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//
// Copyright 2010 Ettus Research LLC
//
// 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 "usrp2_iface.hpp"
#include "clock_ctrl.hpp"
#include "usrp2_regs.hpp" //wishbone address constants
#include <uhd/usrp/dboard_iface.hpp>
#include <uhd/types/dict.hpp>
#include <uhd/utils/assert.hpp>
#include <uhd/utils/algorithm.hpp>
#include <boost/assign/list_of.hpp>
#include <boost/asio.hpp> //htonl and ntohl
#include <boost/math/special_functions/round.hpp>
#include "ad7922_regs.hpp" //aux adc
#include "ad5623_regs.hpp" //aux dac
using namespace uhd;
using namespace uhd::usrp;
using namespace boost::assign;
class usrp2_dboard_iface : public dboard_iface{
public:
usrp2_dboard_iface(usrp2_iface::sptr iface, usrp2_clock_ctrl::sptr clock_ctrl);
~usrp2_dboard_iface(void);
void write_aux_dac(unit_t, aux_dac_t, float);
float read_aux_adc(unit_t, aux_adc_t);
void set_pin_ctrl(unit_t, boost::uint16_t);
void set_atr_reg(unit_t, atr_reg_t, boost::uint16_t);
void set_gpio_ddr(unit_t, boost::uint16_t);
void write_gpio(unit_t, boost::uint16_t);
boost::uint16_t read_gpio(unit_t);
void write_i2c(boost::uint8_t, const byte_vector_t &);
byte_vector_t read_i2c(boost::uint8_t, size_t);
void set_clock_rate(unit_t, double);
double get_clock_rate(unit_t);
std::vector<double> get_clock_rates(unit_t);
void set_clock_enabled(unit_t, bool);
void write_spi(
unit_t unit,
const spi_config_t &config,
boost::uint32_t data,
size_t num_bits
);
boost::uint32_t read_write_spi(
unit_t unit,
const spi_config_t &config,
boost::uint32_t data,
size_t num_bits
);
private:
usrp2_iface::sptr _iface;
usrp2_clock_ctrl::sptr _clock_ctrl;
boost::uint32_t _ddr_shadow;
boost::uint32_t _gpio_shadow;
uhd::dict<unit_t, ad5623_regs_t> _dac_regs;
uhd::dict<unit_t, double> _clock_rates;
void _write_aux_dac(unit_t);
};
/***********************************************************************
* Make Function
**********************************************************************/
dboard_iface::sptr make_usrp2_dboard_iface(
usrp2_iface::sptr iface,
usrp2_clock_ctrl::sptr clock_ctrl
){
return dboard_iface::sptr(new usrp2_dboard_iface(iface, clock_ctrl));
}
/***********************************************************************
* Structors
**********************************************************************/
usrp2_dboard_iface::usrp2_dboard_iface(
usrp2_iface::sptr iface,
usrp2_clock_ctrl::sptr clock_ctrl
){
_iface = iface;
_clock_ctrl = clock_ctrl;
_ddr_shadow = 0;
_gpio_shadow = 0;
//reset the aux dacs
_dac_regs[UNIT_RX] = ad5623_regs_t();
_dac_regs[UNIT_TX] = ad5623_regs_t();
BOOST_FOREACH(unit_t unit, _dac_regs.keys()){
_dac_regs[unit].data = 1;
_dac_regs[unit].addr = ad5623_regs_t::ADDR_ALL;
_dac_regs[unit].cmd = ad5623_regs_t::CMD_RESET;
this->_write_aux_dac(unit);
}
//init the clock rate shadows with max rate clock
this->set_clock_rate(UNIT_RX, sorted(this->get_clock_rates(UNIT_RX)).back());
this->set_clock_rate(UNIT_TX, sorted(this->get_clock_rates(UNIT_TX)).back());
}
usrp2_dboard_iface::~usrp2_dboard_iface(void){
/* NOP */
}
/***********************************************************************
* Clocks
