android_device_xiaomi_sm835.../gps/android/2.0/location_api/GnssAPIClient.cpp
Arian 75da4c0eee sm8350-common: Import gps hal from LA.UM.9.14.r1-16700-LAHAINA.0
Change-Id: I134d6418f1357a4d7ce37358481d6b765d93e1a5
2022-04-02 00:03:09 +02:00

729 lines
29 KiB
C++

/* Copyright (c) 2017-2020, 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 LOG_TAG "LocSvc_GnssAPIClient"
#define SINGLE_SHOT_MIN_TRACKING_INTERVAL_MSEC (590 * 60 * 60 * 1000) // 590 hours
#include <inttypes.h>
#include <log_util.h>
#include <loc_cfg.h>
#include "LocationUtil.h"
#include "GnssAPIClient.h"
#include <LocContext.h>
namespace android {
namespace hardware {
namespace gnss {
namespace V2_0 {
namespace implementation {
using ::android::hardware::gnss::V2_0::IGnss;
using ::android::hardware::gnss::V2_0::IGnssCallback;
using ::android::hardware::gnss::V1_0::IGnssNiCallback;
using ::android::hardware::gnss::V2_0::GnssLocation;
static void convertGnssSvStatus(GnssSvNotification& in, V1_0::IGnssCallback::GnssSvStatus& out);
static void convertGnssSvStatus(GnssSvNotification& in,
hidl_vec<V2_0::IGnssCallback::GnssSvInfo>& out);
GnssAPIClient::GnssAPIClient(const sp<V1_0::IGnssCallback>& gpsCb,
const sp<V1_0::IGnssNiCallback>& niCb) :
LocationAPIClientBase(),
mGnssCbIface(nullptr),
mGnssNiCbIface(nullptr),
mControlClient(new LocationAPIControlClient()),
mLocationCapabilitiesMask(0),
mLocationCapabilitiesCached(false),
mTracking(false),
mGnssCbIface_2_0(nullptr)
{
LOC_LOGD("%s]: (%p %p)", __FUNCTION__, &gpsCb, &niCb);
initLocationOptions();
gnssUpdateCallbacks(gpsCb, niCb);
}
GnssAPIClient::GnssAPIClient(const sp<V2_0::IGnssCallback>& gpsCb) :
LocationAPIClientBase(),
mGnssCbIface(nullptr),
mGnssNiCbIface(nullptr),
mControlClient(new LocationAPIControlClient()),
mLocationCapabilitiesMask(0),
mLocationCapabilitiesCached(false),
mTracking(false),
mGnssCbIface_2_0(nullptr)
{
LOC_LOGD("%s]: (%p)", __FUNCTION__, &gpsCb);
initLocationOptions();
gnssUpdateCallbacks_2_0(gpsCb);
}
GnssAPIClient::~GnssAPIClient()
{
LOC_LOGD("%s]: ()", __FUNCTION__);
if (mControlClient) {
delete mControlClient;
mControlClient = nullptr;
}
}
void GnssAPIClient::initLocationOptions()
{
// set default LocationOptions.
