ghc-8.10.1: nativeGen/AsmCodeGen.hs
-- -----------------------------------------------------------------------------
--
-- (c) The University of Glasgow 1993-2004
--
-- This is the top-level module in the native code generator.
--
-- -----------------------------------------------------------------------------
{-# LANGUAGE BangPatterns, CPP, GADTs, ScopedTypeVariables, PatternSynonyms,
DeriveFunctor #-}
#if !defined(GHC_LOADED_INTO_GHCI)
{-# LANGUAGE UnboxedTuples #-}
#endif
module AsmCodeGen (
-- * Module entry point
nativeCodeGen
-- * Test-only exports: see trac #12744
-- used by testGraphNoSpills, which needs to access
-- the register allocator intermediate data structures
-- cmmNativeGen emits
, cmmNativeGen
, NcgImpl(..)
, x86NcgImpl
) where
#include "HsVersions.h"
import GhcPrelude
import qualified X86.CodeGen
import qualified X86.Regs
import qualified X86.Instr
import qualified X86.Ppr
import qualified SPARC.CodeGen
import qualified SPARC.Regs
import qualified SPARC.Instr
import qualified SPARC.Ppr
import qualified SPARC.ShortcutJump
import qualified SPARC.CodeGen.Expand
import qualified PPC.CodeGen
import qualified PPC.Regs
import qualified PPC.RegInfo
import qualified PPC.Instr
import qualified PPC.Ppr
import RegAlloc.Liveness
import qualified RegAlloc.Linear.Main as Linear
import qualified GraphColor as Color
import qualified RegAlloc.Graph.Main as Color
import qualified RegAlloc.Graph.Stats as Color
import qualified RegAlloc.Graph.TrivColorable as Color
import AsmUtils
import TargetReg
import GHC.Platform
import BlockLayout
import Config
import Instruction
import PIC
import Reg
import NCGMonad
import CFG
import Dwarf
import Debug
import BlockId
import GHC.StgToCmm.CgUtils ( fixStgRegisters )
import Cmm
import CmmUtils
import Hoopl.Collections
import Hoopl.Label
import Hoopl.Block
import CmmOpt ( cmmMachOpFold )
import PprCmm
import CLabel
import UniqFM
import UniqSupply
import DynFlags
import Util
import BasicTypes ( Alignment )
import qualified Pretty
import BufWrite
import Outputable
import FastString
import UniqSet
import ErrUtils
import Module
import Stream (Stream)
import qualified Stream
-- DEBUGGING ONLY
--import OrdList
import Data.List
import Data.Maybe
import Data.Ord ( comparing )
import Control.Exception
import Control.Monad
import System.IO
{-
The native-code generator has machine-independent and
machine-dependent modules.
This module ("AsmCodeGen") is the top-level machine-independent
module. Before entering machine-dependent land, we do some
machine-independent optimisations (defined below) on the
'CmmStmts's.
We convert to the machine-specific 'Instr' datatype with
'cmmCodeGen', assuming an infinite supply of registers. We then use
a machine-independent register allocator ('regAlloc') to rejoin
reality. Obviously, 'regAlloc' has machine-specific helper
functions (see about "RegAllocInfo" below).
Finally, we order the basic blocks of the function so as to minimise
the number of jumps between blocks, by utilising fallthrough wherever
possible.
The machine-dependent bits break down as follows:
* ["MachRegs"] Everything about the target platform's machine
registers (and immediate operands, and addresses, which tend to
intermingle/interact with registers).
* ["MachInstrs"] Includes the 'Instr' datatype (possibly should
have a module of its own), plus a miscellany of other things
(e.g., 'targetDoubleSize', 'smStablePtrTable', ...)
* ["MachCodeGen"] is where 'Cmm' stuff turns into
machine instructions.
* ["PprMach"] 'pprInstr' turns an 'Instr' into text (well, really
a 'SDoc').
* ["RegAllocInfo"] In the register allocator, we manipulate
'MRegsState's, which are 'BitSet's, one bit per machine register.
When we want to say something about a specific machine register
(e.g., ``it gets clobbered by this instruction''), we set/unset
its bit. Obviously, we do this 'BitSet' thing for efficiency
reasons.
The 'RegAllocInfo' module collects together the machine-specific
info needed to do register allocation.
* ["RegisterAlloc"] The (machine-independent) register allocator.
