`std::uniform_real_distribution`

.

There's a really good talk by S.T.L. from this year’s Going Native conference that explains why you should use the standard distributions whenever possible. In short, hand-rolled code tends to be of laughably poor quality (think `std::rand() % 100`

), or have more subtle uniformity flaws, such as in `(std::rand() * 1.0 / RAND_MAX) * 99`

, which is the example given in the talk and is a special case of the code posted in the question.

EDIT: I took a look at libstdc++’s implementation of `std::uniform_real_distribution`

, and this is what I found:

The implementation produces a number in the range `[dist_min, dist_max)`

by using a simple linear transformation from some number produced in the range `[0, 1)`

. It generates this source number using `std::generate_canonical`

, the implementation of which my be found here (at the end of the file). `std::generate_canonical`

determines the number of times (denoted as `k`

) the *range of the distribution*, expressed as an integer and denoted here as `r`

*, will fit in the mantissa of the target type. What it then does is essentially to generate one number in `[0, r)`

for each `r`

-sized segment of the mantissa and, using arithmetic, populate each segment accordingly. The formula for the resulting value may be expressed as

```
Σ(i=0, k-1, X/(r^i))
```

where `X`

is a stochastic variable in `[0, r)`

. Each division by the range is equivalent to a shift by the number of bits used to represent it (i.e., `log2(r)`

), and so fills the corresponding mantissa segment. This way, the whole of the precision of the target type is used, and since the range of the result is `[0, 1)`

, the exponent remains `0`

** (modulo bias) and you don’t get the uniformity issues you have when you start messing with the exponent.

I would not trust implicity that this method is cryptographically secure (and I have suspicions about possible off-by-one errors in the calculation of the size of `r`

), but I imagine it is significantly more reliable in terms of uniformity than the Boost implementation you posted, and **definitely** better than fiddling about with `std::rand`

.

It may be worth noting that the Boost code is in fact a degenerate case of this algorithm where `k = 1`

, meaning that it is equivalent **if** the input range requires at least 23 bits to represent its size (IEE 754 single-precision) or at least 52 bits (double-precision). This means a minimum range of ~8.4 million or ~4.5e15, respectively. In light of this information, I don’t think that if you’re using a binary generator, the Boost implementation is *quite* going to cut it.

After a brief look at libc++’s implementation, it looks like they are using what is the same algorithm, implemented slightly differently.

(*) `r`

is actually the range of the input *plus one*. This allows using the `max`

value of the urng as valid input.

(**) Strictly speaking, the encoded exponent is not `0`

, as IEEE 754 encodes an implicit leading 1 before the radix of the significand. Conceptually, however, this is irrelevant to this algorithm.

`[min, max)`

", because without a range restrictions, there are no uniform random number generators. :)`[min - n*ULP, max + n*ULP)`

would be fine though for some value of`n`

that I'm too lazy to think about but is probably 1.`[std::numeric_limits<double>::Min(), std::numeric_limits<double>::Max())`

, rounded, then discarded if outside of`[min, max)`

. ;)6more comments