{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
-}

module VarEnv (
        -- * Var, Id and TyVar environments (maps)
        VarEnv, IdEnv, TyVarEnv, CoVarEnv, TyCoVarEnv,

        -- ** Manipulating these environments
        emptyVarEnv, unitVarEnv, mkVarEnv, mkVarEnv_Directly,
        elemVarEnv, disjointVarEnv,
        extendVarEnv, extendVarEnv_C, extendVarEnv_Acc, extendVarEnv_Directly,
        extendVarEnvList,
        plusVarEnv, plusVarEnv_C, plusVarEnv_CD, plusMaybeVarEnv_C,
        plusVarEnvList, alterVarEnv,
        delVarEnvList, delVarEnv, delVarEnv_Directly,
        minusVarEnv, intersectsVarEnv,
        lookupVarEnv, lookupVarEnv_NF, lookupWithDefaultVarEnv,
        mapVarEnv, zipVarEnv,
        modifyVarEnv, modifyVarEnv_Directly,
        isEmptyVarEnv,
        elemVarEnvByKey, lookupVarEnv_Directly,
        filterVarEnv, filterVarEnv_Directly, restrictVarEnv,
        partitionVarEnv,

        -- * Deterministic Var environments (maps)
        DVarEnv, DIdEnv, DTyVarEnv,

        -- ** Manipulating these environments
        emptyDVarEnv, mkDVarEnv,
        dVarEnvElts,
        extendDVarEnv, extendDVarEnv_C,
        extendDVarEnvList,
        lookupDVarEnv, elemDVarEnv,
        isEmptyDVarEnv, foldDVarEnv,
        mapDVarEnv,
        modifyDVarEnv,
        alterDVarEnv,
        plusDVarEnv, plusDVarEnv_C,
        unitDVarEnv,
        delDVarEnv,
        delDVarEnvList,
        minusDVarEnv,
        partitionDVarEnv,
        anyDVarEnv,

        -- * The InScopeSet type
        InScopeSet,

        -- ** Operations on InScopeSets
        emptyInScopeSet, mkInScopeSet, delInScopeSet,
        extendInScopeSet, extendInScopeSetList, extendInScopeSetSet,
        getInScopeVars, lookupInScope, lookupInScope_Directly,
        unionInScope, elemInScopeSet, uniqAway,
        varSetInScope,

        -- * The RnEnv2 type
        RnEnv2,

        -- ** Operations on RnEnv2s
        mkRnEnv2, rnBndr2, rnBndrs2, rnBndr2_var,
        rnOccL, rnOccR, inRnEnvL, inRnEnvR, rnOccL_maybe, rnOccR_maybe,
        rnBndrL, rnBndrR, nukeRnEnvL, nukeRnEnvR, rnSwap,
        delBndrL, delBndrR, delBndrsL, delBndrsR,
        addRnInScopeSet,
        rnEtaL, rnEtaR,
        rnInScope, rnInScopeSet, lookupRnInScope,
        rnEnvL, rnEnvR,

        -- * TidyEnv and its operation
        TidyEnv,
        emptyTidyEnv
    ) where

import GhcPrelude

import OccName
import Var
import VarSet
import UniqSet
import UniqFM
import UniqDFM
import Unique
import Util
import Maybes
import Outputable

{-
************************************************************************
*                                                                      *
                In-scope sets
*                                                                      *
************************************************************************
-}

