Samples/multimedia/directshow/baseclasses/winutil.h - deps/third_party/winsdk_samples_v71 - Git at Google

 //------------------------------------------------------------------------------
 // File: WinUtil.h
 //
 // Desc: DirectShow base classes - defines generic handler classes.
 //
 // Copyright (c) 1992-2001 Microsoft Corporation.  All rights reserved.
 //------------------------------------------------------------------------------


 // Make sure that you call PrepareWindow to initialise the window after
 // the object has been constructed. It is a separate method so that
 // derived classes can override useful methods like MessageLoop. Also
 // any derived class must call DoneWithWindow in its destructor. If it
 // doesn't a message may be retrieved and call a derived class member
 // function while a thread is executing the base class destructor code

 #ifndef __WINUTIL__
 #define __WINUTIL__

 const int DEFWIDTH = 320;                    // Initial window width
 const int DEFHEIGHT = 240;                   // Initial window height
 const int CAPTION = 256;                     // Maximum length of caption
 const int TIMELENGTH = 50;                   // Maximum length of times
 const int PROFILESTR = 128;                  // Normal profile string
 const WORD PALVERSION = 0x300;               // GDI palette version
 const LONG PALETTE_VERSION = (LONG) 1;       // Initial palette version
 const COLORREF VIDEO_COLOUR = 0;             // Defaults to black background
 const HANDLE hMEMORY = (HANDLE) (-1);        // Says to open as memory file

 #define WIDTH(x) ((*(x)).right - (*(x)).left)
 #define HEIGHT(x) ((*(x)).bottom - (*(x)).top)
 #define SHOWSTAGE TEXT("WM_SHOWSTAGE")
 #define SHOWSTAGETOP TEXT("WM_SHOWSTAGETOP")
 #define REALIZEPALETTE TEXT("WM_REALIZEPALETTE")

 class AM_NOVTABLE CBaseWindow
 {
 protected:

     HINSTANCE m_hInstance;          // Global module instance handle
     HWND m_hwnd;                    // Handle for our window
     HDC m_hdc;                      // Device context for the window
     LONG m_Width;                   // Client window width
     LONG m_Height;                  // Client window height
     BOOL m_bActivated;              // Has the window been activated
     LPTSTR m_pClassName;            // Static string holding class name
     DWORD m_ClassStyles;            // Passed in to our constructor
     DWORD m_WindowStyles;           // Likewise the initial window styles
     DWORD m_WindowStylesEx;         // And the extended window styles
     UINT m_ShowStageMessage;        // Have the window shown with focus
     UINT m_ShowStageTop;            // Makes the window WS_EX_TOPMOST
     UINT m_RealizePalette;          // Makes us realize our new palette
     HDC m_MemoryDC;                 // Used for fast BitBlt operations
     HPALETTE m_hPalette;            // Handle to any palette we may have
     BYTE m_bNoRealize;              // Don't realize palette now
     BYTE m_bBackground;             // Should we realise in background
     BYTE m_bRealizing;              // already realizing the palette
     CCritSec m_WindowLock;          // Serialise window object access
     BOOL m_bDoGetDC;                // Should this window get a DC
     bool m_bDoPostToDestroy;        // Use PostMessage to destroy
     CCritSec m_PaletteLock;         // This lock protects m_hPalette.
                                     // It should be held anytime the
                                     // program use the value of m_hPalette.

     // Maps windows message procedure into C++ methods
     friend LRESULT CALLBACK WndProc(HWND hwnd,      // Window handle
                                     UINT uMsg,      // Message ID
                                     WPARAM wParam,  // First parameter
                                     LPARAM lParam); // Other parameter

     virtual LRESULT OnPaletteChange(HWND hwnd, UINT Message);

 public:

     CBaseWindow(BOOL bDoGetDC = TRUE, bool bPostToDestroy = false);

 #ifdef DEBUG
     virtual ~CBaseWindow();
 #endif

     virtual HRESULT DoneWithWindow();
     virtual HRESULT PrepareWindow();
     virtual HRESULT InactivateWindow();
     virtual HRESULT ActivateWindow();
     virtual BOOL OnSize(LONG Width, LONG Height);
     virtual BOOL OnClose();
     virtual RECT GetDefaultRect();
     virtual HRESULT UninitialiseWindow();
     virtual HRESULT InitialiseWindow(HWND hwnd);

