ghc-lib-parser-0.20220103: compiler/GHC/Core/Opt/ConstantFold.hs
{-
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
Conceptually, constant folding should be parameterized with the kind
of target machine to get identical behaviour during compilation time
and runtime. We cheat a little bit here...
ToDo:
check boundaries before folding, e.g. we can fold the Float addition
(i1 + i2) only if it results in a valid Float.
-}
{-# LANGUAGE AllowAmbiguousTypes #-}
{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE LambdaCase #-}
{-# LANGUAGE MultiWayIf #-}
{-# LANGUAGE PatternSynonyms #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeApplications #-}
{-# LANGUAGE ViewPatterns #-}
{-# OPTIONS_GHC -optc-DNON_POSIX_SOURCE -Wno-incomplete-uni-patterns #-}
-- | Constant Folder
module GHC.Core.Opt.ConstantFold
( primOpRules
, builtinRules
, caseRules
)
where
import GHC.Prelude
import GHC.Platform
import {-# SOURCE #-} GHC.Types.Id.Make ( mkPrimOpId, voidPrimId )
import GHC.Types.Id
import GHC.Types.Literal
import GHC.Types.Name.Occurrence ( occNameFS )
import GHC.Types.Tickish
import GHC.Types.Name ( Name, nameOccName )
import GHC.Types.Basic
import GHC.Core
import GHC.Core.Make
import GHC.Core.SimpleOpt ( exprIsConApp_maybe, exprIsLiteral_maybe )
import GHC.Core.DataCon ( DataCon,dataConTagZ, dataConTyCon, dataConWrapId, dataConWorkId )
import GHC.Core.Utils ( cheapEqExpr, exprIsHNF, exprType
, stripTicksTop, stripTicksTopT, mkTicks )
import GHC.Core.Multiplicity
import GHC.Core.Type
import GHC.Core.TyCon
( tyConDataCons_maybe, isAlgTyCon, isEnumerationTyCon
, isNewTyCon, tyConDataCons
, tyConFamilySize )
import GHC.Core.Map.Expr ( eqCoreExpr )
import GHC.Builtin.PrimOps ( PrimOp(..), tagToEnumKey )
import GHC.Builtin.Types
import GHC.Builtin.Types.Prim
import GHC.Builtin.Names
import GHC.Data.FastString
import GHC.Data.Maybe ( orElse )
import GHC.Utils.Outputable
import GHC.Utils.Misc
import GHC.Utils.Panic
import GHC.Utils.Panic.Plain
import GHC.Utils.Trace
import Control.Applicative ( Alternative(..) )
import Control.Monad
import Data.Functor (($>))
import qualified Data.ByteString as BS
import Data.Ratio
import Data.Word
import Data.Maybe (fromMaybe, fromJust)
{-
Note [Constant folding]
~~~~~~~~~~~~~~~~~~~~~~~
primOpRules generates a rewrite rule for each primop
These rules do what is often called "constant folding"
E.g. the rules for +# might say
4 +# 5 = 9
Well, of course you'd need a lot of rules if you did it
like that, so we use a BuiltinRule instead, so that we
can match in any two literal values. So the rule is really
more like
(Lit x) +# (Lit y) = Lit (x+#y)
where the (+#) on the rhs is done at compile time
That is why these rules are built in here.
-}
primOpRules :: Name -> PrimOp -> Maybe CoreRule
primOpRules nm = \case
TagToEnumOp -> mkPrimOpRule nm 2 [ tagToEnumRule ]
DataToTagOp -> mkPrimOpRule nm 2 [ dataToTagRule ]
-- Int8 operations
Int8AddOp -> mkPrimOpRule nm 2 [ binaryLit (int8Op2 (+))
, identity zeroI8
, addFoldingRules Int8AddOp int8Ops
]
Int8SubOp -> mkPrimOpRule nm 2 [ binaryLit (int8Op2 (-))
, rightIdentity zeroI8
, equalArgs $> Lit zeroI8
, subFoldingRules Int8SubOp int8Ops
]
Int8MulOp -> mkPrimOpRule nm 2 [ binaryLit (int8Op2 (*))
, zeroElem
, identity oneI8
, mulFoldingRules Int8MulOp int8Ops
]
Int8QuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int8Op2 quot)
, leftZero
, rightIdentity oneI8
, equalArgs $> Lit oneI8 ]
Int8RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int8Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroI8
, equalArgs $> Lit zeroI8 ]
Int8NegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp Int8NegOp ]
Int8SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt8 (const shiftL)
, rightIdentity zeroI8 ]
Int8SraOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt8 (const shiftR)
, rightIdentity zeroI8 ]
Int8SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt8 $ const $ shiftRightLogical @Word8
, rightIdentity zeroI8 ]
-- Word8 operations
Word8AddOp -> mkPrimOpRule nm 2 [ binaryLit (word8Op2 (+))
, identity zeroW8
, addFoldingRules Word8AddOp word8Ops
]
Word8SubOp -> mkPrimOpRule nm 2 [ binaryLit (word8Op2 (-))
, rightIdentity zeroW8
, equalArgs $> Lit zeroW8
, subFoldingRules Word8SubOp word8Ops
]
Word8MulOp -> mkPrimOpRule nm 2 [ binaryLit (word8Op2 (*))
, identity oneW8
, mulFoldingRules Word8MulOp word8Ops
]
Word8QuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word8Op2 quot)
, rightIdentity oneW8 ]
Word8RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word8Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroW8
, equalArgs $> Lit zeroW8 ]
Word8AndOp -> mkPrimOpRule nm 2 [ binaryLit (word8Op2 (.&.))
, idempotent
, zeroElem
, identity (mkLitWord8 0xFF)
, sameArgIdempotentCommut Word8AndOp
, andFoldingRules word8Ops
]
Word8OrOp -> mkPrimOpRule nm 2 [ binaryLit (word8Op2 (.|.))
, idempotent
, identity zeroW8
, sameArgIdempotentCommut Word8OrOp
, orFoldingRules word8Ops
]
Word8XorOp -> mkPrimOpRule nm 2 [ binaryLit (word8Op2 xor)
, identity zeroW8
, equalArgs $> Lit zeroW8 ]
Word8NotOp -> mkPrimOpRule nm 1 [ unaryLit complementOp
, semiInversePrimOp Word8NotOp ]
Word8SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord8 (const shiftL) ]
Word8SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord8 $ const $ shiftRightLogical @Word8 ]
-- Int16 operations
Int16AddOp -> mkPrimOpRule nm 2 [ binaryLit (int16Op2 (+))
, identity zeroI16
, addFoldingRules Int16AddOp int16Ops
]
Int16SubOp -> mkPrimOpRule nm 2 [ binaryLit (int16Op2 (-))
, rightIdentity zeroI16
, equalArgs $> Lit zeroI16
, subFoldingRules Int16SubOp int16Ops
]
Int16MulOp -> mkPrimOpRule nm 2 [ binaryLit (int16Op2 (*))
, zeroElem
, identity oneI16
, mulFoldingRules Int16MulOp int16Ops
]
Int16QuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int16Op2 quot)
, leftZero
, rightIdentity oneI16
, equalArgs $> Lit oneI16 ]
Int16RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int16Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroI16
, equalArgs $> Lit zeroI16 ]
Int16NegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp Int16NegOp ]
Int16SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt16 (const shiftL)
, rightIdentity zeroI16 ]
Int16SraOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt16 (const shiftR)
, rightIdentity zeroI16 ]
Int16SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt16 $ const $ shiftRightLogical @Word16
, rightIdentity zeroI16 ]
-- Word16 operations
Word16AddOp -> mkPrimOpRule nm 2 [ binaryLit (word16Op2 (+))
, identity zeroW16
, addFoldingRules Word16AddOp word16Ops
]
Word16SubOp -> mkPrimOpRule nm 2 [ binaryLit (word16Op2 (-))
, rightIdentity zeroW16
, equalArgs $> Lit zeroW16
, subFoldingRules Word16SubOp word16Ops
]
Word16MulOp -> mkPrimOpRule nm 2 [ binaryLit (word16Op2 (*))
, identity oneW16
, mulFoldingRules Word16MulOp word16Ops
]
Word16QuotOp-> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word16Op2 quot)
, rightIdentity oneW16 ]
Word16RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word16Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroW16
, equalArgs $> Lit zeroW16 ]
Word16AndOp -> mkPrimOpRule nm 2 [ binaryLit (word16Op2 (.&.))
, idempotent
, zeroElem
, identity (mkLitWord16 0xFFFF)
, sameArgIdempotentCommut Word16AndOp
, andFoldingRules word16Ops
]
Word16OrOp -> mkPrimOpRule nm 2 [ binaryLit (word16Op2 (.|.))
, idempotent
, identity zeroW16
, sameArgIdempotentCommut Word16OrOp
, orFoldingRules word16Ops
]
Word16XorOp -> mkPrimOpRule nm 2 [ binaryLit (word16Op2 xor)
, identity zeroW16
, equalArgs $> Lit zeroW16 ]
Word16NotOp -> mkPrimOpRule nm 1 [ unaryLit complementOp
, semiInversePrimOp Word16NotOp ]
Word16SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord16 (const shiftL) ]
Word16SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord16 $ const $ shiftRightLogical @Word16 ]
-- Int32 operations
Int32AddOp -> mkPrimOpRule nm 2 [ binaryLit (int32Op2 (+))
, identity zeroI32
, addFoldingRules Int32AddOp int32Ops
]
Int32SubOp -> mkPrimOpRule nm 2 [ binaryLit (int32Op2 (-))
, rightIdentity zeroI32
, equalArgs $> Lit zeroI32
, subFoldingRules Int32SubOp int32Ops
]
Int32MulOp -> mkPrimOpRule nm 2 [ binaryLit (int32Op2 (*))
, zeroElem
, identity oneI32
, mulFoldingRules Int32MulOp int32Ops
]
Int32QuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int32Op2 quot)
, leftZero
, rightIdentity oneI32
, equalArgs $> Lit oneI32 ]
Int32RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int32Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroI32
, equalArgs $> Lit zeroI32 ]
Int32NegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp Int32NegOp ]
Int32SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt32 (const shiftL)
, rightIdentity zeroI32 ]
Int32SraOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt32 (const shiftR)
, rightIdentity zeroI32 ]
Int32SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt32 $ const $ shiftRightLogical @Word32
, rightIdentity zeroI32 ]
-- Word32 operations
Word32AddOp -> mkPrimOpRule nm 2 [ binaryLit (word32Op2 (+))
, identity zeroW32
, addFoldingRules Word32AddOp word32Ops
]
Word32SubOp -> mkPrimOpRule nm 2 [ binaryLit (word32Op2 (-))
, rightIdentity zeroW32
, equalArgs $> Lit zeroW32
, subFoldingRules Word32SubOp word32Ops
]
Word32MulOp -> mkPrimOpRule nm 2 [ binaryLit (word32Op2 (*))
, identity oneW32
, mulFoldingRules Word32MulOp word32Ops
]
Word32QuotOp-> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word32Op2 quot)
, rightIdentity oneW32 ]
Word32RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word32Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroW32
, equalArgs $> Lit zeroW32 ]
Word32AndOp -> mkPrimOpRule nm 2 [ binaryLit (word32Op2 (.&.))
, idempotent
, zeroElem
, identity (mkLitWord32 0xFFFFFFFF)
, sameArgIdempotentCommut Word32AndOp
, andFoldingRules word32Ops
]
Word32OrOp -> mkPrimOpRule nm 2 [ binaryLit (word32Op2 (.|.))
, idempotent
, identity zeroW32
, sameArgIdempotentCommut Word32OrOp
, orFoldingRules word32Ops
]
Word32XorOp -> mkPrimOpRule nm 2 [ binaryLit (word32Op2 xor)
, identity zeroW32
, equalArgs $> Lit zeroW32 ]
Word32NotOp -> mkPrimOpRule nm 1 [ unaryLit complementOp
, semiInversePrimOp Word32NotOp ]
Word32SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord32 (const shiftL) ]
Word32SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord32 $ const $ shiftRightLogical @Word32 ]
-- Int64 operations
Int64AddOp -> mkPrimOpRule nm 2 [ binaryLit (int64Op2 (+))
, identity zeroI64
, addFoldingRules Int64AddOp int64Ops
]
Int64SubOp -> mkPrimOpRule nm 2 [ binaryLit (int64Op2 (-))
, rightIdentity zeroI64
, equalArgs $> Lit zeroI64
, subFoldingRules Int64SubOp int64Ops
]
Int64MulOp -> mkPrimOpRule nm 2 [ binaryLit (int64Op2 (*))
, zeroElem
, identity oneI64
, mulFoldingRules Int64MulOp int64Ops
]
Int64QuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int64Op2 quot)
, leftZero
, rightIdentity oneI64
, equalArgs $> Lit oneI64 ]
Int64RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (int64Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroI64
, equalArgs $> Lit zeroI64 ]
Int64NegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp Int64NegOp ]
Int64SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt64 (const shiftL)
, rightIdentity zeroI64 ]
Int64SraOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt64 (const shiftR)
, rightIdentity zeroI64 ]
Int64SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt64 $ const $ shiftRightLogical @Word64
, rightIdentity zeroI64 ]
-- Word64 operations
Word64AddOp -> mkPrimOpRule nm 2 [ binaryLit (word64Op2 (+))
, identity zeroW64
, addFoldingRules Word64AddOp word64Ops
]
Word64SubOp -> mkPrimOpRule nm 2 [ binaryLit (word64Op2 (-))
, rightIdentity zeroW64
, equalArgs $> Lit zeroW64
, subFoldingRules Word64SubOp word64Ops
]
Word64MulOp -> mkPrimOpRule nm 2 [ binaryLit (word64Op2 (*))
, identity oneW64
, mulFoldingRules Word64MulOp word64Ops
]
Word64QuotOp-> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word64Op2 quot)
, rightIdentity oneW64 ]
Word64RemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (word64Op2 rem)
, leftZero
, oneLit 1 $> Lit zeroW64
, equalArgs $> Lit zeroW64 ]
Word64AndOp -> mkPrimOpRule nm 2 [ binaryLit (word64Op2 (.&.))
, idempotent
, zeroElem
, identity (mkLitWord64 0xFFFFFFFFFFFFFFFF)
, sameArgIdempotentCommut Word64AndOp
, andFoldingRules word64Ops
]
Word64OrOp -> mkPrimOpRule nm 2 [ binaryLit (word64Op2 (.|.))
, idempotent
, identity zeroW64
, sameArgIdempotentCommut Word64OrOp
, orFoldingRules word64Ops
]
Word64XorOp -> mkPrimOpRule nm 2 [ binaryLit (word64Op2 xor)
, identity zeroW64
, equalArgs $> Lit zeroW64 ]
Word64NotOp -> mkPrimOpRule nm 1 [ unaryLit complementOp
, semiInversePrimOp Word64NotOp ]
Word64SllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord64 (const shiftL) ]
Word64SrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord64 $ const $ shiftRightLogical @Word64 ]
-- Int operations
IntAddOp -> mkPrimOpRule nm 2 [ binaryLit (intOp2 (+))
, identityPlatform zeroi
, addFoldingRules IntAddOp intOps
]
IntSubOp -> mkPrimOpRule nm 2 [ binaryLit (intOp2 (-))
, rightIdentityPlatform zeroi
, equalArgs >> retLit zeroi
, subFoldingRules IntSubOp intOps
]
IntAddCOp -> mkPrimOpRule nm 2 [ binaryLit (intOpC2 (+))
, identityCPlatform zeroi ]
IntSubCOp -> mkPrimOpRule nm 2 [ binaryLit (intOpC2 (-))
, rightIdentityCPlatform zeroi
, equalArgs >> retLitNoC zeroi ]
IntMulOp -> mkPrimOpRule nm 2 [ binaryLit (intOp2 (*))
, zeroElem
, identityPlatform onei
, mulFoldingRules IntMulOp intOps
]
IntMul2Op -> mkPrimOpRule nm 2 [ do
[Lit (LitNumber _ l1), Lit (LitNumber _ l2)] <- getArgs
platform <- getPlatform
let r = l1 * l2
pure $ mkCoreUbxTup [intPrimTy,intPrimTy,intPrimTy]
[ Lit (if platformInIntRange platform r then zeroi platform else onei platform)
, mkIntLitWrap platform (r `shiftR` platformWordSizeInBits platform)
, mkIntLitWrap platform r
]
, zeroElem >>= \z ->
pure (mkCoreUbxTup [intPrimTy,intPrimTy,intPrimTy]
[z,z,z])
-- timesInt2# 1# other
-- ~~~>
-- (# 0#, 0# -# (other >># (WORD_SIZE_IN_BITS-1)), other #)
-- The second element is the sign bit
-- repeated to fill a word.
