1 {-# OPTIONS_GHC -fno-implicit-prelude #-}
2 -----------------------------------------------------------------------------
4 -- Module : GHC.ForeignPtr
5 -- Copyright : (c) The University of Glasgow, 1992-2003
6 -- License : see libraries/base/LICENSE
8 -- Maintainer : cvs-ghc@haskell.org
9 -- Stability : internal
10 -- Portability : non-portable (GHC extensions)
12 -- GHC's implementation of the 'ForeignPtr' data type.
14 -----------------------------------------------------------------------------
23 mallocForeignPtrBytes,
24 addForeignPtrFinalizer,
26 unsafeForeignPtrToPtr,
29 addForeignPtrConcFinalizer,
33 import Control.Monad ( sequence_ )
35 import Foreign.Storable
37 import GHC.List ( null )
40 import GHC.STRef ( STRef(..) )
41 import GHC.Ptr ( Ptr(..) )
45 -- |The type 'ForeignPtr' represents references to objects that are
46 -- maintained in a foreign language, i.e., that are not part of the
47 -- data structures usually managed by the Haskell storage manager.
48 -- The essential difference between 'ForeignPtr's and vanilla memory
49 -- references of type @Ptr a@ is that the former may be associated
50 -- with /finalizers/. A finalizer is a routine that is invoked when
51 -- the Haskell storage manager detects that - within the Haskell heap
52 -- and stack - there are no more references left that are pointing to
53 -- the 'ForeignPtr'. Typically, the finalizer will, then, invoke
54 -- routines in the foreign language that free the resources bound by
55 -- the foreign object.
57 -- The 'ForeignPtr' is parameterised in the same way as 'Ptr'. The
58 -- type argument of 'ForeignPtr' should normally be an instance of
61 data ForeignPtr a = ForeignPtr Addr# ForeignPtrContents
62 -- we cache the Addr# in the ForeignPtr object, but attach
63 -- the finalizer to the IORef (or the MutableByteArray# in
64 -- the case of a MallocPtr). The aim of the representation
65 -- is to make withForeignPtr efficient; in fact, withForeignPtr
66 -- should be just as efficient as unpacking a Ptr, and multiple
67 -- withForeignPtrs can share an unpacked ForeignPtr. Note
68 -- that touchForeignPtr only has to touch the ForeignPtrContents
69 -- object, because that ensures that whatever the finalizer is
70 -- attached to is kept alive.
72 data ForeignPtrContents
73 = PlainForeignPtr !(IORef [IO ()])
74 | MallocPtr (MutableByteArray# RealWorld) !(IORef [IO ()])
76 instance Eq (ForeignPtr a) where
77 p == q = unsafeForeignPtrToPtr p == unsafeForeignPtrToPtr q
79 instance Ord (ForeignPtr a) where
80 compare p q = compare (unsafeForeignPtrToPtr p) (unsafeForeignPtrToPtr q)
82 instance Show (ForeignPtr a) where
83 showsPrec p f = showsPrec p (unsafeForeignPtrToPtr f)
85 -- |A Finalizer is represented as a pointer to a foreign function that, at
86 -- finalisation time, gets as an argument a plain pointer variant of the
87 -- foreign pointer that the finalizer is associated with.
89 type FinalizerPtr a = FunPtr (Ptr a -> IO ())
91 newConcForeignPtr :: Ptr a -> IO () -> IO (ForeignPtr a)
93 -- ^Turns a plain memory reference into a foreign object by
94 -- associating a finalizer - given by the monadic operation - with the
95 -- reference. The storage manager will start the finalizer, in a
96 -- separate thread, some time after the last reference to the
97 -- @ForeignPtr@ is dropped. There is no guarantee of promptness, and
98 -- in fact there is no guarantee that the finalizer will eventually
101 newConcForeignPtr p finalizer
102 = do fObj <- newForeignPtr_ p
103 addForeignPtrConcFinalizer fObj finalizer
106 mallocForeignPtr :: Storable a => IO (ForeignPtr a)
107 -- ^ Allocate some memory and return a 'ForeignPtr' to it. The memory
108 -- will be released automatically when the 'ForeignPtr' is discarded.
110 -- 'mallocForeignPtr' is equivalent to
112 -- > do { p <- malloc; newForeignPtr finalizerFree p }
114 -- although it may be implemented differently internally: you may not
115 -- assume that the memory returned by 'mallocForeignPtr' has been
116 -- allocated with 'Foreign.Marshal.Alloc.malloc'.
117 mallocForeignPtr = doMalloc undefined
118 where doMalloc :: Storable b => b -> IO (ForeignPtr b)
122 case newPinnedByteArray# size s of { (# s, mbarr# #) ->
123 (# s, ForeignPtr (byteArrayContents# (unsafeCoerce# mbarr#))
124 (MallocPtr mbarr# r) #)
126 where (I# size) = sizeOf a
128 -- | This function is similar to 'mallocForeignPtr', except that the
129 -- size of the memory required is given explicitly as a number of bytes.
130 mallocForeignPtrBytes :: Int -> IO (ForeignPtr a)
131 mallocForeignPtrBytes (I# size) = do
134 case newPinnedByteArray# size s of { (# s, mbarr# #) ->
135 (# s, ForeignPtr (byteArrayContents# (unsafeCoerce# mbarr#))
136 (MallocPtr mbarr# r) #)
139 addForeignPtrFinalizer :: FinalizerPtr a -> ForeignPtr a -> IO ()
140 -- ^This function adds a finalizer to the given foreign object. The
141 -- finalizer will run /before/ all other finalizers for the same
142 -- object which have already been registered.
