%
% (c) The University of Glasgow 2002-2006
%
ByteCodeLink: Bytecode assembler and linker
\begin{code}
module ByteCodeAsm (
assembleBCOs, assembleBCO,
CompiledByteCode(..),
UnlinkedBCO(..), BCOPtr(..), BCONPtr(..), bcoFreeNames,
SizedSeq, sizeSS, ssElts,
iNTERP_STACK_CHECK_THRESH
) where
#include "HsVersions.h"
import ByteCodeInstr
import ByteCodeItbls
import Name
import NameSet
import Literal
import TyCon
import PrimOp
import FastString
import StgCmmLayout ( ArgRep(..) )
import SMRep
import DynFlags
import Outputable
import Platform
import Util
import Control.Monad
import Control.Monad.ST ( runST )
import Control.Monad.Trans.Class
import Control.Monad.Trans.State.Strict
import Data.Array.MArray
import qualified Data.Array.Unboxed as Array
import Data.Array.Base ( UArray(..) )
import Data.Array.Unsafe( castSTUArray )
import Foreign
import Data.Char ( ord )
import Data.List
import Data.Map (Map)
import Data.Maybe (fromMaybe)
import qualified Data.Map as Map
import GHC.Base ( ByteArray#, MutableByteArray#, RealWorld )
data CompiledByteCode
= ByteCode [UnlinkedBCO]
ItblEnv
instance Outputable CompiledByteCode where
ppr (ByteCode bcos _) = ppr bcos
data UnlinkedBCO
= UnlinkedBCO {
unlinkedBCOName :: Name,
unlinkedBCOArity :: Int,
unlinkedBCOInstrs :: ByteArray#,
unlinkedBCOBitmap :: ByteArray#,
unlinkedBCOLits :: (SizedSeq BCONPtr),
unlinkedBCOPtrs :: (SizedSeq BCOPtr)
}
data BCOPtr
= BCOPtrName Name
| BCOPtrPrimOp PrimOp
| BCOPtrBCO UnlinkedBCO
| BCOPtrBreakInfo BreakInfo
| BCOPtrArray (MutableByteArray# RealWorld)
data BCONPtr
= BCONPtrWord Word
| BCONPtrLbl FastString
| BCONPtrItbl Name
bcoFreeNames :: UnlinkedBCO -> NameSet
bcoFreeNames bco
= bco_refs bco `minusNameSet` mkNameSet [unlinkedBCOName bco]
where
bco_refs (UnlinkedBCO _ _ _ _ nonptrs ptrs)
= unionManyNameSets (
mkNameSet [ n | BCOPtrName n <- ssElts ptrs ] :
mkNameSet [ n | BCONPtrItbl n <- ssElts nonptrs ] :
map bco_refs [ bco | BCOPtrBCO bco <- ssElts ptrs ]
)
instance Outputable UnlinkedBCO where
ppr (UnlinkedBCO nm _arity _insns _bitmap lits ptrs)
= sep [text "BCO", ppr nm, text "with",
ppr (sizeSS lits), text "lits",
ppr (sizeSS ptrs), text "ptrs" ]
assembleBCOs :: DynFlags -> [ProtoBCO Name] -> [TyCon] -> IO CompiledByteCode
assembleBCOs dflags proto_bcos tycons
= do itblenv <- mkITbls dflags tycons
bcos <- mapM (assembleBCO dflags) proto_bcos
return (ByteCode bcos itblenv)
assembleBCO :: DynFlags -> ProtoBCO Name -> IO UnlinkedBCO
assembleBCO dflags (ProtoBCO nm instrs bitmap bsize arity _origin _malloced) = do
let asm = mapM_ (assembleI dflags) instrs
initial_offset = 0
(n_insns0, lbl_map0) = inspectAsm dflags False initial_offset asm
((n_insns, lbl_map), long_jumps)
| isLarge n_insns0 = (inspectAsm dflags True initial_offset asm, True)
