/*! * \file rtklib_rtksvr.cc * \brief rtk server functions * \authors * * This is a derived work from RTKLIB http://www.rtklib.com/ * The original source code at https://github.com/tomojitakasu/RTKLIB is * released under the BSD 2-clause license with an additional exclusive clause * that does not apply here. This additional clause is reproduced below: * * " The software package includes some companion executive binaries or shared * libraries necessary to execute APs on Windows. These licenses succeed to the * original ones of these software. " * * Neither the executive binaries nor the shared libraries are required by, used * or included in GNSS-SDR. * * ------------------------------------------------------------------------- * Copyright (C) 2007-2013, T. Takasu * Copyright (C) 2017, Javier Arribas * Copyright (C) 2017, Carles Fernandez * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * *----------------------------------------------------------------------------*/ #include "rtklib_rtksvr.h" #include "rtklib_preceph.h" #include "rtklib_rtcm.h" #include "rtklib_rtkcmn.h" #include "rtklib_rtkpos.h" #include "rtklib_sbas.h" #include "rtklib_solution.h" #include "rtklib_stream.h" #include /* write solution header to output stream ------------------------------------*/ void writesolhead(stream_t *stream, const solopt_t *solopt) { unsigned char buff[MAXSOLMSG]; int n; n = outsolheads(buff, solopt); strwrite(stream, buff, n); } /* save output buffer --------------------------------------------------------*/ void saveoutbuf(rtksvr_t *svr, unsigned char *buff, int n, int index) { rtksvrlock(svr); n = n < svr->buffsize - svr->nsb[index] ? n : svr->buffsize - svr->nsb[index]; memcpy(svr->sbuf[index] + svr->nsb[index], buff, n); svr->nsb[index] += n; rtksvrunlock(svr); } /* write solution to output stream -------------------------------------------*/ void writesol(rtksvr_t *svr, int index) { solopt_t solopt = SOLOPT_DEFAULT; unsigned char buff[MAXSOLMSG]; int i; int n; tracet(4, "writesol: index=%d\n", index); for (i = 0; i < 2; i++) { /* output solution */ n = outsols(buff, &svr->rtk.sol, svr->rtk.rb, svr->solopt + i); strwrite(svr->stream + i + 3, buff, n); /* save output buffer */ saveoutbuf(svr, buff, n, i); /* output extended solution */ n = outsolexs(buff, &svr->rtk.sol, svr->rtk.ssat, svr->solopt + i); strwrite(svr->stream + i + 3, buff, n); /* save output buffer */ saveoutbuf(svr, buff, n, i); } /* output solution to monitor port */ if (svr->moni) { n = outsols(buff, &svr->rtk.sol, svr->rtk.rb, &solopt); strwrite(svr->moni, buff, n); } /* save solution buffer */ if (svr->nsol < MAXSOLBUF) { rtksvrlock(svr); svr->solbuf[svr->nsol++] = svr->rtk.sol; rtksvrunlock(svr); } } /* update navigation data ----------------------------------------------------*/ void updatenav(nav_t *nav) { int i; int j; for (i = 0; i < MAXSAT; i++) { for (j = 0; j < NFREQ; j++) { nav->lam[i][j] = satwavelen(i + 1, j, nav); } } } /* update glonass frequency channel number in raw data struct ----------------*/ void updatefcn(rtksvr_t *svr) { int i; int j; int sat; int frq; for (i = 0; i < MAXPRNGLO; i++) { sat = satno(SYS_GLO, i + 1); for (j = 0, frq = -999; j < 3; j++) { if (svr->raw[j].nav.geph[i].sat != sat) { continue; } frq = svr->raw[j].nav.geph[i].frq; } if (frq < -7 || frq > 6) { continue; } for (j = 0; j < 3; j++) { if (svr->raw[j].nav.geph[i].sat == sat) { continue; } svr->raw[j].nav.geph[i].sat = sat; svr->raw[j].nav.geph[i].frq = frq; } } } /* update rtk server struct --------------------------------------------------*/ void updatesvr(rtksvr_t *svr, int ret, obs_t *obs, nav_t *nav, int sat, sbsmsg_t *sbsmsg, int index, int iobs) { eph_t *eph1; eph_t *eph2; eph_t *eph3; geph_t *geph1; geph_t *geph2; geph_t *geph3; // gtime_t tof; double pos[3]; double del[3] = {0}; double dr[3]; int i; int n = 0; int prn; int sbssat = svr->rtk.opt.sbassatsel; int sys; int iode; tracet(4, "updatesvr: ret=%d sat=%2d index=%d\n", ret, sat, index); if (ret == 1) { /* observation data */ if (iobs < MAXOBSBUF) { for (i = 0; i < obs->n; i++) { if (svr->rtk.opt.exsats[obs->data[i].sat - 1] == 1 || !(satsys(obs->data[i].sat, nullptr) & svr->rtk.opt.navsys)) { continue; } svr->obs[index][iobs].data[n] = obs->data[i]; svr->obs[index][iobs].data[n++].rcv = index + 1; } svr->obs[index][iobs].n = n; sortobs(&svr->obs[index][iobs]); } svr->nmsg[index][0]++; } else if (ret == 2) { /* ephemeris */ if (satsys(sat, &prn) != SYS_GLO) { if (!svr->navsel || svr->navsel == index + 1) { eph1 = nav->eph + sat - 1; eph2 = svr->nav.eph + sat - 1; eph3 = svr->nav.eph + sat - 1 + MAXSAT; if (eph2->ttr.time == 0 || (eph1->iode != eph3->iode && eph1->iode != eph2->iode) || (timediff(eph1->toe, eph3->toe) != 0.0 && timediff(eph1->toe, eph2->toe) != 0.0)) { *eph3 = *eph2; *eph2 = *eph1; updatenav(&svr->nav); } } svr->nmsg[index][1]++; } else { if (!svr->navsel || svr->navsel == index + 1) { geph1 = nav->geph + prn - 1; geph2 = svr->nav.geph + prn - 1; geph3 = svr->nav.geph + prn - 1 + MAXPRNGLO; if (geph2->tof.time == 0 || (geph1->iode != geph3->iode && geph1->iode != geph2->iode)) { *geph3 = *geph2; *geph2 = *geph1; updatenav(&svr->nav); updatefcn(svr); } } svr->nmsg[index][6]++; } } else if (ret == 3) { /* sbas message */ if (sbsmsg && (sbssat == sbsmsg->prn || sbssat == 0)) { if (svr->nsbs < MAXSBSMSG) { svr->sbsmsg[svr->nsbs++] = *sbsmsg; } else { for (i = 0; i < MAXSBSMSG - 1; i++) { svr->sbsmsg[i] = svr->sbsmsg[i + 1]; } svr->sbsmsg[i] = *sbsmsg; } sbsupdatecorr(sbsmsg, &svr->nav); } svr->nmsg[index][3]++; } else if (ret == 9) { /* ion/utc parameters */ if (svr->navsel == index || svr->navsel >= 3) { for (i = 0; i < 8; i++) { svr->nav.ion_gps[i] = nav->ion_gps[i]; } for (i = 0; i < 4; i++) { svr->nav.utc_gps[i] = nav->utc_gps[i]; } for (i = 0; i < 4; i++) { svr->nav.ion_gal[i] = nav->ion_gal[i]; } for (i = 0; i < 4; i++) { svr->nav.utc_gal[i] = nav->utc_gal[i]; } for (i = 0; i < 8; i++) { svr->nav.ion_qzs[i] = nav->ion_qzs[i]; } for (i = 0; i < 4; i++) { svr->nav.utc_qzs[i] = nav->utc_qzs[i]; } svr->nav.leaps = nav->leaps; } svr->nmsg[index][2]++; } else if (ret == 5) { /* antenna position parameters */ if (svr->rtk.opt.refpos == 4 && index == 1) { for (i = 0; i < 3; i++) { svr->rtk.rb[i] = svr->rtcm[1].sta.pos[i]; } /* antenna delta */ ecef2pos(svr->rtk.rb, pos); if (svr->rtcm[1].sta.deltype) { /* xyz */ del[2] = svr->rtcm[1].sta.hgt; enu2ecef(pos, del, dr); for (i = 0; i < 3; i++) { svr->rtk.rb[i] += svr->rtcm[1].sta.del[i] + dr[i]; } } else { /* enu */ enu2ecef(pos, svr->rtcm[1].sta.del, dr); for (i = 0; i < 3; i++) { svr->rtk.rb[i] += dr[i]; } } } svr->nmsg[index][4]++; } else if (ret == 7) { /* dgps correction */ svr->nmsg[index][5]++; } else if (ret == 10) { /* ssr message */ for (i = 0; i < MAXSAT; i++) { if (!svr->rtcm[index].ssr[i].update) { continue; } svr->rtcm[index].ssr[i].update = 0; iode = svr->rtcm[index].ssr[i].iode; sys = satsys(i + 1, &prn); /* check