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#include <stdio.h>
#include <getopt.h>
#include <stdlib.h>
#include <string.h>
#include "rsl.h"
int qprint_ray;
usage(char **argv)
{
fprintf(stderr,"Usage: %s [-v] [-f nexrad_id] [infile]\n", argv[0]);
exit(-1);
}
process_args(int argc, char **argv,
char **in_file, int *qprint_ray,
char **site)
{
int c;
while ((c = getopt(argc, argv, "vf:")) != -1)
switch (c) {
case 'v': *qprint_ray = 1; break;
case 'f': *site = strdup(optarg); break;
case '?': usage(argv); break;
default: break;
}
if ((argc-optind) == 0) {
*in_file = NULL;
} else if ((argc-optind) == 1) {
*in_file = strdup(argv[optind]);
} else {
usage(argv);
}
}
void print_ray_values(Ray *ray)
{
int i,j;
if (ray == NULL) {
printf("Ray = NULL\n");
return;
}
for (i=0; i<ray->h.nbins; i+=10) {
for (j=i; j<(i+10)&&j<ray->h.nbins; j++)
printf("%10.2f", ray->h.f(ray->range[j]));
printf("\n");
}
return;
}
void print_header_for_ray(Ray *ray)
{
if (ray==NULL) {printf("NULL."); return;}
printf(" month %d\n", ray->h.month); /* Time for this ray; month (1-12). */
printf(" day %d\n", ray->h.day); /* Time for this ray; day (1-31). */
printf(" year %d\n", ray->h.year); /* Time for this ray; year (eg. 1993). */
printf(" hour %d\n", ray->h.hour); /* Date for this ray; hour (0-23). */
printf(" minute %d\n", ray->h.minute);/* Date for this ray; minute (0-59).*/
printf(" sec %f\n", ray->h.sec); /* Date for this ray; second + fraction of second. */
printf(" unam %f\n", ray->h.unam_rng); /* Unambiguous range. (KM). */
printf(" azimuth %f\n", ray->h.azimuth); /* Azimuth angle. (degrees). 0=North, 90=east, -90=west. */
printf(" ray_num %d\n", ray->h.ray_num); /* Ray no. within elevation scan. */
printf(" elev %f\n", ray->h.elev); /* Elevation angle. (degrees). */
printf("elev_num %d\n", ray->h.elev_num); /* Elevation no. within volume scan. */
printf(" range_bin1 %d\n", ray->h.range_bin1); /* Range to first gate.(meters) */
printf(" gate_size %d\n", ray->h.gate_size); /* Data gate size (meters)*/
printf(" vel_res %f\n", ray->h.vel_res); /* Doppler velocity resolution */
printf(" sweep_rate %f\n", ray->h.sweep_rate); /* Sweep rate. Full sweeps/min. */
printf(" prf %d\n", ray->h.prf); /* Pulse repitition frequency, in Hz. */
printf(" azim_rate %f\n", ray->h.azim_rate);
printf(" fix_angle %f\n", ray->h.fix_angle);
printf("pulse_count %d\n", ray->h.pulse_count);
printf("pulse_width %f\n", ray->h.pulse_width); /* Pulse width (micro-sec). */
printf(" beam_width %f\n", ray->h.beam_width); /* Beamwidth in degrees. */
printf(" frequency %f\n", ray->h.frequency); /* Bandwidth MHz. */
printf(" wavelength %f\n", ray->h.wavelength); /* Wavelength. Meters. */
printf(" nyq_vel %f\n", ray->h.nyq_vel); /* Nyquist velocity. m/s */
printf(" latitude %f\n", ray->h.lat); /* Latitude (decimal) */
printf(" longitude %f\n", ray->h.lon); /* Longitude (decimal) */
printf(" nbins %d\n", ray->h.nbins); /* Number of array elements for 'Range'. */
if (!qprint_ray) return;
print_ray_values(ray);
}
void print_header_for_sweep(Sweep *s)
{
int i;
if (s==NULL) return;
for (i=0; i<s->h.nrays; i++) {
printf("ray[%d] ",i );
print_header_for_ray(s->ray[i]);
printf("\n");
}
}
void print_header_for_volume(Volume *v)
{
int i;
if (v==NULL) return;
for (i=0; i<v->h.nsweeps; i++) {
printf("-------- Sweep %d ---------\n", i);
print_header_for_sweep(v->sweep[i]);
}
}
main(int argc, char **argv)
{
char *infile;
Radar *radar;
char *site = NULL;
int i;
qprint_ray = 0; /* Global flag for printing ray values. */
process_args(argc, argv, &infile, &qprint_ray, &site); /* malloc for in/outfile */
RSL_radar_verbose_on();
RSL_read_these_sweeps("all", NULL);
radar = RSL_anyformat_to_radar(infile, site);
printf("Radar date: %2.2d/%2.2d/%2.2d\n", radar->h.month, radar->h.day, radar->h.year);
printf("Radar time: %2.2d:%2.2d:%f\n", radar->h.hour, radar->h.minute, radar->h.sec);
printf("Radar file: %s\n", infile);
printf("Radar site: %c%c%c%c\n",
radar->h.name[0],
radar->h.name[1],
radar->h.name[2],
radar->h.name[3]);
printf("Radar date: %2.2d/%2.2d/%2.2d\n", radar->h.month, radar->h.day, radar->h.year);
printf("Radar time: %2.2d:%2.2d:%f\n", radar->h.hour, radar->h.minute, radar->h.sec);
printf("Radar sec : %f\n", radar->h.sec); /* Second plus fractional part. */
printf("Radar radar_type: %s\n", radar->h.radar_type);
/* Type of radar. Use for QC-ing the data.
* Supported types are:
* "wsr88d", "lassen", "uf",
* "nsig", "mcgill",
* "kwajalein", "rsl", "toga".
* Set by appropriate ingest routine.
*/
printf("Radar nvolumes : %d\n", radar->h.nvolumes);
printf("Radar number : %d\n", radar->h.number);
printf("Radar name : %s\n", radar->h.name);
printf("Radar radar_name: %s\n", radar->h.radar_name);
printf("Radar city : %s\n", radar->h.city);
printf("Radar state : %s\n", radar->h.state);
printf("Radar latd: %d\n", radar->h.latd);
printf("Radar latm: %d\n", radar->h.latm);
printf("Radar lats: %d\n", radar->h.lats);
printf("Radar lond: %d\n", radar->h.lond);
printf("Radar lonm: %d\n", radar->h.lonm);
printf("Radar lons: %d\n", radar->h.lons);
printf("Radar height: %d\n", radar->h.height);
printf("Radar spulse: %d\n", radar->h.spulse);
printf("Radar lpulse: %d\n", radar->h.lpulse);
printf("Radar lpulse: %d\n", radar->h.lpulse);
for (i=0; i<radar->h.nvolumes; i++) {
if (radar->v[i]) {
printf("PRINT_HEADER_FOR_VOLUME, %d, ... nsweeps = %d\n", i, radar->v[i]->h.nsweeps);
print_header_for_volume(radar->v[i]);
}
}
exit(0);
}
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