// // Copyright 2013 The ANGLE Project Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // // Blit11.cpp: Texture copy utility class. #include "libANGLE/renderer/d3d/d3d11/Blit11.h" #include #include "common/utilities.h" #include "libANGLE/Context.h" #include "libANGLE/formatutils.h" #include "libANGLE/renderer/d3d/d3d11/Context11.h" #include "libANGLE/renderer/d3d/d3d11/RenderTarget11.h" #include "libANGLE/renderer/d3d/d3d11/Renderer11.h" #include "libANGLE/renderer/d3d/d3d11/formatutils11.h" #include "libANGLE/renderer/d3d/d3d11/renderer11_utils.h" #include "libANGLE/renderer/d3d/d3d11/texture_format_table.h" #include "libANGLE/trace.h" namespace rx { namespace { // Include inline shaders in the anonymous namespace to make sure no symbols are exported #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/passthrough2d11vs.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/passthroughdepth2d11ps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/passthrough3d11gs.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/passthrough3d11vs.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/resolvedepth11_ps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/resolvedepthstencil11_ps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/resolvedepthstencil11_vs.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/resolvestencil11_ps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzlef2darrayps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzlef2dps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzlef3dps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzlei2darrayps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzlei2dps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzlei3dps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzleui2darrayps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzleui2dps.h" #include "libANGLE/renderer/d3d/d3d11/shaders/compiled/swizzleui3dps.h" void StretchedBlitNearest_RowByRow(const gl::Box &sourceArea, const gl::Box &destArea, const gl::Rectangle &clippedDestArea, const gl::Extents &sourceSize, unsigned int sourceRowPitch, unsigned int destRowPitch, size_t pixelSize, const uint8_t *sourceData, uint8_t *destData) { int srcHeightSubOne = (sourceArea.height - 1); size_t copySize = pixelSize * clippedDestArea.width; size_t srcOffset = sourceArea.x * pixelSize; size_t destOffset = clippedDestArea.x * pixelSize; for (int y = clippedDestArea.y; y < clippedDestArea.y + clippedDestArea.height; y++) { // TODO: Fix divide by zero when height == 1. http://anglebug.com/6099 float yPerc = static_cast(y - destArea.y) / (destArea.height - 1); // Interpolate using the original source rectangle to determine which row to sample from // while clamping to the edges unsigned int readRow = static_cast( gl::clamp(sourceArea.y + floor(yPerc * srcHeightSubOne + 0.5f), 0, srcHeightSubOne)); unsigned int writeRow = y; const uint8_t *sourceRow = sourceData + readRow * sourceRowPitch + srcOffset; uint8_t *destRow = destData + writeRow * destRowPitch + destOffset; memcpy(destRow, sourceRow, copySize); } } void StretchedBlitNearest_PixelByPixel(const gl::Box &sourceArea, const gl::Box &destArea, const gl::Rectangle &clippedDestArea, const gl::Extents &sourceSize, unsigned int sourceRowPitch, unsigned int destRowPitch, ptrdiff_t readOffset, ptrdiff_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, const uint8_t *sourceData, uint8_t *destData) { auto xMax = clippedDestArea.x + clippedDestArea.width; auto yMax = clippedDestArea.y + clippedDestArea.height; for (int writeRow = clippedDestArea.y; writeRow < yMax; writeRow++) { // Interpolate using the original source rectangle to determine which row to sample from // while clamping to the edges float yPerc = static_cast(writeRow - destArea.y) / (destArea.height - 1); float yRounded = floor(yPerc * (sourceArea.height - 1) + 0.5f); unsigned int readRow = static_cast(gl::clamp(sourceArea.y + yRounded, 0, sourceSize.height - 1)); for (int writeColumn = clippedDestArea.x; writeColumn < xMax; writeColumn++) { // Interpolate the original source rectangle to determine which column to sample // from while clamping to the edges float xPerc = static_cast(writeColumn - destArea.x) / (destArea.width - 1); float xRounded = floor(xPerc * (sourceArea.width - 1) + 0.5f); unsigned int readColumn = static_cast( gl::clamp(sourceArea.x + xRounded, 0, sourceSize.width - 1)); const uint8_t *sourcePixel = sourceData + readRow * sourceRowPitch + readColumn * srcPixelStride + readOffset; uint8_t *destPixel = destData + writeRow * destRowPitch + writeColumn * destPixelStride + writeOffset; memcpy(destPixel, sourcePixel, copySize); } } } void StretchedBlitNearest(const gl::Box &sourceArea, const gl::Box &destArea, const gl::Rectangle &clipRect, const gl::Extents &sourceSize, unsigned int sourceRowPitch, unsigned int destRowPitch, ptrdiff_t readOffset, ptrdiff_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, const uint8_t *sourceData, uint8_t *destData) { gl::Rectangle clippedDestArea(destArea.x, destArea.y, destArea.width, destArea.height); if (!gl::ClipRectangle(clippedDestArea, clipRect, &clippedDestArea)) { return; } // Determine if entire rows can be copied at once instead of each individual pixel. There // must be no out of bounds lookups, whole rows copies, and no scale. if (sourceArea.width == clippedDestArea.width && sourceArea.x >= 0 && sourceArea.x + sourceArea.width <= sourceSize.width && copySize == srcPixelStride && copySize == destPixelStride) { StretchedBlitNearest_RowByRow(sourceArea, destArea, clippedDestArea, sourceSize, sourceRowPitch, destRowPitch, srcPixelStride, sourceData, destData); } else { StretchedBlitNearest_PixelByPixel(sourceArea, destArea, clippedDestArea, sourceSize, sourceRowPitch, destRowPitch, readOffset, writeOffset, copySize, srcPixelStride, destPixelStride, sourceData, destData); } } using DepthStencilLoader = void(const float *, uint8_t *); void LoadDepth16(const float *source, uint8_t *dest) { uint32_t convertedDepth = gl::floatToNormalized<16, uint32_t>(source[0]); memcpy(dest, &convertedDepth, 2u); } void LoadDepth24(const float *source, uint8_t *dest) { uint32_t convertedDepth = gl::floatToNormalized<24, uint32_t>(source[0]); memcpy(dest, &convertedDepth, 3u); } void LoadStencilHelper(const float *source, uint8_t *dest) { uint32_t convertedStencil = gl::getShiftedData<8, 0>(static_cast(source[1])); memcpy(dest, &convertedStencil, 1u); } void LoadStencil8(const float *source, uint8_t *dest) { // STENCIL_INDEX8 is implemented with D24S8, with the depth bits unused. Writes zero for safety. float zero = 0.0f; LoadDepth24(&zero, &dest[0]); LoadStencilHelper(source, &dest[3]); } void LoadDepth24Stencil8(const float *source, uint8_t *dest) { LoadDepth24(source, &dest[0]); LoadStencilHelper(source, &dest[3]); } void LoadDepth32F(const float *source, uint8_t *dest) { memcpy(dest, source, sizeof(float)); } void LoadDepth32FStencil8(const float *source, uint8_t *dest) { LoadDepth32F(source, &dest[0]); LoadStencilHelper(source, &dest[4]); } template void CopyDepthStencil(const gl::Box &sourceArea, const