corresponding ephemeris exists */ if (sys == SYS_GPS || sys == SYS_GAL || sys == SYS_QZS) { if (svr->nav.eph[i].iode != iode && svr->nav.eph[i + MAXSAT].iode != iode) { continue; } } else if (sys == SYS_GLO) { if (svr->nav.geph[prn - 1].iode != iode && svr->nav.geph[prn - 1 + MAXPRNGLO].iode != iode) { continue; } } svr->nav.ssr[i] = svr->rtcm[index].ssr[i]; } svr->nmsg[index][7]++; } else if (ret == 31) { /* lex message */ // lexupdatecorr(&svr->raw[index].lexmsg, &svr->nav, &tof); svr->nmsg[index][8]++; } else if (ret == -1) { /* error */ svr->nmsg[index][9]++; } } /* decode receiver raw/rtcm data ---------------------------------------------*/ int decoderaw(rtksvr_t *svr, int index) { obs_t *obs; nav_t *nav; sbsmsg_t *sbsmsg = nullptr; int i; int ret = 0; int sat; int fobs = 0; tracet(4, "decoderaw: index=%d\n", index); rtksvrlock(svr); for (i = 0; i < svr->nb[index]; i++) { /* input rtcm/receiver raw data from stream */ if (svr->format[index] == STRFMT_RTCM2) { ret = input_rtcm2(svr->rtcm + index, svr->buff[index][i]); obs = &svr->rtcm[index].obs; nav = &svr->rtcm[index].nav; sat = svr->rtcm[index].ephsat; } else if (svr->format[index] == STRFMT_RTCM3) { ret = input_rtcm3(svr->rtcm + index, svr->buff[index][i]); obs = &svr->rtcm[index].obs; nav = &svr->rtcm[index].nav; sat = svr->rtcm[index].ephsat; } else { // Disabled !! // ret = input_raw(svr->raw+index, svr->format[index], svr->buff[index][i]); obs = &svr->raw[index].obs; nav = &svr->raw[index].nav; sat = svr->raw[index].ephsat; sbsmsg = &svr->raw[index].sbsmsg; } #if 0 /* record for receiving tick */ if (ret == 1) { trace(0, "%d %10d T=%s NS=%2d\n", index, tickget(), time_str(obs->data[0].time, 0), obs->n); } #endif /* update rtk server */ if (ret > 0) { updatesvr(svr, ret, obs, nav, sat, sbsmsg, index, fobs); } /* observation data received */ if (ret == 1) { if (fobs < MAXOBSBUF) { fobs++; } else { svr->prcout++; } } } svr->nb[index] = 0; rtksvrunlock(svr); return fobs; } /* decode download file ------------------------------------------------------*/ void decodefile(rtksvr_t *svr, int index) { nav_t nav{}; char file[1024]; int nb; tracet(4, "decodefile: index=%d\n", index); rtksvrlock(svr); /* check file path completed */ if ((nb = svr->nb[index]) <= 2 || svr->buff[index][nb - 2] != '\r' || svr->buff[index][nb - 1] != '\n') { rtksvrunlock(svr); return; } strncpy(file, reinterpret_cast(svr->buff[index]), nb - 2); file[nb - 2] = '\0'; svr->nb[index] = 0; rtksvrunlock(svr); if (svr->format[index] == STRFMT_SP3) { /* precise ephemeris */ /* read sp3 precise ephemeris */ readsp3(file, &nav, 0); if (nav.ne <= 0) { tracet(1, "sp3 file read error: %s\n", file); return; } /* update precise ephemeris */ rtksvrlock(svr); if (svr->nav.peph) { free(svr->nav.peph); } svr->nav.ne = svr->nav.nemax = nav.ne; svr->nav.peph = nav.peph; svr->ftime[index] = utc2gpst(timeget()); std::strncpy(svr->files[index], file, MAXSTRPATH); rtksvrunlock(svr); } else if (svr->format[index] == STRFMT_RNXCLK) { /* precise clock */ /* read rinex clock */ // Disabled!! if (true /*readrnxc(file, &nav)<=0 */) { tracet(1, "rinex clock file read error: %s\n", file); return; } /* update precise clock */ rtksvrlock(svr); if (svr->nav.pclk) { free(svr->nav.pclk); } svr->nav.nc = svr->nav.ncmax = nav.nc; svr->nav.pclk = nav.pclk; svr->ftime[index] = utc2gpst(timeget()); std::strncpy(svr->files[index], file, MAXSTRPATH); rtksvrunlock(svr); } } /* rtk server thread ---------------------------------------------------------*/ void *rtksvrthread(void *arg) { auto *svr = static_cast(arg); obs_t obs; obsd_t data[MAXOBS * 2]; double tt; unsigned int tick; unsigned int ticknmea; unsigned char *p; unsigned char *q; int i; int j; int n; int fobs[3] = {0}; int cycle; int cputime; 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, static_cast(q[0]) - static_cast(p[0]))) <= 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 = static_cast(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 (static_cast(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 && static_cast(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_rtk(svr->rtk.sol.rr, 3) > 0.0) { strsendnmea(svr->stream + 1, svr->rtk.sol.rr); } } ticknmea = tick; } if ((cputime = static_cast(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] = nullptr; free(svr->pbuf[i]); svr->pbuf[i] = nullptr; // 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] = nullptr; } return nullptr; } /* initialize rtk server ------------------------------------------------------- * initialize rtk server * args : rtksvr_t *svr IO rtk server * return : status (0:error, 1:ok) *-----------------------------------------------------------------------------*/ int rtksvrinit(rtksvr_t *svr) { gtime_t time0 = {0, 0.0}; sol_t sol0 = {{0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, '0', '0', '0', 0, 0, 0}; eph_t eph0 = {0, -1, -1, 0, 0, 0, 0, 0, {0, 0.0}, {0, 0.0}, {0, 0.0}, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, {0.0}, {0.0}, 0.0, 0.0}; geph_t geph0 = {0, -1, 0, 0, 0, 0, {0, 0.0}, {0, 0.0}, {0.0}, {0.0}, {0.0}, 0.0, 0.0, 0.0}; seph_t seph0 = {0, {0, 0.0}, {0, 0.0}, 0, 0, {0.0}, {0.0}, {0.0}, 0.0, 0.0}; int i; int j; tracet(3, "rtksvrinit:\n"); svr->state = svr->cycle = svr->nmeacycle = svr->nmeareq = 0; for (i = 0; i < 3; i++) { svr->nmeapos[i] = 0.0; } svr->buffsize = 0; for (i = 0; i < 3; i++) { svr->format[i] = 0; } for (i = 0; i < 2; i++) { svr->solopt[i] = SOLOPT_DEFAULT; } svr->navsel = svr->nsbs = svr->nsol = 0; rtkinit(&svr->rtk, &PRCOPT_DEFAULT); for (i = 0; i < 3; i++) { svr->nb[i] = 0; } for (i = 0; i < 2; i++) { svr->nsb[i] = 0; } for (i = 0; i < 3; i++) { svr->npb[i] = 0; } for (i = 0; i < 3; i++) { svr->buff[i] = nullptr; } for (i = 0; i < 2; i++) { svr->sbuf[i] = nullptr; } for (i = 0; i < 3; i++) { svr->pbuf[i] = nullptr; } for (i = 0; i < MAXSOLBUF; i++) { svr->solbuf[i] = sol0; } for (i = 0; i < 3; i++) { for (j = 0; j < 10; j++) { svr->nmsg[i][j] = 0; } } for (i = 0; i < 3; i++) { svr->ftime[i] = time0; } for (i = 0; i < 3; i++) { svr->files[i][0] = '\0'; } svr->moni = nullptr; svr->tick = 0; svr->thread = 0; // NOLINT svr->cputime = svr->prcout = 0; if (!(svr->nav.eph = static_cast(malloc(sizeof(eph_t) * MAXSAT * 2))) || !(svr->nav.geph = static_cast(malloc(sizeof(geph_t) * NSATGLO * 2))) || !(svr->nav.seph = static_cast(malloc(sizeof(seph_t) * NSATSBS * 2)))) { tracet(1, "rtksvrinit: malloc error\n"); return 0; } for (i = 0; i < MAXSAT * 2; i++) { svr->nav.eph[i] = eph0; } for (i = 0; i < NSATGLO * 2; i++) { svr->nav.geph[i] = geph0; } for (i = 0; i < NSATSBS * 2; i++) { svr->nav.seph[i] = seph0; } svr->nav.n = MAXSAT * 2; svr->nav.ng = NSATGLO * 2; svr->nav.ns = NSATSBS * 2; for (i = 0; i < 3; i++) { for (j = 0; j < MAXOBSBUF; j++) { if (!