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|
{-
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
\section[ConFold]{Constant Folder}
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 CPP, RankNTypes #-}
{-# OPTIONS_GHC -optc-DNON_POSIX_SOURCE #-}
module PrelRules
( primOpRules
, builtinRules
, caseRules
)
where
#include "HsVersions.h"
#include "../includes/MachDeps.h"
import GhcPrelude
import {-# SOURCE #-} MkId ( mkPrimOpId, magicDictId )
import CoreSyn
import MkCore
import Id
import Literal
import CoreOpt ( exprIsLiteral_maybe )
import PrimOp ( PrimOp(..), tagToEnumKey )
import TysWiredIn
import TysPrim
import TyCon ( tyConDataCons_maybe, isAlgTyCon, isEnumerationTyCon
, isNewTyCon, unwrapNewTyCon_maybe, tyConDataCons )
import DataCon ( DataCon, dataConTagZ, dataConTyCon, dataConWorkId )
import CoreUtils ( cheapEqExpr, exprIsHNF, exprType )
import CoreUnfold ( exprIsConApp_maybe )
import Type
import OccName ( occNameFS )
import PrelNames
import Maybes ( orElse )
import Name ( Name, nameOccName )
import Outputable
import FastString
import BasicTypes
import DynFlags
import Platform
import Util
import Coercion (mkUnbranchedAxInstCo,mkSymCo,Role(..))
import Control.Applicative ( Alternative(..) )
import Control.Monad
import qualified Control.Monad.Fail as MonadFail
import Data.Bits as Bits
import qualified Data.ByteString as BS
import Data.Int
import Data.Ratio
import Data.Word
{-
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
-- ToDo: something for integer-shift ops?
-- NotOp
primOpRules nm TagToEnumOp = mkPrimOpRule nm 2 [ tagToEnumRule ]
primOpRules nm DataToTagOp = mkPrimOpRule nm 2 [ dataToTagRule ]
-- Int operations
primOpRules nm IntAddOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (+))
, identityDynFlags zeroi ]
primOpRules nm IntSubOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (-))
, rightIdentityDynFlags zeroi
, equalArgs >> retLit zeroi ]
primOpRules nm IntMulOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (*))
, zeroElem zeroi
, identityDynFlags onei ]
primOpRules nm IntQuotOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (intOp2 quot)
, leftZero zeroi
, rightIdentityDynFlags onei
, equalArgs >> retLit onei ]
primOpRules nm IntRemOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (intOp2 rem)
, leftZero zeroi
, do l <- getLiteral 1
dflags <- getDynFlags
guard (l == onei dflags)
retLit zeroi
, equalArgs >> retLit zeroi
, equalArgs >> retLit zeroi ]
primOpRules nm AndIOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (.&.))
, idempotent
, zeroElem zeroi ]
primOpRules nm OrIOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 (.|.))
, idempotent
, identityDynFlags zeroi ]
primOpRules nm XorIOp = mkPrimOpRule nm 2 [ binaryLit (intOp2 xor)
, identityDynFlags zeroi
, equalArgs >> retLit zeroi ]
primOpRules nm NotIOp = mkPrimOpRule nm 1 [ unaryLit complementOp
, inversePrimOp NotIOp ]
primOpRules nm IntNegOp = mkPrimOpRule nm 1 [ unaryLit negOp
, inversePrimOp IntNegOp ]
primOpRules nm ISllOp = mkPrimOpRule nm 2 [ shiftRule (const Bits.shiftL)
, rightIdentityDynFlags zeroi ]
primOpRules nm ISraOp = mkPrimOpRule nm 2 [ shiftRule (const Bits.shiftR)
, rightIdentityDynFlags zeroi ]
primOpRules nm ISrlOp = mkPrimOpRule nm 2 [ shiftRule shiftRightLogical
, rightIdentityDynFlags zeroi ]
-- Word operations
primOpRules nm WordAddOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (+))
, identityDynFlags zerow ]
primOpRules nm WordSubOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (-))
, rightIdentityDynFlags zerow
, equalArgs >> retLit zerow ]
primOpRules nm WordMulOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (*))
, identityDynFlags onew ]
primOpRules nm WordQuotOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (wordOp2 quot)
, rightIdentityDynFlags onew ]
primOpRules nm WordRemOp = mkPrimOpRule nm 2 [ nonZeroLit 1 >> binaryLit (wordOp2 rem)
, leftZero zerow
, do l <- getLiteral 1
dflags <- getDynFlags
guard (l == onew dflags)
retLit zerow
, equalArgs >> retLit zerow ]
primOpRules nm AndOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (.&.))
, idempotent
, zeroElem zerow ]
primOpRules nm OrOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 (.|.))
, idempotent
, identityDynFlags zerow ]
primOpRules nm XorOp = mkPrimOpRule nm 2 [ binaryLit (wordOp2 xor)
, identityDynFlags zerow
, equalArgs >> retLit zerow ]
primOpRules nm NotOp = mkPrimOpRule nm 1 [ unaryLit complementOp
, inversePrimOp NotOp ]
primOpRules nm SllOp = mkPrimOpRule nm 2 [ shiftRule (const Bits.shiftL) ]
primOpRules nm SrlOp = mkPrimOpRule nm 2 [ shiftRule shiftRightLogical ]
-- coercions
primOpRules nm Word2IntOp = mkPrimOpRule nm 1 [ liftLitDynFlags word2IntLit
, inversePrimOp Int2WordOp ]
primOpRules nm Int2WordOp = mkPrimOpRule nm 1 [ liftLitDynFlags int2WordLit
, inversePrimOp Word2IntOp ]
primOpRules nm Narrow8IntOp = mkPrimOpRule nm 1 [ liftLit narrow8IntLit
, subsumedByPrimOp Narrow8IntOp
, Narrow8IntOp `subsumesPrimOp` Narrow16IntOp
, Narrow8IntOp `subsumesPrimOp` Narrow32IntOp ]
primOpRules nm Narrow16IntOp = mkPrimOpRule nm 1 [ liftLit narrow16IntLit
, subsumedByPrimOp Narrow8IntOp
, subsumedByPrimOp Narrow16IntOp
, Narrow16IntOp `subsumesPrimOp` Narrow32IntOp ]
primOpRules nm Narrow32IntOp = mkPrimOpRule nm 1 [ liftLit narrow32IntLit
, subsumedByPrimOp Narrow8IntOp
