blob: 61dfddd2731873d4893c73ae4ca6a5d0caab3369 [file] [log] [blame]
/*
* Copyright (C) 2020 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 "metrics.h"
#include "base/macros.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "metrics_test.h"
#pragma clang diagnostic push
#pragma clang diagnostic error "-Wconversion"
namespace art {
namespace metrics {
using test::CounterValue;
using test::GetBuckets;
using test::TestBackendBase;
class MetricsTest : public testing::Test {};
TEST_F(MetricsTest, SimpleCounter) {
MetricsCounter<DatumId::kClassVerificationTotalTime> test_counter;
EXPECT_EQ(0u, CounterValue(test_counter));
test_counter.AddOne();
EXPECT_EQ(1u, CounterValue(test_counter));
test_counter.Add(5);
EXPECT_EQ(6u, CounterValue(test_counter));
}
TEST_F(MetricsTest, CounterTimer) {
MetricsCounter<DatumId::kClassVerificationTotalTime> test_counter;
{
AutoTimer timer{&test_counter};
// Sleep for 2µs so the counter will be greater than 0.
NanoSleep(2'000);
}
EXPECT_GT(CounterValue(test_counter), 0u);
}
TEST_F(MetricsTest, CounterTimerExplicitStop) {
MetricsCounter<DatumId::kClassVerificationTotalTime> test_counter;
AutoTimer timer{&test_counter};
// Sleep for 2µs so the counter will be greater than 0.
NanoSleep(2'000);
timer.Stop();
EXPECT_GT(CounterValue(test_counter), 0u);
}
TEST_F(MetricsTest, CounterTimerExplicitStart) {
MetricsCounter<DatumId::kClassVerificationTotalTime> test_counter;
{
AutoTimer timer{&test_counter, /*autostart=*/false};
// Sleep for 2µs so the counter will be greater than 0.
NanoSleep(2'000);
}
EXPECT_EQ(CounterValue(test_counter), 0u);
{
AutoTimer timer{&test_counter, /*autostart=*/false};
timer.Start();
// Sleep for 2µs so the counter will be greater than 0.
NanoSleep(2'000);
}
EXPECT_GT(CounterValue(test_counter), 0u);
}
TEST_F(MetricsTest, CounterTimerExplicitStartStop) {
MetricsCounter<DatumId::kClassVerificationTotalTime> test_counter;
AutoTimer timer{&test_counter, /*autostart=*/false};
// Sleep for 2µs so the counter will be greater than 0.
timer.Start();
NanoSleep(2'000);
timer.Stop();
EXPECT_GT(CounterValue(test_counter), 0u);
}
TEST_F(MetricsTest, AccumulatorMetric) {
MetricsAccumulator<DatumId::kClassLoadingTotalTime, uint64_t, std::max> accumulator;
std::vector<std::thread> threads;
constexpr uint64_t kMaxValue = 100;
for (uint64_t i = 0; i <= kMaxValue; i++) {
threads.emplace_back(std::thread{[&accumulator, i]() {
accumulator.Add(i);
}});
}
for (auto& thread : threads) {
thread.join();
}
EXPECT_EQ(CounterValue(accumulator), kMaxValue);
}
TEST_F(MetricsTest, AverageMetric) {
MetricsAverage<DatumId::kClassLoadingTotalTime, uint64_t> avg;
std::vector<std::thread> threads;
constexpr uint64_t kMaxValue = 100;
for (uint64_t i = 0; i <= kMaxValue; i++) {
threads.emplace_back(std::thread{[&avg, i]() {
avg.Add(i);
}});
}
for (auto& thread : threads) {
thread.join();
}
EXPECT_EQ(CounterValue(avg), (kMaxValue + 1) / 2);
}
TEST_F(MetricsTest, DatumName) {
EXPECT_EQ("ClassVerificationTotalTime", DatumName(DatumId::kClassVerificationTotalTime));
}
TEST_F(MetricsTest, SimpleHistogramTest) {
MetricsHistogram<DatumId::kYoungGcCollectionTime, 5, 0, 100> histogram;
// bucket 0: 0-19
histogram.Add(10);
// bucket 1: 20-39
histogram.Add(20);
histogram.Add(25);
// bucket 2: 40-59
histogram.Add(56);
histogram.Add(57);
histogram.Add(58);
histogram.Add(59);
// bucket 3: 60-79
histogram.Add(70);
histogram.Add(70);
histogram.Add(70);
// bucket 4: 80-99
// leave this bucket empty
std::vector<uint32_t> buckets{GetBuckets(histogram)};
EXPECT_EQ(1u, buckets[0u]);
EXPECT_EQ(2u, buckets[1u]);
EXPECT_EQ(4u, buckets[2u]);
EXPECT_EQ(3u, buckets[3u]);
EXPECT_EQ(0u, buckets[4u]);
}
// Make sure values added outside the range of the histogram go into the first or last bucket.
