foundationdb/fdbserver/workloads/ThreadSafety.actor.cpp

305 lines
7.4 KiB
C++

/*
* ThreadSafety.actor.cpp
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2018 Apple Inc. and the FoundationDB project authors
*
* 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
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* 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 "flow/actorcompiler.h"
#include "fdbrpc/simulator.h"
#include "flow/DeterministicRandom.h"
#include "fdbserver/TesterInterface.h"
#include "fdbserver/QuietDatabase.h"
#include "fdbserver/ServerDBInfo.h"
#include "fdbclient/ThreadSafeTransaction.h"
#include "fdbclient/MultiVersionTransaction.h"
#include "workloads.h"
struct ThreadSafetyWorkload;
// Parameters passed to each thread
struct ThreadInfo {
int id;
ThreadSafetyWorkload *self;
Promise<Void> done;
DeterministicRandom random;
ThreadInfo(int id, ThreadSafetyWorkload *self) : id(id), self(self), random(g_random->randomInt(1, 1e9)) { }
};
// A thread barrier implementation. Reached() method blocks until the required number of threads reach it.
struct Barrier {
Mutex mutex;
std::vector<Event*> events;
int numRequired;
int numReached;
Barrier() : numRequired(0), numReached(0) { }
~Barrier() {
fire();
}
void decrementNumRequired() {
mutex.enter();
if(--numRequired == numReached)
fire();
mutex.leave();
}
void setNumRequired(int numRequired) {
mutex.enter();
this->numRequired = numRequired;
if(numRequired > 0 && numRequired <= numReached)
fire();
mutex.leave();
}
// Called by each thread to signal that the barrier has been reached.
// Blocks until <numRequired> threads have called this function.
void reached() {
mutex.enter();
bool ready = (++numReached == numRequired);
Event *myEvent = NULL;
if(ready)
fire();
else {
myEvent = new Event();
events.push_back(myEvent);
}
mutex.leave();
if(!ready) {
myEvent->block();
delete myEvent;
}
}
private:
void fire() {
numReached = 0;
for(int i = 0; i < events.size(); ++i)
events[i]->set();
events.clear();
}
};
extern bool noUnseed;
//A workload which uses the thread safe API from multiple threads
struct ThreadSafetyWorkload : TestWorkload {
int threadsPerClient;
double threadDuration;
// Used to generate keys for the workload. This is the number of keys that will be available for operations.
int numKeys;
bool success;
bool stopped;
Mutex mutex;
Barrier commitBarrier;
Reference<IDatabase> db;
// ThreadFutures are not thread safe, so they must be copied in other threads inside of mutexes
ThreadFuture<Void> commitFuture;
Reference<ITransaction> tr;
ThreadSafetyWorkload(WorkloadContext const& wcx)
: TestWorkload(wcx), tr(NULL), stopped(false) {
threadsPerClient = getOption(options, LiteralStringRef("threadsPerClient"), 3);
threadDuration = getOption(options, LiteralStringRef("threadDuration"), 60.0);
numKeys = getOption(options, LiteralStringRef("numKeys"), 100);
commitBarrier.setNumRequired(threadsPerClient);
success = true;
// This test is not deterministic
noUnseed = true;
}
virtual std::string description() {
return "ThreadSafety";
}
virtual Future<Void> setup(Database const& cx) {
return Void();
}
virtual Future<Void> start(Database const& cx) {
return _start(cx, this);
}
ACTOR Future<Void> _start(Database cx, ThreadSafetyWorkload *self) {
state std::vector<ThreadInfo*> threadInfo;
Reference<IDatabase> dbRef = wait(unsafeThreadFutureToFuture(ThreadSafeDatabase::createFromExistingDatabase(cx)));
self->db = dbRef;
if(g_random->coinflip()) {
self->db = MultiVersionDatabase::debugCreateFromExistingDatabase(dbRef);
}
state int i;
for(i = 0; i < self->threadsPerClient; ++i) {
threadInfo.push_back(new ThreadInfo(i, self));
g_network->startThread(self->threadStart, threadInfo[i]);
}
Void _ = wait(delay(self->threadDuration));
// Signals the threads to stop
self->mutex.enter();
self->stopped = true;
self->mutex.leave();
for(i = 0; i < threadInfo.size(); ++i) {
try {
Void _ = wait(threadInfo[i]->done.getFuture());
}
catch(Error &e) {
self->success = false;
printf("Thread %d.%d failed: %s\n", self->clientId, i, e.name());
TraceEvent(SevError, "ThreadSafety_ThreadFailed").error(e);
}
delete threadInfo[i];
}
return Void();
}
THREAD_FUNC threadStart(void *arg) {
ThreadInfo *info = (ThreadInfo*)arg;
Error error(error_code_success);
try {
info->self->runTest(info);
}
catch(Error &e) {
error = e;
}
info->self->commitBarrier.decrementNumRequired();
//Signal completion back to the main thread
onMainThreadVoid( [=]() {
if(error.code() != error_code_success)
info->done.sendError(error);
else
info->done.send(Void());
}, NULL );
THREAD_RETURN;
}
Key getRandomKey(DeterministicRandom &random) {
return StringRef(format("ThreadSafetyKey%010d", random.randomInt(0, numKeys)));
}
void runTest(ThreadInfo *info) {
//Create a new transaction
mutex.enter();
if(!tr) {
try {
tr = db->createTransaction();
}
catch(Error &) {
mutex.leave();
throw;
}
}
mutex.leave();
loop {
//Perform a sequence of random operations
for(int i = 0; i < info->random.randomInt(1, 10); ++i) {
int operation = info->random.randomInt(0, 6);
try {
if(operation == 0)
tr->set(getRandomKey(info->random), StringRef(std::string(info->random.randomInt(0, 100), 'x')));
else if(operation == 1)
tr->get(getRandomKey(info->random)).getBlocking();
else if(operation == 2)
tr->getKey(KeySelectorRef(getRandomKey(info->random), info->random.randomInt(0, 2) == 1, info->random.randomInt(-10, 11))).getBlocking();
else if(operation == 3) {
Key key1 = getRandomKey(info->random);
Key key2 = getRandomKey(info->random);
GetRangeLimits limits(info->random.randomInt(1, 1000), info->random.randomInt(1, 1e6));
tr->getRange(KeyRangeRef(std::min(key1, key2), std::max(key1, key2)), limits, info->random.randomInt(0, 2) != 0, info->random.randomInt(0, 2) != 0).getBlocking();
}
else if(operation == 4)
tr->clear(getRandomKey(info->random));
else if(operation == 5) {
Key key1 = getRandomKey(info->random);
Key key2 = getRandomKey(info->random);
tr->clear(KeyRangeRef(std::min(key1, key2), std::max(key1, key2)));
}
}
catch(Error &) {
break;
}
}
commitBarrier.reached();
// One thread starts a commit, and all threads wait on that commit
mutex.enter();
if(!commitFuture.isValid())
commitFuture = tr->commit();
ThreadFuture<Void> commit = commitFuture;
mutex.leave();
try {
commit.getBlocking();
}
catch(Error &) { }
commitBarrier.reached();
mutex.enter();
if(commitFuture.isValid())
commitFuture = ThreadFuture<Void>();
if(stopped) {
mutex.leave();
break;
}
mutex.leave();
}
}
virtual Future<bool> check(Database const& cx) {
return success;
}
virtual void getMetrics(vector<PerfMetric>& m) {
}
};
WorkloadFactory<ThreadSafetyWorkload> ThreadSafetyWorkloadFactory("ThreadSafety");