You did not mention anything about a character can be used only once - so without this restriction is problem of "Can we generate k (or more) different words?" is **undecideable**.^{1}.

(With a constraint on the number of "visites" per element there are finite number of possibilities and the claim and proof does not hold of course).

**Proof:**

It is known that there is no algorithm `A`

that can decide if a terminating algorithm `B`

returns `true`

for `k`

or more different inputs. (will look for citation for this claim later if needed, trust me for now).

We will show that given an algorithm `A`

that says if there are `k`

or more generated words - we can decide if there are `k`

or more different inputs that yield "true":

Let the (terminating) algorithm that decides if there are `k`

or
more generated words be `M`

.

Without loss of generality - assume binary alphabet (we can represent everything with it).

Let:

```
array = 0 1
0 1
```

Note we can generate any binary word while walking on this array.

**Algorithm A:**

**input:** algorithm B, natural number n

output: true if and only if algorithm B answers "true" for n or more different inputs.

**The algorithm**:

(1) use `B(word)`

as the black box dictionary - if the answer is true, then `word`

is in dictionary.

(2) use `array`

as the array.

(3) Run M on (array,dictionary,n), and answer like it.

Note that if M answered true -> there are `n`

or more accepted words -> there are `n`

or more different inputs to B that yields true (definition of dictionary and since we can generate every input with array) -> the answer to the problem is true.

(if the algorithm answered false the proof is similar).

**QED**

**Conclusion:**

If we can repeat a character in the array more then a once (or to be exact - unbounded number of times) - then **the problem is unsolveable without any information on the dictionary.**

(1) An undecideble problem is a problem where there is no algorithm that can answer TRUE/FALSE correctly in 100% of the cases - For every algorithm, there is some case where the algorithm will get "stuck" in an infinite loop (or give a wrong answer). The most common of "undecideable" problems is the Halting Problem - which says - there is no algorithm `A`

that can take any algorithm `B`

and answer if `B`

stops for some input `w`

.

`dict.contains(word)`

, what else are you allowed to do with the dictionary? Can you for example pre-process it to build some data structure? – NPE Dec 3 '12 at 9:38`(ea)+`

and the array`[e,a]`

your answer is ea,eaea,eaeaea,... (for infinity), so basically the problem without any information in the dictionary is equivalent to the Halting Problem. – amit Dec 3 '12 at 10:24