foundationdb/fdbserver/CoroFlow.actor.cpp

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/*
* CoroFlow.actor.cpp
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2018 Apple Inc. and the FoundationDB project authors
*
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* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
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* http://www.apache.org/licenses/LICENSE-2.0
*
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* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "fdbserver/CoroFlow.h"
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#include "flow/ActorCollection.h"
#include "fdbrpc/libcoroutine/Coro.h"
#include "flow/TDMetric.actor.h"
#include "fdbrpc/simulator.h"
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#include "flow/actorcompiler.h" // has to be last include
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Coro *current_coro = 0, *main_coro = 0;
Coro* swapCoro( Coro* n ) {
Coro* t = current_coro;
current_coro = n;
return t;
}
/*struct IThreadlike {
public:
virtual void start() = 0; // Call at most once! Causes run() to be called on the 'thread'.
virtual ~IThreadlike() {} // Pre: start hasn't been called, or run() has returned
virtual void unblock() = 0; // Pre: block() has been called by run(). Causes block() to return.
protected:
virtual void block() = 0; // Call only from run(). Returns when unblock() is called elsewhere.
virtual void run() = 0; // To be overridden by client. Returning causes the thread to block until it is destroyed.
};*/
struct Coroutine /*: IThreadlike*/ {
Coroutine() {
coro = Coro_new();
if (coro == NULL)
platform::outOfMemory();
}
~Coroutine() {
Coro_free(coro);
}
void start() {
int result = Coro_startCoro_( swapCoro(coro), coro, this, &entry );
if (result == ENOMEM)
platform::outOfMemory();
}
void unblock() {
//Coro_switchTo_( swapCoro(coro), coro );
blocked.send(Void());
}
protected:
void block() {
//Coro_switchTo_( swapCoro(main_coro), main_coro );
blocked = Promise<Void>();
double before = now();
CoroThreadPool::waitFor( blocked.getFuture() );
if (g_network->isSimulated() && g_simulator.getCurrentProcess()->rebooting) TraceEvent("CoroUnblocked").detail("After", now()-before);
}
virtual void run() = 0;
private:
void wrapRun() {
run();
Coro_switchTo_( swapCoro(main_coro), main_coro );
//block();
}
static void entry(void* _this) {
((Coroutine*)_this)->wrapRun();
}
Coro* coro;
Promise<Void> blocked;
};
template <class Threadlike, class Mutex, bool IS_CORO>
class WorkPool : public IThreadPool, public ReferenceCounted<WorkPool<Threadlike,Mutex,IS_CORO>> {
struct Worker;
// Pool can survive the destruction of WorkPool while it waits for workers to terminate
struct Pool : ReferenceCounted<Pool> {
Mutex queueLock;
Deque<PThreadAction> work;
std::vector<Worker*> idle, workers;
ActorCollection anyError, allStopped;
Future<Void> m_holdRefUntilStopped;
Pool() : anyError(false), allStopped(true) {
m_holdRefUntilStopped = holdRefUntilStopped(this);
}
~Pool() {
for(int c=0; c<workers.size(); c++)
delete workers[c];
}
ACTOR Future<Void> holdRefUntilStopped( Pool* p ) {
p->addref();
wait( p->allStopped.getResult() );
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p->delref();
return Void();
}
};
struct Worker : Threadlike {
Pool* pool;
IThreadPoolReceiver* userData;
bool stop;
ThreadReturnPromise<Void> stopped;
ThreadReturnPromise<Void> error;
Worker( Pool* pool, IThreadPoolReceiver* userData ) : pool(pool), userData(userData), stop(false) {
}
virtual void run() {
try {
if(!stop)
userData->init();
while (!stop) {
pool->queueLock.enter();
if (pool->work.empty()) {
pool->idle.push_back( this );
pool->queueLock.leave();
Threadlike::block();
} else {
PThreadAction a = pool->work.front();
pool->work.pop_front();
pool->queueLock.leave();
(*a)(userData);
if(IS_CORO) CoroThreadPool::waitFor(yield());
}
}
TraceEvent("CoroStop");
delete userData;
stopped.send(Void());
return;
} catch (Error& e) {
TraceEvent("WorkPoolError").error(e, true);
error.sendError(e);
} catch (...) {
TraceEvent("WorkPoolError");
error.sendError(unknown_error());
}
try {
delete userData;
} catch (...) {
TraceEvent(SevError, "WorkPoolErrorShutdownError");
}
stopped.send(Void());
}
};
Reference<Pool> pool;
Future<Void> m_stopOnError; // must be last, because its cancellation calls stop()!
