src/base/numerics/clamped_math_impl.h - gn.git - Git at Google

 // Copyright 2017 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_NUMERICS_CLAMPED_MATH_IMPL_H_
 #define BASE_NUMERICS_CLAMPED_MATH_IMPL_H_

 #include <stddef.h>
 #include <stdint.h>

 #include <climits>
 #include <cmath>
 #include <cstdlib>
 #include <limits>
 #include <type_traits>

 #include "base/numerics/checked_math.h"
 #include "base/numerics/safe_conversions.h"
 #include "base/numerics/safe_math_shared_impl.h"

 namespace base {
 namespace internal {

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value &&
                                   std::is_signed<T>::value>::type* = nullptr>
 constexpr T SaturatedNegWrapper(T value) {
   return MustTreatAsConstexpr(value) || !ClampedNegFastOp<T>::is_supported
              ? (NegateWrapper(value) != std::numeric_limits<T>::lowest()
                     ? NegateWrapper(value)
                     : std::numeric_limits<T>::max())
              : ClampedNegFastOp<T>::Do(value);
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value &&
                                   !std::is_signed<T>::value>::type* = nullptr>
 constexpr T SaturatedNegWrapper(T value) {
   return T(0);
 }

 template <
     typename T,
     typename std::enable_if<std::is_floating_point<T>::value>::type* = nullptr>
 constexpr T SaturatedNegWrapper(T value) {
   return -value;
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value>::type* = nullptr>
 constexpr T SaturatedAbsWrapper(T value) {
   // The calculation below is a static identity for unsigned types, but for
   // signed integer types it provides a non-branching, saturated absolute value.
   // This works because SafeUnsignedAbs() returns an unsigned type, which can
   // represent the absolute value of all negative numbers of an equal-width
   // integer type. The call to IsValueNegative() then detects overflow in the
   // special case of numeric_limits<T>::min(), by evaluating the bit pattern as
   // a signed integer value. If it is the overflow case, we end up subtracting
   // one from the unsigned result, thus saturating to numeric_limits<T>::max().
   return static_cast<T>(SafeUnsignedAbs(value) -
                         IsValueNegative<T>(SafeUnsignedAbs(value)));
 }

 template <
     typename T,
     typename std::enable_if<std::is_floating_point<T>::value>::type* = nullptr>
 constexpr T SaturatedAbsWrapper(T value) {
   return value < 0 ? -value : value;
 }

 template <typename T, typename U, class Enable = void>
 struct ClampedAddOp {};

 template <typename T, typename U>
 struct ClampedAddOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename MaxExponentPromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     if (ClampedAddFastOp<T, U>::is_supported)
       return ClampedAddFastOp<T, U>::template Do<V>(x, y);

     static_assert(std::is_same<V, result_type>::value ||
                       IsTypeInRangeForNumericType<U, V>::value,
                   "The saturation result cannot be determined from the "
                   "provided types.");
     const V saturated = CommonMaxOrMin<V>(IsValueNegative(y));
     V result = {};
     return BASE_NUMERICS_LIKELY((CheckedAddOp<T, U>::Do(x, y, &result)))
                ? result
                : saturated;
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedSubOp {};

 template <typename T, typename U>
 struct ClampedSubOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename MaxExponentPromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     // TODO(jschuh) Make this "constexpr if" once we're C++17.
     if (ClampedSubFastOp<T, U>::is_supported)
       return ClampedSubFastOp<T, U>::template Do<V>(x, y);

     static_assert(std::is_same<V, result_type>::value ||
                       IsTypeInRangeForNumericType<U, V>::value,
                   "The saturation result cannot be determined from the "
                   "provided types.");
     const V saturated = CommonMaxOrMin<V>(!IsValueNegative(y));
     V result = {};
     return BASE_NUMERICS_LIKELY((CheckedSubOp<T, U>::Do(x, y, &result)))
                ? result
                : saturated;
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedMulOp {};

 template <typename T, typename U>
 struct ClampedMulOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename MaxExponentPromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     // TODO(jschuh) Make this "constexpr if" once we're C++17.
     if (ClampedMulFastOp<T, U>::is_supported)
       return ClampedMulFastOp<T, U>::template Do<V>(x, y);

