Files
rocm-systems/src/rocm_smi_main.cc
T
Hao Zhou be41c19d3c Revert^2 "Revert "Merge amd-staging into amd-master 20230524""
4e044a1f6c

Change-Id: Ibb44f48a8ea2099de01cf04d31b47f2a2f2473ad
2023-06-02 02:12:07 -04:00

806 lines
24 KiB
C++
Executable File

/*
* The University of Illinois/NCSA
* Open Source License (NCSA)
*
* Copyright (c) 2017-2023, Advanced Micro Devices, Inc.
* All rights reserved.
*
* Developed by:
*
* AMD Research and AMD ROC 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 <Name of Development Group, Name of Institution>,
* 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 <dirent.h>
#include <assert.h>
#include <string.h>
#include <unistd.h>
#include <sys/types.h>
#include <stdlib.h>
#include <string>
#include <cstdint>
#include <memory>
#include <fstream>
#include <vector>
#include <set>
#include <utility>
#include <functional>
#include <cerrno>
#include <unordered_map>
#include <iostream>
#include <sstream>
#include "rocm_smi/rocm_smi.h"
#include "rocm_smi/rocm_smi_device.h"
#include "rocm_smi/rocm_smi_main.h"
#include "rocm_smi/rocm_smi_exception.h"
#include "rocm_smi/rocm_smi_utils.h"
#include "rocm_smi/rocm_smi_kfd.h"
static const char *kPathDRMRoot = "/sys/class/drm";
static const char *kPathHWMonRoot = "/sys/class/hwmon";
static const char *kPathPowerRoot = "/sys/kernel/debug/dri";
static const char *kDeviceNamePrefix = "card";
static const char *kAMDMonitorTypes[] = {"radeon", "amdgpu", ""};
static const std::string amdSMI = "amd::smi::";
const std::map<amd::smi::DevInfoTypes, std::string>
amd::smi::RocmSMI::devInfoTypesStrings = {
{amd::smi::kDevPerfLevel, amdSMI + "kDevPerfLevel"},
{amd::smi::kDevOverDriveLevel, amdSMI + "kDevOverDriveLevel"},
{amd::smi::kDevMemOverDriveLevel, amdSMI + "kDevMemOverDriveLevel"},
{amd::smi::kDevDevID, amdSMI + "kDevDevID"},
{amd::smi::kDevDevProdName, amdSMI + "kDevDevProdName"},
{amd::smi::kDevDevProdNum, amdSMI + "kDevDevProdNum"},
{amd::smi::kDevVendorID, amdSMI + "kDevVendorID"},
{amd::smi::kDevSubSysDevID, amdSMI + "kDevSubSysDevID"},
{amd::smi::kDevSubSysVendorID, amdSMI + "kDevSubSysVendorID"},
{amd::smi::kDevGPUMClk, amdSMI + "kDevGPUMClk"},
{amd::smi::kDevGPUSClk, amdSMI + "kDevGPUSClk"},
{amd::smi::kDevDCEFClk, amdSMI + "kDevDCEFClk"},
{amd::smi::kDevFClk, amdSMI + "kDevFClk"},
{amd::smi::kDevSOCClk, amdSMI + "kDevSOCClk"},
{amd::smi::kDevPCIEClk, amdSMI + "kDevPCIEClk"},
{amd::smi::kDevPowerProfileMode, amdSMI + "kDevPowerProfileMode"},
{amd::smi::kDevUsage, amdSMI + "kDevUsage"},
{amd::smi::kDevPowerODVoltage, amdSMI + "kDevPowerODVoltage"},
{amd::smi::kDevVBiosVer, amdSMI + "kDevVBiosVer"},
{amd::smi::kDevPCIEThruPut, amdSMI + "kDevPCIEThruPut"},
{amd::smi::kDevErrCntSDMA, amdSMI + "kDevErrCntSDMA"},
{amd::smi::kDevErrCntUMC, amdSMI + "kDevErrCntUMC"},
{amd::smi::kDevErrCntGFX, amdSMI + "kDevErrCntGFX"},
{amd::smi::kDevErrCntMMHUB, amdSMI + "kDevErrCntMMHUB"},
{amd::smi::kDevErrCntPCIEBIF, amdSMI + "kDevErrCntPCIEBIF"},
