/* multimin.c Ruby/GSL: Ruby extension library for GSL (GNU Scientific Library) (C) Copyright 2004 by Yoshiki Tsunesada Ruby/GSL is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY. */ #include "rb_gsl.h" #include "rb_gsl_array.h" #include "rb_gsl_function.h" #include #ifndef CHECK_MULTIMIN_FUNCTION #define CHECK_MULTIMIN_FUNCTION(x) if(CLASS_OF(x)!=cgsl_multimin_function)\ rb_raise(rb_eTypeError,\ "wrong argument type %s (GSL::MultiMin::Function expected)",\ rb_class2name(CLASS_OF(x))); #endif #ifndef CHECK_MULTIMIN_FUNCTION_FDF #define CHECK_MULTIMIN_FUNCTION_FDF(x) if(CLASS_OF(x)!=cgsl_multimin_function_fdf)\ rb_raise(rb_eTypeError,\ "wrong argument type %s (GSL::MultiMin::Function_fdf expected)",\ rb_class2name(CLASS_OF(x))); #endif VALUE cgsl_multimin_function_fdf; /* Used also in multimin_fsdf.c */ static VALUE cgsl_multimin_function; enum { GSL_FDFMINIMIZER_CONJUGATE_FR, GSL_FDFMINIMIZER_CONJUGATE_PR, GSL_FDFMINIMIZER_VECTOR_BFGS, GSL_FDFMINIMIZER_STEEPEST_DESCENT, GSL_FMINIMIZER_NMSIMPLEX, #ifdef GSL_1_9_LATER GSL_FDFMINIMIZER_VECTOR_BFGS2, #endif #ifdef GSL_1_13_LATER GSL_FMINIMIZER_NMSIMPLEX2RAND, #endif }; static const gsl_multimin_fdfminimizer_type* get_fdfminimizer_type(VALUE t); #ifdef GSL_1_3_LATER static const gsl_multimin_fminimizer_type* get_fminimizer_type(VALUE t); #endif static void define_const(); static void gsl_multimin_function_free(gsl_multimin_function *f); static double rb_gsl_multimin_function_f(const gsl_vector *x, void *p); static void set_function(int i, VALUE *argv, gsl_multimin_function *F); static void gsl_multimin_function_fdf_free(gsl_multimin_function_fdf *f); double rb_gsl_multimin_function_fdf_f(const gsl_vector *x, void *p); void rb_gsl_multimin_function_fdf_df(const gsl_vector *x, void *p, gsl_vector *g); void rb_gsl_multimin_function_fdf_fdf(const gsl_vector *x, void *p, double *f, gsl_vector *g); static void set_function_fdf(int i, VALUE *argv, gsl_multimin_function_fdf *F); /*** multimin_funcion ***/ static void gsl_multimin_function_mark(gsl_multimin_function *F); static void gsl_multimin_function_fdf_mark(gsl_multimin_function_fdf *F); static void gsl_multimin_function_mark(gsl_multimin_function *F) { rb_gc_mark((VALUE) F->params); } static void gsl_multimin_function_fdf_mark(gsl_multimin_function_fdf *F) { rb_gc_mark((VALUE) F->params); } static VALUE rb_gsl_multimin_function_new(int argc, VALUE *argv, VALUE klass) { gsl_multimin_function *F = NULL; VALUE ary; size_t i; F = ALLOC(gsl_multimin_function); F->f = &rb_gsl_multimin_function_f; ary = rb_ary_new2(2); /* (VALUE) F->params = ary;*/ F->params = (void *) ary; if (rb_block_given_p()) rb_ary_store(ary, 0, RB_GSL_MAKE_PROC); else rb_ary_store(ary, 0, Qnil); rb_ary_store(ary, 1, Qnil); switch (argc) { case 0: break; case 1: set_function(0, argv, F); break; case 2: case 3: for (i = 0; i < argc; i++) set_function(i, argv, F); break; default: rb_raise(rb_eArgError, "wrong number of arguments"); } return