cmds/statsd/src/StatsLogProcessor.cpp - platform/frameworks/base - Gitiles

 /*
  * Copyright (C) 2017 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.
  */

 #define DEBUG true  // STOPSHIP if true
 #include "Log.h"
 #include "statslog.h"

 #include <android-base/file.h>
 #include <dirent.h>
 #include "StatsLogProcessor.h"
 #include "stats_log_util.h"
 #include "android-base/stringprintf.h"
 #include "guardrail/StatsdStats.h"
 #include "metrics/CountMetricProducer.h"
 #include "external/StatsPullerManager.h"
 #include "stats_util.h"
 #include "storage/StorageManager.h"

 #include <log/log_event_list.h>
 #include <utils/Errors.h>
 #include <utils/SystemClock.h>

 using namespace android;
 using android::base::StringPrintf;
 using android::util::FIELD_COUNT_REPEATED;
 using android::util::FIELD_TYPE_BOOL;
 using android::util::FIELD_TYPE_FLOAT;
 using android::util::FIELD_TYPE_INT32;
 using android::util::FIELD_TYPE_INT64;
 using android::util::FIELD_TYPE_MESSAGE;
 using android::util::FIELD_TYPE_STRING;
 using android::util::ProtoOutputStream;
 using std::make_unique;
 using std::unique_ptr;
 using std::vector;

 namespace android {
 namespace os {
 namespace statsd {

 // for ConfigMetricsReportList
 const int FIELD_ID_CONFIG_KEY = 1;
 const int FIELD_ID_REPORTS = 2;
 // for ConfigKey
 const int FIELD_ID_UID = 1;
 const int FIELD_ID_ID = 2;
 // for ConfigMetricsReport
 // const int FIELD_ID_METRICS = 1; // written in MetricsManager.cpp
 const int FIELD_ID_UID_MAP = 2;
 const int FIELD_ID_LAST_REPORT_ELAPSED_NANOS = 3;
 const int FIELD_ID_CURRENT_REPORT_ELAPSED_NANOS = 4;

 #define STATS_DATA_DIR "/data/misc/stats-data"

 StatsLogProcessor::StatsLogProcessor(const sp<UidMap>& uidMap,
                                      const sp<AlarmMonitor>& anomalyAlarmMonitor,
                                      const sp<AlarmMonitor>& periodicAlarmMonitor,
                                      const long timeBaseSec,
                                      const std::function<void(const ConfigKey&)>& sendBroadcast)
     : mUidMap(uidMap),
       mAnomalyAlarmMonitor(anomalyAlarmMonitor),
       mPeriodicAlarmMonitor(periodicAlarmMonitor),
       mSendBroadcast(sendBroadcast),
       mTimeBaseSec(timeBaseSec),
       mLastLogTimestamp(0) {
     StatsPullerManager statsPullerManager;
     statsPullerManager.SetTimeBaseSec(mTimeBaseSec);
 }

 StatsLogProcessor::~StatsLogProcessor() {
 }

 void StatsLogProcessor::onAnomalyAlarmFired(
         const uint64_t timestampNs,
         unordered_set<sp<const InternalAlarm>, SpHash<InternalAlarm>> alarmSet) {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     for (const auto& itr : mMetricsManagers) {
         itr.second->onAnomalyAlarmFired(timestampNs, alarmSet);
     }
 }
 void StatsLogProcessor::onPeriodicAlarmFired(
         const uint64_t timestampNs,
         unordered_set<sp<const InternalAlarm>, SpHash<InternalAlarm>> alarmSet) {

     std::lock_guard<std::mutex> lock(mMetricsMutex);
     for (const auto& itr : mMetricsManagers) {
         itr.second->onPeriodicAlarmFired(timestampNs, alarmSet);
     }
 }

 void updateUid(Value* value, int hostUid) {
     int uid = value->int_value;
     if (uid != hostUid) {
         value->setInt(hostUid);
     }
 }

