Beginning ROCm release v5.0, AMD ROCm documentation has a new portal at https://docs.amd.com This portal consists of ROCm documentation v4.5 and above.
For documentation prior to ROCm v4.5, you may continue to access https://rocmdocs.amd.com.
AMD ROCm v5.1.1 is now released. The release documentation is available at https://docs.amd.com.
AMD ROCm v5.1 is now released. The release documentation is available at https://docs.amd.com.
The following defects are fixed in the ROCm v5.0.2 release.
In ROCm v5.0, when using the “assert()” call in a HIP kernel, the compiler may sometimes fail to emit kernel metadata related to the hostcall facility, which results in incomplete initialization of the hostcall facility in the HIP runtime. This can cause the HIP kernel to crash when it attempts to execute the “assert()” call. The root cause was an incorrect check in the compiler to determine whether the hostcall facility is required by the kernel. This is fixed in the ROCm v5.0.2 release. The resolution includes a compiler change, which emits the required metadata by default, unless the compiler can prove that the hostcall facility is not required by the kernel. This ensures that the “assert()” call never fails.
Note: This fix may lead to breakage in some OpenMP offload use cases, which use print inside a target region and result in an abort in device code. The issue will be fixed in a future release.
The compatibility matrix in the AMD Deep Learning Guide is updated for ROCm v5.0.2.
For more information and documentation updates, refer to https://docs.amd.com.
In prior ROCm releases, by default, the hipcc/hipconfig Perl scripts were used to identify and set target compiler options, target platform, compiler, and runtime appropriately. In ROCm v5.0.1, hipcc.bin and hipconfig.bin have been added as the compiled binary implementations of the hipcc and hipconfig. These new binaries are currently a work-in-progress, considered, and marked as experimental. ROCm plans to fully transition to hipcc.bin and hipconfig.bin in the a future ROCm release. The existing hipcc and hipconfig Perl scripts are renamed to hipcc.pl and hipconfig.pl respectively. New top-level hipcc and hipconfig Perl scripts are created, which can switch between the Perl script or the compiled binary based on the environment variable HIPCC_USE_PERL_SCRIPT. In ROCm 5.0.1, by default, this environment variable is set to use hipcc and hipconfig through the Perl scripts. Subsequently, Perl scripts will no longer be available in ROCm in a future release.
-
ROCm Downloads Guide
-
ROCm Installation Guide
-
ROCm Release Notes
For more information, see https://docs.amd.com.
This document describes the features, fixed issues, and information about downloading and installing the AMD ROCm™ software.
It also covers known issues and deprecations in this release.
To make a distinction between open-source and closed-source components, all ROCm repositories will consist of sub-folders in future releases.
- All open-source components will be placed in the
base-url/<rocm-ver>/main
sub-folder - All closed-source components will reside in the
base-url/<rocm-ver>/proprietary
sub-folder
The AMD ROCm platform supports the following operating systems:
OS-Version (64-bit) | Kernel Versions |
---|---|
CentOS 8.3 | 4.18.0-193.el8 |
CentOS 7.9 | 3.10.0-1127 |
RHEL 8.5 | 4.18.0-348.7.1.el8_5.x86_64 |
RHEL 8.4 | 4.18.0-305.el8.x86_64 |
RHEL 7.9 | 3.10.0-1160.6.1.el7 |
SLES 15 SP3 | 5.3.18-59.16-default |
Ubuntu 20.04.3 | 5.8.0 LTS / 5.11 HWE |
Ubuntu 18.04.5 [5.4 HWE kernel] | 5.4.0-71-generic |
This release extends support for RHEL v8.5.
This release extends ROCm support for Radeon Pro V620 and W6800 Workstation GPUs.
- SRIOV virtualization support for Radeon Pro V620
- KVM Hypervisor (1VF support only) on Ubuntu Host OS with Ubuntu, CentOs, and RHEL Guest
- Support for ROCm-SMI in an SRIOV environment. For more details, refer to the ROCm SMI API documentation.
Note: Radeon Pro v620 is not supported on SLES.
This release has the following ROCm installation enhancements.
In this release, users can install the kernel-mode driver using the Installer method. Some of the ROCm-specific use cases that the installer currently supports are:
- OpenCL (ROCr/KFD based) runtime
- HIP runtimes
- ROCm libraries and applications
- ROCm Compiler and device libraries
- ROCr runtime and thunk
- Kernel-mode driver
Users now can install multiple ROCm releases simultaneously on a system using the newly introduced installer script and package manager install mechanism.
