% % (c) The University of Glasgow 2006 % (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 % \section[PatSyntax]{Abstract Haskell syntax---patterns} \begin{code}
{-# OPTIONS -fno-warn-incomplete-patterns #-}
-- The above warning supression flag is a temporary kludge.
-- While working on this module you are encouraged to remove it and fix
-- any warnings in the module. See
--     http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#Warnings
-- for details
{-# LANGUAGE DeriveDataTypeable #-}

module HsPat (
	Pat(..), InPat, OutPat, LPat, 
	
	HsConDetails(..), 
	HsConPatDetails, hsConPatArgs, 
	HsRecFields(..), HsRecField(..), hsRecFields,

	mkPrefixConPat, mkCharLitPat, mkNilPat, 

	isBangHsBind, isBangLPat, hsPatNeedsParens,
	isIrrefutableHsPat,

	pprParendLPat
    ) where

import {-# SOURCE #-} HsExpr		(SyntaxExpr, LHsExpr, pprLExpr)

-- friends:
import HsBinds
import HsLit
import HsTypes
import BasicTypes
-- others:
import PprCore		( {- instance OutputableBndr TyVar -} )
import TysWiredIn
import Var
import DataCon
import TyCon
import Outputable	
import Type
import SrcLoc
import FastString
-- libraries:
import Data.Data hiding (TyCon)
import Data.Maybe
\end{code} \begin{code}
type InPat id  = LPat id	-- No 'Out' constructors
type OutPat id = LPat id	-- No 'In' constructors

type LPat id = Located (Pat id)

data Pat id
  =	------------ Simple patterns ---------------
    WildPat	PostTcType		-- Wild card
	-- The sole reason for a type on a WildPat is to
	-- support hsPatType :: Pat Id -> Type

  | VarPat	id			-- Variable
  | VarPatOut	id TcEvBinds		-- Used only for overloaded Ids; the 
					-- bindings give its overloaded instances
  | LazyPat	(LPat id)		-- Lazy pattern
  | AsPat	(Located id) (LPat id)  -- As pattern
  | ParPat      (LPat id)		-- Parenthesised pattern
  | BangPat	(LPat id)		-- Bang pattern

	------------ Lists, tuples, arrays ---------------
  | ListPat	[LPat id]		-- Syntactic list
		PostTcType		-- The type of the elements
   	    	    
  | TuplePat	[LPat id]		-- Tuple
		Boxity			-- UnitPat is TuplePat []
		PostTcType
	-- You might think that the PostTcType was redundant, but it's essential
	--	data T a where
	--	  T1 :: Int -> T Int
	--	f :: (T a, a) -> Int
	--	f (T1 x, z) = z
	-- When desugaring, we must generate
	--	f = /\a. \v::a.  case v of (t::T a, w::a) ->
	--			 case t of (T1 (x::Int)) -> 
	-- Note the (w::a), NOT (w::Int), because we have not yet
	-- refined 'a' to Int.  So we must know that the second component
	-- of the tuple is of type 'a' not Int.  See selectMatchVar

  | PArrPat	[LPat id]		-- Syntactic parallel array
		PostTcType		-- The type of the elements

	------------ Constructor patterns ---------------
  | ConPatIn	(Located id)
		(HsConPatDetails id)

  | ConPatOut {
	pat_con   :: Located DataCon,
	pat_tvs   :: [TyVar],		-- Existentially bound type variables (tyvars only)
	pat_dicts :: [EvVar],		-- Ditto *coercion variables* and *dictionaries*
					-- One reason for putting coercion variable here, I think,
					-- 	is to ensure their kinds are zonked
	pat_binds :: TcEvBinds,		-- Bindings involving those dictionaries
	pat_args  :: HsConPatDetails id,
	pat_ty	  :: Type   		-- The type of the pattern
    }

	------------ View patterns ---------------
  | ViewPat       (LHsExpr id)      
                  (LPat id)
                  PostTcType        -- The overall type of the pattern
                                    -- (= the argument type of the view function)
                                    -- for hsPatType.

	------------ Quasiquoted patterns ---------------
	-- See Note [Quasi-quote overview] in TcSplice
  | QuasiQuotePat   (HsQuasiQuote id)

	------------ Literal and n+k patterns ---------------
  | LitPat	    HsLit		-- Used for *non-overloaded* literal patterns:
					-- Int#, Char#, Int, Char, String, etc.

  | NPat	    (HsOverLit id)		-- ALWAYS positive
		    (Maybe (SyntaxExpr id))	-- Just (Name of 'negate') for negative
						-- patterns, Nothing otherwise
		    (SyntaxExpr id)		-- Equality checker, of type t->t->Bool

  | NPlusKPat	    (Located id)	-- n+k pattern
		    (HsOverLit id)	-- It'll always be an HsIntegral
		    (SyntaxExpr id)	-- (>=) function, of type t->t->Bool
		    (SyntaxExpr id)	-- Name of '-' (see RnEnv.lookupSyntaxName)

