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   <chapter id="ole">
     <title>COM/OLE in Wine</title>

     <sect1 id="ole-architecture">
       <title>COM/OLE Architecture in Wine</title>

       <para>
         The section goes into detail about how COM/OLE2 are
         implemented in Wine.
       </para>
     </sect1>

     <sect1 id="ole-binary">
       <title>Using Binary OLE components in Wine</title>
       <para>
         This section describes how to import pre-compiled COM/OLE
         components...
       </para>
     </sect1>

     <sect1 id="com-writing">
       <title>Writing OLE Components for Wine</title>

       <para>
         Based on the comments in <filename>wine/include/wine/obj_base.h</filename>.
       </para>
       <para>
         This section describes how to create your own natively
         compiled COM/OLE components.
       </para>

       <sect2>
         <title>Macros to define a COM interface</title>

         <para>
           The goal of the following set of definitions is to provide a
           way to use the same header file definitions to provide both
           a C interface and a C++ object oriented interface to COM
           interfaces. The type of interface is selected automatically
           depending on the language but it is always possible to get
           the C interface in C++ by defining CINTERFACE.
         </para>
         <para>
           It is based on the following assumptions:
         </para>
         <itemizedlist>
           <listitem>
             <para>
               all COM interfaces derive from IUnknown, this should not
               be a problem.
             </para>
           </listitem>
           <listitem>
             <para>
               the header file only defines the interface, the actual
               fields are defined separately in the C file implementing
               the interface.
             </para>
           </listitem>
         </itemizedlist>
         <para>
           The natural approach to this problem would be to make sure
           we get a C++ class and virtual methods in C++ and a
           structure with a table of pointer to functions in C.
           Unfortunately the layout of the virtual table is compiler
           specific, the layout of g++ virtual tables is not the same
           as that of an egcs virtual table which is not the same as
           that generated by Visual C+. There are workarounds to make
           the virtual tables compatible via padding but unfortunately
           the one which is imposed to the WINE emulator by the Windows
           binaries, i.e. the Visual C++ one, is the most compact of
           all.
         </para>
         <para>
           So the solution I finally adopted does not use virtual
           tables. Instead I use inline non virtual methods that
           dereference the method pointer themselves and perform the
           call.
         </para>
         <para>
           Let's take Direct3D as an example:
         </para>
         <programlisting>#define ICOM_INTERFACE IDirect3D
 #define IDirect3D_METHODS \
     ICOM_METHOD1(HRESULT,Initialize,    REFIID,) \
     ICOM_METHOD2(HRESULT,EnumDevices,   LPD3DENUMDEVICESCALLBACK,, LPVOID,) \
     ICOM_METHOD2(HRESULT,CreateLight,   LPDIRECT3DLIGHT*,, IUnknown*,) \
     ICOM_METHOD2(HRESULT,CreateMaterial,LPDIRECT3DMATERIAL*,, IUnknown*,) \
     ICOM_METHOD2(HRESULT,CreateViewport,LPDIRECT3DVIEWPORT*,, IUnknown*,) \
     ICOM_METHOD2(HRESULT,FindDevice,    LPD3DFINDDEVICESEARCH,, LPD3DFINDDEVICERESULT,)
 #define IDirect3D_IMETHODS \
     IUnknown_IMETHODS \
     IDirect3D_METHODS
 ICOM_DEFINE(IDirect3D,IUnknown)
 #undef ICOM_INTERFACE

