#include <boost/format.hpp>
#include <boost/foreach.hpp>
#include <boost/bind.hpp>
#include <boost/make_shared.hpp>
#include <boost/lexical_cast.hpp>
#include <boost/assign/list_of.hpp>
#include "boost/date_time/posix_time/posix_time.hpp"
#include <iostream>
#include <uhd/utils/byteswap.hpp>
#include <uhd/utils/msg.hpp>
#include <uhd/exception.hpp>
#include "e300_ublox_control.hpp"
#ifdef E300_NATIVE
#include "e300_ublox_control_impl.hpp"
namespace uhd { namespace usrp { namespace gps {
namespace ublox { namespace ubx {
control_impl::control_impl(const std::string &node, const size_t baud_rate)
{
_decode_init();
_serial = boost::make_shared<async_serial>(node, baud_rate);
_serial->set_read_callback(boost::bind(&control_impl::_rx_callback, this, _1, _2));
_detect();
configure_message_rate(MSG_GLL, 0);
configure_message_rate(MSG_GSV, 0);
configure_message_rate(MSG_GGA, 0);
configure_message_rate(MSG_GSA, 0);
configure_message_rate(MSG_RMC, 0);
configure_message_rate(MSG_VTG, 0);
configure_message_rate(MSG_NAV_TIMEUTC, 1);
configure_message_rate(MSG_NAV_SOL, 1);
configure_antenna(0x001b, 0x8251);
configure_pps(0xf4240, 0x3d090, 1, 0 /* utc */, 1, 0, 0, 0);
_sensors = boost::assign::list_of("gps_locked")("gps_time");
}
bool control_impl::gps_detected(void)
{
return _detected;
}
void control_impl::_detect(void)
{
_send_message(MSG_MON_VER, NULL, 0);
}
std::vector<std::string> control_impl::get_sensors(void)
{
return _sensors;
}
uhd::sensor_value_t control_impl::get_sensor(std::string key)
{
if (key == "gps_time") {
bool lock;
_locked.wait_and_see(lock);
return sensor_value_t("GPS epoch time",
lock ? int(_get_epoch_time()) : 0, "seconds");
} else if (key == "gps_locked") {
bool lock;
_locked.wait_and_see(lock);
return sensor_value_t("GPS lock status", lock, "locked", "unlocked");
} else
throw uhd::key_error(str(boost::format("sensor %s unknown.") % key));
}
std::time_t control_impl::_get_epoch_time(void)
{
boost::posix_time::ptime ptime;
_ptime.wait_and_see(ptime);
return (ptime - boost::posix_time::from_time_t(0)).total_seconds();
}
control_impl::~control_impl(void)
{
}
void control_impl::_decode_init(void)
{
_decode_state = DECODE_SYNC1;
_rx_ck_a = 0;
_rx_ck_b = 0;
_rx_payload_length = 0;
_rx_payload_index = 0;
}
void control_impl::_add_byte_to_checksum(const boost::uint8_t b)
{
_rx_ck_a = _rx_ck_a + b;
_rx_ck_b = _rx_ck_b + _rx_ck_a;
}
void control_impl::_calc_checksum(
const boost::uint8_t *buffer,
const boost::uint16_t length,
checksum_t &checksum)
{
for (size_t i = 0; i < length; i++)
{
checksum.ck_a = checksum.ck_a + buffer[i];
checksum.ck_b = checksum.ck_b + checksum.ck_a;
}
}
void control_impl::configure_rates(
boost::uint16_t meas_rate,
boost::uint16_t nav_rate,
boost::uint16_t time_ref)
{
payload_tx_cfg_rate_t cfg_rate;
cfg_rate.meas_rate = uhd::htowx<boost::uint16_t>(meas_rate);
cfg_rate.nav_rate = uhd::htowx<boost::uint16_t>(nav_rate);
cfg_rate.time_ref = uhd::htowx<boost::uint16_t>(time_ref);
_send_message(
MSG_CFG_RATE,
reinterpret_cast<const uint8_t*>(&cfg_rate),
sizeof(cfg_rate));
_wait_for_ack(MSG_CFG_RATE, 1.0);
}
void control_impl::configure_message_rate(
const boost::uint16_t msg,
const uint8_t rate)
{
payload_tx_cfg_msg_t cfg_msg;
cfg_msg.msg = uhd::htowx<boost::uint16_t>(msg);
cfg_msg.rate[0] = 0;//rate;
cfg_msg.rate[1] = rate;
cfg_msg.rate[2] = 0;//rate;
cfg_msg.rate[3] = 0;//rate;
cfg_msg.rate[4] = 0;//rate;
cfg_msg.rate[5] = 0;//rate;
_send_message(
MSG_CFG_MSG,
reinterpret_cast<const uint8_t*>(&cfg_msg),
sizeof(cfg_msg));
_wait_for_ack(MSG_CFG_MSG, 1.0);
}
void control_impl::configure_antenna(
const boost::uint16_t flags,
const boost::uint16_t pins)
{
payload_tx_cfg_ant_t cfg_ant;
cfg_ant.pins = uhd::htowx<boost::uint16_t>(pins);
cfg_ant.flags = uhd::htowx<boost::uint16_t>(flags);
_send_message(
