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I tried to parallel a piece of code with OPENMP, but with increasing the number of processors, the code runs slower.!

call OMP_set_num_threads(1)-->16.7sec

call OMP_set_num_threads(4)-->17.7sec

call OMP_set_num_threads(8)-->19sec

System SPEC

Intel Corei7 3610QM 2.3GH up to 3.2GH with 4 cores and 8 threads ///8GB ram DDR3

call OMP_set_num_threads(8)
!$omp parallel 
!$omp do private(k,i,j,r,epsilonxx,epsilonyy,epsilonxy,epsilonzz,epsilonxz,&
 epsilonyz)  reduction(+:dr)

    do k=1,niac
      i = pair_i(k)
      j = pair_j(k)
    dx(1) = x(1,j) - x(1,i)
        dr  = dx(1)*dx(1)

    do d=2,dim
        dx(d) = x(d,j) - x(d,i)
        dr    = dr + dx(d)*dx(d)

    enddo

    r = sqrt(dr)

       do d=1,dim
        dvx(d) = vx(d,j) - vx(d,i)
       enddo


 if (dim.eq.3) then
      if((abs(itype(i)).gt.1000 .and. abs(itype(j)).gt.1000 ) ) then
      epsilonxx  =  dvx(1)*dwdx(1,k)
      epsilonyy  =  dvx(2)*dwdx(2,k)
      epsilonxy  =  (1/2.)*(dvx(1)*dwdx(2,k)+dvx(2)*dwdx(1,k))
      epsilonzz  =  dvx(dim)*dwdx(dim,k)
      epsilonxz  =  (1/2.)*(dvx(1)*dwdx(dim,k)+dvx(dim)*dwdx(1,k))
      epsilonyz  =  (1/2.)*(dvx(2)*dwdx(dim,k)+dvx(dim)*dwdx(2,k))

       epsxx(i) = epsxx(i) + mass(j)*epsilonxx/rho(j)
       epsxx(j) = epsxx(j) + mass(i)*epsilonxx/rho(i)
       epsyy(i) = epsyy(i) + mass(j)*epsilonyy/rho(j)
       epsyy(j) = epsyy(j) + mass(i)*epsilonyy/rho(i)
       epsxy(i) = epsxy(i) + mass(j)*epsilonxy/rho(j)
       epsxy(j) = epsxy(j) + mass(i)*epsilonxy/rho(i)
           epszz(i) = epszz(i) + mass(j)*epsilonzz/rho(j)
           epszz(j) = epszz(j) + mass(i)*epsilonzz/rho(i)
           epsxz(i) = epsxz(i) + mass(j)*epsilonxz/rho(j)
           epsxz(j) = epsxz(j) + mass(i)*epsilonxz/rho(i)
           epsyz(i) = epsyz(i) + mass(j)*epsilonyz/rho(j)
           epsyz(j) = epsyz(j) + mass(i)*epsilonyz/rho(i)


  elseif( (abs(itype(i)).lt.1000 ) .and. (abs(itype(j)).gt.1000 )  ) then


      epsilonxx_interface(i)  =(2/3.)*(2.e0*dvx(1)*dwdx(1,k) 
      epsilonxx_interface(j)  =dvx(1)*dwdx(1,k)
      epsilonyy_interface(i)  =(2/3.)*(2.e0*dvx(2)*dwdx(2,k)     
      epsilonyy_interface(j)  =dvx(2)*dwdx(2,k) 
      epsilonxy_interface(i)  =dvx(1)*dwdx(2,k) + dvx(2)*dwdx(1,k)  
      epsilonxy_interface(j)  =(1/2.)*(dvx(1)*dwdx(2,k)+dvx(2)*dwdx(1,k)) 
      epsilonzz_interface(i)  =(2/3.)*(2.e0*dvx(dim)*dwdx(dim,k)
      epsilonzz_interface(j)  =dvx(dim)*dwdx(dim,k)                  epsilonxz_interface(i)   =dvx(1)*dwdx(dim,k) + dvx(dim)*dwdx(1,k)              
      epsilonxz_interface(j)  =(1/2.)*(dvx(1)*dwdx(dim,k)+dvx(dim)*dwdx(1,k))   
      epsilonyz_interface(i)  =dvx(2)*dwdx(dim,k) + dvx(dim)*dwdx(2,k)  
      epsilonyz_interface(j)  =(1/2.)*(dvx(2)*dwdx(dim,k)+dvx(dim)*dwdx(2,k)) 


