Rework to add and use a binding for radio controldab_3.99.1dab/3.99.13.99.1

A radio binding has been added in the new binding directory, and the
application has been reworked to use it.  The binding uses a modified
version of the rtl_fm code used in the qtmultimedia radio plugin that
was previously used, and some new code has been added to output to
PulseAudio using the asynchronous API to ensure compatibility with
stream corking.  The rtl_fm code has been enhanced to add seeking
support, and the application has been tweaked to use it.

Bug-AGL: SPEC-581

Change-Id: I011e98374accc2cad2b36c93ac800948ee51f2aa
Signed-off-by: Scott Murray <scott.murray@konsulko.com>

1 files changed, 1267 insertions, 0 deletions

diff --git a/binding/rtl_fm.c b/binding/rtl_fm.c
new file mode 100644
index 0000000..1c6a6b2
--- /dev/null
+++ b/binding/rtl_fm.c
@@ -0,0 +1,1267 @@
+/*
+ * 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>
+ * Copyright (C) 2013 by Elias Oenal <EliasOenal@gmail.com>
+ * Copyright (C) 2016, 2017 Konsulko Group
+ *
+ * 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/>.
+ */
+
+/*
+ * Note that this version replaces the standalone main() with separate
+ * init/start/stop API calls to allow building into another application.
+ * Other than removing the separate controller thread and adding an output
+ * function callback, other changes have been kept to a minimum to
+ * potentially allow using other rtl_fm features by modifying rtl_fm_init.
+ *
+ * December 2016, Scott Murray <scott.murray@konsulko.com>
+ */
+
+/*
+ * 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
+ *
+ * lots of locks, but that is okay
+ * (no many-to-many locks)
+ *
+ * todo:
+ *       sanity checks
+ *       scale squelch to other input parameters
+ *       test all the demodulations
+ *       pad output on hop
+ *       frequency ranges could be stored better
+ *       scaled AM demod amplification
+ *       auto-hop after time limit
+ *       peak detector to tune onto stronger signals
+ *       fifo for active hop frequency
+ *       clips
+ *       noise squelch
+ *       merge stereo patch
+ *       merge soft agc patch
+ *       merge udp patch
+ *       testmode to detect overruns
+ *       watchdog to reset bad dongle
+ *       fix oversampling
+ */
+
+#include <errno.h>
+#include <signal.h>
+#include <string.h>
+#include <stdio.h>
+#include <stdlib.h>
+#include <unistd.h>
+#include <math.h>
+#include <pthread.h>
+
+#include "rtl-sdr.h"
+#include "rtl_fm.h"
+#include "convenience/convenience.h"
+
+#define DEFAULT_SAMPLE_RATE		24000
+#define DEFAULT_BUF_LENGTH		RTL_FM_DEFAULT_BUF_LENGTH
+#define MAXIMUM_OVERSAMPLE		RTL_FM_MAXIMUM_OVERSAMPLE
+#define MAXIMUM_BUF_LENGTH		RTL_FM_MAXIMUM_BUF_LENGTH
+#define AUTO_GAIN			-100
+#define BUFFER_DUMP			4096
+
+#define FREQUENCIES_LIMIT		1000
+
+#define DEFAULT_SQUELCH_LEVEL		140
+#define DEFAULT_CONSEQ_SQUELCH		10
+
+static volatile int do_exit = 0;
+static int lcm_post[17] = {1,1,1,3,1,5,3,7,1,9,5,11,3,13,7,15,1};
+static int ACTUAL_BUF_LENGTH;
+
+static int *atan_lut = NULL;
+static int atan_lut_size = 131072; /* 512 KB */
+static int atan_lut_coef = 8;
+
+struct dongle_state
+{
+	int      exit_flag;
+	pthread_t thread;
+	rtlsdr_dev_t *dev;
+	int      dev_index;
+	uint32_t freq;
+	uint32_t rate;
+	int      gain;
+	uint16_t buf16[MAXIMUM_BUF_LENGTH];
+	uint32_t buf_len;
+	int      ppm_error;
+	int      offset_tuning;
+	int      direct_sampling;
+	int      mute;
+	struct demod_state *demod_target;
+};
+
+struct demod_state
+{
+	int      exit_flag;
+	pthread_t thread;
+	int16_t  lowpassed[MAXIMUM_BUF_LENGTH];
+	int      lp_len;
+	int16_t  lp_i_hist[10][6];
