1162 lines
54 KiB
Plaintext
1162 lines
54 KiB
Plaintext
<chapter id="ole">
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<title>COM in Wine</title>
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<sect1 id="com-writing">
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<title>Writing COM Components for Wine</title>
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<para>
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This section describes how to create your own natively
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compiled COM components.
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</para>
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<sect2>
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<title>Macros to define a COM interface</title>
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<para>
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The goal of the following set of definitions is to provide a
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way to use the same header file definitions to provide both
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a C interface and a C++ object oriented interface to COM
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interfaces. The type of interface is selected automatically
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depending on the language but it is always possible to get
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the C interface in C++ by defining CINTERFACE.
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</para>
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<para>
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It is based on the following assumptions:
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</para>
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<itemizedlist>
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<listitem>
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<para>
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all COM interfaces derive from IUnknown, this should not
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be a problem.
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</para>
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</listitem>
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<listitem>
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<para>
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the header file only defines the interface, the actual
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fields are defined separately in the C file implementing
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the interface.
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</para>
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</listitem>
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</itemizedlist>
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<para>
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The natural approach to this problem would be to make sure
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we get a C++ class and virtual methods in C++ and a
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structure with a table of pointer to functions in C.
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Unfortunately the layout of the virtual table is compiler
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specific, the layout of g++ virtual tables is not the same
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as that of an egcs virtual table which is not the same as
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that generated by Visual C++. There are work arounds to make
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the virtual tables compatible via padding but unfortunately
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the one which is imposed to the Wine emulator by the Windows
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binaries, i.e. the Visual C++ one, is the most compact of
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all.
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</para>
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<para>
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So the solution I finally adopted does not use virtual
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tables. Instead I use in-line non virtual methods that
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dereference the method pointer themselves and perform the
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call.
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</para>
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<para>
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Let's take Direct3D as an example:
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</para>
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<programlisting>#define ICOM_INTERFACE IDirect3D
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#define IDirect3D_METHODS \
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ICOM_METHOD1(HRESULT,Initialize, REFIID,) \
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ICOM_METHOD2(HRESULT,EnumDevices, LPD3DENUMDEVICESCALLBACK,, LPVOID,) \
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ICOM_METHOD2(HRESULT,CreateLight, LPDIRECT3DLIGHT*,, IUnknown*,) \
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ICOM_METHOD2(HRESULT,CreateMaterial,LPDIRECT3DMATERIAL*,, IUnknown*,) \
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ICOM_METHOD2(HRESULT,CreateViewport,LPDIRECT3DVIEWPORT*,, IUnknown*,) \
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ICOM_METHOD2(HRESULT,FindDevice, LPD3DFINDDEVICESEARCH,, LPD3DFINDDEVICERESULT,)
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#define IDirect3D_IMETHODS \
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IUnknown_IMETHODS \
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IDirect3D_METHODS
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ICOM_DEFINE(IDirect3D,IUnknown)
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#undef ICOM_INTERFACE
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#ifdef ICOM_CINTERFACE
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// *** IUnknown methods *** //
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#define IDirect3D_QueryInterface(p,a,b) ICOM_CALL2(QueryInterface,p,a,b)
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#define IDirect3D_AddRef(p) ICOM_CALL (AddRef,p)
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#define IDirect3D_Release(p) ICOM_CALL (Release,p)
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// *** IDirect3D methods *** //
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#define IDirect3D_Initialize(p,a) ICOM_CALL1(Initialize,p,a)
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#define IDirect3D_EnumDevices(p,a,b) ICOM_CALL2(EnumDevice,p,a,b)
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#define IDirect3D_CreateLight(p,a,b) ICOM_CALL2(CreateLight,p,a,b)
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#define IDirect3D_CreateMaterial(p,a,b) ICOM_CALL2(CreateMaterial,p,a,b)
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#define IDirect3D_CreateViewport(p,a,b) ICOM_CALL2(CreateViewport,p,a,b)
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#define IDirect3D_FindDevice(p,a,b) ICOM_CALL2(FindDevice,p,a,b)
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#endif</programlisting>
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<para>
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Comments:
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</para>
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<para>
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The ICOM_INTERFACE macro is used in the ICOM_METHOD macros
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to define the type of the 'this' pointer. Defining this
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macro here saves us the trouble of having to repeat the
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interface name everywhere. Note however that because of the
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way macros work, a macro like ICOM_METHOD1 cannot use
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'ICOM_INTERFACE##_VTABLE' because this would give
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'ICOM_INTERFACE_VTABLE' and not 'IDirect3D_VTABLE'.
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</para>
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<para>
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ICOM_METHODS defines the methods specific to this
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interface. It is then aggregated with the inherited methods
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to form ICOM_IMETHODS.
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</para>
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<para>
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ICOM_IMETHODS defines the list of methods that are
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inheritable from this interface. It must be written manually
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(rather than using a macro to generate the equivalent code)
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to avoid macro recursion (which compilers don't like).
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</para>
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<para>
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The ICOM_DEFINE finally declares all the structures
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necessary for the interface. We have to explicitly use the
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interface name for macro expansion reasons again. Inherited
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methods are inherited in C by using the IDirect3D_METHODS
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macro and the parent's Xxx_IMETHODS macro. In C++ we need
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only use the IDirect3D_METHODS since method inheritance is
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taken care of by the language.
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</para>
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<para>
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In C++ the ICOM_METHOD macros generate a function prototype
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and a call to a function pointer method. This means using
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once 't1 p1, t2 p2, ...' and once 'p1, p2' without the
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types. The only way I found to handle this is to have one
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ICOM_METHOD macro per number of parameters and to have it
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take only the type information (with const if necessary) as
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parameters. The 'undef ICOM_INTERFACE' is here to remind
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you that using ICOM_INTERFACE in the following macros will
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not work. This time it's because the ICOM_CALL macro
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expansion is done only once the 'IDirect3D_Xxx' macro is
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expanded. And by that time ICOM_INTERFACE will be long gone
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anyway.
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</para>
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<para>
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You may have noticed the double commas after each parameter
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type. This allows you to put the name of that parameter
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which I think is good for documentation. It is not required
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and since I did not know what to put there for this example
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(I could only find doc about IDirect3D2), I left them blank.