               epsxx(i) = epsxx(i) + mass(j)*epsilonxx_interface(i)/rho(j)
       epsxx(j) = epsxx(j) + mass(i)*epsilonxx_interface(j)/rho(i)
       epsyy(i) = epsyy(i) + mass(j)*epsilonyy_interface(i)/rho(j)
       epsyy(j) = epsyy(j) + mass(i)*epsilonyy_interface(j)/rho(i)
       epsxy(i) = epsxy(i) + mass(j)*epsilonxy_interface(i)/rho(j)
       epsxy(j) = epsxy(j) + mass(i)*epsilonxy_interface(j)/rho(i)
           epszz(i) = epszz(i) + mass(j)*epsilonzz_interface(i)/rho(j)
           epszz(j) = epszz(j) + mass(i)*epsilonzz_interface(j)/rho(i)
           epsxz(i) = epsxz(i) + mass(j)*epsilonxz_interface(i)/rho(j)
           epsxz(j) = epsxz(j) + mass(i)*epsilonxz_interface(j)/rho(i)
           epsyz(i) = epsyz(i) + mass(j)*epsilonyz_interface(i)/rho(j)
           epsyz(j) = epsyz(j) + mass(i)*epsilonyz_interface(j)/rho(i)

    elseif( (abs(itype(i)).gt.1000 ) .and. (abs(itype(j)).lt.1000 ) ) then

      epsilonxx_interface(j)  = (2/3.)*(2.e0*dvx(1)*dwdx(1,k)      
      epsilonxx_interface(i)  =dvx(1)*dwdx(1,k)
      epsilonyy_interface(j)  =(2/3.)*(2.e0*dvx(2)*dwdx(2,k) 
      epsilonyy_interface(i)  = dvx(2)*dwdx(2,k) 
      epsilonxy_interface(j)  =dvx(1)*dwdx(2,k) + dvx(2)*dwdx(1,k)  
      epsilonxy_interface(i)  = (1/2.)*(dvx(1)*dwdx(2,k)+dvx(2)*dwdx(1,k)) 
      epsilonzz_interface(j)  = (2/3.)*(2.e0*dvx(dim)*dwdx(dim,k) 
      epsilonzz_interface(i)  =dvx(dim)*dwdx(dim,k)   
      epsilonxz_interface(j)  =dvx(1)*dwdx(dim,k) + dvx(dim)*dwdx(1,k)              
      epsilonxz_interface(i)  =(1/2.)*(dvx(1)*dwdx(dim,k)+dvx(dim)*dwdx(1,k))   
      epsilonyz_interface(j)  =dvx(2)*dwdx(dim,k) + dvx(dim)*dwdx(2,k)  
      epsilonyz_interface(i)  =(1/2.)*(dvx(2)*dwdx(dim,k)+dvx(dim)*dwdx(2,k))  

       epsxx(i) = epsxx(i) + mass(j)*epsilonxx_interface(i)/rho(j)
       epsxx(j) = epsxx(j) + mass(i)*epsilonxx_interface(j)/rho(i)
       epsyy(i) = epsyy(i) + mass(j)*epsilonyy_interface(i)/rho(j)
       epsyy(j) = epsyy(j) + mass(i)*epsilonyy_interface(j)/rho(i)
       epsxy(i) = epsxy(i) + mass(j)*epsilonxy_interface(i)/rho(j)
       epsxy(j) = epsxy(j) + mass(i)*epsilonxy_interface(j)/rho(i)
   epszz(i) = epszz(i) + mass(j)*epsilonzz_interface(i)/rho(j)
   epszz(j) = epszz(j) + mass(i)*epsilonzz_interface(j)/rho(i)
   epsxz(i) = epsxz(i) + mass(j)*epsilonxz_interface(i)/rho(j)
   epsxz(j) = epsxz(j) + mass(i)*epsilonxz_interface(j)/rho(i)
   epsyz(i) = epsyz(i) + mass(j)*epsilonyz_interface(i)/rho(j)
   epsyz(j) = epsyz(j) + mass(i)*epsilonyz_interface(j)/rho(i)

      endif

   endif
enddo    
!$omp end do nowait
 endif
    !$omp end parallel
share|improve this question
    
