{-# LANGUAGE CPP, RankNTypes #-}
{-# OPTIONS_GHC -optc-DNON_POSIX_SOURCE #-}
module PrelRules
( primOpRules
, builtinRules
, caseRules
)
where
#include "HsVersions.h"
#include "MachDeps.h"
import {-# SOURCE #-} MkId ( mkPrimOpId, magicDictId )
import CoreSyn
import MkCore
import Id
import Literal
import CoreOpt ( exprIsLiteral_maybe )
import PrimOp ( PrimOp(..), tagToEnumKey )
import TysWiredIn
import TysPrim
import TyCon ( tyConDataCons_maybe, isEnumerationTyCon, isNewTyCon, unwrapNewTyCon_maybe )
import DataCon ( dataConTag, dataConTyCon, dataConWorkId )
import CoreUtils ( cheapEqExpr, exprIsHNF )
import CoreUnfold ( exprIsConApp_maybe )
import Type
import OccName ( occNameFS )
import PrelNames
import Maybes ( orElse )
import Name ( Name, nameOccName )
import Outputable
import FastString
import BasicTypes
import DynFlags
import Platform
import Util
import Coercion (mkUnbranchedAxInstCo,mkSymCo,Role(..))
import Control.Applicative ( Alternative(..) )
import Control.Monad
#if __GLASGOW_HASKELL__ > 710
import qualified Control.Monad.Fail as MonadFail
#endif
import Data.Bits as Bits
import qualified Data.ByteString as BS
import Data.Int
import Data.Ratio
import Data.Word
primOpRules :: Name -> PrimOp -> Maybe CoreRule
primOpRules nm TagToEnumOp = mkPrimOpRule nm 2 [ tagToEnumRule ]
primOpRules nm DataToTagOp = mkPrimOpRule nm 2 [ dataToTagRule ]
primOpRules nm IntAddOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (+))
, identityDynFlags zeroi ]
primOpRules nm IntSubOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (-))
, rightIdentityDynFlags zeroi
, equalArgs >> retLit zeroi ]
primOpRules nm IntMulOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (*))
, zeroElem zeroi
, identityDynFlags onei ]
primOpRules nm IntQuotOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (intOp2 quot)
, leftZero zeroi
, rightIdentityDynFlags onei
, equalArgs >> retLit onei ]
primOpRules nm IntRemOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (intOp2 rem)
, leftZero zeroi
, do l <- getLiteral 1
dflags <- getDynFlags
guard (l == onei dflags)
retLit zeroi
, equalArgs >> retLit zeroi
, equalArgs >> retLit zeroi ]
primOpRules nm AndIOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (.&.))
, idempotent
, zeroElem zeroi ]
primOpRules nm OrIOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (.|.))
, idempotent
, identityDynFlags zeroi ]
primOpRules nm XorIOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 xor)
, identityDynFlags zeroi
, equalArgs >> retLit zeroi ]
primOpRules nm NotIOp = mkPrimOpRule nm 1 [ unaryLit complementOp
, inversePrimOp NotIOp ]
primOpRules nm IntNegOp = mkPrimOpRule nm 1 [ unaryLit negOp
, inversePrimOp IntNegOp ]
primOpRules nm ISllOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 Bits.shiftL)
, rightIdentityDynFlags zeroi ]
primOpRules nm ISraOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 Bits.shiftR)
, rightIdentityDynFlags zeroi ]
primOpRules nm ISrlOp = mkPrimOpRule nm 2 [ binaryLit (intOp2' shiftRightLogical)
, rightIdentityDynFlags zeroi ]
primOpRules nm WordAddOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (+))
, identityDynFlags zerow ]
primOpRules nm WordSubOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (-))
, rightIdentityDynFlags zerow
, equalArgs >> retLit zerow ]
primOpRules nm WordMulOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (*))
, identityDynFlags onew ]
primOpRules nm WordQuotOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (wordOp2 quot)
, rightIdentityDynFlags onew ]
primOpRules nm WordRemOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (wordOp2 rem)
, leftZero zerow
, do l <- getLiteral 1
dflags <- getDynFlags
guard (l == onew dflags)
retLit zerow
, equalArgs >> retLit zerow ]
primOpRules nm AndOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (.&.))
, idempotent
, zeroElem zerow ]
primOpRules nm OrOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (.|.))
, idempotent
, identityDynFlags zerow ]
primOpRules nm XorOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 xor)
, identityDynFlags zerow
, equalArgs >> retLit zerow ]
primOpRules nm NotOp = mkPrimOpRule nm 1 [ unaryLit complementOp
, inversePrimOp NotOp ]
primOpRules nm SllOp = mkPrimOpRule nm 2 [ wordShiftRule (const Bits.shiftL) ]
primOpRules nm SrlOp = mkPrimOpRule nm 2 [ wordShiftRule shiftRightLogical ]
primOpRules nm Word2IntOp = mkPrimOpRule nm 1 [ liftLitDynFlags word2IntLit
, inversePrimOp Int2WordOp ]
primOpRules nm Int2WordOp = mkPrimOpRule nm 1 [ liftLitDynFlags int2WordLit
, inversePrimOp Word2IntOp ]
primOpRules nm Narrow8IntOp = mkPrimOpRule nm 1 [ liftLit narrow8IntLit
, subsumedByPrimOp Narrow8IntOp
, Narrow8IntOp `subsumesPrimOp` Narrow16IntOp
