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//
// Copyright 2017 Ettus Research (National Instruments)
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 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 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 "ad937x_device.hpp"
#include "adi/mykonos.h"
#include "mpm/ad937x/ad937x_ctrl.hpp"
#include <mpm/exception.hpp>
#include <sstream>
#include <set>
#include <functional>
#include <iostream>
#include <algorithm>
using namespace mpm::chips;
using namespace mpm::ad937x::device;
//Init cals mask
const uint32_t ad937x_ctrl::TX_BB_FILTER = ::TX_BB_FILTER;
const uint32_t ad937x_ctrl::ADC_TUNER = ::ADC_TUNER;
const uint32_t ad937x_ctrl::TIA_3DB_CORNER = ::TIA_3DB_CORNER;
const uint32_t ad937x_ctrl::DC_OFFSET = ::DC_OFFSET;
const uint32_t ad937x_ctrl::TX_ATTENUATION_DELAY = ::TX_ATTENUATION_DELAY;
const uint32_t ad937x_ctrl::RX_GAIN_DELAY = ::RX_GAIN_DELAY;
const uint32_t ad937x_ctrl::FLASH_CAL = ::FLASH_CAL;
const uint32_t ad937x_ctrl::PATH_DELAY = ::PATH_DELAY;
const uint32_t ad937x_ctrl::TX_LO_LEAKAGE_INTERNAL = ::TX_LO_LEAKAGE_INTERNAL;
const uint32_t ad937x_ctrl::TX_LO_LEAKAGE_EXTERNAL = ::TX_LO_LEAKAGE_EXTERNAL;
const uint32_t ad937x_ctrl::TX_QEC_INIT = ::TX_QEC_INIT;
const uint32_t ad937x_ctrl::LOOPBACK_RX_LO_DELAY = ::LOOPBACK_RX_LO_DELAY;
const uint32_t ad937x_ctrl::LOOPBACK_RX_RX_QEC_INIT = ::LOOPBACK_RX_RX_QEC_INIT;
const uint32_t ad937x_ctrl::RX_LO_DELAY = ::RX_LO_DELAY;
const uint32_t ad937x_ctrl::RX_QEC_INIT = ::RX_QEC_INIT;
const uint32_t ad937x_ctrl::DPD_INIT = ::DPD_INIT;
const uint32_t ad937x_ctrl::CLGC_INIT = ::CLGC_INIT;
const uint32_t ad937x_ctrl::VSWR_INIT = ::VSWR_INIT;
//Tracking Cals mask
const uint32_t ad937x_ctrl::TRACK_RX1_QEC = ::TRACK_RX1_QEC;
const uint32_t ad937x_ctrl::TRACK_RX2_QEC = ::TRACK_RX2_QEC;
const uint32_t ad937x_ctrl::TRACK_ORX1_QEC = ::TRACK_ORX1_QEC;
const uint32_t ad937x_ctrl::TRACK_ORX2_QEC = ::TRACK_ORX2_QEC;
const uint32_t ad937x_ctrl::TRACK_TX1_LOL = ::TRACK_TX1_LOL;
const uint32_t ad937x_ctrl::TRACK_TX2_LOL = ::TRACK_TX2_LOL;
const uint32_t ad937x_ctrl::TRACK_TX1_QEC = ::TRACK_TX1_QEC;
const uint32_t ad937x_ctrl::TRACK_TX2_QEC = ::TRACK_TX2_QEC;
const uint32_t ad937x_ctrl::TRACK_TX1_DPD = ::TRACK_TX1_DPD;
const uint32_t ad937x_ctrl::TRACK_TX2_DPD = ::TRACK_TX2_DPD;
const uint32_t ad937x_ctrl::TRACK_TX1_CLGC = ::TRACK_TX1_CLGC;
const uint32_t ad937x_ctrl::TRACK_TX2_CLGC = ::TRACK_TX2_CLGC;
const uint32_t ad937x_ctrl::TRACK_TX1_VSWR = ::TRACK_TX1_VSWR;
const uint32_t ad937x_ctrl::TRACK_TX2_VSWR = ::TRACK_TX2_VSWR;
const uint32_t ad937x_ctrl::TRACK_ORX1_QEC_SNLO = ::TRACK_ORX1_QEC_SNLO;
const uint32_t ad937x_ctrl::TRACK_ORX2_QEC_SNLO = ::TRACK_ORX2_QEC_SNLO;
const uint32_t ad937x_ctrl::TRACK_SRX_QEC = ::TRACK_SRX_QEC;
const uint32_t ad937x_ctrl::DEFAULT_INIT_CALS_MASKS =
ad937x_ctrl::TX_BB_FILTER |
ad937x_ctrl::ADC_TUNER |
ad937x_ctrl::TIA_3DB_CORNER |
ad937x_ctrl::DC_OFFSET |
ad937x_ctrl::TX_ATTENUATION_DELAY |
ad937x_ctrl::RX_GAIN_DELAY |
ad937x_ctrl::FLASH_CAL |
ad937x_ctrl::PATH_DELAY |
ad937x_ctrl::TX_LO_LEAKAGE_INTERNAL |
ad937x_ctrl::TX_QEC_INIT |
ad937x_ctrl::LOOPBACK_RX_LO_DELAY |
ad937x_ctrl::RX_QEC_INIT
;
const uint32_t ad937x_ctrl::DEFAULT_TRACKING_CALS_MASKS =
ad937x_ctrl::TRACK_RX1_QEC |
ad937x_ctrl::TRACK_RX2_QEC |
ad937x_ctrl::TRACK_TX1_QEC |
ad937x_ctrl::TRACK_TX2_QEC
;
const uint32_t ad937x_ctrl::DEFAULT_INIT_CALS_TIMEOUT = 60000;
static uhd::direction_t _get_direction_from_antenna(const std::string& antenna)
{
auto sub = antenna.substr(0, 2);
if (sub == "RX") {
return uhd::direction_t::RX_DIRECTION;
}
else if (sub == "TX") {
return uhd::direction_t::TX_DIRECTION;
}
else {
throw mpm::runtime_error("ad937x_ctrl got an invalid channel string.");
}
return uhd::direction_t::RX_DIRECTION;
}
