blob: 41000dae146249d6c61850e876c166875c814001 [file] [log] [blame]
/*
* 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 false // STOPSHIP if true
#include "Log.h"
#include "../guardrail/StatsdStats.h"
#include "GaugeMetricProducer.h"
#include "../stats_log_util.h"
#include <cutils/log.h>
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::map;
using std::string;
using std::unordered_map;
using std::vector;
using std::make_shared;
using std::shared_ptr;
namespace android {
namespace os {
namespace statsd {
// for StatsLogReport
const int FIELD_ID_ID = 1;
const int FIELD_ID_GAUGE_METRICS = 8;
const int FIELD_ID_TIME_BASE = 9;
const int FIELD_ID_BUCKET_SIZE = 10;
const int FIELD_ID_DIMENSION_PATH_IN_WHAT = 11;
const int FIELD_ID_DIMENSION_PATH_IN_CONDITION = 12;
const int FIELD_ID_IS_ACTIVE = 14;
// for GaugeMetricDataWrapper
const int FIELD_ID_DATA = 1;
const int FIELD_ID_SKIPPED = 2;
const int FIELD_ID_SKIPPED_START_MILLIS = 3;
const int FIELD_ID_SKIPPED_END_MILLIS = 4;
// for GaugeMetricData
const int FIELD_ID_DIMENSION_IN_WHAT = 1;
const int FIELD_ID_DIMENSION_IN_CONDITION = 2;
const int FIELD_ID_BUCKET_INFO = 3;
const int FIELD_ID_DIMENSION_LEAF_IN_WHAT = 4;
const int FIELD_ID_DIMENSION_LEAF_IN_CONDITION = 5;
// for GaugeBucketInfo
const int FIELD_ID_ATOM = 3;
const int FIELD_ID_ELAPSED_ATOM_TIMESTAMP = 4;
const int FIELD_ID_BUCKET_NUM = 6;
const int FIELD_ID_START_BUCKET_ELAPSED_MILLIS = 7;
const int FIELD_ID_END_BUCKET_ELAPSED_MILLIS = 8;
GaugeMetricProducer::GaugeMetricProducer(
const ConfigKey& key, const GaugeMetric& metric, const int conditionIndex,
const sp<ConditionWizard>& wizard, const int whatMatcherIndex,
const sp<EventMatcherWizard>& matcherWizard, const int pullTagId, const int triggerAtomId,
const int atomId, const int64_t timeBaseNs, const int64_t startTimeNs,
const sp<StatsPullerManager>& pullerManager)
: MetricProducer(metric.id(), key, timeBaseNs, conditionIndex, wizard),
mWhatMatcherIndex(whatMatcherIndex),
mEventMatcherWizard(matcherWizard),
mPullerManager(pullerManager),
mPullTagId(pullTagId),
mTriggerAtomId(triggerAtomId),
mAtomId(atomId),
mIsPulled(pullTagId != -1),
mMinBucketSizeNs(metric.min_bucket_size_nanos()),
mMaxPullDelayNs(metric.max_pull_delay_sec() > 0 ? metric.max_pull_delay_sec() * NS_PER_SEC
: StatsdStats::kPullMaxDelayNs),
mDimensionSoftLimit(StatsdStats::kAtomDimensionKeySizeLimitMap.find(pullTagId) !=
StatsdStats::kAtomDimensionKeySizeLimitMap.end()
? StatsdStats::kAtomDimensionKeySizeLimitMap.at(pullTagId).first
: StatsdStats::kDimensionKeySizeSoftLimit),
mDimensionHardLimit(StatsdStats::kAtomDimensionKeySizeLimitMap.find(pullTagId) !=
StatsdStats::kAtomDimensionKeySizeLimitMap.end()
? StatsdStats::kAtomDimensionKeySizeLimitMap.at(pullTagId).second
: StatsdStats::kDimensionKeySizeHardLimit),
mGaugeAtomsPerDimensionLimit(metric.max_num_gauge_atoms_per_bucket()),
mSplitBucketForAppUpgrade(metric.split_bucket_for_app_upgrade()) {
mCurrentSlicedBucket = std::make_shared<DimToGaugeAtomsMap>();
mCurrentSlicedBucketForAnomaly = std::make_shared<DimToValMap>();
int64_t bucketSizeMills = 0;
if (metric.has_bucket()) {
bucketSizeMills = TimeUnitToBucketSizeInMillisGuardrailed(key.GetUid(), metric.bucket());
} else {
bucketSizeMills = TimeUnitToBucketSizeInMillis(ONE_HOUR);
}