, Narrow8IntOp `subsumesPrimOp` Narrow32IntOp ]
primOpRules nm Narrow16IntOp = mkPrimOpRule nm 1 [ liftLit narrow16IntLit
, subsumedByPrimOp Narrow8IntOp
, subsumedByPrimOp Narrow16IntOp
, Narrow16IntOp `subsumesPrimOp` Narrow32IntOp ]
primOpRules nm Narrow32IntOp = mkPrimOpRule nm 1 [ liftLit narrow32IntLit
, subsumedByPrimOp Narrow8IntOp
, subsumedByPrimOp Narrow16IntOp
, subsumedByPrimOp Narrow32IntOp
, removeOp32 ]
primOpRules nm Narrow8WordOp = mkPrimOpRule nm 1 [ liftLit narrow8WordLit
, subsumedByPrimOp Narrow8WordOp
, Narrow8WordOp `subsumesPrimOp` Narrow16WordOp
, Narrow8WordOp `subsumesPrimOp` Narrow32WordOp ]
primOpRules nm Narrow16WordOp = mkPrimOpRule nm 1 [ liftLit narrow16WordLit
, subsumedByPrimOp Narrow8WordOp
, subsumedByPrimOp Narrow16WordOp
, Narrow16WordOp `subsumesPrimOp` Narrow32WordOp ]
primOpRules nm Narrow32WordOp = mkPrimOpRule nm 1 [ liftLit narrow32WordLit
, subsumedByPrimOp Narrow8WordOp
, subsumedByPrimOp Narrow16WordOp
, subsumedByPrimOp Narrow32WordOp
, removeOp32 ]
primOpRules nm OrdOp = mkPrimOpRule nm 1 [ liftLit char2IntLit
, inversePrimOp ChrOp ]
primOpRules nm ChrOp = mkPrimOpRule nm 1 [ do [Lit lit] <- getArgs
guard (litFitsInChar lit)
liftLit int2CharLit
, inversePrimOp OrdOp ]
primOpRules nm Float2IntOp = mkPrimOpRule nm 1 [ liftLit float2IntLit ]
primOpRules nm Int2FloatOp = mkPrimOpRule nm 1 [ liftLit int2FloatLit ]
primOpRules nm Double2IntOp = mkPrimOpRule nm 1 [ liftLit double2IntLit ]
primOpRules nm Int2DoubleOp = mkPrimOpRule nm 1 [ liftLit int2DoubleLit ]
primOpRules nm Float2DoubleOp = mkPrimOpRule nm 1 [ liftLit float2DoubleLit ]
primOpRules nm Double2FloatOp = mkPrimOpRule nm 1 [ liftLit double2FloatLit ]
primOpRules nm FloatAddOp = mkPrimOpRule nm 2 [ binaryLit (floatOp2 (+))
, identity zerof ]
primOpRules nm FloatSubOp = mkPrimOpRule nm 2 [ binaryLit (floatOp2 (-))
, rightIdentity zerof ]
primOpRules nm FloatMulOp = mkPrimOpRule nm 2 [ binaryLit (floatOp2 (*))
, identity onef
, strengthReduction twof FloatAddOp ]
primOpRules nm FloatDivOp = mkPrimOpRule nm 2 [ guardFloatDiv >> binaryLit (floatOp2 (/))
, rightIdentity onef ]
primOpRules nm FloatNegOp = mkPrimOpRule nm 1 [ unaryLit negOp
, inversePrimOp FloatNegOp ]
primOpRules nm DoubleAddOp = mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (+))
, identity zerod ]
primOpRules nm DoubleSubOp = mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (-))
, rightIdentity zerod ]
primOpRules nm DoubleMulOp = mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (*))
, identity oned
, strengthReduction twod DoubleAddOp ]
primOpRules nm DoubleDivOp = mkPrimOpRule nm 2 [ guardDoubleDiv >> binaryLit (doubleOp2 (/))
, rightIdentity oned ]
primOpRules nm DoubleNegOp = mkPrimOpRule nm 1 [ unaryLit negOp
, inversePrimOp DoubleNegOp ]
primOpRules nm IntEqOp = mkRelOpRule nm (==) [ litEq True ]
primOpRules nm IntNeOp = mkRelOpRule nm (/=) [ litEq False ]
primOpRules nm CharEqOp = mkRelOpRule nm (==) [ litEq True ]
primOpRules nm CharNeOp = mkRelOpRule nm (/=) [ litEq False ]
primOpRules nm IntGtOp = mkRelOpRule nm (>) [ boundsCmp Gt ]
primOpRules nm IntGeOp = mkRelOpRule nm (>=) [ boundsCmp Ge ]
primOpRules nm IntLeOp = mkRelOpRule nm (<=) [ boundsCmp Le ]
primOpRules nm IntLtOp = mkRelOpRule nm (<) [ boundsCmp Lt ]
primOpRules nm CharGtOp = mkRelOpRule nm (>) [ boundsCmp Gt ]
primOpRules nm CharGeOp = mkRelOpRule nm (>=) [ boundsCmp Ge ]
primOpRules nm CharLeOp = mkRelOpRule nm (<=) [ boundsCmp Le ]
primOpRules nm CharLtOp = mkRelOpRule nm (<) [ boundsCmp Lt ]
primOpRules nm FloatGtOp = mkFloatingRelOpRule nm (>)
primOpRules nm FloatGeOp = mkFloatingRelOpRule nm (>=)
primOpRules nm FloatLeOp = mkFloatingRelOpRule nm (<=)
primOpRules nm FloatLtOp = mkFloatingRelOpRule nm (<)
primOpRules nm FloatEqOp = mkFloatingRelOpRule nm (==)
primOpRules nm FloatNeOp = mkFloatingRelOpRule nm (/=)
primOpRules nm DoubleGtOp = mkFloatingRelOpRule nm (>)
primOpRules nm DoubleGeOp = mkFloatingRelOpRule nm (>=)
primOpRules nm DoubleLeOp = mkFloatingRelOpRule nm (<=)
primOpRules nm DoubleLtOp = mkFloatingRelOpRule nm (<)
primOpRules nm DoubleEqOp = mkFloatingRelOpRule nm (==)
primOpRules nm DoubleNeOp = mkFloatingRelOpRule nm (/=)
primOpRules nm WordGtOp = mkRelOpRule nm (>) [ boundsCmp Gt ]
primOpRules nm WordGeOp = mkRelOpRule nm (>=) [ boundsCmp Ge ]
primOpRules nm WordLeOp = mkRelOpRule nm (<=) [ boundsCmp Le ]
primOpRules nm WordLtOp = mkRelOpRule nm (<) [ boundsCmp Lt ]
primOpRules nm WordEqOp = mkRelOpRule nm (==) [ litEq True ]
primOpRules nm WordNeOp = mkRelOpRule nm (/=) [ litEq False ]
primOpRules nm AddrAddOp = mkPrimOpRule nm 2 [ rightIdentityDynFlags zeroi ]
primOpRules nm SeqOp = mkPrimOpRule nm 4 [ seqRule ]
