// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Test of Histogram class #include #include #include #include "base/logging.h" #include "base/memory/scoped_ptr.h" #include "base/metrics/bucket_ranges.h" #include "base/metrics/histogram.h" #include "base/metrics/sample_vector.h" #include "base/metrics/statistics_recorder.h" #include "base/pickle.h" #include "base/time.h" #include "testing/gtest/include/gtest/gtest.h" using std::vector; namespace base { class HistogramTest : public testing::Test { protected: virtual void SetUp() { // Each test will have a clean state (no Histogram / BucketRanges // registered). InitializeStatisticsRecorder(); } virtual void TearDown() { UninitializeStatisticsRecorder(); } void InitializeStatisticsRecorder() { statistics_recorder_ = new StatisticsRecorder(); } void UninitializeStatisticsRecorder() { delete statistics_recorder_; statistics_recorder_ = NULL; } StatisticsRecorder* statistics_recorder_; }; // Check for basic syntax and use. TEST_F(HistogramTest, BasicTest) { // Try basic construction Histogram* histogram(Histogram::FactoryGet( "TestHistogram", 1, 1000, 10, HistogramBase::kNoFlags)); EXPECT_NE(reinterpret_cast(NULL), histogram); Histogram* linear_histogram(LinearHistogram::FactoryGet( "TestLinearHistogram", 1, 1000, 10, HistogramBase::kNoFlags)); EXPECT_NE(reinterpret_cast(NULL), linear_histogram); vector custom_ranges; custom_ranges.push_back(1); custom_ranges.push_back(5); Histogram* custom_histogram(CustomHistogram::FactoryGet( "TestCustomHistogram", custom_ranges, HistogramBase::kNoFlags)); EXPECT_NE(reinterpret_cast(NULL), custom_histogram); // Use standard macros (but with fixed samples) HISTOGRAM_TIMES("Test2Histogram", TimeDelta::FromDays(1)); HISTOGRAM_COUNTS("Test3Histogram", 30); DHISTOGRAM_TIMES("Test4Histogram", TimeDelta::FromDays(1)); DHISTOGRAM_COUNTS("Test5Histogram", 30); HISTOGRAM_ENUMERATION("Test6Histogram", 129, 130); } // Check that the macro correctly matches histograms by name and records their // data together. TEST_F(HistogramTest, NameMatchTest) { HISTOGRAM_PERCENTAGE("DuplicatedHistogram", 10); HISTOGRAM_PERCENTAGE("DuplicatedHistogram", 10); Histogram* histogram(LinearHistogram::FactoryGet( "DuplicatedHistogram", 1, 101, 102, HistogramBase::kNoFlags)); scoped_ptr samples = histogram->SnapshotSampleVector(); EXPECT_EQ(2, samples->TotalCount()); EXPECT_EQ(2, samples->GetCountAtIndex(10)); } TEST_F(HistogramTest, ExponentialRangesTest) { // Check that we got a nice exponential when there was enough rooom. BucketRanges ranges(9); Histogram::InitializeBucketRanges(1, 64, 8, &ranges); EXPECT_EQ(0, ranges.range(0)); int power_of_2 = 1; for (int i = 1; i < 8; i++) { EXPECT_EQ(power_of_2, ranges.range(i)); power_of_2 *= 2; } EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges.range(8)); // Check the corresponding Histogram will use the correct ranges. Histogram* histogram(Histogram::FactoryGet( "Histogram", 1, 64, 8, HistogramBase::kNoFlags)); EXPECT_TRUE(ranges.Equals(histogram->bucket_ranges())); // When bucket count is limited, exponential ranges will partially look