用DirectX绘制使用纹理的立方体

下面将学习DirectX的3D渲染基础部分，但不会对3D数学或图形理论有太详细的介绍。 首先要了解DirectX中的坐标系，要记住的是DirectX采用左手坐标系。

在Direct3D中渲染一个场景，涉及到的三维变换有：世界变换、视图变换、投影变换。

世界变换：三维变换的第一步就是将模型的顶点的局部坐标变换到所有对象都共享的一个坐标系中，也就是从模型空间向世界空间转换。变换到的新的坐标系称为世界坐标系。世界坐标系中的每一个顶点的坐标都以世界坐标系来表示。根据需要，应该将物体进行缩放、旋转、平移后放置到我们想要的位置。

视图变换：又称为观察变换，即如照相机一般，表示用户在屏幕上看到的内容。我们在世界坐标系中选择一个观察点，世界坐标系将被重新定位到这个观察点的视野中，也就是从世界坐标空间向观察空间的转换。需要注意的是，观察变换实际上是坐标系的变换。但是，Direct3D在处理时是对物体顶点进行矩阵变换，所以观察矩阵需要执行与视点变换相反的变换。例如，我们希望视点沿着z轴负方向移动5个单位，那么相对的就是顶点向z轴正方向移动5个单位。

投影变换：这是最后一步，在这里将视图变换的结果投影到屏幕上形成2D图像。视景体(field of view, FOV)用于定义在某个特定的位置能够看到的物体的范围，又称为视锥体或观察体。视景体在三维空间由6个面组成，以你的眼睛为视点向前看，依次是投影平面、近平面、远平面。典型的投影变换包括缩放和透视投影。投影变换将视景体变换为一个立方体。因为视景体的近端比远端小，所以会在投影平面上产生了离摄像机近的物体就被放大的效果。

除此之外，还要理解一些常见的术语，比如顶点缓存、索引缓存、深度缓存、模板缓存、交换链、多重采样、着色器、HLSL，下面将会简要介绍。

DirectX是一种基于COM（Component Object Model，组件对象模型）的系统，它既不属于驱动程序层，也不属于应用层。DirectX的主要设计目标是提供某种设备的独立性的同时获取很高的速度。COM使Direct3D独立于编程语言和具有向下兼容性，通常把COM对象作为一个接口，可以把它当做达到某种目的的C++类来使用，COM接口都具有前缀大写字母I表示，比如接口ID3DTexture2D。在DirectX的体系结构中，处于DirectX下层的是HAL(Hardware Abstract Layer,硬件抽象层）与HEL(Hardware Emulation Layer,硬件模拟层)。HAL负责检测本机的硬件功能，并以一种独立于设备的方式提供这些功能。HEL负责提供DirectX功能中本机硬件不支持部分的软件模拟实现。从DirectX 8.0起，DirectX就不再提供硬件模拟层HEL模块了，最新的DirectX 11要求硬件必须实现全部DirectX 11的特性，因此现在的DirectX是严重依赖于硬件的。Direct3D是一种低层的图形API，它能让我们利用三维硬件加速来渲染三维世界，可以被看成应用程序和图形设备之间的中介。

这里必须提到的是，DirectX 9中采用固定图像渲染管线，而DirectX 10与DirectX 11都放弃了固定的渲染管线，可以通过着色器代码改变渲染管线的过程。 在DirectX 9中，提供了两个独立的着色器：顶点着色器与像素着色器，在硬件中有各自的实现，不能通用。而从DirectX 10起，Shader Model 4.0提出了通用着色器的概念，即硬件上仅仅实现一种着色器，每一个着色阶段都利用通用着色器实现核心功能，每个特定的着色阶段都提供各自的额外功能。在通用着色器中，无论是常数、纹理或是缓存都被视为同样的资源直接或者通过采样器传递给着色器代码进行处理，HLSL便是DirectX使用的着色语言，类似C语言。

顶点着色器：顶点着色阶段将顶点作为输入集，负责处理“逐顶点”的操作，如坐标变换、蒙皮、动画以及顶点光照。顶点着色器的工作是处理一个独立的输入顶点并产生一个独立的输出顶点。顶点着色阶段在渲染管线中必须激活，即便没有对顶点做任何修改，也必须提供一个“不做任何修改”的顶点着色器才能保证渲染管线的正常工作。

几何着色器：这时由Direct3D 10引入的新的着色阶段，用来在已知的输入顶点的基础上生成新的输入顶点。和顶点着色器不同的是，顶点着色器仅仅处理独立的顶点，而几何着色器的输入则是一个图元（两个顶点的线段、三个顶点的三角形、一个顶点的独立点等），也可以将顶点的邻接点作为输入。

像素着色器：可以实现丰富的着色技术如逐像素光照和后期处理等。像素着色器可以通过常量、贴图、插值以及其他数据来产生逐像素的输出值。光栅处理器对每一个图元中的每一个像素都会执行一次像素着色器，但是也可以通过程序设置跳过像素着色器的执行。

计算着色器：是Direct3D 11引入的新着色器，独立于渲染管线之外，和其他着色器一样使用着色器语言实现。计算着色器提供了利用GPU中大量并行处理器进行高速通用计算的能力。

Direct3D管线中用到的所有资源可分为缓存（buffer)资源和纹理(texture)资源。缓存资源是指一组指定类型的数据的集合，分为顶点缓存、索引缓存、常量缓存。顶点缓存用于存储顶点数据，包括顶点的位置、法线、纹理坐标。纹理资源是一种结构，用于存储纹理。Direct3D有三种纹理类型：一维、二维和三维纹理。一维纹理指只在某一方向上变化，相当于高度为1的二维纹理；二维纹理是指纹理在相互垂直的两个方向上变化，用u表示横向纹理，v表示纵向纹理；三维纹理，其纹理单元为三维纹理体，每个纹理单元用u、v、w向量表示。多重纹理是指事先制定一系列分辨率逐渐减小的纹理图像，纹理采用mipmap方式自动生成，即每个层次的纹理细节（LOD）为小于上一级纹理平方根大小，Direct3D会根据所映射的物体尺寸自动选择使用哪个分辨率的纹理图。

Direct3D维护着两个纹理缓存，前台缓存(Front Buffer）和后台缓存(Back Buffer)。前台缓存存储着当前显示在屏幕上的图像数据，下一帧的动画则被绘制在后台缓存上。为了避免动画的闪动，当帧的整个场景在后台缓存中绘制好后，后台缓存和前台缓存就互相交换，这样后台缓存中的内容才被完整地呈现在屏幕上。前台缓存与后台缓存组成了交换链。

深度缓存是一个只包含特定像素深度信息而不包含图像数据的纹理。深度值的范围为[0,1]，0表示能被观察者看到的最近的位置，1表示能被观察者看到的最远的位置。为了理解这个概念，设想这样一个场景，一个圆圈环绕着一个立方体，显然圆圈会遮挡一部分的立方体，该如何绘制场景了？如果采用传统的画家算法，先画什么，再画什么就不行了。Direct3D在像素级别上提供了一个很好的解决方案，它使用一种叫深度缓存，又叫z-buffer的技术。深度缓存保存着每个像素的深度值，也叫z值，在绘制场景时按深度值绘制就可以了。

用像素矩阵表示的图像通常会出现“阶梯效应”，比如一条线段的边缘产生了锯齿，发生走样。这里要采用反走样技术，通过采集并使用线段中的点周围的一些像素，减少图像的阶梯效应。Direct3D支持一种称为多重采样的反走样技术，它使用目标像素周围的一些点来生成该像素点的最终颜色。由于这个过程使用了多个像素采样，所以叫多重采样。

实际的模型可以分为很多个三角形，这些三角形有大量的重复顶点和重复边。如果在顶点缓存中重复保存这些顶点信息，那么显卡将耗费比实际模型体积大得多的空间来保存模型信息。这里必须引入索引缓存的概念，它不能脱离顶点缓存而独立存在。我们需要建立一个顶点缓存，比如一个立方体，顶点缓存中只需要保存8个顶点的信息。除此之外，还需要建立一个缓存来确定每一个顶点对应顶点缓存中的哪一个顶点，这就是索引缓存。

模板是一块特殊的缓存区，称为模板缓存(Stencil Buffer)。模板缓存的作用是限定哪些像素将被绘制到屏幕上而哪些不会。因为模板缓存的容量很小，因此在实际的硬件实现中，并没有一个独立的模板缓存，而是将深度缓存和模板缓存合并成一个深度模板缓存(Depth Stencil Buffer)，其中每一个像素的前24位用作深度缓存，而后8位用于模板缓存。

Direct3D使用由用户自定义的顶点格式，下面是我们将要使用的结构VERTEX。前三个成员变量是顶点的位置，而tu和tv用于表达使用的纹理的坐标，可以使用tu=0.0、tv=0.0指定纹理左上角，tu=1.0、tv=1.0指定纹理右下角。

struct VERTEX
{
    float x, y, z;
    float tu, tv;
};

 

我们要创建一个四边形，所以需要这样一个结构QUAD，显然vertices保存四个顶点，buffer为顶点缓存，texture为用于着色的纹理贴图。

struct QUAD
{
    VERTEX vertices[4];
    LPDIRECT3DVERTEXBUFFER9 buffer;
    LPDIRECT3DTEXTURE9 texture;
};

 

基础部分暂时讲到这里，下面看一个例子，还是基于前面的例子，只有game.cpp文件改变了，也是唯一重要的文件。

DirectSound.h

//-----------------------------------------------------------------------------
// File: DSUtil.h
//
// Desc: 
//
// Copyright (c) Microsoft Corp. All rights reserved.
//-----------------------------------------------------------------------------
//
// Note: This file has been edited for use in Beginning Game Programming, Third Edition,
// originally distributed with a 2004 release of DirectX 9.0c SDK.
//

#ifndef DSUTIL_H
#define DSUTIL_H

#include <windows.h>
#include <mmsystem.h>
#include <mmreg.h>
#include <dsound.h>
#include <dxerr.h>

#pragma comment(lib, "dxerr.lib")
#pragma comment(lib, "dsound.lib")


//-----------------------------------------------------------------------------
// Classes used by this header
//-----------------------------------------------------------------------------
class CSoundManager;
class CSound;
class CStreamingSound;
class CWaveFile;




//-----------------------------------------------------------------------------
// Typing macros 
//-----------------------------------------------------------------------------
#define WAVEFILE_READ   1
#define WAVEFILE_WRITE  2

#define DSUtil_StopSound(s)         { if(s) s->Stop(); }
#define DSUtil_PlaySound(s)         { if(s) s->Play( 0, 0 ); }
#define DSUtil_PlaySoundLooping(s)  { if(s) s->Play( 0, DSBPLAY_LOOPING ); }




//-----------------------------------------------------------------------------
// Name: class CSoundManager
// Desc: 
//-----------------------------------------------------------------------------
class CSoundManager
{
protected:
    LPDIRECTSOUND8 m_pDS;

public:
    CSoundManager();
    ~CSoundManager();

    HRESULT Initialize( HWND hWnd, DWORD dwCoopLevel );

    inline  LPDIRECTSOUND8 GetDirectSound() { return m_pDS; }

    HRESULT SetPrimaryBufferFormat( DWORD dwPrimaryChannels, DWORD dwPrimaryFreq, 
        DWORD dwPrimaryBitRate );

    HRESULT Create( CSound** ppSound, LPTSTR strWaveFileName, DWORD dwCreationFlags = 0,
        GUID guid3DAlgorithm = GUID_NULL, DWORD dwNumBuffers = 1 );
};




