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647 lines
20 KiB
647 lines
20 KiB
/* GSL - Generic Sound Layer
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* Copyright (C) 2001-2002 Tim Janik and Stefan Westerfeld
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Lesser General Public
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* License as published by the Free Software Foundation; either
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* version 2 of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU Lesser General
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* Public License along with this program; if not, write to the
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* Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
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* Boston, MA 02110-1301, USA.
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*/
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#include <gsl/gslmath.h>
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#include <gsl/gslcommon.h>
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#include <gsl/gslmath.h>
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#include <gsl/gslfilter.h>
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#include <gsl/gslloader.h>
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#include <stdlib.h>
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#include <string.h>
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#define PREC "15"
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static void usage (void) G_GNUC_NORETURN;
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static guint shift_argc = 0;
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static const gchar **shift_argv = NULL;
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static const gchar*
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shift (void)
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{
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const gchar *arg;
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if (shift_argc > 1)
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{
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shift_argc--;
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arg = shift_argv++[1];
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if (!arg)
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arg = "";
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}
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else
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arg = NULL;
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return arg;
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}
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static const gchar*
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pshift (void)
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{
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const gchar *arg = shift ();
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return arg ? arg : "";
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}
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int
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main (int argc,
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char *argv[])
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{
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const gchar *arg;
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/* iir filter parameters */
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enum { FILTER_GNUPLOT, FILTER_SCAN } filter_mode = FILTER_GNUPLOT;
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const gchar *filter_label = 0;
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gdouble *a, *b;
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guint order = 0;
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shift_argc = argc;
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shift_argv = (gchar **)argv;
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if (!g_thread_supported ())
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g_thread_init (NULL);
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gsl_init (NULL, NULL);
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arg = shift ();
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if (!arg)
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usage ();
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restart:
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a = b = 0;
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if (strcmp (arg, "wave-scan") == 0)
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{
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const gchar *file = pshift ();
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while (file)
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{
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GslWaveFileInfo *fi;
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GslErrorType error;
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fi = gsl_wave_file_info_load (file, &error);
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if (fi)
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{
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guint i;
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g_print ("Loader \"%s\" found %u waves in \"%s\":\n", fi->loader->name, fi->n_waves, file);
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for (i = 0; i < fi->n_waves; i++)
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g_print ("%u) %s\n", i + 1, fi->waves[i].name);
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gsl_wave_file_info_unref (fi);
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}
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else
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g_print ("Failed to scan \"%s\": %s\n", file, gsl_strerror (error));
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file = pshift ();
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if (!file[0])
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break;
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}
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}
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else if (strcmp (arg, "file-test") == 0)
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{
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const gchar *file = pshift ();
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g_print ("file test for \"%s\":\n", file);
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g_print (" is readable : %s\n", gsl_strerror (gsl_check_file (file, "r")));
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g_print (" is writable : %s\n", gsl_strerror (gsl_check_file (file, "w")));
