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/* 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_BatchingAdapter"
#include <loc_pla.h>
#include <log_util.h>
#include <LocContext.h>
#include <BatchingAdapter.h>
using namespace loc_core;
BatchingAdapter::BatchingAdapter() :
LocAdapterBase(0,
LocContext::getLocContext(LocContext::mLocationHalName),
false, nullptr, true),
mOngoingTripDistance(0),
mOngoingTripTBFInterval(0),
mTripWithOngoingTBFDropped(false),
mTripWithOngoingTripDistanceDropped(false),
mBatchingTimeout(0),
mBatchingAccuracy(1),
mBatchSize(0),
mTripBatchSize(0)
{
LOC_LOGD("%s]: Constructor", __func__);
readConfigCommand();
setConfigCommand();
// at last step, let us inform adapater base that we are done
// with initialization, e.g.: ready to process handleEngineUpEvent
doneInit();
}
void
BatchingAdapter::readConfigCommand()
{
LOC_LOGD("%s]: ", __func__);
struct MsgReadConfig : public LocMsg {
BatchingAdapter& mAdapter;
inline MsgReadConfig(BatchingAdapter& adapter) :
LocMsg(),
mAdapter(adapter) {}
inline virtual void proc() const {
uint32_t batchingTimeout = 0;
uint32_t batchingAccuracy = 0;
uint32_t batchSize = 0;
uint32_t tripBatchSize = 0;
static const loc_param_s_type flp_conf_param_table[] =
{
{"BATCH_SIZE", &batchSize, NULL, 'n'},
{"OUTDOOR_TRIP_BATCH_SIZE", &tripBatchSize, NULL, 'n'},
{"BATCH_SESSION_TIMEOUT", &batchingTimeout, NULL, 'n'},
{"ACCURACY", &batchingAccuracy, NULL, 'n'},
};
UTIL_READ_CONF(LOC_PATH_FLP_CONF, flp_conf_param_table);
LOC_LOGD("%s]: batchSize %u tripBatchSize %u batchingAccuracy %u batchingTimeout %u ",
__func__, batchSize, tripBatchSize, batchingAccuracy, batchingTimeout);
mAdapter.setBatchSize(batchSize);
mAdapter.setTripBatchSize(tripBatchSize);
mAdapter.setBatchingTimeout(batchingTimeout);
mAdapter.setBatchingAccuracy(batchingAccuracy);
}
};
sendMsg(new MsgReadConfig(*this));
}
void
BatchingAdapter::setConfigCommand()
{
LOC_LOGD("%s]: ", __func__);
struct MsgSetConfig : public LocMsg {
BatchingAdapter& mAdapter;
LocApiBase& mApi;
inline MsgSetConfig(BatchingAdapter& adapter,
LocApiBase& api) :
LocMsg(),
mAdapter(adapter),
mApi(api) {}
inline virtual void proc() const {
mApi.setBatchSize(mAdapter.getBatchSize());
mApi.setTripBatchSize(mAdapter.getTripBatchSize());
}
};
sendMsg(new MsgSetConfig(*this, *mLocApi));
}
void
BatchingAdapter::stopClientSessions(LocationAPI* client)
{
LOC_LOGD("%s]: client %p", __func__, client);
typedef struct pairKeyBatchMode {
LocationAPI* client;
uint32_t id;
BatchingMode batchingMode;
inline pairKeyBatchMode(LocationAPI* _client, uint32_t _id, BatchingMode _bMode) :
client(_client), id(_id), batchingMode(_bMode) {}
} pairKeyBatchMode;
std::vector<pairKeyBatchMode> vBatchingClient;
for (auto it : mBatchingSessions) {
if (client == it.first.client) {
vBatchingClient.emplace_back(it.first.client, it.first.id, it.second.batchingMode);
}
}
for (auto keyBatchingMode : vBatchingClient) {
if (keyBatchingMode.batchingMode != BATCHING_MODE_TRIP) {
stopBatching(keyBatchingMode.client, keyBatchingMode.id);
} else {
stopTripBatchingMultiplex(keyBatchingMode.client, keyBatchingMode.id);
}
}
}
void
BatchingAdapter::updateClientsEventMask()
{
LOC_API_ADAPTER_EVENT_MASK_T mask = 0;
for (auto it=mClientData.begin(); it != mClientData.end(); ++it) {
// we don't register LOC_API_ADAPTER_BIT_BATCH_FULL until we
// start batching with ROUTINE or TRIP option
if (it->second.batchingCb != nullptr) {
mask |= LOC_API_ADAPTER_BIT_BATCH_STATUS;
}
}
if (autoReportBatchingSessionsCount() > 0) {
mask |= LOC_API_ADAPTER_BIT_BATCH_FULL;
}
updateEvtMask(mask, LOC_REGISTRATION_MASK_SET);
}
void
BatchingAdapter::handleEngineUpEvent()
{
struct MsgSSREvent : public LocMsg {
BatchingAdapter& mAdapter;
LocApiBase& mApi;