-- | A set of variables that are in scope at some point
-- "Secrets of the Glasgow Haskell Compiler inliner" Section 3.2 provides
-- the motivation for this abstraction.
data InScopeSet = InScope VarSet {-# UNPACK #-} !Int
        -- We store a VarSet here, but we use this for lookups rather than
        -- just membership tests. Typically the InScopeSet contains the
        -- canonical version of the variable (e.g. with an informative
        -- unfolding), so this lookup is useful.
        --
        -- The Int is a kind of hash-value used by uniqAway
        -- For example, it might be the size of the set
        -- INVARIANT: it's not zero; we use it as a multiplier in uniqAway

instance Outputable InScopeSet where
  ppr (InScope s _) =
    text "InScope" <+>
    braces (fsep (map (ppr . Var.varName) (nonDetEltsUniqSet s)))
                      -- It's OK to use nonDetEltsUniqSet here because it's
                      -- only for pretty printing
                      -- In-scope sets get big, and with -dppr-debug
                      -- the output is overwhelming

emptyInScopeSet :: InScopeSet
emptyInScopeSet = InScope emptyVarSet 1

getInScopeVars ::  InScopeSet -> VarSet
getInScopeVars (InScope vs _) = vs

mkInScopeSet :: VarSet -> InScopeSet
mkInScopeSet in_scope = InScope in_scope 1

extendInScopeSet :: InScopeSet -> Var -> InScopeSet
extendInScopeSet (InScope in_scope n) v
   = InScope (extendVarSet in_scope v) (n + 1)

extendInScopeSetList :: InScopeSet -> [Var] -> InScopeSet
extendInScopeSetList (InScope in_scope n) vs
   = InScope (foldl (\s v -> extendVarSet s v) in_scope vs)
                    (n + length vs)

extendInScopeSetSet :: InScopeSet -> VarSet -> InScopeSet
extendInScopeSetSet (InScope in_scope n) vs
   = InScope (in_scope `unionVarSet` vs) (n + sizeUniqSet vs)

delInScopeSet :: InScopeSet -> Var -> InScopeSet
delInScopeSet (InScope in_scope n) v = InScope (in_scope `delVarSet` v) n

elemInScopeSet :: Var -> InScopeSet -> Bool
elemInScopeSet v (InScope in_scope _) = v `elemVarSet` in_scope

-- | Look up a variable the 'InScopeSet'.  This lets you map from
-- the variable's identity (unique) to its full value.
lookupInScope :: InScopeSet -> Var -> Maybe Var
lookupInScope (InScope in_scope _) v  = lookupVarSet in_scope v

lookupInScope_Directly :: InScopeSet -> Unique -> Maybe Var
lookupInScope_Directly (InScope in_scope _) uniq
  = lookupVarSet_Directly in_scope uniq

unionInScope :: InScopeSet -> InScopeSet -> InScopeSet
unionInScope (InScope s1 _) (InScope s2 n2)
  = InScope (s1 `unionVarSet` s2) n2

varSetInScope :: VarSet -> InScopeSet -> Bool
varSetInScope vars (InScope s1 _) = vars `subVarSet` s1

-- | @uniqAway in_scope v@ finds a unique that is not used in the
-- in-scope set, and gives that to v.
uniqAway :: InScopeSet -> Var -> Var
-- It starts with v's current unique, of course, in the hope that it won't
-- have to change, and thereafter uses a combination of that and the hash-code
-- found in the in-scope set
uniqAway in_scope var
  | var `elemInScopeSet` in_scope = uniqAway' in_scope var      -- Make a new one
  | otherwise                     = var                         -- Nothing to do

uniqAway' :: InScopeSet -> Var -> Var
-- This one *always* makes up a new variable
uniqAway' (InScope set n) var
  = try 1
  where
    orig_unique = getUnique var
    try k
          | debugIsOn && (k > 1000)
          = pprPanic "uniqAway loop:" msg
          | uniq `elemVarSetByKey` set = try (k + 1)
          | k > 3
          = pprTraceDebug "uniqAway:" msg
            setVarUnique var uniq
          | otherwise = setVarUnique var uniq
          where
            msg  = ppr k <+> text "tries" <+> ppr var <+> int n
            uniq = deriveUnique orig_unique (n * k)

{-
************************************************************************
*                                                                      *
                Dual renaming
*                                                                      *
************************************************************************
-}