//-----------------------------------------------------------------------------
// Name: class CSound
// Desc: Encapsulates functionality of a DirectSound buffer.
//-----------------------------------------------------------------------------
class CSound
{
protected:
    LPDIRECTSOUNDBUFFER* m_apDSBuffer;
    DWORD                m_dwDSBufferSize;
    CWaveFile*           m_pWaveFile;
    DWORD                m_dwNumBuffers;
    DWORD                m_dwCreationFlags;

    HRESULT RestoreBuffer( LPDIRECTSOUNDBUFFER pDSB, BOOL* pbWasRestored );

public:
    CSound( LPDIRECTSOUNDBUFFER* apDSBuffer, DWORD dwDSBufferSize, DWORD dwNumBuffers,
        CWaveFile* pWaveFile, DWORD dwCreationFlags );
    virtual ~CSound();

    HRESULT FillBufferWithSound( LPDIRECTSOUNDBUFFER pDSB, BOOL bRepeatWavIfBufferLarger );
    LPDIRECTSOUNDBUFFER GetFreeBuffer();

    HRESULT Play( DWORD dwPriority = 0, DWORD dwFlags = 0, LONG lVolume = 0, 
        LONG lFrequency = -1, LONG lPan = 0 );
    HRESULT Stop();
    HRESULT Reset();
    BOOL    IsSoundPlaying();
};


//-----------------------------------------------------------------------------
// Name: class CWaveFile
// Desc: Encapsulates reading or writing sound data to or from a wave file
//-----------------------------------------------------------------------------
class CWaveFile
{
public:
    WAVEFORMATEX* m_pwfx;        // Pointer to WAVEFORMATEX structure
    HMMIO         m_hmmio;       // MM I/O handle for the WAVE
    MMCKINFO      m_ck;          // Multimedia RIFF chunk
    MMCKINFO      m_ckRiff;      // Use in opening a WAVE file
    DWORD         m_dwSize;      // The size of the wave file
    MMIOINFO      m_mmioinfoOut;
    DWORD         m_dwFlags;
    BOOL          m_bIsReadingFromMemory;
    BYTE*         m_pbData;
    BYTE*         m_pbDataCur;
    ULONG         m_ulDataSize;
    CHAR*         m_pResourceBuffer;

protected:
    HRESULT ReadMMIO();
    HRESULT WriteMMIO( WAVEFORMATEX *pwfxDest );

public:
    CWaveFile();
    ~CWaveFile();

    HRESULT Open( LPTSTR strFileName, WAVEFORMATEX* pwfx, DWORD dwFlags );
    HRESULT Close();

    HRESULT Read( BYTE* pBuffer, DWORD dwSizeToRead, DWORD* pdwSizeRead );
    HRESULT Write( UINT nSizeToWrite, BYTE* pbData, UINT* pnSizeWrote );

    DWORD   GetSize();
    HRESULT ResetFile();
    WAVEFORMATEX* GetFormat() { return m_pwfx; };
};




#endif // DSUTIL_H

 

DirectSound.cpp

//-----------------------------------------------------------------------------
// File: DSUtil.cpp
//
// Desc: DirectSound framework classes for reading and writing wav files and
//       playing them in DirectSound buffers. Feel free to use this class 
//       as a starting point for adding extra functionality.
//
// Copyright (c) Microsoft Corp. All rights reserved.
//-----------------------------------------------------------------------------
//
// Note: This file has been edited for use in Beginning Game Programming, Third Edition,
// originally distributed with a 2004 release of DirectX 9.0c SDK.
//

#define STRICT
#include <windows.h>
#include <mmsystem.h>
#include "DirectSound.h"


//-----------------------------------------------------------------------------
// Miscellaneous helper functions
//-----------------------------------------------------------------------------
#define SAFE_DELETE(p)       { if(p) { delete (p);     (p)=NULL; } }
#define SAFE_DELETE_ARRAY(p) { if(p) { delete[] (p);   (p)=NULL; } }
#define SAFE_RELEASE(p)      { if(p) { (p)->Release(); (p)=NULL; } }


//-----------------------------------------------------------------------------
// Name: CSoundManager::CSoundManager()
// Desc: Constructs the class
//-----------------------------------------------------------------------------
CSoundManager::CSoundManager()
{
    m_pDS = NULL;
}

//-----------------------------------------------------------------------------
// Name: CSoundManager::~CSoundManager()
// Desc: Destroys the class
//-----------------------------------------------------------------------------
CSoundManager::~CSoundManager()
{
    SAFE_RELEASE( m_pDS ); 
}

//-----------------------------------------------------------------------------
// Name: CSoundManager::Initialize()
// Desc: Initializes the IDirectSound object and also sets the primary buffer
//       format.  This function must be called before any others.
//-----------------------------------------------------------------------------
HRESULT CSoundManager::Initialize( HWND  hWnd, 
                                   DWORD dwCoopLevel )
{
    HRESULT             hr;

    SAFE_RELEASE( m_pDS );

    // Create IDirectSound using the primary sound device
    if( FAILED( hr = DirectSoundCreate8( NULL, &m_pDS, NULL ) ) )
        return DXTRACE_ERR( TEXT("DirectSoundCreate8"), hr );

    // Set DirectSound coop level 
    if( FAILED( hr = m_pDS->SetCooperativeLevel( hWnd, dwCoopLevel ) ) )
        return DXTRACE_ERR( TEXT("SetCooperativeLevel"), hr );   

    return S_OK;
}




//-----------------------------------------------------------------------------
// Name: CSoundManager::SetPrimaryBufferFormat()
// Desc: Set primary buffer to a specified format 
//       !WARNING! - Setting the primary buffer format and then using this
//                   same dsound object for DirectMusic messes up DirectMusic! 
//       For example, to set the primary buffer format to 22kHz stereo, 16-bit
//       then:   dwPrimaryChannels = 2
//               dwPrimaryFreq     = 22050, 
//               dwPrimaryBitRate  = 16
//-----------------------------------------------------------------------------
HRESULT CSoundManager::SetPrimaryBufferFormat( DWORD dwPrimaryChannels, 
                                               DWORD dwPrimaryFreq, 
                                               DWORD dwPrimaryBitRate )
{
    HRESULT             hr;
    LPDIRECTSOUNDBUFFER pDSBPrimary = NULL;

    if( m_pDS == NULL )
        return CO_E_NOTINITIALIZED;

    // Get the primary buffer 
    DSBUFFERDESC dsbd;
    ZeroMemory( &dsbd, sizeof(DSBUFFERDESC) );
    dsbd.dwSize        = sizeof(DSBUFFERDESC);
    dsbd.dwFlags       = DSBCAPS_PRIMARYBUFFER;
    dsbd.dwBufferBytes = 0;
    dsbd.lpwfxFormat   = NULL;
       
    if( FAILED( hr = m_pDS->CreateSoundBuffer( &dsbd, &pDSBPrimary, NULL ) ) )
        return DXTRACE_ERR( TEXT("CreateSoundBuffer"), hr );

    WAVEFORMATEX wfx;
    ZeroMemory( &wfx, sizeof(WAVEFORMATEX) ); 
    wfx.wFormatTag      = (WORD) WAVE_FORMAT_PCM; 
    wfx.nChannels       = (WORD) dwPrimaryChannels; 
    wfx.nSamplesPerSec  = (DWORD) dwPrimaryFreq; 
    wfx.wBitsPerSample  = (WORD) dwPrimaryBitRate; 
    wfx.nBlockAlign     = (WORD) (wfx.wBitsPerSample / 8 * wfx.nChannels);
    wfx.nAvgBytesPerSec = (DWORD) (wfx.nSamplesPerSec * wfx.nBlockAlign);

    if( FAILED( hr = pDSBPrimary->SetFormat(&wfx) ) )
        return DXTRACE_ERR( TEXT("SetFormat"), hr );

    SAFE_RELEASE( pDSBPrimary );

    return S_OK;
}



//-----------------------------------------------------------------------------
// Name: CSoundManager::Create()
// Desc: 
//-----------------------------------------------------------------------------
HRESULT CSoundManager::Create( CSound** ppSound, 
                               LPTSTR strWaveFileName, 
                               DWORD dwCreationFlags, 
                               GUID guid3DAlgorithm,
                               DWORD dwNumBuffers )
{
    HRESULT hr;
    HRESULT hrRet = S_OK;
    DWORD   i;
    LPDIRECTSOUNDBUFFER* apDSBuffer     = NULL;
    DWORD                dwDSBufferSize = NULL;
    CWaveFile*           pWaveFile      = NULL;

    if( m_pDS == NULL )
        return CO_E_NOTINITIALIZED;
    if( strWaveFileName == NULL || ppSound == NULL || dwNumBuffers < 1 )
        return E_INVALIDARG;

    apDSBuffer = new LPDIRECTSOUNDBUFFER[dwNumBuffers];
    if( apDSBuffer == NULL )
    {
        hr = E_OUTOFMEMORY;
        goto LFail;
    }

    pWaveFile = new CWaveFile();
    if( pWaveFile == NULL )
    {
        hr = E_OUTOFMEMORY;
        goto LFail;
    }

    pWaveFile->Open( strWaveFileName, NULL, WAVEFILE_READ );

    if( pWaveFile->GetSize() == 0 )
    {
        // Wave is blank, so don't create it.
        hr = E_FAIL;
        goto LFail;
    }

    // Make the DirectSound buffer the same size as the wav file
    dwDSBufferSize = pWaveFile->GetSize();

    // Create the direct sound buffer, and only request the flags needed
    // since each requires some overhead and limits if the buffer can 
    // be hardware accelerated
    DSBUFFERDESC dsbd;
    ZeroMemory( &dsbd, sizeof(DSBUFFERDESC) );
    dsbd.dwSize          = sizeof(DSBUFFERDESC);
    dsbd.dwFlags         = dwCreationFlags;
    dsbd.dwBufferBytes   = dwDSBufferSize;
    dsbd.guid3DAlgorithm = guid3DAlgorithm;
    dsbd.lpwfxFormat     = pWaveFile->m_pwfx;
    
    // DirectSound is only guarenteed to play PCM data.  Other
    // formats may or may not work depending the sound card driver.
    hr = m_pDS->CreateSoundBuffer( &dsbd, &apDSBuffer[0], NULL );

    // Be sure to return this error code if it occurs so the
    // callers knows this happened.
    if( hr == DS_NO_VIRTUALIZATION )
        hrRet = DS_NO_VIRTUALIZATION;
            
    if( FAILED(hr) )
    {
        // DSERR_BUFFERTOOSMALL will be returned if the buffer is
        // less than DSBSIZE_FX_MIN and the buffer is created
        // with DSBCAPS_CTRLFX.
        