     HRESULT CompleteConnect();
     HRESULT DoCreateWindow();

     HRESULT PerformanceAlignWindow();
     HRESULT DoShowWindow(LONG ShowCmd);
     void PaintWindow(BOOL bErase);
     void DoSetWindowForeground(BOOL bFocus);
     virtual HRESULT SetPalette(HPALETTE hPalette);
     void SetRealize(BOOL bRealize)
     {
         m_bNoRealize = !bRealize;
     }

     //  Jump over to the window thread to set the current palette
     HRESULT SetPalette();
     void UnsetPalette(void);
     virtual HRESULT DoRealisePalette(BOOL bForceBackground = FALSE);

     void LockPaletteLock();
     void UnlockPaletteLock();

     virtual BOOL PossiblyEatMessage(UINT uMsg, WPARAM wParam, LPARAM lParam)
 	    { return FALSE; };

     // Access our window information

     bool WindowExists();
     LONG GetWindowWidth();
     LONG GetWindowHeight();
     HWND GetWindowHWND();
     HDC GetMemoryHDC();
     HDC GetWindowHDC();

     #ifdef DEBUG
     HPALETTE GetPalette();
     #endif // DEBUG

     // This is the window procedure the derived object should override

     virtual LRESULT OnReceiveMessage(HWND hwnd,          // Window handle
                                      UINT uMsg,          // Message ID
                                      WPARAM wParam,      // First parameter
                                      LPARAM lParam);     // Other parameter

     // Must be overriden to return class and window styles

     virtual LPTSTR GetClassWindowStyles(
                             __out DWORD *pClassStyles,          // Class styles
                             __out DWORD *pWindowStyles,         // Window styles
                             __out DWORD *pWindowStylesEx) PURE; // Extended styles
 };


 // This helper class is entirely subservient to the owning CBaseWindow object
 // All this object does is to split out the actual drawing operation from the
 // main object (because it was becoming too large). We have a number of entry
 // points to set things like the draw device contexts, to implement the actual
 // drawing and to set the destination rectangle in the client window. We have
 // no critical section locking in this class because we are used exclusively
 // by the owning window object which looks after serialising calls into us

 // If you want to use this class make sure you call NotifyAllocator once the
 // allocate has been agreed, also call NotifyMediaType with a pointer to a
 // NON stack based CMediaType once that has been set (we keep a pointer to
 // the original rather than taking a copy). When the palette changes call
 // IncrementPaletteVersion (easiest thing to do is to also call this method
 // in the SetMediaType method most filters implement). Finally before you
 // start rendering anything call SetDrawContext so that we can get the HDCs
 // for drawing from the CBaseWindow object we are given during construction

 class CDrawImage
 {
 protected:

     CBaseWindow *m_pBaseWindow;     // Owning video window object
     CRefTime m_StartSample;         // Start time for the current sample
     CRefTime m_EndSample;           // And likewise it's end sample time
     HDC m_hdc;                      // Main window device context
     HDC m_MemoryDC;                 // Offscreen draw device context
     RECT m_TargetRect;              // Target destination rectangle
     RECT m_SourceRect;              // Source image rectangle
     BOOL m_bStretch;                // Do we have to stretch the images
     BOOL m_bUsingImageAllocator;    // Are the samples shared DIBSECTIONs
     CMediaType *m_pMediaType;       // Pointer to the current format
     int m_perfidRenderTime;         // Time taken to render an image
     LONG m_PaletteVersion;          // Current palette version cookie

     // Draw the video images in the window

     void SlowRender(IMediaSample *pMediaSample);
     void FastRender(IMediaSample *pMediaSample);
     void DisplaySampleTimes(IMediaSample *pSample);
     void UpdateColourTable(HDC hdc,__in BITMAPINFOHEADER *pbmi);
     void SetStretchMode();

 public:

     // Used to control the image drawing

     CDrawImage(__inout CBaseWindow *pBaseWindow);
     BOOL DrawImage(IMediaSample *pMediaSample);
     BOOL DrawVideoImageHere(HDC hdc, IMediaSample *pMediaSample,
                             __in LPRECT lprcSrc, __in LPRECT lprcDst);
     void SetDrawContext();
     void SetTargetRect(__in RECT *pTargetRect);
     void SetSourceRect(__in RECT *pSourceRect);
     void GetTargetRect(__out RECT *pTargetRect);
     void GetSourceRect(__out RECT *pSourceRect);
     virtual RECT ScaleSourceRect(const RECT *pSource);

     // Handle updating palettes as they change

     LONG GetPaletteVersion();
     void ResetPaletteVersion();
     void IncrementPaletteVersion();

     // Tell us media types and allocator assignments

     void NotifyAllocator(BOOL bUsingImageAllocator);
     void NotifyMediaType(__in CMediaType *pMediaType);
     BOOL UsingImageAllocator();

     // Called when we are about to draw an image

     void NotifyStartDraw() {
         MSR_START(m_perfidRenderTime);
     };

     // Called when we complete an image rendering

     void NotifyEndDraw() {
         MSR_STOP(m_perfidRenderTime);
     };
 };


 // This is the structure used to keep information about each GDI DIB. All the
 // samples we create from our allocator will have a DIBSECTION allocated to
 // them. When we receive the sample we know we can BitBlt straight to an HDC

 typedef struct tagDIBDATA {

     LONG        PaletteVersion;     // Current palette version in use
     DIBSECTION  DibSection;         // Details of DIB section allocated
     HBITMAP     hBitmap;            // Handle to bitmap for drawing
     HANDLE      hMapping;           // Handle to shared memory block
     BYTE        *pBase;             // Pointer to base memory address

 } DIBDATA;


 // This class inherits from CMediaSample and uses all of it's methods but it
 // overrides the constructor to initialise itself with the DIBDATA structure
 // When we come to render an IMediaSample we will know if we are using our own
 // allocator, and if we are, we can cast the IMediaSample to a pointer to one
 // of these are retrieve the DIB section information and hence the HBITMAP

 class CImageSample : public CMediaSample
 {
 protected:

     DIBDATA m_DibData;      // Information about the DIBSECTION
     BOOL m_bInit;           // Is the DIB information setup

 public:

     // Constructor

     CImageSample(__inout CBaseAllocator *pAllocator,
                  __in_opt LPCTSTR pName,
                  __inout HRESULT *phr,
                  __in_bcount(length) LPBYTE pBuffer,
                  LONG length);

     // Maintain the DIB/DirectDraw state

     void SetDIBData(__in DIBDATA *pDibData);
     __out DIBDATA *GetDIBData();
 };


 // This is an allocator based on the abstract CBaseAllocator base class that
 // allocates sample buffers in shared memory. The number and size of these
 // are determined when the output pin calls Prepare on us. The shared memory
 // blocks are used in subsequent calls to GDI CreateDIBSection, once that
 // has been done the output pin can fill the buffers with data which will
 // then be handed to GDI through BitBlt calls and thereby remove one copy

 class CImageAllocator : public CBaseAllocator
 {
 protected:

     CBaseFilter *m_pFilter;   // Delegate reference counts to
     CMediaType *m_pMediaType;           // Pointer to the current format

     // Used to create and delete samples

     HRESULT Alloc();
     void Free();

     // Manage the shared DIBSECTION and DCI/DirectDraw buffers

     HRESULT CreateDIB(LONG InSize,DIBDATA &DibData);
     STDMETHODIMP CheckSizes(__in ALLOCATOR_PROPERTIES *pRequest);
     virtual CImageSample *CreateImageSample(__in_bcount(Length) LPBYTE pData,LONG Length);

 public:

     // Constructor and destructor

     CImageAllocator(__inout CBaseFilter *pFilter,__in_opt LPCTSTR pName,__inout HRESULT *phr);
 #ifdef DEBUG
     ~CImageAllocator();
 #endif

     STDMETHODIMP_(ULONG) NonDelegatingAddRef();
     STDMETHODIMP_(ULONG) NonDelegatingRelease();
     void NotifyMediaType(__in CMediaType *pMediaType);

     // Agree the number of buffers to be used and their size

     STDMETHODIMP SetProperties(
         __in ALLOCATOR_PROPERTIES *pRequest,
         __out ALLOCATOR_PROPERTIES *pActual);
 };


