrecedingLinesDeclT :: GHC.LHsDecl GHC.RdrName -> Int -> Int -> Transform () setPrecedingLinesDeclT ld n c = modifyAnnsT (setPrecedingLinesDecl ld n c) -- --------------------------------------------------------------------- -- |'Transform' monad version of 'setPrecedingLines' setPrecedingLinesT :: (SYB.Data a) => GHC.Located a -> Int -> Int -> Transform () setPrecedingLinesT ld n c = modifyAnnsT (setPrecedingLines ld n c) -- --------------------------------------------------------------------- -- | Left bias pair union mergeAnns :: Anns -> Anns -> Anns mergeAnns = Map.union -- |Combine a list of annotations mergeAnnList :: [Anns] -> Anns mergeAnnList [] = error "mergeAnnList must have at lease one entry" mergeAnnList (x:xs) = foldr mergeAnns x xs -- --------------------------------------------------------------------- -- |Unwrap a HsDecl and call setPrecedingLines on it -- ++AZ++ TODO: get rid of this, it is a synonym only setPrecedingLinesDecl :: GHC.LHsDecl GHC.RdrName -> Int -> Int -> Anns -> Anns setPrecedingLinesDecl ld n c ans = setPrecedingLines ld n c ans -- --------------------------------------------------------------------- -- | Adjust the entry annotations to provide an `n` line preceding gap setPrecedingLines :: (SYB.Data a) => GHC.Located a -> Int -> Int -> Anns -> Anns setPrecedingLines ast n c anne = setEntryDP ast (DP (n,c)) anne -- --------------------------------------------------------------------- -- |Return the true entry 'DeltaPos' from the annotation for a given AST -- element. This is the 'DeltaPos' ignoring any comments. getEntryDP :: (Data a) => Anns -> GHC.Located a -> DeltaPos getEntryDP anns ast = case Map.lookup (mkAnnKey ast) anns of Nothing -> DP (0,0) Just ann -> annTrueEntryDelta ann -- --------------------------------------------------------------------- -- |Set the true entry 'DeltaPos' from the annotation for a given AST -- element. This is the 'DeltaPos' ignoring any comments. setEntryDP :: (Data a) => GHC.Located a -> DeltaPos -> Anns -> Anns setEntryDP ast dp anns = case Map.lookup (mkAnnKey ast) anns of Nothing -> Map.insert (mkAnnKey ast) (annNone { annEntryDelta = dp}) anns Just ann -> Map.insert (mkAnnKey ast) (ann' { annEntryDelta = annCommentEntryDelta ann' dp}) anns where ann' = setCommentEntryDP ann dp -- --------------------------------------------------------------------- -- |When setting an entryDP, the leading comment needs to be adjusted too setCommentEntryDP :: Annotation -> DeltaPos -> Annotation -- setCommentEntryDP ann dp = error $ "setCommentEntryDP:ann'=" ++ show ann' setCommentEntryDP ann dp = ann' where ann' = case (annPriorComments ann) of [] -> ann [(pc,_)] -> ann { annPriorComments = [(pc,dp)] } ((pc,_):pcs) -> ann { annPriorComments = ((pc,dp):pcs) } -- --------------------------------------------------------------------- -- |Take the annEntryDelta associated with the first item and associate it with the second. -- Also transfer any comments occuring before it. transferEntryDP :: (SYB.Data a, SYB.Data b) => GHC.Located a -> GHC.Located b -> Anns -> Anns transferEntryDP a b anns = (const anns2) anns where maybeAnns = do -- Maybe monad anA <- Map.lookup (mkAnnKey a) anns anB <- Map.lookup (mkAnnKey b) anns let anB' = Ann { annEntryDelta = DP (0,0) -- Need to adjust