TEST_F(MetricsTest, HistogramOutOfRangeTest) {
MetricsHistogram<DatumId::kYoungGcCollectionTime, 2, 0, 100> histogram;
// bucket 0: 0-49
histogram.Add(-500);
// bucket 1: 50-99
histogram.Add(250);
histogram.Add(1000);
std::vector<uint32_t> buckets{GetBuckets(histogram)};
EXPECT_EQ(1u, buckets[0u]);
EXPECT_EQ(2u, buckets[1u]);
}
// Test adding values to ArtMetrics and reporting them through a test backend.
TEST_F(MetricsTest, ArtMetricsReport) {
ArtMetrics metrics;
// Collect some data
static constexpr uint64_t verification_time = 42;
metrics.ClassVerificationTotalTime()->Add(verification_time);
// Add a negative value so we are guaranteed that it lands in the first bucket.
metrics.YoungGcCollectionTime()->Add(-5);
// Report and check the data
class TestBackend : public TestBackendBase {
public:
~TestBackend() {
EXPECT_TRUE(found_counter_);
EXPECT_TRUE(found_histogram_);
}
void ReportCounter(DatumId counter_type, uint64_t value) override {
if (counter_type == DatumId::kClassVerificationTotalTime) {
EXPECT_EQ(value, verification_time);
found_counter_ = true;
} else {
EXPECT_EQ(value, 0u);
}
}
void ReportHistogram(DatumId histogram_type,
int64_t,
int64_t,
const std::vector<uint32_t>& buckets) override {
if (histogram_type == DatumId::kYoungGcCollectionTime) {
EXPECT_EQ(buckets[0], 1u);
for (size_t i = 1; i < buckets.size(); ++i) {
EXPECT_EQ(buckets[i], 0u);
}
found_histogram_ = true;
} else {
for (size_t i = 0; i < buckets.size(); ++i) {
EXPECT_EQ(buckets[i], 0u);
}
}
}
private:
bool found_counter_{false};
bool found_histogram_{false};
} backend;
metrics.ReportAllMetricsAndResetValueMetrics({&backend});
}
TEST_F(MetricsTest, HistogramTimer) {
MetricsHistogram<DatumId::kYoungGcCollectionTime, 1, 0, 100> test_histogram;
{
AutoTimer timer{&test_histogram};
// Sleep for 2µs so the counter will be greater than 0.
NanoSleep(2'000);
}
EXPECT_GT(GetBuckets(test_histogram)[0], 0u);
}
// Makes sure all defined metrics are included when dumping through StreamBackend.
TEST_F(MetricsTest, StreamBackendDumpAllMetrics) {
ArtMetrics metrics;
StringBackend backend(std::make_unique<TextFormatter>());
metrics.ReportAllMetricsAndResetValueMetrics({&backend});
// Make sure the resulting string lists all the metrics.
const std::string result = backend.GetAndResetBuffer();
#define METRIC(name, type, ...) \
EXPECT_NE(result.find(DatumName(DatumId::k##name)), std::string::npos);
ART_METRICS(METRIC);
#undef METRIC
}
TEST_F(MetricsTest, ResetMetrics) {
ArtMetrics metrics;
// Add something to each of the metrics.