Users can also uninstall multi-version ROCm releases using the amdgpu-uninstall
script and package manager.
In this release, the amdgpu-install
script automates the process of updating local repository information before proceeding to ROCm installation.
Users can now upgrade the existing ROCm installation to specific or latest ROCm releases.
For more details, refer to the AMD ROCm Installation Guide v5.0.
Beginning ROCm release v5.0, AMD ROCm documentation has a new portal at https://docs.amd.com. This portal consists of ROCm documentation v4.5 and above.
For documentation prior to ROCm v4.5, you may continue to access https://rocmdocs.amd.com.
- ROCm Data Center Tool User Guide
- ROCm Data Center Tool API Guide
- System Management Interface Guide
- System Management Interface API Guide
- Command Line Interface Guide
- Deep Learning Guide
- MIGraphX API Guide
- MIOpen API Guide
- MIVisionX API Guide
- hipSOLVER User Guide
- RCCL User Guide
- rocALUTION User Guide
- rocBLAS User Guide
- rocFFT User Guide
- rocRAND User Guide
- rocSOLVER User Guide
- rocSPARSE User Guide
- rocThrust User Guide
- ROCDebugger User Guide
- ROCDebugger API Guide
- ROCTracer User Guide
- ROCTracer API Guide
- AMD Instinct High Performance Computing and Tuning Guide
- AMD Compiler Reference Guide
- HIPify User Guide
- HIP Supported CUDA API Reference Guide
- ROCm Debug Agent Guide
- System Level Debug Guide
- ROCm Validation Suite
- HIP Programming Guide
- HIP API Guide
- HIP FAQ Guide
- OpenMP Support Guide
- ROCm Glossary – Terms and Definitions
- For AMD ROCm documentation, see
https://rocmdocs.amd.com/en/latest/
- For installation instructions on supported platforms, see
https://rocmdocs.amd.com/en/latest/Installation_Guide/Installation-Guide.html
- For AMD ROCm binary structure, see
https://rocmdocs.amd.com/en/latest/Installation_Guide/Software-Stack-for-AMD-GPU.html
- For AMD ROCm release history, see
https://rocmdocs.amd.com/en/latest/Current_Release_Notes/ROCm-Version-History.html
The ROCm v5.0 release consists of the following HIP enhancements.
The HIP Installation Guide is updated to include building HIP from source on the NVIDIA platform.
Refer to the HIP Installation Guide v5.0 for more details.
Managed memory, including the __managed__
keyword, is now supported in the HIP combined host/device compilation. Through unified memory allocation, managed memory allows data to be shared and accessible to both the CPU and GPU using a single pointer. The allocation is managed by the AMD GPU driver using the Linux Heterogeneous Memory Management (HMM) mechanism. The user can call managed memory API hipMallocManaged to allocate a large chunk of HMM memory, execute kernels on a device, and fetch data between the host and device as needed.
Note: In a HIP application, it is recommended to do a capability check before calling the managed memory APIs. For example,
int managed_memory = 0;
HIPCHECK(hipDeviceGetAttribute(&managed_memory, hipDeviceAttributeManagedMemory, p_gpuDevice));
if (!managed_memory) {
printf ("info: managed memory access not supported on the device %d\n Skipped\n", p_gpuDevice);
} else {
HIPCHECK(hipSetDevice(p_gpuDevice));
HIPCHECK(hipMallocManaged(&Hmm, N * sizeof(T)));
. . .
}
Note: The managed memory capability check may not be necessary; however, if HMM is not supported, managed malloc will fall back to using system memory. Other managed memory API calls will, then, have
Refer to the HIP API documentation for more details on managed memory APIs.
