{-# LANGUAGE CPP, MagicHash, RecordWildCards, BangPatterns #-}
{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# OPTIONS_GHC -fprof-auto-top #-}
module ByteCodeGen ( UnlinkedBCO, byteCodeGen, coreExprToBCOs ) where
#include "HsVersions.h"
import GhcPrelude
import ByteCodeInstr
import ByteCodeAsm
import ByteCodeTypes
import GHCi
import GHCi.FFI
import GHCi.RemoteTypes
import BasicTypes
import DynFlags
import Outputable
import GHC.Platform
import Name
import MkId
import Id
import Var ( updateVarType )
import ForeignCall
import HscTypes
import CoreUtils
import CoreSyn
import PprCore
import Literal
import PrimOp
import CoreFVs
import Type
import RepType
import DataCon
import TyCon
import Util
import VarSet
import TysPrim
import TyCoPpr ( pprType )
import ErrUtils
import Unique
import FastString
import Panic
import GHC.StgToCmm.Closure ( NonVoid(..), fromNonVoid, nonVoidIds )
import GHC.StgToCmm.Layout
import SMRep hiding (WordOff, ByteOff, wordsToBytes)
import Bitmap
import OrdList
import Maybes
import VarEnv
import Data.List
import Foreign
import Control.Monad
import Data.Char
import UniqSupply
import Module
import Control.Exception
import Data.Array
import Data.ByteString (ByteString)
import Data.Map (Map)
import Data.IntMap (IntMap)
import qualified Data.Map as Map
import qualified Data.IntMap as IntMap
import qualified FiniteMap as Map
import Data.Ord
import GHC.Stack.CCS
import Data.Either ( partitionEithers )
byteCodeGen :: HscEnv
-> Module
-> CoreProgram
-> [TyCon]
-> Maybe ModBreaks
-> IO CompiledByteCode
byteCodeGen :: HscEnv
-> Module
-> CoreProgram
-> [TyCon]
-> Maybe ModBreaks
-> IO CompiledByteCode
byteCodeGen HscEnv
hsc_env Module
this_mod CoreProgram
binds [TyCon]
tycs Maybe ModBreaks
mb_modBreaks
= DynFlags
-> SDoc
-> (CompiledByteCode -> ())
-> IO CompiledByteCode
-> IO CompiledByteCode
forall (m :: * -> *) a.
MonadIO m =>
DynFlags -> SDoc -> (a -> ()) -> m a -> m a
withTiming DynFlags
dflags
(String -> SDoc
text String
"ByteCodeGen"SDoc -> SDoc -> SDoc
<+>SDoc -> SDoc
brackets (Module -> SDoc
forall a. Outputable a => a -> SDoc
ppr Module
this_mod))
(() -> CompiledByteCode -> ()
forall a b. a -> b -> a
const ()) (IO CompiledByteCode -> IO CompiledByteCode)
-> IO CompiledByteCode -> IO CompiledByteCode
forall a b. (a -> b) -> a -> b
$ do
let ([(CoreBndr, ByteString)]
strings, [(CoreBndr, AnnExpr CoreBndr DVarSet)]
flatBinds) = [Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)]
-> ([(CoreBndr, ByteString)],
[(CoreBndr, AnnExpr CoreBndr DVarSet)])
forall a b. [Either a b] -> ([a], [b])
partitionEithers ([Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)]
-> ([(CoreBndr, ByteString)],
[(CoreBndr, AnnExpr CoreBndr DVarSet)]))
-> [Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)]
-> ([(CoreBndr, ByteString)],
[(CoreBndr, AnnExpr CoreBndr DVarSet)])
forall a b. (a -> b) -> a -> b
$ do
(CoreBndr
bndr, Expr CoreBndr
rhs) <- CoreProgram -> [(CoreBndr, Expr CoreBndr)]
forall b. [Bind b] -> [(b, Expr b)]
flattenBinds CoreProgram
binds
Either (CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)
-> [Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)]
forall (m :: * -> *) a. Monad m => a -> m a
return (Either (CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)
-> [Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)])
-> Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)
-> [Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)]
forall a b. (a -> b) -> a -> b
$ case Expr CoreBndr -> Maybe ByteString
exprIsTickedString_maybe Expr CoreBndr
rhs of
Just ByteString
str -> (CoreBndr, ByteString)
-> Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)
forall a b. a -> Either a b
Left (CoreBndr
bndr, ByteString
str)
Maybe ByteString
_ -> (CoreBndr, AnnExpr CoreBndr DVarSet)
-> Either
(CoreBndr, ByteString) (CoreBndr, AnnExpr CoreBndr DVarSet)
forall a b. b -> Either a b
Right (CoreBndr
bndr, Expr CoreBndr -> AnnExpr CoreBndr DVarSet
simpleFreeVars Expr CoreBndr
rhs)
[(CoreBndr, RemotePtr ())]
stringPtrs <- HscEnv -> [(CoreBndr, ByteString)] -> IO [(CoreBndr, RemotePtr ())]
allocateTopStrings HscEnv
hsc_env [(CoreBndr, ByteString)]
strings
UniqSupply
us <- Char -> IO UniqSupply
mkSplitUniqSupply Char
'y'
(BcM_State{[FFIInfo]
Maybe ModBreaks
Word16
IntMap CgBreakInfo
Module
UniqSupply
IdEnv (RemotePtr ())
HscEnv
topStrings :: BcM_State -> IdEnv (RemotePtr ())
breakInfo :: BcM_State -> IntMap CgBreakInfo
modBreaks :: BcM_State -> Maybe ModBreaks
ffis :: BcM_State -> [FFIInfo]
nextlabel :: BcM_State -> Word16
thisModule :: BcM_State -> Module
uniqSupply :: BcM_State -> UniqSupply
bcm_hsc_env :: BcM_State -> HscEnv
topStrings :: IdEnv (RemotePtr ())
breakInfo :: IntMap CgBreakInfo
modBreaks :: Maybe ModBreaks
ffis :: [FFIInfo]
nextlabel :: Word16
thisModule :: Module
uniqSupply :: UniqSupply
bcm_hsc_env :: HscEnv
..}, [ProtoBCO Name]
proto_bcos) <-
HscEnv
-> UniqSupply
-> Module
-> Maybe ModBreaks
-> IdEnv (RemotePtr ())
-> BcM [ProtoBCO Name]
-> IO (BcM_State, [ProtoBCO Name])
forall r.
HscEnv
-> UniqSupply
-> Module
-> Maybe ModBreaks
-> IdEnv (RemotePtr ())
-> BcM r
-> IO (BcM_State, r)
runBc HscEnv
hsc_env UniqSupply
us Module
this_mod Maybe ModBreaks
mb_modBreaks ([(CoreBndr, RemotePtr ())] -> IdEnv (RemotePtr ())
forall a. [(CoreBndr, a)] -> VarEnv a
mkVarEnv [(CoreBndr, RemotePtr ())]
stringPtrs) (BcM [ProtoBCO Name] -> IO (BcM_State, [ProtoBCO Name]))
-> BcM [ProtoBCO Name] -> IO (BcM_State, [ProtoBCO Name])
forall a b. (a -> b) -> a -> b
$
((CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name))
-> [(CoreBndr, AnnExpr CoreBndr DVarSet)] -> BcM [ProtoBCO Name]
forall (t :: * -> *) (m :: * -> *) a b.
(Traversable t, Monad m) =>
(a -> m b) -> t a -> m (t b)
mapM (CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name)
schemeTopBind [(CoreBndr, AnnExpr CoreBndr DVarSet)]
flatBinds
Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when ([FFIInfo] -> Bool
forall a. [a] -> Bool
notNull [FFIInfo]
ffis)
(String -> IO ()
forall a. String -> a
panic String
"ByteCodeGen.byteCodeGen: missing final emitBc?")
DynFlags -> DumpFlag -> String -> SDoc -> IO ()
dumpIfSet_dyn DynFlags
dflags DumpFlag
Opt_D_dump_BCOs
String
"Proto-BCOs" ([SDoc] -> SDoc
vcat (SDoc -> [SDoc] -> [SDoc]
forall a. a -> [a] -> [a]
intersperse (Char -> SDoc
char Char
' ') ((ProtoBCO Name -> SDoc) -> [ProtoBCO Name] -> [SDoc]
forall a b. (a -> b) -> [a] -> [b]
map ProtoBCO Name -> SDoc
forall a. Outputable a => a -> SDoc
ppr [ProtoBCO Name]
proto_bcos)))
CompiledByteCode
cbc <- HscEnv
-> [ProtoBCO Name]
-> [TyCon]
-> [RemotePtr ()]
-> Maybe ModBreaks
-> IO CompiledByteCode
assembleBCOs HscEnv
hsc_env [ProtoBCO Name]
proto_bcos [TyCon]
tycs (((CoreBndr, RemotePtr ()) -> RemotePtr ())
-> [(CoreBndr, RemotePtr ())] -> [RemotePtr ()]
forall a b. (a -> b) -> [a] -> [b]
map (CoreBndr, RemotePtr ()) -> RemotePtr ()
forall a b. (a, b) -> b
snd [(CoreBndr, RemotePtr ())]
stringPtrs)
(case Maybe ModBreaks
modBreaks of
Maybe ModBreaks
Nothing -> Maybe ModBreaks
forall a. Maybe a
Nothing
Just ModBreaks
mb -> ModBreaks -> Maybe ModBreaks
forall a. a -> Maybe a
Just ModBreaks
mb{ modBreaks_breakInfo :: IntMap CgBreakInfo
modBreaks_breakInfo = IntMap CgBreakInfo
breakInfo })
() -> IO ()
forall a. a -> IO a
evaluate (CompiledByteCode -> ()
seqCompiledByteCode CompiledByteCode
cbc)
CompiledByteCode -> IO CompiledByteCode
forall (m :: * -> *) a. Monad m => a -> m a
return CompiledByteCode
cbc
where dflags :: DynFlags
dflags = HscEnv -> DynFlags
hsc_dflags HscEnv
hsc_env
allocateTopStrings
:: HscEnv
-> [(Id, ByteString)]
-> IO [(Var, RemotePtr ())]
allocateTopStrings :: HscEnv -> [(CoreBndr, ByteString)] -> IO [(CoreBndr, RemotePtr ())]
allocateTopStrings HscEnv
hsc_env [(CoreBndr, ByteString)]
topStrings = do
let !([CoreBndr]
bndrs, [ByteString]
strings) = [(CoreBndr, ByteString)] -> ([CoreBndr], [ByteString])
forall a b. [(a, b)] -> ([a], [b])
unzip [(CoreBndr, ByteString)]
topStrings
[RemotePtr ()]
ptrs <- HscEnv -> Message [RemotePtr ()] -> IO [RemotePtr ()]
forall a. Binary a => HscEnv -> Message a -> IO a
iservCmd HscEnv
hsc_env (Message [RemotePtr ()] -> IO [RemotePtr ()])
-> Message [RemotePtr ()] -> IO [RemotePtr ()]
forall a b. (a -> b) -> a -> b
$ [ByteString] -> Message [RemotePtr ()]
MallocStrings [ByteString]
strings
[(CoreBndr, RemotePtr ())] -> IO [(CoreBndr, RemotePtr ())]
forall (m :: * -> *) a. Monad m => a -> m a
return ([(CoreBndr, RemotePtr ())] -> IO [(CoreBndr, RemotePtr ())])
-> [(CoreBndr, RemotePtr ())] -> IO [(CoreBndr, RemotePtr ())]
forall a b. (a -> b) -> a -> b
$ [CoreBndr] -> [RemotePtr ()] -> [(CoreBndr, RemotePtr ())]
forall a b. [a] -> [b] -> [(a, b)]
zip [CoreBndr]
bndrs [RemotePtr ()]
ptrs
coreExprToBCOs :: HscEnv
-> Module
-> CoreExpr
-> IO UnlinkedBCO
coreExprToBCOs :: HscEnv -> Module -> Expr CoreBndr -> IO UnlinkedBCO
coreExprToBCOs HscEnv
hsc_env Module
this_mod Expr CoreBndr
expr
= DynFlags
-> SDoc -> (UnlinkedBCO -> ()) -> IO UnlinkedBCO -> IO UnlinkedBCO
forall (m :: * -> *) a.
MonadIO m =>
DynFlags -> SDoc -> (a -> ()) -> m a -> m a
withTiming DynFlags
dflags
(String -> SDoc
text String
"ByteCodeGen"SDoc -> SDoc -> SDoc
<+>SDoc -> SDoc
brackets (Module -> SDoc
forall a. Outputable a => a -> SDoc
ppr Module
this_mod))
(() -> UnlinkedBCO -> ()
forall a b. a -> b -> a
const ()) (IO UnlinkedBCO -> IO UnlinkedBCO)
-> IO UnlinkedBCO -> IO UnlinkedBCO
forall a b. (a -> b) -> a -> b
$ do
let invented_name :: Name
invented_name = Unique -> FastString -> Name
mkSystemVarName (Int -> Unique
mkPseudoUniqueE Int
0) (String -> FastString
fsLit String
"ExprTopLevel")
invented_id :: CoreBndr
invented_id = Name -> Type -> CoreBndr
Id.mkLocalId Name
invented_name (String -> Type
forall a. String -> a
panic String
"invented_id's type")
UniqSupply
us <- Char -> IO UniqSupply
mkSplitUniqSupply Char
'y'
(BcM_State HscEnv
_dflags UniqSupply
_us Module
_this_mod Word16
_final_ctr [FFIInfo]
mallocd Maybe ModBreaks
_ IntMap CgBreakInfo
_ IdEnv (RemotePtr ())
_, ProtoBCO Name
proto_bco)
<- HscEnv
-> UniqSupply
-> Module
-> Maybe ModBreaks
-> IdEnv (RemotePtr ())
-> BcM (ProtoBCO Name)
-> IO (BcM_State, ProtoBCO Name)
forall r.
HscEnv
-> UniqSupply
-> Module
-> Maybe ModBreaks
-> IdEnv (RemotePtr ())
-> BcM r
-> IO (BcM_State, r)
runBc HscEnv
hsc_env UniqSupply
us Module
this_mod Maybe ModBreaks
forall a. Maybe a
Nothing IdEnv (RemotePtr ())
forall a. VarEnv a
emptyVarEnv (BcM (ProtoBCO Name) -> IO (BcM_State, ProtoBCO Name))
-> BcM (ProtoBCO Name) -> IO (BcM_State, ProtoBCO Name)
forall a b. (a -> b) -> a -> b
$
(CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name)
schemeTopBind (CoreBndr
invented_id, Expr CoreBndr -> AnnExpr CoreBndr DVarSet
simpleFreeVars Expr CoreBndr
expr)
Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when ([FFIInfo] -> Bool
forall a. [a] -> Bool
notNull [FFIInfo]
mallocd)
(String -> IO ()
forall a. String -> a
panic String
"ByteCodeGen.coreExprToBCOs: missing final emitBc?")
DynFlags -> DumpFlag -> String -> SDoc -> IO ()
dumpIfSet_dyn DynFlags
dflags DumpFlag
Opt_D_dump_BCOs String
"Proto-BCOs" (ProtoBCO Name -> SDoc
forall a. Outputable a => a -> SDoc
ppr ProtoBCO Name
proto_bco)
HscEnv -> ProtoBCO Name -> IO UnlinkedBCO
assembleOneBCO HscEnv
hsc_env ProtoBCO Name
proto_bco
where dflags :: DynFlags
dflags = HscEnv -> DynFlags
hsc_dflags HscEnv
hsc_env
simpleFreeVars :: CoreExpr -> AnnExpr Id DVarSet
simpleFreeVars :: Expr CoreBndr -> AnnExpr CoreBndr DVarSet
simpleFreeVars = Expr CoreBndr -> AnnExpr CoreBndr DVarSet
freeVars
type BCInstrList = OrdList BCInstr
newtype ByteOff = ByteOff Int
deriving (Int -> ByteOff
ByteOff -> Int
ByteOff -> [ByteOff]
ByteOff -> ByteOff
ByteOff -> ByteOff -> [ByteOff]
ByteOff -> ByteOff -> ByteOff -> [ByteOff]
(ByteOff -> ByteOff)
-> (ByteOff -> ByteOff)
-> (Int -> ByteOff)
-> (ByteOff -> Int)
-> (ByteOff -> [ByteOff])
-> (ByteOff -> ByteOff -> [ByteOff])
-> (ByteOff -> ByteOff -> [ByteOff])
-> (ByteOff -> ByteOff -> ByteOff -> [ByteOff])
-> Enum ByteOff
forall a.
(a -> a)
-> (a -> a)
-> (Int -> a)
-> (a -> Int)
-> (a -> [a])
-> (a -> a -> [a])
-> (a -> a -> [a])
-> (a -> a -> a -> [a])
-> Enum a
enumFromThenTo :: ByteOff -> ByteOff -> ByteOff -> [ByteOff]
$cenumFromThenTo :: ByteOff -> ByteOff -> ByteOff -> [ByteOff]
enumFromTo :: ByteOff -> ByteOff -> [ByteOff]
$cenumFromTo :: ByteOff -> ByteOff -> [ByteOff]
enumFromThen :: ByteOff -> ByteOff -> [ByteOff]
$cenumFromThen :: ByteOff -> ByteOff -> [ByteOff]
enumFrom :: ByteOff -> [ByteOff]
$cenumFrom :: ByteOff -> [ByteOff]
fromEnum :: ByteOff -> Int
$cfromEnum :: ByteOff -> Int
toEnum :: Int -> ByteOff
$ctoEnum :: Int -> ByteOff
pred :: ByteOff -> ByteOff
$cpred :: ByteOff -> ByteOff
succ :: ByteOff -> ByteOff
$csucc :: ByteOff -> ByteOff
Enum, ByteOff -> ByteOff -> Bool
(ByteOff -> ByteOff -> Bool)
-> (ByteOff -> ByteOff -> Bool) -> Eq ByteOff
forall a. (a -> a -> Bool) -> (a -> a -> Bool) -> Eq a
/= :: ByteOff -> ByteOff -> Bool
$c/= :: ByteOff -> ByteOff -> Bool
== :: ByteOff -> ByteOff -> Bool
$c== :: ByteOff -> ByteOff -> Bool
Eq, Enum ByteOff
Real ByteOff
Real ByteOff
-> Enum ByteOff
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> (ByteOff, ByteOff))
-> (ByteOff -> ByteOff -> (ByteOff, ByteOff))
-> (ByteOff -> Integer)
-> Integral ByteOff
ByteOff -> Integer
ByteOff -> ByteOff -> (ByteOff, ByteOff)
ByteOff -> ByteOff -> ByteOff
forall a.
Real a
-> Enum a
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> (a, a))
-> (a -> a -> (a, a))
-> (a -> Integer)
-> Integral a
toInteger :: ByteOff -> Integer
$ctoInteger :: ByteOff -> Integer
divMod :: ByteOff -> ByteOff -> (ByteOff, ByteOff)
$cdivMod :: ByteOff -> ByteOff -> (ByteOff, ByteOff)
quotRem :: ByteOff -> ByteOff -> (ByteOff, ByteOff)
$cquotRem :: ByteOff -> ByteOff -> (ByteOff, ByteOff)
mod :: ByteOff -> ByteOff -> ByteOff
$cmod :: ByteOff -> ByteOff -> ByteOff
div :: ByteOff -> ByteOff -> ByteOff
$cdiv :: ByteOff -> ByteOff -> ByteOff
rem :: ByteOff -> ByteOff -> ByteOff
$crem :: ByteOff -> ByteOff -> ByteOff
quot :: ByteOff -> ByteOff -> ByteOff
$cquot :: ByteOff -> ByteOff -> ByteOff
$cp2Integral :: Enum ByteOff
$cp1Integral :: Real ByteOff
Integral, Integer -> ByteOff
ByteOff -> ByteOff
ByteOff -> ByteOff -> ByteOff
(ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff)
-> (ByteOff -> ByteOff)
-> (ByteOff -> ByteOff)
-> (Integer -> ByteOff)
-> Num ByteOff
forall a.
(a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a)
-> (a -> a)
-> (a -> a)
-> (Integer -> a)
-> Num a
fromInteger :: Integer -> ByteOff
$cfromInteger :: Integer -> ByteOff
signum :: ByteOff -> ByteOff
$csignum :: ByteOff -> ByteOff
abs :: ByteOff -> ByteOff
$cabs :: ByteOff -> ByteOff
negate :: ByteOff -> ByteOff
$cnegate :: ByteOff -> ByteOff
* :: ByteOff -> ByteOff -> ByteOff
$c* :: ByteOff -> ByteOff -> ByteOff
- :: ByteOff -> ByteOff -> ByteOff
$c- :: ByteOff -> ByteOff -> ByteOff
+ :: ByteOff -> ByteOff -> ByteOff
$c+ :: ByteOff -> ByteOff -> ByteOff
Num, Eq ByteOff
Eq ByteOff
-> (ByteOff -> ByteOff -> Ordering)
-> (ByteOff -> ByteOff -> Bool)
-> (ByteOff -> ByteOff -> Bool)
-> (ByteOff -> ByteOff -> Bool)
-> (ByteOff -> ByteOff -> Bool)
-> (ByteOff -> ByteOff -> ByteOff)
-> (ByteOff -> ByteOff -> ByteOff)
-> Ord ByteOff
ByteOff -> ByteOff -> Bool
ByteOff -> ByteOff -> Ordering
ByteOff -> ByteOff -> ByteOff
forall a.
Eq a
-> (a -> a -> Ordering)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> a)
-> (a -> a -> a)
-> Ord a
min :: ByteOff -> ByteOff -> ByteOff
$cmin :: ByteOff -> ByteOff -> ByteOff
max :: ByteOff -> ByteOff -> ByteOff
$cmax :: ByteOff -> ByteOff -> ByteOff
>= :: ByteOff -> ByteOff -> Bool
$c>= :: ByteOff -> ByteOff -> Bool
> :: ByteOff -> ByteOff -> Bool
$c> :: ByteOff -> ByteOff -> Bool
<= :: ByteOff -> ByteOff -> Bool
$c<= :: ByteOff -> ByteOff -> Bool
< :: ByteOff -> ByteOff -> Bool
$c< :: ByteOff -> ByteOff -> Bool
compare :: ByteOff -> ByteOff -> Ordering
$ccompare :: ByteOff -> ByteOff -> Ordering
$cp1Ord :: Eq ByteOff
Ord, Num ByteOff
Ord ByteOff
Num ByteOff -> Ord ByteOff -> (ByteOff -> Rational) -> Real ByteOff
ByteOff -> Rational
forall a. Num a -> Ord a -> (a -> Rational) -> Real a
toRational :: ByteOff -> Rational
$ctoRational :: ByteOff -> Rational
$cp2Real :: Ord ByteOff
$cp1Real :: Num ByteOff
Real)
newtype WordOff = WordOff Int
deriving (Int -> WordOff
WordOff -> Int
WordOff -> [WordOff]
WordOff -> WordOff
WordOff -> WordOff -> [WordOff]
WordOff -> WordOff -> WordOff -> [WordOff]
(WordOff -> WordOff)
-> (WordOff -> WordOff)
-> (Int -> WordOff)
-> (WordOff -> Int)
-> (WordOff -> [WordOff])
-> (WordOff -> WordOff -> [WordOff])
-> (WordOff -> WordOff -> [WordOff])
-> (WordOff -> WordOff -> WordOff -> [WordOff])
-> Enum WordOff
forall a.