     V result = {};
     const V saturated =
         CommonMaxOrMin<V>(IsValueNegative(x) ^ IsValueNegative(y));
     return BASE_NUMERICS_LIKELY((CheckedMulOp<T, U>::Do(x, y, &result)))
                ? result
                : saturated;
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedDivOp {};

 template <typename T, typename U>
 struct ClampedDivOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename MaxExponentPromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     V result = {};
     if (BASE_NUMERICS_LIKELY((CheckedDivOp<T, U>::Do(x, y, &result))))
       return result;
     // Saturation goes to max, min, or NaN (if x is zero).
     return x ? CommonMaxOrMin<V>(IsValueNegative(x) ^ IsValueNegative(y))
              : SaturationDefaultLimits<V>::NaN();
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedModOp {};

 template <typename T, typename U>
 struct ClampedModOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename MaxExponentPromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     V result = {};
     return BASE_NUMERICS_LIKELY((CheckedModOp<T, U>::Do(x, y, &result)))
                ? result
                : x;
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedLshOp {};

 // Left shift. Non-zero values saturate in the direction of the sign. A zero
 // shifted by any value always results in zero.
 template <typename T, typename U>
 struct ClampedLshOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = T;
   template <typename V = result_type>
   static constexpr V Do(T x, U shift) {
     static_assert(!std::is_signed<U>::value, "Shift value must be unsigned.");
     if (BASE_NUMERICS_LIKELY(shift < std::numeric_limits<T>::digits)) {
       // Shift as unsigned to avoid undefined behavior.
       V result = static_cast<V>(as_unsigned(x) << shift);
       // If the shift can be reversed, we know it was valid.
       if (BASE_NUMERICS_LIKELY(result >> shift == x))
         return result;
     }
     return x ? CommonMaxOrMin<V>(IsValueNegative(x)) : 0;
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedRshOp {};

 // Right shift. Negative values saturate to -1. Positive or 0 saturates to 0.
 template <typename T, typename U>
 struct ClampedRshOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = T;
   template <typename V = result_type>
   static constexpr V Do(T x, U shift) {
     static_assert(!std::is_signed<U>::value, "Shift value must be unsigned.");
     // Signed right shift is odd, because it saturates to -1 or 0.
     const V saturated = as_unsigned(V(0)) - IsValueNegative(x);
     return BASE_NUMERICS_LIKELY(shift < IntegerBitsPlusSign<T>::value)
                ? saturated_cast<V>(x >> shift)
                : saturated;
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedAndOp {};

 template <typename T, typename U>
 struct ClampedAndOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename std::make_unsigned<
       typename MaxExponentPromotion<T, U>::type>::type;
   template <typename V>
   static constexpr V Do(T x, U y) {
     return static_cast<result_type>(x) & static_cast<result_type>(y);
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedOrOp {};

 // For simplicity we promote to unsigned integers.
 template <typename T, typename U>
 struct ClampedOrOp<T,
                    U,
                    typename std::enable_if<std::is_integral<T>::value &&
                                            std::is_integral<U>::value>::type> {
   using result_type = typename std::make_unsigned<
       typename MaxExponentPromotion<T, U>::type>::type;
   template <typename V>
   static constexpr V Do(T x, U y) {
     return static_cast<result_type>(x) | static_cast<result_type>(y);
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedXorOp {};

