module Literal
( Literal(..) -- Exported to ParseIface
, mkMachInt, mkMachWord
- , mkMachInt64, mkMachWord64
+ , mkMachInt64, mkMachWord64, mkStringLit
, litSize
, litIsDupable, litIsTrivial
- , literalType, literalPrimRep
+ , literalType
, hashLiteral
, inIntRange, inWordRange, tARGET_MAX_INT, inCharRange
- , isZeroLit,
+ , isZeroLit
, word2IntLit, int2WordLit
, narrow8IntLit, narrow16IntLit, narrow32IntLit
import TysPrim ( charPrimTy, addrPrimTy, floatPrimTy, doublePrimTy,
intPrimTy, wordPrimTy, int64PrimTy, word64PrimTy
)
-import PrimRep ( PrimRep(..) )
import Type ( Type )
-import CStrings ( pprFSInCStyle )
-
import Outputable
import FastTypes
import FastString
= ------------------
-- First the primitive guys
MachChar Char -- Char# At least 31 bits
- | MachStr FastString
+
+ | MachStr FastString -- A string-literal: stored and emitted
+ -- UTF-8 encoded, we'll arrange to decode it
+ -- at runtime. Also emitted with a '\0'
+ -- terminator.
| MachNullAddr -- the NULL pointer, the only pointer value
-- that can be represented as a Literal.
mkMachInt64 x = MachInt64 x
mkMachWord64 x = MachWord64 x
+mkStringLit :: String -> Literal
+mkStringLit s = MachStr (mkFastString s) -- stored UTF-8 encoded
+
inIntRange, inWordRange :: Integer -> Bool
inIntRange x = x >= tARGET_MIN_INT && x <= tARGET_MAX_INT
inWordRange x = x >= 0 && x <= tARGET_MAX_WORD
~~~~~
\begin{code}
literalType :: Literal -> Type
-literalType (MachChar _) = charPrimTy
-literalType (MachStr _) = addrPrimTy
-literalType (MachNullAddr) = addrPrimTy
-literalType (MachInt _) = intPrimTy
-literalType (MachWord _) = wordPrimTy
-literalType (MachInt64 _) = int64PrimTy
-literalType (MachWord64 _) = word64PrimTy
-literalType (MachFloat _) = floatPrimTy
-literalType (MachDouble _) = doublePrimTy
-literalType (MachLabel _ _) = addrPrimTy
-\end{code}
-
-\begin{code}
-literalPrimRep :: Literal -> PrimRep
-
-literalPrimRep (MachChar _) = CharRep
-literalPrimRep (MachStr _) = AddrRep -- specifically: "char *"
-literalPrimRep (MachNullAddr) = AddrRep
-literalPrimRep (MachInt _) = IntRep
-literalPrimRep (MachWord _) = WordRep
-literalPrimRep (MachInt64 _) = Int64Rep
-literalPrimRep (MachWord64 _) = Word64Rep
-literalPrimRep (MachFloat _) = FloatRep
-literalPrimRep (MachDouble _) = DoubleRep
-literalPrimRep (MachLabel _ _) = AddrRep
+literalType MachNullAddr = addrPrimTy
+literalType (MachChar _) = charPrimTy
+literalType (MachStr _) = addrPrimTy
+literalType (MachInt _) = intPrimTy
+literalType (MachWord _) = wordPrimTy
+literalType (MachInt64 _) = int64PrimTy
+literalType (MachWord64 _) = word64PrimTy
+literalType (MachFloat _) = floatPrimTy
+literalType (MachDouble _) = doublePrimTy
+literalType (MachLabel _ _) = addrPrimTy
\end{code}
exceptions: MachFloat gets an initial keyword prefix.
\begin{code}
-pprLit lit
- = getPprStyle $ \ sty ->
- let
- code_style = codeStyle sty
- in
- case lit of
- MachChar ch | code_style -> hcat [ptext SLIT("(C_)"), text (show (ord ch))]
- | otherwise -> pprHsChar ch
-
- MachStr s | code_style -> pprFSInCStyle s
- | otherwise -> pprHsString s
- -- Warning: printing MachStr in code_style assumes it contains
- -- only characters '\0'..'\xFF'!
-
- MachInt i | code_style && i == tARGET_MIN_INT -> parens (integer (i+1) <> text "-1")
- -- Avoid a problem whereby gcc interprets
- -- the constant minInt as unsigned.
- | otherwise -> pprIntVal i
-
- MachInt64 i | code_style -> pprIntVal i -- Same problem with gcc???
- | otherwise -> ptext SLIT("__int64") <+> integer i
-
- MachWord w | code_style -> pprHexVal w
- | otherwise -> ptext SLIT("__word") <+> integer w
-
- MachWord64 w | code_style -> pprHexVal w
- | otherwise -> ptext SLIT("__word64") <+> integer w
-
- MachFloat f | code_style -> ptext SLIT("(StgFloat)") <> code_rational f
- | otherwise -> ptext SLIT("__float") <+> rational f
-
- MachDouble d | code_style -> code_rational d
- | otherwise -> rational d
-
- MachNullAddr | code_style -> ptext SLIT("(void*)0")
- | otherwise -> ptext SLIT("__NULL")
-
- MachLabel l mb
- | code_style -> ptext SLIT("(&") <> ftext l <> char ')'
- | otherwise -> ptext SLIT("__label") <+>
- case mb of
- Nothing -> pprHsString l
- Just x -> doubleQuotes (text (unpackFS l ++ '@':show x))
-
--- negative floating literals in code style need parentheses to avoid
--- interacting with surrounding syntax.
-code_rational d | d < 0 = parens (rational d)
- | otherwise = rational d
+pprLit (MachChar ch) = pprHsChar ch
+pprLit (MachStr s) = pprHsString s
+pprLit (MachInt i) = pprIntVal i
+pprLit (MachInt64 i) = ptext SLIT("__int64") <+> integer i
+pprLit (MachWord w) = ptext SLIT("__word") <+> integer w
+pprLit (MachWord64 w) = ptext SLIT("__word64") <+> integer w
+pprLit (MachFloat f) = ptext SLIT("__float") <+> rational f
+pprLit (MachDouble d) = rational d
+pprLit (MachNullAddr) = ptext SLIT("__NULL")
+pprLit (MachLabel l mb) = ptext SLIT("__label") <+>
+ case mb of
+ Nothing -> pprHsString l
+ Just x -> doubleQuotes (text (unpackFS l ++ '@':show x))
pprIntVal :: Integer -> SDoc
-- Print negative integers with parens to be sure it's unambiguous
pprIntVal i | i < 0 = parens (integer i)
| otherwise = integer i
-
-pprHexVal :: Integer -> SDoc
--- Print in C hex format: 0x13fa
-pprHexVal 0 = ptext SLIT("0x0")
-pprHexVal w = ptext SLIT("0x") <> go w
- where
- go 0 = empty
- go w = go quot <> dig
- where
- (quot,rem) = w `quotRem` 16
- dig | rem < 10 = char (chr (fromInteger rem + ord '0'))
- | otherwise = char (chr (fromInteger rem - 10 + ord 'a'))
\end{code}