module X86.CodeGen (
cmmTopCodeGen,
generateJumpTableForInstr,
InstrBlock
)
where
#include "HsVersions.h"
#include "nativeGen/NCG.h"
#include "../includes/MachDeps.h"
import X86.Instr
import X86.Cond
import X86.Regs
import X86.RegInfo
import CodeGen.Platform
import CPrim
import Instruction
import PIC
import NCGMonad
import Size
import Reg
import Platform
import BasicTypes
import BlockId
import Module ( primPackageId )
import PprCmm ()
import CmmUtils
import Cmm
import Hoopl
import CLabel
import ForeignCall ( CCallConv(..) )
import OrdList
import Outputable
import Unique
import FastString
import FastBool ( isFastTrue )
import DynFlags
import Util
import Control.Monad
import Data.Bits
import Data.Int
import Data.Maybe
import Data.Word
is32BitPlatform :: NatM Bool
is32BitPlatform = do
dflags <- getDynFlags
return $ target32Bit (targetPlatform dflags)
sse2Enabled :: NatM Bool
sse2Enabled = do
dflags <- getDynFlags
return (isSse2Enabled dflags)
sse4_2Enabled :: NatM Bool
sse4_2Enabled = do
dflags <- getDynFlags
return (isSse4_2Enabled dflags)
if_sse2 :: NatM a -> NatM a -> NatM a
if_sse2 sse2 x87 = do
b <- sse2Enabled
if b then sse2 else x87
cmmTopCodeGen
:: RawCmmDecl
-> NatM [NatCmmDecl (Alignment, CmmStatics) Instr]
cmmTopCodeGen (CmmProc info lab live graph) = do
let blocks = toBlockListEntryFirst graph
(nat_blocks,statics) <- mapAndUnzipM basicBlockCodeGen blocks
picBaseMb <- getPicBaseMaybeNat
dflags <- getDynFlags
let proc = CmmProc info lab live (ListGraph $ concat nat_blocks)
tops = proc : concat statics
os = platformOS $ targetPlatform dflags
case picBaseMb of
Just picBase -> initializePicBase_x86 ArchX86 os picBase tops
Nothing -> return tops
cmmTopCodeGen (CmmData sec dat) = do
return [CmmData sec (1, dat)]
basicBlockCodeGen
:: CmmBlock
-> NatM ( [NatBasicBlock Instr]
, [NatCmmDecl (Alignment, CmmStatics) Instr])
basicBlockCodeGen block = do
let (CmmEntry id, nodes, tail) = blockSplit block
stmts = blockToList nodes
mid_instrs <- stmtsToInstrs stmts
tail_instrs <- stmtToInstrs tail
let instrs = mid_instrs `appOL` tail_instrs
let
(top,other_blocks,statics) = foldrOL mkBlocks ([],[],[]) instrs
mkBlocks (NEWBLOCK id) (instrs,blocks,statics)
= ([], BasicBlock id instrs : blocks, statics)
mkBlocks (LDATA sec dat) (instrs,blocks,statics)
= (instrs, blocks, CmmData sec dat:statics)
mkBlocks instr (instrs,blocks,statics)
= (instr:instrs, blocks, statics)
return (BasicBlock id top : other_blocks, statics)
stmtsToInstrs :: [CmmNode e x] -> NatM InstrBlock
stmtsToInstrs stmts
= do instrss <- mapM stmtToInstrs stmts
return (concatOL instrss)
stmtToInstrs :: CmmNode e x -> NatM InstrBlock
stmtToInstrs stmt = do
dflags <- getDynFlags
is32Bit <- is32BitPlatform
case stmt of
CmmComment s -> return (unitOL (COMMENT s))
CmmAssign reg src
| isFloatType ty -> assignReg_FltCode size reg src
| is32Bit && isWord64 ty -> assignReg_I64Code reg src
| otherwise -> assignReg_IntCode size reg src
where ty = cmmRegType dflags reg
size = cmmTypeSize ty
CmmStore addr src
| isFloatType ty -> assignMem_FltCode size addr src
| is32Bit && isWord64 ty -> assignMem_I64Code addr src
| otherwise -> assignMem_IntCode size addr src
where ty = cmmExprType dflags src
size = cmmTypeSize ty
CmmUnsafeForeignCall target result_regs args
-> genCCall is32Bit target result_regs args
CmmBranch id -> genBranch id
CmmCondBranch arg true false -> do b1 <- genCondJump true arg
b2 <- genBranch false
return (b1 `appOL` b2)
CmmSwitch arg ids -> do dflags <- getDynFlags
genSwitch dflags arg ids
CmmCall { cml_target = arg
, cml_args_regs = gregs } -> do
dflags <- getDynFlags
genJump arg (jumpRegs dflags gregs)
_ ->
panic "stmtToInstrs: statement should have been cps'd away"
jumpRegs :: DynFlags -> [GlobalReg] -> [Reg]
jumpRegs dflags gregs = [ RegReal r | Just r <- map (globalRegMaybe platform) gregs ]
where platform = targetPlatform dflags
type InstrBlock
= OrdList Instr
data CondCode
= CondCode Bool Cond InstrBlock
data ChildCode64
= ChildCode64
InstrBlock
Reg
data Register
= Fixed Size Reg InstrBlock
| Any Size (Reg -> InstrBlock)
swizzleRegisterRep :: Register -> Size -> Register
swizzleRegisterRep (Fixed _ reg code) size = Fixed size reg code
swizzleRegisterRep (Any _ codefn) size = Any size codefn
getRegisterReg :: Platform -> Bool -> CmmReg -> Reg
getRegisterReg _ use_sse2 (CmmLocal (LocalReg u pk))
= let sz = cmmTypeSize pk in
if isFloatSize sz && not use_sse2
then RegVirtual (mkVirtualReg u FF80)
else RegVirtual (mkVirtualReg u sz)
getRegisterReg platform _ (CmmGlobal mid)
= case globalRegMaybe platform mid of
Just reg -> RegReal $ reg
Nothing -> pprPanic "getRegisterReg-memory" (ppr $ CmmGlobal mid)
data Amode
= Amode AddrMode InstrBlock
is32BitInteger :: Integer -> Bool
is32BitInteger i = i64 <= 0x7fffffff && i64 >= 0x80000000
where i64 = fromIntegral i :: Int64
jumpTableEntry :: DynFlags -> Maybe BlockId -> CmmStatic
jumpTableEntry dflags Nothing = CmmStaticLit (CmmInt 0 (wordWidth dflags))
jumpTableEntry _ (Just blockid) = CmmStaticLit (CmmLabel blockLabel)
where blockLabel = mkAsmTempLabel (getUnique blockid)
mangleIndexTree :: DynFlags -> CmmReg -> Int -> CmmExpr
mangleIndexTree dflags reg off
= CmmMachOp (MO_Add width) [CmmReg reg, CmmLit (CmmInt (fromIntegral off) width)]
where width = typeWidth (cmmRegType dflags reg)
getSomeReg :: CmmExpr -> NatM (Reg, InstrBlock)
getSomeReg expr = do
r <- getRegister expr
case r of
Any rep code -> do
tmp <- getNewRegNat rep
return (tmp, code tmp)
Fixed _ reg code ->
return (reg, code)
assignMem_I64Code :: CmmExpr -> CmmExpr -> NatM InstrBlock
assignMem_I64Code addrTree valueTree = do
Amode addr addr_code <- getAmode addrTree
ChildCode64 vcode rlo <- iselExpr64 valueTree
let
rhi = getHiVRegFromLo rlo
mov_lo = MOV II32 (OpReg rlo) (OpAddr addr)
mov_hi = MOV II32 (OpReg rhi) (OpAddr (fromJust (addrOffset addr 4)))
return (vcode `appOL` addr_code `snocOL` mov_lo `snocOL` mov_hi)
assignReg_I64Code :: CmmReg -> CmmExpr -> NatM InstrBlock
assignReg_I64Code (CmmLocal (LocalReg u_dst _)) valueTree = do
ChildCode64 vcode r_src_lo <- iselExpr64 valueTree
let
r_dst_lo = RegVirtual $ mkVirtualReg u_dst II32
r_dst_hi = getHiVRegFromLo r_dst_lo
r_src_hi = getHiVRegFromLo r_src_lo
mov_lo = MOV II32 (OpReg r_src_lo) (OpReg r_dst_lo)
mov_hi = MOV II32 (OpReg r_src_hi) (OpReg r_dst_hi)
return (
vcode `snocOL` mov_lo `snocOL` mov_hi
)
assignReg_I64Code _ _
= panic "assignReg_I64Code(i386): invalid lvalue"
iselExpr64 :: CmmExpr -> NatM ChildCode64
iselExpr64 (CmmLit (CmmInt i _)) = do
(rlo,rhi) <- getNewRegPairNat II32
let
r = fromIntegral (fromIntegral i :: Word32)
q = fromIntegral (fromIntegral (i `shiftR` 32) :: Word32)
code = toOL [
MOV II32 (OpImm (ImmInteger r)) (OpReg rlo),
MOV II32 (OpImm (ImmInteger q)) (OpReg rhi)
]
return (ChildCode64 code rlo)
iselExpr64 (CmmLoad addrTree ty) | isWord64 ty = do
Amode addr addr_code <- getAmode addrTree
(rlo,rhi) <- getNewRegPairNat II32
let
mov_lo = MOV II32 (OpAddr addr) (OpReg rlo)
mov_hi = MOV II32 (OpAddr (fromJust (addrOffset addr 4))) (OpReg rhi)
return (
ChildCode64 (addr_code `snocOL` mov_lo `snocOL` mov_hi)
rlo
)
iselExpr64 (CmmReg (CmmLocal (LocalReg vu ty))) | isWord64 ty
= return (ChildCode64 nilOL (RegVirtual $ mkVirtualReg vu II32))
iselExpr64 (CmmMachOp (MO_Add _) [e1, CmmLit (CmmInt i _)]) = do
ChildCode64 code1 r1lo <- iselExpr64 e1
(rlo,rhi) <- getNewRegPairNat II32
let
r = fromIntegral (fromIntegral i :: Word32)
q = fromIntegral (fromIntegral (i `shiftR` 32) :: Word32)
r1hi = getHiVRegFromLo r1lo
code = code1 `appOL`
toOL [ MOV II32 (OpReg r1lo) (OpReg rlo),
ADD II32 (OpImm (ImmInteger r)) (OpReg rlo),
MOV II32 (OpReg r1hi) (OpReg rhi),
ADC II32 (OpImm (ImmInteger q)) (OpReg rhi) ]
return (ChildCode64 code rlo)
iselExpr64 (CmmMachOp (MO_Add _) [e1,e2]) = do
ChildCode64 code1 r1lo <- iselExpr64 e1
ChildCode64 code2 r2lo <- iselExpr64 e2
(rlo,rhi) <- getNewRegPairNat II32
let
r1hi = getHiVRegFromLo r1lo
r2hi = getHiVRegFromLo r2lo
code = code1 `appOL`
code2 `appOL`
toOL [ MOV II32 (OpReg r1lo) (OpReg rlo),
ADD II32 (OpReg r2lo) (OpReg rlo),
MOV II32 (OpReg r1hi) (OpReg rhi),
ADC II32 (OpReg r2hi) (OpReg rhi) ]
return (ChildCode64 code rlo)
iselExpr64 (CmmMachOp (MO_UU_Conv _ W64) [expr]) = do
fn <- getAnyReg expr