primOpRules nm SparkOp = mkPrimOpRule nm 4 [ sparkRule ]
primOpRules _ _ = Nothing
mkPrimOpRule :: Name -> Int -> [RuleM CoreExpr] -> Maybe CoreRule
mkPrimOpRule nm arity rules = Just $ mkBasicRule nm arity (msum rules)
mkRelOpRule :: Name -> (forall a . Ord a => a -> a -> Bool)
-> [RuleM CoreExpr] -> Maybe CoreRule
mkRelOpRule nm cmp extra
= mkPrimOpRule nm 2 $
binaryCmpLit cmp : equal_rule : extra
where
equal_rule = do { equalArgs
; dflags <- getDynFlags
; return (if cmp True True
then trueValInt dflags
else falseValInt dflags) }
mkFloatingRelOpRule :: Name -> (forall a . Ord a => a -> a -> Bool)
-> Maybe CoreRule
mkFloatingRelOpRule nm cmp
= mkPrimOpRule nm 2 [binaryCmpLit cmp]
zeroi, onei, zerow, onew :: DynFlags -> Literal
zeroi dflags = mkMachInt dflags 0
onei dflags = mkMachInt dflags 1
zerow dflags = mkMachWord dflags 0
onew dflags = mkMachWord dflags 1
zerof, onef, twof, zerod, oned, twod :: Literal
zerof = mkMachFloat 0.0
onef = mkMachFloat 1.0
twof = mkMachFloat 2.0
zerod = mkMachDouble 0.0
oned = mkMachDouble 1.0
twod = mkMachDouble 2.0
cmpOp :: DynFlags -> (forall a . Ord a => a -> a -> Bool)
-> Literal -> Literal -> Maybe CoreExpr
cmpOp dflags cmp = go
where
done True = Just $ trueValInt dflags
done False = Just $ falseValInt dflags
go (MachChar i1) (MachChar i2) = done (i1 `cmp` i2)
go (MachInt i1) (MachInt i2) = done (i1 `cmp` i2)
go (MachInt64 i1) (MachInt64 i2) = done (i1 `cmp` i2)
go (MachWord i1) (MachWord i2) = done (i1 `cmp` i2)
go (MachWord64 i1) (MachWord64 i2) = done (i1 `cmp` i2)
go (MachFloat i1) (MachFloat i2) = done (i1 `cmp` i2)
go (MachDouble i1) (MachDouble i2) = done (i1 `cmp` i2)
go _ _ = Nothing
negOp :: DynFlags -> Literal -> Maybe CoreExpr
negOp _ (MachFloat 0.0) = Nothing
negOp dflags (MachFloat f) = Just (mkFloatVal dflags (-f))
negOp _ (MachDouble 0.0) = Nothing
negOp dflags (MachDouble d) = Just (mkDoubleVal dflags (-d))
negOp dflags (MachInt i) = intResult dflags (-i)
negOp _ _ = Nothing
complementOp :: DynFlags -> Literal -> Maybe CoreExpr
complementOp dflags (MachWord i) = wordResult dflags (complement i)
complementOp dflags (MachInt i) = intResult dflags (complement i)
complementOp _ _ = Nothing
intOp2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> DynFlags -> Literal -> Literal -> Maybe CoreExpr
intOp2 = intOp2' . const
intOp2' :: (Integral a, Integral b)
=> (DynFlags -> a -> b -> Integer)
-> DynFlags -> Literal -> Literal -> Maybe CoreExpr
intOp2' op dflags (MachInt i1) (MachInt i2) =
let o = op dflags
in intResult dflags (fromInteger i1 `o` fromInteger i2)
intOp2' _ _ _ _ = Nothing
shiftRightLogical :: DynFlags -> Integer -> Int -> Integer
shiftRightLogical dflags x n
| wordSizeInBits dflags == 32 = fromIntegral (fromInteger x `shiftR` n :: Word32)
| wordSizeInBits dflags == 64 = fromIntegral (fromInteger x `shiftR` n :: Word64)
| otherwise = panic "shiftRightLogical: unsupported word size"
retLit :: (DynFlags -> Literal) -> RuleM CoreExpr
retLit l = do dflags <- getDynFlags
return $ Lit $ l dflags
wordOp2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> DynFlags -> Literal -> Literal -> Maybe CoreExpr
wordOp2 op dflags (MachWord w1) (MachWord w2)
= wordResult dflags (fromInteger w1 `op` fromInteger w2)
wordOp2 _ _ _ _ = Nothing
wordShiftRule :: (DynFlags -> Integer -> Int -> Integer) -> RuleM CoreExpr
wordShiftRule shift_op
= do { dflags <- getDynFlags
; [e1, Lit (MachInt shift_len)] <- getArgs
; case e1 of
_ | shift_len == 0
-> return e1
| shift_len < 0 || wordSizeInBits dflags < shift_len
-> return (mkRuntimeErrorApp rUNTIME_ERROR_ID wordPrimTy
("Bad shift length" ++ show shift_len))
Lit (MachWord x)
-> let op = shift_op dflags
in liftMaybe $ wordResult dflags (x `op` fromInteger shift_len)
_ -> mzero }
wordSizeInBits :: DynFlags -> Integer
wordSizeInBits dflags = toInteger (platformWordSize (targetPlatform dflags) `shiftL` 3)
floatOp2 :: (Rational -> Rational -> Rational)
-> DynFlags -> Literal -> Literal
-> Maybe (Expr CoreBndr)
floatOp2 op dflags (MachFloat f1) (MachFloat f2)
= Just (mkFloatVal dflags (f1 `op` f2))
floatOp2 _ _ _ _ = Nothing
doubleOp2 :: (Rational -> Rational -> Rational)
-> DynFlags -> Literal -> Literal
-> Maybe (Expr CoreBndr)
doubleOp2 op dflags (MachDouble f1) (MachDouble f2)
= Just (mkDoubleVal dflags (f1 `op` f2))
doubleOp2 _ _ _ _ = Nothing
litEq :: Bool
-> RuleM CoreExpr
litEq is_eq = msum
[ do [Lit lit, expr] <- getArgs
dflags <- getDynFlags
do_lit_eq dflags lit expr
, do [expr, Lit lit] <- getArgs
dflags <- getDynFlags
do_lit_eq dflags lit expr ]
where
do_lit_eq dflags lit expr = do
guard (not (litIsLifted lit))
return (mkWildCase expr (literalType lit) intPrimTy
[(DEFAULT, [], val_if_neq),
(LitAlt lit, [], val_if_eq)])