| otherwise = ((n_insns0, lbl_map0), False)
env :: Word16 -> Word
env lbl = fromMaybe
(pprPanic "assembleBCO.findLabel" (ppr lbl))
(Map.lookup lbl lbl_map)
let initial_state = (emptySS, emptySS, emptySS)
(final_insns, final_lits, final_ptrs) <- flip execStateT initial_state $ runAsm dflags long_jumps env asm
ASSERT(n_insns == sizeSS final_insns) return ()
let asm_insns = ssElts final_insns
barr a = case a of UArray _lo _hi _n b -> b
insns_arr = Array.listArray (0, n_insns 1) asm_insns
!insns_barr = barr insns_arr
bitmap_arr = mkBitmapArray dflags bsize bitmap
!bitmap_barr = toByteArray bitmap_arr
ul_bco = UnlinkedBCO nm arity insns_barr bitmap_barr final_lits final_ptrs
return ul_bco
#if __GLASGOW_HASKELL__ > 706
mkBitmapArray :: DynFlags -> Word16 -> [StgWord] -> UArrayStgWord Int
mkBitmapArray dflags bsize bitmap
= SMRep.listArray (0, length bitmap) (toStgWord dflags (toInteger bsize) : bitmap)
#else
mkBitmapArray :: DynFlags -> Word16 -> [StgWord] -> UArray Int StgWord
mkBitmapArray dflags bsize bitmap
= Array.listArray (0, length bitmap) (toStgWord dflags (toInteger bsize) : bitmap)
#endif
type AsmState = (SizedSeq Word16,
SizedSeq BCONPtr,
SizedSeq BCOPtr)
data SizedSeq a = SizedSeq !Word [a]
emptySS :: SizedSeq a
emptySS = SizedSeq 0 []
addToSS :: SizedSeq a -> a -> SizedSeq a
addToSS (SizedSeq n r_xs) x = SizedSeq (n+1) (x:r_xs)
addListToSS :: SizedSeq a -> [a] -> SizedSeq a
addListToSS (SizedSeq n r_xs) xs
= SizedSeq (n + genericLength xs) (reverse xs ++ r_xs)
ssElts :: SizedSeq a -> [a]
ssElts (SizedSeq _ r_xs) = reverse r_xs
sizeSS :: SizedSeq a -> Word
sizeSS (SizedSeq n _) = n
data Operand
= Op Word
| SmallOp Word16
| LabelOp Word16
data Assembler a
= AllocPtr (IO BCOPtr) (Word -> Assembler a)
| AllocLit [BCONPtr] (Word -> Assembler a)
| AllocLabel Word16 (Assembler a)
| Emit Word16 [Operand] (Assembler a)
| NullAsm a
instance Monad Assembler where
return = NullAsm
NullAsm x >>= f = f x
AllocPtr p k >>= f = AllocPtr p (k >=> f)
AllocLit l k >>= f = AllocLit l (k >=> f)
AllocLabel lbl k >>= f = AllocLabel lbl (k >>= f)
Emit w ops k >>= f = Emit w ops (k >>= f)
ioptr :: IO BCOPtr -> Assembler Word
ioptr p = AllocPtr p return
ptr :: BCOPtr -> Assembler Word
ptr = ioptr . return
lit :: [BCONPtr] -> Assembler Word
lit l = AllocLit l return
label :: Word16 -> Assembler ()
label w = AllocLabel w (return ())
emit :: Word16 -> [Operand] -> Assembler ()
emit w ops = Emit w ops (return ())
type LabelEnv = Word16 -> Word
largeOp :: Bool -> Operand -> Bool
largeOp long_jumps op = case op of
SmallOp _ -> False
Op w -> isLarge w
LabelOp _ -> long_jumps
runAsm :: DynFlags -> Bool -> LabelEnv -> Assembler a -> StateT AsmState IO a
