base/numerics/clamped_math.h - gn - 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_H_
 #define BASE_NUMERICS_CLAMPED_MATH_H_

 #include <stddef.h>

 #include <limits>
 #include <type_traits>

 #include "base/numerics/clamped_math_impl.h"

 namespace base {
 namespace internal {

 template <typename T>
 class ClampedNumeric {
   static_assert(std::is_arithmetic<T>::value,
                 "ClampedNumeric<T>: T must be a numeric type.");

  public:
   using type = T;

   constexpr ClampedNumeric() : value_(0) {}

   // Copy constructor.
   template <typename Src>
   constexpr ClampedNumeric(const ClampedNumeric<Src>& rhs)
       : value_(saturated_cast<T>(rhs.value_)) {}

   template <typename Src>
   friend class ClampedNumeric;

   // This is not an explicit constructor because we implicitly upgrade regular
   // numerics to ClampedNumerics to make them easier to use.
   template <typename Src>
   constexpr ClampedNumeric(Src value)  // NOLINT(runtime/explicit)
       : value_(saturated_cast<T>(value)) {
     static_assert(std::is_arithmetic<Src>::value, "Argument must be numeric.");
   }

   // This is not an explicit constructor because we want a seamless conversion
   // from StrictNumeric types.
   template <typename Src>
   constexpr ClampedNumeric(
       StrictNumeric<Src> value)  // NOLINT(runtime/explicit)
       : value_(saturated_cast<T>(static_cast<Src>(value))) {}

   // Returns a ClampedNumeric of the specified type, cast from the current
   // ClampedNumeric, and saturated to the destination type.
   template <typename Dst>
   constexpr ClampedNumeric<typename UnderlyingType<Dst>::type> Cast() const {
     return *this;
   }

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

   constexpr ClampedNumeric operator-() const {
     // The negation of two's complement int min is int min, so that's the
     // only overflow case where we will saturate.
     return ClampedNumeric<T>(SaturatedNegWrapper(value_));
   }

   constexpr ClampedNumeric operator~() const {
     return ClampedNumeric<decltype(InvertWrapper(T()))>(InvertWrapper(value_));
   }

   constexpr ClampedNumeric Abs() const {
     // The negation of two's complement int min is int min, so that's the
     // only overflow case where we will saturate.
     return ClampedNumeric<T>(SaturatedAbsWrapper(value_));
   }

   template <typename U>
   constexpr ClampedNumeric<typename MathWrapper<ClampedMaxOp, T, U>::type> Max(
       const U rhs) const {
     using result_type = typename MathWrapper<ClampedMaxOp, T, U>::type;
     return ClampedNumeric<result_type>(
         ClampedMaxOp<T, U>::Do(value_, Wrapper<U>::value(rhs)));
   }

   template <typename U>
   constexpr ClampedNumeric<typename MathWrapper<ClampedMinOp, T, U>::type> Min(
       const U rhs) const {
     using result_type = typename MathWrapper<ClampedMinOp, T, U>::type;
     return ClampedNumeric<result_type>(
         ClampedMinOp<T, U>::Do(value_, Wrapper<U>::value(rhs)));
   }

   // 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.
   constexpr ClampedNumeric<typename UnsignedOrFloatForSize<T>::type>
   UnsignedAbs() const {
     return ClampedNumeric<typename UnsignedOrFloatForSize<T>::type>(
         SafeUnsignedAbs(value_));
   }

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

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

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

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

   // These perform the actual math operations on the ClampedNumerics.
   // Binary arithmetic operations.
   template <template <typename, typename, typename> class M,
             typename L,
             typename R>
   static constexpr ClampedNumeric MathOp(const L lhs, const R rhs) {
     using Math = typename MathWrapper<M, L, R>::math;
     return ClampedNumeric<T>(
         Math::template Do<T>(Wrapper<L>::value(lhs), Wrapper<R>::value(rhs)));
   }