for comments after , annPriorComments = annPriorComments anB , annFollowingComments = annFollowingComments anB , annsDP = annsDP anB , annSortKey = annSortKey anB , annCapturedSpan = annCapturedSpan anB } return ((Map.insert (mkAnnKey b) anB' anns),annLeadingCommentEntryDelta anA) (anns',dp) = fromMaybe (error $ "transferEntryDP: lookup failed (a,b)=" ++ show (mkAnnKey a,mkAnnKey b)) maybeAnns anns2 = setEntryDP b dp anns' -- --------------------------------------------------------------------- addTrailingComma :: (SYB.Data a) => GHC.Located a -> DeltaPos -> Anns -> Anns addTrailingComma a dp anns = case Map.lookup (mkAnnKey a) anns of Nothing -> anns Just an -> case find isAnnComma (annsDP an) of Nothing -> Map.insert (mkAnnKey a) (an { annsDP = annsDP an ++ [(G GHC.AnnComma,dp)]}) anns Just _ -> anns where isAnnComma (G GHC.AnnComma,_) = True isAnnComma _ = False -- --------------------------------------------------------------------- removeTrailingComma :: (SYB.Data a) => GHC.Located a -> Anns -> Anns removeTrailingComma a anns = case Map.lookup (mkAnnKey a) anns of Nothing -> anns Just an -> case find isAnnComma (annsDP an) of Nothing -> anns Just _ -> Map.insert (mkAnnKey a) (an { annsDP = filter (not.isAnnComma) (annsDP an) }) anns where isAnnComma (G GHC.AnnComma,_) = True isAnnComma _ = False -- --------------------------------------------------------------------- -- |The relatavise phase puts all comments appearing between the end of one AST -- item and the beginning of the next as 'annPriorComments' for the second one. -- This function takes two adjacent AST items and moves any 'annPriorComments' -- from the second one to the 'annFollowingComments' of the first if they belong -- to it instead. This is typically required before deleting or duplicating -- either of the AST elements. balanceComments :: (Data a,Data b) => GHC.Located a -> GHC.Located b -> Transform () balanceComments first second = do -- ++AZ++ : replace the nested casts with appropriate SYB.gmapM -- logTr $ "balanceComments entered" -- logDataWithAnnsTr "first" first case cast first :: Maybe (GHC.LHsDecl GHC.RdrName) of Just (GHC.L l (GHC.ValD fb@(GHC.FunBind{}))) -> do balanceCommentsFB (GHC.L l fb) second _ -> case cast first :: Maybe (GHC.LHsBind GHC.RdrName) of Just fb'@(GHC.L _ (GHC.FunBind{})) -> do balanceCommentsFB fb' second _ -> balanceComments' first second -- |Prior to moving an AST element, make sure any trailing comments belonging to -- it are attached to it, and not the following element. Of necessity this is a -- heuristic process, to be tuned later. Possibly a variant should be provided -- with a passed-in decision function. balanceComments' :: (Data a,Data b) => GHC.Located a -> GHC.Located b -> Transform () balanceComments' first second = do let k1 = mkAnnKey first k2 = mkAnnKey second moveComments p ans = ans' where an1 = gfromJust "balanceComments' k1" $ Map.lookup k1 ans an2 = gfromJust "balanceComments' k2" $ Map.lookup k2 ans cs1f = annFollowingComments an1 cs2b = annPriorComments an2 (move,stay) = break p cs2b an1' = an1 { annFollowingComments = cs1f ++ move} an2' = an2 { annPriorComments = stay} ans' = Map.insert k1 an1' $ Map.insert k2 an2' ans simpleBreak (_,DP (r,_c)) = r > 0 modifyAnnsT (moveComments simpleBreak) -- |Once 