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// This file is part of Eigen, a lightweight C++ template library
// for linear algebra.
//
// Copyright (C) 2024 Charles Schlosser <cs.schlosser@gmail.com>
//
// This Source Code Form is subject to the terms of the Mozilla
// Public License v. 2.0. If a copy of the MPL was not distributed
// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
#ifndef EIGEN_RANDOM_IMPL_H
#define EIGEN_RANDOM_IMPL_H
// IWYU pragma: private
#include "./InternalHeaderCheck.h"
namespace Eigen {
namespace internal {
/****************************************************************************
* Implementation of random *
****************************************************************************/
template <typename Scalar, bool IsComplex, bool IsInteger>
struct random_default_impl {};
template <typename Scalar>
struct random_impl : random_default_impl<Scalar, NumTraits<Scalar>::IsComplex, NumTraits<Scalar>::IsInteger> {};
template <typename Scalar>
struct random_retval {
typedef Scalar type;
};
template <typename Scalar>
inline EIGEN_MATHFUNC_RETVAL(random, Scalar) random(const Scalar& x, const Scalar& y) {
return EIGEN_MATHFUNC_IMPL(random, Scalar)::run(x, y);
}
template <typename Scalar>
inline EIGEN_MATHFUNC_RETVAL(random, Scalar) random() {
return EIGEN_MATHFUNC_IMPL(random, Scalar)::run();
}
// TODO: replace or provide alternatives to this, e.g. std::random_device
struct eigen_random_device {
using ReturnType = int;
static constexpr int Entropy = meta_floor_log2<(unsigned int)(RAND_MAX) + 1>::value;
static constexpr ReturnType Highest = RAND_MAX;
static EIGEN_DEVICE_FUNC inline ReturnType run() { return std::rand(); }
};
// Fill a built-in unsigned integer with numRandomBits beginning with the least significant bit
template <typename Scalar>
struct random_bits_impl {
EIGEN_STATIC_ASSERT(std::is_unsigned<Scalar>::value, SCALAR MUST BE A BUILT - IN UNSIGNED INTEGER)
using RandomDevice = eigen_random_device;
using RandomReturnType = typename RandomDevice::ReturnType;
static constexpr int kEntropy = RandomDevice::Entropy;
static constexpr int kTotalBits = sizeof(Scalar) * CHAR_BIT;
// return a Scalar filled with numRandomBits beginning from the least significant bit
static EIGEN_DEVICE_FUNC inline Scalar run(int numRandomBits) {
eigen_assert((numRandomBits >= 0) && (numRandomBits <= kTotalBits));
const Scalar mask = Scalar(-1) >> ((kTotalBits - numRandomBits) & (kTotalBits - 1));
Scalar randomBits = 0;
for (int shift = 0; shift < numRandomBits; shift += kEntropy) {
RandomReturnType r = RandomDevice::run();
randomBits |= static_cast<Scalar>(r) << shift;
}
// clear the excess bits
randomBits &= mask;
return randomBits;
}
};
template <typename BitsType>
EIGEN_DEVICE_FUNC inline BitsType getRandomBits(int numRandomBits) {
return random_bits_impl<BitsType>::run(numRandomBits);
}
// random implementation for a built-in floating point type
template <typename Scalar, bool BuiltIn = std::is_floating_point<Scalar>::value>
struct random_float_impl {
using BitsType = typename numext::get_integer_by_size<sizeof(Scalar)>::unsigned_type;
static constexpr EIGEN_DEVICE_FUNC inline int mantissaBits() {
const int digits = NumTraits<Scalar>::digits();
return digits - 1;
}
static EIGEN_DEVICE_FUNC inline Scalar run(int numRandomBits) {
eigen_assert(numRandomBits >= 0 && numRandomBits <= mantissaBits());
BitsType randomBits = getRandomBits<BitsType>(numRandomBits);
// if fewer than MantissaBits is requested, shift them to the left
randomBits <<= (mantissaBits() - numRandomBits);
// randomBits is in the half-open interval [2,4)
randomBits |= numext::bit_cast<BitsType>(Scalar(2));
// result is in the half-open interval [-1,1)
Scalar result = numext::bit_cast<Scalar>(randomBits) - Scalar(3);
return result;
}
};
// random implementation for a custom floating point type
// uses double as the implementation with a mantissa with a size equal to either the target scalar's mantissa or that of
// double, whichever is smaller
template <typename Scalar>
struct random_float_impl<Scalar, false> {
static EIGEN_DEVICE_FUNC inline int mantissaBits() {
const int digits = NumTraits<Scalar>::digits();
constexpr int kDoubleDigits = NumTraits<double>::digits();
return numext::mini(digits, kDoubleDigits) - 1;
}
static EIGEN_DEVICE_FUNC inline Scalar run(int numRandomBits) {
eigen_assert(numRandomBits >= 0 && numRandomBits <= mantissaBits());
Scalar result = static_cast<Scalar>(random_float_impl<double>::run(numRandomBits));
return result;
}
};
// random implementation for long double
// this specialization is not compatible with double-double scalars
template <bool Specialize = (sizeof(long double) == 2 * sizeof(uint64_t)) &&
((std::numeric_limits<long double>::digits != (2 * std::numeric_limits<double>::digits)))>
struct random_longdouble_impl {
static constexpr int Size = sizeof(long double);
static constexpr EIGEN_DEVICE_FUNC inline int mantissaBits() { return NumTraits<long double>::digits() - 1; }
static EIGEN_DEVICE_FUNC inline long double run(int numRandomBits) {
eigen_assert(numRandomBits >= 0 && numRandomBits <= mantissaBits());