gl::Box &destArea, const gl::Rectangle &clippedDestArea, const gl::Extents &sourceSize, unsigned int sourceRowPitch, unsigned int destRowPitch, ptrdiff_t readOffset, ptrdiff_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, const uint8_t *sourceData, uint8_t *destData) { // No stretching or subregions are supported, only full blits. ASSERT(sourceArea == destArea); ASSERT(sourceSize.width == sourceArea.width && sourceSize.height == sourceArea.height && sourceSize.depth == 1); ASSERT(clippedDestArea.width == sourceSize.width && clippedDestArea.height == sourceSize.height); ASSERT(readOffset == 0 && writeOffset == 0); ASSERT(destArea.x == 0 && destArea.y == 0); for (int row = 0; row < destArea.height; ++row) { for (int column = 0; column < destArea.width; ++column) { ptrdiff_t offset = row * sourceRowPitch + column * srcPixelStride; const float *sourcePixel = reinterpret_cast(sourceData + offset); uint8_t *destPixel = destData + row * destRowPitch + column * destPixelStride; loader(sourcePixel, destPixel); } } } void Depth32FStencil8ToDepth32F(const float *source, float *dest) { *dest = *source; } void Depth24Stencil8ToDepth32F(const uint32_t *source, float *dest) { uint32_t normDepth = source[0] & 0x00FFFFFF; float floatDepth = gl::normalizedToFloat<24>(normDepth); *dest = floatDepth; } void BlitD24S8ToD32F(const gl::Box &sourceArea, const gl::Box &destArea, const gl::Rectangle &clippedDestArea, const gl::Extents &sourceSize, unsigned int sourceRowPitch, unsigned int destRowPitch, ptrdiff_t readOffset, ptrdiff_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, const uint8_t *sourceData, uint8_t *destData) { // No stretching or subregions are supported, only full blits. ASSERT(sourceArea == destArea); ASSERT(sourceSize.width == sourceArea.width && sourceSize.height == sourceArea.height && sourceSize.depth == 1); ASSERT(clippedDestArea.width == sourceSize.width && clippedDestArea.height == sourceSize.height); ASSERT(readOffset == 0 && writeOffset == 0); ASSERT(destArea.x == 0 && destArea.y == 0); for (int row = 0; row < destArea.height; ++row) { for (int column = 0; column < destArea.width; ++column) { ptrdiff_t offset = row * sourceRowPitch + column * srcPixelStride; const uint32_t *sourcePixel = reinterpret_cast(sourceData + offset); float *destPixel = reinterpret_cast(destData + row * destRowPitch + column * destPixelStride); Depth24Stencil8ToDepth32F(sourcePixel, destPixel); } } } void BlitD32FS8ToD32F(const gl::Box &sourceArea, const gl::Box &destArea, const gl::Rectangle &clippedDestArea, const gl::Extents &sourceSize, unsigned int sourceRowPitch, unsigned int destRowPitch, ptrdiff_t readOffset, ptrdiff_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, const uint8_t *sourceData, uint8_t *destData) { // No stretching or subregions are supported, only full blits. ASSERT(sourceArea == destArea); ASSERT(sourceSize.width == sourceArea.width && sourceSize.height == sourceArea.height && sourceSize.depth == 1); ASSERT(clippedDestArea.width == sourceSize.width && clippedDestArea.height == sourceSize.height); ASSERT(readOffset == 0 && writeOffset == 0); ASSERT(destArea.x == 0 && destArea.y == 0); for (int row = 0; row < destArea.height; ++row) { for (int column = 0; column < destArea.width; ++column) { ptrdiff_t offset = row * sourceRowPitch + column * srcPixelStride; const float *sourcePixel = reinterpret_cast(sourceData + offset); float *destPixel = reinterpret_cast(destData + row * destRowPitch + column * destPixelStride); Depth32FStencil8ToDepth32F(sourcePixel, destPixel); } } } Blit11::BlitConvertFunction *GetCopyDepthStencilFunction(GLenum internalFormat) { switch (internalFormat) { case GL_DEPTH_COMPONENT16: return &CopyDepthStencil; case GL_DEPTH_COMPONENT24: return &CopyDepthStencil; case GL_DEPTH_COMPONENT32F: return &CopyDepthStencil; case GL_STENCIL_INDEX8: return &CopyDepthStencil; case GL_DEPTH24_STENCIL8: return &CopyDepthStencil; case GL_DEPTH32F_STENCIL8: return &CopyDepthStencil; default: UNREACHABLE(); return nullptr; } } inline void GenerateVertexCoords(const gl::Box &sourceArea, const gl::Extents &sourceSize, const gl::Box &destArea, const gl::Extents &destSize, float *x1, float *y1, float *x2, float *y2, float *u1, float *v1, float *u2, float *v2) { *x1 = (destArea.x / float(destSize.width)) * 2.0f - 1.0f; *y1 = ((destSize.height - destArea.y - destArea.height) / float(destSize.height)) * 2.0f - 1.0f; *x2 = ((destArea.x + destArea.width) / float(destSize.width)) * 2.0f - 1.0f; *y2 = ((destSize.height - destArea.y) / float(destSize.height)) * 2.0f - 1.0f; *u1 = sourceArea.x / float(sourceSize.width); *v1 = sourceArea.y / float(sourceSize.height); *u2 = (sourceArea.x + sourceArea.width) / float(sourceSize.width); *v2 = (sourceArea.y + sourceArea.height) / float(sourceSize.height); } void Write2DVertices(const gl::Box &sourceArea, const gl::Extents &sourceSize, const gl::Box &destArea, const gl::Extents &destSize, void *outVertices, unsigned int *outStride, unsigned int *outVertexCount, D3D11_PRIMITIVE_TOPOLOGY *outTopology) { float x1, y1, x2, y2, u1, v1, u2, v2; GenerateVertexCoords(sourceArea, sourceSize, destArea, destSize, &x1, &y1, &x2, &y2, &u1, &v1, &u2, &v2); d3d11::PositionTexCoordVertex *vertices = static_cast(outVertices); d3d11::SetPositionTexCoordVertex(&vertices[0], x1, y1, u1, v2); d3d11::SetPositionTexCoordVertex(&vertices[1], x1, y2, u1, v1); d3d11::SetPositionTexCoordVertex(&vertices[2], x2, y1, u2, v2); d3d11::SetPositionTexCoordVertex(&vertices[3], x2, y2, u2, v1); *outStride = sizeof(d3d11::PositionTexCoordVertex); *outVertexCount = 4; *outTopology = D3D_PRIMITIVE_TOPOLOGY_TRIANGLESTRIP; } void Write3DVertices(const gl::Box &sourceArea, const gl::Extents &sourceSize, const gl::Box &destArea, const gl::Extents &destSize, void *outVertices, unsigned int *outStride, unsigned int *outVertexCount, D3D11_PRIMITIVE_TOPOLOGY *outTopology) { ASSERT(sourceSize.depth > 0 && destSize.depth > 0); float x1, y1, x2, y2, u1, v1, u2, v2; GenerateVertexCoords(sourceArea, sourceSize, destArea, destSize, &x1, &y1, &x2, &y2, &u1, &v1, &u2, &v2); d3d11::PositionLayerTexCoord3DVertex *vertices = static_cast(outVertices); for (int i = 0; i < destSize.depth; i++) { float readDepth = (float)i / std::max(destSize.depth - 1, 1); d3d11::SetPositionLayerTexCoord3DVertex(&vertices[i * 6 + 0], x1, y1, i, u1, v2, readDepth); d3d11::SetPositionLayerTexCoord3DVertex(&vertices[i * 6 + 1], x1, y2, i, u1, v1, readDepth); d3d11::SetPositionLayerTexCoord3DVertex(&vertices[i * 6 + 2], x2, y1, i, u2, v2, readDepth); d3d11::SetPositionLayerTexCoord3DVertex(&vertices[i * 6 + 3], x1, y2, i, u1, v1, readDepth); d3d11::SetPositionLayerTexCoord3DVertex(&vertices[i * 6 + 4], x2, y2, i, u2, v1, readDepth); d3d11::SetPositionLayerTexCoord3DVertex(&vertices[i * 6 + 5], x2, y1, i, u2, v2, readDepth); } *outStride = sizeof(d3d11::PositionLayerTexCoord3DVertex); *outVertexCount = destSize.depth * 6; *outTopology = D3D_PRIMITIVE_TOPOLOGY_TRIANGLELIST; } unsigned int GetSwizzleIndex(GLenum swizzle) { unsigned int colorIndex = 0; switch (swizzle) { case GL_RED: colorIndex = 0; break; case GL_GREEN: colorIndex = 1; break; case GL_BLUE: colorIndex = 2; break; case GL_ALPHA: colorIndex = 3; break; case GL_ZERO: colorIndex = 4; break; case GL_ONE: colorIndex = 5; break; default: UNREACHABLE(); break; } return colorIndex; } D3D11_BLEND_DESC GetAlphaMaskBlendStateDesc() { D3D11_BLEND_DESC desc; memset(&desc, 0, sizeof(desc)); desc.RenderTarget[0].BlendEnable = TRUE; desc.RenderTarget[0].SrcBlend = D3D11_BLEND_ONE; desc.RenderTarget[0].DestBlend = D3D11_BLEND_ZERO; desc.RenderTarget[0].BlendOp = D3D11_BLEND_OP_ADD; desc.RenderTarget[0].SrcBlendAlpha = D3D11_BLEND_ZERO; desc.RenderTarget[0].DestBlendAlpha = D3D11_BLEND_ZERO; desc.RenderTarget[0].BlendOpAlpha = D3D11_BLEND_OP_ADD; desc.RenderTarget[0].RenderTargetWriteMask = D3D11_COLOR_WRITE_ENABLE_RED | D3D11_COLOR_WRITE_ENABLE_GREEN | D3D11_COLOR_WRITE_ENABLE_BLUE; return desc; } D3D11_INPUT_ELEMENT_DESC quad2DLayout[] = { {"POSITION", 0, DXGI_FORMAT_R32G32_FLOAT, 0, 0, D3D11_INPUT_PER_VERTEX_DATA, 0}, {"TEXCOORD", 0, DXGI_FORMAT_R32G32_FLOAT, 0, 8, D3D11_INPUT_PER_VERTEX_DATA, 0}, }; D3D11_INPUT_ELEMENT_DESC quad3DLayout[] = { {"POSITION", 0, DXGI_FORMAT_R32G32_FLOAT, 0, 0, D3D11_INPUT_PER_VERTEX_DATA, 0}, {"LAYER", 0, DXGI_FORMAT_R32_UINT, 0, 8, D3D11_INPUT_PER_VERTEX_DATA, 0}, {"TEXCOORD", 0, DXGI_FORMAT_R32G32B32_FLOAT, 0, 12, D3D11_INPUT_PER_VERTEX_DATA, 0}, }; DXGI_FORMAT GetStencilSRVFormat(const d3d11::Format &formatSet) { switch (formatSet.texFormat) { case DXGI_FORMAT_R32G8X24_TYPELESS: return DXGI_FORMAT_X32_TYPELESS_G8X24_UINT; case DXGI_FORMAT_R24G8_TYPELESS: return DXGI_FORMAT_X24_TYPELESS_G8_UINT; default: UNREACHABLE(); return DXGI_FORMAT_UNKNOWN; } } } // namespace #include "libANGLE/renderer/d3d/d3d11/Blit11Helper_autogen.inc" Blit11::Shader::Shader() = default; Blit11::Shader::Shader(Shader &&other) = default; Blit11::Shader::~Shader() = default; Blit11::Shader &Blit11::Shader::operator=(Blit11::Shader &&other) = default; Blit11::Blit11(Renderer11 *renderer) : mRenderer(renderer), mResourcesInitialized(false), mVertexBuffer(), mPointSampler(), mLinearSampler(), mScissorEnabledRasterizerState(), mScissorDisabledRasterizerState(), mDepthStencilState(), mQuad2DIL(quad2DLayout, ArraySize(quad2DLayout), g_VS_Passthrough2D, ArraySize(g_VS_Passthrough2D), "Blit11 2D input layout"), mQuad2DVS(g_VS_Passthrough2D, ArraySize(g_VS_Passthrough2D), "Blit11 2D vertex shader"), mDepthPS(g_PS_PassthroughDepth2D, ArraySize(g_PS_PassthroughDepth2D), "Blit11 2D depth pixel shader"), mQuad3DIL(quad3DLayout, ArraySize(quad3DLayout), g_VS_Passthrough3D, ArraySize(g_VS_Passthrough3D), "Blit11 3D input layout"), mQuad3DVS(g_VS_Passthrough3D, ArraySize(g_VS_Passthrough3D), "Blit11 3D vertex shader"), mQuad3DGS(g_GS_Passthrough3D, ArraySize(g_GS_Passthrough3D), "Blit11 3D geometry shader"), mAlphaMaskBlendState(GetAlphaMaskBlendStateDesc(), "Blit11 Alpha Mask Blend"), mSwizzleCB(), mResolveDepthStencilVS(g_VS_ResolveDepthStencil, ArraySize(g_VS_ResolveDepthStencil), "Blit11::mResolveDepthStencilVS"), mResolveDepthPS(g_PS_ResolveDepth, ArraySize(g_PS_ResolveDepth), "Blit11::mResolveDepthPS"), mResolveDepthStencilPS(g_PS_ResolveDepthStencil, ArraySize(g_PS_ResolveDepthStencil), "Blit11::mResolveDepthStencilPS"), mResolveStencilPS(g_PS_ResolveStencil, ArraySize(g_PS_ResolveStencil), "Blit11::mResolveStencilPS"), mStencilSRV(), mResolvedDepthStencilRTView() {} Blit11::~Blit11() {} angle::Result Blit11::initResources(const gl::Context *context) { if (mResourcesInitialized) { return angle::Result::Continue; } ANGLE_TRACE_EVENT0("gpu.angle", "Blit11::initResources"); D3D11_BUFFER_DESC vbDesc; vbDesc.ByteWidth = static_cast(std::max(sizeof(d3d11::PositionLayerTexCoord3DVertex), sizeof(d3d11::PositionTexCoordVertex)) * 6 * mRenderer->getNativeCaps().max3DTextureSize); vbDesc.Usage = D3D11_USAGE_DYNAMIC; vbDesc.BindFlags = D3D11_BIND_VERTEX_BUFFER; vbDesc.CPUAccessFlags = D3D11_CPU_ACCESS_WRITE; vbDesc.MiscFlags = 0; vbDesc.StructureByteStride = 0; Context11 *context11 = GetImplAs(context); ANGLE_TRY(mRenderer->allocateResource(context11, vbDesc, &mVertexBuffer)); mVertexBuffer.setInternalName("Blit11VertexBuffer"); D3D11_SAMPLER_DESC pointSamplerDesc; pointSamplerDesc.Filter = D3D11_FILTER_MIN_MAG_POINT_MIP_LINEAR; pointSamplerDesc.AddressU = D3D11_TEXTURE_ADDRESS_CLAMP; pointSamplerDesc.AddressV = D3D11_TEXTURE_ADDRESS_CLAMP; pointSamplerDesc.AddressW = D3D11_TEXTURE_ADDRESS_CLAMP; pointSamplerDesc.MipLODBias = 0.0f; pointSamplerDesc.MaxAnisotropy = 0; pointSamplerDesc.ComparisonFunc = D3D11_COMPARISON_NEVER; pointSamplerDesc.BorderColor[0] = 0.0f; pointSamplerDesc.BorderColor[1] = 0.0f; pointSamplerDesc.BorderColor[2] = 0.0f; pointSamplerDesc.BorderColor[3] = 0.0f; pointSamplerDesc.MinLOD = 0.0f; pointSamplerDesc.MaxLOD = FLT_MAX; ANGLE_TRY(mRenderer->allocateResource(context11, pointSamplerDesc, &mPointSampler)); mPointSampler.setInternalName("Blit11PointSampler"); D3D11_SAMPLER_DESC linearSamplerDesc; linearSamplerDesc.Filter = D3D11_FILTER_MIN_MAG_MIP_LINEAR; linearSamplerDesc.AddressU = D3D11_TEXTURE_ADDRESS_CLAMP; linearSamplerDesc.AddressV = D3D11_TEXTURE_ADDRESS_CLAMP; linearSamplerDesc.AddressW = D3D11_TEXTURE_ADDRESS_CLAMP; linearSamplerDesc.MipLODBias = 0.0f; linearSamplerDesc.MaxAnisotropy = 0; linearSamplerDesc.ComparisonFunc = D3D11_COMPARISON_NEVER; linearSamplerDesc.BorderColor[0] = 0.0f; linearSamplerDesc.BorderColor[1] = 0.0f; linearSamplerDesc.BorderColor[2] = 0.0f; linearSamplerDesc.BorderColor[3] = 0.0f; linearSamplerDesc.MinLOD = 0.0f; linearSamplerDesc.MaxLOD = FLT_MAX; ANGLE_TRY(mRenderer->allocateResource(context11, linearSamplerDesc, &mLinearSampler)); mLinearSampler.setInternalName("Blit11LinearSampler"); // Use a rasterizer state that will not cull so that inverted quads will not be culled D3D11_RASTERIZER_DESC rasterDesc; rasterDesc.FillMode = D3D11_FILL_SOLID; rasterDesc.CullMode = D3D11_CULL_NONE; rasterDesc.FrontCounterClockwise = FALSE; rasterDesc.DepthBias = 0; rasterDesc.SlopeScaledDepthBias = 0.0f; rasterDesc.DepthBiasClamp = 0.0f; rasterDesc.DepthClipEnable = TRUE; rasterDesc.MultisampleEnable = FALSE; rasterDesc.AntialiasedLineEnable = FALSE; rasterDesc.ScissorEnable = TRUE; ANGLE_TRY(mRenderer->allocateResource(context11, rasterDesc, &mScissorEnabledRasterizerState)); mScissorEnabledRasterizerState.setInternalName("Blit11ScissoringRasterizerState"); rasterDesc.ScissorEnable = FALSE; ANGLE_TRY(mRenderer->allocateResource(context11, rasterDesc, &mScissorDisabledRasterizerState)); mScissorDisabledRasterizerState.setInternalName("Blit11NoScissoringRasterizerState"); D3D11_DEPTH_STENCIL_DESC depthStencilDesc; depthStencilDesc.DepthEnable = TRUE; depthStencilDesc.DepthWriteMask = D3D11_DEPTH_WRITE_MASK_ALL; depthStencilDesc.DepthFunc = D3D11_COMPARISON_ALWAYS; depthStencilDesc.StencilEnable = FALSE; depthStencilDesc.StencilReadMask = D3D11_DEFAULT_STENCIL_READ_MASK; depthStencilDesc.StencilWriteMask = D3D11_DEFAULT_STENCIL_WRITE_MASK; depthStencilDesc.FrontFace.StencilFailOp = D3D11_STENCIL_OP_KEEP; depthStencilDesc.FrontFace.StencilDepthFailOp = D3D11_STENCIL_OP_KEEP; depthStencilDesc.FrontFace.StencilPassOp = D3D11_STENCIL_OP_KEEP; depthStencilDesc.FrontFace.StencilFunc = D3D11_COMPARISON_ALWAYS; depthStencilDesc.BackFace.StencilFailOp = D3D11_STENCIL_OP_KEEP; depthStencilDesc.BackFace.StencilDepthFailOp = D3D11_STENCIL_OP_KEEP; depthStencilDesc.BackFace.StencilPassOp = D3D11_STENCIL_OP_KEEP; depthStencilDesc.BackFace.StencilFunc = D3D11_COMPARISON_ALWAYS; ANGLE_TRY(mRenderer->allocateResource(context11, depthStencilDesc, &mDepthStencilState)); mDepthStencilState.setInternalName("Blit11DepthStencilState"); D3D11_BUFFER_DESC swizzleBufferDesc; swizzleBufferDesc.ByteWidth = sizeof(unsigned int) * 4; swizzleBufferDesc.Usage = D3D11_USAGE_DYNAMIC; swizzleBufferDesc.BindFlags = D3D11_BIND_CONSTANT_BUFFER; swizzleBufferDesc.CPUAccessFlags = D3D11_CPU_ACCESS_WRITE; swizzleBufferDesc.MiscFlags = 0; swizzleBufferDesc.StructureByteStride = 0; ANGLE_TRY(mRenderer->allocateResource(context11, swizzleBufferDesc, &mSwizzleCB)); mSwizzleCB.setInternalName("Blit11SwizzleConstantBuffer"); mResourcesInitialized = true; return angle::Result::Continue; } // static Blit11::SwizzleShaderType Blit11::GetSwizzleShaderType(GLenum type, D3D11_SRV_DIMENSION dimensionality) { switch (dimensionality) { case D3D11_SRV_DIMENSION_TEXTURE2D: switch (type) { case GL_FLOAT: return SWIZZLESHADER_2D_FLOAT; case GL_UNSIGNED_INT: return SWIZZLESHADER_2D_UINT; case GL_INT: return SWIZZLESHADER_2D_INT; default: UNREACHABLE(); return SWIZZLESHADER_INVALID; } case D3D11_SRV_DIMENSION_TEXTURECUBE: switch (type) { case GL_FLOAT: return SWIZZLESHADER_CUBE_FLOAT; case GL_UNSIGNED_INT: return SWIZZLESHADER_CUBE_UINT; case GL_INT: return SWIZZLESHADER_CUBE_INT; default: UNREACHABLE(); return SWIZZLESHADER_INVALID; } case D3D11_SRV_DIMENSION_TEXTURE3D: switch (type) { case GL_FLOAT: return SWIZZLESHADER_3D_FLOAT; case GL_UNSIGNED_INT: return SWIZZLESHADER_3D_UINT; case GL_INT: return SWIZZLESHADER_3D_INT; default: UNREACHABLE(); return SWIZZLESHADER_INVALID; } case D3D11_SRV_DIMENSION_TEXTURE2DARRAY: switch (type) { case GL_FLOAT: return SWIZZLESHADER_ARRAY_FLOAT; case GL_UNSIGNED_INT: return SWIZZLESHADER_ARRAY_UINT; case GL_INT: return SWIZZLESHADER_ARRAY_INT; default: UNREACHABLE(); return SWIZZLESHADER_INVALID; } default: UNREACHABLE(); return SWIZZLESHADER_INVALID; } } angle::Result Blit11::getShaderSupport(const gl::Context *context, const Shader &shader, Blit11::ShaderSupport *supportOut) { Context11 *context11 = GetImplAs(context); switch (shader.dimension) { case SHADER_2D: { ANGLE_TRY(mQuad2DIL.resolve(context11, mRenderer)); ANGLE_TRY(mQuad2DVS.resolve(context11, mRenderer)); supportOut->inputLayout = &mQuad2DIL.getObj(); supportOut->vertexShader = &mQuad2DVS.getObj(); supportOut->geometryShader = nullptr; supportOut->vertexWriteFunction = Write2DVertices; break; } case SHADER_3D: case SHADER_2DARRAY: { ANGLE_TRY(mQuad3DIL.resolve(context11, mRenderer)); ANGLE_TRY(mQuad3DVS.resolve(context11, mRenderer)); ANGLE_TRY(mQuad3DGS.resolve(context11, mRenderer)); supportOut->inputLayout = &mQuad3DIL.getObj(); supportOut->vertexShader = &mQuad3DVS.getObj(); supportOut->geometryShader = &mQuad3DGS.getObj(); supportOut->vertexWriteFunction = Write3DVertices; break; } default: UNREACHABLE(); } return angle::Result::Continue; } angle::Result Blit11::swizzleTexture(const gl::Context *context, const d3d11::SharedSRV &source, const d3d11::RenderTargetView &dest, const gl::Extents &size, const gl::SwizzleState &swizzleTarget) { ANGLE_TRY(initResources(context)); ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); D3D11_SHADER_RESOURCE_VIEW_DESC sourceSRVDesc; source.get()->GetDesc(&sourceSRVDesc); GLenum componentType = d3d11::GetComponentType(sourceSRVDesc.Format); if (componentType == GL_NONE) { // We're swizzling the depth component of a depth-stencil texture. switch (sourceSRVDesc.Format) { case DXGI_FORMAT_R24_UNORM_X8_TYPELESS: componentType = GL_UNSIGNED_NORMALIZED; break; case DXGI_FORMAT_R32_FLOAT_X8X24_TYPELESS: componentType = GL_FLOAT; break; default: UNREACHABLE(); break; } } GLenum shaderType = GL_NONE; switch (componentType) { case GL_UNSIGNED_NORMALIZED: case GL_SIGNED_NORMALIZED: case GL_FLOAT: shaderType = GL_FLOAT; break; case GL_INT: shaderType = GL_INT; break; case GL_UNSIGNED_INT: shaderType = GL_UNSIGNED_INT; break; default: UNREACHABLE(); break; } const Shader *shader = nullptr; ANGLE_TRY(getSwizzleShader(context, shaderType, sourceSRVDesc.ViewDimension, &shader)); // Set vertices D3D11_MAPPED_SUBRESOURCE mappedResource; ANGLE_TRY(mRenderer->mapResource(context, mVertexBuffer.get(), 0, D3D11_MAP_WRITE_DISCARD, 0, &mappedResource)); ShaderSupport support; ANGLE_TRY(getShaderSupport(context, *shader, &support)); UINT stride = 0; UINT drawCount = 0; D3D11_PRIMITIVE_TOPOLOGY topology; gl::Box area(0, 0, 0, size.width, size.height, size.depth); support.vertexWriteFunction(area, size, area, size, mappedResource.pData, &stride, &drawCount, &topology); deviceContext->Unmap(mVertexBuffer.get(), 0); // Set constant buffer ANGLE_TRY(mRenderer->mapResource(context, mSwizzleCB.get(), 0, D3D11_MAP_WRITE_DISCARD, 0, &mappedResource)); unsigned int *swizzleIndices = static_cast(mappedResource.pData); swizzleIndices[0] = GetSwizzleIndex(swizzleTarget.swizzleRed); swizzleIndices[1] = GetSwizzleIndex(swizzleTarget.swizzleGreen); swizzleIndices[2] = GetSwizzleIndex(swizzleTarget.swizzleBlue); swizzleIndices[3] = GetSwizzleIndex(swizzleTarget.swizzleAlpha); deviceContext->Unmap(mSwizzleCB.get(), 0); StateManager11 *stateManager = mRenderer->getStateManager(); // Apply vertex buffer stateManager->setSingleVertexBuffer(&mVertexBuffer, stride, 0); // Apply constant buffer stateManager->setPixelConstantBuffer(0, &mSwizzleCB); // Apply state stateManager->setSimpleBlendState(nullptr); stateManager->setDepthStencilState(nullptr, 0xFFFFFFFF); stateManager->setRasterizerState(&mScissorDisabledRasterizerState); // Apply shaders stateManager->setInputLayout(support.inputLayout); stateManager->setPrimitiveTopology(topology); stateManager->setDrawShaders(support.vertexShader, support.geometryShader, &shader->pixelShader); // Apply render target stateManager->setRenderTarget(dest.get(), nullptr); // Set the viewport stateManager->setSimpleViewport(size); // Apply textures and sampler stateManager->setSimplePixelTextureAndSampler(source, mPointSampler); // Draw the quad deviceContext->Draw(drawCount, 0); return angle::Result::Continue; } angle::Result Blit11::copyTexture(const gl::Context *context, const d3d11::SharedSRV &source, const gl::Box &sourceArea, const gl::Extents &sourceSize, GLenum sourceFormat, const d3d11::RenderTargetView &dest, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor, GLenum destFormat, GLenum destTypeForDownsampling, GLenum filter, bool maskOffAlpha, bool unpackPremultiplyAlpha, bool unpackUnmultiplyAlpha) { ANGLE_TRY(initResources(context)); ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); // Determine if the source format is a signed integer format, the destFormat will already // be GL_XXXX_INTEGER but it does not tell us if it is signed or unsigned. D3D11_SHADER_RESOURCE_VIEW_DESC sourceSRVDesc; source.get()->GetDesc(&sourceSRVDesc); GLenum