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authorWilliam Joye <wjoye@cfa.harvard.edu>2018-01-09 19:28:07 (GMT)
committerWilliam Joye <wjoye@cfa.harvard.edu>2018-01-09 19:28:07 (GMT)
commit3bfbbb90d4d6ebd44cc5eac38af24d1f78318a58 (patch)
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update ast 8.6.2
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-rw-r--r--ast/cminpack/lmder.c526
1 files changed, 526 insertions, 0 deletions
diff --git a/ast/cminpack/lmder.c b/ast/cminpack/lmder.c
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+#include "cminpack.h"
+#include <math.h>
+#include "cminpackP.h"
+
+__cminpack_attr__
+int __cminpack_func__(lmder)(__cminpack_decl_fcnder_mn__ void *p, int m, int n, real *x,
+ real *fvec, real *fjac, int ldfjac, real ftol,
+ real xtol, real gtol, int maxfev, real *
+ diag, int mode, real factor, int nprint,
+ int *nfev, int *njev, int *ipvt, real *qtf,
+ real *wa1, real *wa2, real *wa3, real *wa4)
+{
+ /* Initialized data */
+
+#define p1 .1
+#define p5 .5
+#define p25 .25
+#define p75 .75
+#define p0001 1e-4
+
+ /* System generated locals */
+ real d1, d2;
+
+ /* Local variables */
+ int i, j, l;
+ real par, sum;
+ int iter;
+ real temp, temp1, temp2;
+ int iflag;
+ real delta = 0.;
+ real ratio;
+ real fnorm, gnorm, pnorm, xnorm = 0., fnorm1, actred, dirder,
+ epsmch, prered;
+ int info;
+
+/* ********** */
+
+/* subroutine lmder */
+
+/* the purpose of lmder is to minimize the sum of the squares of */
+/* m nonlinear functions in n variables by a modification of */
+/* the levenberg-marquardt algorithm. the user must provide a */
+/* subroutine which calculates the functions and the jacobian. */
+
+/* the subroutine statement is */
+
+/* subroutine lmder(fcn,m,n,x,fvec,fjac,ldfjac,ftol,xtol,gtol, */
+/* maxfev,diag,mode,factor,nprint,info,nfev, */
+/* njev,ipvt,qtf,wa1,wa2,wa3,wa4) */
+
+/* where */
+
+/* fcn is the name of the user-supplied subroutine which */
+/* calculates the functions and the jacobian. fcn must */
+/* be declared in an external statement in the user */
+/* calling program, and should be written as follows. */
+
+/* subroutine fcn(m,n,x,fvec,fjac,ldfjac,iflag) */
+/* integer m,n,ldfjac,iflag */
+/* double precision x(n),fvec(m),fjac(ldfjac,n) */
+/* ---------- */
+/* if iflag = 1 calculate the functions at x and */
+/* return this vector in fvec. do not alter fjac. */
+/* if iflag = 2 calculate the jacobian at x and */
+/* return this matrix in fjac. do not alter fvec. */
+/* ---------- */
+/* return */
+/* end */
+
+/* the value of iflag should not be changed by fcn unless */
+/* the user wants to terminate execution of lmder. */
+/* in this case set iflag to a negative integer. */
+
+/* m is a positive integer input variable set to the number */
+/* of functions. */
+
+/* n is a positive integer input variable set to the number */
+/* of variables. n must not exceed m. */
+
+/* x is an array of length n. on input x must contain */
+/* an initial estimate of the solution vector. on output x */
+/* contains the final estimate of the solution vector. */
+
+/* fvec is an output array of length m which contains */
+/* the functions evaluated at the output x. */
+
+/* fjac is an output m by n array. the upper n by n submatrix */
+/* of fjac contains an upper triangular matrix r with */
+/* diagonal elements of nonincreasing magnitude such that */
+
+/* t t t */
+/* p *(jac *jac)*p = r *r, */
+
+/* where p is a permutation matrix and jac is the final */
+/* calculated jacobian. column j of p is column ipvt(j) */
+/* (see below) of the identity matrix. the lower trapezoidal */
