compute-runtime/level_zero/core/source/event/event.cpp

/*
 * Copyright (C) 2020-2023 Intel Corporation
 *
 * SPDX-License-Identifier: MIT
 *
 */

#include "level_zero/core/source/event/event.h"

#include "shared/source/command_stream/command_stream_receiver_hw.h"
#include "shared/source/command_stream/csr_definitions.h"
#include "shared/source/debug_settings/debug_settings_manager.h"
#include "shared/source/device/device.h"
#include "shared/source/execution_environment/execution_environment.h"
#include "shared/source/execution_environment/root_device_environment.h"
#include "shared/source/helpers/aligned_memory.h"
#include "shared/source/helpers/constants.h"
#include "shared/source/helpers/gfx_core_helper.h"
#include "shared/source/helpers/string.h"
#include "shared/source/memory_manager/allocation_properties.h"
#include "shared/source/memory_manager/memory_manager.h"
#include "shared/source/memory_manager/memory_operations_handler.h"
#include "shared/source/utilities/cpuintrinsics.h"
#include "shared/source/utilities/wait_util.h"

#include "level_zero/core/source/cmdlist/cmdlist.h"
#include "level_zero/core/source/cmdlist/cmdlist_imp.h"
#include "level_zero/core/source/cmdqueue/cmdqueue.h"
#include "level_zero/core/source/context/context_imp.h"
#include "level_zero/core/source/device/device.h"
#include "level_zero/core/source/device/device_imp.h"
#include "level_zero/core/source/driver/driver_handle_imp.h"
#include "level_zero/core/source/event/event_impl.inl"
#include "level_zero/core/source/gfx_core_helpers/l0_gfx_core_helper.h"

#include <set>

namespace L0 {
template Event *Event::create<uint64_t>(EventPool *, const ze_event_desc_t *, Device *);
template Event *Event::create<uint32_t>(EventPool *, const ze_event_desc_t *, Device *);

ze_result_t EventPool::initialize(DriverHandle *driver, Context *context, uint32_t numDevices, ze_device_handle_t *deviceHandles) {
    this->context = static_cast<ContextImp *>(context);

    bool ipcPool = eventPoolFlags & ZE_EVENT_POOL_FLAG_IPC;

    if (ipcPool && counterBased) {
        return ZE_RESULT_ERROR_UNSUPPORTED_FEATURE;
    }

    RootDeviceIndicesContainer rootDeviceIndices;
    uint32_t maxRootDeviceIndex = 0u;
    uint32_t currentNumDevices = numDevices;

    DriverHandleImp *driverHandleImp = static_cast<DriverHandleImp *>(driver);
    bool useDevicesFromApi = true;
    this->isDeviceEventPoolAllocation = isEventPoolDeviceAllocationFlagSet();

    if (numDevices == 0) {
        currentNumDevices = static_cast<uint32_t>(driverHandleImp->devices.size());
        useDevicesFromApi = false;
    }

    for (uint32_t i = 0u; i < currentNumDevices; i++) {
        Device *eventDevice = nullptr;

        if (useDevicesFromApi) {
            eventDevice = Device::fromHandle(deviceHandles[i]);
        } else {
            eventDevice = driverHandleImp->devices[i];
        }

        if (!eventDevice) {
            return ZE_RESULT_ERROR_INVALID_ARGUMENT;
        }

        devices.push_back(eventDevice);
        rootDeviceIndices.pushUnique(eventDevice->getNEODevice()->getRootDeviceIndex());
        if (maxRootDeviceIndex < eventDevice->getNEODevice()->getRootDeviceIndex()) {
            maxRootDeviceIndex = eventDevice->getNEODevice()->getRootDeviceIndex();
        }

        isImplicitScalingCapable |= eventDevice->isImplicitScalingCapable();
    }

    auto &rootDeviceEnvironment = getDevice()->getNEODevice()->getRootDeviceEnvironment();
    auto &l0GfxCoreHelper = rootDeviceEnvironment.getHelper<L0GfxCoreHelper>();
    this->isDeviceEventPoolAllocation |= l0GfxCoreHelper.alwaysAllocateEventInLocalMem();

    initializeSizeParameters(numDevices, deviceHandles, *driverHandleImp, rootDeviceEnvironment);

