static int getSensorValue(int sock, ros::Publisher pub[TOPIC_NR]) { int info[2]; size_t size = sizeof(info); ssize_t nbytes; for (char *p = (char *)info; size; size -= nbytes, p += nbytes) { nbytes = recv(sock, info, size, 0); if (nbytes == -1) { perror("recv"); return -1; } if (nbytes == 0) { fprintf(stderr, "peer is shutdown\n"); return -1; } } fprintf(stderr, "info=%d value=%d\n", info[0], info[1]); switch(info[0]) { case 1: { // GEAR tablet_socket_msgs::gear_cmd msg; msg.gear = info[1]; pub[0].publish(msg); break; } case 2: { // MODE tablet_socket_msgs::mode_cmd msg; msg.mode = info[1]; pub[1].publish(msg); break; } case 3: { // ROUTE size = info[1]; if (!size) break; double *points = (double *)malloc(size); if (points == NULL) { perror("malloc"); return -1; } int points_nr = size / sizeof(double); for (char *p = (char *)points; size; size -= nbytes, p += nbytes) { nbytes = recv(sock, p, size, 0); if (nbytes == -1) { perror("recv"); free(points); return -1; } if (nbytes == 0) { fprintf(stderr, "peer is shutdown\n"); free(points); return -1; } } tablet_socket_msgs::route_cmd msg; tablet_socket_msgs::Waypoint point; for (int i = 0; i < points_nr; i++) { if (i % 2) { point.lon = points[i]; msg.point.push_back(point); } else point.lat = points[i]; } free(points); pub[2].publish(msg); break; } case 4: { // S1 if (info[1] >= 0) s1.start(); else s1.stop(); break; } case 5: { // S2 if (info[1] >= 0) s2.start(); else s2.stop(); break; } case 6: { // POSE size = info[1]; if (!size) break; double *buf = (double *)malloc(size); if (buf == NULL) { perror("malloc"); return -1; } for (char *p = (char *)buf; size; size -= nbytes, p += nbytes) { nbytes = recv(sock, p, size, 0); if (nbytes == -1) { perror("recv"); free(buf); return -1; } if (nbytes == 0) { fprintf(stderr, "peer is shutdown\n"); free(buf); return -1; } } geo.llh_to_xyz(buf[0], buf[1], buf[2]); tf::Transform transform; tf::Quaternion q; transform.setOrigin(tf::Vector3(geo.y(), geo.x(), geo.z())); q.setRPY(buf[4], buf[5], buf[3]); transform.setRotation(q); free(buf); ros::Time now = ros::Time::now(); tf::TransformBroadcaster br; br.sendTransform(tf::StampedTransform(transform, now, "map", "gps")); geometry_msgs::PoseStamped pose; pose.header.stamp = now; pose.header.frame_id = "map"; pose.pose.position.x = geo.y(); pose.pose.position.y = geo.x(); pose.pose.position.z = geo.z(); pose.pose.orientation.x = q.x(); pose.pose.orientation.y = q.y(); pose.pose.orientation.z = q.z(); pose.pose.orientation.w = q.w(); std_msgs::Bool stat; if (pose.pose.position.x == 0 || pose.pose.position.y == 0 || pose.pose.position.z == 0) stat.data = false; else stat.data = true; pub[3].publish(pose); pub[4].publish(stat); break; } default: // TERMINATOR fprintf(stderr, "receive %d, terminated.\n", info[0]); sendSignal(sock); return -1; } return 0; }
static void NmeaCallback(const nmea_msgs::Sentence::ConstPtr& msg) { static double qq_time, roll, pitch, yaw; //static double gga_time, x, y, z; static double gga_time; static tf::TransformBroadcaster br; static ros::Time pc_time; std::vector<std::string> nmea; csv_div(msg->sentence, &nmea); //static bool calibration_flag = true; // printf("%s\n",msg->sentence.c_str()); if (nmea[0].compare(0, 2, "QQ") == 0) { pc_time = msg->header.stamp; /* qq_time = str2double(nmea[3]); roll = str2double(nmea[4]) * M_PI / 180.; pitch = -1 * str2double(nmea[5]) * M_PI / 180.; yaw = -1 * str2double(nmea[6]) * M_PI / 180. + M_PI / 2; */ qq_time = stod(nmea[3]); roll = stod(nmea[4]) * M_PI / 180.; pitch = -1 * stod(nmea[5]) * M_PI / 180.; yaw = -1 * stod(nmea[6]) * M_PI / 180. + M_PI / 2; // new QQ message /* if (nmea.size() == NEW_QQ_SIZE) { if (stod(nmea[7]) == 1 && stod(nmea[8]) == 1 && stod(nmea[9]) == 1) { calibration_flag = true; } else { calibration_flag = false; } }*/ //printf("angle %f %f %f %f\n",qq_time,roll,pitch,yaw); } // if (calibration_flag == true) { if (nmea[0] == "$GPGGA") { pc_time = msg->header.stamp; /* gga_time = str2double(nmea[1]); double lat = str2double(nmea[2]); double lon = str2double(nmea[4]); double h = str2double(nmea[9]); //+str2double(nmea[11]); */ gga_time = stod(nmea[1]); double lat = stod(nmea[2]); double lon = stod(nmea[4]); double h = stod(nmea[9]); geo.set_llh_nmea_degrees(lat, lon, h); // printf("pos %f %f %f %f\n",gga_time,geo.x,geo.y,geo.z); } // if (qq_time == gga_time) { if (fabs(qq_time - gga_time) <= __FLT_EPSILON__) { //printf("%f %f %f %f %f %f %f %f\n", pc_time.toSec(), gga_time, geo.x(), geo.y(), geo.z(), roll, pitch, yaw); tf::Transform transform; tf::Quaternion q; transform.setOrigin(tf::Vector3(geo.y(), geo.x(), geo.z())); q.setRPY(roll, pitch, yaw); transform.setRotation(q); br.sendTransform(tf::StampedTransform(transform, pc_time, "map", "gps")); geometry_msgs::PoseStamped pose; pose.header = msg->header; pose.header.frame_id = "map"; pose.pose.position.x = geo.y(); pose.pose.position.y = geo.x(); pose.pose.position.z = geo.z(); pose.pose.orientation.x = q.x(); pose.pose.orientation.y = q.y(); pose.pose.orientation.z = q.z(); pose.pose.orientation.w = q.w(); // set gnss_stat if (pose.pose.position.x == 0.0 || pose.pose.position.y == 0.0 || pose.pose.position.z == 0.0) { gnss_stat_msg.data = false; } else { gnss_stat_msg.data = true; } pose_publisher.publish(pose); stat_publisher.publish(gnss_stat_msg); } /* } else { std::cout << "not calibrated!!" << std::endl; }*/ }