memset(&mTrackingOptions, 0, sizeof(TrackingOptions));
mTrackingOptions.size = sizeof(TrackingOptions);
mTrackingOptions.minInterval = 1000;
mTrackingOptions.minDistance = 0;
mTrackingOptions.mode = GNSS_SUPL_MODE_STANDALONE;
}
void GnssAPIClient::setCallbacks()
{
LocationCallbacks locationCallbacks;
memset(&locationCallbacks, 0, sizeof(LocationCallbacks));
locationCallbacks.size = sizeof(LocationCallbacks);
locationCallbacks.trackingCb = nullptr;
locationCallbacks.trackingCb = [this](Location location) {
onTrackingCb(location);
};
locationCallbacks.batchingCb = nullptr;
locationCallbacks.geofenceBreachCb = nullptr;
locationCallbacks.geofenceStatusCb = nullptr;
locationCallbacks.gnssLocationInfoCb = nullptr;
locationCallbacks.gnssNiCb = nullptr;
if (mGnssNiCbIface != nullptr) {
loc_core::ContextBase* context =
loc_core::LocContext::getLocContext(loc_core::LocContext::mLocationHalName);
if (!context->hasAgpsExtendedCapabilities()) {
LOC_LOGD("Registering NI CB");
locationCallbacks.gnssNiCb = [this](uint32_t id, GnssNiNotification gnssNiNotify) {
onGnssNiCb(id, gnssNiNotify);
};
}
}
locationCallbacks.gnssSvCb = nullptr;
locationCallbacks.gnssSvCb = [this](GnssSvNotification gnssSvNotification) {
onGnssSvCb(gnssSvNotification);
};
locationCallbacks.gnssNmeaCb = nullptr;
locationCallbacks.gnssNmeaCb = [this](GnssNmeaNotification gnssNmeaNotification) {
onGnssNmeaCb(gnssNmeaNotification);
};
locationCallbacks.gnssMeasurementsCb = nullptr;
locAPISetCallbacks(locationCallbacks);
}
// for GpsInterface
void GnssAPIClient::gnssUpdateCallbacks(const sp<V1_0::IGnssCallback>& gpsCb,
const sp<IGnssNiCallback>& niCb)
{
LOC_LOGD("%s]: (%p %p)", __FUNCTION__, &gpsCb, &niCb);
mMutex.lock();
mGnssCbIface = gpsCb;
mGnssNiCbIface = niCb;
mMutex.unlock();
if (mGnssCbIface != nullptr || mGnssNiCbIface != nullptr) {
setCallbacks();
}
}
void GnssAPIClient::gnssUpdateCallbacks_2_0(const sp<V2_0::IGnssCallback>& gpsCb)
{
LOC_LOGD("%s]: (%p)", __FUNCTION__, &gpsCb);
mMutex.lock();
mGnssCbIface_2_0 = gpsCb;
mMutex.unlock();
if (mGnssCbIface_2_0 != nullptr) {
setCallbacks();
}
}
bool GnssAPIClient::gnssStart()
{
LOC_LOGD("%s]: ()", __FUNCTION__);
mMutex.lock();
mTracking = true;
mMutex.unlock();
bool retVal = true;
locAPIStartTracking(mTrackingOptions);
return retVal;
}
bool GnssAPIClient::gnssStop()
{
LOC_LOGD("%s]: ()", __FUNCTION__);
mMutex.lock();
mTracking = false;
mMutex.unlock();
bool retVal = true;
locAPIStopTracking();
return retVal;
}
bool GnssAPIClient::gnssSetPositionMode(IGnss::GnssPositionMode mode,
IGnss::GnssPositionRecurrence recurrence, uint32_t minIntervalMs,
uint32_t preferredAccuracyMeters, uint32_t preferredTimeMs,
GnssPowerMode powerMode, uint32_t timeBetweenMeasurement)
{
LOC_LOGD("%s]: (%d %d %d %d %d %d %d)", __FUNCTION__,
(int)mode, recurrence, minIntervalMs, preferredAccuracyMeters,
preferredTimeMs, (int)powerMode, timeBetweenMeasurement);
bool retVal = true;
memset(&mTrackingOptions, 0, sizeof(TrackingOptions));
mTrackingOptions.size = sizeof(TrackingOptions);
mTrackingOptions.minInterval = minIntervalMs;
if (IGnss::GnssPositionMode::MS_ASSISTED == mode ||
IGnss::GnssPositionRecurrence::RECURRENCE_SINGLE == recurrence) {
// We set a very large interval to simulate SINGLE mode. Once we report a fix,
// the caller should take the responsibility to stop the session.