(a -> a)
-> (a -> a)
-> (Int -> a)
-> (a -> Int)
-> (a -> [a])
-> (a -> a -> [a])
-> (a -> a -> [a])
-> (a -> a -> a -> [a])
-> Enum a
enumFromThenTo :: WordOff -> WordOff -> WordOff -> [WordOff]
$cenumFromThenTo :: WordOff -> WordOff -> WordOff -> [WordOff]
enumFromTo :: WordOff -> WordOff -> [WordOff]
$cenumFromTo :: WordOff -> WordOff -> [WordOff]
enumFromThen :: WordOff -> WordOff -> [WordOff]
$cenumFromThen :: WordOff -> WordOff -> [WordOff]
enumFrom :: WordOff -> [WordOff]
$cenumFrom :: WordOff -> [WordOff]
fromEnum :: WordOff -> Int
$cfromEnum :: WordOff -> Int
toEnum :: Int -> WordOff
$ctoEnum :: Int -> WordOff
pred :: WordOff -> WordOff
$cpred :: WordOff -> WordOff
succ :: WordOff -> WordOff
$csucc :: WordOff -> WordOff
Enum, WordOff -> WordOff -> Bool
(WordOff -> WordOff -> Bool)
-> (WordOff -> WordOff -> Bool) -> Eq WordOff
forall a. (a -> a -> Bool) -> (a -> a -> Bool) -> Eq a
/= :: WordOff -> WordOff -> Bool
$c/= :: WordOff -> WordOff -> Bool
== :: WordOff -> WordOff -> Bool
$c== :: WordOff -> WordOff -> Bool
Eq, Enum WordOff
Real WordOff
Real WordOff
-> Enum WordOff
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> (WordOff, WordOff))
-> (WordOff -> WordOff -> (WordOff, WordOff))
-> (WordOff -> Integer)
-> Integral WordOff
WordOff -> Integer
WordOff -> WordOff -> (WordOff, WordOff)
WordOff -> WordOff -> WordOff
forall a.
Real a
-> Enum a
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> (a, a))
-> (a -> a -> (a, a))
-> (a -> Integer)
-> Integral a
toInteger :: WordOff -> Integer
$ctoInteger :: WordOff -> Integer
divMod :: WordOff -> WordOff -> (WordOff, WordOff)
$cdivMod :: WordOff -> WordOff -> (WordOff, WordOff)
quotRem :: WordOff -> WordOff -> (WordOff, WordOff)
$cquotRem :: WordOff -> WordOff -> (WordOff, WordOff)
mod :: WordOff -> WordOff -> WordOff
$cmod :: WordOff -> WordOff -> WordOff
div :: WordOff -> WordOff -> WordOff
$cdiv :: WordOff -> WordOff -> WordOff
rem :: WordOff -> WordOff -> WordOff
$crem :: WordOff -> WordOff -> WordOff
quot :: WordOff -> WordOff -> WordOff
$cquot :: WordOff -> WordOff -> WordOff
$cp2Integral :: Enum WordOff
$cp1Integral :: Real WordOff
Integral, Integer -> WordOff
WordOff -> WordOff
WordOff -> WordOff -> WordOff
(WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff)
-> (WordOff -> WordOff)
-> (WordOff -> WordOff)
-> (Integer -> WordOff)
-> Num WordOff
forall a.
(a -> a -> a)
-> (a -> a -> a)
-> (a -> a -> a)
-> (a -> a)
-> (a -> a)
-> (a -> a)
-> (Integer -> a)
-> Num a
fromInteger :: Integer -> WordOff
$cfromInteger :: Integer -> WordOff
signum :: WordOff -> WordOff
$csignum :: WordOff -> WordOff
abs :: WordOff -> WordOff
$cabs :: WordOff -> WordOff
negate :: WordOff -> WordOff
$cnegate :: WordOff -> WordOff
* :: WordOff -> WordOff -> WordOff
$c* :: WordOff -> WordOff -> WordOff
- :: WordOff -> WordOff -> WordOff
$c- :: WordOff -> WordOff -> WordOff
+ :: WordOff -> WordOff -> WordOff
$c+ :: WordOff -> WordOff -> WordOff
Num, Eq WordOff
Eq WordOff
-> (WordOff -> WordOff -> Ordering)
-> (WordOff -> WordOff -> Bool)
-> (WordOff -> WordOff -> Bool)
-> (WordOff -> WordOff -> Bool)
-> (WordOff -> WordOff -> Bool)
-> (WordOff -> WordOff -> WordOff)
-> (WordOff -> WordOff -> WordOff)
-> Ord WordOff
WordOff -> WordOff -> Bool
WordOff -> WordOff -> Ordering
WordOff -> WordOff -> WordOff
forall a.
Eq a
-> (a -> a -> Ordering)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> a)
-> (a -> a -> a)
-> Ord a
min :: WordOff -> WordOff -> WordOff
$cmin :: WordOff -> WordOff -> WordOff
max :: WordOff -> WordOff -> WordOff
$cmax :: WordOff -> WordOff -> WordOff
>= :: WordOff -> WordOff -> Bool
$c>= :: WordOff -> WordOff -> Bool
> :: WordOff -> WordOff -> Bool
$c> :: WordOff -> WordOff -> Bool
<= :: WordOff -> WordOff -> Bool
$c<= :: WordOff -> WordOff -> Bool
< :: WordOff -> WordOff -> Bool
$c< :: WordOff -> WordOff -> Bool
compare :: WordOff -> WordOff -> Ordering
$ccompare :: WordOff -> WordOff -> Ordering
$cp1Ord :: Eq WordOff
Ord, Num WordOff
Ord WordOff
Num WordOff -> Ord WordOff -> (WordOff -> Rational) -> Real WordOff
WordOff -> Rational
forall a. Num a -> Ord a -> (a -> Rational) -> Real a
toRational :: WordOff -> Rational
$ctoRational :: WordOff -> Rational
$cp2Real :: Ord WordOff
$cp1Real :: Num WordOff
Real)
wordsToBytes :: DynFlags -> WordOff -> ByteOff
wordsToBytes :: DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags = Int -> ByteOff
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Int -> ByteOff) -> (WordOff -> Int) -> WordOff -> ByteOff
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (Int -> Int -> Int
forall a. Num a => a -> a -> a
* DynFlags -> Int
wORD_SIZE DynFlags
dflags) (Int -> Int) -> (WordOff -> Int) -> WordOff -> Int
forall b c a. (b -> c) -> (a -> b) -> a -> c
. WordOff -> Int
forall a b. (Integral a, Num b) => a -> b
fromIntegral
bytesToWords :: DynFlags -> ByteOff -> WordOff
bytesToWords :: DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff Int
bytes) =
let (Int
q, Int
r) = Int
bytes Int -> Int -> (Int, Int)
forall a. Integral a => a -> a -> (a, a)
`quotRem` (DynFlags -> Int
wORD_SIZE DynFlags
dflags)
in if Int
r Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0
then Int -> WordOff
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
q
else String -> WordOff
forall a. String -> a
panic (String -> WordOff) -> String -> WordOff
forall a b. (a -> b) -> a -> b
$ String
"ByteCodeGen.bytesToWords: bytes=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
bytes
wordSize :: DynFlags -> ByteOff
wordSize :: DynFlags -> ByteOff
wordSize DynFlags
dflags = Int -> ByteOff
ByteOff (DynFlags -> Int
wORD_SIZE DynFlags
dflags)
type Sequel = ByteOff
type StackDepth = ByteOff
type BCEnv = Map Id StackDepth
mkProtoBCO
:: DynFlags
-> name
-> BCInstrList
-> Either [AnnAlt Id DVarSet] (AnnExpr Id DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO name
mkProtoBCO :: DynFlags
-> name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO name
mkProtoBCO DynFlags
dflags name
nm BCInstrList
instrs_ordlist Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
origin Int
arity Word16
bitmap_size [StgWord]
bitmap Bool
is_ret [FFIInfo]
ffis
= ProtoBCO :: forall a.
a
-> [BCInstr]
-> [StgWord]
-> Word16
-> Int
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> [FFIInfo]
-> ProtoBCO a
ProtoBCO {
protoBCOName :: name
protoBCOName = name
nm,
protoBCOInstrs :: [BCInstr]
protoBCOInstrs = [BCInstr]
maybe_with_stack_check,
protoBCOBitmap :: [StgWord]
protoBCOBitmap = [StgWord]
bitmap,
protoBCOBitmapSize :: Word16
protoBCOBitmapSize = Word16
bitmap_size,
protoBCOArity :: Int
protoBCOArity = Int
arity,
protoBCOExpr :: Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
protoBCOExpr = Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
origin,
protoBCOFFIs :: [FFIInfo]
protoBCOFFIs = [FFIInfo]
ffis
}
where
maybe_with_stack_check :: [BCInstr]
maybe_with_stack_check
| Bool
is_ret Bool -> Bool -> Bool
&& Word
stack_usage Word -> Word -> Bool
forall a. Ord a => a -> a -> Bool
< Int -> Word
forall a b. (Integral a, Num b) => a -> b
fromIntegral (DynFlags -> Int
aP_STACK_SPLIM DynFlags
dflags) = [BCInstr]
peep_d
| Word
stack_usage Word -> Word -> Bool
forall a. Ord a => a -> a -> Bool
>= Int -> Word
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
iNTERP_STACK_CHECK_THRESH
= Word -> BCInstr
STKCHECK Word
stack_usage BCInstr -> [BCInstr] -> [BCInstr]
forall a. a -> [a] -> [a]
: [BCInstr]
peep_d
| Bool
otherwise
= [BCInstr]
peep_d
stack_usage :: Word
stack_usage = [Word] -> Word
forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
sum ((BCInstr -> Word) -> [BCInstr] -> [Word]
forall a b. (a -> b) -> [a] -> [b]
map BCInstr -> Word
bciStackUse [BCInstr]
peep_d)
peep_d :: [BCInstr]
peep_d = [BCInstr] -> [BCInstr]
peep (BCInstrList -> [BCInstr]
forall a. OrdList a -> [a]
fromOL BCInstrList
instrs_ordlist)
peep :: [BCInstr] -> [BCInstr]
peep (PUSH_L Word16
off1 : PUSH_L Word16
off2 : PUSH_L Word16
off3 : [BCInstr]
rest)
= Word16 -> Word16 -> Word16 -> BCInstr
PUSH_LLL Word16
off1 (Word16
off2Word16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
-Word16
1) (Word16
off3Word16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
-Word16
2) BCInstr -> [BCInstr] -> [BCInstr]
forall a. a -> [a] -> [a]
: [BCInstr] -> [BCInstr]
peep [BCInstr]
rest
peep (PUSH_L Word16
off1 : PUSH_L Word16
off2 : [BCInstr]
rest)
= Word16 -> Word16 -> BCInstr
PUSH_LL Word16
off1 (Word16
off2Word16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
-Word16
1) BCInstr -> [BCInstr] -> [BCInstr]
forall a. a -> [a] -> [a]
: [BCInstr] -> [BCInstr]
peep [BCInstr]
rest
peep (BCInstr
i:[BCInstr]
rest)
= BCInstr
i BCInstr -> [BCInstr] -> [BCInstr]
forall a. a -> [a] -> [a]
: [BCInstr] -> [BCInstr]
peep [BCInstr]
rest
peep []
= []
argBits :: DynFlags -> [ArgRep] -> [Bool]
argBits :: DynFlags -> [ArgRep] -> [Bool]
argBits DynFlags
_ [] = []
argBits DynFlags
dflags (ArgRep
rep : [ArgRep]
args)
| ArgRep -> Bool
isFollowableArg ArgRep
rep = Bool
False Bool -> [Bool] -> [Bool]
forall a. a -> [a] -> [a]
: DynFlags -> [ArgRep] -> [Bool]
argBits DynFlags
dflags [ArgRep]
args
| Bool
otherwise = Int -> [Bool] -> [Bool]
forall a. Int -> [a] -> [a]
take (DynFlags -> ArgRep -> Int
argRepSizeW DynFlags
dflags ArgRep
rep) (Bool -> [Bool]
forall a. a -> [a]
repeat Bool
True) [Bool] -> [Bool] -> [Bool]
forall a. [a] -> [a] -> [a]
++ DynFlags -> [ArgRep] -> [Bool]
argBits DynFlags
dflags [ArgRep]
args
schemeTopBind :: (Id, AnnExpr Id DVarSet) -> BcM (ProtoBCO Name)
schemeTopBind :: (CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name)
schemeTopBind (CoreBndr
id, AnnExpr CoreBndr DVarSet
rhs)
| Just DataCon
data_con <- CoreBndr -> Maybe DataCon
isDataConWorkId_maybe CoreBndr
id,
DataCon -> Bool
isNullaryRepDataCon DataCon
data_con = do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
([FFIInfo] -> ProtoBCO Name) -> BcM (ProtoBCO Name)
emitBc (DynFlags
-> Name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO Name
forall name.
DynFlags
-> name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO name
mkProtoBCO DynFlags
dflags (CoreBndr -> Name
forall a. NamedThing a => a -> Name
getName CoreBndr
id) ([BCInstr] -> BCInstrList
forall a. [a] -> OrdList a
toOL [DataCon -> Word16 -> BCInstr
PACK DataCon
data_con Word16
0, BCInstr
ENTER])
(AnnExpr CoreBndr DVarSet
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
forall a b. b -> Either a b
Right AnnExpr CoreBndr DVarSet
rhs) Int
0 Word16
0 [] Bool
False)
| Bool
otherwise
= [CoreBndr]
-> (CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name)
schemeR [] (CoreBndr
id, AnnExpr CoreBndr DVarSet
rhs)
schemeR :: [Id]
-> (Id, AnnExpr Id DVarSet)
-> BcM (ProtoBCO Name)
schemeR :: [CoreBndr]
-> (CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name)
schemeR [CoreBndr]
fvs (CoreBndr
nm, AnnExpr CoreBndr DVarSet
rhs)
= [CoreBndr]
-> CoreBndr
-> AnnExpr CoreBndr DVarSet
-> ([CoreBndr], AnnExpr' CoreBndr DVarSet)
-> BcM (ProtoBCO Name)
schemeR_wrk [CoreBndr]
fvs CoreBndr
nm AnnExpr CoreBndr DVarSet
rhs (AnnExpr CoreBndr DVarSet -> ([CoreBndr], AnnExpr' CoreBndr DVarSet)
collect AnnExpr CoreBndr DVarSet
rhs)
collect :: AnnExpr Id DVarSet -> ([Var], AnnExpr' Id DVarSet)
collect :: AnnExpr CoreBndr DVarSet -> ([CoreBndr], AnnExpr' CoreBndr DVarSet)
collect (DVarSet
_, AnnExpr' CoreBndr DVarSet
e) = [CoreBndr]
-> AnnExpr' CoreBndr DVarSet
-> ([CoreBndr], AnnExpr' CoreBndr DVarSet)
forall ann.
[CoreBndr]
-> AnnExpr' CoreBndr ann -> ([CoreBndr], AnnExpr' CoreBndr ann)
go [] AnnExpr' CoreBndr DVarSet
e
where
go :: [CoreBndr]
-> AnnExpr' CoreBndr ann -> ([CoreBndr], AnnExpr' CoreBndr ann)
go [CoreBndr]
xs AnnExpr' CoreBndr ann
e | Just AnnExpr' CoreBndr ann
e' <- AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall ann. AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView AnnExpr' CoreBndr ann
e = [CoreBndr]
-> AnnExpr' CoreBndr ann -> ([CoreBndr], AnnExpr' CoreBndr ann)
go [CoreBndr]
xs AnnExpr' CoreBndr ann
e'
go [CoreBndr]
xs (AnnLam CoreBndr
x (ann
_,AnnExpr' CoreBndr ann
e))
| HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
x) [PrimRep] -> Int -> Bool
forall a. [a] -> Int -> Bool
`lengthExceeds` Int
1
= ([CoreBndr], AnnExpr' CoreBndr ann)
forall a. a
multiValException
| Bool
otherwise
= [CoreBndr]
-> AnnExpr' CoreBndr ann -> ([CoreBndr], AnnExpr' CoreBndr ann)
go (CoreBndr
xCoreBndr -> [CoreBndr] -> [CoreBndr]
forall a. a -> [a] -> [a]
:[CoreBndr]
xs) AnnExpr' CoreBndr ann
e
go [CoreBndr]
xs AnnExpr' CoreBndr ann
not_lambda = ([CoreBndr] -> [CoreBndr]
forall a. [a] -> [a]
reverse [CoreBndr]
xs, AnnExpr' CoreBndr ann
not_lambda)
schemeR_wrk
:: [Id]
-> Id
-> AnnExpr Id DVarSet
-> ([Var], AnnExpr' Var DVarSet)
-> BcM (ProtoBCO Name)
schemeR_wrk :: [CoreBndr]
-> CoreBndr
-> AnnExpr CoreBndr DVarSet
-> ([CoreBndr], AnnExpr' CoreBndr DVarSet)
-> BcM (ProtoBCO Name)
schemeR_wrk [CoreBndr]
fvs CoreBndr
nm AnnExpr CoreBndr DVarSet
original_body ([CoreBndr]
args, AnnExpr' CoreBndr DVarSet
body)
= do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let
all_args :: [CoreBndr]
all_args = [CoreBndr] -> [CoreBndr]
forall a. [a] -> [a]
reverse [CoreBndr]
args [CoreBndr] -> [CoreBndr] -> [CoreBndr]
forall a. [a] -> [a] -> [a]
++ [CoreBndr]
fvs
arity :: Int
arity = [CoreBndr] -> Int
forall (t :: * -> *) a. Foldable t => t a -> Int
length [CoreBndr]
all_args
szsb_args :: [ByteOff]
szsb_args = (CoreBndr -> ByteOff) -> [CoreBndr] -> [ByteOff]
forall a b. (a -> b) -> [a] -> [b]
map (DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags (WordOff -> ByteOff)
-> (CoreBndr -> WordOff) -> CoreBndr -> ByteOff
forall b c a. (b -> c) -> (a -> b) -> a -> c
. DynFlags -> CoreBndr -> WordOff
idSizeW DynFlags
dflags) [CoreBndr]
all_args
sum_szsb_args :: ByteOff
sum_szsb_args = [ByteOff] -> ByteOff
forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
sum [ByteOff]
szsb_args
p_init :: Map CoreBndr ByteOff
p_init = [(CoreBndr, ByteOff)] -> Map CoreBndr ByteOff
forall k a. Ord k => [(k, a)] -> Map k a
Map.fromList ([CoreBndr] -> [ByteOff] -> [(CoreBndr, ByteOff)]
forall a b. [a] -> [b] -> [(a, b)]
zip [CoreBndr]
all_args (ByteOff -> [ByteOff] -> [ByteOff]
mkStackOffsets ByteOff
0 [ByteOff]
szsb_args))
bits :: [Bool]
bits = DynFlags -> [ArgRep] -> [Bool]
argBits DynFlags
dflags ([ArgRep] -> [ArgRep]
forall a. [a] -> [a]
reverse ((CoreBndr -> ArgRep) -> [CoreBndr] -> [ArgRep]
forall a b. (a -> b) -> [a] -> [b]
map CoreBndr -> ArgRep
bcIdArgRep [CoreBndr]
all_args))
bitmap_size :: Word16
bitmap_size = [Bool] -> Word16
forall i a. Num i => [a] -> i
genericLength [Bool]
bits
bitmap :: [StgWord]
bitmap = DynFlags -> [Bool] -> [StgWord]
mkBitmap DynFlags
dflags [Bool]
bits
BCInstrList
body_code <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeER_wrk ByteOff
sum_szsb_args Map CoreBndr ByteOff
p_init AnnExpr' CoreBndr DVarSet
body
([FFIInfo] -> ProtoBCO Name) -> BcM (ProtoBCO Name)
emitBc (DynFlags
-> Name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO Name
forall name.
