//
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#include "rhodium_radio_ctrl_impl.hpp"
#include "rhodium_constants.hpp"
#include <uhdlib/usrp/cores/spi_core_3000.hpp>
#include <uhd/utils/log.hpp>
#include <uhd/utils/algorithm.hpp>
#include <uhd/types/eeprom.hpp>
#include <uhd/types/sensors.hpp>
#include <uhd/transport/chdr.hpp>
#include <vector>
#include <string>
using namespace uhd;
using namespace uhd::rfnoc;
namespace {
enum slave_select_t {
SEN_CPLD = 8,
SEN_TX_LO = 1,
SEN_RX_LO = 2,
SEN_LO_DIST = 4 /* Unused */
};
constexpr uint32_t TX_FE_BASE = 224;
constexpr uint32_t RX_FE_BASE = 232;
constexpr double RHODIUM_DEFAULT_FREQ = 2.5e9; // Hz
// An invalid default index ensures that set gain will apply settings
// the first time it is called
constexpr double RHODIUM_DEFAULT_INVALID_GAIN = -1; // gain index
constexpr double RHODIUM_DEFAULT_GAIN = 0; // gain index
constexpr double RHODIUM_DEFAULT_LO_GAIN = 30; // gain index
constexpr char RHODIUM_DEFAULT_RX_ANTENNA[] = "RX2";
constexpr char RHODIUM_DEFAULT_TX_ANTENNA[] = "TX/RX";
constexpr double RHODIUM_DEFAULT_BANDWIDTH = 250e6; // Hz
//! Rhodium gain profile options
const std::vector<std::string> RHODIUM_GP_OPTIONS = {
"default"
};
//! Returns the SPI config used by the CPLD
spi_config_t _get_cpld_spi_config() {
spi_config_t spi_config;
spi_config.use_custom_divider = true;
spi_config.divider = 10;
spi_config.mosi_edge = spi_config_t::EDGE_RISE;
spi_config.miso_edge = spi_config_t::EDGE_FALL;
return spi_config;
}
//! Returns the SPI config used by the TX LO
spi_config_t _get_tx_lo_spi_config() {
spi_config_t spi_config;
spi_config.use_custom_divider = true;
spi_config.divider = 10;
spi_config.mosi_edge = spi_config_t::EDGE_RISE;
spi_config.miso_edge = spi_config_t::EDGE_FALL;
return spi_config;
}
//! Returns the SPI config used by the RX LO
spi_config_t _get_rx_lo_spi_config() {
spi_config_t spi_config;
spi_config.use_custom_divider = true;
spi_config.divider = 10;
spi_config.mosi_edge = spi_config_t::EDGE_RISE;
spi_config.miso_edge = spi_config_t::EDGE_FALL;
return spi_config;
}
std::function<void(uint32_t)> _generate_write_spi(
uhd::spi_iface::sptr spi,
slave_select_t slave,
spi_config_t config
) {
return [spi, slave, config](const uint32_t transaction) {
spi->write_spi(slave, config, transaction, 24);
};
}
std::function<uint32_t(uint32_t)> _generate_read_spi(
uhd::spi_iface::sptr spi,
slave_select_t slave,
spi_config_t config
) {
return [spi, slave, config](const uint32_t transaction) {
return spi->read_spi(slave, config, transaction, 24);
};
}
}
void rhodium_radio_ctrl_impl::_init_defaults()
{
UHD_LOG_TRACE(unique_id(), "Initializing defaults...");
const size_t num_rx_chans = get_output_ports().size();
const size_t num_tx_chans = get_input_ports().size();
UHD_LOG_TRACE(unique_id(),
"Num TX chans: " << num_tx_chans
<< " Num RX chans: " << num_rx_chans);
for (size_t chan = 0; chan < num_rx_chans; chan++) {
radio_ctrl_impl::set_rx_frequency(RHODIUM_DEFAULT_FREQ, chan);
radio_ctrl_impl::set_rx_gain(RHODIUM_DEFAULT_INVALID_GAIN, chan);
radio_ctrl_impl::set_rx_antenna(RHODIUM_DEFAULT_RX_ANTENNA, chan);
radio_ctrl_impl::set_rx_bandwidth(RHODIUM_DEFAULT_BANDWIDTH, chan);
}
for (size_t chan = 0; chan < num_tx_chans; chan++) {
radio_ctrl_impl::set_tx_frequency(RHODIUM_DEFAULT_FREQ, chan);
radio_ctrl_impl::set_tx_gain(RHODIUM_DEFAULT_INVALID_GAIN, chan);
radio_ctrl_impl::set_tx_antenna(RHODIUM_DEFAULT_TX_ANTENNA, chan);
