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drm_neo.cpp
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/*
* Copyright (C) 2018-2025 Intel Corporation
*
* SPDX-License-Identifier: MIT
*
*/
#include "shared/source/os_interface/linux/drm_neo.h"
#include "shared/source/command_stream/submission_status.h"
#include "shared/source/debug_settings/debug_settings_manager.h"
#include "shared/source/execution_environment/execution_environment.h"
#include "shared/source/execution_environment/root_device_environment.h"
#include "shared/source/gmm_helper/cache_settings_helper.h"
#include "shared/source/gmm_helper/client_context/gmm_client_context.h"
#include "shared/source/gmm_helper/gmm.h"
#include "shared/source/gmm_helper/resource_info.h"
#include "shared/source/helpers/basic_math.h"
#include "shared/source/helpers/constants.h"
#include "shared/source/helpers/debug_helpers.h"
#include "shared/source/helpers/gfx_core_helper.h"
#include "shared/source/helpers/gpu_page_fault_helper.h"
#include "shared/source/helpers/hw_info.h"
#include "shared/source/helpers/ptr_math.h"
#include "shared/source/os_interface/driver_info.h"
#include "shared/source/os_interface/linux/cache_info.h"
#include "shared/source/os_interface/linux/drm_buffer_object.h"
#include "shared/source/os_interface/linux/drm_engine_mapper.h"
#include "shared/source/os_interface/linux/drm_gem_close_worker.h"
#include "shared/source/os_interface/linux/drm_memory_manager.h"
#include "shared/source/os_interface/linux/drm_memory_operations_handler_bind.h"
#include "shared/source/os_interface/linux/drm_wrappers.h"
#include "shared/source/os_interface/linux/engine_info.h"
#include "shared/source/os_interface/linux/hw_device_id.h"
#include "shared/source/os_interface/linux/ioctl_helper.h"
#include "shared/source/os_interface/linux/memory_info.h"
#include "shared/source/os_interface/linux/os_context_linux.h"
#include "shared/source/os_interface/linux/os_inc.h"
#include "shared/source/os_interface/linux/pci_path.h"
#include "shared/source/os_interface/linux/sys_calls.h"
#include "shared/source/os_interface/linux/system_info.h"
#include "shared/source/os_interface/linux/xe/ioctl_helper_xe.h"
#include "shared/source/os_interface/os_environment.h"
#include "shared/source/os_interface/os_interface.h"
#include "shared/source/os_interface/product_helper.h"
#include "shared/source/release_helper/release_helper.h"
#include "shared/source/utilities/api_intercept.h"
#include "shared/source/utilities/directory.h"
#include "shared/source/utilities/io_functions.h"
#include <cstdio>
#include <cstring>
#include <fcntl.h>
#include <fstream>
#include <map>
#include <sstream>
namespace NEO {
Drm::Drm(std::unique_ptr<HwDeviceIdDrm> &&hwDeviceIdIn, RootDeviceEnvironment &rootDeviceEnvironment)
: DriverModel(DriverModelType::drm),
hwDeviceId(std::move(hwDeviceIdIn)), rootDeviceEnvironment(rootDeviceEnvironment) {
pagingFence.fill(0u);
fenceVal.fill(0u);
}
SubmissionStatus Drm::getSubmissionStatusFromReturnCode(int32_t retCode) {
switch (retCode) {
case 0:
return SubmissionStatus::success;
case EWOULDBLOCK:
case ENOMEM:
case ENOSPC:
return SubmissionStatus::outOfHostMemory;
case ENXIO:
return SubmissionStatus::outOfMemory;
default:
return SubmissionStatus::failed;
}
}
void Drm::queryAndSetVmBindPatIndexProgrammingSupport() {
auto &productHelper = rootDeviceEnvironment.getHelper<ProductHelper>();
this->vmBindPatIndexProgrammingSupported = productHelper.isVmBindPatIndexProgrammingSupported();
}
int Drm::ioctl(DrmIoctl request, void *arg) {
auto requestValue = getIoctlRequestValue(request, ioctlHelper.get());
int ret;
int returnedErrno = 0;
SYSTEM_ENTER();
do {
auto measureTime = debugManager.flags.PrintKmdTimes.get();
std::chrono::steady_clock::time_point start;
std::chrono::steady_clock::time_point end;
auto printIoctl = debugManager.flags.PrintIoctlEntries.get();
if (printIoctl) {
printf("IOCTL %s called\n", ioctlHelper->getIoctlString(request).c_str());
}
if (measureTime) {
start = std::chrono::steady_clock::now();
}
ret = SysCalls::ioctl(getFileDescriptor(), requestValue, arg);
