api/optional.h - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 /*
  *  Copyright 2015 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.
  */

 #ifndef API_OPTIONAL_H_
 #define API_OPTIONAL_H_

 #include <algorithm>
 #include <memory>
 #include <utility>

 #ifdef UNIT_TEST
 #include <iomanip>
 #include <ostream>
 #endif  // UNIT_TEST

 #include "api/array_view.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/sanitizer.h"

 namespace rtc {

 namespace optional_internal {

 #if RTC_HAS_ASAN

 // This is a non-inlined function. The optimizer can't see inside it.  It
 // prevents the compiler from generating optimized code that reads value_ even
 // if it is unset. Although safe, this causes memory sanitizers to complain.
 const void* FunctionThatDoesNothingImpl(const void*);

 template <typename T>
 inline const T* FunctionThatDoesNothing(T* x) {
   return reinterpret_cast<const T*>(
       FunctionThatDoesNothingImpl(reinterpret_cast<const void*>(x)));
 }

 #else

 template <typename T>
 inline const T* FunctionThatDoesNothing(T* x) {
   return x;
 }

 #endif

 struct NulloptArg;

 }  // namespace optional_internal

 // nullopt_t must be a non-aggregate literal type with a constexpr constructor
 // that takes some implementation-defined literal type. It mustn't have a
 // default constructor nor an initializer-list constructor.
 // See:
 // http://en.cppreference.com/w/cpp/utility/optional/nullopt_t
 // That page uses int, though this seems to confuse older versions of GCC.
 struct nullopt_t {
   constexpr explicit nullopt_t(rtc::optional_internal::NulloptArg&) {}
 };

 // Specification:
 // http://en.cppreference.com/w/cpp/utility/optional/nullopt
 extern const nullopt_t nullopt;

 // Simple std::optional-wannabe. It either contains a T or not.
 //
 // A moved-from Optional<T> may only be destroyed, and assigned to if T allows
 // being assigned to after having been moved from. Specifically, you may not
 // assume that it just doesn't contain a value anymore.
 //
 // Examples of good places to use Optional:
 //
 // - As a class or struct member, when the member doesn't always have a value:
 //     struct Prisoner {
 //       std::string name;
 //       Optional<int> cell_number;  // Empty if not currently incarcerated.
 //     };
 //
 // - As a return value for functions that may fail to return a value on all
 //   allowed inputs. For example, a function that searches an array might
 //   return an Optional<size_t> (the index where it found the element, or
 //   nothing if it didn't find it); and a function that parses numbers might
 //   return Optional<double> (the parsed number, or nothing if parsing failed).
 //
 // Examples of bad places to use Optional:
 //
 // - As a return value for functions that may fail because of disallowed
 //   inputs. For example, a string length function should not return
 //   Optional<size_t> so that it can return nothing in case the caller passed
 //   it a null pointer; the function should probably use RTC_[D]CHECK instead,
 //   and return plain size_t.
 //
 // - As a return value for functions that may fail to return a value on all
 //   allowed inputs, but need to tell the caller what went wrong. Returning
 //   Optional<double> when parsing a single number as in the example above
 //   might make sense, but any larger parse job is probably going to need to
 //   tell the caller what the problem was, not just that there was one.
 //
 // - As a non-mutable function argument. When you want to pass a value of a
 //   type T that can fail to be there, const T* is almost always both fastest
 //   and cleanest. (If you're *sure* that the the caller will always already
 //   have an Optional<T>, const Optional<T>& is slightly faster than const T*,
 //   but this is a micro-optimization. In general, stick to const T*.)
 //
 // TODO(kwiberg): Get rid of this class when the standard library has
 // std::optional (and we're allowed to use it).
 template <typename T>
 class Optional final {
  public:
   // Construct an empty Optional.
   Optional() : has_value_(false), empty_('\0') { PoisonValue(); }

   Optional(rtc::nullopt_t)  // NOLINT(runtime/explicit)
       : Optional() {}

   // Construct an Optional that contains a value.
   Optional(const T& value)  // NOLINT(runtime/explicit)
       : has_value_(true) {
     new (&value_) T(value);
   }
   Optional(T&& value)  // NOLINT(runtime/explicit)
       : has_value_(true) {
     new (&value_) T(std::move(value));
   }

   // Copy constructor: copies the value from m if it has one.
   Optional(const Optional& m) : has_value_(m.has_value_) {
     if (has_value_)
       new (&value_) T(m.value_);
     else
       PoisonValue();
   }

