%
% (c) The University of Glasgow 2006
% (c) The GRASP/AQUA Project, Glasgow University, 1992-1998
%
\section[HsBinds]{Abstract syntax: top-level bindings and signatures}
Datatype for: @BindGroup@, @Bind@, @Sig@, @Bind@.
\begin{code}
module HsBinds where
import HsExpr ( pprExpr, LHsExpr,
MatchGroup, pprFunBind,
GRHSs, pprPatBind )
import HsPat ( LPat )
import HsLit
import HsTypes
import PprCore ()
import CoreSyn
import TcEvidence
import Type
import Name
import NameSet
import BasicTypes
import Outputable
import SrcLoc
import Var
import Bag
import FastString
import BooleanFormula (BooleanFormula)
import Data.Data hiding ( Fixity )
import Data.List
import Data.Ord
import Data.Foldable ( Foldable(..) )
import Data.Traversable ( Traversable(..) )
import Data.Monoid ( mappend )
import Control.Applicative ( (<$>), (<*>) )
\end{code}
%************************************************************************
%* *
\subsection{Bindings: @BindGroup@}
%* *
%************************************************************************
Global bindings (where clauses)
\begin{code}
type HsLocalBinds id = HsLocalBindsLR id id
data HsLocalBindsLR idL idR
= HsValBinds (HsValBindsLR idL idR)
| HsIPBinds (HsIPBinds idR)
| EmptyLocalBinds
deriving (Data, Typeable)
type HsValBinds id = HsValBindsLR id id
data HsValBindsLR idL idR
=
ValBindsIn
(LHsBindsLR idL idR) [LSig idR]
| ValBindsOut
[(RecFlag, LHsBinds idL)]
[LSig Name]
deriving (Data, Typeable)
type LHsBind id = LHsBindLR id id
type LHsBinds id = LHsBindsLR id id
type HsBind id = HsBindLR id id
type LHsBindsLR idL idR = Bag (Origin, LHsBindLR idL idR)
type LHsBindLR idL idR = Located (HsBindLR idL idR)
data HsBindLR idL idR
=
FunBind {
fun_id :: Located idL,
fun_infix :: Bool,
fun_matches :: MatchGroup idR (LHsExpr idR),
fun_co_fn :: HsWrapper,
bind_fvs :: NameSet,
fun_tick :: Maybe (Tickish Id)
}
| PatBind {
pat_lhs :: LPat idL,
pat_rhs :: GRHSs idR (LHsExpr idR),
pat_rhs_ty :: PostTcType,
bind_fvs :: NameSet,
pat_ticks :: (Maybe (Tickish Id), [Maybe (Tickish Id)])
}
| VarBind {
var_id :: idL,
var_rhs :: LHsExpr idR,
var_inline :: Bool
}
| AbsBinds {
abs_tvs :: [TyVar],
abs_ev_vars :: [EvVar],
abs_exports :: [ABExport idL],
abs_ev_binds :: TcEvBinds,
abs_binds :: LHsBinds idL
}
| PatSynBind {
patsyn_id :: Located idL,
bind_fvs :: NameSet,
patsyn_args :: HsPatSynDetails (Located idR),
patsyn_def :: LPat idR,
patsyn_dir :: HsPatSynDir idR
}
deriving (Data, Typeable)
data ABExport id
= ABE { abe_poly :: id
, abe_mono :: id
, abe_wrap :: HsWrapper
, abe_prags :: TcSpecPrags
} deriving (Data, Typeable)
placeHolderNames :: NameSet
placeHolderNames = panic "placeHolderNames"
\end{code}
Note [AbsBinds]
~~~~~~~~~~~~~~~
The AbsBinds constructor is used in the output of the type checker, to record
*typechecked* and *generalised* bindings. Consider a module M, with this
top-level binding
M.reverse [] = []
M.reverse (x:xs) = M.reverse xs ++ [x]
In Hindley-Milner, a recursive binding is typechecked with the *recursive* uses
being *monomorphic*. So after typechecking *and* desugaring we will get something
like this
M.reverse :: forall a. [a] -> [a]
= /\a. letrec
reverse :: [a] -> [a] = \xs -> case xs of
[] -> []
(x:xs) -> reverse xs ++ [x]
in reverse
Notice that 'M.reverse' is polymorphic as expected, but there is a local
definition for plain 'reverse' which is *monomorphic*. The type variable
'a' scopes over the entire letrec.
