api/test/metrics/metrics_accumulator_test.cc - src/ - Git at Google

 /*
  *  Copyright (c) 2022 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */
 #include "api/test/metrics/metrics_accumulator.h"

 #include <map>
 #include <vector>

 #include "api/test/metrics/metric.h"
 #include "api/units/timestamp.h"
 #include "test/gmock.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace test {
 namespace {

 using ::testing::Eq;
 using ::testing::IsEmpty;
 using ::testing::SizeIs;

 TEST(MetricsAccumulatorTest, AddSampleToTheNewMetricWillCreateOne) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddSample(
       "metric_name", "test_case_name",
       /*value=*/10, Timestamp::Seconds(1),
       /*point_metadata=*/std::map<std::string, std::string>{{"key", "value"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(1));
   const Metric& metric = metrics[0];
   EXPECT_THAT(metric.name, Eq("metric_name"));
   EXPECT_THAT(metric.test_case, Eq("test_case_name"));
   EXPECT_THAT(metric.unit, Eq(Unit::kUnitless));
   EXPECT_THAT(metric.improvement_direction,
               Eq(ImprovementDirection::kNeitherIsBetter));
   EXPECT_THAT(metric.metric_metadata, IsEmpty());
   ASSERT_THAT(metric.time_series.samples, SizeIs(1));
   EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
   EXPECT_THAT(metric.time_series.samples[0].timestamp,
               Eq(Timestamp::Seconds(1)));
   EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key", "value"}}));
   ASSERT_THAT(metric.stats.mean, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.stddev, absl::optional<double>(0.0));
   ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.max, absl::optional<double>(10.0));
 }

 TEST(MetricsAccumulatorTest, AddSamplesToExistingMetricWontCreateNewOne) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddSample(
       "metric_name", "test_case_name",
       /*value=*/10, Timestamp::Seconds(1),
       /*point_metadata=*/
       std::map<std::string, std::string>{{"key1", "value1"}}));
   ASSERT_FALSE(accumulator.AddSample(
       "metric_name", "test_case_name",
       /*value=*/20, Timestamp::Seconds(2),
       /*point_metadata=*/
       std::map<std::string, std::string>{{"key2", "value2"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(1));
   const Metric& metric = metrics[0];
   EXPECT_THAT(metric.name, Eq("metric_name"));
   EXPECT_THAT(metric.test_case, Eq("test_case_name"));
   EXPECT_THAT(metric.unit, Eq(Unit::kUnitless));
   EXPECT_THAT(metric.improvement_direction,
               Eq(ImprovementDirection::kNeitherIsBetter));
   EXPECT_THAT(metric.metric_metadata, IsEmpty());
   ASSERT_THAT(metric.time_series.samples, SizeIs(2));
   EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
   EXPECT_THAT(metric.time_series.samples[0].timestamp,
               Eq(Timestamp::Seconds(1)));
   EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key1", "value1"}}));
   EXPECT_THAT(metric.time_series.samples[1].value, Eq(20.0));
   EXPECT_THAT(metric.time_series.samples[1].timestamp,
               Eq(Timestamp::Seconds(2)));
   EXPECT_THAT(metric.time_series.samples[1].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
   ASSERT_THAT(metric.stats.mean, absl::optional<double>(15.0));
   ASSERT_THAT(metric.stats.stddev, absl::optional<double>(5.0));
   ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.max, absl::optional<double>(20.0));
 }

