/* Copyright (c) 2011-2014, 2016-2021 The Linux Foundation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * 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.
* * Neither the name of The Linux Foundation, nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER 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.
*
*/
#define LOG_NDEBUG 0 //Define to enable LOGV
#define LOG_TAG "LocSvc_LocApiBase"
#include <dlfcn.h>
#include <inttypes.h>
#include <gps_extended_c.h>
#include <LocApiBase.h>
#include <LocAdapterBase.h>
#include <log_util.h>
#include <LocContext.h>
#include <loc_misc_utils.h>
namespace loc_core {
#define TO_ALL_LOCADAPTERS(call) TO_ALL_ADAPTERS(mLocAdapters, (call))
#define TO_1ST_HANDLING_LOCADAPTERS(call) TO_1ST_HANDLING_ADAPTER(mLocAdapters, (call))
int hexcode(char *hexstring, int string_size,
const char *data, int data_size)
{
int i;
for (i = 0; i < data_size; i++)
{
char ch = data[i];
if (i*2 + 3 <= string_size)
{
snprintf(&hexstring[i*2], 3, "%02X", ch);
}
else {
break;
}
}
return i;
}
int decodeAddress(char *addr_string, int string_size,
const char *data, int data_size)
{
const char addr_prefix = 0x91;
int i, idxOutput = 0;
if (!data || !addr_string) { return 0; }
if (data[0] != addr_prefix)
{
LOC_LOGW("decodeAddress: address prefix is not 0x%x but 0x%x", addr_prefix, data[0]);
addr_string[0] = '\0';
return 0; // prefix not correct
}
for (i = 1; i < data_size; i++)
{
unsigned char ch = data[i], low = ch & 0x0F, hi = ch >> 4;
if (low <= 9 && idxOutput < string_size - 1) { addr_string[idxOutput++] = low + '0'; }
if (hi <= 9 && idxOutput < string_size - 1) { addr_string[idxOutput++] = hi + '0'; }
}
addr_string[idxOutput] = '\0'; // Terminates the string
return idxOutput;
}
struct LocSsrMsg : public LocMsg {
LocApiBase* mLocApi;
inline LocSsrMsg(LocApiBase* locApi) :
LocMsg(), mLocApi(locApi)
{
locallog();
}
inline virtual void proc() const {
mLocApi->close();
if (LOC_API_ADAPTER_ERR_SUCCESS == mLocApi->open(mLocApi->getEvtMask())) {
// Notify adapters that engine up after SSR
mLocApi->handleEngineUpEvent();
}
}
inline void locallog() const {
LOC_LOGV("LocSsrMsg");
}
inline virtual void log() const {
locallog();
}
};
struct LocOpenMsg : public LocMsg {
LocApiBase* mLocApi;
LocAdapterBase* mAdapter;
inline LocOpenMsg(LocApiBase* locApi, LocAdapterBase* adapter = nullptr) :
LocMsg(), mLocApi(locApi), mAdapter(adapter)
{
locallog();
}
inline virtual void proc() const {
if (LOC_API_ADAPTER_ERR_SUCCESS == mLocApi->open(mLocApi->getEvtMask()) &&
nullptr != mAdapter) {
mAdapter->handleEngineUpEvent();
}
}
inline void locallog() const {
LOC_LOGv("LocOpen Mask: %" PRIx64 "\n", mLocApi->getEvtMask());
}
inline virtual void log() const {
locallog();
}
};
struct LocCloseMsg : public LocMsg {
LocApiBase* mLocApi;
inline LocCloseMsg(LocApiBase* locApi) :
LocMsg(), mLocApi(locApi)
{
locallog();
}
inline virtual void proc() const {
mLocApi->close();
}
inline void locallog() const {
}
inline virtual void log() const {
locallog();
}
};
MsgTask* LocApiBase::mMsgTask = nullptr;
volatile int32_t LocApiBase::mMsgTaskRefCount = 0;
LocApiBase::LocApiBase(LOC_API_ADAPTER_EVENT_MASK_T excludedMask,
ContextBase* context) :
mContext(context),
mMask(0), mExcludedMask(excludedMask)
{
memset(mLocAdapters, 0, sizeof(mLocAdapters));
android_atomic_inc(&mMsgTaskRefCount);
if (nullptr == mMsgTask) {
mMsgTask = new MsgTask("LocApiMsgTask");
}
}
LOC_API_ADAPTER_EVENT_MASK_T LocApiBase::getEvtMask()
{
LOC_API_ADAPTER_EVENT_MASK_T mask = 0;
TO_ALL_LOCADAPTERS(mask |= mLocAdapters[i]->getEvtMask());
return mask & ~mExcludedMask;
}
bool LocApiBase::isMaster()
{
bool isMaster = false;
for (int i = 0;
!isMaster && i < MAX_ADAPTERS && NULL != mLocAdapters[i];
i++) {
isMaster |= mLocAdapters[i]->isAdapterMaster();
}
return isMaster;
}
bool LocApiBase::isInSession()
{
bool inSession = false;
for (int i = 0;
!inSession && i < MAX_ADAPTERS && NULL != mLocAdapters[i];
i++) {
inSession = mLocAdapters[i]->isInSession();
}
return inSession;
}
bool LocApiBase::needReport(const UlpLocation& ulpLocation,
enum loc_sess_status status,