mBucketSizeNs = bucketSizeMills * 1000000;
mSamplingType = metric.sampling_type();
if (!metric.gauge_fields_filter().include_all()) {
translateFieldMatcher(metric.gauge_fields_filter().fields(), &mFieldMatchers);
}
if (metric.has_dimensions_in_what()) {
translateFieldMatcher(metric.dimensions_in_what(), &mDimensionsInWhat);
mContainANYPositionInDimensionsInWhat = HasPositionANY(metric.dimensions_in_what());
}
if (metric.has_dimensions_in_condition()) {
translateFieldMatcher(metric.dimensions_in_condition(), &mDimensionsInCondition);
}
if (metric.links().size() > 0) {
for (const auto& link : metric.links()) {
Metric2Condition mc;
mc.conditionId = link.condition();
translateFieldMatcher(link.fields_in_what(), &mc.metricFields);
translateFieldMatcher(link.fields_in_condition(), &mc.conditionFields);
mMetric2ConditionLinks.push_back(mc);
}
}
mConditionSliced = (metric.links().size() > 0) || (mDimensionsInCondition.size() > 0);
mSliceByPositionALL = HasPositionALL(metric.dimensions_in_what()) ||
HasPositionALL(metric.dimensions_in_condition());
flushIfNeededLocked(startTimeNs);
// Kicks off the puller immediately.
if (mIsPulled && mSamplingType == GaugeMetric::RANDOM_ONE_SAMPLE) {
mPullerManager->RegisterReceiver(mPullTagId, this, getCurrentBucketEndTimeNs(),
mBucketSizeNs);
}
// Adjust start for partial bucket
mCurrentBucketStartTimeNs = startTimeNs;
VLOG("Gauge metric %lld created. bucket size %lld start_time: %lld sliced %d",
(long long)metric.id(), (long long)mBucketSizeNs, (long long)mTimeBaseNs,
mConditionSliced);
}
GaugeMetricProducer::~GaugeMetricProducer() {
VLOG("~GaugeMetricProducer() called");
if (mIsPulled && mSamplingType == GaugeMetric::RANDOM_ONE_SAMPLE) {
mPullerManager->UnRegisterReceiver(mPullTagId, this);
}
}
void GaugeMetricProducer::dumpStatesLocked(FILE* out, bool verbose) const {
if (mCurrentSlicedBucket == nullptr ||
mCurrentSlicedBucket->size() == 0) {
return;
}
fprintf(out, "GaugeMetric %lld dimension size %lu\n", (long long)mMetricId,
(unsigned long)mCurrentSlicedBucket->size());
if (verbose) {
for (const auto& it : *mCurrentSlicedBucket) {
fprintf(out, "\t(what)%s\t(condition)%s %d atoms\n",
it.first.getDimensionKeyInWhat().toString().c_str(),
it.first.getDimensionKeyInCondition().toString().c_str(),
(int)it.second.size());
}
}
}
void GaugeMetricProducer::clearPastBucketsLocked(const int64_t dumpTimeNs) {
flushIfNeededLocked(dumpTimeNs);
mPastBuckets.clear();
mSkippedBuckets.clear();
}
void GaugeMetricProducer::onDumpReportLocked(const int64_t dumpTimeNs,
const bool include_current_partial_bucket,
const bool erase_data,
const DumpLatency dumpLatency,
std::set<string> *str_set,
ProtoOutputStream* protoOutput) {
VLOG("Gauge metric %lld report now...", (long long)mMetricId);
if (include_current_partial_bucket) {
flushLocked(dumpTimeNs);
} else {
flushIfNeededLocked(dumpTimeNs);
}
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_ID, (long long)mMetricId);
protoOutput->write(FIELD_TYPE_BOOL | FIELD_ID_IS_ACTIVE, isActiveLocked());
if (mPastBuckets.empty()) {
return;
}
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_TIME_BASE, (long long)mTimeBaseNs);
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_BUCKET_SIZE, (long long)mBucketSizeNs);
// Fills the dimension path if not slicing by ALL.