**********************************************************************/
void usrp2_dboard_iface::set_clock_rate(unit_t unit, double rate){
_clock_rates[unit] = rate; //set to shadow
switch(unit){
case UNIT_RX: _clock_ctrl->set_rate_rx_dboard_clock(rate); return;
case UNIT_TX: _clock_ctrl->set_rate_tx_dboard_clock(rate); return;
}
}
double usrp2_dboard_iface::get_clock_rate(unit_t unit){
return _clock_rates[unit]; //get from shadow
}
std::vector<double> usrp2_dboard_iface::get_clock_rates(unit_t unit){
switch(unit){
case UNIT_RX: return _clock_ctrl->get_rates_rx_dboard_clock();
case UNIT_TX: return _clock_ctrl->get_rates_tx_dboard_clock();
default: UHD_THROW_INVALID_CODE_PATH();
}
}
void usrp2_dboard_iface::set_clock_enabled(unit_t unit, bool enb){
switch(unit){
case UNIT_RX: _clock_ctrl->enable_rx_dboard_clock(enb); return;
case UNIT_TX: _clock_ctrl->enable_tx_dboard_clock(enb); return;
}
}
/***********************************************************************
* GPIO
**********************************************************************/
static const uhd::dict<dboard_iface::unit_t, int> unit_to_shift = map_list_of
(dboard_iface::UNIT_RX, 0)
(dboard_iface::UNIT_TX, 16)
;
void usrp2_dboard_iface::set_pin_ctrl(unit_t unit, boost::uint16_t value){
//calculate the new selection mux setting
boost::uint32_t new_sels = 0x0;
for(size_t i = 0; i < 16; i++){
bool is_bit_set = (value & (0x1 << i)) != 0;
new_sels |= ((is_bit_set)? U2_FLAG_GPIO_SEL_ATR : U2_FLAG_GPIO_SEL_GPIO) << (i*2);
}
//write the selection mux value to register
switch(unit){
case UNIT_RX: _iface->poke32(U2_REG_GPIO_RX_SEL, new_sels); return;
case UNIT_TX: _iface->poke32(U2_REG_GPIO_TX_SEL, new_sels); return;
}
}
void usrp2_dboard_iface::set_gpio_ddr(unit_t unit, boost::uint16_t value){
_ddr_shadow = \
(_ddr_shadow & ~(0xffff << unit_to_shift[unit])) |
(boost::uint32_t(value) << unit_to_shift[unit]);
_iface->poke32(U2_REG_GPIO_DDR, _ddr_shadow);
}
void usrp2_dboard_iface::write_gpio(unit_t unit, boost::uint16_t value){
_gpio_shadow = \
(_gpio_shadow & ~(0xffff << unit_to_shift[unit])) |
(boost::uint32_t(value) << unit_to_shift[unit]);
_iface->poke32(U2_REG_GPIO_IO, _gpio_shadow);
}
boost::uint16_t usrp2_dboard_iface::read_gpio(unit_t unit){
return boost::uint16_t(_iface->peek32(U2_REG_GPIO_IO) >> unit_to_shift[unit]);
}
void usrp2_dboard_iface::set_atr_reg(unit_t unit, atr_reg_t atr, boost::uint16_t value){
//define mapping of unit to atr regs to register address
static const uhd::dict<
unit_t, uhd::dict<atr_reg_t, boost::uint32_t>
> unit_to_atr_to_addr = map_list_of
(UNIT_RX, map_list_of
(ATR_REG_IDLE, U2_REG_ATR_IDLE_RXSIDE)
(ATR_REG_TX_ONLY, U2_REG_ATR_INTX_RXSIDE)
(ATR_REG_RX_ONLY, U2_REG_ATR_INRX_RXSIDE)
(ATR_REG_FULL_DUPLEX, U2_REG_ATR_FULL_RXSIDE)
)
(UNIT_TX, map_list_of
(ATR_REG_IDLE, U2_REG_ATR_IDLE_TXSIDE)
(ATR_REG_TX_ONLY, U2_REG_ATR_INTX_TXSIDE)
(ATR_REG_RX_ONLY, U2_REG_ATR_INRX_TXSIDE)
(ATR_REG_FULL_DUPLEX, U2_REG_ATR_FULL_TXSIDE)
)
;
_iface->poke16(unit_to_atr_to_addr[unit][atr], value);
}
/***********************************************************************
* SPI
**********************************************************************/
static const uhd::dict<dboard_iface::unit_t, int> unit_to_spi_dev = map_list_of
