% % (c) The University of Glasgow 2006 % (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 % \section[CgMonad]{The code generation monad} See the beginning of the top-level @CodeGen@ module, to see how this monadic stuff fits into the Big Picture. \begin{code} module CgMonad ( Code, -- type FCode, -- type initC, thenC, thenFC, listCs, listFCs, mapCs, mapFCs, returnFC, fixC, fixC_, checkedAbsC, stmtC, stmtsC, labelC, emitStmts, nopC, whenC, newLabelC, newUnique, newUniqSupply, CgStmts, emitCgStmts, forkCgStmts, cgStmtsToBlocks, getCgStmts', getCgStmts, noCgStmts, oneCgStmt, consCgStmt, getCmm, emitData, emitProc, emitSimpleProc, forkLabelledCode, forkClosureBody, forkStatics, forkAlts, forkEval, forkEvalHelp, forkProc, codeOnly, SemiTaggingStuff, ConTagZ, EndOfBlockInfo(..), setEndOfBlockInfo, getEndOfBlockInfo, setSRT, getSRT, setSRTLabel, getSRTLabel, setTickyCtrLabel, getTickyCtrLabel, StackUsage(..), HeapUsage(..), VirtualSpOffset, VirtualHpOffset, initStkUsage, initHpUsage, getHpUsage, setHpUsage, heapHWM, getModuleName, Sequel(..), -- ToDo: unabstract? -- ideally we wouldn't export these, but some other modules access internal state getState, setState, getInfoDown, getDynFlags, getThisPackage, -- more localised access to monad state getStkUsage, setStkUsage, getBinds, setBinds, getStaticBinds, -- out of general friendliness, we also export ... CgInfoDownwards(..), CgState(..) -- non-abstract ) where #include "HsVersions.h" import {-# SOURCE #-} CgBindery ( CgBindings, nukeVolatileBinds ) import DynFlags import BlockId import Cmm import CmmUtils import CLabel import StgSyn (SRT) import SMRep import Module import Id import VarEnv import OrdList import Unique import Util() import UniqSupply import FastString() import Outputable import Control.Monad import Data.List infixr 9 `thenC` -- Right-associative! infixr 9 `thenFC` \end{code} %************************************************************************ %* * \subsection[CgMonad-environment]{Stuff for manipulating environments} %* * %************************************************************************ This monadery has some information that it only passes {\em downwards}, as well as some ``state'' which is modified as we go along. \begin{code} data CgInfoDownwards -- information only passed *downwards* by the monad = MkCgInfoDown { cgd_dflags :: DynFlags, cgd_mod :: Module, -- Module being compiled cgd_statics :: CgBindings, -- [Id -> info] : static environment cgd_srt_lbl :: CLabel, -- label of the current SRT cgd_srt :: SRT, -- the current SRT cgd_ticky :: CLabel, -- current destination for ticky counts cgd_eob :: EndOfBlockInfo -- Info for stuff to do at end of basic block: } initCgInfoDown :: DynFlags -> Module -> CgInfoDownwards initCgInfoDown dflags mod = MkCgInfoDown { cgd_dflags = dflags, cgd_mod = mod, cgd_statics = emptyVarEnv, cgd_srt_lbl = error "initC: srt_lbl", cgd_srt = error "initC: srt", cgd_ticky = mkTopTickyCtrLabel, cgd_eob = initEobInfo } data CgState = MkCgState { cgs_stmts :: OrdList CgStmt, -- Current proc cgs_tops :: OrdList CmmTop, -- Other procedures and data blocks in this compilation unit -- Both the latter two are ordered only so that we can -- reduce forward references, when it's easy to do so cgs_binds :: CgBindings, -- [Id -> info] : *local* bindings environment -- Bindings for top-level things are given in -- the info-down part cgs_stk_usg :: StackUsage, cgs_hp_usg :: HeapUsage, cgs_uniqs :: UniqSupply } initCgState :: UniqSupply -> CgState initCgState uniqs = MkCgState { cgs_stmts = nilOL, cgs_tops = nilOL, cgs_binds = emptyVarEnv, cgs_stk_usg = initStkUsage, cgs_hp_usg = initHpUsage, cgs_uniqs = uniqs } \end{code} @EndOfBlockInfo@ tells what to do at the end of this block of code or, if the expression is a @case@, what to do at the end of each alternative. \begin{code} data EndOfBlockInfo = EndOfBlockInfo VirtualSpOffset -- Args Sp: trim the stack to this point at a -- return; push arguments starting just -- above this point on a tail call. -- This is therefore the stk ptr as seen -- by a case alternative. Sequel initEobInfo :: EndOfBlockInfo initEobInfo = EndOfBlockInfo 0 OnStack \end{code} Any addressing modes inside @Sequel@ must be ``robust,'' in the sense that it must survive stack pointer adjustments at the end of the block. \begin{code} data Sequel = OnStack -- Continuation is on the stack | CaseAlts CLabel -- Jump to this; if the continuation is for a vectored -- case this might be the label of a return vector SemiTaggingStuff Id -- The case binder, only used to see if it's dead type SemiTaggingStuff = Maybe -- Maybe[1] we don't have any semi-tagging stuff... ([(ConTagZ, CmmLit)], -- Alternatives CmmLit) -- Default (will be a can't happen RTS label if can't happen) type ConTagZ = Int -- A *zero-indexed* contructor tag -- The case branch is executed only from a successful semitagging -- venture, when a case has looked at a variable, found that it's -- evaluated, and wants to load up the contents and go to the join -- point. \end{code} %************************************************************************ %* * CgStmt type %* * %************************************************************************ The CgStmts type is what the code generator outputs: it is a tree of statements, including in-line labels. The job of flattenCgStmts is to turn this into a list of basic blocks, each of which ends in a jump statement (either a local branch or a non-local jump). \begin{code} type CgStmts = OrdList CgStmt data CgStmt = CgStmt CmmStmt | CgLabel BlockId | CgFork BlockId CgStmts flattenCgStmts :: BlockId -> CgStmts -> [CmmBasicBlock] flattenCgStmts id stmts = case flatten (fromOL stmts) of ([],blocks) -> blocks (block,blocks) -> BasicBlock id block : blocks where flatten [] = ([],[]) -- A label at the end of a function or fork: this label must not be reachable, -- but it might be referred to from another BB that also isn't reachable. -- Eliminating these has to be done with a dead-code analysis. For now, -- we just make it into a well-formed block by adding a recursive jump. flatten [CgLabel id] = ( [CmmBranch id], [BasicBlock id [CmmBranch id]] ) -- A jump/branch: throw away all the code up to the next label, because -- it is unreachable. Be careful to keep forks that we find on the way. flatten (CgStmt stmt : stmts) | isJump stmt = case dropWhile isOrdinaryStmt stmts of [] -> ( [stmt], [] ) [CgLabel id] -> ( [stmt], [BasicBlock id [CmmBranch id]]) (CgLabel id : stmts) -> ( [stmt], BasicBlock id block : blocks ) where (block,blocks) = flatten stmts (CgFork fork_id stmts : ss) -> flatten (CgFork fork_id stmts : CgStmt stmt : ss) (CgStmt {} : _) -> panic "CgStmt not seen as ordinary" flatten (s:ss) = case s of CgStmt stmt -> (stmt:block,blocks) CgLabel id -> ([CmmBranch id],BasicBlock id block:blocks) CgFork fork_id stmts -> (block, BasicBlock fork_id fork_block : fork_blocks ++ blocks) where (fork_block, fork_blocks) = flatten (fromOL stmts) where (block,blocks) = flatten ss isJump :: CmmStmt -> Bool isJump (CmmJump _ _) = True isJump (CmmBranch _) = True isJump (CmmSwitch _ _) = True isJump (CmmReturn _) = True isJump _ = False isOrdinaryStmt :: CgStmt -> Bool isOrdinaryStmt (CgStmt _) = True isOrdinaryStmt _ = False \end{code} %************************************************************************ %* * Stack and heap models %* * %************************************************************************ \begin{code} type VirtualHpOffset = WordOff -- Both are in type VirtualSpOffset = WordOff -- units of words data StackUsage = StackUsage { virtSp :: VirtualSpOffset, -- Virtual offset of topmost allocated slot frameSp :: VirtualSpOffset, -- Virtual offset of the return address of the enclosing frame. -- This RA describes the liveness/pointedness of -- all the stack from frameSp downwards -- INVARIANT: less than or equal to virtSp freeStk :: [VirtualSpOffset], -- List of free slots, in *increasing* order -- INVARIANT: all <= virtSp -- All slots <= virtSp are taken except these ones realSp :: VirtualSpOffset, -- Virtual offset of real stack pointer