void parentMode::testTouchEvent() { streak = MotionStreak::create(0.5f, 10, 30, Color3B::WHITE, "Demo/flash.png"); this->addChild(streak, 2); //10.55 9.1 7.65 6.24 4.75 auto listener = EventListenerTouchOneByOne::create(); listener->onTouchBegan = [&](Touch* touch, Event* event){ touch_pos = touch->getLocation(); //滑动拖尾效果 if (touch_pos.x > 0 && touch_pos.x < visibleSize.width /2 *4.2/17.64) { if (touch_pos.y > visibleSize.height / 14.1*9.1 && touch_pos.y < visibleSize.height / 14.1*10.55) { } else if (touch_pos.y > visibleSize.height / 14.1*7.65 && touch_pos.y < visibleSize.height / 14.1*9.1) { timeset(this); } else if (touch_pos.y > visibleSize.height / 14.1*6.24 && touch_pos.y < visibleSize.height / 14.1*7.65) { parentstudy(this); } else if (touch_pos.y > visibleSize.height / 14.1*4.75 && touch_pos.y < visibleSize.height / 14.1*6.24) { this->stopAllActions(); auto scene = introduction::createScene(); CCDirector::sharedDirector()->replaceScene(CCTransitionFade::create(0.1, scene, Color3B::GRAY)); } } return true; }; listener->onTouchMoved = [&](Touch* touch, Event* event){ }; listener->onTouchEnded = [&](Touch* touch, Event* event){ log("onTouchEnded"); }; dispatcher->addEventListenerWithSceneGraphPriority(listener, this); }
void main(void) { OSCCON = 0b11110000; // 内部クロックは8MHzとする OPTION_REG = 0b00000000; // デジタルI/Oに内部プルアップ抵抗を使用する ANSELA = 0b00000000; // AN0-AN4は使用しない全てデジタルI/Oとする ANSELB = 0b00000000; // AN5-AN11は使用しない全てデジタルI/Oとする TRISA = 0b00000011; // ピン(RA)は全て出力に割当てる(RA5は入力のみとなる) TRISB = 0b00010110; // ピン(RB)はRB4(SCL1)/RB1(SDA1)のみ入力 WPUB = 0b00010010; // RB1/4は内部プルアップ抵抗を指定する PORTA = 0b00000000; // RA出力ピンの初期化(全てLOWにする) PORTB = 0b00000000; // RB出力ピンの初期化(全てLOWにする) APFCON0bits.RXDTSEL = 1; APFCON1bits.TXCKSEL = 1; T1CON = 0x21; //Fosc/4, ps:1/4 TMR1H = 0x00; TMR1L = 0x00; PIE1bits.TMR1IE = 1; I2C_init(); LCD_init(); UART_init(PIC16F1827); INTCONbits.PEIE = 1; INTCONbits.GIE = 1; uint8_t buf[70]; ringbuf_init(&tx_buf, buf, sizeof (buf)); RTC_Write(0x07, 0x00); while (1) { display(); if (sw_RA1.flag.press) { sw_RA1.flag.press=0; tx_send('2'); tx_send('0'); tx_send(((YY & 0xF0) >> 4) + '0'); tx_send((YY & 0x0F) + '0'); tx_send('/'); tx_send(((MM & 0xF0) >> 4) + '0'); tx_send((MM & 0x0F) + '0'); tx_send('/'); tx_send(((DD & 0xF0) >> 4) + '0'); tx_send((DD & 0x0F) + '0'); tx_send('('); tx_send((EE & 0x0F) + '0'); tx_send(')'); tx_send(((hh & 0xF0) >> 4) + '0'); tx_send((hh & 0x0F) + '0'); tx_send(':'); tx_send(((mm & 0xF0) >> 4) + '0'); tx_send((mm & 0x0F) + '0'); tx_send('-'); tx_send(((ss & 0xF0) >> 4) + '0'); tx_send((ss & 0x0F) + '0'); tx_send('.'); tx_send('\n'); tx_sends("Real Time Clock\n"); } if (sw_RA0.flag.long_holding_1) { sw_RA0.flag.long_holding_1 = 0; timeset(&YY, 0, 99, 0x06, 0, 0); timeset(&MM, 1, 12, 0x05, 3, 0); timeset(&DD, 1, month_length(YY, MM), 0x04, 6, 0); timeset(&hh, 0, 23, 0x02, 0, 1); timeset(&mm, 0, 59, 0x01, 3, 1); timeset(&ss, 0, 59, 0x00, 6, 1); } }