static chain_t _get_chain_from_antenna(const std::string& antenna)
{
auto sub = antenna.substr(2, 1);
if (sub == "1") {
return chain_t::ONE;
}
else if (sub == "2") {
return chain_t::TWO;
}
else {
throw mpm::runtime_error("ad937x_ctrl got an invalid channel string.");
}
return chain_t::ONE;
}
std::set<size_t> _get_valid_fir_lengths(const std::string& which)
{
auto dir = _get_direction_from_antenna(which);
switch (dir)
{
case uhd::direction_t::RX_DIRECTION:
return{ 24, 48, 72 };
case uhd::direction_t::TX_DIRECTION:
return{ 16, 32, 48, 64, 80, 96 };
default:
MPM_THROW_INVALID_CODE_PATH();
return std::set<size_t>();
}
}
uhd::meta_range_t _get_valid_rx_gain_steps()
{
// 0-7 step size is valid, in 0.5 dB increments
return uhd::meta_range_t(0, 3.5, 0.5);
}
uhd::meta_range_t _get_valid_tx_gain_steps()
{
// 0-31 step size is valid, in 0.05 dB increments
return uhd::meta_range_t(0, 1.55, 0.05);
}
uhd::meta_range_t ad937x_ctrl::get_rf_freq_range(void)
{
return uhd::meta_range_t(ad937x_device::MIN_FREQ, ad937x_device::MAX_FREQ);
}
uhd::meta_range_t ad937x_ctrl::get_bw_filter_range(void)
{
// TODO: fix
return uhd::meta_range_t(0, 1);
}
std::vector<double> ad937x_ctrl::get_clock_rates(void)
{
// TODO: fix
return { 125e6 };
}
uhd::meta_range_t ad937x_ctrl::get_gain_range(const std::string &which)
{
auto dir = _get_direction_from_antenna(which);
switch (dir)
{
case uhd::direction_t::RX_DIRECTION:
return uhd::meta_range_t(ad937x_device::MIN_RX_GAIN, ad937x_device::MAX_RX_GAIN, ad937x_device::RX_GAIN_STEP);
case uhd::direction_t::TX_DIRECTION:
return uhd::meta_range_t(ad937x_device::MIN_TX_GAIN, ad937x_device::MAX_TX_GAIN, ad937x_device::TX_GAIN_STEP);
default:
MPM_THROW_INVALID_CODE_PATH();
return uhd::meta_range_t();
}
}
class ad937x_ctrl_impl : public ad937x_ctrl
{
public:
ad937x_ctrl_impl(
std::shared_ptr<std::mutex> spi_mutex,
mpm::types::regs_iface::sptr iface,
mpm::ad937x::gpio::gain_pins_t gain_pins) :
spi_mutex(spi_mutex),
device(iface.get(), gain_pins),
_iface(iface)
{
/* nop */
}
virtual void begin_initialization()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.begin_initialization();
}
virtual void finish_initialization()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.finish_initialization();
}
virtual void setup_cal(uint32_t init_cals_mask, uint32_t tracking_cals_mask, uint32_t timeout)
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.setup_cal(init_cals_mask, tracking_cals_mask, timeout);
}
virtual void start_jesd_rx()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.start_jesd_rx();
}
virtual void start_jesd_tx()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.start_jesd_tx();
}
virtual void start_radio()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.start_radio();
}
virtual void stop_radio()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.stop_radio();
}
virtual uint8_t get_multichip_sync_status()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_multichip_sync_status();
}
virtual uint8_t get_framer_status()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_framer_status();
}
virtual uint8_t get_deframer_status()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_deframer_status();
}
virtual uint16_t get_ilas_config_match()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_ilas_config_match();
}
virtual void enable_jesd_loopback(uint8_t enable)
{
std::lock_guard<std::mutex> lock(*spi_mutex);
device.enable_jesd_loopback(enable);
}
virtual uint8_t get_product_id()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_product_id();
}
virtual uint8_t get_device_rev()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_device_rev();
}
virtual std::string get_api_version()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
auto api = device.get_api_version();
std::ostringstream ss;
ss << api.silicon_ver << "."