if (!mSliceByPositionALL) {
if (!mDimensionsInWhat.empty()) {
uint64_t dimenPathToken = protoOutput->start(
FIELD_TYPE_MESSAGE | FIELD_ID_DIMENSION_PATH_IN_WHAT);
writeDimensionPathToProto(mDimensionsInWhat, protoOutput);
protoOutput->end(dimenPathToken);
}
if (!mDimensionsInCondition.empty()) {
uint64_t dimenPathToken = protoOutput->start(
FIELD_TYPE_MESSAGE | FIELD_ID_DIMENSION_PATH_IN_CONDITION);
writeDimensionPathToProto(mDimensionsInCondition, protoOutput);
protoOutput->end(dimenPathToken);
}
}
uint64_t protoToken = protoOutput->start(FIELD_TYPE_MESSAGE | FIELD_ID_GAUGE_METRICS);
for (const auto& pair : mSkippedBuckets) {
uint64_t wrapperToken =
protoOutput->start(FIELD_TYPE_MESSAGE | FIELD_COUNT_REPEATED | FIELD_ID_SKIPPED);
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_SKIPPED_START_MILLIS,
(long long)(NanoToMillis(pair.first)));
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_SKIPPED_END_MILLIS,
(long long)(NanoToMillis(pair.second)));
protoOutput->end(wrapperToken);
}
for (const auto& pair : mPastBuckets) {
const MetricDimensionKey& dimensionKey = pair.first;
VLOG("Gauge dimension key %s", dimensionKey.toString().c_str());
uint64_t wrapperToken =
protoOutput->start(FIELD_TYPE_MESSAGE | FIELD_COUNT_REPEATED | FIELD_ID_DATA);
// First fill dimension.
if (mSliceByPositionALL) {
uint64_t dimensionToken = protoOutput->start(
FIELD_TYPE_MESSAGE | FIELD_ID_DIMENSION_IN_WHAT);
writeDimensionToProto(dimensionKey.getDimensionKeyInWhat(), str_set, protoOutput);
protoOutput->end(dimensionToken);
if (dimensionKey.hasDimensionKeyInCondition()) {
uint64_t dimensionInConditionToken = protoOutput->start(
FIELD_TYPE_MESSAGE | FIELD_ID_DIMENSION_IN_CONDITION);
writeDimensionToProto(dimensionKey.getDimensionKeyInCondition(),
str_set, protoOutput);
protoOutput->end(dimensionInConditionToken);
}
} else {
writeDimensionLeafNodesToProto(dimensionKey.getDimensionKeyInWhat(),
FIELD_ID_DIMENSION_LEAF_IN_WHAT, str_set, protoOutput);
if (dimensionKey.hasDimensionKeyInCondition()) {
writeDimensionLeafNodesToProto(dimensionKey.getDimensionKeyInCondition(),
FIELD_ID_DIMENSION_LEAF_IN_CONDITION,
str_set, protoOutput);
}
}
// Then fill bucket_info (GaugeBucketInfo).
for (const auto& bucket : pair.second) {
uint64_t bucketInfoToken = protoOutput->start(
FIELD_TYPE_MESSAGE | FIELD_COUNT_REPEATED | FIELD_ID_BUCKET_INFO);
if (bucket.mBucketEndNs - bucket.mBucketStartNs != mBucketSizeNs) {
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_START_BUCKET_ELAPSED_MILLIS,
(long long)NanoToMillis(bucket.mBucketStartNs));
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_END_BUCKET_ELAPSED_MILLIS,
(long long)NanoToMillis(bucket.mBucketEndNs));
} else {
protoOutput->write(FIELD_TYPE_INT64 | FIELD_ID_BUCKET_NUM,
(long long)(getBucketNumFromEndTimeNs(bucket.mBucketEndNs)));
}
if (!bucket.mGaugeAtoms.empty()) {
for (const auto& atom : bucket.mGaugeAtoms) {
uint64_t atomsToken =
protoOutput->start(FIELD_TYPE_MESSAGE | FIELD_COUNT_REPEATED |
FIELD_ID_ATOM);
writeFieldValueTreeToStream(mAtomId, *(atom.mFields), protoOutput);
protoOutput->end(atomsToken);
}
const bool truncateTimestamp =
android::util::AtomsInfo::kNotTruncatingTimestampAtomWhiteList.find(
mAtomId) ==
android::util::AtomsInfo::kNotTruncatingTimestampAtomWhiteList.end();
for (const auto& atom : bucket.mGaugeAtoms) {
const int64_t elapsedTimestampNs = truncateTimestamp ?
