Acurite minor bugfixes

[rtl-433.git] / src / rtl_fm.c

/*
 * rtl-sdr, turns your Realtek RTL2832 based DVB dongle into a SDR receiver
 * Copyright (C) 2012 by Steve Markgraf <steve@steve-m.de>
 * Copyright (C) 2012 by Hoernchen <la@tfc-server.de>
 * Copyright (C) 2012 by Kyle Keen <keenerd@gmail.com>
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU 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 General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */


/*
 * written because people could not do real time
 * FM demod on Atom hardware with GNU radio
 * based on rtl_sdr.c and rtl_tcp.c
 * todo: realtime ARMv5
 *       remove float math (disqualifies complex.h)
 *       in-place array operations
 *       sanity checks
 *       nicer FIR than square
 *       scale squelch to other input parameters
 *       test all the demodulations
 *       pad output on hop
 *       nearest gain approx
 *       frequency ranges could be stored better
 */

#include <errno.h>
#include <signal.h>
#include <string.h>
#include <stdio.h>
#include <stdlib.h>
#include <math.h>

#ifndef _WIN32
#include <unistd.h>
#else
#include <Windows.h>
#include <fcntl.h>
#include <io.h>
#include "getopt/getopt.h"
#define usleep(x) Sleep(x/1000)
#define round(x) (x > 0.0 ? floor(x + 0.5): ceil(x - 0.5))
#endif

#include <semaphore.h>
#include <pthread.h>
#include <libusb.h>

#include "rtl-sdr.h"

#define DEFAULT_SAMPLE_RATE             24000
#define DEFAULT_ASYNC_BUF_NUMBER        32
#define DEFAULT_BUF_LENGTH              (1 * 16384)
#define MAXIMUM_OVERSAMPLE              16
#define MAXIMUM_BUF_LENGTH              (MAXIMUM_OVERSAMPLE * DEFAULT_BUF_LENGTH)
#define AUTO_GAIN                       -100

static pthread_t demod_thread;
static sem_t data_ready;
static int do_exit = 0;
static rtlsdr_dev_t *dev = NULL;
static int lcm_post[17] = {1,1,1,3,1,5,3,7,1,9,5,11,3,13,7,15,1};

struct fm_state
{
        int      now_r;
        int      now_j;
        int      pre_r;
        int      pre_j;
        int      prev_index;
        int      downsample;    /* min 1, max 256 */
        int      post_downsample;
        int      output_scale;
        int      squelch_level;
        int      conseq_squelch;
        int      squelch_hits;
        int      terminate_on_squelch;
        int      exit_flag;
        uint8_t  buf[MAXIMUM_BUF_LENGTH];
        uint32_t buf_len;
        int      signal[MAXIMUM_BUF_LENGTH];  /* 16 bit signed i/q pairs */
        int16_t  signal2[MAXIMUM_BUF_LENGTH]; /* signal has lowpass, signal2 has demod */
        int      signal_len;
        int      signal2_len;
        FILE     *file;
        int      edge;
        uint32_t freqs[1000];
        int      freq_len;
        int      freq_now;
        uint32_t sample_rate;
        int      output_rate;
        int      fir_enable;
        int      fir[256];  /* fir_len == downsample */
        int      fir_sum;
        int      custom_atan;
        int      deemph;
        int      deemph_a;
        int      now_lpr;
        int      prev_lpr_index;
        void     (*mode_demod)(struct fm_state*);
};