, subsumedByPrimOp Narrow16IntOp
, subsumedByPrimOp Narrow32IntOp
, removeOp32 ]
primOpRules nm Narrow8WordOp = mkPrimOpRule nm 1 [ liftLit narrow8WordLit
, subsumedByPrimOp Narrow8WordOp
, Narrow8WordOp `subsumesPrimOp` Narrow16WordOp
, Narrow8WordOp `subsumesPrimOp` Narrow32WordOp ]
primOpRules nm Narrow16WordOp = mkPrimOpRule nm 1 [ liftLit narrow16WordLit
, subsumedByPrimOp Narrow8WordOp
, subsumedByPrimOp Narrow16WordOp
, Narrow16WordOp `subsumesPrimOp` Narrow32WordOp ]
primOpRules nm Narrow32WordOp = mkPrimOpRule nm 1 [ liftLit narrow32WordLit
, subsumedByPrimOp Narrow8WordOp
, subsumedByPrimOp Narrow16WordOp
, subsumedByPrimOp Narrow32WordOp
, removeOp32 ]
primOpRules nm OrdOp = mkPrimOpRule nm 1 [ liftLit char2IntLit
, inversePrimOp ChrOp ]
primOpRules nm ChrOp = mkPrimOpRule nm 1 [ do [Lit lit] <- getArgs
guard (litFitsInChar lit)
liftLit int2CharLit
, inversePrimOp OrdOp ]
primOpRules nm Float2IntOp = mkPrimOpRule nm 1 [ liftLit float2IntLit ]
primOpRules nm Int2FloatOp = mkPrimOpRule nm 1 [ liftLit int2FloatLit ]
primOpRules nm Double2IntOp = mkPrimOpRule nm 1 [ liftLit double2IntLit ]
primOpRules nm Int2DoubleOp = mkPrimOpRule nm 1 [ liftLit int2DoubleLit ]
-- SUP: Not sure what the standard says about precision in the following 2 cases
primOpRules nm Float2DoubleOp = mkPrimOpRule nm 1 [ liftLit float2DoubleLit ]
primOpRules nm Double2FloatOp = mkPrimOpRule nm 1 [ liftLit double2FloatLit ]
-- Float
primOpRules nm FloatAddOp = mkPrimOpRule nm 2 [ binaryLit (floatOp2 (+))
, identity zerof ]
primOpRules nm FloatSubOp = mkPrimOpRule nm 2 [ binaryLit (floatOp2 (-))
, rightIdentity zerof ]
primOpRules nm FloatMulOp = mkPrimOpRule nm 2 [ binaryLit (floatOp2 (*))
, identity onef
, strengthReduction twof FloatAddOp ]
-- zeroElem zerof doesn't hold because of NaN
primOpRules nm FloatDivOp = mkPrimOpRule nm 2 [ guardFloatDiv >> binaryLit (floatOp2 (/))
, rightIdentity onef ]
primOpRules nm FloatNegOp = mkPrimOpRule nm 1 [ unaryLit negOp
, inversePrimOp FloatNegOp ]
-- Double
primOpRules nm DoubleAddOp = mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (+))
, identity zerod ]
primOpRules nm DoubleSubOp = mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (-))
, rightIdentity zerod ]
primOpRules nm DoubleMulOp = mkPrimOpRule nm 2 [ binaryLit (doubleOp2 (*))
, identity oned
, strengthReduction twod DoubleAddOp ]
-- zeroElem zerod doesn't hold because of NaN
primOpRules nm DoubleDivOp = mkPrimOpRule nm 2 [ guardDoubleDiv >> binaryLit (doubleOp2 (/))
, rightIdentity oned ]
primOpRules nm DoubleNegOp = mkPrimOpRule nm 1 [ unaryLit negOp
, inversePrimOp DoubleNegOp ]
-- Relational operators
primOpRules nm IntEqOp = mkRelOpRule nm (==) [ litEq True ]
primOpRules nm IntNeOp = mkRelOpRule nm (/=) [ litEq False ]
primOpRules nm CharEqOp = mkRelOpRule nm (==) [ litEq True ]
primOpRules nm CharNeOp = mkRelOpRule nm (/=) [ litEq False ]
primOpRules nm IntGtOp = mkRelOpRule nm (>) [ boundsCmp Gt ]
primOpRules nm IntGeOp = mkRelOpRule nm (>=) [ boundsCmp Ge ]
primOpRules nm IntLeOp = mkRelOpRule nm (<=) [ boundsCmp Le ]
primOpRules nm IntLtOp = mkRelOpRule nm (<) [ boundsCmp Lt ]
primOpRules nm CharGtOp = mkRelOpRule nm (>) [ boundsCmp Gt ]
primOpRules nm CharGeOp = mkRelOpRule nm (>=) [ boundsCmp Ge ]
primOpRules nm CharLeOp = mkRelOpRule nm (<=) [ boundsCmp Le ]
primOpRules nm CharLtOp = mkRelOpRule nm (<) [ boundsCmp Lt ]
primOpRules nm FloatGtOp = mkFloatingRelOpRule nm (>)
primOpRules nm FloatGeOp = mkFloatingRelOpRule nm (>=)
primOpRules nm FloatLeOp = mkFloatingRelOpRule nm (<=)
primOpRules nm FloatLtOp = mkFloatingRelOpRule nm (<)
primOpRules nm FloatEqOp = mkFloatingRelOpRule nm (==)
primOpRules nm FloatNeOp = mkFloatingRelOpRule nm (/=)
primOpRules nm DoubleGtOp = mkFloatingRelOpRule nm (>)
primOpRules nm DoubleGeOp = mkFloatingRelOpRule nm (>=)
primOpRules nm DoubleLeOp = mkFloatingRelOpRule nm (<=)
primOpRules nm DoubleLtOp = mkFloatingRelOpRule nm (<)
primOpRules nm DoubleEqOp = mkFloatingRelOpRule nm (==)
primOpRules nm DoubleNeOp = mkFloatingRelOpRule nm (/=)
primOpRules nm WordGtOp = mkRelOpRule nm (>) [ boundsCmp Gt ]
primOpRules nm WordGeOp = mkRelOpRule nm (>=) [ boundsCmp Ge ]
primOpRules nm WordLeOp = mkRelOpRule nm (<=) [ boundsCmp Le ]
primOpRules nm WordLtOp = mkRelOpRule nm (<) [ boundsCmp Lt ]
primOpRules nm WordEqOp = mkRelOpRule nm (==) [ litEq True ]
primOpRules nm WordNeOp = mkRelOpRule nm (/=) [ litEq False ]
primOpRules nm AddrAddOp = mkPrimOpRule nm 2 [ rightIdentityDynFlags zeroi ]
primOpRules nm SeqOp = mkPrimOpRule nm 4 [ seqRule ]
primOpRules nm SparkOp = mkPrimOpRule nm 4 [ sparkRule ]
primOpRules _ _ = Nothing
{-
************************************************************************
* *
\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
; dflags <- getDynFlags
; return (if cmp True True
then trueValInt dflags
else falseValInt dflags) }
{- 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 Trac #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 :: DynFlags -> Literal
zeroi dflags = mkMachInt dflags 0
onei dflags = mkMachInt dflags 1
zerow dflags = mkMachWord dflags 0
onew dflags = mkMachWord dflags 1
zerof, onef, twof, zerod, oned, twod :: Literal
zerof = mkMachFloat 0.0
onef = mkMachFloat 1.0
twof = mkMachFloat 2.0
zerod = mkMachDouble 0.0
oned = mkMachDouble 1.0
twod = mkMachDouble 2.0