 // This class is a fairly specialised helper class for image renderers that
 // have to create and manage palettes. The CBaseWindow class looks after
 // realising palettes once they have been installed. This class can be used
 // to create the palette handles from a media format (which must contain a
 // VIDEOINFO structure in the format block). We try to make the palette an
 // identity palette to maximise performance and also only change palettes
 // if actually required to (we compare palette colours before updating).
 // All the methods are virtual so that they can be overriden if so required

 class CImagePalette
 {
 protected:

     CBaseWindow *m_pBaseWindow;             // Window to realise palette in
     CBaseFilter *m_pFilter;                 // Media filter to send events
     CDrawImage *m_pDrawImage;               // Object who will be drawing
     HPALETTE m_hPalette;                    // The palette handle we own

 public:

     CImagePalette(__inout CBaseFilter *pBaseFilter,
                   __inout CBaseWindow *pBaseWindow,
                   __inout CDrawImage *pDrawImage);

 #ifdef DEBUG
     virtual ~CImagePalette();
 #endif

     static HPALETTE MakePalette(const VIDEOINFOHEADER *pVideoInfo, __in LPSTR szDevice);
     HRESULT RemovePalette();
     static HRESULT MakeIdentityPalette(__inout_ecount_full(iColours) PALETTEENTRY *pEntry,INT iColours, __in LPSTR szDevice);
     HRESULT CopyPalette(const CMediaType *pSrc,__out CMediaType *pDest);
     BOOL ShouldUpdate(const VIDEOINFOHEADER *pNewInfo,const VIDEOINFOHEADER *pOldInfo);
     HRESULT PreparePalette(const CMediaType *pmtNew,const CMediaType *pmtOld,__in LPSTR szDevice);

     BOOL DrawVideoImageHere(HDC hdc, IMediaSample *pMediaSample, __in LPRECT lprcSrc, __in LPRECT lprcDst)
     {
         return m_pDrawImage->DrawVideoImageHere(hdc, pMediaSample, lprcSrc,lprcDst);
     }
 };


 // Another helper class really for video based renderers. Most such renderers
 // need to know what the display format is to some degree or another. This
 // class initialises itself with the display format. The format can be asked
 // for through GetDisplayFormat and various other accessor functions. If a
 // filter detects a display format change (perhaps it gets a WM_DEVMODECHANGE
 // message then it can call RefreshDisplayType to reset that format). Also
 // many video renderers will want to check formats as they are proposed by
 // source filters. This class provides methods to check formats and only
 // accept those video formats that can be efficiently drawn using GDI calls

 class CImageDisplay : public CCritSec
 {
 protected:

     // This holds the display format; biSize should not be too big, so we can
     // safely use the VIDEOINFO structure
     VIDEOINFO m_Display;

     static DWORD CountSetBits(const DWORD Field);
     static DWORD CountPrefixBits(const DWORD Field);
     static BOOL CheckBitFields(const VIDEOINFO *pInput);

 public:

     // Constructor and destructor

     CImageDisplay();

     // Used to manage BITMAPINFOHEADERs and the display format

     const VIDEOINFO *GetDisplayFormat();
     HRESULT RefreshDisplayType(__in_opt LPSTR szDeviceName);
     static BOOL CheckHeaderValidity(const VIDEOINFO *pInput);
     static BOOL CheckPaletteHeader(const VIDEOINFO *pInput);
     BOOL IsPalettised();
     WORD GetDisplayDepth();

     // Provide simple video format type checking

     HRESULT CheckMediaType(const CMediaType *pmtIn);
     HRESULT CheckVideoType(const VIDEOINFO *pInput);
     HRESULT UpdateFormat(__inout VIDEOINFO *pVideoInfo);
     const DWORD *GetBitMasks(const VIDEOINFO *pVideoInfo);

     BOOL GetColourMask(__out DWORD *pMaskRed,
                        __out DWORD *pMaskGreen,
                        __out DWORD *pMaskBlue);
 };

 //  Convert a FORMAT_VideoInfo to FORMAT_VideoInfo2
 STDAPI ConvertVideoInfoToVideoInfo2(__inout AM_MEDIA_TYPE *pmt);

