path: root/Transceiver52M/device/bladerf/bladerf.cpp

/*
 * Copyright 2022 sysmocom - s.f.m.c. GmbH
 *
 * Author: Eric Wild <ewild@sysmocom.de>
 *
 * SPDX-License-Identifier: AGPL-3.0+
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU Affero General Public License as published by
 * the Free Software Foundation, either version 3 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 Affero General Public License for more details.
 *
 * You should have received a copy of the GNU Affero General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 * See the COPYING file in the main directory for details.
 */

#include <map>
#include <libbladeRF.h>
#include "radioDevice.h"
#include "bladerf.h"
#include "Threads.h"
#include "Logger.h"

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

extern "C" {
#include <osmocom/core/utils.h>
#include <osmocom/gsm/gsm_utils.h>
#include <osmocom/vty/cpu_sched_vty.h>
}

#define SAMPLE_BUF_SZ (1 << 20)

#define B2XX_TIMING_4_4SPS 6.18462e-5

#define CHKRET()                                                                                                       \
	{                                                                                                              \
		if (status != 0)                                                                                       \
			LOGC(DDEV, ERROR) << bladerf_strerror(status);                                                 \
	}

static const dev_map_t dev_param_map{
	{ std::make_tuple(blade_dev_type::BLADE2, 4, 4), { 1, 26e6, GSMRATE, B2XX_TIMING_4_4SPS, "B200 4 SPS" } },
};

static const power_map_t dev_band_nom_power_param_map{
	{ std::make_tuple(blade_dev_type::BLADE2, GSM_BAND_850), { 89.75, 13.3, -7.5 } },
	{ std::make_tuple(blade_dev_type::BLADE2, GSM_BAND_900), { 89.75, 13.3, -7.5 } },
	{ std::make_tuple(blade_dev_type::BLADE2, GSM_BAND_1800), { 89.75, 7.5, -11.0 } },
	{ std::make_tuple(blade_dev_type::BLADE2, GSM_BAND_1900), { 89.75, 7.7, -11.0 } },
};

/* So far measurements done for B210 show really close to linear relationship
 * between gain and real output power, so we simply adjust the measured offset
 */
static double TxGain2TxPower(const dev_band_desc &desc, double tx_gain_db)
{
	return desc.nom_out_tx_power - (desc.nom_uhd_tx_gain - tx_gain_db);
}
static double TxPower2TxGain(const dev_band_desc &desc, double tx_power_dbm)
{
	return desc.nom_uhd_tx_gain - (desc.nom_out_tx_power - tx_power_dbm);
}

blade_device::blade_device(InterfaceType iface, const struct trx_cfg *cfg)
	: RadioDevice(iface, cfg), band_manager(dev_band_nom_power_param_map, dev_param_map), dev(nullptr),
	  rx_gain_min(0.0), rx_gain_max(0.0), tx_spp(0), rx_spp(0), started(false), aligned(false), drop_cnt(0),
	  prev_ts(0), ts_initial(0), ts_offset(0), async_event_thrd(NULL)
{
}

blade_device::~blade_device()
{
	if (dev) {
		bladerf_enable_module(dev, BLADERF_CHANNEL_RX(0), false);
		bladerf_enable_module(dev, BLADERF_CHANNEL_TX(0), false);
	}

	stop();

	for (size_t i = 0; i < rx_buffers.size(); i++)
		delete rx_buffers[i];
}

void blade_device::init_gains()
{
	double tx_gain_min, tx_gain_max;
	int status;

	const struct bladerf_range *r;
	bladerf_get_gain_range(dev, BLADERF_RX, &r);

	rx_gain_min = r->min;
	rx_gain_max = r->max;
	LOGC(DDEV, INFO) << "Supported Rx gain range [" << rx_gain_min << "; " << rx_gain_max << "]";

	for (size_t i = 0; i < rx_gains.size(); i++) {
		double gain = (rx_gain_min + rx_gain_max) / 2;
		status = bladerf_set_gain_mode(dev, BLADERF_CHANNEL_RX(i), BLADERF_GAIN_MGC);
		CHKRET()
		bladerf_gain_mode m;
		bladerf_get_gain_mode(dev, BLADERF_CHANNEL_RX(i), &m);
		LOGC(DDEV, INFO) << (m == BLADERF_GAIN_MANUAL ? "gain manual" : "gain AUTO");