r_dst_lo <- getNewRegNat II32
let r_dst_hi = getHiVRegFromLo r_dst_lo
code = fn r_dst_lo
return (
ChildCode64 (code `snocOL`
MOV II32 (OpImm (ImmInt 0)) (OpReg r_dst_hi))
r_dst_lo
)
iselExpr64 expr
= pprPanic "iselExpr64(i386)" (ppr expr)
getRegister :: CmmExpr -> NatM Register
getRegister e = do dflags <- getDynFlags
is32Bit <- is32BitPlatform
getRegister' dflags is32Bit e
getRegister' :: DynFlags -> Bool -> CmmExpr -> NatM Register
getRegister' dflags is32Bit (CmmReg reg)
= case reg of
CmmGlobal PicBaseReg
| is32Bit ->
do reg' <- getPicBaseNat (archWordSize is32Bit)
return (Fixed (archWordSize is32Bit) reg' nilOL)
_ ->
do use_sse2 <- sse2Enabled
let
sz = cmmTypeSize (cmmRegType dflags reg)
size | not use_sse2 && isFloatSize sz = FF80
| otherwise = sz
let platform = targetPlatform dflags
return (Fixed size (getRegisterReg platform use_sse2 reg) nilOL)
getRegister' dflags is32Bit (CmmRegOff r n)
= getRegister' dflags is32Bit $ mangleIndexTree dflags r n
getRegister' _ is32Bit (CmmMachOp (MO_UU_Conv W64 W32)
[CmmMachOp (MO_U_Shr W64) [x,CmmLit (CmmInt 32 _)]])
| is32Bit = do
ChildCode64 code rlo <- iselExpr64 x
return $ Fixed II32 (getHiVRegFromLo rlo) code
getRegister' _ is32Bit (CmmMachOp (MO_SS_Conv W64 W32)
[CmmMachOp (MO_U_Shr W64) [x,CmmLit (CmmInt 32 _)]])
| is32Bit = do
ChildCode64 code rlo <- iselExpr64 x
return $ Fixed II32 (getHiVRegFromLo rlo) code
getRegister' _ is32Bit (CmmMachOp (MO_UU_Conv W64 W32) [x])
| is32Bit = do
ChildCode64 code rlo <- iselExpr64 x
return $ Fixed II32 rlo code
getRegister' _ is32Bit (CmmMachOp (MO_SS_Conv W64 W32) [x])
| is32Bit = do
ChildCode64 code rlo <- iselExpr64 x
return $ Fixed II32 rlo code
getRegister' _ _ (CmmLit lit@(CmmFloat f w)) =
if_sse2 float_const_sse2 float_const_x87
where
float_const_sse2
| f == 0.0 = do
let
size = floatSize w
code dst = unitOL (XOR size (OpReg dst) (OpReg dst))
return (Any size code)
| otherwise = do
Amode addr code <- memConstant (widthInBytes w) lit
loadFloatAmode True w addr code
float_const_x87 = case w of
W64
| f == 0.0 ->
let code dst = unitOL (GLDZ dst)
in return (Any FF80 code)
| f == 1.0 ->
let code dst = unitOL (GLD1 dst)
in return (Any FF80 code)
_otherwise -> do
Amode addr code <- memConstant (widthInBytes w) lit
loadFloatAmode False w addr code
getRegister' _ _ (CmmMachOp (MO_UU_Conv W8 W32) [CmmLoad addr _]) = do
code <- intLoadCode (MOVZxL II8) addr
return (Any II32 code)
getRegister' _ _ (CmmMachOp (MO_SS_Conv W8 W32) [CmmLoad addr _]) = do
code <- intLoadCode (MOVSxL II8) addr
return (Any II32 code)
getRegister' _ _ (CmmMachOp (MO_UU_Conv W16 W32) [CmmLoad addr _]) = do
code <- intLoadCode (MOVZxL II16) addr
return (Any II32 code)
getRegister' _ _ (CmmMachOp (MO_SS_Conv W16 W32) [CmmLoad addr _]) = do
code <- intLoadCode (MOVSxL II16) addr
return (Any II32 code)
getRegister' _ is32Bit (CmmMachOp (MO_UU_Conv W8 W64) [CmmLoad addr _])
| not is32Bit = do
code <- intLoadCode (MOVZxL II8) addr
return (Any II64 code)
getRegister' _ is32Bit (CmmMachOp (MO_SS_Conv W8 W64) [CmmLoad addr _])
| not is32Bit = do
code <- intLoadCode (MOVSxL II8) addr
return (Any II64 code)
getRegister' _ is32Bit (CmmMachOp (MO_UU_Conv W16 W64) [CmmLoad addr _])
| not is32Bit = do
code <- intLoadCode (MOVZxL II16) addr
return (Any II64 code)
getRegister' _ is32Bit (CmmMachOp (MO_SS_Conv W16 W64) [CmmLoad addr _])
| not is32Bit = do
code <- intLoadCode (MOVSxL II16) addr
return (Any II64 code)
getRegister' _ is32Bit (CmmMachOp (MO_UU_Conv W32 W64) [CmmLoad addr _])
| not is32Bit = do
code <- intLoadCode (MOV II32) addr
return (Any II64 code)
getRegister' _ is32Bit (CmmMachOp (MO_SS_Conv W32 W64) [CmmLoad addr _])
| not is32Bit = do
code <- intLoadCode (MOVSxL II32) addr
return (Any II64 code)
getRegister' _ is32Bit (CmmMachOp (MO_Add W64) [CmmReg (CmmGlobal PicBaseReg),
CmmLit displacement])
| not is32Bit = do
return $ Any II64 (\dst -> unitOL $
LEA II64 (OpAddr (ripRel (litToImm displacement))) (OpReg dst))
getRegister' dflags is32Bit (CmmMachOp mop [x]) = do
sse2 <- sse2Enabled
case mop of
MO_F_Neg w
| sse2 -> sse2NegCode w x
| otherwise -> trivialUFCode FF80 (GNEG FF80) x
MO_S_Neg w -> triv_ucode NEGI (intSize w)
MO_Not w -> triv_ucode NOT (intSize w)
MO_UU_Conv W32 W8 -> toI8Reg W32 x
MO_SS_Conv W32 W8 -> toI8Reg W32 x
MO_UU_Conv W16 W8 -> toI8Reg W16 x
MO_SS_Conv W16 W8 -> toI8Reg W16 x
MO_UU_Conv W32 W16 -> toI16Reg W32 x
MO_SS_Conv W32 W16 -> toI16Reg W32 x
MO_UU_Conv W64 W32 | not is32Bit -> conversionNop II64 x
MO_SS_Conv W64 W32 | not is32Bit -> conversionNop II64 x
MO_UU_Conv W64 W16 | not is32Bit -> toI16Reg W64 x
MO_SS_Conv W64 W16 | not is32Bit -> toI16Reg W64 x
MO_UU_Conv W64 W8 | not is32Bit -> toI8Reg W64 x
MO_SS_Conv W64 W8 | not is32Bit -> toI8Reg W64 x
MO_UU_Conv rep1 rep2 | rep1 == rep2 -> conversionNop (intSize rep1) x
MO_SS_Conv rep1 rep2 | rep1 == rep2 -> conversionNop (intSize rep1) x
MO_UU_Conv W8 W32 -> integerExtend W8 W32 MOVZxL x
MO_UU_Conv W16 W32 -> integerExtend W16 W32 MOVZxL x
MO_UU_Conv W8 W16 -> integerExtend W8 W16 MOVZxL x
MO_SS_Conv W8 W32 -> integerExtend W8 W32 MOVSxL x
MO_SS_Conv W16 W32 -> integerExtend W16 W32 MOVSxL x
MO_SS_Conv W8 W16 -> integerExtend W8 W16 MOVSxL x
MO_UU_Conv W8 W64 | not is32Bit -> integerExtend W8 W64 MOVZxL x
MO_UU_Conv W16 W64 | not is32Bit -> integerExtend W16 W64 MOVZxL x
MO_UU_Conv W32 W64 | not is32Bit -> integerExtend W32 W64 MOVZxL x
MO_SS_Conv W8 W64 | not is32Bit -> integerExtend W8 W64 MOVSxL x
MO_SS_Conv W16 W64 | not is32Bit -> integerExtend W16 W64 MOVSxL x
MO_SS_Conv W32 W64 | not is32Bit -> integerExtend W32 W64 MOVSxL x
MO_FF_Conv W32 W64
| sse2 -> coerceFP2FP W64 x
| otherwise -> conversionNop FF80 x
MO_FF_Conv W64 W32 -> coerceFP2FP W32 x
MO_FS_Conv from to -> coerceFP2Int from to x
MO_SF_Conv from to -> coerceInt2FP from to x
MO_V_Insert {} -> needLlvm
MO_V_Extract {} -> needLlvm
MO_V_Add {} -> needLlvm
MO_V_Sub {} -> needLlvm
MO_V_Mul {} -> needLlvm
MO_VS_Quot {} -> needLlvm
MO_VS_Rem {} -> needLlvm
MO_VS_Neg {} -> needLlvm
MO_VU_Quot {} -> needLlvm
MO_VU_Rem {} -> needLlvm
MO_VF_Insert {} -> needLlvm
MO_VF_Extract {} -> needLlvm
MO_VF_Add {} -> needLlvm
MO_VF_Sub {} -> needLlvm
MO_VF_Mul {} -> needLlvm
MO_VF_Quot {} -> needLlvm
MO_VF_Neg {} -> needLlvm
_other -> pprPanic "getRegister" (pprMachOp mop)
where
triv_ucode :: (Size -> Operand -> Instr) -> Size -> NatM Register
triv_ucode instr size = trivialUCode size (instr size) x
integerExtend :: Width -> Width
-> (Size -> Operand -> Operand -> Instr)
-> CmmExpr -> NatM Register
integerExtend from to instr expr = do
(reg,e_code) <- if from == W8 then getByteReg expr
else getSomeReg expr
let
code dst =
e_code `snocOL`
instr (intSize from) (OpReg reg) (OpReg dst)
return (Any (intSize to) code)
toI8Reg :: Width -> CmmExpr -> NatM Register
toI8Reg new_rep expr
= do codefn <- getAnyReg expr
return (Any (intSize new_rep) codefn)
toI16Reg = toI8Reg
conversionNop :: Size -> CmmExpr -> NatM Register
conversionNop new_size expr
= do e_code <- getRegister' dflags is32Bit expr
return (swizzleRegisterRep e_code new_size)
getRegister' _ is32Bit (CmmMachOp mop [x, y]) = do
sse2 <- sse2Enabled
case mop of
MO_F_Eq _ -> condFltReg is32Bit EQQ x y
MO_F_Ne _ -> condFltReg is32Bit NE x y
MO_F_Gt _ -> condFltReg is32Bit GTT x y
MO_F_Ge _ -> condFltReg is32Bit GE x y
MO_F_Lt _ -> condFltReg is32Bit LTT x y
MO_F_Le _ -> condFltReg is32Bit LE x y
MO_Eq _ -> condIntReg EQQ x y
MO_Ne _ -> condIntReg NE x y
MO_S_Gt _ -> condIntReg GTT x y
MO_S_Ge _ -> condIntReg GE x y
MO_S_Lt _ -> condIntReg LTT x y
MO_S_Le _ -> condIntReg LE x y
MO_U_Gt _ -> condIntReg GU x y
MO_U_Ge _ -> condIntReg GEU x y
MO_U_Lt _ -> condIntReg LU x y
MO_U_Le _ -> condIntReg LEU x y
MO_F_Add w | sse2 -> trivialFCode_sse2 w ADD x y
| otherwise -> trivialFCode_x87 GADD x y
MO_F_Sub w | sse2 -> trivialFCode_sse2 w SUB x y
| otherwise -> trivialFCode_x87 GSUB x y
MO_F_Quot w | sse2 -> trivialFCode_sse2 w FDIV x y
| otherwise -> trivialFCode_x87 GDIV x y
MO_F_Mul w | sse2 -> trivialFCode_sse2 w MUL x y
| otherwise -> trivialFCode_x87 GMUL x y
MO_Add rep -> add_code rep x y
MO_Sub rep -> sub_code rep x y
MO_S_Quot rep -> div_code rep True True x y
MO_S_Rem rep -> div_code rep True False x y
MO_U_Quot rep -> div_code rep False True x y