 void StatsLogProcessor::mapIsolatedUidToHostUidIfNecessaryLocked(LogEvent* event) const {
     if (android::util::kAtomsWithAttributionChain.find(event->GetTagId()) !=
         android::util::kAtomsWithAttributionChain.end()) {
         for (auto& value : *(event->getMutableValues())) {
             if (value.mField.getPosAtDepth(0) > kAttributionField) {
                 break;
             }
             if (isAttributionUidField(value)) {
                 const int hostUid = mUidMap->getHostUidOrSelf(value.mValue.int_value);
                 updateUid(&value.mValue, hostUid);
             }
         }
     } else if (android::util::kAtomsWithUidField.find(event->GetTagId()) !=
                        android::util::kAtomsWithUidField.end() &&
                event->getValues().size() > 0 && (event->getValues())[0].mValue.getType() == INT) {
         Value& value = (*event->getMutableValues())[0].mValue;
         const int hostUid = mUidMap->getHostUidOrSelf(value.int_value);
         updateUid(&value, hostUid);
     }
 }

 void StatsLogProcessor::onIsolatedUidChangedEventLocked(const LogEvent& event) {
     status_t err = NO_ERROR, err2 = NO_ERROR, err3 = NO_ERROR;
     bool is_create = event.GetBool(3, &err);
     auto parent_uid = int(event.GetLong(1, &err2));
     auto isolated_uid = int(event.GetLong(2, &err3));
     if (err == NO_ERROR && err2 == NO_ERROR && err3 == NO_ERROR) {
         if (is_create) {
             mUidMap->assignIsolatedUid(isolated_uid, parent_uid);
         } else {
             mUidMap->removeIsolatedUid(isolated_uid, parent_uid);
         }
     } else {
         ALOGE("Failed to parse uid in the isolated uid change event.");
     }
 }

 void StatsLogProcessor::OnLogEvent(LogEvent* event) {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     if (event->GetElapsedTimestampNs() < mLastLogTimestamp) {
         return;
     }
     mLastLogTimestamp = event->GetElapsedTimestampNs();
     StatsdStats::getInstance().noteAtomLogged(
         event->GetTagId(), event->GetElapsedTimestampNs() / NS_PER_SEC);

     // Hard-coded logic to update the isolated uid's in the uid-map.
     // The field numbers need to be currently updated by hand with atoms.proto
     if (event->GetTagId() == android::util::ISOLATED_UID_CHANGED) {
         onIsolatedUidChangedEventLocked(*event);
     }

     if (mMetricsManagers.empty()) {
         return;
     }

     uint64_t curTimeSec = getElapsedRealtimeSec();
     if (curTimeSec - mLastPullerCacheClearTimeSec > StatsdStats::kPullerCacheClearIntervalSec) {
         mStatsPullerManager.ClearPullerCacheIfNecessary(curTimeSec);
         mLastPullerCacheClearTimeSec = curTimeSec;
     }

     if (event->GetTagId() != android::util::ISOLATED_UID_CHANGED) {
         // Map the isolated uid to host uid if necessary.
         mapIsolatedUidToHostUidIfNecessaryLocked(event);
     }

     // pass the event to metrics managers.
     for (auto& pair : mMetricsManagers) {
         pair.second->onLogEvent(*event);
         flushIfNecessaryLocked(event->GetElapsedTimestampNs(), pair.first, *(pair.second));
     }
 }

 void StatsLogProcessor::OnConfigUpdated(const ConfigKey& key, const StatsdConfig& config) {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     VLOG("Updated configuration for key %s", key.ToString().c_str());
     sp<MetricsManager> newMetricsManager =
         new MetricsManager(key, config, mTimeBaseSec, mUidMap,
                            mAnomalyAlarmMonitor, mPeriodicAlarmMonitor);
     auto it = mMetricsManagers.find(key);
     if (it == mMetricsManagers.end() && mMetricsManagers.size() > StatsdStats::kMaxConfigCount) {
         ALOGE("Can't accept more configs!");
         return;
     }

     if (newMetricsManager->isConfigValid()) {
         mUidMap->OnConfigUpdated(key);
         if (newMetricsManager->shouldAddUidMapListener()) {
             // We have to add listener after the MetricsManager is constructed because it's
             // not safe to create wp or sp from this pointer inside its constructor.
             mUidMap->addListener(newMetricsManager.get());
         }
         mMetricsManagers[key] = newMetricsManager;
         // Why doesn't this work? mMetricsManagers.insert({key, std::move(newMetricsManager)});
         VLOG("StatsdConfig valid");
     } else {
         // If there is any error in the config, don't use it.
         ALOGE("StatsdConfig NOT valid");
     }
 }