runAsm dflags long_jumps e = go
where
go (NullAsm x) = return x
go (AllocPtr p_io k) = do
p <- lift p_io
w <- state $ \(st_i0,st_l0,st_p0) ->
let st_p1 = addToSS st_p0 p
in (sizeSS st_p0, (st_i0,st_l0,st_p1))
go $ k w
go (AllocLit lits k) = do
w <- state $ \(st_i0,st_l0,st_p0) ->
let st_l1 = addListToSS st_l0 lits
in (sizeSS st_l0, (st_i0,st_l1,st_p0))
go $ k w
go (AllocLabel _ k) = go k
go (Emit w ops k) = do
let largeOps = any (largeOp long_jumps) ops
opcode
| largeOps = largeArgInstr w
| otherwise = w
words = concatMap expand ops
expand (SmallOp w) = [w]
expand (LabelOp w) = expand (Op (e w))
expand (Op w) = if largeOps then largeArg dflags w else [fromIntegral w]
state $ \(st_i0,st_l0,st_p0) ->
let st_i1 = addListToSS st_i0 (opcode : words)
in ((), (st_i1,st_l0,st_p0))
go k
type LabelEnvMap = Map Word16 Word
data InspectState = InspectState
{ instrCount :: !Word
, ptrCount :: !Word
, litCount :: !Word
, lblEnv :: LabelEnvMap
}
inspectAsm :: DynFlags -> Bool -> Word -> Assembler a -> (Word, LabelEnvMap)
inspectAsm dflags long_jumps initial_offset
= go (InspectState initial_offset 0 0 Map.empty)
where
go s (NullAsm _) = (instrCount s, lblEnv s)
go s (AllocPtr _ k) = go (s { ptrCount = n + 1 }) (k n)
where n = ptrCount s
go s (AllocLit ls k) = go (s { litCount = n + genericLength ls }) (k n)
where n = litCount s
go s (AllocLabel lbl k) = go s' k
where s' = s { lblEnv = Map.insert lbl (instrCount s) (lblEnv s) }
go s (Emit _ ops k) = go s' k
where
s' = s { instrCount = instrCount s + size }
size = sum (map count ops) + 1
largeOps = any (largeOp long_jumps) ops
count (SmallOp _) = 1
count (LabelOp _) = count (Op 0)
count (Op _) = if largeOps then largeArg16s dflags else 1
#include "rts/Bytecodes.h"
largeArgInstr :: Word16 -> Word16
largeArgInstr bci = bci_FLAG_LARGE_ARGS .|. bci
largeArg :: DynFlags -> Word -> [Word16]
largeArg dflags w
| wORD_SIZE_IN_BITS dflags == 64
= [fromIntegral (w `shiftR` 48),
fromIntegral (w `shiftR` 32),
fromIntegral (w `shiftR` 16),
fromIntegral w]
| wORD_SIZE_IN_BITS dflags == 32
= [fromIntegral (w `shiftR` 16),
fromIntegral w]
| otherwise = error "wORD_SIZE_IN_BITS not 32 or 64?"
largeArg16s :: DynFlags -> Word
largeArg16s dflags | wORD_SIZE_IN_BITS dflags == 64 = 4
| otherwise = 2
assembleI :: DynFlags
-> BCInstr
-> Assembler ()
assembleI dflags i = case i of
STKCHECK n -> emit bci_STKCHECK [Op n]
PUSH_L o1 -> emit bci_PUSH_L [SmallOp o1]
PUSH_LL o1 o2 -> emit bci_PUSH_LL [SmallOp o1, SmallOp o2]
PUSH_LLL o1 o2 o3 -> emit bci_PUSH_LLL [SmallOp o1, SmallOp o2, SmallOp o3]
PUSH_G nm -> do p <- ptr (BCOPtrName nm)
emit bci_PUSH_G [Op p]
PUSH_PRIMOP op -> do p <- ptr (BCOPtrPrimOp op)
emit bci_PUSH_G [Op p]
PUSH_BCO proto -> do let ul_bco = assembleBCO dflags proto