like // linear. BucketRanges ranges2(16); Histogram::InitializeBucketRanges(1, 32, 15, &ranges2); EXPECT_EQ(0, ranges2.range(0)); EXPECT_EQ(1, ranges2.range(1)); EXPECT_EQ(2, ranges2.range(2)); EXPECT_EQ(3, ranges2.range(3)); EXPECT_EQ(4, ranges2.range(4)); EXPECT_EQ(5, ranges2.range(5)); EXPECT_EQ(6, ranges2.range(6)); EXPECT_EQ(7, ranges2.range(7)); EXPECT_EQ(9, ranges2.range(8)); EXPECT_EQ(11, ranges2.range(9)); EXPECT_EQ(14, ranges2.range(10)); EXPECT_EQ(17, ranges2.range(11)); EXPECT_EQ(21, ranges2.range(12)); EXPECT_EQ(26, ranges2.range(13)); EXPECT_EQ(32, ranges2.range(14)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges2.range(15)); // Check the corresponding Histogram will use the correct ranges. Histogram* histogram2(Histogram::FactoryGet( "Histogram2", 1, 32, 15, HistogramBase::kNoFlags)); EXPECT_TRUE(ranges2.Equals(histogram2->bucket_ranges())); } TEST_F(HistogramTest, LinearRangesTest) { BucketRanges ranges(9); LinearHistogram::InitializeBucketRanges(1, 7, 8, &ranges); // Gets a nice linear set of bucket ranges. for (int i = 0; i < 8; i++) EXPECT_EQ(i, ranges.range(i)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges.range(8)); // The correspoding LinearHistogram should use the correct ranges. Histogram* histogram( LinearHistogram::FactoryGet("Linear", 1, 7, 8, HistogramBase::kNoFlags)); EXPECT_TRUE(ranges.Equals(histogram->bucket_ranges())); // Linear ranges are not divisible. BucketRanges ranges2(6); LinearHistogram::InitializeBucketRanges(1, 6, 5, &ranges2); EXPECT_EQ(0, ranges2.range(0)); EXPECT_EQ(1, ranges2.range(1)); EXPECT_EQ(3, ranges2.range(2)); EXPECT_EQ(4, ranges2.range(3)); EXPECT_EQ(6, ranges2.range(4)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges2.range(5)); // The correspoding LinearHistogram should use the correct ranges. Histogram* histogram2( LinearHistogram::FactoryGet("Linear2", 1, 6, 5, HistogramBase::kNoFlags)); EXPECT_TRUE(ranges2.Equals(histogram2->bucket_ranges())); } TEST_F(HistogramTest, ArrayToCustomRangesTest) { const HistogramBase::Sample ranges[3] = {5, 10, 20}; vector ranges_vec = CustomHistogram::ArrayToCustomRanges(ranges, 3); ASSERT_EQ(6u, ranges_vec.size()); EXPECT_EQ(5, ranges_vec[0]); EXPECT_EQ(6, ranges_vec[1]); EXPECT_EQ(10, ranges_vec[2]); EXPECT_EQ(11, ranges_vec[3]); EXPECT_EQ(20, ranges_vec[4]); EXPECT_EQ(21, ranges_vec[5]); } TEST_F(HistogramTest, CustomHistogramTest) { // A well prepared custom ranges. vector custom_ranges; custom_ranges.push_back(1); custom_ranges.push_back(2); Histogram* histogram = CustomHistogram::FactoryGet( "TestCustomHistogram1", custom_ranges, HistogramBase::kNoFlags); const BucketRanges* ranges = histogram->bucket_ranges(); ASSERT_EQ(4u, ranges->size()); EXPECT_EQ(0, ranges->range(0)); // Auto added. EXPECT_EQ(1, ranges->range(1)); EXPECT_EQ(2, ranges->range(2)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges->range(3)); // Auto added. // A unordered custom ranges. custom_ranges.clear(); custom_ranges.push_back(2); custom_ranges.push_back(1); histogram = CustomHistogram::FactoryGet( "TestCustomHistogram2", custom_ranges, HistogramBase::kNoFlags); ranges = histogram->bucket_ranges(); ASSERT_EQ(4u, ranges->size()); EXPECT_EQ(0, ranges->range(0)); EXPECT_EQ(1, ranges->range(1)); EXPECT_EQ(2, ranges->range(2)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges->range(3)); // A custom ranges with duplicated values. custom_ranges.clear(); custom_ranges.push_back(4); custom_ranges.push_back(1); custom_ranges.push_back(4); histogram = CustomHistogram::FactoryGet( "TestCustomHistogram3", custom_ranges, HistogramBase::kNoFlags); ranges = histogram->bucket_ranges(); ASSERT_EQ(4u, ranges->size()); EXPECT_EQ(0, ranges->range(0)); EXPECT_EQ(1, ranges->range(1)); EXPECT_EQ(4, ranges->range(2)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges->range(3)); } TEST_F(HistogramTest, CustomHistogramWithOnly2Buckets) { // This test exploits the fact that the CustomHistogram can have 2 buckets, // while the base class Histogram is *supposed* to have at least 3 buckets. // We should probably change the restriction on the base class (or not inherit // the base class!). vector custom_ranges; custom_ranges.push_back(4); Histogram* histogram = CustomHistogram::FactoryGet( "2BucketsCustomHistogram", custom_ranges, HistogramBase::kNoFlags); const BucketRanges* ranges = histogram->bucket_ranges(); ASSERT_EQ(3u, ranges->size()); EXPECT_EQ(0, ranges->range(0)); EXPECT_EQ(4, ranges->range(1)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges->range(2)); } // Make sure histogram handles out-of-bounds data gracefully. TEST_F(HistogramTest, BoundsTest) { const size_t kBucketCount = 50; Histogram* histogram(Histogram::FactoryGet( "Bounded", 10, 100, kBucketCount, HistogramBase::kNoFlags)); // Put two samples "out of bounds" above and below. histogram->Add(5); histogram->Add(-50); histogram->Add(100); histogram->Add(10000); // Verify they landed in the underflow, and overflow buckets. scoped_ptr samples = histogram->SnapshotSampleVector(); EXPECT_EQ(2, samples->GetCountAtIndex(0)); EXPECT_EQ(0, samples->GetCountAtIndex(1)); size_t array_size = histogram->bucket_count(); EXPECT_EQ(kBucketCount, array_size); EXPECT_EQ(0, samples->GetCountAtIndex(array_size - 2)); EXPECT_EQ(2, samples->GetCountAtIndex(array_size - 1)); vector custom_ranges; custom_ranges.push_back(10); custom_ranges.push_back(50); custom_ranges.push_back(100); Histogram* test_custom_histogram = CustomHistogram::FactoryGet( "TestCustomRangeBoundedHistogram", custom_ranges, HistogramBase::kNoFlags); // Put two samples "out of bounds" above and below. test_custom_histogram->Add(5); test_custom_histogram->Add(-50); test_custom_histogram->Add(100); test_custom_histogram->Add(1000); test_custom_histogram->Add(INT_MAX); // Verify they landed in the underflow, and overflow buckets. scoped_ptr custom_samples = test_custom_histogram->SnapshotSampleVector(); EXPECT_EQ(2, custom_samples->GetCountAtIndex(0)); EXPECT_EQ(0, custom_samples->GetCountAtIndex(1)); size_t bucket_count = test_custom_histogram->bucket_count(); EXPECT_EQ(0, custom_samples->GetCountAtIndex(bucket_count - 2)); EXPECT_EQ(3, custom_samples->GetCountAtIndex(bucket_count - 