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I'm looking for a library that performs matrix operations on large sparse matrices w/o sacrificing numerical stability. Matrices will be 1000+ by 1000+ and values of the matrix will be between 0 and 1000. I will be performing the index calculus algorithm (en.wikipedia.org/wiki/Index_calculus_algorithm) so I will be generating (sparse) row vectors of the matrix serially. As I develop each row, I will need to test for linear independence. Once I fill my matrix with the desired number of linearly independent vectors, I will then need to transform the matrix into reduced row echelon form.

The problem now is that my implementation uses Gaussian elimination to determine linear independence (ensuring row echelon form once all my row vectors have been found). However, given the density and size of the matrix, this means the entries in each new row become exponentially larger over time, as the lcm of the leading entries must be found in order to perform cancellation. Finding the reduced form of the matrix further exacerbates the problem.

So my question is, is there an algorithm, or better yet an implementation, that can test linear independence and solve the reduced row echelon form while keeping the entries as small as possible? An efficient test for linear independence is especially important since in the index calculus algorithm it is performed by far the most.

Thanks in advance!

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What language are you working with? –  laser_wizard Oct 21 '12 at 10:11
    
I presume you put cryptography in there because tests on linear independence may be related to crypto-analysis? –  Maarten Bodewes Oct 21 '12 at 16:59
    
@owlstead: No, this question is not related to the cryptology. –  Pavel Ognev Oct 22 '12 at 16:59
    
You will not find algorithms better than O3(n), so you have to do about 10^9 mathematical operations. You need a supercomputer for this task. –  Pavel Ognev Oct 22 '12 at 17:02
    
Or you can optimize a memory usage somehow for ubiquitous usage of processor's cache. –  Pavel Ognev Oct 22 '12 at 17:07

1 Answer 1

Usually if you are working with large matrices, people use LAPACK: this library contains all the basic matrix routines and support many different matrix types (sparse, ...). You can use this library to implement your algorithm, I think it will help you

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