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kc3-lang/angle/src/libANGLE/angletypes.cpp
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Author :
Jamie Madill
Date : 2019-01-16 13:27:14
Hash : 6e18a238
Message : Optimize more front-end VertexArray binding. Improves perf slightly (1-2%) in the Vulkan VBO state change test. Bug: angleproject:3014 Change-Id: Ia8082b5b3f5e847a6b2775e896893fa8d38c1afd Reviewed-on: https://chromium-review.googlesource.com/c/1393904 Commit-Queue: Jamie Madill <jmadill@chromium.org> Reviewed-by: Geoff Lang <geofflang@chromium.org> Reviewed-by: Shahbaz Youssefi <syoussefi@chromium.org>
- src/libANGLE/angletypes.cpp
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// // Copyright (c) 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. // // angletypes.h : Defines a variety of structures and enum types that are used throughout libGLESv2 #include "libANGLE/angletypes.h" #include "libANGLE/Program.h" #include "libANGLE/State.h" #include "libANGLE/VertexArray.h" #include "libANGLE/VertexAttribute.h" namespace gl { RasterizerState::RasterizerState() { memset(this, 0, sizeof(RasterizerState)); rasterizerDiscard = false; cullFace = false; cullMode = CullFaceMode::Back; frontFace = GL_CCW; polygonOffsetFill = false; polygonOffsetFactor = 0.0f; polygonOffsetUnits = 0.0f; pointDrawMode = false; multiSample = false; } bool operator==(const RasterizerState &a, const RasterizerState &b) { return memcmp(&a, &b, sizeof(RasterizerState)) == 0; } bool operator!=(const RasterizerState &a, const RasterizerState &b) { return !(a == b); } BlendState::BlendState() { memset(this, 0, sizeof(BlendState)); blend = false; sourceBlendRGB = GL_ONE; sourceBlendAlpha = GL_ONE; destBlendRGB = GL_ZERO; destBlendAlpha = GL_ZERO; blendEquationRGB = GL_FUNC_ADD; blendEquationAlpha = GL_FUNC_ADD; sampleAlphaToCoverage = false; dither = true; } BlendState::BlendState(const BlendState &other) { memcpy(this, &other, sizeof(BlendState)); } bool operator==(const BlendState &a, const BlendState &b) { return memcmp(&a, &b, sizeof(BlendState)) == 0; } bool operator!=(const BlendState &a, const BlendState &b) { return !(a == b); } DepthStencilState::DepthStencilState() { memset(this, 0, sizeof(DepthStencilState)); depthTest = false; depthFunc = GL_LESS; depthMask = true; stencilTest = false; stencilFunc = GL_ALWAYS; stencilMask = static_cast<GLuint>(-1); stencilWritemask = static_cast<GLuint>(-1); stencilBackFunc = GL_ALWAYS; stencilBackMask = static_cast<GLuint>(-1); stencilBackWritemask = static_cast<GLuint>(-1); stencilFail = GL_KEEP; stencilPassDepthFail = GL_KEEP; stencilPassDepthPass = GL_KEEP; stencilBackFail = GL_KEEP; stencilBackPassDepthFail = GL_KEEP; stencilBackPassDepthPass = GL_KEEP; } DepthStencilState::DepthStencilState(const DepthStencilState &other) { memcpy(this, &other, sizeof(DepthStencilState)); } bool operator==(const DepthStencilState &a, const DepthStencilState &b) { return memcmp(&a, &b, sizeof(DepthStencilState)) == 0; } bool operator!=(const DepthStencilState &a, const DepthStencilState &b) { return !(a == b); } SamplerState::SamplerState() { memset(this, 0, sizeof(SamplerState)); setMinFilter(GL_NEAREST_MIPMAP_LINEAR); setMagFilter(GL_LINEAR); setWrapS(GL_REPEAT); setWrapT(GL_REPEAT); setWrapR(GL_REPEAT); setMaxAnisotropy(1.0f); setMinLod(-1000.0f); setMaxLod(1000.0f); setCompareMode(GL_NONE); setCompareFunc(GL_LEQUAL); setSRGBDecode(GL_DECODE_EXT); } SamplerState::SamplerState(const SamplerState &other) = default; // static SamplerState SamplerState::CreateDefaultForTarget(TextureType type) { SamplerState state; // According to OES_EGL_image_external and ARB_texture_rectangle: For external textures, the // default min filter is GL_LINEAR and the default s and t wrap modes are GL_CLAMP_TO_EDGE. if (type == TextureType::External || type == TextureType::Rectangle) { state.mMinFilter = GL_LINEAR; state.mWrapS = GL_CLAMP_TO_EDGE; state.mWrapT = GL_CLAMP_TO_EDGE; } return state; } void SamplerState::setMinFilter(GLenum minFilter) { mMinFilter = minFilter; mCompleteness.typed.minFilter = static_cast<uint8_t>(FromGLenum<FilterMode>(minFilter)); } void SamplerState::setMagFilter(GLenum magFilter) { mMagFilter = magFilter; mCompleteness.typed.magFilter = static_cast<uint8_t>(FromGLenum<FilterMode>(magFilter)); } void SamplerState::setWrapS(GLenum wrapS) { mWrapS = wrapS; mCompleteness.typed.wrapS = static_cast<uint8_t>(FromGLenum<WrapMode>(wrapS)); } void SamplerState::setWrapT(GLenum wrapT) { mWrapT = wrapT; updateWrapTCompareMode(); } void SamplerState::setWrapR(GLenum wrapR) { mWrapR = wrapR; } void SamplerState::setMaxAnisotropy(float maxAnisotropy) { mMaxAnisotropy = maxAnisotropy; } void SamplerState::setMinLod(GLfloat minLod) { mMinLod = minLod; } void SamplerState::setMaxLod(GLfloat maxLod) { mMaxLod = maxLod; } void SamplerState::setCompareMode(GLenum compareMode) { mCompareMode = compareMode; updateWrapTCompareMode(); } void SamplerState::setCompareFunc(GLenum compareFunc) { mCompareFunc = compareFunc; } void SamplerState::setSRGBDecode(GLenum sRGBDecode) { mSRGBDecode = sRGBDecode; } void SamplerState::setBorderColor(const ColorGeneric &color) { mBorderColor = color; } void SamplerState::updateWrapTCompareMode() { uint8_t wrap = static_cast<uint8_t>(FromGLenum<WrapMode>(mWrapT)); uint8_t compare = static_cast<uint8_t>(mCompareMode == GL_NONE ? 