quic/core/quic_interval.h - quiche - Git at Google

 // Copyright (c) 2019 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 QUICHE_QUIC_CORE_QUIC_INTERVAL_H_
 #define QUICHE_QUIC_CORE_QUIC_INTERVAL_H_

 // An QuicInterval<T> is a data structure used to represent a contiguous,
 // mutable range over an ordered type T. Supported operations include testing a
 // value to see whether it is included in the QuicInterval, comparing two
 // QuicIntervals, and performing their union, intersection, and difference. For
 // the purposes of this library, an "ordered type" is any type that induces a
 // total order on its values via its less-than operator (operator<()). Examples
 // of such types are basic arithmetic types like int and double as well as class
 // types like string.
 //
 // An QuicInterval<T> is represented using the usual C++ STL convention, namely
 // as the half-open QuicInterval [min, max). A point p is considered to be
 // contained in the QuicInterval iff p >= min && p < max. One consequence of
 // this definition is that for any non-empty QuicInterval, min is contained in
 // the QuicInterval but max is not. There is no canonical representation for the
 // empty QuicInterval; rather, any QuicInterval where max <= min is regarded as
 // empty. As a consequence, two empty QuicIntervals will still compare as equal
 // despite possibly having different underlying min() or max() values. Also
 // beware of the terminology used here: the library uses the terms "min" and
 // "max" rather than "begin" and "end" as is conventional for the STL.
 //
 // T is required to be default- and copy-constructable, to have an assignment
 // operator, and the full complement of comparison operators (<, <=, ==, !=, >=,
 // >).  A difference operator (operator-()) is required if
 // QuicInterval<T>::Length is used.
 //
 // QuicInterval supports operator==. Two QuicIntervals are considered equal if
 // either they are both empty or if their corresponding min and max fields
 // compare equal. QuicInterval also provides an operator<. Unfortunately,
 // operator< is currently buggy because its behavior is inconsistent with
 // operator==: two empty ranges with different representations may be regarded
 // as equal by operator== but regarded as different by operator<. Bug 9240050
 // has been created to address this.
 //
 //
 // Examples:
 //   QuicInterval<int> r1(0, 100);  // The QuicInterval [0, 100).
 //   EXPECT_TRUE(r1.Contains(0));
 //   EXPECT_TRUE(r1.Contains(50));
 //   EXPECT_FALSE(r1.Contains(100));  // 100 is just outside the QuicInterval.
 //
 //   QuicInterval<int> r2(50, 150);  // The QuicInterval [50, 150).
 //   EXPECT_TRUE(r1.Intersects(r2));
 //   EXPECT_FALSE(r1.Contains(r2));
 //   EXPECT_TRUE(r1.IntersectWith(r2));  // Mutates r1.
 //   EXPECT_EQ(QuicInterval<int>(50, 100), r1);  // r1 is now [50, 100).
 //
 //   QuicInterval<int> r3(1000, 2000);  // The QuicInterval [1000, 2000).
 //   EXPECT_TRUE(r1.IntersectWith(r3));  // Mutates r1.
 //   EXPECT_TRUE(r1.Empty());  // Now r1 is empty.
 //   EXPECT_FALSE(r1.Contains(r1.min()));  // e.g. doesn't contain its own min.

 #include <stddef.h>
 #include <algorithm>
 #include <ostream>
 #include <type_traits>
 #include <utility>
 #include <vector>

 #include "quic/platform/api/quic_export.h"

 namespace quic {

 template <typename T>
 class QUIC_NO_EXPORT QuicInterval {
  private:
   // Type trait for deriving the return type for QuicInterval::Length.  If
   // operator-() is not defined for T, then the return type is void.  This makes
   // the signature for Length compile so that the class can be used for such T,
   // but code that calls Length would still generate a compilation error.
   template <typename U>
   class QUIC_NO_EXPORT DiffTypeOrVoid {
    private:
     template <typename V>
     static auto f(const V* v) -> decltype(*v - *v);
     template <typename V>
     static void f(...);

    public:
     using type = typename std::decay<decltype(f<U>(nullptr))>::type;
   };

  public:
   // Construct an QuicInterval representing an empty QuicInterval.
   QuicInterval() : min_(), max_() {}

