First, note that this regex applies to numbers represented in a unary counting system, i.e.

```
1 is 1
11 is 2
111 is 3
1111 is 4
11111 is 5
111111 is 6
1111111 is 7
```

and so on. Really, any character can be used (hence the `.`

s in the expression), but I'll use "1".

Second, note that this regex matches *composite* (non-prime) numbers; thus negation detects primality.

**Explanation:**

The first half of the expression,

```
.?
```

says that the strings "" (0) and "1" (1) are matches, *i.e. not prime* (by definition, though arguable.)

The second half, in simple English, says:

Match the shortest string whose length is at least 2, for example, "11" (2). Now, see if we can match the entire string by repeating it. Does "1111" (4) match? Does "111111" (6) match? Does "11111111" (8) match? And so on. If not, then try it again for the next shortest string, "111" (3). Etc.

You can now see how, if the original string can't be matched as a *multiple* of its substrings, then by definition, it's prime!

BTW, the non-greedy operator `?`

is what makes the "algorithm" start from the shortest and count up.

**Efficiency:**

It's interesting, but certainly not efficient, by various arguments, some of which I'll consolidate below:

As @TeddHopp notes, the well-known sieve-of-Eratosthenes approach would not bother to check multiples of integers such as 4, 6, and 9, having been "visited" already while checking multiples of 2 and 3. Alas, this regex approach exhaustively checks every smaller integer.

As @PetarMinchev notes, we can "short-circuit" the multiples-checking scheme once we reach the square root of the number. We should be able to because a factor *greater* than the square root must partner with a factor *lesser* than the square root (since otherwise two factors greater than the square root would produce a product greater than the number), and if this greater factor exists, then we should have already encountered (and thus, matched) the lesser factor.

As @Jesper and @Brian note with concision, from a non-algorithmic perspective, consider how a regular expression would begin by *allocating memory to store the string*, *e.g.* `char[9000]`

for 9000. Well, that was easy, wasn't it? ;)

As @Foon notes, there exist probabilistic methods which may be more efficient for larger numbers, though they may not always be correct (turning up pseudoprimes instead). But also there are deterministic tests that are 100% accurate and far more efficient than sieve-based methods. Wolfram's has a nice summary.

notimplement the sieve of Eratosthenes. It exhaustively checks every divisor. (E.g., if it fails for 2, it will still try 4.) – Ted Hopp Oct 3 '12 at 19:55