For the application, see hipMallocManaged.cpp
The following new environment variable is added in this release:
Environment Variable | Value | Description |
---|---|---|
HSA_COOP_CU_COUNT | 0 or 1 (default is 0) | Some processors support more compute units than can reliably be used in a cooperative dispatch. Setting the environment variable HSA_COOP_CU_COUNT to 1 will cause ROCr to return the correct CU count for cooperative groups through the HSA_AMD_AGENT_INFO_COOPERATIVE_COMPUTE_UNIT_COUNT attribute of hsa_agent_get_info(). Setting HSA_COOP_CU_COUNT to other values, or leaving it unset, will cause ROCr to return the same CU count for the attributes HSA_AMD_AGENT_INFO_COOPERATIVE_COMPUTE_UNIT_COUNT and HSA_AMD_AGENT_INFO_COMPUTE_UNIT_COUNT. Future ROCm releases will make HSA_COOP_CU_COUNT=1 the default. |
|
Library | Changes |
---|---|
rocBLAS | Added
|
hipBLAS | Added
|
rocFFT | Changed
|
hipFFT | Fixed
|
rocSPARSE | Added
|
hipSPARSE | Added
|
rocALUTION | Changed
|
rocTHRUST | Updates
|
rocSOLVER | Added
|
hipSOLVER | Added
|
RCCL | Added
|
hipCUB | Fixed
|
rocPRIM | Fixed
|
This feature lists GPU events as they occur in real-time and can be used with kfdtest to produce vm_fault events for testing.
The command can be called with either " -e
or --showevents
like this:
-e [EVENT [EVENT ...]], --showevents [EVENT [EVENT ...]] Show event list
Where EVENT
is any list combination of VM_FAULT
, THERMAL_THROTTLE
, or GPU_RESET
and is NOT case sensitive.
Note: If no event arguments are passed, all events will be watched by default.
$ rocm-smi --showevents vm_fault thermal_throttle gpu_reset
======================= ROCm System Management Interface =======================
================================= Show Events ==================================
press 'q' or 'ctrl + c' to quit
DEVICE TIME TYPE DESCRIPTION
============================= End of ROCm SMI Log ==============================
(Run kfdtest in another window to test for vm_fault events.)
Note: Unlike other rocm-smi CLI commands, this command does not quit unless specified by the user. Users may press either q
or ctrl + c
to quit.
The rsmi_minmax_bandwidth_get API reads the HW Topology file and displays bandwidth (min-max) between any two NUMA nodes in a matrix format.
The Command Line Interface (CLI) command can be called as follows:
$ rocm-smi --shownodesbw
======================= ROCm System Management Interface =======================
================================== Bandwidth ===================================
GPU0 GPU1 GPU2 GPU3 GPU4 GPU5 GPU6 GPU7
GPU0 N/A 50000-200000 50000-50000 0-0 0-0 0-0 50000-100000 0-0
GPU1 50000-200000 N/A 0-0 50000-50000 0-0 50000-50000 0-0 0-0
GPU2 50000-50000 0-0 N/A 50000-200000 50000-100000 0-0 0-0 0-0
GPU3 0-0 50000-50000 50000-200000 N/A 0-0 0-0 0-0 50000-50000
GPU4 0-0 0-0 50000-100000 0-0 N/A 50000-200000 50000-50000 0-0
GPU5 0-0 50000-50000 0-0 0-0 50000-200000 N/A 0-0 50000-50000
GPU6 50000-100000 0-0 0-0 0-0 50000-50000 0-0 N/A 50000-200000
GPU7 0-0 0-0 0-0 50000-50000 0-0 50000-50000 50000-200000 N/A
Format: min-max; Units: mps
============================= End of ROCm SMI Log ==============================
The sample output above shows the maximum theoretical xgmi bandwidth between 2 numa nodes,
Note: "0-0" min-max bandwidth indicates devices are not connected directly.
The rsmi_is_p2p_accessible API returns "True" if P2P can be implemented between two nodes, and returns "False" if P2P cannot be implemented between the two nodes.
The Command Line Interface command can be called as follows:
rocm-smi --showtopoaccess
Sample Output:
$ rocm-smi --showtopoaccess
======================= ROCm System Management Interface =======================
===================== Link accessibility between two GPUs ======================
GPU0 GPU1
GPU0 True True
GPU1 True True
============================= End of ROCm SMI Log ==============================
Re-ordering of the enumerated type in hip_runtime_api.h to better match NV. See below for the difference in enumerated types.
