absl/random/internal/chi_square.cc - chromiumos/third_party/webrtc-apm - Git at Google

 // Copyright 2017 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/random/internal/chi_square.h"

 #include <cmath>

 #include "absl/random/internal/distribution_test_util.h"

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace random_internal {
 namespace {

 #if defined(__EMSCRIPTEN__)
 // Workaround __EMSCRIPTEN__ error: llvm_fma_f64 not found.
 inline double fma(double x, double y, double z) {
   return (x * y) + z;
 }
 #endif

 // Use Horner's method to evaluate a polynomial.
 template <typename T, unsigned N>
 inline T EvaluatePolynomial(T x, const T (&poly)[N]) {
 #if !defined(__EMSCRIPTEN__)
   using std::fma;
 #endif
   T p = poly[N - 1];
   for (unsigned i = 2; i <= N; i++) {
     p = fma(p, x, poly[N - i]);
   }
   return p;
 }

 static constexpr int kLargeDOF = 150;

 // Returns the probability of a normal z-value.
 //
 // Adapted from the POZ function in:
 //     Ibbetson D, Algorithm 209
 //     Collected Algorithms of the CACM 1963 p. 616
 //
 double POZ(double z) {
   static constexpr double kP1[] = {
       0.797884560593,  -0.531923007300, 0.319152932694,
       -0.151968751364, 0.059054035642,  -0.019198292004,
       0.005198775019,  -0.001075204047, 0.000124818987,
   };
   static constexpr double kP2[] = {
       0.999936657524,  0.000535310849,  -0.002141268741, 0.005353579108,
       -0.009279453341, 0.011630447319,  -0.010557625006, 0.006549791214,
       -0.002034254874, -0.000794620820, 0.001390604284,  -0.000676904986,
       -0.000019538132, 0.000152529290,  -0.000045255659,
   };

   const double kZMax = 6.0;  // Maximum meaningful z-value.
   if (z == 0.0) {
     return 0.5;
   }
   double x;
   double y = 0.5 * std::fabs(z);
   if (y >= (kZMax * 0.5)) {
     x = 1.0;
   } else if (y < 1.0) {
     double w = y * y;
     x = EvaluatePolynomial(w, kP1) * y * 2.0;
   } else {
     y -= 2.0;
     x = EvaluatePolynomial(y, kP2);
   }
   return z > 0.0 ? ((x + 1.0) * 0.5) : ((1.0 - x) * 0.5);
 }

 // Approximates the survival function of the normal distribution.
 //
 // Algorithm 26.2.18, from:
 // [Abramowitz and Stegun, Handbook of Mathematical Functions,p.932]
 // http://people.math.sfu.ca/~cbm/aands/abramowitz_and_stegun.pdf
 //
 double normal_survival(double z) {
   // Maybe replace with the alternate formulation.
   // 0.5 * erfc((x - mean)/(sqrt(2) * sigma))
   static constexpr double kR[] = {
       1.0, 0.196854, 0.115194, 0.000344, 0.019527,
   };
   double r = EvaluatePolynomial(z, kR);
   r *= r;
   return 0.5 / (r * r);
 }

 }  // namespace

 // Calculates the critical chi-square value given degrees-of-freedom and a
 // p-value, usually using bisection. Also known by the name CRITCHI.
 double ChiSquareValue(int dof, double p) {
   static constexpr double kChiEpsilon =
       0.000001;  // Accuracy of the approximation.
   static constexpr double kChiMax =
       99999.0;  // Maximum chi-squared value.

   const double p_value = 1.0 - p;
   if (dof < 1 || p_value > 1.0) {
     return 0.0;
   }

   if (dof > kLargeDOF) {
     // For large degrees of freedom, use the normal approximation by
     //     Wilson, E. B. and Hilferty, M. M. (1931)
     //                     chi^2 - mean
     //                Z = --------------
     //                        stddev
     const double z = InverseNormalSurvival(p_value);
     const double mean = 1 - 2.0 / (9 * dof);
     const double variance = 2.0 / (9 * dof);
     // Cannot use this method if the variance is 0.
     if (variance != 0) {
       return std::pow(z * std::sqrt(variance) + mean, 3.0) * dof;
     }
   }

   if (p_value <= 0.0) return kChiMax;

   // Otherwise search for the p value by bisection
   double min_chisq = 0.0;
   double max_chisq = kChiMax;
   double current = dof / std::sqrt(p_value);
   while ((max_chisq - min_chisq) > kChiEpsilon) {
     if (ChiSquarePValue(current, dof) < p_value) {
       max_chisq = current;
     } else {
       min_chisq = current;
     }
     current = (max_chisq + min_chisq) * 0.5;
   }
   return current;
 }

 // Calculates the p-value (probability) of a given chi-square value
 // and degrees of freedom.
 //
 // Adapted from the POCHISQ function from:
 //     Hill, I. D. and Pike, M. C.  Algorithm 299
 //     Collected Algorithms of the CACM 1963 p. 243
 //
 double ChiSquarePValue(double chi_square, int dof) {
   static constexpr double kLogSqrtPi =
       0.5723649429247000870717135;  // Log[Sqrt[Pi]]
   static constexpr double kInverseSqrtPi =
       0.5641895835477562869480795;  // 1/(Sqrt[Pi])