+	int16_t  lp_q_hist[10][6];
+	int16_t  result[MAXIMUM_BUF_LENGTH];
+	int16_t  droop_i_hist[9];
+	int16_t  droop_q_hist[9];
+	int      result_len;
+	int      rate_in;
+	int      rate_out;
+	int      rate_out2;
+	int      now_r, now_j;
+	int      pre_r, pre_j;
+	int      prev_index;
+	int      downsample;    /* min 1, max 256 */
+	int      post_downsample;
+	int      output_scale;
+	int      squelch_level, conseq_squelch, squelch_hits, terminate_on_squelch;
+	int      downsample_passes;
+	int      comp_fir_size;
+	int      custom_atan;
+	int      deemph, deemph_a;
+	int      now_lpr;
+	int      prev_lpr_index;
+	int      dc_block, dc_avg;
+	void     (*mode_demod)(struct demod_state*);
+	pthread_rwlock_t rw;
+	pthread_cond_t ready;
+	pthread_mutex_t ready_m;
+	struct output_state *output_target;
+};
+
+struct output_state
+{
+	int      exit_flag;
+	pthread_t thread;
+	rtl_fm_output_fn_t output_fn;
+	void     *output_fn_data;
+	int16_t  result[MAXIMUM_BUF_LENGTH];
+	int      result_len;
+	int      rate;
+	pthread_rwlock_t rw;
+	pthread_cond_t ready;
+	pthread_mutex_t ready_m;
+};
+
+struct controller_state
+{
+	int      exit_flag;
+	pthread_t thread;
+	uint32_t freqs[FREQUENCIES_LIMIT];
+	int      freq_len;
+	int      freq_now;
+	int      edge;
+	int      wb_mode;
+	pthread_cond_t hop;
+	pthread_mutex_t hop_m;
+
+	void (*freq_callback)(uint32_t, void*);
+	void *freq_callback_data;
+
+	int scanning;
+	int scan_direction;
+	void (*scan_callback)(uint32_t, void*);
+	void *scan_callback_data;
+	uint32_t scan_step;
+	uint32_t scan_min;
+	uint32_t scan_max;
+	int scan_squelch_level;
+	int scan_squelch_count;
+};
+
+// multiple of these, eventually
+struct dongle_state dongle;
+struct demod_state demod;
+struct output_state output;
+struct controller_state controller;
+
+#if 0
+static void sighandler(int signum)
+{
+	fprintf(stderr, "Signal caught, exiting!\n");
+	do_exit = 1;
+	rtlsdr_cancel_async(dongle.dev);
+}
+#endif
+
+/* more cond dumbness */
+#define safe_cond_signal(n, m) pthread_mutex_lock(m); pthread_cond_signal(n); pthread_mutex_unlock(m)
+#define safe_cond_wait(n, m) pthread_mutex_lock(m); pthread_cond_wait(n, m); pthread_mutex_unlock(m)
+
+/* {length, coef, coef, coef}  and scaled by 2^15
+   for now, only length 9, optimal way to get +85% bandwidth */
+#define CIC_TABLE_MAX 10
+int cic_9_tables[][10] = {
+	{0,},
+	{9, -156,  -97, 2798, -15489, 61019, -15489, 2798,  -97, -156},
+	{9, -128, -568, 5593, -24125, 74126, -24125, 5593, -568, -128},
+	{9, -129, -639, 6187, -26281, 77511, -26281, 6187, -639, -129},
+	{9, -122, -612, 6082, -26353, 77818, -26353, 6082, -612, -122},
+	{9, -120, -602, 6015, -26269, 77757, -26269, 6015, -602, -120},
+	{9, -120, -582, 5951, -26128, 77542, -26128, 5951, -582, -120},
+	{9, -119, -580, 5931, -26094, 77505, -26094, 5931, -580, -119},
+	{9, -119, -578, 5921, -26077, 77484, -26077, 5921, -578, -119},
+	{9, -119, -577, 5917, -26067, 77473, -26067, 5917, -577, -119},
+	{9, -199, -362, 5303, -25505, 77489, -25505, 5303, -362, -199},
+};
+
+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 demod_state *d)
+/* simple square window FIR */
+{
+	int i=0, i2=0;
+	while (i < d->lp_len) {
+		d->now_r += d->lowpassed[i];
+		d->now_j += d->lowpassed[i+1];
+		i += 2;
+		d->prev_index++;
+		if (d->prev_index < d->downsample) {
+			continue;
+		}
+		d->lowpassed[i2]   = d->now_r; // * d->output_scale;
+		d->lowpassed[i2+1] = d->now_j; // * d->output_scale;
+		d->prev_index = 0;
+		d->now_r = 0;
+		d->now_j = 0;
+		i2 += 2;
+	}
+	d->lp_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 demod_state *s)
+/* simple square window FIR */
+// add support for upsampling?