// For MSA, we always treat it as SINGLE mode.
mTrackingOptions.minInterval = SINGLE_SHOT_MIN_TRACKING_INTERVAL_MSEC;
}
if (mode == IGnss::GnssPositionMode::STANDALONE)
mTrackingOptions.mode = GNSS_SUPL_MODE_STANDALONE;
else if (mode == IGnss::GnssPositionMode::MS_BASED)
mTrackingOptions.mode = GNSS_SUPL_MODE_MSB;
else if (mode == IGnss::GnssPositionMode::MS_ASSISTED)
mTrackingOptions.mode = GNSS_SUPL_MODE_MSA;
else {
LOC_LOGD("%s]: invalid GnssPositionMode: %d", __FUNCTION__, (int)mode);
retVal = false;
}
if (GNSS_POWER_MODE_INVALID != powerMode) {
mTrackingOptions.powerMode = powerMode;
mTrackingOptions.tbm = timeBetweenMeasurement;
}
locAPIUpdateTrackingOptions(mTrackingOptions);
return retVal;
}
// for GpsNiInterface
void GnssAPIClient::gnssNiRespond(int32_t notifId,
IGnssNiCallback::GnssUserResponseType userResponse)
{
LOC_LOGD("%s]: (%d %d)", __FUNCTION__, notifId, static_cast<int>(userResponse));
GnssNiResponse data;
switch (userResponse) {
case IGnssNiCallback::GnssUserResponseType::RESPONSE_ACCEPT:
data = GNSS_NI_RESPONSE_ACCEPT;
break;
case IGnssNiCallback::GnssUserResponseType::RESPONSE_DENY:
data = GNSS_NI_RESPONSE_DENY;
break;
case IGnssNiCallback::GnssUserResponseType::RESPONSE_NORESP:
data = GNSS_NI_RESPONSE_NO_RESPONSE;
break;
default:
data = GNSS_NI_RESPONSE_IGNORE;
break;
}
locAPIGnssNiResponse(notifId, data);
}
// these apis using LocationAPIControlClient
void GnssAPIClient::gnssDeleteAidingData(IGnss::GnssAidingData aidingDataFlags)
{
LOC_LOGD("%s]: (%02hx)", __FUNCTION__, aidingDataFlags);
if (mControlClient == nullptr) {
return;
}
GnssAidingData data;
memset(&data, 0, sizeof (GnssAidingData));
data.sv.svTypeMask = GNSS_AIDING_DATA_SV_TYPE_GPS_BIT |
GNSS_AIDING_DATA_SV_TYPE_GLONASS_BIT |
GNSS_AIDING_DATA_SV_TYPE_QZSS_BIT |
GNSS_AIDING_DATA_SV_TYPE_BEIDOU_BIT |
GNSS_AIDING_DATA_SV_TYPE_GALILEO_BIT |
GNSS_AIDING_DATA_SV_TYPE_NAVIC_BIT;
data.posEngineMask = STANDARD_POSITIONING_ENGINE;
if (aidingDataFlags == IGnss::GnssAidingData::DELETE_ALL)
data.deleteAll = true;
else {
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_EPHEMERIS)
data.sv.svMask |= GNSS_AIDING_DATA_SV_EPHEMERIS_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_ALMANAC)
data.sv.svMask |= GNSS_AIDING_DATA_SV_ALMANAC_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_POSITION)
data.common.mask |= GNSS_AIDING_DATA_COMMON_POSITION_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_TIME)
data.common.mask |= GNSS_AIDING_DATA_COMMON_TIME_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_IONO)
data.sv.svMask |= GNSS_AIDING_DATA_SV_IONOSPHERE_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_UTC)
data.common.mask |= GNSS_AIDING_DATA_COMMON_UTC_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_HEALTH)
data.sv.svMask |= GNSS_AIDING_DATA_SV_HEALTH_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_SVDIR)
data.sv.svMask |= GNSS_AIDING_DATA_SV_DIRECTION_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_SVSTEER)
data.sv.svMask |= GNSS_AIDING_DATA_SV_STEER_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_SADATA)
