gps/gps_qemu.c - device/generic/goldfish - Git at Google

 /*
  * Copyright (C) 2010 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 /* this implements a GPS hardware library for the Android emulator.
  * the following code should be built as a shared library that will be
  * placed into /system/lib/hw/gps.goldfish.so
  *
  * it will be loaded by the code in hardware/libhardware/hardware.c
  * which is itself called from android_location_GpsLocationProvider.cpp
  */


 #include <errno.h>
 #include <pthread.h>
 #include <fcntl.h>
 #include <sys/epoll.h>
 #include <math.h>
 #include <time.h>

 #define  LOG_TAG  "gps_qemu"
 #include <cutils/log.h>
 #include <cutils/sockets.h>
 #include <hardware/gps.h>
 #include <hardware/qemud.h>

 /* the name of the qemud-controlled socket */
 #define  QEMU_CHANNEL_NAME  "gps"

 #define  GPS_DEBUG  0

 #if GPS_DEBUG
 #  define  D(...)   ALOGD(__VA_ARGS__)
 #else
 #  define  D(...)   ((void)0)
 #endif

 /*****************************************************************/
 /*****************************************************************/
 /*****                                                       *****/
 /*****       N M E A   T O K E N I Z E R                     *****/
 /*****                                                       *****/
 /*****************************************************************/
 /*****************************************************************/

 typedef struct {
     const char*  p;
     const char*  end;
 } Token;

 #define  MAX_NMEA_TOKENS  16

 typedef struct {
     int     count;
     Token   tokens[ MAX_NMEA_TOKENS ];
 } NmeaTokenizer;

 static int
 nmea_tokenizer_init( NmeaTokenizer*  t, const char*  p, const char*  end )
 {
     int    count = 0;
     char*  q;

     // the initial '$' is optional
     if (p < end && p[0] == '$')
         p += 1;

     // remove trailing newline
     if (end > p && end[-1] == '\n') {
         end -= 1;
         if (end > p && end[-1] == '\r')
             end -= 1;
     }

     // get rid of checksum at the end of the sentecne
     if (end >= p+3 && end[-3] == '*') {
         end -= 3;
     }

     while (p < end) {
         const char*  q = p;

         q = memchr(p, ',', end-p);
         if (q == NULL)
             q = end;

         if (q > p) {
             if (count < MAX_NMEA_TOKENS) {
                 t->tokens[count].p   = p;
                 t->tokens[count].end = q;
                 count += 1;
             }
         }
         if (q < end)
             q += 1;

         p = q;
     }

     t->count = count;
     return count;
 }

 static Token
 nmea_tokenizer_get( NmeaTokenizer*  t, int  index )
 {
     Token  tok;
     static const char*  dummy = "";

     if (index < 0 || index >= t->count) {
         tok.p = tok.end = dummy;
     } else
         tok = t->tokens[index];

     return tok;
 }


 static int
 str2int( const char*  p, const char*  end )
 {
     int   result = 0;
     int   len    = end - p;

     for ( ; len > 0; len--, p++ )
     {
         int  c;

         if (p >= end)
             goto Fail;

         c = *p - '0';
         if ((unsigned)c >= 10)
             goto Fail;

         result = result*10 + c;
     }
     return  result;

 Fail:
     return -1;
 }

 static double
 str2float( const char*  p, const char*  end )
 {
     int   result = 0;
     int   len    = end - p;
     char  temp[16];

     if (len >= (int)sizeof(temp))
         return 0.;

     memcpy( temp, p, len );
     temp[len] = 0;
     return strtod( temp, NULL );
 }

 /*****************************************************************/
 /*****************************************************************/
 /*****                                                       *****/
 /*****       N M E A   P A R S E R                           *****/
 /*****                                                       *****/
 /*****************************************************************/
 /*****************************************************************/

 #define  NMEA_MAX_SIZE  83

 typedef struct {
     int     pos;
     int     overflow;
     int     utc_year;
     int     utc_mon;
     int     utc_day;
     int     utc_diff;
     GpsLocation  fix;
     gps_location_callback  callback;
     char    in[ NMEA_MAX_SIZE+1 ];
 } NmeaReader;


 static void
 nmea_reader_update_utc_diff( NmeaReader*  r )
 {
     time_t         now = time(NULL);
     struct tm      tm_local;
     struct tm      tm_utc;
     long           time_local, time_utc;

     gmtime_r( &now, &tm_utc );
     localtime_r( &now, &tm_local );

     time_local = tm_local.tm_sec +
                  60*(tm_local.tm_min +
                  60*(tm_local.tm_hour +
                  24*(tm_local.tm_yday +
                  365*tm_local.tm_year)));

     time_utc = tm_utc.tm_sec +
                60*(tm_utc.tm_min +
                60*(tm_utc.tm_hour +
                24*(tm_utc.tm_yday +
                365*tm_utc.tm_year)));

     r->utc_diff = time_utc - time_local;
 }


 static void
 nmea_reader_init( NmeaReader*  r )
 {
     memset( r, 0, sizeof(*r) );

     r->pos      = 0;
     r->overflow = 0;
     r->utc_year = -1;
     r->utc_mon  = -1;
     r->utc_day  = -1;
     r->callback = NULL;
     r->fix.size = sizeof(r->fix);

     nmea_reader_update_utc_diff( r );
 }


 static void
 nmea_reader_set_callback( NmeaReader*  r, gps_location_callback  cb )
 {
     r->callback = cb;
     if (cb != NULL && r->fix.flags != 0) {
         D("%s: sending latest fix to new callback", __FUNCTION__);
         r->callback( &r->fix );
         r->fix.flags = 0;
     }
 }


 static int
 nmea_reader_update_time( NmeaReader*  r, Token  tok )
 {
     int        hour, minute;
     double     seconds;
     struct tm  tm;
     time_t     fix_time;

     if (tok.p + 6 > tok.end)
         return -1;

     if (r->utc_year < 0) {
         // no date yet, get current one
         time_t  now = time(NULL);
         gmtime_r( &now, &tm );
         r->utc_year = tm.tm_year + 1900;
         r->utc_mon  = tm.tm_mon + 1;
         r->utc_day  = tm.tm_mday;
     }

     hour    = str2int(tok.p,   tok.p+2);
     minute  = str2int(tok.p+2, tok.p+4);
     seconds = str2float(tok.p+4, tok.end);

