//
// Copyright 2010-2011 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 .
//
#include "usrp2_impl.hpp"
#include "usrp2_regs.hpp"
#include "fw_common.h"
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
static const double mimo_clock_delay_usrp2_rev4 = 4.18e-9;
static const double mimo_clock_delay_usrp_n2xx = 3.55e-9;
static const size_t mimo_clock_sync_delay_cycles = 137;
using namespace uhd;
using namespace uhd::usrp;
using namespace uhd::transport;
/***********************************************************************
* Helpers
**********************************************************************/
static void init_xport(zero_copy_if::sptr xport){
//Send a small data packet so the usrp2 knows the udp source port.
//This setup must happen before further initialization occurs
//or the async update packets will cause ICMP destination unreachable.
static const boost::uint32_t data[2] = {
uhd::htonx(boost::uint32_t(0 /* don't care seq num */)),
uhd::htonx(boost::uint32_t(USRP2_INVALID_VRT_HEADER))
};
transport::managed_send_buffer::sptr send_buff = xport->get_send_buff();
std::memcpy(send_buff->cast(), &data, sizeof(data));
send_buff->commit(sizeof(data));
}
/***********************************************************************
* Structors
**********************************************************************/
usrp2_mboard_impl::usrp2_mboard_impl(
const device_addr_t &device_addr,
size_t index, usrp2_impl &device
):
_index(index), _device(device),
_iface(usrp2_iface::make(udp_simple::make_connected(
device_addr["addr"], BOOST_STRINGIZE(USRP2_UDP_CTRL_PORT)
)))
{
//check the fpga compatibility number
const boost::uint32_t fpga_compat_num = _iface->peek32(U2_REG_COMPAT_NUM_RB);
if (fpga_compat_num != USRP2_FPGA_COMPAT_NUM){
throw uhd::runtime_error(str(boost::format(
"\nPlease update the firmware and FPGA images for your device.\n"
"See the application notes for USRP2/N-Series for instructions.\n"
"Expected FPGA compatibility number %d, but got %d:\n"
"The FPGA build is not compatible with the host code build."
) % int(USRP2_FPGA_COMPAT_NUM) % fpga_compat_num));
}
//lock the device/motherboard to this process
_iface->lock_device(true);
//construct transports for dsp and async errors
UHD_LOG << "Making transport for DSP0..." << std::endl;
device.dsp_xports.push_back(udp_zero_copy::make(
device_addr["addr"], BOOST_STRINGIZE(USRP2_UDP_DSP0_PORT), device_addr
));
init_xport(device.dsp_xports.back());
UHD_LOG << "Making transport for DSP1..." << std::endl;
device.dsp_xports.push_back(udp_zero_copy::make(
device_addr["addr"], BOOST_STRINGIZE(USRP2_UDP_DSP1_PORT), device_addr
));
init_xport(device.dsp_xports.back());
UHD_LOG << "Making transport for ERR0..." << std::endl;
device.err_xports.push_back(udp_zero_copy::make(
device_addr["addr"], BOOST_STRINGIZE(USRP2_UDP_ERR0_PORT), device_addr_t()
));
init_xport(device.err_xports.back());
//contruct the interfaces to mboard perifs
_clock_ctrl = usrp2_clock_ctrl::make(_iface);
_codec_ctrl = usrp2_codec_ctrl::make(_iface);
if (_iface->mb_eeprom["gpsdo"] == "internal"){
_gps_ctrl = gps_ctrl::make(
_iface->get_gps_write_fn(),
_iface->get_gps_read_fn());
}
//init the dsp stuff (before setting update packets)
dsp_init();
//setting the cycles per update (disabled by default)
const double ups_per_sec = device_addr.cast("ups_per_sec", 20);
if (ups_per_sec > 0.0){
const size_t cycles_per_up = size_t(_clock_ctrl->get_master_clock_rate()/ups_per_sec);
_iface->poke32(U2_REG_TX_CTRL_CYCLES_PER_UP, U2_FLAG_TX_CTRL_UP_ENB | cycles_per_up);
}
//setting the packets per update (enabled by default)
size_t send_frame_size = device.dsp_xports[0]->get_send_frame_size();
const double ups_per_fifo = device_addr.cast("ups_per_fifo", 8.0);
if (ups_per_fifo > 0.0){
const size_t packets_per_up = size_t(usrp2_impl::sram_bytes/ups_per_fifo/send_frame_size);
_iface->poke32(U2_REG_TX_CTRL_PACKETS_PER_UP, U2_FLAG_TX_CTRL_UP_ENB | packets_per_up);
}
//initialize the clock configuration
if (device_addr.has_key("mimo_mode")){
if (device_addr["mimo_mode"] == "master"){
_mimo_clocking_mode_is_master = true;
}
else if (device_addr["mimo_mode"] == "slave"){
_mimo_clocking_mode_is_master = false;
}
else throw uhd::value_error(
"mimo_mode must be set to master or slave"
);
}
else {
_mimo_clocking_mode_is_master = (_iface->peek32(U2_REG_STATUS) & (1 << 8)) != 0;
}
UHD_MSG(status) << boost::format("mboard%d is MIMO %s") % _index %
(_mimo_clocking_mode_is_master?"master":"slave") << std::endl;
//init the clock config
_clock_config = clock_config_t::internal();
update_clock_config();
//init the codec before the dboard
codec_init();
//init the tx and rx dboards (do last)
dboard_init();
//set default subdev specs
(*this)[MBOARD_PROP_RX_SUBDEV_SPEC] = subdev_spec_t();
(*this)[MBOARD_PROP_TX_SUBDEV_SPEC] = subdev_spec_t();
//------------------------------------------------------------------
//This is a hack/fix for the lingering packet problem.