Data_Wrap_Struct(klass, gsl_multimin_function_mark, gsl_multimin_function_free, F); } static void gsl_multimin_function_free(gsl_multimin_function *f) { free((gsl_multimin_function *) f); } static VALUE rb_gsl_multimin_function_n(VALUE obj) { gsl_multimin_function *F = NULL; Data_Get_Struct(obj, gsl_multimin_function, F); return INT2FIX(F->n); } static double rb_gsl_multimin_function_f(const gsl_vector *x, void *p) { VALUE vx, vp, proc, result; vx = Data_Wrap_Struct(cgsl_vector, 0, NULL, (gsl_vector *) x); proc = rb_ary_entry((VALUE) p, 0); vp = rb_ary_entry((VALUE) p, 1); if (NIL_P(vp)) result = rb_funcall(proc, RBGSL_ID_call, 1, vx); else result = rb_funcall(proc, RBGSL_ID_call, 2, vx, vp); return NUM2DBL(result); } static VALUE rb_gsl_multimin_function_eval(VALUE obj, VALUE vx) { gsl_multimin_function *F = NULL; VALUE vp, proc, ary, result; Data_Get_Struct(obj, gsl_multimin_function, F); ary = (VALUE) F->params; proc = rb_ary_entry(ary, 0); vp = rb_ary_entry(ary, 1); if (NIL_P(vp)) result = rb_funcall(proc, RBGSL_ID_call, 1, vx); else result = rb_funcall(proc, RBGSL_ID_call, 2, vx, vp); return result; } static void set_function(int i, VALUE *argv, gsl_multimin_function *F) { VALUE ary; ary = (VALUE) F->params; if (TYPE(argv[i]) == T_FIXNUM) F->n = FIX2INT(argv[i]); else if (rb_obj_is_kind_of(argv[i], rb_cProc)) rb_ary_store(ary, 0, argv[i]); else if (TYPE(argv[i]) == T_ARRAY || rb_obj_is_kind_of(argv[i], cgsl_vector) || TYPE(argv[i]) == T_FIXNUM || TYPE(argv[i]) == T_FLOAT) { rb_ary_store(ary, 1, argv[i]); } else { rb_raise(rb_eTypeError, "wrong type of argument %d (Fixnum or Proc)", i); } } static VALUE rb_gsl_multimin_function_set_f(int argc, VALUE *argv, VALUE obj) { gsl_multimin_function *F = NULL; VALUE ary; size_t i; Data_Get_Struct(obj, gsl_multimin_function, F); ary = (VALUE) F->params; if (rb_block_given_p()) rb_ary_store(ary, 0, RB_GSL_MAKE_PROC); switch (argc) { case 1: set_function(0, argv, F); break; case 2: case 3: for (i = 0; i < argc; i++) set_function(i, argv, F); break; default: rb_raise(rb_eArgError, "wrong number of arguments"); } return obj; } static VALUE rb_gsl_multimin_function_set_params(int argc, VALUE *argv, VALUE obj) { gsl_multimin_function *F = NULL; VALUE ary, ary2; size_t i; if (argc == 0) return obj; Data_Get_Struct(obj, gsl_multimin_function, F); if (F->params == NULL) { ary = rb_ary_new2(4); /* (VALUE) F->params = ary;*/ F->params = (void *) ary; } else { ary = (VALUE) F->params; } if (argc == 1) rb_ary_store(ary, 1, argv[0]); else { ary2 = rb_ary_new2(argc); for (i = 0; i < argc; i++) rb_ary_store(ary2, i, argv[i]); rb_ary_store(ary, 1, ary2); } return obj; } static VALUE rb_gsl_multimin_function_params(VALUE obj) { gsl_multimin_function *F = NULL; Data_Get_Struct(obj, gsl_multimin_function, F); return rb_ary_entry((VALUE) F->params, 1); } /*** multimin_function_fdf ***/ static void set_function_fdf(int argc, VALUE *argv, gsl_multimin_function_fdf *F); static VALUE