static void *rtksvrthread(void *arg) #endif { rtksvr_t *svr=(rtksvr_t *)arg; obs_t obs; obsd_t data[MAXOBS*2]; double tt; unsigned int tick,ticknmea; unsigned char *p,*q; int i,j,n,fobs[3],cycle,cputime; INIT_ZERO(fobs); tracet(3,"rtksvrthread:\n"); svr->state=1; obs.data=data; svr->tick=tickget(); ticknmea=svr->tick-1000; for (cycle=0;svr->state;cycle++) { tick=tickget(); for (i=0;i<3;i++) { p=svr->buff[i]+svr->nb[i]; q=svr->buff[i]+svr->buffsize; /* read receiver raw/rtcm data from input stream */ if ((n=strread(svr->stream+i,p,q-p))<=0) { continue; } /* write receiver raw/rtcm data to log stream */ strwrite(svr->stream+i+5,p,n); svr->nb[i]+=n; /* save peek buffer */ rtksvrlock(svr); n=n<svr->buffsize-svr->npb[i]?n:svr->buffsize-svr->npb[i]; memcpy(svr->pbuf[i]+svr->npb[i],p,n); svr->npb[i]+=n; rtksvrunlock(svr); } for (i=0;i<3;i++) { if (svr->format[i]==STRFMT_SP3||svr->format[i]==STRFMT_RNXCLK) { /* decode download file */ decodefile(svr,i); } else { /* decode receiver raw/rtcm data */ fobs[i]=decoderaw(svr,i); } } for (i=0;i<fobs[0];i++) { /* for each rover observation data */ obs.n=0; for (j=0;j<svr->obs[0][i].n&&obs.n<MAXOBS*2;j++) { obs.data[obs.n++]=svr->obs[0][i].data[j]; } for (j=0;j<svr->obs[1][0].n&&obs.n<MAXOBS*2;j++) { obs.data[obs.n++]=svr->obs[1][0].data[j]; } /* rtk positioning */ rtksvrlock(svr); rtkpos(&svr->rtk,obs.data,obs.n,&svr->nav); rtksvrunlock(svr); if (svr->rtk.sol.stat!=SOLQ_NONE) { /* adjust current time */ tt=(int)(tickget()-tick)/1000.0+DTTOL; timeset(gpst2utc(timeadd(svr->rtk.sol.time,tt))); /* write solution */ writesol(svr,i); } /* if cpu overload, inclement obs outage counter and break */ if ((int)(tickget()-tick)>=svr->cycle) { svr->prcout+=fobs[0]-i-1; #if 0 /* omitted v.2.4.1 */ break; #endif } } /* send null solution if no solution (1hz) */ if (svr->rtk.sol.stat==SOLQ_NONE&&cycle%(1000/svr->cycle)==0) { writesol(svr,0); } /* send nmea request to base/nrtk input stream */ if (svr->nmeacycle>0&&(int)(tick-ticknmea)>=svr->nmeacycle) { if (svr->stream[1].state==1) { if (svr->nmeareq==1) { strsendnmea(svr->stream+1,svr->nmeapos); } else if (svr->nmeareq==2&&norm(svr->rtk.sol.rr,3)>0.0) { strsendnmea(svr->stream+1,svr->rtk.sol.rr); } } ticknmea=tick; } if ((cputime=(int)(tickget()-tick))>0) svr->cputime=cputime; /* sleep until next cycle */ sleepms(svr->cycle-cputime); } for (i=0;i<MAXSTRRTK;i++) strclose(svr->stream+i); for (i=0;i<3;i++) { svr->nb[i]=svr->npb[i]=0; free(svr->buff[i]); svr->buff[i]=NULL; free(svr->pbuf[i]); svr->pbuf[i]=NULL; free_raw (svr->raw +i); free_rtcm(svr->rtcm+i); } for (i=0;i<2;i++) { svr->nsb[i]=0; free(svr->sbuf[i]); svr->sbuf[i]=NULL; } return 0; }
