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I have a piece of code that I use to test various containers (e.g. deque and a circular buffer) when passing data from a producer (thread 1) to a consumer (thread 2). A data is represented by a struct with a pair of timestamps. First timestamp is taken before push in the producer, and the second one is taken when data is popped by the consumer. The container is protected with a pthread spinlock.

The machine runs redhat 5.5 with 2.6.18 kernel (old!), it is a 4-core system with hyperthreading disabled. gcc 4.7 with -std=c++11 flag was used in all tests.

Producer acquires the lock, timestamps the data and pushes it into the queue, unlocks and sleeps in a busy loop for 2 microseconds (the only reliable way I found to sleep for precisely 2 micros on that system).

Consumer locks, pops the data, timestamps it and generates some statistics (running mean delay and standard deviation). The stats is printed every 5 seconds (M is the mean, M2 is the std dev) and reset. I used gettimeofday() to obtain the timestamps, which means that the mean delay number can be thought of as the percentage of delays that exceed 1 microsecond.

Most of the time the output looks like this:

    CNT=2500000 M=0.00935 M2=0.910238
    CNT=2500000 M=0.0204112 M2=1.57601
    CNT=2500000 M=0.0045016 M2=0.372065

but sometimes (probably 1 trial out of 20) like this:

    CNT=2500000 M=0.523413 M2=4.83898
    CNT=2500000 M=0.558525 M2=4.98872
    CNT=2500000 M=0.581157 M2=5.05889

(note the mean number is much worse than in the first case, and it never recovers as the program runs).

I would appreciate thoughts on why this could happen. Thanks.

#include <iostream>
#include <string.h>
#include <stdexcept>
#include <sys/time.h>
#include <deque>
#include <thread>
#include <cstdint>
#include <cmath>
#include <unistd.h>
#include <xmmintrin.h> // _mm_pause()

int64_t timestamp() {
    struct timeval tv;
    gettimeofday(&tv, 0);
    return 1000000L * tv.tv_sec + tv.tv_usec;
}

//running mean and a second moment
struct StatsM2 {
    StatsM2() {}
    double m = 0;
    double m2 = 0;
    long count = 0;
    inline void update(long x, long c) {
        count = c;
        double delta = x - m;
        m += delta / count;
        m2 += delta * (x - m);
    }
    inline void reset() {
        m = m2 = 0;
        count = 0;
    }
    inline double getM2() { // running second moment
        return (count > 1) ? m2 / (count - 1) : 0.;
    }
    inline double getDeviation() {
        return std::sqrt(getM2() );
    }
    inline double getM() { // running mean
        return m;
    }
};

// pause for usec microseconds using busy loop
int64_t busyloop_microsec_sleep(unsigned long usec) {
    int64_t t, tend;
    tend = t = timestamp();
    tend += usec;
    while (t < tend) {
        t = timestamp();
    }
    return t;
}

struct Data {
    Data() : time_produced(timestamp() ) {}
    int64_t time_produced;
    int64_t time_consumed;
};

int64_t sleep_interval = 2;
StatsM2 statsm2;
std::deque<Data> queue;
bool producer_running = true;
bool consumer_running = true;
pthread_spinlock_t spin;

void producer() {
    producer_running = true;
    while(producer_running) {
        pthread_spin_lock(&spin);
        queue.push_back(Data() );
        pthread_spin_unlock(&spin);
        busyloop_microsec_sleep(sleep_interval);
    }
}

void consumer() {
    int64_t count = 0;
    int64_t print_at = 1000000/sleep_interval * 5;
    Data data;
    consumer_running = true;
    while (consumer_running) {
        pthread_spin_lock(&spin);
        if (queue.empty() ) {
            pthread_spin_unlock(&spin);
            // _mm_pause();
            continue;
        }
        data = queue.front();
        queue.pop_front();
        pthread_spin_unlock(&spin);
        ++count;
        data.time_consumed = timestamp();
        statsm2.update(data.time_consumed - data.time_produced, count);
        if (count >= print_at) {
            std::cerr << "CNT=" << count << " M=" << statsm2.getM() << " M2=" << statsm2.getDeviation() << "\n";
            statsm2.reset();
            count = 0;
        }
    }
}

int main(void) {
    if (pthread_spin_init(&spin, PTHREAD_PROCESS_PRIVATE) < 0)
        exit(2);
    std::thread consumer_thread(consumer);
    std::thread producer_thread(producer);
    sleep(40);
    consumer_running = false;
    producer_running = false;
    consumer_thread.join();
    producer_thread.join();
    return 0;
}
share|improve this question
    
Nice room heater. –  Martin James Jan 30 at 10:17
    
Try to record the full data set that make up the stats to track this down. It is conceivable that you get these because of garbage in the data. While the dequeue is not thread safe, you shouldn’t need volatile on the face of it - because the lock is supposed to issue the barriers. Nevertheless maybe the compiler is still moving the variable around – hard to say without looking at the disassembly. Mark the dequeue volatile to see if it helps. –  mockinterface Feb 3 at 8:58
    
I recorded the data, it is consistent, and unfortunately volatile didn't help. Thank you for your suggestions. –  Cattus Feb 4 at 16:47
    
I would add that the throughput suffers as well; when things run ok, I can pump millions of messages through the queue, when timings are bad, the count is in the tens of thousands. –  Cattus Feb 4 at 21:17

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