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fuchsia / third_party / vulkan-cts / a8c8a8df7a6b04c70caed1beff6307dfec871386 / . / external / vulkancts / modules / vulkan / memory_model / vktMemoryModelSharedLayout.cpp
blob: 5e94044f0f2a9dd6066fdb00324a34582b6faa5b [file] [log] [blame]
/*------------------------------------------------------------------------
* Vulkan Conformance Tests
* ------------------------
*
* Copyright (c) 2021 The Khronos Group Inc.
* Copyright (c) 2021 Google LLC.
*
* 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 Shared memory model layout tests.
*//*--------------------------------------------------------------------*/
#include "vktMemoryModelSharedLayout.hpp"
#include "vktMemoryModelSharedLayoutCase.hpp"
#include "tcuCommandLine.hpp"
#include "tcuTestLog.hpp"
#include "deRandom.hpp"
#include "deStringUtil.hpp"
#include "vktTestCaseUtil.hpp"
#include "vkMemUtil.hpp"
namespace vkt
{
namespace MemoryModel
{
using std::string;
using std::vector;
namespace
{
enum FeatureBits
{
FEATURE_VECTORS = (1 << 0),
FEATURE_MATRICES = (1 << 1),
FEATURE_ARRAYS = (1 << 2),
FEATURE_STRUCTS = (1 << 3),
FEATURE_UNUSED_VARS = (1 << 4),
FEATURE_UNUSED_MEMBERS = (1 << 5),
FEATURE_ARRAYS_OF_ARRAYS = (1 << 6),
FEATURE_16BIT_TYPES = (1 << 7),
FEATURE_8BIT_TYPES = (1 << 8),
};
/*--------------------------------------------------------------------*//*!
* \brief Generates names for shared memory structs and their members.
* \param first The first character of the alphabet.
* \param last The last character of the alphabet.
* \param ndx The index of the name in the alphabet.
*
* If the index lies within the range [1, (last-first)+1], returns
* the character represented by the ASCII code 'first + ndx - 1'
* as a string.
*
* E.g. if "first" is 'a', "last" 'z' and "ndx" is 1, returns a. If "ndx"
* is 2, returns b and so forth.
*
* If "ndx" is greater than the range, the function keeps dividing it by
* the alphabet length until the index is within the range. In each iteration,
* the name is prefixed with the ASCII character represented by the modulo
* of the index.
*
* E.g. if "first" is 'a', "last" 'z' and "ndx" is 28, returns ab. If "ndx"
* is 702, returns aaa and so forth.
*//*--------------------------------------------------------------------*/
string genName (char first, char last, int ndx)
{
string str;
int alphabetLen = static_cast<int>(last) - static_cast<int>(first) + 1;
while (ndx > 0)
{
const int asciiCode = static_cast<int>(first) + ((ndx - 1) % alphabetLen);
str.insert(str.begin(), static_cast<char>(asciiCode));
ndx = ((ndx - 1) / alphabetLen);
}
return str;
}
void createRandomCaseGroup (tcu::TestCaseGroup* parentGroup, tcu::TestContext &testCtx, const char *groupName,
const char *description, const deUint32 features, const int numCases, deUint32 baseSeed)
{
tcu::TestCaseGroup *group = new tcu::TestCaseGroup(testCtx, groupName, description);
parentGroup->addChild(group);
baseSeed += static_cast<deUint32>(testCtx.getCommandLine().getBaseSeed());
for (int i = 0; i < numCases; i++)
group->addChild(new RandomSharedLayoutCase(testCtx, de::toString(i).c_str(), "", features, static_cast<deUint32>(i + baseSeed)));
}
} // anonymous
RandomSharedLayoutCase::RandomSharedLayoutCase (tcu::TestContext &testCtx, const char *name, const char *description,
deUint32 features, deUint32 seed)
: SharedLayoutCase(testCtx, name, description)
, m_features(features)
, m_maxArrayLength((features & FEATURE_ARRAYS) ? 3 : 0)
, m_seed(seed)
{
de::Random rnd(m_seed);
m_interface.enable16BitTypes(features & FEATURE_16BIT_TYPES);
m_interface.enable8BitTypes(features & FEATURE_8BIT_TYPES);
for (int i = 0; i < rnd.getInt(1, m_maxSharedObjects); i++)
generateSharedMemoryObject(rnd);
init();
}
/*--------------------------------------------------------------------*//*!