		status = bladerf_set_gain(dev, BLADERF_CHANNEL_RX(i), 0);
		CHKRET()
		int actual_gain;
		status = bladerf_get_gain(dev, BLADERF_CHANNEL_RX(i), &actual_gain);
		CHKRET()
		LOGC(DDEV, INFO) << "Default setting Rx gain for channel " << i << " to " << gain << " scale "
				 << r->scale << " actual " << actual_gain;
		rx_gains[i] = actual_gain;

		status = bladerf_set_gain(dev, BLADERF_CHANNEL_RX(i), 0);
		CHKRET()
		status = bladerf_get_gain(dev, BLADERF_CHANNEL_RX(i), &actual_gain);
		CHKRET()
		LOGC(DDEV, INFO) << "Default setting Rx gain for channel " << i << " to " << gain << " scale "
				 << r->scale << " actual " << actual_gain;
		rx_gains[i] = actual_gain;
	}

	status = bladerf_get_gain_range(dev, BLADERF_TX, &r);
	CHKRET()
	tx_gain_min = r->min;
	tx_gain_max = r->max;
	LOGC(DDEV, INFO) << "Supported Tx gain range [" << tx_gain_min << "; " << tx_gain_max << "]";

	for (size_t i = 0; i < tx_gains.size(); i++) {
		double gain = (tx_gain_min + tx_gain_max) / 2;
		status = bladerf_set_gain(dev, BLADERF_CHANNEL_TX(i), 30);
		CHKRET()
		int actual_gain;
		status = bladerf_get_gain(dev, BLADERF_CHANNEL_TX(i), &actual_gain);
		CHKRET()
		LOGC(DDEV, INFO) << "Default setting Tx gain for channel " << i << " to " << gain << " scale "
				 << r->scale << " actual " << actual_gain;
		tx_gains[i] = actual_gain;
	}

	return;
}

void blade_device::set_rates()
{
	struct bladerf_rational_rate rate = { 0, static_cast<uint64_t>((1625e3 * 4)), 6 }, actual;
	auto status = bladerf_set_rational_sample_rate(dev, BLADERF_CHANNEL_RX(0), &rate, &actual);
	CHKRET()
	status = bladerf_set_rational_sample_rate(dev, BLADERF_CHANNEL_TX(0), &rate, &actual);
	CHKRET()

	tx_rate = rx_rate = (double)rate.num / (double)rate.den;

	LOGC(DDEV, INFO) << "Rates set to" << tx_rate << " / " << rx_rate;

	bladerf_set_bandwidth(dev, BLADERF_CHANNEL_RX(0), (bladerf_bandwidth)2e6, (bladerf_bandwidth *)NULL);
	bladerf_set_bandwidth(dev, BLADERF_CHANNEL_TX(0), (bladerf_bandwidth)2e6, (bladerf_bandwidth *)NULL);

	ts_offset = 60; // FIXME: actual blade offset, should equal b2xx
}

double blade_device::setRxGain(double db, size_t chan)
{
	if (chan >= rx_gains.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return 0.0f;
	}

	bladerf_set_gain(dev, BLADERF_CHANNEL_RX(chan), 30); //db);
	int actual_gain;
	bladerf_get_gain(dev, BLADERF_CHANNEL_RX(chan), &actual_gain);

	rx_gains[chan] = actual_gain;

	LOGC(DDEV, INFO) << "Set RX gain to " << rx_gains[chan] << "dB (asked for " << db << "dB)";

	return rx_gains[chan];
}

double blade_device::getRxGain(size_t chan)
{
	if (chan >= rx_gains.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return 0.0f;
	}

	return rx_gains[chan];
}

double blade_device::rssiOffset(size_t chan)
{
	double rssiOffset;
	dev_band_desc desc;

	if (chan >= rx_gains.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return 0.0f;
	}

	get_dev_band_desc(desc);
	rssiOffset = rx_gains[chan] + desc.rxgain2rssioffset_rel;
	return rssiOffset;
}

double blade_device::setPowerAttenuation(int atten, size_t chan)
{
	double tx_power, db;
	dev_band_desc desc;

	if (chan >= tx_gains.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel" << chan;
		return 0.0f;
	}

	get_dev_band_desc(desc);
	tx_power = desc.nom_out_tx_power - atten;
	db = TxPower2TxGain(desc, tx_power);

	bladerf_set_gain(dev, BLADERF_CHANNEL_TX(chan), 30);
	int actual_gain;
	bladerf_get_gain(dev, BLADERF_CHANNEL_RX(chan), &actual_gain);

	tx_gains[chan] = actual_gain;

