//
// Copyright 2010-2012 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 "fw_common.h"
#include "apply_corrections.hpp"
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include //used for htonl and ntohl
using namespace uhd;
using namespace uhd::usrp;
using namespace uhd::transport;
namespace asio = boost::asio;
/***********************************************************************
* Discovery over the udp transport
**********************************************************************/
static device_addrs_t usrp2_find(const device_addr_t &hint_){
//handle the multi-device discovery
device_addrs_t hints = separate_device_addr(hint_);
if (hints.size() > 1){
device_addrs_t found_devices;
BOOST_FOREACH(const device_addr_t &hint_i, hints){
device_addrs_t found_devices_i = usrp2_find(hint_i);
if (found_devices_i.size() != 1) throw uhd::value_error(str(boost::format(
"Could not resolve device hint \"%s\" to a single device."
) % hint_i.to_string()));
found_devices.push_back(found_devices_i[0]);
}
return device_addrs_t(1, combine_device_addrs(found_devices));
}
//initialize the hint for a single device case
UHD_ASSERT_THROW(hints.size() <= 1);
hints.resize(1); //in case it was empty
device_addr_t hint = hints[0];
device_addrs_t usrp2_addrs;
//return an empty list of addresses when type is set to non-usrp2
if (hint.has_key("type") and hint["type"] != "usrp2") return usrp2_addrs;
//if no address was specified, send a broadcast on each interface
if (not hint.has_key("addr")){
BOOST_FOREACH(const if_addrs_t &if_addrs, get_if_addrs()){
//avoid the loopback device
if (if_addrs.inet == asio::ip::address_v4::loopback().to_string()) continue;
//create a new hint with this broadcast address
device_addr_t new_hint = hint;
new_hint["addr"] = if_addrs.bcast;
//call discover with the new hint and append results
device_addrs_t new_usrp2_addrs = usrp2_find(new_hint);
usrp2_addrs.insert(usrp2_addrs.begin(),
new_usrp2_addrs.begin(), new_usrp2_addrs.end()
);
}
return usrp2_addrs;
}
//Create a UDP transport to communicate:
//Some devices will cause a throw when opened for a broadcast address.
//We print and recover so the caller can loop through all bcast addrs.
udp_simple::sptr udp_transport;
try{
udp_transport = udp_simple::make_broadcast(hint["addr"], BOOST_STRINGIZE(USRP2_UDP_CTRL_PORT));
}
catch(const std::exception &e){
UHD_MSG(error) << boost::format("Cannot open UDP transport on %s\n%s") % hint["addr"] % e.what() << std::endl;
return usrp2_addrs; //dont throw, but return empty address so caller can insert
}
//send a hello control packet
usrp2_ctrl_data_t ctrl_data_out = usrp2_ctrl_data_t();
ctrl_data_out.proto_ver = uhd::htonx(USRP2_FW_COMPAT_NUM);
ctrl_data_out.id = uhd::htonx(USRP2_CTRL_ID_WAZZUP_BRO);
udp_transport->send(boost::asio::buffer(&ctrl_data_out, sizeof(ctrl_data_out)));
//loop and recieve until the timeout
boost::uint8_t usrp2_ctrl_data_in_mem[udp_simple::mtu]; //allocate max bytes for recv
const usrp2_ctrl_data_t *ctrl_data_in = reinterpret_cast(usrp2_ctrl_data_in_mem);
while(true){
size_t len = udp_transport->recv(asio::buffer(usrp2_ctrl_data_in_mem));
if (len > offsetof(usrp2_ctrl_data_t, data) and ntohl(ctrl_data_in->id) == USRP2_CTRL_ID_WAZZUP_DUDE){
//make a boost asio ipv4 with the raw addr in host byte order
device_addr_t new_addr;
new_addr["type"] = "usrp2";
//We used to get the address from the control packet.
//Now now uses the socket itself to yield the address.
//boost::asio::ip::address_v4 ip_addr(ntohl(ctrl_data_in->data.ip_addr));
//new_addr["addr"] = ip_addr.to_string();
new_addr["addr"] = udp_transport->get_recv_addr();
//Attempt to read the name from the EEPROM and perform filtering.
