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I'm performing QR decomposition in two different ways: using standard numpy method and using GEQRF LAPACK function implemented in CULA library. Here is simple example in python (PyCULA used to access CULA):

from PyCULA.cula import culaInitialize,culaShutdown
from PyCULA.cula import gpu_geqrf, gpu_orgqr

import numpy as np
import sys

def test_numpy(A):
    Q, R = np.linalg.qr(A)
    print "Q"
    print Q
    print "R"
    print R
    print "transpose(Q)*Q"
    print np.dot(np.transpose(Q), Q)
    print "Q*R"
    print np.dot(Q,R)

def test_cula(A):
    culaInitialize()
    QR, TAU = gpu_geqrf(A)
    R = np.triu(QR)
    Q = gpu_orgqr(QR, A.shape[0], TAU)
    culaShutdown()
    print "Q"
    print Q
    print "R"
    print R
    print "transpose(Q)*Q"
    print np.dot(np.transpose(Q), Q)
    print "Q*R"
    print np.dot(Q,R)

def main():
    rows = int(sys.argv[1])
    cols = int(sys.argv[2])
    A = np.array(np.ones((rows,cols)).astype(np.float64))
    print "A"
    print A
    print "NUMPY"
    test_numpy(A.copy())
    print "CULA"
    test_cula(A.copy())

if __name__ == '__main__':
    main()

It produces following output:

A
[[ 1.  1.  1.]
 [ 1.  1.  1.]
 [ 1.  1.  1.]]
NUMPY
Q
[[-0.57735027 -0.57735027 -0.57735027]
 [-0.57735027  0.78867513 -0.21132487]
 [-0.57735027 -0.21132487  0.78867513]]
R
[[-1.73205081 -1.73205081 -1.73205081]
 [ 0.          0.          0.        ]
 [ 0.          0.          0.        ]]
transpose(Q)*Q
[[  1.00000000e+00   2.77555756e-17   0.00000000e+00]
 [  2.77555756e-17   1.00000000e+00   0.00000000e+00]
 [  0.00000000e+00   0.00000000e+00   1.00000000e+00]]
Q*R
[[ 1.  1.  1.]
 [ 1.  1.  1.]
 [ 1.  1.  1.]]
CULA
Q
[[-0.57735027 -0.57735027 -0.57735027]
 [-0.57735027  0.78867513 -0.21132487]
 [-0.57735027 -0.21132487  0.78867513]]
R
[[-1.73205081  0.3660254   0.3660254 ]
 [-0.          0.          0.        ]
 [-0.          0.          0.        ]]
transpose(Q)*Q
[[  1.00000000e+00   2.77555756e-17   0.00000000e+00]
 [  2.77555756e-17   1.00000000e+00   0.00000000e+00]
 [  0.00000000e+00   0.00000000e+00   1.00000000e+00]]
Q*R
[[ 1.         -0.21132487 -0.21132487]
 [ 1.         -0.21132487 -0.21132487]
 [ 1.         -0.21132487 -0.21132487]]

What is wrong with my code?

share|improve this question
    
QR decomposition is not unique if the matrix is not invertible. –  pv. Apr 24 at 17:18
    
@pv. As you can see in my example, CULA produces invalid R matrix so Q*R not equals A. The same problem with invertible matrix (e.g. [[2, 2], [2, 3]]). –  grapescan Apr 25 at 9:52
    
I've only tested CULA a couple of times, but I found it to yield incorrect results on a number of tests (particularly computing the SVD of a matrix). I didn't investigate too much, but it looked to me like an issue using 32-bit vs 64-bit floats. –  lmjohns3 Apr 28 at 16:57

1 Answer 1

I tested your example in R. CULA seems to provide the same results as R. Here is my code:

#include <Rcpp.h>
#include <cula.h>

// [[Rcpp::export]]
std::vector< float > gpuQR_cula( std::vector< float > x, const uint32_t nRows, const uint32_t nCols )
{       
    std::vector< float > tau( nCols ) ;

    culaInitialize() ;   
    culaSgeqrf( nRows, nCols, &x.front(), nRows, &tau.front() ) ;
    culaShutdown() ;

    Rcpp::Rcout << "Tau: " << tau[ 0 ] << ", " << tau[ 1 ] << ", " << tau[ 2 ] << "\n" ;

    for( uint32_t jj = 0 ; jj < nCols ; ++jj ) {
        for( uint32_t ii = 1 ; ii < nRows ; ++ii ) {
            if( ii > jj ) { x[ ii + jj * nRows ] *= tau[ jj ] ; }
        }
    }

    return x ;
}

Your matrix:

(A <- matrix(1, 3, 3))

     [,1] [,2] [,3]
[1,]    1    1    1
[2,]    1    1    1
[3,]    1    1    1
n_row <- nrow(A)
n_col <- ncol(A)

Here are the results from CULA:

matrix(gpuQR_cula(c(A), n_row, n_col), n_row, n_col)

Tau: 1.57735, 0, 0
           [,1]      [,2]      [,3]
[1,] -1.7320509 -1.732051 -1.732051
[2,]  0.5773503  0.000000  0.000000
[3,]  0.5773503  0.000000  0.000000

Here are the results from R:

(qrA <- qr(A))
$qr
           [,1]      [,2]      [,3]
[1,] -1.7320508 -1.732051 -1.732051
[2,]  0.5773503  0.000000  0.000000
[3,]  0.5773503  0.000000  0.000000

$qraux
[1] 1.57735 0.00000 0.00000

Q <- qr.Q(qrA)
R <- qr.R(qrA)
crossprod(Q)

             [,1]         [,2]         [,3]
[1,] 1.000000e+00 4.163336e-17 5.551115e-17
[2,] 4.163336e-17 1.000000e+00 0.000000e+00
[3,] 5.551115e-17 0.000000e+00 1.000000e+00

Q %*% R
     [,1] [,2] [,3]
[1,]    1    1    1
[2,]    1    1    1
[3,]    1    1    1

I hope that helps!

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