 #ifdef ICOM_CINTERFACE
 // *** IUnknown methods *** //
 #define IDirect3D_QueryInterface(p,a,b) ICOM_CALL2(QueryInterface,p,a,b)
 #define IDirect3D_AddRef(p)             ICOM_CALL (AddRef,p)
 #define IDirect3D_Release(p)            ICOM_CALL (Release,p)
 // *** IDirect3D methods *** //
 #define IDirect3D_Initialize(p,a)       ICOM_CALL1(Initialize,p,a)
 #define IDirect3D_EnumDevices(p,a,b)    ICOM_CALL2(EnumDevice,p,a,b)
 #define IDirect3D_CreateLight(p,a,b)    ICOM_CALL2(CreateLight,p,a,b)
 #define IDirect3D_CreateMaterial(p,a,b) ICOM_CALL2(CreateMaterial,p,a,b)
 #define IDirect3D_CreateViewport(p,a,b) ICOM_CALL2(CreateViewport,p,a,b)
 #define IDirect3D_FindDevice(p,a,b)     ICOM_CALL2(FindDevice,p,a,b)
 #endif</programlisting>
         <para>
           Comments:
         </para>
         <para>
           The ICOM_INTERFACE macro is used in the ICOM_METHOD macros
           to define the type of the 'this' pointer. Defining this
           macro here saves us the trouble of having to repeat the
           interface name everywhere. Note however that because of the
           way macros work, a macro like ICOM_METHOD1 cannot use
           'ICOM_INTERFACE##_VTABLE' because this would give
           'ICOM_INTERFACE_VTABLE' and not 'IDirect3D_VTABLE'.
         </para>
         <para>
           ICOM_METHODS defines the methods specific to this
           interface. It is then aggregated with the inherited methods
           to form ICOM_IMETHODS.
         </para>
         <para>
           ICOM_IMETHODS defines the list of methods that are
           inheritable from this interface. It must be written manually
           (rather than using a macro to generate the equivalent code)
           to avoid macro recursion (which compilers don't like).
         </para>
         <para>
           The ICOM_DEFINE finally declares all the structures
           necessary for the interface. We have to explicitly use the
           interface name for macro expansion reasons again.  Inherited
           methods are inherited in C by using the IDirect3D_METHODS
           macro and the parent's Xxx_IMETHODS macro. In C++ we need
           only use the IDirect3D_METHODS since method inheritance is
           taken care of by the language.
         </para>
         <para>
           In C++ the ICOM_METHOD macros generate a function prototype
           and a call to a function pointer method. This means using
           once 't1 p1, t2 p2, ...' and once 'p1, p2' without the
           types. The only way I found to handle this is to have one
           ICOM_METHOD macro per number of parameters and to have it
           take only the type information (with const if necessary) as
           parameters.  The 'undef ICOM_INTERFACE' is here to remind
           you that using ICOM_INTERFACE in the following macros will
           not work. This time it's because the ICOM_CALL macro
           expansion is done only once the 'IDirect3D_Xxx' macro is
           expanded. And by that time ICOM_INTERFACE will be long gone
           anyway.
         </para>
         <para>
           You may have noticed the double commas after each parameter
           type. This allows you to put the name of that parameter
           which I think is good for documentation. It is not required
           and since I did not know what to put there for this example
           (I could only find doc about IDirect3D2), I left them blank.
         </para>
         <para>
           Finally the set of 'IDirect3D_Xxx' macros is a standard set
           of macros defined to ease access to the interface methods in
           C. Unfortunately I don't see any way to avoid having to
           duplicate the inherited method definitions there. This time
           I could have used a trick to use only one macro whatever the
           number of parameters but I prefered to have it work the same
           way as above.
         </para>
         <para>
           You probably have noticed that we don't define the fields we
           need to actually implement this interface: reference count,
           pointer to other resources and miscellaneous fields. That's
           because these interfaces are just that: interfaces. They may
           be implemented more than once, in different contexts and
           sometimes not even in Wine. Thus it would not make sense to
           impose that the interface contains some specific fields.
         </para>
       </sect2>

       <sect2>
         <title>Bindings in C</title>

         <para>
           In C this gives:
         </para>
         <programlisting>typedef struct IDirect3DVtbl IDirect3DVtbl;
 struct IDirect3D {
     IDirect3DVtbl* lpVtbl;
 };
 struct IDirect3DVtbl {
     HRESULT (*fnQueryInterface)(IDirect3D* me, REFIID riid, LPVOID* ppvObj);
     ULONG (*fnAddRef)(IDirect3D* me);
     ULONG (*fnRelease)(IDirect3D* me);
     HRESULT (*fnInitialize)(IDirect3D* me, REFIID a);
     HRESULT (*fnEnumDevices)(IDirect3D* me, LPD3DENUMDEVICESCALLBACK a, LPVOID b);
     HRESULT (*fnCreateLight)(IDirect3D* me, LPDIRECT3DLIGHT* a, IUnknown* b);
     HRESULT (*fnCreateMaterial)(IDirect3D* me, LPDIRECT3DMATERIAL* a, IUnknown* b);
     HRESULT (*fnCreateViewport)(IDirect3D* me, LPDIRECT3DVIEWPORT* a, IUnknown* b);
     HRESULT (*fnFindDevice)(IDirect3D* me, LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b);
 };

