third_party/chromium/base/numerics/safe_math.h - weave/libweave - Git at Google

 // Copyright 2014 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_SAFE_MATH_H_
 #define BASE_NUMERICS_SAFE_MATH_H_

 #include <stddef.h>

 #include "base/numerics/safe_math_impl.h"

 namespace base {

 namespace internal {

 // CheckedNumeric implements all the logic and operators for detecting integer
 // boundary conditions such as overflow, underflow, and invalid conversions.
 // The CheckedNumeric type implicitly converts from floating point and integer
 // data types, and contains overloads for basic arithmetic operations (i.e.: +,
 // -, *, /, %).
 //
 // The following methods convert from CheckedNumeric to standard numeric values:
 // IsValid() - Returns true if the underlying numeric value is valid (i.e. has
 //             has not wrapped and is not the result of an invalid conversion).
 // ValueOrDie() - Returns the underlying value. If the state is not valid this
 //                call will crash on a CHECK.
 // ValueOrDefault() - Returns the current value, or the supplied default if the
 //                    state is not valid.
 // ValueFloating() - Returns the underlying floating point value (valid only
 //                   only for floating point CheckedNumeric types).
 //
 // Bitwise operations are explicitly not supported, because correct
 // handling of some cases (e.g. sign manipulation) is ambiguous. Comparison
 // operations are explicitly not supported because they could result in a crash
 // on a CHECK condition. You should use patterns like the following for these
 // operations:
 // Bitwise operation:
 //     CheckedNumeric<int> checked_int = untrusted_input_value;
 //     int x = checked_int.ValueOrDefault(0) | kFlagValues;
 // Comparison:
 //   CheckedNumeric<size_t> checked_size = untrusted_input_value;
 //   checked_size += HEADER LENGTH;
 //   if (checked_size.IsValid() && checked_size.ValueOrDie() < buffer_size)
 //     Do stuff...
 template <typename T>
 class CheckedNumeric {
  public:
   typedef T type;

   CheckedNumeric() {}

   // Copy constructor.
   template <typename Src>
   CheckedNumeric(const CheckedNumeric<Src>& rhs)
       : state_(rhs.ValueUnsafe(), rhs.validity()) {}

   template <typename Src>
   CheckedNumeric(Src value, RangeConstraint validity)
       : state_(value, validity) {}

   // This is not an explicit constructor because we implicitly upgrade regular
   // numerics to CheckedNumerics to make them easier to use.
   template <typename Src>
   CheckedNumeric(Src value)
       : state_(value) {
     static_assert(std::numeric_limits<Src>::is_specialized,
                   "Argument must be numeric.");
   }

   // This is not an explicit constructor because we want a seamless conversion
   // from StrictNumeric types.
   template <typename Src>
   CheckedNumeric(StrictNumeric<Src> value)
       : state_(static_cast<Src>(value)) {
   }

   // IsValid() is the public API to test if a CheckedNumeric is currently valid.
   bool IsValid() const { return validity() == RANGE_VALID; }

   // ValueOrDie() The primary accessor for the underlying value. If the current
   // state is not valid it will CHECK and crash.
   T ValueOrDie() const {
     CHECK(IsValid());
     return state_.value();
   }

   // ValueOrDefault(T default_value) A convenience method that returns the
   // current value if the state is valid, and the supplied default_value for
   // any other state.
   T ValueOrDefault(T default_value) const {
     return IsValid() ? state_.value() : default_value;
   }

   // ValueFloating() - Since floating point values include their validity state,
   // we provide an easy method for extracting them directly, without a risk of
   // crashing on a CHECK.
   T ValueFloating() const {
     static_assert(std::numeric_limits<T>::is_iec559, "Argument must be float.");
     return CheckedNumeric<T>::cast(*this).ValueUnsafe();
   }

   // validity() - DO NOT USE THIS IN EXTERNAL CODE - It is public right now for
   // tests and to avoid a big matrix of friend operator overloads. But the
   // values it returns are likely to change in the future.
   // Returns: current validity state (i.e. valid, overflow, underflow, nan).
   // TODO(jschuh): crbug.com/332611 Figure out and implement semantics for
   // saturation/wrapping so we can expose this state consistently and implement
   // saturated arithmetic.
   RangeConstraint validity() const { return state_.validity(); }

