absl/base/internal/exponential_biased_test.cc - third_party/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/base/internal/exponential_biased.h"

 #include <stddef.h>

 #include <cmath>
 #include <cstdint>
 #include <vector>

 #include "gmock/gmock.h"
 #include "gtest/gtest.h"
 #include "absl/strings/str_cat.h"

 using ::testing::Ge;

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace base_internal {

 MATCHER_P2(IsBetween, a, b,
            absl::StrCat(std::string(negation ? "isn't" : "is"), " between ", a,
                         " and ", b)) {
   return a <= arg && arg <= b;
 }

 // Tests of the quality of the random numbers generated
 // This uses the Anderson Darling test for uniformity.
 // See "Evaluating the Anderson-Darling Distribution" by Marsaglia
 // for details.

 // Short cut version of ADinf(z), z>0 (from Marsaglia)
 // This returns the p-value for Anderson Darling statistic in
 // the limit as n-> infinity. For finite n, apply the error fix below.
 double AndersonDarlingInf(double z) {
   if (z < 2) {
     return exp(-1.2337141 / z) / sqrt(z) *
            (2.00012 +
             (0.247105 -
              (0.0649821 - (0.0347962 - (0.011672 - 0.00168691 * z) * z) * z) *
                  z) *
                 z);
   }
   return exp(
       -exp(1.0776 -
            (2.30695 -
             (0.43424 - (0.082433 - (0.008056 - 0.0003146 * z) * z) * z) * z) *
                z));
 }

 // Corrects the approximation error in AndersonDarlingInf for small values of n
 // Add this to AndersonDarlingInf to get a better approximation
 // (from Marsaglia)
 double AndersonDarlingErrFix(int n, double x) {
   if (x > 0.8) {
     return (-130.2137 +
             (745.2337 -
              (1705.091 - (1950.646 - (1116.360 - 255.7844 * x) * x) * x) * x) *
                 x) /
            n;
   }
   double cutoff = 0.01265 + 0.1757 / n;
   if (x < cutoff) {
     double t = x / cutoff;
     t = sqrt(t) * (1 - t) * (49 * t - 102);
     return t * (0.0037 / (n * n) + 0.00078 / n + 0.00006) / n;
   } else {
     double t = (x - cutoff) / (0.8 - cutoff);
     t = -0.00022633 +
         (6.54034 - (14.6538 - (14.458 - (8.259 - 1.91864 * t) * t) * t) * t) *
             t;
     return t * (0.04213 + 0.01365 / n) / n;
   }
 }

 // Returns the AndersonDarling p-value given n and the value of the statistic
 double AndersonDarlingPValue(int n, double z) {
   double ad = AndersonDarlingInf(z);
   double errfix = AndersonDarlingErrFix(n, ad);
   return ad + errfix;
 }

 double AndersonDarlingStatistic(const std::vector<double>& random_sample) {
   int n = random_sample.size();
   double ad_sum = 0;
   for (int i = 0; i < n; i++) {
     ad_sum += (2 * i + 1) *
               std::log(random_sample[i] * (1 - random_sample[n - 1 - i]));
   }
   double ad_statistic = -n - 1 / static_cast<double>(n) * ad_sum;
   return ad_statistic;
 }

 // Tests if the array of doubles is uniformly distributed.
 // Returns the p-value of the Anderson Darling Statistic
 // for the given set of sorted random doubles
 // See "Evaluating the Anderson-Darling Distribution" by
 // Marsaglia and Marsaglia for details.
 double AndersonDarlingTest(const std::vector<double>& random_sample) {
   double ad_statistic = AndersonDarlingStatistic(random_sample);
   double p = AndersonDarlingPValue(random_sample.size(), ad_statistic);
   return p;
 }

 TEST(ExponentialBiasedTest, CoinTossDemoWithGetSkipCount) {
   ExponentialBiased eb;
   for (int runs = 0; runs < 10; ++runs) {
     for (int flips = eb.GetSkipCount(1); flips > 0; --flips) {
       printf("head...");
     }
     printf("tail\n");
   }
   int heads = 0;
   for (int i = 0; i < 10000000; i += 1 + eb.GetSkipCount(1)) {
     ++heads;
   }
   printf("Heads = %d (%f%%)\n", heads, 100.0 * heads / 10000000);
 }

 TEST(ExponentialBiasedTest, SampleDemoWithStride) {
   ExponentialBiased eb;
   int stride = eb.GetStride(10);
   int samples = 0;
   for (int i = 0; i < 10000000; ++i) {
     if (--stride == 0) {
       ++samples;
       stride = eb.GetStride(10);
     }
   }
   printf("Samples = %d (%f%%)\n", samples, 100.0 * samples / 10000000);
 }


