If we have two arrays say A=[1,2,3,4]
and B=[1,2,3]
we need to find the sum 1*1+1*2+1*3+2*1+2*2+2*3+3*1+3*2+3*3+4*1+4*2+4*3
,i.e sum of product of all possible pairs in both arrays which may be of different lenghts.
Of course we can do it in O(n^2)
but is there any efficient way to do it ?
Thanks.
Also both the arrays have integers in the range 1..m
and 1..n
respectively

3you meant O(n*m) probably – giorgim Jan 4 '18 at 11:37
This can be done in O(n+m)
time by levying the distributive property of multiplication over addition.
The required sum can be generalized as follows:
(A[0]*B[0] + A[1]*B[0] + ... + A[m1]*B[0]) + (A[0]*B[1] + A[1]*B[1] + ... + A[m1]*B[1]) + ... + (A[0]*B[n1] + A[1]*B[n1] + ... + A[m1]*B[n1])
Note that in each partial sum, we can factor out the element of B
. The series then simplifies to
(A[0] + A[1] + ... + A[m1]) * B[0] + (A[0] + A[1] + ... + A[m1]) * B[1] + ... + (A[0] + A[1] + ... + A[m1]) * B[n1]
Note that the sum of all the elements in A
is a factor of each term in the above series, which can be factored out to give
(A[0] + A[1] + ... + A[m1]) * (B[0] + B[1] + ... + B[n1])
We can thus compute the sum of elements of both the arrays and multiply them together to obtain the sum of the series.
1*1+1*2+1*3+2*1+2*2+2*3+3*1+3*2+3*3+4*1+4*2+4*3
=60
(1+2+3) * (1+2+3+4)
=60
Why?
sum(B) + 2*sum(B) + 3*sum(B) + 4*sum(B)
sum(B) * sum(A)
We can observe following fact:
A = [1,2,3,4];
B = [1,2,3];
A * B =
A[0] * B[0] + A[0] * B[1] + A[0] * B[2]+ .. +
A[3] * B[0] + A[3] * B[1] + A[3] * B[2] =
A[0] * (B[0]+B[1]+B[2]) + .. +
A[3] * (B[0]+B[1]+B[2]) = (A[0] + A[1] + A[2] + A[3]) * (B[0] + B[1] + B[2])
As others said, you can rewrite your formula as a product of the sums of your vectors.
I am not sure if your arrays hold arbitrary values in range 1...n or the exact range.
If they hold all elements in range 1...n you can rewrite the sum of 1...n
as n*(n+1) / 2