where
val_if_eq | is_eq = trueValInt dflags
| otherwise = falseValInt dflags
val_if_neq | is_eq = falseValInt dflags
| otherwise = trueValInt dflags
boundsCmp :: Comparison -> RuleM CoreExpr
boundsCmp op = do
dflags <- getDynFlags
[a, b] <- getArgs
liftMaybe $ mkRuleFn dflags op a b
data Comparison = Gt | Ge | Lt | Le
mkRuleFn :: DynFlags -> Comparison -> CoreExpr -> CoreExpr -> Maybe CoreExpr
mkRuleFn dflags Gt (Lit lit) _ | isMinBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Le (Lit lit) _ | isMinBound dflags lit = Just $ trueValInt dflags
mkRuleFn dflags Ge _ (Lit lit) | isMinBound dflags lit = Just $ trueValInt dflags
mkRuleFn dflags Lt _ (Lit lit) | isMinBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Ge (Lit lit) _ | isMaxBound dflags lit = Just $ trueValInt dflags
mkRuleFn dflags Lt (Lit lit) _ | isMaxBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Gt _ (Lit lit) | isMaxBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Le _ (Lit lit) | isMaxBound dflags lit = Just $ trueValInt dflags
mkRuleFn _ _ _ _ = Nothing
isMinBound :: DynFlags -> Literal -> Bool
isMinBound _ (MachChar c) = c == minBound
isMinBound dflags (MachInt i) = i == tARGET_MIN_INT dflags
isMinBound _ (MachInt64 i) = i == toInteger (minBound :: Int64)
isMinBound _ (MachWord i) = i == 0
isMinBound _ (MachWord64 i) = i == 0
isMinBound _ _ = False
isMaxBound :: DynFlags -> Literal -> Bool
isMaxBound _ (MachChar c) = c == maxBound
isMaxBound dflags (MachInt i) = i == tARGET_MAX_INT dflags
isMaxBound _ (MachInt64 i) = i == toInteger (maxBound :: Int64)
isMaxBound dflags (MachWord i) = i == tARGET_MAX_WORD dflags
isMaxBound _ (MachWord64 i) = i == toInteger (maxBound :: Word64)
isMaxBound _ _ = False
intResult' :: DynFlags -> Integer -> Integer
intResult' dflags result = case platformWordSize (targetPlatform dflags) of
4 -> toInteger (fromInteger result :: Int32)
8 -> toInteger (fromInteger result :: Int64)
w -> panic ("intResult: Unknown platformWordSize: " ++ show w)
wordResult' :: DynFlags -> Integer -> Integer
wordResult' dflags result = case platformWordSize (targetPlatform dflags) of
4 -> toInteger (fromInteger result :: Word32)
8 -> toInteger (fromInteger result :: Word64)
w -> panic ("wordResult: Unknown platformWordSize: " ++ show w)
intResult :: DynFlags -> Integer -> Maybe CoreExpr
intResult dflags result = Just (mkIntVal dflags (intResult' dflags result))
wordResult :: DynFlags -> Integer -> Maybe CoreExpr
wordResult dflags result = Just (mkWordVal dflags (wordResult' dflags result))
inversePrimOp :: PrimOp -> RuleM CoreExpr
inversePrimOp primop = do
[Var primop_id `App` e] <- getArgs
matchPrimOpId primop primop_id
return e
subsumesPrimOp :: PrimOp -> PrimOp -> RuleM CoreExpr
this `subsumesPrimOp` that = do
[Var primop_id `App` e] <- getArgs
matchPrimOpId that primop_id
return (Var (mkPrimOpId this) `App` e)
subsumedByPrimOp :: PrimOp -> RuleM CoreExpr
subsumedByPrimOp primop = do
[e@(Var primop_id `App` _)] <- getArgs
matchPrimOpId primop primop_id
return e
idempotent :: RuleM CoreExpr
idempotent = do [e1, e2] <- getArgs
guard $ cheapEqExpr e1 e2
return e1
mkBasicRule :: Name -> Int -> RuleM CoreExpr -> CoreRule
mkBasicRule op_name n_args rm
= BuiltinRule { ru_name = occNameFS (nameOccName op_name),
ru_fn = op_name,
ru_nargs = n_args,
ru_try = \ dflags in_scope _ -> runRuleM rm dflags in_scope }
newtype RuleM r = RuleM
{ runRuleM :: DynFlags -> InScopeEnv -> [CoreExpr] -> Maybe r }
instance Functor RuleM where
fmap = liftM
instance Applicative RuleM where
pure x = RuleM $ \_ _ _ -> Just x
(<*>) = ap
instance Monad RuleM where
RuleM f >>= g = RuleM $ \dflags iu e -> case f dflags iu e of
Nothing -> Nothing
Just r -> runRuleM (g r) dflags iu e
fail _ = mzero
#if __GLASGOW_HASKELL__ > 710
instance MonadFail.MonadFail RuleM where
fail _ = mzero
#endif
instance Alternative RuleM where
empty = RuleM $ \_ _ _ -> Nothing
RuleM f1 <|> RuleM f2 = RuleM $ \dflags iu args ->
f1 dflags iu args <|> f2 dflags iu args
instance MonadPlus RuleM
instance HasDynFlags RuleM where
getDynFlags = RuleM $ \dflags _ _ -> Just dflags
liftMaybe :: Maybe a -> RuleM a
liftMaybe Nothing = mzero
liftMaybe (Just x) = return x
liftLit :: (Literal -> Literal) -> RuleM CoreExpr
liftLit f = liftLitDynFlags (const f)
liftLitDynFlags :: (DynFlags -> Literal -> Literal) -> RuleM CoreExpr
liftLitDynFlags f = do
dflags <- getDynFlags
[Lit lit] <- getArgs
return $ Lit (f dflags lit)
removeOp32 :: RuleM CoreExpr
removeOp32 = do
dflags <- getDynFlags
if wordSizeInBits dflags == 32
then do
[e] <- getArgs
return e
else mzero
getArgs :: RuleM [CoreExpr]
getArgs = RuleM $ \_ _ args -> Just args
getInScopeEnv :: RuleM InScopeEnv
getInScopeEnv = RuleM $ \_ iu _ -> Just iu