ROCm software will be affected if any of the defined enums listed below are used in the code. Applications built with ROCm v5.0 enumerated types will work with a ROCm 4.5.2 driver. However, an undefined behavior error will occur with a ROCm v4.5.2 application that uses these enumerated types with a ROCm 5.0 runtime.
typedef enum hipDeviceAttribute_t {
hipDeviceAttributeMaxThreadsPerBlock, // Maximum number of threads per block.
hipDeviceAttributeMaxBlockDimX, // Maximum x-dimension of a block.
hipDeviceAttributeMaxBlockDimY, // Maximum y-dimension of a block.
hipDeviceAttributeMaxBlockDimZ, // Maximum z-dimension of a block.
hipDeviceAttributeMaxGridDimX, // Maximum x-dimension of a grid.
hipDeviceAttributeMaxGridDimY, // Maximum y-dimension of a grid.
hipDeviceAttributeMaxGridDimZ, // Maximum z-dimension of a grid.
hipDeviceAttributeMaxSharedMemoryPerBlock, // Maximum shared memory available per block in bytes.
hipDeviceAttributeTotalConstantMemory, // Constant memory size in bytes.
hipDeviceAttributeWarpSize, // Warp size in threads.
hipDeviceAttributeMaxRegistersPerBlock, // Maximum number of 32-bit registers available to a
// thread block. This number is shared by all thread
// blocks simultaneously resident on a
// multiprocessor.
hipDeviceAttributeClockRate, // Peak clock frequency in kilohertz.
hipDeviceAttributeMemoryClockRate, // Peak memory clock frequency in kilohertz.
hipDeviceAttributeMemoryBusWidth, // Global memory bus width in bits.
hipDeviceAttributeMultiprocessorCount, // Number of multiprocessors on the device.
hipDeviceAttributeComputeMode, // Compute mode that device is currently in.
hipDeviceAttributeL2CacheSize, // Size of L2 cache in bytes. 0 if the device doesn't have L2
// cache.
hipDeviceAttributeMaxThreadsPerMultiProcessor, // Maximum resident threads per
// multiprocessor.
hipDeviceAttributeComputeCapabilityMajor, // Major compute capability version number.
hipDeviceAttributeComputeCapabilityMinor, // Minor compute capability version number.
hipDeviceAttributeConcurrentKernels, // Device can possibly execute multiple kernels
// concurrently.
hipDeviceAttributePciBusId, // PCI Bus ID.
hipDeviceAttributePciDeviceId, // PCI Device ID.
hipDeviceAttributeMaxSharedMemoryPerMultiprocessor, // Maximum Shared Memory Per
// Multiprocessor.
hipDeviceAttributeIsMultiGpuBoard, // Multiple GPU devices.
hipDeviceAttributeIntegrated, // iGPU
hipDeviceAttributeCooperativeLaunch, // Support cooperative launch
hipDeviceAttributeCooperativeMultiDeviceLaunch, // Support cooperative launch on multiple devices
hipDeviceAttributeMaxTexture1DWidth, // Maximum number of elements in 1D images
hipDeviceAttributeMaxTexture2DWidth, // Maximum dimension width of 2D images in image elements
hipDeviceAttributeMaxTexture2DHeight, // Maximum dimension height of 2D images in image elements
hipDeviceAttributeMaxTexture3DWidth, // Maximum dimension width of 3D images in image elements
hipDeviceAttributeMaxTexture3DHeight, // Maximum dimensions height of 3D images in image elements
hipDeviceAttributeMaxTexture3DDepth, // Maximum dimensions depth of 3D images in image elements
hipDeviceAttributeCudaCompatibleBegin = 0,
hipDeviceAttributeHdpMemFlushCntl, // Address of the HDP\_MEM\_COHERENCY\_FLUSH\_CNTL register
hipDeviceAttributeHdpRegFlushCntl, // Address of the HDP\_REG\_COHERENCY\_FLUSH\_CNTL register
hipDeviceAttributeEccEnabled = hipDeviceAttributeCudaCompatibleBegin, // Whether ECC support is enabled.
hipDeviceAttributeAccessPolicyMaxWindowSize, // Cuda only. The maximum size of the window policy in bytes.
hipDeviceAttributeAsyncEngineCount, // Cuda only. Asynchronous engines number.
hipDeviceAttributeCanMapHostMemory, // Whether host memory can be mapped into device address space
hipDeviceAttributeCanUseHostPointerForRegisteredMem, // Cuda only. Device can access host registered memory
// at the same virtual address as the CPU
hipDeviceAttributeClockRate, // Peak clock frequency in kilohertz.
hipDeviceAttributeComputeMode, // Compute mode that device is currently in.
hipDeviceAttributeComputePreemptionSupported, // Cuda only. Device supports Compute Preemption.
hipDeviceAttributeConcurrentKernels, // Device can possibly execute multiple kernels concurrently.
hipDeviceAttributeConcurrentManagedAccess, // Device can coherently access managed memory concurrently with the CPU
hipDeviceAttributeCooperativeLaunch, // Support cooperative launch
hipDeviceAttributeCooperativeMultiDeviceLaunch, // Support cooperative launch on multiple devices
hipDeviceAttributeDeviceOverlap, // Cuda only. Device can concurrently copy memory and execute a kernel.
