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When I call function execution time is 6.8 sec. Call it from a thread time is 3.4 sec and when using 2 thread 1.8 sec. No matter what optimization I use rations stay same.

In Visual Studio times are like expected 3.1, 3 and 1.7 sec.

#include <time.h>

using namespace std;

#define N 400

float a[N][N];

struct b{
    int begin;
    int end;

    b b_t = *(b*)p;

    for(int i=0;i<N;i++)
        for(int j=b_t.begin;j<b_t.end;j++)
            a[i][j] = 0;
            for(int k=0;k<i;k++)

    return (0);

int main()
    clock_t t;
    HANDLE hn[2];

    b b_t[3];

    b_t[0].begin = 0;
    b_t[0].end = N;

    b_t[1].begin = 0;
    b_t[1].end = N/2;

    b_t[2].begin = N/2;
    b_t[2].end = N;

    t = clock();
    printf("0 - %d\n",clock()-t);

    t = clock();
    hn[0] = CreateThread ( NULL, 0, thread,  &b_t[0], 0, NULL);
    WaitForSingleObject(hn[0], INFINITE );
    printf("1 - %d\n",clock()-t);

    t = clock();
    hn[0] = CreateThread ( NULL, 0, thread,  &b_t[1], 0, NULL);
    hn[1] = CreateThread ( NULL, 0, thread,  &b_t[2], 0, NULL);
    WaitForMultipleObjects(2, hn, TRUE, INFINITE );
    printf("2 - %d\n",clock()-t);

    return 0;


0 - 6868
1 - 3362
2 - 1827

CPU - Core 2 Duo T9300

OS - Windows 8, 64 - bit

compiler: mingw32-g++.exe, gcc version 4.6.2


Tried different order, same result, even tried separate applications. Task Manager showing CPU Utilization around 50% for function and 1 thread and 100% for 2 thread

Sum of all elements after each call is the same: 3189909.237955

Cygwin result: 2.5, 2.5 and 2.5 sec Linux result(pthread): 3.7, 3.7 and 2.1 sec

@borisbn results: 0 - 1446 1 - 1439 2 - 721.

share|improve this question
I can feel Mysticial typing... – Seth Carnegie Jan 15 '13 at 0:25
@SethCarnegie Nah... I can't spot the problem at a glance and I don't have mingw32 installed. – Mysticial Jan 15 '13 at 0:29
Yes, try a different order, and see if that makes a difference. I bet "the first time" takes longer, rather than the thread vs no thread. – Mats Petersson Jan 15 '13 at 0:30
MinGW 4.6.2. Exactly your code. Compile options: -O2. Results: 0 - 1446 1 - 1439 2 - 721. The same results with std::thread. I tried to run thread before function call, I moved float a[N][N]; inside struct b - the result didn't change – borisbn Jan 15 '13 at 5:42
@user1978768 here is an exe-file, compiled by my mingw from your code - – borisbn Jan 15 '13 at 13:57
up vote 6 down vote accepted

The difference is a result of something in the math library implementing sin() and cos() - if you replace the calls to those functions with something else that takes time the significant difference between step and 0 and step 1 goes away.

Note that I see the difference with gcc (tdm-1) 4.6.1, which is a 32-bit toolchain targeting 32 bit binaries. Optimization makes no difference (not surprising since it seems to be something in the math library).

However, if I build using gcc (tdm64-1) 4.6.1, which is a 64-bit toolchain, the difference does not appear - regardless if the build is creating a 32-bit program (using the -m32 option) or a 64-bit program (-m64).

Here are some example test runs (I made minor modifications to the source to make it C99 compatible):

  • Using the 32-bit TDM MinGW 4.6.1 compiler:

    C:\temp>gcc --version
    gcc (tdm-1) 4.6.1
    C:\temp>gcc -m32 -std=gnu99 -o test.exe test.c
    0 - 4082
    1 - 2439
    2 - 1238
  • Using the 64-bit TDM 4.6.1 compiler:

    C:\temp>gcc --version
    gcc (tdm64-1) 4.6.1
    C:\temp>gcc -m32 -std=gnu99 -o test.exe test.c
    0 - 2506
    1 - 2476
    2 - 1254
    C:\temp>gcc -m64 -std=gnu99 -o test.exe test.c
    0 - 3031
    1 - 3031
    2 - 1539

A little more information:

The 32-bit TDM distribution (gcc (tdm-1) 4.6.1) links to the sin()/cos() implementations in the msvcrt.dll system DLL via a provided import library:

                0x004a113c                _imp__cos

While the 64-bit distribution (gcc (tdm64-1) 4.6.1) doesn't appear to do that, instead linking to some static library implementation provided with the distribution:

                              C:\Users\mikeb\AppData\Local\Temp\cc3pk20i.o (cos)


After a bit of spelunking in a debugger stepping through the assembly of msvcrt.dll's implementation of cos() I've found that the difference in the timing of the main thread versus an explicitly created thread is due to the FPU's precision being set to a non-default setting (presumably the MinGW runtime in question does this at start up). In the situation where the thread() function takes twice as long, the FPU is set to 64-bit precision (REAL10 or in MSVC-speak _PC_64). When the FPU control word is something other than 0x27f (the default state?), the msvcrt.dll runtime will perform the following steps in the sin() and cos() function (and probably other floating point functions):

  • save the current FPU control word
  • set the FPU control word to 0x27f (I believe it's possible for this value to be modified)
  • perform the fsin/fcos operation
  • restore the saved FPU control word

The save/restore of the FPU control word is skipped if it's already set to the expected/desired 0x27f value. Apparently saving/restoring the FPU control word is expensive, since it appears to double the amount of time the function takes.

You can solve the problem by adding the following line to main() before calling thread():

_control87( _PC_53, _MCW_PC);   // requires <float.h>
share|improve this answer
The answer has been updated with a more precise culprit to the problem. – Michael Burr Jan 16 '13 at 22:38
+1 very nicely worked out. But what could be the purpose for MinGW to have these weird settings, to let 'main thread' and 'user created threads` have a different FPU precision? – Arno Jan 17 '13 at 10:24
@Arno: I don't know why some MinGW builds set the FP precision to 64-bit. And as far as the precision setting for created threads - that's a Windows detail of not 'inheriting' the FP precision when a thread is created - MinGW's library isn't involved in CreateThread(). And It seems to me to be a bug in msvcrt.dll to reduce the precision when performing the fcos/fsin operation (I imagine the safe/modify/restore precision logic was intended to make sure the operation wasn't done with the FPU set to single precision). – Michael Burr Jan 17 '13 at 15:55

Not a cache matterhere.

Likely different runtime libraries for user created threads and main thread. You may compare the calculations a[i][j]+=k*sin(j)-j*cos(k); in detail (numbers) for specific values of i, j, and k to confirm differences.

share|improve this answer
Sum of all elements after each call is the same: 3189909.237955 – user1978768 Jan 15 '13 at 9:55
Pls. checkout the RTL selection here and verify which one you are using. MinGW defines MSVCRT_VERSION". – Arno Jan 15 '13 at 14:51
# define MSVCRT_VERSION 0x0600 – user1978768 Jan 15 '13 at 18:46
seeing that you accepted the answer telling that you're facing a library problem which was my initial thought, I'd suggest to compile with -D__MSVCRT_VERSION__=0x0601 since you're running Windows 8 – Arno Jan 16 '13 at 13:02

The reason is the main thread is doing 64 bit float math and the threads are doing 53 bit math.

You can know this / fix it by changing the code to

extern "C" unsigned int _control87( unsigned int newv, unsigned int mask );

    printf( "_control87(): 0x%.4x\n", _control87( 0, 0 ) );

The output will be:

_control87(): 0x8001f
0 - 2667
_control87(): 0x9001f
1 - 2683
_control87(): 0x9001f
_control87(): 0x9001f
2 - 1373

c:\temp>mingw32-c++ --version
mingw32-c++ (GCC) 4.6.2

You can see that 0 was going to run w/o the 0x10000 flag, but once set, runs at the same speed as 1 & 2. If you look up the _control87() function, you'll see that this value is the _PC_53 flag, which sets the precision to be 53 instead of 64 had it been left as zero.

For some reason, Mingw isn't setting it to the same value at process init time that CreateThread() does at thread create time.

Another work around it to turn on SSE2 with _set_SSE2_enable(1), which will run even faster, but may give different results.

0 - 1341
1 - 1326
2 - 702

I believe this is on by default for the 64 bit because all 64 bit processors support SSE2.

share|improve this answer

As others suggested, change the order of your three tests to get some more insight. Also, the fact that you have a multi-core machine pretty well explains why using two threads doing half the work each takes half the time. Take a look at your CPU usage monitor (Control-Shift-Escape) to find out how many cores are maxed out during the running time.

share|improve this answer
Tried different order, same result, even tried separate applications. Task Manager showing CPU Utilization around 50% for function and 1 thread and 100% for 2 thread – user1978768 Jan 15 '13 at 9:55

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