/* 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 Weboreceived a copy of the GNU General Public License along with this program. If not, see . */ /* simulator connector for webots simulator */ #include "SIM_Webots.h" #if HAL_SIM_WEBOTS_ENABLED #include #include #include #include #include #include #include #include #include "pthread.h" #include extern const AP_HAL::HAL& hal; using namespace SITL; static const struct { const char *name; float value; bool save; } sim_defaults[] = { { "AHRS_EKF_TYPE", 10 }, { "INS_GYR_CAL", 0 }, { "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 }, }; Webots::Webots(const char *frame_str) : Aircraft(frame_str) { use_time_sync = false; use_smoothing = false; last_state.timestamp = 0.0l; char *saveptr = nullptr; char *s = strdup(frame_str); char *frame_option = strtok_r(s, ":", &saveptr); char *args1 = strtok_r(nullptr, ":", &saveptr); char *args2 = strtok_r(nullptr, ":", &saveptr); /* allow setting of IP, sensors port and control port format morse:IPADDRESS:SENSORS_PORT:CONTROL_PORT */ if (args1) { webots_ip = args1; printf("Simulation Port %s\n",args1); } if (args2) { webots_sensors_port = atoi(args2); } if (strstr(frame_option, "-rover")) { output_type = OUTPUT_ROVER; } else if (strstr(frame_option, "-quad")) { output_type = OUTPUT_QUAD; } else if (strstr(frame_option, "-tri")) { output_type = OUTPUT_TRICOPTER; } else if (strstr(frame_option, "-pwm")) { output_type = OUTPUT_PWM; } else { // default to rover output_type = OUTPUT_ROVER; } for (uint8_t i=0; iconfigured()) { p->save(); } } } printf("Started Webots with %s:%u type %u\n", webots_ip, webots_sensors_port, (unsigned)output_type); } /* very simple JSON parser for sensor data called with pointer to one row of sensor data, nul terminated This parser does not do any syntax checking, and is not at all general purpose {"timestamp": 1563474924.817575, "vehicle.imu": {"timestamp": 1563474924.8009083, "angular_velocity": [2.319516170246061e-06, -3.5830129263558774e-07, 7.009341995711793e-09], "linear_acceleration": [0.005075275432318449, 0.22471635043621063, 9.80748176574707], "magnetic_field": [23088.65625, 3875.89453125, -53204.51171875]}, "vehicle.gps": {"timestamp": 1563474924.8009083, "x": 5.386466364143416e-05, "y": -0.0010969983413815498, "z": 0.03717954829335213}, "vehicle.velocity": {"timestamp": 1563474924.8009083, "linear_velocity": [4.818238585890811e-10, 2.1333558919423012e-08, 9.310780910709582e-07], "angular_velocity": [2.319516170246061e-06, -3.5830129263558774e-07, 7.009341995711793e-09], "world_linear_velocity": [5.551115123125783e-17, 0.0, 9.313225746154785e-07]}, "vehicle.pose": {"timestamp": 1563474924.8009083, "x": 5.386466364143416e-05, "y": -0.0010969983413815498, "z": 0.03717954829335213, "yaw": 7.137723878258839e-05, "pitch": -0.0005173543468117714, "roll": 0.022908739745616913}} */ bool Webots::parse_sensors(const char *json) { //printf("%s\n", json); for (uint16_t i=0; ix, &v->y, &v->z) != 3) { printf("Failed to parse Vector3f for %s %s/%s\n",p, key.section, key.key); //printf("Failed to parse Vector3f for %s/%s\n", key.section, key.key); return false; } else { //printf("GOT %s/%s [%f, %f, %f]\n", key.section, key.key, v->x, v->y, v->z); } break; } case DATA_VECTOR3F_ARRAY: { // example: [[0.0, 0.0, 0.0], [-8.97607135772705, -8.976069450378418, -8.642673492431641e-07]] if (*p++ != '[') { return false; } uint16_t n = 0; struct vector3f_array *v = (struct vector3f_array *)key.ptr; while (true) { if (n >= v->length) { Vector3f *d = (Vector3f *)realloc(v->data, sizeof(Vector3f)*(n+1)); if (d == nullptr) { return false; } v->data = d; v->length = n+1; } if (sscanf(p, "[%f, %f, %f]", &v->data[n].x, &v->data[n].y, &v->data[n].z) != 3) { //printf("Failed to parse Vector3f for %s/%s[%u]\n", key.section, key.key, n); return false; } else { //printf("GOT %s/%s [%f, %f, %f]\n", key.section, key.key, v->data[n].x, v->data[n].y, v->data[n].z); } n++; p = strchr(p,']'); if (!p) { return false; } p++; if (p[0] != ',') { break; } if (p[1] != ' ') { return false; } p += 2; } if (p[0] != ']') { return false; } v->length = n; break; } case DATA_FLOAT_ARRAY: { // example: [18.0, 12.694079399108887] if (*p++ != '[') { return false; } uint16_t n = 0; struct float_array *v = (struct float_array *)key.ptr; while (true) { if (n >= v->length) { float *d = (float *)realloc(v->data, sizeof(float)*(n+1)); if (d == nullptr) { return false; } v->data = d; v->length = n+1; } v->data[n] = atof(p); n++; p = strchr(p,','); if (!p) { break; } p++; } v->length = n; break; } } } socket_frame_counter++; return true; } /* connect to the required sockets */ bool Webots::connect_sockets(void) { if (!sim_sock) { sim_sock = NEW_NOTHROW SocketAPM_native(false); if (!sim_sock) { AP_HAL::panic("Out of memory for sensors socket"); } if (!sim_sock->connect(webots_ip, webots_sensors_port)) { usleep(100000); if (connect_counter++ == 20) { printf("Waiting to connect to sensors control on %s:%u\n", webots_ip, webots_sensors_port); connect_counter = 0; } delete sim_sock; sim_sock = nullptr; return false; } // wait for Webots packets sim_sock->set_blocking(true); sim_sock->reuseaddress(); printf("Sensors connected\n"); } return true; } /* get any new data from the sensors socket */ bool Webots::sensors_receive(void) { ssize_t ret = sim_sock->recv(&sensor_buffer[sensor_buffer_len], sizeof(sensor_buffer)-sensor_buffer_len, 0); if (ret <= 0) { return false; } // convert '\n' into nul while (uint8_t *p = (uint8_t *)memchr(&sensor_buffer[sensor_buffer_len], '\n', ret)) { *p = 0; } sensor_buffer_len += ret; const uint8_t *p2 = (const uint8_t *)memrchr(sensor_buffer, 0, sensor_buffer_len); if (p2 == nullptr || p2 == sensor_buffer) { return false; } const uint8_t *p1 = (const uint8_t *)memrchr(sensor_buffer, 0, p2 - sensor_buffer); if (p1 == nullptr) { return false; } bool parse_ok = parse_sensors((const char *)(p1+1)); memmove(sensor_buffer, p2, sensor_buffer_len - (p2 - sensor_buffer)); sensor_buffer_len = sensor_buffer_len - (p2 - sensor_buffer); return parse_ok; } /* output control command assuming skid-steering rover */ void Webots::output_rover(const struct sitl_input &input) { const float motor1 = 2*((input.servos[0]-1000)/1000.0f - 0.5f); const float motor2 = 2*((input.servos[2]-1000)/1000.0f - 0.5f); // construct a JSON packet for v and w char buf[200]; const int len = snprintf(buf, sizeof(buf)-1, "{\"rover\": [%f, %f], \"wnd\": [%f, %f, %f, %f]}\n", motor1, motor2, input.wind.speed, wind_ef.x, wind_ef.y, wind_ef.z); buf[len] = 0; sim_sock->send(buf, len); } /* output control command assuming a 3 channels motors and 1 channel servo */ void Webots::output_tricopter(const struct sitl_input &input) { const float max_thrust = 1.0; float motors[3]; const float servo = ((input.servos[6]-1000)/1000.0f - 0.5f); motors[0] = constrain_float(((input.servos[0]-1000)/1000.0f) * max_thrust, 