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</para>
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<para>
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Finally the set of 'IDirect3D_Xxx' macros is a standard set
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of macros defined to ease access to the interface methods in
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C. Unfortunately I don't see any way to avoid having to
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duplicate the inherited method definitions there. This time
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I could have used a trick to use only one macro whatever the
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number of parameters but I preferred to have it work the same
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way as above.
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</para>
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<para>
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You probably have noticed that we don't define the fields we
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need to actually implement this interface: reference count,
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pointer to other resources and miscellaneous fields. That's
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because these interfaces are just that: interfaces. They may
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be implemented more than once, in different contexts and
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sometimes not even in Wine. Thus it would not make sense to
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impose that the interface contains some specific fields.
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</para>
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</sect2>
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<sect2>
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<title>Bindings in C</title>
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<para>
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In C this gives:
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</para>
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<programlisting>typedef struct IDirect3DVtbl IDirect3DVtbl;
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struct IDirect3D {
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IDirect3DVtbl* lpVtbl;
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};
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struct IDirect3DVtbl {
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HRESULT (*fnQueryInterface)(IDirect3D* me, REFIID riid, LPVOID* ppvObj);
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ULONG (*fnAddRef)(IDirect3D* me);
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ULONG (*fnRelease)(IDirect3D* me);
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HRESULT (*fnInitialize)(IDirect3D* me, REFIID a);
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HRESULT (*fnEnumDevices)(IDirect3D* me, LPD3DENUMDEVICESCALLBACK a, LPVOID b);
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HRESULT (*fnCreateLight)(IDirect3D* me, LPDIRECT3DLIGHT* a, IUnknown* b);
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HRESULT (*fnCreateMaterial)(IDirect3D* me, LPDIRECT3DMATERIAL* a, IUnknown* b);
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HRESULT (*fnCreateViewport)(IDirect3D* me, LPDIRECT3DVIEWPORT* a, IUnknown* b);
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HRESULT (*fnFindDevice)(IDirect3D* me, LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b);
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};
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#ifdef ICOM_CINTERFACE
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// *** IUnknown methods *** //
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#define IDirect3D_QueryInterface(p,a,b) (p)->lpVtbl->fnQueryInterface(p,a,b)
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#define IDirect3D_AddRef(p) (p)->lpVtbl->fnAddRef(p)
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#define IDirect3D_Release(p) (p)->lpVtbl->fnRelease(p)
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// *** IDirect3D methods *** //
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#define IDirect3D_Initialize(p,a) (p)->lpVtbl->fnInitialize(p,a)
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#define IDirect3D_EnumDevices(p,a,b) (p)->lpVtbl->fnEnumDevice(p,a,b)
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#define IDirect3D_CreateLight(p,a,b) (p)->lpVtbl->fnCreateLight(p,a,b)
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#define IDirect3D_CreateMaterial(p,a,b) (p)->lpVtbl->fnCreateMaterial(p,a,b)
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#define IDirect3D_CreateViewport(p,a,b) (p)->lpVtbl->fnCreateViewport(p,a,b)
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#define IDirect3D_FindDevice(p,a,b) (p)->lpVtbl->fnFindDevice(p,a,b)
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#endif</programlisting>
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<para>
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Comments:
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</para>
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<para>
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IDirect3D only contains a pointer to the IDirect3D
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virtual/jump table. This is the only thing the user needs to
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know to use the interface. Of course the structure we will
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define to implement this interface will have more fields but
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the first one will match this pointer.
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</para>
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<para>
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The code generated by ICOM_DEFINE defines both the structure
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representing the interface and the structure for the jump
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table. ICOM_DEFINE uses the parent's Xxx_IMETHODS macro to
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automatically repeat the prototypes of all the inherited
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methods and then uses IDirect3D_METHODS to define the
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IDirect3D methods.
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</para>
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<para>
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Each method is declared as a pointer to function field in
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the jump table. The implementation will fill this jump table
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with appropriate values, probably using a static variable,
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and initialize the lpVtbl field to point to this variable.
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</para>
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<para>
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The IDirect3D_Xxx macros then just dereference the lpVtbl
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pointer and use the function pointer corresponding to the
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macro name. This emulates the behavior of a virtual table
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and should be just as fast.
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</para>
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<para>
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This C code should be quite compatible with the Windows
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headers both for code that uses COM interfaces and for code
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implementing a COM interface.
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</para>
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</sect2>
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<sect2>
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<title>Bindings in C++</title>
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<para>
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And in C++ (with gcc's g++):
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</para>
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<programlisting>typedef struct IDirect3D: public IUnknown {
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private: HRESULT (*fnInitialize)(IDirect3D* me, REFIID a);
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public: inline HRESULT Initialize(REFIID a) { return ((IDirect3D*)t.lpVtbl)->fnInitialize(this,a); };
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private: HRESULT (*fnEnumDevices)(IDirect3D* me, LPD3DENUMDEVICESCALLBACK a, LPVOID b);
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public: inline HRESULT EnumDevices(LPD3DENUMDEVICESCALLBACK a, LPVOID b)
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{ return ((IDirect3D*)t.lpVtbl)->fnEnumDevices(this,a,b); };
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private: HRESULT (*fnCreateLight)(IDirect3D* me, LPDIRECT3DLIGHT* a, IUnknown* b);
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public: inline HRESULT CreateLight(LPDIRECT3DLIGHT* a, IUnknown* b)
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{ return ((IDirect3D*)t.lpVtbl)->fnCreateLight(this,a,b); };
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private: HRESULT (*fnCreateMaterial)(IDirect3D* me, LPDIRECT3DMATERIAL* a, IUnknown* b);
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public: inline HRESULT CreateMaterial(LPDIRECT3DMATERIAL* a, IUnknown* b)
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{ return ((IDirect3D*)t.lpVtbl)->fnCreateMaterial(this,a,b); };
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private: HRESULT (*fnCreateViewport)(IDirect3D* me, LPDIRECT3DVIEWPORT* a, IUnknown* b);
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public: inline HRESULT CreateViewport(LPDIRECT3DVIEWPORT* a, IUnknown* b)
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{ return ((IDirect3D*)t.lpVtbl)->fnCreateViewport(this,a,b); };
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private: HRESULT (*fnFindDevice)(IDirect3D* me, LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b);
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public: inline HRESULT FindDevice(LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b)
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{ return ((IDirect3D*)t.lpVtbl)->fnFindDevice(this,a,b); };
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};</programlisting>
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<para>
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Comments:
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</para>
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<para>
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In C++ IDirect3D does double duty as both the virtual/jump
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table and as the interface definition. The reason for this
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is to avoid having to duplicate the method definitions: once
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to have the function pointers in the jump table and once to
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have the methods in the interface class. Here one macro can
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generate both. This means though that the first pointer,
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t.lpVtbl defined in IUnknown, must be interpreted as the
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jump table pointer if we interpret the structure as the
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interface class, and as the function pointer to the
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QueryInterface method, t.fnQueryInterface, if we interpret
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the structure as the jump table. Fortunately this gymnastic
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is entirely taken care of in the header of IUnknown.