+/* part of fjac contains information generated during */
+/* the computation of r. */
+
+/* ldfjac is a positive integer input variable not less than m */
+/* which specifies the leading dimension of the array fjac. */
+
+/* ftol is a nonnegative input variable. termination */
+/* occurs when both the actual and predicted relative */
+/* reductions in the sum of squares are at most ftol. */
+/* therefore, ftol measures the relative error desired */
+/* in the sum of squares. */
+
+/* xtol is a nonnegative input variable. termination */
+/* occurs when the relative error between two consecutive */
+/* iterates is at most xtol. therefore, xtol measures the */
+/* relative error desired in the approximate solution. */
+
+/* gtol is a nonnegative input variable. termination */
+/* occurs when the cosine of the angle between fvec and */
+/* any column of the jacobian is at most gtol in absolute */
+/* value. therefore, gtol measures the orthogonality */
+/* desired between the function vector and the columns */
+/* of the jacobian. */
+
+/* maxfev is a positive integer input variable. termination */
+/* occurs when the number of calls to fcn with iflag = 1 */
+/* has reached maxfev. */
+
+/* diag is an array of length n. if mode = 1 (see */
+/* below), diag is internally set. if mode = 2, diag */
+/* must contain positive entries that serve as */
+/* multiplicative scale factors for the variables. */
+
+/* mode is an integer input variable. if mode = 1, the */
+/* variables will be scaled internally. if mode = 2, */
+/* the scaling is specified by the input diag. other */
+/* values of mode are equivalent to mode = 1. */
+
+/* factor is a positive input variable used in determining the */
+/* initial step bound. this bound is set to the product of */
+/* factor and the euclidean norm of diag*x if nonzero, or else */
+/* to factor itself. in most cases factor should lie in the */
+/* interval (.1,100.).100. is a generally recommended value. */
+
+/* nprint is an integer input variable that enables controlled */
+/* printing of iterates if it is positive. in this case, */
+/* fcn is called with iflag = 0 at the beginning of the first */
+/* iteration and every nprint iterations thereafter and */
+/* immediately prior to return, with x, fvec, and fjac */
+/* available for printing. fvec and fjac should not be */
+/* altered. if nprint is not positive, no special calls */
+/* of fcn with iflag = 0 are made. */
+
+/* info is an integer output variable. if the user has */
+/* terminated execution, info is set to the (negative) */
+/* value of iflag. see description of fcn. otherwise, */
+/* info is set as follows. */
+
+/* info = 0 improper input parameters. */
+
+/* info = 1 both actual and predicted relative reductions */
+/* in the sum of squares are at most ftol. */
+
+/* info = 2 relative error between two consecutive iterates */
+/* is at most xtol. */
+
+/* info = 3 conditions for info = 1 and info = 2 both hold. */
+
+/* info = 4 the cosine of the angle between fvec and any */
+/* column of the jacobian is at most gtol in */
+/* absolute value. */
+
+/* info = 5 number of calls to fcn with iflag = 1 has */
+/* reached maxfev. */
+
+/* info = 6 ftol is too small. no further reduction in */
+/* the sum of squares is possible. */
+
+/* info = 7 xtol is too small. no further improvement in */
+/* the approximate solution x is possible. */
+
+/* info = 8 gtol is too small. fvec is orthogonal to the */
+/* columns of the jacobian to machine precision. */
+
+/* nfev is an integer output variable set to the number of */
+/* calls to fcn with iflag = 1. */