'balanceComments' has been called to move trailing comments to a -- 'GHC.FunBind', these need to be pushed down from the top level to the last -- 'GHC.Match' if that 'GHC.Match' needs to be manipulated. balanceCommentsFB :: (Data b) => GHC.LHsBind GHC.RdrName -> GHC.Located b -> Transform () balanceCommentsFB (GHC.L _ (GHC.FunBind _ _ (GHC.MG matches _ _ _) _ _ _)) second = do -- logTr $ "balanceCommentsFB entered" balanceComments' (last matches) second balanceCommentsFB f s = balanceComments' f s -- --------------------------------------------------------------------- -- |After moving an AST element, make sure any comments that may belong -- with the following element in fact do. Of necessity this is a heuristic -- process, to be tuned later. Possibly a variant should be provided with a -- passed-in decision function. balanceTrailingComments :: (Monad m) => (Data a,Data b) => GHC.Located a -> GHC.Located b -> TransformT m [(Comment, DeltaPos)] balanceTrailingComments first second = do let k1 = mkAnnKey first k2 = mkAnnKey second moveComments p ans = (ans',move) where an1 = gfromJust "balanceTrailingComments k1" $ Map.lookup k1 ans an2 = gfromJust "balanceTrailingComments k2" $ Map.lookup k2 ans cs1f = annFollowingComments an1 (move,stay) = break p cs1f an1' = an1 { annFollowingComments = stay } ans' = Map.insert k1 an1' $ Map.insert k2 an2 ans simpleBreak (_,DP (r,_c)) = r > 0 ans <- getAnnsT let (ans',mov) = moveComments simpleBreak ans putAnnsT ans' return mov -- --------------------------------------------------------------------- -- ++AZ++ TODO: This needs to be renamed/reworked, based on what it actually gets used for -- |Move any 'annFollowingComments' values from the 'Annotation' associated to -- the first parameter to that of the second. moveTrailingComments :: (Data a,Data b) => GHC.Located a -> GHC.Located b -> Transform () moveTrailingComments first second = do let k1 = mkAnnKey first k2 = mkAnnKey second moveComments ans = ans' where an1 = gfromJust "moveTrailingComments k1" $ Map.lookup k1 ans an2 = gfromJust "moveTrailingComments k2" $ Map.lookup k2 ans cs1f = annFollowingComments an1 cs2f = annFollowingComments an2 an1' = an1 { annFollowingComments = [] } an2' = an2 { annFollowingComments = cs1f ++ cs2f } ans' = Map.insert k1 an1' $ Map.insert k2 an2' ans modifyAnnsT moveComments -- --------------------------------------------------------------------- -- |Insert a declaration into an AST element having sub-declarations -- (@HasDecls@) according to the given location function. insertAt :: (Data ast, HasDecls (GHC.Located ast)) => (GHC.LHsDecl GHC.RdrName -> [GHC.LHsDecl GHC.RdrName] -> [GHC.LHsDecl GHC.RdrName]) -> GHC.Located ast -> GHC.LHsDecl GHC.RdrName -> Transform (GHC.Located ast) insertAt f t decl = do oldDecls <- hsDecls t replaceDecls t (f decl oldDecls) -- |Insert a declaration at the beginning or end of the subdecls of the given -- AST item insertAtStart, insertAtEnd :: (Data ast, HasDecls (GHC.Located ast)) => GHC.Located ast -> GHC.LHsDecl GHC.RdrName -> Transform (GHC.Located ast) insertAtStart = insertAt (:) insertAtEnd = insertAt (\x xs -> xs ++ [x]) -- |Insert a declaration at a specific location in the subdecls of the given -- AST item insertAfter, insertBefore :: (Data ast, HasDecls (GHC.Located