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cobalt / cobalt / b95ea55ccebda33f820d043e4b4dc85c10d7584d / . / third_party / angle / src / libANGLE / renderer / gl / StateManagerGL.cpp
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//
// Copyright 2015 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.
//
// StateManagerGL.h: Defines a class for caching applied OpenGL state
#include "libANGLE/renderer/gl/StateManagerGL.h"
#include <string.h>
#include <algorithm>
#include <limits>
#include "anglebase/numerics/safe_conversions.h"
#include "common/bitset_utils.h"
#include "common/mathutil.h"
#include "common/matrix_utils.h"
#include "libANGLE/Context.h"
#include "libANGLE/Framebuffer.h"
#include "libANGLE/Query.h"
#include "libANGLE/TransformFeedback.h"
#include "libANGLE/VertexArray.h"
#include "libANGLE/renderer/gl/BufferGL.h"
#include "libANGLE/renderer/gl/FramebufferGL.h"
#include "libANGLE/renderer/gl/FunctionsGL.h"
#include "libANGLE/renderer/gl/ProgramGL.h"
#include "libANGLE/renderer/gl/QueryGL.h"
#include "libANGLE/renderer/gl/SamplerGL.h"
#include "libANGLE/renderer/gl/TextureGL.h"
#include "libANGLE/renderer/gl/TransformFeedbackGL.h"
#include "libANGLE/renderer/gl/VertexArrayGL.h"
namespace rx
{
namespace
{
static void ValidateStateHelper(const FunctionsGL *functions,
const GLuint localValue,
const GLenum pname,
const char *localName,
const char *driverName)
{
GLint queryValue;
functions->getIntegerv(pname, &queryValue);
if (localValue != static_cast<GLuint>(queryValue))
{
WARN() << localName << " (" << localValue << ") != " << driverName << " (" << queryValue
<< ")";
// Re-add ASSERT: http://anglebug.com/3900
// ASSERT(false);
}
}
} // anonymous namespace
StateManagerGL::IndexedBufferBinding::IndexedBufferBinding() : offset(0), size(0), buffer(0) {}
StateManagerGL::StateManagerGL(const FunctionsGL *functions,
const gl::Caps &rendererCaps,
const gl::Extensions &extensions,
const angle::FeaturesGL &features)
: mFunctions(functions),
mFeatures(features),
mProgram(0),
mVAO(0),
mVertexAttribCurrentValues(rendererCaps.maxVertexAttributes),
mBuffers(),
mIndexedBuffers(),
mTextureUnitIndex(0),
mTextures{},
mSamplers{},
mImages(rendererCaps.maxImageUnits, ImageUnitBinding()),
mTransformFeedback(0),
mCurrentTransformFeedback(nullptr),
mQueries(),
mPrevDrawContext(0),
mUnpackAlignment(4),
mUnpackRowLength(0),
mUnpackSkipRows(0),
mUnpackSkipPixels(0),
mUnpackImageHeight(0),
mUnpackSkipImages(0),
mPackAlignment(4),
mPackRowLength(0),
mPackSkipRows(0),
mPackSkipPixels(0),
mFramebuffers(angle::FramebufferBindingSingletonMax, 0),
mRenderbuffer(0),
mScissorTestEnabled(false),
mScissor(0, 0, 0, 0),
mViewport(0, 0, 0, 0),
mNear(0.0f),
mFar(1.0f),
mBlendEnabled(false),
mBlendColor(0, 0, 0, 0),
mSourceBlendRGB(GL_ONE),
mDestBlendRGB(GL_ZERO),
mSourceBlendAlpha(GL_ONE),
mDestBlendAlpha(GL_ZERO),
mBlendEquationRGB(GL_FUNC_ADD),
mBlendEquationAlpha(GL_FUNC_ADD),
mColorMaskRed(true),
mColorMaskGreen(true),
mColorMaskBlue(true),
mColorMaskAlpha(true),
mSampleAlphaToCoverageEnabled(false),
mSampleCoverageEnabled(false),
mSampleCoverageValue(1.0f),
mSampleCoverageInvert(false),
mSampleMaskEnabled(false),
mDepthTestEnabled(false),
mDepthFunc(GL_LESS),
mDepthMask(true),
mStencilTestEnabled(false),
mStencilFrontFunc(GL_ALWAYS),
mStencilFrontRef(0),
mStencilFrontValueMask(static_cast<GLuint>(-1)),
mStencilFrontStencilFailOp(GL_KEEP),
mStencilFrontStencilPassDepthFailOp(GL_KEEP),
mStencilFrontStencilPassDepthPassOp(GL_KEEP),
mStencilFrontWritemask(static_cast<GLuint>(-1)),
mStencilBackFunc(GL_ALWAYS),
mStencilBackRef(0),
mStencilBackValueMask(static_cast<GLuint>(-1)),
mStencilBackStencilFailOp(GL_KEEP),
mStencilBackStencilPassDepthFailOp(GL_KEEP),
mStencilBackStencilPassDepthPassOp(GL_KEEP),
mStencilBackWritemask(static_cast<GLuint>(-1)),
mCullFaceEnabled(false),
mCullFace(gl::CullFaceMode::Back),
mFrontFace(GL_CCW),
mPolygonOffsetFillEnabled(false),
mPolygonOffsetFactor(0.0f),
mPolygonOffsetUnits(0.0f),
mRasterizerDiscardEnabled(false),
mLineWidth(1.0f),
mPrimitiveRestartEnabled(false),
mPrimitiveRestartIndex(0),
mClearColor(0.0f, 0.0f, 0.0f, 0.0f),
mClearDepth(1.0f),
mClearStencil(0),
mFramebufferSRGBEnabled(false),
mDitherEnabled(true),
mTextureCubemapSeamlessEnabled(false),
mMultisamplingEnabled(true),
mSampleAlphaToOneEnabled(false),
mCoverageModulation(GL_NONE),
mPathStencilFunc(GL_ALWAYS),
mPathStencilRef(0),
mPathStencilMask(std::numeric_limits<GLuint>::max()),
mIsMultiviewEnabled(extensions.multiview || extensions.multiview2),
mProvokingVertex(GL_LAST_VERTEX_CONVENTION),
mLocalDirtyBits()
{
ASSERT(mFunctions);
ASSERT(extensions.maxViews >= 1u);
mIndexedBuffers[gl::BufferBinding::Uniform].resize(rendererCaps.maxUniformBufferBindings);
mIndexedBuffers[gl::BufferBinding::AtomicCounter].resize(
rendererCaps.maxAtomicCounterBufferBindings);
mIndexedBuffers[gl::BufferBinding::ShaderStorage].resize(
rendererCaps.maxShaderStorageBufferBindings);
mSampleMaskValues.fill(~GLbitfield(0));
mQueries.fill(nullptr);
mTemporaryPausedQueries.fill(nullptr);
// Initialize point sprite state for desktop GL
if (mFunctions->standard == STANDARD_GL_DESKTOP)
{
mFunctions->enable(GL_PROGRAM_POINT_SIZE);
// GL_POINT_SPRITE was deprecated in the core profile. Point rasterization is always
// performed
// as though POINT_SPRITE were enabled.