 #ifdef ICOM_CINTERFACE
 // *** IUnknown methods *** //
 #define IDirect3D_QueryInterface(p,a,b) (p)->lpVtbl->fnQueryInterface(p,a,b)
 #define IDirect3D_AddRef(p)             (p)->lpVtbl->fnAddRef(p)
 #define IDirect3D_Release(p)            (p)->lpVtbl->fnRelease(p)
 // *** IDirect3D methods *** //
 #define IDirect3D_Initialize(p,a)       (p)->lpVtbl->fnInitialize(p,a)
 #define IDirect3D_EnumDevices(p,a,b)    (p)->lpVtbl->fnEnumDevice(p,a,b)
 #define IDirect3D_CreateLight(p,a,b)    (p)->lpVtbl->fnCreateLight(p,a,b)
 #define IDirect3D_CreateMaterial(p,a,b) (p)->lpVtbl->fnCreateMaterial(p,a,b)
 #define IDirect3D_CreateViewport(p,a,b) (p)->lpVtbl->fnCreateViewport(p,a,b)
 #define IDirect3D_FindDevice(p,a,b)     (p)->lpVtbl->fnFindDevice(p,a,b)
 #endif</programlisting>
         <para>
           Comments:
         </para>
         <para>
           IDirect3D only contains a pointer to the IDirect3D
           virtual/jump table. This is the only thing the user needs to
           know to use the interface. Of course the structure we will
           define to implement this interface will have more fields but
           the first one will match this pointer.
         </para>
         <para>
           The code generated by ICOM_DEFINE defines both the structure
           representing the interface and the structure for the jump
           table. ICOM_DEFINE uses the parent's Xxx_IMETHODS macro to
           automatically repeat the prototypes of all the inherited
           methods and then uses IDirect3D_METHODS to define the
           IDirect3D methods.
         </para>
         <para>
           Each method is declared as a pointer to function field in
           the jump table. The implementation will fill this jump table
           with appropriate values, probably using a static variable,
           and initialize the lpVtbl field to point to this variable.
         </para>
         <para>
           The IDirect3D_Xxx macros then just derefence the lpVtbl
           pointer and use the function pointer corresponding to the
           macro name. This emulates the behavior of a virtual table
           and should be just as fast.
         </para>
         <para>
           This C code should be quite compatible with the Windows
           headers both for code that uses COM interfaces and for code
           implementing a COM interface.
         </para>
       </sect2>

