Everyone here did a great job of explaining how the code works and showing how you can construct your own examples, but here's an information theoretical answer showing why we can reasonably expect a solution to exist that the brute force search will eventually find.

The 26 different lower-case letters form our alphabet `Σ`

. To allow generating words of different lengths, we further add a terminator symbol `⊥`

to yield an extended alphabet `Σ' := Σ ∪ {⊥}`

.

Let `α`

be a symbol and X a uniformly distributed random variable over `Σ'`

. The probability of obtaining that symbol, `P(X = α)`

, and its information content, `I(α)`

, are given by:

P(X = α) = 1/|Σ'| = 1/27

I(α) = -log₂[P(X = α)] = -log₂(1/27) = log₂(27)

For a word `ω ∈ Σ*`

and its `⊥-`

terminated counterpart `ω' := ω · ⊥ ∈ (Σ')*`

, we have

I(ω) := I(ω') = |ω'| * log₂(27) = (|ω| + 1) * log₂(27)

Since the Pseudorandom Number Generator (PRNG) is initialized with a 32-bit seed, we can expect most words of length up to

λ = floor[32/log₂(27)] - 1 = 5

to be generated by at least one seed. Even if we were to search for a 6-character word, we would still be successful about 41.06% of the time. Not too shabby.

For 7 letters we're looking at closer to 1.52%, but I hadn't realized that before giving it a try:

```
#include <iostream>
#include <random>
int main()
{
std::mt19937 rng(631647094);
std::uniform_int_distribution<char> dist('a', 'z' + 1);
char alpha;
while ((alpha = dist(rng)) != 'z' + 1)
{
std::cout << alpha;
}
}
```

See the output: http://ideone.com/JRGb3l

`n`

in`for (int n = 0; ; n++)`

. They could use`for(;;)`

or`while(true)`

instead!`fixedAndNotSoRandomString`

or something...