if (ret != 0) {
returnedErrno = getErrno();
}
if (measureTime) {
end = std::chrono::steady_clock::now();
long long elapsedTime = std::chrono::duration_cast<std::chrono::nanoseconds>(end - start).count();
IoctlStatisticsEntry ioctlData{};
auto ioctlDataIt = this->ioctlStatistics.find(request);
if (ioctlDataIt != this->ioctlStatistics.end()) {
ioctlData = ioctlDataIt->second;
}
ioctlData.totalTime += elapsedTime;
ioctlData.count++;
ioctlData.minTime = std::min(ioctlData.minTime, elapsedTime);
ioctlData.maxTime = std::max(ioctlData.maxTime, elapsedTime);
this->ioctlStatistics[request] = ioctlData;
}
if (printIoctl) {
if (ret == 0) {
printf("IOCTL %s returns %d\n",
ioctlHelper->getIoctlString(request).c_str(), ret);
} else {
printf("IOCTL %s returns %d, errno %d(%s)\n",
ioctlHelper->getIoctlString(request).c_str(), ret, returnedErrno, strerror(returnedErrno));
}
}
} while (ret == -1 && checkIfIoctlReinvokeRequired(returnedErrno, request, ioctlHelper.get()));
SYSTEM_LEAVE(request);
return ret;
}
int Drm::getParamIoctl(DrmParam param, int *dstValue) {
GetParam getParam{};
getParam.param = ioctlHelper->getDrmParamValue(param);
getParam.value = dstValue;
int retVal = ioctlHelper->ioctl(DrmIoctl::getparam, &getParam);
if (debugManager.flags.PrintIoctlEntries.get()) {
printf("DRM_IOCTL_I915_GETPARAM: param: %s, output value: %d, retCode:% d\n",
ioctlHelper->getDrmParamString(param).c_str(),
*getParam.value,
retVal);
}
return retVal;
}
int Drm::enableTurboBoost() {
GemContextParam contextParam = {};
contextParam.param = contextPrivateParamBoost;
contextParam.value = 1;
return ioctlHelper->ioctl(DrmIoctl::gemContextSetparam, &contextParam);
}
int Drm::getEnabledPooledEu(int &enabled) {
return getParamIoctl(DrmParam::paramHasPooledEu, &enabled);
}
std::string Drm::getSysFsPciPath() {
std::string path = std::string(Os::sysFsPciPathPrefix) + hwDeviceId->getPciPath() + "/drm";
std::string expectedFilePrefix = path + "/card";
auto files = Directory::getFiles(path.c_str());
for (auto &file : files) {
if (file.find(expectedFilePrefix.c_str()) != std::string::npos) {
return file;
}
}
return {};
}
bool Drm::readSysFsAsString(const std::string &relativeFilePath, std::string &readString) {
auto devicePath = getSysFsPciPath();
if (devicePath.empty()) {
return false;
}
const std::string fileName = devicePath + relativeFilePath;
int fd = SysCalls::open(fileName.c_str(), O_RDONLY);
if (fd < 0) {
return false;
}
ssize_t bytesRead = SysCalls::pread(fd, readString.data(), readString.size() - 1, 0);
NEO::SysCalls::close(fd);
if (bytesRead <= 0) {
return false;
}
std::replace(readString.begin(), readString.end(), '\n', '\0');
return true;
}
int Drm::queryGttSize(uint64_t >tSizeOutput, bool alignUpToFullRange) {
GemContextParam contextParam = {0};
contextParam.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamGttSize);
int ret = ioctlHelper->ioctl(DrmIoctl::gemContextGetparam, &contextParam);
if (ret == 0) {
if (alignUpToFullRange) {
gttSizeOutput = Drm::alignUpGttSize(contextParam.value);
} else {
gttSizeOutput = contextParam.value;
}
}
return ret;
}
bool Drm::isGpuHangDetected(OsContext &osContext) {
bool ret = checkResetStatus(osContext);
auto threshold = getGpuFaultCheckThreshold();
if (checkGpuPageFaultRequired()) {
if (gpuFaultCheckCounter >= threshold) {
auto memoryManager = static_cast<DrmMemoryManager *>(this->rootDeviceEnvironment.executionEnvironment.memoryManager.get());
memoryManager->checkUnexpectedGpuPageFault();
gpuFaultCheckCounter = 0;
return false;
}
gpuFaultCheckCounter++;
}
return ret;
}
bool Drm::checkResetStatus(OsContext &osContext) {
const auto osContextLinux = static_cast<OsContextLinux *>(&osContext);
const auto &drmContextIds = osContextLinux->getDrmContextIds();
for (const auto drmContextId : drmContextIds) {
ResetStats resetStats{};
resetStats.contextId = drmContextId;
ResetStatsFault fault{};
uint32_t status = 0;
const auto retVal{ioctlHelper->getResetStats(resetStats, &status, &fault)};
UNRECOVERABLE_IF(retVal != 0);
if (checkToDisableScratchPage() && ioctlHelper->validPageFault(fault.flags)) {
