absl/random/internal/distribution_impl.h - external/github.com/abseil/abseil-cpp - 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.

 #ifndef ABSL_RANDOM_INTERNAL_DISTRIBUTION_IMPL_H_
 #define ABSL_RANDOM_INTERNAL_DISTRIBUTION_IMPL_H_

 // This file contains some implementation details which are used by one or more
 // of the absl random number distributions.

 #include <cfloat>
 #include <cstddef>
 #include <cstdint>
 #include <cstring>
 #include <limits>
 #include <type_traits>

 #if (defined(_WIN32) || defined(_WIN64)) && defined(_M_IA64)
 #include <intrin.h>  // NOLINT(build/include_order)
 #pragma intrinsic(_umul128)
 #define ABSL_INTERNAL_USE_UMUL128 1
 #endif

 #include "absl/base/config.h"
 #include "absl/base/internal/bits.h"
 #include "absl/numeric/int128.h"
 #include "absl/random/internal/fastmath.h"
 #include "absl/random/internal/traits.h"

 namespace absl {
 inline namespace lts_2019_08_08 {
 namespace random_internal {

 // Creates a double from `bits`, with the template fields controlling the
 // output.
 //
 // RandU64To is both more efficient and generates more unique values in the
 // result interval than known implementations of std::generate_canonical().
 //
 // The `Signed` parameter controls whether positive, negative, or both are
 // returned (thus affecting the output interval).
 //   When Signed == SignedValueT, range is U(-1, 1)
 //   When Signed == NegativeValueT, range is U(-1, 0)
 //   When Signed == PositiveValueT, range is U(0, 1)
 //
 // When the `IncludeZero` parameter is true, the function may return 0 for some
 // inputs, otherwise it never returns 0.
 //
 // The `ExponentBias` parameter determines the scale of the output range by
 // adjusting the exponent.
 //
 // When a value in U(0,1) is required, use:
 //   RandU64ToDouble<PositiveValueT, true, 0>();
 //
 // When a value in U(-1,1) is required, use:
 //   RandU64ToDouble<SignedValueT, false, 0>() => U(-1, 1)
 // This generates more distinct values than the mathematically equivalent
 // expression `U(0, 1) * 2.0 - 1.0`, and is preferable.
 //
 // Scaling the result by powers of 2 (and avoiding a multiply) is also possible:
 //   RandU64ToDouble<PositiveValueT, false, 1>();  => U(0, 2)
 //   RandU64ToDouble<PositiveValueT, false, -1>();  => U(0, 0.5)
 //

 // Tristate types controlling the output.
 struct PositiveValueT {};
 struct NegativeValueT {};
 struct SignedValueT {};

 // RandU64ToDouble is the double-result variant of RandU64To, described above.
 template <typename Signed, bool IncludeZero, int ExponentBias = 0>
 inline double RandU64ToDouble(uint64_t bits) {
   static_assert(std::is_same<Signed, PositiveValueT>::value ||
                     std::is_same<Signed, NegativeValueT>::value ||
                     std::is_same<Signed, SignedValueT>::value,
                 "");

   // Maybe use the left-most bit for a sign bit.
   uint64_t sign = std::is_same<Signed, NegativeValueT>::value
                       ? 0x8000000000000000ull
                       : 0;  // Sign bits.

   if (std::is_same<Signed, SignedValueT>::value) {
     sign = bits & 0x8000000000000000ull;
     bits = bits & 0x7FFFFFFFFFFFFFFFull;
   }
   if (IncludeZero) {
     if (bits == 0u) return 0;
   }

   // Number of leading zeros is mapped to the exponent: 2^-clz
   int clz = base_internal::CountLeadingZeros64(bits);
   // Shift number left to erase leading zeros.
   bits <<= IncludeZero ? clz : (clz & 63);

   // Shift number right to remove bits that overflow double mantissa.  The
   // direction of the shift depends on `clz`.
   bits >>= (64 - DBL_MANT_DIG);

