static void *
workerLoop(UA_Worker *worker) {
UA_Server *server = worker->server;
UA_UInt32 *counter = &worker->counter;
volatile UA_Boolean *running = &worker->running;
/* Initialize the (thread local) random seed with the ram address of worker */
UA_random_seed((uintptr_t)worker);
rcu_register_thread();
pthread_mutex_t mutex; // required for the condition variable
pthread_mutex_init(&mutex, 0);
pthread_mutex_lock(&mutex);
while(*running) {
struct DispatchJob *dj = (struct DispatchJob*)
cds_wfcq_dequeue_blocking(&server->dispatchQueue_head, &server->dispatchQueue_tail);
if(dj) {
processJob(server, &dj->job);
UA_free(dj);
} else {
/* nothing to do. sleep until a job is dispatched (and wakes up all worker threads) */
pthread_cond_wait(&server->dispatchQueue_condition, &mutex);
}
uatomic_inc(counter);
}
pthread_mutex_unlock(&mutex);
pthread_mutex_destroy(&mutex);
UA_ASSERT_RCU_UNLOCKED();
rcu_barrier(); // wait for all scheduled call_rcu work to complete
rcu_unregister_thread();
return NULL;
}
DWORD WINAPI ThreadPool::WorkerThread(LPVOID lpParam)
{
CoInitialize(NULL);
ThreadPool *obj = (ThreadPool *)lpParam;
CARBONLOG_CLASS_PTR logger(carbonLogger::getLoggerPtr());
CARBONLOG_INFO(logger, "[WorkerThread] : starting worker thread now..");
while(obj->shouldContinue)
{
std::string jobMsg, jobOutput;
if(obj->getJobMsg(jobMsg))
{
CARBONLOG_DEBUG(logger, "[WorkerThread] : Processing job ..");
processJob(jobMsg,jobOutput);
if(!obj->writeJobOutput(jobOutput))
CARBONLOG_ERROR(logger, "[WorkerThread] : Failed to write packet to BI");
}
else
Sleep(10);
}
CARBONLOG_INFO(logger, "[WorkerThread] : exiting worker thread now..");
CoUninitialize();
return 0;
}
static void
emptyDispatchQueue(UA_Server *server) {
while(!cds_wfcq_empty(&server->dispatchQueue_head, &server->dispatchQueue_tail)) {
struct DispatchJob *dj = (struct DispatchJob*)
cds_wfcq_dequeue_blocking(&server->dispatchQueue_head, &server->dispatchQueue_tail);
processJob(server, &dj->job);
UA_free(dj);
}
}
workload_result_t processWorkload(int * workload, int workloadSize) {
workload_result_t result;
job_eval_result_t jobResult;
memset(&result, 0, sizeof(workload_result_t));
// Worst case scenario we get all type 2 jobs and they give us a maximum number of integers.
int i;
for(i = 0; i < workloadSize; i++) {
jobResult = processJob(workload[i]);
result.integerArray = appendToArray(result.integerArray, jobResult.job_result.job_results, jobResult.job_result.results_size, result.arraySize);
result.arraySize += jobResult.job_result.results_size;
switch(workload[i]) {
case 0:
result.type0ProcessingTime += jobResult.sleepTime;
break;
case 1:
result.type1ProcessingTime += jobResult.sleepTime;
break;
case 2:
result.type2ProcessingTime += jobResult.sleepTime;
break;
}
}
return result;
}
/** parse messages (internal or IM messages), they are already decoded */
static F2FError parseBuffer(F2FPeer *srcPeer, F2FPeer *dstPeer, F2FGroup *group,
F2FMessageType type, const char * buffer, F2FSize buffersize )
{
F2FError error;
/* TODO: evaluate fromPeer to the source Peer sent in the message
* for doing the proper routing */
if( group == NULL ) /* group unknown */
return F2FErrNotFound;
/* srcPeer can be null, if it was an invite answer,
* where the actual source is not known */
if( srcPeer != NULL ) /* is in the local peer list */
srcPeer->lastActivity = time(NULL); // update timestamp
/* TODO: Check length of the message extensions, should match! */
/* process different messages */
F2FSize mesExtLen = buffersize;
if(mesExtLen > F2FMaxMessageSize)
mesExtLen = F2FMaxMessageSize;
const char * mesExt = buffer/* + sizeof( F2FMessageHeader ) obsolet */;
switch ( type )
{
case F2FMessageTypeInviteAnswer:
error = processInviteMessageAnswer(
group, srcPeer, dstPeer,
(F2FMessageInviteAnswer *) mesExt );
if( error != F2FErrOK ) return error;
break;
case F2FMessageTypeInvite:
error = processInviteMessage(
group, srcPeer, dstPeer,
(F2FMessageInvite *) mesExt);
if( error != F2FErrOK ) return error;
break;
case F2FMessageTypeRaw:
fillAdapterReceiveBuffer(F2FAdapterReceiveMessageTypeData,
group->id.hi, group->id.lo, srcPeer->id.hi, srcPeer->id.lo,
dstPeer->id.hi, dstPeer->id.lo, type,
mesExt, mesExtLen );
// they are parsed now return F2FErrNotParsed;
return F2FErrOK;
break;
case F2FMessageTypeText:
fillAdapterReceiveBuffer(F2FAdapterReceiveMessageTypeData,
group->id.hi, group->id.lo, srcPeer->id.hi, srcPeer->id.lo,
dstPeer->id.hi, dstPeer->id.lo, type,
mesExt, mesExtLen );
// they are parsed now return F2FErrNotParsed;
return F2FErrOK;
break;
case F2FMessageTypeGetJobTicket:
error = processGetJobTicket(
group, srcPeer, dstPeer,
(F2FMessageGetJobTicket *) mesExt);
if( error != F2FErrOK ) return error;
break;
case F2FMessageTypeGetJobTicketAnswer:
error = processGetJobTicketAnswer(
group, srcPeer, dstPeer,
(F2FMessageGetJobTicketAnswer *) mesExt);
if( error != F2FErrOK ) return error;
break;
case F2FMessageTypeJob:
error = processJob(
group, srcPeer, dstPeer,
(F2FMessageJob *) mesExt);
if( error != F2FErrOK ) return error;
// they are parsed now else return F2FErrNotParsed;
return F2FErrOK;
break;
case F2FMessageTypeAnnounceNewPeerInGroup:
error = processAnnounceNewPeerInGroup(
group, srcPeer, dstPeer,
(F2FMessageAnnounceNewPeerInGroup *) mesExt);
if( error != F2FErrOK ) return error;
break;
case F2FMessageTypePeerListInfo:
error = processPeerListInfo(
group, srcPeer, dstPeer,
(F2FMessagePeerListInfo *) mesExt);
if( error != F2FErrOK ) return error;
break;
default:
return F2FErrMessageTypeUnknown;
break;
}
return F2FErrOK;
}
