module StgCmmMonad (
FCode,
initC, runC, thenC, thenFC, listCs,
returnFC, fixC,
newUnique, newUniqSupply,
newLabelC, emitLabel,
emit, emitDecl, emitProc,
emitProcWithConvention, emitProcWithStackFrame,
emitOutOfLine, emitAssign, emitStore, emitComment,
emitTick, emitUnwind,
getCmm, aGraphToGraph,
getCodeR, getCode, getCodeScoped, getHeapUsage,
mkCmmIfThenElse, mkCmmIfThen, mkCmmIfGoto,
mkCall, mkCmmCall,
forkClosureBody, forkLneBody, forkAlts, codeOnly,
ConTagZ,
Sequel(..), ReturnKind(..),
withSequel, getSequel,
setTickyCtrLabel, getTickyCtrLabel,
tickScope, getTickScope,
withUpdFrameOff, getUpdFrameOff, initUpdFrameOff,
HeapUsage(..), VirtualHpOffset, initHpUsage,
getHpUsage, setHpUsage, heapHWM,
setVirtHp, getVirtHp, setRealHp,
getModuleName,
getState, setState, getSelfLoop, withSelfLoop, getInfoDown, getDynFlags, getThisPackage,
CgIdInfo(..),
getBinds, setBinds,
CgInfoDownwards(..), CgState(..)
) where
#include "HsVersions.h"
import Cmm
import StgCmmClosure
import DynFlags
import Hoopl
import Maybes
import MkGraph
import BlockId
import CLabel
import SMRep
import Module
import Id
import VarEnv
import OrdList
import Unique
import UniqSupply
import FastString
import Outputable
import qualified Control.Applicative as A
import Control.Monad
import Data.List
import Prelude hiding( sequence, succ )
infixr 9 `thenC`
infixr 9 `thenFC`
newtype FCode a = FCode (CgInfoDownwards -> CgState -> (# a, CgState #))
instance Functor FCode where
fmap f (FCode g) = FCode $ \i s -> case g i s of (# a, s' #) -> (# f a, s' #)
instance A.Applicative FCode where
pure = returnFC
(<*>) = ap
instance Monad FCode where
(>>=) = thenFC
return = A.pure
initC :: IO CgState
initC = do { uniqs <- mkSplitUniqSupply 'c'
; return (initCgState uniqs) }
runC :: DynFlags -> Module -> CgState -> FCode a -> (a,CgState)
runC dflags mod st fcode = doFCode fcode (initCgInfoDown dflags mod) st
returnFC :: a -> FCode a
returnFC val = FCode (\_info_down state -> (# val, state #))
thenC :: FCode () -> FCode a -> FCode a
thenC (FCode m) (FCode k) =
FCode $ \info_down state -> case m info_down state of
(# _,new_state #) -> k info_down new_state
listCs :: [FCode ()] -> FCode ()
listCs [] = return ()
listCs (fc:fcs) = do
fc
listCs fcs
thenFC :: FCode a -> (a -> FCode c) -> FCode c
thenFC (FCode m) k = FCode $
\info_down state ->
case m info_down state of
(# m_result, new_state #) ->
case k m_result of
FCode kcode -> kcode info_down new_state
fixC :: (a -> FCode a) -> FCode a
fixC fcode = FCode (
\info_down state ->
let
(v,s) = doFCode (fcode v) info_down state
in
(# v, s #)
)
data CgInfoDownwards
= MkCgInfoDown {
cgd_dflags :: DynFlags,
cgd_mod :: Module,
cgd_updfr_off :: UpdFrameOffset,
cgd_ticky :: CLabel,
cgd_sequel :: Sequel,
cgd_self_loop :: Maybe SelfLoopInfo,
cgd_tick_scope:: CmmTickScope
}
type CgBindings = IdEnv CgIdInfo
data CgIdInfo
= CgIdInfo
{ cg_id :: Id
, cg_lf :: LambdaFormInfo
, cg_loc :: CgLoc
}
instance Outputable CgIdInfo where
ppr (CgIdInfo { cg_id = id, cg_loc = loc })
= ppr id <+> text "-->" <+> ppr loc
data Sequel
= Return Bool
| AssignTo
[LocalReg]
Bool
instance Outputable Sequel where
ppr (Return b) = text "Return" <+> ppr b