0x10 : 0x00); mCompleteness.typed.wrapTCompareMode = wrap | compare; } ImageUnit::ImageUnit() : texture(), level(0), layered(false), layer(0), access(GL_READ_ONLY), format(GL_R32UI) {} ImageUnit::ImageUnit(const ImageUnit &other) = default; ImageUnit::~ImageUnit() = default; static void MinMax(int a, int b, int *minimum, int *maximum) { if (a < b) { *minimum = a; *maximum = b; } else { *minimum = b; *maximum = a; } } Rectangle Rectangle::removeReversal() const { Rectangle unreversed = *this; if (isReversedX()) { unreversed.x = unreversed.x + unreversed.width; unreversed.width = -unreversed.width; } if (isReversedY()) { unreversed.y = unreversed.y + unreversed.height; unreversed.height = -unreversed.height; } return unreversed; } bool ClipRectangle(const Rectangle &source, const Rectangle &clip, Rectangle *intersection) { int minSourceX, maxSourceX, minSourceY, maxSourceY; MinMax(source.x, source.x + source.width, &minSourceX, &maxSourceX); MinMax(source.y, source.y + source.height, &minSourceY, &maxSourceY); int minClipX, maxClipX, minClipY, maxClipY; MinMax(clip.x, clip.x + clip.width, &minClipX, &maxClipX); MinMax(clip.y, clip.y + clip.height, &minClipY, &maxClipY); if (minSourceX >= maxClipX || maxSourceX <= minClipX || minSourceY >= maxClipY || maxSourceY <= minClipY) { return false; } if (intersection) { intersection->x = std::max(minSourceX, minClipX); intersection->y = std::max(minSourceY, minClipY); intersection->width = std::min(maxSourceX, maxClipX) - std::max(minSourceX, minClipX); intersection->height = std::min(maxSourceY, maxClipY) - std::max(minSourceY, minClipY); } return true; } bool Box::operator==(const Box &other) const { return (x == other.x && y == other.y && z == other.z && width == other.width && height == other.height && depth == other.depth); } bool Box::operator!=(const Box &other) const { return !(*this == other); } Rectangle Box::toRect() const { ASSERT(z == 0 && depth == 1); return Rectangle(x, y, width, height); } bool operator==(const Offset &a, const Offset &b) { return a.x == b.x && a.y == b.y && a.z == b.z; } bool operator!=(const Offset &a, const Offset &b) { return !(a == b); } bool operator==(const Extents &lhs, const Extents &rhs) { return lhs.width == rhs.width && lhs.height == rhs.height && lhs.depth == rhs.depth; } bool operator!=(const Extents &lhs, const Extents &rhs) { return !(lhs == rhs); } bool ValidateComponentTypeMasks(unsigned long outputTypes, unsigned long inputTypes, unsigned long outputMask, unsigned long inputMask) { static_assert(IMPLEMENTATION_MAX_DRAW_BUFFERS <= kMaxComponentTypeMaskIndex, "Output/input masks should fit into 16 bits - 1 bit per draw buffer. The " "corresponding type masks should fit into 32 bits - 2 bits per draw buffer."); static_assert(MAX_VERTEX_ATTRIBS <= kMaxComponentTypeMaskIndex, "Output/input masks should fit into 16 bits - 1 bit per attrib. The " "corresponding type masks should fit into 32 bits - 2 bits per attrib."); // For performance reasons, draw buffer and attribute type validation is done using bit masks. // We store two bits representing the type split, with the low bit in the lower 16 bits of the // variable, and the high bit in the upper 16 bits of the variable. This is done so we can AND // with the elswewhere used DrawBufferMask or AttributeMask. // OR the masks with themselves, shifted 16 bits. This is to match our split type bits. outputMask |= (outputMask << kMaxComponentTypeMaskIndex); inputMask |= (inputMask << kMaxComponentTypeMaskIndex); // To validate: // 1. Remove any indexes that are not enabled in the input (& inputMask) // 2. Remove any indexes that exist in output, but not in input (& outputMask) // 3. Use == to verify equality return (outputTypes & inputMask) == ((inputTypes & outputMask) & inputMask); } GLsizeiptr GetBoundBufferAvailableSize(const OffsetBindingPointer<Buffer> &binding) { Buffer *buffer = binding.get(); if (buffer) { if (binding.getSize() == 0) return static_cast<GLsizeiptr>(buffer->getSize()); angle::CheckedNumeric<GLintptr> offset = binding.getOffset(); angle::CheckedNumeric<GLsizeiptr> size = binding.getSize(); angle::CheckedNumeric<GLsizeiptr> bufferSize = buffer->getSize(); auto end = offset + size; auto clampedSize = size; auto difference = end - bufferSize; if (!difference.IsValid()) { return 0; } if (difference.ValueOrDie() > 0) { clampedSize = size - difference; } return clampedSize.ValueOrDefault(0); } else { return 0; } } } // namespace gl