modules/glshared/glsRandomUniformBlockCase.cpp - third_party/vulkan-cts - Git at Google

 /*-------------------------------------------------------------------------
  * drawElements Quality Program OpenGL (ES) Module
  * -----------------------------------------------
  *
  * Copyright 2014 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *//*!
  * \file
  * \brief Random uniform block layout case.
  *//*--------------------------------------------------------------------*/

 #include "glsRandomUniformBlockCase.hpp"
 #include "tcuCommandLine.hpp"
 #include "deRandom.hpp"
 #include "deStringUtil.hpp"

 using std::string;
 using std::vector;

 namespace deqp
 {
 namespace gls
 {

 using namespace gls::ub;

 RandomUniformBlockCase::RandomUniformBlockCase (tcu::TestContext&	testCtx,
 												glu::RenderContext&	renderCtx,
 												glu::GLSLVersion	glslVersion,
 												const char*			name,
 												const char*			description,
 												BufferMode			bufferMode,
 												deUint32			features,
 												deUint32			seed)
 	: UniformBlockCase		(testCtx, renderCtx, name, description, glslVersion, bufferMode)
 	, m_features			(features)
 	, m_maxVertexBlocks		((features & FEATURE_VERTEX_BLOCKS)		? 4 : 0)
 	, m_maxFragmentBlocks	((features & FEATURE_FRAGMENT_BLOCKS)	? 4 : 0)
 	, m_maxSharedBlocks		((features & FEATURE_SHARED_BLOCKS)		? 4 : 0)
 	, m_maxInstances		((features & FEATURE_INSTANCE_ARRAYS)	? 3 : 0)
 	, m_maxArrayLength		((features & FEATURE_ARRAYS)			? 8 : 0)
 	, m_maxStructDepth		((features & FEATURE_STRUCTS)			? 2 : 0)
 	, m_maxBlockMembers		(5)
 	, m_maxStructMembers	(4)
 	, m_seed				(seed)
 	, m_blockNdx			(1)
 	, m_uniformNdx			(1)
 	, m_structNdx			(1)
 {
 }

 void RandomUniformBlockCase::init (void)
 {
 	de::Random rnd(m_seed);

 	int numShared		= m_maxSharedBlocks				> 0	? rnd.getInt(1, m_maxSharedBlocks)				: 0;
 	int numVtxBlocks	= m_maxVertexBlocks-numShared	> 0	? rnd.getInt(1, m_maxVertexBlocks-numShared)	: 0;
 	int	numFragBlocks	= m_maxFragmentBlocks-numShared	> 0 ? rnd.getInt(1, m_maxFragmentBlocks-numShared)	: 0;

 	for (int ndx = 0; ndx < numShared; ndx++)
 		generateBlock(rnd, DECLARE_VERTEX|DECLARE_FRAGMENT);

 	for (int ndx = 0; ndx < numVtxBlocks; ndx++)
 		generateBlock(rnd, DECLARE_VERTEX);

 	for (int ndx = 0; ndx < numFragBlocks; ndx++)
 		generateBlock(rnd, DECLARE_FRAGMENT);
 }

 void RandomUniformBlockCase::generateBlock (de::Random& rnd, deUint32 layoutFlags)
 {
 	DE_ASSERT(m_blockNdx <= 'z' - 'a');

 	const float		instanceArrayWeight	= 0.3f;
 	UniformBlock&	block				= m_interface.allocBlock((string("Block") + (char)('A' + m_blockNdx)).c_str());
 	int				numInstances		= (m_maxInstances > 0 && rnd.getFloat() < instanceArrayWeight) ? rnd.getInt(0, m_maxInstances) : 0;
 	int				numUniforms			= rnd.getInt(1, m_maxBlockMembers);

 	if (numInstances > 0)
 		block.setArraySize(numInstances);

 	if (numInstances > 0 || rnd.getBool())
 		block.setInstanceName((string("block") + (char)('A' + m_blockNdx)).c_str());

