// // 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. // // IndexConversionPerf: // Performance tests for ANGLE index conversion in D3D11. // #include "ANGLEPerfTest.h" #include "tests/test_utils/draw_call_perf_utils.h" #include using namespace angle; namespace { struct IndexConversionPerfParams final : public RenderTestParams { std::string story() const override { std::stringstream strstr; if (indexRangeOffset > 0) { strstr << "_index_range"; } strstr << RenderTestParams::story(); return strstr.str(); } unsigned int numIndexTris; // A second test, which covers using index ranges with an offset. unsigned int indexRangeOffset; }; // Provide a custom gtest parameter name function for IndexConversionPerfParams. std::ostream &operator<<(std::ostream &stream, const IndexConversionPerfParams ¶m) { stream << param.backendAndStory().substr(1); return stream; } class IndexConversionPerfTest : public ANGLERenderTest, public ::testing::WithParamInterface { public: IndexConversionPerfTest(); void initializeBenchmark() override; void destroyBenchmark() override; void drawBenchmark() override; private: void updateBufferData(); void drawConversion(); void drawIndexRange(); GLuint mProgram; GLuint mVertexBuffer; GLuint mIndexBuffer; std::vector mIndexData; }; IndexConversionPerfTest::IndexConversionPerfTest() : ANGLERenderTest("IndexConversionPerfTest", GetParam()), mProgram(0), mVertexBuffer(0), mIndexBuffer(0) {} void IndexConversionPerfTest::initializeBenchmark() { const auto ¶ms = GetParam(); ASSERT_LT(0u, params.iterationsPerStep); ASSERT_LT(0u, params.numIndexTris); mProgram = SetupSimpleScaleAndOffsetProgram(); ASSERT_NE(0u, mProgram); glClearColor(0.0f, 0.0f, 0.0f, 0.0f); // Initialize the vertex data size_t numTris = std::numeric_limits::max() / 3 + 1; mVertexBuffer = Create2DTriangleBuffer(numTris, GL_STATIC_DRAW); glVertexAttribPointer(0, 2, GL_FLOAT, GL_FALSE, 0, 0); glEnableVertexAttribArray(0); // Initialize the index buffer for (unsigned int triIndex = 0; triIndex < params.numIndexTris; ++triIndex) { // Handle two different types of tests, one with index conversion triggered by a -1 index. if (params.indexRangeOffset == 0) { mIndexData.push_back(std::numeric_limits::max()); } else { mIndexData.push_back(0); } mIndexData.push_back(1); mIndexData.push_back(2); } glGenBuffers(1, &mIndexBuffer); glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, mIndexBuffer); updateBufferData(); // Set the viewport glViewport(0, 0, getWindow()->getWidth(), getWindow()->getHeight()); ASSERT_GL_NO_ERROR(); } void IndexConversionPerfTest::updateBufferData() { glBufferData(GL_ELEMENT_ARRAY_BUFFER, mIndexData.size() * sizeof(mIndexData[0]), &mIndexData[0], GL_STATIC_DRAW); } void IndexConversionPerfTest::destroyBenchmark() { glDeleteProgram(mProgram); glDeleteBuffers(1, &mVertexBuffer); glDeleteBuffers(1, &mIndexBuffer); } void IndexConversionPerfTest::drawBenchmark() { const auto ¶ms = GetParam(); if (params.indexRangeOffset == 0) { drawConversion(); } else { drawIndexRange(); } } void IndexConversionPerfTest::drawConversion() { const auto ¶ms = GetParam(); // Trigger an update to ensure we convert once a frame updateBufferData(); for (unsigned int it = 0; it < params.iterationsPerStep; it++) { glDrawElements(GL_TRIANGLES, static_cast(params.numIndexTris * 3 - 1), GL_UNSIGNED_SHORT, reinterpret_cast(0)); } ASSERT_GL_NO_ERROR(); } void IndexConversionPerfTest::drawIndexRange() { const auto ¶ms = GetParam(); unsigned int indexCount = 3; size_t offset = static_cast(indexCount * getNumStepsPerformed()); offset %= (params.numIndexTris * 3); // This test increments an offset each step. Drawing repeatedly may cause the system memory // to release. Then, using a fresh offset will require index range validation, which pages // it back in. The performance should be good even if the data is was used quite a bit. for (unsigned int it = 0; it < params.iterationsPerStep; it++) { glDrawElements(GL_TRIANGLES, static_cast(indexCount), GL_UNSIGNED_SHORT, reinterpret_cast(offset)); } ASSERT_GL_NO_ERROR(); } IndexConversionPerfParams IndexConversionPerfD3D11Params() { IndexConversionPerfParams params; params.eglParameters = egl_platform::D3D11_NULL(); params.majorVersion = 2; params.minorVersion = 0; params.windowWidth = 256; params.windowHeight = 256; params.iterationsPerStep = 225; params.numIndexTris = 3000; params.indexRangeOffset = 0; return params; } IndexConversionPerfParams IndexRangeOffsetPerfD3D11Params() { IndexConversionPerfParams params; params.eglParameters = egl_platform::D3D11_NULL(); params.majorVersion = 2; params.minorVersion = 0; params.windowWidth = 256; params.windowHeight = 256; params.iterationsPerStep = 16; params.numIndexTris = 50000; params.indexRangeOffset = 64; return params; } TEST_P(IndexConversionPerfTest, Run) { run(); } ANGLE_INSTANTIATE_TEST(IndexConversionPerfTest, IndexConversionPerfD3D11Params(), IndexRangeOffsetPerfD3D11Params()); // This test suite is not instantiated on some OSes. GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(IndexConversionPerfTest); } // namespace