522 lines
18 KiB
C
522 lines
18 KiB
C
// Part of dump1090, a Mode S message decoder for RTLSDR devices.
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//
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// sdr_bladerf.c: bladeRF support
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//
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// Copyright (c) 2017 FlightAware LLC
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//
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// This file is free software: you may copy, redistribute and/or modify it
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// under the terms of the GNU General Public License as published by the
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// Free Software Foundation, either version 2 of the License, or (at your
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// option) any later version.
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//
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// This file is distributed in the hope that it will be useful, but
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// WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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// General Public License for more details.
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//
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// You should have received a copy of the GNU General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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#include "dump1090.h"
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#include "sdr_bladerf.h"
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#include <libbladeRF.h>
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#include <inttypes.h>
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#if !defined(LIBBLADERF_API_VERSION) || (LIBBLADERF_API_VERSION < 0x01060100)
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#error This libbladeRF is too old, upgrade or disable bladerf support
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#endif
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// Polyfill for the older bladerf API
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#if LIBBLADERF_API_VERSION < 0x02000000
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typedef unsigned int bladerf_frequency;
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#endif
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static struct {
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const char *device_str;
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const char *fpga_path;
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unsigned decimation;
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bladerf_lpf_mode lpf_mode;
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unsigned lpf_bandwidth;
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struct bladerf *device;
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iq_convert_fn converter;
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struct converter_state *converter_state;
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unsigned block_size;
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} BladeRF;
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void bladeRFInitConfig()
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{
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BladeRF.device_str = NULL;
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BladeRF.fpga_path = NULL;
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BladeRF.decimation = 1;
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BladeRF.lpf_mode = BLADERF_LPF_NORMAL;
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BladeRF.lpf_bandwidth = 1750000;
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BladeRF.device = NULL;
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}
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bool bladeRFHandleOption(int argc, char **argv, int *jptr)
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{
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int j = *jptr;
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bool more = (j+1 < argc);
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if (!strcmp(argv[j], "--bladerf-fpga") && more) {
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BladeRF.fpga_path = strdup(argv[++j]);
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} else if (!strcmp(argv[j], "--bladerf-decimation") && more) {
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BladeRF.decimation = atoi(argv[++j]);
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} else if (!strcmp(argv[j], "--bladerf-bandwidth") && more) {
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++j;
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if (!strcasecmp(argv[j], "bypass")) {
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BladeRF.lpf_mode = BLADERF_LPF_BYPASSED;
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} else {
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BladeRF.lpf_mode = BLADERF_LPF_NORMAL;
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BladeRF.lpf_bandwidth = atoi(argv[j]);
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}
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} else {
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return false;
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}
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*jptr = j;
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return true;
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}
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void bladeRFShowHelp()
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{
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printf(" bladeRF-specific options (use with --device-type bladerf)\n");
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printf("\n");
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printf("--device <ident> select device by bladeRF 'device identifier'\n");
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printf("--bladerf-fpga <path> use alternative FPGA bitstream ('' to disable FPGA load)\n");
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printf("--bladerf-decimation <N> assume FPGA decimates by a factor of N\n");
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printf("--bladerf-bandwidth <hz> set LPF bandwidth ('bypass' to bypass the LPF)\n");
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printf("\n");
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}
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static int lna_gain_db(bladerf_lna_gain gain)
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{
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switch (gain) {
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case BLADERF_LNA_GAIN_BYPASS:
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return 0;
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case BLADERF_LNA_GAIN_MID:
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return BLADERF_LNA_GAIN_MID_DB;
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case BLADERF_LNA_GAIN_MAX:
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return BLADERF_LNA_GAIN_MAX_DB;
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default:
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return -1;
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}
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}
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static void show_config()
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{
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int status;
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unsigned rate;