#define METRIC(name, type, ...) metrics.name()->Add(42);
ART_METRICS(METRIC)
#undef METRIC
class NonZeroBackend : public TestBackendBase {
public:
void ReportCounter([[maybe_unused]] DatumId counter_type, uint64_t value) override {
EXPECT_NE(value, 0u);
}
void ReportHistogram([[maybe_unused]] DatumId histogram_type,
[[maybe_unused]] int64_t minimum_value,
[[maybe_unused]] int64_t maximum_value,
const std::vector<uint32_t>& buckets) override {
bool nonzero = false;
for (const auto value : buckets) {
nonzero |= (value != 0u);
}
EXPECT_TRUE(nonzero);
}
} non_zero_backend;
// Make sure the metrics all have a nonzero value.
metrics.ReportAllMetricsAndResetValueMetrics({&non_zero_backend});
// Reset the metrics and make sure they are all zero again
metrics.Reset();
class ZeroBackend : public TestBackendBase {
public:
void ReportCounter([[maybe_unused]] DatumId counter_type, uint64_t value) override {
EXPECT_EQ(value, 0u);
}
void ReportHistogram([[maybe_unused]] DatumId histogram_type,
[[maybe_unused]] int64_t minimum_value,
[[maybe_unused]] int64_t maximum_value,
const std::vector<uint32_t>& buckets) override {
for (const auto value : buckets) {
EXPECT_EQ(value, 0u);
}
}
} zero_backend;
metrics.ReportAllMetricsAndResetValueMetrics({&zero_backend});
}
TEST_F(MetricsTest, KeepEventMetricsResetValueMetricsAfterReporting) {
ArtMetrics metrics;
// Add something to each of the metrics.
#define METRIC(name, type, ...) metrics.name()->Add(42);
ART_METRICS(METRIC)
#undef METRIC
class FirstBackend : public TestBackendBase {
public:
void ReportCounter([[maybe_unused]] DatumId counter_type, uint64_t value) override {
EXPECT_NE(value, 0u);
}
void ReportHistogram([[maybe_unused]] DatumId histogram_type,
[[maybe_unused]] int64_t minimum_value,
[[maybe_unused]] int64_t maximum_value,
const std::vector<uint32_t>& buckets) override {
EXPECT_NE(buckets[0], 0u) << "Bucket 0 should have a non-zero value";
for (size_t i = 1; i < buckets.size(); i++) {
EXPECT_EQ(buckets[i], 0u) << "Bucket " << i << " should have a zero value";
}
}
} first_backend;
// Make sure the metrics all have a nonzero value, and they are not reset between backends.
metrics.ReportAllMetricsAndResetValueMetrics({&first_backend, &first_backend});
// After reporting, the Value Metrics should have been reset.
class SecondBackend : public TestBackendBase {
public:
void ReportCounter(DatumId datum_id, uint64_t value) override {
switch (datum_id) {
// Value metrics - expected to have been reset
#define CHECK_METRIC(name, ...) case DatumId::k##name:
ART_VALUE_METRICS(CHECK_METRIC)
#undef CHECK_METRIC
EXPECT_EQ(value, 0u);
return;
// Event metrics - expected to have retained their previous value
#define CHECK_METRIC(name, ...) case DatumId::k##name:
ART_EVENT_METRICS(CHECK_METRIC)
#undef CHECK_METRIC
EXPECT_NE(value, 0u);
return;
default:
// unknown metric - it should not be possible to reach this path
FAIL();
UNREACHABLE();
}
}
// All histograms are event metrics.