, identityPlatform onei >>= \other -> do
platform <- getPlatform
pure $ mkCoreUbxTup [intPrimTy,intPrimTy,intPrimTy]
[ Lit (zeroi platform)
, mkCoreApps (Var (mkPrimOpId IntSubOp))
[ Lit (zeroi platform)
, mkCoreApps (Var (mkPrimOpId IntSrlOp))
[ other
, mkIntLit platform (fromIntegral (platformWordSizeInBits platform - 1))
]
]
, other
]
]
IntQuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (intOp2 quot)
, leftZero
, rightIdentityPlatform onei
, equalArgs >> retLit onei ]
IntRemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (intOp2 rem)
, leftZero
, oneLit 1 >> retLit zeroi
, equalArgs >> retLit zeroi ]
IntAndOp -> mkPrimOpRule nm 2 [ binaryLit (intOp2 (.&.))
, idempotent
, zeroElem
, identityPlatform (\p -> mkLitInt p (-1))
, sameArgIdempotentCommut IntAndOp
, andFoldingRules intOps
]
IntOrOp -> mkPrimOpRule nm 2 [ binaryLit (intOp2 (.|.))
, idempotent
, identityPlatform zeroi
, sameArgIdempotentCommut IntOrOp
, orFoldingRules intOps
]
IntXorOp -> mkPrimOpRule nm 2 [ binaryLit (intOp2 xor)
, identityPlatform zeroi
, equalArgs >> retLit zeroi ]
IntNotOp -> mkPrimOpRule nm 1 [ unaryLit complementOp
, semiInversePrimOp IntNotOp ]
IntNegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp IntNegOp ]
IntSllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt (const shiftL)
, rightIdentityPlatform zeroi ]
IntSraOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt (const shiftR)
, rightIdentityPlatform zeroi ]
IntSrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumInt shiftRightLogicalNative
, rightIdentityPlatform zeroi ]
-- Word operations
WordAddOp -> mkPrimOpRule nm 2 [ binaryLit (wordOp2 (+))
, identityPlatform zerow
, addFoldingRules WordAddOp wordOps
]
WordSubOp -> mkPrimOpRule nm 2 [ binaryLit (wordOp2 (-))
, rightIdentityPlatform zerow
, equalArgs >> retLit zerow
, subFoldingRules WordSubOp wordOps
]
WordAddCOp -> mkPrimOpRule nm 2 [ binaryLit (wordOpC2 (+))
, identityCPlatform zerow ]
WordSubCOp -> mkPrimOpRule nm 2 [ binaryLit (wordOpC2 (-))
, rightIdentityCPlatform zerow
, equalArgs >> retLitNoC zerow ]
WordMulOp -> mkPrimOpRule nm 2 [ binaryLit (wordOp2 (*))
, identityPlatform onew
, mulFoldingRules WordMulOp wordOps
]
WordQuotOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (wordOp2 quot)
, rightIdentityPlatform onew ]
WordRemOp -> mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (wordOp2 rem)
, leftZero
, oneLit 1 >> retLit zerow
, equalArgs >> retLit zerow ]
WordAndOp -> mkPrimOpRule nm 2 [ binaryLit (wordOp2 (.&.))
, idempotent
, zeroElem
, identityPlatform (\p -> mkLitWord p (platformMaxWord p))
, sameArgIdempotentCommut WordAndOp
, andFoldingRules wordOps
]
WordOrOp -> mkPrimOpRule nm 2 [ binaryLit (wordOp2 (.|.))
, idempotent
, identityPlatform zerow
, sameArgIdempotentCommut WordOrOp
, orFoldingRules wordOps
]
WordXorOp -> mkPrimOpRule nm 2 [ binaryLit (wordOp2 xor)
, identityPlatform zerow
, equalArgs >> retLit zerow ]
WordNotOp -> mkPrimOpRule nm 1 [ unaryLit complementOp
, semiInversePrimOp WordNotOp ]
WordSllOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord (const shiftL) ]
WordSrlOp -> mkPrimOpRule nm 2 [ shiftRule LitNumWord shiftRightLogicalNative ]
PopCnt8Op -> mkPrimOpRule nm 1 [ pop_count @Word8 ]
PopCnt16Op -> mkPrimOpRule nm 1 [ pop_count @Word16 ]
PopCnt32Op -> mkPrimOpRule nm 1 [ pop_count @Word32 ]
PopCnt64Op -> mkPrimOpRule nm 1 [ pop_count @Word64 ]
PopCntOp -> mkPrimOpRule nm 1 [ getWordSize >>= \case
PW4 -> pop_count @Word32
PW8 -> pop_count @Word64
]
Ctz8Op -> mkPrimOpRule nm 1 [ ctz @Word8 ]
Ctz16Op -> mkPrimOpRule nm 1 [ ctz @Word16 ]
Ctz32Op -> mkPrimOpRule nm 1 [ ctz @Word32 ]
Ctz64Op -> mkPrimOpRule nm 1 [ ctz @Word64 ]
CtzOp -> mkPrimOpRule nm 1 [ getWordSize >>= \case
PW4 -> ctz @Word32
PW8 -> ctz @Word64
]
Clz8Op -> mkPrimOpRule nm 1 [ clz @Word8 ]
Clz16Op -> mkPrimOpRule nm 1 [ clz @Word16 ]
Clz32Op -> mkPrimOpRule nm 1 [ clz @Word32 ]
Clz64Op -> mkPrimOpRule nm 1 [ clz @Word64 ]
ClzOp -> mkPrimOpRule nm 1 [ getWordSize >>= \case
PW4 -> clz @Word32
PW8 -> clz @Word64
]
-- coercions
Int8ToIntOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToIntLit ]
Int16ToIntOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToIntLit ]
Int32ToIntOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToIntLit ]
Int64ToIntOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToIntLit ]
IntToInt8Op -> mkPrimOpRule nm 1 [ liftLit narrowInt8Lit
, narrowSubsumesAnd IntAndOp IntToInt8Op 8 ]
IntToInt16Op -> mkPrimOpRule nm 1 [ liftLit narrowInt16Lit
, narrowSubsumesAnd IntAndOp IntToInt16Op 16 ]
IntToInt32Op -> mkPrimOpRule nm 1 [ liftLit narrowInt32Lit
, narrowSubsumesAnd IntAndOp IntToInt32Op 32 ]
IntToInt64Op -> mkPrimOpRule nm 1 [ liftLit narrowInt64Lit ]
Word8ToWordOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToWordLit
, extendNarrowPassthrough WordToWord8Op 0xFF
]
Word16ToWordOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToWordLit
, extendNarrowPassthrough WordToWord16Op 0xFFFF
]
Word32ToWordOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToWordLit
, extendNarrowPassthrough WordToWord32Op 0xFFFFFFFF
]
Word64ToWordOp -> mkPrimOpRule nm 1 [ liftLitPlatform convertToWordLit ]
WordToWord8Op -> mkPrimOpRule nm 1 [ liftLit narrowWord8Lit
, narrowSubsumesAnd WordAndOp WordToWord8Op 8 ]
WordToWord16Op -> mkPrimOpRule nm 1 [ liftLit narrowWord16Lit
, narrowSubsumesAnd WordAndOp WordToWord16Op 16 ]
WordToWord32Op -> mkPrimOpRule nm 1 [ liftLit narrowWord32Lit
, narrowSubsumesAnd WordAndOp WordToWord32Op 32 ]
WordToWord64Op -> mkPrimOpRule nm 1 [ liftLit narrowWord64Lit ]
Word8ToInt8Op -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumInt8) ]
Int8ToWord8Op -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumWord8) ]
Word16ToInt16Op-> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumInt16) ]
Int16ToWord16Op-> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumWord16) ]
Word32ToInt32Op-> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumInt32) ]
Int32ToWord32Op-> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumWord32) ]
Word64ToInt64Op-> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumInt64) ]
Int64ToWord64Op-> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumWord64) ]
WordToIntOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumInt) ]
IntToWordOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumCoerce LitNumWord) ]
Narrow8IntOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumNarrow LitNumInt8)
, subsumedByPrimOp Narrow8IntOp
, Narrow8IntOp `subsumesPrimOp` Narrow16IntOp
, Narrow8IntOp `subsumesPrimOp` Narrow32IntOp
, narrowSubsumesAnd IntAndOp Narrow8IntOp 8 ]
Narrow16IntOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumNarrow LitNumInt16)
, subsumedByPrimOp Narrow8IntOp
, subsumedByPrimOp Narrow16IntOp
, Narrow16IntOp `subsumesPrimOp` Narrow32IntOp
, narrowSubsumesAnd IntAndOp Narrow16IntOp 16 ]
Narrow32IntOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumNarrow LitNumInt32)
, subsumedByPrimOp Narrow8IntOp
, subsumedByPrimOp Narrow16IntOp
, subsumedByPrimOp Narrow32IntOp
, removeOp32
, narrowSubsumesAnd IntAndOp Narrow32IntOp 32 ]
Narrow8WordOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumNarrow LitNumWord8)
, subsumedByPrimOp Narrow8WordOp
, Narrow8WordOp `subsumesPrimOp` Narrow16WordOp
, Narrow8WordOp `subsumesPrimOp` Narrow32WordOp
, narrowSubsumesAnd WordAndOp Narrow8WordOp 8 ]
Narrow16WordOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumNarrow LitNumWord16)
, subsumedByPrimOp Narrow8WordOp
, subsumedByPrimOp Narrow16WordOp
, Narrow16WordOp `subsumesPrimOp` Narrow32WordOp
, narrowSubsumesAnd WordAndOp Narrow16WordOp 16 ]
Narrow32WordOp -> mkPrimOpRule nm 1 [ liftLitPlatform (litNumNarrow LitNumWord32)
, subsumedByPrimOp Narrow8WordOp
, subsumedByPrimOp Narrow16WordOp
, subsumedByPrimOp Narrow32WordOp
, removeOp32
, narrowSubsumesAnd WordAndOp Narrow32WordOp 32 ]
OrdOp -> mkPrimOpRule nm 1 [ liftLit charToIntLit
, semiInversePrimOp ChrOp ]
ChrOp -> mkPrimOpRule nm 1 [ do [Lit lit] <- getArgs
guard (litFitsInChar lit)
liftLit intToCharLit
, semiInversePrimOp OrdOp ]
FloatToIntOp -> mkPrimOpRule nm 1 [ liftLit floatToIntLit ]
IntToFloatOp -> mkPrimOpRule nm 1 [ liftLit intToFloatLit ]
DoubleToIntOp -> mkPrimOpRule nm 1 [ liftLit doubleToIntLit ]
IntToDoubleOp -> mkPrimOpRule nm 1 [ liftLit intToDoubleLit ]
-- SUP: Not sure what the standard says about precision in the following 2 cases
FloatToDoubleOp -> mkPrimOpRule nm 1 [ liftLit floatToDoubleLit ]
DoubleToFloatOp -> mkPrimOpRule nm 1 [ liftLit doubleToFloatLit ]
-- Float
FloatAddOp -> mkPrimOpRule nm 2 [ binaryLit (floatOp2 (+))
, identity zerof ]
FloatSubOp -> mkPrimOpRule nm 2 [ binaryLit (floatOp2 (-))
, rightIdentity zerof ]
FloatMulOp -> mkPrimOpRule nm 2 [ binaryLit (floatOp2 (*))
, identity onef
, strengthReduction twof FloatAddOp ]
-- zeroElem zerof doesn't hold because of NaN
FloatDivOp -> mkPrimOpRule nm 2 [ guardFloatDiv >> binaryLit (floatOp2 (/))
, rightIdentity onef ]
FloatNegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp FloatNegOp ]
FloatDecode_IntOp -> mkPrimOpRule nm 1 [ unaryLit floatDecodeOp ]
-- Double
DoubleAddOp -> mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (+))
, identity zerod ]
DoubleSubOp -> mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (-))
, rightIdentity zerod ]
DoubleMulOp -> mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (*))
, identity oned
, strengthReduction twod DoubleAddOp ]
-- zeroElem zerod doesn't hold because of NaN
DoubleDivOp -> mkPrimOpRule nm 2 [ guardDoubleDiv >> binaryLit (doubleOp2 (/))
, rightIdentity oned ]
DoubleNegOp -> mkPrimOpRule nm 1 [ unaryLit negOp
, semiInversePrimOp DoubleNegOp ]
DoubleDecode_Int64Op -> mkPrimOpRule nm 1 [ unaryLit doubleDecodeOp ]
-- Relational operators, equality
Int8EqOp -> mkRelOpRule nm (==) [ litEq True ]
Int8NeOp -> mkRelOpRule nm (/=) [ litEq False ]
Int16EqOp -> mkRelOpRule nm (==) [ litEq True ]
Int16NeOp -> mkRelOpRule nm (/=) [ litEq False ]
Int32EqOp -> mkRelOpRule nm (==) [ litEq True ]
Int32NeOp -> mkRelOpRule nm (/=) [ litEq False ]
Int64EqOp -> mkRelOpRule nm (==) [ litEq True ]
Int64NeOp -> mkRelOpRule nm (/=) [ litEq False ]
IntEqOp -> mkRelOpRule nm (==) [ litEq True ]
IntNeOp -> mkRelOpRule nm (/=) [ litEq False ]
Word8EqOp -> mkRelOpRule nm (==) [ litEq True ]
Word8NeOp -> mkRelOpRule nm (/=) [ litEq False ]
Word16EqOp -> mkRelOpRule nm (==) [ litEq True ]
Word16NeOp -> mkRelOpRule nm (/=) [ litEq False ]
Word32EqOp -> mkRelOpRule nm (==) [ litEq True ]
Word32NeOp -> mkRelOpRule nm (/=) [ litEq False ]
Word64EqOp -> mkRelOpRule nm (==) [ litEq True ]
Word64NeOp -> mkRelOpRule nm (/=) [ litEq False ]
WordEqOp -> mkRelOpRule nm (==) [ litEq True ]
WordNeOp -> mkRelOpRule nm (/=) [ litEq False ]
CharEqOp -> mkRelOpRule nm (==) [ litEq True ]
CharNeOp -> mkRelOpRule nm (/=) [ litEq False ]
FloatEqOp -> mkFloatingRelOpRule nm (==)
FloatNeOp -> mkFloatingRelOpRule nm (/=)
DoubleEqOp -> mkFloatingRelOpRule nm (==)
DoubleNeOp -> mkFloatingRelOpRule nm (/=)
-- Relational operators, ordering
Int8GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Int8GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Int8LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Int8LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Int16GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Int16GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Int16LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Int16LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Int32GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Int32GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Int32LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Int32LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Int64GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Int64GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Int64LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Int64LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
IntGtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
IntGeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
IntLeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
IntLtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Word8GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Word8GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Word8LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Word8LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Word16GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Word16GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Word16LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Word16LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Word32GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Word32GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Word32LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Word32LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
Word64GtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
Word64GeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
Word64LeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
Word64LtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
WordGtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
WordGeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
WordLeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
WordLtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
CharGtOp -> mkRelOpRule nm (>) [ boundsCmp Gt ]
CharGeOp -> mkRelOpRule nm (>=) [ boundsCmp Ge ]
CharLeOp -> mkRelOpRule nm (<=) [ boundsCmp Le ]
CharLtOp -> mkRelOpRule nm (<) [ boundsCmp Lt ]
FloatGtOp -> mkFloatingRelOpRule nm (>)
FloatGeOp -> mkFloatingRelOpRule nm (>=)
FloatLeOp -> mkFloatingRelOpRule nm (<=)
FloatLtOp -> mkFloatingRelOpRule nm (<)
DoubleGtOp -> mkFloatingRelOpRule nm (>)
DoubleGeOp -> mkFloatingRelOpRule nm (>=)
DoubleLeOp -> mkFloatingRelOpRule nm (<=)
DoubleLtOp -> mkFloatingRelOpRule nm (<)
-- Misc
AddrAddOp -> mkPrimOpRule nm 2 [ rightIdentityPlatform zeroi ]
SeqOp -> mkPrimOpRule nm 4 [ seqRule ]
SparkOp -> mkPrimOpRule nm 4 [ sparkRule ]
_ -> Nothing
{-
************************************************************************
* *
\subsection{Doing the business}
* *
************************************************************************
-}
-- useful shorthands
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
-- x `cmp` x does not depend on x, so
-- compute it for the arbitrary value 'True'
-- and use that result
equal_rule = do { equalArgs
; platform <- getPlatform
; return (if cmp True True
then trueValInt platform
else falseValInt platform) }
{- Note [Rules for floating-point comparisons]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We need different rules for floating-point values because for floats
it is not true that x = x (for NaNs); so we do not want the equal_rule
rule that mkRelOpRule uses.