	LOGC(DDEV, INFO)
		<< "Set TX gain to " << tx_gains[chan] << "dB, ~" << TxGain2TxPower(desc, tx_gains[chan]) << " dBm "
		<< "(asked for " << db << " dB, ~" << tx_power << " dBm)";

	return desc.nom_out_tx_power - TxGain2TxPower(desc, tx_gains[chan]);
}
double blade_device::getPowerAttenuation(size_t chan)
{
	dev_band_desc desc;
	if (chan >= tx_gains.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return 0.0f;
	}

	get_dev_band_desc(desc);
	return desc.nom_out_tx_power - TxGain2TxPower(desc, tx_gains[chan]);
}

int blade_device::getNominalTxPower(size_t chan)
{
	dev_band_desc desc;
	get_dev_band_desc(desc);

	return desc.nom_out_tx_power;
}

int blade_device::open()
{
	bladerf_log_set_verbosity(BLADERF_LOG_LEVEL_VERBOSE);
	bladerf_set_usb_reset_on_open(true);
	auto success = bladerf_open(&dev, cfg->dev_args);
	if (success != 0) {
		struct bladerf_devinfo *info;
		auto num_devs = bladerf_get_device_list(&info);
		LOGC(DDEV, ALERT) << "No bladerf devices found with identifier '" << cfg->dev_args << "'";
		if (num_devs) {
			for (int i = 0; i < num_devs; i++)
				LOGC(DDEV, ALERT) << "Found device:" << info[i].product << " serial " << info[i].serial;
		}

		return -1;
	}
	if (strcmp("bladerf2", bladerf_get_board_name(dev))) {
		LOGC(DDEV, ALERT) << "Only BladeRF2 supported! found:" << bladerf_get_board_name(dev);
		return -1;
	}

	dev_type = blade_dev_type::BLADE2;
	tx_window = TX_WINDOW_FIXED;
	update_band_dev(dev_key(dev_type, tx_sps, rx_sps));

	struct bladerf_devinfo info;
	bladerf_get_devinfo(dev, &info);
	LOGC(DDEV, INFO) << "Using discovered bladerf device " << info.serial;

	tx_freqs.resize(chans);
	rx_freqs.resize(chans);
	tx_gains.resize(chans);
	rx_gains.resize(chans);
	rx_buffers.resize(chans);

	switch (cfg->clock_ref) {
	case REF_INTERNAL:
	case REF_EXTERNAL:
		break;
	default:
		LOGC(DDEV, ALERT) << "Invalid reference type";
		return -1;
	}

	if (cfg->clock_ref == REF_EXTERNAL) {
		bool is_locked;
		int status = bladerf_set_pll_enable(dev, true);
		CHKRET()
		status = bladerf_set_pll_refclk(dev, 10000000);
		CHKRET()
		for (int i = 0; i < 20; i++) {
			usleep(50 * 1000);
			status = bladerf_get_pll_lock_state(dev, &is_locked);
			CHKRET()
			if (is_locked)
				break;
		}
		if (!is_locked) {
			LOGC(DDEV, ALERT) << "unable to lock refclk!";
			return -1;
		}
	}

	LOGC(DDEV, INFO)
		<< "Selected clock source is " << ((cfg->clock_ref == REF_INTERNAL) ? "internal" : "external 10Mhz");

	set_rates();

