Files
rocm-systems/runtime/hsa-runtime/core/runtime/amd_topology.cpp
T
Sean Keely ee8b1b64ad Report HMM driver support status.
Implements HSA_AMD_SYSTEM_INFO_SVM_SUPPORTED.

Change-Id: If5182edcc1fa067fa514aa2c1bd326c4c42d1b64
2021-04-21 21:44:42 -05:00

377 строки
13 KiB
C++

////////////////////////////////////////////////////////////////////////////////
//
// The University of Illinois/NCSA
// Open Source License (NCSA)
//
// Copyright (c) 2014-2020, Advanced Micro Devices, Inc. All rights reserved.
//
// Developed by:
//
// AMD Research and AMD HSA Software Development
//
// Advanced Micro Devices, Inc.
//
// www.amd.com
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to
// deal with 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:
//
// - Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimers.
// - Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimers in
// the documentation and/or other materials provided with the distribution.
// - Neither the names of Advanced Micro Devices, Inc,
// nor the names of its contributors may be used to endorse or promote
// products derived from this Software without specific prior written
// permission.
//
// 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 CONTRIBUTORS 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 WITH THE SOFTWARE.
//
////////////////////////////////////////////////////////////////////////////////
#include "core/inc/amd_topology.h"
#include "core/inc/amd_filter_device.h"
#include <algorithm>
#include <cstring>
#include <vector>
#include <map>
#include <string>
#include <sstream>
#ifndef NDBEUG
#include <iostream>
#endif
#include "hsakmt.h"
#include "core/inc/runtime.h"
#include "core/inc/amd_cpu_agent.h"
#include "core/inc/amd_gpu_agent.h"
#include "core/inc/amd_memory_region.h"
#include "core/util/utils.h"
namespace rocr {
namespace AMD {
// Minimum acceptable KFD version numbers
static const uint kKfdVersionMajor = 0;
static const uint kKfdVersionMinor = 99;
// Query for user preference and use that to determine Xnack mode of ROCm system.
// Return true if Xnack mode is ON or false if OFF. Xnack mode of a system is
// orthogonal to devices that do not support Xnack mode. It is legal for a
// system with Xnack ON to have devices that do not support Xnack functionality.
bool BindXnackMode() {
// Get users' preference for Xnack mode of ROCm platform
HSAint32 mode;
mode = core::Runtime::runtime_singleton_->flag().xnack();
bool config_xnack =
(core::Runtime::runtime_singleton_->flag().xnack() != Flag::XNACK_REQUEST::XNACK_UNCHANGED);
// Indicate to driver users' preference for Xnack mode
// Call to driver can fail and is a supported feature
HSAKMT_STATUS status = HSAKMT_STATUS_ERROR;
if (config_xnack) {
status = hsaKmtSetXNACKMode(mode);
if (status == HSAKMT_STATUS_SUCCESS) {
return mode;
}
}
// Get Xnack mode of devices bound by driver. This could happen
// when a call to SET Xnack mode fails or user has no particular
// preference
status = hsaKmtGetXNACKMode((HSAint32*)&mode);
if(status != HSAKMT_STATUS_SUCCESS) {
debug_print("KFD does not support xnack mode query.\nROCr must assume xnack is disabled.\n");
return false;
}
return mode;
}
CpuAgent* DiscoverCpu(HSAuint32 node_id, HsaNodeProperties& node_prop) {
if (node_prop.NumCPUCores == 0) {
return nullptr;
}
CpuAgent* cpu = new CpuAgent(node_id, node_prop);
core::Runtime::runtime_singleton_->RegisterAgent(cpu);
return cpu;
}
GpuAgent* DiscoverGpu(HSAuint32 node_id, HsaNodeProperties& node_prop, bool xnack_mode) {
GpuAgent* gpu = nullptr;
if (node_prop.NumFComputeCores == 0) {
// Ignore non GPUs.
return nullptr;
}
try {
gpu = new GpuAgent(node_id, node_prop, xnack_mode);
const HsaVersionInfo& kfd_version = core::Runtime::runtime_singleton_->KfdVersion();
// Check for sramecc incompatibility due to sramecc not being reported correctly in kfd before
// 1.4.
if (gpu->isa()->IsSrameccSupported() && (kfd_version.KernelInterfaceMajorVersion <= 1 &&
kfd_version.KernelInterfaceMinorVersion < 4)) {
// gfx906 has both sramecc modes in use. Suppress the device.