//This operation can throw due to compatibility mismatch.
try{
usrp2_iface::sptr iface = usrp2_iface::make(udp_simple::make_connected(
new_addr["addr"], BOOST_STRINGIZE(USRP2_UDP_CTRL_PORT)
));
if (iface->is_device_locked()) continue; //ignore locked devices
mboard_eeprom_t mb_eeprom = iface->mb_eeprom;
new_addr["name"] = mb_eeprom["name"];
new_addr["serial"] = mb_eeprom["serial"];
}
catch(const std::exception &){
//set these values as empty string so the device may still be found
//and the filter's below can still operate on the discovered device
new_addr["name"] = "";
new_addr["serial"] = "";
}
//filter the discovered device below by matching optional keys
if (
(not hint.has_key("name") or hint["name"] == new_addr["name"]) and
(not hint.has_key("serial") or hint["serial"] == new_addr["serial"])
){
usrp2_addrs.push_back(new_addr);
}
//dont break here, it will exit the while loop
//just continue on to the next loop iteration
}
if (len == 0) break; //timeout
}
return usrp2_addrs;
}
/***********************************************************************
* Make
**********************************************************************/
static device::sptr usrp2_make(const device_addr_t &device_addr){
return device::sptr(new usrp2_impl(device_addr));
}
UHD_STATIC_BLOCK(register_usrp2_device){
device::register_device(&usrp2_find, &usrp2_make);
}
/***********************************************************************
* MTU Discovery
**********************************************************************/
struct mtu_result_t{
size_t recv_mtu, send_mtu;
};
static mtu_result_t determine_mtu(const std::string &addr, const mtu_result_t &user_mtu){
udp_simple::sptr udp_sock = udp_simple::make_connected(
addr, BOOST_STRINGIZE(USRP2_UDP_CTRL_PORT)
);
//The FPGA offers 4K buffers, and the user may manually request this.
//However, multiple simultaneous receives (2DSP slave + 2DSP master),
//require that buffering to be used internally, and this is a safe setting.
std::vector buffer(std::max(user_mtu.recv_mtu, user_mtu.send_mtu));
usrp2_ctrl_data_t *ctrl_data = reinterpret_cast(&buffer.front());
static const double echo_timeout = 0.020; //20 ms
//test holler - check if its supported in this fw version
ctrl_data->id = htonl(USRP2_CTRL_ID_HOLLER_AT_ME_BRO);
ctrl_data->proto_ver = htonl(USRP2_FW_COMPAT_NUM);
ctrl_data->data.echo_args.len = htonl(sizeof(usrp2_ctrl_data_t));
udp_sock->send(boost::asio::buffer(buffer, sizeof(usrp2_ctrl_data_t)));
udp_sock->recv(boost::asio::buffer(buffer), echo_timeout);
if (ntohl(ctrl_data->id) != USRP2_CTRL_ID_HOLLER_BACK_DUDE)
throw uhd::not_implemented_error("holler protocol not implemented");
size_t min_recv_mtu = sizeof(usrp2_ctrl_data_t), max_recv_mtu = user_mtu.recv_mtu;
size_t min_send_mtu = sizeof(usrp2_ctrl_data_t), max_send_mtu = user_mtu.send_mtu;
while (min_recv_mtu < max_recv_mtu){
size_t test_mtu = (max_recv_mtu/2 + min_recv_mtu/2 + 3) & ~3;
ctrl_data->id = htonl(USRP2_CTRL_ID_HOLLER_AT_ME_BRO);
ctrl_data->proto_ver = htonl(USRP2_FW_COMPAT_NUM);
ctrl_data->data.echo_args.len = htonl(test_mtu);
udp_sock->send(boost::asio::buffer(buffer, sizeof(usrp2_ctrl_data_t)));
size_t len = udp_sock->recv(boost::asio::buffer(buffer), echo_timeout);
if (len >= test_mtu) min_recv_mtu = test_mtu;
else max_recv_mtu = test_mtu - 4;
}
while (min_send_mtu < max_send_mtu){
size_t test_mtu = (max_send_mtu/2 + min_send_mtu/2 + 3) & ~3;
ctrl_data->id = htonl(USRP2_CTRL_ID_HOLLER_AT_ME_BRO);
ctrl_data->proto_ver = htonl(USRP2_FW_COMPAT_NUM);
ctrl_data->data.echo_args.len = htonl(sizeof(usrp2_ctrl_data_t));
udp_sock->send(boost::asio::buffer(buffer, test_mtu));
size_t len = udp_sock->recv(boost::asio::buffer(buffer), echo_timeout);