       <sect2>
         <title>Bindings in C++</title>
         <para>
           And in C++ (with gcc's g++):
         </para>
         <programlisting>typedef struct IDirect3D: public IUnknown {
     private: HRESULT (*fnInitialize)(IDirect3D* me, REFIID a);
     public: inline HRESULT Initialize(REFIID a) { return ((IDirect3D*)t.lpVtbl)->fnInitialize(this,a); };
     private: HRESULT (*fnEnumDevices)(IDirect3D* me, LPD3DENUMDEVICESCALLBACK a, LPVOID b);
     public: inline HRESULT EnumDevices(LPD3DENUMDEVICESCALLBACK a, LPVOID b)
         { return ((IDirect3D*)t.lpVtbl)->fnEnumDevices(this,a,b); };
     private: HRESULT (*fnCreateLight)(IDirect3D* me, LPDIRECT3DLIGHT* a, IUnknown* b);
     public: inline HRESULT CreateLight(LPDIRECT3DLIGHT* a, IUnknown* b)
         { return ((IDirect3D*)t.lpVtbl)->fnCreateLight(this,a,b); };
     private: HRESULT (*fnCreateMaterial)(IDirect3D* me, LPDIRECT3DMATERIAL* a, IUnknown* b);
     public: inline HRESULT CreateMaterial(LPDIRECT3DMATERIAL* a, IUnknown* b)
         { return ((IDirect3D*)t.lpVtbl)->fnCreateMaterial(this,a,b); };
     private: HRESULT (*fnCreateViewport)(IDirect3D* me, LPDIRECT3DVIEWPORT* a, IUnknown* b);
     public: inline HRESULT CreateViewport(LPDIRECT3DVIEWPORT* a, IUnknown* b)
         { return ((IDirect3D*)t.lpVtbl)->fnCreateViewport(this,a,b); };
     private:  HRESULT (*fnFindDevice)(IDirect3D* me, LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b);
     public: inline HRESULT FindDevice(LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b)
         { return ((IDirect3D*)t.lpVtbl)->fnFindDevice(this,a,b); };
 };</programlisting>
         <para>
           Comments:
         </para>
         <para>
           In C++ IDirect3D does double duty as both the virtual/jump
           table and as the interface definition. The reason for this
           is to avoid having to duplicate the mehod definitions: once
           to have the function pointers in the jump table and once to
           have the methods in the interface class. Here one macro can
           generate both. This means though that the first pointer,
           t.lpVtbl defined in IUnknown, must be interpreted as the
           jump table pointer if we interpret the structure as the
           interface class, and as the function pointer to the
           QueryInterface method, t.fnQueryInterface, if we interpret
           the structure as the jump table. Fortunately this gymnastic
           is entirely taken care of in the header of IUnknown.
         </para>
         <para>
           Of course in C++ we use inheritance so that we don't have to
           duplicate the method definitions.
         </para>
         <para>
           Since IDirect3D does double duty, each ICOM_METHOD macro
           defines both a function pointer and a non-virtual inline
           method which dereferences it and calls it. This way this
           method behaves just like a virtual method but does not
           create a true C++ virtual table which would break the
           structure layout. If you look at the implementation of these
           methods you'll notice that they would not work for void
           functions. We have to return something and fortunately this
           seems to be what all the COM methods do (otherwise we would
           need another set of macros).
         </para>
         <para>
           Note how the ICOM_METHOD generates both function prototypes
           mixing types and formal parameter names and the method
           invocation using only the formal parameter name. This is the
           reason why we need different macros to handle different
           numbers of parameters.
         </para>
         <para>
           Finally there is no IDirect3D_Xxx macro. These are not
           needed in C++ unless the CINTERFACE macro is defined in
           which case we would not be here.
         </para>
         <para>
           This C++ code works well for code that just uses COM
           interfaces. But it will not work with C++ code implement a
           COM interface. That's because such code assumes the
           interface methods are declared as virtual C++ methods which
           is not the case here.
         </para>
       </sect2>

       <sect2>
         <title>Implementing a COM interface.</title>

         <para>
           This continues the above example. This example assumes that
           the implementation is in C.
         </para>
         <programlisting>typedef struct _IDirect3D {
     void* lpVtbl;
     // ...
  } _IDirect3D;

 static ICOM_VTABLE(IDirect3D) d3dvt;

 // implement the IDirect3D methods here

 int IDirect3D_fnQueryInterface(IDirect3D* me)
 {
     ICOM_THIS(IDirect3D,me);
     // ...
 }

 // ...

 static ICOM_VTABLE(IDirect3D) d3dvt = {
     ICOM_MSVTABLE_COMPAT_DummyRTTIVALUE
     IDirect3D_fnQueryInterface,
     IDirect3D_fnAdd,
     IDirect3D_fnAdd2,
     IDirect3D_fnInitialize,
     IDirect3D_fnSetWidth
 };</programlisting>
         <para>
           Comments:
         </para>
         <para>
           We first define what the interface really contains. This is
           the _IDirect3D structure. The first field must of course be
           the virtual table pointer. Everything else is free.
         </para>
         <para>
           Then we predeclare our static virtual table variable, we
           will need its address in some methods to initialize the
           virtual table pointer of the returned interface objects.
         </para>
         <para>
           Then we implement the interface methods. To match what has
           been declared in the header file they must take a pointer to
           a IDirect3D structure and we must cast it to an _IDirect3D
           so that we can manipulate the fields. This is performed by
           the ICOM_THIS macro.
         </para>
         <para>
           Finally we initialize the virtual table.
         </para>
       </sect2>
     </sect1>
   </chapter>