        // It might also fail if hardware buffer mixing was requested
        // on a device that doesn't support it.
        DXTRACE_ERR( TEXT("CreateSoundBuffer"), hr );
                    
        goto LFail;
    }

    // Default to use DuplicateSoundBuffer() when created extra buffers since always 
    // create a buffer that uses the same memory however DuplicateSoundBuffer() will fail if 
    // DSBCAPS_CTRLFX is used, so use CreateSoundBuffer() instead in this case.
    if( (dwCreationFlags & DSBCAPS_CTRLFX) == 0 )
    {
        for( i=1; i<dwNumBuffers; i++ )
        {
            if( FAILED( hr = m_pDS->DuplicateSoundBuffer( apDSBuffer[0], &apDSBuffer[i] ) ) )
            {
                DXTRACE_ERR( TEXT("DuplicateSoundBuffer"), hr );
                goto LFail;
            }
        }
    }
    else
    {
        for( i=1; i<dwNumBuffers; i++ )
        {
            hr = m_pDS->CreateSoundBuffer( &dsbd, &apDSBuffer[i], NULL );
            if( FAILED(hr) )
            {
                DXTRACE_ERR( TEXT("CreateSoundBuffer"), hr );
                goto LFail;
            }
        }
   }
    
    // Create the sound
    *ppSound = new CSound( apDSBuffer, dwDSBufferSize, dwNumBuffers, pWaveFile, dwCreationFlags );
    
    SAFE_DELETE_ARRAY( apDSBuffer );
    return hrRet;

LFail:
    // Cleanup
    SAFE_DELETE( pWaveFile );
    SAFE_DELETE_ARRAY( apDSBuffer );
    return hr;
}



//-----------------------------------------------------------------------------
// Name: CSound::CSound()
// Desc: Constructs the class
//-----------------------------------------------------------------------------
CSound::CSound( LPDIRECTSOUNDBUFFER* apDSBuffer, DWORD dwDSBufferSize, 
                DWORD dwNumBuffers, CWaveFile* pWaveFile, DWORD dwCreationFlags )
{
    DWORD i;

    m_apDSBuffer = new LPDIRECTSOUNDBUFFER[dwNumBuffers];
    if( NULL != m_apDSBuffer )
    {
        for( i=0; i<dwNumBuffers; i++ )
            m_apDSBuffer[i] = apDSBuffer[i];
    
        m_dwDSBufferSize = dwDSBufferSize;
        m_dwNumBuffers   = dwNumBuffers;
        m_pWaveFile      = pWaveFile;
        m_dwCreationFlags = dwCreationFlags;
        
        FillBufferWithSound( m_apDSBuffer[0], FALSE );
    }
}




//-----------------------------------------------------------------------------
// Name: CSound::~CSound()
// Desc: Destroys the class
//-----------------------------------------------------------------------------
CSound::~CSound()
{
    for( DWORD i=0; i<m_dwNumBuffers; i++ )
    {
        SAFE_RELEASE( m_apDSBuffer[i] ); 
    }

    SAFE_DELETE_ARRAY( m_apDSBuffer ); 
    SAFE_DELETE( m_pWaveFile );
}




//-----------------------------------------------------------------------------
// Name: CSound::FillBufferWithSound()
// Desc: Fills a DirectSound buffer with a sound file 
//-----------------------------------------------------------------------------
HRESULT CSound::FillBufferWithSound( LPDIRECTSOUNDBUFFER pDSB, BOOL bRepeatWavIfBufferLarger )
{
    HRESULT hr; 
    VOID*   pDSLockedBuffer      = NULL; // Pointer to locked buffer memory
    DWORD   dwDSLockedBufferSize = 0;    // Size of the locked DirectSound buffer
    DWORD   dwWavDataRead        = 0;    // Amount of data read from the wav file 

    if( pDSB == NULL )
        return CO_E_NOTINITIALIZED;

    // Make sure we have focus, and we didn't just switch in from
    // an app which had a DirectSound device
    if( FAILED( hr = RestoreBuffer( pDSB, NULL ) ) ) 
        return DXTRACE_ERR( TEXT("RestoreBuffer"), hr );

    // Lock the buffer down
    if( FAILED( hr = pDSB->Lock( 0, m_dwDSBufferSize, 
                                 &pDSLockedBuffer, &dwDSLockedBufferSize, 
                                 NULL, NULL, 0L ) ) )
        return DXTRACE_ERR( TEXT("Lock"), hr );

    // Reset the wave file to the beginning 
    m_pWaveFile->ResetFile();

    if( FAILED( hr = m_pWaveFile->Read( (BYTE*) pDSLockedBuffer,
                                        dwDSLockedBufferSize, 
                                        &dwWavDataRead ) ) )           
        return DXTRACE_ERR( TEXT("Read"), hr );

    if( dwWavDataRead == 0 )
    {
        // Wav is blank, so just fill with silence
        FillMemory( (BYTE*) pDSLockedBuffer, 
                    dwDSLockedBufferSize, 
                    (BYTE)(m_pWaveFile->m_pwfx->wBitsPerSample == 8 ? 128 : 0 ) );
    }
    else if( dwWavDataRead < dwDSLockedBufferSize )
    {
        // If the wav file was smaller than the DirectSound buffer, 
        // we need to fill the remainder of the buffer with data 
        if( bRepeatWavIfBufferLarger )
        {       
            // Reset the file and fill the buffer with wav data
            DWORD dwReadSoFar = dwWavDataRead;    // From previous call above.
            while( dwReadSoFar < dwDSLockedBufferSize )
            {  
                // This will keep reading in until the buffer is full 
                // for very short files
                if( FAILED( hr = m_pWaveFile->ResetFile() ) )
                    return DXTRACE_ERR( TEXT("ResetFile"), hr );

                hr = m_pWaveFile->Read( (BYTE*)pDSLockedBuffer + dwReadSoFar,
                                        dwDSLockedBufferSize - dwReadSoFar,
                                        &dwWavDataRead );
                if( FAILED(hr) )
                    return DXTRACE_ERR( TEXT("Read"), hr );

                dwReadSoFar += dwWavDataRead;
            } 
        }
        else
        {
            // Don't repeat the wav file, just fill in silence 
            FillMemory( (BYTE*) pDSLockedBuffer + dwWavDataRead, 
                        dwDSLockedBufferSize - dwWavDataRead, 
                        (BYTE)(m_pWaveFile->m_pwfx->wBitsPerSample == 8 ? 128 : 0 ) );
        }
    }

    // Unlock the buffer, we don't need it anymore.
    pDSB->Unlock( pDSLockedBuffer, dwDSLockedBufferSize, NULL, 0 );

    return S_OK;
}




//-----------------------------------------------------------------------------
// Name: CSound::RestoreBuffer()
// Desc: Restores the lost buffer. *pbWasRestored returns TRUE if the buffer was 
//       restored.  It can also NULL if the information is not needed.
//-----------------------------------------------------------------------------
HRESULT CSound::RestoreBuffer( LPDIRECTSOUNDBUFFER pDSB, BOOL* pbWasRestored )
{
    HRESULT hr;

    if( pDSB == NULL )
        return CO_E_NOTINITIALIZED;
    if( pbWasRestored )
        *pbWasRestored = FALSE;

    DWORD dwStatus;
    if( FAILED( hr = pDSB->GetStatus( &dwStatus ) ) )
        return DXTRACE_ERR( TEXT("GetStatus"), hr );

    if( dwStatus & DSBSTATUS_BUFFERLOST )
    {
        // Since the app could have just been activated, then
        // DirectSound may not be giving us control yet, so 
        // the restoring the buffer may fail.  
        // If it does, sleep until DirectSound gives us control.
        do 
        {
            hr = pDSB->Restore();
            if( hr == DSERR_BUFFERLOST )
                Sleep( 10 );
        }
        while( ( hr = pDSB->Restore() ) == DSERR_BUFFERLOST );

        if( pbWasRestored != NULL )
            *pbWasRestored = TRUE;

        return S_OK;
    }
    else
    {
        return S_FALSE;
    }
}




//-----------------------------------------------------------------------------
// Name: CSound::GetFreeBuffer()
// Desc: Finding the first buffer that is not playing and return a pointer to 
//       it, or if all are playing return a pointer to a randomly selected buffer.
//-----------------------------------------------------------------------------
LPDIRECTSOUNDBUFFER CSound::GetFreeBuffer()
{
    if( m_apDSBuffer == NULL )
        return FALSE; 
    DWORD i;
    for( i=0; i<m_dwNumBuffers; i++ )
    {
        if( m_apDSBuffer[i] )
        {  
            DWORD dwStatus = 0;
            m_apDSBuffer[i]->GetStatus( &dwStatus );
            if ( ( dwStatus & DSBSTATUS_PLAYING ) == 0 )
                break;
        }
    }

    if( i != m_dwNumBuffers )
        return m_apDSBuffer[ i ];
    else
        return m_apDSBuffer[ rand() % m_dwNumBuffers ];
}



//-----------------------------------------------------------------------------
// Name: CSound::Play()
// Desc: Plays the sound using voice management flags.  Pass in DSBPLAY_LOOPING
//       in the dwFlags to loop the sound
//-----------------------------------------------------------------------------
HRESULT CSound::Play( DWORD dwPriority, DWORD dwFlags, LONG lVolume, LONG lFrequency, LONG lPan )
{
    HRESULT hr;
    BOOL    bRestored;

    if( m_apDSBuffer == NULL )
        return CO_E_NOTINITIALIZED;

    LPDIRECTSOUNDBUFFER pDSB = GetFreeBuffer();

    if( pDSB == NULL )
        return DXTRACE_ERR( TEXT("GetFreeBuffer"), E_FAIL );

    // Restore the buffer if it was lost
    if( FAILED( hr = RestoreBuffer( pDSB, &bRestored ) ) )
        return DXTRACE_ERR( TEXT("RestoreBuffer"), hr );

    if( bRestored )
    {
        // The buffer was restored, so we need to fill it with new data
        if( FAILED( hr = FillBufferWithSound( pDSB, FALSE ) ) )
            return DXTRACE_ERR( TEXT("FillBufferWithSound"), hr );
    }

    if( m_dwCreationFlags & DSBCAPS_CTRLVOLUME )
    {
        pDSB->SetVolume( lVolume );
    }

    if( lFrequency != -1 && 
        (m_dwCreationFlags & DSBCAPS_CTRLFREQUENCY) )
    {
        pDSB->SetFrequency( lFrequency );
    }
    
    if( m_dwCreationFlags & DSBCAPS_CTRLPAN )
    {
        pDSB->SetPan( lPan );
    }
    
    return pDSB->Play( 0, dwPriority, dwFlags );
}



//-----------------------------------------------------------------------------
// Name: CSound::Stop()
// Desc: Stops the sound from playing
//-----------------------------------------------------------------------------
HRESULT CSound::Stop()
{
    if( m_apDSBuffer == NULL )
        return CO_E_NOTINITIALIZED;

    HRESULT hr = 0;

    for( DWORD i=0; i<m_dwNumBuffers; i++ )
        hr |= m_apDSBuffer[i]->Stop();

    return hr;
}




//-----------------------------------------------------------------------------
// Name: CSound::Reset()
// Desc: Reset all of the sound buffers
//-----------------------------------------------------------------------------
HRESULT CSound::Reset()
{
    if( m_apDSBuffer == NULL )
        return CO_E_NOTINITIALIZED;

