% % (c) The University of Glasgow 2006 % (c) The GRASP/AQUA Project, Glasgow University, 1998 % \section[PatSyn]{@PatSyn@: Pattern synonyms} \begin{code} 

module PatSyn (
        -- * Main data types
        PatSyn, mkPatSyn,

        -- ** Type deconstruction
        patSynName, patSynArity, patSynIsInfix,
        patSynArgs, patSynTyDetails, patSynType,
        patSynWrapper, patSynMatcher,
        patSynExTyVars, patSynSig,
        patSynInstArgTys, patSynInstResTy,
        tidyPatSynIds
    ) where

#include "HsVersions.h"

import Type
import TcType( mkSigmaTy )
import Name
import Outputable
import Unique
import Util
import BasicTypes
import FastString
import Var
import HsBinds( HsPatSynDetails(..) )

import qualified Data.Data as Data
import qualified Data.Typeable
import Data.Function
\end{code} Note [Pattern synonym representation] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider the following pattern synonym declaration pattern P x = MkT [x] (Just 42) where data T a where MkT :: (Show a, Ord b) => [b] -> a -> T a so pattern P has type b -> T (Maybe t) with the following typeclass constraints: provides: (Show (Maybe t), Ord b) requires: (Eq t, Num t) In this case, the fields of MkPatSyn will be set as follows: psArgs = [b] psArity = 1 psInfix = False psUnivTyVars = [t] psExTyVars = [b] psProvTheta = (Show (Maybe t), Ord b) psReqTheta = (Eq t, Num t) psOrigResTy = T (Maybe t) Note [Matchers and wrappers for pattern synonyms] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For each pattern synonym, we generate a single matcher function which implements the actual matching. For the above example, the matcher will have type: $mP :: forall r t. (Eq t, Num t) => T (Maybe t) -> (forall b. (Show (Maybe t), Ord b) => b -> r) -> r -> r with the following implementation: $mP @r @t $dEq $dNum scrut cont fail = case scrut of MkT @b $dShow $dOrd [x] (Just 42) -> cont @b $dShow $dOrd x _ -> fail For *bidirectional* pattern synonyms, we also generate a single wrapper function which implements the pattern synonym in an expression context. For our running example, it will be: $WP :: forall t b. (Show (Maybe t), Ord b, Eq t, Num t) => b -> T (Maybe t) $WP x = MkT [x] (Just 42) NB: the existential/universal and required/provided split does not apply to the wrapper since you are only putting stuff in, not getting stuff out. Injectivity of bidirectional pattern synonyms is checked in tcPatToExpr which walks the pattern and returns its corresponding expression when available. %************************************************************************ %* * \subsection{Pattern synonyms} %* * %************************************************************************ \begin{code} 
-- | A pattern synonym
-- See Note [Pattern synonym representation]
data PatSyn
  = MkPatSyn {
        psName        :: Name,
        psUnique      :: Unique,      -- Cached from Name

        psArgs        :: [Type],
        psArity       :: Arity,       -- == length psArgs
        psInfix       :: Bool,        -- True <=> declared infix

        psUnivTyVars  :: [TyVar],     -- Universially-quantified type variables
        psExTyVars    :: [TyVar],     -- Existentially-quantified type vars
        psProvTheta   :: ThetaType,   -- Provided dictionaries
        psReqTheta    :: ThetaType,   -- Required dictionaries
        psOrigResTy   :: Type,        -- Mentions only psUnivTyVars

        -- See Note [Matchers and wrappers for pattern synonyms]
        psMatcher     :: Id,
             -- Matcher function, of type
             --   forall r univ_tvs. req_theta
             --                   => res_ty
             --                   -> (forall ex_tvs. prov_theta -> arg_tys -> r)
             --                   -> r -> r

        psWrapper     :: Maybe Id
             -- Nothing  => uni-directional pattern synonym
             -- Just wid => bi-direcitonal
             -- Wrapper function, of type
             --  forall univ_tvs, ex_tvs. (prov_theta, req_theta)
             --                       =>  arg_tys -> res_ty
  }
  deriving Data.Typeable.Typeable
\end{code} %************************************************************************ %* * \subsection{Instances} %* * %************************************************************************ \begin{code} 
instance Eq PatSyn where
    (==) = (==) `on` getUnique
    (/=) = (/=) `on` getUnique

instance Ord PatSyn where
    (<=) = (<=) `on` getUnique
    (<) = (<) `on` getUnique
    (>=) = (>=) `on` getUnique
    (>) = (>) `on` getUnique
    compare = compare `on` getUnique

instance Uniquable PatSyn where
    getUnique = psUnique

instance NamedThing PatSyn where
    getName = patSynName

instance Outputable PatSyn where
    ppr = ppr . getName

instance OutputableBndr PatSyn where
    pprInfixOcc = pprInfixName . getName
    pprPrefixOcc = pprPrefixName . getName