 TEST(MetricsAccumulatorTest, AddSampleToDifferentMetricsWillCreateBoth) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddSample(
       "metric_name1", "test_case_name1",
       /*value=*/10, Timestamp::Seconds(1),
       /*point_metadata=*/
       std::map<std::string, std::string>{{"key1", "value1"}}));
   ASSERT_TRUE(accumulator.AddSample(
       "metric_name2", "test_case_name2",
       /*value=*/20, Timestamp::Seconds(2),
       /*point_metadata=*/
       std::map<std::string, std::string>{{"key2", "value2"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(2));
   EXPECT_THAT(metrics[0].name, Eq("metric_name1"));
   EXPECT_THAT(metrics[0].test_case, Eq("test_case_name1"));
   EXPECT_THAT(metrics[0].unit, Eq(Unit::kUnitless));
   EXPECT_THAT(metrics[0].improvement_direction,
               Eq(ImprovementDirection::kNeitherIsBetter));
   EXPECT_THAT(metrics[0].metric_metadata, IsEmpty());
   ASSERT_THAT(metrics[0].time_series.samples, SizeIs(1));
   EXPECT_THAT(metrics[0].time_series.samples[0].value, Eq(10.0));
   EXPECT_THAT(metrics[0].time_series.samples[0].timestamp,
               Eq(Timestamp::Seconds(1)));
   EXPECT_THAT(metrics[0].time_series.samples[0].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key1", "value1"}}));
   ASSERT_THAT(metrics[0].stats.mean, absl::optional<double>(10.0));
   ASSERT_THAT(metrics[0].stats.stddev, absl::optional<double>(0.0));
   ASSERT_THAT(metrics[0].stats.min, absl::optional<double>(10.0));
   ASSERT_THAT(metrics[0].stats.max, absl::optional<double>(10.0));
   EXPECT_THAT(metrics[1].name, Eq("metric_name2"));
   EXPECT_THAT(metrics[1].test_case, Eq("test_case_name2"));
   EXPECT_THAT(metrics[1].unit, Eq(Unit::kUnitless));
   EXPECT_THAT(metrics[1].improvement_direction,
               Eq(ImprovementDirection::kNeitherIsBetter));
   EXPECT_THAT(metrics[1].metric_metadata, IsEmpty());
   ASSERT_THAT(metrics[1].time_series.samples, SizeIs(1));
   EXPECT_THAT(metrics[1].time_series.samples[0].value, Eq(20.0));
   EXPECT_THAT(metrics[1].time_series.samples[0].timestamp,
               Eq(Timestamp::Seconds(2)));
   EXPECT_THAT(metrics[1].time_series.samples[0].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
   ASSERT_THAT(metrics[1].stats.mean, absl::optional<double>(20.0));
   ASSERT_THAT(metrics[1].stats.stddev, absl::optional<double>(0.0));
   ASSERT_THAT(metrics[1].stats.min, absl::optional<double>(20.0));
   ASSERT_THAT(metrics[1].stats.max, absl::optional<double>(20.0));
 }

 TEST(MetricsAccumulatorTest, AddMetadataToTheNewMetricWillCreateOne) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddMetricMetadata(
       "metric_name", "test_case_name", Unit::kMilliseconds,
       ImprovementDirection::kBiggerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key", "value"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(1));
   const Metric& metric = metrics[0];
   EXPECT_THAT(metric.name, Eq("metric_name"));
   EXPECT_THAT(metric.test_case, Eq("test_case_name"));
   EXPECT_THAT(metric.unit, Eq(Unit::kMilliseconds));
   EXPECT_THAT(metric.improvement_direction,
               Eq(ImprovementDirection::kBiggerIsBetter));
   EXPECT_THAT(metric.metric_metadata,
               Eq(std::map<std::string, std::string>{{"key", "value"}}));
   ASSERT_THAT(metric.time_series.samples, IsEmpty());
   ASSERT_THAT(metric.stats.mean, absl::nullopt);
   ASSERT_THAT(metric.stats.stddev, absl::nullopt);
   ASSERT_THAT(metric.stats.min, absl::nullopt);
   ASSERT_THAT(metric.stats.max, absl::nullopt);
 }

 TEST(MetricsAccumulatorTest,
      AddMetadataToTheExistingMetricWillOverwriteValues) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddMetricMetadata(
       "metric_name", "test_case_name", Unit::kMilliseconds,
       ImprovementDirection::kBiggerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key1", "value1"}}));