radio_ctrl_impl::set_tx_bandwidth(RHODIUM_DEFAULT_BANDWIDTH, chan);
}
/** Update default SPP (overwrites the default value from the XML file) **/
const size_t max_bytes_header =
uhd::transport::vrt::chdr::max_if_hdr_words64 * sizeof(uint64_t);
const size_t default_spp =
(_tree->access<size_t>("mtu/recv").get() - max_bytes_header)
/ (2 * sizeof(int16_t));
UHD_LOG_DEBUG(unique_id(),
"Setting default spp to " << default_spp);
_tree->access<int>(get_arg_path("spp") / "value").set(default_spp);
// Update configurable block arguments from the device arguments provided
if (_block_args.has_key(SPUR_DODGING_ARG_NAME)) {
_tree->access<std::string>(get_arg_path(SPUR_DODGING_ARG_NAME) / "value")
.set(_block_args.get(SPUR_DODGING_ARG_NAME));
}
if (_block_args.has_key(SPUR_DODGING_THRESHOLD_ARG_NAME)) {
_tree->access<double>(get_arg_path(SPUR_DODGING_THRESHOLD_ARG_NAME) / "value")
.set(boost::lexical_cast<double>(_block_args.get(SPUR_DODGING_THRESHOLD_ARG_NAME)));
}
}
void rhodium_radio_ctrl_impl::_init_peripherals()
{
UHD_LOG_TRACE(unique_id(), "Initializing peripherals...");
UHD_LOG_TRACE(unique_id(), "Initializing SPI core...");
_spi = spi_core_3000::make(_get_ctrl(0),
regs::sr_addr(regs::SPI),
regs::rb_addr(regs::RB_SPI)
);
UHD_LOG_TRACE(unique_id(), "Initializing CPLD...");
_cpld = std::make_shared<rhodium_cpld_ctrl>(
_generate_write_spi(this->_spi, SEN_CPLD, _get_cpld_spi_config()),
_generate_read_spi(this->_spi, SEN_CPLD, _get_cpld_spi_config()));
UHD_LOG_TRACE(unique_id(), "Writing initial gain values...");
set_tx_gain(RHODIUM_DEFAULT_GAIN, 0);
set_tx_lo_gain(RHODIUM_DEFAULT_LO_GAIN, RHODIUM_LO1, 0);
set_rx_gain(RHODIUM_DEFAULT_GAIN, 0);
set_rx_lo_gain(RHODIUM_DEFAULT_LO_GAIN, RHODIUM_LO1, 0);
UHD_LOG_TRACE(unique_id(), "Initializing TX LO...");
_tx_lo = lmx2592_iface::make(
_generate_write_spi(this->_spi, SEN_TX_LO, _get_tx_lo_spi_config()),
_generate_read_spi(this->_spi, SEN_TX_LO, _get_tx_lo_spi_config()));
UHD_LOG_TRACE(unique_id(), "Writing initial TX LO state...");
_tx_lo->set_reference_frequency(RHODIUM_LO1_REF_FREQ);
_tx_lo->set_mash_order(lmx2592_iface::mash_order_t::THIRD);
UHD_LOG_TRACE(unique_id(), "Initializing RX LO...");
_rx_lo = lmx2592_iface::make(
_generate_write_spi(this->_spi, SEN_RX_LO, _get_rx_lo_spi_config()),
_generate_read_spi(this->_spi, SEN_RX_LO, _get_rx_lo_spi_config()));
UHD_LOG_TRACE(unique_id(), "Writing initial RX LO state...");
_rx_lo->set_reference_frequency(RHODIUM_LO1_REF_FREQ);
_rx_lo->set_mash_order(lmx2592_iface::mash_order_t::THIRD);
UHD_LOG_TRACE(unique_id(), "Initializing GPIOs...");
_gpio =
usrp::gpio_atr::gpio_atr_3000::make(
_get_ctrl(0),
regs::sr_addr(regs::GPIO),
regs::rb_addr(regs::RB_DB_GPIO)
);
_gpio->set_atr_mode(
usrp::gpio_atr::MODE_GPIO, // Disable ATR mode
usrp::gpio_atr::gpio_atr_3000::MASK_SET_ALL
);
_gpio->set_gpio_ddr(
usrp::gpio_atr::DDR_OUTPUT, // Make all GPIOs outputs
usrp::gpio_atr::gpio_atr_3000::MASK_SET_ALL
);
// Updating the TX frequency path may include an update to SW10, which is
// GPIO controlled, so this must follow CPLD and GPIO initialization
UHD_LOG_TRACE(unique_id(), "Writing initial switch values...");
_update_tx_freq_switches(RHODIUM_DEFAULT_FREQ);
_update_rx_freq_switches(RHODIUM_DEFAULT_FREQ);
// Antenna setting requires both CPLD and GPIO control
UHD_LOG_TRACE(unique_id(), "Setting initial antenna settings");
_update_tx_output_switches(RHODIUM_DEFAULT_TX_ANTENNA);
_update_rx_input_switches(RHODIUM_DEFAULT_RX_ANTENNA);