if (len >= sizeof(usrp2_ctrl_data_t)) len = ntohl(ctrl_data->data.echo_args.len);
if (len >= test_mtu) min_send_mtu = test_mtu;
else max_send_mtu = test_mtu - 4;
}
mtu_result_t mtu;
mtu.recv_mtu = min_recv_mtu;
mtu.send_mtu = min_send_mtu;
return mtu;
}
/***********************************************************************
* Helpers
**********************************************************************/
static zero_copy_if::sptr make_xport(
const std::string &addr,
const std::string &port,
const device_addr_t &hints,
const std::string &filter
){
//only copy hints that contain the filter word
device_addr_t filtered_hints;
BOOST_FOREACH(const std::string &key, hints.keys()){
if (key.find(filter) == std::string::npos) continue;
filtered_hints[key] = hints[key];
}
//make the transport object with the filtered hints
zero_copy_if::sptr xport = udp_zero_copy::make(addr, port, filtered_hints);
//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));
return xport;
}
/***********************************************************************
* Structors
**********************************************************************/
usrp2_impl::usrp2_impl(const device_addr_t &_device_addr){
UHD_MSG(status) << "Opening a USRP2/N-Series device..." << std::endl;
device_addr_t device_addr = _device_addr;
//setup the dsp transport hints (default to a large recv buff)
if (not device_addr.has_key("recv_buff_size")){
#if defined(UHD_PLATFORM_MACOS) || defined(UHD_PLATFORM_BSD)
//limit buffer resize on macos or it will error
device_addr["recv_buff_size"] = "1e6";
#elif defined(UHD_PLATFORM_LINUX) || defined(UHD_PLATFORM_WIN32)
//set to half-a-second of buffering at max rate
device_addr["recv_buff_size"] = "50e6";
#endif
}
if (not device_addr.has_key("send_buff_size")){
//The buffer should be the size of the SRAM on the device,
//because we will never commit more than the SRAM can hold.
device_addr["send_buff_size"] = boost::lexical_cast(USRP2_SRAM_BYTES);
}
device_addrs_t device_args = separate_device_addr(device_addr);
//extract the user's requested MTU size or default
mtu_result_t user_mtu;
user_mtu.recv_mtu = size_t(device_addr.cast("recv_frame_size", udp_simple::mtu));
user_mtu.send_mtu = size_t(device_addr.cast("send_frame_size", udp_simple::mtu));
try{
//calculate the minimum send and recv mtu of all devices
mtu_result_t mtu = determine_mtu(device_args[0]["addr"], user_mtu);
for (size_t i = 1; i < device_args.size(); i++){
mtu_result_t mtu_i = determine_mtu(device_args[i]["addr"], user_mtu);
mtu.recv_mtu = std::min(mtu.recv_mtu, mtu_i.recv_mtu);
mtu.send_mtu = std::min(mtu.send_mtu, mtu_i.send_mtu);
}
device_addr["recv_frame_size"] = boost::lexical_cast(mtu.recv_mtu);
device_addr["send_frame_size"] = boost::lexical_cast(mtu.send_mtu);
UHD_MSG(status) << boost::format("Current recv frame size: %d bytes") % mtu.recv_mtu << std::endl;
UHD_MSG(status) << boost::format("Current send frame size: %d bytes") % mtu.send_mtu << std::endl;
}
catch(const uhd::not_implemented_error &){
//just ignore this error, makes older fw work...
}
device_args = separate_device_addr(device_addr); //update args for new frame sizes
////////////////////////////////////////////////////////////////////
// create controller objects and initialize the properties tree
////////////////////////////////////////////////////////////////////
_tree = property_tree::make();
_tree->create("/name").set("USRP2 / N-Series Device");
for (size_t mbi = 0; mbi < device_args.size(); mbi++){
const device_addr_t device_args_i = device_args[mbi];
const std::string mb = boost::lexical_cast(mbi);
const std::string addr = device_args_i["addr"];
const fs_path mb_path = "/mboards/" + mb;
////////////////////////////////////////////////////////////////