+{
+	int i=0, i2=0;
+	int fast = (int)s->rate_out;
+	int slow = s->rate_out2;
+	while (i < s->result_len) {
+		s->now_lpr += s->result[i];
+		i++;
+		s->prev_lpr_index += slow;
+		if (s->prev_lpr_index < fast) {
+			continue;
+		}
+		s->result[i2] = (int16_t)(s->now_lpr / (fast/slow));
+		s->prev_lpr_index -= fast;
+		s->now_lpr = 0;
+		i2 += 1;
+	}
+	s->result_len = i2;
+}
+
+void fifth_order(int16_t *data, int length, int16_t *hist)
+/* for half of interleaved data */
+{
+	int i;
+	int16_t a, b, c, d, e, f;
+	a = hist[1];
+	b = hist[2];
+	c = hist[3];
+	d = hist[4];
+	e = hist[5];
+	f = data[0];
+	/* a downsample should improve resolution, so don't fully shift */
+	data[0] = (a + (b+e)*5 + (c+d)*10 + f) >> 4;
+	for (i=4; i<length; i+=4) {
+		a = c;
+		b = d;
+		c = e;
+		d = f;
+		e = data[i-2];
+		f = data[i];
+		data[i/2] = (a + (b+e)*5 + (c+d)*10 + f) >> 4;
+	}
+	/* archive */
+	hist[0] = a;
+	hist[1] = b;
+	hist[2] = c;
+	hist[3] = d;
+	hist[4] = e;
+	hist[5] = f;
+}
+
+void generic_fir(int16_t *data, int length, int *fir, int16_t *hist)
+/* Okay, not at all generic.  Assumes length 9, fix that eventually. */
+{
+	int d, temp, sum;
+	for (d=0; d<length; d+=2) {
+		temp = data[d];
+		sum = 0;
+		sum += (hist[0] + hist[8]) * fir[1];
+		sum += (hist[1] + hist[7]) * fir[2];
+		sum += (hist[2] + hist[6]) * fir[3];
+		sum += (hist[3] + hist[5]) * fir[4];
+		sum +=            hist[4]  * fir[5];
+		data[d] = sum >> 15 ;
+		hist[0] = hist[1];
+		hist[1] = hist[2];
+		hist[2] = hist[3];
+		hist[3] = hist[4];
+		hist[4] = hist[5];
+		hist[5] = hist[6];
+		hist[6] = hist[7];
+		hist[7] = hist[8];
+		hist[8] = temp;
+	}
+}
+
+/* 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);
+}
+
+int atan_lut_init(void)
+{
+	int i = 0;
+
+	atan_lut = malloc(atan_lut_size * sizeof(int));
+
+	for (i = 0; i < atan_lut_size; i++) {
+		atan_lut[i] = (int) (atan((double) i / (1<<atan_lut_coef)) / 3.14159 * (1<<14));
+	}
+
+	return 0;
+}
+
+int polar_disc_lut(int ar, int aj, int br, int bj)
+{
+	int cr, cj, x, x_abs;
+
+	multiply(ar, aj, br, -bj, &cr, &cj);
+
+	/* special cases */
+	if (cr == 0 || cj == 0) {
+		if (cr == 0 && cj == 0)
+			{return 0;}
+		if (cr == 0 && cj > 0)
+			{return 1 << 13;}
+		if (cr == 0 && cj < 0)
+			{return -(1 << 13);}
+		if (cj == 0 && cr > 0)
+			{return 0;}
+		if (cj == 0 && cr < 0)
+			{return 1 << 14;}
+	}
+
+	/* real range -32768 - 32768 use 64x range -> absolute maximum: 2097152 */
+	x = (cj << atan_lut_coef) / cr;
+	x_abs = abs(x);
+
+	if (x_abs >= atan_lut_size) {
+		/* we can use linear range, but it is not necessary */
+		return (cj > 0) ? 1<<13 : -1<<13;
+	}
+
+	if (x > 0) {
+		return (cj > 0) ? atan_lut[x] : atan_lut[x] - (1<<14);
+	} else {
+		return (cj > 0) ? (1<<14) - atan_lut[-x] : -atan_lut[-x];
+	}
+
+	return 0;
+}
+
+void fm_demod(struct demod_state *fm)
+{
+	int i, pcm;
+	int16_t *lp = fm->lowpassed;
+	pcm = polar_discriminant(lp[0], lp[1],
+		fm->pre_r, fm->pre_j);
+	fm->result[0] = (int16_t)pcm;
+	for (i = 2; i < (fm->lp_len-1); i += 2) {
+		switch (fm->custom_atan) {
+		case 0:
+			pcm = polar_discriminant(lp[i], lp[i+1],
+				lp[i-2], lp[i-1]);
+			break;
+		case 1:
+			pcm = polar_disc_fast(lp[i], lp[i+1],
+				lp[i-2], lp[i-1]);
+			break;
+		case 2:
+			pcm = polar_disc_lut(lp[i], lp[i+1],
+				lp[i-2], lp[i-1]);
+			break;
+		}
+		fm->result[i/2] = (int16_t)pcm;
+	}
+	fm->pre_r = lp[fm->lp_len - 2];
+	fm->pre_j = lp[fm->lp_len - 1];
+	fm->result_len = fm->lp_len/2;
+}
+
+void am_demod(struct demod_state *fm)
+// todo, fix this extreme laziness
+{
+	int i, pcm;
+	int16_t *lp = fm->lowpassed;
+	int16_t *r  = fm->result;
+	for (i = 0; i < fm->lp_len; i += 2) {
+		// hypot uses floats but won't overflow
+		//r[i/2] = (int16_t)hypot(lp[i], lp[i+1]);
+		pcm = lp[i] * lp[i];
+		pcm += lp[i+1] * lp[i+1];
+		r[i/2] = (int16_t)sqrt(pcm) * fm->output_scale;
+	}
+	fm->result_len = fm->lp_len/2;
+	// lowpass? (3khz)  highpass?  (dc)
+}
+
+void usb_demod(struct demod_state *fm)
+{
+	int i, pcm;
+	int16_t *lp = fm->lowpassed;
+	int16_t *r  = fm->result;
+	for (i = 0; i < fm->lp_len; i += 2) {
+		pcm = lp[i] + lp[i+1];
+		r[i/2] = (int16_t)pcm * fm->output_scale;
+	}
+	fm->result_len = fm->lp_len/2;
+}
+
+void lsb_demod(struct demod_state *fm)
+{
+	int i, pcm;
+	int16_t *lp = fm->lowpassed;
+	int16_t *r  = fm->result;
+	for (i = 0; i < fm->lp_len; i += 2) {
+		pcm = lp[i] - lp[i+1];
+		r[i/2] = (int16_t)pcm * fm->output_scale;
+	}
+	fm->result_len = fm->lp_len/2;
+}
+
+void raw_demod(struct demod_state *fm)
+{
+	int i;
+	for (i = 0; i < fm->lp_len; i++) {
+		fm->result[i] = (int16_t)fm->lowpassed[i];
+	}
+	fm->result_len = fm->lp_len;
+}
+
+void deemph_filter(struct demod_state *fm)
+{
+	static int avg;  // cheating...