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</para>
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<para>
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Of course in C++ we use inheritance so that we don't have to
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duplicate the method definitions.
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</para>
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<para>
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Since IDirect3D does double duty, each ICOM_METHOD macro
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defines both a function pointer and a non-virtual inline
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method which dereferences it and calls it. This way this
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method behaves just like a virtual method but does not
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create a true C++ virtual table which would break the
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structure layout. If you look at the implementation of these
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methods you'll notice that they would not work for void
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functions. We have to return something and fortunately this
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seems to be what all the COM methods do (otherwise we would
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need another set of macros).
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</para>
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<para>
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Note how the ICOM_METHOD generates both function prototypes
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mixing types and formal parameter names and the method
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invocation using only the formal parameter name. This is the
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reason why we need different macros to handle different
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numbers of parameters.
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</para>
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<para>
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Finally there is no IDirect3D_Xxx macro. These are not
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needed in C++ unless the CINTERFACE macro is defined in
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which case we would not be here.
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</para>
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<para>
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This C++ code works well for code that just uses COM
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interfaces. But it will not work with C++ code implement a
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COM interface. That's because such code assumes the
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interface methods are declared as virtual C++ methods which
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is not the case here.
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</para>
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</sect2>
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<sect2>
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<title>Implementing a COM interface.</title>
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<para>
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This continues the above example. This example assumes that
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the implementation is in C.
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</para>
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<programlisting>typedef struct _IDirect3D {
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void* lpVtbl;
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// ...
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} _IDirect3D;
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static ICOM_VTABLE(IDirect3D) d3dvt;
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// implement the IDirect3D methods here
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int IDirect3D_fnQueryInterface(IDirect3D* me)
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{
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ICOM_THIS(IDirect3D,me);
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// ...
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}
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// ...
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static ICOM_VTABLE(IDirect3D) d3dvt = {
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ICOM_MSVTABLE_COMPAT_DummyRTTIVALUE
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IDirect3D_fnQueryInterface,
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IDirect3D_fnAdd,
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IDirect3D_fnAdd2,
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IDirect3D_fnInitialize,
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IDirect3D_fnSetWidth
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};</programlisting>
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<para>
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Comments:
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</para>
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<para>
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We first define what the interface really contains. This is
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the _IDirect3D structure. The first field must of course be
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the virtual table pointer. Everything else is free.
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</para>
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<para>
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Then we predeclare our static virtual table variable, we
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will need its address in some methods to initialize the
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virtual table pointer of the returned interface objects.
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</para>
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<para>
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Then we implement the interface methods. To match what has
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been declared in the header file they must take a pointer to
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an IDirect3D structure and we must cast it to an _IDirect3D
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so that we can manipulate the fields. This is performed by
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the ICOM_THIS macro.
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</para>
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<para>
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Finally we initialize the virtual table.
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</para>
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</sect2>
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</sect1>
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<sect1 id="dcom-1">
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<title>A brief introduction to DCOM in Wine</title>
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<para>
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This section explains the basic principles behind DCOM remoting as used by InstallShield and others.
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</para>
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<sect2>
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<title>Basics</title>
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<para>
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The basic idea behind DCOM is to take a COM object and make it location
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transparent. That means you can use it from other threads, processes and
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machines without having to worry about the fact that you can't just
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dereference the interface vtable pointer to call methods on it.
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</para>
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<para>
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You might be wondering about putting threads next to processes and
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machines in that last paragraph. You can access thread safe objects from
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multiple threads without DCOM normally, right? Why would you need RPC
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magic to do that?
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</para>
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<para>
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The answer is of course that COM doesn't assume that objects actually
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are thread-safe. Most real-world objects aren't, in fact, for various
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reasons. What these reasons are isn't too important here, though; it's
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just important to realize that the problem of thread-unsafe objects is
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what COM tries hard to solve with its apartment model. There are also
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ways to tell COM that your object is truly thread-safe (namely the
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free-threaded marshaller). In general, no object is truly thread-safe if
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it could potentially use another not so thread-safe object, though, so
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the free-threaded marshaller is less used than you'd think.
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</para>
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<para>
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For now, suffice it to say that COM lets you "marshal" interfaces into
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other "apartments". An apartment (you may see it referred to as a
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context in modern versions of COM) can be thought of as a location, and
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contains objects.
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</para>
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<para>
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Every thread in a program that uses COM exists in an apartment. If a
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thread wishes to use an object from another apartment, marshalling and
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the whole DCOM infrastructure gets involved to make that happen behind
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the scenes.
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</para>
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<para>
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So. Each COM object resides in an apartment, and each apartment
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resides in a process, and each process resides in a machine, and each
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machine resides in a network. Allowing those objects to be used
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from <emphasis>any</emphasis> of these different places is what DCOM
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is all about.
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</para>
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<para>
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The process of marshalling refers to taking a function call in an
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apartment and actually performing it in another apartment. Let's say you
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have two machines, A and B, and on machine B there is an object sitting
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in a DLL on the hard disk. You want to create an instance of that object
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(activate it) and use it as if you had compiled it into your own
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program. This is hard, because the remote object is expecting to be
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called by code in its own address space - it may do things like accept
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pointers to linked lists and even return other objects.
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</para>
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<para>
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Very basic marshalling is easy enough to understand. You take a method
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on a remote interface (that is a COM interface that is
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implemented on the remote computer), copy each of its
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parameters into a buffer, and
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send it to the remote computer. On the other end, the remote server
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reads each parameter from the buffer, calls the method, writes the
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result into another buffer and sends it back.