rb_gsl_multimin_function_fdf_new(int argc, VALUE *argv, VALUE klass) { gsl_multimin_function_fdf *F = NULL; VALUE ary; F = ALLOC(gsl_multimin_function_fdf); F->f = &rb_gsl_multimin_function_fdf_f; F->df = &rb_gsl_multimin_function_fdf_df; F->fdf = &rb_gsl_multimin_function_fdf_fdf; ary = rb_ary_new2(4); /* (VALUE) F->params = ary;*/ F->params = (void *) ary; rb_ary_store(ary, 2, Qnil); rb_ary_store(ary, 3, Qnil); set_function_fdf(argc, argv, F); return Data_Wrap_Struct(klass, gsl_multimin_function_fdf_mark, gsl_multimin_function_fdf_free, F); } static void gsl_multimin_function_fdf_free(gsl_multimin_function_fdf *f) { free((gsl_multimin_function_fdf *) f); } static VALUE rb_gsl_multimin_function_fdf_n(VALUE obj) { gsl_multimin_function_fdf *F = NULL; Data_Get_Struct(obj, gsl_multimin_function_fdf, F); return INT2FIX(F->n); } static void set_function_fdf(int argc, VALUE *argv, gsl_multimin_function_fdf *F) { VALUE ary; if (F->params == NULL) { ary = rb_ary_new2(4); /* (VALUE) F->params = ary;*/ F->params = (void *) ary; } else { ary = (VALUE) F->params; } switch (argc) { case 1: if (TYPE(argv[0]) != T_FIXNUM) rb_raise(rb_eTypeError, "Fixnum expected"); F->n = FIX2INT(argv[0]); break; case 2: rb_ary_store(ary, 0, argv[0]); rb_ary_store(ary, 1, argv[1]); rb_ary_store(ary, 2, Qnil); break; case 3: rb_ary_store(ary, 0, argv[0]); rb_ary_store(ary, 1, argv[1]); if (TYPE(argv[2]) == T_FIXNUM) { F->n = FIX2INT(argv[2]); rb_ary_store(ary, 2, Qnil); } else { rb_ary_store(ary, 2, argv[2]); } break; case 4: case 5: if (TYPE(argv[0]) == T_FIXNUM) { F->n = FIX2INT(argv[0]); rb_ary_store(ary, 0, argv[1]); rb_ary_store(ary, 1, argv[2]); rb_ary_store(ary, 2, argv[3]); } else { rb_ary_store(ary, 0, argv[0]); rb_ary_store(ary, 1, argv[1]); rb_ary_store(ary, 2, argv[2]); F->n = FIX2INT(argv[3]); } if (argc == 5) rb_ary_store(ary, 3, argv[4]); break; default: rb_raise(rb_eArgError, "wrong number of arguments (1, 3, or 4)"); } } static VALUE rb_gsl_multimin_function_fdf_set_procs(int argc, VALUE *argv, VALUE obj) { VALUE ary; gsl_multimin_function_fdf *F = NULL; Data_Get_Struct(obj, gsl_multimin_function_fdf, F); if (F->params == NULL) { ary = rb_ary_new2(4); /* (VALUE) F->params = ary;*/ F->params = (void *) ary; } else { ary = (VALUE) F->params; } switch (argc) { case 2: rb_ary_store(ary, 0, argv[0]); rb_ary_store(ary, 1, argv[1]); rb_ary_store(ary, 2, Qnil); break; case 3: rb_ary_store(ary, 0, argv[0]); rb_ary_store(ary, 1, argv[1]); if (TYPE(argv[2]) == T_FIXNUM) { F->n = FIX2INT(argv[2]); rb_ary_store(ary, 2, Qnil); } else { rb_ary_store(ary, 2, argv[2]); } break; case 4: case 5: if (TYPE(argv[0]) == T_FIXNUM) { F->n = FIX2INT(argv[0]); rb_ary_store(ary, 0, argv[1]); rb_ary_store(ary, 1, argv[2]); rb_ary_store(ary, 2, argv[3]); } else { rb_ary_store(ary, 0, argv[0]); rb_ary_store(ary, 1, argv[1]); rb_ary_store(ary, 2, argv[2]); F->n = FIX2INT(argv[3]); } if (argc == 5) rb_ary_store(ary, 3, argv[4]); break; default: rb_raise(rb_eArgError, "wrong