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	<chapter id="ole">
	<title>COM/OLE in Wine</title>

	<sect1 id="ole-architecture">
	<title>COM/OLE Architecture in Wine</title>

	<para>
	The section goes into detail about how COM/OLE2 are
	implemented in Wine.
	</para>
	</sect1>

	<sect1 id="ole-binary">
	<title>Using Binary OLE components in Wine</title>
	<para>
	This section describes how to import pre-compiled COM/OLE
	components...
	</para>
	</sect1>

	<sect1 id="com-writing">
	<title>Writing OLE Components for Wine</title>

	<para>
	Based on the comments in <filename>wine/include/wine/obj_base.h</filename>.
	</para>
	<para>
	This section describes how to create your own natively
	compiled COM/OLE components.
	</para>

	<sect2>
	<title>Macros to define a COM interface</title>

	<para>
	The goal of the following set of definitions is to provide a
	way to use the same header file definitions to provide both
	a C interface and a C++ object oriented interface to COM
	interfaces. The type of interface is selected automatically
	depending on the language but it is always possible to get
	the C interface in C++ by defining CINTERFACE.
	</para>
	<para>
	It is based on the following assumptions:
	</para>
	<itemizedlist>
	<listitem>
	<para>
	all COM interfaces derive from IUnknown, this should not
	be a problem.
	</para>
	</listitem>
	<listitem>
	<para>
	the header file only defines the interface, the actual
	fields are defined separately in the C file implementing
	the interface.
	</para>
	</listitem>
	</itemizedlist>
	<para>
	The natural approach to this problem would be to make sure
	we get a C++ class and virtual methods in C++ and a
	structure with a table of pointer to functions in C.
	Unfortunately the layout of the virtual table is compiler
	specific, the layout of g++ virtual tables is not the same
	as that of an egcs virtual table which is not the same as
	that generated by Visual C+. There are workarounds to make
	the virtual tables compatible via padding but unfortunately
	the one which is imposed to the WINE emulator by the Windows
	binaries, i.e. the Visual C++ one, is the most compact of
	all.
	</para>
	<para>
	So the solution I finally adopted does not use virtual
	tables. Instead I use inline non virtual methods that
	dereference the method pointer themselves and perform the
	call.
	</para>
	<para>
	Let's take Direct3D as an example:
	</para>
	<programlisting>#define ICOM_INTERFACE IDirect3D
	#define IDirect3D_METHODS \
	ICOM_METHOD1(HRESULT,Initialize, REFIID,) \
	ICOM_METHOD2(HRESULT,EnumDevices, LPD3DENUMDEVICESCALLBACK,, LPVOID,) \
	ICOM_METHOD2(HRESULT,CreateLight, LPDIRECT3DLIGHT,, IUnknown,) \
	ICOM_METHOD2(HRESULT,CreateMaterial,LPDIRECT3DMATERIAL,, IUnknown,) \
	ICOM_METHOD2(HRESULT,CreateViewport,LPDIRECT3DVIEWPORT,, IUnknown,) \
	ICOM_METHOD2(HRESULT,FindDevice, LPD3DFINDDEVICESEARCH,, LPD3DFINDDEVICERESULT,)
	#define IDirect3D_IMETHODS \
	IUnknown_IMETHODS \
	IDirect3D_METHODS
	ICOM_DEFINE(IDirect3D,IUnknown)
	#undef ICOM_INTERFACE