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</para>
|
|
|
|
<para>
|
|
The tricky part is exactly how to encode those parameters in the buffer,
|
|
and how to convert standard stdcall/cdecl method calls to network
|
|
packets and back again. This is the job of the RPCRT4.DLL file - or the
|
|
Remote Procedure Call Runtime.
|
|
</para>
|
|
|
|
<para>
|
|
The backbone of DCOM is this RPC runtime, which is an implementation
|
|
of <ulink
|
|
url="http://www.opengroup.org/onlinepubs/009629399/toc.htm">DCE
|
|
RPC</ulink>. DCE RPC is not naturally object oriented, so this
|
|
protocol is extended with some new constructs and by assigning new
|
|
meanings to some of the packet fields, to produce ORPC or Object
|
|
RPC. You might see it called MS-RPC as well.
|
|
</para>
|
|
|
|
<para>
|
|
RPC packets contain a buffer containing marshalled data in NDR format.
|
|
NDR is short for "Network Data Representation" and is similar
|
|
to the XDR
|
|
format used in SunRPC (the closest native equivalent on Linux to DCE
|
|
RPC). NDR/XDR are all based on the idea of graph serialization and were
|
|
worked out during the 80s, meaning they are very powerful and can do
|
|
things like marshal doubly linked lists and other rather tricky
|
|
structures.
|
|
</para>
|
|
|
|
<para>
|
|
In Wine, our DCOM implementation is <emphasis>not</emphasis>
|
|
currently based on the
|
|
RPC runtime, as while few programs use DCOM even fewer use
|
|
RPC directly so it was developed some time after
|
|
OLE32/OLEAUT32 were. Eventually this will have to be fixed,
|
|
otherwise our DCOM will never be compatible with
|
|
Microsoft's. Bear this in mind as you read through the code
|
|
however.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Proxies and Stubs</title>
|
|
|
|
<para>
|
|
Manually marshalling and unmarshalling each method call using the NDR
|
|
APIs (NdrConformantArrayMarshall etc) is very tedious work, so the
|
|
Platform SDK ships with a tool called "midl" which is an IDL compiler.
|
|
IDL or the "Interface Definition Language" is a tool designed
|
|
specifically for describing interfaces in a reasonably language neutral
|
|
fashion, though in reality it bears a close resemblence to C++.
|
|
</para>
|
|
|
|
<para>
|
|
By describing the functions you want to expose via RPC in IDL therefore,
|
|
it becomes possible to pass this file to MIDL which spits out a huge
|
|
amount of C source code. That code defines functions which have the same
|
|
prototype as the functions described in your IDL but which internally
|
|
take each argument, marshal it using Ndr, send the packet, and unmarshal
|
|
the return.
|
|
</para>
|
|
|
|
<para>
|
|
Because this code proxies the code from the client to the server, the
|
|
functions are called proxies. Easy, right?
|
|
</para>
|
|
|
|
<para>
|
|
Of course, in the RPC server process at the other end, you need some way
|
|
to unmarshal the RPCs, so you have functions also generated by MIDL
|
|
which are the inverse of the proxies; they accept an NDR buffer, extract
|
|
the parameters, call the real function and then marshal the result back.
|
|
They are called stubs, and stand in for the real calling code in the
|
|
client process.
|
|
</para>
|
|
|
|
<para>
|
|
The sort of marshalling/unmarshalling code that MIDL spits out can be
|
|
seen in dlls/oleaut32/oaidl_p.c - it's not exactly what it would look
|
|
like as that file contains DCOM proxies/stubs which are different, but
|
|
you get the idea. Proxy functions take the arguments and feed them to
|
|
the NDR marshallers (or picklers), invoke an NdrProxySendReceive and
|
|
then convert the out parameters and return code. There's a ton of goop
|
|
in there for dealing with buffer allocation, exceptions and so on - it's
|
|
really ugly code. But, this is the basic concept behind DCE RPC.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Interface Marshalling</title>
|
|
|
|
<para>
|
|
Standard NDR only knows about C style function calls - they
|
|
can accept and even return structures, but it has no concept
|
|
of COM interfaces. Confusingly DCE RPC <emphasis>does</emphasis> have a
|
|
concept of RPC interfaces which are just convenient ways to
|
|
bundle function calls together into namespaces, but let's
|
|
ignore that for now as it just muddies the water. The
|
|
primary extension made by Microsoft to NDR then was the
|
|
ability to take a COM interface pointer and marshal that
|
|
into the NDR stream.
|
|
</para>
|
|
|
|
<para>
|
|
The basic theory of proxies and stubs and IDL is still here, but it's
|
|
been modified slightly. Whereas before you could define a bunch of
|
|
functions in IDL, now a new "object" keyword has appeared. This tells
|
|
MIDL that you're describing a COM interface, and as a result the
|
|
proxies/stubs it generates are also COM objects.
|
|
</para>
|
|
|
|
<para>
|
|
That's a very important distinction. When you make a call to a remote
|
|
COM object you do it via a proxy object that COM has constructed on the
|
|
fly. Likewise, a stub object on the remote end unpacks the RPC packet
|
|
and makes the call.
|
|
</para>
|
|
|
|
<para>
|
|
Because this is object-oriented RPC, there are a few complications: for
|
|
instance, a call that goes via the same proxies/stubs may end up at a
|
|
different object instance, so the RPC runtime keeps track of "this" and
|
|
"that" in the RPC packets.
|
|
</para>
|
|
|
|
<para>
|
|
This leads naturally onto the question of how we got those proxy/stub
|
|
objects in the first place, and where they came from. You can use the
|
|
CoCreateInstanceEx API to activate COM objects on a remote machine, this
|
|
works like CoCreateInstance API. Behind the scenes, a lot of stuff is
|
|
involved to do this (like IRemoteActivation, IOXIDResolver and so on)
|
|
but let's gloss over that for now.
|
|
</para>
|
|
|
|
<para>
|
|
When DCOM creates an object on a remote machine, the DCOM runtime on
|
|
that machine activates the object in the usual way (by looking it up in
|
|
the registry etc) and then marshals the requested interface back to the
|
|
client. Marshalling an interface takes a pointer, and produces a buffer
|
|
containing all the information DCOM needs to construct a proxy object in
|
|
the client, a stub object in the server and link the two together.
|
|
</para>
|
|
|
|
<para>
|
|
The structure of a marshalled interface pointer is somewhat complex.
|
|
Let's ignore that too. The important thing is how COM proxies/stubs are
|
|
loaded.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>COM Proxy/Stub System</title>
|
|
|
|
<para>
|
|
COM proxies are objects that implement both the interfaces needing to be
|
|
proxied and also IRpcProxyBuffer. Likewise, COM stubs implement
|
|
IRpcStubBuffer and understand how to invoke the methods of the requested
|
|
interface.
