3

I have to pass arrays to other functions, through referencing or pointer, I don't care as long as it works fast. That's why I started to use the boost library. I did it in the following way:

using namespace boost;

typedef  multi_array<long double, 4> array_type;
typedef  multi_array<long double, 2> twod_array_type;
typedef  multi_array<long double, 1> vec_type;

as functions:

void pde_3d_7_stencil_discretization(array_type& A, vec_type& b, vec_type& x,const int& xdim, const int& ydim,const int& zdim)

void gmressolver3d(array_type& A, vec_type& x, vec_type& rhs,const int& KrylovDim,const int& xdim,const int& ydim,const int& zdim,const int& COP, const int& threeDStencil)

and in the main function:

  array_type A(extents[threeDimStencil][COP][COP][xdim*ydim*zdim]);
  vec_type b(extents[xdim*ydim*zdim*COP]);
  vec_type x(extents[xdim*ydim*zdim*COP]);

  pde_3d_7_stencil_discretization(A,b,x,xdim,ydim,zdim);
  gmressolver3d(A,x,b,KrylovDim,xdim,ydim,zdim,COP,threeDimStencil);

Obviously, I'm doing something wrong, because the code works really slower than the static version, which doesn't involve any references/pointers, just passing arrays from one function to another.

What can I do to accelerate this?

Thank you for any kind of help..

edit: I'm posting what these codes do, a sequence from GMRES solver: All arrays in it were initialized also using Boost, such as:

vec_type pp(extents[zdim*xdim*ydim*COP]);
vec_type ppp(extents[zdim*xdim*ydim*COP]);
vec_type w(extents[zdim*xdim*ydim*COP]);
vec_type y(extents[KrylovDim]);
vec_type vv(extents[zdim*xdim*ydim*COP]);
vec_type b(extents[KrylovDim+1]);
vec_type ro(extents[zdim*xdim*ydim*COP]);
vec_type out1(extents[xdim*zdim*ydim*COP]);
vec_type m_jac(extents[xdim*zdim*ydim*COP]);
twod_array_type h(extents[KrylovDim+1][KrylovDim]);
twod_array_type v(extents[zdim*xdim*ydim*COP][KrylovDim]);
twod_array_type hess(extents[KrylovDim+1][KrylovDim]);
array_type maa(extents[threeDStencil][COP][COP][zdim*xdim*ydim]);
array_type maaa(extents[threeDStencil][COP][COP][zdim*xdim*ydim]);

for (i=0;i<m+1;i++){
            b[i] = 0;
            for(k=0;k<m;k++){
                h[i][k] = 0.0;
            }
        }

        for (i=0;i<n;i++){
            v[i][0] = ro[i]/r;
        }
        for(j=0;j<m;j++){
            b[0] = r;
            vector_zero_fill(n,ppp);
            for(i=0;i<n;i++){
                vv[i]=v[i][j];
            }
            //********************MATRIX FREE********************
            matrix_vector_product_heptadiagonal_discret(A,vv,pp,xdim,ydim,zdim);
            //two_vector_dot_product(n,pp,m_jac);
    //      if(isPrec)
    //      forback(A,pp);
            //********************MATRIX FREE********************
            //pretty fast**
            for(i=0;i<=j;i++){
                for(k=0;k<n;k++){
                    h[i][j] = h[i][j] + pp[k]*v[k][i];
                }
            }

            for(i=0;i<=j;i++){
                for(k=0;k<n;k++){
                    ppp[k] = ppp[k] + h[i][j]*v[k][i];
                }
            }
            p=0.0;

            for(i=0;i<n;i++){
                w[i] = pp[i] - ppp[i];
                p = p + pow(w[i],2);
            }

            h[j+1][j] = sqrt(p);

            for(i=0;i<=j+1;i++){
                for(k=0;k<=j;k++){
                    hess[i][k] = h[i][k];
                }
            }
            for(i=0;i<j+1;i++){
                c = hess[i][i]/sqrt(pow(hess[i][i],2)+pow(hess[i+1][i],2));
                s = hess[i+1][i]/sqrt(pow(hess[i][i],2)+pow(hess[i+1][i],2));
                for (k=0;k<=j;k++){
                    inner1=c*hess[i][k]+s*hess[i+1][k];
                    inner2=(-s)*hess[i][k]+c*hess[i+1][k];
                    hess[i][k] = inner1;
                    hess[i+1][k] = inner2;
                }
                b[i+1] = -s*b[i];
                b[i] = c*b[i];
            }
13
  • 1
    All you have posted are declarations. Are we supposed to guess what pde_3d_7_stencil_discretization and gmressolver3d do? Please show the actual code where you access your multi_arrays. Show the loops and inner loops. You should also try running a profiler to see where the bottleneck is. Mar 12, 2011 at 15:10
  • 1
    Silly question: are you compiling with optimization enabled? If optimization is disabled, then multi_array is sure to run slowly. Mar 12, 2011 at 15:12
  • 1
    How did you profile both versions to conclude the usage of multi_array is the bottleneck?
    – Sam Miller
    Mar 12, 2011 at 15:13
  • @Emilie Cormier - I just thought that the problem might lie in the declarations, that's why I just posted these Mar 12, 2011 at 15:18
  • @Sam Miller - My only criterion is speed. It's just too slow. The routines gmressolver and pde-discretization are being used to discretize and solving PDEs Mar 12, 2011 at 15:19

