external/vulkancts/modules/vulkan/synchronization/vktSynchronizationOperationMultiQueueTests.cpp - third_party/vulkan-cts - Git at Google

 /*------------------------------------------------------------------------
  * Vulkan Conformance Tests
  * ------------------------
  *
  * Copyright (c) 2016 The Khronos Group Inc.
  *
  * 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 Synchronization primitive tests with multi queue
  *//*--------------------------------------------------------------------*/

 #include "vktSynchronizationOperationMultiQueueTests.hpp"
 #include "vkDefs.hpp"
 #include "vktTestCase.hpp"
 #include "vktTestCaseUtil.hpp"
 #include "vkRef.hpp"
 #include "vkRefUtil.hpp"
 #include "vkMemUtil.hpp"
 #include "vkQueryUtil.hpp"
 #include "vkTypeUtil.hpp"
 #include "vkPlatform.hpp"
 #include "deUniquePtr.hpp"
 #include "tcuTestLog.hpp"
 #include "vktSynchronizationUtil.hpp"
 #include "vktSynchronizationOperation.hpp"
 #include "vktSynchronizationOperationTestData.hpp"
 #include "vktTestGroupUtil.hpp"

 namespace vkt
 {
 namespace synchronization
 {
 namespace
 {
 using namespace vk;
 using de::MovePtr;
 using de::UniquePtr;

 enum QueueType
 {
 	QUEUETYPE_WRITE,
 	QUEUETYPE_READ
 };

 struct QueuePair
 {
 	QueuePair	(const deUint32 familyWrite, const deUint32 familyRead, const VkQueue write, const VkQueue read)
 		: familyIndexWrite	(familyWrite)
 		, familyIndexRead	(familyRead)
 		, queueWrite		(write)
 		, queueRead			(read)
 	{}

 	deUint32	familyIndexWrite;
 	deUint32	familyIndexRead;
 	VkQueue		queueWrite;
 	VkQueue		queueRead;
 };

 bool checkQueueFlags (VkQueueFlags availableFlags, const VkQueueFlags neededFlags)
 {
 	if ((availableFlags & (VK_QUEUE_GRAPHICS_BIT | VK_QUEUE_COMPUTE_BIT)) != 0)
 		availableFlags |= VK_QUEUE_TRANSFER_BIT;

 	return (availableFlags & neededFlags) != 0;
 }

 class MultiQueues
 {
 	struct QueueData
 	{
 		VkQueueFlags			flags;
 		std::vector<VkQueue>	queue;
 	};

 public:
 	MultiQueues	(const Context& context)
 	{
 		const InstanceInterface&					instance				= context.getInstanceInterface();
 		const VkPhysicalDevice						physicalDevice			= context.getPhysicalDevice();
 		const std::vector<VkQueueFamilyProperties>	queueFamilyProperties	= getPhysicalDeviceQueueFamilyProperties(instance, physicalDevice);

 		for (deUint32 queuePropertiesNdx = 0; queuePropertiesNdx < queueFamilyProperties.size(); ++queuePropertiesNdx)
 		{
 			addQueueIndex(queuePropertiesNdx,
 						  std::min(2u, queueFamilyProperties[queuePropertiesNdx].queueCount),
 						  queueFamilyProperties[queuePropertiesNdx].queueFlags);
 		}

 		std::vector<VkDeviceQueueCreateInfo>	queueInfos;
 		const float								queuePriorities[2] = { 1.0f, 1.0f };	//get max 2 queues from one family

 		for (std::map<deUint32, QueueData>::iterator it = m_queues.begin(); it!= m_queues.end(); ++it)
 		{
 			const VkDeviceQueueCreateInfo queueInfo	=
 			{
 				VK_STRUCTURE_TYPE_DEVICE_QUEUE_CREATE_INFO,		//VkStructureType			sType;
 				DE_NULL,										//const void*				pNext;
 				(VkDeviceQueueCreateFlags)0u,					//VkDeviceQueueCreateFlags	flags;
 				it->first,										//deUint32					queueFamilyIndex;
 				static_cast<deUint32>(it->second.queue.size()),	//deUint32					queueCount;
 				&queuePriorities[0]								//const float*				pQueuePriorities;
 			};
 			queueInfos.push_back(queueInfo);
 		}

 		{
 			const std::vector<std::string>&	deviceExtensions	= context.getDeviceExtensions();
 			std::vector<const char*>		charDevExtensions;

 			for (size_t ndx = 0; ndx < deviceExtensions.size(); ++ndx)
 				charDevExtensions.push_back(deviceExtensions[ndx].c_str());

 			const VkDeviceCreateInfo		deviceInfo		=
 			{
 				VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO,			//VkStructureType					sType;
 				DE_NULL,										//const void*						pNext;
 				0u,												//VkDeviceCreateFlags				flags;
 				static_cast<deUint32>(queueInfos.size()),		//deUint32							queueCreateInfoCount;
 				&queueInfos[0],									//const VkDeviceQueueCreateInfo*	pQueueCreateInfos;
 				0u,												//deUint32							enabledLayerCount;
 				DE_NULL,										//const char* const*				ppEnabledLayerNames;
 				static_cast<deUint32>(deviceExtensions.size()),	//deUint32							enabledExtensionCount;
 				&charDevExtensions[0],							//const char* const*				ppEnabledExtensionNames;
 				&context.getDeviceFeatures()					//const VkPhysicalDeviceFeatures*	pEnabledFeatures;
 			};

 			m_logicalDevice	= createDevice(instance, physicalDevice, &deviceInfo);
 			m_deviceDriver	= MovePtr<DeviceDriver>(new DeviceDriver(instance, *m_logicalDevice));
 			m_allocator		= MovePtr<Allocator>(new SimpleAllocator(*m_deviceDriver, *m_logicalDevice, getPhysicalDeviceMemoryProperties(instance, physicalDevice)));

 			for (std::map<deUint32, QueueData>::iterator it = m_queues.begin(); it != m_queues.end(); ++it)
 			for (int queueNdx = 0; queueNdx < static_cast<int>(it->second.queue.size()); ++queueNdx)
 				m_deviceDriver->getDeviceQueue(*m_logicalDevice, it->first, queueNdx, &it->second.queue[queueNdx]);
 		}
 	}

 	void addQueueIndex (const deUint32 queueFamilyIndex, const deUint32 count, const VkQueueFlags flags)
 	{
 		QueueData dataToPush;
 		dataToPush.flags = flags;
 		dataToPush.queue.resize(count);
 		m_queues[queueFamilyIndex] = dataToPush;
 	}

 	std::vector<QueuePair> getQueuesPairs (const VkQueueFlags flagsWrite, const VkQueueFlags flagsRead)
 	{
 		std::map<deUint32, QueueData>	queuesWrite;
 		std::map<deUint32, QueueData>	queuesRead;
 		std::vector<QueuePair>			queuesPairs;