 // Testing that NextRandom generates uniform random numbers. Applies the
 // Anderson-Darling test for uniformity
 TEST(ExponentialBiasedTest, TestNextRandom) {
   for (auto n : std::vector<int>({
            10,  // Check short-range correlation
            100, 1000,
            10000  // Make sure there's no systemic error
        })) {
     uint64_t x = 1;
     // This assumes that the prng returns 48 bit numbers
     uint64_t max_prng_value = static_cast<uint64_t>(1) << 48;
     // Initialize.
     for (int i = 1; i <= 20; i++) {
       x = ExponentialBiased::NextRandom(x);
     }
     std::vector<uint64_t> int_random_sample(n);
     // Collect samples
     for (int i = 0; i < n; i++) {
       int_random_sample[i] = x;
       x = ExponentialBiased::NextRandom(x);
     }
     // First sort them...
     std::sort(int_random_sample.begin(), int_random_sample.end());
     std::vector<double> random_sample(n);
     // Convert them to uniform randoms (in the range [0,1])
     for (int i = 0; i < n; i++) {
       random_sample[i] =
           static_cast<double>(int_random_sample[i]) / max_prng_value;
     }
     // Now compute the Anderson-Darling statistic
     double ad_pvalue = AndersonDarlingTest(random_sample);
     EXPECT_GT(std::min(ad_pvalue, 1 - ad_pvalue), 0.0001)
         << "prng is not uniform: n = " << n << " p = " << ad_pvalue;
   }
 }

 // The generator needs to be available as a thread_local and as a static
 // variable.
 TEST(ExponentialBiasedTest, InitializationModes) {
   ABSL_CONST_INIT static ExponentialBiased eb_static;
   EXPECT_THAT(eb_static.GetSkipCount(2), Ge(0));

 #ifdef ABSL_HAVE_THREAD_LOCAL
   thread_local ExponentialBiased eb_thread;
   EXPECT_THAT(eb_thread.GetSkipCount(2), Ge(0));
 #endif

   ExponentialBiased eb_stack;
   EXPECT_THAT(eb_stack.GetSkipCount(2), Ge(0));
 }

 }  // namespace base_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/base/internal/exponential_biased.h"

	#include <stddef.h>

	#include <cmath>
	#include <cstdint>
	#include <vector>

	#include "gmock/gmock.h"
	#include "gtest/gtest.h"
	#include "absl/strings/str_cat.h"

	using ::testing::Ge;

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace base_internal {

	MATCHER_P2(IsBetween, a, b,
	absl::StrCat(std::string(negation ? "isn't" : "is"), " between ", a,
	" and ", b)) {
	return a <= arg && arg <= b;
	}

	// Tests of the quality of the random numbers generated
	// This uses the Anderson Darling test for uniformity.
	// See "Evaluating the Anderson-Darling Distribution" by Marsaglia
	// for details.

	// Short cut version of ADinf(z), z>0 (from Marsaglia)
	// This returns the p-value for Anderson Darling statistic in
	// the limit as n-> infinity. For finite n, apply the error fix below.
	double AndersonDarlingInf(double z) {
	if (z < 2) {
	return exp(-1.2337141 / z) / sqrt(z) *
	(2.00012 +
	(0.247105 -
	(0.0649821 - (0.0347962 - (0.011672 - 0.00168691 * z) * z) * z) *
	z) *
	z);
	}
	return exp(
	-exp(1.0776 -
	(2.30695 -
	(0.43424 - (0.082433 - (0.008056 - 0.0003146 * z) * z) * z) * z) *
	z));
	}

	// Corrects the approximation error in AndersonDarlingInf for small values of n
	// Add this to AndersonDarlingInf to get a better approximation
	// (from Marsaglia)
	double AndersonDarlingErrFix(int n, double x) {
	if (x > 0.8) {
	return (-130.2137 +
	(745.2337 -
	(1705.091 - (1950.646 - (1116.360 - 255.7844 * x) * x) * x) * x) *
	x) /
	n;
	}
	double cutoff = 0.01265 + 0.1757 / n;
	if (x < cutoff) {
	double t = x / cutoff;
	t = sqrt(t) * (1 - t) * (49 * t - 102);
	return t * (0.0037 / (n * n) + 0.00078 / n + 0.00006) / n;
	} else {
	double t = (x - cutoff) / (0.8 - cutoff);
	t = -0.00022633 +
	(6.54034 - (14.6538 - (14.458 - (8.259 - 1.91864 * t) * t) * t) * t) *
	t;
	return t * (0.04213 + 0.01365 / n) / n;
	}
	}