    HRESULT hr = 0;

    for( DWORD i=0; i<m_dwNumBuffers; i++ )
        hr |= m_apDSBuffer[i]->SetCurrentPosition( 0 );

    return hr;
}




//-----------------------------------------------------------------------------
// Name: CSound::IsSoundPlaying()
// Desc: Checks to see if a buffer is playing and returns TRUE if it is.
//-----------------------------------------------------------------------------
BOOL CSound::IsSoundPlaying()
{
    BOOL bIsPlaying = FALSE;

    if( m_apDSBuffer == NULL )
        return FALSE; 

    for( DWORD i=0; i<m_dwNumBuffers; i++ )
    {
        if( m_apDSBuffer[i] )
        {  
            DWORD dwStatus = 0;
            m_apDSBuffer[i]->GetStatus( &dwStatus );
            bIsPlaying |= ( ( dwStatus & DSBSTATUS_PLAYING ) != 0 );
        }
    }

    return bIsPlaying;
}



//-----------------------------------------------------------------------------
// Name: CWaveFile::CWaveFile()
// Desc: Constructs the class.  Call Open() to open a wave file for reading.  
//       Then call Read() as needed.  Calling the destructor or Close() 
//       will close the file.  
//-----------------------------------------------------------------------------
CWaveFile::CWaveFile()
{
    m_pwfx    = NULL;
    m_hmmio   = NULL;
    m_pResourceBuffer = NULL;
    m_dwSize  = 0;
    m_bIsReadingFromMemory = FALSE;
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::~CWaveFile()
// Desc: Destructs the class
//-----------------------------------------------------------------------------
CWaveFile::~CWaveFile()
{
    Close();

    if( !m_bIsReadingFromMemory )
        SAFE_DELETE_ARRAY( m_pwfx );
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::Open()
// Desc: Opens a wave file for reading
//-----------------------------------------------------------------------------
HRESULT CWaveFile::Open( LPTSTR strFileName, WAVEFORMATEX* pwfx, DWORD dwFlags )
{
    HRESULT hr;

    m_dwFlags = dwFlags;
    m_bIsReadingFromMemory = FALSE;

    if( m_dwFlags == WAVEFILE_READ )
    {
        if( strFileName == NULL )
            return E_INVALIDARG;
        SAFE_DELETE_ARRAY( m_pwfx );

        m_hmmio = mmioOpen( strFileName, NULL, MMIO_ALLOCBUF | MMIO_READ );

        if( NULL == m_hmmio )
        {
            HRSRC   hResInfo;
            HGLOBAL hResData;
            DWORD   dwSize;
            VOID*   pvRes;

            // Loading it as a file failed, so try it as a resource
            if( NULL == ( hResInfo = FindResource( NULL, strFileName, TEXT("WAVE") ) ) )
            {
                if( NULL == ( hResInfo = FindResource( NULL, strFileName, TEXT("WAV") ) ) )
                    return DXTRACE_ERR( TEXT("FindResource"), E_FAIL );
            }

            if( NULL == ( hResData = LoadResource( NULL, hResInfo ) ) )
                return DXTRACE_ERR( TEXT("LoadResource"), E_FAIL );

            if( 0 == ( dwSize = SizeofResource( NULL, hResInfo ) ) ) 
                return DXTRACE_ERR( TEXT("SizeofResource"), E_FAIL );

            if( NULL == ( pvRes = LockResource( hResData ) ) )
                return DXTRACE_ERR( TEXT("LockResource"), E_FAIL );

            m_pResourceBuffer = new CHAR[ dwSize ];
            memcpy( m_pResourceBuffer, pvRes, dwSize );

            MMIOINFO mmioInfo;
            ZeroMemory( &mmioInfo, sizeof(mmioInfo) );
            mmioInfo.fccIOProc = FOURCC_MEM;
            mmioInfo.cchBuffer = dwSize;
            mmioInfo.pchBuffer = (CHAR*) m_pResourceBuffer;

            m_hmmio = mmioOpen( NULL, &mmioInfo, MMIO_ALLOCBUF | MMIO_READ );
        }

        if( FAILED( hr = ReadMMIO() ) )
        {
            // ReadMMIO will fail if its an not a wave file
            mmioClose( m_hmmio, 0 );
            return DXTRACE_ERR( TEXT("ReadMMIO"), hr );
        }

        if( FAILED( hr = ResetFile() ) )
            return DXTRACE_ERR( TEXT("ResetFile"), hr );

        // After the reset, the size of the wav file is m_ck.cksize so store it now
        m_dwSize = m_ck.cksize;
    }
    else
    {
        m_hmmio = mmioOpen( strFileName, NULL, MMIO_ALLOCBUF  | 
                                                  MMIO_READWRITE | 
                                                  MMIO_CREATE );
        if( NULL == m_hmmio )
            return DXTRACE_ERR( TEXT("mmioOpen"), E_FAIL );

        if( FAILED( hr = WriteMMIO( pwfx ) ) )
        {
            mmioClose( m_hmmio, 0 );
            return DXTRACE_ERR( TEXT("WriteMMIO"), hr );
        }
                        
        if( FAILED( hr = ResetFile() ) )
            return DXTRACE_ERR( TEXT("ResetFile"), hr );
    }

    return hr;
}



//-----------------------------------------------------------------------------
// Name: CWaveFile::ReadMMIO()
// Desc: Support function for reading from a multimedia I/O stream.
//       m_hmmio must be valid before calling.  This function uses it to
//       update m_ckRiff, and m_pwfx. 
//-----------------------------------------------------------------------------
HRESULT CWaveFile::ReadMMIO()
{
    MMCKINFO        ckIn;           // chunk info. for general use.
    PCMWAVEFORMAT   pcmWaveFormat;  // Temp PCM structure to load in.       

    m_pwfx = NULL;

    if( ( 0 != mmioDescend( m_hmmio, &m_ckRiff, NULL, 0 ) ) )
        return DXTRACE_ERR( TEXT("mmioDescend"), E_FAIL );

    // Check to make sure this is a valid wave file
    if( (m_ckRiff.ckid != FOURCC_RIFF) ||
        (m_ckRiff.fccType != mmioFOURCC('W', 'A', 'V', 'E') ) )
        return DXTRACE_ERR( TEXT("mmioFOURCC"), E_FAIL ); 

    // Search the input file for for the 'fmt ' chunk.
    ckIn.ckid = mmioFOURCC('f', 'm', 't', ' ');
    if( 0 != mmioDescend( m_hmmio, &ckIn, &m_ckRiff, MMIO_FINDCHUNK ) )
        return DXTRACE_ERR( TEXT("mmioDescend"), E_FAIL );

    // Expect the 'fmt' chunk to be at least as large as <PCMWAVEFORMAT>;
    // if there are extra parameters at the end, we'll ignore them
       if( ckIn.cksize < (LONG) sizeof(PCMWAVEFORMAT) )
           return DXTRACE_ERR( TEXT("sizeof(PCMWAVEFORMAT)"), E_FAIL );

    // Read the 'fmt ' chunk into <pcmWaveFormat>.
    if( mmioRead( m_hmmio, (HPSTR) &pcmWaveFormat, 
                  sizeof(pcmWaveFormat)) != sizeof(pcmWaveFormat) )
        return DXTRACE_ERR( TEXT("mmioRead"), E_FAIL );

    // Allocate the waveformatex, but if its not pcm format, read the next
    // word, and thats how many extra bytes to allocate.
    if( pcmWaveFormat.wf.wFormatTag == WAVE_FORMAT_PCM )
    {
        m_pwfx = (WAVEFORMATEX*)new CHAR[ sizeof(WAVEFORMATEX) ];
        if( NULL == m_pwfx )
            return DXTRACE_ERR( TEXT("m_pwfx"), E_FAIL );

        // Copy the bytes from the pcm structure to the waveformatex structure
        memcpy( m_pwfx, &pcmWaveFormat, sizeof(pcmWaveFormat) );
        m_pwfx->cbSize = 0;
    }
    else
    {
        // Read in length of extra bytes.
        WORD cbExtraBytes = 0L;
        if( mmioRead( m_hmmio, (CHAR*)&cbExtraBytes, sizeof(WORD)) != sizeof(WORD) )
            return DXTRACE_ERR( TEXT("mmioRead"), E_FAIL );

        m_pwfx = (WAVEFORMATEX*)new CHAR[ sizeof(WAVEFORMATEX) + cbExtraBytes ];
        if( NULL == m_pwfx )
            return DXTRACE_ERR( TEXT("new"), E_FAIL );

        // Copy the bytes from the pcm structure to the waveformatex structure
        memcpy( m_pwfx, &pcmWaveFormat, sizeof(pcmWaveFormat) );
        m_pwfx->cbSize = cbExtraBytes;

        // Now, read those extra bytes into the structure, if cbExtraAlloc != 0.
        if( mmioRead( m_hmmio, (CHAR*)(((BYTE*)&(m_pwfx->cbSize))+sizeof(WORD)),
                      cbExtraBytes ) != cbExtraBytes )
        {
            SAFE_DELETE( m_pwfx );
            return DXTRACE_ERR( TEXT("mmioRead"), E_FAIL );
        }
    }

    // Ascend the input file out of the 'fmt ' chunk.
    if( 0 != mmioAscend( m_hmmio, &ckIn, 0 ) )
    {
        SAFE_DELETE( m_pwfx );
        return DXTRACE_ERR( TEXT("mmioAscend"), E_FAIL );
    }

    return S_OK;
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::GetSize()
// Desc: Retuns the size of the read access wave file 
//-----------------------------------------------------------------------------
DWORD CWaveFile::GetSize()
{
    return m_dwSize;
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::ResetFile()
// Desc: Resets the internal m_ck pointer so reading starts from the 
//       beginning of the file again 
//-----------------------------------------------------------------------------
HRESULT CWaveFile::ResetFile()
{
    if( m_bIsReadingFromMemory )
    {
        m_pbDataCur = m_pbData;
    }
    else 
    {
        if( m_hmmio == NULL )
            return CO_E_NOTINITIALIZED;

        if( m_dwFlags == WAVEFILE_READ )
        {
            // Seek to the data
            if( -1 == mmioSeek( m_hmmio, m_ckRiff.dwDataOffset + sizeof(FOURCC),
                            SEEK_SET ) )
                return DXTRACE_ERR( TEXT("mmioSeek"), E_FAIL );

            // Search the input file for the 'data' chunk.
            m_ck.ckid = mmioFOURCC('d', 'a', 't', 'a');
            if( 0 != mmioDescend( m_hmmio, &m_ck, &m_ckRiff, MMIO_FINDCHUNK ) )
              return DXTRACE_ERR( TEXT("mmioDescend"), E_FAIL );
        }
        else
        {
            // Create the 'data' chunk that holds the waveform samples.  
            m_ck.ckid = mmioFOURCC('d', 'a', 't', 'a');
            m_ck.cksize = 0;

            if( 0 != mmioCreateChunk( m_hmmio, &m_ck, 0 ) ) 
                return DXTRACE_ERR( TEXT("mmioCreateChunk"), E_FAIL );

            if( 0 != mmioGetInfo( m_hmmio, &m_mmioinfoOut, 0 ) )
                return DXTRACE_ERR( TEXT("mmioGetInfo"), E_FAIL );
        }
    }
    
    return S_OK;
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::Read()
// Desc: Reads section of data from a wave file into pBuffer and returns 
//       how much read in pdwSizeRead, reading not more than dwSizeToRead.
//       This uses m_ck to determine where to start reading from.  So 
//       subsequent calls will be continue where the last left off unless 
//       Reset() is called.
//-----------------------------------------------------------------------------
HRESULT CWaveFile::Read( BYTE* pBuffer, DWORD dwSizeToRead, DWORD* pdwSizeRead )
{
    if( m_bIsReadingFromMemory )
    {
        if( m_pbDataCur == NULL )
            return CO_E_NOTINITIALIZED;
        if( pdwSizeRead != NULL )
            *pdwSizeRead = 0;

        if( (BYTE*)(m_pbDataCur + dwSizeToRead) > 
            (BYTE*)(m_pbData + m_ulDataSize) )
        {
            dwSizeToRead = m_ulDataSize - (DWORD)(m_pbDataCur - m_pbData);
        }
        