0, max_thrust); motors[1] = constrain_float(((input.servos[1]-1000)/1000.0f) * max_thrust, 0, max_thrust); motors[2] = constrain_float(((input.servos[3]-1000)/1000.0f) * max_thrust, 0, max_thrust); const float &m_right = motors[0]; const float &m_left = motors[1]; const float &m_servo = servo ; const float &m_back = motors[2]; // construct a JSON packet for motors char buf[200]; const int len = snprintf(buf, sizeof(buf)-1, "{\"eng\": [%.3f, %.3f, %.3f, %.3f], \"wnd\": [%f, %3.1f, %1.1f, %2.1f]}\n", m_right, m_left, m_servo, m_back, input.wind.speed, wind_ef.x, wind_ef.y, wind_ef.z); //printf("\"eng\": [%.3f, %.3f, %.3f, %.3f]\n",m_right, m_left, m_servo, m_back); buf[len] = 0; sim_sock->send(buf, len); } /* output all 16 channels as PWM values. This allows for general control of a robot */ void Webots::output_pwm(const struct sitl_input &input) { char buf[2000]; const int len = snprintf(buf, sizeof(buf)-1, "{\"pwm\": [%d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0, %d.0], \"wnd\": [%3.3f, %f, %3.3f, %3.3f]}\n", input.servos[0], input.servos[1], input.servos[2], input.servos[3], input.servos[4], input.servos[5], input.servos[6], input.servos[7], input.servos[8], input.servos[9], input.servos[10], input.servos[11], input.servos[12], input.servos[13], input.servos[14], input.servos[15], input.wind.speed, wind_ef.x, wind_ef.y, wind_ef.z); buf[len] = 0; sim_sock->send(buf, len); } void Webots::output (const struct sitl_input &input) { switch (output_type) { case OUTPUT_ROVER: output_rover(input); break; case OUTPUT_QUAD: output_pwm(input); break; case OUTPUT_TRICOPTER: output_tricopter(input); break; case OUTPUT_PWM: output_pwm(input); break; } } /* update the Webots simulation by one time step */ void Webots::update(const struct sitl_input &input) { static bool first = true; if (!connect_sockets()) { return; } const bool valid = sensors_receive(); if (!valid) { return ; } //time frame from simulator frame_time_us = ((state.timestamp - last_state.timestamp) * 1.0e6f); //HERE if ((!first) && (frame_time_us ==0)) { first = false; printf("frame_time_us Zero \n"); output(input); return ; } time_now_us += frame_time_us; if (valid) { // convert from state variables to ardupilot conventions dcm.from_euler(state.pose.roll, state.pose.pitch, -state.pose.yaw); gyro = Vector3f(state.imu.angular_velocity[0] , state.imu.angular_velocity[1] , -state.imu.angular_velocity[2] ); accel_body = Vector3f(+state.imu.linear_acceleration[0], +state.imu.linear_acceleration[1], -state.imu.linear_acceleration[2]); velocity_ef = Vector3f(+state.velocity.world_linear_velocity[0], +state.velocity.world_linear_velocity[1], -state.velocity.world_linear_velocity[2]); position = Vector3d(state.gps.x, state.gps.y, -state.gps.z); position.xy() += origin.get_distance_NE_double(home); // limit to 16G to match pixhawk1 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); // fill in laser scanner results, if available scanner.points = state.scanner.points; scanner.ranges = state.scanner.ranges; update_position(); // update magnetic field update_mag_field_bf(); time_advance(); update_wind (input); //report_FPS(); } output(input); last_state = state; } /* report frame rates */ void Webots::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.timestamp - 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.timestamp; // } } #endif // HAL_SIM_WEBOTS_ENABLED