\begin{code}
module ByteCodeGen ( UnlinkedBCO, UnlinkedBCOExpr, ItblEnv, ClosureEnv, HValue,
filterNameMap,
- byteCodeGen, coreExprToBCOs,
- linkIModules, linkIExpr
+ byteCodeGen, coreExprToBCOs
) where
#include "HsVersions.h"
import Outputable
-import Name ( Name, getName, nameModule, mkSysLocalName, toRdrName )
-import RdrName ( rdrNameOcc, rdrNameModule )
-import OccName ( occNameString )
-import Id ( Id, idType, isDataConId_maybe, mkVanillaId )
+import Name ( Name, getName )
+import Id ( Id, idType, isDataConId_maybe, isPrimOpId_maybe, isFCallId,
+ idPrimRep, mkSysLocal, idName, isFCallId_maybe )
+import ForeignCall ( ForeignCall(..), CCallTarget(..), CCallSpec(..) )
import OrdList ( OrdList, consOL, snocOL, appOL, unitOL,
nilOL, toOL, concatOL, fromOL )
-import FiniteMap ( FiniteMap, addListToFM, listToFM, filterFM,
- addToFM, lookupFM, fmToList, emptyFM, plusFM )
+import FiniteMap ( FiniteMap, addListToFM, listToFM,
+ addToFM, lookupFM, fmToList )
import CoreSyn
-import PprCore ( pprCoreExpr, pprCoreAlt )
+import PprCore ( pprCoreExpr )
import Literal ( Literal(..), literalPrimRep )
import PrimRep ( PrimRep(..) )
+import PrimOp ( PrimOp(..) )
import CoreFVs ( freeVars )
-import Type ( typePrimRep )
-import DataCon ( DataCon, dataConTag, fIRST_TAG, dataConTyCon,
- dataConRepArgTys )
-import TyCon ( TyCon, tyConFamilySize, isDataTyCon, tyConDataCons )
+import Type ( typePrimRep, splitTyConApp_maybe, isTyVarTy )
+import DataCon ( dataConTag, fIRST_TAG, dataConTyCon,
+ dataConWrapId, isUnboxedTupleCon )
+import TyCon ( TyCon(..), tyConFamilySize, isDataTyCon, tyConDataCons,
+ isFunTyCon, isUnboxedTupleTyCon )
import Class ( Class, classTyCon )
-import Util ( zipEqual, zipWith4Equal, naturalMergeSortLe, nOfThem, global )
+import Type ( Type, repType, splitRepFunTys )
+import Util ( zipEqual, zipWith4Equal, naturalMergeSortLe, nOfThem )
import Var ( isTyVar )
import VarSet ( VarSet, varSetElems )
-import PrimRep ( getPrimRepSize, isFollowableRep )
-import Constants ( wORD_SIZE )
+import PrimRep ( isFollowableRep )
import CmdLineOpts ( DynFlags, DynFlag(..) )
import ErrUtils ( showPass, dumpIfSet_dyn )
-import ClosureInfo ( mkVirtHeapOffsets )
-import Module ( ModuleName, moduleName, moduleNameFS )
import Unique ( mkPseudoUnique3 )
+import FastString ( FastString(..) )
+import Panic ( GhcException(..) )
+import PprType ( pprType )
+import SMRep ( arrWordsHdrSize, arrPtrsHdrSize )
+import Constants ( wORD_SIZE )
+import ByteCodeInstr ( BCInstr(..), ProtoBCO(..), nameOfProtoBCO, bciStackUse )
+import ByteCodeItbls ( ItblEnv, mkITbls )
+import ByteCodeLink ( UnlinkedBCO, UnlinkedBCOExpr, assembleBCO,
+ ClosureEnv, HValue, filterNameMap, linkFail,
+ iNTERP_STACK_CHECK_THRESH )
+import ByteCodeFFI ( taggedSizeW, untaggedSizeW, mkMarshalCode, moan64 )
import Linker ( lookupSymbol )
-import List ( intersperse )
-import Monad ( foldM )
-import ST ( runST )
-import MArray ( castSTUArray,
- newFloatArray, writeFloatArray,
- newDoubleArray, writeDoubleArray,
- newIntArray, writeIntArray,
- newAddrArray, writeAddrArray )
-import Foreign ( Storable(..), Word8, Word16, Word32, Ptr(..),
- malloc, castPtr, plusPtr )
-import Addr ( Word, addrToInt, nullAddr )
-import Bits ( Bits(..), shiftR )
-
-import PrelAddr ( Addr(..) )
-import PrelGHC ( BCO#, newBCO#, unsafeCoerce#,
- ByteArray#, Array#, addrToHValue# )
-import IOExts ( IORef, fixIO )
-import ArrayBase
-import PrelArr ( Array(..) )
+import List ( intersperse, sortBy, zip4 )
+import Foreign ( Ptr(..), mallocBytes )
+import Addr ( Addr(..), writeCharOffAddr )
+import CTypes ( CInt )
+import Exception ( throwDyn )
+
+import PrelBase ( Int(..) )
+import PrelGHC ( ByteArray# )
import PrelIOBase ( IO(..) )
+import Monad ( when )
\end{code}
let flatBinds = concatMap getBind binds
getBind (NonRec bndr rhs) = [(bndr, freeVars rhs)]
getBind (Rec binds) = [(bndr, freeVars rhs) | (bndr,rhs) <- binds]
- final_state = runBc (BcM_State [] 0)
- (mapBc schemeR flatBinds `thenBc_` returnBc ())
- (BcM_State proto_bcos final_ctr) = final_state
+
+ (BcM_State proto_bcos final_ctr mallocd, ())
+ <- runBc (BcM_State [] 0 [])
+ (mapBc (schemeR True) flatBinds `thenBc_` returnBc ())
+
+ when (not (null mallocd))
+ (panic "ByteCodeGen.byteCodeGen: missing final emitBc?")
dumpIfSet_dyn dflags Opt_D_dump_BCOs
"Proto-bcos" (vcat (intersperse (char ' ') (map ppr proto_bcos)))
-- create a totally bogus name for the top-level BCO; this
-- should be harmless, since it's never used for anything
- let invented_name = mkSysLocalName (mkPseudoUnique3 0) SLIT("Expr-Top-Level")
- let invented_id = mkVanillaId invented_name (panic "invented_id's type")
+ let invented_id = mkSysLocal SLIT("Expr-Top-Level") (mkPseudoUnique3 0)
+ (panic "invented_id's type")
+ let invented_name = idName invented_id
+
+ (BcM_State all_proto_bcos final_ctr mallocd, ())
+ <- runBc (BcM_State [] 0 [])
+ (schemeR True (invented_id, freeVars expr))
+
+ when (not (null mallocd))
+ (panic "ByteCodeGen.coreExprToBCOs: missing final emitBc?")
- let (BcM_State all_proto_bcos final_ctr)
- = runBc (BcM_State [] 0)
- (schemeR (invented_id, freeVars expr))
dumpIfSet_dyn dflags Opt_D_dump_BCOs
"Proto-bcos" (vcat (intersperse (char ' ') (map ppr all_proto_bcos)))
root_bco <- assembleBCO root_proto_bco
return (root_bco, auxiliary_bcos)
-
-
--- Linking stuff
-linkIModules :: ItblEnv -- incoming global itbl env; returned updated
- -> ClosureEnv -- incoming global closure env; returned updated
- -> [([UnlinkedBCO], ItblEnv)]
- -> IO ([HValue], ItblEnv, ClosureEnv)
-linkIModules gie gce mods
- = do let (bcoss, ies) = unzip mods
- bcos = concat bcoss
- final_gie = foldr plusFM gie ies
- (final_gce, linked_bcos) <- linkSomeBCOs final_gie gce bcos
- return (linked_bcos, final_gie, final_gce)
-
-
-linkIExpr :: ItblEnv -> ClosureEnv -> UnlinkedBCOExpr
- -> IO HValue -- IO BCO# really
-linkIExpr ie ce (root_ul_bco, aux_ul_bcos)
- = do (aux_ce, _) <- linkSomeBCOs ie ce aux_ul_bcos
- (_, [root_bco]) <- linkSomeBCOs ie aux_ce [root_ul_bco]
- return root_bco
-
--- Link a bunch of BCOs and return them + updated closure env.
-linkSomeBCOs :: ItblEnv -> ClosureEnv -> [UnlinkedBCO]
- -> IO (ClosureEnv, [HValue])
-linkSomeBCOs ie ce_in ul_bcos
- = do let nms = map nameOfUnlinkedBCO ul_bcos
- hvals <- fixIO
- ( \ hvs -> let ce_out = addListToFM ce_in (zipLazily nms hvs)
- in mapM (linkBCO ie ce_out) ul_bcos )
- let ce_out = addListToFM ce_in (zip nms hvals)
- return (ce_out, hvals)
- where
- -- A lazier zip, in which no demand is propagated to the second
- -- list unless some demand is propagated to the snd of one of the
- -- result list elems.
- zipLazily [] ys = []
- zipLazily (x:xs) ys = (x, head ys) : zipLazily xs (tail ys)
-
-
-data UnlinkedBCO
- = UnlinkedBCO Name
- (SizedSeq Word16) -- insns
- (SizedSeq Word) -- literals
- (SizedSeq Name) -- ptrs
- (SizedSeq Name) -- itbl refs
-
-nameOfUnlinkedBCO (UnlinkedBCO nm _ _ _ _) = nm
-
--- When translating expressions, we need to distinguish the root
--- BCO for the expression
-type UnlinkedBCOExpr = (UnlinkedBCO, [UnlinkedBCO])
-
-instance Outputable UnlinkedBCO where
- ppr (UnlinkedBCO nm insns lits ptrs itbls)
- = sep [text "BCO", ppr nm, text "with",
- int (sizeSS insns), text "insns",
- int (sizeSS lits), text "lits",
- int (sizeSS ptrs), text "ptrs",
- int (sizeSS itbls), text "itbls"]
-
-
--- these need a proper home
-type ItblEnv = FiniteMap Name (Ptr StgInfoTable)
-type ClosureEnv = FiniteMap Name HValue
-data HValue = HValue -- dummy type, actually a pointer to some Real Code.
-
--- remove all entries for a given set of modules from the environment
-filterNameMap :: [ModuleName] -> FiniteMap Name a -> FiniteMap Name a
-filterNameMap mods env
- = filterFM (\n _ -> moduleName (nameModule n) `notElem` mods) env
-\end{code}
-
-%************************************************************************
-%* *
-\subsection{Bytecodes, and Outputery.}
-%* *
-%************************************************************************
-
-\begin{code}
-
-type LocalLabel = Int
-
-data BCInstr
- -- Messing with the stack
- = ARGCHECK Int
- -- Push locals (existing bits of the stack)
- | PUSH_L Int{-offset-}
- | PUSH_LL Int Int{-2 offsets-}
- | PUSH_LLL Int Int Int{-3 offsets-}
- -- Push a ptr
- | PUSH_G Name
- -- Push an alt continuation
- | PUSH_AS Name PrimRep -- push alts and BCO_ptr_ret_info
- -- PrimRep so we know which itbl
- -- Pushing literals
- | PUSH_UBX Literal Int
- -- push this int/float/double, NO TAG, on the stack
- -- Int is # of words to copy from literal pool
- | PUSH_TAG Int -- push this tag on the stack
-
- | SLIDE Int{-this many-} Int{-down by this much-}
- -- To do with the heap
- | ALLOC Int -- make an AP_UPD with this many payload words, zeroed
- | MKAP Int{-ptr to AP_UPD is this far down stack-} Int{-# words-}
- | UNPACK Int -- unpack N ptr words from t.o.s Constr
- | UPK_TAG Int Int Int
- -- unpack N non-ptr words from offset M in constructor
- -- K words down the stack
- | PACK DataCon Int
- -- after assembly, the DataCon is an index into the
- -- itbl array
- -- For doing case trees
- | LABEL LocalLabel
- | TESTLT_I Int LocalLabel
- | TESTEQ_I Int LocalLabel
- | TESTLT_F Float LocalLabel
- | TESTEQ_F Float LocalLabel
- | TESTLT_D Double LocalLabel
- | TESTEQ_D Double LocalLabel
-
- -- The Int value is a constructor number and therefore
- -- stored in the insn stream rather than as an offset into
- -- the literal pool.
