void CompositorRenderPass::Commit(CommitContext& context) {
if (context.rsys->GetTicket() != this->renderSystemTicket) {
if (numTextureToResolve == 1) {
TextureUnit tu;
RenderTarget* target = context.GetTargetByName(_rtJustOne.name);
if (target && target->GetRenderTargetType() == RenderTargetType::TEXTURE) {
tu.texture = static_cast<RenderTexture*>(target);
parameters.SetData(&tu, _rtJustOne.offset);
}
} else {
for (uint32 i = 0; i < numTextureToResolve; ++i) {
TextureUnit tu;
RenderTarget* target = context.GetTargetByName(_rtBunchOf[i].name);
if (target && target->GetRenderTargetType() == RenderTargetType::TEXTURE) {
tu.texture = static_cast<RenderTexture*>(target);
parameters.SetData(&tu, _rtBunchOf[i].offset);
}
}
}
this->renderSystemTicket = context.rsys->GetTicket();
}
BeginRender(context);
RenderPrimitive(context, (uint32)(ptrdiff_t)this, &primitive);
EndRender(context);
}
void RenderWindowD11_2::Render()
{
BeginRender();
// Render all render component from scene
if (m_bActive && m_pSceneToRender && m_pCamera) {
_lSceneObject objects;
m_pSceneToRender->GetSceneObjects(objects);
for (auto object : objects)
{
_lCoreComponent components;
object->GetObjectComponents(components);
for (auto component : components)
{
switch (component->GetType())
{
case Dex::OCT_RENDER:
{
RenderOneComponent(dynamic_cast<RenderComponentD11_2*>(component));
}
break;
case Dex::OCT_CAMERA:
break;
case Dex::OCT_LIGHT:
break;
}
}
}
}
EndRender();
}
void Pipeline::OnRender(const App& app, const AppUpdateInfo&)
{
BeginRender();
GfxTestureEx_SwapChain& swapChainTexture = m_swapChain.GetTexture();
GfxGraphicsContext& context = m_contextManager.GetGraphicsContext(0);
context.SetPipelineState(m_graphicsState);
context.SetGraphicsRootSignature(m_rootSignature);
context.SetRenderTarget(swapChainTexture);
GfxViewport viewport(0.0f, 0.0f, (float)swapChainTexture.GetWidth(), (float)swapChainTexture.GetHeight());
GfxScissor scissor(0, 0, swapChainTexture.GetWidth(), swapChainTexture.GetHeight());
context.SetViewports(1, &viewport);
context.SetScissors(1, &scissor);
swapChainTexture.SetClearColor(GfxColorRGBA(0.0f, 0.2f, 0.4f, 1.0f));
context.ClearRenderTarget(swapChainTexture);
context.SetPrimitiveTopology(GfxPrimitiveTopology::TriangleList);
GfxVertexBufferView vbView(m_vertexBuffer, m_vertexBuffer.GetSize(), sizeof(PosColorVertex));
context.SetVertexBuffer(
0,
vbView);
context.DrawInstanced(3, 1, 0, 0);
EndRender();
}
void SimpleSurface::applyFilter (Surface *inSrc, const Rect &inRect, ImagePoint inOffset, Filter *inFilter) {
if (!mBase) return;
FilterList f;
f.push_back (inFilter);
Rect src_rect (inRect.w, inRect.h);
Rect dest = GetFilteredObjectRect (f, src_rect);
inSrc->IncRef ();
Surface *result = FilterBitmap (f, inSrc, src_rect, dest, false, ImagePoint (inRect.x, inRect.y));
dest.Translate (inOffset.x, inOffset.y);
src_rect = Rect (0, 0, result->Width (), result->Height ());
int dx = dest.x;
int dy = dest.y;
dest = dest.Intersect (Rect (0, 0, mWidth, mHeight));
dest.Translate (-dx, -dy);
dest = dest.Intersect (src_rect);
dest.Translate (dx, dy);
int bpp = BytesPP ();
RenderTarget t = BeginRender (dest, false);
//printf("Copy back @ %d,%d %dx%d + (%d,%d)\n", dest.x, dest.y, t.Width(), t.Height(), dx, dy);
for (int y = 0; y < t.Height (); y++)
memcpy ((void *)(t.Row (y + dest.y) + ((dest.x) * bpp)), result->Row (y - dy) - (dx * bpp), dest.w * bpp);
EndRender ();
result->DecRef ();
}
void SpectralEffect::InitInGame()
{
test.LoadFiles("Data.zip", d3dd);
while (test.GetProgress() != 100)
{
Sleep (100);
}
string temp[1];
temp[0] = "YellowBall.png";
testpipe.SetPipeType(d3dd, 100, 100, 280, 5, 1, temp, 1, "Pipe.png");