getLiteral :: Int -> RuleM Literal
getLiteral n = RuleM $ \_ _ exprs -> case drop n exprs of
(Lit l:_) -> Just l
_ -> Nothing
unaryLit :: (DynFlags -> Literal -> Maybe CoreExpr) -> RuleM CoreExpr
unaryLit op = do
dflags <- getDynFlags
[Lit l] <- getArgs
liftMaybe $ op dflags (convFloating dflags l)
binaryLit :: (DynFlags -> Literal -> Literal -> Maybe CoreExpr) -> RuleM CoreExpr
binaryLit op = do
dflags <- getDynFlags
[Lit l1, Lit l2] <- getArgs
liftMaybe $ op dflags (convFloating dflags l1) (convFloating dflags l2)
binaryCmpLit :: (forall a . Ord a => a -> a -> Bool) -> RuleM CoreExpr
binaryCmpLit op = do
dflags <- getDynFlags
binaryLit (\_ -> cmpOp dflags op)
leftIdentity :: Literal -> RuleM CoreExpr
leftIdentity id_lit = leftIdentityDynFlags (const id_lit)
rightIdentity :: Literal -> RuleM CoreExpr
rightIdentity id_lit = rightIdentityDynFlags (const id_lit)
identity :: Literal -> RuleM CoreExpr
identity lit = leftIdentity lit `mplus` rightIdentity lit
leftIdentityDynFlags :: (DynFlags -> Literal) -> RuleM CoreExpr
leftIdentityDynFlags id_lit = do
dflags <- getDynFlags
[Lit l1, e2] <- getArgs
guard $ l1 == id_lit dflags
return e2
rightIdentityDynFlags :: (DynFlags -> Literal) -> RuleM CoreExpr
rightIdentityDynFlags id_lit = do
dflags <- getDynFlags
[e1, Lit l2] <- getArgs
guard $ l2 == id_lit dflags
return e1
identityDynFlags :: (DynFlags -> Literal) -> RuleM CoreExpr
identityDynFlags lit = leftIdentityDynFlags lit `mplus` rightIdentityDynFlags lit
leftZero :: (DynFlags -> Literal) -> RuleM CoreExpr
leftZero zero = do
dflags <- getDynFlags
[Lit l1, _] <- getArgs
guard $ l1 == zero dflags
return $ Lit l1
rightZero :: (DynFlags -> Literal) -> RuleM CoreExpr
rightZero zero = do
dflags <- getDynFlags
[_, Lit l2] <- getArgs
guard $ l2 == zero dflags
return $ Lit l2
zeroElem :: (DynFlags -> Literal) -> RuleM CoreExpr
zeroElem lit = leftZero lit `mplus` rightZero lit
equalArgs :: RuleM ()
equalArgs = do
[e1, e2] <- getArgs
guard $ e1 `cheapEqExpr` e2
nonZeroLit :: Int -> RuleM ()
nonZeroLit n = getLiteral n >>= guard . not . isZeroLit
convFloating :: DynFlags -> Literal -> Literal
convFloating dflags (MachFloat f) | not (gopt Opt_ExcessPrecision dflags) =
MachFloat (toRational (fromRational f :: Float ))
convFloating dflags (MachDouble d) | not (gopt Opt_ExcessPrecision dflags) =
MachDouble (toRational (fromRational d :: Double))
convFloating _ l = l
guardFloatDiv :: RuleM ()
guardFloatDiv = do
[Lit (MachFloat f1), Lit (MachFloat f2)] <- getArgs
guard $ (f1 /=0 || f2 > 0)
&& f2 /= 0
guardDoubleDiv :: RuleM ()
guardDoubleDiv = do
[Lit (MachDouble d1), Lit (MachDouble d2)] <- getArgs
guard $ (d1 /=0 || d2 > 0)
&& d2 /= 0
strengthReduction :: Literal -> PrimOp -> RuleM CoreExpr
strengthReduction two_lit add_op = do
arg <- msum [ do [arg, Lit mult_lit] <- getArgs
guard (mult_lit == two_lit)
return arg
, do [Lit mult_lit, arg] <- getArgs
guard (mult_lit == two_lit)
return arg ]
return $ Var (mkPrimOpId add_op) `App` arg `App` arg
trueValInt, falseValInt :: DynFlags -> Expr CoreBndr
trueValInt dflags = Lit $ onei dflags
falseValInt dflags = Lit $ zeroi dflags
trueValBool, falseValBool :: Expr CoreBndr
trueValBool = Var trueDataConId
falseValBool = Var falseDataConId
ltVal, eqVal, gtVal :: Expr CoreBndr
ltVal = Var ltDataConId
eqVal = Var eqDataConId
gtVal = Var gtDataConId
mkIntVal :: DynFlags -> Integer -> Expr CoreBndr
mkIntVal dflags i = Lit (mkMachInt dflags i)
mkWordVal :: DynFlags -> Integer -> Expr CoreBndr
mkWordVal dflags w = Lit (mkMachWord dflags w)
mkFloatVal :: DynFlags -> Rational -> Expr CoreBndr
mkFloatVal dflags f = Lit (convFloating dflags (MachFloat f))
mkDoubleVal :: DynFlags -> Rational -> Expr CoreBndr
mkDoubleVal dflags d = Lit (convFloating dflags (MachDouble d))
matchPrimOpId :: PrimOp -> Id -> RuleM ()
matchPrimOpId op id = do
op' <- liftMaybe $ isPrimOpId_maybe id
guard $ op == op'
tagToEnumRule :: RuleM CoreExpr
tagToEnumRule = do
[Type ty, Lit (MachInt i)] <- getArgs
case splitTyConApp_maybe ty of
Just (tycon, tc_args) | isEnumerationTyCon tycon -> do
let tag = fromInteger i
correct_tag dc = (dataConTag dc - fIRST_TAG) == tag
(dc:rest) <- return $ filter correct_tag (tyConDataCons_maybe tycon `orElse` [])
ASSERT(null rest) return ()
return $ mkTyApps (Var (dataConWorkId dc)) tc_args
_ -> WARN( True, text "tagToEnum# on non-enumeration type" <+> ppr ty )
return $ mkRuntimeErrorApp rUNTIME_ERROR_ID ty "tagToEnum# on non-enumeration type"
dataToTagRule :: RuleM CoreExpr
dataToTagRule = a `mplus` b
where
a = do
[Type ty1, Var tag_to_enum `App` Type ty2 `App` tag] <- getArgs
guard $ tag_to_enum `hasKey` tagToEnumKey
guard $ ty1 `eqType` ty2
return tag
b = do
dflags <- getDynFlags
