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We are given an N dimensional matrix of order [m][m][m]....n times where value position contains the value sum of its index.. For example in 6x6 matrix A, value at position A[3][4] will be 7.

We have to find out the total number of counts of elements greater than x. For 2 dimensional matrix we have following approach:

If we know the one index say [i][j] {i+j = x} then we create a diagonal by just doing [i++][j--] of [i--][j++] with constraint that i and j are always in range of 0 to m. For example in two dimensional matrix A[6][6] for value A[3][4] (x = 7), diagonal can be created via:

A[1][6] -> A[2][5] -> A[3][4] -> A[4][3] -> A[5][2] -> A[6][2]

Here we have converted our problem into another problem which is count the element below the diagonal including the diagonal. We can easily count in O(m) complexity instead spending O(m^2) where 2 is order of matrix. But if we consider N dimensional matrix, how we will do it, because in N dimensional matrix if we know the index of that location, where sum of index is x say A[i1][i2][i3][i4]....[in] times. Then there may be multiple diagonal which satisfy that condition, say by doing i1-- we can increment any of {i2, i3, i4....in}

So, above used approach for 2 dimensional matrix become useless here... because there is only two variable quantity i1 and i2 is present. Please help me to find solution

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I may not be understanding correctly, but it seems like you are asking this: given x, n (number of dimensions) and N, find in how many ways you can sum up n integers between 0 and N to get some value greater than x. –  Artyom Sep 24 '12 at 12:30
@Artyom: correct.. same it. –  Rahul Kumar Patle Sep 24 '12 at 16:10

2 Answers 2

For 2D: count of the elements below diagonal is triangular number.

For 3D: count of the elements below diagonal plane is tetrahedral number

Note that Kth tetrahedral number is the sum of the first K triangular numbers.

For nD: n-simplexial (I don't know exact english term) number (is sum of first (n-1)-simplexial numbers).

The value of Kth n-simplexial is

 S(k, n) = k * (k+1) * (k+2).. (k + n - 1) / n! = BinomialCoefficient(k+n-1, n)

Edit: this method works "as is" for limited values of X below main anti-diagonal (hyper)plane.

Generating function approach: Let's we have polynom


then it's nth power
B(s) = An(s) has important property: coefficient of kth power of s is the number of ways to compose k from n summands. So the sum of nth to kth coefficients gives us the count of the elements below kth diagonal

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For a 2-dimensional matrix, you converted the problem into another problem, which is count the elements below the diagonal including the diagonal.

Try and visualize it for a 3-d matrix. In case of a 3-dimensional matrix, the problem will be reduced to another problem, which is to count the elements below the diagonal plane including the diagonal

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