testcannons.InitCannonType(&testpipe, 30, 20, 100, 15, "Cannon.png");
int time = 0, speed = 1;
SetFPS(30);
while (gameRunning)
{
StartFrame();
BeginRender();
testcannons.Render();
testpipe.Render();
EndRender();
if (time > 500)
{
speed ++;
testpipe.SetSpeed(speed);
time = 0;
}
time ++;
EndFrame();
}
gameRunning = true;
}
void VulkanWindow::Run()
{
#ifdef _WIN32
MSG msg;
bool done = false;
while ( !done )
{
if ( PeekMessage ( &msg, NULL, 0, 0, PM_REMOVE ) )
{
if ( msg.message == WM_QUIT )
{
done = true;
}
else
{
TranslateMessage ( &msg );
DispatchMessage ( &msg );
}
}
else
{
BeginRender();
EndRender();
}
}
#else
#endif
}
void CRenderSystemBase::ShowSplash(const std::string& message)
{
if (!g_advancedSettings.m_splashImage && !(m_splashImage || !message.empty()))
return;
if (!m_splashImage)
{
std::string splashImage = "special://home/media/Splash.png";
if (!XFILE::CFile::Exists(splashImage))
splashImage = "special://xbmc/media/Splash.png";
m_splashImage = std::unique_ptr<CGUIImage>(new CGUIImage(0, 0, 0, 0, g_graphicsContext.GetWidth(),
g_graphicsContext.GetHeight(), CTextureInfo(splashImage)));
m_splashImage->SetAspectRatio(CAspectRatio::AR_SCALE);
}
g_graphicsContext.lock();
g_graphicsContext.Clear();
RESOLUTION_INFO res = g_graphicsContext.GetResInfo();
g_graphicsContext.SetRenderingResolution(res, true);
//render splash image
BeginRender();
m_splashImage->AllocResources();
m_splashImage->Render();
m_splashImage->FreeResources();
if (!message.empty())
{
if (!m_splashMessageLayout)
{
auto messageFont = g_fontManager.LoadTTF("__splash__", "arial.ttf", 0xFFFFFFFF, 0, 20, FONT_STYLE_NORMAL, false, 1.0f, 1.0f, &res);
if (messageFont)
m_splashMessageLayout = std::unique_ptr<CGUITextLayout>(new CGUITextLayout(messageFont, true, 0));
}
if (m_splashMessageLayout)
{
m_splashMessageLayout->Update(message, 1150, false, true);
float textWidth, textHeight;
m_splashMessageLayout->GetTextExtent(textWidth, textHeight);
int width = g_graphicsContext.GetWidth();
int height = g_graphicsContext.GetHeight();
float y = height - textHeight - 100;
m_splashMessageLayout->RenderOutline(width/2, y, 0, 0xFF000000, XBFONT_CENTER_X, width);
}
}
//show it on screen
EndRender();
g_graphicsContext.unlock();
g_graphicsContext.Flip(true, false);
}
void GlutKeyboard(unsigned char key, int x, int y)
{
switch ( key ) {
case 27: // ESC
exit(0);
break;
case ' ':
switch ( mode ) {
case MODE_READY:
mode = MODE_RENDERING;
viewMode = VIEWMODE_IMAGE;
if ( dofImage ) {
Color24 *p = renderImage.GetPixels();
for ( int i=0; i<camera.imgWidth*camera.imgHeight; i++ ) p[i] = dofImage[i];
} else {
DrawScene();
glReadPixels( 0, 0, renderImage.GetWidth(), renderImage.GetHeight(), GL_RGB, GL_UNSIGNED_BYTE, renderImage.GetPixels() );
}
startTime = time(NULL);
BeginRender();
break;
case MODE_RENDERING:
mode = MODE_READY;
StopRender();
glutPostRedisplay();
break;
case MODE_RENDER_DONE:
mode = MODE_READY;
viewMode = VIEWMODE_OPENGL;
glutPostRedisplay();
break;
}
break;
case '1':
viewAngle1 = viewAngle2 = 0;
viewMode = VIEWMODE_OPENGL;
glutPostRedisplay();
break;
case '2':
viewMode = VIEWMODE_IMAGE;
glutPostRedisplay();
break;
case '3':
viewMode = VIEWMODE_Z;
glutPostRedisplay();
break;
case '4':
viewMode = VIEWMODE_SAMPLECOUNT;
glutPostRedisplay();
break;
case '5':
viewMode = VIEWMODE_IRRADCOMP;
glutPostRedisplay();
break;
}
}
void Graphics::Update()
{
BeginRender();
Render3D();
Begin2DRender();
Render2D();
End2DRender();
PostRender3D();
EndRender();
}
HRESULT CObject::RenderObject()
{
HRESULT hr = D3D_OK;
CShaderManager::GetInstance()->SetObject( this );
V_RETURN( BeginRender() );
CShaderManager::GetInstance()->Render();
V_RETURN( EndRender() );
return hr;
}
void ForwardRenderPass::Commit(CommitContext& context) {