[_, val_arg] <- getArgs
in_scope <- getInScopeEnv
(dc,_,_) <- liftMaybe $ exprIsConApp_maybe in_scope val_arg
ASSERT( not (isNewTyCon (dataConTyCon dc)) ) return ()
return $ mkIntVal dflags (toInteger (dataConTag dc - fIRST_TAG))
seqRule :: RuleM CoreExpr
seqRule = do
[Type ty_a, Type ty_s, a, s] <- getArgs
guard $ exprIsHNF a
return $ mkCoreUbxTup [mkStatePrimTy ty_s, ty_a] [s, a]
sparkRule :: RuleM CoreExpr
sparkRule = seqRule
builtinRules :: [CoreRule]
builtinRules
= [BuiltinRule { ru_name = fsLit "AppendLitString",
ru_fn = unpackCStringFoldrName,
ru_nargs = 4, ru_try = match_append_lit },
BuiltinRule { ru_name = fsLit "EqString", ru_fn = eqStringName,
ru_nargs = 2, ru_try = match_eq_string },
BuiltinRule { ru_name = fsLit "Inline", ru_fn = inlineIdName,
ru_nargs = 2, ru_try = \_ _ _ -> match_inline },
BuiltinRule { ru_name = fsLit "MagicDict", ru_fn = idName magicDictId,
ru_nargs = 4, ru_try = \_ _ _ -> match_magicDict },
mkBasicRule divIntName 2 $ msum
[ nonZeroLit 1 >> binaryLit (intOp2 div)
, leftZero zeroi
, do
[arg, Lit (MachInt d)] <- getArgs
Just n <- return $ exactLog2 d
dflags <- getDynFlags
return $ Var (mkPrimOpId ISraOp) `App` arg `App` mkIntVal dflags n
],
mkBasicRule modIntName 2 $ msum
[ nonZeroLit 1 >> binaryLit (intOp2 mod)
, leftZero zeroi
, do
[arg, Lit (MachInt d)] <- getArgs
Just _ <- return $ exactLog2 d
dflags <- getDynFlags
return $ Var (mkPrimOpId AndIOp)
`App` arg `App` mkIntVal dflags (d - 1)
]
]
++ builtinIntegerRules
builtinIntegerRules :: [CoreRule]
builtinIntegerRules =
[rule_IntToInteger "smallInteger" smallIntegerName,
rule_WordToInteger "wordToInteger" wordToIntegerName,
rule_Int64ToInteger "int64ToInteger" int64ToIntegerName,
rule_Word64ToInteger "word64ToInteger" word64ToIntegerName,
rule_convert "integerToWord" integerToWordName mkWordLitWord,
rule_convert "integerToInt" integerToIntName mkIntLitInt,
rule_convert "integerToWord64" integerToWord64Name (\_ -> mkWord64LitWord64),
rule_convert "integerToInt64" integerToInt64Name (\_ -> mkInt64LitInt64),
rule_binop "plusInteger" plusIntegerName (+),
rule_binop "minusInteger" minusIntegerName (-),
rule_binop "timesInteger" timesIntegerName (*),
rule_unop "negateInteger" negateIntegerName negate,
rule_binop_Prim "eqInteger#" eqIntegerPrimName (==),
rule_binop_Prim "neqInteger#" neqIntegerPrimName (/=),
rule_unop "absInteger" absIntegerName abs,
rule_unop "signumInteger" signumIntegerName signum,
rule_binop_Prim "leInteger#" leIntegerPrimName (<=),
rule_binop_Prim "gtInteger#" gtIntegerPrimName (>),
rule_binop_Prim "ltInteger#" ltIntegerPrimName (<),
rule_binop_Prim "geInteger#" geIntegerPrimName (>=),
rule_binop_Ordering "compareInteger" compareIntegerName compare,
rule_encodeFloat "encodeFloatInteger" encodeFloatIntegerName mkFloatLitFloat,
rule_convert "floatFromInteger" floatFromIntegerName (\_ -> mkFloatLitFloat),
rule_encodeFloat "encodeDoubleInteger" encodeDoubleIntegerName mkDoubleLitDouble,
rule_decodeDouble "decodeDoubleInteger" decodeDoubleIntegerName,
rule_convert "doubleFromInteger" doubleFromIntegerName (\_ -> mkDoubleLitDouble),
rule_rationalTo "rationalToFloat" rationalToFloatName mkFloatExpr,
rule_rationalTo "rationalToDouble" rationalToDoubleName mkDoubleExpr,
rule_binop "gcdInteger" gcdIntegerName gcd,
rule_binop "lcmInteger" lcmIntegerName lcm,
rule_binop "andInteger" andIntegerName (.&.),
rule_binop "orInteger" orIntegerName (.|.),
rule_binop "xorInteger" xorIntegerName xor,
rule_unop "complementInteger" complementIntegerName complement,
rule_Int_binop "shiftLInteger" shiftLIntegerName shiftL,
rule_Int_binop "shiftRInteger" shiftRIntegerName shiftR,
rule_bitInteger "bitInteger" bitIntegerName,
rule_divop_one "quotInteger" quotIntegerName quot,
rule_divop_one "remInteger" remIntegerName rem,
rule_divop_one "divInteger" divIntegerName div,
rule_divop_one "modInteger" modIntegerName mod,
rule_divop_both "divModInteger" divModIntegerName divMod,
rule_divop_both "quotRemInteger" quotRemIntegerName quotRem,
rule_XToIntegerToX "smallIntegerToInt" integerToIntName smallIntegerName,
rule_XToIntegerToX "wordToIntegerToWord" integerToWordName wordToIntegerName,
rule_XToIntegerToX "int64ToIntegerToInt64" integerToInt64Name int64ToIntegerName,
rule_XToIntegerToX "word64ToIntegerToWord64" integerToWord64Name word64ToIntegerName,
rule_smallIntegerTo "smallIntegerToWord" integerToWordName Int2WordOp,
rule_smallIntegerTo "smallIntegerToFloat" floatFromIntegerName Int2FloatOp,
rule_smallIntegerTo "smallIntegerToDouble" doubleFromIntegerName Int2DoubleOp
]
where rule_convert str name convert
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Integer_convert convert }
rule_IntToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_IntToInteger }