-}
--------------------
nativeCodeGen :: forall a . DynFlags -> Module -> ModLocation -> Handle -> UniqSupply
-> Stream IO RawCmmGroup a
-> IO a
nativeCodeGen dflags this_mod modLoc h us cmms
= let platform = targetPlatform dflags
nCG' :: ( Outputable statics, Outputable instr
, Outputable jumpDest, Instruction instr)
=> NcgImpl statics instr jumpDest -> IO a
nCG' ncgImpl = nativeCodeGen' dflags this_mod modLoc ncgImpl h us cmms
in case platformArch platform of
ArchX86 -> nCG' (x86NcgImpl dflags)
ArchX86_64 -> nCG' (x86_64NcgImpl dflags)
ArchPPC -> nCG' (ppcNcgImpl dflags)
ArchS390X -> panic "nativeCodeGen: No NCG for S390X"
ArchSPARC -> nCG' (sparcNcgImpl dflags)
ArchSPARC64 -> panic "nativeCodeGen: No NCG for SPARC64"
ArchARM {} -> panic "nativeCodeGen: No NCG for ARM"
ArchARM64 -> panic "nativeCodeGen: No NCG for ARM64"
ArchPPC_64 _ -> nCG' (ppcNcgImpl dflags)
ArchAlpha -> panic "nativeCodeGen: No NCG for Alpha"
ArchMipseb -> panic "nativeCodeGen: No NCG for mipseb"
ArchMipsel -> panic "nativeCodeGen: No NCG for mipsel"
ArchUnknown -> panic "nativeCodeGen: No NCG for unknown arch"
ArchJavaScript-> panic "nativeCodeGen: No NCG for JavaScript"
x86NcgImpl :: DynFlags -> NcgImpl (Alignment, CmmStatics)
X86.Instr.Instr X86.Instr.JumpDest
x86NcgImpl dflags
= (x86_64NcgImpl dflags)
x86_64NcgImpl :: DynFlags -> NcgImpl (Alignment, CmmStatics)
X86.Instr.Instr X86.Instr.JumpDest
x86_64NcgImpl dflags
= NcgImpl {
cmmTopCodeGen = X86.CodeGen.cmmTopCodeGen
,generateJumpTableForInstr = X86.CodeGen.generateJumpTableForInstr dflags
,getJumpDestBlockId = X86.Instr.getJumpDestBlockId
,canShortcut = X86.Instr.canShortcut
,shortcutStatics = X86.Instr.shortcutStatics
,shortcutJump = X86.Instr.shortcutJump
,pprNatCmmDecl = X86.Ppr.pprNatCmmDecl
,maxSpillSlots = X86.Instr.maxSpillSlots dflags
,allocatableRegs = X86.Regs.allocatableRegs platform
,ncgAllocMoreStack = X86.Instr.allocMoreStack platform
,ncgExpandTop = id
,ncgMakeFarBranches = const id
,extractUnwindPoints = X86.CodeGen.extractUnwindPoints
,invertCondBranches = X86.CodeGen.invertCondBranches
}
where platform = targetPlatform dflags
ppcNcgImpl :: DynFlags -> NcgImpl CmmStatics PPC.Instr.Instr PPC.RegInfo.JumpDest
ppcNcgImpl dflags
= NcgImpl {
cmmTopCodeGen = PPC.CodeGen.cmmTopCodeGen
,generateJumpTableForInstr = PPC.CodeGen.generateJumpTableForInstr dflags
,getJumpDestBlockId = PPC.RegInfo.getJumpDestBlockId
,canShortcut = PPC.RegInfo.canShortcut
,shortcutStatics = PPC.RegInfo.shortcutStatics
,shortcutJump = PPC.RegInfo.shortcutJump
,pprNatCmmDecl = PPC.Ppr.pprNatCmmDecl
,maxSpillSlots = PPC.Instr.maxSpillSlots dflags
,allocatableRegs = PPC.Regs.allocatableRegs platform
,ncgAllocMoreStack = PPC.Instr.allocMoreStack platform
,ncgExpandTop = id
,ncgMakeFarBranches = PPC.Instr.makeFarBranches
,extractUnwindPoints = const []
,invertCondBranches = \_ _ -> id
}
where platform = targetPlatform dflags
sparcNcgImpl :: DynFlags -> NcgImpl CmmStatics SPARC.Instr.Instr SPARC.ShortcutJump.JumpDest
sparcNcgImpl dflags
= NcgImpl {
cmmTopCodeGen = SPARC.CodeGen.cmmTopCodeGen
,generateJumpTableForInstr = SPARC.CodeGen.generateJumpTableForInstr dflags
,getJumpDestBlockId = SPARC.ShortcutJump.getJumpDestBlockId
,canShortcut = SPARC.ShortcutJump.canShortcut
,shortcutStatics = SPARC.ShortcutJump.shortcutStatics
,shortcutJump = SPARC.ShortcutJump.shortcutJump
,pprNatCmmDecl = SPARC.Ppr.pprNatCmmDecl
,maxSpillSlots = SPARC.Instr.maxSpillSlots dflags
,allocatableRegs = SPARC.Regs.allocatableRegs
,ncgAllocMoreStack = noAllocMoreStack
,ncgExpandTop = map SPARC.CodeGen.Expand.expandTop
,ncgMakeFarBranches = const id
,extractUnwindPoints = const []
,invertCondBranches = \_ _ -> id
}
--
-- Allocating more stack space for spilling is currently only
-- supported for the linear register allocator on x86/x86_64, the rest
-- default to the panic below. To support allocating extra stack on
-- more platforms provide a definition of ncgAllocMoreStack.
--
noAllocMoreStack :: Int -> NatCmmDecl statics instr
-> UniqSM (NatCmmDecl statics instr, [(BlockId,BlockId)])
noAllocMoreStack amount _
= panic $ "Register allocator: out of stack slots (need " ++ show amount ++ ")\n"
++ " If you are trying to compile SHA1.hs from the crypto library then this\n"
++ " is a known limitation in the linear allocator.\n"
++ "\n"
++ " Try enabling the graph colouring allocator with -fregs-graph instead."
++ " You can still file a bug report if you like.\n"
-- | Data accumulated during code generation. Mostly about statistics,
-- but also collects debug data for DWARF generation.
data NativeGenAcc statics instr
= NGS { ngs_imports :: ![[CLabel]]
, ngs_natives :: ![[NatCmmDecl statics instr]]
-- ^ Native code generated, for statistics. This might
-- hold a lot of data, so it is important to clear this
-- field as early as possible if it isn't actually
-- required.
, ngs_colorStats :: ![[Color.RegAllocStats statics instr]]
, ngs_linearStats :: ![[Linear.RegAllocStats]]
, ngs_labels :: ![Label]
, ngs_debug :: ![DebugBlock]
, ngs_dwarfFiles :: !DwarfFiles
, ngs_unwinds :: !(LabelMap [UnwindPoint])
-- ^ see Note [Unwinding information in the NCG]
-- and Note [What is this unwinding business?] in Debug.
}
{-
Note [Unwinding information in the NCG]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Unwind information is a type of metadata which allows a debugging tool
to reconstruct the values of machine registers at the time a procedure was
entered. For the most part, the production of unwind information is handled by
the Cmm stage, where it is represented by CmmUnwind nodes.
Unfortunately, the Cmm stage doesn't know everything necessary to produce
accurate unwinding information. For instance, the x86-64 calling convention
requires that the stack pointer be aligned to 16 bytes, which in turn means that
GHC must sometimes add padding to $sp prior to performing a foreign call. When
this happens unwind information must be updated accordingly.
For this reason, we make the NCG backends responsible for producing
unwinding tables (with the extractUnwindPoints function in NcgImpl).
