absl/strings/internal/cordz_functions_test.cc - external/github.com/abseil/abseil-cpp - Git at Google

 // Copyright 2019 The Abseil Authors.
 //
 // 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
 //
 //      https://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 "absl/strings/internal/cordz_functions.h"

 #include <thread>  // NOLINT we need real clean new threads

 #include "gmock/gmock.h"
 #include "gtest/gtest.h"
 #include "absl/base/config.h"

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace cord_internal {
 namespace {

 using ::testing::Eq;
 using ::testing::Ge;
 using ::testing::Le;

 TEST(CordzFunctionsTest, SampleRate) {
   int32_t orig_sample_rate = get_cordz_mean_interval();
   int32_t expected_sample_rate = 123;
   set_cordz_mean_interval(expected_sample_rate);
   EXPECT_THAT(get_cordz_mean_interval(), Eq(expected_sample_rate));
   set_cordz_mean_interval(orig_sample_rate);
 }

 // Cordz is disabled when we don't have thread_local. All calls to
 // should_profile will return false when cordz is diabled, so we might want to
 // avoid those tests.
 #ifdef ABSL_INTERNAL_CORDZ_ENABLED

 TEST(CordzFunctionsTest, ShouldProfileDisable) {
   int32_t orig_sample_rate = get_cordz_mean_interval();

   set_cordz_mean_interval(0);
   cordz_set_next_sample_for_testing(0);
   EXPECT_FALSE(cordz_should_profile());
   // 1 << 16 is from kIntervalIfDisabled in cordz_functions.cc.
   EXPECT_THAT(cordz_next_sample, Eq(1 << 16));

   set_cordz_mean_interval(orig_sample_rate);
 }

 TEST(CordzFunctionsTest, ShouldProfileAlways) {
   int32_t orig_sample_rate = get_cordz_mean_interval();

   set_cordz_mean_interval(1);
   cordz_set_next_sample_for_testing(1);
   EXPECT_TRUE(cordz_should_profile());
   EXPECT_THAT(cordz_next_sample, Le(1));

   set_cordz_mean_interval(orig_sample_rate);
 }

 TEST(CordzFunctionsTest, DoesNotAlwaysSampleFirstCord) {
   // Set large enough interval such that the chance of 'tons' of threads
   // randomly sampling the first call is infinitely small.
   set_cordz_mean_interval(10000);
   int tries = 0;
   bool sampled = false;
   do {
     ++tries;
     ASSERT_THAT(tries, Le(1000));
     std::thread thread([&sampled] {
       sampled = cordz_should_profile();
     });
     thread.join();
   } while (sampled);
 }

 TEST(CordzFunctionsTest, ShouldProfileRate) {
   static constexpr int kDesiredMeanInterval = 1000;
   static constexpr int kSamples = 10000;
   int32_t orig_sample_rate = get_cordz_mean_interval();

   set_cordz_mean_interval(kDesiredMeanInterval);

   int64_t sum_of_intervals = 0;
   for (int i = 0; i < kSamples; i++) {
     // Setting next_sample to 0 will force cordz_should_profile to generate a
     // new value for next_sample each iteration.
     cordz_set_next_sample_for_testing(0);
     cordz_should_profile();
     sum_of_intervals += cordz_next_sample;
   }

   // The sum of independent exponential variables is an Erlang distribution,
   // which is a gamma distribution where the shape parameter is equal to the
   // number of summands. The distribution used for cordz_should_profile is
   // actually floor(Exponential(1/mean)) which introduces bias. However, we can
   // apply the squint-really-hard correction factor. That is, when mean is
   // large, then if we squint really hard the shape of the distribution between
   // N and N+1 looks like a uniform distribution. On average, each value for
   // next_sample will be about 0.5 lower than we would expect from an
   // exponential distribution. This squint-really-hard correction approach won't
   // work when mean is smaller than about 10 but works fine when mean is 1000.
   //
   // We can use R to calculate a confidence interval. This
   // shows how to generate a confidence interval with a false positive rate of
   // one in a billion.
   //
   // $ R -q
   // > mean = 1000
   // > kSamples = 10000
   // > errorRate = 1e-9
   // > correction = -kSamples / 2
   // > low = qgamma(errorRate/2, kSamples, 1/mean) + correction
   // > high = qgamma(1 - errorRate/2, kSamples, 1/mean) + correction
   // > low
   // [1] 9396115
   // > high
   // [1] 10618100
   EXPECT_THAT(sum_of_intervals, Ge(9396115));
   EXPECT_THAT(sum_of_intervals, Le(10618100));

   set_cordz_mean_interval(orig_sample_rate);
 }

 #else  // ABSL_INTERNAL_CORDZ_ENABLED

 TEST(CordzFunctionsTest, ShouldProfileDisabled) {
   int32_t orig_sample_rate = get_cordz_mean_interval();

   set_cordz_mean_interval(1);
   cordz_set_next_sample_for_testing(0);
   EXPECT_FALSE(cordz_should_profile());

   set_cordz_mean_interval(orig_sample_rate);
 }

 #endif  // ABSL_INTERNAL_CORDZ_ENABLED

 }  // namespace
 }  // namespace cord_internal
 ABSL_NAMESPACE_END
 }  // namespace absl
	// Copyright 2019 The Abseil Authors.
	//
	// 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
	//
	// https://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 "absl/strings/internal/cordz_functions.h"