   // Compute IEEE 754 double exponent.
   // In the Signed case, bits is a 63-bit number with a 0 msb.  Adjust the
   // exponent to account for that.
   const uint64_t exp =
       (std::is_same<Signed, SignedValueT>::value ? 1023U : 1022U) +
       static_cast<uint64_t>(ExponentBias - clz);
   constexpr int kExp = DBL_MANT_DIG - 1;
   // Construct IEEE 754 double from exponent and mantissa.
   const uint64_t val = sign | (exp << kExp) | (bits & ((1ULL << kExp) - 1U));

   double res;
   static_assert(sizeof(res) == sizeof(val), "double is not 64 bit");
   // Memcpy value from "val" to "res" to avoid aliasing problems.  Assumes that
   // endian-ness is same for double and uint64_t.
   std::memcpy(&res, &val, sizeof(res));

   return res;
 }

 // RandU64ToFloat is the float-result variant of RandU64To, described above.
 template <typename Signed, bool IncludeZero, int ExponentBias = 0>
 inline float RandU64ToFloat(uint64_t bits) {
   static_assert(std::is_same<Signed, PositiveValueT>::value ||
                     std::is_same<Signed, NegativeValueT>::value ||
                     std::is_same<Signed, SignedValueT>::value,
                 "");

   // Maybe use the left-most bit for a sign bit.
   uint64_t sign = std::is_same<Signed, NegativeValueT>::value
                       ? 0x80000000ul
                       : 0;  // Sign bits.

   if (std::is_same<Signed, SignedValueT>::value) {
     uint64_t a = bits & 0x8000000000000000ull;
     sign = static_cast<uint32_t>(a >> 32);
     bits = bits & 0x7FFFFFFFFFFFFFFFull;
   }
   if (IncludeZero) {
     if (bits == 0u) return 0;
   }

   // Number of leading zeros is mapped to the exponent: 2^-clz
   int clz = base_internal::CountLeadingZeros64(bits);
   // Shift number left to erase leading zeros.
   bits <<= IncludeZero ? clz : (clz & 63);
   // Shift number right to remove bits that overflow double mantissa.  The
   // direction of the shift depends on `clz`.
   bits >>= (64 - FLT_MANT_DIG);

   // Construct IEEE 754 float exponent.
   // In the Signed case, bits is a 63-bit number with a 0 msb.  Adjust the
   // exponent to account for that.
   const uint32_t exp =
       (std::is_same<Signed, SignedValueT>::value ? 127U : 126U) +
       static_cast<uint32_t>(ExponentBias - clz);
   constexpr int kExp = FLT_MANT_DIG - 1;
   const uint32_t val = sign | (exp << kExp) | (bits & ((1U << kExp) - 1U));

   float res;
   static_assert(sizeof(res) == sizeof(val), "float is not 32 bit");
   // Assumes that endian-ness is same for float and uint32_t.
   std::memcpy(&res, &val, sizeof(res));

   return res;
 }

 template <typename Result>
 struct RandU64ToReal {
   template <typename Signed, bool IncludeZero, int ExponentBias = 0>
   static inline Result Value(uint64_t bits) {
     return RandU64ToDouble<Signed, IncludeZero, ExponentBias>(bits);
   }
 };

 template <>
 struct RandU64ToReal<float> {
   template <typename Signed, bool IncludeZero, int ExponentBias = 0>
   static inline float Value(uint64_t bits) {
     return RandU64ToFloat<Signed, IncludeZero, ExponentBias>(bits);
   }
 };

 inline uint128 MultiplyU64ToU128(uint64_t a, uint64_t b) {
 #if defined(ABSL_HAVE_INTRINSIC_INT128)
   return uint128(static_cast<__uint128_t>(a) * b);
 #elif defined(ABSL_INTERNAL_USE_UMUL128)
   // uint64_t * uint64_t => uint128 multiply using imul intrinsic on MSVC.
   uint64_t high = 0;
   const uint64_t low = _umul128(a, b, &high);
   return absl::MakeUint128(high, low);
 #else
   // uint128(a) * uint128(b) in emulated mode computes a full 128-bit x 128-bit
   // multiply.  However there are many cases where that is not necessary, and it
   // is only necessary to support a 64-bit x 64-bit = 128-bit multiply.  This is
   // for those cases.
   const uint64_t a00 = static_cast<uint32_t>(a);
   const uint64_t a32 = a >> 32;
   const uint64_t b00 = static_cast<uint32_t>(b);
   const uint64_t b32 = b >> 32;