truncateTimestampNsToFiveMinutes(atom.mElapsedTimestamps) :
atom.mElapsedTimestamps;
protoOutput->write(
FIELD_TYPE_INT64 | FIELD_COUNT_REPEATED | FIELD_ID_ELAPSED_ATOM_TIMESTAMP,
(long long)elapsedTimestampNs);
}
}
protoOutput->end(bucketInfoToken);
VLOG("Gauge \t bucket [%lld - %lld] includes %d atoms.",
(long long)bucket.mBucketStartNs, (long long)bucket.mBucketEndNs,
(int)bucket.mGaugeAtoms.size());
}
protoOutput->end(wrapperToken);
}
protoOutput->end(protoToken);
if (erase_data) {
mPastBuckets.clear();
mSkippedBuckets.clear();
}
}
void GaugeMetricProducer::prepareFirstBucketLocked() {
if (mIsActive && mIsPulled && mSamplingType == GaugeMetric::RANDOM_ONE_SAMPLE) {
pullAndMatchEventsLocked(mCurrentBucketStartTimeNs);
}
}
void GaugeMetricProducer::pullAndMatchEventsLocked(const int64_t timestampNs) {
bool triggerPuller = false;
switch(mSamplingType) {
// When the metric wants to do random sampling and there is already one gauge atom for the
// current bucket, do not do it again.
case GaugeMetric::RANDOM_ONE_SAMPLE: {
triggerPuller = mCondition == ConditionState::kTrue && mCurrentSlicedBucket->empty();
break;
}
case GaugeMetric::CONDITION_CHANGE_TO_TRUE: {
triggerPuller = mCondition == ConditionState::kTrue;
break;
}
case GaugeMetric::FIRST_N_SAMPLES: {
triggerPuller = mCondition == ConditionState::kTrue;
break;
}
default:
break;
}
if (!triggerPuller) {
return;
}
vector<std::shared_ptr<LogEvent>> allData;
if (!mPullerManager->Pull(mPullTagId, &allData)) {
ALOGE("Gauge Stats puller failed for tag: %d at %lld", mPullTagId, (long long)timestampNs);
return;
}
const int64_t pullDelayNs = getElapsedRealtimeNs() - timestampNs;
if (pullDelayNs > mMaxPullDelayNs) {
ALOGE("Pull finish too late for atom %d", mPullTagId);
StatsdStats::getInstance().notePullExceedMaxDelay(mPullTagId);
StatsdStats::getInstance().notePullDelay(mPullTagId, pullDelayNs);
return;
}
StatsdStats::getInstance().notePullDelay(mPullTagId, pullDelayNs);
for (const auto& data : allData) {
LogEvent localCopy = data->makeCopy();
localCopy.setElapsedTimestampNs(timestampNs);
if (mEventMatcherWizard->matchLogEvent(localCopy, mWhatMatcherIndex) ==
MatchingState::kMatched) {
onMatchedLogEventLocked(mWhatMatcherIndex, localCopy);
}
}
}
void GaugeMetricProducer::onConditionChangedLocked(const bool conditionMet,
const int64_t eventTimeNs) {
VLOG("GaugeMetric %lld onConditionChanged", (long long)mMetricId);
flushIfNeededLocked(eventTimeNs);
mCondition = conditionMet ? ConditionState::kTrue : ConditionState::kFalse;
if (mIsPulled && mTriggerAtomId == -1) {
pullAndMatchEventsLocked(eventTimeNs);
} // else: Push mode. No need to proactively pull the gauge data.
}
void GaugeMetricProducer::onSlicedConditionMayChangeLocked(bool overallCondition,
const int64_t eventTimeNs) {
VLOG("GaugeMetric %lld onSlicedConditionMayChange overall condition %d", (long long)mMetricId,
overallCondition);
flushIfNeededLocked(eventTimeNs);
// If the condition is sliced, mCondition is true if any of the dimensions is true. And we will
// pull for every dimension.
mCondition = overallCondition ? ConditionState::kTrue : ConditionState::kFalse;
if (mIsPulled && mTriggerAtomId == -1) {
pullAndMatchEventsLocked(eventTimeNs);
} // else: Push mode. No need to proactively pull the gauge data.