MO_U_Rem rep -> div_code rep False False x y
MO_S_MulMayOflo rep -> imulMayOflo rep x y
MO_Mul rep -> triv_op rep IMUL
MO_And rep -> triv_op rep AND
MO_Or rep -> triv_op rep OR
MO_Xor rep -> triv_op rep XOR
MO_Shl rep -> shift_code rep SHL x y
MO_U_Shr rep -> shift_code rep SHR x y
MO_S_Shr rep -> shift_code rep SAR x y
MO_V_Insert {} -> needLlvm
MO_V_Extract {} -> needLlvm
MO_V_Add {} -> needLlvm
MO_V_Sub {} -> needLlvm
MO_V_Mul {} -> needLlvm
MO_VS_Quot {} -> needLlvm
MO_VS_Rem {} -> needLlvm
MO_VS_Neg {} -> needLlvm
MO_VF_Insert {} -> needLlvm
MO_VF_Extract {} -> needLlvm
MO_VF_Add {} -> needLlvm
MO_VF_Sub {} -> needLlvm
MO_VF_Mul {} -> needLlvm
MO_VF_Quot {} -> needLlvm
MO_VF_Neg {} -> needLlvm
_other -> pprPanic "getRegister(x86) - binary CmmMachOp (1)" (pprMachOp mop)
where
triv_op width instr = trivialCode width op (Just op) x y
where op = instr (intSize width)
imulMayOflo :: Width -> CmmExpr -> CmmExpr -> NatM Register
imulMayOflo rep a b = do
(a_reg, a_code) <- getNonClobberedReg a
b_code <- getAnyReg b
let
shift_amt = case rep of
W32 -> 31
W64 -> 63
_ -> panic "shift_amt"
size = intSize rep
code = a_code `appOL` b_code eax `appOL`
toOL [
IMUL2 size (OpReg a_reg),
SAR size (OpImm (ImmInt shift_amt)) (OpReg eax),
SUB size (OpReg edx) (OpReg eax)
]
return (Fixed size eax code)
shift_code :: Width
-> (Size -> Operand -> Operand -> Instr)
-> CmmExpr
-> CmmExpr
-> NatM Register
shift_code width instr x (CmmLit lit) = do
x_code <- getAnyReg x
let
size = intSize width
code dst
= x_code dst `snocOL`
instr size (OpImm (litToImm lit)) (OpReg dst)
return (Any size code)
shift_code width instr x y = do
x_code <- getAnyReg x
let size = intSize width
tmp <- getNewRegNat size
y_code <- getAnyReg y
let
code = x_code tmp `appOL`
y_code ecx `snocOL`
instr size (OpReg ecx) (OpReg tmp)
return (Fixed size tmp code)
add_code :: Width -> CmmExpr -> CmmExpr -> NatM Register
add_code rep x (CmmLit (CmmInt y _))
| is32BitInteger y = add_int rep x y
add_code rep x y = trivialCode rep (ADD size) (Just (ADD size)) x y
where size = intSize rep
sub_code :: Width -> CmmExpr -> CmmExpr -> NatM Register
sub_code rep x (CmmLit (CmmInt y _))
| is32BitInteger (y) = add_int rep x (y)
sub_code rep x y = trivialCode rep (SUB (intSize rep)) Nothing x y
add_int width x y = do
(x_reg, x_code) <- getSomeReg x
let
size = intSize width
imm = ImmInt (fromInteger y)
code dst
= x_code `snocOL`
LEA size
(OpAddr (AddrBaseIndex (EABaseReg x_reg) EAIndexNone imm))
(OpReg dst)
return (Any size code)
div_code width signed quotient x y = do
(y_op, y_code) <- getRegOrMem y
x_code <- getAnyReg x
let
size = intSize width
widen | signed = CLTD size
| otherwise = XOR size (OpReg edx) (OpReg edx)
instr | signed = IDIV
| otherwise = DIV
code = y_code `appOL`
x_code eax `appOL`
toOL [widen, instr size y_op]
result | quotient = eax
| otherwise = edx
return (Fixed size result code)
getRegister' _ _ (CmmLoad mem pk)
| isFloatType pk
= do
Amode addr mem_code <- getAmode mem
use_sse2 <- sse2Enabled
loadFloatAmode use_sse2 (typeWidth pk) addr mem_code
getRegister' _ is32Bit (CmmLoad mem pk)
| is32Bit && not (isWord64 pk)
= do
code <- intLoadCode instr mem
return (Any size code)
where
width = typeWidth pk
size = intSize width
instr = case width of
W8 -> MOVZxL II8
_other -> MOV size
getRegister' _ is32Bit (CmmLoad mem pk)
| not is32Bit
= do
code <- intLoadCode (MOV size) mem
return (Any size code)
where size = intSize $ typeWidth pk
getRegister' _ is32Bit (CmmLit (CmmInt 0 width))
= let
size = intSize width
size1 = if is32Bit then size
else case size of
II64 -> II32
_ -> size
code dst
= unitOL (XOR size1 (OpReg dst) (OpReg dst))
in
return (Any size code)
getRegister' dflags is32Bit (CmmLit lit)
| not is32Bit, isWord64 (cmmLitType dflags lit), not (isBigLit lit)
= let
imm = litToImm lit
code dst = unitOL (MOV II32 (OpImm imm) (OpReg dst))
in
return (Any II64 code)
where
isBigLit (CmmInt i _) = i < 0 || i > 0xffffffff
isBigLit _ = False
getRegister' dflags _ (CmmLit lit)
= do let size = cmmTypeSize (cmmLitType dflags lit)
imm = litToImm lit
code dst = unitOL (MOV size (OpImm imm) (OpReg dst))
return (Any size code)
getRegister' _ _ other
| isVecExpr other = needLlvm
| otherwise = pprPanic "getRegister(x86)" (ppr other)
intLoadCode :: (Operand -> Operand -> Instr) -> CmmExpr
-> NatM (Reg -> InstrBlock)
intLoadCode instr mem = do
Amode src mem_code <- getAmode mem
return (\dst -> mem_code `snocOL` instr (OpAddr src) (OpReg dst))
getAnyReg :: CmmExpr -> NatM (Reg -> InstrBlock)
getAnyReg expr = do
r <- getRegister expr
anyReg r
anyReg :: Register -> NatM (Reg -> InstrBlock)
anyReg (Any _ code) = return code
anyReg (Fixed rep reg fcode) = return (\dst -> fcode `snocOL` reg2reg rep reg dst)
getByteReg :: CmmExpr -> NatM (Reg, InstrBlock)
getByteReg expr = do
is32Bit <- is32BitPlatform
if is32Bit
then do r <- getRegister expr
case r of
Any rep code -> do
tmp <- getNewRegNat rep
return (tmp, code tmp)
Fixed rep reg code
| isVirtualReg reg -> return (reg,code)
| otherwise -> do
tmp <- getNewRegNat rep
return (tmp, code `snocOL` reg2reg rep reg tmp)
else getSomeReg expr
getNonClobberedReg :: CmmExpr -> NatM (Reg, InstrBlock)
getNonClobberedReg expr = do
dflags <- getDynFlags
r <- getRegister expr
case r of
Any rep code -> do
tmp <- getNewRegNat rep
return (tmp, code tmp)
Fixed rep reg code
| reg `elem` instrClobberedRegs (targetPlatform dflags)
-> do
tmp <- getNewRegNat rep
return (tmp, code `snocOL` reg2reg rep reg tmp)
| otherwise ->
return (reg, code)
reg2reg :: Size -> Reg -> Reg -> Instr
reg2reg size src dst
| size == FF80 = GMOV src dst
| otherwise = MOV size (OpReg src) (OpReg dst)
getAmode :: CmmExpr -> NatM Amode
getAmode e = do is32Bit <- is32BitPlatform
getAmode' is32Bit e
getAmode' :: Bool -> CmmExpr -> NatM Amode
getAmode' _ (CmmRegOff r n) = do dflags <- getDynFlags
getAmode $ mangleIndexTree dflags r n
getAmode' is32Bit (CmmMachOp (MO_Add W64) [CmmReg (CmmGlobal PicBaseReg),
CmmLit displacement])
| not is32Bit
= return $ Amode (ripRel (litToImm displacement)) nilOL
getAmode' is32Bit (CmmMachOp (MO_Sub _rep) [x, CmmLit lit@(CmmInt i _)])
| is32BitLit is32Bit lit
= do (x_reg, x_code) <- getSomeReg x
let off = ImmInt ((fromInteger i))
return (Amode (AddrBaseIndex (EABaseReg x_reg) EAIndexNone off) x_code)
getAmode' is32Bit (CmmMachOp (MO_Add _rep) [x, CmmLit lit])
| is32BitLit is32Bit lit
= do (x_reg, x_code) <- getSomeReg x
let off = litToImm lit
return (Amode (AddrBaseIndex (EABaseReg x_reg) EAIndexNone off) x_code)
getAmode' is32Bit (CmmMachOp (MO_Add rep) [a@(CmmMachOp (MO_Shl _) _),
b@(CmmLit _)])
= getAmode' is32Bit (CmmMachOp (MO_Add rep) [b,a])
getAmode' _ (CmmMachOp (MO_Add _) [x, CmmMachOp (MO_Shl _)
[y, CmmLit (CmmInt shift _)]])
| shift == 0 || shift == 1 || shift == 2 || shift == 3
= x86_complex_amode x y shift 0
getAmode' _ (CmmMachOp (MO_Add _)
[x, CmmMachOp (MO_Add _)
[CmmMachOp (MO_Shl _) [y, CmmLit (CmmInt shift _)],
CmmLit (CmmInt offset _)]])
| shift == 0 || shift == 1 || shift == 2 || shift == 3
&& is32BitInteger offset
= x86_complex_amode x y shift offset
getAmode' _ (CmmMachOp (MO_Add _) [x,y])
= x86_complex_amode x y 0 0
getAmode' is32Bit (CmmLit lit) | is32BitLit is32Bit lit
= return (Amode (ImmAddr (litToImm lit) 0) nilOL)
getAmode' _ expr = do
(reg,code) <- getSomeReg expr
return (Amode (AddrBaseIndex (EABaseReg reg) EAIndexNone (ImmInt 0)) code)
x86_complex_amode :: CmmExpr -> CmmExpr -> Integer -> Integer -> NatM Amode
x86_complex_amode base index shift offset
= do (x_reg, x_code) <- getNonClobberedReg base
(y_reg, y_code) <- getSomeReg index
let
code = x_code `appOL` y_code
base = case shift of 0 -> 1; 1 -> 2; 2 -> 4; 3 -> 8;
n -> panic $ "x86_complex_amode: unhandled shift! (" ++ show n ++ ")"
return (Amode (AddrBaseIndex (EABaseReg x_reg) (EAIndex y_reg base) (ImmInt (fromIntegral offset)))
code)
getNonClobberedOperand :: CmmExpr -> NatM (Operand, InstrBlock)
getNonClobberedOperand (CmmLit lit) = do
use_sse2 <- sse2Enabled
if use_sse2 && isSuitableFloatingPointLit lit
then do
let CmmFloat _ w = lit
Amode addr code <- memConstant (widthInBytes w) lit
return (OpAddr addr, code)
else do
is32Bit <- is32BitPlatform
dflags <- getDynFlags