+	int i, d;
+	// de-emph IIR
+	// avg = avg * (1 - alpha) + sample * alpha;
+	for (i = 0; i < fm->result_len; i++) {
+		d = fm->result[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->result[i] = (int16_t)avg;
+	}
+}
+
+void dc_block_filter(struct demod_state *fm)
+{
+	int i, avg;
+	int64_t sum = 0;
+	for (i=0; i < fm->result_len; i++) {
+		sum += fm->result[i];
+	}
+	avg = sum / fm->result_len;
+	avg = (avg + fm->dc_avg * 9) / 10;
+	for (i=0; i < fm->result_len; i++) {
+		fm->result[i] -= avg;
+	}
+	fm->dc_avg = avg;
+}
+
+int mad(int16_t *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 rms(int16_t *samples, int len, int step)
+/* largely lifted from rtl_power */
+{
+	int i;
+	long p, t, s;
+	double dc, err;
+
+	p = t = 0L;
+	for (i=0; i<len; i+=step) {
+		s = (long)samples[i];
+		t += s;
+		p += s * s;
+	}
+	/* correct for dc offset in squares */
+	dc = (double)(t*step) / (double)len;
+	err = t * 2 * dc - dc * dc * len;
+
+	return (int)sqrt((p-err) / len);
+}
+
+void arbitrary_upsample(int16_t *buf1, int16_t *buf2, int len1, int len2)
+/* linear interpolation, len1 < len2 */
+{
+	int i = 1;
+	int j = 0;
+	int tick = 0;
+	double frac;  // use integers...
+	while (j < len2) {
+		frac = (double)tick / (double)len2;
+		buf2[j] = (int16_t)(buf1[i-1]*(1-frac) + buf1[i]*frac);
+		j++;
+		tick += len1;
+		if (tick > len2) {
+			tick -= len2;
+			i++;
+		}
+		if (i >= len1) {
+			i = len1 - 1;
+			tick = len2;
+		}
+	}
+}
+
+void arbitrary_downsample(int16_t *buf1, int16_t *buf2, int len1, int len2)
+/* fractional boxcar lowpass, len1 > len2 */
+{
+	int i = 1;
+	int j = 0;
+	int tick = 0;
+	double remainder = 0;
+	double frac;  // use integers...
+	buf2[0] = 0;
+	while (j < len2) {
+		frac = 1.0;
+		if ((tick + len2) > len1) {
+			frac = (double)(len1 - tick) / (double)len2;}
+		buf2[j] += (int16_t)((double)buf1[i] * frac + remainder);
+		remainder = (double)buf1[i] * (1.0-frac);
+		tick += len2;
+		i++;
+		if (tick > len1) {
+			j++;
+			buf2[j] = 0;
+			tick -= len1;
+		}
+		if (i >= len1) {
+			i = len1 - 1;
+			tick = len1;
+		}
+	}
+	for (j=0; j<len2; j++) {
+		buf2[j] = buf2[j] * len2 / len1;}
+}
+
+void arbitrary_resample(int16_t *buf1, int16_t *buf2, int len1, int len2)
+/* up to you to calculate lengths and make sure it does not go OOB
+ * okay for buffers to overlap, if you are downsampling */
+{
+	if (len1 < len2) {
+		arbitrary_upsample(buf1, buf2, len1, len2);
+	} else {
+		arbitrary_downsample(buf1, buf2, len1, len2);
+	}
+}
+
+void full_demod(struct demod_state *d)
+{
+	int i, ds_p;
+	int sr = 0;
+	ds_p = d->downsample_passes;
+	if (ds_p) {
+		for (i=0; i < ds_p; i++) {
+			fifth_order(d->lowpassed,   (d->lp_len >> i), d->lp_i_hist[i]);
+			fifth_order(d->lowpassed+1, (d->lp_len >> i) - 1, d->lp_q_hist[i]);
+		}
+		d->lp_len = d->lp_len >> ds_p;
+		/* droop compensation */
+		if (d->comp_fir_size == 9 && ds_p <= CIC_TABLE_MAX) {
+			generic_fir(d->lowpassed, d->lp_len,
+				cic_9_tables[ds_p], d->droop_i_hist);
+			generic_fir(d->lowpassed+1, d->lp_len-1,
+				cic_9_tables[ds_p], d->droop_q_hist);
+		}
+	} else {
+		low_pass(d);
+	}
+	/* power squelch */
+	if (d->squelch_level) {
+		sr = rms(d->lowpassed, d->lp_len, 1);
+		if (sr < d->squelch_level) {
+			d->squelch_hits++;
+			for (i=0; i< d->lp_len; i++) {
+				d->lowpassed[i] = 0;
+			}
+		} else {
+			d->squelch_hits = 0;
+		}
+	}
+	d->mode_demod(d);  /* lowpassed -> result */
+	if (d->mode_demod == &raw_demod) {
+		return;
+	}
+	/* todo, fm noise squelch */
+	// use nicer filter here too?