_rx_fe_core = rx_frontend_core_3000::make(_get_ctrl(0), regs::sr_addr(RX_FE_BASE));
_rx_fe_core->set_adc_rate(_master_clock_rate);
_rx_fe_core->set_dc_offset(rx_frontend_core_3000::DEFAULT_DC_OFFSET_VALUE);
_rx_fe_core->set_dc_offset_auto(rx_frontend_core_3000::DEFAULT_DC_OFFSET_ENABLE);
_rx_fe_core->populate_subtree(_tree->subtree(_root_path / "rx_fe_corrections" / 0));
_tx_fe_core = tx_frontend_core_200::make(_get_ctrl(0), regs::sr_addr(TX_FE_BASE));
_tx_fe_core->set_dc_offset(tx_frontend_core_200::DEFAULT_DC_OFFSET_VALUE);
_tx_fe_core->set_iq_balance(tx_frontend_core_200::DEFAULT_IQ_BALANCE_VALUE);
_tx_fe_core->populate_subtree(_tree->subtree(_root_path / "tx_fe_corrections" / 0));
UHD_LOG_TRACE(unique_id(), "Checking for existence of LO Distribution board");
_lo_dist_present = _rpcc->request_with_token<bool>(_rpc_prefix + "is_lo_dist_present");
UHD_LOG_DEBUG(unique_id(), str(boost::format("LO distribution board is%s present") % (_lo_dist_present ? "" : " NOT")));
}
void rhodium_radio_ctrl_impl::_init_frontend_subtree(
uhd::property_tree::sptr subtree,
const size_t chan_idx
) {
const fs_path tx_fe_path = fs_path("tx_frontends") / chan_idx;
const fs_path rx_fe_path = fs_path("rx_frontends") / chan_idx;
UHD_LOG_TRACE(unique_id(),
"Adding non-RFNoC block properties for channel " << chan_idx <<
" to prop tree path " << tx_fe_path << " and " << rx_fe_path);
// TX Standard attributes
subtree->create<std::string>(tx_fe_path / "name")
.set(str(boost::format("Rhodium")))
;
subtree->create<std::string>(tx_fe_path / "connection")
.add_coerced_subscriber([this](const std::string& conn){
this->_set_tx_fe_connection(conn);
})
.set_publisher([this](){
return this->_get_tx_fe_connection();
})
;
subtree->create<device_addr_t>(tx_fe_path / "tune_args")
.set(device_addr_t())
;
// RX Standard attributes
subtree->create<std::string>(rx_fe_path / "name")
.set(str(boost::format("Rhodium")))
;
subtree->create<std::string>(rx_fe_path / "connection")
.add_coerced_subscriber([this](const std::string& conn){
this->_set_rx_fe_connection(conn);
})
.set_publisher([this](){
return this->_get_rx_fe_connection();
})
;
subtree->create<device_addr_t>(rx_fe_path / "tune_args")
.set(device_addr_t())
;
// TX Antenna
subtree->create<std::string>(tx_fe_path / "antenna" / "value")
.add_coerced_subscriber([this, chan_idx](const std::string &ant){
this->set_tx_antenna(ant, chan_idx);
})
.set_publisher([this, chan_idx](){
return this->get_tx_antenna(chan_idx);
})
;
subtree->create<std::vector<std::string>>(tx_fe_path / "antenna" / "options")
.set({RHODIUM_DEFAULT_TX_ANTENNA})
.add_coerced_subscriber([](const std::vector<std::string> &){
throw uhd::runtime_error(
"Attempting to update antenna options!");
})
;
// RX Antenna
subtree->create<std::string>(rx_fe_path / "antenna" / "value")
.add_coerced_subscriber([this, chan_idx](const std::string &ant){
this->set_rx_antenna(ant, chan_idx);
})
.set_publisher([this, chan_idx](){
return this->get_rx_antenna(chan_idx);
})
;
subtree->create<std::vector<std::string>>(rx_fe_path / "antenna" / "options")
.set(RHODIUM_RX_ANTENNAS)
.add_coerced_subscriber([](const std::vector<std::string> &){
throw uhd::runtime_error(
"Attempting to update antenna options!");
})
;
// TX frequency
subtree->create<double>(tx_fe_path / "freq" / "value")
.set_coercer([this, chan_idx](const double freq){
return this->set_tx_frequency(freq, chan_idx);
})
.set_publisher([this, chan_idx](){
