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jama_svd.h
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jama_svd.h
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#ifndef JAMA_SVD_H
#define JAMA_SVD_H
#include "tnt_array1d.h"
#include "tnt_array1d_utils.h"
#include "tnt_array2d.h"
#include "tnt_array2d_utils.h"
#include "tnt_math_utils.h"
#include <algorithm>
// for min(), max() below
#include <cmath>
// for abs() below
using namespace TNT;
using namespace std;
namespace JAMA
{
/** Singular Value Decomposition.
<P>
For an m-by-n matrix A with m >= n, the singular value decomposition is
an m-by-n orthogonal matrix U, an n-by-n diagonal matrix S, and
an n-by-n orthogonal matrix V so that A = U*S*V'.
<P>
The singular values, sigma[k] = S[k][k], are ordered so that
sigma[0] >= sigma[1] >= ... >= sigma[n-1].
<P>
The singular value decompostion always exists, so the constructor will
never fail. The matrix condition number and the effective numerical
rank can be computed from this decomposition.
<p>
(Adapted from JAMA, a Java Matrix Library, developed by jointly
by the Mathworks and NIST; see http://math.nist.gov/javanumerics/jama).
*/
template <class Real>
class SVD
{
Array2D<Real> U, V;
Array1D<Real> s;
int m, n;
public:
SVD (const Array2D<Real> &Arg) {
m = Arg.dim1();
n = Arg.dim2();
int nu = min(m,n);
s = Array1D<Real>(min(m+1,n));
U = Array2D<Real>(m, nu, Real(0));
V = Array2D<Real>(n,n);
Array1D<Real> e(n);
Array1D<Real> work(m);
Array2D<Real> A(Arg.copy());
int wantu = 1; /* boolean */
int wantv = 1; /* boolean */
int i=0, j=0, k=0;
// Reduce A to bidiagonal form, storing the diagonal elements
// in s and the super-diagonal elements in e.
int nct = min(m-1,n);
int nrt = max(0,min(n-2,m));
for (k = 0; k < max(nct,nrt); k++) {
if (k < nct) {
// Compute the transformation for the k-th column and
// place the k-th diagonal in s[k].
// Compute 2-norm of k-th column without under/overflow.
s[k] = 0;
for (i = k; i < m; i++) {
s[k] = hypot(s[k],A[i][k]);
}
if (s[k] != 0.0) {
if (A[k][k] < 0.0) {
s[k] = -s[k];
}
for (i = k; i < m; i++) {
A[i][k] /= s[k];
}
A[k][k] += 1.0;
}
s[k] = -s[k];
}
for (j = k+1; j < n; j++) {
if ((k < nct) && (s[k] != 0.0)) {
// Apply the transformation.
double t = 0;
for (i = k; i < m; i++) {
t += A[i][k]*A[i][j];
}
t = -t/A[k][k];
for (i = k; i < m; i++) {
A[i][j] += t*A[i][k];
}
}
// Place the k-th row of A into e for the
// subsequent calculation of the row transformation.
e[j] = A[k][j];
}
if (wantu & (k < nct)) {
// Place the transformation in U for subsequent back
// multiplication.
for (i = k; i < m; i++) {
U[i][k] = A[i][k];
}
}
if (k < nrt) {
// Compute the k-th row transformation and place the
// k-th super-diagonal in e[k].
// Compute 2-norm without under/overflow.
e[k] = 0;
for (i = k+1; i < n; i++) {
e[k] = hypot(e[k],e[i]);
}
if (e[k] != 0.0) {
if (e[k+1] < 0.0) {
e[k] = -e[k];
}
for (i = k+1; i < n; i++) {
e[i] /= e[k];
}
e[k+1] += 1.0;
}
e[k] = -e[k];
if ((k+1 < m) & (e[k] != 0.0)) {
// Apply the transformation.
for (i = k+1; i < m; i++) {
work[i] = 0.0;
}
for (j = k+1; j < n; j++) {
for (i = k+1; i < m; i++) {
work[i] += e[j]*A[i][j];
}
}
for (j = k+1; j < n; j++) {
double t = -e[j]/e[k+1];
for (i = k+1; i < m; i++) {
A[i][j] += t*work[i];
}
}
}
if (wantv) {
// Place the transformation in V for subsequent
// back multiplication.
for (i = k+1; i < n; i++) {
V[i][k] = e[i];
}
}
}
}
// Set up the final bidiagonal matrix or order p.