DynFlags
-> name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO name
mkProtoBCO DynFlags
dflags (CoreBndr -> Name
forall a. NamedThing a => a -> Name
getName CoreBndr
nm) BCInstrList
body_code (AnnExpr CoreBndr DVarSet
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
forall a b. b -> Either a b
Right AnnExpr CoreBndr DVarSet
original_body)
Int
arity Word16
bitmap_size [StgWord]
bitmap Bool
False)
schemeER_wrk :: StackDepth -> BCEnv -> AnnExpr' Id DVarSet -> BcM BCInstrList
schemeER_wrk :: ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeER_wrk ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
rhs
| AnnTick (Breakpoint Int
tick_no [CoreBndr]
fvs) (DVarSet
_annot, AnnExpr' CoreBndr DVarSet
newRhs) <- AnnExpr' CoreBndr DVarSet
rhs
= do BCInstrList
code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
0 Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
newRhs
Array Int (RemotePtr CostCentre)
cc_arr <- BcM (Array Int (RemotePtr CostCentre))
getCCArray
ModuleName
this_mod <- Module -> ModuleName
moduleName (Module -> ModuleName) -> BcM Module -> BcM ModuleName
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
<$> BcM Module
getCurrentModule
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let idOffSets :: [Maybe (CoreBndr, Word16)]
idOffSets = DynFlags
-> ByteOff
-> Map CoreBndr ByteOff
-> [CoreBndr]
-> [Maybe (CoreBndr, Word16)]
getVarOffSets DynFlags
dflags ByteOff
d Map CoreBndr ByteOff
p [CoreBndr]
fvs
let breakInfo :: CgBreakInfo
breakInfo = CgBreakInfo :: [Maybe (CoreBndr, Word16)] -> Type -> CgBreakInfo
CgBreakInfo
{ cgb_vars :: [Maybe (CoreBndr, Word16)]
cgb_vars = [Maybe (CoreBndr, Word16)]
idOffSets
, cgb_resty :: Type
cgb_resty = Expr CoreBndr -> Type
exprType (AnnExpr' CoreBndr DVarSet -> Expr CoreBndr
forall bndr annot. AnnExpr' bndr annot -> Expr bndr
deAnnotate' AnnExpr' CoreBndr DVarSet
newRhs)
}
Int -> CgBreakInfo -> BcM ()
newBreakInfo Int
tick_no CgBreakInfo
breakInfo
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let cc :: RemotePtr CostCentre
cc | DynFlags -> Bool
interpreterProfiled DynFlags
dflags = Array Int (RemotePtr CostCentre)
cc_arr Array Int (RemotePtr CostCentre) -> Int -> RemotePtr CostCentre
forall i e. Ix i => Array i e -> i -> e
! Int
tick_no
| Bool
otherwise = Ptr CostCentre -> RemotePtr CostCentre
forall a. Ptr a -> RemotePtr a
toRemotePtr Ptr CostCentre
forall a. Ptr a
nullPtr
let breakInstr :: BCInstr
breakInstr = Word16 -> Unique -> RemotePtr CostCentre -> BCInstr
BRK_FUN (Int -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
tick_no) (ModuleName -> Unique
forall a. Uniquable a => a -> Unique
getUnique ModuleName
this_mod) RemotePtr CostCentre
cc
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList -> BcM BCInstrList) -> BCInstrList -> BcM BCInstrList
forall a b. (a -> b) -> a -> b
$ BCInstr
breakInstr BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` BCInstrList
code
| Bool
otherwise = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
0 Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
rhs
getVarOffSets :: DynFlags -> StackDepth -> BCEnv -> [Id] -> [Maybe (Id, Word16)]
getVarOffSets :: DynFlags
-> ByteOff
-> Map CoreBndr ByteOff
-> [CoreBndr]
-> [Maybe (CoreBndr, Word16)]
getVarOffSets DynFlags
dflags ByteOff
depth Map CoreBndr ByteOff
env = (CoreBndr -> Maybe (CoreBndr, Word16))
-> [CoreBndr] -> [Maybe (CoreBndr, Word16)]
forall a b. (a -> b) -> [a] -> [b]
map CoreBndr -> Maybe (CoreBndr, Word16)
getOffSet
where
getOffSet :: CoreBndr -> Maybe (CoreBndr, Word16)
getOffSet CoreBndr
id = case CoreBndr -> Map CoreBndr ByteOff -> Maybe ByteOff
lookupBCEnv_maybe CoreBndr
id Map CoreBndr ByteOff
env of
Maybe ByteOff
Nothing -> Maybe (CoreBndr, Word16)
forall a. Maybe a
Nothing
Just ByteOff
offset ->
let !var_depth_ws :: Word16
var_depth_ws =
WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
depth ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
offset) WordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
+ WordOff
2
in (CoreBndr, Word16) -> Maybe (CoreBndr, Word16)
forall a. a -> Maybe a
Just (CoreBndr
id, Word16
var_depth_ws)
truncIntegral16 :: Integral a => a -> Word16
truncIntegral16 :: a -> Word16
truncIntegral16 a
w
| a
w a -> a -> Bool
forall a. Ord a => a -> a -> Bool
> Word16 -> a
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Word16
forall a. Bounded a => a
maxBound :: Word16)
= String -> Word16
forall a. String -> a
panic String
"stack depth overflow"
| Bool
otherwise
= a -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral a
w
trunc16B :: ByteOff -> Word16
trunc16B :: ByteOff -> Word16
trunc16B = ByteOff -> Word16
forall a. Integral a => a -> Word16
truncIntegral16
trunc16W :: WordOff -> Word16
trunc16W :: WordOff -> Word16
trunc16W = WordOff -> Word16
forall a. Integral a => a -> Word16
truncIntegral16
fvsToEnv :: BCEnv -> DVarSet -> [Id]
fvsToEnv :: Map CoreBndr ByteOff -> DVarSet -> [CoreBndr]
fvsToEnv Map CoreBndr ByteOff
p DVarSet
fvs = [CoreBndr
v | CoreBndr
v <- DVarSet -> [CoreBndr]
dVarSetElems DVarSet
fvs,
CoreBndr -> Bool
isId CoreBndr
v,
CoreBndr
v CoreBndr -> Map CoreBndr ByteOff -> Bool
forall k a. Ord k => k -> Map k a -> Bool
`Map.member` Map CoreBndr ByteOff
p]
returnUnboxedAtom
:: StackDepth
-> Sequel
-> BCEnv
-> AnnExpr' Id DVarSet
-> ArgRep
-> BcM BCInstrList
returnUnboxedAtom :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> ArgRep
-> BcM BCInstrList
returnUnboxedAtom ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e ArgRep
e_rep = do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
(BCInstrList
push, ByteOff
szb) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` DynFlags -> ByteOff -> ByteOff -> BCInstrList
mkSlideB DynFlags
dflags ByteOff
szb (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s)
BCInstrList -> BCInstr -> BCInstrList
forall a. OrdList a -> a -> OrdList a
`snocOL` ArgRep -> BCInstr
RETURN_UBX ArgRep
e_rep)
schemeE
:: StackDepth -> Sequel -> BCEnv -> AnnExpr' Id DVarSet -> BcM BCInstrList
schemeE :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e
| Just AnnExpr' CoreBndr DVarSet
e' <- AnnExpr' CoreBndr DVarSet -> Maybe (AnnExpr' CoreBndr DVarSet)
forall ann. AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView AnnExpr' CoreBndr DVarSet
e
= ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e'
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p e :: AnnExpr' CoreBndr DVarSet
e@(AnnApp AnnExpr CoreBndr DVarSet
_ AnnExpr CoreBndr DVarSet
_) = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeT ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p e :: AnnExpr' CoreBndr DVarSet
e@(AnnLit Literal
lit) = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> ArgRep
-> BcM BCInstrList
returnUnboxedAtom ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e (Type -> ArgRep
typeArgRep (Literal -> Type
literalType Literal
lit))
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p e :: AnnExpr' CoreBndr DVarSet
e@(AnnCoercion {}) = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> ArgRep
-> BcM BCInstrList
returnUnboxedAtom ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e ArgRep
V
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p e :: AnnExpr' CoreBndr DVarSet
e@(AnnVar CoreBndr
v)
| CoreBndr -> Bool
isNNLJoinPoint CoreBndr
v = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> CoreBndr
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
doTailCall ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (CoreBndr -> CoreBndr
protectNNLJoinPointId CoreBndr
v) [CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
voidPrimId]
| HasDebugCallStack => Type -> Bool
Type -> Bool
isUnliftedType (CoreBndr -> Type
idType CoreBndr
v) = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> ArgRep
-> BcM BCInstrList
returnUnboxedAtom ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e (CoreBndr -> ArgRep
bcIdArgRep CoreBndr
v)
| Bool
otherwise = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeT ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnLet (AnnNonRec CoreBndr
x (DVarSet
_,AnnExpr' CoreBndr DVarSet
rhs)) (DVarSet
_,AnnExpr' CoreBndr DVarSet
body))
| (AnnVar CoreBndr
v, [AnnExpr' CoreBndr DVarSet]
args_r_to_l) <- AnnExpr' CoreBndr DVarSet
-> (AnnExpr' CoreBndr DVarSet, [AnnExpr' CoreBndr DVarSet])
forall ann.
AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
splitApp AnnExpr' CoreBndr DVarSet
rhs,
Just DataCon
data_con <- CoreBndr -> Maybe DataCon
isDataConWorkId_maybe CoreBndr
v,
DataCon -> Int
dataConRepArity DataCon
data_con Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== [AnnExpr' CoreBndr DVarSet] -> Int
forall (t :: * -> *) a. Foldable t => t a -> Int
length [AnnExpr' CoreBndr DVarSet]
args_r_to_l
= do
BCInstrList
alloc_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> DataCon
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
mkConAppCode ByteOff
d ByteOff
s Map CoreBndr ByteOff
p DataCon
data_con [AnnExpr' CoreBndr DVarSet]
args_r_to_l
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let !d2 :: ByteOff
d2 = ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> ByteOff
wordSize DynFlags
dflags
BCInstrList
body_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d2 ByteOff
s (CoreBndr -> ByteOff -> Map CoreBndr ByteOff -> Map CoreBndr ByteOff
forall k a. Ord k => k -> a -> Map k a -> Map k a
Map.insert CoreBndr
x ByteOff
d2 Map CoreBndr ByteOff
p) AnnExpr' CoreBndr DVarSet
body
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
alloc_code BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
body_code)
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnLet AnnBind CoreBndr DVarSet
binds (DVarSet
_,AnnExpr' CoreBndr DVarSet
body)) = do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let ([CoreBndr]
xs,[AnnExpr CoreBndr DVarSet]
rhss) = case AnnBind CoreBndr DVarSet
binds of AnnNonRec CoreBndr
x AnnExpr CoreBndr DVarSet
rhs -> ([CoreBndr
x],[AnnExpr CoreBndr DVarSet
rhs])
AnnRec [(CoreBndr, AnnExpr CoreBndr DVarSet)]
xs_n_rhss -> [(CoreBndr, AnnExpr CoreBndr DVarSet)]
-> ([CoreBndr], [AnnExpr CoreBndr DVarSet])
forall a b. [(a, b)] -> ([a], [b])
unzip [(CoreBndr, AnnExpr CoreBndr DVarSet)]
xs_n_rhss
n_binds :: WordOff
n_binds = [CoreBndr] -> WordOff
forall i a. Num i => [a] -> i
genericLength [CoreBndr]
xs
fvss :: [[CoreBndr]]
fvss = (AnnExpr CoreBndr DVarSet -> [CoreBndr])
-> [AnnExpr CoreBndr DVarSet] -> [[CoreBndr]]
forall a b. (a -> b) -> [a] -> [b]
map (Map CoreBndr ByteOff -> DVarSet -> [CoreBndr]
fvsToEnv Map CoreBndr ByteOff
p' (DVarSet -> [CoreBndr])
-> (AnnExpr CoreBndr DVarSet -> DVarSet)
-> AnnExpr CoreBndr DVarSet
-> [CoreBndr]
forall b c a. (b -> c) -> (a -> b) -> a -> c
. AnnExpr CoreBndr DVarSet -> DVarSet
forall a b. (a, b) -> a
fst) [AnnExpr CoreBndr DVarSet]
rhss
([CoreBndr]
xs',[AnnExpr CoreBndr DVarSet]
rhss') = (CoreBndr
-> AnnExpr CoreBndr DVarSet
-> (CoreBndr, AnnExpr CoreBndr DVarSet))
-> [CoreBndr]
-> [AnnExpr CoreBndr DVarSet]
-> ([CoreBndr], [AnnExpr CoreBndr DVarSet])
forall a b c d. (a -> b -> (c, d)) -> [a] -> [b] -> ([c], [d])
zipWithAndUnzip CoreBndr
-> AnnExpr CoreBndr DVarSet -> (CoreBndr, AnnExpr CoreBndr DVarSet)
protectNNLJoinPointBind [CoreBndr]
xs [AnnExpr CoreBndr DVarSet]
rhss
size_w :: CoreBndr -> Word16
size_w = WordOff -> Word16
trunc16W (WordOff -> Word16) -> (CoreBndr -> WordOff) -> CoreBndr -> Word16
forall b c a. (b -> c) -> (a -> b) -> a -> c
. DynFlags -> CoreBndr -> WordOff
idSizeW DynFlags
dflags
sizes :: [Word16]
sizes = ([CoreBndr] -> Word16) -> [[CoreBndr]] -> [Word16]
forall a b. (a -> b) -> [a] -> [b]
map (\[CoreBndr]
rhs_fvs -> [Word16] -> Word16
forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
sum ((CoreBndr -> Word16) -> [CoreBndr] -> [Word16]
forall a b. (a -> b) -> [a] -> [b]
map CoreBndr -> Word16
size_w [CoreBndr]
rhs_fvs)) [[CoreBndr]]
fvss
arities :: [Word16]
arities = (AnnExpr CoreBndr DVarSet -> Word16)
-> [AnnExpr CoreBndr DVarSet] -> [Word16]
forall a b. (a -> b) -> [a] -> [b]
map ([CoreBndr] -> Word16
forall i a. Num i => [a] -> i
genericLength ([CoreBndr] -> Word16)
-> (AnnExpr CoreBndr DVarSet -> [CoreBndr])
-> AnnExpr CoreBndr DVarSet
-> Word16
forall b c a. (b -> c) -> (a -> b) -> a -> c
. ([CoreBndr], AnnExpr' CoreBndr DVarSet) -> [CoreBndr]
forall a b. (a, b) -> a
fst (([CoreBndr], AnnExpr' CoreBndr DVarSet) -> [CoreBndr])
-> (AnnExpr CoreBndr DVarSet
-> ([CoreBndr], AnnExpr' CoreBndr DVarSet))
-> AnnExpr CoreBndr DVarSet
-> [CoreBndr]
forall b c a. (b -> c) -> (a -> b) -> a -> c
. AnnExpr CoreBndr DVarSet -> ([CoreBndr], AnnExpr' CoreBndr DVarSet)
collect) [AnnExpr CoreBndr DVarSet]
rhss'
offsets :: [ByteOff]
offsets = ByteOff -> [ByteOff] -> [ByteOff]
mkStackOffsets ByteOff
d (WordOff -> ByteOff -> [ByteOff]
forall i a. Integral i => i -> a -> [a]
genericReplicate WordOff
n_binds (DynFlags -> ByteOff
wordSize DynFlags
dflags))
p' :: Map CoreBndr ByteOff
p' = [(CoreBndr, ByteOff)]
-> Map CoreBndr ByteOff -> Map CoreBndr ByteOff
forall key elt.
Ord key =>
[(key, elt)] -> Map key elt -> Map key elt
Map.insertList ([CoreBndr] -> [ByteOff] -> [(CoreBndr, ByteOff)]
forall a b. [a] -> [b] -> [(a, b)]
zipE [CoreBndr]
xs' [ByteOff]
offsets) Map CoreBndr ByteOff
p
d' :: ByteOff
d' = ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags WordOff
n_binds
zipE :: [a] -> [b] -> [(a, b)]
zipE = String -> [a] -> [b] -> [(a, b)]
forall a b. String -> [a] -> [b] -> [(a, b)]
zipEqual String
"schemeE"
build_thunk
:: StackDepth
-> [Id]
-> Word16
-> ProtoBCO Name
-> Word16
-> Word16
-> BcM BCInstrList
build_thunk :: ByteOff
-> [CoreBndr]
-> Word16
-> ProtoBCO Name
-> Word16
-> Word16
-> BcM BCInstrList
build_thunk ByteOff
_ [] Word16
size ProtoBCO Name
bco Word16
off Word16
arity
= BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (ProtoBCO Name -> BCInstr
PUSH_BCO ProtoBCO Name
bco BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Word16 -> Word16 -> BCInstr
mkap (Word16
offWord16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
+Word16
size) Word16
size))
where
mkap :: Word16 -> Word16 -> BCInstr
mkap | Word16
arity Word16 -> Word16 -> Bool
forall a. Eq a => a -> a -> Bool
== Word16
0 = Word16 -> Word16 -> BCInstr
MKAP
| Bool
otherwise = Word16 -> Word16 -> BCInstr
MKPAP
build_thunk ByteOff
dd (CoreBndr
fv:[CoreBndr]
fvs) Word16
size ProtoBCO Name
bco Word16
off Word16
arity = do
(BCInstrList
push_code, ByteOff
pushed_szb) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
dd Map CoreBndr ByteOff
p' (CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
fv)
BCInstrList
more_push_code <-
ByteOff
-> [CoreBndr]
-> Word16
-> ProtoBCO Name
-> Word16
-> Word16
-> BcM BCInstrList
build_thunk (ByteOff
dd ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
pushed_szb) [CoreBndr]
fvs Word16
size ProtoBCO Name
bco Word16
off Word16
arity
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push_code BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
more_push_code)
alloc_code :: BCInstrList
alloc_code = [BCInstr] -> BCInstrList
forall a. [a] -> OrdList a
toOL ((Word16 -> Word16 -> BCInstr) -> [Word16] -> [Word16] -> [BCInstr]
forall a b c. (a -> b -> c) -> [a] -> [b] -> [c]
zipWith Word16 -> Word16 -> BCInstr
mkAlloc [Word16]
sizes [Word16]
arities)
where mkAlloc :: Word16 -> Word16 -> BCInstr
mkAlloc Word16
sz Word16
0
| Bool
is_tick = Word16 -> BCInstr
ALLOC_AP_NOUPD Word16
sz
| Bool
otherwise = Word16 -> BCInstr
ALLOC_AP Word16
sz
mkAlloc Word16
sz Word16
arity = Word16 -> Word16 -> BCInstr
ALLOC_PAP Word16
arity Word16
sz
is_tick :: Bool
is_tick = case AnnBind CoreBndr DVarSet
binds of
AnnNonRec CoreBndr
id AnnExpr CoreBndr DVarSet
_ -> OccName -> FastString
occNameFS (CoreBndr -> OccName
forall a. NamedThing a => a -> OccName
getOccName CoreBndr
id) FastString -> FastString -> Bool
forall a. Eq a => a -> a -> Bool
== FastString
tickFS
AnnBind CoreBndr DVarSet
_other -> Bool
False
compile_bind :: ByteOff
-> [CoreBndr]
-> CoreBndr
-> AnnExpr CoreBndr DVarSet
-> Word16
-> Word16
-> Word16
-> BcM BCInstrList
compile_bind ByteOff
d' [CoreBndr]
fvs CoreBndr
x AnnExpr CoreBndr DVarSet
rhs Word16
size Word16
arity Word16
off = do
ProtoBCO Name
bco <- [CoreBndr]
-> (CoreBndr, AnnExpr CoreBndr DVarSet) -> BcM (ProtoBCO Name)
schemeR [CoreBndr]
fvs (CoreBndr
x,AnnExpr CoreBndr DVarSet
rhs)
ByteOff
-> [CoreBndr]
-> Word16
-> ProtoBCO Name
-> Word16
-> Word16
-> BcM BCInstrList
build_thunk ByteOff
d' [CoreBndr]
fvs Word16
size ProtoBCO Name
bco Word16
off Word16
arity
compile_binds :: [BcM BCInstrList]
compile_binds =
[ ByteOff
-> [CoreBndr]
-> CoreBndr
-> AnnExpr CoreBndr DVarSet
-> Word16
-> Word16
-> Word16
-> BcM BCInstrList
compile_bind ByteOff
d' [CoreBndr]
fvs CoreBndr
x AnnExpr CoreBndr DVarSet
rhs Word16
size Word16
arity (WordOff -> Word16
trunc16W WordOff
n)
| ([CoreBndr]
fvs, CoreBndr
x, AnnExpr CoreBndr DVarSet
rhs, Word16
size, Word16
arity, WordOff
n) <-
[[CoreBndr]]
-> [CoreBndr]
-> [AnnExpr CoreBndr DVarSet]
-> [Word16]
-> [Word16]
-> [WordOff]
-> [([CoreBndr], CoreBndr, AnnExpr CoreBndr DVarSet, Word16,
Word16, WordOff)]
forall a b c d e f.
[a] -> [b] -> [c] -> [d] -> [e] -> [f] -> [(a, b, c, d, e, f)]
zip6 [[CoreBndr]]
fvss [CoreBndr]
xs' [AnnExpr CoreBndr DVarSet]
rhss' [Word16]
sizes [Word16]
arities [WordOff
n_binds, WordOff
n_bindsWordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
-WordOff
1 .. WordOff
1]
]
BCInstrList
body_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d' ByteOff
s Map CoreBndr ByteOff
p' AnnExpr' CoreBndr DVarSet
body
[BCInstrList]
thunk_codes <- [BcM BCInstrList] -> BcM [BCInstrList]
forall (t :: * -> *) (m :: * -> *) a.
(Traversable t, Monad m) =>
t (m a) -> m (t a)
sequence [BcM BCInstrList]
compile_binds
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
alloc_code BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` [BCInstrList] -> BCInstrList
forall a. [OrdList a] -> OrdList a
concatOL [BCInstrList]
thunk_codes BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
body_code)
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p exp :: AnnExpr' CoreBndr DVarSet
exp@(AnnTick (Breakpoint Int
_id [CoreBndr]
_fvs) AnnExpr CoreBndr DVarSet
_rhs)
| Type -> Bool
isLiftedTypeKind (HasDebugCallStack => Type -> Type
Type -> Type
typeKind Type
ty)
= do CoreBndr
id <- Type -> BcM CoreBndr
newId Type
ty
let letExp :: AnnExpr' CoreBndr DVarSet
letExp = AnnBind CoreBndr DVarSet
-> AnnExpr CoreBndr DVarSet -> AnnExpr' CoreBndr DVarSet
forall bndr annot.
AnnBind bndr annot -> AnnExpr bndr annot -> AnnExpr' bndr annot
AnnLet (CoreBndr -> AnnExpr CoreBndr DVarSet -> AnnBind CoreBndr DVarSet
forall bndr annot. bndr -> AnnExpr bndr annot -> AnnBind bndr annot
AnnNonRec CoreBndr
id (DVarSet
fvs, AnnExpr' CoreBndr DVarSet
exp)) (DVarSet
emptyDVarSet, CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
id)
ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
letExp
| Bool
otherwise
= do
CoreBndr
id <- Type -> BcM CoreBndr
newId (Type -> Type -> Type
mkVisFunTy Type
realWorldStatePrimTy Type
ty)
CoreBndr
st <- Type -> BcM CoreBndr
newId Type
realWorldStatePrimTy
let letExp :: AnnExpr' CoreBndr DVarSet
letExp = AnnBind CoreBndr DVarSet
-> AnnExpr CoreBndr DVarSet -> AnnExpr' CoreBndr DVarSet
forall bndr annot.
AnnBind bndr annot -> AnnExpr bndr annot -> AnnExpr' bndr annot
AnnLet (CoreBndr -> AnnExpr CoreBndr DVarSet -> AnnBind CoreBndr DVarSet
forall bndr annot. bndr -> AnnExpr bndr annot -> AnnBind bndr annot
AnnNonRec CoreBndr
id (DVarSet
fvs, CoreBndr -> AnnExpr CoreBndr DVarSet -> AnnExpr' CoreBndr DVarSet
forall bndr annot.
bndr -> AnnExpr bndr annot -> AnnExpr' bndr annot
AnnLam CoreBndr
st (DVarSet
emptyDVarSet, AnnExpr' CoreBndr DVarSet
exp)))
(DVarSet
emptyDVarSet, (AnnExpr CoreBndr DVarSet
-> AnnExpr CoreBndr DVarSet -> AnnExpr' CoreBndr DVarSet
forall bndr annot.
