void D2DComponent::BeginDraw(Windows::Foundation::Rect updateRect)
{
Microsoft::WRL::ComPtr<IDXGISurface> surface;
POINT offset;
RECT updateRectNative =
{
(LONG)updateRect.Left,
(LONG)updateRect.Top,
(LONG)updateRect.Right,
(LONG)updateRect.Bottom
};
HRESULT beginDrawHR = _sisNative->BeginDraw(updateRectNative, &surface, &offset);
if (beginDrawHR == DXGI_ERROR_DEVICE_REMOVED || beginDrawHR == DXGI_ERROR_DEVICE_RESET)
{
CreateDeviceResources();
BeginDraw(updateRect);
}
else
{
ThrowIfFailed(beginDrawHR);
}
Microsoft::WRL::ComPtr<ID2D1Bitmap1> bitmap;
ThrowIfFailed(_d2dDeviceContext->CreateBitmapFromDxgiSurface(surface.Get(), nullptr, &bitmap));
_d2dDeviceContext->BeginDraw();
_d2dDeviceContext->SetTarget(bitmap.Get());
}
void Model::CreatePipelineState()
{
Microsoft::WRL::ComPtr<ID3DBlob> VertexShader;
Microsoft::WRL::ComPtr<ID3DBlob> PixelShader;
LoadAndCompileShader(VertexShader, PixelShader);
std::array<D3D12_INPUT_ELEMENT_DESC, 2> InputElementDesc
{ {
{ "POSITION", 0, DXGI_FORMAT_R32G32B32_FLOAT, 0, 0, D3D12_INPUT_CLASSIFICATION_PER_VERTEX_DATA, 0 },
{ "COLOR", 0, DXGI_FORMAT_R32G32B32A32_FLOAT, 0, 12, D3D12_INPUT_CLASSIFICATION_PER_VERTEX_DATA, 0 }
} };
D3D12_GRAPHICS_PIPELINE_STATE_DESC PipelineStateDesc = {};
PipelineStateDesc.InputLayout = { InputElementDesc.data(), static_cast<UINT>(InputElementDesc.size()) };
PipelineStateDesc.pRootSignature = RootSignature.Get();
PipelineStateDesc.VS = CD3DX12_SHADER_BYTECODE(VertexShader.Get());
PipelineStateDesc.PS = CD3DX12_SHADER_BYTECODE(PixelShader.Get());
PipelineStateDesc.RasterizerState = CD3DX12_RASTERIZER_DESC(D3D12_DEFAULT);
PipelineStateDesc.BlendState = CD3DX12_BLEND_DESC(D3D12_DEFAULT);
PipelineStateDesc.DepthStencilState = CD3DX12_DEPTH_STENCIL_DESC(D3D12_DEFAULT);
PipelineStateDesc.SampleMask = UINT_MAX;
PipelineStateDesc.SampleDesc.Count = 1;
PipelineStateDesc.NumRenderTargets = 1;
PipelineStateDesc.RTVFormats[0] = DXGI_FORMAT_R8G8B8A8_UNORM;
PipelineStateDesc.DSVFormat = DXGI_FORMAT_D32_FLOAT;
PipelineStateDesc.PrimitiveTopologyType = D3D12_PRIMITIVE_TOPOLOGY_TYPE_TRIANGLE;
Utility::ThrowOnFail(DeviceContext.GetDevice()->CreateGraphicsPipelineState(&PipelineStateDesc, IID_PPV_ARGS(&PipelineState)));
}
void glClear(GLbitfield mask)
{
if( g_pD3DContext )
{
g_pD3DContext->ClearRenderTargetView( g_pD3DRenderTargetView.Get(), g_ClearColor );
g_pD3DContext->ClearDepthStencilView( g_pD3DDepthStencilView.Get(), D3D11_CLEAR_DEPTH, 1.0f, 0 );
}
}
bool Shape::CombineWith(Shape* otherShape, D2D1_COMBINE_MODE mode)
{
Microsoft::WRL::ComPtr<ID2D1GeometrySink> sink;
Microsoft::WRL::ComPtr<ID2D1PathGeometry> path;
HRESULT hr = Canvas::c_D2DFactory->CreatePathGeometry(path.GetAddressOf());
if (FAILED(hr)) return false;
hr = path->Open(sink.GetAddressOf());
if (FAILED(hr)) return false;
if (otherShape)
{
hr = m_Shape->CombineWithGeometry(
otherShape->m_Shape.Get(),
mode,
otherShape->GetShapeMatrix(),
sink.Get());
if (FAILED(hr)) return false;
sink->Close();
hr = path.CopyTo(m_Shape.ReleaseAndGetAddressOf());
if (FAILED(hr)) return false;
return true;
}
static const D2D1_RECT_F rect = { 0.0f, 0.0f, 0.0f, 0.0f };
Microsoft::WRL::ComPtr<ID2D1RectangleGeometry> emptyShape;
hr = Canvas::c_D2DFactory->CreateRectangleGeometry(rect, emptyShape.GetAddressOf());
if (FAILED(hr)) return false;
hr = emptyShape->CombineWithGeometry(m_Shape.Get(), mode, GetShapeMatrix(), sink.Get());
sink->Close();
if (FAILED(hr)) return false;