if ((mFunctions->profile & GL_CONTEXT_CORE_PROFILE_BIT) == 0)
{
mFunctions->enable(GL_POINT_SPRITE);
}
}
angle::Matrix<GLfloat>::setToIdentity(mPathMatrixProj);
angle::Matrix<GLfloat>::setToIdentity(mPathMatrixMV);
}
StateManagerGL::~StateManagerGL() {}
void StateManagerGL::deleteProgram(GLuint program)
{
if (program != 0)
{
if (mProgram == program)
{
useProgram(0);
}
mFunctions->deleteProgram(program);
}
}
void StateManagerGL::deleteVertexArray(GLuint vao)
{
if (vao != 0)
{
if (mVAO == vao)
{
bindVertexArray(0, 0);
}
mFunctions->deleteVertexArrays(1, &vao);
}
}
void StateManagerGL::deleteTexture(GLuint texture)
{
if (texture != 0)
{
for (gl::TextureType type : angle::AllEnums<gl::TextureType>())
{
const auto &textureVector = mTextures[type];
for (size_t textureUnitIndex = 0; textureUnitIndex < textureVector.size();
textureUnitIndex++)
{
if (textureVector[textureUnitIndex] == texture)
{
activeTexture(textureUnitIndex);
bindTexture(type, 0);
}
}
}
for (size_t imageUnitIndex = 0; imageUnitIndex < mImages.size(); imageUnitIndex++)
{
if (mImages[imageUnitIndex].texture == texture)
{
bindImageTexture(imageUnitIndex, 0, 0, false, 0, GL_READ_ONLY, GL_R32UI);
}
}
mFunctions->deleteTextures(1, &texture);
}
}
void StateManagerGL::deleteSampler(GLuint sampler)
{
if (sampler != 0)
{
for (size_t unit = 0; unit < mSamplers.size(); unit++)
{
if (mSamplers[unit] == sampler)
{
bindSampler(unit, 0);
}
}
mFunctions->deleteSamplers(1, &sampler);
}
}
void StateManagerGL::deleteBuffer(GLuint buffer)
{
if (buffer == 0)
{
return;
}
for (auto target : angle::AllEnums<gl::BufferBinding>())
{
if (mBuffers[target] == buffer)
{
bindBuffer(target, 0);
}
auto &indexedTarget = mIndexedBuffers[target];
for (size_t bindIndex = 0; bindIndex < indexedTarget.size(); ++bindIndex)
{
if (indexedTarget[bindIndex].buffer == buffer)
{
bindBufferBase(target, bindIndex, 0);
}
}
}
mFunctions->deleteBuffers(1, &buffer);
}
void StateManagerGL::deleteFramebuffer(GLuint fbo)
{
if (fbo != 0)
{
for (size_t binding = 0; binding < mFramebuffers.size(); ++binding)
{
if (mFramebuffers[binding] == fbo)
{
GLenum enumValue = angle::FramebufferBindingToEnum(
static_cast<angle::FramebufferBinding>(binding));
bindFramebuffer(enumValue, 0);
}
}
mFunctions->deleteFramebuffers(1, &fbo);
}
}
void StateManagerGL::deleteRenderbuffer(GLuint rbo)
{
if (rbo != 0)
{
if (mRenderbuffer == rbo)
{
bindRenderbuffer(GL_RENDERBUFFER, 0);
}
mFunctions->deleteRenderbuffers(1, &rbo);
}
}
void StateManagerGL::deleteTransformFeedback(GLuint transformFeedback)
{
if (transformFeedback != 0)
{
if (mTransformFeedback == transformFeedback)
{
bindTransformFeedback(GL_TRANSFORM_FEEDBACK, 0);
}
if (mCurrentTransformFeedback != nullptr &&
mCurrentTransformFeedback->getTransformFeedbackID() == transformFeedback)
{
mCurrentTransformFeedback = nullptr;
}
mFunctions->deleteTransformFeedbacks(1, &transformFeedback);
}
}
void StateManagerGL::useProgram(GLuint program)
{
if (mProgram != program)
{
forceUseProgram(program);
}
}
void StateManagerGL::forceUseProgram(GLuint program)
{
mProgram = program;
mFunctions->useProgram(mProgram);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PROGRAM_BINDING);
}
void StateManagerGL::bindVertexArray(GLuint vao, GLuint elementArrayBuffer)
{
if (mVAO != vao)
{
mVAO = vao;
mBuffers[gl::BufferBinding::ElementArray] = elementArrayBuffer;
mFunctions->bindVertexArray(vao);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_VERTEX_ARRAY_BINDING);
}
}
void StateManagerGL::bindBuffer(gl::BufferBinding target, GLuint buffer)
{
// GL drivers differ in whether the transform feedback bind point is modified when
// glBindTransformFeedback is called. To avoid these behavior differences we shouldn't try to
// use it.
ASSERT(target != gl::BufferBinding::TransformFeedback);
if (mBuffers[target] != buffer)
{
mBuffers[target] = buffer;
mFunctions->bindBuffer(gl::ToGLenum(target), buffer);
}
}
void StateManagerGL::bindBufferBase(gl::BufferBinding target, size_t index, GLuint buffer)
{
// Transform feedback buffer bindings are tracked in TransformFeedbackGL
ASSERT(target != gl::BufferBinding::TransformFeedback);
ASSERT(index < mIndexedBuffers[target].size());
auto &binding = mIndexedBuffers[target][index];
if (binding.buffer != buffer || binding.offset != static_cast<size_t>(-1) ||
binding.size != static_cast<size_t>(-1))
{
binding.buffer = buffer;
binding.offset = static_cast<size_t>(-1);
binding.size = static_cast<size_t>(-1);
mBuffers[target] = buffer;
mFunctions->bindBufferBase(gl::ToGLenum(target), static_cast<GLuint>(index), buffer);
}
}
void StateManagerGL::bindBufferRange(gl::BufferBinding target,
size_t index,
GLuint buffer,
size_t offset,
size_t size)
{
// Transform feedback buffer bindings are tracked in TransformFeedbackGL
ASSERT(target != gl::BufferBinding::TransformFeedback);
auto &binding = mIndexedBuffers[target][index];
if (binding.buffer != buffer || binding.offset != offset || binding.size != size)
{
binding.buffer = buffer;
binding.offset = offset;
binding.size = size;
mBuffers[target] = buffer;
mFunctions->bindBufferRange(gl::ToGLenum(target), static_cast<GLuint>(index), buffer,
offset, size);
}
}
void StateManagerGL::activeTexture(size_t unit)
{
if (mTextureUnitIndex != unit)
{
mTextureUnitIndex = unit;
mFunctions->activeTexture(GL_TEXTURE0 + static_cast<GLenum>(mTextureUnitIndex));
}
}
void StateManagerGL::bindTexture(gl::TextureType type, GLuint texture)
{
if (mTextures[type][mTextureUnitIndex] != texture)
{
mTextures[type][mTextureUnitIndex] = texture;
mFunctions->bindTexture(ToGLenum(type), texture);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_TEXTURE_BINDINGS);
}
}
void StateManagerGL::invalidateTexture(gl::TextureType type)
{
// Assume the tracked texture binding is incorrect, query the real bound texture from GL.
GLint boundTexture = 0;
mFunctions->getIntegerv(nativegl::GetTextureBindingQuery(type), &boundTexture);
mTextures[type][mTextureUnitIndex] = static_cast<GLuint>(boundTexture);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_TEXTURE_BINDINGS);
}
void StateManagerGL::bindSampler(size_t unit, GLuint sampler)
{
if (mSamplers[unit] != sampler)
{
mSamplers[unit] = sampler;
mFunctions->bindSampler(static_cast<GLuint>(unit), sampler);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLER_BINDINGS);
}
}
void StateManagerGL::bindImageTexture(size_t unit,
GLuint texture,
GLint level,
GLboolean layered,
GLint layer,
GLenum access,
GLenum format)
{
auto &binding = mImages[unit];
if (binding.texture != texture || binding.level != level || binding.layered != layered ||
binding.layer != layer || binding.access != access || binding.format != format)
{
binding.texture = texture;
binding.level = level;
binding.layered = layered;
binding.layer = layer;
binding.access = access;
binding.format = format;
mFunctions->bindImageTexture(angle::base::checked_cast<GLuint>(unit), texture, level,
layered, layer, access, format);
}
}
void StateManagerGL::setPixelUnpackState(const gl::PixelUnpackState &unpack)
{
if (mUnpackAlignment != unpack.alignment)
{
mUnpackAlignment = unpack.alignment;
mFunctions->pixelStorei(GL_UNPACK_ALIGNMENT, mUnpackAlignment);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_UNPACK_STATE);
}
if (mUnpackRowLength != unpack.rowLength)
{
mUnpackRowLength = unpack.rowLength;
mFunctions->pixelStorei(GL_UNPACK_ROW_LENGTH, mUnpackRowLength);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_UNPACK_STATE);
}
if (mUnpackSkipRows != unpack.skipRows)
{
mUnpackSkipRows = unpack.skipRows;
mFunctions->pixelStorei(GL_UNPACK_SKIP_ROWS, mUnpackSkipRows);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_UNPACK_STATE);
}
if (mUnpackSkipPixels != unpack.skipPixels)
{
mUnpackSkipPixels = unpack.skipPixels;
mFunctions->pixelStorei(GL_UNPACK_SKIP_PIXELS, mUnpackSkipPixels);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_UNPACK_STATE);
}
if (mUnpackImageHeight != unpack.imageHeight)
{
mUnpackImageHeight = unpack.imageHeight;
mFunctions->pixelStorei(GL_UNPACK_IMAGE_HEIGHT, mUnpackImageHeight);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_UNPACK_STATE);
}
if (mUnpackSkipImages != unpack.skipImages)
{
mUnpackSkipImages = unpack.skipImages;