int main(int argc,char **argv) { ros::init(argc, argv, "rtk_robot"); ROS_INFO("RTKlib for ROS Robot Edition"); ros::NodeHandle nn; ros::NodeHandle pn("~"); ros::Subscriber ecef_sub; if(pn.getParam("base_position/x", ecef_base_station.position.x) && pn.getParam("base_position/y", ecef_base_station.position.y) && pn.getParam("base_position/z", ecef_base_station.position.z)) { ROS_INFO("RTK -- Loading base station parameters from the parameter server..."); XmlRpc::XmlRpcValue position_covariance; if( pn.getParam("base_position/covariance", position_covariance) ) { ROS_ASSERT(position_covariance.getType() == XmlRpc::XmlRpcValue::TypeArray); if(position_covariance.size() != 9) { ROS_WARN("RTK -- The base station covariances are not complete! Using default values..."); } else { for(int i=0 ; i<position_covariance.size() ; ++i) { ROS_ASSERT(position_covariance[i].getType() == XmlRpc::XmlRpcValue::TypeDouble); ecef_base_station.position_covariance[i] = static_cast<double>(position_covariance[i]); } } } } else { ROS_INFO("RTK -- Subscribing to the base station for online parameters..."); ecef_sub = nn.subscribe("base_station/gps/ecef", 50, ecefCallback); } double rate; pn.param("rate", rate, 2.0); std::string gps_frame_id; pn.param<std::string>("gps_frame_id", gps_frame_id, "gps"); std::string port; pn.param<std::string>("port", port, "ttyACM0"); int baudrate; pn.param("baudrate", baudrate, 115200); ros::Publisher gps_pub = nn.advertise<sensor_msgs::NavSatFix>("gps/fix", 50); ros::Publisher status_pub = nn.advertise<rtk_msgs::Status>("gps/status", 50); ros::Subscriber gps_sub = nn.subscribe("base_station/gps/raw_data", 50, baseStationCallback); int n; //********************* rtklib stuff ********************* rtksvrinit(&server); if(server.state) { ROS_FATAL("RTK -- Failed to initialize rtklib server!"); ROS_BREAK(); } gtime_t time, time0 = {0}; int format[] = {STRFMT_UBX, STRFMT_UBX, STRFMT_RTCM2}; prcopt_t options = prcopt_default; options.mode = 2; options.nf = 1; options.navsys = SYS_GPS | SYS_SBS; options.modear = 3; options.glomodear = 0; options.minfix = 3; options.ionoopt = IONOOPT_BRDC; options.tropopt = TROPOPT_SAAS; options.rb[0] = ecef_base_station.position.x; options.rb[1] = ecef_base_station.position.y; options.rb[2] = ecef_base_station.position.z; strinitcom(); server.cycle = 10; server.nmeacycle = 1000; server.nmeareq = 0; for(int i=0 ; i<3 ; i++) server.nmeapos[i] = 0; server.buffsize = BUFFSIZE; for(int i=0 ; i<3 ; i++) server.format[i] = format[i]; server.navsel = 0; server.nsbs = 0; server.nsol = 0; server.prcout = 0; rtkfree(&server.rtk); rtkinit(&server.rtk, &options); for(int i=0 ; i<3 ; i++) { server.nb[i] = server.npb[i] = 0; if(!(server.buff[i]=(unsigned char *)malloc(BUFFSIZE)) || !(server.pbuf[i]=(unsigned char *)malloc(BUFFSIZE))) { ROS_FATAL("RTK -- Failed to initialize rtklib server - malloc error!"); ROS_BREAK(); } for(int j=0 ; j<10 ; j++) server.nmsg[i][j] = 0; for(int j=0 ; j<MAXOBSBUF ; j++) server.obs[i][j].n = 0; /* initialize receiver raw and rtcm control */ init_raw(server.raw + i); init_rtcm(server.rtcm + i); /* set receiver option */ strcpy(server.raw[i].opt, ""); strcpy(server.rtcm[i].opt, ""); /* connect dgps corrections */ server.rtcm[i].dgps = server.nav.dgps; } /* output peek buffer */ for(int i=0 ; i<2 ; i++) { if (!