AnnExpr bndr annot -> AnnExpr bndr annot -> AnnExpr' bndr annot
AnnApp (DVarSet
emptyDVarSet, CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
id)
(DVarSet
emptyDVarSet, CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
realWorldPrimId)))
ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
letExp
where
exp' :: Expr CoreBndr
exp' = AnnExpr' CoreBndr DVarSet -> Expr CoreBndr
forall bndr annot. AnnExpr' bndr annot -> Expr bndr
deAnnotate' AnnExpr' CoreBndr DVarSet
exp
fvs :: DVarSet
fvs = Expr CoreBndr -> DVarSet
exprFreeVarsDSet Expr CoreBndr
exp'
ty :: Type
ty = Expr CoreBndr -> Type
exprType Expr CoreBndr
exp'
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnTick Tickish CoreBndr
_ (DVarSet
_, AnnExpr' CoreBndr DVarSet
rhs)) = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
rhs
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnCase (DVarSet
_,AnnExpr' CoreBndr DVarSet
scrut) CoreBndr
_ Type
_ []) = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
scrut
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnCase AnnExpr CoreBndr DVarSet
scrut CoreBndr
bndr Type
_ [(DataAlt DataCon
dc, [CoreBndr
bind1, CoreBndr
bind2], AnnExpr CoreBndr DVarSet
rhs)])
| DataCon -> Bool
isUnboxedTupleCon DataCon
dc
, Just BcM BCInstrList
res <- case (HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
bind1), HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
bind2)) of
([], [PrimRep
_])
-> BcM BCInstrList -> Maybe (BcM BCInstrList)
forall a. a -> Maybe a
Just (BcM BCInstrList -> Maybe (BcM BCInstrList))
-> BcM BCInstrList -> Maybe (BcM BCInstrList)
forall a b. (a -> b) -> a -> b
$ ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr CoreBndr DVarSet
-> CoreBndr
-> [AnnAlt CoreBndr DVarSet]
-> Maybe CoreBndr
-> BcM BCInstrList
doCase ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr CoreBndr DVarSet
scrut CoreBndr
bind2 [(AltCon
DEFAULT, [], AnnExpr CoreBndr DVarSet
rhs)] (CoreBndr -> Maybe CoreBndr
forall a. a -> Maybe a
Just CoreBndr
bndr)
([PrimRep
_], [])
-> BcM BCInstrList -> Maybe (BcM BCInstrList)
forall a. a -> Maybe a
Just (BcM BCInstrList -> Maybe (BcM BCInstrList))
-> BcM BCInstrList -> Maybe (BcM BCInstrList)
forall a b. (a -> b) -> a -> b
$ ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr CoreBndr DVarSet
-> CoreBndr
-> [AnnAlt CoreBndr DVarSet]
-> Maybe CoreBndr
-> BcM BCInstrList
doCase ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr CoreBndr DVarSet
scrut CoreBndr
bind1 [(AltCon
DEFAULT, [], AnnExpr CoreBndr DVarSet
rhs)] (CoreBndr -> Maybe CoreBndr
forall a. a -> Maybe a
Just CoreBndr
bndr)
([PrimRep], [PrimRep])
_ -> Maybe (BcM BCInstrList)
forall a. Maybe a
Nothing
= BcM BCInstrList
res
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnCase AnnExpr CoreBndr DVarSet
scrut CoreBndr
bndr Type
_ [(DataAlt DataCon
dc, [CoreBndr
bind1], AnnExpr CoreBndr DVarSet
rhs)])
| DataCon -> Bool
isUnboxedTupleCon DataCon
dc
, HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
bndr) [PrimRep] -> Int -> Bool
forall a. [a] -> Int -> Bool
`lengthAtMost` Int
1
= ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr CoreBndr DVarSet
-> CoreBndr
-> [AnnAlt CoreBndr DVarSet]
-> Maybe CoreBndr
-> BcM BCInstrList
doCase ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr CoreBndr DVarSet
scrut CoreBndr
bind1 [(AltCon
DEFAULT, [], AnnExpr CoreBndr DVarSet
rhs)] (CoreBndr -> Maybe CoreBndr
forall a. a -> Maybe a
Just CoreBndr
bndr)
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnCase AnnExpr CoreBndr DVarSet
scrut CoreBndr
bndr Type
_ alt :: [AnnAlt CoreBndr DVarSet]
alt@[(AltCon
DEFAULT, [], AnnExpr CoreBndr DVarSet
_)])
| Type -> Bool
isUnboxedTupleType (CoreBndr -> Type
idType CoreBndr
bndr)
, Just Type
ty <- case HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
bndr) of
[PrimRep
_] -> Type -> Maybe Type
forall a. a -> Maybe a
Just (Type -> Type
unwrapType (CoreBndr -> Type
idType CoreBndr
bndr))
[] -> Type -> Maybe Type
forall a. a -> Maybe a
Just Type
voidPrimTy
[PrimRep]
_ -> Maybe Type
forall a. Maybe a
Nothing
= ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr CoreBndr DVarSet
-> CoreBndr
-> [AnnAlt CoreBndr DVarSet]
-> Maybe CoreBndr
-> BcM BCInstrList
doCase ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr CoreBndr DVarSet
scrut (CoreBndr
bndr CoreBndr -> Type -> CoreBndr
`setIdType` Type
ty) [AnnAlt CoreBndr DVarSet]
alt (CoreBndr -> Maybe CoreBndr
forall a. a -> Maybe a
Just CoreBndr
bndr)
schemeE ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (AnnCase AnnExpr CoreBndr DVarSet
scrut CoreBndr
bndr Type
_ [AnnAlt CoreBndr DVarSet]
alts)
= ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr CoreBndr DVarSet
-> CoreBndr
-> [AnnAlt CoreBndr DVarSet]
-> Maybe CoreBndr
-> BcM BCInstrList
doCase ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr CoreBndr DVarSet
scrut CoreBndr
bndr [AnnAlt CoreBndr DVarSet]
alts Maybe CoreBndr
forall a. Maybe a
Nothing
schemeE ByteOff
_ ByteOff
_ Map CoreBndr ByteOff
_ AnnExpr' CoreBndr DVarSet
expr
= String -> SDoc -> BcM BCInstrList
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"ByteCodeGen.schemeE: unhandled case"
(Expr CoreBndr -> SDoc
forall b. OutputableBndr b => Expr b -> SDoc
pprCoreExpr (AnnExpr' CoreBndr DVarSet -> Expr CoreBndr
forall bndr annot. AnnExpr' bndr annot -> Expr bndr
deAnnotate' AnnExpr' CoreBndr DVarSet
expr))
isNNLJoinPoint :: Id -> Bool
isNNLJoinPoint :: CoreBndr -> Bool
isNNLJoinPoint CoreBndr
x = CoreBndr -> Bool
isJoinId CoreBndr
x Bool -> Bool -> Bool
&&
Bool -> Maybe Bool
forall a. a -> Maybe a
Just Bool
True Maybe Bool -> Maybe Bool -> Bool
forall a. Eq a => a -> a -> Bool
/= HasDebugCallStack => Type -> Maybe Bool
Type -> Maybe Bool
isLiftedType_maybe (CoreBndr -> Type
idType CoreBndr
x)
protectNNLJoinPointBind :: Id -> AnnExpr Id DVarSet -> (Id, AnnExpr Id DVarSet)
protectNNLJoinPointBind :: CoreBndr
-> AnnExpr CoreBndr DVarSet -> (CoreBndr, AnnExpr CoreBndr DVarSet)
protectNNLJoinPointBind CoreBndr
x rhs :: AnnExpr CoreBndr DVarSet
rhs@(DVarSet
fvs, AnnExpr' CoreBndr DVarSet
_)
| CoreBndr -> Bool
isNNLJoinPoint CoreBndr
x
= (CoreBndr -> CoreBndr
protectNNLJoinPointId CoreBndr
x, (DVarSet
fvs, CoreBndr -> AnnExpr CoreBndr DVarSet -> AnnExpr' CoreBndr DVarSet
forall bndr annot.
bndr -> AnnExpr bndr annot -> AnnExpr' bndr annot
AnnLam CoreBndr
voidArgId AnnExpr CoreBndr DVarSet
rhs))
| Bool
otherwise
= (CoreBndr
x, AnnExpr CoreBndr DVarSet
rhs)
protectNNLJoinPointId :: Id -> Id
protectNNLJoinPointId :: CoreBndr -> CoreBndr
protectNNLJoinPointId CoreBndr
x
= ASSERT( isNNLJoinPoint x )
(Type -> Type) -> CoreBndr -> CoreBndr
updateVarType (Type
voidPrimTy Type -> Type -> Type
`mkVisFunTy`) CoreBndr
x
schemeT :: StackDepth
-> Sequel
-> BCEnv
-> AnnExpr' Id DVarSet
-> BcM BCInstrList
schemeT :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeT ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
app
| Just (AnnExpr' CoreBndr DVarSet
arg, [Name]
constr_names) <- AnnExpr' CoreBndr DVarSet
-> Maybe (AnnExpr' CoreBndr DVarSet, [Name])
maybe_is_tagToEnum_call AnnExpr' CoreBndr DVarSet
app
= ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> [Name]
-> BcM BCInstrList
implement_tagToId ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg [Name]
constr_names
| Just (CCall CCallSpec
ccall_spec) <- CoreBndr -> Maybe ForeignCall
isFCallId_maybe CoreBndr
fn
= if CCallSpec -> Bool
isSupportedCConv CCallSpec
ccall_spec
then ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> CCallSpec
-> CoreBndr
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
generateCCall ByteOff
d ByteOff
s Map CoreBndr ByteOff
p CCallSpec
ccall_spec CoreBndr
fn [AnnExpr' CoreBndr DVarSet]
args_r_to_l
else BcM BCInstrList
forall a. a
unsupportedCConvException
| Just DataCon
con <- Maybe DataCon
maybe_saturated_dcon
, DataCon -> Bool
isUnboxedTupleCon DataCon
con
= case [AnnExpr' CoreBndr DVarSet]
args_r_to_l of
[AnnExpr' CoreBndr DVarSet
arg1,AnnExpr' CoreBndr DVarSet
arg2] | AnnExpr' CoreBndr DVarSet -> Bool
forall ann. AnnExpr' CoreBndr ann -> Bool
isVAtom AnnExpr' CoreBndr DVarSet
arg1 ->
ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
unboxedTupleReturn ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg2
[AnnExpr' CoreBndr DVarSet
arg1,AnnExpr' CoreBndr DVarSet
arg2] | AnnExpr' CoreBndr DVarSet -> Bool
forall ann. AnnExpr' CoreBndr ann -> Bool
isVAtom AnnExpr' CoreBndr DVarSet
arg2 ->
ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
unboxedTupleReturn ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg1
[AnnExpr' CoreBndr DVarSet]
_other -> BcM BCInstrList
forall a. a
multiValException
| Just DataCon
con <- Maybe DataCon
maybe_saturated_dcon
= do BCInstrList
alloc_con <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> DataCon
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
mkConAppCode ByteOff
d ByteOff
s Map CoreBndr ByteOff
p DataCon
con [AnnExpr' CoreBndr DVarSet]
args_r_to_l
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
alloc_con BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL`
Word16 -> WordOff -> BCInstrList
mkSlideW Word16
1 (DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff -> WordOff) -> ByteOff -> WordOff
forall a b. (a -> b) -> a -> b
$ ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s) BCInstrList -> BCInstr -> BCInstrList
forall a. OrdList a -> a -> OrdList a
`snocOL`
BCInstr
ENTER)
| Bool
otherwise
= ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> CoreBndr
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
doTailCall ByteOff
d ByteOff
s Map CoreBndr ByteOff
p CoreBndr
fn [AnnExpr' CoreBndr DVarSet]
args_r_to_l
where
(AnnVar CoreBndr
fn, [AnnExpr' CoreBndr DVarSet]
args_r_to_l) = AnnExpr' CoreBndr DVarSet
-> (AnnExpr' CoreBndr DVarSet, [AnnExpr' CoreBndr DVarSet])
forall ann.
AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
splitApp AnnExpr' CoreBndr DVarSet
app
n_args :: Int
n_args = [AnnExpr' CoreBndr DVarSet] -> Int
forall (t :: * -> *) a. Foldable t => t a -> Int
length [AnnExpr' CoreBndr DVarSet]
args_r_to_l
maybe_saturated_dcon :: Maybe DataCon
maybe_saturated_dcon
= case CoreBndr -> Maybe DataCon
isDataConWorkId_maybe CoreBndr
fn of
Just DataCon
con | DataCon -> Int
dataConRepArity DataCon
con Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
n_args -> DataCon -> Maybe DataCon
forall a. a -> Maybe a
Just DataCon
con
Maybe DataCon
_ -> Maybe DataCon
forall a. Maybe a
Nothing
mkConAppCode
:: StackDepth
-> Sequel
-> BCEnv
-> DataCon
-> [AnnExpr' Id DVarSet]
-> BcM BCInstrList
mkConAppCode :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> DataCon
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
mkConAppCode ByteOff
_ ByteOff
_ Map CoreBndr ByteOff
_ DataCon
con []
= ASSERT( isNullaryRepDataCon con )
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Name -> BCInstr
PUSH_G (CoreBndr -> Name
forall a. NamedThing a => a -> Name
getName (DataCon -> CoreBndr
dataConWorkId DataCon
con))))
mkConAppCode ByteOff
orig_d ByteOff
_ Map CoreBndr ByteOff
p DataCon
con [AnnExpr' CoreBndr DVarSet]
args_r_to_l =
ASSERT( args_r_to_l `lengthIs` dataConRepArity con ) app_code
where
app_code :: BcM BCInstrList
app_code = do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let non_voids :: [NonVoid (PrimRep, AnnExpr' CoreBndr DVarSet)]
non_voids =
[ (PrimRep, AnnExpr' CoreBndr DVarSet)
-> NonVoid (PrimRep, AnnExpr' CoreBndr DVarSet)
forall a. a -> NonVoid a
NonVoid (PrimRep
prim_rep, AnnExpr' CoreBndr DVarSet
arg)
| AnnExpr' CoreBndr DVarSet
arg <- [AnnExpr' CoreBndr DVarSet] -> [AnnExpr' CoreBndr DVarSet]
forall a. [a] -> [a]
reverse [AnnExpr' CoreBndr DVarSet]
args_r_to_l
, let prim_rep :: PrimRep
prim_rep = AnnExpr' CoreBndr DVarSet -> PrimRep
forall ann. AnnExpr' CoreBndr ann -> PrimRep
atomPrimRep AnnExpr' CoreBndr DVarSet
arg
, Bool -> Bool
not (PrimRep -> Bool
isVoidRep PrimRep
prim_rep)
]
(Int
_, Int
_, [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
args_offsets) =
DynFlags
-> ClosureHeader
-> [NonVoid (PrimRep, AnnExpr' CoreBndr DVarSet)]
-> (Int, Int, [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)])
forall a.
DynFlags
-> ClosureHeader
-> [NonVoid (PrimRep, a)]
-> (Int, Int, [FieldOffOrPadding a])
mkVirtHeapOffsetsWithPadding DynFlags
dflags ClosureHeader
StdHeader [NonVoid (PrimRep, AnnExpr' CoreBndr DVarSet)]
non_voids
do_pushery :: ByteOff
-> [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
-> BcM BCInstrList
do_pushery !ByteOff
d (FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)
arg : [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
args) = do
(BCInstrList
push, ByteOff
arg_bytes) <- case FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)
arg of
(Padding Int
l Int
_) -> (BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return ((BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff))
-> (BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall a b. (a -> b) -> a -> b
$! Int -> (BCInstrList, ByteOff)
pushPadding Int
l
(FieldOff NonVoid (AnnExpr' CoreBndr DVarSet)
a Int
_) -> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushConstrAtom ByteOff
d Map CoreBndr ByteOff
p (NonVoid (AnnExpr' CoreBndr DVarSet) -> AnnExpr' CoreBndr DVarSet
forall a. NonVoid a -> a
fromNonVoid NonVoid (AnnExpr' CoreBndr DVarSet)
a)
BCInstrList
more_push_code <- ByteOff
-> [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
-> BcM BCInstrList
do_pushery (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
arg_bytes) [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
args
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
more_push_code)
do_pushery !ByteOff
d [] = do
let !n_arg_words :: Word16
n_arg_words = WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
orig_d)
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (DataCon -> Word16 -> BCInstr
PACK DataCon
con Word16
n_arg_words))
ByteOff
-> [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
-> BcM BCInstrList
do_pushery ByteOff
orig_d ([FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
-> [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
forall a. [a] -> [a]
reverse [FieldOffOrPadding (AnnExpr' CoreBndr DVarSet)]
args_offsets)
unboxedTupleReturn
:: StackDepth -> Sequel -> BCEnv -> AnnExpr' Id DVarSet -> BcM BCInstrList
unboxedTupleReturn :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
unboxedTupleReturn ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg = ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> ArgRep
-> BcM BCInstrList
returnUnboxedAtom ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg (AnnExpr' CoreBndr DVarSet -> ArgRep
forall ann. AnnExpr' CoreBndr ann -> ArgRep
atomRep AnnExpr' CoreBndr DVarSet
arg)
doTailCall
:: StackDepth
-> Sequel
-> BCEnv
-> Id
-> [AnnExpr' Id DVarSet]
-> BcM BCInstrList
doTailCall :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> CoreBndr
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
doTailCall ByteOff
init_d ByteOff
s Map CoreBndr ByteOff
p CoreBndr
fn [AnnExpr' CoreBndr DVarSet]
args = ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> [ArgRep] -> BcM BCInstrList
do_pushes ByteOff
init_d [AnnExpr' CoreBndr DVarSet]
args ((AnnExpr' CoreBndr DVarSet -> ArgRep)
-> [AnnExpr' CoreBndr DVarSet] -> [ArgRep]
forall a b. (a -> b) -> [a] -> [b]
map AnnExpr' CoreBndr DVarSet -> ArgRep
forall ann. AnnExpr' CoreBndr ann -> ArgRep
atomRep [AnnExpr' CoreBndr DVarSet]
args)
where
do_pushes :: ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> [ArgRep] -> BcM BCInstrList
do_pushes !ByteOff
d [] [ArgRep]
reps = do
ASSERT( null reps ) return ()
(BCInstrList
push_fn, ByteOff
sz) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p (CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
fn)
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
ASSERT( sz == wordSize dflags ) return ()
let slide :: BCInstrList
slide = DynFlags -> ByteOff -> ByteOff -> BCInstrList
mkSlideB DynFlags
dflags (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
init_d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> ByteOff
wordSize DynFlags
dflags) (ByteOff
init_d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s)
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push_fn BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` (BCInstrList
slide BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL BCInstr
ENTER))
do_pushes !ByteOff
d [AnnExpr' CoreBndr DVarSet]
args [ArgRep]
reps = do
let (BCInstr
push_apply, Int
n, [ArgRep]
rest_of_reps) = [ArgRep] -> (BCInstr, Int, [ArgRep])
findPushSeq [ArgRep]
reps
([AnnExpr' CoreBndr DVarSet]
these_args, [AnnExpr' CoreBndr DVarSet]
rest_of_args) = Int
-> [AnnExpr' CoreBndr DVarSet]
-> ([AnnExpr' CoreBndr DVarSet], [AnnExpr' CoreBndr DVarSet])
forall a. Int -> [a] -> ([a], [a])
splitAt Int
n [AnnExpr' CoreBndr DVarSet]
args
(ByteOff
next_d, BCInstrList
push_code) <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM (ByteOff, BCInstrList)
push_seq ByteOff
d [AnnExpr' CoreBndr DVarSet]
these_args
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
BCInstrList
instrs <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> [ArgRep] -> BcM BCInstrList
do_pushes (ByteOff
next_d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> ByteOff
wordSize DynFlags
dflags) [AnnExpr' CoreBndr DVarSet]
rest_of_args [ArgRep]
rest_of_reps
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push_code BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` (BCInstr
push_apply BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` BCInstrList
instrs))
push_seq :: ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM (ByteOff, BCInstrList)
push_seq ByteOff
d [] = (ByteOff, BCInstrList) -> BcM (ByteOff, BCInstrList)
forall (m :: * -> *) a. Monad m => a -> m a
return (ByteOff
d, BCInstrList
forall a. OrdList a
nilOL)
push_seq ByteOff
d (AnnExpr' CoreBndr DVarSet
arg:[AnnExpr' CoreBndr DVarSet]
args) = do
(BCInstrList
push_code, ByteOff
sz) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg
(ByteOff
final_d, BCInstrList
more_push_code) <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM (ByteOff, BCInstrList)
push_seq (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
sz) [AnnExpr' CoreBndr DVarSet]
args
(ByteOff, BCInstrList) -> BcM (ByteOff, BCInstrList)
forall (m :: * -> *) a. Monad m => a -> m a
return (ByteOff
final_d, BCInstrList
push_code BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
more_push_code)
findPushSeq :: [ArgRep] -> (BCInstr, Int, [ArgRep])
findPushSeq :: [ArgRep] -> (BCInstr, Int, [ArgRep])
findPushSeq (ArgRep
P: ArgRep
P: ArgRep
P: ArgRep
P: ArgRep
P: ArgRep
P: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_PPPPPP, Int
6, [ArgRep]
rest)
findPushSeq (ArgRep
P: ArgRep
P: ArgRep
P: ArgRep
P: ArgRep
P: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_PPPPP, Int
5, [ArgRep]
rest)
findPushSeq (ArgRep
P: ArgRep
P: ArgRep
P: ArgRep
P: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_PPPP, Int
4, [ArgRep]
rest)
findPushSeq (ArgRep
P: ArgRep
P: ArgRep
P: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_PPP, Int
3, [ArgRep]
rest)
findPushSeq (ArgRep
P: ArgRep
P: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_PP, Int
2, [ArgRep]
rest)
findPushSeq (ArgRep
P: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_P, Int
1, [ArgRep]
rest)
findPushSeq (ArgRep
V: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_V, Int
1, [ArgRep]
rest)
findPushSeq (ArgRep
N: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_N, Int
1, [ArgRep]
rest)
findPushSeq (ArgRep
F: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_F, Int
1, [ArgRep]
rest)
findPushSeq (ArgRep
D: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_D, Int
1, [ArgRep]
rest)
findPushSeq (ArgRep
L: [ArgRep]
rest)
= (BCInstr
PUSH_APPLY_L, Int
1, [ArgRep]
rest)
findPushSeq [ArgRep]
_
= String -> (BCInstr, Int, [ArgRep])
forall a. String -> a
panic String
"ByteCodeGen.findPushSeq"
doCase
:: StackDepth
-> Sequel
-> BCEnv
-> AnnExpr Id DVarSet
-> Id
-> [AnnAlt Id DVarSet]
-> Maybe Id
-> BcM BCInstrList
doCase :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr CoreBndr DVarSet
-> CoreBndr
-> [AnnAlt CoreBndr DVarSet]
-> Maybe CoreBndr
-> BcM BCInstrList
doCase ByteOff
d ByteOff
s Map CoreBndr ByteOff
p (DVarSet
_,AnnExpr' CoreBndr DVarSet
scrut) CoreBndr
bndr [AnnAlt CoreBndr DVarSet]
alts Maybe CoreBndr
is_unboxed_tuple
| HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
bndr) [PrimRep] -> Int -> Bool
forall a. [a] -> Int -> Bool
`lengthExceeds` Int
1
= BcM BCInstrList
forall a. a
multiValException
| Bool
otherwise
= do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let
profiling :: Bool
profiling
| GeneralFlag -> DynFlags -> Bool
gopt GeneralFlag
Opt_ExternalInterpreter DynFlags
dflags = GeneralFlag -> DynFlags -> Bool
gopt GeneralFlag
Opt_SccProfilingOn DynFlags
dflags
| Bool
otherwise = Bool
rtsIsProfiled
ret_frame_size_b :: StackDepth
ret_frame_size_b :: ByteOff
ret_frame_size_b = ByteOff
2 ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
* DynFlags -> ByteOff
wordSize DynFlags
dflags
save_ccs_size_b :: ByteOff
save_ccs_size_b | Bool
profiling = ByteOff
2 ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
* DynFlags -> ByteOff
wordSize DynFlags
dflags
| Bool
otherwise = ByteOff
0
unlifted_itbl_size_b :: StackDepth
unlifted_itbl_size_b :: ByteOff
unlifted_itbl_size_b | Bool
isAlgCase = ByteOff
0
| Bool
otherwise = DynFlags -> ByteOff
wordSize DynFlags
dflags
d_bndr :: ByteOff
d_bndr =
ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
ret_frame_size_b ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags (DynFlags -> CoreBndr -> WordOff
idSizeW DynFlags
dflags CoreBndr
bndr)
d_alts :: ByteOff
d_alts = ByteOff
d_bndr ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
unlifted_itbl_size_b
p_alts0 :: Map CoreBndr ByteOff
p_alts0 = CoreBndr -> ByteOff -> Map CoreBndr ByteOff -> Map CoreBndr ByteOff
forall k a. Ord k => k -> a -> Map k a -> Map k a
Map.insert CoreBndr
bndr ByteOff
d_bndr Map CoreBndr ByteOff
p
p_alts :: Map CoreBndr ByteOff
p_alts = case Maybe CoreBndr
is_unboxed_tuple of
Just CoreBndr
ubx_bndr -> CoreBndr -> ByteOff -> Map CoreBndr ByteOff -> Map CoreBndr ByteOff
forall k a. Ord k => k -> a -> Map k a -> Map k a
Map.insert CoreBndr
ubx_bndr ByteOff
d_bndr Map CoreBndr ByteOff
p_alts0
Maybe CoreBndr
Nothing -> Map CoreBndr ByteOff
p_alts0
bndr_ty :: Type
bndr_ty = CoreBndr -> Type
idType CoreBndr
bndr
isAlgCase :: Bool
isAlgCase = Bool -> Bool
not (HasDebugCallStack => Type -> Bool
Type -> Bool
isUnliftedType Type
bndr_ty) Bool -> Bool -> Bool
&& Maybe CoreBndr -> Bool
forall a. Maybe a -> Bool
isNothing Maybe CoreBndr
is_unboxed_tuple
codeAlt :: (AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet))
-> BcM (Discr, BCInstrList)
codeAlt (AltCon
DEFAULT, [CoreBndr]
_, (a
_,AnnExpr' CoreBndr DVarSet
rhs))
= do BCInstrList
rhs_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d_alts ByteOff
s Map CoreBndr ByteOff
p_alts AnnExpr' CoreBndr DVarSet
rhs
(Discr, BCInstrList) -> BcM (Discr, BCInstrList)
forall (m :: * -> *) a. Monad m => a -> m a
return (Discr
NoDiscr, BCInstrList
rhs_code)
codeAlt alt :: (AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet))
alt@(AltCon
_, [CoreBndr]
bndrs, (a
_,AnnExpr' CoreBndr DVarSet
rhs))
| [CoreBndr] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [CoreBndr]
real_bndrs = do
BCInstrList
rhs_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
d_alts ByteOff
s Map CoreBndr ByteOff
p_alts AnnExpr' CoreBndr DVarSet
rhs
(Discr, BCInstrList) -> BcM (Discr, BCInstrList)
forall (m :: * -> *) a. Monad m => a -> m a
return ((AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet)) -> Discr
forall b c. (AltCon, b, c) -> Discr
my_discr (AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet))
alt, BCInstrList
rhs_code)
| (CoreBndr -> Bool) -> [CoreBndr] -> Bool
forall (t :: * -> *) a. Foldable t => (a -> Bool) -> t a -> Bool
any (\CoreBndr
bndr -> HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
bndr) [PrimRep] -> Int -> Bool
forall a. [a] -> Int -> Bool
`lengthExceeds` Int
1) [CoreBndr]
bndrs
= BcM (Discr, BCInstrList)
forall a. a
multiValException
| Bool
otherwise =
let (Int
tot_wds, Int
_ptrs_wds, [(NonVoid CoreBndr, Int)]
args_offsets) =
DynFlags
-> ClosureHeader
-> [NonVoid (PrimRep, CoreBndr)]
-> (Int, Int, [(NonVoid CoreBndr, Int)])
forall a.
