/*
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 .
*/
/*
simulator connector for FlightAxis
*/
#include "SIM_FlightAxis.h"
#if HAL_SIM_FLIGHTAXIS_ENABLED
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
extern const AP_HAL::HAL& hal;
using namespace SITL;
/*
we use a thread for socket creation to reduce the impact of socket
creation latency. These condition variables are used to synchronise
the thread
*/
static pthread_cond_t sockcond1 = PTHREAD_COND_INITIALIZER;
static pthread_cond_t sockcond2 = PTHREAD_COND_INITIALIZER;
static pthread_mutex_t sockmtx = PTHREAD_MUTEX_INITIALIZER;
// the asprintf() calls are not worth checking for SITL
#pragma GCC diagnostic ignored "-Wunused-result"
static const struct {
const char *name;
float value;
bool save;
} sim_defaults[] = {
{ "BRD_OPTIONS", 0},
{ "AHRS_EKF_TYPE", 10 },
{ "INS_GYR_CAL", 0 },
{ "BATT_MONITOR", 4 },
{ "RC1_MIN", 1000, true },
{ "RC1_MAX", 2000, true },
{ "RC2_MIN", 1000, true },
{ "RC2_MAX", 2000, true },
{ "RC3_MIN", 1000, true },
{ "RC3_MAX", 2000, true },
{ "RC4_MIN", 1000, true },
{ "RC4_MAX", 2000, true },
{ "RC2_REVERSED", 1 }, // interlink has reversed rc2
{ "SERVO1_MIN", 1000 },
{ "SERVO1_MAX", 2000 },
{ "SERVO2_MIN", 1000 },
{ "SERVO2_MAX", 2000 },
{ "SERVO3_MIN", 1000 },
{ "SERVO3_MAX", 2000 },
{ "SERVO4_MIN", 1000 },
{ "SERVO4_MAX", 2000 },
{ "SERVO5_MIN", 1000 },
{ "SERVO5_MAX", 2000 },
{ "SERVO6_MIN", 1000 },
{ "SERVO6_MAX", 2000 },
{ "SERVO6_MIN", 1000 },
{ "SERVO6_MAX", 2000 },
{ "INS_ACC2OFFS_X", 0.001 },
{ "INS_ACC2OFFS_Y", 0.001 },
{ "INS_ACC2OFFS_Z", 0.001 },
{ "INS_ACC2SCAL_X", 1.001 },
{ "INS_ACC2SCAL_Y", 1.001 },
{ "INS_ACC2SCAL_Z", 1.001 },
{ "INS_ACCOFFS_X", 0.001 },
{ "INS_ACCOFFS_Y", 0.001 },
{ "INS_ACCOFFS_Z", 0.001 },
{ "INS_ACCSCAL_X", 1.001 },
{ "INS_ACCSCAL_Y", 1.001 },
{ "INS_ACCSCAL_Z", 1.001 },
{ "RPM1_TYPE", 10 },
};
/*
get system timestamp in seconds
*/
static double timestamp_sec()
{
struct timeval tval;
gettimeofday(&tval,NULL);
return tval.tv_sec + (tval.tv_usec*1.0e-6);
}
FlightAxis::FlightAxis(const char *frame_str) :
Aircraft(frame_str)
{
use_time_sync = false;
num_motors = 2;
rate_hz = 250 / target_speedup;
heli_demix = strstr(frame_str, "helidemix") != nullptr;
rev4_servos = strstr(frame_str, "rev4") != nullptr;
const char *colon = strchr(frame_str, ':');
if (colon) {
controller_ip = colon+1;
}
for (uint8_t i=0; iconfigured()) {
p->save();
}
}
}
if (!hal.scheduler->thread_create(FUNCTOR_BIND_MEMBER(&FlightAxis::socket_creator, void), "SocketCreator", 8192,
AP_HAL::Scheduler::PRIORITY_BOOST, 0)) {
printf("Failed to create socket_creator thread\n");
}
}
/*
extremely primitive SOAP parser that assumes the format used by FlightAxis
*/
void FlightAxis::parse_reply(const char *reply)
{
const char *reply0 = reply;
for (uint16_t i=0; i');
if (p != nullptr) {
reply = p;
}
}
}
/*
make a SOAP request, returning body of reply
*/
bool FlightAxis::soap_request_start(const char *action, const char *fmt, ...)
