/* Copyright (c) 2018 - 2022 Advanced Micro Devices, Inc. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include "hip_internal.hpp" #include "hip_mempool_impl.hpp" #include "hip_platform.hpp" #undef hipGetDeviceProperties #undef hipDeviceProp_t namespace hip { // ================================================================================================ hip::Stream* Device::NullStream(bool wait) { if (null_stream_ == nullptr) { amd::ScopedLock lock(lock_); if (null_stream_ == nullptr) { null_stream_ = new Stream(this, Stream::Priority::Normal, 0, true); } } if (null_stream_ == nullptr) { return nullptr; } if (wait == true) { // Wait for all active streams before executing commands on the default WaitActiveStreams(null_stream_); } return null_stream_; } // ================================================================================================ bool Device::Create() { // Create default memory pool default_mem_pool_ = new MemoryPool(this); if (default_mem_pool_ == nullptr) { return false; } // Create graph memory pool graph_mem_pool_ = new MemoryPool(this, nullptr, true); if (graph_mem_pool_ == nullptr) { return false; } if (!HIP_MEM_POOL_USE_VM) { uint64_t max_size = std::numeric_limits::max(); // Use maximum value to hold memory, because current implementation doesn't support VM // Note: the call for the threshold is always successful auto error = graph_mem_pool_->SetAttribute(hipMemPoolAttrReleaseThreshold, &max_size); } // Current is default pool after device creation current_mem_pool_ = default_mem_pool_; return true; } // ================================================================================================ bool Device::IsMemoryPoolValid(MemoryPool* pool) { amd::ScopedLock lock(lock_); bool result = (mem_pools_.find(pool) != mem_pools_.end()) ? true : false; return result; } // ================================================================================================ void Device::AddMemoryPool(MemoryPool* pool) { amd::ScopedLock lock(lock_); if (auto it = mem_pools_.find(pool); it == mem_pools_.end()) { mem_pools_.insert(pool); } } // ================================================================================================ void Device::RemoveMemoryPool(MemoryPool* pool) { amd::ScopedLock lock(lock_); if (auto it = mem_pools_.find(pool); it != mem_pools_.end()) { mem_pools_.erase(it); } } // ================================================================================================ bool Device::FreeMemory(amd::Memory* memory, Stream* stream, Event* event) { amd::ScopedLock lock(lock_); // Search for memory in the entire list of pools for (auto it : mem_pools_) { if (it->FreeMemory(memory, stream, event)) { return true; } } return false; } // ================================================================================================ void Device::ReleaseFreedMemory() { amd::ScopedLock lock(lock_); // Search for memory in the entire list of pools for (auto it : mem_pools_) { it->ReleaseFreedMemory(); } } // ================================================================================================ void Device::RemoveStreamFromPools(Stream* stream) { amd::ScopedLock lock(lock_); // Update all pools with the destroyed stream for (auto it : mem_pools_) { it->RemoveStream(stream); } } // ================================================================================================ void Device::AddSafeStream(Stream* event_stream, Stream* wait_stream) { amd::ScopedLock lock(lock_); // Update all pools with the safe streams for (auto it : mem_pools_) { it->AddSafeStream(event_stream, wait_stream); } } // ================================================================================================ void