# When performing a calculation - how many threads should I open?

I am writing a program that performs some long computation, which I can break into as many tasks as I want. For the sake of discussion, let's suppose I am writing an algorithm for finding whether or not a number p is prime by trying to divide it by all numbers between 2 and p-1. This task can obviously be broken down to many threads.

I actually wrote a sample app that does just that. As a parameter, I give the number I want to check for, and the number of threads to use (each thread is given a range of equal size of numbers to try and divide p by - together they cover the entire range).

My machine has 8 cores. I started running the program with a large number that I know is prime (2971215073), and with 1, 2, 3 threads etc. until reaching 8 threads - each time the program ran faster than the previous, which was what I expected. However, when I tried numbers larger than 8, the computation time actually kept getting smaller (even if by a little)!

There's no I/O or anything like that in my threads, just pure cpu computations. I was expecting the run-time to become worse when I passed 8 threads as there would be more context switching and the number of parallel running threads remains at 8. It is hard to say where the peak is as the differences are very little and change from one run to another, however it is clear that i.e. 50 threads somehow runs faster than 8 (by ~300 ms)...

My guess is that since I have so many threads, I get more running time since I have a larger portion in the system's thread pool, so my threads get selected more. However, it doesn't seem to make sense that the more threads I create, the faster the program runs (otherwise why don't everyone create 1000 threads??).

Can anyone offer an explanation, and perhaps a best-practice as to how many threads to create relative to the number of cores on the machine?

Thanks.

My code for whoever's interested (compiled on Windows, VS2012):

``````#include <Windows.h>
#include <conio.h>
#include <iostream>
#include <vector>

using namespace std;

typedef struct
{
unsigned int primeCandidate;
unsigned int rangeStart;
unsigned int rangeEnd;
} param_t;

DWORD WINAPI isDivisible(LPVOID p)
{
param_t* param = reinterpret_cast<param_t*>(p);

for (unsigned int d = param->rangeStart; d < param->rangeEnd; ++d)
{
if (param->primeCandidate % d == 0)
{
cout << param->primeCandidate << " is divisible by " << d << endl;
return 1;
}
}

return 0;
}

bool isPrime(unsigned int primeCandidate, unsigned int numOfCores)
{
vector<HANDLE> handles(numOfCores);
vector<param_t> params(numOfCores);
for (unsigned int i = 0; i < numOfCores; ++i)
{
params[i].primeCandidate = primeCandidate;
params[i].rangeStart = (primeCandidate - 2) * (static_cast<double>(i) / numOfCores) + 2;
params[i].rangeEnd = (primeCandidate - 2) * (static_cast<double>(i+1) / numOfCores) + 2;
HANDLE h = CreateThread(nullptr, 0, reinterpret_cast<LPTHREAD_START_ROUTINE>(isDivisible), &params[i], 0, 0);
if (NULL == h)
{
cout << "ERROR creating thread: " << GetLastError() << endl;
throw exception();
}
handles[i] = h;
}

DWORD ret = WaitForMultipleObjects(numOfCores, &handles[0], TRUE, INFINITE);
if (ret >= WAIT_OBJECT_0 && ret <= WAIT_OBJECT_0 + numOfCores - 1)
{
for (unsigned int i = 0; i < numOfCores; ++i)
{
DWORD exitCode = -1;
if (0 == GetExitCodeThread(handles[i], &exitCode))
{
cout << "Failed to get thread's exit code: " << GetLastError() << endl;
throw exception();
}

if (1 == exitCode)
{
return false;
}
}

return true;
}
else
{
cout << "ERROR waiting on threads: " << ret << endl;
throw exception();
}
}

int main()
{
unsigned int primeCandidate = 1;
unsigned int numOfCores = 1;

cout << "Enter prime candidate: ";
cin >> primeCandidate;
cout << "Enter # of cores (0 means all): ";
cin >> numOfCores;
while (primeCandidate > 0)
{
if (0 == numOfCores) numOfCores = thread::hardware_concurrency();

DWORD start = GetTickCount();
bool res = isPrime(primeCandidate, numOfCores);
DWORD end = GetTickCount();
cout << "Time: " << end-start << endl;
cout << primeCandidate << " is " << (res ? "" : "not ") << "prime!" << endl;

cout << "Enter prime candidate: ";
cin >> primeCandidate;
cout << "Enter # of cores (0 means all): ";
cin >> numOfCores;
}

return 0;
}
``````
-
Good question. Could you post or link to your test code? Also, I would suggest doing a test using std::async to see how it compares. I think the majority of threading in the future will use std::async instead of managing threads directly. –  Dave Jun 15 at 12:52
@E.K. to validate your hypothesis is would be interesting to run your program on an idle system, because if you run your browser, IDE and WoW at the same time there could be some strange side effects like the one you describe ;) Anyway really interesting :) +1 –  Pragmateek Jun 15 at 13:03
How did you split the sequence? by contiguous renges or by overlapping the whole range? (I mean (1,2,3,4),(5,6,7,8) or (1,3,5,7),(2,4,6,8)) –  Emilio Garavaglia Jun 15 at 13:28
First of all, it prints `4 is prime` for me. –  Lol4t0 Jun 15 at 13:34
@Pragmateek - yes, I have seen the same behaviour and, like you, I guessed that the improvement was just the 'base load' being displaced somewhat by the extra threads. I may try running the tests again, but with the priority set really low, so that the base load is not displaced. –  Martin James Jun 15 at 13:35
show 4 more comments