// Deprecated. Use instead asyncEngineCount.
hipDeviceAttributeDirectManagedMemAccessFromHost, // Host can directly access managed memory on
// the device without migration
hipDeviceAttributeGlobalL1CacheSupported, // Cuda only. Device supports caching globals in L1
hipDeviceAttributeHostNativeAtomicSupported, // Cuda only. Link between the device and the host supports native atomic operations
hipDeviceAttributeIntegrated, // Device is integrated GPU
hipDeviceAttributeIsMultiGpuBoard, // Multiple GPU devices.
hipDeviceAttributeKernelExecTimeout, // Run time limit for kernels executed on the device
hipDeviceAttributeL2CacheSize, // Size of L2 cache in bytes. 0 if the device doesn't have L2 cache.
hipDeviceAttributeLocalL1CacheSupported, // caching locals in L1 is supported
hipDeviceAttributeLuid, // Cuda only. 8-byte locally unique identifier in 8 bytes. Undefined on TCC and non-Windows platforms
hipDeviceAttributeLuidDeviceNodeMask, // Cuda only. Luid device node mask. Undefined on TCC and non-Windows platforms
hipDeviceAttributeComputeCapabilityMajor, // Major compute capability version number.
hipDeviceAttributeManagedMemory, // Device supports allocating managed memory on this system
hipDeviceAttributeMaxBlocksPerMultiProcessor, // Cuda only. Max block size per multiprocessor
hipDeviceAttributeMaxBlockDimX, // Max block size in width.
hipDeviceAttributeMaxBlockDimY, // Max block size in height.
hipDeviceAttributeMaxBlockDimZ, // Max block size in depth.
hipDeviceAttributeMaxGridDimX, // Max grid size in width.
hipDeviceAttributeMaxGridDimY, // Max grid size in height.
hipDeviceAttributeMaxGridDimZ, // Max grid size in depth.
hipDeviceAttributeMaxSurface1D, // Maximum size of 1D surface.
hipDeviceAttributeMaxSurface1DLayered, // Cuda only. Maximum dimensions of 1D layered surface.
hipDeviceAttributeMaxSurface2D, // Maximum dimension (width, height) of 2D surface.
hipDeviceAttributeMaxSurface2DLayered, // Cuda only. Maximum dimensions of 2D layered surface.
hipDeviceAttributeMaxSurface3D, // Maximum dimension (width, height, depth) of 3D surface.
hipDeviceAttributeMaxSurfaceCubemap, // Cuda only. Maximum dimensions of Cubemap surface.
hipDeviceAttributeMaxSurfaceCubemapLayered, // Cuda only. Maximum dimension of Cubemap layered surface.
hipDeviceAttributeMaxTexture1DWidth, // Maximum size of 1D texture.
hipDeviceAttributeMaxTexture1DLayered, // Cuda only. Maximum dimensions of 1D layered texture.
hipDeviceAttributeMaxTexture1DLinear, // Maximum number of elements allocatable in a 1D linear texture.
// Use cudaDeviceGetTexture1DLinearMaxWidth() instead on Cuda.
hipDeviceAttributeMaxTexture1DMipmap, // Cuda only. Maximum size of 1D mipmapped texture.
hipDeviceAttributeMaxTexture2DWidth, // Maximum dimension width of 2D texture.
hipDeviceAttributeMaxTexture2DHeight, // Maximum dimension hight of 2D texture.
hipDeviceAttributeMaxTexture2DGather, // Cuda only. Maximum dimensions of 2D texture if gather operations performed.
hipDeviceAttributeMaxTexture2DLayered, // Cuda only. Maximum dimensions of 2D layered texture.
hipDeviceAttributeMaxTexture2DLinear, // Cuda only. Maximum dimensions (width, height, pitch) of 2D textures bound to pitched memory.