componentType = d3d11::GetComponentType(sourceSRVDesc.Format); ASSERT(componentType != GL_NONE); ASSERT(componentType != GL_SIGNED_NORMALIZED); bool isSrcSigned = (componentType == GL_INT); D3D11_RENDER_TARGET_VIEW_DESC destRTVDesc; dest.get()->GetDesc(&destRTVDesc); GLenum destComponentType = d3d11::GetComponentType(destRTVDesc.Format); ASSERT(componentType != GL_NONE); bool isDestSigned = (destComponentType == GL_INT); ShaderDimension dimension = SHADER_INVALID; switch (sourceSRVDesc.ViewDimension) { case D3D11_SRV_DIMENSION_TEXTURE2D: dimension = SHADER_2D; break; case D3D11_SRV_DIMENSION_TEXTURE3D: dimension = SHADER_3D; break; case D3D11_SRV_DIMENSION_TEXTURE2DARRAY: dimension = SHADER_2DARRAY; break; default: UNREACHABLE(); } const Shader *shader = nullptr; ANGLE_TRY(getBlitShader(context, destFormat, sourceFormat, isSrcSigned, isDestSigned, unpackPremultiplyAlpha, unpackUnmultiplyAlpha, destTypeForDownsampling, dimension, &shader)); ShaderSupport support; ANGLE_TRY(getShaderSupport(context, *shader, &support)); // Set vertices D3D11_MAPPED_SUBRESOURCE mappedResource; ANGLE_TRY(mRenderer->mapResource(context, mVertexBuffer.get(), 0, D3D11_MAP_WRITE_DISCARD, 0, &mappedResource)); UINT stride = 0; UINT drawCount = 0; D3D11_PRIMITIVE_TOPOLOGY topology; support.vertexWriteFunction(sourceArea, sourceSize, destArea, destSize, mappedResource.pData, &stride, &drawCount, &topology); deviceContext->Unmap(mVertexBuffer.get(), 0); StateManager11 *stateManager = mRenderer->getStateManager(); // Apply vertex buffer stateManager->setSingleVertexBuffer(&mVertexBuffer, stride, 0); // Apply state if (maskOffAlpha) { ANGLE_TRY(mAlphaMaskBlendState.resolve(GetImplAs(context), mRenderer)); stateManager->setSimpleBlendState(&mAlphaMaskBlendState.getObj()); } else { stateManager->setSimpleBlendState(nullptr); } stateManager->setDepthStencilState(nullptr, 0xFFFFFFFF); if (scissor) { stateManager->setSimpleScissorRect(*scissor); stateManager->setRasterizerState(&mScissorEnabledRasterizerState); } else { stateManager->setRasterizerState(&mScissorDisabledRasterizerState); } // Apply shaders stateManager->setInputLayout(support.inputLayout); stateManager->setPrimitiveTopology(topology); stateManager->setDrawShaders(support.vertexShader, support.geometryShader, &shader->pixelShader); // Apply render target stateManager->setRenderTarget(dest.get(), nullptr); // Set the viewport stateManager->setSimpleViewport(destSize); // Apply texture and sampler switch (filter) { case GL_NEAREST: stateManager->setSimplePixelTextureAndSampler(source, mPointSampler); break; case GL_LINEAR: stateManager->setSimplePixelTextureAndSampler(source, mLinearSampler); break; default: UNREACHABLE(); ANGLE_TRY_HR(GetImplAs(context), E_FAIL, "Internal error, unknown blit filter mode."); } // Draw the quad deviceContext->Draw(drawCount, 0); return angle::Result::Continue; } angle::Result Blit11::copyStencil(const gl::Context *context, const TextureHelper11 &source, unsigned int sourceSubresource, const gl::Box &sourceArea, const gl::Extents &sourceSize, const TextureHelper11 &dest, unsigned int destSubresource, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor) { return copyDepthStencilImpl(context, source, sourceSubresource, sourceArea, sourceSize, dest, destSubresource, destArea, destSize, scissor, true); } angle::Result Blit11::copyDepth(const gl::Context *context, const d3d11::SharedSRV &source, const gl::Box &sourceArea, const gl::Extents &sourceSize, const d3d11::DepthStencilView &dest, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor) { ANGLE_TRY(initResources(context)); ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); // Set vertices D3D11_MAPPED_SUBRESOURCE mappedResource; ANGLE_TRY(mRenderer->mapResource(context, mVertexBuffer.get(), 0, D3D11_MAP_WRITE_DISCARD, 0, &mappedResource)); UINT stride = 0; UINT drawCount = 0; D3D11_PRIMITIVE_TOPOLOGY topology; Write2DVertices(sourceArea, sourceSize, destArea, destSize, mappedResource.pData, &stride, &drawCount, &topology); deviceContext->Unmap(mVertexBuffer.get(), 0); StateManager11 *stateManager = mRenderer->getStateManager(); // Apply vertex buffer stateManager->setSingleVertexBuffer(&mVertexBuffer, stride, 0); // Apply state stateManager->setSimpleBlendState(nullptr); stateManager->setDepthStencilState(&mDepthStencilState, 0xFFFFFFFF); if (scissor) { stateManager->setSimpleScissorRect(*scissor); stateManager->setRasterizerState(&mScissorEnabledRasterizerState); } else { stateManager->setRasterizerState(&mScissorDisabledRasterizerState); } Context11 *context11 = GetImplAs(context); ANGLE_TRY(mQuad2DIL.resolve(context11, mRenderer)); ANGLE_TRY(mQuad2DVS.resolve(context11, mRenderer)); ANGLE_TRY(mDepthPS.resolve(context11, mRenderer)); // Apply shaders stateManager->setInputLayout(&mQuad2DIL.getObj()); stateManager->setPrimitiveTopology(topology); stateManager->setDrawShaders(&mQuad2DVS.getObj(), nullptr, &mDepthPS.getObj()); // Apply render target stateManager->setRenderTarget(nullptr, dest.get()); // Set the viewport stateManager->setSimpleViewport(destSize); // Apply texture and sampler stateManager->setSimplePixelTextureAndSampler(source, mPointSampler); // Draw the quad deviceContext->Draw(drawCount, 0); return angle::Result::Continue; } angle::Result Blit11::copyDepthStencil(const gl::Context *context, const TextureHelper11 &source, unsigned int sourceSubresource, const gl::Box &sourceArea, const gl::Extents &sourceSize, const TextureHelper11 &dest, unsigned int destSubresource, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor) { return copyDepthStencilImpl(context, source, sourceSubresource, sourceArea, sourceSize, dest, destSubresource, destArea, destSize, scissor, false); } angle::Result Blit11::copyDepthStencilImpl(const gl::Context *context, const TextureHelper11 &source, unsigned int sourceSubresource, const gl::Box &sourceArea, const gl::Extents &sourceSize, const TextureHelper11 &dest, unsigned int destSubresource, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor, bool stencilOnly) { auto srcDXGIFormat = source.getFormat(); const auto &srcSizeInfo = d3d11::GetDXGIFormatSizeInfo(srcDXGIFormat); unsigned int srcPixelSize = srcSizeInfo.pixelBytes; unsigned int copyOffset = 0; unsigned int copySize = srcPixelSize; auto destDXGIFormat = dest.getFormat(); const auto &destSizeInfo = d3d11::GetDXGIFormatSizeInfo(destDXGIFormat); unsigned int destPixelSize = destSizeInfo.pixelBytes; ASSERT(srcDXGIFormat == destDXGIFormat || destDXGIFormat == DXGI_FORMAT_R32_TYPELESS); if (stencilOnly) { const auto &srcFormat = source.getFormatSet().format(); // Stencil channel should be right after the depth channel. Some views to depth/stencil // resources have red channel for depth, in which case the depth channel bit width is in // redBits. ASSERT((srcFormat.redBits != 0) != (srcFormat.depthBits != 0)); GLuint depthBits = srcFormat.redBits + srcFormat.depthBits; // Known formats have either 24 or 32 bits of depth. ASSERT(depthBits == 24 || depthBits == 32); copyOffset = depthBits / 8; // Stencil is assumed to be 8-bit - currently this is true for all possible