cmpOp :: DynFlags -> (forall a . Ord a => a -> a -> Bool)
-> Literal -> Literal -> Maybe CoreExpr
cmpOp dflags cmp = go
where
done True = Just $ trueValInt dflags
done False = Just $ falseValInt dflags
-- These compares are at different types
go (MachChar i1) (MachChar i2) = done (i1 `cmp` i2)
go (MachInt i1) (MachInt i2) = done (i1 `cmp` i2)
go (MachInt64 i1) (MachInt64 i2) = done (i1 `cmp` i2)
go (MachWord i1) (MachWord i2) = done (i1 `cmp` i2)
go (MachWord64 i1) (MachWord64 i2) = done (i1 `cmp` i2)
go (MachFloat i1) (MachFloat i2) = done (i1 `cmp` i2)
go (MachDouble i1) (MachDouble i2) = done (i1 `cmp` i2)
go _ _ = Nothing
--------------------------
negOp :: DynFlags -> Literal -> Maybe CoreExpr -- Negate
negOp _ (MachFloat 0.0) = Nothing -- can't represent -0.0 as a Rational
negOp dflags (MachFloat f) = Just (mkFloatVal dflags (-f))
negOp _ (MachDouble 0.0) = Nothing
negOp dflags (MachDouble d) = Just (mkDoubleVal dflags (-d))
negOp dflags (MachInt i) = intResult dflags (-i)
negOp _ _ = Nothing
complementOp :: DynFlags -> Literal -> Maybe CoreExpr -- Binary complement
complementOp dflags (MachWord i) = wordResult dflags (complement i)
complementOp dflags (MachInt i) = intResult dflags (complement i)
complementOp _ _ = Nothing
--------------------------
intOp2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> DynFlags -> Literal -> Literal -> Maybe CoreExpr
intOp2 = intOp2' . const
intOp2' :: (Integral a, Integral b)
=> (DynFlags -> a -> b -> Integer)
-> DynFlags -> Literal -> Literal -> Maybe CoreExpr
intOp2' op dflags (MachInt i1) (MachInt i2) =
let o = op dflags
in intResult dflags (fromInteger i1 `o` fromInteger i2)
intOp2' _ _ _ _ = Nothing -- Could find LitLit
shiftRightLogical :: DynFlags -> Integer -> Int -> Integer
-- Shift right, putting zeros in rather than sign-propagating as Bits.shiftR would do
-- Do this by converting to Word and back. Obviously this won't work for big
-- values, but its ok as we use it here
shiftRightLogical dflags x n
| wordSizeInBits dflags == 32 = fromIntegral (fromInteger x `shiftR` n :: Word32)
| wordSizeInBits dflags == 64 = fromIntegral (fromInteger x `shiftR` n :: Word64)
| otherwise = panic "shiftRightLogical: unsupported word size"
--------------------------
retLit :: (DynFlags -> Literal) -> RuleM CoreExpr
retLit l = do dflags <- getDynFlags
return $ Lit $ l dflags
wordOp2 :: (Integral a, Integral b)
=> (a -> b -> Integer)
-> DynFlags -> Literal -> Literal -> Maybe CoreExpr
wordOp2 op dflags (MachWord w1) (MachWord w2)
= wordResult dflags (fromInteger w1 `op` fromInteger w2)
wordOp2 _ _ _ _ = Nothing -- Could find LitLit
shiftRule :: (DynFlags -> Integer -> Int -> Integer) -> RuleM CoreExpr
-- Shifts take an Int; hence third arg of op is Int
-- See Note [Guarding against silly shifts]
shiftRule shift_op
= do { dflags <- getDynFlags
; [e1, Lit (MachInt shift_len)] <- getArgs
; case e1 of
_ | shift_len == 0
-> return e1
| shift_len < 0 || wordSizeInBits dflags < shift_len
-> return (mkRuntimeErrorApp rUNTIME_ERROR_ID wordPrimTy
("Bad shift length" ++ show shift_len))
-- Do the shift at type Integer, but shift length is Int
Lit (MachInt x)
-> let op = shift_op dflags
in liftMaybe $ intResult dflags (x `op` fromInteger shift_len)
Lit (MachWord x)
-> let op = shift_op dflags
in liftMaybe $ wordResult dflags (x `op` fromInteger shift_len)
_ -> mzero }
wordSizeInBits :: DynFlags -> Integer
wordSizeInBits dflags = toInteger (platformWordSize (targetPlatform dflags) `shiftL` 3)
--------------------------
floatOp2 :: (Rational -> Rational -> Rational)
-> DynFlags -> Literal -> Literal
-> Maybe (Expr CoreBndr)
floatOp2 op dflags (MachFloat f1) (MachFloat f2)
= Just (mkFloatVal dflags (f1 `op` f2))
floatOp2 _ _ _ _ = Nothing
--------------------------
doubleOp2 :: (Rational -> Rational -> Rational)
-> DynFlags -> Literal -> Literal
-> Maybe (Expr CoreBndr)
doubleOp2 op dflags (MachDouble f1) (MachDouble f2)
= Just (mkDoubleVal dflags (f1 `op` f2))
doubleOp2 _ _ _ _ = Nothing
--------------------------
{- 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
dflags <- getDynFlags
do_lit_eq dflags lit expr
, do [expr, Lit lit] <- getArgs
dflags <- getDynFlags
do_lit_eq dflags lit expr ]
where
do_lit_eq dflags lit expr = do
guard (not (litIsLifted lit))
return (mkWildCase expr (literalType lit) intPrimTy
[(DEFAULT, [], val_if_neq),
(LitAlt lit, [], val_if_eq)])
where
val_if_eq | is_eq = trueValInt dflags
| otherwise = falseValInt dflags
val_if_neq | is_eq = falseValInt dflags
| otherwise = trueValInt dflags
-- | 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
dflags <- getDynFlags
[a, b] <- getArgs
liftMaybe $ mkRuleFn dflags op a b
data Comparison = Gt | Ge | Lt | Le
mkRuleFn :: DynFlags -> Comparison -> CoreExpr -> CoreExpr -> Maybe CoreExpr
mkRuleFn dflags Gt (Lit lit) _ | isMinBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Le (Lit lit) _ | isMinBound dflags lit = Just $ trueValInt dflags
mkRuleFn dflags Ge _ (Lit lit) | isMinBound dflags lit = Just $ trueValInt dflags
mkRuleFn dflags Lt _ (Lit lit) | isMinBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Ge (Lit lit) _ | isMaxBound dflags lit = Just $ trueValInt dflags
mkRuleFn dflags Lt (Lit lit) _ | isMaxBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Gt _ (Lit lit) | isMaxBound dflags lit = Just $ falseValInt dflags
