You should be aware that you cannot *guarantee* the random number generator is working properly. Note that even a perfect uniform distribution in range [1,10] - there is a 10^{-10} chance of getting 10 times 10 in a random sampling of 10 numbers.

Is it likely? Of course not.

So - what *can* we do?

We can **statistically prove** that the combination (10,10,....,10) is *unlikely* if the random number generator is indeed uniformly distributed. This concept is called **Hypothesis testing**. With this approach we can say "with certainty level of x% - we can reject the hypothesis that the data is taken from a uniform distribution".

A common way to do it, is using **Pearson's Chi-Squared test**, The idea is similar to yours - you fill in a table - check what is the *observed* (generated) number of numbers for each cell, and what is the *expected* number of numbers for each cell under the null hypothesis (in your case, the expected is `k/M`

- where M is the range's size, and k is the total number of numbers taken).

You then do some manipulation on the data (see the wikipedia article for more info what this manipulation is exactly) - and get a number (the test statistic). You then check if this number is *likely* to be taken from a Chi-Square Distribution. If it is - you cannot reject the null hypothesis, if it is not - you can be certain with x% certainty that the data is not taken from a uniform random generator.

**EDIT:** example:

You have a cube, and you want to check if it is "fair" (uniformly distributed in `[1,6]`

). Throw it 200 times (for example) and create the following table:

```
number: 1 2 3 4 5 6
empirical occurances: 37 41 30 27 32 33
expected occurances: 33.3 33.3 33.3 33.3 33.3 33.3
```

Now, according to Pearson's test, the statistic is:

```
X = ((37-33.3)^2)/33.3 + ((41-33.3)^2)/33.3 + ... + ((33-33.3)^2)/33.3
X = (18.49 + 59.29 + 10.89 + 39.69 + 1.69 + 0.09) / 33.3
X = 3.9
```

For a random `C~ChiSquare(5)`

, the probability of being higher then `3.9`

is `~0.45`

(which is not improbable)^{1}.

So we *cannot* reject the null hypothesis, and we can conclude that the data is *probably* uniformly distributed in `[1,6]`

(1) We usually reject the null hypothesis if the value is smaller then 0.05, but this is very case dependent.

numberof failures and see if it's reasonable. – David Schwartz Aug 30 '12 at 5:01