|
|
</para>
|
|
|
|
<para>
|
|
You may be wondering what the word "buffer" is doing in those interface
|
|
names. I'm not sure either, except that a running theme in DCOM is that
|
|
interfaces which have nothing to do with buffers have the word Buffer
|
|
appended to them, seemingly at random. Ignore it and <emphasis>don't let it
|
|
confuse you</emphasis> :) This stuff is convoluted enough ...
|
|
</para>
|
|
|
|
<para>
|
|
The IRpc[Proxy/Stub]Buffer interfaces are used to control the proxy/stub
|
|
objects and are one of the many semi-public interfaces used in DCOM.
|
|
</para>
|
|
|
|
<para>
|
|
DCOM is theoretically an internet RFC
|
|
<ulink url="http://www.grimes.demon.co.uk/DCOM/DCOMSpec.htm">[2]</ulink> and is
|
|
specced out, but in reality the only implementation of it apart from
|
|
ours is Microsoft's, and as a result there are lots of interfaces
|
|
which <emphasis>can</emphasis> be used if you want to customize or
|
|
control DCOM but in practice are badly documented or not documented at
|
|
all, or exist mostly as interfaces between MIDL generated code and COM
|
|
itself. Don't pay too much attention to the MSDN definitions of these
|
|
interfaces and APIs.
|
|
</para>
|
|
|
|
<para>
|
|
COM proxies and stubs are like any other normal COM object - they are
|
|
registered in the registry, they can be loaded with CoCreateInstance and
|
|
so on. They have to be in process (in DLLs) however. They aren't
|
|
activated directly by COM however, instead the process goes something
|
|
like this:
|
|
|
|
<itemizedlist>
|
|
<listitem> <para> COM receives a marshalled interface packet, and retrieves the IID of
|
|
the marshalled interface from it </para> </listitem>
|
|
|
|
|
|
<listitem> <para> COM looks in
|
|
HKEY_CLASSES_ROOT/Interface/{whatever-iid}/ProxyStubClsId32
|
|
to retrieve the CLSID of another COM object, which
|
|
implements IPSFactoryBuffer. </para> </listitem>
|
|
|
|
<listitem> <para> IPSFactoryBuffer has only two methods, CreateProxy and CreateStub. COM
|
|
calls whichever is appropriate: CreateStub for the server, CreateProxy
|
|
for the client. MIDL will normally provide an implementation of this
|
|
object for you in the code it generates. </para></listitem>
|
|
</itemizedlist>
|
|
|
|
</para>
|
|
|
|
<para>
|
|
Once CreateProxy has been called, the resultant object is QueryInterfaced to
|
|
IRpcProxyBuffer, which only has 1 method, IRpcProxyBuffer::Connect.
|
|
This method only takes one parameter, the IRpcChannelBuffer object which
|
|
encapsulates the "RPC Channel" between the client and server.
|
|
</para>
|
|
|
|
<para>
|
|
On the server side, a similar process is performed - the PSFactoryBuffer
|
|
is created, CreateStub is called, result is QId to IRpcStubBuffer, and
|
|
IRpcStubBuffer::Connect is used to link it to the RPC channel.
|
|
</para>
|
|
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>RPC Channels</title>
|
|
|
|
<para>
|
|
Remember the RPC runtime? Well, that's not just responsible for
|
|
marshalling stuff, it also controls the connection and protocols between
|
|
the client and server. We can ignore the details of this for now,
|
|
suffice it to say that an RPC Channel is a COM object that implements
|
|
IRpcChannelBuffer, and it's basically an abstraction of different RPC
|
|
methods. For instance, in the case of inter-thread marshalling (not
|
|
covered here) the RPC connection code isn't used, only the NDR
|
|
marshallers are, so IRpcChannelBuffer in that case isn't actually
|
|
implemented by RPCRT4 but rather just by the COM/OLE DLLS.
|
|
</para>
|
|
|
|
<para>
|
|
On this topic, Ove Kaaven says: It depends on the Windows version, I
|
|
think. Windows 95 and Windows NT 4 certainly had very different models
|
|
when I looked. I'm pretty sure the Windows 98 version of RPCRT4 was
|
|
able to dispatch messages directly to individual apartments. I'd be
|
|
surprised if some similar functionality was not added to Windows
|
|
2000. After all, if an object on machine A wanted to use an object on
|
|
machine B in an apartment C, wouldn't it be most efficient if the RPC
|
|
system knew about apartments and could dispatch the message directly
|
|
to it? And if RPC does know how to efficiently dispatch to apartments,
|
|
why should COM duplicate this functionality? There were, however, no
|
|
unified way to tell RPC about them across Windows versions, so in that
|
|
old patch of mine, I let the COM/OLE dlls do the apartment dispatch,
|
|
but even then, the RPC runtime was always involved. After all, it
|
|
could be quite tricky to tell whether the call is merely interthread,
|
|
without involving the RPC runtime...
|
|
</para>
|
|
|
|
<para>
|
|
RPC channels are constructed on the fly by DCOM as part of the
|
|
marshalling process. So, when you make a call on a COM proxy, it goes
|
|
like this:
|
|
</para>
|
|
|
|
<para>
|
|
Your code -> COM proxy object -> RPC Channel -> COM stub object -> Their code
|
|
</para>
|
|
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>How this actually works in Wine</title>
|
|
|
|
<para>
|
|
Right now, Wine does not use the NDR marshallers or RPC to implement its
|
|
DCOM. When you marshal an interface in Wine, in the server process a
|
|
_StubMgrThread thread is started. I haven't gone into the stub manager
|
|
here. The important thing is that eventually a _StubReaderThread is
|
|
started which accepts marshalled DCOM RPCs, and then passes them to
|
|
IRpcStubBuffer::Invoke on the correct stub object which in turn
|
|
demarshals the packet and performs the call. The threads started by our
|
|
implementation of DCOM are never terminated, they just hang around until
|
|
the process dies.
|
|
</para>
|
|
|
|
<para>
|
|
Remember that I said our DCOM doesn't use RPC? Well, you might be
|
|
thinking "but we use IRpcStubBuffer like we're supposed to ... isn't
|
|
that provided by MIDL which generates code that uses the NDR APIs?". If
|
|
so pat yourself on the back, you're still with me. Go get a cup of
|
|
coffee.
