mirror of https://github.com/ArduPilot/ardupilot
404 lines
13 KiB
C++
404 lines
13 KiB
C++
/*
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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/*
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Simulator Connector for AirSim
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*/
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#include "SIM_AirSim.h"
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#include <stdio.h>
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#include <arpa/inet.h>
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#include <errno.h>
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#include <AP_HAL/AP_HAL.h>
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#include <AP_Logger/AP_Logger.h>
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#include <AP_HAL/utility/replace.h>
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extern const AP_HAL::HAL& hal;
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using namespace SITL;
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AirSim::AirSim(const char *frame_str) :
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Aircraft(frame_str),
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sock(true)
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{
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if (strstr(frame_str, "-copter")) {
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output_type = OutputType::Copter;
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} else if (strstr(frame_str, "-rover")) {
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output_type = OutputType::Rover;
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} else {
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// default to copter
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output_type = OutputType::Copter;
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}
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printf("Starting SITL Airsim type %u\n", (unsigned)output_type);
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}
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/*
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Create & set in/out socket
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*/
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void AirSim::set_interface_ports(const char* address, const int port_in, const int port_out)
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{
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if (!sock.bind("0.0.0.0", port_in)) {
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printf("Unable to bind Airsim sensor_in socket at port %u - Error: %s\n",
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port_in, strerror(errno));
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return;
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}
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printf("Bind SITL sensor input at %s:%u\n", "127.0.0.1", port_in);
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sock.set_blocking(false);
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sock.reuseaddress();
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airsim_ip = address;
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airsim_control_port = port_out;
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airsim_sensor_port = port_in;
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printf("AirSim control interface set to %s:%u\n", airsim_ip, airsim_control_port);
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}
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/*
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Decode and send servos
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*/
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void AirSim::output_copter(const struct sitl_input &input)
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{
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servo_packet pkt;
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for (uint8_t i=0; i<kArduCopterRotorControlCount; i++) {
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pkt.pwm[i] = input.servos[i];
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}
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ssize_t send_ret = sock.sendto(&pkt, sizeof(pkt), airsim_ip, airsim_control_port);
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if (send_ret != sizeof(pkt)) {
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if (send_ret <= 0) {
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printf("Unable to send servo output to %s:%u - Error: %s, Return value: %ld\n",
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airsim_ip, airsim_control_port, strerror(errno), (long)send_ret);
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} else {
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printf("Sent %ld bytes instead of %lu bytes\n", (long)send_ret, (unsigned long)sizeof(pkt));
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}
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}
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}
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void AirSim::output_rover(const struct sitl_input &input)
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{
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rover_packet pkt;
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pkt.steering = 2*((input.servos[0]-1000)/1000.0f - 0.5f);
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pkt.throttle = 2*((input.servos[2]-1000)/1000.0f - 0.5f);
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ssize_t send_ret = sock.sendto(&pkt, sizeof(pkt), airsim_ip, airsim_control_port);
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if (send_ret != sizeof(pkt)) {
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if (send_ret <= 0) {
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printf("Unable to send control output to %s:%u - Error: %s, Return value: %ld\n",
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airsim_ip, airsim_control_port, strerror(errno), (long)send_ret);
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} else {
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printf("Sent %ld bytes instead of %lu bytes\n", (long)send_ret, (unsigned long)sizeof(pkt));
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}
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}
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}
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/*
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very simple JSON parser for sensor data
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called with pointer to one row of sensor data, nul terminated
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This parser does not do any syntax checking, and is not at all
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general purpose
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*/
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bool AirSim::parse_sensors(const char *json)
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{
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// printf("%s\n", json);
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for (uint16_t i=0; i<ARRAY_SIZE(keytable); i++) {
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struct keytable &key = keytable[i];
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/* look for section header */
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const char *p = strstr(json, key.section);
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if (!p) {
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// we don't have this sensor
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continue;
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}
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p += strlen(key.section)+1;
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// find key inside section
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p = strstr(p, key.key);
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if (!p) {
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printf("Failed to find key %s/%s\n", key.section, key.key);
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return false;
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}
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p += strlen(key.key)+3;
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switch (key.type) {
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case DATA_UINT64:
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*((uint64_t *)key.ptr) = strtoul(p, nullptr, 10);
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break;
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case DATA_FLOAT:
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*((float *)key.ptr) = atof(p);