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g_print (" is executable : %s\n", gsl_strerror (gsl_check_file (file, "x")));
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g_print (" is file : %s\n", gsl_strerror (gsl_check_file (file, "f")));
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g_print (" is directory : %s\n", gsl_strerror (gsl_check_file (file, "d")));
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g_print (" is link : %s\n", gsl_strerror (gsl_check_file (file, "l")));
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}
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else if (strcmp (arg, "rf") == 0)
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{
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double x, y, z;
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x = atof (pshift ());
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y = atof (pshift ());
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z = atof (pshift ());
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g_print ("rf(%f, %f, %f) = %."PREC"f\n", x, y, z, gsl_ellip_rf (x, y, z));
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}
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else if (strcmp (arg, "F") == 0)
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{
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double phi, ak;
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phi = atof (pshift ());
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ak = atof (pshift ());
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g_print ("F(%f, %f) = %."PREC"f\n", phi, ak, gsl_ellip_F (phi, ak));
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}
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else if (strcmp (arg, "sn") == 0)
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{
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double u, emmc;
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u = atof (pshift ());
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emmc = atof (pshift ());
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g_print ("sn(%f, %f) = %."PREC"f\n", u, emmc, gsl_ellip_sn (u, emmc));
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}
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else if (strcmp (arg, "snc") == 0)
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{
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GslComplex u, emmc;
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u.re = atof (pshift ());
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u.im = atof (pshift ());
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emmc.re = atof (pshift ());
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emmc.im = atof (pshift ());
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g_print ("snc(%s, %s) = %s\n",
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gsl_complex_str (u),
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gsl_complex_str (emmc),
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gsl_complex_str (gsl_complex_ellip_sn (u, emmc)));
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}
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else if (strcmp (arg, "sci_snc") == 0)
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{
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GslComplex u, k2;
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u.re = atof (pshift ());
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u.im = atof (pshift ());
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k2.re = atof (pshift ());
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k2.im = atof (pshift ());
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g_print ("sci_snc(%s, %s) = %s\n",
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gsl_complex_str (u),
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gsl_complex_str (k2),
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gsl_complex_str (gsl_complex_ellip_sn (u, gsl_complex_sub (gsl_complex (1.0, 0), k2))));
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}
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else if (strcmp (arg, "asn") == 0)
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{
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double y, emmc;
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y = atof (pshift ());
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emmc = atof (pshift ());
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g_print ("asn(%f, %f) = %."PREC"f\n", y, emmc, gsl_ellip_asn (y, emmc));
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}
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else if (strcmp (arg, "asnc") == 0)
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{
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GslComplex y, emmc;
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y.re = atof (pshift ());
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y.im = atof (pshift ());
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emmc.re = atof (pshift ());
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emmc.im = atof (pshift ());
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g_print ("asnc(%s, %s) = %s\n",
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gsl_complex_str (y), gsl_complex_str (emmc),
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gsl_complex_str (gsl_complex_ellip_asn (y, emmc)));
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g_print ("asn(%f, %f = %."PREC"f\n",
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y.re, emmc.re, gsl_ellip_asn (y.re, emmc.re));
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}
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else if (strcmp (arg, "sci_sn") == 0)
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{
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double u, k2;
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u = atof (pshift ());
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k2 = atof (pshift ());
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g_print ("sci_sn(%f, %f) = %."PREC"f\n", u, k2, gsl_ellip_sn (u, 1.0 - k2));
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}
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else if (strcmp (arg, "sci_asn") == 0)
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{
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double y, k2;
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y = atof (pshift ());
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k2 = atof (pshift ());
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g_print ("sci_asn(%f, %f) = %."PREC"f\n", y, k2, gsl_ellip_asn (y, 1.0 - k2));
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}
