{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 \section[NameEnv]{@NameEnv@: name environments} -} {-# LANGUAGE CPP #-} {-# LANGUAGE BangPatterns #-} {-# LANGUAGE ScopedTypeVariables #-} module GHC.Types.Name.Env ( -- * Var, Id and TyVar environments (maps) NameEnv, -- ** Manipulating these environments mkNameEnv, mkNameEnvWith, emptyNameEnv, isEmptyNameEnv, unitNameEnv, nameEnvElts, extendNameEnv_C, extendNameEnv_Acc, extendNameEnv, extendNameEnvList, extendNameEnvList_C, filterNameEnv, anyNameEnv, plusNameEnv, plusNameEnv_C, plusNameEnv_CD, plusNameEnv_CD2, alterNameEnv, lookupNameEnv, lookupNameEnv_NF, delFromNameEnv, delListFromNameEnv, elemNameEnv, mapNameEnv, disjointNameEnv, DNameEnv, emptyDNameEnv, lookupDNameEnv, delFromDNameEnv, filterDNameEnv, mapDNameEnv, adjustDNameEnv, alterDNameEnv, extendDNameEnv, -- ** Dependency analysis depAnal ) where #include "HsVersions.h" import GHC.Prelude import GHC.Data.Graph.Directed import GHC.Types.Name import GHC.Types.Unique.FM import GHC.Types.Unique.DFM import GHC.Data.Maybe {- ************************************************************************ * * \subsection{Name environment} * * ************************************************************************ -} {- Note [depAnal determinism] ~~~~~~~~~~~~~~~~~~~~~~~~~~ depAnal is deterministic provided it gets the nodes in a deterministic order. The order of lists that get_defs and get_uses return doesn't matter, as these are only used to construct the edges, and stronglyConnCompFromEdgedVertices is deterministic even when the edges are not in deterministic order as explained in Note [Deterministic SCC] in GHC.Data.Graph.Directed. -} depAnal :: forall node. (node -> [Name]) -- Defs -> (node -> [Name]) -- Uses -> [node] -> [SCC node] -- Perform dependency analysis on a group of definitions, -- where each definition may define more than one Name -- -- The get_defs and get_uses functions are called only once per node depAnal get_defs get_uses nodes = stronglyConnCompFromEdgedVerticesUniq graph_nodes where graph_nodes = (map mk_node keyed_nodes) :: [Node Int node] keyed_nodes = nodes `zip` [(1::Int)..] mk_node (node, key) = let !edges = (mapMaybe (lookupNameEnv key_map) (get_uses node)) in DigraphNode node key edges key_map :: NameEnv Int -- Maps a Name to the key of the decl that defines it key_map = mkNameEnv [(name,key) | (node, key) <- keyed_nodes, name <- get_defs node] {- ************************************************************************ * * \subsection{Name environment} * * ************************************************************************ -} -- | Name Environment type NameEnv a = UniqFM Name a -- Domain is Name emptyNameEnv :: NameEnv a isEmptyNameEnv :: NameEnv a -> Bool mkNameEnv :: [(Name,a)] -> NameEnv a mkNameEnvWith :: (a -> Name) -> [a] -> NameEnv a nameEnvElts :: NameEnv a -> [a] alterNameEnv :: (Maybe a-> Maybe a) -> NameEnv a -> Name -> NameEnv a extendNameEnv_C :: (a->a->a) -> NameEnv a -> Name -> a -> NameEnv a extendNameEnv_Acc :: (a->b->b) -> (a->b) -> NameEnv b -> Name -> a -> NameEnv b extendNameEnv :: NameEnv a -> Name -> a -> NameEnv a plusNameEnv :: NameEnv a -> NameEnv a -> NameEnv a plusNameEnv_C :: (a->a->a) -> NameEnv a -> NameEnv a -> NameEnv a plusNameEnv_CD :: (a->a->a) -> NameEnv a -> a -> NameEnv a -> a -> NameEnv a plusNameEnv_CD2 :: (Maybe a->Maybe a->a) -> NameEnv a -> NameEnv a -> NameEnv a extendNameEnvList :: NameEnv a -> [(Name,a)] -> NameEnv a extendNameEnvList_C :: (a->a->a) -> NameEnv a -> [(Name,a)] -> NameEnv a delFromNameEnv :: NameEnv a -> Name -> NameEnv a delListFromNameEnv :: NameEnv a -> [Name] -> NameEnv a elemNameEnv :: Name -> NameEnv a -> Bool unitNameEnv :: Name -> a -> NameEnv a lookupNameEnv :: NameEnv a -> Name -> Maybe a lookupNameEnv_NF :: NameEnv a -> Name -> a filterNameEnv :: (elt -> Bool) -> NameEnv elt -> NameEnv elt anyNameEnv :: (elt -> Bool) -> NameEnv elt -> Bool mapNameEnv :: (elt1 -> elt2) -> NameEnv elt1 -> NameEnv elt2 disjointNameEnv :: NameEnv a -> NameEnv a -> Bool nameEnvElts x = eltsUFM x emptyNameEnv = emptyUFM isEmptyNameEnv = isNullUFM unitNameEnv x y = unitUFM x y extendNameEnv x y z = addToUFM x y z extendNameEnvList x l = addListToUFM x l lookupNameEnv x y = lookupUFM x y alterNameEnv = alterUFM mkNameEnv l = listToUFM l mkNameEnvWith f = mkNameEnv . map (\a -> (f a, a)) elemNameEnv x y = elemUFM x y plusNameEnv x y = plusUFM x y plusNameEnv_C f x y = plusUFM_C f x y plusNameEnv_CD f x d y b = plusUFM_CD f x d y b plusNameEnv_CD2 f x y = plusUFM_CD2 f x y extendNameEnv_C f x y z = addToUFM_C f x y z mapNameEnv f x = mapUFM f x extendNameEnv_Acc x y z a b = addToUFM_Acc x y z a b extendNameEnvList_C x y z = addListToUFM_C x y z delFromNameEnv x y = delFromUFM x y delListFromNameEnv x y = delListFromUFM x y filterNameEnv x y = filterUFM x y anyNameEnv f x = foldUFM ((||) . f) False x disjointNameEnv x y = disjointUFM x y lookupNameEnv_NF env n = expectJust "lookupNameEnv_NF" (lookupNameEnv env n) -- | Deterministic Name Environment -- -- See Note [Deterministic UniqFM] in "GHC.Types.Unique.DFM" for explanation why -- we need DNameEnv. type DNameEnv a = UniqDFM Name a emptyDNameEnv :: DNameEnv a emptyDNameEnv = emptyUDFM lookupDNameEnv :: DNameEnv a -> Name -> Maybe a lookupDNameEnv = lookupUDFM delFromDNameEnv :: DNameEnv a -> Name -> DNameEnv a delFromDNameEnv = delFromUDFM filterDNameEnv :: (a -> Bool) -> DNameEnv a -> DNameEnv a filterDNameEnv = filterUDFM mapDNameEnv :: (a -> b) -> DNameEnv a -> DNameEnv b mapDNameEnv = mapUDFM adjustDNameEnv :: (a -> a) -> DNameEnv a -> Name -> DNameEnv a adjustDNameEnv = adjustUDFM alterDNameEnv :: (Maybe a -> Maybe a) -> DNameEnv a -> Name -> DNameEnv a alterDNameEnv = alterUDFM extendDNameEnv :: DNameEnv a -> Name -> a -> DNameEnv a extendDNameEnv = addToUDFM