	------------ Generics ---------------
  | TypePat	    (LHsType id)	-- Type pattern for generic definitions
                                        -- e.g  f{| a+b |} = ...
                                        -- These show up only in class declarations,
                                        -- and should be a top-level pattern

	------------ Pattern type signatures ---------------
  | SigPatIn	    (LPat id)		-- Pattern with a type signature
		    (LHsType id)

  | SigPatOut	    (LPat id)		-- Pattern with a type signature
		    Type

	------------ Pattern coercions (translation only) ---------------
  | CoPat 	HsWrapper		-- If co :: t1 ~ t2, p :: t2, 
					-- then (CoPat co p) :: t1
		(Pat id)		-- Why not LPat?  Ans: existing locn will do
	    	Type			-- Type of whole pattern, t1
	-- During desugaring a (CoPat co pat) turns into a cast with 'co' on 
	-- the scrutinee, followed by a match on 'pat'
  deriving (Data, Typeable)
\end{code} HsConDetails is use for patterns/expressions *and* for data type declarations \begin{code}
data HsConDetails arg rec
  = PrefixCon [arg]             -- C p1 p2 p3
  | RecCon    rec		-- C { x = p1, y = p2 }
  | InfixCon  arg arg		-- p1 `C` p2
  deriving (Data, Typeable)

type HsConPatDetails id = HsConDetails (LPat id) (HsRecFields id (LPat id))

hsConPatArgs :: HsConPatDetails id -> [LPat id]
hsConPatArgs (PrefixCon ps)   = ps
hsConPatArgs (RecCon fs)      = map hsRecFieldArg (rec_flds fs)
hsConPatArgs (InfixCon p1 p2) = [p1,p2]
\end{code} However HsRecFields is used only for patterns and expressions (not data type declarations) \begin{code}
data HsRecFields id arg 	-- A bunch of record fields
				--	{ x = 3, y = True }
	-- Used for both expressions and patterns
  = HsRecFields { rec_flds   :: [HsRecField id arg],
		  rec_dotdot :: Maybe Int }  -- Note [DotDot fields]
  deriving (Data, Typeable)

-- Note [DotDot fields]
-- ~~~~~~~~~~~~~~~~~~~~
-- The rec_dotdot field means this:
--   Nothing => the normal case
--   Just n  => the group uses ".." notation, 
--
-- In the latter case: 
--
--   *before* renamer: rec_flds are exactly the n user-written fields
--
--   *after* renamer:  rec_flds includes *all* fields, with 
--   	     	       the first 'n' being the user-written ones
--		       and the remainder being 'filled in' implicitly

data HsRecField id arg = HsRecField {
	hsRecFieldId  :: Located id,
	hsRecFieldArg :: arg,		-- Filled in by renamer
	hsRecPun      :: Bool 		-- Note [Punning]
  } deriving (Data, Typeable)

-- Note [Punning]
-- ~~~~~~~~~~~~~~
-- If you write T { x, y = v+1 }, the HsRecFields will be
--	HsRecField x x True ...
--	HsRecField y (v+1) False ...
-- That is, for "punned" field x is expanded (in the renamer) 
-- to x=x; but with a punning flag so we can detect it later
-- (e.g. when pretty printing)
--
-- If the original field was qualified, we un-qualify it, thus
--    T { A.x } means T { A.x = x }

hsRecFields :: HsRecFields id arg -> [id]
hsRecFields rbinds = map (unLoc . hsRecFieldId) (rec_flds rbinds)
\end{code} %************************************************************************ %* * %* Printing patterns %* * %************************************************************************ \begin{code}
instance (OutputableBndr name) => Outputable (Pat name) where
    ppr = pprPat

pprPatBndr :: OutputableBndr name => name -> SDoc
pprPatBndr var		  	-- Print with type info if -dppr-debug is on
  = getPprStyle $ \ sty ->
    if debugStyle sty then
	parens (pprBndr LambdaBind var)		-- Could pass the site to pprPat
						-- but is it worth it?
    else
	ppr var

pprParendLPat :: (OutputableBndr name) => LPat name -> SDoc
pprParendLPat (L _ p) = pprParendPat p

pprParendPat :: (OutputableBndr name) => Pat name -> SDoc
pprParendPat p | patNeedsParens p = parens (pprPat p)
               | otherwise        = pprPat p

patNeedsParens :: Pat name -> Bool
patNeedsParens (ConPatIn _ d)               = not (null (hsConPatArgs d))
patNeedsParens (ConPatOut { pat_args = d }) = not (null (hsConPatArgs d))
patNeedsParens (SigPatIn {})  = True
patNeedsParens (SigPatOut {}) = True
patNeedsParens (ViewPat {})   = True
patNeedsParens (CoPat {})     = True
patNeedsParens _              = False