   // Construct an QuicInterval representing the QuicInterval [min, max). If min
   // < max, the constructed object will represent the non-empty QuicInterval
   // containing all values from min up to (but not including) max. On the other
   // hand, if min >= max, the constructed object will represent the empty
   // QuicInterval.
   QuicInterval(const T& min, const T& max) : min_(min), max_(max) {}

   template <typename U1,
             typename U2,
             typename = typename std::enable_if<
                 std::is_convertible<U1, T>::value &&
                 std::is_convertible<U2, T>::value>::type>
   QuicInterval(U1&& min, U2&& max)
       : min_(std::forward<U1>(min)), max_(std::forward<U2>(max)) {}

   const T& min() const { return min_; }
   const T& max() const { return max_; }
   void SetMin(const T& t) { min_ = t; }
   void SetMax(const T& t) { max_ = t; }

   void Set(const T& min, const T& max) {
     SetMin(min);
     SetMax(max);
   }

   void Clear() { *this = {}; }

   bool Empty() const { return min() >= max(); }

   // Returns the length of this QuicInterval. The value returned is zero if
   // Empty() is true; otherwise the value returned is max() - min().
   typename DiffTypeOrVoid<T>::type Length() const {
     return (Empty() ? min() : max()) - min();
   }

   // Returns true iff t >= min() && t < max().
   bool Contains(const T& t) const { return min() <= t && max() > t; }

   // Returns true iff *this and i are non-empty, and *this includes i. "*this
   // includes i" means that for all t, if i.Contains(t) then this->Contains(t).
   // Note the unintuitive consequence of this definition: this method always
   // returns false when i is the empty QuicInterval.
   bool Contains(const QuicInterval& i) const {
     return !Empty() && !i.Empty() && min() <= i.min() && max() >= i.max();
   }

   // Returns true iff there exists some point t for which this->Contains(t) &&
   // i.Contains(t) evaluates to true, i.e. if the intersection is non-empty.
   bool Intersects(const QuicInterval& i) const {
     return !Empty() && !i.Empty() && min() < i.max() && max() > i.min();
   }

   // Returns true iff there exists some point t for which this->Contains(t) &&
   // i.Contains(t) evaluates to true, i.e. if the intersection is non-empty.
   // Furthermore, if the intersection is non-empty and the out pointer is not
   // null, this method stores the calculated intersection in *out.
   bool Intersects(const QuicInterval& i, QuicInterval* out) const;

   // Sets *this to be the intersection of itself with i. Returns true iff
   // *this was modified.
   bool IntersectWith(const QuicInterval& i);

   // Returns true iff this and other have disjoint closures.  For nonempty
   // intervals, that means there is at least one point between this and other.
   // Roughly speaking that means the intervals don't intersect, and they are not
   // adjacent.   Empty intervals are always separated from any other interval.
   bool Separated(const QuicInterval& other) const {
     if (Empty() || other.Empty())
       return true;
     return other.max() < min() || max() < other.min();
   }

   // Calculates the smallest QuicInterval containing both *this i, and updates
   // *this to represent that QuicInterval, and returns true iff *this was
   // modified.
   bool SpanningUnion(const QuicInterval& i);

   // Determines the difference between two QuicIntervals by finding all points
   // that are contained in *this but not in i, coalesces those points into the
   // largest possible contiguous QuicIntervals, and appends those QuicIntervals
   // to the *difference vector. Intuitively this can be thought of as "erasing"
   // i from *this. This will either completely erase *this (leaving nothing
   // behind), partially erase some of *this from the left or right side (leaving
   // some residual behind), or erase a hole in the middle of *this (leaving
   // behind an QuicInterval on either side). Therefore, 0, 1, or 2 QuicIntervals
   // will be appended to *difference. The method returns true iff the
   // intersection of *this and i is non-empty. The caller owns the vector and
   // the QuicInterval* pointers inside it. The difference vector is required to
   // be non-null.
   bool Difference(const QuicInterval& i,
                   std::vector<QuicInterval*>* difference) const;