formats. copySize = 1; } if (srcDXGIFormat != destDXGIFormat) { if (srcDXGIFormat == DXGI_FORMAT_R24G8_TYPELESS) { ASSERT(sourceArea == destArea && sourceSize == destSize && scissor == nullptr); return copyAndConvert(context, source, sourceSubresource, sourceArea, sourceSize, dest, destSubresource, destArea, destSize, scissor, copyOffset, copyOffset, copySize, srcPixelSize, destPixelSize, BlitD24S8ToD32F); } ASSERT(srcDXGIFormat == DXGI_FORMAT_R32G8X24_TYPELESS); return copyAndConvert(context, source, sourceSubresource, sourceArea, sourceSize, dest, destSubresource, destArea, destSize, scissor, copyOffset, copyOffset, copySize, srcPixelSize, destPixelSize, BlitD32FS8ToD32F); } return copyAndConvert(context, source, sourceSubresource, sourceArea, sourceSize, dest, destSubresource, destArea, destSize, scissor, copyOffset, copyOffset, copySize, srcPixelSize, destPixelSize, StretchedBlitNearest); } angle::Result Blit11::copyAndConvertImpl(const gl::Context *context, const TextureHelper11 &source, unsigned int sourceSubresource, const gl::Box &sourceArea, const gl::Extents &sourceSize, const TextureHelper11 &destStaging, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor, size_t readOffset, size_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, BlitConvertFunction *convertFunction) { ANGLE_TRY(initResources(context)); ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); TextureHelper11 sourceStaging; ANGLE_TRY(mRenderer->createStagingTexture(context, ResourceType::Texture2D, source.getFormatSet(), sourceSize, StagingAccess::READ, &sourceStaging)); deviceContext->CopySubresourceRegion(sourceStaging.get(), 0, 0, 0, 0, source.get(), sourceSubresource, nullptr); D3D11_MAPPED_SUBRESOURCE sourceMapping; ANGLE_TRY( mRenderer->mapResource(context, sourceStaging.get(), 0, D3D11_MAP_READ, 0, &sourceMapping)); D3D11_MAPPED_SUBRESOURCE destMapping; angle::Result error = mRenderer->mapResource(context, destStaging.get(), 0, D3D11_MAP_WRITE, 0, &destMapping); if (error == angle::Result::Stop) { deviceContext->Unmap(sourceStaging.get(), 0); return error; } // Clip dest area to the destination size gl::Rectangle clipRect = gl::Rectangle(0, 0, destSize.width, destSize.height); // Clip dest area to the scissor if (scissor) { if (!gl::ClipRectangle(clipRect, *scissor, &clipRect)) { return angle::Result::Continue; } } convertFunction(sourceArea, destArea, clipRect, sourceSize, sourceMapping.RowPitch, destMapping.RowPitch, readOffset, writeOffset, copySize, srcPixelStride, destPixelStride, static_cast(sourceMapping.pData), static_cast(destMapping.pData)); deviceContext->Unmap(sourceStaging.get(), 0); deviceContext->Unmap(destStaging.get(), 0); return angle::Result::Continue; } angle::Result Blit11::copyAndConvert(const gl::Context *context, const TextureHelper11 &source, unsigned int sourceSubresource, const gl::Box &sourceArea, const gl::Extents &sourceSize, const TextureHelper11 &dest, unsigned int destSubresource, const gl::Box &destArea, const gl::Extents &destSize, const gl::Rectangle *scissor, size_t readOffset, size_t writeOffset, size_t copySize, size_t srcPixelStride, size_t destPixelStride, BlitConvertFunction *convertFunction) { ANGLE_TRY(initResources(context)); ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); // HACK: Create the destination staging buffer as a read/write texture so // ID3D11DevicContext::UpdateSubresource can be called // using it's mapped data as a source TextureHelper11 destStaging; ANGLE_TRY(mRenderer->createStagingTexture(context, ResourceType::Texture2D, dest.getFormatSet(), destSize, StagingAccess::READ_WRITE, &destStaging)); deviceContext->CopySubresourceRegion(destStaging.get(), 0, 0, 0, 0, dest.get(), destSubresource, nullptr); ANGLE_TRY(copyAndConvertImpl(context, source, sourceSubresource, sourceArea, sourceSize, destStaging, destArea, destSize, scissor, readOffset, writeOffset, copySize, srcPixelStride, destPixelStride, convertFunction)); // Work around timeouts/TDRs in older NVIDIA drivers. if (mRenderer->getFeatures().depthStencilBlitExtraCopy.enabled) { D3D11_MAPPED_SUBRESOURCE mapped; ANGLE_TRY( mRenderer->mapResource(context, destStaging.get(), 0, D3D11_MAP_READ, 0, &mapped)); deviceContext->UpdateSubresource(dest.get(), destSubresource, nullptr, mapped.pData, mapped.RowPitch, mapped.DepthPitch); deviceContext->Unmap(destStaging.get(), 0); } else { deviceContext->CopySubresourceRegion(dest.get(), destSubresource, 0, 0, 0, destStaging.get(), 0, nullptr); } return angle::Result::Continue; } angle::Result Blit11::addBlitShaderToMap(const gl::Context *context, BlitShaderType blitShaderType, ShaderDimension dimension, const ShaderData &shaderData, const char *name) { ASSERT(mBlitShaderMap.find(blitShaderType) == mBlitShaderMap.end()); d3d11::PixelShader ps; ANGLE_TRY(mRenderer->allocateResource(GetImplAs(context), shaderData, &ps)); ps.setInternalName(name); Shader shader; shader.dimension = dimension; shader.pixelShader = std::move(ps); mBlitShaderMap[blitShaderType] = std::move(shader); return angle::Result::Continue; } angle::Result Blit11::addSwizzleShaderToMap(const gl::Context *context, SwizzleShaderType swizzleShaderType, ShaderDimension dimension, const ShaderData &shaderData, const char *name) { ASSERT(mSwizzleShaderMap.find(swizzleShaderType) == mSwizzleShaderMap.end()); d3d11::PixelShader ps; ANGLE_TRY(mRenderer->allocateResource(GetImplAs(context), shaderData, &ps)); ps.setInternalName(name); Shader shader; shader.dimension = dimension; shader.pixelShader = std::move(ps); mSwizzleShaderMap[swizzleShaderType] = std::move(shader); return angle::Result::Continue; } void Blit11::clearShaderMap() { mBlitShaderMap.clear(); mSwizzleShaderMap.clear(); } Blit11::BlitShaderOperation Blit11::getBlitShaderOperation(GLenum destinationFormat, GLenum sourceFormat, bool isSrcSigned, bool isDestSigned, bool unpackPremultiplyAlpha, bool unpackUnmultiplyAlpha, GLenum destTypeForDownsampling) { bool floatToIntBlit = !gl::IsIntegerFormat(sourceFormat) && gl::IsIntegerFormat(destinationFormat); if (isSrcSigned) { ASSERT(!unpackPremultiplyAlpha && !unpackUnmultiplyAlpha); switch (destinationFormat) { case GL_RGBA_INTEGER: return RGBAI; case GL_RGB_INTEGER: return RGBI; case GL_RG_INTEGER: return RGI; case GL_RED_INTEGER: return RI; default: UNREACHABLE(); return OPERATION_INVALID; } } else if (isDestSigned) { ASSERT(floatToIntBlit); switch (destinationFormat) { case GL_RGBA_INTEGER: if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBAF_TOI; } return unpackPremultiplyAlpha ? RGBAF_TOI_PREMULTIPLY : RGBAF_TOI_UNMULTIPLY; case GL_RGB_INTEGER: case GL_RG_INTEGER: case GL_RED_INTEGER: if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBF_TOI; } return unpackPremultiplyAlpha ? RGBF_TOI_PREMULTIPLY : RGBF_TOI_UNMULTIPLY; default: UNREACHABLE(); return OPERATION_INVALID; } } else { // Check for the downsample formats first switch (destTypeForDownsampling) { case GL_UNSIGNED_SHORT_4_4_4_4: ASSERT(destinationFormat == GL_RGBA && !floatToIntBlit); if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBAF_4444; } else if (unpackPremultiplyAlpha) { return