mFunctions->pixelStorei(GL_UNPACK_SKIP_IMAGES, mUnpackSkipImages);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_UNPACK_STATE);
}
}
void StateManagerGL::setPixelUnpackBuffer(const gl::Buffer *pixelBuffer)
{
GLuint bufferID = 0;
if (pixelBuffer != nullptr)
{
bufferID = GetImplAs<BufferGL>(pixelBuffer)->getBufferID();
}
bindBuffer(gl::BufferBinding::PixelUnpack, bufferID);
}
void StateManagerGL::setPixelPackState(const gl::PixelPackState &pack)
{
if (mPackAlignment != pack.alignment)
{
mPackAlignment = pack.alignment;
mFunctions->pixelStorei(GL_PACK_ALIGNMENT, mPackAlignment);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PACK_STATE);
}
if (mPackRowLength != pack.rowLength)
{
mPackRowLength = pack.rowLength;
mFunctions->pixelStorei(GL_PACK_ROW_LENGTH, mPackRowLength);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PACK_STATE);
}
if (mPackSkipRows != pack.skipRows)
{
mPackSkipRows = pack.skipRows;
mFunctions->pixelStorei(GL_PACK_SKIP_ROWS, mPackSkipRows);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PACK_STATE);
}
if (mPackSkipPixels != pack.skipPixels)
{
mPackSkipPixels = pack.skipPixels;
mFunctions->pixelStorei(GL_PACK_SKIP_PIXELS, mPackSkipPixels);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PACK_STATE);
}
}
void StateManagerGL::setPixelPackBuffer(const gl::Buffer *pixelBuffer)
{
GLuint bufferID = 0;
if (pixelBuffer != nullptr)
{
bufferID = GetImplAs<BufferGL>(pixelBuffer)->getBufferID();
}
bindBuffer(gl::BufferBinding::PixelPack, bufferID);
}
void StateManagerGL::bindFramebuffer(GLenum type, GLuint framebuffer)
{
switch (type)
{
case GL_FRAMEBUFFER:
if (mFramebuffers[angle::FramebufferBindingRead] != framebuffer ||
mFramebuffers[angle::FramebufferBindingDraw] != framebuffer)
{
mFramebuffers[angle::FramebufferBindingRead] = framebuffer;
mFramebuffers[angle::FramebufferBindingDraw] = framebuffer;
mFunctions->bindFramebuffer(GL_FRAMEBUFFER, framebuffer);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_READ_FRAMEBUFFER_BINDING);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_DRAW_FRAMEBUFFER_BINDING);
}
break;
case GL_READ_FRAMEBUFFER:
if (mFramebuffers[angle::FramebufferBindingRead] != framebuffer)
{
mFramebuffers[angle::FramebufferBindingRead] = framebuffer;
mFunctions->bindFramebuffer(GL_READ_FRAMEBUFFER, framebuffer);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_READ_FRAMEBUFFER_BINDING);
}
break;
case GL_DRAW_FRAMEBUFFER:
if (mFramebuffers[angle::FramebufferBindingDraw] != framebuffer)
{
mFramebuffers[angle::FramebufferBindingDraw] = framebuffer;
mFunctions->bindFramebuffer(GL_DRAW_FRAMEBUFFER, framebuffer);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_DRAW_FRAMEBUFFER_BINDING);
}
break;
default:
UNREACHABLE();
break;
}
}
void StateManagerGL::bindRenderbuffer(GLenum type, GLuint renderbuffer)
{
ASSERT(type == GL_RENDERBUFFER);
if (mRenderbuffer != renderbuffer)
{
mRenderbuffer = renderbuffer;
mFunctions->bindRenderbuffer(type, mRenderbuffer);
}
}
void StateManagerGL::bindTransformFeedback(GLenum type, GLuint transformFeedback)
{
ASSERT(type == GL_TRANSFORM_FEEDBACK);
if (mTransformFeedback != transformFeedback)
{
// Pause the current transform feedback if one is active.
// To handle virtualized contexts, StateManagerGL needs to be able to bind a new transform
// feedback at any time, even if there is one active.
if (mCurrentTransformFeedback != nullptr &&
mCurrentTransformFeedback->getTransformFeedbackID() != transformFeedback)
{
mCurrentTransformFeedback->syncPausedState(true);
mCurrentTransformFeedback = nullptr;
}
mTransformFeedback = transformFeedback;
mFunctions->bindTransformFeedback(type, mTransformFeedback);
onTransformFeedbackStateChange();
}
}
void StateManagerGL::onTransformFeedbackStateChange()
{
mLocalDirtyBits.set(gl::State::DIRTY_BIT_TRANSFORM_FEEDBACK_BINDING);
}
void StateManagerGL::beginQuery(gl::QueryType type, QueryGL *queryObject, GLuint queryId)
{
// Make sure this is a valid query type and there is no current active query of this type
ASSERT(mQueries[type] == nullptr);
ASSERT(queryId != 0);
mQueries[type] = queryObject;
mFunctions->beginQuery(ToGLenum(type), queryId);
}
void StateManagerGL::endQuery(gl::QueryType type, QueryGL *queryObject, GLuint queryId)
{
ASSERT(queryObject != nullptr);
ASSERT(mQueries[type] == queryObject);
mQueries[type] = nullptr;
mFunctions->endQuery(ToGLenum(type));
}
void StateManagerGL::updateDrawIndirectBufferBinding(const gl::Context *context)
{
gl::Buffer *drawIndirectBuffer =
context->getState().getTargetBuffer(gl::BufferBinding::DrawIndirect);
if (drawIndirectBuffer != nullptr)
{
const BufferGL *bufferGL = GetImplAs<BufferGL>(drawIndirectBuffer);
bindBuffer(gl::BufferBinding::DrawIndirect, bufferGL->getBufferID());
}
}
void StateManagerGL::updateDispatchIndirectBufferBinding(const gl::Context *context)
{
gl::Buffer *dispatchIndirectBuffer =
context->getState().getTargetBuffer(gl::BufferBinding::DispatchIndirect);
if (dispatchIndirectBuffer != nullptr)
{
const BufferGL *bufferGL = GetImplAs<BufferGL>(dispatchIndirectBuffer);
bindBuffer(gl::BufferBinding::DispatchIndirect, bufferGL->getBufferID());
}
}
void StateManagerGL::pauseTransformFeedback()
{
if (mCurrentTransformFeedback != nullptr)
{
mCurrentTransformFeedback->syncPausedState(true);
onTransformFeedbackStateChange();
}
}
angle::Result StateManagerGL::pauseAllQueries(const gl::Context *context)
{
for (gl::QueryType type : angle::AllEnums<gl::QueryType>())
{
QueryGL *previousQuery = mQueries[type];
if (previousQuery != nullptr)
{
ANGLE_TRY(previousQuery->pause(context));
mTemporaryPausedQueries[type] = previousQuery;
mQueries[type] = nullptr;
}
}
return angle::Result::Continue;
}
angle::Result StateManagerGL::pauseQuery(const gl::Context *context, gl::QueryType type)
{
QueryGL *previousQuery = mQueries[type];
if (previousQuery)
{
ANGLE_TRY(previousQuery->pause(context));
mTemporaryPausedQueries[type] = previousQuery;
mQueries[type] = nullptr;
}
return angle::Result::Continue;
}
angle::Result StateManagerGL::resumeAllQueries(const gl::Context *context)
{
for (gl::QueryType type : angle::AllEnums<gl::QueryType>())
{
QueryGL *pausedQuery = mTemporaryPausedQueries[type];
if (pausedQuery != nullptr)
{
ASSERT(mQueries[type] == nullptr);
ANGLE_TRY(pausedQuery->resume(context));
mTemporaryPausedQueries[type] = nullptr;
}
}
return angle::Result::Continue;
}
angle::Result StateManagerGL::resumeQuery(const gl::Context *context, gl::QueryType type)
{
QueryGL *pausedQuery = mTemporaryPausedQueries[type];
if (pausedQuery != nullptr)
{
ANGLE_TRY(pausedQuery->resume(context));
mTemporaryPausedQueries[type] = nullptr;
}
return angle::Result::Continue;
}
angle::Result StateManagerGL::onMakeCurrent(const gl::Context *context)
{
const gl::State &glState = context->getState();
#if defined(ANGLE_ENABLE_ASSERTS)
// Temporarily pausing queries during context switch is not supported
for (QueryGL *pausedQuery : mTemporaryPausedQueries)
{
ASSERT(pausedQuery == nullptr);
}
#endif
// If the context has changed, pause the previous context's queries
auto contextID = context->getState().getContextID();
if (contextID != mPrevDrawContext)
{
for (gl::QueryType type : angle::AllEnums<gl::QueryType>())
{
QueryGL *currentQuery = mQueries[type];
// Pause any old query object
if (currentQuery != nullptr)
{
ANGLE_TRY(currentQuery->pause(context));
mQueries[type] = nullptr;
}
// Check if this new context needs to resume a query
gl::Query *newQuery = glState.getActiveQuery(type);
if (newQuery != nullptr)
{
QueryGL *queryGL = GetImplAs<QueryGL>(newQuery);
ANGLE_TRY(queryGL->resume(context));
}
}
}
onTransformFeedbackStateChange();
mPrevDrawContext = contextID;
// Seamless cubemaps are required for ES3 and higher contexts. It should be the cheapest to set
// this state here since MakeCurrent is expected to be called less frequently than draw calls.
setTextureCubemapSeamlessEnabled(context->getClientMajorVersion() >= 3);
return angle::Result::Continue;
}
void StateManagerGL::updateProgramTextureBindings(const gl::Context *context)
{
const gl::State &glState = context->getState();
const gl::Program *program = glState.getProgram();
// It is possible there is no active program during a path operation.