register hwSp :: VirtualSpOffset } -- Highest value ever taken by virtSp -- INVARIANT: The environment contains no Stable references to -- stack slots below (lower offset) frameSp -- It can contain volatile references to this area though. data HeapUsage = HeapUsage { virtHp :: VirtualHpOffset, -- Virtual offset of highest-allocated word realHp :: VirtualHpOffset -- realHp: Virtual offset of real heap ptr } \end{code} The heap high water mark is the larger of virtHp and hwHp. The latter is only records the high water marks of forked-off branches, so to find the heap high water mark you have to take the max of virtHp and hwHp. Remember, virtHp never retreats! Note Jan 04: ok, so why do we only look at the virtual Hp?? \begin{code} heapHWM :: HeapUsage -> VirtualHpOffset heapHWM = virtHp \end{code} Initialisation. \begin{code} initStkUsage :: StackUsage initStkUsage = StackUsage { virtSp = 0, frameSp = 0, freeStk = [], realSp = 0, hwSp = 0 } initHpUsage :: HeapUsage initHpUsage = HeapUsage { virtHp = 0, realHp = 0 } \end{code} @stateIncUsage@$~e_1~e_2$ incorporates in $e_1$ the stack and heap high water marks found in $e_2$. \begin{code} stateIncUsage :: CgState -> CgState -> CgState stateIncUsage s1 s2@(MkCgState { cgs_stk_usg = stk_usg, cgs_hp_usg = hp_usg }) = s1 { cgs_hp_usg = cgs_hp_usg s1 `maxHpHw` virtHp hp_usg, cgs_stk_usg = cgs_stk_usg s1 `maxStkHw` hwSp stk_usg } `addCodeBlocksFrom` s2 stateIncUsageEval :: CgState -> CgState -> CgState stateIncUsageEval s1 s2 = s1 { cgs_stk_usg = cgs_stk_usg s1 `maxStkHw` hwSp (cgs_stk_usg s2) } `addCodeBlocksFrom` s2 -- We don't max the heap high-watermark because stateIncUsageEval is -- used only in forkEval, which in turn is only used for blocks of code -- which do their own heap-check. addCodeBlocksFrom :: CgState -> CgState -> CgState -- Add code blocks from the latter to the former -- (The cgs_stmts will often be empty, but not always; see codeOnly) s1 `addCodeBlocksFrom` s2 = s1 { cgs_stmts = cgs_stmts s1 `appOL` cgs_stmts s2, cgs_tops = cgs_tops s1 `appOL` cgs_tops s2 } maxHpHw :: HeapUsage -> VirtualHpOffset -> HeapUsage hp_usg `maxHpHw` hw = hp_usg { virtHp = virtHp hp_usg `max` hw } maxStkHw :: StackUsage -> VirtualSpOffset -> StackUsage stk_usg `maxStkHw` hw = stk_usg { hwSp = hwSp stk_usg `max` hw } \end{code} %************************************************************************ %* * The FCode monad %* * %************************************************************************ \begin{code} newtype FCode a = FCode (CgInfoDownwards -> CgState -> (a, CgState)) type Code = FCode () instance Monad FCode where (>>=) = thenFC return = returnFC {-# INLINE thenC #-} {-# INLINE thenFC #-} {-# INLINE returnFC #-} \end{code} The Abstract~C is not in the environment so as to improve strictness. \begin{code} initC :: DynFlags -> Module -> FCode a -> IO a initC dflags mod (FCode code) = do { uniqs <- mkSplitUniqSupply 'c' ; case code (initCgInfoDown dflags mod) (initCgState uniqs) of (res, _) -> return res } returnFC :: a -> FCode a returnFC val = FCode (\_ state -> (val, state)) \end{code} \begin{code} thenC :: Code -> FCode a -> FCode a thenC (FCode m) (FCode k) = FCode (\info_down state -> let (_,new_state) = m info_down state in k info_down new_state) listCs :: [Code] -> Code listCs [] = return () listCs (fc:fcs) = do fc listCs fcs mapCs :: (a -> Code) -> [a] -> Code mapCs = mapM_ \end{code} \begin{code} thenFC :: FCode a -> (a -> FCode c) -> FCode c thenFC (FCode m) k = FCode ( \info_down state -> let (m_result, new_state) = m info_down state (FCode kcode) = k m_result in kcode info_down new_state ) listFCs :: [FCode a] -> FCode [a] listFCs = sequence mapFCs :: (a -> FCode b) -> [a] -> FCode [b] mapFCs = mapM \end{code} And the knot-tying combinator: \begin{code} fixC :: (a -> FCode a) -> FCode a fixC fcode = FCode ( \info_down state -> let FCode fc = fcode v result@(v,_) = fc info_down state -- ^--------^ in result ) fixC_ :: (a -> FCode a) -> FCode () fixC_ fcode = fixC fcode >> return () \end{code} %************************************************************************ %* * Operators for getting and setting the state and "info_down". %* * %************************************************************************ \begin{code} getState :: FCode CgState getState = FCode $ \_ state -> (state,state) setState :: CgState -> FCode () setState state = FCode $ \_ _ -> ((),state) getStkUsage :: FCode StackUsage getStkUsage = do state <- getState return $ cgs_stk_usg state setStkUsage :: StackUsage -> Code setStkUsage new_stk_usg = do state <- getState setState $ state {cgs_stk_usg = new_stk_usg} getHpUsage :: FCode HeapUsage getHpUsage = do state <- getState return $ cgs_hp_usg state setHpUsage :: HeapUsage -> Code setHpUsage new_hp_usg = do state <- getState setState $ state {cgs_hp_usg = new_hp_usg} 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} getStaticBinds :: FCode CgBindings getStaticBinds = do info <- getInfoDown return (cgd_statics info) withState :: FCode a -> CgState -> FCode (a,CgState) withState (FCode fcode) newstate = FCode $ \info_down state -> let (retval, state2) = fcode info_down newstate in ((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 us <- newUniqSupply return (uniqFromSupply us) ------------------ getInfoDown :: FCode CgInfoDownwards getInfoDown = FCode $ \info_down state -> (info_down,state) getDynFlags :: FCode DynFlags getDynFlags = liftM cgd_dflags getInfoDown getThisPackage :: FCode PackageId 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 = fcode info_down state \end{code} %************************************************************************ %* * Forking %* * %************************************************************************ @forkClosureBody@ takes a code, $c$, and compiles it in a completely fresh environment, except that: - compilation info and statics are passed in unchanged. The current environment is passed on completely unaltered, except that abstract C from the fork is incorporated. @forkProc@ takes a code and compiles it in the current environment, returning the basic blocks thus constructed. The current environment is passed on completely unchanged. It is pretty similar to @getBlocks@, except that the latter does affect the environment. @forkStatics@ $fc$ compiles $fc$ in an environment whose statics come from the current bindings, but which is otherwise freshly initialised. The Abstract~C returned is attached to the current state, but the bindings and usage information is otherwise unchanged. \begin{code} forkClosureBody :: Code -> Code forkClosureBody body_code = do { info <- getInfoDown ; us <- newUniqSupply ; state <- getState ; let body_info_down = info { cgd_eob = initEobInfo } ((),fork_state) = doFCode body_code body_info_down (initCgState us) ; ASSERT( isNilOL (cgs_stmts fork_state) ) setState $ state `addCodeBlocksFrom` fork_state } forkStatics :: FCode a -> FCode a forkStatics body_code = do { info <- getInfoDown ; us <- newUniqSupply ; state <- getState ; let rhs_info_down = info { cgd_statics = cgs_binds state, cgd_eob = initEobInfo } (result, fork_state_out) = doFCode body_code rhs_info_down (initCgState us) ; ASSERT( isNilOL (cgs_stmts fork_state_out) ) setState (state `addCodeBlocksFrom` fork_state_out) ; return result } forkProc :: Code -> FCode CgStmts forkProc body_code = do { info_down <- getInfoDown ; us <- newUniqSupply ; state <- getState ; let fork_state_in = (initCgState us) { cgs_binds = cgs_binds state, cgs_stk_usg = cgs_stk_usg state, cgs_hp_usg = cgs_hp_usg state } -- ToDo: is the hp usage necesary? (code_blks, fork_state_out) = doFCode (getCgStmts body_code) info_down fork_state_in ; setState $ state `stateIncUsageEval` fork_state_out ; return code_blks } codeOnly :: Code -> Code -- Emit any code from the inner thing into the outer thing -- Do not affect anything else in the outer state -- Used in almost-circular code to prevent false loop dependencies codeOnly body_code = do { info_down <- getInfoDown ; us <- newUniqSupply ; state <- getState ; let fork_state_in = (initCgState us) { cgs_binds = cgs_binds