if is32BitLit is32Bit lit && not (isFloatType (cmmLitType dflags lit))
then return (OpImm (litToImm lit), nilOL)
else getNonClobberedOperand_generic (CmmLit lit)
getNonClobberedOperand (CmmLoad mem pk) = do
is32Bit <- is32BitPlatform
use_sse2 <- sse2Enabled
if (not (isFloatType pk) || use_sse2)
&& (if is32Bit then not (isWord64 pk) else True)
then do
dflags <- getDynFlags
let platform = targetPlatform dflags
Amode src mem_code <- getAmode mem
(src',save_code) <-
if (amodeCouldBeClobbered platform src)
then do
tmp <- getNewRegNat (archWordSize is32Bit)
return (AddrBaseIndex (EABaseReg tmp) EAIndexNone (ImmInt 0),
unitOL (LEA (archWordSize is32Bit) (OpAddr src) (OpReg tmp)))
else
return (src, nilOL)
return (OpAddr src', mem_code `appOL` save_code)
else do
getNonClobberedOperand_generic (CmmLoad mem pk)
getNonClobberedOperand e = getNonClobberedOperand_generic e
getNonClobberedOperand_generic :: CmmExpr -> NatM (Operand, InstrBlock)
getNonClobberedOperand_generic e = do
(reg, code) <- getNonClobberedReg e
return (OpReg reg, code)
amodeCouldBeClobbered :: Platform -> AddrMode -> Bool
amodeCouldBeClobbered platform amode = any (regClobbered platform) (addrModeRegs amode)
regClobbered :: Platform -> Reg -> Bool
regClobbered platform (RegReal (RealRegSingle rr)) = isFastTrue (freeReg platform rr)
regClobbered _ _ = False
getOperand :: CmmExpr -> NatM (Operand, InstrBlock)
getOperand (CmmLit lit) = do
use_sse2 <- sse2Enabled
if (use_sse2 && isSuitableFloatingPointLit lit)
then do
let CmmFloat _ w = lit
Amode addr code <- memConstant (widthInBytes w) lit
return (OpAddr addr, code)
else do
is32Bit <- is32BitPlatform
dflags <- getDynFlags
if is32BitLit is32Bit lit && not (isFloatType (cmmLitType dflags lit))
then return (OpImm (litToImm lit), nilOL)
else getOperand_generic (CmmLit lit)
getOperand (CmmLoad mem pk) = do
is32Bit <- is32BitPlatform
use_sse2 <- sse2Enabled
if (not (isFloatType pk) || use_sse2) && (if is32Bit then not (isWord64 pk) else True)
then do
Amode src mem_code <- getAmode mem
return (OpAddr src, mem_code)
else
getOperand_generic (CmmLoad mem pk)
getOperand e = getOperand_generic e
getOperand_generic :: CmmExpr -> NatM (Operand, InstrBlock)
getOperand_generic e = do
(reg, code) <- getSomeReg e
return (OpReg reg, code)
isOperand :: Bool -> CmmExpr -> Bool
isOperand _ (CmmLoad _ _) = True
isOperand is32Bit (CmmLit lit) = is32BitLit is32Bit lit
|| isSuitableFloatingPointLit lit
isOperand _ _ = False
memConstant :: Int -> CmmLit -> NatM Amode
memConstant align lit = do
lbl <- getNewLabelNat
dflags <- getDynFlags
(addr, addr_code) <- if target32Bit (targetPlatform dflags)
then do dynRef <- cmmMakeDynamicReference
dflags
DataReference
lbl
Amode addr addr_code <- getAmode dynRef
return (addr, addr_code)
else return (ripRel (ImmCLbl lbl), nilOL)
let code =
LDATA ReadOnlyData (align, Statics lbl [CmmStaticLit lit])
`consOL` addr_code
return (Amode addr code)
loadFloatAmode :: Bool -> Width -> AddrMode -> InstrBlock -> NatM Register
loadFloatAmode use_sse2 w addr addr_code = do
let size = floatSize w
code dst = addr_code `snocOL`
if use_sse2
then MOV size (OpAddr addr) (OpReg dst)
else GLD size addr dst
return (Any (if use_sse2 then size else FF80) code)
isSuitableFloatingPointLit :: CmmLit -> Bool
isSuitableFloatingPointLit (CmmFloat f _) = f /= 0.0
isSuitableFloatingPointLit _ = False
getRegOrMem :: CmmExpr -> NatM (Operand, InstrBlock)
getRegOrMem e@(CmmLoad mem pk) = do
is32Bit <- is32BitPlatform
use_sse2 <- sse2Enabled
if (not (isFloatType pk) || use_sse2) && (if is32Bit then not (isWord64 pk) else True)
then do
Amode src mem_code <- getAmode mem
return (OpAddr src, mem_code)
else do
(reg, code) <- getNonClobberedReg e
return (OpReg reg, code)
getRegOrMem e = do
(reg, code) <- getNonClobberedReg e
return (OpReg reg, code)
is32BitLit :: Bool -> CmmLit -> Bool
is32BitLit is32Bit (CmmInt i W64)
| not is32Bit
=
is32BitInteger i
is32BitLit _ _ = True
getCondCode :: CmmExpr -> NatM CondCode
getCondCode (CmmMachOp mop [x, y])
=
case mop of
MO_F_Eq W32 -> condFltCode EQQ x y
MO_F_Ne W32 -> condFltCode NE x y
MO_F_Gt W32 -> condFltCode GTT x y
MO_F_Ge W32 -> condFltCode GE x y
MO_F_Lt W32 -> condFltCode LTT x y
MO_F_Le W32 -> condFltCode LE x y
MO_F_Eq W64 -> condFltCode EQQ x y
MO_F_Ne W64 -> condFltCode NE x y
MO_F_Gt W64 -> condFltCode GTT x y
MO_F_Ge W64 -> condFltCode GE x y
MO_F_Lt W64 -> condFltCode LTT x y
MO_F_Le W64 -> condFltCode LE x y
MO_Eq _ -> condIntCode EQQ x y
MO_Ne _ -> condIntCode NE x y
MO_S_Gt _ -> condIntCode GTT x y
MO_S_Ge _ -> condIntCode GE x y
MO_S_Lt _ -> condIntCode LTT x y
MO_S_Le _ -> condIntCode LE x y
MO_U_Gt _ -> condIntCode GU x y
MO_U_Ge _ -> condIntCode GEU x y
MO_U_Lt _ -> condIntCode LU x y
MO_U_Le _ -> condIntCode LEU x y
_other -> pprPanic "getCondCode(x86,x86_64)" (ppr (CmmMachOp mop [x,y]))
getCondCode other = pprPanic "getCondCode(2)(x86,x86_64)" (ppr other)
condIntCode :: Cond -> CmmExpr -> CmmExpr -> NatM CondCode
condIntCode cond x y = do is32Bit <- is32BitPlatform
condIntCode' is32Bit cond x y
condIntCode' :: Bool -> Cond -> CmmExpr -> CmmExpr -> NatM CondCode
condIntCode' is32Bit cond (CmmLoad x pk) (CmmLit lit)
| is32BitLit is32Bit lit = do
Amode x_addr x_code <- getAmode x
let
imm = litToImm lit
code = x_code `snocOL`
CMP (cmmTypeSize pk) (OpImm imm) (OpAddr x_addr)
return (CondCode False cond code)
condIntCode' is32Bit cond (CmmMachOp (MO_And _) [x,o2]) (CmmLit (CmmInt 0 pk))
| (CmmLit lit@(CmmInt mask _)) <- o2, is32BitLit is32Bit lit
= do
(x_reg, x_code) <- getSomeReg x
let
code = x_code `snocOL`
TEST (intSize pk) (OpImm (ImmInteger mask)) (OpReg x_reg)
return (CondCode False cond code)
condIntCode' _ cond x (CmmLit (CmmInt 0 pk)) = do
(x_reg, x_code) <- getSomeReg x
let
code = x_code `snocOL`
TEST (intSize pk) (OpReg x_reg) (OpReg x_reg)
return (CondCode False cond code)
condIntCode' is32Bit cond x y
| isOperand is32Bit y = do
dflags <- getDynFlags
(x_reg, x_code) <- getNonClobberedReg x
(y_op, y_code) <- getOperand y
let
code = x_code `appOL` y_code `snocOL`
CMP (cmmTypeSize (cmmExprType dflags x)) y_op (OpReg x_reg)
return (CondCode False cond code)
| isOperand is32Bit x
, Just revcond <- maybeFlipCond cond = do
dflags <- getDynFlags
(y_reg, y_code) <- getNonClobberedReg y
(x_op, x_code) <- getOperand x
let
code = y_code `appOL` x_code `snocOL`
CMP (cmmTypeSize (cmmExprType dflags x)) x_op (OpReg y_reg)
return (CondCode False revcond code)
condIntCode' _ cond x y = do
dflags <- getDynFlags
(y_reg, y_code) <- getNonClobberedReg y
(x_op, x_code) <- getRegOrMem x
let
code = y_code `appOL`
x_code `snocOL`
CMP (cmmTypeSize (cmmExprType dflags x)) (OpReg y_reg) x_op
return (CondCode False cond code)
condFltCode :: Cond -> CmmExpr -> CmmExpr -> NatM CondCode
condFltCode cond x y
= if_sse2 condFltCode_sse2 condFltCode_x87
where
condFltCode_x87
= ASSERT(cond `elem` ([EQQ, NE, LE, LTT, GE, GTT])) do
(x_reg, x_code) <- getNonClobberedReg x
(y_reg, y_code) <- getSomeReg y
let
code = x_code `appOL` y_code `snocOL`
GCMP cond x_reg y_reg
return (CondCode True EQQ code)
condFltCode_sse2 = do
dflags <- getDynFlags
(x_reg, x_code) <- getNonClobberedReg x
(y_op, y_code) <- getOperand y
let
code = x_code `appOL`
y_code `snocOL`
CMP (floatSize $ cmmExprWidth dflags x) y_op (OpReg x_reg)
return (CondCode True (condToUnsigned cond) code)
assignMem_IntCode :: Size -> CmmExpr -> CmmExpr -> NatM InstrBlock
assignReg_IntCode :: Size -> CmmReg -> CmmExpr -> NatM InstrBlock
assignMem_FltCode :: Size -> CmmExpr -> CmmExpr -> NatM InstrBlock
assignReg_FltCode :: Size -> CmmReg -> CmmExpr -> NatM InstrBlock
assignMem_IntCode pk addr (CmmMachOp op [CmmLoad addr2 _,
CmmLit (CmmInt i _)])
| addr == addr2, pk /= II64 || is32BitInteger i,
Just instr <- check op
= do Amode amode code_addr <- getAmode addr
let code = code_addr `snocOL`
instr pk (OpImm (ImmInt (fromIntegral i))) (OpAddr amode)
return code
where
check (MO_Add _) = Just ADD
check (MO_Sub _) = Just SUB
check _ = Nothing
assignMem_IntCode pk addr src = do
is32Bit <- is32BitPlatform
Amode addr code_addr <- getAmode addr
(code_src, op_src) <- get_op_RI is32Bit src
let
code = code_src `appOL`
code_addr `snocOL`
MOV pk op_src (OpAddr addr)
return code
where
get_op_RI :: Bool -> CmmExpr -> NatM (InstrBlock,Operand)