- | TESTLT_P Int LocalLabel
- | TESTEQ_P Int LocalLabel
-
- | CASEFAIL
- -- To Infinity And Beyond
- | ENTER
- | RETURN PrimRep
- -- unboxed value on TOS. Use tag to find underlying ret itbl
- -- and return as per that.
-
-
-instance Outputable BCInstr where
- ppr (ARGCHECK n) = text "ARGCHECK" <+> int n
- ppr (PUSH_L offset) = text "PUSH_L " <+> int offset
- ppr (PUSH_LL o1 o2) = text "PUSH_LL " <+> int o1 <+> int o2
- ppr (PUSH_LLL o1 o2 o3) = text "PUSH_LLL" <+> int o1 <+> int o2 <+> int o3
- ppr (PUSH_G nm) = text "PUSH_G " <+> ppr nm
- ppr (PUSH_AS nm pk) = text "PUSH_AS " <+> ppr nm <+> ppr pk
- ppr (PUSH_UBX lit nw) = text "PUSH_UBX" <+> parens (int nw) <+> ppr lit
- ppr (PUSH_TAG n) = text "PUSH_TAG" <+> int n
- ppr (SLIDE n d) = text "SLIDE " <+> int n <+> int d
- ppr (ALLOC sz) = text "ALLOC " <+> int sz
- ppr (MKAP offset sz) = text "MKAP " <+> int sz <+> text "words,"
- <+> int offset <+> text "stkoff"
- ppr (UNPACK sz) = text "UNPACK " <+> int sz
- ppr (UPK_TAG n m k) = text "UPK_TAG " <+> int n <> text "words"
- <+> int m <> text "conoff"
- <+> int k <> text "stkoff"
- ppr (PACK dcon sz) = text "PACK " <+> ppr dcon <+> ppr sz
- ppr (LABEL lab) = text "__" <> int lab <> colon
- ppr (TESTLT_I i lab) = text "TESTLT_I" <+> int i <+> text "__" <> int lab
- ppr (TESTEQ_I i lab) = text "TESTEQ_I" <+> int i <+> text "__" <> int lab
- ppr (TESTLT_F f lab) = text "TESTLT_F" <+> float f <+> text "__" <> int lab
- ppr (TESTEQ_F f lab) = text "TESTEQ_F" <+> float f <+> text "__" <> int lab
- ppr (TESTLT_D d lab) = text "TESTLT_D" <+> double d <+> text "__" <> int lab
- ppr (TESTEQ_D d lab) = text "TESTEQ_D" <+> double d <+> text "__" <> int lab
- ppr (TESTLT_P i lab) = text "TESTLT_P" <+> int i <+> text "__" <> int lab
- ppr (TESTEQ_P i lab) = text "TESTEQ_P" <+> int i <+> text "__" <> int lab
- ppr CASEFAIL = text "CASEFAIL"
- ppr ENTER = text "ENTER"
- ppr (RETURN pk) = text "RETURN " <+> ppr pk
-
-instance Outputable a => Outputable (ProtoBCO a) where
- ppr (ProtoBCO name instrs origin)
- = (text "ProtoBCO" <+> ppr name <> colon)
- $$ nest 6 (vcat (map ppr instrs))
- $$ case origin of
- Left alts -> vcat (map (pprCoreAlt.deAnnAlt) alts)
- Right rhs -> pprCoreExpr (deAnnotate rhs)
\end{code}
%************************************************************************
type BCInstrList = OrdList BCInstr
-data ProtoBCO a
- = ProtoBCO a -- name, in some sense
- [BCInstr] -- instrs
- -- what the BCO came from
- (Either [AnnAlt Id VarSet]
- (AnnExpr Id VarSet))
-
-nameOfProtoBCO (ProtoBCO nm insns origin) = nm
-
-
type Sequel = Int -- back off to this depth before ENTER
-- Maps Ids to the offset from the stack _base_ so we don't have
-- to mess with it after each push/pop.
type BCEnv = FiniteMap Id Int -- To find vars on the stack
+ppBCEnv :: BCEnv -> SDoc
+ppBCEnv p
+ = text "begin-env"
+ $$ nest 4 (vcat (map pp_one (sortBy cmp_snd (fmToList p))))
+ $$ text "end-env"
+ where
+ pp_one (var, offset) = int offset <> colon <+> ppr var
+ cmp_snd x y = compare (snd x) (snd y)
-- Create a BCO and do a spot of peephole optimisation on the insns
-- at the same time.
-mkProtoBCO nm instrs_ordlist origin
- = ProtoBCO nm (id {-peep-} (fromOL instrs_ordlist)) origin
+mkProtoBCO nm instrs_ordlist origin mallocd_blocks
+ = ProtoBCO nm maybe_with_stack_check origin mallocd_blocks
where
+ -- Overestimate the stack usage (in words) of this BCO,
+ -- and if >= iNTERP_STACK_CHECK_THRESH, add an explicit
+ -- stack check. (The interpreter always does a stack check
+ -- for iNTERP_STACK_CHECK_THRESH words at the start of each
+ -- BCO anyway, so we only need to add an explicit on in the
+ -- (hopefully rare) cases when the (overestimated) stack use
+ -- exceeds iNTERP_STACK_CHECK_THRESH.
+ maybe_with_stack_check
+ | stack_overest >= 65535
+ = pprPanic "mkProtoBCO: stack use won't fit in 16 bits"
+ (int stack_overest)
+ | stack_overest >= iNTERP_STACK_CHECK_THRESH
+ = (STKCHECK stack_overest) : peep_d
+ | otherwise
+ = peep_d -- the supposedly common case
+
+ stack_overest = sum (map bciStackUse peep_d)
+ + 10 {- just to be really really sure -}
+
+
+ -- Merge local pushes
+ peep_d = peep (fromOL instrs_ordlist)
+
peep (PUSH_L off1 : PUSH_L off2 : PUSH_L off3 : rest)
= PUSH_LLL off1 (off2-1) (off3-2) : peep rest
peep (PUSH_L off1 : PUSH_L off2 : rest)
- = PUSH_LL off1 off2 : peep rest
+ = PUSH_LL off1 (off2-1) : peep rest
peep (i:rest)
= i : peep rest
peep []
-- Compile code for the right hand side of a let binding.
-- Park the resulting BCO in the monad. Also requires the
-- variable to which this value was bound, so as to give the
--- resulting BCO a name.
-schemeR :: (Id, AnnExpr Id VarSet) -> BcM ()
-schemeR (nm, rhs)
+-- resulting BCO a name. Bool indicates top-levelness.
+
+schemeR :: Bool -> (Id, AnnExpr Id VarSet) -> BcM ()
+schemeR is_top (nm, rhs)
{-
| trace (showSDoc (
(char ' '
= undefined
-}
| otherwise
- = schemeR_wrk rhs nm (collect [] rhs)
+ = schemeR_wrk is_top rhs nm (collect [] rhs)
+collect xs (_, AnnNote note e)
+ = collect xs e
collect xs (_, AnnLam x e)
= collect (if isTyVar x then xs else (x:xs)) e
collect xs not_lambda
= (reverse xs, not_lambda)
-schemeR_wrk original_body nm (args, body)
+schemeR_wrk is_top original_body nm (args, body)
+ | Just dcon <- maybe_toplevel_null_con_rhs
+ = --trace ("nullary constructor! " ++ showSDocDebug (ppr nm)) (
+ emitBc (mkProtoBCO (getName nm) (toOL [PACK dcon 0, ENTER])
+ (Right original_body))
+ --)
+
+ | otherwise
= let fvs = filter (not.isTyVar) (varSetElems (fst original_body))
- all_args = fvs ++ reverse args
+ all_args = reverse args ++ fvs
szsw_args = map taggedIdSizeW all_args
szw_args = sum szsw_args
p_init = listToFM (zip all_args (mkStackOffsets 0 szsw_args))
- argcheck = {-if null args then nilOL else-} unitOL (ARGCHECK szw_args)
+ argcheck = unitOL (ARGCHECK szw_args)
in
schemeE szw_args 0 p_init body `thenBc` \ body_code ->
- emitBc (mkProtoBCO (getName nm) (appOL argcheck body_code) (Right original_body))
+ emitBc (mkProtoBCO (getName nm) (appOL argcheck body_code)
+ (Right original_body))
+
+ where
+ maybe_toplevel_null_con_rhs
+ | is_top && null args
+ = case nukeTyArgs (snd body) of
+ AnnVar v_wrk
+ -> case isDataConId_maybe v_wrk of
+ Nothing -> Nothing
+ Just dc_wrk | nm == dataConWrapId dc_wrk
+ -> Just dc_wrk
+ | otherwise
+ -> Nothing
+ other -> Nothing
+ | otherwise
+ = Nothing
+
+ nukeTyArgs (AnnApp f (_, AnnType _)) = nukeTyArgs (snd f)
+ nukeTyArgs other = other
+
-- Let szsw be the sizes in words of some items pushed onto the stack,
-- which has initial depth d'. Return the values which the stack environment
-- Delegate tail-calls to schemeT.
schemeE d s p e@(fvs, AnnApp f a)
- = returnBc (schemeT (should_args_be_tagged e) d s 0 p (fvs, AnnApp f a))
+ = schemeT d s p (fvs, AnnApp f a)
+
schemeE d s p e@(fvs, AnnVar v)
| isFollowableRep v_rep
- = returnBc (schemeT (should_args_be_tagged e) d s 0 p (fvs, AnnVar v))
+ = -- Ptr-ish thing; push it in the normal way
+ schemeT d s p (fvs, AnnVar v)
+
| otherwise
= -- returning an unboxed value. Heave it on the stack, SLIDE, and RETURN.
