If you want a script to generate just some small amount of tokens (like *2, 5, 10, 100, 1000, 10 000*, etc), then the best way would be to simply keep the already generated tokens in memory and retry until a new one is generated (statistically speaking, this wont take long). If this is not the case - keep reading.

After thinking about it, this problem turned out to be in fact very interenting. For brievety, I will not mention the requirement to have at least one number, capital and lower case letters, but it will be included in the final solution. Also let

`all = [*'1'..'9', *'a'..'z', *'A'..'Z']`

.

To sum it up, we want to generate k-permutations of n elements with repetition **randomly** with **uniqueness constraint**.
k = 10, n = 61 (`all.size`

)

Ruby just so happens to have such method, it's `Array#repeated_permutation`

. So everything is great, we can just use:

```
all.repeated_permutation(10).to_a.map(&join).shuffle
```

and pop the resulting strings one by one, right? Wrong! The problem is that the amount of possibilities happens to be:

k^n = 10000000000000000000000000000000000000000000000000000000000000 (`10**61`

).

Even if you had an infinetelly fast processor, you still can't hold such amount of data, no matter if this was the count of complex objects or simple bits.

The opposite would be to generate random permutations, keep the already generated in a set and make checks for inclusion before returning the next element. This is just delaying the innevitable - not only you would still have to hold the same amount of information at some point, but as the number of generated permutations grows, the number of tries required to generate a new permutation diverges to infinity.

As you might have thought, the root of the problem is that *randomness* and *uniqueness* hardly go hand to hand.

Firstly, we would have to define what we would consider as random. Judging by

the amount of

nerdy comics on

the subject, you could deduce that this isn't that black and white either.

An intuitive definition for a random program would be one that doesn't generate the tokens in the same order with each execution. Great, so now we can just take the first n permutations (where `n = rand(100)`

), put them at the end and enumerate everything in order? You can sense where this is going. In order for a random generation to be considered good, the generated outputs of consecutive runs should be equaly distributed. In simpler terms, the probability of getting any possible output should be equal to **1 / #__all_possible_outputs__**.

Now lets explore the boundaries of our problem a little:

The number of possible k-permutations of n elements without repetition is:

n!/(n-k)! = 327_234_915_316_108_800 (`(61 - 10 + 1).upto(61).reduce(:*)`

)

Still out of reach. Same goes for

The number of possible full permutations of n elements without repetition:

n! = 507_580_213_877_224_798_800_856_812_176_625_227_226_004_528_988_036_003_099_405_939_480_985_600_000_000_000_000 (`1.upto(61).reduce(:*)`

)

The number of possible k-combinations of n elements without repetition:

n!/k!(n-k)! = 90_177_170_226 (`(61 - 10 + 1).upto(61).reduce(:*)/1.upto(10).reduce(:*)`

)

Finally, where we might have a break through with full permutation of k elements without repetition:

k! = 3_628_800 (`1.upto(10).reduce(:*)`

)

**~3.5m** isn't nothing, but at least it's reasonably computable. On my personal laptop `k_permutations = 0.upto(9).to_a.permutation.to_a`

took **2.008337** seconds on average. Generally, as computing time goes, this is a lot. However, assuming that you will be running this on an actual server and only once per application startup, this is nothing. In fact, it would even be reasonable to create some seeds. A single `k_permutations.shuffle`

took **0.154134** seconds, therefore in about a minute we can acquire *61* random permutations: `k_seeds = 61.times.map { k_permutations.shuffle }.to_a`

.

Now lets try to convert the problem of k-permutations of n elements without repetition to solving multiple times full k-permutations without repetitions.

A cool trick for generating permutations is using numbers and bitmaps. The idea is to generate all numbers from *0* to *2^61 - 1* and look at the bits. If there is a `1`

on position `i`

, we will use the `all[i]`

element, otherwise we will skip it. We still didn't escape the issue as *2^61* = 2305843009213693952 (`2**61`

) which we can't keep in memory.

Fortunatelly, another cool trick comes to the rescue, this time from number theory.

Any *m* consecutive numbers raised to the power of a prime number by modulo of *m* give the numbers from 0 to *m* - 1

In other words:

```
5.upto(65).map { |number| number**17 % 61 }.sort # => [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60]
5.upto(65).map { |number| number**17 % 61 } # => [36, 31, 51, 28, 20, 59, 11, 22, 47, 48, 42, 12, 54, 26, 5, 34, 29, 57, 24, 53, 15, 55, 3, 38, 21, 18, 43, 40, 23, 58, 6, 46, 8, 37, 4, 32, 27, 56, 35, 7, 49, 19, 13, 14, 39, 50, 2, 41, 33, 10, 30, 25, 16, 9, 17, 60, 0, 1, 44, 52, 45]
```

Now actually, how random is that? As it turns out - the more common divisors shared by *m* and the selected *m* numbers, the less evenly distributed the sequence is. But we are at luck here - *61^2 - 1* is a prime number (also called Mersenne prime). Therefore, the only divisors it can share are *1* and *61^2 - 1*. This means that no matter what power we choose, the positions of the numbers *0* and *1* will be fixed. That is not perfect, but the other *61^2 - 3* numbers can be found at any position. And guess what - we don't care about *0* and *1* anyway, because they don't have *10* `1`

s in their binary representation!