(svr->obs[i][j].data = static_cast(malloc(sizeof(obsd_t) * MAXOBS)))) { tracet(1, "rtksvrinit: malloc error\n"); return 0; } } } for (i = 0; i < 3; i++) { memset(svr->raw + i, 0, sizeof(raw_t)); memset(svr->rtcm + i, 0, sizeof(rtcm_t)); } for (i = 0; i < MAXSTRRTK; i++) { strinit(svr->stream + i); } initlock(&svr->lock); return 1; } /* free rtk server ------------------------------------------------------------- * free rtk server * args : rtksvr_t *svr IO rtk server * return : none *-----------------------------------------------------------------------------*/ void rtksvrfree(rtksvr_t *svr) { int i; int j; free(svr->nav.eph); free(svr->nav.geph); free(svr->nav.seph); for (i = 0; i < 3; i++) { for (j = 0; j < MAXOBSBUF; j++) { free(svr->obs[i][j].data); } } } /* lock/unlock rtk server ------------------------------------------------------ * lock/unlock rtk server * args : rtksvr_t *svr IO rtk server * return : status (1:ok 0:error) *-----------------------------------------------------------------------------*/ void rtksvrlock(rtksvr_t *svr) { rtk_lock(&svr->lock); } void rtksvrunlock(rtksvr_t *svr) { rtk_unlock(&svr->lock); } /* start rtk server ------------------------------------------------------------ * start rtk server thread * args : rtksvr_t *svr IO rtk server * int cycle I server cycle (ms) * int buffsize I input buffer size (bytes) * int *strs I stream types (STR_???) * types[0]=input stream rover * types[1]=input stream base station * types[2]=input stream correction * types[3]=output stream solution 1 * types[4]=output stream solution 2 * types[5]=log stream rover * types[6]=log stream base station * types[7]=log stream correction * char *paths I input stream paths * int *format I input stream formats (STRFMT_???) * format[0]=input stream rover * format[1]=input stream base station * format[2]=input stream correction * int navsel I navigation message select * (0:rover, 1:base, 2:ephem, 3:all) * char **cmds I input stream start commands * cmds[0]=input stream rover (NULL: no command) * cmds[1]=input stream base (NULL: no command) * cmds[2]=input stream corr (NULL: no command) * char **rcvopts I receiver options * rcvopt[0]=receiver option rover * rcvopt[1]=receiver option base * rcvopt[2]=receiver option corr * int nmeacycle I nmea request cycle (ms) (0:no request) * int nmeareq I nmea request type (0:no, 1:base pos, 2:single sol) * double *nmeapos I transmitted nmea position (ecef) (m) * prcopt_t *prcopt I rtk processing options * solopt_t *solopt I solution options * solopt[0]=solution 1 options * solopt[1]=solution 2 options * stream_t *moni I monitor stream (NULL: not used) * return : status (1:ok 0:error) *-----------------------------------------------------------------------------*/ int rtksvrstart(rtksvr_t *svr, int cycle, int buffsize, int *strs, char **paths, const int *formats, int navsel, char **cmds, char **rcvopts, int nmeacycle, int nmeareq, const double *nmeapos, prcopt_t *prcopt, solopt_t *solopt, stream_t *moni) { gtime_t time; gtime_t time0 = {0, 0.0}; int i; int j; int rw; tracet(3, "rtksvrstart: cycle=%d buffsize=%d navsel=%d nmeacycle=%d nmeareq=%d\n", cycle, buffsize, navsel, nmeacycle, nmeareq); if (svr->state) { return 0; } strinitcom(); svr->cycle = cycle > 1 ? cycle : 1; svr->nmeacycle = nmeacycle > 1000 ? nmeacycle : 1000; svr->nmeareq = nmeareq; for (i = 0; i < 3; i++) { svr->nmeapos[i] = nmeapos[i]; } svr->buffsize = buffsize > 4096 ? buffsize : 4096; for (i = 0; i < 3; i++) { svr->format[i] = formats[i]; } svr->navsel = navsel; svr->nsbs = 0; svr->nsol = 0; svr->prcout = 0; rtkfree(&svr->rtk); rtkinit(&svr->rtk, prcopt); for (i = 0; i < 3; i++) { /* input/log streams */ svr->nb[i] = svr->npb[i] = 0; if (!