 		for (std::map<deUint32, QueueData>::iterator it = m_queues.begin(); it != m_queues.end(); ++it)
 		{
 			const bool writeQueue	= checkQueueFlags(it->second.flags, flagsWrite);
 			const bool readQueue	= checkQueueFlags(it->second.flags, flagsRead);

 			if (!(writeQueue || readQueue))
 				continue;

 			if (writeQueue && readQueue)
 			{
 				queuesWrite[it->first]	= it->second;
 				queuesRead[it->first]	= it->second;
 			}
 			else if (writeQueue)
 				queuesWrite[it->first]	= it->second;
 			else if (readQueue)
 				queuesRead[it->first]	= it->second;
 		}

 		for (std::map<deUint32, QueueData>::iterator write = queuesWrite.begin(); write != queuesWrite.end(); ++write)
 		for (std::map<deUint32, QueueData>::iterator read  = queuesRead.begin();  read  != queuesRead.end();  ++read)
 		{
 			const int writeSize	= static_cast<int>(write->second.queue.size());
 			const int readSize	= static_cast<int>(read->second.queue.size());

 			for (int writeNdx = 0; writeNdx < writeSize; ++writeNdx)
 			for (int readNdx  = 0; readNdx  < readSize;  ++readNdx)
 			{
 				if (write->second.queue[writeNdx] != read->second.queue[readNdx])
 				{
 					queuesPairs.push_back(QueuePair(write->first, read->first, write->second.queue[writeNdx], read->second.queue[readNdx]));
 					writeNdx = readNdx = std::max(writeSize, readSize);	//exit from the loops
 				}
 			}
 		}

 		if (queuesPairs.empty())
 			TCU_THROW(NotSupportedError, "Queue not found");

 		return queuesPairs;
 	}

 	VkDevice getDevice (void) const
 	{
 		return *m_logicalDevice;
 	}

 	const DeviceInterface& getDeviceInterface (void) const
 	{
 		return *m_deviceDriver;
 	}

 	Allocator& getAllocator (void)
 	{
 		return *m_allocator;
 	}

 private:
 	Move<VkDevice>					m_logicalDevice;
 	MovePtr<DeviceDriver>			m_deviceDriver;
 	MovePtr<Allocator>				m_allocator;
 	std::map<deUint32, QueueData>	m_queues;
 };

 void createBarrierMultiQueue (const DeviceInterface&	vk,
 							  const VkCommandBuffer&	cmdBuffer,
 							  const SyncInfo&			writeSync,
 							  const SyncInfo&			readSync,
 							  const Resource&			resource,
 							  const deUint32			writeFamily,
 							  const deUint32			readFamily,
 							  const VkSharingMode		sharingMode,
 							  const bool				secondQueue = false)
 {
 	if (resource.getType() == RESOURCE_TYPE_IMAGE)
 	{
 		VkImageMemoryBarrier barrier = makeImageMemoryBarrier(writeSync.accessMask, readSync.accessMask,
 			writeSync.imageLayout, readSync.imageLayout, resource.getImage().handle, resource.getImage().subresourceRange);

 		if (writeFamily != readFamily && VK_SHARING_MODE_EXCLUSIVE == sharingMode)
 		{
 			barrier.srcQueueFamilyIndex = writeFamily;
 			barrier.dstQueueFamilyIndex = readFamily;
 			if (secondQueue)
 			{
 				barrier.oldLayout		= barrier.newLayout;
 				barrier.srcAccessMask	= barrier.dstAccessMask;
 			}
 			vk.cmdPipelineBarrier(cmdBuffer, writeSync.stageMask, readSync.stageMask, (VkDependencyFlags)0, 0u, (const VkMemoryBarrier*)DE_NULL, 0u, (const VkBufferMemoryBarrier*)DE_NULL, 1u, &barrier);
 		}
 		else if (!secondQueue)
 			vk.cmdPipelineBarrier(cmdBuffer, writeSync.stageMask, readSync.stageMask, (VkDependencyFlags)0, 0u, (const VkMemoryBarrier*)DE_NULL, 0u, (const VkBufferMemoryBarrier*)DE_NULL, 1u, &barrier);
 	}
 	else if ((resource.getType() == RESOURCE_TYPE_BUFFER || isIndirectBuffer(resource.getType()))	&&
 			 writeFamily != readFamily																&&
 			 VK_SHARING_MODE_EXCLUSIVE == sharingMode)
 	{
 		const VkBufferMemoryBarrier barrier =
 		{
 			VK_STRUCTURE_TYPE_BUFFER_MEMORY_BARRIER,	// VkStructureType	sType;
 			DE_NULL,									// const void*		pNext;
 			writeSync.accessMask ,						// VkAccessFlags	srcAccessMask;
 			readSync.accessMask,						// VkAccessFlags	dstAccessMask;
 			writeFamily,								// deUint32			srcQueueFamilyIndex;
 			readFamily,									// deUint32			destQueueFamilyIndex;
 			resource.getBuffer().handle,				// VkBuffer			buffer;
 			resource.getBuffer().offset,				// VkDeviceSize		offset;
 			resource.getBuffer().size,					// VkDeviceSize		size;
 		};
 		vk.cmdPipelineBarrier(cmdBuffer, writeSync.stageMask, readSync.stageMask, (VkDependencyFlags)0, 0u, (const VkMemoryBarrier*)DE_NULL, 1u, (const VkBufferMemoryBarrier*)&barrier, 0u, (const VkImageMemoryBarrier *)DE_NULL);
 	}
 }

 class BaseTestInstance : public TestInstance
 {
 public:
 	BaseTestInstance (Context& context, const ResourceDescription& resourceDesc, const OperationSupport& writeOp, const OperationSupport& readOp, PipelineCacheData& pipelineCacheData)
 		: TestInstance		(context)
 		, m_queues			(new MultiQueues(context))
 		, m_opContext		(new OperationContext(context, pipelineCacheData, m_queues->getDeviceInterface(), m_queues->getDevice(), m_queues->getAllocator()))
 		, m_resourceDesc	(resourceDesc)
 		, m_writeOp			(writeOp)
 		, m_readOp			(readOp)
 	{
 	}

 protected:
 	const UniquePtr<MultiQueues>		m_queues;
 	const UniquePtr<OperationContext>	m_opContext;
 	const ResourceDescription			m_resourceDesc;
 	const OperationSupport&				m_writeOp;
 	const OperationSupport&				m_readOp;
 };