mkRuleFn dflags Le _ (Lit lit) | isMaxBound dflags lit = Just $ trueValInt dflags
mkRuleFn _ _ _ _ = Nothing
isMinBound :: DynFlags -> Literal -> Bool
isMinBound _ (MachChar c) = c == minBound
isMinBound dflags (MachInt i) = i == tARGET_MIN_INT dflags
isMinBound _ (MachInt64 i) = i == toInteger (minBound :: Int64)
isMinBound _ (MachWord i) = i == 0
isMinBound _ (MachWord64 i) = i == 0
isMinBound _ _ = False
isMaxBound :: DynFlags -> Literal -> Bool
isMaxBound _ (MachChar c) = c == maxBound
isMaxBound dflags (MachInt i) = i == tARGET_MAX_INT dflags
isMaxBound _ (MachInt64 i) = i == toInteger (maxBound :: Int64)
isMaxBound dflags (MachWord i) = i == tARGET_MAX_WORD dflags
isMaxBound _ (MachWord64 i) = i == toInteger (maxBound :: Word64)
isMaxBound _ _ = False
-- | Create an Int literal expression while ensuring the given Integer is in the
-- target Int range
intResult :: DynFlags -> Integer -> Maybe CoreExpr
intResult dflags result = Just (Lit (mkMachIntWrap dflags result))
-- | Create a Word literal expression while ensuring the given Integer is in the
-- target Word range
wordResult :: DynFlags -> Integer -> Maybe CoreExpr
wordResult dflags result = Just (Lit (mkMachWordWrap dflags result))
inversePrimOp :: PrimOp -> RuleM CoreExpr
inversePrimOp primop = do
[Var primop_id `App` e] <- getArgs
matchPrimOpId primop primop_id
return e
subsumesPrimOp :: PrimOp -> PrimOp -> RuleM CoreExpr
this `subsumesPrimOp` that = do
[Var primop_id `App` e] <- getArgs
matchPrimOpId that primop_id
return (Var (mkPrimOpId this) `App` e)
subsumedByPrimOp :: PrimOp -> RuleM CoreExpr
subsumedByPrimOp primop = do
[e@(Var primop_id `App` _)] <- getArgs
matchPrimOpId primop primop_id
return e
idempotent :: RuleM CoreExpr
idempotent = do [e1, e2] <- getArgs
guard $ cheapEqExpr e1 e2
return e1
{-
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 NO 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 assember 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 stupid.
************************************************************************
* *
\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 = \ dflags in_scope _ -> runRuleM rm dflags in_scope }
newtype RuleM r = RuleM
{ runRuleM :: DynFlags -> InScopeEnv -> [CoreExpr] -> Maybe r }
instance Functor RuleM where
fmap = liftM
instance Applicative RuleM where
pure x = RuleM $ \_ _ _ -> Just x
(<*>) = ap
instance Monad RuleM where
RuleM f >>= g = RuleM $ \dflags iu e -> case f dflags iu e of
Nothing -> Nothing
Just r -> runRuleM (g r) dflags iu e
fail = MonadFail.fail
instance MonadFail.MonadFail RuleM where
fail _ = mzero
instance Alternative RuleM where
empty = RuleM $ \_ _ _ -> Nothing
RuleM f1 <|> RuleM f2 = RuleM $ \dflags iu args ->
f1 dflags iu args <|> f2 dflags iu args
instance MonadPlus RuleM
instance HasDynFlags RuleM where
getDynFlags = RuleM $ \dflags _ _ -> Just dflags
liftMaybe :: Maybe a -> RuleM a
liftMaybe Nothing = mzero
liftMaybe (Just x) = return x
liftLit :: (Literal -> Literal) -> RuleM CoreExpr
liftLit f = liftLitDynFlags (const f)
liftLitDynFlags :: (DynFlags -> Literal -> Literal) -> RuleM CoreExpr
liftLitDynFlags f = do
dflags <- getDynFlags
[Lit lit] <- getArgs
return $ Lit (f dflags lit)
removeOp32 :: RuleM CoreExpr
removeOp32 = do
dflags <- getDynFlags
if wordSizeInBits dflags == 32
then do
[e] <- getArgs
return e
else mzero
getArgs :: RuleM [CoreExpr]
getArgs = RuleM $ \_ _ args -> Just args
getInScopeEnv :: RuleM InScopeEnv
getInScopeEnv = RuleM $ \_ iu _ -> Just iu
-- 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 :: (DynFlags -> Literal -> Maybe CoreExpr) -> RuleM CoreExpr
unaryLit op = do
dflags <- getDynFlags
[Lit l] <- getArgs
liftMaybe $ op dflags (convFloating dflags l)
binaryLit :: (DynFlags -> Literal -> Literal -> Maybe CoreExpr) -> RuleM CoreExpr
binaryLit op = do
dflags <- getDynFlags
[Lit l1, Lit l2] <- getArgs
liftMaybe $ op dflags (convFloating dflags l1) (convFloating dflags l2)
binaryCmpLit :: (forall a . Ord a => a -> a -> Bool) -> RuleM CoreExpr
binaryCmpLit op = do
dflags <- getDynFlags
binaryLit (\_ -> cmpOp dflags op)
leftIdentity :: Literal -> RuleM CoreExpr
leftIdentity id_lit = leftIdentityDynFlags (const id_lit)
rightIdentity :: Literal -> RuleM CoreExpr
rightIdentity id_lit = rightIdentityDynFlags (const id_lit)
identity :: Literal -> RuleM CoreExpr
identity lit = leftIdentity lit `mplus` rightIdentity lit
leftIdentityDynFlags :: (DynFlags -> Literal) -> RuleM CoreExpr
leftIdentityDynFlags id_lit = do
dflags <- getDynFlags
[Lit l1, e2] <- getArgs
guard $ l1 == id_lit dflags
return e2
rightIdentityDynFlags :: (DynFlags -> Literal) -> RuleM CoreExpr
rightIdentityDynFlags id_lit = do
dflags <- getDynFlags
[e1, Lit l2] <- getArgs
guard $ l2 == id_lit dflags
return e1
identityDynFlags :: (DynFlags -> Literal) -> RuleM CoreExpr
identityDynFlags lit = leftIdentityDynFlags lit `mplus` rightIdentityDynFlags lit
leftZero :: (DynFlags -> Literal) -> RuleM CoreExpr
leftZero zero = do
dflags <- getDynFlags
[Lit l1, _] <- getArgs
guard $ l1 == zero dflags
return $ Lit l1
rightZero :: (DynFlags -> Literal) -> RuleM CoreExpr
rightZero zero = do
dflags <- getDynFlags
[_, Lit l2] <- getArgs
guard $ l2 == zero dflags
return $ Lit l2
zeroElem :: (DynFlags -> Literal) -> RuleM CoreExpr
zeroElem lit = leftZero lit `mplus` rightZero lit
equalArgs :: RuleM ()
