# How to find sum of all the GCDs of all the subarrays of an array?

Given an array A of length n = 10^5. I have to find the sum of GCD of all subarrays of this array efficiently.

``````import math
def lgcd(a):
g = a
for i in range(1,len(a)):
g = math.gcd(g,a[i])
return g

n = int(input())
A = list(map(int,input().split()))
ans = 0
for i in range(n):
for j in range(i,n):
ans+=lgcd(A[i:j+1])

print(ans)
``````
• Sorry for storing the GCDs, I need to calculate the sum of GCDs only. – Mohan Singh Aug 29 at 12:17
• What is the maximum value for an element in the array? – user3386109 Aug 29 at 16:11
• @user3386109 1<=A[i]<=10^8 – Mohan Singh Aug 29 at 23:34
• @MohanSinghcan you give me the link of the problem you are trying to solve? Will like to solve it myself. – Abhishek Keshri Sep 8 at 19:16

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

• Can you please explain your algorithm by an example? Suppose for A = [120 ,15 ,36, 20], ans = 218. – Mohan Singh Aug 29 at 23:41
• For 120 there is only one block - 120. So Total sum is now 0 + 120 * 1 = 120. For 15 there is only one block of length two - 15. So the total sum is now 120 + 15 * 2 = 150. For 36 there are two blocks - 36 (length 1) and 3 (length 2). So the total sum is now 192 = 150 + 36 * 1 + 3 * 2 = 192. For 20 there are three blocks - 20 (length 1), 4 (length 1) and 1 (length 2). So the total sum is now 102 + 20 * 1 + 4 * 1 + 1 * 2 = 218. – Roman Svistunov Aug 30 at 7:01
• You should edit the example into the answer. – user3386109 Aug 30 at 18:40
• @RomanSvistunov can I use this algorithm to get the count of all gcd(s) of all sub-arrays? – Abhishek Keshri Sep 8 at 18:56
• @AbhishekKeshri that will work but still you will get time out for the problem that you are trying to solve. – Rakesh Sep 11 at 18:35

The efficient method is observing the problem statement closely. Example we have array as [1,2,3,45]. Now when we find GCD of [1,2] and we need to find GCD of [1,2,3] we can simply do it with GCD(GCD([1,2]),3). So here are overlapping subproblems. So just store the result.

A subarray of length k is constructed from subarray of length k-1 + 1 element. So GCD of subarray including k'th element is GCD of k'th element and GCD of subarray of k-1 elements i.e. GCD(GCD(A[i:i+k],A[k]).

``````final = dict()

def gcd(a, b):
if b == 0:
return a
return gcd(b, a % b)

A = [int(i) for i in input().split()]
dp = [[-1 for _ in range(len(A))] for _ in range(len(A))]

# Set GCD of single element as the elemnt itself
for i in range(len(A)):
dp[i][i] = A[i]

# For every other subarrays of length l
# Calculate gcd using  length l - 1
for i in range(0, len(A)):
for j in range(i + 1, len(A)):

dp[i][j] = gcd(dp[i][j - 1], A[j])
final[tuple(A[i: j + 1])] = dp[i][j]

print(final)
``````
• It's still O(n^2). I need to do it better than this. – Mohan Singh Aug 29 at 12:14
• I think this will be the best case as we need the answer for each subarray. – learner-coder Aug 29 at 16:32
• I think we need a solution of complexity O(n logn). That's usually the case when n~10^5. – A. Mashreghi Aug 29 at 18:02
• @Kamesh-Bakshi I want to extend it for multiple queries for all subarrays of a given range, that's why a O(log n) solution is needed for a single query. – Mohan Singh Aug 30 at 0:05
• In that case, you will need to look into segment tree. It will give the answer to all queries in O(log n). But you will need to store the GCD of all subarray. – learner-coder Aug 30 at 2:27