   // ValueUnsafe() - DO NOT USE THIS IN EXTERNAL CODE - It is public right now
   // for tests and to avoid a big matrix of friend operator overloads. But the
   // values it returns are likely to change in the future.
   // Returns: the raw numeric value, regardless of the current state.
   // TODO(jschuh): crbug.com/332611 Figure out and implement semantics for
   // saturation/wrapping so we can expose this state consistently and implement
   // saturated arithmetic.
   T ValueUnsafe() const { return state_.value(); }

   // Prototypes for the supported arithmetic operator overloads.
   template <typename Src> CheckedNumeric& operator+=(Src rhs);
   template <typename Src> CheckedNumeric& operator-=(Src rhs);
   template <typename Src> CheckedNumeric& operator*=(Src rhs);
   template <typename Src> CheckedNumeric& operator/=(Src rhs);
   template <typename Src> CheckedNumeric& operator%=(Src rhs);

   CheckedNumeric operator-() const {
     RangeConstraint validity;
     T value = CheckedNeg(state_.value(), &validity);
     // Negation is always valid for floating point.
     if (std::numeric_limits<T>::is_iec559)
       return CheckedNumeric<T>(value);

     validity = GetRangeConstraint(state_.validity() | validity);
     return CheckedNumeric<T>(value, validity);
   }

   CheckedNumeric Abs() const {
     RangeConstraint validity;
     T value = CheckedAbs(state_.value(), &validity);
     // Absolute value is always valid for floating point.
     if (std::numeric_limits<T>::is_iec559)
       return CheckedNumeric<T>(value);

     validity = GetRangeConstraint(state_.validity() | validity);
     return CheckedNumeric<T>(value, validity);
   }

   // This function is available only for integral types. It returns an unsigned
   // integer of the same width as the source type, containing the absolute value
   // of the source, and properly handling signed min.
   CheckedNumeric<typename UnsignedOrFloatForSize<T>::type> UnsignedAbs() const {
     return CheckedNumeric<typename UnsignedOrFloatForSize<T>::type>(
         CheckedUnsignedAbs(state_.value()), state_.validity());
   }

   CheckedNumeric& operator++() {
     *this += 1;
     return *this;
   }

   CheckedNumeric operator++(int) {
     CheckedNumeric value = *this;
     *this += 1;
     return value;
   }

   CheckedNumeric& operator--() {
     *this -= 1;
     return *this;
   }

   CheckedNumeric operator--(int) {
     CheckedNumeric value = *this;
     *this -= 1;
     return value;
   }

   // These static methods behave like a convenience cast operator targeting
   // the desired CheckedNumeric type. As an optimization, a reference is
   // returned when Src is the same type as T.
   template <typename Src>
   static CheckedNumeric<T> cast(
       Src u,
       typename std::enable_if<std::numeric_limits<Src>::is_specialized,
                               int>::type = 0) {
     return u;
   }

   template <typename Src>
   static CheckedNumeric<T> cast(
       const CheckedNumeric<Src>& u,
       typename std::enable_if<!std::is_same<Src, T>::value, int>::type = 0) {
     return u;
   }

   static const CheckedNumeric<T>& cast(const CheckedNumeric<T>& u) { return u; }

  private:
   template <typename NumericType>
   struct UnderlyingType {
     using type = NumericType;
   };

   template <typename NumericType>
   struct UnderlyingType<CheckedNumeric<NumericType>> {
     using type = NumericType;
   };

   CheckedNumericState<T> state_;
 };