   // For large degrees of freedom, use the normal approximation by
   //     Wilson, E. B. and Hilferty, M. M. (1931)
   // Via Wikipedia:
   //   By the Central Limit Theorem, because the chi-square distribution is the
   //   sum of k independent random variables with finite mean and variance, it
   //   converges to a normal distribution for large k.
   if (dof > kLargeDOF) {
     // Re-scale everything.
     const double chi_square_scaled = std::pow(chi_square / dof, 1.0 / 3);
     const double mean = 1 - 2.0 / (9 * dof);
     const double variance = 2.0 / (9 * dof);
     // If variance is 0, this method cannot be used.
     if (variance != 0) {
       const double z = (chi_square_scaled - mean) / std::sqrt(variance);
       if (z > 0) {
         return normal_survival(z);
       } else if (z < 0) {
         return 1.0 - normal_survival(-z);
       } else {
         return 0.5;
       }
     }
   }

   // The chi square function is >= 0 for any degrees of freedom.
   // In other words, probability that the chi square function >= 0 is 1.
   if (chi_square <= 0.0) return 1.0;

   // If the degrees of freedom is zero, the chi square function is always 0 by
   // definition. In other words, the probability that the chi square function
   // is > 0 is zero (chi square values <= 0 have been filtered above).
   if (dof < 1) return 0;

   auto capped_exp = [](double x) { return x < -20 ? 0.0 : std::exp(x); };
   static constexpr double kBigX = 20;

   double a = 0.5 * chi_square;
   const bool even = !(dof & 1);  // True if dof is an even number.
   const double y = capped_exp(-a);
   double s = even ? y : (2.0 * POZ(-std::sqrt(chi_square)));

   if (dof <= 2) {
     return s;
   }

   chi_square = 0.5 * (dof - 1.0);
   double z = (even ? 1.0 : 0.5);
   if (a > kBigX) {
     double e = (even ? 0.0 : kLogSqrtPi);
     double c = std::log(a);
     while (z <= chi_square) {
       e = std::log(z) + e;
       s += capped_exp(c * z - a - e);
       z += 1.0;
     }
     return s;
   }

   double e = (even ? 1.0 : (kInverseSqrtPi / std::sqrt(a)));
   double c = 0.0;
   while (z <= chi_square) {
     e = e * (a / z);
     c = c + e;
     z += 1.0;
   }
   return c * y + s;
 }

 }  // namespace random_internal
 ABSL_NAMESPACE_END
 }  // namespace absl
	// Copyright 2017 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/random/internal/chi_square.h"

	#include <cmath>

	#include "absl/random/internal/distribution_test_util.h"

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace random_internal {
	namespace {

	#if defined(__EMSCRIPTEN__)
	// Workaround __EMSCRIPTEN__ error: llvm_fma_f64 not found.
	inline double fma(double x, double y, double z) {
	return (x * y) + z;
	}
	#endif

	// Use Horner's method to evaluate a polynomial.
	template <typename T, unsigned N>
	inline T EvaluatePolynomial(T x, const T (&poly)[N]) {
	#if !defined(__EMSCRIPTEN__)
	using std::fma;
	#endif
	T p = poly[N - 1];
	for (unsigned i = 2; i <= N; i++) {
	p = fma(p, x, poly[N - i]);
	}
	return p;
	}

	static constexpr int kLargeDOF = 150;

	// Returns the probability of a normal z-value.
	//
	// Adapted from the POZ function in:
	// Ibbetson D, Algorithm 209
	// Collected Algorithms of the CACM 1963 p. 616
	//
	double POZ(double z) {
	static constexpr double kP1[] = {
	0.797884560593, -0.531923007300, 0.319152932694,
	-0.151968751364, 0.059054035642, -0.019198292004,
	0.005198775019, -0.001075204047, 0.000124818987,
	};
	static constexpr double kP2[] = {
	0.999936657524, 0.000535310849, -0.002141268741, 0.005353579108,
	-0.009279453341, 0.011630447319, -0.010557625006, 0.006549791214,
	-0.002034254874, -0.000794620820, 0.001390604284, -0.000676904986,
	-0.000019538132, 0.000152529290, -0.000045255659,
	};

	const double kZMax = 6.0; // Maximum meaningful z-value.
	if (z == 0.0) {
	return 0.5;
	}
	double x;
	double y = 0.5 * std::fabs(z);
	if (y >= (kZMax * 0.5)) {
	x = 1.0;
	} else if (y < 1.0) {
	double w = y * y;
	x = EvaluatePolynomial(w, kP1) * y * 2.0;
	} else {
	y -= 2.0;
	x = EvaluatePolynomial(y, kP2);
	}
	return z > 0.0 ? ((x + 1.0) * 0.5) : ((1.0 - x) * 0.5);
	}

