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I'm not really familiar with vectorization, but I am aware that, amongst MATLAB's strengths, code vectorization is probably the most rewarded.

I have this code:

ikx= (-Nx/2:Nx/2-1)*dk1;
iky= (-Ny/2:Ny/2-1)*dk2;
ikz= (-Nz/2:Nz/2-1)*dk3;

[k1,k2,k3] = ndgrid(ikx,iky,ikz);
k = sqrt(k1.^2 + k2.^2 + k3.^2);
Cij = zeros(3,3,Nx,Ny,Nz);
count = 0;
for ii = 1:Nx
    for jj = 1:Ny
        for kk = 1:Nz
            if ~isequal(k1(ii,jj,kk),0)
                count = count +1;
                fprintf('iteration step %i\r\n',count)
                E_int = interp1(k_vec,E_vec,k(ii,jj,kk),'spline','extrap');
                beta = c*gamma./(k(ii,jj,kk).*sqrt(E_int));
                k30 = k3(ii,jj,kk) + beta*k1(ii,jj,kk);
                k0 = sqrt(k1(ii,jj,kk)^2 + k2(ii,jj,kk)^2 + k30^2);
                Ek0 = 1.453*(k0^4/((1 + k0^2)^(17/6)));
                B = sigmaiso*sqrt((Ek0./(k0.^2))*((dk1*dk2*dk3)/(4*pi)));
                C1 = ((beta.*k1(ii,jj,kk).^2).*(k0.^2 - 2*k30.^2 + k30.*beta.*k1(ii,jj,kk)))./(k(ii,jj,kk).^2.*(k1(ii,jj,kk).^2 + k2(ii,jj,kk).^2));
                C2 = ((k2(ii,jj,kk).*(k0.^2))./((k1(ii,jj,kk).^2 + k2(ii,jj,kk).^2).^(3/2))).*atan2((beta.*k1(ii,jj,kk).*sqrt(k1(ii,jj,kk).^2 + k2(ii,jj,kk).^2)),(k0.^2 - k30.*beta.*k1(ii,jj,kk)));
                xhsi1 = C1 - C2.*(k2(ii,jj,kk)./k1(ii,jj,kk));
                xhsi2 = C1.*(k2(ii,jj,kk)./k1(ii,jj,kk)) + C2;
                Cij(1,1,ii,jj,kk) = B.*((k2(ii,jj,kk).*xhsi1)./(k0));
                Cij(1,2,ii,jj,kk) = B.*((k3(ii,jj,kk)-k1(ii,jj,kk).*xhsi1+beta.*k1(ii,jj,kk))./(k0));
                Cij(1,3,ii,jj,kk) = B.*(-k2(ii,jj,kk)./(k0));
                Cij(2,1,ii,jj,kk) = B.*((k2(ii,jj,kk).*xhsi2-k3(ii,jj,kk)-beta.*k1(ii,jj,kk))./(k0));
                Cij(2,2,ii,jj,kk) = B.*((-k1(ii,jj,kk).*xhsi2)./(k0));
                Cij(2,3,ii,jj,kk) = B.*(k1(ii,jj,kk)./(k0));
                Cij(3,1,ii,jj,kk) = B.*(k2(ii,jj,kk).*k0./(k(ii,jj,kk).^2));
                Cij(3,2,ii,jj,kk) = B.*(-k1(ii,jj,kk).*k0./(k(ii,jj,kk).^2));               

Generally, I might avoid the nested for loops; nonetheless, the if statement on k1 values is currently directing me towards the classical and old-fashion code structure.

I blatantly would like to bypass the presence of the for loops in favour of vectorized and more elegant solution.

Any support is more than welcome.


To let better understand what the code is expected to perform, I hereby provide you with some basics:

enter image description here

enter image description here

enter image description here

enter image description here


As @Floris advised, I came up with this alternative solution:

ikx= (-Nx/2:Nx/2-1)*dk1;
iky= (-Ny/2:Ny/2-1)*dk2;
ikz= (-Nz/2:Nz/2-1)*dk3;

[k1,k2,k3] = ndgrid(ikx,iky,ikz);
k = sqrt(k1.^2 + k2.^2 + k3.^2);

ii = (ikx ~= 0);
k1w = k1(ii,:,:);
k2w = k2(ii,:,:);
k3w = k3(ii,:,:);
kw = k(ii,:,:);

E_int = interp1(k_vec,E_vec,kw,'spline','extrap');
beta = c*gamma./(kw.*sqrt(E_int));

k30 = k3w + beta.*k1w;
k0 = sqrt(k1w.^2 + k2w.^2 + k30.^2);
Ek0 = (1.453*k0.^4)./((1 + k0.^2).^(17/6));
B = sqrt((2*(pi^2)*(l^3))*(Ek0./(V*k0.^4)));

k1w_2 = k1w.^2;
k2w_2 = k2w.^2;
k30_2 = k30.^2;
k0_2 = k0.^2;
kw_2 = kw.^2;