 //  Check a media type containing VIDEOINFOHEADER
 STDAPI CheckVideoInfoType(const AM_MEDIA_TYPE *pmt);

 //  Check a media type containing VIDEOINFOHEADER
 STDAPI CheckVideoInfo2Type(const AM_MEDIA_TYPE *pmt);

 #endif // __WINUTIL__
	//------------------------------------------------------------------------------
	// File: WinUtil.h
	//
	// Desc: DirectShow base classes - defines generic handler classes.
	//
	// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
	//------------------------------------------------------------------------------


	// Make sure that you call PrepareWindow to initialise the window after
	// the object has been constructed. It is a separate method so that
	// derived classes can override useful methods like MessageLoop. Also
	// any derived class must call DoneWithWindow in its destructor. If it
	// doesn't a message may be retrieved and call a derived class member
	// function while a thread is executing the base class destructor code

	#ifndef __WINUTIL__
	#define __WINUTIL__

	const int DEFWIDTH = 320; // Initial window width
	const int DEFHEIGHT = 240; // Initial window height
	const int CAPTION = 256; // Maximum length of caption
	const int TIMELENGTH = 50; // Maximum length of times
	const int PROFILESTR = 128; // Normal profile string
	const WORD PALVERSION = 0x300; // GDI palette version
	const LONG PALETTE_VERSION = (LONG) 1; // Initial palette version
	const COLORREF VIDEO_COLOUR = 0; // Defaults to black background
	const HANDLE hMEMORY = (HANDLE) (-1); // Says to open as memory file

	#define WIDTH(x) (((x)).right - ((x)).left)
	#define HEIGHT(x) (((x)).bottom - ((x)).top)
	#define SHOWSTAGE TEXT("WM_SHOWSTAGE")
	#define SHOWSTAGETOP TEXT("WM_SHOWSTAGETOP")
	#define REALIZEPALETTE TEXT("WM_REALIZEPALETTE")

	class AM_NOVTABLE CBaseWindow
	{
	protected:

	HINSTANCE m_hInstance; // Global module instance handle
	HWND m_hwnd; // Handle for our window
	HDC m_hdc; // Device context for the window
	LONG m_Width; // Client window width
	LONG m_Height; // Client window height
	BOOL m_bActivated; // Has the window been activated
	LPTSTR m_pClassName; // Static string holding class name
	DWORD m_ClassStyles; // Passed in to our constructor
	DWORD m_WindowStyles; // Likewise the initial window styles
	DWORD m_WindowStylesEx; // And the extended window styles
	UINT m_ShowStageMessage; // Have the window shown with focus
	UINT m_ShowStageTop; // Makes the window WS_EX_TOPMOST
	UINT m_RealizePalette; // Makes us realize our new palette
	HDC m_MemoryDC; // Used for fast BitBlt operations
	HPALETTE m_hPalette; // Handle to any palette we may have
	BYTE m_bNoRealize; // Don't realize palette now
	BYTE m_bBackground; // Should we realise in background
	BYTE m_bRealizing; // already realizing the palette
	CCritSec m_WindowLock; // Serialise window object access
	BOOL m_bDoGetDC; // Should this window get a DC
	bool m_bDoPostToDestroy; // Use PostMessage to destroy
	CCritSec m_PaletteLock; // This lock protects m_hPalette.
	// It should be held anytime the
	// program use the value of m_hPalette.

	// Maps windows message procedure into C++ methods
	friend LRESULT CALLBACK WndProc(HWND hwnd, // Window handle
	UINT uMsg, // Message ID
	WPARAM wParam, // First parameter
	LPARAM lParam); // Other parameter

	virtual LRESULT OnPaletteChange(HWND hwnd, UINT Message);

	public:

	CBaseWindow(BOOL bDoGetDC = TRUE, bool bPostToDestroy = false);

	#ifdef DEBUG
	virtual ~CBaseWindow();
	#endif

	virtual HRESULT DoneWithWindow();
	virtual HRESULT PrepareWindow();
	virtual HRESULT InactivateWindow();
	virtual HRESULT ActivateWindow();
	virtual BOOL OnSize(LONG Width, LONG Height);
	virtual BOOL OnClose();
	virtual RECT GetDefaultRect();
	virtual HRESULT UninitialiseWindow();
	virtual HRESULT InitialiseWindow(HWND hwnd);

