Asked by Derek O'Connor
on 17 Nov 2012

Here is a profile of the call `n = 2*10^3; M = DStochMat02(n,ones(n)./n);`

More specifically, can the hot-spot, statement 14, be reduced?

time calls line 1 function M = DStochMat02(n,c) 2 % Generate a random doubly stochastic matrix using 3 % Theorem (Birkhoff [1946], von Neumann [1953]) 4 % Any doubly stochastic matrix M can be written as a convex combination 5 % of permutation matrices P1,...,Pk (i.e. M = c1*P1+...+ ck*Pk 6 % for nonnegative c1,...,ck with c1+...+ck = 1). 7 % Complexity: O(n^2) 8 % USE: M = DStochMat02(4,[1/2 1/8 1/8 1/4]) 9 % Derek O'Connor, Oct 2006, Nov 2012. derekroconnor@eircom.net

0.02 1 10 M = zeros(n,n); < 0.01 1 11 I = eye(n); < 0.01 1 12 for k = 1:n 1.64 2000 13 pidx = GRPdur(n); % Random Permutation 107.72 2000 14 P = I(pidx,:); % Random P matrix 41.09 2000 15 M = M + c(k)*P; < 0.01 2000 16 end

%-------------------------------------------------------------- function p = GRPdur(n) % ------------------------------------------------------------- % Generate a random permutation p(1:n) using Durstenfeld's % O(n) Shuffle Algorithm, CACM, 1964. % See Knuth, Section 3.4.2, TAOCP, Vol 2, 3rd Ed. % Complexity: O(n) % USE: p = GRPdur(10^7); % Derek O'Connor, 8 Dec 2010. derekroconnor@eircom.net % -------------------------------------------------------------

p = 1:n; % Start with Identity permutation for k = n:-1:2 r = 1+floor(rand*k); % random integer between 1 and k t = p(k); p(k) = p(r); % Swap(p(r),p(k)). p(r) = t; end return % GRPdur

Answer by Matt Fig
on 17 Nov 2012

Edited by Matt Fig
on 17 Nov 2012

Accepted answer

This looks promising. I have kept some notes in the comments so you can see what I was doing...

There are three lines of code that are commented out. If you uncomment them, and comment the line after the second one, you can check that these give the same results. Of course the timing is not fair under those circumstances, but with the code commented the timings show a fantastic speed difference for large values....

M = zeros(n,n); I = eye(n);

tic % Original method. for k = 1:n pidx = GRPdur(n); % Random Permutation % F{k} = pidx; % Used to check same results below.... P = I(pidx,:); % Random P matrix M = M + c(k)*P; end toc

M2 = zeros(n,n);

tic % proposed alternative for k = 1:n % [~,idx] = sort(F{k}); % Used to compare same results. [~,idx] = sort(GRPdur(n)); % Or just idx = GRPdur(n); ?? idx = idx + (0:n-1)*n; M2(idx) = M2(idx) + c(k); end toc

% max(abs(M2(:)-M(:))) % Used to compare same results.

Matt Fig
on 18 Nov 2012

**Derek comments:**

@Matt, Amazing, obscure, and very fast (x70), and it seems to give the correct results. I need to do more testing.

Now, can you explain, mathematically, what you are doing? You have transformed the problem somehow. Can you explain?

function times = TestStochMatFig(nvals); % nalgs = 2; times = zeros(length(nvals),nalgs); kn = 0; for n = nvals kn = kn+1; M = zeros(n,n); I = eye(n); c = rand(n,1); c = c./sum(c); algno = 1; M1 = M; tic; % Original method. O'Connor for k = 1:n pidx = GRPdur(n); % Random Permutation P = I(pidx,:); % Random P matrix M1 = M1 + c(k)*P; end times(kn,algno) = toc; algno = 2; M2 = M; tic; % proposed alternative. Matt Fig for k = 1:n [~,idx] = sort(GRPdur(n)); % Or just idx = GRPdur(n); ?? idx = idx + (0:n-1)*n; M2(idx) = M2(idx) + c(k); end times(kn,algno) = toc; max(abs(M2(:)-M1(:))) % Used to compare same results.

end

Matt Fig
on 18 Nov 2012

Hi Derek, I am glad you found the results useful. What I did was basically take the operations from matrix operations to vector operations. Since you are multiplying a scalar (c(k)) by an identity matrix, there is no need to keep all the zeros. I simply take the single vector of values (there are n c(k) values) and index that directly into only those elements of M that are actually updating - thus avoiding the unnecessary addition of

K = n^2 - n

zeros each time through the loop. There is no need to add K zeros to M each time through! In addition, my approach avoids multiplying K+n numbers by c(k) each time through the loop, when we don't even need to do a *single* such multiplication. When n is large these operations takes a significant amount of time and memory acrobatics....

Also, note that I only kept the call to SORT in there in order to make sure that the codes produced the exact same result (when the appropriate lines are uncommented of course). After hundreds of runs, my code does produce the exact same result. Thus I think you could avoid the call to SORT all together unless you have some statistical connection to GRPdur you are trying to preserve.

Answer by Derek O'Connor
on 23 Nov 2012

@Matt, You are a true blue Matlabber. With just matrix indexing you have written a function which is many times faster than mine. See below

% ------------------------------------------------------------- function table = TestStochMat02Fig(nvals); % ------------------------------------------------------------- % Testing two functions for generating random doubly stochastic % matrices % USE: times = TestStochMat02Fig([10^3:10^3:6*10^3]); % Derek O'Connor, Matt Fig, 20 Nov 2012 % ------------------------------------------------------------- nalgs = 2; times = zeros(length(nvals),nalgs); kn = 0; for n = nvals kn = kn+1; M = zeros(n,n); I = eye(n); c = rand(n,1); c = c./sum(c); %---------------- Function by Derek O'Connor ------------- algno = 1; M1 = M; tic; for k = 1:n p = GRPdur(n); % Random Permutation p P = I(p,:); % Random P-matrix P M1 = M1 + c(k)*P; end times(kn,algno) = toc; %---------------- Function by Matt Fig-------------------- algno = 2; M2 = M; tic; for k = 1:n p = GRPdur(n); p = p + (0:n-1)*n; M2(p) = M2(p) + c(k); end times(kn,algno) = toc;

max(abs(M2(:)-M1(:))) % Used to compare same results. end % n = nvals table = [nvals' times(:,1) times(:,2) times(:,1)./times(:,2)];

% ----------- End: table = TestStochMat02Fig(nvals); -------------

>table = TestStochMat02Fig([10^3:10^3:6*10^3]);

n Derek Matt D/M 1000 6.6936 0.10741 62.317 2000 60.822 0.51116 118.99 3000 209.14 1.1846 176.54 4000 453.56 1.8474 245.51 5000 897.59 3.7354 240.29 6000 1490.2 4.8622 306.49

**Be warned!** There is a trickier problem to come.

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## 1 Comment

## Matt Fig (view profile)

Direct link to this comment:http://www.mathworks.com/matlabcentral/answers/53957#comment_111585

Can you post what GRPdur does? Is it akin to RANDPERM?