We accumulate the produced unwind tables over CmmGroups in the ngs_unwinds
field of NativeGenAcc. This is a label map which contains an entry for each
procedure, containing a list of unwinding points (e.g. a label and an associated
unwinding table).
See also Note [What is this unwinding business?] in Debug.
-}
nativeCodeGen' :: (Outputable statics, Outputable instr,Outputable jumpDest,
Instruction instr)
=> DynFlags
-> Module -> ModLocation
-> NcgImpl statics instr jumpDest
-> Handle
-> UniqSupply
-> Stream IO RawCmmGroup a
-> IO a
nativeCodeGen' dflags this_mod modLoc ncgImpl h us cmms
= do
-- BufHandle is a performance hack. We could hide it inside
-- Pretty if it weren't for the fact that we do lots of little
-- printDocs here (in order to do codegen in constant space).
bufh <- newBufHandle h
let ngs0 = NGS [] [] [] [] [] [] emptyUFM mapEmpty
(ngs, us', a) <- cmmNativeGenStream dflags this_mod modLoc ncgImpl bufh us
cmms ngs0
_ <- finishNativeGen dflags modLoc bufh us' ngs
return a
finishNativeGen :: Instruction instr
=> DynFlags
-> ModLocation
-> BufHandle
-> UniqSupply
-> NativeGenAcc statics instr
-> IO UniqSupply
finishNativeGen dflags modLoc bufh@(BufHandle _ _ h) us ngs
= withTimingSilent dflags (text "NCG") (`seq` ()) $ do
-- Write debug data and finish
let emitDw = debugLevel dflags > 0
us' <- if not emitDw then return us else do
(dwarf, us') <- dwarfGen dflags modLoc us (ngs_debug ngs)
emitNativeCode dflags bufh dwarf
return us'
bFlush bufh
-- dump global NCG stats for graph coloring allocator
let stats = concat (ngs_colorStats ngs)
unless (null stats) $ do
-- build the global register conflict graph
let graphGlobal
= foldl' Color.union Color.initGraph
$ [ Color.raGraph stat
| stat@Color.RegAllocStatsStart{} <- stats]
dump_stats (Color.pprStats stats graphGlobal)
let platform = targetPlatform dflags
dumpIfSet_dyn dflags
Opt_D_dump_asm_conflicts "Register conflict graph"
$ Color.dotGraph
(targetRegDotColor platform)
(Color.trivColorable platform
(targetVirtualRegSqueeze platform)
(targetRealRegSqueeze platform))
$ graphGlobal
-- dump global NCG stats for linear allocator
let linearStats = concat (ngs_linearStats ngs)
unless (null linearStats) $
dump_stats (Linear.pprStats (concat (ngs_natives ngs)) linearStats)
-- write out the imports
printSDocLn Pretty.LeftMode dflags h (mkCodeStyle AsmStyle)
$ makeImportsDoc dflags (concat (ngs_imports ngs))
return us'
where
dump_stats = dumpSDoc dflags alwaysQualify Opt_D_dump_asm_stats "NCG stats"
cmmNativeGenStream :: (Outputable statics, Outputable instr
,Outputable jumpDest, Instruction instr)
=> DynFlags
-> Module -> ModLocation
-> NcgImpl statics instr jumpDest
-> BufHandle
-> UniqSupply
-> Stream IO RawCmmGroup a
-> NativeGenAcc statics instr
-> IO (NativeGenAcc statics instr, UniqSupply, a)
cmmNativeGenStream dflags this_mod modLoc ncgImpl h us cmm_stream ngs
= do r <- Stream.runStream cmm_stream
case r of
Left a ->
return (ngs { ngs_imports = reverse $ ngs_imports ngs
, ngs_natives = reverse $ ngs_natives ngs
, ngs_colorStats = reverse $ ngs_colorStats ngs
, ngs_linearStats = reverse $ ngs_linearStats ngs
},
us,
a)
Right (cmms, cmm_stream') -> do
(us', ngs'') <-
withTimingSilent
dflags
ncglabel (\(a, b) -> a `seq` b `seq` ()) $ do
-- Generate debug information
let debugFlag = debugLevel dflags > 0
!ndbgs | debugFlag = cmmDebugGen modLoc cmms
| otherwise = []
dbgMap = debugToMap ndbgs
-- Generate native code
(ngs',us') <- cmmNativeGens dflags this_mod modLoc ncgImpl h
dbgMap us cmms ngs 0
-- Link native code information into debug blocks
-- See Note [What is this unwinding business?] in Debug.
let !ldbgs = cmmDebugLink (ngs_labels ngs') (ngs_unwinds ngs') ndbgs
unless (null ldbgs) $
dumpIfSet_dyn dflags Opt_D_dump_debug "Debug Infos"
(vcat $ map ppr ldbgs)
-- Accumulate debug information for emission in finishNativeGen.
let ngs'' = ngs' { ngs_debug = ngs_debug ngs' ++ ldbgs, ngs_labels = [] }
return (us', ngs'')
cmmNativeGenStream dflags this_mod modLoc ncgImpl h us'
cmm_stream' ngs''
where ncglabel = text "NCG"
-- | Do native code generation on all these cmms.
--
cmmNativeGens :: forall statics instr jumpDest.
(Outputable statics, Outputable instr
,Outputable jumpDest, Instruction instr)
=> DynFlags
-> Module -> ModLocation
-> NcgImpl statics instr jumpDest
-> BufHandle
-> LabelMap DebugBlock
-> UniqSupply
-> [RawCmmDecl]
-> NativeGenAcc statics instr
-> Int
-> IO (NativeGenAcc statics instr, UniqSupply)
cmmNativeGens dflags this_mod modLoc ncgImpl h dbgMap = go
where
go :: UniqSupply -> [RawCmmDecl]
-> NativeGenAcc statics instr -> Int
-> IO (NativeGenAcc statics instr, UniqSupply)
go us [] ngs !_ =
return (ngs, us)
go us (cmm : cmms) ngs count = do
let fileIds = ngs_dwarfFiles ngs
(us', fileIds', native, imports, colorStats, linearStats, unwinds)
<- {-# SCC "cmmNativeGen" #-}
cmmNativeGen dflags this_mod modLoc ncgImpl us fileIds dbgMap
cmm count
-- Generate .file directives for every new file that has been
-- used. Note that it is important that we generate these in
-- ascending order, as Clang's 3.6 assembler complains.