   const uint64_t c00 = a00 * b00;
   const uint64_t c32a = a00 * b32;
   const uint64_t c32b = a32 * b00;
   const uint64_t c64 = a32 * b32;

   const uint32_t carry =
       static_cast<uint32_t>(((c00 >> 32) + static_cast<uint32_t>(c32a) +
                              static_cast<uint32_t>(c32b)) >>
                             32);

   return absl::MakeUint128(c64 + (c32a >> 32) + (c32b >> 32) + carry,
                            c00 + (c32a << 32) + (c32b << 32));
 #endif
 }

 // wide_multiply<T> multiplies two N-bit values to a 2N-bit result.
 template <typename UIntType>
 struct wide_multiply {
   static constexpr size_t kN = std::numeric_limits<UIntType>::digits;
   using input_type = UIntType;
   using result_type = typename random_internal::unsigned_bits<kN * 2>::type;

   static result_type multiply(input_type a, input_type b) {
     return static_cast<result_type>(a) * b;
   }

   static input_type hi(result_type r) { return r >> kN; }
   static input_type lo(result_type r) { return r; }

   static_assert(std::is_unsigned<UIntType>::value,
                 "Class-template wide_multiply<> argument must be unsigned.");
 };

 #ifndef ABSL_HAVE_INTRINSIC_INT128
 template <>
 struct wide_multiply<uint64_t> {
   using input_type = uint64_t;
   using result_type = uint128;

   static result_type multiply(uint64_t a, uint64_t b) {
     return MultiplyU64ToU128(a, b);
   }

   static uint64_t hi(result_type r) { return Uint128High64(r); }
   static uint64_t lo(result_type r) { return Uint128Low64(r); }
 };
 #endif

 }  // namespace random_internal
 }  // inline namespace lts_2019_08_08
 }  // namespace absl

 #endif  // ABSL_RANDOM_INTERNAL_DISTRIBUTION_IMPL_H_
	// 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.

	#ifndef ABSL_RANDOM_INTERNAL_DISTRIBUTION_IMPL_H_
	#define ABSL_RANDOM_INTERNAL_DISTRIBUTION_IMPL_H_

	// This file contains some implementation details which are used by one or more
	// of the absl random number distributions.

	#include <cfloat>
	#include <cstddef>
	#include <cstdint>
	#include <cstring>
	#include <limits>
	#include <type_traits>

	#if (defined(_WIN32) \|\| defined(_WIN64)) && defined(_M_IA64)
	#include <intrin.h> // NOLINT(build/include_order)
	#pragma intrinsic(_umul128)
	#define ABSL_INTERNAL_USE_UMUL128 1
	#endif

	#include "absl/base/config.h"
	#include "absl/base/internal/bits.h"
	#include "absl/numeric/int128.h"
	#include "absl/random/internal/fastmath.h"
	#include "absl/random/internal/traits.h"

	namespace absl {
	inline namespace lts_2019_08_08 {
	namespace random_internal {

	// Creates a double from `bits`, with the template fields controlling the
	// output.
	//
	// RandU64To is both more efficient and generates more unique values in the
	// result interval than known implementations of std::generate_canonical().
	//
	// The `Signed` parameter controls whether positive, negative, or both are
	// returned (thus affecting the output interval).
	// When Signed == SignedValueT, range is U(-1, 1)
	// When Signed == NegativeValueT, range is U(-1, 0)
	// When Signed == PositiveValueT, range is U(0, 1)
	//
	// When the `IncludeZero` parameter is true, the function may return 0 for some
	// inputs, otherwise it never returns 0.
	//
	// The `ExponentBias` parameter determines the scale of the output range by
	// adjusting the exponent.
	//
	// When a value in U(0,1) is required, use:
	// RandU64ToDouble<PositiveValueT, true, 0>();
	//
	// When a value in U(-1,1) is required, use:
	// RandU64ToDouble<SignedValueT, false, 0>() => U(-1, 1)
	// This generates more distinct values than the mathematically equivalent
	// expression `U(0, 1) * 2.0 - 1.0`, and is preferable.
	//
	// Scaling the result by powers of 2 (and avoiding a multiply) is also possible:
	// RandU64ToDouble<PositiveValueT, false, 1>(); => U(0, 2)
	// RandU64ToDouble<PositiveValueT, false, -1>(); => U(0, 0.5)
	//

