src/third_party/angle/src/libANGLE/Config_unittest.cpp - cobalt - Git at Google

 //
 // Copyright (c) 2014 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.
 //

 #include "gmock/gmock.h"
 #include "gtest/gtest.h"
 #include "libANGLE/AttributeMap.h"
 #include "libANGLE/Config.h"

 // Create a generic, valid EGL config that can be modified to test sorting and
 // filtering routines
 static egl::Config GenerateGenericConfig()
 {
     egl::Config config;

     config.bufferSize = 24;
     config.redSize = 8;
     config.greenSize = 8;
     config.blueSize = 8;
     config.luminanceSize = 0;
     config.alphaSize = 8;
     config.alphaMaskSize = 0;
     config.bindToTextureRGB = EGL_TRUE;
     config.bindToTextureRGBA = EGL_TRUE;
     config.colorBufferType = EGL_RGB_BUFFER;
     config.configCaveat = EGL_NONE;
     config.configID = 0;
     config.conformant = EGL_OPENGL_ES2_BIT;
     config.depthSize = 24;
     config.level = 0;
     config.matchNativePixmap = EGL_NONE;
     config.maxPBufferWidth = 1024;
     config.maxPBufferHeight = 1024;
     config.maxPBufferPixels = config.maxPBufferWidth * config.maxPBufferWidth;
     config.maxSwapInterval = 0;
     config.minSwapInterval = 4;
     config.nativeRenderable = EGL_OPENGL_ES2_BIT;
     config.nativeVisualID = 0;
     config.nativeVisualType = 0;
     config.renderableType = EGL_FALSE;
     config.sampleBuffers = 0;
     config.samples = 0;
     config.stencilSize = 8;
     config.surfaceType = EGL_PBUFFER_BIT | EGL_WINDOW_BIT | EGL_SWAP_BEHAVIOR_PRESERVED_BIT;
     config.transparentType = EGL_NONE;
     config.transparentRedValue = 0;
     config.transparentGreenValue = 0;
     config.transparentBlueValue = 0;

     return config;
 }

 static std::vector<egl::Config> GenerateUniqueConfigs(size_t count)
 {
     std::vector<egl::Config> configs;

     for (size_t i = 0; i < count; i++)
     {
         egl::Config config = GenerateGenericConfig();
         config.samples = static_cast<EGLint>(i);
         configs.push_back(config);
     }

     return configs;
 }

 // Add unique configs to a ConfigSet and expect that the size of the
 // set is equal to the number of configs added.
 TEST(ConfigSetTest, Size)
 {
     egl::ConfigSet set;

     std::vector<egl::Config> uniqueConfigs = GenerateUniqueConfigs(16);
     for (size_t i = 0; i < uniqueConfigs.size(); i++)
     {
         set.add(uniqueConfigs[i]);
         EXPECT_EQ(set.size(), i + 1);
     }
 }

 // [EGL 1.5] section 3.4:
 // EGL_CONFIG_ID is a unique integer identifying different EGLConfigs. Configuration IDs
 // must be small positive integers starting at 1 and ID assignment should be compact;
 // that is, if there are N EGLConfigs defined by the EGL implementation, their
 // configuration IDs should be in the range [1, N].
 TEST(ConfigSetTest, IDs)
 {
     egl::ConfigSet set;

     std::set<EGLint> ids;

     std::vector<egl::Config> uniqueConfigs = GenerateUniqueConfigs(16);
     for (size_t i = 0; i < uniqueConfigs.size(); i++)
     {
         EGLint id = set.add(uniqueConfigs[i]);

         // Check that the config that was inserted has the ID that was returned
         // by ConfigSet::add
         EXPECT_EQ(id, set.get(id).configID);

         ids.insert(id);
     }

     // Verify configCount unique IDs
     EXPECT_EQ(ids.size(), set.size());

     // Check that there are no gaps and the IDs are in the range [1, N].
     EXPECT_EQ(*std::min_element(ids.begin(), ids.end()), 1);
     EXPECT_EQ(*std::max_element(ids.begin(), ids.end()), static_cast<EGLint>(set.size()));
 }