int p = min(n,m+1);
if (nct < n) {
s[nct] = A[nct][nct];
}
if (m < p) {
s[p-1] = 0.0;
}
if (nrt+1 < p) {
e[nrt] = A[nrt][p-1];
}
e[p-1] = 0.0;
// If required, generate U.
if (wantu) {
for (j = nct; j < nu; j++) {
for (i = 0; i < m; i++) {
U[i][j] = 0.0;
}
U[j][j] = 1.0;
}
for (k = nct-1; k >= 0; k--) {
if (s[k] != 0.0) {
for (j = k+1; j < nu; j++) {
double t = 0;
for (i = k; i < m; i++) {
t += U[i][k]*U[i][j];
}
t = -t/U[k][k];
for (i = k; i < m; i++) {
U[i][j] += t*U[i][k];
}
}
for (i = k; i < m; i++ ) {
U[i][k] = -U[i][k];
}
U[k][k] = 1.0 + U[k][k];
for (i = 0; i < k-1; i++) {
U[i][k] = 0.0;
}
} else {
for (i = 0; i < m; i++) {
U[i][k] = 0.0;
}
U[k][k] = 1.0;
}
}
}
// If required, generate V.
if (wantv) {
for (k = n-1; k >= 0; k--) {
if ((k < nrt) & (e[k] != 0.0)) {
for (j = k+1; j < nu; j++) {
double t = 0;
for (i = k+1; i < n; i++) {
t += V[i][k]*V[i][j];
}
t = -t/V[k+1][k];
for (i = k+1; i < n; i++) {
V[i][j] += t*V[i][k];
}
}
}
for (i = 0; i < n; i++) {
V[i][k] = 0.0;
}
V[k][k] = 1.0;
}
}
// Main iteration loop for the singular values.
int pp = p-1;
int iter = 0;
double eps = pow(2.0,-52.0);
while (p > 0) {
int k=0;
int kase=0;
// Here is where a test for too many iterations would go.
// This section of the program inspects for
// negligible elements in the s and e arrays. On
// completion the variables kase and k are set as follows.
// kase = 1 if s(p) and e[k-1] are negligible and k<p
// kase = 2 if s(k) is negligible and k<p
// kase = 3 if e[k-1] is negligible, k<p, and
// s(k), ..., s(p) are not negligible (qr step).
// kase = 4 if e(p-1) is negligible (convergence).
for (k = p-2; k >= -1; k--) {
if (k == -1) {
break;
}
if (abs(e[k]) <= eps*(abs(s[k]) + abs(s[k+1]))) {
e[k] = 0.0;
break;
}
}
if (k == p-2) {
kase = 4;
} else {
int ks;
for (ks = p-1; ks >= k; ks--) {
if (ks == k) {
break;
}
double t = (ks != p ? abs(e[ks]) : 0.) +
(ks != k+1 ? abs(e[ks-1]) : 0.);
if (abs(s[ks]) <= eps*t) {
s[ks] = 0.0;
break;
}
}
if (ks == k) {
kase = 3;
} else if (ks == p-1) {
kase = 1;
} else {
kase = 2;
k = ks;
}
}
k++;
// Perform the task indicated by kase.
switch (kase) {
// Deflate negligible s(p).
case 1: {
double f = e[p-2];
e[p-2] = 0.0;
for (j = p-2; j >= k; j--) {
double t = hypot(s[j],f);
double cs = s[j]/t;
double sn = f/t;
s[j] = t;
if (j != k) {
f = -sn*e[j-1];
e[j-1] = cs*e[j-1];
}
if (wantv) {
for (i = 0; i < n; i++) {
t = cs*V[i][j] + sn*V[i][p-1];
V[i][p-1] = -sn*V[i][j] + cs*V[i][p-1];
V[i][j] = t;
}
}
}
}
break;
// Split at negligible s(k).
case 2: {
double f = e[k-1];
e[k-1] = 0.0;
for (j = k; j < p; j++) {
double t = hypot(s[j],f);
double cs = s[j]/t;
double sn = f/t;
s[j] = t;
f = -sn*e[j];
e[j] = cs*e[j];
if (wantu) {
for (i = 0; i < m; i++) {
t = cs*U[i][j] + sn*U[i][k-1];
U[i][k-1] = -sn*U[i][j] + cs*U[i][k-1];
U[i][j] = t;
}
}
}
}
break;
// Perform one qr step.