data.sv.svMask |= GNSS_AIDING_DATA_SV_SA_DATA_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_RTI)
data.common.mask |= GNSS_AIDING_DATA_COMMON_RTI_BIT;
if (aidingDataFlags & IGnss::GnssAidingData::DELETE_CELLDB_INFO)
data.common.mask |= GNSS_AIDING_DATA_COMMON_CELLDB_BIT;
}
mControlClient->locAPIGnssDeleteAidingData(data);
}
void GnssAPIClient::gnssEnable(LocationTechnologyType techType)
{
LOC_LOGD("%s]: (%0d)", __FUNCTION__, techType);
if (mControlClient == nullptr) {
return;
}
mControlClient->locAPIEnable(techType);
}
void GnssAPIClient::gnssDisable()
{
LOC_LOGD("%s]: ()", __FUNCTION__);
if (mControlClient == nullptr) {
return;
}
mControlClient->locAPIDisable();
}
void GnssAPIClient::gnssConfigurationUpdate(const GnssConfig& gnssConfig)
{
LOC_LOGD("%s]: (%02x)", __FUNCTION__, gnssConfig.flags);
if (mControlClient == nullptr) {
return;
}
mControlClient->locAPIGnssUpdateConfig(gnssConfig);
}
void GnssAPIClient::requestCapabilities() {
// only send capablities if it's already cached, otherwise the first time LocationAPI
// is initialized, capabilities will be sent by LocationAPI
if (mLocationCapabilitiesCached) {
onCapabilitiesCb(mLocationCapabilitiesMask);
}
}
// callbacks
void GnssAPIClient::onCapabilitiesCb(LocationCapabilitiesMask capabilitiesMask)
{
LOC_LOGD("%s]: (%" PRIu64 ")", __FUNCTION__, capabilitiesMask);
mLocationCapabilitiesMask = capabilitiesMask;
mLocationCapabilitiesCached = true;
mMutex.lock();
auto gnssCbIface(mGnssCbIface);
auto gnssCbIface_2_0(mGnssCbIface_2_0);
mMutex.unlock();
if (gnssCbIface_2_0 != nullptr || gnssCbIface != nullptr) {
uint32_t data = 0;
if ((capabilitiesMask & LOCATION_CAPABILITIES_TIME_BASED_TRACKING_BIT) ||
(capabilitiesMask & LOCATION_CAPABILITIES_TIME_BASED_BATCHING_BIT) ||
(capabilitiesMask & LOCATION_CAPABILITIES_DISTANCE_BASED_TRACKING_BIT) ||
(capabilitiesMask & LOCATION_CAPABILITIES_DISTANCE_BASED_BATCHING_BIT))
data |= IGnssCallback::Capabilities::SCHEDULING;
if (capabilitiesMask & LOCATION_CAPABILITIES_GEOFENCE_BIT)
data |= V1_0::IGnssCallback::Capabilities::GEOFENCING;
if (capabilitiesMask & LOCATION_CAPABILITIES_GNSS_MEASUREMENTS_BIT)
data |= V1_0::IGnssCallback::Capabilities::MEASUREMENTS;
if (capabilitiesMask & LOCATION_CAPABILITIES_GNSS_MSB_BIT)
data |= IGnssCallback::Capabilities::MSB;
if (capabilitiesMask & LOCATION_CAPABILITIES_GNSS_MSA_BIT)
data |= IGnssCallback::Capabilities::MSA;
if (capabilitiesMask & LOCATION_CAPABILITIES_AGPM_BIT)
data |= IGnssCallback::Capabilities::LOW_POWER_MODE;
if (capabilitiesMask & LOCATION_CAPABILITIES_CONSTELLATION_ENABLEMENT_BIT)
data |= IGnssCallback::Capabilities::SATELLITE_BLACKLIST;
IGnssCallback::GnssSystemInfo gnssInfo = { .yearOfHw = 2015 };
if (capabilitiesMask & LOCATION_CAPABILITIES_GNSS_MEASUREMENTS_BIT) {
gnssInfo.yearOfHw++; // 2016
if (capabilitiesMask & LOCATION_CAPABILITIES_DEBUG_NMEA_BIT) {
gnssInfo.yearOfHw++; // 2017
if (capabilitiesMask & LOCATION_CAPABILITIES_CONSTELLATION_ENABLEMENT_BIT ||
capabilitiesMask & LOCATION_CAPABILITIES_AGPM_BIT) {
gnssInfo.yearOfHw++; // 2018
if (capabilitiesMask & LOCATION_CAPABILITIES_PRIVACY_BIT) {
gnssInfo.yearOfHw++; // 2019
}
}
}
}