 // For simplicity we support only unsigned integers.
 template <typename T, typename U>
 struct ClampedXorOp<T,
                     U,
                     typename std::enable_if<std::is_integral<T>::value &&
                                             std::is_integral<U>::value>::type> {
   using result_type = typename std::make_unsigned<
       typename MaxExponentPromotion<T, U>::type>::type;
   template <typename V>
   static constexpr V Do(T x, U y) {
     return static_cast<result_type>(x) ^ static_cast<result_type>(y);
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedMaxOp {};

 template <typename T, typename U>
 struct ClampedMaxOp<
     T,
     U,
     typename std::enable_if<std::is_arithmetic<T>::value &&
                             std::is_arithmetic<U>::value>::type> {
   using result_type = typename MaxExponentPromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     return IsGreater<T, U>::Test(x, y) ? saturated_cast<V>(x)
                                        : saturated_cast<V>(y);
   }
 };

 template <typename T, typename U, class Enable = void>
 struct ClampedMinOp {};

 template <typename T, typename U>
 struct ClampedMinOp<
     T,
     U,
     typename std::enable_if<std::is_arithmetic<T>::value &&
                             std::is_arithmetic<U>::value>::type> {
   using result_type = typename LowestValuePromotion<T, U>::type;
   template <typename V = result_type>
   static constexpr V Do(T x, U y) {
     return IsLess<T, U>::Test(x, y) ? saturated_cast<V>(x)
                                     : saturated_cast<V>(y);
   }
 };

 // This is just boilerplate that wraps the standard floating point arithmetic.
 // A macro isn't the nicest solution, but it beats rewriting these repeatedly.
 #define BASE_FLOAT_ARITHMETIC_OPS(NAME, OP)                              \
   template <typename T, typename U>                                      \
   struct Clamped##NAME##Op<                                              \
       T, U,                                                              \
       typename std::enable_if<std::is_floating_point<T>::value ||        \
                               std::is_floating_point<U>::value>::type> { \
     using result_type = typename MaxExponentPromotion<T, U>::type;       \
     template <typename V = result_type>                                  \
     static constexpr V Do(T x, U y) {                                    \
       return saturated_cast<V>(x OP y);                                  \
     }                                                                    \
   };

 BASE_FLOAT_ARITHMETIC_OPS(Add, +)
 BASE_FLOAT_ARITHMETIC_OPS(Sub, -)
 BASE_FLOAT_ARITHMETIC_OPS(Mul, *)
 BASE_FLOAT_ARITHMETIC_OPS(Div, /)

 #undef BASE_FLOAT_ARITHMETIC_OPS

 }  // namespace internal
 }  // namespace base

 #endif  // BASE_NUMERICS_CLAMPED_MATH_IMPL_H_
	// Copyright 2017 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_NUMERICS_CLAMPED_MATH_IMPL_H_
	#define BASE_NUMERICS_CLAMPED_MATH_IMPL_H_

	#include <stddef.h>
	#include <stdint.h>

	#include <climits>
	#include <cmath>
	#include <cstdlib>
	#include <limits>
	#include <type_traits>

	#include "base/numerics/checked_math.h"
	#include "base/numerics/safe_conversions.h"
	#include "base/numerics/safe_math_shared_impl.h"

	namespace base {
	namespace internal {

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_signed<T>::value>::type* = nullptr>
	constexpr T SaturatedNegWrapper(T value) {
	return MustTreatAsConstexpr(value) \|\| !ClampedNegFastOp<T>::is_supported
	? (NegateWrapper(value) != std::numeric_limits<T>::lowest()
	? NegateWrapper(value)
	: std::numeric_limits<T>::max())
	: ClampedNegFastOp<T>::Do(value);
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value &&
	!std::is_signed<T>::value>::type* = nullptr>
	constexpr T SaturatedNegWrapper(T value) {
	return T(0);
	}

	template <
	typename T,
	typename std::enable_if<std::is_floating_point<T>::value>::type* = nullptr>
	constexpr T SaturatedNegWrapper(T value) {
	return -value;
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value>::type* = nullptr>
	constexpr T SaturatedAbsWrapper(T value) {
	// The calculation below is a static identity for unsigned types, but for
	// signed integer types it provides a non-branching, saturated absolute value.
	// This works because SafeUnsignedAbs() returns an unsigned type, which can
	// represent the absolute value of all negative numbers of an equal-width
	// integer type. The call to IsValueNegative() then detects overflow in the
	// special case of numeric_limits<T>::min(), by evaluating the bit pattern as
	// a signed integer value. If it is the overflow case, we end up subtracting
	// one from the unsigned result, thus saturating to numeric_limits<T>::max().
	return static_cast<T>(SafeUnsignedAbs(value) -
	IsValueNegative<T>(SafeUnsignedAbs(value)));
	}