DynFlags
-> ClosureHeader
-> [NonVoid (PrimRep, a)]
-> (Int, Int, [(NonVoid a, Int)])
mkVirtHeapOffsets DynFlags
dflags ClosureHeader
NoHeader
[ (PrimRep, CoreBndr) -> NonVoid (PrimRep, CoreBndr)
forall a. a -> NonVoid a
NonVoid (CoreBndr -> PrimRep
bcIdPrimRep CoreBndr
id, CoreBndr
id)
| NonVoid CoreBndr
id <- [CoreBndr] -> [NonVoid CoreBndr]
nonVoidIds [CoreBndr]
real_bndrs
]
size :: WordOff
size = Int -> WordOff
WordOff Int
tot_wds
stack_bot :: ByteOff
stack_bot = ByteOff
d_alts ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags WordOff
size
p' :: Map CoreBndr ByteOff
p' = [(CoreBndr, ByteOff)]
-> Map CoreBndr ByteOff -> Map CoreBndr ByteOff
forall key elt.
Ord key =>
[(key, elt)] -> Map key elt -> Map key elt
Map.insertList
[ (CoreBndr
arg, ByteOff
stack_bot ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- Int -> ByteOff
ByteOff Int
offset)
| (NonVoid CoreBndr
arg, Int
offset) <- [(NonVoid CoreBndr, Int)]
args_offsets ]
Map CoreBndr ByteOff
p_alts
in do
MASSERT(isAlgCase)
BCInstrList
rhs_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE ByteOff
stack_bot ByteOff
s Map CoreBndr ByteOff
p' AnnExpr' CoreBndr DVarSet
rhs
(Discr, BCInstrList) -> BcM (Discr, BCInstrList)
forall (m :: * -> *) a. Monad m => a -> m a
return ((AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet)) -> Discr
forall b c. (AltCon, b, c) -> Discr
my_discr (AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet))
alt,
BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Word16 -> BCInstr
UNPACK (WordOff -> Word16
trunc16W WordOff
size)) BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
rhs_code)
where
real_bndrs :: [CoreBndr]
real_bndrs = (CoreBndr -> Bool) -> [CoreBndr] -> [CoreBndr]
forall a. (a -> Bool) -> [a] -> [a]
filterOut CoreBndr -> Bool
isTyVar [CoreBndr]
bndrs
my_discr :: (AltCon, b, c) -> Discr
my_discr (AltCon
DEFAULT, b
_, c
_) = Discr
NoDiscr
my_discr (DataAlt DataCon
dc, b
_, c
_)
| DataCon -> Bool
isUnboxedTupleCon DataCon
dc Bool -> Bool -> Bool
|| DataCon -> Bool
isUnboxedSumCon DataCon
dc
= Discr
forall a. a
multiValException
| Bool
otherwise
= Word16 -> Discr
DiscrP (Int -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral (DataCon -> Int
dataConTag DataCon
dc Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
fIRST_TAG))
my_discr (LitAlt Literal
l, b
_, c
_)
= case Literal
l of LitNumber LitNumType
LitNumInt Integer
i Type
_ -> Int -> Discr
DiscrI (Integer -> Int
forall a. Num a => Integer -> a
fromInteger Integer
i)
LitNumber LitNumType
LitNumWord Integer
w Type
_ -> Word -> Discr
DiscrW (Integer -> Word
forall a. Num a => Integer -> a
fromInteger Integer
w)
LitFloat Rational
r -> Float -> Discr
DiscrF (Rational -> Float
forall a. Fractional a => Rational -> a
fromRational Rational
r)
LitDouble Rational
r -> Double -> Discr
DiscrD (Rational -> Double
forall a. Fractional a => Rational -> a
fromRational Rational
r)
LitChar Char
i -> Int -> Discr
DiscrI (Char -> Int
ord Char
i)
Literal
_ -> String -> SDoc -> Discr
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"schemeE(AnnCase).my_discr" (Literal -> SDoc
forall a. Outputable a => a -> SDoc
ppr Literal
l)
maybe_ncons :: Maybe Int
maybe_ncons
| Bool -> Bool
not Bool
isAlgCase = Maybe Int
forall a. Maybe a
Nothing
| Bool
otherwise
= case [DataCon
dc | (DataAlt DataCon
dc, [CoreBndr]
_, AnnExpr CoreBndr DVarSet
_) <- [AnnAlt CoreBndr DVarSet]
alts] of
[] -> Maybe Int
forall a. Maybe a
Nothing
(DataCon
dc:[DataCon]
_) -> Int -> Maybe Int
forall a. a -> Maybe a
Just (TyCon -> Int
tyConFamilySize (DataCon -> TyCon
dataConTyCon DataCon
dc))
bitmap_size :: Word16
bitmap_size = WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s)
bitmap_size' :: Int
bitmap_size' :: Int
bitmap_size' = Word16 -> Int
forall a b. (Integral a, Num b) => a -> b
fromIntegral Word16
bitmap_size
bitmap :: [StgWord]
bitmap = DynFlags -> Int -> [Int] -> [StgWord]
intsToReverseBitmap DynFlags
dflags Int
bitmap_size'
([Int] -> [Int]
forall a. Ord a => [a] -> [a]
sort ((Int -> Bool) -> [Int] -> [Int]
forall a. (a -> Bool) -> [a] -> [a]
filter (Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
bitmap_size') [Int]
rel_slots))
where
binds :: [(CoreBndr, ByteOff)]
binds = Map CoreBndr ByteOff -> [(CoreBndr, ByteOff)]
forall k a. Map k a -> [(k, a)]
Map.toList Map CoreBndr ByteOff
p
rel_slots :: [Int]
rel_slots = [Int] -> [Int]
forall a. Eq a => [a] -> [a]
nub ([Int] -> [Int]) -> [Int] -> [Int]
forall a b. (a -> b) -> a -> b
$ (Word16 -> Int) -> [Word16] -> [Int]
forall a b. (a -> b) -> [a] -> [b]
map Word16 -> Int
forall a b. (Integral a, Num b) => a -> b
fromIntegral ([Word16] -> [Int]) -> [Word16] -> [Int]
forall a b. (a -> b) -> a -> b
$ [[Word16]] -> [Word16]
forall (t :: * -> *) a. Foldable t => t [a] -> [a]
concat (((CoreBndr, ByteOff) -> [Word16])
-> [(CoreBndr, ByteOff)] -> [[Word16]]
forall a b. (a -> b) -> [a] -> [b]
map (CoreBndr, ByteOff) -> [Word16]
spread [(CoreBndr, ByteOff)]
binds)
spread :: (CoreBndr, ByteOff) -> [Word16]
spread (CoreBndr
id, ByteOff
offset) | ArgRep -> Bool
isFollowableArg (CoreBndr -> ArgRep
bcIdArgRep CoreBndr
id) = [ Word16
rel_offset ]
| Bool
otherwise = []
where rel_offset :: Word16
rel_offset = WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
offset)
[(Discr, BCInstrList)]
alt_stuff <- (AnnAlt CoreBndr DVarSet -> BcM (Discr, BCInstrList))
-> [AnnAlt CoreBndr DVarSet] -> BcM [(Discr, BCInstrList)]
forall (t :: * -> *) (m :: * -> *) a b.
(Traversable t, Monad m) =>
(a -> m b) -> t a -> m (t b)
mapM AnnAlt CoreBndr DVarSet -> BcM (Discr, BCInstrList)
forall a.
(AltCon, [CoreBndr], (a, AnnExpr' CoreBndr DVarSet))
-> BcM (Discr, BCInstrList)
codeAlt [AnnAlt CoreBndr DVarSet]
alts
BCInstrList
alt_final <- Maybe Int -> [(Discr, BCInstrList)] -> BcM BCInstrList
mkMultiBranch Maybe Int
maybe_ncons [(Discr, BCInstrList)]
alt_stuff
let
alt_bco_name :: Name
alt_bco_name = CoreBndr -> Name
forall a. NamedThing a => a -> Name
getName CoreBndr
bndr
alt_bco :: [FFIInfo] -> ProtoBCO Name
alt_bco = DynFlags
-> Name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO Name
forall name.
DynFlags
-> name
-> BCInstrList
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
-> Int
-> Word16
-> [StgWord]
-> Bool
-> [FFIInfo]
-> ProtoBCO name
mkProtoBCO DynFlags
dflags Name
alt_bco_name BCInstrList
alt_final ([AnnAlt CoreBndr DVarSet]
-> Either [AnnAlt CoreBndr DVarSet] (AnnExpr CoreBndr DVarSet)
forall a b. a -> Either a b
Left [AnnAlt CoreBndr DVarSet]
alts)
Int
0 Word16
bitmap_size [StgWord]
bitmap Bool
True
BCInstrList
scrut_code <- ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
schemeE (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
ret_frame_size_b ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
save_ccs_size_b)
(ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
ret_frame_size_b ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
save_ccs_size_b)
Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
scrut
ProtoBCO Name
alt_bco' <- ([FFIInfo] -> ProtoBCO Name) -> BcM (ProtoBCO Name)
emitBc [FFIInfo] -> ProtoBCO Name
alt_bco
let push_alts :: BCInstr
push_alts
| Bool
isAlgCase = ProtoBCO Name -> BCInstr
PUSH_ALTS ProtoBCO Name
alt_bco'
| Bool
otherwise = ProtoBCO Name -> ArgRep -> BCInstr
PUSH_ALTS_UNLIFTED ProtoBCO Name
alt_bco' (Type -> ArgRep
typeArgRep Type
bndr_ty)
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr
push_alts BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` BCInstrList
scrut_code)
generateCCall
:: StackDepth
-> Sequel
-> BCEnv
-> CCallSpec
-> Id
-> [AnnExpr' Id DVarSet]
-> BcM BCInstrList
generateCCall :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> CCallSpec
-> CoreBndr
-> [AnnExpr' CoreBndr DVarSet]
-> BcM BCInstrList
generateCCall ByteOff
d0 ByteOff
s Map CoreBndr ByteOff
p (CCallSpec CCallTarget
target CCallConv
cconv Safety
safety) CoreBndr
fn [AnnExpr' CoreBndr DVarSet]
args_r_to_l
= do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let
addr_size_b :: ByteOff
addr_size_b :: ByteOff
addr_size_b = DynFlags -> ByteOff
wordSize DynFlags
dflags
pargs
:: ByteOff -> [AnnExpr' Id DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs :: ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs ByteOff
_ [] = [(BCInstrList, PrimRep)] -> BcM [(BCInstrList, PrimRep)]
forall (m :: * -> *) a. Monad m => a -> m a
return []
pargs ByteOff
d (AnnExpr' CoreBndr DVarSet
a:[AnnExpr' CoreBndr DVarSet]
az)
= let arg_ty :: Type
arg_ty = Type -> Type
unwrapType (Expr CoreBndr -> Type
exprType (AnnExpr' CoreBndr DVarSet -> Expr CoreBndr
forall bndr annot. AnnExpr' bndr annot -> Expr bndr
deAnnotate' AnnExpr' CoreBndr DVarSet
a))
in case Type -> Maybe TyCon
tyConAppTyCon_maybe Type
arg_ty of
Just TyCon
t
| TyCon
t TyCon -> TyCon -> Bool
forall a. Eq a => a -> a -> Bool
== TyCon
arrayPrimTyCon Bool -> Bool -> Bool
|| TyCon
t TyCon -> TyCon -> Bool
forall a. Eq a => a -> a -> Bool
== TyCon
mutableArrayPrimTyCon
-> do [(BCInstrList, PrimRep)]
rest <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
addr_size_b) [AnnExpr' CoreBndr DVarSet]
az
BCInstrList
code <- Word16
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
parg_ArrayishRep (Int -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral (DynFlags -> Int
arrPtrsHdrSize DynFlags
dflags)) ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
[(BCInstrList, PrimRep)] -> BcM [(BCInstrList, PrimRep)]
forall (m :: * -> *) a. Monad m => a -> m a
return ((BCInstrList
code,PrimRep
AddrRep)(BCInstrList, PrimRep)
-> [(BCInstrList, PrimRep)] -> [(BCInstrList, PrimRep)]
forall a. a -> [a] -> [a]
:[(BCInstrList, PrimRep)]
rest)
| TyCon
t TyCon -> TyCon -> Bool
forall a. Eq a => a -> a -> Bool
== TyCon
smallArrayPrimTyCon Bool -> Bool -> Bool
|| TyCon
t TyCon -> TyCon -> Bool
forall a. Eq a => a -> a -> Bool
== TyCon
smallMutableArrayPrimTyCon
-> do [(BCInstrList, PrimRep)]
rest <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
addr_size_b) [AnnExpr' CoreBndr DVarSet]
az
BCInstrList
code <- Word16
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
parg_ArrayishRep (Int -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral (DynFlags -> Int
smallArrPtrsHdrSize DynFlags
dflags)) ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
[(BCInstrList, PrimRep)] -> BcM [(BCInstrList, PrimRep)]
forall (m :: * -> *) a. Monad m => a -> m a
return ((BCInstrList
code,PrimRep
AddrRep)(BCInstrList, PrimRep)
-> [(BCInstrList, PrimRep)] -> [(BCInstrList, PrimRep)]
forall a. a -> [a] -> [a]
:[(BCInstrList, PrimRep)]
rest)
| TyCon
t TyCon -> TyCon -> Bool
forall a. Eq a => a -> a -> Bool
== TyCon
byteArrayPrimTyCon Bool -> Bool -> Bool
|| TyCon
t TyCon -> TyCon -> Bool
forall a. Eq a => a -> a -> Bool
== TyCon
mutableByteArrayPrimTyCon
-> do [(BCInstrList, PrimRep)]
rest <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
addr_size_b) [AnnExpr' CoreBndr DVarSet]
az
BCInstrList
code <- Word16
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
parg_ArrayishRep (Int -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral (DynFlags -> Int
arrWordsHdrSize DynFlags
dflags)) ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
[(BCInstrList, PrimRep)] -> BcM [(BCInstrList, PrimRep)]
forall (m :: * -> *) a. Monad m => a -> m a
return ((BCInstrList
code,PrimRep
AddrRep)(BCInstrList, PrimRep)
-> [(BCInstrList, PrimRep)] -> [(BCInstrList, PrimRep)]
forall a. a -> [a] -> [a]
:[(BCInstrList, PrimRep)]
rest)
Maybe TyCon
_
-> do (BCInstrList
code_a, ByteOff
sz_a) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
[(BCInstrList, PrimRep)]
rest <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
sz_a) [AnnExpr' CoreBndr DVarSet]
az
[(BCInstrList, PrimRep)] -> BcM [(BCInstrList, PrimRep)]
forall (m :: * -> *) a. Monad m => a -> m a
return ((BCInstrList
code_a, AnnExpr' CoreBndr DVarSet -> PrimRep
forall ann. AnnExpr' CoreBndr ann -> PrimRep
atomPrimRep AnnExpr' CoreBndr DVarSet
a) (BCInstrList, PrimRep)
-> [(BCInstrList, PrimRep)] -> [(BCInstrList, PrimRep)]
forall a. a -> [a] -> [a]
: [(BCInstrList, PrimRep)]
rest)
parg_ArrayishRep
:: Word16
-> StackDepth
-> BCEnv
-> AnnExpr' Id DVarSet
-> BcM BCInstrList
parg_ArrayishRep :: Word16
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM BCInstrList
parg_ArrayishRep Word16
hdrSize ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
= do (BCInstrList
push_fo, ByteOff
_) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push_fo BCInstrList -> BCInstr -> BCInstrList
forall a. OrdList a -> a -> OrdList a
`snocOL` Word16 -> Word16 -> BCInstr
SWIZZLE Word16
0 Word16
hdrSize)
[(BCInstrList, PrimRep)]
code_n_reps <- ByteOff
-> [AnnExpr' CoreBndr DVarSet] -> BcM [(BCInstrList, PrimRep)]
pargs ByteOff
d0 [AnnExpr' CoreBndr DVarSet]
args_r_to_l
let
([BCInstrList]
pushs_arg, [PrimRep]
a_reps_pushed_r_to_l) = [(BCInstrList, PrimRep)] -> ([BCInstrList], [PrimRep])
forall a b. [(a, b)] -> ([a], [b])
unzip [(BCInstrList, PrimRep)]
code_n_reps
a_reps_sizeW :: WordOff
a_reps_sizeW = [WordOff] -> WordOff
forall (t :: * -> *) a. (Foldable t, Num a) => t a -> a
sum ((PrimRep -> WordOff) -> [PrimRep] -> [WordOff]
forall a b. (a -> b) -> [a] -> [b]
map (DynFlags -> PrimRep -> WordOff
repSizeWords DynFlags
dflags) [PrimRep]
a_reps_pushed_r_to_l)
push_args :: BCInstrList
push_args = [BCInstrList] -> BCInstrList
forall a. [OrdList a] -> OrdList a
concatOL [BCInstrList]
pushs_arg
!d_after_args :: ByteOff
d_after_args = ByteOff
d0 ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags WordOff
a_reps_sizeW
a_reps_pushed_RAW :: [PrimRep]
a_reps_pushed_RAW
| [PrimRep] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [PrimRep]
a_reps_pushed_r_to_l Bool -> Bool -> Bool
|| Bool -> Bool
not (PrimRep -> Bool
isVoidRep ([PrimRep] -> PrimRep
forall a. [a] -> a
head [PrimRep]
a_reps_pushed_r_to_l))
= String -> [PrimRep]
forall a. String -> a
panic String
"ByteCodeGen.generateCCall: missing or invalid World token?"