if (!program)
return;
const gl::ActiveTexturePointerArray &textures = glState.getActiveTexturesCache();
const gl::ActiveTextureMask &activeTextures = program->getActiveSamplersMask();
const gl::ActiveTextureTypeArray &textureTypes = program->getActiveSamplerTypes();
for (size_t textureUnitIndex : activeTextures)
{
gl::TextureType textureType = textureTypes[textureUnitIndex];
gl::Texture *texture = textures[textureUnitIndex];
// A nullptr texture indicates incomplete.
if (texture != nullptr)
{
const TextureGL *textureGL = GetImplAs<TextureGL>(texture);
ASSERT(!texture->hasAnyDirtyBit());
ASSERT(!textureGL->hasAnyDirtyBit());
activeTexture(textureUnitIndex);
bindTexture(textureType, textureGL->getTextureID());
}
else
{
activeTexture(textureUnitIndex);
bindTexture(textureType, 0);
}
}
}
void StateManagerGL::updateProgramStorageBufferBindings(const gl::Context *context)
{
const gl::State &glState = context->getState();
const gl::Program *program = glState.getProgram();
// It is possible there is no active program during a path operation.
if (!program)
return;
for (size_t blockIndex = 0; blockIndex < program->getActiveShaderStorageBlockCount();
blockIndex++)
{
GLuint binding = program->getShaderStorageBlockBinding(static_cast<GLuint>(blockIndex));
const auto &shaderStorageBuffer = glState.getIndexedShaderStorageBuffer(binding);
if (shaderStorageBuffer.get() != nullptr)
{
BufferGL *bufferGL = GetImplAs<BufferGL>(shaderStorageBuffer.get());
if (shaderStorageBuffer.getSize() == 0)
{
bindBufferBase(gl::BufferBinding::ShaderStorage, binding, bufferGL->getBufferID());
}
else
{
bindBufferRange(gl::BufferBinding::ShaderStorage, binding, bufferGL->getBufferID(),
shaderStorageBuffer.getOffset(), shaderStorageBuffer.getSize());
}
}
}
}
void StateManagerGL::updateProgramUniformBufferBindings(const gl::Context *context)
{
// Sync the current program state
const gl::State &glState = context->getState();
const gl::Program *program = glState.getProgram();
// It is possible there is no active program during a path operation.
if (!program)
return;
for (size_t uniformBlockIndex = 0; uniformBlockIndex < program->getActiveUniformBlockCount();
uniformBlockIndex++)
{
GLuint binding = program->getUniformBlockBinding(static_cast<GLuint>(uniformBlockIndex));
const auto &uniformBuffer = glState.getIndexedUniformBuffer(binding);
if (uniformBuffer.get() != nullptr)
{
BufferGL *bufferGL = GetImplAs<BufferGL>(uniformBuffer.get());
if (uniformBuffer.getSize() == 0)
{
bindBufferBase(gl::BufferBinding::Uniform, binding, bufferGL->getBufferID());
}
else
{
bindBufferRange(gl::BufferBinding::Uniform, binding, bufferGL->getBufferID(),
uniformBuffer.getOffset(), uniformBuffer.getSize());
}
}
}
}
void StateManagerGL::updateProgramAtomicCounterBufferBindings(const gl::Context *context)
{
const gl::State &glState = context->getState();
const gl::Program *program = glState.getProgram();
// It is possible there is no active program during a path operation.
if (!program)
return;
for (const auto &atomicCounterBuffer : program->getState().getAtomicCounterBuffers())
{
GLuint binding = atomicCounterBuffer.binding;
const auto &buffer = glState.getIndexedAtomicCounterBuffer(binding);
if (buffer.get() != nullptr)
{
BufferGL *bufferGL = GetImplAs<BufferGL>(buffer.get());
if (buffer.getSize() == 0)
{
bindBufferBase(gl::BufferBinding::AtomicCounter, binding, bufferGL->getBufferID());
}
else
{
bindBufferRange(gl::BufferBinding::AtomicCounter, binding, bufferGL->getBufferID(),
buffer.getOffset(), buffer.getSize());
}
}
}
}
void StateManagerGL::updateProgramImageBindings(const gl::Context *context)
{
const gl::State &glState = context->getState();
const gl::Program *program = glState.getProgram();
// It is possible there is no active program during a path operation.
if (!program)
return;
ASSERT(context->getClientVersion() >= gl::ES_3_1 || program->getImageBindings().size() == 0);
for (size_t imageUnitIndex : program->getActiveImagesMask())
{
const gl::ImageUnit &imageUnit = glState.getImageUnit(imageUnitIndex);
const TextureGL *textureGL = SafeGetImplAs<TextureGL>(imageUnit.texture.get());
if (textureGL)
{
bindImageTexture(imageUnitIndex, textureGL->getTextureID(), imageUnit.level,
imageUnit.layered, imageUnit.layer, imageUnit.access,
imageUnit.format);
}
else
{
bindImageTexture(imageUnitIndex, 0, imageUnit.level, imageUnit.layered, imageUnit.layer,
imageUnit.access, imageUnit.format);
}
}
}
void StateManagerGL::setAttributeCurrentData(size_t index,
const gl::VertexAttribCurrentValueData &data)
{
if (mVertexAttribCurrentValues[index] != data)
{
mVertexAttribCurrentValues[index] = data;
switch (mVertexAttribCurrentValues[index].Type)
{
case gl::VertexAttribType::Float:
mFunctions->vertexAttrib4fv(static_cast<GLuint>(index),
mVertexAttribCurrentValues[index].Values.FloatValues);
break;
case gl::VertexAttribType::Int:
mFunctions->vertexAttribI4iv(static_cast<GLuint>(index),
mVertexAttribCurrentValues[index].Values.IntValues);
break;
case gl::VertexAttribType::UnsignedInt:
mFunctions->vertexAttribI4uiv(
static_cast<GLuint>(index),
mVertexAttribCurrentValues[index].Values.UnsignedIntValues);
break;
default:
UNREACHABLE();
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_CURRENT_VALUES);
mLocalDirtyCurrentValues.set(index);
}
}
void StateManagerGL::setScissorTestEnabled(bool enabled)
{
if (mScissorTestEnabled != enabled)
{
mScissorTestEnabled = enabled;
if (mScissorTestEnabled)
{
mFunctions->enable(GL_SCISSOR_TEST);
}
else
{
mFunctions->disable(GL_SCISSOR_TEST);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SCISSOR_TEST_ENABLED);
}
}
void StateManagerGL::setScissor(const gl::Rectangle &scissor)
{
if (scissor != mScissor)
{
mScissor = scissor;
mFunctions->scissor(mScissor.x, mScissor.y, mScissor.width, mScissor.height);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SCISSOR);
}
}
void StateManagerGL::setViewport(const gl::Rectangle &viewport)
{
if (viewport != mViewport)
{
mViewport = viewport;
mFunctions->viewport(mViewport.x, mViewport.y, mViewport.width, mViewport.height);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_VIEWPORT);
}
}
void StateManagerGL::setDepthRange(float near, float far)
{
mNear = near;
mFar = far;
// The glDepthRangef function isn't available until OpenGL 4.1. Prefer it when it is
// available because OpenGL ES only works in floats.