hipDeviceAttributeMaxTexture2DMipmap, // Cuda only. Maximum dimensions of 2D mipmapped texture.
hipDeviceAttributeMaxTexture3DWidth, // Maximum dimension width of 3D texture.
hipDeviceAttributeMaxTexture3DHeight, // Maximum dimension height of 3D texture.
hipDeviceAttributeMaxTexture3DDepth, // Maximum dimension depth of 3D texture.
hipDeviceAttributeMaxTexture3DAlt, // Cuda only. Maximum dimensions of alternate 3D texture.
hipDeviceAttributeMaxTextureCubemap, // Cuda only. Maximum dimensions of Cubemap texture
hipDeviceAttributeMaxTextureCubemapLayered, // Cuda only. Maximum dimensions of Cubemap layered texture.
hipDeviceAttributeMaxThreadsDim, // Maximum dimension of a block
hipDeviceAttributeMaxThreadsPerBlock, // Maximum number of threads per block.
hipDeviceAttributeMaxThreadsPerMultiProcessor, // Maximum resident threads per multiprocessor.
hipDeviceAttributeMaxPitch, // Maximum pitch in bytes allowed by memory copies
hipDeviceAttributeMemoryBusWidth, // Global memory bus width in bits.
hipDeviceAttributeMemoryClockRate, // Peak memory clock frequency in kilohertz.
hipDeviceAttributeComputeCapabilityMinor, // Minor compute capability version number.
hipDeviceAttributeMultiGpuBoardGroupID, // Cuda only. Unique ID of device group on the same multi-GPU board
hipDeviceAttributeMultiprocessorCount, // Number of multiprocessors on the device.
hipDeviceAttributeName, // Device name.
hipDeviceAttributePageableMemoryAccess, // Device supports coherently accessing pageable memory
// without calling hipHostRegister on it
hipDeviceAttributePageableMemoryAccessUsesHostPageTables, // Device accesses pageable memory via the host's page tables
hipDeviceAttributePciBusId, // PCI Bus ID.
hipDeviceAttributePciDeviceId, // PCI Device ID.
hipDeviceAttributePciDomainID, // PCI Domain ID.
hipDeviceAttributePersistingL2CacheMaxSize, // Cuda11 only. Maximum l2 persisting lines capacity in bytes
hipDeviceAttributeMaxRegistersPerBlock, // 32-bit registers available to a thread block. This number is shared
// by all thread blocks simultaneously resident on a multiprocessor.
hipDeviceAttributeMaxRegistersPerMultiprocessor, // 32-bit registers available per block.
hipDeviceAttributeReservedSharedMemPerBlock, // Cuda11 only. Shared memory reserved by CUDA driver per block.
hipDeviceAttributeMaxSharedMemoryPerBlock, // Maximum shared memory available per block in bytes.
hipDeviceAttributeSharedMemPerBlockOptin, // Cuda only. Maximum shared memory per block usable by special opt in.
hipDeviceAttributeSharedMemPerMultiprocessor, // Cuda only. Shared memory available per multiprocessor.
hipDeviceAttributeSingleToDoublePrecisionPerfRatio, // Cuda only. Performance ratio of single precision to double precision.
hipDeviceAttributeStreamPrioritiesSupported, // Cuda only. Whether to support stream priorities.
hipDeviceAttributeSurfaceAlignment, // Cuda only. Alignment requirement for surfaces
hipDeviceAttributeTccDriver, // Cuda only. Whether device is a Tesla device using TCC driver
hipDeviceAttributeTextureAlignment, // Alignment requirement for textures
hipDeviceAttributeTexturePitchAlignment, // Pitch alignment requirement for 2D texture references bound to pitched memory;
hipDeviceAttributeTotalConstantMemory, // Constant memory size in bytes.
hipDeviceAttributeTotalGlobalMem, // Global memory available on devicice.
hipDeviceAttributeUnifiedAddressing, // Cuda only. An unified address space shared with the host.
hipDeviceAttributeUuid, // Cuda only. Unique ID in 16 byte.
hipDeviceAttributeWarpSize, // Warp size in threads.