	/*
	1ts = 3/5200s
	1024*2 = small gap(~180us) every 9.23ms = every 16 ts? -> every 2 frames
	1024*1 = large gap(~627us) every 9.23ms = every 16 ts? -> every 2 frames

	rif convertbuffer = 625*4 = 2500 -> 4 ts
	rif rxtxbuf = 4 * segment(625*4) = 10000 -> 16 ts
	*/
	const unsigned int num_buffers = 256;
	const unsigned int buffer_size = 1024 * 4; /* Must be a multiple of 1024 */
	const unsigned int num_transfers = 32;
	const unsigned int timeout_ms = 3500;

	bladerf_sync_config(dev, BLADERF_RX_X1, BLADERF_FORMAT_SC16_Q11_META, num_buffers, buffer_size, num_transfers,
			    timeout_ms);

	bladerf_sync_config(dev, BLADERF_TX_X1, BLADERF_FORMAT_SC16_Q11_META, num_buffers, buffer_size, num_transfers,
			    timeout_ms);

	/* Number of samples per over-the-wire packet */
	tx_spp = rx_spp = buffer_size;

	size_t buf_len = SAMPLE_BUF_SZ / sizeof(uint32_t);
	for (size_t i = 0; i < rx_buffers.size(); i++)
		rx_buffers[i] = new smpl_buf(buf_len);

	pkt_bufs = std::vector<std::vector<short> >(chans, std::vector<short>(2 * rx_spp));
	for (size_t i = 0; i < pkt_bufs.size(); i++)
		pkt_ptrs.push_back(&pkt_bufs[i].front());

	init_gains();

	return NORMAL;
}

bool blade_device::restart()
{
	/* Allow 100 ms delay to align multi-channel streams */
	double delay = 0.2;
	int status;

	status = bladerf_enable_module(dev, BLADERF_CHANNEL_RX(0), true);
	CHKRET()
	status = bladerf_enable_module(dev, BLADERF_CHANNEL_TX(0), true);
	CHKRET()

	bladerf_timestamp now;
	status = bladerf_get_timestamp(dev, BLADERF_RX, &now);
	ts_initial = now + rx_rate * delay;
	LOGC(DDEV, INFO) << "Initial timestamp " << ts_initial << std::endl;

	return true;
}

bool blade_device::start()
{
	LOGC(DDEV, INFO) << "Starting USRP...";

	if (started) {
		LOGC(DDEV, ERROR) << "Device already started";
		return false;
	}

	if (!restart())
		return false;

	started = true;
	return true;
}

bool blade_device::stop()
{
	if (!started)
		return false;

	/* reset internal buffer timestamps */
	for (size_t i = 0; i < rx_buffers.size(); i++)
		rx_buffers[i]->reset();

	band_reset();

	started = false;
	return true;
}

int blade_device::readSamples(std::vector<short *> &bufs, int len, bool *overrun, TIMESTAMP timestamp, bool *underrun)
{
	ssize_t rc;
	uint64_t ts;

	if (bufs.size() != chans) {
		LOGC(DDEV, ALERT) << "Invalid channel combination " << bufs.size();
		return -1;
	}

	*overrun = false;
	*underrun = false;

	// Shift read time with respect to transmit clock
	timestamp += ts_offset;

	ts = timestamp;
	LOGC(DDEV, DEBUG) << "Requested timestamp = " << ts;

	// Check that timestamp is valid
	rc = rx_buffers[0]->avail_smpls(timestamp);
	if (rc < 0) {
		LOGC(DDEV, ERROR) << rx_buffers[0]->str_code(rc);
		LOGC(DDEV, ERROR) << rx_buffers[0]->str_status(timestamp);
		return 0;
	}

	struct bladerf_metadata meta = {};
	meta.timestamp = ts;

	while (rx_buffers[0]->avail_smpls(timestamp) < len) {
		thread_enable_cancel(false);
		int status = bladerf_sync_rx(dev, pkt_ptrs[0], len, &meta, 200U);
		thread_enable_cancel(true);

		if (status != 0)
			LOGC(DDEV, ERROR) << "RX broken: " << bladerf_strerror(status);
		if (meta.flags & BLADERF_META_STATUS_OVERRUN)
			LOGC(DDEV, ERROR) << "RX borken, OVERRUN: " << bladerf_strerror(status);

		size_t num_smpls = meta.actual_count;
		;
		ts = meta.timestamp;

		for (size_t i = 0; i < rx_buffers.size(); i++) {
			rc = rx_buffers[i]->write((short *)&pkt_bufs[i].front(), num_smpls, ts);