if ((gpu->isa()->GetProcessorName() == "gfx906") &&
core::Runtime::runtime_singleton_->flag().check_sramecc_validity()) {
char name[64];
gpu->GetInfo((hsa_agent_info_t)HSA_AMD_AGENT_INFO_PRODUCT_NAME, name);
name[63] = '\0';
fprintf(stderr,
"HSA Error: Incompatible kernel and userspace, %s disabled. Upgrade amdgpu.\n",
name);
delete gpu;
return nullptr;
}
// gfx908 always has sramecc set to on in vbios. Set mode bit to on and recreate the device.
if (gpu->isa()->GetProcessorName() == "gfx908") {
node_prop.Capability.ui32.SRAM_EDCSupport = 1;
delete gpu;
gpu = new GpuAgent(node_id, node_prop, xnack_mode);
}
}
} catch (const hsa_exception& e) {
if(e.error_code() == HSA_STATUS_ERROR_INVALID_ISA) {
ifdebug {
if (!strIsEmpty(e.what())) debug_print("Warning: %s\n", e.what());
}
// Ignore unrecognized GPUs.
return nullptr;
} else {
// Rethrow remaining exceptions.
throw;
}
}
core::Runtime::runtime_singleton_->RegisterAgent(gpu);
return gpu;
}
void RegisterLinkInfo(uint32_t node_id, uint32_t num_link) {
// Register connectivity links for this agent to the runtime.
if (num_link == 0) {
return;
}
std::vector<HsaIoLinkProperties> links(num_link);
if (HSAKMT_STATUS_SUCCESS !=
hsaKmtGetNodeIoLinkProperties(node_id, num_link, &links[0])) {
return;
}
for (HsaIoLinkProperties io_link : links) {
// Populate link info with thunk property.
hsa_amd_memory_pool_link_info_t link_info = {0};
switch (io_link.IoLinkType) {
case HSA_IOLINKTYPE_HYPERTRANSPORT:
link_info.link_type = HSA_AMD_LINK_INFO_TYPE_HYPERTRANSPORT;
link_info.atomic_support_32bit = true;
link_info.atomic_support_64bit = true;
link_info.coherent_support = true;
break;
case HSA_IOLINKTYPE_PCIEXPRESS:
link_info.link_type = HSA_AMD_LINK_INFO_TYPE_PCIE;
link_info.atomic_support_32bit = true;
link_info.atomic_support_64bit = true;
link_info.coherent_support = true;
break;
case HSA_IOLINK_TYPE_QPI_1_1:
link_info.link_type = HSA_AMD_LINK_INFO_TYPE_QPI;
link_info.atomic_support_32bit = true;
link_info.atomic_support_64bit = true;
link_info.coherent_support = true;
break;
case HSA_IOLINK_TYPE_INFINIBAND:
link_info.link_type = HSA_AMD_LINK_INFO_TYPE_INFINBAND;
debug_print("IOLINK is missing atomic and coherency defaults.\n");
break;
case HSA_IOLINK_TYPE_XGMI:
link_info.link_type = HSA_AMD_LINK_INFO_TYPE_XGMI;
link_info.atomic_support_32bit = true;
link_info.atomic_support_64bit = true;
link_info.coherent_support = true;
if (core::Runtime::runtime_singleton_->flag().patch_xgmi_link_weight()) {
if (io_link.Weight == 0) {
io_link.Weight = 15;
}
}
break;
default:
debug_print("Unrecognized IOLINK type.\n");
break;
}
// KFD is reporting wrong override status for XGMI. Disallow override for bringup.
if (!core::Runtime::runtime_singleton_->flag().patch_link_override()) {
if (io_link.Flags.ui32.Override == 1) {
if (io_link.Flags.ui32.NoPeerToPeerDMA == 1) {
// Ignore this link since peer to peer is not allowed.