ast)) => GHC.Located old -> GHC.Located ast -> GHC.LHsDecl GHC.RdrName -> Transform (GHC.Located ast) insertAfter (GHC.getLoc -> k) = insertAt findAfter where findAfter x xs = let (fs, b:bs) = span (\(GHC.L l _) -> l /= k) xs in fs ++ (b : x : bs) insertBefore (GHC.getLoc -> k) = insertAt findBefore where findBefore x xs = let (fs, bs) = span (\(GHC.L l _) -> l /= k) xs in fs ++ (x : bs) -- ===================================================================== -- start of HasDecls instances -- ===================================================================== -- |Provide a means to get and process the immediate child declartions of a -- given AST element. class (Data t) => HasDecls t where -- ++AZ++: TODO: add tests to confirm that hsDecls followed by replaceDecls is idempotent -- | Return the 'GHC.HsDecl's that are directly enclosed in the -- given syntax phrase. They are always returned in the wrapped 'GHC.HsDecl' -- form, even if orginating in local decls. This is safe, as annotations -- never attach to the wrapper, only to the wrapped item. hsDecls :: (Monad m) => t -> TransformT m [GHC.LHsDecl GHC.RdrName] -- | Replace the directly enclosed decl list by the given -- decl list. Runs in the 'Transform' monad to be able to update list order -- annotations, and rebalance comments and other layout changes as needed. -- -- For example, a call on replaceDecls for a wrapped 'GHC.FunBind' having no -- where clause will convert -- -- @ -- -- |This is a function -- foo = x -- comment1 -- @ -- in to -- -- @ -- -- |This is a function -- foo = x -- comment1 -- where -- nn = 2 -- @ replaceDecls :: (Monad m) => t -> [GHC.LHsDecl GHC.RdrName] -> TransformT m t -- --------------------------------------------------------------------- instance HasDecls GHC.ParsedSource where hsDecls (GHC.L _ (GHC.HsModule _mn _exps _imps decls _ _)) = return decls replaceDecls m@(GHC.L l (GHC.HsModule mn exps imps _decls deps haddocks)) decls = do logTr "replaceDecls LHsModule" modifyAnnsT (captureOrder m decls) return (GHC.L l (GHC.HsModule mn exps imps decls deps haddocks)) -- --------------------------------------------------------------------- instance HasDecls (GHC.LMatch GHC.RdrName (GHC.LHsExpr GHC.RdrName)) where hsDecls d@(GHC.L _ (GHC.Match _ _ _ (GHC.GRHSs _ lb))) = do decls <- hsDeclsValBinds lb orderedDecls d decls replaceDecls m@(GHC.L l (GHC.Match mf p t (GHC.GRHSs rhs binds))) [] = do logTr "replaceDecls LMatch" let noWhere (G GHC.AnnWhere,_) = False noWhere _ = True removeWhere mkds = case Map.lookup (mkAnnKey m) mkds of Nothing -> error "wtf" Just ann -> Map.insert (mkAnnKey m) ann1 mkds where ann1 = ann { annsDP = filter noWhere (annsDP ann) } modifyAnnsT removeWhere binds' <- replaceDeclsValbinds binds [] return (GHC.L l (GHC.Match mf p t (GHC.GRHSs rhs binds'))) replaceDecls m@(GHC.L l (GHC.Match mf p t (GHC.GRHSs rhs binds))) newBinds = do logTr "replaceDecls LMatch" -- Need to throw in a fresh where clause if the binds were empty, -- in the annotations. case binds of GHC.EmptyLocalBinds -> do let addWhere mkds = case Map.lookup (mkAnnKey m) mkds of Nothing -> error "wtf" Just ann -> Map.insert (mkAnnKey m) ann1 mkds where ann1 = ann { annsDP = annsDP ann ++ [(G GHC.AnnWhere,DP (1,2))] } modifyAnnsT addWhere modifyAnnsT (setPrecedingLines (ghead "LMatch.replaceDecls" newBinds) 1 4) -- only move the comment if the original where clause was empty. toMove <- balanceTrailingComments m m insertCommentBefore (mkAnnKey m) toMove (matchApiAnn GHC.AnnWhere) _ -> return () modifyAnnsT (captureOrderAnnKey (mkAnnKey m) newBinds) binds' <- replaceDeclsValbinds binds newBinds -- logDataWithAnnsTr "Match.replaceDecls:binds'" binds' return (GHC.L l (GHC.Match mf p t (GHC.GRHSs rhs binds'))) -- --------------------------------------------------------------------- instance HasDecls (GHC.LHsExpr GHC.RdrName) where hsDecls ls@(GHC.L _ (GHC.HsLet decls _ex)) = do ds <- hsDeclsValBinds decls orderedDecls ls ds hsDecls _ = return [] replaceDecls e@(GHC.L l (GHC.HsLet decls ex)) newDecls = do logTr "replaceDecls HsLet" modifyAnnsT (captureOrder e newDecls) decls' <- replaceDeclsValbinds decls newDecls return (GHC.L l (GHC.HsLet decls' ex)) replaceDecls (GHC.L l (GHC.HsPar e)) newDecls = do logTr "replaceDecls HsPar" e' <- replaceDecls e newDecls return (GHC.L l (GHC.HsPar e')) replaceDecls old _new = error $ "replaceDecls (GHC.LHsExpr GHC.RdrName) undefined for:" ++ showGhc old -- --------------------------------------------------------------------- -- | Extract the immediate declarations for a 'GHC.PatBind' wrapped in a 'GHC.ValD'. This -- cannot be a member of 'HasDecls' because a 'GHC.FunBind' is not idempotent -- for 'hsDecls' \/ 'replaceDecls'. 'hsDeclsPatBindD' \/ 'replaceDeclsPatBindD' is -- idempotent. hsDeclsPatBindD :: (Monad m) => GHC.LHsDecl GHC.RdrName -> TransformT m [GHC.LHsDecl GHC.RdrName] hsDeclsPatBindD (GHC.L l (GHC.ValD d)) = hsDeclsPatBind (GHC.L l d) hsDeclsPatBindD x = error $ "hsDeclsPatBindD called for:" ++ showGhc x -- | Extract the immediate declarations for a 'GHC.PatBind'. This -- cannot be a member of 'HasDecls' because a 'GHC.FunBind' is not idempotent -- for 'hsDecls' \/ 'replaceDecls'. 'hsDeclsPatBind' \/ 'replaceDeclsPatBind' is -- idempotent. hsDeclsPatBind :: (Monad m) => GHC.LHsBind GHC.RdrName -> TransformT m [GHC.LHsDecl GHC.RdrName] hsDeclsPatBind d@(GHC.L _ (GHC.PatBind _ (GHC.GRHSs _grhs lb) _ _ _)) = do decls <- hsDeclsValBinds lb orderedDecls d decls hsDeclsPatBind x = error $ "hsDeclsPatBind called for:" ++ showGhc x -- ------------------------------------- -- | Replace the immediate declarations for a 'GHC.PatBind' wrapped in a 'GHC.ValD'. This -- cannot be a member of 'HasDecls' because a 'GHC.FunBind' is not idempotent -- for 'hsDecls' \/ 'replaceDecls'. 'hsDeclsPatBindD' \/ 'replaceDeclsPatBindD' is -- idempotent. replaceDeclsPatBindD :: (Monad m) => GHC.LHsDecl GHC.RdrName -> [GHC.LHsDecl GHC.RdrName] -> TransformT m (GHC.LHsDecl GHC.RdrName) replaceDeclsPatBindD (GHC.L l (GHC.ValD d)) newDecls = do (GHC.L _ d') <- replaceDeclsPatBind (GHC.L l d) newDecls return (GHC.L l (GHC.ValD d')) replaceDeclsPatBindD x _ = error $ "replaceDeclsPatBindD called for:" ++ showGhc x -- | Replace the immediate declarations for a 'GHC.PatBind'. This -- cannot be a member of 'HasDecls' because a 'GHC.FunBind' is not idempotent -- for 'hsDecls' \/ 'replaceDecls'. 