{-# LANGUAGE TemplateHaskell #-} {-# OPTIONS -funbox-strict-fields #-} module Cmm.Op where import Data.Binary import Data.DeriveTH import Util.Gen import qualified Text.ParserCombinators.ReadP as P import Text.Read.Lex {- Basic operations. These are chosen to be roughly equivalent to c-- operations, but can be effectively used to generate C or assembly code as well. An operation consists of the operation itself, the type of the arguments and return value, and a hint attached to each argument. A condition is that the operation must be fully determined by the operation name and the type of its arguments. this specifically does not include the hint. For instance, since whether a number is signed or unsigned is in the hint, so the operation itself must say whether it is signed or unsigned. Also, distinct algorithms should be given different operations, for instance floating point and integer comparison are so different that they should be separate opcodes, even if it could be determined by the type they operate on. -} -- these take 2 arguments of the same type, and return one of the same type. -- an exception are the mulx routines, which may return a type exactly -- double in size of the original, and the shift and rotate routines, where the -- second argument may be of any width and is interpreted as an unsigned -- number. -- -- the invarient is that the return type is always exactly determined by the -- argument types data BinOp = Add | Sub | Mul | Mulx | UMulx | Div -- ^ round to -Infinity | Mod -- ^ mod rounding to -Infinity | Quot -- ^ round to 0 | Rem -- ^ rem rounding to 0 | UDiv -- ^ round to zero (unsigned) | UMod -- ^ unsigned mod -- bitwise | And | Or | Xor | Shl | Shr -- ^ shift right logical | Shra -- ^ shift right arithmetic | Rotl | Rotr -- floating | FAdd | FSub | FDiv | FMul | FPwr | FAtan2 -- These all compare two things of the same type, and return a boolean. | Eq | NEq | Gt | Gte | Lt | Lte -- unsigned versions | UGt | UGte | ULt | ULte -- floating point comparasons | FEq | FNEq | FGt | FGte | FLt | FLte -- whether two values can be compared at all. | FOrdered deriving(Eq,Show,Ord,Read,Enum,Bounded) data UnOp = Neg -- ^ 2s compliment negation | Com -- ^ bitwise compliment -- floating | FAbs -- ^ floating absolute value | FNeg -- ^ floating point negation | Sin | Cos | Tan | Sinh | Cosh | Tanh | Asin | Acos | Atan | Log | Exp | Sqrt -- exotic bit operations | Bswap -- ^ Switch the order of the bytes in a word | Ffs -- ^ Returns one plus the index of the least -- significant 1-bit of x, 0 if x is zero. | Clz -- ^ number of leading (from MSB) zeros, undefined if zero | Ctz -- ^ number of trailing (from LSB) zeros, undefined if zero. | Popcount -- ^ number of bits set to 1 in word | Parity -- ^ number of bits set to 1 mod 2 deriving(Eq,Show,Ord,Read,Enum,Bounded) -- conversion ops data ConvOp = F2I -- ^ convert a floating point to an integral value via truncation | F2U -- ^ convert a floating point to an unsigned integral value via truncation, negative values become zero | U2F -- ^ convert an unsigned integral value to a floating point number | I2F -- ^ convert an integral value to a floating point number | F2F -- ^ convert a float from one precision to another, preserving value as much as possible | Lobits -- ^ extract the low order bits | Sx -- ^ sign extend a value (signed) | Zx -- ^ zero extend a value (unsigned) | I2I -- ^ perform a 'Lobits' or a 'Sx' depending on the sizes of the arguments | U2U -- ^ perform a 