- let (push, szw) = pushAtom True d p (AnnVar v)
- in returnBc (push -- value onto stack
- `snocOL` SLIDE szw (d-s) -- clear to sequel
- `snocOL` RETURN v_rep) -- go
+ pushAtom True d p (AnnVar v) `thenBc` \ (push, szw) ->
+ returnBc (push -- value onto stack
+ `appOL` mkSLIDE szw (d-s) -- clear to sequel
+ `snocOL` RETURN v_rep) -- go
where
v_rep = typePrimRep (idType v)
schemeE d s p (fvs, AnnLit literal)
- = let (push, szw) = pushAtom True d p (AnnLit literal)
- l_rep = literalPrimRep literal
+ = pushAtom True d p (AnnLit literal) `thenBc` \ (push, szw) ->
+ let l_rep = literalPrimRep literal
in returnBc (push -- value onto stack
- `snocOL` SLIDE szw (d-s) -- clear to sequel
- `snocOL` RETURN l_rep) -- go
+ `appOL` mkSLIDE szw (d-s) -- clear to sequel
+ `snocOL` RETURN l_rep) -- go
schemeE d s p (fvs, AnnLet binds b)
= let (xs,rhss) = case binds of AnnNonRec x rhs -> ([x],[rhs])
-- ToDo: don't build thunks for things with no free variables
buildThunk dd ([], size, id, off)
- = PUSH_G (getName id)
- `consOL` unitOL (MKAP (off+size-1) size)
+ = returnBc (PUSH_G (Left (getName id))
+ `consOL` unitOL (MKAP (off+size-1) size))
buildThunk dd ((fv:fvs), size, id, off)
- = case pushAtom True dd p' (AnnVar fv) of
- (push_code, pushed_szw)
- -> push_code `appOL`
- buildThunk (dd+pushed_szw) (fvs, size, id, off)
+ = pushAtom True dd p' (AnnVar fv)
+ `thenBc` \ (push_code, pushed_szw) ->
+ buildThunk (dd+pushed_szw) (fvs, size, id, off)
+ `thenBc` \ more_push_code ->
+ returnBc (push_code `appOL` more_push_code)
+
+ genThunkCode = mapBc (buildThunk d') infos `thenBc` \ tcodes ->
+ returnBc (concatOL tcodes)
- thunkCode = concatOL (map (buildThunk d') infos)
allocCode = toOL (map ALLOC sizes)
in
schemeE d' s p' b `thenBc` \ bodyCode ->
- mapBc schemeR (zip xs rhss) `thenBc_`
+ mapBc (schemeR False) (zip xs rhss) `thenBc_`
+ genThunkCode `thenBc` \ thunkCode ->
returnBc (allocCode `appOL` thunkCode `appOL` bodyCode)
+
+
+
+schemeE d s p (fvs_case, AnnCase (fvs_scrut, scrut) bndr
+ [(DEFAULT, [], (fvs_rhs, rhs))])
+
+ | let isFunType var_type
+ = case splitTyConApp_maybe var_type of
+ Just (tycon,_) | isFunTyCon tycon -> True
+ _ -> False
+ ty_bndr = repType (idType bndr)
+ in isFunType ty_bndr || isTyVarTy ty_bndr
+
+ -- Nasty hack; treat
+ -- case scrut::suspect of bndr { DEFAULT -> rhs }
+ -- as
+ -- let bndr = scrut in rhs
+ -- when suspect is polymorphic or arrowtyped
+ -- So the required strictness properties are not observed.
+ -- At some point, must fix this properly.
+ = let new_expr
+ = (fvs_case,
+ AnnLet
+ (AnnNonRec bndr (fvs_scrut, scrut)) (fvs_rhs, rhs)
+ )
+
+ in trace ("WARNING: ignoring polymorphic case in interpreted mode.\n" ++
+ " Possibly due to strict polymorphic/functional constructor args.\n" ++
+ " Your program may leak space unexpectedly.\n")
+ (schemeE d s p new_expr)
+
+
+
+{- Convert case .... of (# VoidRep'd-thing, a #) -> ...
+ as
+ case .... of a -> ...
+ Use a as the name of the binder too.
+
+ Also case .... of (# a #) -> ...
+ to
+ case .... of a -> ...
+-}
+schemeE d s p (fvs, AnnCase scrut bndr [(DataAlt dc, [bind1, bind2], rhs)])
+ | isUnboxedTupleCon dc && VoidRep == typePrimRep (idType bind1)
+ = --trace "automagic mashing of case alts (# VoidRep, a #)" (
+ schemeE d s p (fvs, AnnCase scrut bind2 [(DEFAULT, [bind2], rhs)])
+ --)
+
+schemeE d s p (fvs, AnnCase scrut bndr [(DataAlt dc, [bind1], rhs)])
+ | isUnboxedTupleCon dc
+ = --trace "automagic mashing of case alts (# a #)" (
+ schemeE d s p (fvs, AnnCase scrut bind1 [(DEFAULT, [bind1], rhs)])
+ --)
+
schemeE d s p (fvs, AnnCase scrut bndr alts)
= let
-- Top of stack is the return itbl, as usual.
scrut_primrep = typePrimRep (idType bndr)
isAlgCase
- = case scrut_primrep of
- IntRep -> False ; FloatRep -> False ; DoubleRep -> False
- PtrRep -> True
- other -> pprPanic "ByteCodeGen.schemeE" (ppr other)
+ | scrut_primrep == PtrRep
+ = True
+ | scrut_primrep `elem`
+ [CharRep, AddrRep, WordRep, IntRep, FloatRep, DoubleRep,
+ VoidRep, Int8Rep, Int16Rep, Int32Rep, Int64Rep,
+ Word8Rep, Word16Rep, Word32Rep, Word64Rep]
+ = False
+ | otherwise
+ = pprPanic "ByteCodeGen.schemeE" (ppr scrut_primrep)
-- given an alt, return a discr and code for it.
codeAlt alt@(discr, binds_f, rhs)
| isAlgCase
- = let binds_r = reverse binds_f
- binds_r_szsw = map untaggedIdSizeW binds_r
- binds_szw = sum binds_r_szsw
- p'' = addListToFM
- p' (zip binds_r (mkStackOffsets d' binds_r_szsw))
- d'' = d' + binds_szw
- unpack_code = mkUnpackCode 0 0 (map (typePrimRep.idType) binds_f)
- in schemeE d'' s p'' rhs `thenBc` \ rhs_code ->
- returnBc (my_discr alt, unpack_code `appOL` rhs_code)
+ = let (unpack_code, d_after_unpack, p_after_unpack)
+ = mkUnpackCode (filter (not.isTyVar) binds_f) d' p'
+ in schemeE d_after_unpack s p_after_unpack rhs
+ `thenBc` \ rhs_code ->
+ returnBc (my_discr alt, unpack_code `appOL` rhs_code)
| otherwise
= ASSERT(null binds_f)
schemeE d' s p' rhs `thenBc` \ rhs_code ->
returnBc (my_discr alt, rhs_code)
- my_discr (DEFAULT, binds, rhs) = NoDiscr
- my_discr (DataAlt dc, binds, rhs) = DiscrP (dataConTag dc)
+ my_discr (DEFAULT, binds, rhs) = NoDiscr
+ my_discr (DataAlt dc, binds, rhs)
+ | isUnboxedTupleCon dc
+ = unboxedTupleException
+ | otherwise
+ = DiscrP (dataConTag dc - fIRST_TAG)
my_discr (LitAlt l, binds, rhs)
= case l of MachInt i -> DiscrI (fromInteger i)
MachFloat r -> DiscrF (fromRational r)
MachDouble r -> DiscrD (fromRational r)
+ MachChar i -> DiscrI i
+ _ -> pprPanic "schemeE(AnnCase).my_discr" (ppr l)
maybe_ncons
| not isAlgCase = Nothing
mapBc codeAlt alts `thenBc` \ alt_stuff ->
mkMultiBranch maybe_ncons alt_stuff `thenBc` \ alt_final ->
let
+ alt_final_ac = ARGCHECK (taggedIdSizeW bndr) `consOL` alt_final
alt_bco_name = getName bndr
- alt_bco = mkProtoBCO alt_bco_name alt_final (Left alts)
+ alt_bco = mkProtoBCO alt_bco_name alt_final_ac (Left alts)
in
schemeE (d + ret_frame_sizeW)
(d + ret_frame_sizeW) p scrut `thenBc` \ scrut_code ->
(pprCoreExpr (deAnnotate other))
--- Compile code to do a tail call. Doesn't need to be monadic.
-schemeT :: Bool -- do tagging?
- -> Int -- Stack depth
+-- Compile code to do a tail call. Specifically, push the fn,
+-- slide the on-stack app back down to the sequel depth,
+-- and enter. Four cases:
+--
+-- 0. (Nasty hack).
+-- An application "PrelGHC.tagToEnum# <type> unboxed-int".
+-- The int will be on the stack. Generate a code sequence
+-- to convert it to the relevant constructor, SLIDE and ENTER.
+--
+-- 1. A nullary constructor. Push its closure on the stack
+-- and SLIDE and RETURN.
+--
+-- 2. (Another nasty hack). Spot (# a::VoidRep, b #) and treat
+-- it simply as b -- since the representations are identical
+-- (the VoidRep takes up zero stack space). Also, spot
+-- (# b #) and treat it as b.
+--
+-- 3. The fn denotes a ccall. Defer to generateCCall.
+--
+-- 4. Application of a non-nullary constructor, by defn saturated.
+-- Split the args into ptrs and non-ptrs, and push the nonptrs,
+-- then the ptrs, and then do PACK and RETURN.
+--
+-- 5. Otherwise, it must be a function call. Push the args
+-- right to left, SLIDE and ENTER.
+
+schemeT :: Int -- Stack depth
-> Sequel -- Sequel depth
- -> Int -- # arg words so far
-> BCEnv -- stack env
-> AnnExpr Id VarSet
- -> BCInstrList
-
-schemeT enTag d s narg_words p (_, AnnApp f a)
- = case snd a of
- AnnType _ -> schemeT enTag d s narg_words p f
- other
- -> let (push, arg_words) = pushAtom enTag d p (snd a)
- in push
- `appOL` schemeT enTag (d+arg_words) s (narg_words+arg_words) p f
-
-schemeT enTag d s narg_words p (_, AnnVar f)
- | Just con <- isDataConId_maybe f
- = ASSERT(enTag == False)
- PACK con narg_words `consOL` (mkSLIDE 1 (d-s-1) `snocOL` ENTER)
- | otherwise
- = ASSERT(enTag == True)
- let (push, arg_words) = pushAtom True d p (AnnVar f)
- in push
- `appOL` mkSLIDE (narg_words+arg_words) (d - s - narg_words)
- `snocOL` ENTER
-
-mkSLIDE n d
- = if d == 0 then nilOL else unitOL (SLIDE n d)
-
-should_args_be_tagged (_, AnnVar v)
- = case isDataConId_maybe v of
- Just dcon -> False; Nothing -> True
-should_args_be_tagged (_, AnnApp f a)
- = should_args_be_tagged f
-should_args_be_tagged (_, other)
- = panic "should_args_be_tagged: tail call to non-con, non-var"
-
-
--- Make code to unpack a constructor onto the stack, adding
--- tags for the unboxed bits. Takes the PrimReps of the constructor's
--- arguments, and a travelling offset along both the constructor
--- (off_h) and the stack (off_s).
-mkUnpackCode :: Int -> Int -> [PrimRep] -> BCInstrList
-mkUnpackCode off_h off_s [] = nilOL
-mkUnpackCode off_h off_s (r:rs)
- | isFollowableRep r
- = let (rs_ptr, rs_nptr) = span isFollowableRep (r:rs)
- ptrs_szw = sum (map untaggedSizeW rs_ptr)
- in ASSERT(ptrs_szw == length rs_ptr)
- ASSERT(off_h == 0)
- ASSERT(off_s == 0)
- UNPACK ptrs_szw
- `consOL` mkUnpackCode (off_h + ptrs_szw) (off_s + ptrs_szw) rs_nptr
+ -> BcM BCInstrList
+
+schemeT d s p app
+
+-- | trace ("schemeT: env in = \n" ++ showSDocDebug (ppBCEnv p)) False
+-- = panic "schemeT ?!?!"
+
+-- | trace ("\nschemeT\n" ++ showSDoc (pprCoreExpr (deAnnotate app)) ++ "\n") False
+-- = error "?!?!"
