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.

The loop is as follows:

for j = 1:20   
  sigma = (y<0) - (y>=0);    
  x0 = x;  
  out_angle = out_angle - sigma*lut(j);  
  x = x-(y.*sigma)*poweroftwo;  
  y = y+(x0.*sigma)*poweroftwo;   
  poweroftwo = poweroftwo/2;  
end  

out_angle, x,y and sigma are matrices of dim m*n. lut is an array of size 20. poweroftwo is a scalar with initial value 1. Is it possible to vectorize this code and avoid the for loop?

share|improve this question
    
I assume m and/or n are very large, or that the 20 is an example value which is really much larger for your problem? Because if that isn't so, a vectorization of this tiny loop makes little sense, and will in all probability be slower than the loop (see this for example) –  Rody Oldenhuis Aug 9 '12 at 7:08
    
Yes, m and n are pretty large. Infact, there is no limit on their values. The code is designed so as to work for any value of m and n. Because of the interdependancies between the matrices x,y and sigma, I'm finding it extremely difficult to vectorize this. Is there any way to do that? –  user1586556 Aug 9 '12 at 8:48
    
Did you profile this? It doesn't seem like it should be slow...Are you positive this is your bottleneck? –  Rody Oldenhuis Aug 9 '12 at 9:01
    
Actually, it is not a matter of whether it is slow or fast. This is an assignment given to me and it was specifically mentioned to avoid for loops. Also, now that I have worked on it for quite a long time, I would like to know whether vectorization is possible for this problem, even if it is slower. –  user1586556 Aug 9 '12 at 9:16

1 Answer 1

A lot of informaiton is missing for the vectorization of this loop. Just have a look at the line

out_angle = out_angle - sigma*lut(j);

After vectorization you would like to have an expression similar to

out_angle(j) = out_angle(j-1) - sigma*lut(j);

You immediately see that the current out_angle depends on the previously computed value. This also means that out_angle can only be computed sequentially except if you can come up with an explicit representation of out_angle.

out_angle(j) = out_angle(j-1) - sigma*lut(j)
             = out_angle(j-2) - sigma*lut(j-1) - sigma*lut(j)
             = out_angle(j-3) - sigma*lut(j-2) - sigma*lut(j-1) - sigma*lut(j)
             = ...
             = out_angle(0) - sum_{k = 0}^j (sigma*lut(k))

The thing gets more complicated as sigma also depends on j, i.e. actually you have sigma(j) and thus

out_angle(j) = out_angle(0) - sum_{k = 0}^j (sigma(k)*lut(k))

Unfortunately you also have only an implicit expression for sigma which you have to resolve in the same manner. You can probably think a bit about the structure behind sigma. This is a variable, which is 1, where y is negative and -1 where y is positive or zero, i.e. it is something like

sigma = -mySign(y)

where mySign acts like the sign function but gives 1 for a zero argument.

If you can find an explicit representation for sigma, you can insert it into the explicit representation of out_angle above. After that you can (most likely) vectorize the code.

share|improve this answer
    
But even if I find such an expression, the problems doesnt end. The value of x depends on the previously computed value of y, which inturn depends on the previous value of x. Is there any way to counter this or is it safe to assume that vectorization is simply not possible in this case? –  user1586556 Aug 9 '12 at 12:51
    
You can of course apply the same approach to the x variable as well even if it depends on the previous y value. The question is what you know about x(0) and y(0). Is this random or measured data? In this case vectorization is not possible. If this data is static, you can probably vectorize the code. However, the effort seems to be quite big. Finally it is also questionable, if you have enough memory. Right now you need to store x, y, sigma and out_data only once. After vectorization you have 20 copies of them. –  Mehrwolf Aug 9 '12 at 17:04

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.