That's after desugaring. What about after type checking but before desugaring?
That's where AbsBinds comes in. It looks like this:
AbsBinds { abs_tvs = [a]
, abs_exports = [ABE { abe_poly = M.reverse :: forall a. [a] -> [a],
, abe_mono = reverse :: a -> a}]
, abs_binds = { reverse :: [a] -> [a]
= \xs -> case xs of
[] -> []
(x:xs) -> reverse xs ++ [x] } }
Here,
* abs_tvs says what type variables are abstracted over the binding group,
just 'a' in this case.
* abs_binds is the *monomorphic* bindings of the group
* abs_exports describes how to get the polymorphic Id 'M.reverse' from the
monomorphic one 'reverse'
Notice that the *original* function (the polymorphic one you thought
you were defining) appears in the abe_poly field of the
abs_exports. The bindings in abs_binds are for fresh, local, Ids with
a *monomorphic* Id.
If there is a group of mutually recursive functions without type
signatures, we get one AbsBinds with the monomorphic versions of the
bindings in abs_binds, and one element of abe_exports for each
variable bound in the mutually recursive group. This is true even for
pattern bindings. Example:
(f,g) = (\x -> x, f)
After type checking we get
AbsBinds { abs_tvs = [a]
, abs_exports = [ ABE { abe_poly = M.f :: forall a. a -> a
, abe_mono = f :: a -> a }
, ABE { abe_poly = M.g :: forall a. a -> a
, abe_mono = g :: a -> a }]
, abs_binds = { (f,g) = (\x -> x, f) }
Note [AbsBinds wrappers]
~~~~~~~~~~~~~~~~~~~~~~~~
Consider
(f,g) = (\x.x, \y.y)
This ultimately desugars to something like this:
tup :: forall a b. (a->a, b->b)
tup = /\a b. (\x:a.x, \y:b.y)
f :: forall a. a -> a
f = /\a. case tup a Any of
(fm::a->a,gm:Any->Any) -> fm
...similarly for g...
The abe_wrap field deals with impedence-matching between
(/\a b. case tup a b of { (f,g) -> f })
and the thing we really want, which may have fewer type
variables. The action happens in TcBinds.mkExport.
Note [Bind free vars]
~~~~~~~~~~~~~~~~~~~~~
The bind_fvs field of FunBind and PatBind records the free variables
of the definition. It is used for two purposes
a) Dependency analysis prior to type checking
(see TcBinds.tc_group)
b) Deciding whether we can do generalisation of the binding
(see TcBinds.decideGeneralisationPlan)
Specifically,
* bind_fvs includes all free vars that are defined in this module
(including top-level things and lexically scoped type variables)
* bind_fvs excludes imported vars; this is just to keep the set smaller
* Before renaming, and after typechecking, the field is unused;
it's just an error thunk
\begin{code}
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (HsLocalBindsLR idL idR) where
ppr (HsValBinds bs) = ppr bs
ppr (HsIPBinds bs) = ppr bs
ppr EmptyLocalBinds = empty
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (HsValBindsLR idL idR) where