    NEO::AllocationType allocationType = isEventPoolTimestampFlagSet() ? NEO::AllocationType::TIMESTAMP_PACKET_TAG_BUFFER
                                                                       : NEO::AllocationType::BUFFER_HOST_MEMORY;
    if (this->devices.size() > 1) {
        this->isDeviceEventPoolAllocation = false;
    }

    if (this->isDeviceEventPoolAllocation) {
        allocationType = NEO::AllocationType::GPU_TIMESTAMP_DEVICE_BUFFER;
    }

    eventPoolAllocations = std::make_unique<NEO::MultiGraphicsAllocation>(maxRootDeviceIndex);

    bool allocatedMemory = false;

    auto neoDevice = devices[0]->getNEODevice();
    if (this->isDeviceEventPoolAllocation) {
        this->isHostVisibleEventPoolAllocation = !(isEventPoolDeviceAllocationFlagSet());
        NEO::AllocationProperties allocationProperties{*rootDeviceIndices.begin(), this->eventPoolSize, allocationType, neoDevice->getDeviceBitfield()};
        allocationProperties.alignment = eventAlignment;

        auto memoryManager = driver->getMemoryManager();
        auto graphicsAllocation = memoryManager->allocateGraphicsMemoryWithProperties(allocationProperties);
        if (graphicsAllocation) {
            eventPoolAllocations->addAllocation(graphicsAllocation);
            allocatedMemory = true;
            if (ipcPool) {
                uint64_t handle = 0;
                this->isShareableEventMemory = (graphicsAllocation->peekInternalHandle(memoryManager, handle) == 0);
            }
        }
    } else {
        this->isHostVisibleEventPoolAllocation = true;
        NEO::AllocationProperties allocationProperties{*rootDeviceIndices.begin(), this->eventPoolSize, allocationType, systemMemoryBitfield};
        allocationProperties.alignment = eventAlignment;

        eventPoolPtr = driver->getMemoryManager()->createMultiGraphicsAllocationInSystemMemoryPool(rootDeviceIndices,
                                                                                                   allocationProperties,
                                                                                                   *eventPoolAllocations);
        if (ipcPool) {
            this->isShareableEventMemory = eventPoolAllocations->getDefaultGraphicsAllocation()->isShareableHostMemory;
        }
        allocatedMemory = (nullptr != eventPoolPtr);
    }

    if (!allocatedMemory) {
        return ZE_RESULT_ERROR_OUT_OF_DEVICE_MEMORY;
    }
    if (neoDevice->getDefaultEngine().commandStreamReceiver->isTbxMode()) {
        eventPoolAllocations->getDefaultGraphicsAllocation()->setWriteMemoryOnly(true);
    }
    return ZE_RESULT_SUCCESS;
}

EventPool::~EventPool() {
    if (eventPoolAllocations) {
        auto graphicsAllocations = eventPoolAllocations->getGraphicsAllocations();
        auto memoryManager = devices[0]->getDriverHandle()->getMemoryManager();
        for (auto gpuAllocation : graphicsAllocations) {
            memoryManager->freeGraphicsMemory(gpuAllocation);
        }
    }
}

ze_result_t EventPool::destroy() {
    delete this;

    return ZE_RESULT_SUCCESS;
}

ze_result_t EventPool::createEvent(const ze_event_desc_t *desc, ze_event_handle_t *eventHandle) {
    if (desc->index > (getNumEvents() - 1)) {
        return ZE_RESULT_ERROR_INVALID_ARGUMENT;
    }

    auto &l0GfxCoreHelper = getDevice()->getNEODevice()->getRootDeviceEnvironment().getHelper<L0GfxCoreHelper>();

    *eventHandle = l0GfxCoreHelper.createEvent(this, desc, getDevice());

    return ZE_RESULT_SUCCESS;
}

void EventPool::initializeSizeParameters(uint32_t numDevices, ze_device_handle_t *deviceHandles, DriverHandleImp &driver, const NEO::RootDeviceEnvironment &rootDeviceEnvironment) {

    auto &l0GfxCoreHelper = rootDeviceEnvironment.getHelper<L0GfxCoreHelper>();
    auto &gfxCoreHelper = rootDeviceEnvironment.getHelper<NEO::GfxCoreHelper>();

    setEventAlignment(static_cast<uint32_t>(gfxCoreHelper.getTimestampPacketAllocatorAlignment()));

    auto &hwInfo = *rootDeviceEnvironment.getHardwareInfo();
    bool useDynamicEventPackets = l0GfxCoreHelper.useDynamicEventPacketsCount(hwInfo);
    eventPackets = EventPacketsCount::eventPackets;
    maxKernelCount = EventPacketsCount::maxKernelSplit;
    if (useDynamicEventPackets) {
        eventPackets = driver.getEventMaxPacketCount(numDevices, deviceHandles);
        maxKernelCount = driver.getEventMaxKernelCount(numDevices, deviceHandles);
    }
    setEventSize(static_cast<uint32_t>(alignUp(eventPackets * gfxCoreHelper.getSingleTimestampPacketSize(), eventAlignment)));

    eventPoolSize = alignUp<size_t>(this->numEvents * eventSize, MemoryConstants::pageSize64k);
}

