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I just had a (to me) very odd observation and want to know how this can be. I tested the following two versions of code:

chrono::steady_clock::time_point t1 = chrono::steady_clock::now();
process_data(l, 8);
chrono::steady_clock::time_point t2 = chrono::steady_clock::now();
chrono::duration<double> time_span = chrono::duration_cast<chrono::duration<double>>(t2 - t1);
cout << "time used: " << time_span.count() << endl;

vs

chrono::steady_clock::time_point t1 = chrono::steady_clock::now();
thread t1 = thread(process_data, l, 8);
t1.join();
chrono::steady_clock::time_point t2 = chrono::steady_clock::now();
chrono::duration<double> time_span = chrono::duration_cast<chrono::duration<double>>(t2 - t1);
cout << "time used: " << time_span.count() << endl;

For reasons I don't understand, the second version is 20% faster...

How can this be? The chrono::steady_clock should measure the time correctly, I think... But then I fail to see how creating another thread, and waiting for it can actually be faster then doing it with the initial thread. What am I missing?

Some details: there is no code besides the definition of l before above posted snippets, and no other calculations comes after it (it is the main function) and process_data() is just a massive number-cruncher, including some file-reading operations (no threads used there).

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    i'm using visual studio pro 2013, and i'm measuring it in 2 programs
    – Mahrgell
    May 6, 2014 at 11:52
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    what you could try is to average it over multiple executions, to get a more acurate result. I had the experience that execution time can vary from time to time, especially for short running programs. Also, I had the problem once that I was using a notebook for testing, where battery saving functions made measurements unreliable, even in performance mode.
    – MatthiasB
    May 6, 2014 at 12:02
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    I tried it over 100 runs each, the first code takes 7,7 secs on average, the second one 6,5 secs.
    – Mahrgell
    May 6, 2014 at 12:07
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    Is there any possibility that every time you run the second test the file data happens to be in memory, and every time you run the first test the file data is not in memory? Is there any possibility of NUMA effects on the machine you are using?
    – kec
    May 6, 2014 at 12:28
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    Do both threads have the same affinity? Priority? Allowing a 6-second computation to proceed on a CPU for which the OS is not competing can reduce time-to-completion. Wrap the whole thing in an additional thread and the 'benefit' to multithreading might go away.
    – AndrewS
    May 14, 2014 at 19:54

1 Answer 1

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The only overhead you got is the thread creation , since your main thread will just sleep until the join.

The thread creation overhead is meaningless compared to your process_data , considering that your program takes 7,7 or 6,5 seconds to run.

So your question can now become : How come a worker thread is faster then the main thread ?

There are many reasons why this could happen , couple that go through my mind :

  • When you are creating the new thread he gets lucky and ends up on a core all by itself
  • There are watchers added by the OS/other programs on your main thread -> which result in the comp running slower as a whole when your main thread isn't idle

The OS / other programs usually go after the main thread of a process for communication, watching etc. so it's not unusual for a main thread to be slower then a worker thread for big data processing.

Even if the thread is a higher priority thread, it doesn't guarantee that things on that thread will move faster.

Here's another similar question: Why main thread is slower than worker thread in pthread-win32?

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