   ASSERT_FALSE(accumulator.AddMetricMetadata(
       "metric_name", "test_case_name", Unit::kBytes,
       ImprovementDirection::kSmallerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key2", "value2"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(1));
   const Metric& metric = metrics[0];
   EXPECT_THAT(metric.name, Eq("metric_name"));
   EXPECT_THAT(metric.test_case, Eq("test_case_name"));
   EXPECT_THAT(metric.unit, Eq(Unit::kBytes));
   EXPECT_THAT(metric.improvement_direction,
               Eq(ImprovementDirection::kSmallerIsBetter));
   EXPECT_THAT(metric.metric_metadata,
               Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
   ASSERT_THAT(metric.time_series.samples, IsEmpty());
   ASSERT_THAT(metric.stats.mean, absl::nullopt);
   ASSERT_THAT(metric.stats.stddev, absl::nullopt);
   ASSERT_THAT(metric.stats.min, absl::nullopt);
   ASSERT_THAT(metric.stats.max, absl::nullopt);
 }

 TEST(MetricsAccumulatorTest, AddMetadataToDifferentMetricsWillCreateBoth) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddMetricMetadata(
       "metric_name1", "test_case_name1", Unit::kMilliseconds,
       ImprovementDirection::kBiggerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key1", "value1"}}));

   ASSERT_TRUE(accumulator.AddMetricMetadata(
       "metric_name2", "test_case_name2", Unit::kBytes,
       ImprovementDirection::kSmallerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key2", "value2"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(2));
   EXPECT_THAT(metrics[0].name, Eq("metric_name1"));
   EXPECT_THAT(metrics[0].test_case, Eq("test_case_name1"));
   EXPECT_THAT(metrics[0].unit, Eq(Unit::kMilliseconds));
   EXPECT_THAT(metrics[0].improvement_direction,
               Eq(ImprovementDirection::kBiggerIsBetter));
   EXPECT_THAT(metrics[0].metric_metadata,
               Eq(std::map<std::string, std::string>{{"key1", "value1"}}));
   ASSERT_THAT(metrics[0].time_series.samples, IsEmpty());
   ASSERT_THAT(metrics[0].stats.mean, absl::nullopt);
   ASSERT_THAT(metrics[0].stats.stddev, absl::nullopt);
   ASSERT_THAT(metrics[0].stats.min, absl::nullopt);
   ASSERT_THAT(metrics[0].stats.max, absl::nullopt);
   EXPECT_THAT(metrics[1].name, Eq("metric_name2"));
   EXPECT_THAT(metrics[1].test_case, Eq("test_case_name2"));
   EXPECT_THAT(metrics[1].unit, Eq(Unit::kBytes));
   EXPECT_THAT(metrics[1].improvement_direction,
               Eq(ImprovementDirection::kSmallerIsBetter));
   EXPECT_THAT(metrics[1].metric_metadata,
               Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
   ASSERT_THAT(metrics[1].time_series.samples, IsEmpty());
   ASSERT_THAT(metrics[1].stats.mean, absl::nullopt);
   ASSERT_THAT(metrics[1].stats.stddev, absl::nullopt);
   ASSERT_THAT(metrics[1].stats.min, absl::nullopt);
   ASSERT_THAT(metrics[1].stats.max, absl::nullopt);
 }

 TEST(MetricsAccumulatorTest, AddMetadataAfterAddingSampleWontCreateNewMetric) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddSample(
       "metric_name", "test_case_name",
       /*value=*/10, Timestamp::Seconds(1),
       /*point_metadata=*/
       std::map<std::string, std::string>{{"key_s", "value_s"}}));
   ASSERT_FALSE(accumulator.AddMetricMetadata(
       "metric_name", "test_case_name", Unit::kMilliseconds,
       ImprovementDirection::kBiggerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key_m", "value_m"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(1));
   const Metric& metric = metrics[0];
   EXPECT_THAT(metric.name, Eq("metric_name"));
   EXPECT_THAT(metric.test_case, Eq("test_case_name"));
   EXPECT_THAT(metric.unit, Eq(Unit::kMilliseconds));
   EXPECT_THAT(metric.improvement_direction,
               Eq(ImprovementDirection::kBiggerIsBetter));
   EXPECT_THAT(metric.metric_metadata,
               Eq(std::map<std::string, std::string>{{"key_m", "value_m"}}));
   ASSERT_THAT(metric.time_series.samples, SizeIs(1));
   EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
   EXPECT_THAT(metric.time_series.samples[0].timestamp,
               Eq(Timestamp::Seconds(1)));
   EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key_s", "value_s"}}));
   ASSERT_THAT(metric.stats.mean, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.stddev, absl::optional<double>(0.0));
   ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.max, absl::optional<double>(10.0));
 }