Sir , i do not understand what i should do! edit my answer? which one? –  user2490552 Jun 18 '13 at 19:10
    
Please, try to edit your question to improve it (for instance provide a better code indentation and possibly a SSCE). –  Massimiliano Jun 18 '13 at 19:11
    
Sir, i tried my best to SSCE my Question –  user2490552 Jun 18 '13 at 19:31
    
Sir, i tried my best to SSCE my Question –  user2490552 Jun 18 '13 at 19:35
2  

1 Answer 1

up vote 2 down vote accepted

The performance problem that you observe comes from the very foundation of the algorithm that you use. Each thread picks a pair of particles and computes some values, then modifies the value of eps?? (where ?? is xx, yy, zz, etc.) for both particles. Depending on how the pair list is built, this could lead to many threads trying to modify the values for neighbouring particles or even for the same particle concurrently. In the former case it results in false sharing, which presents itself as huge slowdown due to cache lines being constantly invalidated and reloaded from higher level caches or from main memory. The latter results in completely wrong values for the array elements being computed.

While the latter problem can be easily fixed by either using atomic updates, e.g.

!$OMP ATOMIC UPDATE
epszz(i) = epszz(i) + mass(j)*epsilonzz_interface(i)/rho(j)

or CRITICAL constructs, e.g.

!$OMP CRITICAL
epsxx(i) = epsxx(i) + mass(j)*epsilonxx_interface(i)/rho(j)
epsxx(j) = epsxx(j) + mass(i)*epsilonxx_interface(j)/rho(i)
epsyy(i) = epsyy(i) + mass(j)*epsilonyy_interface(i)/rho(j)
epsyy(j) = epsyy(j) + mass(i)*epsilonyy_interface(j)/rho(i)
epsxy(i) = epsxy(i) + mass(j)*epsilonxy_interface(i)/rho(j)
epsxy(j) = epsxy(j) + mass(i)*epsilonxy_interface(j)/rho(i)
epszz(i) = epszz(i) + mass(j)*epsilonzz_interface(i)/rho(j)
epszz(j) = epszz(j) + mass(i)*epsilonzz_interface(j)/rho(i)
epsxz(i) = epsxz(i) + mass(j)*epsilonxz_interface(i)/rho(j)
epsxz(j) = epsxz(j) + mass(i)*epsilonxz_interface(j)/rho(i)
epsyz(i) = epsyz(i) + mass(j)*epsilonyz_interface(i)/rho(j)
epsyz(j) = epsyz(j) + mass(i)*epsilonyz_interface(j)/rho(i)
!$OMP END CRITICAL

or even array reductions, e.g.

!$OMP PARALLEL REDUCTION(+:epsxx,epsyy,epsxy,epszz,...)

the former problem requires that you change the algorithm. For example you can switch to a different pair list structure, e.g. an array of lists, where the array index is the particle number and each list contains the neighbours of that particle. Sorting the neighbour list will (kind of) reduce the false sharing. Depending on the geometry of the particle distribution, you might end up with severely unbalanced problem, therefore you should think about using dynamic loop scheduling.

share|improve this answer
    
Thank you very much dear Hristo Iliev, I'm much appriciated my friend thank you very very very much, God bless you –  user2490552 Jun 19 '13 at 10:56
    
Dear Hristo Iliev, it seems that you are completely familiar with particle methods and more importantly the neighboring search in particles methods like SPH ! Very interesting –  user2490552 Jun 19 '13 at 11:05
    
DEAR Hristo Iliev, when i use reduction for arrays, for example here REDUCTION(+:epsxx,epsyy,epsxy,epszz,...), the code crashes!I do not know why!! is it becuase of using Allocatable arrays?? –  user2490552 Jun 19 '13 at 11:15
1  
Reduction makes a private copy of each argument. Allocatable arrays retain their allocation status, i.e. if they were allocated before the entry to the parallel region, then the private copies are automatically allocated with the same bounds as the original arrays. You might be running out of memory or your original array might not be properly allocated before the region. It could also be a compiler bug. Run your program within a debugger to see what is the case. –  Hristo Iliev Jun 20 '13 at 18:02
    
Thank you Very Much Dear Hristo . –  user2490552 Jun 23 '13 at 11:17

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