bool banned = ((status & ioctlHelper->getStatusForResetStats(true)) != 0);
IoFunctions::fprintf(stderr, "Segmentation fault from GPU at 0x%llx, ctx_id: %u (%s) type: %d (%s), level: %d (%s), access: %d (%s), banned: %d, aborting.\n",
fault.addr,
resetStats.contextId,
EngineHelpers::engineTypeToString(osContext.getEngineType()).c_str(),
fault.type, GpuPageFaultHelpers::faultTypeToString(static_cast<FaultType>(fault.type)).c_str(),
fault.level, GpuPageFaultHelpers::faultLevelToString(static_cast<FaultLevel>(fault.level)).c_str(),
fault.access, GpuPageFaultHelpers::faultAccessToString(static_cast<FaultAccess>(fault.access)).c_str(),
banned);
IoFunctions::fprintf(stdout, "Segmentation fault from GPU at 0x%llx, ctx_id: %u (%s) type: %d (%s), level: %d (%s), access: %d (%s), banned: %d, aborting.\n",
fault.addr,
resetStats.contextId,
EngineHelpers::engineTypeToString(osContext.getEngineType()).c_str(),
fault.type, GpuPageFaultHelpers::faultTypeToString(static_cast<FaultType>(fault.type)).c_str(),
fault.level, GpuPageFaultHelpers::faultLevelToString(static_cast<FaultLevel>(fault.level)).c_str(),
fault.access, GpuPageFaultHelpers::faultAccessToString(static_cast<FaultAccess>(fault.access)).c_str(),
banned);
UNRECOVERABLE_IF(true);
}
if (resetStats.batchActive > 0 || resetStats.batchPending > 0) {
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "ERROR: GPU HANG detected!\n");
osContextLinux->setHangDetected();
return true;
}
}
return false;
}
void Drm::checkPreemptionSupport() {
preemptionSupported = ioctlHelper->isPreemptionSupported();
}
void Drm::checkQueueSliceSupport() {
sliceCountChangeSupported = getQueueSliceCount(&sseu) == 0 ? true : false;
}
void Drm::setLowPriorityContextParam(uint32_t drmContextId) {
GemContextParam gcp = {};
gcp.contextId = drmContextId;
gcp.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamPriority);
gcp.value = -1023;
auto retVal = ioctlHelper->ioctl(DrmIoctl::gemContextSetparam, &gcp);
UNRECOVERABLE_IF(retVal != 0);
}
int Drm::getQueueSliceCount(GemContextParamSseu *sseu) {
GemContextParam contextParam = {};
contextParam.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamSseu);
sseu->engine.engineClass = ioctlHelper->getDrmParamValue(DrmParam::engineClassRender);
sseu->engine.engineInstance = ioctlHelper->getDrmParamValue(DrmParam::execDefault);
contextParam.value = reinterpret_cast<uint64_t>(sseu);
contextParam.size = sizeof(struct GemContextParamSseu);
return ioctlHelper->ioctl(DrmIoctl::gemContextGetparam, &contextParam);
}
uint64_t Drm::getSliceMask(uint64_t sliceCount) {
return maxNBitValue(sliceCount);
}
bool Drm::setQueueSliceCount(uint64_t sliceCount) {
if (sliceCountChangeSupported) {
GemContextParam contextParam = {};
sseu.sliceMask = getSliceMask(sliceCount);
contextParam.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamSseu);
contextParam.contextId = 0;
contextParam.value = reinterpret_cast<uint64_t>(&sseu);
contextParam.size = sizeof(struct GemContextParamSseu);
int retVal = ioctlHelper->ioctl(DrmIoctl::gemContextSetparam, &contextParam);
if (retVal == 0) {
return true;
}
}
return false;
}
void Drm::checkNonPersistentContextsSupport() {
GemContextParam contextParam = {};
contextParam.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamPersistence);
auto retVal = ioctlHelper->ioctl(DrmIoctl::gemContextGetparam, &contextParam);
if (retVal == 0 && contextParam.value == 1) {
nonPersistentContextsSupported = true;
} else {
nonPersistentContextsSupported = false;
}
}
void Drm::setNonPersistentContext(uint32_t drmContextId) {
GemContextParam contextParam = {};
contextParam.contextId = drmContextId;
contextParam.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamPersistence);
ioctlHelper->ioctl(DrmIoctl::gemContextSetparam, &contextParam);
}
void Drm::setUnrecoverableContext(uint32_t drmContextId) {
GemContextParam contextParam = {};
contextParam.contextId = drmContextId;
contextParam.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamRecoverable);
contextParam.value = 0;
contextParam.size = 0;
ioctlHelper->ioctl(DrmIoctl::gemContextSetparam, &contextParam);