 // This is the boilerplate for the standard arithmetic operator overloads. A
 // macro isn't the prettiest solution, but it beats rewriting these five times.
 // Some details worth noting are:
 //  * We apply the standard arithmetic promotions.
 //  * We skip range checks for floating points.
 //  * We skip range checks for destination integers with sufficient range.
 // TODO(jschuh): extract these out into templates.
 #define BASE_NUMERIC_ARITHMETIC_OPERATORS(NAME, OP, COMPOUND_OP)              \
   /* Binary arithmetic operator for CheckedNumerics of the same type. */      \
   template <typename T>                                                       \
   CheckedNumeric<typename ArithmeticPromotion<T>::type> operator OP(          \
       const CheckedNumeric<T>& lhs, const CheckedNumeric<T>& rhs) {           \
     typedef typename ArithmeticPromotion<T>::type Promotion;                  \
     /* Floating point always takes the fast path */                           \
     if (std::numeric_limits<T>::is_iec559)                                    \
       return CheckedNumeric<T>(lhs.ValueUnsafe() OP rhs.ValueUnsafe());       \
     if (IsIntegerArithmeticSafe<Promotion, T, T>::value)                      \
       return CheckedNumeric<Promotion>(                                       \
           lhs.ValueUnsafe() OP rhs.ValueUnsafe(),                             \
           GetRangeConstraint(rhs.validity() | lhs.validity()));               \
     RangeConstraint validity = RANGE_VALID;                                   \
     T result = static_cast<T>(Checked##NAME(                                  \
         static_cast<Promotion>(lhs.ValueUnsafe()),                            \
         static_cast<Promotion>(rhs.ValueUnsafe()),                            \
         &validity));                                                          \
     return CheckedNumeric<Promotion>(                                         \
         result,                                                               \
         GetRangeConstraint(validity | lhs.validity() | rhs.validity()));      \
   }                                                                           \
   /* Assignment arithmetic operator implementation from CheckedNumeric. */    \
   template <typename T>                                                       \
   template <typename Src>                                                     \
   CheckedNumeric<T>& CheckedNumeric<T>::operator COMPOUND_OP(Src rhs) {       \
     *this = CheckedNumeric<T>::cast(*this)                                    \
         OP CheckedNumeric<typename UnderlyingType<Src>::type>::cast(rhs);     \
     return *this;                                                             \
   }                                                                           \
   /* Binary arithmetic operator for CheckedNumeric of different type. */      \
   template <typename T, typename Src>                                         \
   CheckedNumeric<typename ArithmeticPromotion<T, Src>::type> operator OP(     \
       const CheckedNumeric<Src>& lhs, const CheckedNumeric<T>& rhs) {         \
     typedef typename ArithmeticPromotion<T, Src>::type Promotion;             \
     if (IsIntegerArithmeticSafe<Promotion, T, Src>::value)                    \
       return CheckedNumeric<Promotion>(                                       \
           lhs.ValueUnsafe() OP rhs.ValueUnsafe(),                             \
           GetRangeConstraint(rhs.validity() | lhs.validity()));               \
     return CheckedNumeric<Promotion>::cast(lhs)                               \
         OP CheckedNumeric<Promotion>::cast(rhs);                              \
   }                                                                           \
   /* Binary arithmetic operator for left CheckedNumeric and right numeric. */ \
   template <typename T, typename Src>                                         \
   CheckedNumeric<typename ArithmeticPromotion<T, Src>::type> operator OP(     \
       const CheckedNumeric<T>& lhs, Src rhs) {                                \
     typedef typename ArithmeticPromotion<T, Src>::type Promotion;             \
     if (IsIntegerArithmeticSafe<Promotion, T, Src>::value)                    \
       return CheckedNumeric<Promotion>(lhs.ValueUnsafe() OP rhs,              \
                                        lhs.validity());                       \
     return CheckedNumeric<Promotion>::cast(lhs)                               \
         OP CheckedNumeric<Promotion>::cast(rhs);                              \
   }                                                                           \
   /* Binary arithmetic operator for right numeric and left CheckedNumeric. */ \
   template <typename T, typename Src>                                         \
   CheckedNumeric<typename ArithmeticPromotion<T, Src>::type> operator OP(     \
       Src lhs, const CheckedNumeric<T>& rhs) {                                \
     typedef typename ArithmeticPromotion<T, Src>::type Promotion;             \
     if (IsIntegerArithmeticSafe<Promotion, T, Src>::value)                    \
       return CheckedNumeric<Promotion>(lhs OP rhs.ValueUnsafe(),              \
                                        rhs.validity());                       \
     return CheckedNumeric<Promotion>::cast(lhs)                               \
         OP CheckedNumeric<Promotion>::cast(rhs);                              \
   }

 BASE_NUMERIC_ARITHMETIC_OPERATORS(Add, +, += )
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Sub, -, -= )
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Mul, *, *= )
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Div, /, /= )
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Mod, %, %= )