p <- ioptr (liftM BCOPtrBCO ul_bco)
emit bci_PUSH_G [Op p]
PUSH_ALTS proto -> do let ul_bco = assembleBCO dflags proto
p <- ioptr (liftM BCOPtrBCO ul_bco)
emit bci_PUSH_ALTS [Op p]
PUSH_ALTS_UNLIFTED proto pk
-> do let ul_bco = assembleBCO dflags proto
p <- ioptr (liftM BCOPtrBCO ul_bco)
emit (push_alts pk) [Op p]
PUSH_UBX (Left lit) nws -> do np <- literal lit
emit bci_PUSH_UBX [Op np, SmallOp nws]
PUSH_UBX (Right aa) nws -> do np <- addr aa
emit bci_PUSH_UBX [Op np, SmallOp nws]
PUSH_APPLY_N -> emit bci_PUSH_APPLY_N []
PUSH_APPLY_V -> emit bci_PUSH_APPLY_V []
PUSH_APPLY_F -> emit bci_PUSH_APPLY_F []
PUSH_APPLY_D -> emit bci_PUSH_APPLY_D []
PUSH_APPLY_L -> emit bci_PUSH_APPLY_L []
PUSH_APPLY_P -> emit bci_PUSH_APPLY_P []
PUSH_APPLY_PP -> emit bci_PUSH_APPLY_PP []
PUSH_APPLY_PPP -> emit bci_PUSH_APPLY_PPP []
PUSH_APPLY_PPPP -> emit bci_PUSH_APPLY_PPPP []
PUSH_APPLY_PPPPP -> emit bci_PUSH_APPLY_PPPPP []
PUSH_APPLY_PPPPPP -> emit bci_PUSH_APPLY_PPPPPP []
SLIDE n by -> emit bci_SLIDE [SmallOp n, SmallOp by]
ALLOC_AP n -> emit bci_ALLOC_AP [SmallOp n]
ALLOC_AP_NOUPD n -> emit bci_ALLOC_AP_NOUPD [SmallOp n]
ALLOC_PAP arity n -> emit bci_ALLOC_PAP [SmallOp arity, SmallOp n]
MKAP off sz -> emit bci_MKAP [SmallOp off, SmallOp sz]
MKPAP off sz -> emit bci_MKPAP [SmallOp off, SmallOp sz]
UNPACK n -> emit bci_UNPACK [SmallOp n]
PACK dcon sz -> do itbl_no <- lit [BCONPtrItbl (getName dcon)]
emit bci_PACK [Op itbl_no, SmallOp sz]
LABEL lbl -> label lbl
TESTLT_I i l -> do np <- int i
emit bci_TESTLT_I [Op np, LabelOp l]
TESTEQ_I i l -> do np <- int i
emit bci_TESTEQ_I [Op np, LabelOp l]
TESTLT_W w l -> do np <- word w
emit bci_TESTLT_W [Op np, LabelOp l]
TESTEQ_W w l -> do np <- word w
emit bci_TESTEQ_W [Op np, LabelOp l]
TESTLT_F f l -> do np <- float f
emit bci_TESTLT_F [Op np, LabelOp l]
TESTEQ_F f l -> do np <- float f
emit bci_TESTEQ_F [Op np, LabelOp l]
TESTLT_D d l -> do np <- double d
emit bci_TESTLT_D [Op np, LabelOp l]
TESTEQ_D d l -> do np <- double d
emit bci_TESTEQ_D [Op np, LabelOp l]
TESTLT_P i l -> emit bci_TESTLT_P [SmallOp i, LabelOp l]
TESTEQ_P i l -> emit bci_TESTEQ_P [SmallOp i, LabelOp l]
CASEFAIL -> emit bci_CASEFAIL []
SWIZZLE stkoff n -> emit bci_SWIZZLE [SmallOp stkoff, SmallOp n]
JMP l -> emit bci_JMP [LabelOp l]
ENTER -> emit bci_ENTER []
RETURN -> emit bci_RETURN []
RETURN_UBX rep -> emit (return_ubx rep) []
CCALL off m_addr i -> do np <- addr m_addr
emit bci_CCALL [SmallOp off, Op np, SmallOp i]
BRK_FUN array index info -> do p1 <- ptr (BCOPtrArray array)
p2 <- ptr (BCOPtrBreakInfo info)
emit bci_BRK_FUN [Op p1, SmallOp index, Op p2]
where
literal (MachLabel fs (Just sz) _)
| platformOS (targetPlatform dflags) == OSMinGW32
= litlabel (appendFS fs (mkFastString ('@':show sz)))