MSG_CFG_ANT,
reinterpret_cast<const uint8_t*>(&cfg_ant),
sizeof(cfg_ant));
if (_wait_for_ack(MSG_CFG_ANT, 1.0) < 0) {
throw uhd::runtime_error("Didn't get an ACK for antenna configuration.");
}
}
void control_impl::configure_pps(
const boost::uint32_t interval,
const boost::uint32_t length,
const boost::int8_t status,
const boost::uint8_t time_ref,
const boost::uint8_t flags,
const boost::int16_t antenna_delay,
const boost::int16_t rf_group_delay,
const boost::int32_t user_delay)
{
payload_tx_cfg_tp_t cfg_tp;
cfg_tp.interval = uhd::htowx<boost::uint32_t>(interval);
cfg_tp.length = uhd::htowx<boost::uint32_t>(length);
cfg_tp.status = status;
cfg_tp.time_ref = time_ref;
cfg_tp.flags = flags;
cfg_tp.antenna_delay = uhd::htowx<boost::int16_t>(antenna_delay);
cfg_tp.rf_group_delay = uhd::htowx<boost::int16_t>(rf_group_delay);
cfg_tp.user_delay = uhd::htowx<boost::int32_t>(user_delay);
_send_message(
MSG_CFG_TP,
reinterpret_cast<const uint8_t*>(&cfg_tp),
sizeof(cfg_tp));
if (_wait_for_ack(MSG_CFG_TP, 1.0) < 0) {
throw uhd::runtime_error("Didn't get an ACK for PPS configuration.");
}
}
void control_impl::_rx_callback(const char *data, unsigned int len)
{
//std::cout << "IN RX CALLBACK" << std::flush << std::endl;
std::vector<char> v(data, data+len);
BOOST_FOREACH(const char &c, v)
{
_parse_char(c);
}
}
void control_impl::_parse_char(const boost::uint8_t b)
{
int ret = 0;
switch (_decode_state) {
// we're expecting the first sync byte
case DECODE_SYNC1:
if (b == SYNC1) { // sync1 found goto next step
_decode_state = DECODE_SYNC2;
} // else stay around
break;
// we're expecting the second sync byte
case DECODE_SYNC2:
if (b == SYNC2) { // sync2 found goto next step
_decode_state = DECODE_CLASS;
} else {
// failed, reset
_decode_init();
}
break;
// we're expecting the class byte
case DECODE_CLASS:
_add_byte_to_checksum(b);
_rx_msg = b;
_decode_state = DECODE_ID;
break;
// we're expecting the id byte
case DECODE_ID:
_add_byte_to_checksum(b);
_rx_msg |= (b << 8);
_decode_state = DECODE_LENGTH1;
break;
// we're expecting the first length byte
case DECODE_LENGTH1:
_add_byte_to_checksum(b);
_rx_payload_length = b;
_decode_state = DECODE_LENGTH2;
break;
// we're expecting the second length byte
case DECODE_LENGTH2:
_add_byte_to_checksum(b);
_rx_payload_length |= (b << 8);
if(_payload_rx_init()) {
_decode_init(); // we failed, give up for this one
} else {
_decode_state = _rx_payload_length ?
DECODE_PAYLOAD : DECODE_CHKSUM1;
}
break;
// we're expecting payload
case DECODE_PAYLOAD:
_add_byte_to_checksum(b);
switch(_rx_msg) {
default:
ret = _payload_rx_add(b);
break;
};
if (ret < 0) {
// we couldn't deal with the payload, discard the whole thing
_decode_init();
} else if (ret > 0) {
// payload was complete, let's check the checksum;
_decode_state = DECODE_CHKSUM1;
} else {
// more payload expected, don't move
}
ret = 0;
break;
case DECODE_CHKSUM1:
if (_rx_ck_a != b) {
// checksum didn't match, barf
std::cout << boost::format("Failed checksum byte1 %lx != %lx")
% int(_rx_ck_a) % int(b) << std::endl;
_decode_init();
} else {
_decode_state = DECODE_CHKSUM2;
}
break;
case DECODE_CHKSUM2:
if (_rx_ck_b != b) {
// checksum didn't match, barf
std::cout << boost::format("Failed checksum byte2 %lx != %lx")
% int(_rx_ck_b) % int(b) << std::endl;
} else {
ret = _payload_rx_done(); // payload done
}
_decode_init();
break;
default:
break;
};
}
int control_impl::_payload_rx_init(void)
{
int ret = 0;
_rx_state = RXMSG_HANDLE; // by default handle
switch(_rx_msg) {
case MSG_NAV_SOL:
if (not (_rx_payload_length == sizeof(payload_rx_nav_sol_t)))
_rx_state = RXMSG_ERROR_LENGTH;
break;
case MSG_NAV_TIMEUTC:
if (not (_rx_payload_length == sizeof(payload_rx_nav_timeutc_t)))
_rx_state = RXMSG_ERROR_LENGTH;
break;
case MSG_MON_VER:
break; // always take this one