'Lobits' or a 'Zx' depending on the sizes of the arguments | B2B -- ^ a nop, useful for coercing hints (bits 2 bits) deriving(Eq,Show,Ord,Read,Enum,Bounded) data ValOp = NaN | PInf | NInf | PZero | NZero deriving(Eq,Show,Ord,Read,Bounded) data ArchBits = BitsMax | BitsPtr | BitsUnknown deriving(Eq,Ord) data TyBits = Bits {-# UNPACK #-} !Int | BitsArch !ArchBits | BitsExt String deriving(Eq,Ord) data TyHint = HintSigned | HintUnsigned | HintFloat -- an IEEE floating point value | HintCharacter -- a unicode character, implies unsigned | HintNone -- no hint deriving(Eq,Ord) data Ty = TyBits !TyBits !TyHint | TyBool | TyComplex Ty | TyVector !Int Ty deriving(Eq,Ord) --runReadP :: ReadP a -> String -> Maybe a --runReadP rp s = case readP_to_S rp s of -- [(x,"")] -> Just x -- _ -> Nothing preadTy :: P.ReadP Ty preadTy = P.choice cs where cs = [ do P.string "bool"; return TyBool , do P.char 's'; TyBits x _ <- preadTy; return $ TyBits x HintSigned , do P.char 'u'; TyBits x _ <- preadTy; return $ TyBits x HintUnsigned , do P.char 'f'; TyBits x _ <- preadTy; return $ TyBits x HintFloat , do P.char 'c'; TyBits x _ <- preadTy; return $ TyBits x HintCharacter , do P.string "bits<"; x <- P.manyTill P.get (P.char '>'); return $ TyBits (f x) HintNone , do P.string "bits"; x <- readDecP; return $ TyBits (Bits x) HintNone , do n <- readDecP; P.char '*'; t <- preadTy; return (TyVector n t) , do P.string "i"; t <- preadTy; return (TyComplex t) ] f "ptr" = BitsArch BitsPtr f "max" = BitsArch BitsMax f "?" = BitsArch BitsUnknown f x = BitsExt x readTy :: Monad m => String -> m Ty readTy s = case runReadP preadTy s of Nothing -> fail "readTy: not type" Just x -> return x stringToOpTy :: String -> Ty stringToOpTy s = case readTy s of Just t -> t _ -> error $ "stringToOpTy: " ++ show s bool = TyBool bits_ptr = TyBits (BitsArch BitsPtr) HintNone bits_max = TyBits (BitsArch BitsMax) HintNone bits8 = TyBits (Bits 8) HintNone bits16 = TyBits (Bits 16) HintNone bits32 = TyBits (Bits 32) HintNone bits64 = TyBits (Bits 64) HintNone class ToCmmTy a where toCmmTy :: a -> Maybe Ty instance ToCmmTy Ty where toCmmTy a = Just a instance ToCmmTy String where toCmmTy s = readTy s cmmTyBits :: ToCmmTy a => a -> Maybe Int cmmTyBits x = do TyBits (Bits b) _ <- toCmmTy x; return b cmmTyHint x = do TyBits _ hint <- toCmmTy x; return hint instance Show TyHint where showsPrec _ HintSigned = ('s':) showsPrec _ HintUnsigned = ('u':) showsPrec _ HintFloat = ('f':) showsPrec _ HintCharacter = ('c':) showsPrec _ HintNone = id instance Show Ty where showsPrec _ TyBool = showString "bool" showsPrec _ (TyBits b h) = shows h . showString "bits" . shows b showsPrec _ (TyVector n t) = shows n . showChar '*' . shows t showsPrec _ (TyComplex t) = showChar 'i' . shows t instance Show TyBits where showsPrec _ (Bits n) = shows n showsPrec _ (BitsExt s) = showChar '<' . showString s . showChar '>' showsPrec _ (BitsArch s) = showChar '<' . shows s . showChar '>' instance Show ArchBits where show BitsMax = "max" show BitsPtr = "ptr" show BitsUnknown = "?" data Op v = BinOp BinOp v v | UnOp UnOp v | ValOp ValOp | ConvOp ConvOp v deriving(Eq,Show,Ord) binopType :: BinOp -> Ty -> Ty -> Ty binopType Mulx (TyBits (Bits i) h) _ = TyBits (Bits (i*2)) h binopType UMulx (TyBits (Bits i) h) _ = TyBits (Bits (i*2)) h binopType Eq _ _ = TyBool binopType NEq _ _ = TyBool binopType Gt _ _ = TyBool binopType Gte _ _ = TyBool binopType Lt _ _ = TyBool binopType Lte _ _ = TyBool binopType UGt _ _ = TyBool binopType