rule_WordToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_WordToInteger }
rule_Int64ToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Int64ToInteger }
rule_Word64ToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Word64ToInteger }
rule_unop str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Integer_unop op }
rule_bitInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_IntToInteger_unop (bit . fromIntegral) }
rule_binop str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_binop op }
rule_divop_both str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_divop_both op }
rule_divop_one str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_divop_one op }
rule_Int_binop str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_Int_binop op }
rule_binop_Prim str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_binop_Prim op }
rule_binop_Ordering str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_binop_Ordering op }
rule_encodeFloat str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_Int_encodeFloat op }
rule_decodeDouble str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_decodeDouble }
rule_XToIntegerToX str name toIntegerName
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_XToIntegerToX toIntegerName }
rule_smallIntegerTo str name primOp
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_smallIntegerTo primOp }
rule_rationalTo str name mkLit
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_rationalTo mkLit }
match_append_lit :: RuleFun
match_append_lit _ id_unf _
[ Type ty1
, lit1
, c1
, Var unpk `App` Type ty2
`App` lit2
`App` c2
`App` n
]
| unpk `hasKey` unpackCStringFoldrIdKey &&
c1 `cheapEqExpr` c2
, Just (MachStr s1) <- exprIsLiteral_maybe id_unf lit1
, Just (MachStr s2) <- exprIsLiteral_maybe id_unf lit2
= ASSERT( ty1 `eqType` ty2 )
Just (Var unpk `App` Type ty1
`App` Lit (MachStr (s1 `BS.append` s2))
`App` c1
`App` n)
match_append_lit _ _ _ _ = Nothing
match_eq_string :: RuleFun
match_eq_string _ id_unf _
[Var unpk1 `App` lit1, Var unpk2 `App` lit2]
| unpk1 `hasKey` unpackCStringIdKey
, unpk2 `hasKey` unpackCStringIdKey
, Just (MachStr s1) <- exprIsLiteral_maybe id_unf lit1
, Just (MachStr s2) <- exprIsLiteral_maybe id_unf lit2
= Just (if s1 == s2 then trueValBool else falseValBool)
match_eq_string _ _ _ _ = Nothing
match_inline :: [Expr CoreBndr] -> Maybe (Expr CoreBndr)
match_inline (Type _ : e : _)
| (Var f, args1) <- collectArgs e,
Just unf <- maybeUnfoldingTemplate (realIdUnfolding f)
= Just (mkApps unf args1)
match_inline _ = Nothing
match_magicDict :: [Expr CoreBndr] -> Maybe (Expr CoreBndr)
match_magicDict [Type _, Var wrap `App` Type a `App` Type _ `App` f, x, y ]
| Just (fieldTy, _) <- splitFunTy_maybe $ dropForAlls $ idType wrap
, Just (dictTy, _) <- splitFunTy_maybe fieldTy
, Just dictTc <- tyConAppTyCon_maybe dictTy
, Just (_,_,co) <- unwrapNewTyCon_maybe dictTc
= Just
$ f `App` Cast x (mkSymCo (mkUnbranchedAxInstCo Representational co [a] []))
`App` y
match_magicDict _ = Nothing
match_IntToInteger :: RuleFun
match_IntToInteger = match_IntToInteger_unop id
match_WordToInteger :: RuleFun
match_WordToInteger _ id_unf id [xl]
| Just (MachWord x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType id) of
Just (_, integerTy) ->
Just (Lit (LitInteger x integerTy))
_ ->
panic "match_WordToInteger: Id has the wrong type"
match_WordToInteger _ _ _ _ = Nothing
match_Int64ToInteger :: RuleFun
match_Int64ToInteger _ id_unf id [xl]
| Just (MachInt64 x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType id) of
Just (_, integerTy) ->
Just (Lit (LitInteger x integerTy))
_ ->
panic "match_Int64ToInteger: Id has the wrong type"
match_Int64ToInteger _ _ _ _ = Nothing
match_Word64ToInteger :: RuleFun
match_Word64ToInteger _ id_unf id [xl]
| Just (MachWord64 x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType id) of
Just (_, integerTy) ->
Just (Lit (LitInteger x integerTy))
_ ->
panic "match_Word64ToInteger: Id has the wrong type"
match_Word64ToInteger _ _ _ _ = Nothing
match_Integer_convert :: Num a
=> (DynFlags -> a -> Expr CoreBndr)
-> RuleFun
match_Integer_convert convert dflags id_unf _ [xl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
= Just (convert dflags (fromInteger x))
match_Integer_convert _ _ _ _ _ = Nothing
match_Integer_unop :: (Integer -> Integer) -> RuleFun
match_Integer_unop unop _ id_unf _ [xl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
= Just (Lit (LitInteger (unop x) i))
match_Integer_unop _ _ _ _ _ = Nothing
match_IntToInteger_unop :: (Integer -> Integer) -> RuleFun
match_IntToInteger_unop unop _ id_unf fn [xl]
| Just (MachInt x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType fn) of