inline MsgSSREvent(BatchingAdapter& adapter,
LocApiBase& api) :
LocMsg(),
mAdapter(adapter),
mApi(api) {}
virtual void proc() const {
mAdapter.setEngineCapabilitiesKnown(true);
mAdapter.broadcastCapabilities(mAdapter.getCapabilities());
mApi.setBatchSize(mAdapter.getBatchSize());
mApi.setTripBatchSize(mAdapter.getTripBatchSize());
mAdapter.restartSessions();
for (auto msg: mAdapter.mPendingMsgs) {
mAdapter.sendMsg(msg);
}
mAdapter.mPendingMsgs.clear();
}
};
sendMsg(new MsgSSREvent(*this, *mLocApi));
}
void
BatchingAdapter::restartSessions()
{
LOC_LOGD("%s]: ", __func__);
if (autoReportBatchingSessionsCount() > 0) {
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_ENABLED);
}
for (auto it = mBatchingSessions.begin();
it != mBatchingSessions.end(); ++it) {
if (it->second.batchingMode != BATCHING_MODE_TRIP) {
mLocApi->startBatching(it->first.id, it->second,
getBatchingAccuracy(), getBatchingTimeout(),
new LocApiResponse(*getContext(),
[] (LocationError /*err*/) {}));
}
}
if (mTripSessions.size() > 0) {
// restart outdoor trip batching session if any.
mOngoingTripDistance = 0;
mOngoingTripTBFInterval = 0;
// record the min trip distance and min tbf interval of all ongoing sessions
for (auto tripSession : mTripSessions) {
TripSessionStatus &tripSessStatus = tripSession.second;
if ((0 == mOngoingTripDistance) ||
(mOngoingTripDistance >
(tripSessStatus.tripDistance - tripSessStatus.accumulatedDistanceThisTrip))) {
mOngoingTripDistance = tripSessStatus.tripDistance -
tripSessStatus.accumulatedDistanceThisTrip;
}
if ((0 == mOngoingTripTBFInterval) ||
(mOngoingTripTBFInterval > tripSessStatus.tripTBFInterval)) {
mOngoingTripTBFInterval = tripSessStatus.tripTBFInterval;
}
// reset the accumulatedDistanceOngoingBatch for each session
tripSessStatus.accumulatedDistanceOngoingBatch = 0;
}
mLocApi->startOutdoorTripBatching(mOngoingTripDistance, mOngoingTripTBFInterval,
getBatchingTimeout(), new LocApiResponse(*getContext(), [this] (LocationError err) {
if (LOCATION_ERROR_SUCCESS != err) {
mOngoingTripDistance = 0;
mOngoingTripTBFInterval = 0;
}
printTripReport();
}));
}
}
bool
BatchingAdapter::hasBatchingCallback(LocationAPI* client)
{
auto it = mClientData.find(client);
return (it != mClientData.end() && it->second.batchingCb);
}
bool
BatchingAdapter::isBatchingSession(LocationAPI* client, uint32_t sessionId)
{
LocationSessionKey key(client, sessionId);
return (mBatchingSessions.find(key) != mBatchingSessions.end());
}
bool
BatchingAdapter::isTripSession(uint32_t sessionId) {
return (mTripSessions.find(sessionId) != mTripSessions.end());
}
void
BatchingAdapter::saveBatchingSession(LocationAPI* client, uint32_t sessionId,
const BatchingOptions& batchingOptions)
{
LocationSessionKey key(client, sessionId);
mBatchingSessions[key] = batchingOptions;
}
void
BatchingAdapter::eraseBatchingSession(LocationAPI* client, uint32_t sessionId)
{
LocationSessionKey key(client, sessionId);
auto it = mBatchingSessions.find(key);
if (it != mBatchingSessions.end()) {
mBatchingSessions.erase(it);
}
}
void
BatchingAdapter::reportResponse(LocationAPI* client, LocationError err, uint32_t sessionId)
{
LOC_LOGD("%s]: client %p id %u err %u", __func__, client, sessionId, err);
auto it = mClientData.find(client);
if (it != mClientData.end() &&
it->second.responseCb != nullptr) {
it->second.responseCb(err, sessionId);
} else {
LOC_LOGE("%s]: client %p id %u not found in data", __func__, client, sessionId);
}
}
uint32_t
BatchingAdapter::autoReportBatchingSessionsCount()
{
uint32_t count = 0;
for (auto batchingSession: mBatchingSessions) {
if (batchingSession.second.batchingMode != BATCHING_MODE_NO_AUTO_REPORT) {
count++;
}
}
count += mTripSessions.size();
return count;
}
uint32_t
BatchingAdapter::startBatchingCommand(