+
+ -- Case 0
+ | Just (arg, constr_names) <- maybe_is_tagToEnum_call
+ = pushAtom True d p arg `thenBc` \ (push, arg_words) ->
+ implement_tagToId constr_names `thenBc` \ tagToId_sequence ->
+ returnBc (push `appOL` tagToId_sequence
+ `appOL` mkSLIDE 1 (d+arg_words-s)
+ `snocOL` ENTER)
+
+ -- Case 1
+ | is_con_call && null args_r_to_l
+ = returnBc (
+ (PUSH_G (Left (getName con)) `consOL` mkSLIDE 1 (d-s))
+ `snocOL` ENTER
+ )
+
+ -- Case 2
+ | let isVoidRepAtom (_, AnnVar v) = VoidRep == typePrimRep (idType v)
+ isVoidRepAtom (_, AnnNote n e) = isVoidRepAtom e
+ in is_con_call && isUnboxedTupleCon con
+ && ( (length args_r_to_l == 2 && isVoidRepAtom (last (args_r_to_l)))
+ || (length args_r_to_l == 1)
+ )
+ = --trace (if length args_r_to_l == 1
+ -- then "schemeT: unboxed singleton"
+ -- else "schemeT: unboxed pair with Void first component") (
+ schemeT d s p (head args_r_to_l)
+ --)
+
+ -- Case 3
+ | Just (CCall ccall_spec) <- isFCallId_maybe fn
+ = generateCCall d s p ccall_spec fn args_r_to_l
+
+ -- Cases 4 and 5
| otherwise
- = case r of
- IntRep -> approved
- FloatRep -> approved
- DoubleRep -> approved
+ = if is_con_call && isUnboxedTupleCon con
+ then unboxedTupleException
+ else do_pushery d (map snd args_final_r_to_l)
+
+ where
+ -- Detect and extract relevant info for the tagToEnum kludge.
+ maybe_is_tagToEnum_call
+ = let extract_constr_Names ty
+ = case splitTyConApp_maybe (repType ty) of
+ (Just (tyc, [])) | isDataTyCon tyc
+ -> map getName (tyConDataCons tyc)
+ other -> panic "maybe_is_tagToEnum_call.extract_constr_Ids"
+ in
+ case app of
+ (_, AnnApp (_, AnnApp (_, AnnVar v) (_, AnnType t)) arg)
+ -> case isPrimOpId_maybe v of
+ Just TagToEnumOp -> Just (snd arg, extract_constr_Names t)
+ other -> Nothing
+ other -> Nothing
+
+ -- Extract the args (R->L) and fn
+ (args_r_to_l_raw, fn) = chomp app
+ chomp expr
+ = case snd expr of
+ AnnVar v -> ([], v)
+ AnnApp f a -> case chomp f of (az, f) -> (a:az, f)
+ AnnNote n e -> chomp e
+ other -> pprPanic "schemeT"
+ (ppr (deAnnotate (panic "schemeT.chomp", other)))
+
+ args_r_to_l = filter (not.isTypeAtom.snd) args_r_to_l_raw
+ isTypeAtom (AnnType _) = True
+ isTypeAtom _ = False
+
+ -- decide if this is a constructor call, and rearrange
+ -- args appropriately.
+ maybe_dcon = isDataConId_maybe fn
+ is_con_call = case maybe_dcon of Nothing -> False; Just _ -> True
+ (Just con) = maybe_dcon
+
+ args_final_r_to_l
+ | not is_con_call
+ = args_r_to_l
+ | otherwise
+ = filter (not.isPtr.snd) args_r_to_l ++ filter (isPtr.snd) args_r_to_l
+ where isPtr = isFollowableRep . atomRep
+
+ -- make code to push the args and then do the SLIDE-ENTER thing
+ tag_when_push = not is_con_call
+ narg_words = sum (map (get_arg_szw . atomRep . snd) args_r_to_l)
+ get_arg_szw = if tag_when_push then taggedSizeW else untaggedSizeW
+
+ do_pushery d (arg:args)
+ = pushAtom tag_when_push d p arg `thenBc` \ (push, arg_words) ->
+ do_pushery (d+arg_words) args `thenBc` \ more_push_code ->
+ returnBc (push `appOL` more_push_code)
+ do_pushery d []
+ | Just (CCall ccall_spec) <- isFCallId_maybe fn
+ = panic "schemeT.do_pushery: unexpected ccall"
+ | otherwise
+ = case maybe_dcon of
+ Just con -> returnBc (
+ (PACK con narg_words `consOL`
+ mkSLIDE 1 (d - narg_words - s)) `snocOL`
+ ENTER
+ )
+ Nothing
+ -> pushAtom True d p (AnnVar fn)
+ `thenBc` \ (push, arg_words) ->
+ returnBc (push `appOL` mkSLIDE (narg_words+arg_words)
+ (d - s - narg_words)
+ `snocOL` ENTER)
+
+
+
+{- Deal with a CCall. Taggedly push the args onto the stack R->L,
+ deferencing ForeignObj#s and (ToDo: adjusting addrs to point to
+ payloads in Ptr/Byte arrays). Then, generate the marshalling
+ (machine) code for the ccall, and create bytecodes to call that and
+ then return in the right way.
+-}
+generateCCall :: Int -> Sequel -- stack and sequel depths
+ -> BCEnv
+ -> CCallSpec -- where to call
+ -> Id -- of target, for type info
+ -> [AnnExpr Id VarSet] -- args (atoms)
+ -> BcM BCInstrList
+
+generateCCall d0 s p ccall_spec@(CCallSpec target cconv safety) fn args_r_to_l
+ = let
+ -- useful constants
+ addr_usizeW = untaggedSizeW AddrRep
+ addr_tsizeW = taggedSizeW AddrRep
+
+ -- Get the args on the stack, with tags and suitably
+ -- dereferenced for the CCall. For each arg, return the
+ -- depth to the first word of the bits for that arg, and the
+ -- PrimRep of what was actually pushed.
+
+ pargs d [] = returnBc []
+ pargs d ((_,a):az)
+ = let rep_arg = atomRep a
+ in case rep_arg of
+ -- Don't push the FO; instead push the Addr# it
+ -- contains.
+ ForeignObjRep
+ -> pushAtom False{-irrelevant-} d p a
+ `thenBc` \ (push_fo, _) ->
+ let foro_szW = taggedSizeW ForeignObjRep
+ d_now = d + addr_tsizeW
+ code = push_fo `appOL` toOL [
+ UPK_TAG addr_usizeW 0 0,
+ SLIDE addr_tsizeW foro_szW
+ ]
+ in pargs d_now az `thenBc` \ rest ->
+ returnBc ((code, AddrRep) : rest)
+
+ ArrayRep
+ -> pargs (d + addr_tsizeW) az `thenBc` \ rest ->
+ parg_ArrayishRep arrPtrsHdrSize d p a
+ `thenBc` \ code ->
+ returnBc ((code,AddrRep):rest)
+
+ ByteArrayRep
+ -> pargs (d + addr_tsizeW) az `thenBc` \ rest ->
+ parg_ArrayishRep arrWordsHdrSize d p a
+ `thenBc` \ code ->
+ returnBc ((code,AddrRep):rest)
+
+ -- Default case: push taggedly, but otherwise intact.
+ other
+ -> pushAtom True d p a `thenBc` \ (code_a, sz_a) ->
+ pargs (d+sz_a) az `thenBc` \ rest ->
+ returnBc ((code_a, rep_arg) : rest)
+
+ -- Do magic for Ptr/Byte arrays. Push a ptr to the array on
+ -- the stack but then advance it over the headers, so as to
+ -- point to the payload.
+ parg_ArrayishRep hdrSizeW d p a
+ = pushAtom False{-irrel-} d p a `thenBc` \ (push_fo, _) ->
+ -- The ptr points at the header. Advance it over the
+ -- header and then pretend this is an Addr# (push a tag).
+ returnBc (push_fo `snocOL`
+ SWIZZLE 0 (hdrSizeW * untaggedSizeW PtrRep
+ * wORD_SIZE)
+ `snocOL`
+ PUSH_TAG addr_usizeW)
+
+ in
+ pargs d0 args_r_to_l `thenBc` \ code_n_reps ->
+ let
+ (pushs_arg, a_reps_pushed_r_to_l) = unzip code_n_reps
+
+ push_args = concatOL pushs_arg
+ d_after_args = d0 + sum (map taggedSizeW a_reps_pushed_r_to_l)
+ a_reps_pushed_RAW
+ | null a_reps_pushed_r_to_l || head a_reps_pushed_r_to_l /= VoidRep
+ = panic "ByteCodeGen.generateCCall: missing or invalid World token?"
+ | otherwise
+ = reverse (tail a_reps_pushed_r_to_l)
+
+ -- Now: a_reps_pushed_RAW are the reps which are actually on the stack.
+ -- push_args is the code to do that.
+ -- d_after_args is the stack depth once the args are on.
+
+ -- Get the result rep.
+ (returns_void, r_rep)
+ = case maybe_getCCallReturnRep (idType fn) of
+ Nothing -> (True, VoidRep)
+ Just rr -> (False, rr)
+ {-
+ Because the Haskell stack grows down, the a_reps refer to
+ lowest to highest addresses in that order. The args for the call
+ are on the stack. Now push an unboxed, tagged Addr# indicating
+ the C function to call. Then push a dummy placeholder for the
+ result. Finally, emit a CCALL insn with an offset pointing to the
+ Addr# just pushed, and a literal field holding the mallocville
+ address of the piece of marshalling code we generate.
+ So, just prior to the CCALL insn, the stack looks like this
+ (growing down, as usual):
+
+ <arg_n>
+ ...
+ <arg_1>
+ Addr# address_of_C_fn
+ <placeholder-for-result#> (must be an unboxed type)
+
+ The interpreter then calls the marshall code mentioned
+ in the CCALL insn, passing it (& <placeholder-for-result#>),
+ that is, the addr of the topmost word in the stack.
+ When this returns, the placeholder will have been
+ filled in. The placeholder is slid down to the sequel
+ depth, and we RETURN.
+
+ This arrangement makes it simple to do f-i-dynamic since the Addr#
+ value is the first arg anyway. It also has the virtue that the
+ stack is GC-understandable at all times.
+
+ The marshalling code is generated specifically for this
+ call site, and so knows exactly the (Haskell) stack
+ offsets of the args, fn address and placeholder. It
+ copies the args to the C stack, calls the stacked addr,
+ and parks the result back in the placeholder. The interpreter
+ calls it as a normal C call, assuming it has a signature
+ void marshall_code ( StgWord* ptr_to_top_of_stack )
+ -}
+ -- resolve static address
+ get_target_info
+ = case target of
+ DynamicTarget
+ -> returnBc (False, panic "ByteCodeGen.generateCCall(dyn)")
+ StaticTarget target
+ -> let sym_to_find = _UNPK_ target in
+ ioToBc (lookupSymbol sym_to_find) `thenBc` \res ->
+ case res of
+ Just aa -> case aa of Ptr a# -> returnBc (True, A# a#)
+ Nothing -> ioToBc (linkFail "ByteCodeGen.generateCCall"
+ sym_to_find)
+ CasmTarget _
+ -> pprPanic "ByteCodeGen.generateCCall: casm" (ppr ccall_spec)
+ in
+ get_target_info `thenBc` \ (is_static, static_target_addr) ->
+ let
+
+ -- Get the arg reps, zapping the leading Addr# in the dynamic case
+ a_reps -- | trace (showSDoc (ppr a_reps_pushed_RAW)) False = error "???"
+ | is_static = a_reps_pushed_RAW
+ | otherwise = if null a_reps_pushed_RAW
+ then panic "ByteCodeGen.generateCCall: dyn with no args"
+ else tail a_reps_pushed_RAW
+
+ -- push the Addr#
+ (push_Addr, d_after_Addr)
+ | is_static
+ = (toOL [PUSH_UBX (Right static_target_addr) addr_usizeW,
+ PUSH_TAG addr_usizeW],
+ d_after_args + addr_tsizeW)
+ | otherwise -- is already on the stack
+ = (nilOL, d_after_args)
+
+ -- Push the return placeholder. For a call returning nothing,
+ -- this is a VoidRep (tag).
