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I am trying to construct a summed area table or integral image given an image matrix. For those of you who dont know what it is, from wikipedia:

A summed area table (also known as an integral image) is a data structure and algorithm for quickly and efficiently generating the sum of values in a rectangular subset of a grid

In other words, its used to sum up values of any rectangular region in the image/matrix in constant time.

I am trying to implement this in R. However, my code seems to take too long to run.

Here is the pseudo code from this link. in is the input matrix or image and intImg is whats returned

for i=0 to w do

   for j=0 to h do
      sum ← sum + in[i, j]

      if i = 0 then
         intImg[i, j] ← sum
         intImg[i, j] ← intImg[i − 1, j] + sum
      end if
   end for 
end for

And here is my implementation

w = ncol(im)
h = nrow(im)
intImg = c(NA)
length(intImg) = w*h

for(i in 1:w){ #x
  sum = 0;
  for(j in 1:h){ #y
    ind = ((j-1)*w)+ (i-1) + 1 #index
    sum = sum + im[ind]
    if(i == 1){
      intImg[ind] = sum
      intImg[ind] = intImg[ind-1]+sum
intImg = matrix(intImg, h, w, byrow=T)

Example of input and output matrix:

enter image description here

However, on a 480x640 matrix, this takes ~ 4 seconds. In the paper they describe it to take on the order of milliseconds for those dimensions.

Am I doing something inefficient in my loops or indexing?

I considered writing it in C++ and wrapping it in R, but I am not very familiar with C++.

Thank you

share|improve this question
a link to im would make this reproducible. it's hard for me to parse what you're doing without an example, but you can probably use colSums() and rowSums() or some other vectorized function(s). – Chase May 14 '13 at 14:50
im is just any matrix. I've added an example of the input and output in the question – by0 May 14 '13 at 14:55
How much improvement do you get by changing intImg = c(NA) to intImg <- rep(NA, 480*460)? – joran May 14 '13 at 14:59
Hi joran, I've tried that. Doesn't change much. What's the difference? – by0 May 14 '13 at 15:01
You need to start being much more specific. "Doesn't change much" and providing images of example matrices isn't very helpful. – joran May 14 '13 at 15:02
up vote 5 down vote accepted

You could try to use apply (isn't faster than your for-loops if you pre-allocating the memory):

areaTable <- function(x) {
  return(apply(apply(x, 1, cumsum), 1, cumsum))

#      [,1] [,2] [,3] [,4]
# [1,]    4    5    7    9
# [2,]    4    9   12   17
# [3,]    7   13   16   25
# [4,]    9   16   22   33
share|improve this answer
It will be quicker - though probably not by a huge margin - as you are doing 8 cumsum calls (plus the loop forming code and allocation etc) whereas the OP's code is doing lots of calls to + to give the equivalent of your cumsum calls. As it is interpreted code all those function calls will add up. – Gavin Simpson May 14 '13 at 15:26
@GavinSimpson I'm actually surprised at how much faster it is, based on a quick timing of a 500x500 example. – joran May 14 '13 at 15:30
Yes, its vastly faster. I gave up waiting for two nested for loops, the double-apply took less than a second. – Spacedman May 14 '13 at 15:32
@joran I should have stuck to my initial thought - I went back and added the caveat before submitting the comment in a moment of self-doubt. cumsum is very efficient code and all those + calls will mount up as the dimensions of the input increase. Profiling the OP's code will show that. – Gavin Simpson May 14 '13 at 15:33
@GavinSimpson: you are right, I didn't thought about this fact of interpreted code. – sgibb May 14 '13 at 16:06

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