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#include "executor.h"
#include "thread_extra.h"
#include "what_thread_does.h"
#include "what_thread_does_guard.h"
#include <util/generic/utility.h>
#include <util/random/random.h>
#include <util/stream/str.h>
#include <util/system/tls.h>
#include <util/system/yassert.h>
#include <array>
using namespace NActor;
using namespace NActor::NPrivate;
namespace {
struct THistoryInternal {
struct TRecord {
TAtomic MaxQueueSize;
TRecord()
: MaxQueueSize()
{
}
TExecutorHistory::THistoryRecord Capture() {
TExecutorHistory::THistoryRecord r;
r.MaxQueueSize = AtomicGet(MaxQueueSize);
return r;
}
};
ui64 Start;
ui64 LastTime;
std::array<TRecord, 3600> Records;
THistoryInternal() {
Start = TInstant::Now().Seconds();
LastTime = Start - 1;
}
TRecord& GetRecordForTime(ui64 time) {
return Records[time % Records.size()];
}
TRecord& GetNowRecord(ui64 now) {
for (ui64 t = LastTime + 1; t <= now; ++t) {
GetRecordForTime(t) = TRecord();
}
LastTime = now;
return GetRecordForTime(now);
}
TExecutorHistory Capture() {
TExecutorHistory history;
ui64 now = TInstant::Now().Seconds();
ui64 lastHistoryRecord = now - 1;
ui32 historySize = Min<ui32>(lastHistoryRecord - Start, Records.size() - 1);
history.HistoryRecords.resize(historySize);
for (ui32 i = 0; i < historySize; ++i) {
history.HistoryRecords[i] = GetRecordForTime(lastHistoryRecord - historySize + i).Capture();
}
history.LastHistoryRecordSecond = lastHistoryRecord;
return history;
}
};
}
Y_POD_STATIC_THREAD(TExecutor*)
ThreadCurrentExecutor;
static const char* NoLocation = "nowhere";
struct TExecutorWorkerThreadLocalData {
ui32 MaxQueueSize;
};
static TExecutorWorkerThreadLocalData WorkerNoThreadLocalData;
Y_POD_STATIC_THREAD(TExecutorWorkerThreadLocalData)
WorkerThreadLocalData;
namespace NActor {
struct TExecutorWorker {
TExecutor* const Executor;
TThread Thread;
const char** WhatThreadDoesLocation;
TExecutorWorkerThreadLocalData* ThreadLocalData;
TExecutorWorker(TExecutor* executor)
: Executor(executor)
, Thread(RunThreadProc, this)
, WhatThreadDoesLocation(&NoLocation)
, ThreadLocalData(&::WorkerNoThreadLocalData)
{
Thread.Start();
}
void Run() {
WhatThreadDoesLocation = ::WhatThreadDoesLocation();
AtomicSet(ThreadLocalData, &::WorkerThreadLocalData);
WHAT_THREAD_DOES_PUSH_POP_CURRENT_FUNC();
Executor->RunWorker();
}
static void* RunThreadProc(void* thiz0) {
TExecutorWorker* thiz = (TExecutorWorker*)thiz0;
thiz->Run();
return nullptr;
}
};
struct TExecutor::TImpl {
TExecutor* const Executor;
THistoryInternal History;
TSystemEvent HelperStopSignal;
TThread HelperThread;
TImpl(TExecutor* executor)
: Executor(executor)
, HelperThread(HelperThreadProc, this)
{
}
void RunHelper() {
ui64 nowSeconds = TInstant::Now().Seconds();
for (;;) {
TInstant nextStop = TInstant::Seconds(nowSeconds + 1) + TDuration::MilliSeconds(RandomNumber<ui32>(1000));
if (HelperStopSignal.WaitD(nextStop)) {
return;
}
nowSeconds = nextStop.Seconds();
THistoryInternal::TRecord& record = History.GetNowRecord(nowSeconds);
ui32 maxQueueSize = Executor->GetMaxQueueSizeAndClear();
if (maxQueueSize > record.MaxQueueSize) {
AtomicSet(record.MaxQueueSize, maxQueueSize);
}
}
}
static void* HelperThreadProc(void* impl0) {
TImpl* impl = (TImpl*)impl0;
impl->RunHelper();
return nullptr;
}
};
}
static TExecutor::TConfig MakeConfig(unsigned workerCount) {
TExecutor::TConfig config;
config.WorkerCount = workerCount;
return config;
}
TExecutor::TExecutor(size_t workerCount)
: Config(MakeConfig(workerCount))
{
Init();
}
TExecutor::TExecutor(const TExecutor::TConfig& config)
: Config(config)
{
Init();
}
void TExecutor::Init() {
Impl.Reset(new TImpl(this));