return this->get_tx_frequency(chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "freq" / "range")
.set(meta_range_t(RHODIUM_MIN_FREQ, RHODIUM_MAX_FREQ, 1.0))
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error(
"Attempting to update freq range!");
})
;
// RX frequency
subtree->create<double>(rx_fe_path / "freq" / "value")
.set_coercer([this, chan_idx](const double freq){
return this->set_rx_frequency(freq, chan_idx);
})
.set_publisher([this, chan_idx](){
return this->get_rx_frequency(chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "freq" / "range")
.set(meta_range_t(RHODIUM_MIN_FREQ, RHODIUM_MAX_FREQ, 1.0))
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error(
"Attempting to update freq range!");
})
;
// TX bandwidth
subtree->create<double>(tx_fe_path / "bandwidth" / "value")
.set_coercer([this, chan_idx](const double bw){
return this->set_tx_bandwidth(bw, chan_idx);
})
.set_publisher([this, chan_idx](){
return this->get_tx_bandwidth(chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "bandwidth" / "range")
.set(meta_range_t(0.0, 0.0, 0.0)) // FIXME
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error(
"Attempting to update bandwidth range!");
})
;
// RX bandwidth
subtree->create<double>(rx_fe_path / "bandwidth" / "value")
.set_coercer([this, chan_idx](const double bw){
return this->set_rx_bandwidth(bw, chan_idx);
})
.set_publisher([this, chan_idx](){
return this->get_rx_bandwidth(chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "bandwidth" / "range")
.set(meta_range_t(0.0, 0.0, 0.0)) // FIXME
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error(
"Attempting to update bandwidth range!");
})
;
// TX gains
subtree->create<double>(tx_fe_path / "gains" / "all" / "value")
.set_coercer([this, chan_idx](const double gain){
return this->set_tx_gain(gain, chan_idx);
})
.set_publisher([this, chan_idx](){
return radio_ctrl_impl::get_tx_gain(chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "gains" / "all" / "range")
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error(
"Attempting to update gain range!");
})
.set_publisher([](){
return rhodium_radio_ctrl_impl::_get_gain_range(TX_DIRECTION);
})
;
subtree->create<std::vector<std::string>>(tx_fe_path / "gains/all/profile/options")
.set(RHODIUM_GP_OPTIONS);
subtree->create<std::string>(tx_fe_path / "gains/all/profile/value")
.set_coercer([this](const std::string& profile){
std::string return_profile = profile;
if (!uhd::has(RHODIUM_GP_OPTIONS, profile))
{
return_profile = "default";
}
_gain_profile[TX_DIRECTION] = return_profile;
return return_profile;
})
.set_publisher([this](){
return _gain_profile[TX_DIRECTION];
})
;
// RX gains
subtree->create<double>(rx_fe_path / "gains" / "all" / "value")
.set_coercer([this, chan_idx](const double gain){
return this->set_rx_gain(gain, chan_idx);
})
.set_publisher([this, chan_idx](){
return radio_ctrl_impl::get_rx_gain(chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "gains" / "all" / "range")
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error(
"Attempting to update gain range!");
})
.set_publisher([](){
return rhodium_radio_ctrl_impl::_get_gain_range(RX_DIRECTION);
})
;
subtree->create<std::vector<std::string> >(rx_fe_path / "gains/all/profile/options")
.set(RHODIUM_GP_OPTIONS);
subtree->create<std::string>(rx_fe_path / "gains/all/profile/value")
.set_coercer([this](const std::string& profile){
std::string return_profile = profile;
