There is a solution that would take O(n):

Let our numbers be `a_i`

. First, calculate `m=a_0*a_1*a_2*...`

. For each number a_i, calculate `gcd(m/a_i, a_i)`

. The number you are looking for is the maximum of these values.

I haven't proved that this is always true, but in your example, it works:

`m=2*4*5*15=600,`

`max(gcd(m/2,2), gcd(m/4,4), gcd(m/5,5), gcd(m/15,15))=max(2, 2, 5, 5)=5`

NOTE: This is not correct. If the number `a_i`

has a factor `p_j`

repeated twice, and if two other numbers also contain this factor, `p_j`

, then you get the incorrect result `p_j^2`

insted of `p_j`

. For example, for the set `3, 5, 15, 25`

, you get `25`

as the answer instead of `5`

.

However, you can still use this to quickly filter out numbers. For example, in the above case, once you determine the 25, you can first do the exhaustive search for `a_3=25`

with `gcd(a_3, a_i)`

to find the real maximum, `5`

, then filter out `gcd(m/a_i, a_i), i!=3`

which are less than or equal to `5`

(in the example above, this filters out all others).

*Added for clarification and justification*:

To see why this should work, note that `gcd(a_i, a_j)`

divides `gcd(m/a_i, a_i)`

for all `j!=i`

.

Let's call `gcd(m/a_i, a_i)`

as `g_i`

, and `max(gcd(a_i, a_j),j=1..n, j!=i)`

as `r_i`

. What I say above is `g_i=x_i*r_i`

, and `x_i`

is an integer. It is obvious that `r_i <= g_i`

, so in `n`

gcd operations, we get an upper bound for `r_i`

for all `i`

.

The above claim is not very obvious. Let's examine it a bit deeper to see why it is true: the gcd of `a_i`

and `a_j`

is the product of all prime factors that appear in both `a_i`

and `a_j`

(by definition). Now, multiply `a_j`

with another number, `b`

. The gcd of `a_i`

and `b*a_j`

is either equal to `gcd(a_i, a_j)`

, or is a multiple of it, because `b*a_j`

contains all prime factors of `a_j`

, and some more prime factors contributed by `b`

, which may also be included in the factorization of `a_i`

. In fact, `gcd(a_i, b*a_j)=gcd(a_i/gcd(a_i, a_j), b)*gcd(a_i, a_j)`

, I think. But I can't see a way to make use of this. :)

Anyhow, in our construction, `m/a_i`

is simply a shortcut to calculate the product of all `a_j`

, where `j=1..1, j!=i`

. As a result, `gcd(m/a_i, a_i)`

contains all `gcd(a_i, a_j)`

as a factor. So, obviously, the maximum of these individual gcd results will divide `g_i`

.

Now, the largest `g_i`

is of particular interest to us: it is either the maximum gcd itself (if `x_i`

is 1), or a good candidate for being one. To do that, we do another `n-1`

gcd operations, and calculate `r_i`

explicitly. Then, we drop all `g_j`

less than or equal to `r_i`

as candidates. If we don't have any other candidate left, we are done. If not, we pick up the next largest `g_k`

, and calculate `r_k`

. If `r_k <= r_i`

, we drop `g_k`

, and repeat with another `g_k'`

. If `r_k > r_i`

, we filter out remaining `g_j <= r_k`

, and repeat.

I think it is possible to construct a number set that will make this algorithm run in O(n^2) (if we fail to filter out anything), but on random number sets, I think it will quickly get rid of large chunks of candidates.