// 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. #include "src/metrics/duration_helper/OringDurationTracker.h" #include "src/condition/ConditionWizard.h" #include "metrics_test_helper.h" #include "tests/statsd_test_util.h" #include #include #include #include #include #include #include using namespace testing; using android::sp; using std::set; using std::unordered_map; using std::vector; #ifdef __ANDROID__ namespace android { namespace os { namespace statsd { const ConfigKey kConfigKey(0, 12345); const int TagId = 1; const int64_t metricId = 123; const optional emptyThreshold; const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kConditionKey1 = getMockedDimensionKey(TagId, 1, "maps"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); const int64_t bucketSizeNs = 30 * NS_PER_SEC; TEST(OringDurationTrackerTest, TestDurationOverlap) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); unordered_map> buckets; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketStartTimeNs = 10000000000; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; int64_t durationTimeNs = 2 * 1000; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, false, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, false, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, ConditionKey()); EXPECT_EQ((long long)eventStartTimeNs, tracker.mLastStartTime); tracker.noteStart(kEventKey1, true, eventStartTimeNs + 10, ConditionKey()); // overlapping wl EXPECT_EQ((long long)eventStartTimeNs, tracker.mLastStartTime); tracker.noteStop(kEventKey1, eventStartTimeNs + durationTimeNs, false); tracker.flushIfNeeded(eventStartTimeNs + bucketSizeNs + 1, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(durationTimeNs, buckets[eventKey][0].mDuration); } TEST(OringDurationTrackerTest, TestDurationNested) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); unordered_map> buckets; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketStartTimeNs = 10000000000; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, false, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, ConditionKey()); tracker.noteStart(kEventKey1, true, eventStartTimeNs + 10, ConditionKey()); // overlapping wl tracker.noteStop(kEventKey1, eventStartTimeNs + 2000, false); tracker.noteStop(kEventKey1, eventStartTimeNs + 2003, false); tracker.flushIfNeeded(bucketStartTimeNs + bucketSizeNs + 1, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(2003LL, buckets[eventKey][0].mDuration); } TEST(OringDurationTrackerTest, TestStopAll) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const std::vector kConditionKey1 = {getMockedDimensionKey(TagId, 1, "maps")}; const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); unordered_map> buckets; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketStartTimeNs = 10000000000; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, false, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, ConditionKey()); tracker.noteStart(kEventKey2, true, eventStartTimeNs + 10, ConditionKey()); // overlapping wl tracker.noteStopAll(eventStartTimeNs + 2003); tracker.flushIfNeeded(bucketStartTimeNs + bucketSizeNs + 1, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(2003LL, buckets[eventKey][0].mDuration); } TEST(OringDurationTrackerTest, TestCrossBucketBoundary) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); unordered_map> buckets; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketStartTimeNs = 10000000000; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; int64_t durationTimeNs = 2 * 1000; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, false, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, ConditionKey()); EXPECT_EQ((long long)eventStartTimeNs, tracker.mLastStartTime); tracker.flushIfNeeded(eventStartTimeNs + 2 * bucketSizeNs, emptyThreshold, &buckets); tracker.noteStart(kEventKey1, true, eventStartTimeNs + 2 * bucketSizeNs, ConditionKey()); EXPECT_EQ((long long)(bucketStartTimeNs + 2 * bucketSizeNs), tracker.mLastStartTime); ASSERT_EQ(2u, buckets[eventKey].size()); EXPECT_EQ(bucketSizeNs - 1, buckets[eventKey][0].mDuration); EXPECT_EQ(bucketSizeNs, buckets[eventKey][1].mDuration); tracker.noteStop(kEventKey1, eventStartTimeNs + 2 * bucketSizeNs + 10, false); tracker.noteStop(kEventKey1, eventStartTimeNs + 2 * bucketSizeNs + 12, false); tracker.flushIfNeeded(eventStartTimeNs + 2 * bucketSizeNs + 12, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(2u, buckets[eventKey].size()); EXPECT_EQ(bucketSizeNs - 1, buckets[eventKey][0].mDuration); EXPECT_EQ(bucketSizeNs, buckets[eventKey][1].mDuration); } TEST(OringDurationTrackerTest, TestDurationConditionChange) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); ConditionKey key1; key1[StringToId("APP_BACKGROUND")] = kConditionKey1; EXPECT_CALL(*wizard, query(_, key1, _)) // #4 .WillOnce(Return(ConditionState::kFalse)); unordered_map> buckets; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketStartTimeNs = 10000000000; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; int64_t durationTimeNs = 2 * 1000; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, false, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, true, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, key1); tracker.onSlicedConditionMayChange(true, eventStartTimeNs + 5); tracker.noteStop(kEventKey1, eventStartTimeNs + durationTimeNs, false); tracker.flushIfNeeded(bucketStartTimeNs + bucketSizeNs + 1, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(5LL, buckets[eventKey][0].mDuration); } TEST(OringDurationTrackerTest, TestDurationConditionChange2) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); ConditionKey key1; key1[StringToId("APP_BACKGROUND")] = kConditionKey1; EXPECT_CALL(*wizard, query(_, key1, _)) .Times(2) .WillOnce(Return(ConditionState::kFalse)) .WillOnce(Return(ConditionState::kTrue)); unordered_map> buckets; int64_t bucketStartTimeNs = 10000000000; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; int64_t durationTimeNs = 2 * 1000; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, false, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, true, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, key1); // condition to false; record duration 5n tracker.onSlicedConditionMayChange(true, eventStartTimeNs + 5); // condition to true. tracker.onSlicedConditionMayChange(true, eventStartTimeNs + 1000); // 2nd duration: 1000ns tracker.noteStop(kEventKey1, eventStartTimeNs + durationTimeNs, false); tracker.flushIfNeeded(bucketStartTimeNs + bucketSizeNs + 1, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(1005LL, buckets[eventKey][0].mDuration); } TEST(OringDurationTrackerTest, TestDurationConditionChangeNested) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); sp wizard = new NaggyMock(); ConditionKey key1; key1[StringToId("APP_BACKGROUND")] = kConditionKey1; EXPECT_CALL(*wizard, query(_, key1, _)) // #4 .WillOnce(Return(ConditionState::kFalse)); unordered_map> buckets; int64_t bucketStartTimeNs = 10000000000; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, true, false, {}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, key1); tracker.noteStart(kEventKey1, true, eventStartTimeNs + 2, key1); tracker.noteStop(kEventKey1, eventStartTimeNs + 3, false); tracker.onSlicedConditionMayChange(true, eventStartTimeNs + 15); tracker.noteStop(kEventKey1, eventStartTimeNs + 2003, false); tracker.flushIfNeeded(bucketStartTimeNs + bucketSizeNs + 1, emptyThreshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(15LL, buckets[eventKey][0].mDuration); } TEST(OringDurationTrackerTest, TestPredictAnomalyTimestamp) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); Alert alert; alert.set_id(101); alert.set_metric_id(1); alert.set_trigger_if_sum_gt(40 * NS_PER_SEC); alert.set_num_buckets(2); alert.set_refractory_period_secs(1); unordered_map> buckets; sp wizard = new NaggyMock(); int64_t bucketStartTimeNs = 10 * NS_PER_SEC; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + NS_PER_SEC + 1; sp alarmMonitor; sp anomalyTracker = new DurationAnomalyTracker(alert, kConfigKey, alarmMonitor); OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, true, false, {anomalyTracker}); // Nothing in the past bucket. tracker.noteStart(DEFAULT_DIMENSION_KEY, true, eventStartTimeNs, ConditionKey()); EXPECT_EQ((long long)(alert.trigger_if_sum_gt() + eventStartTimeNs), tracker.predictAnomalyTimestampNs(*anomalyTracker, eventStartTimeNs)); tracker.noteStop(DEFAULT_DIMENSION_KEY, eventStartTimeNs + 3, false); ASSERT_EQ(0u, buckets[eventKey].size()); int64_t event1StartTimeNs = eventStartTimeNs + 10; tracker.noteStart(kEventKey1, true, event1StartTimeNs, ConditionKey()); // No past buckets. The anomaly will happen in bucket #0. EXPECT_EQ((long long)(event1StartTimeNs + alert.trigger_if_sum_gt() - 3), tracker.predictAnomalyTimestampNs(*anomalyTracker, event1StartTimeNs)); int64_t event1StopTimeNs = eventStartTimeNs + bucketSizeNs + 10; tracker.flushIfNeeded(event1StopTimeNs, emptyThreshold, &buckets); tracker.noteStop(kEventKey1, event1StopTimeNs, false); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(3LL + bucketStartTimeNs + bucketSizeNs - eventStartTimeNs - 10, buckets[eventKey][0].mDuration); const int64_t bucket0Duration = 3ULL + bucketStartTimeNs + bucketSizeNs - eventStartTimeNs - 10; const int64_t bucket1Duration = eventStartTimeNs + 10 - bucketStartTimeNs; // One past buckets. The anomaly will happen in bucket #1. int64_t event2StartTimeNs = eventStartTimeNs + bucketSizeNs + 15; tracker.noteStart(kEventKey1, true, event2StartTimeNs, ConditionKey()); EXPECT_EQ((long long)(event2StartTimeNs + alert.trigger_if_sum_gt() - bucket0Duration - bucket1Duration), tracker.predictAnomalyTimestampNs(*anomalyTracker, event2StartTimeNs)); tracker.noteStop(kEventKey1, event2StartTimeNs + 1, false); // Only one past buckets is applicable. Bucket +0 should be trashed. The anomaly will happen in // bucket #2. int64_t event3StartTimeNs = bucketStartTimeNs + 2 * bucketSizeNs - 9 * NS_PER_SEC; tracker.noteStart(kEventKey1, true, event3StartTimeNs, ConditionKey()); EXPECT_EQ((long long)(event3StartTimeNs + alert.trigger_if_sum_gt() - bucket1Duration - 1LL), tracker.predictAnomalyTimestampNs(*anomalyTracker, event3StartTimeNs)); } TEST(OringDurationTrackerTest, TestPredictAnomalyTimestamp2) { Alert