equalArgs = do
[e1, e2] <- getArgs
guard $ e1 `cheapEqExpr` e2
nonZeroLit :: Int -> RuleM ()
nonZeroLit n = getLiteral n >>= guard . not . isZeroLit
-- 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 :: DynFlags -> Literal -> Literal
convFloating dflags (MachFloat f) | not (gopt Opt_ExcessPrecision dflags) =
MachFloat (toRational (fromRational f :: Float ))
convFloating dflags (MachDouble d) | not (gopt Opt_ExcessPrecision dflags) =
MachDouble (toRational (fromRational d :: Double))
convFloating _ l = l
guardFloatDiv :: RuleM ()
guardFloatDiv = do
[Lit (MachFloat f1), Lit (MachFloat f2)] <- getArgs
guard $ (f1 /=0 || f2 > 0) -- see Note [negative zero]
&& f2 /= 0 -- avoid NaN and Infinity/-Infinity
guardDoubleDiv :: RuleM ()
guardDoubleDiv = do
[Lit (MachDouble d1), Lit (MachDouble 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 :: DynFlags -> Expr CoreBndr
trueValInt dflags = Lit $ onei dflags -- see Note [What's true and false]
falseValInt dflags = Lit $ zeroi dflags
trueValBool, falseValBool :: Expr CoreBndr
trueValBool = Var trueDataConId -- see Note [What's true and false]
falseValBool = Var falseDataConId
ltVal, eqVal, gtVal :: Expr CoreBndr
ltVal = Var ltDataConId
eqVal = Var eqDataConId
gtVal = Var gtDataConId
mkIntVal :: DynFlags -> Integer -> Expr CoreBndr
mkIntVal dflags i = Lit (mkMachInt dflags i)
mkFloatVal :: DynFlags -> Rational -> Expr CoreBndr
mkFloatVal dflags f = Lit (convFloating dflags (MachFloat f))
mkDoubleVal :: DynFlags -> Rational -> Expr CoreBndr
mkDoubleVal dflags d = Lit (convFloating dflags (MachDouble d))
matchPrimOpId :: PrimOp -> Id -> RuleM ()
matchPrimOpId op id = do
op' <- liftMaybe $ isPrimOpId_maybe id
guard $ op == op'
{-
************************************************************************
* *
\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 tag2Enum# (T ty) 2# --> B ty
tagToEnumRule = do
[Type ty, Lit (MachInt i)] <- getArgs
case splitTyConApp_maybe ty of
Just (tycon, tc_args) | isEnumerationTyCon tycon -> do
let tag = fromInteger i
correct_tag dc = (dataConTagZ dc) == tag
(dc:rest) <- return $ filter correct_tag (tyConDataCons_maybe tycon `orElse` [])
ASSERT(null rest) return ()
return $ mkTyApps (Var (dataConWorkId dc)) tc_args
-- See Note [tagToEnum#]
_ -> WARN( True, text "tagToEnum# on non-enumeration type" <+> ppr ty )
return $ mkRuntimeErrorApp rUNTIME_ERROR_ID ty "tagToEnum# on non-enumeration type"
------------------------------
dataToTagRule :: RuleM CoreExpr
-- Rules for dataToTag#
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
-- Why don't we simplify tagToEnum# (dataToTag# x) to x? We would
-- like to, but it seems tricky. See #14282. The trouble is that
-- we never actually see tagToEnum# (dataToTag# x). Because dataToTag#
-- is can_fail, this expression is immediately transformed into
--
-- case dataToTag# @T x of wild
-- { __DEFAULT -> tagToEnum# @T wild }
--
-- and wild has no unfolding. Simon Peyton Jones speculates one way around
-- might be to arrange to give unfoldings to case binders of CONLIKE
-- applications and mark dataToTag# CONLIKE, but he doubts it's really
-- worth the trouble.
-- 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 <- getDynFlags
[_, val_arg] <- getArgs
in_scope <- getInScopeEnv
(dc,_,_) <- liftMaybe $ exprIsConApp_maybe in_scope val_arg
ASSERT( not (isNewTyCon (dataConTyCon dc)) ) return ()
return $ mkIntVal dflags (toInteger (dataConTagZ dc))
{-
************************************************************************
* *
\subsection{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 Trac #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
- PrelRules.seqRule: eliminate (seq# <whnf> s)
- StgCmmExpr.cgExpr, and cgCase: special case for seq#
- CoreUtils.exprOkForSpeculation;
see Note [seq# and expr_ok] in CoreUtils
-}
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. With -O we do a GlomBinds step that does a new SCC analysis on the whole
set of bindings, which sorts out the dependency. Without -O we don't do any rule
rewriting so again we are fine.
(This whole thing doesn't show up for non-built-in rules because their dependencies
are explicit.)
-}
builtinRules :: [CoreRule]
-- Rules for non-primops that can't be expressed using a RULE pragma
builtinRules
= [BuiltinRule { ru_name = fsLit "AppendLitString",
ru_fn = unpackCStringFoldrName,
ru_nargs = 4, ru_try = match_append_lit },
BuiltinRule { ru_name = fsLit "EqString", ru_fn = eqStringName,
ru_nargs = 2, ru_try = match_eq_string },
BuiltinRule { ru_name = fsLit "Inline", ru_fn = inlineIdName,
ru_nargs = 2, ru_try = \_ _ _ -> match_inline },
BuiltinRule { ru_name = fsLit "MagicDict", ru_fn = idName magicDictId,
ru_nargs = 4, ru_try = \_ _ _ -> match_magicDict },
mkBasicRule divIntName 2 $ msum
[ nonZeroLit 1 >> binaryLit (intOp2 div)
, leftZero zeroi
, do
[arg, Lit (MachInt d)] <- getArgs
Just n <- return $ exactLog2 d
dflags <- getDynFlags
return $ Var (mkPrimOpId ISraOp) `App` arg `App` mkIntVal dflags n
],
mkBasicRule modIntName 2 $ msum
[ nonZeroLit 1 >> binaryLit (intOp2 mod)
, leftZero zeroi
, do
[arg, Lit (MachInt d)] <- getArgs
Just _ <- return $ exactLog2 d
dflags <- getDynFlags
return $ Var (mkPrimOpId AndIOp)
`App` arg `App` mkIntVal dflags (d - 1)
]
]
++ builtinIntegerRules
{-# 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.