Device::Reset() { { amd::ScopedLock lock(lock_); auto it = mem_pools_.begin(); while (it != mem_pools_.end()) { auto current = it++; (*current)->ReleaseAllMemory(); delete *current; } mem_pools_.clear(); } flags_ = hipDeviceScheduleSpin; destroyAllStreams(); amd::MemObjMap::Purge(devices()[0]); Create(); } // ================================================================================================ void Device::WaitActiveStreams(hip::Stream* blocking_stream, bool wait_null_stream) { amd::Command::EventWaitList eventWaitList(0); bool submitMarker = 0; auto waitForStream = [&submitMarker, &eventWaitList](hip::Stream* stream) { if (amd::Command *command = stream->getLastQueuedCommand(true)) { amd::Event &event = command->event(); // Check HW status of the ROCcrl event. // Note: not all ROCclr modes support HW status bool ready = stream->device().IsHwEventReady(event); if (!ready) { ready = (command->status() == CL_COMPLETE); } submitMarker |= stream->vdev()->isFenceDirty(); // Check the current active status if (!ready) { command->notifyCmdQueue(); eventWaitList.push_back(command); } else { command->release(); } } }; if (wait_null_stream) { if (null_stream_) { waitForStream(null_stream_); } } else { amd::ScopedLock lock(streamSetLock); for (const auto& active_stream : streamSet) { // If it's the current device if (// Make sure it's a default stream ((active_stream->Flags() & hipStreamNonBlocking) == 0) && // and it's not the current stream (active_stream != blocking_stream)) { // Get the last valid command waitForStream(active_stream); } } } // Check if we have to wait anything if (eventWaitList.size() > 0 || submitMarker) { amd::Command* command = new amd::Marker(*blocking_stream, kMarkerDisableFlush, eventWaitList); if (command != nullptr) { command->enqueue(); command->release(); } } // Release all active commands. It's safe after the marker was enqueued for (const auto& it : eventWaitList) { it->release(); } } // ================================================================================================ void Device::AddStream(Stream* stream) { amd::ScopedLock lock(streamSetLock); streamSet.insert(stream); } // ================================================================================================ void Device::RemoveStream(Stream* stream){ amd::ScopedLock lock(streamSetLock); streamSet.erase(stream); } // ================================================================================================ bool Device::StreamExists(Stream* stream){ amd::ScopedLock lock(streamSetLock); if (streamSet.find(stream) != streamSet.end()) { return true; } return false; } // ================================================================================================ void Device::destroyAllStreams() { std::vector toBeDeleted; { amd::ScopedLock lock(streamSetLock); for (auto& it : streamSet) { if (it->Null() == false ) { toBeDeleted.push_back(it); } } } for (auto& it : toBeDeleted) { hip::Stream::Destroy(it); } } // ================================================================================================ void Device::SyncAllStreams( bool cpu_wait) { // Make a local copy to avoid stalls for GPU finish with multiple threads std::vector streams; streams.reserve(streamSet.size()); { amd::ScopedLock lock(streamSetLock); for (auto it : streamSet) { streams.push_back(it); it->retain(); } } for (auto it : streams) { it->finish(cpu_wait); it->release(); } // Release freed memory for all memory pools on the device ReleaseFreedMemory(); // Release all graph exec objects destroyed by user. ReleaseGraphExec(hip::getCurrentDevice()->deviceId()); } // ================================================================================================ bool