}
int Drm::createDrmContext(uint32_t drmVmId, bool isDirectSubmissionRequested, bool isCooperativeContextRequested) {
GemContextCreateExt gcc{};
if (debugManager.flags.DirectSubmissionDrmContext.get() != -1) {
isDirectSubmissionRequested = debugManager.flags.DirectSubmissionDrmContext.get();
}
if (isDirectSubmissionRequested) {
gcc.flags |= ioctlHelper->getDirectSubmissionFlag();
}
GemContextCreateExtSetParam extSetparam = {};
if (drmVmId > 0) {
extSetparam.base.name = ioctlHelper->getDrmParamValue(DrmParam::contextCreateExtSetparam);
extSetparam.param.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamVm);
extSetparam.param.value = drmVmId;
gcc.extensions = reinterpret_cast<uint64_t>(&extSetparam);
gcc.flags |= ioctlHelper->getDrmParamValue(DrmParam::contextCreateFlagsUseExtensions);
}
if (debugManager.flags.CreateContextWithAccessCounters.get() > 0) {
return ioctlHelper->createContextWithAccessCounters(gcc);
}
if (debugManager.flags.ForceRunAloneContext.get() != -1) {
isCooperativeContextRequested = debugManager.flags.ForceRunAloneContext.get();
}
if (isCooperativeContextRequested) {
return ioctlHelper->createCooperativeContext(gcc);
}
auto ioctlResult = ioctlHelper->ioctl(DrmIoctl::gemContextCreateExt, &gcc);
if (ioctlResult < 0) {
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "WARNING: GemContextCreateExt ioctl failed. Not exposing this root device\n");
return ioctlResult;
}
return gcc.contextId;
}
void Drm::destroyDrmContext(uint32_t drmContextId) {
GemContextDestroy destroy{};
destroy.contextId = drmContextId;
auto retVal = ioctlHelper->ioctl(DrmIoctl::gemContextDestroy, &destroy);
UNRECOVERABLE_IF((retVal != 0) && (errno != ENODEV));
}
void Drm::destroyDrmVirtualMemory(uint32_t drmVmId) {
GemVmControl ctl = {};
ctl.vmId = drmVmId;
auto ret = ioctlHelper->ioctl(DrmIoctl::gemVmDestroy, &ctl);
UNRECOVERABLE_IF((ret != 0) && (errno != ENODEV));
}
int Drm::queryVmId(uint32_t drmContextId, uint32_t &vmId) {
GemContextParam param{};
param.contextId = drmContextId;
param.value = 0;
param.param = ioctlHelper->getDrmParamValue(DrmParam::contextParamVm);
auto retVal = ioctlHelper->ioctl(DrmIoctl::gemContextGetparam, ¶m);
vmId = static_cast<uint32_t>(param.value);
return retVal;
}
std::unique_lock<std::mutex> Drm::lockBindFenceMutex() {
return std::unique_lock<std::mutex>(this->bindFenceMutex);
}
int Drm::getEuTotal(int &euTotal) {
return getParamIoctl(DrmParam::paramEuTotal, &euTotal);
}
int Drm::getSubsliceTotal(int &subsliceTotal) {
return getParamIoctl(DrmParam::paramSubsliceTotal, &subsliceTotal);
}
int Drm::getMinEuInPool(int &minEUinPool) {
return getParamIoctl(DrmParam::paramMinEuInPool, &minEUinPool);
}
int Drm::getErrno() {
return errno;
}
int Drm::setupHardwareInfo(const DeviceDescriptor *device, bool setupFeatureTableAndWorkaroundTable) {
const auto usDeviceIdOverride = rootDeviceEnvironment.getHardwareInfo()->platform.usDeviceID;
const auto usRevIdOverride = rootDeviceEnvironment.getHardwareInfo()->platform.usRevId;
// reset hwInfo and apply overrides
rootDeviceEnvironment.setHwInfo(device->pHwInfo);
HardwareInfo *hwInfo = rootDeviceEnvironment.getMutableHardwareInfo();
hwInfo->platform.usDeviceID = usDeviceIdOverride;
hwInfo->platform.usRevId = usRevIdOverride;
rootDeviceEnvironment.initProductHelper();
rootDeviceEnvironment.initGfxCoreHelper();
rootDeviceEnvironment.initApiGfxCoreHelper();
rootDeviceEnvironment.initCompilerProductHelper();
rootDeviceEnvironment.initAilConfigurationHelper();
auto result = rootDeviceEnvironment.initAilConfiguration();
if (false == result) {
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "FATAL: AIL creation failed!\n");
return -1;
}
const auto productFamily = hwInfo->platform.eProductFamily;
setupIoctlHelper(productFamily);
ioctlHelper->setupIpVersion();
rootDeviceEnvironment.initReleaseHelper();
auto releaseHelper = rootDeviceEnvironment.getReleaseHelper();
device->setupHardwareInfo(hwInfo, setupFeatureTableAndWorkaroundTable, releaseHelper);
querySystemInfo();
if (systemInfo) {
systemInfo->checkSysInfoMismatch(hwInfo);
setupSystemInfo(hwInfo, systemInfo.get());
