int main(int argc, char *argv[]) {
/* Cmd line */
static struct option long_opts[] = {
{"output", 1, NULL, 'o'},
{"npulse", 1, NULL, 'n'},
{"nbin", 1, NULL, 'b'},
{"nthread", 1, NULL, 'j'},
{"initial", 1, NULL, 'i'},
{"final", 1, NULL, 'f'},
{"time", 1, NULL, 'T'},
{"length", 1, NULL, 'L'},
{"src", 1, NULL, 's'},
{"polyco", 1, NULL, 'p'},
{"parfile", 1, NULL, 'P'},
{"foldfreq",1, NULL, 'F'},
{"cal", 0, NULL, 'C'},
{"unsigned",0, NULL, 'u'},
{"quiet", 0, NULL, 'q'},
{"help", 0, NULL, 'h'},
{0,0,0,0}
};
int opt, opti;
int nbin=256, nthread=4, fnum_start=1, fnum_end=0;
int quiet=0, raw_signed=1, use_polycos=1, cal=0;
int npulse_per_file = 64;
double start_time=0.0, process_time=0.0;
double fold_frequency=0.0;
char output_base[256] = "";
char polyco_file[256] = "";
char par_file[256] = "";
char source[24]; source[0]='\0';
while ((opt=getopt_long(argc,argv,"o:n:b:j:i:f:T:L:s:p:P:F:Cuqh",long_opts,&opti))!=-1) {
switch (opt) {
case 'o':
strncpy(output_base, optarg, 255);
output_base[255]='\0';
break;
case 'n':
npulse_per_file = atoi(optarg);
break;
case 'b':
nbin = atoi(optarg);
break;
case 'j':
nthread = atoi(optarg);
break;
case 'i':
fnum_start = atoi(optarg);
break;
case 'f':
fnum_end = atoi(optarg);
break;
case 'T':
start_time = atof(optarg);
break;
case 'L':
process_time = atof(optarg);
break;
case 's':
strncpy(source, optarg, 24);
source[23]='\0';
break;
case 'p':
strncpy(polyco_file, optarg, 255);
polyco_file[255]='\0';
use_polycos = 1;
break;
case 'P':
strncpy(par_file, optarg, 255);
par_file[255] = '\0';
break;
case 'F':
fold_frequency = atof(optarg);
use_polycos = 0;
break;
case 'C':
cal = 1;
use_polycos = 0;
break;
case 'u':
raw_signed=0;
break;
case 'q':
quiet=1;
break;
case 'h':
default:
usage();
exit(0);
break;
}
}
if (optind==argc) {
usage();
exit(1);
}
/* If no polyco/par file given, default to polyco.dat */
if (use_polycos && (par_file[0]=='\0' && polyco_file[0]=='\0'))
sprintf(polyco_file, "polyco.dat");
/* Open first file */
struct psrfits pf;
strcpy(pf.basefilename, argv[optind]);
pf.filenum = fnum_start;
pf.tot_rows = pf.N = pf.T = pf.status = 0;
pf.hdr.chan_dm = 0.0; // What if folding data that has been partially de-dispersed?