/*context.sunLightIntensity = Vector4(1, 1, 1, 1);
context.sunLightPosition = Vector4(0, 400, 0, 1);
context.sunLightColor = Color(0.8f, 0.8f, 0.4f, 1);*/
BeginRender(context);
VisibilitySet& visibles = *context.visibiles;
RenderQueueList& layerList = visibles.GetRenderQueues();
for (auto &layer : layerList) {
if (Test(layer.flags & RenderQueueFlags::FORWARD)) {
for (auto &prim : layer.visibles) {
RenderPrimitive(context, prim.first, prim.second);
}
}
}
EndRender(context);
}
void GlutKeyboard(unsigned char key, int x, int y)
{
switch ( key ) {
case 27: // ESC
exit(0);
break;
case ' ':
switch ( mode ) {
case MODE_READY:
mode = MODE_RENDERING;
viewMode = VIEWMODE_IMAGE;
DrawScene();
glReadPixels( 0, 0, renderImage.GetWidth(), renderImage.GetHeight(), GL_RGB, GL_UNSIGNED_BYTE, renderImage.GetPixels() );
startTime = time(NULL);
BeginRender();
break;
case MODE_RENDERING:
mode = MODE_READY;
StopRender();
glutPostRedisplay();
break;
case MODE_RENDER_DONE:
mode = MODE_READY;
viewMode = VIEWMODE_OPENGL;
glutPostRedisplay();
break;
}
break;
case '1':
viewAngle1 = viewAngle2 = 0;
viewMode = VIEWMODE_OPENGL;
glutPostRedisplay();
break;
case '2':
viewMode = VIEWMODE_IMAGE;
glutPostRedisplay();
break;
case '3':
viewMode = VIEWMODE_Z;
glutPostRedisplay();
break;
}
}
void CGUIWindowTestPattern::Render()
{
BeginRender();
const RESOLUTION_INFO info = g_graphicsContext.GetResInfo();
int top = info.Overscan.top;
int bottom = info.Overscan.bottom;
int left = info.Overscan.left;
int right = info.Overscan.right;
switch (m_pattern)
{
case 0:
DrawContrastBrightnessPattern(top, left, bottom, right);
break;
case 1:
DrawVerticalLines(top, left, bottom, right);
break;
case 2:
DrawHorizontalLines(top, left, bottom, right);
break;
case 3:
DrawCheckers(top, left, bottom, right);
break;
case 4:
DrawBouncingRectangle(top, left, bottom, right);
break;
}
EndRender();
CGUIWindow::Render();
}
void CGUIWindowTestPattern::Render()
{
BeginRender();
int top = g_settings.m_ResInfo[g_graphicsContext.GetVideoResolution()].Overscan.top;
int bottom = g_settings.m_ResInfo[g_graphicsContext.GetVideoResolution()].Overscan.bottom;
int left = g_settings.m_ResInfo[g_graphicsContext.GetVideoResolution()].Overscan.left;
int right = g_settings.m_ResInfo[g_graphicsContext.GetVideoResolution()].Overscan.right;
switch (m_pattern)
{
case 0:
DrawContrastBrightnessPattern(top, left, bottom, right);
break;
case 1:
DrawVerticalLines(top, left, bottom, right);
break;
case 2:
DrawHorizontalLines(top, left, bottom, right);
break;
case 3:
DrawCheckers(top, left, bottom, right);
break;
case 4:
DrawBouncingRectangle(top, left, bottom, right);
break;
}
EndRender();
CGUIWindow::Render();
}
int main(){
auto pLogger = CB::Log::CLogger::GetInstance();
pLogger->AddStream(CB::IO::File::Open(L"main.log", CB::IO::File::AccessType::WriteOnly, CB::IO::File::OpenAction::AlwaysCreate).Cast<CB::IO::IStream>());
pLogger->AddStream(CB::IO::Console::Create().Cast<CB::IO::IStream>(), CB::Log::CTextFormatter::Create(CB::String::Encoding::ANSI).Cast<CB::Log::IEntryFormatter>());
pLogger->SetDebugMode(true);
try{
auto pWinDriver = CB::Window::LoadDriver(L"MSWindowDriver");
auto pGraphicDriver = CB::Graphic::LoadDriver(L"OGLGraphicDriver");
{
auto pWinManager = pWinDriver->CreateManager();
auto pGraphicManager = pGraphicDriver->CreateManager(pWinManager);
CB::Math::CSize outSize(640, 480);
auto pWindow = pWinManager->CreateWindow(L"GraphicTest", CB::Window::Style::Single, outSize);
auto pGraphicAdapter = pGraphicManager->GetDefaultAdapter();
CB::Graphic::CDisplayMode dispMode(pWindow->GetSize(), 0, CB::Graphic::BufferFormat::B8G8R8X8);
CB::Graphic::CDeviceDesc devDesc(pWindow, dispMode, CB::Graphic::BufferFormat::D24S8, false);
