https://github.com/cran/rstpm2
Tip revision: 13e45eaa4f4a7f231224f1b8ca4dff03903d250b authored by Mark Clements on 31 August 2017, 20:37:09 UTC
version 1.4.0
version 1.4.0
Tip revision: 13e45ea
gsl_bspline.c
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include "gsl_bspline.h"
#include <R.h>
/* Code to replicate bs() in splines package. Note that feeding in
x_min and x_max is necessary if you want to replicate predict.bs()
- use x_min/x_max for your training data and let x be the
evaluation data.
knots_int is an integer (0=uniform knots, 1=quantile knots) and
quantile_vector a vector of knots.*/
int gsl_bspline(double *x,
int *n,
int *degree,
int *nbreak,
double *x_min,
double *x_max,
double *quantile_vector,
int *knots_int,
double *Bx)
{
int k = *degree + 1; /* k in gsl */
int ncoeffs;
int i, j;
gsl_bspline_workspace *bw = gsl_bspline_alloc(k, *nbreak);
ncoeffs = (int)gsl_bspline_ncoeffs(bw); /* *nbreak+k-2 */
gsl_vector *B = gsl_vector_alloc(ncoeffs);
gsl_vector *quantile_vec = gsl_vector_alloc(*nbreak);
/* 7/12/10 added support for quantile knots */
if(*knots_int == 0) {
gsl_bspline_knots_uniform(*x_min, *x_max, bw);
} else {
for(i = 0; i < *nbreak; i++) gsl_vector_set(quantile_vec, i, quantile_vector[i]);
gsl_bspline_knots(quantile_vec, bw);
}
for (i = 0; i < *n; ++i)
{
/* compute B_j(xi) for all j */
gsl_bspline_eval(x[i], B, bw);
/* fill in row i of Bx */
for (j = 0; j < ncoeffs; ++j)
{
double Bj = gsl_vector_get(B, j);
Bx[i*ncoeffs+j] = Bj; /* Bx:*n-by-(*nbreak+*degree-1) */
}
}
gsl_bspline_free(bw);
gsl_vector_free(B);
gsl_vector_free(quantile_vec);
return(0);
} /* main() */
/* Provide missing functionality derivative bs() function in package
splines */
int gsl_bspline_deriv(double *x,
int *n,
int *degree,
int *nbreak,
int *order,
int *order_max,
double *x_min,
double *x_max,
double *quantile_vector,
int *knots_int,
double *Bx)
{
int k = *degree + 1; /* k in gsl */
int ncoeffs;
size_t i, j;
gsl_bspline_workspace *bw = gsl_bspline_alloc(k, *nbreak);
ncoeffs = (int)gsl_bspline_ncoeffs(bw);
gsl_vector *dBorder = gsl_vector_alloc(ncoeffs);
gsl_bspline_deriv_workspace *derivWS = gsl_bspline_deriv_alloc(k);
gsl_matrix *dB = gsl_matrix_alloc(ncoeffs, *order_max+1);
gsl_vector *quantile_vec = gsl_vector_alloc(*nbreak);
/* 7/12/10 added support for quantile knots */
if(*knots_int == 0) {
gsl_bspline_knots_uniform(*x_min, *x_max, bw);
} else {
for(i = 0; i < *nbreak; i++) gsl_vector_set(quantile_vec, i, quantile_vector[i]);
gsl_bspline_knots(quantile_vec, bw);
}
for (i = 0; i < *n; ++i)
{
/* compute B_j(xi) for all j */
gsl_bspline_deriv_eval(x[i], order[i], dB, bw, derivWS);
/* fill in row i of Bx */
gsl_matrix_get_col(dBorder, dB, order[i]);
for (j = 0; j < ncoeffs; ++j)
{
double Bj = gsl_vector_get(dBorder, j);
Bx[i*ncoeffs+j] = Bj;
}
}
gsl_bspline_free(bw);
gsl_vector_free(dBorder);
gsl_matrix_free(dB);
/* gsl_vector_free(quantile_vec);*/
gsl_bspline_deriv_free(derivWS);
return(0);
} /* main() */