-- | Rename Environment 2
--
-- When we are comparing (or matching) types or terms, we are faced with
-- \"going under\" corresponding binders.  E.g. when comparing:
--
-- > \x. e1     ~   \y. e2
--
-- Basically we want to rename [@x@ -> @y@] or [@y@ -> @x@], but there are lots of
-- things we must be careful of.  In particular, @x@ might be free in @e2@, or
-- y in @e1@.  So the idea is that we come up with a fresh binder that is free
-- in neither, and rename @x@ and @y@ respectively.  That means we must maintain:
--
-- 1. A renaming for the left-hand expression
--
-- 2. A renaming for the right-hand expressions
--
-- 3. An in-scope set
--
-- Furthermore, when matching, we want to be able to have an 'occurs check',
-- to prevent:
--
-- > \x. f   ~   \y. y
--
-- matching with [@f@ -> @y@].  So for each expression we want to know that set of
-- locally-bound variables. That is precisely the domain of the mappings 1.
-- and 2., but we must ensure that we always extend the mappings as we go in.
--
-- All of this information is bundled up in the 'RnEnv2'
data RnEnv2
  = RV2 { envL     :: VarEnv Var        -- Renaming for Left term
        , envR     :: VarEnv Var        -- Renaming for Right term
        , in_scope :: InScopeSet }      -- In scope in left or right terms

-- The renamings envL and envR are *guaranteed* to contain a binding
-- for every variable bound as we go into the term, even if it is not
-- renamed.  That way we can ask what variables are locally bound
-- (inRnEnvL, inRnEnvR)

mkRnEnv2 :: InScopeSet -> RnEnv2
mkRnEnv2 vars = RV2     { envL     = emptyVarEnv
                        , envR     = emptyVarEnv
                        , in_scope = vars }

addRnInScopeSet :: RnEnv2 -> VarSet -> RnEnv2
addRnInScopeSet env vs
  | isEmptyVarSet vs = env
  | otherwise        = env { in_scope = extendInScopeSetSet (in_scope env) vs }

rnInScope :: Var -> RnEnv2 -> Bool
rnInScope x env = x `elemInScopeSet` in_scope env

rnInScopeSet :: RnEnv2 -> InScopeSet
rnInScopeSet = in_scope

-- | Retrieve the left mapping
rnEnvL :: RnEnv2 -> VarEnv Var
rnEnvL = envL

-- | Retrieve the right mapping
rnEnvR :: RnEnv2 -> VarEnv Var
rnEnvR = envR

rnBndrs2 :: RnEnv2 -> [Var] -> [Var] -> RnEnv2
-- ^ Applies 'rnBndr2' to several variables: the two variable lists must be of equal length
rnBndrs2 env bsL bsR = foldl2 rnBndr2 env bsL bsR

rnBndr2 :: RnEnv2 -> Var -> Var -> RnEnv2
-- ^ @rnBndr2 env bL bR@ goes under a binder @bL@ in the Left term,
--                       and binder @bR@ in the Right term.
-- It finds a new binder, @new_b@,
-- and returns an environment mapping @bL -> new_b@ and @bR -> new_b@
rnBndr2 env bL bR = fst $ rnBndr2_var env bL bR

rnBndr2_var :: RnEnv2 -> Var -> Var -> (RnEnv2, Var)
-- ^ Similar to 'rnBndr2' but returns the new variable as well as the
-- new environment
rnBndr2_var (RV2 { envL = envL, envR = envR, in_scope = in_scope }) bL bR
  = (RV2 { envL            = extendVarEnv envL bL new_b   -- See Note
         , envR            = extendVarEnv envR bR new_b   -- [Rebinding]
         , in_scope = extendInScopeSet in_scope new_b }, new_b)
  where
        -- Find a new binder not in scope in either term
    new_b | not (bL `elemInScopeSet` in_scope) = bL
          | not (bR `elemInScopeSet` in_scope) = bR
          | otherwise                          = uniqAway' in_scope bL

