rtc_base/safe_minmax.h - src/webrtc - Git at Google

 /*
  *  Copyright 2017 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 // Minimum and maximum
 // ===================
 //
 //   rtc::SafeMin(x, y)
 //   rtc::SafeMax(x, y)
 //
 // (These are both constexpr.)
 //
 // Accept two arguments of either any two integral or any two floating-point
 // types, and return the smaller and larger value, respectively, with no
 // truncation or wrap-around. If only one of the input types is statically
 // guaranteed to be able to represent the result, the return type is that type;
 // if either one would do, the result type is the smaller type. (One of these
 // two cases always applies.)
 //
 //   * The case with one floating-point and one integral type is not allowed,
 //     because the floating-point type will have greater range, but may not
 //     have sufficient precision to represent the integer value exactly.)
 //
 // Clamp (a.k.a. constrain to a given interval)
 // ============================================
 //
 //   rtc::SafeClamp(x, a, b)
 //
 // Accepts three arguments of any mix of integral types or any mix of
 // floating-point types, and returns the value in the closed interval [a, b]
 // that is closest to x (that is, if x < a it returns a; if x > b it returns b;
 // and if a <= x <= b it returns x). As for SafeMin() and SafeMax(), there is
 // no truncation or wrap-around. The result type
 //
 //   1. is statically guaranteed to be able to represent the result;
 //
 //   2. is no larger than the largest of the three argument types; and
 //
 //   3. has the same signedness as the type of the third argument, if this is
 //      possible without violating the First or Second Law.
 //
 // There is always at least one type that meets criteria 1 and 2. If more than
 // one type meets these criteria equally well, the result type is one of the
 // types that is smallest. Note that unlike SafeMin() and SafeMax(),
 // SafeClamp() will sometimes pick a return type that isn't the type of any of
 // its arguments.
 //
 //   * In this context, a type A is smaller than a type B if it has a smaller
 //     range; that is, if A::max() - A::min() < B::max() - B::min(). For
 //     example, int8_t < int16_t == uint16_t < int32_t, and all integral types
 //     are smaller than all floating-point types.)
 //
 //   * As for SafeMin and SafeMax, mixing integer and floating-point arguments
 //     is not allowed, because floating-point types have greater range than
 //     integer types, but do not have sufficient precision to represent the
 //     values of most integer types exactly.
 //
 // Requesting a specific return type
 // =================================
 //
 // All three functions allow callers to explicitly specify the return type as a
 // template parameter, overriding the default return type. E.g.
 //
 //   rtc::SafeMin<int>(x, y)  // returns an int
 //
 // If the requested type is statically guaranteed to be able to represent the
 // result, then everything's fine, and the return type is as requested. But if
 // the requested type is too small, a static_assert is triggered.

 #ifndef WEBRTC_RTC_BASE_SAFE_MINMAX_H_
 #define WEBRTC_RTC_BASE_SAFE_MINMAX_H_

 #include <limits>
 #include <type_traits>

 #include "webrtc/rtc_base/checks.h"
 #include "webrtc/rtc_base/safe_compare.h"
 #include "webrtc/rtc_base/type_traits.h"

 namespace rtc {

 namespace safe_minmax_impl {

 // Make the range of a type available via something other than a constexpr
 // function, to work around MSVC limitations. See
 // https://blogs.msdn.microsoft.com/vcblog/2015/12/02/partial-support-for-expression-sfinae-in-vs-2015-update-1/
 template <typename T>
 struct Limits {
   static constexpr T lowest = std::numeric_limits<T>::lowest();
   static constexpr T max = std::numeric_limits<T>::max();
 };

 template <typename T, bool is_enum = std::is_enum<T>::value>
 struct UnderlyingType;

 template <typename T>
 struct UnderlyingType<T, false> {
   using type = T;
 };

 template <typename T>
 struct UnderlyingType<T, true> {
   using type = typename std::underlying_type<T>::type;
 };

 // Given two types T1 and T2, find types that can hold the smallest (in
 // ::min_t) and the largest (in ::max_t) of the two values.
 template <typename T1,
           typename T2,
           bool int1 = IsIntlike<T1>::value,
           bool int2 = IsIntlike<T2>::value>
 struct MType {
   static_assert(int1 == int2,
                 "You may not mix integral and floating-point arguments");
 };