if (mFunctions->depthRangef)
{
mFunctions->depthRangef(mNear, mFar);
}
else
{
ASSERT(mFunctions->depthRange);
mFunctions->depthRange(mNear, mFar);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_DEPTH_RANGE);
}
void StateManagerGL::setBlendEnabled(bool enabled)
{
if (mBlendEnabled != enabled)
{
mBlendEnabled = enabled;
if (mBlendEnabled)
{
mFunctions->enable(GL_BLEND);
}
else
{
mFunctions->disable(GL_BLEND);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_BLEND_ENABLED);
}
}
void StateManagerGL::setBlendColor(const gl::ColorF &blendColor)
{
if (mBlendColor != blendColor)
{
mBlendColor = blendColor;
mFunctions->blendColor(mBlendColor.red, mBlendColor.green, mBlendColor.blue,
mBlendColor.alpha);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_BLEND_COLOR);
}
}
void StateManagerGL::setBlendFuncs(GLenum sourceBlendRGB,
GLenum destBlendRGB,
GLenum sourceBlendAlpha,
GLenum destBlendAlpha)
{
if (mSourceBlendRGB != sourceBlendRGB || mDestBlendRGB != destBlendRGB ||
mSourceBlendAlpha != sourceBlendAlpha || mDestBlendAlpha != destBlendAlpha)
{
mSourceBlendRGB = sourceBlendRGB;
mDestBlendRGB = destBlendRGB;
mSourceBlendAlpha = sourceBlendAlpha;
mDestBlendAlpha = destBlendAlpha;
mFunctions->blendFuncSeparate(mSourceBlendRGB, mDestBlendRGB, mSourceBlendAlpha,
mDestBlendAlpha);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_BLEND_FUNCS);
}
}
void StateManagerGL::setBlendEquations(GLenum blendEquationRGB, GLenum blendEquationAlpha)
{
if (mBlendEquationRGB != blendEquationRGB || mBlendEquationAlpha != blendEquationAlpha)
{
mBlendEquationRGB = blendEquationRGB;
mBlendEquationAlpha = blendEquationAlpha;
mFunctions->blendEquationSeparate(mBlendEquationRGB, mBlendEquationAlpha);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_BLEND_EQUATIONS);
}
}
void StateManagerGL::setColorMask(bool red, bool green, bool blue, bool alpha)
{
if (mColorMaskRed != red || mColorMaskGreen != green || mColorMaskBlue != blue ||
mColorMaskAlpha != alpha)
{
mColorMaskRed = red;
mColorMaskGreen = green;
mColorMaskBlue = blue;
mColorMaskAlpha = alpha;
mFunctions->colorMask(mColorMaskRed, mColorMaskGreen, mColorMaskBlue, mColorMaskAlpha);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_COLOR_MASK);
}
}
void StateManagerGL::setSampleAlphaToCoverageEnabled(bool enabled)
{
if (mSampleAlphaToCoverageEnabled != enabled)
{
mSampleAlphaToCoverageEnabled = enabled;
if (mSampleAlphaToCoverageEnabled)
{
mFunctions->enable(GL_SAMPLE_ALPHA_TO_COVERAGE);
}
else
{
mFunctions->disable(GL_SAMPLE_ALPHA_TO_COVERAGE);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLE_ALPHA_TO_COVERAGE_ENABLED);
}
}
void StateManagerGL::setSampleCoverageEnabled(bool enabled)
{
if (mSampleCoverageEnabled != enabled)
{
mSampleCoverageEnabled = enabled;
if (mSampleCoverageEnabled)
{
mFunctions->enable(GL_SAMPLE_COVERAGE);
}
else
{
mFunctions->disable(GL_SAMPLE_COVERAGE);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLE_COVERAGE_ENABLED);
}
}
void StateManagerGL::setSampleCoverage(float value, bool invert)
{
if (mSampleCoverageValue != value || mSampleCoverageInvert != invert)
{
mSampleCoverageValue = value;
mSampleCoverageInvert = invert;
mFunctions->sampleCoverage(mSampleCoverageValue, mSampleCoverageInvert);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLE_COVERAGE);
}
}
void StateManagerGL::setSampleMaskEnabled(bool enabled)
{
if (mSampleMaskEnabled != enabled)
{
mSampleMaskEnabled = enabled;
if (mSampleMaskEnabled)
{
mFunctions->enable(GL_SAMPLE_MASK);
}
else
{
mFunctions->disable(GL_SAMPLE_MASK);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLE_MASK_ENABLED);
}
}
void StateManagerGL::setSampleMaski(GLuint maskNumber, GLbitfield mask)
{
ASSERT(maskNumber < mSampleMaskValues.size());
if (mSampleMaskValues[maskNumber] != mask)
{
mSampleMaskValues[maskNumber] = mask;
mFunctions->sampleMaski(maskNumber, mask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLE_MASK);
}
}
// Depth and stencil redundant state changes are guarded in the
// frontend so for related cases here just set the dirty bit
// and update backend states.
void StateManagerGL::setDepthTestEnabled(bool enabled)
{
mDepthTestEnabled = enabled;
if (mDepthTestEnabled)
{
mFunctions->enable(GL_DEPTH_TEST);
}
else
{
mFunctions->disable(GL_DEPTH_TEST);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_DEPTH_TEST_ENABLED);
}
void StateManagerGL::setDepthFunc(GLenum depthFunc)
{
mDepthFunc = depthFunc;
mFunctions->depthFunc(mDepthFunc);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_DEPTH_FUNC);
}
void StateManagerGL::setDepthMask(bool mask)
{
mDepthMask = mask;
mFunctions->depthMask(mDepthMask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_DEPTH_MASK);
}
void StateManagerGL::setStencilTestEnabled(bool enabled)
{
mStencilTestEnabled = enabled;
if (mStencilTestEnabled)
{
mFunctions->enable(GL_STENCIL_TEST);
}
else
{
mFunctions->disable(GL_STENCIL_TEST);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_TEST_ENABLED);
}
void StateManagerGL::setStencilFrontWritemask(GLuint mask)
{
mStencilFrontWritemask = mask;
mFunctions->stencilMaskSeparate(GL_FRONT, mStencilFrontWritemask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_WRITEMASK_FRONT);
}
void StateManagerGL::setStencilBackWritemask(GLuint mask)
{
mStencilBackWritemask = mask;
mFunctions->stencilMaskSeparate(GL_BACK, mStencilBackWritemask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_WRITEMASK_BACK);
}
void StateManagerGL::setStencilFrontFuncs(GLenum func, GLint ref, GLuint mask)
{
mStencilFrontFunc = func;
mStencilFrontRef = ref;
mStencilFrontValueMask = mask;
mFunctions->stencilFuncSeparate(GL_FRONT, mStencilFrontFunc, mStencilFrontRef,
mStencilFrontValueMask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_FUNCS_FRONT);
}
void StateManagerGL::setStencilBackFuncs(GLenum func, GLint ref, GLuint mask)
{
mStencilBackFunc = func;
mStencilBackRef = ref;
mStencilBackValueMask = mask;
mFunctions->stencilFuncSeparate(GL_BACK, mStencilBackFunc, mStencilBackRef,
mStencilBackValueMask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_FUNCS_BACK);
}
void StateManagerGL::setStencilFrontOps(GLenum sfail, GLenum dpfail, GLenum dppass)
{
mStencilFrontStencilFailOp = sfail;
mStencilFrontStencilPassDepthFailOp = dpfail;
mStencilFrontStencilPassDepthPassOp = dppass;
mFunctions->stencilOpSeparate(GL_FRONT, mStencilFrontStencilFailOp,
mStencilFrontStencilPassDepthFailOp,
mStencilFrontStencilPassDepthPassOp);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_OPS_FRONT);
}
void StateManagerGL::setStencilBackOps(GLenum sfail, GLenum dpfail, GLenum dppass)
{
mStencilBackStencilFailOp = sfail;
mStencilBackStencilPassDepthFailOp = dpfail;
mStencilBackStencilPassDepthPassOp = dppass;
mFunctions->stencilOpSeparate(GL_BACK, mStencilBackStencilFailOp,
mStencilBackStencilPassDepthFailOp,
mStencilBackStencilPassDepthPassOp);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_STENCIL_OPS_BACK);
}
void StateManagerGL::setCullFaceEnabled(bool enabled)
{
if (mCullFaceEnabled != enabled)
{
mCullFaceEnabled = enabled;
if (mCullFaceEnabled)
{
mFunctions->enable(GL_CULL_FACE);
}
else
{
mFunctions->disable(GL_CULL_FACE);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_CULL_FACE_ENABLED);
}
}
void StateManagerGL::setCullFace(gl::CullFaceMode cullFace)
{
if (mCullFace != cullFace)
{
mCullFace = cullFace;
mFunctions->cullFace(ToGLenum(mCullFace));
mLocalDirtyBits.set(gl::State::DIRTY_BIT_CULL_FACE);
}
}
void StateManagerGL::setFrontFace(GLenum frontFace)
{
if (mFrontFace != frontFace)
{
mFrontFace = frontFace;
mFunctions->frontFace(mFrontFace);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_FRONT_FACE);
}
}
void StateManagerGL::setPolygonOffsetFillEnabled(bool enabled)
{
if (mPolygonOffsetFillEnabled != enabled)
{
mPolygonOffsetFillEnabled = enabled;
if (mPolygonOffsetFillEnabled)
{
mFunctions->enable(GL_POLYGON_OFFSET_FILL);
}
else
{
mFunctions->disable(GL_POLYGON_OFFSET_FILL);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_POLYGON_OFFSET_FILL_ENABLED);
}
}
void StateManagerGL::setPolygonOffset(float factor, float units)
{
if (mPolygonOffsetFactor != factor || mPolygonOffsetUnits != units)
{
mPolygonOffsetFactor = factor;
mPolygonOffsetUnits = units;
mFunctions->polygonOffset(mPolygonOffsetFactor, mPolygonOffsetUnits);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_POLYGON_OFFSET);
}
}
void StateManagerGL::setRasterizerDiscardEnabled(bool enabled)
{
if (mRasterizerDiscardEnabled != enabled)
{
mRasterizerDiscardEnabled = enabled;
if (mRasterizerDiscardEnabled)
{
mFunctions->enable(GL_RASTERIZER_DISCARD);
}
else
{
mFunctions->disable(GL_RASTERIZER_DISCARD);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_RASTERIZER_DISCARD_ENABLED);
}
}
void StateManagerGL::setLineWidth(float width)
{
if (mLineWidth != width)
{
mLineWidth = width;
mFunctions->lineWidth(mLineWidth);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_LINE_WIDTH);
}
}
void StateManagerGL::setPrimitiveRestartEnabled(bool enabled)
{
if (mPrimitiveRestartEnabled != enabled)
{
mPrimitiveRestartEnabled = enabled;
GLenum cap = mFeatures.emulatePrimitiveRestartFixedIndex.enabled
? GL_PRIMITIVE_RESTART
: GL_PRIMITIVE_RESTART_FIXED_INDEX;
if (mPrimitiveRestartEnabled)
{
mFunctions->enable(cap);
}
else
{
mFunctions->disable(cap);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PRIMITIVE_RESTART_ENABLED);
}
}
void StateManagerGL::setPrimitiveRestartIndex(GLuint index)
{
if (mPrimitiveRestartIndex != index)
{
mPrimitiveRestartIndex = index;
mFunctions->primitiveRestartIndex(index);
// No dirty bit for this state, it is not exposed to the frontend.