 size_t StatsLogProcessor::GetMetricsSize(const ConfigKey& key) const {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     auto it = mMetricsManagers.find(key);
     if (it == mMetricsManagers.end()) {
         ALOGW("Config source %s does not exist", key.ToString().c_str());
         return 0;
     }
     return it->second->byteSize();
 }

 void StatsLogProcessor::dumpStates(FILE* out, bool verbose) {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     fprintf(out, "MetricsManager count: %lu\n", (unsigned long)mMetricsManagers.size());
     for (auto metricsManager : mMetricsManagers) {
         metricsManager.second->dumpStates(out, verbose);
     }
 }

 void StatsLogProcessor::onDumpReport(const ConfigKey& key, const uint64_t dumpTimeStampNs,
                                      vector<uint8_t>* outData) {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     onDumpReportLocked(key, dumpTimeStampNs, outData);
 }

 void StatsLogProcessor::onDumpReportLocked(const ConfigKey& key, const uint64_t dumpTimeStampNs,
                                            vector<uint8_t>* outData) {
     auto it = mMetricsManagers.find(key);
     if (it == mMetricsManagers.end()) {
         ALOGW("Config source %s does not exist", key.ToString().c_str());
         return;
     }

     // This allows another broadcast to be sent within the rate-limit period if we get close to
     // filling the buffer again soon.
     mLastBroadcastTimes.erase(key);

     ProtoOutputStream proto;

     // Start of ConfigKey.
     uint64_t configKeyToken = proto.start(FIELD_TYPE_MESSAGE | FIELD_ID_CONFIG_KEY);
     proto.write(FIELD_TYPE_INT32 | FIELD_ID_UID, key.GetUid());
     proto.write(FIELD_TYPE_INT64 | FIELD_ID_ID, (long long)key.GetId());
     proto.end(configKeyToken);
     // End of ConfigKey.

     // Start of ConfigMetricsReport (reports).
     uint64_t reportsToken =
             proto.start(FIELD_TYPE_MESSAGE | FIELD_COUNT_REPEATED | FIELD_ID_REPORTS);

     int64_t lastReportTimeNs = it->second->getLastReportTimeNs();
     // First, fill in ConfigMetricsReport using current data on memory, which
     // starts from filling in StatsLogReport's.
     it->second->onDumpReport(dumpTimeStampNs, &proto);

     // Fill in UidMap.
     auto uidMap = mUidMap->getOutput(key);
     const int uidMapSize = uidMap.ByteSize();
     char uidMapBuffer[uidMapSize];
     uidMap.SerializeToArray(&uidMapBuffer[0], uidMapSize);
     proto.write(FIELD_TYPE_MESSAGE | FIELD_ID_UID_MAP, uidMapBuffer, uidMapSize);

     // Fill in the timestamps.
     proto.write(FIELD_TYPE_INT64 | FIELD_ID_LAST_REPORT_ELAPSED_NANOS,
                 (long long)lastReportTimeNs);
     proto.write(FIELD_TYPE_INT64 | FIELD_ID_CURRENT_REPORT_ELAPSED_NANOS,
                 (long long)dumpTimeStampNs);

     // End of ConfigMetricsReport (reports).
     proto.end(reportsToken);

     // Then, check stats-data directory to see there's any file containing
     // ConfigMetricsReport from previous shutdowns to concatenate to reports.
     StorageManager::appendConfigMetricsReport(proto);

     if (outData != nullptr) {
         outData->clear();
         outData->resize(proto.size());
         size_t pos = 0;
         auto iter = proto.data();
         while (iter.readBuffer() != NULL) {
             size_t toRead = iter.currentToRead();
             std::memcpy(&((*outData)[pos]), iter.readBuffer(), toRead);
             pos += toRead;
             iter.rp()->move(toRead);
         }
     }

     StatsdStats::getInstance().noteMetricsReportSent(key);
 }

 void StatsLogProcessor::OnConfigRemoved(const ConfigKey& key) {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     auto it = mMetricsManagers.find(key);
     if (it != mMetricsManagers.end()) {
         mMetricsManagers.erase(it);
         mUidMap->OnConfigRemoved(key);
     }
     StatsdStats::getInstance().noteConfigRemoved(key);

     mLastBroadcastTimes.erase(key);

     if (mMetricsManagers.empty()) {
         mStatsPullerManager.ForceClearPullerCache();
     }
 }

 void StatsLogProcessor::flushIfNecessaryLocked(
     uint64_t timestampNs, const ConfigKey& key, MetricsManager& metricsManager) {
     auto lastCheckTime = mLastByteSizeTimes.find(key);
     if (lastCheckTime != mLastByteSizeTimes.end()) {
         if (timestampNs - lastCheckTime->second < StatsdStats::kMinByteSizeCheckPeriodNs) {
             return;
         }
     }