get_op_RI is32Bit (CmmLit lit) | is32BitLit is32Bit lit
= return (nilOL, OpImm (litToImm lit))
get_op_RI _ op
= do (reg,code) <- getNonClobberedReg op
return (code, OpReg reg)
assignReg_IntCode pk reg (CmmLoad src _) = do
load_code <- intLoadCode (MOV pk) src
dflags <- getDynFlags
let platform = targetPlatform dflags
return (load_code (getRegisterReg platform False reg))
assignReg_IntCode _ reg src = do
dflags <- getDynFlags
let platform = targetPlatform dflags
code <- getAnyReg src
return (code (getRegisterReg platform False reg))
assignMem_FltCode pk addr src = do
(src_reg, src_code) <- getNonClobberedReg src
Amode addr addr_code <- getAmode addr
use_sse2 <- sse2Enabled
let
code = src_code `appOL`
addr_code `snocOL`
if use_sse2 then MOV pk (OpReg src_reg) (OpAddr addr)
else GST pk src_reg addr
return code
assignReg_FltCode _ reg src = do
use_sse2 <- sse2Enabled
src_code <- getAnyReg src
dflags <- getDynFlags
let platform = targetPlatform dflags
return (src_code (getRegisterReg platform use_sse2 reg))
genJump :: CmmExpr -> [Reg] -> NatM InstrBlock
genJump (CmmLoad mem _) regs = do
Amode target code <- getAmode mem
return (code `snocOL` JMP (OpAddr target) regs)
genJump (CmmLit lit) regs = do
return (unitOL (JMP (OpImm (litToImm lit)) regs))
genJump expr regs = do
(reg,code) <- getSomeReg expr
return (code `snocOL` JMP (OpReg reg) regs)
genBranch :: BlockId -> NatM InstrBlock
genBranch = return . toOL . mkJumpInstr
genCondJump
:: BlockId
-> CmmExpr
-> NatM InstrBlock
genCondJump id bool = do
CondCode is_float cond cond_code <- getCondCode bool
use_sse2 <- sse2Enabled
if not is_float || not use_sse2
then
return (cond_code `snocOL` JXX cond id)
else do
lbl <- getBlockIdNat
let code = case cond of
NE -> or_unordered
GU -> plain_test
GEU -> plain_test
_ -> and_ordered
plain_test = unitOL (
JXX cond id
)
or_unordered = toOL [
JXX cond id,
JXX PARITY id
]
and_ordered = toOL [
JXX PARITY lbl,
JXX cond id,
JXX ALWAYS lbl,
NEWBLOCK lbl
]
return (cond_code `appOL` code)
genCCall
:: Bool
-> ForeignTarget
-> [CmmFormal]
-> [CmmActual]
-> NatM InstrBlock
genCCall is32Bit (PrimTarget MO_Memcpy) _
[dst, src,
(CmmLit (CmmInt n _)),
(CmmLit (CmmInt align _))]
| n <= maxInlineSizeThreshold && align .&. 3 == 0 = do
code_dst <- getAnyReg dst
dst_r <- getNewRegNat size
code_src <- getAnyReg src
src_r <- getNewRegNat size
tmp_r <- getNewRegNat size
return $ code_dst dst_r `appOL` code_src src_r `appOL`
go dst_r src_r tmp_r n
where
size = if align .&. 4 /= 0 then II32 else (archWordSize is32Bit)
sizeBytes = fromIntegral (sizeInBytes size)
go :: Reg -> Reg -> Reg -> Integer -> OrdList Instr
go dst src tmp i
| i >= sizeBytes =
unitOL (MOV size (OpAddr src_addr) (OpReg tmp)) `appOL`
unitOL (MOV size (OpReg tmp) (OpAddr dst_addr)) `appOL`
go dst src tmp (i sizeBytes)
| i >= 4 =
unitOL (MOV II32 (OpAddr src_addr) (OpReg tmp)) `appOL`
unitOL (MOV II32 (OpReg tmp) (OpAddr dst_addr)) `appOL`
go dst src tmp (i 4)
| i >= 2 =
unitOL (MOVZxL II16 (OpAddr src_addr) (OpReg tmp)) `appOL`
unitOL (MOV II16 (OpReg tmp) (OpAddr dst_addr)) `appOL`
go dst src tmp (i 2)
| i >= 1 =
unitOL (MOVZxL II8 (OpAddr src_addr) (OpReg tmp)) `appOL`
unitOL (MOV II8 (OpReg tmp) (OpAddr dst_addr)) `appOL`
go dst src tmp (i 1)
| otherwise = nilOL
where
src_addr = AddrBaseIndex (EABaseReg src) EAIndexNone
(ImmInteger (n i))
dst_addr = AddrBaseIndex (EABaseReg dst) EAIndexNone
(ImmInteger (n i))
genCCall _ (PrimTarget MO_Memset) _
[dst,
CmmLit (CmmInt c _),
CmmLit (CmmInt n _),
CmmLit (CmmInt align _)]
| n <= maxInlineSizeThreshold && align .&. 3 == 0 = do
code_dst <- getAnyReg dst
dst_r <- getNewRegNat size
return $ code_dst dst_r `appOL` go dst_r n
where
(size, val) = case align .&. 3 of
2 -> (II16, c2)
0 -> (II32, c4)
_ -> (II8, c)
c2 = c `shiftL` 8 .|. c
c4 = c2 `shiftL` 16 .|. c2
sizeBytes = fromIntegral (sizeInBytes size)
go :: Reg -> Integer -> OrdList Instr
go dst i
| i >= sizeBytes =
unitOL (MOV size (OpImm (ImmInteger val)) (OpAddr dst_addr)) `appOL`
go dst (i sizeBytes)
| i >= 4 =
unitOL (MOV II32 (OpImm (ImmInteger c4)) (OpAddr dst_addr)) `appOL`
go dst (i 4)
| i >= 2 =
unitOL (MOV II16 (OpImm (ImmInteger c2)) (OpAddr dst_addr)) `appOL`
go dst (i 2)
| i >= 1 =
unitOL (MOV II8 (OpImm (ImmInteger c)) (OpAddr dst_addr)) `appOL`
go dst (i 1)
| otherwise = nilOL
where
dst_addr = AddrBaseIndex (EABaseReg dst) EAIndexNone
(ImmInteger (n i))
genCCall _ (PrimTarget MO_WriteBarrier) _ _ = return nilOL
genCCall _ (PrimTarget MO_Touch) _ _ = return nilOL
genCCall is32bit (PrimTarget (MO_Prefetch_Data n )) _ [src] =
case n of
0 -> genPrefetch src $ PREFETCH NTA size
1 -> genPrefetch src $ PREFETCH Lvl2 size
2 -> genPrefetch src $ PREFETCH Lvl1 size
3 -> genPrefetch src $ PREFETCH Lvl0 size
l -> panic $ "unexpected prefetch level in genCCall MO_Prefetch_Data: " ++ (show l)
where
size = archWordSize is32bit
genPrefetch inRegSrc prefetchCTor =
do
code_src <- getAnyReg inRegSrc
src_r <- getNewRegNat size
return $ code_src src_r `appOL`
(unitOL (prefetchCTor (OpAddr
((AddrBaseIndex (EABaseReg src_r ) EAIndexNone (ImmInt 0)))) ))
genCCall is32Bit (PrimTarget (MO_BSwap width)) [dst] [src] = do
dflags <- getDynFlags
let platform = targetPlatform dflags
let dst_r = getRegisterReg platform False (CmmLocal dst)
case width of
W64 | is32Bit -> do
ChildCode64 vcode rlo <- iselExpr64 src
let dst_rhi = getHiVRegFromLo dst_r
rhi = getHiVRegFromLo rlo
return $ vcode `appOL`
toOL [ MOV II32 (OpReg rlo) (OpReg dst_rhi),
MOV II32 (OpReg rhi) (OpReg dst_r),
BSWAP II32 dst_rhi,
BSWAP II32 dst_r ]
W16 -> do code_src <- getAnyReg src
return $ code_src dst_r `appOL`
unitOL (BSWAP II32 dst_r) `appOL`
unitOL (SHR II32 (OpImm $ ImmInt 16) (OpReg dst_r))
_ -> do code_src <- getAnyReg src
return $ code_src dst_r `appOL` unitOL (BSWAP size dst_r)
where
size = intSize width
genCCall is32Bit (PrimTarget (MO_PopCnt width)) dest_regs@[dst]
args@[src] = do
sse4_2 <- sse4_2Enabled
dflags <- getDynFlags
let platform = targetPlatform dflags
if sse4_2
then do code_src <- getAnyReg src
src_r <- getNewRegNat size
return $ code_src src_r `appOL`
(if width == W8 then
unitOL (MOVZxL II8 (OpReg src_r) (OpReg src_r)) `appOL`
unitOL (POPCNT II16 (OpReg src_r)
(getRegisterReg platform False (CmmLocal dst)))
else
unitOL (POPCNT size (OpReg src_r)
(getRegisterReg platform False (CmmLocal dst))))
else do
targetExpr <- cmmMakeDynamicReference dflags
CallReference lbl
let target = ForeignTarget targetExpr (ForeignConvention CCallConv
[NoHint] [NoHint]
CmmMayReturn)
genCCall is32Bit target dest_regs args
where
size = intSize width
lbl = mkCmmCodeLabel primPackageId (fsLit (popCntLabel width))
genCCall is32Bit (PrimTarget (MO_UF_Conv width)) dest_regs args = do
dflags <- getDynFlags
targetExpr <- cmmMakeDynamicReference dflags
CallReference lbl
let target = ForeignTarget targetExpr (ForeignConvention CCallConv
[NoHint] [NoHint]
CmmMayReturn)
genCCall is32Bit target dest_regs args
where
lbl = mkCmmCodeLabel primPackageId (fsLit (word2FloatLabel width))
genCCall is32Bit target dest_regs args
| is32Bit = genCCall32 target dest_regs args
| otherwise = genCCall64 target dest_regs args
genCCall32 :: ForeignTarget
-> [CmmFormal]
-> [CmmActual]
-> NatM InstrBlock
genCCall32 target dest_regs args = do
dflags <- getDynFlags
let platform = targetPlatform dflags
case (target, dest_regs) of
(PrimTarget op, []) ->
outOfLineCmmOp op Nothing args
(PrimTarget op, [r]) -> do
l1 <- getNewLabelNat
l2 <- getNewLabelNat
sse2 <- sse2Enabled
if sse2
then
outOfLineCmmOp op (Just r) args
else case op of
MO_F32_Sqrt -> actuallyInlineFloatOp GSQRT FF32 args
MO_F64_Sqrt -> actuallyInlineFloatOp GSQRT FF64 args
MO_F32_Sin -> actuallyInlineFloatOp (\s -> GSIN s l1 l2) FF32 args
MO_F64_Sin -> actuallyInlineFloatOp (\s -> GSIN s l1 l2) FF64 args
MO_F32_Cos -> actuallyInlineFloatOp (\s -> GCOS s l1 l2) FF32 args
MO_F64_Cos -> actuallyInlineFloatOp (\s -> GCOS s l1 l2) FF64 args
MO_F32_Tan -> actuallyInlineFloatOp (\s -> GTAN s l1 l2) FF32 args
MO_F64_Tan -> actuallyInlineFloatOp (\s -> GTAN s l1 l2) FF64 args
_other_op -> outOfLineCmmOp op (Just r) args
where
actuallyInlineFloatOp instr size [x]
= do res <- trivialUFCode size (instr size) x
any <- anyReg res
return (any (getRegisterReg platform False (CmmLocal r)))