LocationAPI* client, BatchingOptions& batchOptions)
{
uint32_t sessionId = generateSessionId();
LOC_LOGD("%s]: client %p id %u minInterval %u minDistance %u mode %u Batching Mode %d",
__func__, client, sessionId, batchOptions.minInterval, batchOptions.minDistance,
batchOptions.mode,batchOptions.batchingMode);
struct MsgStartBatching : public LocMsg {
BatchingAdapter& mAdapter;
LocApiBase& mApi;
LocationAPI* mClient;
uint32_t mSessionId;
BatchingOptions mBatchingOptions;
inline MsgStartBatching(BatchingAdapter& adapter,
LocApiBase& api,
LocationAPI* client,
uint32_t sessionId,
BatchingOptions batchOptions) :
LocMsg(),
mAdapter(adapter),
mApi(api),
mClient(client),
mSessionId(sessionId),
mBatchingOptions(batchOptions) {}
inline virtual void proc() const {
if (!mAdapter.isEngineCapabilitiesKnown()) {
mAdapter.mPendingMsgs.push_back(new MsgStartBatching(*this));
return;
}
LocationError err = LOCATION_ERROR_SUCCESS;
if (!mAdapter.hasBatchingCallback(mClient)) {
err = LOCATION_ERROR_CALLBACK_MISSING;
} else if (0 == mBatchingOptions.size) {
err = LOCATION_ERROR_INVALID_PARAMETER;
} else if (!ContextBase::isMessageSupported(
LOC_API_ADAPTER_MESSAGE_DISTANCE_BASE_LOCATION_BATCHING)) {
err = LOCATION_ERROR_NOT_SUPPORTED;
}
if (LOCATION_ERROR_SUCCESS == err) {
if (mBatchingOptions.batchingMode == BATCHING_MODE_ROUTINE ||
mBatchingOptions.batchingMode == BATCHING_MODE_NO_AUTO_REPORT) {
mAdapter.startBatching(mClient, mSessionId, mBatchingOptions);
} else if (mBatchingOptions.batchingMode == BATCHING_MODE_TRIP) {
mAdapter.startTripBatchingMultiplex(mClient, mSessionId, mBatchingOptions);
} else {
mAdapter.reportResponse(mClient, LOCATION_ERROR_INVALID_PARAMETER, mSessionId);
}
}
}
};
sendMsg(new MsgStartBatching(*this, *mLocApi, client, sessionId, batchOptions));
return sessionId;
}
void
BatchingAdapter::startBatching(LocationAPI* client, uint32_t sessionId,
const BatchingOptions& batchingOptions)
{
if (batchingOptions.batchingMode != BATCHING_MODE_NO_AUTO_REPORT &&
0 == autoReportBatchingSessionsCount()) {
// if there is currenty no batching sessions interested in batch full event, then this
// new session will need to register for batch full event
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_ENABLED);
}
// Assume start will be OK, remove session if not
saveBatchingSession(client, sessionId, batchingOptions);
mLocApi->startBatching(sessionId, batchingOptions, getBatchingAccuracy(), getBatchingTimeout(),
new LocApiResponse(*getContext(),
[this, client, sessionId, batchingOptions] (LocationError err) {
if (LOCATION_ERROR_SUCCESS != err) {
eraseBatchingSession(client, sessionId);
}
if (LOCATION_ERROR_SUCCESS != err &&
batchingOptions.batchingMode != BATCHING_MODE_NO_AUTO_REPORT &&
0 == autoReportBatchingSessionsCount()) {
// if we fail to start batching and we have already registered batch full event
// we need to undo that since no sessions are now interested in batch full event
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_DISABLED);
}
reportResponse(client, err, sessionId);
}));
}
void
BatchingAdapter::updateBatchingOptionsCommand(LocationAPI* client, uint32_t id,
BatchingOptions& batchOptions)
{
LOC_LOGD("%s]: client %p id %u minInterval %u minDistance %u mode %u batchMode %u",
__func__, client, id, batchOptions.minInterval,
batchOptions.minDistance, batchOptions.mode,
batchOptions.batchingMode);
struct MsgUpdateBatching : public LocMsg {
BatchingAdapter& mAdapter;
LocApiBase& mApi;
LocationAPI* mClient;
uint32_t mSessionId;
BatchingOptions mBatchOptions;
inline MsgUpdateBatching(BatchingAdapter& adapter,
LocApiBase& api,
LocationAPI* client,
uint32_t sessionId,
BatchingOptions batchOptions) :
LocMsg(),
mAdapter(adapter),
mApi(api),
mClient(client),
mSessionId(sessionId),