}
std::shared_ptr<vector<FieldValue>> GaugeMetricProducer::getGaugeFields(const LogEvent& event) {
std::shared_ptr<vector<FieldValue>> gaugeFields;
if (mFieldMatchers.size() > 0) {
gaugeFields = std::make_shared<vector<FieldValue>>();
filterGaugeValues(mFieldMatchers, event.getValues(), gaugeFields.get());
} else {
gaugeFields = std::make_shared<vector<FieldValue>>(event.getValues());
}
// Trim all dimension fields from output. Dimensions will appear in output report and will
// benefit from dictionary encoding. For large pulled atoms, this can give the benefit of
// optional repeated field.
for (const auto& field : mDimensionsInWhat) {
for (auto it = gaugeFields->begin(); it != gaugeFields->end();) {
if (it->mField.matches(field)) {
it = gaugeFields->erase(it);
} else {
it++;
}
}
}
return gaugeFields;
}
void GaugeMetricProducer::onDataPulled(const std::vector<std::shared_ptr<LogEvent>>& allData,
bool pullSuccess, int64_t originalPullTimeNs) {
std::lock_guard<std::mutex> lock(mMutex);
if (!pullSuccess || allData.size() == 0) {
return;
}
for (const auto& data : allData) {
if (mEventMatcherWizard->matchLogEvent(
*data, mWhatMatcherIndex) == MatchingState::kMatched) {
onMatchedLogEventLocked(mWhatMatcherIndex, *data);
}
}
}
bool GaugeMetricProducer::hitGuardRailLocked(const MetricDimensionKey& newKey) {
if (mCurrentSlicedBucket->find(newKey) != mCurrentSlicedBucket->end()) {
return false;
}
// 1. Report the tuple count if the tuple count > soft limit
if (mCurrentSlicedBucket->size() > mDimensionSoftLimit - 1) {
size_t newTupleCount = mCurrentSlicedBucket->size() + 1;
StatsdStats::getInstance().noteMetricDimensionSize(mConfigKey, mMetricId, newTupleCount);
// 2. Don't add more tuples, we are above the allowed threshold. Drop the data.
if (newTupleCount > mDimensionHardLimit) {
ALOGE("GaugeMetric %lld dropping data for dimension key %s",
(long long)mMetricId, newKey.toString().c_str());
return true;
}
}
return false;
}
void GaugeMetricProducer::onMatchedLogEventInternalLocked(
const size_t matcherIndex, const MetricDimensionKey& eventKey,
const ConditionKey& conditionKey, bool condition,
const LogEvent& event) {
if (condition == false) {
return;
}
int64_t eventTimeNs = event.GetElapsedTimestampNs();
if (eventTimeNs < mCurrentBucketStartTimeNs) {
VLOG("Gauge Skip event due to late arrival: %lld vs %lld", (long long)eventTimeNs,
(long long)mCurrentBucketStartTimeNs);
return;
}
flushIfNeededLocked(eventTimeNs);
if (mTriggerAtomId == event.GetTagId()) {
pullAndMatchEventsLocked(eventTimeNs);
return;
}
// When gauge metric wants to randomly sample the output atom, we just simply use the first
// gauge in the given bucket.
if (mCurrentSlicedBucket->find(eventKey) != mCurrentSlicedBucket->end() &&
mSamplingType == GaugeMetric::RANDOM_ONE_SAMPLE) {
return;
}
if (hitGuardRailLocked(eventKey)) {
return;
}
if ((*mCurrentSlicedBucket)[eventKey].size() >= mGaugeAtomsPerDimensionLimit) {
return;
}
GaugeAtom gaugeAtom(getGaugeFields(event), eventTimeNs);
(*mCurrentSlicedBucket)[eventKey].push_back(gaugeAtom);
// Anomaly detection on gauge metric only works when there is one numeric
// field specified.