{
va_list ap;
char *req1;
if (sock) {
delete sock;
sock = nullptr;
}
va_start(ap, fmt);
vasprintf(&req1, fmt, ap);
va_end(ap);
pthread_mutex_lock(&sockmtx);
while (socknext == nullptr) {
pthread_cond_wait(&sockcond1, &sockmtx);
}
sock = socknext;
socknext = nullptr;
pthread_cond_broadcast(&sockcond2);
pthread_mutex_unlock(&sockmtx);
char *req;
asprintf(&req, R"(POST / HTTP/1.1
soapaction: '%s'
content-length: %u
content-type: text/xml;charset='UTF-8'
Connection: Keep-Alive
%s)",
action,
(unsigned)strlen(req1), req1);
sock->send(req, strlen(req));
free(req1);
free(req);
return true;
}
char *FlightAxis::soap_request_end(uint32_t timeout_ms)
{
if (!sock) {
return nullptr;
}
if (!sock->pollin(timeout_ms)) {
return nullptr;
}
sock->set_blocking(true);
ssize_t ret = sock->recv(replybuf, sizeof(replybuf)-1, 1000);
if (ret <= 0) {
return nullptr;
}
replybuf[ret] = 0;
char *p = strstr(replybuf, "Content-Length: ");
if (p == nullptr) {
delete sock;
sock = nullptr;
printf("No Content-Length\n");
return nullptr;
}
// get the content length
uint32_t content_length = strtoul(p+16, nullptr, 10);
char *body = strstr(p, "\r\n\r\n");
if (body == nullptr) {
printf("No body\n");
delete sock;
sock = nullptr;
return nullptr;
}
body += 4;
// get the rest of the body
int32_t expected_length = content_length + (body - replybuf);
if (expected_length >= (int32_t)sizeof(replybuf)) {
printf("Reply too large %i\n", expected_length);
delete sock;
sock = nullptr;
return nullptr;
}
while (ret < expected_length) {
ssize_t ret2 = sock->recv(&replybuf[ret], sizeof(replybuf)-(1+ret), 1000);
if (ret2 <= 0) {
delete sock;
sock = nullptr;
return nullptr;
}
// nul terminate
replybuf[ret+ret2] = 0;
ret += ret2;
}
delete sock;
sock = nullptr;
return strdup(replybuf);
}
void FlightAxis::exchange_data(const struct sitl_input &input)
{
if (!sock &&
(!controller_started ||
is_zero(state.m_flightAxisControllerIsActive) ||
!is_zero(state.m_resetButtonHasBeenPressed))) {
printf("Starting controller at %s\n", controller_ip);
// call a restore first. This allows us to connect after the aircraft is changed in RealFlight
soap_request_start("RestoreOriginalControllerDevice", R"(
12
)");
soap_request_end(1000);
soap_request_start("InjectUAVControllerInterface", R"(
12
)");
soap_request_end(1000);
activation_frame_counter = frame_counter;
controller_started = true;
}
// maximum number of servos to send is 12 with new FlightAxis
float scaled_servos[12];
for (uint8_t i=0; iis_system_initialized()?4095:0;
if (!sock) {
soap_request_start("ExchangeData", R"(
%u
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
- %.4f
)",
channels,
scaled_servos[0],
scaled_servos[1],
scaled_servos[2],
scaled_servos[3],
scaled_servos[4],
scaled_servos[5],
scaled_servos[6],
scaled_servos[7],
scaled_servos[8],
scaled_servos[9],
scaled_servos[10],
scaled_servos[11]);
}
char *reply = nullptr;
if (sock) {
reply = soap_request_end(0);
if (reply == nullptr) {
sock_error_count++;
if (sock_error_count >= 10000 && timestamp_sec() - last_recv_sec > 1) {
printf("socket timeout\n");
delete sock;
sock = nullptr;
sock_error_count = 0;
last_recv_sec = timestamp_sec();
}
}
}
if (reply) {
sock_error_count = 0;
last_recv_sec = timestamp_sec();
double lastt_s = state.m_currentPhysicsTime_SEC;
parse_reply(reply);
double dt = state.m_currentPhysicsTime_SEC - lastt_s;
if (dt > 0 && dt < 0.1) {
if (average_frame_time_s < 1.0e-6) {
average_frame_time_s = dt;
}
average_frame_time_s = average_frame_time_s * 0.98 + dt * 0.02;
}
socket_frame_counter++;
free(reply);
}
}
/*
update the FlightAxis simulation by one time step
*/
void FlightAxis::update(const struct sitl_input &input)
{
last_input = input;
exchange_data(input);
double dt_seconds = state.m_currentPhysicsTime_SEC - last_time_s;
if (dt_seconds < 0) {
// cope with restarting RealFlight while connected
initial_time_s = time_now_us * 1.0e-6f;
last_time_s = state.m_currentPhysicsTime_SEC;
position_offset.zero();
return;
}
if (dt_seconds < 0.00001f) {
float delta_time = 0.001;
// don't go past the next expected frame
if (delta_time + extrapolated_s > average_frame_time_s) {
delta_time = average_frame_time_s - extrapolated_s;
}
if (delta_time <= 0) {
return;
}
time_now_us += delta_time * 1.0e6;