number of arguments (2, 3, or 4)"); } return obj; } static VALUE rb_gsl_multimin_function_fdf_set_params(int argc, VALUE *argv, VALUE obj) { gsl_multimin_function_fdf *F = NULL; VALUE ary, ary2; size_t i; if (argc == 0) return obj; Data_Get_Struct(obj, gsl_multimin_function_fdf, F); if (F->params == NULL) { ary = rb_ary_new2(4); /* (VALUE) F->params = ary;*/ F->params = (void *) ary; } else { ary = (VALUE) F->params; } if (argc == 1) { rb_ary_store(ary, 3, argv[0]); } else { ary2 = rb_ary_new2(argc); for (i = 0; i < argc; i++) rb_ary_store(ary2, i, argv[i]); rb_ary_store(ary, 3, ary2); } return obj; } static VALUE rb_gsl_multimin_function_fdf_set(int argc, VALUE *argv, VALUE obj) { gsl_multimin_function_fdf *F = NULL; Data_Get_Struct(obj, gsl_multimin_function_fdf, F); set_function_fdf(argc, argv, F); return obj; } double rb_gsl_multimin_function_fdf_f(const gsl_vector *x, void *p) { VALUE vx, proc, vp, result, ary; vx = Data_Wrap_Struct(cgsl_vector, 0, NULL, (gsl_vector *) x); ary = (VALUE) p; proc = rb_ary_entry(ary, 0); vp = rb_ary_entry(ary, RARRAY_LEN(ary)-1); if (NIL_P(vp)) result = rb_funcall(proc, RBGSL_ID_call, 1, vx); else result = rb_funcall(proc, RBGSL_ID_call, 2, vx, vp); return NUM2DBL(result); } void rb_gsl_multimin_function_fdf_df(const gsl_vector *x, void *p, gsl_vector *g) { VALUE vx, vg, proc, vp, ary; vx = Data_Wrap_Struct(cgsl_vector, 0, NULL, (gsl_vector *) x); vg = Data_Wrap_Struct(cgsl_vector, 0, NULL, g); ary = (VALUE) p; proc = rb_ary_entry(ary, 1); vp = rb_ary_entry(ary, RARRAY_LEN(ary)-1); if (NIL_P(vp)) { rb_funcall(proc, RBGSL_ID_call, 2, vx, vg); } else { rb_funcall(proc, RBGSL_ID_call, 3, vx, vp, vg); } } void rb_gsl_multimin_function_fdf_fdf(const gsl_vector *x, void *p, double *f, gsl_vector *g) { VALUE vx, vf, vg, proc_fdf, proc_f, proc_df, vp, ary, result; vx = Data_Wrap_Struct(cgsl_vector, 0, NULL, (gsl_vector *) x); vg = Data_Wrap_Struct(cgsl_vector, 0, NULL, g); vf = rb_float_new(*f); ary = (VALUE) p; proc_f = rb_ary_entry(ary, 0); proc_df = rb_ary_entry(ary, 1); proc_fdf = rb_ary_entry(ary, 2); vp = rb_ary_entry(ary, RARRAY_LEN(ary)-1); if (NIL_P(vp)) { result = rb_funcall(proc_f, RBGSL_ID_call, 1, vx); rb_funcall(proc_df, RBGSL_ID_call, 2, vx, vg); } else { result = rb_funcall(proc_f, RBGSL_ID_call, 2, vx, vp); rb_funcall(proc_df, RBGSL_ID_call, 3, vx, vp, vg); } *f = NUM2DBL(result); } static VALUE rb_gsl_multimin_function_fdf_params(VALUE obj) { gsl_multimin_function_fdf *F = NULL; Data_Get_Struct(obj, gsl_multimin_function_fdf, F); return rb_ary_entry((VALUE) F->params, 3); } /****************/ static void define_const(VALUE klass1, VALUE klass2) { rb_define_const(klass1, "CONJUGATE_FR", INT2FIX(GSL_FDFMINIMIZER_CONJUGATE_FR)); rb_define_const(klass1, "CONJUGATE_PR", INT2FIX(GSL_FDFMINIMIZER_CONJUGATE_PR)); rb_define_const(klass1, "VECTOR_BFGS", INT2FIX(GSL_FDFMINIMIZER_VECTOR_BFGS)); rb_define_const(klass1, "STEEPEST_DESCENT", INT2FIX(GSL_FDFMINIMIZER_STEEPEST_DESCENT)); #ifdef