mBatchOptions(batchOptions) {}
inline virtual void proc() const {
if (!mAdapter.isEngineCapabilitiesKnown()) {
mAdapter.mPendingMsgs.push_back(new MsgUpdateBatching(*this));
return;
}
LocationError err = LOCATION_ERROR_SUCCESS;
if (!mAdapter.isBatchingSession(mClient, mSessionId)) {
err = LOCATION_ERROR_ID_UNKNOWN;
} else if ((0 == mBatchOptions.size) ||
(mBatchOptions.batchingMode > BATCHING_MODE_NO_AUTO_REPORT)) {
err = LOCATION_ERROR_INVALID_PARAMETER;
}
if (LOCATION_ERROR_SUCCESS == err) {
if (!mAdapter.isTripSession(mSessionId)) {
mAdapter.stopBatching(mClient, mSessionId, true, mBatchOptions);
} else {
mAdapter.stopTripBatchingMultiplex(mClient, mSessionId, true, mBatchOptions);
}
}
}
};
sendMsg(new MsgUpdateBatching(*this, *mLocApi, client, id, batchOptions));
}
void
BatchingAdapter::stopBatchingCommand(LocationAPI* client, uint32_t id)
{
LOC_LOGD("%s]: client %p id %u", __func__, client, id);
struct MsgStopBatching : public LocMsg {
BatchingAdapter& mAdapter;
LocApiBase& mApi;
LocationAPI* mClient;
uint32_t mSessionId;
inline MsgStopBatching(BatchingAdapter& adapter,
LocApiBase& api,
LocationAPI* client,
uint32_t sessionId) :
LocMsg(),
mAdapter(adapter),
mApi(api),
mClient(client),
mSessionId(sessionId) {}
inline virtual void proc() const {
if (!mAdapter.isEngineCapabilitiesKnown()) {
mAdapter.mPendingMsgs.push_back(new MsgStopBatching(*this));
return;
}
LocationError err = LOCATION_ERROR_SUCCESS;
if (!mAdapter.isBatchingSession(mClient, mSessionId)) {
err = LOCATION_ERROR_ID_UNKNOWN;
}
if (LOCATION_ERROR_SUCCESS == err) {
if (mAdapter.isTripSession(mSessionId)) {
mAdapter.stopTripBatchingMultiplex(mClient, mSessionId);
} else {
mAdapter.stopBatching(mClient, mSessionId);
}
}
}
};
sendMsg(new MsgStopBatching(*this, *mLocApi, client, id));
}
void
BatchingAdapter::stopBatching(LocationAPI* client, uint32_t sessionId, bool restartNeeded,
const BatchingOptions& batchOptions)
{
LocationSessionKey key(client, sessionId);
auto it = mBatchingSessions.find(key);
if (it != mBatchingSessions.end()) {
auto flpOptions = it->second;
// Assume stop will be OK, restore session if not
eraseBatchingSession(client, sessionId);
mLocApi->stopBatching(sessionId,
new LocApiResponse(*getContext(),
[this, client, sessionId, flpOptions, restartNeeded, batchOptions]
(LocationError err) {
if (LOCATION_ERROR_SUCCESS != err) {
saveBatchingSession(client, sessionId, batchOptions);
} else {
// if stopBatching is success, unregister for batch full event if this was the last
// batching session that is interested in batch full event
if (0 == autoReportBatchingSessionsCount() &&
flpOptions.batchingMode != BATCHING_MODE_NO_AUTO_REPORT) {
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_DISABLED);
}
if (restartNeeded) {
if (batchOptions.batchingMode == BATCHING_MODE_ROUTINE ||
batchOptions.batchingMode == BATCHING_MODE_NO_AUTO_REPORT) {
startBatching(client, sessionId, batchOptions);
} else if (batchOptions.batchingMode == BATCHING_MODE_TRIP) {
startTripBatchingMultiplex(client, sessionId, batchOptions);
}
}
}
reportResponse(client, err, sessionId);
}));
}
}
void
BatchingAdapter::getBatchedLocationsCommand(LocationAPI* client, uint32_t id, size_t count)
{
LOC_LOGD("%s]: client %p id %u count %zu", __func__, client, id, count);
struct MsgGetBatchedLocations : public LocMsg {
BatchingAdapter& mAdapter;
LocApiBase& mApi;
LocationAPI* mClient;
uint32_t mSessionId;
size_t mCount;
inline MsgGetBatchedLocations(BatchingAdapter& adapter,
LocApiBase& api,
LocationAPI* client,
uint32_t sessionId,
size_t count) :
LocMsg(),
mAdapter(adapter),
mApi(api),
mClient(client),
mSessionId(sessionId),
mCount(count) {}
inline virtual void proc() const {
if (!mAdapter.isEngineCapabilitiesKnown()) {
