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rocm-systems/libhsakmt/src/memory.c
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Philip Yang 6e6f445f75 libhsakmt: Update contiguous memory support ioctl version
KFD ioctl version is 1.16 on upstream for contiguous memory support.

Remove pc_sampling version, should be added after pc_sample upstream.

Change-Id: I6e6c3340bc8e371d68dd7741b02578be2fdef801
Signed-off-by: Philip Yang <Philip.Yang@amd.com>
Signed-off-by: Chris Freehill <cfreehil@amd.com>
2024-06-24 14:26:21 -05:00

668 linhas
18 KiB
C

/*
* Copyright © 2014 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 (including
* the next paragraph) 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 "libhsakmt.h"
#include "hsakmt/linux/kfd_ioctl.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include <sys/types.h>
#include <sys/mman.h>
#include <fcntl.h>
#include "fmm.h"
HSAKMT_STATUS HSAKMTAPI hsaKmtSetMemoryPolicy(HSAuint32 Node,
HSAuint32 DefaultPolicy,
HSAuint32 AlternatePolicy,
void *MemoryAddressAlternate,
HSAuint64 MemorySizeInBytes)
{
struct kfd_ioctl_set_memory_policy_args args = {0};
HSAKMT_STATUS result;
uint32_t gpu_id;
CHECK_KFD_OPEN();
pr_debug("[%s] node %d; default %d; alternate %d\n",
__func__, Node, DefaultPolicy, AlternatePolicy);
result = validate_nodeid(Node, &gpu_id);
if (result != HSAKMT_STATUS_SUCCESS)
return result;
if (get_gfxv_by_node_id(Node) != GFX_VERSION_KAVERI)
/* This is a legacy API useful on Kaveri only. On dGPU
* the alternate aperture is setup and used
* automatically for coherent allocations. Don't let
* app override it.
*/
return HSAKMT_STATUS_NOT_IMPLEMENTED;
/*
* We accept any legal policy and alternate address location.
* You get CC everywhere anyway.
*/
if ((DefaultPolicy != HSA_CACHING_CACHED &&
DefaultPolicy != HSA_CACHING_NONCACHED) ||
(AlternatePolicy != HSA_CACHING_CACHED &&
AlternatePolicy != HSA_CACHING_NONCACHED))
return HSAKMT_STATUS_INVALID_PARAMETER;
CHECK_PAGE_MULTIPLE(MemoryAddressAlternate);
CHECK_PAGE_MULTIPLE(MemorySizeInBytes);
args.gpu_id = gpu_id;
args.default_policy = (DefaultPolicy == HSA_CACHING_CACHED) ?
KFD_IOC_CACHE_POLICY_COHERENT :
KFD_IOC_CACHE_POLICY_NONCOHERENT;
args.alternate_policy = (AlternatePolicy == HSA_CACHING_CACHED) ?