 class SemaphoreTestInstance : public BaseTestInstance
 {
 public:
 	SemaphoreTestInstance (Context& context, const ResourceDescription& resourceDesc, const OperationSupport& writeOp, const OperationSupport& readOp, PipelineCacheData& pipelineCacheData, const VkSharingMode sharingMode)
 		: BaseTestInstance	(context, resourceDesc, writeOp, readOp, pipelineCacheData)
 		, m_sharingMode		(sharingMode)
 	{
 	}

 	tcu::TestStatus	iterate (void)
 	{
 		const DeviceInterface&			vk			= m_opContext->getDeviceInterface();
 		const VkDevice					device		= m_opContext->getDevice();
 		const std::vector<QueuePair>	queuePairs	= m_queues->getQueuesPairs(m_writeOp.getQueueFlags(*m_opContext), m_readOp.getQueueFlags(*m_opContext));

 		for (deUint32 pairNdx = 0; pairNdx < static_cast<deUint32>(queuePairs.size()); ++pairNdx)
 		{

 			const UniquePtr<Resource>		resource		(new Resource(*m_opContext, m_resourceDesc, m_writeOp.getResourceUsageFlags() | m_readOp.getResourceUsageFlags()));
 			const UniquePtr<Operation>		writeOp			(m_writeOp.build(*m_opContext, *resource));
 			const UniquePtr<Operation>		readOp			(m_readOp.build (*m_opContext, *resource));

 			const Move<VkCommandPool>		cmdPool[]		=
 			{
 				makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexWrite),
 				makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexRead)
 			};
 			const Move<VkCommandBuffer>		ptrCmdBuffer[]	=
 			{
 				makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_WRITE]),
 				makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_READ])
 			};
 			const VkCommandBuffer			cmdBuffers[]	=
 			{
 				*ptrCmdBuffer[QUEUETYPE_WRITE],
 				*ptrCmdBuffer[QUEUETYPE_READ]
 			};
 			const VkSemaphoreCreateInfo		semaphoreInfo	=
 			{
 				VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO,	//VkStructureType			sType;
 				DE_NULL,									//const void*				pNext;
 				0u											//VkSemaphoreCreateFlags	flags;
 			};
 			const Unique<VkSemaphore>		semaphore		(createSemaphore(vk, device, &semaphoreInfo, DE_NULL));
 			const VkPipelineStageFlags		stageBits[]		= { VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT };
 			const VkSubmitInfo				submitInfo[]	=
 			{
 				{
 					VK_STRUCTURE_TYPE_SUBMIT_INFO,		// VkStructureType			sType;
 					DE_NULL,							// const void*				pNext;
 					0u,									// deUint32					waitSemaphoreCount;
 					DE_NULL,							// const VkSemaphore*		pWaitSemaphores;
 					(const VkPipelineStageFlags*)DE_NULL,
 					1u,									// deUint32					commandBufferCount;
 					&cmdBuffers[QUEUETYPE_WRITE],		// const VkCommandBuffer*	pCommandBuffers;
 					1u,									// deUint32					signalSemaphoreCount;
 					&semaphore.get(),					// const VkSemaphore*		pSignalSemaphores;
 				},
 				{
 					VK_STRUCTURE_TYPE_SUBMIT_INFO,		// VkStructureType				sType;
 					DE_NULL,							// const void*					pNext;
 					1u,									// deUint32						waitSemaphoreCount;
 					&semaphore.get(),					// const VkSemaphore*			pWaitSemaphores;
 					stageBits,							// const VkPipelineStageFlags*	pWaitDstStageMask;
 					1u,									// deUint32						commandBufferCount;
 					&cmdBuffers[QUEUETYPE_READ],		// const VkCommandBuffer*		pCommandBuffers;
 					0u,									// deUint32						signalSemaphoreCount;
 					DE_NULL,							// const VkSemaphore*			pSignalSemaphores;
 				}
 			};
 			const SyncInfo					writeSync		= writeOp->getSyncInfo();
 			const SyncInfo					readSync		= readOp->getSyncInfo();

 			beginCommandBuffer		(vk, cmdBuffers[QUEUETYPE_WRITE]);
 			writeOp->recordCommands	(cmdBuffers[QUEUETYPE_WRITE]);
 			createBarrierMultiQueue	(vk, cmdBuffers[QUEUETYPE_WRITE], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode);
 			endCommandBuffer		(vk, cmdBuffers[QUEUETYPE_WRITE]);

 			beginCommandBuffer		(vk, cmdBuffers[QUEUETYPE_READ]);
 			createBarrierMultiQueue	(vk, cmdBuffers[QUEUETYPE_READ], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode, true);
 			readOp->recordCommands	(cmdBuffers[QUEUETYPE_READ]);
 			endCommandBuffer		(vk, cmdBuffers[QUEUETYPE_READ]);

 			VK_CHECK(vk.queueSubmit(queuePairs[pairNdx].queueWrite, 1u, &submitInfo[QUEUETYPE_WRITE], DE_NULL));
 			VK_CHECK(vk.queueSubmit(queuePairs[pairNdx].queueRead, 1u, &submitInfo[QUEUETYPE_READ], DE_NULL));
 			VK_CHECK(vk.queueWaitIdle(queuePairs[pairNdx].queueWrite));
 			VK_CHECK(vk.queueWaitIdle(queuePairs[pairNdx].queueRead));

 			{
 				const Data	expected	= writeOp->getData();
 				const Data	actual		= readOp->getData();

 				if (0 != deMemCmp(expected.data, actual.data, expected.size))
 					return tcu::TestStatus::fail("Memory contents don't match");
 			}
 		}
 		return tcu::TestStatus::pass("OK");
 	}

 private:
 	const VkSharingMode	m_sharingMode;
 };

 class FenceTestInstance : public BaseTestInstance
 {
 public:
 	FenceTestInstance (Context& context, const ResourceDescription& resourceDesc, const OperationSupport& writeOp, const OperationSupport& readOp, PipelineCacheData& pipelineCacheData, const VkSharingMode sharingMode)
 		: BaseTestInstance	(context, resourceDesc, writeOp, readOp, pipelineCacheData)
 		, m_sharingMode		(sharingMode)
 	{
 	}

 	tcu::TestStatus	iterate (void)
 	{
 		const DeviceInterface&			vk			= m_opContext->getDeviceInterface();
 		const VkDevice					device		= m_opContext->getDevice();
 		const std::vector<QueuePair>	queuePairs	= m_queues->getQueuesPairs(m_writeOp.getQueueFlags(*m_opContext), m_readOp.getQueueFlags(*m_opContext));