 TEST(MetricsAccumulatorTest, AddSampleAfterAddingMetadataWontCreateNewMetric) {
   MetricsAccumulator accumulator;
   ASSERT_TRUE(accumulator.AddMetricMetadata(
       "metric_name", "test_case_name", Unit::kMilliseconds,
       ImprovementDirection::kBiggerIsBetter,
       /*metric_metadata=*/
       std::map<std::string, std::string>{{"key_m", "value_m"}}));
   ASSERT_FALSE(accumulator.AddSample(
       "metric_name", "test_case_name",
       /*value=*/10, Timestamp::Seconds(1),
       /*point_metadata=*/
       std::map<std::string, std::string>{{"key_s", "value_s"}}));

   std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
   ASSERT_THAT(metrics, SizeIs(1));
   const Metric& metric = metrics[0];
   EXPECT_THAT(metric.name, Eq("metric_name"));
   EXPECT_THAT(metric.test_case, Eq("test_case_name"));
   EXPECT_THAT(metric.unit, Eq(Unit::kMilliseconds));
   EXPECT_THAT(metric.improvement_direction,
               Eq(ImprovementDirection::kBiggerIsBetter));
   EXPECT_THAT(metric.metric_metadata,
               Eq(std::map<std::string, std::string>{{"key_m", "value_m"}}));
   ASSERT_THAT(metric.time_series.samples, SizeIs(1));
   EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
   EXPECT_THAT(metric.time_series.samples[0].timestamp,
               Eq(Timestamp::Seconds(1)));
   EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
               Eq(std::map<std::string, std::string>{{"key_s", "value_s"}}));
   ASSERT_THAT(metric.stats.mean, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.stddev, absl::optional<double>(0.0));
   ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
   ASSERT_THAT(metric.stats.max, absl::optional<double>(10.0));
 }

 }  // namespace
 }  // namespace test
 }  // namespace webrtc
	/*
	* Copyright (c) 2022 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/
	#include "api/test/metrics/metrics_accumulator.h"

	#include <map>
	#include <vector>

	#include "api/test/metrics/metric.h"
	#include "api/units/timestamp.h"
	#include "test/gmock.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace test {
	namespace {

	using ::testing::Eq;
	using ::testing::IsEmpty;
	using ::testing::SizeIs;

	TEST(MetricsAccumulatorTest, AddSampleToTheNewMetricWillCreateOne) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddSample(
	"metric_name", "test_case_name",
	/value=/10, Timestamp::Seconds(1),
	/point_metadata=/std::map<std::string, std::string>{{"key", "value"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(1));
	const Metric& metric = metrics[0];
	EXPECT_THAT(metric.name, Eq("metric_name"));
	EXPECT_THAT(metric.test_case, Eq("test_case_name"));
	EXPECT_THAT(metric.unit, Eq(Unit::kUnitless));
	EXPECT_THAT(metric.improvement_direction,
	Eq(ImprovementDirection::kNeitherIsBetter));
	EXPECT_THAT(metric.metric_metadata, IsEmpty());
	ASSERT_THAT(metric.time_series.samples, SizeIs(1));
	EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
	EXPECT_THAT(metric.time_series.samples[0].timestamp,
	Eq(Timestamp::Seconds(1)));
	EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key", "value"}}));
	ASSERT_THAT(metric.stats.mean, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.stddev, absl::optional<double>(0.0));
	ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.max, absl::optional<double>(10.0));
	}