void usage(void)
{
        fprintf(stderr,
                "rtl_fm, a simple narrow band FM demodulator for RTL2832 based DVB-T receivers\n\n"
                "Use:\trtl_fm -f freq [-options] [filename]\n"
                "\t-f frequency_to_tune_to [Hz]\n"
                "\t (use multiple -f for scanning, requires squelch)\n"
                "\t (ranges supported, -f 118M:137M:25k)\n"
                "\t[-s sample_rate (default: 24k)]\n"
                "\t[-d device_index (default: 0)]\n"
                "\t[-g tuner_gain (default: automatic)]\n"
                "\t[-l squelch_level (default: 0/off)]\n"
                "\t[-o oversampling (default: 1, 4 recommended)]\n"
                "\t[-p ppm_error (default: 0)]\n"
                "\t[-E sets lower edge tuning (default: center)]\n"
                "\t[-N enables NBFM mode (default: on)]\n"
                "\t[-W enables WBFM mode (default: off)]\n"
                "\t (-N -s 170k -o 4 -A -r 32k -l 0 -D)\n"
                "\tfilename (a '-' dumps samples to stdout)\n"
                "\t (omitting the filename also uses stdout)\n\n"
                "Experimental options:\n"
                "\t[-r output_rate (default: same as -s)]\n"
                "\t[-t squelch_delay (default: 20)]\n"
                "\t (+values will mute/scan, -values will exit)\n"
                "\t[-M enables AM mode (default: off)]\n"
                "\t[-L enables LSB mode (default: off)]\n"
                "\t[-U enables USB mode (default: off)]\n"
                //"\t[-D enables DSB mode (default: off)]\n"
                "\t[-R enables raw mode (default: off, 2x16 bit output)]\n"
                "\t[-F enables high quality FIR (default: off/square)]\n"
                "\t[-D enables de-emphasis (default: off)]\n"
                "\t[-A enables high speed arctan (default: off)]\n\n"
                "Produces signed 16 bit ints, use Sox or aplay to hear them.\n"
                "\trtl_fm ... - | play -t raw -r 24k -e signed-integer -b 16 -c 1 -V1 -\n"
                "\t             | aplay -r 24k -f S16_LE -t raw -c 1\n"
                "\t  -s 22.5k - | multimon -t raw /dev/stdin\n\n");
        exit(1);
}

#ifdef _WIN32
BOOL WINAPI
sighandler(int signum)
{
        if (CTRL_C_EVENT == signum) {
                fprintf(stderr, "Signal caught, exiting!\n");
                do_exit = 1;
                rtlsdr_cancel_async(dev);
                return TRUE;
        }
        return FALSE;
}
#else
static void sighandler(int signum)
{
        fprintf(stderr, "Signal caught, exiting!\n");
        do_exit = 1;
        rtlsdr_cancel_async(dev);
}
#endif

void rotate_90(unsigned char *buf, uint32_t len)
/* 90 rotation is 1+0j, 0+1j, -1+0j, 0-1j
   or [0, 1, -3, 2, -4, -5, 7, -6] */
{
        uint32_t i;
        unsigned char tmp;
        for (i=0; i<len; i+=8) {
                /* uint8_t negation = 255 - x */
                tmp = 255 - buf[i+3];
                buf[i+3] = buf[i+2];
                buf[i+2] = tmp;

                buf[i+4] = 255 - buf[i+4];
                buf[i+5] = 255 - buf[i+5];

                tmp = 255 - buf[i+6];
                buf[i+6] = buf[i+7];
                buf[i+7] = tmp;
        }
}

void low_pass(struct fm_state *fm, unsigned char *buf, uint32_t len)
/* simple square window FIR */
{
        int i=0, i2=0;
        while (i < (int)len) {
                fm->now_r += ((int)buf[i]   - 128);
                fm->now_j += ((int)buf[i+1] - 128);
                i += 2;
                fm->prev_index++;
                if (fm->prev_index < fm->downsample) {
                        continue;
                }
                fm->signal[i2]   = fm->now_r * fm->output_scale;
                fm->signal[i2+1] = fm->now_j * fm->output_scale;
                fm->prev_index = 0;
                fm->now_r = 0;
                fm->now_j = 0;
                i2 += 2;
        }
        fm->signal_len = i2;
}

void build_fir(struct fm_state *fm)
/* for now, a simple triangle 
 * fancy FIRs are equally expensive, so use one */
/* point = sum(sample[i] * fir[i] * fir_len / fir_sum) */
{
        int i, len;
        len = fm->downsample;
        for(i = 0; i < (len/2); i++) {
                fm->fir[i] = i;
        }
        for(i = len-1; i >= (len/2); i--) {
                fm->fir[i] = len - i;
        }
        fm->fir_sum = 0;
        for(i = 0; i < len; i++) {
                fm->fir_sum += fm->fir[i];
        }
}