	template <
	typename T,
	typename std::enable_if<std::is_floating_point<T>::value>::type* = nullptr>
	constexpr T SaturatedAbsWrapper(T value) {
	return value < 0 ? -value : value;
	}

	template <typename T, typename U, class Enable = void>
	struct ClampedAddOp {};

	template <typename T, typename U>
	struct ClampedAddOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename MaxExponentPromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	if (ClampedAddFastOp<T, U>::is_supported)
	return ClampedAddFastOp<T, U>::template Do<V>(x, y);

	static_assert(std::is_same<V, result_type>::value \|\|
	IsTypeInRangeForNumericType<U, V>::value,
	"The saturation result cannot be determined from the "
	"provided types.");
	const V saturated = CommonMaxOrMin<V>(IsValueNegative(y));
	V result = {};
	return BASE_NUMERICS_LIKELY((CheckedAddOp<T, U>::Do(x, y, &result)))
	? result
	: saturated;
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedSubOp {};

	template <typename T, typename U>
	struct ClampedSubOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename MaxExponentPromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	// TODO(jschuh) Make this "constexpr if" once we're C++17.
	if (ClampedSubFastOp<T, U>::is_supported)
	return ClampedSubFastOp<T, U>::template Do<V>(x, y);

	static_assert(std::is_same<V, result_type>::value \|\|
	IsTypeInRangeForNumericType<U, V>::value,
	"The saturation result cannot be determined from the "
	"provided types.");
	const V saturated = CommonMaxOrMin<V>(!IsValueNegative(y));
	V result = {};
	return BASE_NUMERICS_LIKELY((CheckedSubOp<T, U>::Do(x, y, &result)))
	? result
	: saturated;
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedMulOp {};

	template <typename T, typename U>
	struct ClampedMulOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename MaxExponentPromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	// TODO(jschuh) Make this "constexpr if" once we're C++17.
	if (ClampedMulFastOp<T, U>::is_supported)
	return ClampedMulFastOp<T, U>::template Do<V>(x, y);

	V result = {};
	const V saturated =
	CommonMaxOrMin<V>(IsValueNegative(x) ^ IsValueNegative(y));
	return BASE_NUMERICS_LIKELY((CheckedMulOp<T, U>::Do(x, y, &result)))
	? result
	: saturated;
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedDivOp {};

	template <typename T, typename U>
	struct ClampedDivOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename MaxExponentPromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	V result = {};
	if (BASE_NUMERICS_LIKELY((CheckedDivOp<T, U>::Do(x, y, &result))))
	return result;
	// Saturation goes to max, min, or NaN (if x is zero).
	return x ? CommonMaxOrMin<V>(IsValueNegative(x) ^ IsValueNegative(y))
	: SaturationDefaultLimits<V>::NaN();
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedModOp {};

	template <typename T, typename U>
	struct ClampedModOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename MaxExponentPromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	V result = {};
	return BASE_NUMERICS_LIKELY((CheckedModOp<T, U>::Do(x, y, &result)))
	? result
	: x;
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedLshOp {};

	// Left shift. Non-zero values saturate in the direction of the sign. A zero
	// shifted by any value always results in zero.
	template <typename T, typename U>
	struct ClampedLshOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = T;
	template <typename V = result_type>
	static constexpr V Do(T x, U shift) {
	static_assert(!std::is_signed<U>::value, "Shift value must be unsigned.");
	if (BASE_NUMERICS_LIKELY(shift < std::numeric_limits<T>::digits)) {
	// Shift as unsigned to avoid undefined behavior.
	V result = static_cast<V>(as_unsigned(x) << shift);
	// If the shift can be reversed, we know it was valid.
	if (BASE_NUMERICS_LIKELY(result >> shift == x))
	return result;
	}
	return x ? CommonMaxOrMin<V>(IsValueNegative(x)) : 0;
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedRshOp {};