KFD_IOC_CACHE_POLICY_COHERENT :
KFD_IOC_CACHE_POLICY_NONCOHERENT;
args.alternate_aperture_base = (uintptr_t) MemoryAddressAlternate;
args.alternate_aperture_size = MemorySizeInBytes;
int err = kmtIoctl(kfd_fd, AMDKFD_IOC_SET_MEMORY_POLICY, &args);
return (err == -1) ? HSAKMT_STATUS_ERROR : HSAKMT_STATUS_SUCCESS;
}
HSAuint32 PageSizeFromFlags(unsigned int pageSizeFlags)
{
switch (pageSizeFlags) {
case HSA_PAGE_SIZE_4KB: return 4*1024;
case HSA_PAGE_SIZE_64KB: return 64*1024;
case HSA_PAGE_SIZE_2MB: return 2*1024*1024;
case HSA_PAGE_SIZE_1GB: return 1024*1024*1024;
default:
assert(false);
return 4*1024;
}
}
HSAKMT_STATUS HSAKMTAPI hsaKmtAllocMemory(HSAuint32 PreferredNode,
HSAuint64 SizeInBytes,
HsaMemFlags MemFlags,
void **MemoryAddress)
{
return hsaKmtAllocMemoryAlign(PreferredNode, SizeInBytes, 0, MemFlags, MemoryAddress);
}
#define POWER_OF_2(x) ((x && (!(x & (x - 1)))) ? 1 : 0)
HSAKMT_STATUS HSAKMTAPI hsaKmtAllocMemoryAlign(HSAuint32 PreferredNode,
HSAuint64 SizeInBytes,
HSAuint64 Alignment,
HsaMemFlags MemFlags,
void **MemoryAddress)
{
HSAKMT_STATUS result;
uint32_t gpu_id;
HSAuint64 page_size;
CHECK_KFD_OPEN();
if (MemFlags.ui32.Contiguous)
CHECK_KFD_MINOR_VERSION(16);
pr_debug("[%s] node %d\n", __func__, PreferredNode);
result = validate_nodeid(PreferredNode, &gpu_id);
if (result != HSAKMT_STATUS_SUCCESS) {
pr_err("[%s] invalid node ID: %d\n", __func__, PreferredNode);
return result;
}
page_size = PageSizeFromFlags(MemFlags.ui32.PageSize);
if (Alignment && (Alignment < page_size || !POWER_OF_2(Alignment)))
return HSAKMT_STATUS_INVALID_PARAMETER;
if (!MemoryAddress || !SizeInBytes || (SizeInBytes & (page_size-1)))
return HSAKMT_STATUS_INVALID_PARAMETER;
if (MemFlags.ui32.FixedAddress) {
if (*MemoryAddress == NULL)
return HSAKMT_STATUS_INVALID_PARAMETER;
} else
*MemoryAddress = NULL;
if ((MemFlags.ui32.CoarseGrain && MemFlags.ui32.ExtendedCoherent) ||
(MemFlags.ui32.CoarseGrain && MemFlags.ui32.Uncached) ||
(MemFlags.ui32.ExtendedCoherent && MemFlags.ui32.Uncached))
return HSAKMT_STATUS_INVALID_PARAMETER;
if (MemFlags.ui32.Scratch) {
if (Alignment) {
// Scratch memory currently forced to SCRATCH_ALIGN
pr_err("[%s] Alignment not supported for scratch memory: %d\n", __func__, PreferredNode);
return HSAKMT_STATUS_NOT_IMPLEMENTED;
}
*MemoryAddress = fmm_allocate_scratch(gpu_id, *MemoryAddress, SizeInBytes);
if (!(*MemoryAddress)) {
pr_err("[%s] failed to allocate %lu bytes from scratch\n",
__func__, SizeInBytes);
return HSAKMT_STATUS_NO_MEMORY;
}
return HSAKMT_STATUS_SUCCESS;
}
/* GPU allocated system memory */
if (!gpu_id || !MemFlags.ui32.NonPaged || zfb_support || MemFlags.ui32.GTTAccess) {
/* Backwards compatibility hack: Allocate system memory if app
* asks for paged memory from a GPU node.
