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//
// Copyright 2012 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.
//
// InputLayoutCache.cpp: Defines InputLayoutCache, a class that builds and caches
// D3D11 input layouts.
#include "libANGLE/renderer/d3d/d3d11/InputLayoutCache.h"
#include "common/bitset_utils.h"
#include "common/utilities.h"
#include "libANGLE/Context.h"
#include "libANGLE/Program.h"
#include "libANGLE/VertexArray.h"
#include "libANGLE/VertexAttribute.h"
#include "libANGLE/renderer/d3d/IndexDataManager.h"
#include "libANGLE/renderer/d3d/ProgramD3D.h"
#include "libANGLE/renderer/d3d/VertexDataManager.h"
#include "libANGLE/renderer/d3d/d3d11/Context11.h"
#include "libANGLE/renderer/d3d/d3d11/Renderer11.h"
#include "libANGLE/renderer/d3d/d3d11/ShaderExecutable11.h"
#include "libANGLE/renderer/d3d/d3d11/VertexArray11.h"
#include "libANGLE/renderer/d3d/d3d11/formatutils11.h"
namespace rx
{
namespace
{
GLenum GetGLSLAttributeType(const std::vector<sh::ShaderVariable> &shaderAttributes, size_t index)
{
// Count matrices differently
for (const sh::ShaderVariable &attrib : shaderAttributes)
{
if (attrib.location == -1)
{
continue;
}
GLenum transposedType = gl::TransposeMatrixType(attrib.type);
int rows = gl::VariableRowCount(transposedType);
int intIndex = static_cast<int>(index);
if (intIndex >= attrib.location && intIndex < attrib.location + rows)
{
return transposedType;
}
}
UNREACHABLE();
return GL_NONE;
}
struct PackedAttribute
{
uint8_t attribType;
uint8_t semanticIndex;
uint8_t vertexFormatType;
uint8_t unusedPadding;
uint32_t divisor;
};
} // anonymous namespace
PackedAttributeLayout::PackedAttributeLayout() : numAttributes(0), flags(0), attributeData({}) {}
PackedAttributeLayout::PackedAttributeLayout(const PackedAttributeLayout &other) = default;
void PackedAttributeLayout::addAttributeData(GLenum glType,
UINT semanticIndex,
angle::FormatID vertexFormatID,
unsigned int divisor)
{
gl::AttributeType attribType = gl::GetAttributeType(glType);
PackedAttribute packedAttrib;
packedAttrib.attribType = static_cast<uint8_t>(attribType);
packedAttrib.semanticIndex = static_cast<uint8_t>(semanticIndex);
packedAttrib.vertexFormatType = static_cast<uint8_t>(vertexFormatID);
packedAttrib.unusedPadding = 0u;
packedAttrib.divisor = static_cast<uint32_t>(divisor);
ASSERT(static_cast<gl::AttributeType>(packedAttrib.attribType) == attribType);
ASSERT(static_cast<UINT>(packedAttrib.semanticIndex) == semanticIndex);
ASSERT(static_cast<angle::FormatID>(packedAttrib.vertexFormatType) == vertexFormatID);
ASSERT(static_cast<unsigned int>(packedAttrib.divisor) == divisor);
static_assert(sizeof(uint64_t) == sizeof(PackedAttribute),
"PackedAttributes must be 64-bits exactly.");
attributeData[numAttributes++] = gl::bitCast<uint64_t>(packedAttrib);
}
bool PackedAttributeLayout::operator==(const PackedAttributeLayout &other) const
{
return (numAttributes == other.numAttributes) && (flags == other.flags) &&
(attributeData == other.attributeData);
}
InputLayoutCache::InputLayoutCache() : mLayoutCache(kDefaultCacheSize * 2) {}
InputLayoutCache::~InputLayoutCache() {}
void InputLayoutCache::clear()
{
mLayoutCache.Clear();
}
angle::Result InputLayoutCache::getInputLayout(
Context11 *context11,
const gl::State &state,
const std::vector<const TranslatedAttribute *> ¤tAttributes,
const AttribIndexArray &sortedSemanticIndices,
gl::PrimitiveMode mode,
GLsizei vertexCount,
GLsizei instances,
const d3d11::InputLayout **inputLayoutOut)
{
gl::Program *program = state.getProgram();
const auto &shaderAttributes = program->getAttributes();
PackedAttributeLayout layout;
ProgramD3D *programD3D = GetImplAs<ProgramD3D>(program);
bool programUsesInstancedPointSprites =
programD3D->usesPointSize() && programD3D->usesInstancedPointSpriteEmulation();