GSL_1_3_LATER rb_define_const(klass2, "NMSIMPLEX", INT2FIX(GSL_FMINIMIZER_NMSIMPLEX)); #endif #ifdef GSL_1_9_LATER rb_define_const(klass1, "VECTOR_BFGS2", INT2FIX(GSL_FDFMINIMIZER_VECTOR_BFGS2)); #endif #ifdef GSL_1_13_LATER rb_define_const(klass2, "NMSIMPLEX2RAND", INT2FIX(GSL_FMINIMIZER_NMSIMPLEX2RAND)); #endif } static const gsl_multimin_fdfminimizer_type* get_fdfminimizer_type(VALUE t) { char name[64]; switch (TYPE(t)) { case T_STRING: strcpy(name, STR2CSTR(t)); if (str_tail_grep(name, "conjugate_fr") == 0) return gsl_multimin_fdfminimizer_conjugate_fr; else if (str_tail_grep(name, "conjugate_pr") == 0) return gsl_multimin_fdfminimizer_conjugate_pr; else if (str_tail_grep(name, "vector_bfgs") == 0) return gsl_multimin_fdfminimizer_vector_bfgs; else if (str_tail_grep(name, "steepest_descent") == 0) return gsl_multimin_fdfminimizer_steepest_descent; #ifdef GSL_1_9_LATER else if (str_tail_grep(name, "vector_bfgs2") == 0) return gsl_multimin_fdfminimizer_vector_bfgs2; #endif else rb_raise(rb_eTypeError, "%s: unknown minimizer type", name); break; case T_FIXNUM: switch (FIX2INT(t)) { case GSL_FDFMINIMIZER_CONJUGATE_FR: return gsl_multimin_fdfminimizer_conjugate_fr; break; case GSL_FDFMINIMIZER_CONJUGATE_PR: return gsl_multimin_fdfminimizer_conjugate_pr; break; case GSL_FDFMINIMIZER_VECTOR_BFGS: return gsl_multimin_fdfminimizer_vector_bfgs; break; case GSL_FDFMINIMIZER_STEEPEST_DESCENT: return gsl_multimin_fdfminimizer_steepest_descent; break; #ifdef GSL_1_9_LATER case GSL_FDFMINIMIZER_VECTOR_BFGS2: return gsl_multimin_fdfminimizer_vector_bfgs2; break; #endif default: rb_raise(rb_eTypeError, "%d: unknown type", FIX2INT(t)); break; } break; default: rb_raise(rb_eTypeError, "type is given by a String or a Fixnum"); break; } } static VALUE rb_gsl_fdfminimizer_new(VALUE klass, VALUE t, VALUE n) { gsl_multimin_fdfminimizer *gmf = NULL; const gsl_multimin_fdfminimizer_type *T; T = get_fdfminimizer_type(t); gmf = gsl_multimin_fdfminimizer_alloc(T, FIX2INT(n)); return Data_Wrap_Struct(klass, 0, gsl_multimin_fdfminimizer_free, gmf); } static VALUE rb_gsl_fdfminimizer_set(VALUE obj, VALUE ff, VALUE xx, VALUE ss, VALUE tt) { gsl_multimin_fdfminimizer *gmf = NULL; gsl_multimin_function_fdf *F = NULL; gsl_vector *x; double stepsize, tol; int status; CHECK_MULTIMIN_FUNCTION_FDF(ff); Need_Float(ss); Need_Float(tt); Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); Data_Get_Struct(ff, gsl_multimin_function_fdf, F); Data_Get_Vector(xx, x); stepsize = NUM2DBL(ss); tol = NUM2DBL(tt); status = gsl_multimin_fdfminimizer_set(gmf, F, x, stepsize, tol); return INT2FIX(status); } static VALUE rb_gsl_fdfminimizer_name(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); return rb_str_new2(gsl_multimin_fdfminimizer_name(gmf)); } static VALUE rb_gsl_fdfminimizer_iterate(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); return INT2FIX(gsl_multimin_fdfminimizer_iterate(gmf)); } static VALUE