   // Assignment arithmetic operations.
   template <template <typename, typename, typename> class M, typename R>
   constexpr ClampedNumeric& MathOp(const R rhs) {
     using Math = typename MathWrapper<M, T, R>::math;
     *this =
         ClampedNumeric<T>(Math::template Do<T>(value_, Wrapper<R>::value(rhs)));
     return *this;
   }

   template <typename Dst>
   constexpr operator Dst() const {
     return saturated_cast<typename ArithmeticOrUnderlyingEnum<Dst>::type>(
         value_);
   }

   // This method extracts the raw integer value without saturating it to the
   // destination type as the conversion operator does. This is useful when
   // e.g. assigning to an auto type or passing as a deduced template parameter.
   constexpr T RawValue() const { return value_; }

  private:
   T value_;

   // These wrappers allow us to handle state the same way for both
   // ClampedNumeric and POD arithmetic types.
   template <typename Src>
   struct Wrapper {
     static constexpr Src value(Src value) {
       return static_cast<typename UnderlyingType<Src>::type>(value);
     }
   };
 };

 // Convience wrapper to return a new ClampedNumeric from the provided arithmetic
 // or ClampedNumericType.
 template <typename T>
 constexpr ClampedNumeric<typename UnderlyingType<T>::type> MakeClampedNum(
     const T value) {
   return value;
 }

 // Overload the ostream output operator to make logging work nicely.
 template <typename T>
 std::ostream& operator<<(std::ostream& os, const ClampedNumeric<T>& value) {
   os << static_cast<T>(value);
   return os;
 }

 // These implement the variadic wrapper for the math operations.
 template <template <typename, typename, typename> class M,
           typename L,
           typename R>
 constexpr ClampedNumeric<typename MathWrapper<M, L, R>::type> ClampMathOp(
     const L lhs,
     const R rhs) {
   using Math = typename MathWrapper<M, L, R>::math;
   return ClampedNumeric<typename Math::result_type>::template MathOp<M>(lhs,
                                                                         rhs);
 }

 // General purpose wrapper template for arithmetic operations.
 template <template <typename, typename, typename> class M,
           typename L,
           typename R,
           typename... Args>
 constexpr ClampedNumeric<typename ResultType<M, L, R, Args...>::type>
 ClampMathOp(const L lhs, const R rhs, const Args... args) {
   return ClampMathOp<M>(ClampMathOp<M>(lhs, rhs), args...);
 }

 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Add, +, +=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Sub, -, -=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Mul, *, *=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Div, /, /=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Mod, %, %=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Lsh, <<, <<=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Rsh, >>, >>=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, And, &, &=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Or, |, |=)
 BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Xor, ^, ^=)
 BASE_NUMERIC_ARITHMETIC_VARIADIC(Clamped, Clamp, Max)
 BASE_NUMERIC_ARITHMETIC_VARIADIC(Clamped, Clamp, Min)
 BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsLess, <);
 BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsLessOrEqual, <=);
 BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsGreater, >);
 BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsGreaterOrEqual, >=);
 BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsEqual, ==);
 BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsNotEqual, !=);

 }  // namespace internal

 using internal::ClampAdd;
 using internal::ClampAnd;
 using internal::ClampDiv;
 using internal::ClampedNumeric;
 using internal::ClampLsh;
 using internal::ClampMax;
 using internal::ClampMin;
 using internal::ClampMod;
 using internal::ClampMul;
 using internal::ClampOr;
 using internal::ClampRsh;
 using internal::ClampSub;
 using internal::ClampXor;
 using internal::MakeClampedNum;

 }  // namespace base

 #endif  // BASE_NUMERICS_CLAMPED_MATH_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_H_
	#define BASE_NUMERICS_CLAMPED_MATH_H_