	TEST(MetricsAccumulatorTest, AddSamplesToExistingMetricWontCreateNewOne) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddSample(
	"metric_name", "test_case_name",
	/value=/10, Timestamp::Seconds(1),
	/point_metadata=/
	std::map<std::string, std::string>{{"key1", "value1"}}));
	ASSERT_FALSE(accumulator.AddSample(
	"metric_name", "test_case_name",
	/value=/20, Timestamp::Seconds(2),
	/point_metadata=/
	std::map<std::string, std::string>{{"key2", "value2"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(1));
	const Metric& metric = metrics[0];
	EXPECT_THAT(metric.name, Eq("metric_name"));
	EXPECT_THAT(metric.test_case, Eq("test_case_name"));
	EXPECT_THAT(metric.unit, Eq(Unit::kUnitless));
	EXPECT_THAT(metric.improvement_direction,
	Eq(ImprovementDirection::kNeitherIsBetter));
	EXPECT_THAT(metric.metric_metadata, IsEmpty());
	ASSERT_THAT(metric.time_series.samples, SizeIs(2));
	EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
	EXPECT_THAT(metric.time_series.samples[0].timestamp,
	Eq(Timestamp::Seconds(1)));
	EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key1", "value1"}}));
	EXPECT_THAT(metric.time_series.samples[1].value, Eq(20.0));
	EXPECT_THAT(metric.time_series.samples[1].timestamp,
	Eq(Timestamp::Seconds(2)));
	EXPECT_THAT(metric.time_series.samples[1].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
	ASSERT_THAT(metric.stats.mean, absl::optional<double>(15.0));
	ASSERT_THAT(metric.stats.stddev, absl::optional<double>(5.0));
	ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.max, absl::optional<double>(20.0));
	}

	TEST(MetricsAccumulatorTest, AddSampleToDifferentMetricsWillCreateBoth) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddSample(
	"metric_name1", "test_case_name1",
	/value=/10, Timestamp::Seconds(1),
	/point_metadata=/
	std::map<std::string, std::string>{{"key1", "value1"}}));
	ASSERT_TRUE(accumulator.AddSample(
	"metric_name2", "test_case_name2",
	/value=/20, Timestamp::Seconds(2),
	/point_metadata=/
	std::map<std::string, std::string>{{"key2", "value2"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(2));
	EXPECT_THAT(metrics[0].name, Eq("metric_name1"));
	EXPECT_THAT(metrics[0].test_case, Eq("test_case_name1"));
	EXPECT_THAT(metrics[0].unit, Eq(Unit::kUnitless));
	EXPECT_THAT(metrics[0].improvement_direction,
	Eq(ImprovementDirection::kNeitherIsBetter));
	EXPECT_THAT(metrics[0].metric_metadata, IsEmpty());
	ASSERT_THAT(metrics[0].time_series.samples, SizeIs(1));
	EXPECT_THAT(metrics[0].time_series.samples[0].value, Eq(10.0));
	EXPECT_THAT(metrics[0].time_series.samples[0].timestamp,
	Eq(Timestamp::Seconds(1)));
	EXPECT_THAT(metrics[0].time_series.samples[0].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key1", "value1"}}));
	ASSERT_THAT(metrics[0].stats.mean, absl::optional<double>(10.0));
	ASSERT_THAT(metrics[0].stats.stddev, absl::optional<double>(0.0));
	ASSERT_THAT(metrics[0].stats.min, absl::optional<double>(10.0));
	ASSERT_THAT(metrics[0].stats.max, absl::optional<double>(10.0));
	EXPECT_THAT(metrics[1].name, Eq("metric_name2"));
	EXPECT_THAT(metrics[1].test_case, Eq("test_case_name2"));
	EXPECT_THAT(metrics[1].unit, Eq(Unit::kUnitless));
	EXPECT_THAT(metrics[1].improvement_direction,
	Eq(ImprovementDirection::kNeitherIsBetter));
	EXPECT_THAT(metrics[1].metric_metadata, IsEmpty());
	ASSERT_THAT(metrics[1].time_series.samples, SizeIs(1));
	EXPECT_THAT(metrics[1].time_series.samples[0].value, Eq(20.0));
	EXPECT_THAT(metrics[1].time_series.samples[0].timestamp,
	Eq(Timestamp::Seconds(2)));
	EXPECT_THAT(metrics[1].time_series.samples[0].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
	ASSERT_THAT(metrics[1].stats.mean, absl::optional<double>(20.0));
	ASSERT_THAT(metrics[1].stats.stddev, absl::optional<double>(0.0));
	ASSERT_THAT(metrics[1].stats.min, absl::optional<double>(20.0));
	ASSERT_THAT(metrics[1].stats.max, absl::optional<double>(20.0));
	}