LocPosTechMask techMask)
{
bool reported = false;
if (LOC_SESS_SUCCESS == status) {
// this is a final fix
LocPosTechMask mask =
LOC_POS_TECH_MASK_SATELLITE | LOC_POS_TECH_MASK_SENSORS | LOC_POS_TECH_MASK_HYBRID;
// it is a Satellite fix or a sensor fix
reported = (mask & techMask);
}
else if (LOC_SESS_INTERMEDIATE == status &&
LOC_SESS_INTERMEDIATE == ContextBase::mGps_conf.INTERMEDIATE_POS) {
// this is a intermediate fix and we accept intermediate
// it is NOT the case that
// there is inaccuracy; and
// we care about inaccuracy; and
// the inaccuracy exceeds our tolerance
reported = !((ulpLocation.gpsLocation.flags & LOC_GPS_LOCATION_HAS_ACCURACY) &&
(ContextBase::mGps_conf.ACCURACY_THRES != 0) &&
(ulpLocation.gpsLocation.accuracy > ContextBase::mGps_conf.ACCURACY_THRES));
}
return reported;
}
void LocApiBase::addAdapter(LocAdapterBase* adapter)
{
for (int i = 0; i < MAX_ADAPTERS && mLocAdapters[i] != adapter; i++) {
if (mLocAdapters[i] == NULL) {
mLocAdapters[i] = adapter;
sendMsg(new LocOpenMsg(this, adapter));
break;
}
}
}
void LocApiBase::removeAdapter(LocAdapterBase* adapter)
{
for (int i = 0;
i < MAX_ADAPTERS && NULL != mLocAdapters[i];
i++) {
if (mLocAdapters[i] == adapter) {
mLocAdapters[i] = NULL;
// shift the rest of the adapters up so that the pointers
// in the array do not have holes. This should be more
// performant, because the array maintenance is much much
// less frequent than event handlings, which need to linear
// search all the adapters
int j = i;
while (++i < MAX_ADAPTERS && mLocAdapters[i] != NULL);
// i would be MAX_ADAPTERS or point to a NULL
i--;
// i now should point to a none NULL adapter within valid
// range although i could be equal to j, but it won't hurt.
// No need to check it, as it gains nothing.
mLocAdapters[j] = mLocAdapters[i];
// this makes sure that we exit the for loop
mLocAdapters[i] = NULL;
// if we have an empty list of adapters
if (0 == i) {
sendMsg(new LocCloseMsg(this));
} else {
// else we need to remove the bit
sendMsg(new LocOpenMsg(this));
}
}
}
}
void LocApiBase::updateEvtMask()
{
sendMsg(new LocOpenMsg(this));
}
void LocApiBase::updateNmeaMask(uint32_t mask)
{
struct LocSetNmeaMsg : public LocMsg {
LocApiBase* mLocApi;
uint32_t mMask;
inline LocSetNmeaMsg(LocApiBase* locApi, uint32_t mask) :
LocMsg(), mLocApi(locApi), mMask(mask)
{
locallog();
}
inline virtual void proc() const {
mLocApi->setNMEATypesSync(mMask);
}
inline void locallog() const {
LOC_LOGv("LocSyncNmea NmeaMask: %" PRIx32 "\n", mMask);
}
inline virtual void log() const {
locallog();
}
};
sendMsg(new LocSetNmeaMsg(this, mask));
}
void LocApiBase::handleEngineUpEvent()
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->handleEngineUpEvent());
}
void LocApiBase::handleEngineDownEvent()
{ // This will take care of renegotiating the loc handle
sendMsg(new LocSsrMsg(this));
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->handleEngineDownEvent());
}
void LocApiBase::reportPosition(UlpLocation& location,
GpsLocationExtended& locationExtended,
enum loc_sess_status status,
LocPosTechMask loc_technology_mask,
GnssDataNotification* pDataNotify,
int msInWeek)
{
// print the location info before delivering
LOC_LOGD("flags: %d\n source: %d\n latitude: %f\n longitude: %f\n "
"altitude: %f\n speed: %f\n bearing: %f\n accuracy: %f\n "
"timestamp: %" PRId64 "\n"
"Session status: %d\n Technology mask: %u\n "
"SV used in fix (gps/glo/bds/gal/qzss) : \
(0x%" PRIx64 "/0x%" PRIx64 "/0x%" PRIx64 "/0x%" PRIx64 "/0x%" PRIx64 "/0x%" PRIx64 ")",
location.gpsLocation.flags, location.position_source,
location.gpsLocation.latitude, location.gpsLocation.longitude,
location.gpsLocation.altitude, location.gpsLocation.speed,
location.gpsLocation.bearing, location.gpsLocation.accuracy,
location.gpsLocation.timestamp, status, loc_technology_mask,
locationExtended.gnss_sv_used_ids.gps_sv_used_ids_mask,
locationExtended.gnss_sv_used_ids.glo_sv_used_ids_mask,
locationExtended.gnss_sv_used_ids.bds_sv_used_ids_mask,
locationExtended.gnss_sv_used_ids.gal_sv_used_ids_mask,
locationExtended.gnss_sv_used_ids.qzss_sv_used_ids_mask,