instance Data.Data PatSyn where
    -- don't traverse?
    toConstr _   = abstractConstr "PatSyn"
    gunfold _ _  = error "gunfold"
    dataTypeOf _ = mkNoRepType "PatSyn"
\end{code} %************************************************************************ %* * \subsection{Construction} %* * %************************************************************************ \begin{code} 
-- | Build a new pattern synonym
mkPatSyn :: Name
         -> Bool       -- ^ Is the pattern synonym declared infix?
         -> [Type]     -- ^ Original arguments
         -> [TyVar]    -- ^ Universially-quantified type variables
         -> [TyVar]    -- ^ Existentially-quantified type variables
         -> ThetaType  -- ^ Wanted dicts
         -> ThetaType  -- ^ Given dicts
         -> Type       -- ^ Original result type
         -> Id         -- ^ Name of matcher
         -> Maybe Id   -- ^ Name of wrapper
         -> PatSyn
mkPatSyn name declared_infix orig_args
         univ_tvs ex_tvs
         prov_theta req_theta
         orig_res_ty
         matcher wrapper
    = MkPatSyn {psName = name, psUnique = getUnique name,
                psUnivTyVars = univ_tvs, psExTyVars = ex_tvs,
                psProvTheta = prov_theta, psReqTheta = req_theta,
                psInfix = declared_infix,
                psArgs = orig_args,
                psArity = length orig_args,
                psOrigResTy = orig_res_ty,
                psMatcher = matcher,
                psWrapper = wrapper }
\end{code} \begin{code} 
-- | The 'Name' of the 'PatSyn', giving it a unique, rooted identification
patSynName :: PatSyn -> Name
patSynName = psName

patSynType :: PatSyn -> Type
-- The full pattern type, used only in error messages
patSynType (MkPatSyn { psUnivTyVars = univ_tvs, psReqTheta = req_theta
                     , psExTyVars   = ex_tvs,   psProvTheta = prov_theta
                     , psArgs = orig_args, psOrigResTy = orig_res_ty })
  = mkSigmaTy univ_tvs req_theta $
    mkSigmaTy ex_tvs prov_theta $
    mkFunTys orig_args orig_res_ty

-- | Should the 'PatSyn' be presented infix?
patSynIsInfix :: PatSyn -> Bool
patSynIsInfix = psInfix

-- | Arity of the pattern synonym
patSynArity :: PatSyn -> Arity
patSynArity = psArity

patSynArgs :: PatSyn -> [Type]
patSynArgs = psArgs

patSynTyDetails :: PatSyn -> HsPatSynDetails Type
patSynTyDetails (MkPatSyn { psInfix = is_infix, psArgs = arg_tys })
  | is_infix, [left,right] <- arg_tys
  = InfixPatSyn left right
  | otherwise
  = PrefixPatSyn arg_tys

patSynExTyVars :: PatSyn -> [TyVar]
patSynExTyVars = psExTyVars

patSynSig :: PatSyn -> ([TyVar], [TyVar], ThetaType, ThetaType, [Type], Type)
patSynSig (MkPatSyn { psUnivTyVars = univ_tvs, psExTyVars = ex_tvs
                    , psProvTheta = prov, psReqTheta = req
                    , psArgs = arg_tys, psOrigResTy = res_ty })
  = (univ_tvs, ex_tvs, prov, req, arg_tys, res_ty)

patSynWrapper :: PatSyn -> Maybe Id
patSynWrapper = psWrapper

patSynMatcher :: PatSyn -> Id
patSynMatcher = psMatcher

tidyPatSynIds :: (Id -> Id) -> PatSyn -> PatSyn
tidyPatSynIds tidy_fn ps@(MkPatSyn { psMatcher = match_id, psWrapper = mb_wrap_id })
  = ps { psMatcher = tidy_fn match_id, psWrapper = fmap tidy_fn mb_wrap_id }

patSynInstArgTys :: PatSyn -> [Type] -> [Type]
-- Return the types of the argument patterns
-- e.g.  data D a = forall b. MkD a b (b->a)
--       pattern P f x y = MkD (x,True) y f
--          D :: forall a. forall b. a -> b -> (b->a) -> D a
--          P :: forall c. forall b. (b->(c,Bool)) -> c -> b -> P c
--   patSynInstArgTys P [Int,bb] = [bb->(Int,Bool), Int, bb]
-- NB: the inst_tys should be both universal and existential
patSynInstArgTys (MkPatSyn { psName = name, psUnivTyVars = univ_tvs
                           , psExTyVars = ex_tvs, psArgs = arg_tys })
                 inst_tys
  = ASSERT2( length tyvars == length inst_tys
          , ptext (sLit "patSynInstArgTys") <+> ppr name $$ ppr tyvars $$ ppr inst_tys )
    map (substTyWith tyvars inst_tys) arg_tys
  where
    tyvars = univ_tvs ++ ex_tvs

patSynInstResTy :: PatSyn -> [Type] -> Type
-- Return the type of whole pattern
-- E.g.  pattern P x y = Just (x,x,y)
--         P :: a -> b -> Just (a,a,b)
--         (patSynInstResTy P [Int,Bool] = Maybe (Int,Int,Bool)
-- NB: unlikepatSynInstArgTys, the inst_tys should be just the *universal* tyvars
patSynInstResTy (MkPatSyn { psName = name, psUnivTyVars = univ_tvs
                          , psOrigResTy = res_ty })
                inst_tys
  = ASSERT2( length univ_tvs == length inst_tys
           , ptext (sLit "patSynInstResTy") <+> ppr name $$ ppr univ_tvs $$ ppr inst_tys )
    substTyWith univ_tvs inst_tys res_ty
\end{code}