   // Move constructor: if m has a value, moves the value from m, leaving m
   // still in a state where it has a value, but a moved-from one (the
   // properties of which depends on T; the only general guarantee is that we
   // can destroy m).
   Optional(Optional&& m) : has_value_(m.has_value_) {
     if (has_value_)
       new (&value_) T(std::move(m.value_));
     else
       PoisonValue();
   }

   ~Optional() {
     if (has_value_)
       value_.~T();
     else
       UnpoisonValue();
   }

   Optional& operator=(rtc::nullopt_t) {
     reset();
     return *this;
   }

   // Copy assignment. Uses T's copy assignment if both sides have a value, T's
   // copy constructor if only the right-hand side has a value.
   Optional& operator=(const Optional& m) {
     if (m.has_value_) {
       if (has_value_) {
         value_ = m.value_;  // T's copy assignment.
       } else {
         UnpoisonValue();
         new (&value_) T(m.value_);  // T's copy constructor.
         has_value_ = true;
       }
     } else {
       reset();
     }
     return *this;
   }

   // Move assignment. Uses T's move assignment if both sides have a value, T's
   // move constructor if only the right-hand side has a value. The state of m
   // after it's been moved from is as for the move constructor.
   Optional& operator=(Optional&& m) {
     if (m.has_value_) {
       if (has_value_) {
         value_ = std::move(m.value_);  // T's move assignment.
       } else {
         UnpoisonValue();
         new (&value_) T(std::move(m.value_));  // T's move constructor.
         has_value_ = true;
       }
     } else {
       reset();
     }
     return *this;
   }

   // Swap the values if both m1 and m2 have values; move the value if only one
   // of them has one.
   friend void swap(Optional& m1, Optional& m2) {
     if (m1.has_value_) {
       if (m2.has_value_) {
         // Both have values: swap.
         using std::swap;
         swap(m1.value_, m2.value_);
       } else {
         // Only m1 has a value: move it to m2.
         m2.UnpoisonValue();
         new (&m2.value_) T(std::move(m1.value_));
         m1.value_.~T();  // Destroy the moved-from value.
         m1.has_value_ = false;
         m2.has_value_ = true;
         m1.PoisonValue();
       }
     } else if (m2.has_value_) {
       // Only m2 has a value: move it to m1.
       m1.UnpoisonValue();
       new (&m1.value_) T(std::move(m2.value_));
       m2.value_.~T();  // Destroy the moved-from value.
       m1.has_value_ = true;
       m2.has_value_ = false;
       m2.PoisonValue();
     }
   }

   // Destroy any contained value. Has no effect if we have no value.
   void reset() {
     if (!has_value_)
       return;
     value_.~T();
     has_value_ = false;
     PoisonValue();
   }

   template <class... Args>
   void emplace(Args&&... args) {
     if (has_value_)
       value_.~T();
     else
       UnpoisonValue();
     new (&value_) T(std::forward<Args>(args)...);
     has_value_ = true;
   }

   // Conversion to bool to test if we have a value.
   explicit operator bool() const { return has_value_; }
   bool has_value() const { return has_value_; }

   // Dereferencing. Only allowed if we have a value.
   const T* operator->() const {
     RTC_DCHECK(has_value_);
     return &value_;
   }
   T* operator->() {
     RTC_DCHECK(has_value_);
     return &value_;
   }
   const T& operator*() const {
     RTC_DCHECK(has_value_);
     return value_;
   }
   T& operator*() {
     RTC_DCHECK(has_value_);
     return value_;
   }
   const T& value() const {
     RTC_DCHECK(has_value_);
     return value_;
   }
   T& value() {
     RTC_DCHECK(has_value_);
     return value_;
   }

   // Dereference with a default value in case we don't have a value.
   const T& value_or(const T& default_val) const {
     // The no-op call prevents the compiler from generating optimized code that
     // reads value_ even if !has_value_, but only if FunctionThatDoesNothing is
     // not completely inlined; see its declaration.).
     return has_value_ ? *optional_internal::FunctionThatDoesNothing(&value_)
                       : default_val;
   }