extrapolate_sensors(delta_time);
update_position();
update_mag_field_bf();
extrapolated_s += delta_time;
report_FPS();
return;
}
extrapolated_s = 0;
if (initial_time_s <= 0) {
dt_seconds = 0.001f;
initial_time_s = state.m_currentPhysicsTime_SEC - dt_seconds;
}
/*
the quaternion convention in realflight seems to have Z negative
*/
Quaternion quat(state.m_orientationQuaternion_W,
state.m_orientationQuaternion_Y,
state.m_orientationQuaternion_X,
-state.m_orientationQuaternion_Z);
quat.rotation_matrix(dcm);
gyro = Vector3f(radians(constrain_float(state.m_rollRate_DEGpSEC, -2000, 2000)),
radians(constrain_float(state.m_pitchRate_DEGpSEC, -2000, 2000)),
-radians(constrain_float(state.m_yawRate_DEGpSEC, -2000, 2000))) * target_speedup;
velocity_ef = Vector3f(state.m_velocityWorldU_MPS,
state.m_velocityWorldV_MPS,
state.m_velocityWorldW_MPS);
position = Vector3d(state.m_aircraftPositionY_MTR,
state.m_aircraftPositionX_MTR,
-state.m_altitudeASL_MTR - home.alt*0.01);
position.xy() += origin.get_distance_NE_double(home);
accel_body = {
float(state.m_accelerationBodyAX_MPS2),
float(state.m_accelerationBodyAY_MPS2),
float(state.m_accelerationBodyAZ_MPS2)
};
// accel on the ground is nasty in realflight, and prevents helicopter disarm
if (!is_zero(state.m_isTouchingGround)) {
Vector3f accel_ef = (velocity_ef - last_velocity_ef) / dt_seconds;
accel_ef.z -= GRAVITY_MSS;
accel_body = dcm.transposed() * accel_ef;
}
// limit to 16G to match pixhawk
float a_limit = GRAVITY_MSS*16;
accel_body.x = constrain_float(accel_body.x, -a_limit, a_limit);
accel_body.y = constrain_float(accel_body.y, -a_limit, a_limit);
accel_body.z = constrain_float(accel_body.z, -a_limit, a_limit);
// offset based on first position to account for offset in RF world
if (position_offset.is_zero() || !is_zero(state.m_resetButtonHasBeenPressed)) {
position_offset = position;
}
position -= position_offset;
airspeed = state.m_airspeed_MPS;
/* for pitot airspeed we need the airspeed along the X axis. We
can't get that from m_airspeed_MPS, so instead we calculate it
from wind vector and ground speed
*/
wind_ef = Vector3f(state.m_windY_MPS,state.m_windX_MPS,state.m_windZ_MPS);
Vector3f airspeed_3d_ef = velocity_ef - wind_ef;
Vector3f airspeed3d = dcm.mul_transpose(airspeed_3d_ef);
if (last_imu_rotation != ROTATION_NONE) {
airspeed3d = sitl->ahrs_rotation * airspeed3d;
}
airspeed_pitot = MAX(airspeed3d.x,0);
#if 0
printf("WIND: %.1f %.1f %.1f AS3D %.1f %.1f %.1f\n",
state.m_windX_MPS,
state.m_windY_MPS,
state.m_windZ_MPS,
airspeed3d.x,
airspeed3d.y,
airspeed3d.z);
#endif
battery_voltage = MAX(state.m_batteryVoltage_VOLTS, 0);
battery_current = MAX(state.m_batteryCurrentDraw_AMPS, 0);
rpm[0] = state.m_heliMainRotorRPM;
rpm[1] = state.m_propRPM;
/*
the interlink interface supports 12 input channels
*/
rcin_chan_count = 12;
for (uint8_t i=0; i 500000) {
// time going backwards
time_now_us = new_time_us;
}
} else {
time_now_us = new_time_us;
}
last_time_s = state.m_currentPhysicsTime_SEC;
last_velocity_ef = velocity_ef;
// update magnetic field
update_mag_field_bf();
report_FPS();
}
/*
report frame rates
*/
void FlightAxis::report_FPS(void)
{
if (frame_counter++ % 1000 == 0) {
if (!is_zero(last_frame_count_s)) {
uint64_t frames = socket_frame_counter - last_socket_frame_counter;
last_socket_frame_counter = socket_frame_counter;
double dt = state.m_currentPhysicsTime_SEC - last_frame_count_s;
printf("%.2f/%.2f FPS avg=%.2f\n",
frames / dt, 1000 / dt, 1.0/average_frame_time_s);
} else {
printf("Initial position %f %f %f\n", position.x, position.y, position.z);
}
last_frame_count_s = state.m_currentPhysicsTime_SEC;
}
}
void FlightAxis::socket_creator(void)
{
socket_pid = getpid();
while (true) {
pthread_mutex_lock(&sockmtx);
while (socknext != nullptr) {
pthread_cond_wait(&sockcond2, &sockmtx);
}
pthread_mutex_unlock(&sockmtx);
auto *sck = new SocketAPM(false);
if (sck == nullptr) {
usleep(500);
continue;
}
if (!sck->connect(controller_ip, controller_port)) {
::printf("connect failed\n");
delete sck;
usleep(5000);
continue;
}
sck->set_blocking(false);
socknext = sck;
pthread_mutex_lock(&sockmtx);
pthread_cond_broadcast(&sockcond1);
pthread_mutex_unlock(&sockmtx);
}
}
#endif // HAL_SIM_FLIGHTAXIS_ENABLED