	TEST(MetricsAccumulatorTest, AddMetadataToTheNewMetricWillCreateOne) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddMetricMetadata(
	"metric_name", "test_case_name", Unit::kMilliseconds,
	ImprovementDirection::kBiggerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key", "value"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(1));
	const Metric& metric = metrics[0];
	EXPECT_THAT(metric.name, Eq("metric_name"));
	EXPECT_THAT(metric.test_case, Eq("test_case_name"));
	EXPECT_THAT(metric.unit, Eq(Unit::kMilliseconds));
	EXPECT_THAT(metric.improvement_direction,
	Eq(ImprovementDirection::kBiggerIsBetter));
	EXPECT_THAT(metric.metric_metadata,
	Eq(std::map<std::string, std::string>{{"key", "value"}}));
	ASSERT_THAT(metric.time_series.samples, IsEmpty());
	ASSERT_THAT(metric.stats.mean, absl::nullopt);
	ASSERT_THAT(metric.stats.stddev, absl::nullopt);
	ASSERT_THAT(metric.stats.min, absl::nullopt);
	ASSERT_THAT(metric.stats.max, absl::nullopt);
	}

	TEST(MetricsAccumulatorTest,
	AddMetadataToTheExistingMetricWillOverwriteValues) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddMetricMetadata(
	"metric_name", "test_case_name", Unit::kMilliseconds,
	ImprovementDirection::kBiggerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key1", "value1"}}));

	ASSERT_FALSE(accumulator.AddMetricMetadata(
	"metric_name", "test_case_name", Unit::kBytes,
	ImprovementDirection::kSmallerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key2", "value2"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(1));
	const Metric& metric = metrics[0];
	EXPECT_THAT(metric.name, Eq("metric_name"));
	EXPECT_THAT(metric.test_case, Eq("test_case_name"));
	EXPECT_THAT(metric.unit, Eq(Unit::kBytes));
	EXPECT_THAT(metric.improvement_direction,
	Eq(ImprovementDirection::kSmallerIsBetter));
	EXPECT_THAT(metric.metric_metadata,
	Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
	ASSERT_THAT(metric.time_series.samples, IsEmpty());
	ASSERT_THAT(metric.stats.mean, absl::nullopt);
	ASSERT_THAT(metric.stats.stddev, absl::nullopt);
	ASSERT_THAT(metric.stats.min, absl::nullopt);
	ASSERT_THAT(metric.stats.max, absl::nullopt);
	}

	TEST(MetricsAccumulatorTest, AddMetadataToDifferentMetricsWillCreateBoth) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddMetricMetadata(
	"metric_name1", "test_case_name1", Unit::kMilliseconds,
	ImprovementDirection::kBiggerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key1", "value1"}}));

	ASSERT_TRUE(accumulator.AddMetricMetadata(
	"metric_name2", "test_case_name2", Unit::kBytes,
	ImprovementDirection::kSmallerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key2", "value2"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(2));
	EXPECT_THAT(metrics[0].name, Eq("metric_name1"));
	EXPECT_THAT(metrics[0].test_case, Eq("test_case_name1"));
	EXPECT_THAT(metrics[0].unit, Eq(Unit::kMilliseconds));
	EXPECT_THAT(metrics[0].improvement_direction,
	Eq(ImprovementDirection::kBiggerIsBetter));
	EXPECT_THAT(metrics[0].metric_metadata,
	Eq(std::map<std::string, std::string>{{"key1", "value1"}}));
	ASSERT_THAT(metrics[0].time_series.samples, IsEmpty());
	ASSERT_THAT(metrics[0].stats.mean, absl::nullopt);
	ASSERT_THAT(metrics[0].stats.stddev, absl::nullopt);
	ASSERT_THAT(metrics[0].stats.min, absl::nullopt);
	ASSERT_THAT(metrics[0].stats.max, absl::nullopt);
	EXPECT_THAT(metrics[1].name, Eq("metric_name2"));
	EXPECT_THAT(metrics[1].test_case, Eq("test_case_name2"));
	EXPECT_THAT(metrics[1].unit, Eq(Unit::kBytes));
	EXPECT_THAT(metrics[1].improvement_direction,
	Eq(ImprovementDirection::kSmallerIsBetter));
	EXPECT_THAT(metrics[1].metric_metadata,
	Eq(std::map<std::string, std::string>{{"key2", "value2"}}));
	ASSERT_THAT(metrics[1].time_series.samples, IsEmpty());
	ASSERT_THAT(metrics[1].stats.mean, absl::nullopt);
	ASSERT_THAT(metrics[1].stats.stddev, absl::nullopt);
	ASSERT_THAT(metrics[1].stats.min, absl::nullopt);
	ASSERT_THAT(metrics[1].stats.max, absl::nullopt);
	}