Note also that, in the case of equality/inequality, we do /not/
want to switch to a case-expression. For example, we do not want
to convert
case (eqFloat# x 3.8#) of
True -> this
False -> that
to
case x of
3.8#::Float# -> this
_ -> that
See #9238. Reason: comparing floating-point values for equality
delicate, and we don't want to implement that delicacy in the code for
case expressions. So we make it an invariant of Core that a case
expression never scrutinises a Float# or Double#.
This transformation is what the litEq rule does;
see Note [The litEq rule: converting equality to case].
So we /refrain/ from using litEq for mkFloatingRelOpRule.
-}
mkFloatingRelOpRule :: Name -> (forall a . Ord a => a -> a -> Bool)
-> Maybe CoreRule
-- See Note [Rules for floating-point comparisons]
mkFloatingRelOpRule nm cmp
= mkPrimOpRule nm 2 [binaryCmpLit cmp]
-- common constants
zeroi, onei, zerow, onew :: Platform -> Literal
zeroi platform = mkLitInt platform 0
onei platform = mkLitInt platform 1
zerow platform = mkLitWord platform 0
onew platform = mkLitWord platform 1
zeroI8, oneI8, zeroW8, oneW8 :: Literal
zeroI8 = mkLitInt8 0
oneI8 = mkLitInt8 1
zeroW8 = mkLitWord8 0
oneW8 = mkLitWord8 1
zeroI16, oneI16, zeroW16, oneW16 :: Literal
zeroI16 = mkLitInt16 0
oneI16 = mkLitInt16 1
zeroW16 = mkLitWord16 0
oneW16 = mkLitWord16 1
zeroI32, oneI32, zeroW32, oneW32 :: Literal
zeroI32 = mkLitInt32 0
oneI32 = mkLitInt32 1
zeroW32 = mkLitWord32 0
oneW32 = mkLitWord32 1
zeroI64, oneI64, zeroW64, oneW64 :: Literal
zeroI64 = mkLitInt64 0
oneI64 = mkLitInt64 1
zeroW64 = mkLitWord64 0
oneW64 = mkLitWord64 1
zerof, onef, twof, zerod, oned, twod :: Literal
zerof = mkLitFloat 0.0
onef = mkLitFloat 1.0
twof = mkLitFloat 2.0
zerod = mkLitDouble 0.0
oned = mkLitDouble 1.0
twod = mkLitDouble 2.0
cmpOp :: Platform -> (forall a . Ord a => a -> a -> Bool)
-> Literal -> Literal -> Maybe CoreExpr
cmpOp platform cmp = go
where
done True = Just $ trueValInt platform
done False = Just $ falseValInt platform
-- These compares are at different types
go (LitChar i1) (LitChar i2) = done (i1 `cmp` i2)
go (LitFloat i1) (LitFloat i2) = done (i1 `cmp` i2)
go (LitDouble i1) (LitDouble i2) = done (i1 `cmp` i2)
go (LitNumber nt1 i1) (LitNumber nt2 i2)
| nt1 /= nt2 = Nothing
| otherwise = done (i1 `cmp` i2)
go _ _ = Nothing
--------------------------
negOp :: RuleOpts -> Literal -> Maybe CoreExpr -- Negate
negOp env = \case
(LitFloat 0.0) -> Nothing -- can't represent -0.0 as a Rational
(LitFloat f) -> Just (mkFloatVal env (-f))
(LitDouble 0.0) -> Nothing
(LitDouble d) -> Just (mkDoubleVal env (-d))
(LitNumber nt i)
| litNumIsSigned nt -> Just (Lit (mkLitNumberWrap (roPlatform env) nt (-i)))
_ -> Nothing
complementOp :: RuleOpts -> Literal -> Maybe CoreExpr -- Binary complement
complementOp env (LitNumber nt i) =
Just (Lit (mkLitNumberWrap (roPlatform env) nt (complement i)))
complementOp _ _ = Nothing
int8Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
int8Op2 op _ (LitNumber LitNumInt8 i1) (LitNumber LitNumInt8 i2) =
int8Result (fromInteger i1 `op` fromInteger i2)
int8Op2 _ _ _ _ = Nothing
int16Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
int16Op2 op _ (LitNumber LitNumInt16 i1) (LitNumber LitNumInt16 i2) =
int16Result (fromInteger i1 `op` fromInteger i2)
int16Op2 _ _ _ _ = Nothing
int32Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
int32Op2 op _ (LitNumber LitNumInt32 i1) (LitNumber LitNumInt32 i2) =
int32Result (fromInteger i1 `op` fromInteger i2)
int32Op2 _ _ _ _ = Nothing
int64Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
int64Op2 op _ (LitNumber LitNumInt64 i1) (LitNumber LitNumInt64 i2) =
int64Result (fromInteger i1 `op` fromInteger i2)
int64Op2 _ _ _ _ = Nothing
intOp2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
intOp2 = intOp2' . const
intOp2' :: (Integral a, Integral b)
=> (RuleOpts -> a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
intOp2' op env (LitNumber LitNumInt i1) (LitNumber LitNumInt i2) =
let o = op env
in intResult (roPlatform env) (fromInteger i1 `o` fromInteger i2)
intOp2' _ _ _ _ = Nothing
intOpC2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
intOpC2 op env (LitNumber LitNumInt i1) (LitNumber LitNumInt i2) =
intCResult (roPlatform env) (fromInteger i1 `op` fromInteger i2)
intOpC2 _ _ _ _ = Nothing
shiftRightLogical :: forall t. (Integral t, Bits t) => Integer -> Int -> Integer
shiftRightLogical x n = fromIntegral (fromInteger x `shiftR` n :: t)
-- | Shift right, putting zeros in rather than sign-propagating as
-- 'Bits.shiftR' would do. Do this by converting to the appropriate Word
-- and back. Obviously this won't work for too-big values, but its ok as
-- we use it here.
shiftRightLogicalNative :: Platform -> Integer -> Int -> Integer
shiftRightLogicalNative platform =
case platformWordSize platform of
PW4 -> shiftRightLogical @Word32
PW8 -> shiftRightLogical @Word64
--------------------------
retLit :: (Platform -> Literal) -> RuleM CoreExpr
retLit l = do platform <- getPlatform
return $ Lit $ l platform
retLitNoC :: (Platform -> Literal) -> RuleM CoreExpr
retLitNoC l = do platform <- getPlatform
let lit = l platform
let ty = literalType lit
return $ mkCoreUbxTup [ty, ty] [Lit lit, Lit (zeroi platform)]
word8Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
word8Op2 op _ (LitNumber LitNumWord8 i1) (LitNumber LitNumWord8 i2) =
word8Result (fromInteger i1 `op` fromInteger i2)
word8Op2 _ _ _ _ = Nothing
word16Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
word16Op2 op _ (LitNumber LitNumWord16 i1) (LitNumber LitNumWord16 i2) =
word16Result (fromInteger i1 `op` fromInteger i2)
word16Op2 _ _ _ _ = Nothing
word32Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
word32Op2 op _ (LitNumber LitNumWord32 i1) (LitNumber LitNumWord32 i2) =
word32Result (fromInteger i1 `op` fromInteger i2)
word32Op2 _ _ _ _ = Nothing
word64Op2
:: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
word64Op2 op _ (LitNumber LitNumWord64 i1) (LitNumber LitNumWord64 i2) =
word64Result (fromInteger i1 `op` fromInteger i2)
word64Op2 _ _ _ _ = Nothing
wordOp2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
wordOp2 op env (LitNumber LitNumWord w1) (LitNumber LitNumWord w2)
= wordResult (roPlatform env) (fromInteger w1 `op` fromInteger w2)
wordOp2 _ _ _ _ = Nothing
wordOpC2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> RuleOpts -> Literal -> Literal -> Maybe CoreExpr
wordOpC2 op env (LitNumber LitNumWord w1) (LitNumber LitNumWord w2) =
wordCResult (roPlatform env) (fromInteger w1 `op` fromInteger w2)
wordOpC2 _ _ _ _ = Nothing
shiftRule :: LitNumType
-> (Platform -> Integer -> Int -> Integer)
-> RuleM CoreExpr
-- Shifts take an Int; hence third arg of op is Int
-- Used for shift primops
-- IntSllOp, IntSraOp, IntSrlOp :: Int# -> Int# -> Int#
-- SllOp, SrlOp :: Word# -> Int# -> Word#
shiftRule lit_num_ty shift_op = do
platform <- getPlatform
[e1, Lit (LitNumber LitNumInt shift_len)] <- getArgs
bit_size <- case litNumBitSize platform lit_num_ty of
Nothing -> mzero
Just bs -> pure (toInteger bs)
case e1 of
_ | shift_len == 0 -> pure e1
-- See Note [Guarding against silly shifts]
_ | shift_len < 0 || shift_len > bit_size
-> pure $ Lit $ mkLitNumberWrap platform lit_num_ty 0
-- Be sure to use lit_num_ty here, so we get a correctly typed zero.
-- See #18589
Lit (LitNumber nt x)
| 0 < shift_len && shift_len <= bit_size
-> assert (nt == lit_num_ty) $
let op = shift_op platform
-- Do the shift at type Integer, but shift length is Int.
-- Using host's Int is ok even if target's Int has a different size
-- because we test that shift_len <= bit_size (which is at most 64)
y = x `op` fromInteger shift_len
in pure $ Lit $ mkLitNumberWrap platform nt y
_ -> mzero
--------------------------
floatOp2 :: (Rational -> Rational -> Rational)
-> RuleOpts -> Literal -> Literal
-> Maybe (Expr CoreBndr)
floatOp2 op env (LitFloat f1) (LitFloat f2)
= Just (mkFloatVal env (f1 `op` f2))
floatOp2 _ _ _ _ = Nothing
--------------------------
floatDecodeOp :: RuleOpts -> Literal -> Maybe CoreExpr
floatDecodeOp env (LitFloat ((decodeFloat . fromRational @Float) -> (m, e)))
= Just $ mkCoreUbxTup [intPrimTy, intPrimTy]
[ mkIntVal (roPlatform env) (toInteger m)
, mkIntVal (roPlatform env) (toInteger e) ]
floatDecodeOp _ _
= Nothing
--------------------------
doubleOp2 :: (Rational -> Rational -> Rational)
-> RuleOpts -> Literal -> Literal
-> Maybe (Expr CoreBndr)
doubleOp2 op env (LitDouble f1) (LitDouble f2)
= Just (mkDoubleVal env (f1 `op` f2))
doubleOp2 _ _ _ _ = Nothing
--------------------------
doubleDecodeOp :: RuleOpts -> Literal -> Maybe CoreExpr
doubleDecodeOp env (LitDouble ((decodeFloat . fromRational @Double) -> (m, e)))
= Just $ mkCoreUbxTup [iNT64Ty, intPrimTy]
[ Lit (mkLitINT64 (toInteger m))
, mkIntVal platform (toInteger e) ]
where
platform = roPlatform env
(iNT64Ty, mkLitINT64)
| platformWordSizeInBits platform < 64
= (int64PrimTy, mkLitInt64Wrap)
| otherwise
= (intPrimTy , mkLitIntWrap platform)
doubleDecodeOp _ _
= Nothing
--------------------------
{- Note [The litEq rule: converting equality to case]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This stuff turns
n ==# 3#
into
case n of
3# -> True
m -> False
This is a Good Thing, because it allows case-of case things
to happen, and case-default absorption to happen. For
example:
if (n ==# 3#) || (n ==# 4#) then e1 else e2
will transform to
case n of
3# -> e1
4# -> e1
m -> e2
(modulo the usual precautions to avoid duplicating e1)
-}
litEq :: Bool -- True <=> equality, False <=> inequality
-> RuleM CoreExpr
litEq is_eq = msum
[ do [Lit lit, expr] <- getArgs
platform <- getPlatform
do_lit_eq platform lit expr
, do [expr, Lit lit] <- getArgs
platform <- getPlatform
do_lit_eq platform lit expr ]
where
do_lit_eq platform lit expr = do
guard (not (litIsLifted lit))
return (mkWildCase expr (unrestricted $ literalType lit) intPrimTy
[ Alt DEFAULT [] val_if_neq
, Alt (LitAlt lit) [] val_if_eq])
where
val_if_eq | is_eq = trueValInt platform
| otherwise = falseValInt platform
val_if_neq | is_eq = falseValInt platform
| otherwise = trueValInt platform
-- | Check if there is comparison with minBound or maxBound, that is
-- always true or false. For instance, an Int cannot be smaller than its
-- minBound, so we can replace such comparison with False.
boundsCmp :: Comparison -> RuleM CoreExpr
boundsCmp op = do
platform <- getPlatform
[a, b] <- getArgs
liftMaybe $ mkRuleFn platform op a b
data Comparison = Gt | Ge | Lt | Le
mkRuleFn :: Platform -> Comparison -> CoreExpr -> CoreExpr -> Maybe CoreExpr
mkRuleFn platform Gt (Lit lit) _ | isMinBound platform lit = Just $ falseValInt platform
mkRuleFn platform Le (Lit lit) _ | isMinBound platform lit = Just $ trueValInt platform
mkRuleFn platform Ge _ (Lit lit) | isMinBound platform lit = Just $ trueValInt platform
mkRuleFn platform Lt _ (Lit lit) | isMinBound platform lit = Just $ falseValInt platform
mkRuleFn platform Ge (Lit lit) _ | isMaxBound platform lit = Just $ trueValInt platform
mkRuleFn platform Lt (Lit lit) _ | isMaxBound platform lit = Just $ falseValInt platform
mkRuleFn platform Gt _ (Lit lit) | isMaxBound platform lit = Just $ falseValInt platform
mkRuleFn platform Le _ (Lit lit) | isMaxBound platform lit = Just $ trueValInt platform
mkRuleFn _ _ _ _ = Nothing
-- | Create an Int literal expression while ensuring the given Integer is in the
-- target Int range
int8Result :: Integer -> Maybe CoreExpr
int8Result result = Just (int8Result' result)
int8Result' :: Integer -> CoreExpr
int8Result' result = Lit (mkLitInt8Wrap result)
-- | Create an Int literal expression while ensuring the given Integer is in the
-- target Int range
int16Result :: Integer -> Maybe CoreExpr
int16Result result = Just (int16Result' result)
int16Result' :: Integer -> CoreExpr
int16Result' result = Lit (mkLitInt16Wrap result)
-- | Create an Int literal expression while ensuring the given Integer is in the
-- target Int range
int32Result :: Integer -> Maybe CoreExpr
int32Result result = Just (int32Result' result)
int32Result' :: Integer -> CoreExpr
int32Result' result = Lit (mkLitInt32Wrap result)
intResult :: Platform -> Integer -> Maybe CoreExpr
intResult platform result = Just (intResult' platform result)
intResult' :: Platform -> Integer -> CoreExpr
intResult' platform result = Lit (mkLitIntWrap platform result)
-- | Create an unboxed pair of an Int literal expression, ensuring the given
-- Integer is in the target Int range and the corresponding overflow flag
-- (@0#@/@1#@) if it wasn't.
intCResult :: Platform -> Integer -> Maybe CoreExpr
intCResult platform result = Just (mkPair [Lit lit, Lit c])
where
mkPair = mkCoreUbxTup [intPrimTy, intPrimTy]
(lit, b) = mkLitIntWrapC platform result
c = if b then onei platform else zeroi platform
-- | Create a Word literal expression while ensuring the given Integer is in the
-- target Word range
word8Result :: Integer -> Maybe CoreExpr
word8Result result = Just (word8Result' result)
word8Result' :: Integer -> CoreExpr
word8Result' result = Lit (mkLitWord8Wrap result)
-- | Create a Word literal expression while ensuring the given Integer is in the
-- target Word range
word16Result :: Integer -> Maybe CoreExpr
word16Result result = Just (word16Result' result)
word16Result' :: Integer -> CoreExpr
word16Result' result = Lit (mkLitWord16Wrap result)
-- | Create a Word literal expression while ensuring the given Integer is in the
-- target Word range
word32Result :: Integer -> Maybe CoreExpr
word32Result result = Just (word32Result' result)
word32Result' :: Integer -> CoreExpr
word32Result' result = Lit (mkLitWord32Wrap result)
-- | Create a Word literal expression while ensuring the given Integer is in the
-- target Word range
wordResult :: Platform -> Integer -> Maybe CoreExpr
wordResult platform result = Just (wordResult' platform result)
wordResult' :: Platform -> Integer -> CoreExpr
wordResult' platform result = Lit (mkLitWordWrap platform result)
-- | Create an unboxed pair of a Word literal expression, ensuring the given
-- Integer is in the target Word range and the corresponding carry flag
-- (@0#@/@1#@) if it wasn't.