     tm.tm_hour  = hour;
     tm.tm_min   = minute;
     tm.tm_sec   = (int) seconds;
     tm.tm_year  = r->utc_year - 1900;
     tm.tm_mon   = r->utc_mon - 1;
     tm.tm_mday  = r->utc_day;
     tm.tm_isdst = -1;

     fix_time = mktime( &tm ) + r->utc_diff;
     r->fix.timestamp = (long long)fix_time * 1000;
     return 0;
 }

 static int
 nmea_reader_update_date( NmeaReader*  r, Token  date, Token  time )
 {
     Token  tok = date;
     int    day, mon, year;

     if (tok.p + 6 != tok.end) {
         D("date not properly formatted: '%.*s'", tok.end-tok.p, tok.p);
         return -1;
     }
     day  = str2int(tok.p, tok.p+2);
     mon  = str2int(tok.p+2, tok.p+4);
     year = str2int(tok.p+4, tok.p+6) + 2000;

     if ((day|mon|year) < 0) {
         D("date not properly formatted: '%.*s'", tok.end-tok.p, tok.p);
         return -1;
     }

     r->utc_year  = year;
     r->utc_mon   = mon;
     r->utc_day   = day;

     return nmea_reader_update_time( r, time );
 }


 static double
 convert_from_hhmm( Token  tok )
 {
     double  val     = str2float(tok.p, tok.end);
     int     degrees = (int)(floor(val) / 100);
     double  minutes = val - degrees*100.;
     double  dcoord  = degrees + minutes / 60.0;
     return dcoord;
 }


 static int
 nmea_reader_update_latlong( NmeaReader*  r,
                             Token        latitude,
                             char         latitudeHemi,
                             Token        longitude,
                             char         longitudeHemi )
 {
     double   lat, lon;
     Token    tok;

     tok = latitude;
     if (tok.p + 6 > tok.end) {
         D("latitude is too short: '%.*s'", tok.end-tok.p, tok.p);
         return -1;
     }
     lat = convert_from_hhmm(tok);
     if (latitudeHemi == 'S')
         lat = -lat;

     tok = longitude;
     if (tok.p + 6 > tok.end) {
         D("longitude is too short: '%.*s'", tok.end-tok.p, tok.p);
         return -1;
     }
     lon = convert_from_hhmm(tok);
     if (longitudeHemi == 'W')
         lon = -lon;

     r->fix.flags    |= GPS_LOCATION_HAS_LAT_LONG;
     r->fix.latitude  = lat;
     r->fix.longitude = lon;
     return 0;
 }


 static int
 nmea_reader_update_altitude( NmeaReader*  r,
                              Token        altitude,
                              Token        units )
 {
     double  alt;
     Token   tok = altitude;

     if (tok.p >= tok.end)
         return -1;

     r->fix.flags   |= GPS_LOCATION_HAS_ALTITUDE;
     r->fix.altitude = str2float(tok.p, tok.end);
     return 0;
 }


 static int
 nmea_reader_update_bearing( NmeaReader*  r,
                             Token        bearing )
 {
     double  alt;
     Token   tok = bearing;

     if (tok.p >= tok.end)
         return -1;

     r->fix.flags   |= GPS_LOCATION_HAS_BEARING;
     r->fix.bearing  = str2float(tok.p, tok.end);
     return 0;
 }


 static int
 nmea_reader_update_speed( NmeaReader*  r,
                           Token        speed )
 {
     double  alt;
     Token   tok = speed;

     if (tok.p >= tok.end)
         return -1;

     r->fix.flags   |= GPS_LOCATION_HAS_SPEED;
     r->fix.speed    = str2float(tok.p, tok.end);
     return 0;
 }

 static int
 nmea_reader_update_accuracy( NmeaReader*  r )
 {
     // Always return 20m accuracy.
     // Possibly parse it from the NMEA sentence in the future.
     r->fix.flags    |= GPS_LOCATION_HAS_ACCURACY;
     r->fix.accuracy = 20;
     return 0;
 }


 static void
 nmea_reader_parse( NmeaReader*  r )
 {
    /* we received a complete sentence, now parse it to generate
     * a new GPS fix...
     */
     NmeaTokenizer  tzer[1];
     Token          tok;

     D("Received: '%.*s'", r->pos, r->in);
     if (r->pos < 9) {
         D("Too short. discarded.");
         return;
     }

     nmea_tokenizer_init(tzer, r->in, r->in + r->pos);
 #if GPS_DEBUG
     {
         int  n;
         D("Found %d tokens", tzer->count);
         for (n = 0; n < tzer->count; n++) {
             Token  tok = nmea_tokenizer_get(tzer,n);
             D("%2d: '%.*s'", n, tok.end-tok.p, tok.p);
         }
     }
 #endif

     tok = nmea_tokenizer_get(tzer, 0);
     if (tok.p + 5 > tok.end) {
         D("sentence id '%.*s' too short, ignored.", tok.end-tok.p, tok.p);
         return;
     }

     // ignore first two characters.
     tok.p += 2;
     if ( !memcmp(tok.p, "GGA", 3) ) {
         // GPS fix
         Token  tok_time          = nmea_tokenizer_get(tzer,1);
         Token  tok_latitude      = nmea_tokenizer_get(tzer,2);
         Token  tok_latitudeHemi  = nmea_tokenizer_get(tzer,3);
         Token  tok_longitude     = nmea_tokenizer_get(tzer,4);
         Token  tok_longitudeHemi = nmea_tokenizer_get(tzer,5);
         Token  tok_altitude      = nmea_tokenizer_get(tzer,9);
         Token  tok_altitudeUnits = nmea_tokenizer_get(tzer,10);

         nmea_reader_update_time(r, tok_time);
         nmea_reader_update_latlong(r, tok_latitude,
                                       tok_latitudeHemi.p[0],
                                       tok_longitude,
                                       tok_longitudeHemi.p[0]);
         nmea_reader_update_altitude(r, tok_altitude, tok_altitudeUnits);

     } else if ( !memcmp(tok.p, "GSA", 3) ) {
         // do something ?
     } else if ( !memcmp(tok.p, "RMC", 3) ) {
         Token  tok_time          = nmea_tokenizer_get(tzer,1);
         Token  tok_fixStatus     = nmea_tokenizer_get(tzer,2);
         Token  tok_latitude      = nmea_tokenizer_get(tzer,3);
         Token  tok_latitudeHemi  = nmea_tokenizer_get(tzer,4);
         Token  tok_longitude     = nmea_tokenizer_get(tzer,5);
         Token  tok_longitudeHemi = nmea_tokenizer_get(tzer,6);
         Token  tok_speed         = nmea_tokenizer_get(tzer,7);
         Token  tok_bearing       = nmea_tokenizer_get(tzer,8);
         Token  tok_date          = nmea_tokenizer_get(tzer,9);