ppr (AssignTo regs b) = text "AssignTo" <+> ppr regs <+> ppr b
data ReturnKind
= AssignedDirectly
| ReturnedTo BlockId ByteOff
initCgInfoDown :: DynFlags -> Module -> CgInfoDownwards
initCgInfoDown dflags mod
= MkCgInfoDown { cgd_dflags = dflags
, cgd_mod = mod
, cgd_updfr_off = initUpdFrameOff dflags
, cgd_ticky = mkTopTickyCtrLabel
, cgd_sequel = initSequel
, cgd_self_loop = Nothing
, cgd_tick_scope= GlobalScope }
initSequel :: Sequel
initSequel = Return False
initUpdFrameOff :: DynFlags -> UpdFrameOffset
initUpdFrameOff dflags = widthInBytes (wordWidth dflags)
data CgState
= MkCgState {
cgs_stmts :: CmmAGraph,
cgs_tops :: OrdList CmmDecl,
cgs_binds :: CgBindings,
cgs_hp_usg :: HeapUsage,
cgs_uniqs :: UniqSupply }
data HeapUsage
= HeapUsage {
virtHp :: VirtualHpOffset,
realHp :: VirtualHpOffset
}
type VirtualHpOffset = WordOff
initCgState :: UniqSupply -> CgState
initCgState uniqs
= MkCgState { cgs_stmts = mkNop
, cgs_tops = nilOL
, cgs_binds = emptyVarEnv
, cgs_hp_usg = initHpUsage
, cgs_uniqs = uniqs }
stateIncUsage :: CgState -> CgState -> CgState
stateIncUsage s1 s2@(MkCgState { cgs_hp_usg = hp_usg })
= s1 { cgs_hp_usg = cgs_hp_usg s1 `maxHpHw` virtHp hp_usg }
`addCodeBlocksFrom` s2
addCodeBlocksFrom :: CgState -> CgState -> CgState
s1 `addCodeBlocksFrom` s2
= s1 { cgs_stmts = cgs_stmts s1 MkGraph.<*> cgs_stmts s2,
cgs_tops = cgs_tops s1 `appOL` cgs_tops s2 }
heapHWM :: HeapUsage -> VirtualHpOffset
heapHWM = virtHp
initHpUsage :: HeapUsage
initHpUsage = HeapUsage { virtHp = 0, realHp = 0 }
maxHpHw :: HeapUsage -> VirtualHpOffset -> HeapUsage
hp_usg `maxHpHw` hw = hp_usg { virtHp = virtHp hp_usg `max` hw }
getState :: FCode CgState
getState = FCode $ \_info_down state -> (# state, state #)
setState :: CgState -> FCode ()
setState state = FCode $ \_info_down _ -> (# (), state #)
getHpUsage :: FCode HeapUsage
getHpUsage = do
state <- getState
return $ cgs_hp_usg state
setHpUsage :: HeapUsage -> FCode ()
setHpUsage new_hp_usg = do
state <- getState
setState $ state {cgs_hp_usg = new_hp_usg}
setVirtHp :: VirtualHpOffset -> FCode ()
setVirtHp new_virtHp
= do { hp_usage <- getHpUsage
; setHpUsage (hp_usage {virtHp = new_virtHp}) }
getVirtHp :: FCode VirtualHpOffset
getVirtHp
= do { hp_usage <- getHpUsage
; return (virtHp hp_usage) }
setRealHp :: VirtualHpOffset -> FCode ()
setRealHp new_realHp
= do { hp_usage <- getHpUsage
; setHpUsage (hp_usage {realHp = new_realHp}) }
getBinds :: FCode CgBindings
getBinds = do
state <- getState
return $ cgs_binds state
setBinds :: CgBindings -> FCode ()
setBinds new_binds = do
state <- getState
setState $ state {cgs_binds = new_binds}
withState :: FCode a -> CgState -> FCode (a,CgState)
withState (FCode fcode) newstate = FCode $ \info_down state ->
case fcode info_down newstate of
(# retval, state2 #) -> (# (retval,state2), state #)
newUniqSupply :: FCode UniqSupply
newUniqSupply = do
state <- getState
let (us1, us2) = splitUniqSupply (cgs_uniqs state)
setState $ state { cgs_uniqs = us1 }
return us2
newUnique :: FCode Unique
newUnique = do
state <- getState
let (u,us') = takeUniqFromSupply (cgs_uniqs state)
setState $ state { cgs_uniqs = us' }
return u
getInfoDown :: FCode CgInfoDownwards