Device::StreamCaptureBlocking() { amd::ScopedLock lock(streamSetLock); for (auto& it : streamSet) { if (it->GetCaptureStatus() == hipStreamCaptureStatusActive && it->Flags() != hipStreamNonBlocking) { return true; } } return false; } // ================================================================================================ bool Device::existsActiveStreamForDevice() { amd::ScopedLock lock(streamSetLock); for (const auto& active_stream : streamSet) { if (active_stream->GetQueueStatus()) { return true; } } return false; } // ================================================================================================ Device::~Device() { if (default_mem_pool_ != nullptr) { default_mem_pool_->release(); } if (graph_mem_pool_ != nullptr) { graph_mem_pool_->release(); } if (null_stream_ != nullptr) { hip::Stream::Destroy(null_stream_); } } void ihipDestroyDevice() { for (auto deviceHandle : g_devices) { delete deviceHandle; } } hipError_t ihipDeviceGet(hipDevice_t* device, int deviceId) { if (device == nullptr) { return hipErrorInvalidValue; } if (deviceId < 0 || static_cast(deviceId) >= g_devices.size()) { return hipErrorInvalidDevice; } *device = deviceId; return hipSuccess; } hipError_t hipDeviceGet(hipDevice_t* device, int deviceId) { HIP_INIT_API(hipDeviceGet, device, deviceId); HIP_RETURN(ihipDeviceGet(device, deviceId)); } hipError_t hipDeviceTotalMem(size_t* bytes, hipDevice_t device) { HIP_INIT_API(hipDeviceTotalMem, bytes, device); if (device < 0 || static_cast(device) >= g_devices.size()) { HIP_RETURN(hipErrorInvalidDevice); } if (bytes == nullptr) { HIP_RETURN(hipErrorInvalidValue); } auto* deviceHandle = g_devices[device]->devices()[0]; const auto& info = deviceHandle->info(); *bytes = info.globalMemSize_; HIP_RETURN(hipSuccess); } hipError_t hipDeviceComputeCapability(int* major, int* minor, hipDevice_t device) { HIP_INIT_API(hipDeviceComputeCapability, major, minor, device); if (device < 0 || static_cast(device) >= g_devices.size()) { HIP_RETURN(hipErrorInvalidDevice); } if (major == nullptr || minor == nullptr) { HIP_RETURN(hipErrorInvalidValue); } auto* deviceHandle = g_devices[device]->devices()[0]; const auto& isa = deviceHandle->isa(); *major = isa.versionMajor(); *minor = isa.versionMinor(); HIP_RETURN(hipSuccess); } hipError_t hipDeviceGetCount(int* count) { HIP_INIT_API(hipDeviceGetCount, count); HIP_RETURN(ihipDeviceGetCount(count)); } hipError_t ihipDeviceGetCount(int* count) { if (count == nullptr) { return hipErrorInvalidValue; } // Get all available devices *count = g_devices.size(); if (*count < 1) { return hipErrorNoDevice; } return hipSuccess; } hipError_t hipDeviceGetName(char* name, int len, hipDevice_t device) { HIP_INIT_API(hipDeviceGetName, (void*)name, len, device); if (device < 0 || static_cast(device) >= g_devices.size()) { HIP_RETURN(hipErrorInvalidDevice); } if (name == nullptr || len <= 0) { HIP_RETURN(hipErrorInvalidValue); } auto* deviceHandle = g_devices[device]->devices()[0]; const auto& info = deviceHandle->info(); const auto nameLen = ::strlen(info.boardName_); // Only copy partial name if size of `dest` is smaller than size of `src` including // trailing zero byte auto memcpySize = (len <= (nameLen + 1) ? (len - 1) : nameLen); ::memcpy(name, info.boardName_, memcpySize); name[memcpySize] = '\0'; HIP_RETURN(hipSuccess); } hipError_t hipDeviceGetUuid(hipUUID* uuid, hipDevice_t device) { HIP_INIT_API(hipDeviceGetUuid, reinterpret_cast(uuid), device); if (device < 0 || static_cast(device) >= g_devices.size()) { HIP_RETURN(hipErrorInvalidDevice); } if (uuid == nullptr) { HIP_RETURN(hipErrorInvalidValue); } auto* deviceHandle = g_devices[device]->devices()[0]; const auto& info = deviceHandle->info(); memcpy(uuid->bytes, info.uuid_, sizeof(info.uuid_)); HIP_RETURN(hipSuccess); } hipError_t ihipGetDeviceProperties(hipDeviceProp_tR0600* props, int device) { if (props == nullptr) { return hipErrorInvalidValue; } if (unsigned(device) >= g_devices.size()) { return hipErrorInvalidDevice; } auto* deviceHandle = g_devices[device]->devices()[0]; constexpr auto int32_max = static_cast(std::numeric_limits::max()); constexpr auto uint16_max = static_cast(std::numeric_limits::max()) + 1; hipDeviceProp_tR0600 deviceProps = {0}; const auto& info = deviceHandle->info(); const auto& isa = deviceHandle->isa(); ::strncpy(deviceProps.name, info.boardName_, sizeof(info.boardName_)); memcpy(deviceProps.uuid.bytes, info.uuid_, sizeof(info.uuid_)); deviceProps.totalGlobalMem = info.globalMemSize_; deviceProps.sharedMemPerBlock = info.localMemSizePerCU_; deviceProps.sharedMemPerMultiprocessor = info.localMemSizePerCU_ * info.numRTCUs_; deviceProps.regsPerBlock = info.availableRegistersPerCU_; deviceProps.warpSize = info.wavefrontWidth_; deviceProps.maxThreadsPerBlock = info.maxWorkGroupSize_; deviceProps.maxThreadsDim[0] = info.maxWorkItemSizes_[0]; deviceProps.maxThreadsDim[1] = info.maxWorkItemSizes_[1]; deviceProps.maxThreadsDim[2] = info.maxWorkItemSizes_[2]; deviceProps.maxGridSize[0] = int32_max; deviceProps.maxGridSize[1] = uint16_max; deviceProps.maxGridSize[2] = uint16_max; deviceProps.clockRate = info.maxEngineClockFrequency_ * 1000; deviceProps.memoryClockRate = info.maxMemoryClockFrequency_ * 1000; deviceProps.memoryBusWidth = info.globalMemChannels_; deviceProps.totalConstMem = std::min(info.maxConstantBufferSize_, int32_max); deviceProps.major = isa.versionMajor(); deviceProps.minor = isa.versionMinor(); deviceProps.multiProcessorCount = info.maxComputeUnits_; deviceProps.l2CacheSize = info.l2CacheSize_; deviceProps.maxThreadsPerMultiProcessor = info.maxThreadsPerCU_; deviceProps.maxBlocksPerMultiProcessor = int(info.maxThreadsPerCU_ / info.maxWorkGroupSize_); deviceProps.computeMode = 0; deviceProps.clockInstructionRate = info.timeStampFrequency_; deviceProps.arch.hasGlobalInt32Atomics = 1; deviceProps.arch.hasGlobalFloatAtomicExch = 1; deviceProps.arch.hasSharedInt32Atomics = 1; deviceProps.arch.hasSharedFloatAtomicExch = 1; deviceProps.arch.hasFloatAtomicAdd = 1; deviceProps.arch.hasGlobalInt64Atomics = 1; deviceProps.arch.hasSharedInt64Atomics = 1; deviceProps.hostNativeAtomicSupported = info.pcie_atomics_ ? 1 : 0; deviceProps.arch.hasDoubles = 1; deviceProps.arch.hasWarpVote = 1; deviceProps.arch.hasWarpBallot = 1; deviceProps.arch.hasWarpShuffle = 1; deviceProps.arch.hasFunnelShift = 0; deviceProps.arch.hasThreadFenceSystem = 1; deviceProps.arch.hasSyncThreadsExt = 0; deviceProps.arch.hasSurfaceFuncs = 0; deviceProps.arch.has3dGrid = 1; deviceProps.arch.hasDynamicParallelism = 0; deviceProps.concurrentKernels = 1; deviceProps.pciDomainID = info.pciDomainID; deviceProps.pciBusID = info.deviceTopology_.pcie.bus; deviceProps.pciDeviceID = info.deviceTopology_.pcie.device; deviceProps.maxSharedMemoryPerMultiProcessor = info.localMemSizePerCU_; deviceProps.canMapHostMemory = 1; deviceProps.regsPerMultiprocessor = info.availableRegistersPerCU_; sprintf(deviceProps.gcnArchName, "%s", isa.targetId()); deviceProps.cooperativeLaunch = info.cooperativeGroups_; deviceProps.cooperativeMultiDeviceLaunch = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedFunc = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedGridDim = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedBlockDim = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedSharedMem = info.cooperativeMultiDeviceGroups_; deviceProps.maxTexture1DLinear = std::min(16 * info.imageMaxBufferSize_, int32_max); // Max pixel size is 16 bytes