|
|
</para>
|
|
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Typelib Marshaller</title>
|
|
|
|
<para>
|
|
In fact, the reason for the PSFactoryBuffer layer of indirection is
|
|
because not all interfaces are marshalled using MIDL generated code.
|
|
Why not? Well, to understand <emphasis>that</emphasis>
|
|
you have to see that one of the
|
|
driving forces behind OLE and by extension DCOM was the development of
|
|
Visual Basic. Microsoft wanted VB developers to be first class citizens
|
|
in the COM world, but things like writing IDL and compiling them with a
|
|
C compiler into DLLs wasn't easy enough.
|
|
</para>
|
|
|
|
<para>
|
|
So, type libraries were invented. Actually they were invented as part of
|
|
a parallel line of COM development known as "OLE Automation", but let's
|
|
not get into that here. Type libraries are basically binary IDL files,
|
|
except that despite there being two type library formats neither of them
|
|
can fully express everything expressable in IDL. Anyway, with a type
|
|
library (which can be embedded as a resource into a DLL) you have
|
|
another option beyond compiling MIDL output - you can set the
|
|
ProxyStubClsId32 registry entry for your interfaces to the CLSID of the
|
|
"type library marshaller" or "universal marshaller". Both terms are
|
|
used, but in the Wine source it's called the typelib marshaller.
|
|
</para>
|
|
|
|
<para>
|
|
The type library marshaller constructs proxy and stub objects on the
|
|
fly. It does so by having generic marshalling glue which reads the
|
|
information from the type libraries, and takes the parameters directly
|
|
off the stack. The CreateProxy method actually builds a vtable out of
|
|
blocks of assembly stitched together which pass control to _xCall, which
|
|
then does the marshalling. You can see all this magic in
|
|
dlls/oleaut32/tmarshal.c
|
|
</para>
|
|
|
|
<para>
|
|
In the case of InstallShield, it actually comes with typelibs for all
|
|
the interfaces it needs to marshal (fixme: is this right?), but they
|
|
actually use a mix of MIDL and typelib marshalling. In order to cover up
|
|
for the fact that we don't really use RPC they're all forced to go via
|
|
the typelib marshaller - that's what the 1 || hack is for and what the
|
|
"Registering non-automation type library!" warning is about (I think).
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Appartments</title>
|
|
|
|
<para>
|
|
Before a thread can use COM it must enter an apartment. Apartments are
|
|
an abstraction of a COM objects thread safety level. There are many types
|
|
of apartment but the only two we care about right now are single threaded
|
|
apartments (STAs) and the multi-threaded apartment (MTA).
|
|
</para>
|
|
|
|
<para>
|
|
Any given process may contain at most one MTA and potentially many STAs.
|
|
This is because all objects in MTAs never care where they are invoked from
|
|
and hence can all be treated the same. Since objects in STAs do care, they
|
|
cannot be treated the same.
|
|
</para>
|
|
|
|
<para>
|
|
You enter an apartment by calling <function>CoInitializeEx()</function> and
|
|
passing the desired thread model in as a parameter. The default if you use
|
|
the deprecated <function>CoInitialize()</function> is a STA, and this is the
|
|
most common type of apartment used in COM.
|
|
</para>
|
|
|
|
<para>
|
|
An object in the multi-threaded apartment may be accessed concurrently by
|
|
multiple threads: eg, it's supposed to be entirely thread safe. It must also
|
|
not care about thread-affinity, the object should react the same way no matter
|
|
which thread is calling it.
|
|
</para>
|
|
|
|
<para>
|
|
An object inside a STA does not have to be thread safe, and all calls upon it
|
|
should come from the same thread - the thread that entered the apartment in
|
|
the first place.
|
|
</para>
|
|
|
|
<para>
|
|
The apartment system was originally designed to deal with the disparity between
|
|
the Windows NT/C++ world in which threading was given a strong emphasis, and the
|
|
Visual Basic world in which threading was barely supported and even if it had
|
|
been fully supported most developers would not have used it. Visual Basic code
|
|
is not truly multi-threaded, instead if you start a new thread you get an entirely
|
|
new VM, with separate sets of global variables. Changes made in one thread do
|
|
<emphasis>not</emphasis> reflect in another, which pretty much violates the
|
|
expected semantics of multi-threading entirely but this is Visual Basic, so what
|
|
did you expect? If you access a VB object concurrently from multiple threads,
|
|
behind the scenes each VM runs in a STA and the calls are marshaled between the
|
|
threads using DCOM.
|
|
</para>
|
|
|
|
<para>
|
|
In the Windows 2000 release of COM, several new types of apartment were added, the
|
|
most important of which are RTAs (the rental threaded apartment) in which concurrent
|
|
access are serialised by COM using an apartment-wide lock but thread affinity is
|
|
not guaranteed.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Structure of a marshaled interface pointer</title>
|
|
|
|
<para>
|
|
When an interface is marshaled using <function>CoMarshalInterface()</function>,
|
|
the result is a serialized OBJREF structure. An OBJREF actually contains a union,
|
|
but we'll be assuming the variant that embeds a STDOBJREF here which is what's
|
|
used by the system provided standard marshaling. A STDOBJREF (standard object
|
|
reference) consists of the magic signature 'MEOW', then some flags, then the IID
|
|
of the marshaled interface. Quite what MEOW stands for is a mystery, but it's
|
|
definitely not "Microsoft Extended Object Wire". Next comes the STDOBJREF flags,
|
|
identified by their SORF_ prefix. Most of these are reserved, and their purpose
|
|
(if any) is unknown, but a few are defined.
|
|
</para>
|
|
|
|
<para>
|
|
After the SORF flags comes a count of the references represented by this marshaled
|
|
interface. Typically this will be 5 in the case of a normal marshal, but may be 0
|
|
for table-strong and table-weak marshals (the difference between these is explained below).
|
|
The reasoning is this: In the general case, we want to know exactly when an object
|
|
is unmarshaled and released, so we can accurately control the lifetime of the stub
|
|
object. This is what happens when cPublicRefs is zero. However, in many cases, we
|
|
only want to unmarshal an object once. Therefore, if we strengthen the rules to say
|
|
when marshaling that we will only unmarshal once, then we no longer have to know when
|
|
it is unmarshaled. Therefore, we can give out an arbitrary number of references when
|
|
marshaling and basically say "don't call me, except when you die."