void low_pass_fir(struct fm_state *fm, unsigned char *buf, uint32_t len)
/* perform an arbitrary FIR, doubles CPU use */
// possibly bugged, or overflowing
{
        int i=0, i2=0, i3=0;
        while (i < (int)len) {
                i3 = fm->prev_index;
                fm->now_r += ((int)buf[i]   - 128) * fm->fir[i3] * fm->downsample / fm->fir_sum;
                fm->now_j += ((int)buf[i+1] - 128) * fm->fir[i3] * fm->downsample / fm->fir_sum;
                i += 2;
                fm->prev_index++;
                if (fm->prev_index < fm->downsample) {
                        continue;
                }
                fm->signal[i2]   = fm->now_r * fm->output_scale;
                fm->signal[i2+1] = fm->now_j * fm->output_scale;
                fm->prev_index = 0;
                fm->now_r = 0;
                fm->now_j = 0;
                i2 += 2;
        }
        fm->signal_len = i2;
}

int low_pass_simple(int16_t *signal2, int len, int step)
// no wrap around, length must be multiple of step
{
        int i, i2, sum;
        for(i=0; i < len; i+=step) {
                sum = 0;
                for(i2=0; i2<step; i2++) {
                        sum += (int)signal2[i + i2];
                }
                //signal2[i/step] = (int16_t)(sum / step);
                signal2[i/step] = (int16_t)(sum);
        }
        signal2[i/step + 1] = signal2[i/step];
        return len / step;
}

void low_pass_real(struct fm_state *fm)
/* simple square window FIR */
// add support for upsampling?
{
        int i=0, i2=0;
        int fast = (int)fm->sample_rate / fm->post_downsample;
        int slow = fm->output_rate;
        while (i < fm->signal2_len) {
                fm->now_lpr += fm->signal2[i];
                i++;
                fm->prev_lpr_index += slow;
                if (fm->prev_lpr_index < fast) {
                        continue;
                }
                fm->signal2[i2] = (int16_t)(fm->now_lpr / (fast/slow));
                fm->prev_lpr_index -= fast;
                fm->now_lpr = 0;
                i2 += 1;
        }
        fm->signal2_len = i2;
}

/* define our own complex math ops
   because ARMv5 has no hardware float */

void multiply(int ar, int aj, int br, int bj, int *cr, int *cj)
{
        *cr = ar*br - aj*bj;
        *cj = aj*br + ar*bj;
}

int polar_discriminant(int ar, int aj, int br, int bj)
{
        int cr, cj;
        double angle;
        multiply(ar, aj, br, -bj, &cr, &cj);
        angle = atan2((double)cj, (double)cr);
        return (int)(angle / 3.14159 * (1<<14));
}

int fast_atan2(int y, int x)
/* pre scaled for int16 */
{
        int yabs, angle;
        int pi4=(1<<12), pi34=3*(1<<12);  // note pi = 1<<14
        if (x==0 && y==0) {
                return 0;
        }
        yabs = y;
        if (yabs < 0) {
                yabs = -yabs;
        }
        if (x >= 0) {
                angle = pi4  - pi4 * (x-yabs) / (x+yabs);
        } else {
                angle = pi34 - pi4 * (x+yabs) / (yabs-x);
        }
        if (y < 0) {
                return -angle;
        }
        return angle;
}

int polar_disc_fast(int ar, int aj, int br, int bj)
{
        int cr, cj;
        multiply(ar, aj, br, -bj, &cr, &cj);
        return fast_atan2(cj, cr);
}

void fm_demod(struct fm_state *fm)
{
        int i, pcm;
        pcm = polar_discriminant(fm->signal[0], fm->signal[1],
                fm->pre_r, fm->pre_j);
        fm->signal2[0] = (int16_t)pcm;
        for (i = 2; i < (fm->signal_len); i += 2) {
                if (fm->custom_atan) {
                        pcm = polar_disc_fast(fm->signal[i], fm->signal[i+1],
                                fm->signal[i-2], fm->signal[i-1]);
                } else {
                        pcm = polar_discriminant(fm->signal[i], fm->signal[i+1],
                                fm->signal[i-2], fm->signal[i-1]);
                }
                fm->signal2[i/2] = (int16_t)pcm;
        }
        fm->pre_r = fm->signal[fm->signal_len - 2];
        fm->pre_j = fm->signal[fm->signal_len - 1];
        fm->signal2_len = fm->signal_len/2;
}