auto numRegions = systemInfo->getNumRegions();
if (numRegions > 0) {
hwInfo->featureTable.regionCount = numRegions;
}
}
if (!queryMemoryInfo()) {
setPerContextVMRequired(true);
printDebugString(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "WARNING: Failed to query memory info\n");
}
if (!queryEngineInfo()) {
setPerContextVMRequired(true);
printDebugString(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "WARNING: Failed to query engine info\n");
}
if (!hwInfo->gtSystemInfo.L3BankCount) {
hwInfo->gtSystemInfo.L3BankCount = hwInfo->gtSystemInfo.MaxDualSubSlicesSupported;
}
DrmQueryTopologyData topologyData = {};
if (!queryTopology(*hwInfo, topologyData)) {
topologyData.sliceCount = hwInfo->gtSystemInfo.SliceCount;
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "WARNING: Topology query failed!\n");
auto ret = getEuTotal(topologyData.euCount);
if (ret != 0) {
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "FATAL: Cannot query EU total parameter!\n");
return ret;
}
ret = getSubsliceTotal(topologyData.subSliceCount);
if (ret != 0) {
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "FATAL: Cannot query subslice total parameter!\n");
return ret;
}
}
hwInfo->gtSystemInfo.SliceCount = static_cast<uint32_t>(topologyData.sliceCount);
if (!topologyMap.empty()) {
hwInfo->gtSystemInfo.IsDynamicallyPopulated = true;
std::bitset<GT_MAX_SLICE> totalSliceMask{maxNBitValue(GT_MAX_SLICE)};
uint32_t latestSliceIndex = 0;
for (auto &mapping : topologyMap) {
std::bitset<GT_MAX_SLICE> sliceMask;
DEBUG_BREAK_IF(mapping.second.sliceIndices.empty());
for (auto &slice : mapping.second.sliceIndices) {
sliceMask.set(slice);
latestSliceIndex = slice;
}
totalSliceMask &= sliceMask;
}
for (uint32_t slice = 0; slice < GT_MAX_SLICE; slice++) {
hwInfo->gtSystemInfo.SliceInfo[slice].Enabled = totalSliceMask.test(slice);
}
if (totalSliceMask.none()) {
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "%s", "FATAL: Incorrect slice mask from topology map!\n");
return -1;
}
if (totalSliceMask.count() == 1u) {
std::bitset<GT_MAX_SUBSLICE_PER_SLICE> totalSubSliceMask{maxNBitValue(GT_MAX_SUBSLICE_PER_SLICE)};
for (auto &mapping : topologyMap) {
std::bitset<GT_MAX_SUBSLICE_PER_SLICE> subSliceMask;
DEBUG_BREAK_IF(mapping.second.subsliceIndices.empty());
for (auto &subslice : mapping.second.subsliceIndices) {
if (subslice >= GT_MAX_SUBSLICE_PER_SLICE) {
subSliceMask = {};
break;
}
subSliceMask.set(subslice);
}
totalSubSliceMask &= subSliceMask;
}
for (uint32_t subslice = 0; subslice < GT_MAX_SUBSLICE_PER_SLICE; subslice++) {
hwInfo->gtSystemInfo.SliceInfo[latestSliceIndex].SubSliceInfo[subslice].Enabled = totalSubSliceMask.test(subslice);
}
}
}
hwInfo->gtSystemInfo.SubSliceCount = static_cast<uint32_t>(topologyData.subSliceCount);
hwInfo->gtSystemInfo.DualSubSliceCount = static_cast<uint32_t>(topologyData.subSliceCount);
if (!hwInfo->gtSystemInfo.MaxEuPerSubSlice) {
hwInfo->gtSystemInfo.MaxEuPerSubSlice = topologyData.maxEusPerSubSlice;
}
auto maxEuCount = static_cast<uint32_t>(topologyData.subSliceCount) * hwInfo->gtSystemInfo.MaxEuPerSubSlice;
if (topologyData.euCount == 0 || static_cast<uint32_t>(topologyData.euCount) > maxEuCount) {
hwInfo->gtSystemInfo.EUCount = maxEuCount;
} else {
hwInfo->gtSystemInfo.EUCount = static_cast<uint32_t>(topologyData.euCount);
}
if (!hwInfo->gtSystemInfo.EUCount) {
return -1;
}
auto numThreadsPerEu = systemInfo ? systemInfo->getNumThreadsPerEu() : (releaseHelper ? releaseHelper->getNumThreadsPerEu() : 7u);
hwInfo->gtSystemInfo.ThreadCount = numThreadsPerEu * hwInfo->gtSystemInfo.EUCount;
hwInfo->gtSystemInfo.MaxSlicesSupported = hwInfo->gtSystemInfo.SliceCount;
auto calculatedMaxSubSliceCount = topologyData.maxSlices * topologyData.maxSubSlicesPerSlice;
auto maxSubSliceCount = std::max(static_cast<uint32_t>(calculatedMaxSubSliceCount), hwInfo->gtSystemInfo.MaxSubSlicesSupported);
hwInfo->gtSystemInfo.MaxSubSlicesSupported = maxSubSliceCount;
hwInfo->gtSystemInfo.MaxDualSubSlicesSupported = maxSubSliceCount;
if (topologyData.numL3Banks > 0) {
hwInfo->gtSystemInfo.L3BankCount = topologyData.numL3Banks;