|
|
</para>
|
|
|
|
<para>
|
|
The most interesting part of a STDOBJREF is the OXID, OID, IPID triple. This triple
|
|
identifies any given marshaled interface pointer in the network. OXIDs are apartment
|
|
identifiers, and are supposed to be unique network-wide. How this is guaranteed is
|
|
currently unknown: the original algorithm Windows used was something like the current
|
|
UNIX time and a local counter.
|
|
</para>
|
|
|
|
<para>
|
|
OXIDs are generated and registered with the OXID resolver by performing local RPCs
|
|
to the RPC subsystem (rpcss.exe). In a fully security-patched Windows system they
|
|
appear to be randomly generated. This registration is done using the
|
|
<function>ILocalOxidResolver</function> interface, however the exact structure of
|
|
this interface is currently unknown.
|
|
</para>
|
|
|
|
<para>
|
|
OIDs are object identifiers, and identify a stub manager. The stub manager manages
|
|
interface stubs. For each exported COM object there are multiple interfaces and
|
|
therefore multiple interface stubs (<function>IRpcStubBuffer</function> implementations).
|
|
OIDs are apartment scoped. Each ifstub is identified by an IPID, which identifies
|
|
a marshaled interface pointer. IPIDs are apartment scoped.
|
|
</para>
|
|
|
|
<para>
|
|
Unmarshaling one of these streams therefore means setting up a connection to the
|
|
object exporter (the apartment holding the marshaled interface pointer) and being
|
|
able to send RPCs to the right ifstub. Each apartment has its own RPC endpoint and
|
|
calls can be routed to the correct interface pointer by embedding the IPID into the
|
|
call using RpcBindingSetObject. IRemUnknown, discussed below, uses a reserved IPID.
|
|
Please note that this is true only in the current implementation. The native version
|
|
generates an IPID as per any other object and simply notifies the SCM of this IPID.
|
|
</para>
|
|
|
|
<para>
|
|
Both standard and handler marshaled OBJREFs contains an OXID resolver endpoint which
|
|
is an RPC string binding in a DUALSTRINGARRAY. This is necessary because an OXID
|
|
alone is not enough to contact the host, as it doesn't contain any network address
|
|
data. Instead, the combination of the remote OXID resolver RPC endpoint and the OXID
|
|
itself are passed to the local OXID resolver. It then returns the apartment string binding.
|
|
</para>
|
|
|
|
<para>
|
|
This step is an optimisation: technically the OBJREF itself could contain the string
|
|
binding of the apartment endpoint and the OXID resolver could be bypassed, but by using
|
|
this DCOM can optimise out a server round-trip by having the local OXID resolver cache
|
|
the query results. The OXID resolver is a service in the RPC subsystem (rpcss.exe) which
|
|
implements a raw (non object-oriented) RPC interface called <function>IOXIDResolver</function>.
|
|
Despite the identical naming convention this is not a COM interface.
|
|
</para>
|
|
|
|
<para>
|
|
Unmarshaling an interface pointer stream therefore consists of
|
|
reading the OXID, OID and IPID from the STDOBJREF, then reading
|
|
one or more RPC string bindings for the remote OXID resolver.
|
|
Then <function>RpcBindingFromStringBinding</function> is used
|
|
to convert this remote string binding into an RPC binding handle
|
|
which can be passed to the local
|
|
<function>IOXIDResolver::ResolveOxid</function> implementation
|
|
along with the OXID. The local OXID resolver consults its list
|
|
of same-machine OXIDs, then its cache of remote OXIDs, and if
|
|
not found does an RPC to the remote OXID resolver using the
|
|
binding handle passed in earlier. The result of the query is
|
|
stored for future reference in the cache, and finally the
|
|
unmarshaling application gets back the apartment string binding,
|
|
the IPID of that apartments <function>IRemUnknown</function>
|
|
implementation, and a security hint (let's ignore this for now).
|
|
</para>
|
|
|
|
<para>
|
|
Once the remote apartments string binding has been located the
|
|
unmarshalling process constructs an RPC Channel Buffer
|
|
implementation with the connection handle and the IPID of the
|
|
needed interface, loads and constructs the
|
|
<function>IRpcProxyBuffer</function> implementation for that
|
|
IID and connects it to the channel. Finally the proxy is passed
|
|
back to the application.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Handling IUnknown</title>
|
|
|
|
<para>
|
|
There are some subtleties here with respect to IUnknown. IUnknown
|
|
itself is never marshaled directly: instead a version of it
|
|
optimised for network usage is used. IRemUnknown is similar in
|
|
concept to IUnknown except that it allows you to add and release
|
|
arbitrary numbers of references at once, and it also allows you to
|
|
query for multiple interfaces at once.
|
|
</para>
|
|
|
|
<para>
|
|
IRemUnknown is used for lifecycle management, and for marshaling
|
|
new interfaces on an object back to the client. Its definition can
|
|
be seen in dcom.idl - basically the IRemUnknown::RemQueryInterface
|
|
method takes an IPID and a list of IIDs, then returns STDOBJREFs
|
|
of each new marshaled interface pointer.
|
|
</para>
|
|
|
|
<para>
|
|
There is one IRemUnknown implementation per apartment, not per
|
|
stub manager as you might expect. This is OK because IPIDs are
|
|
apartment not object scoped (In fact, according to the DCOM draft
|
|
spec, they are machine-scoped, but this implies apartment-scoped).
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Table marshaling</title>
|
|
|
|
<para>
|
|
Normally once you have unmarshaled a marshaled interface pointer
|
|
that stream is dead, you can't unmarshal it again. Sometimes this
|
|
isn't what you want. In this case, table marshaling can be used.
|
|
There are two types: strong and weak. In table-strong marshaling,
|
|
selected by a specific flag to <function>CoMarshalInterface()</function>,
|
|
a stream can be unmarshaled as many times as you like. Even if
|
|
all the proxies are released, the marshaled object reference is
|
|
still valid. Effectively the stream itself holds a ref on the object.
|
|
To release the object entirely so its server can shut down, you
|
|
must use <function>CoReleaseMarshalData()</function> on the stream.