wordCResult :: Platform -> Integer -> Maybe CoreExpr
wordCResult platform result = Just (mkPair [Lit lit, Lit c])
where
mkPair = mkCoreUbxTup [wordPrimTy, intPrimTy]
(lit, b) = mkLitWordWrapC platform result
c = if b then onei platform else zeroi platform
int64Result :: Integer -> Maybe CoreExpr
int64Result result = Just (int64Result' result)
int64Result' :: Integer -> CoreExpr
int64Result' result = Lit (mkLitInt64Wrap result)
word64Result :: Integer -> Maybe CoreExpr
word64Result result = Just (word64Result' result)
word64Result' :: Integer -> CoreExpr
word64Result' result = Lit (mkLitWord64Wrap result)
-- | 'ambiant (primop x) = x', but not nececesarily 'primop (ambient x) = x'.
semiInversePrimOp :: PrimOp -> RuleM CoreExpr
semiInversePrimOp 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
-- | Transform `extendWordN (narrowWordN x)` into `x .&. 0xFF..FF`
extendNarrowPassthrough :: PrimOp -> Integer -> RuleM CoreExpr
extendNarrowPassthrough narrow_primop n = do
[Var primop_id `App` x] <- getArgs
matchPrimOpId narrow_primop primop_id
return (Var (mkPrimOpId WordAndOp) `App` x `App` Lit (LitNumber LitNumWord n))
-- | narrow subsumes bitwise `and` with full mask (cf #16402):
--
-- narrowN (x .&. m)
-- m .&. (2^N-1) = 2^N-1
-- ==> narrowN x
--
-- e.g. narrow16 (x .&. 0xFFFF)
-- ==> narrow16 x
--
narrowSubsumesAnd :: PrimOp -> PrimOp -> Int -> RuleM CoreExpr
narrowSubsumesAnd and_primop narrw n = do
[Var primop_id `App` x `App` y] <- getArgs
matchPrimOpId and_primop primop_id
let mask = bit n -1
g v (Lit (LitNumber _ m)) = do
guard (m .&. mask == mask)
return (Var (mkPrimOpId narrw) `App` v)
g _ _ = mzero
g x y <|> g y x
idempotent :: RuleM CoreExpr
idempotent = do [e1, e2] <- getArgs
guard $ cheapEqExpr e1 e2
return e1
-- | Match
-- (op (op v e) e)
-- or (op e (op v e))
-- or (op (op e v) e)
-- or (op e (op e v))
-- and return the innermost (op v e) or (op e v).
sameArgIdempotentCommut :: PrimOp -> RuleM CoreExpr
sameArgIdempotentCommut op = do
[a,b] <- getArgs
case (a,b) of
(is_binop op -> Just (e1,e2), e3)
| cheapEqExpr e2 e3 -> return a
| cheapEqExpr e1 e3 -> return a
(e3, is_binop op -> Just (e1,e2))
| cheapEqExpr e2 e3 -> return b
| cheapEqExpr e1 e3 -> return b
_ -> mzero
{-
Note [Guarding against silly shifts]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider this code:
import Data.Bits( (.|.), shiftL )
chunkToBitmap :: [Bool] -> Word32
chunkToBitmap chunk = foldr (.|.) 0 [ 1 `shiftL` n | (True,n) <- zip chunk [0..] ]
This optimises to:
Shift.$wgo = \ (w_sCS :: GHC.Prim.Int#) (w1_sCT :: [GHC.Types.Bool]) ->
case w1_sCT of _ {
[] -> 0##;
: x_aAW xs_aAX ->
case x_aAW of _ {
GHC.Types.False ->
case w_sCS of wild2_Xh {
__DEFAULT -> Shift.$wgo (GHC.Prim.+# wild2_Xh 1) xs_aAX;
9223372036854775807 -> 0## };
GHC.Types.True ->
case GHC.Prim.>=# w_sCS 64 of _ {
GHC.Types.False ->
case w_sCS of wild3_Xh {
__DEFAULT ->
case Shift.$wgo (GHC.Prim.+# wild3_Xh 1) xs_aAX of ww_sCW { __DEFAULT ->
GHC.Prim.or# (GHC.Prim.narrow32Word#
(GHC.Prim.uncheckedShiftL# 1## wild3_Xh))
ww_sCW
};
9223372036854775807 ->
GHC.Prim.narrow32Word#
!!!!--> (GHC.Prim.uncheckedShiftL# 1## 9223372036854775807)
};
GHC.Types.True ->
case w_sCS of wild3_Xh {
__DEFAULT -> Shift.$wgo (GHC.Prim.+# wild3_Xh 1) xs_aAX;
9223372036854775807 -> 0##
} } } }
Note the massive shift on line "!!!!". It can't happen, because we've checked
that w < 64, but the optimiser didn't spot that. We DO NOT want to constant-fold this!
Moreover, if the programmer writes (n `uncheckedShiftL` 9223372036854775807), we
can't constant fold it, but if it gets to the assembler we get
Error: operand type mismatch for `shl'
So the best thing to do is to rewrite the shift with a call to error,
when the second arg is large. However, in general we cannot do this; consider
this case
let x = I# (uncheckedIShiftL# n 80)
in ...
Here x contains an invalid shift and consequently we would like to rewrite it
as follows:
let x = I# (error "invalid shift")
in ...
This was originally done in the fix to #16449 but this breaks the let/app
invariant (see Note [Core let/app invariant] in GHC.Core) as noted in #16742.
For the reasons discussed in Note [Checking versus non-checking primops] (in
the PrimOp module) there is no safe way rewrite the argument of I# such that
it bottoms.
Consequently we instead take advantage of the fact that large shifts are
undefined behavior (see associated documentation in primops.txt.pp) and
transform the invalid shift into an "obviously incorrect" value.
There are two cases:
- Shifting fixed-width things: the primops IntSll, Sll, etc
These are handled by shiftRule.
We are happy to shift by any amount up to wordSize but no more.
- Shifting Bignums (Integer, Natural): these are handled by bignum_shift.
Here we could in principle shift by any amount, but we arbitrary
limit the shift to 4 bits; in particular we do not want shift by a
huge amount, which can happen in code like that above.
The two cases are more different in their code paths that is comfortable,
but that is only a historical accident.
************************************************************************
* *
\subsection{Vaguely generic functions}
* *
************************************************************************
-}
mkBasicRule :: Name -> Int -> RuleM CoreExpr -> CoreRule
-- Gives the Rule the same name as the primop itself
mkBasicRule op_name n_args rm
= BuiltinRule { ru_name = occNameFS (nameOccName op_name),
ru_fn = op_name,
ru_nargs = n_args,
ru_try = runRuleM rm }
newtype RuleM r = RuleM
{ runRuleM :: RuleOpts -> InScopeEnv -> Id -> [CoreExpr] -> Maybe r }
deriving (Functor)
instance Applicative RuleM where
pure x = RuleM $ \_ _ _ _ -> Just x
(<*>) = ap
instance Monad RuleM where
RuleM f >>= g
= RuleM $ \env iu fn args ->
case f env iu fn args of
Nothing -> Nothing
Just r -> runRuleM (g r) env iu fn args
instance MonadFail RuleM where
fail _ = mzero
instance Alternative RuleM where
empty = RuleM $ \_ _ _ _ -> Nothing
RuleM f1 <|> RuleM f2 = RuleM $ \env iu fn args ->
f1 env iu fn args <|> f2 env iu fn args
instance MonadPlus RuleM
getPlatform :: RuleM Platform
getPlatform = roPlatform <$> getRuleOpts
getWordSize :: RuleM PlatformWordSize
getWordSize = platformWordSize <$> getPlatform
getRuleOpts :: RuleM RuleOpts
getRuleOpts = RuleM $ \rule_opts _ _ _ -> Just rule_opts
liftMaybe :: Maybe a -> RuleM a
liftMaybe Nothing = mzero
liftMaybe (Just x) = return x
liftLit :: (Literal -> Literal) -> RuleM CoreExpr
liftLit f = liftLitPlatform (const f)
liftLitPlatform :: (Platform -> Literal -> Literal) -> RuleM CoreExpr
liftLitPlatform f = do
platform <- getPlatform
[Lit lit] <- getArgs
return $ Lit (f platform lit)
removeOp32 :: RuleM CoreExpr
removeOp32 = do
platform <- getPlatform
case platformWordSize platform of
PW4 -> do
[e] <- getArgs
return e
PW8 ->
mzero
getArgs :: RuleM [CoreExpr]
getArgs = RuleM $ \_ _ _ args -> Just args
getInScopeEnv :: RuleM InScopeEnv
getInScopeEnv = RuleM $ \_ iu _ _ -> Just iu
getFunction :: RuleM Id
getFunction = RuleM $ \_ _ fn _ -> Just fn
isLiteral :: CoreExpr -> RuleM Literal
isLiteral e = do
env <- getInScopeEnv
case exprIsLiteral_maybe env e of
Nothing -> mzero
Just l -> pure l
-- | Match BigNat#, Integer and Natural literals
isBignumLiteral :: CoreExpr -> RuleM Integer
isBignumLiteral e = isNumberLiteral e <|> isIntegerLiteral e <|> isNaturalLiteral e
-- | Match numeric literals
isNumberLiteral :: CoreExpr -> RuleM Integer
isNumberLiteral e = isLiteral e >>= \case
LitNumber _ x -> pure x
_ -> mzero
-- | Match the application of a DataCon to a numeric literal.
--
-- Can be used to match e.g.:
-- IS 123#
-- IP bigNatLiteral
-- W# 123##
isLitNumConApp :: CoreExpr -> RuleM (DataCon,Integer)
isLitNumConApp e = do
env <- getInScopeEnv
case exprIsConApp_maybe env e of
Just (_env,_fb,dc,_tys,[arg]) -> case exprIsLiteral_maybe env arg of
Just (LitNumber _ i) -> pure (dc,i)
_ -> mzero
_ -> mzero
isIntegerLiteral :: CoreExpr -> RuleM Integer
isIntegerLiteral e = do
(dc,i) <- isLitNumConApp e
if | dc == integerISDataCon -> pure i
| dc == integerINDataCon -> pure (negate i)
| dc == integerIPDataCon -> pure i
| otherwise -> mzero
isBigIntegerLiteral :: CoreExpr -> RuleM Integer
isBigIntegerLiteral e = do
(dc,i) <- isLitNumConApp e
if | dc == integerINDataCon -> pure (negate i)
| dc == integerIPDataCon -> pure i
| otherwise -> mzero
isNaturalLiteral :: CoreExpr -> RuleM Integer
isNaturalLiteral e = do
(dc,i) <- isLitNumConApp e
if | dc == naturalNSDataCon -> pure i
| dc == naturalNBDataCon -> pure i
| otherwise -> mzero
-- return the n-th argument of this rule, if it is a literal
-- argument indices start from 0
getLiteral :: Int -> RuleM Literal
getLiteral n = RuleM $ \_ _ _ exprs -> case drop n exprs of
(Lit l:_) -> Just l
_ -> Nothing
unaryLit :: (RuleOpts -> Literal -> Maybe CoreExpr) -> RuleM CoreExpr
unaryLit op = do
env <- getRuleOpts
[Lit l] <- getArgs
liftMaybe $ op env (convFloating env l)
binaryLit :: (RuleOpts -> Literal -> Literal -> Maybe CoreExpr) -> RuleM CoreExpr
binaryLit op = do
env <- getRuleOpts
[Lit l1, Lit l2] <- getArgs
liftMaybe $ op env (convFloating env l1) (convFloating env l2)
binaryCmpLit :: (forall a . Ord a => a -> a -> Bool) -> RuleM CoreExpr
binaryCmpLit op = do
platform <- getPlatform
binaryLit (\_ -> cmpOp platform op)
leftIdentity :: Literal -> RuleM CoreExpr
leftIdentity id_lit = leftIdentityPlatform (const id_lit)
rightIdentity :: Literal -> RuleM CoreExpr
rightIdentity id_lit = rightIdentityPlatform (const id_lit)
identity :: Literal -> RuleM CoreExpr
identity lit = leftIdentity lit `mplus` rightIdentity lit
leftIdentityPlatform :: (Platform -> Literal) -> RuleM CoreExpr
leftIdentityPlatform id_lit = do
platform <- getPlatform
[Lit l1, e2] <- getArgs
guard $ l1 == id_lit platform
return e2
-- | Left identity rule for PrimOps like 'IntAddC' and 'WordAddC', where, in
-- addition to the result, we have to indicate that no carry/overflow occurred.
leftIdentityCPlatform :: (Platform -> Literal) -> RuleM CoreExpr
leftIdentityCPlatform id_lit = do
platform <- getPlatform
[Lit l1, e2] <- getArgs
guard $ l1 == id_lit platform
let no_c = Lit (zeroi platform)
return (mkCoreUbxTup [exprType e2, intPrimTy] [e2, no_c])
rightIdentityPlatform :: (Platform -> Literal) -> RuleM CoreExpr
rightIdentityPlatform id_lit = do
platform <- getPlatform
[e1, Lit l2] <- getArgs
guard $ l2 == id_lit platform
return e1
-- | Right identity rule for PrimOps like 'IntSubC' and 'WordSubC', where, in
-- addition to the result, we have to indicate that no carry/overflow occurred.
rightIdentityCPlatform :: (Platform -> Literal) -> RuleM CoreExpr
rightIdentityCPlatform id_lit = do
platform <- getPlatform
[e1, Lit l2] <- getArgs
guard $ l2 == id_lit platform
let no_c = Lit (zeroi platform)
return (mkCoreUbxTup [exprType e1, intPrimTy] [e1, no_c])
identityPlatform :: (Platform -> Literal) -> RuleM CoreExpr
identityPlatform lit =
leftIdentityPlatform lit `mplus` rightIdentityPlatform lit
-- | Identity rule for PrimOps like 'IntAddC' and 'WordAddC', where, in addition
-- to the result, we have to indicate that no carry/overflow occurred.
identityCPlatform :: (Platform -> Literal) -> RuleM CoreExpr
identityCPlatform lit =
leftIdentityCPlatform lit `mplus` rightIdentityCPlatform lit
leftZero :: RuleM CoreExpr
leftZero = do
[Lit l1, _] <- getArgs
guard $ isZeroLit l1
return $ Lit l1
rightZero :: RuleM CoreExpr
rightZero = do
[_, Lit l2] <- getArgs
guard $ isZeroLit l2
return $ Lit l2
zeroElem :: RuleM CoreExpr
zeroElem = leftZero `mplus` rightZero
equalArgs :: RuleM ()
equalArgs = do
[e1, e2] <- getArgs
guard $ e1 `cheapEqExpr` e2
nonZeroLit :: Int -> RuleM ()
nonZeroLit n = getLiteral n >>= guard . not . isZeroLit
oneLit :: Int -> RuleM ()
oneLit n = getLiteral n >>= guard . isOneLit
lift_bits_op :: forall a. (Num a, FiniteBits a) => (a -> Integer) -> RuleM CoreExpr
lift_bits_op op = do
platform <- getPlatform
[Lit (LitNumber _ l)] <- getArgs
pure $ mkWordLit platform $ op (fromInteger l :: a)
pop_count :: forall a. (Num a, FiniteBits a) => RuleM CoreExpr
pop_count = lift_bits_op @a (fromIntegral . popCount)
ctz :: forall a. (Num a, FiniteBits a) => RuleM CoreExpr
ctz = lift_bits_op @a (fromIntegral . countTrailingZeros)
clz :: forall a. (Num a, FiniteBits a) => RuleM CoreExpr
clz = lift_bits_op @a (fromIntegral . countLeadingZeros)
-- When excess precision is not requested, cut down the precision of the
-- Rational value to that of Float/Double. We confuse host architecture
-- and target architecture here, but it's convenient (and wrong :-).
convFloating :: RuleOpts -> Literal -> Literal
convFloating env (LitFloat f) | not (roExcessRationalPrecision env) =
LitFloat (toRational (fromRational f :: Float ))
convFloating env (LitDouble d) | not (roExcessRationalPrecision env) =
LitDouble (toRational (fromRational d :: Double))
convFloating _ l = l
guardFloatDiv :: RuleM ()
guardFloatDiv = do
[Lit (LitFloat f1), Lit (LitFloat f2)] <- getArgs
guard $ (f1 /=0 || f2 > 0) -- see Note [negative zero]
&& f2 /= 0 -- avoid NaN and Infinity/-Infinity
guardDoubleDiv :: RuleM ()
guardDoubleDiv = do
[Lit (LitDouble d1), Lit (LitDouble d2)] <- getArgs
guard $ (d1 /=0 || d2 > 0) -- see Note [negative zero]
&& d2 /= 0 -- avoid NaN and Infinity/-Infinity
-- Note [negative zero] Avoid (0 / -d), otherwise 0/(-1) reduces to
-- zero, but we might want to preserve the negative zero here which
-- is representable in Float/Double but not in (normalised)
-- Rational. (#3676) Perhaps we should generate (0 :% (-1)) instead?
strengthReduction :: Literal -> PrimOp -> RuleM CoreExpr
strengthReduction two_lit add_op = do -- Note [Strength reduction]
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
-- Note [Strength reduction]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- This rule turns floating point multiplications of the form 2.0 * x and
-- x * 2.0 into x + x addition, because addition costs less than multiplication.
