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I need to compute the nullspace of several thousand small matrices (8x9, not 4x3 as I wrote previously) in parallel (CUDA). All references point to SVD but the algorithm in numerical recipes seems very expensive, and gives me lots of things other than the null space that I don't really need. Is Gaussian elimination really not an option? Are there any other commonly used methods?

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Why did you edit out my 'Hi', and 'Thanks'? Is common courtesy not allowed any more? – zenna Feb 2 '10 at 2:26
You need to align the tachyon transponders and invert the phase polarity. Or, transpose the conjugate of the vector quadrature in Levenstein space. – BobMcGee Feb 2 '10 at 2:29
Can you post one of the 8x9 matricies? – duffymo Feb 2 '10 at 23:40
up vote 6 down vote accepted

To answer your question directly... yes! QR decomposition!

Let A be an m-by-n matrix with rank n. QR decomposition finds orthonormal m-by-m matrix Q and upper triangular m-by-n matrix R such that A = QR. If we define Q = [Q1 Q2], where Q1 is m-by-n and Q2 is m-by-(m-n), then the columns of Q2 form the null space of A^T.

QR decomposition is computed either by Gram-Schmidt, Givens rotations, or Householder reflections. They have different stability properties and operation counts.

You are right: SVD is expensive! I can't speak for what state-of-the-art stuff uses, but when I hear "compute null space" (EDIT: in a way that is simple for me to understand), I think QR.

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Thanks, Coincidentally after a lot of reading (much of which was through old school parallel implementations on vector machines in the 1980s) I had decided to attempt using the QR decomposition with givens rotations, will update this if it works out well. – zenna Feb 10 '10 at 11:57
Great! Glad to hear. Although you are using CUDA, I have Matlab code if you need any assistance. – Steve Tjoa Feb 10 '10 at 14:18
I implemented a QR decomposition using givens rotations, I parallelised at 3 levels 1. The matrix multiplication between a row pair of matrix A and the 2 x 2 Givens matrix: using 16 threads for each element of the multiplication product 2. I do 4 row pairs in parallel, 2 for Q and 2 for A, and 3. I do the 25000 matrices in parallel. Overall I halved the run time from 20 ms to 9.5ms when compared to the SVD. So success! – zenna Feb 17 '10 at 23:45
Wow, that's awesome! Yes, these rotations should definitely be parallelizable. Now I want to try this myself. :-) – Steve Tjoa Feb 17 '10 at 23:47
Yeah! get in touch if you need any assistance, was quite a complex job, might right a block post on it or something – zenna Feb 17 '10 at 23:52

Gaussian elimination is plenty fast for 4x3 matrices. IIRC I've done about 5 million per second with Java without parallelism. With such a small problem, your best bet is to code the routine (row reduce etc.) yourself; otherwise you'll waste most of the time putting the data into the right format for the external routine.

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By 'not an option' I was referring to errors due to rounding being a problem or not. Or does it depend heavily on the application? – zenna Feb 2 '10 at 2:37
It depends heavily on the application. If it is okay to treat nearly null and actually null both as null, you set some epsilon that is considered "close enough to zero" and use Gaussian elimination. If it matters very much to you when things are close to singular but not quite, your numerical accuracy will be a lot better with SVD (typically). The larger your matrix, the worse it gets (typically), so now that you say 8x9, I'd more seriously consider SVD. Why not try out both methods with non-CUDA code and see if SVD is required? – Rex Kerr Feb 2 '10 at 12:54

I think the most important thing for CUDA is to find an algorithm that doesn't depend on conditional branching (which is quite slow on graphics hardware). Simple if statements that can be optimized into conditional assignment are much better (or you can use the ?: operator).

If necessary, you should be able to do some form of pivoting using conditional assignment. It might actually be harder to determine how to store your result: if your matrix is rank-deficient, what do you want your CUDA program to do about it?

If you assume your 4x3 matrix is not actually rank-deficient, you can find your (single) null-space vector without any conditionals at all: the matrix is small enough that you can use Cramer's rule efficiently.

Actually, since you don't actually care about the scale of your null vector, you don't have to divide by the determinant -- you can just take the determinants of the minors:

    x1 x2 x3
M = y1 y2 y3
    z1 z2 z3
    w1 w2 w3

         |y1 y2 y3|        |x1 x2 x3|       |x1 x2 x3|        |x1 x2 x3|
->  x0 = |z1 z2 z3|  y0 = -|z1 z2 z3|  z0 = |y1 y2 y3|  w0 = -|y1 y2 y3|
         |w1 w2 w3|        |w1 w2 w3|       |w1 w2 w3|        |z1 z2 z3|

Note that these 3x3 determinants are just triple products; you can save computation by reusing the cross products.