         D("in RMC, fixStatus=%c", tok_fixStatus.p[0]);
         if (tok_fixStatus.p[0] == 'A')
         {
             nmea_reader_update_date( r, tok_date, tok_time );

             nmea_reader_update_latlong( r, tok_latitude,
                                            tok_latitudeHemi.p[0],
                                            tok_longitude,
                                            tok_longitudeHemi.p[0] );

             nmea_reader_update_bearing( r, tok_bearing );
             nmea_reader_update_speed  ( r, tok_speed );
         }
     } else {
         tok.p -= 2;
         D("unknown sentence '%.*s", tok.end-tok.p, tok.p);
     }

     // Always update accuracy
     nmea_reader_update_accuracy( r );

     if (r->fix.flags != 0) {
 #if GPS_DEBUG
         char   temp[256];
         char*  p   = temp;
         char*  end = p + sizeof(temp);
         struct tm   utc;

         p += snprintf( p, end-p, "sending fix" );
         if (r->fix.flags & GPS_LOCATION_HAS_LAT_LONG) {
             p += snprintf(p, end-p, " lat=%g lon=%g", r->fix.latitude, r->fix.longitude);
         }
         if (r->fix.flags & GPS_LOCATION_HAS_ALTITUDE) {
             p += snprintf(p, end-p, " altitude=%g", r->fix.altitude);
         }
         if (r->fix.flags & GPS_LOCATION_HAS_SPEED) {
             p += snprintf(p, end-p, " speed=%g", r->fix.speed);
         }
         if (r->fix.flags & GPS_LOCATION_HAS_BEARING) {
             p += snprintf(p, end-p, " bearing=%g", r->fix.bearing);
         }
         if (r->fix.flags & GPS_LOCATION_HAS_ACCURACY) {
             p += snprintf(p,end-p, " accuracy=%g", r->fix.accuracy);
         }
         gmtime_r( (time_t*) &r->fix.timestamp, &utc );
         p += snprintf(p, end-p, " time=%s", asctime( &utc ) );
         D(temp);
 #endif
         if (r->callback) {
             r->callback( &r->fix );
             r->fix.flags = 0;
         }
         else {
             D("no callback, keeping data until needed !");
         }
     }
 }


 static void
 nmea_reader_addc( NmeaReader*  r, int  c )
 {
     if (r->overflow) {
         r->overflow = (c != '\n');
         return;
     }

     if (r->pos >= (int) sizeof(r->in)-1 ) {
         r->overflow = 1;
         r->pos      = 0;
         return;
     }

     r->in[r->pos] = (char)c;
     r->pos       += 1;

     if (c == '\n') {
         nmea_reader_parse( r );
         r->pos = 0;
     }
 }


 /*****************************************************************/
 /*****************************************************************/
 /*****                                                       *****/
 /*****       C O N N E C T I O N   S T A T E                 *****/
 /*****                                                       *****/
 /*****************************************************************/
 /*****************************************************************/

 /* commands sent to the gps thread */
 enum {
     CMD_QUIT  = 0,
     CMD_START = 1,
     CMD_STOP  = 2
 };


 /* this is the state of our connection to the qemu_gpsd daemon */
 typedef struct {
     int                     init;
     int                     fd;
     GpsCallbacks            callbacks;
     pthread_t               thread;
     int                     control[2];
 } GpsState;

 static GpsState  _gps_state[1];


 static void
 gps_state_done( GpsState*  s )
 {
     // tell the thread to quit, and wait for it
     char   cmd = CMD_QUIT;
     void*  dummy;
     write( s->control[0], &cmd, 1 );
     pthread_join(s->thread, &dummy);

     // close the control socket pair
     close( s->control[0] ); s->control[0] = -1;
     close( s->control[1] ); s->control[1] = -1;

     // close connection to the QEMU GPS daemon
     close( s->fd ); s->fd = -1;
     s->init = 0;
 }


 static void
 gps_state_start( GpsState*  s )
 {
     char  cmd = CMD_START;
     int   ret;

     do { ret=write( s->control[0], &cmd, 1 ); }
     while (ret < 0 && errno == EINTR);

     if (ret != 1)
         D("%s: could not send CMD_START command: ret=%d: %s",
           __FUNCTION__, ret, strerror(errno));
 }


 static void
 gps_state_stop( GpsState*  s )
 {
     char  cmd = CMD_STOP;
     int   ret;

     do { ret=write( s->control[0], &cmd, 1 ); }
     while (ret < 0 && errno == EINTR);

     if (ret != 1)
         D("%s: could not send CMD_STOP command: ret=%d: %s",
           __FUNCTION__, ret, strerror(errno));
 }


 static int
 epoll_register( int  epoll_fd, int  fd )
 {
     struct epoll_event  ev;
     int                 ret, flags;

     /* important: make the fd non-blocking */
     flags = fcntl(fd, F_GETFL);
     fcntl(fd, F_SETFL, flags | O_NONBLOCK);

     ev.events  = EPOLLIN;
     ev.data.fd = fd;
     do {
         ret = epoll_ctl( epoll_fd, EPOLL_CTL_ADD, fd, &ev );
     } while (ret < 0 && errno == EINTR);
     return ret;
 }


 static int
 epoll_deregister( int  epoll_fd, int  fd )
 {
     int  ret;
     do {
         ret = epoll_ctl( epoll_fd, EPOLL_CTL_DEL, fd, NULL );
     } while (ret < 0 && errno == EINTR);
     return ret;
 }

 /* this is the main thread, it waits for commands from gps_state_start/stop and,
  * when started, messages from the QEMU GPS daemon. these are simple NMEA sentences
  * that must be parsed to be converted into GPS fixes sent to the framework
  */
 static void
 gps_state_thread( void*  arg )
 {
     GpsState*   state = (GpsState*) arg;
     NmeaReader  reader[1];
     int         epoll_fd   = epoll_create(2);
     int         started    = 0;
     int         gps_fd     = state->fd;
     int         control_fd = state->control[1];

     nmea_reader_init( reader );

     // register control file descriptors for polling
     epoll_register( epoll_fd, control_fd );
     epoll_register( epoll_fd, gps_fd );