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else if (strcmp (arg, "sci_asnc") == 0)
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{
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GslComplex y, k2;
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y.re = atof (pshift ());
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y.im = atof (pshift ());
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k2.re = atof (pshift ());
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k2.im = atof (pshift ());
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g_print ("sci_asnc(%s, %s) = %s\n",
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gsl_complex_str (y), gsl_complex_str (k2),
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gsl_complex_str (gsl_complex_ellip_asn (y, gsl_complex_sub (gsl_complex (1.0, 0), k2))));
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g_print ("asn(%f, %f = %."PREC"f\n",
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y.re, k2.re, gsl_ellip_asn (y.re, 1.0 - k2.re));
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}
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else if (strcmp (arg, "sin") == 0)
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{
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GslComplex phi;
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phi.re = atof (pshift ());
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phi.im = atof (pshift ());
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g_print ("sin(%s) = %s\n",
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gsl_complex_str (phi),
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gsl_complex_str (gsl_complex_sin (phi)));
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}
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else if (strcmp (arg, "cos") == 0)
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{
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GslComplex phi;
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phi.re = atof (pshift ());
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phi.im = atof (pshift ());
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g_print ("cos(%s) = %s\n",
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gsl_complex_str (phi),
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gsl_complex_str (gsl_complex_cos (phi)));
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}
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else if (strcmp (arg, "tan") == 0)
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{
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GslComplex phi;
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phi.re = atof (pshift ());
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phi.im = atof (pshift ());
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g_print ("tan(%s) = %s\n",
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gsl_complex_str (phi),
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gsl_complex_str (gsl_complex_tan (phi)));
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}
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else if (strcmp (arg, "sinh") == 0)
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{
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GslComplex phi;
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phi.re = atof (pshift ());
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phi.im = atof (pshift ());
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g_print ("sinh(%s) = %s\n",
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gsl_complex_str (phi),
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gsl_complex_str (gsl_complex_sinh (phi)));
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}
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else if (strcmp (arg, "cosh") == 0)
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{
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GslComplex phi;
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phi.re = atof (pshift ());
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phi.im = atof (pshift ());
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g_print ("cosh(%s) = %s\n",
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gsl_complex_str (phi),
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gsl_complex_str (gsl_complex_cosh (phi)));
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}
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else if (strcmp (arg, "tanh") == 0)
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{
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GslComplex phi;
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phi.re = atof (pshift ());
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phi.im = atof (pshift ());
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g_print ("tanh(%s) = %s\n",
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gsl_complex_str (phi),
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gsl_complex_str (gsl_complex_tanh (phi)));
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}
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else if (strcmp (arg, "midi2freq") == 0)
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{
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gint note;
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note = atol (pshift ());
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note = CLAMP (note, 0, 128);
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g_print ("midi2freq(%u) = %f\n",
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note,
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gsl_temp_freq (gsl_get_config ()->kammer_freq,
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note - gsl_get_config ()->midi_kammer_note));
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}
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else if (strcmp (arg, "blp") == 0)
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{
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double f, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f = atof (pshift ());
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e = atof (pshift ());
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f *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_butter_lp (order, f, e, a, b);
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g_print ("# Lowpass Butterworth filter order=%u freq=%f epsilon(s^2)=%f norm0=%f:\n",
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order, f, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "BL";
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}
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else if (strcmp (arg, "bhp") == 0)
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{