pf.filename[0]='\0';
int rv = psrfits_open(&pf);
if (rv) { fits_report_error(stderr, rv); exit(1); }
/* Check any constraints */
if (pf.hdr.nbits!=8) {
fprintf(stderr, "Only implemented for 8-bit data (read nbits=%d).\n",
pf.hdr.nbits);
exit(1);
}
/* Check for calfreq */
if (cal) {
if (pf.hdr.cal_freq==0.0) {
if (fold_frequency==0.0) {
fprintf(stderr, "Error: Cal mode selected, but CAL_FREQ=0. "
"Set cal frequency with -F\n");
exit(1);
} else {
pf.hdr.cal_freq = fold_frequency;
}
} else {
fold_frequency = pf.hdr.cal_freq;
}
}
/* Set up output file */
struct psrfits pf_out;
memcpy(&pf_out, &pf, sizeof(struct psrfits));
if (source[0]!='\0') { strncpy(pf_out.hdr.source, source, 24); }
else { strncpy(source, pf.hdr.source, 24); source[23]='\0'; }
if (output_base[0]=='\0') {
/* Set up default output filename */
if (start_time>0.0)
sprintf(output_base, "%s_SP_%s_%5.5d_%5.5d_%4.4d_%3.3d%s",
pf_out.hdr.backend,
pf_out.hdr.source, pf_out.hdr.start_day,
(int)pf_out.hdr.start_sec, fnum_start,
(int)start_time,
cal ? "_cal" : "");
else
sprintf(output_base, "%s_SP_%s_%5.5d_%5.5d%s", pf_out.hdr.backend,
pf_out.hdr.source, pf_out.hdr.start_day,
(int)pf_out.hdr.start_sec, cal ? "_cal" : "");
}
strcpy(pf_out.basefilename, output_base);
if (cal) {
sprintf(pf_out.hdr.obs_mode, "CAL");
sprintf(pf_out.hdr.cal_mode, "SYNC");
} else
sprintf(pf_out.hdr.obs_mode, "PSR");
strncpy(pf_out.fold.parfile,par_file,255); pf_out.fold.parfile[255]='\0';
pf_out.fptr = NULL;
pf_out.filenum=0;
pf_out.status=0;
pf_out.hdr.nbin=nbin;
pf_out.sub.FITS_typecode = TFLOAT;
pf_out.sub.bytes_per_subint = sizeof(float) *
pf_out.hdr.nchan * pf_out.hdr.npol * pf_out.hdr.nbin;
pf_out.multifile = 1;
pf_out.quiet = 1;
pf_out.rows_per_file = npulse_per_file;
rv = psrfits_create(&pf_out);
if (rv) { fits_report_error(stderr, rv); exit(1); }
/* Alloc data buffers */
pf.sub.dat_freqs = (float *)malloc(sizeof(float) * pf.hdr.nchan);
pf_out.sub.dat_freqs = pf.sub.dat_freqs;
pf.sub.dat_weights = (float *)malloc(sizeof(float) * pf.hdr.nchan);
pf_out.sub.dat_weights = (float *)malloc(sizeof(float) * pf.hdr.nchan);
pf.sub.dat_offsets = (float *)malloc(sizeof(float)
* pf.hdr.nchan * pf.hdr.npol);
pf_out.sub.dat_offsets = (float *)malloc(sizeof(float)
* pf.hdr.nchan * pf.hdr.npol);
pf.sub.dat_scales = (float *)malloc(sizeof(float)
* pf.hdr.nchan * pf.hdr.npol);
pf_out.sub.dat_scales = (float *)malloc(sizeof(float)
* pf.hdr.nchan * pf.hdr.npol);
pf_out.sub.data = (unsigned char *)malloc(pf_out.sub.bytes_per_subint);
/* Output scale/offset */
int i, j, ipol, ichan;
float offset_uv=0.0;
// Extra cross-term offset for GUPPI
if (strcmp("GUPPI",pf.hdr.backend)==0) {
offset_uv=0.5;
fprintf(stderr, "Found backend=GUPPI, setting offset_uv=%f\n",
offset_uv);
}
// TODO: copy these from the input file
for (ipol=0; ipol<pf.hdr.npol; ipol++) {
for (ichan=0; ichan<pf.hdr.nchan; ichan++) {
float offs = 0.0;
if (ipol>1) offs = offset_uv;
pf_out.sub.dat_scales[ipol*pf.hdr.nchan + ichan] = 1.0;
pf_out.sub.dat_offsets[ipol*pf.hdr.nchan + ichan] = offs;
}
}
for (i=0; i<pf.hdr.nchan; i++) { pf_out.sub.dat_weights[i]=1.0; }
/* Read or make polycos */
int npc=0, ipc=0;
struct polyco *pc = NULL;
if (use_polycos) {
if (polyco_file[0]=='\0') {
/* Generate from par file */
npc = make_polycos(par_file, &pf.hdr, source, &pc);
if (npc<=0) {
fprintf(stderr, "Error generating polycos.\n");
exit(1);
}
printf("Auto-generated %d polycos, src=%s\n", npc, source);
} else {
/* Read from polyco file */
FILE *pcfile = fopen(polyco_file, "r");
if (pcfile==NULL) {
fprintf(stderr, "Couldn't open polyco file.\n");
exit(1);
}
npc = read_all_pc(pcfile, &pc);
if (npc==0) {
fprintf(stderr, "Error parsing polyco file.\n");
exit(1);
}
fclose(pcfile);
}
} else {
// Const fold period mode, generate a fake polyco?