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break;
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case DATA_DOUBLE:
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*((double *)key.ptr) = atof(p);
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break;
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case DATA_VECTOR3F: {
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Vector3f *v = (Vector3f *)key.ptr;
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if (sscanf(p, "[%f, %f, %f]", &v->x, &v->y, &v->z) != 3) {
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printf("Failed to parse Vector3f for %s/%s\n", key.section, key.key);
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return false;
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}
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break;
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}
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case DATA_VECTOR3F_ARRAY: {
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// - array of floats that represent [x,y,z] coordinate for each point hit within the range
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// x0, y0, z0, x1, y1, z1, ..., xn, yn, zn
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// example: [23.1,0.677024,1.4784,-8.97607135772705,-8.976069450378418,-8.642673492431641e-07,]
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if (*p++ != '[') {
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return false;
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}
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uint16_t n = 0;
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struct vector3f_array *v = (struct vector3f_array *)key.ptr;
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while (true) {
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if (n >= v->length) {
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Vector3f *d = (Vector3f *)realloc(v->data, sizeof(Vector3f)*(n+1));
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if (d == nullptr) {
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return false;
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}
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v->data = d;
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v->length = n+1;
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}
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if (sscanf(p, "%f,%f,%f,", &v->data[n].x, &v->data[n].y, &v->data[n].z) != 3) {
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printf("Failed to parse Vector3f for %s/%s[%u]\n", key.section, key.key, n);
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return false;
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}
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n++;
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// Goto 3rd occurence of ,
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p = strchr(p,',');
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if (!p) {
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return false;
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}
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p++;
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p = strchr(p,',');
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if (!p) {
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return false;
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}
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p++;
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p = strchr(p,',');
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if (!p) {
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return false;
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}
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p++;
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// Reached end of point cloud
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if (p[0] == ']') {
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break;
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}
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}
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v->length = n;
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break;
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}
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case DATA_FLOAT_ARRAY: {
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// example: [18.0, 12.694079399108887]
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if (*p++ != '[') {
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return false;
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}
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uint16_t n = 0;
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struct float_array *v = (struct float_array *)key.ptr;
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while (true) {
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if (n >= v->length) {
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float *d = (float *)realloc(v->data, sizeof(float)*(n+1));
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if (d == nullptr) {
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return false;
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}
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v->data = d;
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v->length = n+1;
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}
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v->data[n] = atof(p);
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n++;
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p = strchr(p,',');
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if (!p) {
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break;
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}
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p++;
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}
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v->length = n;
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break;
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}
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}
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}
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return true;
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}
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/*
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Receive new sensor data from simulator
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This is a blocking function
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*/
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void AirSim::recv_fdm()
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{
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// Receive sensor packet
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ssize_t ret = sock.recv(&sensor_buffer[sensor_buffer_len], sizeof(sensor_buffer)-sensor_buffer_len, 100);
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while (ret <= 0) {
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printf("No sensor message received - %s\n", strerror(errno));
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ret = sock.recv(&sensor_buffer[sensor_buffer_len], sizeof(sensor_buffer)-sensor_buffer_len, 100);
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}
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// convert '\n' into nul
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while (uint8_t *p = (uint8_t *)memchr(&sensor_buffer[sensor_buffer_len], '\n', ret)) {
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*p = 0;
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}
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sensor_buffer_len += ret;
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const uint8_t *p2 = (const uint8_t *)memrchr(sensor_buffer, 0, sensor_buffer_len);
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if (p2 == nullptr || p2 == sensor_buffer) {
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return;
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}
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const uint8_t *p1 = (const uint8_t *)memrchr(sensor_buffer, 0, p2 - sensor_buffer);
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if (p1 == nullptr) {
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return;
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}
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parse_sensors((const char *)(p1+1));
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memmove(sensor_buffer, p2, sensor_buffer_len - (p2 - sensor_buffer));
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sensor_buffer_len = sensor_buffer_len - (p2 - sensor_buffer);
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accel_body = Vector3f(state.imu.linear_acceleration[0],