 #undef BASE_NUMERIC_ARITHMETIC_OPERATORS

 }  // namespace internal

 using internal::CheckedNumeric;

 }  // namespace base

 #endif  // BASE_NUMERICS_SAFE_MATH_H_
	// Copyright 2014 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_SAFE_MATH_H_
	#define BASE_NUMERICS_SAFE_MATH_H_

	#include <stddef.h>

	#include "base/numerics/safe_math_impl.h"

	namespace base {

	namespace internal {

	// CheckedNumeric implements all the logic and operators for detecting integer
	// boundary conditions such as overflow, underflow, and invalid conversions.
	// The CheckedNumeric type implicitly converts from floating point and integer
	// data types, and contains overloads for basic arithmetic operations (i.e.: +,
	// -, *, /, %).
	//
	// The following methods convert from CheckedNumeric to standard numeric values:
	// IsValid() - Returns true if the underlying numeric value is valid (i.e. has
	// has not wrapped and is not the result of an invalid conversion).
	// ValueOrDie() - Returns the underlying value. If the state is not valid this
	// call will crash on a CHECK.
	// ValueOrDefault() - Returns the current value, or the supplied default if the
	// state is not valid.
	// ValueFloating() - Returns the underlying floating point value (valid only
	// only for floating point CheckedNumeric types).
	//
	// Bitwise operations are explicitly not supported, because correct
	// handling of some cases (e.g. sign manipulation) is ambiguous. Comparison
	// operations are explicitly not supported because they could result in a crash
	// on a CHECK condition. You should use patterns like the following for these
	// operations:
	// Bitwise operation:
	// CheckedNumeric<int> checked_int = untrusted_input_value;
	// int x = checked_int.ValueOrDefault(0) \| kFlagValues;
	// Comparison:
	// CheckedNumeric<size_t> checked_size = untrusted_input_value;
	// checked_size += HEADER LENGTH;
	// if (checked_size.IsValid() && checked_size.ValueOrDie() < buffer_size)
	// Do stuff...
	template <typename T>
	class CheckedNumeric {
	public:
	typedef T type;

	CheckedNumeric() {}

	// Copy constructor.
	template <typename Src>
	CheckedNumeric(const CheckedNumeric<Src>& rhs)
	: state_(rhs.ValueUnsafe(), rhs.validity()) {}

	template <typename Src>
	CheckedNumeric(Src value, RangeConstraint validity)
	: state_(value, validity) {}

	// This is not an explicit constructor because we implicitly upgrade regular
	// numerics to CheckedNumerics to make them easier to use.
	template <typename Src>
	CheckedNumeric(Src value)
	: state_(value) {
	static_assert(std::numeric_limits<Src>::is_specialized,
	"Argument must be numeric.");
	}

	// This is not an explicit constructor because we want a seamless conversion
	// from StrictNumeric types.
	template <typename Src>
	CheckedNumeric(StrictNumeric<Src> value)
	: state_(static_cast<Src>(value)) {
	}

	// IsValid() is the public API to test if a CheckedNumeric is currently valid.
	bool IsValid() const { return validity() == RANGE_VALID; }

	// ValueOrDie() The primary accessor for the underlying value. If the current
	// state is not valid it will CHECK and crash.
	T ValueOrDie() const {
	CHECK(IsValid());
	return state_.value();
	}

	// ValueOrDefault(T default_value) A convenience method that returns the
	// current value if the state is valid, and the supplied default_value for
	// any other state.
	T ValueOrDefault(T default_value) const {
	return IsValid() ? state_.value() : default_value;
	}

	// ValueFloating() - Since floating point values include their validity state,
	// we provide an easy method for extracting them directly, without a risk of
	// crashing on a CHECK.
	T ValueFloating() const {
	static_assert(std::numeric_limits<T>::is_iec559, "Argument must be float.");
	return CheckedNumeric<T>::cast(*this).ValueUnsafe();
	}

	// validity() - DO NOT USE THIS IN EXTERNAL CODE - It is public right now for
	// tests and to avoid a big matrix of friend operator overloads. But the
	// values it returns are likely to change in the future.
	// Returns: current validity state (i.e. valid, overflow, underflow, nan).
	// TODO(jschuh): crbug.com/332611 Figure out and implement semantics for
	// saturation/wrapping so we can expose this state consistently and implement
	// saturated arithmetic.
	RangeConstraint validity() const { return state_.validity(); }