rb_gsl_fdfminimizer_x(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; gsl_vector *x = NULL; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); x = gsl_multimin_fdfminimizer_x(gmf); return Data_Wrap_Struct(cgsl_vector_view_ro, 0, NULL, x); } static VALUE rb_gsl_fdfminimizer_gradient(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; gsl_vector *gradient = NULL; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); gradient = gsl_multimin_fdfminimizer_gradient(gmf); return Data_Wrap_Struct(cgsl_vector_view_ro, 0, NULL, gradient); } static VALUE rb_gsl_fdfminimizer_minimum(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; double min; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); min = gsl_multimin_fdfminimizer_minimum(gmf); return rb_float_new(min); } static VALUE rb_gsl_fdfminimizer_f(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); return rb_float_new(gmf->f); } static VALUE rb_gsl_fdfminimizer_restart(VALUE obj) { gsl_multimin_fdfminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); return INT2FIX(gsl_multimin_fdfminimizer_restart(gmf)); } static VALUE rb_gsl_fdfminimizer_test_gradient(VALUE obj, VALUE ea) { gsl_multimin_fdfminimizer *gmf = NULL; gsl_vector *g = NULL; Need_Float(ea); Data_Get_Struct(obj, gsl_multimin_fdfminimizer, gmf); g = gsl_multimin_fdfminimizer_gradient(gmf); return INT2FIX(gsl_multimin_test_gradient(g, NUM2DBL(ea))); } static VALUE rb_gsl_multimin_test_gradient(VALUE obj, VALUE gg, VALUE ea) { gsl_vector *g = NULL; Need_Float(ea); Data_Get_Vector(gg, g); return INT2FIX(gsl_multimin_test_gradient(g, NUM2DBL(ea))); } /*****/ #ifdef GSL_1_3_LATER static const gsl_multimin_fminimizer_type* get_fminimizer_type(VALUE t) { char name[64]; switch (TYPE(t)) { case T_STRING: strcpy(name, STR2CSTR(t)); if (str_tail_grep(name, "nmsimplex") == 0) return gsl_multimin_fminimizer_nmsimplex; #ifdef GSL_1_13_LATER if (str_tail_grep(name, "nmsimplex2rand") == 0) return gsl_multimin_fminimizer_nmsimplex2rand; #endif else rb_raise(rb_eTypeError, "unknown type %s (nmsimplex and nmsimplex2rand supported)", name); break; case T_FIXNUM: switch (FIX2INT(t)) { case GSL_FMINIMIZER_NMSIMPLEX: return gsl_multimin_fminimizer_nmsimplex; break; #ifdef GSL_1_13_LATER case GSL_FMINIMIZER_NMSIMPLEX2RAND: return gsl_multimin_fminimizer_nmsimplex2rand; break; #endif default: rb_raise(rb_eTypeError, "%d: unknown type (not supported)", FIX2INT(t)); break; } break; default: rb_raise(rb_eTypeError, "wrong argument type %s (String or Fixnum expected)", rb_class2name(CLASS_OF(t))); break; } } static VALUE rb_gsl_fminimizer_new(VALUE klass, VALUE t, VALUE n) { gsl_multimin_fminimizer *gmf = NULL; const gsl_multimin_fminimizer_type *T; CHECK_FIXNUM(n); T = get_fminimizer_type(t); gmf = gsl_multimin_fminimizer_alloc(T, FIX2INT(n)); return Data_Wrap_Struct(klass, 0, gsl_multimin_fminimizer_free, gmf); } static VALUE rb_gsl_fminimizer_set(VALUE obj, VALUE ff, VALUE xx, VALUE ss) { gsl_multimin_fminimizer *gmf = NULL; gsl_multimin_function *F = NULL; gsl_vector *x = NULL, *s = NULL; CHECK_MULTIMIN_FUNCTION(ff); Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); Data_Get_Struct(ff, gsl_multimin_function, F); Data_Get_Vector(xx, x); Data_Get_Vector(ss, s); return INT2FIX(gsl_multimin_fminimizer_set(gmf, F, x, s)); } static VALUE rb_gsl_fminimizer_name(VALUE obj) { gsl_multimin_fminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); return rb_str_new2(gsl_multimin_fminimizer_name(gmf)); } static VALUE rb_gsl_fminimizer_iterate(VALUE obj) { gsl_multimin_fminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); return INT2FIX(gsl_multimin_fminimizer_iterate(gmf)); } static VALUE rb_gsl_fminimizer_x(VALUE obj) { gsl_multimin_fminimizer *gmf = NULL; gsl_vector *x = NULL; Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); x = gsl_multimin_fminimizer_x(gmf); return Data_Wrap_Struct(cgsl_vector_view_ro, 0, NULL, x); } static VALUE rb_gsl_fminimizer_minimum(VALUE obj) { gsl_multimin_fminimizer *gmf = NULL; double min; Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); min = gsl_multimin_fminimizer_minimum(gmf); return rb_float_new(min); } static VALUE rb_gsl_fminimizer_size(VALUE obj) { gsl_multimin_fminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); return rb_float_new(gsl_multimin_fminimizer_size(gmf)); } static VALUE rb_gsl_fminimizer_fval(VALUE obj) { gsl_multimin_fminimizer *gmf = NULL; Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); return rb_float_new(gmf->fval); } static VALUE rb_gsl_fminimizer_test_size(VALUE obj, VALUE ea) { gsl_multimin_fminimizer *gmf = NULL; Need_Float(ea); Data_Get_Struct(obj, gsl_multimin_fminimizer, gmf); return INT2FIX(gsl_multimin_test_size(gmf->size, NUM2DBL(ea))); } static VALUE rb_gsl_multimin_test_size(VALUE obj, VALUE ss, VALUE ea) { Need_Float(ss); Need_Float(ea); return INT2FIX(gsl_multimin_test_size(NUM2DBL(ss), NUM2DBL(ea))); } #endif #ifdef HAVE_GSL_GSL_MULTIMIN_FSDF_H void Init_multimin_fsdf(VALUE module); #endif /*****/ void Init_gsl_multimin(VALUE module) { VALUE mgsl_multimin; VALUE cgsl_multimin_fdfminimizer; VALUE cgsl_multimin_fminimizer; mgsl_multimin = rb_define_module_under(module, "MultiMin"); rb_define_singleton_method(mgsl_multimin, "test_gradient", rb_gsl_multimin_test_gradient, 2); #ifdef GSL_1_3_LATER rb_define_singleton_method(mgsl_multimin, "test_size", rb_gsl_multimin_test_size, 2); #endif cgsl_multimin_fdfminimizer = rb_define_class_under(mgsl_multimin, "FdfMinimizer", cGSL_Object); cgsl_multimin_fminimizer = rb_define_class_under(mgsl_multimin, "FMinimizer", cGSL_Object); define_const(cgsl_multimin_fdfminimizer, cgsl_multimin_fminimizer); cgsl_multimin_function = rb_define_class_under(mgsl_multimin, "Function", cgsl_function); rb_define_singleton_method(cgsl_multimin_function, "alloc", rb_gsl_multimin_function_new, -1); rb_define_method(cgsl_multimin_function, "eval", rb_gsl_multimin_function_eval, 