mAdapter.mPendingMsgs.push_back(new MsgGetBatchedLocations(*this));
return;
}
LocationError err = LOCATION_ERROR_SUCCESS;
if (!mAdapter.hasBatchingCallback(mClient)) {
err = LOCATION_ERROR_CALLBACK_MISSING;
} else if (!mAdapter.isBatchingSession(mClient, mSessionId)) {
err = LOCATION_ERROR_ID_UNKNOWN;
}
if (LOCATION_ERROR_SUCCESS == err) {
if (mAdapter.isTripSession(mSessionId)) {
mApi.getBatchedTripLocations(mCount, 0,
new LocApiResponse(*mAdapter.getContext(),
[&mAdapter = mAdapter, mSessionId = mSessionId,
mClient = mClient] (LocationError err) {
mAdapter.reportResponse(mClient, err, mSessionId);
}));
} else {
mApi.getBatchedLocations(mCount, new LocApiResponse(*mAdapter.getContext(),
[&mAdapter = mAdapter, mSessionId = mSessionId,
mClient = mClient] (LocationError err) {
mAdapter.reportResponse(mClient, err, mSessionId);
}));
}
} else {
mAdapter.reportResponse(mClient, err, mSessionId);
}
}
};
sendMsg(new MsgGetBatchedLocations(*this, *mLocApi, client, id, count));
}
void
BatchingAdapter::reportLocationsEvent(const Location* locations, size_t count,
BatchingMode batchingMode)
{
LOC_LOGD("%s]: count %zu batchMode %d", __func__, count, batchingMode);
struct MsgReportLocations : public LocMsg {
BatchingAdapter& mAdapter;
Location* mLocations;
size_t mCount;
BatchingMode mBatchingMode;
inline MsgReportLocations(BatchingAdapter& adapter,
const Location* locations,
size_t count,
BatchingMode batchingMode) :
LocMsg(),
mAdapter(adapter),
mLocations(new Location[count]),
mCount(count),
mBatchingMode(batchingMode)
{
if (nullptr == mLocations) {
LOC_LOGE("%s]: new failed to allocate mLocations", __func__);
return;
}
for (size_t i=0; i < mCount; ++i) {
mLocations[i] = locations[i];
}
}
inline virtual ~MsgReportLocations() {
if (nullptr != mLocations)
delete[] mLocations;
}
inline virtual void proc() const {
mAdapter.reportLocations(mLocations, mCount, mBatchingMode);
}
};
sendMsg(new MsgReportLocations(*this, locations, count, batchingMode));
}
void
BatchingAdapter::reportLocations(Location* locations, size_t count, BatchingMode batchingMode)
{
BatchingOptions batchOptions = {sizeof(BatchingOptions), batchingMode};
for (auto it=mClientData.begin(); it != mClientData.end(); ++it) {
if (nullptr != it->second.batchingCb) {
it->second.batchingCb(count, locations, batchOptions);
}
}
}
void
BatchingAdapter::reportCompletedTripsEvent(uint32_t accumulated_distance)
{
struct MsgReportCompletedTrips : public LocMsg {
BatchingAdapter& mAdapter;
uint32_t mAccumulatedDistance;
inline MsgReportCompletedTrips(BatchingAdapter& adapter,
uint32_t accumulated_distance) :
LocMsg(),
mAdapter(adapter),
mAccumulatedDistance(accumulated_distance)
{
}
inline virtual ~MsgReportCompletedTrips() {
}
inline virtual void proc() const {
// Check if any trips are completed
std::list<uint32_t> completedTripsList;
completedTripsList.clear();
for(auto itt = mAdapter.mTripSessions.begin(); itt != mAdapter.mTripSessions.end();)
{
TripSessionStatus &tripSession = itt->second;
tripSession.accumulatedDistanceThisTrip =
tripSession.accumulatedDistanceOnTripRestart
+ (mAccumulatedDistance - tripSession.accumulatedDistanceOngoingBatch);
if (tripSession.tripDistance <= tripSession.accumulatedDistanceThisTrip) {
// trip is completed
completedTripsList.push_back(itt->first);
itt = mAdapter.mTripSessions.erase(itt);
if (tripSession.tripTBFInterval == mAdapter.mOngoingTripTBFInterval) {
// trip with ongoing TBF interval is completed
mAdapter.mTripWithOngoingTBFDropped = true;
}
if (tripSession.tripDistance == mAdapter.mOngoingTripDistance) {
// trip with ongoing trip distance is completed
mAdapter.mTripWithOngoingTripDistanceDropped = true;
}
} else {
itt++;
}
}
if (completedTripsList.size() > 0) {
mAdapter.reportBatchStatusChange(BATCHING_STATUS_TRIP_COMPLETED,