	HRESULT CompleteConnect();
	HRESULT DoCreateWindow();

	HRESULT PerformanceAlignWindow();
	HRESULT DoShowWindow(LONG ShowCmd);
	void PaintWindow(BOOL bErase);
	void DoSetWindowForeground(BOOL bFocus);
	virtual HRESULT SetPalette(HPALETTE hPalette);
	void SetRealize(BOOL bRealize)
	{
	m_bNoRealize = !bRealize;
	}

	// Jump over to the window thread to set the current palette
	HRESULT SetPalette();
	void UnsetPalette(void);
	virtual HRESULT DoRealisePalette(BOOL bForceBackground = FALSE);

	void LockPaletteLock();
	void UnlockPaletteLock();

	virtual BOOL PossiblyEatMessage(UINT uMsg, WPARAM wParam, LPARAM lParam)
	{ return FALSE; };

	// Access our window information

	bool WindowExists();
	LONG GetWindowWidth();
	LONG GetWindowHeight();
	HWND GetWindowHWND();
	HDC GetMemoryHDC();
	HDC GetWindowHDC();

	#ifdef DEBUG
	HPALETTE GetPalette();
	#endif // DEBUG

	// This is the window procedure the derived object should override

	virtual LRESULT OnReceiveMessage(HWND hwnd, // Window handle
	UINT uMsg, // Message ID
	WPARAM wParam, // First parameter
	LPARAM lParam); // Other parameter

	// Must be overriden to return class and window styles

	virtual LPTSTR GetClassWindowStyles(
	__out DWORD *pClassStyles, // Class styles
	__out DWORD *pWindowStyles, // Window styles
	__out DWORD *pWindowStylesEx) PURE; // Extended styles
	};


	// This helper class is entirely subservient to the owning CBaseWindow object
	// All this object does is to split out the actual drawing operation from the
	// main object (because it was becoming too large). We have a number of entry
	// points to set things like the draw device contexts, to implement the actual
	// drawing and to set the destination rectangle in the client window. We have
	// no critical section locking in this class because we are used exclusively
	// by the owning window object which looks after serialising calls into us

	// If you want to use this class make sure you call NotifyAllocator once the
	// allocate has been agreed, also call NotifyMediaType with a pointer to a
	// NON stack based CMediaType once that has been set (we keep a pointer to
	// the original rather than taking a copy). When the palette changes call
	// IncrementPaletteVersion (easiest thing to do is to also call this method
	// in the SetMediaType method most filters implement). Finally before you
	// start rendering anything call SetDrawContext so that we can get the HDCs
	// for drawing from the CBaseWindow object we are given during construction

	class CDrawImage
	{
	protected:

	CBaseWindow *m_pBaseWindow; // Owning video window object
	CRefTime m_StartSample; // Start time for the current sample
	CRefTime m_EndSample; // And likewise it's end sample time
	HDC m_hdc; // Main window device context
	HDC m_MemoryDC; // Offscreen draw device context
	RECT m_TargetRect; // Target destination rectangle
	RECT m_SourceRect; // Source image rectangle
	BOOL m_bStretch; // Do we have to stretch the images
	BOOL m_bUsingImageAllocator; // Are the samples shared DIBSECTIONs
	CMediaType *m_pMediaType; // Pointer to the current format
	int m_perfidRenderTime; // Time taken to render an image
	LONG m_PaletteVersion; // Current palette version cookie

	// Draw the video images in the window

	void SlowRender(IMediaSample *pMediaSample);
	void FastRender(IMediaSample *pMediaSample);
	void DisplaySampleTimes(IMediaSample *pSample);
	void UpdateColourTable(HDC hdc,__in BITMAPINFOHEADER *pbmi);
	void SetStretchMode();

	public:

	// Used to control the image drawing

	CDrawImage(__inout CBaseWindow *pBaseWindow);
	BOOL DrawImage(IMediaSample *pMediaSample);
	BOOL DrawVideoImageHere(HDC hdc, IMediaSample *pMediaSample,
	__in LPRECT lprcSrc, __in LPRECT lprcDst);
	void SetDrawContext();
	void SetTargetRect(__in RECT *pTargetRect);
	void SetSourceRect(__in RECT *pSourceRect);
	void GetTargetRect(__out RECT *pTargetRect);
	void GetSourceRect(__out RECT *pSourceRect);
	virtual RECT ScaleSourceRect(const RECT *pSource);