*/
/* If allocate VRAM under ZFB mode */
if (zfb_support && gpu_id && MemFlags.ui32.NonPaged == 1)
MemFlags.ui32.CoarseGrain = 1;
*MemoryAddress = fmm_allocate_host(gpu_id, MemFlags.ui32.GTTAccess ? 0 : PreferredNode,
*MemoryAddress, SizeInBytes, Alignment, MemFlags);
if (!(*MemoryAddress)) {
pr_err("[%s] failed to allocate %lu bytes from host\n",
__func__, SizeInBytes);
return HSAKMT_STATUS_ERROR;
}
return HSAKMT_STATUS_SUCCESS;
}
/* GPU allocated VRAM */
/* sanity check cannot do OnlyAddress and NoAddress alloc at same time */
if (MemFlags.ui32.OnlyAddress && MemFlags.ui32.NoAddress) {
pr_err("[%s] allocate addr-only and memory-only at same time\n",
__func__);
return HSAKMT_STATUS_INVALID_PARAMETER;
}
*MemoryAddress = fmm_allocate_device(gpu_id, PreferredNode, *MemoryAddress,
SizeInBytes, Alignment, MemFlags);
if (!(*MemoryAddress)) {
pr_err("[%s] failed to allocate %lu bytes from device\n",
__func__, SizeInBytes);
return HSAKMT_STATUS_NO_MEMORY;
}
return HSAKMT_STATUS_SUCCESS;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtFreeMemory(void *MemoryAddress,
HSAuint64 SizeInBytes)
{
CHECK_KFD_OPEN();
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
if (!MemoryAddress) {
pr_err("FIXME: freeing NULL pointer\n");
return HSAKMT_STATUS_ERROR;
}
return fmm_release(MemoryAddress);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtAvailableMemory(HSAuint32 Node,
HSAuint64 *AvailableBytes)
{
struct kfd_ioctl_get_available_memory_args args = {};
HSAKMT_STATUS result;
CHECK_KFD_OPEN();
CHECK_KFD_MINOR_VERSION(9);
pr_debug("[%s] node %d\n", __func__, Node);
result = validate_nodeid(Node, &args.gpu_id);
if (result != HSAKMT_STATUS_SUCCESS) {
pr_err("[%s] invalid node ID: %d\n", __func__, Node);
return result;
}
if (kmtIoctl(kfd_fd, AMDKFD_IOC_AVAILABLE_MEMORY, &args))
return HSAKMT_STATUS_ERROR;
*AvailableBytes = args.available;
return HSAKMT_STATUS_SUCCESS;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtRegisterMemory(void *MemoryAddress,
HSAuint64 MemorySizeInBytes)
{
CHECK_KFD_OPEN();
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
if (!is_dgpu)
/* TODO: support mixed APU and dGPU configurations */
return HSAKMT_STATUS_SUCCESS;
return fmm_register_memory(MemoryAddress, MemorySizeInBytes,
NULL, 0, true, false);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtRegisterMemoryToNodes(void *MemoryAddress,
HSAuint64 MemorySizeInBytes,
HSAuint64 NumberOfNodes,
HSAuint32 *NodeArray)
{
CHECK_KFD_OPEN();
uint32_t *gpu_id_array;
HSAKMT_STATUS ret = HSAKMT_STATUS_SUCCESS;
pr_debug("[%s] address %p number of nodes %lu\n",
__func__, MemoryAddress, NumberOfNodes);
if (!is_dgpu)
/* TODO: support mixed APU and dGPU configurations */
return HSAKMT_STATUS_NOT_SUPPORTED;
ret = validate_nodeid_array(&gpu_id_array,
NumberOfNodes, NodeArray);
if (ret == HSAKMT_STATUS_SUCCESS) {
ret = fmm_register_memory(MemoryAddress, MemorySizeInBytes,
gpu_id_array,
NumberOfNodes*sizeof(uint32_t),
true, false);
if (ret != HSAKMT_STATUS_SUCCESS)
free(gpu_id_array);
}
return ret;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtRegisterMemoryWithFlags(void *MemoryAddress,
HSAuint64 MemorySizeInBytes,
HsaMemFlags MemFlags)
{
CHECK_KFD_OPEN();
HSAKMT_STATUS ret = HSAKMT_STATUS_SUCCESS;
pr_debug("[%s] address %p\n",
__func__, MemoryAddress);
if (MemFlags.ui32.ExtendedCoherent && MemFlags.ui32.CoarseGrain)
return HSAKMT_STATUS_INVALID_PARAMETER;
// Registered memory should be ordinary paged host memory.