{amd::smi::kDevErrCntHDP, amdSMI + "kDevErrCntHDP"},
{amd::smi::kDevErrCntXGMIWAFL, amdSMI + "kDevErrCntXGMIWAFL"},
{amd::smi::kDevErrCntFeatures, amdSMI + "kDevErrCntFeatures"},
{amd::smi::kDevMemTotGTT, amdSMI + "kDevMemTotGTT"},
{amd::smi::kDevMemTotVisVRAM, amdSMI + "kDevMemTotVisVRAM"},
{amd::smi::kDevMemTotVRAM, amdSMI + "kDevMemTotVRAM"},
{amd::smi::kDevMemUsedGTT, amdSMI + "kDevMemUsedGTT"},
{amd::smi::kDevMemUsedVisVRAM, amdSMI + "kDevMemUsedVisVRAM"},
{amd::smi::kDevMemUsedVRAM, amdSMI + "kDevMemUsedVRAM"},
{amd::smi::kDevVramVendor, amdSMI + "kDevVramVendor"},
{amd::smi::kDevPCIEReplayCount, amdSMI + "kDevPCIEReplayCount"},
{amd::smi::kDevUniqueId, amdSMI + "kDevUniqueId"},
{amd::smi::kDevDFCountersAvailable, amdSMI + "kDevDFCountersAvailable"},
{amd::smi::kDevMemBusyPercent, amdSMI + "kDevMemBusyPercent"},
{amd::smi::kDevXGMIError, amdSMI + "kDevXGMIError"},
{amd::smi::kDevFwVersionAsd, amdSMI + "kDevFwVersionAsd"},
{amd::smi::kDevFwVersionCe, amdSMI + "kDevFwVersionCe"},
{amd::smi::kDevFwVersionDmcu, amdSMI + "kDevFwVersionDmcu"},
{amd::smi::kDevFwVersionMc, amdSMI + "kDevFwVersionMc"},
{amd::smi::kDevFwVersionMe, amdSMI + "kDevFwVersionMe"},
{amd::smi::kDevFwVersionMec, amdSMI + "kDevFwVersionMec"},
{amd::smi::kDevFwVersionMec2, amdSMI + "kDevFwVersionMec2"},
{amd::smi::kDevFwVersionPfp, amdSMI + "kDevFwVersionPfp"},
{amd::smi::kDevFwVersionRlc, amdSMI + "kDevFwVersionRlc"},
{amd::smi::kDevFwVersionRlcSrlc, amdSMI + "kDevFwVersionRlcSrlc"},
{amd::smi::kDevFwVersionRlcSrlg, amdSMI + "kDevFwVersionRlcSrlg"},
{amd::smi::kDevFwVersionRlcSrls, amdSMI + "kDevFwVersionRlcSrls"},
{amd::smi::kDevFwVersionSdma, amdSMI + "kDevFwVersionSdma"},
{amd::smi::kDevFwVersionSdma2, amdSMI + "kDevFwVersionSdma2"},
{amd::smi::kDevFwVersionSmc, amdSMI + "kDevFwVersionSmc"},
{amd::smi::kDevFwVersionSos, amdSMI + "kDevFwVersionSos"},
{amd::smi::kDevFwVersionTaRas, amdSMI + "kDevFwVersionTaRas"},
{amd::smi::kDevFwVersionTaXgmi, amdSMI + "kDevFwVersionTaXgmi"},
{amd::smi::kDevFwVersionUvd, amdSMI + "kDevFwVersionUvd"},
{amd::smi::kDevFwVersionVce, amdSMI + "kDevFwVersionVce"},
{amd::smi::kDevFwVersionVcn, amdSMI + "kDevFwVersionVcn"},
{amd::smi::kDevSerialNumber, amdSMI + "kDevSerialNumber"},
{amd::smi::kDevMemPageBad, amdSMI + "kDevMemPageBad"},
{amd::smi::kDevNumaNode, amdSMI + "kDevNumaNode"},
{amd::smi::kDevGpuMetrics, amdSMI + "kDevGpuMetrics"},
{amd::smi::kDevGpuReset, amdSMI + "kDevGpuReset"},
{amd::smi::kDevAvailableComputePartition, amdSMI +
"kDevAvailableComputePartition"},
{amd::smi::kDevComputePartition, amdSMI + "kDevComputePartition"},
{amd::smi::kDevMemoryPartition, amdSMI + "kDevMemoryPartition"}
};
namespace amd {
namespace smi {
static uint32_t GetDeviceIndex(const std::string s) {
std::string t = s;
size_t tmp = t.find_last_not_of("0123456789");
t.erase(0, tmp+1);
assert(stoi(t) >= 0);
return static_cast<uint32_t>(stoi(t));
}
// Find the drm minor from from sysfs path "/sys/class/drm/cardX/device/drm".
