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sdr_soapy.c
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sdr_soapy.c
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// Part of dump1090, a Mode S message decoder for RTLSDR devices.
//
// sdr_soapy.c: SoapySDR support
//
// Copyright (c) 2014-2017 Oliver Jowett <oliver@mutability.co.uk>
// Copyright (c) 2017 FlightAware LLC
//
// This file is free software: you may copy, redistribute 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 file 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/>.
#include "readsb.h"
#include "sdr_soapy.h"
#include <SoapySDR/Version.h>
#include <SoapySDR/Device.h>
#include <SoapySDR/Formats.h>
static struct {
SoapySDRDevice *dev;
SoapySDRStream *stream;
iq_convert_fn converter;
struct converter_state *converter_state;
size_t channel;
const char* antenna;
double bandwidth;
bool enable_agc;
int num_gain_elements;
char **gain_elements;
SoapySDRRange gain_range;
int current_gain_step;
} SOAPY;
static struct timespec thread_cpu;
// Polyfill some differences between SoapySDR 0.7 and 0.8
#if !defined(SOAPY_SDR_API_VERSION) || (SOAPY_SDR_API_VERSION < 0x00080000)
static void polyfill_SoapySDR_free(void *ignored)
{
(void) ignored;
}
static SoapySDRStream *polyfill_SoapySDRDevice_setupStream(SoapySDRDevice *device,
const int direction,
const char *format,
const size_t *channels,
const size_t numChans,
const SoapySDRKwargs *args)
{
SoapySDRStream *result;
if (SoapySDRDevice_setupStream(device, &result, direction, format, channels, numChans, args) == 0)
return result;
else
return NULL;
}
#define SoapySDR_free polyfill_SoapySDR_free
#define SoapySDRDevice_setupStream polyfill_SoapySDRDevice_setupStream
#endif /* pre-0.8 API */
//
// =============================== SoapySDR handling ==========================
//
void soapyInitConfig()
{
SOAPY.dev = NULL;
SOAPY.stream = NULL;
SOAPY.converter = NULL;
SOAPY.converter_state = NULL;
SOAPY.channel = 0;
SOAPY.antenna = NULL;
SOAPY.bandwidth = 0;
SOAPY.enable_agc = false;
SOAPY.num_gain_elements = 0;
SOAPY.gain_elements = NULL;
}
/*void soapyShowHelp()
{
printf(" SoapySDR-specific options (use with --device-type soapy)\n");
printf("\n");
printf("--device <string> select/configure device\n");
printf("--channel <num> select channel if device supports multiple channels (default: 0)\n");
printf("--antenna <string> select antenna (default depends on device)\n");
printf("--bandwidth <hz> set the baseband filter width (default: 3MHz, SDRPlay: 5MHz)\n");
printf("--enable-agc enable Automatic Gain Control if supported by device\n");
printf("--gain-element <name>:<db> set gain in dB for a named gain element\n");
printf("\n");
}*/
bool soapyHandleOption(int key, char *arg)
{
switch (key) {
case OptSoapyAntenna:
SOAPY.antenna = strdup(arg);
break;
case OptSoapyBandwith:
SOAPY.bandwidth = atoi(arg);
break;
case OptSoapyEnableAgc:
SOAPY.enable_agc = true;
break;
case OptSoapyGainElement:
++SOAPY.num_gain_elements;
if (! (SOAPY.gain_elements = realloc(SOAPY.gain_elements, SOAPY.num_gain_elements * sizeof(*SOAPY.gain_elements))) ) {
perror("realloc");
abort();
}
if (! (SOAPY.gain_elements[SOAPY.num_gain_elements-1] = strdup(arg)) ) {
perror("strdup");
abort();
}
break;
default:
return false;
}
return true;
}
static void soapyShowDevices(SoapySDRKwargs *results, size_t length)
{
for (size_t i = 0; i < length; ++i) {
fprintf(stderr, " #%zu: ", i);
for (size_t j = 0; j < results[i].size; ++j) {
if (j) fprintf(stderr, ", ");
fprintf(stderr, "%s=%s", results[i].keys[j], results[i].vals[j]);
}
fprintf(stderr, "\n");
}
}
static void soapyShowAllDevices()
{
size_t length = 0;
SoapySDRKwargs *results = SoapySDRDevice_enumerate(NULL, &length);
soapyShowDevices(results, length);
