%
% (c) The University of Glasgow 2006
% (c) The GRASP/AQUA Project, Glasgow University, 19921998
%
\section[HsLit]{Abstract syntax: sourcelanguage literals}
\begin{code}
module HsLit where
#include "HsVersions.h"
import HsExpr( SyntaxExpr, pprExpr )
import HsTypes (PostTcType)
import Type ( Type )
import Outputable
import FastString
\end{code}
%************************************************************************
%* *
\subsection[HsLit]{Literals}
%* *
%************************************************************************
\begin{code}
data HsLit
= HsChar Char
| HsCharPrim Char
| HsString FastString
| HsStringPrim FastString
| HsInt Integer
| HsIntPrim Integer
| HsWordPrim Integer
| HsInteger Integer Type
| HsRat Rational Type
| HsFloatPrim Rational
| HsDoublePrim Rational
instance Eq HsLit where
(HsChar x1) == (HsChar x2) = x1==x2
(HsCharPrim x1) == (HsCharPrim x2) = x1==x2
(HsString x1) == (HsString x2) = x1==x2
(HsStringPrim x1) == (HsStringPrim x2) = x1==x2
(HsInt x1) == (HsInt x2) = x1==x2
(HsIntPrim x1) == (HsIntPrim x2) = x1==x2
(HsWordPrim x1) == (HsWordPrim x2) = x1==x2
(HsInteger x1 _) == (HsInteger x2 _) = x1==x2
(HsRat x1 _) == (HsRat x2 _) = x1==x2
(HsFloatPrim x1) == (HsFloatPrim x2) = x1==x2
(HsDoublePrim x1) == (HsDoublePrim x2) = x1==x2
_ == _ = False
data HsOverLit id
= OverLit {
ol_val :: OverLitVal,
ol_rebindable :: Bool,
ol_witness :: SyntaxExpr id,
ol_type :: PostTcType }
data OverLitVal
= HsIntegral !Integer
| HsFractional !Rational
| HsIsString !FastString
overLitType :: HsOverLit a -> Type
overLitType = ol_type
\end{code}
Note [Overloaded literal witnesses]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
*Before* type checking, the SyntaxExpr in an HsOverLit is the
name of the coercion function, 'fromInteger' or 'fromRational'.
*After* type checking, it is a witness for the literal, such as
(fromInteger 3) or lit_78
This witness should replace the literal.
This dual role is unusual, because we're replacing 'fromInteger' with
a call to fromInteger. Reason: it allows commoning up of the fromInteger
calls, which wouldn't be possible if the desguarar made the application
The PostTcType in each branch records the type the overload literal is
found to have.
\begin{code}
instance Eq (HsOverLit id) where
(OverLit {ol_val = val1}) == (OverLit {ol_val=val2}) = val1 == val2
instance Eq OverLitVal where
(HsIntegral i1) == (HsIntegral i2) = i1 == i2
(HsFractional f1) == (HsFractional f2) = f1 == f2
(HsIsString s1) == (HsIsString s2) = s1 == s2
_ == _ = False
instance Ord (HsOverLit id) where
compare (OverLit {ol_val=val1}) (OverLit {ol_val=val2}) = val1 `compare` val2
instance Ord OverLitVal where
compare (HsIntegral i1) (HsIntegral i2) = i1 `compare` i2
compare (HsIntegral _) (HsFractional _) = LT
compare (HsIntegral _) (HsIsString _) = LT
compare (HsFractional f1) (HsFractional f2) = f1 `compare` f2
compare (HsFractional _) (HsIntegral _) = GT
compare (HsFractional _) (HsIsString _) = LT
compare (HsIsString s1) (HsIsString s2) = s1 `compare` s2
compare (HsIsString _) (HsIntegral _) = GT
compare (HsIsString _) (HsFractional _) = GT
\end{code}
\begin{code}
instance Outputable HsLit where
ppr (HsChar c) = pprHsChar c
ppr (HsCharPrim c) = pprHsChar c <> char '#'
ppr (HsString s) = pprHsString s
ppr (HsStringPrim s) = pprHsString s <> char '#'
ppr (HsInt i) = integer i
ppr (HsInteger i _) = integer i
ppr (HsRat f _) = rational f
ppr (HsFloatPrim f) = rational f <> char '#'
ppr (HsDoublePrim d) = rational d <> text "##"
ppr (HsIntPrim i) = integer i <> char '#'
ppr (HsWordPrim w) = integer w <> text "##"
instance OutputableBndr id => Outputable (HsOverLit id) where
ppr (OverLit {ol_val=val, ol_witness=witness})
= ppr val <+> (ifPprDebug (parens (pprExpr witness)))
instance Outputable OverLitVal where
ppr (HsIntegral i) = integer i
ppr (HsFractional f) = rational f
ppr (HsIsString s) = pprHsString s
\end{code}