// create the iface that controls i2c, spi, uart, and wb
////////////////////////////////////////////////////////////////
_mbc[mb].iface = usrp2_iface::make(udp_simple::make_connected(
addr, BOOST_STRINGIZE(USRP2_UDP_CTRL_PORT)
));
_tree->create(mb_path / "name").set(_mbc[mb].iface->get_cname());
_tree->create(mb_path / "fw_version").set(_mbc[mb].iface->get_fw_version_string());
//check the fpga compatibility number
const boost::uint32_t fpga_compat_num = _mbc[mb].iface->peek32(U2_REG_COMPAT_NUM_RB);
boost::uint16_t fpga_major = fpga_compat_num >> 16, fpga_minor = fpga_compat_num & 0xffff;
if (fpga_major == 0){ //old version scheme
fpga_major = fpga_minor;
fpga_minor = 0;
}
if (fpga_major != 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_major));
}
_tree->create(mb_path / "fpga_version").set(str(boost::format("%u.%u") % fpga_major % fpga_minor));
//lock the device/motherboard to this process
_mbc[mb].iface->lock_device(true);
////////////////////////////////////////////////////////////////
// construct transports for RX and TX DSPs
////////////////////////////////////////////////////////////////
UHD_LOG << "Making transport for RX DSP0..." << std::endl;
_mbc[mb].rx_dsp_xports.push_back(make_xport(
addr, BOOST_STRINGIZE(USRP2_UDP_RX_DSP0_PORT), device_args_i, "recv"
));
UHD_LOG << "Making transport for RX DSP1..." << std::endl;
_mbc[mb].rx_dsp_xports.push_back(make_xport(
addr, BOOST_STRINGIZE(USRP2_UDP_RX_DSP1_PORT), device_args_i, "recv"
));
UHD_LOG << "Making transport for TX DSP0..." << std::endl;
_mbc[mb].tx_dsp_xport = make_xport(
addr, BOOST_STRINGIZE(USRP2_UDP_TX_DSP0_PORT), device_args_i, "send"
);
//set the filter on the router to take dsp data from this port
_mbc[mb].iface->poke32(U2_REG_ROUTER_CTRL_PORTS, USRP2_UDP_TX_DSP0_PORT);
////////////////////////////////////////////////////////////////
// setup the mboard eeprom
////////////////////////////////////////////////////////////////
_tree->create(mb_path / "eeprom")
.set(_mbc[mb].iface->mb_eeprom)
.subscribe(boost::bind(&usrp2_impl::set_mb_eeprom, this, mb, _1));
////////////////////////////////////////////////////////////////
// create clock control objects
////////////////////////////////////////////////////////////////
_mbc[mb].clock = usrp2_clock_ctrl::make(_mbc[mb].iface);
_tree->create(mb_path / "tick_rate")
.publish(boost::bind(&usrp2_clock_ctrl::get_master_clock_rate, _mbc[mb].clock))
.subscribe(boost::bind(&usrp2_impl::update_tick_rate, this, _1));
////////////////////////////////////////////////////////////////
// create codec control objects
////////////////////////////////////////////////////////////////
const fs_path rx_codec_path = mb_path / "rx_codecs/A";
const fs_path tx_codec_path = mb_path / "tx_codecs/A";
_tree->create(rx_codec_path / "gains"); //phony property so this dir exists
_tree->create(tx_codec_path / "gains"); //phony property so this dir exists
_mbc[mb].codec = usrp2_codec_ctrl::make(_mbc[mb].iface);
switch(_mbc[mb].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:{
_tree->create(rx_codec_path / "name").set("ads62p44");
_tree->create(rx_codec_path / "gains/digital/range").set(meta_range_t(0, 6.0, 0.5));
_tree->create(rx_codec_path / "gains/digital/value")
.subscribe(boost::bind(&usrp2_codec_ctrl::set_rx_digital_gain, _mbc[mb].codec, _1)).set(0);
_tree->create(rx_codec_path / "gains/fine/range").set(meta_range_t(0, 0.5, 0.05));
_tree->create(rx_codec_path / "gains/fine/value")
.subscribe(boost::bind(&usrp2_codec_ctrl::set_rx_digital_fine_gain, _mbc[mb].codec, _1)).set(0);
}break;
case usrp2_iface::USRP2_REV3:
case usrp2_iface::USRP2_REV4:
_tree->create(rx_codec_path / "name").set("ltc2284");
break;
case usrp2_iface::USRP_NXXX:
_tree->create(rx_codec_path / "name").set("??????");
break;
}
_tree->create(tx_codec_path / "name").set("ad9777");
////////////////////////////////////////////////////////////////
// create gpsdo control objects
////////////////////////////////////////////////////////////////
if (_mbc[mb].iface->mb_eeprom["gpsdo"] == "internal"){
_mbc[mb].gps = gps_ctrl::make(udp_simple::make_uart(udp_simple::make_connected(
addr, BOOST_STRINGIZE(USRP2_UDP_UART_GPS_PORT)
)));
if(_mbc[mb].gps->gps_detected()) {
BOOST_FOREACH(const std::string &name, _mbc[mb].gps->get_sensors()){
_tree->create(mb_path / "sensors" / name)
.publish(boost::bind(&gps_ctrl::get_sensor, _mbc[mb].gps, name));
}
}
}
////////////////////////////////////////////////////////////////
// and do the misc mboard sensors
////////////////////////////////////////////////////////////////
_tree->create(mb_path / "sensors/mimo_locked")
.publish(boost::bind(&usrp2_impl::get_mimo_locked, this, mb));
_tree->create(mb_path / "sensors/ref_locked")
.publish(boost::bind(&usrp2_impl::get_ref_locked, this, mb));
////////////////////////////////////////////////////////////////
// create frontend control objects
////////////////////////////////////////////////////////////////
_mbc[mb].rx_fe = rx_frontend_core_200::make(
_mbc[mb].iface, U2_REG_SR_ADDR(SR_RX_FRONT)
);
_mbc[mb].tx_fe = tx_frontend_core_200::make(
_mbc[mb].iface, U2_REG_SR_ADDR(SR_TX_FRONT)
);
_tree->create(mb_path / "rx_subdev_spec")
.subscribe(boost::bind(&usrp2_impl::update_rx_subdev_spec, this, mb, _1));
_tree->create(mb_path / "tx_subdev_spec")
.subscribe(boost::bind(&usrp2_impl::update_tx_subdev_spec, this, mb, _1));
const fs_path rx_fe_path = mb_path / "rx_frontends" / "A";
const fs_path tx_fe_path = mb_path / "tx_frontends" / "A";
_tree->create >(rx_fe_path / "dc_offset" / "value")
.coerce(boost::bind(&rx_frontend_core_200::set_dc_offset, _mbc[mb].rx_fe, _1))
.set(std::complex(0.0, 0.0));
_tree->create(rx_fe_path / "dc_offset" / "enable")
.subscribe(boost::bind(&rx_frontend_core_200::set_dc_offset_auto, _mbc[mb].rx_fe, _1))
.set(true);
_tree->create >(rx_fe_path / "iq_balance" / "value")
.subscribe(boost::bind(&rx_frontend_core_200::set_iq_balance, _mbc[mb].rx_fe, _1))
.set(std::complex(0.0, 0.0));
_tree->create >(tx_fe_path / "dc_offset" / "value")
.coerce(boost::bind(&tx_frontend_core_200::set_dc_offset, _mbc[mb].tx_fe, _1))
.set(std::complex(0.0, 0.0));
_tree->create >(tx_fe_path / "iq_balance" / "value")
.subscribe(boost::bind(&tx_frontend_core_200::set_iq_balance, _mbc[mb].tx_fe, _1))
.set(std::complex(0.0, 0.0));
////////////////////////////////////////////////////////////////
// create rx dsp control objects
////////////////////////////////////////////////////////////////
_mbc[mb].rx_dsps.push_back(rx_dsp_core_200::make(
_mbc[mb].iface, U2_REG_SR_ADDR(SR_RX_DSP0), U2_REG_SR_ADDR(SR_RX_CTRL0), USRP2_RX_SID_BASE + 0, true
));
_mbc[mb].rx_dsps.push_back(rx_dsp_core_200::make(
_mbc[mb].iface, U2_REG_SR_ADDR(SR_RX_DSP1), U2_REG_SR_ADDR(SR_RX_CTRL1), USRP2_RX_SID_BASE + 1, true
));
for (size_t dspno = 0; dspno < _mbc[mb].rx_dsps.size(); dspno++){
_mbc[mb].rx_dsps[dspno]->set_link_rate(USRP2_LINK_RATE_BPS);
_tree->access(mb_path / "tick_rate")
.subscribe(boost::bind(&rx_dsp_core_200::set_tick_rate, _mbc[mb].rx_dsps[dspno], _1));
fs_path rx_dsp_path = mb_path / str(boost::format("rx_dsps/%u") % dspno);
_tree->create(rx_dsp_path / "rate/range")
.publish(boost::bind(&rx_dsp_core_200::get_host_rates, _mbc[mb].rx_dsps[dspno]));
_tree->create(rx_dsp_path / "rate/value")
.set(1e6) //some default
.coerce(boost::bind(&rx_dsp_core_200::set_host_rate, _mbc[mb].rx_dsps[dspno], _1))
.subscribe(boost::bind(&usrp2_impl::update_rx_samp_rate, this, mb, dspno, _1));