void am_demod(struct fm_state *fm)
// todo, fix this extreme laziness
{
        int i, pcm;
        for (i = 0; i < (fm->signal_len); i += 2) {
                // hypot uses floats but won't overflow
                //fm->signal2[i/2] = (int16_t)hypot(fm->signal[i], fm->signal[i+1]);
                pcm = fm->signal[i] * fm->signal[i];
                pcm += fm->signal[i+1] * fm->signal[i+1];
                fm->signal2[i/2] = (int16_t)sqrt(pcm); // * fm->output_scale;
        }
        fm->signal2_len = fm->signal_len/2;
        // lowpass? (3khz)  highpass?  (dc)
}

void usb_demod(struct fm_state *fm)
{
        int i, pcm;
        for (i = 0; i < (fm->signal_len); i += 2) {
                pcm = fm->signal[i] + fm->signal[i+1];
                fm->signal2[i/2] = (int16_t)pcm; // * fm->output_scale;
        }
        fm->signal2_len = fm->signal_len/2;
}

void lsb_demod(struct fm_state *fm)
{
        int i, pcm;
        for (i = 0; i < (fm->signal_len); i += 2) {
                pcm = fm->signal[i] - fm->signal[i+1];
                fm->signal2[i/2] = (int16_t)pcm; // * fm->output_scale;
        }
        fm->signal2_len = fm->signal_len/2;
}

void raw_demod(struct fm_state *fm)
{
        /* hacky and pointless code */
        int i;
        for (i = 0; i < (fm->signal_len); i++) {
                fm->signal2[i] = (int16_t)fm->signal[i];
        }
        fm->signal2_len = fm->signal_len;
}

void deemph_filter(struct fm_state *fm)
{
        static int avg;  // cheating...
        int i, d;
        // de-emph IIR
        // avg = avg * (1 - alpha) + sample * alpha;
        for (i = 0; i < fm->signal2_len; i++) {
                d = fm->signal2[i] - avg;
                if (d > 0) {
                        avg += (d + fm->deemph_a/2) / fm->deemph_a;
                } else {
                        avg += (d - fm->deemph_a/2) / fm->deemph_a;
                }
                fm->signal2[i] = (int16_t)avg;
        }
}

int mad(int *samples, int len, int step)
/* mean average deviation */
{
        int i=0, sum=0, ave=0;
        if (len == 0)
                {return 0;}
        for (i=0; i<len; i+=step) {
                sum += samples[i];
        }
        ave = sum / (len * step);
        sum = 0;
        for (i=0; i<len; i+=step) {
                sum += abs(samples[i] - ave);
        }
        return sum / (len / step);
}

int post_squelch(struct fm_state *fm)
/* returns 1 for active signal, 0 for no signal */
{
        int dev_r, dev_j, len, sq_l;
        /* only for small samples, big samples need chunk processing */
        len = fm->signal_len;
        sq_l = fm->squelch_level;
        dev_r = mad(&(fm->signal[0]), len, 2);
        dev_j = mad(&(fm->signal[1]), len, 2);
        if ((dev_r > sq_l) || (dev_j > sq_l)) {
                fm->squelch_hits = 0;
                return 1;
        }
        fm->squelch_hits++;
        return 0;
}

static void optimal_settings(struct fm_state *fm, int freq, int hopping)
{
        int r, capture_freq, capture_rate;
        fm->downsample = (1000000 / fm->sample_rate) + 1;
        fm->freq_now = freq;
        capture_rate = fm->downsample * fm->sample_rate;
        capture_freq = fm->freqs[freq] + capture_rate/4;
        capture_freq += fm->edge * fm->sample_rate / 2;
        fm->output_scale = (1<<15) / (128 * fm->downsample);
        if (fm->output_scale < 1) {
                fm->output_scale = 1;}
        fm->output_scale = 1;
        /* Set the frequency */
        r = rtlsdr_set_center_freq(dev, (uint32_t)capture_freq);
        if (hopping) {
                return;}
        fprintf(stderr, "Oversampling input by: %ix.\n", fm->downsample);
        fprintf(stderr, "Oversampling output by: %ix.\n", fm->post_downsample);
        fprintf(stderr, "Buffer size: %0.2fms\n",
                1000 * 0.5 * lcm_post[fm->post_downsample] * (float)DEFAULT_BUF_LENGTH / (float)capture_rate);
        if (r < 0) {
                fprintf(stderr, "WARNING: Failed to set center freq.\n");}
        else {
                fprintf(stderr, "Tuned to %u Hz.\n", capture_freq);}