+ r_usizeW = untaggedSizeW r_rep
+ r_tsizeW = taggedSizeW r_rep
+ d_after_r = d_after_Addr + r_tsizeW
+ r_lit = mkDummyLiteral r_rep
+ push_r = (if returns_void
+ then nilOL
+ else unitOL (PUSH_UBX (Left r_lit) r_usizeW))
+ `appOL`
+ unitOL (PUSH_TAG r_usizeW)
+
+ -- generate the marshalling code we're going to call
+ r_offW = 0
+ addr_offW = r_tsizeW
+ arg1_offW = r_tsizeW + addr_tsizeW
+ args_offW = map (arg1_offW +)
+ (init (scanl (+) 0 (map taggedSizeW a_reps)))
+ in
+ ioToBc (mkMarshalCode cconv
+ (r_offW, r_rep) addr_offW
+ (zip args_offW a_reps)) `thenBc` \ addr_of_marshaller ->
+ recordMallocBc addr_of_marshaller `thenBc_`
+ let
+ -- do the call
+ do_call = unitOL (CCALL addr_of_marshaller)
+ -- slide and return
+ wrapup = mkSLIDE r_tsizeW (d_after_r - r_tsizeW - s)
+ `snocOL` RETURN r_rep
+ in
+ --trace (show (arg1_offW, args_offW , (map taggedSizeW a_reps) )) (
+ returnBc (
+ push_args `appOL`
+ push_Addr `appOL` push_r `appOL` do_call `appOL` wrapup
+ )
+ --)
+
+
+-- Make a dummy literal, to be used as a placeholder for FFI return
+-- values on the stack.
+mkDummyLiteral :: PrimRep -> Literal
+mkDummyLiteral pr
+ = case pr of
+ CharRep -> MachChar 0
+ IntRep -> MachInt 0
+ WordRep -> MachWord 0
+ DoubleRep -> MachDouble 0
+ FloatRep -> MachFloat 0
+ AddrRep | taggedSizeW AddrRep == taggedSizeW WordRep -> MachWord 0
+ _ -> moan64 "mkDummyLiteral" (ppr pr)
+
+
+-- Convert (eg)
+-- PrelGHC.Char# -> PrelGHC.State# PrelGHC.RealWorld
+-- -> (# PrelGHC.State# PrelGHC.RealWorld, PrelGHC.Int# #)
+--
+-- to Just IntRep
+-- and check that an unboxed pair is returned wherein the first arg is VoidRep'd.
+--
+-- Alternatively, for call-targets returning nothing, convert
+--
+-- PrelGHC.Char# -> PrelGHC.State# PrelGHC.RealWorld
+-- -> (# PrelGHC.State# PrelGHC.RealWorld #)
+--
+-- to Nothing
+
+maybe_getCCallReturnRep :: Type -> Maybe PrimRep
+maybe_getCCallReturnRep fn_ty
+ = let (a_tys, r_ty) = splitRepFunTys fn_ty
+ maybe_r_rep_to_go
+ = if length r_reps == 1 then Nothing else Just (r_reps !! 1)
+ (r_tycon, r_reps)
+ = case splitTyConApp_maybe (repType r_ty) of
+ (Just (tyc, tys)) -> (tyc, map typePrimRep tys)
+ Nothing -> blargh
+ ok = ( (length r_reps == 2 && VoidRep == head r_reps)
+ || r_reps == [VoidRep] )
+ && isUnboxedTupleTyCon r_tycon
+ && case maybe_r_rep_to_go of
+ Nothing -> True
+ Just r_rep -> r_rep /= PtrRep
+ -- if it was, it would be impossible
+ -- to create a valid return value
+ -- placeholder on the stack
+ blargh = pprPanic "maybe_getCCallReturn: can't handle:"
+ (pprType fn_ty)
+ in
+ --trace (showSDoc (ppr (a_reps, r_reps))) (
+ if ok then maybe_r_rep_to_go else blargh
+ --)
+
+atomRep (AnnVar v) = typePrimRep (idType v)
+atomRep (AnnLit l) = literalPrimRep l
+atomRep (AnnNote n b) = atomRep (snd b)
+atomRep (AnnApp f (_, AnnType _)) = atomRep (snd f)
+atomRep (AnnLam x e) | isTyVar x = atomRep (snd e)
+atomRep other = pprPanic "atomRep" (ppr (deAnnotate (undefined,other)))
+
+
+-- Compile code which expects an unboxed Int on the top of stack,
+-- (call it i), and pushes the i'th closure in the supplied list
+-- as a consequence.
+implement_tagToId :: [Name] -> BcM BCInstrList
+implement_tagToId names
+ = ASSERT(not (null names))
+ getLabelsBc (length names) `thenBc` \ labels ->
+ getLabelBc `thenBc` \ label_fail ->
+ getLabelBc `thenBc` \ label_exit ->
+ zip4 labels (tail labels ++ [label_fail])
+ [0 ..] names `bind` \ infos ->
+ map (mkStep label_exit) infos `bind` \ steps ->
+ returnBc (concatOL steps
+ `appOL`
+ toOL [LABEL label_fail, CASEFAIL, LABEL label_exit])
where
- approved = UPK_TAG usizeW off_h off_s `consOL` theRest
- theRest = mkUnpackCode (off_h + usizeW) (off_s + tsizeW) rs
- usizeW = untaggedSizeW r
- tsizeW = taggedSizeW r
+ mkStep l_exit (my_label, next_label, n, name_for_n)
+ = toOL [LABEL my_label,
+ TESTEQ_I n next_label,
+ PUSH_G (Left name_for_n),
+ JMP l_exit]
+
+
+-- Make code to unpack the top-of-stack constructor onto the stack,
+-- adding tags for the unboxed bits. Takes the PrimReps of the
+-- constructor's arguments. off_h and off_s are travelling offsets
+-- along the constructor and the stack.
+--
+-- Supposing a constructor in the heap has layout
+--
+-- Itbl p_1 ... p_i np_1 ... np_j
+--
+-- then we add to the stack, shown growing down, the following:
+--
+-- (previous stack)
+-- p_i
+-- ...
+-- p_1
+-- np_j
+-- tag_for(np_j)
+-- ..
+-- np_1
+-- tag_for(np_1)
+--
+-- so that in the common case (ptrs only) a single UNPACK instr can
+-- copy all the payload of the constr onto the stack with no further ado.
+
+mkUnpackCode :: [Id] -- constr args
+ -> Int -- depth before unpack
+ -> BCEnv -- env before unpack
+ -> (BCInstrList, Int, BCEnv)
+mkUnpackCode vars d p
+ = --trace ("mkUnpackCode: " ++ showSDocDebug (ppr vars)
+ -- ++ " --> " ++ show d' ++ "\n" ++ showSDocDebug (ppBCEnv p')
+ -- ++ "\n") (
+ (code_p `appOL` code_np, d', p')
+ --)
+ where
+ -- vars with reps
+ vreps = [(var, typePrimRep (idType var)) | var <- vars]
+
+ -- ptrs and nonptrs, forward
+ vreps_p = filter (isFollowableRep.snd) vreps
+ vreps_np = filter (not.isFollowableRep.snd) vreps
+
+ -- the order in which we will augment the environment
+ vreps_env = reverse vreps_p ++ reverse vreps_np
+
+ -- new env and depth
+ vreps_env_tszsw = map (taggedSizeW.snd) vreps_env
+ p' = addListToFM p (zip (map fst vreps_env)
+ (mkStackOffsets d vreps_env_tszsw))
+ d' = d + sum vreps_env_tszsw
+
+ -- code to unpack the ptrs
+ ptrs_szw = sum (map (untaggedSizeW.snd) vreps_p)
+ code_p | null vreps_p = nilOL
+ | otherwise = unitOL (UNPACK ptrs_szw)
+
+ -- code to unpack the nonptrs
+ vreps_env_uszw = sum (map (untaggedSizeW.snd) vreps_env)
+ code_np = do_nptrs vreps_env_uszw ptrs_szw (reverse (map snd vreps_np))
+ do_nptrs off_h off_s [] = nilOL
+ do_nptrs off_h off_s (npr:nprs)
+ | npr `elem` [IntRep, WordRep, FloatRep, DoubleRep, CharRep, AddrRep]
+ = approved
+ | otherwise
+ = moan64 "ByteCodeGen.mkUnpackCode" (ppr npr)
+ where
+ approved = UPK_TAG usizeW (off_h-usizeW) off_s `consOL` theRest
+ theRest = do_nptrs (off_h-usizeW) (off_s + tsizeW) nprs
+ usizeW = untaggedSizeW npr
+ tsizeW = taggedSizeW npr
+
-- Push an atom onto the stack, returning suitable code & number of
-- stack words used. Pushes it either tagged or untagged, since
-- 5 and not to 4. Stack locations are numbered from zero, so a depth
-- 6 stack has valid words 0 .. 5.
-pushAtom :: Bool -> Int -> BCEnv -> AnnExpr' Id VarSet -> (BCInstrList, Int)
-pushAtom tagged d p (AnnVar v)
- = let str = "\npushAtom " ++ showSDocDebug (ppr v) ++ ", depth = " ++ show d
- ++ ", env =\n" ++
- showSDocDebug (nest 4 (vcat (map ppr (fmToList p))))
- ++ " -->\n" ++
+pushAtom :: Bool -> Int -> BCEnv -> AnnExpr' Id VarSet -> BcM (BCInstrList, Int)
+pushAtom tagged d p (AnnVar v)
+
+ | idPrimRep v == VoidRep
+ = if tagged then returnBc (unitOL (PUSH_TAG 0), 1)
+ else panic "ByteCodeGen.pushAtom(VoidRep,untaggedly)"
+
+ | isFCallId v
+ = pprPanic "pushAtom: shouldn't get an FCallId here" (ppr v)
+
+ | Just primop <- isPrimOpId_maybe v
+ = returnBc (unitOL (PUSH_G (Right primop)), 1)
+
+ | otherwise
+ = let {-
+ str = "\npushAtom " ++ showSDocDebug (ppr v)
+ ++ " :: " ++ showSDocDebug (pprType (idType v))
+ ++ ", depth = " ++ show d
+ ++ ", tagged = " ++ show tagged ++ ", env =\n" ++
+ showSDocDebug (ppBCEnv p)
+ ++ " --> words: " ++ show (snd result) ++ "\n" ++
showSDoc (nest 4 (vcat (map ppr (fromOL (fst result)))))
++ "\nendPushAtom " ++ showSDocDebug (ppr v)
- str' = if str == str then str else str
+ -}
result
= case lookupBCEnv_maybe p v of
- Just d_v -> (toOL (nOfThem nwords (PUSH_L (d-d_v+sz_t-2))), sz_t)
- Nothing -> ASSERT(sz_t == 1) (unitOL (PUSH_G nm), sz_t)
+ Just d_v -> (toOL (nOfThem nwords (PUSH_L (d-d_v+sz_t-2))), nwords)
+ Nothing -> ASSERT(sz_t == 1) (unitOL (PUSH_G (Left nm)), nwords)
+
+ nm = case isDataConId_maybe v of
+ Just c -> getName c
+ Nothing -> getName v
- nm = getName v
sz_t = taggedIdSizeW v
sz_u = untaggedIdSizeW v
nwords = if tagged then sz_t else sz_u
in
- --trace str'
- result
+ returnBc result
pushAtom True d p (AnnLit lit)
- = let (ubx_code, ubx_size) = pushAtom False d p (AnnLit lit)
- in (ubx_code `snocOL` PUSH_TAG ubx_size, 1 + ubx_size)
+ = pushAtom False d p (AnnLit lit) `thenBc` \ (ubx_code, ubx_size) ->
+ returnBc (ubx_code `snocOL` PUSH_TAG ubx_size, 1 + ubx_size)
pushAtom False d p (AnnLit lit)
= case lit of
+ MachWord w -> code WordRep
MachInt i -> code IntRep
MachFloat r -> code FloatRep
MachDouble r -> code DoubleRep
MachChar c -> code CharRep
+ MachStr s -> pushStr s
where
code rep
= let size_host_words = untaggedSizeW rep
- in (unitOL (PUSH_UBX lit size_host_words), size_host_words)
+ in returnBc (unitOL (PUSH_UBX (Left lit) size_host_words),
+ size_host_words)
+
+ pushStr s
+ = let getMallocvilleAddr
+ = case s of
+ CharStr s i -> returnBc (A# s)
+
+ FastString _ l ba ->
+ -- sigh, a string in the heap is no good to us.