 // Specialization for when neither type is integral (and therefore presumably
 // floating-point).
 template <typename T1, typename T2>
 struct MType<T1, T2, false, false> {
   using min_t = typename std::common_type<T1, T2>::type;
   static_assert(std::is_same<min_t, T1>::value ||
                     std::is_same<min_t, T2>::value,
                 "");

   using max_t = typename std::common_type<T1, T2>::type;
   static_assert(std::is_same<max_t, T1>::value ||
                     std::is_same<max_t, T2>::value,
                 "");
 };

 // Specialization for when both types are integral.
 template <typename T1, typename T2>
 struct MType<T1, T2, true, true> {
   // The type with the lowest minimum value. In case of a tie, the type with
   // the lowest maximum value. In case that too is a tie, the types have the
   // same range, and we arbitrarily pick T1.
   using min_t = typename std::conditional<
       SafeLt(Limits<T1>::lowest, Limits<T2>::lowest),
       T1,
       typename std::conditional<
           SafeGt(Limits<T1>::lowest, Limits<T2>::lowest),
           T2,
           typename std::conditional<SafeLe(Limits<T1>::max, Limits<T2>::max),
                                     T1,
                                     T2>::type>::type>::type;
   static_assert(std::is_same<min_t, T1>::value ||
                     std::is_same<min_t, T2>::value,
                 "");

   // The type with the highest maximum value. In case of a tie, the types have
   // the same range (because in C++, integer types with the same maximum also
   // have the same minimum).
   static_assert(SafeNe(Limits<T1>::max, Limits<T2>::max) ||
                     SafeEq(Limits<T1>::lowest, Limits<T2>::lowest),
                 "integer types with the same max should have the same min");
   using max_t = typename std::
       conditional<SafeGe(Limits<T1>::max, Limits<T2>::max), T1, T2>::type;
   static_assert(std::is_same<max_t, T1>::value ||
                     std::is_same<max_t, T2>::value,
                 "");
 };

 // A dummy type that we pass around at compile time but never actually use.
 // Declared but not defined.
 struct DefaultType;

 // ::type is A, except we fall back to B if A is DefaultType. We static_assert
 // that the chosen type can hold all values that B can hold.
 template <typename A, typename B>
 struct TypeOr {
   using type = typename std::
       conditional<std::is_same<A, DefaultType>::value, B, A>::type;
   static_assert(SafeLe(Limits<type>::lowest, Limits<B>::lowest) &&
                     SafeGe(Limits<type>::max, Limits<B>::max),
                 "The specified type isn't large enough");
   static_assert(IsIntlike<type>::value == IsIntlike<B>::value &&
                     std::is_floating_point<type>::value ==
                         std::is_floating_point<type>::value,
                 "float<->int conversions not allowed");
 };

 }  // namespace safe_minmax_impl

 template <
     typename R = safe_minmax_impl::DefaultType,
     typename T1 = safe_minmax_impl::DefaultType,
     typename T2 = safe_minmax_impl::DefaultType,
     typename R2 = typename safe_minmax_impl::TypeOr<
         R,
         typename safe_minmax_impl::MType<
             typename safe_minmax_impl::UnderlyingType<T1>::type,
             typename safe_minmax_impl::UnderlyingType<T2>::type>::min_t>::type>
 constexpr R2 SafeMin(T1 a, T2 b) {
   static_assert(IsIntlike<T1>::value || std::is_floating_point<T1>::value,
                 "The first argument must be integral or floating-point");
   static_assert(IsIntlike<T2>::value || std::is_floating_point<T2>::value,
                 "The second argument must be integral or floating-point");
   return SafeLt(a, b) ? static_cast<R2>(a) : static_cast<R2>(b);
 }

 template <
     typename R = safe_minmax_impl::DefaultType,
     typename T1 = safe_minmax_impl::DefaultType,
     typename T2 = safe_minmax_impl::DefaultType,
     typename R2 = typename safe_minmax_impl::TypeOr<
         R,
         typename safe_minmax_impl::MType<
             typename safe_minmax_impl::UnderlyingType<T1>::type,
             typename safe_minmax_impl::UnderlyingType<T2>::type>::max_t>::type>
 constexpr R2 SafeMax(T1 a, T2 b) {
   static_assert(IsIntlike<T1>::value || std::is_floating_point<T1>::value,
                 "The first argument must be integral or floating-point");
   static_assert(IsIntlike<T2>::value || std::is_floating_point<T2>::value,
                 "The second argument must be integral or floating-point");
   return SafeGt(a, b) ? static_cast<R2>(a) : static_cast<R2>(b);
 }

 namespace safe_minmax_impl {

 // Given three types T, L, and H, let ::type be a suitable return value for
 // SafeClamp(T, L, H). See the docs at the top of this file for details.
 template <typename T,
           typename L,
           typename H,
           bool int1 = IsIntlike<T>::value,
           bool int2 = IsIntlike<L>::value,
           bool int3 = IsIntlike<H>::value>
 struct ClampType {
   static_assert(int1 == int2 && int1 == int3,
                 "You may not mix integral and floating-point arguments");
 };