if (!uhd::has(RHODIUM_GP_OPTIONS, profile))
{
return_profile = "default";
}
_gain_profile[RX_DIRECTION] = return_profile;
return return_profile;
})
.set_publisher([this](){
return _gain_profile[RX_DIRECTION];
})
;
// TX LO lock sensor
subtree->create<sensor_value_t>(tx_fe_path / "sensors" / "lo_locked")
.set(sensor_value_t("all_los", false, "locked", "unlocked"))
.add_coerced_subscriber([](const sensor_value_t &){
throw uhd::runtime_error(
"Attempting to write to sensor!");
})
.set_publisher([this](){
return sensor_value_t(
"all_los",
this->get_lo_lock_status(TX_DIRECTION),
"locked", "unlocked"
);
})
;
// RX LO lock sensor
subtree->create<sensor_value_t>(rx_fe_path / "sensors" / "lo_locked")
.set(sensor_value_t("all_los", false, "locked", "unlocked"))
.add_coerced_subscriber([](const sensor_value_t &){
throw uhd::runtime_error(
"Attempting to write to sensor!");
})
.set_publisher([this](){
return sensor_value_t(
"all_los",
this->get_lo_lock_status(RX_DIRECTION),
"locked", "unlocked"
);
})
;
//LO Specific
//RX LO
//RX LO1 Frequency
subtree->create<double>(rx_fe_path / "los"/RHODIUM_LO1/"freq/value")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_freq(RHODIUM_LO1, chan_idx);
})
.set_coercer([this,chan_idx](const double freq){
return this->set_rx_lo_freq(freq, RHODIUM_LO1, chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "los"/RHODIUM_LO1/"freq/range")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_freq_range(RHODIUM_LO1, chan_idx);
})
;
//RX LO1 Source
subtree->create<std::vector<std::string>>(rx_fe_path / "los"/RHODIUM_LO1/"source/options")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_sources(RHODIUM_LO1, chan_idx);
})
;
subtree->create<std::string>(rx_fe_path / "los"/RHODIUM_LO1/"source/value")
.add_coerced_subscriber([this,chan_idx](std::string src){
this->set_rx_lo_source(src, RHODIUM_LO1,chan_idx);
})
.set_publisher([this,chan_idx](){
return this->get_rx_lo_source(RHODIUM_LO1, chan_idx);
})
;
//RX LO1 Export
subtree->create<bool>(rx_fe_path / "los"/RHODIUM_LO1/"export")
.add_coerced_subscriber([this,chan_idx](bool enabled){
this->set_rx_lo_export_enabled(enabled, RHODIUM_LO1, chan_idx);
})
;
//RX LO1 Gain
subtree->create<double>(rx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_GAIN / "value")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_gain(RHODIUM_LO1, chan_idx);
})
.set_coercer([this,chan_idx](const double gain){
return this->set_rx_lo_gain(gain, RHODIUM_LO1, chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_GAIN / "range")
.set_publisher([](){
return rhodium_radio_ctrl_impl::_get_lo_gain_range();
})
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error("Attempting to update LO gain range!");
})
;
//RX LO1 Output Power
subtree->create<double>(rx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_POWER / "value")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_power(RHODIUM_LO1, chan_idx);
})
.set_coercer([this,chan_idx](const double gain){
return this->set_rx_lo_power(gain, RHODIUM_LO1, chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_POWER / "range")
.set_publisher([](){
return rhodium_radio_ctrl_impl::_get_lo_power_range();
})
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error("Attempting to update LO output power range!");
})
;
//RX LO2 Frequency
subtree->create<double>(rx_fe_path / "los"/RHODIUM_LO2/"freq/value")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_freq(RHODIUM_LO2, chan_idx);
})
