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I have a few questions. Bear with me please. I wrote down a program and am trying to optimize it. I am posting only the code snippets that I believe that can be further optimized.

1. First of all I am trying to calculate the gradient of an image. I previously used the gradient operator of the MATLAB but found it to be slow. So I wrote down my own code. Please find my code at my gradient code here!

I ran the profiler on MATLAB and found that my program still had a few bottlenecks. I am posting an image here : gradient profile

As you can see I am using two extra matrices A and B two times each for the calculation of the gradient in the horizontal & vertical direction. Is it really necessary ? Can't the operation be integrated in line 5 & line 8 without the use of extra matrices A & B. Will the removal of the extra matrices A & B make my code run faster ?

2. Secondly I needed to use the Laplacian operator in my code and found it to be one of the bottlenecks of my program. I have already read the matlab documentation & also read the links Discrepancy between Matlab del2 and Matlab gradient of gradient and Understanding DEL2 function in Matlab in order to code it in C++.

I then checked the profile of del2 and found this. enter image description here. My question is this what are the functions of the children function parse_inputs and ipermute in this case ? It is to be noted that I am working with an image matrix whose size will always be greater than 64X64.

I read the explanation for permute and it said that "Permute so that the del2 is always taken along the columns.". What does it mean actually ? I read somewhere that MATLAB uses column major format . Could anyone please explain what it means ?

Regarding the parse_inputs sub-function I read the explanation where it stated that

                  %   [ERR,F,LOC,CFLAG] = PARSE_INPUTS(F,V) returns the spacing LOC
                  %   along the x,y,z,... directions and a column vector flag CFLAG. ERR
                  %   will be true if there is an error.

I have no idea what this function does. Please can anyone explain ?

3. I also tried to write down my own del2 function for matlab so as to make it faster but strangely I could only cope with the interior points. Is the implementation in MATLAB correct for del2 ? Why does it do extrapolation at the boundary points ?

Should not the basis of the Laplacian operator be always that it should hold the equality ?

laplacian = del2(image);

[x, y] = gradient(image);
[xx, xy] = gradient(x);
[yx, yy] = gradient(y);
laplacian = xx + yy;

This code was taken from Please check code. I read all the posts there but the explanation did not satisfy me. Please could you explain why the above code does not give the same output ?

Thanks everyone for reading this long and boring set of questions. Any help will be greatly appreciated. If anyone has a problem I will split the questions and post it separately. Just say so guys!

Thanks in advance !

EDIT : After slogging through the whole day finally managed to remove the offending matrices A & B. I am writing down the code below :

function [dx dy] = gradient_my_code(I)
dx=[I(:,2)-I(:,1) (I(:,3:end)-I(:,1:end-2))./2 I(:,end)-I(:,end-1)];
dy=[I(2,:)-I(1,:) ; (I(3:end,:)-I(1:end-2,:))./2 ; I(end,:)-I(end-1,:)];

For timing purposes I did this :

xaxis = [10,20,30,40,50,60,70,80,90,100,200,300,400,500,600,700,800,900,1000,2000,3000,4000,5000];
n1 = zeros(1,length(xaxis));
n2 = zeros(1,length(xaxis));
for i=1:length(xaxis);
    [dx dy] = gradient(u);
    [dx dy] = gradient_my_code(u);
hold on;
hold off;

Speed comparison between gradient of matlab and my code

And I plotted the speed comparison . Please check and guys give your comments.

share|improve this question
up vote 2 down vote accepted

Given the large number of questions I attempt to summarize:

(1) Matlab is highly optimized, so it is unlikely that you can beat the native routines written by the people at Mathworks based on extensive numerical research. As a caveat, because the Mathworks code often performs error, data type, and dimensionality checking on inputs, you can save some time during execution by writing code that does not perform those tasks, but I don't recommend that unless you have a very good reason to do so. You can also write mex functions which can (but I can't verify this) save some time on execution if you have a large project.

(2) Matlab routines are generally written to process arrays columnwise (since the routines are written to take advantage of columnwise data storage). If you read the code behind function gradient you'll find, for instance, that one of the steps is to "permute so that the gradient is always taken along the columns."

(3) I recommend you look at the code behind del2 (with edit del2) and gradient to understand why computing the Laplacian as del2 versus xx+yy as in your code would be different. It has to do with different finite difference approximations for continuous 1st vs 2nd derivatives.

As far as the behavior of del2 at the edges, it turns out that one step in the algorithm is to "linearly extrapolate second differences from interior". It's simply a way of obtaining an approximation of the Laplacian for all of the points in the input array, including at the edges where only a single-sided approx is possible.

Finally, on parse_inputs: this is just a function that takes care of assigning values to all of the variables used in the gradient computation, using either user input or defaults as the case may be.

share|improve this answer
@roni That is an interesting result. I'll take your word for it and attempt the computations when I have some more time :). If you look at function gradient, there is some overhead (as I mentioned) in parsing the input, applying permutations as necessary, and, I think most importantly (but have not verified!) dividing the differences by a step size, something you do not do. Since division is costly, I am not surprised if your routine, which basically removes all of the aforementioned steps, is faster. The factor of 2 is however somewhat impressive. – Try Hard Sep 25 '13 at 17:31
@roni On the other hand, if you are serious about performance and not just getting practice with different algorithms, follow the advice provided to your previous question and use the routines accompanying the image processing toolbox (if you have it) or look at similar routines at matlab central. Those are optimized (using compiled mex routines) for heavy duty processing of large datasets. – Try Hard Sep 25 '13 at 17:33
@roni I checked your computations, the result is as you report. I was actually surprised to see that modifying the code in gradient - in particular I/O handling, had a large effect on the time. The main effect was due to division by a step size array, as I mentioned. I don't have the profiler to check the effect of these changes in detail without a large investment in time. Your code for computation of the gradient looks fine however. Keep in mind that you lack a step size. – Try Hard Sep 26 '13 at 12:59
BTW if this answered your question feel free to click on the check mark next to the answer. – Try Hard Sep 26 '13 at 13:00
@Try Hard I just wanted to let you know that I have seen a few instances where custom code is faster than Matlab's defaults. The cases are usually specialized, but not uncommon. A great example is using fft->multiply->ifft instead of conv. And the reason why compiled code is (sometimes) faster is because a compiler tries to reorganize/rewrite your code to improve performance using a defined set of rules. Though, even when scripting, Matlab has a "Just In Time" compiler that's supposed to do some degree of optimization of your script before running it. – TTT Sep 26 '13 at 13:47

Try using Jan Simon's DGradient MEX function. It is 10-20 times faster than gradient and provides the same results. You can then modify its source code for a similar improvement to the del2 performance.

This is indeed a rare example where a Mex file outperforms a native Matlab function by such a significant speedup.

share|improve this answer
Thanks for the info! I will try it out and let u know. Actually I do not know how to run a MEX function in matlab. I am using a windows 7 64 bit OS and do not have C/C++ installed. That's why I was searching for inbuilt matlab command .....Anyway could u give any suggestions for improving the del2 performance ? – roni Oct 17 '13 at 7:10
Re Mex, read mathworks.com/help/matlab/create-mex-files.html – Yair Altman Oct 17 '13 at 10:32

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