abseil-cpp/absl/random/internal/chi_square.cc

// 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
Export of internal Abseil changes -- f012012ef78234a6a4585321b67d7b7c92ebc266 by Laramie Leavitt <lar@google.com>: Slight restructuring of absl/random/internal randen implementation. Convert round-keys.inc into randen_round_keys.cc file. Consistently use a 128-bit pointer type for internal method parameters. This allows simpler pointer arithmetic in C++ & permits removal of some constants and casts. Remove some redundancy in comments & constexpr variables. Specifically, all references to Randen algorithm parameters use RandenTraits; duplication in RandenSlow removed. PiperOrigin-RevId: 312190313 -- dc8b42e054046741e9ed65335bfdface997c6063 by Abseil Team <absl-team@google.com>: Internal change. PiperOrigin-RevId: 312167304 -- f13d248fafaf206492c1362c3574031aea3abaf7 by Matthew Brown <matthewbr@google.com>: Cleanup StrFormat extensions a little. PiperOrigin-RevId: 312166336 -- 9d9117589667afe2332bb7ad42bc967ca7c54502 by Derek Mauro <dmauro@google.com>: Internal change PiperOrigin-RevId: 312105213 -- 9a12b9b3aa0e59b8ee6cf9408ed0029045543a9b by Abseil Team <absl-team@google.com>: Complete IGNORE_TYPE macro renaming. PiperOrigin-RevId: 311999699 -- 64756f20d61021d999bd0d4c15e9ad3857382f57 by Gennadiy Rozental <rogeeff@google.com>: Switch to fixed bytes specific default value. This fixes the Abseil Flags for big endian platforms. PiperOrigin-RevId: 311844448 -- bdbe6b5b29791dbc3816ada1828458b3010ff1e9 by Laramie Leavitt <lar@google.com>: Change many distribution tests to use pcg_engine as a deterministic source of entropy. It's reasonable to test that the BitGen itself has good entropy, however when testing the cross product of all random distributions x all the architecture variations x all submitted changes results in a large number of tests. In order to account for these failures while still using good entropy requires that our allowed sigma need to account for all of these independent tests. Our current sigma values are too restrictive, and we see a lot of failures, so we have to either relax the sigma values or convert some of the statistical tests to use deterministic values. This changelist does the latter. PiperOrigin-RevId: 311840096 GitOrigin-RevId: f012012ef78234a6a4585321b67d7b7c92ebc266 Change-Id: Ic84886f38ff30d7d72c126e9b63c9a61eb729a1a 5 years ago			`// 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`