.set_coercer([this,chan_idx](double freq){
return this->set_rx_lo_freq(freq, RHODIUM_LO2, chan_idx);
})
;
subtree->create<meta_range_t>(rx_fe_path / "los"/RHODIUM_LO2/"freq/range")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_freq_range(RHODIUM_LO2, chan_idx);
})
;
//RX LO2 Source
subtree->create<std::vector<std::string>>(rx_fe_path / "los"/RHODIUM_LO2/"source/options")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_sources(RHODIUM_LO2, chan_idx);
})
;
subtree->create<std::string>(rx_fe_path / "los"/RHODIUM_LO2/"source/value")
.add_coerced_subscriber([this,chan_idx](std::string src){
this->set_rx_lo_source(src, RHODIUM_LO2, chan_idx);
})
.set_publisher([this,chan_idx](){
return this->get_rx_lo_source(RHODIUM_LO2, chan_idx);
})
;
//RX LO2 Export
subtree->create<bool>(rx_fe_path / "los"/RHODIUM_LO2/"export")
.add_coerced_subscriber([this,chan_idx](bool enabled){
this->set_rx_lo_export_enabled(enabled, RHODIUM_LO2, chan_idx);
});
//TX LO
//TX LO1 Frequency
subtree->create<double>(tx_fe_path / "los"/RHODIUM_LO1/"freq/value ")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_freq(RHODIUM_LO1, chan_idx);
})
.set_coercer([this,chan_idx](double freq){
return this->set_tx_lo_freq(freq, RHODIUM_LO1, chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "los"/RHODIUM_LO1/"freq/range")
.set_publisher([this,chan_idx](){
return this->get_rx_lo_freq_range(RHODIUM_LO1, chan_idx);
})
;
//TX LO1 Source
subtree->create<std::vector<std::string>>(tx_fe_path / "los"/RHODIUM_LO1/"source/options")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_sources(RHODIUM_LO1, chan_idx);
})
;
subtree->create<std::string>(tx_fe_path / "los"/RHODIUM_LO1/"source/value")
.add_coerced_subscriber([this,chan_idx](std::string src){
this->set_tx_lo_source(src, RHODIUM_LO1, chan_idx);
})
.set_publisher([this,chan_idx](){
return this->get_tx_lo_source(RHODIUM_LO1, chan_idx);
})
;
//TX LO1 Export
subtree->create<bool>(tx_fe_path / "los"/RHODIUM_LO1/"export")
.add_coerced_subscriber([this,chan_idx](bool enabled){
this->set_tx_lo_export_enabled(enabled, RHODIUM_LO1, chan_idx);
})
;
//TX LO1 Gain
subtree->create<double>(tx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_GAIN / "value")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_gain(RHODIUM_LO1, chan_idx);
})
.set_coercer([this,chan_idx](const double gain){
return this->set_tx_lo_gain(gain, RHODIUM_LO1, chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_GAIN / "range")
.set_publisher([](){
return rhodium_radio_ctrl_impl::_get_lo_gain_range();
})
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error("Attempting to update LO gain range!");
})
;
//TX LO1 Output Power
subtree->create<double>(tx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_POWER / "value")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_power(RHODIUM_LO1, chan_idx);
})
.set_coercer([this,chan_idx](const double gain){
return this->set_tx_lo_power(gain, RHODIUM_LO1, chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "los" /RHODIUM_LO1/ "gains" / RHODIUM_LO_POWER / "range")
.set_publisher([](){
return rhodium_radio_ctrl_impl::_get_lo_power_range();
})
.add_coerced_subscriber([](const meta_range_t &){
throw uhd::runtime_error("Attempting to update LO output power range!");
})
;
//TX LO2 Frequency
subtree->create<double>(tx_fe_path / "los"/RHODIUM_LO2/"freq/value")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_freq(RHODIUM_LO2, chan_idx);
})