 	// Layout flag candidates.
 	vector<deUint32> layoutFlagCandidates;
 	layoutFlagCandidates.push_back(0);
 	if (m_features & FEATURE_PACKED_LAYOUT)
 		layoutFlagCandidates.push_back(LAYOUT_SHARED);
 	if ((m_features & FEATURE_SHARED_LAYOUT) && ((layoutFlags & DECLARE_BOTH) != DECLARE_BOTH))
 		layoutFlagCandidates.push_back(LAYOUT_PACKED); // \note packed layout can only be used in a single shader stage.
 	if (m_features & FEATURE_STD140_LAYOUT)
 		layoutFlagCandidates.push_back(LAYOUT_STD140);

 	layoutFlags |= rnd.choose<deUint32>(layoutFlagCandidates.begin(), layoutFlagCandidates.end());

 	if (m_features & FEATURE_MATRIX_LAYOUT)
 	{
 		static const deUint32 matrixCandidates[] = { 0, LAYOUT_ROW_MAJOR, LAYOUT_COLUMN_MAJOR };
 		layoutFlags |= rnd.choose<deUint32>(&matrixCandidates[0], &matrixCandidates[DE_LENGTH_OF_ARRAY(matrixCandidates)]);
 	}

 	block.setFlags(layoutFlags);

 	for (int ndx = 0; ndx < numUniforms; ndx++)
 		generateUniform(rnd, block);

 	m_blockNdx += 1;
 }

 static std::string genName (char first, char last, int ndx)
 {
 	std::string	str			= "";
 	int			alphabetLen	= last - first + 1;

 	while (ndx > alphabetLen)
 	{
 		str.insert(str.begin(), (char)(first + ((ndx-1)%alphabetLen)));
 		ndx = ((ndx-1) / alphabetLen);
 	}

 	str.insert(str.begin(), (char)(first + (ndx%(alphabetLen+1)) - 1));

 	return str;
 }

 void RandomUniformBlockCase::generateUniform (de::Random& rnd, UniformBlock& block)
 {
 	const float		unusedVtxWeight		= 0.15f;
 	const float		unusedFragWeight	= 0.15f;
 	bool			unusedOk			= (m_features & FEATURE_UNUSED_UNIFORMS) != 0;
 	deUint32		flags				= 0;
 	std::string		name				= genName('a', 'z', m_uniformNdx);
 	VarType			type				= generateType(rnd, 0, true);

 	flags |= (unusedOk && rnd.getFloat() < unusedVtxWeight)		? UNUSED_VERTEX		: 0;
 	flags |= (unusedOk && rnd.getFloat() < unusedFragWeight)	? UNUSED_FRAGMENT	: 0;

 	block.addUniform(Uniform(name.c_str(), type, flags));

 	m_uniformNdx += 1;
 }

 VarType RandomUniformBlockCase::generateType (de::Random& rnd, int typeDepth, bool arrayOk)
 {
 	const float structWeight	= 0.1f;
 	const float arrayWeight		= 0.1f;

 	if (typeDepth < m_maxStructDepth && rnd.getFloat() < structWeight)
 	{
 		const float		unusedVtxWeight		= 0.15f;
 		const float		unusedFragWeight	= 0.15f;
 		bool			unusedOk			= (m_features & FEATURE_UNUSED_MEMBERS) != 0;
 		vector<VarType>	memberTypes;
 		int				numMembers = rnd.getInt(1, m_maxStructMembers);

 		// Generate members first so nested struct declarations are in correct order.
 		for (int ndx = 0; ndx < numMembers; ndx++)
 			memberTypes.push_back(generateType(rnd, typeDepth+1, true));

 		StructType& structType = m_interface.allocStruct((string("s") + genName('A', 'Z', m_structNdx)).c_str());
 		m_structNdx += 1;

 		DE_ASSERT(numMembers <= 'Z' - 'A');
 		for (int ndx = 0; ndx < numMembers; ndx++)
 		{
 			deUint32 flags = 0;

 			flags |= (unusedOk && rnd.getFloat() < unusedVtxWeight)		? UNUSED_VERTEX		: 0;
 			flags |= (unusedOk && rnd.getFloat() < unusedFragWeight)	? UNUSED_FRAGMENT	: 0;

 			structType.addMember((string("m") + (char)('A' + ndx)).c_str(), memberTypes[ndx], flags);
 		}

 		return VarType(&structType);
 	}
 	else if (m_maxArrayLength > 0 && arrayOk && rnd.getFloat() < arrayWeight)
 	{
 		const bool	arraysOfArraysOk	= (m_features & FEATURE_ARRAYS_OF_ARRAYS) != 0;
 		const int	arrayLength			= rnd.getInt(1, m_maxArrayLength);
 		VarType	elementType	= generateType(rnd, typeDepth, arraysOfArraysOk);
 		return VarType(elementType, arrayLength);
 	}
 	else
 	{
 		vector<glu::DataType> typeCandidates;