	// ValueUnsafe() - DO NOT USE THIS IN EXTERNAL CODE - It is public right now
	// for tests and to avoid a big matrix of friend operator overloads. But the
	// values it returns are likely to change in the future.
	// Returns: the raw numeric value, regardless of the current state.
	// TODO(jschuh): crbug.com/332611 Figure out and implement semantics for
	// saturation/wrapping so we can expose this state consistently and implement
	// saturated arithmetic.
	T ValueUnsafe() const { return state_.value(); }

	// Prototypes for the supported arithmetic operator overloads.
	template <typename Src> CheckedNumeric& operator+=(Src rhs);
	template <typename Src> CheckedNumeric& operator-=(Src rhs);
	template <typename Src> CheckedNumeric& operator*=(Src rhs);
	template <typename Src> CheckedNumeric& operator/=(Src rhs);
	template <typename Src> CheckedNumeric& operator%=(Src rhs);

	CheckedNumeric operator-() const {
	RangeConstraint validity;
	T value = CheckedNeg(state_.value(), &validity);
	// Negation is always valid for floating point.
	if (std::numeric_limits<T>::is_iec559)
	return CheckedNumeric<T>(value);

	validity = GetRangeConstraint(state_.validity() \| validity);
	return CheckedNumeric<T>(value, validity);
	}

	CheckedNumeric Abs() const {
	RangeConstraint validity;
	T value = CheckedAbs(state_.value(), &validity);
	// Absolute value is always valid for floating point.
	if (std::numeric_limits<T>::is_iec559)
	return CheckedNumeric<T>(value);

	validity = GetRangeConstraint(state_.validity() \| validity);
	return CheckedNumeric<T>(value, validity);
	}

	// This function is available only for integral types. It returns an unsigned
	// integer of the same width as the source type, containing the absolute value
	// of the source, and properly handling signed min.
	CheckedNumeric<typename UnsignedOrFloatForSize<T>::type> UnsignedAbs() const {
	return CheckedNumeric<typename UnsignedOrFloatForSize<T>::type>(
	CheckedUnsignedAbs(state_.value()), state_.validity());
	}

	CheckedNumeric& operator++() {
	*this += 1;
	return *this;
	}

	CheckedNumeric operator++(int) {
	CheckedNumeric value = *this;
	*this += 1;
	return value;
	}

	CheckedNumeric& operator--() {
	*this -= 1;
	return *this;
	}

	CheckedNumeric operator--(int) {
	CheckedNumeric value = *this;
	*this -= 1;
	return value;
	}

	// These static methods behave like a convenience cast operator targeting
	// the desired CheckedNumeric type. As an optimization, a reference is
	// returned when Src is the same type as T.
	template <typename Src>
	static CheckedNumeric<T> cast(
	Src u,
	typename std::enable_if<std::numeric_limits<Src>::is_specialized,
	int>::type = 0) {
	return u;
	}

	template <typename Src>
	static CheckedNumeric<T> cast(
	const CheckedNumeric<Src>& u,
	typename std::enable_if<!std::is_same<Src, T>::value, int>::type = 0) {
	return u;
	}

	static const CheckedNumeric<T>& cast(const CheckedNumeric<T>& u) { return u; }

	private:
	template <typename NumericType>
	struct UnderlyingType {
	using type = NumericType;
	};

	template <typename NumericType>
	struct UnderlyingType<CheckedNumeric<NumericType>> {
	using type = NumericType;
	};

	CheckedNumericState<T> state_;
	};