SoapySDRKwargsList_clear(results, length);
}
bool soapyOpen(void)
{
size_t length = 0;
SoapySDRKwargs *results = SoapySDRDevice_enumerateStrArgs(Modes.dev_name ? Modes.dev_name : "", &length);
if (length == 0) {
SoapySDRKwargsList_clear(results, length);
fprintf(stderr, "soapy: no matching devices found; available devices:\n");
soapyShowAllDevices();
return false;
}
if (length > 1) {
fprintf(stderr, "soapy: more than one matching device found; matching devices:\n");
soapyShowDevices(results, length);
SoapySDRKwargsList_clear(results, length);
fprintf(stderr, "soapy: please select a single device with --device\n");
return false;
}
fprintf(stderr, "soapy: selected device: ");
for (size_t j = 0; j < results[0].size; j++) {
if (j) fprintf(stderr, ", ");
fprintf(stderr, "%s=%s", results[0].keys[j], results[0].vals[j]);
}
fprintf(stderr, "\n");
SoapySDRKwargsList_clear(results, length);
SOAPY.dev = SoapySDRDevice_makeStrArgs(Modes.dev_name ? Modes.dev_name : "");
if (!SOAPY.dev) {
fprintf(stderr, "soapy: failed to create device: %s\n", SoapySDRDevice_lastError());
return false;
}
SoapySDRKwargs result = SoapySDRDevice_getHardwareInfo(SOAPY.dev);
if (result.size > 0) {
fprintf(stderr, "soapy: hardware info: ");
for (size_t i = 0; i < result.size; ++i) {
if (i) fprintf(stderr, ", ");
fprintf(stderr, "%s=%s", result.keys[i], result.vals[i]);
}
fprintf(stderr, "\n");
}
SoapySDRKwargs_clear(&result);
char* driver_key = SoapySDRDevice_getDriverKey(SOAPY.dev);
if (driver_key) {
fprintf(stderr, "soapy: driver key: %s\n", driver_key);
// Apply driver-specific defaults
if (!strcmp(driver_key, "SDRplay")) {
// Default to 5MHz bandwidth
if (SOAPY.bandwidth == 0)
SOAPY.bandwidth = 5.0e6;
}
SoapySDR_free(driver_key);
}
char* hw_key = SoapySDRDevice_getHardwareKey(SOAPY.dev);
if (hw_key) {
fprintf(stderr, "soapy: hardware key: %s\n", hw_key);
SoapySDR_free(hw_key);
}
//
// Apply generic defaults
//
if (SOAPY.bandwidth == 0) {
SOAPY.bandwidth = 3.0e6;
}
//
// Configure everything
//
if (SOAPY.channel) {
size_t supported_channels = SoapySDRDevice_getNumChannels(SOAPY.dev, SOAPY_SDR_RX);
if (SOAPY.channel >= supported_channels) {
fprintf(stderr, "soapy: device only supports %zu channels, not %zu\n", supported_channels, SOAPY.channel + 1);
goto error;
}
}
if (SoapySDRDevice_setSampleRate(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, Modes.sample_rate) != 0) {
fprintf(stderr, "soapy: setSampleRate failed: %s\n", SoapySDRDevice_lastError());
goto error;
}
if (SOAPY.antenna && SoapySDRDevice_setAntenna(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, SOAPY.antenna) != 0) {
fprintf(stderr, "soapy: setAntenna(%s) failed: %s\n", SOAPY.antenna, SoapySDRDevice_lastError());
length = 0;
char** available_antennas = SoapySDRDevice_listAntennas(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, &length);
fprintf(stderr, "soapy: available antennas: ");
for (size_t i = 0; i < length; i++) {
fprintf(stderr, "%s", available_antennas[i]);
if (i+1 < length) fprintf(stderr, ", ");
}
fprintf(stderr, "\n");
if (available_antennas)
SoapySDRStrings_clear(&available_antennas, length);
goto error;
}
if (SoapySDRDevice_setFrequency(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, Modes.freq, NULL) != 0) {
fprintf(stderr, "soapy: setFrequency failed: %s\n", SoapySDRDevice_lastError());
goto error;
}
SOAPY.gain_range = SoapySDRDevice_getGainRange(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel);
if (SOAPY.gain_range.step <= 0)
SOAPY.gain_range.step = 1.0;
else if (SOAPY.gain_range.step <= 0.1)
SOAPY.gain_range.step = 0.1;
bool has_agc = SoapySDRDevice_hasGainMode(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel);
if (SOAPY.enable_agc) {
if (has_agc) {
if (SoapySDRDevice_setGainMode(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, 1) != 0) {
