### TL;DR

For maximum performance, if you only need a singe sample, use

```
R = a( sum( (rand(1) >= cumsum(w./sum(w)))) + 1 );
```

and if you need multiple samples, use

```
[~, R] = histc(rand(N,1),cumsum([0;w(:)./sum(w)]));
```

Avoid `randsample`

. Generating multiple samples upfront is three orders of magnitude faster than generating individual values.

### Performance metrics

Since this showed up near the top of my Google search, I just wanted to add some performance metrics to show that the right solution will depend very much on the value of N and the requirements of the application. Also that changing the design of the application can dramatically increase performance.

For large `N`

, or indeed `N > 1`

:

```
a = 1:3; % possible numbers
w = [0.3 0.1 0.2]; % corresponding weights
N = 100000000; % number of values to generate
w_normalized = w / sum(w) % normalised weights, for indication
fprintf('randsample:\n');
tic
R = randsample(a, N, true, w);
toc
tabulate(R)
fprintf('bsxfun:\n');
tic
R = a( sum( bsxfun(@ge, rand(N,1), cumsum(w./sum(w))), 2) + 1 );
toc
tabulate(R)
fprintf('histc:\n');
tic
[~, R] = histc(rand(N,1),cumsum([0;w(:)./sum(w)]));
toc
tabulate(R)
```

Results:

```
w_normalized =
0.5000 0.1667 0.3333
randsample:
Elapsed time is 2.976893 seconds.
Value Count Percent
1 49997864 50.00%
2 16670394 16.67%
3 33331742 33.33%
bsxfun:
Elapsed time is 2.712315 seconds.
Value Count Percent
1 49996820 50.00%
2 16665005 16.67%
3 33338175 33.34%
histc:
Elapsed time is 2.078809 seconds.
Value Count Percent
1 50004044 50.00%
2 16665508 16.67%
3 33330448 33.33%
```

In this case, `histc`

is fastest

However, in the case where maybe it is not possible to generate all N values up front, perhaps because the weights are updated on each iterations, i.e. `N=1`

:

```
a = 1:3; % possible numbers
w = [0.3 0.1 0.2]; % corresponding weights
I = 100000; % number of values to generate
w_normalized = w / sum(w) % normalised weights, for indication
R=zeros(N,1);
fprintf('randsample:\n');
tic
for i=1:I
R(i) = randsample(a, 1, true, w);
end
toc
tabulate(R)
fprintf('cumsum:\n');
tic
for i=1:I
R(i) = a( sum( (rand(1) >= cumsum(w./sum(w)))) + 1 );
end
toc
tabulate(R)
fprintf('histc:\n');
tic
for i=1:I
[~, R(i)] = histc(rand(1),cumsum([0;w(:)./sum(w)]));
end
toc
tabulate(R)
```

Results:

```
0.5000 0.1667 0.3333
randsample:
Elapsed time is 3.526473 seconds.
Value Count Percent
1 50437 50.44%
2 16149 16.15%
3 33414 33.41%
cumsum:
Elapsed time is 0.473207 seconds.
Value Count Percent
1 50018 50.02%
2 16748 16.75%
3 33234 33.23%
histc:
Elapsed time is 1.046981 seconds.
Value Count Percent
1 50134 50.13%
2 16684 16.68%
3 33182 33.18%
```

In this case, the custom `cumsum`

approach (based on the `bsxfun`

version) is fastest.

In any case, `randsample`

certainly looks like a bad choice all round. It also goes to show that if an algorithm can be arranged to generate all random variables upfront then it will perform *much* better (note that there are three orders of magnitude less values generated in the `N=1`

case in a similar execution time).

Code is available here.