getInfoDown = FCode $ \info_down state -> (# info_down,state #)
getSelfLoop :: FCode (Maybe SelfLoopInfo)
getSelfLoop = do
info_down <- getInfoDown
return $ cgd_self_loop info_down
withSelfLoop :: SelfLoopInfo -> FCode a -> FCode a
withSelfLoop self_loop code = do
info_down <- getInfoDown
withInfoDown code (info_down {cgd_self_loop = Just self_loop})
instance HasDynFlags FCode where
getDynFlags = liftM cgd_dflags getInfoDown
getThisPackage :: FCode UnitId
getThisPackage = liftM thisPackage getDynFlags
withInfoDown :: FCode a -> CgInfoDownwards -> FCode a
withInfoDown (FCode fcode) info_down = FCode $ \_ state -> fcode info_down state
doFCode :: FCode a -> CgInfoDownwards -> CgState -> (a,CgState)
doFCode (FCode fcode) info_down state =
case fcode info_down state of
(# a, s #) -> ( a, s )
getModuleName :: FCode Module
getModuleName = do { info <- getInfoDown; return (cgd_mod info) }
withSequel :: Sequel -> FCode a -> FCode a
withSequel sequel code
= do { info <- getInfoDown
; withInfoDown code (info {cgd_sequel = sequel, cgd_self_loop = Nothing }) }
getSequel :: FCode Sequel
getSequel = do { info <- getInfoDown
; return (cgd_sequel info) }
withUpdFrameOff :: UpdFrameOffset -> FCode a -> FCode a
withUpdFrameOff size code
= do { info <- getInfoDown
; withInfoDown code (info {cgd_updfr_off = size }) }
getUpdFrameOff :: FCode UpdFrameOffset
getUpdFrameOff
= do { info <- getInfoDown
; return $ cgd_updfr_off info }
getTickyCtrLabel :: FCode CLabel
getTickyCtrLabel = do
info <- getInfoDown
return (cgd_ticky info)
setTickyCtrLabel :: CLabel -> FCode a -> FCode a
setTickyCtrLabel ticky code = do
info <- getInfoDown
withInfoDown code (info {cgd_ticky = ticky})
getTickScope :: FCode CmmTickScope
getTickScope = do
info <- getInfoDown
return (cgd_tick_scope info)
tickScope :: FCode a -> FCode a
tickScope code = do
info <- getInfoDown
if debugLevel (cgd_dflags info) == 0 then code else do
u <- newUnique
let scope' = SubScope u (cgd_tick_scope info)
withInfoDown code info{ cgd_tick_scope = scope' }
forkClosureBody :: FCode () -> FCode ()
forkClosureBody body_code
= do { dflags <- getDynFlags
; info <- getInfoDown
; us <- newUniqSupply
; state <- getState
; let body_info_down = info { cgd_sequel = initSequel
, cgd_updfr_off = initUpdFrameOff dflags
, cgd_self_loop = Nothing }
fork_state_in = (initCgState us) { cgs_binds = cgs_binds state }
((),fork_state_out) = doFCode body_code body_info_down fork_state_in
; setState $ state `addCodeBlocksFrom` fork_state_out }
forkLneBody :: FCode a -> FCode a
forkLneBody body_code
= do { info_down <- getInfoDown
; us <- newUniqSupply
; state <- getState
; let fork_state_in = (initCgState us) { cgs_binds = cgs_binds state }
(result, fork_state_out) = doFCode body_code info_down fork_state_in
; setState $ state `addCodeBlocksFrom` fork_state_out
; return result }
codeOnly :: FCode () -> FCode ()
codeOnly body_code
= do { info_down <- getInfoDown
; us <- newUniqSupply
; state <- getState
; let fork_state_in = (initCgState us) { cgs_binds = cgs_binds state
, cgs_hp_usg = cgs_hp_usg state }
((), fork_state_out) = doFCode body_code info_down fork_state_in
; setState $ state `addCodeBlocksFrom` fork_state_out }