hipDeviceAttributeMaxPitch, // Maximum pitch in bytes allowed by memory copies
hipDeviceAttributeTextureAlignment, //Alignment requirement for textures
hipDeviceAttributeTexturePitchAlignment, //Pitch alignment requirement for 2D texture references bound to pitched memory;
hipDeviceAttributeKernelExecTimeout, //Run time limit for kernels executed on the device
hipDeviceAttributeCanMapHostMemory, //Device can map host memory into device address space
hipDeviceAttributeEccEnabled, //Device has ECC support enabled
hipDeviceAttributeCudaCompatibleEnd = 9999,
hipDeviceAttributeAmdSpecificBegin = 10000,
hipDeviceAttributeCooperativeMultiDeviceUnmatchedFunc, // Supports cooperative launch on multiple
// devices with unmatched functions
hipDeviceAttributeCooperativeMultiDeviceUnmatchedGridDim, // Supports cooperative launch on multiple
// devices with unmatched grid dimensions
hipDeviceAttributeCooperativeMultiDeviceUnmatchedBlockDim, // Supports cooperative launch on multiple
// devices with unmatched block dimensions
hipDeviceAttributeCooperativeMultiDeviceUnmatchedSharedMem, // Supports cooperative launch on multiple
// devices with unmatched shared memories
hipDeviceAttributeAsicRevision, // Revision of the GPU in this device
hipDeviceAttributeManagedMemory, // Device supports allocating managed memory on this system
hipDeviceAttributeDirectManagedMemAccessFromHost, // Host can directly access managed memory on
// the device without migration
hipDeviceAttributeConcurrentManagedAccess, // Device can coherently access managed memory
// concurrently with the CPU
hipDeviceAttributePageableMemoryAccess, // Device supports coherently accessing pageable memory
// without calling hipHostRegister on it
hipDeviceAttributePageableMemoryAccessUsesHostPageTables, // Device accesses pageable memory via
// the host's page tables
hipDeviceAttributeCanUseStreamWaitValue // '1' if Device supports hipStreamWaitValue32() and
// hipStreamWaitValue64(), '0' otherwise.
hipDeviceAttributeClockInstructionRate = hipDeviceAttributeAmdSpecificBegin, // Frequency in khz of the timer used by the device-side "clock"
hipDeviceAttributeArch, // Device architecture
hipDeviceAttributeMaxSharedMemoryPerMultiprocessor, // Maximum Shared Memory PerMultiprocessor.
hipDeviceAttributeGcnArch, // Device gcn architecture
hipDeviceAttributeGcnArchName, // Device gcnArch name in 256 bytes
hipDeviceAttributeHdpMemFlushCntl, // Address of the HDP_MEM_COHERENCY_FLUSH_CNTL register
hipDeviceAttributeHdpRegFlushCntl, // Address of the HDP_REG_COHERENCY_FLUSH_CNTL register
hipDeviceAttributeCooperativeMultiDeviceUnmatchedFunc, // Supports cooperative launch on multiple
// devices with unmatched functions
hipDeviceAttributeCooperativeMultiDeviceUnmatchedGridDim, // Supports cooperative launch on multiple
// devices with unmatched grid dimensions
hipDeviceAttributeCooperativeMultiDeviceUnmatchedBlockDim, // Supports cooperative launch on multiple
// devices with unmatched block dimensions
hipDeviceAttributeCooperativeMultiDeviceUnmatchedSharedMem, // Supports cooperative launch on multiple
// devices with unmatched shared memories
hipDeviceAttributeIsLargeBar, // Whether it is LargeBar
hipDeviceAttributeAsicRevision, // Revision of the GPU in this device
hipDeviceAttributeCanUseStreamWaitValue, // '1' if Device supports hipStreamWaitValue32() and
// hipStreamWaitValue64() , '0' otherwise.
hipDeviceAttributeAmdSpecificEnd = 19999,
hipDeviceAttributeVendorSpecificBegin = 20000, // Extended attributes for vendors
} hipDeviceAttribute_t;
The AMDVBFlash tool, used for flashing the VBIOS image to dGPU, does not communicate with the ROM Controller specifically when the driver is present. This is because the driver, as part of its runtime power management feature, puts the dGPU to a sleep state.
As a workaround, users can run amdgpu.runpm=0
, which temporarily disables the runtime power management feature from the driver and dynamically changes some power control-related sysfs files.
Users may encounter an issue with the enabled timestamp functionality for monitoring one or multiple counters. ROCProfiler outputs the following four timestamps for each kernel:
- Dispatch
- Start
- End
- Complete
Issue
This defect is related to the Start timestamp functionality, which incorrectly shows an earlier time than the Dispatch timestamp.