     // We suspect that the byteSize() computation is expensive, so we set a rate limit.
     size_t totalBytes = metricsManager.byteSize();
     mLastByteSizeTimes[key] = timestampNs;
     if (totalBytes >
         StatsdStats::kMaxMetricsBytesPerConfig) {  // Too late. We need to start clearing data.
         metricsManager.dropData(timestampNs);
         StatsdStats::getInstance().noteDataDropped(key);
         VLOG("StatsD had to toss out metrics for %s", key.ToString().c_str());
     } else if (totalBytes > .9 * StatsdStats::kMaxMetricsBytesPerConfig) {
         // Send broadcast so that receivers can pull data.
         auto lastBroadcastTime = mLastBroadcastTimes.find(key);
         if (lastBroadcastTime != mLastBroadcastTimes.end()) {
             if (timestampNs - lastBroadcastTime->second < StatsdStats::kMinBroadcastPeriodNs) {
                 VLOG("StatsD would've sent a broadcast but the rate limit stopped us.");
                 return;
             }
         }
         mLastBroadcastTimes[key] = timestampNs;
         VLOG("StatsD requesting broadcast for %s", key.ToString().c_str());
         mSendBroadcast(key);
         StatsdStats::getInstance().noteBroadcastSent(key);
     }
 }

 void StatsLogProcessor::WriteDataToDisk() {
     std::lock_guard<std::mutex> lock(mMetricsMutex);
     for (auto& pair : mMetricsManagers) {
         const ConfigKey& key = pair.first;
         vector<uint8_t> data;
         onDumpReportLocked(key, getElapsedRealtimeNs(), &data);
         string file_name = StringPrintf("%s/%ld_%d_%lld", STATS_DATA_DIR,
              (long)getWallClockSec(), key.GetUid(), (long long)key.GetId());
         StorageManager::writeFile(file_name.c_str(), &data[0], data.size());
     }
 }

 }  // namespace statsd
 }  // namespace os
 }  // namespace android
	/*
	* Copyright (C) 2017 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.
	*/

	#define DEBUG true // STOPSHIP if true
	#include "Log.h"
	#include "statslog.h"

	#include <android-base/file.h>
	#include <dirent.h>
	#include "StatsLogProcessor.h"
	#include "stats_log_util.h"
	#include "android-base/stringprintf.h"
	#include "guardrail/StatsdStats.h"
	#include "metrics/CountMetricProducer.h"
	#include "external/StatsPullerManager.h"
	#include "stats_util.h"
	#include "storage/StorageManager.h"

	#include <log/log_event_list.h>
	#include <utils/Errors.h>
	#include <utils/SystemClock.h>

	using namespace android;
	using android::base::StringPrintf;
	using android::util::FIELD_COUNT_REPEATED;
	using android::util::FIELD_TYPE_BOOL;
	using android::util::FIELD_TYPE_FLOAT;
	using android::util::FIELD_TYPE_INT32;
	using android::util::FIELD_TYPE_INT64;
	using android::util::FIELD_TYPE_MESSAGE;
	using android::util::FIELD_TYPE_STRING;
	using android::util::ProtoOutputStream;
	using std::make_unique;
	using std::unique_ptr;
	using std::vector;

	namespace android {
	namespace os {
	namespace statsd {

	// for ConfigMetricsReportList
	const int FIELD_ID_CONFIG_KEY = 1;
	const int FIELD_ID_REPORTS = 2;
	// for ConfigKey
	const int FIELD_ID_UID = 1;
	const int FIELD_ID_ID = 2;
	// for ConfigMetricsReport
	// const int FIELD_ID_METRICS = 1; // written in MetricsManager.cpp
	const int FIELD_ID_UID_MAP = 2;
	const int FIELD_ID_LAST_REPORT_ELAPSED_NANOS = 3;
	const int FIELD_ID_CURRENT_REPORT_ELAPSED_NANOS = 4;

	#define STATS_DATA_DIR "/data/misc/stats-data"

