You can speed things up a bit from what mtrw posted above just by doing what you initially described (generating a bunch of random numbers and multiplying and dividing accordingly)...

Also, you probably already know this, but be sure to do the operations in-place (*=, /=, +=, etc) when working with large-ish numpy arrays. It makes a huge difference in memory usage with large arrays, and will give a considerable speed increase, too.

```
In [53]: def rand_row_doubles(row_limits, num):
....: ncols = len(row_limits)
....: x = np.random.random((num, ncols))
....: x *= row_limits
....: return x
....:
In [59]: %timeit rand_row_doubles(np.arange(7) + 1, 1000000)
10 loops, best of 3: 187 ms per loop
```

As compared to:

```
In [66]: %timeit ManyRandDoubles(np.arange(7) + 1, 1000000)
1 loops, best of 3: 222 ms per loop
```

It's not a huge difference, but if you're *really* worried about speed, it's something.

Just to show that it's correct:

```
In [68]: x.max(0)
Out[68]:
array([ 0.99999991, 1.99999971, 2.99999737, 3.99999569, 4.99999836,
5.99999114, 6.99999738])
In [69]: x.min(0)
Out[69]:
array([ 4.02099599e-07, 4.41729377e-07, 4.33480302e-08,
7.43497138e-06, 1.28446819e-05, 4.27614385e-07,
1.34106753e-05])
```

Likewise, for your "rows sum to one" part...

```
In [70]: def rand_rows_sum_to_one(nrows, ncols):
....: x = np.random.random((ncols, nrows))
....: y = x.sum(axis=0)
....: x /= y
....: return x.T
....:
In [71]: %timeit rand_rows_sum_to_one(1000000, 13)
1 loops, best of 3: 455 ms per loop
In [72]: x = rand_rows_sum_to_one(1000000, 13)
In [73]: x.sum(axis=1)
Out[73]: array([ 1., 1., 1., ..., 1., 1., 1.])
```

Honestly, even if you re-implement things in C, I'm not sure you'll be able to beat numpy by much on this one... I could be very wrong, though!

`python -mtimeit -s'import numpy as np' 'np.random.randint(low=0, high=500, size=(1000000,1))'`

->`100 loops, best of 3: 11.9 msec per loop`

– J.F. Sebastian Apr 25 '10 at 20:50