locationExtended.gnss_sv_used_ids.navic_sv_used_ids_mask);
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(
mLocAdapters[i]->reportPositionEvent(location, locationExtended,
status, loc_technology_mask,
pDataNotify, msInWeek)
);
}
void LocApiBase::reportWwanZppFix(LocGpsLocation &zppLoc)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->reportWwanZppFix(zppLoc));
}
void LocApiBase::reportZppBestAvailableFix(LocGpsLocation &zppLoc,
GpsLocationExtended &location_extended, LocPosTechMask tech_mask)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->reportZppBestAvailableFix(zppLoc,
location_extended, tech_mask));
}
void LocApiBase::requestOdcpi(OdcpiRequestInfo& request)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->requestOdcpiEvent(request));
}
void LocApiBase::reportGnssEngEnergyConsumedEvent(uint64_t energyConsumedSinceFirstBoot)
{
// loop through adapters, and deliver to the first handling adapter.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportGnssEngEnergyConsumedEvent(
energyConsumedSinceFirstBoot));
}
void LocApiBase::reportDeleteAidingDataEvent(GnssAidingData& aidingData) {
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->reportDeleteAidingDataEvent(aidingData));
}
void LocApiBase::reportKlobucharIonoModel(GnssKlobucharIonoModel & ionoModel) {
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->reportKlobucharIonoModelEvent(ionoModel));
}
void LocApiBase::reportGnssAdditionalSystemInfo(GnssAdditionalSystemInfo& additionalSystemInfo) {
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->reportGnssAdditionalSystemInfoEvent(
additionalSystemInfo));
}
void LocApiBase::sendNfwNotification(GnssNfwNotification& notification)
{
// loop through adapters, and deliver to the first handling adapter.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportNfwNotificationEvent(notification));
}
void LocApiBase::reportSv(GnssSvNotification& svNotify)
{
const char* constellationString[] = { "Unknown", "GPS", "SBAS", "GLONASS",
"QZSS", "BEIDOU", "GALILEO", "NAVIC" };
// print the SV info before delivering
LOC_LOGV("num sv: %u\n"
" sv: constellation svid cN0 basebandCN0"
" elevation azimuth flags",
svNotify.count);
for (size_t i = 0; i < svNotify.count && i < GNSS_SV_MAX; i++) {
if (svNotify.gnssSvs[i].type >
sizeof(constellationString) / sizeof(constellationString[0]) - 1) {
svNotify.gnssSvs[i].type = GNSS_SV_TYPE_UNKNOWN;
}
// Display what we report to clients
LOC_LOGV(" %03zu: %*s %02d %f %f %f %f %f 0x%02X 0x%2X",
i,
13,
constellationString[svNotify.gnssSvs[i].type],
svNotify.gnssSvs[i].svId,
svNotify.gnssSvs[i].cN0Dbhz,
svNotify.gnssSvs[i].basebandCarrierToNoiseDbHz,
svNotify.gnssSvs[i].elevation,
svNotify.gnssSvs[i].azimuth,
svNotify.gnssSvs[i].carrierFrequencyHz,
svNotify.gnssSvs[i].gnssSvOptionsMask,
svNotify.gnssSvs[i].gnssSignalTypeMask);
}
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(
mLocAdapters[i]->reportSvEvent(svNotify)
);
}
void LocApiBase::reportSvPolynomial(GnssSvPolynomial &svPolynomial)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(
mLocAdapters[i]->reportSvPolynomialEvent(svPolynomial)
);
}
void LocApiBase::reportSvEphemeris(GnssSvEphemerisReport & svEphemeris)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(
mLocAdapters[i]->reportSvEphemerisEvent(svEphemeris)
);
}
void LocApiBase::reportStatus(LocGpsStatusValue status)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportStatus(status));
}
void LocApiBase::reportData(GnssDataNotification& dataNotify, int msInWeek)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportDataEvent(dataNotify, msInWeek));
}
void LocApiBase::reportNmea(const char* nmea, int length)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportNmeaEvent(nmea, length));
}
void LocApiBase::reportXtraServer(const char* url1, const char* url2,
const char* url3, const int maxlength)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->reportXtraServer(url1, url2, url3, maxlength));
}
void LocApiBase::reportLocationSystemInfo(const LocationSystemInfo& locationSystemInfo)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportLocationSystemInfoEvent(locationSystemInfo));