 // Specialization for when all three types are floating-point.
 template <typename T, typename L, typename H>
 struct ClampType<T, L, H, false, false, false> {
   using type = typename std::common_type<T, L, H>::type;
 };

 // Specialization for when all three types are integral.
 template <typename T, typename L, typename H>
 struct ClampType<T, L, H, true, true, true> {
  private:
   // Range of the return value. The return type must be able to represent this
   // full range.
   static constexpr auto r_min =
       SafeMax(Limits<L>::lowest, SafeMin(Limits<H>::lowest, Limits<T>::lowest));
   static constexpr auto r_max =
       SafeMin(Limits<H>::max, SafeMax(Limits<L>::max, Limits<T>::max));

   // Is the given type an acceptable return type? (That is, can it represent
   // all possible return values, and is it no larger than the largest of the
   // input types?)
   template <typename A>
   struct AcceptableType {
    private:
     static constexpr bool not_too_large = sizeof(A) <= sizeof(L) ||
                                           sizeof(A) <= sizeof(H) ||
                                           sizeof(A) <= sizeof(T);
     static constexpr bool range_contained =
         SafeLe(Limits<A>::lowest, r_min) && SafeLe(r_max, Limits<A>::max);

    public:
     static constexpr bool value = not_too_large && range_contained;
   };

   using best_signed_type = typename std::conditional<
       AcceptableType<int8_t>::value,
       int8_t,
       typename std::conditional<
           AcceptableType<int16_t>::value,
           int16_t,
           typename std::conditional<AcceptableType<int32_t>::value,
                                     int32_t,
                                     int64_t>::type>::type>::type;

   using best_unsigned_type = typename std::conditional<
       AcceptableType<uint8_t>::value,
       uint8_t,
       typename std::conditional<
           AcceptableType<uint16_t>::value,
           uint16_t,
           typename std::conditional<AcceptableType<uint32_t>::value,
                                     uint32_t,
                                     uint64_t>::type>::type>::type;

  public:
   // Pick the best type, preferring the same signedness as T but falling back
   // to the other one if necessary.
   using type = typename std::conditional<
       std::is_signed<T>::value,
       typename std::conditional<AcceptableType<best_signed_type>::value,
                                 best_signed_type,
                                 best_unsigned_type>::type,
       typename std::conditional<AcceptableType<best_unsigned_type>::value,
                                 best_unsigned_type,
                                 best_signed_type>::type>::type;
   static_assert(AcceptableType<type>::value, "");
 };

 }  // namespace safe_minmax_impl

 template <
     typename R = safe_minmax_impl::DefaultType,
     typename T = safe_minmax_impl::DefaultType,
     typename L = safe_minmax_impl::DefaultType,
     typename H = safe_minmax_impl::DefaultType,
     typename R2 = typename safe_minmax_impl::TypeOr<
         R,
         typename safe_minmax_impl::ClampType<
             typename safe_minmax_impl::UnderlyingType<T>::type,
             typename safe_minmax_impl::UnderlyingType<L>::type,
             typename safe_minmax_impl::UnderlyingType<H>::type>::type>::type>
 R2 SafeClamp(T x, L min, H max) {
   static_assert(IsIntlike<H>::value || std::is_floating_point<H>::value,
                 "The first argument must be integral or floating-point");
   static_assert(IsIntlike<T>::value || std::is_floating_point<T>::value,
                 "The second argument must be integral or floating-point");
   static_assert(IsIntlike<L>::value || std::is_floating_point<L>::value,
                 "The third argument must be integral or floating-point");
   RTC_DCHECK_LE(min, max);
   return SafeLe(x, min)
              ? static_cast<R2>(min)
              : SafeGe(x, max) ? static_cast<R2>(max) : static_cast<R2>(x);
 }