RGBAF_4444_PREMULTIPLY; } else { return RGBAF_4444_UNMULTIPLY; } case GL_UNSIGNED_SHORT_5_6_5: ASSERT(destinationFormat == GL_RGB && !floatToIntBlit); if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBF_565; } else { return unpackPremultiplyAlpha ? RGBF_565_PREMULTIPLY : RGBF_565_UNMULTIPLY; } case GL_UNSIGNED_SHORT_5_5_5_1: if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBAF_5551; } else { return unpackPremultiplyAlpha ? RGBAF_5551_PREMULTIPLY : RGBAF_5551_UNMULTIPLY; } default: // By default, use the regular passthrough/multiply/unmultiply shaders. The above // shaders are only needed for some emulated texture formats. break; } if (unpackPremultiplyAlpha != unpackUnmultiplyAlpha || floatToIntBlit) { switch (destinationFormat) { case GL_RGBA: case GL_BGRA_EXT: ASSERT(!floatToIntBlit); return unpackPremultiplyAlpha ? RGBAF_PREMULTIPLY : RGBAF_UNMULTIPLY; case GL_RGB: case GL_RG: case GL_RED: if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBF_TOUI; } else { return unpackPremultiplyAlpha ? RGBF_PREMULTIPLY : RGBF_UNMULTIPLY; } case GL_RGBA_INTEGER: if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBAF_TOUI; } else { return unpackPremultiplyAlpha ? RGBAF_TOUI_PREMULTIPLY : RGBAF_TOUI_UNMULTIPLY; } case GL_RGB_INTEGER: case GL_RG_INTEGER: case GL_RED_INTEGER: if (unpackPremultiplyAlpha == unpackUnmultiplyAlpha) { return RGBF_TOUI; } else { return unpackPremultiplyAlpha ? RGBF_TOUI_PREMULTIPLY : RGBF_TOUI_UNMULTIPLY; } case GL_LUMINANCE: ASSERT(!floatToIntBlit); return unpackPremultiplyAlpha ? LUMAF_PREMULTIPLY : LUMAF_UNMULTIPLY; case GL_LUMINANCE_ALPHA: ASSERT(!floatToIntBlit); return unpackPremultiplyAlpha ? LUMAALPHAF_PREMULTIPLY : LUMAALPHAF_UNMULTIPLY; case GL_ALPHA: return ALPHA; default: UNREACHABLE(); return OPERATION_INVALID; } } else { switch (destinationFormat) { case GL_RGBA: return RGBAF; case GL_RGBA_INTEGER: return RGBAUI; case GL_BGRA_EXT: return BGRAF; case GL_RGB: return RGBF; case GL_RGB_INTEGER: return RGBUI; case GL_RG: return RGF; case GL_RG_INTEGER: return RGUI; case GL_RED: return RF; case GL_RED_INTEGER: return RUI; case GL_ALPHA: return ALPHA; case GL_LUMINANCE: return LUMA; case GL_LUMINANCE_ALPHA: return LUMAALPHA; default: UNREACHABLE(); return OPERATION_INVALID; } } } } angle::Result Blit11::getBlitShader(const gl::Context *context, GLenum destFormat, GLenum sourceFormat, bool isSrcSigned, bool isDestSigned, bool unpackPremultiplyAlpha, bool unpackUnmultiplyAlpha, GLenum destTypeForDownsampling, ShaderDimension dimension, const Shader **shader) { BlitShaderOperation blitShaderOperation = OPERATION_INVALID; blitShaderOperation = getBlitShaderOperation(destFormat, sourceFormat, isSrcSigned, isDestSigned, unpackPremultiplyAlpha, unpackUnmultiplyAlpha, destTypeForDownsampling); BlitShaderType blitShaderType = BLITSHADER_INVALID; blitShaderType = getBlitShaderType(blitShaderOperation, dimension); ANGLE_CHECK_HR(GetImplAs(context), blitShaderType != BLITSHADER_INVALID, "Internal blit shader type mismatch", E_FAIL); auto blitShaderIt = mBlitShaderMap.find(blitShaderType); if (blitShaderIt != mBlitShaderMap.end()) { *shader = &blitShaderIt->second; return angle::Result::Continue; } ASSERT(dimension == SHADER_2D || mRenderer->isES3Capable()); ANGLE_TRY(mapBlitShader(context, blitShaderType)); blitShaderIt = mBlitShaderMap.find(blitShaderType); ASSERT(blitShaderIt != mBlitShaderMap.end()); *shader = &blitShaderIt->second; return angle::Result::Continue; } angle::Result Blit11::getSwizzleShader(const gl::Context *context, GLenum type, D3D11_SRV_DIMENSION viewDimension, const Shader **shader) { SwizzleShaderType swizzleShaderType = GetSwizzleShaderType(type, viewDimension); ANGLE_CHECK_HR(GetImplAs(context), swizzleShaderType != SWIZZLESHADER_INVALID, "Swizzle shader type not found", E_FAIL); auto swizzleShaderIt = mSwizzleShaderMap.find(swizzleShaderType); if (swizzleShaderIt != mSwizzleShaderMap.end()) { *shader = &swizzleShaderIt->second; return angle::Result::Continue; } // Swizzling shaders (OpenGL ES 3+) ASSERT(mRenderer->isES3Capable()); switch (swizzleShaderType) { case SWIZZLESHADER_2D_FLOAT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_2D, ShaderData(g_PS_SwizzleF2D), "Blit11 2D F swizzle pixel shader")); break; case SWIZZLESHADER_2D_UINT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_2D, ShaderData(g_PS_SwizzleUI2D), "Blit11 2D UI swizzle pixel shader")); break; case SWIZZLESHADER_2D_INT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_2D, ShaderData(g_PS_SwizzleI2D), "Blit11 2D I swizzle pixel shader")); break; case SWIZZLESHADER_CUBE_FLOAT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleF2DArray), "Blit11 2D Cube F swizzle pixel shader")); break; case SWIZZLESHADER_CUBE_UINT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleUI2DArray), "Blit11 2D Cube UI swizzle pixel shader")); break; case SWIZZLESHADER_CUBE_INT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleI2DArray), "Blit11 2D Cube I swizzle pixel shader")); break; case SWIZZLESHADER_3D_FLOAT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleF3D), "Blit11 3D F swizzle pixel shader")); break; case SWIZZLESHADER_3D_UINT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleUI3D), "Blit11 3D UI swizzle pixel shader")); break; case SWIZZLESHADER_3D_INT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleI3D), "Blit11 3D I swizzle pixel shader")); break; case SWIZZLESHADER_ARRAY_FLOAT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleF2DArray), "Blit11 2D Array F swizzle pixel shader")); break; case SWIZZLESHADER_ARRAY_UINT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleUI2DArray), "Blit11 2D Array UI swizzle pixel shader")); break; case SWIZZLESHADER_ARRAY_INT: ANGLE_TRY(addSwizzleShaderToMap(context, swizzleShaderType, SHADER_3D, ShaderData(g_PS_SwizzleI2DArray), "Blit11 2D Array I swizzle pixel shader")); break; default: ANGLE_HR_UNREACHABLE(GetImplAs(context)); } swizzleShaderIt = mSwizzleShaderMap.find(swizzleShaderType); ASSERT(swizzleShaderIt != mSwizzleShaderMap.end()); *shader = &swizzleShaderIt->second; return angle::Result::Continue; } angle::Result Blit11::resolveDepth(const gl::Context *context, RenderTarget11 *depth, TextureHelper11 *textureOut) { ANGLE_TRY(initResources(context)); // Multisampled depth stencil SRVs are not available in feature level 10.0 ASSERT(mRenderer->getRenderer11DeviceCaps().featureLevel > D3D_FEATURE_LEVEL_10_0); const auto &extents = depth->getExtents(); auto *deviceContext = mRenderer->getDeviceContext(); auto *stateManager = mRenderer->getStateManager(); ANGLE_TRY(initResolveDepthOnly(context, depth->getFormatSet(), extents)); Context11 *context11 = GetImplAs(context); ANGLE_TRY(mResolveDepthStencilVS.resolve(context11, mRenderer)); ANGLE_TRY(mResolveDepthPS.resolve(context11, mRenderer)); // Apply the necessary state changes to the D3D11 immediate device context. stateManager->setInputLayout(nullptr); stateManager->setPrimitiveTopology(D3D11_PRIMITIVE_TOPOLOGY_TRIANGLELIST); stateManager->setDrawShaders(&mResolveDepthStencilVS.getObj(), nullptr, &mResolveDepthPS.getObj()); stateManager->setRasterizerState(nullptr); stateManager->setDepthStencilState(&mDepthStencilState, 