|
|
</para>
|
|
|
|
<para>
|
|
In table-weak marshaling the stream can be unmarshaled many times,
|
|
however the stream does not hold a ref. If you unmarshal the
|
|
stream twice, once those two proxies have been released remote
|
|
object will also be released. Attempting to unmarshal the stream
|
|
at this point will yield <function>CO_E_DISCONNECTED</function>.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>RPC dispatch</title>
|
|
|
|
<para>
|
|
Exactly how RPC dispatch occurs depends on whether the exported
|
|
object is in a STA or the MTA. If it's in the MTA then all is
|
|
simple: the RPC dispatch thread can temporarily enter the MTA,
|
|
perform the remote call, and then leave it again. If it's in a
|
|
STA things get more complex, because of the requirement that only
|
|
one thread can ever access the object.
|
|
</para>
|
|
|
|
<para>
|
|
Instead, when entering a STA a hidden window is created implicitly
|
|
by COM, and the user must manually pump the message loop in order
|
|
to service incoming RPCs. The RPC dispatch thread performs the
|
|
context switch into the STA by sending a message to the apartments
|
|
window, which then proceeds to invoke the remote call in the right
|
|
thread.
|
|
</para>
|
|
|
|
<para>
|
|
RPC dispatch threads are pooled by the RPC runtime. When an incoming
|
|
RPC needs to be serviced, a thread is pulled from the pool and
|
|
invokes the call. The main RPC thread then goes back to listening
|
|
for new calls. It's quite likely for objects in the MTA to therefore
|
|
be servicing more than one call at once.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Message filtering and re-entrancy</title>
|
|
|
|
<para>
|
|
When an outgoing call is made from a STA, it's possible that the
|
|
remote server will re-enter the client, for instance to perform a
|
|
callback. Because of this potential re-entrancy, when waiting for
|
|
the reply to an RPC made inside a STA, COM will pump the message loop.
|
|
That's because while this thread is blocked, the incoming callback
|
|
will be dispatched by a thread from the RPC dispatch pool, so it
|
|
must be processing messages.
|
|
</para>
|
|
|
|
<para>
|
|
While COM is pumping the message loop, all incoming messages from
|
|
the operating system are filtered through one or more message filters.
|
|
These filters are themselves COM objects which can choose to discard,
|
|
hold or forward window messages. The default message filter drops all
|
|
input messages and forwards the rest. This is so that if the user
|
|
chooses a menu option which triggers an RPC, they then cannot choose
|
|
that menu option *again* and restart the function from the beginning.
|
|
That type of unexpected re-entrancy is extremely difficult to debug,
|
|
so it's disallowed.
|
|
</para>
|
|
|
|
<para>
|
|
Unfortunately other window messages are allowed through, meaning that
|
|
it's possible your UI will be required to repaint itself during an
|
|
outgoing RPC. This makes programming with STAs more complex than it
|
|
may appear, as you must be prepared to run all kinds of code any time
|
|
an outgoing call is made. In turn this breaks the idea that COM
|
|
should abstract object location from the programmer, because an
|
|
object that was originally free-threaded and is then run from a STA
|
|
could trigger new and untested codepaths in a program.
|
|
</para>
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Wrapup</title>
|
|
|
|
<para>
|
|
Theres are still a lot of topics that have not been covered:
|
|
</para>
|
|
|
|
<itemizedlist>
|
|
<listitem><para> Format strings/MOPs</para></listitem>
|
|
|
|
<listitem><para> IRemoteActivation</para></listitem>
|
|
|
|
<listitem><para> Complex/simple pings, distributed garbage collection</para></listitem>
|
|
|
|
<listitem><para> Marshalling IDispatch</para></listitem>
|
|
|
|
<listitem><para> ICallFrame</para></listitem>
|
|
|
|
<listitem><para> Interface pointer swizzling</para></listitem>
|
|
|
|
<listitem><para> Runtime class object registration (CoRegisterClassObject), ROT</para></listitem>
|
|
|
|
<listitem><para> Exactly how InstallShield uses DCOM</para></listitem>
|
|
</itemizedlist>
|
|
|
|
</sect2>
|
|
|
|
<sect2>
|
|
<title>Further Reading</title>
|
|
|
|
<para>
|
|
Most of these documents assume you have knowledge only contained in
|
|
other documents. You may have to reread them a few times for it all to
|
|
make sense. Don't feel you need to read these to understand DCOM, you
|
|
don't, you only need to look at them if you're planning to help
|
|
implement it.
|
|
</para>
|
|
|
|
<itemizedlist>
|
|
<listitem><para>
|
|
<ulink url="http://www-csag.ucsd.edu/individual/achien/cs491-f97/projects/dcom-writeup.ps">
|
|
http://www-csag.ucsd.edu/individual/achien/cs491-f97/projects/dcom-writeup.ps</ulink>
|
|
|
|
</para></listitem>
|
|
|
|
<listitem><para>
|
|
<ulink url="http://msdn.microsoft.com/library/default.asp?url=/library/en-us/com/htm/cmi_n2p_459u.asp">
|
|
http://msdn.microsoft.com/library/default.asp?url=/library/en-us/com/htm/cmi_n2p_459u.asp</ulink>
|
|
|
|
</para></listitem>
|
|
|
|
|
|
<listitem><para>
|
|
<ulink url="http://msdn.microsoft.com/library/default.asp?url=/library/en-us/com/htm/cmi_q2z_5ygi.asp">
|
|
http://msdn.microsoft.com/library/default.asp?url=/library/en-us/com/htm/cmi_q2z_5ygi.asp</ulink>
|
|
</para></listitem>
|
|
|
|
|
|
<listitem><para>
|
|
<ulink url="http://www.microsoft.com/msj/0398/dcom.aspx">
|
|
http://www.microsoft.com/msj/0398/dcom.aspx</ulink>
|
|
</para></listitem>
|
|
|
|
<listitem><para>
|
|
<ulink url="http://www.microsoft.com/ntserver/techresources/appserv/COM/DCOM/4_ConnectionMgmt.asp">
|
|
http://www.microsoft.com/ntserver/techresources/appserv/COM/DCOM/4_ConnectionMgmt.asp</ulink>
|
|
</para></listitem>
|
|
|
|
|
|
<listitem><para><ulink url="http://www.idevresource.com/com/library/articles/comonlinux.asp">
|
|
http://www.idevresource.com/com/library/articles/comonlinux.asp</ulink>
|
|
|
|
(unfortunately part 2 of this article does not seem to exist anymore, if it was ever written)</para></listitem>
|
|
</itemizedlist>
|
|
</sect2>
|
|
</sect1>
|
|
</chapter>
|
|
|
|
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|
|
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|
|
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|
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