_tree->create(rx_dsp_path / "freq/value")
.coerce(boost::bind(&rx_dsp_core_200::set_freq, _mbc[mb].rx_dsps[dspno], _1));
_tree->create(rx_dsp_path / "freq/range")
.publish(boost::bind(&rx_dsp_core_200::get_freq_range, _mbc[mb].rx_dsps[dspno]));
_tree->create(rx_dsp_path / "stream_cmd")
.subscribe(boost::bind(&rx_dsp_core_200::issue_stream_command, _mbc[mb].rx_dsps[dspno], _1));
}
////////////////////////////////////////////////////////////////
// create tx dsp control objects
////////////////////////////////////////////////////////////////
_mbc[mb].tx_dsp = tx_dsp_core_200::make(
_mbc[mb].iface, U2_REG_SR_ADDR(SR_TX_DSP), U2_REG_SR_ADDR(SR_TX_CTRL), USRP2_TX_ASYNC_SID
);
_mbc[mb].tx_dsp->set_link_rate(USRP2_LINK_RATE_BPS);
_tree->access(mb_path / "tick_rate")
.subscribe(boost::bind(&tx_dsp_core_200::set_tick_rate, _mbc[mb].tx_dsp, _1));
_tree->create(mb_path / "tx_dsps/0/rate/range")
.publish(boost::bind(&tx_dsp_core_200::get_host_rates, _mbc[mb].tx_dsp));
_tree->create(mb_path / "tx_dsps/0/rate/value")
.set(1e6) //some default
.coerce(boost::bind(&tx_dsp_core_200::set_host_rate, _mbc[mb].tx_dsp, _1))
.subscribe(boost::bind(&usrp2_impl::update_tx_samp_rate, this, mb, 0, _1));
_tree->create(mb_path / "tx_dsps/0/freq/value")
.coerce(boost::bind(&usrp2_impl::set_tx_dsp_freq, this, mb, _1));
_tree->create(mb_path / "tx_dsps/0/freq/range")
.publish(boost::bind(&usrp2_impl::get_tx_dsp_freq_range, this, mb));
//setup dsp flow control
const double ups_per_sec = device_args_i.cast("ups_per_sec", 20);
const size_t send_frame_size = _mbc[mb].tx_dsp_xport->get_send_frame_size();
const double ups_per_fifo = device_args_i.cast("ups_per_fifo", 8.0);
_mbc[mb].tx_dsp->set_updates(
(ups_per_sec > 0.0)? size_t(100e6/*approx tick rate*//ups_per_sec) : 0,
(ups_per_fifo > 0.0)? size_t(USRP2_SRAM_BYTES/ups_per_fifo/send_frame_size) : 0
);
////////////////////////////////////////////////////////////////
// create time control objects
////////////////////////////////////////////////////////////////
time64_core_200::readback_bases_type time64_rb_bases;
time64_rb_bases.rb_hi_now = U2_REG_TIME64_HI_RB_IMM;
time64_rb_bases.rb_lo_now = U2_REG_TIME64_LO_RB_IMM;
time64_rb_bases.rb_hi_pps = U2_REG_TIME64_HI_RB_PPS;
time64_rb_bases.rb_lo_pps = U2_REG_TIME64_LO_RB_PPS;
_mbc[mb].time64 = time64_core_200::make(
_mbc[mb].iface, U2_REG_SR_ADDR(SR_TIME64), time64_rb_bases, mimo_clock_sync_delay_cycles
);
_tree->access(mb_path / "tick_rate")
.subscribe(boost::bind(&time64_core_200::set_tick_rate, _mbc[mb].time64, _1));
_tree->create(mb_path / "time/now")
.publish(boost::bind(&time64_core_200::get_time_now, _mbc[mb].time64))
.subscribe(boost::bind(&time64_core_200::set_time_now, _mbc[mb].time64, _1));
_tree->create(mb_path / "time/pps")
.publish(boost::bind(&time64_core_200::get_time_last_pps, _mbc[mb].time64))
.subscribe(boost::bind(&time64_core_200::set_time_next_pps, _mbc[mb].time64, _1));
//setup time source props
_tree->create(mb_path / "time_source/value")
.subscribe(boost::bind(&time64_core_200::set_time_source, _mbc[mb].time64, _1));
_tree->create >(mb_path / "time_source/options")
.publish(boost::bind(&time64_core_200::get_time_sources, _mbc[mb].time64));
//setup reference source props
_tree->create(mb_path / "clock_source/value")
.subscribe(boost::bind(&usrp2_impl::update_clock_source, this, mb, _1));
static const std::vector clock_sources = boost::assign::list_of("internal")("external")("mimo");
_tree->create >(mb_path / "clock_source/options").set(clock_sources);
////////////////////////////////////////////////////////////////////
// create user-defined control objects
////////////////////////////////////////////////////////////////////
_mbc[mb].user = user_settings_core_200::make(_mbc[mb].iface, U2_REG_SR_ADDR(SR_USER_REGS));