	StatsLogProcessor::StatsLogProcessor(const sp<UidMap>& uidMap,
	const sp<AlarmMonitor>& anomalyAlarmMonitor,
	const sp<AlarmMonitor>& periodicAlarmMonitor,
	const long timeBaseSec,
	const std::function<void(const ConfigKey&)>& sendBroadcast)
	: mUidMap(uidMap),
	mAnomalyAlarmMonitor(anomalyAlarmMonitor),
	mPeriodicAlarmMonitor(periodicAlarmMonitor),
	mSendBroadcast(sendBroadcast),
	mTimeBaseSec(timeBaseSec),
	mLastLogTimestamp(0) {
	StatsPullerManager statsPullerManager;
	statsPullerManager.SetTimeBaseSec(mTimeBaseSec);
	}

	StatsLogProcessor::~StatsLogProcessor() {
	}

	void StatsLogProcessor::onAnomalyAlarmFired(
	const uint64_t timestampNs,
	unordered_set<sp<const InternalAlarm>, SpHash<InternalAlarm>> alarmSet) {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	for (const auto& itr : mMetricsManagers) {
	itr.second->onAnomalyAlarmFired(timestampNs, alarmSet);
	}
	}
	void StatsLogProcessor::onPeriodicAlarmFired(
	const uint64_t timestampNs,
	unordered_set<sp<const InternalAlarm>, SpHash<InternalAlarm>> alarmSet) {

	std::lock_guard<std::mutex> lock(mMetricsMutex);
	for (const auto& itr : mMetricsManagers) {
	itr.second->onPeriodicAlarmFired(timestampNs, alarmSet);
	}
	}

	void updateUid(Value* value, int hostUid) {
	int uid = value->int_value;
	if (uid != hostUid) {
	value->setInt(hostUid);
	}
	}

	void StatsLogProcessor::mapIsolatedUidToHostUidIfNecessaryLocked(LogEvent* event) const {
	if (android::util::kAtomsWithAttributionChain.find(event->GetTagId()) !=
	android::util::kAtomsWithAttributionChain.end()) {
	for (auto& value : *(event->getMutableValues())) {
	if (value.mField.getPosAtDepth(0) > kAttributionField) {
	break;
	}
	if (isAttributionUidField(value)) {
	const int hostUid = mUidMap->getHostUidOrSelf(value.mValue.int_value);
	updateUid(&value.mValue, hostUid);
	}
	}
	} else if (android::util::kAtomsWithUidField.find(event->GetTagId()) !=
	android::util::kAtomsWithUidField.end() &&
	event->getValues().size() > 0 && (event->getValues())[0].mValue.getType() == INT) {
	Value& value = (*event->getMutableValues())[0].mValue;
	const int hostUid = mUidMap->getHostUidOrSelf(value.int_value);
	updateUid(&value, hostUid);
	}
	}

	void StatsLogProcessor::onIsolatedUidChangedEventLocked(const LogEvent& event) {
	status_t err = NO_ERROR, err2 = NO_ERROR, err3 = NO_ERROR;
	bool is_create = event.GetBool(3, &err);
	auto parent_uid = int(event.GetLong(1, &err2));
	auto isolated_uid = int(event.GetLong(2, &err3));
	if (err == NO_ERROR && err2 == NO_ERROR && err3 == NO_ERROR) {
	if (is_create) {
	mUidMap->assignIsolatedUid(isolated_uid, parent_uid);
	} else {
	mUidMap->removeIsolatedUid(isolated_uid, parent_uid);
	}
	} else {
	ALOGE("Failed to parse uid in the isolated uid change event.");
	}
	}

	void StatsLogProcessor::OnLogEvent(LogEvent* event) {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	if (event->GetElapsedTimestampNs() < mLastLogTimestamp) {
	return;
	}
	mLastLogTimestamp = event->GetElapsedTimestampNs();
	StatsdStats::getInstance().noteAtomLogged(
	event->GetTagId(), event->GetElapsedTimestampNs() / NS_PER_SEC);

	// Hard-coded logic to update the isolated uid's in the uid-map.
	// The field numbers need to be currently updated by hand with atoms.proto
	if (event->GetTagId() == android::util::ISOLATED_UID_CHANGED) {
	onIsolatedUidChangedEventLocked(*event);
	}

	if (mMetricsManagers.empty()) {
	return;
	}

	uint64_t curTimeSec = getElapsedRealtimeSec();
	if (curTimeSec - mLastPullerCacheClearTimeSec > StatsdStats::kPullerCacheClearIntervalSec) {
	mStatsPullerManager.ClearPullerCacheIfNecessary(curTimeSec);
	mLastPullerCacheClearTimeSec = curTimeSec;
	}

	if (event->GetTagId() != android::util::ISOLATED_UID_CHANGED) {
	// Map the isolated uid to host uid if necessary.
	mapIsolatedUidToHostUidIfNecessaryLocked(event);
	}