}
}
void StateManagerGL::setClearDepth(float clearDepth)
{
if (mClearDepth != clearDepth)
{
mClearDepth = clearDepth;
// The glClearDepthf function isn't available until OpenGL 4.1. Prefer it when it is
// available because OpenGL ES only works in floats.
if (mFunctions->clearDepthf)
{
mFunctions->clearDepthf(mClearDepth);
}
else
{
ASSERT(mFunctions->clearDepth);
mFunctions->clearDepth(mClearDepth);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_CLEAR_DEPTH);
}
}
void StateManagerGL::setClearColor(const gl::ColorF &clearColor)
{
gl::ColorF modifiedClearColor = clearColor;
if (mFeatures.clearToZeroOrOneBroken.enabled &&
(clearColor.red == 1.0f || clearColor.red == 0.0f) &&
(clearColor.green == 1.0f || clearColor.green == 0.0f) &&
(clearColor.blue == 1.0f || clearColor.blue == 0.0f) &&
(clearColor.alpha == 1.0f || clearColor.alpha == 0.0f))
{
if (clearColor.alpha == 1.0f)
{
modifiedClearColor.alpha = 2.0f;
}
else
{
modifiedClearColor.alpha = -1.0f;
}
}
if (mClearColor != modifiedClearColor)
{
mClearColor = modifiedClearColor;
mFunctions->clearColor(mClearColor.red, mClearColor.green, mClearColor.blue,
mClearColor.alpha);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_CLEAR_COLOR);
}
}
void StateManagerGL::setClearStencil(GLint clearStencil)
{
if (mClearStencil != clearStencil)
{
mClearStencil = clearStencil;
mFunctions->clearStencil(mClearStencil);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_CLEAR_STENCIL);
}
}
void StateManagerGL::syncState(const gl::Context *context,
const gl::State::DirtyBits &glDirtyBits,
const gl::State::DirtyBits &bitMask)
{
const gl::State &state = context->getState();
const gl::State::DirtyBits glAndLocalDirtyBits = (glDirtyBits | mLocalDirtyBits) & bitMask;
if (!glAndLocalDirtyBits.any())
{
return;
}
// TODO(jmadill): Investigate only syncing vertex state for active attributes
for (auto iter = glAndLocalDirtyBits.begin(), endIter = glAndLocalDirtyBits.end();
iter != endIter; ++iter)
{
switch (*iter)
{
case gl::State::DIRTY_BIT_SCISSOR_TEST_ENABLED:
setScissorTestEnabled(state.isScissorTestEnabled());
break;
case gl::State::DIRTY_BIT_SCISSOR:
{
const gl::Rectangle &scissor = state.getScissor();
setScissor(scissor);
}
break;
case gl::State::DIRTY_BIT_VIEWPORT:
{
const gl::Rectangle &viewport = state.getViewport();
setViewport(viewport);
}
break;
case gl::State::DIRTY_BIT_DEPTH_RANGE:
setDepthRange(state.getNearPlane(), state.getFarPlane());
break;
case gl::State::DIRTY_BIT_BLEND_ENABLED:
setBlendEnabled(state.isBlendEnabled());
break;
case gl::State::DIRTY_BIT_BLEND_COLOR:
setBlendColor(state.getBlendColor());
break;
case gl::State::DIRTY_BIT_BLEND_FUNCS:
{
const auto &blendState = state.getBlendState();
setBlendFuncs(blendState.sourceBlendRGB, blendState.destBlendRGB,
blendState.sourceBlendAlpha, blendState.destBlendAlpha);
break;
}
case gl::State::DIRTY_BIT_BLEND_EQUATIONS:
{
const auto &blendState = state.getBlendState();
setBlendEquations(blendState.blendEquationRGB, blendState.blendEquationAlpha);
break;
}
case gl::State::DIRTY_BIT_COLOR_MASK:
{
gl::Framebuffer *framebuffer = state.getDrawFramebuffer();
FramebufferGL *framebufferGL = GetImplAs<FramebufferGL>(framebuffer);
const auto &blendState = state.getBlendState();
setColorMaskForFramebuffer(blendState.colorMaskRed, blendState.colorMaskGreen,
blendState.colorMaskBlue, blendState.colorMaskAlpha,
framebufferGL);
break;
}
case gl::State::DIRTY_BIT_SAMPLE_ALPHA_TO_COVERAGE_ENABLED:
setSampleAlphaToCoverageEnabled(state.isSampleAlphaToCoverageEnabled());
break;
case gl::State::DIRTY_BIT_SAMPLE_COVERAGE_ENABLED:
setSampleCoverageEnabled(state.isSampleCoverageEnabled());
break;
case gl::State::DIRTY_BIT_SAMPLE_COVERAGE:
setSampleCoverage(state.getSampleCoverageValue(), state.getSampleCoverageInvert());
break;
case gl::State::DIRTY_BIT_DEPTH_TEST_ENABLED:
setDepthTestEnabled(state.isDepthTestEnabled());
break;
case gl::State::DIRTY_BIT_DEPTH_FUNC:
setDepthFunc(state.getDepthStencilState().depthFunc);
break;
case gl::State::DIRTY_BIT_DEPTH_MASK:
setDepthMask(state.getDepthStencilState().depthMask);
break;
case gl::State::DIRTY_BIT_STENCIL_TEST_ENABLED:
setStencilTestEnabled(state.isStencilTestEnabled());
break;
case gl::State::DIRTY_BIT_STENCIL_FUNCS_FRONT:
{
const auto &depthStencilState = state.getDepthStencilState();
setStencilFrontFuncs(depthStencilState.stencilFunc, state.getStencilRef(),
depthStencilState.stencilMask);
break;
}
case gl::State::DIRTY_BIT_STENCIL_FUNCS_BACK:
{
const auto &depthStencilState = state.getDepthStencilState();
setStencilBackFuncs(depthStencilState.stencilBackFunc, state.getStencilBackRef(),
depthStencilState.stencilBackMask);
break;
}
case gl::State::DIRTY_BIT_STENCIL_OPS_FRONT:
{
const auto &depthStencilState = state.getDepthStencilState();
setStencilFrontOps(depthStencilState.stencilFail,
depthStencilState.stencilPassDepthFail,
depthStencilState.stencilPassDepthPass);
break;
}
case gl::State::DIRTY_BIT_STENCIL_OPS_BACK:
{
const auto &depthStencilState = state.getDepthStencilState();
setStencilBackOps(depthStencilState.stencilBackFail,
depthStencilState.stencilBackPassDepthFail,
depthStencilState.stencilBackPassDepthPass);
break;
}
case gl::State::DIRTY_BIT_STENCIL_WRITEMASK_FRONT:
setStencilFrontWritemask(state.getDepthStencilState().stencilWritemask);
break;
case gl::State::DIRTY_BIT_STENCIL_WRITEMASK_BACK:
setStencilBackWritemask(state.getDepthStencilState().stencilBackWritemask);
break;
case gl::State::DIRTY_BIT_CULL_FACE_ENABLED:
setCullFaceEnabled(state.isCullFaceEnabled());
break;
case gl::State::DIRTY_BIT_CULL_FACE:
setCullFace(state.getRasterizerState().cullMode);
break;
case gl::State::DIRTY_BIT_FRONT_FACE:
setFrontFace(state.getRasterizerState().frontFace);
break;
case gl::State::DIRTY_BIT_POLYGON_OFFSET_FILL_ENABLED:
setPolygonOffsetFillEnabled(state.isPolygonOffsetFillEnabled());
break;
case gl::State::DIRTY_BIT_POLYGON_OFFSET:
{
const auto &rasterizerState = state.getRasterizerState();
setPolygonOffset(rasterizerState.polygonOffsetFactor,
rasterizerState.polygonOffsetUnits);
break;
}
case gl::State::DIRTY_BIT_RASTERIZER_DISCARD_ENABLED:
setRasterizerDiscardEnabled(state.isRasterizerDiscardEnabled());
break;
case gl::State::DIRTY_BIT_LINE_WIDTH:
setLineWidth(state.getLineWidth());
break;
case gl::State::DIRTY_BIT_PRIMITIVE_RESTART_ENABLED:
setPrimitiveRestartEnabled(state.isPrimitiveRestartEnabled());
break;
case gl::State::DIRTY_BIT_CLEAR_COLOR:
setClearColor(state.getColorClearValue());
break;
case gl::State::DIRTY_BIT_CLEAR_DEPTH:
setClearDepth(state.getDepthClearValue());
break;
case gl::State::DIRTY_BIT_CLEAR_STENCIL:
setClearStencil(state.getStencilClearValue());
break;
case gl::State::DIRTY_BIT_UNPACK_STATE:
setPixelUnpackState(state.getUnpackState());
break;
case gl::State::DIRTY_BIT_UNPACK_BUFFER_BINDING:
setPixelUnpackBuffer(state.getTargetBuffer(gl::BufferBinding::PixelUnpack));
break;
case gl::State::DIRTY_BIT_PACK_STATE:
setPixelPackState(state.getPackState());
break;
case gl::State::DIRTY_BIT_PACK_BUFFER_BINDING:
setPixelPackBuffer(state.getTargetBuffer(gl::BufferBinding::PixelPack));
break;
case gl::State::DIRTY_BIT_DITHER_ENABLED:
setDitherEnabled(state.isDitherEnabled());
break;
case gl::State::DIRTY_BIT_GENERATE_MIPMAP_HINT:
// TODO(jmadill): implement this
break;
case gl::State::DIRTY_BIT_SHADER_DERIVATIVE_HINT:
// TODO(jmadill): implement this
break;
case gl::State::DIRTY_BIT_READ_FRAMEBUFFER_BINDING:
{
gl::Framebuffer *framebuffer = state.getReadFramebuffer();
// Necessary for an Intel TexImage workaround.