	#ifdef ICOM_CINTERFACE
	// * IUnknown methods * //
	#define IDirect3D_QueryInterface(p,a,b) ICOM_CALL2(QueryInterface,p,a,b)
	#define IDirect3D_AddRef(p) ICOM_CALL (AddRef,p)
	#define IDirect3D_Release(p) ICOM_CALL (Release,p)
	// * IDirect3D methods * //
	#define IDirect3D_Initialize(p,a) ICOM_CALL1(Initialize,p,a)
	#define IDirect3D_EnumDevices(p,a,b) ICOM_CALL2(EnumDevice,p,a,b)
	#define IDirect3D_CreateLight(p,a,b) ICOM_CALL2(CreateLight,p,a,b)
	#define IDirect3D_CreateMaterial(p,a,b) ICOM_CALL2(CreateMaterial,p,a,b)
	#define IDirect3D_CreateViewport(p,a,b) ICOM_CALL2(CreateViewport,p,a,b)
	#define IDirect3D_FindDevice(p,a,b) ICOM_CALL2(FindDevice,p,a,b)
	#endif</programlisting>
	<para>
	Comments:
	</para>
	<para>
	The ICOM_INTERFACE macro is used in the ICOM_METHOD macros
	to define the type of the 'this' pointer. Defining this
	macro here saves us the trouble of having to repeat the
	interface name everywhere. Note however that because of the
	way macros work, a macro like ICOM_METHOD1 cannot use
	'ICOM_INTERFACE##_VTABLE' because this would give
	'ICOM_INTERFACE_VTABLE' and not 'IDirect3D_VTABLE'.
	</para>
	<para>
	ICOM_METHODS defines the methods specific to this
	interface. It is then aggregated with the inherited methods
	to form ICOM_IMETHODS.
	</para>
	<para>
	ICOM_IMETHODS defines the list of methods that are
	inheritable from this interface. It must be written manually
	(rather than using a macro to generate the equivalent code)
	to avoid macro recursion (which compilers don't like).
	</para>
	<para>
	The ICOM_DEFINE finally declares all the structures
	necessary for the interface. We have to explicitly use the
	interface name for macro expansion reasons again. Inherited
	methods are inherited in C by using the IDirect3D_METHODS
	macro and the parent's Xxx_IMETHODS macro. In C++ we need
	only use the IDirect3D_METHODS since method inheritance is
	taken care of by the language.
	</para>
	<para>
	In C++ the ICOM_METHOD macros generate a function prototype
	and a call to a function pointer method. This means using
	once 't1 p1, t2 p2, ...' and once 'p1, p2' without the
	types. The only way I found to handle this is to have one
	ICOM_METHOD macro per number of parameters and to have it
	take only the type information (with const if necessary) as
	parameters. The 'undef ICOM_INTERFACE' is here to remind
	you that using ICOM_INTERFACE in the following macros will
	not work. This time it's because the ICOM_CALL macro
	expansion is done only once the 'IDirect3D_Xxx' macro is
	expanded. And by that time ICOM_INTERFACE will be long gone
	anyway.
	</para>
	<para>
	You may have noticed the double commas after each parameter
	type. This allows you to put the name of that parameter
	which I think is good for documentation. It is not required
	and since I did not know what to put there for this example
	(I could only find doc about IDirect3D2), I left them blank.
	</para>
	<para>
	Finally the set of 'IDirect3D_Xxx' macros is a standard set
	of macros defined to ease access to the interface methods in
	C. Unfortunately I don't see any way to avoid having to
	duplicate the inherited method definitions there. This time
	I could have used a trick to use only one macro whatever the
	number of parameters but I prefered to have it work the same
	way as above.
	</para>
	<para>
	You probably have noticed that we don't define the fields we
	need to actually implement this interface: reference count,
	pointer to other resources and miscellaneous fields. That's
	because these interfaces are just that: interfaces. They may
	be implemented more than once, in different contexts and
	sometimes not even in Wine. Thus it would not make sense to
	impose that the interface contains some specific fields.
	</para>
	</sect2>

	<sect2>
	<title>Bindings in C</title>

	<para>
	In C this gives:
	</para>
	<programlisting>typedef struct IDirect3DVtbl IDirect3DVtbl;
	struct IDirect3D {
	IDirect3DVtbl* lpVtbl;
	};
	struct IDirect3DVtbl {
	HRESULT (fnQueryInterface)(IDirect3D me, REFIID riid, LPVOID* ppvObj);
	ULONG (fnAddRef)(IDirect3D me);
	ULONG (fnRelease)(IDirect3D me);
	HRESULT (fnInitialize)(IDirect3D me, REFIID a);
	HRESULT (fnEnumDevices)(IDirect3D me, LPD3DENUMDEVICESCALLBACK a, LPVOID b);
	HRESULT (fnCreateLight)(IDirect3D me, LPDIRECT3DLIGHT* a, IUnknown* b);
	HRESULT (fnCreateMaterial)(IDirect3D me, LPDIRECT3DMATERIAL* a, IUnknown* b);
	HRESULT (fnCreateViewport)(IDirect3D me, LPDIRECT3DVIEWPORT* a, IUnknown* b);
	HRESULT (fnFindDevice)(IDirect3D me, LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b);
	};