stream_cmd_t stream_cmd(stream_cmd_t::STREAM_MODE_NUM_SAMPS_AND_DONE);
for (size_t i = 0; i < NUM_RX_DSPS; i++){
size_t index = device.dsp_xports.size() - NUM_RX_DSPS + i;
stream_cmd.num_samps = 1;
this->issue_ddc_stream_cmd(stream_cmd, i);
device.dsp_xports.at(index)->get_recv_buff(0.01).get(); //recv with timeout for lingering
device.dsp_xports.at(index)->get_recv_buff(0.01).get(); //recv with timeout for expected
_iface->poke32(U2_REG_RX_CTRL_CLEAR(i), 1); //resets sequence
}
//------------------------------------------------------------------
}
usrp2_mboard_impl::~usrp2_mboard_impl(void){UHD_SAFE_CALL(
_iface->poke32(U2_REG_TX_CTRL_CYCLES_PER_UP, 0);
_iface->poke32(U2_REG_TX_CTRL_PACKETS_PER_UP, 0);
)}
/***********************************************************************
* Helper Methods
**********************************************************************/
void usrp2_mboard_impl::update_clock_config(void){
boost::uint32_t pps_flags = 0;
//slave mode overrides clock config settings
if (not _mimo_clocking_mode_is_master){
_clock_config.ref_source = clock_config_t::REF_MIMO;
_clock_config.pps_source = clock_config_t::PPS_MIMO;
}
//translate pps source enums
switch(_clock_config.pps_source){
case clock_config_t::PPS_MIMO:
_iface->poke32(U2_REG_TIME64_MIMO_SYNC,
(1 << 8) | (mimo_clock_sync_delay_cycles & 0xff)
);
break;
case clock_config_t::PPS_SMA:
_iface->poke32(U2_REG_TIME64_MIMO_SYNC, 0);
pps_flags |= U2_FLAG_TIME64_PPS_SMA;
break;
default: throw uhd::value_error("unhandled clock configuration pps source");
}
//translate pps polarity enums
switch(_clock_config.pps_polarity){
case clock_config_t::PPS_POS: pps_flags |= U2_FLAG_TIME64_PPS_POSEDGE; break;
case clock_config_t::PPS_NEG: pps_flags |= U2_FLAG_TIME64_PPS_NEGEDGE; break;
default: throw uhd::value_error("unhandled clock configuration pps polarity");
}
//set the pps flags
_iface->poke32(U2_REG_TIME64_FLAGS, pps_flags);
//clock source ref 10mhz
switch(_iface->get_rev()){
case usrp2_iface::USRP_N200:
case usrp2_iface::USRP_N210:
case usrp2_iface::USRP_N200_R4:
case usrp2_iface::USRP_N210_R4:
switch(_clock_config.ref_source){
case clock_config_t::REF_INT : _iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x12); break;
case clock_config_t::REF_SMA : _iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x1C); break;
case clock_config_t::REF_MIMO: _iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x15); break;
default: throw uhd::value_error("unhandled clock configuration reference source");
}
_clock_ctrl->enable_external_ref(true); //USRP2P has an internal 10MHz TCXO
break;
case usrp2_iface::USRP2_REV3:
case usrp2_iface::USRP2_REV4:
switch(_clock_config.ref_source){
case clock_config_t::REF_INT : _iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x10); break;
case clock_config_t::REF_SMA : _iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x1C); break;
case clock_config_t::REF_MIMO: _iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x15); break;
default: throw uhd::value_error("unhandled clock configuration reference source");
}
_clock_ctrl->enable_external_ref(_clock_config.ref_source != clock_config_t::REF_INT);
break;
case usrp2_iface::USRP_NXXX: break;
}
//masters always drive the clock over serdes
_clock_ctrl->enable_mimo_clock_out(_mimo_clocking_mode_is_master);
//set the mimo clock delay over the serdes