_tree->create(mb_path / "user/regs")
.subscribe(boost::bind(&user_settings_core_200::set_reg, _mbc[mb].user, _1));
////////////////////////////////////////////////////////////////
// create dboard control objects
////////////////////////////////////////////////////////////////
//read the dboard eeprom to extract the dboard ids
dboard_eeprom_t rx_db_eeprom, tx_db_eeprom, gdb_eeprom;
rx_db_eeprom.load(*_mbc[mb].iface, USRP2_I2C_ADDR_RX_DB);
tx_db_eeprom.load(*_mbc[mb].iface, USRP2_I2C_ADDR_TX_DB);
gdb_eeprom.load(*_mbc[mb].iface, USRP2_I2C_ADDR_TX_DB ^ 5);
//create the properties and register subscribers
_tree->create(mb_path / "dboards/A/rx_eeprom")
.set(rx_db_eeprom)
.subscribe(boost::bind(&usrp2_impl::set_db_eeprom, this, mb, "rx", _1));
_tree->create(mb_path / "dboards/A/tx_eeprom")
.set(tx_db_eeprom)
.subscribe(boost::bind(&usrp2_impl::set_db_eeprom, this, mb, "tx", _1));
_tree->create(mb_path / "dboards/A/gdb_eeprom")
.set(gdb_eeprom)
.subscribe(boost::bind(&usrp2_impl::set_db_eeprom, this, mb, "gdb", _1));
//create a new dboard interface and manager
_mbc[mb].dboard_iface = make_usrp2_dboard_iface(_mbc[mb].iface, _mbc[mb].clock);
_tree->create(mb_path / "dboards/A/iface").set(_mbc[mb].dboard_iface);
_mbc[mb].dboard_manager = dboard_manager::make(
rx_db_eeprom.id, tx_db_eeprom.id, gdb_eeprom.id,
_mbc[mb].dboard_iface, _tree->subtree(mb_path / "dboards/A")
);
//bind frontend corrections to the dboard freq props
const fs_path db_tx_fe_path = mb_path / "dboards" / "A" / "tx_frontends";
BOOST_FOREACH(const std::string &name, _tree->list(db_tx_fe_path)){
_tree->access(db_tx_fe_path / name / "freq" / "value")
.subscribe(boost::bind(&usrp2_impl::set_tx_fe_corrections, this, mb, _1));
}
const fs_path db_rx_fe_path = mb_path / "dboards" / "A" / "rx_frontends";
BOOST_FOREACH(const std::string &name, _tree->list(db_rx_fe_path)){
_tree->access(db_rx_fe_path / name / "freq" / "value")
.subscribe(boost::bind(&usrp2_impl::set_rx_fe_corrections, this, mb, _1));
}
}
//initialize io handling
this->io_init();
//do some post-init tasks
this->update_rates();
BOOST_FOREACH(const std::string &mb, _mbc.keys()){
fs_path root = "/mboards/" + mb;
//reset cordic rates and their properties to zero
BOOST_FOREACH(const std::string &name, _tree->list(root / "rx_dsps")){
_tree->access(root / "rx_dsps" / name / "freq" / "value").set(0.0);
}
BOOST_FOREACH(const std::string &name, _tree->list(root / "tx_dsps")){
_tree->access(root / "tx_dsps" / name / "freq" / "value").set(0.0);
}
_tree->access(root / "rx_subdev_spec").set(subdev_spec_t("A:" + _tree->list(root / "dboards/A/rx_frontends").at(0)));
_tree->access(root / "tx_subdev_spec").set(subdev_spec_t("A:" + _tree->list(root / "dboards/A/tx_frontends").at(0)));
_tree->access(root / "clock_source/value").set("internal");
_tree->access(root / "time_source/value").set("none");
//GPS installed: use external ref, time, and init time spec
if (_mbc[mb].gps.get() and _mbc[mb].gps->gps_detected()){
UHD_MSG(status) << "Setting references to the internal GPSDO" << std::endl;
_tree->access(root / "time_source/value").set("external");
_tree->access(root / "clock_source/value").set("external");
UHD_MSG(status) << "Initializing time to the internal GPSDO" << std::endl;
_mbc[mb].time64->set_time_next_pps(time_spec_t(time_t(_mbc[mb].gps->get_sensor("gps_time").to_int()+1)));
}
}
}
usrp2_impl::~usrp2_impl(void){UHD_SAFE_CALL(
BOOST_FOREACH(const std::string &mb, _mbc.keys()){
_mbc[mb].tx_dsp->set_updates(0, 0);
}
)}
void usrp2_impl::set_mb_eeprom(const std::string &mb, const uhd::usrp::mboard_eeprom_t &mb_eeprom){
mb_eeprom.commit(*(_mbc[mb].iface), mboard_eeprom_t::MAP_N100);
}