void ReportHistogram([[maybe_unused]] DatumId histogram_type,
[[maybe_unused]] int64_t minimum_value,
[[maybe_unused]] int64_t maximum_value,
const std::vector<uint32_t>& buckets) override {
EXPECT_NE(buckets[0], 0u) << "Bucket 0 should have a non-zero value";
for (size_t i = 1; i < buckets.size(); i++) {
EXPECT_EQ(buckets[i], 0u) << "Bucket " << i << " should have a zero value";
}
}
} second_backend;
metrics.ReportAllMetricsAndResetValueMetrics({&second_backend});
}
TEST(TextFormatterTest, ReportMetrics_WithBuckets) {
TextFormatter text_formatter;
SessionData session_data {
.session_id = 1000,
.uid = 50,
.compilation_reason = CompilationReason::kInstall,
.compiler_filter = CompilerFilterReporting::kSpeed,
};
text_formatter.FormatBeginReport(200, session_data);
text_formatter.FormatReportCounter(DatumId::kFullGcCount, 1u);
text_formatter.FormatReportHistogram(DatumId::kFullGcCollectionTime,
50,
200,
{2, 4, 7, 1});
text_formatter.FormatEndReport();
const std::string result = text_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"\n*** ART internal metrics ***\n"
" Metadata:\n"
" timestamp_since_start_ms: 200\n"
" session_id: 1000\n"
" uid: 50\n"
" compilation_reason: install\n"
" compiler_filter: speed\n"
" Metrics:\n"
" FullGcCount: count = 1\n"
" FullGcCollectionTime: range = 50...200, buckets: 2,4,7,1\n"
"*** Done dumping ART internal metrics ***\n");
}
TEST(TextFormatterTest, ReportMetrics_NoBuckets) {
TextFormatter text_formatter;
SessionData session_data {
.session_id = 500,
.uid = 15,
.compilation_reason = CompilationReason::kCmdLine,
.compiler_filter = CompilerFilterReporting::kExtract,
};
text_formatter.FormatBeginReport(400, session_data);
text_formatter.FormatReportHistogram(DatumId::kFullGcCollectionTime, 10, 20, {});
text_formatter.FormatEndReport();
std::string result = text_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"\n*** ART internal metrics ***\n"
" Metadata:\n"
" timestamp_since_start_ms: 400\n"
" session_id: 500\n"
" uid: 15\n"
" compilation_reason: cmdline\n"
" compiler_filter: extract\n"
" Metrics:\n"
" FullGcCollectionTime: range = 10...20, no buckets\n"
"*** Done dumping ART internal metrics ***\n");
}
TEST(TextFormatterTest, BeginReport_NoSessionData) {
TextFormatter text_formatter;
std::optional<SessionData> empty_session_data;
text_formatter.FormatBeginReport(100, empty_session_data);
text_formatter.FormatEndReport();
std::string result = text_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"\n*** ART internal metrics ***\n"
" Metadata:\n"
" timestamp_since_start_ms: 100\n"
" Metrics:\n"
"*** Done dumping ART internal metrics ***\n");
}
TEST(TextFormatterTest, GetAndResetBuffer_ActuallyResetsBuffer) {
TextFormatter text_formatter;
std::optional<SessionData> empty_session_data;
text_formatter.FormatBeginReport(200, empty_session_data);
text_formatter.FormatReportCounter(DatumId::kFullGcCount, 1u);
text_formatter.FormatEndReport();
std::string result = text_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"\n*** ART internal metrics ***\n"
" Metadata:\n"
" timestamp_since_start_ms: 200\n"
" Metrics:\n"
" FullGcCount: count = 1\n"
"*** Done dumping ART internal metrics ***\n");
text_formatter.FormatBeginReport(300, empty_session_data);
text_formatter.FormatReportCounter(DatumId::kFullGcCount, 5u);
text_formatter.FormatEndReport();
result = text_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"\n*** ART internal metrics ***\n"