deviceProps.maxTexture1DMipmap = std::min(16 * info.imageMaxBufferSize_, int32_max); deviceProps.maxTexture1D = deviceProps.maxSurface1D = std::min(info.image1DMaxWidth_, int32_max); deviceProps.maxTexture2D[0] = deviceProps.maxSurface2D[0] = std::min(info.image2DMaxWidth_, int32_max); deviceProps.maxTexture2D[1] = deviceProps.maxSurface2D[1] = std::min(info.image2DMaxHeight_, int32_max); deviceProps.maxTexture3D[0] = deviceProps.maxSurface3D[0] = std::min(info.image3DMaxWidth_, int32_max); deviceProps.maxTexture3D[1] = deviceProps.maxSurface3D[1] = std::min(info.image3DMaxHeight_, int32_max); deviceProps.maxTexture3D[2] = deviceProps.maxSurface3D[2] = std::min(info.image3DMaxDepth_, int32_max); deviceProps.maxTexture1DLayered[0] = deviceProps.maxSurface1DLayered[0] = std::min(info.image1DAMaxWidth_, int32_max); deviceProps.maxTexture1DLayered[1] = deviceProps.maxSurface1DLayered[1] = std::min(info.imageMaxArraySize_, int32_max); deviceProps.maxTexture2DLayered[0] = deviceProps.maxSurface2DLayered[0] = std::min(info.image2DAMaxWidth_[0], int32_max); deviceProps.maxTexture2DLayered[1] = deviceProps.maxSurface2DLayered[1] = std::min(info.image2DAMaxWidth_[1], int32_max); deviceProps.maxTexture2DLayered[2] = deviceProps.maxSurface2DLayered[2] = std::min(info.imageMaxArraySize_, int32_max); deviceProps.hdpMemFlushCntl = info.hdpMemFlushCntl; deviceProps.hdpRegFlushCntl = info.hdpRegFlushCntl; deviceProps.memPitch = std::min(info.maxMemAllocSize_, int32_max); deviceProps.textureAlignment = deviceProps.surfaceAlignment = info.imageBaseAddressAlignment_; deviceProps.texturePitchAlignment = info.imagePitchAlignment_; deviceProps.kernelExecTimeoutEnabled = 0; deviceProps.ECCEnabled = info.errorCorrectionSupport_ ? 1 : 0; deviceProps.isLargeBar = info.largeBar_ ? 1 : 0; deviceProps.asicRevision = info.asicRevision_; deviceProps.ipcEventSupported = 1; deviceProps.streamPrioritiesSupported = 1; deviceProps.multiGpuBoardGroupID = info.deviceTopology_.pcie.device; // HMM capabilities deviceProps.asyncEngineCount = info.numAsyncQueues_; deviceProps.deviceOverlap = (info.numAsyncQueues_ > 0) ? 1 : 0; deviceProps.unifiedAddressing = info.hmmDirectHostAccess_; deviceProps.managedMemory = info.hmmSupported_; deviceProps.concurrentManagedAccess = info.hmmSupported_; deviceProps.directManagedMemAccessFromHost = info.hmmDirectHostAccess_; deviceProps.canUseHostPointerForRegisteredMem = info.hostUnifiedMemory_; deviceProps.pageableMemoryAccess = info.hmmCpuMemoryAccessible_; deviceProps.hostRegisterSupported = true; deviceProps.pageableMemoryAccessUsesHostPageTables = info.iommuv2_; // Mem pool deviceProps.memoryPoolsSupported = HIP_MEM_POOL_SUPPORT; unsigned int memPoolHandleType = 0; if (HIP_MEM_POOL_SUPPORT) { #if defined(__linux__) memPoolHandleType |= hipMemHandleTypePosixFileDescriptor; #elif defined(_WIN32) memPoolHandleType |= hipMemHandleTypeWin32; memPoolHandleType |= hipMemHandleTypeWin32Kmt; #endif } deviceProps.memoryPoolSupportedHandleTypes = memPoolHandleType; // Caching behavior deviceProps.globalL1CacheSupported = 1; deviceProps.localL1CacheSupported = 1; deviceProps.persistingL2CacheMaxSize = info.l2CacheSize_; deviceProps.reservedSharedMemPerBlock = 0; deviceProps.sharedMemPerBlockOptin = info.localMemSizePerCU_; // Unsupported features // Single to double precision perf ratio deviceProps.singleToDoublePrecisionPerfRatio = 0; // Flag hipHostRegisterReadOnly deviceProps.hostRegisterReadOnlySupported = 0; // Compute preemption deviceProps.computePreemptionSupported = 0; // Cubemaps deviceProps.maxTextureCubemap = 0; deviceProps.maxTextureCubemapLayered[0] = 0; deviceProps.maxTextureCubemapLayered[1] = 0; deviceProps.maxSurfaceCubemap = 0; deviceProps.maxSurfaceCubemapLayered[0] = 