The first thing that should be marked is that GCD(A[i-1 : j]) * d = GCD(A[i : j]) where d is natural number. So for the fixed subarray end, there will be some blocks with equal GCD, and there will be no more than *log n* blocks, since GCD in one block is the divisor of GCD of another block, and, therefore, is at least two times smaller.

So the next algorithm can be used: for all elements in array lets assume that they are last elements of the subarray, and then will find all blocks of equal GCDs and add to our total sum *block size \* block gcd*.

To fastly find blocks with equal GCD you can use a segment tree. To find a block you just need to find the longest subarray ending in fixed element, where gcd is smaller, then on your previously checked block.

This algorithm is O(*n \* log n \* log k*) where k is a maximal number in the array.

### Example:

For A = [120 ,15 ,36, 20]

For 120 there is only one block - 120 (GCD(120) = 120). So Total sum is now 0 + 120 * 1 = 120

For 15 there is only one block of length two - 15 (GCD(15) = 15, GCD(120, 15) = 15). So the total sum is now 120 + 15 * 2 = 150.

For 36 there are two blocks - 36 (GCD(36) = 36) and 3 (GCD(15, 36) = GCD(120, 15, 36) = 3). So the total sum is now 192 = 150 + 36 * 1 + 3 * 2 = 192.

For 20 there are three blocks - 20 (GCD(20) = 20), 4 (GCD(36, 20) = 4) and 1 (GCD(15, 36, 20) = GCD(120, 15, 36, 20) = 1). So the total sum is now 102 + 20 * 1 + 4 * 1 + 1 * 2 = 218, and it is the answer