hr = path.CopyTo(m_Shape.ReleaseAndGetAddressOf());
if (FAILED(hr)) return false;
m_Rotation = 0.0f;
m_RotationAnchor = D2D1::Point2F();
m_RotationAnchorDefined = false;
m_Scale = D2D1::SizeF(1.0f, 1.0f);
m_ScaleAnchor = D2D1::Point2F();
m_ScaleAnchorDefined = false;
m_Skew = D2D1::Point2F();
m_SkewAnchor = D2D1::Point2F();
m_SkewAnchorDefined = false;
m_Offset = D2D1::SizeF(0.0f, 0.0f);
return true;
}
IFACEMETHODIMP CustomTextRenderer::DrawStrikethrough(
_In_opt_ void* clientDrawingContext,
FLOAT baselineOriginX,
FLOAT baselineOriginY,
_In_ DWRITE_STRIKETHROUGH const* strikethrough,
IUnknown* clientDrawingEffect
)
{
HRESULT hr;
D2D1_RECT_F rect = D2D1::RectF(
0,
strikethrough->offset,
strikethrough->width,
strikethrough->offset + strikethrough->thickness
);
Microsoft::WRL::ComPtr<ID2D1RectangleGeometry> rectangleGeometry;
hr = D2DFactory.Get()->CreateRectangleGeometry(
&rect,
&rectangleGeometry
);
// Initialize a matrix to translate the origin of the strikethrough
D2D1::Matrix3x2F const matrix = D2D1::Matrix3x2F(
1.0f, 0.0f,
0.0f, 1.0f,
baselineOriginX, baselineOriginY
);
Microsoft::WRL::ComPtr<ID2D1TransformedGeometry> transformedGeometry;
if (SUCCEEDED(hr))
{
hr = D2DFactory.Get()->CreateTransformedGeometry(
rectangleGeometry.Get(),
&matrix,
&transformedGeometry
);
}
// Draw the outline of the rectangle
D2DDeviceContext.Get()->DrawGeometry(
transformedGeometry.Get(),
outlineBrush.Get()
);
// Fill in the rectangle
D2DDeviceContext.Get()->FillGeometry(
transformedGeometry.Get(),
fillBrush.Get()
);
return S_OK;
}
Microsoft::WRL::ComPtr<ID3D12Resource> Renderer::UploadIndexData(void *data, long dataSize)
{
WaitForGpu();
// Command list allocators can only be reset when the associated
// command lists have finished execution on the GPU; apps should use
// fences to determine GPU execution progress.
ThrowIfFailed(_commandAllocators[_frameIndex]->Reset());
// However, when ExecuteCommandList() is called on a particular command
// list, that command list can then be reset at any time and must be before
// re-recording.
ThrowIfFailed(_commandList->Reset(_commandAllocators[_frameIndex].Get(), NULL));
Microsoft::WRL::ComPtr<ID3D12Resource> indexBuffer;
Microsoft::WRL::ComPtr<ID3D12Resource> indexBufferUpload;
ThrowIfFailed(_device->CreateCommittedResource(
&CD3DX12_HEAP_PROPERTIES(D3D12_HEAP_TYPE_DEFAULT),
D3D12_HEAP_FLAG_NONE,
&CD3DX12_RESOURCE_DESC::Buffer(dataSize),
D3D12_RESOURCE_STATE_COPY_DEST,
nullptr,
IID_PPV_ARGS(&indexBuffer)));
ThrowIfFailed(_device->CreateCommittedResource(
&CD3DX12_HEAP_PROPERTIES(D3D12_HEAP_TYPE_UPLOAD),
D3D12_HEAP_FLAG_NONE,
&CD3DX12_RESOURCE_DESC::Buffer(dataSize),
D3D12_RESOURCE_STATE_GENERIC_READ,
nullptr,
IID_PPV_ARGS(&indexBufferUpload)));
// Copy data to the intermediate upload heap and then schedule a copy
// from the upload heap to the vertex buffer.
UINT8* pIndexDataBegin;
ThrowIfFailed(indexBufferUpload->Map(0, &CD3DX12_RANGE(0, dataSize), reinterpret_cast<void**>(&pIndexDataBegin)));
memcpy(pIndexDataBegin, data, dataSize);
indexBufferUpload->Unmap(0, nullptr);
_commandList->CopyBufferRegion(indexBuffer.Get(), 0, indexBufferUpload.Get(), 0, dataSize);
_commandList->ResourceBarrier(1, &CD3DX12_RESOURCE_BARRIER::Transition(indexBuffer.Get(), D3D12_RESOURCE_STATE_COPY_DEST, D3D12_RESOURCE_STATE_INDEX_BUFFER));
// Close the command list and execute it to begin the vertex buffer copy into
// the default heap.
