ref: 5644827b542969905631515d03d8441db453d26a
dir: /src/stat.c/
/* * July 5, 1991 * Copyright 1991 Lance Norskog And Sundry Contributors * This source code is freely redistributable and may be used for * any purpose. This copyright notice must be maintained. * Lance Norskog And Sundry Contributors are not responsible for * the consequences of using this software. */ /* * Sound Tools statistics "effect" file. * * Build various statistics on file and print them. * No output. */ #include <math.h> #include "st.h" /* Private data for STAT effect */ typedef struct statstuff { double min, max; double asum; double sum1, sum2; /* amplitudes */ double dmin, dmax; double dsum1, dsum2; /* deltas */ double scale; /* scale-factor */ double last; /* previous sample */ ULONG read; /* samples processed */ int volume; int srms; ULONG bin[4]; } *stat_t; /* * Process options */ int st_stat_getopts(effp, n, argv) eff_t effp; int n; char **argv; { stat_t stat = (stat_t) effp->priv; stat->scale = MAXLONG; stat->volume = 0; stat->srms = 0; while (n>0) { if (!(strcmp(argv[0], "-v"))) { stat->volume = 1; goto did1; } if (!(strcmp(argv[0], "-s"))) { double scale; if (n <= 1) { st_fail("-s option: invalid argument"); return (ST_EOF); } if (!strcmp(argv[1],"rms")) { stat->srms=1; goto did2; } if (!sscanf(argv[1], "%lf", &scale)) { st_fail("-s option: invalid argument"); return (ST_EOF); } stat->scale = scale; goto did2; } if (!(strcmp(argv[0], "-rms"))) { double scale; if (n <= 1 || !sscanf(argv[1], "%lf", &scale)) { st_fail("-s option expects float argument"); return(ST_EOF); } stat->srms = 1; goto did2; } if (!(strcmp(argv[0], "debug"))) { stat->volume = 2; goto did1; } else { st_fail("Summary effect: unknown option"); return(ST_EOF); } did2: --n; ++argv; did1: --n; ++argv; } return (ST_SUCCESS); } /* * Prepare processing. */ int st_stat_start(effp) eff_t effp; { stat_t stat = (stat_t) effp->priv; int i; stat->min = stat->max = 0; stat->asum = 0; stat->sum1 = stat->sum2 = 0; stat->dmin = stat->dmax = 0; stat->dsum1 = stat->dsum2 = 0; stat->last = 0; stat->read = 0; for (i = 0; i < 4; i++) stat->bin[i] = 0; return (ST_SUCCESS); } /* * Processed signed long samples from ibuf to obuf. * Return number of samples processed. */ int st_stat_flow(effp, ibuf, obuf, isamp, osamp) eff_t effp; LONG *ibuf, *obuf; LONG *isamp, *osamp; { stat_t stat = (stat_t) effp->priv; int len, done; short count; count = 0; len = ((*isamp > *osamp) ? *osamp : *isamp); if (len==0) return (ST_SUCCESS); if (stat->read == 0) /* 1st sample */ stat->min = stat->max = stat->last = (*ibuf)/stat->scale; for(done = 0; done < len; done++) { long lsamp; double samp, delta; /* work in scaled levels for both sample and delta */ lsamp = *ibuf++; samp = (double)lsamp/stat->scale; stat->bin[RIGHT(lsamp,30)+2]++; *obuf++ = lsamp; if (stat->volume == 2) { fprintf(stderr,"%f ",samp); if (count++ == 5) { fprintf(stderr,"\n"); count = 0; } } /* update min/max */ if (stat->min > samp) stat->min = samp; else if (stat->max < samp) stat->max = samp; stat->sum1 += samp; stat->sum2 += samp*samp; stat->asum += fabs(samp); delta = fabs(samp - stat->last); if (delta < stat->dmin) stat->dmin = delta; else if (delta > stat->dmax) stat->dmax = delta; stat->dsum1 += delta; stat->dsum2 += delta*delta; stat->last = samp; } stat->read += len; *isamp = *osamp = len; /* Process all samples */ return (ST_SUCCESS); } /* * Do anything required when you stop reading samples. * Don't close input file! */ int st_stat_stop(effp) eff_t effp; { stat_t stat = (stat_t) effp->priv; double amp, scale, rms = 0, freq; double x, ct; ct = stat->read; if (stat->srms) { /* adjust results to units of rms */ double f; rms = sqrt(stat->sum2/ct); f = 1.0/rms; stat->max *= f; stat->min *= f; stat->asum *= f; stat->sum1 *= f; stat->sum2 *= f*f; stat->dmax *= f; stat->dmin *= f; stat->dsum1 *= f; stat->dsum2 *= f*f; stat->scale *= rms; } scale = stat->scale; amp = -stat->min; if (amp < stat->max) amp = stat->max; /* Just print the volume adjustment */ if (stat->volume == 1 && amp > 0) { fprintf(stderr, "%.3f\n", MAXLONG/(amp*scale)); return (ST_SUCCESS); } if (stat->volume == 2) { fprintf(stderr, "\n"); } /* print out the info */ fprintf(stderr, "Samples read: %12lu\n", stat->read); fprintf(stderr, "Length (seconds): %12.6f\n", (double)stat->read/effp->ininfo.rate); if (stat->srms) fprintf(stderr, "Scaled by rms: %12.6f\n", rms); else fprintf(stderr, "Scaled by: %12.1f\n", scale); fprintf(stderr, "Maximum amplitude: %12.6f\n", stat->max); fprintf(stderr, "Minimum amplitude: %12.6f\n", stat->min); fprintf(stderr, "Mean norm: %12.6f\n", stat->asum/ct); fprintf(stderr, "Mean amplitude: %12.6f\n", stat->sum1/ct); fprintf(stderr, "RMS amplitude: %12.6f\n", sqrt(stat->sum2/ct)); fprintf(stderr, "Maximum delta: %12.6f\n", stat->dmax); fprintf(stderr, "Minimum delta: %12.6f\n", stat->dmin); fprintf(stderr, "Mean delta: %12.6f\n", stat->dsum1/(ct-1)); fprintf(stderr, "RMS delta: %12.6f\n", sqrt(stat->dsum2/(ct-1))); freq = sqrt(stat->dsum2/stat->sum2)*effp->ininfo.rate/(M_PI*2); fprintf(stderr, "Rough frequency: %12d\n", (int)freq); if (amp>0) fprintf(stderr, "Volume adjustment: %12.3f\n", MAXLONG/(amp*scale)); if (stat->bin[2] == 0 && stat->bin[3] == 0) fprintf(stderr, "\nProbably text, not sound\n"); else { x = (float)(stat->bin[0] + stat->bin[3]) / (float)(stat->bin[1] + stat->bin[2]); if (x >= 3.0) /* use opposite encoding */ { if (effp->ininfo.encoding == ST_ENCODING_UNSIGNED) { fprintf (stderr,"\nTry: -t raw -b -s \n"); } else { fprintf (stderr,"\nTry: -t raw -b -u \n"); } } else if (x <= 1.0/3.0) { ;; /* correctly decoded */ } else if (x >= 0.5 && x <= 2.0) /* use ULAW */ { if (effp->ininfo.encoding == ST_ENCODING_ULAW) { fprintf (stderr,"\nTry: -t raw -b -u \n"); } else { fprintf (stderr,"\nTry: -t raw -b -U \n"); } } else { fprintf (stderr, "\nCan't guess the type\n"); } } return (ST_SUCCESS); }