{-# LANGUAGE OverloadedStrings #-}
-{-# LANGUAGE ForeignFunctionInterface #-}
+{-# LANGUAGE CPP #-}
module Mate.Types where
-import Data.Char
import Data.Word
import Data.Int
import qualified Data.Map as M
import qualified Data.ByteString.Lazy as B
-import Codec.Binary.UTF8.String hiding (encode,decode)
-import Foreign.Ptr
-import Foreign.StablePtr
+import Data.IORef
+import System.IO.Unsafe
import JVM.ClassFile
import JVM.Assembler
type MapBB = M.Map BlockID BasicBlock
+data RawMethod = RawMethod {
+ rawMapBB :: MapBB,
+ rawLocals :: Int,
+ rawStackSize :: Int,
+ rawArgCount :: Word32 }
-- Word32 = point of method call in generated code
-- MethodInfo = relevant information about callee
-type TrapMap = M.Map Word32 TrapInfo
+type TrapMap = M.Map Word32 TrapCause
-data TrapInfo =
- MI MethodInfo | -- for static calls
- VI MethodInfo | -- for virtual calls
- II MethodInfo | -- for interface calls
- SFI StaticFieldInfo deriving Show
+data TrapCause =
+ StaticMethod MethodInfo | -- for static calls
+ VirtualMethod Bool MethodInfo | -- for virtual calls
+ InterfaceMethod Bool MethodInfo | -- for interface calls
+ InstanceOf B.ByteString | -- class name
+ StaticField StaticFieldInfo deriving Show
data StaticFieldInfo = StaticFieldInfo {
sfiClassName :: B.ByteString,
methSignature :: MethodSignature
} deriving (Eq, Ord)
--- TODO(bernhard): not really efficient. also, outsource that to hs-java
--- deriving should be enough?
-instance Ord MethodSignature where
- compare (MethodSignature args_a ret_a) (MethodSignature args_b ret_b)
- | cmp_args /= EQ = cmp_args
- | otherwise = show ret_a `compare` show ret_b
- where cmp_args = show args_a `compare` show args_b
-
instance Show MethodInfo where
show (MethodInfo method c sig) =
toString c ++ "." ++ toString method ++ "." ++ show sig
data ClassInfo = ClassInfo {
ciName :: B.ByteString,
- ciFile :: Class Resolved,
+ ciFile :: Class Direct,
ciStaticMap :: FieldMap,
ciFieldMap :: FieldMap,
ciMethodMap :: FieldMap,
-- store each parsed Interface upon first loading
-type InterfaceMap = M.Map B.ByteString (Class Resolved)
+type InterfaceMap = M.Map B.ByteString (Class Direct)
-- store offset for each <Interface><Method><Signature> pair
type InterfaceMethodMap = M.Map B.ByteString Word32
+{-
toString :: B.ByteString -> String
toString bstr = decodeString $ map (chr . fromIntegral) $ B.unpack bstr
+-}
-
--- those functions are for the "global map hax"
--- TODO(bernhard): other solution please
-foreign import ccall "set_mate_context"
- set_mate_context :: Ptr () -> IO ()
-
-foreign import ccall "get_mate_context"
- get_mate_context :: IO (Ptr ())
+-- better solutions for a global map hack are welcome! (typeclasses, TH, ...?)
data MateCtx = MateCtx {
ctxMethodMap :: MethodMap,
emptyMateCtx :: MateCtx
emptyMateCtx = MateCtx M.empty M.empty M.empty M.empty M.empty M.empty M.empty
-ctx2ptr :: MateCtx -> IO (Ptr ())
-ctx2ptr ctx = do
- ptr <- newStablePtr ctx
- return $ castStablePtrToPtr ptr
-
-ptr2ctx :: Ptr () -> IO MateCtx
-ptr2ctx ptr = deRefStablePtr (castPtrToStablePtr ptr :: StablePtr MateCtx)
-
-
-setMethodMap :: MethodMap -> IO ()
-setMethodMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxMethodMap = m } >>= set_mate_context
-
-getMethodMap :: IO MethodMap
-getMethodMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxMethodMap ctx
-
-
-setTrapMap :: TrapMap -> IO ()
-setTrapMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxTrapMap = m } >>= set_mate_context
-
-getTrapMap :: IO TrapMap
-getTrapMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxTrapMap ctx
-
-
-setClassMap :: ClassMap -> IO ()
-setClassMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxClassMap = m } >>= set_mate_context
-
-getClassMap :: IO ClassMap
-getClassMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxClassMap ctx
-
-
-setVirtualMap :: VirtualMap -> IO ()
-setVirtualMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxVirtualMap = m } >>= set_mate_context
-
-getVirtualMap :: IO VirtualMap
-getVirtualMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxVirtualMap ctx
+mateCtx :: IORef MateCtx
+{-# NOINLINE mateCtx #-}
+mateCtx = unsafePerformIO $ newIORef emptyMateCtx
+-- TODO(bernhard): if we ever have thread support, don't forget MVars
+#define SETMAP(name) set##name :: name -> IO (); \
+ set##name m = do ctx <- readIORef mateCtx; \
+ writeIORef mateCtx $ ctx { ctx##name = m };
-setStringMap :: StringMap -> IO ()
-setStringMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxStringMap = m } >>= set_mate_context
+#define GETMAP(name) get##name :: IO name ; \
+ get##name = do ctx <- readIORef mateCtx; \
+ return $ ctx##name ctx;
-getStringMap :: IO StringMap
-getStringMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxStringMap ctx
+SETMAP(MethodMap);
+GETMAP(MethodMap)
+SETMAP(TrapMap)
+GETMAP(TrapMap)
-setInterfaceMap :: InterfaceMap -> IO ()
-setInterfaceMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxInterfaceMap = m } >>= set_mate_context
+SETMAP(ClassMap)
+GETMAP(ClassMap)
-getInterfaceMap :: IO InterfaceMap
-getInterfaceMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxInterfaceMap ctx
+SETMAP(VirtualMap)
+GETMAP(VirtualMap)
+SETMAP(StringMap)
+GETMAP(StringMap)
-setInterfaceMethodMap :: InterfaceMethodMap -> IO ()
-setInterfaceMethodMap m = do
- ctx <- get_mate_context >>= ptr2ctx
- ctx2ptr ctx { ctxInterfaceMethodMap = m } >>= set_mate_context
+SETMAP(InterfaceMap)
+GETMAP(InterfaceMap)
-getInterfaceMethodMap :: IO InterfaceMethodMap
-getInterfaceMethodMap = do
- ctx <- get_mate_context >>= ptr2ctx
- return $ ctxInterfaceMethodMap ctx
+SETMAP(InterfaceMethodMap)
+GETMAP(InterfaceMethodMap)