case 3: {
// Calculate the shift.
double scale = max(max(max(max(
abs(s[p-1]),abs(s[p-2])),abs(e[p-2])),
abs(s[k])),abs(e[k]));
double sp = s[p-1]/scale;
double spm1 = s[p-2]/scale;
double epm1 = e[p-2]/scale;
double sk = s[k]/scale;
double ek = e[k]/scale;
double b = ((spm1 + sp)*(spm1 - sp) + epm1*epm1)/2.0;
double c = (sp*epm1)*(sp*epm1);
double shift = 0.0;
if ((b != 0.0) || (c != 0.0)) {
shift = sqrt(b*b + c);
if (b < 0.0) {
shift = -shift;
}
shift = c/(b + shift);
}
double f = (sk + sp)*(sk - sp) + shift;
double g = sk*ek;
// Chase zeros.
for (j = k; j < p-1; j++) {
double t = hypot(f,g);
double cs = f/t;
double sn = g/t;
if (j != k) {
e[j-1] = t;
}
f = cs*s[j] + sn*e[j];
e[j] = cs*e[j] - sn*s[j];
g = sn*s[j+1];
s[j+1] = cs*s[j+1];
if (wantv) {
for (i = 0; i < n; i++) {
t = cs*V[i][j] + sn*V[i][j+1];
V[i][j+1] = -sn*V[i][j] + cs*V[i][j+1];
V[i][j] = t;
}
}
t = hypot(f,g);
cs = f/t;
sn = g/t;
s[j] = t;
f = cs*e[j] + sn*s[j+1];
s[j+1] = -sn*e[j] + cs*s[j+1];
g = sn*e[j+1];
e[j+1] = cs*e[j+1];
if (wantu && (j < m-1)) {
for (i = 0; i < m; i++) {
t = cs*U[i][j] + sn*U[i][j+1];
U[i][j+1] = -sn*U[i][j] + cs*U[i][j+1];
U[i][j] = t;
}
}
}
e[p-2] = f;
iter = iter + 1;
}
break;
// Convergence.
case 4: {
// Make the singular values positive.
if (s[k] <= 0.0) {
s[k] = (s[k] < 0.0 ? -s[k] : 0.0);
if (wantv) {
for (i = 0; i <= pp; i++) {
V[i][k] = -V[i][k];
}
}
}
// Order the singular values.
while (k < pp) {
if (s[k] >= s[k+1]) {
break;
}
double t = s[k];
s[k] = s[k+1];
s[k+1] = t;
if (wantv && (k < n-1)) {
for (i = 0; i < n; i++) {
t = V[i][k+1]; V[i][k+1] = V[i][k]; V[i][k] = t;
}
}
if (wantu && (k < m-1)) {
for (i = 0; i < m; i++) {
t = U[i][k+1]; U[i][k+1] = U[i][k]; U[i][k] = t;
}
}
k++;
}
iter = 0;
p--;
}
break;
}
}
}
void getU (Array2D<Real> &A)
{
int minm = min(m+1,n);
A = Array2D<Real>(m, minm);
for (int i=0; i<m; i++)
for (int j=0; j<minm; j++)
A[i][j] = U[i][j];
}
/* Return the right singular vectors */
void getV (Array2D<Real> &A)
{
A = V;
}
/** Return the one-dimensional array of singular values */
void getSingularValues (Array1D<Real> &x)
{
x = s;
}
/** Return the diagonal matrix of singular values
@return S
*/
void getS (Array2D<Real> &A) {
A = Array2D<Real>(n,n);
for (int i = 0; i < n; i++) {
for (int j = 0; j < n; j++) {
A[i][j] = 0.0;
}
A[i][i] = s[i];
}
}
/** Two norm (max(S)) */
double norm2 () {
return s[0];
}
/** Two norm of condition number (max(S)/min(S)) */
double cond () {
return s[0]/s[min(m,n)-1];
}
/** Effective numerical matrix rank
@return Number of nonnegligible singular values.
*/
int rank ()
{
double eps = pow(2.0,-52.0);
double tol = max(m,n)*s[0]*eps;
int r = 0;
for (int i = 0; i < s.dim(); i++) {
if (s[i] > tol) {
r++;
}
}
return r;
}
};
}
#endif
// JAMA_SVD_H