EventPool *EventPool::create(DriverHandle *driver, Context *context, uint32_t numDevices, ze_device_handle_t *deviceHandles, const ze_event_pool_desc_t *desc, ze_result_t &result) {
    auto eventPool = std::make_unique<EventPool>(desc);

    result = eventPool->initialize(driver, context, numDevices, deviceHandles);
    if (result) {
        return nullptr;
    }
    return eventPool.release();
}

void EventPool::setupDescriptorFlags(const ze_event_pool_desc_t *desc) {
    eventPoolFlags = desc->flags;

    if (eventPoolFlags & ZE_EVENT_POOL_FLAG_KERNEL_MAPPED_TIMESTAMP) {
        eventPoolFlags |= ZE_EVENT_POOL_FLAG_KERNEL_TIMESTAMP;
    }

    auto pNext = reinterpret_cast<const ze_base_desc_t *>(desc->pNext);

    if (pNext && pNext->stype == ZE_STRUCTURE_TYPE_COUNTER_BASED_EVENT_POOL_EXP_DESC) {
        counterBased = true;
    }
}

bool EventPool::isEventPoolTimestampFlagSet() const {
    if (NEO::DebugManager.flags.OverrideTimestampEvents.get() != -1) {
        auto timestampOverride = !!NEO::DebugManager.flags.OverrideTimestampEvents.get();
        return timestampOverride;
    }
    if (eventPoolFlags & ZE_EVENT_POOL_FLAG_KERNEL_TIMESTAMP) {
        return true;
    }
    return false;
}

ze_result_t EventPool::closeIpcHandle() {
    return this->destroy();
}

ze_result_t EventPool::getIpcHandle(ze_ipc_event_pool_handle_t *ipcHandle) {
    if (!this->isShareableEventMemory) {
        return ZE_RESULT_ERROR_UNSUPPORTED_FEATURE;
    }

    IpcEventPoolData &poolData = *reinterpret_cast<IpcEventPoolData *>(ipcHandle->data);
    poolData = {};
    poolData.numEvents = this->numEvents;
    poolData.rootDeviceIndex = this->getDevice()->getRootDeviceIndex();
    poolData.isDeviceEventPoolAllocation = this->isDeviceEventPoolAllocation;
    poolData.isHostVisibleEventPoolAllocation = this->isHostVisibleEventPoolAllocation;
    poolData.isImplicitScalingCapable = this->isImplicitScalingCapable;
    poolData.maxEventPackets = this->getEventMaxPackets();
    poolData.numDevices = static_cast<uint32_t>(this->devices.size());

    int retCode = this->eventPoolAllocations->getDefaultGraphicsAllocation()->peekInternalHandle(this->context->getDriverHandle()->getMemoryManager(), poolData.handle);
    return retCode == 0 ? ZE_RESULT_SUCCESS : ZE_RESULT_ERROR_OUT_OF_HOST_MEMORY;
}

ze_result_t EventPool::openEventPoolIpcHandle(const ze_ipc_event_pool_handle_t &ipcEventPoolHandle, ze_event_pool_handle_t *eventPoolHandle,
                                              DriverHandleImp *driver, ContextImp *context, uint32_t numDevices, ze_device_handle_t *deviceHandles) {
    const IpcEventPoolData &poolData = *reinterpret_cast<const IpcEventPoolData *>(ipcEventPoolHandle.data);

    ze_event_pool_desc_t desc = {ZE_STRUCTURE_TYPE_EVENT_POOL_DESC};
    desc.count = static_cast<uint32_t>(poolData.numEvents);
    auto eventPool = std::make_unique<EventPool>(&desc);
    eventPool->isDeviceEventPoolAllocation = poolData.isDeviceEventPoolAllocation;
    eventPool->isHostVisibleEventPoolAllocation = poolData.isHostVisibleEventPoolAllocation;
    eventPool->isImplicitScalingCapable = poolData.isImplicitScalingCapable;
    ze_device_handle_t *deviceHandlesUsed = deviceHandles;