// From the directory renderDN in that sysfs path, the drm minor can be
// computed for cardX.
// On success, return drm_minor which is >= 128 otherwise return 0
static uint32_t GetDrmRenderMinor(const std::string s) {
std::string drm_path = s;
int drm_minor = 0;
const std::string render_file_prefix = "renderD";
const uint64_t prefix_size = render_file_prefix.size();
drm_path += "/device/drm";
auto drm_dir = opendir(drm_path.c_str());
if (drm_dir == nullptr)
return 0;
auto dentry = readdir(drm_dir);
while (dentry != nullptr) {
std::string render_file = dentry->d_name;
if (!render_file.compare(0, prefix_size, render_file_prefix)) {
drm_minor = stoi(render_file.substr(prefix_size));
if (drm_minor)
break;
}
dentry = readdir(drm_dir);
}
if (closedir(drm_dir)) {
return 0;
}
return static_cast<uint32_t>(drm_minor);
}
// Determine if provided string is a bdfid pci path directory of the form
// XXXX:XX:XX.X,
// domain:bus:device.function
//
// where X is a hex integer (lower case is expected). If so, write the value
// to bdfid
static bool bdfid_from_path(const std::string in_name, uint64_t *bdfid) {
char *p = nullptr;
char *name_start;
char name[13] = {'\0'};
uint64_t tmp;
assert(bdfid != nullptr);
if (in_name.size() != 12) {
return false;
}
tmp = in_name.copy(name, 12);
assert(tmp == 12);
// BDFID = ((<DOMAIN> & 0xffff) << 32) | ((<BUS> & 0xff) << 8) |
// ((device& 0x1f) <<3 ) | (function & 0x7)
*bdfid = 0;
name_start = name;
p = name_start;
// Match this: XXXX:xx:xx.x
tmp = std::strtoul(p, &p, 16);
if (*p != ':' || p - name_start != 4) {
return false;
}
*bdfid |= tmp << 32;
// Match this: xxxx:XX:xx.x
p++; // Skip past ':'
tmp = std::strtoul(p, &p, 16);
if (*p != ':' || p - name_start != 7) {
return false;
}
*bdfid |= tmp << 8;
// Match this: xxxx:xx:XX.x
p++; // Skip past ':'
tmp = std::strtoul(p, &p, 16);
if (*p != '.' || p - name_start != 10) {
return false;
}
*bdfid |= tmp << 3;
// Match this: xxxx:xx:xx.X
p++; // Skip past '.'
tmp = std::strtoul(p, &p, 16);
if (*p != '\0' || p - name_start != 12) {
return false;
}
*bdfid |= tmp;
return true;
}
// 0 = successful bdfid found
// 1 = not a good bdfid found
static uint32_t ConstructBDFID(std::string path, uint64_t *bdfid) {
assert(bdfid != nullptr);
const unsigned int MAX_BDF_LENGTH = 512;
char tpath[MAX_BDF_LENGTH] = {'\0'};
ssize_t ret;
memset(tpath,0,MAX_BDF_LENGTH);
ret = readlink(path.c_str(), tpath, MAX_BDF_LENGTH);
assert(ret > 0);
assert(ret < MAX_BDF_LENGTH);
if (ret <= 0 || ret >= MAX_BDF_LENGTH) {
return 1;
}
// We are looking for the last element in the path that has the form
// XXXX:XX:XX.X, where X is a hex integer (lower case is expected)
std::size_t slash_i, end_i;
std::string tmp;
std::string tpath_str(tpath);
end_i = tpath_str.size() - 1;
while (end_i > 0) {
slash_i = tpath_str.find_last_of('/', end_i);
tmp = tpath_str.substr(slash_i + 1, end_i - slash_i);
if (bdfid_from_path(tmp, bdfid)) {
return 0;
}
end_i = slash_i - 1;
}
return 1;
}
void
RocmSMI::Initialize(uint64_t flags) {
auto i = 0;
uint32_t ret;
int i_ret;
assert(ref_count_ == 1);
if (ref_count_ != 1) {
throw amd::smi::rsmi_exception(RSMI_INITIALIZATION_ERROR,
"Unexpected: RocmSMI ref_count_ != 1");
}
init_options_ = flags;
euid_ = geteuid();
GetEnvVariables();
// To help debug env variable issues
// printEnvVarInfo();
while (env_vars_.debug_inf_loop) {}
while (std::string(kAMDMonitorTypes[i]) != "") {
amd_monitor_types_.insert(kAMDMonitorTypes[i]);
++i;
}
// DiscoverAmdgpuDevices() will search for devices and monitors and update
// internal data structures.