LOC_LOGV("%s:%d] set_system_info_cb (%d)", __FUNCTION__, __LINE__, gnssInfo.yearOfHw);
if (gnssCbIface_2_0 != nullptr) {
auto r = gnssCbIface_2_0->gnssSetCapabilitiesCb_2_0(data);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssSetCapabilitiesCb_2_0 description=%s",
__func__, r.description().c_str());
}
r = gnssCbIface_2_0->gnssSetSystemInfoCb(gnssInfo);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssSetSystemInfoCb description=%s",
__func__, r.description().c_str());
}
} else if (gnssCbIface != nullptr) {
auto r = gnssCbIface->gnssSetCapabilitesCb(data);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssSetCapabilitesCb description=%s",
__func__, r.description().c_str());
}
r = gnssCbIface->gnssSetSystemInfoCb(gnssInfo);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssSetSystemInfoCb description=%s",
__func__, r.description().c_str());
}
}
}
}
void GnssAPIClient::onTrackingCb(Location location)
{
mMutex.lock();
auto gnssCbIface(mGnssCbIface);
auto gnssCbIface_2_0(mGnssCbIface_2_0);
bool isTracking = mTracking;
mMutex.unlock();
LOC_LOGD("%s]: (flags: %02x isTracking: %d)", __FUNCTION__, location.flags, isTracking);
if (!isTracking) {
return;
}
if (gnssCbIface_2_0 != nullptr) {
V2_0::GnssLocation gnssLocation;
convertGnssLocation(location, gnssLocation);
auto r = gnssCbIface_2_0->gnssLocationCb_2_0(gnssLocation);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssLocationCb_2_0 description=%s",
__func__, r.description().c_str());
}
} else if (gnssCbIface != nullptr) {
V1_0::GnssLocation gnssLocation;
convertGnssLocation(location, gnssLocation);
auto r = gnssCbIface->gnssLocationCb(gnssLocation);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssLocationCb description=%s",
__func__, r.description().c_str());
}
} else {
LOC_LOGW("%s] No GNSS Interface ready for gnssLocationCb ", __FUNCTION__);
}
}
void GnssAPIClient::onGnssNiCb(uint32_t id, GnssNiNotification gnssNiNotification)
{
LOC_LOGD("%s]: (id: %d)", __FUNCTION__, id);
mMutex.lock();
auto gnssNiCbIface(mGnssNiCbIface);
mMutex.unlock();
if (gnssNiCbIface == nullptr) {
LOC_LOGE("%s]: mGnssNiCbIface is nullptr", __FUNCTION__);
return;
}
IGnssNiCallback::GnssNiNotification notificationGnss = {};
notificationGnss.notificationId = id;
if (gnssNiNotification.type == GNSS_NI_TYPE_VOICE)
notificationGnss.niType = IGnssNiCallback::GnssNiType::VOICE;
else if (gnssNiNotification.type == GNSS_NI_TYPE_SUPL)
notificationGnss.niType = IGnssNiCallback::GnssNiType::UMTS_SUPL;
else if (gnssNiNotification.type == GNSS_NI_TYPE_CONTROL_PLANE)
notificationGnss.niType = IGnssNiCallback::GnssNiType::UMTS_CTRL_PLANE;
else if (gnssNiNotification.type == GNSS_NI_TYPE_EMERGENCY_SUPL)
notificationGnss.niType = IGnssNiCallback::GnssNiType::EMERGENCY_SUPL;
if (gnssNiNotification.options & GNSS_NI_OPTIONS_NOTIFICATION_BIT)
notificationGnss.notifyFlags |= IGnssNiCallback::GnssNiNotifyFlags::NEED_NOTIFY;
if (gnssNiNotification.options & GNSS_NI_OPTIONS_VERIFICATION_BIT)
notificationGnss.notifyFlags |= IGnssNiCallback::GnssNiNotifyFlags::NEED_VERIFY;
if (gnssNiNotification.options & GNSS_NI_OPTIONS_PRIVACY_OVERRIDE_BIT)