if (!framebuffer)
continue;
FramebufferGL *framebufferGL = GetImplAs<FramebufferGL>(framebuffer);
bindFramebuffer(GL_READ_FRAMEBUFFER, framebufferGL->getFramebufferID());
break;
}
case gl::State::DIRTY_BIT_DRAW_FRAMEBUFFER_BINDING:
{
gl::Framebuffer *framebuffer = state.getDrawFramebuffer();
// Necessary for an Intel TexImage workaround.
if (!framebuffer)
continue;
FramebufferGL *framebufferGL = GetImplAs<FramebufferGL>(framebuffer);
bindFramebuffer(GL_DRAW_FRAMEBUFFER, framebufferGL->getFramebufferID());
const gl::Program *program = state.getProgram();
if (program)
{
updateMultiviewBaseViewLayerIndexUniform(program, framebufferGL->getState());
}
// Changing the draw framebuffer binding sometimes requires resetting srgb blending.
if (mFunctions->standard == STANDARD_GL_DESKTOP)
{
iter.setLaterBit(gl::State::DIRTY_BIT_FRAMEBUFFER_SRGB);
}
// If the framebuffer is emulating RGB on top of RGBA, the color mask has to be
// updated
iter.setLaterBit(gl::State::DIRTY_BIT_COLOR_MASK);
break;
}
case gl::State::DIRTY_BIT_RENDERBUFFER_BINDING:
// TODO(jmadill): implement this
break;
case gl::State::DIRTY_BIT_VERTEX_ARRAY_BINDING:
{
const VertexArrayGL *vaoGL = GetImplAs<VertexArrayGL>(state.getVertexArray());
bindVertexArray(vaoGL->getVertexArrayID(), vaoGL->getAppliedElementArrayBufferID());
propagateProgramToVAO(state.getProgram(),
GetImplAs<VertexArrayGL>(state.getVertexArray()));
break;
}
case gl::State::DIRTY_BIT_DRAW_INDIRECT_BUFFER_BINDING:
updateDrawIndirectBufferBinding(context);
break;
case gl::State::DIRTY_BIT_DISPATCH_INDIRECT_BUFFER_BINDING:
updateDispatchIndirectBufferBinding(context);
break;
case gl::State::DIRTY_BIT_PROGRAM_BINDING:
{
gl::Program *program = state.getProgram();
if (program != nullptr)
{
useProgram(GetImplAs<ProgramGL>(program)->getProgramID());
}
break;
}
case gl::State::DIRTY_BIT_PROGRAM_EXECUTABLE:
{
const gl::Program *program = state.getProgram();
if (program)
{
iter.setLaterBit(gl::State::DIRTY_BIT_TEXTURE_BINDINGS);
if (program->getActiveImagesMask().any())
{
iter.setLaterBit(gl::State::DIRTY_BIT_IMAGE_BINDINGS);
}
if (program->getActiveShaderStorageBlockCount() > 0)
{
iter.setLaterBit(gl::State::DIRTY_BIT_SHADER_STORAGE_BUFFER_BINDING);
}
if (program->getActiveUniformBlockCount() > 0)
{
iter.setLaterBit(gl::State::DIRTY_BIT_UNIFORM_BUFFER_BINDINGS);
}
if (program->getActiveAtomicCounterBufferCount() > 0)
{
iter.setLaterBit(gl::State::DIRTY_BIT_ATOMIC_COUNTER_BUFFER_BINDING);
}
if (mIsMultiviewEnabled && program->usesMultiview())
{
updateMultiviewBaseViewLayerIndexUniform(
program, state.getDrawFramebuffer()->getImplementation()->getState());
}
}
if (!program || !program->hasLinkedShaderStage(gl::ShaderType::Compute))
{
propagateProgramToVAO(program,
GetImplAs<VertexArrayGL>(state.getVertexArray()));
}
break;
}
case gl::State::DIRTY_BIT_TEXTURE_BINDINGS:
updateProgramTextureBindings(context);
break;
case gl::State::DIRTY_BIT_SAMPLER_BINDINGS:
syncSamplersState(context);
break;
case gl::State::DIRTY_BIT_IMAGE_BINDINGS:
updateProgramImageBindings(context);
break;
case gl::State::DIRTY_BIT_TRANSFORM_FEEDBACK_BINDING:
syncTransformFeedbackState(context);
break;
case gl::State::DIRTY_BIT_SHADER_STORAGE_BUFFER_BINDING:
updateProgramStorageBufferBindings(context);
break;
case gl::State::DIRTY_BIT_UNIFORM_BUFFER_BINDINGS:
updateProgramUniformBufferBindings(context);
break;
case gl::State::DIRTY_BIT_ATOMIC_COUNTER_BUFFER_BINDING:
updateProgramAtomicCounterBufferBindings(context);
break;
case gl::State::DIRTY_BIT_MULTISAMPLING:
setMultisamplingStateEnabled(state.isMultisamplingEnabled());
break;
case gl::State::DIRTY_BIT_SAMPLE_ALPHA_TO_ONE:
setSampleAlphaToOneStateEnabled(state.isSampleAlphaToOneEnabled());
break;
case gl::State::DIRTY_BIT_COVERAGE_MODULATION:
setCoverageModulation(state.getCoverageModulation());
break;
case gl::State::DIRTY_BIT_PATH_RENDERING:
setPathRenderingModelViewMatrix(
state.getPathRenderingMatrix(GL_PATH_MODELVIEW_MATRIX_CHROMIUM));
setPathRenderingProjectionMatrix(
state.getPathRenderingMatrix(GL_PATH_PROJECTION_MATRIX_CHROMIUM));
setPathRenderingStencilState(state.getPathStencilFunc(), state.getPathStencilRef(),
state.getPathStencilMask());
break;
case gl::State::DIRTY_BIT_FRAMEBUFFER_SRGB:
setFramebufferSRGBEnabledForFramebuffer(
context, state.getFramebufferSRGB(),
GetImplAs<FramebufferGL>(state.getDrawFramebuffer()));
break;
case gl::State::DIRTY_BIT_SAMPLE_MASK_ENABLED:
setSampleMaskEnabled(state.isSampleMaskEnabled());
break;
case gl::State::DIRTY_BIT_SAMPLE_MASK:
{
for (GLuint maskNumber = 0; maskNumber < state.getMaxSampleMaskWords();
++maskNumber)
{
setSampleMaski(maskNumber, state.getSampleMaskWord(maskNumber));
}
break;
}
case gl::State::DIRTY_BIT_CURRENT_VALUES:
{
gl::AttributesMask combinedMask =
(state.getAndResetDirtyCurrentValues() | mLocalDirtyCurrentValues);
mLocalDirtyCurrentValues.reset();
for (auto attribIndex : combinedMask)
{
setAttributeCurrentData(attribIndex,
state.getVertexAttribCurrentValue(attribIndex));
}
break;
}
case gl::State::DIRTY_BIT_PROVOKING_VERTEX:
setProvokingVertex(ToGLenum(state.getProvokingVertex()));
break;
default:
UNREACHABLE();
break;
}
}
mLocalDirtyBits &= ~(bitMask);
}
void StateManagerGL::setFramebufferSRGBEnabled(const gl::Context *context, bool enabled)
{
if (!context->getExtensions().sRGBWriteControl)
{
return;
}
if (mFramebufferSRGBEnabled != enabled)
{
mFramebufferSRGBEnabled = enabled;
if (mFramebufferSRGBEnabled)
{
mFunctions->enable(GL_FRAMEBUFFER_SRGB);
}
else
{
mFunctions->disable(GL_FRAMEBUFFER_SRGB);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_FRAMEBUFFER_SRGB);
}
}
void StateManagerGL::setFramebufferSRGBEnabledForFramebuffer(const gl::Context *context,
bool enabled,
const FramebufferGL *framebuffer)
{
if (mFunctions->standard == STANDARD_GL_DESKTOP && framebuffer->isDefault())
{
// Obey the framebuffer sRGB state for blending on all framebuffers except the default
// framebuffer on Desktop OpenGL.