        CopyMemory( pBuffer, m_pbDataCur, dwSizeToRead );
        
        if( pdwSizeRead != NULL )
            *pdwSizeRead = dwSizeToRead;

        return S_OK;
    }
    else 
    {
        MMIOINFO mmioinfoIn; // current status of m_hmmio

        if( m_hmmio == NULL )
            return CO_E_NOTINITIALIZED;
        if( pBuffer == NULL || pdwSizeRead == NULL )
            return E_INVALIDARG;

        if( pdwSizeRead != NULL )
            *pdwSizeRead = 0;

        if( 0 != mmioGetInfo( m_hmmio, &mmioinfoIn, 0 ) )
            return DXTRACE_ERR( TEXT("mmioGetInfo"), E_FAIL );
                
        UINT cbDataIn = dwSizeToRead;
        if( cbDataIn > m_ck.cksize ) 
            cbDataIn = m_ck.cksize;       

        m_ck.cksize -= cbDataIn;
    
        for( DWORD cT = 0; cT < cbDataIn; cT++ )
        {
            // Copy the bytes from the io to the buffer.
            if( mmioinfoIn.pchNext == mmioinfoIn.pchEndRead )
            {
                if( 0 != mmioAdvance( m_hmmio, &mmioinfoIn, MMIO_READ ) )
                    return DXTRACE_ERR( TEXT("mmioAdvance"), E_FAIL );

                if( mmioinfoIn.pchNext == mmioinfoIn.pchEndRead )
                    return DXTRACE_ERR( TEXT("mmioinfoIn.pchNext"), E_FAIL );
            }

            // Actual copy.
            *((BYTE*)pBuffer+cT) = *((BYTE*)mmioinfoIn.pchNext);
            mmioinfoIn.pchNext++;
        }

        if( 0 != mmioSetInfo( m_hmmio, &mmioinfoIn, 0 ) )
            return DXTRACE_ERR( TEXT("mmioSetInfo"), E_FAIL );

        if( pdwSizeRead != NULL )
            *pdwSizeRead = cbDataIn;

        return S_OK;
    }
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::Close()
// Desc: Closes the wave file 
//-----------------------------------------------------------------------------
HRESULT CWaveFile::Close()
{
    if( m_dwFlags == WAVEFILE_READ )
    {
        mmioClose( m_hmmio, 0 );
        m_hmmio = NULL;
        SAFE_DELETE_ARRAY( m_pResourceBuffer );
    }
    else
    {
        m_mmioinfoOut.dwFlags |= MMIO_DIRTY;

        if( m_hmmio == NULL )
            return CO_E_NOTINITIALIZED;

        if( 0 != mmioSetInfo( m_hmmio, &m_mmioinfoOut, 0 ) )
            return DXTRACE_ERR( TEXT("mmioSetInfo"), E_FAIL );
    
        // Ascend the output file out of the 'data' chunk -- this will cause
        // the chunk size of the 'data' chunk to be written.
        if( 0 != mmioAscend( m_hmmio, &m_ck, 0 ) )
            return DXTRACE_ERR( TEXT("mmioAscend"), E_FAIL );
    
        // Do this here instead...
        if( 0 != mmioAscend( m_hmmio, &m_ckRiff, 0 ) )
            return DXTRACE_ERR( TEXT("mmioAscend"), E_FAIL );
        
        mmioSeek( m_hmmio, 0, SEEK_SET );

        if( 0 != (INT)mmioDescend( m_hmmio, &m_ckRiff, NULL, 0 ) )
            return DXTRACE_ERR( TEXT("mmioDescend"), E_FAIL );
    
        m_ck.ckid = mmioFOURCC('f', 'a', 'c', 't');

        if( 0 == mmioDescend( m_hmmio, &m_ck, &m_ckRiff, MMIO_FINDCHUNK ) ) 
        {
            DWORD dwSamples = 0;
            mmioWrite( m_hmmio, (HPSTR)&dwSamples, sizeof(DWORD) );
            mmioAscend( m_hmmio, &m_ck, 0 ); 
        }
    
        // Ascend the output file out of the 'RIFF' chunk -- this will cause
        // the chunk size of the 'RIFF' chunk to be written.
        if( 0 != mmioAscend( m_hmmio, &m_ckRiff, 0 ) )
            return DXTRACE_ERR( TEXT("mmioAscend"), E_FAIL );
    
        mmioClose( m_hmmio, 0 );
        m_hmmio = NULL;
    }

    return S_OK;
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::WriteMMIO()
// Desc: Support function for reading from a multimedia I/O stream
//       pwfxDest is the WAVEFORMATEX for this new wave file.  
//       m_hmmio must be valid before calling.  This function uses it to
//       update m_ckRiff, and m_ck.  
//-----------------------------------------------------------------------------
HRESULT CWaveFile::WriteMMIO( WAVEFORMATEX *pwfxDest )
{
    DWORD    dwFactChunk; // Contains the actual fact chunk. Garbage until WaveCloseWriteFile.
    MMCKINFO ckOut1;
    
    dwFactChunk = (DWORD)-1;

    // Create the output file RIFF chunk of form type 'WAVE'.
    m_ckRiff.fccType = mmioFOURCC('W', 'A', 'V', 'E');       
    m_ckRiff.cksize = 0;

    if( 0 != mmioCreateChunk( m_hmmio, &m_ckRiff, MMIO_CREATERIFF ) )
        return DXTRACE_ERR( TEXT("mmioCreateChunk"), E_FAIL );
    
    // We are now descended into the 'RIFF' chunk we just created.
    // Now create the 'fmt ' chunk. Since we know the size of this chunk,
    // specify it in the MMCKINFO structure so MMIO doesn't have to seek
    // back and set the chunk size after ascending from the chunk.
    m_ck.ckid = mmioFOURCC('f', 'm', 't', ' ');
    m_ck.cksize = sizeof(PCMWAVEFORMAT);   

    if( 0 != mmioCreateChunk( m_hmmio, &m_ck, 0 ) )
        return DXTRACE_ERR( TEXT("mmioCreateChunk"), E_FAIL );
    
    // Write the PCMWAVEFORMAT structure to the 'fmt ' chunk if its that type. 
    if( pwfxDest->wFormatTag == WAVE_FORMAT_PCM )
    {
        if( mmioWrite( m_hmmio, (HPSTR) pwfxDest, 
                       sizeof(PCMWAVEFORMAT)) != sizeof(PCMWAVEFORMAT))
            return DXTRACE_ERR( TEXT("mmioWrite"), E_FAIL );
    }   
    else 
    {
        // Write the variable length size.
        if( (UINT)mmioWrite( m_hmmio, (HPSTR) pwfxDest, 
                             sizeof(*pwfxDest) + pwfxDest->cbSize ) != 
                             ( sizeof(*pwfxDest) + pwfxDest->cbSize ) )
            return DXTRACE_ERR( TEXT("mmioWrite"), E_FAIL );
    }  
    
    // Ascend out of the 'fmt ' chunk, back into the 'RIFF' chunk.
    if( 0 != mmioAscend( m_hmmio, &m_ck, 0 ) )
        return DXTRACE_ERR( TEXT("mmioAscend"), E_FAIL );
    
    // Now create the fact chunk, not required for PCM but nice to have.  This is filled
    // in when the close routine is called.
    ckOut1.ckid = mmioFOURCC('f', 'a', 'c', 't');
    ckOut1.cksize = 0;

    if( 0 != mmioCreateChunk( m_hmmio, &ckOut1, 0 ) )
        return DXTRACE_ERR( TEXT("mmioCreateChunk"), E_FAIL );
    
    if( mmioWrite( m_hmmio, (HPSTR)&dwFactChunk, sizeof(dwFactChunk)) != 
                    sizeof(dwFactChunk) )
         return DXTRACE_ERR( TEXT("mmioWrite"), E_FAIL );
    
    // Now ascend out of the fact chunk...
    if( 0 != mmioAscend( m_hmmio, &ckOut1, 0 ) )
        return DXTRACE_ERR( TEXT("mmioAscend"), E_FAIL );
       
    return S_OK;
}




//-----------------------------------------------------------------------------
// Name: CWaveFile::Write()
// Desc: Writes data to the open wave file
//-----------------------------------------------------------------------------
HRESULT CWaveFile::Write( UINT nSizeToWrite, BYTE* pbSrcData, UINT* pnSizeWrote )
{
    UINT cT;

    if( m_bIsReadingFromMemory )
        return E_NOTIMPL;
    if( m_hmmio == NULL )
        return CO_E_NOTINITIALIZED;
    if( pnSizeWrote == NULL || pbSrcData == NULL )
        return E_INVALIDARG;

    *pnSizeWrote = 0;
    
    for( cT = 0; cT < nSizeToWrite; cT++ )
    {       
        if( m_mmioinfoOut.pchNext == m_mmioinfoOut.pchEndWrite )
        {
            m_mmioinfoOut.dwFlags |= MMIO_DIRTY;
            if( 0 != mmioAdvance( m_hmmio, &m_mmioinfoOut, MMIO_WRITE ) )
                return DXTRACE_ERR( TEXT("mmioAdvance"), E_FAIL );
        }

        *((BYTE*)m_mmioinfoOut.pchNext) = *((BYTE*)pbSrcData+cT);
        (BYTE*)m_mmioinfoOut.pchNext++;

        (*pnSizeWrote)++;
    }

    return S_OK;
}

 

DirectX.h

#pragma once

//header files
#define WIN32_EXTRA_LEAN
#define DIRECTINPUT_VERSION 0x0800
#include <windows.h>
#include <d3d9.h>
#include <d3dx9.h>
#include <dxerr.h>
#include <dinput.h>
#include <xinput.h>
#include <ctime>
#include <iostream>
#include <iomanip>
#include "DirectSound.h"
using namespace std;

//libraries
#pragma comment(lib,"winmm.lib")
#pragma comment(lib,"user32.lib")
#pragma comment(lib,"gdi32.lib")
#pragma comment(lib,"dxguid.lib")
#pragma comment(lib,"d3d9.lib")
#pragma comment(lib,"d3dx9.lib")
#pragma comment(lib, "dxerr.lib")
#pragma comment(lib,"dinput8.lib")
#pragma comment(lib,"xinput.lib")

//program values
extern const string APPTITLE;
extern const int SCREENW;
extern const int SCREENH;
extern bool gameover;

//macro to detect key presses
#define KEY_DOWN(vk_code) ((GetAsyncKeyState(vk_code) & 0x8000) ? 1 : 0)

//Direct3D objects
extern LPDIRECT3D9 d3d; 
extern LPDIRECT3DDEVICE9 d3ddev; 
extern LPDIRECT3DSURFACE9 backbuffer;
extern LPD3DXSPRITE spriteobj;

//DirectSound object
extern CSoundManager *dsound;

//sprite structure
struct SPRITE
{
    float x,y;
    int frame, columns;
    int width, height;
    float scaling, rotation;
    int startframe, endframe;
    int starttime, delay;
    int direction;
    float velx, vely;
    D3DCOLOR color;

    SPRITE() 
    {
        frame = 0;
        columns = 1;
        width = height = 0;
        scaling = 1.0f;
        rotation = 0.0f;
        startframe = endframe = 0;
        direction = 1;
        starttime = delay = 0;
        velx = vely = 0.0f;
        color = D3DCOLOR_XRGB(255,255,255);
    }
};