+
+/* njev is an integer output variable set to the number of */
+/* calls to fcn with iflag = 2. */
+
+/* ipvt is an integer output array of length n. ipvt */
+/* defines a permutation matrix p such that jac*p = q*r, */
+/* where jac is the final calculated jacobian, q is */
+/* orthogonal (not stored), and r is upper triangular */
+/* with diagonal elements of nonincreasing magnitude. */
+/* column j of p is column ipvt(j) of the identity matrix. */
+
+/* qtf is an output array of length n which contains */
+/* the first n elements of the vector (q transpose)*fvec. */
+
+/* wa1, wa2, and wa3 are work arrays of length n. */
+
+/* wa4 is a work array of length m. */
+
+/* subprograms called */
+
+/* user-supplied ...... fcn */
+
+/* minpack-supplied ... dpmpar,enorm,lmpar,qrfac */
+
+/* fortran-supplied ... dabs,dmax1,dmin1,dsqrt,mod */
+
+/* argonne national laboratory. minpack project. march 1980. */
+/* burton s. garbow, kenneth e. hillstrom, jorge j. more */
+
+/* ********** */
+
+/* epsmch is the machine precision. */
+
+ epsmch = __cminpack_func__(dpmpar)(1);
+
+ info = 0;
+ iflag = 0;
+ *nfev = 0;
+ *njev = 0;
+
+/* check the input parameters for errors. */
+
+ if (n <= 0 || m < n || ldfjac < m || ftol < 0. || xtol < 0. ||
+ gtol < 0. || maxfev <= 0 || factor <= 0.) {
+ goto TERMINATE;
+ }
+ if (mode == 2) {
+ for (j = 0; j < n; ++j) {
+ if (diag[j] <= 0.) {
+ goto TERMINATE;
+ }
+ }
+ }
+
+/* evaluate the function at the starting point */
+/* and calculate its norm. */
+
+ iflag = fcnder_mn(p, m, n, x, fvec, fjac, ldfjac, 1);
+ *nfev = 1;
+ if (iflag < 0) {
+ goto TERMINATE;
+ }
+ fnorm = __cminpack_enorm__(m, fvec);
+
+/* initialize levenberg-marquardt parameter and iteration counter. */
+
+ par = 0.;
+ iter = 1;
+
+/* beginning of the outer loop. */
+
+ for (;;) {
+
+/* calculate the jacobian matrix. */
+
+ iflag = fcnder_mn(p, m, n, x, fvec, fjac, ldfjac, 2);
+ ++(*njev);
+ if (iflag < 0) {
+ goto TERMINATE;
+ }
+
+/* if requested, call fcn to enable printing of iterates. */
+
+ if (nprint > 0) {
+ iflag = 0;
+ if ((iter - 1) % nprint == 0) {
+ iflag = fcnder_mn(p, m, n, x, fvec, fjac, ldfjac, 0);
+ }
+ if (iflag < 0) {
+ goto TERMINATE;
+ }
+ }
+
+/* compute the qr factorization of the jacobian. */
+
+ __cminpack_func__(qrfac)(m, n, fjac, ldfjac, TRUE_, ipvt, n,
+ wa1, wa2, wa3);
+
+/* on the first iteration and if mode is 1, scale according */
+/* to the norms of the columns of the initial jacobian. */
+
+ if (iter == 1) {
+ if (mode != 2) {
+ for (j = 0; j < n; ++j) {
+ diag[j] = wa2[j];
+ if (wa2[j] == 0.) {
+ diag[j] = 1.;
+ }
+ }
+ }
+
+/* on the first iteration, calculate the norm of the scaled x */
+/* and initialize the step bound delta. */
+
+ for (j = 0; j < n; ++j) {
+ wa3[j] = diag[j] * x[j];
+ }
+ xnorm = __cminpack_enorm__(n, wa3);
+ delta = factor * xnorm;
+ if (delta == 0.) {
+ delta = factor;
+ }
+ }
+
+/* form (q transpose)*fvec and store the first n components in */
+/* qtf. */
+
+ for (i = 0; i < m; ++i) {
+ wa4[i] = fvec[i];
+ }
+ for (j = 0; j < n; ++j) {
+ if (fjac[j + j * ldfjac] != 0.) {
+ sum = 0.;
+ for (i = j; i < m; ++i) {
+ sum += fjac[i + j * ldfjac] * wa4[i];
+ }
+ temp = -sum / fjac[j + j * ldfjac];
+ for (i = j; i < m; ++i) {
+ wa4[i] += fjac[i + j * ldfjac] * temp;
+ }
+ }
+ fjac[j + j * ldfjac] = wa1[j];
+ qtf[j] = wa4[j];
+ }
+
+/* compute the norm of the scaled gradient. */
+
+ gnorm = 0.;
+ if (fnorm != 0.) {
+ for (j = 0; j < n; ++j) {
+ l = ipvt[j]-1;
+ if (wa2[l] != 0.) {
+ sum = 0.;
+ for (i = 0; i <= j; ++i) {
+ sum += fjac[i + j * ldfjac] * (qtf[i] / fnorm);
+ }