2 Answers 2

4

Where you zero-initialize your multi_arays, you can try using std::memset instead. For example

std::memset(b.data(), 0, size_of_b_in_bytes);

There are a few places in your code where you index the same multi_array element more than once. For example, instead of

h[i][j] = h[i][j] + pp[k]*v[k][i]

try

h[i][j] += pp[k]*v[k][i]

Normally, the optimizer would automatically make such substitutions for you, but maybe it can't with multi_array.

I also spotted two for loops that can be merged into one to avoid indexing the same multi_array element multiple times:

/*
for(i=0; i<=j; i++)
{
    for(k=0; k<n; k++)
    {
        h[i][j] = h[i][j] + pp[k]*v[k][i];
    }
}

for(i=0; i<=j; i++)
{
    for(k=0; k<n; k++)
    {
        ppp[k] = ppp[k] + h[i][j]*v[k][i];
    }
}
*/

for(i=0; i<=j; i++)
{
    for(k=0; k<n; k++)
    {
        long double& h_elem = h[i][j];
        long double v_elem = v[k][i];
        h_elem += pp[k]*v_elem;
        ppp[k] += h_elem*v_elem;
    }
}

There might be more like these. Note the use of references and variables to "remember" an element and to avoid having to recompute its position in the multi_array.

In the last for loop from your code, you can avoid lots of recomputing of multi_array indices by using temporary variables and references:

/*
for(i=0;i<j+1;i++){
    c = hess[i][i]/sqrt(pow(hess[i][i],2)+pow(hess[i+1][i],2));
    s = hess[i+1][i]/sqrt(pow(hess[i][i],2)+pow(hess[i+1][i],2));
    for (k=0;k<=j;k++){
        inner1=c*hess[i][k]+s*hess[i+1][k];
        inner2=(-s)*hess[i][k]+c*hess[i+1][k];
        hess[i][k] = inner1;
        hess[i+1][k] = inner2;
    }
    b[i+1] = -s*b[i];
    b[i] = c*b[i];
}
*/

for(i=0;i<j+1;i++){
    long double hess_i_i = hess[i][i];
    long double hess_ip1_i = hess[i+1][i];
    long double temp = sqrt(pow(hess_i_i,2)+pow(hess_ip1_i,2));
    c = hess_i_i/temp;
    s = hess_ip1_i/temp;
    for (k=0;k<=j;k++){
        long double& hess_i_k = hess[i][k];
        long double& hess_ip1_k = hess[i+1][k];
        inner1=c*hess_i_k+s*hess_ip1_k;
        inner2=(-s)*hess_i_k+c*hess_ip1_k;
        hess_i_k = inner1;
        hess_ip1_k = inner2;
    }
    long double b_i& = b[i];
    b[i+1] = -s*b_i;
    b_i = c*b_i;
}

Double check my work -- it's certain I've made a mistake somewhere. Note that I've stored the sqrt(pow(hess_i_i,2)+pow(hess_ip1_i,2)) in a variable so that it's not needlessly computed twice.

I doubt these minor tweaks will bring the runtime down to 5 seconds. The problem with multi_array is that the array dimensions are only known at runtime. Support for row-major/column-major ordering probably also induces some overhead.

With C-style multi-dimensional arrays, dimensions are known at compile time, so the compiler can produce "tighter" code.

By using Boost multi_arrays you're basically trading off speed for flexibilty and convenience.

2
  • Thank you very much for your help. I applied first changes you proposed - it was reduced to 54 sec. now i will perform these. Mar 12, 2011 at 17:16
  • @Emre: Feel free to upvote my answer if you find it useful. :-) Mar 12, 2011 at 17:32
0

See rodrigob's answer here. Also, using Blaze DynamicMatrix with the same compiler optimization can give almost an extra factor 2 improvement.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.