continue;
}
link_info.atomic_support_32bit = (io_link.Flags.ui32.NoAtomics32bit == 0);
link_info.atomic_support_64bit = (io_link.Flags.ui32.NoAtomics64bit == 0);
link_info.coherent_support = (io_link.Flags.ui32.NonCoherent == 0);
}
}
link_info.max_bandwidth = io_link.MaximumBandwidth;
link_info.max_latency = io_link.MaximumLatency;
link_info.min_bandwidth = io_link.MinimumBandwidth;
link_info.min_latency = io_link.MinimumLatency;
link_info.numa_distance = io_link.Weight;
core::Runtime::runtime_singleton_->RegisterLinkInfo(
io_link.NodeFrom, io_link.NodeTo, io_link.Weight, link_info);
}
}
/**
* Process the list of Gpus that are surfaced to user
*/
static void SurfaceGpuList(std::vector<int32_t>& gpu_list, bool xnack_mode) {
// Process user visible Gpu devices
int32_t invalidIdx = -1;
int32_t list_sz = gpu_list.size();
HsaNodeProperties node_prop = {0};
for (int32_t idx = 0; idx < list_sz; idx++) {
if (gpu_list[idx] == invalidIdx) {
break;
}
// Obtain properties of the node
HSAKMT_STATUS err_val = hsaKmtGetNodeProperties(gpu_list[idx], &node_prop);
assert(err_val == HSAKMT_STATUS_SUCCESS && "Error in getting Node Properties");
// Instantiate a Gpu device. The IO links
// of this node have already been registered
assert((node_prop.NumFComputeCores != 0) && "Improper node used for GPU device discovery.");
DiscoverGpu(gpu_list[idx], node_prop, xnack_mode);
}
}
/// @brief Calls Kfd thunk to get the snapshot of the topology of the system,
/// which includes associations between, node, devices, memory and caches.
void BuildTopology() {
HsaVersionInfo kfd_version;
if (hsaKmtGetVersion(&kfd_version) != HSAKMT_STATUS_SUCCESS) {
return;
}
if (kfd_version.KernelInterfaceMajorVersion == kKfdVersionMajor &&
kfd_version.KernelInterfaceMinorVersion < kKfdVersionMinor) {
return;
}
// Disable KFD event support when using open source KFD
if (kfd_version.KernelInterfaceMajorVersion == 1 &&
kfd_version.KernelInterfaceMinorVersion == 0) {
core::g_use_interrupt_wait = false;
}
core::Runtime::runtime_singleton_->KfdVersion(kfd_version);
HsaSystemProperties props;
hsaKmtReleaseSystemProperties();
if (hsaKmtAcquireSystemProperties(&props) != HSAKMT_STATUS_SUCCESS) {
return;
}
core::Runtime::runtime_singleton_->SetLinkCount(props.NumNodes);
// Query if env ROCR_VISIBLE_DEVICES is defined. If defined
// determine number and order of GPU devices to be surfaced
RvdFilter rvdFilter;
int32_t invalidIdx = -1;
uint32_t visibleCnt = 0;
std::vector<int32_t> gpu_usr_list;
bool filter = RvdFilter::FilterDevices();
if (filter) {
rvdFilter.BuildRvdTokenList();
rvdFilter.BuildDeviceUuidList(props.NumNodes);
visibleCnt = rvdFilter.BuildUsrDeviceList();
for (int32_t idx = 0; idx < visibleCnt; idx++) {
gpu_usr_list.push_back(invalidIdx);
}
}
// Discover agents on every node in the platform.
int32_t kfdIdx = 0;
for (HSAuint32 node_id = 0; node_id < props.NumNodes; node_id++) {
HsaNodeProperties node_prop = {0};
if (hsaKmtGetNodeProperties(node_id, &node_prop) != HSAKMT_STATUS_SUCCESS) {
continue;
}
// Instantiate a Cpu device
const CpuAgent* cpu = DiscoverCpu(node_id, node_prop);
assert(((node_prop.NumCPUCores == 0) || (cpu != nullptr)) && "CPU device failed discovery.");
// Current node is either a dGpu or Apu and might belong
// to user visible list. Process node if present in usr
// visible list, continue if not found
if (node_prop.NumFComputeCores != 0) {
if (filter) {
int32_t devRank = rvdFilter.GetUsrDeviceRank(kfdIdx);
if (devRank != (-1)) {
gpu_usr_list[devRank] = node_id;
}
} else {
gpu_usr_list.push_back(node_id);
}
kfdIdx++;
}
// Register IO links of node without regard to
// it being visible to user or not. It is not
// possible to access links of nodes that are
// not visible
RegisterLinkInfo(node_id, node_prop.NumIOLinks);
}
// Determine the Xnack mode to be bound for system
bool xnack_mode = BindXnackMode();
// Instantiate ROCr objects to encapsulate Gpu devices
SurfaceGpuList(gpu_usr_list, xnack_mode);
}
bool Load() {
// Open connection to kernel driver.
if (hsaKmtOpenKFD() != HSAKMT_STATUS_SUCCESS) {
return false;
}
// Build topology table.
BuildTopology();
return true;
}
bool Unload() {
hsaKmtReleaseSystemProperties();
// Close connection to kernel driver.
hsaKmtCloseKFD();
return true;
}
} // namespace amd
} // namespace rocr