-- See #7116
-- Note [What's true and false]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- trueValInt and falseValInt represent true and false values returned by
-- comparison primops for Char, Int, Word, Integer, Double, Float and Addr.
-- True is represented as an unboxed 1# literal, while false is represented
-- as 0# literal.
-- We still need Bool data constructors (True and False) to use in a rule
-- for constant folding of equal Strings
trueValInt, falseValInt :: Platform -> Expr CoreBndr
trueValInt platform = Lit $ onei platform -- see Note [What's true and false]
falseValInt platform = Lit $ zeroi platform
trueValBool, falseValBool :: Expr CoreBndr
trueValBool = Var trueDataConId -- see Note [What's true and false]
falseValBool = Var falseDataConId
ltVal, eqVal, gtVal :: Expr CoreBndr
ltVal = Var ordLTDataConId
eqVal = Var ordEQDataConId
gtVal = Var ordGTDataConId
mkIntVal :: Platform -> Integer -> Expr CoreBndr
mkIntVal platform i = Lit (mkLitInt platform i)
mkFloatVal :: RuleOpts -> Rational -> Expr CoreBndr
mkFloatVal env f = Lit (convFloating env (LitFloat f))
mkDoubleVal :: RuleOpts -> Rational -> Expr CoreBndr
mkDoubleVal env d = Lit (convFloating env (LitDouble d))
matchPrimOpId :: PrimOp -> Id -> RuleM ()
matchPrimOpId op id = do
op' <- liftMaybe $ isPrimOpId_maybe id
guard $ op == op'
{-
************************************************************************
* *
\subsection{Special rules for seq, tagToEnum, dataToTag}
* *
************************************************************************
Note [tagToEnum#]
~~~~~~~~~~~~~~~~~
Nasty check to ensure that tagToEnum# is applied to a type that is an
enumeration TyCon. Unification may refine the type later, but this
check won't see that, alas. It's crude but it works.
Here's are two cases that should fail
f :: forall a. a
f = tagToEnum# 0 -- Can't do tagToEnum# at a type variable
g :: Int
g = tagToEnum# 0 -- Int is not an enumeration
We used to make this check in the type inference engine, but it's quite
ugly to do so, because the delayed constraint solving means that we don't
really know what's going on until the end. It's very much a corner case
because we don't expect the user to call tagToEnum# at all; we merely
generate calls in derived instances of Enum. So we compromise: a
rewrite rule rewrites a bad instance of tagToEnum# to an error call,
and emits a warning.
-}
tagToEnumRule :: RuleM CoreExpr
-- If data T a = A | B | C
-- then tagToEnum# (T ty) 2# --> B ty
tagToEnumRule = do
[Type ty, Lit (LitNumber LitNumInt i)] <- getArgs
case splitTyConApp_maybe ty of
Just (tycon, tc_args) | isEnumerationTyCon tycon -> do
let tag = fromInteger i
correct_tag dc = (dataConTagZ dc) == tag
(dc:rest) <- return $ filter correct_tag (tyConDataCons_maybe tycon `orElse` [])
massert (null rest)
return $ mkTyApps (Var (dataConWorkId dc)) tc_args
-- See Note [tagToEnum#]
_ -> warnPprTrace True (text "tagToEnum# on non-enumeration type" <+> ppr ty) $
return $ mkRuntimeErrorApp rUNTIME_ERROR_ID ty "tagToEnum# on non-enumeration type"
------------------------------
dataToTagRule :: RuleM CoreExpr
-- See Note [dataToTag#] in primops.txt.pp
dataToTagRule = a `mplus` b
where
-- dataToTag (tagToEnum x) ==> x
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
-- dataToTag (K e1 e2) ==> tag-of K
-- This also works (via exprIsConApp_maybe) for
-- dataToTag x
-- where x's unfolding is a constructor application
b = do
dflags <- getPlatform
[_, val_arg] <- getArgs
in_scope <- getInScopeEnv
(_,floats, dc,_,_) <- liftMaybe $ exprIsConApp_maybe in_scope val_arg
massert (not (isNewTyCon (dataConTyCon dc)))
return $ wrapFloats floats (mkIntVal dflags (toInteger (dataConTagZ dc)))
{- Note [dataToTag# magic]
~~~~~~~~~~~~~~~~~~~~~~~~~~
The primop dataToTag# is unusual because it evaluates its argument.
Only `SeqOp` shares that property. (Other primops do not do anything
as fancy as argument evaluation.) The special handling for dataToTag#
is:
* GHC.Core.Utils.exprOkForSpeculation has a special case for DataToTagOp,
(actually in app_ok). Most primops with lifted arguments do not
evaluate those arguments, but DataToTagOp and SeqOp are two
exceptions. We say that they are /never/ ok-for-speculation,
regardless of the evaluated-ness of their argument.
See GHC.Core.Utils Note [exprOkForSpeculation and SeqOp/DataToTagOp]
* There is a special case for DataToTagOp in GHC.StgToCmm.Expr.cgExpr,
that evaluates its argument and then extracts the tag from
the returned value.
* An application like (dataToTag# (Just x)) is optimised by
dataToTagRule in GHC.Core.Opt.ConstantFold.
* A case expression like
case (dataToTag# e) of <alts>
gets transformed t
case e of <transformed alts>
by GHC.Core.Opt.ConstantFold.caseRules; see Note [caseRules for dataToTag]
See #15696 for a long saga.
-}
{- *********************************************************************
* *
unsafeEqualityProof
* *
********************************************************************* -}
-- unsafeEqualityProof k t t ==> UnsafeRefl (Refl t)
-- That is, if the two types are equal, it's not unsafe!
unsafeEqualityProofRule :: RuleM CoreExpr
unsafeEqualityProofRule
= do { [Type rep, Type t1, Type t2] <- getArgs
; guard (t1 `eqType` t2)
; fn <- getFunction
; let (_, ue) = splitForAllTyCoVars (idType fn)
tc = tyConAppTyCon ue -- tycon: UnsafeEquality
(dc:_) = tyConDataCons tc -- data con: UnsafeRefl
-- UnsafeRefl :: forall (r :: RuntimeRep) (a :: TYPE r).
-- UnsafeEquality r a a
; return (mkTyApps (Var (dataConWrapId dc)) [rep, t1]) }
{- *********************************************************************
* *
Rules for seq# and spark#
* *
********************************************************************* -}
{- Note [seq# magic]
~~~~~~~~~~~~~~~~~~~~
The primop
seq# :: forall a s . a -> State# s -> (# State# s, a #)
is /not/ the same as the Prelude function seq :: a -> b -> b
as you can see from its type. In fact, seq# is the implementation
mechanism for 'evaluate'
evaluate :: a -> IO a
evaluate a = IO $ \s -> seq# a s
The semantics of seq# is
* evaluate its first argument
* and return it
Things to note
* Why do we need a primop at all? That is, instead of
case seq# x s of (# x, s #) -> blah
why not instead say this?
case x of { DEFAULT -> blah)
Reason (see #5129): if we saw
catch# (\s -> case x of { DEFAULT -> raiseIO# exn s }) handler
then we'd drop the 'case x' because the body of the case is bottom
anyway. But we don't want to do that; the whole /point/ of
seq#/evaluate is to evaluate 'x' first in the IO monad.
In short, we /always/ evaluate the first argument and never
just discard it.
* Why return the value? So that we can control sharing of seq'd
values: in
let x = e in x `seq` ... x ...
We don't want to inline x, so better to represent it as
let x = e in case seq# x RW of (# _, x' #) -> ... x' ...
also it matches the type of rseq in the Eval monad.
Implementing seq#. The compiler has magic for SeqOp in
- GHC.Core.Opt.ConstantFold.seqRule: eliminate (seq# <whnf> s)
- GHC.StgToCmm.Expr.cgExpr, and cgCase: special case for seq#
- GHC.Core.Utils.exprOkForSpeculation;
see Note [exprOkForSpeculation and SeqOp/DataToTagOp] in GHC.Core.Utils
- Simplify.addEvals records evaluated-ness for the result; see
Note [Adding evaluatedness info to pattern-bound variables]
in GHC.Core.Opt.Simplify
-}
seqRule :: RuleM CoreExpr
seqRule = do
[Type ty_a, Type _ty_s, a, s] <- getArgs
guard $ exprIsHNF a
return $ mkCoreUbxTup [exprType s, ty_a] [s, a]
-- spark# :: forall a s . a -> State# s -> (# State# s, a #)
sparkRule :: RuleM CoreExpr
sparkRule = seqRule -- reduce on HNF, just the same
-- XXX perhaps we shouldn't do this, because a spark eliminated by
-- this rule won't be counted as a dud at runtime?
{-
************************************************************************
* *
\subsection{Built in rules}
* *
************************************************************************
Note [Scoping for Builtin rules]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When compiling a (base-package) module that defines one of the
functions mentioned in the RHS of a built-in rule, there's a danger
that we'll see
f = ...(eq String x)....
....and lower down...
eqString = ...
Then a rewrite would give
f = ...(eqString x)...
....and lower down...
eqString = ...
and lo, eqString is not in scope. This only really matters when we
get to code generation. But the occurrence analyser does a GlomBinds
step when necessary, that does a new SCC analysis on the whole set of
bindings (see occurAnalysePgm), which sorts out the dependency, so all
is fine.
-}
builtinRules :: [CoreRule]
-- Rules for non-primops that can't be expressed using a RULE pragma
builtinRules
= [BuiltinRule { ru_name = fsLit "CStringFoldrLit",
ru_fn = unpackCStringFoldrName,
ru_nargs = 4, ru_try = match_cstring_foldr_lit_C },
BuiltinRule { ru_name = fsLit "CStringFoldrLitUtf8",
ru_fn = unpackCStringFoldrUtf8Name,
ru_nargs = 4, ru_try = match_cstring_foldr_lit_utf8 },
BuiltinRule { ru_name = fsLit "CStringAppendLit",
ru_fn = unpackCStringAppendName,
ru_nargs = 2, ru_try = match_cstring_append_lit_C },
BuiltinRule { ru_name = fsLit "CStringAppendLitUtf8",
ru_fn = unpackCStringAppendUtf8Name,
ru_nargs = 2, ru_try = match_cstring_append_lit_utf8 },
BuiltinRule { ru_name = fsLit "EqString", ru_fn = eqStringName,
ru_nargs = 2, ru_try = match_eq_string },
BuiltinRule { ru_name = fsLit "CStringLength", ru_fn = cstringLengthName,
ru_nargs = 1, ru_try = match_cstring_length },
BuiltinRule { ru_name = fsLit "Inline", ru_fn = inlineIdName,
ru_nargs = 2, ru_try = \_ _ _ -> match_inline },
mkBasicRule unsafeEqualityProofName 3 unsafeEqualityProofRule,
mkBasicRule divIntName 2 $ msum
[ nonZeroLit 1 >> binaryLit (intOp2 div)
, leftZero
, do
[arg, Lit (LitNumber LitNumInt d)] <- getArgs
Just n <- return $ exactLog2 d
platform <- getPlatform
return $ Var (mkPrimOpId IntSraOp) `App` arg `App` mkIntVal platform n
],
mkBasicRule modIntName 2 $ msum
[ nonZeroLit 1 >> binaryLit (intOp2 mod)
, leftZero
, do
[arg, Lit (LitNumber LitNumInt d)] <- getArgs
Just _ <- return $ exactLog2 d
platform <- getPlatform
return $ Var (mkPrimOpId IntAndOp)
`App` arg `App` mkIntVal platform (d - 1)
]
]
++ builtinBignumRules
{-# NOINLINE builtinRules #-}
-- there is no benefit to inlining these yet, despite this, GHC produces
-- unfoldings for this regardless since the floated list entries look small.
builtinBignumRules :: [CoreRule]
builtinBignumRules =
[ -- conversions
lit_to_integer "Word# -> Integer" integerFromWordName
, lit_to_integer "Int64# -> Integer" integerFromInt64Name
, lit_to_integer "Word64# -> Integer" integerFromWord64Name
, lit_to_integer "Natural -> Integer" integerFromNaturalName
, integer_to_lit "Integer -> Word# (wrap)" integerToWordName mkWordLitWrap
, integer_to_lit "Integer -> Int# (wrap)" integerToIntName mkIntLitWrap
, integer_to_lit "Integer -> Word64# (wrap)" integerToWord64Name (\_ -> mkWord64LitWord64 . fromInteger)
, integer_to_lit "Integer -> Int64# (wrap)" integerToInt64Name (\_ -> mkInt64LitInt64 . fromInteger)
, integer_to_lit "Integer -> Float#" integerToFloatName (\_ -> mkFloatLitFloat . fromInteger)
, integer_to_lit "Integer -> Double#" integerToDoubleName (\_ -> mkDoubleLitDouble . fromInteger)
, integer_to_natural "Integer -> Natural (clamp)" integerToNaturalClampName False True
, integer_to_natural "Integer -> Natural (wrap)" integerToNaturalName False False
, integer_to_natural "Integer -> Natural (throw)" integerToNaturalThrowName True False
, natural_to_word "Natural -> Word# (wrap)" naturalToWordName
-- comparisons (return an unlifted Int#)
, bignum_bin_pred "bigNatEq#" bignatEqName (==)
-- comparisons (return an Ordering)
, bignum_compare "bignatCompare" bignatCompareName
, bignum_compare "bignatCompareWord#" bignatCompareWordName
-- binary operations
, integer_binop "integerAdd" integerAddName (+)
, integer_binop "integerSub" integerSubName (-)
, integer_binop "integerMul" integerMulName (*)
, integer_binop "integerGcd" integerGcdName gcd
, integer_binop "integerLcm" integerLcmName lcm
, integer_binop "integerAnd" integerAndName (.&.)
, integer_binop "integerOr" integerOrName (.|.)
, integer_binop "integerXor" integerXorName xor
, natural_binop "naturalAdd" naturalAddName (+)
, natural_binop "naturalMul" naturalMulName (*)
, natural_binop "naturalGcd" naturalGcdName gcd
, natural_binop "naturalLcm" naturalLcmName lcm
, natural_binop "naturalAnd" naturalAndName (.&.)
, natural_binop "naturalOr" naturalOrName (.|.)
, natural_binop "naturalXor" naturalXorName xor
-- Natural subtraction: it's a binop but it can fail because of underflow so
-- we have several primitives to handle here.