	// This is the boilerplate for the standard arithmetic operator overloads. A
	// macro isn't the prettiest solution, but it beats rewriting these five times.
	// Some details worth noting are:
	// * We apply the standard arithmetic promotions.
	// * We skip range checks for floating points.
	// * We skip range checks for destination integers with sufficient range.
	// TODO(jschuh): extract these out into templates.
	#define BASE_NUMERIC_ARITHMETIC_OPERATORS(NAME, OP, COMPOUND_OP) \
	/* Binary arithmetic operator for CheckedNumerics of the same type. */ \
	template <typename T> \
	CheckedNumeric<typename ArithmeticPromotion<T>::type> operator OP( \
	const CheckedNumeric<T>& lhs, const CheckedNumeric<T>& rhs) { \
	typedef typename ArithmeticPromotion<T>::type Promotion; \
	/* Floating point always takes the fast path */ \
	if (std::numeric_limits<T>::is_iec559) \
	return CheckedNumeric<T>(lhs.ValueUnsafe() OP rhs.ValueUnsafe()); \
	if (IsIntegerArithmeticSafe<Promotion, T, T>::value) \
	return CheckedNumeric<Promotion>( \
	lhs.ValueUnsafe() OP rhs.ValueUnsafe(), \
	GetRangeConstraint(rhs.validity() \| lhs.validity())); \
	RangeConstraint validity = RANGE_VALID; \
	T result = static_cast<T>(Checked##NAME( \
	static_cast<Promotion>(lhs.ValueUnsafe()), \
	static_cast<Promotion>(rhs.ValueUnsafe()), \
	&validity)); \
	return CheckedNumeric<Promotion>( \
	result, \
	GetRangeConstraint(validity \| lhs.validity() \| rhs.validity())); \
	} \
	/* Assignment arithmetic operator implementation from CheckedNumeric. */ \
	template <typename T> \
	template <typename Src> \
	CheckedNumeric<T>& CheckedNumeric<T>::operator COMPOUND_OP(Src rhs) { \
	this = CheckedNumeric<T>::cast(this) \
	OP CheckedNumeric<typename UnderlyingType<Src>::type>::cast(rhs); \
	return *this; \
	} \
	/* Binary arithmetic operator for CheckedNumeric of different type. */ \
	template <typename T, typename Src> \
	CheckedNumeric<typename ArithmeticPromotion<T, Src>::type> operator OP( \
	const CheckedNumeric<Src>& lhs, const CheckedNumeric<T>& rhs) { \
	typedef typename ArithmeticPromotion<T, Src>::type Promotion; \
	if (IsIntegerArithmeticSafe<Promotion, T, Src>::value) \
	return CheckedNumeric<Promotion>( \
	lhs.ValueUnsafe() OP rhs.ValueUnsafe(), \
	GetRangeConstraint(rhs.validity() \| lhs.validity())); \
	return CheckedNumeric<Promotion>::cast(lhs) \
	OP CheckedNumeric<Promotion>::cast(rhs); \
	} \
	/* Binary arithmetic operator for left CheckedNumeric and right numeric. */ \
	template <typename T, typename Src> \
	CheckedNumeric<typename ArithmeticPromotion<T, Src>::type> operator OP( \
	const CheckedNumeric<T>& lhs, Src rhs) { \
	typedef typename ArithmeticPromotion<T, Src>::type Promotion; \
	if (IsIntegerArithmeticSafe<Promotion, T, Src>::value) \
	return CheckedNumeric<Promotion>(lhs.ValueUnsafe() OP rhs, \
	lhs.validity()); \
	return CheckedNumeric<Promotion>::cast(lhs) \
	OP CheckedNumeric<Promotion>::cast(rhs); \
	} \
	/* Binary arithmetic operator for right numeric and left CheckedNumeric. */ \
	template <typename T, typename Src> \
	CheckedNumeric<typename ArithmeticPromotion<T, Src>::type> operator OP( \
	Src lhs, const CheckedNumeric<T>& rhs) { \
	typedef typename ArithmeticPromotion<T, Src>::type Promotion; \
	if (IsIntegerArithmeticSafe<Promotion, T, Src>::value) \
	return CheckedNumeric<Promotion>(lhs OP rhs.ValueUnsafe(), \
	rhs.validity()); \
	return CheckedNumeric<Promotion>::cast(lhs) \
	OP CheckedNumeric<Promotion>::cast(rhs); \
	}

	BASE_NUMERIC_ARITHMETIC_OPERATORS(Add, +, += )
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Sub, -, -= )
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Mul, , = )
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Div, /, /= )
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Mod, %, %= )

	#undef BASE_NUMERIC_ARITHMETIC_OPERATORS

	} // namespace internal

	using internal::CheckedNumeric;

	} // namespace base

	#endif // BASE_NUMERICS_SAFE_MATH_H_