if ((MemFlags.ui32.HostAccess != 1) || (MemFlags.ui32.NonPaged == 1))
return HSAKMT_STATUS_NOT_SUPPORTED;
if (!is_dgpu)
/* TODO: support mixed APU and dGPU configurations */
return HSAKMT_STATUS_NOT_SUPPORTED;
ret = fmm_register_memory(MemoryAddress, MemorySizeInBytes,
NULL, 0, MemFlags.ui32.CoarseGrain, MemFlags.ui32.ExtendedCoherent);
return ret;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtRegisterGraphicsHandleToNodes(HSAuint64 GraphicsResourceHandle,
HsaGraphicsResourceInfo *GraphicsResourceInfo,
HSAuint64 NumberOfNodes,
HSAuint32 *NodeArray)
{
CHECK_KFD_OPEN();
uint32_t *gpu_id_array = NULL;
HSAKMT_STATUS ret = HSAKMT_STATUS_SUCCESS;
pr_debug("[%s] number of nodes %lu\n", __func__, NumberOfNodes);
if (NodeArray != NULL || NumberOfNodes != 0) {
ret = validate_nodeid_array(&gpu_id_array,
NumberOfNodes, NodeArray);
}
if (ret == HSAKMT_STATUS_SUCCESS) {
ret = fmm_register_graphics_handle(
GraphicsResourceHandle, GraphicsResourceInfo,
gpu_id_array, NumberOfNodes * sizeof(uint32_t));
if (ret != HSAKMT_STATUS_SUCCESS)
free(gpu_id_array);
}
return ret;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtExportDMABufHandle(void *MemoryAddress,
HSAuint64 MemorySizeInBytes,
int *DMABufFd,
HSAuint64 *Offset)
{
CHECK_KFD_OPEN();
CHECK_KFD_MINOR_VERSION(12);
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
return fmm_export_dma_buf_fd(MemoryAddress, MemorySizeInBytes,
DMABufFd, Offset);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtShareMemory(void *MemoryAddress,
HSAuint64 SizeInBytes,
HsaSharedMemoryHandle *SharedMemoryHandle)
{
CHECK_KFD_OPEN();
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
if (!SharedMemoryHandle)
return HSAKMT_STATUS_INVALID_PARAMETER;
return fmm_share_memory(MemoryAddress, SizeInBytes, SharedMemoryHandle);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtRegisterSharedHandle(const HsaSharedMemoryHandle *SharedMemoryHandle,
void **MemoryAddress,
HSAuint64 *SizeInBytes)
{
CHECK_KFD_OPEN();
pr_debug("[%s] handle %p\n", __func__, SharedMemoryHandle);
return hsaKmtRegisterSharedHandleToNodes(SharedMemoryHandle,
MemoryAddress,
SizeInBytes,
0,
NULL);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtRegisterSharedHandleToNodes(const HsaSharedMemoryHandle *SharedMemoryHandle,
void **MemoryAddress,
HSAuint64 *SizeInBytes,
HSAuint64 NumberOfNodes,
HSAuint32 *NodeArray)
{
CHECK_KFD_OPEN();
uint32_t *gpu_id_array = NULL;
HSAKMT_STATUS ret = HSAKMT_STATUS_SUCCESS;
pr_debug("[%s] handle %p number of nodes %lu\n",
__func__, SharedMemoryHandle, NumberOfNodes);
if (!SharedMemoryHandle)
return HSAKMT_STATUS_INVALID_PARAMETER;
if (NodeArray) {
ret = validate_nodeid_array(&gpu_id_array, NumberOfNodes, NodeArray);
if (ret != HSAKMT_STATUS_SUCCESS)
goto error;
}
ret = fmm_register_shared_memory(SharedMemoryHandle,
SizeInBytes,
MemoryAddress,
gpu_id_array,
NumberOfNodes*sizeof(uint32_t));
if (ret != HSAKMT_STATUS_SUCCESS)
goto error;
return ret;
error:
if (gpu_id_array)
free(gpu_id_array);