* \brief Creates definitions for shared memory structs.
* \param rnd Random value generator used for deciding the type of the variable.
*
* Creates definitions for shared memory structs. Each struct's name starts with
* an upper-case S and its instance name with a lower-case s followed by its index
* number.
*//*--------------------------------------------------------------------*/
void RandomSharedLayoutCase::generateSharedMemoryObject (de::Random &rnd)
{
const string name = "S" + de::toString(m_interface.getNumSharedObjects() + 1);
const string instanceName = "s" + de::toString(m_interface.getNumSharedObjects() + 1);
SharedStruct &object = m_interface.allocSharedObject(name, instanceName);
const int numVars = rnd.getInt(2, m_maxSharedObjectMembers);
for (int i = 0; i < numVars; i++)
generateSharedMemoryVar(rnd, object);
}
void RandomSharedLayoutCase::generateSharedMemoryVar (de::Random &rnd, SharedStruct &object)
{
SharedStructVar var;
var.name = genName('a', 'z', object.getNumMembers() + 1);
if ((m_features & FEATURE_ARRAYS_OF_ARRAYS) != 0 || (m_features & FEATURE_STRUCTS) != 0)
var.type = generateType(rnd, 3, true);
else
var.type = generateType(rnd, 1, true);
var.topLevelArraySize = 1;
if (var.type.isArrayType())
var.topLevelArraySize = var.type.getArraySize() == glu::VarType::UNSIZED_ARRAY ? 0 : var.type.getArraySize();
object.addMember(var);
}
glu::VarType RandomSharedLayoutCase::generateType (de::Random &rnd, int typeDepth, bool arrayOk)
{
const float structWeight = 0.7f;
const float arrayWeight = 0.8f;
if (typeDepth > 0 && rnd.getFloat() < structWeight && (m_features & FEATURE_STRUCTS))
{
vector<glu::VarType> memberTypes;
const int numMembers = rnd.getInt(1, m_maxStructMembers);
// Generate members first so nested struct declarations are in correct order.
for (int i = 0; i < numMembers; i++)
memberTypes.push_back(generateType(rnd, typeDepth - 1, true));
const string name = "s" + genName('A', 'Z', m_interface.getNumStructs() + 1);
de::SharedPtr<glu::StructType> structType = m_interface.allocStruct(name);
DE_ASSERT(numMembers <= 'Z' - 'A');
for (int i = 0; i < numMembers; i++)
structType.get()->addMember((string("m") + static_cast<char>(('A' + i))).c_str(), memberTypes[i]);
return glu::VarType(structType.get());
}
else if (typeDepth > 0 && m_maxArrayLength > 0 && arrayOk && rnd.getFloat() < arrayWeight)
{
const int arrayLength = rnd.getInt(1, m_maxArrayLength);
const bool childArrayOk = (m_features & FEATURE_ARRAYS_OF_ARRAYS) != 0;
const glu::VarType elementType = generateType(rnd, typeDepth - 1, childArrayOk);
return glu::VarType(elementType, arrayLength);
}
else
{
const float weight8Bit = (m_features & FEATURE_8BIT_TYPES) ? 0.7f : 0.0f;
const float weight16Bit = (m_features & FEATURE_16BIT_TYPES) ? 0.7f : 0.0f;
const float weightMatrices = (m_features & FEATURE_MATRICES) ? 0.3f : 0.0f;
vector<glu::DataType> typeCandidates;
if (rnd.getFloat() < weight16Bit)
{
typeCandidates.push_back(glu::TYPE_UINT16);
typeCandidates.push_back(glu::TYPE_INT16);
typeCandidates.push_back(glu::TYPE_FLOAT16);
if (m_features & FEATURE_VECTORS)
{
typeCandidates.push_back(glu::TYPE_FLOAT16_VEC2);
typeCandidates.push_back(glu::TYPE_FLOAT16_VEC3);
typeCandidates.push_back(glu::TYPE_FLOAT16_VEC4);
typeCandidates.push_back(glu::TYPE_INT16_VEC2);