+	if (d->post_downsample > 1) {
+		d->result_len = low_pass_simple(d->result, d->result_len, d->post_downsample);}
+	if (d->deemph) {
+		deemph_filter(d);}
+	if (d->dc_block) {
+		dc_block_filter(d);}
+	if (d->rate_out2 > 0) {
+		low_pass_real(d);
+		//arbitrary_resample(d->result, d->result, d->result_len, d->result_len * d->rate_out2 / d->rate_out);
+	}
+}
+
+static void rtlsdr_callback(unsigned char *buf, uint32_t len, void *ctx)
+{
+	int i;
+	struct dongle_state *s = ctx;
+	struct demod_state *d = s->demod_target;
+
+	if (do_exit) {
+		return;}
+	if (!ctx) {
+		return;}
+	if (s->mute) {
+		for (i=0; i<s->mute; i++) {
+			buf[i] = 127;}
+		s->mute = 0;
+	}
+	if (!s->offset_tuning) {
+		rotate_90(buf, len);}
+	for (i=0; i<(int)len; i++) {
+		s->buf16[i] = (int16_t)buf[i] - 127;}
+	pthread_rwlock_wrlock(&d->rw);
+	memcpy(d->lowpassed, s->buf16, 2*len);
+	d->lp_len = len;
+	pthread_rwlock_unlock(&d->rw);
+	safe_cond_signal(&d->ready, &d->ready_m);
+}
+
+static void *dongle_thread_fn(void *arg)
+{
+	struct dongle_state *s = arg;
+	fprintf(stderr, "dongle_thread_fn running\n");
+	rtlsdr_read_async(s->dev, rtlsdr_callback, s, 0, s->buf_len);
+	fprintf(stderr, "dongle_thread_fn exited!\n");
+	return 0;
+}
+
+static void rtl_fm_scan_callback(void)
+{
+	struct controller_state *s = &controller;
+	uint32_t frequency = rtl_fm_get_freq();
+
+	if(!s->scanning)
+		return;
+
+	if(!s->scan_direction) {
+		frequency += s->scan_step;
+		if(frequency > s->scan_max)
+			frequency = s->scan_min;
+	} else {
+		frequency -= s->scan_step;
+		if(frequency < s->scan_min)
+			frequency = s->scan_max;
+	}
+
+	rtl_fm_set_freq(frequency);
+}
+
+static void rtl_fm_scan_end_callback(void)
+{
+	struct controller_state *s = &controller;
+
+	if(!s->scanning)
+		return;
+
+	rtl_fm_scan_stop();
+
+	if(s->scan_callback)
+		s->scan_callback(rtl_fm_get_freq(), s->scan_callback_data);
+}
+
+static void *demod_thread_fn(void *arg)
+{
+	struct demod_state *d = arg;
+	struct output_state *o = d->output_target;
+	fprintf(stderr, "demod_thread_fn running\n");
+	while (!do_exit) {
+		safe_cond_wait(&d->ready, &d->ready_m);
+		pthread_rwlock_wrlock(&d->rw);
+		full_demod(d);
+		pthread_rwlock_unlock(&d->rw);
+		if (d->exit_flag) {
+			do_exit = 1;
+		}
+		if (d->squelch_level) {
+			if(d->squelch_hits > d->conseq_squelch) {
+				d->squelch_hits = d->conseq_squelch + 1;  /* hair trigger */
+				//safe_cond_signal(&controller.hop, &controller.hop_m);
+				rtl_fm_scan_callback();
+				continue;
+			} else if(!d->squelch_hits) {
+				rtl_fm_scan_end_callback();
+			}
+		}
+		pthread_rwlock_wrlock(&o->rw);
+		memcpy(o->result, d->result, 2*d->result_len);
+		o->result_len = d->result_len;
+		pthread_rwlock_unlock(&o->rw);
+		safe_cond_signal(&o->ready, &o->ready_m);
+	}
+	fprintf(stderr, "demod_thread_fn exited!\n");
+	return 0;
+}
+
+static void *output_thread_fn(void *arg)
+{
+	struct output_state *s = arg;
+	fprintf(stderr, "output_thread_fn running\n");
+	while (!do_exit) {
+		// use timedwait and pad out under runs
+		safe_cond_wait(&s->ready, &s->ready_m);
+		pthread_rwlock_rdlock(&s->rw);