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"seems very expensive" - what data do you have that supports this?

Maybe Block Lanczos is the answer you seek.

Or maybe this.

Both JAMA and Apache Commons Math have SVD implementations in Java. Why not take those and try them out? Get some real data for your case instead of impressions. It won't cost you much, since the code is already written and tested.

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Seems expensive in that the complexity is much higher than a row reduction method for example. I am not an expert but I can calculate the null space using Gaussian elimination by hand and as far as I am aware its unsuitability is down solely to rounding errors. – zenna Feb 2 '10 at 2:14
"seems" is the operative word here. This article suggests that it's O(m^3): – duffymo Feb 2 '10 at 2:28
I give this post a -1 for incorrect information. Gaussian Elimination can be used for solving Ax = 0. Isn't that just the null space? – Aryabhatta Feb 2 '10 at 5:12
Fair enough, you're correct. – duffymo Feb 2 '10 at 10:58

I wondered if the matrixes are related rather than just being random, so that the null spaces you are seeking can be considered to be like 1-dimensional tangents to a curve in N-space (N = 9). If so, you may be able to speed things up by using Newton's method to solve successive instances of the system of quadratic equations Ax = 0, |x|^2 = 1, starting from a previous null space vector. Newton's method uses first derivatives to converge to a solution, and so would use Gaussian elimination to solve 9x9 systems. Using this technique would require that you be able to make small steps from matrix to matrix by say varying a parameter.

So the idea is that you initialize using SVD on the first matrix, but thereafter you step from matrix to matrix, using the null space vector of one as the starting point for the iteration for the next one. You need one or two iterations to get convergence. If you don't get convegence you use SVD to restart. If this situation is what you have, it is much faster than starting fresh on each matrix.

I used this a long time ago to map contours in the solutions of sets of 50 x 50 quadratic equations associated with the behavior of electric power systems.

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Interesting, in this case the matrices are not related but this method will surely be useful elsewhere, and after reading your response I have seen a lot more literature on this kind of updating method. – zenna Feb 10 '10 at 11:57
Oh yes, I used QR transformations, not SVD. There are lots of efficiencies to be had there. It's not so easy to remember details after more than 25 years though. – Permaquid Feb 15 '10 at 3:09

I don't think the above proposed method always gives the whole null space. To recap: "A = QR, where Q = [Q1 Q2], and Q1 is m-by-n and Q2 is m-by-(m-n). Then the columns of Q2 form the null space of A^T."

Indeed, this may only give a subspace of the null space. Simple counter-example is when A=0, in which case the null space of A^T is the whole R^m.

Therefore, it is necessary to check R too. Based on my experience with Matlab, if a row of R is straight 0, then the corresponding column in Q should also be a basis of the null space of A^T. Clearly this observation is heuristic and hinges on the particular algorithm used for QR decomposition.

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In the anwers above, it has been already pointed out how the null space of a matrix can be calculated by using the QR or the SVD approach. SVD should be preferred when accuracy is required, see also Null-space of a rectangular dense matrix.

As of February 2015, CUDA 7 (now in release candidate) makes SVD available through its new cuSOLVER library. Below I report an example on how using cuSOLVER's SVD to calculate the null space of a matrix.

Be aware that the problem you are focusing on concerns the calculation of several small matrices, so you should adapt the example I'm providing below by using streams to make sense for your case. To associate a stream to each task you can use




#include "cuda_runtime.h"
#include "device_launch_paraMeters.h"


#include <cusolverDn.h>
#include <cuda_runtime_api.h>

#include "Utilities.cuh"

/* MAIN */
int main(){

    // --- gesvd only supports Nrows >= Ncols
    // --- column major memory ordering

    const int Nrows = 7;
    const int Ncols = 5;

    // --- cuSOLVE input/output parameters/arrays
    int work_size = 0;
    int *devInfo;           gpuErrchk(cudaMalloc(&devInfo,          sizeof(int)));

    // --- CUDA solver initialization
    cusolverDnHandle_t solver_handle;

    // --- Singular values threshold
    double threshold = 1e-12;

    // --- Setting the host, Nrows x Ncols matrix
    double *h_A = (double *)malloc(Nrows * Ncols * sizeof(double));
    for(int j = 0; j < Nrows; j++)
        for(int i = 0; i < Ncols; i++)
            h_A[j + i*Nrows] = (i + j*j) * sqrt((double)(i + j));