	#ifdef ICOM_CINTERFACE
	// * IUnknown methods * //
	#define IDirect3D_QueryInterface(p,a,b) (p)->lpVtbl->fnQueryInterface(p,a,b)
	#define IDirect3D_AddRef(p) (p)->lpVtbl->fnAddRef(p)
	#define IDirect3D_Release(p) (p)->lpVtbl->fnRelease(p)
	// * IDirect3D methods * //
	#define IDirect3D_Initialize(p,a) (p)->lpVtbl->fnInitialize(p,a)
	#define IDirect3D_EnumDevices(p,a,b) (p)->lpVtbl->fnEnumDevice(p,a,b)
	#define IDirect3D_CreateLight(p,a,b) (p)->lpVtbl->fnCreateLight(p,a,b)
	#define IDirect3D_CreateMaterial(p,a,b) (p)->lpVtbl->fnCreateMaterial(p,a,b)
	#define IDirect3D_CreateViewport(p,a,b) (p)->lpVtbl->fnCreateViewport(p,a,b)
	#define IDirect3D_FindDevice(p,a,b) (p)->lpVtbl->fnFindDevice(p,a,b)
	#endif</programlisting>
	<para>
	Comments:
	</para>
	<para>
	IDirect3D only contains a pointer to the IDirect3D
	virtual/jump table. This is the only thing the user needs to
	know to use the interface. Of course the structure we will
	define to implement this interface will have more fields but
	the first one will match this pointer.
	</para>
	<para>
	The code generated by ICOM_DEFINE defines both the structure
	representing the interface and the structure for the jump
	table. ICOM_DEFINE uses the parent's Xxx_IMETHODS macro to
	automatically repeat the prototypes of all the inherited
	methods and then uses IDirect3D_METHODS to define the
	IDirect3D methods.
	</para>
	<para>
	Each method is declared as a pointer to function field in
	the jump table. The implementation will fill this jump table
	with appropriate values, probably using a static variable,
	and initialize the lpVtbl field to point to this variable.
	</para>
	<para>
	The IDirect3D_Xxx macros then just derefence the lpVtbl
	pointer and use the function pointer corresponding to the
	macro name. This emulates the behavior of a virtual table
	and should be just as fast.
	</para>
	<para>
	This C code should be quite compatible with the Windows
	headers both for code that uses COM interfaces and for code
	implementing a COM interface.
	</para>
	</sect2>

