Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

In the first Matlab script below when I run it as shown I get no errors what so ever and the code produces the expected results, however when I take out matlabpool open and matlabpool close as well as changing the parfor loop to a for loop, I get the following error:

Running...       ??? Error using ==> mldivide
Matrix is singular to working precision.
Error in ==> NSS_betas at 11
    betas = G\data.y2.';
Error in ==> DElambda at 19
        betas(:,ii) = NSS_betas(P1(:,ii),data); end
Error in ==> Individual_Lambdas at 46
    beta{ii} = DElambda(de,dataList, @OF_NSS);

I will happily send CRM_22_12.mat if required.

Why does the error only trigger when I use a regular for loop instead if a parfor loop?

clear all, clc

load Euro_CRM_22_12.mat

matlabpool open 

tic

warnState(1) = warning('error', 'MATLAB:singularMatrix'); 
warnState(2) = warning('error', 'MATLAB:illConditionedMatrix'); 

mats  = 1:50;
mats2 = [2 5 10 30];


% RO: unloop these
de = struct(...
'min', [0;0],...
'max', [50;50],...
'd'  , 2,...
'nP' , 500,...
'nG' , 600,...
'ww' , 0.1,...
'F'  , 0.5,...
'CR' , 0.99,...
'R'  , 0,...
'oneElementfromPm',1);

% RO: initialize beta
beta  = cell(size(rates,1),1);

clc, fprintf('Running...       ');

%for ii = 1:size(rates,1)
parfor ii = 1:size(rates,1)    
% RO: use status indicator for things that take this long
%fprintf('\b\b\b\b\b\b\b%6.2f%%', ii/size(rates,1)*100);

dataList = struct(...
    'yM'   , rates(ii,:),...
    'mats' , mats,...
    'model', @NSS,...
    'mats2', mats2,...
    'y2'   , rates(ii,mats2));

beta{ii} = DElambda(de,dataList, @OF_NSS);

end

toc

matlabpool close

%

function [output] = DElambda(de,data,OF)

% RO: also saves time
 %   warning off; %#ok
warning on verbose;

P1 = zeros(de.d,de.nP);
Pu = zeros(de.d,de.nP);

for ii = 1:de.d
    P1(ii,:) = de.min(ii,1)+(de.max(ii,1)-de.min(ii,1))*rand(de.nP,1); end

P1(:,1:de.d) = diag(de.max);
P1(:,de.d+1:2*de.d) = diag(de.min);

%  RO: pre allocate betas
betas = zeros(size(data.y2,2), de.nP);
for ii = 1:de.nP
    betas(:,ii) = NSS_betas(P1(:,ii),data); end

Params = vertcat(betas,P1);

Fbv = NaN(de.nG,1);

% must pass OF as @OF
F = zeros(de.nP,1);
P = zeros(de.nP,1);

for ii = 1:de.nP
    F(ii) = OF(Params(:,ii)',data);
    P(ii) = pen(P1(:,ii),de,F(ii));
    F(ii) = F(ii)+P(ii);
end

[Fbest indice]  = min(F);
xbest = Params(:,indice);

Col = 1:de.nP;

% RO: pre allocate betasPu
betasPu = zeros(size(data.y2,2), de.nP);

% RO: if Fbest hasn't changed for 25 generations, 
% it's not gonna anymore: break off
count = 0;

for g = 1:de.nG

    P0 = P1;
    rowS = randperm(de.nP).';
    colS = randperm(4).';

    % RO: replace circshift for JIT accelleration
%         RS = circshift(rowS,colS(1));
%         R1 = circshift(rowS,colS(2));
%         R2 = circshift(rowS,colS(3));
%         R3 = circshift(rowS,colS(4));

    RS = rowS([end-colS(1)+1:end 1:end-colS(1)]);        
    R1 = rowS([end-colS(2)+1:end 1:end-colS(2)]);
    R2 = rowS([end-colS(3)+1:end 1:end-colS(3)]);
    R3 = rowS([end-colS(4)+1:end 1:end-colS(4)]);