 TEST(ConfigSetTest, Filtering_BitSizes)
 {
     egl::ConfigSet set;

     struct VariableConfigBitSize
     {
         EGLint Name;
         EGLint(egl::Config::*ConfigMember);
     };

     VariableConfigBitSize testMembers[] =
     {
         { EGL_RED_SIZE,     &egl::Config::redSize     },
         { EGL_GREEN_SIZE,   &egl::Config::greenSize   },
         { EGL_BLUE_SIZE,    &egl::Config::blueSize    },
         { EGL_ALPHA_SIZE,   &egl::Config::alphaSize   },
         { EGL_DEPTH_SIZE,   &egl::Config::depthSize   },
         { EGL_STENCIL_SIZE, &egl::Config::stencilSize },
     };

     // Generate configsPerType configs with varying bit sizes of each type
     size_t configsPerType = 4;
     for (size_t i = 0; i < ArraySize(testMembers); i++)
     {
         for (size_t j = 0; j < configsPerType; j++)
         {
             egl::Config config = GenerateGenericConfig();

             // Set all the other tested members of this config to 0
             for (size_t k = 0; k < ArraySize(testMembers); k++)
             {
                 config.*(testMembers[k].ConfigMember) = 0;
             }

             // Set the tested member of this config to i so it ranges from
             // [1, configsPerType]
             config.*(testMembers[i].ConfigMember) = static_cast<EGLint>(j) + 1;

             set.add(config);
         }
     }

     // for each tested member, filter by it's type and verify that the correct number
     // of results are returned
     for (size_t i = 0; i < ArraySize(testMembers); i++)
     {
         // Start with a filter of 1 to not grab the other members
         for (EGLint j = 0; j < static_cast<EGLint>(configsPerType); j++)
         {
             egl::AttributeMap filter;
             filter.insert(testMembers[i].Name, j + 1);

             std::vector<const egl::Config *> filteredConfigs = set.filter(filter);

             EXPECT_EQ(filteredConfigs.size(), configsPerType - j);
         }
     }
 }

 // Verify the sorting, [EGL 1.5] section 3.4.1.2 pg 30:
 // [configs are sorted] by larger total number of color bits (for an RGB
 // color buffer this is the sum of EGL_RED_SIZE, EGL_GREEN_SIZE, EGL_BLUE_SIZE,
 // and EGL_ALPHA_SIZE; for a luminance color buffer, the sum of EGL_LUMINANCE_SIZE
 // and EGL_ALPHA_SIZE).If the requested number of bits in attrib list for a
 // particular color component is 0 or EGL_DONT_CARE, then the number of bits
 // for that component is not considered.
 TEST(ConfigSetTest, Sorting_BitSizes)
 {
     egl::ConfigSet set;
     size_t testConfigCount = 64;
     for (size_t i = 0; i < testConfigCount; i++)
     {
         egl::Config config = GenerateGenericConfig();

         // Give random-ish bit sizes to the config
         config.redSize =   (i *  2) %  3;
         config.greenSize = (i +  5) %  7;
         config.blueSize =  (i +  7) % 11;
         config.alphaSize = (i + 13) % 17;

         set.add(config);
     }

     egl::AttributeMap greaterThan1BitFilter;
     greaterThan1BitFilter.insert(EGL_RED_SIZE, 1);
     greaterThan1BitFilter.insert(EGL_GREEN_SIZE, 1);
     greaterThan1BitFilter.insert(EGL_BLUE_SIZE, 1);
     greaterThan1BitFilter.insert(EGL_ALPHA_SIZE, 1);

     std::vector<const egl::Config *> filteredConfigs = set.filter(greaterThan1BitFilter);
     for (size_t i = 1; i < filteredConfigs.size(); i++)
     {
         const egl::Config &prevConfig = *filteredConfigs[i - 1];
         size_t prevBitCount = prevConfig.redSize +
                               prevConfig.greenSize +
                               prevConfig.blueSize +
                               prevConfig.alphaSize;

         const egl::Config &curConfig = *filteredConfigs[i];
         size_t curBitCount = curConfig.redSize +
                              curConfig.greenSize +
                              curConfig.blueSize +
                              curConfig.alphaSize;