Just (_, integerTy) ->
Just (Lit (LitInteger (unop x) integerTy))
_ ->
panic "match_IntToInteger_unop: Id has the wrong type"
match_IntToInteger_unop _ _ _ _ _ = Nothing
match_Integer_binop :: (Integer -> Integer -> Integer) -> RuleFun
match_Integer_binop binop _ id_unf _ [xl,yl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
= Just (Lit (LitInteger (x `binop` y) i))
match_Integer_binop _ _ _ _ _ = Nothing
match_Integer_divop_both
:: (Integer -> Integer -> (Integer, Integer)) -> RuleFun
match_Integer_divop_both divop _ id_unf _ [xl,yl]
| Just (LitInteger x t) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
, y /= 0
, (r,s) <- x `divop` y
= Just $ mkCoreUbxTup [t,t] [Lit (LitInteger r t), Lit (LitInteger s t)]
match_Integer_divop_both _ _ _ _ _ = Nothing
match_Integer_divop_one :: (Integer -> Integer -> Integer) -> RuleFun
match_Integer_divop_one divop _ id_unf _ [xl,yl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
, y /= 0
= Just (Lit (LitInteger (x `divop` y) i))
match_Integer_divop_one _ _ _ _ _ = Nothing
match_Integer_Int_binop :: (Integer -> Int -> Integer) -> RuleFun
match_Integer_Int_binop binop _ id_unf _ [xl,yl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
, Just (MachInt y) <- exprIsLiteral_maybe id_unf yl
= Just (Lit (LitInteger (x `binop` fromIntegral y) i))
match_Integer_Int_binop _ _ _ _ _ = Nothing
match_Integer_binop_Prim :: (Integer -> Integer -> Bool) -> RuleFun
match_Integer_binop_Prim binop dflags id_unf _ [xl, yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
= Just (if x `binop` y then trueValInt dflags else falseValInt dflags)
match_Integer_binop_Prim _ _ _ _ _ = Nothing
match_Integer_binop_Ordering :: (Integer -> Integer -> Ordering) -> RuleFun
match_Integer_binop_Ordering binop _ id_unf _ [xl, yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
= Just $ case x `binop` y of
LT -> ltVal
EQ -> eqVal
GT -> gtVal
match_Integer_binop_Ordering _ _ _ _ _ = Nothing
match_Integer_Int_encodeFloat :: RealFloat a
=> (a -> Expr CoreBndr)
-> RuleFun
match_Integer_Int_encodeFloat mkLit _ id_unf _ [xl,yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (MachInt y) <- exprIsLiteral_maybe id_unf yl
= Just (mkLit $ encodeFloat x (fromInteger y))
match_Integer_Int_encodeFloat _ _ _ _ _ = Nothing
match_rationalTo :: RealFloat a
=> (a -> Expr CoreBndr)
-> RuleFun
match_rationalTo mkLit _ id_unf _ [xl, yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
, y /= 0
= Just (mkLit (fromRational (x % y)))
match_rationalTo _ _ _ _ _ = Nothing
match_decodeDouble :: RuleFun
match_decodeDouble _ id_unf fn [xl]
| Just (MachDouble x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType fn) of
Just (_, res)
| Just [_lev1, _lev2, integerTy, intHashTy] <- tyConAppArgs_maybe res
-> case decodeFloat (fromRational x :: Double) of
(y, z) ->
Just $ mkCoreUbxTup [integerTy, intHashTy]
[Lit (LitInteger y integerTy),
Lit (MachInt (toInteger z))]
_ ->
pprPanic "match_decodeDouble: Id has the wrong type"
(ppr fn <+> dcolon <+> ppr (idType fn))
match_decodeDouble _ _ _ _ = Nothing
match_XToIntegerToX :: Name -> RuleFun
match_XToIntegerToX n _ _ _ [App (Var x) y]
| idName x == n
= Just y
match_XToIntegerToX _ _ _ _ _ = Nothing
match_smallIntegerTo :: PrimOp -> RuleFun
match_smallIntegerTo primOp _ _ _ [App (Var x) y]
| idName x == smallIntegerName
= Just $ App (Var (mkPrimOpId primOp)) y
match_smallIntegerTo _ _ _ _ _ = Nothing
caseRules :: DynFlags -> CoreExpr -> Maybe (CoreExpr, Integer -> Integer)
caseRules dflags scrut = case scrut of
App (App (Var f) v) (Lit l)
| Just op <- isPrimOpId_maybe f
, Just x <- isLitValue_maybe l ->
case op of
WordAddOp -> Just (v, \y -> wordResult' dflags $ y-x )
IntAddOp -> Just (v, \y -> intResult' dflags $ y-x )
WordSubOp -> Just (v, \y -> wordResult' dflags $ y+x )
IntSubOp -> Just (v, \y -> intResult' dflags $ y+x )
XorOp -> Just (v, \y -> wordResult' dflags $ y `xor` x)
XorIOp -> Just (v, \y -> intResult' dflags $ y `xor` x)
_ -> Nothing
App (App (Var f) (Lit l)) v
| Just op <- isPrimOpId_maybe f
, Just x <- isLitValue_maybe l ->
case op of
WordAddOp -> Just (v, \y -> wordResult' dflags $ y-x )
IntAddOp -> Just (v, \y -> intResult' dflags $ y-x )
WordSubOp -> Just (v, \y -> wordResult' dflags $ x-y )
IntSubOp -> Just (v, \y -> intResult' dflags $ x-y )
XorOp -> Just (v, \y -> wordResult' dflags $ y `xor` x)
XorIOp -> Just (v, \y -> intResult' dflags $ y `xor` x)
_ -> Nothing
App (Var f) v
| Just op <- isPrimOpId_maybe f ->
case op of
NotOp -> Just (v, \y -> wordResult' dflags $ complement y)
NotIOp -> Just (v, \y -> intResult' dflags $ complement y)
IntNegOp -> Just (v, \y -> intResult' dflags $ negate y )
_ -> Nothing
_ -> Nothing