ThrowIfFailed(_commandList->Close());
ID3D12CommandList* ppCommandLists[] = { _commandList.Get() };
_commandQueue->ExecuteCommandLists(_countof(ppCommandLists), ppCommandLists);
WaitForGpu();
return indexBuffer;
}
EncodedJSValue JSC_HOST_CALL COMMethodCall::call(ExecState* execState) {
COMMethodCall* callee = jsCast<COMMethodCall*>(execState->callee());
if (execState->argumentCount() != callee->_parameterCells.size()) {
// TODO: error
CRASH();
}
COMInterop* interop = jsCast<GlobalObject*>(execState->lexicalGlobalObject())->interop();
size_t numberOfABIParameters = callee->_parameterCells.size() + (callee->_isVoid ? 1 : 2);
HRESULT hr;
Microsoft::WRL::ComPtr<IUnknown> self;
hr = interop->wrap(execState->thisValue(), callee->_methodInterface, self.GetAddressOf());
void** vtable = *reinterpret_cast<void***>(self.Get());
void* fn = vtable[callee->_methodIndex];
WTF::Vector<void*> arguments;
arguments.reserveCapacity(numberOfABIParameters);
IUnknown* thisValue = self.Get();
arguments.append(&thisValue);
for (int i = 0; i < callee->_parameterCells.size(); i++) {
JSCell* type = callee->_parameterCells[i].get();
void* buffer = _alloca(std::max(sizeof(ffi_arg), callee->_parameterTypes[i + 1]->size));
getFFIMethodTable(type)->marshalJSToNative(type, execState, execState->uncheckedArgument(i), buffer);
arguments.append(buffer);
}
void* returnBuffer = nullptr;
if (!callee->_isVoid) {
returnBuffer = _alloca(std::max(sizeof(ffi_arg), callee->_parameterTypes[numberOfABIParameters - 1]->size));
arguments.append(&returnBuffer);
}
ffi_call(&callee->_cif, FFI_FN(fn), &hr, arguments.data());
JSValue jsResult;
if (!SUCCEEDED(hr)) {
_com_error error(hr, nullptr);
jsResult = execState->vm().throwException(execState, createError(execState, error.ErrorMessage()));
} else if (!callee->_isVoid) {
JSCell* returnType = callee->_returnType.get();
jsResult = getFFIMethodTable(returnType)->marshalNativeToJS(returnType, execState, returnBuffer);
} else {
jsResult = jsUndefined();
}
return JSValue::encode(jsResult);
}
void UpdateDepthState()
{
if( g_DepthTestEnabled == true && g_DepthMaskEnabled == true )
g_pD3DContext->OMSetDepthStencilState( g_pD3DDepthStencilState_DepthTestEnabled_DepthWriteEnabled.Get(), 1 );
else if( g_DepthTestEnabled == false && g_DepthMaskEnabled == true )
g_pD3DContext->OMSetDepthStencilState( g_pD3DDepthStencilState_DepthTestDisabled_DepthWriteEnabled.Get(), 1 );
else if( g_DepthTestEnabled == true && g_DepthMaskEnabled == false )
g_pD3DContext->OMSetDepthStencilState( g_pD3DDepthStencilState_DepthTestEnabled_DepthWriteDisabled.Get(), 1 );
else if( g_DepthTestEnabled == false && g_DepthMaskEnabled == false )
g_pD3DContext->OMSetDepthStencilState( g_pD3DDepthStencilState_DepthTestDisabled_DepthWriteDisabled.Get(), 1 );
}
// Callbacks to draw things in world space, left-hand space, and right-hand
// space.
void DrawWorld(
void* userData //< Passed into AddRenderCallback
,
osvr::renderkit::GraphicsLibrary library //< Graphics library context to use
,
osvr::renderkit::RenderBuffer buffers //< Buffers to use
,
osvr::renderkit::OSVR_ViewportDescription
viewport //< Viewport we're rendering into
,
OSVR_PoseState pose //< OSVR ModelView matrix set by RenderManager
,
osvr::renderkit::OSVR_ProjectionMatrix
projection //< Projection matrix set by RenderManager
,
OSVR_TimeValue deadline //< When the frame should be sent to the screen
) {
// Make sure our pointers are filled in correctly.