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double f, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f = atof (pshift ());
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e = atof (pshift ());
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f *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_butter_hp (order, f, e, a, b);
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g_print ("# Highpass Butterworth filter order=%u freq=%f epsilon(s^2)=%f norm0=%f:\n",
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order, f, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "BH";
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}
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else if (strcmp (arg, "bbp") == 0)
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{
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double f1, f2, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f1 = atof (pshift ());
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f2 = atof (pshift ());
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e = atof (pshift ());
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f1 *= GSL_PI / 2.;
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f2 *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_butter_bp (order, f1, f2, e, a, b);
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g_print ("# Bandpass Butterworth filter order=%u freq1=%f freq2=%f epsilon(s^2)=%f norm0=%f:\n",
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order, f1, f2, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "BP";
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}
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else if (strcmp (arg, "bbs") == 0)
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{
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double f1, f2, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f1 = atof (pshift ());
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f2 = atof (pshift ());
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e = atof (pshift ());
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f1 *= GSL_PI / 2.;
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f2 *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_butter_bs (order, f1, f2, e, a, b);
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g_print ("# Bandstop Butterworth filter order=%u freq1=%f freq2=%f epsilon(s^2)=%f norm0=%f:\n",
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order, f1, f2, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "BS";
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}
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else if (strcmp (arg, "t1l") == 0)
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{
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double f, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f = atof (pshift ());
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e = atof (pshift ());
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f *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_tscheb1_lp (order, f, e, a, b);
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g_print ("# Lowpass Tschebyscheff Type1 order=%u freq=%f epsilon(s^2)=%f norm0=%f:\n",
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order, f, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "T1L";
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}
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else if (strcmp (arg, "t1h") == 0)
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{
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double f, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f = atof (pshift ());
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e = atof (pshift ());
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f *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_tscheb1_hp (order, f, e, a, b);
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g_print ("# Highpass Tschebyscheff Type1 order=%u freq=%f epsilon(s^2)=%f norm0=%f:\n",
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order, f, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "T1H";
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}
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else if (strcmp (arg, "t1s") == 0)
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{
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double fc, fr, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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fc = atof (pshift ());
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fr = atof (pshift ());
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e = atof (pshift ());
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fc *= GSL_PI / 2.;
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fr *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_tscheb1_bs (order, fc, fr, e, a, b);
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g_print ("# Bandstop Tschebyscheff Type1 order=%u freq_c=%f freq_r=%f epsilon(s^2)=%f norm=%f:\n",
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order, fc, fr, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "T1S";
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}
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else if (strcmp (arg, "t1p") == 0)
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{
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double fc, fr, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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fc = atof (pshift ());
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fr = atof (pshift ());
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e = atof (pshift ());
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fc *= GSL_PI / 2.;
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fr *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_tscheb1_bp (order, fc, fr, e, a, b);
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g_print ("# Bandpass Tschebyscheff Type1 order=%u freq_c=%f freq_r=%f epsilon(s^2)=%f norm=%f:\n",
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order, fc, fr, e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "T1P";
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}
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else if (strcmp (arg, "t2l") == 0)
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{
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double f, st, e;
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order = atoi (pshift ()); order = MAX (order, 1);
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f = atof (pshift ());
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st = atof (pshift ());
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e = atof (pshift ());