+		if(s->output_fn) {
+			s->output_fn(s->result, s->result_len, s->output_fn_data);
+		}
+		pthread_rwlock_unlock(&s->rw);
+	}
+	fprintf(stderr, "output_thread_fn exited!\n");
+	return 0;
+}
+
+static void optimal_settings(int freq, int rate)
+{
+	// giant ball of hacks
+	// seems unable to do a single pass, 2:1
+	int capture_freq, capture_rate;
+	struct dongle_state *d = &dongle;
+	struct demod_state *dm = &demod;
+	struct controller_state *cs = &controller;
+	dm->downsample = (1000000 / dm->rate_in) + 1;
+	if (dm->downsample_passes) {
+		dm->downsample_passes = (int)log2(dm->downsample) + 1;
+		dm->downsample = 1 << dm->downsample_passes;
+	}
+	capture_freq = freq;
+	capture_rate = dm->downsample * dm->rate_in;
+	if (!d->offset_tuning) {
+		capture_freq = freq + capture_rate/4;}
+	capture_freq += cs->edge * dm->rate_in / 2;
+	dm->output_scale = (1<<15) / (128 * dm->downsample);
+	if (dm->output_scale < 1) {
+		dm->output_scale = 1;}
+	if (dm->mode_demod == &fm_demod) {
+		dm->output_scale = 1;}
+	d->freq = (uint32_t)capture_freq;
+	d->rate = (uint32_t)capture_rate;
+}
+
+
+void frequency_range(struct controller_state *s, 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))
+	{
+		s->freqs[s->freq_len] = (uint32_t)i;
+		s->freq_len++;
+		if (s->freq_len >= FREQUENCIES_LIMIT) {
+			break;}
+	}
+	stop[-1] = ':';
+	step[-1] = ':';
+}
+
+void dongle_init(struct dongle_state *s)
+{
+	s->rate = DEFAULT_SAMPLE_RATE;
+	s->gain = AUTO_GAIN; // tenths of a dB
+	s->mute = 0;
+	s->direct_sampling = 0;
+	s->offset_tuning = 0;
+	s->demod_target = &demod;
+}
+
+void demod_init(struct demod_state *s)
+{
+	s->rate_in = DEFAULT_SAMPLE_RATE;
+	s->rate_out = DEFAULT_SAMPLE_RATE;
+	s->squelch_level = 0;
+	s->conseq_squelch = DEFAULT_CONSEQ_SQUELCH;
+	s->terminate_on_squelch = 0;
+	s->squelch_hits = DEFAULT_CONSEQ_SQUELCH + 1;
+	s->downsample_passes = 0;
+	s->comp_fir_size = 0;
+	s->prev_index = 0;
+	s->post_downsample = 1;  // once this works, default = 4
+	s->custom_atan = 0;
+	s->deemph = 0;
+	s->rate_out2 = -1;  // flag for disabled
+	s->mode_demod = &fm_demod;
+	s->pre_j = s->pre_r = s->now_r = s->now_j = 0;
+	s->prev_lpr_index = 0;
+	s->deemph_a = 0;
+	s->now_lpr = 0;
+	s->dc_block = 0;
+	s->dc_avg = 0;
+	pthread_rwlock_init(&s->rw, NULL);
+	pthread_cond_init(&s->ready, NULL);
+	pthread_mutex_init(&s->ready_m, NULL);
+	s->output_target = &output;
+}
+
+void demod_cleanup(struct demod_state *s)
+{
+	pthread_rwlock_destroy(&s->rw);
+	pthread_cond_destroy(&s->ready);
+	pthread_mutex_destroy(&s->ready_m);
+}
+
+void output_init(struct output_state *s)
+{
+	s->rate = DEFAULT_SAMPLE_RATE;
+	s->output_fn = NULL;
+	s->output_fn_data = NULL;
+	pthread_rwlock_init(&s->rw, NULL);
+	pthread_cond_init(&s->ready, NULL);
+	pthread_mutex_init(&s->ready_m, NULL);
+}
+
+void output_cleanup(struct output_state *s)
+{
+	pthread_rwlock_destroy(&s->rw);
+	pthread_cond_destroy(&s->ready);
+	pthread_mutex_destroy(&s->ready_m);
+}
+
+void controller_init(struct controller_state *s)
+{
+	s->freqs[0] = 100000000;
+	s->freq_len = 0;
+	s->edge = 0;
+	s->wb_mode = 0;
+	pthread_cond_init(&s->hop, NULL);