	<sect2>
	<title>Bindings in C++</title>
	<para>
	And in C++ (with gcc's g++):
	</para>
	<programlisting>typedef struct IDirect3D: public IUnknown {
	private: HRESULT (fnInitialize)(IDirect3D me, REFIID a);
	public: inline HRESULT Initialize(REFIID a) { return ((IDirect3D*)t.lpVtbl)->fnInitialize(this,a); };
	private: HRESULT (fnEnumDevices)(IDirect3D me, LPD3DENUMDEVICESCALLBACK a, LPVOID b);
	public: inline HRESULT EnumDevices(LPD3DENUMDEVICESCALLBACK a, LPVOID b)
	{ return ((IDirect3D*)t.lpVtbl)->fnEnumDevices(this,a,b); };
	private: HRESULT (fnCreateLight)(IDirect3D me, LPDIRECT3DLIGHT* a, IUnknown* b);
	public: inline HRESULT CreateLight(LPDIRECT3DLIGHT* a, IUnknown* b)
	{ return ((IDirect3D*)t.lpVtbl)->fnCreateLight(this,a,b); };
	private: HRESULT (fnCreateMaterial)(IDirect3D me, LPDIRECT3DMATERIAL* a, IUnknown* b);
	public: inline HRESULT CreateMaterial(LPDIRECT3DMATERIAL* a, IUnknown* b)
	{ return ((IDirect3D*)t.lpVtbl)->fnCreateMaterial(this,a,b); };
	private: HRESULT (fnCreateViewport)(IDirect3D me, LPDIRECT3DVIEWPORT* a, IUnknown* b);
	public: inline HRESULT CreateViewport(LPDIRECT3DVIEWPORT* a, IUnknown* b)
	{ return ((IDirect3D*)t.lpVtbl)->fnCreateViewport(this,a,b); };
	private: HRESULT (fnFindDevice)(IDirect3D me, LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b);
	public: inline HRESULT FindDevice(LPD3DFINDDEVICESEARCH a, LPD3DFINDDEVICERESULT b)
	{ return ((IDirect3D*)t.lpVtbl)->fnFindDevice(this,a,b); };
	};</programlisting>
	<para>
	Comments:
	</para>
	<para>
	In C++ IDirect3D does double duty as both the virtual/jump
	table and as the interface definition. The reason for this
	is to avoid having to duplicate the mehod definitions: once
	to have the function pointers in the jump table and once to
	have the methods in the interface class. Here one macro can
	generate both. This means though that the first pointer,
	t.lpVtbl defined in IUnknown, must be interpreted as the
	jump table pointer if we interpret the structure as the
	interface class, and as the function pointer to the
	QueryInterface method, t.fnQueryInterface, if we interpret
	the structure as the jump table. Fortunately this gymnastic
	is entirely taken care of in the header of IUnknown.
	</para>
	<para>
	Of course in C++ we use inheritance so that we don't have to
	duplicate the method definitions.
	</para>
	<para>
	Since IDirect3D does double duty, each ICOM_METHOD macro
	defines both a function pointer and a non-virtual inline
	method which dereferences it and calls it. This way this
	method behaves just like a virtual method but does not
	create a true C++ virtual table which would break the
	structure layout. If you look at the implementation of these
	methods you'll notice that they would not work for void
	functions. We have to return something and fortunately this
	seems to be what all the COM methods do (otherwise we would
	need another set of macros).
	</para>
	<para>
	Note how the ICOM_METHOD generates both function prototypes
	mixing types and formal parameter names and the method
	invocation using only the formal parameter name. This is the
	reason why we need different macros to handle different
	numbers of parameters.
	</para>
	<para>
	Finally there is no IDirect3D_Xxx macro. These are not
	needed in C++ unless the CINTERFACE macro is defined in
	which case we would not be here.
	</para>
	<para>
	This C++ code works well for code that just uses COM
	interfaces. But it will not work with C++ code implement a
	COM interface. That's because such code assumes the
	interface methods are declared as virtual C++ methods which
	is not the case here.
	</para>
	</sect2>

	<sect2>
	<title>Implementing a COM interface.</title>

	<para>
	This continues the above example. This example assumes that
	the implementation is in C.
	</para>
	<programlisting>typedef struct _IDirect3D {
	void* lpVtbl;
	// ...
	} _IDirect3D;

	static ICOM_VTABLE(IDirect3D) d3dvt;

	// implement the IDirect3D methods here

	int IDirect3D_fnQueryInterface(IDirect3D* me)
	{
	ICOM_THIS(IDirect3D,me);
	// ...
	}

	// ...

	static ICOM_VTABLE(IDirect3D) d3dvt = {
	ICOM_MSVTABLE_COMPAT_DummyRTTIVALUE
	IDirect3D_fnQueryInterface,
	IDirect3D_fnAdd,
	IDirect3D_fnAdd2,
	IDirect3D_fnInitialize,
	IDirect3D_fnSetWidth
	};</programlisting>
	<para>
	Comments:
	</para>
	<para>
	We first define what the interface really contains. This is
	the _IDirect3D structure. The first field must of course be
	the virtual table pointer. Everything else is free.
	</para>
	<para>
	Then we predeclare our static virtual table variable, we
	will need its address in some methods to initialize the
	virtual table pointer of the returned interface objects.
	</para>
	<para>
	Then we implement the interface methods. To match what has
	been declared in the header file they must take a pointer to
	a IDirect3D structure and we must cast it to an _IDirect3D
	so that we can manipulate the fields. This is performed by
	the ICOM_THIS macro.
	</para>
	<para>
	Finally we initialize the virtual table.
	</para>
	</sect2>
	</sect1>
	</chapter>

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