 		for (deUint32 pairNdx = 0; pairNdx < static_cast<deUint32>(queuePairs.size()); ++pairNdx)
 		{
 			const UniquePtr<Resource>		resource		(new Resource(*m_opContext, m_resourceDesc, m_writeOp.getResourceUsageFlags() | m_readOp.getResourceUsageFlags()));
 			const UniquePtr<Operation>		writeOp			(m_writeOp.build(*m_opContext, *resource));
 			const UniquePtr<Operation>		readOp			(m_readOp.build(*m_opContext, *resource));
 			const Move<VkCommandPool>		cmdPool[]		=
 			{
 				makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexWrite),
 				makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexRead)
 			};
 			const Move<VkCommandBuffer>		ptrCmdBuffer[]	=
 			{
 				makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_WRITE]),
 				makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_READ])
 			};
 			const VkCommandBuffer			cmdBuffers[]	=
 			{
 				*ptrCmdBuffer[QUEUETYPE_WRITE],
 				*ptrCmdBuffer[QUEUETYPE_READ]
 			};
 			const SyncInfo					writeSync		= writeOp->getSyncInfo();
 			const SyncInfo					readSync		= readOp->getSyncInfo();

 			beginCommandBuffer		(vk, cmdBuffers[QUEUETYPE_WRITE]);
 			writeOp->recordCommands	(cmdBuffers[QUEUETYPE_WRITE]);
 			createBarrierMultiQueue	(vk, cmdBuffers[QUEUETYPE_WRITE], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode);
 			endCommandBuffer		(vk, cmdBuffers[QUEUETYPE_WRITE]);

 			submitCommandsAndWait	(vk, device, queuePairs[pairNdx].queueWrite, cmdBuffers[QUEUETYPE_WRITE]);

 			beginCommandBuffer		(vk, cmdBuffers[QUEUETYPE_READ]);
 			createBarrierMultiQueue	(vk, cmdBuffers[QUEUETYPE_READ], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode, true);
 			readOp->recordCommands	(cmdBuffers[QUEUETYPE_READ]);
 			endCommandBuffer		(vk, cmdBuffers[QUEUETYPE_READ]);

 			submitCommandsAndWait	(vk, device, queuePairs[pairNdx].queueRead, cmdBuffers[QUEUETYPE_READ]);

 			{
 				const Data	expected = writeOp->getData();
 				const Data	actual	 = readOp->getData();

 				if (0 != deMemCmp(expected.data, actual.data, expected.size))
 					return tcu::TestStatus::fail("Memory contents don't match");
 			}
 		}
 		return tcu::TestStatus::pass("OK");
 	}

 private:
 	const VkSharingMode	m_sharingMode;
 };

 class BaseTestCase : public TestCase
 {
 public:
 	BaseTestCase (tcu::TestContext&			testCtx,
 				  const std::string&		name,
 				  const std::string&		description,
 				  const SyncPrimitive		syncPrimitive,
 				  const ResourceDescription	resourceDesc,
 				  const OperationName		writeOp,
 				  const OperationName		readOp,
 				  const VkSharingMode		sharingMode,
 				  PipelineCacheData&		pipelineCacheData)
 		: TestCase				(testCtx, name, description)
 		, m_resourceDesc		(resourceDesc)
 		, m_writeOp				(makeOperationSupport(writeOp, resourceDesc))
 		, m_readOp				(makeOperationSupport(readOp, resourceDesc))
 		, m_syncPrimitive		(syncPrimitive)
 		, m_sharingMode			(sharingMode)
 		, m_pipelineCacheData	(pipelineCacheData)
 	{
 	}

 	void initPrograms (SourceCollections& programCollection) const
 	{
 		m_writeOp->initPrograms(programCollection);
 		m_readOp->initPrograms(programCollection);
 	}

 	TestInstance* createInstance (Context& context) const
 	{
 		switch (m_syncPrimitive)
 		{
 			case SYNC_PRIMITIVE_FENCE:
 				return new FenceTestInstance(context, m_resourceDesc, *m_writeOp, *m_readOp, m_pipelineCacheData, m_sharingMode);
 			case SYNC_PRIMITIVE_SEMAPHORE:
 				return new SemaphoreTestInstance(context, m_resourceDesc, *m_writeOp, *m_readOp, m_pipelineCacheData, m_sharingMode);
 			default:
 				DE_ASSERT(0);
 				return DE_NULL;
 		}
 	}

 private:
 	const ResourceDescription				m_resourceDesc;
 	const UniquePtr<OperationSupport>		m_writeOp;
 	const UniquePtr<OperationSupport>		m_readOp;
 	const SyncPrimitive						m_syncPrimitive;
 	const VkSharingMode						m_sharingMode;
 	PipelineCacheData&						m_pipelineCacheData;
 };

 void createTests (tcu::TestCaseGroup* group, PipelineCacheData* pipelineCacheData)
 {
 	tcu::TestContext& testCtx = group->getTestContext();

 	static const struct
 	{
 		const char*		name;
 		SyncPrimitive	syncPrimitive;
 		int				numOptions;
 	} groups[] =
 	{
 		{ "fence",		SYNC_PRIMITIVE_FENCE,		1 },
 		{ "semaphore",	SYNC_PRIMITIVE_SEMAPHORE,	1 }
 	};

 	for (int groupNdx = 0; groupNdx < DE_LENGTH_OF_ARRAY(groups); ++groupNdx)
 	{
 		MovePtr<tcu::TestCaseGroup> synchGroup (new tcu::TestCaseGroup(testCtx, groups[groupNdx].name, ""));

 		for (int writeOpNdx = 0; writeOpNdx < DE_LENGTH_OF_ARRAY(s_writeOps); ++writeOpNdx)
 		for (int readOpNdx  = 0; readOpNdx  < DE_LENGTH_OF_ARRAY(s_readOps);  ++readOpNdx)
 		{
 			const OperationName	writeOp		= s_writeOps[writeOpNdx];
 			const OperationName	readOp		= s_readOps[readOpNdx];
 			const std::string	opGroupName = getOperationName(writeOp) + "_" + getOperationName(readOp);
 			bool				empty		= true;

 			MovePtr<tcu::TestCaseGroup> opGroup		(new tcu::TestCaseGroup(testCtx, opGroupName.c_str(), ""));

 			for (int optionNdx = 0; optionNdx <= groups[groupNdx].numOptions; ++optionNdx)
 			for (int resourceNdx = 0; resourceNdx < DE_LENGTH_OF_ARRAY(s_resources); ++resourceNdx)
 			{
 				const ResourceDescription&	resource	= s_resources[resourceNdx];
 				std::string					name		= getResourceName(resource);
 				VkSharingMode				sharingMode = VK_SHARING_MODE_EXCLUSIVE;