+	pthread_mutex_init(&s->hop_m, NULL);
+}
+
+void controller_cleanup(struct controller_state *s)
+{
+	pthread_cond_destroy(&s->hop);
+	pthread_mutex_destroy(&s->hop_m);
+}
+
+void sanity_checks(void)
+{
+	if (controller.freq_len == 0) {
+		fprintf(stderr, "Please specify a frequency.\n");
+		exit(1);
+	}
+
+	if (controller.freq_len >= FREQUENCIES_LIMIT) {
+		fprintf(stderr, "Too many channels, maximum %i.\n", FREQUENCIES_LIMIT);
+		exit(1);
+	}
+
+	if (controller.freq_len > 1 && demod.squelch_level == 0) {
+		fprintf(stderr, "Please specify a squelch level.  Required for scanning multiple frequencies.\n");
+		exit(1);
+	}
+
+}
+
+int rtl_fm_init(uint32_t freq,
+		uint32_t sample_rate,
+		uint32_t resample_rate,
+		rtl_fm_output_fn_t output_fn,
+		void *output_fn_data)
+{
+	int r = 0;
+
+	dongle_init(&dongle);
+	demod_init(&demod);
+	output_init(&output);
+	controller_init(&controller);
+
+	/*
+	 * Simulate the effects of command line arguments:
+	 *
+	 * -W wbfm -s <sample rate> -r <resample rate>
+	 */
+
+	/* Set initial frequency */
+	controller.freqs[0] = freq;
+	controller.freq_len++;
+
+	/* Set mode to wbfm */
+	controller.wb_mode = 1;
+	demod.mode_demod = &fm_demod;
+	demod.rate_in = 170000;
+	demod.rate_out = 170000;
+	demod.rate_out2 = 32000;
+	demod.custom_atan = 1;
+	//demod.post_downsample = 4;
+	demod.deemph = 1;
+	controller.scan_squelch_count = DEFAULT_CONSEQ_SQUELCH;
+	controller.scan_squelch_level = DEFAULT_SQUELCH_LEVEL;
+	demod.squelch_level = 0;
+
+	/* Adjust frequency for wb mode */
+	controller.freqs[0] += 16000;
+
+	/* Set sample rate */
+	demod.rate_in = sample_rate;
+	demod.rate_out = sample_rate;
+
+	/* Set resample rate */
+	output.rate = (int) resample_rate;
+	demod.rate_out2 = (int) resample_rate;
+
+	/* Set output function pointer */
+	if(output_fn) {
+		output.output_fn = output_fn;
+		output.output_fn_data = output_fn_data;
+	}
+
+	/* quadruple sample_rate to limit to Δθ to ±π/2 */
+	demod.rate_in *= demod.post_downsample;
+
+	if (!output.rate) {
+		output.rate = demod.rate_out;
+	}
+
+	sanity_checks();
+
+	if (controller.freq_len > 1) {
+		demod.terminate_on_squelch = 0;
+	}
+
+	ACTUAL_BUF_LENGTH = lcm_post[demod.post_downsample] * DEFAULT_BUF_LENGTH;
+
+	dongle.dev_index = verbose_device_search("0");
+	if (dongle.dev_index < 0) {
+		return -1;
+	}
+
+	r = rtlsdr_open(&dongle.dev, (uint32_t)dongle.dev_index);
+	if (r < 0) {
+		fprintf(stderr, "Failed to open rtlsdr device #%d.\n", dongle.dev_index);
+		return r;
+	}
+
+	if (demod.deemph) {
+		demod.deemph_a = (int)round(1.0/((1.0-exp(-1.0/(demod.rate_out * 75e-6)))));
+	}
+
+	/* Set the tuner gain */
+	if (dongle.gain == AUTO_GAIN) {
+		verbose_auto_gain(dongle.dev);
+	} else {
+		dongle.gain = nearest_gain(dongle.dev, dongle.gain);
+		verbose_gain_set(dongle.dev, dongle.gain);
+	}
+
+	verbose_ppm_set(dongle.dev, dongle.ppm_error);
+
+	//r = rtlsdr_set_testmode(dongle.dev, 1);
+
+	return r;
+}
+
+void rtl_fm_start(void)
+{
+	struct controller_state *s = &controller;
+
+	/*
+	 * A bunch of the following is pulled from the controller_thread_fn,
+	 * which has been removed.