     D("gps thread running");

     // now loop
     for (;;) {
         struct epoll_event   events[2];
         int                  ne, nevents;

         nevents = epoll_wait( epoll_fd, events, 2, -1 );
         if (nevents < 0) {
             if (errno != EINTR)
                 ALOGE("epoll_wait() unexpected error: %s", strerror(errno));
             continue;
         }
         D("gps thread received %d events", nevents);
         for (ne = 0; ne < nevents; ne++) {
             if ((events[ne].events & (EPOLLERR|EPOLLHUP)) != 0) {
                 ALOGE("EPOLLERR or EPOLLHUP after epoll_wait() !?");
                 return;
             }
             if ((events[ne].events & EPOLLIN) != 0) {
                 int  fd = events[ne].data.fd;

                 if (fd == control_fd)
                 {
                     char  cmd = 255;
                     int   ret;
                     D("gps control fd event");
                     do {
                         ret = read( fd, &cmd, 1 );
                     } while (ret < 0 && errno == EINTR);

                     if (cmd == CMD_QUIT) {
                         D("gps thread quitting on demand");
                         return;
                     }
                     else if (cmd == CMD_START) {
                         if (!started) {
                             D("gps thread starting  location_cb=%p", state->callbacks.location_cb);
                             started = 1;
                             nmea_reader_set_callback( reader, state->callbacks.location_cb );
                         }
                     }
                     else if (cmd == CMD_STOP) {
                         if (started) {
                             D("gps thread stopping");
                             started = 0;
                             nmea_reader_set_callback( reader, NULL );
                         }
                     }
                 }
                 else if (fd == gps_fd)
                 {
                     char  buff[32];
                     D("gps fd event");
                     for (;;) {
                         int  nn, ret;

                         ret = read( fd, buff, sizeof(buff) );
                         if (ret < 0) {
                             if (errno == EINTR)
                                 continue;
                             if (errno != EWOULDBLOCK)
                                 ALOGE("error while reading from gps daemon socket: %s:", strerror(errno));
                             break;
                         }
                         D("received %d bytes: %.*s", ret, ret, buff);
                         for (nn = 0; nn < ret; nn++)
                             nmea_reader_addc( reader, buff[nn] );
                     }
                     D("gps fd event end");
                 }
                 else
                 {
                     ALOGE("epoll_wait() returned unkown fd %d ?", fd);
                 }
             }
         }
     }
 }


 static void
 gps_state_init( GpsState*  state, GpsCallbacks* callbacks )
 {
     state->init       = 1;
     state->control[0] = -1;
     state->control[1] = -1;
     state->fd         = -1;

     state->fd = qemud_channel_open(QEMU_CHANNEL_NAME);

     if (state->fd < 0) {
         D("no gps emulation detected");
         return;
     }

     D("gps emulation will read from '%s' qemud channel", QEMU_CHANNEL_NAME );

     if ( socketpair( AF_LOCAL, SOCK_STREAM, 0, state->control ) < 0 ) {
         ALOGE("could not create thread control socket pair: %s", strerror(errno));
         goto Fail;
     }

     state->thread = callbacks->create_thread_cb( "gps_state_thread", gps_state_thread, state );

     if ( !state->thread ) {
         ALOGE("could not create gps thread: %s", strerror(errno));
         goto Fail;
     }

     state->callbacks = *callbacks;

     D("gps state initialized");
     return;

 Fail:
     gps_state_done( state );
 }


 /*****************************************************************/
 /*****************************************************************/
 /*****                                                       *****/
 /*****       I N T E R F A C E                               *****/
 /*****                                                       *****/
 /*****************************************************************/
 /*****************************************************************/


 static int
 qemu_gps_init(GpsCallbacks* callbacks)
 {
     GpsState*  s = _gps_state;

     if (!s->init)
         gps_state_init(s, callbacks);

     if (s->fd < 0)
         return -1;

     return 0;
 }

 static void
 qemu_gps_cleanup(void)
 {
     GpsState*  s = _gps_state;

     if (s->init)
         gps_state_done(s);
 }


 static int
 qemu_gps_start()
 {
     GpsState*  s = _gps_state;

     if (!s->init) {
         D("%s: called with uninitialized state !!", __FUNCTION__);
         return -1;
     }

     D("%s: called", __FUNCTION__);
     gps_state_start(s);
     return 0;
 }


 static int
 qemu_gps_stop()
 {
     GpsState*  s = _gps_state;

     if (!s->init) {
         D("%s: called with uninitialized state !!", __FUNCTION__);
         return -1;
     }

     D("%s: called", __FUNCTION__);
     gps_state_stop(s);
     return 0;
 }


 static int
 qemu_gps_inject_time(GpsUtcTime time, int64_t timeReference, int uncertainty)
 {
     return 0;
 }

 static int
 qemu_gps_inject_location(double latitude, double longitude, float accuracy)
 {
     return 0;
 }

 static void
 qemu_gps_delete_aiding_data(GpsAidingData flags)
 {
 }

 static int qemu_gps_set_position_mode(GpsPositionMode mode, int fix_frequency)
 {
     // FIXME - support fix_frequency
     return 0;
 }

 static const void*
 qemu_gps_get_extension(const char* name)
 {
     // no extensions supported
     return NULL;
 }

 static const GpsInterface  qemuGpsInterface = {
     sizeof(GpsInterface),
     qemu_gps_init,
     qemu_gps_start,
     qemu_gps_stop,
     qemu_gps_cleanup,
     qemu_gps_inject_time,
     qemu_gps_inject_location,
     qemu_gps_delete_aiding_data,
     qemu_gps_set_position_mode,
     qemu_gps_get_extension,
 };

 const GpsInterface* gps__get_gps_interface(struct gps_device_t* dev)
 {
     return &qemuGpsInterface;
 }

 static int open_gps(const struct hw_module_t* module, char const* name,
         struct hw_device_t** device)
 {
     struct gps_device_t *dev = malloc(sizeof(struct gps_device_t));
     memset(dev, 0, sizeof(*dev));

     dev->common.tag = HARDWARE_DEVICE_TAG;
     dev->common.version = 0;
     dev->common.module = (struct hw_module_t*)module;
 //    dev->common.close = (int (*)(struct hw_device_t*))close_lights;
     dev->get_gps_interface = gps__get_gps_interface;