   // Equality tests. Two Optionals are equal if they contain equivalent values,
   // or if they're both empty.
   friend bool operator==(const Optional& m1, const Optional& m2) {
     return m1.has_value_ && m2.has_value_ ? m1.value_ == m2.value_
                                           : m1.has_value_ == m2.has_value_;
   }
   friend bool operator==(const Optional& opt, const T& value) {
     return opt.has_value_ && opt.value_ == value;
   }
   friend bool operator==(const T& value, const Optional& opt) {
     return opt.has_value_ && value == opt.value_;
   }

   friend bool operator==(const Optional& opt, rtc::nullopt_t) {
     return !opt.has_value_;
   }

   friend bool operator==(rtc::nullopt_t, const Optional& opt) {
     return !opt.has_value_;
   }

   friend bool operator!=(const Optional& m1, const Optional& m2) {
     return m1.has_value_ && m2.has_value_ ? m1.value_ != m2.value_
                                           : m1.has_value_ != m2.has_value_;
   }
   friend bool operator!=(const Optional& opt, const T& value) {
     return !opt.has_value_ || opt.value_ != value;
   }
   friend bool operator!=(const T& value, const Optional& opt) {
     return !opt.has_value_ || value != opt.value_;
   }

   friend bool operator!=(const Optional& opt, rtc::nullopt_t) {
     return opt.has_value_;
   }

   friend bool operator!=(rtc::nullopt_t, const Optional& opt) {
     return opt.has_value_;
   }

  private:
   // Tell sanitizers that value_ shouldn't be touched.
   void PoisonValue() {
     rtc::AsanPoison(rtc::MakeArrayView(&value_, 1));
     rtc::MsanMarkUninitialized(rtc::MakeArrayView(&value_, 1));
   }

   // Tell sanitizers that value_ is OK to touch again.
   void UnpoisonValue() { rtc::AsanUnpoison(rtc::MakeArrayView(&value_, 1)); }

   bool has_value_;  // True iff value_ contains a live value.
   union {
     // empty_ exists only to make it possible to initialize the union, even when
     // it doesn't contain any data. If the union goes uninitialized, it may
     // trigger compiler warnings.
     char empty_;
     // By placing value_ in a union, we get to manage its construction and
     // destruction manually: the Optional constructors won't automatically
     // construct it, and the Optional destructor won't automatically destroy
     // it. Basically, this just allocates a properly sized and aligned block of
     // memory in which we can manually put a T with placement new.
     T value_;
   };
 };

 #ifdef UNIT_TEST
 namespace optional_internal {

 // Checks if there's a valid PrintTo(const T&, std::ostream*) call for T.
 template <typename T>
 struct HasPrintTo {
  private:
   struct No {};

   template <typename T2>
   static auto Test(const T2& obj)
       -> decltype(PrintTo(obj, std::declval<std::ostream*>()));

   template <typename>
   static No Test(...);

  public:
   static constexpr bool value =
       !std::is_same<decltype(Test<T>(std::declval<const T&>())), No>::value;
 };

 // Checks if there's a valid operator<<(std::ostream&, const T&) call for T.
 template <typename T>
 struct HasOstreamOperator {
  private:
   struct No {};

   template <typename T2>
   static auto Test(const T2& obj)
       -> decltype(std::declval<std::ostream&>() << obj);

   template <typename>
   static No Test(...);

  public:
   static constexpr bool value =
       !std::is_same<decltype(Test<T>(std::declval<const T&>())), No>::value;
 };

 // Prefer using PrintTo to print the object.
 template <typename T>
 typename std::enable_if<HasPrintTo<T>::value, void>::type OptionalPrintToHelper(
     const T& value,
     std::ostream* os) {
   PrintTo(value, os);
 }

 // Fall back to operator<<(std::ostream&, ...) if it exists.
 template <typename T>
 typename std::enable_if<HasOstreamOperator<T>::value && !HasPrintTo<T>::value,
                         void>::type
 OptionalPrintToHelper(const T& value, std::ostream* os) {
   *os << value;
 }

 inline void OptionalPrintObjectBytes(const unsigned char* bytes,
                                      size_t size,
                                      std::ostream* os) {
   *os << "<optional with " << size << "-byte object [";
   for (size_t i = 0; i != size; ++i) {
     *os << (i == 0 ? "" : ((i & 1) ? "-" : " "));
     *os << std::hex << std::setw(2) << std::setfill('0')
         << static_cast<int>(bytes[i]);
   }
   *os << "]>";
 }

 // As a final back-up, just print the contents of the objcets byte-wise.
 template <typename T>
 typename std::enable_if<!HasOstreamOperator<T>::value && !HasPrintTo<T>::value,
                         void>::type
 OptionalPrintToHelper(const T& value, std::ostream* os) {
   OptionalPrintObjectBytes(reinterpret_cast<const unsigned char*>(&value),
                            sizeof(value), os);
 }