CB::Collection::CList<CB::Graphic::FeatureLevel> featureLevels;
featureLevels.Add(CB::Graphic::FeatureLevel::Level_1);
auto pGraphicDevice = pGraphicAdapter->CreateDevice(pWindow, devDesc, featureLevels);
pWindow->OnClose += CB::Signals::CFunc<const bool, CB::CRefPtr<CB::Window::IWindow>>(CloseEvent);
pWindow->SetVisible(true);
CB::Graphic::CDepthStencilStateDesc depthDesc;
depthDesc.bDepthTestEnabled = true;
depthDesc.uDepthFunction = CB::Graphic::CompareFunc::LessEqual;
auto pDepthState = pGraphicDevice->CreateState(depthDesc);
pGraphicDevice->SetState(pDepthState.Cast<CB::Graphic::IDeviceState>());
CB::Graphic::CRasterizerStateDesc rastDesc;
rastDesc.uCullMode = CB::Graphic::CullMode::None;
auto pRastState = pGraphicDevice->CreateState(rastDesc);
pGraphicDevice->SetState(pRastState.Cast<CB::Graphic::IDeviceState>());
CB::Graphic::CBlendStateDesc blendDesc;
blendDesc.ColorBlend.uDestOperand = CB::Graphic::BlendOption::OneMinusSourceAlpha;
blendDesc.ColorBlend.uSourceOperand = CB::Graphic::BlendOption::SourceAlpha;
blendDesc.ColorBlend.uOperation = CB::Graphic::BlendOperation::Add;
blendDesc.AlphaBlend.uDestOperand = CB::Graphic::BlendOption::OneMinusSourceAlpha;
blendDesc.AlphaBlend.uSourceOperand = CB::Graphic::BlendOption::SourceAlpha;
blendDesc.AlphaBlend.uOperation = CB::Graphic::BlendOperation::Add;
blendDesc.bEnabled[0] = true;
auto pBlendState = pGraphicDevice->CreateState(blendDesc);
pGraphicDevice->SetState(pBlendState.Cast<CB::Graphic::IDeviceState>());
auto pFontManager = CB::Font::CManager::Create();
auto pFontStream = CB::IO::File::Open(L"Assets/font.ttf").Cast<CB::IO::IStream>();
auto pFont = pFontManager->Load(pFontStream);
pFont->SelectFace(0);
pFont->SetSize(24);
CB::Collection::CList<CB::Tools::CFontCharDesc> charDescs;
CB::Tools::CFontTextureGenerator fontGen(pGraphicDevice);
fontGen.MaxTextureSize.Set(512, 512);
auto pTexture = fontGen.Generate(pFont, charDescs);
CB::Tools::CTextMeshGenerator textGen(charDescs);
CB::Tools::CMeshRawIVT textMesh;
textGen.Generate(L"Marek M³ynarski!", textMesh);
CB::Collection::CList<CB::Graphic::CVertexElement> vEls;
vEls.Add(CB::Graphic::CVertexElement(0, L"vinput.vPosition", CB::Graphic::VertexType::Float, 3, 0));
vEls.Add(CB::Graphic::CVertexElement(1, L"vinput.vTexCoord", CB::Graphic::VertexType::Float, 2, 0));
GraphicTest::CShaderLoader shaders(pGraphicDevice, L"Shaders/TextureShader.cg");
auto pTextDecl = pGraphicDevice->CreateVertexDeclaration(shaders.pVertexShader, vEls);
auto pTextVertexBuffer = pGraphicDevice->CreateBuffer(CB::Graphic::BufferType::Vertex, CB::Graphic::BufferUsage::Dynamic, CB::Graphic::BufferAccess::Write, textMesh.Vertices);
auto pTextTCoordBuffer = pGraphicDevice->CreateBuffer(CB::Graphic::BufferType::Vertex, CB::Graphic::BufferUsage::Dynamic, CB::Graphic::BufferAccess::Write, textMesh.TexCoords);
auto pTextIndexBuffer = pGraphicDevice->CreateBuffer(CB::Graphic::BufferType::Index, CB::Graphic::BufferUsage::Dynamic, CB::Graphic::BufferAccess::Write, textMesh.Indices);
float32 fAspect = (float32)outSize.Width / (float32)outSize.Height;
CB::Math::CMatrix mProj = CB::Math::CMatrix::GetPerspective(fAspect, 60.0f, 1.0f, 100.0f);
CB::Math::CMatrix mView = CB::Math::CMatrix::GetTranslation(-4.0f, 0.0f, -3.4f);
CB::Math::CMatrix mModel = CB::Math::CMatrix::GetIdentity();
shaders.pFragmentShader->SetSampler(L"texDiffuse", pTexture.Cast<CB::Graphic::IBaseTexture>());
pTexture->SetFilters(CB::Graphic::TextureFilter::Linear, CB::Graphic::TextureFilter::Linear, CB::Graphic::TextureFilter::Linear);
pTexture->SetAnisotropy(8);
//g_pTexture = texture.pTexture;
while(g_bRun){
pGraphicDevice->Clear(1.0f, 1);