literal (MachLabel fs _ _) = litlabel fs
literal (MachWord w) = int (fromIntegral w)
literal (MachInt j) = int (fromIntegral j)
literal MachNullAddr = int 0
literal (MachFloat r) = float (fromRational r)
literal (MachDouble r) = double (fromRational r)
literal (MachChar c) = int (ord c)
literal (MachInt64 ii) = int64 (fromIntegral ii)
literal (MachWord64 ii) = int64 (fromIntegral ii)
literal other = pprPanic "ByteCodeAsm.literal" (ppr other)
litlabel fs = lit [BCONPtrLbl fs]
addr = words . mkLitPtr
float = words . mkLitF
double = words . mkLitD dflags
int = words . mkLitI
int64 = words . mkLitI64 dflags
words ws = lit (map BCONPtrWord ws)
word w = words [w]
isLarge :: Word -> Bool
isLarge n = n > 65535
push_alts :: ArgRep -> Word16
push_alts V = bci_PUSH_ALTS_V
push_alts P = bci_PUSH_ALTS_P
push_alts N = bci_PUSH_ALTS_N
push_alts L = bci_PUSH_ALTS_L
push_alts F = bci_PUSH_ALTS_F
push_alts D = bci_PUSH_ALTS_D
push_alts V16 = error "push_alts: vector"
return_ubx :: ArgRep -> Word16
return_ubx V = bci_RETURN_V
return_ubx P = bci_RETURN_P
return_ubx N = bci_RETURN_N
return_ubx L = bci_RETURN_L
return_ubx F = bci_RETURN_F
return_ubx D = bci_RETURN_D
return_ubx V16 = error "return_ubx: vector"
mkLitI :: Int -> [Word]
mkLitF :: Float -> [Word]
mkLitD :: DynFlags -> Double -> [Word]
mkLitPtr :: Ptr () -> [Word]
mkLitI64 :: DynFlags -> Int64 -> [Word]
mkLitF f
= runST (do
arr <- newArray_ ((0::Int),0)
writeArray arr 0 f
f_arr <- castSTUArray arr
w0 <- readArray f_arr 0
return [w0 :: Word]
)
mkLitD dflags d
| wORD_SIZE dflags == 4
= runST (do
arr <- newArray_ ((0::Int),1)
writeArray arr 0 d
d_arr <- castSTUArray arr
w0 <- readArray d_arr 0
w1 <- readArray d_arr 1
return [w0 :: Word, w1]
)
| wORD_SIZE dflags == 8
= runST (do
arr <- newArray_ ((0::Int),0)
writeArray arr 0 d
d_arr <- castSTUArray arr
w0 <- readArray d_arr 0
return [w0 :: Word]
)
| otherwise
= panic "mkLitD: Bad wORD_SIZE"
mkLitI64 dflags ii
| wORD_SIZE dflags == 4
= runST (do
arr <- newArray_ ((0::Int),1)
writeArray arr 0 ii
d_arr <- castSTUArray arr
w0 <- readArray d_arr 0
w1 <- readArray d_arr 1
return [w0 :: Word,w1]
)
| wORD_SIZE dflags == 8
= runST (do
arr <- newArray_ ((0::Int),0)
writeArray arr 0 ii
d_arr <- castSTUArray arr
w0 <- readArray d_arr 0
return [w0 :: Word]
)
| otherwise
= panic "mkLitI64: Bad wORD_SIZE"
mkLitI i
= runST (do
arr <- newArray_ ((0::Int),0)
writeArray arr 0 i
i_arr <- castSTUArray arr
w0 <- readArray i_arr 0
return [w0 :: Word]
)
mkLitPtr a
= runST (do
arr <- newArray_ ((0::Int),0)
writeArray arr 0 a
a_arr <- castSTUArray arr
w0 <- readArray a_arr 0
return [w0 :: Word]
)
iNTERP_STACK_CHECK_THRESH :: Int
iNTERP_STACK_CHECK_THRESH = INTERP_STACK_CHECK_THRESH
\end{code}