Unfortunatelly, a bottleneck for our randomness is the fact that the bigger prime number we want to generate, the harder it gets. This is the best I can come up with when it comes to generating all the numbers in a range in a shuffled order, without keeping them in memory simultaneously.

So to put everything in use:

- We generate seeds of full permutations of
*10* elements.
- We generate a random prime number.
- We randomly choose if we want to generate permutations for the next number in the sequence or a number that we already started (up to a finite number of started numbers).
- We use bitmaps of the generated numbers to get said permutations.

**Note** that this will solve only the problem of k-permutations of n elements without repetition. I still haven't thought of a way to add repetition.

**DISCLAIMER: The following code comes with no guarantees of any kind, explicit or implied. Its point is to further express the author's ideas, rather than be a production ready solution**:

```
require 'prime'
class TokenGenerator
NUMBERS_UPPER_BOUND = 2**61 - 1
HAS_NUMBER_MASK = ('1' * 9 + '0' * (61 - 9)).reverse.to_i(2)
HAS_LOWER_CASE_MASK = ('0' * 9 + '1' * 26 + '0' * 26).reverse.to_i(2)
HAS_UPPER_CASE_MASK = ('0' * (9 + 26) + '1' * 26).reverse.to_i(2)
ALL_CHARACTERS = [*'1'..'9', *'a'..'z', *'A'..'Z']
K_PERMUTATIONS = 0.upto(9).to_a.permutation.to_a # give it a couple of seconds
def initialize
random_prime = Prime.take(10_000).drop(100).sample
@all_numbers_generator = 1.upto(NUMBERS_UPPER_BOUND).lazy.map do |number|
number**random_prime % NUMBERS_UPPER_BOUND
end.select do |number|
!(number & HAS_NUMBER_MASK).zero? and
!(number & HAS_LOWER_CASE_MASK).zero? and
!(number & HAS_UPPER_CASE_MASK).zero? and
number.to_s(2).chars.count('1') == 10
end
@k_permutation_seeds = 61.times.map { K_PERMUTATIONS.shuffle }.to_a # this will take a minute
@numbers_in_iteration = {go_fish: nil}
end
def next
raise StopIteration if @numbers_in_iteration.empty?
number_generator = @numbers_in_iteration.keys.sample
if number_generator == :go_fish
add_next_number if @numbers_in_iteration.size < 1_000_000
self.next
else
next_permutation(number_generator)
end
end
private
def add_next_number
@numbers_in_iteration[@all_numbers_generator.next] = @k_permutation_seeds.sample.to_enum
rescue StopIteration # lol, you actually managed to traverse all 2^61 numbers!
@numbers_in_iteration.delete(:go_fish)
end
def next_permutation(number)
fetch_permutation(number, @numbers_in_iteration[number].next)
rescue StopIteration # all k permutations for this number were already generated
@numbers_in_iteration.delete(number)
self.next
end
def fetch_permutation(number_mask, k_permutation)
k_from_n_indices = number_mask.to_s(2).chars.reverse.map.with_index { |bit, index| index if bit == '1' }.compact
k_permutation.each_with_object([]) { |order_index, k_from_n_values| k_from_n_values << ALL_CHARACTERS[k_from_n_indices[order_index]] }
end
end
```

**EDIT**: it turned out that our constraints eliminate too much possibilities. This causes `@all_numbers_generator`

to take too much time testing and skipping numbers. I will try to think of a better generator, but everything else remains valid.

The old version that generates tokens with uniqueness constraint on the containing characters:

```
numbers = ('0'..'9').to_a
downcase_letters = ('a'..'z').to_a
upcase_letters = downcase_letters.map(&:upcase)
all = [numbers, downcase_letters, upcase_letters]
one_of_each_set = all.map(&:sample)
random_code = (one_of_each_set + (all.flatten - one_of_each_set).sample(7)).shuffle.join
```

at leasta couple of hours. You don't want to discourage other, possibly better, or just interesting, answers, and a quick selection is not appreciated by those still preparing answers. You just selected my answer. Please consider removing the checkmark for now anyway. – Cary Swoveland Aug 6 '15 at 7:10characters, i.e. the characters in the string don't appear twice. It's like drawing 10 items from an urn that contains all 62 items (a-z, A-Z, 0-9), without placing them back in the urn. This might or might not be what you actually want. There is however no guarantee that you don't draw the same 10 items again later. It's just not very likely. – Stefan Aug 6 '15 at 8:00