}
void LocApiBase::reportQwesCapabilities
(
const std::unordered_map<LocationQwesFeatureType, bool> &featureMap
)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportQwesCapabilities(featureMap));
}
void LocApiBase::requestXtraData()
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->requestXtraData());
}
void LocApiBase::requestTime()
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->requestTime());
}
void LocApiBase::requestLocation()
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->requestLocation());
}
void LocApiBase::requestATL(int connHandle, LocAGpsType agps_type,
LocApnTypeMask apn_type_mask)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(
mLocAdapters[i]->requestATL(connHandle, agps_type, apn_type_mask));
}
void LocApiBase::releaseATL(int connHandle)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(mLocAdapters[i]->releaseATL(connHandle));
}
void LocApiBase::requestNiNotify(GnssNiNotification ¬ify, const void* data,
const LocInEmergency emergencyState)
{
// loop through adapters, and deliver to the first handling adapter.
TO_1ST_HANDLING_LOCADAPTERS(
mLocAdapters[i]->requestNiNotifyEvent(notify,
data,
emergencyState));
}
void* LocApiBase :: getSibling()
DEFAULT_IMPL(NULL)
LocApiProxyBase* LocApiBase :: getLocApiProxy()
DEFAULT_IMPL(NULL)
void LocApiBase::reportGnssMeasurements(GnssMeasurements& gnssMeasurements, int msInWeek)
{
// loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportGnssMeasurementsEvent(gnssMeasurements, msInWeek));
}
void LocApiBase::reportGnssSvIdConfig(const GnssSvIdConfig& config)
{
// Print the config
LOC_LOGv("gloBlacklistSvMask: %" PRIu64 ", bdsBlacklistSvMask: %" PRIu64 ",\n"
"qzssBlacklistSvMask: %" PRIu64 ", galBlacklistSvMask: %" PRIu64 ",\n"
"navicBlacklistSvMask: %" PRIu64,
config.gloBlacklistSvMask, config.bdsBlacklistSvMask,
config.qzssBlacklistSvMask, config.galBlacklistSvMask, config.navicBlacklistSvMask);
// Loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportGnssSvIdConfigEvent(config));
}
void LocApiBase::reportGnssSvTypeConfig(const GnssSvTypeConfig& config)
{
// Print the config
LOC_LOGv("blacklistedMask: %" PRIu64 ", enabledMask: %" PRIu64,
config.blacklistedSvTypesMask, config.enabledSvTypesMask);
// Loop through adapters, and deliver to all adapters.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportGnssSvTypeConfigEvent(config));
}
void LocApiBase::geofenceBreach(size_t count, uint32_t* hwIds, Location& location,
GeofenceBreachType breachType, uint64_t timestamp)
{
TO_ALL_LOCADAPTERS(mLocAdapters[i]->geofenceBreachEvent(count, hwIds, location, breachType,
timestamp));
}
void LocApiBase::geofenceStatus(GeofenceStatusAvailable available)
{
TO_ALL_LOCADAPTERS(mLocAdapters[i]->geofenceStatusEvent(available));
}
void LocApiBase::reportDBTPosition(UlpLocation &location, GpsLocationExtended &locationExtended,
enum loc_sess_status status, LocPosTechMask loc_technology_mask)
{
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportPositionEvent(location, locationExtended, status,
loc_technology_mask));
}
void LocApiBase::reportLocations(Location* locations, size_t count, BatchingMode batchingMode)
{
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportLocationsEvent(locations, count, batchingMode));
}
void LocApiBase::reportCompletedTrips(uint32_t accumulated_distance)
{
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportCompletedTripsEvent(accumulated_distance));
}
void LocApiBase::handleBatchStatusEvent(BatchingStatus batchStatus)
{
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportBatchStatusChangeEvent(batchStatus));
}
void LocApiBase::reportGnssConfig(uint32_t sessionId, const GnssConfig& gnssConfig)
{
// loop through adapters, and deliver to the first handling adapter.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportGnssConfigEvent(sessionId, gnssConfig));
}
void LocApiBase::reportLatencyInfo(GnssLatencyInfo& gnssLatencyInfo)
{
// loop through adapters, and deliver to the first handling adapter.