actuallyInlineFloatOp _ _ args
= panic $ "genCCall32.actuallyInlineFloatOp: bad number of arguments! ("
++ show (length args) ++ ")"
(PrimTarget (MO_S_QuotRem width), _) -> divOp1 platform True width dest_regs args
(PrimTarget (MO_U_QuotRem width), _) -> divOp1 platform False width dest_regs args
(PrimTarget (MO_U_QuotRem2 width), _) -> divOp2 platform False width dest_regs args
(PrimTarget (MO_Add2 width), [res_h, res_l]) ->
case args of
[arg_x, arg_y] ->
do hCode <- getAnyReg (CmmLit (CmmInt 0 width))
lCode <- getAnyReg (CmmMachOp (MO_Add width) [arg_x, arg_y])
let size = intSize width
reg_l = getRegisterReg platform True (CmmLocal res_l)
reg_h = getRegisterReg platform True (CmmLocal res_h)
code = hCode reg_h `appOL`
lCode reg_l `snocOL`
ADC size (OpImm (ImmInteger 0)) (OpReg reg_h)
return code
_ -> panic "genCCall32: Wrong number of arguments/results for add2"
(PrimTarget (MO_U_Mul2 width), [res_h, res_l]) ->
case args of
[arg_x, arg_y] ->
do (y_reg, y_code) <- getRegOrMem arg_y
x_code <- getAnyReg arg_x
let size = intSize width
reg_h = getRegisterReg platform True (CmmLocal res_h)
reg_l = getRegisterReg platform True (CmmLocal res_l)
code = y_code `appOL`
x_code rax `appOL`
toOL [MUL2 size y_reg,
MOV size (OpReg rdx) (OpReg reg_h),
MOV size (OpReg rax) (OpReg reg_l)]
return code
_ -> panic "genCCall32: Wrong number of arguments/results for add2"
_ -> genCCall32' dflags target dest_regs args
where divOp1 platform signed width results [arg_x, arg_y]
= divOp platform signed width results Nothing arg_x arg_y
divOp1 _ _ _ _ _
= panic "genCCall32: Wrong number of arguments for divOp1"
divOp2 platform signed width results [arg_x_high, arg_x_low, arg_y]
= divOp platform signed width results (Just arg_x_high) arg_x_low arg_y
divOp2 _ _ _ _ _
= panic "genCCall64: Wrong number of arguments for divOp2"
divOp platform signed width [res_q, res_r]
m_arg_x_high arg_x_low arg_y
= do let size = intSize width
reg_q = getRegisterReg platform True (CmmLocal res_q)
reg_r = getRegisterReg platform True (CmmLocal res_r)
widen | signed = CLTD size
| otherwise = XOR size (OpReg rdx) (OpReg rdx)
instr | signed = IDIV
| otherwise = DIV
(y_reg, y_code) <- getRegOrMem arg_y
x_low_code <- getAnyReg arg_x_low
x_high_code <- case m_arg_x_high of
Just arg_x_high ->
getAnyReg arg_x_high
Nothing ->
return $ const $ unitOL widen
return $ y_code `appOL`
x_low_code rax `appOL`
x_high_code rdx `appOL`
toOL [instr size y_reg,
MOV size (OpReg rax) (OpReg reg_q),
MOV size (OpReg rdx) (OpReg reg_r)]
divOp _ _ _ _ _ _ _
= panic "genCCall32: Wrong number of results for divOp"
genCCall32' :: DynFlags
-> ForeignTarget
-> [CmmFormal]
-> [CmmActual]
-> NatM InstrBlock
genCCall32' dflags target dest_regs args = do
let
prom_args = map (maybePromoteCArg dflags W32) args
sizes = map (arg_size . cmmExprType dflags) (reverse args)
raw_arg_size = sum sizes + wORD_SIZE dflags
arg_pad_size = (roundTo 16 $ raw_arg_size) raw_arg_size
tot_arg_size = raw_arg_size + arg_pad_size wORD_SIZE dflags
delta0 <- getDeltaNat
setDeltaNat (delta0 arg_pad_size)
use_sse2 <- sse2Enabled
push_codes <- mapM (push_arg use_sse2) (reverse prom_args)
delta <- getDeltaNat
MASSERT(delta == delta0 tot_arg_size)
(callinsns,cconv) <-
case target of
ForeignTarget (CmmLit (CmmLabel lbl)) conv
->
return (unitOL (CALL (Left fn_imm) []), conv)
where fn_imm = ImmCLbl lbl
ForeignTarget expr conv
-> do { (dyn_r, dyn_c) <- getSomeReg expr
; ASSERT( isWord32 (cmmExprType dflags expr) )
return (dyn_c `snocOL` CALL (Right dyn_r) [], conv) }
PrimTarget _
-> panic $ "genCCall: Can't handle PrimTarget call type here, error "
++ "probably because too many return values."
let push_code
| arg_pad_size /= 0
= toOL [SUB II32 (OpImm (ImmInt arg_pad_size)) (OpReg esp),
DELTA (delta0 arg_pad_size)]
`appOL` concatOL push_codes
| otherwise
= concatOL push_codes
pop_size
| ForeignConvention StdCallConv _ _ _ <- cconv = arg_pad_size
| otherwise = tot_arg_size
call = callinsns `appOL`
toOL (
(if pop_size==0 then [] else
[ADD II32 (OpImm (ImmInt pop_size)) (OpReg esp)])
++
[DELTA delta0]
)
setDeltaNat delta0
dflags <- getDynFlags
let platform = targetPlatform dflags
let
assign_code [] = nilOL
assign_code [dest]
| isFloatType ty =
if use_sse2
then let tmp_amode = AddrBaseIndex (EABaseReg esp)
EAIndexNone
(ImmInt 0)
sz = floatSize w
in toOL [ SUB II32 (OpImm (ImmInt b)) (OpReg esp),
DELTA (delta0 b),
GST sz fake0 tmp_amode,
MOV sz (OpAddr tmp_amode) (OpReg r_dest),
ADD II32 (OpImm (ImmInt b)) (OpReg esp),
DELTA delta0]
else unitOL (GMOV fake0 r_dest)
| isWord64 ty = toOL [MOV II32 (OpReg eax) (OpReg r_dest),
MOV II32 (OpReg edx) (OpReg r_dest_hi)]
| otherwise = unitOL (MOV (intSize w) (OpReg eax) (OpReg r_dest))
where
ty = localRegType dest
w = typeWidth ty
b = widthInBytes w
r_dest_hi = getHiVRegFromLo r_dest
r_dest = getRegisterReg platform use_sse2 (CmmLocal dest)
assign_code many = pprPanic "genCCall.assign_code - too many return values:" (ppr many)
return (push_code `appOL`
call `appOL`
assign_code dest_regs)
where
arg_size :: CmmType -> Int
arg_size ty = widthInBytes (typeWidth ty)
roundTo a x | x `mod` a == 0 = x
| otherwise = x + a (x `mod` a)
push_arg :: Bool -> CmmActual
-> NatM InstrBlock
push_arg use_sse2 arg
| isWord64 arg_ty = do
ChildCode64 code r_lo <- iselExpr64 arg
delta <- getDeltaNat
setDeltaNat (delta 8)
let
r_hi = getHiVRegFromLo r_lo
return ( code `appOL`
toOL [PUSH II32 (OpReg r_hi), DELTA (delta 4),
PUSH II32 (OpReg r_lo), DELTA (delta 8),
DELTA (delta8)]
)
| isFloatType arg_ty = do
(reg, code) <- getSomeReg arg
delta <- getDeltaNat
setDeltaNat (deltasize)
return (code `appOL`
toOL [SUB II32 (OpImm (ImmInt size)) (OpReg esp),
DELTA (deltasize),
let addr = AddrBaseIndex (EABaseReg esp)
EAIndexNone
(ImmInt 0)
size = floatSize (typeWidth arg_ty)
in
if use_sse2
then MOV size (OpReg reg) (OpAddr addr)
else GST size reg addr
]
)
| otherwise = do
(operand, code) <- getOperand arg
delta <- getDeltaNat
setDeltaNat (deltasize)
return (code `snocOL`
PUSH II32 operand `snocOL`
DELTA (deltasize))
where
arg_ty = cmmExprType dflags arg
size = arg_size arg_ty
genCCall64 :: ForeignTarget
-> [CmmFormal]
-> [CmmActual]
-> NatM InstrBlock
genCCall64 target dest_regs args = do
dflags <- getDynFlags
let platform = targetPlatform dflags
case (target, dest_regs) of
(PrimTarget op, []) ->
outOfLineCmmOp op Nothing args
(PrimTarget op, [res]) ->
outOfLineCmmOp op (Just res) args
(PrimTarget (MO_S_QuotRem width), _) -> divOp1 platform True width dest_regs args
(PrimTarget (MO_U_QuotRem width), _) -> divOp1 platform False width dest_regs args
(PrimTarget (MO_U_QuotRem2 width), _) -> divOp2 platform False width dest_regs args
(PrimTarget (MO_Add2 width), [res_h, res_l]) ->
case args of
[arg_x, arg_y] ->
do hCode <- getAnyReg (CmmLit (CmmInt 0 width))
lCode <- getAnyReg (CmmMachOp (MO_Add width) [arg_x, arg_y])
let size = intSize width
reg_l = getRegisterReg platform True (CmmLocal res_l)
reg_h = getRegisterReg platform True (CmmLocal res_h)
code = hCode reg_h `appOL`
lCode reg_l `snocOL`
ADC size (OpImm (ImmInteger 0)) (OpReg reg_h)
return code
_ -> panic "genCCall64: Wrong number of arguments/results for add2"
(PrimTarget (MO_U_Mul2 width), [res_h, res_l]) ->
case args of
[arg_x, arg_y] ->
do (y_reg, y_code) <- getRegOrMem arg_y
x_code <- getAnyReg arg_x
let size = intSize width
reg_h = getRegisterReg platform True (CmmLocal res_h)
reg_l = getRegisterReg platform True (CmmLocal res_l)
code = y_code `appOL`
x_code rax `appOL`
toOL [MUL2 size y_reg,
MOV size (OpReg rdx) (OpReg reg_h),
MOV size (OpReg rax) (OpReg reg_l)]
return code
_ -> panic "genCCall64: Wrong number of arguments/results for add2"
_ ->
do dflags <- getDynFlags
genCCall64' dflags target dest_regs args
where divOp1 platform signed width results [arg_x, arg_y]
= divOp platform signed width results Nothing arg_x arg_y
divOp1 _ _ _ _ _
= panic "genCCall64: Wrong number of arguments for divOp1"
divOp2 platform signed width results [arg_x_high, arg_x_low, arg_y]
= divOp platform signed width results (Just arg_x_high) arg_x_low arg_y
divOp2 _ _ _ _ _
= panic "genCCall64: Wrong number of arguments for divOp2"
divOp platform signed width [res_q, res_r]
m_arg_x_high arg_x_low arg_y
= do let size = intSize width