let newFileIds = sortBy (comparing snd) $
nonDetEltsUFM $ fileIds' `minusUFM` fileIds
-- See Note [Unique Determinism and code generation]
pprDecl (f,n) = text "\t.file " <> ppr n <+>
pprFilePathString (unpackFS f)
emitNativeCode dflags h $ vcat $
map pprDecl newFileIds ++
map (pprNatCmmDecl ncgImpl) native
-- force evaluation all this stuff to avoid space leaks
{-# SCC "seqString" #-} evaluate $ seqList (showSDoc dflags $ vcat $ map ppr imports) ()
let !labels' = if debugLevel dflags > 0
then cmmDebugLabels isMetaInstr native else []
!natives' = if dopt Opt_D_dump_asm_stats dflags
then native : ngs_natives ngs else []
mCon = maybe id (:)
ngs' = ngs{ ngs_imports = imports : ngs_imports ngs
, ngs_natives = natives'
, ngs_colorStats = colorStats `mCon` ngs_colorStats ngs
, ngs_linearStats = linearStats `mCon` ngs_linearStats ngs
, ngs_labels = ngs_labels ngs ++ labels'
, ngs_dwarfFiles = fileIds'
, ngs_unwinds = ngs_unwinds ngs `mapUnion` unwinds
}
go us' cmms ngs' (count + 1)
emitNativeCode :: DynFlags -> BufHandle -> SDoc -> IO ()
emitNativeCode dflags h sdoc = do
{-# SCC "pprNativeCode" #-} bufLeftRenderSDoc dflags h
(mkCodeStyle AsmStyle) sdoc
-- dump native code
dumpIfSet_dyn dflags
Opt_D_dump_asm "Asm code"
sdoc
-- | Complete native code generation phase for a single top-level chunk of Cmm.
-- Dumping the output of each stage along the way.
-- Global conflict graph and NGC stats
cmmNativeGen
:: forall statics instr jumpDest. (Instruction instr,
Outputable statics, Outputable instr, Outputable jumpDest)
=> DynFlags
-> Module -> ModLocation
-> NcgImpl statics instr jumpDest
-> UniqSupply
-> DwarfFiles
-> LabelMap DebugBlock
-> RawCmmDecl -- ^ the cmm to generate code for
-> Int -- ^ sequence number of this top thing
-> IO ( UniqSupply
, DwarfFiles
, [NatCmmDecl statics instr] -- native code
, [CLabel] -- things imported by this cmm
, Maybe [Color.RegAllocStats statics instr] -- stats for the coloring register allocator
, Maybe [Linear.RegAllocStats] -- stats for the linear register allocators
, LabelMap [UnwindPoint] -- unwinding information for blocks
)
cmmNativeGen dflags this_mod modLoc ncgImpl us fileIds dbgMap cmm count
= do
let platform = targetPlatform dflags
let proc_name = case cmm of
(CmmProc _ entry_label _ _) -> ppr entry_label
_ -> text "DataChunk"
-- rewrite assignments to global regs
let fixed_cmm =
{-# SCC "fixStgRegisters" #-}
fixStgRegisters dflags cmm
-- cmm to cmm optimisations
let (opt_cmm, imports) =
{-# SCC "cmmToCmm" #-}
cmmToCmm dflags this_mod fixed_cmm
dumpIfSet_dyn dflags
Opt_D_dump_opt_cmm "Optimised Cmm"
(pprCmmGroup [opt_cmm])
let cmmCfg = {-# SCC "getCFG" #-}
getCfgProc (cfgWeightInfo dflags) opt_cmm
-- generate native code from cmm
let ((native, lastMinuteImports, fileIds', nativeCfgWeights), usGen) =
{-# SCC "genMachCode" #-}
initUs us $ genMachCode dflags this_mod modLoc
(cmmTopCodeGen ncgImpl)
fileIds dbgMap opt_cmm cmmCfg
dumpIfSet_dyn dflags
Opt_D_dump_asm_native "Native code"
(vcat $ map (pprNatCmmDecl ncgImpl) native)
maybeDumpCfg dflags (Just nativeCfgWeights) "CFG Weights - Native" proc_name
-- tag instructions with register liveness information
-- also drops dead code. We don't keep the cfg in sync on
-- some backends, so don't use it there.