//Direct3D functions
bool Direct3D_Init(HWND hwnd, int width, int height, bool fullscreen);
void Direct3D_Shutdown();
LPDIRECT3DSURFACE9 LoadSurface(string filename);
void DrawSurface(LPDIRECT3DSURFACE9 dest, float x, float y, LPDIRECT3DSURFACE9 source);
LPDIRECT3DTEXTURE9 LoadTexture(string filename, D3DCOLOR transcolor = D3DCOLOR_XRGB(0,0,0));
void Sprite_Draw_Frame(LPDIRECT3DTEXTURE9 texture, int destx, int desty, 
    int framenum, int framew, int frameh, int columns);
void Sprite_Animate(int &frame, int startframe, int endframe, int direction, int &starttime, int delay);

void Sprite_Transform_Draw(LPDIRECT3DTEXTURE9 image, int x, int y, int width, int height, 
    int frame = 0, int columns = 1, float rotation = 0.0f, float scaling = 1.0f, 
    D3DCOLOR color = D3DCOLOR_XRGB(255,255,255));

//bounding box collision detection
int Collision(SPRITE sprite1, SPRITE sprite2);

//distance based collision detection
bool CollisionD(SPRITE sprite1, SPRITE sprite2);

//DirectInput objects, devices, and states
extern LPDIRECTINPUT8 dinput;
extern LPDIRECTINPUTDEVICE8 dimouse;
extern LPDIRECTINPUTDEVICE8 dikeyboard;
extern DIMOUSESTATE mouse_state;
extern XINPUT_GAMEPAD controllers[4];

//DirectInput functions
bool DirectInput_Init(HWND);
void DirectInput_Update();
void DirectInput_Shutdown();
bool Key_Down(int);
int Mouse_Button(int);
int Mouse_X();
int Mouse_Y();
void XInput_Vibrate(int contNum = 0, int amount = 65535);
bool XInput_Controller_Found();

//game functions
bool Game_Init(HWND window);
void Game_Run(HWND window);
void Game_End();


//font functions
LPD3DXFONT MakeFont(string name, int size);
void FontPrint(LPD3DXFONT font, int x, int y, string text, D3DCOLOR color = D3DCOLOR_XRGB(255,255,255));

//DirectSound functions
bool DirectSound_Init(HWND hwnd);
void DirectSound_Shutdown();
CSound* LoadSound(string filename);
void PlaySound(CSound *sound);
void LoopSound(CSound *sound);
void StopSound(CSound *sound);

 

DirectX.cpp

#include "DirectX.h"
#include <iostream>
#include <string>
using namespace std;

//DirectSound object
CSoundManager *dsound = NULL;

//Direct3D variables
LPDIRECT3D9 d3d = NULL; 
LPDIRECT3DDEVICE9 d3ddev = NULL; 
LPDIRECT3DSURFACE9 backbuffer = NULL;
LPD3DXSPRITE spriteobj;

//DirectInput variables
LPDIRECTINPUT8 dinput = NULL;
LPDIRECTINPUTDEVICE8 dimouse = NULL;
LPDIRECTINPUTDEVICE8 dikeyboard = NULL;
DIMOUSESTATE mouse_state;
char keys[256];
XINPUT_GAMEPAD controllers[4];


bool Direct3D_Init(HWND window, int width, int height, bool fullscreen)
{
    //initialize Direct3D
    d3d = Direct3DCreate9(D3D_SDK_VERSION);
    if (!d3d) return false;

    //set Direct3D presentation parameters
    D3DPRESENT_PARAMETERS d3dpp; 
    ZeroMemory(&d3dpp, sizeof(d3dpp));
    d3dpp.hDeviceWindow = window;
    d3dpp.Windowed = (!fullscreen);
    d3dpp.SwapEffect = D3DSWAPEFFECT_DISCARD;
    d3dpp.EnableAutoDepthStencil = 1;
    d3dpp.AutoDepthStencilFormat = D3DFMT_D24S8;
    d3dpp.Flags = D3DPRESENTFLAG_DISCARD_DEPTHSTENCIL;
    d3dpp.PresentationInterval = D3DPRESENT_INTERVAL_IMMEDIATE;
    d3dpp.BackBufferFormat = D3DFMT_X8R8G8B8;
    d3dpp.BackBufferCount = 1;
    d3dpp.BackBufferWidth = width;
    d3dpp.BackBufferHeight = height;

    //create Direct3D device
    d3d->CreateDevice( D3DADAPTER_DEFAULT, D3DDEVTYPE_HAL, window,
        D3DCREATE_SOFTWARE_VERTEXPROCESSING, &d3dpp, &d3ddev);
    if (!d3ddev) return false;


    //get a pointer to the back buffer surface
    d3ddev->GetBackBuffer(0, 0, D3DBACKBUFFER_TYPE_MONO, &backbuffer);

    //create sprite object
    D3DXCreateSprite(d3ddev, &spriteobj);

    return 1;
}

void Direct3D_Shutdown()
{
    if (spriteobj) spriteobj->Release();

    if (d3ddev) d3ddev->Release();
    if (d3d) d3d->Release();
}

void DrawSurface(LPDIRECT3DSURFACE9 dest, float x, float y, LPDIRECT3DSURFACE9 source)
{
    //get width/height from source surface
    D3DSURFACE_DESC desc;
    source->GetDesc(&desc);

    //create rects for drawing
    RECT source_rect = {0, 0, (long)desc.Width, (long)desc.Height };
    RECT dest_rect = { (long)x, (long)y, (long)x+desc.Width, (long)y+desc.Height};
    
    //draw the source surface onto the dest
    d3ddev->StretchRect(source, &source_rect, dest, &dest_rect, D3DTEXF_NONE);

}

LPDIRECT3DSURFACE9 LoadSurface(string filename)
{
    LPDIRECT3DSURFACE9 image = NULL;
    
    //get width and height from bitmap file
    D3DXIMAGE_INFO info;
    HRESULT result = D3DXGetImageInfoFromFile(filename.c_str(), &info);
    if (result != D3D_OK)
        return NULL;

    //create surface
    result = d3ddev->CreateOffscreenPlainSurface(
        info.Width,         //width of the surface
        info.Height,        //height of the surface
        D3DFMT_X8R8G8B8,    //surface format
        D3DPOOL_DEFAULT,    //memory pool to use
        &image,             //pointer to the surface
        NULL);              //reserved (always NULL)

    if (result != D3D_OK) return NULL;

    //load surface from file into newly created surface
    result = D3DXLoadSurfaceFromFile(
        image,                  //destination surface
        NULL,                   //destination palette
        NULL,                   //destination rectangle
        filename.c_str(),       //source filename
        NULL,                   //source rectangle
        D3DX_DEFAULT,           //controls how image is filtered
        D3DCOLOR_XRGB(0,0,0),   //for transparency (0 for none)
        NULL);                  //source image info (usually NULL)

    //make sure file was loaded okay
    if (result != D3D_OK) return NULL;

    return image;
}


LPDIRECT3DTEXTURE9 LoadTexture(std::string filename, D3DCOLOR transcolor)
{  
    LPDIRECT3DTEXTURE9 texture = NULL;

    //get width and height from bitmap file
    D3DXIMAGE_INFO info;
    HRESULT result = D3DXGetImageInfoFromFile(filename.c_str(), &info);
    if (result != D3D_OK) return NULL;

    //create the new texture by loading a bitmap image file
    D3DXCreateTextureFromFileEx( 
        d3ddev,                //Direct3D device object
        filename.c_str(),      //bitmap filename
        info.Width,            //bitmap image width
        info.Height,           //bitmap image height
        1,                     //mip-map levels (1 for no chain)
        D3DPOOL_DEFAULT,       //the type of surface (standard)
        D3DFMT_UNKNOWN,        //surface format (default)
        D3DPOOL_DEFAULT,       //memory class for the texture
        D3DX_DEFAULT,          //image filter
        D3DX_DEFAULT,          //mip filter
        transcolor,            //color key for transparency
        &info,                 //bitmap file info (from loaded file)
        NULL,                  //color palette
        &texture );            //destination texture

    //make sure the bitmap textre was loaded correctly
    if (result != D3D_OK) return NULL;

    return texture;
}


void Sprite_Draw_Frame(LPDIRECT3DTEXTURE9 texture, int destx, int desty, int framenum, int framew, int frameh, int columns)
{
    D3DXVECTOR3 position( (float)destx, (float)desty, 0 );
    D3DCOLOR white = D3DCOLOR_XRGB(255,255,255);

    RECT rect;
     rect.left = (framenum % columns) * framew;
    rect.top = (framenum / columns) * frameh;
    rect.right = rect.left + framew;
    rect.bottom = rect.top + frameh;

    spriteobj->Draw( texture, &rect, NULL, &position, white);
}

void Sprite_Animate(int &frame, int startframe, int endframe, int direction, int &starttime, int delay)
{
    if ((int)GetTickCount() > starttime + delay)
    {
        starttime = GetTickCount();

        frame += direction;
        if (frame > endframe) frame = startframe;
        if (frame < startframe) frame = endframe;
    }    
}
void Sprite_Transform_Draw(LPDIRECT3DTEXTURE9 image, int x, int y, int width, int height, 
    int frame, int columns, float rotation, float scaling, D3DCOLOR color)
{
    //create a scale vector
    D3DXVECTOR2 scale( scaling, scaling );

    //create a translate vector
    D3DXVECTOR2 trans( x, y );

    //set center by dividing width and height by two
    D3DXVECTOR2 center( (float)( width * scaling )/2, (float)( height * scaling )/2);

    //create 2D transformation matrix
    D3DXMATRIX mat;
    D3DXMatrixTransformation2D( &mat, NULL, 0, &scale, &center, rotation, &trans );
    
    //tell sprite object to use the transform
    spriteobj->SetTransform( &mat );

    //calculate frame location in source image
    int fx = (frame % columns) * width;
    int fy = (frame / columns) * height;
    RECT srcRect = {fx, fy, fx + width, fy + height};

    //draw the sprite frame
    spriteobj->Draw( image, &srcRect, NULL, NULL, color );
}

//bounding  box collision detection
int Collision(SPRITE sprite1, SPRITE sprite2)
{
    RECT rect1;
    rect1.left = (long)sprite1.x;
    rect1.top = (long)sprite1.y;
    rect1.right = (long)sprite1.x + sprite1.width * sprite1.scaling;
    rect1.bottom = (long)sprite1.y + sprite1.height * sprite1.scaling;

    RECT rect2;
    rect2.left = (long)sprite2.x;
    rect2.top = (long)sprite2.y;
    rect2.right = (long)sprite2.x + sprite2.width * sprite2.scaling;
    rect2.bottom = (long)sprite2.y + sprite2.height * sprite2.scaling;

    RECT dest; //ignored
    return IntersectRect(&dest, &rect1, &rect2);
}


bool CollisionD(SPRITE sprite1, SPRITE sprite2)
{
    double radius1, radius2;

    //calculate radius 1
    if (sprite1.width > sprite1.height)
        radius1 = (sprite1.width * sprite1.scaling) / 2.0;
    else
        radius1 = (sprite1.height * sprite1.scaling) / 2.0;

    //center point 1
    double x1 = sprite1.x + radius1;
    double y1 = sprite1.y + radius1;
    D3DXVECTOR2 vector1(x1, y1);

    //calculate radius 2
    if (sprite2.width > sprite2.height)
        radius2 = (sprite2.width * sprite2.scaling) / 2.0;
    else
        radius2 = (sprite2.height * sprite2.scaling) / 2.0;