typeCandidates.push_back(glu::TYPE_INT16_VEC3);
typeCandidates.push_back(glu::TYPE_INT16_VEC4);
typeCandidates.push_back(glu::TYPE_UINT16_VEC2);
typeCandidates.push_back(glu::TYPE_UINT16_VEC3);
typeCandidates.push_back(glu::TYPE_UINT16_VEC4);
}
}
else if (rnd.getFloat() < weight8Bit)
{
typeCandidates.push_back(glu::TYPE_UINT8);
typeCandidates.push_back(glu::TYPE_INT8);
if (m_features & FEATURE_VECTORS)
{
typeCandidates.push_back(glu::TYPE_INT8_VEC2);
typeCandidates.push_back(glu::TYPE_INT8_VEC3);
typeCandidates.push_back(glu::TYPE_INT8_VEC4);
typeCandidates.push_back(glu::TYPE_UINT8_VEC2);
typeCandidates.push_back(glu::TYPE_UINT8_VEC3);
typeCandidates.push_back(glu::TYPE_UINT8_VEC4);
}
}
else
{
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 (rnd.getFloat() < weightMatrices)
{
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());
glu::Precision precision;
if (glu::dataTypeSupportsPrecisionModifier(type))
{
const glu::Precision precisionCandidates[] = { glu::PRECISION_LOWP, glu::PRECISION_MEDIUMP, glu::PRECISION_HIGHP};
precision = rnd.choose<glu::Precision>(&precisionCandidates[0],
&precisionCandidates[DE_LENGTH_OF_ARRAY(precisionCandidates)]);
}
else
precision = glu::PRECISION_LAST;
return glu::VarType(type, precision);
}
}
tcu::TestCaseGroup* createSharedMemoryLayoutTests (tcu::TestContext &testCtx)
{
de::MovePtr<tcu::TestCaseGroup> sharedMemoryLayoutGroup(new tcu::TestCaseGroup(testCtx, "shared", "Shared memory layout tests"));
tcu::TestCaseGroup *parentGroup = sharedMemoryLayoutGroup.get();
{
const deUint32 allBasicTypes = FEATURE_VECTORS | FEATURE_MATRICES;
const deUint32 unused = FEATURE_UNUSED_MEMBERS | FEATURE_UNUSED_VARS;
for (int i = 0; i < 3; ++i)
{
if (i == 1)
{
parentGroup = new tcu::TestCaseGroup(testCtx, "16bit", "16bit");
sharedMemoryLayoutGroup->addChild(parentGroup);
}
else if (i == 2)
{
parentGroup = new tcu::TestCaseGroup(testCtx, "8bit", "8bit");
sharedMemoryLayoutGroup->addChild(parentGroup);
}
const deUint32 use16BitTypes = i == 1 ? FEATURE_16BIT_TYPES : 0;
const deUint32 use8BitTypes = i == 2 ? FEATURE_8BIT_TYPES : 0;
createRandomCaseGroup(parentGroup, testCtx, "scalar_types", "Scalar types only",
use8BitTypes | use16BitTypes | unused, 10, 0);
createRandomCaseGroup(parentGroup, testCtx, "vector_types", "Scalar and vector types only",
use8BitTypes | use16BitTypes | unused | FEATURE_VECTORS, 10, 25);
createRandomCaseGroup(parentGroup, testCtx, "basic_types", "All basic types",
use8BitTypes | use16BitTypes | unused | allBasicTypes, 10, 50);
createRandomCaseGroup(parentGroup, testCtx, "basic_arrays", "Arrays",
use8BitTypes | use16BitTypes | unused | allBasicTypes | FEATURE_ARRAYS, 10, 50);
createRandomCaseGroup(parentGroup, testCtx, "arrays_of_arrays", "Arrays of arrays",
use8BitTypes | use16BitTypes | unused | allBasicTypes | FEATURE_ARRAYS |
FEATURE_ARRAYS_OF_ARRAYS, 10, 950);
createRandomCaseGroup(parentGroup, testCtx, "nested_structs", "Nested structs",
use8BitTypes | use16BitTypes | unused | allBasicTypes | FEATURE_STRUCTS, 10, 100);
createRandomCaseGroup(parentGroup, testCtx, "nested_structs_arrays", "Nested structs, arrays",
use8BitTypes | use16BitTypes | unused | allBasicTypes | FEATURE_STRUCTS |
FEATURE_ARRAYS | FEATURE_ARRAYS_OF_ARRAYS, 10, 150);
}
}
return sharedMemoryLayoutGroup.release();
}
} // MemoryModel
} // vkt