Why are the timings for the vectorized reduction for a simple Riemann sum-integral on Xeon Phi so bad?

I am new to the Xeon Phi and so I am going through the manuals trying to understand how to improve performance on the Phi using the vector registers.

Consider the short code at the end of this question which calculates the area under the curve 4/(1+x^2) on `[0,1]` using a Riemann sum. The analytic answer is pi = 3.14159....

The code basically consists of two nearly identical chunks of code which use OpenMP to calculate the answer using 4 threads. The only difference is that in the second chunk I am using the vectorized function `__sec_reduce_add()` to compute the Riemann sum of the sub-domain of [0,1] given to the thread.

The timings for the first chunk of the code is `0.0866439 s` and for the second(vectorized) chunk it is `0.0868771 s`

Why did these both yield nearly the same timings. I would have thought that using the vector register would have significantly improved the performance.

I compiled this with `icc -mmic -vec-report3 -openmp` flags

[Note: I have put a for loop with the `rpt` variable over the two sections, because rpt=0 and rpt=1 are "warm-up" loops and so will have somewhat higher timings. I have given the timings of the two sections at rpt=3]

``````#include <iostream>
#include <omp.h>
using namespace std;

int main (void)
{
int num_steps     = 2e8           ;
double dx        = 1.0/num_steps ;
double x         = 0.            ;
double* fn = new double[num_steps];

// Initialize an array containing function values
for(int i=0 ; i<num_steps ;++i )
{
fn[i] = 4.0*dx/(1.0 + x*x);
x += dx;
}

for(size_t rpt=0 ; rpt<4 ; ++rpt)
{
double start = omp_get_wtime();
double parallel_sum = 0.;
{
int begin = threadIdx * num_steps/4 ; //integer index of left-end  point of sub-interval
int end   = begin + num_steps/4     ;// integer index of right-end point of sub-interval
double dx_local = dx                ;
double temp = 0                     ;
double x    = begin*dx              ;

for (int i = begin; i < end; ++i)
{
temp += fn[i];
}
#pragma omp atomic
parallel_sum += temp;
}
double end   = omp_get_wtime();
std::cout << "\nTime taken for the parallel computation: "    << end-start << " seconds";

//%%%%%%%%%%%%%%%%%%%%%%%%%

start = omp_get_wtime();
double parallel_vector_sum = 0.;
{
int begin = threadIdx * num_steps/4 ; //integer index of left-end  point of sub-interval
int end   = begin + num_steps/4     ;// integer index of right-end point of sub-interval
double dx_local = dx                ;
double temp = 0                     ;
double x    = begin*dx              ;

#pragma omp atomic
parallel_vector_sum += temp;
}
end   = omp_get_wtime();
std::cout << "Time taken for the parallel vector computation: "    << end-start << " seconds"  ;

}// end for rpt
return 0;
}
``````
-
are you executing this code nativly on the mic? edit: the icc may auto-vectorize your for loop. try to disable auto-vectorization by using -vec- and benchmark again. –  Michael Haidl Jan 31 '14 at 7:23
Just a side node: on the Phi you need to use (much) more than 4 threads otherwise you are using only a margin of the processing power of the Phi. You need to create at as many threads as twice the number of cores to use them all fully. Assuming 60 cores on your Phi, use `num_threads(120)` or `num_threads(180)` or `num_threads(240)` –  damienfrancois Jan 31 '14 at 7:52
I suspect @kronos is correct. ICC probably detected the summation and generated a vectorized summation for you. You're likely running near identical instructions in each loop. –  pburka Jan 31 '14 at 16:31