let livenessCfg = if (backendMaintainsCfg dflags)
then Just nativeCfgWeights
else Nothing
let (withLiveness, usLive) =
{-# SCC "regLiveness" #-}
initUs usGen
$ mapM (cmmTopLiveness livenessCfg platform) native
dumpIfSet_dyn dflags
Opt_D_dump_asm_liveness "Liveness annotations added"
(vcat $ map ppr withLiveness)
-- allocate registers
(alloced, usAlloc, ppr_raStatsColor, ppr_raStatsLinear, raStats, stack_updt_blks) <-
if ( gopt Opt_RegsGraph dflags
|| gopt Opt_RegsIterative dflags )
then do
-- the regs usable for allocation
let (alloc_regs :: UniqFM (UniqSet RealReg))
= foldr (\r -> plusUFM_C unionUniqSets
$ unitUFM (targetClassOfRealReg platform r) (unitUniqSet r))
emptyUFM
$ allocatableRegs ncgImpl
-- do the graph coloring register allocation
let ((alloced, maybe_more_stack, regAllocStats), usAlloc)
= {-# SCC "RegAlloc-color" #-}
initUs usLive
$ Color.regAlloc
dflags
alloc_regs
(mkUniqSet [0 .. maxSpillSlots ncgImpl])
(maxSpillSlots ncgImpl)
withLiveness
livenessCfg
let ((alloced', stack_updt_blks), usAlloc')
= initUs usAlloc $
case maybe_more_stack of
Nothing -> return (alloced, [])
Just amount -> do
(alloced',stack_updt_blks) <- unzip <$>
(mapM ((ncgAllocMoreStack ncgImpl) amount) alloced)
return (alloced', concat stack_updt_blks )
-- dump out what happened during register allocation
dumpIfSet_dyn dflags
Opt_D_dump_asm_regalloc "Registers allocated"
(vcat $ map (pprNatCmmDecl ncgImpl) alloced)
dumpIfSet_dyn dflags
Opt_D_dump_asm_regalloc_stages "Build/spill stages"
(vcat $ map (\(stage, stats)
-> text "# --------------------------"
$$ text "# cmm " <> int count <> text " Stage " <> int stage
$$ ppr stats)
$ zip [0..] regAllocStats)
let mPprStats =
if dopt Opt_D_dump_asm_stats dflags
then Just regAllocStats else Nothing
-- force evaluation of the Maybe to avoid space leak
mPprStats `seq` return ()
return ( alloced', usAlloc'
, mPprStats
, Nothing
, [], stack_updt_blks)
else do
-- do linear register allocation
let reg_alloc proc = do
(alloced, maybe_more_stack, ra_stats) <-
Linear.regAlloc dflags proc
case maybe_more_stack of
Nothing -> return ( alloced, ra_stats, [] )
Just amount -> do
(alloced',stack_updt_blks) <-
ncgAllocMoreStack ncgImpl amount alloced
return (alloced', ra_stats, stack_updt_blks )
let ((alloced, regAllocStats, stack_updt_blks), usAlloc)
= {-# SCC "RegAlloc-linear" #-}
initUs usLive
$ liftM unzip3
$ mapM reg_alloc withLiveness
dumpIfSet_dyn dflags
Opt_D_dump_asm_regalloc "Registers allocated"
(vcat $ map (pprNatCmmDecl ncgImpl) alloced)
let mPprStats =
if dopt Opt_D_dump_asm_stats dflags
then Just (catMaybes regAllocStats) else Nothing
-- force evaluation of the Maybe to avoid space leak
mPprStats `seq` return ()
return ( alloced, usAlloc
, Nothing
, mPprStats, (catMaybes regAllocStats)
, concat stack_updt_blks )
-- Fixupblocks the register allocator inserted (from, regMoves, to)
let cfgRegAllocUpdates :: [(BlockId,BlockId,BlockId)]
cfgRegAllocUpdates = (concatMap Linear.ra_fixupList raStats)
let cfgWithFixupBlks =
(\cfg -> addNodesBetween cfg cfgRegAllocUpdates) <$> livenessCfg
-- Insert stack update blocks
let postRegCFG =
pure (foldl' (\m (from,to) -> addImmediateSuccessor from to m ))
<*> cfgWithFixupBlks
<*> pure stack_updt_blks
---- generate jump tables
let tabled =
{-# SCC "generateJumpTables" #-}
generateJumpTables ncgImpl alloced
when (not $ null nativeCfgWeights) $ dumpIfSet_dyn dflags
Opt_D_dump_cfg_weights "CFG Update information"
( text "stack:" <+> ppr stack_updt_blks $$
text "linearAlloc:" <+> ppr cfgRegAllocUpdates )
---- shortcut branches
let (shorted, postShortCFG) =
{-# SCC "shortcutBranches" #-}
shortcutBranches dflags ncgImpl tabled postRegCFG
let optimizedCFG :: Maybe CFG
optimizedCFG =
optimizeCFG (cfgWeightInfo dflags) cmm <$!> postShortCFG
maybeDumpCfg dflags optimizedCFG "CFG Weights - Final" proc_name
--TODO: Partially check validity of the cfg.
let getBlks (CmmProc _info _lbl _live (ListGraph blocks)) = blocks
getBlks _ = []
when ( backendMaintainsCfg dflags &&
(gopt Opt_DoAsmLinting dflags || debugIsOn )) $ do
let blocks = concatMap getBlks shorted
let labels = setFromList $ fmap blockId blocks :: LabelSet
let cfg = fromJust optimizedCFG
return $! seq (sanityCheckCfg cfg labels $
text "cfg not in lockstep") ()
---- sequence blocks
let sequenced :: [NatCmmDecl statics instr]
sequenced =
checkLayout shorted $
{-# SCC "sequenceBlocks" #-}
map (BlockLayout.sequenceTop
dflags
ncgImpl optimizedCFG)
shorted
let branchOpt :: [NatCmmDecl statics instr]
branchOpt =
{-# SCC "invertCondBranches" #-}
map invert sequenced
where
invertConds :: LabelMap CmmStatics -> [NatBasicBlock instr]
-> [NatBasicBlock instr]
invertConds = invertCondBranches ncgImpl optimizedCFG
invert top@CmmData {} = top
invert (CmmProc info lbl live (ListGraph blocks)) =
CmmProc info lbl live (ListGraph $ invertConds info blocks)
---- expansion of SPARC synthetic instrs
let expanded =
{-# SCC "sparc_expand" #-}
ncgExpandTop ncgImpl branchOpt
--ncgExpandTop ncgImpl sequenced
dumpIfSet_dyn dflags
Opt_D_dump_asm_expanded "Synthetic instructions expanded"
(vcat $ map (pprNatCmmDecl ncgImpl) expanded)
-- generate unwinding information from cmm
let unwinds :: BlockMap [UnwindPoint]
unwinds =
{-# SCC "unwindingInfo" #-}
foldl' addUnwind mapEmpty expanded
where
addUnwind acc proc =
acc `mapUnion` computeUnwinding dflags ncgImpl proc
return ( usAlloc
, fileIds'
, expanded
, lastMinuteImports ++ imports
, ppr_raStatsColor
, ppr_raStatsLinear
, unwinds )
maybeDumpCfg :: DynFlags -> Maybe CFG -> String -> SDoc -> IO ()
maybeDumpCfg _dflags Nothing _ _ = return ()
maybeDumpCfg dflags (Just cfg) msg proc_name
| null cfg = return ()
| otherwise
= dumpIfSet_dyn
dflags Opt_D_dump_cfg_weights msg
(proc_name <> char ':' $$ pprEdgeWeights cfg)
-- | Make sure all blocks we want the layout algorithm to place have been placed.