pGraphicDevice->Clear(CB::Math::CColor(1.0f, 0.5f, 0.0f, 1.0f));
pGraphicDevice->BeginRender();
pGraphicDevice->SetShader(shaders.pVertexShader);
pGraphicDevice->SetShader(shaders.pFragmentShader);
static float32 fV = 0.0f;
fV += 20 * g_Timer.GetTimeDelta();
mModel = CB::Math::CMatrix::GetRotation(CB::Math::AxisOrientation::AxisX, fV);
shaders.pVertexShader->SetUniform(L"vinput.mProj", mProj);
shaders.pVertexShader->SetUniform(L"vinput.mView", mView);
shaders.pVertexShader->SetUniform(L"vinput.mModel", mModel);
pGraphicDevice->SetVertexDeclaration(pTextDecl);
pGraphicDevice->SetVertexBuffer(0, pTextVertexBuffer);
pGraphicDevice->SetVertexBuffer(1, pTextTCoordBuffer);
pGraphicDevice->SetIndexBuffer(pTextIndexBuffer);
pGraphicDevice->RenderIndexed(textMesh.uNumberOfPolygons);
pGraphicDevice->EndRender();
g_Timer.Update();
pWinManager->ProcessEvents();
float fFPS = 1.0f / (g_Timer.GetTimeDelta() == 0.0f ? 1.0f : g_Timer.GetTimeDelta());
uint32 uFPS = (uint32)fFPS;
textMesh.Clear();
textGen.Generate(L"FPS: " + CB::String::ToString(uFPS), textMesh);
pTextVertexBuffer->LoadData(textMesh.Vertices);
pTextTCoordBuffer->LoadData(textMesh.TexCoords);
pTextIndexBuffer->LoadData(textMesh.Indices);
pGraphicDevice->Swap();
}
g_pTexture.Release();
}
}
catch(CB::Exception::CException& Exception){
CB::Log::Write(Exception, CB::Log::LogLevel::Fatal);
CB::Message::Show(Exception, CB::Message::Icon::Error);
}
return 0;
}
void HookGui::HGWidgetShader::Render(VulkanWrapper::Context* _graphicContext, int _swapchainImageIndex)
{
// Check if this shader is valid to be used
if (!IsValid())
{
return;
}
// Update the instance data
UpdateInstanceData(_graphicContext);
// Begin the rendering process
BeginRender(_graphicContext, _swapchainImageIndex);
// Get the vertex buffers
VulkanWrapper::Buffer* vertexBuffer = m_WidgetModel->GetVertexBuffer();
VulkanWrapper::Buffer* indexBuffer = m_WidgetModel->GetIndexBuffer();
// Set the buffers and offsets
VkBuffer vertexBuffers[] = { vertexBuffer->GetRawBuffer() };
VkBuffer instanceBuffers[] = { m_InstanceBuffer.GetRawBuffer() };
VkDeviceSize vertexOffsets[] = { 0 };
VkDeviceSize instaceOffsets[] = { 0 };
// Bind them
vkCmdBindVertexBuffers(m_CommandBuffer, 0, 1, vertexBuffers, vertexOffsets);
vkCmdBindVertexBuffers(m_CommandBuffer, 1, 1, instanceBuffers, instaceOffsets);
vkCmdBindIndexBuffer(m_CommandBuffer, indexBuffer->GetRawBuffer(), 0, VK_INDEX_TYPE_UINT32);
// Set the initial texture identificator
uint32_t currentTextureIdentificator = -1;
// The total number of instances to be rendered
uint32_t totalInstances = 0;
// The first instance to be rendered
uint32_t firstInstance = 0;
// For each widget
for (int i = 0; i < m_Renderables.size(); i++)
{
// Get the current widget
HGWidget* widget = m_Renderables[i];
// Get the widget image
HGImage* widgetImage = widget->GetImage();
// Get the image texture group
VulkanWrapper::TextureGroup* widgetImageTextureGroup = widgetImage->GetTextureGroupReference();
// Get the texture group identificator
uint32_t textureIdentificator = widgetImageTextureGroup->GetTextureGroupIdentificator();
// Check if we are using the same texture group
if (currentTextureIdentificator != textureIdentificator)
{
// Update the texture identificator
VkDescriptorSet descriptorSets[] = { widgetImageTextureGroup->GetDescriptorSet(), m_DescriptorSet };
vkCmdBindDescriptorSets(m_CommandBuffer, VK_PIPELINE_BIND_POINT_GRAPHICS, m_PipelineLayout, 0, 2, descriptorSets, 0, nullptr);
// If we have at last one instance
if (totalInstances)
{
// Issue a draw call
vkCmdDrawIndexed(m_CommandBuffer, m_WidgetModel->GetIndexCount(), totalInstances, 0, 0, firstInstance);
// Set the new first instance