 				// queue family sharing mode used for resource
 				if (optionNdx)
 				{
 					name += "_concurrent";
 					sharingMode = VK_SHARING_MODE_CONCURRENT;
 				}
 				else
 					name += "_exclusive";

 				if (isResourceSupported(writeOp, resource) && isResourceSupported(readOp, resource))
 				{
 					opGroup->addChild(new BaseTestCase(testCtx, name, "", groups[groupNdx].syncPrimitive, resource, writeOp, readOp, sharingMode, *pipelineCacheData));
 					empty = false;
 				}
 			}
 			if (!empty)
 				synchGroup->addChild(opGroup.release());
 		}
 		group->addChild(synchGroup.release());
 	}
 }

 } // anonymous

 tcu::TestCaseGroup* createSynchronizedOperationMultiQueueTests (tcu::TestContext& testCtx, PipelineCacheData& pipelineCacheData)
 {
 	return createTestGroup(testCtx, "multi_queue", "Synchronization of a memory-modifying operation", createTests, &pipelineCacheData);
 }

 } // synchronization
 } // vkt
	/*------------------------------------------------------------------------
	* Vulkan Conformance Tests
	* ------------------------
	*
	* Copyright (c) 2016 The Khronos Group Inc.
	*
	* 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 Synchronization primitive tests with multi queue
	//--------------------------------------------------------------------*/

	#include "vktSynchronizationOperationMultiQueueTests.hpp"
	#include "vkDefs.hpp"
	#include "vktTestCase.hpp"
	#include "vktTestCaseUtil.hpp"
	#include "vkRef.hpp"
	#include "vkRefUtil.hpp"
	#include "vkMemUtil.hpp"
	#include "vkQueryUtil.hpp"
	#include "vkTypeUtil.hpp"
	#include "vkPlatform.hpp"
	#include "deUniquePtr.hpp"
	#include "tcuTestLog.hpp"
	#include "vktSynchronizationUtil.hpp"
	#include "vktSynchronizationOperation.hpp"
	#include "vktSynchronizationOperationTestData.hpp"
	#include "vktTestGroupUtil.hpp"

	namespace vkt
	{
	namespace synchronization
	{
	namespace
	{
	using namespace vk;
	using de::MovePtr;
	using de::UniquePtr;

	enum QueueType
	{
	QUEUETYPE_WRITE,
	QUEUETYPE_READ
	};

	struct QueuePair
	{
	QueuePair (const deUint32 familyWrite, const deUint32 familyRead, const VkQueue write, const VkQueue read)
	: familyIndexWrite (familyWrite)
	, familyIndexRead (familyRead)
	, queueWrite (write)
	, queueRead (read)
	{}

	deUint32 familyIndexWrite;
	deUint32 familyIndexRead;
	VkQueue queueWrite;
	VkQueue queueRead;
	};

	bool checkQueueFlags (VkQueueFlags availableFlags, const VkQueueFlags neededFlags)
	{
	if ((availableFlags & (VK_QUEUE_GRAPHICS_BIT \| VK_QUEUE_COMPUTE_BIT)) != 0)
	availableFlags \|= VK_QUEUE_TRANSFER_BIT;

	return (availableFlags & neededFlags) != 0;
	}

	class MultiQueues
	{
	struct QueueData
	{
	VkQueueFlags flags;
	std::vector<VkQueue> queue;
	};

	public:
	MultiQueues (const Context& context)
	{
	const InstanceInterface& instance = context.getInstanceInterface();
	const VkPhysicalDevice physicalDevice = context.getPhysicalDevice();
	const std::vector<VkQueueFamilyProperties> queueFamilyProperties = getPhysicalDeviceQueueFamilyProperties(instance, physicalDevice);

	for (deUint32 queuePropertiesNdx = 0; queuePropertiesNdx < queueFamilyProperties.size(); ++queuePropertiesNdx)
	{
	addQueueIndex(queuePropertiesNdx,
	std::min(2u, queueFamilyProperties[queuePropertiesNdx].queueCount),
	queueFamilyProperties[queuePropertiesNdx].queueFlags);
	}

	std::vector<VkDeviceQueueCreateInfo> queueInfos;
	const float queuePriorities[2] = { 1.0f, 1.0f }; //get max 2 queues from one family

	for (std::map<deUint32, QueueData>::iterator it = m_queues.begin(); it!= m_queues.end(); ++it)
	{
	const VkDeviceQueueCreateInfo queueInfo =
	{
	VK_STRUCTURE_TYPE_DEVICE_QUEUE_CREATE_INFO, //VkStructureType sType;
	DE_NULL, //const void* pNext;
	(VkDeviceQueueCreateFlags)0u, //VkDeviceQueueCreateFlags flags;
	it->first, //deUint32 queueFamilyIndex;
	static_cast<deUint32>(it->second.queue.size()), //deUint32 queueCount;
	&queuePriorities[0] //const float* pQueuePriorities;
	};
	queueInfos.push_back(queueInfo);
	}

	{
	const std::vector<std::string>& deviceExtensions = context.getDeviceExtensions();
	std::vector<const char*> charDevExtensions;

	for (size_t ndx = 0; ndx < deviceExtensions.size(); ++ndx)
	charDevExtensions.push_back(deviceExtensions[ndx].c_str());

	const VkDeviceCreateInfo deviceInfo =
	{
	VK_STRUCTURE_TYPE_DEVICE_CREATE_INFO, //VkStructureType sType;
	DE_NULL, //const void* pNext;
	0u, //VkDeviceCreateFlags flags;
	static_cast<deUint32>(queueInfos.size()), //deUint32 queueCreateInfoCount;
	&queueInfos[0], //const VkDeviceQueueCreateInfo* pQueueCreateInfos;
	0u, //deUint32 enabledLayerCount;
	DE_NULL, //const char* const* ppEnabledLayerNames;
	static_cast<deUint32>(deviceExtensions.size()), //deUint32 enabledExtensionCount;
	&charDevExtensions[0], //const char* const* ppEnabledExtensionNames;
	&context.getDeviceFeatures() //const VkPhysicalDeviceFeatures* pEnabledFeatures;
	};

	m_logicalDevice = createDevice(instance, physicalDevice, &deviceInfo);
	m_deviceDriver = MovePtr<DeviceDriver>(new DeviceDriver(instance, *m_logicalDevice));
	m_allocator = MovePtr<Allocator>(new SimpleAllocator(m_deviceDriver, m_logicalDevice, getPhysicalDeviceMemoryProperties(instance, physicalDevice)));

	for (std::map<deUint32, QueueData>::iterator it = m_queues.begin(); it != m_queues.end(); ++it)
	for (int queueNdx = 0; queueNdx < static_cast<int>(it->second.queue.size()); ++queueNdx)
	m_deviceDriver->getDeviceQueue(*m_logicalDevice, it->first, queueNdx, &it->second.queue[queueNdx]);
	}
	}