1)); } // Check to be sure samples land as expected is "correct" buckets. TEST_F(HistogramTest, BucketPlacementTest) { Histogram* histogram(Histogram::FactoryGet( "Histogram", 1, 64, 8, HistogramBase::kNoFlags)); // Add i+1 samples to the i'th bucket. histogram->Add(0); int power_of_2 = 1; for (int i = 1; i < 8; i++) { for (int j = 0; j <= i; j++) histogram->Add(power_of_2); power_of_2 *= 2; } // Check to see that the bucket counts reflect our additions. scoped_ptr samples = histogram->SnapshotSampleVector(); for (int i = 0; i < 8; i++) EXPECT_EQ(i + 1, samples->GetCountAtIndex(i)); } TEST_F(HistogramTest, CorruptSampleCounts) { Histogram* histogram(Histogram::FactoryGet( "Histogram", 1, 64, 8, HistogramBase::kNoFlags)); // As per header file. // Add some samples. histogram->Add(20); histogram->Add(40); scoped_ptr snapshot = histogram->SnapshotSampleVector(); EXPECT_EQ(Histogram::NO_INCONSISTENCIES, histogram->FindCorruption(*snapshot)); EXPECT_EQ(2, snapshot->redundant_count()); EXPECT_EQ(2, snapshot->TotalCount()); snapshot->counts_[3] += 100; // Sample count won't match redundant count. EXPECT_EQ(Histogram::COUNT_LOW_ERROR, histogram->FindCorruption(*snapshot)); snapshot->counts_[2] -= 200; EXPECT_EQ(Histogram::COUNT_HIGH_ERROR, histogram->FindCorruption(*snapshot)); // But we can't spot a corruption if it is compensated for. snapshot->counts_[1] += 100; EXPECT_EQ(Histogram::NO_INCONSISTENCIES, histogram->FindCorruption(*snapshot)); } TEST_F(HistogramTest, CorruptBucketBounds) { Histogram* histogram(Histogram::FactoryGet( "Histogram", 1, 64, 8, HistogramBase::kNoFlags)); // As per header file. scoped_ptr snapshot = histogram->SnapshotSampleVector(); EXPECT_EQ(Histogram::NO_INCONSISTENCIES, histogram->FindCorruption(*snapshot)); BucketRanges* bucket_ranges = const_cast(histogram->bucket_ranges()); HistogramBase::Sample tmp = bucket_ranges->range(1); bucket_ranges->set_range(1, bucket_ranges->range(2)); bucket_ranges->set_range(2, tmp); EXPECT_EQ(Histogram::BUCKET_ORDER_ERROR | Histogram::RANGE_CHECKSUM_ERROR, histogram->FindCorruption(*snapshot)); bucket_ranges->set_range(2, bucket_ranges->range(1)); bucket_ranges->set_range(1, tmp); EXPECT_EQ(0, histogram->FindCorruption(*snapshot)); // Show that two simple changes don't offset each other bucket_ranges->set_range(3, bucket_ranges->range(3) + 1); EXPECT_EQ(Histogram::RANGE_CHECKSUM_ERROR, histogram->FindCorruption(*snapshot)); bucket_ranges->set_range(4, bucket_ranges->range(4) - 1); EXPECT_EQ(Histogram::RANGE_CHECKSUM_ERROR, histogram->FindCorruption(*snapshot)); // Repair histogram so that destructor won't DCHECK(). bucket_ranges->set_range(3, bucket_ranges->range(3) - 1); bucket_ranges->set_range(4, bucket_ranges->range(4) + 1); } TEST_F(HistogramTest, HistogramSerializeInfo) { Histogram* histogram = Histogram::FactoryGet( "Histogram", 1, 64, 8, HistogramBase::kIPCSerializationSourceFlag); Pickle pickle; histogram->SerializeInfo(&pickle); PickleIterator iter(pickle); int type; EXPECT_TRUE(iter.ReadInt(&type)); EXPECT_EQ(HISTOGRAM, type); std::string name; EXPECT_TRUE(iter.ReadString(&name)); EXPECT_EQ("Histogram", name); int