 		typeCandidates.push_back(glu::TYPE_FLOAT);
 		typeCandidates.push_back(glu::TYPE_INT);
 		typeCandidates.push_back(glu::TYPE_UINT);
 		typeCandidates.push_back(glu::TYPE_BOOL);

 		if (m_features & FEATURE_VECTORS)
 		{
 			typeCandidates.push_back(glu::TYPE_FLOAT_VEC2);
 			typeCandidates.push_back(glu::TYPE_FLOAT_VEC3);
 			typeCandidates.push_back(glu::TYPE_FLOAT_VEC4);
 			typeCandidates.push_back(glu::TYPE_INT_VEC2);
 			typeCandidates.push_back(glu::TYPE_INT_VEC3);
 			typeCandidates.push_back(glu::TYPE_INT_VEC4);
 			typeCandidates.push_back(glu::TYPE_UINT_VEC2);
 			typeCandidates.push_back(glu::TYPE_UINT_VEC3);
 			typeCandidates.push_back(glu::TYPE_UINT_VEC4);
 			typeCandidates.push_back(glu::TYPE_BOOL_VEC2);
 			typeCandidates.push_back(glu::TYPE_BOOL_VEC3);
 			typeCandidates.push_back(glu::TYPE_BOOL_VEC4);
 		}

 		if (m_features & FEATURE_MATRICES)
 		{
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT2);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT2X3);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT3X2);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT3);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT3X4);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT4X2);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT4X3);
 			typeCandidates.push_back(glu::TYPE_FLOAT_MAT4);
 		}

 		glu::DataType	type	= rnd.choose<glu::DataType>(typeCandidates.begin(), typeCandidates.end());
 		deUint32		flags	= 0;

 		if (!glu::isDataTypeBoolOrBVec(type))
 		{
 			// Precision.
 			static const deUint32 precisionCandidates[] = { PRECISION_LOW, PRECISION_MEDIUM, PRECISION_HIGH };
 			flags |= rnd.choose<deUint32>(&precisionCandidates[0], &precisionCandidates[DE_LENGTH_OF_ARRAY(precisionCandidates)]);
 		}

 		return VarType(type, flags);
 	}
 }

 } // gls
 } // deqp
	/*-------------------------------------------------------------------------
	* drawElements Quality Program OpenGL (ES) Module
	* -----------------------------------------------
	*
	* Copyright 2014 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	//!
	* \file
	* \brief Random uniform block layout case.
	//--------------------------------------------------------------------*/

	#include "glsRandomUniformBlockCase.hpp"
	#include "tcuCommandLine.hpp"
	#include "deRandom.hpp"
	#include "deStringUtil.hpp"

	using std::string;
	using std::vector;

	namespace deqp
	{
	namespace gls
	{

	using namespace gls::ub;

	RandomUniformBlockCase::RandomUniformBlockCase (tcu::TestContext& testCtx,
	glu::RenderContext& renderCtx,
	glu::GLSLVersion glslVersion,
	const char* name,
	const char* description,
	BufferMode bufferMode,
	deUint32 features,
	deUint32 seed)
	: UniformBlockCase (testCtx, renderCtx, name, description, glslVersion, bufferMode)
	, m_features (features)
	, m_maxVertexBlocks ((features & FEATURE_VERTEX_BLOCKS) ? 4 : 0)
	, m_maxFragmentBlocks ((features & FEATURE_FRAGMENT_BLOCKS) ? 4 : 0)
	, m_maxSharedBlocks ((features & FEATURE_SHARED_BLOCKS) ? 4 : 0)
	, m_maxInstances ((features & FEATURE_INSTANCE_ARRAYS) ? 3 : 0)
	, m_maxArrayLength ((features & FEATURE_ARRAYS) ? 8 : 0)
	, m_maxStructDepth ((features & FEATURE_STRUCTS) ? 2 : 0)
	, m_maxBlockMembers (5)
	, m_maxStructMembers (4)
	, m_seed (seed)
	, m_blockNdx (1)
	, m_uniformNdx (1)
	, m_structNdx (1)
	{
	}