	// pass the event to metrics managers.
	for (auto& pair : mMetricsManagers) {
	pair.second->onLogEvent(*event);
	flushIfNecessaryLocked(event->GetElapsedTimestampNs(), pair.first, *(pair.second));
	}
	}

	void StatsLogProcessor::OnConfigUpdated(const ConfigKey& key, const StatsdConfig& config) {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	VLOG("Updated configuration for key %s", key.ToString().c_str());
	sp<MetricsManager> newMetricsManager =
	new MetricsManager(key, config, mTimeBaseSec, mUidMap,
	mAnomalyAlarmMonitor, mPeriodicAlarmMonitor);
	auto it = mMetricsManagers.find(key);
	if (it == mMetricsManagers.end() && mMetricsManagers.size() > StatsdStats::kMaxConfigCount) {
	ALOGE("Can't accept more configs!");
	return;
	}

	if (newMetricsManager->isConfigValid()) {
	mUidMap->OnConfigUpdated(key);
	if (newMetricsManager->shouldAddUidMapListener()) {
	// We have to add listener after the MetricsManager is constructed because it's
	// not safe to create wp or sp from this pointer inside its constructor.
	mUidMap->addListener(newMetricsManager.get());
	}
	mMetricsManagers[key] = newMetricsManager;
	// Why doesn't this work? mMetricsManagers.insert({key, std::move(newMetricsManager)});
	VLOG("StatsdConfig valid");
	} else {
	// If there is any error in the config, don't use it.
	ALOGE("StatsdConfig NOT valid");
	}
	}

	size_t StatsLogProcessor::GetMetricsSize(const ConfigKey& key) const {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	auto it = mMetricsManagers.find(key);
	if (it == mMetricsManagers.end()) {
	ALOGW("Config source %s does not exist", key.ToString().c_str());
	return 0;
	}
	return it->second->byteSize();
	}

	void StatsLogProcessor::dumpStates(FILE* out, bool verbose) {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	fprintf(out, "MetricsManager count: %lu\n", (unsigned long)mMetricsManagers.size());
	for (auto metricsManager : mMetricsManagers) {
	metricsManager.second->dumpStates(out, verbose);
	}
	}

	void StatsLogProcessor::onDumpReport(const ConfigKey& key, const uint64_t dumpTimeStampNs,
	vector<uint8_t>* outData) {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	onDumpReportLocked(key, dumpTimeStampNs, outData);
	}

	void StatsLogProcessor::onDumpReportLocked(const ConfigKey& key, const uint64_t dumpTimeStampNs,
	vector<uint8_t>* outData) {
	auto it = mMetricsManagers.find(key);
	if (it == mMetricsManagers.end()) {
	ALOGW("Config source %s does not exist", key.ToString().c_str());
	return;
	}

	// This allows another broadcast to be sent within the rate-limit period if we get close to
	// filling the buffer again soon.
	mLastBroadcastTimes.erase(key);

	ProtoOutputStream proto;

	// Start of ConfigKey.
	uint64_t configKeyToken = proto.start(FIELD_TYPE_MESSAGE \| FIELD_ID_CONFIG_KEY);
	proto.write(FIELD_TYPE_INT32 \| FIELD_ID_UID, key.GetUid());
	proto.write(FIELD_TYPE_INT64 \| FIELD_ID_ID, (long long)key.GetId());
	proto.end(configKeyToken);
	// End of ConfigKey.