builtinIntegerRules :: [CoreRule]
builtinIntegerRules =
[rule_IntToInteger "smallInteger" smallIntegerName,
rule_WordToInteger "wordToInteger" wordToIntegerName,
rule_Int64ToInteger "int64ToInteger" int64ToIntegerName,
rule_Word64ToInteger "word64ToInteger" word64ToIntegerName,
rule_convert "integerToWord" integerToWordName mkWordLitWord,
rule_convert "integerToInt" integerToIntName mkIntLitInt,
rule_convert "integerToWord64" integerToWord64Name (\_ -> mkWord64LitWord64),
rule_convert "integerToInt64" integerToInt64Name (\_ -> mkInt64LitInt64),
rule_binop "plusInteger" plusIntegerName (+),
rule_binop "minusInteger" minusIntegerName (-),
rule_binop "timesInteger" timesIntegerName (*),
rule_unop "negateInteger" negateIntegerName negate,
rule_binop_Prim "eqInteger#" eqIntegerPrimName (==),
rule_binop_Prim "neqInteger#" neqIntegerPrimName (/=),
rule_unop "absInteger" absIntegerName abs,
rule_unop "signumInteger" signumIntegerName signum,
rule_binop_Prim "leInteger#" leIntegerPrimName (<=),
rule_binop_Prim "gtInteger#" gtIntegerPrimName (>),
rule_binop_Prim "ltInteger#" ltIntegerPrimName (<),
rule_binop_Prim "geInteger#" geIntegerPrimName (>=),
rule_binop_Ordering "compareInteger" compareIntegerName compare,
rule_encodeFloat "encodeFloatInteger" encodeFloatIntegerName mkFloatLitFloat,
rule_convert "floatFromInteger" floatFromIntegerName (\_ -> mkFloatLitFloat),
rule_encodeFloat "encodeDoubleInteger" encodeDoubleIntegerName mkDoubleLitDouble,
rule_decodeDouble "decodeDoubleInteger" decodeDoubleIntegerName,
rule_convert "doubleFromInteger" doubleFromIntegerName (\_ -> mkDoubleLitDouble),
rule_rationalTo "rationalToFloat" rationalToFloatName mkFloatExpr,
rule_rationalTo "rationalToDouble" rationalToDoubleName mkDoubleExpr,
rule_binop "gcdInteger" gcdIntegerName gcd,
rule_binop "lcmInteger" lcmIntegerName lcm,
rule_binop "andInteger" andIntegerName (.&.),
rule_binop "orInteger" orIntegerName (.|.),
rule_binop "xorInteger" xorIntegerName xor,
rule_unop "complementInteger" complementIntegerName complement,
rule_Int_binop "shiftLInteger" shiftLIntegerName shiftL,
rule_Int_binop "shiftRInteger" shiftRIntegerName shiftR,
rule_bitInteger "bitInteger" bitIntegerName,
-- See Note [Integer division constant folding] in libraries/base/GHC/Real.hs
rule_divop_one "quotInteger" quotIntegerName quot,
rule_divop_one "remInteger" remIntegerName rem,
rule_divop_one "divInteger" divIntegerName div,
rule_divop_one "modInteger" modIntegerName mod,
rule_divop_both "divModInteger" divModIntegerName divMod,
rule_divop_both "quotRemInteger" quotRemIntegerName quotRem,
-- These rules below don't actually have to be built in, but if we
-- put them in the Haskell source then we'd have to duplicate them
-- between all Integer implementations
rule_XToIntegerToX "smallIntegerToInt" integerToIntName smallIntegerName,
rule_XToIntegerToX "wordToIntegerToWord" integerToWordName wordToIntegerName,
rule_XToIntegerToX "int64ToIntegerToInt64" integerToInt64Name int64ToIntegerName,
rule_XToIntegerToX "word64ToIntegerToWord64" integerToWord64Name word64ToIntegerName,
rule_smallIntegerTo "smallIntegerToWord" integerToWordName Int2WordOp,
rule_smallIntegerTo "smallIntegerToFloat" floatFromIntegerName Int2FloatOp,
rule_smallIntegerTo "smallIntegerToDouble" doubleFromIntegerName Int2DoubleOp
]
where rule_convert str name convert
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Integer_convert convert }
rule_IntToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_IntToInteger }
rule_WordToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_WordToInteger }
rule_Int64ToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Int64ToInteger }
rule_Word64ToInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Word64ToInteger }
rule_unop str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_Integer_unop op }
rule_bitInteger str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_bitInteger }
rule_binop str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_binop op }
rule_divop_both str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_divop_both op }
rule_divop_one str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_divop_one op }
rule_Int_binop str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_Int_binop op }
rule_binop_Prim str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_binop_Prim op }
rule_binop_Ordering str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_binop_Ordering op }
rule_encodeFloat str name op
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_Integer_Int_encodeFloat op }
rule_decodeDouble str name
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_decodeDouble }
rule_XToIntegerToX str name toIntegerName
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_XToIntegerToX toIntegerName }
rule_smallIntegerTo str name primOp
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 1,
ru_try = match_smallIntegerTo primOp }
rule_rationalTo str name mkLit
= BuiltinRule { ru_name = fsLit str, ru_fn = name, ru_nargs = 2,
ru_try = match_rationalTo mkLit }
---------------------------------------------------
-- The rule is this:
-- unpackFoldrCString# "foo" c (unpackFoldrCString# "baz" c n)
-- = unpackFoldrCString# "foobaz" c n
match_append_lit :: RuleFun
match_append_lit _ id_unf _
[ Type ty1
, lit1
, c1
, Var unpk `App` Type ty2
`App` lit2
`App` c2
`App` n
]
| unpk `hasKey` unpackCStringFoldrIdKey &&
c1 `cheapEqExpr` c2
, Just (MachStr s1) <- exprIsLiteral_maybe id_unf lit1
, Just (MachStr s2) <- exprIsLiteral_maybe id_unf lit2
= ASSERT( ty1 `eqType` ty2 )
Just (Var unpk `App` Type ty1
`App` Lit (MachStr (s1 `BS.append` s2))
`App` c1
`App` n)
match_append_lit _ _ _ _ = Nothing
---------------------------------------------------
-- The rule is this:
-- eqString (unpackCString# (Lit s1)) (unpackCString# (Lit s2)) = s1==s2
match_eq_string :: RuleFun
match_eq_string _ id_unf _
[Var unpk1 `App` lit1, Var unpk2 `App` lit2]
| unpk1 `hasKey` unpackCStringIdKey
, unpk2 `hasKey` unpackCStringIdKey
, Just (MachStr s1) <- exprIsLiteral_maybe id_unf lit1
, Just (MachStr s2) <- exprIsLiteral_maybe id_unf lit2
= Just (if s1 == s2 then trueValBool else falseValBool)
match_eq_string _ _ _ _ = Nothing
---------------------------------------------------
-- The rule 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
-- 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
--
-- 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
-- See Note [magicDictId magic] in `basicTypes/MkId.hs`
-- for a description of what is going on here.