pc = (struct polyco *)malloc(sizeof(struct polyco));
sprintf(pc[0].psr, "CONST");
pc[0].mjd = (int)pf.hdr.MJD_epoch;
pc[0].fmjd = fmod(pf.hdr.MJD_epoch,1.0);
pc[0].rphase = 0.0;
pc[0].f0 = fold_frequency;
pc[0].nsite = 0; // Does this matter?
pc[0].nmin = 24 * 60;
pc[0].nc = 1;
pc[0].rf = pf.hdr.fctr;
pc[0].c[0] = 0.0;
pc[0].used = 0;
npc = 1;
}
int *pc_written = (int *)malloc(sizeof(int) * npc);
for (i=0; i<npc; i++) pc_written[i]=0;
/* Set up fold buf */
struct foldbuf fb;
fb.nchan = pf.hdr.nchan;
fb.npol = pf.hdr.npol;
fb.nbin = pf_out.hdr.nbin;
malloc_foldbuf(&fb);
clear_foldbuf(&fb);
struct fold_args fargs;
fargs.data = (char *)malloc(sizeof(char)*pf.sub.bytes_per_subint);
fargs.fb = &fb;
fargs.nsamp = 1;
fargs.tsamp = pf.hdr.dt;
fargs.raw_signed = raw_signed;
/* Main loop */
rv=0;
int imjd;
double fmjd, fmjd0=0, fmjd_samp, fmjd_epoch;
long long cur_pulse=0, last_pulse=0;
double psr_freq=0.0;
int first_loop=1, first_data=1, sampcount=0, last_filenum=0;
int bytes_per_sample = pf.hdr.nchan * pf.hdr.npol;
signal(SIGINT, cc);
while (run) {
/* Read data block */
pf.sub.data = (unsigned char *)fargs.data;
rv = psrfits_read_subint(&pf);
if (rv) {
if (rv==FILE_NOT_OPENED) rv=0; // Don't complain on file not found
run=0;
break;
}
/* If we've passed final file, exit */
if (fnum_end && pf.filenum>fnum_end) { run=0; break; }
/* Get start date, etc */
imjd = (int)pf.hdr.MJD_epoch;
fmjd = (double)(pf.hdr.MJD_epoch - (long double)imjd);
fmjd += (pf.sub.offs-0.5*pf.sub.tsubint)/86400.0;
/* Select polyco set.
* We'll assume same one is valid for whole data block.
*/
if (use_polycos) {
ipc = select_pc(pc, npc, source, imjd, fmjd);
//ipc = select_pc(pc, npc, NULL, imjd, fmjd);
if (ipc<0) {
fprintf(stderr,
"No matching polycos (src=%s, imjd=%d, fmjd=%f)\n",
source, imjd, fmjd);
break;
}
} else {
ipc = 0;
}
pc[ipc].used = 1; // Mark this polyco set as used for folding
/* First time stuff */
if (first_loop) {
fmjd0 = fmjd;
psr_phase(&pc[ipc], imjd, fmjd, NULL, &last_pulse);
pf_out.sub.offs=0.0;
first_loop=0;
for (i=0; i<pf.hdr.nchan; i++) {
pf_out.sub.dat_weights[i]=pf.sub.dat_weights[i];
}
last_filenum = pf_out.filenum;
}
/* Check to see if its time to process data */
if (start_time>0.0) {
double cur_time = (fmjd - fmjd0) * 86400.0;
if (cur_time<start_time)
continue;
}
if (first_data) {
psr_phase(&pc[ipc], imjd, fmjd, NULL, &last_pulse);
first_data=0;
}
/* Check to see if we're done */
if (process_time>0.0) {
double cur_time = (fmjd - fmjd0) * 86400.0;
if (cur_time > start_time + process_time) {
run=0;
break;
}
}
/* for singlepulse: loop over samples, output a new subint
* whenever pulse number increases.
*/
for (i=0; i<pf.hdr.nsblk; i++) {
/* Keep track of timestamp */
// TODO also pointing stuff?