   // Determines the difference between two QuicIntervals as in
   // Difference(QuicInterval&, vector*), but stores the results directly in out
   // parameters rather than dynamically allocating an QuicInterval* and
   // appending it to a vector. If two results are generated, the one with the
   // smaller value of min() will be stored in *lo and the other in *hi.
   // Otherwise (if fewer than two results are generated), unused arguments will
   // be set to the empty QuicInterval (it is possible that *lo will be empty and
   // *hi non-empty). The method returns true iff the intersection of *this and i
   // is non-empty.
   bool Difference(const QuicInterval& i,
                   QuicInterval* lo,
                   QuicInterval* hi) const;

   friend bool operator==(const QuicInterval& a, const QuicInterval& b) {
     bool ae = a.Empty();
     bool be = b.Empty();
     if (ae && be)
       return true;  // All empties are equal.
     if (ae != be)
       return false;  // Empty cannot equal nonempty.
     return a.min() == b.min() && a.max() == b.max();
   }

   friend bool operator!=(const QuicInterval& a, const QuicInterval& b) {
     return !(a == b);
   }

   // Defines a comparator which can be used to induce an order on QuicIntervals,
   // so that, for example, they can be stored in an ordered container such as
   // std::set. The ordering is arbitrary, but does provide the guarantee that,
   // for non-empty QuicIntervals X and Y, if X contains Y, then X <= Y.
   // TODO(kosak): The current implementation of this comparator has a problem
   // because the ordering it induces is inconsistent with that of Equals(). In
   // particular, this comparator does not properly consider all empty
   // QuicIntervals equivalent. Bug 9240050 has been created to track this.
   friend bool operator<(const QuicInterval& a, const QuicInterval& b) {
     return a.min() < b.min() || (!(b.min() < a.min()) && b.max() < a.max());
   }

  private:
   T min_;  // Inclusive lower bound.
   T max_;  // Exclusive upper bound.
 };

 // Constructs an QuicInterval by deducing the types from the function arguments.
 template <typename T>
 QuicInterval<T> MakeQuicInterval(T&& lhs, T&& rhs) {
   return QuicInterval<T>(std::forward<T>(lhs), std::forward<T>(rhs));
 }

 // Note: ideally we'd use
 //   decltype(out << "[" << i.min() << ", " << i.max() << ")")
 // as return type of the function, but as of July 2017 this triggers g++
 // "sorry, unimplemented: string literal in function template signature" error.
 template <typename T>
 auto operator<<(std::ostream& out, const QuicInterval<T>& i)
     -> decltype(out << i.min()) {
   return out << "[" << i.min() << ", " << i.max() << ")";
 }

 //==============================================================================
 // Implementation details: Clients can stop reading here.

 template <typename T>
 bool QuicInterval<T>::Intersects(const QuicInterval& i,
                                  QuicInterval* out) const {
   if (!Intersects(i))
     return false;
   if (out != nullptr) {
     *out = QuicInterval(std::max(min(), i.min()), std::min(max(), i.max()));
   }
   return true;
 }

 template <typename T>
 bool QuicInterval<T>::IntersectWith(const QuicInterval& i) {
   if (Empty())
     return false;
   bool modified = false;
   if (i.min() > min()) {
     SetMin(i.min());
     modified = true;
   }
   if (i.max() < max()) {
     SetMax(i.max());
     modified = true;
   }
   return modified;
 }

 template <typename T>
 bool QuicInterval<T>::SpanningUnion(const QuicInterval& i) {
   if (i.Empty())
     return false;
   if (Empty()) {
     *this = i;
     return true;
   }
   bool modified = false;
   if (i.min() < min()) {
     SetMin(i.min());
     modified = true;
   }
   if (i.max() > max()) {
     SetMax(i.max());
     modified = true;
   }
   return modified;
 }