match_magicDict :: [Expr CoreBndr] -> Maybe (Expr CoreBndr)
match_magicDict [Type _, Var wrap `App` Type a `App` Type _ `App` f, x, y ]
| Just (fieldTy, _) <- splitFunTy_maybe $ dropForAlls $ idType wrap
, Just (dictTy, _) <- splitFunTy_maybe fieldTy
, Just dictTc <- tyConAppTyCon_maybe dictTy
, Just (_,_,co) <- unwrapNewTyCon_maybe dictTc
= Just
$ f `App` Cast x (mkSymCo (mkUnbranchedAxInstCo Representational co [a] []))
`App` y
match_magicDict _ = Nothing
-------------------------------------------------
-- Integer rules
-- smallInteger (79::Int#) = 79::Integer
-- wordToInteger (79::Word#) = 79::Integer
-- Similarly Int64, Word64
match_IntToInteger :: RuleFun
match_IntToInteger = match_IntToInteger_unop id
match_WordToInteger :: RuleFun
match_WordToInteger _ id_unf id [xl]
| Just (MachWord x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType id) of
Just (_, integerTy) ->
Just (Lit (LitInteger x integerTy))
_ ->
panic "match_WordToInteger: Id has the wrong type"
match_WordToInteger _ _ _ _ = Nothing
match_Int64ToInteger :: RuleFun
match_Int64ToInteger _ id_unf id [xl]
| Just (MachInt64 x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType id) of
Just (_, integerTy) ->
Just (Lit (LitInteger x integerTy))
_ ->
panic "match_Int64ToInteger: Id has the wrong type"
match_Int64ToInteger _ _ _ _ = Nothing
match_Word64ToInteger :: RuleFun
match_Word64ToInteger _ id_unf id [xl]
| Just (MachWord64 x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType id) of
Just (_, integerTy) ->
Just (Lit (LitInteger x integerTy))
_ ->
panic "match_Word64ToInteger: Id has the wrong type"
match_Word64ToInteger _ _ _ _ = Nothing
-------------------------------------------------
{- Note [Rewriting bitInteger]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For most types the bitInteger operation can be implemented in terms of shifts.
The integer-gmp package, however, can do substantially better than this if
allowed to provide its own implementation. However, in so doing it previously lost
constant-folding (see Trac #8832). The bitInteger rule above provides constant folding
specifically for this function.
There is, however, a bit of trickiness here when it comes to ranges. While the
AST encodes all integers (even MachInts) as Integers, `bit` expects the bit
index to be given as an Int. Hence we coerce to an Int in the rule definition.
This will behave a bit funny for constants larger than the word size, but the user
should expect some funniness given that they will have at very least ignored a
warning in this case.
-}
match_bitInteger :: RuleFun
-- Just for GHC.Integer.Type.bitInteger :: Int# -> Integer
match_bitInteger dflags id_unf fn [arg]
| Just (MachInt x) <- exprIsLiteral_maybe id_unf arg
, x >= 0
, x <= (wordSizeInBits dflags - 1)
-- Make sure x is small enough to yield a decently small iteger
-- Attempting to construct the Integer for
-- (bitInteger 9223372036854775807#)
-- would be a bad idea (Trac #14959)
, let x_int = fromIntegral x :: Int
= case splitFunTy_maybe (idType fn) of
Just (_, integerTy)
-> Just (Lit (LitInteger (bit x_int) integerTy))
_ -> panic "match_IntToInteger_unop: Id has the wrong type"
match_bitInteger _ _ _ _ = Nothing
-------------------------------------------------
match_Integer_convert :: Num a
=> (DynFlags -> a -> Expr CoreBndr)
-> RuleFun
match_Integer_convert convert dflags id_unf _ [xl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
= Just (convert dflags (fromInteger x))
match_Integer_convert _ _ _ _ _ = Nothing
match_Integer_unop :: (Integer -> Integer) -> RuleFun
match_Integer_unop unop _ id_unf _ [xl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
= Just (Lit (LitInteger (unop x) i))
match_Integer_unop _ _ _ _ _ = Nothing
match_IntToInteger_unop :: (Integer -> Integer) -> RuleFun
match_IntToInteger_unop unop _ id_unf fn [xl]
| Just (MachInt x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType fn) of
Just (_, integerTy) ->
Just (Lit (LitInteger (unop x) integerTy))
_ ->
panic "match_IntToInteger_unop: Id has the wrong type"
match_IntToInteger_unop _ _ _ _ _ = Nothing
match_Integer_binop :: (Integer -> Integer -> Integer) -> RuleFun
match_Integer_binop binop _ id_unf _ [xl,yl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
= Just (Lit (LitInteger (x `binop` y) i))
match_Integer_binop _ _ _ _ _ = Nothing
-- This helper is used for the quotRem and divMod functions
match_Integer_divop_both
:: (Integer -> Integer -> (Integer, Integer)) -> RuleFun
match_Integer_divop_both divop _ id_unf _ [xl,yl]
| Just (LitInteger x t) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
, y /= 0
, (r,s) <- x `divop` y
= Just $ mkCoreUbxTup [t,t] [Lit (LitInteger r t), Lit (LitInteger s t)]
match_Integer_divop_both _ _ _ _ _ = Nothing
-- This helper is used for the quot and rem functions
match_Integer_divop_one :: (Integer -> Integer -> Integer) -> RuleFun
match_Integer_divop_one divop _ id_unf _ [xl,yl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
, y /= 0
= Just (Lit (LitInteger (x `divop` y) i))
match_Integer_divop_one _ _ _ _ _ = Nothing
match_Integer_Int_binop :: (Integer -> Int -> Integer) -> RuleFun
match_Integer_Int_binop binop _ id_unf _ [xl,yl]
| Just (LitInteger x i) <- exprIsLiteral_maybe id_unf xl
, Just (MachInt y) <- exprIsLiteral_maybe id_unf yl
= Just (Lit (LitInteger (x `binop` fromIntegral y) i))
match_Integer_Int_binop _ _ _ _ _ = Nothing
match_Integer_binop_Prim :: (Integer -> Integer -> Bool) -> RuleFun
match_Integer_binop_Prim binop dflags id_unf _ [xl, yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
= Just (if x `binop` y then trueValInt dflags else falseValInt dflags)
match_Integer_binop_Prim _ _ _ _ _ = Nothing
match_Integer_binop_Ordering :: (Integer -> Integer -> Ordering) -> RuleFun
match_Integer_binop_Ordering binop _ id_unf _ [xl, yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
= Just $ case x `binop` y of
LT -> ltVal
EQ -> eqVal
GT -> gtVal
match_Integer_binop_Ordering _ _ _ _ _ = Nothing
match_Integer_Int_encodeFloat :: RealFloat a
=> (a -> Expr CoreBndr)
-> RuleFun
match_Integer_Int_encodeFloat mkLit _ id_unf _ [xl,yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (MachInt y) <- exprIsLiteral_maybe id_unf yl
= Just (mkLit $ encodeFloat x (fromInteger y))
match_Integer_Int_encodeFloat _ _ _ _ _ = Nothing
---------------------------------------------------
-- constant folding for Float/Double
--
-- This turns
-- rationalToFloat n d
-- into a literal Float, and similarly for Doubles.