 }  // namespace optional_internal

 // PrintTo is used by gtest to print out the results of tests. We want to ensure
 // the object contained in an Optional can be printed out if it's set, while
 // avoiding touching the object's storage if it is undefined.
 template <typename T>
 void PrintTo(const rtc::Optional<T>& opt, std::ostream* os) {
   if (opt) {
     optional_internal::OptionalPrintToHelper(*opt, os);
   } else {
     *os << "<empty optional>";
   }
 }

 #endif  // UNIT_TEST

 }  // namespace rtc

 #endif  // API_OPTIONAL_H_
	/*
	* Copyright 2015 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.
	*/

	#ifndef API_OPTIONAL_H_
	#define API_OPTIONAL_H_

	#include <algorithm>
	#include <memory>
	#include <utility>

	#ifdef UNIT_TEST
	#include <iomanip>
	#include <ostream>
	#endif // UNIT_TEST

	#include "api/array_view.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/sanitizer.h"

	namespace rtc {

	namespace optional_internal {

	#if RTC_HAS_ASAN

	// This is a non-inlined function. The optimizer can't see inside it. It
	// prevents the compiler from generating optimized code that reads value_ even
	// if it is unset. Although safe, this causes memory sanitizers to complain.
	const void* FunctionThatDoesNothingImpl(const void*);

	template <typename T>
	inline const T* FunctionThatDoesNothing(T* x) {
	return reinterpret_cast<const T*>(
	FunctionThatDoesNothingImpl(reinterpret_cast<const void*>(x)));
	}

	#else

	template <typename T>
	inline const T* FunctionThatDoesNothing(T* x) {
	return x;
	}

	#endif

	struct NulloptArg;

	} // namespace optional_internal

	// nullopt_t must be a non-aggregate literal type with a constexpr constructor
	// that takes some implementation-defined literal type. It mustn't have a
	// default constructor nor an initializer-list constructor.
	// See:
	// http://en.cppreference.com/w/cpp/utility/optional/nullopt_t
	// That page uses int, though this seems to confuse older versions of GCC.
	struct nullopt_t {
	constexpr explicit nullopt_t(rtc::optional_internal::NulloptArg&) {}
	};

	// Specification:
	// http://en.cppreference.com/w/cpp/utility/optional/nullopt
	extern const nullopt_t nullopt;

	// Simple std::optional-wannabe. It either contains a T or not.
	//
	// A moved-from Optional<T> may only be destroyed, and assigned to if T allows
	// being assigned to after having been moved from. Specifically, you may not
	// assume that it just doesn't contain a value anymore.
	//
	// Examples of good places to use Optional:
	//
	// - As a class or struct member, when the member doesn't always have a value:
	// struct Prisoner {
	// std::string name;
	// Optional<int> cell_number; // Empty if not currently incarcerated.
	// };
	//
	// - As a return value for functions that may fail to return a value on all
	// allowed inputs. For example, a function that searches an array might
	// return an Optional<size_t> (the index where it found the element, or
	// nothing if it didn't find it); and a function that parses numbers might
	// return Optional<double> (the parsed number, or nothing if parsing failed).
	//
	// Examples of bad places to use Optional:
	//
	// - As a return value for functions that may fail because of disallowed
	// inputs. For example, a string length function should not return
	// Optional<size_t> so that it can return nothing in case the caller passed
	// it a null pointer; the function should probably use RTC_[D]CHECK instead,
	// and return plain size_t.
	//
	// - As a return value for functions that may fail to return a value on all
	// allowed inputs, but need to tell the caller what went wrong. Returning
	// Optional<double> when parsing a single number as in the example above
	// might make sense, but any larger parse job is probably going to need to
	// tell the caller what the problem was, not just that there was one.
	//
	// - As a non-mutable function argument. When you want to pass a value of a
	// type T that can fail to be there, const T* is almost always both fastest
	// and cleanest. (If you're sure that the the caller will always already
	// have an Optional<T>, const Optional<T>& is slightly faster than const T*,
	// but this is a micro-optimization. In general, stick to const T*.)
	//
	// TODO(kwiberg): Get rid of this class when the standard library has
	// std::optional (and we're allowed to use it).
	template <typename T>
	class Optional final {
	public:
	// Construct an empty Optional.
	Optional() : has_value_(false), empty_('\0') { PoisonValue(); }