if (library.D3D11 == nullptr) {
std::cerr
<< "DrawWorld: No D3D11 GraphicsLibrary, this should not happen"
<< std::endl;
return;
}
if (buffers.D3D11 == nullptr) {
std::cerr << "DrawWorld: No D3D11 RenderBuffer, this should not happen"
<< std::endl;
return;
}
ID3D11DeviceContext* context = library.D3D11->context;
ID3D11RenderTargetView* renderTargetView = buffers.D3D11->colorBufferView;
// Set vertex buffer
UINT stride = sizeof(SimpleVertex);
UINT offset = 0;
context->IASetVertexBuffers(0, 1, &g_vertexBuffer, &stride, &offset);
// Set primitive topology
context->IASetPrimitiveTopology(D3D11_PRIMITIVE_TOPOLOGY_TRIANGLELIST);
// Set depth/stencil state
context->OMSetDepthStencilState(g_depthStencilState, 1);
// Draw a triangle using the simple shaders
context->VSSetShader(vertexShader.Get(), nullptr, 0);
context->PSSetShader(pixelShader.Get(), nullptr, 0);
context->Draw(3, 0);
}
void Draw(const Microsoft::WRL::ComPtr<ID3D11DeviceContext> &pDeviceContext)
{
// VBのセット
ID3D11Buffer* pBufferTbl[] = { m_pVertexBuf.Get() };
UINT SizeTbl[] = { sizeof(Vertex) };
UINT OffsetTbl[] = { 0 };
pDeviceContext->IASetVertexBuffers(0, 1, pBufferTbl, SizeTbl, OffsetTbl);
// IBのセット
pDeviceContext->IASetIndexBuffer(m_pIndexBuf.Get(), DXGI_FORMAT_R32_UINT, 0);
// プリミティブタイプのセット
pDeviceContext->IASetPrimitiveTopology(D3D11_PRIMITIVE_TOPOLOGY_TRIANGLELIST);
pDeviceContext->DrawIndexed(m_indices // index count
, 0, 0);
}
ID3D11DepthStencilView* CreateDepthStencilView(ID3D11Device* pDevice,DWORD dwWidth, DWORD dwHeight)
{
HRESULT hr;
ID3D11DepthStencilView* pDSV = nullptr;
Microsoft::WRL::ComPtr<ID3D11Texture2D> pDSTexture = nullptr;
D3D11_TEXTURE2D_DESC DescDepth;
DescDepth.Width = dwWidth;
DescDepth.Height = dwHeight;
DescDepth.MipLevels = 1;
DescDepth.ArraySize = 1;
DescDepth.Format = DXGI_FORMAT_D24_UNORM_S8_UINT;
DescDepth.SampleDesc.Count = 1;
DescDepth.SampleDesc.Quality = 0;
DescDepth.Usage = D3D11_USAGE_DEFAULT;
DescDepth.BindFlags = D3D11_BIND_DEPTH_STENCIL;
DescDepth.CPUAccessFlags = 0;
DescDepth.MiscFlags = 0;
if (FAILED(hr = pDevice->CreateTexture2D(&DescDepth, NULL, &pDSTexture)))
{
return nullptr;
}
D3D11_DEPTH_STENCIL_VIEW_DESC dsvd;
ZeroMemory(&dsvd, sizeof(dsvd));
dsvd.Format = DescDepth.Format;
dsvd.ViewDimension = D3D11_DSV_DIMENSION_TEXTURE2D;
dsvd.Texture2D.MipSlice = 0;
if (FAILED(hr = pDevice->CreateDepthStencilView(
pDSTexture.Get(), &dsvd, &pDSV)))
{
return nullptr;
}
return pDSV;
}
void FlowLayoutSink::SetGlyphRun(
float x,
float y,
UINT32 glyphCount,
const UINT16* glyphIndices, // [glyphCount]
const float* glyphAdvances, // [glyphCount]
const DWRITE_GLYPH_OFFSET* glyphOffsets, // [glyphCount]
Microsoft::WRL::ComPtr<IDWriteFontFace> fontFace,
float fontEmSize,
UINT8 glyphOrientation,
bool isReversed,
bool isSideways
)
{
// Append this glyph run to the list.
m_glyphRuns.resize(m_glyphRuns.size() + 1);
CustomGlyphRun& glyphRun = m_glyphRuns.back();
UINT32 glyphStart = static_cast<UINT32>(m_glyphAdvances.size());
m_glyphIndices.insert (m_glyphIndices.end(), glyphIndices, glyphIndices + glyphCount);
m_glyphAdvances.insert(m_glyphAdvances.end(), glyphAdvances, glyphAdvances + glyphCount);
m_glyphOffsets.insert (m_glyphOffsets.end(), glyphOffsets, glyphOffsets + glyphCount);
glyphRun.x = x;
glyphRun.y = y;
glyphRun.glyphOrientation = glyphOrientation;
glyphRun.glyphStart = glyphStart;
glyphRun.isSideways = isSideways;
glyphRun.isReversed = isReversed;
glyphRun.glyphCount = glyphCount;
glyphRun.fontEmSize = fontEmSize;
glyphRun.fontFace = fontFace.Get();
}
ID3D12DescriptorHeap* DynamicDescriptorHeap::RequestDescriptorHeap(void)
{
std::lock_guard<std::mutex> LockGuard(sm_Mutex);
while (!sm_RetiredDescriptorHeaps.empty() && g_CommandManager.IsFenceComplete(sm_RetiredDescriptorHeaps.front().first))
{
sm_AvailableDescriptorHeaps.push(sm_RetiredDescriptorHeaps.front().second);
sm_RetiredDescriptorHeaps.pop();
}
if (!sm_AvailableDescriptorHeaps.empty())
{
ID3D12DescriptorHeap* HeapPtr = sm_AvailableDescriptorHeaps.front();
sm_AvailableDescriptorHeaps.pop();
return HeapPtr;