0; deviceProps.maxSurfaceCubemapLayered[1] = 0; // Texture gather ops deviceProps.maxTexture2DGather[0] = 0; deviceProps.maxTexture2DGather[1] = 0; // Textures bound to pitch memory deviceProps.maxTexture2DLinear[0] = 0; deviceProps.maxTexture2DLinear[1] = 0; deviceProps.maxTexture2DLinear[2] = 0; // Alternate 3D texture deviceProps.maxTexture3DAlt[0] = 0; deviceProps.maxTexture3DAlt[1] = 0; deviceProps.maxTexture3DAlt[2] = 0; // access policy deviceProps.accessPolicyMaxWindowSize = 0; // cluster launch deviceProps.clusterLaunch = 0; // Mapping HIP array deviceProps.deferredMappingHipArraySupported = 0; // RDMA options deviceProps.gpuDirectRDMASupported = 0; deviceProps.gpuDirectRDMAFlushWritesOptions = 0; deviceProps.gpuDirectRDMAWritesOrdering = 0; *reinterpret_cast(&deviceProps.luid[0]) = info.luidLowPart_; *reinterpret_cast(&deviceProps.luid[sizeof(uint32_t)]) = info.luidHighPart_; deviceProps.luidDeviceNodeMask = info.luidDeviceNodeMask_; deviceProps.sparseHipArraySupported = 0; deviceProps.timelineSemaphoreInteropSupported = 0; deviceProps.unifiedFunctionPointers = 0; deviceProps.integrated = info.hostUnifiedMemory_; *props = deviceProps; return hipSuccess; } hipError_t hipGetDevicePropertiesR0600(hipDeviceProp_tR0600* prop, int device) { HIP_INIT_API(hipGetDevicePropertiesR0600, prop, device); HIP_RETURN(ihipGetDeviceProperties(prop, device)); } hipError_t hipGetDevicePropertiesR0000(hipDeviceProp_tR0000* prop, int device) { HIP_INIT_API(hipGetDevicePropertiesR0000, prop, device); if (prop == nullptr) { HIP_RETURN(hipErrorInvalidValue); } if (unsigned(device) >= g_devices.size()) { HIP_RETURN(hipErrorInvalidDevice); } auto* deviceHandle = g_devices[device]->devices()[0]; constexpr auto int32_max = static_cast(std::numeric_limits::max()); constexpr auto uint16_max = static_cast(std::numeric_limits::max()) + 1; hipDeviceProp_tR0000 deviceProps = {0}; const auto& info = deviceHandle->info(); const auto& isa = deviceHandle->isa(); ::strncpy(deviceProps.name, info.boardName_, 128); deviceProps.totalGlobalMem = info.globalMemSize_; deviceProps.sharedMemPerBlock = info.localMemSizePerCU_; deviceProps.regsPerBlock = info.availableRegistersPerCU_; deviceProps.warpSize = info.wavefrontWidth_; deviceProps.maxThreadsPerBlock = info.maxWorkGroupSize_; deviceProps.maxThreadsDim[0] = info.maxWorkItemSizes_[0]; deviceProps.maxThreadsDim[1] = info.maxWorkItemSizes_[1]; deviceProps.maxThreadsDim[2] = info.maxWorkItemSizes_[2]; deviceProps.maxGridSize[0] = int32_max; deviceProps.maxGridSize[1] = uint16_max; deviceProps.maxGridSize[2] = uint16_max; deviceProps.clockRate = info.maxEngineClockFrequency_ * 1000; deviceProps.memoryClockRate = info.maxMemoryClockFrequency_ * 1000; deviceProps.memoryBusWidth = info.globalMemChannels_; deviceProps.totalConstMem = std::min(info.maxConstantBufferSize_, int32_max); deviceProps.major = isa.versionMajor(); deviceProps.minor = isa.versionMinor(); deviceProps.multiProcessorCount = info.maxComputeUnits_; deviceProps.l2CacheSize = info.l2CacheSize_; deviceProps.maxThreadsPerMultiProcessor = info.maxThreadsPerCU_; deviceProps.computeMode = 0; deviceProps.clockInstructionRate = info.timeStampFrequency_; deviceProps.arch.hasGlobalInt32Atomics = 1; deviceProps.arch.hasGlobalFloatAtomicExch = 1; deviceProps.arch.hasSharedInt32Atomics = 1; deviceProps.arch.hasSharedFloatAtomicExch = 1; deviceProps.arch.hasFloatAtomicAdd = 1; deviceProps.arch.hasGlobalInt64Atomics = 1; deviceProps.arch.hasSharedInt64Atomics = 1; deviceProps.arch.hasDoubles = 1; deviceProps.arch.hasWarpVote = 1; deviceProps.arch.hasWarpBallot = 1; deviceProps.arch.hasWarpShuffle = 1; deviceProps.arch.hasFunnelShift = 0; deviceProps.arch.hasThreadFenceSystem = 