checkLayout :: [NatCmmDecl statics instr] -> [NatCmmDecl statics instr]
-> [NatCmmDecl statics instr]
checkLayout procsUnsequenced procsSequenced =
ASSERT2(setNull diff,
ppr "Block sequencing dropped blocks:" <> ppr diff)
procsSequenced
where
blocks1 = foldl' (setUnion) setEmpty $
map getBlockIds procsUnsequenced :: LabelSet
blocks2 = foldl' (setUnion) setEmpty $
map getBlockIds procsSequenced
diff = setDifference blocks1 blocks2
getBlockIds (CmmData _ _) = setEmpty
getBlockIds (CmmProc _ _ _ (ListGraph blocks)) =
setFromList $ map blockId blocks
-- | Compute unwinding tables for the blocks of a procedure
computeUnwinding :: Instruction instr
=> DynFlags -> NcgImpl statics instr jumpDest
-> NatCmmDecl statics instr
-- ^ the native code generated for the procedure
-> LabelMap [UnwindPoint]
-- ^ unwinding tables for all points of all blocks of the
-- procedure
computeUnwinding dflags _ _
| debugLevel dflags == 0 = mapEmpty
computeUnwinding _ _ (CmmData _ _) = mapEmpty
computeUnwinding _ ncgImpl (CmmProc _ _ _ (ListGraph blks)) =
-- In general we would need to push unwinding information down the
-- block-level call-graph to ensure that we fully account for all
-- relevant register writes within a procedure.
--
-- However, the only unwinding information that we care about in GHC is for
-- Sp. The fact that CmmLayoutStack already ensures that we have unwind
-- information at the beginning of every block means that there is no need
-- to perform this sort of push-down.
mapFromList [ (blk_lbl, extractUnwindPoints ncgImpl instrs)
| BasicBlock blk_lbl instrs <- blks ]
-- | Build a doc for all the imports.
--
makeImportsDoc :: DynFlags -> [CLabel] -> SDoc
makeImportsDoc dflags imports
= dyld_stubs imports
$$
-- On recent versions of Darwin, the linker supports
-- dead-stripping of code and data on a per-symbol basis.
-- There's a hack to make this work in PprMach.pprNatCmmDecl.
(if platformHasSubsectionsViaSymbols platform
then text ".subsections_via_symbols"
else Outputable.empty)
$$
-- On recent GNU ELF systems one can mark an object file
-- as not requiring an executable stack. If all objects
-- linked into a program have this note then the program
-- will not use an executable stack, which is good for
-- security. GHC generated code does not need an executable
-- stack so add the note in:
(if platformHasGnuNonexecStack platform
then text ".section .note.GNU-stack,\"\"," <> sectionType "progbits"
else Outputable.empty)
$$
-- And just because every other compiler does, let's stick in
-- an identifier directive: .ident "GHC x.y.z"
(if platformHasIdentDirective platform
then let compilerIdent = text "GHC" <+> text cProjectVersion
in text ".ident" <+> doubleQuotes compilerIdent
else Outputable.empty)
where
platform = targetPlatform dflags
arch = platformArch platform
os = platformOS platform
-- Generate "symbol stubs" for all external symbols that might
-- come from a dynamic library.
dyld_stubs :: [CLabel] -> SDoc
{- dyld_stubs imps = vcat $ map pprDyldSymbolStub $
map head $ group $ sort imps-}
-- (Hack) sometimes two Labels pretty-print the same, but have
-- different uniques; so we compare their text versions...
dyld_stubs imps
| needImportedSymbols dflags arch os
= vcat $
(pprGotDeclaration dflags arch os :) $
map ( pprImportedSymbol dflags platform . fst . head) $
groupBy (\(_,a) (_,b) -> a == b) $
sortBy (\(_,a) (_,b) -> compare a b) $
map doPpr $
imps
| otherwise
= Outputable.empty
doPpr lbl = (lbl, renderWithStyle dflags (pprCLabel dflags lbl) astyle)
astyle = mkCodeStyle AsmStyle
-- -----------------------------------------------------------------------------
-- Generate jump tables
-- Analyzes all native code and generates data sections for all jump
-- table instructions.
generateJumpTables
:: NcgImpl statics instr jumpDest
-> [NatCmmDecl statics instr] -> [NatCmmDecl statics instr]
generateJumpTables ncgImpl xs = concatMap f xs
where f p@(CmmProc _ _ _ (ListGraph xs)) = p : concatMap g xs
f p = [p]
g (BasicBlock _ xs) = catMaybes (map (generateJumpTableForInstr ncgImpl) xs)
-- -----------------------------------------------------------------------------
-- Shortcut branches
shortcutBranches
:: forall statics instr jumpDest. (Outputable jumpDest) => DynFlags
-> NcgImpl statics instr jumpDest
-> [NatCmmDecl statics instr]
-> Maybe CFG
-> ([NatCmmDecl statics instr],Maybe CFG)
shortcutBranches dflags ncgImpl tops weights
| gopt Opt_AsmShortcutting dflags
= ( map (apply_mapping ncgImpl mapping) tops'
, shortcutWeightMap mappingBid <$!> weights )
| otherwise
= (tops, weights)
where
(tops', mappings) = mapAndUnzip (build_mapping ncgImpl) tops
mapping = mapUnions mappings :: LabelMap jumpDest
mappingBid = fmap (getJumpDestBlockId ncgImpl) mapping
build_mapping :: forall instr t d statics jumpDest.
NcgImpl statics instr jumpDest
-> GenCmmDecl d (LabelMap t) (ListGraph instr)
-> (GenCmmDecl d (LabelMap t) (ListGraph instr)
,LabelMap jumpDest)
build_mapping _ top@(CmmData _ _) = (top, mapEmpty)
build_mapping _ (CmmProc info lbl live (ListGraph []))
= (CmmProc info lbl live (ListGraph []), mapEmpty)
build_mapping ncgImpl (CmmProc info lbl live (ListGraph (head:blocks)))
= (CmmProc info lbl live (ListGraph (head:others)), mapping)
-- drop the shorted blocks, but don't ever drop the first one,
-- because it is pointed to by a global label.
where
-- find all the blocks that just consist of a jump that can be
-- shorted.