+	 */
+
+	/* Reset endpoint before we start reading from it (mandatory) */
+	verbose_reset_buffer(dongle.dev);
+
+	/* set up primary channel */
+	optimal_settings(s->freqs[0], demod.rate_in);
+	if (dongle.direct_sampling) {
+		verbose_direct_sampling(dongle.dev, 1);}
+	if (dongle.offset_tuning) {
+		verbose_offset_tuning(dongle.dev);}
+
+	/* Set the frequency */
+	verbose_set_frequency(dongle.dev, dongle.freq);
+	fprintf(stderr, "Oversampling input by: %ix.\n", demod.downsample);
+	fprintf(stderr, "Oversampling output by: %ix.\n", demod.post_downsample);
+	fprintf(stderr, "Buffer size: %0.2fms\n",
+		1000 * 0.5 * (float)ACTUAL_BUF_LENGTH / (float)dongle.rate);
+
+	/* Set the sample rate */
+	verbose_set_sample_rate(dongle.dev, dongle.rate);
+	fprintf(stderr, "Output at %u Hz.\n", demod.rate_in/demod.post_downsample);
+	usleep(100000);
+
+	rtl_fm_scan_stop();
+
+	do_exit = 0;
+	pthread_create(&output.thread, NULL, output_thread_fn, (void *)(&output));
+	pthread_create(&demod.thread, NULL, demod_thread_fn, (void *)(&demod));
+	pthread_create(&dongle.thread, NULL, dongle_thread_fn, (void *)(&dongle));
+}
+
+void rtl_fm_set_freq(uint32_t freq)
+{
+	struct controller_state *s = &controller;
+
+	if(s->freqs[0] == freq)
+		return;
+
+	s->freqs[0] = freq;
+	s->freq_len = 1;
+
+	if (s->wb_mode) {
+		s->freqs[0] += 16000;
+	}
+
+	optimal_settings(s->freqs[0], demod.rate_in);
+	if (dongle.offset_tuning) {
+		verbose_offset_tuning(dongle.dev);
+	}
+	rtlsdr_set_center_freq(dongle.dev, dongle.freq);
+
+	// It does not look like refreshing the sample rate is desirable
+	// (e.g. the scanning code in the removed controller thread function
+	// did not do it), and behavior seemed a bit less robust with it
+	// present.  However, I am leaving this here as a reminder to revisit
+	// via some more testing.
+	//rtlsdr_set_sample_rate(dongle.dev, dongle.rate);
+
+	// This triggers a mute during the frequency change
+	dongle.mute = BUFFER_DUMP;
+
+	if(s->freq_callback)
+		s->freq_callback(freq, s->freq_callback_data);
+}
+
+void rtl_fm_set_freq_callback(void (*callback)(uint32_t, void *),
+			      void *data)
+{
+	struct controller_state *s = &controller;
+
+	s->freq_callback = callback;
+	s->freq_callback_data = data;
+}
+
+uint32_t rtl_fm_get_freq(void)
+{
+	struct controller_state *s = &controller;
+	uint32_t frequency = s->freqs[0];
+
+	if (s->wb_mode)
+		frequency -= 16000;
+
+	return frequency;
+}
+
+void rtl_fm_stop(void)
+{
+	rtl_fm_scan_stop();
+
+	rtlsdr_cancel_async(dongle.dev);
+	do_exit = 1;
+	pthread_join(dongle.thread, NULL);
+	safe_cond_signal(&demod.ready, &demod.ready_m);
+	pthread_join(demod.thread, NULL);
+	safe_cond_signal(&output.ready, &output.ready_m);
+	pthread_join(output.thread, NULL);
+}
+
+void rtl_fm_scan_start(int direction,
+		       void (*callback)(uint32_t, void *),
+		       void *data,
+		       uint32_t step,
+		       uint32_t min,
+		       uint32_t max)
+{
+	struct controller_state *s = &controller;
+	struct demod_state *dm = &demod;
+	uint32_t frequency = rtl_fm_get_freq();
+
+	if(s->scanning && s->scan_direction == direction)
+		return;
+
+	s->scanning = 1;
+	s->scan_direction = direction;
+	s->scan_callback = callback;
+	s->scan_callback_data = data;
+	s->scan_step = step;
+	s->scan_min = min;
+	s->scan_max = max;
+
+	/* Start scan by stepping in the desired direction */
+	if(!direction) {
+		frequency += s->scan_step;
+		if(frequency > s->scan_max)
+			frequency = s->scan_min;
+	} else {
+		frequency -= s->scan_step;
+		if(frequency < s->scan_min)
+			frequency = s->scan_max;
+	}
+
+	rtl_fm_set_freq(frequency);
+
+	dm->conseq_squelch = s->scan_squelch_count;
+	dm->squelch_hits = s->scan_squelch_count + 1;
+	dm->squelch_level = s->scan_squelch_level;
+}
+
+void rtl_fm_scan_stop(void)
+{
+	struct controller_state *s = &controller;
+	struct demod_state *dm = &demod;
+
+	s->scanning = 0;
+
+	dm->squelch_hits = s->scan_squelch_count + 1;
+	dm->squelch_level = 0;
+}
+
+void rtl_fm_scan_set_squelch_level(int level)
+{
+	struct controller_state *s = &controller;
+
+	s->scan_squelch_level = level;
+}
+
+void rtl_fm_scan_set_squelch_limit(int count)
+{
+	struct controller_state *s = &controller;
+
+	s->scan_squelch_count = count;
+}
+
+void rtl_fm_cleanup(void)
+{
+	//dongle_cleanup(&dongle);
+	demod_cleanup(&demod);
+	output_cleanup(&output);
+	controller_cleanup(&controller);
+
+	rtlsdr_close(dongle.dev);
+}
+
+// vim: tabstop=8:softtabstop=8:shiftwidth=8:noexpandtab