Analyzing your question is harder than it might seem:

You seed the mersenne twister with `rd()`

, which returns an `unsigned int`

, and therefore (on most platforms) contains at most 32 random bits.

Everything that the mersenne twister does from this point on is determined by those 32 bits.

This means that the `value`

can only take on 2**32 different values, which can be a problem if any attack vector exists that attacks whatever you do with this number by brute force. In fact, the mersenne twister's seeding routine may even reduce the number of possible values for the first result, since it distributes the 32 random bits over its complete state (to ensure that this is not the case you would have to analyse the seed routine boost uses).

The primary weakness of the mersenne twister (its state can be derived after seeing 624 numbers) is not even of interest in this case however, since you generate a sequence that is so short (1 value).

### Generating 64 cryptographically secure bits

Assuming that `unsigned int`

is equivalent to `uint32_t`

on your platform, you can easily generate 64 cryptographically secure random bits by using `boost::random_device`

:

```
boost::random_device rd;
std::uint64_t value = rd();
value = (value << 32) | rd();
```

This is fairly secure, since the implementations for both linux and windows use the operating system's own cryptographically secure randomness sources.

### Generating cryptographically secure values with arbitrary distributions

While the previous works well enough, you may wish for a more flexible solution. This is easy to do by realizing that you can actually use the random distributions boost provides with `random_device`

as well. A simple example would be to rewrite the previous solution like this:

```
boost::random_device rd;
boost::random::uniform_int_distribution<std::uint64_t> dis;
std::uint64_t value = dis(rd);
```

(While this can in theory also provide a more robust solution if the previous one does not actually contain a number in [0, 2**32), this is not a problem in practice.)

### Binding distribution to generator

To improve usability you will often find usage of `boost::bind`

to bind distribution and generator together. Since `boost::bind`

copies its arguments, and the copy ctor is deleted for `boost::random_device`

, you need to use a little trick:

```
boost::random_device rd;
boost::random::uniform_int_distribution<std::uint64_t> dis;
boost::function<std::uint64_t()> gen = boost::bind(dis, boost::ref(rd));
std::uint64_t value = gen();
```

`random_device`

twice (assuming 32-bit`int`

), and append the results. Also, you may not want to use the default`/dev/urandom`

source, but pass the argument`"/dev/random"`

to the`random_device`

constructor. Unlike the former, the latter will block when there are no more random bits available in the entropy pool. – Praetorian Apr 29 at 18:47`/dev/urandom`

over`/dev/random`

. Once sufficiently seeded (with say 200 bits of entropy) a PRNG cannot run out of entropy, no matter how much you read. So`/dev/random`

does lots of unnecessary blocking. The only concern with`/dev/urandom`

is that it might not besufficiently seeded yet, which is mostly relevant early in the boot process on embedded devices. – CodesInChaos May 2 at 9:30