    % mutate
    Pm = P0(:,R1) + de.F*(P0(:,R2)-P0(:,R3));
    if de.R>0, Pm = Pm+de.r*randn(de.d,de.nP); end

    % crossover
    PmElements = rand(de.d,de.nP)<de.CR;        
    if de.oneElementfromPm
        % RO: JIT...
        %Row = unidrnd(de.d,1,de.nP);
        Row = ceil(de.d .* rand(1,de.nP));

        ExtraPmElements = sparse(Row,Col,1,de.d,de.nP);
        PmElements = PmElements|ExtraPmElements;
    end

    P0_Elements = ~PmElements;
    Pu(:,RS) = P0(:,RS).*P0_Elements+PmElements.*Pm;

    % RO: inline NSS_betas, so that this loop can
    % be compiled by the JIT
    mats = data.mats2.';
    yM   = data.y2.';
    nObs = size(data.y2,2);
    one  = ones(nObs,1);

    % RO: version below is faster
%         for ii = 1:de.nP
%             %betasPu(:,ii) = NSS_betas(Pu(:,ii),data);
%             
%             lambda = Pu(:,ii);
%             G =  [one,...
%                  (1-exp(-mats/lambda(1)))./(mats/lambda(1)),...
%                 ((1-exp(-mats/lambda(1)))./(mats/lambda(1)) - exp(-mats/lambda(1))),...
%                 ((1-exp(-mats/lambda(2)))./(mats/lambda(2)) - exp(-mats/lambda(2)))];
%             
%             betasPu(:,ii) = G\yM;
%             
%         end

    aux  = bsxfun(@rdivide, mats, Pu(:).');
    aux2 = exp(-aux);
    aux3 = (1-aux2)./aux;
    for ii = 1:2:2*de.nP            
%             betasPu(:,(ii+1)/2) =[...
%                one,...
%                aux3(:,ii),...
%                aux3(:,ii) - aux2(:,ii),...
%                aux3(:,ii+1) - aux2(:,ii+1)] \ yM;   
        G=[one, aux3(:,ii), aux3(:,ii) - aux2(:,ii),aux3(:,ii+1) - aux2(:,ii+1)];

        try
        betasPu(:,(ii+1)/2) =G\yM;
        catch ME
         CondPen(1,(ii+1)/2)=0;
        end
     end

    ParamsPu = [betasPu;Pu];
    flag = 0;

    mats  = data.mats;
    yM    = data.yM;

    for ii = 1:de.nP

        % RO: inline OF_NSS.m here for JIT accelleration
        %Ftemp = OF(ParamsPu(:,ii).',data);

        beta = ParamsPu(:,ii).';

        %model = data.model;

        yy = zeros(size(yM));
        for jj = 1:size(beta,3)

            % RO: inline for JIT accelleration
            %y(ii,:) = model(beta(:,:,ii),mats);

            betai = beta(:,:,jj);
            gam1  = mats/betai(5);
            gam2  = mats/betai(6);
            aux1  = 1-exp(-gam1);
            aux2  = 1-exp(-gam2);

            % I have a feeling this is the same as G and therefore 
            % this can be done shorter and quicker...
            % something like yy(jj,:) = sum(G,2)
            yy(jj,:)  = ...
                betai(1) + ...
                betai(2)*(aux1./gam1) + ...
                betai(3)*(aux1./gam1+aux1-1) + ...
                betai(4)*(aux2./gam2+aux2-1);

        end

        yy = yy-yM;

        % RO: this whole loop can be replaced...