'hsDeclsPatBind' \/ 'replaceDeclsPatBind' is -- idempotent. replaceDeclsPatBind :: (Monad m) => GHC.LHsBind GHC.RdrName -> [GHC.LHsDecl GHC.RdrName] -> TransformT m (GHC.LHsBind GHC.RdrName) replaceDeclsPatBind p@(GHC.L l (GHC.PatBind a (GHC.GRHSs rhss binds) b c d)) newDecls = do logTr "replaceDecls PatBind" -- Need to throw in a fresh where clause if the binds were empty, -- in the annotations. case binds of GHC.EmptyLocalBinds -> do let addWhere mkds = case Map.lookup (mkAnnKey p) mkds of Nothing -> error "wtf" Just ann -> Map.insert (mkAnnKey p) ann1 mkds where ann1 = ann { annsDP = annsDP ann ++ [(G GHC.AnnWhere,DP (1,2))] } modifyAnnsT addWhere modifyAnnsT (setPrecedingLines (ghead "LMatch.replaceDecls" newDecls) 1 4) _ -> return () modifyAnnsT (captureOrderAnnKey (mkAnnKey p) newDecls) binds' <- replaceDeclsValbinds binds newDecls return (GHC.L l (GHC.PatBind a (GHC.GRHSs rhss binds') b c d)) replaceDeclsPatBind x _ = error $ "replaceDeclsPatBind called for:" ++ showGhc x -- --------------------------------------------------------------------- instance HasDecls (GHC.LStmt GHC.RdrName (GHC.LHsExpr GHC.RdrName)) where hsDecls ls@(GHC.L _ (GHC.LetStmt lb)) = do decls <- hsDeclsValBinds lb orderedDecls ls decls hsDecls (GHC.L _ (GHC.LastStmt e _)) = hsDecls e hsDecls (GHC.L _ (GHC.BindStmt _pat e _ _)) = hsDecls e hsDecls (GHC.L _ (GHC.BodyStmt e _ _ _)) = hsDecls e hsDecls _ = return [] replaceDecls s@(GHC.L l (GHC.LetStmt lb)) newDecls = do modifyAnnsT (captureOrder s newDecls) lb' <- replaceDeclsValbinds lb newDecls return (GHC.L l (GHC.LetStmt lb')) replaceDecls (GHC.L l (GHC.LastStmt e se)) newDecls = do e' <- replaceDecls e newDecls return (GHC.L l (GHC.LastStmt e' se)) replaceDecls (GHC.L l (GHC.BindStmt pat e a b)) newDecls = do e' <- replaceDecls e newDecls return (GHC.L l (GHC.BindStmt pat e' a b)) replaceDecls (GHC.L l (GHC.BodyStmt e a b c)) newDecls = do e' <- replaceDecls e newDecls return (GHC.L l (GHC.BodyStmt e' a b c)) replaceDecls x _newDecls = return x -- ===================================================================== -- end of HasDecls instances -- ===================================================================== -- --------------------------------------------------------------------- -- |Do a transformation on an AST fragment by providing a function to process -- the general case and one specific for a 'GHC.LHsBind'. This is required -- because a 'GHC.FunBind' may have multiple 'GHC.Match' items, so we cannot -- gurantee that 'replaceDecls' after 'hsDecls' is idempotent. hasDeclsSybTransform :: (SYB.Data t2, SYB.Typeable t2,Monad m) => (forall t. HasDecls t => t -> m t) -- ^Worker function for the general case -> (GHC.LHsBind GHC.RdrName -> m (GHC.LHsBind GHC.RdrName)) -- ^Worker function for FunBind/PatBind -> t2 -- ^Item to be updated -> m t2 hasDeclsSybTransform workerHasDecls workerBind t = trf t where trf = SYB.mkM parsedSource `SYB.extM` lmatch `SYB.extM` lexpr `SYB.extM` lstmt `SYB.extM` lhsbind `SYB.extM` lvald parsedSource (p::GHC.ParsedSource) = workerHasDecls p lmatch (lm::GHC.LMatch GHC.RdrName (GHC.LHsExpr GHC.RdrName)) = workerHasDecls lm lexpr (le::GHC.LHsExpr GHC.RdrName) = workerHasDecls le lstmt (d::GHC.LStmt GHC.RdrName (GHC.LHsExpr GHC.RdrName)) = workerHasDecls d lhsbind (b@(GHC.L _ GHC.FunBind{}):: GHC.LHsBind GHC.RdrName) = workerBind b lhsbind b@(GHC.L _ GHC.PatBind{}) = workerBind b lhsbind x = return x lvald (GHC.L l (GHC.ValD d)) = do (GHC.L _ d') <- lhsbind (GHC.L l d) return (GHC.L l (GHC.ValD d')) lvald x = return x -- --------------------------------------------------------------------- -- |A 'GHC.FunBind' wraps up one or more 'GHC.Match' items. 