	void RandomUniformBlockCase::init (void)
	{
	de::Random rnd(m_seed);

	int numShared = m_maxSharedBlocks > 0 ? rnd.getInt(1, m_maxSharedBlocks) : 0;
	int numVtxBlocks = m_maxVertexBlocks-numShared > 0 ? rnd.getInt(1, m_maxVertexBlocks-numShared) : 0;
	int numFragBlocks = m_maxFragmentBlocks-numShared > 0 ? rnd.getInt(1, m_maxFragmentBlocks-numShared) : 0;

	for (int ndx = 0; ndx < numShared; ndx++)
	generateBlock(rnd, DECLARE_VERTEX\|DECLARE_FRAGMENT);

	for (int ndx = 0; ndx < numVtxBlocks; ndx++)
	generateBlock(rnd, DECLARE_VERTEX);

	for (int ndx = 0; ndx < numFragBlocks; ndx++)
	generateBlock(rnd, DECLARE_FRAGMENT);
	}

	void RandomUniformBlockCase::generateBlock (de::Random& rnd, deUint32 layoutFlags)
	{
	DE_ASSERT(m_blockNdx <= 'z' - 'a');

	const float instanceArrayWeight = 0.3f;
	UniformBlock& block = m_interface.allocBlock((string("Block") + (char)('A' + m_blockNdx)).c_str());
	int numInstances = (m_maxInstances > 0 && rnd.getFloat() < instanceArrayWeight) ? rnd.getInt(0, m_maxInstances) : 0;
	int numUniforms = rnd.getInt(1, m_maxBlockMembers);

	if (numInstances > 0)
	block.setArraySize(numInstances);

	if (numInstances > 0 \|\| rnd.getBool())
	block.setInstanceName((string("block") + (char)('A' + m_blockNdx)).c_str());

	// Layout flag candidates.
	vector<deUint32> layoutFlagCandidates;
	layoutFlagCandidates.push_back(0);
	if (m_features & FEATURE_PACKED_LAYOUT)
	layoutFlagCandidates.push_back(LAYOUT_SHARED);
	if ((m_features & FEATURE_SHARED_LAYOUT) && ((layoutFlags & DECLARE_BOTH) != DECLARE_BOTH))
	layoutFlagCandidates.push_back(LAYOUT_PACKED); // \note packed layout can only be used in a single shader stage.
	if (m_features & FEATURE_STD140_LAYOUT)
	layoutFlagCandidates.push_back(LAYOUT_STD140);

	layoutFlags \|= rnd.choose<deUint32>(layoutFlagCandidates.begin(), layoutFlagCandidates.end());

	if (m_features & FEATURE_MATRIX_LAYOUT)
	{
	static const deUint32 matrixCandidates[] = { 0, LAYOUT_ROW_MAJOR, LAYOUT_COLUMN_MAJOR };
	layoutFlags \|= rnd.choose<deUint32>(&matrixCandidates[0], &matrixCandidates[DE_LENGTH_OF_ARRAY(matrixCandidates)]);
	}

	block.setFlags(layoutFlags);

	for (int ndx = 0; ndx < numUniforms; ndx++)
	generateUniform(rnd, block);

	m_blockNdx += 1;
	}

	static std::string genName (char first, char last, int ndx)
	{
	std::string str = "";
	int alphabetLen = last - first + 1;

	while (ndx > alphabetLen)
	{
	str.insert(str.begin(), (char)(first + ((ndx-1)%alphabetLen)));
	ndx = ((ndx-1) / alphabetLen);
	}

	str.insert(str.begin(), (char)(first + (ndx%(alphabetLen+1)) - 1));

	return str;
	}

	void RandomUniformBlockCase::generateUniform (de::Random& rnd, UniformBlock& block)
	{
	const float unusedVtxWeight = 0.15f;
	const float unusedFragWeight = 0.15f;
	bool unusedOk = (m_features & FEATURE_UNUSED_UNIFORMS) != 0;
	deUint32 flags = 0;
	std::string name = genName('a', 'z', m_uniformNdx);
	VarType type = generateType(rnd, 0, true);

	flags \|= (unusedOk && rnd.getFloat() < unusedVtxWeight) ? UNUSED_VERTEX : 0;
	flags \|= (unusedOk && rnd.getFloat() < unusedFragWeight) ? UNUSED_FRAGMENT : 0;