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bladerf_frequency freq;
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bladerf_lpf_mode lpf_mode;
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unsigned lpf_bw;
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bladerf_lna_gain lna_gain;
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int rxvga1_gain;
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int rxvga2_gain;
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int16_t lms_dc_i, lms_dc_q;
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int16_t fpga_phase, fpga_gain;
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struct bladerf_lms_dc_cals dc_cals;
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if ((status = bladerf_get_sample_rate(BladeRF.device, BLADERF_MODULE_RX, &rate)) < 0 ||
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(status = bladerf_get_frequency(BladeRF.device, BLADERF_MODULE_RX, &freq)) < 0 ||
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(status = bladerf_get_lpf_mode(BladeRF.device, BLADERF_MODULE_RX, &lpf_mode)) < 0 ||
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(status = bladerf_get_bandwidth(BladeRF.device, BLADERF_MODULE_RX, &lpf_bw)) < 0 ||
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(status = bladerf_get_lna_gain(BladeRF.device, &lna_gain)) < 0 ||
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(status = bladerf_get_rxvga1(BladeRF.device, &rxvga1_gain)) < 0 ||
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(status = bladerf_get_rxvga2(BladeRF.device, &rxvga2_gain)) < 0 ||
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(status = bladerf_get_correction(BladeRF.device, BLADERF_MODULE_RX, BLADERF_CORR_LMS_DCOFF_I, &lms_dc_i)) < 0 ||
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(status = bladerf_get_correction(BladeRF.device, BLADERF_MODULE_RX, BLADERF_CORR_LMS_DCOFF_Q, &lms_dc_q)) < 0 ||
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(status = bladerf_get_correction(BladeRF.device, BLADERF_MODULE_RX, BLADERF_CORR_FPGA_PHASE, &fpga_phase)) < 0 ||
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(status = bladerf_get_correction(BladeRF.device, BLADERF_MODULE_RX, BLADERF_CORR_FPGA_GAIN, &fpga_gain)) < 0 ||
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(status = bladerf_lms_get_dc_cals(BladeRF.device, &dc_cals)) < 0) {
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fprintf(stderr, "bladeRF: couldn't read back device configuration\n");
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return;
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}
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fprintf(stderr, "bladeRF: sampling rate: %.1f MHz\n", rate/1e6);
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fprintf(stderr, "bladeRF: frequency: %.1f MHz\n", freq/1e6);
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fprintf(stderr, "bladeRF: LNA gain: %ddB\n", lna_gain_db(lna_gain));
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fprintf(stderr, "bladeRF: RXVGA1 gain: %ddB\n", rxvga1_gain);
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fprintf(stderr, "bladeRF: RXVGA2 gain: %ddB\n", rxvga2_gain);
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switch (lpf_mode) {
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case BLADERF_LPF_NORMAL:
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fprintf(stderr, "bladeRF: LPF bandwidth: %.2f MHz\n", lpf_bw/1e6);
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break;
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case BLADERF_LPF_BYPASSED:
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fprintf(stderr, "bladeRF: LPF bypassed\n");
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break;
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case BLADERF_LPF_DISABLED:
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fprintf(stderr, "bladeRF: LPF disabled\n");
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break;
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default:
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fprintf(stderr, "bladeRF: LPF in unknown state\n");
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break;
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}
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fprintf(stderr, "bladeRF: calibration settings:\n");
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fprintf(stderr, " LMS DC adjust: I=%d Q=%d\n", lms_dc_i, lms_dc_q);
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fprintf(stderr, " FPGA phase adjust: %+.3f degrees\n", fpga_phase * 10.0 / 4096);
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fprintf(stderr, " FPGA gain adjust: %+.3f\n", fpga_gain * 1.0 / 4096);
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fprintf(stderr, " LMS LPF tuning: %d\n", dc_cals.lpf_tuning);
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fprintf(stderr, " LMS RX LPF filter: I=%d Q=%d\n", dc_cals.rx_lpf_i, dc_cals.rx_lpf_q);
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fprintf(stderr, " LMS RXVGA2 DC ref: %d\n", dc_cals.dc_ref);
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fprintf(stderr, " LMS RXVGA2A: I=%d Q=%d\n", dc_cals.rxvga2a_i, dc_cals.rxvga2a_q);
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fprintf(stderr, " LMS RXVGA2B: I=%d Q=%d\n", dc_cals.rxvga2b_i, dc_cals.rxvga2b_q);
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}
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bool bladeRFOpen()
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{
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if (BladeRF.device) {
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return true;
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}
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int status;
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bladerf_set_usb_reset_on_open(true);
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if ((status = bladerf_open(&BladeRF.device, Modes.dev_name)) < 0) {
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fprintf(stderr, "Failed to open bladeRF: %s\n", bladerf_strerror(status));
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goto error;
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}
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const char *fpga_path;
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if (BladeRF.fpga_path) {
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fpga_path = BladeRF.fpga_path;
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} else {
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bladerf_fpga_size size;
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if ((status = bladerf_get_fpga_size(BladeRF.device, &size)) < 0) {
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fprintf(stderr, "bladerf_get_fpga_size failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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switch (size) {
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case BLADERF_FPGA_40KLE:
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fpga_path = "/usr/share/Nuand/bladeRF/hostedx40.rbf";
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break;
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case BLADERF_FPGA_115KLE:
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fpga_path = "/usr/share/Nuand/bladeRF/hostedx115.rbf";
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break;
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default:
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fprintf(stderr, "bladeRF: unknown FPGA size, skipping FPGA load");
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fpga_path = NULL;
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break;
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}
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}