     *device = (struct hw_device_t*)dev;
     return 0;
 }


 static struct hw_module_methods_t gps_module_methods = {
     .open = open_gps
 };

 struct hw_module_t HAL_MODULE_INFO_SYM = {
     .tag = HARDWARE_MODULE_TAG,
     .version_major = 1,
     .version_minor = 0,
     .id = GPS_HARDWARE_MODULE_ID,
     .name = "Goldfish GPS Module",
     .author = "The Android Open Source Project",
     .methods = &gps_module_methods,
 };
	/*
	* Copyright (C) 2010 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	/* this implements a GPS hardware library for the Android emulator.
	* the following code should be built as a shared library that will be
	* placed into /system/lib/hw/gps.goldfish.so
	*
	* it will be loaded by the code in hardware/libhardware/hardware.c
	* which is itself called from android_location_GpsLocationProvider.cpp
	*/


	#include <errno.h>
	#include <pthread.h>
	#include <fcntl.h>
	#include <sys/epoll.h>
	#include <math.h>
	#include <time.h>

	#define LOG_TAG "gps_qemu"
	#include <cutils/log.h>
	#include <cutils/sockets.h>
	#include <hardware/gps.h>
	#include <hardware/qemud.h>

	/* the name of the qemud-controlled socket */
	#define QEMU_CHANNEL_NAME "gps"

	#define GPS_DEBUG 0

	#if GPS_DEBUG
	# define D(...) ALOGD(__VA_ARGS__)
	#else
	# define D(...) ((void)0)
	#endif

	/*****************************************************************/
	/*****************************************************************/
	/*** ***/
	/*** N M E A T O K E N I Z E R ***/
	/*** ***/
	/*****************************************************************/
	/*****************************************************************/

	typedef struct {
	const char* p;
	const char* end;
	} Token;

	#define MAX_NMEA_TOKENS 16

	typedef struct {
	int count;
	Token tokens[ MAX_NMEA_TOKENS ];
	} NmeaTokenizer;

	static int
	nmea_tokenizer_init( NmeaTokenizer* t, const char* p, const char* end )
	{
	int count = 0;
	char* q;

	// the initial '$' is optional
	if (p < end && p[0] == '$')
	p += 1;

	// remove trailing newline
	if (end > p && end[-1] == '\n') {
	end -= 1;
	if (end > p && end[-1] == '\r')
	end -= 1;
	}

	// get rid of checksum at the end of the sentecne
	if (end >= p+3 && end[-3] == '*') {
	end -= 3;
	}

	while (p < end) {
	const char* q = p;

	q = memchr(p, ',', end-p);
	if (q == NULL)
	q = end;

	if (q > p) {
	if (count < MAX_NMEA_TOKENS) {
	t->tokens[count].p = p;
	t->tokens[count].end = q;
	count += 1;
	}
	}
	if (q < end)
	q += 1;

	p = q;
	}

	t->count = count;
	return count;
	}

	static Token
	nmea_tokenizer_get( NmeaTokenizer* t, int index )
	{
	Token tok;
	static const char* dummy = "";

	if (index < 0 \|\| index >= t->count) {
	tok.p = tok.end = dummy;
	} else
	tok = t->tokens[index];

	return tok;
	}


	static int
	str2int( const char* p, const char* end )
	{
	int result = 0;
	int len = end - p;

	for ( ; len > 0; len--, p++ )
	{
	int c;

	if (p >= end)
	goto Fail;

	c = *p - '0';
	if ((unsigned)c >= 10)
	goto Fail;

	result = result*10 + c;
	}
	return result;

	Fail:
	return -1;
	}

	static double
	str2float( const char* p, const char* end )
	{
	int result = 0;
	int len = end - p;
	char temp[16];

	if (len >= (int)sizeof(temp))
	return 0.;

	memcpy( temp, p, len );
	temp[len] = 0;
	return strtod( temp, NULL );
	}

	/*****************************************************************/
	/*****************************************************************/
	/*** ***/
	/*** N M E A P A R S E R ***/
	/*** ***/
	/*****************************************************************/
	/*****************************************************************/

	#define NMEA_MAX_SIZE 83

	typedef struct {
	int pos;
	int overflow;
	int utc_year;
	int utc_mon;
	int utc_day;
	int utc_diff;
	GpsLocation fix;
	gps_location_callback callback;
	char in[ NMEA_MAX_SIZE+1 ];
	} NmeaReader;


	static void
	nmea_reader_update_utc_diff( NmeaReader* r )
	{
	time_t now = time(NULL);
	struct tm tm_local;
	struct tm tm_utc;
	long time_local, time_utc;

	gmtime_r( &now, &tm_utc );
	localtime_r( &now, &tm_local );

	time_local = tm_local.tm_sec +
	60*(tm_local.tm_min +
	60*(tm_local.tm_hour +
	24*(tm_local.tm_yday +
	365*tm_local.tm_year)));

	time_utc = tm_utc.tm_sec +
	60*(tm_utc.tm_min +
	60*(tm_utc.tm_hour +
	24*(tm_utc.tm_yday +
	365*tm_utc.tm_year)));

	r->utc_diff = time_utc - time_local;
	}


	static void
	nmea_reader_init( NmeaReader* r )
	{
	memset( r, 0, sizeof(*r) );

	r->pos = 0;
	r->overflow = 0;
	r->utc_year = -1;
	r->utc_mon = -1;
	r->utc_day = -1;
	r->callback = NULL;
	r->fix.size = sizeof(r->fix);

	nmea_reader_update_utc_diff( r );
	}


	static void
	nmea_reader_set_callback( NmeaReader* r, gps_location_callback cb )
	{
	r->callback = cb;
	if (cb != NULL && r->fix.flags != 0) {
	D("%s: sending latest fix to new callback", __FUNCTION__);
	r->callback( &r->fix );
	r->fix.flags = 0;
	}
	}


	static int
	nmea_reader_update_time( NmeaReader* r, Token tok )
	{
	int hour, minute;
	double seconds;
	struct tm tm;
	time_t fix_time;

	if (tok.p + 6 > tok.end)
	return -1;

	if (r->utc_year < 0) {
	// no date yet, get current one
	time_t now = time(NULL);
	gmtime_r( &now, &tm );
	r->utc_year = tm.tm_year + 1900;
	r->utc_mon = tm.tm_mon + 1;
	r->utc_day = tm.tm_mday;
	}

	hour = str2int(tok.p, tok.p+2);
	minute = str2int(tok.p+2, tok.p+4);
	seconds = str2float(tok.p+4, tok.end);