TO_ALL_LOCADAPTERS(mLocAdapters[i]->reportLatencyInfoEvent(gnssLatencyInfo));
}
enum loc_api_adapter_err LocApiBase::
open(LOC_API_ADAPTER_EVENT_MASK_T /*mask*/)
DEFAULT_IMPL(LOC_API_ADAPTER_ERR_SUCCESS)
enum loc_api_adapter_err LocApiBase::
close()
DEFAULT_IMPL(LOC_API_ADAPTER_ERR_SUCCESS)
void LocApiBase::startFix(const LocPosMode& /*posMode*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::stopFix(LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
deleteAidingData(const GnssAidingData& /*data*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
injectPosition(double /*latitude*/, double /*longitude*/, float /*accuracy*/,
bool /*onDemandCpi*/)
DEFAULT_IMPL()
void LocApiBase::
injectPosition(const Location& /*location*/, bool /*onDemandCpi*/)
DEFAULT_IMPL()
void LocApiBase::
injectPosition(const GnssLocationInfoNotification & /*locationInfo*/, bool /*onDemandCpi*/)
DEFAULT_IMPL()
void LocApiBase::
setTime(LocGpsUtcTime /*time*/, int64_t /*timeReference*/, int /*uncertainty*/)
DEFAULT_IMPL()
void LocApiBase::
atlOpenStatus(int /*handle*/, int /*is_succ*/, char* /*apn*/, uint32_t /*apnLen*/,
AGpsBearerType /*bear*/, LocAGpsType /*agpsType*/,
LocApnTypeMask /*mask*/)
DEFAULT_IMPL()
void LocApiBase::
atlCloseStatus(int /*handle*/, int /*is_succ*/)
DEFAULT_IMPL()
LocationError LocApiBase::
setServerSync(const char* /*url*/, int /*len*/, LocServerType /*type*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
LocationError LocApiBase::
setServerSync(unsigned int /*ip*/, int /*port*/, LocServerType /*type*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::
informNiResponse(GnssNiResponse /*userResponse*/, const void* /*passThroughData*/)
DEFAULT_IMPL()
LocationError LocApiBase::
setSUPLVersionSync(GnssConfigSuplVersion /*version*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
enum loc_api_adapter_err LocApiBase::
setNMEATypesSync (uint32_t /*typesMask*/)
DEFAULT_IMPL(LOC_API_ADAPTER_ERR_SUCCESS)
LocationError LocApiBase::
setLPPConfigSync(GnssConfigLppProfileMask /*profileMask*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
enum loc_api_adapter_err LocApiBase::
setSensorPropertiesSync(bool /*gyroBiasVarianceRandomWalk_valid*/,
float /*gyroBiasVarianceRandomWalk*/,
bool /*accelBiasVarianceRandomWalk_valid*/,
float /*accelBiasVarianceRandomWalk*/,
bool /*angleBiasVarianceRandomWalk_valid*/,
float /*angleBiasVarianceRandomWalk*/,
bool /*rateBiasVarianceRandomWalk_valid*/,
float /*rateBiasVarianceRandomWalk*/,
bool /*velocityBiasVarianceRandomWalk_valid*/,
float /*velocityBiasVarianceRandomWalk*/)
DEFAULT_IMPL(LOC_API_ADAPTER_ERR_SUCCESS)
enum loc_api_adapter_err LocApiBase::
setSensorPerfControlConfigSync(int /*controlMode*/,
int /*accelSamplesPerBatch*/,
int /*accelBatchesPerSec*/,
int /*gyroSamplesPerBatch*/,
int /*gyroBatchesPerSec*/,
int /*accelSamplesPerBatchHigh*/,
int /*accelBatchesPerSecHigh*/,
int /*gyroSamplesPerBatchHigh*/,
int /*gyroBatchesPerSecHigh*/,
int /*algorithmConfig*/)
DEFAULT_IMPL(LOC_API_ADAPTER_ERR_SUCCESS)
LocationError LocApiBase::
setAGLONASSProtocolSync(GnssConfigAGlonassPositionProtocolMask /*aGlonassProtocol*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
LocationError LocApiBase::
setLPPeProtocolCpSync(GnssConfigLppeControlPlaneMask /*lppeCP*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
LocationError LocApiBase::
setLPPeProtocolUpSync(GnssConfigLppeUserPlaneMask /*lppeUP*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
GnssConfigSuplVersion LocApiBase::convertSuplVersion(const uint32_t /*suplVersion*/)
DEFAULT_IMPL(GNSS_CONFIG_SUPL_VERSION_1_0_0)
GnssConfigLppeControlPlaneMask LocApiBase::convertLppeCp(const uint32_t /*lppeControlPlaneMask*/)
DEFAULT_IMPL(0)
