First off, there's a problem in your code: Try `randomInRange(0,5e-324)`

or just enter `Math.random()*5e-324`

in your browser's JavaScript console.

Even without overflow/underflow/denorms, it's difficult to reason reliably about floating point ops. After a bit of digging, I can find a counterexample:

```
>>> a=1.0
>>> b=2**-54
>>> rand=a-2*b
>>> a
1.0
>>> b
5.551115123125783e-17
>>> rand
0.9999999999999999
>>> (a-b)*rand+b
1.0
```

It's easier to explain why this happens with a=2^{53} and b=0.5: 2^{53}-1 is the next representable number down. The default rounding mode ("round to nearest even") rounds 2^{53}-0.5 up (because 2^{53} is "even" [LSB = 0] and 2^{53}-1 is "odd" [LSB = 1]), so you subtract `b`

and get 2^{53}, multiply to get 2^{53}-1, and add `b`

to get 2^{53} again.

To answer your second question: Because the underlying PRNG almost always generates a random number in the interval [0,2^{n}-1], i.e. it generates random bits. It's very easy to pick a suitable n (the bits of precision in your floating point representation) and divide by 2^{n} and get a predictable distribution. Note that there are some numbers in `[0,1)`

that you will will *never* generate using this method (anything in (0,2^{-53}) with IEEE doubles).

It also means that you can do `a[Math.floor(Math.random()*a.length)]`

and not worry about overflow (homework: In IEEE binary floating point, prove that `b < 1`

implies `a*b < a`

for positive integer `a`

).

The other nice thing is that you can think of each random output x as representing an interval [x,x+2^{-53}) (the not-so-nice thing is that the average value returned is slightly less than 0.5). If you return in [0,1], do you return the endpoints with the same probability as everything else, or should they only have half the probability because they only represent half the interval as everything else?

To answer the simpler question of returning a number in [0,1], the method below effectively generates an integer [0,2^{n}] (by generating an integer in [0,2^{n+1}-1] and throwing it away if it's too big) and dividing by 2^{n}:

```
function randominclusive() {
// Generate a random "top bit". Is it set?
while (Math.random() >= 0.5) {
// Generate the rest of the random bits. Are they zero?
// If so, then we've generated 2^n, and dividing by 2^n gives us 1.
if (Math.random() == 0) { return 1.0; }
// If not, generate a new random number.
}
// If the top bits are not set, just divide by 2^n.
return Math.random();
}
```

The comments imply base 2, but I *think* the assumptions are thus:

- 0 and 1 should be returned equiprobably (i.e. the Math.random() doesn't make use of the closer spacing of floating point numbers near 0).
- Math.random() >= 0.5 with probability 1/2 (should be true for even bases)
- The underlying PRNG is good enough that we can do this.

Note that random numbers are always generated in pairs: the one in the `while`

(a) is always followed by either the one in the `if`

or the one at the end (b). It's fairly easy to verify that it's sensible by considering a PRNG that returns either 0 or 0.5:

`a=0 b=0 `

: return 0
`a=0 b=0.5`

: return 0.5
`a=0.5 b=0 `

: return 1
`a=0.5 b=0.5`

: loop

Problems:

- The assumptions might not be true. In particular, a common PRNG is to take the top 32 bits of a 48-bit LCG (Firefox and Java do this). To generate a double, you take 53 bits from two consecutive outputs and divide by 2
^{53}, but some outputs are impossible (you can't generate 2^{53} outputs with 48 bits of state!). I suspect some of them never return 0 (assuming single-threaded access), but I don't feel like checking Java's implementation right now.
- Math.random() is twice for every
*potential* output as a consequence of needing to get the extra bit, but this places more constraints on the PRNG (requiring us to reason about four consecutive outputs of the above LCG).
- Math.random() is called on average about
*four* times per output. A bit slow.
- It throws away results deterministically (assuming single-threaded access), so is pretty much guaranteed to reduce the output space.