 template <typename T>
 bool QuicInterval<T>::Difference(const QuicInterval& i,
                                  std::vector<QuicInterval*>* difference) const {
   if (Empty()) {
     // <empty> - <i> = <empty>
     return false;
   }
   if (i.Empty()) {
     // <this> - <empty> = <this>
     difference->push_back(new QuicInterval(*this));
     return false;
   }
   if (min() < i.max() && min() >= i.min() && max() > i.max()) {
     //            [------ this ------)
     // [------ i ------)
     //                 [-- result ---)
     difference->push_back(new QuicInterval(i.max(), max()));
     return true;
   }
   if (max() > i.min() && max() <= i.max() && min() < i.min()) {
     // [------ this ------)
     //            [------ i ------)
     // [- result -)
     difference->push_back(new QuicInterval(min(), i.min()));
     return true;
   }
   if (min() < i.min() && max() > i.max()) {
     // [------- this --------)
     //      [---- i ----)
     // [ R1 )           [ R2 )
     // There are two results: R1 and R2.
     difference->push_back(new QuicInterval(min(), i.min()));
     difference->push_back(new QuicInterval(i.max(), max()));
     return true;
   }
   if (min() >= i.min() && max() <= i.max()) {
     //   [--- this ---)
     // [------ i --------)
     // Intersection is <this>, so difference yields the empty QuicInterval.
     // Nothing is appended to *difference.
     return true;
   }
   // No intersection. Append <this>.
   difference->push_back(new QuicInterval(*this));
   return false;
 }

 template <typename T>
 bool QuicInterval<T>::Difference(const QuicInterval& i,
                                  QuicInterval* lo,
                                  QuicInterval* hi) const {
   // Initialize *lo and *hi to empty
   *lo = {};
   *hi = {};
   if (Empty())
     return false;
   if (i.Empty()) {
     *lo = *this;
     return false;
   }
   if (min() < i.max() && min() >= i.min() && max() > i.max()) {
     //            [------ this ------)
     // [------ i ------)
     //                 [-- result ---)
     *hi = QuicInterval(i.max(), max());
     return true;
   }
   if (max() > i.min() && max() <= i.max() && min() < i.min()) {
     // [------ this ------)
     //            [------ i ------)
     // [- result -)
     *lo = QuicInterval(min(), i.min());
     return true;
   }
   if (min() < i.min() && max() > i.max()) {
     // [------- this --------)
     //      [---- i ----)
     // [ R1 )           [ R2 )
     // There are two results: R1 and R2.
     *lo = QuicInterval(min(), i.min());
     *hi = QuicInterval(i.max(), max());
     return true;
   }
   if (min() >= i.min() && max() <= i.max()) {
     //   [--- this ---)
     // [------ i --------)
     // Intersection is <this>, so difference yields the empty QuicInterval.
     return true;
   }
   *lo = *this;  // No intersection.
   return false;
 }

 }  // namespace quic

 #endif  // QUICHE_QUIC_CORE_QUIC_INTERVAL_H_
	// Copyright (c) 2019 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 QUICHE_QUIC_CORE_QUIC_INTERVAL_H_
	#define QUICHE_QUIC_CORE_QUIC_INTERVAL_H_

	// An QuicInterval<T> is a data structure used to represent a contiguous,
	// mutable range over an ordered type T. Supported operations include testing a
	// value to see whether it is included in the QuicInterval, comparing two
	// QuicIntervals, and performing their union, intersection, and difference. For
	// the purposes of this library, an "ordered type" is any type that induces a
	// total order on its values via its less-than operator (operator<()). Examples
	// of such types are basic arithmetic types like int and double as well as class
	// types like string.
	//
	// An QuicInterval<T> is represented using the usual C++ STL convention, namely
	// as the half-open QuicInterval [min, max). A point p is considered to be
	// contained in the QuicInterval iff p >= min && p < max. One consequence of
	// this definition is that for any non-empty QuicInterval, min is contained in
	// the QuicInterval but max is not. There is no canonical representation for the
	// empty QuicInterval; rather, any QuicInterval where max <= min is regarded as
	// empty. As a consequence, two empty QuicIntervals will still compare as equal
	// despite possibly having different underlying min() or max() values. Also
	// beware of the terminology used here: the library uses the terms "min" and
	// "max" rather than "begin" and "end" as is conventional for the STL.
	//
	// T is required to be default- and copy-constructable, to have an assignment
	// operator, and the full complement of comparison operators (<, <=, ==, !=, >=,
	// >). A difference operator (operator-()) is required if
	// QuicInterval<T>::Length is used.
	//
	// QuicInterval supports operator==. Two QuicIntervals are considered equal if
	// either they are both empty or if their corresponding min and max fields
	// compare equal. QuicInterval also provides an operator<. Unfortunately,
	// operator< is currently buggy because its behavior is inconsistent with
	// operator==: two empty ranges with different representations may be regarded
	// as equal by operator== but regarded as different by operator<. Bug 9240050
	// has been created to address this.
	//
	//
	// Examples:
	// QuicInterval<int> r1(0, 100); // The QuicInterval [0, 100).
	// EXPECT_TRUE(r1.Contains(0));
	// EXPECT_TRUE(r1.Contains(50));
	// EXPECT_FALSE(r1.Contains(100)); // 100 is just outside the QuicInterval.
	//
	// QuicInterval<int> r2(50, 150); // The QuicInterval [50, 150).
	// EXPECT_TRUE(r1.Intersects(r2));
	// EXPECT_FALSE(r1.Contains(r2));
	// EXPECT_TRUE(r1.IntersectWith(r2)); // Mutates r1.
	// EXPECT_EQ(QuicInterval<int>(50, 100), r1); // r1 is now [50, 100).
	//
	// QuicInterval<int> r3(1000, 2000); // The QuicInterval [1000, 2000).
	// EXPECT_TRUE(r1.IntersectWith(r3)); // Mutates r1.
	// EXPECT_TRUE(r1.Empty()); // Now r1 is empty.
	// EXPECT_FALSE(r1.Contains(r1.min())); // e.g. doesn't contain its own min.