AtomicSet(ExitWorkers, 0);
Y_VERIFY(Config.WorkerCount > 0);
for (size_t i = 0; i < Config.WorkerCount; i++) {
WorkerThreads.push_back(new TExecutorWorker(this));
}
Impl->HelperThread.Start();
}
TExecutor::~TExecutor() {
Stop();
}
void TExecutor::Stop() {
AtomicSet(ExitWorkers, 1);
Impl->HelperStopSignal.Signal();
Impl->HelperThread.Join();
{
TWhatThreadDoesAcquireGuard<TMutex> guard(WorkMutex, "executor: acquiring lock for Stop");
WorkAvailable.BroadCast();
}
for (size_t i = 0; i < WorkerThreads.size(); i++) {
WorkerThreads[i]->Thread.Join();
}
// TODO: make queue empty at this point
ProcessWorkQueueHere();
}
void TExecutor::EnqueueWork(TArrayRef<IWorkItem* const> wis) {
if (wis.empty())
return;
if (Y_UNLIKELY(AtomicGet(ExitWorkers) != 0)) {
Y_VERIFY(WorkItems.Empty(), "executor %s: cannot add tasks after queue shutdown", Config.Name);
}
TWhatThreadDoesPushPop pp("executor: EnqueueWork");
WorkItems.PushAll(wis);
{
if (wis.size() == 1) {
TWhatThreadDoesAcquireGuard<TMutex> g(WorkMutex, "executor: acquiring lock for EnqueueWork");
WorkAvailable.Signal();
} else {
TWhatThreadDoesAcquireGuard<TMutex> g(WorkMutex, "executor: acquiring lock for EnqueueWork");
WorkAvailable.BroadCast();
}
}
}
size_t TExecutor::GetWorkQueueSize() const {
return WorkItems.Size();
}
using namespace NTSAN;
ui32 TExecutor::GetMaxQueueSizeAndClear() const {
ui32 max = 0;
for (unsigned i = 0; i < WorkerThreads.size(); ++i) {
TExecutorWorkerThreadLocalData* wtls = AtomicGet(WorkerThreads[i]->ThreadLocalData);
max = Max<ui32>(max, RelaxedLoad(&wtls->MaxQueueSize));
RelaxedStore<ui32>(&wtls->MaxQueueSize, 0);
}
return max;
}
TString TExecutor::GetStatus() const {
return GetStatusRecordInternal().Status;
}
TString TExecutor::GetStatusSingleLine() const {
TStringStream ss;
ss << "work items: " << GetWorkQueueSize();
return ss.Str();
}
TExecutorStatus TExecutor::GetStatusRecordInternal() const {
TExecutorStatus r;
r.WorkQueueSize = GetWorkQueueSize();
{
TStringStream ss;
ss << "work items: " << GetWorkQueueSize() << "\n";
ss << "workers:\n";
for (unsigned i = 0; i < WorkerThreads.size(); ++i) {
ss << "-- " << AtomicGet(*AtomicGet(WorkerThreads[i]->WhatThreadDoesLocation)) << "\n";
}
r.Status = ss.Str();
}
r.History = Impl->History.Capture();
return r;
}
bool TExecutor::IsInExecutorThread() const {
return ThreadCurrentExecutor == this;
}
TAutoPtr<IWorkItem> TExecutor::DequeueWork() {
IWorkItem* wi = reinterpret_cast<IWorkItem*>(1);
size_t queueSize = Max<size_t>();
if (!WorkItems.TryPop(&wi, &queueSize)) {
TWhatThreadDoesAcquireGuard<TMutex> g(WorkMutex, "executor: acquiring lock for DequeueWork");
while (!WorkItems.TryPop(&wi, &queueSize)) {
if (AtomicGet(ExitWorkers) != 0)
return nullptr;
TWhatThreadDoesPushPop pp("waiting for work on condvar");
WorkAvailable.Wait(WorkMutex);
}
}
auto& wtls = TlsRef(WorkerThreadLocalData);
if (queueSize > RelaxedLoad(&wtls.MaxQueueSize)) {
RelaxedStore<ui32>(&wtls.MaxQueueSize, queueSize);
}
return wi;
}
void TExecutor::RunWorkItem(TAutoPtr<IWorkItem> wi) {
WHAT_THREAD_DOES_PUSH_POP_CURRENT_FUNC();
wi.Release()->DoWork();
}
void TExecutor::ProcessWorkQueueHere() {
IWorkItem* wi;
while (WorkItems.TryPop(&wi)) {
RunWorkItem(wi);
}
}
void TExecutor::RunWorker() {
Y_VERIFY(!ThreadCurrentExecutor, "state check");
ThreadCurrentExecutor = this;
SetCurrentThreadName("wrkr");
for (;;) {
TAutoPtr<IWorkItem> wi = DequeueWork();
if (!wi) {
break;
}
// Note for messagebus users: make sure program crashes
// on uncaught exception in thread, otherewise messagebus may just hang on error.
RunWorkItem(wi);
}
ThreadCurrentExecutor = (TExecutor*)nullptr;
}
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