To reproduce the issue,
- Enable timing using the
--timestamp on
flag. - Use the
-i
option with the input filename that contains the name of the counter(s) to monitor. - Run the program.
- Check the output result file.
Current behavior
BeginNS is lower than DispatchNS, which is incorrect.
Expected behavior
The correct order is:
Dispatch < Start < End < Complete
Users cannot use ROCProfiler to measure the time spent on each kernel because of the incorrect timestamp with counter collection enabled.
Recommended Workaround
Users are recommended to collect kernel execution timestamps without monitoring counters, as follows:
- Enable timing using the
--timestamp on
flag, and run the application. - Rerun the application using the
-i
option with the input filename that contains the name of the counter(s) to monitor, and save this to a different output file using the-o
flag. - Check the output result file from step 1.
- The order of timestamps correctly displays as:
DispathNS < BeginNS < EndNS < CompleteNS
- Users can find the values of the collected counters in the output file generated in step 2.
System Management Interface (SMI) and ROCDebugger are not supported in the SRIOV environment on any GPU. For more information, refer to the Systems Management Interface documentation.
- The hipfft.h header is now provided only by the hipfft package. Up to ROCm 5.0, users would get hipfft.h in the rocfft package too.
- The GlobalPairwiseAMG class is now entirely removed, users should use the PairwiseAMG class instead.
- The rocsparse_spmm signature in 5.0 was changed to match that of rocsparse_spmm_ex. In 5.0, rocsparse_spmm_ex is still present, but deprecated. Signature diff for rocsparse_spmm
rocsparse_status rocsparse_spmm(rocsparse_handle handle,
rocsparse_operation trans_A,
rocsparse_operation trans_B,
const void* alpha,
const rocsparse_spmat_descr mat_A,
const rocsparse_dnmat_descr mat_B,
const void* beta,
const rocsparse_dnmat_descr mat_C,
rocsparse_datatype compute_type,
rocsparse_spmm_alg alg,
rocsparse_spmm_stage stage,
size_t* buffer_size,
void* temp_buffer);
rocsparse_status rocsparse_spmm(rocsparse_handle handle,
rocsparse_operation trans_A,
rocsparse_operation trans_B,
const void* alpha,
const rocsparse_spmat_descr mat_A,
const rocsparse_dnmat_descr mat_B,
const void* beta,
const rocsparse_dnmat_descr mat_C,
rocsparse_datatype compute_type,
rocsparse_spmm_alg alg,
size_t* buffer_size,
void* temp_buffer);
In this release, arithmetic operators of HIP complex and vector types are deprecated.
- As alternatives to arithmetic operators of HIP complex types, users can use arithmetic operators of std::complex types.
- As alternatives to arithmetic operators of HIP vector types, users can use the operators of the native clang vector type associated with the data member of HIP vector types.
During the deprecation, two macros __HIP_ENABLE_COMPLEX_OPERATORS
and __HIP_ENABLE_VECTOR_OPERATORS
are provided to allow users to conditionally enable arithmetic operators of HIP complex or vector types.
Note, the two macros are mutually exclusive and, by default, set to off.
The arithmetic operators of HIP complex and vector types will be removed in a future release.
Refer to the HIP API Guide for more information.
In prior ROCm releases, by default, the hipcc/hipconfig Perl scripts were used to identify and set target compiler options, target platform, compiler, and runtime appropriately.
In ROCm v5.0, hipcc.bin and hipconfig.bin have been added as the compiled binary implementations of the hipcc and hipconfig. These new binaries are currently a work-in-progress, considered, and marked as experimental. ROCm plans to fully transition to hipcc.bin and hipconfig.bin in the a future ROCm release. The existing hipcc and hipconfig Perl scripts are renamed to hipcc.pl and hipconfig.pl respectively. New top-level hipcc and hipconfig Perl scripts are created, which can switch between the Perl script or the compiled binary based on the environment variable HIPCC_USE_PERL_SCRIPT
.
In ROCm 5.0, by default, this environment variable is set to use hipcc and hipconfig through the Perl scripts.
Subsequently, Perl scripts will no longer be available in ROCm in a future release.
Support for loading compiler-generated code object version 4 will be deprecated in a future release with no release announcement and replaced with code object 5 as the default version.
The current default is code object version 4.
MIOpenTensile will be deprecated in a future release.
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