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{-# LANGUAGE CPP #-}
-----------------------------------------------------------------------------
--
-- Stg to C-- code generation
--
-- (c) The University of Glasgow 2004-2006
--
-----------------------------------------------------------------------------
module StgCmm ( codeGen ) where
#include "HsVersions.h"
import StgCmmProf (initCostCentres, ldvEnter)
import StgCmmMonad
import StgCmmEnv
import StgCmmBind
import StgCmmCon
import StgCmmLayout
import StgCmmUtils
import StgCmmClosure
import StgCmmHpc
import StgCmmTicky
import Cmm
import CmmUtils
import CLabel
import StgSyn
import DynFlags
import HscTypes
import CostCentre
import Id
import IdInfo
import RepType
import DataCon
import Name
import TyCon
import Module
import Outputable
import Stream
import BasicTypes
import OrdList
import MkGraph
import qualified Data.ByteString as BS
import Data.IORef
import Control.Monad (when,void)
import Util
codeGen :: DynFlags
-> Module
-> [TyCon]
-> CollectedCCs -- (Local/global) cost-centres needing declaring/registering.
-> [StgTopBinding] -- Bindings to convert
-> HpcInfo
-> Stream IO CmmGroup () -- Output as a stream, so codegen can
-- be interleaved with output
codeGen dflags this_mod data_tycons
cost_centre_info stg_binds hpc_info
= do { -- cg: run the code generator, and yield the resulting CmmGroup
-- Using an IORef to store the state is a bit crude, but otherwise
-- we would need to add a state monad layer.
; cgref <- liftIO $ newIORef =<< initC
; let cg :: FCode () -> Stream IO CmmGroup ()
cg fcode = do
cmm <- liftIO $ do
st <- readIORef cgref
let (a,st') = runC dflags this_mod st (getCmm fcode)
-- NB. stub-out cgs_tops and cgs_stmts. This fixes
-- a big space leak. DO NOT REMOVE!
writeIORef cgref $! st'{ cgs_tops = nilOL,
cgs_stmts = mkNop }
return a
yield cmm
-- Note [codegen-split-init] the cmm_init block must come
-- FIRST. This is because when -split-objs is on we need to
-- combine this block with its initialisation routines; see
-- Note [pipeline-split-init].
; cg (mkModuleInit cost_centre_info this_mod hpc_info)
; mapM_ (cg . cgTopBinding dflags) stg_binds
-- Put datatype_stuff after code_stuff, because the
-- datatype closure table (for enumeration types) to
-- (say) PrelBase_True_closure, which is defined in
-- code_stuff
; let do_tycon tycon = do
-- Generate a table of static closures for an
-- enumeration type Note that the closure pointers are
-- tagged.
when (isEnumerationTyCon tycon) $ cg (cgEnumerationTyCon tycon)
mapM_ (cg . cgDataCon) (tyConDataCons tycon)
; mapM_ do_tycon data_tycons
}
---------------------------------------------------------------
-- Top-level bindings
---------------------------------------------------------------
{- 'cgTopBinding' is only used for top-level bindings, since they need
to be allocated statically (not in the heap) and need to be labelled.
No unboxed bindings can happen at top level.
In the code below, the static bindings are accumulated in the
@MkCgState@, and transferred into the ``statics'' slot by @forkStatics@.
This is so that we can write the top level processing in a compositional
style, with the increasing static environment being plumbed as a state
variable. -}
cgTopBinding :: DynFlags -> StgTopBinding -> FCode ()
cgTopBinding dflags (StgTopLifted (StgNonRec id rhs))
= do { id' <- maybeExternaliseId dflags id
; let (info, fcode) = cgTopRhs dflags NonRecursive id' rhs
; fcode
; addBindC info -- Add the *un-externalised* Id to the envt,
-- so we find it when we look up occurrences
}
cgTopBinding dflags (StgTopLifted (StgRec pairs))
= do { let (bndrs, rhss) = unzip pairs
; bndrs' <- Prelude.mapM (maybeExternaliseId dflags) bndrs
; let pairs' = zip bndrs' rhss
r = unzipWith (cgTopRhs dflags Recursive) pairs'
(infos, fcodes) = unzip r
; addBindsC infos
; sequence_ fcodes
}
cgTopBinding dflags (StgTopStringLit id str)
= do { id' <- maybeExternaliseId dflags id
; let label = mkBytesLabel (idName id')
; let (lit, decl) = mkByteStringCLit label (BS.unpack str)
; emitDecl decl
; addBindC (litIdInfo dflags id' mkLFStringLit lit)
}
cgTopRhs :: DynFlags -> RecFlag -> Id -> StgRhs -> (CgIdInfo, FCode ())
-- The Id is passed along for setting up a binding...