Error error;
ACTOR Future<Void> stopOnError( WorkPool* w ) {
try {
wait( w->getError() );
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} catch (Error& e) {
w->error = e;
}
w->stop();
return Void();
}
void checkError() {
if (error.code() != invalid_error_code) {
ASSERT( error.code() != error_code_success ); // Calling post or addThread after stop is an error
throw error;
}
}
public:
WorkPool() : pool( new Pool ) {
m_stopOnError = stopOnError( this );
}
virtual Future<Void> getError() { return pool->anyError.getResult(); }
virtual void addThread( IThreadPoolReceiver* userData ) {
checkError();
auto w = new Worker(pool.getPtr(), userData);
pool->queueLock.enter();
pool->workers.push_back( w );
pool->queueLock.leave();
pool->anyError.add( w->error.getFuture() );
pool->allStopped.add( w->stopped.getFuture() );
startWorker(w);
}
ACTOR static void startWorker( Worker* w ) {
// We want to make sure that coroutines are always started after Net2::run() is called, so the main coroutine is
// initialized.
wait( delay(0, g_network->getCurrentTask() ));
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w->start();
}
virtual void post( PThreadAction action ) {
checkError();
pool->queueLock.enter();
pool->work.push_back(action);
if (!pool->idle.empty()) {
Worker* c = pool->idle.back();
pool->idle.pop_back();
pool->queueLock.leave();
c->unblock();
} else
pool->queueLock.leave();
}
virtual Future<Void> stop() {
if (error.code() == invalid_error_code) error = success();
pool->queueLock.enter();
TraceEvent("WorkPool_Stop").detail("Workers", pool->workers.size()).detail("Idle", pool->idle.size())
.detail("Work", pool->work.size());
for (uint32_t i=0; i<pool->work.size(); i++)
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pool->work[i]->cancel(); // What if cancel() does something to this?
pool->work.clear();
for(int i=0; i<pool->workers.size(); i++)
pool->workers[i]->stop = true;
std::vector<Worker*> idle;
std::swap(idle, pool->idle);
pool->queueLock.leave();
for(int i=0; i<idle.size(); i++)
idle[i]->unblock();
pool->allStopped.add( Void() );
return pool->allStopped.getResult();
}
virtual bool isCoro() const { return IS_CORO; }
virtual void addref() { ReferenceCounted<WorkPool>::addref(); }
virtual void delref() { ReferenceCounted<WorkPool>::delref(); }
};
typedef WorkPool<Coroutine, ThreadUnsafeSpinLock, true> CoroPool;
ACTOR void coroSwitcher( Future<Void> what, int taskID, Coro* coro ) {
try {
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// state double t = now();
wait(what);
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//if (g_network->isSimulated() && g_simulator.getCurrentProcess()->rebooting && now()!=t)
// TraceEvent("NonzeroWaitDuringReboot").detail("TaskID", taskID).detail("Elapsed", now()-t).backtrace("Flow");
} catch (Error&) {}
wait( delay(0, taskID) );
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Coro_switchTo_( swapCoro(coro), coro );
}
void CoroThreadPool::waitFor( Future<Void> what ) {
ASSERT (current_coro != main_coro);
if (what.isReady()) return;
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// double t = now();
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coroSwitcher(what, g_network->getCurrentTask(), current_coro);
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Coro_switchTo_( swapCoro(main_coro), main_coro );
//if (g_network->isSimulated() && g_simulator.getCurrentProcess()->rebooting && now()!=t)
// TraceEvent("NonzeroWaitDuringReboot").detail("TaskID", currentTaskID).detail("Elapsed", now()-t).backtrace("Coro");
ASSERT( what.isReady() );
}
// Right After INet2::run
void CoroThreadPool::init()
{
if (!current_coro) {
current_coro = main_coro = Coro_new();
if (main_coro == NULL)
platform::outOfMemory();
Coro_initializeMainCoro(main_coro);
//printf("Main thread: %d bytes stack presumed available\n", Coro_bytesLeftOnStack(current_coro));
}
}
Reference<IThreadPool> CoroThreadPool::createThreadPool() {
return Reference<IThreadPool>( new CoroPool );
}