GnssConfigLppeUserPlaneMask LocApiBase::convertLppeUp(const uint32_t /*lppeUserPlaneMask*/)
DEFAULT_IMPL(0)
LocationError LocApiBase::setEmergencyExtensionWindowSync(
const uint32_t /*emergencyExtensionSeconds*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::setMeasurementCorrections(
const GnssMeasurementCorrections& /*gnssMeasurementCorrections*/)
DEFAULT_IMPL()
void LocApiBase::
getWwanZppFix()
DEFAULT_IMPL()
void LocApiBase::
getBestAvailableZppFix()
DEFAULT_IMPL()
LocationError LocApiBase::
setGpsLockSync(GnssConfigGpsLock /*lock*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::
requestForAidingData(GnssAidingDataSvMask /*svDataMask*/)
DEFAULT_IMPL()
LocationError LocApiBase::
setXtraVersionCheckSync(uint32_t /*check*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
LocationError LocApiBase::setBlacklistSvSync(const GnssSvIdConfig& /*config*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::setBlacklistSv(const GnssSvIdConfig& /*config*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::getBlacklistSv()
DEFAULT_IMPL()
void LocApiBase::setConstellationControl(const GnssSvTypeConfig& /*config*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::getConstellationControl()
DEFAULT_IMPL()
void LocApiBase::resetConstellationControl(LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
setConstrainedTuncMode(bool /*enabled*/,
float /*tuncConstraint*/,
uint32_t /*energyBudget*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
setPositionAssistedClockEstimatorMode(bool /*enabled*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::getGnssEnergyConsumed()
DEFAULT_IMPL()
void LocApiBase::addGeofence(uint32_t /*clientId*/, const GeofenceOption& /*options*/,
const GeofenceInfo& /*info*/,
LocApiResponseData<LocApiGeofenceData>* /*adapterResponseData*/)
DEFAULT_IMPL()
void LocApiBase::removeGeofence(uint32_t /*hwId*/, uint32_t /*clientId*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::pauseGeofence(uint32_t /*hwId*/, uint32_t /*clientId*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::resumeGeofence(uint32_t /*hwId*/, uint32_t /*clientId*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::modifyGeofence(uint32_t /*hwId*/, uint32_t /*clientId*/,
const GeofenceOption& /*options*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::startTimeBasedTracking(const TrackingOptions& /*options*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::stopTimeBasedTracking(LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::startDistanceBasedTracking(uint32_t /*sessionId*/,
const LocationOptions& /*options*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::stopDistanceBasedTracking(uint32_t /*sessionId*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::startBatching(uint32_t /*sessionId*/, const LocationOptions& /*options*/,
uint32_t /*accuracy*/, uint32_t /*timeout*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::stopBatching(uint32_t /*sessionId*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
LocationError LocApiBase::startOutdoorTripBatchingSync(uint32_t /*tripDistance*/,
uint32_t /*tripTbf*/, uint32_t /*timeout*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::startOutdoorTripBatching(uint32_t /*tripDistance*/, uint32_t /*tripTbf*/,
uint32_t /*timeout*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::reStartOutdoorTripBatching(uint32_t /*ongoingTripDistance*/,
uint32_t /*ongoingTripInterval*/, uint32_t /*batchingTimeout,*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
LocationError LocApiBase::stopOutdoorTripBatchingSync(bool /*deallocBatchBuffer*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::stopOutdoorTripBatching(bool /*deallocBatchBuffer*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