}
if (systemInfo) {
hwInfo->gtSystemInfo.L3CacheSizeInKb = systemInfo->getL3BankSizeInKb() * hwInfo->gtSystemInfo.L3BankCount;
}
rootDeviceEnvironment.setRcsExposure();
setupCacheInfo(*hwInfo);
hwInfo->capabilityTable.deviceName = device->devName;
rootDeviceEnvironment.initializeGfxCoreHelperFromHwInfo();
return 0;
}
void appendHwDeviceId(std::vector<std::unique_ptr<HwDeviceId>> &hwDeviceIds, int fileDescriptor, const char *pciPath, const char *devNodePath) {
if (fileDescriptor >= 0) {
if (Drm::isDrmSupported(fileDescriptor)) {
hwDeviceIds.push_back(std::make_unique<HwDeviceIdDrm>(fileDescriptor, pciPath, devNodePath));
} else {
SysCalls::close(fileDescriptor);
}
}
}
std::vector<std::unique_ptr<HwDeviceId>> Drm::discoverDevices(ExecutionEnvironment &executionEnvironment) {
std::string str = "";
return Drm::discoverDevices(executionEnvironment, str);
}
std::vector<std::unique_ptr<HwDeviceId>> Drm::discoverDevice(ExecutionEnvironment &executionEnvironment, std::string &osPciPath) {
return Drm::discoverDevices(executionEnvironment, osPciPath);
}
std::vector<std::unique_ptr<HwDeviceId>> Drm::discoverDevices(ExecutionEnvironment &executionEnvironment, std::string &osPciPath) {
std::vector<std::unique_ptr<HwDeviceId>> hwDeviceIds;
executionEnvironment.osEnvironment = std::make_unique<OsEnvironment>();
size_t numRootDevices = 0u;
if (debugManager.flags.CreateMultipleRootDevices.get()) {
numRootDevices = debugManager.flags.CreateMultipleRootDevices.get();
}
std::vector<std::string> files = Directory::getFiles(Os::pciDevicesDirectory);
if (files.size() == 0) {
const char *pathPrefix = "/dev/dri/renderD";
const unsigned int maxDrmDevices = 64;
unsigned int startNum = 128;
for (unsigned int i = 0; i < maxDrmDevices; i++) {
std::string path = std::string(pathPrefix) + std::to_string(i + startNum);
int fileDescriptor = SysCalls::open(path.c_str(), O_RDWR | O_CLOEXEC);
if (fileDescriptor < 0) {
continue;
}
auto pciPath = NEO::getPciPath(fileDescriptor);
appendHwDeviceId(hwDeviceIds, fileDescriptor, pciPath.value_or("0000:00:02.0").c_str(), path.c_str());
if (!hwDeviceIds.empty() && hwDeviceIds.size() == numRootDevices) {
break;
}
}
return hwDeviceIds;
}
do {
constexpr const char *renderDeviceSuffix = "-render";
size_t renderDevSufSize = std::char_traits<char>::length(renderDeviceSuffix);
size_t pciDevDirLen = std::char_traits<char>::length(Os::pciDevicesDirectory);
for (std::vector<std::string>::iterator file = files.begin(); file != files.end(); ++file) {
std::string_view devicePathView(file->c_str(), file->size());
devicePathView = devicePathView.substr(pciDevDirLen);
auto rdsPos = devicePathView.rfind(renderDeviceSuffix);
if (rdsPos == std::string::npos) {
continue;
}
if (rdsPos < devicePathView.size() - renderDevSufSize) {
continue;
}
// at least 'pci-0000:00:00.0' -> 16
if (rdsPos < 16 || devicePathView[rdsPos - 13] != '-') {
continue;
}
std::string pciPath(devicePathView.substr(rdsPos - 12, 12));
if (!osPciPath.empty()) {
if (osPciPath.compare(pciPath) != 0) {
// if osPciPath is non-empty, then interest is only in discovering device having same bdf as ocPciPath. Skip all other devices.
continue;
}
}
if (debugManager.flags.FilterBdfPath.get() != "unk") {
if (devicePathView.find(debugManager.flags.FilterBdfPath.get().c_str()) == std::string::npos) {
continue;
}
}
int fileDescriptor = SysCalls::open(file->c_str(), O_RDWR | O_CLOEXEC);
appendHwDeviceId(hwDeviceIds, fileDescriptor, pciPath.c_str(), file->c_str());
if (!hwDeviceIds.empty() && hwDeviceIds.size() == numRootDevices) {
break;
}
}
if (hwDeviceIds.empty()) {
return hwDeviceIds;
}
} while (hwDeviceIds.size() < numRootDevices);
return hwDeviceIds;
}
std::string Drm::getDrmVersion(int fileDescriptor) {
DrmVersion version = {};
char name[5] = {};
version.name = name;
version.nameLen = 5;
auto requestValue = getIoctlRequestValue(DrmIoctl::version, nullptr);
int ret = SysCalls::ioctl(fileDescriptor, requestValue, &version);
if (ret) {
return {};
}
name[4] = '\0';
return std::string(name);
}
template <typename DataType>