return ret;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtProcessVMRead(HSAuint32 Pid,
HsaMemoryRange *LocalMemoryArray,
HSAuint64 LocalMemoryArrayCount,
HsaMemoryRange *RemoteMemoryArray,
HSAuint64 RemoteMemoryArrayCount,
HSAuint64 *SizeCopied)
{
pr_err("[%s] Deprecated\n", __func__);
return HSAKMT_STATUS_NOT_IMPLEMENTED;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtProcessVMWrite(HSAuint32 Pid,
HsaMemoryRange *LocalMemoryArray,
HSAuint64 LocalMemoryArrayCount,
HsaMemoryRange *RemoteMemoryArray,
HSAuint64 RemoteMemoryArrayCount,
HSAuint64 *SizeCopied)
{
pr_err("[%s] Deprecated\n", __func__);
return HSAKMT_STATUS_NOT_IMPLEMENTED;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtDeregisterMemory(void *MemoryAddress)
{
CHECK_KFD_OPEN();
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
return fmm_deregister_memory(MemoryAddress);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtMapMemoryToGPU(void *MemoryAddress,
HSAuint64 MemorySizeInBytes,
HSAuint64 *AlternateVAGPU)
{
CHECK_KFD_OPEN();
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
if (!MemoryAddress) {
pr_err("FIXME: mapping NULL pointer\n");
return HSAKMT_STATUS_ERROR;
}
if (AlternateVAGPU)
*AlternateVAGPU = 0;
return fmm_map_to_gpu(MemoryAddress, MemorySizeInBytes, AlternateVAGPU);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtMapMemoryToGPUNodes(void *MemoryAddress,
HSAuint64 MemorySizeInBytes,
HSAuint64 *AlternateVAGPU,
HsaMemMapFlags MemMapFlags,
HSAuint64 NumberOfNodes,
HSAuint32 *NodeArray)
{
uint32_t *gpu_id_array;
HSAKMT_STATUS ret;
CHECK_KFD_OPEN();
pr_debug("[%s] address %p number of nodes %lu\n",
__func__, MemoryAddress, NumberOfNodes);
if (!MemoryAddress) {
pr_err("FIXME: mapping NULL pointer\n");
return HSAKMT_STATUS_ERROR;
}
if (!is_dgpu && NumberOfNodes == 1)
return hsaKmtMapMemoryToGPU(MemoryAddress,
MemorySizeInBytes,
AlternateVAGPU);
ret = validate_nodeid_array(&gpu_id_array,
NumberOfNodes, NodeArray);
if (ret != HSAKMT_STATUS_SUCCESS)
return ret;
ret = fmm_map_to_gpu_nodes(MemoryAddress, MemorySizeInBytes,
gpu_id_array, NumberOfNodes, AlternateVAGPU);
if (gpu_id_array)
free(gpu_id_array);
return ret;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtUnmapMemoryToGPU(void *MemoryAddress)
{
CHECK_KFD_OPEN();
pr_debug("[%s] address %p\n", __func__, MemoryAddress);
if (!MemoryAddress) {
/* Workaround for runtime bug */
pr_err("FIXME: Unmapping NULL pointer\n");
return HSAKMT_STATUS_SUCCESS;
}
if (!fmm_unmap_from_gpu(MemoryAddress))
return HSAKMT_STATUS_SUCCESS;
else
return HSAKMT_STATUS_ERROR;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtMapGraphicHandle(HSAuint32 NodeId,
HSAuint64 GraphicDeviceHandle,
HSAuint64 GraphicResourceHandle,
HSAuint64 GraphicResourceOffset,
HSAuint64 GraphicResourceSize,
HSAuint64 *FlatMemoryAddress)
{
/* This API was only ever implemented in KFD for Kaveri and
* was never upstreamed. There are no open-source users of
* this interface. It has been superseded by
* RegisterGraphicsHandleToNodes.