" Metadata:\n"
" timestamp_since_start_ms: 300\n"
" Metrics:\n"
" FullGcCount: count = 5\n"
"*** Done dumping ART internal metrics ***\n");
}
TEST(XmlFormatterTest, ReportMetrics_WithBuckets) {
XmlFormatter xml_formatter;
SessionData session_data {
.session_id = 123,
.uid = 456,
.compilation_reason = CompilationReason::kFirstBoot,
.compiler_filter = CompilerFilterReporting::kSpace,
};
xml_formatter.FormatBeginReport(250, session_data);
xml_formatter.FormatReportCounter(DatumId::kYoungGcCount, 3u);
xml_formatter.FormatReportHistogram(DatumId::kYoungGcCollectionTime,
300,
600,
{1, 5, 3});
xml_formatter.FormatEndReport();
const std::string result = xml_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"<art_runtime_metrics>"
"<version>1.0</version>"
"<metadata>"
"<timestamp_since_start_ms>250</timestamp_since_start_ms>"
"<session_id>123</session_id>"
"<uid>456</uid>"
"<compilation_reason>first-boot</compilation_reason>"
"<compiler_filter>space</compiler_filter>"
"</metadata>"
"<metrics>"
"<YoungGcCount>"
"<counter_type>count</counter_type>"
"<value>3</value>"
"</YoungGcCount>"
"<YoungGcCollectionTime>"
"<counter_type>histogram</counter_type>"
"<minimum_value>300</minimum_value>"
"<maximum_value>600</maximum_value>"
"<buckets>"
"<bucket>1</bucket>"
"<bucket>5</bucket>"
"<bucket>3</bucket>"
"</buckets>"
"</YoungGcCollectionTime>"
"</metrics>"
"</art_runtime_metrics>");
}
TEST(XmlFormatterTest, ReportMetrics_NoBuckets) {
XmlFormatter xml_formatter;
SessionData session_data {
.session_id = 234,
.uid = 345,
.compilation_reason = CompilationReason::kFirstBoot,
.compiler_filter = CompilerFilterReporting::kSpace,
};
xml_formatter.FormatBeginReport(160, session_data);
xml_formatter.FormatReportCounter(DatumId::kYoungGcCount, 4u);
xml_formatter.FormatReportHistogram(DatumId::kYoungGcCollectionTime, 20, 40, {});
xml_formatter.FormatEndReport();
const std::string result = xml_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"<art_runtime_metrics>"
"<version>1.0</version>"
"<metadata>"
"<timestamp_since_start_ms>160</timestamp_since_start_ms>"
"<session_id>234</session_id>"
"<uid>345</uid>"
"<compilation_reason>first-boot</compilation_reason>"
"<compiler_filter>space</compiler_filter>"
"</metadata>"
"<metrics>"
"<YoungGcCount>"
"<counter_type>count</counter_type>"
"<value>4</value>"
"</YoungGcCount>"
"<YoungGcCollectionTime>"
"<counter_type>histogram</counter_type>"
"<minimum_value>20</minimum_value>"
"<maximum_value>40</maximum_value>"
"<buckets/>"
"</YoungGcCollectionTime>"
"</metrics>"
"</art_runtime_metrics>");
}
TEST(XmlFormatterTest, BeginReport_NoSessionData) {
XmlFormatter xml_formatter;
std::optional<SessionData> empty_session_data;
xml_formatter.FormatBeginReport(100, empty_session_data);
xml_formatter.FormatReportCounter(DatumId::kYoungGcCount, 3u);
xml_formatter.FormatEndReport();
std::string result = xml_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"<art_runtime_metrics>"
"<version>1.0</version>"
"<metadata>"
"<timestamp_since_start_ms>100</timestamp_since_start_ms>"
"</metadata>"
"<metrics>"
"<YoungGcCount>"
"<counter_type>count</counter_type>"
"<value>3</value>"
"</YoungGcCount>"
"</metrics>"
"</art_runtime_metrics>");
}
TEST(XmlFormatterTest, GetAndResetBuffer_ActuallyResetsBuffer) {
XmlFormatter xml_formatter;
std::optional<SessionData> empty_session_data;
xml_formatter.FormatBeginReport(200, empty_session_data);
xml_formatter.FormatReportCounter(DatumId::kFullGcCount, 1u);