        -- Note [Rebinding]
        -- If the new var is the same as the old one, note that
        -- the extendVarEnv *deletes* any current renaming
        -- E.g.   (\x. \x. ...)  ~  (\y. \z. ...)
        --
        --   Inside \x  \y      { [x->y], [y->y],       {y} }
        --       \x  \z         { [x->x], [y->y, z->x], {y,x} }

rnBndrL :: RnEnv2 -> Var -> (RnEnv2, Var)
-- ^ Similar to 'rnBndr2' but used when there's a binder on the left
-- side only.
rnBndrL (RV2 { envL = envL, envR = envR, in_scope = in_scope }) bL
  = (RV2 { envL     = extendVarEnv envL bL new_b
         , envR     = envR
         , in_scope = extendInScopeSet in_scope new_b }, new_b)
  where
    new_b = uniqAway in_scope bL

rnBndrR :: RnEnv2 -> Var -> (RnEnv2, Var)
-- ^ Similar to 'rnBndr2' but used when there's a binder on the right
-- side only.
rnBndrR (RV2 { envL = envL, envR = envR, in_scope = in_scope }) bR
  = (RV2 { envR     = extendVarEnv envR bR new_b
         , envL     = envL
         , in_scope = extendInScopeSet in_scope new_b }, new_b)
  where
    new_b = uniqAway in_scope bR

rnEtaL :: RnEnv2 -> Var -> (RnEnv2, Var)
-- ^ Similar to 'rnBndrL' but used for eta expansion
-- See Note [Eta expansion]
rnEtaL (RV2 { envL = envL, envR = envR, in_scope = in_scope }) bL
  = (RV2 { envL     = extendVarEnv envL bL new_b
         , envR     = extendVarEnv envR new_b new_b     -- Note [Eta expansion]
         , in_scope = extendInScopeSet in_scope new_b }, new_b)
  where
    new_b = uniqAway in_scope bL

rnEtaR :: RnEnv2 -> Var -> (RnEnv2, Var)
-- ^ Similar to 'rnBndr2' but used for eta expansion
-- See Note [Eta expansion]
rnEtaR (RV2 { envL = envL, envR = envR, in_scope = in_scope }) bR
  = (RV2 { envL     = extendVarEnv envL new_b new_b     -- Note [Eta expansion]
         , envR     = extendVarEnv envR bR new_b
         , in_scope = extendInScopeSet in_scope new_b }, new_b)
  where
    new_b = uniqAway in_scope bR

delBndrL, delBndrR :: RnEnv2 -> Var -> RnEnv2
delBndrL rn@(RV2 { envL = env, in_scope = in_scope }) v
  = rn { envL = env `delVarEnv` v, in_scope = in_scope `extendInScopeSet` v }
delBndrR rn@(RV2 { envR = env, in_scope = in_scope }) v
  = rn { envR = env `delVarEnv` v, in_scope = in_scope `extendInScopeSet` v }

delBndrsL, delBndrsR :: RnEnv2 -> [Var] -> RnEnv2
delBndrsL rn@(RV2 { envL = env, in_scope = in_scope }) v
  = rn { envL = env `delVarEnvList` v, in_scope = in_scope `extendInScopeSetList` v }
delBndrsR rn@(RV2 { envR = env, in_scope = in_scope }) v
  = rn { envR = env `delVarEnvList` v, in_scope = in_scope `extendInScopeSetList` v }

rnOccL, rnOccR :: RnEnv2 -> Var -> Var
-- ^ Look up the renaming of an occurrence in the left or right term
rnOccL (RV2 { envL = env }) v = lookupVarEnv env v `orElse` v
rnOccR (RV2 { envR = env }) v = lookupVarEnv env v `orElse` v