143 addForeignPtrFinalizer finalizer fptr =
144 addForeignPtrConcFinalizer fptr
145 (mkFinalizer finalizer (unsafeForeignPtrToPtr fptr))
147 addForeignPtrConcFinalizer :: ForeignPtr a -> IO () -> IO ()
148 -- ^This function adds a finalizer to the given @ForeignPtr@. The
149 -- finalizer will run /before/ all other finalizers for the same
150 -- object which have already been registered.
152 -- This is a variant of @addForeignPtrFinalizer@, where the finalizer
153 -- is an arbitrary @IO@ action. When it is invoked, the finalizer
154 -- will run in a new thread.
156 -- NB. Be very careful with these finalizers. One common trap is that
157 -- if a finalizer references another finalized value, it does not
158 -- prevent that value from being finalized. In particular, 'Handle's
159 -- are finalized objects, so a finalizer should not refer to a 'Handle'
160 -- (including @stdout@, @stdin@ or @stderr@).
162 addForeignPtrConcFinalizer (ForeignPtr a c) finalizer =
163 addForeignPtrConcFinalizer_ c finalizer
165 addForeignPtrConcFinalizer_ f@(PlainForeignPtr r) finalizer = do
167 writeIORef r (finalizer : fs)
170 case r of { IORef (STRef r#) ->
171 case mkWeak# r# () (foreignPtrFinalizer r) s of { (# s1, w #) ->
174 addForeignPtrConcFinalizer_ f@(MallocPtr fo r) finalizer = do
176 writeIORef r (finalizer : fs)
179 case mkWeak# fo () (do foreignPtrFinalizer r; touch f) s of
180 (# s1, w #) -> (# s1, () #)
183 foreign import ccall "dynamic"
184 mkFinalizer :: FinalizerPtr a -> Ptr a -> IO ()
186 foreignPtrFinalizer :: IORef [IO ()] -> IO ()
187 foreignPtrFinalizer r = do fs <- readIORef r; sequence_ fs
189 newForeignPtr_ :: Ptr a -> IO (ForeignPtr a)
190 -- ^Turns a plain memory reference into a foreign pointer that may be
191 -- associated with finalizers by using 'addForeignPtrFinalizer'.
192 newForeignPtr_ (Ptr obj) = do
194 return (ForeignPtr obj (PlainForeignPtr r))
196 touchForeignPtr :: ForeignPtr a -> IO ()
197 -- ^This function ensures that the foreign object in
198 -- question is alive at the given place in the sequence of IO
199 -- actions. In particular 'Foreign.ForeignPtr.withForeignPtr'
200 -- does a 'touchForeignPtr' after it
201 -- executes the user action.
203 -- Note that this function should not be used to express liveness
204 -- dependencies between 'ForeignPtr's. For example, if the finalizer
205 -- for a 'ForeignPtr' @F1@ calls 'touchForeignPtr' on a second
206 -- 'ForeignPtr' @F2@, then the only guarantee is that the finalizer
207 -- for @F2@ is never started before the finalizer for @F1@. They
208 -- might be started together if for example both @F1@ and @F2@ are
209 -- otherwise unreachable, and in that case the scheduler might end up
210 -- running the finalizer for @F2@ first.
212 -- In general, it is not recommended to use finalizers on separate
213 -- objects with ordering constraints between them. To express the
214 -- ordering robustly requires explicit synchronisation using @MVar@s
215 -- between the finalizers, but even then the runtime sometimes runs
216 -- multiple finalizers sequentially in a single thread (for
217 -- performance reasons), so synchronisation between finalizers could
218 -- result in artificial deadlock.
220 touchForeignPtr (ForeignPtr fo r) = touch r
222 touch r = IO $ \s -> case touch# r s of s -> (# s, () #)
224 unsafeForeignPtrToPtr :: ForeignPtr a -> Ptr a
225 -- ^This function extracts the pointer component of a foreign
226 -- pointer. This is a potentially dangerous operations, as if the
227 -- argument to 'unsafeForeignPtrToPtr' is the last usage
228 -- occurrence of the given foreign pointer, then its finalizer(s) will
229 -- be run, which potentially invalidates the plain pointer just
230 -- obtained. Hence, 'touchForeignPtr' must be used
231 -- wherever it has to be guaranteed that the pointer lives on - i.e.,
232 -- has another usage occurrence.
234 -- To avoid subtle coding errors, hand written marshalling code
235 -- should preferably use 'Foreign.ForeignPtr.withForeignPtr' rather
236 -- than combinations of 'unsafeForeignPtrToPtr' and
237 -- 'touchForeignPtr'. However, the later routines
238 -- are occasionally preferred in tool generated marshalling code.
239 unsafeForeignPtrToPtr (ForeignPtr fo r) = Ptr fo
241 castForeignPtr :: ForeignPtr a -> ForeignPtr b
242 -- ^This function casts a 'ForeignPtr'
243 -- parameterised by one type into another type.
244 castForeignPtr f = unsafeCoerce# f
246 -- | Causes the finalizers associated with a foreign pointer to be run
248 finalizeForeignPtr :: ForeignPtr a -> IO ()
249 finalizeForeignPtr (ForeignPtr _ foreignPtr) = do
250 finalizers <- readIORef refFinalizers
252 writeIORef refFinalizers []
254 refFinalizers = case foreignPtr of
255 (PlainForeignPtr ref) -> ref
256 (MallocPtr _ ref) -> ref