C1 = ((beta.*k1w_2).*(k0_2 - 2.*k30_2 + beta.*k1w.*k30))./(kw_2.*(k1w_2 + k2w_2));
C2 = ((k2w.*k0_2)./((k1w_2 + k2w_2).^(3/2))).*atan2((beta.*k1w).*sqrt(k1w_2 + k2w_2),(k0_2 - k30.*k1w.*beta));

xhsi1 = C1 - (k2w./k1w).*C2;
xhsi2 = (k2w./k1w).*C1 + C2;

Cij = zeros(3,3,Nx,Ny,Nz);

Cij(1,1,ii,:,:) = B.*(k2w.*xhsi1);
Cij(1,2,ii,:,:) = B.*(k3w - k1w.*xhsi1 + beta.*k1w);
Cij(1,3,ii,:,:) = B.*(-k2w);
Cij(2,1,ii,:,:) = B.*(k2w.*xhsi2 - k3w - beta.*k1w);
Cij(2,2,ii,:,:) = B.*(-k1w.*xhsi2);
Cij(2,3,ii,:,:) = B.*(k1w);
Cij(3,1,ii,:,:) = B.*((k0_2./kw_2).*k2w);
Cij(3,2,ii,:,:) = B.*(-(k0_2./kw_2).*k1w);
share|improve this question
start simple: mathworks.com/help/matlab/matlab_prog/vectorization.html – thang Feb 12 '13 at 22:14
Do you have to use a 5 dimensional array (Cij)? Speed is usually a function of how close things are in memory and you are spreading them out far. Maybe 8 arrays of 3 dims would serve you better. – ja72 Feb 12 '13 at 22:19
Remove the fprintf() from the inner loop. If you want speed, do not so any I/O in the main loop. – ja72 Feb 12 '13 at 22:19
maybe you could explain what the code does in general (variables and operations) ? to be honest its very hard to follow the code with all ii,kk stuff :) – amas Feb 12 '13 at 22:25
Within your nested loops, I don't see anything that depends on something other than the current indices (ii,jj,kk) so this should be straightforward to vectorize. The only 'gotcha' might be if your interp1 step depends on previous iterations, but I don't think it does (you don't include the definitions of all the parameters though). Within the inner loop, make your single-value calculations do a 3D matrix instead. Then get rid of the indices for the rest of it, and do the entire matrix at once. You can check for your condition all at once either before or after the calculations. – tmpearce Feb 12 '13 at 22:46
up vote 1 down vote accepted

You can do your test just once, and then create arrays of "just the elements you need". Example:

% create an index of all the elements that are worth computing:
worthComputing = find(k1(:)~=0);
% now create sub-arrays of all the other arrays... a little bit expensive on memory,
% but much faster for computation:
kw =  k(worthComputing);
k1w = k1(worthComputing);
k2w = k2(worthComputing);
k3w = k3(worthComputing);

% now we'll compute all the results of the innermost for loop in single statements:
E_int = interp1(k_vec,E_vec,kw,'spline','extrap');
beta = c*gamma./kw.*sqrt(E_int));
k30 = k3w + beta*k1w;
k0 = sqrt(k1w.^2 + k2w.^2 + k30.^2);
Ek0 = 1.453*(k0.^4/((1 + k0.^2).^(17/6)));

% the next line has dk1, dk2, dk3 ... not sure what they are? Not shown to be initialized. Assuming scalars as they are not indexed.

B = sigmaiso*sqrt((Ek0./(k0.^2))*((dk1*dk2*dk3)/(4*pi)));
C1 = ((beta.*k1w.^2).*(k0.^2 - 2*k30.^2 + k30.*beta.*k1w))./(kw.^2.*(k1w.^2 + k2w.^2));
C2 = ((k2w.*(k0.^2))./((k1w.^2 + k2w.^2).^(3/2))).*atan2((beta.*k1w.*sqrt(k1w.^2 + ...
    k2w.^2)),(k0.^2 - k30.*beta.*k1w));
xhsi1 = C1 - C2.*(k2w./k1w);
xhsi2 = C1.*(k2w./k1w) + C2;

% in the next lines I am using the trick of "collapsing" the remaining indices % in other words, Matlab figures out that I want to access the elements in C % that correspond to the ii, jj, kk that were picked before...

Cij(1,1,worthComputing) = B.*((k2w.*xhsi1)./(k0));
Cij(1,2,worthComputing) = B.*((k3w-k1w.*xhsi1+beta.*k1w)./(k0));
Cij(1,3,worthComputing) = B.*(-k2w./(k0));
Cij(2,1,worthComputing) = B.*((k2w.*xhsi2-k3w-beta.*k1w)./(k0));
Cij(2,2,worthComputing) = B.*((-k1w.*xhsi2)./(k0));
Cij(2,3,worthComputing) = B.*(k1w./(k0));
Cij(3,1,worthComputing) = B.*(k2w.*k0./(kw.^2));
Cij(3,2,worthComputing) = B.*(-k1w.*k0./(kw.^2));

It is entirely possible there's a typo or two in the above - but this is the basic approach to vectorization.

share|improve this answer

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