	// Start of ConfigMetricsReport (reports).
	uint64_t reportsToken =
	proto.start(FIELD_TYPE_MESSAGE \| FIELD_COUNT_REPEATED \| FIELD_ID_REPORTS);

	int64_t lastReportTimeNs = it->second->getLastReportTimeNs();
	// First, fill in ConfigMetricsReport using current data on memory, which
	// starts from filling in StatsLogReport's.
	it->second->onDumpReport(dumpTimeStampNs, &proto);

	// Fill in UidMap.
	auto uidMap = mUidMap->getOutput(key);
	const int uidMapSize = uidMap.ByteSize();
	char uidMapBuffer[uidMapSize];
	uidMap.SerializeToArray(&uidMapBuffer[0], uidMapSize);
	proto.write(FIELD_TYPE_MESSAGE \| FIELD_ID_UID_MAP, uidMapBuffer, uidMapSize);

	// Fill in the timestamps.
	proto.write(FIELD_TYPE_INT64 \| FIELD_ID_LAST_REPORT_ELAPSED_NANOS,
	(long long)lastReportTimeNs);
	proto.write(FIELD_TYPE_INT64 \| FIELD_ID_CURRENT_REPORT_ELAPSED_NANOS,
	(long long)dumpTimeStampNs);

	// End of ConfigMetricsReport (reports).
	proto.end(reportsToken);

	// Then, check stats-data directory to see there's any file containing
	// ConfigMetricsReport from previous shutdowns to concatenate to reports.
	StorageManager::appendConfigMetricsReport(proto);

	if (outData != nullptr) {
	outData->clear();
	outData->resize(proto.size());
	size_t pos = 0;
	auto iter = proto.data();
	while (iter.readBuffer() != NULL) {
	size_t toRead = iter.currentToRead();
	std::memcpy(&((*outData)[pos]), iter.readBuffer(), toRead);
	pos += toRead;
	iter.rp()->move(toRead);
	}
	}

	StatsdStats::getInstance().noteMetricsReportSent(key);
	}

	void StatsLogProcessor::OnConfigRemoved(const ConfigKey& key) {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	auto it = mMetricsManagers.find(key);
	if (it != mMetricsManagers.end()) {
	mMetricsManagers.erase(it);
	mUidMap->OnConfigRemoved(key);
	}
	StatsdStats::getInstance().noteConfigRemoved(key);

	mLastBroadcastTimes.erase(key);

	if (mMetricsManagers.empty()) {
	mStatsPullerManager.ForceClearPullerCache();
	}
	}

	void StatsLogProcessor::flushIfNecessaryLocked(
	uint64_t timestampNs, const ConfigKey& key, MetricsManager& metricsManager) {
	auto lastCheckTime = mLastByteSizeTimes.find(key);
	if (lastCheckTime != mLastByteSizeTimes.end()) {
	if (timestampNs - lastCheckTime->second < StatsdStats::kMinByteSizeCheckPeriodNs) {
	return;
	}
	}

	// We suspect that the byteSize() computation is expensive, so we set a rate limit.
	size_t totalBytes = metricsManager.byteSize();
	mLastByteSizeTimes[key] = timestampNs;
	if (totalBytes >
	StatsdStats::kMaxMetricsBytesPerConfig) { // Too late. We need to start clearing data.
	metricsManager.dropData(timestampNs);
	StatsdStats::getInstance().noteDataDropped(key);
	VLOG("StatsD had to toss out metrics for %s", key.ToString().c_str());
	} else if (totalBytes > .9 * StatsdStats::kMaxMetricsBytesPerConfig) {
	// Send broadcast so that receivers can pull data.
	auto lastBroadcastTime = mLastBroadcastTimes.find(key);
	if (lastBroadcastTime != mLastBroadcastTimes.end()) {
	if (timestampNs - lastBroadcastTime->second < StatsdStats::kMinBroadcastPeriodNs) {
	VLOG("StatsD would've sent a broadcast but the rate limit stopped us.");
	return;
	}
	}
	mLastBroadcastTimes[key] = timestampNs;
	VLOG("StatsD requesting broadcast for %s", key.ToString().c_str());
	mSendBroadcast(key);
	StatsdStats::getInstance().noteBroadcastSent(key);
	}
	}

	void StatsLogProcessor::WriteDataToDisk() {
	std::lock_guard<std::mutex> lock(mMetricsMutex);
	for (auto& pair : mMetricsManagers) {
	const ConfigKey& key = pair.first;
	vector<uint8_t> data;
	onDumpReportLocked(key, getElapsedRealtimeNs(), &data);
	string file_name = StringPrintf("%s/%ld_%d_%lld", STATS_DATA_DIR,
	(long)getWallClockSec(), key.GetUid(), (long long)key.GetId());
	StorageManager::writeFile(file_name.c_str(), &data[0], data.size());
	}
	}

	} // namespace statsd
	} // namespace os
	} // namespace android