// When SRGB blending is enabled, only SRGB capable formats will use it but the default
// framebuffer will always use it if it is enabled.
// TODO(geofflang): Update this when the framebuffer binding dirty changes, when it exists.
setFramebufferSRGBEnabled(context, false);
}
else
{
setFramebufferSRGBEnabled(context, enabled);
}
}
void StateManagerGL::setColorMaskForFramebuffer(bool red,
bool green,
bool blue,
bool alpha,
const FramebufferGL *framebuffer)
{
bool modifiedAlphaMask = alpha;
if (framebuffer->hasEmulatedAlphaChannelTextureAttachment())
{
modifiedAlphaMask = false;
}
setColorMask(red, green, blue, modifiedAlphaMask);
}
void StateManagerGL::setDitherEnabled(bool enabled)
{
if (mDitherEnabled != enabled)
{
mDitherEnabled = enabled;
if (mDitherEnabled)
{
mFunctions->enable(GL_DITHER);
}
else
{
mFunctions->disable(GL_DITHER);
}
}
}
void StateManagerGL::setMultisamplingStateEnabled(bool enabled)
{
if (mMultisamplingEnabled != enabled)
{
mMultisamplingEnabled = enabled;
if (mMultisamplingEnabled)
{
mFunctions->enable(GL_MULTISAMPLE_EXT);
}
else
{
mFunctions->disable(GL_MULTISAMPLE_EXT);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_MULTISAMPLING);
}
}
void StateManagerGL::setSampleAlphaToOneStateEnabled(bool enabled)
{
if (mSampleAlphaToOneEnabled != enabled)
{
mSampleAlphaToOneEnabled = enabled;
if (mSampleAlphaToOneEnabled)
{
mFunctions->enable(GL_SAMPLE_ALPHA_TO_ONE);
}
else
{
mFunctions->disable(GL_SAMPLE_ALPHA_TO_ONE);
}
mLocalDirtyBits.set(gl::State::DIRTY_BIT_SAMPLE_ALPHA_TO_ONE);
}
}
void StateManagerGL::setCoverageModulation(GLenum components)
{
if (mCoverageModulation != components)
{
mCoverageModulation = components;
mFunctions->coverageModulationNV(components);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_COVERAGE_MODULATION);
}
}
void StateManagerGL::setPathRenderingModelViewMatrix(const GLfloat *m)
{
if (memcmp(mPathMatrixMV, m, sizeof(mPathMatrixMV)) != 0)
{
memcpy(mPathMatrixMV, m, sizeof(mPathMatrixMV));
mFunctions->matrixLoadfEXT(GL_PATH_MODELVIEW_CHROMIUM, m);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PATH_RENDERING);
}
}
void StateManagerGL::setPathRenderingProjectionMatrix(const GLfloat *m)
{
if (memcmp(mPathMatrixProj, m, sizeof(mPathMatrixProj)) != 0)
{
memcpy(mPathMatrixProj, m, sizeof(mPathMatrixProj));
mFunctions->matrixLoadfEXT(GL_PATH_PROJECTION_CHROMIUM, m);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PATH_RENDERING);
}
}
void StateManagerGL::setPathRenderingStencilState(GLenum func, GLint ref, GLuint mask)
{
if (func != mPathStencilFunc || ref != mPathStencilRef || mask != mPathStencilMask)
{
mPathStencilFunc = func;
mPathStencilRef = ref;
mPathStencilMask = mask;
mFunctions->pathStencilFuncNV(func, ref, mask);
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PATH_RENDERING);
}
}
void StateManagerGL::setProvokingVertex(GLenum mode)
{
if (mode != mProvokingVertex)
{
mFunctions->provokingVertex(mode);
mProvokingVertex = mode;
mLocalDirtyBits.set(gl::State::DIRTY_BIT_PROVOKING_VERTEX);
}
}
void StateManagerGL::setTextureCubemapSeamlessEnabled(bool enabled)
{
// TODO(jmadill): Also check for seamless extension.
if (!mFunctions->isAtLeastGL(gl::Version(3, 2)))
{
return;
}
if (mTextureCubemapSeamlessEnabled != enabled)
{
mTextureCubemapSeamlessEnabled = enabled;
if (mTextureCubemapSeamlessEnabled)
{
mFunctions->enable(GL_TEXTURE_CUBE_MAP_SEAMLESS);
}
else
{
mFunctions->disable(GL_TEXTURE_CUBE_MAP_SEAMLESS);
}
}
}
void StateManagerGL::propagateProgramToVAO(const gl::Program *program, VertexArrayGL *vao)
{
if (vao == nullptr)
{
return;
}
// Number of views:
if (mIsMultiviewEnabled)
{
int programNumViews = 1;
if (program && program->usesMultiview())
{
programNumViews = program->getNumViews();
}
vao->applyNumViewsToDivisor(programNumViews);
}
// Attribute enabled mask:
if (program)
{
vao->applyActiveAttribLocationsMask(program->getActiveAttribLocationsMask());
}
}
void StateManagerGL::updateMultiviewBaseViewLayerIndexUniformImpl(
const gl::Program *program,
const gl::FramebufferState &drawFramebufferState) const
{
ASSERT(mIsMultiviewEnabled && program && program->usesMultiview());
const ProgramGL *programGL = GetImplAs<ProgramGL>(program);
if (drawFramebufferState.isMultiview())
{
programGL->enableLayeredRenderingPath(drawFramebufferState.getBaseViewIndex());
}
}
void StateManagerGL::syncSamplersState(const gl::Context *context)
{
const gl::State::SamplerBindingVector &samplers = context->getState().getSamplers();
// This could be optimized by using a separate binding dirty bit per sampler.
for (size_t samplerIndex = 0; samplerIndex < samplers.size(); ++samplerIndex)
{
const gl::Sampler *sampler = samplers[samplerIndex].get();
if (sampler != nullptr)
{
SamplerGL *samplerGL = GetImplAs<SamplerGL>(sampler);
bindSampler(samplerIndex, samplerGL->getSamplerID());
}
else
{
bindSampler(samplerIndex, 0);
}
}
}
void StateManagerGL::syncTransformFeedbackState(const gl::Context *context)
{
// Set the current transform feedback state
gl::TransformFeedback *transformFeedback = context->getState().getCurrentTransformFeedback();
if (transformFeedback)
{
TransformFeedbackGL *transformFeedbackGL =
GetImplAs<TransformFeedbackGL>(transformFeedback);
bindTransformFeedback(GL_TRANSFORM_FEEDBACK, transformFeedbackGL->getTransformFeedbackID());
transformFeedbackGL->syncActiveState(context, transformFeedback->isActive(),
transformFeedback->getPrimitiveMode());
transformFeedbackGL->syncPausedState(transformFeedback->isPaused());
mCurrentTransformFeedback = transformFeedbackGL;
}
else
{
bindTransformFeedback(GL_TRANSFORM_FEEDBACK, 0);
mCurrentTransformFeedback = nullptr;
}
}
void StateManagerGL::validateState() const
{
// Current program
ValidateStateHelper(mFunctions, mProgram, GL_CURRENT_PROGRAM, "mProgram", "GL_CURRENT_PROGRAM");
// Buffers
for (gl::BufferBinding bindingType : angle::AllEnums<gl::BufferBinding>())
{
// These binding types need compute support to be queried
if (bindingType == gl::BufferBinding::AtomicCounter ||
bindingType == gl::BufferBinding::DispatchIndirect ||
bindingType == gl::BufferBinding::ShaderStorage)
{
if (!nativegl::SupportsCompute(mFunctions))
{
continue;
}
}
// Transform feedback buffer bindings are tracked in TransformFeedbackGL
if (bindingType == gl::BufferBinding::TransformFeedback)
{
continue;
}
GLenum bindingTypeGL = nativegl::GetBufferBindingQuery(bindingType);
std::string localName = "mBuffers[" + ToString(bindingType) + "]";
ValidateStateHelper(mFunctions, mBuffers[bindingType], bindingTypeGL, localName.c_str(),
nativegl::GetBufferBindingString(bindingType).c_str());
}
// Vertex array object
ValidateStateHelper(mFunctions, mVAO, GL_VERTEX_ARRAY_BINDING, "mVAO",
"GL_VERTEX_ARRAY_BINDING");
}
} // namespace rx