	// Handle updating palettes as they change

	LONG GetPaletteVersion();
	void ResetPaletteVersion();
	void IncrementPaletteVersion();

	// Tell us media types and allocator assignments

	void NotifyAllocator(BOOL bUsingImageAllocator);
	void NotifyMediaType(__in CMediaType *pMediaType);
	BOOL UsingImageAllocator();

	// Called when we are about to draw an image

	void NotifyStartDraw() {
	MSR_START(m_perfidRenderTime);
	};

	// Called when we complete an image rendering

	void NotifyEndDraw() {
	MSR_STOP(m_perfidRenderTime);
	};
	};


	// This is the structure used to keep information about each GDI DIB. All the
	// samples we create from our allocator will have a DIBSECTION allocated to
	// them. When we receive the sample we know we can BitBlt straight to an HDC

	typedef struct tagDIBDATA {

	LONG PaletteVersion; // Current palette version in use
	DIBSECTION DibSection; // Details of DIB section allocated
	HBITMAP hBitmap; // Handle to bitmap for drawing
	HANDLE hMapping; // Handle to shared memory block
	BYTE *pBase; // Pointer to base memory address

	} DIBDATA;


	// This class inherits from CMediaSample and uses all of it's methods but it
	// overrides the constructor to initialise itself with the DIBDATA structure
	// When we come to render an IMediaSample we will know if we are using our own
	// allocator, and if we are, we can cast the IMediaSample to a pointer to one
	// of these are retrieve the DIB section information and hence the HBITMAP

	class CImageSample : public CMediaSample
	{
	protected:

	DIBDATA m_DibData; // Information about the DIBSECTION
	BOOL m_bInit; // Is the DIB information setup

	public:

	// Constructor

	CImageSample(__inout CBaseAllocator *pAllocator,
	__in_opt LPCTSTR pName,
	__inout HRESULT *phr,
	__in_bcount(length) LPBYTE pBuffer,
	LONG length);

	// Maintain the DIB/DirectDraw state

	void SetDIBData(__in DIBDATA *pDibData);
	__out DIBDATA *GetDIBData();
	};


	// This is an allocator based on the abstract CBaseAllocator base class that
	// allocates sample buffers in shared memory. The number and size of these
	// are determined when the output pin calls Prepare on us. The shared memory
	// blocks are used in subsequent calls to GDI CreateDIBSection, once that
	// has been done the output pin can fill the buffers with data which will
	// then be handed to GDI through BitBlt calls and thereby remove one copy

	class CImageAllocator : public CBaseAllocator
	{
	protected:

	CBaseFilter *m_pFilter; // Delegate reference counts to
	CMediaType *m_pMediaType; // Pointer to the current format

	// Used to create and delete samples

	HRESULT Alloc();
	void Free();

	// Manage the shared DIBSECTION and DCI/DirectDraw buffers

	HRESULT CreateDIB(LONG InSize,DIBDATA &DibData);
	STDMETHODIMP CheckSizes(__in ALLOCATOR_PROPERTIES *pRequest);
	virtual CImageSample *CreateImageSample(__in_bcount(Length) LPBYTE pData,LONG Length);

	public:

	// Constructor and destructor

	CImageAllocator(__inout CBaseFilter pFilter,__in_opt LPCTSTR pName,__inout HRESULT phr);
	#ifdef DEBUG
	~CImageAllocator();
	#endif

	STDMETHODIMP_(ULONG) NonDelegatingAddRef();
	STDMETHODIMP_(ULONG) NonDelegatingRelease();
	void NotifyMediaType(__in CMediaType *pMediaType);

	// Agree the number of buffers to be used and their size

	STDMETHODIMP SetProperties(
	__in ALLOCATOR_PROPERTIES *pRequest,
	__out ALLOCATOR_PROPERTIES *pActual);
	};