	// Right shift. Negative values saturate to -1. Positive or 0 saturates to 0.
	template <typename T, typename U>
	struct ClampedRshOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = T;
	template <typename V = result_type>
	static constexpr V Do(T x, U shift) {
	static_assert(!std::is_signed<U>::value, "Shift value must be unsigned.");
	// Signed right shift is odd, because it saturates to -1 or 0.
	const V saturated = as_unsigned(V(0)) - IsValueNegative(x);
	return BASE_NUMERICS_LIKELY(shift < IntegerBitsPlusSign<T>::value)
	? saturated_cast<V>(x >> shift)
	: saturated;
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedAndOp {};

	template <typename T, typename U>
	struct ClampedAndOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename std::make_unsigned<
	typename MaxExponentPromotion<T, U>::type>::type;
	template <typename V>
	static constexpr V Do(T x, U y) {
	return static_cast<result_type>(x) & static_cast<result_type>(y);
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedOrOp {};

	// For simplicity we promote to unsigned integers.
	template <typename T, typename U>
	struct ClampedOrOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename std::make_unsigned<
	typename MaxExponentPromotion<T, U>::type>::type;
	template <typename V>
	static constexpr V Do(T x, U y) {
	return static_cast<result_type>(x) \| static_cast<result_type>(y);
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedXorOp {};

	// For simplicity we support only unsigned integers.
	template <typename T, typename U>
	struct ClampedXorOp<T,
	U,
	typename std::enable_if<std::is_integral<T>::value &&
	std::is_integral<U>::value>::type> {
	using result_type = typename std::make_unsigned<
	typename MaxExponentPromotion<T, U>::type>::type;
	template <typename V>
	static constexpr V Do(T x, U y) {
	return static_cast<result_type>(x) ^ static_cast<result_type>(y);
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedMaxOp {};

	template <typename T, typename U>
	struct ClampedMaxOp<
	T,
	U,
	typename std::enable_if<std::is_arithmetic<T>::value &&
	std::is_arithmetic<U>::value>::type> {
	using result_type = typename MaxExponentPromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	return IsGreater<T, U>::Test(x, y) ? saturated_cast<V>(x)
	: saturated_cast<V>(y);
	}
	};

	template <typename T, typename U, class Enable = void>
	struct ClampedMinOp {};

	template <typename T, typename U>
	struct ClampedMinOp<
	T,
	U,
	typename std::enable_if<std::is_arithmetic<T>::value &&
	std::is_arithmetic<U>::value>::type> {
	using result_type = typename LowestValuePromotion<T, U>::type;
	template <typename V = result_type>
	static constexpr V Do(T x, U y) {
	return IsLess<T, U>::Test(x, y) ? saturated_cast<V>(x)
	: saturated_cast<V>(y);
	}
	};

	// This is just boilerplate that wraps the standard floating point arithmetic.
	// A macro isn't the nicest solution, but it beats rewriting these repeatedly.
	#define BASE_FLOAT_ARITHMETIC_OPS(NAME, OP) \
	template <typename T, typename U> \
	struct Clamped##NAME##Op< \
	T, U, \
	typename std::enable_if<std::is_floating_point<T>::value \|\| \
	std::is_floating_point<U>::value>::type> { \
	using result_type = typename MaxExponentPromotion<T, U>::type; \
	template <typename V = result_type> \
	static constexpr V Do(T x, U y) { \
	return saturated_cast<V>(x OP y); \
	} \
	};

	BASE_FLOAT_ARITHMETIC_OPS(Add, +)
	BASE_FLOAT_ARITHMETIC_OPS(Sub, -)
	BASE_FLOAT_ARITHMETIC_OPS(Mul, *)
	BASE_FLOAT_ARITHMETIC_OPS(Div, /)

	#undef BASE_FLOAT_ARITHMETIC_OPS

	} // namespace internal
	} // namespace base

	#endif // BASE_NUMERICS_CLAMPED_MATH_IMPL_H_