state, cgs_stk_usg = cgs_stk_usg 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 } \end{code} @forkAlts@ $bs~d$ takes fcodes $bs$ for the branches of a @case@, and an fcode for the default case $d$, and compiles each in the current environment. The current environment is passed on unmodified, except that - the worst stack high-water mark is incorporated - the virtual Hp is moved on to the worst virtual Hp for the branches \begin{code} 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_stk_usg = cgs_stk_usg 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 -- NB foldl. state is the *left* argument to stateIncUsage ; return branch_results } \end{code} @forkEval@ takes two blocks of code. - The first meddles with the environment to set it up as expected by the alternatives of a @case@ which does an eval (or gc-possible primop). - The second block is the code for the alternatives. (plus info for semi-tagging purposes) @forkEval@ picks up the virtual stack pointer and returns a suitable @EndOfBlockInfo@ for the caller to use, together with whatever value is returned by the second block. It uses @initEnvForAlternatives@ to initialise the environment, and @stateIncUsageAlt@ to incorporate usage; the latter ignores the heap usage. \begin{code} forkEval :: EndOfBlockInfo -- For the body -> Code -- Code to set environment -> FCode Sequel -- Semi-tagging info to store -> FCode EndOfBlockInfo -- The new end of block info forkEval body_eob_info env_code body_code = do { (v, sequel) <- forkEvalHelp body_eob_info env_code body_code ; returnFC (EndOfBlockInfo v sequel) } forkEvalHelp :: EndOfBlockInfo -- For the body -> Code -- Code to set environment -> FCode a -- The code to do after the eval -> FCode (VirtualSpOffset, -- Sp a) -- Result of the FCode -- A disturbingly complicated function forkEvalHelp body_eob_info env_code body_code = do { info_down <- getInfoDown ; us <- newUniqSupply ; state <- getState ; let { info_down_for_body = info_down {cgd_eob = body_eob_info} ; (_, env_state) = doFCode env_code info_down_for_body (state {cgs_uniqs = us}) ; state_for_body = (initCgState (cgs_uniqs env_state)) { cgs_binds = binds_for_body, cgs_stk_usg = stk_usg_for_body } ; binds_for_body = nukeVolatileBinds (cgs_binds env_state) ; stk_usg_from_env = cgs_stk_usg env_state ; virtSp_from_env = virtSp stk_usg_from_env ; stk_usg_for_body = stk_usg_from_env {realSp = virtSp_from_env, hwSp = virtSp_from_env} ; (value_returned, state_at_end_return) = doFCode body_code info_down_for_body state_for_body } ; ASSERT( isNilOL (cgs_stmts state_at_end_return) ) -- The code coming back should consist only of nested declarations, -- notably of the return vector! setState $ state `stateIncUsageEval` state_at_end_return ; return (virtSp_from_env, value_returned) } -- ---------------------------------------------------------------------------- -- Combinators for emitting code nopC :: Code nopC = return () whenC :: Bool -> Code -> Code whenC True code = code whenC False _ = nopC stmtC :: CmmStmt -> Code stmtC stmt = emitCgStmt (CgStmt stmt) labelC :: BlockId -> Code labelC id = emitCgStmt (CgLabel id) newLabelC :: FCode BlockId newLabelC = do { u <- newUnique ; return $ BlockId u } checkedAbsC :: CmmStmt -> Code -- Emit code, eliminating no-ops checkedAbsC stmt = emitStmts (if isNopStmt stmt then nilOL else unitOL stmt) stmtsC :: [CmmStmt] -> Code stmtsC stmts = emitStmts (toOL stmts) -- Emit code; no no-op checking emitStmts :: CmmStmts -> Code emitStmts stmts = emitCgStmts (fmap CgStmt stmts) -- forkLabelledCode is for emitting a chunk of code with a label, outside -- of the current instruction stream. forkLabelledCode :: Code -> FCode BlockId forkLabelledCode code = getCgStmts code >>= forkCgStmts emitCgStmt :: CgStmt -> Code emitCgStmt stmt = do { state <- getState ; setState $ state { cgs_stmts = cgs_stmts state `snocOL` stmt } } emitData :: Section -> [CmmStatic] -> Code emitData sect lits = do { state <- getState ; setState $ state { cgs_tops = cgs_tops state `snocOL` data_block } } where data_block = CmmData sect lits emitProc :: CmmInfo -> CLabel -> CmmFormals -> [CmmBasicBlock] -> Code emitProc info lbl args blocks = do { let proc_block = CmmProc info lbl args (ListGraph blocks) ; state <- getState ; setState $ state { cgs_tops = cgs_tops state `snocOL` proc_block } } emitSimpleProc :: CLabel -> Code -> Code -- Emit a procedure whose body is the specified code; no info table emitSimpleProc lbl code = do { stmts <- getCgStmts code ; blks <- cgStmtsToBlocks stmts ; emitProc (CmmInfo Nothing Nothing CmmNonInfoTable) lbl [] blks } getCmm :: Code -> FCode Cmm -- Get all the CmmTops (there should be no stmts) -- Return a single Cmm which may be split from other Cmms by -- object splitting (at a later stage) getCmm code = do { state1 <- getState ; ((), state2) <- withState code (state1 { cgs_tops = nilOL }) ; setState $ state2 { cgs_tops = cgs_tops state1 } ; return (Cmm (fromOL (cgs_tops state2))) } -- ---------------------------------------------------------------------------- -- CgStmts -- These functions deal in terms of CgStmts, which is an abstract type -- representing the code in the current proc. -- emit CgStmts into the current instruction stream emitCgStmts :: CgStmts -> Code emitCgStmts stmts = do { state <- getState ; setState $ state { cgs_stmts = cgs_stmts state `appOL` stmts } } -- emit CgStmts outside the current instruction stream, and return a label forkCgStmts :: CgStmts -> FCode BlockId forkCgStmts stmts = do { id <- newLabelC ; emitCgStmt (CgFork id stmts) ; return id } -- turn CgStmts into [CmmBasicBlock], for making a new proc. cgStmtsToBlocks :: CgStmts -> FCode [CmmBasicBlock] cgStmtsToBlocks stmts = do { id <- newLabelC ; return (flattenCgStmts id stmts) } -- collect the code emitted by an FCode computation getCgStmts' :: FCode a -> FCode (a, CgStmts) getCgStmts' fcode = do { state1 <- getState ; (a, state2) <- withState fcode (state1 { cgs_stmts = nilOL }) ; setState $ state2 { cgs_stmts = cgs_stmts state1 } ; return (a, cgs_stmts state2) } getCgStmts :: FCode a -> FCode CgStmts getCgStmts fcode = do { (_,stmts) <- getCgStmts' fcode; return stmts } -- Simple ways to construct CgStmts: noCgStmts :: CgStmts noCgStmts = nilOL oneCgStmt :: CmmStmt -> CgStmts oneCgStmt stmt = unitOL (CgStmt stmt) consCgStmt :: CmmStmt -> CgStmts -> CgStmts consCgStmt stmt stmts = CgStmt stmt `consOL` stmts -- ---------------------------------------------------------------------------- -- Get the current module name getModuleName :: FCode Module getModuleName = do { info <- getInfoDown; return (cgd_mod info) } -- ---------------------------------------------------------------------------- -- Get/set the end-of-block info setEndOfBlockInfo :: EndOfBlockInfo -> Code -> Code setEndOfBlockInfo eob_info code = do info <- getInfoDown withInfoDown code (info {cgd_eob = eob_info}) getEndOfBlockInfo :: FCode EndOfBlockInfo getEndOfBlockInfo = do info <- getInfoDown return (cgd_eob info) -- ---------------------------------------------------------------------------- -- Get/set the current SRT label -- There is just one SRT for each top level binding; all the nested -- bindings use sub-sections of this SRT. The label is passed down to -- the nested bindings via the monad. getSRTLabel :: FCode CLabel -- Used only by cgPanic getSRTLabel = do info <- getInfoDown return (cgd_srt_lbl info) setSRTLabel :: CLabel -> FCode a -> FCode a setSRTLabel srt_lbl code = do info <- getInfoDown withInfoDown code (info { cgd_srt_lbl = srt_lbl}) getSRT :: FCode SRT getSRT = do info <- getInfoDown return (cgd_srt info) setSRT :: SRT -> FCode a -> FCode a setSRT srt code = do info <- getInfoDown withInfoDown code (info { cgd_srt = srt}) -- ---------------------------------------------------------------------------- -- Get/set the current ticky counter label getTickyCtrLabel :: FCode CLabel getTickyCtrLabel = do info <- getInfoDown return (cgd_ticky info) setTickyCtrLabel :: CLabel -> Code -> Code setTickyCtrLabel ticky code = do info <- getInfoDown withInfoDown code (info {cgd_ticky = ticky}) \end{code}