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f *= GSL_PI / 2.;
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a = g_new (gdouble, order + 1);
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b = g_new (gdouble, order + 1);
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gsl_filter_tscheb2_lp (order, f, st, e, a, b);
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g_print ("# Lowpass Tschebyscheff Type2 order=%u freq=%f steepness=%f (%f) epsilon(s^2)=%f norm=%f:\n",
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order, f, st, f * (1.+st), e,
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gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
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filter_label = "T2L";
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}
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else if (strcmp (arg, "t2h") == 0)
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{
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double f, st, e;
|
|
order = atoi (pshift ()); order = MAX (order, 1);
|
|
f = atof (pshift ());
|
|
st = atof (pshift ());
|
|
e = atof (pshift ());
|
|
f *= GSL_PI / 2.;
|
|
|
|
a = g_new (gdouble, order + 1);
|
|
b = g_new (gdouble, order + 1);
|
|
|
|
gsl_filter_tscheb2_hp (order, f, st, e, a, b);
|
|
g_print ("# Highpass Tschebyscheff Type2 order=%u freq=%f steepness=%f (%f, %f) epsilon(s^2)=%f norm=%f:\n",
|
|
order, f, st, GSL_PI - f, (GSL_PI - f) * (1.+st), e,
|
|
gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
|
|
filter_label = "T2H";
|
|
}
|
|
else if (strcmp (arg, "t2p") == 0)
|
|
{
|
|
double f1, f2, st, e;
|
|
order = atoi (pshift ()); order = MAX (order, 1);
|
|
f1 = atof (pshift ());
|
|
f2 = atof (pshift ());
|
|
st = atof (pshift ());
|
|
e = atof (pshift ());
|
|
f1 *= GSL_PI / 2.;
|
|
f2 *= GSL_PI / 2.;
|
|
|
|
a = g_new (gdouble, order + 1);
|
|
b = g_new (gdouble, order + 1);
|
|
|
|
gsl_filter_tscheb2_bp (order, f1, f2, st, e, a, b);
|
|
g_print ("# Bandpass Tschebyscheff Type2 order=%u freq1=%f freq2=%f steepness=%f epsilon(s^2)=%f norm=%f:\n",
|
|
order, f1, f2, st, e,
|
|
gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
|
|
filter_label = "T2P";
|
|
}
|
|
else if (strcmp (arg, "t2s") == 0)
|
|
{
|
|
double f1, f2, st, e;
|
|
order = atoi (pshift ()); order = MAX (order, 1);
|
|
f1 = atof (pshift ());
|
|
f2 = atof (pshift ());
|
|
st = atof (pshift ());
|
|
e = atof (pshift ());
|
|
f1 *= GSL_PI / 2.;
|
|
f2 *= GSL_PI / 2.;
|
|
|
|
a = g_new (gdouble, order + 1);
|
|
b = g_new (gdouble, order + 1);
|
|
|
|
gsl_filter_tscheb2_bs (order, f1, f2, st, e, a, b);
|
|
g_print ("# Bandstop Tschebyscheff Type2 order=%u freq1=%f freq2=%f steepness=%f epsilon(s^2)=%f norm=%f:\n",
|
|
order, f1, f2, st, e,
|
|
gsl_poly_eval (order, a, 1) / gsl_poly_eval (order, b, 1));
|
|
filter_label = "T2S";
|
|
}
|
|
else if (strcmp (arg, "scan") == 0)
|
|
{
|
|
filter_mode = FILTER_SCAN;
|
|
}
|
|
else if (strcmp (arg, "fir") == 0)
|
|
{
|
|
unsigned int iorder = atoi (pshift ());
|
|
unsigned int n_points = 0;
|
|
|
|
double *freq = g_newa (double, argc / 2 + 1);
|
|
double *value = g_newa (double, argc / 2 + 1);
|
|
double *a = g_newa (double, iorder);
|
|
const char *f, *v;
|
|
|
|
do
|
|
{
|
|
f = pshift ();
|
|
v = pshift ();
|
|
|
|
if (f[0] && v[0])
|
|
{
|
|
freq[n_points] = atof (f) * GSL_PI;
|
|
value[n_points] = atof (v);
|
|
n_points++;
|
|
}
|
|
}
|
|
while (f[0] && v[0]);
|
|
|
|
gsl_filter_fir_approx (iorder, a, n_points, freq, value);
|
|
g_print ("FIR%u(z)=%s\n", iorder, gsl_poly_str (iorder, a, "z"));
|
|
}
|
|
else if (strncmp (arg, "poly", 4) == 0)
|
|
{
|
|
guint order;
|
|
arg = arg + 4;
|
|
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
|
|
usage ();
|
|
|
|
if (a && b)
|
|
{
|
|
gdouble freq;
|
|
|
|
if (filter_mode == FILTER_SCAN)
|
|
{
|
|
freq = 0.001;
|
|
while (freq < 3.14)
|
|
{
|
|
g_print ("%f %.20f\n", freq, gsl_filter_sine_scan (order, a, b, freq, MAX((int)(1000.0/freq),10000)));
|
|
freq = MIN (freq * 1.1, freq + 0.01);
|
|
}
|
|
}
|
|
else if (filter_mode == FILTER_GNUPLOT)
|
|
{
|
|
g_print ("%s%u(z)=%s/%s\n", filter_label, order,
|
|
gsl_poly_str (order, a, "z"),
|
|
gsl_poly_str (order, b, "z"));
|
|
}
|
|
else
|
|
g_error ("unknown filter_mode");
|
|
g_free (a);
|
|
g_free (b);
|
|
}
|
|
|
|
arg = shift ();
|
|
if (arg)
|
|
goto restart;
|
|
|
|
return 0;
|
|
}
|
|
|
|
static void
|
|
usage (void)
|
|
{
|
|
g_print ("usage: gsltests {test} [args...]\n");
|
|
g_print ("tests:\n");
|
|
g_print (" wave-scan <file> scan a wave file for waves\n");
|
|
g_print (" file-test <file> test file properties\n");
|
|
g_print (" rf <x> <y> <z> Carlson's elliptic integral of the first kind\n");
|
|
g_print (" F <phi> <ak> Legendre elliptic integral of the 1st kind\n");
|
|
g_print (" sn <u> <emmc> Jacobian elliptic function sn()\n");
|
|
g_print (" asn <y> <emmc> elliptic integral, inverse sn()\n");
|
|
g_print (" sin <phi.re> <phi.im> complex sine\n");
|
|
g_print (" cos <phi.re> <phi.im> complex cosine\n");
|
|
g_print (" tan <phi.re> <phi.im> complex tangent\n");
|
|
g_print (" sinh <phi.re> <phi.im> complex hyperbolic sine\n");
|
|
g_print (" cosh <phi.re> <phi.im> complex hyperbolic cosine\n");
|
|
g_print (" tanh <phi.re> <phi.im> complex hyperbolic tangent\n");
|
|
g_print (" midi2freq <midinote> convert midinote into oscilaltor frequency\n");
|
|
g_print (" snc <u.re> <u.im> <emmc.re> <emmc.im> sn() for complex numbers\n");
|
|
g_print (" asnc <y.re> <y.im> <emmc.re> <emmc.im> asn() for complex numbers\n");
|
|
g_print (" sci_sn <u> <k2> scilab version of sn()\n");
|
|
g_print (" sci_asn <y> <k2> scilab version of asn()\n");
|
|
g_print (" sci_snc <u.re> <u.im> <k2.re> <k2.im> scilab version of snc()\n");
|
|
g_print (" sci_asnc <y.re> <y.im> <k2.re> <k2.im> scilab version of asnc()\n");
|
|
g_print (" blp <order> <freq> <epsilon> butterworth lowpass filter\n");
|
|
g_print (" bhp <order> <freq> <epsilon> butterworth higpass filter\n");
|
|
g_print (" bbp <order> <freqc> <freqr> <epsilon> butterworth bandpass filter\n");
|
|
g_print (" t1l <order> <freq> <epsilon> type1 tschebyscheff lowpass filter\n");
|
|
g_print (" t1h <order> <freq> <epsilon> type1 tschebyscheff highpass filter\n");
|
|
g_print (" t1s <order> <freqc> <freqr> <epsilon> type1 tschebyscheff bandstop filter\n");
|
|
g_print (" t1p <order> <freqc> <freqr> <epsilon> type1 tschebyscheff bandpass filter\n");
|
|
g_print (" t2l <order> <freqc> <steepn> <epsilon> type2 tschebyscheff lowpass filter\n");
|
|
g_print (" t2h <order> <freqc> <steepn> <epsilon> type2 tschebyscheff highpass filter\n");
|
|
g_print (" fir <order> <freq1> <value1> ... fir approximation\n");
|
|
g_print (" scan blp <order> <freq> <epsilon> scan butterworth lowpass filter\n");
|
|
g_print (" poly | polyr | polyp polynom test (+roots or +poles)\n");
|
|
exit (1);
|
|
}
|