reg_q = getRegisterReg platform True (CmmLocal res_q)
reg_r = getRegisterReg platform True (CmmLocal res_r)
widen | signed = CLTD size
| otherwise = XOR size (OpReg rdx) (OpReg rdx)
instr | signed = IDIV
| otherwise = DIV
(y_reg, y_code) <- getRegOrMem arg_y
x_low_code <- getAnyReg arg_x_low
x_high_code <- case m_arg_x_high of
Just arg_x_high -> getAnyReg arg_x_high
Nothing -> return $ const $ unitOL widen
return $ y_code `appOL`
x_low_code rax `appOL`
x_high_code rdx `appOL`
toOL [instr size y_reg,
MOV size (OpReg rax) (OpReg reg_q),
MOV size (OpReg rdx) (OpReg reg_r)]
divOp _ _ _ _ _ _ _
= panic "genCCall64: Wrong number of results for divOp"
genCCall64' :: DynFlags
-> ForeignTarget
-> [CmmFormal]
-> [CmmActual]
-> NatM InstrBlock
genCCall64' dflags target dest_regs args = do
let prom_args = map (maybePromoteCArg dflags W32) args
(stack_args, int_regs_used, fp_regs_used, load_args_code)
<-
if platformOS platform == OSMinGW32
then load_args_win prom_args [] [] (allArgRegs platform) nilOL
else do (stack_args, aregs, fregs, load_args_code)
<- load_args prom_args (allIntArgRegs platform) (allFPArgRegs platform) nilOL
let fp_regs_used = reverse (drop (length fregs) (reverse (allFPArgRegs platform)))
int_regs_used = reverse (drop (length aregs) (reverse (allIntArgRegs platform)))
return (stack_args, int_regs_used, fp_regs_used, load_args_code)
let
arg_regs_used = int_regs_used ++ fp_regs_used
arg_regs = [eax] ++ arg_regs_used
sse_regs = length fp_regs_used
arg_stack_slots = if platformOS platform == OSMinGW32
then length stack_args + length (allArgRegs platform)
else length stack_args
tot_arg_size = arg_size * arg_stack_slots
(real_size, adjust_rsp) <-
if (tot_arg_size + wORD_SIZE dflags) `rem` 16 == 0
then return (tot_arg_size, nilOL)
else do
delta <- getDeltaNat
setDeltaNat (delta wORD_SIZE dflags)
return (tot_arg_size + wORD_SIZE dflags, toOL [
SUB II64 (OpImm (ImmInt (wORD_SIZE dflags))) (OpReg rsp),
DELTA (delta wORD_SIZE dflags) ])
push_code <- push_args (reverse stack_args) nilOL
lss_code <- if platformOS platform == OSMinGW32
then leaveStackSpace (length (allArgRegs platform))
else return nilOL
delta <- getDeltaNat
(callinsns,_cconv) <-
case target of
ForeignTarget (CmmLit (CmmLabel lbl)) conv
->
return (unitOL (CALL (Left fn_imm) arg_regs), conv)
where fn_imm = ImmCLbl lbl
ForeignTarget expr conv
-> do (dyn_r, dyn_c) <- getSomeReg expr
return (dyn_c `snocOL` CALL (Right dyn_r) arg_regs, conv)
PrimTarget _
-> panic $ "genCCall: Can't handle PrimTarget call type here, error "
++ "probably because too many return values."
let
assign_eax n = unitOL (MOV II32 (OpImm (ImmInt n)) (OpReg eax))
let call = callinsns `appOL`
toOL (
(if real_size==0 then [] else
[ADD (intSize (wordWidth dflags)) (OpImm (ImmInt real_size)) (OpReg esp)])
++
[DELTA (delta + real_size)]
)
setDeltaNat (delta + real_size)
let
assign_code [] = nilOL
assign_code [dest] =
case typeWidth rep of
W32 | isFloatType rep -> unitOL (MOV (floatSize W32) (OpReg xmm0) (OpReg r_dest))
W64 | isFloatType rep -> unitOL (MOV (floatSize W64) (OpReg xmm0) (OpReg r_dest))
_ -> unitOL (MOV (cmmTypeSize rep) (OpReg rax) (OpReg r_dest))
where
rep = localRegType dest
r_dest = getRegisterReg platform True (CmmLocal dest)
assign_code _many = panic "genCCall.assign_code many"
return (load_args_code `appOL`
adjust_rsp `appOL`
push_code `appOL`
lss_code `appOL`
assign_eax sse_regs `appOL`
call `appOL`
assign_code dest_regs)
where platform = targetPlatform dflags
arg_size = 8
load_args :: [CmmExpr]
-> [Reg]
-> [Reg]
-> InstrBlock
-> NatM ([CmmExpr],[Reg],[Reg],InstrBlock)
load_args args [] [] code = return (args, [], [], code)
load_args [] aregs fregs code = return ([], aregs, fregs, code)
load_args (arg : rest) aregs fregs code
| isFloatType arg_rep =
case fregs of
[] -> push_this_arg
(r:rs) -> do
arg_code <- getAnyReg arg
load_args rest aregs rs (code `appOL` arg_code r)
| otherwise =
case aregs of
[] -> push_this_arg
(r:rs) -> do
arg_code <- getAnyReg arg
load_args rest rs fregs (code `appOL` arg_code r)
where
arg_rep = cmmExprType dflags arg
push_this_arg = do
(args',ars,frs,code') <- load_args rest aregs fregs code
return (arg:args', ars, frs, code')
load_args_win :: [CmmExpr]
-> [Reg]
-> [Reg]
-> [(Reg, Reg)]
-> InstrBlock
-> NatM ([CmmExpr],[Reg],[Reg],InstrBlock)
load_args_win args usedInt usedFP [] code
= return (args, usedInt, usedFP, code)
load_args_win [] usedInt usedFP _ code
= return ([], usedInt, usedFP, code)
load_args_win (arg : rest) usedInt usedFP
((ireg, freg) : regs) code
| isFloatType arg_rep = do
arg_code <- getAnyReg arg
load_args_win rest (ireg : usedInt) (freg : usedFP) regs
(code `appOL`
arg_code freg `snocOL`
MOV II64 (OpReg freg) (OpReg ireg))
| otherwise = do
arg_code <- getAnyReg arg
load_args_win rest (ireg : usedInt) usedFP regs
(code `appOL` arg_code ireg)
where
arg_rep = cmmExprType dflags arg
push_args [] code = return code
push_args (arg:rest) code
| isFloatType arg_rep = do
(arg_reg, arg_code) <- getSomeReg arg
delta <- getDeltaNat
setDeltaNat (deltaarg_size)
let code' = code `appOL` arg_code `appOL` toOL [
SUB (intSize (wordWidth dflags)) (OpImm (ImmInt arg_size)) (OpReg rsp) ,
DELTA (deltaarg_size),
MOV (floatSize width) (OpReg arg_reg) (OpAddr (spRel dflags 0))]
push_args rest code'
| otherwise = do
ASSERT(width == W64) return ()
(arg_op, arg_code) <- getOperand arg
delta <- getDeltaNat
setDeltaNat (deltaarg_size)
let code' = code `appOL` arg_code `appOL` toOL [
PUSH II64 arg_op,
DELTA (deltaarg_size)]
push_args rest code'
where
arg_rep = cmmExprType dflags arg
width = typeWidth arg_rep
leaveStackSpace n = do
delta <- getDeltaNat
setDeltaNat (delta n * arg_size)
return $ toOL [
SUB II64 (OpImm (ImmInt (n * wORD_SIZE dflags))) (OpReg rsp),
DELTA (delta n * arg_size)]
maybePromoteCArg :: DynFlags -> Width -> CmmExpr -> CmmExpr
maybePromoteCArg dflags wto arg
| wfrom < wto = CmmMachOp (MO_UU_Conv wfrom wto) [arg]
| otherwise = arg
where
wfrom = cmmExprWidth dflags arg
maxInlineSizeThreshold :: Integer
maxInlineSizeThreshold = 128
outOfLineCmmOp :: CallishMachOp -> Maybe CmmFormal -> [CmmActual] -> NatM InstrBlock
outOfLineCmmOp mop res args
= do
dflags <- getDynFlags
targetExpr <- cmmMakeDynamicReference dflags CallReference lbl
let target = ForeignTarget targetExpr
(ForeignConvention CCallConv [] [] CmmMayReturn)
stmtToInstrs (CmmUnsafeForeignCall target (catMaybes [res]) args')
where
lbl = mkForeignLabel fn Nothing ForeignLabelInThisPackage IsFunction
args' = case mop of
MO_Memcpy -> init args
MO_Memset -> init args
MO_Memmove -> init args
_ -> args
fn = case mop of
MO_F32_Sqrt -> fsLit "sqrtf"
MO_F32_Sin -> fsLit "sinf"
MO_F32_Cos -> fsLit "cosf"
MO_F32_Tan -> fsLit "tanf"
MO_F32_Exp -> fsLit "expf"
MO_F32_Log -> fsLit "logf"
MO_F32_Asin -> fsLit "asinf"
MO_F32_Acos -> fsLit "acosf"
MO_F32_Atan -> fsLit "atanf"
MO_F32_Sinh -> fsLit "sinhf"
MO_F32_Cosh -> fsLit "coshf"
MO_F32_Tanh -> fsLit "tanhf"
MO_F32_Pwr -> fsLit "powf"
MO_F64_Sqrt -> fsLit "sqrt"
MO_F64_Sin -> fsLit "sin"
MO_F64_Cos -> fsLit "cos"
MO_F64_Tan -> fsLit "tan"
MO_F64_Exp -> fsLit "exp"
MO_F64_Log -> fsLit "log"
MO_F64_Asin -> fsLit "asin"
MO_F64_Acos -> fsLit "acos"
MO_F64_Atan -> fsLit "atan"
MO_F64_Sinh -> fsLit "sinh"
MO_F64_Cosh -> fsLit "cosh"
MO_F64_Tanh -> fsLit "tanh"
MO_F64_Pwr -> fsLit "pow"
MO_Memcpy -> fsLit "memcpy"
MO_Memset -> fsLit "memset"
MO_Memmove -> fsLit "memmove"
MO_PopCnt _ -> fsLit "popcnt"
MO_BSwap _ -> fsLit "bswap"
MO_UF_Conv _ -> unsupported
MO_S_QuotRem {} -> unsupported
MO_U_QuotRem {} -> unsupported
MO_U_QuotRem2 {} -> unsupported
MO_Add2 {} -> unsupported
MO_U_Mul2 {} -> unsupported
MO_WriteBarrier -> unsupported
MO_Touch -> unsupported
(MO_Prefetch_Data _ ) -> unsupported
unsupported = panic ("outOfLineCmmOp: " ++ show mop
++ " not supported here")
genSwitch :: DynFlags -> CmmExpr -> [Maybe BlockId] -> NatM InstrBlock
genSwitch dflags expr ids
| gopt Opt_PIC dflags
= do
(reg,e_code) <- getSomeReg expr
lbl <- getNewLabelNat
dflags <- getDynFlags
dynRef <- cmmMakeDynamicReference dflags DataReference lbl
(tableReg,t_code) <- getSomeReg $ dynRef
let op = OpAddr (AddrBaseIndex (EABaseReg tableReg)
(EAIndex reg (wORD_SIZE dflags)) (ImmInt 0))
return $ if target32Bit (targetPlatform dflags)