ppr (ValBindsIn binds sigs)
= pprDeclList (pprLHsBindsForUser binds sigs)
ppr (ValBindsOut sccs sigs)
= getPprStyle $ \ sty ->
if debugStyle sty then
vcat (map ppr sigs) $$ vcat (map ppr_scc sccs)
else
pprDeclList (pprLHsBindsForUser (unionManyBags (map snd sccs)) sigs)
where
ppr_scc (rec_flag, binds) = pp_rec rec_flag <+> pprLHsBinds binds
pp_rec Recursive = ptext (sLit "rec")
pp_rec NonRecursive = ptext (sLit "nonrec")
pprLHsBinds :: (OutputableBndr idL, OutputableBndr idR) => LHsBindsLR idL idR -> SDoc
pprLHsBinds binds
| isEmptyLHsBinds binds = empty
| otherwise = pprDeclList (map (ppr . snd) (bagToList binds))
pprLHsBindsForUser :: (OutputableBndr idL, OutputableBndr idR, OutputableBndr id2)
=> LHsBindsLR idL idR -> [LSig id2] -> [SDoc]
pprLHsBindsForUser binds sigs
= map snd (sort_by_loc decls)
where
decls :: [(SrcSpan, SDoc)]
decls = [(loc, ppr sig) | L loc sig <- sigs] ++
[(loc, ppr bind) | (_, L loc bind) <- bagToList binds]
sort_by_loc decls = sortBy (comparing fst) decls
pprDeclList :: [SDoc] -> SDoc
pprDeclList ds = pprDeeperList vcat ds
emptyLocalBinds :: HsLocalBindsLR a b
emptyLocalBinds = EmptyLocalBinds
isEmptyLocalBinds :: HsLocalBindsLR a b -> Bool
isEmptyLocalBinds (HsValBinds ds) = isEmptyValBinds ds
isEmptyLocalBinds (HsIPBinds ds) = isEmptyIPBinds ds
isEmptyLocalBinds EmptyLocalBinds = True
isEmptyValBinds :: HsValBindsLR a b -> Bool
isEmptyValBinds (ValBindsIn ds sigs) = isEmptyLHsBinds ds && null sigs
isEmptyValBinds (ValBindsOut ds sigs) = null ds && null sigs
emptyValBindsIn, emptyValBindsOut :: HsValBindsLR a b
emptyValBindsIn = ValBindsIn emptyBag []
emptyValBindsOut = ValBindsOut [] []
emptyLHsBinds :: LHsBindsLR idL idR
emptyLHsBinds = emptyBag
isEmptyLHsBinds :: LHsBindsLR idL idR -> Bool
isEmptyLHsBinds = isEmptyBag
plusHsValBinds :: HsValBinds a -> HsValBinds a -> HsValBinds a
plusHsValBinds (ValBindsIn ds1 sigs1) (ValBindsIn ds2 sigs2)
= ValBindsIn (ds1 `unionBags` ds2) (sigs1 ++ sigs2)
plusHsValBinds (ValBindsOut ds1 sigs1) (ValBindsOut ds2 sigs2)
= ValBindsOut (ds1 ++ ds2) (sigs1 ++ sigs2)
plusHsValBinds _ _
= panic "HsBinds.plusHsValBinds"
getTypeSigNames :: HsValBinds a -> NameSet
getTypeSigNames (ValBindsOut _ sigs)
= mkNameSet [unLoc n | L _ (TypeSig names _) <- sigs, n <- names]
getTypeSigNames _
= panic "HsBinds.getTypeSigNames"
\end{code}
What AbsBinds means
~~~~~~~~~~~~~~~~~~~
AbsBinds tvs
[d1,d2]
[(tvs1, f1p, f1m),
(tvs2, f2p, f2m)]
BIND
means
f1p = /\ tvs -> \ [d1,d2] -> letrec DBINDS and BIND
in fm
gp = ...same again, with gm instead of fm
This is a pretty bad translation, because it duplicates all the bindings.
So the desugarer tries to do a better job:
fp = /\ [a,b] -> \ [d1,d2] -> case tp [a,b] [d1,d2] of
(fm,gm) -> fm
..ditto for gp..