			// Continue on local overrun, exit on other errors
			if ((rc < 0)) {
				LOGC(DDEV, ERROR) << rx_buffers[i]->str_code(rc);
				LOGC(DDEV, ERROR) << rx_buffers[i]->str_status(timestamp);
				if (rc != smpl_buf::ERROR_OVERFLOW)
					return 0;
			}
		}
		meta = {};
		meta.timestamp = ts + num_smpls;
	}

	for (size_t i = 0; i < rx_buffers.size(); i++) {
		rc = rx_buffers[i]->read(bufs[i], len, timestamp);
		if ((rc < 0) || (rc != len)) {
			LOGC(DDEV, ERROR) << rx_buffers[i]->str_code(rc);
			LOGC(DDEV, ERROR) << rx_buffers[i]->str_status(timestamp);
			return 0;
		}
	}

	return len;
}

int blade_device::writeSamples(std::vector<short *> &bufs, int len, bool *underrun, unsigned long long timestamp)
{
	*underrun = false;
	static bool first_tx = true;
	struct bladerf_metadata meta = {};
	if (first_tx) {
		meta.timestamp = timestamp;
		meta.flags = BLADERF_META_FLAG_TX_BURST_START;
		first_tx = false;
	}

	thread_enable_cancel(false);
	int status = bladerf_sync_tx(dev, (const void *)bufs[0], len, &meta, 200U);
	thread_enable_cancel(true);

	if (status != 0)
		LOGC(DDEV, ERROR) << "TX broken: " << bladerf_strerror(status);

	return len;
}

bool blade_device::updateAlignment(TIMESTAMP timestamp)
{
	return true;
}

bool blade_device::set_freq(double freq, size_t chan, bool tx)
{
	if (tx) {
		bladerf_set_frequency(dev, BLADERF_CHANNEL_TX(chan), freq);
		bladerf_frequency f;
		bladerf_get_frequency(dev, BLADERF_CHANNEL_TX(chan), &f);
		tx_freqs[chan] = f;
	} else {
		bladerf_set_frequency(dev, BLADERF_CHANNEL_RX(chan), freq);
		bladerf_frequency f;
		bladerf_get_frequency(dev, BLADERF_CHANNEL_RX(chan), &f);
		rx_freqs[chan] = f;
	}
	LOGCHAN(chan, DDEV, INFO) << "set_freq(" << freq << ", " << (tx ? "TX" : "RX") << "): " << std::endl;

	return true;
}

bool blade_device::setTxFreq(double wFreq, size_t chan)
{
	if (chan >= tx_freqs.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return false;
	}
	ScopedLock lock(tune_lock);

	if (!update_band_from_freq(wFreq, chan, true))
		return false;

	if (!set_freq(wFreq, chan, true))
		return false;

	return true;
}

bool blade_device::setRxFreq(double wFreq, size_t chan)
{
	if (chan >= rx_freqs.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return false;
	}
	ScopedLock lock(tune_lock);

	if (!update_band_from_freq(wFreq, chan, false))
		return false;

	return set_freq(wFreq, chan, false);
}

double blade_device::getTxFreq(size_t chan)
{
	if (chan >= tx_freqs.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return 0.0;
	}

	return tx_freqs[chan];
}

double blade_device::getRxFreq(size_t chan)
{
	if (chan >= rx_freqs.size()) {
		LOGC(DDEV, ALERT) << "Requested non-existent channel " << chan;
		return 0.0;
	}

	return rx_freqs[chan];
}

bool blade_device::requiresRadioAlign()
{
	return false;
}

GSM::Time blade_device::minLatency()
{
	return GSM::Time(6, 7);
}

TIMESTAMP blade_device::initialWriteTimestamp()
{
	return ts_initial;
}

TIMESTAMP blade_device::initialReadTimestamp()
{
	return ts_initial;
}

double blade_device::fullScaleInputValue()
{
	return (double)2047;
}

double blade_device::fullScaleOutputValue()
{
	return (double)2047;
}

RadioDevice *RadioDevice::make(InterfaceType type, const struct trx_cfg *cfg)
{
	return new blade_device(type, cfg);
}