    //center point 2
    double x2 = sprite2.x + radius2;
    double y2 = sprite2.y + radius2;
    D3DXVECTOR2 vector2(x2, y2);

    //calculate distance
    double deltax = vector1.x - vector2.x;
    double deltay = vector2.y - vector1.y;
    double dist = sqrt((deltax * deltax) + (deltay * deltay));

    //return distance comparison
    return (dist < radius1 + radius2);
}

bool DirectInput_Init(HWND hwnd)
{
    //initialize DirectInput object
    DirectInput8Create(
        GetModuleHandle(NULL), 
        DIRECTINPUT_VERSION, 
        IID_IDirectInput8,
        (void**)&dinput,
        NULL);

    //initialize the keyboard
    dinput->CreateDevice(GUID_SysKeyboard, &dikeyboard, NULL);
    dikeyboard->SetDataFormat(&c_dfDIKeyboard);
    dikeyboard->SetCooperativeLevel(hwnd, DISCL_NONEXCLUSIVE | DISCL_FOREGROUND);
    dikeyboard->Acquire();

    //initialize the mouse
    dinput->CreateDevice(GUID_SysMouse, &dimouse, NULL);
    dimouse->SetDataFormat(&c_dfDIMouse);
    dimouse->SetCooperativeLevel(hwnd, DISCL_NONEXCLUSIVE | DISCL_FOREGROUND);
    dimouse->Acquire();
    d3ddev->ShowCursor(false);

    return true;
}

void DirectInput_Update()
{
    //update mouse
    dimouse->Poll();
    if (!SUCCEEDED(dimouse->GetDeviceState(sizeof(DIMOUSESTATE),&mouse_state)))
    {
        //mouse device lose, try to re-acquire
        dimouse->Acquire();
    }

    //update keyboard
    dikeyboard->Poll();
    if (!SUCCEEDED(dikeyboard->GetDeviceState(256,(LPVOID)&keys)))
    {
        //keyboard device lost, try to re-acquire
        dikeyboard->Acquire();
    }

    //update controllers
    for (int i=0; i< 4; i++ )
    {
        ZeroMemory( &controllers[i], sizeof(XINPUT_STATE) );

        //get the state of the controller
        XINPUT_STATE state;
        DWORD result = XInputGetState( i, &state );

        //store state in global controllers array
        if (result == 0) controllers[i] = state.Gamepad;
    }
}


int Mouse_X()
{
    return mouse_state.lX;
}

int Mouse_Y()
{
    return mouse_state.lY;
}

int Mouse_Button(int button)
{
    return mouse_state.rgbButtons[button] & 0x80;
}

bool Key_Down(int key) 
{
    return (bool)(keys[key] & 0x80);
}


void DirectInput_Shutdown()
{
    if (dikeyboard) 
    {
        dikeyboard->Unacquire();
        dikeyboard->Release();
        dikeyboard = NULL;
    }
    if (dimouse) 
    {
        dimouse->Unacquire();
        dimouse->Release();
        dimouse = NULL;
    }
}

bool XInput_Controller_Found()
{
    XINPUT_CAPABILITIES caps;
    ZeroMemory(&caps, sizeof(XINPUT_CAPABILITIES));
    XInputGetCapabilities(0, XINPUT_FLAG_GAMEPAD, &caps);
    if (caps.Type != 0) return false;
    
    return true;
}

void XInput_Vibrate(int contNum, int amount)
{
    XINPUT_VIBRATION vibration;
    ZeroMemory( &vibration, sizeof(XINPUT_VIBRATION) );
    vibration.wLeftMotorSpeed = amount;
    vibration.wRightMotorSpeed = amount; 
    XInputSetState( contNum, &vibration );
}

LPD3DXFONT MakeFont(string name, int size)
{
    LPD3DXFONT font = NULL;

    D3DXFONT_DESC desc = {
        size,                   //height
        0,                      //width
        0,                      //weight
        0,                      //miplevels
        false,                  //italic
        DEFAULT_CHARSET,        //charset
        OUT_TT_PRECIS,          //output precision
        CLIP_DEFAULT_PRECIS,    //quality
        DEFAULT_PITCH,          //pitch and family
        ""                      //font name
    };

    strcpy(desc.FaceName, name.c_str());

    D3DXCreateFontIndirect(d3ddev, &desc, &font);

    return font;
}

void FontPrint(LPD3DXFONT font, int x, int y, string text, D3DCOLOR color)
{
    //figure out the text boundary
    RECT rect = { x, y, 0, 0 };
    font->DrawText( NULL, text.c_str(), text.length(), &rect, DT_CALCRECT, color); 

    //print the text
    font->DrawText(spriteobj, text.c_str(), text.length(), &rect, DT_LEFT, color); 
}

bool DirectSound_Init(HWND hwnd)
{
    //create DirectSound manager object
    dsound = new CSoundManager();

    //initialize DirectSound
    HRESULT result;
    result = dsound->Initialize(hwnd, DSSCL_PRIORITY);
    if (FAILED(result))
        return false;

    //set the primary buffer format
    result = dsound->SetPrimaryBufferFormat(2, 22050, 16);
    if (FAILED(result))
        return false;

    return true;
}

void DirectSound_Shutdown()
{
    if (dsound)
        delete dsound;
}

CSound* LoadSound(string filename)
{
    HRESULT result;

    //create local reference to wave data
    CSound *wave = NULL;

    //attempt to load the wave file
    char s[255];
    sprintf(s, "%s", filename.c_str());
    result = dsound->Create(&wave, s);
    if (FAILED(result))
        wave = NULL;

    return wave;
}

void PlaySound(CSound *sound)
{
    sound->Play();
}

void LoopSound(CSound *sound)
{
    sound->Play(0, DSBPLAY_LOOPING);
}

void StopSound(CSound *sound)
{
    sound->Stop();
}

 

main.cpp

#include "DirectX.h"
using namespace std;

bool gameover = false;

//windows event handling function
LRESULT CALLBACK WinProc(HWND hwnd, UINT message, WPARAM wParam, LPARAM lParam)
{
    switch (message)
    {
    case WM_DESTROY:
        gameover = true;
        PostQuitMessage(0);
        return 0;
    }

    return DefWindowProc(hwnd, message, wParam, lParam);
}


int WINAPI WinMain(HINSTANCE hInstance, HINSTANCE hPreInstance, LPSTR lpCmdLine, int nCmdShow)
{
    //set the windows properties
    WNDCLASSEX wc;
    wc.cbSize = sizeof(WNDCLASSEX);
    wc.style = CS_HREDRAW | CS_VREDRAW;
    wc.lpfnWndProc = (WNDPROC)WinProc;
    wc.cbClsExtra = 0;
    wc.cbWndExtra = 0;
    wc.hInstance = hInstance;
    wc.hIcon = NULL;
    wc.hCursor = LoadCursor(NULL, IDC_ARROW);
    wc.hbrBackground = (HBRUSH)GetStockObject(WHITE_BRUSH);
    wc.lpszMenuName = NULL;
    wc.lpszClassName = APPTITLE.c_str();
    wc.hIconSm = NULL;
    RegisterClassEx(&wc);

    //determine the resolution of the clients desktop screen
    int screenWidth = GetSystemMetrics(SM_CXSCREEN);
    int screenHeight = GetSystemMetrics(SM_CYSCREEN);

    //place the window in the middle of screen
    int posX = (GetSystemMetrics(SM_CXSCREEN) - SCREENW) / 2;
    int posY = (GetSystemMetrics(SM_CYSCREEN) - SCREENH) / 2;

    //Create a window
    HWND window;
    window = CreateWindow(APPTITLE.c_str(), APPTITLE.c_str(),
        WS_CAPTION | WS_MINIMIZEBOX | WS_SYSMENU, posX, posY, SCREENW, SCREENH,
        NULL, NULL, hInstance, NULL); 
    if (window == 0)
        return false;

    //display the window
    ShowWindow(window, nCmdShow);
    UpdateWindow(window);

    //initialize the game
    if (!Game_Init(window))
        return 0;

    //main message loop
    MSG msg;
    while (!gameover)
    {
        //process windows events
        if (PeekMessage(&msg, NULL, 0, 0, PM_REMOVE))
        {
            //handle any event messages
            TranslateMessage(&msg);
            DispatchMessage(&msg);
        }

        //process game loop
        Game_Run(window);
    }

    //free game resources
    Game_End();

    return msg.wParam;
}

 

下面是game.cpp文件，先看开头部分。宏定义D3DFVF_MYVERTEX表示顶点流的类型，D3DFVF_XYZ与D3DFVF_TEX1分别代表顶点位置与纹理坐标。这里的cube数组是立方体的顶点信息，由6个面组成。

#include "DirectX.h"
using namespace std;

const string APPTITLE = "Direct3D Cube";
const int SCREENW = 1024;
const int SCREENH = 576;

DWORD screentimer = timeGetTime();

//vertex and quad definitions
#define D3DFVF_MYVERTEX (D3DFVF_XYZ | D3DFVF_TEX1)

struct VERTEX
{
    float x, y, z;
    float tu, tv;
};

struct QUAD
{
    VERTEX vertices[4];
    LPDIRECT3DVERTEXBUFFER9 buffer;
    LPDIRECT3DTEXTURE9 texture;
};

VERTEX cube[] = {
    {-1.0f, 1.0f,-1.0f, 0.0f,0.0f},     //side 1
    { 1.0f, 1.0f,-1.0f, 1.0f,0.0f },
    {-1.0f,-1.0f,-1.0f, 0.0f,1.0f },
    { 1.0f,-1.0f,-1.0f, 1.0f,1.0f },
    
    {-1.0f, 1.0f, 1.0f, 1.0f,0.0f },    //side 2
    {-1.0f,-1.0f, 1.0f, 1.0f,1.0f },
    { 1.0f, 1.0f, 1.0f, 0.0f,0.0f },
    { 1.0f,-1.0f, 1.0f, 0.0f,1.0f },
    
    {-1.0f, 1.0f, 1.0f, 0.0f,0.0f },    //side 3
    { 1.0f, 1.0f, 1.0f, 1.0f,0.0f },
    {-1.0f, 1.0f,-1.0f, 0.0f,1.0f },
    { 1.0f, 1.0f,-1.0f, 1.0f,1.0f },
    
    {-1.0f,-1.0f, 1.0f, 0.0f,0.0f },    //side 4
    {-1.0f,-1.0f,-1.0f, 1.0f,0.0f },
    { 1.0f,-1.0f, 1.0f, 0.0f,1.0f },
    { 1.0f,-1.0f,-1.0f, 1.0f,1.0f },

    { 1.0f, 1.0f,-1.0f, 0.0f,0.0f },    //side 5
    { 1.0f, 1.0f, 1.0f, 1.0f,0.0f },
    { 1.0f,-1.0f,-1.0f, 0.0f,1.0f },
    { 1.0f,-1.0f, 1.0f, 1.0f,1.0f },
    
    {-1.0f, 1.0f,-1.0f, 1.0f,0.0f },    //side 6
    {-1.0f,-1.0f,-1.0f, 1.0f,1.0f },
    {-1.0f, 1.0f, 1.0f, 0.0f,0.0f },
    {-1.0f,-1.0f, 1.0f, 0.0f,1.0f }
};

QUAD *quads[6];
D3DXVECTOR3 cameraSource;
D3DXVECTOR3 cameraTarget;