+ -- We need a static C pointer, since the type of
+ -- a string literal is Addr#. So, copy the string
+ -- into C land and introduce a memory leak
+ -- at the same time.
+ let n = I# l
+ -- CAREFUL! Chars are 32 bits in ghc 4.09+
+ in ioToBc (mallocBytes (n+1)) `thenBc` \ (Ptr a#) ->
+ recordMallocBc (A# a#) `thenBc_`
+ ioToBc (
+ do strncpy (Ptr a#) ba (fromIntegral n)
+ writeCharOffAddr (A# a#) n '\0'
+ return (A# a#)
+ )
+ other -> panic "ByteCodeGen.pushAtom.pushStr"
+ in
+ getMallocvilleAddr `thenBc` \ addr ->
+ -- Get the addr on the stack, untaggedly
+ returnBc (unitOL (PUSH_UBX (Right addr) 1), 1)
+
+
+
+
pushAtom tagged d p (AnnApp f (_, AnnType _))
= pushAtom tagged d p (snd f)
+pushAtom tagged d p (AnnNote note e)
+ = pushAtom tagged d p (snd e)
+
+pushAtom tagged d p (AnnLam x e)
+ | isTyVar x
+ = pushAtom tagged d p (snd e)
+
pushAtom tagged d p other
= pprPanic "ByteCodeGen.pushAtom"
(pprCoreExpr (deAnnotate (undefined, other)))
+foreign import "strncpy" strncpy :: Ptr a -> ByteArray# -> CInt -> IO ()
+
-- Given a bunch of alts code and their discrs, do the donkey work
-- of making a multiway branch using a switch tree.
(algMinBound, algMaxBound)
= case maybe_ncons of
- Just n -> (fIRST_TAG, fIRST_TAG + n - 1)
+ Just n -> (0, n - 1)
Nothing -> (minBound, maxBound)
(DiscrI i1) `eqAlt` (DiscrI i2) = i1 == i2
lookupBCEnv_maybe = lookupFM
--- When I push one of these on the stack, how much does Sp move by?
-taggedSizeW :: PrimRep -> Int
-taggedSizeW pr
- | isFollowableRep pr = 1
- | otherwise = 1{-the tag-} + getPrimRepSize pr
-
-
--- The plain size of something, without tag.
-untaggedSizeW :: PrimRep -> Int
-untaggedSizeW pr
- | isFollowableRep pr = 1
- | otherwise = getPrimRepSize pr
-
-
taggedIdSizeW, untaggedIdSizeW :: Id -> Int
taggedIdSizeW = taggedSizeW . typePrimRep . idType
untaggedIdSizeW = untaggedSizeW . typePrimRep . idType
+unboxedTupleException :: a
+unboxedTupleException
+ = throwDyn
+ (Panic
+ ("Bytecode generator can't handle unboxed tuples. Possibly due\n" ++
+ "\tto foreign import/export decls in source. Workaround:\n" ++
+ "\tcompile this module to a .o file, then restart session."))
+
+
+mkSLIDE n d = if d == 0 then nilOL else unitOL (SLIDE n d)
+bind x f = f x
+
\end{code}
%************************************************************************
\begin{code}
data BcM_State
= BcM_State { bcos :: [ProtoBCO Name], -- accumulates completed BCOs
- nextlabel :: Int } -- for generating local labels
+ nextlabel :: Int, -- for generating local labels
+ malloced :: [Addr] } -- ptrs malloced for current BCO
+ -- Should be free()d when it is GCd
+type BcM r = BcM_State -> IO (BcM_State, r)
-type BcM result = BcM_State -> (result, BcM_State)
+ioToBc :: IO a -> BcM a
+ioToBc io st = do x <- io
+ return (st, x)
-runBc :: BcM_State -> BcM () -> BcM_State
-runBc init_st m = case m init_st of { (r,st) -> st }
+runBc :: BcM_State -> BcM r -> IO (BcM_State, r)
+runBc st0 m = do (st1, res) <- m st0
+ return (st1, res)
thenBc :: BcM a -> (a -> BcM b) -> BcM b
-thenBc expr cont st
- = case expr st of { (result, st') -> cont result st' }
+thenBc expr cont st0
+ = do (st1, q) <- expr st0
+ (st2, r) <- cont q st1
+ return (st2, r)
thenBc_ :: BcM a -> BcM b -> BcM b
-thenBc_ expr cont st
- = case expr st of { (result, st') -> cont st' }
+thenBc_ expr cont st0
+ = do (st1, q) <- expr st0
+ (st2, r) <- cont st1
+ return (st2, r)
returnBc :: a -> BcM a
-returnBc result st = (result, st)
+returnBc result st = return (st, result)
+
mapBc :: (a -> BcM b) -> [a] -> BcM [b]
mapBc f [] = returnBc []
mapBc f xs `thenBc` \ rs ->
returnBc (r:rs)
-emitBc :: ProtoBCO Name -> BcM ()
+emitBc :: ([Addr] -> ProtoBCO Name) -> BcM ()
emitBc bco st
- = ((), st{bcos = bco : bcos st})
-
-getLabelBc :: BcM Int
-getLabelBc st
- = (nextlabel st, st{nextlabel = 1 + nextlabel st})
-
-\end{code}
-
-%************************************************************************
-%* *
-\subsection{The bytecode assembler}
-%* *
-%************************************************************************
-
-The object format for bytecodes is: 16 bits for the opcode, and 16 for
-each field -- so the code can be considered a sequence of 16-bit ints.
-Each field denotes either a stack offset or number of items on the
-stack (eg SLIDE), and index into the pointer table (eg PUSH_G), an
-index into the literal table (eg PUSH_I/D/L), or a bytecode address in
-this BCO.
-
-\begin{code}
--- Top level assembler fn.
-assembleBCO :: ProtoBCO Name -> IO UnlinkedBCO
-
-assembleBCO (ProtoBCO nm instrs origin)
- = let
- -- pass 1: collect up the offsets of the local labels.
- -- Remember that the first insn starts at offset 1 since offset 0
- -- (eventually) will hold the total # of insns.
- label_env = mkLabelEnv emptyFM 1 instrs
-
- mkLabelEnv env i_offset [] = env
- mkLabelEnv env i_offset (i:is)
- = let new_env
- = case i of LABEL n -> addToFM env n i_offset ; _ -> env
- in mkLabelEnv new_env (i_offset + instrSizeB i) is
-
- findLabel lab
- = case lookupFM label_env lab of
- Just bco_offset -> bco_offset
- Nothing -> pprPanic "assembleBCO.findLabel" (int lab)
- in
- do -- pass 2: generate the instruction, ptr and nonptr bits
- insns <- return emptySS :: IO (SizedSeq Word16)
- lits <- return emptySS :: IO (SizedSeq Word)
- ptrs <- return emptySS :: IO (SizedSeq Name)
- itbls <- return emptySS :: IO (SizedSeq Name)
- let init_asm_state = (insns,lits,ptrs,itbls)
- (final_insns, final_lits, final_ptrs, final_itbls)
- <- mkBits findLabel init_asm_state instrs
-
- return (UnlinkedBCO nm final_insns final_lits final_ptrs final_itbls)
-
--- instrs nonptrs ptrs itbls
-type AsmState = (SizedSeq Word16, SizedSeq Word, SizedSeq Name, SizedSeq Name)
-
-data SizedSeq a = SizedSeq !Int [a]
-emptySS = SizedSeq 0 []
-addToSS (SizedSeq n r_xs) x = return (SizedSeq (n+1) (x:r_xs))
-addListToSS (SizedSeq n r_xs) xs
- = return (SizedSeq (n + length xs) (reverse xs ++ r_xs))
-sizeSS (SizedSeq n r_xs) = n
-listFromSS (SizedSeq n r_xs) = return (reverse r_xs)
-
-
--- This is where all the action is (pass 2 of the assembler)
-mkBits :: (Int -> Int) -- label finder
- -> AsmState
- -> [BCInstr] -- instructions (in)
- -> IO AsmState
-
-mkBits findLabel st proto_insns
- = foldM doInstr st proto_insns
- where
- doInstr :: AsmState -> BCInstr -> IO AsmState
- doInstr st i
- = case i of
- ARGCHECK n -> instr2 st i_ARGCHECK n
- PUSH_L o1 -> instr2 st i_PUSH_L o1
- PUSH_LL o1 o2 -> instr3 st i_PUSH_LL o1 o2
- PUSH_LLL o1 o2 o3 -> instr4 st i_PUSH_LLL o1 o2 o3
- PUSH_G nm -> do (p, st2) <- ptr st nm
- instr2 st2 i_PUSH_G p
- PUSH_AS nm pk -> do (p, st2) <- ptr st nm
- (np, st3) <- ctoi_itbl st2 pk
- instr3 st3 i_PUSH_AS p np
- PUSH_UBX lit nws -> do (np, st2) <- literal st lit
- instr3 st2 i_PUSH_UBX np nws
- PUSH_TAG tag -> instr2 st i_PUSH_TAG tag
- SLIDE n by -> instr3 st i_SLIDE n by
- ALLOC n -> instr2 st i_ALLOC n
- MKAP off sz -> instr3 st i_MKAP off sz
- UNPACK n -> instr2 st i_UNPACK n
- UPK_TAG n m k -> instr4 st i_UPK_TAG n m k
- PACK dcon sz -> do (itbl_no,st2) <- itbl st dcon
- instr3 st2 i_PACK itbl_no sz
- LABEL lab -> return st
- TESTLT_I i l -> do (np, st2) <- int st i
- instr3 st2 i_TESTLT_I np (findLabel l)
- TESTEQ_I i l -> do (np, st2) <- int st i
- instr3 st2 i_TESTEQ_I np (findLabel l)
- TESTLT_F f l -> do (np, st2) <- float st f
- instr3 st2 i_TESTLT_F np (findLabel l)
- TESTEQ_F f l -> do (np, st2) <- float st f
- instr3 st2 i_TESTEQ_F np (findLabel l)
- TESTLT_D d l -> do (np, st2) <- double st d
- instr3 st2 i_TESTLT_D np (findLabel l)
- TESTEQ_D d l -> do (np, st2) <- double st d
- instr3 st2 i_TESTEQ_D np (findLabel l)
- TESTLT_P i l -> instr3 st i_TESTLT_P i (findLabel l)
- TESTEQ_P i l -> instr3 st i_TESTEQ_P i (findLabel l)
- CASEFAIL -> instr1 st i_CASEFAIL
- ENTER -> instr1 st i_ENTER
- RETURN rep -> do (itbl_no,st2) <- itoc_itbl st rep
- instr2 st2 i_RETURN itbl_no
-
- i2s :: Int -> Word16
- i2s = fromIntegral
-
- instr1 (st_i0,st_l0,st_p0,st_I0) i1
- = do st_i1 <- addToSS st_i0 (i2s i1)
- return (st_i1,st_l0,st_p0,st_I0)
-
- instr2 (st_i0,st_l0,st_p0,st_I0) i1 i2
- = do st_i1 <- addToSS st_i0 (i2s i1)