tp = /\ [a,b] -> \ [d1,d2] -> letrec DBINDS and BIND
in (fm,gm)
\begin{code}
instance (OutputableBndr idL, OutputableBndr idR) => Outputable (HsBindLR idL idR) where
ppr mbind = ppr_monobind mbind
ppr_monobind :: (OutputableBndr idL, OutputableBndr idR) => HsBindLR idL idR -> SDoc
ppr_monobind (PatBind { pat_lhs = pat, pat_rhs = grhss })
= pprPatBind pat grhss
ppr_monobind (VarBind { var_id = var, var_rhs = rhs })
= sep [pprBndr CaseBind var, nest 2 $ equals <+> pprExpr (unLoc rhs)]
ppr_monobind (FunBind { fun_id = fun, fun_infix = inf,
fun_co_fn = wrap,
fun_matches = matches,
fun_tick = tick })
= pprTicks empty (case tick of
Nothing -> empty
Just t -> text "-- tick id = " <> ppr t)
$$ ifPprDebug (pprBndr LetBind (unLoc fun))
$$ pprFunBind (unLoc fun) inf matches
$$ ifPprDebug (ppr wrap)
ppr_monobind (PatSynBind{ patsyn_id = L _ psyn, patsyn_args = details,
patsyn_def = pat, patsyn_dir = dir })
= ppr_lhs <+> ppr_rhs
where
ppr_lhs = ptext (sLit "pattern") <+> ppr_details details
ppr_simple syntax = syntax <+> ppr pat
ppr_details (InfixPatSyn v1 v2) = hsep [ppr v1, pprInfixOcc psyn, ppr v2]
ppr_details (PrefixPatSyn vs) = hsep (pprPrefixOcc psyn : map ppr vs)
ppr_rhs = case dir of
Unidirectional -> ppr_simple (ptext (sLit "<-"))
ImplicitBidirectional -> ppr_simple equals
ppr_monobind (AbsBinds { abs_tvs = tyvars, abs_ev_vars = dictvars
, abs_exports = exports, abs_binds = val_binds
, abs_ev_binds = ev_binds })
= hang (ptext (sLit "AbsBinds") <+> brackets (interpp'SP tyvars)
<+> brackets (interpp'SP dictvars))
2 $ braces $ vcat
[ ptext (sLit "Exports:") <+> brackets (sep (punctuate comma (map ppr exports)))
, ptext (sLit "Exported types:") <+> vcat [pprBndr LetBind (abe_poly ex) | ex <- exports]
, ptext (sLit "Binds:") <+> pprLHsBinds val_binds
, ifPprDebug (ptext (sLit "Evidence:") <+> ppr ev_binds) ]
instance (OutputableBndr id) => Outputable (ABExport id) where
ppr (ABE { abe_wrap = wrap, abe_poly = gbl, abe_mono = lcl, abe_prags = prags })
= vcat [ ppr gbl <+> ptext (sLit "<=") <+> ppr lcl
, nest 2 (pprTcSpecPrags prags)
, nest 2 (ppr wrap)]
\end{code}
\begin{code}
pprTicks :: SDoc -> SDoc -> SDoc
pprTicks pp_no_debug pp_when_debug
= getPprStyle (\ sty -> if debugStyle sty || dumpStyle sty
then pp_when_debug
else pp_no_debug)
\end{code}
%************************************************************************
%* *
Implicit parameter bindings
%* *
%************************************************************************
\begin{code}
data HsIPBinds id
= IPBinds
[LIPBind id]
TcEvBinds
deriving (Data, Typeable)
isEmptyIPBinds :: HsIPBinds id -> Bool
isEmptyIPBinds (IPBinds is ds) = null is && isEmptyTcEvBinds ds
type LIPBind id = Located (IPBind id)
data IPBind id
= IPBind (Either HsIPName id) (LHsExpr id)
deriving (Data, Typeable)
instance (OutputableBndr id) => Outputable (HsIPBinds id) where
ppr (IPBinds bs ds) = pprDeeperList vcat (map ppr bs)
$$ ifPprDebug (ppr ds)
instance (OutputableBndr id) => Outputable (IPBind id) where
ppr (IPBind lr rhs) = name <+> equals <+> pprExpr (unLoc rhs)
where name = case lr of
Left ip -> pprBndr LetBind ip
Right id -> pprBndr LetBind id
\end{code}
%************************************************************************
%* *
\subsection{@Sig@: type signatures and value-modifying user pragmas}
%* *
%************************************************************************
It is convenient to lump ``value-modifying'' user-pragmas (e.g.,
``specialise this function to these four types...'') in with type
signatures. Then all the machinery to move them into place, etc.,
serves for both.