 

 函数SetVertex调用SetPosition设置四边形的顶点信息。CreateVertex用于创建顶点。

void SetPosition(QUAD* quad, int ivert, float x, float y, float z)
{
    quad->vertices[ivert].x = x;
    quad->vertices[ivert].y = y;
    quad->vertices[ivert].z = z;
}

void SetVertex(QUAD *quad, int ivert, float x, float y, float z, float tu, float tv)
{
    SetPosition(quad, ivert, x, y, z);
    quad->vertices[ivert].tu = tu;
    quad->vertices[ivert].tv = tv;
}

VERTEX CreateVertex(float x, float y, float z, float tu, float tv)
{
    VERTEX vertex;
    vertex.x = x;
    vertex.y = y;
    vertex.z = z;
    vertex.tu = tu;
    vertex.tv = tv;
    
    return vertex;
}

 

在下面的CreateQuad函数中，首先使用D3DXCreateTextureFromFile用图片文件创建了纹理，然后赋值给quad->texture。接着用CreateVertexBuffer创建了顶点缓存并赋值给quad->buffer，quad由3部分组成，下面就剩下顶点信息vertices了。下面对quad->vertices进行了默认的初始化工作，我们实际使用的顶点数据来源于之前的cube数组。

QUAD* CreateQuad(char *textureFilename)
{
    QUAD *quad = (QUAD*)malloc(sizeof(QUAD));

    //load the texture
    D3DXCreateTextureFromFile(d3ddev, textureFilename, &quad->texture);

    //create vertex buffer for quad
    d3ddev->CreateVertexBuffer(
        4*sizeof(VERTEX),
        0,
        D3DFVF_MYVERTEX, D3DPOOL_DEFAULT,
        &quad->buffer, NULL);

    //create the four corners of this quad triangle strip
    quad->vertices[0] = CreateVertex(-1.0f, 1.0f, 0.0f, 0.0f, 0.0f);
    quad->vertices[1] = CreateVertex(1.0f, 1.0f, 0.0f, 1.0f, 0.0f);
    quad->vertices[2] = CreateVertex(-1.0f, -1.0f, 0.0f, 0.0f, 1.0f);
    quad->vertices[3] = CreateVertex(1.0f, -1.0f, 0.0f, 1.0f, 1.0f);

    return quad;
}

void DeleteQuad(QUAD *quad)
{
    if (quad == NULL)
        return;

    if (quad->buffer != NULL)
        quad->buffer->Release();

    if (quad->texture != NULL)
        quad->texture->Release();

    free(quad);
}

 

下面的函数DrawQuad用于绘制四边形。首先，需要把初始化好的顶点信息传递给顶点缓存，这里定义了一个临时指针变量temp，然后调用lock函数来锁住顶点缓冲区，同时使用temp指向了顶点缓存。然后，就可以用memcpy给这个代表顶点缓存的temp赋值了，最后要Unlock才行。接着用SetTexture设置使用的纹理，用SetStreamSource设置流源，使Direct3D知道顶点的来源以及需要渲染多少顶点。最后，绘制流源指定的基元(primitive)，即基础图元。在DirectX中，基础图元只有点、线、三角形，这里使用三角形条的方式绘制四边形。传入的参数0代表索引，2代表两个三角形，而参数TRIANGLESTRIP也能换成TRIANGLELIST，只是绘制方式不同，下面就是区别。三角形列表需要6个顶点来绘制一个四边形，而三角形条只需要4个顶点信息。

void DrawQuad(QUAD *quad)
{
    //fill vertex buffer with quad vertices
    void *temp = NULL;
    quad->buffer->Lock(0, sizeof(quad->vertices), (void**)&temp, 0);
    memcpy(temp, quad->vertices, sizeof(quad->vertices));
    quad->buffer->Unlock();

    //draw the textured dual triangle strip
    d3ddev->SetTexture(0, quad->texture);
    d3ddev->SetStreamSource(0, quad->buffer, 0, sizeof(VERTEX));
    d3ddev->DrawPrimitive(D3DPT_TRIANGLESTRIP, 0, 2);
}

 

SetIdentity函数最后使用了SetTransform，下面还会使用，这个函数用于在渲染之前进行矩阵转换，你不妨再看看前面的世界变换、视图变换、投影变换这些概念。D3DXMatrixTranslation用于设置平移矩阵，将设置的矩阵信息保存在矩阵matWorld中。D3DTS_WORLD是一个宏定义，这段就表示进行世界变换的操作。

void SetIdentity()
{
    //set default position, scale, rotation
    D3DXMATRIX matWorld;
    D3DXMatrixTranslation(&matWorld, 0.0f, 0.0f, 0.0f);
    d3ddev->SetTransform(D3DTS_WORLD, &matWorld);
}

void ClearScene(D3DXCOLOR color)
{
    d3ddev->Clear(0, NULL, D3DCLEAR_TARGET | D3DCLEAR_ZBUFFER, color, 1.0f, 0);
}

 

下面的SetCamera函数用于设置相机信息，显然这里的相机是虚拟的，用视图变换来表示。看到D3DXMatrixLookAtLH这个重要的函数，这个函数最终得到一个用于视图变换的观察矩阵matView，参数cameraSource表示相机的位置（观察点），cameraTarget表示相机朝着什么方向看的向量，updir代表当前世界方向向上的向量，默认为(0, 1, 0)。最后，通过SetTransform(D3DTS_VIEW,&matView)进行了视图变换。

void SetCamera(float x, float y, float z, float lookx, float looky, float lookz)
{
    D3DXMATRIX matView;
    D3DXVECTOR3 updir(0.0f, 1.0f, 0.0f);

    //move the camera
    cameraSource.x = x;
    cameraSource.y = y;
    cameraSource.z = z;

    //point the camera
    cameraTarget.x = lookx;
    cameraTarget.y = looky;
    cameraTarget.z = lookz;

    //set up the camera view matrix
    D3DXMatrixLookAtLH(&matView, &cameraSource, &cameraTarget, &updir);
    d3ddev->SetTransform(D3DTS_VIEW, &matView);
}

 

最后还有一个投影变换，使用SetTransform(D3DTS_PROJECTION, &matProj)完成，Projection就是投影的意思。参数fieldOfView代表视景体，aspectRatio代表图像的宽高比，nearRange与farRange代表近平面与远平面。

void SetPerspective(float fieldOfView, float aspectRatio, float nearRange, float farRange)
{
    //set the perspective so things in the distance will look smaller
    D3DXMATRIX matProj;
    D3DXMatrixPerspectiveFovLH(&matProj, fieldOfView, aspectRatio, nearRange, farRange);
    d3ddev->SetTransform(D3DTS_PROJECTION, &matProj);
}

 

下面这个函数用于初始化立方体，调用CreateQuad函数创建了带纹理贴图的四边形，然后用cube数组对这些四边形的顶点赋值。

void Init_Cube()
{
    for (int q = 0; q < 6; q++)
    {
        int i = q*4;
        quads[q] = CreateQuad("cube.bmp");
        for (int v = 0; v < 4; v++)
        {
            quads[q]->vertices[v] = CreateVertex(
                cube[i].x, cube[i].y, cube[i].z,
                cube[i].tu, cube[i].tv);
            i++;
        }
    }
}

 

我们还要做一件事，就是让立方体旋转起来。在Rotate_Cube中，xrot、yrot、zrot组成了旋转需要的旋转轴，而我们对3D物体进行旋转还需要进行旋转的旋转矩阵matRot。这里还设置了平移矩阵matTrans，不过这里暂时没有平移。函数D3DXMatrixRotationYawPitchRoll用于创建旋转矩阵，最后用matRot*matTrans来得到一个组合了平移与旋转的矩阵matWorld。

void Rotate_Cube()
{
    static float xrot = 0.0f;
    static float yrot = 0.0f;
    static float zrot = 0.0f;

    //rotate the x and y axes
    xrot += 0.2f;
    yrot += 0.00f;

    //create the matrices
    D3DXMATRIX matWorld;
    D3DXMATRIX matTrans;
    D3DXMATRIX matRot;

    //get an identity matrix
    D3DXMatrixTranslation(&matTrans, 0.0f, 0.0f, 0.0f);

    //rotate the cube
    D3DXMatrixRotationYawPitchRoll(&matRot,D3DXToRadian(xrot),D3DXToRadian(yrot),D3DXToRadian(zrot));
    matWorld = matRot * matTrans;

    //complete the operation
    d3ddev->SetTransform(D3DTS_WORLD, &matWorld);
}

 

下面是Game_Init函数，可以直接从SetCamera开始看起。如果改变SetCamera函数的参数，就能使图像放大与缩小。

bool Game_Init(HWND window)
{
    srand(time(NULL));

    //initialize Direct3D
    if (!Direct3D_Init(window, SCREENW, SCREENH, false))
    {
        MessageBox(window,"Error initializing Direct3D",APPTITLE.c_str(),0);
        return false;
    }

    //initialize DirectInput
    if (!DirectInput_Init(window))
    {
        MessageBox(window,"Error initializing DirectInput",APPTITLE.c_str(),0);
        return false;
    }

    //initialize DirectSound
    if (!DirectSound_Init(window))
    {
        MessageBox(window,"Error initializing DirectSound",APPTITLE.c_str(),0);
        return false;
    }

    //position the camera
    SetCamera(0.0f, 2.0f, -4.0f, 0, 0, 0);

    float ratio = (float)SCREENW / (float)SCREENH;
    SetPerspective(45.0f, ratio, 0.1f, 10000.0f);

    //turn dynamic lighting off, z-buffer on
    d3ddev->SetRenderState(D3DRS_LIGHTING, FALSE);
    d3ddev->SetRenderState(D3DRS_ZENABLE, TRUE);

    //set the Direct3D stream to use the custom vertex
    d3ddev->SetFVF(D3DFVF_MYVERTEX);

    //convert the cube values into quads
    Init_Cube();

    return true;
}

 

函数Game_Run变得很简单，先Rotate_Cube使立方体产生旋转效果，接着在for循环中DrawQuad绘制立方体的6个面就可以了。

void Game_Run(HWND window)
{
    if (!d3ddev) return;
    DirectInput_Update();
    d3ddev->Clear(0, NULL, D3DCLEAR_TARGET | D3DCLEAR_ZBUFFER, D3DCOLOR_XRGB(0,0,0), 1.0f, 0);

    //slow rendering to approximately 60 fps
    if (timeGetTime() > screentimer + 14)
    {
        screentimer = GetTickCount();

        Rotate_Cube();

        //start rendering
        if (d3ddev->BeginScene())
        {
           for (int n = 0; n < 6; n++)
           {
               DrawQuad(quads[n]);
           }

            //stop rendering
            d3ddev->EndScene();
            d3ddev->Present(NULL, NULL, NULL, NULL);
        }
    }

    //exit with escape key or controller Back button
    if (KEY_DOWN(VK_ESCAPE)) gameover = true;
    if (controllers[0].wButtons & XINPUT_GAMEPAD_BACK) gameover = true;

}

 

最后是Game_End函数

void Game_End()
{
    for (int q = 0; q < 6; q++)
        DeleteQuad(quads[q]);
    DirectSound_Shutdown();
    DirectInput_Shutdown();
    Direct3D_Shutdown();
}

 

本文只是用DirectX 9的知识简单的绘制了一个立方体，如果不使用纹理图片，直接使用顶点颜色信息也是可以的。下面是运行截图，源代码，参考自游戏编程入门。