 }  // namespace rtc

 #endif  // WEBRTC_RTC_BASE_SAFE_MINMAX_H_
	/*
	* Copyright 2017 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	// Minimum and maximum
	// ===================
	//
	// rtc::SafeMin(x, y)
	// rtc::SafeMax(x, y)
	//
	// (These are both constexpr.)
	//
	// Accept two arguments of either any two integral or any two floating-point
	// types, and return the smaller and larger value, respectively, with no
	// truncation or wrap-around. If only one of the input types is statically
	// guaranteed to be able to represent the result, the return type is that type;
	// if either one would do, the result type is the smaller type. (One of these
	// two cases always applies.)
	//
	// * The case with one floating-point and one integral type is not allowed,
	// because the floating-point type will have greater range, but may not
	// have sufficient precision to represent the integer value exactly.)
	//
	// Clamp (a.k.a. constrain to a given interval)
	// ============================================
	//
	// rtc::SafeClamp(x, a, b)
	//
	// Accepts three arguments of any mix of integral types or any mix of
	// floating-point types, and returns the value in the closed interval [a, b]
	// that is closest to x (that is, if x < a it returns a; if x > b it returns b;
	// and if a <= x <= b it returns x). As for SafeMin() and SafeMax(), there is
	// no truncation or wrap-around. The result type
	//
	// 1. is statically guaranteed to be able to represent the result;
	//
	// 2. is no larger than the largest of the three argument types; and
	//
	// 3. has the same signedness as the type of the third argument, if this is
	// possible without violating the First or Second Law.
	//
	// There is always at least one type that meets criteria 1 and 2. If more than
	// one type meets these criteria equally well, the result type is one of the
	// types that is smallest. Note that unlike SafeMin() and SafeMax(),
	// SafeClamp() will sometimes pick a return type that isn't the type of any of
	// its arguments.
	//
	// * In this context, a type A is smaller than a type B if it has a smaller
	// range; that is, if A::max() - A::min() < B::max() - B::min(). For
	// example, int8_t < int16_t == uint16_t < int32_t, and all integral types
	// are smaller than all floating-point types.)
	//
	// * As for SafeMin and SafeMax, mixing integer and floating-point arguments
	// is not allowed, because floating-point types have greater range than
	// integer types, but do not have sufficient precision to represent the
	// values of most integer types exactly.
	//
	// Requesting a specific return type
	// =================================
	//
	// All three functions allow callers to explicitly specify the return type as a
	// template parameter, overriding the default return type. E.g.
	//
	// rtc::SafeMin<int>(x, y) // returns an int
	//
	// If the requested type is statically guaranteed to be able to represent the
	// result, then everything's fine, and the return type is as requested. But if
	// the requested type is too small, a static_assert is triggered.

	#ifndef WEBRTC_RTC_BASE_SAFE_MINMAX_H_
	#define WEBRTC_RTC_BASE_SAFE_MINMAX_H_

	#include <limits>
	#include <type_traits>

	#include "webrtc/rtc_base/checks.h"
	#include "webrtc/rtc_base/safe_compare.h"
	#include "webrtc/rtc_base/type_traits.h"

	namespace rtc {

	namespace safe_minmax_impl {

	// Make the range of a type available via something other than a constexpr
	// function, to work around MSVC limitations. See
	// https://blogs.msdn.microsoft.com/vcblog/2015/12/02/partial-support-for-expression-sfinae-in-vs-2015-update-1/
	template <typename T>
	struct Limits {
	static constexpr T lowest = std::numeric_limits<T>::lowest();
	static constexpr T max = std::numeric_limits<T>::max();
	};

	template <typename T, bool is_enum = std::is_enum<T>::value>
	struct UnderlyingType;

	template <typename T>
	struct UnderlyingType<T, false> {
	using type = T;
	};

	template <typename T>
	struct UnderlyingType<T, true> {
	using type = typename std::underlying_type<T>::type;
	};

	// Given two types T1 and T2, find types that can hold the smallest (in
	// ::min_t) and the largest (in ::max_t) of the two values.
	template <typename T1,
	typename T2,
	bool int1 = IsIntlike<T1>::value,
	bool int2 = IsIntlike<T2>::value>
	struct MType {
	static_assert(int1 == int2,
	"You may not mix integral and floating-point arguments");
	};