forkAlts :: [FCode a] -> FCode [a]
forkAlts branch_fcodes
= do { info_down <- getInfoDown
; us <- newUniqSupply
; state <- getState
; let compile us branch
= (us2, doFCode branch info_down branch_state)
where
(us1,us2) = splitUniqSupply us
branch_state = (initCgState us1) {
cgs_binds = cgs_binds state
, cgs_hp_usg = cgs_hp_usg state }
(_us, results) = mapAccumL compile us branch_fcodes
(branch_results, branch_out_states) = unzip results
; setState $ foldl stateIncUsage state branch_out_states
; return branch_results }
getCodeR :: FCode a -> FCode (a, CmmAGraph)
getCodeR fcode
= do { state1 <- getState
; (a, state2) <- withState fcode (state1 { cgs_stmts = mkNop })
; setState $ state2 { cgs_stmts = cgs_stmts state1 }
; return (a, cgs_stmts state2) }
getCode :: FCode a -> FCode CmmAGraph
getCode fcode = do { (_,stmts) <- getCodeR fcode; return stmts }
getCodeScoped :: FCode a -> FCode (a, CmmAGraphScoped)
getCodeScoped fcode
= do { state1 <- getState
; ((a, tscope), state2) <-
tickScope $
flip withState state1 { cgs_stmts = mkNop } $
do { a <- fcode
; scp <- getTickScope
; return (a, scp) }
; setState $ state2 { cgs_stmts = cgs_stmts state1 }
; return (a, (cgs_stmts state2, tscope)) }
getHeapUsage :: (VirtualHpOffset -> FCode a) -> FCode a
getHeapUsage fcode
= do { info_down <- getInfoDown
; state <- getState
; let fstate_in = state { cgs_hp_usg = initHpUsage }
(r, fstate_out) = doFCode (fcode hp_hw) info_down fstate_in
hp_hw = heapHWM (cgs_hp_usg fstate_out)
; setState $ fstate_out { cgs_hp_usg = cgs_hp_usg state }
; return r }
emitCgStmt :: CgStmt -> FCode ()
emitCgStmt stmt
= do { state <- getState
; setState $ state { cgs_stmts = cgs_stmts state `snocOL` stmt }
}
emitLabel :: BlockId -> FCode ()
emitLabel id = do tscope <- getTickScope
emitCgStmt (CgLabel id tscope)
emitComment :: FastString -> FCode ()
#if 0 /* def DEBUG */
emitComment s = emitCgStmt (CgStmt (CmmComment s))
#else
emitComment _ = return ()
#endif
emitTick :: CmmTickish -> FCode ()
emitTick = emitCgStmt . CgStmt . CmmTick
emitUnwind :: GlobalReg -> CmmExpr -> FCode ()
emitUnwind g e = do
dflags <- getDynFlags
when (debugLevel dflags > 0) $
emitCgStmt $ CgStmt $ CmmUnwind g e
emitAssign :: CmmReg -> CmmExpr -> FCode ()
emitAssign l r = emitCgStmt (CgStmt (CmmAssign l r))
emitStore :: CmmExpr -> CmmExpr -> FCode ()
emitStore l r = emitCgStmt (CgStmt (CmmStore l r))
newLabelC :: FCode BlockId
newLabelC = do { u <- newUnique
; return $ mkBlockId u }
emit :: CmmAGraph -> FCode ()
emit ag
= do { state <- getState
; setState $ state { cgs_stmts = cgs_stmts state MkGraph.<*> ag } }
emitDecl :: CmmDecl -> FCode ()
emitDecl decl
= do { state <- getState
; setState $ state { cgs_tops = cgs_tops state `snocOL` decl } }
emitOutOfLine :: BlockId -> CmmAGraphScoped -> FCode ()
emitOutOfLine l (stmts, tscope) = emitCgStmt (CgFork l stmts tscope)
emitProcWithStackFrame
:: Convention
-> Maybe CmmInfoTable
-> CLabel
-> [CmmFormal]
-> [CmmFormal]
-> CmmAGraphScoped
-> Bool
-> FCode ()
emitProcWithStackFrame _conv mb_info lbl _stk_args [] blocks False
= do { dflags <- getDynFlags
; emitProc_ mb_info lbl [] blocks (widthInBytes (wordWidth dflags)) False