xml_formatter.FormatEndReport();
std::string result = xml_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"<art_runtime_metrics>"
"<version>1.0</version>"
"<metadata>"
"<timestamp_since_start_ms>200</timestamp_since_start_ms>"
"</metadata>"
"<metrics>"
"<FullGcCount>"
"<counter_type>count</counter_type>"
"<value>1</value>"
"</FullGcCount>"
"</metrics>"
"</art_runtime_metrics>");
xml_formatter.FormatBeginReport(300, empty_session_data);
xml_formatter.FormatReportCounter(DatumId::kFullGcCount, 5u);
xml_formatter.FormatEndReport();
result = xml_formatter.GetAndResetBuffer();
ASSERT_EQ(result,
"<art_runtime_metrics>"
"<version>1.0</version>"
"<metadata>"
"<timestamp_since_start_ms>300</timestamp_since_start_ms>"
"</metadata>"
"<metrics>"
"<FullGcCount>"
"<counter_type>count</counter_type>"
"<value>5</value>"
"</FullGcCount>"
"</metrics>"
"</art_runtime_metrics>");
}
TEST(CompilerFilterReportingTest, FromName) {
ASSERT_EQ(CompilerFilterReportingFromName("error"),
CompilerFilterReporting::kError);
ASSERT_EQ(CompilerFilterReportingFromName("unknown"),
CompilerFilterReporting::kUnknown);
ASSERT_EQ(CompilerFilterReportingFromName("assume-verified"),
CompilerFilterReporting::kAssumeVerified);
ASSERT_EQ(CompilerFilterReportingFromName("extract"),
CompilerFilterReporting::kExtract);
ASSERT_EQ(CompilerFilterReportingFromName("verify"),
CompilerFilterReporting::kVerify);
ASSERT_EQ(CompilerFilterReportingFromName("space-profile"),
CompilerFilterReporting::kSpaceProfile);
ASSERT_EQ(CompilerFilterReportingFromName("space"),
CompilerFilterReporting::kSpace);
ASSERT_EQ(CompilerFilterReportingFromName("speed-profile"),
CompilerFilterReporting::kSpeedProfile);
ASSERT_EQ(CompilerFilterReportingFromName("speed"),
CompilerFilterReporting::kSpeed);
ASSERT_EQ(CompilerFilterReportingFromName("everything-profile"),
CompilerFilterReporting::kEverythingProfile);
ASSERT_EQ(CompilerFilterReportingFromName("everything"),
CompilerFilterReporting::kEverything);
ASSERT_EQ(CompilerFilterReportingFromName("run-from-apk"),
CompilerFilterReporting::kRunFromApk);
ASSERT_EQ(CompilerFilterReportingFromName("run-from-apk-fallback"),
CompilerFilterReporting::kRunFromApkFallback);
}
TEST(CompilerFilterReportingTest, Name) {
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kError),
"error");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kUnknown),
"unknown");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kAssumeVerified),
"assume-verified");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kExtract),
"extract");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kVerify),
"verify");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kSpaceProfile),
"space-profile");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kSpace),
"space");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kSpeedProfile),
"speed-profile");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kSpeed),
"speed");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kEverythingProfile),
"everything-profile");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kEverything),
"everything");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kRunFromApk),
"run-from-apk");
ASSERT_EQ(CompilerFilterReportingName(CompilerFilterReporting::kRunFromApkFallback),
"run-from-apk-fallback");
}
TEST(CompilerReason, FromName) {
ASSERT_EQ(CompilationReasonFromName("unknown"),
CompilationReason::kUnknown);
ASSERT_EQ(CompilationReasonFromName("first-boot"),