notificationGnss.notifyFlags |= IGnssNiCallback::GnssNiNotifyFlags::PRIVACY_OVERRIDE;
notificationGnss.timeoutSec = gnssNiNotification.timeout;
if (gnssNiNotification.timeoutResponse == GNSS_NI_RESPONSE_ACCEPT)
notificationGnss.defaultResponse = IGnssNiCallback::GnssUserResponseType::RESPONSE_ACCEPT;
else if (gnssNiNotification.timeoutResponse == GNSS_NI_RESPONSE_DENY)
notificationGnss.defaultResponse = IGnssNiCallback::GnssUserResponseType::RESPONSE_DENY;
else if (gnssNiNotification.timeoutResponse == GNSS_NI_RESPONSE_NO_RESPONSE ||
gnssNiNotification.timeoutResponse == GNSS_NI_RESPONSE_IGNORE)
notificationGnss.defaultResponse = IGnssNiCallback::GnssUserResponseType::RESPONSE_NORESP;
notificationGnss.requestorId = gnssNiNotification.requestor;
notificationGnss.notificationMessage = gnssNiNotification.message;
if (gnssNiNotification.requestorEncoding == GNSS_NI_ENCODING_TYPE_NONE)
notificationGnss.requestorIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_NONE;
else if (gnssNiNotification.requestorEncoding == GNSS_NI_ENCODING_TYPE_GSM_DEFAULT)
notificationGnss.requestorIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_SUPL_GSM_DEFAULT;
else if (gnssNiNotification.requestorEncoding == GNSS_NI_ENCODING_TYPE_UTF8)
notificationGnss.requestorIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_SUPL_UTF8;
else if (gnssNiNotification.requestorEncoding == GNSS_NI_ENCODING_TYPE_UCS2)
notificationGnss.requestorIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_SUPL_UCS2;
if (gnssNiNotification.messageEncoding == GNSS_NI_ENCODING_TYPE_NONE)
notificationGnss.notificationIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_NONE;
else if (gnssNiNotification.messageEncoding == GNSS_NI_ENCODING_TYPE_GSM_DEFAULT)
notificationGnss.notificationIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_SUPL_GSM_DEFAULT;
else if (gnssNiNotification.messageEncoding == GNSS_NI_ENCODING_TYPE_UTF8)
notificationGnss.notificationIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_SUPL_UTF8;
else if (gnssNiNotification.messageEncoding == GNSS_NI_ENCODING_TYPE_UCS2)
notificationGnss.notificationIdEncoding =
IGnssNiCallback::GnssNiEncodingType::ENC_SUPL_UCS2;
gnssNiCbIface->niNotifyCb(notificationGnss);
}
void GnssAPIClient::onGnssSvCb(GnssSvNotification gnssSvNotification)
{
LOC_LOGD("%s]: (count: %u)", __FUNCTION__, gnssSvNotification.count);
mMutex.lock();
auto gnssCbIface(mGnssCbIface);
auto gnssCbIface_2_0(mGnssCbIface_2_0);
mMutex.unlock();
if (gnssCbIface_2_0 != nullptr) {
hidl_vec<V2_0::IGnssCallback::GnssSvInfo> svInfoList;
convertGnssSvStatus(gnssSvNotification, svInfoList);
auto r = gnssCbIface_2_0->gnssSvStatusCb_2_0(svInfoList);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssSvStatusCb_2_0 description=%s",
__func__, r.description().c_str());
}
} else if (gnssCbIface != nullptr) {
V1_0::IGnssCallback::GnssSvStatus svStatus;
convertGnssSvStatus(gnssSvNotification, svStatus);
auto r = gnssCbIface->gnssSvStatusCb(svStatus);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssSvStatusCb description=%s",
__func__, r.description().c_str());
}
}
}