	TEST(MetricsAccumulatorTest, AddMetadataAfterAddingSampleWontCreateNewMetric) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddSample(
	"metric_name", "test_case_name",
	/value=/10, Timestamp::Seconds(1),
	/point_metadata=/
	std::map<std::string, std::string>{{"key_s", "value_s"}}));
	ASSERT_FALSE(accumulator.AddMetricMetadata(
	"metric_name", "test_case_name", Unit::kMilliseconds,
	ImprovementDirection::kBiggerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key_m", "value_m"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(1));
	const Metric& metric = metrics[0];
	EXPECT_THAT(metric.name, Eq("metric_name"));
	EXPECT_THAT(metric.test_case, Eq("test_case_name"));
	EXPECT_THAT(metric.unit, Eq(Unit::kMilliseconds));
	EXPECT_THAT(metric.improvement_direction,
	Eq(ImprovementDirection::kBiggerIsBetter));
	EXPECT_THAT(metric.metric_metadata,
	Eq(std::map<std::string, std::string>{{"key_m", "value_m"}}));
	ASSERT_THAT(metric.time_series.samples, SizeIs(1));
	EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
	EXPECT_THAT(metric.time_series.samples[0].timestamp,
	Eq(Timestamp::Seconds(1)));
	EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key_s", "value_s"}}));
	ASSERT_THAT(metric.stats.mean, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.stddev, absl::optional<double>(0.0));
	ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.max, absl::optional<double>(10.0));
	}

	TEST(MetricsAccumulatorTest, AddSampleAfterAddingMetadataWontCreateNewMetric) {
	MetricsAccumulator accumulator;
	ASSERT_TRUE(accumulator.AddMetricMetadata(
	"metric_name", "test_case_name", Unit::kMilliseconds,
	ImprovementDirection::kBiggerIsBetter,
	/metric_metadata=/
	std::map<std::string, std::string>{{"key_m", "value_m"}}));
	ASSERT_FALSE(accumulator.AddSample(
	"metric_name", "test_case_name",
	/value=/10, Timestamp::Seconds(1),
	/point_metadata=/
	std::map<std::string, std::string>{{"key_s", "value_s"}}));

	std::vector<Metric> metrics = accumulator.GetCollectedMetrics();
	ASSERT_THAT(metrics, SizeIs(1));
	const Metric& metric = metrics[0];
	EXPECT_THAT(metric.name, Eq("metric_name"));
	EXPECT_THAT(metric.test_case, Eq("test_case_name"));
	EXPECT_THAT(metric.unit, Eq(Unit::kMilliseconds));
	EXPECT_THAT(metric.improvement_direction,
	Eq(ImprovementDirection::kBiggerIsBetter));
	EXPECT_THAT(metric.metric_metadata,
	Eq(std::map<std::string, std::string>{{"key_m", "value_m"}}));
	ASSERT_THAT(metric.time_series.samples, SizeIs(1));
	EXPECT_THAT(metric.time_series.samples[0].value, Eq(10.0));
	EXPECT_THAT(metric.time_series.samples[0].timestamp,
	Eq(Timestamp::Seconds(1)));
	EXPECT_THAT(metric.time_series.samples[0].sample_metadata,
	Eq(std::map<std::string, std::string>{{"key_s", "value_s"}}));
	ASSERT_THAT(metric.stats.mean, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.stddev, absl::optional<double>(0.0));
	ASSERT_THAT(metric.stats.min, absl::optional<double>(10.0));
	ASSERT_THAT(metric.stats.max, absl::optional<double>(10.0));
	}

	} // namespace
	} // namespace test
	} // namespace webrtc