(server.sbuf[i]=(unsigned char *)malloc(BUFFSIZE))) { ROS_FATAL("RTK -- Failed to initialize rtklib server - malloc error!"); ROS_BREAK(); } } /* set solution options */ solopt_t sol_options[2]; sol_options[0] = solopt_default; sol_options[1] = solopt_default; for(int i=0 ; i<2 ; i++) server.solopt[i] = sol_options[i]; /* set base station position */ for(int i=0 ; i<6 ; i++) server.rtk.rb[i] = i < 3 ? options.rb[i] : 0.0; /* update navigation data */ for(int i=0 ; i<MAXSAT*2 ; i++) server.nav.eph[i].ttr = time0; for(int i=0 ; i<NSATGLO*2 ; i++) server.nav.geph[i].tof = time0; for(int i=0 ; i<NSATSBS*2 ; i++) server.nav.seph[i].tof = time0; updatenav(&server.nav); /* set monitor stream */ server.moni = NULL; /* open input streams */ int stream_type[8] = {STR_SERIAL, 0, 0, 0, 0, 0, 0, 0}; char gps_path[64]; sprintf(gps_path, "%s:%d:8:n:1:off", port.c_str(), baudrate); char * paths[] = {gps_path, "localhost:27015", "", "", "", "", "", ""}; char * cmds[] = {"", "", ""}; int rw; for(int i=0 ; i<8 ; i++) { rw = i < 3 ? STR_MODE_R : STR_MODE_W; if(stream_type[i] != STR_FILE) rw |= STR_MODE_W; if(!stropen(server.stream+i, stream_type[i], rw, paths[i])) { ROS_ERROR("RTK -- Failed to open stream %s", paths[i]); for(i-- ; i>=0 ; i--) strclose(server.stream+i); ROS_FATAL("RTK -- Failed to initialize rtklib server - failed to open all streams!"); ROS_BREAK(); } /* set initial time for rtcm and raw */ if(i<3) { time = utc2gpst(timeget()); server.raw[i].time = stream_type[i] == STR_FILE ? strgettime(server.stream+i) : time; server.rtcm[i].time = stream_type[i] == STR_FILE ? strgettime(server.stream+i) : time; } } /* sync input streams */ strsync(server.stream, server.stream+1); strsync(server.stream, server.stream+2); /* write start commands to input streams */ for(int i=0 ; i<3 ; i++) { if(cmds[i]) strsendcmd(server.stream+i, cmds[i]); } /* write solution header to solution streams */ for(int i=3 ; i<5 ; i++) { unsigned char buff[1024]; int n; n = outsolheads(buff, server.solopt+i-3); strwrite(server.stream+i, buff, n); } //******************************************************** obs_t obs; obsd_t data[MAXOBS*2]; server.state=1; obs.data=data; double tt; unsigned int tick; int fobs[3] = {0}; server.tick = tickget(); ROS_DEBUG("RTK -- Initialization complete."); ros::Rate r(rate); while(ros::ok()) { tick = tickget(); unsigned char *p = server.buff[RTK_ROBOT]+server.nb[RTK_ROBOT]; unsigned char *q = server.buff[RTK_ROBOT]+server.buffsize; ROS_DEBUG("RTK -- Getting data from GPS..."); /* read receiver raw/rtcm data from input stream */ n = strread(server.stream, p, q-p); /* write receiver raw/rtcm data to log stream */ strwrite(server.stream+5, p, n); server.nb[RTK_ROBOT] += n; /* save peek buffer */ rtksvrlock(&server); n = n < server.buffsize - server.npb[RTK_ROBOT] ? n : server.buffsize - server.npb[RTK_ROBOT]; memcpy(server.pbuf[RTK_ROBOT] + server.npb[RTK_ROBOT], p, n); server.npb[RTK_ROBOT] += n; rtksvrunlock(&server); ROS_DEBUG("RTK -- Decoding GPS data..."); /* decode data */ fobs[RTK_ROBOT] = decoderaw(&server, RTK_ROBOT); fobs[RTK_BASE_STATION] = decoderaw(&server, RTK_BASE_STATION); ROS_DEBUG("RTK -- Got %d observations.", fobs[RTK_ROBOT]); /* for each rover observation data */ for(int i=0 ; i<fobs[RTK_ROBOT] ; i++) { obs.n = 0; for(int j=0 ; j<server.obs[RTK_ROBOT][i].n && obs.n<MAXOBS*2 ; j++) { obs.data[obs.n++] = server.obs[RTK_ROBOT][i].data[j]; } for(int j=0 ; j<server.obs[1][0].n && obs.n<MAXOBS*2 ; j++) { obs.data[obs.n++] = server.obs[1][0].data[j]; } ROS_DEBUG("RTK -- Calculating RTK positioning..."); /* rtk positioning */ rtksvrlock(&server); rtkpos(&server.rtk, obs.data, obs.n, &server.nav); rtksvrunlock(&server); sensor_msgs::NavSatFix gps_msg; gps_msg.header.stamp = ros::Time::now(); gps_msg.header.frame_id = gps_frame_id; rtk_msgs::Status status_msg; status_msg.stamp = gps_msg.header.stamp; if(server.rtk.sol.stat != SOLQ_NONE) { /* adjust current time */ tt = (int)(tickget()-tick)/1000.0+DTTOL; timeset(gpst2utc(timeadd(server.rtk.sol.time,tt))); /* write solution */ unsigned char buff[1024]; n = outsols(buff, &server.rtk.sol, server.rtk.rb, server.solopt); if(n==141 && buff[0]>'0' && buff[0]<'9') { int ano,mes,dia,horas,minutos,Q,nsat; double segundos,lat,longi,alt,sde,sdn,sdu,sdne,sdeu,sdun; sscanf((const char *)(buff),"%d/%d/%d %d:%d:%lf %lf %lf %lf %d %d %lf %lf %lf %lf %lf %lf", &ano, &mes, &dia, &horas, &minutos, &segundos, &lat, &longi, &alt, &Q, &nsat, &sdn, &sde, &sdu, &sdne, &sdeu, &sdun); gps_msg.latitude = lat; gps_msg.longitude = longi; gps_msg.altitude = alt; gps_msg.position_covariance_type = sensor_msgs::NavSatFix::COVARIANCE_TYPE_KNOWN; gps_msg.position_covariance[0] = sde + ecef_base_station.position_covariance[0]; gps_msg.position_covariance[1] = sdne + ecef_base_station.position_covariance[1]; gps_msg.position_covariance[2] = sdeu + ecef_base_station.position_covariance[2]; gps_msg.position_covariance[3] = sdne + ecef_base_station.position_covariance[3]; gps_msg.position_covariance[4] = sdn + ecef_base_station.position_covariance[4]; gps_msg.position_covariance[5] = sdun + ecef_base_station.position_covariance[5]; gps_msg.position_covariance[6] = sdeu + ecef_base_station.position_covariance[6]; gps_msg.position_covariance[7] = sdun + ecef_base_station.position_covariance[7]; gps_msg.position_covariance[8] = sdu + ecef_base_station.position_covariance[8]; gps_msg.status.status = Q==5 ? sensor_msgs::NavSatStatus::STATUS_FIX : sensor_msgs::NavSatStatus::STATUS_GBAS_FIX; gps_msg.status.service = sensor_msgs::NavSatStatus::SERVICE_GPS; status_msg.fix_quality = Q; status_msg.number_of_satellites = nsat; } } else { gps_msg.status.status = sensor_msgs::NavSatStatus::STATUS_NO_FIX; gps_msg.status.service = sensor_msgs::NavSatStatus::SERVICE_GPS; } ROS_DEBUG("RTK -- Publishing ROS msg..."); gps_pub.publish(gps_msg); status_pub.publish(status_msg); } ros::spinOnce(); r.sleep(); } return(0); }