ret = DiscoverAmdgpuDevices();
if (ret != 0) {
throw amd::smi::rsmi_exception(RSMI_INITIALIZATION_ERROR,
"DiscoverAmdgpuDevices() failed.");
}
uint64_t bdfid;
for (uint32_t i = 0; i < devices_.size(); ++i) {
if (ConstructBDFID(devices_[i]->path(), &bdfid) != 0) {
std::cerr << "Failed to construct BDFID." << std::endl;
ret = 1;
}
devices_[i]->set_bdfid(bdfid);
}
if (ret != 0) {
throw amd::smi::rsmi_exception(RSMI_INITIALIZATION_ERROR,
"Failed to initialize rocm_smi library (amdgpu node discovery).");
}
std::map<uint64_t, std::shared_ptr<KFDNode>> tmp_map;
i_ret = DiscoverKFDNodes(&tmp_map);
if (i_ret != 0) {
throw amd::smi::rsmi_exception(RSMI_INITIALIZATION_ERROR,
"Failed to initialize rocm_smi library (KFD node discovery).");
}
std::map<std::pair<uint32_t, uint32_t>, std::shared_ptr<IOLink>>
io_link_map_tmp;
i_ret = DiscoverIOLinks(&io_link_map_tmp);
if (i_ret != 0) {
throw amd::smi::rsmi_exception(RSMI_INITIALIZATION_ERROR,
"Failed to initialize rocm_smi library (IO Links discovery).");
}
std::map<std::pair<uint32_t, uint32_t>, std::shared_ptr<IOLink>>::iterator it;
for (it = io_link_map_tmp.begin(); it != io_link_map_tmp.end(); it++)
io_link_map_[it->first] = it->second;
std::shared_ptr<amd::smi::Device> dev;
// Remove any drm nodes that don't have a corresponding readable kfd node.
// kfd nodes will not be added if their properties file is not readable.
auto dev_iter = devices_.begin();
while (dev_iter != devices_.end()) {
uint64_t bdfid = (*dev_iter)->bdfid();
if (tmp_map.find(bdfid) == tmp_map.end()) {
dev_iter = devices_.erase(dev_iter);
continue;
}
dev_iter++;
}
// 1. construct kfd_node_map_ with gpu_id as key and *Device as value
// 2. for each kfd node, write the corresponding dv_ind
// 3. for each amdgpu device, write the corresponding gpu_id
// 4. for each amdgpu device, attempt to store it's boot partition
for (uint32_t dv_ind = 0; dv_ind < devices_.size(); ++dv_ind) {
dev = devices_[dv_ind];
uint64_t bdfid = dev->bdfid();
assert(tmp_map.find(bdfid) != tmp_map.end());
if (tmp_map.find(bdfid) == tmp_map.end()) {
throw amd::smi::rsmi_exception(RSMI_INITIALIZATION_ERROR,
"amdgpu device bdfid has no KFD matching node");
}
tmp_map[bdfid]->set_amdgpu_dev_index(dv_ind);
dev_ind_to_node_ind_map_[dv_ind] = tmp_map[bdfid]->node_index();
uint64_t gpu_id = tmp_map[bdfid]->gpu_id();
dev->set_kfd_gpu_id(gpu_id);
kfd_node_map_[gpu_id] = tmp_map[bdfid];
// store each device boot partition state, if file doesn't exist
dev->storeDevicePartitions(dv_ind);
}
// Leaving below to help debug temp file issues
// displayAppTmpFilesContent();
}
void
RocmSMI::Cleanup() {
devices_.clear();
monitors_.clear();
if (kfd_notif_evt_fh() >= 0) {
int ret = close(kfd_notif_evt_fh());
if (ret < 0) {
throw amd::smi::rsmi_exception(RSMI_STATUS_FILE_ERROR,
"Failed to close kfd file handle on shutdown.");
}
}
}
RocmSMI::RocmSMI(uint64_t flags) : init_options_(flags),
kfd_notif_evt_fh_(-1), kfd_notif_evt_fh_refcnt_(0) {
}
RocmSMI::~RocmSMI() {
}
RocmSMI& RocmSMI::getInstance(uint64_t flags) {
// Assume c++11 or greater. static objects will be created by only 1 thread
// and creation will be thread-safe.
