Further exploiting the ideas I mentioned in my question, I actually managed to come up with a solution myself. As some of you may be interested in it, I will describe it briefly. It does work in O(m log m + n), I've already implemented it in C++ and tested - solves the biggest cases (10^6 integers) in less than 5 seconds.
We have n integers, all not greater than m. We start by doing Eratosthenes Sieve mapping each integer up to m to it's smalles prime factor, allowing us to factor out any number not greater than m in O(log m) time. Then for all given numbers A[i], as long as there is some prime p than divides A[i] in a power greater than one, we divide A[i] by it, because when asking if two numbers are coprime we can omit the exponents. That leaves us with all A[i] being products of distinct primes.
Now, let us assume that we were able to construct in a reasonable time a table T, such that T[i] is number of entries A[j] such that i divides A[j]. This is somehow similar to the approach @Brainless took in his second answer. Constructing table T quickly was the technic I spoke about in the comments below my question.
From now, we will work by Inclusion-Exclusion Principle. Having T, for each i we calculate P[i] - the amount of pairs (j,k) such that A[j] and A[k] are both divisible by i. Then to compute the answer, sum all P[i], taking minus sign before those P[i] for which i has an even number of prime divisors. Note that all prime divisors of i are distinct, because for all other indices i P[i] equals 0. By Inclusion-Exclusion each pair will be counted only once. To see this differently, take a pair A[i] and A[j], assuming that they share exactly k common prime divisors. Then this pair will be counted k times, then discounted kC2 times, counted kC3 times, discounted kC4 times... for nCk see the Newton's Symbol. Some mathematical manipulation makes us see that the considered pair will be counted 1 - (1-1)^k = 1 times, what concludes the proof.
Steps made so far required O(m log log m) for the Sieve and O(m) for computing the result. The last thing to do is to construct array T. We could for every A[i] just increment T[j] for all j dividing i. As A[i] can have at most O(sqrt(A[i])) divisors (and in practice even less than that) then we could construct T in O(n sqrt m). But we can do better than that!
Take two-dimensional array W. At each moment a following invariant holds - if for each non-zero W[i][j] we would increment the counter in table T by W[i][j] for all numbers that divide i, and also share the exact exponents i has in j smallest primes divisors of i, then T would be constructed properly. As this may seem a little confusing, let's see it in action. At start, to make the invariant true, for each A[i] we just increment W[A[i]]. Also note that a number not exceeding m can have at most O(log m) prime divisors, so the overall size of W is O(m log m). Now we see that an information stored in W[i][j] can be "pushed forward" in a following way: consider p to be (j+1)-th prime divisor of i, assuming it has one. Then some divisor of i can either have p with an exponent same as in i, or lower. First of these cases is W[i][j+1] - we add another prime that has to be "fully taken" by a divisor. Second case is W[i/p][j] as a divisor of i that doesn't have p with a highest exponent must also divide i/p. And that's it! We consider all i in descending order, then j in ascending order. We "push forward" information from W[i][j]. See that if i has exactly j prime divisors, then the information from it cannot be pushed, but we don't really need that! If i has j prime divisors, then W[i][j] basically says: increment by W[i][j] only index i in array T. So when all the information has been pushed to "last rows" in each W[i] we pass through those rows and finish constructing T. As each cell of W[i][j] has been visited once, this algorithm takes O(m log m) time, and also O(n) at the begining. That concludes the construction. Here's some C++ code from the actual implementation:
FORD(i,SIZE(W)-1,2) //i in descending order
int v = i, p;
FOR(j,0,SIZE(W[i])-2) //exclude last row
p = S[v]; //j-th divisor; S[v] - smallest prime divisor of v
while (v%p == 0) v /= p;
W[i][j+1] += W[i][j];
W[i/p][j] += W[i][j];
T[i] = W[i].back();
At the end I'd say that I think array T can be constructed faster and simpler than what I've shown. If anyone has some neat idea about how it could be done, I would appreciate all feedback.