if (_mimo_clocking_mode_is_master){
switch(_iface->get_rev()){
case usrp2_iface::USRP_N200:
case usrp2_iface::USRP_N210:
case usrp2_iface::USRP_N200_R4:
case usrp2_iface::USRP_N210_R4:
_clock_ctrl->set_mimo_clock_delay(mimo_clock_delay_usrp_n2xx);
break;
case usrp2_iface::USRP2_REV4:
_clock_ctrl->set_mimo_clock_delay(mimo_clock_delay_usrp2_rev4);
break;
default: break; //not handled
}
}
}
void usrp2_mboard_impl::set_time_spec(const time_spec_t &time_spec, bool now){
//dont set the time for slave devices, they always take from mimo cable
if (not _mimo_clocking_mode_is_master) return;
//set the ticks
_iface->poke32(U2_REG_TIME64_TICKS, time_spec.get_tick_count(get_master_clock_freq()));
//set the flags register
boost::uint32_t imm_flags = (now)? U2_FLAG_TIME64_LATCH_NOW : U2_FLAG_TIME64_LATCH_NEXT_PPS;
_iface->poke32(U2_REG_TIME64_IMM, imm_flags);
//set the seconds (latches in all 3 registers)
_iface->poke32(U2_REG_TIME64_SECS, boost::uint32_t(time_spec.get_full_secs()));
}
/***********************************************************************
* MBoard Get Properties
**********************************************************************/
static const std::string dboard_name = "0";
void usrp2_mboard_impl::get(const wax::obj &key_, wax::obj &val){
named_prop_t key = named_prop_t::extract(key_);
//handle the get request conditioned on the key
switch(key.as()){
case MBOARD_PROP_NAME:
val = _iface->get_cname() + " mboard";
return;
case MBOARD_PROP_OTHERS:
val = prop_names_t();
return;
case MBOARD_PROP_RX_DBOARD:
UHD_ASSERT_THROW(key.name == dboard_name);
val = _rx_dboard_proxy->get_link();
return;
case MBOARD_PROP_RX_DBOARD_NAMES:
val = prop_names_t(1, dboard_name);
return;
case MBOARD_PROP_TX_DBOARD:
UHD_ASSERT_THROW(key.name == dboard_name);
val = _tx_dboard_proxy->get_link();
return;
case MBOARD_PROP_TX_DBOARD_NAMES:
val = prop_names_t(1, dboard_name);
return;
case MBOARD_PROP_RX_DSP:
val = _rx_dsp_proxies[key.name]->get_link();
return;
case MBOARD_PROP_RX_DSP_NAMES:
val = _rx_dsp_proxies.keys();
return;
case MBOARD_PROP_TX_DSP:
val = _tx_dsp_proxies[key.name]->get_link();
return;
case MBOARD_PROP_TX_DSP_NAMES:
val = _tx_dsp_proxies.keys();
return;
case MBOARD_PROP_CLOCK_CONFIG:
val = _clock_config;
return;
case MBOARD_PROP_TIME_NOW: while(true){
uint32_t secs = _iface->peek32(U2_REG_TIME64_SECS_RB_IMM);
uint32_t ticks = _iface->peek32(U2_REG_TIME64_TICKS_RB_IMM);
if (secs != _iface->peek32(U2_REG_TIME64_SECS_RB_IMM)) continue;
val = time_spec_t(secs, ticks, get_master_clock_freq());
return;
}
case MBOARD_PROP_TIME_PPS: while(true){
uint32_t secs = _iface->peek32(U2_REG_TIME64_SECS_RB_PPS);
uint32_t ticks = _iface->peek32(U2_REG_TIME64_TICKS_RB_PPS);
if (secs != _iface->peek32(U2_REG_TIME64_SECS_RB_PPS)) continue;
val = time_spec_t(secs, ticks, get_master_clock_freq());
return;
}
case MBOARD_PROP_RX_SUBDEV_SPEC:
val = _rx_subdev_spec;
return;
case MBOARD_PROP_TX_SUBDEV_SPEC:
val = _tx_subdev_spec;
return;
case MBOARD_PROP_EEPROM_MAP:
val = _iface->mb_eeprom;
return;
case MBOARD_PROP_CLOCK_RATE:
val = this->get_master_clock_freq();
return;
case SUBDEV_PROP_SENSOR_NAMES:{
prop_names_t names = boost::assign::list_of("mimo_locked")("ref_locked");
if (_gps_ctrl.get()) names.push_back("gps_time");
val = names;
}
return;
case MBOARD_PROP_SENSOR:
if(key.name == "mimo_locked") {