.set_coercer([this,chan_idx](double freq){
return this->set_tx_lo_freq(freq, RHODIUM_LO2, chan_idx);
})
;
subtree->create<meta_range_t>(tx_fe_path / "los"/RHODIUM_LO2/"freq/range")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_freq_range(RHODIUM_LO2,chan_idx);
})
;
//TX LO2 Source
subtree->create<std::vector<std::string>>(tx_fe_path / "los"/RHODIUM_LO2/"source/options")
.set_publisher([this,chan_idx](){
return this->get_tx_lo_sources(RHODIUM_LO2, chan_idx);
})
;
subtree->create<std::string>(tx_fe_path / "los"/RHODIUM_LO2/"source/value")
.add_coerced_subscriber([this,chan_idx](std::string src){
this->set_tx_lo_source(src, RHODIUM_LO2, chan_idx);
})
.set_publisher([this,chan_idx](){
return this->get_tx_lo_source(RHODIUM_LO2, chan_idx);
})
;
//TX LO2 Export
subtree->create<bool>(tx_fe_path / "los"/RHODIUM_LO2/"export")
.add_coerced_subscriber([this,chan_idx](bool enabled){
this->set_tx_lo_export_enabled(enabled, RHODIUM_LO2, chan_idx);
})
;
//LO Distribution Output Ports
if (_lo_dist_present) {
for (const auto& port : LO_OUTPUT_PORT_NAMES) {
subtree->create<bool>(tx_fe_path / "los" / RHODIUM_LO1 / "lo_distribution" / port / "export")
.add_coerced_subscriber([this, chan_idx, port](bool enabled) {
this->set_tx_lo_output_enabled(enabled, port, chan_idx);
})
.set_publisher([this, chan_idx, port]() {
return this->get_tx_lo_output_enabled(port, chan_idx);
})
;
subtree->create<bool>(rx_fe_path / "los" / RHODIUM_LO1 / "lo_distribution" / port / "export")
.add_coerced_subscriber([this, chan_idx, port](bool enabled) {
this->set_rx_lo_output_enabled(enabled, port, chan_idx);
})
.set_publisher([this, chan_idx, port]() {
return this->get_rx_lo_output_enabled(port, chan_idx);
})
;
}
}
}
void rhodium_radio_ctrl_impl::_init_prop_tree()
{
const fs_path fe_base = fs_path("dboards") / _radio_slot;
this->_init_frontend_subtree(_tree->subtree(fe_base), 0);
// EEPROM paths subject to change FIXME
_tree->create<eeprom_map_t>(_root_path / "eeprom")
.set(eeprom_map_t());
_tree->create<int>("rx_codecs" / _radio_slot / "gains");
_tree->create<int>("tx_codecs" / _radio_slot / "gains");
_tree->create<std::string>("rx_codecs" / _radio_slot / "name").set("ad9695-625");
_tree->create<std::string>("tx_codecs" / _radio_slot / "name").set("dac37j82");
// TODO remove this dirty hack
if (not _tree->exists("tick_rate"))
{
_tree->create<double>("tick_rate")
.set_publisher([this](){ return this->get_rate(); })
;
}
}
void rhodium_radio_ctrl_impl::_init_mpm_sensors(
const direction_t dir,
const size_t chan_idx
) {
const std::string trx = (dir == RX_DIRECTION) ? "RX" : "TX";
const fs_path fe_path =
fs_path("dboards") / _radio_slot /
(dir == RX_DIRECTION ? "rx_frontends" : "tx_frontends") / chan_idx;
auto sensor_list =
_rpcc->request_with_token<std::vector<std::string>>(
this->_rpc_prefix + "get_sensors", trx);
UHD_LOG_TRACE(unique_id(),
"Chan " << chan_idx << ": Found "
<< sensor_list.size() << " " << trx << " sensors.");
for (const auto &sensor_name : sensor_list) {
UHD_LOG_TRACE(unique_id(),
"Adding " << trx << " sensor " << sensor_name);
_tree->create<sensor_value_t>(fe_path / "sensors" / sensor_name)
.add_coerced_subscriber([](const sensor_value_t &){
throw uhd::runtime_error(
"Attempting to write to sensor!");
})
.set_publisher([this, trx, sensor_name, chan_idx](){
return sensor_value_t(
this->_rpcc->request_with_token<sensor_value_t::sensor_map_t>(
this->_rpc_prefix + "get_sensor",
trx, sensor_name, chan_idx)
);
})
;
}
}