(dboard_iface::UNIT_TX, SPI_SS_TX_DB)
(dboard_iface::UNIT_RX, SPI_SS_RX_DB)
;
void usrp2_dboard_iface::write_spi(
unit_t unit,
const spi_config_t &config,
boost::uint32_t data,
size_t num_bits
){
_iface->transact_spi(unit_to_spi_dev[unit], config, data, num_bits, false /*no rb*/);
}
boost::uint32_t usrp2_dboard_iface::read_write_spi(
unit_t unit,
const spi_config_t &config,
boost::uint32_t data,
size_t num_bits
){
return _iface->transact_spi(unit_to_spi_dev[unit], config, data, num_bits, true /*rb*/);
}
/***********************************************************************
* I2C
**********************************************************************/
void usrp2_dboard_iface::write_i2c(boost::uint8_t addr, const byte_vector_t &bytes){
return _iface->write_i2c(addr, bytes);
}
byte_vector_t usrp2_dboard_iface::read_i2c(boost::uint8_t addr, size_t num_bytes){
return _iface->read_i2c(addr, num_bytes);
}
/***********************************************************************
* Aux DAX/ADC
**********************************************************************/
void usrp2_dboard_iface::_write_aux_dac(unit_t unit){
static const uhd::dict<unit_t, int> unit_to_spi_dac = map_list_of
(UNIT_RX, SPI_SS_RX_DAC)
(UNIT_TX, SPI_SS_TX_DAC)
;
_iface->transact_spi(
unit_to_spi_dac[unit], spi_config_t::EDGE_FALL,
_dac_regs[unit].get_reg(), 24, false /*no rb*/
);
}
void usrp2_dboard_iface::write_aux_dac(unit_t unit, aux_dac_t which, float value){
_dac_regs[unit].data = boost::math::iround(4095*value/3.3);
_dac_regs[unit].cmd = ad5623_regs_t::CMD_WR_UP_DAC_CHAN_N;
typedef uhd::dict<aux_dac_t, ad5623_regs_t::addr_t> aux_dac_to_addr;
static const uhd::dict<unit_t, aux_dac_to_addr> unit_to_which_to_addr = map_list_of
(UNIT_RX, map_list_of
(AUX_DAC_A, ad5623_regs_t::ADDR_DAC_B)
(AUX_DAC_B, ad5623_regs_t::ADDR_DAC_A)
(AUX_DAC_C, ad5623_regs_t::ADDR_DAC_A)
(AUX_DAC_D, ad5623_regs_t::ADDR_DAC_B)
)
(UNIT_TX, map_list_of
(AUX_DAC_A, ad5623_regs_t::ADDR_DAC_A)
(AUX_DAC_B, ad5623_regs_t::ADDR_DAC_B)
(AUX_DAC_C, ad5623_regs_t::ADDR_DAC_B)
(AUX_DAC_D, ad5623_regs_t::ADDR_DAC_A)
)
;
_dac_regs[unit].addr = unit_to_which_to_addr[unit][which];
this->_write_aux_dac(unit);
}
float usrp2_dboard_iface::read_aux_adc(unit_t unit, aux_adc_t which){
static const uhd::dict<unit_t, int> unit_to_spi_adc = map_list_of
(UNIT_RX, SPI_SS_RX_ADC)
(UNIT_TX, SPI_SS_TX_ADC)
;
//setup spi config args
spi_config_t config;
config.mosi_edge = spi_config_t::EDGE_FALL;
config.miso_edge = spi_config_t::EDGE_RISE;
//setup the spi registers
ad7922_regs_t ad7922_regs;
switch(which){
case AUX_ADC_A: ad7922_regs.mod = 0; break;
case AUX_ADC_B: ad7922_regs.mod = 1; break;
} ad7922_regs.chn = ad7922_regs.mod; //normal mode: mod == chn
//write and read spi
_iface->transact_spi(
unit_to_spi_adc[unit], config,
ad7922_regs.get_reg(), 16, false /*no rb*/
);
ad7922_regs.set_reg(boost::uint16_t(_iface->transact_spi(
unit_to_spi_adc[unit], config,
ad7922_regs.get_reg(), 16, true /*rb*/
)));
//convert to voltage and return
return float(3.3*ad7922_regs.result/4095);
}
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