/* GSL - Generic Sound Layer * Copyright (C) 2001 Stefan Westerfeld and Tim Janik * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General * Public License along with this program; if not, write to the * Free Software Foundation, Inc., 59 Temple Place, Suite 330, * Boston, MA 02111-1307, USA. */ #include #include #include #include #include #define PREC "15" static void usage (char *s) { printf ("usage: gslmathtest %s\n", s); exit (1); } int main (int argc, char *argv[]) { gchar *arg; if (argc < 2) goto abort; if (strcmp (argv[1], "rf") == 0) { double x, y, z; if (argc != 5) usage ("rf "); x = atof (argv[2]); y = atof (argv[3]); z = atof (argv[4]); printf ("rf(%f, %f, %f) = %."PREC"f\n", x, y, z, gsl_ellip_rf (x, y, z)); } else if (strcmp (argv[1], "F") == 0) { double phi, ak; if (argc != 4) usage ("F "); phi = atof (argv[2]); ak = atof (argv[3]); printf ("F(%f, %f) = %."PREC"f\n", phi, ak, gsl_ellip_F (phi, ak)); } else if (strcmp (argv[1], "sn") == 0) { double u, emmc; if (argc != 4) usage ("sn "); u = atof (argv[2]); emmc = atof (argv[3]); printf ("sn(%f, %f) = %."PREC"f\n", u, emmc, gsl_ellip_sn (u, emmc)); } else if (strcmp (argv[1], "snc") == 0) { GslComplex u, emmc; if (argc != 6) usage ("sn "); u.re = atof (argv[2]); u.im = atof (argv[3]); emmc.re = atof (argv[4]); emmc.im = atof (argv[5]); printf ("snc(%s, %s) = %s\n", gsl_complex_str (u), gsl_complex_str (emmc), gsl_complex_str (gsl_complex_ellip_sn (u, emmc))); } else if (strcmp (argv[1], "sci_snc") == 0) { GslComplex u, k2; if (argc != 6) usage ("sci_sn "); u.re = atof (argv[2]); u.im = atof (argv[3]); k2.re = atof (argv[4]); k2.im = atof (argv[5]); printf ("sci_snc(%s, %s) = %s\n", gsl_complex_str (u), gsl_complex_str (k2), gsl_complex_str (gsl_complex_ellip_sn (u, gsl_complex_sub (gsl_complex (1.0, 0), k2)))); } else if (strcmp (argv[1], "asn") == 0) { double y, emmc; if (argc != 4) usage ("asn "); y = atof (argv[2]); emmc = atof (argv[3]); printf ("asn(%f, %f) = %."PREC"f\n", y, emmc, gsl_ellip_asn (y, emmc)); } else if (strcmp (argv[1], "asnc") == 0) { GslComplex y, emmc; if (argc != 6) usage ("asnc "); y.re = atof (argv[2]); y.im = atof (argv[3]); emmc.re = atof (argv[4]); emmc.im = atof (argv[5]); printf ("asnc(%s, %s) = %s\n", gsl_complex_str (y), gsl_complex_str (emmc), gsl_complex_str (gsl_complex_ellip_asn (y, emmc))); printf ("asn(%f, %f = %."PREC"f\n", y.re, emmc.re, gsl_ellip_asn (y.re, emmc.re)); } else if (strcmp (argv[1], "sci_sn") == 0) { double u, k2; if (argc != 4) usage ("sci_sn "); u = atof (argv[2]); k2 = atof (argv[3]); printf ("sci_sn(%f, %f) = %."PREC"f\n", u, k2, gsl_ellip_sn (u, 1.0 - k2)); } else if (strcmp (argv[1], "sci_asn") == 0) { double y, k2; if (argc != 4) usage ("sci_asn "); y = atof (argv[2]); k2 = atof (argv[3]); printf ("sci_asn(%f, %f) = %."PREC"f\n", y, k2, gsl_ellip_asn (y, 1.0 - k2)); } else if (strcmp (argv[1], "sci_asnc") == 0) { GslComplex y, k2; if (argc != 6) usage ("sci_asnc "); y.re = atof (argv[2]); y.im = atof (argv[3]); k2.re = atof (argv[4]); k2.im = atof (argv[5]); printf ("sci_asnc(%s, %s) = %s\n", gsl_complex_str (y), gsl_complex_str (k2), gsl_complex_str (gsl_complex_ellip_asn (y, gsl_complex_sub (gsl_complex (1.0, 0), k2)))); printf ("asn(%f, %f = %."PREC"f\n", y.re, k2.re, gsl_ellip_asn (y.re, 1.0 - k2.re)); } else if (strcmp (argv[1], "sin") == 0) { GslComplex phi; if (argc != 4) usage ("sin "); phi.re = atof (argv[2]); phi.im = atof (argv[3]); printf ("sin(%s) = %s\n", gsl_complex_str (phi), gsl_complex_str (gsl_complex_sin (phi))); } else if (strcmp (argv[1], "cos") == 0) { GslComplex phi; if (argc != 4) usage ("cos "); phi.re = atof (argv[2]); phi.im = atof (argv[3]); printf ("cos(%s) = %s\n", gsl_complex_str (phi), gsl_complex_str (gsl_complex_cos (phi))); } else if (strcmp (argv[1], "tan") == 0) { GslComplex phi; if (argc != 4) usage ("tan "); phi.re = atof (argv[2]); phi.im = atof (argv[3]); printf ("tan(%s) = %s\n", gsl_complex_str (phi), gsl_complex_str (gsl_complex_tan (phi))); } else if (strcmp (argv[1], "sinh") == 0) { GslComplex phi; if (argc != 4) usage ("sinh "); phi.re = atof (argv[2]); phi.im = atof (argv[3]); printf ("sinh(%s) = %s\n", gsl_complex_str (phi), gsl_complex_str (gsl_complex_sinh (phi))); } else if (strcmp (argv[1], "cosh") == 0) { GslComplex phi; if (argc != 4) usage ("cosh "); phi.re = atof (argv[2]); phi.im = atof (argv[3]); printf ("cosh(%s) = %s\n", gsl_complex_str (phi), gsl_complex_str (gsl_complex_cosh (phi))); } else if (strcmp (argv[1], "tanh") == 0) { GslComplex phi; if (argc != 4) usage ("tanh "); phi.re = atof (argv[2]); phi.im = atof (argv[3]); printf ("tanh(%s) = %s\n", gsl_complex_str (phi), gsl_complex_str (gsl_complex_tanh (phi))); } else if (strcmp (argv[1], "t1") == 0) { guint order; double f, e; if (argc != 5) usage ("t1 "); order = atoi (argv[2]); f = atof (argv[3]); e = atof (argv[4]); f *= GSL_PI / 2.; e = gsl_trans_zepsilon2ss (e); { double a[order + 1], b[order + 1]; gsl_filter_tscheb1 (order, f, e, a, b); g_print ("# Tschebyscheff Type1 order=%u freq=%f s^2epsilon=%f norm0=%f:\n", order, f, e, gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1)); g_print ("H%u(z)=%s/%s\n", order, gsl_poly_str (order, a, "z"), gsl_poly_str (order, b, "z")); } } else if (strcmp (argv[1], "t2") == 0) { guint order; double fc, fr, e; if (argc != 6) usage ("t1 "); order = atoi (argv[2]); fc = atof (argv[3]); fr = atof (argv[4]); e = atof (argv[5]); fc *= GSL_PI / 2.; fr *= GSL_PI / 2.; e = gsl_trans_zepsilon2ss (e); { double a[order + 1], b[order + 1]; gsl_filter_tscheb2 (order, fc, fr, e, a, b); g_print ("# Tschebyscheff Type2 order=%u freq_c=%f freq_r=%f s^2epsilon=%f norm=%f:\n", order, fc, fr, e, gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1)); g_print ("H%u(z)=%s/%s\n", order, gsl_poly_str (order, a, "z"), gsl_poly_str (order, b, "z")); } } else if (strncmp (argv[1], "test", 4) == 0) { guint order; arg = argv[1] + 4; if (argc != argc) usage ("test"); order = 2; { double a[100] = { 1, 2, 1 }, b[100] = { 1, -3./2., 0.5 }; g_print ("# Test order=%u norm=%f:\n", order, gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1)); g_print ("H%u(z)=%s/%s\n", order, gsl_poly_str (order, a, "z"), gsl_poly_str (order, b, "z")); if (*arg) { GslComplex root, roots[100]; guint i; if (*arg == 'r') { g_print ("#roots:\n"); gsl_poly_complex_roots (order, a, roots); for (i = 0; i < order; i++) { root = gsl_complex_div (gsl_complex (1, 0), roots[i]); g_print ("%+.14f %+.14f # %.14f\n", root.re, root.im, gsl_complex_abs (root)); } } if (*arg == 'p') { g_print ("#poles:\n"); gsl_poly_complex_roots (order, b, roots); for (i = 0; i < order; i++) { root = gsl_complex_div (gsl_complex (1, 0), roots[i]); g_print ("%+.14f %+.14f # %.14f\n", root.re, root.im, gsl_complex_abs (root)); } } } } } else { abort: usage ("{rf|F|sn|snc|sci_sn|sci_snc|asn|asnc|sci_asn|sci_asnc|sin(h)|cos(h)|tan(h)|t1|t2} ..."); } return 0; }