	// Approximates the survival function of the normal distribution.
	//
	// Algorithm 26.2.18, from:
	// [Abramowitz and Stegun, Handbook of Mathematical Functions,p.932]
	// http://people.math.sfu.ca/~cbm/aands/abramowitz_and_stegun.pdf
	//
	double normal_survival(double z) {
	// Maybe replace with the alternate formulation.
	// 0.5 * erfc((x - mean)/(sqrt(2) * sigma))
	static constexpr double kR[] = {
	1.0, 0.196854, 0.115194, 0.000344, 0.019527,
	};
	double r = EvaluatePolynomial(z, kR);
	r *= r;
	return 0.5 / (r * r);
	}

	} // namespace

	// Calculates the critical chi-square value given degrees-of-freedom and a
	// p-value, usually using bisection. Also known by the name CRITCHI.
	double ChiSquareValue(int dof, double p) {
	static constexpr double kChiEpsilon =
	0.000001; // Accuracy of the approximation.
	static constexpr double kChiMax =
	99999.0; // Maximum chi-squared value.

	const double p_value = 1.0 - p;
	if (dof < 1 \|\| p_value > 1.0) {
	return 0.0;
	}

	if (dof > kLargeDOF) {
	// For large degrees of freedom, use the normal approximation by
	// Wilson, E. B. and Hilferty, M. M. (1931)
	// chi^2 - mean
	// Z = --------------
	// stddev
	const double z = InverseNormalSurvival(p_value);
	const double mean = 1 - 2.0 / (9 * dof);
	const double variance = 2.0 / (9 * dof);
	// Cannot use this method if the variance is 0.
	if (variance != 0) {
	return std::pow(z * std::sqrt(variance) + mean, 3.0) * dof;
	}
	}

	if (p_value <= 0.0) return kChiMax;

	// Otherwise search for the p value by bisection
	double min_chisq = 0.0;
	double max_chisq = kChiMax;
	double current = dof / std::sqrt(p_value);
	while ((max_chisq - min_chisq) > kChiEpsilon) {
	if (ChiSquarePValue(current, dof) < p_value) {
	max_chisq = current;
	} else {
	min_chisq = current;
	}
	current = (max_chisq + min_chisq) * 0.5;
	}
	return current;
	}

	// Calculates the p-value (probability) of a given chi-square value
	// and degrees of freedom.
	//
	// Adapted from the POCHISQ function from:
	// Hill, I. D. and Pike, M. C. Algorithm 299
	// Collected Algorithms of the CACM 1963 p. 243
	//
	double ChiSquarePValue(double chi_square, int dof) {
	static constexpr double kLogSqrtPi =
	0.5723649429247000870717135; // Log[Sqrt[Pi]]
	static constexpr double kInverseSqrtPi =
	0.5641895835477562869480795; // 1/(Sqrt[Pi])

	// For large degrees of freedom, use the normal approximation by
	// Wilson, E. B. and Hilferty, M. M. (1931)
	// Via Wikipedia:
	// By the Central Limit Theorem, because the chi-square distribution is the
	// sum of k independent random variables with finite mean and variance, it
	// converges to a normal distribution for large k.
	if (dof > kLargeDOF) {
	// Re-scale everything.
	const double chi_square_scaled = std::pow(chi_square / dof, 1.0 / 3);
	const double mean = 1 - 2.0 / (9 * dof);
	const double variance = 2.0 / (9 * dof);
	// If variance is 0, this method cannot be used.
	if (variance != 0) {
	const double z = (chi_square_scaled - mean) / std::sqrt(variance);
	if (z > 0) {
	return normal_survival(z);
	} else if (z < 0) {
	return 1.0 - normal_survival(-z);
	} else {
	return 0.5;
	}
	}
	}

	// The chi square function is >= 0 for any degrees of freedom.
	// In other words, probability that the chi square function >= 0 is 1.
	if (chi_square <= 0.0) return 1.0;

	// If the degrees of freedom is zero, the chi square function is always 0 by
	// definition. In other words, the probability that the chi square function
	// is > 0 is zero (chi square values <= 0 have been filtered above).
	if (dof < 1) return 0;

	auto capped_exp = [](double x) { return x < -20 ? 0.0 : std::exp(x); };
	static constexpr double kBigX = 20;

	double a = 0.5 * chi_square;
	const bool even = !(dof & 1); // True if dof is an even number.
	const double y = capped_exp(-a);
	double s = even ? y : (2.0 * POZ(-std::sqrt(chi_square)));

	if (dof <= 2) {
	return s;
	}

	chi_square = 0.5 * (dof - 1.0);
	double z = (even ? 1.0 : 0.5);
	if (a > kBigX) {
	double e = (even ? 0.0 : kLogSqrtPi);
	double c = std::log(a);
	while (z <= chi_square) {
	e = std::log(z) + e;
	s += capped_exp(c * z - a - e);
	z += 1.0;
	}
	return s;
	}

	double e = (even ? 1.0 : (kInverseSqrtPi / std::sqrt(a)));
	double c = 0.0;
	while (z <= chi_square) {
	e = e * (a / z);
	c = c + e;
	z += 1.0;
	}
	return c * y + s;
	}

	} // namespace random_internal
	ABSL_NAMESPACE_END
	} // namespace absl