fprintf(stderr, "soapy: setGainMode failed: %s\n", SoapySDRDevice_lastError());
goto error;
}else {
fprintf(stdout, "soapy: AGC enabled!\n");
}
}
else {
fprintf(stderr, "soapy: device does not support enabling AGC\n");
goto error;
}
} else {
// Manual gain path
if (has_agc) {
if (SoapySDRDevice_setGainMode(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, 0) != 0) {
fprintf(stderr, "soapy: setGainMode failed: %s\n", SoapySDRDevice_lastError());
goto error;
}
}
//double gain = (Modes.gain == MODES_DEFAULT_GAIN ? SOAPY.gain_range.maximum : Modes.gain);
double gain = (Modes.gain == MODES_MAX_GAIN ? SOAPY.gain_range.maximum : Modes.gain);
if (SoapySDRDevice_setGain(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, gain) < 0) {
fprintf(stderr, "soapy: setGain(%.1fdB) failed\n", gain);
goto error;
}
for (int i = 0; i < SOAPY.num_gain_elements; ++i) {
char *element = SOAPY.gain_elements[i];
char *sep = strchr(element, ':');
printf("number gains: %i\n", SOAPY.num_gain_elements); // hier gehts nicht mehr weiter
if (!sep || !sep[1]) {
fprintf(stderr, "soapy: don't understand a gain element setting of '%s' (should be formatted as <element>:<db>)\n", element);
goto error;
}
*sep = 0;
char *endptr = NULL;
double gain = strtod(sep + 1, &endptr);
if ((gain == 0 && !endptr) || *endptr) {
fprintf(stderr, "soapy: don't understand a gain value of '%s' for gain element %s (should be a floating-point gain in dB)\n", sep + 1, element);
goto error;
}
if (SoapySDRDevice_setGainElement(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, element, gain) != 0) {
fprintf(stderr, "soapy: setGainElement(%s,%.1fdB) failed: %s\n", element, gain, SoapySDRDevice_lastError());
goto error;
}
}
}
SOAPY.current_gain_step = (int) round( (SoapySDRDevice_getGain(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) - SOAPY.gain_range.minimum) / SOAPY.gain_range.step );
//if (Modes.adaptive_range_target == 0)
// Modes.adaptive_range_target = (SOAPY.gain_range.maximum - SOAPY.gain_range.minimum) * 0.6; // just a wild guess
if (SoapySDRDevice_setBandwidth(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, SOAPY.bandwidth) != 0) {
fprintf(stderr, "soapy: setBandwidth(%.1f MHz) failed: %s\n", SOAPY.bandwidth / 1e6, SoapySDRDevice_lastError());
goto error;
}
//
// Done configuring, report the final device state
//
fprintf(stderr, "soapy: total gain: %.1fdB",
SoapySDRDevice_getGain(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel));
char** gain_elements = SoapySDRDevice_listGains(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, &length);
if (gain_elements) {
for (size_t i = 0; i < length; i++) {
fprintf(stderr, "; %s=%.1fdB", gain_elements[i],
SoapySDRDevice_getGainElement(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, gain_elements[i]));
}
SoapySDRStrings_clear(&gain_elements, length);
}
fprintf(stderr, "\n");
fprintf(stderr, "soapy: frequency: %.1f MHz\n",
SoapySDRDevice_getFrequency(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) / 1e6);
fprintf(stderr, "soapy: sample rate: %.1f MHz\n",
SoapySDRDevice_getSampleRate(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) / 1e6);
fprintf(stderr, "soapy: bandwidth: %.1f MHz\n",
SoapySDRDevice_getBandwidth(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) / 1e6);
if (has_agc) {
fprintf(stderr, "soapy: AGC mode: %s\n",
SoapySDRDevice_getGainMode(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) ? "automatic" : "manual");
}
char* antenna = SoapySDRDevice_getAntenna(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel);
if (antenna) {
fprintf(stderr, "soapy: antenna: %s\n", antenna);
SoapySDR_free(antenna);
}
if (SoapySDRDevice_hasDCOffset(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel)) {