fmjd_samp = fmjd + i*pf.hdr.dt/86400.0;
pf_out.sub.offs += pf.sub.offs - 0.5*pf.sub.tsubint + i*pf.hdr.dt;
sampcount++;
/* Calc current pulse number */
psr_phase(&pc[ipc], imjd, fmjd_samp, &psr_freq, &cur_pulse);
/* TODO: deal with scale/offset? */
/* Fold this sample */
fargs.pc = &pc[ipc];
fargs.imjd = imjd;
fargs.fmjd = fmjd_samp;
rv = fold_8bit_power(fargs.pc,
fargs.imjd, fargs.fmjd,
fargs.data + i*bytes_per_sample,
fargs.nsamp, fargs.tsamp, fargs.raw_signed, fargs.fb);
if (rv!=0) {
fprintf(stderr, "Fold error.\n");
exit(1);
}
/* See if integration needs to be written, etc */
if (cur_pulse > last_pulse) {
/* Figure out timestamp */
pf_out.sub.offs /= (double)sampcount;
pf_out.sub.tsubint = 1.0/psr_freq;
fmjd_epoch = fmjd0 + pf_out.sub.offs/86400.0;
/* Transpose, output subint */
normalize_transpose_folds((float *)pf_out.sub.data, &fb);
psrfits_write_subint(&pf_out);
/* If file incremented, clear polyco flags */
if (pf_out.filenum > last_filenum)
for (j=0; j<npc; j++)
pc_written[j]=0;
/* Write this polyco if needed */
if (pc_written[ipc]==0) {
psrfits_write_polycos(&pf_out, pc, npc);
pc_written[ipc] = 1;
}
/* Check for write errors */
if (pf_out.status) {
fprintf(stderr, "Error writing subint.\n");
fits_report_error(stderr, pf_out.status);
exit(1);
}
/* Clear counters, avgs */
clear_foldbuf(&fb);
pf_out.sub.offs = 0.0;
sampcount=0;
last_pulse = cur_pulse;
last_filenum = pf_out.filenum;
}
}
/* Progress report */
if (!quiet) {
printf("\rFile %d %5.1f%%", pf.filenum,
100.0 * (float)(pf.rownum-1)/(float)pf.rows_per_file);
fflush(stdout);
}
}
psrfits_close(&pf_out);
psrfits_close(&pf);
if (rv) { fits_report_error(stderr, rv); }
exit(0);
}
int fold_16bit_power(const struct polyco *pc, int imjd, double fmjd,
const int16_t *data, int nsamp, double tsamp, int raw_signed,
struct foldbuf *f) {
/* Find midtime */
double fmjd_mid = fmjd + nsamp*tsamp/2.0/86400.0;
/* Check polyco set, allow 5% expansion of range */
if (pc_out_of_range_sloppy(pc, imjd, fmjd,1.05)) { return(-1); }
/* Calc phase, phase step */
/* NOTE: Starting sample phase is computed for the middle
* of the first sample, assuming input fmjd refers to
* the rising edge of the first sample given
*/
double dphase=0.0;
double phase = psr_phase(pc, imjd, fmjd + tsamp/2.0/86400.0, NULL, NULL);
phase = fmod(phase, 1.0);
if (phase<0.0) { phase += 1.0; }
psr_phase(pc, imjd, fmjd_mid, &dphase, NULL);
dphase *= tsamp;
/* Fold em */
int i, ibin;
float *fptr;
for (i=0; i<nsamp; i++) {
ibin = (int)(phase * (double)f->nbin);
if (ibin<0) { ibin+=f->nbin; }
if (ibin>=f->nbin) { ibin-=f->nbin; }
fptr = &f->data[ibin*f->nchan*f->npol];
if (zero_check((const char *)&data[i*f->nchan*f->npol],
2*f->nchan*f->npol)==0) {
if (raw_signed==1)
vector_accumulate_16bit(fptr,
&data[i*f->nchan*f->npol],
f->nchan*f->npol);
else if (raw_signed==2) {
// First 2 polns are unsigned, last 2 are signed
vector_accumulate_16bit_unsigned(fptr,
&data[i*f->nchan*f->npol],
f->nchan*2);
vector_accumulate_16bit(fptr + 2*f->nchan,
&data[i*f->nchan*f->npol + 2*f->nchan],
f->nchan*2);
} else if (raw_signed==3) {
// First 1 pol is unsigned, last 3 are signed
vector_accumulate_16bit_unsigned(fptr,
&data[i*f->nchan*f->npol],
f->nchan);
vector_accumulate_16bit(fptr + f->nchan,
&data[i*f->nchan*f->npol + f->nchan],
f->nchan*3);
} else
// All unsigned
vector_accumulate_16bit_unsigned(fptr,
(uint16_t *)&data[i*f->nchan*f->npol],
f->nchan*f->npol);
f->count[ibin]++;
}
phase += dphase;
if (phase>1.0) { phase -= 1.0; }
}
return(0);
}