- st_i2 <- addToSS st_i1 (i2s i2)
- return (st_i2,st_l0,st_p0,st_I0)
-
- instr3 (st_i0,st_l0,st_p0,st_I0) i1 i2 i3
- = do st_i1 <- addToSS st_i0 (i2s i1)
- st_i2 <- addToSS st_i1 (i2s i2)
- st_i3 <- addToSS st_i2 (i2s i3)
- return (st_i3,st_l0,st_p0,st_I0)
-
- instr4 (st_i0,st_l0,st_p0,st_I0) i1 i2 i3 i4
- = do st_i1 <- addToSS st_i0 (i2s i1)
- st_i2 <- addToSS st_i1 (i2s i2)
- st_i3 <- addToSS st_i2 (i2s i3)
- st_i4 <- addToSS st_i3 (i2s i4)
- return (st_i4,st_l0,st_p0,st_I0)
-
- float (st_i0,st_l0,st_p0,st_I0) f
- = do let ws = mkLitF f
- st_l1 <- addListToSS st_l0 ws
- return (sizeSS st_l0, (st_i0,st_l1,st_p0,st_I0))
-
- double (st_i0,st_l0,st_p0,st_I0) d
- = do let ws = mkLitD d
- st_l1 <- addListToSS st_l0 ws
- return (sizeSS st_l0, (st_i0,st_l1,st_p0,st_I0))
-
- int (st_i0,st_l0,st_p0,st_I0) i
- = do let ws = mkLitI i
- st_l1 <- addListToSS st_l0 ws
- return (sizeSS st_l0, (st_i0,st_l1,st_p0,st_I0))
-
- addr (st_i0,st_l0,st_p0,st_I0) a
- = do let ws = mkLitA a
- st_l1 <- addListToSS st_l0 ws
- return (sizeSS st_l0, (st_i0,st_l1,st_p0,st_I0))
-
- ptr (st_i0,st_l0,st_p0,st_I0) p
- = do st_p1 <- addToSS st_p0 p
- return (sizeSS st_p0, (st_i0,st_l0,st_p1,st_I0))
-
- itbl (st_i0,st_l0,st_p0,st_I0) dcon
- = do st_I1 <- addToSS st_I0 (getName dcon)
- return (sizeSS st_I0, (st_i0,st_l0,st_p0,st_I1))
-
- literal st (MachInt j) = int st (fromIntegral j)
- literal st (MachFloat r) = float st (fromRational r)
- literal st (MachDouble r) = double st (fromRational r)
- literal st (MachChar c) = int st c
-
- ctoi_itbl st pk
- = addr st ret_itbl_addr
- where
- ret_itbl_addr = case pk of
- IntRep -> stg_ctoi_ret_R1_info
- FloatRep -> stg_ctoi_ret_F1_info
- DoubleRep -> stg_ctoi_ret_D1_info
- where -- TEMP HACK
- stg_ctoi_ret_F1_info = nullAddr
- stg_ctoi_ret_D1_info = nullAddr
-
- itoc_itbl st pk
- = addr st ret_itbl_addr
- where
- ret_itbl_addr = case pk of
- IntRep -> stg_gc_unbx_r1_info
- FloatRep -> stg_gc_f1_info
- DoubleRep -> stg_gc_d1_info
-
-foreign label "stg_ctoi_ret_R1_info" stg_ctoi_ret_R1_info :: Addr
---foreign label "stg_ctoi_ret_F1_info" stg_ctoi_ret_F1_info :: Addr
---foreign label "stg_ctoi_ret_D1_info" stg_ctoi_ret_D1_info :: Addr
-
-foreign label "stg_gc_unbx_r1_info" stg_gc_unbx_r1_info :: Addr
-foreign label "stg_gc_f1_info" stg_gc_f1_info :: Addr
-foreign label "stg_gc_d1_info" stg_gc_d1_info :: Addr
-
--- The size in bytes of an instruction.
-instrSizeB :: BCInstr -> Int
-instrSizeB instr
- = case instr of
- ARGCHECK _ -> 4
- PUSH_L _ -> 4
- PUSH_LL _ _ -> 6
- PUSH_LLL _ _ _ -> 8
- PUSH_G _ -> 4
- PUSH_AS _ _ -> 6
- PUSH_UBX _ _ -> 6
- PUSH_TAG _ -> 4
- SLIDE _ _ -> 6
- ALLOC _ -> 4
- MKAP _ _ -> 6
- UNPACK _ -> 4
- UPK_TAG _ _ _ -> 8
- PACK _ _ -> 6
- LABEL _ -> 0 -- !!
- TESTLT_I _ _ -> 6
- TESTEQ_I _ _ -> 6
- TESTLT_F _ _ -> 6
- TESTEQ_F _ _ -> 6
- TESTLT_D _ _ -> 6
- TESTEQ_D _ _ -> 6
- TESTLT_P _ _ -> 6
- TESTEQ_P _ _ -> 6
- CASEFAIL -> 2
- ENTER -> 2
- RETURN _ -> 4
-
-
--- Make lists of host-sized words for literals, so that when the
--- words are placed in memory at increasing addresses, the
--- bit pattern is correct for the host's word size and endianness.
-mkLitI :: Int -> [Word]
-mkLitF :: Float -> [Word]
-mkLitD :: Double -> [Word]
-mkLitA :: Addr -> [Word]
-
-mkLitF f
- = runST (do
- arr <- newFloatArray ((0::Int),0)
- writeFloatArray arr 0 f
- f_arr <- castSTUArray arr
- w0 <- readWordArray f_arr 0
- return [w0]
- )
-
-mkLitD d
- | wORD_SIZE == 4
- = runST (do
- arr <- newDoubleArray ((0::Int),0)
- writeDoubleArray arr 0 d
- d_arr <- castSTUArray arr
- w0 <- readWordArray d_arr 0
- w1 <- readWordArray d_arr 1
- return [w0,w1]
- )
- | wORD_SIZE == 8
- = runST (do
- arr <- newDoubleArray ((0::Int),0)
- writeDoubleArray arr 0 d
- d_arr <- castSTUArray arr
- w0 <- readWordArray d_arr 0
- return [w0]
- )
-
-mkLitI i
- = runST (do
- arr <- newIntArray ((0::Int),0)
- writeIntArray arr 0 i
- i_arr <- castSTUArray arr
- w0 <- readWordArray i_arr 0
- return [w0]
- )
-
-mkLitA a
- = runST (do
- arr <- newAddrArray ((0::Int),0)
- writeAddrArray arr 0 a
- a_arr <- castSTUArray arr
- w0 <- readWordArray a_arr 0
- return [w0]
- )
-
-\end{code}
-
-%************************************************************************
-%* *
-\subsection{Linking interpretables into something we can run}
-%* *
-%************************************************************************
-
-\begin{code}
-
-{-
-data BCO# = BCO# ByteArray# -- instrs :: array Word16#
- ByteArray# -- literals :: array Word32#
- PtrArray# -- ptrs :: Array HValue
- ByteArray# -- itbls :: Array Addr#
--}
-
-GLOBAL_VAR(v_cafTable, [], [HValue])
-
---addCAF :: HValue -> IO ()
---addCAF x = do xs <- readIORef v_cafTable; writeIORef v_cafTable (x:xs)
-
---bcosToHValue :: ItblEnv -> ClosureEnv -> UnlinkedBCOExpr -> IO HValue
---bcosToHValue ie ce (root_bco, other_bcos)
--- = do linked_expr <- linkIExpr ie ce (root_bco, other_bcos)
--- return linked_expr
-
-linkBCO ie ce (UnlinkedBCO nm insnsSS literalsSS ptrsSS itblsSS)
- = do insns <- listFromSS insnsSS
- literals <- listFromSS literalsSS
- ptrs <- listFromSS ptrsSS
- itbls <- listFromSS itblsSS
-
- linked_ptrs <- mapM (lookupCE ce) ptrs
- linked_itbls <- mapM (lookupIE ie) itbls
-
- let n_insns = sizeSS insnsSS
- n_literals = sizeSS literalsSS
- n_ptrs = sizeSS ptrsSS
- n_itbls = sizeSS itblsSS
-
- let ptrs_arr = array (0, n_ptrs-1) (indexify linked_ptrs)
- :: Array Int HValue
- ptrs_parr = case ptrs_arr of Array lo hi parr -> parr
-
- itbls_arr = array (0, n_itbls-1) (indexify linked_itbls)
- :: UArray Int Addr
- itbls_barr = case itbls_arr of UArray lo hi barr -> barr
-
- insns_arr | n_insns > 65535
- = panic "linkBCO: >= 64k insns in BCO"
- | otherwise
- = array (0, n_insns)
- (indexify (fromIntegral n_insns:insns))
- :: UArray Int Word16
- insns_barr = case insns_arr of UArray lo hi barr -> barr
-
- literals_arr = array (0, n_literals-1) (indexify literals)
- :: UArray Int Word
- literals_barr = case literals_arr of UArray lo hi barr -> barr
-
- indexify :: [a] -> [(Int, a)]
- indexify xs = zip [0..] xs
-
- BCO bco# <- newBCO insns_barr literals_barr ptrs_parr itbls_barr
-
- return (unsafeCoerce# bco#)
-
-
-data BCO = BCO BCO#
-
-newBCO :: ByteArray# -> ByteArray# -> Array# a -> ByteArray# -> IO BCO
-newBCO a b c d
- = IO (\s -> case newBCO# a b c d s of (# s1, bco #) -> (# s1, BCO bco #))
-
-
-lookupCE :: ClosureEnv -> Name -> IO HValue
-lookupCE ce nm
- = case lookupFM ce nm of
- Just aa -> return aa
- Nothing
- -> do m <- lookupSymbol (nameToCLabel nm "closure")
- case m of
- Just (A# addr) -> case addrToHValue# addr of
- (# hval #) -> return hval
- Nothing -> pprPanic "ByteCodeGen.lookupCE" (ppr nm)
-
-lookupIE :: ItblEnv -> Name -> IO Addr
-lookupIE ie con_nm
- = case lookupFM ie con_nm of
- Just (Ptr a) -> return a
- Nothing
- -> do -- try looking up in the object files.
- m <- lookupSymbol (nameToCLabel con_nm "con_info")
- case m of
- Just addr -> return addr
- Nothing -> pprPanic "ByteCodeGen.lookupIE" (ppr con_nm)
-
--- HACK!!! ToDo: cleaner
-nameToCLabel :: Name -> String{-suffix-} -> String
-nameToCLabel n suffix
- = _UNPK_(moduleNameFS (rdrNameModule rn))
- ++ '_':occNameString(rdrNameOcc rn) ++ '_':suffix
- where rn = toRdrName n
-
+ = return (st{bcos = bco (malloced st) : bcos st, malloced=[]}, ())
-{-
-lookupCon ie con =
- case lookupFM ie con of
- Just (Ptr addr) -> return addr
- Nothing -> do
- -- try looking up in the object files.
- m <- lookupSymbol (nameToCLabel con "con_info")
- case m of
- Just addr -> return addr
- Nothing -> pprPanic "linkIExpr" (ppr con)
-
--- nullary constructors don't have normal _con_info tables.
-lookupNullaryCon ie con =
- case lookupFM ie con of
- Just (Ptr addr) -> return (ConApp addr)
- Nothing -> do
- -- try looking up in the object files.
- m <- lookupSymbol (nameToCLabel con "closure")
- case m of
- Just (A# addr) -> return (Native (unsafeCoerce# addr))
- Nothing -> pprPanic "lookupNullaryCon" (ppr con)
-
-
-lookupNative ce var =
- unsafeInterleaveIO (do
- case lookupFM ce var of
- Just e -> return (Native e)
- Nothing -> do
- -- try looking up in the object files.