UGte _ _ = TyBool binopType ULt _ _ = TyBool binopType ULte _ _ = TyBool binopType FEq _ _ = TyBool binopType FNEq _ _ = TyBool binopType FGt _ _ = TyBool binopType FGte _ _ = TyBool binopType FLt _ _ = TyBool binopType FLte _ _ = TyBool binopType FOrdered _ _ = TyBool binopType _ t1 _ = t1 isCommutable :: BinOp -> Bool isCommutable x = f x where f Add = True f Mul = True f And = True f Or = True f Xor = True f Eq = True f NEq = True f FAdd = True f FMul = True f FEq = True f FNEq = True f FOrdered = True f _ = False commuteBinOp :: BinOp -> Maybe BinOp commuteBinOp x | isCommutable x = return x commuteBinOp Lt = return Gt commuteBinOp Gt = return Lt commuteBinOp Lte = return Gte commuteBinOp Gte = return Lte commuteBinOp ULt = return UGt commuteBinOp UGt = return ULt commuteBinOp ULte = return UGte commuteBinOp UGte = return ULte commuteBinOp FLt = return FGt commuteBinOp FGt = return FLt commuteBinOp FLte = return FGte commuteBinOp FGte = return FLte commuteBinOp _ = Nothing isAssociative :: BinOp -> Bool isAssociative x = f x where f Add = True f Mul = True f And = True f Or = True f Xor = True f _ = False unopFloat :: Ty -> UnOp -> Maybe String unopFloat (TyBits b HintFloat) op = g b =<< f op where g (Bits 64) x = return x g (Bits 32) x = return $ x ++ "f" g _ _ = Nothing f FAbs = return "fabs" f Sin = return "sin" f Cos = return "cos" f Tan = return "tan" f Sinh = return "sinh" f Cosh = return "cosh" f Tanh = return "tanh" f Asin = return "asin" f Acos = return "acos" f Atan = return "atan" f Sqrt = return "sqrt" f Log = return "log" f Exp = return "exp" f _ = Nothing unopFloat _ _ = Nothing binopFunc :: Ty -> Ty -> BinOp -> Maybe String binopFunc (TyBits b _) _ bop = g b =<< f bop where g (Bits 64) x = return x g (Bits 32) x = return $ x ++ "f" g _ _ = Nothing f FPwr = Just "pow" f FAtan2 = Just "atan2" f _ = Nothing binopFunc TyBool _ bop = Nothing binopFunc _ _ _ = error "Op.binopFunc: bad." binopInfix :: BinOp -> Maybe (String,Int) binopInfix UDiv = Just ("/",8) binopInfix Mul = Just ("*",8) binopInfix UMod = Just ("%",8) binopInfix Sub = Just ("-",7) binopInfix Add = Just ("+",7) binopInfix Shr = Just (">>",6) binopInfix Shl = Just ("<<",6) binopInfix And = Just ("&",5) binopInfix Xor = Just ("^",4) binopInfix Or = Just ("|",3) binopInfix UGte = Just (">=",2) binopInfix UGt = Just (">",2) binopInfix ULte = Just ("<=",2) binopInfix ULt = Just ("<",2) binopInfix Eq = Just ("==",2) binopInfix NEq = Just ("!=",2) binopInfix _ = Nothing class IsOperator o where isCheap :: o -> Bool isEagerSafe :: o -> Bool instance IsOperator BinOp where isCheap FAtan2 = False isCheap _ = True isEagerSafe Div = False isEagerSafe Mod = False isEagerSafe Quot = False isEagerSafe Rem = False isEagerSafe UDiv = False isEagerSafe UMod = False isEagerSafe _ = True instance IsOperator UnOp where isCheap _ = True isEagerSafe _ = True instance IsOperator ConvOp where isCheap _ = True isEagerSafe _ = True instance IsOperator (Op v) where isCheap (BinOp o _ _) = isCheap o isCheap (UnOp o _) = isCheap o isCheap (ConvOp o _) = isCheap o isCheap _ = False isEagerSafe (BinOp o _ _) = isEagerSafe o isEagerSafe (UnOp o _) = isEagerSafe o isEagerSafe (ConvOp o _) = isEagerSafe o isEagerSafe _ = False $(derive makeBinary ''BinOp) $(derive makeBinary ''UnOp) $(derive makeBinary ''ConvOp) $(derive makeBinary ''ValOp) $(derive makeBinary ''ArchBits) $(derive makeBinary ''TyBits) $(derive makeBinary ''TyHint) $(derive makeBinary ''Ty) $(derive makeBinary ''Op)