It is perfectly possible that it will never return exactly zero. Java's included PRNG is a 48-bit LCG from which only 32 bits are ever used. For all 53 bits of a `double`

mantissa to be zero, you'll essentially need at least *one* call to `next()`

where the upper 32 bits are zero and another where most of them are. (If I'm not mistaken, I'd say this won't ever happen with how the generator works, but it's late, I'm tired, and I won't bet much on it.)

Since the method documentation explicitly states how random numbers are obtained there is also little leeway for other implementations of the Java runtime to yield different results. The *contract* might say that the number you get is from [0, 1). But in practice there are quite a number of values you'll never hit (because you need two successive values from a generator that foribly yields a linear dependency between successive values – there are only 48 bits of state. You can't generate all different 53-bit combinations from that – at least not how it's done.).

Of course, since `Math.random()`

automatically seeds a static `Random`

instance, we might also have to consider the seed here, which *may* need to be very specific for a test case to work out. And that might mean that that exact point in time could be a few decades or millennia away.

`double`

with 53 uniformly-distributed pseudo-random bits in its mantissa. – Joey Jun 17 '10 at 23:31