void usrp2_impl::set_db_eeprom(const std::string &mb, const std::string &type, const uhd::usrp::dboard_eeprom_t &db_eeprom){
if (type == "rx") db_eeprom.store(*_mbc[mb].iface, USRP2_I2C_ADDR_RX_DB);
if (type == "tx") db_eeprom.store(*_mbc[mb].iface, USRP2_I2C_ADDR_TX_DB);
if (type == "gdb") db_eeprom.store(*_mbc[mb].iface, USRP2_I2C_ADDR_TX_DB ^ 5);
}
sensor_value_t usrp2_impl::get_mimo_locked(const std::string &mb){
const bool lock = (_mbc[mb].iface->peek32(U2_REG_IRQ_RB) & (1<<10)) != 0;
return sensor_value_t("MIMO", lock, "locked", "unlocked");
}
sensor_value_t usrp2_impl::get_ref_locked(const std::string &mb){
const bool lock = (_mbc[mb].iface->peek32(U2_REG_IRQ_RB) & (1<<11)) != 0;
return sensor_value_t("Ref", lock, "locked", "unlocked");
}
void usrp2_impl::set_rx_fe_corrections(const std::string &mb, const double lo_freq){
apply_rx_fe_corrections(this->get_tree()->subtree("/mboards/" + mb), "A", lo_freq);
}
void usrp2_impl::set_tx_fe_corrections(const std::string &mb, const double lo_freq){
apply_tx_fe_corrections(this->get_tree()->subtree("/mboards/" + mb), "A", lo_freq);
}
#include
#include
double usrp2_impl::set_tx_dsp_freq(const std::string &mb, const double freq_){
double new_freq = freq_;
const double tick_rate = _tree->access("/mboards/"+mb+"/tick_rate").get();
//calculate the DAC shift (multiples of rate)
const int sign = boost::math::sign(new_freq);
const int zone = std::min(boost::math::iround(new_freq/tick_rate), 2);
const double dac_shift = sign*zone*tick_rate;
new_freq -= dac_shift; //update FPGA DSP target freq
//set the DAC shift (modulation mode)
if (zone == 0) _mbc[mb].codec->set_tx_mod_mode(0); //no shift
else _mbc[mb].codec->set_tx_mod_mode(sign*4/zone); //DAC interp = 4
return _mbc[mb].tx_dsp->set_freq(new_freq) + dac_shift; //actual freq
}
meta_range_t usrp2_impl::get_tx_dsp_freq_range(const std::string &mb){
const double tick_rate = _tree->access("/mboards/"+mb+"/tick_rate").get();
const meta_range_t dsp_range = _mbc[mb].tx_dsp->get_freq_range();
return meta_range_t(dsp_range.start() - tick_rate*2, dsp_range.stop() + tick_rate*2, dsp_range.step());
}
void usrp2_impl::update_clock_source(const std::string &mb, const std::string &source){
//clock source ref 10mhz
switch(_mbc[mb].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:
if (source == "internal") _mbc[mb].iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x12);
else if (source == "external") _mbc[mb].iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x1C);
else if (source == "mimo") _mbc[mb].iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x15);
else throw uhd::value_error("unhandled clock configuration reference source: " + source);
_mbc[mb].clock->enable_external_ref(true); //USRP2P has an internal 10MHz TCXO
break;
case usrp2_iface::USRP2_REV3:
case usrp2_iface::USRP2_REV4:
if (source == "internal") _mbc[mb].iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x10);
else if (source == "external") _mbc[mb].iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x1C);
else if (source == "mimo") _mbc[mb].iface->poke32(U2_REG_MISC_CTRL_CLOCK, 0x15);
else throw uhd::value_error("unhandled clock configuration reference source: " + source);
_mbc[mb].clock->enable_external_ref(source != "internal");
break;
case usrp2_iface::USRP_NXXX: break;
}
//always drive the clock over serdes if not locking to it
_mbc[mb].clock->enable_mimo_clock_out(source != "mimo");
//set the mimo clock delay over the serdes
if (source != "mimo"){
switch(_mbc[mb].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:
_mbc[mb].clock->set_mimo_clock_delay(mimo_clock_delay_usrp_n2xx);
break;
case usrp2_iface::USRP2_REV4:
_mbc[mb].clock->set_mimo_clock_delay(mimo_clock_delay_usrp2_rev4);
break;
default: break; //not handled
}
}
}