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state.imu.linear_acceleration[1],
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state.imu.linear_acceleration[2]);
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gyro = Vector3f(state.imu.angular_velocity[0],
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state.imu.angular_velocity[1],
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state.imu.angular_velocity[2]);
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velocity_ef = Vector3f(state.velocity.world_linear_velocity[0],
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state.velocity.world_linear_velocity[1],
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state.velocity.world_linear_velocity[2]);
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location.lat = state.gps.lat * 1.0e7;
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location.lng = state.gps.lon * 1.0e7;
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location.alt = state.gps.alt * 100.0f;
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dcm.from_euler(state.pose.roll, state.pose.pitch, state.pose.yaw);
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if (last_timestamp) {
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int deltat = state.timestamp - last_timestamp;
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time_now_us += deltat;
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if (deltat > 0 && deltat < 100000) {
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if (average_frame_time < 1) {
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average_frame_time = deltat;
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}
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average_frame_time = average_frame_time * 0.98 + deltat * 0.02;
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}
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}
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scanner.points = state.lidar.points;
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rcin_chan_count = state.rc.rc_channels.length < 8 ? state.rc.rc_channels.length : 8;
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for (uint8_t i=0; i < rcin_chan_count; i++) {
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rcin[i] = state.rc.rc_channels.data[i];
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}
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#if 0
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// @LoggerMessage: ASM1
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// @Description: AirSim simulation data
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// @Field: TimeUS: Time since system startup
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// @Field: TUS: Simulation's timestamp
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// @Field: R: Simulation's roll
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// @Field: P: Simulation's pitch
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// @Field: Y: Simulation's yaw
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// @Field: GX: Simulated gyroscope, X-axis
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// @Field: GY: Simulated gyroscope, Y-axis
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// @Field: GZ: Simulated gyroscope, Z-axis
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AP::logger().Write("ASM1", "TimeUS,TUS,R,P,Y,GX,GY,GZ",
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"QQffffff",
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AP_HAL::micros64(),
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state.timestamp,
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degrees(state.pose.roll),
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degrees(state.pose.pitch),
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degrees(state.pose.yaw),
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degrees(gyro.x),
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degrees(gyro.y),
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degrees(gyro.z));
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Vector3f velocity_bf = dcm.transposed() * velocity_ef;
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position = home.get_distance_NED(location);
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// @LoggerMessage: ASM2
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// @Description: More AirSim simulation data
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// @Field: TimeUS: Time since system startup
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// @Field: AX: simulation's acceleration, X-axis
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// @Field: AY: simulation's acceleration, Y-axis
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// @Field: AZ: simulation's acceleration, Z-axis
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// @Field: VX: simulation's velocity, X-axis
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// @Field: VY: simulation's velocity, Y-axis
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// @Field: VZ: simulation's velocity, Z-axis
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// @Field: PX: simulation's position, X-axis
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// @Field: PY: simulation's position, Y-axis
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// @Field: PZ: simulation's position, Z-axis
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// @Field: Alt: simulation's gps altitude
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// @Field: SD: simulation's earth-frame speed-down
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AP::logger().Write("ASM2", "TimeUS,AX,AY,AZ,VX,VY,VZ,PX,PY,PZ,Alt,SD",
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"Qfffffffffff",
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AP_HAL::micros64(),
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accel_body.x,
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accel_body.y,
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accel_body.z,
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velocity_bf.x,
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velocity_bf.y,
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velocity_bf.z,
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position.x,
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position.y,
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position.z,
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state.gps.alt,
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velocity_ef.z);
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#endif
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last_timestamp = state.timestamp;
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}
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/*
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update the AirSim simulation by one time step
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*/
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void AirSim::update(const struct sitl_input &input)
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{
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switch (output_type) {
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case OutputType::Copter:
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output_copter(input);
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break;
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case OutputType::Rover:
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output_rover(input);
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break;
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}
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recv_fdm();
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// update magnetic field
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update_mag_field_bf();
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report_FPS();
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}
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/*
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report frame rates
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*/
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void AirSim::report_FPS(void)
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{
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if (frame_counter++ % 1000 == 0) {
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if (last_frame_count != 0) {
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printf("FPS avg=%.2f\n", 1.0e6/average_frame_time);
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}
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last_frame_count = state.timestamp;
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}
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}
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