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if (fpga_path && fpga_path[0]) {
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fprintf(stderr, "bladeRF: loading FPGA bitstream from %s\n", fpga_path);
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if ((status = bladerf_load_fpga(BladeRF.device, fpga_path)) < 0) {
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fprintf(stderr, "bladerf_load_fpga() failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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}
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switch (bladerf_device_speed(BladeRF.device)) {
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case BLADERF_DEVICE_SPEED_HIGH:
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BladeRF.block_size = 1024;
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break;
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case BLADERF_DEVICE_SPEED_SUPER:
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BladeRF.block_size = 2048;
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break;
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default:
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fprintf(stderr, "couldn't determine bladerf device speed\n");
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goto error;
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}
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if ((status = bladerf_set_sample_rate(BladeRF.device, BLADERF_MODULE_RX, Modes.sample_rate * BladeRF.decimation, NULL)) < 0) {
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fprintf(stderr, "bladerf_set_sample_rate failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_set_frequency(BladeRF.device, BLADERF_MODULE_RX, Modes.freq)) < 0) {
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fprintf(stderr, "bladerf_set_frequency failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_set_lpf_mode(BladeRF.device, BLADERF_MODULE_RX, BladeRF.lpf_mode)) < 0) {
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fprintf(stderr, "bladerf_set_lpf_mode failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_set_bandwidth(BladeRF.device, BLADERF_MODULE_RX, BladeRF.lpf_bandwidth, NULL)) < 0) {
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fprintf(stderr, "bladerf_set_lpf_bandwidth failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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/* turn the tx gain right off, just in case */
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if ((status = bladerf_set_gain(BladeRF.device, BLADERF_MODULE_TX, -100)) < 0) {
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fprintf(stderr, "bladerf_set_gain(TX) failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_set_gain(BladeRF.device, BLADERF_MODULE_RX, Modes.gain / 10.0)) < 0) {
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fprintf(stderr, "bladerf_set_gain(RX) failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_set_loopback(BladeRF.device, BLADERF_LB_NONE)) < 0) {
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fprintf(stderr, "bladerf_set_loopback() failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_calibrate_dc(BladeRF.device, BLADERF_DC_CAL_LPF_TUNING)) < 0) {
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fprintf(stderr, "bladerf_calibrate_dc(LPF_TUNING) failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_calibrate_dc(BladeRF.device, BLADERF_DC_CAL_RX_LPF)) < 0) {
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fprintf(stderr, "bladerf_calibrate_dc(RX_LPF) failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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if ((status = bladerf_calibrate_dc(BladeRF.device, BLADERF_DC_CAL_RXVGA2)) < 0) {
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fprintf(stderr, "bladerf_calibrate_dc(RXVGA2) failed: %s\n", bladerf_strerror(status));
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goto error;
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}
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show_config();
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BladeRF.converter = init_converter(INPUT_SC16Q11,
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Modes.sample_rate,
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Modes.dc_filter,
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&BladeRF.converter_state);
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if (!BladeRF.converter) {
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fprintf(stderr, "can't initialize sample converter\n");
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goto error;
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}
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return true;
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error:
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if (BladeRF.device) {
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bladerf_close(BladeRF.device);
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BladeRF.device = NULL;
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}
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return false;
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}
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static struct timespec thread_cpu;
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static unsigned timeouts = 0;
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static void *handle_bladerf_samples(struct bladerf *dev,
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struct bladerf_stream *stream,
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struct bladerf_metadata *meta,
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void *samples,
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size_t num_samples,
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void *user_data)
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{
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static uint64_t nextTimestamp = 0;
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static bool dropping = false;
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MODES_NOTUSED(dev);
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MODES_NOTUSED(stream);
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MODES_NOTUSED(meta);
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MODES_NOTUSED(user_data);
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MODES_NOTUSED(num_samples);
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// record initial time for later sys timestamp calculation
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uint64_t entryTimestamp = mstime();
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pthread_mutex_lock(&Modes.data_mutex);
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if (Modes.exit) {
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pthread_mutex_unlock(&Modes.data_mutex);
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return BLADERF_STREAM_SHUTDOWN;
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}
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unsigned next_free_buffer = (Modes.first_free_buffer + 1) % MODES_MAG_BUFFERS;
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struct mag_buf *outbuf = &Modes.mag_buffers[Modes.first_free_buffer];
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struct mag_buf *lastbuf = &Modes.mag_buffers[(Modes.first_free_buffer + MODES_MAG_BUFFERS - 1) % MODES_MAG_BUFFERS];
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unsigned free_bufs = (Modes.first_filled_buffer - next_free_buffer + MODES_MAG_BUFFERS) % MODES_MAG_BUFFERS;
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if (free_bufs == 0 || (dropping && free_bufs < MODES_MAG_BUFFERS/2)) {
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// FIFO is full. Drop this block.