bool instancedPointSpritesActive =
programUsesInstancedPointSprites && (mode == gl::PrimitiveMode::Points);
if (programUsesInstancedPointSprites)
{
layout.flags |= PackedAttributeLayout::FLAG_USES_INSTANCED_SPRITES;
}
if (instancedPointSpritesActive)
{
layout.flags |= PackedAttributeLayout::FLAG_INSTANCED_SPRITES_ACTIVE;
}
if (instances > 0)
{
layout.flags |= PackedAttributeLayout::FLAG_INSTANCED_RENDERING_ACTIVE;
}
const auto &attribs = state.getVertexArray()->getVertexAttributes();
const auto &bindings = state.getVertexArray()->getVertexBindings();
const auto &locationToSemantic = programD3D->getAttribLocationToD3DSemantics();
int divisorMultiplier = program->usesMultiview() ? program->getNumViews() : 1;
for (size_t attribIndex : state.getProgramExecutable()->getActiveAttribLocationsMask())
{
// Record the type of the associated vertex shader vector in our key
// This will prevent mismatched vertex shaders from using the same input layout
GLenum glslElementType = GetGLSLAttributeType(shaderAttributes, attribIndex);
const auto &attrib = attribs[attribIndex];
const auto &binding = bindings[attrib.bindingIndex];
int d3dSemantic = locationToSemantic[attribIndex];
const auto ¤tValue =
state.getVertexAttribCurrentValue(static_cast<unsigned int>(attribIndex));
angle::FormatID vertexFormatID = gl::GetVertexFormatID(attrib, currentValue.Type);
layout.addAttributeData(glslElementType, d3dSemantic, vertexFormatID,
binding.getDivisor() * divisorMultiplier);
}
if (layout.numAttributes > 0 || layout.flags != 0)
{
auto it = mLayoutCache.Get(layout);
if (it != mLayoutCache.end())
{
*inputLayoutOut = &it->second;
}
else
{
angle::TrimCache(mLayoutCache.max_size() / 2, kGCLimit, "input layout", &mLayoutCache);
d3d11::InputLayout newInputLayout;
ANGLE_TRY(createInputLayout(context11, sortedSemanticIndices, currentAttributes, mode,
vertexCount, instances, &newInputLayout));
auto insertIt = mLayoutCache.Put(layout, std::move(newInputLayout));
*inputLayoutOut = &insertIt->second;
}
}
return angle::Result::Continue;
}
angle::Result InputLayoutCache::createInputLayout(
Context11 *context11,
const AttribIndexArray &sortedSemanticIndices,
const std::vector<const TranslatedAttribute *> ¤tAttributes,
gl::PrimitiveMode mode,
GLsizei vertexCount,
GLsizei instances,
d3d11::InputLayout *inputLayoutOut)
{
Renderer11 *renderer = context11->getRenderer();
ProgramD3D *programD3D = renderer->getStateManager()->getProgramD3D();
D3D_FEATURE_LEVEL featureLevel = renderer->getRenderer11DeviceCaps().featureLevel;
bool programUsesInstancedPointSprites =
programD3D->usesPointSize() && programD3D->usesInstancedPointSpriteEmulation();
unsigned int inputElementCount = 0;
gl::AttribArray<D3D11_INPUT_ELEMENT_DESC> inputElements;
for (size_t attribIndex = 0; attribIndex < currentAttributes.size(); ++attribIndex)
{
const auto &attrib = *currentAttributes[attribIndex];
const int sortedIndex = sortedSemanticIndices[attribIndex];
D3D11_INPUT_CLASSIFICATION inputClass =
attrib.divisor > 0 ? D3D11_INPUT_PER_INSTANCE_DATA : D3D11_INPUT_PER_VERTEX_DATA;
angle::FormatID vertexFormatID =
gl::GetVertexFormatID(*attrib.attribute, attrib.currentValueType);
const auto &vertexFormatInfo = d3d11::GetVertexFormatInfo(vertexFormatID, featureLevel);
auto *inputElement = &inputElements[inputElementCount];
inputElement->SemanticName = "TEXCOORD";
inputElement->SemanticIndex = sortedIndex;
inputElement->Format = vertexFormatInfo.nativeFormat;
inputElement->InputSlot = static_cast<UINT>(attribIndex);
inputElement->AlignedByteOffset = 0;
inputElement->InputSlotClass = inputClass;
inputElement->InstanceDataStepRate = attrib.divisor;
inputElementCount++;
}
// Instanced PointSprite emulation requires additional entries in the
// inputlayout to support the vertices that make up the pointsprite quad.