    // --- Setting the device matrix and moving the host matrix to the device
    double *d_A;            gpuErrchk(cudaMalloc(&d_A,      Nrows * Ncols * sizeof(double)));
    gpuErrchk(cudaMemcpy(d_A, h_A, Nrows * Ncols * sizeof(double), cudaMemcpyHostToDevice));

    // --- host side SVD results space
    double *h_U = (double *)malloc(Nrows * Nrows     * sizeof(double));
    double *h_V = (double *)malloc(Ncols * Ncols     * sizeof(double));
    double *h_S = (double *)malloc(min(Nrows, Ncols) * sizeof(double));

    // --- device side SVD workspace and matrices
    double *d_U;            gpuErrchk(cudaMalloc(&d_U,  Nrows * Nrows     * sizeof(double)));
    double *d_V;            gpuErrchk(cudaMalloc(&d_V,  Ncols * Ncols     * sizeof(double)));
    double *d_S;            gpuErrchk(cudaMalloc(&d_S,  min(Nrows, Ncols) * sizeof(double)));

    // --- CUDA SVD initialization
    cusolveSafeCall(cusolverDnDgesvd_bufferSize(solver_handle, Nrows, Ncols, &work_size));
    double *work;   gpuErrchk(cudaMalloc(&work, work_size * sizeof(double)));

    // --- CUDA SVD execution
    cusolveSafeCall(cusolverDnDgesvd(solver_handle, 'A', 'A', Nrows, Ncols, d_A, Nrows, d_S, d_U, Nrows, d_V, Ncols, work, work_size, NULL, devInfo));
    int devInfo_h = 0;  gpuErrchk(cudaMemcpy(&devInfo_h, devInfo, sizeof(int), cudaMemcpyDeviceToHost));
    if (devInfo_h != 0) std::cout   << "Unsuccessful SVD execution\n\n";

    // --- Moving the results from device to host
    gpuErrchk(cudaMemcpy(h_S, d_S, min(Nrows, Ncols) * sizeof(double), cudaMemcpyDeviceToHost));
    gpuErrchk(cudaMemcpy(h_U, d_U, Nrows * Nrows     * sizeof(double), cudaMemcpyDeviceToHost));
    gpuErrchk(cudaMemcpy(h_V, d_V, Ncols * Ncols     * sizeof(double), cudaMemcpyDeviceToHost));

    for(int i = 0; i < min(Nrows, Ncols); i++) 
        std::cout << "d_S["<<i<<"] = " << std::setprecision(15) << h_S[i] << std::endl;


    int count = 0;
    bool flag = 0;
    while (!flag) {
        if (h_S[count] < threshold) flag = 1;
        if (count == min(Nrows, Ncols)) flag = 1;
    printf("The null space of A has dimension %i\n\n", min(Ncols, Nrows) - count);

    for(int j = count; j < Ncols; j++) {
        printf("Basis vector nr. %i\n", j - count);
        for(int i = 0; i < Ncols; i++)
                std::cout << "d_V["<<i<<"] = " << std::setprecision(15) << h_U[j*Ncols + i] << std::endl;


    return 0;




extern "C" int iDivUp(int, int);
extern "C" void gpuErrchk(cudaError_t);
extern "C" void cusolveSafeCall(cusolverStatus_t);


#include <stdio.h>
#include <assert.h>

#include "cuda_runtime.h"
#include <cuda.h>

#include <cusolverDn.h>

/* iDivUp FUNCTION */
extern "C" int iDivUp(int a, int b){ return ((a % b) != 0) ? (a / b + 1) : (a / b); }

// --- Credit to
void gpuAssert(cudaError_t code, char *file, int line, bool abort=true)
   if (code != cudaSuccess)
      fprintf(stderr,"GPUassert: %s %s %d\n", cudaGetErrorString(code), file, line);
      if (abort) { exit(code); }

extern "C" void gpuErrchk(cudaError_t ans) { gpuAssert((ans), __FILE__, __LINE__); }

static const char *_cudaGetErrorEnum(cusolverStatus_t error)
    switch (error)
            return "CUSOLVER_SUCCESS";


            return "CUSOLVER_STATUS_ALLOC_FAILED";







    return "<unknown>";

inline void __cusolveSafeCall(cusolverStatus_t err, const char *file, const int line)
        fprintf(stderr, "CUSOLVE error in file '%s', line %d\n %s\nerror %d: %s\nterminating!\n",__FILE__, __LINE__,err, \
                                _cudaGetErrorEnum(err)); \
        cudaDeviceReset(); assert(0); \

extern "C" void cusolveSafeCall(cusolverStatus_t err) { __cusolveSafeCall(err, __FILE__, __LINE__); }
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