	Optional(rtc::nullopt_t) // NOLINT(runtime/explicit)
	: Optional() {}

	// Construct an Optional that contains a value.
	Optional(const T& value) // NOLINT(runtime/explicit)
	: has_value_(true) {
	new (&value_) T(value);
	}
	Optional(T&& value) // NOLINT(runtime/explicit)
	: has_value_(true) {
	new (&value_) T(std::move(value));
	}

	// Copy constructor: copies the value from m if it has one.
	Optional(const Optional& m) : has_value_(m.has_value_) {
	if (has_value_)
	new (&value_) T(m.value_);
	else
	PoisonValue();
	}

	// Move constructor: if m has a value, moves the value from m, leaving m
	// still in a state where it has a value, but a moved-from one (the
	// properties of which depends on T; the only general guarantee is that we
	// can destroy m).
	Optional(Optional&& m) : has_value_(m.has_value_) {
	if (has_value_)
	new (&value_) T(std::move(m.value_));
	else
	PoisonValue();
	}

	~Optional() {
	if (has_value_)
	value_.~T();
	else
	UnpoisonValue();
	}

	Optional& operator=(rtc::nullopt_t) {
	reset();
	return *this;
	}

	// Copy assignment. Uses T's copy assignment if both sides have a value, T's
	// copy constructor if only the right-hand side has a value.
	Optional& operator=(const Optional& m) {
	if (m.has_value_) {
	if (has_value_) {
	value_ = m.value_; // T's copy assignment.
	} else {
	UnpoisonValue();
	new (&value_) T(m.value_); // T's copy constructor.
	has_value_ = true;
	}
	} else {
	reset();
	}
	return *this;
	}

	// Move assignment. Uses T's move assignment if both sides have a value, T's
	// move constructor if only the right-hand side has a value. The state of m
	// after it's been moved from is as for the move constructor.
	Optional& operator=(Optional&& m) {
	if (m.has_value_) {
	if (has_value_) {
	value_ = std::move(m.value_); // T's move assignment.
	} else {
	UnpoisonValue();
	new (&value_) T(std::move(m.value_)); // T's move constructor.
	has_value_ = true;
	}
	} else {
	reset();
	}
	return *this;
	}

	// Swap the values if both m1 and m2 have values; move the value if only one
	// of them has one.
	friend void swap(Optional& m1, Optional& m2) {
	if (m1.has_value_) {
	if (m2.has_value_) {
	// Both have values: swap.
	using std::swap;
	swap(m1.value_, m2.value_);
	} else {
	// Only m1 has a value: move it to m2.
	m2.UnpoisonValue();
	new (&m2.value_) T(std::move(m1.value_));
	m1.value_.~T(); // Destroy the moved-from value.
	m1.has_value_ = false;
	m2.has_value_ = true;
	m1.PoisonValue();
	}
	} else if (m2.has_value_) {
	// Only m2 has a value: move it to m1.
	m1.UnpoisonValue();
	new (&m1.value_) T(std::move(m2.value_));
	m2.value_.~T(); // Destroy the moved-from value.
	m1.has_value_ = true;
	m2.has_value_ = false;
	m2.PoisonValue();
	}
	}

	// Destroy any contained value. Has no effect if we have no value.
	void reset() {
	if (!has_value_)
	return;
	value_.~T();
	has_value_ = false;
	PoisonValue();
	}

	template <class... Args>
	void emplace(Args&&... args) {
	if (has_value_)
	value_.~T();
	else
	UnpoisonValue();
	new (&value_) T(std::forward<Args>(args)...);
	has_value_ = true;
	}

	// Conversion to bool to test if we have a value.
	explicit operator bool() const { return has_value_; }
	bool has_value() const { return has_value_; }

	// Dereferencing. Only allowed if we have a value.
	const T* operator->() const {
	RTC_DCHECK(has_value_);
	return &value_;
	}
	T* operator->() {
	RTC_DCHECK(has_value_);
	return &value_;
	}
	const T& operator*() const {
	RTC_DCHECK(has_value_);
	return value_;
	}
	T& operator*() {
	RTC_DCHECK(has_value_);
	return value_;
	}
	const T& value() const {
	RTC_DCHECK(has_value_);
	return value_;
	}
	T& value() {
	RTC_DCHECK(has_value_);
	return value_;
	}

	// Dereference with a default value in case we don't have a value.
	const T& value_or(const T& default_val) const {
	// The no-op call prevents the compiler from generating optimized code that
	// reads value_ even if !has_value_, but only if FunctionThatDoesNothing is
	// not completely inlined; see its declaration.).
	return has_value_ ? *optional_internal::FunctionThatDoesNothing(&value_)
	: default_val;
	}