(svr->buff[i] = static_cast(malloc(buffsize))) || !(svr->pbuf[i] = static_cast(malloc(buffsize)))) { tracet(1, "rtksvrstart: malloc error\n"); return 0; } for (j = 0; j < 10; j++) { svr->nmsg[i][j] = 0; } for (j = 0; j < MAXOBSBUF; j++) { svr->obs[i][j].n = 0; } /* initialize receiver raw and rtcm control */ // init_raw (svr->raw +i); init_rtcm(svr->rtcm + i); /* set receiver and rtcm option */ if (strlen(rcvopts[i]) < 256) { std::strncpy(svr->raw[i].opt, rcvopts[i], 256); svr->raw[i].opt[255] = '\0'; } if (strlen(rcvopts[i]) < 256) { std::strncpy(svr->rtcm[i].opt, rcvopts[i], 256); svr->rtcm[i].opt[255] = '\0'; } /* connect dgps corrections */ svr->rtcm[i].dgps = svr->nav.dgps; } for (i = 0; i < 2; i++) { /* output peek buffer */ if (!(svr->sbuf[i] = static_cast(malloc(buffsize)))) { tracet(1, "rtksvrstart: malloc error\n"); return 0; } } /* set solution options */ for (i = 0; i < 2; i++) { svr->solopt[i] = solopt[i]; } /* set base station position */ for (i = 0; i < 6; i++) { svr->rtk.rb[i] = i < 3 ? prcopt->rb[i] : 0.0; } /* update navigation data */ for (i = 0; i < MAXSAT * 2; i++) { svr->nav.eph[i].ttr = time0; } for (i = 0; i < NSATGLO * 2; i++) { svr->nav.geph[i].tof = time0; } for (i = 0; i < NSATSBS * 2; i++) { svr->nav.seph[i].tof = time0; } updatenav(&svr->nav); /* set monitor stream */ svr->moni = moni; /* open input streams */ for (i = 0; i < 8; i++) { rw = i < 3 ? STR_MODE_R : STR_MODE_W; if (strs[i] != STR_FILE) { rw |= STR_MODE_W; } if (!stropen(svr->stream + i, strs[i], rw, paths[i])) { for (i--; i >= 0; i--) { strclose(svr->stream + i); } return 0; } /* set initial time for rtcm and raw */ if (i < 3) { time = utc2gpst(timeget()); svr->raw[i].time = strs[i] == STR_FILE ? strgettime(svr->stream + i) : time; svr->rtcm[i].time = strs[i] == STR_FILE ? strgettime(svr->stream + i) : time; } } /* sync input streams */ strsync(svr->stream, svr->stream + 1); strsync(svr->stream, svr->stream + 2); /* write start commands to input streams */ for (i = 0; i < 3; i++) { if (cmds[i]) { strsendcmd(svr->stream + i, cmds[i]); } } /* write solution header to solution streams */ for (i = 3; i < 5; i++) { writesolhead(svr->stream + i, svr->solopt + i - 3); } /* create rtk server thread */ if (pthread_create(&svr->thread, nullptr, rtksvrthread, svr)) { for (i = 0; i < MAXSTRRTK; i++) { strclose(svr->stream + i); } return 0; } return 1; } /* stop rtk server ------------------------------------------------------------- * start rtk server thread * args : rtksvr_t *svr IO rtk server * char **cmds I input stream stop commands * cmds[0]=input stream rover (NULL: no command) * cmds[1]=input stream base (NULL: no command) * cmds[2]=input stream ephem (NULL: no command) * return : none *-----------------------------------------------------------------------------*/ void rtksvrstop(rtksvr_t *svr, char **cmds) { int i; tracet(3, "rtksvrstop:\n"); /* write stop commands to input streams */ rtksvrlock(svr); for (i = 0; i < 3; i++) { if (cmds[i]) { strsendcmd(svr->stream + i, cmds[i]); } } rtksvrunlock(svr); /* stop rtk server */ svr->state = 0; /* free rtk server thread */ pthread_join(svr->thread, nullptr); } /* open output/log stream ------------------------------------------------------ * open output/log stream * args : rtksvr_t *svr IO rtk server * int index I output/log stream index * (3:solution 1, 4:solution 2, 5:log rover, * 6:log base