	void addQueueIndex (const deUint32 queueFamilyIndex, const deUint32 count, const VkQueueFlags flags)
	{
	QueueData dataToPush;
	dataToPush.flags = flags;
	dataToPush.queue.resize(count);
	m_queues[queueFamilyIndex] = dataToPush;
	}

	std::vector<QueuePair> getQueuesPairs (const VkQueueFlags flagsWrite, const VkQueueFlags flagsRead)
	{
	std::map<deUint32, QueueData> queuesWrite;
	std::map<deUint32, QueueData> queuesRead;
	std::vector<QueuePair> queuesPairs;

	for (std::map<deUint32, QueueData>::iterator it = m_queues.begin(); it != m_queues.end(); ++it)
	{
	const bool writeQueue = checkQueueFlags(it->second.flags, flagsWrite);
	const bool readQueue = checkQueueFlags(it->second.flags, flagsRead);

	if (!(writeQueue \|\| readQueue))
	continue;

	if (writeQueue && readQueue)
	{
	queuesWrite[it->first] = it->second;
	queuesRead[it->first] = it->second;
	}
	else if (writeQueue)
	queuesWrite[it->first] = it->second;
	else if (readQueue)
	queuesRead[it->first] = it->second;
	}

	for (std::map<deUint32, QueueData>::iterator write = queuesWrite.begin(); write != queuesWrite.end(); ++write)
	for (std::map<deUint32, QueueData>::iterator read = queuesRead.begin(); read != queuesRead.end(); ++read)
	{
	const int writeSize = static_cast<int>(write->second.queue.size());
	const int readSize = static_cast<int>(read->second.queue.size());

	for (int writeNdx = 0; writeNdx < writeSize; ++writeNdx)
	for (int readNdx = 0; readNdx < readSize; ++readNdx)
	{
	if (write->second.queue[writeNdx] != read->second.queue[readNdx])
	{
	queuesPairs.push_back(QueuePair(write->first, read->first, write->second.queue[writeNdx], read->second.queue[readNdx]));
	writeNdx = readNdx = std::max(writeSize, readSize); //exit from the loops
	}
	}
	}

	if (queuesPairs.empty())
	TCU_THROW(NotSupportedError, "Queue not found");

	return queuesPairs;
	}

	VkDevice getDevice (void) const
	{
	return *m_logicalDevice;
	}

	const DeviceInterface& getDeviceInterface (void) const
	{
	return *m_deviceDriver;
	}

	Allocator& getAllocator (void)
	{
	return *m_allocator;
	}

	private:
	Move<VkDevice> m_logicalDevice;
	MovePtr<DeviceDriver> m_deviceDriver;
	MovePtr<Allocator> m_allocator;
	std::map<deUint32, QueueData> m_queues;
	};

	void createBarrierMultiQueue (const DeviceInterface& vk,
	const VkCommandBuffer& cmdBuffer,
	const SyncInfo& writeSync,
	const SyncInfo& readSync,
	const Resource& resource,
	const deUint32 writeFamily,
	const deUint32 readFamily,
	const VkSharingMode sharingMode,
	const bool secondQueue = false)
	{
	if (resource.getType() == RESOURCE_TYPE_IMAGE)
	{
	VkImageMemoryBarrier barrier = makeImageMemoryBarrier(writeSync.accessMask, readSync.accessMask,
	writeSync.imageLayout, readSync.imageLayout, resource.getImage().handle, resource.getImage().subresourceRange);

	if (writeFamily != readFamily && VK_SHARING_MODE_EXCLUSIVE == sharingMode)
	{
	barrier.srcQueueFamilyIndex = writeFamily;
	barrier.dstQueueFamilyIndex = readFamily;
	if (secondQueue)
	{
	barrier.oldLayout = barrier.newLayout;
	barrier.srcAccessMask = barrier.dstAccessMask;
	}
	vk.cmdPipelineBarrier(cmdBuffer, writeSync.stageMask, readSync.stageMask, (VkDependencyFlags)0, 0u, (const VkMemoryBarrier)DE_NULL, 0u, (const VkBufferMemoryBarrier)DE_NULL, 1u, &barrier);
	}
	else if (!secondQueue)
	vk.cmdPipelineBarrier(cmdBuffer, writeSync.stageMask, readSync.stageMask, (VkDependencyFlags)0, 0u, (const VkMemoryBarrier)DE_NULL, 0u, (const VkBufferMemoryBarrier)DE_NULL, 1u, &barrier);
	}
	else if ((resource.getType() == RESOURCE_TYPE_BUFFER \|\| isIndirectBuffer(resource.getType())) &&
	writeFamily != readFamily &&
	VK_SHARING_MODE_EXCLUSIVE == sharingMode)
	{
	const VkBufferMemoryBarrier barrier =
	{
	VK_STRUCTURE_TYPE_BUFFER_MEMORY_BARRIER, // VkStructureType sType;
	DE_NULL, // const void* pNext;
	writeSync.accessMask , // VkAccessFlags srcAccessMask;
	readSync.accessMask, // VkAccessFlags dstAccessMask;
	writeFamily, // deUint32 srcQueueFamilyIndex;
	readFamily, // deUint32 destQueueFamilyIndex;
	resource.getBuffer().handle, // VkBuffer buffer;
	resource.getBuffer().offset, // VkDeviceSize offset;
	resource.getBuffer().size, // VkDeviceSize size;
	};
	vk.cmdPipelineBarrier(cmdBuffer, writeSync.stageMask, readSync.stageMask, (VkDependencyFlags)0, 0u, (const VkMemoryBarrier)DE_NULL, 1u, (const VkBufferMemoryBarrier)&barrier, 0u, (const VkImageMemoryBarrier *)DE_NULL);
	}
	}

	class BaseTestInstance : public TestInstance
	{
	public:
	BaseTestInstance (Context& context, const ResourceDescription& resourceDesc, const OperationSupport& writeOp, const OperationSupport& readOp, PipelineCacheData& pipelineCacheData)
	: TestInstance (context)
	, m_queues (new MultiQueues(context))
	, m_opContext (new OperationContext(context, pipelineCacheData, m_queues->getDeviceInterface(), m_queues->getDevice(), m_queues->getAllocator()))
	, m_resourceDesc (resourceDesc)
	, m_writeOp (writeOp)
	, m_readOp (readOp)
	{
	}

	protected:
	const UniquePtr<MultiQueues> m_queues;
	const UniquePtr<OperationContext> m_opContext;
	const ResourceDescription m_resourceDesc;
	const OperationSupport& m_writeOp;
	const OperationSupport& m_readOp;
	};

	class SemaphoreTestInstance : public BaseTestInstance
	{
	public:
	SemaphoreTestInstance (Context& context, const ResourceDescription& resourceDesc, const OperationSupport& writeOp, const OperationSupport& readOp, PipelineCacheData& pipelineCacheData, const VkSharingMode sharingMode)
	: BaseTestInstance (context, resourceDesc, writeOp, readOp, pipelineCacheData)
	, m_sharingMode (sharingMode)
	{
	}