if (mAnomalyTrackers.size() > 0) {
if (gaugeAtom.mFields->size() == 1) {
const Value& value = gaugeAtom.mFields->begin()->mValue;
long gaugeVal = 0;
if (value.getType() == INT) {
gaugeVal = (long)value.int_value;
} else if (value.getType() == LONG) {
gaugeVal = value.long_value;
}
for (auto& tracker : mAnomalyTrackers) {
tracker->detectAndDeclareAnomaly(eventTimeNs, mCurrentBucketNum, mMetricId,
eventKey, gaugeVal);
}
}
}
}
void GaugeMetricProducer::updateCurrentSlicedBucketForAnomaly() {
for (const auto& slice : *mCurrentSlicedBucket) {
if (slice.second.empty()) {
continue;
}
const Value& value = slice.second.front().mFields->front().mValue;
long gaugeVal = 0;
if (value.getType() == INT) {
gaugeVal = (long)value.int_value;
} else if (value.getType() == LONG) {
gaugeVal = value.long_value;
}
(*mCurrentSlicedBucketForAnomaly)[slice.first] = gaugeVal;
}
}
void GaugeMetricProducer::dropDataLocked(const int64_t dropTimeNs) {
flushIfNeededLocked(dropTimeNs);
StatsdStats::getInstance().noteBucketDropped(mMetricId);
mPastBuckets.clear();
}
// When a new matched event comes in, we check if event falls into the current
// bucket. If not, flush the old counter to past buckets and initialize the new
// bucket.
// if data is pushed, onMatchedLogEvent will only be called through onConditionChanged() inside
// the GaugeMetricProducer while holding the lock.
void GaugeMetricProducer::flushIfNeededLocked(const int64_t& eventTimeNs) {
int64_t currentBucketEndTimeNs = getCurrentBucketEndTimeNs();
if (eventTimeNs < currentBucketEndTimeNs) {
VLOG("Gauge eventTime is %lld, less than next bucket start time %lld",
(long long)eventTimeNs, (long long)(mCurrentBucketStartTimeNs + mBucketSizeNs));
return;
}
// Adjusts the bucket start and end times.
int64_t numBucketsForward = 1 + (eventTimeNs - currentBucketEndTimeNs) / mBucketSizeNs;
int64_t nextBucketNs = currentBucketEndTimeNs + (numBucketsForward - 1) * mBucketSizeNs;
flushCurrentBucketLocked(eventTimeNs, nextBucketNs);
mCurrentBucketNum += numBucketsForward;
VLOG("Gauge metric %lld: new bucket start time: %lld", (long long)mMetricId,
(long long)mCurrentBucketStartTimeNs);
}
void GaugeMetricProducer::flushCurrentBucketLocked(const int64_t& eventTimeNs,
const int64_t& nextBucketStartTimeNs) {
int64_t fullBucketEndTimeNs = getCurrentBucketEndTimeNs();
GaugeBucket info;
info.mBucketStartNs = mCurrentBucketStartTimeNs;
if (eventTimeNs < fullBucketEndTimeNs) {
info.mBucketEndNs = eventTimeNs;
} else {
info.mBucketEndNs = fullBucketEndTimeNs;
}
if (info.mBucketEndNs - mCurrentBucketStartTimeNs >= mMinBucketSizeNs) {
for (const auto& slice : *mCurrentSlicedBucket) {
info.mGaugeAtoms = slice.second;
auto& bucketList = mPastBuckets[slice.first];
bucketList.push_back(info);
VLOG("Gauge gauge metric %lld, dump key value: %s", (long long)mMetricId,
slice.first.toString().c_str());
}
} else {
mSkippedBuckets.emplace_back(info.mBucketStartNs, info.mBucketEndNs);
}
// If we have anomaly trackers, we need to update the partial bucket values.
if (mAnomalyTrackers.size() > 0) {
updateCurrentSlicedBucketForAnomaly();
if (eventTimeNs > fullBucketEndTimeNs) {
// This is known to be a full bucket, so send this data to the anomaly tracker.
for (auto& tracker : mAnomalyTrackers) {
tracker->addPastBucket(mCurrentSlicedBucketForAnomaly, mCurrentBucketNum);
}
mCurrentSlicedBucketForAnomaly = std::make_shared<DimToValMap>();
}
}
StatsdStats::getInstance().noteBucketCount(mMetricId);
mCurrentSlicedBucket = std::make_shared<DimToGaugeAtomsMap>();
mCurrentBucketStartTimeNs = nextBucketStartTimeNs;
}
size_t GaugeMetricProducer::byteSizeLocked() const {
size_t totalSize = 0;
for (const auto& pair : mPastBuckets) {
for (const auto& bucket : pair.second) {
totalSize += bucket.mGaugeAtoms.size() * sizeof(GaugeAtom);
for (const auto& atom : bucket.mGaugeAtoms) {
if (atom.mFields != nullptr) {
totalSize += atom.mFields->size() * sizeof(FieldValue);
}
}
}
}
return totalSize;
}
} // namespace statsd
} // namespace os
} // namespace android