# José's Daylight Dices

Or is there an easy way to generate a true random uint?

I admit, it's not the OQ. It will become clear that there are faster ways to generate random uints which are not true ones. Nevertheless I assume that nobody is too interested in generating those, except when a non-flat distribution is needed for some reason. Let's start with some *research* to get it easy and fast in C#. Easy and fast often behave like synonyms when I write code.

## First: Some important properties

See MSDN.

`Random`

constructors:

`Random()`

: Initializes a new instance of the `Random`

class, using a time-dependent default seed value.
`Random(int seed)`

: Initializes a new instance of the `Random`

class, using the specified seed value.

To improve performance, create one `Random`

object to generate many random numbers over time, instead of repeatedly creating new `Random`

objects to generate one random number, so:

```
private static Random rand = new Random();
```

`Random`

methods:

`rand.Next()`

: Returns a positive random number, greater than or equal to zero, less than `int.MaxValue`

.
`rand.Next(int max)`

: Returns a positive random number, greater than or equal to zero, less then max, max must be greater than or equal to zero.
`rand.Next(int min, int max)`

: Returns a positive random number, greater than or equal to min, less then max, max must be greater than or equal to min.

Homework shows that `rand.Next()`

is about twice as fast as `rand.Next(int max)`

.

## Second: A solution.

Suppose a positive int has only two bits, forget the sign bit, it's zero, `rand.Next()`

returns three different values with equal probability:

```
00
01
10
```

For a true random number the lowest bit is zero as often as it is one, same for the highest bit.

To make it work for the lowest bit use: `rand.Next(2)`

Suppose an int has three bits, `rand.Next()`

returns seven different values:

```
000
001
010
011
100
101
110
```

To make it work for the lowest two bits use: `rand.Next(4)`

Suppose an int has *n* bits.

To make it work for *n* bits use: `rand.Next(1 << n)`

To make it work for a maximum of 30 bits use: `rand.Next(1 << 30)`

It's the maximum, 1 << 31 is larger than `int.MaxValue`

.

Which leads to a way to generate a true random uint:

```
private static uint rnd32()
{
return (uint)(rand.Next(1 << 30)) << 2 | (uint)(rand.Next(1 << 2));
}
```

A quick check: What's the chance to generate zero?

1 << 2 = 4 = 2^{2}, 1 << 30 = 2^{30}

The chance for zero is: 1/2^{2} * 1/2^{30} = 1/2^{32}
The total number of uints, including zero: 2^{32}

It's as clear as daylight, no smog alert, isn't it?

## Finally: A misleading idea.

Is it possible to do it faster using `rand.Next()`

```
int.Maxvalue is: (2^31)-1
The largest value rand.Next() returns is: (2^31)-2
uint.MaxValue is: (2^32)-1
```

When `rand.Next()`

is used twice and the results are added, the largest possible value is:

```
2*((2^31)-2) = (2^32)-4
```

The difference with uint.MaxValue is:

```
(2^32)-1 - ((2^32)-4) = 3
```

To reach `uint.MaxValue`

, another value, `rand.Next(4)`

has to be added, thus we get:

rand.Next() + rand.Next() + rand.Next(4)

What's the chance to generate zero?

Aproximately: 1/2^{31} * 1/2^{31} * 1/4 = 1/2^{64}, it should be 1/2^{32}

Wait a second, what about:

```
2 * rand.Next() + rand.Next(4)
```

Again, what's the chance to generate zero?

Aproximately: 1/2^{31} * 1/4 = 1/2^{33}, too small to be truly random.

Another easy example:

`rand.Next(2) + rand.Next(2)`

, all possible results:

```
0 + 0 = 0
0 + 1 = 1
1 + 0 = 1
1 + 1 = 2
```

Equal probabilities? No way José.

Conclusion: The addition of true random numbers gives a random number, but not a true random number. Throw two fair dice ...