	tcu::TestStatus iterate (void)
	{
	const DeviceInterface& vk = m_opContext->getDeviceInterface();
	const VkDevice device = m_opContext->getDevice();
	const std::vector<QueuePair> queuePairs = m_queues->getQueuesPairs(m_writeOp.getQueueFlags(m_opContext), m_readOp.getQueueFlags(m_opContext));

	for (deUint32 pairNdx = 0; pairNdx < static_cast<deUint32>(queuePairs.size()); ++pairNdx)
	{

	const UniquePtr<Resource> resource (new Resource(*m_opContext, m_resourceDesc, m_writeOp.getResourceUsageFlags() \| m_readOp.getResourceUsageFlags()));
	const UniquePtr<Operation> writeOp (m_writeOp.build(m_opContext, resource));
	const UniquePtr<Operation> readOp (m_readOp.build (m_opContext, resource));

	const Move<VkCommandPool> cmdPool[] =
	{
	makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexWrite),
	makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexRead)
	};
	const Move<VkCommandBuffer> ptrCmdBuffer[] =
	{
	makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_WRITE]),
	makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_READ])
	};
	const VkCommandBuffer cmdBuffers[] =
	{
	*ptrCmdBuffer[QUEUETYPE_WRITE],
	*ptrCmdBuffer[QUEUETYPE_READ]
	};
	const VkSemaphoreCreateInfo semaphoreInfo =
	{
	VK_STRUCTURE_TYPE_SEMAPHORE_CREATE_INFO, //VkStructureType sType;
	DE_NULL, //const void* pNext;
	0u //VkSemaphoreCreateFlags flags;
	};
	const Unique<VkSemaphore> semaphore (createSemaphore(vk, device, &semaphoreInfo, DE_NULL));
	const VkPipelineStageFlags stageBits[] = { VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT };
	const VkSubmitInfo submitInfo[] =
	{
	{
	VK_STRUCTURE_TYPE_SUBMIT_INFO, // VkStructureType sType;
	DE_NULL, // const void* pNext;
	0u, // deUint32 waitSemaphoreCount;
	DE_NULL, // const VkSemaphore* pWaitSemaphores;
	(const VkPipelineStageFlags*)DE_NULL,
	1u, // deUint32 commandBufferCount;
	&cmdBuffers[QUEUETYPE_WRITE], // const VkCommandBuffer* pCommandBuffers;
	1u, // deUint32 signalSemaphoreCount;
	&semaphore.get(), // const VkSemaphore* pSignalSemaphores;
	},
	{
	VK_STRUCTURE_TYPE_SUBMIT_INFO, // VkStructureType sType;
	DE_NULL, // const void* pNext;
	1u, // deUint32 waitSemaphoreCount;
	&semaphore.get(), // const VkSemaphore* pWaitSemaphores;
	stageBits, // const VkPipelineStageFlags* pWaitDstStageMask;
	1u, // deUint32 commandBufferCount;
	&cmdBuffers[QUEUETYPE_READ], // const VkCommandBuffer* pCommandBuffers;
	0u, // deUint32 signalSemaphoreCount;
	DE_NULL, // const VkSemaphore* pSignalSemaphores;
	}
	};
	const SyncInfo writeSync = writeOp->getSyncInfo();
	const SyncInfo readSync = readOp->getSyncInfo();

	beginCommandBuffer (vk, cmdBuffers[QUEUETYPE_WRITE]);
	writeOp->recordCommands (cmdBuffers[QUEUETYPE_WRITE]);
	createBarrierMultiQueue (vk, cmdBuffers[QUEUETYPE_WRITE], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode);
	endCommandBuffer (vk, cmdBuffers[QUEUETYPE_WRITE]);

	beginCommandBuffer (vk, cmdBuffers[QUEUETYPE_READ]);
	createBarrierMultiQueue (vk, cmdBuffers[QUEUETYPE_READ], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode, true);
	readOp->recordCommands (cmdBuffers[QUEUETYPE_READ]);
	endCommandBuffer (vk, cmdBuffers[QUEUETYPE_READ]);

	VK_CHECK(vk.queueSubmit(queuePairs[pairNdx].queueWrite, 1u, &submitInfo[QUEUETYPE_WRITE], DE_NULL));
	VK_CHECK(vk.queueSubmit(queuePairs[pairNdx].queueRead, 1u, &submitInfo[QUEUETYPE_READ], DE_NULL));
	VK_CHECK(vk.queueWaitIdle(queuePairs[pairNdx].queueWrite));
	VK_CHECK(vk.queueWaitIdle(queuePairs[pairNdx].queueRead));

	{
	const Data expected = writeOp->getData();
	const Data actual = readOp->getData();

	if (0 != deMemCmp(expected.data, actual.data, expected.size))
	return tcu::TestStatus::fail("Memory contents don't match");
	}
	}
	return tcu::TestStatus::pass("OK");
	}

	private:
	const VkSharingMode m_sharingMode;
	};

	class FenceTestInstance : public BaseTestInstance
	{
	public:
	FenceTestInstance (Context& context, const ResourceDescription& resourceDesc, const OperationSupport& writeOp, const OperationSupport& readOp, PipelineCacheData& pipelineCacheData, const VkSharingMode sharingMode)
	: BaseTestInstance (context, resourceDesc, writeOp, readOp, pipelineCacheData)
	, m_sharingMode (sharingMode)
	{
	}

	tcu::TestStatus iterate (void)
	{
	const DeviceInterface& vk = m_opContext->getDeviceInterface();
	const VkDevice device = m_opContext->getDevice();
	const std::vector<QueuePair> queuePairs = m_queues->getQueuesPairs(m_writeOp.getQueueFlags(m_opContext), m_readOp.getQueueFlags(m_opContext));

	for (deUint32 pairNdx = 0; pairNdx < static_cast<deUint32>(queuePairs.size()); ++pairNdx)
	{
	const UniquePtr<Resource> resource (new Resource(*m_opContext, m_resourceDesc, m_writeOp.getResourceUsageFlags() \| m_readOp.getResourceUsageFlags()));
	const UniquePtr<Operation> writeOp (m_writeOp.build(m_opContext, resource));
	const UniquePtr<Operation> readOp (m_readOp.build(m_opContext, resource));
	const Move<VkCommandPool> cmdPool[] =
	{
	makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexWrite),
	makeCommandPool(vk, device, queuePairs[pairNdx].familyIndexRead)
	};
	const Move<VkCommandBuffer> ptrCmdBuffer[] =
	{
	makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_WRITE]),
	makeCommandBuffer(vk, device, *cmdPool[QUEUETYPE_READ])
	};
	const VkCommandBuffer cmdBuffers[] =
	{
	*ptrCmdBuffer[QUEUETYPE_WRITE],
	*ptrCmdBuffer[QUEUETYPE_READ]
	};
	const SyncInfo writeSync = writeOp->getSyncInfo();
	const SyncInfo readSync = readOp->getSyncInfo();