    UNRECOVERABLE_IF(numDevices == 0);
    auto device = Device::fromHandle(*deviceHandles);
    auto neoDevice = device->getNEODevice();
    NEO::osHandle osHandle = static_cast<NEO::osHandle>(poolData.handle);

    if (poolData.numDevices == 1) {
        for (uint32_t i = 0; i < numDevices; i++) {
            auto deviceStruct = Device::fromHandle(deviceHandles[i]);
            auto neoDeviceIteration = deviceStruct->getNEODevice();
            if (neoDeviceIteration->getRootDeviceIndex() == poolData.rootDeviceIndex) {
                *deviceHandlesUsed = deviceHandles[i];
                neoDevice = neoDeviceIteration;
                break;
            }
        }
        numDevices = 1;
    }

    eventPool->initializeSizeParameters(numDevices, deviceHandlesUsed, *driver, neoDevice->getRootDeviceEnvironment());
    if (eventPool->getEventMaxPackets() != poolData.maxEventPackets) {
        PRINT_DEBUG_STRING(NEO::DebugManager.flags.PrintDebugMessages.get(),
                           stderr,
                           "IPC handle max event packets %u does not match context devices max event packet %u\n",
                           poolData.maxEventPackets, eventPool->getEventMaxPackets());
        return ZE_RESULT_ERROR_INVALID_ARGUMENT;
    }

    NEO::AllocationType allocationType = NEO::AllocationType::BUFFER_HOST_MEMORY;
    if (eventPool->isDeviceEventPoolAllocation) {
        allocationType = NEO::AllocationType::GPU_TIMESTAMP_DEVICE_BUFFER;
    }

    NEO::AllocationProperties unifiedMemoryProperties{poolData.rootDeviceIndex,
                                                      eventPool->getEventPoolSize(),
                                                      allocationType,
                                                      systemMemoryBitfield};

    unifiedMemoryProperties.subDevicesBitfield = neoDevice->getDeviceBitfield();
    auto memoryManager = driver->getMemoryManager();
    NEO::GraphicsAllocation *alloc = memoryManager->createGraphicsAllocationFromSharedHandle(osHandle,
                                                                                             unifiedMemoryProperties,
                                                                                             false,
                                                                                             eventPool->isHostVisibleEventPoolAllocation,
                                                                                             false,
                                                                                             nullptr);

    if (alloc == nullptr) {
        return ZE_RESULT_ERROR_OUT_OF_DEVICE_MEMORY;
    }

    if (neoDevice->getDefaultEngine().commandStreamReceiver->isTbxMode()) {
        alloc->setWriteMemoryOnly(true);
    }

    eventPool->context = context;
    eventPool->eventPoolAllocations =
        std::make_unique<NEO::MultiGraphicsAllocation>(static_cast<uint32_t>(context->rootDeviceIndices.size()));
    eventPool->eventPoolAllocations->addAllocation(alloc);
    eventPool->eventPoolPtr = reinterpret_cast<void *>(alloc->getUnderlyingBuffer());
    for (uint32_t i = 0; i < numDevices; i++) {
        eventPool->devices.push_back(Device::fromHandle(deviceHandlesUsed[i]));
    }
    eventPool->isImportedIpcPool = true;

    if (numDevices > 1) {
        for (auto currDeviceIndex : context->rootDeviceIndices) {
            if (currDeviceIndex == poolData.rootDeviceIndex) {
                continue;
            }

            unifiedMemoryProperties.rootDeviceIndex = currDeviceIndex;
            unifiedMemoryProperties.flags.isUSMHostAllocation = true;
            unifiedMemoryProperties.flags.forceSystemMemory = true;
            unifiedMemoryProperties.flags.allocateMemory = false;
            auto graphicsAllocation = memoryManager->createGraphicsAllocationFromExistingStorage(unifiedMemoryProperties,
                                                                                                 eventPool->eventPoolPtr,
                                                                                                 eventPool->getAllocation());
            if (!graphicsAllocation) {
                return ZE_RESULT_ERROR_OUT_OF_HOST_MEMORY;
            }
            eventPool->eventPoolAllocations->addAllocation(graphicsAllocation);
        }
    }