Yes. Here is a small extract of some tests I did on my i7/Vista 64 box, (4 'real' cores + hyperthreading):

``````8 tests,
counting to 10000000,
Ticks: 2199
Ticks: 2184
Ticks: 2215
Ticks: 2153
Ticks: 2200
Ticks: 2215
Ticks: 2200
Ticks: 2230
Average: 2199 ms

8 tests,
counting to 10000000,
Ticks: 2137
Ticks: 2121
Ticks: 2153
Ticks: 2138
Ticks: 2137
Ticks: 2121
Ticks: 2153
Ticks: 2137
Average: 2137 ms
``````

.. showing that, like in your tests, an 'over-subscription' of threads does result in a marginal 2-3% improvement in overall execution time. My tests submitted simple 'count up an integer' CPU-intensive tasks to a threadpool with varying numbers of threads.

My conclusion at the time was that the minor improvement was because the larger number of threads took up a larger %age of the 'base load' on my box - the 1-4% of load from the few of the 1000-odd threads in the nearly-always-idle Firefox, uTorrent, Word, Taskbar etc etc. that happened to run a bit during the tests.

It would appear that, in my test, the 'context switching overhead' from, say, using 64 threads instead of 8 is negligible, and can be ignored.

This only applies when the data used by the tasks is very small. I later repeated a similar batch of tests where the tasks used an 8K array - the size of the L1 cache. In this 'worst case' scenario, using more threads than cores resulted in a very noticeable slowdown until, at 16 threads and above, the performance dropped by 40% as the threads swapped the whole cache in and out. Above about 20 threads, the slowdown did not get any worse since, no matter how many threads ran the tasks, the cache still got swapped out of every core at the same rate.

Note also that I had plenty of RAM and so very few page faults.

-
Thanks for the benchmark. +1 –  Pragmateek Jun 15 at 13:40
So what is the conclusion then? If my threads don't take up a lot of memory - create as many as I can to receive best performance?? –  E.K. Jun 15 at 14:25
Well... for my tests there is not really a worth-while improvement with the larger number of threads. Given a real app like this, I would probably just run with 64 threads, knowing that the performance will scale nicely with available cores up to 64, without any 'tweaking' of the pool size to match the number of cores. 64 threads also seems to be a good number for tasks that block, eg. a web-crawler. The only solid advice I might offer is to use threadpools and make the thread count configurable/tweakable or, ultimately, use some heuristic algorithm to continually optimize the count. –  Martin James Jun 15 at 15:22