completedTripsList);
mAdapter.restartTripBatching(false, mAccumulatedDistance, 0);
} else {
mAdapter.printTripReport();
}
}
};
LOC_LOGD("%s]: Accumulated Distance so far: %u",
__func__, accumulated_distance);
sendMsg(new MsgReportCompletedTrips(*this, accumulated_distance));
}
void
BatchingAdapter::reportBatchStatusChange(BatchingStatus batchStatus,
std::list<uint32_t> & completedTripsList)
{
BatchingStatusInfo batchStatusInfo =
{sizeof(BatchingStatusInfo), batchStatus};
for (auto it=mClientData.begin(); it != mClientData.end(); ++it) {
if (nullptr != it->second.batchingStatusCb) {
it->second.batchingStatusCb(batchStatusInfo, completedTripsList);
}
}
}
void
BatchingAdapter::reportBatchStatusChangeEvent(BatchingStatus batchStatus)
{
struct MsgReportBatchStatus : public LocMsg {
BatchingAdapter& mAdapter;
BatchingStatus mBatchStatus;
inline MsgReportBatchStatus(BatchingAdapter& adapter,
BatchingStatus batchStatus) :
LocMsg(),
mAdapter(adapter),
mBatchStatus(batchStatus)
{
}
inline virtual ~MsgReportBatchStatus() {
}
inline virtual void proc() const {
std::list<uint32_t> tempList;
tempList.clear();
mAdapter.reportBatchStatusChange(mBatchStatus, tempList);
}
};
sendMsg(new MsgReportBatchStatus(*this, batchStatus));
}
void
BatchingAdapter::startTripBatchingMultiplex(LocationAPI* client, uint32_t sessionId,
const BatchingOptions& batchingOptions)
{
if (mTripSessions.size() == 0) {
// if there is currenty no batching sessions interested in batch full event, then this
// new session will need to register for batch full event
if (0 == autoReportBatchingSessionsCount()) {
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_ENABLED);
}
// Assume start will be OK, remove session if not
saveBatchingSession(client, sessionId, batchingOptions);
mTripSessions[sessionId] = { 0, 0, 0, batchingOptions.minDistance,
batchingOptions.minInterval};
mLocApi->startOutdoorTripBatching(batchingOptions.minDistance,
batchingOptions.minInterval, getBatchingTimeout(), new LocApiResponse(*getContext(),
[this, client, sessionId, batchingOptions] (LocationError err) {
if (err == LOCATION_ERROR_SUCCESS) {
mOngoingTripDistance = batchingOptions.minDistance;
mOngoingTripTBFInterval = batchingOptions.minInterval;
LOC_LOGD("%s] New Trip started ...", __func__);
printTripReport();
} else {
eraseBatchingSession(client, sessionId);
mTripSessions.erase(sessionId);
// if we fail to start batching and we have already registered batch full event
// we need to undo that since no sessions are now interested in batch full event
if (0 == autoReportBatchingSessionsCount()) {
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_DISABLED);
}
}
reportResponse(client, err, sessionId);
}));
} else {
// query accumulated distance
mLocApi->queryAccumulatedTripDistance(
new LocApiResponseData<LocApiBatchData>(*getContext(),
[this, batchingOptions, sessionId, client]
(LocationError err, LocApiBatchData data) {
uint32_t accumulatedDistanceOngoingBatch = 0;
uint32_t numOfBatchedPositions = 0;
uint32_t ongoingTripDistance = mOngoingTripDistance;
uint32_t ongoingTripInterval = mOngoingTripTBFInterval;
bool needsRestart = false;
// check if TBF of new session is lesser than ongoing TBF interval
if (ongoingTripInterval > batchingOptions.minInterval) {
ongoingTripInterval = batchingOptions.minInterval;
needsRestart = true;
}
accumulatedDistanceOngoingBatch = data.accumulatedDistance;
numOfBatchedPositions = data.numOfBatchedPositions;
TripSessionStatus newTripSession = { accumulatedDistanceOngoingBatch, 0, 0,
batchingOptions.minDistance,
batchingOptions.minInterval};
if (err != LOCATION_ERROR_SUCCESS) {
// unable to query accumulated distance, assume remaining distance in
// ongoing batch is mongoingTripDistance.