CompilationReason::kFirstBoot);
ASSERT_EQ(CompilationReasonFromName("boot-after-ota"),
CompilationReason::kBootAfterOTA);
ASSERT_EQ(CompilationReasonFromName("post-boot"),
CompilationReason::kPostBoot);
ASSERT_EQ(CompilationReasonFromName("install"),
CompilationReason::kInstall);
ASSERT_EQ(CompilationReasonFromName("install-fast"),
CompilationReason::kInstallFast);
ASSERT_EQ(CompilationReasonFromName("install-bulk"),
CompilationReason::kInstallBulk);
ASSERT_EQ(CompilationReasonFromName("install-bulk-secondary"),
CompilationReason::kInstallBulkSecondary);
ASSERT_EQ(CompilationReasonFromName("install-bulk-downgraded"),
CompilationReason::kInstallBulkDowngraded);
ASSERT_EQ(CompilationReasonFromName("install-bulk-secondary-downgraded"),
CompilationReason::kInstallBulkSecondaryDowngraded);
ASSERT_EQ(CompilationReasonFromName("bg-dexopt"),
CompilationReason::kBgDexopt);
ASSERT_EQ(CompilationReasonFromName("ab-ota"),
CompilationReason::kABOTA);
ASSERT_EQ(CompilationReasonFromName("inactive"),
CompilationReason::kInactive);
ASSERT_EQ(CompilationReasonFromName("shared"),
CompilationReason::kShared);
ASSERT_EQ(CompilationReasonFromName("install-with-dex-metadata"),
CompilationReason::kInstallWithDexMetadata);
ASSERT_EQ(CompilationReasonFromName("prebuilt"),
CompilationReason::kPrebuilt);
ASSERT_EQ(CompilationReasonFromName("cmdline"),
CompilationReason::kCmdLine);
ASSERT_EQ(CompilationReasonFromName("error"),
CompilationReason::kError);
ASSERT_EQ(CompilationReasonFromName("vdex"),
CompilationReason::kVdex);
ASSERT_EQ(CompilationReasonFromName("boot-after-mainline-update"),
CompilationReason::kBootAfterMainlineUpdate);
}
TEST(CompilerReason, Name) {
ASSERT_EQ(CompilationReasonName(CompilationReason::kUnknown),
"unknown");
ASSERT_EQ(CompilationReasonName(CompilationReason::kFirstBoot),
"first-boot");
ASSERT_EQ(CompilationReasonName(CompilationReason::kBootAfterOTA),
"boot-after-ota");
ASSERT_EQ(CompilationReasonName(CompilationReason::kPostBoot),
"post-boot");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstall),
"install");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstallFast),
"install-fast");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstallBulk),
"install-bulk");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstallBulkSecondary),
"install-bulk-secondary");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstallBulkDowngraded),
"install-bulk-downgraded");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstallBulkSecondaryDowngraded),
"install-bulk-secondary-downgraded");
ASSERT_EQ(CompilationReasonName(CompilationReason::kBgDexopt),
"bg-dexopt");
ASSERT_EQ(CompilationReasonName(CompilationReason::kABOTA),
"ab-ota");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInactive),
"inactive");
ASSERT_EQ(CompilationReasonName(CompilationReason::kShared),
"shared");
ASSERT_EQ(CompilationReasonName(CompilationReason::kInstallWithDexMetadata),
"install-with-dex-metadata");
ASSERT_EQ(CompilationReasonName(CompilationReason::kPrebuilt),
"prebuilt");
ASSERT_EQ(CompilationReasonName(CompilationReason::kCmdLine),
"cmdline");
ASSERT_EQ(CompilationReasonName(CompilationReason::kError),
"error");
ASSERT_EQ(CompilationReasonName(CompilationReason::kVdex),
"vdex");
ASSERT_EQ(CompilationReasonName(CompilationReason::kBootAfterMainlineUpdate),
"boot-after-mainline-update");
}
} // namespace metrics
} // namespace art
#pragma clang diagnostic pop // -Wconversion