LocationError LocApiBase::getBatchedLocationsSync(size_t /*count*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::getBatchedLocations(size_t /*count*/, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
LocationError LocApiBase::getBatchedTripLocationsSync(size_t /*count*/,
uint32_t /*accumulatedDistance*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::getBatchedTripLocations(size_t /*count*/, uint32_t /*accumulatedDistance*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
LocationError LocApiBase::queryAccumulatedTripDistanceSync(uint32_t& /*accumulated_trip_distance*/,
uint32_t& /*numOfBatchedPositions*/)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::queryAccumulatedTripDistance(
LocApiResponseData<LocApiBatchData>* /*adapterResponseData*/)
DEFAULT_IMPL()
void LocApiBase::setBatchSize(size_t /*size*/)
DEFAULT_IMPL()
void LocApiBase::setTripBatchSize(size_t /*size*/)
DEFAULT_IMPL()
void LocApiBase::addToCallQueue(LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::updateSystemPowerState(PowerStateType /*powerState*/)
DEFAULT_IMPL()
void LocApiBase::
configRobustLocation(bool /*enabled*/,
bool /*enableForE911*/,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
getRobustLocationConfig(uint32_t sessionId, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
configMinGpsWeek(uint16_t minGpsWeek,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
getMinGpsWeek(uint32_t sessionId, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
LocationError LocApiBase::
setParameterSync(const GnssConfig& gnssConfig)
DEFAULT_IMPL(LOCATION_ERROR_SUCCESS)
void LocApiBase::
getParameter(uint32_t sessionId, GnssConfigFlagsMask flags, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
configConstellationMultiBand(const GnssSvTypeConfig& secondaryBandConfig,
LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
void LocApiBase::
getConstellationMultiBandConfig(uint32_t sessionId, LocApiResponse* /*adapterResponse*/)
DEFAULT_IMPL()
int64_t ElapsedRealtimeEstimator::getElapsedRealtimeEstimateNanos(int64_t curDataTimeNanos,
bool isCurDataTimeTrustable, int64_t tbf) {
//The algorithm works follow below steps:
//When isCurDataTimeTrustable is meet (means Modem timestamp is already stable),
//1, Wait for mFixTimeStablizationThreshold fixes; While waiting for modem time
// stable, we set the traveltime to a default value;
//2, When the mFixTimeStablizationThreshold fix comes, we think now the mode time
// is already stable, calculate the initial AP-Modem clock diff(mCurrentClockDiff)
// using formula:
// mCurrentClockDiff = currentTimeNanos - locationTimeNanos - currentTravelTimeNanos
//3, since then, when the nth fix comes,
// 3.1 First update mCurrentClockDiff using below formula:
// mCurrentClockDiff = mCurrentClockDiff + (currentTimeNanos - sinceBootTimeNanos)
// - (mPrevUtcTimeNanos - mPrevBootTimeNanos)
// 3.2 Calculate currentTravelTimeNanos:
// currentTravelTimeNanos = currentTimeNanos - locationTimeNanos - mCurrentClockDiff
//4, It is possible that locationTimeNanos will jump,
// reset mFixTimeStablizationThreshold to default value, jump to step 2 to continue.
int64_t currentTravelTimeNanos = mInitialTravelTime;
struct timespec currentTime;
int64_t sinceBootTimeNanos;
if (getCurrentTime(currentTime, sinceBootTimeNanos)) {
if (isCurDataTimeTrustable) {
if (tbf > 0 && tbf != curDataTimeNanos - mPrevDataTimeNanos) {
mFixTimeStablizationThreshold = 5;
}
int64_t currentTimeNanos = (int64_t)currentTime.tv_sec*1000000000 + currentTime.tv_nsec;
LOC_LOGd("sinceBootTimeNanos:%" PRIi64 " currentTimeNanos:%" PRIi64 ""
" locationTimeNanos:%" PRIi64 "",
sinceBootTimeNanos, currentTimeNanos, curDataTimeNanos);