        /* Set the sample rate */
        fprintf(stderr, "Sampling at %u Hz.\n", capture_rate);
        if (fm->output_rate > 0) {
                fprintf(stderr, "Output at %u Hz.\n", fm->output_rate);
        } else {
                fprintf(stderr, "Output at %u Hz.\n", fm->sample_rate/fm->post_downsample);}
        r = rtlsdr_set_sample_rate(dev, (uint32_t)capture_rate);
        if (r < 0) {
                fprintf(stderr, "WARNING: Failed to set sample rate.\n");}

}

void full_demod(struct fm_state *fm)
{
        int i, sr, freq_next, hop = 0;
        rotate_90(fm->buf, fm->buf_len);
        if (fm->fir_enable) {
                low_pass_fir(fm, fm->buf, fm->buf_len);
        } else {
                low_pass(fm, fm->buf, fm->buf_len);
        }
        fm->mode_demod(fm);
        if (fm->mode_demod == &raw_demod) {
                fwrite(fm->signal2, 2, fm->signal2_len, fm->file);
                return;
        }
        sr = post_squelch(fm);
        if (!sr && fm->squelch_hits > fm->conseq_squelch) {
                if (fm->terminate_on_squelch) {
                        fm->exit_flag = 1;}
                if (fm->freq_len == 1) {  /* mute */
                        for (i=0; i<fm->signal_len; i++) {
                                fm->signal2[i] = 0;}
                }
                else {
                        hop = 1;}
        }
        if (fm->post_downsample > 1) {
                fm->signal2_len = low_pass_simple(fm->signal2, fm->signal2_len, fm->post_downsample);}
        if (fm->output_rate > 0) {
                low_pass_real(fm);
        }
        if (fm->deemph) {
                deemph_filter(fm);}
        /* ignore under runs for now */
        fwrite(fm->signal2, 2, fm->signal2_len, fm->file);
        if (hop) {
                freq_next = (fm->freq_now + 1) % fm->freq_len;
                optimal_settings(fm, freq_next, 1);
                fm->squelch_hits = fm->conseq_squelch + 1;  /* hair trigger */
                /* wait for settling and flush buffer */
                usleep(5000);
                rtlsdr_read_sync(dev, NULL, 4096, NULL);
        }
}

static void rtlsdr_callback(unsigned char *buf, uint32_t len, void *ctx)
{
        struct fm_state *fm2 = ctx;
        int dr_val;
        if (do_exit) {
                return;}
        if (!ctx) {
                return;}
        memcpy(fm2->buf, buf, len);
        fm2->buf_len = len;
        /* single threaded uses 25% less CPU? */
        /* full_demod(fm2); */
        sem_getvalue(&data_ready, &dr_val);
        if (dr_val <= 0) {
                sem_post(&data_ready);}
}

static void *demod_thread_fn(void *arg)
{
        struct fm_state *fm2 = arg;
        while (!do_exit) {
                sem_wait(&data_ready);
                full_demod(fm2);
                if (fm2->exit_flag) {
                        do_exit = 1;
                        rtlsdr_cancel_async(dev);}
        }
        return 0;
}

double atofs(char* f)
/* standard suffixes */
{
        char* chop;
        double suff = 1.0;
        chop = malloc((strlen(f)+1)*sizeof(char));
        strncpy(chop, f, strlen(f)-1);
        switch (f[strlen(f)-1]) {
                case 'G':
                        suff *= 1e3;
                case 'M':
                        suff *= 1e3;
                case 'k':
                        suff *= 1e3;
                        suff *= atof(chop);}
        free(chop);
        if (suff != 1.0) {
                return suff;}
        return atof(f);
}