rnOccL_maybe, rnOccR_maybe :: RnEnv2 -> Var -> Maybe Var
-- ^ Look up the renaming of an occurrence in the left or right term
rnOccL_maybe (RV2 { envL = env }) v = lookupVarEnv env v
rnOccR_maybe (RV2 { envR = env }) v = lookupVarEnv env v

inRnEnvL, inRnEnvR :: RnEnv2 -> Var -> Bool
-- ^ Tells whether a variable is locally bound
inRnEnvL (RV2 { envL = env }) v = v `elemVarEnv` env
inRnEnvR (RV2 { envR = env }) v = v `elemVarEnv` env

lookupRnInScope :: RnEnv2 -> Var -> Var
lookupRnInScope env v = lookupInScope (in_scope env) v `orElse` v

nukeRnEnvL, nukeRnEnvR :: RnEnv2 -> RnEnv2
-- ^ Wipe the left or right side renaming
nukeRnEnvL env = env { envL = emptyVarEnv }
nukeRnEnvR env = env { envR = emptyVarEnv }

rnSwap :: RnEnv2 -> RnEnv2
-- ^ swap the meaning of left and right
rnSwap (RV2 { envL = envL, envR = envR, in_scope = in_scope })
  = RV2 { envL = envR, envR = envL, in_scope = in_scope }