// We do this even if mode != GL_POINTS, since the shader signature has these inputs, and the
// input layout must match the shader
if (programUsesInstancedPointSprites)
{
// On 9_3, we must ensure that slot 0 contains non-instanced data.
// If slot 0 currently contains instanced data then we swap it with a non-instanced element.
// Note that instancing is only available on 9_3 via ANGLE_instanced_arrays, since 9_3
// doesn't support OpenGL ES 3.0.
// As per the spec for ANGLE_instanced_arrays, not all attributes can be instanced
// simultaneously, so a non-instanced element must exist.
UINT numIndicesPerInstance = 0;
if (instances > 0)
{
// This requires that the index range is resolved.
// Note: Vertex indexes can be arbitrarily large.
numIndicesPerInstance = gl::clampCast<UINT>(vertexCount);
}
for (size_t elementIndex = 0; elementIndex < inputElementCount; ++elementIndex)
{
// If rendering points and instanced pointsprite emulation is being used, the
// inputClass is required to be configured as per instance data
if (mode == gl::PrimitiveMode::Points)
{
inputElements[elementIndex].InputSlotClass = D3D11_INPUT_PER_INSTANCE_DATA;
inputElements[elementIndex].InstanceDataStepRate = 1;
if (numIndicesPerInstance > 0 && currentAttributes[elementIndex]->divisor > 0)
{
inputElements[elementIndex].InstanceDataStepRate = numIndicesPerInstance;
}
}
inputElements[elementIndex].InputSlot++;
}
inputElements[inputElementCount].SemanticName = "SPRITEPOSITION";
inputElements[inputElementCount].SemanticIndex = 0;
inputElements[inputElementCount].Format = DXGI_FORMAT_R32G32B32_FLOAT;
inputElements[inputElementCount].InputSlot = 0;
inputElements[inputElementCount].AlignedByteOffset = 0;
inputElements[inputElementCount].InputSlotClass = D3D11_INPUT_PER_VERTEX_DATA;
inputElements[inputElementCount].InstanceDataStepRate = 0;
inputElementCount++;
inputElements[inputElementCount].SemanticName = "SPRITETEXCOORD";
inputElements[inputElementCount].SemanticIndex = 0;
inputElements[inputElementCount].Format = DXGI_FORMAT_R32G32_FLOAT;
inputElements[inputElementCount].InputSlot = 0;
inputElements[inputElementCount].AlignedByteOffset = sizeof(float) * 3;
inputElements[inputElementCount].InputSlotClass = D3D11_INPUT_PER_VERTEX_DATA;
inputElements[inputElementCount].InstanceDataStepRate = 0;
inputElementCount++;
}
ShaderExecutableD3D *shader = nullptr;
ANGLE_TRY(programD3D->getVertexExecutableForCachedInputLayout(context11, &shader, nullptr));
ShaderExecutableD3D *shader11 = GetAs<ShaderExecutable11>(shader);
InputElementArray inputElementArray(inputElements.data(), inputElementCount);
ShaderData vertexShaderData(shader11->getFunction(), shader11->getLength());
ANGLE_TRY(renderer->allocateResource(context11, inputElementArray, &vertexShaderData,
inputLayoutOut));
return angle::Result::Continue;
}
void InputLayoutCache::setCacheSize(size_t newCacheSize)
{
// Forces a reset of the cache.
LayoutCache newCache(newCacheSize);
mLayoutCache.Swap(newCache);
}
} // namespace rx
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