	// Tristate types controlling the output.
	struct PositiveValueT {};
	struct NegativeValueT {};
	struct SignedValueT {};

	// RandU64ToDouble is the double-result variant of RandU64To, described above.
	template <typename Signed, bool IncludeZero, int ExponentBias = 0>
	inline double RandU64ToDouble(uint64_t bits) {
	static_assert(std::is_same<Signed, PositiveValueT>::value \|\|
	std::is_same<Signed, NegativeValueT>::value \|\|
	std::is_same<Signed, SignedValueT>::value,
	"");

	// Maybe use the left-most bit for a sign bit.
	uint64_t sign = std::is_same<Signed, NegativeValueT>::value
	? 0x8000000000000000ull
	: 0; // Sign bits.

	if (std::is_same<Signed, SignedValueT>::value) {
	sign = bits & 0x8000000000000000ull;
	bits = bits & 0x7FFFFFFFFFFFFFFFull;
	}
	if (IncludeZero) {
	if (bits == 0u) return 0;
	}

	// Number of leading zeros is mapped to the exponent: 2^-clz
	int clz = base_internal::CountLeadingZeros64(bits);
	// Shift number left to erase leading zeros.
	bits <<= IncludeZero ? clz : (clz & 63);

	// Shift number right to remove bits that overflow double mantissa. The
	// direction of the shift depends on `clz`.
	bits >>= (64 - DBL_MANT_DIG);

	// Compute IEEE 754 double exponent.
	// In the Signed case, bits is a 63-bit number with a 0 msb. Adjust the
	// exponent to account for that.
	const uint64_t exp =
	(std::is_same<Signed, SignedValueT>::value ? 1023U : 1022U) +
	static_cast<uint64_t>(ExponentBias - clz);
	constexpr int kExp = DBL_MANT_DIG - 1;
	// Construct IEEE 754 double from exponent and mantissa.
	const uint64_t val = sign \| (exp << kExp) \| (bits & ((1ULL << kExp) - 1U));

	double res;
	static_assert(sizeof(res) == sizeof(val), "double is not 64 bit");
	// Memcpy value from "val" to "res" to avoid aliasing problems. Assumes that
	// endian-ness is same for double and uint64_t.
	std::memcpy(&res, &val, sizeof(res));

	return res;
	}

	// RandU64ToFloat is the float-result variant of RandU64To, described above.
	template <typename Signed, bool IncludeZero, int ExponentBias = 0>
	inline float RandU64ToFloat(uint64_t bits) {
	static_assert(std::is_same<Signed, PositiveValueT>::value \|\|
	std::is_same<Signed, NegativeValueT>::value \|\|
	std::is_same<Signed, SignedValueT>::value,
	"");

	// Maybe use the left-most bit for a sign bit.
	uint64_t sign = std::is_same<Signed, NegativeValueT>::value
	? 0x80000000ul
	: 0; // Sign bits.

	if (std::is_same<Signed, SignedValueT>::value) {
	uint64_t a = bits & 0x8000000000000000ull;
	sign = static_cast<uint32_t>(a >> 32);
	bits = bits & 0x7FFFFFFFFFFFFFFFull;
	}
	if (IncludeZero) {
	if (bits == 0u) return 0;
	}

	// Number of leading zeros is mapped to the exponent: 2^-clz
	int clz = base_internal::CountLeadingZeros64(bits);
	// Shift number left to erase leading zeros.
	bits <<= IncludeZero ? clz : (clz & 63);
	// Shift number right to remove bits that overflow double mantissa. The
	// direction of the shift depends on `clz`.
	bits >>= (64 - FLT_MANT_DIG);