	block.addUniform(Uniform(name.c_str(), type, flags));

	m_uniformNdx += 1;
	}

	VarType RandomUniformBlockCase::generateType (de::Random& rnd, int typeDepth, bool arrayOk)
	{
	const float structWeight = 0.1f;
	const float arrayWeight = 0.1f;

	if (typeDepth < m_maxStructDepth && rnd.getFloat() < structWeight)
	{
	const float unusedVtxWeight = 0.15f;
	const float unusedFragWeight = 0.15f;
	bool unusedOk = (m_features & FEATURE_UNUSED_MEMBERS) != 0;
	vector<VarType> memberTypes;
	int numMembers = rnd.getInt(1, m_maxStructMembers);

	// Generate members first so nested struct declarations are in correct order.
	for (int ndx = 0; ndx < numMembers; ndx++)
	memberTypes.push_back(generateType(rnd, typeDepth+1, true));

	StructType& structType = m_interface.allocStruct((string("s") + genName('A', 'Z', m_structNdx)).c_str());
	m_structNdx += 1;

	DE_ASSERT(numMembers <= 'Z' - 'A');
	for (int ndx = 0; ndx < numMembers; ndx++)
	{
	deUint32 flags = 0;

	flags \|= (unusedOk && rnd.getFloat() < unusedVtxWeight) ? UNUSED_VERTEX : 0;
	flags \|= (unusedOk && rnd.getFloat() < unusedFragWeight) ? UNUSED_FRAGMENT : 0;

	structType.addMember((string("m") + (char)('A' + ndx)).c_str(), memberTypes[ndx], flags);
	}

	return VarType(&structType);
	}
	else if (m_maxArrayLength > 0 && arrayOk && rnd.getFloat() < arrayWeight)
	{
	const bool arraysOfArraysOk = (m_features & FEATURE_ARRAYS_OF_ARRAYS) != 0;
	const int arrayLength = rnd.getInt(1, m_maxArrayLength);
	VarType elementType = generateType(rnd, typeDepth, arraysOfArraysOk);
	return VarType(elementType, arrayLength);
	}
	else
	{
	vector<glu::DataType> typeCandidates;

	typeCandidates.push_back(glu::TYPE_FLOAT);
	typeCandidates.push_back(glu::TYPE_INT);
	typeCandidates.push_back(glu::TYPE_UINT);
	typeCandidates.push_back(glu::TYPE_BOOL);

	if (m_features & FEATURE_VECTORS)
	{
	typeCandidates.push_back(glu::TYPE_FLOAT_VEC2);
	typeCandidates.push_back(glu::TYPE_FLOAT_VEC3);
	typeCandidates.push_back(glu::TYPE_FLOAT_VEC4);
	typeCandidates.push_back(glu::TYPE_INT_VEC2);
	typeCandidates.push_back(glu::TYPE_INT_VEC3);
	typeCandidates.push_back(glu::TYPE_INT_VEC4);
	typeCandidates.push_back(glu::TYPE_UINT_VEC2);
	typeCandidates.push_back(glu::TYPE_UINT_VEC3);
	typeCandidates.push_back(glu::TYPE_UINT_VEC4);
	typeCandidates.push_back(glu::TYPE_BOOL_VEC2);
	typeCandidates.push_back(glu::TYPE_BOOL_VEC3);
	typeCandidates.push_back(glu::TYPE_BOOL_VEC4);
	}

	if (m_features & FEATURE_MATRICES)
	{
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT2);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT2X3);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT3X2);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT3);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT3X4);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT4X2);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT4X3);
	typeCandidates.push_back(glu::TYPE_FLOAT_MAT4);
	}

	glu::DataType type = rnd.choose<glu::DataType>(typeCandidates.begin(), typeCandidates.end());
	deUint32 flags = 0;

	if (!glu::isDataTypeBoolOrBVec(type))
	{
	// Precision.
	static const deUint32 precisionCandidates[] = { PRECISION_LOW, PRECISION_MEDIUM, PRECISION_HIGH };
	flags \|= rnd.choose<deUint32>(&precisionCandidates[0], &precisionCandidates[DE_LENGTH_OF_ARRAY(precisionCandidates)]);
	}

	return VarType(type, flags);
	}
	}

	} // gls
	} // deqp