/* 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 connection for morse simulator http://morse-simulator.github.io/ */ #pragma once #include #ifndef HAL_SIM_MORSE_ENABLED #define HAL_SIM_MORSE_ENABLED (CONFIG_HAL_BOARD == HAL_BOARD_SITL) #endif #if HAL_SIM_MORSE_ENABLED #include #include "SIM_Aircraft.h" namespace SITL { /* simulation interface */ class Morse : public Aircraft { public: Morse(const char *frame_str); /* update model by one time step */ void update(const struct sitl_input &input) override; /* static object creator */ static Aircraft *create(const char *frame_str) { return new Morse(frame_str); } private: // loopback to convert inbound Morse lidar data into inbound mavlink msgs const char *mavlink_loopback_address = "127.0.0.1"; const uint16_t mavlink_loopback_port = 5762; SocketAPM_native mav_socket { false }; struct { // socket to telem2 on aircraft bool connected; mavlink_message_t rxmsg; mavlink_status_t status; uint8_t seq; } mavlink {}; void send_report(void); uint32_t send_report_last_ms; const char *morse_ip = "127.0.0.1"; // assume sensors are streamed on port 60000 uint16_t morse_sensors_port = 60000; // assume we control vehicle on port 60001 uint16_t morse_control_port = 60001; enum { OUTPUT_ROVER_REGULAR=1, OUTPUT_ROVER_SKID=2, OUTPUT_QUAD=3, OUTPUT_PWM=4 } output_type; bool connect_sockets(void); bool parse_sensors(const char *json); bool sensors_receive(void); void output_rover_regular(const struct sitl_input &input); void output_rover_skid(const struct sitl_input &input); void output_quad(const struct sitl_input &input); void output_pwm(const struct sitl_input &input); void report_FPS(); // buffer for parsing pose data in JSON format uint8_t sensor_buffer[50000]; uint32_t sensor_buffer_len; SocketAPM_native *sensors_sock; SocketAPM_native *control_sock; uint32_t no_data_counter; uint32_t connect_counter; double initial_time_s; double last_time_s; double extrapolated_s; double average_frame_time_s; uint64_t socket_frame_counter; uint64_t last_socket_frame_counter; uint64_t frame_counter; double last_frame_count_s; enum data_type { DATA_FLOAT, DATA_DOUBLE, DATA_VECTOR3F, DATA_VECTOR3F_ARRAY, DATA_FLOAT_ARRAY, }; struct { double timestamp; struct { Vector3f angular_velocity; Vector3f linear_acceleration; Vector3f magnetic_field; } imu; struct { float x, y, z; } gps; struct { float roll, pitch, yaw; } pose; struct { Vector3f world_linear_velocity; } velocity; struct { struct vector3f_array points; struct float_array ranges; } scanner; } state, last_state; // table to aid parsing of JSON sensor data struct keytable { const char *section; const char *key; void *ptr; enum data_type type; } keytable[13] = { { "", "timestamp", &state.timestamp, DATA_DOUBLE }, { ".imu", "angular_velocity", &state.imu.angular_velocity, DATA_VECTOR3F }, { ".imu", "linear_acceleration", &state.imu.linear_acceleration, DATA_VECTOR3F }, { ".imu", "magnetic_field", &state.imu.magnetic_field, DATA_VECTOR3F }, { ".gps", "x", &state.gps.x, DATA_FLOAT }, { ".gps", "y", &state.gps.y, DATA_FLOAT }, { ".gps", "z", &state.gps.z, DATA_FLOAT }, { ".pose", "roll", &state.pose.roll, DATA_FLOAT }, { ".pose", "pitch", &state.pose.pitch, DATA_FLOAT }, { ".pose", "yaw", &state.pose.yaw, DATA_FLOAT }, { ".velocity", "world_linear_velocity", &state.velocity.world_linear_velocity, DATA_VECTOR3F }, { ".scan", "point_list", &state.scanner.points, DATA_VECTOR3F_ARRAY }, { ".scan", "range_list", &state.scanner.ranges, DATA_FLOAT_ARRAY }, }; }; } // namespace SITL #endif // HAL_SIM_MORSE_ENABLED