If you know the distribution you want (called the Probability Distribution Function (PDF)) and have it properly normalized, you can integrate it to get the Cumulative Distribution Function (CDF), then invert the CDF (if possible) to get the transformation you need from uniform `[0,1]`

distribution to your desired.

So you start by defining the distribution you want.

```
P = F(x)
```

(for x in [0,1]) then integrated to give

```
C(y) = \int_0^y F(x) dx
```

If this can be inverted you get

```
y = F^{-1}(C)
```

So call `rand()`

and plug the result in as `C`

in the last line and use y.

This result is called the Fundamental Theorem of Sampling. This is a hassle because of the normalization requirement and the need to analytically invert the function.

Alternately you can use a rejection technique: throw a number uniformly in the desired range, then throw another number and compare to the PDF at the location indeicated by your first throw. Reject if the second throw exceeds the PDF. Tends to be inefficient for PDFs with a lot of low probability region, like those with long tails...

An intermediate approach involves inverting the CDF by brute force: you store the CDF as a lookup table, and do a reverse lookup to get the result.

The real stinker here is that simple `x^-n`

distributions are non-normalizable on the range `[0,1]`

, so you can't use the sampling theorem. Try (x+1)^-n instead...