if (batchingOptions.minDistance < ongoingTripDistance) {
ongoingTripDistance = batchingOptions.minDistance;
needsRestart = true;
}
} else {
// compute the remaining distance
uint32_t ongoing_trip_remaining_distance = ongoingTripDistance -
accumulatedDistanceOngoingBatch;
// check if new trip distance is lesser than the ongoing batch remaining distance
if (batchingOptions.minDistance < ongoing_trip_remaining_distance) {
ongoingTripDistance = batchingOptions.minDistance;
needsRestart = true;
} else if (needsRestart == true) {
// needsRestart is anyways true , may be because of lesser TBF of new session.
ongoingTripDistance = ongoing_trip_remaining_distance;
}
mTripSessions[sessionId] = newTripSession;
LOC_LOGD("%s] New Trip started ...", __func__);
printTripReport();
}
if (needsRestart) {
mOngoingTripDistance = ongoingTripDistance;
mOngoingTripTBFInterval = ongoingTripInterval;
// reset the accumulatedDistanceOngoingBatch for each session,
// and record the total accumulated distance so far for the session.
for (auto itt = mTripSessions.begin(); itt != mTripSessions.end(); itt++) {
TripSessionStatus &tripSessStatus = itt->second;
tripSessStatus.accumulatedDistanceOngoingBatch = 0;
tripSessStatus.accumulatedDistanceOnTripRestart =
tripSessStatus.accumulatedDistanceThisTrip;
}
mLocApi->reStartOutdoorTripBatching(ongoingTripDistance, ongoingTripInterval,
getBatchingTimeout(), new LocApiResponse(*getContext(),
[this, client, sessionId] (LocationError err) {
if (err != LOCATION_ERROR_SUCCESS) {
LOC_LOGE("%s] New Trip restart failed!", __func__);
}
reportResponse(client, err, sessionId);
}));
} else {
reportResponse(client, LOCATION_ERROR_SUCCESS, sessionId);
}
}));
}
}
void
BatchingAdapter::stopTripBatchingMultiplex(LocationAPI* client, uint32_t sessionId,
bool restartNeeded, const BatchingOptions& batchOptions)
{
LocationError err = LOCATION_ERROR_SUCCESS;
if (mTripSessions.size() == 1) {
mLocApi->stopOutdoorTripBatching(true, new LocApiResponse(*getContext(),
[this, restartNeeded, client, sessionId, batchOptions]
(LocationError err) {
if (LOCATION_ERROR_SUCCESS == err) {
// if stopOutdoorTripBatching is success, unregister for batch full event if this
// was the last batching session that is interested in batch full event
if (1 == autoReportBatchingSessionsCount()) {
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_DISABLED);
}
}
stopTripBatchingMultiplexCommon(err, client, sessionId, restartNeeded, batchOptions);
}));
return;
}
stopTripBatchingMultiplexCommon(err, client, sessionId, restartNeeded, batchOptions);
}
void
BatchingAdapter::stopTripBatchingMultiplexCommon(LocationError err, LocationAPI* client,
uint32_t sessionId, bool restartNeeded, const BatchingOptions& batchOptions)
{
auto itt = mTripSessions.find(sessionId);
TripSessionStatus tripSess = itt->second;
if (tripSess.tripTBFInterval == mOngoingTripTBFInterval) {
// trip with ongoing trip interval is stopped
mTripWithOngoingTBFDropped = true;
}
if (tripSess.tripDistance == mOngoingTripDistance) {
// trip with ongoing trip distance is stopped
mTripWithOngoingTripDistanceDropped = true;
}
mTripSessions.erase(sessionId);
if (mTripSessions.size() == 0) {
mOngoingTripDistance = 0;
mOngoingTripTBFInterval = 0;
} else {
restartTripBatching(true);
}
if (restartNeeded) {
eraseBatchingSession(client, sessionId);
if (batchOptions.batchingMode == BATCHING_MODE_ROUTINE ||
batchOptions.batchingMode == BATCHING_MODE_NO_AUTO_REPORT) {
startBatching(client, sessionId, batchOptions);
} else if (batchOptions.batchingMode == BATCHING_MODE_TRIP) {
startTripBatchingMultiplex(client, sessionId, batchOptions);
}
}
reportResponse(client, err, sessionId);
}
void
BatchingAdapter::restartTripBatching(bool queryAccumulatedDistance, uint32_t accDist,
uint32_t numbatchedPos)
{
// does batch need restart with new trip distance / TBF interval
uint32_t minRemainingDistance = 0;
uint32_t minTBFInterval = 0;
