ruby/inline/curve1_rubyinline.rb - platform/external/lmfit - Git at Google

 #! /usr/bin/env ruby

 # This is 'curve1.c' demo done with RubyInline gem (instead of using swig)
 # Contributed by Igor Drozdov <idrozdov@gmail.com> 2012
 # $ ruby curve1_rubyinline.rb
 #
 # Requirements:
 #
 # $ gem install RubyInline
 #
 # To make sure header files and shared librares can be found,
 # export appropriate LD_LIBRARY_PATH and C_INCLUDE_PATH.

 require 'rubygems'
 require 'inline'

 class Curve
   inline(:C) do |builder|
     builder.include("\"lmcurve.h\"")
     builder.include("\"lmmin.h\"")
     builder.include("<math.h>")
     builder.include("<stdio.h>")
     builder.include("<ruby.h>)")
     builder.add_link_flags("-llmmin")

     builder.c_raw <<EOC
 double f( double t, const double *p )
 {
     return p[0] + p[1]*(t-p[2])*(t-p[2]);
 }
 EOC

     builder.c <<EOC
 VALUE demo(VALUE t_ary, VALUE y_ary) {
     /* parameter vector */
     int n_par = 3; // number of parameters in model function f
     double par[3] = { 1, 0, -1 }; // relatively bad starting value

     /* data pairs: slightly distorted standard parabola */

     int m_dat = 11; // number of data pairs
     int i;

     /* ruby macros dealing with inputs */
     int t_len = RARRAY_LEN(t_ary);
     int y_len = RARRAY_LEN(y_ary);

     double t[t_len];
     double y[t_len];

     VALUE *t_arr = RARRAY_PTR(t_ary);
     VALUE *y_arr = RARRAY_PTR(y_ary);

     VALUE result_pars = rb_ary_new();   // ruby array containing fitted params

     /* auxiliary parameters */
     lm_status_struct status;
     lm_control_struct control = lm_control_double;

     for (i = 0; i < t_len; i++) {
       t[i] = NUM2DBL(t_arr[i]);
       y[i] = NUM2DBL(y_arr[i]);
     }

     lmcurve_fit( n_par, par, m_dat, t, y, f, &control, &status );
     /* print results */

     printf( "\\nResults:\\n" );
     printf( "status after %d function evaluations:\\n  %s\\n",
             status.nfev, lm_infmsg[status.outcome] );

     printf("obtained parameters:\\n");
     for ( i = 0; i < n_par; ++i)
          rb_ary_push(result_pars,DBL2NUM(par[i]));
  	printf("  par[%i] = %12g\\n", i, par[i]);
     printf("obtained norm:\\n  %12g\\n", status.fnorm );

     printf("fitting data as follows:\\n");
     for ( i = 0; i < m_dat; ++i)
         printf( "  t[%2d]=%12g y=%12g fit=%12g residue=%12g\\n",
                 i, t[i], y[i], f(t[i],par), y[i] - f(t[i],par) );

     printf("\\n");
     return result_pars;
 }
 EOC

   end
 end

 #

 t = [ -5.0, -4.0, -3.0, -2.0, -1.0, 0.0, 1.0, 2.0, 3.0, 4.0, 5.0 ]
 y = [ 25.5, 16.6, 9.9, 4.4, 1.1, 0, 1.1, 4.2, 9.3, 16.4, 25.5 ]

 c = Curve.new
 p c.demo(t,y)
	#! /usr/bin/env ruby

	# This is 'curve1.c' demo done with RubyInline gem (instead of using swig)
	# Contributed by Igor Drozdov <idrozdov@gmail.com> 2012
	# $ ruby curve1_rubyinline.rb
	#
	# Requirements:
	#
	# $ gem install RubyInline
	#
	# To make sure header files and shared librares can be found,
	# export appropriate LD_LIBRARY_PATH and C_INCLUDE_PATH.

	require 'rubygems'
	require 'inline'

	class Curve
	inline(:C) do \|builder\|
	builder.include("\"lmcurve.h\"")
	builder.include("\"lmmin.h\"")
	builder.include("<math.h>")
	builder.include("<stdio.h>")
	builder.include("<ruby.h>)")
	builder.add_link_flags("-llmmin")

	builder.c_raw <<EOC
	double f( double t, const double *p )
	{
	return p[0] + p[1](t-p[2])(t-p[2]);
	}
	EOC

	builder.c <<EOC
	VALUE demo(VALUE t_ary, VALUE y_ary) {
	/* parameter vector */
	int n_par = 3; // number of parameters in model function f
	double par[3] = { 1, 0, -1 }; // relatively bad starting value

	/* data pairs: slightly distorted standard parabola */

	int m_dat = 11; // number of data pairs
	int i;

	/* ruby macros dealing with inputs */
	int t_len = RARRAY_LEN(t_ary);
	int y_len = RARRAY_LEN(y_ary);

	double t[t_len];
	double y[t_len];

	VALUE *t_arr = RARRAY_PTR(t_ary);
	VALUE *y_arr = RARRAY_PTR(y_ary);

	VALUE result_pars = rb_ary_new(); // ruby array containing fitted params

	/* auxiliary parameters */
	lm_status_struct status;
	lm_control_struct control = lm_control_double;

	for (i = 0; i < t_len; i++) {
	t[i] = NUM2DBL(t_arr[i]);
	y[i] = NUM2DBL(y_arr[i]);
	}

	lmcurve_fit( n_par, par, m_dat, t, y, f, &control, &status );
	/* print results */

	printf( "\\nResults:\\n" );
	printf( "status after %d function evaluations:\\n %s\\n",
	status.nfev, lm_infmsg[status.outcome] );

	printf("obtained parameters:\\n");
	for ( i = 0; i < n_par; ++i)
	rb_ary_push(result_pars,DBL2NUM(par[i]));
	printf(" par[%i] = %12g\\n", i, par[i]);
	printf("obtained norm:\\n %12g\\n", status.fnorm );

	printf("fitting data as follows:\\n");
	for ( i = 0; i < m_dat; ++i)
	printf( " t[%2d]=%12g y=%12g fit=%12g residue=%12g\\n",
	i, t[i], y[i], f(t[i],par), y[i] - f(t[i],par) );

	printf("\\n");
	return result_pars;
	}
	EOC

	end
	end

	#

	t = [ -5.0, -4.0, -3.0, -2.0, -1.0, 0.0, 1.0, 2.0, 3.0, 4.0, 5.0 ]
	y = [ 25.5, 16.6, 9.9, 4.4, 1.1, 0, 1.1, 4.2, 9.3, 16.4, 25.5 ]

	c = Curve.new
	p c.demo(t,y)