'hsDecls' cannot -- return anything for these as there is not meaningful 'replaceDecls' for it. -- This function provides a version of 'hsDecls' that returns the 'GHC.FunBind' -- decls too, where they are needed for analysis only. hsDeclsGeneric :: (SYB.Data t,SYB.Typeable t) => t -> Transform [GHC.LHsDecl GHC.RdrName] hsDeclsGeneric t = q t where q = return [] `SYB.mkQ` parsedSource `SYB.extQ` lmatch `SYB.extQ` lexpr `SYB.extQ` lstmt `SYB.extQ` lhsbind `SYB.extQ` lhsbindd `SYB.extQ` localbinds parsedSource (p::GHC.ParsedSource) = hsDecls p lmatch (lm::GHC.LMatch GHC.RdrName (GHC.LHsExpr GHC.RdrName)) = hsDecls lm lexpr (le::GHC.LHsExpr GHC.RdrName) = hsDecls le lstmt (d::GHC.LStmt GHC.RdrName (GHC.LHsExpr GHC.RdrName)) = hsDecls d -- --------------------------------- lhsbind :: GHC.LHsBind GHC.RdrName -> Transform [GHC.LHsDecl GHC.RdrName] lhsbind (GHC.L _ (GHC.FunBind _ _ (GHC.MG matches _ _ _) _ _ _)) = do dss <- mapM hsDecls matches return (concat dss) lhsbind p@(GHC.L _ (GHC.PatBind{})) = do hsDeclsPatBind p lhsbind _ = return [] -- --------------------------------- lhsbindd (GHC.L l (GHC.ValD d)) = lhsbind (GHC.L l d) lhsbindd _ = return [] -- --------------------------------- localbinds :: GHC.HsLocalBinds GHC.RdrName -> Transform [GHC.LHsDecl GHC.RdrName] localbinds d = hsDeclsValBinds d -- --------------------------------------------------------------------- -- |Look up the annotated order and sort the decls accordingly orderedDecls :: (Data a,Monad m) => GHC.Located a -> [GHC.LHsDecl GHC.RdrName] -> TransformT m [GHC.LHsDecl GHC.RdrName] orderedDecls parent decls = do ans <- getAnnsT case getAnnotationEP parent ans of Nothing -> error $ "orderedDecls:no annotation for:" ++ showAnnData emptyAnns 0 parent Just ann -> case annSortKey ann of Nothing -> do return decls Just keys -> do let ds = map (\s -> (GHC.getLoc s,s)) decls ordered = orderByKey ds keys return ordered -- --------------------------------------------------------------------- -- | Utility function for extracting decls from 'GHC.HsLocalBinds'. Use with -- care, as this does not necessarily return the declarations in order, the -- ordering should be done by the calling function from the 'GHC.HsLocalBinds' -- context in the AST. hsDeclsValBinds :: (Monad m) => GHC.HsLocalBinds GHC.RdrName -> TransformT m [GHC.LHsDecl GHC.RdrName] hsDeclsValBinds lb = case lb of GHC.HsValBinds (GHC.ValBindsIn bs sigs) -> do let bds = map wrapDecl (GHC.bagToList bs) sds = map wrapSig sigs return (bds ++ sds) GHC.HsValBinds (GHC.ValBindsOut _ _) -> error $ "hsDecls.ValbindsOut not valid" GHC.HsIPBinds _ -> return [] GHC.EmptyLocalBinds -> return [] -- | Utility function for returning decls to 'GHC.HsLocalBinds'. Use with -- care, as this does not manage the declaration order, the -- ordering should be done by the calling function from the 'GHC.HsLocalBinds' -- context in the AST. replaceDeclsValbinds :: (Monad m) => GHC.HsLocalBinds GHC.RdrName -> [GHC.LHsDecl GHC.RdrName] -> TransformT m (GHC.HsLocalBinds GHC.RdrName) replaceDeclsValbinds _ [] = do return (GHC.EmptyLocalBinds) replaceDeclsValbinds (GHC.HsValBinds _b) new = do logTr "replaceDecls HsLocalBinds" let decs = GHC.listToBag $ concatMap decl2Bind new let sigs = concatMap decl2Sig new return (GHC.HsValBinds (GHC.ValBindsIn decs sigs)) replaceDeclsValbinds (GHC.HsIPBinds _b) _new = error "undefined replaceDecls HsIPBinds" replaceDeclsValbinds (GHC.EmptyLocalBinds) new = do logTr "replaceDecls HsLocalBinds" let newBinds = map decl2Bind new newSigs = map decl2Sig new let decs = GHC.listToBag $ concat newBinds let sigs = concat newSigs return (GHC.HsValBinds (GHC.ValBindsIn decs sigs)) -- --------------------------------------------------------------------- type Decl = GHC.LHsDecl GHC.RdrName type Match = GHC.LMatch GHC.RdrName (GHC.LHsExpr GHC.RdrName) -- |Modify a 'GHC.LHsBind' wrapped in a 'GHC.ValD'. For a 'GHC.PatBind' the -- declarations are extracted and returned after modification. For a -- 'GHC.FunBind' the supplied 'GHC.SrcSpan' is used to identify the specific -- 'GHC.Match' to be transformed, for when there are multiple of them. modifyValD :: forall m t. (HasTransform m) => GHC.SrcSpan -> Decl -> (Match -> [Decl] -> m ([Decl], Maybe t)) -> m (Decl,Maybe t) modifyValD p pb@(GHC.L ss (GHC.ValD (GHC.PatBind {} ))) f = if ss == p then do ds <- liftT $ hsDeclsPatBindD pb (ds',r) <- f (error "modifyValD.PatBind should not touch Match") ds pb' <- liftT $ replaceDeclsPatBindD pb ds' return (pb',r) else return (pb,Nothing) modifyValD p ast f = do (ast',r) <- runStateT (SYB.everywhereM (SYB.mkM doModLocal) ast) Nothing return (ast',r) where doModLocal :: Match -> StateT (Maybe t) m Match doModLocal (match@(GHC.L ss _) :: Match) = do let if ss == p then do ds <- lift $ liftT $ hsDecls match (ds',r) <- lift $ f match ds put r match' <- lift $ liftT $ replaceDecls match ds' return match' else return match -- --------------------------------------------------------------------- -- |Used to integrate a @Transform@ into other Monad stacks class (Monad m) => (HasTransform m) where liftT :: Transform a -> m a instance HasTransform (TransformT Identity) where liftT = id -- --------------------------------------------------------------------- -- | Apply a transformation to the decls contained in @t@ modifyDeclsT :: (HasDecls t,HasTransform m) => ([GHC.LHsDecl GHC.RdrName] -> m [GHC.LHsDecl GHC.RdrName]) -> t -> m t modifyDeclsT action t = do decls <- liftT $ hsDecls t decls' <- action decls liftT $ replaceDecls t decls' -- --------------------------------------------------------------------- matchApiAnn :: GHC.AnnKeywordId -> (KeywordId,DeltaPos) -> Bool matchApiAnn mkw (kw,_) = case kw of (G akw) -> mkw == akw _ -> False -- We comments extracted from annPriorComments or annFollowingComments, which -- need to move to just before the item identified by the predicate, if it -- fires, else at the end of the annotations. insertCommentBefore :: (Monad m) => AnnKey -> [(Comment, DeltaPos)] -> ((KeywordId, DeltaPos) -> Bool) -> TransformT m () insertCommentBefore key toMove p = do let doInsert ans = case Map.lookup key ans of Nothing -> error $ "insertCommentBefore:no AnnKey for:" ++ showGhc key Just ann -> Map.insert key ann' ans where (before,after) = break p (annsDP ann) ann' = ann { annsDP = before ++ (map comment2dp toMove) ++ after} modifyAnnsT doInsert