// if no more trips left, stop the ongoing trip
if (mTripSessions.size() == 0) {
mLocApi->stopOutdoorTripBatching(true, new LocApiResponse(*getContext(),
[] (LocationError /*err*/) {}));
mOngoingTripDistance = 0;
mOngoingTripTBFInterval = 0;
// unregister for batch full event if there are no more
// batching session that is interested in batch full event
if (0 == autoReportBatchingSessionsCount()) {
updateEvtMask(LOC_API_ADAPTER_BIT_BATCH_FULL,
LOC_REGISTRATION_MASK_DISABLED);
}
return;
}
// record the min trip distance and min tbf interval of all ongoing sessions
for (auto itt = mTripSessions.begin(); itt != mTripSessions.end(); itt++) {
TripSessionStatus tripSessStatus = itt->second;
if ((minRemainingDistance == 0) ||
(minRemainingDistance > (tripSessStatus.tripDistance
- tripSessStatus.accumulatedDistanceThisTrip))) {
minRemainingDistance = tripSessStatus.tripDistance -
tripSessStatus.accumulatedDistanceThisTrip;
}
if ((minTBFInterval == 0) ||
(minTBFInterval > tripSessStatus.tripTBFInterval)) {
minTBFInterval = tripSessStatus.tripTBFInterval;
}
}
mLocApi->queryAccumulatedTripDistance(
new LocApiResponseData<LocApiBatchData>(*getContext(),
[this, queryAccumulatedDistance, minRemainingDistance, minTBFInterval, accDist,
numbatchedPos] (LocationError /*err*/, LocApiBatchData data) {
bool needsRestart = false;
uint32_t ongoingTripDistance = mOngoingTripDistance;
uint32_t ongoingTripInterval = mOngoingTripTBFInterval;
uint32_t accumulatedDistance = accDist;
uint32_t numOfBatchedPositions = numbatchedPos;
if (queryAccumulatedDistance) {
accumulatedDistance = data.accumulatedDistance;
numOfBatchedPositions = data.numOfBatchedPositions;
}
if ((!mTripWithOngoingTripDistanceDropped) &&
(ongoingTripDistance - accumulatedDistance != 0)) {
// if ongoing trip is already not completed still,
// check the min distance against the remaining distance
if (minRemainingDistance <
(ongoingTripDistance - accumulatedDistance)) {
ongoingTripDistance = minRemainingDistance;
needsRestart = true;
}
} else if (minRemainingDistance != 0) {
// else if ongoing trip is already completed / dropped,
// use the minRemainingDistance of ongoing sessions
ongoingTripDistance = minRemainingDistance;
needsRestart = true;
}
if ((minTBFInterval < ongoingTripInterval) ||
((minTBFInterval != ongoingTripInterval) &&
(mTripWithOngoingTBFDropped))) {
ongoingTripInterval = minTBFInterval;
needsRestart = true;
}
if (needsRestart) {
mLocApi->reStartOutdoorTripBatching(ongoingTripDistance, ongoingTripInterval,
getBatchingTimeout(), new LocApiResponse(*getContext(),
[this, accumulatedDistance, ongoingTripDistance, ongoingTripInterval]
(LocationError err) {
if (err == LOCATION_ERROR_SUCCESS) {
for(auto itt = mTripSessions.begin(); itt != mTripSessions.end(); itt++) {
TripSessionStatus &tripSessStatus = itt->second;
tripSessStatus.accumulatedDistanceThisTrip =
tripSessStatus.accumulatedDistanceOnTripRestart +
(accumulatedDistance -
tripSessStatus.accumulatedDistanceOngoingBatch);
tripSessStatus.accumulatedDistanceOngoingBatch = 0;
tripSessStatus.accumulatedDistanceOnTripRestart =
tripSessStatus.accumulatedDistanceThisTrip;
}
mOngoingTripDistance = ongoingTripDistance;
mOngoingTripTBFInterval = ongoingTripInterval;
}
}));
}
}));
}
void
BatchingAdapter::printTripReport()
{
IF_LOC_LOGD {
LOC_LOGD("Ongoing Trip Distance = %u, Ongoing Trip TBF Interval = %u",
mOngoingTripDistance, mOngoingTripTBFInterval);
for (auto itt = mTripSessions.begin(); itt != mTripSessions.end(); itt++) {
TripSessionStatus tripSessStatus = itt->second;
LOC_LOGD("tripDistance:%u tripTBFInterval:%u"
" trip accumulated Distance:%u"
" trip accumualted distance ongoing batch:%u"
" trip accumulated distance on trip restart %u \r\n",
tripSessStatus.tripDistance, tripSessStatus.tripTBFInterval,
tripSessStatus.accumulatedDistanceThisTrip,
tripSessStatus.accumulatedDistanceOngoingBatch,
tripSessStatus.accumulatedDistanceOnTripRestart);
}
}
}