Nested Loops and efficiency
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Hi,
I have the following function, and there are some nested loops with multiple if statements inside. The code, runs extremely slow in Matlab ( fortran executes the whole code in 15 min, matlab needs a couple of hours). Nonetheless, this is one part of the code, that Matlab needs some time to complete
function [ystar, cstar, plterm]=decision_rules(r,w, brolillas, model, pl_flag)
global nshock one update tinies aproxdr e a
du=zeros(length(a)+1);
errrel = 3.0e-30;
rules_converge =false;
iter=0;
%*************************************************************
% First Get last term
%*************************************************************
if(iter>1)
iterflag=1;
end
plterm=0.0;
% reset plterm
if(brolillas<1)
plterm0=0.0d0;
end
if(model==2 && pl_flag >= 1 && brolillas >= 1)
[plterm]=exterm(fdist, w, r, ystar) ;
if(abs(plterm-plterm0)<1.0d-6)
update_flag=1;
end
if(abs(plbnd(1)-plbnd(2))<1.0d-9)
update_flag=1;
end
if(plterm>=plterm0)
plbnd(1)=max(plterm0,plbnd(1));
end
if(plterm<=plterm0)
plbnd(2)=min(plterm0,plbnd(2));
end
if(brolillas >= 3)
plterm=update_pl.*plterm+(1.0d0-update_pl).*plterm0;
if(plterm>plbnd(2) || plterm<plbnd(1))
plterm=sum(sum(plbnd))./2.;
end
else
plterm=update_pl.*plterm+(1.0d0-update_pl).*plterm0;
end;
elseif(model==2 && brolillas==0)
plbnd(1)=-1.;
plbnd(2)=1.;
plterm=plterm0;
end
pl_flag=pl_flag+1;
brolillas=brolillas+1;
% Initialization 2: construct cstar from ystar
y0=zeros(length(a),nshock);
c0=zeros(length(a),nshock);
ystar=zeros(length(a),nshock);
cstar=zeros(length(a),nshock);
for i=1:nshock
for n=1: length(a)
cstar(n,i)=r.*a(n)+w.*e(i)-ystar(n,i);
end
end
% Initialization 3 : initial updating
y0 =(one-update).*y0+update.*ystar;
c0 =(one-update).*c0+update.*cstar;
%****************************************************************
% Main Loop
%****************************************************************
while(~rules_converge)
iter = iter + 1;
disp(['Iteration No:' num2str(iter)])
%*************************************************************
% Solve the decision rule
%*************************************************************
for i=1:nshock
for n=1:length(a)
%Find ystar
for np=1:length(a)+1
if(np>length(a))
break;
end
if(upap(n,a(np),i,r,w) > 100/tinies)
break;
end
du(np)=-upap(n,a(np),i,r,w)+ meru(a(np),i,r,c0)+plterm;
if(du(np)<=0)
break;
end
end
if(np>length(a))
yy1=a(length(a));
elseif(upap(n,a(np),i,r,w) > 100/tinies)
if(np==1)
yy1=a(1);
else
yexp=a(n)*r+w*e(i) - tinies;
dusup=upap(n,yexp,i,r,w)-meru(yexp,i,r,c0)-plterm;
if((yexp-a(np-1))>tinies && dusup>0.)
yy1=zbrent(a(np-1),yexp,errrel,i,n,r,w,c0,plterm);
else
yy1=a(np-1);
end
end
else
if(np==1)
yy1=a(1);
else
yy1=zbrent(a(np-1),a(np),errrel,i,n,r,w,c0,plterm);
end
end
ystar(n,i) = yy1;
cstar(n,i) = r.*a(n)+w.*e(i)-ystar(n,i);
end
end
%*************************************************************
% Check convergence
%*************************************************************
no_converge_y=zeros(length(a),nshock);
no_converge_y(abs(ystar-y0)>aproxdr)=1;
no_converge =fix(sum(sum(no_converge_y)));
tempmaxval=abs(ystar-y0);
error=max(tempmaxval(:));
disp(['the error in optimal plans is:' num2str(error)])
if(no_converge==0)
rules_converge=true;
else
rules_converge=false;
end
%*************************************************************
% Update y0 and c0
%*************************************************************
y0=ystar;
c0=cstar;
end
disp(['Total Iteration No:' num2str(iter)])
end
Can anybody here suggest some modifications that I could improve efficiency ?