0xFFFFFFFF); stateManager->setRenderTargets(nullptr, 0, mResolvedDepthDSView.get()); stateManager->setSimpleBlendState(nullptr); stateManager->setSimpleViewport(extents); // Set the viewport const d3d11::SharedSRV *srv; ANGLE_TRY(depth->getShaderResourceView(context, &srv)); stateManager->setShaderResourceShared(gl::ShaderType::Fragment, 0, srv); // Trigger the blit on the GPU. deviceContext->Draw(6, 0); *textureOut = mResolvedDepth; return angle::Result::Continue; } angle::Result Blit11::initResolveDepthOnly(const gl::Context *context, const d3d11::Format &format, const gl::Extents &extents) { if (mResolvedDepth.valid() && extents == mResolvedDepth.getExtents() && format.texFormat == mResolvedDepth.getFormat()) { return angle::Result::Continue; } D3D11_TEXTURE2D_DESC textureDesc; textureDesc.Width = extents.width; textureDesc.Height = extents.height; textureDesc.MipLevels = 1; textureDesc.ArraySize = 1; textureDesc.Format = format.texFormat; textureDesc.SampleDesc.Count = 1; textureDesc.SampleDesc.Quality = 0; textureDesc.Usage = D3D11_USAGE_DEFAULT; textureDesc.BindFlags = D3D11_BIND_DEPTH_STENCIL | D3D11_BIND_SHADER_RESOURCE; textureDesc.CPUAccessFlags = 0; textureDesc.MiscFlags = 0; Context11 *context11 = GetImplAs(context); ANGLE_TRY(mRenderer->allocateTexture(context11, textureDesc, format, &mResolvedDepth)); mResolvedDepth.setInternalName("Blit11::mResolvedDepth"); D3D11_DEPTH_STENCIL_VIEW_DESC dsvDesc; dsvDesc.Flags = 0; dsvDesc.Format = format.dsvFormat; dsvDesc.Texture2D.MipSlice = 0; dsvDesc.ViewDimension = D3D11_DSV_DIMENSION_TEXTURE2D; ANGLE_TRY(mRenderer->allocateResource(context11, dsvDesc, mResolvedDepth.get(), &mResolvedDepthDSView)); mResolvedDepthDSView.setInternalName("Blit11::mResolvedDepthDSView"); // Possibly D3D11 bug or undefined behaviour: Clear the DSV so that our first render // works as expected. Otherwise the results of the first use seem to be incorrect. ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); deviceContext->ClearDepthStencilView(mResolvedDepthDSView.get(), D3D11_CLEAR_DEPTH, 1.0f, 0); return angle::Result::Continue; } angle::Result Blit11::initResolveDepthStencil(const gl::Context *context, const gl::Extents &extents) { // Check if we need to recreate depth stencil view if (mResolvedDepthStencil.valid() && extents == mResolvedDepthStencil.getExtents()) { ASSERT(mResolvedDepthStencil.getFormat() == DXGI_FORMAT_R32G32_FLOAT); return angle::Result::Continue; } if (mResolvedDepthStencil.valid()) { releaseResolveDepthStencilResources(); } const auto &formatSet = d3d11::Format::Get(GL_RG32F, mRenderer->getRenderer11DeviceCaps()); D3D11_TEXTURE2D_DESC textureDesc; textureDesc.Width = extents.width; textureDesc.Height = extents.height; textureDesc.MipLevels = 1; textureDesc.ArraySize = 1; textureDesc.Format = formatSet.texFormat; textureDesc.SampleDesc.Count = 1; textureDesc.SampleDesc.Quality = 0; textureDesc.Usage = D3D11_USAGE_DEFAULT; textureDesc.BindFlags = D3D11_BIND_RENDER_TARGET; textureDesc.CPUAccessFlags = 0; textureDesc.MiscFlags = 0; Context11 *context11 = GetImplAs(context); ANGLE_TRY( mRenderer->allocateTexture(context11, textureDesc, formatSet, &mResolvedDepthStencil)); mResolvedDepthStencil.setInternalName("Blit11::mResolvedDepthStencil"); ANGLE_TRY(mRenderer->allocateResourceNoDesc(context11, mResolvedDepthStencil.get(), &mResolvedDepthStencilRTView)); mResolvedDepthStencilRTView.setInternalName("Blit11::mResolvedDepthStencilRTView"); return angle::Result::Continue; } angle::Result Blit11::resolveStencil(const gl::Context *context, RenderTarget11 *depthStencil, bool alsoDepth, TextureHelper11 *textureOut) { ANGLE_TRY(initResources(context)); // Multisampled depth stencil SRVs are not available in feature level 10.0 ASSERT(mRenderer->getRenderer11DeviceCaps().featureLevel > D3D_FEATURE_LEVEL_10_0); const auto &extents = depthStencil->getExtents(); ANGLE_TRY(initResolveDepthStencil(context, extents)); ID3D11DeviceContext *deviceContext = mRenderer->getDeviceContext(); auto *stateManager = mRenderer->getStateManager(); ID3D11Resource *stencilResource = depthStencil->getTexture().get(); // Check if we need to re-create the stencil SRV. if (mStencilSRV.valid()) { ID3D11Resource *priorResource = nullptr; mStencilSRV.get()->GetResource(&priorResource); if (stencilResource != priorResource) { mStencilSRV.reset(); } SafeRelease(priorResource); } Context11 *context11 = GetImplAs(context); if (!mStencilSRV.valid()) { D3D11_SHADER_RESOURCE_VIEW_DESC srViewDesc; srViewDesc.Format = GetStencilSRVFormat(depthStencil->getFormatSet()); srViewDesc.ViewDimension = D3D11_SRV_DIMENSION_TEXTURE2DMS; ANGLE_TRY( mRenderer->allocateResource(context11, srViewDesc, stencilResource, &mStencilSRV)); mStencilSRV.setInternalName("Blit11::mStencilSRV"); } // Notify the Renderer that all state should be invalidated. ANGLE_TRY(mResolveDepthStencilVS.resolve(context11, mRenderer)); // Resolving the depth buffer works by sampling the depth in the shader using a SRV, then // writing to the resolved depth buffer using SV_Depth. We can't use this method for stencil // because SV_StencilRef isn't supported until HLSL 5.1/D3D11.3. const d3d11::PixelShader *pixelShader = nullptr; if (alsoDepth) { ANGLE_TRY(mResolveDepthStencilPS.resolve(context11, mRenderer)); pixelShader = &mResolveDepthStencilPS.getObj(); } else { ANGLE_TRY(mResolveStencilPS.resolve(context11, mRenderer)); pixelShader = &mResolveStencilPS.getObj(); } // Apply the necessary state changes to the D3D11 immediate device context. stateManager->setInputLayout(nullptr); stateManager->setPrimitiveTopology(D3D11_PRIMITIVE_TOPOLOGY_TRIANGLELIST); stateManager->setDrawShaders(&mResolveDepthStencilVS.getObj(), nullptr, pixelShader); stateManager->setRasterizerState(nullptr); stateManager->setDepthStencilState(nullptr, 0xFFFFFFFF); stateManager->setRenderTarget(mResolvedDepthStencilRTView.get(), nullptr); stateManager->setSimpleBlendState(nullptr); // Set the viewport stateManager->setSimpleViewport(extents); const d3d11::SharedSRV *srv; ANGLE_TRY(depthStencil->getShaderResourceView(context, &srv)); stateManager->setShaderResourceShared(gl::ShaderType::Fragment, 0, srv); stateManager->setShaderResource(gl::ShaderType::Fragment, 1, &mStencilSRV); // Trigger the blit on the GPU. deviceContext->Draw(6, 0); gl::Box copyBox(0, 0, 0, extents.width, extents.height, 1); ANGLE_TRY(mRenderer->createStagingTexture(context, ResourceType::Texture2D, depthStencil->getFormatSet(), extents, StagingAccess::READ_WRITE, textureOut)); const auto ©Function = GetCopyDepthStencilFunction(depthStencil->getInternalFormat()); const auto &dsFormatSet = depthStencil->getFormatSet(); const auto &dsDxgiInfo = d3d11::GetDXGIFormatSizeInfo(dsFormatSet.texFormat); ANGLE_TRY(copyAndConvertImpl(context, mResolvedDepthStencil, 0, copyBox, extents, *textureOut, copyBox, extents, nullptr, 0, 0, 0, 8u, dsDxgiInfo.pixelBytes, copyFunction)); return angle::Result::Continue; } void Blit11::releaseResolveDepthStencilResources() { mStencilSRV.reset(); mResolvedDepthStencilRTView.reset(); } } // namespace rx