std::vector<DataType> Drm::query(uint32_t queryId, uint32_t queryItemFlags) {
Query query{};
QueryItem queryItem{};
queryItem.queryId = queryId;
queryItem.length = 0; // query length first
queryItem.flags = queryItemFlags;
query.itemsPtr = reinterpret_cast<uint64_t>(&queryItem);
query.numItems = 1;
auto ret = ioctlHelper->ioctl(DrmIoctl::query, &query);
if (ret != 0 || queryItem.length <= 0) {
return {};
}
auto data = std::vector<DataType>(Math::divideAndRoundUp(queryItem.length, sizeof(DataType)), 0);
queryItem.dataPtr = castToUint64(data.data());
ret = ioctlHelper->ioctl(DrmIoctl::query, &query);
if (ret != 0 || queryItem.length <= 0) {
return {};
}
return data;
}
void Drm::printIoctlStatistics() {
if (!debugManager.flags.PrintKmdTimes.get()) {
return;
}
printf("\n--- Ioctls statistics ---\n");
printf("%41s %15s %10s %20s %20s %20s", "Request", "Total time(ns)", "Count", "Avg time per ioctl", "Min", "Max\n");
for (const auto &ioctlData : this->ioctlStatistics) {
printf("%41s %15llu %10lu %20f %20lld %20lld\n",
ioctlHelper->getIoctlString(ioctlData.first).c_str(),
ioctlData.second.totalTime,
static_cast<unsigned long>(ioctlData.second.count),
ioctlData.second.totalTime / static_cast<double>(ioctlData.second.count),
ioctlData.second.minTime,
ioctlData.second.maxTime);
}
printf("\n");
}
bool Drm::createVirtualMemoryAddressSpace(uint32_t vmCount) {
for (auto i = 0u; i < vmCount; i++) {
uint32_t id = i;
if (0 != createDrmVirtualMemory(id)) {
return false;
}
virtualMemoryIds.push_back(id);
}
return true;
}
void Drm::destroyVirtualMemoryAddressSpace() {
for (auto id : virtualMemoryIds) {
destroyDrmVirtualMemory(id);
}
virtualMemoryIds.clear();
}
uint32_t Drm::getVirtualMemoryAddressSpace(uint32_t vmId) const {
if (vmId < virtualMemoryIds.size()) {
return virtualMemoryIds[vmId];
}
return 0;
}
void Drm::setNewResourceBoundToVM(BufferObject *bo, uint32_t vmHandleId) {
if (!this->rootDeviceEnvironment.getProductHelper().isTlbFlushRequired()) {
return;
}
const auto &engines = this->rootDeviceEnvironment.executionEnvironment.memoryManager->getRegisteredEngines(bo->getRootDeviceIndex());
for (const auto &engine : engines) {
if (engine.osContext->getDeviceBitfield().test(vmHandleId)) {
auto osContextLinux = static_cast<OsContextLinux *>(engine.osContext);
osContextLinux->setNewResourceBound();
}
}
}
PhysicalDevicePciBusInfo Drm::getPciBusInfo() const {
PhysicalDevicePciBusInfo pciBusInfo(PhysicalDevicePciBusInfo::invalidValue, PhysicalDevicePciBusInfo::invalidValue, PhysicalDevicePciBusInfo::invalidValue, PhysicalDevicePciBusInfo::invalidValue);
if (adapterBDF.Data != std::numeric_limits<uint32_t>::max()) {
pciBusInfo.pciDomain = this->pciDomain;
pciBusInfo.pciBus = adapterBDF.Bus;
pciBusInfo.pciDevice = adapterBDF.Device;
pciBusInfo.pciFunction = adapterBDF.Function;
}
return pciBusInfo;
}
void Drm::cleanup() {
destroyVirtualMemoryAddressSpace();
}
Drm::~Drm() {
this->printIoctlStatistics();
}
int Drm::queryAdapterBDF() {
constexpr int pciBusInfoTokensNum = 4;
uint16_t domain = -1;
uint8_t bus = -1, device = -1, function = -1;
if (NEO::parseBdfString(hwDeviceId->getPciPath(), domain, bus, device, function) != pciBusInfoTokensNum) {
adapterBDF.Data = std::numeric_limits<uint32_t>::max();
return 1;
}
setPciDomain(domain);
adapterBDF.Bus = bus;
adapterBDF.Function = function;
adapterBDF.Device = device;
return 0;
}
void Drm::setGmmInputArgs(void *args) {
auto gmmInArgs = reinterpret_cast<GMM_INIT_IN_ARGS *>(args);
#if defined(__linux__)
gmmInArgs->FileDescriptor = adapterBDF.Data;
#endif
gmmInArgs->ClientType = GMM_CLIENT::GMM_OCL_VISTA;
}
const std::vector<int> &Drm::getSliceMappings(uint32_t deviceIndex) {
return topologyMap[deviceIndex].sliceIndices;
}
int Drm::waitHandle(uint32_t waitHandle, int64_t timeout) {
UNRECOVERABLE_IF(isVmBindAvailable());
GemWait wait{};
wait.boHandle = waitHandle;
wait.timeoutNs = timeout;
int ret = ioctlHelper->ioctl(DrmIoctl::gemWait, &wait);
if (ret != 0) {
int err = errno;
PRINT_DEBUG_STRING(debugManager.flags.PrintDebugMessages.get(), stderr, "ioctl(I915_GEM_WAIT) failed with %d. errno=%d(%s)\n", ret, err, strerror(err));