fprintf(stderr, "soapy: DC offset mode: %s\n",
SoapySDRDevice_getDCOffsetMode(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) ? "automatic" : "manual");
double offsetI;
double offsetQ;
if (!SoapySDRDevice_getDCOffset(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, &offsetI, &offsetQ)) {
fprintf(stderr, "soapy: DC offset: I=%.3f Q=%.3f\n", offsetI, offsetQ);
}
}
if (SoapySDRDevice_hasIQBalance(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel)) {
#ifdef SOAPY_SDR_API_HAS_IQ_BALANCE_MODE
fprintf(stderr, "soapy: IQ balance mode: %s\n",
SoapySDRDevice_getIQBalanceMode(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel) ? "automatic" : "manual");
#endif
double balanceI;
double balanceQ;
if (!SoapySDRDevice_getIQBalance(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, &balanceI, &balanceQ)) {
fprintf(stderr, "soapy: IQ balance is I=%.1f, Q=%.1f\n", balanceI, balanceQ);
}
}
if (SoapySDRDevice_hasFrequencyCorrection(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel)) {
fprintf(stderr, "soapy: freq correction: %.1f ppm\n",
SoapySDRDevice_getFrequencyCorrection(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel));
}
size_t channels[1] = { SOAPY.channel };
SoapySDRKwargs stream_args = { 0, NULL, NULL };
if ((SOAPY.stream = SoapySDRDevice_setupStream(SOAPY.dev, SOAPY_SDR_RX, SOAPY_SDR_CS16, channels, 1, &stream_args)) == NULL) {
fprintf(stderr, "soapy: setupStream failed: %s\n", SoapySDRDevice_lastError());
goto error;
}
SOAPY.converter = init_converter(INPUT_SC16,
Modes.sample_rate,
Modes.dc_filter,
&SOAPY.converter_state);
if (!SOAPY.converter) {
fprintf(stderr, "soapy: can't initialize sample converter\n");
goto error;
}
return true;
error:
if (SOAPY.dev != NULL) {
SoapySDRDevice_unmake(SOAPY.dev);
SOAPY.dev = NULL;
}
return false;
}
void soapyRun()
{
if (!SOAPY.dev) {
return;
}
start_cpu_timing(&thread_cpu);
if (SoapySDRDevice_activateStream(SOAPY.dev, SOAPY.stream, 0, 0, 0) != 0) {
fprintf(stderr, "soapy: activateStream failed: %s\n", SoapySDRDevice_lastError());
return;
}
struct mag_buf *outbuf;
struct mag_buf *lastbuf;
uint32_t slen;
unsigned next_free_buffer;
unsigned free_bufs;
int64_t block_duration;
static int dropping = 0;
static uint64_t sampleCounter = 0;
static int antiSpam;
static int antiSpam2;
uint8_t* buf;
const int buffer_elements = Modes.sdr_buf_samples;
buf = malloc(buffer_elements * 4);
while (!Modes.exit) {
int flags;
long long timeNs;
int32_t samples_read = SoapySDRDevice_readStream(SOAPY.dev, SOAPY.stream, (void *) &buf, buffer_elements, &flags, &timeNs, 5000000);
if (samples_read == 0) {
usleep(500);
continue;
}
if (samples_read < 0) {
fprintf(stderr, "soapy: readStream failed: %s\n", SoapySDRDevice_lastError());
break;
}
int64_t sysMicroseconds = mono_micro_seconds();
int64_t sysTimestamp = mstime();
// Lock the data buffer variables before accessing them
lockReader();
next_free_buffer = (Modes.first_free_buffer + 1) % MODES_MAG_BUFFERS;
outbuf = &Modes.mag_buffers[Modes.first_free_buffer];
lastbuf = &Modes.mag_buffers[(Modes.first_free_buffer + MODES_MAG_BUFFERS - 1) % MODES_MAG_BUFFERS];
free_bufs = (Modes.first_filled_buffer - next_free_buffer + MODES_MAG_BUFFERS) % MODES_MAG_BUFFERS;
unlockReader();
slen = (uint32_t) samples_read;
if (slen != Modes.sdr_buf_samples) {
fprintf(stderr, "weirdness: soapysdr gave us a block with an unusual size (got %u samples, expected %u samples)\n",
(unsigned) slen, (unsigned) Modes.sdr_buf_samples);
if (slen > Modes.sdr_buf_samples) {
// wat?! Discard the start.
unsigned discard = slen - Modes.sdr_buf_samples;
outbuf->dropped += discard;
buf += discard * 2;
slen -= discard * 2;
}
}
if (free_bufs == 0 || (dropping && free_bufs < MODES_MAG_BUFFERS / 2)) {
// FIFO is full. Drop this block.