\begin{code}
type LSig name = Located (Sig name)
data Sig name
=
TypeSig [Located name] (LHsType name)
| PatSynSig (Located name)
(HsPatSynDetails (LHsType name))
(LHsType name)
(LHsContext name)
(LHsContext name)
| GenericSig [Located name] (LHsType name)
| IdSig Id
| FixSig (FixitySig name)
| InlineSig (Located name)
InlinePragma
| SpecSig (Located name)
(LHsType name)
InlinePragma
| SpecInstSig (LHsType name)
| MinimalSig (BooleanFormula (Located name))
deriving (Data, Typeable)
type LFixitySig name = Located (FixitySig name)
data FixitySig name = FixitySig (Located name) Fixity
deriving (Data, Typeable)
data TcSpecPrags
= IsDefaultMethod
| SpecPrags [LTcSpecPrag]
deriving (Data, Typeable)
type LTcSpecPrag = Located TcSpecPrag
data TcSpecPrag
= SpecPrag
Id
HsWrapper
InlinePragma
deriving (Data, Typeable)
noSpecPrags :: TcSpecPrags
noSpecPrags = SpecPrags []
hasSpecPrags :: TcSpecPrags -> Bool
hasSpecPrags (SpecPrags ps) = not (null ps)
hasSpecPrags IsDefaultMethod = False
isDefaultMethod :: TcSpecPrags -> Bool
isDefaultMethod IsDefaultMethod = True
isDefaultMethod (SpecPrags {}) = False
isFixityLSig :: LSig name -> Bool
isFixityLSig (L _ (FixSig {})) = True
isFixityLSig _ = False
isVanillaLSig :: LSig name -> Bool
isVanillaLSig (L _(TypeSig {})) = True
isVanillaLSig _ = False
isTypeLSig :: LSig name -> Bool
isTypeLSig (L _(TypeSig {})) = True
isTypeLSig (L _(GenericSig {})) = True
isTypeLSig (L _(IdSig {})) = True
isTypeLSig _ = False
isSpecLSig :: LSig name -> Bool
isSpecLSig (L _(SpecSig {})) = True
isSpecLSig _ = False
isSpecInstLSig :: LSig name -> Bool
isSpecInstLSig (L _ (SpecInstSig {})) = True
isSpecInstLSig _ = False
isPragLSig :: LSig name -> Bool
isPragLSig (L _ (SpecSig {})) = True
isPragLSig (L _ (InlineSig {})) = True
isPragLSig _ = False
isInlineLSig :: LSig name -> Bool
isInlineLSig (L _ (InlineSig {})) = True
isInlineLSig _ = False
isMinimalLSig :: LSig name -> Bool
isMinimalLSig (L _ (MinimalSig {})) = True
isMinimalLSig _ = False
hsSigDoc :: Sig name -> SDoc
hsSigDoc (TypeSig {}) = ptext (sLit "type signature")
hsSigDoc (PatSynSig {}) = ptext (sLit "pattern synonym signature")
hsSigDoc (GenericSig {}) = ptext (sLit "default type signature")
hsSigDoc (IdSig {}) = ptext (sLit "id signature")
hsSigDoc (SpecSig {}) = ptext (sLit "SPECIALISE pragma")
hsSigDoc (InlineSig _ prag) = ppr (inlinePragmaSpec prag) <+> ptext (sLit "pragma")
hsSigDoc (SpecInstSig {}) = ptext (sLit "SPECIALISE instance pragma")
hsSigDoc (FixSig {}) = ptext (sLit "fixity declaration")
hsSigDoc (MinimalSig {}) = ptext (sLit "MINIMAL pragma")
\end{code}
Check if signatures overlap; this is used when checking for duplicate
signatures. Since some of the signatures contain a list of names, testing for
equality is not enough -- we have to check if they overlap.