if (mFixTimeStablizationThreshold == 0) {
currentTravelTimeNanos = mInitialTravelTime;
mCurrentClockDiff = currentTimeNanos - curDataTimeNanos - currentTravelTimeNanos;
} else if (mFixTimeStablizationThreshold < 0) {
mCurrentClockDiff = mCurrentClockDiff + (currentTimeNanos - sinceBootTimeNanos)
- (mPrevUtcTimeNanos - mPrevBootTimeNanos);
currentTravelTimeNanos = currentTimeNanos - curDataTimeNanos - mCurrentClockDiff;
}
mPrevUtcTimeNanos = currentTimeNanos;
mPrevBootTimeNanos = sinceBootTimeNanos;
mPrevDataTimeNanos = curDataTimeNanos;
mFixTimeStablizationThreshold--;
}
} else {
return -1;
}
LOC_LOGd("Estimated travel time: %" PRIi64 "", currentTravelTimeNanos);
return (sinceBootTimeNanos - currentTravelTimeNanos);
}
void ElapsedRealtimeEstimator::reset() {
mCurrentClockDiff = 0;
mPrevDataTimeNanos = 0;
mPrevUtcTimeNanos = 0;
mPrevBootTimeNanos = 0;
mFixTimeStablizationThreshold = 5;
}
int64_t ElapsedRealtimeEstimator::getElapsedRealtimeQtimer(int64_t qtimerTicksAtOrigin) {
struct timespec currentTime;
int64_t sinceBootTimeNanos;
int64_t elapsedRealTimeNanos;
if (getCurrentTime(currentTime, sinceBootTimeNanos)) {
uint64_t qtimerDiff = 0;
uint64_t qTimerTickCount = getQTimerTickCount();
if (qTimerTickCount >= qtimerTicksAtOrigin) {
qtimerDiff = qTimerTickCount - qtimerTicksAtOrigin;
}
LOC_LOGd("sinceBootTimeNanos:%" PRIi64 " qtimerTicksAtOrigin=%" PRIi64 ""
" qTimerTickCount=%" PRIi64 " qtimerDiff=%" PRIi64 "",
sinceBootTimeNanos, qtimerTicksAtOrigin, qTimerTickCount, qtimerDiff);
uint64_t qTimerDiffNanos = qTimerTicksToNanos(double(qtimerDiff));
/* If the time difference between Qtimer on modem side and Qtimer on AP side
is greater than one second we assume this is a dual-SoC device such as
Kona and will try to get Qtimer on modem side and on AP side and
will adjust our difference accordingly */
if (qTimerDiffNanos > 1000000000) {
uint64_t qtimerDelta = getQTimerDeltaNanos();
if (qTimerDiffNanos >= qtimerDelta) {
qTimerDiffNanos -= qtimerDelta;
}
}
LOC_LOGd("Qtimer travel time: %" PRIi64 "", qTimerDiffNanos);
if (sinceBootTimeNanos >= qTimerDiffNanos) {
elapsedRealTimeNanos = sinceBootTimeNanos - qTimerDiffNanos;
} else {
elapsedRealTimeNanos = -1;
}
} else {
elapsedRealTimeNanos = -1;
}
return elapsedRealTimeNanos;
}
bool ElapsedRealtimeEstimator::getCurrentTime(
struct timespec& currentTime, int64_t& sinceBootTimeNanos)
{
struct timespec sinceBootTime;
struct timespec sinceBootTimeTest;
bool clockGetTimeSuccess = false;
const uint32_t MAX_TIME_DELTA_VALUE_NANOS = 10000;
const uint32_t MAX_GET_TIME_COUNT = 20;
/* Attempt to get CLOCK_REALTIME and CLOCK_BOOTIME in succession without an interruption
or context switch (for up to MAX_GET_TIME_COUNT times) to avoid errors in the calculation */
for (uint32_t i = 0; i < MAX_GET_TIME_COUNT; i++) {
if (clock_gettime(CLOCK_BOOTTIME, &sinceBootTime) != 0) {
break;
};
if (clock_gettime(CLOCK_REALTIME, ¤tTime) != 0) {
break;
}
if (clock_gettime(CLOCK_BOOTTIME, &sinceBootTimeTest) != 0) {
break;
};
sinceBootTimeNanos = (int64_t)sinceBootTime.tv_sec * 1000000000 + sinceBootTime.tv_nsec;
int64_t sinceBootTimeTestNanos =
(int64_t)sinceBootTimeTest.tv_sec * 1000000000 + sinceBootTimeTest.tv_nsec;
int64_t sinceBootTimeDeltaNanos = sinceBootTimeTestNanos - sinceBootTimeNanos;
/* sinceBootTime and sinceBootTimeTest should have a close value if there was no
interruption or context switch between clock_gettime for CLOCK_BOOTIME and
clock_gettime for CLOCK_REALTIME */
if (sinceBootTimeDeltaNanos < MAX_TIME_DELTA_VALUE_NANOS) {
clockGetTimeSuccess = true;
break;
} else {
LOC_LOGd("Delta:%" PRIi64 "ns time too large, retry number #%u...",
sinceBootTimeDeltaNanos, i + 1);
}
}
return clockGetTimeSuccess;
}
} // namespace loc_core