}
emitProcWithStackFrame conv mb_info lbl stk_args args (graph, tscope) True
= do { dflags <- getDynFlags
; let (offset, live, entry) = mkCallEntry dflags conv args stk_args
graph' = entry MkGraph.<*> graph
; emitProc_ mb_info lbl live (graph', tscope) offset True
}
emitProcWithStackFrame _ _ _ _ _ _ _ = panic "emitProcWithStackFrame"
emitProcWithConvention :: Convention -> Maybe CmmInfoTable -> CLabel
-> [CmmFormal]
-> CmmAGraphScoped
-> FCode ()
emitProcWithConvention conv mb_info lbl args blocks
= emitProcWithStackFrame conv mb_info lbl [] args blocks True
emitProc :: Maybe CmmInfoTable -> CLabel -> [GlobalReg] -> CmmAGraphScoped
-> Int -> FCode ()
emitProc mb_info lbl live blocks offset
= emitProc_ mb_info lbl live blocks offset True
emitProc_ :: Maybe CmmInfoTable -> CLabel -> [GlobalReg] -> CmmAGraphScoped
-> Int -> Bool -> FCode ()
emitProc_ mb_info lbl live blocks offset do_layout
= do { dflags <- getDynFlags
; l <- newLabelC
; let
blks = labelAGraph l blocks
infos | Just info <- mb_info = mapSingleton (g_entry blks) info
| otherwise = mapEmpty
sinfo = StackInfo { arg_space = offset
, updfr_space = Just (initUpdFrameOff dflags)
, do_layout = do_layout }
tinfo = TopInfo { info_tbls = infos
, stack_info=sinfo}
proc_block = CmmProc tinfo lbl live blks
; state <- getState
; setState $ state { cgs_tops = cgs_tops state `snocOL` proc_block } }
getCmm :: FCode () -> FCode CmmGroup
getCmm code
= do { state1 <- getState
; ((), state2) <- withState code (state1 { cgs_tops = nilOL })
; setState $ state2 { cgs_tops = cgs_tops state1 }
; return (fromOL (cgs_tops state2)) }
mkCmmIfThenElse :: CmmExpr -> CmmAGraph -> CmmAGraph -> FCode CmmAGraph
mkCmmIfThenElse e tbranch fbranch = do
tscp <- getTickScope
endif <- newLabelC
tid <- newLabelC
fid <- newLabelC
return $ catAGraphs [ mkCbranch e tid fid Nothing
, mkLabel tid tscp, tbranch, mkBranch endif
, mkLabel fid tscp, fbranch, mkLabel endif tscp ]
mkCmmIfGoto :: CmmExpr -> BlockId -> FCode CmmAGraph
mkCmmIfGoto e tid = do
endif <- newLabelC
tscp <- getTickScope
return $ catAGraphs [ mkCbranch e tid endif Nothing, mkLabel endif tscp ]
mkCmmIfThen :: CmmExpr -> CmmAGraph -> FCode CmmAGraph
mkCmmIfThen e tbranch = do
endif <- newLabelC
tid <- newLabelC
tscp <- getTickScope
return $ catAGraphs [ mkCbranch e tid endif Nothing
, mkLabel tid tscp, tbranch, mkLabel endif tscp ]
mkCall :: CmmExpr -> (Convention, Convention) -> [CmmFormal] -> [CmmActual]
-> UpdFrameOffset -> [CmmActual] -> FCode CmmAGraph
mkCall f (callConv, retConv) results actuals updfr_off extra_stack = do
dflags <- getDynFlags
k <- newLabelC
tscp <- getTickScope
let area = Young k
(off, _, copyin) = copyInOflow dflags retConv area results []
copyout = mkCallReturnsTo dflags f callConv actuals k off updfr_off extra_stack
return $ catAGraphs [copyout, mkLabel k tscp, copyin]
mkCmmCall :: CmmExpr -> [CmmFormal] -> [CmmActual] -> UpdFrameOffset
-> FCode CmmAGraph
mkCmmCall f results actuals updfr_off
= mkCall f (NativeDirectCall, NativeReturn) results actuals updfr_off []
aGraphToGraph :: CmmAGraphScoped -> FCode CmmGraph
aGraphToGraph stmts
= do { l <- newLabelC
; return (labelAGraph l stmts) }