}
else
{
D3D12_DESCRIPTOR_HEAP_DESC HeapDesc = {};
HeapDesc.Type = D3D12_DESCRIPTOR_HEAP_TYPE_CBV_SRV_UAV;
HeapDesc.NumDescriptors = kNumDescriptorsPerHeap;
HeapDesc.Flags = D3D12_DESCRIPTOR_HEAP_FLAG_SHADER_VISIBLE;
HeapDesc.NodeMask = 1;
Microsoft::WRL::ComPtr<ID3D12DescriptorHeap> HeapPtr;
ASSERT_SUCCEEDED(g_Device->CreateDescriptorHeap(&HeapDesc, MY_IID_PPV_ARGS(&HeapPtr)));
sm_DescriptorHeapPool.emplace_back(HeapPtr);
return HeapPtr.Get();
}
}
void Model::Create()
{
CreateRootSignature();
CreatePipelineState();
Microsoft::WRL::ComPtr<ID3D12CommandAllocator> CommandAllocator;
Microsoft::WRL::ComPtr<ID3D12GraphicsCommandList> CommandList;
Microsoft::WRL::ComPtr<ID3D12Resource> VertexUploadResource;
Microsoft::WRL::ComPtr<ID3D12Resource> IndexUploadResource;
GPUFence Fence;
Fence.Initialize(DeviceContext.GetDevice());
Utility::ThrowOnFail(DeviceContext.GetDevice()->CreateCommandAllocator(D3D12_COMMAND_LIST_TYPE_DIRECT, IID_PPV_ARGS(&CommandAllocator)));
Utility::ThrowOnFail(DeviceContext.GetDevice()->CreateCommandList(0, D3D12_COMMAND_LIST_TYPE_DIRECT, CommandAllocator.Get(), nullptr, IID_PPV_ARGS(&CommandList)));
UploadVertices(CommandList, VertexUploadResource);
UploadIndices(CommandList, IndexUploadResource);
Utility::ThrowOnFail(CommandList->Close());
ID3D12CommandList * CommandListPointer = CommandList.Get();
DeviceContext.GetCommandQueue()->ExecuteCommandLists(1, &CommandListPointer);
Fence.SetAndWait(DeviceContext.GetCommandQueue());
}
HRESULT Sample2DSceneRenderer::CreateBitmapBrush(PCWSTR uri, ID2D1BitmapBrush **ppBitmapBrush)
{
Microsoft::WRL::ComPtr<ID2D1Bitmap> ppBitmap;
auto hr = LoadBitmapFromFile(m_deviceResources.get(), uri, &ppBitmap);
auto context = m_deviceResources->GetD2DDeviceContext();
hr = context->CreateBitmapBrush(ppBitmap.Get(), &m_pBitmapBrush);
return hr;
}
void PrimitveDrawer::End()
{
Microsoft::WRL::ComPtr<ID3D11RasterizerState> pRSState;
m_pContext->RSGetState(&pRSState);
m_pContext->RSSetState(m_pStates->CullClockwise());
m_pDirectXBatch->End();
m_pContext->RSSetState(pRSState.Get());
}
void MazeWallObstacle::Render( Microsoft::WRL::ComPtr<ID2D1DeviceContext> & d2dContext ) const
{
Microsoft::WRL::ComPtr<ID2D1SolidColorBrush> brush;
DX::ThrowIfFailed(d2dContext->CreateSolidColorBrush(D2D1::ColorF(D2D1::ColorF::Black), &brush));
D2D1_POINT_2F const pt1 = {(float)m_pt1.m_x, (float)m_pt1.m_y};
D2D1_POINT_2F const pt2 = {(float)m_pt2.m_x, (float)m_pt2.m_y};
d2dContext->DrawLine(pt1, pt2, brush.Get());
}
void DXWrapper_InitDeviceAndContext( Microsoft::WRL::ComPtr<ID3D11Device1> pDevice,
Microsoft::WRL::ComPtr<ID3D11DeviceContext1> pContext,
Microsoft::WRL::ComPtr<ID3D11RenderTargetView> pRenderTargetView,
Microsoft::WRL::ComPtr<ID3D11DepthStencilView> pDepthStencilView )
{
g_pD3DDevice = pDevice;
g_pD3DContext = pContext;
g_pD3DRenderTargetView = pRenderTargetView;
g_pD3DDepthStencilView = pDepthStencilView;
g_pD3DContext->OMSetRenderTargets( 1, g_pD3DRenderTargetView.GetAddressOf(), g_pD3DDepthStencilView.Get() );
D3DCreateDepthStencilStates();
D3DCreateSamplerStates();
D3DCreateBlendStates();
float blendfactor[4] = { 1.0f, 1.0f, 1.0f, 1.0f };
g_pD3DContext->OMSetBlendState( g_pD3DBlendStateEnabled.Get(), blendfactor, 0xfff );
UpdateDepthState();
}
static inline HRESULT CreateMemoryStream( _Outptr_ IStream** stream )
{
Microsoft::WRL::ComPtr<ABI::Windows::Storage::Streams::IRandomAccessStream> abiStream;
HRESULT hr = Windows::Foundation::ActivateInstance(
Microsoft::WRL::Wrappers::HStringReference( RuntimeClass_Windows_Storage_Streams_InMemoryRandomAccessStream ).Get(),
abiStream.GetAddressOf() );
if (SUCCEEDED(hr))
{
hr = CreateStreamOverRandomAccessStream( abiStream.Get(), IID_PPV_ARGS( stream ) );
}
return hr;
}
Microsoft::WRL::ComPtr<ID3D12Resource> d3dUtil::CreateDefaultBuffer(
ID3D12Device* device,
ID3D12GraphicsCommandList* cmdList,
const void* initData,
UINT64 byteSize,
Microsoft::WRL::ComPtr<ID3D12Resource>& uploadBuffer)
{
ComPtr<ID3D12Resource> defaultBuffer;
// Create the actual default buffer resource.