	#include <thread> // NOLINT we need real clean new threads

	#include "gmock/gmock.h"
	#include "gtest/gtest.h"
	#include "absl/base/config.h"

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace cord_internal {
	namespace {

	using ::testing::Eq;
	using ::testing::Ge;
	using ::testing::Le;

	TEST(CordzFunctionsTest, SampleRate) {
	int32_t orig_sample_rate = get_cordz_mean_interval();
	int32_t expected_sample_rate = 123;
	set_cordz_mean_interval(expected_sample_rate);
	EXPECT_THAT(get_cordz_mean_interval(), Eq(expected_sample_rate));
	set_cordz_mean_interval(orig_sample_rate);
	}

	// Cordz is disabled when we don't have thread_local. All calls to
	// should_profile will return false when cordz is diabled, so we might want to
	// avoid those tests.
	#ifdef ABSL_INTERNAL_CORDZ_ENABLED

	TEST(CordzFunctionsTest, ShouldProfileDisable) {
	int32_t orig_sample_rate = get_cordz_mean_interval();

	set_cordz_mean_interval(0);
	cordz_set_next_sample_for_testing(0);
	EXPECT_FALSE(cordz_should_profile());
	// 1 << 16 is from kIntervalIfDisabled in cordz_functions.cc.
	EXPECT_THAT(cordz_next_sample, Eq(1 << 16));

	set_cordz_mean_interval(orig_sample_rate);
	}

	TEST(CordzFunctionsTest, ShouldProfileAlways) {
	int32_t orig_sample_rate = get_cordz_mean_interval();

	set_cordz_mean_interval(1);
	cordz_set_next_sample_for_testing(1);
	EXPECT_TRUE(cordz_should_profile());
	EXPECT_THAT(cordz_next_sample, Le(1));

	set_cordz_mean_interval(orig_sample_rate);
	}

	TEST(CordzFunctionsTest, DoesNotAlwaysSampleFirstCord) {
	// Set large enough interval such that the chance of 'tons' of threads
	// randomly sampling the first call is infinitely small.
	set_cordz_mean_interval(10000);
	int tries = 0;
	bool sampled = false;
	do {
	++tries;
	ASSERT_THAT(tries, Le(1000));
	std::thread thread([&sampled] {
	sampled = cordz_should_profile();
	});
	thread.join();
	} while (sampled);
	}

	TEST(CordzFunctionsTest, ShouldProfileRate) {
	static constexpr int kDesiredMeanInterval = 1000;
	static constexpr int kSamples = 10000;
	int32_t orig_sample_rate = get_cordz_mean_interval();

	set_cordz_mean_interval(kDesiredMeanInterval);

	int64_t sum_of_intervals = 0;
	for (int i = 0; i < kSamples; i++) {
	// Setting next_sample to 0 will force cordz_should_profile to generate a
	// new value for next_sample each iteration.
	cordz_set_next_sample_for_testing(0);
	cordz_should_profile();
	sum_of_intervals += cordz_next_sample;
	}

	// The sum of independent exponential variables is an Erlang distribution,
	// which is a gamma distribution where the shape parameter is equal to the
	// number of summands. The distribution used for cordz_should_profile is
	// actually floor(Exponential(1/mean)) which introduces bias. However, we can
	// apply the squint-really-hard correction factor. That is, when mean is
	// large, then if we squint really hard the shape of the distribution between
	// N and N+1 looks like a uniform distribution. On average, each value for
	// next_sample will be about 0.5 lower than we would expect from an
	// exponential distribution. This squint-really-hard correction approach won't
	// work when mean is smaller than about 10 but works fine when mean is 1000.
	//
	// We can use R to calculate a confidence interval. This
	// shows how to generate a confidence interval with a false positive rate of
	// one in a billion.
	//
	// $ R -q
	// > mean = 1000
	// > kSamples = 10000
	// > errorRate = 1e-9
	// > correction = -kSamples / 2
	// > low = qgamma(errorRate/2, kSamples, 1/mean) + correction
	// > high = qgamma(1 - errorRate/2, kSamples, 1/mean) + correction
	// > low
	// [1] 9396115
	// > high
	// [1] 10618100
	EXPECT_THAT(sum_of_intervals, Ge(9396115));
	EXPECT_THAT(sum_of_intervals, Le(10618100));

	set_cordz_mean_interval(orig_sample_rate);
	}

	#else // ABSL_INTERNAL_CORDZ_ENABLED

	TEST(CordzFunctionsTest, ShouldProfileDisabled) {
	int32_t orig_sample_rate = get_cordz_mean_interval();

	set_cordz_mean_interval(1);
	cordz_set_next_sample_for_testing(0);
	EXPECT_FALSE(cordz_should_profile());

	set_cordz_mean_interval(orig_sample_rate);
	}

	#endif // ABSL_INTERNAL_CORDZ_ENABLED

	} // namespace
	} // namespace cord_internal
	ABSL_NAMESPACE_END
	} // namespace absl