         EXPECT_GE(prevBitCount, curBitCount);
     }
 }
	//
	// Copyright (c) 2014 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.
	//

	#include "gmock/gmock.h"
	#include "gtest/gtest.h"
	#include "libANGLE/AttributeMap.h"
	#include "libANGLE/Config.h"

	// Create a generic, valid EGL config that can be modified to test sorting and
	// filtering routines
	static egl::Config GenerateGenericConfig()
	{
	egl::Config config;

	config.bufferSize = 24;
	config.redSize = 8;
	config.greenSize = 8;
	config.blueSize = 8;
	config.luminanceSize = 0;
	config.alphaSize = 8;
	config.alphaMaskSize = 0;
	config.bindToTextureRGB = EGL_TRUE;
	config.bindToTextureRGBA = EGL_TRUE;
	config.colorBufferType = EGL_RGB_BUFFER;
	config.configCaveat = EGL_NONE;
	config.configID = 0;
	config.conformant = EGL_OPENGL_ES2_BIT;
	config.depthSize = 24;
	config.level = 0;
	config.matchNativePixmap = EGL_NONE;
	config.maxPBufferWidth = 1024;
	config.maxPBufferHeight = 1024;
	config.maxPBufferPixels = config.maxPBufferWidth * config.maxPBufferWidth;
	config.maxSwapInterval = 0;
	config.minSwapInterval = 4;
	config.nativeRenderable = EGL_OPENGL_ES2_BIT;
	config.nativeVisualID = 0;
	config.nativeVisualType = 0;
	config.renderableType = EGL_FALSE;
	config.sampleBuffers = 0;
	config.samples = 0;
	config.stencilSize = 8;
	config.surfaceType = EGL_PBUFFER_BIT \| EGL_WINDOW_BIT \| EGL_SWAP_BEHAVIOR_PRESERVED_BIT;
	config.transparentType = EGL_NONE;
	config.transparentRedValue = 0;
	config.transparentGreenValue = 0;
	config.transparentBlueValue = 0;

	return config;
	}

	static std::vector<egl::Config> GenerateUniqueConfigs(size_t count)
	{
	std::vector<egl::Config> configs;

	for (size_t i = 0; i < count; i++)
	{
	egl::Config config = GenerateGenericConfig();
	config.samples = static_cast<EGLint>(i);
	configs.push_back(config);
	}

	return configs;
	}

	// Add unique configs to a ConfigSet and expect that the size of the
	// set is equal to the number of configs added.
	TEST(ConfigSetTest, Size)
	{
	egl::ConfigSet set;

	std::vector<egl::Config> uniqueConfigs = GenerateUniqueConfigs(16);
	for (size_t i = 0; i < uniqueConfigs.size(); i++)
	{
	set.add(uniqueConfigs[i]);
	EXPECT_EQ(set.size(), i + 1);
	}
	}

	// [EGL 1.5] section 3.4:
	// EGL_CONFIG_ID is a unique integer identifying different EGLConfigs. Configuration IDs
	// must be small positive integers starting at 1 and ID assignment should be compact;
	// that is, if there are N EGLConfigs defined by the EGL implementation, their
	// configuration IDs should be in the range [1, N].
	TEST(ConfigSetTest, IDs)
	{
	egl::ConfigSet set;

	std::set<EGLint> ids;

	std::vector<egl::Config> uniqueConfigs = GenerateUniqueConfigs(16);
	for (size_t i = 0; i < uniqueConfigs.size(); i++)
	{
	EGLint id = set.add(uniqueConfigs[i]);

	// Check that the config that was inserted has the ID that was returned
	// by ConfigSet::add
	EXPECT_EQ(id, set.get(id).configID);

	ids.insert(id);
	}

	// Verify configCount unique IDs
	EXPECT_EQ(ids.size(), set.size());

	// Check that there are no gaps and the IDs are in the range [1, N].
	EXPECT_EQ(*std::min_element(ids.begin(), ids.end()), 1);
	EXPECT_EQ(*std::max_element(ids.begin(), ids.end()), static_cast<EGLint>(set.size()));
	}

