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matrix.c
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369 lines (314 loc) · 8.43 KB
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/* NOTICE: Change of Copyright Status
*
* The author of this module, Carsten Grammes, has expressed in
* personal email that he has no more interest in this code, and
* doesn't claim any copyright. He has agreed to put this module
* into the public domain.
*
* Lars Hecking 15-02-1999
*/
/*
* Matrix algebra, part of
*
* Nonlinear least squares fit according to the
* Marquardt-Levenberg-algorithm
*
* added as Patch to Gnuplot (v3.2 and higher)
* by Carsten Grammes
* Experimental Physics, University of Saarbruecken, Germany
*
* Previous copyright of this module: Carsten Grammes, 1993
*
*/
#include "matrix.h"
#include "alloc.h"
#include "fit.h"
#include "util.h"
/*****************************************************************/
#define Swap(a,b) {double _temp = (a); (a) = (b); (b) = _temp;}
/* HBB 20010424: unused: */
/* #define WINZIG 1e-30 */
/*****************************************************************
internal prototypes
*****************************************************************/
static GP_INLINE int fsign(double x);
/*****************************************************************
first straightforward vector and matrix allocation functions
*****************************************************************/
/* allocates a double vector with n elements */
double *
vec(int n)
{
double *dp;
if (n < 1)
return NULL;
dp = gp_alloc(n * sizeof(double), "vec");
return dp;
}
/* allocates a double matrix */
double **
matr(int rows, int cols)
{
int i;
double **m;
if (rows < 1 || cols < 1)
return NULL;
m = gp_alloc(rows * sizeof(m[0]), "matrix row pointers");
m[0] = gp_alloc(rows * cols * sizeof(m[0][0]), "matrix elements");
for (i = 1; i < rows; i++)
m[i] = m[i - 1] + cols;
return m;
}
void
free_matr(double **m)
{
if (m != NULL) {
free(m[0]);
free(m);
}
}
double *
redim_vec(double **v, int n)
{
if (n < 1)
*v = NULL;
else
*v = gp_realloc(*v, n * sizeof((*v)[0]), "vec");
return *v;
}
/* HBB: TODO: is there a better value for 'epsilon'? how to specify
* 'inline'? is 'fsign' really not available elsewhere? use
* row-oriented version (p. 309) instead?
*/
static GP_INLINE int
fsign(double x)
{
return (x > 0 ? 1 : (x < 0) ? -1 : 0);
}
/*****************************************************************
Solve least squares Problem C*x+d = r, |r| = min!, by Given rotations
(QR-decomposition). Direct implementation of the algorithm
presented in H.R.Schwarz: Numerische Mathematik, Equation 7.33
If 'd == NULL', d is not accessed: the routine just computes the QR
decomposition of C and exits.
*****************************************************************/
void
Givens(
double **C,
double *d,
double *x,
int N,
int n)
{
int i, j, k;
double w, gamma, sigma, rho, temp;
double epsilon = DBL_EPSILON;
/*
* First, construct QR decomposition of C, by 'rotating away'
* all elements of C below the diagonal. The rotations are
* stored in place as Givens coefficients rho.
* Vector d is also rotated in this same turn, if it exists
*/
for (j = 0; j < n; j++) {
for (i = j + 1; i < N; i++) {
if (C[i][j]) {
if (fabs(C[j][j]) < epsilon * fabs(C[i][j])) {
/* find the rotation parameters */
w = -C[i][j];
gamma = 0;
sigma = 1;
rho = 1;
} else {
w = fsign(C[j][j]) * sqrt(C[j][j] * C[j][j] + C[i][j] * C[i][j]);
if (w == 0)
Eex3("w = 0 in Givens(); Cjj = %g, Cij = %g", C[j][j], C[i][j]);
gamma = C[j][j] / w;
sigma = -C[i][j] / w;
rho = (fabs(sigma) < gamma) ? sigma : fsign(sigma) / gamma;
}
C[j][j] = w;
C[i][j] = rho; /* store rho in place, for later use */
for (k = j + 1; k < n; k++) {
/* rotation on index pair (i,j) */
temp = gamma * C[j][k] - sigma * C[i][k];
C[i][k] = sigma * C[j][k] + gamma * C[i][k];
C[j][k] = temp;
}
if (d) { /* if no d vector given, don't use it */
temp = gamma * d[j] - sigma * d[i]; /* rotate d */
d[i] = sigma * d[j] + gamma * d[i];
d[j] = temp;
}
}
}
}
if (!d) /* stop here if no d was specified */
return;
/* solve R*x+d = 0, by backsubstitution */
for (i = n - 1; i >= 0; i--) {
double s = d[i];
for (k = i + 1; k < n; k++)
s += C[i][k] * x[k];
if (C[i][i] == 0)
Eex("Singular matrix in Givens()");
x[i] = -s / C[i][i];
}
}
/* Given a triangular Matrix R, compute (R^T * R)^(-1), by forward
* then back substitution
*
* R, I are n x n Matrices, I is for the result. Both must already be
* allocated.