firstInstance = i;
// Zero the total instances
totalInstances = 0;
}
// Set the new current texture identificator
currentTextureIdentificator = textureIdentificator;
}
// Increment the total number of instances
totalInstances++;
}
// Check if we have instances remaining
if (totalInstances)
{
// Issue the last draw call
vkCmdDrawIndexed(m_CommandBuffer, m_WidgetModel->GetIndexCount(), totalInstances, 0, 0, firstInstance);
}
// Clear the renderable array
m_Renderables.clear();
// End the rendering process
EndRender();
}
void Pipeline::OnRender(const App& app, const AppUpdateInfo&)
{
BeginRender();
GfxGraphicsContext& context = m_contextManager.GetGraphicsContext(0);
context.ResourceBarrier(
m_depth,
GfxResourceState::DepthWrite);
context.ResourceBarrier(
m_rt,
GfxResourceState::RenderTarget);
context.SetRenderTarget(m_rt, m_depth);
GfxViewport viewport0 = GfxViewport(0.0f, 0.0f, (float)m_rt.GetWidth(), (float)m_rt.GetHeight());
GfxScissor scissor0 = GfxScissor(0, 0, m_rt.GetWidth(), m_rt.GetHeight());
context.SetViewports(1, &viewport0);
context.SetScissors(1, &scissor0);
context.ClearRenderTarget(m_rt);
context.ClearDepthStencilTarget(m_depth);
{
m_renderer.SetViewMatrix(m_view);
m_renderer.SetProjectionMatrix(m_proj);
RendererGraphicsStateDesc renderDesc;
renderDesc.m_rtvFormats[0] = GfxFormat::R8G8B8A8_Unorm;
renderDesc.m_dsvFormat = GfxFormat::D32_Float;
renderDesc.m_depthEnable = true;
renderDesc.m_depthWriteMask = GfxDepthWriteMask::All;
m_renderer.Render(
context,
RendererDrawStageType::RendererDrawStageType_Opaque,
renderDesc);
}
context.ResourceBarrier(m_rt, GfxResourceState::PixelShaderResource);
context.ResourceBarrier(m_depth, GfxResourceState::GenericRead);
// 箱を描いたレンダーターゲットテクスチャをスワップチェインに描画する
{
GfxTestureEx_SwapChain& swapChainTexture = m_swapChain.GetTexture();
GfxViewport viewport1(0.0f, 0.0f, (float)swapChainTexture.GetWidth(), (float)swapChainTexture.GetHeight());
GfxScissor scissor1(0, 0, swapChainTexture.GetWidth(), swapChainTexture.GetHeight());
context.SetRenderTarget(swapChainTexture);
context.SetViewports(1, &viewport1);
context.SetScissors(1, &scissor1);
context.SetPipelineState(m_graphicsState);
context.SetGraphicsRootSignature(m_rootSignature);
context.SetDynamicViewDescriptor(0, 0, m_rt);
context.SetDynamicSamplerDescriptor(1, 0, m_sampler);
context.SetGraphicsRootCBV(2, m_constantBuffer.Get());
swapChainTexture.SetClearColor(GfxColorRGBA(0.0f, 0.2f, 0.4f, 1.0f));
context.ClearRenderTarget(swapChainTexture);
context.SetPrimitiveTopology(GfxPrimitiveTopology::TriangleList);
context.SetDynamicVB(0, ArraySize(kVertexData), sizeof(kVertexData[0]), kVertexData);
context.DrawInstanced(6, 1, 0, 0);
}
EndRender();
}
void FrameBuffer::Init()
{
glGenFramebuffers(1, &id);
glBindFramebuffer(GL_FRAMEBUFFER, id);
// GetGame()->Log(glGetError());
drawBuffers.clear();
Texture* tex = nullptr;
if(textures.size() > 0)
{
for(uint i = 0; i < textures.size(); ++i)
{
tex = textures[i];
// tex->scaleFilter = Texture::ScaleFilter::Linear;
tex->wrapMode = Texture::WrapMode::Clamp;
// tex->mode = GL_TEXTURE_2D_MULTISAMPLE;
tex->size = uvec2(rect.width, rect.height);
tex->SetIndex(startIndex+i);
tex->InitData(0);
uint32 attachment = startIndex+GL_COLOR_ATTACHMENT0+i;
GetGame()->Log("Setting up textures for FrameBuffer, tex ", i, " gets attachment ", attachment, ". GL_COLOR_ATTACHMENT0 = ", GL_COLOR_ATTACHMENT0);
tex->Bind();
glFramebufferTexture2D(GL_FRAMEBUFFER, attachment, tex->GetMode(), tex->GetId(), 0);
drawBuffers.push_back(attachment);
}
}
if(hasDepth)
{
/* glGenRenderbuffers(1, &depthBuffer);
glBindRenderbuffer(GL_RENDERBUFFER, depthBuffer);
glRenderbufferStorage(GL_RENDERBUFFER, GL_DEPTH24_STENCIL8, rect.width, rect.height);