- let lbl = (nameToCLabel var "closure")
- m <- lookupSymbol lbl
- case m of
- Just (A# addr)
- -> do addCAF (unsafeCoerce# addr)
- return (Native (unsafeCoerce# addr))
- Nothing -> pprPanic "linkIExpr" (ppr var)
- )
-
--- some VarI/VarP refer to top-level interpreted functions; we change
--- them into Natives here.
-lookupVar ce f v =
- unsafeInterleaveIO (
- case lookupFM ce (getName v) of
- Nothing -> return (f v)
- Just e -> return (Native e)
- )
--}
-\end{code}
-
-%************************************************************************
-%* *
-\subsection{Manufacturing of info tables for DataCons}
-%* *
-%************************************************************************
-
-\begin{code}
-
-#if __GLASGOW_HASKELL__ <= 408
-type ItblPtr = Addr
-#else
-type ItblPtr = Ptr StgInfoTable
-#endif
-
--- Make info tables for the data decls in this module
-mkITbls :: [TyCon] -> IO ItblEnv
-mkITbls [] = return emptyFM
-mkITbls (tc:tcs) = do itbls <- mkITbl tc
- itbls2 <- mkITbls tcs
- return (itbls `plusFM` itbls2)
-
-mkITbl :: TyCon -> IO ItblEnv
-mkITbl tc
--- | trace ("TYCON: " ++ showSDoc (ppr tc)) False
--- = error "?!?!"
- | not (isDataTyCon tc)
- = return emptyFM
- | n == length dcs -- paranoia; this is an assertion.
- = make_constr_itbls dcs
- where
- dcs = tyConDataCons tc
- n = tyConFamilySize tc
-
-cONSTR :: Int
-cONSTR = 1 -- as defined in ghc/includes/ClosureTypes.h
-
--- Assumes constructors are numbered from zero, not one
-make_constr_itbls :: [DataCon] -> IO ItblEnv
-make_constr_itbls cons
- | length cons <= 8
- = do is <- mapM mk_vecret_itbl (zip cons [0..])
- return (listToFM is)
+newbcoBc :: BcM ()
+newbcoBc st
+ | not (null (malloced st))
+ = panic "ByteCodeGen.newbcoBc: missed prior emitBc?"
| otherwise
- = do is <- mapM mk_dirret_itbl (zip cons [0..])
- return (listToFM is)
- where
- mk_vecret_itbl (dcon, conNo)
- = mk_itbl dcon conNo (vecret_entry conNo)
- mk_dirret_itbl (dcon, conNo)
- = mk_itbl dcon conNo stg_interp_constr_entry
-
- mk_itbl :: DataCon -> Int -> Addr -> IO (Name,ItblPtr)
- mk_itbl dcon conNo entry_addr
- = let (tot_wds, ptr_wds, _)
- = mkVirtHeapOffsets typePrimRep (dataConRepArgTys dcon)
- ptrs = ptr_wds
- nptrs = tot_wds - ptr_wds
- itbl = StgInfoTable {
- ptrs = fromIntegral ptrs, nptrs = fromIntegral nptrs,
- tipe = fromIntegral cONSTR,
- srtlen = fromIntegral conNo,
- code0 = fromIntegral code0, code1 = fromIntegral code1,
- code2 = fromIntegral code2, code3 = fromIntegral code3,
- code4 = fromIntegral code4, code5 = fromIntegral code5,
- code6 = fromIntegral code6, code7 = fromIntegral code7
- }
- -- Make a piece of code to jump to "entry_label".
- -- This is the only arch-dependent bit.
- -- On x86, if entry_label has an address 0xWWXXYYZZ,
- -- emit movl $0xWWXXYYZZ,%eax ; jmp *%eax
- -- which is
- -- B8 ZZ YY XX WW FF E0
- (code0,code1,code2,code3,code4,code5,code6,code7)
- = (0xB8, byte 0 entry_addr_w, byte 1 entry_addr_w,
- byte 2 entry_addr_w, byte 3 entry_addr_w,
- 0xFF, 0xE0,
- 0x90 {-nop-})
-
- entry_addr_w :: Word32
- entry_addr_w = fromIntegral (addrToInt entry_addr)
- in
- do addr <- malloc
- --putStrLn ("SIZE of itbl is " ++ show (sizeOf itbl))
- --putStrLn ("# ptrs of itbl is " ++ show ptrs)
- --putStrLn ("# nptrs of itbl is " ++ show nptrs)
- poke addr itbl
- return (getName dcon, addr `plusPtr` 8)
-
-
-byte :: Int -> Word32 -> Word32
-byte 0 w = w .&. 0xFF
-byte 1 w = (w `shiftR` 8) .&. 0xFF
-byte 2 w = (w `shiftR` 16) .&. 0xFF
-byte 3 w = (w `shiftR` 24) .&. 0xFF
-
-
-vecret_entry 0 = stg_interp_constr1_entry
-vecret_entry 1 = stg_interp_constr2_entry
-vecret_entry 2 = stg_interp_constr3_entry
-vecret_entry 3 = stg_interp_constr4_entry
-vecret_entry 4 = stg_interp_constr5_entry
-vecret_entry 5 = stg_interp_constr6_entry
-vecret_entry 6 = stg_interp_constr7_entry
-vecret_entry 7 = stg_interp_constr8_entry
-
--- entry point for direct returns for created constr itbls
-foreign label "stg_interp_constr_entry" stg_interp_constr_entry :: Addr
--- and the 8 vectored ones
-foreign label "stg_interp_constr1_entry" stg_interp_constr1_entry :: Addr
-foreign label "stg_interp_constr2_entry" stg_interp_constr2_entry :: Addr
-foreign label "stg_interp_constr3_entry" stg_interp_constr3_entry :: Addr
-foreign label "stg_interp_constr4_entry" stg_interp_constr4_entry :: Addr
-foreign label "stg_interp_constr5_entry" stg_interp_constr5_entry :: Addr
-foreign label "stg_interp_constr6_entry" stg_interp_constr6_entry :: Addr
-foreign label "stg_interp_constr7_entry" stg_interp_constr7_entry :: Addr
-foreign label "stg_interp_constr8_entry" stg_interp_constr8_entry :: Addr
-
-
-
-
-
--- Ultra-minimalist version specially for constructors
-data StgInfoTable = StgInfoTable {
- ptrs :: Word16,
- nptrs :: Word16,
- srtlen :: Word16,
- tipe :: Word16,
- code0, code1, code2, code3, code4, code5, code6, code7 :: Word8
-}
-
-
-instance Storable StgInfoTable where
-
- sizeOf itbl
- = (sum . map (\f -> f itbl))
- [fieldSz ptrs, fieldSz nptrs, fieldSz srtlen, fieldSz tipe,
- fieldSz code0, fieldSz code1, fieldSz code2, fieldSz code3,
- fieldSz code4, fieldSz code5, fieldSz code6, fieldSz code7]
-
- alignment itbl
- = (sum . map (\f -> f itbl))
- [fieldAl ptrs, fieldAl nptrs, fieldAl srtlen, fieldAl tipe,
- fieldAl code0, fieldAl code1, fieldAl code2, fieldAl code3,
- fieldAl code4, fieldAl code5, fieldAl code6, fieldAl code7]
-
- poke a0 itbl
- = do a1 <- store (ptrs itbl) (castPtr a0)
- a2 <- store (nptrs itbl) a1
- a3 <- store (tipe itbl) a2
- a4 <- store (srtlen itbl) a3
- a5 <- store (code0 itbl) a4
- a6 <- store (code1 itbl) a5
- a7 <- store (code2 itbl) a6
- a8 <- store (code3 itbl) a7
- a9 <- store (code4 itbl) a8
- aA <- store (code5 itbl) a9
- aB <- store (code6 itbl) aA
- aC <- store (code7 itbl) aB
- return ()
-
- peek a0
- = do (a1,ptrs) <- load (castPtr a0)
- (a2,nptrs) <- load a1
- (a3,tipe) <- load a2
- (a4,srtlen) <- load a3
- (a5,code0) <- load a4
- (a6,code1) <- load a5
- (a7,code2) <- load a6
- (a8,code3) <- load a7
- (a9,code4) <- load a8
- (aA,code5) <- load a9
- (aB,code6) <- load aA
- (aC,code7) <- load aB
- return StgInfoTable { ptrs = ptrs, nptrs = nptrs,
- srtlen = srtlen, tipe = tipe,
- code0 = code0, code1 = code1, code2 = code2,
- code3 = code3, code4 = code4, code5 = code5,
- code6 = code6, code7 = code7 }
-
-fieldSz :: (Storable a, Storable b) => (a -> b) -> a -> Int
-fieldSz sel x = sizeOf (sel x)
-
-fieldAl :: (Storable a, Storable b) => (a -> b) -> a -> Int
-fieldAl sel x = alignment (sel x)
-
-store :: Storable a => a -> Ptr a -> IO (Ptr b)
-store x addr = do poke addr x
- return (castPtr (addr `plusPtr` sizeOf x))
-
-load :: Storable a => Ptr a -> IO (Ptr b, a)
-load addr = do x <- peek addr
- return (castPtr (addr `plusPtr` sizeOf x), x)
+ = return (st, ())
-\end{code}
+recordMallocBc :: Addr -> BcM ()
+recordMallocBc a st
+ = return (st{malloced = a : malloced st}, ())
-%************************************************************************
-%* *
-\subsection{Connect to actual values for bytecode opcodes}
-%* *
-%************************************************************************
-
-\begin{code}
+getLabelBc :: BcM Int
+getLabelBc st
+ = return (st{nextlabel = 1 + nextlabel st}, nextlabel st)
-#include "Bytecodes.h"
-
-i_ARGCHECK = (bci_ARGCHECK :: Int)
-i_PUSH_L = (bci_PUSH_L :: Int)
-i_PUSH_LL = (bci_PUSH_LL :: Int)
-i_PUSH_LLL = (bci_PUSH_LLL :: Int)
-i_PUSH_G = (bci_PUSH_G :: Int)
-i_PUSH_AS = (bci_PUSH_AS :: Int)
-i_PUSH_UBX = (bci_PUSH_UBX :: Int)
-i_PUSH_TAG = (bci_PUSH_TAG :: Int)
-i_SLIDE = (bci_SLIDE :: Int)
-i_ALLOC = (bci_ALLOC :: Int)
-i_MKAP = (bci_MKAP :: Int)
-i_UNPACK = (bci_UNPACK :: Int)
-i_UPK_TAG = (bci_UPK_TAG :: Int)
-i_PACK = (bci_PACK :: Int)
-i_TESTLT_I = (bci_TESTLT_I :: Int)
-i_TESTEQ_I = (bci_TESTEQ_I :: Int)
-i_TESTLT_F = (bci_TESTLT_F :: Int)
-i_TESTEQ_F = (bci_TESTEQ_F :: Int)
-i_TESTLT_D = (bci_TESTLT_D :: Int)
-i_TESTEQ_D = (bci_TESTEQ_D :: Int)
-i_TESTLT_P = (bci_TESTLT_P :: Int)
-i_TESTEQ_P = (bci_TESTEQ_P :: Int)
-i_CASEFAIL = (bci_CASEFAIL :: Int)
-i_ENTER = (bci_ENTER :: Int)
-i_RETURN = (bci_RETURN :: Int)
+getLabelsBc :: Int -> BcM [Int]
+getLabelsBc n st
+ = let ctr = nextlabel st
+ in return (st{nextlabel = ctr+n}, [ctr .. ctr+n-1])
\end{code}