*
* Will only calculate the lower triangle of I, as it is symmetric
*/
void
Invert_RtR(double **R, double **I, int n)
{
int i, j, k;
/* fill in the I matrix, and check R for regularity : */
for (i = 0; i < n; i++) {
for (j = 0; j < i; j++) /* upper triangle isn't needed */
I[i][j] = 0;
I[i][i] = 1;
if (!R[i][i])
Eex("Singular matrix in Invert_RtR");
}
/* Forward substitution: Solve R^T * B = I, store B in place of I */
for (k = 0; k < n; k++) {
for (i = k; i < n; i++) { /* upper half needn't be computed */
double s = I[i][k];
for (j = k; j < i; j++) /* for j<k, I[j][k] always stays zero! */
s -= R[j][i] * I[j][k];
I[i][k] = s / R[i][i];
}
}
/* Backward substitution: Solve R * A = B, store A in place of B */
for (k = 0; k < n; k++) {
for (i = n - 1; i >= k; i--) { /* don't compute upper triangle of A */
double s = I[i][k];
for (j = i + 1; j < n; j++)
s -= R[i][j] * I[j][k];
I[i][k] = s / R[i][i];
}
}
}
void
lu_decomp(double **a, int n, int *indx, double *d)
{
int i, imax = -1, j, k; /* HBB: added initial value, to shut up gcc -Wall */
double large, dummy, temp, **ar, **lim, *limc, *ac, *dp, *vscal;
dp = vscal = vec(n);
*d = 1.0;
for (ar = a, lim = &(a[n]); ar < lim; ar++) {
large = 0.0;
for (ac = *ar, limc = &(ac[n]); ac < limc;)
if ((temp = fabs(*ac++)) > large)
large = temp;
if (large == 0.0)
int_error(NO_CARET, "Singular matrix in LU-DECOMP");
*dp++ = 1 / large;
}
ar = a;
for (j = 0; j < n; j++, ar++) {
for (i = 0; i < j; i++) {
ac = &(a[i][j]);
for (k = 0; k < i; k++)
*ac -= a[i][k] * a[k][j];
}
large = 0.0;
dp = &(vscal[j]);
for (i = j; i < n; i++) {
ac = &(a[i][j]);
for (k = 0; k < j; k++)
*ac -= a[i][k] * a[k][j];
if ((dummy = *dp++ * fabs(*ac)) >= large) {
large = dummy;
imax = i;
}
}
if (j != imax) {
ac = a[imax];
dp = *ar;
for (k = 0; k < n; k++, ac++, dp++)
Swap(*ac, *dp);
*d = -(*d);
vscal[imax] = vscal[j];
}
indx[j] = imax;
if (*(dp = &(*ar)[j]) == 0)
*dp = 1e-30;
if (j != n - 1) {
dummy = 1 / (*ar)[j];
for (i = j + 1; i < n; i++)
a[i][j] *= dummy;
}
}
free(vscal);
}
void
lu_backsubst(double **a, int n, int *indx, double *b)
{
int i, memi = -1, ip, j;
double sum, *bp, *bip, **ar, *ac;
ar = a;
for (i = 0; i < n; i++, ar++) {
ip = indx[i];
sum = b[ip];
b[ip] = b[i];
if (memi >= 0) {
ac = &((*ar)[memi]);
bp = &(b[memi]);
for (j = memi; j <= i - 1; j++)
sum -= *ac++ * *bp++;
} else if (sum)
memi = i;
b[i] = sum;
}
ar--;
for (i = n - 1; i >= 0; i--) {
ac = &(*ar)[i + 1];
bp = &(b[i + 1]);
bip = &(b[i]);
for (j = i + 1; j < n; j++)
*bip -= *ac++ * *bp++;
*bip /= (*ar--)[i];
}
}
/*****************************************************************
Sum up squared components of a vector
In order to reduce rounding errors in summing up the entries
of a vector, we employ the Neumaier variant of the Kahan and
Babuska algorithm:
A. Neumaier, Rundungsfehleranalyse einiger Verfahren zur
Summation endlicher Summen, Z. angew. Math. Mechanik, 54:39-51, 1974
*****************************************************************/
double
sumsq_vec(int n, const double *x)
{
int i;
double s;
double c = 0.0;
if ((x == NULL) || (n == 0))
return 0;
s = x[0] * x[0];
for (i = 1; i < n; i++) {
double xi = x[i] * x[i];
double t = s + xi;
if (fabs(s) >= fabs(xi))
c += ((s - t) + xi);
else
c += ((xi - t) + s);
s = t;
};
s += c;
return s;
}
/*****************************************************************
Euclidean norm of a vector
*****************************************************************/
double
enorm_vec(int n, const double *x)
{
return sqrt(sumsq_vec(n, x));
}