glFramebufferRenderbuffer(GL_FRAMEBUFFER, GL_DEPTH_STENCIL_ATTACHMENT, GL_RENDERBUFFER, depthBuffer);
*/
if(depthTexture)
{
// depthTexture->SetFormat(Texture::Format::Depth32F_Stencil8, Texture::Format::Depth);
depthTexture->SetFormat(Texture::Format::Depth32F, Texture::Format::Depth);
depthTexture->wrapMode = Texture::WrapMode::Clamp;
depthTexture->dataType = Texture::DataType::Float;
depthTexture->size = uvec2(rect.width, rect.height);
depthTexture->SetIndex(startIndex+textures.size());
depthTexture->InitData(0);
depthTexture->Bind();
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_DEPTH_STENCIL_ATTACHMENT, depthTexture->GetMode(), depthTexture->GetId(), 0);
GetGame()->Log(glGetError());
}
}
DrawBuffers();
BeginRender();
Unbind();
}
void ParticleSystem::Init()
{
BeginRender();
}
// |----------------------------------------------------------------------------|
// | Render |
// |----------------------------------------------------------------------------|
bool GraphicsClass::Render(int mouseX, int mouseY, Coord camera_position)
{
bool result;
static float rotation = 0.0f;
result = BeginRender();
// Turn off the Z buffer and culling for skybox
m_D3D->TurnZBufferOff();
m_D3D->TurnOffBackCulling();
// Skybox rendering
D3DXMATRIX ident, translationMatrix;
D3DXMatrixIdentity(&ident);
D3DXMatrixTranslation(&translationMatrix, camera_position.x, camera_position.y, camera_position.z-300);
result = result && SunRender(*m_skybox, ident, translationMatrix, ident);
// Turn the Z buffer and back culling on now that skybox is rendered.
m_D3D->TurnZBufferOn();
m_D3D->TurnOnBackCulling();
// Render planets
ModelClass* planet_model(0);
m_sun->GetModel(planet_model);
result = result && SunRender(*planet_model, m_sun->GetScale(), m_sun->GetTranslate(),
m_sun->GetRotate());
m_mercury->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_mercury->GetScale(), m_mercury->GetTranslate(),
m_mercury->GetRotate());
m_venus->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_venus->GetScale(), m_venus->GetTranslate(),
m_venus->GetRotate());
m_earth->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_earth->GetScale(), m_earth->GetTranslate(),
m_earth->GetRotate());
m_mars->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_mars->GetScale(), m_mars->GetTranslate(),
m_mars->GetRotate());
m_jupiter->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_jupiter->GetScale(), m_jupiter->GetTranslate(),
m_jupiter->GetRotate());
m_saturn->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_saturn->GetScale(), m_saturn->GetTranslate(),
m_saturn->GetRotate());
m_uranus->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_uranus->GetScale(), m_uranus->GetTranslate(),
m_uranus->GetRotate());
m_neptune->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_neptune->GetScale(), m_neptune->GetTranslate(),
m_neptune->GetRotate());
m_halley->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_halley->GetScale(), m_halley->GetTranslate(),
m_halley->GetRotate());
m_luna->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_luna->GetScale(), m_luna->GetTranslate(),
m_luna->GetRotate());
m_phobos->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_phobos->GetScale(), m_phobos->GetTranslate(),
m_phobos->GetRotate());
m_deimos->GetModel(planet_model);
result = result && ModelRender(*planet_model, m_deimos->GetScale(), m_deimos->GetTranslate(),
m_deimos->GetRotate());
// Turn on alpha blending.
m_D3D->TurnOnAlphaBlending();
// Put the particle system vertex and index buffers on the graphics pipeline to prepare them for drawing.
m_ParticleSystem->Render(m_D3D->GetDeviceContext());
// Render the particles using the texture shader.