	// This class is a fairly specialised helper class for image renderers that
	// have to create and manage palettes. The CBaseWindow class looks after
	// realising palettes once they have been installed. This class can be used
	// to create the palette handles from a media format (which must contain a
	// VIDEOINFO structure in the format block). We try to make the palette an
	// identity palette to maximise performance and also only change palettes
	// if actually required to (we compare palette colours before updating).
	// All the methods are virtual so that they can be overriden if so required

	class CImagePalette
	{
	protected:

	CBaseWindow *m_pBaseWindow; // Window to realise palette in
	CBaseFilter *m_pFilter; // Media filter to send events
	CDrawImage *m_pDrawImage; // Object who will be drawing
	HPALETTE m_hPalette; // The palette handle we own

	public:

	CImagePalette(__inout CBaseFilter *pBaseFilter,
	__inout CBaseWindow *pBaseWindow,
	__inout CDrawImage *pDrawImage);

	#ifdef DEBUG
	virtual ~CImagePalette();
	#endif

	static HPALETTE MakePalette(const VIDEOINFOHEADER *pVideoInfo, __in LPSTR szDevice);
	HRESULT RemovePalette();
	static HRESULT MakeIdentityPalette(__inout_ecount_full(iColours) PALETTEENTRY *pEntry,INT iColours, __in LPSTR szDevice);
	HRESULT CopyPalette(const CMediaType pSrc,__out CMediaType pDest);
	BOOL ShouldUpdate(const VIDEOINFOHEADER pNewInfo,const VIDEOINFOHEADER pOldInfo);
	HRESULT PreparePalette(const CMediaType pmtNew,const CMediaType pmtOld,__in LPSTR szDevice);

	BOOL DrawVideoImageHere(HDC hdc, IMediaSample *pMediaSample, __in LPRECT lprcSrc, __in LPRECT lprcDst)
	{
	return m_pDrawImage->DrawVideoImageHere(hdc, pMediaSample, lprcSrc,lprcDst);
	}
	};


	// Another helper class really for video based renderers. Most such renderers
	// need to know what the display format is to some degree or another. This
	// class initialises itself with the display format. The format can be asked
	// for through GetDisplayFormat and various other accessor functions. If a
	// filter detects a display format change (perhaps it gets a WM_DEVMODECHANGE
	// message then it can call RefreshDisplayType to reset that format). Also
	// many video renderers will want to check formats as they are proposed by
	// source filters. This class provides methods to check formats and only
	// accept those video formats that can be efficiently drawn using GDI calls

	class CImageDisplay : public CCritSec
	{
	protected:

	// This holds the display format; biSize should not be too big, so we can
	// safely use the VIDEOINFO structure
	VIDEOINFO m_Display;

	static DWORD CountSetBits(const DWORD Field);
	static DWORD CountPrefixBits(const DWORD Field);
	static BOOL CheckBitFields(const VIDEOINFO *pInput);

	public:

	// Constructor and destructor

	CImageDisplay();

	// Used to manage BITMAPINFOHEADERs and the display format

	const VIDEOINFO *GetDisplayFormat();
	HRESULT RefreshDisplayType(__in_opt LPSTR szDeviceName);
	static BOOL CheckHeaderValidity(const VIDEOINFO *pInput);
	static BOOL CheckPaletteHeader(const VIDEOINFO *pInput);
	BOOL IsPalettised();
	WORD GetDisplayDepth();

	// Provide simple video format type checking

	HRESULT CheckMediaType(const CMediaType *pmtIn);
	HRESULT CheckVideoType(const VIDEOINFO *pInput);
	HRESULT UpdateFormat(__inout VIDEOINFO *pVideoInfo);
	const DWORD GetBitMasks(const VIDEOINFO pVideoInfo);

	BOOL GetColourMask(__out DWORD *pMaskRed,
	__out DWORD *pMaskGreen,
	__out DWORD *pMaskBlue);
	};

	// Convert a FORMAT_VideoInfo to FORMAT_VideoInfo2
	STDAPI ConvertVideoInfoToVideoInfo2(__inout AM_MEDIA_TYPE *pmt);

	// Check a media type containing VIDEOINFOHEADER
	STDAPI CheckVideoInfoType(const AM_MEDIA_TYPE *pmt);

	// Check a media type containing VIDEOINFOHEADER
	STDAPI CheckVideoInfo2Type(const AM_MEDIA_TYPE *pmt);

	#endif // __WINUTIL__