val = sensor_value_t("MIMO", this->get_mimo_locked(), "locked", "unlocked");
return;
}
else if(key.name == "ref_locked") {
val = sensor_value_t("Ref", this->get_ref_locked(), "locked", "unlocked");
return;
}
else if(key.name == "gps_time" and _gps_ctrl.get()) {
val = sensor_value_t("GPS time", int(_gps_ctrl->get_epoch_time()), "seconds");
}
else {
UHD_THROW_PROP_GET_ERROR();
}
break;
default: UHD_THROW_PROP_GET_ERROR();
}
}
bool usrp2_mboard_impl::get_mimo_locked(void) {
return bool((_iface->peek32(U2_REG_IRQ_RB) & (1<<10)) > 0);
}
bool usrp2_mboard_impl::get_ref_locked(void) {
return bool((_iface->peek32(U2_REG_IRQ_RB) & (1<<11)) > 0);
}
/***********************************************************************
* MBoard Set Properties
**********************************************************************/
void usrp2_mboard_impl::set(const wax::obj &key, const wax::obj &val){
//handle the set request conditioned on the key
switch(key.as()){
case MBOARD_PROP_CLOCK_CONFIG:
_clock_config = val.as();
update_clock_config();
return;
case MBOARD_PROP_TIME_NOW:
set_time_spec(val.as(), true);
return;
case MBOARD_PROP_TIME_PPS:
set_time_spec(val.as(), false);
return;
case MBOARD_PROP_RX_SUBDEV_SPEC:{
_rx_subdev_spec = val.as();
verify_rx_subdev_spec(_rx_subdev_spec, this->get_link());
//sanity check
UHD_ASSERT_THROW(_rx_subdev_spec.size() <= NUM_RX_DSPS);
//determine frontend swap IQ from the first channel
bool fe_swap_iq = false;
switch(_dboard_manager->get_rx_subdev(_rx_subdev_spec.at(0).sd_name)[SUBDEV_PROP_CONNECTION].as()){
case SUBDEV_CONN_COMPLEX_QI:
case SUBDEV_CONN_REAL_Q:
fe_swap_iq = true;
break;
default: fe_swap_iq = false;
}
_iface->poke32(U2_REG_RX_FE_SWAP_IQ, fe_swap_iq? 1 : 0);
//set the dsp mux for each channel
for (size_t i = 0; i < _rx_subdev_spec.size(); i++){
bool iq_swap = false, real_mode = false;
switch(_dboard_manager->get_rx_subdev(_rx_subdev_spec.at(i).sd_name)[SUBDEV_PROP_CONNECTION].as()){
case SUBDEV_CONN_COMPLEX_IQ:
iq_swap = fe_swap_iq;
real_mode = false;
break;
case SUBDEV_CONN_COMPLEX_QI:
iq_swap = not fe_swap_iq;
real_mode = false;
break;
case SUBDEV_CONN_REAL_I:
iq_swap = fe_swap_iq;
real_mode = true;
break;
case SUBDEV_CONN_REAL_Q:
iq_swap = not fe_swap_iq;
real_mode = true;
break;
}
_iface->poke32(U2_REG_DSP_RX_MUX(i),
(iq_swap? U2_FLAG_DSP_RX_MUX_SWAP_IQ : 0) |
(real_mode? U2_FLAG_DSP_RX_MUX_REAL_MODE : 0)
);
}
_device.update_xport_channel_mapping();
}return;
case MBOARD_PROP_TX_SUBDEV_SPEC:
_tx_subdev_spec = val.as();
verify_tx_subdev_spec(_tx_subdev_spec, this->get_link());
//sanity check
UHD_ASSERT_THROW(_tx_subdev_spec.size() <= NUM_TX_DSPS);
//set the mux
for (size_t i = 0; i < _rx_subdev_spec.size(); i++){
_iface->poke32(U2_REG_TX_FE_MUX, dsp_type1::calc_tx_mux_word(
_dboard_manager->get_tx_subdev(_tx_subdev_spec[i].sd_name)[SUBDEV_PROP_CONNECTION].as()
));
}
_device.update_xport_channel_mapping();
return;
case MBOARD_PROP_EEPROM_MAP:
// Step1: commit the map, writing only those values set.
// Step2: readback the entire eeprom map into the iface.
val.as().commit(*_iface, mboard_eeprom_t::MAP_N100);
_iface->mb_eeprom = mboard_eeprom_t(*_iface, mboard_eeprom_t::MAP_N100);
return;
case MBOARD_PROP_CLOCK_RATE:
UHD_ASSERT_THROW(val.as() == this->get_master_clock_freq());
_device.update_xport_channel_mapping();
return;
default: UHD_THROW_PROP_SET_ERROR();
}
}