D3DXMatrixIdentity(&worldMatrix);
result = m_ParticleShader->Render(m_D3D->GetDeviceContext(), m_ParticleSystem->GetIndexCount(), worldMatrix, viewMatrix, projectionMatrix,
m_ParticleSystem->GetTexture());
if(!result)
{
return false;
}
// Turn off alpha blending.
m_D3D->TurnOffAlphaBlending();
// Turn off the Z buffer to begin all 2D rendering.
m_D3D->TurnZBufferOff();
// Turn on the alpha blending before rendering the text.
m_D3D->TurnOnAlphaBlending();
// BITMAP rendering
result = result && BitmapRender(*crosshairs, mouseX-30, mouseY-25);
result = result && BitmapRender(*HUD, 0, 0);
// TEXT rendering
result = m_Text->Render(m_D3D->GetDeviceContext(), worldMatrix, orthoMatrix);
if(!result)
{
return false;
}
// Turn off alpha blending after rendering the text.
m_D3D->TurnOffAlphaBlending();
// TITLE SCREEN rendering
if (m_screen == 0) result = result && BitmapRender(*m_titleScreen, 0, 0);
if (m_screen == 1) result = result && BitmapRender(*m_controlsScreen, 0, 0);
// Turn the Z buffer back on now that all 2D rendering has completed.
m_D3D->TurnZBufferOn();
// Perform closing actions
result = result && EndRender();
return result;
}
void DCRenderer::Draw(f32 fDeltaTime)
{
// For our world matrix, we will just rotate the object about the y-axis.
D3DXMATRIXA16 mxView, mxProj;
D3DXVECTOR3 vEye(0.0f, 5.0f,-5.0f);
D3DXVECTOR3 vAt(0.0f,0.0f,1.0f);
D3DXVECTOR3 vUp(0.0f,1.0f,0.0f);
float fAspectRatio = m_pRenderWidget->width() / (FLOAT)m_pRenderWidget->height();
D3DXMatrixLookAtLH(&mxView, &vEye, &vAt, &vUp);
D3DXMatrixPerspectiveFovLH(&mxProj, D3DX_PI/3, fAspectRatio, 0.001f, 100.0f);
//models
// For our world matrix, we will just rotate the object about the y-axis.
D3DXMATRIXA16 mxWorld, mxViewProj;
D3DXMatrixIdentity(&mxViewProj);
BM_AssertHr(DEVICEPTR->BeginScene());
{
BeginRender();
DEVICEPTR->Clear( 0, NULL, D3DCLEAR_TARGET | D3DCLEAR_ZBUFFER,D3DCOLOR_COLORVALUE(85.0f/255.0f,101.0f/255.0f,215.0f/255.0f,1.0f), 1.0f, 0 );
BM_AssertHr(DEVICEPTR->EndScene());
//models
const std::vector<BatchNode>& nodes = BatchNodes;
const u32 nodeNum = nodes.size();
for(u32 nodeIdx = 0; nodeIdx<nodeNum; nodeIdx++)
{
BM_AssertHr(DEVICEPTR->BeginScene());
const BatchNode& nodePtrRef = nodes[nodeIdx];
const XMFLOAT3& translation = nodePtrRef.translation;
D3DXMatrixTranslation(&mxWorld, translation.x, translation.y, translation.z);
mxViewProj = mxView * mxProj;
DEVICEPTR->SetVertexShaderConstantF(0,(float*)&(mxWorld),4);
DEVICEPTR->SetVertexShaderConstantF(4,(float*)mViewProjMatrix,4);
DEVICEPTR->SetRenderState(D3DRS_CULLMODE, D3DCULL_NONE);
DEVICEPTR->SetRenderState(D3DRS_ZENABLE, D3DZB_TRUE);
nodePtrRef.model->Draw(0);
BM_AssertHr(DEVICEPTR->EndScene());
}
BM_AssertHr(DEVICEPTR->BeginScene());
//terrain
if(TerrainPtr)
{
TerrainPtr->Draw(&mxWorld, (D3DXMATRIXA16*)mViewMatrix, (D3DXMATRIXA16*)mProjMatrix);
}
BMPostFXRenderer::GetInstance()->Render();
EndRender();
BM_AssertHr(DEVICEPTR->EndScene());
}
BatchNodes.clear();
}
// Convenience method to render a single copy of a geometry.
inline void RenderSimpleGeom(glm::mat4* mvpMat, SimpleGeom *sg) {
BeginRender(sg->vbuf);
Render(sg->ibuf, mvpMat);
EndRender();
}