void GnssAPIClient::onGnssNmeaCb(GnssNmeaNotification gnssNmeaNotification)
{
mMutex.lock();
auto gnssCbIface(mGnssCbIface);
auto gnssCbIface_2_0(mGnssCbIface_2_0);
mMutex.unlock();
if (gnssCbIface != nullptr || gnssCbIface_2_0 != nullptr) {
const std::string s(gnssNmeaNotification.nmea);
std::stringstream ss(s);
std::string each;
while(std::getline(ss, each, '\n')) {
each += '\n';
android::hardware::hidl_string nmeaString;
nmeaString.setToExternal(each.c_str(), each.length());
if (gnssCbIface_2_0 != nullptr) {
auto r = gnssCbIface_2_0->gnssNmeaCb(
static_cast<V1_0::GnssUtcTime>(gnssNmeaNotification.timestamp), nmeaString);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssCbIface_2_0 nmea=%s length=%u description=%s",
__func__, gnssNmeaNotification.nmea, gnssNmeaNotification.length,
r.description().c_str());
}
} else if (gnssCbIface != nullptr) {
auto r = gnssCbIface->gnssNmeaCb(
static_cast<V1_0::GnssUtcTime>(gnssNmeaNotification.timestamp), nmeaString);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssNmeaCb nmea=%s length=%u description=%s",
__func__, gnssNmeaNotification.nmea, gnssNmeaNotification.length,
r.description().c_str());
}
}
}
}
}
void GnssAPIClient::onStartTrackingCb(LocationError error)
{
LOC_LOGD("%s]: (%d)", __FUNCTION__, error);
mMutex.lock();
auto gnssCbIface(mGnssCbIface);
auto gnssCbIface_2_0(mGnssCbIface_2_0);
mMutex.unlock();
if (error == LOCATION_ERROR_SUCCESS) {
if (gnssCbIface_2_0 != nullptr) {
auto r = gnssCbIface_2_0->gnssStatusCb(IGnssCallback::GnssStatusValue::ENGINE_ON);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb 2.0 ENGINE_ON description=%s",
__func__, r.description().c_str());
}
r = gnssCbIface_2_0->gnssStatusCb(IGnssCallback::GnssStatusValue::SESSION_BEGIN);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb 2.0 SESSION_BEGIN description=%s",
__func__, r.description().c_str());
}
} else if (gnssCbIface != nullptr) {
auto r = gnssCbIface->gnssStatusCb(IGnssCallback::GnssStatusValue::ENGINE_ON);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb ENGINE_ON description=%s",
__func__, r.description().c_str());
}
r = gnssCbIface->gnssStatusCb(IGnssCallback::GnssStatusValue::SESSION_BEGIN);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb SESSION_BEGIN description=%s",
__func__, r.description().c_str());
}
}
}
}
void GnssAPIClient::onStopTrackingCb(LocationError error)
{
LOC_LOGD("%s]: (%d)", __FUNCTION__, error);
mMutex.lock();
auto gnssCbIface(mGnssCbIface);
auto gnssCbIface_2_0(mGnssCbIface_2_0);
mMutex.unlock();
if (error == LOCATION_ERROR_SUCCESS) {
if (gnssCbIface_2_0 != nullptr) {
auto r = gnssCbIface_2_0->gnssStatusCb(IGnssCallback::GnssStatusValue::SESSION_END);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb 2.0 SESSION_END description=%s",
__func__, r.description().c_str());
}
r = gnssCbIface_2_0->gnssStatusCb(IGnssCallback::GnssStatusValue::ENGINE_OFF);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb 2.0 ENGINE_OFF description=%s",
__func__, r.description().c_str());
}
} else if (gnssCbIface != nullptr) {
auto r = gnssCbIface->gnssStatusCb(IGnssCallback::GnssStatusValue::SESSION_END);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb SESSION_END description=%s",