	#include <stddef.h>

	#include <limits>
	#include <type_traits>

	#include "base/numerics/clamped_math_impl.h"

	namespace base {
	namespace internal {

	template <typename T>
	class ClampedNumeric {
	static_assert(std::is_arithmetic<T>::value,
	"ClampedNumeric<T>: T must be a numeric type.");

	public:
	using type = T;

	constexpr ClampedNumeric() : value_(0) {}

	// Copy constructor.
	template <typename Src>
	constexpr ClampedNumeric(const ClampedNumeric<Src>& rhs)
	: value_(saturated_cast<T>(rhs.value_)) {}

	template <typename Src>
	friend class ClampedNumeric;

	// This is not an explicit constructor because we implicitly upgrade regular
	// numerics to ClampedNumerics to make them easier to use.
	template <typename Src>
	constexpr ClampedNumeric(Src value) // NOLINT(runtime/explicit)
	: value_(saturated_cast<T>(value)) {
	static_assert(std::is_arithmetic<Src>::value, "Argument must be numeric.");
	}

	// This is not an explicit constructor because we want a seamless conversion
	// from StrictNumeric types.
	template <typename Src>
	constexpr ClampedNumeric(
	StrictNumeric<Src> value) // NOLINT(runtime/explicit)
	: value_(saturated_cast<T>(static_cast<Src>(value))) {}

	// Returns a ClampedNumeric of the specified type, cast from the current
	// ClampedNumeric, and saturated to the destination type.
	template <typename Dst>
	constexpr ClampedNumeric<typename UnderlyingType<Dst>::type> Cast() const {
	return *this;
	}

	// Prototypes for the supported arithmetic operator overloads.
	template <typename Src>
	constexpr ClampedNumeric& operator+=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator-=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator*=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator/=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator%=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator<<=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator>>=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator&=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator\|=(const Src rhs);
	template <typename Src>
	constexpr ClampedNumeric& operator^=(const Src rhs);

	constexpr ClampedNumeric operator-() const {
	// The negation of two's complement int min is int min, so that's the
	// only overflow case where we will saturate.
	return ClampedNumeric<T>(SaturatedNegWrapper(value_));
	}

	constexpr ClampedNumeric operator~() const {
	return ClampedNumeric<decltype(InvertWrapper(T()))>(InvertWrapper(value_));
	}

	constexpr ClampedNumeric Abs() const {
	// The negation of two's complement int min is int min, so that's the
	// only overflow case where we will saturate.
	return ClampedNumeric<T>(SaturatedAbsWrapper(value_));
	}

	template <typename U>
	constexpr ClampedNumeric<typename MathWrapper<ClampedMaxOp, T, U>::type> Max(
	const U rhs) const {
	using result_type = typename MathWrapper<ClampedMaxOp, T, U>::type;
	return ClampedNumeric<result_type>(
	ClampedMaxOp<T, U>::Do(value_, Wrapper<U>::value(rhs)));
	}

	template <typename U>
	constexpr ClampedNumeric<typename MathWrapper<ClampedMinOp, T, U>::type> Min(
	const U rhs) const {
	using result_type = typename MathWrapper<ClampedMinOp, T, U>::type;
	return ClampedNumeric<result_type>(
	ClampedMinOp<T, U>::Do(value_, Wrapper<U>::value(rhs)));
	}

	// 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.
	constexpr ClampedNumeric<typename UnsignedOrFloatForSize<T>::type>
	UnsignedAbs() const {
	return ClampedNumeric<typename UnsignedOrFloatForSize<T>::type>(
	SafeUnsignedAbs(value_));
	}

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

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

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

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

	// These perform the actual math operations on the ClampedNumerics.
	// Binary arithmetic operations.
	template <template <typename, typename, typename> class M,
	typename L,
	typename R>
	static constexpr ClampedNumeric MathOp(const L lhs, const R rhs) {
	using Math = typename MathWrapper<M, L, R>::math;
	return ClampedNumeric<T>(
	Math::template Do<T>(Wrapper<L>::value(lhs), Wrapper<R>::value(rhs)));
	}