{-
Note [Eta expansion]
~~~~~~~~~~~~~~~~~~~~
When matching
     (\x.M) ~ N
we rename x to x' with, where x' is not in scope in
either term.  Then we want to behave as if we'd seen
     (\x'.M) ~ (\x'.N x')
Since x' isn't in scope in N, the form (\x'. N x') doesn't
capture any variables in N.  But we must nevertheless extend
the envR with a binding [x' -> x'], to support the occurs check.
For example, if we don't do this, we can get silly matches like
        forall a.  (\y.a)  ~   v
succeeding with [a -> v y], which is bogus of course.


************************************************************************
*                                                                      *
                Tidying
*                                                                      *
************************************************************************
-}

-- | Tidy Environment
--
-- When tidying up print names, we keep a mapping of in-scope occ-names
-- (the 'TidyOccEnv') and a Var-to-Var of the current renamings
type TidyEnv = (TidyOccEnv, VarEnv Var)

emptyTidyEnv :: TidyEnv
emptyTidyEnv = (emptyTidyOccEnv, emptyVarEnv)

{-
************************************************************************
*                                                                      *
\subsection{@VarEnv@s}
*                                                                      *
************************************************************************
-}

-- | Variable Environment
type VarEnv elt     = UniqFM elt

-- | Identifier Environment
type IdEnv elt      = VarEnv elt

-- | Type Variable Environment
type TyVarEnv elt   = VarEnv elt

-- | Type or Coercion Variable Environment
type TyCoVarEnv elt = VarEnv elt

-- | Coercion Variable Environment
type CoVarEnv elt   = VarEnv elt

emptyVarEnv       :: VarEnv a
mkVarEnv          :: [(Var, a)] -> VarEnv a
mkVarEnv_Directly :: [(Unique, a)] -> VarEnv a
zipVarEnv         :: [Var] -> [a] -> VarEnv a
unitVarEnv        :: Var -> a -> VarEnv a
alterVarEnv       :: (Maybe a -> Maybe a) -> VarEnv a -> Var -> VarEnv a
extendVarEnv      :: VarEnv a -> Var -> a -> VarEnv a
extendVarEnv_C    :: (a->a->a) -> VarEnv a -> Var -> a -> VarEnv a
extendVarEnv_Acc  :: (a->b->b) -> (a->b) -> VarEnv b -> Var -> a -> VarEnv b
extendVarEnv_Directly :: VarEnv a -> Unique -> a -> VarEnv a
plusVarEnv        :: VarEnv a -> VarEnv a -> VarEnv a
plusVarEnvList    :: [VarEnv a] -> VarEnv a
extendVarEnvList  :: VarEnv a -> [(Var, a)] -> VarEnv a

lookupVarEnv_Directly :: VarEnv a -> Unique -> Maybe a
filterVarEnv_Directly :: (Unique -> a -> Bool) -> VarEnv a -> VarEnv a
delVarEnv_Directly    :: VarEnv a -> Unique -> VarEnv a
partitionVarEnv   :: (a -> Bool) -> VarEnv a -> (VarEnv a, VarEnv a)
restrictVarEnv    :: VarEnv a -> VarSet -> VarEnv a
delVarEnvList     :: VarEnv a -> [Var] -> VarEnv a
delVarEnv         :: VarEnv a -> Var -> VarEnv a
minusVarEnv       :: VarEnv a -> VarEnv b -> VarEnv a
intersectsVarEnv  :: VarEnv a -> VarEnv a -> Bool
plusVarEnv_C      :: (a -> a -> a) -> VarEnv a -> VarEnv a -> VarEnv a
plusVarEnv_CD     :: (a -> a -> a) -> VarEnv a -> a -> VarEnv a -> a -> VarEnv a
plusMaybeVarEnv_C :: (a -> a -> Maybe a) -> VarEnv a -> VarEnv a -> VarEnv a
mapVarEnv         :: (a -> b) -> VarEnv a -> VarEnv b
modifyVarEnv      :: (a -> a) -> VarEnv a -> Var -> VarEnv a

isEmptyVarEnv     :: VarEnv a -> Bool
lookupVarEnv      :: VarEnv a -> Var -> Maybe a
filterVarEnv      :: (a -> Bool) -> VarEnv a -> VarEnv a
lookupVarEnv_NF   :: VarEnv a -> Var -> a
lookupWithDefaultVarEnv :: VarEnv a -> a -> Var -> a
elemVarEnv        :: Var -> VarEnv a -> Bool
elemVarEnvByKey   :: Unique -> VarEnv a -> Bool
disjointVarEnv    :: VarEnv a -> VarEnv a -> Bool

elemVarEnv       = elemUFM
elemVarEnvByKey  = elemUFM_Directly
disjointVarEnv   = disjointUFM