pprPat :: (OutputableBndr name) => Pat name -> SDoc
pprPat (VarPat var)  	  = pprPatBndr var
pprPat (VarPatOut var bs) = pprPatBndr var <+> braces (ppr bs)
pprPat (WildPat _)	  = char '_'
pprPat (LazyPat pat)      = char '~' <> pprParendLPat pat
pprPat (BangPat pat)      = char '!' <> pprParendLPat pat
pprPat (AsPat name pat)   = hcat [ppr name, char '@', pprParendLPat pat]
pprPat (ViewPat expr pat _) = hcat [pprLExpr expr, text " -> ", ppr pat]
pprPat (ParPat pat)	    = parens (ppr pat)
pprPat (ListPat pats _)     = brackets (interpp'SP pats)
pprPat (PArrPat pats _)     = pabrackets (interpp'SP pats)
pprPat (TuplePat pats bx _) = tupleParens bx (interpp'SP pats)

pprPat (ConPatIn con details) = pprUserCon con details
pprPat (ConPatOut { pat_con = con, pat_tvs = tvs, pat_dicts = dicts, 
		    pat_binds = binds, pat_args = details })
  = getPprStyle $ \ sty ->	-- Tiresome; in TcBinds.tcRhs we print out a 
    if debugStyle sty then 	-- typechecked Pat in an error message, 
				-- and we want to make sure it prints nicely
	ppr con <+> sep [ hsep (map pprPatBndr tvs) <+> hsep (map pprPatBndr dicts),
		   	  ppr binds, pprConArgs details]
    else pprUserCon con details

pprPat (LitPat s)	    = ppr s
pprPat (NPat l Nothing  _)  = ppr l
pprPat (NPat l (Just _) _)  = char '-' <> ppr l
pprPat (NPlusKPat n k _ _)  = hcat [ppr n, char '+', ppr k]
pprPat (QuasiQuotePat qq)   = ppr qq
pprPat (TypePat ty)	    = ptext (sLit "{|") <> ppr ty <> ptext (sLit "|}")
pprPat (CoPat co pat _)	    = pprHsWrapper (ppr pat) co
pprPat (SigPatIn pat ty)    = ppr pat <+> dcolon <+> ppr ty
pprPat (SigPatOut pat ty)   = ppr pat <+> dcolon <+> ppr ty

pprUserCon :: (Outputable con, OutputableBndr id) => con -> HsConPatDetails id -> SDoc
pprUserCon c (InfixCon p1 p2) = ppr p1 <+> ppr c <+> ppr p2
pprUserCon c details          = ppr c <+> pprConArgs details

pprConArgs ::  OutputableBndr id => HsConPatDetails id -> SDoc
pprConArgs (PrefixCon pats) = sep (map pprParendLPat pats)
pprConArgs (InfixCon p1 p2) = sep [pprParendLPat p1, pprParendLPat p2]
pprConArgs (RecCon rpats)   = ppr rpats

instance (OutputableBndr id, Outputable arg)
      => Outputable (HsRecFields id arg) where
  ppr (HsRecFields { rec_flds = flds, rec_dotdot = Nothing })
	= braces (fsep (punctuate comma (map ppr flds)))
  ppr (HsRecFields { rec_flds = flds, rec_dotdot = Just n })
	= braces (fsep (punctuate comma (map ppr (take n flds) ++ [dotdot])))
	where
	  dotdot = ptext (sLit "..") <+> ifPprDebug (ppr (drop n flds))

instance (OutputableBndr id, Outputable arg)
      => Outputable (HsRecField id arg) where
  ppr (HsRecField { hsRecFieldId = f, hsRecFieldArg = arg, 
		    hsRecPun = pun })
    = ppr f <+> (ppUnless pun $ equals <+> ppr arg)

-- add parallel array brackets around a document
--
pabrackets   :: SDoc -> SDoc
pabrackets p  = ptext (sLit "[:") <> p <> ptext (sLit ":]")
\end{code} %************************************************************************ %* * %* Building patterns %* * %************************************************************************ \begin{code}
mkPrefixConPat :: DataCon -> [OutPat id] -> Type -> OutPat id
-- Make a vanilla Prefix constructor pattern
mkPrefixConPat dc pats ty 
  = noLoc $ ConPatOut { pat_con = noLoc dc, pat_tvs = [], pat_dicts = [],
			pat_binds = emptyTcEvBinds, pat_args = PrefixCon pats, 
			pat_ty = ty }