flag; EXPECT_TRUE(iter.ReadInt(&flag)); EXPECT_EQ(HistogramBase::kIPCSerializationSourceFlag, flag); int min; EXPECT_TRUE(iter.ReadInt(&min)); EXPECT_EQ(1, min); int max; EXPECT_TRUE(iter.ReadInt(&max)); EXPECT_EQ(64, max); int64 bucket_count; EXPECT_TRUE(iter.ReadInt64(&bucket_count)); EXPECT_EQ(8, bucket_count); uint32 checksum; EXPECT_TRUE(iter.ReadUInt32(&checksum)); EXPECT_EQ(histogram->bucket_ranges()->checksum(), checksum); // No more data in the pickle. EXPECT_FALSE(iter.SkipBytes(1)); } TEST_F(HistogramTest, CustomHistogramSerializeInfo) { vector custom_ranges; custom_ranges.push_back(10); custom_ranges.push_back(100); Histogram* custom_histogram = CustomHistogram::FactoryGet( "TestCustomRangeBoundedHistogram", custom_ranges, HistogramBase::kNoFlags); Pickle pickle; custom_histogram->SerializeInfo(&pickle); // Validate the pickle. PickleIterator iter(pickle); int i; std::string s; int64 bucket_count; uint32 ui32; EXPECT_TRUE(iter.ReadInt(&i) && iter.ReadString(&s) && iter.ReadInt(&i) && iter.ReadInt(&i) && iter.ReadInt(&i) && iter.ReadInt64(&bucket_count) && iter.ReadUInt32(&ui32)); EXPECT_EQ(3, bucket_count); int range; EXPECT_TRUE(iter.ReadInt(&range)); EXPECT_EQ(10, range); EXPECT_TRUE(iter.ReadInt(&range)); EXPECT_EQ(100, range); // No more data in the pickle. EXPECT_FALSE(iter.SkipBytes(1)); } #if GTEST_HAS_DEATH_TEST // For Histogram, LinearHistogram and CustomHistogram, the minimum for a // declared range is 1, while the maximum is (HistogramBase::kSampleType_MAX - // 1). But we accept ranges exceeding those limits, and silently clamped to // those limits. This is for backwards compatibility. TEST(HistogramDeathTest, BadRangesTest) { Histogram* histogram = Histogram::FactoryGet( "BadRanges", 0, HistogramBase::kSampleType_MAX, 8, HistogramBase::kNoFlags); EXPECT_EQ(1, histogram->declared_min()); EXPECT_EQ(HistogramBase::kSampleType_MAX - 1, histogram->declared_max()); Histogram* linear_histogram = LinearHistogram::FactoryGet( "BadRangesLinear", 0, HistogramBase::kSampleType_MAX, 8, HistogramBase::kNoFlags); EXPECT_EQ(1, linear_histogram->declared_min()); EXPECT_EQ(HistogramBase::kSampleType_MAX - 1, linear_histogram->declared_max()); vector custom_ranges; custom_ranges.push_back(0); custom_ranges.push_back(5); Histogram* custom_histogram1 = CustomHistogram::FactoryGet( "BadRangesCustom", custom_ranges, HistogramBase::kNoFlags); const BucketRanges* ranges = custom_histogram1->bucket_ranges(); ASSERT_EQ(3u, ranges->size()); EXPECT_EQ(0, ranges->range(0)); EXPECT_EQ(5, ranges->range(1)); EXPECT_EQ(HistogramBase::kSampleType_MAX, ranges->range(2)); // CustomHistogram does not accepts kSampleType_MAX as range. custom_ranges.push_back(HistogramBase::kSampleType_MAX); EXPECT_DEATH(CustomHistogram::FactoryGet("BadRangesCustom2", custom_ranges, HistogramBase::kNoFlags), ""); // CustomHistogram needs at least 1 valid range. custom_ranges.clear(); custom_ranges.push_back(0); EXPECT_DEATH(CustomHistogram::FactoryGet("BadRangesCustom3", custom_ranges, HistogramBase::kNoFlags), ""); } #endif } // namespace base