| Bool
otherwise
= [PrimRep] -> [PrimRep]
forall a. [a] -> [a]
reverse ([PrimRep] -> [PrimRep]
forall a. [a] -> [a]
tail [PrimRep]
a_reps_pushed_r_to_l)
(Bool
returns_void, PrimRep
r_rep)
= case Type -> Maybe PrimRep
maybe_getCCallReturnRep (CoreBndr -> Type
idType CoreBndr
fn) of
Maybe PrimRep
Nothing -> (Bool
True, PrimRep
VoidRep)
Just PrimRep
rr -> (Bool
False, PrimRep
rr)
maybe_static_target :: Maybe Literal
maybe_static_target :: Maybe Literal
maybe_static_target =
case CCallTarget
target of
CCallTarget
DynamicTarget -> Maybe Literal
forall a. Maybe a
Nothing
StaticTarget SourceText
_ FastString
_ Maybe UnitId
_ Bool
False ->
String -> Maybe Literal
forall a. String -> a
panic String
"generateCCall: unexpected FFI value import"
StaticTarget SourceText
_ FastString
target Maybe UnitId
_ Bool
True ->
Literal -> Maybe Literal
forall a. a -> Maybe a
Just (FastString -> Maybe Int -> FunctionOrData -> Literal
LitLabel FastString
target Maybe Int
mb_size FunctionOrData
IsFunction)
where
mb_size :: Maybe Int
mb_size
| OS
OSMinGW32 <- Platform -> OS
platformOS (DynFlags -> Platform
targetPlatform DynFlags
dflags)
, CCallConv
StdCallConv <- CCallConv
cconv
= Int -> Maybe Int
forall a. a -> Maybe a
Just (WordOff -> Int
forall a b. (Integral a, Num b) => a -> b
fromIntegral WordOff
a_reps_sizeW Int -> Int -> Int
forall a. Num a => a -> a -> a
* DynFlags -> Int
wORD_SIZE DynFlags
dflags)
| Bool
otherwise
= Maybe Int
forall a. Maybe a
Nothing
let
is_static :: Bool
is_static = Maybe Literal -> Bool
forall a. Maybe a -> Bool
isJust Maybe Literal
maybe_static_target
a_reps :: [PrimRep]
a_reps
| Bool
is_static = [PrimRep]
a_reps_pushed_RAW
| Bool
otherwise = if [PrimRep] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [PrimRep]
a_reps_pushed_RAW
then String -> [PrimRep]
forall a. String -> a
panic String
"ByteCodeGen.generateCCall: dyn with no args"
else [PrimRep] -> [PrimRep]
forall a. [a] -> [a]
tail [PrimRep]
a_reps_pushed_RAW
(BCInstrList
push_Addr, ByteOff
d_after_Addr)
| Just Literal
machlabel <- Maybe Literal
maybe_static_target
= ([BCInstr] -> BCInstrList
forall a. [a] -> OrdList a
toOL [Literal -> Word16 -> BCInstr
PUSH_UBX Literal
machlabel Word16
1], ByteOff
d_after_args ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
addr_size_b)
| Bool
otherwise
= (BCInstrList
forall a. OrdList a
nilOL, ByteOff
d_after_args)
r_sizeW :: WordOff
r_sizeW = DynFlags -> PrimRep -> WordOff
repSizeWords DynFlags
dflags PrimRep
r_rep
d_after_r :: ByteOff
d_after_r = ByteOff
d_after_Addr ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags WordOff
r_sizeW
push_r :: BCInstrList
push_r =
if Bool
returns_void
then BCInstrList
forall a. OrdList a
nilOL
else BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Literal -> Word16 -> BCInstr
PUSH_UBX (DynFlags -> PrimRep -> Literal
mkDummyLiteral DynFlags
dflags PrimRep
r_rep) (WordOff -> Word16
trunc16W WordOff
r_sizeW))
stk_offset :: Word16
stk_offset = WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d_after_r ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s)
conv :: FFIConv
conv = case CCallConv
cconv of
CCallConv
CCallConv -> FFIConv
FFICCall
CCallConv
StdCallConv -> FFIConv
FFIStdCall
CCallConv
_ -> String -> FFIConv
forall a. String -> a
panic String
"ByteCodeGen: unexpected calling convention"
let ffires :: FFIType
ffires = DynFlags -> PrimRep -> FFIType
primRepToFFIType DynFlags
dflags PrimRep
r_rep
ffiargs :: [FFIType]
ffiargs = (PrimRep -> FFIType) -> [PrimRep] -> [FFIType]
forall a b. (a -> b) -> [a] -> [b]
map (DynFlags -> PrimRep -> FFIType
primRepToFFIType DynFlags
dflags) [PrimRep]
a_reps
HscEnv
hsc_env <- BcM HscEnv
getHscEnv
RemotePtr C_ffi_cif
token <- IO (RemotePtr C_ffi_cif) -> BcM (RemotePtr C_ffi_cif)
forall a. IO a -> BcM a
ioToBc (IO (RemotePtr C_ffi_cif) -> BcM (RemotePtr C_ffi_cif))
-> IO (RemotePtr C_ffi_cif) -> BcM (RemotePtr C_ffi_cif)
forall a b. (a -> b) -> a -> b
$ HscEnv -> Message (RemotePtr C_ffi_cif) -> IO (RemotePtr C_ffi_cif)
forall a. Binary a => HscEnv -> Message a -> IO a
iservCmd HscEnv
hsc_env (FFIConv -> [FFIType] -> FFIType -> Message (RemotePtr C_ffi_cif)
PrepFFI FFIConv
conv [FFIType]
ffiargs FFIType
ffires)
RemotePtr C_ffi_cif -> BcM ()
recordFFIBc RemotePtr C_ffi_cif
token
let
do_call :: BCInstrList
do_call = BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Word16 -> RemotePtr C_ffi_cif -> Word16 -> BCInstr
CCALL Word16
stk_offset RemotePtr C_ffi_cif
token Word16
flags)
where flags :: Word16
flags = case Safety
safety of
Safety
PlaySafe -> Word16
0x0
Safety
PlayInterruptible -> Word16
0x1
Safety
PlayRisky -> Word16
0x2
d_after_r_min_s :: WordOff
d_after_r_min_s = DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d_after_r ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s)
wrapup :: BCInstrList
wrapup = Word16 -> WordOff -> BCInstrList
mkSlideW (WordOff -> Word16
trunc16W WordOff
r_sizeW) (WordOff
d_after_r_min_s WordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
- WordOff
r_sizeW)
BCInstrList -> BCInstr -> BCInstrList
forall a. OrdList a -> a -> OrdList a
`snocOL` ArgRep -> BCInstr
RETURN_UBX (PrimRep -> ArgRep
toArgRep PrimRep
r_rep)
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (
BCInstrList
push_args BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL`
BCInstrList
push_Addr BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
push_r BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
do_call BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
wrapup
)
primRepToFFIType :: DynFlags -> PrimRep -> FFIType
primRepToFFIType :: DynFlags -> PrimRep -> FFIType
primRepToFFIType DynFlags
dflags PrimRep
r
= case PrimRep
r of
PrimRep
VoidRep -> FFIType
FFIVoid
PrimRep
IntRep -> FFIType
signed_word
PrimRep
WordRep -> FFIType
unsigned_word
PrimRep
Int64Rep -> FFIType
FFISInt64
PrimRep
Word64Rep -> FFIType
FFIUInt64
PrimRep
AddrRep -> FFIType
FFIPointer
PrimRep
FloatRep -> FFIType
FFIFloat
PrimRep
DoubleRep -> FFIType
FFIDouble
PrimRep
_ -> String -> FFIType
forall a. String -> a
panic String
"primRepToFFIType"
where
(FFIType
signed_word, FFIType
unsigned_word)
| DynFlags -> Int
wORD_SIZE DynFlags
dflags Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
4 = (FFIType
FFISInt32, FFIType
FFIUInt32)
| DynFlags -> Int
wORD_SIZE DynFlags
dflags Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
8 = (FFIType
FFISInt64, FFIType
FFIUInt64)
| Bool
otherwise = String -> (FFIType, FFIType)
forall a. String -> a
panic String
"primTyDescChar"
mkDummyLiteral :: DynFlags -> PrimRep -> Literal
mkDummyLiteral :: DynFlags -> PrimRep -> Literal
mkDummyLiteral DynFlags
dflags PrimRep
pr
= case PrimRep
pr of
PrimRep
IntRep -> DynFlags -> Integer -> Literal
mkLitInt DynFlags
dflags Integer
0
PrimRep
WordRep -> DynFlags -> Integer -> Literal
mkLitWord DynFlags
dflags Integer
0
PrimRep
Int64Rep -> Integer -> Literal
mkLitInt64 Integer
0
PrimRep
Word64Rep -> Integer -> Literal
mkLitWord64 Integer
0
PrimRep
AddrRep -> Literal
LitNullAddr
PrimRep
DoubleRep -> Rational -> Literal
LitDouble Rational
0
PrimRep
FloatRep -> Rational -> Literal
LitFloat Rational
0
PrimRep
_ -> String -> SDoc -> Literal
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"mkDummyLiteral" (PrimRep -> SDoc
forall a. Outputable a => a -> SDoc
ppr PrimRep
pr)
maybe_getCCallReturnRep :: Type -> Maybe PrimRep
maybe_getCCallReturnRep :: Type -> Maybe PrimRep
maybe_getCCallReturnRep Type
fn_ty
= let
([Type]
_a_tys, Type
r_ty) = Type -> ([Type], Type)
splitFunTys (Type -> Type
dropForAlls Type
fn_ty)
r_reps :: [PrimRep]
r_reps = HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRepArgs Type
r_ty
blargh :: a
blargh :: a
blargh = String -> SDoc -> a
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"maybe_getCCallReturn: can't handle:"
(Type -> SDoc
pprType Type
fn_ty)
in
case [PrimRep]
r_reps of
[] -> String -> Maybe PrimRep
forall a. String -> a
panic String
"empty typePrimRepArgs"
[PrimRep
VoidRep] -> Maybe PrimRep
forall a. Maybe a
Nothing
[PrimRep
rep]
| PrimRep -> Bool
isGcPtrRep PrimRep
rep -> Maybe PrimRep
forall a. a
blargh
| Bool
otherwise -> PrimRep -> Maybe PrimRep
forall a. a -> Maybe a
Just PrimRep
rep
[PrimRep]
_ -> Maybe PrimRep
forall a. a
blargh
maybe_is_tagToEnum_call :: AnnExpr' Id DVarSet -> Maybe (AnnExpr' Id DVarSet, [Name])
maybe_is_tagToEnum_call :: AnnExpr' CoreBndr DVarSet
-> Maybe (AnnExpr' CoreBndr DVarSet, [Name])
maybe_is_tagToEnum_call AnnExpr' CoreBndr DVarSet
app
| AnnApp (DVarSet
_, AnnApp (DVarSet
_, AnnVar CoreBndr
v) (DVarSet
_, AnnType Type
t)) AnnExpr CoreBndr DVarSet
arg <- AnnExpr' CoreBndr DVarSet
app
, Just PrimOp
TagToEnumOp <- CoreBndr -> Maybe PrimOp
isPrimOpId_maybe CoreBndr
v
= (AnnExpr' CoreBndr DVarSet, [Name])
-> Maybe (AnnExpr' CoreBndr DVarSet, [Name])
forall a. a -> Maybe a
Just (AnnExpr CoreBndr DVarSet -> AnnExpr' CoreBndr DVarSet
forall a b. (a, b) -> b
snd AnnExpr CoreBndr DVarSet
arg, Type -> [Name]
extract_constr_Names Type
t)
| Bool
otherwise
= Maybe (AnnExpr' CoreBndr DVarSet, [Name])
forall a. Maybe a
Nothing
where
extract_constr_Names :: Type -> [Name]
extract_constr_Names Type
ty
| Type
rep_ty <- Type -> Type
unwrapType Type
ty
, Just TyCon
tyc <- Type -> Maybe TyCon
tyConAppTyCon_maybe Type
rep_ty
, TyCon -> Bool
isDataTyCon TyCon
tyc
= (DataCon -> Name) -> [DataCon] -> [Name]
forall a b. (a -> b) -> [a] -> [b]
map (CoreBndr -> Name
forall a. NamedThing a => a -> Name
getName (CoreBndr -> Name) -> (DataCon -> CoreBndr) -> DataCon -> Name
forall b c a. (b -> c) -> (a -> b) -> a -> c
. DataCon -> CoreBndr
dataConWorkId) (TyCon -> [DataCon]
tyConDataCons TyCon
tyc)
| Bool
otherwise
= String -> SDoc -> [Name]
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"maybe_is_tagToEnum_call.extract_constr_Ids" (Type -> SDoc
forall a. Outputable a => a -> SDoc
ppr Type
ty)
implement_tagToId
:: StackDepth
-> Sequel
-> BCEnv
-> AnnExpr' Id DVarSet
-> [Name]
-> BcM BCInstrList
implement_tagToId :: ByteOff
-> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> [Name]
-> BcM BCInstrList
implement_tagToId ByteOff
d ByteOff
s Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg [Name]
names
= ASSERT( notNull names )
do (BCInstrList
push_arg, ByteOff
arg_bytes) <- ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
arg
[Word16]
labels <- Word16 -> BcM [Word16]
getLabelsBc ([Name] -> Word16
forall i a. Num i => [a] -> i
genericLength [Name]
names)
Word16
label_fail <- BcM Word16
getLabelBc
Word16
label_exit <- BcM Word16
getLabelBc
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let infos :: [(Word16, Word16, Int, Name)]
infos = [Word16]
-> [Word16] -> [Int] -> [Name] -> [(Word16, Word16, Int, Name)]
forall a b c d. [a] -> [b] -> [c] -> [d] -> [(a, b, c, d)]
zip4 [Word16]
labels ([Word16] -> [Word16]
forall a. [a] -> [a]
tail [Word16]
labels [Word16] -> [Word16] -> [Word16]
forall a. [a] -> [a] -> [a]
++ [Word16
label_fail])
[Int
0 ..] [Name]
names
steps :: [BCInstrList]
steps = ((Word16, Word16, Int, Name) -> BCInstrList)
-> [(Word16, Word16, Int, Name)] -> [BCInstrList]
forall a b. (a -> b) -> [a] -> [b]
map (Word16 -> (Word16, Word16, Int, Name) -> BCInstrList
mkStep Word16
label_exit) [(Word16, Word16, Int, Name)]
infos
slide_ws :: WordOff
slide_ws = DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
s ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
+ ByteOff
arg_bytes)
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
push_arg
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Literal -> Word16 -> BCInstr
PUSH_UBX Literal
LitNullAddr Word16
1)
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` [BCInstrList] -> BCInstrList
forall a. [OrdList a] -> OrdList a
concatOL [BCInstrList]
steps
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` [BCInstr] -> BCInstrList
forall a. [a] -> OrdList a
toOL [ Word16 -> BCInstr
LABEL Word16
label_fail, BCInstr
CASEFAIL,
Word16 -> BCInstr
LABEL Word16
label_exit ]
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` Word16 -> WordOff -> BCInstrList
mkSlideW Word16
1 (WordOff
slide_ws WordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
+ WordOff
1)
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL BCInstr
ENTER)
where
mkStep :: Word16 -> (Word16, Word16, Int, Name) -> BCInstrList
mkStep Word16
l_exit (Word16
my_label, Word16
next_label, Int
n, Name
name_for_n)
= [BCInstr] -> BCInstrList
forall a. [a] -> OrdList a
toOL [Word16 -> BCInstr
LABEL Word16
my_label,
Int -> Word16 -> BCInstr
TESTEQ_I Int
n Word16
next_label,
Name -> BCInstr
PUSH_G Name
name_for_n,
Word16 -> BCInstr
JMP Word16
l_exit]
pushAtom
:: StackDepth -> BCEnv -> AnnExpr' Id DVarSet -> BcM (BCInstrList, ByteOff)
pushAtom :: ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e
| Just AnnExpr' CoreBndr DVarSet
e' <- AnnExpr' CoreBndr DVarSet -> Maybe (AnnExpr' CoreBndr DVarSet)
forall ann. AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView AnnExpr' CoreBndr DVarSet
e
= ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
e'
pushAtom ByteOff
_ Map CoreBndr ByteOff
_ (AnnCoercion {})
= (BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
forall a. OrdList a
nilOL, ByteOff
0)
pushAtom ByteOff
d Map CoreBndr ByteOff
p (AnnCase (DVarSet
_, AnnExpr' CoreBndr DVarSet
a) CoreBndr
_ Type
_ [])
= ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
a
pushAtom ByteOff
d Map CoreBndr ByteOff
p (AnnVar CoreBndr
var)
| [] <- HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRep (CoreBndr -> Type
idType CoreBndr
var)
= (BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
forall a. OrdList a
nilOL, ByteOff
0)
| CoreBndr -> Bool
isFCallId CoreBndr
var
= String -> SDoc -> BcM (BCInstrList, ByteOff)
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"pushAtom: shouldn't get an FCallId here" (CoreBndr -> SDoc
forall a. Outputable a => a -> SDoc
ppr CoreBndr
var)
| Just PrimOp
primop <- CoreBndr -> Maybe PrimOp
isPrimOpId_maybe CoreBndr
var
= do
DynFlags
dflags <-BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
(BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (PrimOp -> BCInstr
PUSH_PRIMOP PrimOp
primop), DynFlags -> ByteOff
wordSize DynFlags
dflags)
| Just ByteOff
d_v <- CoreBndr -> Map CoreBndr ByteOff -> Maybe ByteOff
lookupBCEnv_maybe CoreBndr
var Map CoreBndr ByteOff
p
= do DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let !szb :: ByteOff
szb = DynFlags -> CoreBndr -> ByteOff
idSizeCon DynFlags
dflags CoreBndr
var
with_instr :: (Word16 -> a) -> m (OrdList a, ByteOff)
with_instr Word16 -> a
instr = do
let !off_b :: Word16
off_b = ByteOff -> Word16
trunc16B (ByteOff -> Word16) -> ByteOff -> Word16
forall a b. (a -> b) -> a -> b
$ ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
d_v
(OrdList a, ByteOff) -> m (OrdList a, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (a -> OrdList a
forall a. a -> OrdList a
unitOL (Word16 -> a
instr Word16
off_b), DynFlags -> ByteOff
wordSize DynFlags
dflags)
case ByteOff
szb of
ByteOff
1 -> (Word16 -> BCInstr) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a.
Monad m =>
(Word16 -> a) -> m (OrdList a, ByteOff)
with_instr Word16 -> BCInstr
PUSH8_W
ByteOff
2 -> (Word16 -> BCInstr) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a.
Monad m =>
(Word16 -> a) -> m (OrdList a, ByteOff)
with_instr Word16 -> BCInstr
PUSH16_W
ByteOff
4 -> (Word16 -> BCInstr) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a.
Monad m =>
(Word16 -> a) -> m (OrdList a, ByteOff)
with_instr Word16 -> BCInstr
PUSH32_W
ByteOff
_ -> do
let !szw :: WordOff
szw = DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags ByteOff
szb
!off_w :: Word16
off_w = WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags (ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
d_v) WordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
+ WordOff
szw WordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
- WordOff
1
(BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return ([BCInstr] -> BCInstrList
forall a. [a] -> OrdList a
toOL (WordOff -> BCInstr -> [BCInstr]
forall i a. Integral i => i -> a -> [a]
genericReplicate WordOff
szw (Word16 -> BCInstr
PUSH_L Word16
off_w)), ByteOff
szb)
| Bool
otherwise
= do IdEnv (RemotePtr ())
topStrings <- BcM (IdEnv (RemotePtr ()))
getTopStrings
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
case IdEnv (RemotePtr ()) -> CoreBndr -> Maybe (RemotePtr ())
forall a. VarEnv a -> CoreBndr -> Maybe a
lookupVarEnv IdEnv (RemotePtr ())
topStrings CoreBndr
var of
Just RemotePtr ()
ptr -> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p (AnnExpr' CoreBndr DVarSet -> BcM (BCInstrList, ByteOff))
-> AnnExpr' CoreBndr DVarSet -> BcM (BCInstrList, ByteOff)
forall a b. (a -> b) -> a -> b
$ Literal -> AnnExpr' CoreBndr DVarSet
forall bndr annot. Literal -> AnnExpr' bndr annot
AnnLit (Literal -> AnnExpr' CoreBndr DVarSet)
-> Literal -> AnnExpr' CoreBndr DVarSet
forall a b. (a -> b) -> a -> b
$ DynFlags -> Integer -> Literal
mkLitWord DynFlags
dflags (Integer -> Literal) -> Integer -> Literal
forall a b. (a -> b) -> a -> b
$
WordPtr -> Integer
forall a b. (Integral a, Num b) => a -> b
fromIntegral (WordPtr -> Integer) -> WordPtr -> Integer
forall a b. (a -> b) -> a -> b
$ Ptr () -> WordPtr
forall a. Ptr a -> WordPtr
ptrToWordPtr (Ptr () -> WordPtr) -> Ptr () -> WordPtr
forall a b. (a -> b) -> a -> b
$ RemotePtr () -> Ptr ()
forall a. RemotePtr a -> Ptr a
fromRemotePtr RemotePtr ()
ptr
Maybe (RemotePtr ())
Nothing -> do
let sz :: ByteOff
sz = DynFlags -> CoreBndr -> ByteOff
idSizeCon DynFlags
dflags CoreBndr
var
MASSERT( sz == wordSize dflags )
(BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Name -> BCInstr
PUSH_G (CoreBndr -> Name
forall a. NamedThing a => a -> Name
getName CoreBndr
var)), ByteOff
sz)
pushAtom ByteOff
_ Map CoreBndr ByteOff
_ (AnnLit Literal
lit) = do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let code :: ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
rep
= let size_words :: WordOff
size_words = Int -> WordOff
WordOff (DynFlags -> ArgRep -> Int
argRepSizeW DynFlags
dflags ArgRep
rep)
in (BCInstrList, ByteOff) -> m (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Literal -> Word16 -> BCInstr
PUSH_UBX Literal
lit (WordOff -> Word16
trunc16W WordOff
size_words)),
DynFlags -> WordOff -> ByteOff
wordsToBytes DynFlags
dflags WordOff
size_words)
case Literal
lit of
LitLabel FastString
_ Maybe Int
_ FunctionOrData
_ -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
LitFloat Rational
_ -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
F
LitDouble Rational
_ -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
D
LitChar Char
_ -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
Literal
LitNullAddr -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
LitString ByteString
_ -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
Literal
LitRubbish -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
LitNumber LitNumType
nt Integer
_ Type
_ -> case LitNumType
nt of
LitNumType
LitNumInt -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
LitNumType
LitNumWord -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
N
LitNumType
LitNumInt64 -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
L
LitNumType
LitNumWord64 -> ArgRep -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *). Monad m => ArgRep -> m (BCInstrList, ByteOff)
code ArgRep
L
LitNumType
LitNumInteger -> String -> BcM (BCInstrList, ByteOff)
forall a. String -> a
panic String
"pushAtom: LitInteger"
LitNumType
LitNumNatural -> String -> BcM (BCInstrList, ByteOff)
forall a. String -> a
panic String
"pushAtom: LitNatural"
pushAtom ByteOff
_ Map CoreBndr ByteOff
_ AnnExpr' CoreBndr DVarSet
expr
= String -> SDoc -> BcM (BCInstrList, ByteOff)
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"ByteCodeGen.pushAtom"
(Expr CoreBndr -> SDoc
forall b. OutputableBndr b => Expr b -> SDoc
pprCoreExpr (AnnExpr' CoreBndr DVarSet -> Expr CoreBndr
forall bndr annot. AnnExpr' bndr annot -> Expr bndr
deAnnotate' AnnExpr' CoreBndr DVarSet
expr))
pushConstrAtom
:: StackDepth -> BCEnv -> AnnExpr' Id DVarSet -> BcM (BCInstrList, ByteOff)
pushConstrAtom :: ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushConstrAtom ByteOff
_ Map CoreBndr ByteOff
_ (AnnLit lit :: Literal
lit@(LitFloat Rational
_)) =
(BCInstrList, ByteOff) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Literal -> BCInstr
PUSH_UBX32 Literal
lit), ByteOff
4)
pushConstrAtom ByteOff
d Map CoreBndr ByteOff
p (AnnVar CoreBndr
v)
| Just ByteOff
d_v <- CoreBndr -> Map CoreBndr ByteOff -> Maybe ByteOff
lookupBCEnv_maybe CoreBndr
v Map CoreBndr ByteOff
p = do
DynFlags
dflags <- BcM DynFlags
forall (m :: * -> *). HasDynFlags m => m DynFlags
getDynFlags
let !szb :: ByteOff
szb = DynFlags -> CoreBndr -> ByteOff
idSizeCon DynFlags
dflags CoreBndr
v
done :: (Word16 -> a) -> m (OrdList a, ByteOff)
done Word16 -> a
instr = do
let !off :: Word16
off = ByteOff -> Word16
trunc16B (ByteOff -> Word16) -> ByteOff -> Word16
forall a b. (a -> b) -> a -> b
$ ByteOff
d ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
- ByteOff
d_v
(OrdList a, ByteOff) -> m (OrdList a, ByteOff)
forall (m :: * -> *) a. Monad m => a -> m a
return (a -> OrdList a
forall a. a -> OrdList a
unitOL (Word16 -> a
instr Word16
off), ByteOff
szb)
case ByteOff
szb of
ByteOff
1 -> (Word16 -> BCInstr) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a.