static RocmSMI singleton(flags);
return singleton;
}
static uint32_t GetEnvVarUInteger(const char *ev_str) {
#ifndef DEBUG
(void)ev_str;
#else
ev_str = getenv(ev_str);
if (ev_str) {
int ret = atoi(ev_str);
assert(ret >= 0);
return static_cast<uint32_t>(ret);
}
#endif
return 0;
}
static std::unordered_set<uint32_t> GetEnvVarUIntegerSets(const char *ev_str) {
std::unordered_set<uint32_t> returnSet;
#ifndef DEBUG
(void)ev_str;
#else
ev_str = getenv(ev_str);
if(ev_str == nullptr) { return returnSet; }
std::string stringEnv = ev_str;
if (stringEnv.empty() == false) {
// parse out values by commas
std::string parsedVal;
std::istringstream ev_str_ss(stringEnv);
while (std::getline(ev_str_ss, parsedVal, ',')) {
int parsedInt = std::stoi(parsedVal);
assert(parsedInt >= 0);
uint32_t parsedUInt = static_cast<uint32_t>(parsedInt);
returnSet.insert(parsedUInt);
}
}
#endif
return returnSet;
}
// Get and store env. variables in this method
void RocmSMI::GetEnvVariables(void) {
#ifndef DEBUG
(void)GetEnvVarUInteger(nullptr); // This is to quiet release build warning.
env_vars_.debug_output_bitfield = 0;
env_vars_.path_DRM_root_override = nullptr;
env_vars_.path_HWMon_root_override = nullptr;
env_vars_.path_power_root_override = nullptr;
env_vars_.debug_inf_loop = 0;
env_vars_.enum_overrides.clear();
#else
env_vars_.debug_output_bitfield = GetEnvVarUInteger("RSMI_DEBUG_BITFIELD");
env_vars_.path_DRM_root_override = getenv("RSMI_DEBUG_DRM_ROOT_OVERRIDE");
env_vars_.path_HWMon_root_override = getenv("RSMI_DEBUG_HWMON_ROOT_OVERRIDE");
env_vars_.path_power_root_override = getenv("RSMI_DEBUG_PP_ROOT_OVERRIDE");
env_vars_.debug_inf_loop = GetEnvVarUInteger("RSMI_DEBUG_INFINITE_LOOP");
env_vars_.enum_overrides = GetEnvVarUIntegerSets("RSMI_DEBUG_ENUM_OVERRIDE");
#endif
}
const RocmSMI_env_vars& RocmSMI::getEnv(void) {
return env_vars_;
}
void RocmSMI::printEnvVarInfo(void) {
std::cout << __PRETTY_FUNCTION__ << " | env_vars_.debug_output_bitfield = "
<< ((env_vars_.debug_output_bitfield == 0) ? "<undefined>"
: std::to_string(env_vars_.debug_output_bitfield))
<< std::endl;
std::cout << __PRETTY_FUNCTION__ << " | env_vars_.path_DRM_root_override = "
<< ((env_vars_.path_DRM_root_override == nullptr)
? "<undefined>" : env_vars_.path_DRM_root_override)
<< std::endl;
std::cout << __PRETTY_FUNCTION__ << " | env_vars_.path_HWMon_root_override = "
<< ((env_vars_.path_HWMon_root_override == nullptr)
? "<undefined>" : env_vars_.path_HWMon_root_override)
<< std::endl;
std::cout << __PRETTY_FUNCTION__ << " | env_vars_.path_power_root_override = "
<< ((env_vars_.path_power_root_override == nullptr)
? "<undefined>" : env_vars_.path_power_root_override)
<< std::endl;
std::cout << __PRETTY_FUNCTION__ << " | env_vars_.debug_inf_loop = "
<< ((env_vars_.debug_inf_loop == 0) ? "<undefined>"
: std::to_string(env_vars_.debug_output_bitfield))