	// Construct IEEE 754 float exponent.
	// In the Signed case, bits is a 63-bit number with a 0 msb. Adjust the
	// exponent to account for that.
	const uint32_t exp =
	(std::is_same<Signed, SignedValueT>::value ? 127U : 126U) +
	static_cast<uint32_t>(ExponentBias - clz);
	constexpr int kExp = FLT_MANT_DIG - 1;
	const uint32_t val = sign \| (exp << kExp) \| (bits & ((1U << kExp) - 1U));

	float res;
	static_assert(sizeof(res) == sizeof(val), "float is not 32 bit");
	// Assumes that endian-ness is same for float and uint32_t.
	std::memcpy(&res, &val, sizeof(res));

	return res;
	}

	template <typename Result>
	struct RandU64ToReal {
	template <typename Signed, bool IncludeZero, int ExponentBias = 0>
	static inline Result Value(uint64_t bits) {
	return RandU64ToDouble<Signed, IncludeZero, ExponentBias>(bits);
	}
	};

	template <>
	struct RandU64ToReal<float> {
	template <typename Signed, bool IncludeZero, int ExponentBias = 0>
	static inline float Value(uint64_t bits) {
	return RandU64ToFloat<Signed, IncludeZero, ExponentBias>(bits);
	}
	};

	inline uint128 MultiplyU64ToU128(uint64_t a, uint64_t b) {
	#if defined(ABSL_HAVE_INTRINSIC_INT128)
	return uint128(static_cast<__uint128_t>(a) * b);
	#elif defined(ABSL_INTERNAL_USE_UMUL128)
	// uint64_t * uint64_t => uint128 multiply using imul intrinsic on MSVC.
	uint64_t high = 0;
	const uint64_t low = _umul128(a, b, &high);
	return absl::MakeUint128(high, low);
	#else
	// uint128(a) * uint128(b) in emulated mode computes a full 128-bit x 128-bit
	// multiply. However there are many cases where that is not necessary, and it
	// is only necessary to support a 64-bit x 64-bit = 128-bit multiply. This is
	// for those cases.
	const uint64_t a00 = static_cast<uint32_t>(a);
	const uint64_t a32 = a >> 32;
	const uint64_t b00 = static_cast<uint32_t>(b);
	const uint64_t b32 = b >> 32;

	const uint64_t c00 = a00 * b00;
	const uint64_t c32a = a00 * b32;
	const uint64_t c32b = a32 * b00;
	const uint64_t c64 = a32 * b32;

	const uint32_t carry =
	static_cast<uint32_t>(((c00 >> 32) + static_cast<uint32_t>(c32a) +
	static_cast<uint32_t>(c32b)) >>
	32);

	return absl::MakeUint128(c64 + (c32a >> 32) + (c32b >> 32) + carry,
	c00 + (c32a << 32) + (c32b << 32));
	#endif
	}

	// wide_multiply<T> multiplies two N-bit values to a 2N-bit result.
	template <typename UIntType>
	struct wide_multiply {
	static constexpr size_t kN = std::numeric_limits<UIntType>::digits;
	using input_type = UIntType;
	using result_type = typename random_internal::unsigned_bits<kN * 2>::type;

	static result_type multiply(input_type a, input_type b) {
	return static_cast<result_type>(a) * b;
	}

	static input_type hi(result_type r) { return r >> kN; }
	static input_type lo(result_type r) { return r; }

	static_assert(std::is_unsigned<UIntType>::value,
	"Class-template wide_multiply<> argument must be unsigned.");
	};

	#ifndef ABSL_HAVE_INTRINSIC_INT128
	template <>
	struct wide_multiply<uint64_t> {
	using input_type = uint64_t;
	using result_type = uint128;

	static result_type multiply(uint64_t a, uint64_t b) {
	return MultiplyU64ToU128(a, b);
	}

	static uint64_t hi(result_type r) { return Uint128High64(r); }
	static uint64_t lo(result_type r) { return Uint128Low64(r); }
	};
	#endif

	} // namespace random_internal
	} // inline namespace lts_2019_08_08
	} // namespace absl

	#endif // ABSL_RANDOM_INTERNAL_DISTRIBUTION_IMPL_H_