1); rb_define_alias(cgsl_multimin_function, "call", "eval"); rb_define_method(cgsl_multimin_function, "set_proc", rb_gsl_multimin_function_set_f, -1); rb_define_alias(cgsl_multimin_function, "set_f", "set_proc"); rb_define_method(cgsl_multimin_function, "set_params", rb_gsl_multimin_function_set_params, -1); rb_define_method(cgsl_multimin_function, "params", rb_gsl_multimin_function_params, 0); rb_define_method(cgsl_multimin_function, "n", rb_gsl_multimin_function_n, 0); cgsl_multimin_function_fdf = rb_define_class_under(mgsl_multimin, "Function_fdf", cGSL_Object); rb_define_singleton_method(cgsl_multimin_function_fdf, "alloc", rb_gsl_multimin_function_fdf_new, -1); rb_define_method(cgsl_multimin_function_fdf, "set", rb_gsl_multimin_function_fdf_set, -1); rb_define_method(cgsl_multimin_function_fdf, "set_params", rb_gsl_multimin_function_fdf_set_params, -1); rb_define_method(cgsl_multimin_function_fdf, "set_procs", rb_gsl_multimin_function_fdf_set_procs, -1); rb_define_method(cgsl_multimin_function_fdf, "params", rb_gsl_multimin_function_fdf_params, 0); rb_define_method(cgsl_multimin_function_fdf, "n", rb_gsl_multimin_function_fdf_n, 0); rb_define_singleton_method(cgsl_multimin_fdfminimizer, "alloc", rb_gsl_fdfminimizer_new, 2); rb_define_method(cgsl_multimin_fdfminimizer, "set", rb_gsl_fdfminimizer_set, 4); rb_define_method(cgsl_multimin_fdfminimizer, "name", rb_gsl_fdfminimizer_name, 0); rb_define_method(cgsl_multimin_fdfminimizer, "iterate", rb_gsl_fdfminimizer_iterate, 0); rb_define_method(cgsl_multimin_fdfminimizer, "x", rb_gsl_fdfminimizer_x, 0); rb_define_method(cgsl_multimin_fdfminimizer, "f", rb_gsl_fdfminimizer_f, 0); rb_define_method(cgsl_multimin_fdfminimizer, "gradient", rb_gsl_fdfminimizer_gradient, 0); rb_define_method(cgsl_multimin_fdfminimizer, "minimum", rb_gsl_fdfminimizer_minimum, 0); rb_define_method(cgsl_multimin_fdfminimizer, "restart", rb_gsl_fdfminimizer_restart, 0); rb_define_method(cgsl_multimin_fdfminimizer, "test_gradient", rb_gsl_fdfminimizer_test_gradient, 1); /*****/ #ifdef GSL_1_3_LATER rb_define_singleton_method(cgsl_multimin_fminimizer, "alloc", rb_gsl_fminimizer_new, 2); rb_define_method(cgsl_multimin_fminimizer, "set", rb_gsl_fminimizer_set, 3); rb_define_method(cgsl_multimin_fminimizer, "name", rb_gsl_fminimizer_name, 0); rb_define_method(cgsl_multimin_fminimizer, "iterate", rb_gsl_fminimizer_iterate, 0); rb_define_method(cgsl_multimin_fminimizer, "x", rb_gsl_fminimizer_x, 0); rb_define_method(cgsl_multimin_fminimizer, "fval", rb_gsl_fminimizer_fval, 0); rb_define_method(cgsl_multimin_fminimizer, "minimum", rb_gsl_fminimizer_minimum, 0); rb_define_method(cgsl_multimin_fminimizer, "size", rb_gsl_fminimizer_size, 0); rb_define_method(cgsl_multimin_fminimizer, "test_size", rb_gsl_fminimizer_test_size, 1); #endif #ifdef HAVE_GSL_GSL_MULTIMIN_FSDF_H Init_multimin_fsdf(mgsl_multimin); #endif } #ifdef CHECK_MULTIMIN_FUNCTION #undef CHECK_MULTIMIN_FUNCTION #endif #ifdef CHECK_MULTIMIN_FUNCTION_FDF #undef CHECK_MULTIMIN_FUNCTION_FDF #endif