	tm.tm_hour = hour;
	tm.tm_min = minute;
	tm.tm_sec = (int) seconds;
	tm.tm_year = r->utc_year - 1900;
	tm.tm_mon = r->utc_mon - 1;
	tm.tm_mday = r->utc_day;
	tm.tm_isdst = -1;

	fix_time = mktime( &tm ) + r->utc_diff;
	r->fix.timestamp = (long long)fix_time * 1000;
	return 0;
	}

	static int
	nmea_reader_update_date( NmeaReader* r, Token date, Token time )
	{
	Token tok = date;
	int day, mon, year;

	if (tok.p + 6 != tok.end) {
	D("date not properly formatted: '%.*s'", tok.end-tok.p, tok.p);
	return -1;
	}
	day = str2int(tok.p, tok.p+2);
	mon = str2int(tok.p+2, tok.p+4);
	year = str2int(tok.p+4, tok.p+6) + 2000;

	if ((day\|mon\|year) < 0) {
	D("date not properly formatted: '%.*s'", tok.end-tok.p, tok.p);
	return -1;
	}

	r->utc_year = year;
	r->utc_mon = mon;
	r->utc_day = day;

	return nmea_reader_update_time( r, time );
	}


	static double
	convert_from_hhmm( Token tok )
	{
	double val = str2float(tok.p, tok.end);
	int degrees = (int)(floor(val) / 100);
	double minutes = val - degrees*100.;
	double dcoord = degrees + minutes / 60.0;
	return dcoord;
	}


	static int
	nmea_reader_update_latlong( NmeaReader* r,
	Token latitude,
	char latitudeHemi,
	Token longitude,
	char longitudeHemi )
	{
	double lat, lon;
	Token tok;

	tok = latitude;
	if (tok.p + 6 > tok.end) {
	D("latitude is too short: '%.*s'", tok.end-tok.p, tok.p);
	return -1;
	}
	lat = convert_from_hhmm(tok);
	if (latitudeHemi == 'S')
	lat = -lat;

	tok = longitude;
	if (tok.p + 6 > tok.end) {
	D("longitude is too short: '%.*s'", tok.end-tok.p, tok.p);
	return -1;
	}
	lon = convert_from_hhmm(tok);
	if (longitudeHemi == 'W')
	lon = -lon;

	r->fix.flags \|= GPS_LOCATION_HAS_LAT_LONG;
	r->fix.latitude = lat;
	r->fix.longitude = lon;
	return 0;
	}


	static int
	nmea_reader_update_altitude( NmeaReader* r,
	Token altitude,
	Token units )
	{
	double alt;
	Token tok = altitude;

	if (tok.p >= tok.end)
	return -1;

	r->fix.flags \|= GPS_LOCATION_HAS_ALTITUDE;
	r->fix.altitude = str2float(tok.p, tok.end);
	return 0;
	}


	static int
	nmea_reader_update_bearing( NmeaReader* r,
	Token bearing )
	{
	double alt;
	Token tok = bearing;

	if (tok.p >= tok.end)
	return -1;

	r->fix.flags \|= GPS_LOCATION_HAS_BEARING;
	r->fix.bearing = str2float(tok.p, tok.end);
	return 0;
	}


	static int
	nmea_reader_update_speed( NmeaReader* r,
	Token speed )
	{
	double alt;
	Token tok = speed;

	if (tok.p >= tok.end)
	return -1;

	r->fix.flags \|= GPS_LOCATION_HAS_SPEED;
	r->fix.speed = str2float(tok.p, tok.end);
	return 0;
	}

	static int
	nmea_reader_update_accuracy( NmeaReader* r )
	{
	// Always return 20m accuracy.
	// Possibly parse it from the NMEA sentence in the future.
	r->fix.flags \|= GPS_LOCATION_HAS_ACCURACY;
	r->fix.accuracy = 20;
	return 0;
	}


	static void
	nmea_reader_parse( NmeaReader* r )
	{
	/* we received a complete sentence, now parse it to generate
	* a new GPS fix...
	*/
	NmeaTokenizer tzer[1];
	Token tok;

	D("Received: '%.*s'", r->pos, r->in);
	if (r->pos < 9) {
	D("Too short. discarded.");
	return;
	}

	nmea_tokenizer_init(tzer, r->in, r->in + r->pos);
	#if GPS_DEBUG
	{
	int n;
	D("Found %d tokens", tzer->count);
	for (n = 0; n < tzer->count; n++) {
	Token tok = nmea_tokenizer_get(tzer,n);
	D("%2d: '%.*s'", n, tok.end-tok.p, tok.p);
	}
	}
	#endif

	tok = nmea_tokenizer_get(tzer, 0);
	if (tok.p + 5 > tok.end) {
	D("sentence id '%.*s' too short, ignored.", tok.end-tok.p, tok.p);
	return;
	}

	// ignore first two characters.
	tok.p += 2;
	if ( !memcmp(tok.p, "GGA", 3) ) {
	// GPS fix
	Token tok_time = nmea_tokenizer_get(tzer,1);
	Token tok_latitude = nmea_tokenizer_get(tzer,2);
	Token tok_latitudeHemi = nmea_tokenizer_get(tzer,3);
	Token tok_longitude = nmea_tokenizer_get(tzer,4);
	Token tok_longitudeHemi = nmea_tokenizer_get(tzer,5);
	Token tok_altitude = nmea_tokenizer_get(tzer,9);
	Token tok_altitudeUnits = nmea_tokenizer_get(tzer,10);

	nmea_reader_update_time(r, tok_time);
	nmea_reader_update_latlong(r, tok_latitude,
	tok_latitudeHemi.p[0],
	tok_longitude,
	tok_longitudeHemi.p[0]);
	nmea_reader_update_altitude(r, tok_altitude, tok_altitudeUnits);

	} else if ( !memcmp(tok.p, "GSA", 3) ) {
	// do something ?
	} else if ( !memcmp(tok.p, "RMC", 3) ) {
	Token tok_time = nmea_tokenizer_get(tzer,1);
	Token tok_fixStatus = nmea_tokenizer_get(tzer,2);
	Token tok_latitude = nmea_tokenizer_get(tzer,3);
	Token tok_latitudeHemi = nmea_tokenizer_get(tzer,4);
	Token tok_longitude = nmea_tokenizer_get(tzer,5);
	Token tok_longitudeHemi = nmea_tokenizer_get(tzer,6);
	Token tok_speed = nmea_tokenizer_get(tzer,7);
	Token tok_bearing = nmea_tokenizer_get(tzer,8);
	Token tok_date = nmea_tokenizer_get(tzer,9);