	#include <stddef.h>
	#include <algorithm>
	#include <ostream>
	#include <type_traits>
	#include <utility>
	#include <vector>

	#include "quic/platform/api/quic_export.h"

	namespace quic {

	template <typename T>
	class QUIC_NO_EXPORT QuicInterval {
	private:
	// Type trait for deriving the return type for QuicInterval::Length. If
	// operator-() is not defined for T, then the return type is void. This makes
	// the signature for Length compile so that the class can be used for such T,
	// but code that calls Length would still generate a compilation error.
	template <typename U>
	class QUIC_NO_EXPORT DiffTypeOrVoid {
	private:
	template <typename V>
	static auto f(const V* v) -> decltype(v - v);
	template <typename V>
	static void f(...);

	public:
	using type = typename std::decay<decltype(f<U>(nullptr))>::type;
	};

	public:
	// Construct an QuicInterval representing an empty QuicInterval.
	QuicInterval() : min_(), max_() {}

	// Construct an QuicInterval representing the QuicInterval [min, max). If min
	// < max, the constructed object will represent the non-empty QuicInterval
	// containing all values from min up to (but not including) max. On the other
	// hand, if min >= max, the constructed object will represent the empty
	// QuicInterval.
	QuicInterval(const T& min, const T& max) : min_(min), max_(max) {}

	template <typename U1,
	typename U2,
	typename = typename std::enable_if<
	std::is_convertible<U1, T>::value &&
	std::is_convertible<U2, T>::value>::type>
	QuicInterval(U1&& min, U2&& max)
	: min_(std::forward<U1>(min)), max_(std::forward<U2>(max)) {}

	const T& min() const { return min_; }
	const T& max() const { return max_; }
	void SetMin(const T& t) { min_ = t; }
	void SetMax(const T& t) { max_ = t; }

	void Set(const T& min, const T& max) {
	SetMin(min);
	SetMax(max);
	}

	void Clear() { *this = {}; }

	bool Empty() const { return min() >= max(); }

	// Returns the length of this QuicInterval. The value returned is zero if
	// Empty() is true; otherwise the value returned is max() - min().
	typename DiffTypeOrVoid<T>::type Length() const {
	return (Empty() ? min() : max()) - min();
	}

	// Returns true iff t >= min() && t < max().
	bool Contains(const T& t) const { return min() <= t && max() > t; }

	// Returns true iff this and i are non-empty, and this includes i. "*this
	// includes i" means that for all t, if i.Contains(t) then this->Contains(t).
	// Note the unintuitive consequence of this definition: this method always
	// returns false when i is the empty QuicInterval.
	bool Contains(const QuicInterval& i) const {
	return !Empty() && !i.Empty() && min() <= i.min() && max() >= i.max();
	}

	// Returns true iff there exists some point t for which this->Contains(t) &&
	// i.Contains(t) evaluates to true, i.e. if the intersection is non-empty.
	bool Intersects(const QuicInterval& i) const {
	return !Empty() && !i.Empty() && min() < i.max() && max() > i.min();
	}