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dropping = true;
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pthread_mutex_unlock(&Modes.data_mutex);
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return samples;
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}
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dropping = false;
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pthread_mutex_unlock(&Modes.data_mutex);
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// Copy trailing data from last block (or reset if not valid)
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if (outbuf->dropped == 0) {
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memcpy(outbuf->data, lastbuf->data + lastbuf->length, Modes.trailing_samples * sizeof(uint16_t));
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} else {
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memset(outbuf->data, 0, Modes.trailing_samples * sizeof(uint16_t));
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}
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// start handling metadata blocks
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outbuf->dropped = 0;
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outbuf->length = 0;
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outbuf->mean_level = outbuf->mean_power = 0;
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unsigned blocks_processed = 0;
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unsigned samples_per_block = (BladeRF.block_size - 16) / 4;
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static bool overrun = true; // ignore initial overruns as we get up to speed
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static bool first_buffer = true;
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for (unsigned offset = 0; offset < MODES_MAG_BUF_SAMPLES * 4; offset += BladeRF.block_size) {
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// read the next metadata header
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uint8_t *header = ((uint8_t*)samples) + offset;
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uint64_t metadata_magic = le32toh(*(uint32_t*)(header));
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uint64_t metadata_timestamp = le64toh(*(uint64_t*)(header + 4));
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uint32_t metadata_flags = le32toh(*(uint32_t*)(header + 12));
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void *sample_data = header + 16;
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if (metadata_magic != 0x12344321) {
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// first buffer is often in the wrong mode
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if (!first_buffer) {
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fprintf(stderr, "bladeRF: wrong metadata header magic value, skipping rest of buffer\n");
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}
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break;
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}
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if (metadata_flags & BLADERF_META_STATUS_OVERRUN) {
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if (!overrun) {
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fprintf(stderr, "bladeRF: receive overrun\n");
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}
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overrun = true;
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} else {
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overrun = false;
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}
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#ifndef BROKEN_FPGA_METADATA
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// this needs a fixed decimating FPGA image that handles the timestamp correctly
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if (nextTimestamp && nextTimestamp != metadata_timestamp) {
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// dropped data or lost sync. start again.