--
-- 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
match_rationalTo :: RealFloat a
=> (a -> Expr CoreBndr)
-> RuleFun
match_rationalTo mkLit _ id_unf _ [xl, yl]
| Just (LitInteger x _) <- exprIsLiteral_maybe id_unf xl
, Just (LitInteger y _) <- exprIsLiteral_maybe id_unf yl
, y /= 0
= Just (mkLit (fromRational (x % y)))
match_rationalTo _ _ _ _ _ = Nothing
match_decodeDouble :: RuleFun
match_decodeDouble _ id_unf fn [xl]
| Just (MachDouble x) <- exprIsLiteral_maybe id_unf xl
= case splitFunTy_maybe (idType fn) of
Just (_, res)
| Just [_lev1, _lev2, integerTy, intHashTy] <- tyConAppArgs_maybe res
-> case decodeFloat (fromRational x :: Double) of
(y, z) ->
Just $ mkCoreUbxTup [integerTy, intHashTy]
[Lit (LitInteger y integerTy),
Lit (MachInt (toInteger z))]
_ ->
pprPanic "match_decodeDouble: Id has the wrong type"
(ppr fn <+> dcolon <+> ppr (idType fn))
match_decodeDouble _ _ _ _ = Nothing
match_XToIntegerToX :: Name -> RuleFun
match_XToIntegerToX n _ _ _ [App (Var x) y]
| idName x == n
= Just y
match_XToIntegerToX _ _ _ _ _ = Nothing
match_smallIntegerTo :: PrimOp -> RuleFun
match_smallIntegerTo primOp _ _ _ [App (Var x) y]
| idName x == smallIntegerName
= Just $ App (Var (mkPrimOpId primOp)) y
match_smallIntegerTo _ _ _ _ _ = Nothing
--------------------------------------------------------
-- Constant folding through case-expressions
--
-- cf Scrutinee Constant Folding in simplCore/SimplUtils
--------------------------------------------------------
-- | Match the scrutinee of a case and potentially return a new scrutinee and a
-- function to apply to each literal alternative.
caseRules :: DynFlags
-> CoreExpr -- Scrutinee
-> Maybe ( CoreExpr -- New scrutinee
, AltCon -> AltCon -- How to fix up the alt pattern
, 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 dflags (App (App (Var f) v) (Lit l)) -- v `op` x#
| Just op <- isPrimOpId_maybe f
, Just x <- isLitValue_maybe l
, Just adjust_lit <- adjustDyadicRight op x
= Just (v, tx_lit_con dflags adjust_lit
, \v -> (App (App (Var f) (Var v)) (Lit l)))
caseRules dflags (App (App (Var f) (Lit l)) v) -- x# `op` v
| Just op <- isPrimOpId_maybe f
, Just x <- isLitValue_maybe l
, Just adjust_lit <- adjustDyadicLeft x op
= Just (v, tx_lit_con dflags adjust_lit
, \v -> (App (App (Var f) (Lit l)) (Var v)))
caseRules dflags (App (Var f) v ) -- op v
| Just op <- isPrimOpId_maybe f
, Just adjust_lit <- adjustUnary op
= Just (v, tx_lit_con dflags adjust_lit
, \v -> App (Var f) (Var v))
-- See Note [caseRules for tagToEnum]
caseRules dflags (App (App (Var f) type_arg) v)
| Just TagToEnumOp <- isPrimOpId_maybe f
= Just (v, tx_con_tte dflags
, \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 :: DynFlags -> (Integer -> Integer) -> AltCon -> AltCon
tx_lit_con _ _ DEFAULT = DEFAULT
tx_lit_con dflags adjust (LitAlt l) = LitAlt (mapLitValue dflags adjust l)
tx_lit_con _ _ alt = pprPanic "caseRules" (ppr alt)
-- NB: mapLitValue uses mkMachIntWrap etc, to ensure that the
-- literal alternatives remain in Word/Int target ranges
-- (See Note [Word/Int underflow/overflow] in 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 )
XorOp -> Just (\y -> y `xor` lit)
XorIOp -> 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 )
XorOp -> Just (\y -> y `xor` lit)
XorIOp -> 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
NotOp -> Just (\y -> complement y)
NotIOp -> Just (\y -> complement y)
IntNegOp -> Just (\y -> negate y )
_ -> Nothing
tx_con_tte :: DynFlags -> AltCon -> AltCon
tx_con_tte _ DEFAULT = DEFAULT
tx_con_tte _ alt@(LitAlt {}) = pprPanic "caseRules" (ppr alt)
tx_con_tte dflags (DataAlt dc) -- See Note [caseRules for tagToEnum]
= LitAlt $ mkMachInt dflags $ toInteger $ dataConTagZ dc
tx_con_dtt :: Type -> AltCon -> AltCon
tx_con_dtt _ DEFAULT = DEFAULT
tx_con_dtt ty (LitAlt (MachInt i)) = DataAlt (get_con ty (fromInteger i))
tx_con_dtt _ alt = pprPanic "caseRules" (ppr alt)
get_con :: Type -> ConTagZ -> DataCon
get_con ty tag = tyConDataCons (tyConAppTyCon ty) !! tag
{- 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 (Trac #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 DEAFULT in SimplUtils
(add_default in mkCase3).
Note [caseRules for dataToTag]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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).
-}
|