        % ObjVal = 0;
        % for i = 1:size(yM,1) %dim
        % ObjVal = ObjVal+dot(aux(i,:)',aux(i,:)');
        % %ObjVal = sum(ObjVal);
        % end
        % ObjVal

        % RO ...by this one-liner
        Ftemp = sum(yy(:).^2);


        % RO: inline penalty here as well
        Ptemp = 0;%pen(Pu(:,ii),de,F(ii));


        Ftemp = Ftemp+Ptemp;%+CondPen(1,ii);

        if Ftemp <= F(ii);
            P1(:,ii) = Pu(:,ii);
            F(ii) = Ftemp;
            if Ftemp < Fbest
                Fbest = Ftemp; xbest = ParamsPu(:,ii); 
                flag = 1; 
                count = 0; 
            end

        else
            P1(:,ii) = P0(:,ii);

        end
    end

    if flag
        Fbv(g) = Fbest; end

    % RO: if Fbest hasn't changed for 25 generatios, break off
    count = count + 1;
    if count > 25, break; end

end

output.Fbest = Fbest; 
output.xbest = xbest; 
output.Fbv = Fbv;    

end


% look to inline penalty later (i.e. incoporate into code
function penVal = pen(~,~,~)%pen(beta,pso,vF,data)
penVal = 0;  
end

%

function [betas r r2] = NSS_betas(lambda,data)

mats = data.mats2.';        
nObs = size(data.y2,2);

G =  [ones(nObs,1),...
     (1-exp(-mats/lambda(1)))./(mats/lambda(1)),...
    ((1-exp(-mats/lambda(1)))./(mats/lambda(1)) - exp(-mats/lambda(1))),...
    ((1-exp(-mats/lambda(2)))./(mats/lambda(2)) - exp(-mats/lambda(2)))];

betas = G\data.y2.';

% RO: output hardly ever needed, while rank() 
% is very time consuming
if nargout > 1 && ~isnan(G)
    r = rank(G);
    r2 = rcond(G);
end


end
share|improve this question
add comment

1 Answer

up vote 1 down vote accepted

It's a bit cryptic, but here's what I can tell you for sure.

Error in ==> NSS_betas at 11
    betas = G\data.y2.';
Error in ==> DElambda at 19
        betas(:,ii) = NSS_betas(P1(:,ii),data); end
Error in ==> Individual_Lambdas at 46
    beta{ii} = DElambda(de,dataList, @OF_NSS);

Essentially, this means that the G matrix is singular, and thus doesn't have a solution. That would be this:

G =  [ones(nObs,1),...
     (1-exp(-mats/lambda(1)))./(mats/lambda(1)),...
    ((1-exp(-mats/lambda(1)))./(mats/lambda(1)) - exp(-mats/lambda(1))),...
    ((1-exp(-mats/lambda(2)))./(mats/lambda(2)) - exp(-mats/lambda(2)))];

betas = G\data.y2.';

What I would do to further diagnose this is to set the stop on error flag. There is a few ways to do this, one from the gui, and another via command. Take a look to see if the matrix looks correct. Odds are, something isn't right. Trace back the error, and you'll figure it out.

share|improve this answer
    
Thanks Pearsonartphto, but I am aware that this is what generates teh error, sorry if I didn't make that clear. What is confusing me is why does this error does not occur when I use parfor? The error only occurs when I use for ii = 1:size(rates,1), instead of parfor ii = 1:size(rates,1)?? Are error's handled differently in parfor loops? –  Bazman Nov 12 '12 at 19:27
    
They are handled somewhat differently, also parfor is somewhat sandboxed. –  PearsonArtPhoto Nov 12 '12 at 19:28
    
Thanks again, can you elaborate on how they are handled different and what you mean by sandboxed? The reason I am doing the coding this way is that rdivide is generating these error messages, so rdivide is clearly using rcond() to test the conditioning of the matrices. I need to check the conditioning of the matrices, rather than me having to call rcond() again to duplicate this work, I would just like to get access to the rcond values and/or the decision at to whether the matrix is badly conditioned or not that rdivide is producing. Ideally within a parallel structure is this possible? –  Bazman Nov 12 '12 at 19:34
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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