	// Specialization for when neither type is integral (and therefore presumably
	// floating-point).
	template <typename T1, typename T2>
	struct MType<T1, T2, false, false> {
	using min_t = typename std::common_type<T1, T2>::type;
	static_assert(std::is_same<min_t, T1>::value \|\|
	std::is_same<min_t, T2>::value,
	"");

	using max_t = typename std::common_type<T1, T2>::type;
	static_assert(std::is_same<max_t, T1>::value \|\|
	std::is_same<max_t, T2>::value,
	"");
	};

	// Specialization for when both types are integral.
	template <typename T1, typename T2>
	struct MType<T1, T2, true, true> {
	// The type with the lowest minimum value. In case of a tie, the type with
	// the lowest maximum value. In case that too is a tie, the types have the
	// same range, and we arbitrarily pick T1.
	using min_t = typename std::conditional<
	SafeLt(Limits<T1>::lowest, Limits<T2>::lowest),
	T1,
	typename std::conditional<
	SafeGt(Limits<T1>::lowest, Limits<T2>::lowest),
	T2,
	typename std::conditional<SafeLe(Limits<T1>::max, Limits<T2>::max),
	T1,
	T2>::type>::type>::type;
	static_assert(std::is_same<min_t, T1>::value \|\|
	std::is_same<min_t, T2>::value,
	"");

	// The type with the highest maximum value. In case of a tie, the types have
	// the same range (because in C++, integer types with the same maximum also
	// have the same minimum).
	static_assert(SafeNe(Limits<T1>::max, Limits<T2>::max) \|\|
	SafeEq(Limits<T1>::lowest, Limits<T2>::lowest),
	"integer types with the same max should have the same min");
	using max_t = typename std::
	conditional<SafeGe(Limits<T1>::max, Limits<T2>::max), T1, T2>::type;
	static_assert(std::is_same<max_t, T1>::value \|\|
	std::is_same<max_t, T2>::value,
	"");
	};

	// A dummy type that we pass around at compile time but never actually use.
	// Declared but not defined.
	struct DefaultType;

	// ::type is A, except we fall back to B if A is DefaultType. We static_assert
	// that the chosen type can hold all values that B can hold.
	template <typename A, typename B>
	struct TypeOr {
	using type = typename std::
	conditional<std::is_same<A, DefaultType>::value, B, A>::type;
	static_assert(SafeLe(Limits<type>::lowest, Limits<B>::lowest) &&
	SafeGe(Limits<type>::max, Limits<B>::max),
	"The specified type isn't large enough");
	static_assert(IsIntlike<type>::value == IsIntlike<B>::value &&
	std::is_floating_point<type>::value ==
	std::is_floating_point<type>::value,
	"float<->int conversions not allowed");
	};

	} // namespace safe_minmax_impl

	template <
	typename R = safe_minmax_impl::DefaultType,
	typename T1 = safe_minmax_impl::DefaultType,
	typename T2 = safe_minmax_impl::DefaultType,
	typename R2 = typename safe_minmax_impl::TypeOr<
	R,
	typename safe_minmax_impl::MType<
	typename safe_minmax_impl::UnderlyingType<T1>::type,
	typename safe_minmax_impl::UnderlyingType<T2>::type>::min_t>::type>
	constexpr R2 SafeMin(T1 a, T2 b) {
	static_assert(IsIntlike<T1>::value \|\| std::is_floating_point<T1>::value,
	"The first argument must be integral or floating-point");
	static_assert(IsIntlike<T2>::value \|\| std::is_floating_point<T2>::value,
	"The second argument must be integral or floating-point");
	return SafeLt(a, b) ? static_cast<R2>(a) : static_cast<R2>(b);
	}

	template <
	typename R = safe_minmax_impl::DefaultType,
	typename T1 = safe_minmax_impl::DefaultType,
	typename T2 = safe_minmax_impl::DefaultType,
	typename R2 = typename safe_minmax_impl::TypeOr<
	R,
	typename safe_minmax_impl::MType<
	typename safe_minmax_impl::UnderlyingType<T1>::type,
	typename safe_minmax_impl::UnderlyingType<T2>::type>::max_t>::type>
	constexpr R2 SafeMax(T1 a, T2 b) {
	static_assert(IsIntlike<T1>::value \|\| std::is_floating_point<T1>::value,
	"The first argument must be integral or floating-point");
	static_assert(IsIntlike<T2>::value \|\| std::is_floating_point<T2>::value,
	"The second argument must be integral or floating-point");
	return SafeGt(a, b) ? static_cast<R2>(a) : static_cast<R2>(b);
	}

	namespace safe_minmax_impl {

	// Given three types T, L, and H, let ::type be a suitable return value for
	// SafeClamp(T, L, H). See the docs at the top of this file for details.
	template <typename T,
	typename L,
	typename H,
	bool int1 = IsIntlike<T>::value,
	bool int2 = IsIntlike<L>::value,
	bool int3 = IsIntlike<H>::value>
	struct ClampType {
	static_assert(int1 == int2 && int1 == int3,
	"You may not mix integral and floating-point arguments");
	};

