Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them, it only takes a minute:

I'm trying to come up with fast algorithm to find result of AtLA operation, where

  • L - is symmetric n x n matrix with real numbers.
  • A - is sparse n x m matrix, m < n. Each row has one and only one non-zero element, and it's equal to 1. It's also guaranteed that every column has at most two non-zero elements.

I come up with one algorithm, but I feel like there should be something faster than this.

Let's represent every column of A as pair of row numbers with non-zero elements. If a column has only one non-zero element, its row number listed twice. E.g. for the following matrix

Sparse matrix example

Such representation would be

column 0: [0, 2]; column 1: [1, 3]; column 2: [4, 4]

Or we can list it as a single array: A = [0, 2, 1, 3, 4, 4]; Now, L' = LA can be calculated as:

for (i = 0; i < A.length; i += 2):
  if A[i] != A[i + 1]:
     # sum of two column vectors, i/2-th column of L'
     L'[i/2] = L[A[i]] + L[A[i + 1]] 
     L'[i/2] = L[A[i]]

To calculate L''=AtL' we do it one more time:

for (i = 0; i < A.length; i += 2):
  if A[i] != A[i + 1]:
    # sum of two row vectors, i/2-th row of L''
    L''[i/2] = L'[A[i]] + L'[A[i + 1]]
    L''[i/2] = L'[A[i]]

The time complexity of such approach is O(m*n + m*n), and space complexity (to get final AtLA result) is O(n*n). I'm wondering if it's possible to improve it to O(m*m) in terms of space and/or performance?

share|improve this question

3 Answers 3

up vote 0 down vote accepted

The second loop combines at most 2m rows of L', so if m is much smaller than n there will be several rows of L' that are never used.

One way to avoid calculating and storing these unused entries is to change your first loop into a function and only calculate the individual elements of L' as they are needed.

def L'(row,col):
  if A[i] != A[i + 1]:
    # sum of two column vectors, i/2-th column of L'
    return L[row][A[i]] + L[row][A[i + 1]] 
    return L[row][A[i]]

for (i = 0; i < A.length; i += 2):
  if A[i] != A[i + 1]:
    for (k=0;k<m;k++):
      L''[i/2][k] = L'(A[i],k) + L'(A[i + 1],k)
    for (k=0;k<m;k++):
      L''[i/2][k] = L'(A[i],k)

This should then have space and complexity O(m*m)

share|improve this answer

The operation Transpose(A) * L works as follows:

For each column of A we see:

column 1 has `1` in row 1 and 3
column 2 has `1` in row 2 and 4
column 3 has `1` in row 5

The output matrix B = Transpose(A) * L has three rows which are equal to:

Row(B, 1) = Row(A, 1) + Row(A, 3)
Row(B, 2) = Row(A, 2) + Row(A, 4)
Row(B, 3) = Row(A, 5)

If we multiply C = B * A:

Column(C, 1) = Column(B, 1) + Column(B, 3)
Column(C, 2) = Column(B, 2) + Column(B, 4)
Column(C, 3) = Column(B, 5)

If you follow through this in a algorithmic way, you should achieve something very similar to what Peter de Rivaz has suggested.

share|improve this answer

The time complexity of your algorithm is O(n^2), not O(m*n). The rows and columns of L have length n, and the A array has length 2n.

If a[k] is the column where row k of A has a 1, then you can write:

A[k,i] = δ(a[k],i)

and the product, P = A^T*L*A is:

P[i,j] = Σ(k,l) A^T[i,k]*L[k,l]*A[l,j]
       = Σ(k,l) A[k,i]*L[k,l]*A[l,j]
       = Σ(k,l) δ(a[k],i)*L[k,l]*δ(a[l],j)

If we turn this around and look at what happens to the elements of L, we see that L[k,l] is added to P[a[k],a[l]], and it's easy to get O(m^2) space complexity using O(n^2) time complexity.

Because a[k] is defined for all k=0..n-1, we know that every element of L must appear somewhere in the product. Because there are O(n^2) distinct elements in L, you can't do better than O(n^2) time complexity.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.