}
return ret;
}
int Drm::getTimestampFrequency(int &frequency) {
frequency = 0;
return getParamIoctl(DrmParam::paramCsTimestampFrequency, &frequency);
}
int Drm::getOaTimestampFrequency(int &frequency) {
frequency = 0;
return getParamIoctl(DrmParam::paramOATimestampFrequency, &frequency);
}
bool Drm::queryEngineInfo() {
UNRECOVERABLE_IF(!memoryInfoQueried);
UNRECOVERABLE_IF(engineInfoQueried);
engineInfoQueried = true;
return Drm::queryEngineInfo(false);
}
bool Drm::sysmanQueryEngineInfo() {
return Drm::queryEngineInfo(true);
}
bool Drm::isDebugAttachAvailable() {
int enableEuDebug = getEuDebugSysFsEnable();
return (enableEuDebug == 1) && ioctlHelper->isDebugAttachAvailable();
}
int Drm::getEuDebugSysFsEnable() {
return ioctlHelper->getEuDebugSysFsEnable();
}
int getMaxGpuFrequencyOfDevice(Drm &drm, std::string &sysFsPciPath, int &maxGpuFrequency) {
maxGpuFrequency = 0;
std::string clockSysFsPath = sysFsPciPath + drm.getIoctlHelper()->getFileForMaxGpuFrequency();
std::ifstream ifs(clockSysFsPath.c_str(), std::ifstream::in);
if (ifs.fail()) {
return -1;
}
ifs >> maxGpuFrequency;
ifs.close();
return 0;
}
int getMaxGpuFrequencyOfSubDevice(Drm &drm, std::string &sysFsPciPath, int subDeviceId, int &maxGpuFrequency) {
maxGpuFrequency = 0;
std::string clockSysFsPath = sysFsPciPath + drm.getIoctlHelper()->getFileForMaxGpuFrequencyOfSubDevice(subDeviceId);
std::ifstream ifs(clockSysFsPath.c_str(), std::ifstream::in);
if (ifs.fail()) {
return -1;
}
ifs >> maxGpuFrequency;
ifs.close();
return 0;
}
int Drm::getMaxGpuFrequency(HardwareInfo &hwInfo, int &maxGpuFrequency) {
int ret = 0;
std::string sysFsPciPath = getSysFsPciPath();
auto tileCount = hwInfo.gtSystemInfo.MultiTileArchInfo.TileCount;
if (hwInfo.gtSystemInfo.MultiTileArchInfo.IsValid && tileCount > 0) {
for (auto tileId = 0; tileId < tileCount; tileId++) {
int maxGpuFreqOfSubDevice = 0;
ret |= getMaxGpuFrequencyOfSubDevice(*this, sysFsPciPath, tileId, maxGpuFreqOfSubDevice);
maxGpuFrequency = std::max(maxGpuFrequency, maxGpuFreqOfSubDevice);
}
if (ret == 0) {
return 0;
}
}
return getMaxGpuFrequencyOfDevice(*this, sysFsPciPath, maxGpuFrequency);
}
bool Drm::getDeviceMemoryMaxClockRateInMhz(uint32_t tileId, uint32_t &clkRate) {
const std::string relativefilePath = ioctlHelper->getFileForMaxMemoryFrequencyOfSubDevice(tileId);
std::string readString(64, '\0');
errno = 0;
if (readSysFsAsString(relativefilePath, readString) == false) {
return false;
}
char *endPtr = nullptr;
uint32_t retClkRate = static_cast<uint32_t>(std::strtoul(readString.data(), &endPtr, 10));
if ((endPtr == readString.data()) || (errno != 0)) {
return false;
}
clkRate = retClkRate;
return true;
}
bool Drm::getDeviceMemoryPhysicalSizeInBytes(uint32_t tileId, uint64_t &physicalSize) {
const std::string relativefilePath = "/gt/gt" + std::to_string(tileId) + "/addr_range";
std::string readString(64, '\0');
errno = 0;
if (readSysFsAsString(relativefilePath, readString) == false) {
return false;
}
char *endPtr = nullptr;
uint64_t retSize = static_cast<uint64_t>(std::strtoull(readString.data(), &endPtr, 16));
if ((endPtr == readString.data()) || (errno != 0)) {
return false;
}
physicalSize = retSize;
return true;
}
bool Drm::useVMBindImmediate() const {
bool useBindImmediate = isDirectSubmissionActive() || hasPageFaultSupport() || ioctlHelper->isImmediateVmBindRequired();
if (debugManager.flags.EnableImmediateVmBindExt.get() != -1) {
useBindImmediate = debugManager.flags.EnableImmediateVmBindExt.get();
}
return useBindImmediate;
}
void Drm::setupSystemInfo(HardwareInfo *hwInfo, SystemInfo *sysInfo) {
GT_SYSTEM_INFO *gtSysInfo = &hwInfo->gtSystemInfo;
gtSysInfo->MaxEuPerSubSlice = sysInfo->getMaxEuPerDualSubSlice();
gtSysInfo->MemoryType = sysInfo->getMemoryType();
gtSysInfo->MaxSlicesSupported = sysInfo->getMaxSlicesSupported();
gtSysInfo->MaxSubSlicesSupported = sysInfo->getMaxDualSubSlicesSupported();
gtSysInfo->MaxDualSubSlicesSupported = sysInfo->getMaxDualSubSlicesSupported();
gtSysInfo->CsrSizeInMb = sysInfo->getCsrSizeInMb();
gtSysInfo->SLMSizeInKb = sysInfo->getSlmSizePerDss();
}