case MSG_ACK_ACK:
if (not (_rx_payload_length == sizeof(payload_rx_ack_ack_t)))
_rx_state = RXMSG_ERROR_LENGTH;
break;
case MSG_ACK_NAK:
if (not (_rx_payload_length == sizeof(payload_rx_ack_nak_t)))
_rx_state = RXMSG_ERROR_LENGTH;
break;
default:
_rx_state = RXMSG_DISABLE;
break;
};
switch (_rx_state) {
case RXMSG_HANDLE: // handle message
case RXMSG_IGNORE: // ignore message but don't report error
ret = 0;
break;
case RXMSG_DISABLE: // ignore message but don't report error
case RXMSG_ERROR_LENGTH: // the length doesn't match
ret = -1;
break;
default: // invalid, error
ret = -1;
break;
};
return ret;
}
int control_impl::_payload_rx_add(const boost::uint8_t b)
{
int ret = 0;
_buf.raw[_rx_payload_index] = b;
if (++_rx_payload_index >= _rx_payload_length)
ret = 1;
return ret;
}
int control_impl::_payload_rx_done(void)
{
int ret = 0;
if (_rx_state != RXMSG_HANDLE) {
return 0;
}
switch (_rx_msg) {
case MSG_MON_VER:
_detected = true;
break;
case MSG_MON_HW:
std::cout << "MON-HW" << std::endl;
break;
case MSG_ACK_ACK:
if ((_ack_state == ACK_WAITING) and (_buf.payload_rx_ack_ack.msg == _ack_waiting_msg))
_ack_state = ACK_GOT_ACK;
break;
case MSG_ACK_NAK:
if ((_ack_state == ACK_WAITING) and (_buf.payload_rx_ack_nak.msg == _ack_waiting_msg))
_ack_state = ACK_GOT_NAK;
break;
case MSG_CFG_ANT:
break;
case MSG_NAV_TIMEUTC:
_ptime.update(boost::posix_time::ptime(
boost::gregorian::date(
boost::gregorian::greg_year(uhd::wtohx<boost::uint16_t>(
_buf.payload_rx_nav_timeutc.year)),
boost::gregorian::greg_month(_buf.payload_rx_nav_timeutc.month),
boost::gregorian::greg_day(_buf.payload_rx_nav_timeutc.day)),
(boost::posix_time::hours(_buf.payload_rx_nav_timeutc.hour)
+ boost::posix_time::minutes(_buf.payload_rx_nav_timeutc.min)
+ boost::posix_time::seconds(_buf.payload_rx_nav_timeutc.sec))));
break;
case MSG_NAV_SOL:
_locked.update(_buf.payload_rx_nav_sol.gps_fix > 0);
break;
default:
std::cout << boost::format("Got unknown message %lx , with good checksum [") % int(_rx_msg);
for(size_t i = 0; i < _rx_payload_length; i++)
std::cout << boost::format("%lx, ") % int(_buf.raw[i]);
std::cout << "]"<< std::endl;
break;
};
return ret;
}
void control_impl::_send_message(
const boost::uint16_t msg,
const boost::uint8_t *payload,
const boost::uint16_t len)
{
header_t header = {SYNC1, SYNC2, msg, len};
checksum_t checksum = {0, 0};
// calculate checksums, first header without sync
// then payload
_calc_checksum(
reinterpret_cast<boost::uint8_t*>(&header) + 2,
sizeof(header) - 2, checksum);
if (payload)
_calc_checksum(payload, len, checksum);
_serial->write(
reinterpret_cast<const char*>(&header),
sizeof(header));
if (payload)
_serial->write((const char *) payload, len);
_serial->write(
reinterpret_cast<const char*>(&checksum),
sizeof(checksum));
}
int control_impl::_wait_for_ack(
const boost::uint16_t msg,
const double timeout)
{
int ret = -1;
_ack_state = ACK_WAITING;
_ack_waiting_msg = msg;
boost::system_time timeout_time =
boost::get_system_time() +
boost::posix_time::milliseconds(timeout * 1000.0);
do {
if(_ack_state == ACK_GOT_ACK)
return 0;
else if (_ack_state == ACK_GOT_NAK) {
return -1;
}
boost::this_thread::sleep(boost::posix_time::milliseconds(20));
} while (boost::get_system_time() < timeout_time);
// we get here ... it's a timeout
_ack_state = ACK_IDLE;
return ret;
}
}} // namespace ublox::ubx
}}} // namespace
using namespace uhd::usrp::gps::ublox::ubx;
control::sptr control::make(const std::string &node, const size_t baud_rate)
{
return control::sptr(new control_impl(node, baud_rate));
}
#else
using namespace uhd::usrp::gps::ublox::ubx;
control::sptr control::make(const std::string& /* node */, const size_t /* baud_rate */)
{
throw uhd::assertion_error("control::sptr::make: !E300_NATIVE");
}
#endif // E300_NATIVE