, natural_sub "naturalSubUnsafe" naturalSubUnsafeName
, natural_sub "naturalSubThrow" naturalSubThrowName
, mkRule "naturalSub" naturalSubName 2 $ do
[a0,a1] <- getArgs
x <- isNaturalLiteral a0
y <- isNaturalLiteral a1
-- return an unboxed sum: (# (# #) | Natural #)
let ret n v = pure $ mkCoreUbxSum 2 n [unboxedUnitTy,naturalTy] v
platform <- getPlatform
if x < y
then ret 1 $ Var voidPrimId
else ret 2 $ mkNaturalExpr platform (x - y)
-- unary operations
, bignum_unop "integerNegate" integerNegateName mkIntegerExpr negate
, bignum_unop "integerAbs" integerAbsName mkIntegerExpr abs
, bignum_unop "integerComplement" integerComplementName mkIntegerExpr complement
, bignum_popcount "integerPopCount" integerPopCountName mkLitIntWrap
, bignum_popcount "naturalPopCount" naturalPopCountName mkLitWordWrap
-- Bits.bit
, bignum_bit "integerBit" integerBitName mkIntegerExpr
, bignum_bit "naturalBit" naturalBitName mkNaturalExpr
-- Bits.testBit
, bignum_testbit "integerTestBit" integerTestBitName
, bignum_testbit "naturalTestBit" naturalTestBitName
-- Bits.shift
, bignum_shift "integerShiftL" integerShiftLName shiftL mkIntegerExpr
, bignum_shift "integerShiftR" integerShiftRName shiftR mkIntegerExpr
, bignum_shift "naturalShiftL" naturalShiftLName shiftL mkNaturalExpr
, bignum_shift "naturalShiftR" naturalShiftRName shiftR mkNaturalExpr
-- division
, divop_one "integerQuot" integerQuotName quot mkIntegerExpr
, divop_one "integerRem" integerRemName rem mkIntegerExpr
, divop_one "integerDiv" integerDivName div mkIntegerExpr
, divop_one "integerMod" integerModName mod mkIntegerExpr
, divop_both "integerDivMod" integerDivModName divMod mkIntegerExpr integerTy
, divop_both "integerQuotRem" integerQuotRemName quotRem mkIntegerExpr integerTy
, divop_one "naturalQuot" naturalQuotName quot mkNaturalExpr
, divop_one "naturalRem" naturalRemName rem mkNaturalExpr
, divop_both "naturalQuotRem" naturalQuotRemName quotRem mkNaturalExpr naturalTy
-- conversions from Rational for Float/Double literals
, rational_to "rationalToFloat" rationalToFloatName mkFloatExpr
, rational_to "rationalToDouble" rationalToDoubleName mkDoubleExpr
-- conversions from Integer for Float/Double literals
, integer_encode_float "integerEncodeFloat" integerEncodeFloatName mkFloatLitFloat
, integer_encode_float "integerEncodeDouble" integerEncodeDoubleName mkDoubleLitDouble
]
where
mkRule str name nargs f = BuiltinRule
{ ru_name = fsLit str
, ru_fn = name
, ru_nargs = nargs
, ru_try = runRuleM $ do
env <- getRuleOpts
guard (roBignumRules env)
f
}
integer_to_lit str name convert = mkRule str name 1 $ do
[a0] <- getArgs
platform <- getPlatform
-- we only match on Big Integer literals. Small literals
-- are matched by the "Int# -> Integer -> *" rules
x <- isBigIntegerLiteral a0
pure (convert platform x)
natural_to_word str name = mkRule str name 1 $ do
[a0] <- getArgs
n <- isNaturalLiteral a0
platform <- getPlatform
pure (Lit (mkLitWordWrap platform n))
integer_to_natural str name thrw clamp = mkRule str name 1 $ do
[a0] <- getArgs
x <- isIntegerLiteral a0
platform <- getPlatform
if | x >= 0 -> pure $ mkNaturalExpr platform x
| thrw -> mzero
| clamp -> pure $ mkNaturalExpr platform 0 -- clamp to 0
| otherwise -> pure $ mkNaturalExpr platform (abs x) -- negate/wrap
lit_to_integer str name = mkRule str name 1 $ do
[a0] <- getArgs
platform <- getPlatform
i <- isBignumLiteral a0
-- convert any numeric literal into an Integer literal
pure (mkIntegerExpr platform i)
integer_binop str name op = mkRule str name 2 $ do
[a0,a1] <- getArgs
x <- isIntegerLiteral a0
y <- isIntegerLiteral a1
platform <- getPlatform
pure (mkIntegerExpr platform (x `op` y))
natural_binop str name op = mkRule str name 2 $ do
[a0,a1] <- getArgs
x <- isNaturalLiteral a0
y <- isNaturalLiteral a1
platform <- getPlatform
pure (mkNaturalExpr platform (x `op` y))
natural_sub str name = mkRule str name 2 $ do
[a0,a1] <- getArgs
x <- isNaturalLiteral a0
y <- isNaturalLiteral a1
guard (x >= y)
platform <- getPlatform
pure (mkNaturalExpr platform (x - y))
bignum_bin_pred str name op = mkRule str name 2 $ do
platform <- getPlatform
[a0,a1] <- getArgs
x <- isBignumLiteral a0
y <- isBignumLiteral a1
pure $ if x `op` y
then trueValInt platform
else falseValInt platform
bignum_compare str name = mkRule str name 2 $ do
[a0,a1] <- getArgs
x <- isBignumLiteral a0
y <- isBignumLiteral a1
pure $ case x `compare` y of
LT -> ltVal
EQ -> eqVal
GT -> gtVal
bignum_unop str name mk_lit op = mkRule str name 1 $ do
[a0] <- getArgs
x <- isBignumLiteral a0
platform <- getPlatform
pure $ mk_lit platform (op x)
bignum_popcount str name mk_lit = mkRule str name 1 $ do
platform <- getPlatform
-- We use a host Int to compute the popCount. If we compile on a 32-bit
-- host for a 64-bit target, the result may be different than if computed
-- by the target. So we disable this rule if sizes don't match.
guard (platformWordSizeInBits platform == finiteBitSize (0 :: Word))
[a0] <- getArgs
x <- isBignumLiteral a0
pure $ Lit (mk_lit platform (fromIntegral (popCount x)))
bignum_bit str name mk_lit = mkRule str name 1 $ do
[a0] <- getArgs
platform <- getPlatform
n <- isNumberLiteral a0
-- Make sure n is positive and small enough to yield a decently
-- small number. Attempting to construct the Integer for
-- (integerBit 9223372036854775807#)
-- would be a bad idea (#14959)
guard (n >= 0 && n <= fromIntegral (platformWordSizeInBits platform))
-- it's safe to convert a target Int value into a host Int value
-- to perform the "bit" operation because n is very small (<= 64).
pure $ mk_lit platform (bit (fromIntegral n))
bignum_testbit str name = mkRule str name 2 $ do
[a0,a1] <- getArgs
platform <- getPlatform
x <- isBignumLiteral a0
n <- isNumberLiteral a1
-- ensure that we can store 'n' in a host Int
guard (n >= 0 && n <= fromIntegral (maxBound :: Int))
pure $ if testBit x (fromIntegral n)
then trueValInt platform
else falseValInt platform
bignum_shift str name shift_op mk_lit = mkRule str name 2 $ do
[a0,a1] <- getArgs
x <- isBignumLiteral a0
n <- isNumberLiteral a1
-- See Note [Guarding against silly shifts]
-- Restrict constant-folding of shifts on Integers, somewhat arbitrary.
-- We can get huge shifts in inaccessible code (#15673)
guard (n <= 4)
platform <- getPlatform
pure $ mk_lit platform (x `shift_op` fromIntegral n)
divop_one str name divop mk_lit = mkRule str name 2 $ do
[a0,a1] <- getArgs
n <- isBignumLiteral a0
d <- isBignumLiteral a1
guard (d /= 0)
platform <- getPlatform
pure $ mk_lit platform (n `divop` d)
divop_both str name divop mk_lit ty = mkRule str name 2 $ do
[a0,a1] <- getArgs
n <- isBignumLiteral a0
d <- isBignumLiteral a1
guard (d /= 0)
let (r,s) = n `divop` d
platform <- getPlatform
pure $ mkCoreUbxTup [ty,ty] [mk_lit platform r, mk_lit platform s]
integer_encode_float :: RealFloat a => String -> Name -> (a -> CoreExpr) -> CoreRule
integer_encode_float str name mk_lit = mkRule str name 2 $ do
[a0,a1] <- getArgs
x <- isIntegerLiteral a0
y <- isNumberLiteral a1
-- check that y (a target Int) is in the host Int range
guard (y <= fromIntegral (maxBound :: Int))
pure (mk_lit $ encodeFloat x (fromInteger y))
rational_to :: RealFloat a => String -> Name -> (a -> CoreExpr) -> CoreRule
rational_to str name mk_lit = mkRule str name 2 $ do
-- This turns `rationalToFloat n d` where `n` and `d` are literals into
-- a literal Float (and similarly for Double).
[a0,a1] <- getArgs
n <- isIntegerLiteral a0
d <- isIntegerLiteral a1
-- it's important to not match d == 0, because that may represent a
-- literal "0/0" or similar, and we can't produce a literal value for
-- NaN or +-Inf
guard (d /= 0)
pure $ mk_lit (fromRational (n % d))
---------------------------------------------------
-- The rules are:
-- unpackAppendCString*# "foo"# (unpackCString*# "baz"#)
-- = unpackCString*# "foobaz"#
--
-- unpackAppendCString*# "foo"# (unpackAppendCString*# "baz"# e)
-- = unpackAppendCString*# "foobaz"# e
--
-- CString version
match_cstring_append_lit_C :: RuleFun
match_cstring_append_lit_C = match_cstring_append_lit unpackCStringAppendIdKey unpackCStringIdKey
-- CStringUTF8 version
match_cstring_append_lit_utf8 :: RuleFun
match_cstring_append_lit_utf8 = match_cstring_append_lit unpackCStringAppendUtf8IdKey unpackCStringUtf8IdKey
{-# INLINE match_cstring_append_lit #-}
match_cstring_append_lit :: Unique -> Unique -> RuleFun
match_cstring_append_lit append_key unpack_key _ env _ [lit1, e2]
| Just (LitString s1) <- exprIsLiteral_maybe env lit1
, (strTicks, Var unpk `App` lit2) <- stripStrTopTicks env e2
, unpk `hasKey` unpack_key
, Just (LitString s2) <- exprIsLiteral_maybe env lit2
= Just $ mkTicks strTicks
$ Var unpk `App` Lit (LitString (s1 `BS.append` s2))
| Just (LitString s1) <- exprIsLiteral_maybe env lit1
, (strTicks, Var appnd `App` lit2 `App` e) <- stripStrTopTicks env e2
, appnd `hasKey` append_key
, Just (LitString s2) <- exprIsLiteral_maybe env lit2
= Just $ mkTicks strTicks
$ Var appnd `App` Lit (LitString (s1 `BS.append` s2)) `App` e
match_cstring_append_lit _ _ _ _ _ _ = Nothing
---------------------------------------------------
-- The rule is this:
-- unpackFoldrCString*# "foo"# c (unpackFoldrCString*# "baz"# c n)
-- = unpackFoldrCString*# "foobaz"# c n
--
-- See also Note [String literals in GHC] in CString.hs
-- CString version
match_cstring_foldr_lit_C :: RuleFun
match_cstring_foldr_lit_C = match_cstring_foldr_lit unpackCStringFoldrIdKey
-- CStringUTF8 version
match_cstring_foldr_lit_utf8 :: RuleFun
match_cstring_foldr_lit_utf8 = match_cstring_foldr_lit unpackCStringFoldrUtf8IdKey
{-# INLINE match_cstring_foldr_lit #-}
match_cstring_foldr_lit :: Unique -> RuleFun
match_cstring_foldr_lit foldVariant _ env _
[ Type ty1
, lit1
, c1
, e2
]
| (strTicks, Var unpk `App` Type ty2
`App` lit2
`App` c2
`App` n) <- stripStrTopTicks env e2
, unpk `hasKey` foldVariant
, Just (LitString s1) <- exprIsLiteral_maybe env lit1
, Just (LitString s2) <- exprIsLiteral_maybe env lit2
, eqCoreExpr c1 c2
, (c1Ticks, c1') <- stripStrTopTicks env c1
, c2Ticks <- stripStrTopTicksT c2
= assert (ty1 `eqType` ty2) $
Just $ mkTicks strTicks
$ Var unpk `App` Type ty1
`App` Lit (LitString (s1 `BS.append` s2))
`App` mkTicks (c1Ticks ++ c2Ticks) c1'
`App` n
match_cstring_foldr_lit _ _ _ _ _ = Nothing
-- N.B. Ensure that we strip off any ticks (e.g. source notes) from the
-- argument, lest this may fail to fire when building with -g3. See #16740.
--
-- Also, look into variable's unfolding just in case the expression we look for
-- is in a top-level thunk.
stripStrTopTicks :: InScopeEnv -> CoreExpr -> ([CoreTickish], CoreExpr)
stripStrTopTicks (_,id_unf) e = case e of
Var v
| Just rhs <- expandUnfolding_maybe (id_unf v)
-> stripTicksTop tickishFloatable rhs
_ -> stripTicksTop tickishFloatable e
stripStrTopTicksT :: CoreExpr -> [CoreTickish]
stripStrTopTicksT e = stripTicksTopT tickishFloatable e
---------------------------------------------------
-- The rule is this:
-- eqString (unpackCString# (Lit s1)) (unpackCString# (Lit s2)) = s1==s2
-- Also matches unpackCStringUtf8#
match_eq_string :: RuleFun
match_eq_string _ env _ [e1, e2]
| (ticks1, Var unpk1 `App` lit1) <- stripStrTopTicks env e1
, (ticks2, Var unpk2 `App` lit2) <- stripStrTopTicks env e2
, unpk_key1 <- getUnique unpk1
, unpk_key2 <- getUnique unpk2
, unpk_key1 == unpk_key2
-- For now we insist the literals have to agree in their encoding
-- to keep the rule simple. But we could check if the decoded strings
-- compare equal in here as well.
, unpk_key1 `elem` [unpackCStringUtf8IdKey, unpackCStringIdKey]
, Just (LitString s1) <- exprIsLiteral_maybe env lit1
, Just (LitString s2) <- exprIsLiteral_maybe env lit2
= Just $ mkTicks (ticks1 ++ ticks2)
$ (if s1 == s2 then trueValBool else falseValBool)
match_eq_string _ _ _ _ = Nothing
-----------------------------------------------------------------------
-- Illustration of this rule:
--
-- cstringLength# "foobar"# --> 6
-- cstringLength# "fizz\NULzz"# --> 4
--
-- Nota bene: Addr# literals are suffixed by a NUL byte when they are
-- compiled to read-only data sections. That's why cstringLength# is
-- well defined on Addr# literals that do not explicitly have an embedded
-- NUL byte.
--
-- See GHC issue #5218, MR 2165, and bytestring PR 191. This is particularly
-- helpful when using OverloadedStrings to create a ByteString since the
-- function computing the length of such ByteStrings can often be constant
-- folded.
match_cstring_length :: RuleFun
match_cstring_length rule_env env _ [lit1]
| Just (LitString str) <- exprIsLiteral_maybe env lit1
-- If elemIndex returns Just, it has the index of the first embedded NUL
-- in the string. If no NUL bytes are present (the common case) then use
-- full length of the byte string.
= let len = fromMaybe (BS.length str) (BS.elemIndex 0 str)
in Just (Lit (mkLitInt (roPlatform rule_env) (fromIntegral len)))
match_cstring_length _ _ _ _ = Nothing
---------------------------------------------------
{- Note [inlineId magic]
~~~~~~~~~~~~~~~~~~~~~~~~
The call 'inline f' arranges that 'f' is inlined, regardless of
its size. More precisely, the call 'inline f' rewrites to the
right-hand side of 'f's definition. This allows the programmer to
control inlining from a particular call site rather than the
definition site of the function.
The moving parts are simple:
* A very simple definition in the library base:GHC.Magic
{-# NOINLINE[0] inline #-}
inline :: a -> a
inline x = x
So in phase 0, 'inline' will be inlined, so its use imposes
no overhead.
* A rewrite rule, in GHC.Core.Opt.ConstantFold, which makes
(inline f) inline, implemented by match_inline.
The rule for the 'inline' function is this:
inline f_ty (f a b c) = <f's unfolding> a b c
(if f has an unfolding, EVEN if it's a loop breaker)
It's important to allow the argument to 'inline' to have args itself
(a) because its more forgiving to allow the programmer to write
either inline f a b c
or inline (f a b c)
(b) because a polymorphic f wll get a type argument that the
programmer can't avoid, so the call may look like
inline (map @Int @Bool) g xs
Also, don't forget about 'inline's type argument!
-}
match_inline :: [Expr CoreBndr] -> Maybe (Expr CoreBndr)
match_inline (Type _ : e : _)
| (Var f, args1) <- collectArgs e,
Just unf <- maybeUnfoldingTemplate (realIdUnfolding f)
-- Ignore the IdUnfoldingFun here!
