Let A be a given square matrix whose size is nxn. Let A[i] denote the nxn matrix formed by replacing the i-th column of A with the zero column vector.

Now I want to calculate the following (n^4+n^3+n^2) matrix products:

{A[x]*A[y]*A[z]*A[w] | for all x=1,...n , y=1,...,n , z=1,...n, and w=1,...,n}

{A[y]*A[z]*A[w] | for all y=1,...,n , z=1,...n, and w=1,...,n}

{A[z]*A[w] | for all z=1,...n, and w=1,...,n}

If I calculate each product naively, it would take O((n^4+n^3+n^2)*n^3) time complexity (assuming that a matrix multiplication requires O(n^3) time).

However, I noticed that there are many duplicate multiplications that can be memoized. Is there an efficient way (like DP) that can reduce the number of matrix multiplications as fewer as possible ?


The first - obvious - optimization is to use results from the 3rd set to calculate the first one.

The second one which comes in mind is slightly more tricky.

Let B[i] denote the nxn 0-matrix with i-th column replaced by i-th column of A (i.o.w. B[i] = A - A[i]).

Then rewrite the matrix product using matrix distribution law[1], like this. A[x]*A[y] = (A - B[x])(A - B[y]) = (A - B[x])A - (A - B[x])B[y] = AA - B[x]A - AB[y] - B[x]B[y].

Since B[i] are sparse matrices with only a single non-zero column, the products above are very easy to calculate, plus the one "full" matrix multiplication - AA - need to be calculated only once.

The 3-multiplications case would look like following. A[x]*A[y]*A[z] = AAA - B[x]AA - AB[y]A + B[x]B[y]A - AAB[z] + B[x]AB[z] + AB[y]B[z] + B[x]B[y]B[z].

After previous step we already have most of the factors (every B[i]A and AB[i]), if memory is of no concern; or we can easily calculate it (since, once again, the B[i] are sparse).

The 4-multiplcations case can then be done analogues.

[1] https://en.wikipedia.org/wiki/Matrix_multiplication#Properties_of_the_matrix_product_.28two_matrices.29


Multiply A[z] and A[w], skipping over the '0' column in w in each iteration, and then simply filling that column with zeros in the answer (or if you calloc'd the memory, then its already 0 by default). This is your problem #3

Now, take this matrix, which has a column that is zero (wth column), and multiply A[y] by it, again taking advantage of the fact that the same column is zero and you can skip multiplies. You now have #2.

Repeat this once more multiplying A[x] by this result, taking advantage of the same 0 column.

This means overall, you have 3 * (n-1)*n * (2n) = 6 * n^3 - 6 * n^2 multiplications total (if my math is correct).

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