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if (metadata_timestamp > nextTimestamp)
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outbuf->dropped += (metadata_timestamp - nextTimestamp);
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outbuf->dropped += outbuf->length;
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outbuf->length = 0;
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blocks_processed = 0;
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outbuf->mean_level = outbuf->mean_power = 0;
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nextTimestamp = metadata_timestamp;
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}
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#else
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MODES_NOTUSED(metadata_timestamp);
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#endif
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if (!blocks_processed) {
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// Compute the sample timestamp for the start of the block
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outbuf->sampleTimestamp = nextTimestamp * 12e6 / Modes.sample_rate / BladeRF.decimation;
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}
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// Convert a block of data
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double mean_level, mean_power;
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BladeRF.converter(sample_data, &outbuf->data[Modes.trailing_samples + outbuf->length], samples_per_block, BladeRF.converter_state, &mean_level, &mean_power);
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outbuf->length += samples_per_block;
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outbuf->mean_level += mean_level;
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outbuf->mean_power += mean_power;
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nextTimestamp += samples_per_block * BladeRF.decimation;
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++blocks_processed;
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timeouts = 0;
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}
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first_buffer = false;
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if (blocks_processed) {
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// Get the approx system time for the start of this block
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unsigned block_duration = 1e3 * outbuf->length / Modes.sample_rate;
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outbuf->sysTimestamp = entryTimestamp - block_duration;
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outbuf->mean_level /= blocks_processed;
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outbuf->mean_power /= blocks_processed;
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// Push the new data to the demodulation thread
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pthread_mutex_lock(&Modes.data_mutex);
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|
|
// accumulate CPU while holding the mutex, and restart measurement
|
|
end_cpu_timing(&thread_cpu, &Modes.reader_cpu_accumulator);
|
|
start_cpu_timing(&thread_cpu);
|
|
|
|
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;
|
|
|
|
pthread_cond_signal(&Modes.data_cond);
|
|
pthread_mutex_unlock(&Modes.data_mutex);
|
|
}
|
|
|
|
return samples;
|
|
}
|
|
|
|
|
|
void bladeRFRun()
|
|
{
|
|
if (!BladeRF.device) {
|
|
return;
|
|
}
|
|
|
|
unsigned transfers = 7;
|
|
|
|
int status;
|
|
struct bladerf_stream *stream = NULL;
|
|
void **buffers = NULL;
|
|
|
|
if ((status = bladerf_init_stream(&stream,
|
|
BladeRF.device,
|
|
handle_bladerf_samples,
|
|
&buffers,
|
|
/* num_buffers */ transfers,
|
|
BLADERF_FORMAT_SC16_Q11_META,
|
|
/* samples_per_buffer */ MODES_MAG_BUF_SAMPLES,
|
|
/* num_transfers */ transfers,
|
|
/* user_data */ NULL)) < 0) {
|
|
fprintf(stderr, "bladerf_init_stream() failed: %s\n", bladerf_strerror(status));
|
|
goto out;
|
|
}
|
|
|
|
unsigned ms_per_transfer = 1000 * MODES_MAG_BUF_SAMPLES / Modes.sample_rate;
|
|
if ((status = bladerf_set_stream_timeout(BladeRF.device, BLADERF_MODULE_RX, ms_per_transfer * (transfers + 2))) < 0) {
|
|
fprintf(stderr, "bladerf_set_stream_timeout() failed: %s\n", bladerf_strerror(status));
|
|
goto out;
|
|
}
|
|
|
|
if ((status = bladerf_enable_module(BladeRF.device, BLADERF_MODULE_RX, true) < 0)) {
|
|
fprintf(stderr, "bladerf_enable_module(RX, true) failed: %s\n", bladerf_strerror(status));
|
|
goto out;
|
|
}
|
|
|
|
start_cpu_timing(&thread_cpu);
|
|
|
|
timeouts = 0; // reset to zero when we get a callback with some data
|
|
retry:
|
|
if ((status = bladerf_stream(stream, BLADERF_MODULE_RX)) < 0) {
|
|
fprintf(stderr, "bladerf_stream() failed: %s\n", bladerf_strerror(status));
|
|
if (status == BLADERF_ERR_TIMEOUT) {
|
|
if (++timeouts < 5)
|
|
goto retry;
|
|
fprintf(stderr, "bladerf is wedged, giving up.\n");
|
|
}
|
|
goto out;
|
|
}
|
|
|
|
out:
|
|
if ((status = bladerf_enable_module(BladeRF.device, BLADERF_MODULE_RX, false) < 0)) {
|
|
fprintf(stderr, "bladerf_enable_module(RX, false) failed: %s\n", bladerf_strerror(status));
|
|
}
|
|
|
|
if (stream) {
|
|
bladerf_deinit_stream(stream);
|
|
}
|
|
}
|
|
|
|
void bladeRFClose()
|
|
{
|
|
if (BladeRF.converter) {
|
|
cleanup_converter(BladeRF.converter_state);
|
|
BladeRF.converter = NULL;
|
|
BladeRF.converter_state = NULL;
|
|
}
|
|
|
|
if (BladeRF.device) {
|
|
bladerf_close(BladeRF.device);
|
|
BladeRF.device = NULL;
|
|
}
|
|
}
|