<< std::endl;
std::cout << __PRETTY_FUNCTION__ << " | env_vars_.enum_overrides = {";
if (env_vars_.enum_overrides.empty()) {
std::cout << "}" << std::endl;
return;
}
for (auto it=env_vars_.enum_overrides.begin();
it != env_vars_.enum_overrides.end(); ++it) {
DevInfoTypes type = static_cast<DevInfoTypes>(*it);
std::cout << (std::to_string(*it) + " (" + devInfoTypesStrings.at(type)
+ ")");
auto temp_it = it;
if(++temp_it != env_vars_.enum_overrides.end()) {
std::cout << ", ";
}
}
std::cout << "}" << std::endl;
}
std::shared_ptr<Monitor>
RocmSMI::FindMonitor(std::string monitor_path) {
std::string tmp;
std::string err_msg;
std::string mon_name;
std::shared_ptr<Monitor> m;
if (!FileExists(monitor_path.c_str())) {
return nullptr;
}
auto mon_dir = opendir(monitor_path.c_str());
if (mon_dir == nullptr) {
return nullptr;
}
auto dentry = readdir(mon_dir);
while (dentry != nullptr) {
if (dentry->d_name[0] == '.') {
dentry = readdir(mon_dir);
continue;
}
mon_name = monitor_path;
mon_name += "/";
mon_name += dentry->d_name;
tmp = mon_name + "/name";
if (FileExists(tmp.c_str())) {
std::ifstream fs;
fs.open(tmp);
if (!fs.is_open()) {
err_msg = "Failed to open monitor file ";
err_msg += tmp;
err_msg += ".";
perror(err_msg.c_str());
return nullptr;
}
std::string mon_type;
fs >> mon_type;
fs.close();
if (amd_monitor_types_.find(mon_type) != amd_monitor_types_.end()) {
m = std::shared_ptr<Monitor>(new Monitor(mon_name, &env_vars_));
m->setTempSensorLabelMap();
m->setVoltSensorLabelMap();
break;
}
}
dentry = readdir(mon_dir);
}
if (closedir(mon_dir)) {
err_msg = "Failed to close monitor directory ";
err_msg += kPathHWMonRoot;
err_msg += ".";
perror(err_msg.c_str());
return nullptr;
}
return m;
}
void
RocmSMI::AddToDeviceList(std::string dev_name) {
auto dev_path = std::string(kPathDRMRoot);
dev_path += "/";
dev_path += dev_name;
auto dev = std::shared_ptr<Device>(new Device(dev_path, &env_vars_));
std::shared_ptr<Monitor> m = FindMonitor(dev_path + "/device/hwmon");
dev->set_monitor(m);
std::string d_name = dev_name;
uint32_t card_indx = GetDeviceIndex(d_name);
dev->set_drm_render_minor(GetDrmRenderMinor(dev_path));
dev->set_card_index(card_indx);
GetSupportedEventGroups(card_indx, dev->supported_event_groups());
devices_.push_back(dev);
return;
}
static const uint32_t kAmdGpuId = 0x1002;
static bool isAMDGPU(std::string dev_path) {
std::string vend_path = dev_path + "/device/vendor";
if (!FileExists(vend_path.c_str())) {
return false;
}
std::ifstream fs;
fs.open(vend_path);
if (!fs.is_open()) {
return false;
}
uint32_t vendor_id;
fs >> std::hex >> vendor_id;
fs.close();
if (vendor_id == kAmdGpuId) {
return true;
}
return false;
}
uint32_t RocmSMI::DiscoverAmdgpuDevices(void) {
std::string err_msg;
uint32_t count = 0;
// If this gets called more than once, clear previous findings.