ThrowIfFailed(device->CreateCommittedResource(
&CD3DX12_HEAP_PROPERTIES(D3D12_HEAP_TYPE_DEFAULT),
D3D12_HEAP_FLAG_NONE,
&CD3DX12_RESOURCE_DESC::Buffer(byteSize),
D3D12_RESOURCE_STATE_COMMON,
nullptr,
IID_PPV_ARGS(defaultBuffer.GetAddressOf())));
// In order to copy CPU memory data into our default buffer, we need to create
// an intermediate upload heap.
ThrowIfFailed(device->CreateCommittedResource(
&CD3DX12_HEAP_PROPERTIES(D3D12_HEAP_TYPE_UPLOAD),
D3D12_HEAP_FLAG_NONE,
&CD3DX12_RESOURCE_DESC::Buffer(byteSize),
D3D12_RESOURCE_STATE_GENERIC_READ,
nullptr,
IID_PPV_ARGS(uploadBuffer.GetAddressOf())));
// Describe the data we want to copy into the default buffer.
D3D12_SUBRESOURCE_DATA subResourceData ={};
subResourceData.pData = initData;
subResourceData.RowPitch = byteSize;
subResourceData.SlicePitch = subResourceData.RowPitch;
// Schedule to copy the data to the default buffer resource. At a high level, the helper function UpdateSubresources
// will copy the CPU memory into the intermediate upload heap. Then, using ID3D12CommandList::CopySubresourceRegion,
// the intermediate upload heap data will be copied to mBuffer.
cmdList->ResourceBarrier(1, &CD3DX12_RESOURCE_BARRIER::Transition(defaultBuffer.Get(),
D3D12_RESOURCE_STATE_COMMON, D3D12_RESOURCE_STATE_COPY_DEST));
UpdateSubresources<1>(cmdList, defaultBuffer.Get(), uploadBuffer.Get(), 0, 0, 1, &subResourceData);
cmdList->ResourceBarrier(1, &CD3DX12_RESOURCE_BARRIER::Transition(defaultBuffer.Get(),
D3D12_RESOURCE_STATE_COPY_DEST, D3D12_RESOURCE_STATE_GENERIC_READ));
// Note: uploadBuffer has to be kept alive after the above function calls because
// the command list has not been executed yet that performs the actual copy.
// The caller can Release the uploadBuffer after it knows the copy has been executed.
return defaultBuffer;
}
void TextInlineFormat_Color::ApplyInlineFormat(ID2D1RenderTarget* target, IDWriteTextLayout* layout)
{
if (!target || !layout) return;
Microsoft::WRL::ComPtr<ID2D1SolidColorBrush> solidBrush;
HRESULT hr = target->CreateSolidColorBrush(ToColorF(m_Color), solidBrush.GetAddressOf());
if (FAILED(hr)) return;
for (const auto& range : GetRanges())
{
if (range.length <= 0) continue;
layout->SetDrawingEffect(solidBrush.Get(), range);
}
}
ID3D12DescriptorHeap* DescriptorAllocator::RequestNewHeap(DeviceManager* deviceManager, D3D12_DESCRIPTOR_HEAP_TYPE Type)
{
std::lock_guard<std::mutex> LockGuard(s_allocationMutex);
D3D12_DESCRIPTOR_HEAP_DESC Desc;
Desc.Type = Type;
Desc.NumDescriptors = s_numDescriptorsPerHeap;
Desc.Flags = D3D12_DESCRIPTOR_HEAP_FLAG_NONE;
Desc.NodeMask = 1;
Microsoft::WRL::ComPtr<ID3D12DescriptorHeap> pHeap;
assert(S_OK == deviceManager->GetDevice()->CreateDescriptorHeap(&Desc, IID_PPV_ARGS(&pHeap)));
s_descriptorHeapPool.emplace_back(pHeap);
return pHeap.Get();
}
STDMETHODIMP TextAnalysis::GenerateResults(
Microsoft::WRL::ComPtr<IDWriteTextAnalyzer1> textAnalyzer,
_Out_ std::vector<TextAnalysis::Run>& runs,
_Out_ std::vector<DWRITE_LINE_BREAKPOINT>& breakpoints
)
{
// Analyzes the text using each of the analyzers and returns
// their results as a series of runs.
HRESULT hr = S_OK;
// Initially start out with one result that covers the entire range.