-- Don't completely eliminate loops here -- that can leave a dangling jump!
shortcut_blocks :: [(BlockId, jumpDest)]
(_, shortcut_blocks, others) =
foldl' split (setEmpty :: LabelSet, [], []) blocks
split (s, shortcut_blocks, others) b@(BasicBlock id [insn])
| Just jd <- canShortcut ncgImpl insn
, Just dest <- getJumpDestBlockId ncgImpl jd
, not (has_info id)
, (setMember dest s) || dest == id -- loop checks
= (s, shortcut_blocks, b : others)
split (s, shortcut_blocks, others) (BasicBlock id [insn])
| Just dest <- canShortcut ncgImpl insn
, not (has_info id)
= (setInsert id s, (id,dest) : shortcut_blocks, others)
split (s, shortcut_blocks, others) other = (s, shortcut_blocks, other : others)
-- do not eliminate blocks that have an info table
has_info l = mapMember l info
-- build a mapping from BlockId to JumpDest for shorting branches
mapping = mapFromList shortcut_blocks
apply_mapping :: NcgImpl statics instr jumpDest
-> LabelMap jumpDest
-> GenCmmDecl statics h (ListGraph instr)
-> GenCmmDecl statics h (ListGraph instr)
apply_mapping ncgImpl ufm (CmmData sec statics)
= CmmData sec (shortcutStatics ncgImpl (\bid -> mapLookup bid ufm) statics)
apply_mapping ncgImpl ufm (CmmProc info lbl live (ListGraph blocks))
= CmmProc info lbl live (ListGraph $ map short_bb blocks)
where
short_bb (BasicBlock id insns) = BasicBlock id $! map short_insn insns
short_insn i = shortcutJump ncgImpl (\bid -> mapLookup bid ufm) i
-- shortcutJump should apply the mapping repeatedly,
-- just in case we can short multiple branches.
-- -----------------------------------------------------------------------------
-- Instruction selection
-- Native code instruction selection for a chunk of stix code. For
-- this part of the computation, we switch from the UniqSM monad to
-- the NatM monad. The latter carries not only a Unique, but also an
-- Int denoting the current C stack pointer offset in the generated
-- code; this is needed for creating correct spill offsets on
-- architectures which don't offer, or for which it would be
-- prohibitively expensive to employ, a frame pointer register. Viz,
-- x86.
-- The offset is measured in bytes, and indicates the difference
-- between the current (simulated) C stack-ptr and the value it was at
-- the beginning of the block. For stacks which grow down, this value
-- should be either zero or negative.
-- Along with the stack pointer offset, we also carry along a LabelMap of
-- DebugBlocks, which we read to generate .location directives.
--
-- Switching between the two monads whilst carrying along the same
-- Unique supply breaks abstraction. Is that bad?
genMachCode
:: DynFlags
-> Module -> ModLocation
-> (RawCmmDecl -> NatM [NatCmmDecl statics instr])
-> DwarfFiles
-> LabelMap DebugBlock
-> RawCmmDecl
-> CFG
-> UniqSM
( [NatCmmDecl statics instr]
, [CLabel]
, DwarfFiles
, CFG
)
genMachCode dflags this_mod modLoc cmmTopCodeGen fileIds dbgMap cmm_top cmm_cfg
= do { initial_us <- getUniqueSupplyM
; let initial_st = mkNatM_State initial_us 0 dflags this_mod
modLoc fileIds dbgMap cmm_cfg
(new_tops, final_st) = initNat initial_st (cmmTopCodeGen cmm_top)
final_delta = natm_delta final_st
final_imports = natm_imports final_st
final_cfg = natm_cfg final_st
; if final_delta == 0
then return (new_tops, final_imports
, natm_fileid final_st, final_cfg)
else pprPanic "genMachCode: nonzero final delta" (int final_delta)
}
-- -----------------------------------------------------------------------------
-- Generic Cmm optimiser
{-
Here we do:
(a) Constant folding
(c) Position independent code and dynamic linking
(i) introduce the appropriate indirections
and position independent refs
(ii) compile a list of imported symbols
(d) Some arch-specific optimizations
(a) will be moving to the new Hoopl pipeline, however, (c) and
(d) are only needed by the native backend and will continue to live
here.
Ideas for other things we could do (put these in Hoopl please!):
- shortcut jumps-to-jumps
- simple CSE: if an expr is assigned to a temp, then replace later occs of
that expr with the temp, until the expr is no longer valid (can push through
temp assignments, and certain assigns to mem...)