*/
return HSAKMT_STATUS_NOT_IMPLEMENTED;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtUnmapGraphicHandle(HSAuint32 NodeId,
HSAuint64 FlatMemoryAddress,
HSAuint64 SizeInBytes)
{
CHECK_KFD_OPEN();
return hsaKmtUnmapMemoryToGPU(PORT_UINT64_TO_VPTR(FlatMemoryAddress));
}
HSAKMT_STATUS HSAKMTAPI hsaKmtGetTileConfig(HSAuint32 NodeId, HsaGpuTileConfig *config)
{
struct kfd_ioctl_get_tile_config_args args = {0};
uint32_t gpu_id;
HSAKMT_STATUS result;
CHECK_KFD_OPEN();
pr_debug("[%s] node %d\n", __func__, NodeId);
result = validate_nodeid(NodeId, &gpu_id);
if (result != HSAKMT_STATUS_SUCCESS)
return result;
/* Avoid Valgrind warnings about uninitialized data. Valgrind doesn't
* know that KFD writes this.
*/
memset(config->TileConfig, 0, sizeof(*config->TileConfig) * config->NumTileConfigs);
memset(config->MacroTileConfig, 0, sizeof(*config->MacroTileConfig) * config->NumMacroTileConfigs);
args.gpu_id = gpu_id;
args.tile_config_ptr = (uint64_t)config->TileConfig;
args.macro_tile_config_ptr = (uint64_t)config->MacroTileConfig;
args.num_tile_configs = config->NumTileConfigs;
args.num_macro_tile_configs = config->NumMacroTileConfigs;
if (kmtIoctl(kfd_fd, AMDKFD_IOC_GET_TILE_CONFIG, &args) != 0)
return HSAKMT_STATUS_ERROR;
config->NumTileConfigs = args.num_tile_configs;
config->NumMacroTileConfigs = args.num_macro_tile_configs;
config->GbAddrConfig = args.gb_addr_config;
config->NumBanks = args.num_banks;
config->NumRanks = args.num_ranks;
return HSAKMT_STATUS_SUCCESS;
}
HSAKMT_STATUS HSAKMTAPI hsaKmtQueryPointerInfo(const void *Pointer,
HsaPointerInfo *PointerInfo)
{
CHECK_KFD_OPEN();
pr_debug("[%s] pointer %p\n", __func__, Pointer);
if (!PointerInfo)
return HSAKMT_STATUS_INVALID_PARAMETER;
return fmm_get_mem_info(Pointer, PointerInfo);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtSetMemoryUserData(const void *Pointer,
void *UserData)
{
CHECK_KFD_OPEN();
pr_debug("[%s] pointer %p\n", __func__, Pointer);
return fmm_set_mem_user_data(Pointer, UserData);
}
HSAKMT_STATUS HSAKMTAPI hsaKmtReplaceAsanHeaderPage(void *addr)
{
#ifdef SANITIZER_AMDGPU
pr_debug("[%s] address %p\n", __func__, addr);
CHECK_KFD_OPEN();
return fmm_replace_asan_header_page(addr);
#else
return HSAKMT_STATUS_NOT_SUPPORTED;
#endif
}
HSAKMT_STATUS HSAKMTAPI hsaKmtReturnAsanHeaderPage(void *addr)
{
#ifdef SANITIZER_AMDGPU
pr_debug("[%s] address %p\n", __func__, addr);
CHECK_KFD_OPEN();
return fmm_return_asan_header_page(addr);
#else
return HSAKMT_STATUS_NOT_SUPPORTED;
#endif
}
HSAKMT_STATUS HSAKMTAPI hsaKmtGetAMDGPUDeviceHandle( HSAuint32 NodeId,
HsaAMDGPUDeviceHandle *DeviceHandle)
{
CHECK_KFD_OPEN();
return fmm_get_amdgpu_device_handle(NodeId, DeviceHandle);
}