// This result will be subdivided by the analysis processes.
m_runs.resize(1);
LinkedRun& initialRun = m_runs[0];
initialRun.nextRunIndex = 0;
initialRun.textStart = 0;
initialRun.textLength = m_textLength;
initialRun.bidiLevel = (m_readingDirection & ReadingDirectionPrimaryProgression) != 0;
// Allocate enough room to have one breakpoint per code unit.
m_breakpoints.resize(m_textLength);
// Call each of the analyzers in sequence, recording their results.
if (SUCCEEDED(hr = textAnalyzer->AnalyzeLineBreakpoints(this, 0, m_textLength, this))
&& SUCCEEDED(hr = AnalyzeBidi(textAnalyzer.Get(), this, 0, m_textLength, this))
&& SUCCEEDED(hr = textAnalyzer->AnalyzeScript(this, 0, m_textLength, this))
&& SUCCEEDED(hr = textAnalyzer->AnalyzeNumberSubstitution(this, 0, m_textLength, this))
&& SUCCEEDED(hr = AnalyzeGlyphOrientation(textAnalyzer, this, 0, m_textLength, this))
)
{
// Exchange our results with the caller's.
breakpoints.swap(m_breakpoints);
// Resequence the resulting runs in order before returning to caller.
size_t totalRuns = m_runs.size();
runs.resize(totalRuns);
UINT32 nextRunIndex = 0;
for (size_t i = 0; i < totalRuns; ++i)
{
runs[i] = m_runs[nextRunIndex];
nextRunIndex = m_runs[nextRunIndex].nextRunIndex;
}
}
return hr;
}
void TextureManager::LoadTextures(const std::vector<std::string>& TexturesLocation)
{
for (std::string TextureLoc : TexturesLocation)
{
const std::string &fixed = "..\\examples\\assets\\" + TextureLoc.substr(0, TextureLoc.find_last_of('.')) + ".DDS";
std::ifstream DDSFile(fixed, std::ifstream::binary);
irr::video::CImageLoaderDDS DDSPic(DDSFile);
#ifdef GLBUILD
WrapperResource *res = (WrapperResource*)malloc(sizeof(WrapperResource));
// TODO : clean it
GLTexture *tmptexture = new GLTexture(DDSPic.getLoadedImage());
res->GLValue.Resource = tmptexture->Id;
res->GLValue.Type = GL_TEXTURE_2D;
#endif
#ifdef DXBUILD
D3DTexture TextureInRam(DDSPic.getLoadedImage());
WrapperResource *res = (WrapperResource*)malloc(sizeof(WrapperResource));
HRESULT hr = Context::getInstance()->dev->CreateCommittedResource(
&CD3D12_HEAP_PROPERTIES(D3D12_HEAP_TYPE_DEFAULT),
D3D12_HEAP_MISC_NONE,
&CD3D12_RESOURCE_DESC::Tex2D(TextureInRam.getFormat(), (UINT)TextureInRam.getWidth(), (UINT)TextureInRam.getHeight(), 1, (UINT16)TextureInRam.getMipLevelsCount()),
D3D12_RESOURCE_USAGE_GENERIC_READ,
nullptr,
IID_PPV_ARGS(&res->D3DValue.resource)
);
Microsoft::WRL::ComPtr<ID3D12CommandAllocator> cmdalloc;
Context::getInstance()->dev->CreateCommandAllocator(D3D12_COMMAND_LIST_TYPE_DIRECT, IID_PPV_ARGS(&cmdalloc));
Microsoft::WRL::ComPtr<ID3D12GraphicsCommandList> cmdlist;
Context::getInstance()->dev->CreateCommandList(1, D3D12_COMMAND_LIST_TYPE_DIRECT, cmdalloc.Get(), nullptr, IID_PPV_ARGS(&cmdlist));
TextureInRam.CreateUploadCommandToResourceInDefaultHeap(cmdlist.Get(), res->D3DValue.resource);
cmdlist->Close();
Context::getInstance()->cmdqueue->ExecuteCommandLists(1, (ID3D12CommandList**)cmdlist.GetAddressOf());
HANDLE handle = getCPUSyncHandle(Context::getInstance()->cmdqueue.Get());
res->D3DValue.description.TextureView.SRV = TextureInRam.getResourceViewDesc();
WaitForSingleObject(handle, INFINITE);
CloseHandle(handle);
#endif
textureSet.emplace(TextureLoc, res);
}
}
// Initialize the DirectX resources required to run.