alert; alert.set_id(101); alert.set_metric_id(1); alert.set_trigger_if_sum_gt(5 * NS_PER_SEC); alert.set_num_buckets(1); alert.set_refractory_period_secs(20); int64_t bucketStartTimeNs = 10 * NS_PER_SEC; int64_t bucketNum = 0; sp wizard = new NaggyMock(); sp alarmMonitor; sp anomalyTracker = new DurationAnomalyTracker(alert, kConfigKey, alarmMonitor); OringDurationTracker tracker(kConfigKey, metricId, DEFAULT_METRIC_DIMENSION_KEY, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, true, false, {anomalyTracker}); int64_t eventStartTimeNs = bucketStartTimeNs + 9 * NS_PER_SEC; tracker.noteStart(DEFAULT_DIMENSION_KEY, true, eventStartTimeNs, ConditionKey()); // Anomaly happens in the bucket #1. EXPECT_EQ((long long)(bucketStartTimeNs + 14 * NS_PER_SEC), tracker.predictAnomalyTimestampNs(*anomalyTracker, eventStartTimeNs)); tracker.noteStop(DEFAULT_DIMENSION_KEY, bucketStartTimeNs + 14 * NS_PER_SEC, false); EXPECT_EQ((long long)(bucketStartTimeNs + 34 * NS_PER_SEC) / NS_PER_SEC, anomalyTracker->getRefractoryPeriodEndsSec(DEFAULT_METRIC_DIMENSION_KEY)); int64_t event2StartTimeNs = bucketStartTimeNs + 22 * NS_PER_SEC; EXPECT_EQ((long long)(bucketStartTimeNs + 34 * NS_PER_SEC) / NS_PER_SEC, anomalyTracker->getRefractoryPeriodEndsSec(DEFAULT_METRIC_DIMENSION_KEY)); EXPECT_EQ((long long)(bucketStartTimeNs + 35 * NS_PER_SEC), tracker.predictAnomalyTimestampNs(*anomalyTracker, event2StartTimeNs)); } TEST(OringDurationTrackerTest, TestPredictAnomalyTimestamp3) { // Test the cases where the refractory period is smaller than the bucket size, longer than // the bucket size, and longer than 2x of the anomaly detection window. for (int j = 0; j < 3; j++) { int64_t thresholdNs = j * bucketSizeNs + 5 * NS_PER_SEC; for (int i = 0; i <= 7; ++i) { Alert alert; alert.set_id(101); alert.set_metric_id(1); alert.set_trigger_if_sum_gt(thresholdNs); alert.set_num_buckets(3); alert.set_refractory_period_secs( bucketSizeNs / NS_PER_SEC / 2 + i * bucketSizeNs / NS_PER_SEC); int64_t bucketStartTimeNs = 10 * NS_PER_SEC; int64_t bucketNum = 101; sp wizard = new NaggyMock(); sp alarmMonitor; sp anomalyTracker = new DurationAnomalyTracker(alert, kConfigKey, alarmMonitor); OringDurationTracker tracker(kConfigKey, metricId, DEFAULT_METRIC_DIMENSION_KEY, wizard, 1, true, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, true, false, {anomalyTracker}); int64_t eventStartTimeNs = bucketStartTimeNs + 9 * NS_PER_SEC; tracker.noteStart(DEFAULT_DIMENSION_KEY, true, eventStartTimeNs, ConditionKey()); EXPECT_EQ((long long)(eventStartTimeNs + thresholdNs), tracker.predictAnomalyTimestampNs(*anomalyTracker, eventStartTimeNs)); int64_t eventStopTimeNs = eventStartTimeNs + thresholdNs + NS_PER_SEC; tracker.noteStop(DEFAULT_DIMENSION_KEY, eventStopTimeNs, false); int64_t refractoryPeriodEndSec = anomalyTracker->getRefractoryPeriodEndsSec(DEFAULT_METRIC_DIMENSION_KEY); EXPECT_EQ(eventStopTimeNs / (int64_t)NS_PER_SEC + alert.refractory_period_secs(), refractoryPeriodEndSec); // Acquire and release a wakelock in the next bucket. int64_t event2StartTimeNs = eventStopTimeNs + bucketSizeNs; tracker.noteStart(DEFAULT_DIMENSION_KEY, true, event2StartTimeNs, ConditionKey()); int64_t event2StopTimeNs = event2StartTimeNs + 4 * NS_PER_SEC; tracker.noteStop(DEFAULT_DIMENSION_KEY, event2StopTimeNs, false); // Test the alarm prediction works well when seeing another wakelock start event. for (int k = 0; k <= 2; ++k) { int64_t event3StartTimeNs = event2StopTimeNs + NS_PER_SEC + k * bucketSizeNs; int64_t alarmTimestampNs = tracker.predictAnomalyTimestampNs(*anomalyTracker, event3StartTimeNs); EXPECT_GT(alarmTimestampNs, 0u); EXPECT_GE(alarmTimestampNs, event3StartTimeNs); EXPECT_GE(alarmTimestampNs, refractoryPeriodEndSec *(int64_t) NS_PER_SEC); } } } } TEST(OringDurationTrackerTest, TestAnomalyDetectionExpiredAlarm) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); Alert alert; alert.set_id(101); alert.set_metric_id(1); alert.set_trigger_if_sum_gt(40 * NS_PER_SEC); alert.set_num_buckets(2); const int32_t refPeriodSec = 45; alert.set_refractory_period_secs(refPeriodSec); unordered_map> buckets; sp wizard = new NaggyMock(); int64_t bucketStartTimeNs = 10 * NS_PER_SEC; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + NS_PER_SEC + 1; sp alarmMonitor; sp anomalyTracker = new DurationAnomalyTracker(alert, kConfigKey, alarmMonitor); OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true /*nesting*/, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, false, false, {anomalyTracker}); tracker.noteStart(kEventKey1, true, eventStartTimeNs, ConditionKey()); tracker.noteStop(kEventKey1, eventStartTimeNs + 10, false); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 0U); EXPECT_TRUE(tracker.mStarted.empty()); EXPECT_EQ(10LL, tracker.mStateKeyDurationMap[DEFAULT_DIMENSION_KEY].mDuration); // 10ns ASSERT_EQ(0u, tracker.mStarted.size()); tracker.noteStart(kEventKey1, true, eventStartTimeNs + 20, ConditionKey()); ASSERT_EQ(1u, anomalyTracker->mAlarms.size()); EXPECT_EQ((long long)(52ULL * NS_PER_SEC), // (10s + 1s + 1ns + 20ns) - 10ns + 40s, rounded up (long long)(anomalyTracker->mAlarms.begin()->second->timestampSec * NS_PER_SEC)); // The alarm is set to fire at 52s, and when it does, an anomaly would be declared. However, // because this is a unit test, the alarm won't actually fire at all. Since the alarm fails // to fire in time, the anomaly is instead caught when noteStop is called, at around 71s. tracker.flushIfNeeded(eventStartTimeNs + 2 * bucketSizeNs + 25, emptyThreshold, &buckets); tracker.noteStop(kEventKey1, eventStartTimeNs + 2 * bucketSizeNs + 25, false); EXPECT_EQ(anomalyTracker->getSumOverPastBuckets(eventKey), (long long)(bucketSizeNs)); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), std::ceil((eventStartTimeNs + 2 * bucketSizeNs + 25.0) / NS_PER_SEC + refPeriodSec)); } TEST(OringDurationTrackerTest, TestAnomalyDetectionFiredAlarm) { const MetricDimensionKey eventKey = getMockedMetricDimensionKey(TagId, 0, "event"); const HashableDimensionKey kEventKey1 = getMockedDimensionKey(TagId, 2, "maps"); const HashableDimensionKey kEventKey2 = getMockedDimensionKey(TagId, 3, "maps"); Alert alert; alert.set_id(101); alert.set_metric_id(1); alert.set_trigger_if_sum_gt(40 * NS_PER_SEC); alert.set_num_buckets(2); const int32_t refPeriodSec = 45; alert.set_refractory_period_secs(refPeriodSec); unordered_map> buckets; sp wizard = new NaggyMock(); ConditionKey conkey; conkey[StringToId("APP_BACKGROUND")] = kConditionKey1; int64_t bucketStartTimeNs = 10 * NS_PER_SEC; int64_t bucketSizeNs = 30 * NS_PER_SEC; sp alarmMonitor; sp anomalyTracker = new DurationAnomalyTracker(alert, kConfigKey, alarmMonitor); OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, true /*nesting*/, bucketStartTimeNs, 0, bucketStartTimeNs, bucketSizeNs, false, false, {anomalyTracker}); tracker.noteStart(kEventKey1, true, 15 * NS_PER_SEC, conkey); // start key1 ASSERT_EQ(1u, anomalyTracker->mAlarms.size()); sp