devices_.clear();
monitors_.clear();
auto drm_dir = opendir(kPathDRMRoot);
if (drm_dir == nullptr) {
err_msg = "Failed to open drm root directory ";
err_msg += kPathDRMRoot;
err_msg += ".";
perror(err_msg.c_str());
return 1;
}
auto dentry = readdir(drm_dir);
while (dentry != nullptr) {
if (memcmp(dentry->d_name, kDeviceNamePrefix, strlen(kDeviceNamePrefix))
== 0) {
if ((strcmp(dentry->d_name, ".") == 0) ||
(strcmp(dentry->d_name, "..") == 0))
continue;
count++;
}
dentry = readdir(drm_dir);
}
for (uint32_t node_id = 0; node_id < count; node_id++) {
std::string path = kPathDRMRoot;
path += "/card";
path += std::to_string(node_id);
if (isAMDGPU(path) ||
(init_options_ & RSMI_INIT_FLAG_ALL_GPUS)) {
std::string d_name = "card";
d_name += std::to_string(node_id);
AddToDeviceList(d_name);
}
}
if (closedir(drm_dir)) {
err_msg = "Failed to close drm root directory ";
err_msg += kPathDRMRoot;
err_msg += ".";
perror(err_msg.c_str());
return 1;
}
return 0;
}
// Since these sysfs files require sudo access, we won't discover them
// with rsmi_init() (and thus always require the user to use "sudo".
// Instead, we will discover() all the power monitors the first time
// they are needed and then check for previous discovery on each subsequent
// call.
int RocmSMI::DiscoverAMDPowerMonitors(bool force_update) {
if (force_update) {
power_mons_.clear();
}
if (power_mons_.size() != 0) {
return 0;
}
errno = 0;
auto dri_dir = opendir(kPathPowerRoot);
if (dri_dir == nullptr) {
return errno;
}
auto dentry = readdir(dri_dir);
std::string mon_name;
std::string tmp;
while (dentry != nullptr) {
if (dentry->d_name[0] == '.') {
dentry = readdir(dri_dir);
continue;
}
mon_name = kPathPowerRoot;
mon_name += "/";
mon_name += dentry->d_name;
tmp = mon_name + "/amdgpu_pm_info";
if (FileExists(tmp.c_str())) {
std::shared_ptr<PowerMon> mon =
std::shared_ptr<PowerMon>(new PowerMon(mon_name, &env_vars_));
power_mons_.push_back(mon);
mon->set_dev_index(GetDeviceIndex(dentry->d_name));
}
dentry = readdir(dri_dir);
}
errno = 0;
if (closedir(dri_dir)) {
power_mons_.clear();
return errno;
}
for (auto m : power_mons_) {
for (auto d : devices_) {
if (m->dev_index() == d->index()) {
d->set_power_monitor(m);
break;
}
}
}
return 0;
}
uint32_t RocmSMI::IterateSMIDevices(
std::function<uint32_t(std::shared_ptr<Device>&, void *)> func, void *p) {
if (func == nullptr) {
return 1;
}
auto d = devices_.begin();
uint32_t ret;
while (d != devices_.end()) {
ret = func(*d, p);
if (ret != 0) {
return ret;
}
++d;
}
return 0;
}
int RocmSMI::get_node_index(uint32_t dv_ind, uint32_t *node_ind) {
if (dev_ind_to_node_ind_map_.find(dv_ind) == dev_ind_to_node_ind_map_.end()) {
return EINVAL;
}
*node_ind = dev_ind_to_node_ind_map_[dv_ind];
return 0;
}
int RocmSMI::get_io_link_weight(uint32_t node_from, uint32_t node_to,
uint64_t *weight) {
assert(weight != nullptr);
if (weight == nullptr) {
return EINVAL;
}
if (io_link_map_.find(std::make_pair(node_from, node_to)) ==
io_link_map_.end()) {
return EINVAL;
}
*weight = io_link_map_[std::make_pair(node_from, node_to)]->weight();
return 0;
}
} // namespace smi
} // namespace amd