void Graphics::Initialize(void)
{
ASSERT(s_SwapChain1 == nullptr, "Graphics has already been initialized");
Microsoft::WRL::ComPtr<ID3D12Device> pDevice;
#if _DEBUG
Microsoft::WRL::ComPtr<ID3D12Debug> debugInterface;
if (SUCCEEDED(D3D12GetDebugInterface(MY_IID_PPV_ARGS(&debugInterface))))
debugInterface->EnableDebugLayer();
else
Utility::Print("WARNING: Unable to enable D3D12 debug validation layer\n");
#endif
#ifdef DXIL
EnableExperimentalShaderModels();
#endif
// Obtain the DXGI factory
Microsoft::WRL::ComPtr<IDXGIFactory4> dxgiFactory;
ASSERT_SUCCEEDED(CreateDXGIFactory2(0, MY_IID_PPV_ARGS(&dxgiFactory)));
// Create the D3D graphics device
Microsoft::WRL::ComPtr<IDXGIAdapter1> pAdapter;
static const bool bUseWarpDriver = false;
if (!bUseWarpDriver)
{
SIZE_T MaxSize = 0;
for (uint32_t Idx = 0; DXGI_ERROR_NOT_FOUND != dxgiFactory->EnumAdapters1(Idx, &pAdapter); ++Idx)
{
DXGI_ADAPTER_DESC1 desc;
pAdapter->GetDesc1(&desc);
if (desc.Flags & DXGI_ADAPTER_FLAG_SOFTWARE)
continue;
if (desc.DedicatedVideoMemory > MaxSize && SUCCEEDED(D3D12CreateDevice(pAdapter.Get(), D3D_FEATURE_LEVEL_11_0, MY_IID_PPV_ARGS(&pDevice))))
{
pAdapter->GetDesc1(&desc);
Utility::Printf(L"D3D12-capable hardware found: %s (%u MB)\n", desc.Description, desc.DedicatedVideoMemory >> 20);
MaxSize = desc.DedicatedVideoMemory;
}
}
void RasterizeShadowRenderer::initialize(
int imageWidth,
int imageHeight,
Microsoft::WRL::ComPtr< ID3D11Device > device,
Microsoft::WRL::ComPtr< ID3D11DeviceContext > deviceContext )
{
m_device = device;
m_deviceContext = deviceContext;
m_imageWidth = imageWidth;
m_imageHeight = imageHeight;
createComputeTargets( imageWidth, imageHeight, *device.Get() );
loadAndCompileShaders( device );
m_initialized = true;
}
void CanvasD2D::FillRectangle(Gdiplus::Rect& rect, const Gdiplus::SolidBrush& brush)
{
if (!m_Target) // Use GDI+ if D2D render target has not been created.
{
m_GdipGraphics->FillRectangle(&brush, rect);
return;
}
Gdiplus::Color color;
brush.GetColor(&color);
Microsoft::WRL::ComPtr<ID2D1SolidColorBrush> solidBrush;
HRESULT hr = m_Target->CreateSolidColorBrush(ToColorF(color), solidBrush.GetAddressOf());
if (SUCCEEDED(hr))
{
m_Target->FillRectangle(ToRectF(rect), solidBrush.Get());
}
}
void TextInlineFormat_Typography::ApplyInlineFormat(IDWriteTextLayout* layout)
{
if (!layout) return;
for (const auto& range : GetRanges())
{
if (range.length <= 0) continue;
Microsoft::WRL::ComPtr<IDWriteTypography> typography;
HRESULT hr = Canvas::c_DWFactory->CreateTypography(typography.GetAddressOf());
if (FAILED(hr)) continue;
DWRITE_FONT_FEATURE feature = { m_Tag, m_Parameter };
hr = typography->AddFontFeature(feature);
if (FAILED(hr)) continue;
layout->SetTypography(typography.Get(), range);
}
}
void Scene::onKeyUp(UINT8 key)
{
if (key == 'Z') {
DXGI_SWAP_CHAIN_DESC desc;
this->mpSwapChain->GetDesc(&desc);
Microsoft::WRL::ComPtr<IDXGIOutput> pOutput;
if (desc.Windowed) {
//全画面モードに切り替える際はどのディスプレイを対象にするか決めれる
if (DXGI_ERROR_NOT_FOUND == this->mpAdapter->EnumOutputs(0, pOutput.GetAddressOf())) {
throw std::runtime_error("アダプターの出力先が見つかりません。");
}
}
auto hr = this->mpSwapChain->SetFullscreenState(desc.Windowed, pOutput.Get());
if (FAILED(hr)) {
throw std::runtime_error("フルスリーンモードとウィンドウモードの切り替えに失敗。");
}
}
}
void Audio::CreateReverb(IXAudio2* engine, IXAudio2MasteringVoice* masteringVoice, XAUDIO2FX_REVERB_PARAMETERS* parameters, IXAudio2SubmixVoice** newSubmix, bool enableEffect)
{
XAUDIO2_EFFECT_DESCRIPTOR soundEffectdescriptor;
XAUDIO2_EFFECT_CHAIN soundEffectChain;
Microsoft::WRL::ComPtr<IUnknown> soundEffectXAPO;
DX::ThrowIfFailed(
XAudio2CreateReverb(&soundEffectXAPO)
);
soundEffectdescriptor.InitialState = false;
soundEffectdescriptor.OutputChannels = 2;
soundEffectdescriptor.pEffect = soundEffectXAPO.Get();
soundEffectChain.EffectCount = 1;
soundEffectChain.pEffectDescriptors = &soundEffectdescriptor;
DX::ThrowIfFailed(
engine->CreateSubmixVoice(newSubmix, 2, 48000, 0, 0, nullptr, &soundEffectChain)
);
DX::ThrowIfFailed(
(*newSubmix)->SetEffectParameters(0, parameters, sizeof(m_reverbParametersSmall))
);
if (enableEffect)
{
DX::ThrowIfFailed(
(*newSubmix)->EnableEffect(0)
);
}
DX::ThrowIfFailed(
(*newSubmix)->SetVolume (1.0f)
);
float outputMatrix[4] = {0, 0, 0, 0};
DX::ThrowIfFailed(
(*newSubmix)->SetOutputMatrix(masteringVoice, 2, 2, outputMatrix)
);
}