station, 7:log correction) * int str I output/log stream types (STR_???) * char *path I output/log stream path * solopt_t *solopt I solution options * return : status (1:ok 0:error) *-----------------------------------------------------------------------------*/ int rtksvropenstr(rtksvr_t *svr, int index, int str, const char *path, const solopt_t *solopt) { tracet(3, "rtksvropenstr: index=%d str=%d path=%s\n", index, str, path); if (index < 3 || index > 7 || !svr->state) { return 0; } rtksvrlock(svr); if (svr->stream[index].state > 0) { rtksvrunlock(svr); return 0; } if (!stropen(svr->stream + index, str, STR_MODE_W, path)) { tracet(2, "stream open error: index=%d\n", index); rtksvrunlock(svr); return 0; } if (index <= 4) { svr->solopt[index - 3] = *solopt; /* write solution header to solution stream */ writesolhead(svr->stream + index, svr->solopt + index - 3); } rtksvrunlock(svr); return 1; } /* close output/log stream ----------------------------------------------------- * close output/log stream * args : rtksvr_t *svr IO rtk server * int index I output/log stream index * (3:solution 1, 4:solution 2, 5:log rover, * 6:log base station, 7:log correction) * return : none *-----------------------------------------------------------------------------*/ void rtksvrclosestr(rtksvr_t *svr, int index) { tracet(3, "rtksvrclosestr: index=%d\n", index); if (index < 3 || index > 7 || !svr->state) { return; } rtksvrlock(svr); strclose(svr->stream + index); rtksvrunlock(svr); } /* get observation data status ------------------------------------------------- * get current observation data status * args : rtksvr_t *svr I rtk server * int rcv I receiver (0:rover, 1:base, 2:ephem) * gtime_t *time O time of observation data * int *sat O satellite prn numbers * double *az O satellite azimuth angles (rad) * double *el O satellite elevation angles (rad) * int **snr O satellite snr for each freq (dBHz) * snr[i][j] = sat i freq j snr * int *vsat O valid satellite flag * return : number of satellites *-----------------------------------------------------------------------------*/ int rtksvrostat(rtksvr_t *svr, int rcv, gtime_t *time, int *sat, double *az, double *el, int **snr, int *vsat) { int i; int j; int ns; tracet(4, "rtksvrostat: rcv=%d\n", rcv); if (!svr->state) { return 0; } rtksvrlock(svr); ns = svr->obs[rcv][0].n; if (ns > 0) { *time = svr->obs[rcv][0].data[0].time; } for (i = 0; i < ns; i++) { sat[i] = svr->obs[rcv][0].data[i].sat; az[i] = svr->rtk.ssat[sat[i] - 1].azel[0]; el[i] = svr->rtk.ssat[sat[i] - 1].azel[1]; for (j = 0; j < NFREQ; j++) { snr[i][j] = static_cast(svr->obs[rcv][0].data[i].SNR[j] * 0.25); } if (svr->rtk.sol.stat == SOLQ_NONE || svr->rtk.sol.stat == SOLQ_SINGLE) { vsat[i] = svr->rtk.ssat[sat[i] - 1].vs; } else { vsat[i] = svr->rtk.ssat[sat[i] - 1].vsat[0]; } } rtksvrunlock(svr); return ns; } /* get stream status ----------------------------------------------------------- * get current stream status * args : rtksvr_t *svr I rtk server * int *sstat O status of streams * char *msg O status messages * return : none *-----------------------------------------------------------------------------*/ void rtksvrsstat(rtksvr_t *svr, int *sstat, char *msg) { int i; char s[MAXSTRMSG]; char *p = msg; tracet(4, "rtksvrsstat:\n"); rtksvrlock(svr); for (i = 0; i < MAXSTRRTK; i++) { sstat[i] = strstat(svr->stream + i, s); if (*s) { p += std::snprintf(p, MAXSTRMSG, "(%d) %s ", i + 1, s); } } rtksvrunlock(svr); }