Assuming that:

- i starts at 1
- intersum starts at zeros

Here's a vectorized form of you code that produces the exact same result as your original:

```
function C = version_a()
source_data = rand(10,20)<.8;
G = rand(10,15)<.9;
intersum = zeros(1, size(source_data,2));
z = 1;
i = 1;
while i <= 15
for j=1:10
if(G(j,i)==1)
intersum(z+1,:)=xor(intersum(z,:), source_data(j,:));
z=z+1;
end
end
C(i,:)=intersum(z,:);
i=i+1;
end
ret = C;
end
function C = version_b()
source_data = rand(10,20)<.8; % Can initialize in a single call
G = rand(10,15)<.9; % Same here
C = zeros(size(G,2),size(source_data,2));
C(1,:) = mod(sum(source_data(G(:,1),:)),2);
for i = 2:15
C(i,:) = mod(C(i-1,:) + sum(source_data(G(:,i),:)),2);
end
end
```

To check the timing of both versions I used this test function:

```
function ret = xor_test()
ret = 0;
seed = 123456789;
laps = 10000;
tic
for i = 1:laps
RandStream.getDefaultStream.reset(seed);
a = version_a();
end
toc
tic
for i = 1:laps
RandStream.getDefaultStream.reset(seed);
b = version_b();
end
toc
ret = ret + sum(sum(b ~= a));
end
```

And I got the following timings on my machine:

```
Elapsed time is 13.537738 seconds.
Elapsed time is 2.302747 seconds.
ans =
0
```

Now to why I changed it that way...

A `xor`

operation over an array of `logical`

s is pretty much checking the parity of the sum (treating `true`

values as 1). Furhtermore, `intersum`

is being used as an accumulator, so there's who's values eventually ends up in `C`

so we skip it altogether. Taking the rows for which `G(j,i)`

is 1 can be done by logical indexing.

And finally, even if you don't like this proposed version, I'd recommend preallocating your your `C`

and `intersum`

vectors (in case you're not doing so already). That has made a lot of difference for me in the past.

`i`

and what is`K`

in the last loop?`xor`

itself is already vectorized, perhaps it's helpful for you: mathworks.de/help/techdoc/ref/xor.html Otherwise you could have a look at`arrayfun`

– tim Feb 1 '12 at 7:51