	// Specialization for when all three types are floating-point.
	template <typename T, typename L, typename H>
	struct ClampType<T, L, H, false, false, false> {
	using type = typename std::common_type<T, L, H>::type;
	};

	// Specialization for when all three types are integral.
	template <typename T, typename L, typename H>
	struct ClampType<T, L, H, true, true, true> {
	private:
	// Range of the return value. The return type must be able to represent this
	// full range.
	static constexpr auto r_min =
	SafeMax(Limits<L>::lowest, SafeMin(Limits<H>::lowest, Limits<T>::lowest));
	static constexpr auto r_max =
	SafeMin(Limits<H>::max, SafeMax(Limits<L>::max, Limits<T>::max));

	// Is the given type an acceptable return type? (That is, can it represent
	// all possible return values, and is it no larger than the largest of the
	// input types?)
	template <typename A>
	struct AcceptableType {
	private:
	static constexpr bool not_too_large = sizeof(A) <= sizeof(L) \|\|
	sizeof(A) <= sizeof(H) \|\|
	sizeof(A) <= sizeof(T);
	static constexpr bool range_contained =
	SafeLe(Limits<A>::lowest, r_min) && SafeLe(r_max, Limits<A>::max);

	public:
	static constexpr bool value = not_too_large && range_contained;
	};

	using best_signed_type = typename std::conditional<
	AcceptableType<int8_t>::value,
	int8_t,
	typename std::conditional<
	AcceptableType<int16_t>::value,
	int16_t,
	typename std::conditional<AcceptableType<int32_t>::value,
	int32_t,
	int64_t>::type>::type>::type;

	using best_unsigned_type = typename std::conditional<
	AcceptableType<uint8_t>::value,
	uint8_t,
	typename std::conditional<
	AcceptableType<uint16_t>::value,
	uint16_t,
	typename std::conditional<AcceptableType<uint32_t>::value,
	uint32_t,
	uint64_t>::type>::type>::type;

	public:
	// Pick the best type, preferring the same signedness as T but falling back
	// to the other one if necessary.
	using type = typename std::conditional<
	std::is_signed<T>::value,
	typename std::conditional<AcceptableType<best_signed_type>::value,
	best_signed_type,
	best_unsigned_type>::type,
	typename std::conditional<AcceptableType<best_unsigned_type>::value,
	best_unsigned_type,
	best_signed_type>::type>::type;
	static_assert(AcceptableType<type>::value, "");
	};

	} // namespace safe_minmax_impl

	template <
	typename R = safe_minmax_impl::DefaultType,
	typename T = safe_minmax_impl::DefaultType,
	typename L = safe_minmax_impl::DefaultType,
	typename H = safe_minmax_impl::DefaultType,
	typename R2 = typename safe_minmax_impl::TypeOr<
	R,
	typename safe_minmax_impl::ClampType<
	typename safe_minmax_impl::UnderlyingType<T>::type,
	typename safe_minmax_impl::UnderlyingType<L>::type,
	typename safe_minmax_impl::UnderlyingType<H>::type>::type>::type>
	R2 SafeClamp(T x, L min, H max) {
	static_assert(IsIntlike<H>::value \|\| std::is_floating_point<H>::value,
	"The first argument must be integral or floating-point");
	static_assert(IsIntlike<T>::value \|\| std::is_floating_point<T>::value,
	"The second argument must be integral or floating-point");
	static_assert(IsIntlike<L>::value \|\| std::is_floating_point<L>::value,
	"The third argument must be integral or floating-point");
	RTC_DCHECK_LE(min, max);
	return SafeLe(x, min)
	? static_cast<R2>(min)
	: SafeGe(x, max) ? static_cast<R2>(max) : static_cast<R2>(x);
	}

	} // namespace rtc

	#endif // WEBRTC_RTC_BASE_SAFE_MINMAX_H_