- 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
ret = C;
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);
To check the timing of both versions I used this test function:
function ret = xor_test()
ret = 0;
seed = 123456789;
laps = 10000;
for i = 1:laps
a = version_a();
for i = 1:laps
b = version_b();
ret = ret + sum(sum(b ~= a));
And I got the following timings on my machine:
Elapsed time is 13.537738 seconds.
Elapsed time is 2.302747 seconds.
Now to why I changed it that way...
xor operation over an array of
logicals 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
intersum vectors (in case you're not doing so already). That has made a lot of difference for me in the past.