void frequency_range(struct fm_state *fm, char *arg)
{
        char *start, *stop, *step;
        int i;
        start = arg;
        stop = strchr(start, ':') + 1;
        stop[-1] = '\0';
        step = strchr(stop, ':') + 1;
        step[-1] = '\0';
        for(i=(int)atofs(start); i<=(int)atofs(stop); i+=(int)atofs(step))
        {
                fm->freqs[fm->freq_len] = (uint32_t)i;
                fm->freq_len++;
        }
        stop[-1] = ':';
        step[-1] = ':';
}

int main(int argc, char **argv)
{
#ifndef _WIN32
        struct sigaction sigact;
#endif
        struct fm_state fm; 
        char *filename = NULL;
        int n_read, r, opt, wb_mode = 0;
        int i, gain = AUTO_GAIN; // tenths of a dB
        uint8_t *buffer;
        uint32_t dev_index = 0;
        int device_count;
        int ppm_error = 0;
        char vendor[256], product[256], serial[256];
        fm.freqs[0] = 100000000;
        fm.sample_rate = DEFAULT_SAMPLE_RATE;
        fm.squelch_level = 0;
        fm.conseq_squelch = 20;
        fm.terminate_on_squelch = 0;
        fm.freq_len = 0;
        fm.edge = 0;
        fm.fir_enable = 0;
        fm.prev_index = 0;
        fm.post_downsample = 1;  // once this works, default = 4
        fm.custom_atan = 0;
        fm.deemph = 0;
        fm.output_rate = -1;  // flag for disabled
        fm.mode_demod = &fm_demod;
        sem_init(&data_ready, 0, 0);

        while ((opt = getopt(argc, argv, "d:f:g:s:b:l:o:t:r:p:EFANWMULRD")) != -1) {
                switch (opt) {
                case 'd':
                        dev_index = atoi(optarg);
                        break;
                case 'f':
                        if (strchr(optarg, ':'))
                                {frequency_range(&fm, optarg);}
                        else
                        {
                                fm.freqs[fm.freq_len] = (uint32_t)atofs(optarg);
                                fm.freq_len++;
                        }
                        break;
                case 'g':
                        gain = (int)(atof(optarg) * 10);
                        break;
                case 'l':
                        fm.squelch_level = (int)atof(optarg);
                        break;
                case 's':
                        fm.sample_rate = (uint32_t)atofs(optarg);
                        break;
                case 'r':
                        fm.output_rate = (int)atofs(optarg);
                        break;
                case 'o':
                        fm.post_downsample = (int)atof(optarg);
                        if (fm.post_downsample < 1 || fm.post_downsample > MAXIMUM_OVERSAMPLE) {
                                fprintf(stderr, "Oversample must be between 1 and %i\n", MAXIMUM_OVERSAMPLE);}
                        break;
                case 't':
                        fm.conseq_squelch = (int)atof(optarg);
                        if (fm.conseq_squelch < 0) {
                                fm.conseq_squelch = -fm.conseq_squelch;
                                fm.terminate_on_squelch = 1;
                        }
                        break;
                case 'p':
                        ppm_error = atoi(optarg);
                        break;
                case 'E':
                        fm.edge = 1;
                        break;
                case 'F':
                        fm.fir_enable = 1;
                        break;
                case 'A':
                        fm.custom_atan = 1;
                        break;
                case 'D':
                        fm.deemph = 1;
                        break;
                case 'N':
                        fm.mode_demod = &fm_demod;
                        break;
                case 'W':
                        wb_mode = 1;
                        fm.mode_demod = &fm_demod;
                        fm.sample_rate = 170000;
                        fm.output_rate = 32000;
                        fm.custom_atan = 1;
                        fm.post_downsample = 4;
                        fm.deemph = 1;
                        fm.squelch_level = 0;
                        break;
                case 'M':
                        fm.mode_demod = &am_demod;
                        break;
                case 'U':
                        fm.mode_demod = &usb_demod;
                        break;
                case 'L':
                        fm.mode_demod = &lsb_demod;
                        break;
                case 'R':
                        fm.mode_demod = &raw_demod;
                        break;
                default:
                        usage();
                        break;
                }
        }
        /* quadruple sample_rate to limit to Δθ to ±π/2 */
        fm.sample_rate *= fm.post_downsample;