    *eventPoolHandle = eventPool.release();

    return ZE_RESULT_SUCCESS;
}

ze_result_t Event::destroy() {
    delete this;
    return ZE_RESULT_SUCCESS;
}

void Event::enableCounterBasedMode(bool apiRequest) {
    if (counterBasedMode == CounterBasedMode::InitiallyDisabled) {
        counterBasedMode = apiRequest ? CounterBasedMode::ExplicitlyEnabled : CounterBasedMode::ImplicitlyEnabled;
    }
}

void Event::disableImplicitCounterBasedMode() {
    if (isCounterBasedExplicitlyEnabled()) {
        return;
    }

    if (counterBasedMode == CounterBasedMode::ImplicitlyEnabled || counterBasedMode == CounterBasedMode::InitiallyDisabled) {
        counterBasedMode = CounterBasedMode::ImplicitlyDisabled;
        inOrderExecInfo.reset();
        inOrderExecSignalValue = 0;
    }
}

uint64_t Event::getGpuAddress(Device *device) const {
    return getAllocation(device).getGpuAddress() + this->eventPoolOffset;
}

NEO::GraphicsAllocation &Event::getAllocation(Device *device) const {
    return *this->eventPool->getAllocation().getGraphicsAllocation(device->getNEODevice()->getRootDeviceIndex());
}

void Event::setGpuStartTimestamp() {
    if (isEventTimestampFlagSet()) {
        this->device->getGlobalTimestamps(&cpuStartTimestamp, &gpuStartTimestamp);
        cpuStartTimestamp = cpuStartTimestamp / this->device->getNEODevice()->getDeviceInfo().outProfilingTimerResolution;
    }
}

void Event::setGpuEndTimestamp() {
    if (isEventTimestampFlagSet()) {
        auto resolution = this->device->getNEODevice()->getDeviceInfo().outProfilingTimerResolution;
        uint64_t cpuEndTimestamp = 0;
        this->device->getNEODevice()->getOSTime()->getCpuTime(&cpuEndTimestamp);
        cpuEndTimestamp = cpuEndTimestamp / resolution;
        this->gpuEndTimestamp = gpuStartTimestamp + std::max<size_t>(1u, (cpuEndTimestamp - cpuStartTimestamp));
    }
}

void *Event::getCompletionFieldHostAddress() const {
    return ptrOffset(getHostAddress(), getCompletionFieldOffset());
}

void Event::increaseKernelCount() {
    kernelCount++;
    UNRECOVERABLE_IF(kernelCount > maxKernelCount);
}

void Event::resetPackets(bool resetAllPackets) {
    if (resetAllPackets) {
        resetKernelCountAndPacketUsedCount();
    }
    cpuStartTimestamp = 0;
    gpuStartTimestamp = 0;
    gpuEndTimestamp = 0;
    this->csrs.clear();
    this->csrs.push_back(this->device->getNEODevice()->getDefaultEngine().commandStreamReceiver);
}

void Event::setIsCompleted() {
    if (this->isCompleted.load() == STATE_CLEARED) {
        this->isCompleted = STATE_SIGNALED;
    }
    unsetCmdQueue();
}

void Event::updateInOrderExecState(std::shared_ptr<InOrderExecInfo> &newInOrderExecInfo, uint64_t signalValue, uint32_t allocationOffset) {
    resetCompletionStatus();

    if (this->inOrderExecInfo.get() != newInOrderExecInfo.get()) {
        inOrderExecInfo = newInOrderExecInfo;
    }

    inOrderExecSignalValue = signalValue;
    inOrderAllocationOffset = allocationOffset;
}

uint64_t Event::getInOrderExecSignalValueWithSubmissionCounter() const {
    return (inOrderExecSignalValue + InOrderPatchCommandHelpers::getAppendCounterValue(*inOrderExecInfo));
}

void Event::setLatestUsedCmdQueue(CommandQueue *newCmdQ) {
    this->latestUsedCmdQueue = newCmdQ;
}

void Event::unsetCmdQueue() {
    for (auto &csr : csrs) {
        csr->unregisterClient(latestUsedCmdQueue);
    }

    latestUsedCmdQueue = nullptr;
}

void Event::setReferenceTs(uint64_t currentCpuTimeStamp) {
    const auto recalculate =
        (currentCpuTimeStamp - referenceTs.cpuTimeinNS) > timestampRefreshIntervalInNanoSec;
    if (referenceTs.cpuTimeinNS == 0 || recalculate) {
        device->getNEODevice()->getOSTime()->getGpuCpuTime(&referenceTs);
    }
}

NEO::GraphicsAllocation *Event::getInOrderExecDataAllocation() const { return inOrderExecInfo.get() ? &inOrderExecInfo->inOrderDependencyCounterAllocation : nullptr; }

} // namespace L0