EIGEN_USING_STD(memcpy);
int numLowBits = numext::mini(numRandomBits, 64);
int numHighBits = numext::maxi(numRandomBits - 64, 0);
uint64_t randomBits[2];
long double result = 2.0L;
memcpy(&randomBits, &result, Size);
randomBits[0] |= getRandomBits<uint64_t>(numLowBits);
randomBits[1] |= getRandomBits<uint64_t>(numHighBits);
memcpy(&result, &randomBits, Size);
result -= 3.0L;
return result;
}
};
template <>
struct random_longdouble_impl<false> {
static constexpr EIGEN_DEVICE_FUNC inline int mantissaBits() { return NumTraits<double>::digits() - 1; }
static EIGEN_DEVICE_FUNC inline long double run(int numRandomBits) {
return static_cast<long double>(random_float_impl<double>::run(numRandomBits));
}
};
template <>
struct random_float_impl<long double> : random_longdouble_impl<> {};
template <typename Scalar>
struct random_default_impl<Scalar, false, false> {
using Impl = random_float_impl<Scalar>;
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar& x, const Scalar& y, int numRandomBits) {
Scalar half_x = Scalar(0.5) * x;
Scalar half_y = Scalar(0.5) * y;
Scalar result = (half_x + half_y) + (half_y - half_x) * run(numRandomBits);
// result is in the half-open interval [x, y) -- provided that x < y
return result;
}
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar& x, const Scalar& y) {
return run(x, y, Impl::mantissaBits());
}
static EIGEN_DEVICE_FUNC inline Scalar run(int numRandomBits) { return Impl::run(numRandomBits); }
static EIGEN_DEVICE_FUNC inline Scalar run() { return run(Impl::mantissaBits()); }
};
template <typename Scalar, bool IsSigned = NumTraits<Scalar>::IsSigned, bool BuiltIn = std::is_integral<Scalar>::value>
struct random_int_impl;
// random implementation for a built-in unsigned integer type
template <typename Scalar>
struct random_int_impl<Scalar, false, true> {
static constexpr int kTotalBits = sizeof(Scalar) * CHAR_BIT;
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar& x, const Scalar& y) {
if (y <= x) return x;
Scalar range = y - x;
// handle edge case where [x,y] spans the entire range of Scalar
if (range == NumTraits<Scalar>::highest()) return run();
Scalar count = range + 1;
// calculate the number of random bits needed to fill range
int numRandomBits = log2_ceil(count);
Scalar randomBits;
do {
randomBits = getRandomBits<Scalar>(numRandomBits);
// if the random draw is outside [0, range), try again (rejection sampling)
// in the worst-case scenario, the probability of rejection is: 1/2 - 1/2^numRandomBits < 50%
} while (randomBits >= count);
Scalar result = x + randomBits;
return result;
}
static EIGEN_DEVICE_FUNC inline Scalar run() { return getRandomBits<Scalar>(kTotalBits); }
};
// random implementation for a built-in signed integer type
template <typename Scalar>
struct random_int_impl<Scalar, true, true> {
static constexpr int kTotalBits = sizeof(Scalar) * CHAR_BIT;
using BitsType = typename make_unsigned<Scalar>::type;
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar& x, const Scalar& y) {
if (y <= x) return x;
// Avoid overflow by representing `range` as an unsigned type
BitsType range = static_cast<BitsType>(y) - static_cast<BitsType>(x);
BitsType randomBits = random_int_impl<BitsType>::run(0, range);
// Avoid overflow in the case where `x` is negative and there is a large range so
// `randomBits` would also be negative if cast to `Scalar` first.
Scalar result = static_cast<Scalar>(static_cast<BitsType>(x) + randomBits);
return result;
}
static EIGEN_DEVICE_FUNC inline Scalar run() { return static_cast<Scalar>(getRandomBits<BitsType>(kTotalBits)); }
};
// todo: custom integers
template <typename Scalar, bool IsSigned>
struct random_int_impl<Scalar, IsSigned, false> {
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar&, const Scalar&) { return run(); }
static EIGEN_DEVICE_FUNC inline Scalar run() {
eigen_assert(std::false_type::value && "RANDOM FOR CUSTOM INTEGERS NOT YET SUPPORTED");
return Scalar(0);
}
};
template <typename Scalar>
struct random_default_impl<Scalar, false, true> : random_int_impl<Scalar> {};
template <>
struct random_impl<bool> {
static EIGEN_DEVICE_FUNC inline bool run(const bool& x, const bool& y) {
if (y <= x) return x;
return run();
}
static EIGEN_DEVICE_FUNC inline bool run() { return getRandomBits<unsigned>(1) ? true : false; }
};
template <typename Scalar>
struct random_default_impl<Scalar, true, false> {
typedef typename NumTraits<Scalar>::Real RealScalar;
using Impl = random_impl<RealScalar>;
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar& x, const Scalar& y, int numRandomBits) {
return Scalar(Impl::run(x.real(), y.real(), numRandomBits), Impl::run(x.imag(), y.imag(), numRandomBits));
}
static EIGEN_DEVICE_FUNC inline Scalar run(const Scalar& x, const Scalar& y) {
return Scalar(Impl::run(x.real(), y.real()), Impl::run(x.imag(), y.imag()));
}
static EIGEN_DEVICE_FUNC inline Scalar run(int numRandomBits) {
return Scalar(Impl::run(numRandomBits), Impl::run(numRandomBits));
}
static EIGEN_DEVICE_FUNC inline Scalar run() { return Scalar(Impl::run(), Impl::run()); }
};
} // namespace internal
} // namespace Eigen
#endif // EIGEN_RANDOM_IMPL_H