= Just (mkApps unf args1)
match_inline _ = Nothing
--------------------------------------------------------
-- Note [Constant folding through nested expressions]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- We use rewrites rules to perform constant folding. It means that we don't
-- have a global view of the expression we are trying to optimise. As a
-- consequence we only perform local (small-step) transformations that either:
-- 1) reduce the number of operations
-- 2) rearrange the expression to increase the odds that other rules will
-- match
--
-- We don't try to handle more complex expression optimisation cases that would
-- require a global view. For example, rewriting expressions to increase
-- sharing (e.g., Horner's method); optimisations that require local
-- transformations increasing the number of operations; rearrangements to
-- cancel/factorize terms (e.g., (a+b-a-b) isn't rearranged to reduce to 0).
--
-- We already have rules to perform constant folding on expressions with the
-- following shape (where a and/or b are literals):
--
-- D) op
-- /\
-- / \
-- / \
-- a b
--
-- To support nested expressions, we match three other shapes of expression
-- trees:
--
-- A) op1 B) op1 C) op1
-- /\ /\ /\
-- / \ / \ / \
-- / \ / \ / \
-- a op2 op2 c op2 op3
-- /\ /\ /\ /\
-- / \ / \ / \ / \
-- b c a b a b c d
--
--
-- R1) +/- simplification:
-- ops = + or -, two literals (not siblings)
--
-- Examples:
-- A: 5 + (10-x) ==> 15-x
-- B: (10+x) + 5 ==> 15+x
-- C: (5+a)-(5-b) ==> 0+(a+b)
--
-- R2) *, `and`, `or` simplification
-- ops = *, `and`, `or` two literals (not siblings)
--
-- Examples:
-- A: 5 * (10*x) ==> 50*x
-- B: (10*x) * 5 ==> 50*x
-- C: (5*a)*(5*b) ==> 25*(a*b)
--
-- R3) * distribution over +/-
-- op1 = *, op2 = + or -, two literals (not siblings)
--
-- This transformation doesn't reduce the number of operations but switches
-- the outer and the inner operations so that the outer is (+) or (-) instead
-- of (*). It increases the odds that other rules will match after this one.
--
-- Examples:
-- A: 5 * (10-x) ==> 50 - (5*x)
-- B: (10+x) * 5 ==> 50 + (5*x)
-- C: Not supported as it would increase the number of operations:
-- (5+a)*(5-b) ==> 25 - 5*b + 5*a - a*b
--
-- R4) Simple factorization
--
-- op1 = + or -, op2/op3 = *,
-- one literal for each innermost * operation (except in the D case),
-- the two other terms are equals
--
-- Examples:
-- A: x - (10*x) ==> (-9)*x
-- B: (10*x) + x ==> 11*x
-- C: (5*x)-(x*3) ==> 2*x
-- D: x+x ==> 2*x
--
-- R5) +/- propagation
--
-- ops = + or -, one literal
--
-- This transformation doesn't reduce the number of operations but propagates
-- the constant to the outer level. It increases the odds that other rules
-- will match after this one.
--
-- Examples:
-- A: x - (10-y) ==> (x+y) - 10
-- B: (10+x) - y ==> 10 + (x-y)
-- C: N/A (caught by the A and B cases)
--
--------------------------------------------------------
-- Rules to perform constant folding into nested expressions
--
--See Note [Constant folding through nested expressions]
addFoldingRules :: PrimOp -> NumOps -> RuleM CoreExpr
addFoldingRules op num_ops = do
massert (op == numAdd num_ops)
env <- getRuleOpts
guard (roNumConstantFolding env)
[arg1,arg2] <- getArgs
platform <- getPlatform
liftMaybe
-- commutativity for + is handled here
(addFoldingRules' platform arg1 arg2 num_ops
<|> addFoldingRules' platform arg2 arg1 num_ops)
subFoldingRules :: PrimOp -> NumOps -> RuleM CoreExpr
subFoldingRules op num_ops = do
massert (op == numSub num_ops)
env <- getRuleOpts
guard (roNumConstantFolding env)
[arg1,arg2] <- getArgs
platform <- getPlatform
liftMaybe (subFoldingRules' platform arg1 arg2 num_ops)
mulFoldingRules :: PrimOp -> NumOps -> RuleM CoreExpr
mulFoldingRules op num_ops = do
massert (op == numMul num_ops)
env <- getRuleOpts
guard (roNumConstantFolding env)
[arg1,arg2] <- getArgs
platform <- getPlatform
liftMaybe
-- commutativity for * is handled here
(mulFoldingRules' platform arg1 arg2 num_ops
<|> mulFoldingRules' platform arg2 arg1 num_ops)
andFoldingRules :: NumOps -> RuleM CoreExpr
andFoldingRules num_ops = do
env <- getRuleOpts
guard (roNumConstantFolding env)
[arg1,arg2] <- getArgs
platform <- getPlatform
liftMaybe
-- commutativity for `and` is handled here
(andFoldingRules' platform arg1 arg2 num_ops
<|> andFoldingRules' platform arg2 arg1 num_ops)
orFoldingRules :: NumOps -> RuleM CoreExpr
orFoldingRules num_ops = do
env <- getRuleOpts
guard (roNumConstantFolding env)
[arg1,arg2] <- getArgs
platform <- getPlatform
liftMaybe
-- commutativity for `or` is handled here
(orFoldingRules' platform arg1 arg2 num_ops
<|> orFoldingRules' platform arg2 arg1 num_ops)
addFoldingRules' :: Platform -> CoreExpr -> CoreExpr -> NumOps -> Maybe CoreExpr
addFoldingRules' platform arg1 arg2 num_ops = case (arg1, arg2) of
-- x + (-y) ==> x-y
(x, is_neg num_ops -> Just y)
-> Just (x `sub` y)
-- R1) +/- simplification
-- l1 + (l2 + x) ==> (l1+l2) + x
(L l1, is_lit_add num_ops -> Just (l2,x))
-> Just (mkL (l1+l2) `add` x)
-- l1 + (l2 - x) ==> (l1+l2) - x
(L l1, is_sub num_ops -> Just (L l2,x))
-> Just (mkL (l1+l2) `sub` x)
-- l1 + (x - l2) ==> (l1-l2) + x
(L l1, is_sub num_ops -> Just (x,L l2))
-> Just (mkL (l1-l2) `add` x)
-- (l1 + x) + (l2 + y) ==> (l1+l2) + (x+y)
(is_lit_add num_ops -> Just (l1,x), is_lit_add num_ops -> Just (l2,y))
-> Just (mkL (l1+l2) `add` (x `add` y))
-- (l1 + x) + (l2 - y) ==> (l1+l2) + (x-y)
(is_lit_add num_ops -> Just (l1,x), is_sub num_ops -> Just (L l2,y))
-> Just (mkL (l1+l2) `add` (x `sub` y))
-- (l1 + x) + (y - l2) ==> (l1-l2) + (x+y)
(is_lit_add num_ops -> Just (l1,x), is_sub num_ops -> Just (y,L l2))
-> Just (mkL (l1-l2) `add` (x `add` y))
-- (l1 - x) + (l2 - y) ==> (l1+l2) - (x+y)
(is_sub num_ops -> Just (L l1,x), is_sub num_ops -> Just (L l2,y))
-> Just (mkL (l1+l2) `sub` (x `add` y))
-- (l1 - x) + (y - l2) ==> (l1-l2) + (y-x)
(is_sub num_ops -> Just (L l1,x), is_sub num_ops -> Just (y,L l2))
-> Just (mkL (l1-l2) `add` (y `sub` x))
-- (x - l1) + (y - l2) ==> (0-l1-l2) + (x+y)
(is_sub num_ops -> Just (x,L l1), is_sub num_ops -> Just (y,L l2))
-> Just (mkL (0-l1-l2) `add` (x `add` y))
-- R4) Simple factorization
-- x + x ==> 2 * x
_ | Just l1 <- is_expr_mul num_ops arg1 arg2
-> Just (mkL (l1+1) `mul` arg1)
-- (l1 * x) + x ==> (l1+1) * x
_ | Just l1 <- is_expr_mul num_ops arg2 arg1
-> Just (mkL (l1+1) `mul` arg2)
-- (l1 * x) + (l2 * x) ==> (l1+l2) * x
(is_lit_mul num_ops -> Just (l1,x), is_expr_mul num_ops x -> Just l2)
-> Just (mkL (l1+l2) `mul` x)
-- R5) +/- propagation: these transformations push literals outwards
-- with the hope that other rules can then be applied.
-- In the following rules, x can't be a literal otherwise another
-- rule would have combined it with the other literal in arg2. So we
-- don't have to check this to avoid loops here.
-- x + (l1 + y) ==> l1 + (x + y)
(_, is_lit_add num_ops -> Just (l1,y))
-> Just (mkL l1 `add` (arg1 `add` y))
-- x + (l1 - y) ==> l1 + (x - y)
(_, is_sub num_ops -> Just (L l1,y))
-> Just (mkL l1 `add` (arg1 `sub` y))
-- x + (y - l1) ==> (x + y) - l1
(_, is_sub num_ops -> Just (y,L l1))
-> Just ((arg1 `add` y) `sub` mkL l1)
_ -> Nothing
where
mkL = Lit . mkNumLiteral platform num_ops
add x y = BinOpApp x (numAdd num_ops) y
sub x y = BinOpApp x (numSub num_ops) y
mul x y = BinOpApp x (numMul num_ops) y
subFoldingRules' :: Platform -> CoreExpr -> CoreExpr -> NumOps -> Maybe CoreExpr
subFoldingRules' platform arg1 arg2 num_ops = case (arg1,arg2) of
-- x - (-y) ==> x+y
(x, is_neg num_ops -> Just y)
-> Just (x `add` y)
-- R1) +/- simplification
-- l1 - (l2 + x) ==> (l1-l2) - x
(L l1, is_lit_add num_ops -> Just (l2,x))
-> Just (mkL (l1-l2) `sub` x)
-- l1 - (l2 - x) ==> (l1-l2) + x
(L l1, is_sub num_ops -> Just (L l2,x))
-> Just (mkL (l1-l2) `add` x)
-- l1 - (x - l2) ==> (l1+l2) - x
(L l1, is_sub num_ops -> Just (x, L l2))
-> Just (mkL (l1+l2) `sub` x)
-- (l1 + x) - l2 ==> (l1-l2) + x
(is_lit_add num_ops -> Just (l1,x), L l2)
-> Just (mkL (l1-l2) `add` x)
-- (l1 - x) - l2 ==> (l1-l2) - x
(is_sub num_ops -> Just (L l1,x), L l2)
-> Just (mkL (l1-l2) `sub` x)
-- (x - l1) - l2 ==> x - (l1+l2)
(is_sub num_ops -> Just (x,L l1), L l2)
-> Just (x `sub` mkL (l1+l2))
-- (l1 + x) - (l2 + y) ==> (l1-l2) + (x-y)
(is_lit_add num_ops -> Just (l1,x), is_lit_add num_ops -> Just (l2,y))
-> Just (mkL (l1-l2) `add` (x `sub` y))
-- (l1 + x) - (l2 - y) ==> (l1-l2) + (x+y)
(is_lit_add num_ops -> Just (l1,x), is_sub num_ops -> Just (L l2,y))
-> Just (mkL (l1-l2) `add` (x `add` y))
-- (l1 + x) - (y - l2) ==> (l1+l2) + (x-y)
(is_lit_add num_ops -> Just (l1,x), is_sub num_ops -> Just (y,L l2))
-> Just (mkL (l1+l2) `add` (x `sub` y))
-- (l1 - x) - (l2 + y) ==> (l1-l2) - (x+y)
(is_sub num_ops -> Just (L l1,x), is_lit_add num_ops -> Just (l2,y))
-> Just (mkL (l1-l2) `sub` (x `add` y))
-- (x - l1) - (l2 + y) ==> (0-l1-l2) + (x-y)
(is_sub num_ops -> Just (x,L l1), is_lit_add num_ops -> Just (l2,y))
-> Just (mkL (0-l1-l2) `add` (x `sub` y))
-- (l1 - x) - (l2 - y) ==> (l1-l2) + (y-x)
(is_sub num_ops -> Just (L l1,x), is_sub num_ops -> Just (L l2,y))
-> Just (mkL (l1-l2) `add` (y `sub` x))
-- (l1 - x) - (y - l2) ==> (l1+l2) - (x+y)
(is_sub num_ops -> Just (L l1,x), is_sub num_ops -> Just (y,L l2))
-> Just (mkL (l1+l2) `sub` (x `add` y))
-- (x - l1) - (l2 - y) ==> (0-l1-l2) + (x+y)
(is_sub num_ops -> Just (x,L l1), is_sub num_ops -> Just (L l2,y))
-> Just (mkL (0-l1-l2) `add` (x `add` y))
-- (x - l1) - (y - l2) ==> (l2-l1) + (x-y)
(is_sub num_ops -> Just (x,L l1), is_sub num_ops -> Just (y,L l2))
-> Just (mkL (l2-l1) `add` (x `sub` y))
-- R4) Simple factorization
-- x - (l1 * x) ==> (1-l1) * x
_ | Just l1 <- is_expr_mul num_ops arg1 arg2
-> Just (mkL (1-l1) `mul` arg1)
-- (l1 * x) - x ==> (l1-1) * x
_ | Just l1 <- is_expr_mul num_ops arg2 arg1
-> Just (mkL (l1-1) `mul` arg2)
-- (l1 * x) - (l2 * x) ==> (l1-l2) * x
(is_lit_mul num_ops -> Just (l1,x), is_expr_mul num_ops x -> Just l2)
-> Just (mkL (l1-l2) `mul` x)
-- R5) +/- propagation: these transformations push literals outwards
-- with the hope that other rules can then be applied.
-- In the following rules, x can't be a literal otherwise another
-- rule would have combined it with the other literal in arg2. So we
-- don't have to check this to avoid loops here.