alarm = anomalyTracker->mAlarms.begin()->second; EXPECT_EQ((long long)(55ULL * NS_PER_SEC), (long long)(alarm->timestampSec * NS_PER_SEC)); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 0U); tracker.noteStop(kEventKey1, 17 * NS_PER_SEC, false); // stop key1 (2 seconds later) ASSERT_EQ(0u, anomalyTracker->mAlarms.size()); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 0U); tracker.noteStart(kEventKey1, true, 22 * NS_PER_SEC, conkey); // start key1 again ASSERT_EQ(1u, anomalyTracker->mAlarms.size()); alarm = anomalyTracker->mAlarms.begin()->second; EXPECT_EQ((long long)(60ULL * NS_PER_SEC), (long long)(alarm->timestampSec * NS_PER_SEC)); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 0U); tracker.noteStart(kEventKey2, true, 32 * NS_PER_SEC, conkey); // start key2 ASSERT_EQ(1u, anomalyTracker->mAlarms.size()); alarm = anomalyTracker->mAlarms.begin()->second; EXPECT_EQ((long long)(60ULL * NS_PER_SEC), (long long)(alarm->timestampSec * NS_PER_SEC)); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 0U); tracker.noteStop(kEventKey1, 47 * NS_PER_SEC, false); // stop key1 ASSERT_EQ(1u, anomalyTracker->mAlarms.size()); alarm = anomalyTracker->mAlarms.begin()->second; EXPECT_EQ((long long)(60ULL * NS_PER_SEC), (long long)(alarm->timestampSec * NS_PER_SEC)); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 0U); // Now, at 60s, which is 38s after key1 started again, we have reached 40s of 'on' time. std::unordered_set, SpHash> firedAlarms({alarm}); anomalyTracker->informAlarmsFired(62 * NS_PER_SEC, firedAlarms); ASSERT_EQ(0u, anomalyTracker->mAlarms.size()); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 62U + refPeriodSec); tracker.noteStop(kEventKey2, 69 * NS_PER_SEC, false); // stop key2 ASSERT_EQ(0u, anomalyTracker->mAlarms.size()); EXPECT_EQ(anomalyTracker->getRefractoryPeriodEndsSec(eventKey), 62U + refPeriodSec); } TEST(OringDurationTrackerTest, TestUploadThreshold) { sp wizard = new NaggyMock(); unordered_map> buckets; int64_t bucketSizeNs = 30 * 1000 * 1000 * 1000LL; int64_t bucketStartTimeNs = 10000000000; int64_t bucketNum = 0; int64_t eventStartTimeNs = bucketStartTimeNs + 1; int64_t event2StartTimeNs = bucketStartTimeNs + bucketSizeNs + 1; int64_t thresholdDurationNs = 2000; UploadThreshold threshold; threshold.set_gt_int(thresholdDurationNs); OringDurationTracker tracker(kConfigKey, metricId, eventKey, wizard, 1, false, bucketStartTimeNs, bucketNum, bucketStartTimeNs, bucketSizeNs, false, false, {}); // Duration below the gt_int threshold should not be added to past buckets. tracker.noteStart(kEventKey1, true, eventStartTimeNs, ConditionKey()); tracker.noteStop(kEventKey1, eventStartTimeNs + thresholdDurationNs, false); tracker.flushIfNeeded(eventStartTimeNs + bucketSizeNs + 1, threshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) == buckets.end()); // Duration above the gt_int threshold should be added to past buckets. tracker.noteStart(kEventKey1, true, event2StartTimeNs, ConditionKey()); tracker.noteStop(kEventKey1, event2StartTimeNs + thresholdDurationNs + 1, false); tracker.flushIfNeeded(event2StartTimeNs + bucketSizeNs + 1, threshold, &buckets); EXPECT_TRUE(buckets.find(eventKey) != buckets.end()); ASSERT_EQ(1u, buckets[eventKey].size()); EXPECT_EQ(thresholdDurationNs + 1, buckets[eventKey][0].mDuration); } } // namespace statsd } // namespace os } // namespace android #else GTEST_LOG_(INFO) << "This test does nothing.\n"; #endif