	// Assignment arithmetic operations.
	template <template <typename, typename, typename> class M, typename R>
	constexpr ClampedNumeric& MathOp(const R rhs) {
	using Math = typename MathWrapper<M, T, R>::math;
	*this =
	ClampedNumeric<T>(Math::template Do<T>(value_, Wrapper<R>::value(rhs)));
	return *this;
	}

	template <typename Dst>
	constexpr operator Dst() const {
	return saturated_cast<typename ArithmeticOrUnderlyingEnum<Dst>::type>(
	value_);
	}

	// This method extracts the raw integer value without saturating it to the
	// destination type as the conversion operator does. This is useful when
	// e.g. assigning to an auto type or passing as a deduced template parameter.
	constexpr T RawValue() const { return value_; }

	private:
	T value_;

	// These wrappers allow us to handle state the same way for both
	// ClampedNumeric and POD arithmetic types.
	template <typename Src>
	struct Wrapper {
	static constexpr Src value(Src value) {
	return static_cast<typename UnderlyingType<Src>::type>(value);
	}
	};
	};

	// Convience wrapper to return a new ClampedNumeric from the provided arithmetic
	// or ClampedNumericType.
	template <typename T>
	constexpr ClampedNumeric<typename UnderlyingType<T>::type> MakeClampedNum(
	const T value) {
	return value;
	}

	// Overload the ostream output operator to make logging work nicely.
	template <typename T>
	std::ostream& operator<<(std::ostream& os, const ClampedNumeric<T>& value) {
	os << static_cast<T>(value);
	return os;
	}

	// These implement the variadic wrapper for the math operations.
	template <template <typename, typename, typename> class M,
	typename L,
	typename R>
	constexpr ClampedNumeric<typename MathWrapper<M, L, R>::type> ClampMathOp(
	const L lhs,
	const R rhs) {
	using Math = typename MathWrapper<M, L, R>::math;
	return ClampedNumeric<typename Math::result_type>::template MathOp<M>(lhs,
	rhs);
	}

	// General purpose wrapper template for arithmetic operations.
	template <template <typename, typename, typename> class M,
	typename L,
	typename R,
	typename... Args>
	constexpr ClampedNumeric<typename ResultType<M, L, R, Args...>::type>
	ClampMathOp(const L lhs, const R rhs, const Args... args) {
	return ClampMathOp<M>(ClampMathOp<M>(lhs, rhs), args...);
	}

	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Add, +, +=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Sub, -, -=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Mul, , =)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Div, /, /=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Mod, %, %=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Lsh, <<, <<=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Rsh, >>, >>=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, And, &, &=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Or, \|, \|=)
	BASE_NUMERIC_ARITHMETIC_OPERATORS(Clamped, Clamp, Xor, ^, ^=)
	BASE_NUMERIC_ARITHMETIC_VARIADIC(Clamped, Clamp, Max)
	BASE_NUMERIC_ARITHMETIC_VARIADIC(Clamped, Clamp, Min)
	BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsLess, <);
	BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsLessOrEqual, <=);
	BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsGreater, >);
	BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsGreaterOrEqual, >=);
	BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsEqual, ==);
	BASE_NUMERIC_COMPARISON_OPERATORS(Clamped, IsNotEqual, !=);

	} // namespace internal

	using internal::ClampAdd;
	using internal::ClampAnd;
	using internal::ClampDiv;
	using internal::ClampedNumeric;
	using internal::ClampLsh;
	using internal::ClampMax;
	using internal::ClampMin;
	using internal::ClampMod;
	using internal::ClampMul;
	using internal::ClampOr;
	using internal::ClampRsh;
	using internal::ClampSub;
	using internal::ClampXor;
	using internal::MakeClampedNum;

	} // namespace base

	#endif // BASE_NUMERICS_CLAMPED_MATH_H_