\begin{code}
instance (OutputableBndr name) => Outputable (Sig name) where
ppr sig = ppr_sig sig
ppr_sig :: OutputableBndr name => Sig name -> SDoc
ppr_sig (TypeSig vars ty) = pprVarSig (map unLoc vars) (ppr ty)
ppr_sig (GenericSig vars ty) = ptext (sLit "default") <+> pprVarSig (map unLoc vars) (ppr ty)
ppr_sig (IdSig id) = pprVarSig [id] (ppr (varType id))
ppr_sig (FixSig fix_sig) = ppr fix_sig
ppr_sig (SpecSig var ty inl) = pragBrackets (pprSpec (unLoc var) (ppr ty) inl)
ppr_sig (InlineSig var inl) = pragBrackets (ppr inl <+> pprPrefixOcc (unLoc var))
ppr_sig (SpecInstSig ty) = pragBrackets (ptext (sLit "SPECIALIZE instance") <+> ppr ty)
ppr_sig (MinimalSig bf) = pragBrackets (pprMinimalSig bf)
ppr_sig (PatSynSig name arg_tys ty prov req)
= pprPatSynSig (unLoc name) False args (ppr ty) (pprCtx prov) (pprCtx req)
where
args = fmap ppr arg_tys
pprCtx lctx = case unLoc lctx of
[] -> Nothing
ctx -> Just (pprHsContextNoArrow ctx)
pprPatSynSig :: (OutputableBndr a)
=> a -> Bool -> HsPatSynDetails SDoc -> SDoc -> Maybe SDoc -> Maybe SDoc -> SDoc
pprPatSynSig ident is_bidir args rhs_ty prov_theta req_theta
= sep [ ptext (sLit "pattern")
, thetaOpt prov_theta, name_and_args
, colon
, thetaOpt req_theta, rhs_ty
]
where
name_and_args = case args of
PrefixPatSyn arg_tys ->
pprPrefixOcc ident <+> sep arg_tys
InfixPatSyn left_ty right_ty ->
left_ty <+> pprInfixOcc ident <+> right_ty
thetaOpt = maybe empty (<+> darrow)
colon = if is_bidir then dcolon else dcolon
instance OutputableBndr name => Outputable (FixitySig name) where
ppr (FixitySig name fixity) = sep [ppr fixity, pprInfixOcc (unLoc name)]
pragBrackets :: SDoc -> SDoc
pragBrackets doc = ptext (sLit "{-#") <+> doc <+> ptext (sLit "#-}")
pprVarSig :: (OutputableBndr id) => [id] -> SDoc -> SDoc
pprVarSig vars pp_ty = sep [pprvars <+> dcolon, nest 2 pp_ty]
where
pprvars = hsep $ punctuate comma (map pprPrefixOcc vars)
pprSpec :: (OutputableBndr id) => id -> SDoc -> InlinePragma -> SDoc
pprSpec var pp_ty inl = ptext (sLit "SPECIALIZE") <+> pp_inl <+> pprVarSig [var] pp_ty
where
pp_inl | isDefaultInlinePragma inl = empty
| otherwise = ppr inl
pprTcSpecPrags :: TcSpecPrags -> SDoc
pprTcSpecPrags IsDefaultMethod = ptext (sLit "<default method>")
pprTcSpecPrags (SpecPrags ps) = vcat (map (ppr . unLoc) ps)
instance Outputable TcSpecPrag where
ppr (SpecPrag var _ inl) = pprSpec var (ptext (sLit "<type>")) inl
pprMinimalSig :: OutputableBndr name => BooleanFormula (Located name) -> SDoc
pprMinimalSig bf = ptext (sLit "MINIMAL") <+> ppr (fmap unLoc bf)
\end{code}
%************************************************************************
%* *
\subsection[PatSynBind]{A pattern synonym definition}
%* *
%************************************************************************
\begin{code}
data HsPatSynDetails a
= InfixPatSyn a a
| PrefixPatSyn [a]
deriving (Data, Typeable)
instance Functor HsPatSynDetails where
fmap f (InfixPatSyn left right) = InfixPatSyn (f left) (f right)
fmap f (PrefixPatSyn args) = PrefixPatSyn (fmap f args)
instance Foldable HsPatSynDetails where
foldMap f (InfixPatSyn left right) = f left `mappend` f right
foldMap f (PrefixPatSyn args) = foldMap f args
instance Traversable HsPatSynDetails where
traverse f (InfixPatSyn left right) = InfixPatSyn <$> f left <*> f right
traverse f (PrefixPatSyn args) = PrefixPatSyn <$> traverse f args
data HsPatSynDirLR idL idR
= Unidirectional
| ImplicitBidirectional
deriving (Data, Typeable)
type HsPatSynDir id = HsPatSynDirLR id id
\end{code}