	// Returns true iff there exists some point t for which this->Contains(t) &&
	// i.Contains(t) evaluates to true, i.e. if the intersection is non-empty.
	// Furthermore, if the intersection is non-empty and the out pointer is not
	// null, this method stores the calculated intersection in *out.
	bool Intersects(const QuicInterval& i, QuicInterval* out) const;

	// Sets *this to be the intersection of itself with i. Returns true iff
	// *this was modified.
	bool IntersectWith(const QuicInterval& i);

	// Returns true iff this and other have disjoint closures. For nonempty
	// intervals, that means there is at least one point between this and other.
	// Roughly speaking that means the intervals don't intersect, and they are not
	// adjacent. Empty intervals are always separated from any other interval.
	bool Separated(const QuicInterval& other) const {
	if (Empty() \|\| other.Empty())
	return true;
	return other.max() < min() \|\| max() < other.min();
	}

	// Calculates the smallest QuicInterval containing both *this i, and updates
	// this to represent that QuicInterval, and returns true iff this was
	// modified.
	bool SpanningUnion(const QuicInterval& i);

	// Determines the difference between two QuicIntervals by finding all points
	// that are contained in *this but not in i, coalesces those points into the
	// largest possible contiguous QuicIntervals, and appends those QuicIntervals
	// to the *difference vector. Intuitively this can be thought of as "erasing"
	// i from this. This will either completely erase this (leaving nothing
	// behind), partially erase some of *this from the left or right side (leaving
	// some residual behind), or erase a hole in the middle of *this (leaving
	// behind an QuicInterval on either side). Therefore, 0, 1, or 2 QuicIntervals
	// will be appended to *difference. The method returns true iff the
	// intersection of *this and i is non-empty. The caller owns the vector and
	// the QuicInterval* pointers inside it. The difference vector is required to
	// be non-null.
	bool Difference(const QuicInterval& i,
	std::vector<QuicInterval> difference) const;

	// Determines the difference between two QuicIntervals as in
	// Difference(QuicInterval&, vector*), but stores the results directly in out
	// parameters rather than dynamically allocating an QuicInterval* and
	// appending it to a vector. If two results are generated, the one with the
	// smaller value of min() will be stored in lo and the other in hi.
	// Otherwise (if fewer than two results are generated), unused arguments will
	// be set to the empty QuicInterval (it is possible that *lo will be empty and
	// hi non-empty). The method returns true iff the intersection of this and i
	// is non-empty.
	bool Difference(const QuicInterval& i,
	QuicInterval* lo,
	QuicInterval* hi) const;

	friend bool operator==(const QuicInterval& a, const QuicInterval& b) {
	bool ae = a.Empty();
	bool be = b.Empty();
	if (ae && be)
	return true; // All empties are equal.
	if (ae != be)
	return false; // Empty cannot equal nonempty.
	return a.min() == b.min() && a.max() == b.max();
	}

	friend bool operator!=(const QuicInterval& a, const QuicInterval& b) {
	return !(a == b);
	}

	// Defines a comparator which can be used to induce an order on QuicIntervals,
	// so that, for example, they can be stored in an ordered container such as
	// std::set. The ordering is arbitrary, but does provide the guarantee that,
	// for non-empty QuicIntervals X and Y, if X contains Y, then X <= Y.
	// TODO(kosak): The current implementation of this comparator has a problem
	// because the ordering it induces is inconsistent with that of Equals(). In
	// particular, this comparator does not properly consider all empty
	// QuicIntervals equivalent. Bug 9240050 has been created to track this.
	friend bool operator<(const QuicInterval& a, const QuicInterval& b) {
	return a.min() < b.min() \|\| (!(b.min() < a.min()) && b.max() < a.max());
	}

	private:
	T min_; // Inclusive lower bound.
	T max_; // Exclusive upper bound.
	};

	// Constructs an QuicInterval by deducing the types from the function arguments.
	template <typename T>
	QuicInterval<T> MakeQuicInterval(T&& lhs, T&& rhs) {
	return QuicInterval<T>(std::forward<T>(lhs), std::forward<T>(rhs));
	}

	// Note: ideally we'd use
	// decltype(out << "[" << i.min() << ", " << i.max() << ")")
	// as return type of the function, but as of July 2017 this triggers g++
	// "sorry, unimplemented: string literal in function template signature" error.
	template <typename T>
	auto operator<<(std::ostream& out, const QuicInterval<T>& i)
	-> decltype(out << i.min()) {
	return out << "[" << i.min() << ", " << i.max() << ")";
	}