	D("in RMC, fixStatus=%c", tok_fixStatus.p[0]);
	if (tok_fixStatus.p[0] == 'A')
	{
	nmea_reader_update_date( r, tok_date, tok_time );

	nmea_reader_update_latlong( r, tok_latitude,
	tok_latitudeHemi.p[0],
	tok_longitude,
	tok_longitudeHemi.p[0] );

	nmea_reader_update_bearing( r, tok_bearing );
	nmea_reader_update_speed ( r, tok_speed );
	}
	} else {
	tok.p -= 2;
	D("unknown sentence '%.*s", tok.end-tok.p, tok.p);
	}

	// Always update accuracy
	nmea_reader_update_accuracy( r );

	if (r->fix.flags != 0) {
	#if GPS_DEBUG
	char temp[256];
	char* p = temp;
	char* end = p + sizeof(temp);
	struct tm utc;

	p += snprintf( p, end-p, "sending fix" );
	if (r->fix.flags & GPS_LOCATION_HAS_LAT_LONG) {
	p += snprintf(p, end-p, " lat=%g lon=%g", r->fix.latitude, r->fix.longitude);
	}
	if (r->fix.flags & GPS_LOCATION_HAS_ALTITUDE) {
	p += snprintf(p, end-p, " altitude=%g", r->fix.altitude);
	}
	if (r->fix.flags & GPS_LOCATION_HAS_SPEED) {
	p += snprintf(p, end-p, " speed=%g", r->fix.speed);
	}
	if (r->fix.flags & GPS_LOCATION_HAS_BEARING) {
	p += snprintf(p, end-p, " bearing=%g", r->fix.bearing);
	}
	if (r->fix.flags & GPS_LOCATION_HAS_ACCURACY) {
	p += snprintf(p,end-p, " accuracy=%g", r->fix.accuracy);
	}
	gmtime_r( (time_t*) &r->fix.timestamp, &utc );
	p += snprintf(p, end-p, " time=%s", asctime( &utc ) );
	D(temp);
	#endif
	if (r->callback) {
	r->callback( &r->fix );
	r->fix.flags = 0;
	}
	else {
	D("no callback, keeping data until needed !");
	}
	}
	}


	static void
	nmea_reader_addc( NmeaReader* r, int c )
	{
	if (r->overflow) {
	r->overflow = (c != '\n');
	return;
	}

	if (r->pos >= (int) sizeof(r->in)-1 ) {
	r->overflow = 1;
	r->pos = 0;
	return;
	}

	r->in[r->pos] = (char)c;
	r->pos += 1;

	if (c == '\n') {
	nmea_reader_parse( r );
	r->pos = 0;
	}
	}


	/*****************************************************************/
	/*****************************************************************/
	/*** ***/
	/*** C O N N E C T I O N S T A T E ***/
	/*** ***/
	/*****************************************************************/
	/*****************************************************************/

	/* commands sent to the gps thread */
	enum {
	CMD_QUIT = 0,
	CMD_START = 1,
	CMD_STOP = 2
	};


	/* this is the state of our connection to the qemu_gpsd daemon */
	typedef struct {
	int init;
	int fd;
	GpsCallbacks callbacks;
	pthread_t thread;
	int control[2];
	} GpsState;

	static GpsState _gps_state[1];


	static void
	gps_state_done( GpsState* s )
	{
	// tell the thread to quit, and wait for it
	char cmd = CMD_QUIT;
	void* dummy;
	write( s->control[0], &cmd, 1 );
	pthread_join(s->thread, &dummy);

	// close the control socket pair
	close( s->control[0] ); s->control[0] = -1;
	close( s->control[1] ); s->control[1] = -1;

	// close connection to the QEMU GPS daemon
	close( s->fd ); s->fd = -1;
	s->init = 0;
	}


	static void
	gps_state_start( GpsState* s )
	{
	char cmd = CMD_START;
	int ret;

	do { ret=write( s->control[0], &cmd, 1 ); }
	while (ret < 0 && errno == EINTR);

	if (ret != 1)
	D("%s: could not send CMD_START command: ret=%d: %s",
	__FUNCTION__, ret, strerror(errno));
	}


	static void
	gps_state_stop( GpsState* s )
	{
	char cmd = CMD_STOP;
	int ret;

	do { ret=write( s->control[0], &cmd, 1 ); }
	while (ret < 0 && errno == EINTR);

	if (ret != 1)
	D("%s: could not send CMD_STOP command: ret=%d: %s",
	__FUNCTION__, ret, strerror(errno));
	}


	static int
	epoll_register( int epoll_fd, int fd )
	{
	struct epoll_event ev;
	int ret, flags;

	/* important: make the fd non-blocking */
	flags = fcntl(fd, F_GETFL);
	fcntl(fd, F_SETFL, flags \| O_NONBLOCK);

	ev.events = EPOLLIN;
	ev.data.fd = fd;
	do {
	ret = epoll_ctl( epoll_fd, EPOLL_CTL_ADD, fd, &ev );
	} while (ret < 0 && errno == EINTR);
	return ret;
	}


	static int
	epoll_deregister( int epoll_fd, int fd )
	{
	int ret;
	do {
	ret = epoll_ctl( epoll_fd, EPOLL_CTL_DEL, fd, NULL );
	} while (ret < 0 && errno == EINTR);
	return ret;
	}

	/* this is the main thread, it waits for commands from gps_state_start/stop and,
	* when started, messages from the QEMU GPS daemon. these are simple NMEA sentences
	* that must be parsed to be converted into GPS fixes sent to the framework
	*/
	static void
	gps_state_thread( void* arg )
	{
	GpsState* state = (GpsState*) arg;
	NmeaReader reader[1];
	int epoll_fd = epoll_create(2);
	int started = 0;
	int gps_fd = state->fd;
	int control_fd = state->control[1];

	nmea_reader_init( reader );

	// register control file descriptors for polling
	epoll_register( epoll_fd, control_fd );
	epoll_register( epoll_fd, gps_fd );

	D("gps thread running");