	beginCommandBuffer (vk, cmdBuffers[QUEUETYPE_WRITE]);
	writeOp->recordCommands (cmdBuffers[QUEUETYPE_WRITE]);
	createBarrierMultiQueue (vk, cmdBuffers[QUEUETYPE_WRITE], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode);
	endCommandBuffer (vk, cmdBuffers[QUEUETYPE_WRITE]);

	submitCommandsAndWait (vk, device, queuePairs[pairNdx].queueWrite, cmdBuffers[QUEUETYPE_WRITE]);

	beginCommandBuffer (vk, cmdBuffers[QUEUETYPE_READ]);
	createBarrierMultiQueue (vk, cmdBuffers[QUEUETYPE_READ], writeSync, readSync, *resource, queuePairs[pairNdx].familyIndexWrite, queuePairs[pairNdx].familyIndexRead, m_sharingMode, true);
	readOp->recordCommands (cmdBuffers[QUEUETYPE_READ]);
	endCommandBuffer (vk, cmdBuffers[QUEUETYPE_READ]);

	submitCommandsAndWait (vk, device, queuePairs[pairNdx].queueRead, cmdBuffers[QUEUETYPE_READ]);

	{
	const Data expected = writeOp->getData();
	const Data actual = readOp->getData();

	if (0 != deMemCmp(expected.data, actual.data, expected.size))
	return tcu::TestStatus::fail("Memory contents don't match");
	}
	}
	return tcu::TestStatus::pass("OK");
	}

	private:
	const VkSharingMode m_sharingMode;
	};

	class BaseTestCase : public TestCase
	{
	public:
	BaseTestCase (tcu::TestContext& testCtx,
	const std::string& name,
	const std::string& description,
	const SyncPrimitive syncPrimitive,
	const ResourceDescription resourceDesc,
	const OperationName writeOp,
	const OperationName readOp,
	const VkSharingMode sharingMode,
	PipelineCacheData& pipelineCacheData)
	: TestCase (testCtx, name, description)
	, m_resourceDesc (resourceDesc)
	, m_writeOp (makeOperationSupport(writeOp, resourceDesc))
	, m_readOp (makeOperationSupport(readOp, resourceDesc))
	, m_syncPrimitive (syncPrimitive)
	, m_sharingMode (sharingMode)
	, m_pipelineCacheData (pipelineCacheData)
	{
	}

	void initPrograms (SourceCollections& programCollection) const
	{
	m_writeOp->initPrograms(programCollection);
	m_readOp->initPrograms(programCollection);
	}

	TestInstance* createInstance (Context& context) const
	{
	switch (m_syncPrimitive)
	{
	case SYNC_PRIMITIVE_FENCE:
	return new FenceTestInstance(context, m_resourceDesc, m_writeOp, m_readOp, m_pipelineCacheData, m_sharingMode);
	case SYNC_PRIMITIVE_SEMAPHORE:
	return new SemaphoreTestInstance(context, m_resourceDesc, m_writeOp, m_readOp, m_pipelineCacheData, m_sharingMode);
	default:
	DE_ASSERT(0);
	return DE_NULL;
	}
	}

	private:
	const ResourceDescription m_resourceDesc;
	const UniquePtr<OperationSupport> m_writeOp;
	const UniquePtr<OperationSupport> m_readOp;
	const SyncPrimitive m_syncPrimitive;
	const VkSharingMode m_sharingMode;
	PipelineCacheData& m_pipelineCacheData;
	};

	void createTests (tcu::TestCaseGroup* group, PipelineCacheData* pipelineCacheData)
	{
	tcu::TestContext& testCtx = group->getTestContext();

	static const struct
	{
	const char* name;
	SyncPrimitive syncPrimitive;
	int numOptions;
	} groups[] =
	{
	{ "fence", SYNC_PRIMITIVE_FENCE, 1 },
	{ "semaphore", SYNC_PRIMITIVE_SEMAPHORE, 1 }
	};

	for (int groupNdx = 0; groupNdx < DE_LENGTH_OF_ARRAY(groups); ++groupNdx)
	{
	MovePtr<tcu::TestCaseGroup> synchGroup (new tcu::TestCaseGroup(testCtx, groups[groupNdx].name, ""));

	for (int writeOpNdx = 0; writeOpNdx < DE_LENGTH_OF_ARRAY(s_writeOps); ++writeOpNdx)
	for (int readOpNdx = 0; readOpNdx < DE_LENGTH_OF_ARRAY(s_readOps); ++readOpNdx)
	{
	const OperationName writeOp = s_writeOps[writeOpNdx];
	const OperationName readOp = s_readOps[readOpNdx];
	const std::string opGroupName = getOperationName(writeOp) + "_" + getOperationName(readOp);
	bool empty = true;

	MovePtr<tcu::TestCaseGroup> opGroup (new tcu::TestCaseGroup(testCtx, opGroupName.c_str(), ""));

	for (int optionNdx = 0; optionNdx <= groups[groupNdx].numOptions; ++optionNdx)
	for (int resourceNdx = 0; resourceNdx < DE_LENGTH_OF_ARRAY(s_resources); ++resourceNdx)
	{
	const ResourceDescription& resource = s_resources[resourceNdx];
	std::string name = getResourceName(resource);
	VkSharingMode sharingMode = VK_SHARING_MODE_EXCLUSIVE;

	// queue family sharing mode used for resource
	if (optionNdx)
	{
	name += "_concurrent";
	sharingMode = VK_SHARING_MODE_CONCURRENT;
	}
	else
	name += "_exclusive";

	if (isResourceSupported(writeOp, resource) && isResourceSupported(readOp, resource))
	{
	opGroup->addChild(new BaseTestCase(testCtx, name, "", groups[groupNdx].syncPrimitive, resource, writeOp, readOp, sharingMode, *pipelineCacheData));
	empty = false;
	}
	}
	if (!empty)
	synchGroup->addChild(opGroup.release());
	}
	group->addChild(synchGroup.release());
	}
	}

	} // anonymous

	tcu::TestCaseGroup* createSynchronizedOperationMultiQueueTests (tcu::TestContext& testCtx, PipelineCacheData& pipelineCacheData)
	{
	return createTestGroup(testCtx, "multi_queue", "Synchronization of a memory-modifying operation", createTests, &pipelineCacheData);
	}

	} // synchronization
	} // vkt