__func__, r.description().c_str());
}
r = gnssCbIface->gnssStatusCb(IGnssCallback::GnssStatusValue::ENGINE_OFF);
if (!r.isOk()) {
LOC_LOGE("%s] Error from gnssStatusCb ENGINE_OFF description=%s",
__func__, r.description().c_str());
}
}
}
}
static void convertGnssSvStatus(GnssSvNotification& in, V1_0::IGnssCallback::GnssSvStatus& out)
{
memset(&out, 0, sizeof(IGnssCallback::GnssSvStatus));
out.numSvs = in.count;
if (out.numSvs > static_cast<uint32_t>(V1_0::GnssMax::SVS_COUNT)) {
LOC_LOGW("%s]: Too many satellites %u. Clamps to %d.",
__FUNCTION__, out.numSvs, V1_0::GnssMax::SVS_COUNT);
out.numSvs = static_cast<uint32_t>(V1_0::GnssMax::SVS_COUNT);
}
for (size_t i = 0; i < out.numSvs; i++) {
convertGnssSvid(in.gnssSvs[i], out.gnssSvList[i].svid);
convertGnssConstellationType(in.gnssSvs[i].type, out.gnssSvList[i].constellation);
out.gnssSvList[i].cN0Dbhz = in.gnssSvs[i].cN0Dbhz;
out.gnssSvList[i].elevationDegrees = in.gnssSvs[i].elevation;
out.gnssSvList[i].azimuthDegrees = in.gnssSvs[i].azimuth;
out.gnssSvList[i].carrierFrequencyHz = in.gnssSvs[i].carrierFrequencyHz;
out.gnssSvList[i].svFlag = static_cast<uint8_t>(IGnssCallback::GnssSvFlags::NONE);
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_HAS_EPHEMER_BIT)
out.gnssSvList[i].svFlag |= IGnssCallback::GnssSvFlags::HAS_EPHEMERIS_DATA;
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_HAS_ALMANAC_BIT)
out.gnssSvList[i].svFlag |= IGnssCallback::GnssSvFlags::HAS_ALMANAC_DATA;
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_USED_IN_FIX_BIT)
out.gnssSvList[i].svFlag |= IGnssCallback::GnssSvFlags::USED_IN_FIX;
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_HAS_CARRIER_FREQUENCY_BIT)
out.gnssSvList[i].svFlag |= IGnssCallback::GnssSvFlags::HAS_CARRIER_FREQUENCY;
}
}
static void convertGnssSvStatus(GnssSvNotification& in,
hidl_vec<V2_0::IGnssCallback::GnssSvInfo>& out)
{
out.resize(in.count);
for (size_t i = 0; i < in.count; i++) {
convertGnssSvid(in.gnssSvs[i], out[i].v1_0.svid);
out[i].v1_0.cN0Dbhz = in.gnssSvs[i].cN0Dbhz;
out[i].v1_0.elevationDegrees = in.gnssSvs[i].elevation;
out[i].v1_0.azimuthDegrees = in.gnssSvs[i].azimuth;
out[i].v1_0.carrierFrequencyHz = in.gnssSvs[i].carrierFrequencyHz;
out[i].v1_0.svFlag = static_cast<uint8_t>(IGnssCallback::GnssSvFlags::NONE);
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_HAS_EPHEMER_BIT)
out[i].v1_0.svFlag |= IGnssCallback::GnssSvFlags::HAS_EPHEMERIS_DATA;
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_HAS_ALMANAC_BIT)
out[i].v1_0.svFlag |= IGnssCallback::GnssSvFlags::HAS_ALMANAC_DATA;
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_USED_IN_FIX_BIT)
out[i].v1_0.svFlag |= IGnssCallback::GnssSvFlags::USED_IN_FIX;
if (in.gnssSvs[i].gnssSvOptionsMask & GNSS_SV_OPTIONS_HAS_CARRIER_FREQUENCY_BIT)
out[i].v1_0.svFlag |= IGnssCallback::GnssSvFlags::HAS_CARRIER_FREQUENCY;
convertGnssConstellationType(in.gnssSvs[i].type, out[i].constellation);
}
}
} // namespace implementation
} // namespace V2_0
} // namespace gnss
} // namespace hardware
} // namespace android