Thanks
4 Comments
dpb
on 22 Jun 2014
Edited: dpb
on 23 Jun 2014
See
doc profile
for running the profiler. It's not the overall time taken, it's where within the code precisely the largest fraction of time is taken up that's important so as to know precisely where in the overall function one should concentrate efforts.
The difficulty of this code in Matlab to generate speed while guaranteeing the same result is that the loops all have all the break conditions in them and the later results are dependent upon the point within the loop at which the exit occurred. A prime example is that condition on the first loop end index Jan and I were just discussing. The next step is dependent on where that loop exits and why.
To get best performance in Matlab one needs to be able to vectorize the loops but it would take a significant amount of detailed investigation of the algorithm to be able to tell what, specifically, would be the proper action after the vectorization of one of these loops that otherwise would have exited before completion. That level of effort is just too much to expect for a respondent here to be able to infer just how that should look.
There's the snippit section
if(upap(n,a(np),i,r,w) > 100/tinies), break; end
du(np)=-upap(n,a(np),i,r,w)+ meru(a(np),i,r,c0)+plterm;
if(du(np)<=0), break; end
One could easily enough write the function upap to take the vectors a and n and return a logical array or the first index of the condition but one might then find that doing the whole thing is as or more expensive than shortening the loop because the condition occurs early on in a high percentage of typical cases while the function could be relatively costly. As Jan points out, whether those functions are significant computation-wise is one of the things the profiler will tell you.
If one had a functional descripton of the inputs/expected outputs, one could possibly write a Matlab function that does that that does use typical Matlab constructs effectively, but to start from translating Fortran to Matlab for such a case is very difficult task other than the literal transliteration process you've got here and the resulting inefficiency that comes with that.
Jan
on 22 Jun 2014
Edited: Jan
on 22 Jun 2014
@Safis: To profile the code use the command profiler. Lokk in the documentation to learn more about it.
This function will reveal, if the loops are the main problem, of if the time is spent in meru and upap. Without profiling it is possible, that we optimize the nested loops, which need only some percent of the total computing time.
Answers (2)
Jan
on 22 Jun 2014
The code can be improved. E.g. this is not useful:
for np=1:length(a)+1
if(np>length(a))
break;
end
...
What about:
for np=1:length(a)
...
This should be vectorized for a fair speed in Matlab:
for i=1:nshock
for n=1: length(a)
cstar(n,i)=r.*a(n)+w.*e(i)-ystar(n,i);
end
end
But I don't assume, that this is a bottleneck of the code.
Nevertheless, questions about improving the speed of the code cannot be answered only by seeing the code, but you need the profiler and the readers of the forum need a running example with matching testdata.
A general but a little bit disappointing advice: Avoid expressions like 0. and 0.0d0 in Matlab.Although they work currently and should work for reasons of compatibility, this is not documented.
5 Comments
dpb
on 22 Jun 2014
Edited: dpb
on 22 Jun 2014
Since the index condition of
np=length(a)+1
causes an immediate break the value of np is defined on exit of the loop. It's not the case the index has "run off the end".
That the behavior of the iterator variable after normal loop completion isn't documented at all (whether it is undefined or retains the value at the end of the loop as Fortran) is another case where the documentation of Matlab syntax is (and always has been) lacking. I've harped on this point of needing a definitive "Standard" (for lack of better nomenclature) for going on 30 yr now.
As a practical programming matter it should be defined and be the value at the last iteration but if it's TMW's desire that it not be relied on then that should definitely be documented as being so. It's this "black hole" of no definition that is a quagmire.
dpb
on 26 Jun 2014
I submitted a Service Request on the definition of the for iterator after loop completion being undocumented behavior. The "interpretation" is that it is defined and retains the value it had during at the exit of the loop. The text of the response is included below--
I am writing in reference to your Service Request, Case #01012664 regarding 'For iterator status on completion of loop'.
The iterator is always defined at the end of a loop. Whether a variable is defined or not in any context depends upon the workspace that you are looking at and the workspace that the variable exists in.
In MATLAB, loops run in their parent workspace. So, if a for loop is defined in a script, the for loop utilizes the base workspace (the workspace used by scripts) and the iterator is defined in the base workspace.
If the for loop is running in a function, the for loop utilizes the function's workspace and hence the iterator is also defined in the function workspace.
At the end of the for loop, the iterator will retain the final value that it reached during the execution of the for loop for the last time. [emphasis added as this was our point of uncertainty and the point of the SR being filed]
You are right in your observation that this particular behavior is not clearly documented and it should be. I will go ahead and put in an enhancement request so that the documentation team can consider adding this information to the documentation in a future release of MATLAB.
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