	// Returns the AndersonDarling p-value given n and the value of the statistic
	double AndersonDarlingPValue(int n, double z) {
	double ad = AndersonDarlingInf(z);
	double errfix = AndersonDarlingErrFix(n, ad);
	return ad + errfix;
	}

	double AndersonDarlingStatistic(const std::vector<double>& random_sample) {
	int n = random_sample.size();
	double ad_sum = 0;
	for (int i = 0; i < n; i++) {
	ad_sum += (2 * i + 1) *
	std::log(random_sample[i] * (1 - random_sample[n - 1 - i]));
	}
	double ad_statistic = -n - 1 / static_cast<double>(n) * ad_sum;
	return ad_statistic;
	}

	// Tests if the array of doubles is uniformly distributed.
	// Returns the p-value of the Anderson Darling Statistic
	// for the given set of sorted random doubles
	// See "Evaluating the Anderson-Darling Distribution" by
	// Marsaglia and Marsaglia for details.
	double AndersonDarlingTest(const std::vector<double>& random_sample) {
	double ad_statistic = AndersonDarlingStatistic(random_sample);
	double p = AndersonDarlingPValue(random_sample.size(), ad_statistic);
	return p;
	}

	TEST(ExponentialBiasedTest, CoinTossDemoWithGetSkipCount) {
	ExponentialBiased eb;
	for (int runs = 0; runs < 10; ++runs) {
	for (int flips = eb.GetSkipCount(1); flips > 0; --flips) {
	printf("head...");
	}
	printf("tail\n");
	}
	int heads = 0;
	for (int i = 0; i < 10000000; i += 1 + eb.GetSkipCount(1)) {
	++heads;
	}
	printf("Heads = %d (%f%%)\n", heads, 100.0 * heads / 10000000);
	}

	TEST(ExponentialBiasedTest, SampleDemoWithStride) {
	ExponentialBiased eb;
	int stride = eb.GetStride(10);
	int samples = 0;
	for (int i = 0; i < 10000000; ++i) {
	if (--stride == 0) {
	++samples;
	stride = eb.GetStride(10);
	}
	}
	printf("Samples = %d (%f%%)\n", samples, 100.0 * samples / 10000000);
	}


	// Testing that NextRandom generates uniform random numbers. Applies the
	// Anderson-Darling test for uniformity
	TEST(ExponentialBiasedTest, TestNextRandom) {
	for (auto n : std::vector<int>({
	10, // Check short-range correlation
	100, 1000,
	10000 // Make sure there's no systemic error
	})) {
	uint64_t x = 1;
	// This assumes that the prng returns 48 bit numbers
	uint64_t max_prng_value = static_cast<uint64_t>(1) << 48;
	// Initialize.
	for (int i = 1; i <= 20; i++) {
	x = ExponentialBiased::NextRandom(x);
	}
	std::vector<uint64_t> int_random_sample(n);
	// Collect samples
	for (int i = 0; i < n; i++) {
	int_random_sample[i] = x;
	x = ExponentialBiased::NextRandom(x);
	}
	// First sort them...
	std::sort(int_random_sample.begin(), int_random_sample.end());
	std::vector<double> random_sample(n);
	// Convert them to uniform randoms (in the range [0,1])
	for (int i = 0; i < n; i++) {
	random_sample[i] =
	static_cast<double>(int_random_sample[i]) / max_prng_value;
	}
	// Now compute the Anderson-Darling statistic
	double ad_pvalue = AndersonDarlingTest(random_sample);
	EXPECT_GT(std::min(ad_pvalue, 1 - ad_pvalue), 0.0001)
	<< "prng is not uniform: n = " << n << " p = " << ad_pvalue;
	}
	}

	// The generator needs to be available as a thread_local and as a static
	// variable.
	TEST(ExponentialBiasedTest, InitializationModes) {
	ABSL_CONST_INIT static ExponentialBiased eb_static;
	EXPECT_THAT(eb_static.GetSkipCount(2), Ge(0));

	#ifdef ABSL_HAVE_THREAD_LOCAL
	thread_local ExponentialBiased eb_thread;
	EXPECT_THAT(eb_thread.GetSkipCount(2), Ge(0));
	#endif

	ExponentialBiased eb_stack;
	EXPECT_THAT(eb_stack.GetSkipCount(2), Ge(0));
	}

	} // namespace base_internal
	ABSL_NAMESPACE_END
	} // namespace absl