alterVarEnv      = alterUFM
extendVarEnv     = addToUFM
extendVarEnv_C   = addToUFM_C
extendVarEnv_Acc = addToUFM_Acc
extendVarEnv_Directly = addToUFM_Directly
extendVarEnvList = addListToUFM
plusVarEnv_C     = plusUFM_C
plusVarEnv_CD    = plusUFM_CD
plusMaybeVarEnv_C = plusMaybeUFM_C
delVarEnvList    = delListFromUFM
delVarEnv        = delFromUFM
minusVarEnv      = minusUFM
intersectsVarEnv e1 e2 = not (isEmptyVarEnv (e1 `intersectUFM` e2))
plusVarEnv       = plusUFM
plusVarEnvList   = plusUFMList
lookupVarEnv     = lookupUFM
filterVarEnv     = filterUFM
lookupWithDefaultVarEnv = lookupWithDefaultUFM
mapVarEnv        = mapUFM
mkVarEnv         = listToUFM
mkVarEnv_Directly= listToUFM_Directly
emptyVarEnv      = emptyUFM
unitVarEnv       = unitUFM
isEmptyVarEnv    = isNullUFM
lookupVarEnv_Directly = lookupUFM_Directly
filterVarEnv_Directly = filterUFM_Directly
delVarEnv_Directly    = delFromUFM_Directly
partitionVarEnv       = partitionUFM

restrictVarEnv env vs = filterVarEnv_Directly keep env
  where
    keep u _ = u `elemVarSetByKey` vs

zipVarEnv tyvars tys   = mkVarEnv (zipEqual "zipVarEnv" tyvars tys)
lookupVarEnv_NF env id = case lookupVarEnv env id of
                         Just xx -> xx
                         Nothing -> panic "lookupVarEnv_NF: Nothing"

{-
@modifyVarEnv@: Look up a thing in the VarEnv,
then mash it with the modify function, and put it back.
-}

modifyVarEnv mangle_fn env key
  = case (lookupVarEnv env key) of
      Nothing -> env
      Just xx -> extendVarEnv env key (mangle_fn xx)

modifyVarEnv_Directly :: (a -> a) -> UniqFM a -> Unique -> UniqFM a
modifyVarEnv_Directly mangle_fn env key
  = case (lookupUFM_Directly env key) of
      Nothing -> env
      Just xx -> addToUFM_Directly env key (mangle_fn xx)

-- Deterministic VarEnv
-- See Note [Deterministic UniqFM] in UniqDFM for explanation why we need
-- DVarEnv.

-- | Deterministic Variable Environment
type DVarEnv elt = UniqDFM elt

-- | Deterministic Identifier Environment
type DIdEnv elt = DVarEnv elt

-- | Deterministic Type Variable Environment
type DTyVarEnv elt = DVarEnv elt

emptyDVarEnv :: DVarEnv a
emptyDVarEnv = emptyUDFM

dVarEnvElts :: DVarEnv a -> [a]
dVarEnvElts = eltsUDFM

mkDVarEnv :: [(Var, a)] -> DVarEnv a
mkDVarEnv = listToUDFM

extendDVarEnv :: DVarEnv a -> Var -> a -> DVarEnv a
extendDVarEnv = addToUDFM

minusDVarEnv :: DVarEnv a -> DVarEnv a' -> DVarEnv a
minusDVarEnv = minusUDFM

lookupDVarEnv :: DVarEnv a -> Var -> Maybe a
lookupDVarEnv = lookupUDFM

foldDVarEnv :: (a -> b -> b) -> b -> DVarEnv a -> b
foldDVarEnv = foldUDFM

mapDVarEnv :: (a -> b) -> DVarEnv a -> DVarEnv b
mapDVarEnv = mapUDFM

alterDVarEnv :: (Maybe a -> Maybe a) -> DVarEnv a -> Var -> DVarEnv a
alterDVarEnv = alterUDFM

plusDVarEnv :: DVarEnv a -> DVarEnv a -> DVarEnv a
plusDVarEnv = plusUDFM

plusDVarEnv_C :: (a -> a -> a) -> DVarEnv a -> DVarEnv a -> DVarEnv a
plusDVarEnv_C = plusUDFM_C

unitDVarEnv :: Var -> a -> DVarEnv a
unitDVarEnv = unitUDFM

delDVarEnv :: DVarEnv a -> Var -> DVarEnv a
delDVarEnv = delFromUDFM

delDVarEnvList :: DVarEnv a -> [Var] -> DVarEnv a
delDVarEnvList = delListFromUDFM

isEmptyDVarEnv :: DVarEnv a -> Bool
isEmptyDVarEnv = isNullUDFM

elemDVarEnv :: Var -> DVarEnv a -> Bool
elemDVarEnv = elemUDFM

extendDVarEnv_C :: (a -> a -> a) -> DVarEnv a -> Var -> a -> DVarEnv a
extendDVarEnv_C = addToUDFM_C

modifyDVarEnv :: (a -> a) -> DVarEnv a -> Var -> DVarEnv a
modifyDVarEnv mangle_fn env key
  = case (lookupDVarEnv env key) of
      Nothing -> env
      Just xx -> extendDVarEnv env key (mangle_fn xx)

partitionDVarEnv :: (a -> Bool) -> DVarEnv a -> (DVarEnv a, DVarEnv a)
partitionDVarEnv = partitionUDFM

extendDVarEnvList :: DVarEnv a -> [(Var, a)] -> DVarEnv a
extendDVarEnvList = addListToUDFM

anyDVarEnv :: (a -> Bool) -> DVarEnv a -> Bool
anyDVarEnv = anyUDFM