dropping = 1;
outbuf->dropped += slen;
sampleCounter += slen;
// make extra sure that the decode thread isn't sleeping
wakeDecode();
if (--antiSpam <= 0 && !Modes.exit) {
fprintf(stderr, "FIFO dropped, suppressing this message for 30 seconds.\n");
antiSpam = 300;
}
continue;
}
dropping = false;
// Compute the sample timestamp and system timestamp for the start of the block
outbuf->sampleTimestamp = sampleCounter * 12e6 / Modes.sample_rate;
sampleCounter += slen;
if (Modes.debug_sampleCounter && --antiSpam2 <= 0) {
fprintf(stderr, "sampleTimestamp: %020llu\n", (unsigned long long) outbuf->sampleTimestamp);
antiSpam2 = 3000;
}
// Get the approx system time for the start of this block
block_duration = 1e3 * slen / Modes.sample_rate;
outbuf->sysTimestamp = sysTimestamp;
outbuf->sysMicroseconds = sysMicroseconds;
outbuf->sysTimestamp -= block_duration;
outbuf->sysMicroseconds -= block_duration * 1000;
// Copy trailing data from last block (or reset if not valid)
if (outbuf->dropped == 0) {
memcpy(outbuf->data, lastbuf->data + lastbuf->length, Modes.trailing_samples * sizeof (uint16_t));
} else {
memset(outbuf->data, 0, Modes.trailing_samples * sizeof (uint16_t));
}
// Convert the new data
outbuf->length = slen;
SOAPY.converter(buf, &outbuf->data[Modes.trailing_samples], slen, SOAPY.converter_state, &outbuf->mean_level, &outbuf->mean_power);
// Push the new data to the demodulation thread
lockReader();
Modes.mag_buffers[next_free_buffer].dropped = 0;
Modes.mag_buffers[next_free_buffer].length = 0; // just in case
Modes.first_free_buffer = next_free_buffer;
// accumulate CPU while holding the mutex, and restart measurement
end_cpu_timing(&thread_cpu, &Modes.reader_cpu_accumulator);
start_cpu_timing(&thread_cpu);
wakeDecode();
unlockReader();
}
}
void soapyClose()
{
if (SOAPY.stream) {
SoapySDRDevice_closeStream(SOAPY.dev, SOAPY.stream);
SOAPY.stream = NULL;
}
if (SOAPY.dev) {
SoapySDRDevice_unmake(SOAPY.dev);
SOAPY.dev = NULL;
}
if (SOAPY.converter) {
cleanup_converter(&SOAPY.converter_state);
SOAPY.converter = NULL;
SOAPY.converter_state = NULL;
}
for (int i = 0; i < SOAPY.num_gain_elements; ++i) {
free(SOAPY.gain_elements[i]);
}
free(SOAPY.gain_elements);
SOAPY.gain_elements = NULL;
}
//
// This is a bit horrible; since soapy doesn't tell us the actual device steps,
// we track the last requested gain step ourselves and always report that as
// the current step. Otherwise adaptive gain will get confused if there are
// any step values that can't actually be set, i.e.:
//
// current gain is at step 4
// adaptive wants to increase gain, set gain = current + 1 = 5
// request gain 5, hardware can't actually do that, nearest is step 4
// adaptive wants to increase gain further, set gain = current + 1 = 5
// we make no progress
int soapyGetGain() {
return SOAPY.current_gain_step;
}
int soapyGetMaxGain() {
return (int) ceil( (SOAPY.gain_range.maximum - SOAPY.gain_range.minimum) / SOAPY.gain_range.step );
}
double soapyGetGainDb(int step) {
double gain = SOAPY.gain_range.minimum + step * SOAPY.gain_range.step;
if (gain < SOAPY.gain_range.minimum)
gain = SOAPY.gain_range.minimum;
if (gain > SOAPY.gain_range.maximum)
gain = SOAPY.gain_range.maximum;
return gain;
}
int soapySetGain(int step) {
double gainDb = soapyGetGainDb(step);
if (SoapySDRDevice_setGain(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, gainDb) != 0) {
fprintf(stderr, "soapy: setGain(%.1fdB) failed: %s\n", gainDb, SoapySDRDevice_lastError());
return -1;
}
fprintf(stderr, "soapy: total gain set to %.1fdB", SoapySDRDevice_getGain(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel));
size_t length = 0;
char** gain_elements = SoapySDRDevice_listGains(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, &length);
for (size_t i = 0; i < length; i++) {
fprintf(stderr, "; %s=%.1fdB", gain_elements[i],
SoapySDRDevice_getGainElement(SOAPY.dev, SOAPY_SDR_RX, SOAPY.channel, gain_elements[i]));
}
if (gain_elements)
SoapySDRStrings_clear(&gain_elements, length);
fprintf(stderr, "\n");
SOAPY.current_gain_step = step;
return step;
}