1; deviceProps.arch.hasSyncThreadsExt = 0; deviceProps.arch.hasSurfaceFuncs = 0; deviceProps.arch.has3dGrid = 1; deviceProps.arch.hasDynamicParallelism = 0; deviceProps.concurrentKernels = 1; deviceProps.pciDomainID = info.pciDomainID; deviceProps.pciBusID = info.deviceTopology_.pcie.bus; deviceProps.pciDeviceID = info.deviceTopology_.pcie.device; deviceProps.maxSharedMemoryPerMultiProcessor = info.localMemSizePerCU_; deviceProps.canMapHostMemory = 1; // FIXME: This should be removed, targets can have character names as well. deviceProps.gcnArch = isa.versionMajor() * 100 + isa.versionMinor() * 10 + isa.versionStepping(); sprintf(deviceProps.gcnArchName, "%s", isa.targetId()); deviceProps.cooperativeLaunch = info.cooperativeGroups_; deviceProps.cooperativeMultiDeviceLaunch = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedFunc = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedGridDim = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedBlockDim = info.cooperativeMultiDeviceGroups_; deviceProps.cooperativeMultiDeviceUnmatchedSharedMem = info.cooperativeMultiDeviceGroups_; deviceProps.maxTexture1DLinear = std::min(16 * info.imageMaxBufferSize_, int32_max); // Max pixel size is 16 bytes deviceProps.maxTexture1D = std::min(info.image1DMaxWidth_, int32_max); deviceProps.maxTexture2D[0] = std::min(info.image2DMaxWidth_, int32_max); deviceProps.maxTexture2D[1] = std::min(info.image2DMaxHeight_, int32_max); deviceProps.maxTexture3D[0] = std::min(info.image3DMaxWidth_, int32_max); deviceProps.maxTexture3D[1] = std::min(info.image3DMaxHeight_, int32_max); deviceProps.maxTexture3D[2] = std::min(info.image3DMaxDepth_, int32_max); deviceProps.hdpMemFlushCntl = info.hdpMemFlushCntl; deviceProps.hdpRegFlushCntl = info.hdpRegFlushCntl; deviceProps.memPitch = std::min(info.maxMemAllocSize_, int32_max); deviceProps.textureAlignment = info.imageBaseAddressAlignment_; deviceProps.texturePitchAlignment = info.imagePitchAlignment_; deviceProps.kernelExecTimeoutEnabled = 0; deviceProps.ECCEnabled = info.errorCorrectionSupport_ ? 1 : 0; deviceProps.isLargeBar = info.largeBar_ ? 1 : 0; deviceProps.asicRevision = info.asicRevision_; // HMM capabilities deviceProps.managedMemory = info.hmmSupported_; deviceProps.concurrentManagedAccess = info.hmmSupported_; deviceProps.directManagedMemAccessFromHost = info.hmmDirectHostAccess_; deviceProps.pageableMemoryAccess = info.hmmCpuMemoryAccessible_; deviceProps.pageableMemoryAccessUsesHostPageTables = info.hostUnifiedMemory_; *prop = deviceProps; HIP_RETURN(hipSuccess); } hipError_t hipGetProcAddress(const char* symbol, void** pfn, int hipVersion, uint64_t flags, hipDriverProcAddressQueryResult* symbolStatus) { HIP_INIT_API(hipGetProcAddress, symbol, pfn, hipVersion, flags, symbolStatus); std::string symbolString = symbol; if(symbol == nullptr || symbolString == "" || pfn == nullptr){ HIP_RETURN(hipErrorInvalidValue); } if (symbolString == "hipGetDeviceProperties"){ if (hipVersion >= 600){ symbolString = "hipGetDevicePropertiesR0600"; } } else if (symbolString == "hipChooseDevice") { if (hipVersion >= 600){ symbolString = "hipChooseDeviceR0600"; } } void* handle = hip::PlatformState::instance().getDynamicLibraryHandle(); if (handle == nullptr){ HIP_RETURN(hipErrorInvalidValue); } *pfn = amd::Os::getSymbol(handle, symbolString.c_str()); if (!(*pfn)) { if (symbolStatus != nullptr) { *symbolStatus = HIP_GET_PROC_ADDRESS_SYMBOL_NOT_FOUND; } HIP_RETURN(hipErrorInvalidValue); } if (symbolStatus != nullptr) { *symbolStatus = HIP_GET_PROC_ADDRESS_SUCCESS; } HIP_RETURN(hipSuccess); } } // namespace hip extern "C" hipError_t hipGetDeviceProperties(hipDeviceProp_tR0000* props, hipDevice_t device) { return hip::hipGetDevicePropertiesR0000(props, device); }