then e_code `appOL` t_code `appOL` toOL [
ADD (intSize (wordWidth dflags)) op (OpReg tableReg),
JMP_TBL (OpReg tableReg) ids ReadOnlyData lbl
]
else case platformOS (targetPlatform dflags) of
OSDarwin ->
e_code `appOL` t_code `appOL` toOL [
ADD (intSize (wordWidth dflags)) op (OpReg tableReg),
JMP_TBL (OpReg tableReg) ids Text lbl
]
_ ->
e_code `appOL` t_code `appOL` toOL [
MOVSxL II32 op (OpReg reg),
ADD (intSize (wordWidth dflags)) (OpReg reg) (OpReg tableReg),
JMP_TBL (OpReg tableReg) ids ReadOnlyData lbl
]
| otherwise
= do
(reg,e_code) <- getSomeReg expr
lbl <- getNewLabelNat
let op = OpAddr (AddrBaseIndex EABaseNone (EAIndex reg (wORD_SIZE dflags)) (ImmCLbl lbl))
code = e_code `appOL` toOL [
JMP_TBL op ids ReadOnlyData lbl
]
return code
generateJumpTableForInstr :: DynFlags -> Instr -> Maybe (NatCmmDecl (Alignment, CmmStatics) Instr)
generateJumpTableForInstr dflags (JMP_TBL _ ids section lbl)
= Just (createJumpTable dflags ids section lbl)
generateJumpTableForInstr _ _ = Nothing
createJumpTable :: DynFlags -> [Maybe BlockId] -> Section -> CLabel
-> GenCmmDecl (Alignment, CmmStatics) h g
createJumpTable dflags ids section lbl
= let jumpTable
| gopt Opt_PIC dflags =
let jumpTableEntryRel Nothing
= CmmStaticLit (CmmInt 0 (wordWidth dflags))
jumpTableEntryRel (Just blockid)
= CmmStaticLit (CmmLabelDiffOff blockLabel lbl 0)
where blockLabel = mkAsmTempLabel (getUnique blockid)
in map jumpTableEntryRel ids
| otherwise = map (jumpTableEntry dflags) ids
in CmmData section (1, Statics lbl jumpTable)
condIntReg :: Cond -> CmmExpr -> CmmExpr -> NatM Register
condIntReg cond x y = do
CondCode _ cond cond_code <- condIntCode cond x y
tmp <- getNewRegNat II8
let
code dst = cond_code `appOL` toOL [
SETCC cond (OpReg tmp),
MOVZxL II8 (OpReg tmp) (OpReg dst)
]
return (Any II32 code)
condFltReg :: Bool -> Cond -> CmmExpr -> CmmExpr -> NatM Register
condFltReg is32Bit cond x y = if_sse2 condFltReg_sse2 condFltReg_x87
where
condFltReg_x87 = do
CondCode _ cond cond_code <- condFltCode cond x y
tmp <- getNewRegNat II8
let
code dst = cond_code `appOL` toOL [
SETCC cond (OpReg tmp),
MOVZxL II8 (OpReg tmp) (OpReg dst)
]
return (Any II32 code)
condFltReg_sse2 = do
CondCode _ cond cond_code <- condFltCode cond x y
tmp1 <- getNewRegNat (archWordSize is32Bit)
tmp2 <- getNewRegNat (archWordSize is32Bit)
let
code dst =
cond_code `appOL`
(case cond of
NE -> or_unordered dst
GU -> plain_test dst
GEU -> plain_test dst
_ -> and_ordered dst)
plain_test dst = toOL [
SETCC cond (OpReg tmp1),
MOVZxL II8 (OpReg tmp1) (OpReg dst)
]
or_unordered dst = toOL [
SETCC cond (OpReg tmp1),
SETCC PARITY (OpReg tmp2),
OR II8 (OpReg tmp1) (OpReg tmp2),
MOVZxL II8 (OpReg tmp2) (OpReg dst)
]
and_ordered dst = toOL [
SETCC cond (OpReg tmp1),
SETCC NOTPARITY (OpReg tmp2),
AND II8 (OpReg tmp1) (OpReg tmp2),
MOVZxL II8 (OpReg tmp2) (OpReg dst)
]
return (Any II32 code)
trivialCode :: Width -> (Operand -> Operand -> Instr)
-> Maybe (Operand -> Operand -> Instr)
-> CmmExpr -> CmmExpr -> NatM Register
trivialCode width instr m a b
= do is32Bit <- is32BitPlatform
trivialCode' is32Bit width instr m a b
trivialCode' :: Bool -> Width -> (Operand -> Operand -> Instr)
-> Maybe (Operand -> Operand -> Instr)
-> CmmExpr -> CmmExpr -> NatM Register
trivialCode' is32Bit width _ (Just revinstr) (CmmLit lit_a) b
| is32BitLit is32Bit lit_a = do
b_code <- getAnyReg b
let
code dst
= b_code dst `snocOL`
revinstr (OpImm (litToImm lit_a)) (OpReg dst)
return (Any (intSize width) code)
trivialCode' _ width instr _ a b
= genTrivialCode (intSize width) instr a b
genTrivialCode :: Size -> (Operand -> Operand -> Instr)
-> CmmExpr -> CmmExpr -> NatM Register
genTrivialCode rep instr a b = do
(b_op, b_code) <- getNonClobberedOperand b
a_code <- getAnyReg a
tmp <- getNewRegNat rep
let
code dst
| dst `regClashesWithOp` b_op =
b_code `appOL`
unitOL (MOV rep b_op (OpReg tmp)) `appOL`
a_code dst `snocOL`
instr (OpReg tmp) (OpReg dst)
| otherwise =
b_code `appOL`
a_code dst `snocOL`
instr b_op (OpReg dst)
return (Any rep code)
regClashesWithOp :: Reg -> Operand -> Bool
reg `regClashesWithOp` OpReg reg2 = reg == reg2
reg `regClashesWithOp` OpAddr amode = any (==reg) (addrModeRegs amode)
_ `regClashesWithOp` _ = False
trivialUCode :: Size -> (Operand -> Instr)
-> CmmExpr -> NatM Register
trivialUCode rep instr x = do
x_code <- getAnyReg x
let
code dst =
x_code dst `snocOL`
instr (OpReg dst)
return (Any rep code)
trivialFCode_x87 :: (Size -> Reg -> Reg -> Reg -> Instr)
-> CmmExpr -> CmmExpr -> NatM Register
trivialFCode_x87 instr x y = do
(x_reg, x_code) <- getNonClobberedReg x
(y_reg, y_code) <- getSomeReg y
let
size = FF80
code dst =
x_code `appOL`
y_code `snocOL`
instr size x_reg y_reg dst
return (Any size code)
trivialFCode_sse2 :: Width -> (Size -> Operand -> Operand -> Instr)
-> CmmExpr -> CmmExpr -> NatM Register
trivialFCode_sse2 pk instr x y
= genTrivialCode size (instr size) x y
where size = floatSize pk
trivialUFCode :: Size -> (Reg -> Reg -> Instr) -> CmmExpr -> NatM Register
trivialUFCode size instr x = do
(x_reg, x_code) <- getSomeReg x
let
code dst =
x_code `snocOL`
instr x_reg dst
return (Any size code)
coerceInt2FP :: Width -> Width -> CmmExpr -> NatM Register
coerceInt2FP from to x = if_sse2 coerce_sse2 coerce_x87
where
coerce_x87 = do
(x_reg, x_code) <- getSomeReg x
let
opc = case to of W32 -> GITOF; W64 -> GITOD;
n -> panic $ "coerceInt2FP.x87: unhandled width ("
++ show n ++ ")"
code dst = x_code `snocOL` opc x_reg dst
return (Any FF80 code)
coerce_sse2 = do
(x_op, x_code) <- getOperand x
let
opc = case to of W32 -> CVTSI2SS; W64 -> CVTSI2SD
n -> panic $ "coerceInt2FP.sse: unhandled width ("
++ show n ++ ")"
code dst = x_code `snocOL` opc (intSize from) x_op dst
return (Any (floatSize to) code)
coerceFP2Int :: Width -> Width -> CmmExpr -> NatM Register
coerceFP2Int from to x = if_sse2 coerceFP2Int_sse2 coerceFP2Int_x87
where
coerceFP2Int_x87 = do
(x_reg, x_code) <- getSomeReg x
let
opc = case from of W32 -> GFTOI; W64 -> GDTOI
n -> panic $ "coerceFP2Int.x87: unhandled width ("
++ show n ++ ")"
code dst = x_code `snocOL` opc x_reg dst
return (Any (intSize to) code)
coerceFP2Int_sse2 = do
(x_op, x_code) <- getOperand x
let
opc = case from of W32 -> CVTTSS2SIQ; W64 -> CVTTSD2SIQ;
n -> panic $ "coerceFP2Init.sse: unhandled width ("
++ show n ++ ")"
code dst = x_code `snocOL` opc (intSize to) x_op dst
return (Any (intSize to) code)
coerceFP2FP :: Width -> CmmExpr -> NatM Register
coerceFP2FP to x = do
use_sse2 <- sse2Enabled
(x_reg, x_code) <- getSomeReg x
let
opc | use_sse2 = case to of W32 -> CVTSD2SS; W64 -> CVTSS2SD;
n -> panic $ "coerceFP2FP: unhandled width ("
++ show n ++ ")"
| otherwise = GDTOF
code dst = x_code `snocOL` opc x_reg dst
return (Any (if use_sse2 then floatSize to else FF80) code)
sse2NegCode :: Width -> CmmExpr -> NatM Register
sse2NegCode w x = do
let sz = floatSize w
x_code <- getAnyReg x
let
const | FF32 <- sz = CmmInt 0x80000000 W32
| otherwise = CmmInt 0x8000000000000000 W64
Amode amode amode_code <- memConstant (widthInBytes w) const
tmp <- getNewRegNat sz
let
code dst = x_code dst `appOL` amode_code `appOL` toOL [
MOV sz (OpAddr amode) (OpReg tmp),
XOR sz (OpReg tmp) (OpReg dst)
]
return (Any sz code)
isVecExpr :: CmmExpr -> Bool
isVecExpr (CmmMachOp (MO_V_Insert {}) _) = True
isVecExpr (CmmMachOp (MO_V_Extract {}) _) = True
isVecExpr (CmmMachOp (MO_V_Add {}) _) = True
isVecExpr (CmmMachOp (MO_V_Sub {}) _) = True
isVecExpr (CmmMachOp (MO_V_Mul {}) _) = True
isVecExpr (CmmMachOp (MO_VS_Quot {}) _) = True
isVecExpr (CmmMachOp (MO_VS_Rem {}) _) = True
isVecExpr (CmmMachOp (MO_VS_Neg {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Insert {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Extract {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Add {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Sub {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Mul {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Quot {}) _) = True
isVecExpr (CmmMachOp (MO_VF_Neg {}) _) = True
isVecExpr (CmmMachOp _ [e]) = isVecExpr e
isVecExpr _ = False
needLlvm :: NatM a
needLlvm =
sorry $ unlines ["The native code generator does not support vector"
,"instructions. Please use -fllvm."]