<< api.major_ver << "."
<< api.minor_ver << "."
<< api.build_ver;
return ss.str();
}
virtual std::string get_arm_version()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
auto arm = device.get_arm_version();
std::ostringstream ss;
ss << arm.major_ver << "."
<< arm.minor_ver << "."
<< arm.rc_ver;
switch (arm.build_type)
{
case mpm::ad937x::device::build_type_t::RELEASE:
ss << " Release";
break;
case mpm::ad937x::device::build_type_t::DEBUG:
ss << " Debug";
break;
case mpm::ad937x::device::build_type_t::TEST_OBJECT:
ss << " Test Object";
break;
}
return ss.str();
}
virtual double set_bw_filter(const std::string &which, double value)
{
// TODO implement
return double();
}
virtual double set_gain(const std::string &which, double value)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.set_gain(dir, chain, value);
}
virtual double get_gain(const std::string &which)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_gain(dir, chain);
}
// TODO: does agc mode need to have a which parameter?
// this affects all RX channels on the device
virtual void set_agc_mode(const std::string &which, const std::string &mode)
{
auto dir = _get_direction_from_antenna(which);
if (dir != uhd::direction_t::RX_DIRECTION)
{
throw mpm::runtime_error("set_agc not valid for non-rx channels");
}
ad937x_device::gain_mode_t gain_mode;
if (mode == "automatic")
{
gain_mode = ad937x_device::gain_mode_t::AUTOMATIC;
}
else if (mode == "manual") {
gain_mode = ad937x_device::gain_mode_t::MANUAL;
}
else if (mode == "hybrid") {
gain_mode = ad937x_device::gain_mode_t::HYBRID;
}
else {
throw mpm::runtime_error("invalid agc mode");
}
std::lock_guard<std::mutex> lock(*spi_mutex);
device.set_agc_mode(dir, gain_mode);
}
virtual double set_clock_rate(double value)
{
auto rates = get_clock_rates();
if (std::find(rates.cbegin(), rates.cend(), value) == rates.end())
{
value = *(rates.cbegin());
}
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.set_clock_rate(value);
}
virtual void enable_channel(const std::string &which, bool enable)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.enable_channel(dir, chain, enable);
}
virtual double set_freq(const std::string &which, double value, bool wait_for_lock)
{
auto dir = _get_direction_from_antenna(which);
auto clipped_value = get_rf_freq_range().clip(value);
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.tune(dir, clipped_value, wait_for_lock);
}
virtual double get_freq(const std::string &which)
{
auto dir = _get_direction_from_antenna(which);
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_freq(dir);
}
virtual void set_fir(const std::string &which, int8_t gain, const std::vector<int16_t> & fir)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
auto lengths = _get_valid_fir_lengths(which);
if (std::find(lengths.begin(), lengths.end(), fir.size()) == lengths.end())
{
throw mpm::value_error("invalid filter length");
}
std::lock_guard<std::mutex> lock(*spi_mutex);
device.set_fir(dir, chain, gain, fir);
}
virtual std::vector<int16_t> get_fir(const std::string &which, int8_t &gain)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_fir(dir, chain, gain);
}
virtual int16_t get_temperature()
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return device.get_temperature();
}
virtual void set_enable_gain_pins(const std::string &which, bool enable)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
std::lock_guard<std::mutex> lock(*spi_mutex);
device.set_enable_gain_pins(dir, chain, enable);
}
virtual void set_gain_pin_step_sizes(const std::string &which, double inc_step, double dec_step)
{
auto dir = _get_direction_from_antenna(which);
auto chain = _get_chain_from_antenna(which);
if (dir == uhd::RX_DIRECTION)
{
auto steps = _get_valid_rx_gain_steps();
inc_step = steps.clip(inc_step);
dec_step = steps.clip(dec_step);
}
else if (dir == uhd::TX_DIRECTION)
{
auto steps = _get_valid_tx_gain_steps();
inc_step = steps.clip(inc_step);
dec_step = steps.clip(dec_step);
// double comparison here should be okay because of clipping
if (inc_step != dec_step)
{
throw mpm::value_error("TX gain increment and decrement steps must be equal");
}
}
std::lock_guard<std::mutex> lock(*spi_mutex);
device.set_gain_pin_step_sizes(dir, chain, inc_step, dec_step);
}
uint8_t peek8(const uint32_t addr)
{
std::lock_guard<std::mutex> lock(*spi_mutex);
return _iface->peek8(addr);
}
void poke8(const uint32_t addr, const uint8_t val)
{
std::lock_guard<std::mutex> lock(*spi_mutex);
_iface->poke8(addr, val);
}
private:
ad937x_device device;
std::shared_ptr<std::mutex> spi_mutex;
mpm::types::regs_iface::sptr _iface;
};
ad937x_ctrl::sptr ad937x_ctrl::make(
std::shared_ptr<std::mutex> spi_mutex,
mpm::types::regs_iface::sptr iface,
mpm::ad937x::gpio::gain_pins_t gain_pins
) {
return std::make_shared<ad937x_ctrl_impl>(spi_mutex, iface, gain_pins);
}
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