	//==============================================================================
	// Implementation details: Clients can stop reading here.

	template <typename T>
	bool QuicInterval<T>::Intersects(const QuicInterval& i,
	QuicInterval* out) const {
	if (!Intersects(i))
	return false;
	if (out != nullptr) {
	*out = QuicInterval(std::max(min(), i.min()), std::min(max(), i.max()));
	}
	return true;
	}

	template <typename T>
	bool QuicInterval<T>::IntersectWith(const QuicInterval& i) {
	if (Empty())
	return false;
	bool modified = false;
	if (i.min() > min()) {
	SetMin(i.min());
	modified = true;
	}
	if (i.max() < max()) {
	SetMax(i.max());
	modified = true;
	}
	return modified;
	}

	template <typename T>
	bool QuicInterval<T>::SpanningUnion(const QuicInterval& i) {
	if (i.Empty())
	return false;
	if (Empty()) {
	*this = i;
	return true;
	}
	bool modified = false;
	if (i.min() < min()) {
	SetMin(i.min());
	modified = true;
	}
	if (i.max() > max()) {
	SetMax(i.max());
	modified = true;
	}
	return modified;
	}

	template <typename T>
	bool QuicInterval<T>::Difference(const QuicInterval& i,
	std::vector<QuicInterval> difference) const {
	if (Empty()) {
	// <empty> - <i> = <empty>
	return false;
	}
	if (i.Empty()) {
	// <this> - <empty> = <this>
	difference->push_back(new QuicInterval(*this));
	return false;
	}
	if (min() < i.max() && min() >= i.min() && max() > i.max()) {
	// [------ this ------)
	// [------ i ------)
	// [-- result ---)
	difference->push_back(new QuicInterval(i.max(), max()));
	return true;
	}
	if (max() > i.min() && max() <= i.max() && min() < i.min()) {
	// [------ this ------)
	// [------ i ------)
	// [- result -)
	difference->push_back(new QuicInterval(min(), i.min()));
	return true;
	}
	if (min() < i.min() && max() > i.max()) {
	// [------- this --------)
	// [---- i ----)
	// [ R1 ) [ R2 )
	// There are two results: R1 and R2.
	difference->push_back(new QuicInterval(min(), i.min()));
	difference->push_back(new QuicInterval(i.max(), max()));
	return true;
	}
	if (min() >= i.min() && max() <= i.max()) {
	// [--- this ---)
	// [------ i --------)
	// Intersection is <this>, so difference yields the empty QuicInterval.
	// Nothing is appended to *difference.
	return true;
	}
	// No intersection. Append <this>.
	difference->push_back(new QuicInterval(*this));
	return false;
	}

	template <typename T>
	bool QuicInterval<T>::Difference(const QuicInterval& i,
	QuicInterval* lo,
	QuicInterval* hi) const {
	// Initialize lo and hi to empty
	*lo = {};
	*hi = {};
	if (Empty())
	return false;
	if (i.Empty()) {
	lo = this;
	return false;
	}
	if (min() < i.max() && min() >= i.min() && max() > i.max()) {
	// [------ this ------)
	// [------ i ------)
	// [-- result ---)
	*hi = QuicInterval(i.max(), max());
	return true;
	}
	if (max() > i.min() && max() <= i.max() && min() < i.min()) {
	// [------ this ------)
	// [------ i ------)
	// [- result -)
	*lo = QuicInterval(min(), i.min());
	return true;
	}
	if (min() < i.min() && max() > i.max()) {
	// [------- this --------)
	// [---- i ----)
	// [ R1 ) [ R2 )
	// There are two results: R1 and R2.
	*lo = QuicInterval(min(), i.min());
	*hi = QuicInterval(i.max(), max());
	return true;
	}
	if (min() >= i.min() && max() <= i.max()) {
	// [--- this ---)
	// [------ i --------)
	// Intersection is <this>, so difference yields the empty QuicInterval.
	return true;
	}
	lo = this; // No intersection.
	return false;
	}

	} // namespace quic

	#endif // QUICHE_QUIC_CORE_QUIC_INTERVAL_H_