-}
cmmToCmm :: DynFlags -> Module -> RawCmmDecl -> (RawCmmDecl, [CLabel])
cmmToCmm _ _ top@(CmmData _ _) = (top, [])
cmmToCmm dflags this_mod (CmmProc info lbl live graph)
= runCmmOpt dflags this_mod $
do blocks' <- mapM cmmBlockConFold (toBlockList graph)
return $ CmmProc info lbl live (ofBlockList (g_entry graph) blocks')
-- Avoids using unboxed tuples when loading into GHCi
#if !defined(GHC_LOADED_INTO_GHCI)
type OptMResult a = (# a, [CLabel] #)
pattern OptMResult :: a -> b -> (# a, b #)
pattern OptMResult x y = (# x, y #)
{-# COMPLETE OptMResult #-}
#else
data OptMResult a = OptMResult !a ![CLabel] deriving (Functor)
#endif
newtype CmmOptM a = CmmOptM (DynFlags -> Module -> [CLabel] -> OptMResult a)
deriving (Functor)
instance Applicative CmmOptM where
pure x = CmmOptM $ \_ _ imports -> OptMResult x imports
(<*>) = ap
instance Monad CmmOptM where
(CmmOptM f) >>= g =
CmmOptM $ \dflags this_mod imports0 ->
case f dflags this_mod imports0 of
OptMResult x imports1 ->
case g x of
CmmOptM g' -> g' dflags this_mod imports1
instance CmmMakeDynamicReferenceM CmmOptM where
addImport = addImportCmmOpt
getThisModule = CmmOptM $ \_ this_mod imports -> OptMResult this_mod imports
addImportCmmOpt :: CLabel -> CmmOptM ()
addImportCmmOpt lbl = CmmOptM $ \_ _ imports -> OptMResult () (lbl:imports)
instance HasDynFlags CmmOptM where
getDynFlags = CmmOptM $ \dflags _ imports -> OptMResult dflags imports
runCmmOpt :: DynFlags -> Module -> CmmOptM a -> (a, [CLabel])
runCmmOpt dflags this_mod (CmmOptM f) =
case f dflags this_mod [] of
OptMResult result imports -> (result, imports)
cmmBlockConFold :: CmmBlock -> CmmOptM CmmBlock
cmmBlockConFold block = do
let (entry, middle, last) = blockSplit block
stmts = blockToList middle
stmts' <- mapM cmmStmtConFold stmts
last' <- cmmStmtConFold last
return $ blockJoin entry (blockFromList stmts') last'
-- This does three optimizations, but they're very quick to check, so we don't
-- bother turning them off even when the Hoopl code is active. Since
-- this is on the old Cmm representation, we can't reuse the code either:
-- * reg = reg --> nop
-- * if 0 then jump --> nop
-- * if 1 then jump --> jump
-- We might be tempted to skip this step entirely of not Opt_PIC, but
-- there is some PowerPC code for the non-PIC case, which would also
-- have to be separated.
cmmStmtConFold :: CmmNode e x -> CmmOptM (CmmNode e x)
cmmStmtConFold stmt
= case stmt of
CmmAssign reg src
-> do src' <- cmmExprConFold DataReference src
return $ case src' of
CmmReg reg' | reg == reg' -> CmmComment (fsLit "nop")
new_src -> CmmAssign reg new_src
CmmStore addr src
-> do addr' <- cmmExprConFold DataReference addr
src' <- cmmExprConFold DataReference src
return $ CmmStore addr' src'
CmmCall { cml_target = addr }
-> do addr' <- cmmExprConFold JumpReference addr
return $ stmt { cml_target = addr' }
CmmUnsafeForeignCall target regs args
-> do target' <- case target of
ForeignTarget e conv -> do
e' <- cmmExprConFold CallReference e
return $ ForeignTarget e' conv
PrimTarget _ ->
return target
args' <- mapM (cmmExprConFold DataReference) args
return $ CmmUnsafeForeignCall target' regs args'
CmmCondBranch test true false likely
-> do test' <- cmmExprConFold DataReference test
return $ case test' of
CmmLit (CmmInt 0 _) -> CmmBranch false
CmmLit (CmmInt _ _) -> CmmBranch true
_other -> CmmCondBranch test' true false likely
CmmSwitch expr ids
-> do expr' <- cmmExprConFold DataReference expr
return $ CmmSwitch expr' ids
other
-> return other
cmmExprConFold :: ReferenceKind -> CmmExpr -> CmmOptM CmmExpr
cmmExprConFold referenceKind expr = do
dflags <- getDynFlags
-- With -O1 and greater, the cmmSink pass does constant-folding, so
-- we don't need to do it again here.
let expr' = if optLevel dflags >= 1
then expr
else cmmExprCon dflags expr
cmmExprNative referenceKind expr'
cmmExprCon :: DynFlags -> CmmExpr -> CmmExpr
cmmExprCon dflags (CmmLoad addr rep) = CmmLoad (cmmExprCon dflags addr) rep
cmmExprCon dflags (CmmMachOp mop args)
= cmmMachOpFold dflags mop (map (cmmExprCon dflags) args)
cmmExprCon _ other = other
-- handles both PIC and non-PIC cases... a very strange mixture
-- of things to do.
cmmExprNative :: ReferenceKind -> CmmExpr -> CmmOptM CmmExpr
cmmExprNative referenceKind expr = do
dflags <- getDynFlags
let platform = targetPlatform dflags
arch = platformArch platform
case expr of
CmmLoad addr rep
-> do addr' <- cmmExprNative DataReference addr
return $ CmmLoad addr' rep
CmmMachOp mop args
-> do args' <- mapM (cmmExprNative DataReference) args
return $ CmmMachOp mop args'
CmmLit (CmmBlock id)
-> cmmExprNative referenceKind (CmmLit (CmmLabel (infoTblLbl id)))
-- we must convert block Ids to CLabels here, because we
-- might have to do the PIC transformation. Hence we must
-- not modify BlockIds beyond this point.
CmmLit (CmmLabel lbl)
-> do
cmmMakeDynamicReference dflags referenceKind lbl
CmmLit (CmmLabelOff lbl off)
-> do
dynRef <- cmmMakeDynamicReference dflags referenceKind lbl
-- need to optimize here, since it's late
return $ cmmMachOpFold dflags (MO_Add (wordWidth dflags)) [
dynRef,
(CmmLit $ CmmInt (fromIntegral off) (wordWidth dflags))
]
-- On powerpc (non-PIC), it's easier to jump directly to a label than
-- to use the register table, so we replace these registers
-- with the corresponding labels:
CmmReg (CmmGlobal EagerBlackholeInfo)
| arch == ArchPPC && not (positionIndependent dflags)
-> cmmExprNative referenceKind $
CmmLit (CmmLabel (mkCmmCodeLabel rtsUnitId (fsLit "__stg_EAGER_BLACKHOLE_info")))
CmmReg (CmmGlobal GCEnter1)
| arch == ArchPPC && not (positionIndependent dflags)
-> cmmExprNative referenceKind $
CmmLit (CmmLabel (mkCmmCodeLabel rtsUnitId (fsLit "__stg_gc_enter_1")))
CmmReg (CmmGlobal GCFun)
| arch == ArchPPC && not (positionIndependent dflags)
-> cmmExprNative referenceKind $
CmmLit (CmmLabel (mkCmmCodeLabel rtsUnitId (fsLit "__stg_gc_fun")))
other
-> return other