mkNilPat :: Type -> OutPat id
mkNilPat ty = mkPrefixConPat nilDataCon [] ty

mkCharLitPat :: Char -> OutPat id
mkCharLitPat c = mkPrefixConPat charDataCon [noLoc $ LitPat (HsCharPrim c)] charTy
\end{code} %************************************************************************ %* * %* Predicates for checking things about pattern-lists in EquationInfo * %* * %************************************************************************ \subsection[Pat-list-predicates]{Look for interesting things in patterns} Unlike in the Wadler chapter, where patterns are either ``variables'' or ``constructors,'' here we distinguish between: \begin{description} \item[unfailable:] Patterns that cannot fail to match: variables, wildcards, and lazy patterns. These are the irrefutable patterns; the two other categories are refutable patterns. \item[constructor:] A non-literal constructor pattern (see next category). \item[literal patterns:] At least the numeric ones may be overloaded. \end{description} A pattern is in {\em exactly one} of the above three categories; `as' patterns are treated specially, of course. The 1.3 report defines what ``irrefutable'' and ``failure-free'' patterns are. \begin{code}
isBangLPat :: LPat id -> Bool
isBangLPat (L _ (BangPat {})) = True
isBangLPat (L _ (ParPat p))   = isBangLPat p
isBangLPat _                  = False

isBangHsBind :: HsBind id -> Bool
-- In this module because HsPat is above HsBinds in the import graph
isBangHsBind (PatBind { pat_lhs = p }) = isBangLPat p
isBangHsBind _                         = False

isIrrefutableHsPat :: OutputableBndr id => LPat id -> Bool
-- (isIrrefutableHsPat p) is true if matching against p cannot fail,
-- in the sense of falling through to the next pattern.
--	(NB: this is not quite the same as the (silly) defn
--	in 3.17.2 of the Haskell 98 report.)
-- 
-- isIrrefutableHsPat returns False if it's in doubt; specifically
-- on a ConPatIn it doesn't know the size of the constructor family
-- But if it returns True, the pattern is definitely irrefutable
isIrrefutableHsPat pat
  = go pat
  where
    go (L _ pat) = go1 pat

    go1 (WildPat {})        = True
    go1 (VarPat {})         = True
    go1 (VarPatOut {})      = True
    go1 (LazyPat {})        = True
    go1 (BangPat pat)       = go pat
    go1 (CoPat _ pat _)     = go1 pat
    go1 (ParPat pat)        = go pat
    go1 (AsPat _ pat)       = go pat
    go1 (ViewPat _ pat _)   = go pat
    go1 (SigPatIn pat _)    = go pat
    go1 (SigPatOut pat _)   = go pat
    go1 (TuplePat pats _ _) = all go pats
    go1 (ListPat {})        = False
    go1 (PArrPat {})        = False	-- ?

    go1 (ConPatIn {})       = False	-- Conservative
    go1 (ConPatOut{ pat_con = L _ con, pat_args = details }) 
	=  isJust (tyConSingleDataCon_maybe (dataConTyCon con))
	   -- NB: tyConSingleDataCon_maybe, *not* isProductTyCon, because 
	   -- the latter is false of existentials. See Trac #4439
	&& all go (hsConPatArgs details)

    go1 (LitPat {})    = False
    go1 (NPat {})      = False
    go1 (NPlusKPat {}) = False

    go1 (QuasiQuotePat {}) = urk pat	-- Gotten rid of by renamer, before
					-- isIrrefutablePat is called
    go1 (TypePat {})       = urk pat

    urk pat = pprPanic "isIrrefutableHsPat:" (ppr pat)

hsPatNeedsParens :: Pat a -> Bool
hsPatNeedsParens (WildPat {})        = False
hsPatNeedsParens (VarPat {})         = False
hsPatNeedsParens (VarPatOut {})      = True
hsPatNeedsParens (LazyPat {})        = False
hsPatNeedsParens (BangPat {})        = False
hsPatNeedsParens (CoPat {})          = True
hsPatNeedsParens (ParPat {})         = False
hsPatNeedsParens (AsPat {})          = False
hsPatNeedsParens (ViewPat {})        = True
hsPatNeedsParens (SigPatIn {})       = True
hsPatNeedsParens (SigPatOut {})      = True
hsPatNeedsParens (TuplePat {})       = False
hsPatNeedsParens (ListPat {})        = False
hsPatNeedsParens (PArrPat {})        = False	
hsPatNeedsParens (ConPatIn _ ds)     = conPatNeedsParens ds
hsPatNeedsParens (ConPatOut {})      = True
hsPatNeedsParens (LitPat {})   	     = False
hsPatNeedsParens (NPat {})	     = False
hsPatNeedsParens (NPlusKPat {})      = True
hsPatNeedsParens (QuasiQuotePat {})  = True
hsPatNeedsParens (TypePat {})        = False

conPatNeedsParens :: HsConDetails a b -> Bool
conPatNeedsParens (PrefixCon args) = not (null args)
conPatNeedsParens (InfixCon {})    = False
conPatNeedsParens (RecCon {})      = False
\end{code}