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I have written this test application: it goes through iterations from 0 to 9999, for each integer in the range it calculates some useless but calculation-intensive function. As a result the program outputs the sum of function values. To make it run on several threads I'm using InterlockedIncrement - if after increment the iteration number is <10000 then a thread processes this iteration, otherwise it terminates.

I am wondering why it is not scaling as well as I would like it to. With 5 threads it runs 8s versus 36s with a single thread. This gives ~4.5 scalability. During my experiments with OpenMP (on slightly different problems) I was getting much better scalability.

The source code is shown below.

I am running Windows7 OS on a Phenom II X6 desktop. Don't know what other parameters might be relevant.

Could you please help me explain this sub-optimal scalability? Many thanks.

#include <boost/thread.hpp>
#include <boost/shared_ptr.hpp>
#include <boost/make_shared.hpp>
#include <vector>
#include <windows.h>
#include <iostream>
#include <cmath>

using namespace std;
using namespace boost;

struct sThreadData
  sThreadData() : iterCount(0), value( 0.0 ) {}
  unsigned iterCount;
  double value;

volatile LONG g_globalCounter;
const LONG g_maxIter = 10000;

void ThreadProc( shared_ptr<sThreadData> data )
  double threadValue = 0.0;
  unsigned threadCount = 0;

  while( true )
    LONG iterIndex = InterlockedIncrement( &g_globalCounter );
    if( iterIndex >= g_maxIter )


    double value = iterIndex * 0.12345777;
    for( unsigned i = 0; i < 100000; ++i )
      value = sqrt( value * log(1.0 + value) );

    threadValue += value;

  data->value = threadValue;
  data->iterCount = threadCount;

int main()
  const unsigned threadCount = 1;

  vector< shared_ptr<sThreadData> > threadData;
  for( unsigned i = 0; i < threadCount; ++i )
    threadData.push_back( make_shared<sThreadData>() );

  g_globalCounter = 0;

  DWORD t1 = GetTickCount();
  vector< shared_ptr<thread> > threads;
  for( unsigned i = 0; i < threadCount; ++i )
    threads.push_back( make_shared<thread>( &ThreadProc, threadData[i] ) );

  double sum = 0.0;
  for( unsigned i = 0; i < threadData.size(); ++i )
    sum += threadData[i]->value;

  DWORD t2 = GetTickCount();
  cout << "T=" << static_cast<double>(t2 - t1) / 1000.0 << "s\n";

  cout << "Sum= " << sum << "\n";
  for( unsigned i = 0; i < threadData.size(); ++i )
    cout << threadData[i]->iterCount << "\n";

  return 0;

Edit: Attaching sample output of this test program (1 and 5 threads): enter image description here

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Have you tried splitting the tasks beforehand instead of having the threads access shared state? – Jonas Wielicki Oct 11 '12 at 11:45
Thanks for reading this. By shared state do you mean the g_globalCounter variable? No, I haven't tried that. My assuption was that first-come-first-serve would give optimal load balancing. I have tried increasing the number of value = sqrt( value * log(1.0 + value) ); iterations 10 times (this should reduce contention on the iteration counter). The results were 80.43s versus 358s - so I don't think the shared state is causing this. – Alexander Chertov Oct 11 '12 at 11:51
Next bad guess <g> how are sqrt/log implemented? FPU contention, maybe? – Martin James Oct 11 '12 at 12:31
@j_random_hacker, I have changed the function interface to 'void ThreadProc( shared_ptr<sThreadData> data, unsigned iStart, unsigned iEnd )'. No speedup, same old 36s vs 8s. – Alexander Chertov Oct 11 '12 at 13:09
Thanks (I assume you got rid of the InterlockedIncrement() too). I think it was worthwhile eliminating that as a possible cause. But in that case, I'm baffled! AFAIK each CPU has its own FPU (and SSE registers), so I can't see how there would be FP contention as Martin suggested. Do you have other programs running in the background? If you start 5 simultaneous instances of a single-threaded program that only does g_maxIter / 5 iterations, do they each take longer than if you only start 1? – j_random_hacker Oct 11 '12 at 13:18

1 Answer 1

up vote 2 down vote accepted

It turned out the the results can be explained by the fact that my CPU supports the AMD Turbo Core technology.

While in Turbo CORE mode, the AMD Phenom™ II X6 1090T shifts frequency speed from 3.2GHz on six cores, to 3.6GHz on three cores

So the clock frequencies were not the same in single-threaded mode and multi-threaded mode. I was used to playing aroung with multithreading on CPUs that don't support TurboCore. Below is an image that shows results of

  • AMD OverDrive utility window (a thing that allows to toggle TurboCore on/off)
  • a run with 1 threads with TurboCore ON
  • a run with 1 threads with TurboCore OFF
  • a run with 5 threads enter image description here

Many thanks to people who tried to help.

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