+ /* Computing MAX */
+ d1 = fabs(sum / wa2[l]);
+ gnorm = max(gnorm,d1);
+ }
+ }
+ }
+
+/* test for convergence of the gradient norm. */
+
+ if (gnorm <= gtol) {
+ info = 4;
+ }
+ if (info != 0) {
+ goto TERMINATE;
+ }
+
+/* rescale if necessary. */
+
+ if (mode != 2) {
+ for (j = 0; j < n; ++j) {
+ /* Computing MAX */
+ d1 = diag[j], d2 = wa2[j];
+ diag[j] = max(d1,d2);
+ }
+ }
+
+/* beginning of the inner loop. */
+
+ do {
+
+/* determine the levenberg-marquardt parameter. */
+
+ __cminpack_func__(lmpar)(n, fjac, ldfjac, ipvt, diag, qtf, delta,
+ &par, wa1, wa2, wa3, wa4);
+
+/* store the direction p and x + p. calculate the norm of p. */
+
+ for (j = 0; j < n; ++j) {
+ wa1[j] = -wa1[j];
+ wa2[j] = x[j] + wa1[j];
+ wa3[j] = diag[j] * wa1[j];
+ }
+ pnorm = __cminpack_enorm__(n, wa3);
+
+/* on the first iteration, adjust the initial step bound. */
+
+ if (iter == 1) {
+ delta = min(delta,pnorm);
+ }
+
+/* evaluate the function at x + p and calculate its norm. */
+
+ iflag = fcnder_mn(p, m, n, wa2, wa4, fjac, ldfjac, 1);
+ ++(*nfev);
+ if (iflag < 0) {
+ goto TERMINATE;
+ }
+ fnorm1 = __cminpack_enorm__(m, wa4);
+
+/* compute the scaled actual reduction. */
+
+ actred = -1.;
+ if (p1 * fnorm1 < fnorm) {
+ /* Computing 2nd power */
+ d1 = fnorm1 / fnorm;
+ actred = 1. - d1 * d1;
+ }
+
+/* compute the scaled predicted reduction and */
+/* the scaled directional derivative. */
+
+ for (j = 0; j < n; ++j) {
+ wa3[j] = 0.;
+ l = ipvt[j]-1;
+ temp = wa1[l];
+ for (i = 0; i <= j; ++i) {
+ wa3[i] += fjac[i + j * ldfjac] * temp;
+ }
+ }
+ temp1 = __cminpack_enorm__(n, wa3) / fnorm;
+ temp2 = (sqrt(par) * pnorm) / fnorm;
+ prered = temp1 * temp1 + temp2 * temp2 / p5;
+ dirder = -(temp1 * temp1 + temp2 * temp2);
+
+/* compute the ratio of the actual to the predicted */
+/* reduction. */
+
+ ratio = 0.;
+ if (prered != 0.) {
+ ratio = actred / prered;
+ }
+
+/* update the step bound. */
+
+ if (ratio <= p25) {
+ if (actred >= 0.) {
+ temp = p5;
+ } else {
+ temp = p5 * dirder / (dirder + p5 * actred);
+ }
+ if (p1 * fnorm1 >= fnorm || temp < p1) {
+ temp = p1;
+ }
+ /* Computing MIN */
+ d1 = pnorm / p1;
+ delta = temp * min(delta,d1);
+ par /= temp;
+ } else {
+ if (par == 0. || ratio >= p75) {
+ delta = pnorm / p5;
+ par = p5 * par;
+ }
+ }
+
+/* test for successful iteration. */
+
+ if (ratio >= p0001) {
+
+/* successful iteration. update x, fvec, and their norms. */
+
+ for (j = 0; j < n; ++j) {
+ x[j] = wa2[j];
+ wa2[j] = diag[j] * x[j];
+ }
+ for (i = 0; i < m; ++i) {
+ fvec[i] = wa4[i];
+ }
+ xnorm = __cminpack_enorm__(n, wa2);
+ fnorm = fnorm1;
+ ++iter;
+ }
+
+/* tests for convergence. */
+
+ if (fabs(actred) <= ftol && prered <= ftol && p5 * ratio <= 1.) {
+ info = 1;
+ }
+ if (delta <= xtol * xnorm) {
+ info = 2;
+ }
+ if (fabs(actred) <= ftol && prered <= ftol && p5 * ratio <= 1. && info == 2) {
+ info = 3;
+ }
+ if (info != 0) {
+ goto TERMINATE;
+ }
+
+/* tests for termination and stringent tolerances. */
+
+ if (*nfev >= maxfev) {
+ info = 5;
+ }
+ if (fabs(actred) <= epsmch && prered <= epsmch && p5 * ratio <= 1.) {
+ info = 6;
+ }
+ if (delta <= epsmch * xnorm) {
+ info = 7;
+ }
+ if (gnorm <= epsmch) {
+ info = 8;
+ }
+ if (info != 0) {
+ goto TERMINATE;
+ }
+
+/* end of the inner loop. repeat if iteration unsuccessful. */
+
+ } while (ratio < p0001);
+
+/* end of the outer loop. */
+
+ }
+TERMINATE:
+
+/* termination, either normal or user imposed. */
+
+ if (iflag < 0) {
+ info = iflag;
+ }
+ if (nprint > 0) {
+ fcnder_mn(p, m, n, x, fvec, fjac, ldfjac, 0);
+ }
+ return info;
+
+/* last card of subroutine lmder. */
+
+} /* lmder_ */
+