-- x - (l1 + y) ==> (x - y) - l1
(_, is_lit_add num_ops -> Just (l1,y))
-> Just ((arg1 `sub` y) `sub` mkL l1)
-- (l1 + x) - y ==> l1 + (x - y)
(is_lit_add num_ops -> Just (l1,x), _)
-> Just (mkL l1 `add` (x `sub` arg2))
-- x - (l1 - y) ==> (x + y) - l1
(_, is_sub num_ops -> Just (L l1,y))
-> Just ((arg1 `add` y) `sub` mkL l1)
-- x - (y - l1) ==> l1 + (x - y)
(_, is_sub num_ops -> Just (y,L l1))
-> Just (mkL l1 `add` (arg1 `sub` y))
-- (l1 - x) - y ==> l1 - (x + y)
(is_sub num_ops -> Just (L l1,x), _)
-> Just (mkL l1 `sub` (x `add` arg2))
-- (x - l1) - y ==> (x - y) - l1
(is_sub num_ops -> Just (x,L l1), _)
-> Just ((x `sub` arg2) `sub` mkL l1)
_ -> Nothing
where
mkL = Lit . mkNumLiteral platform num_ops
add x y = BinOpApp x (numAdd num_ops) y
sub x y = BinOpApp x (numSub num_ops) y
mul x y = BinOpApp x (numMul num_ops) y
mulFoldingRules' :: Platform -> CoreExpr -> CoreExpr -> NumOps -> Maybe CoreExpr
mulFoldingRules' platform arg1 arg2 num_ops = case (arg1,arg2) of
-- (-x) * (-y) ==> x*y
(is_neg num_ops -> Just x, is_neg num_ops -> Just y)
-> Just (x `mul` y)
-- l1 * (-x) ==> (-l1) * x
(L l1, is_neg num_ops -> Just x)
-> Just (mkL (-l1) `mul` x)
-- l1 * (l2 * x) ==> (l1*l2) * x
(L l1, is_lit_mul num_ops -> Just (l2,x))
-> Just (mkL (l1*l2) `mul` x)
-- l1 * (l2 + x) ==> (l1*l2) + (l1 * x)
(L l1, is_lit_add num_ops -> Just (l2,x))
-> Just (mkL (l1*l2) `add` (arg1 `mul` x))
-- l1 * (l2 - x) ==> (l1*l2) - (l1 * x)
(L l1, is_sub num_ops -> Just (L l2,x))
-> Just (mkL (l1*l2) `sub` (arg1 `mul` x))
-- l1 * (x - l2) ==> (l1 * x) - (l1*l2)
(L l1, is_sub num_ops -> Just (x, L l2))
-> Just ((arg1 `mul` x) `sub` mkL (l1*l2))
-- (l1 * x) * (l2 * y) ==> (l1*l2) * (x * y)
(is_lit_mul num_ops -> Just (l1,x), is_lit_mul num_ops -> Just (l2,y))
-> Just (mkL (l1*l2) `mul` (x `mul` y))
_ -> Nothing
where
mkL = Lit . mkNumLiteral platform num_ops
add x y = BinOpApp x (numAdd num_ops) y
sub x y = BinOpApp x (numSub num_ops) y
mul x y = BinOpApp x (numMul num_ops) y
andFoldingRules' :: Platform -> CoreExpr -> CoreExpr -> NumOps -> Maybe CoreExpr
andFoldingRules' platform arg1 arg2 num_ops = case (arg1, arg2) of
-- R2) * `or` `and` simplications
-- l1 and (l2 and x) ==> (l1 and l2) and x
(L l1, is_lit_and num_ops -> Just (l2, x))
-> Just (mkL (l1 .&. l2) `and` x)
-- l1 and (l2 or x) ==> (l1 and l2) or (l1 and x)
-- does not decrease operations
-- (l1 and x) and (l2 and y) ==> (l1 and l2) and (x and y)
(is_lit_and num_ops -> Just (l1, x), is_lit_and num_ops -> Just (l2, y))
-> Just (mkL (l1 .&. l2) `and` (x `and` y))
-- (l1 and x) and (l2 or y) ==> (l1 and l2 and x) or (l1 and x and y)
-- (l1 or x) and (l2 or y) ==> (l1 and l2) or (x and l2) or (l1 and y) or (x and y)
-- increase operation numbers
_ -> Nothing
where
mkL = Lit . mkNumLiteral platform num_ops
and x y = BinOpApp x (fromJust (numAnd num_ops)) y
orFoldingRules' :: Platform -> CoreExpr -> CoreExpr -> NumOps -> Maybe CoreExpr
orFoldingRules' platform arg1 arg2 num_ops = case (arg1, arg2) of
-- R2) * `or` `and` simplications
-- l1 or (l2 or x) ==> (l1 or l2) or x
(L l1, is_lit_or num_ops -> Just (l2, x))
-> Just (mkL (l1 .|. l2) `or` x)
-- l1 or (l2 and x) ==> (l1 or l2) and (l1 and x)
-- does not decrease operations
-- (l1 or x) or (l2 or y) ==> (l1 or l2) or (x or y)
(is_lit_or num_ops -> Just (l1, x), is_lit_or num_ops -> Just (l2, y))
-> Just (mkL (l1 .|. l2) `or` (x `or` y))
-- (l1 and x) or (l2 or y) ==> (l1 and l2 and x) or (l1 and x and y)
-- (l1 and x) or (l2 and y) ==> (l1 and l2) or (x and l2) or (l1 and y) or (x and y)
-- increase operation numbers
_ -> Nothing
where
mkL = Lit . mkNumLiteral platform num_ops
or x y = BinOpApp x (fromJust (numOr num_ops)) y
is_binop :: PrimOp -> CoreExpr -> Maybe (Arg CoreBndr, Arg CoreBndr)
is_binop op e = case e of
BinOpApp x op' y | op == op' -> Just (x,y)
_ -> Nothing
is_op :: PrimOp -> CoreExpr -> Maybe (Arg CoreBndr)
is_op op e = case e of
App (OpVal op') x | op == op' -> Just x
_ -> Nothing
is_add, is_sub, is_mul, is_and, is_or :: NumOps -> CoreExpr -> Maybe (Arg CoreBndr, Arg CoreBndr)
is_add num_ops e = is_binop (numAdd num_ops) e
is_sub num_ops e = is_binop (numSub num_ops) e
is_mul num_ops e = is_binop (numMul num_ops) e
is_and num_ops e = numAnd num_ops >>= \op -> is_binop op e
is_or num_ops e = numOr num_ops >>= \op -> is_binop op e
is_neg :: NumOps -> CoreExpr -> Maybe (Arg CoreBndr)
is_neg num_ops e = numNeg num_ops >>= \op -> is_op op e
-- match operation with a literal (handles commutativity)
is_lit_add, is_lit_mul, is_lit_and, is_lit_or :: NumOps -> CoreExpr -> Maybe (Integer, Arg CoreBndr)
is_lit_add num_ops e = is_lit' is_add num_ops e
is_lit_mul num_ops e = is_lit' is_mul num_ops e
is_lit_and num_ops e = is_lit' is_and num_ops e
is_lit_or num_ops e = is_lit' is_or num_ops e
is_lit' :: (NumOps -> CoreExpr -> Maybe (Arg CoreBndr, Arg CoreBndr)) -> NumOps -> CoreExpr -> Maybe (Integer, Arg CoreBndr)
is_lit' f num_ops e = case f num_ops e of
Just (L l, x ) -> Just (l,x)
Just (x , L l) -> Just (l,x)
_ -> Nothing
-- match given "x": return 1
-- match "lit * x": return lit value (handles commutativity)
is_expr_mul :: NumOps -> Expr CoreBndr -> Expr CoreBndr -> Maybe Integer
is_expr_mul num_ops x e = if
| x `cheapEqExpr` e
-> Just 1
| Just (k,x') <- is_lit_mul num_ops e
, x `cheapEqExpr` x'
-> return k
| otherwise
-> Nothing
-- | Match the application of a binary primop
pattern BinOpApp :: Arg CoreBndr -> PrimOp -> Arg CoreBndr -> CoreExpr
pattern BinOpApp x op y = OpVal op `App` x `App` y
-- | Match a primop
pattern OpVal:: PrimOp -> Arg CoreBndr
pattern OpVal op <- Var (isPrimOpId_maybe -> Just op) where
OpVal op = Var (mkPrimOpId op)
-- | Match a literal
pattern L :: Integer -> Arg CoreBndr
pattern L i <- Lit (LitNumber _ i)
-- | Explicit "type-class"-like dictionary for numeric primops
data NumOps = NumOps
{ numAdd :: !PrimOp -- ^ Add two numbers
, numSub :: !PrimOp -- ^ Sub two numbers
, numMul :: !PrimOp -- ^ Multiply two numbers
, numAnd :: !(Maybe PrimOp) -- ^ And two numbers
, numOr :: !(Maybe PrimOp) -- ^ Or two numbers
, numNeg :: !(Maybe PrimOp) -- ^ Negate a number
, numLitType :: !LitNumType -- ^ Literal type
}
-- | Create a numeric literal
mkNumLiteral :: Platform -> NumOps -> Integer -> Literal
mkNumLiteral platform ops i = mkLitNumberWrap platform (numLitType ops) i
int8Ops :: NumOps
int8Ops = NumOps
{ numAdd = Int8AddOp
, numSub = Int8SubOp
, numMul = Int8MulOp
, numLitType = LitNumInt8
, numAnd = Nothing
, numOr = Nothing
, numNeg = Just Int8NegOp
}
word8Ops :: NumOps
word8Ops = NumOps
{ numAdd = Word8AddOp
, numSub = Word8SubOp
, numMul = Word8MulOp
, numAnd = Just Word8AndOp
, numOr = Just Word8OrOp
, numNeg = Nothing
, numLitType = LitNumWord8
}
int16Ops :: NumOps
int16Ops = NumOps
{ numAdd = Int16AddOp
, numSub = Int16SubOp
, numMul = Int16MulOp
, numLitType = LitNumInt16
, numAnd = Nothing
, numOr = Nothing
, numNeg = Just Int16NegOp
}
word16Ops :: NumOps
word16Ops = NumOps
{ numAdd = Word16AddOp
, numSub = Word16SubOp
, numMul = Word16MulOp
, numAnd = Just Word16AndOp
, numOr = Just Word16OrOp
, numNeg = Nothing
, numLitType = LitNumWord16
}
int32Ops :: NumOps
int32Ops = NumOps
{ numAdd = Int32AddOp
, numSub = Int32SubOp
, numMul = Int32MulOp
, numLitType = LitNumInt32
, numAnd = Nothing
, numOr = Nothing
, numNeg = Just Int32NegOp
}
word32Ops :: NumOps
word32Ops = NumOps
{ numAdd = Word32AddOp
, numSub = Word32SubOp
, numMul = Word32MulOp
, numAnd = Just Word32AndOp
, numOr = Just Word32OrOp
, numNeg = Nothing
, numLitType = LitNumWord32
}
int64Ops :: NumOps
int64Ops = NumOps
{ numAdd = Int64AddOp
, numSub = Int64SubOp
, numMul = Int64MulOp
, numLitType = LitNumInt64
, numAnd = Nothing
, numOr = Nothing
, numNeg = Just Int64NegOp
}
word64Ops :: NumOps
word64Ops = NumOps
{ numAdd = Word64AddOp
, numSub = Word64SubOp
, numMul = Word64MulOp
, numAnd = Just Word64AndOp
, numOr = Just Word64OrOp
, numNeg = Nothing
, numLitType = LitNumWord64
}
intOps :: NumOps
intOps = NumOps
{ numAdd = IntAddOp
, numSub = IntSubOp
, numMul = IntMulOp
, numAnd = Just IntAndOp
, numOr = Just IntOrOp
, numNeg = Just IntNegOp
, numLitType = LitNumInt
}
wordOps :: NumOps
wordOps = NumOps
{ numAdd = WordAddOp
, numSub = WordSubOp
, numMul = WordMulOp
, numAnd = Just WordAndOp
, numOr = Just WordOrOp
, numNeg = Nothing
, numLitType = LitNumWord
}
--------------------------------------------------------
-- Constant folding through case-expressions
--
-- cf Scrutinee Constant Folding in simplCore/GHC.Core.Opt.Simplify.Utils
--------------------------------------------------------
-- | Match the scrutinee of a case and potentially return a new scrutinee and a
-- function to apply to each literal alternative.
caseRules :: Platform
-> CoreExpr -- Scrutinee
-> Maybe ( CoreExpr -- New scrutinee
, AltCon -> Maybe AltCon -- How to fix up the alt pattern
-- Nothing <=> Unreachable
-- See Note [Unreachable caseRules alternatives]
, Id -> CoreExpr) -- How to reconstruct the original scrutinee
-- from the new case-binder
-- e.g case e of b {
-- ...;
-- con bs -> rhs;
-- ... }
-- ==>
-- case e' of b' {
-- ...;
-- fixup_altcon[con] bs -> let b = mk_orig[b] in rhs;
-- ... }
caseRules platform (App (App (Var f) v) (Lit l)) -- v `op` x#
| Just op <- isPrimOpId_maybe f
, LitNumber _ x <- l
, Just adjust_lit <- adjustDyadicRight op x
= Just (v, tx_lit_con platform adjust_lit
, \v -> (App (App (Var f) (Var v)) (Lit l)))
caseRules platform (App (App (Var f) (Lit l)) v) -- x# `op` v
| Just op <- isPrimOpId_maybe f
, LitNumber _ x <- l
, Just adjust_lit <- adjustDyadicLeft x op
= Just (v, tx_lit_con platform adjust_lit
, \v -> (App (App (Var f) (Lit l)) (Var v)))
caseRules platform (App (Var f) v ) -- op v
| Just op <- isPrimOpId_maybe f
, Just adjust_lit <- adjustUnary op
= Just (v, tx_lit_con platform adjust_lit
, \v -> App (Var f) (Var v))
-- See Note [caseRules for tagToEnum]
caseRules platform (App (App (Var f) type_arg) v)
| Just TagToEnumOp <- isPrimOpId_maybe f
= Just (v, tx_con_tte platform
, \v -> (App (App (Var f) type_arg) (Var v)))
-- See Note [caseRules for dataToTag]
caseRules _ (App (App (Var f) (Type ty)) v) -- dataToTag x
| Just DataToTagOp <- isPrimOpId_maybe f
, Just (tc, _) <- tcSplitTyConApp_maybe ty
, isAlgTyCon tc
= Just (v, tx_con_dtt ty
, \v -> App (App (Var f) (Type ty)) (Var v))
caseRules _ _ = Nothing
tx_lit_con :: Platform -> (Integer -> Integer) -> AltCon -> Maybe AltCon
tx_lit_con _ _ DEFAULT = Just DEFAULT
tx_lit_con platform adjust (LitAlt l) = Just $ LitAlt (mapLitValue platform adjust l)
tx_lit_con _ _ alt = pprPanic "caseRules" (ppr alt)
-- NB: mapLitValue uses mkLitIntWrap etc, to ensure that the
-- literal alternatives remain in Word/Int target ranges
-- (See Note [Word/Int underflow/overflow] in GHC.Types.Literal and #13172).
adjustDyadicRight :: PrimOp -> Integer -> Maybe (Integer -> Integer)
-- Given (x `op` lit) return a function 'f' s.t. f (x `op` lit) = x
adjustDyadicRight op lit
= case op of
WordAddOp -> Just (\y -> y-lit )
IntAddOp -> Just (\y -> y-lit )
WordSubOp -> Just (\y -> y+lit )
IntSubOp -> Just (\y -> y+lit )
WordXorOp -> Just (\y -> y `xor` lit)
IntXorOp -> Just (\y -> y `xor` lit)
_ -> Nothing
adjustDyadicLeft :: Integer -> PrimOp -> Maybe (Integer -> Integer)
-- Given (lit `op` x) return a function 'f' s.t. f (lit `op` x) = x
adjustDyadicLeft lit op
= case op of
WordAddOp -> Just (\y -> y-lit )
IntAddOp -> Just (\y -> y-lit )
WordSubOp -> Just (\y -> lit-y )
IntSubOp -> Just (\y -> lit-y )
WordXorOp -> Just (\y -> y `xor` lit)
IntXorOp -> Just (\y -> y `xor` lit)
_ -> Nothing
adjustUnary :: PrimOp -> Maybe (Integer -> Integer)
-- Given (op x) return a function 'f' s.t. f (op x) = x
adjustUnary op
= case op of
WordNotOp -> Just (\y -> complement y)
IntNotOp -> Just (\y -> complement y)
IntNegOp -> Just (\y -> negate y )
_ -> Nothing
tx_con_tte :: Platform -> AltCon -> Maybe AltCon
tx_con_tte _ DEFAULT = Just DEFAULT
tx_con_tte _ alt@(LitAlt {}) = pprPanic "caseRules" (ppr alt)
tx_con_tte platform (DataAlt dc) -- See Note [caseRules for tagToEnum]
= Just $ LitAlt $ mkLitInt platform $ toInteger $ dataConTagZ dc
tx_con_dtt :: Type -> AltCon -> Maybe AltCon
tx_con_dtt _ DEFAULT = Just DEFAULT
tx_con_dtt ty (LitAlt (LitNumber LitNumInt i))
| tag >= 0
, tag < n_data_cons
= Just (DataAlt (data_cons !! tag)) -- tag is zero-indexed, as is (!!)
| otherwise
= Nothing
where
tag = fromInteger i :: ConTagZ
tc = tyConAppTyCon ty
n_data_cons = tyConFamilySize tc
data_cons = tyConDataCons tc
tx_con_dtt _ alt = pprPanic "caseRules" (ppr alt)
{- Note [caseRules for tagToEnum]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We want to transform
case tagToEnum x of
False -> e1
True -> e2
into
case x of
0# -> e1
1# -> e2
This rule eliminates a lot of boilerplate. For
if (x>y) then e2 else e1
we generate
case tagToEnum (x ># y) of
False -> e1
True -> e2
and it is nice to then get rid of the tagToEnum.
Beware (#14768): avoid the temptation to map constructor 0 to
DEFAULT, in the hope of getting this
case (x ># y) of
DEFAULT -> e1
1# -> e2
That fails utterly in the case of
data Colour = Red | Green | Blue
case tagToEnum x of
DEFAULT -> e1
Red -> e2
We don't want to get this!
case x of
DEFAULT -> e1
DEFAULT -> e2
Instead, we deal with turning one branch into DEFAULT in GHC.Core.Opt.Simplify.Utils
(add_default in mkCase3).
Note [caseRules for dataToTag]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
See also Note [dataToTag#] in primops.txt.pp
We want to transform
case dataToTag x of
DEFAULT -> e1
1# -> e2
into
case x of
DEFAULT -> e1
(:) _ _ -> e2
Note the need for some wildcard binders in
the 'cons' case.
For the time, we only apply this transformation when the type of `x` is a type
headed by a normal tycon. In particular, we do not apply this in the case of a
data family tycon, since that would require carefully applying coercion(s)
between the data family and the data family instance's representation type,
which caseRules isn't currently engineered to handle (#14680).
Note [Unreachable caseRules alternatives]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Take care if we see something like
case dataToTag x of
DEFAULT -> e1
-1# -> e2
100 -> e3
because there isn't a data constructor with tag -1 or 100. In this case the
out-of-range alternative is dead code -- we know the range of tags for x.
Hence caseRules returns (AltCon -> Maybe AltCon), with Nothing indicating
an alternative that is unreachable.
You may wonder how this can happen: check out #15436.
-}