-- It's already been externalised if necessary
cgTopRhs dflags _rec bndr (StgRhsCon _cc con args)
= cgTopRhsCon dflags bndr con (assertNonVoidStgArgs args)
-- con args are always non-void,
-- see Note [Post-unarisation invariants] in UnariseStg
cgTopRhs dflags rec bndr (StgRhsClosure cc bi fvs upd_flag args body)
= ASSERT(null fvs) -- There should be no free variables
cgTopRhsClosure dflags rec bndr cc bi upd_flag args body
---------------------------------------------------------------
-- Module initialisation code
---------------------------------------------------------------
{- The module initialisation code looks like this, roughly:
FN(__stginit_Foo) {
JMP_(__stginit_Foo_1_p)
}
FN(__stginit_Foo_1_p) {
...
}
We have one version of the init code with a module version and the
'way' attached to it. The version number helps to catch cases
where modules are not compiled in dependency order before being
linked: if a module has been compiled since any modules which depend on
it, then the latter modules will refer to a different version in their
init blocks and a link error will ensue.
The 'way' suffix helps to catch cases where modules compiled in different
ways are linked together (eg. profiled and non-profiled).
We provide a plain, unadorned, version of the module init code
which just jumps to the version with the label and way attached. The
reason for this is that when using foreign exports, the caller of
startupHaskell() must supply the name of the init function for the "top"
module in the program, and we don't want to require that this name
has the version and way info appended to it.
We initialise the module tree by keeping a work-stack,
* pointed to by Sp
* that grows downward
* Sp points to the last occupied slot
-}
mkModuleInit
:: CollectedCCs -- cost centre info
-> Module
-> HpcInfo
-> FCode ()
mkModuleInit cost_centre_info this_mod hpc_info
= do { initHpc this_mod hpc_info
; initCostCentres cost_centre_info
-- For backwards compatibility: user code may refer to this
-- label for calling hs_add_root().
; let lbl = mkPlainModuleInitLabel this_mod
; emitDecl (CmmData (Section Data lbl) (Statics lbl []))
}
---------------------------------------------------------------
-- Generating static stuff for algebraic data types
---------------------------------------------------------------
cgEnumerationTyCon :: TyCon -> FCode ()
cgEnumerationTyCon tycon
= do dflags <- getDynFlags
emitRODataLits (mkLocalClosureTableLabel (tyConName tycon) NoCafRefs)
[ CmmLabelOff (mkLocalClosureLabel (dataConName con) NoCafRefs)
(tagForCon dflags con)
| con <- tyConDataCons tycon]
cgDataCon :: DataCon -> FCode ()
-- Generate the entry code, info tables, and (for niladic constructor)
-- the static closure, for a constructor.
cgDataCon data_con
= do { dflags <- getDynFlags
; let
(tot_wds, -- #ptr_wds + #nonptr_wds
ptr_wds) -- #ptr_wds
= mkVirtConstrSizes dflags arg_reps
nonptr_wds = tot_wds - ptr_wds
dyn_info_tbl =
mkDataConInfoTable dflags data_con False ptr_wds nonptr_wds
-- We're generating info tables, so we don't know and care about
-- what the actual arguments are. Using () here as the place holder.
arg_reps :: [NonVoid PrimRep]
arg_reps = [ NonVoid rep_ty
| ty <- dataConRepArgTys data_con
, rep_ty <- typePrimRep ty
, not (isVoidRep rep_ty) ]
; emitClosureAndInfoTable dyn_info_tbl NativeDirectCall [] $
-- NB: the closure pointer is assumed *untagged* on
-- entry to a constructor. If the pointer is tagged,
-- then we should not be entering it. This assumption
-- is used in ldvEnter and when tagging the pointer to
-- return it.
-- NB 2: We don't set CC when entering data (WDP 94/06)
do { tickyEnterDynCon
; ldvEnter (CmmReg nodeReg)
; tickyReturnOldCon (length arg_reps)
; void $ emitReturn [cmmOffsetB dflags (CmmReg nodeReg) (tagForCon dflags data_con)]
}
-- The case continuation code expects a tagged pointer
}
---------------------------------------------------------------
-- Stuff to support splitting
---------------------------------------------------------------
maybeExternaliseId :: DynFlags -> Id -> FCode Id
maybeExternaliseId dflags id
| gopt Opt_SplitObjs dflags, -- See Note [Externalise when splitting]
-- in StgCmmMonad
isInternalName name = do { mod <- getModuleName
; returnFC (setIdName id (externalise mod)) }
| otherwise = returnFC id
where
externalise mod = mkExternalName uniq mod new_occ loc
name = idName id
uniq = nameUnique name
new_occ = mkLocalOcc uniq (nameOccName name)
loc = nameSrcSpan name
-- We want to conjure up a name that can't clash with any
-- existing name. So we generate
-- Mod_$L243foo
-- where 243 is the unique.
|