        if (fm.freq_len > 1) {
                fm.terminate_on_squelch = 0;
        }

        if (argc <= optind) {
                //usage();
                filename = "-";
        } else {
                filename = argv[optind];
        }

        buffer = malloc(lcm_post[fm.post_downsample] * DEFAULT_BUF_LENGTH * sizeof(uint8_t));

        device_count = rtlsdr_get_device_count();
        if (!device_count) {
                fprintf(stderr, "No supported devices found.\n");
                exit(1);
        }

        fprintf(stderr, "Found %d device(s):\n", device_count);
        for (i = 0; i < device_count; i++) {
                rtlsdr_get_device_usb_strings(i, vendor, product, serial);
                fprintf(stderr, "  %d:  %s, %s, SN: %s\n", i, vendor, product, serial);
        }
        fprintf(stderr, "\n");

        fprintf(stderr, "Using device %d: %s\n",
                dev_index, rtlsdr_get_device_name(dev_index));

        r = rtlsdr_open(&dev, dev_index);
        if (r < 0) {
                fprintf(stderr, "Failed to open rtlsdr device #%d.\n", dev_index);
                exit(1);
        }
#ifndef _WIN32
        sigact.sa_handler = sighandler;
        sigemptyset(&sigact.sa_mask);
        sigact.sa_flags = 0;
        sigaction(SIGINT, &sigact, NULL);
        sigaction(SIGTERM, &sigact, NULL);
        sigaction(SIGQUIT, &sigact, NULL);
        sigaction(SIGPIPE, &sigact, NULL);
#else
        SetConsoleCtrlHandler( (PHANDLER_ROUTINE) sighandler, TRUE );
#endif

        /* WBFM is special */
        if (wb_mode) {
                fm.freqs[0] += 16000;
        }

        if (fm.deemph) {
                fm.deemph_a = (int)round(1.0/((1.0-exp(-1.0/(fm.output_rate * 75e-6)))));
        }

        optimal_settings(&fm, 0, 0);
        build_fir(&fm);

        /* Set the tuner gain */
        if (gain == AUTO_GAIN) {
                r = rtlsdr_set_tuner_gain_mode(dev, 0);
        } else {
                r = rtlsdr_set_tuner_gain_mode(dev, 1);
                r = rtlsdr_set_tuner_gain(dev, gain);
        }
        if (r != 0) {
                fprintf(stderr, "WARNING: Failed to set tuner gain.\n");
        } else if (gain == AUTO_GAIN) {
                fprintf(stderr, "Tuner gain set to automatic.\n");
        } else {
                fprintf(stderr, "Tuner gain set to %0.2f dB.\n", gain/10.0);
        }
        r = rtlsdr_set_freq_correction(dev, ppm_error);

        if (strcmp(filename, "-") == 0) { /* Write samples to stdout */
                fm.file = stdout;
#ifdef _WIN32
                _setmode(_fileno(fm.file), _O_BINARY);
#endif
        } else {
                fm.file = fopen(filename, "wb");
                if (!fm.file) {
                        fprintf(stderr, "Failed to open %s\n", filename);
                        exit(1);
                }
        }

        /* Reset endpoint before we start reading from it (mandatory) */
        r = rtlsdr_reset_buffer(dev);
        if (r < 0) {
                fprintf(stderr, "WARNING: Failed to reset buffers.\n");}

        pthread_create(&demod_thread, NULL, demod_thread_fn, (void *)(&fm));
        rtlsdr_read_async(dev, rtlsdr_callback, (void *)(&fm),
                              DEFAULT_ASYNC_BUF_NUMBER,
                              lcm_post[fm.post_downsample] * DEFAULT_BUF_LENGTH);

        if (do_exit) {
                fprintf(stderr, "\nUser cancel, exiting...\n");}
        else {
                fprintf(stderr, "\nLibrary error %d, exiting...\n", r);}
        rtlsdr_cancel_async(dev);

        if (fm.file != stdout) {
                fclose(fm.file);}

        rtlsdr_close(dev);
        free (buffer);
        return r >= 0 ? r : -r;
}