Monad m =>
(Word16 -> a) -> m (OrdList a, ByteOff)
done Word16 -> BCInstr
PUSH8
ByteOff
2 -> (Word16 -> BCInstr) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a.
Monad m =>
(Word16 -> a) -> m (OrdList a, ByteOff)
done Word16 -> BCInstr
PUSH16
ByteOff
4 -> (Word16 -> BCInstr) -> BcM (BCInstrList, ByteOff)
forall (m :: * -> *) a.
Monad m =>
(Word16 -> a) -> m (OrdList a, ByteOff)
done Word16 -> BCInstr
PUSH32
ByteOff
_ -> ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p (CoreBndr -> AnnExpr' CoreBndr DVarSet
forall bndr annot. CoreBndr -> AnnExpr' bndr annot
AnnVar CoreBndr
v)
pushConstrAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
expr = ByteOff
-> Map CoreBndr ByteOff
-> AnnExpr' CoreBndr DVarSet
-> BcM (BCInstrList, ByteOff)
pushAtom ByteOff
d Map CoreBndr ByteOff
p AnnExpr' CoreBndr DVarSet
expr
pushPadding :: Int -> (BCInstrList, ByteOff)
pushPadding :: Int -> (BCInstrList, ByteOff)
pushPadding !Int
n = Int -> (BCInstrList, ByteOff) -> (BCInstrList, ByteOff)
forall t a.
(Eq t, Num t, Num a) =>
t -> (BCInstrList, a) -> (BCInstrList, a)
go Int
n (BCInstrList
forall a. OrdList a
nilOL, ByteOff
0)
where
go :: t -> (BCInstrList, a) -> (BCInstrList, a)
go t
n acc :: (BCInstrList, a)
acc@(!BCInstrList
instrs, !a
off) = case t
n of
t
0 -> (BCInstrList, a)
acc
t
1 -> (BCInstrList
instrs BCInstrList -> BCInstrList -> BCInstrList
forall a. Monoid a => a -> a -> a
`mappend` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL BCInstr
PUSH_PAD8, a
off a -> a -> a
forall a. Num a => a -> a -> a
+ a
1)
t
2 -> (BCInstrList
instrs BCInstrList -> BCInstrList -> BCInstrList
forall a. Monoid a => a -> a -> a
`mappend` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL BCInstr
PUSH_PAD16, a
off a -> a -> a
forall a. Num a => a -> a -> a
+ a
2)
t
3 -> t -> (BCInstrList, a) -> (BCInstrList, a)
go t
1 (t -> (BCInstrList, a) -> (BCInstrList, a)
go t
2 (BCInstrList, a)
acc)
t
4 -> (BCInstrList
instrs BCInstrList -> BCInstrList -> BCInstrList
forall a. Monoid a => a -> a -> a
`mappend` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL BCInstr
PUSH_PAD32, a
off a -> a -> a
forall a. Num a => a -> a -> a
+ a
4)
t
_ -> t -> (BCInstrList, a) -> (BCInstrList, a)
go (t
n t -> t -> t
forall a. Num a => a -> a -> a
- t
4) (t -> (BCInstrList, a) -> (BCInstrList, a)
go t
4 (BCInstrList, a)
acc)
mkMultiBranch :: Maybe Int
-> [(Discr, BCInstrList)]
-> BcM BCInstrList
mkMultiBranch :: Maybe Int -> [(Discr, BCInstrList)] -> BcM BCInstrList
mkMultiBranch Maybe Int
maybe_ncons [(Discr, BCInstrList)]
raw_ways = do
Word16
lbl_default <- BcM Word16
getLabelBc
let
mkTree :: [(Discr, BCInstrList)] -> Discr -> Discr -> BcM BCInstrList
mkTree :: [(Discr, BCInstrList)] -> Discr -> Discr -> BcM BCInstrList
mkTree [] Discr
_range_lo Discr
_range_hi = BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Word16 -> BCInstr
JMP Word16
lbl_default))
mkTree [(Discr, BCInstrList)
val] Discr
range_lo Discr
range_hi
| Discr
range_lo Discr -> Discr -> Bool
forall a. Eq a => a -> a -> Bool
== Discr
range_hi
= BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return ((Discr, BCInstrList) -> BCInstrList
forall a b. (a, b) -> b
snd (Discr, BCInstrList)
val)
| [(Discr, BCInstrList)] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [(Discr, BCInstrList)]
defaults
= do Word16
lbl <- BcM Word16
getLabelBc
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (Discr -> Word16 -> BCInstr
testEQ ((Discr, BCInstrList) -> Discr
forall a b. (a, b) -> a
fst (Discr, BCInstrList)
val) Word16
lbl
BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` ((Discr, BCInstrList) -> BCInstrList
forall a b. (a, b) -> b
snd (Discr, BCInstrList)
val
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` (Word16 -> BCInstr
LABEL Word16
lbl BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL BCInstr
CASEFAIL)))
| Bool
otherwise
= BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (Discr -> Word16 -> BCInstr
testEQ ((Discr, BCInstrList) -> Discr
forall a b. (a, b) -> a
fst (Discr, BCInstrList)
val) Word16
lbl_default BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` (Discr, BCInstrList) -> BCInstrList
forall a b. (a, b) -> b
snd (Discr, BCInstrList)
val)
mkTree [(Discr, BCInstrList)]
vals Discr
range_lo Discr
range_hi
= let n :: Int
n = [(Discr, BCInstrList)] -> Int
forall (t :: * -> *) a. Foldable t => t a -> Int
length [(Discr, BCInstrList)]
vals Int -> Int -> Int
forall a. Integral a => a -> a -> a
`div` Int
2
vals_lo :: [(Discr, BCInstrList)]
vals_lo = Int -> [(Discr, BCInstrList)] -> [(Discr, BCInstrList)]
forall a. Int -> [a] -> [a]
take Int
n [(Discr, BCInstrList)]
vals
vals_hi :: [(Discr, BCInstrList)]
vals_hi = Int -> [(Discr, BCInstrList)] -> [(Discr, BCInstrList)]
forall a. Int -> [a] -> [a]
drop Int
n [(Discr, BCInstrList)]
vals
v_mid :: Discr
v_mid = (Discr, BCInstrList) -> Discr
forall a b. (a, b) -> a
fst ([(Discr, BCInstrList)] -> (Discr, BCInstrList)
forall a. [a] -> a
head [(Discr, BCInstrList)]
vals_hi)
in do
Word16
label_geq <- BcM Word16
getLabelBc
BCInstrList
code_lo <- [(Discr, BCInstrList)] -> Discr -> Discr -> BcM BCInstrList
mkTree [(Discr, BCInstrList)]
vals_lo Discr
range_lo (Discr -> Discr
dec Discr
v_mid)
BCInstrList
code_hi <- [(Discr, BCInstrList)] -> Discr -> Discr -> BcM BCInstrList
mkTree [(Discr, BCInstrList)]
vals_hi Discr
v_mid Discr
range_hi
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (Discr -> Word16 -> BCInstr
testLT Discr
v_mid Word16
label_geq
BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` (BCInstrList
code_lo
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Word16 -> BCInstr
LABEL Word16
label_geq)
BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
code_hi))
the_default :: BCInstrList
the_default
= case [(Discr, BCInstrList)]
defaults of
[] -> BCInstrList
forall a. OrdList a
nilOL
[(Discr
_, BCInstrList
def)] -> Word16 -> BCInstr
LABEL Word16
lbl_default BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` BCInstrList
def
[(Discr, BCInstrList)]
_ -> String -> BCInstrList
forall a. String -> a
panic String
"mkMultiBranch/the_default"
BCInstrList
instrs <- [(Discr, BCInstrList)] -> Discr -> Discr -> BcM BCInstrList
mkTree [(Discr, BCInstrList)]
notd_ways Discr
init_lo Discr
init_hi
BCInstrList -> BcM BCInstrList
forall (m :: * -> *) a. Monad m => a -> m a
return (BCInstrList
instrs BCInstrList -> BCInstrList -> BCInstrList
forall a. OrdList a -> OrdList a -> OrdList a
`appOL` BCInstrList
the_default)
where
([(Discr, BCInstrList)]
defaults, [(Discr, BCInstrList)]
not_defaults) = ((Discr, BCInstrList) -> Bool)
-> [(Discr, BCInstrList)]
-> ([(Discr, BCInstrList)], [(Discr, BCInstrList)])
forall a. (a -> Bool) -> [a] -> ([a], [a])
partition (Discr -> Bool
isNoDiscr(Discr -> Bool)
-> ((Discr, BCInstrList) -> Discr) -> (Discr, BCInstrList) -> Bool
forall b c a. (b -> c) -> (a -> b) -> a -> c
.(Discr, BCInstrList) -> Discr
forall a b. (a, b) -> a
fst) [(Discr, BCInstrList)]
raw_ways
notd_ways :: [(Discr, BCInstrList)]
notd_ways = ((Discr, BCInstrList) -> (Discr, BCInstrList) -> Ordering)
-> [(Discr, BCInstrList)] -> [(Discr, BCInstrList)]
forall a. (a -> a -> Ordering) -> [a] -> [a]
sortBy (((Discr, BCInstrList) -> Discr)
-> (Discr, BCInstrList) -> (Discr, BCInstrList) -> Ordering
forall a b. Ord a => (b -> a) -> b -> b -> Ordering
comparing (Discr, BCInstrList) -> Discr
forall a b. (a, b) -> a
fst) [(Discr, BCInstrList)]
not_defaults
testLT :: Discr -> Word16 -> BCInstr
testLT (DiscrI Int
i) Word16
fail_label = Int -> Word16 -> BCInstr
TESTLT_I Int
i Word16
fail_label
testLT (DiscrW Word
i) Word16
fail_label = Word -> Word16 -> BCInstr
TESTLT_W Word
i Word16
fail_label
testLT (DiscrF Float
i) Word16
fail_label = Float -> Word16 -> BCInstr
TESTLT_F Float
i Word16
fail_label
testLT (DiscrD Double
i) Word16
fail_label = Double -> Word16 -> BCInstr
TESTLT_D Double
i Word16
fail_label
testLT (DiscrP Word16
i) Word16
fail_label = Word16 -> Word16 -> BCInstr
TESTLT_P Word16
i Word16
fail_label
testLT Discr
NoDiscr Word16
_ = String -> BCInstr
forall a. String -> a
panic String
"mkMultiBranch NoDiscr"
testEQ :: Discr -> Word16 -> BCInstr
testEQ (DiscrI Int
i) Word16
fail_label = Int -> Word16 -> BCInstr
TESTEQ_I Int
i Word16
fail_label
testEQ (DiscrW Word
i) Word16
fail_label = Word -> Word16 -> BCInstr
TESTEQ_W Word
i Word16
fail_label
testEQ (DiscrF Float
i) Word16
fail_label = Float -> Word16 -> BCInstr
TESTEQ_F Float
i Word16
fail_label
testEQ (DiscrD Double
i) Word16
fail_label = Double -> Word16 -> BCInstr
TESTEQ_D Double
i Word16
fail_label
testEQ (DiscrP Word16
i) Word16
fail_label = Word16 -> Word16 -> BCInstr
TESTEQ_P Word16
i Word16
fail_label
testEQ Discr
NoDiscr Word16
_ = String -> BCInstr
forall a. String -> a
panic String
"mkMultiBranch NoDiscr"
(Discr
init_lo, Discr
init_hi)
| [(Discr, BCInstrList)] -> Bool
forall (t :: * -> *) a. Foldable t => t a -> Bool
null [(Discr, BCInstrList)]
notd_ways
= String -> (Discr, Discr)
forall a. String -> a
panic String
"mkMultiBranch: awesome foursome"
| Bool
otherwise
= case (Discr, BCInstrList) -> Discr
forall a b. (a, b) -> a
fst ([(Discr, BCInstrList)] -> (Discr, BCInstrList)
forall a. [a] -> a
head [(Discr, BCInstrList)]
notd_ways) of
DiscrI Int
_ -> ( Int -> Discr
DiscrI Int
forall a. Bounded a => a
minBound, Int -> Discr
DiscrI Int
forall a. Bounded a => a
maxBound )
DiscrW Word
_ -> ( Word -> Discr
DiscrW Word
forall a. Bounded a => a
minBound, Word -> Discr
DiscrW Word
forall a. Bounded a => a
maxBound )
DiscrF Float
_ -> ( Float -> Discr
DiscrF Float
minF, Float -> Discr
DiscrF Float
maxF )
DiscrD Double
_ -> ( Double -> Discr
DiscrD Double
minD, Double -> Discr
DiscrD Double
maxD )
DiscrP Word16
_ -> ( Word16 -> Discr
DiscrP Word16
algMinBound, Word16 -> Discr
DiscrP Word16
algMaxBound )
Discr
NoDiscr -> String -> (Discr, Discr)
forall a. String -> a
panic String
"mkMultiBranch NoDiscr"
(Word16
algMinBound, Word16
algMaxBound)
= case Maybe Int
maybe_ncons of
Just Int
n -> (Word16
0, Int -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
n Word16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
- Word16
1)
Maybe Int
Nothing -> (Word16
forall a. Bounded a => a
minBound, Word16
forall a. Bounded a => a
maxBound)
isNoDiscr :: Discr -> Bool
isNoDiscr Discr
NoDiscr = Bool
True
isNoDiscr Discr
_ = Bool
False
dec :: Discr -> Discr
dec (DiscrI Int
i) = Int -> Discr
DiscrI (Int
iInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1)
dec (DiscrW Word
w) = Word -> Discr
DiscrW (Word
wWord -> Word -> Word
forall a. Num a => a -> a -> a
-Word
1)
dec (DiscrP Word16
i) = Word16 -> Discr
DiscrP (Word16
iWord16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
-Word16
1)
dec Discr
other = Discr
other
minF, maxF :: Float
minD, maxD :: Double
minF :: Float
minF = -Float
1.0e37
maxF :: Float
maxF = Float
1.0e37
minD :: Double
minD = -Double
1.0e308
maxD :: Double
maxD = Double
1.0e308
data Discr
= DiscrI Int
| DiscrW Word
| DiscrF Float
| DiscrD Double
| DiscrP Word16
| NoDiscr
deriving (Discr -> Discr -> Bool
(Discr -> Discr -> Bool) -> (Discr -> Discr -> Bool) -> Eq Discr
forall a. (a -> a -> Bool) -> (a -> a -> Bool) -> Eq a
/= :: Discr -> Discr -> Bool
$c/= :: Discr -> Discr -> Bool
== :: Discr -> Discr -> Bool
$c== :: Discr -> Discr -> Bool
Eq, Eq Discr
Eq Discr
-> (Discr -> Discr -> Ordering)
-> (Discr -> Discr -> Bool)
-> (Discr -> Discr -> Bool)
-> (Discr -> Discr -> Bool)
-> (Discr -> Discr -> Bool)
-> (Discr -> Discr -> Discr)
-> (Discr -> Discr -> Discr)
-> Ord Discr
Discr -> Discr -> Bool
Discr -> Discr -> Ordering
Discr -> Discr -> Discr
forall a.
Eq a
-> (a -> a -> Ordering)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> Bool)
-> (a -> a -> a)
-> (a -> a -> a)
-> Ord a
min :: Discr -> Discr -> Discr
$cmin :: Discr -> Discr -> Discr
max :: Discr -> Discr -> Discr
$cmax :: Discr -> Discr -> Discr
>= :: Discr -> Discr -> Bool
$c>= :: Discr -> Discr -> Bool
> :: Discr -> Discr -> Bool
$c> :: Discr -> Discr -> Bool
<= :: Discr -> Discr -> Bool
$c<= :: Discr -> Discr -> Bool
< :: Discr -> Discr -> Bool
$c< :: Discr -> Discr -> Bool
compare :: Discr -> Discr -> Ordering
$ccompare :: Discr -> Discr -> Ordering
$cp1Ord :: Eq Discr
Ord)
instance Outputable Discr where
ppr :: Discr -> SDoc
ppr (DiscrI Int
i) = Int -> SDoc
int Int
i
ppr (DiscrW Word
w) = String -> SDoc
text (Word -> String
forall a. Show a => a -> String
show Word
w)
ppr (DiscrF Float
f) = String -> SDoc
text (Float -> String
forall a. Show a => a -> String
show Float
f)
ppr (DiscrD Double
d) = String -> SDoc
text (Double -> String
forall a. Show a => a -> String
show Double
d)
ppr (DiscrP Word16
i) = Word16 -> SDoc
forall a. Outputable a => a -> SDoc
ppr Word16
i
ppr Discr
NoDiscr = String -> SDoc
text String
"DEF"
lookupBCEnv_maybe :: Id -> BCEnv -> Maybe ByteOff
lookupBCEnv_maybe :: CoreBndr -> Map CoreBndr ByteOff -> Maybe ByteOff
lookupBCEnv_maybe = CoreBndr -> Map CoreBndr ByteOff -> Maybe ByteOff
forall k a. Ord k => k -> Map k a -> Maybe a
Map.lookup
idSizeW :: DynFlags -> Id -> WordOff
idSizeW :: DynFlags -> CoreBndr -> WordOff
idSizeW DynFlags
dflags = Int -> WordOff
WordOff (Int -> WordOff) -> (CoreBndr -> Int) -> CoreBndr -> WordOff
forall b c a. (b -> c) -> (a -> b) -> a -> c
. DynFlags -> ArgRep -> Int
argRepSizeW DynFlags
dflags (ArgRep -> Int) -> (CoreBndr -> ArgRep) -> CoreBndr -> Int
forall b c a. (b -> c) -> (a -> b) -> a -> c
. CoreBndr -> ArgRep
bcIdArgRep
idSizeCon :: DynFlags -> Id -> ByteOff
idSizeCon :: DynFlags -> CoreBndr -> ByteOff
idSizeCon DynFlags
dflags = Int -> ByteOff
ByteOff (Int -> ByteOff) -> (CoreBndr -> Int) -> CoreBndr -> ByteOff
forall b c a. (b -> c) -> (a -> b) -> a -> c
. DynFlags -> PrimRep -> Int
primRepSizeB DynFlags
dflags (PrimRep -> Int) -> (CoreBndr -> PrimRep) -> CoreBndr -> Int
forall b c a. (b -> c) -> (a -> b) -> a -> c
. CoreBndr -> PrimRep
bcIdPrimRep
bcIdArgRep :: Id -> ArgRep
bcIdArgRep :: CoreBndr -> ArgRep
bcIdArgRep = PrimRep -> ArgRep
toArgRep (PrimRep -> ArgRep) -> (CoreBndr -> PrimRep) -> CoreBndr -> ArgRep
forall b c a. (b -> c) -> (a -> b) -> a -> c
. CoreBndr -> PrimRep
bcIdPrimRep
bcIdPrimRep :: Id -> PrimRep
bcIdPrimRep :: CoreBndr -> PrimRep
bcIdPrimRep CoreBndr
id
| [PrimRep
rep] <- HasDebugCallStack => Type -> [PrimRep]
Type -> [PrimRep]
typePrimRepArgs (CoreBndr -> Type
idType CoreBndr
id)
= PrimRep
rep
| Bool
otherwise
= String -> SDoc -> PrimRep
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"bcIdPrimRep" (CoreBndr -> SDoc
forall a. Outputable a => a -> SDoc
ppr CoreBndr
id SDoc -> SDoc -> SDoc
<+> SDoc
dcolon SDoc -> SDoc -> SDoc
<+> Type -> SDoc
forall a. Outputable a => a -> SDoc
ppr (CoreBndr -> Type
idType CoreBndr
id))
repSizeWords :: DynFlags -> PrimRep -> WordOff
repSizeWords :: DynFlags -> PrimRep -> WordOff
repSizeWords DynFlags
dflags PrimRep
rep = Int -> WordOff
WordOff (Int -> WordOff) -> Int -> WordOff
forall a b. (a -> b) -> a -> b
$ DynFlags -> ArgRep -> Int
argRepSizeW DynFlags
dflags (PrimRep -> ArgRep
toArgRep PrimRep
rep)
isFollowableArg :: ArgRep -> Bool
isFollowableArg :: ArgRep -> Bool
isFollowableArg ArgRep
P = Bool
True
isFollowableArg ArgRep
_ = Bool
False
isVoidArg :: ArgRep -> Bool
isVoidArg :: ArgRep -> Bool
isVoidArg ArgRep
V = Bool
True
isVoidArg ArgRep
_ = Bool
False
multiValException :: a
multiValException :: a
multiValException = GhcException -> a
forall a. GhcException -> a
throwGhcException (String -> GhcException
ProgramError
(String
"Error: bytecode compiler can't handle unboxed tuples and sums.\n"String -> String -> String
forall a. [a] -> [a] -> [a]
++
String
" Possibly due to foreign import/export decls in source.\n"String -> String -> String
forall a. [a] -> [a] -> [a]
++
String
" Workaround: use -fobject-code, or compile this module to .o separately."))
isSupportedCConv :: CCallSpec -> Bool
isSupportedCConv :: CCallSpec -> Bool
isSupportedCConv (CCallSpec CCallTarget
_ CCallConv
cconv Safety
_) = case CCallConv
cconv of
CCallConv
CCallConv -> Bool
True
CCallConv
StdCallConv -> Bool
True
CCallConv
PrimCallConv -> Bool
False
CCallConv
JavaScriptCallConv -> Bool
False
CCallConv
CApiConv -> Bool
False
unsupportedCConvException :: a
unsupportedCConvException :: a
unsupportedCConvException = GhcException -> a
forall a. GhcException -> a
throwGhcException (String -> GhcException
ProgramError
(String
"Error: bytecode compiler can't handle some foreign calling conventions\n"String -> String -> String
forall a. [a] -> [a] -> [a]
++
String
" Workaround: use -fobject-code, or compile this module to .o separately."))
mkSlideB :: DynFlags -> ByteOff -> ByteOff -> OrdList BCInstr
mkSlideB :: DynFlags -> ByteOff -> ByteOff -> BCInstrList
mkSlideB DynFlags
dflags !ByteOff
nb !ByteOff
db = Word16 -> WordOff -> BCInstrList
mkSlideW Word16
n WordOff
d
where
!n :: Word16
n = WordOff -> Word16
trunc16W (WordOff -> Word16) -> WordOff -> Word16
forall a b. (a -> b) -> a -> b
$ DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags ByteOff
nb
!d :: WordOff
d = DynFlags -> ByteOff -> WordOff
bytesToWords DynFlags
dflags ByteOff
db
mkSlideW :: Word16 -> WordOff -> OrdList BCInstr
mkSlideW :: Word16 -> WordOff -> BCInstrList
mkSlideW !Word16
n !WordOff
ws
| WordOff
ws WordOff -> WordOff -> Bool
forall a. Ord a => a -> a -> Bool
> Word16 -> WordOff
forall a b. (Integral a, Num b) => a -> b
fromIntegral Word16
limit
= Word16 -> Word16 -> BCInstr
SLIDE Word16
n Word16
limit BCInstr -> BCInstrList -> BCInstrList
forall a. a -> OrdList a -> OrdList a
`consOL` Word16 -> WordOff -> BCInstrList
mkSlideW Word16
n (WordOff
ws WordOff -> WordOff -> WordOff
forall a. Num a => a -> a -> a
- Word16 -> WordOff
forall a b. (Integral a, Num b) => a -> b
fromIntegral Word16
limit)
| WordOff
ws WordOff -> WordOff -> Bool
forall a. Eq a => a -> a -> Bool
== WordOff
0
= BCInstrList
forall a. OrdList a
nilOL
| Bool
otherwise
= BCInstr -> BCInstrList
forall a. a -> OrdList a
unitOL (Word16 -> Word16 -> BCInstr
SLIDE Word16
n (Word16 -> BCInstr) -> Word16 -> BCInstr
forall a b. (a -> b) -> a -> b
$ WordOff -> Word16
forall a b. (Integral a, Num b) => a -> b
fromIntegral WordOff
ws)
where
limit :: Word16
limit :: Word16
limit = Word16
forall a. Bounded a => a
maxBound
splitApp :: AnnExpr' Var ann -> (AnnExpr' Var ann, [AnnExpr' Var ann])
splitApp :: AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
splitApp AnnExpr' CoreBndr ann
e | Just AnnExpr' CoreBndr ann
e' <- AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall ann. AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView AnnExpr' CoreBndr ann
e = AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
forall ann.
AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
splitApp AnnExpr' CoreBndr ann
e'
splitApp (AnnApp (ann
_,AnnExpr' CoreBndr ann
f) (ann
_,AnnExpr' CoreBndr ann
a)) = case AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
forall ann.
AnnExpr' CoreBndr ann
-> (AnnExpr' CoreBndr ann, [AnnExpr' CoreBndr ann])
splitApp AnnExpr' CoreBndr ann
f of
(AnnExpr' CoreBndr ann
f', [AnnExpr' CoreBndr ann]
as) -> (AnnExpr' CoreBndr ann
f', AnnExpr' CoreBndr ann
aAnnExpr' CoreBndr ann
-> [AnnExpr' CoreBndr ann] -> [AnnExpr' CoreBndr ann]
forall a. a -> [a] -> [a]
:[AnnExpr' CoreBndr ann]
as)
splitApp AnnExpr' CoreBndr ann
e = (AnnExpr' CoreBndr ann
e, [])
bcView :: AnnExpr' Var ann -> Maybe (AnnExpr' Var ann)
bcView :: AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView (AnnCast (ann
_,AnnExpr' CoreBndr ann
e) (ann, Coercion)
_) = AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall a. a -> Maybe a
Just AnnExpr' CoreBndr ann
e
bcView (AnnLam CoreBndr
v (ann
_,AnnExpr' CoreBndr ann
e)) | CoreBndr -> Bool
isTyVar CoreBndr
v = AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall a. a -> Maybe a
Just AnnExpr' CoreBndr ann
e
bcView (AnnApp (ann
_,AnnExpr' CoreBndr ann
e) (ann
_, AnnType Type
_)) = AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall a. a -> Maybe a
Just AnnExpr' CoreBndr ann
e
bcView (AnnTick Breakpoint{} (ann, AnnExpr' CoreBndr ann)
_) = Maybe (AnnExpr' CoreBndr ann)
forall a. Maybe a
Nothing
bcView (AnnTick Tickish CoreBndr
_other_tick (ann
_,AnnExpr' CoreBndr ann
e)) = AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall a. a -> Maybe a
Just AnnExpr' CoreBndr ann
e
bcView AnnExpr' CoreBndr ann
_ = Maybe (AnnExpr' CoreBndr ann)
forall a. Maybe a
Nothing
isVAtom :: AnnExpr' Var ann -> Bool
isVAtom :: AnnExpr' CoreBndr ann -> Bool
isVAtom AnnExpr' CoreBndr ann
e | Just AnnExpr' CoreBndr ann
e' <- AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall ann. AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView AnnExpr' CoreBndr ann
e = AnnExpr' CoreBndr ann -> Bool
forall ann. AnnExpr' CoreBndr ann -> Bool
isVAtom AnnExpr' CoreBndr ann
e'
isVAtom (AnnVar CoreBndr
v) = ArgRep -> Bool
isVoidArg (CoreBndr -> ArgRep
bcIdArgRep CoreBndr
v)
isVAtom (AnnCoercion {}) = Bool
True
isVAtom AnnExpr' CoreBndr ann
_ = Bool
False
atomPrimRep :: AnnExpr' Id ann -> PrimRep
atomPrimRep :: AnnExpr' CoreBndr ann -> PrimRep
atomPrimRep AnnExpr' CoreBndr ann
e | Just AnnExpr' CoreBndr ann
e' <- AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
forall ann. AnnExpr' CoreBndr ann -> Maybe (AnnExpr' CoreBndr ann)
bcView AnnExpr' CoreBndr ann
e = AnnExpr' CoreBndr ann -> PrimRep
forall ann. AnnExpr' CoreBndr ann -> PrimRep
atomPrimRep AnnExpr' CoreBndr ann
e'
atomPrimRep (AnnVar CoreBndr
v) = CoreBndr -> PrimRep
bcIdPrimRep CoreBndr
v
atomPrimRep (AnnLit Literal
l) = HasDebugCallStack => Type -> PrimRep
Type -> PrimRep
typePrimRep1 (Literal -> Type
literalType Literal
l)
atomPrimRep (AnnCase AnnExpr CoreBndr ann
_ CoreBndr
_ Type
ty [AnnAlt CoreBndr ann]
_) =
ASSERT(case typePrimRep ty of [LiftedRep] -> True; _ -> False) LiftedRep
atomPrimRep (AnnCoercion {}) = PrimRep
VoidRep
atomPrimRep AnnExpr' CoreBndr ann
other = String -> SDoc -> PrimRep
forall a. HasCallStack => String -> SDoc -> a
pprPanic String
"atomPrimRep" (Expr CoreBndr -> SDoc
forall a. Outputable a => a -> SDoc
ppr (AnnExpr' CoreBndr ann -> Expr CoreBndr
forall bndr annot. AnnExpr' bndr annot -> Expr bndr
deAnnotate' AnnExpr' CoreBndr ann
other))
atomRep :: AnnExpr' Id ann -> ArgRep
atomRep :: AnnExpr' CoreBndr ann -> ArgRep
atomRep AnnExpr' CoreBndr ann
e = PrimRep -> ArgRep
toArgRep (AnnExpr' CoreBndr ann -> PrimRep
forall ann. AnnExpr' CoreBndr ann -> PrimRep
atomPrimRep AnnExpr' CoreBndr ann
e)
mkStackOffsets :: ByteOff -> [ByteOff] -> [ByteOff]
mkStackOffsets :: ByteOff -> [ByteOff] -> [ByteOff]
mkStackOffsets ByteOff
original_depth [ByteOff]
szsb = [ByteOff] -> [ByteOff]
forall a. [a] -> [a]
tail ((ByteOff -> ByteOff -> ByteOff)
-> ByteOff -> [ByteOff] -> [ByteOff]
forall b a. (b -> a -> b) -> b -> [a] -> [b]
scanl' ByteOff -> ByteOff -> ByteOff
forall a. Num a => a -> a -> a
(+) ByteOff
original_depth [ByteOff]
szsb)
typeArgRep :: Type -> ArgRep
typeArgRep :: Type -> ArgRep
typeArgRep = PrimRep -> ArgRep
toArgRep (PrimRep -> ArgRep) -> (Type -> PrimRep) -> Type -> ArgRep
forall b c a. (b -> c) -> (a -> b) -> a -> c
. HasDebugCallStack => Type -> PrimRep
Type -> PrimRep
typePrimRep1
data BcM_State
= BcM_State
{ BcM_State -> HscEnv
bcm_hsc_env :: HscEnv
, BcM_State -> UniqSupply
uniqSupply :: UniqSupply
, BcM_State -> Module
thisModule :: Module
, BcM_State -> Word16
nextlabel :: Word16
, BcM_State -> [FFIInfo]
ffis :: [FFIInfo]
, BcM_State -> Maybe ModBreaks
modBreaks :: Maybe ModBreaks
, BcM_State -> IntMap CgBreakInfo
breakInfo :: IntMap CgBreakInfo
, BcM_State -> IdEnv (RemotePtr ())
topStrings :: IdEnv (RemotePtr ())
}
newtype BcM r = BcM (BcM_State -> IO (BcM_State, r)) deriving (a -> BcM b -> BcM a
(a -> b) -> BcM a -> BcM b
(forall a b. (a -> b) -> BcM a -> BcM b)
-> (forall a b. a -> BcM b -> BcM a) -> Functor BcM
forall a b. a -> BcM b -> BcM a
forall a b. (a -> b) -> BcM a -> BcM b
forall (f :: * -> *).
(forall a b. (a -> b) -> f a -> f b)
-> (forall a b. a -> f b -> f a) -> Functor f
<$ :: a -> BcM b -> BcM a
$c<$ :: forall a b. a -> BcM b -> BcM a
fmap :: (a -> b) -> BcM a -> BcM b
$cfmap :: forall a b. (a -> b) -> BcM a -> BcM b
Functor)
ioToBc :: IO a -> BcM a
ioToBc :: IO a -> BcM a
ioToBc IO a
io = (BcM_State -> IO (BcM_State, a)) -> BcM a
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, a)) -> BcM a)
-> (BcM_State -> IO (BcM_State, a)) -> BcM a
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> do
a
x <- IO a
io
(BcM_State, a) -> IO (BcM_State, a)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, a
x)
runBc :: HscEnv -> UniqSupply -> Module -> Maybe ModBreaks
-> IdEnv (RemotePtr ())
-> BcM r
-> IO (BcM_State, r)
runBc :: HscEnv
-> UniqSupply
-> Module
-> Maybe ModBreaks
-> IdEnv (RemotePtr ())
-> BcM r
-> IO (BcM_State, r)
runBc HscEnv
hsc_env UniqSupply
us Module
this_mod Maybe ModBreaks
modBreaks IdEnv (RemotePtr ())
topStrings (BcM BcM_State -> IO (BcM_State, r)
m)
= BcM_State -> IO (BcM_State, r)
m (HscEnv
-> UniqSupply
-> Module
-> Word16
-> [FFIInfo]
-> Maybe ModBreaks
-> IntMap CgBreakInfo
-> IdEnv (RemotePtr ())
-> BcM_State
BcM_State HscEnv
hsc_env UniqSupply
us Module
this_mod Word16
0 [] Maybe ModBreaks
modBreaks IntMap CgBreakInfo
forall a. IntMap a
IntMap.empty IdEnv (RemotePtr ())
topStrings)
thenBc :: BcM a -> (a -> BcM b) -> BcM b
thenBc :: BcM a -> (a -> BcM b) -> BcM b
thenBc (BcM BcM_State -> IO (BcM_State, a)
expr) a -> BcM b
cont = (BcM_State -> IO (BcM_State, b)) -> BcM b
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, b)) -> BcM b)
-> (BcM_State -> IO (BcM_State, b)) -> BcM b
forall a b. (a -> b) -> a -> b
$ \BcM_State
st0 -> do
(BcM_State
st1, a
q) <- BcM_State -> IO (BcM_State, a)
expr BcM_State
st0
let BcM BcM_State -> IO (BcM_State, b)
k = a -> BcM b
cont a
q
(BcM_State
st2, b
r) <- BcM_State -> IO (BcM_State, b)
k BcM_State
st1
(BcM_State, b) -> IO (BcM_State, b)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st2, b
r)
thenBc_ :: BcM a -> BcM b -> BcM b
thenBc_ :: BcM a -> BcM b -> BcM b
thenBc_ (BcM BcM_State -> IO (BcM_State, a)
expr) (BcM BcM_State -> IO (BcM_State, b)
cont) = (BcM_State -> IO (BcM_State, b)) -> BcM b
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, b)) -> BcM b)
-> (BcM_State -> IO (BcM_State, b)) -> BcM b
forall a b. (a -> b) -> a -> b
$ \BcM_State
st0 -> do
(BcM_State
st1, a
_) <- BcM_State -> IO (BcM_State, a)
expr BcM_State
st0
(BcM_State
st2, b
r) <- BcM_State -> IO (BcM_State, b)
cont BcM_State
st1
(BcM_State, b) -> IO (BcM_State, b)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st2, b
r)
returnBc :: a -> BcM a
returnBc :: a -> BcM a
returnBc a
result = (BcM_State -> IO (BcM_State, a)) -> BcM a
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, a)) -> BcM a)
-> (BcM_State -> IO (BcM_State, a)) -> BcM a
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> ((BcM_State, a) -> IO (BcM_State, a)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, a
result))
instance Applicative BcM where
pure :: a -> BcM a
pure = a -> BcM a
forall a. a -> BcM a
returnBc
<*> :: BcM (a -> b) -> BcM a -> BcM b
(<*>) = BcM (a -> b) -> BcM a -> BcM b
forall (m :: * -> *) a b. Monad m => m (a -> b) -> m a -> m b
ap
*> :: BcM a -> BcM b -> BcM b
(*>) = BcM a -> BcM b -> BcM b
forall a b. BcM a -> BcM b -> BcM b
thenBc_
instance Monad BcM where
>>= :: BcM a -> (a -> BcM b) -> BcM b
(>>=) = BcM a -> (a -> BcM b) -> BcM b
forall a b. BcM a -> (a -> BcM b) -> BcM b
thenBc
>> :: BcM a -> BcM b -> BcM b
(>>) = BcM a -> BcM b -> BcM b
forall (f :: * -> *) a b. Applicative f => f a -> f b -> f b
(*>)
instance HasDynFlags BcM where
getDynFlags :: BcM DynFlags
getDynFlags = (BcM_State -> IO (BcM_State, DynFlags)) -> BcM DynFlags
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, DynFlags)) -> BcM DynFlags)
-> (BcM_State -> IO (BcM_State, DynFlags)) -> BcM DynFlags
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> (BcM_State, DynFlags) -> IO (BcM_State, DynFlags)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, HscEnv -> DynFlags
hsc_dflags (BcM_State -> HscEnv
bcm_hsc_env BcM_State
st))
getHscEnv :: BcM HscEnv
getHscEnv :: BcM HscEnv
getHscEnv = (BcM_State -> IO (BcM_State, HscEnv)) -> BcM HscEnv
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, HscEnv)) -> BcM HscEnv)
-> (BcM_State -> IO (BcM_State, HscEnv)) -> BcM HscEnv
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> (BcM_State, HscEnv) -> IO (BcM_State, HscEnv)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, BcM_State -> HscEnv
bcm_hsc_env BcM_State
st)
emitBc :: ([FFIInfo] -> ProtoBCO Name) -> BcM (ProtoBCO Name)
emitBc :: ([FFIInfo] -> ProtoBCO Name) -> BcM (ProtoBCO Name)
emitBc [FFIInfo] -> ProtoBCO Name
bco
= (BcM_State -> IO (BcM_State, ProtoBCO Name)) -> BcM (ProtoBCO Name)
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, ProtoBCO Name))
-> BcM (ProtoBCO Name))
-> (BcM_State -> IO (BcM_State, ProtoBCO Name))
-> BcM (ProtoBCO Name)
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> (BcM_State, ProtoBCO Name) -> IO (BcM_State, ProtoBCO Name)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st{ffis :: [FFIInfo]
ffis=[]}, [FFIInfo] -> ProtoBCO Name
bco (BcM_State -> [FFIInfo]
ffis BcM_State
st))
recordFFIBc :: RemotePtr C_ffi_cif -> BcM ()
recordFFIBc :: RemotePtr C_ffi_cif -> BcM ()
recordFFIBc RemotePtr C_ffi_cif
a
= (BcM_State -> IO (BcM_State, ())) -> BcM ()
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, ())) -> BcM ())
-> (BcM_State -> IO (BcM_State, ())) -> BcM ()
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> (BcM_State, ()) -> IO (BcM_State, ())
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st{ffis :: [FFIInfo]
ffis = RemotePtr C_ffi_cif -> FFIInfo
FFIInfo RemotePtr C_ffi_cif
a FFIInfo -> [FFIInfo] -> [FFIInfo]
forall a. a -> [a] -> [a]
: BcM_State -> [FFIInfo]
ffis BcM_State
st}, ())
getLabelBc :: BcM Word16
getLabelBc :: BcM Word16
getLabelBc
= (BcM_State -> IO (BcM_State, Word16)) -> BcM Word16
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, Word16)) -> BcM Word16)
-> (BcM_State -> IO (BcM_State, Word16)) -> BcM Word16
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> do let nl :: Word16
nl = BcM_State -> Word16
nextlabel BcM_State
st
Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when (Word16
nl Word16 -> Word16 -> Bool
forall a. Eq a => a -> a -> Bool
== Word16
forall a. Bounded a => a
maxBound) (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$
String -> IO ()
forall a. String -> a
panic String
"getLabelBc: Ran out of labels"
(BcM_State, Word16) -> IO (BcM_State, Word16)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st{nextlabel :: Word16
nextlabel = Word16
nl Word16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
+ Word16
1}, Word16
nl)
getLabelsBc :: Word16 -> BcM [Word16]
getLabelsBc :: Word16 -> BcM [Word16]
getLabelsBc Word16
n
= (BcM_State -> IO (BcM_State, [Word16])) -> BcM [Word16]
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, [Word16])) -> BcM [Word16])
-> (BcM_State -> IO (BcM_State, [Word16])) -> BcM [Word16]
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> let ctr :: Word16
ctr = BcM_State -> Word16
nextlabel BcM_State
st
in (BcM_State, [Word16]) -> IO (BcM_State, [Word16])
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st{nextlabel :: Word16
nextlabel = Word16
ctrWord16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
+Word16
n}, [Word16
ctr .. Word16
ctrWord16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
+Word16
nWord16 -> Word16 -> Word16
forall a. Num a => a -> a -> a
-Word16
1])
getCCArray :: BcM (Array BreakIndex (RemotePtr CostCentre))
getCCArray :: BcM (Array Int (RemotePtr CostCentre))
getCCArray = (BcM_State -> IO (BcM_State, Array Int (RemotePtr CostCentre)))
-> BcM (Array Int (RemotePtr CostCentre))
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, Array Int (RemotePtr CostCentre)))
-> BcM (Array Int (RemotePtr CostCentre)))
-> (BcM_State -> IO (BcM_State, Array Int (RemotePtr CostCentre)))
-> BcM (Array Int (RemotePtr CostCentre))
forall a b. (a -> b) -> a -> b
$ \BcM_State
st ->
let breaks :: ModBreaks
breaks = String -> Maybe ModBreaks -> ModBreaks
forall a. HasCallStack => String -> Maybe a -> a
expectJust String
"ByteCodeGen.getCCArray" (Maybe ModBreaks -> ModBreaks) -> Maybe ModBreaks -> ModBreaks
forall a b. (a -> b) -> a -> b
$ BcM_State -> Maybe ModBreaks
modBreaks BcM_State
st in
(BcM_State, Array Int (RemotePtr CostCentre))
-> IO (BcM_State, Array Int (RemotePtr CostCentre))
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, ModBreaks -> Array Int (RemotePtr CostCentre)
modBreaks_ccs ModBreaks
breaks)
newBreakInfo :: BreakIndex -> CgBreakInfo -> BcM ()
newBreakInfo :: Int -> CgBreakInfo -> BcM ()
newBreakInfo Int
ix CgBreakInfo
info = (BcM_State -> IO (BcM_State, ())) -> BcM ()
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, ())) -> BcM ())
-> (BcM_State -> IO (BcM_State, ())) -> BcM ()
forall a b. (a -> b) -> a -> b
$ \BcM_State
st ->
(BcM_State, ()) -> IO (BcM_State, ())
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st{breakInfo :: IntMap CgBreakInfo
breakInfo = Int -> CgBreakInfo -> IntMap CgBreakInfo -> IntMap CgBreakInfo
forall a. Int -> a -> IntMap a -> IntMap a
IntMap.insert Int
ix CgBreakInfo
info (BcM_State -> IntMap CgBreakInfo
breakInfo BcM_State
st)}, ())
newUnique :: BcM Unique
newUnique :: BcM Unique
newUnique = (BcM_State -> IO (BcM_State, Unique)) -> BcM Unique
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, Unique)) -> BcM Unique)
-> (BcM_State -> IO (BcM_State, Unique)) -> BcM Unique
forall a b. (a -> b) -> a -> b
$
\BcM_State
st -> case UniqSupply -> (Unique, UniqSupply)
takeUniqFromSupply (BcM_State -> UniqSupply
uniqSupply BcM_State
st) of
(Unique
uniq, UniqSupply
us) -> let newState :: BcM_State
newState = BcM_State
st { uniqSupply :: UniqSupply
uniqSupply = UniqSupply
us }
in (BcM_State, Unique) -> IO (BcM_State, Unique)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
newState, Unique
uniq)
getCurrentModule :: BcM Module
getCurrentModule :: BcM Module
getCurrentModule = (BcM_State -> IO (BcM_State, Module)) -> BcM Module
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, Module)) -> BcM Module)
-> (BcM_State -> IO (BcM_State, Module)) -> BcM Module
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> (BcM_State, Module) -> IO (BcM_State, Module)
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, BcM_State -> Module
thisModule BcM_State
st)
getTopStrings :: BcM (IdEnv (RemotePtr ()))
getTopStrings :: BcM (IdEnv (RemotePtr ()))
getTopStrings = (BcM_State -> IO (BcM_State, IdEnv (RemotePtr ())))
-> BcM (IdEnv (RemotePtr ()))
forall r. (BcM_State -> IO (BcM_State, r)) -> BcM r
BcM ((BcM_State -> IO (BcM_State, IdEnv (RemotePtr ())))
-> BcM (IdEnv (RemotePtr ())))
-> (BcM_State -> IO (BcM_State, IdEnv (RemotePtr ())))
-> BcM (IdEnv (RemotePtr ()))
forall a b. (a -> b) -> a -> b
$ \BcM_State
st -> (BcM_State, IdEnv (RemotePtr ()))
-> IO (BcM_State, IdEnv (RemotePtr ()))
forall (m :: * -> *) a. Monad m => a -> m a
return (BcM_State
st, BcM_State -> IdEnv (RemotePtr ())
topStrings BcM_State
st)
newId :: Type -> BcM Id
newId :: Type -> BcM CoreBndr
newId Type
ty = do
Unique
uniq <- BcM Unique
newUnique
CoreBndr -> BcM CoreBndr
forall (m :: * -> *) a. Monad m => a -> m a
return (CoreBndr -> BcM CoreBndr) -> CoreBndr -> BcM CoreBndr
forall a b. (a -> b) -> a -> b
$ FastString -> Unique -> Type -> CoreBndr
mkSysLocal FastString
tickFS Unique
uniq Type
ty
tickFS :: FastString
tickFS :: FastString
tickFS = String -> FastString
fsLit String
"ticked"