	TEST(ConfigSetTest, Filtering_BitSizes)
	{
	egl::ConfigSet set;

	struct VariableConfigBitSize
	{
	EGLint Name;
	EGLint(egl::Config::*ConfigMember);
	};

	VariableConfigBitSize testMembers[] =
	{
	{ EGL_RED_SIZE, &egl::Config::redSize },
	{ EGL_GREEN_SIZE, &egl::Config::greenSize },
	{ EGL_BLUE_SIZE, &egl::Config::blueSize },
	{ EGL_ALPHA_SIZE, &egl::Config::alphaSize },
	{ EGL_DEPTH_SIZE, &egl::Config::depthSize },
	{ EGL_STENCIL_SIZE, &egl::Config::stencilSize },
	};

	// Generate configsPerType configs with varying bit sizes of each type
	size_t configsPerType = 4;
	for (size_t i = 0; i < ArraySize(testMembers); i++)
	{
	for (size_t j = 0; j < configsPerType; j++)
	{
	egl::Config config = GenerateGenericConfig();

	// Set all the other tested members of this config to 0
	for (size_t k = 0; k < ArraySize(testMembers); k++)
	{
	config.*(testMembers[k].ConfigMember) = 0;
	}

	// Set the tested member of this config to i so it ranges from
	// [1, configsPerType]
	config.*(testMembers[i].ConfigMember) = static_cast<EGLint>(j) + 1;

	set.add(config);
	}
	}

	// for each tested member, filter by it's type and verify that the correct number
	// of results are returned
	for (size_t i = 0; i < ArraySize(testMembers); i++)
	{
	// Start with a filter of 1 to not grab the other members
	for (EGLint j = 0; j < static_cast<EGLint>(configsPerType); j++)
	{
	egl::AttributeMap filter;
	filter.insert(testMembers[i].Name, j + 1);

	std::vector<const egl::Config *> filteredConfigs = set.filter(filter);

	EXPECT_EQ(filteredConfigs.size(), configsPerType - j);
	}
	}
	}

	// Verify the sorting, [EGL 1.5] section 3.4.1.2 pg 30:
	// [configs are sorted] by larger total number of color bits (for an RGB
	// color buffer this is the sum of EGL_RED_SIZE, EGL_GREEN_SIZE, EGL_BLUE_SIZE,
	// and EGL_ALPHA_SIZE; for a luminance color buffer, the sum of EGL_LUMINANCE_SIZE
	// and EGL_ALPHA_SIZE).If the requested number of bits in attrib list for a
	// particular color component is 0 or EGL_DONT_CARE, then the number of bits
	// for that component is not considered.
	TEST(ConfigSetTest, Sorting_BitSizes)
	{
	egl::ConfigSet set;
	size_t testConfigCount = 64;
	for (size_t i = 0; i < testConfigCount; i++)
	{
	egl::Config config = GenerateGenericConfig();

	// Give random-ish bit sizes to the config
	config.redSize = (i * 2) % 3;
	config.greenSize = (i + 5) % 7;
	config.blueSize = (i + 7) % 11;
	config.alphaSize = (i + 13) % 17;

	set.add(config);
	}

	egl::AttributeMap greaterThan1BitFilter;
	greaterThan1BitFilter.insert(EGL_RED_SIZE, 1);
	greaterThan1BitFilter.insert(EGL_GREEN_SIZE, 1);
	greaterThan1BitFilter.insert(EGL_BLUE_SIZE, 1);
	greaterThan1BitFilter.insert(EGL_ALPHA_SIZE, 1);

	std::vector<const egl::Config *> filteredConfigs = set.filter(greaterThan1BitFilter);
	for (size_t i = 1; i < filteredConfigs.size(); i++)
	{
	const egl::Config &prevConfig = *filteredConfigs[i - 1];
	size_t prevBitCount = prevConfig.redSize +
	prevConfig.greenSize +
	prevConfig.blueSize +
	prevConfig.alphaSize;

	const egl::Config &curConfig = *filteredConfigs[i];
	size_t curBitCount = curConfig.redSize +
	curConfig.greenSize +
	curConfig.blueSize +
	curConfig.alphaSize;

	EXPECT_GE(prevBitCount, curBitCount);
	}
	}