	// now loop
	for (;;) {
	struct epoll_event events[2];
	int ne, nevents;

	nevents = epoll_wait( epoll_fd, events, 2, -1 );
	if (nevents < 0) {
	if (errno != EINTR)
	ALOGE("epoll_wait() unexpected error: %s", strerror(errno));
	continue;
	}
	D("gps thread received %d events", nevents);
	for (ne = 0; ne < nevents; ne++) {
	if ((events[ne].events & (EPOLLERR\|EPOLLHUP)) != 0) {
	ALOGE("EPOLLERR or EPOLLHUP after epoll_wait() !?");
	return;
	}
	if ((events[ne].events & EPOLLIN) != 0) {
	int fd = events[ne].data.fd;

	if (fd == control_fd)
	{
	char cmd = 255;
	int ret;
	D("gps control fd event");
	do {
	ret = read( fd, &cmd, 1 );
	} while (ret < 0 && errno == EINTR);

	if (cmd == CMD_QUIT) {
	D("gps thread quitting on demand");
	return;
	}
	else if (cmd == CMD_START) {
	if (!started) {
	D("gps thread starting location_cb=%p", state->callbacks.location_cb);
	started = 1;
	nmea_reader_set_callback( reader, state->callbacks.location_cb );
	}
	}
	else if (cmd == CMD_STOP) {
	if (started) {
	D("gps thread stopping");
	started = 0;
	nmea_reader_set_callback( reader, NULL );
	}
	}
	}
	else if (fd == gps_fd)
	{
	char buff[32];
	D("gps fd event");
	for (;;) {
	int nn, ret;

	ret = read( fd, buff, sizeof(buff) );
	if (ret < 0) {
	if (errno == EINTR)
	continue;
	if (errno != EWOULDBLOCK)
	ALOGE("error while reading from gps daemon socket: %s:", strerror(errno));
	break;
	}
	D("received %d bytes: %.*s", ret, ret, buff);
	for (nn = 0; nn < ret; nn++)
	nmea_reader_addc( reader, buff[nn] );
	}
	D("gps fd event end");
	}
	else
	{
	ALOGE("epoll_wait() returned unkown fd %d ?", fd);
	}
	}
	}
	}
	}


	static void
	gps_state_init( GpsState* state, GpsCallbacks* callbacks )
	{
	state->init = 1;
	state->control[0] = -1;
	state->control[1] = -1;
	state->fd = -1;

	state->fd = qemud_channel_open(QEMU_CHANNEL_NAME);

	if (state->fd < 0) {
	D("no gps emulation detected");
	return;
	}

	D("gps emulation will read from '%s' qemud channel", QEMU_CHANNEL_NAME );

	if ( socketpair( AF_LOCAL, SOCK_STREAM, 0, state->control ) < 0 ) {
	ALOGE("could not create thread control socket pair: %s", strerror(errno));
	goto Fail;
	}

	state->thread = callbacks->create_thread_cb( "gps_state_thread", gps_state_thread, state );

	if ( !state->thread ) {
	ALOGE("could not create gps thread: %s", strerror(errno));
	goto Fail;
	}

	state->callbacks = *callbacks;

	D("gps state initialized");
	return;

	Fail:
	gps_state_done( state );
	}


	/*****************************************************************/
	/*****************************************************************/
	/*** ***/
	/*** I N T E R F A C E ***/
	/*** ***/
	/*****************************************************************/
	/*****************************************************************/


	static int
	qemu_gps_init(GpsCallbacks* callbacks)
	{
	GpsState* s = _gps_state;

	if (!s->init)
	gps_state_init(s, callbacks);

	if (s->fd < 0)
	return -1;

	return 0;
	}

	static void
	qemu_gps_cleanup(void)
	{
	GpsState* s = _gps_state;

	if (s->init)
	gps_state_done(s);
	}


	static int
	qemu_gps_start()
	{
	GpsState* s = _gps_state;

	if (!s->init) {
	D("%s: called with uninitialized state !!", __FUNCTION__);
	return -1;
	}

	D("%s: called", __FUNCTION__);
	gps_state_start(s);
	return 0;
	}


	static int
	qemu_gps_stop()
	{
	GpsState* s = _gps_state;

	if (!s->init) {
	D("%s: called with uninitialized state !!", __FUNCTION__);
	return -1;
	}

	D("%s: called", __FUNCTION__);
	gps_state_stop(s);
	return 0;
	}


	static int
	qemu_gps_inject_time(GpsUtcTime time, int64_t timeReference, int uncertainty)
	{
	return 0;
	}

	static int
	qemu_gps_inject_location(double latitude, double longitude, float accuracy)
	{
	return 0;
	}

	static void
	qemu_gps_delete_aiding_data(GpsAidingData flags)
	{
	}

	static int qemu_gps_set_position_mode(GpsPositionMode mode, int fix_frequency)
	{
	// FIXME - support fix_frequency
	return 0;
	}

	static const void*
	qemu_gps_get_extension(const char* name)
	{
	// no extensions supported
	return NULL;
	}

	static const GpsInterface qemuGpsInterface = {
	sizeof(GpsInterface),
	qemu_gps_init,
	qemu_gps_start,
	qemu_gps_stop,
	qemu_gps_cleanup,
	qemu_gps_inject_time,
	qemu_gps_inject_location,
	qemu_gps_delete_aiding_data,
	qemu_gps_set_position_mode,
	qemu_gps_get_extension,
	};

	const GpsInterface* gps__get_gps_interface(struct gps_device_t* dev)
	{
	return &qemuGpsInterface;
	}

	static int open_gps(const struct hw_module_t* module, char const* name,
	struct hw_device_t** device)
	{
	struct gps_device_t *dev = malloc(sizeof(struct gps_device_t));
	memset(dev, 0, sizeof(*dev));

	dev->common.tag = HARDWARE_DEVICE_TAG;
	dev->common.version = 0;
	dev->common.module = (struct hw_module_t*)module;
	// dev->common.close = (int ()(struct hw_device_t))close_lights;
	dev->get_gps_interface = gps__get_gps_interface;

	device = (struct hw_device_t)dev;
	return 0;
	}


	static struct hw_module_methods_t gps_module_methods = {
	.open = open_gps
	};

	struct hw_module_t HAL_MODULE_INFO_SYM = {
	.tag = HARDWARE_MODULE_TAG,
	.version_major = 1,
	.version_minor = 0,
	.id = GPS_HARDWARE_MODULE_ID,
	.name = "Goldfish GPS Module",
	.author = "The Android Open Source Project",
	.methods = &gps_module_methods,
	};