	// Equality tests. Two Optionals are equal if they contain equivalent values,
	// or if they're both empty.
	friend bool operator==(const Optional& m1, const Optional& m2) {
	return m1.has_value_ && m2.has_value_ ? m1.value_ == m2.value_
	: m1.has_value_ == m2.has_value_;
	}
	friend bool operator==(const Optional& opt, const T& value) {
	return opt.has_value_ && opt.value_ == value;
	}
	friend bool operator==(const T& value, const Optional& opt) {
	return opt.has_value_ && value == opt.value_;
	}

	friend bool operator==(const Optional& opt, rtc::nullopt_t) {
	return !opt.has_value_;
	}

	friend bool operator==(rtc::nullopt_t, const Optional& opt) {
	return !opt.has_value_;
	}

	friend bool operator!=(const Optional& m1, const Optional& m2) {
	return m1.has_value_ && m2.has_value_ ? m1.value_ != m2.value_
	: m1.has_value_ != m2.has_value_;
	}
	friend bool operator!=(const Optional& opt, const T& value) {
	return !opt.has_value_ \|\| opt.value_ != value;
	}
	friend bool operator!=(const T& value, const Optional& opt) {
	return !opt.has_value_ \|\| value != opt.value_;
	}

	friend bool operator!=(const Optional& opt, rtc::nullopt_t) {
	return opt.has_value_;
	}

	friend bool operator!=(rtc::nullopt_t, const Optional& opt) {
	return opt.has_value_;
	}

	private:
	// Tell sanitizers that value_ shouldn't be touched.
	void PoisonValue() {
	rtc::AsanPoison(rtc::MakeArrayView(&value_, 1));
	rtc::MsanMarkUninitialized(rtc::MakeArrayView(&value_, 1));
	}

	// Tell sanitizers that value_ is OK to touch again.
	void UnpoisonValue() { rtc::AsanUnpoison(rtc::MakeArrayView(&value_, 1)); }

	bool has_value_; // True iff value_ contains a live value.
	union {
	// empty_ exists only to make it possible to initialize the union, even when
	// it doesn't contain any data. If the union goes uninitialized, it may
	// trigger compiler warnings.
	char empty_;
	// By placing value_ in a union, we get to manage its construction and
	// destruction manually: the Optional constructors won't automatically
	// construct it, and the Optional destructor won't automatically destroy
	// it. Basically, this just allocates a properly sized and aligned block of
	// memory in which we can manually put a T with placement new.
	T value_;
	};
	};

	#ifdef UNIT_TEST
	namespace optional_internal {

	// Checks if there's a valid PrintTo(const T&, std::ostream*) call for T.
	template <typename T>
	struct HasPrintTo {
	private:
	struct No {};

	template <typename T2>
	static auto Test(const T2& obj)
	-> decltype(PrintTo(obj, std::declval<std::ostream*>()));

	template <typename>
	static No Test(...);

	public:
	static constexpr bool value =
	!std::is_same<decltype(Test<T>(std::declval<const T&>())), No>::value;
	};

	// Checks if there's a valid operator<<(std::ostream&, const T&) call for T.
	template <typename T>
	struct HasOstreamOperator {
	private:
	struct No {};

	template <typename T2>
	static auto Test(const T2& obj)
	-> decltype(std::declval<std::ostream&>() << obj);

	template <typename>
	static No Test(...);

	public:
	static constexpr bool value =
	!std::is_same<decltype(Test<T>(std::declval<const T&>())), No>::value;
	};

	// Prefer using PrintTo to print the object.
	template <typename T>
	typename std::enable_if<HasPrintTo<T>::value, void>::type OptionalPrintToHelper(
	const T& value,
	std::ostream* os) {
	PrintTo(value, os);
	}

	// Fall back to operator<<(std::ostream&, ...) if it exists.
	template <typename T>
	typename std::enable_if<HasOstreamOperator<T>::value && !HasPrintTo<T>::value,
	void>::type
	OptionalPrintToHelper(const T& value, std::ostream* os) {
	*os << value;
	}

	inline void OptionalPrintObjectBytes(const unsigned char* bytes,
	size_t size,
	std::ostream* os) {
	*os << "<optional with " << size << "-byte object [";
	for (size_t i = 0; i != size; ++i) {
	*os << (i == 0 ? "" : ((i & 1) ? "-" : " "));
	*os << std::hex << std::setw(2) << std::setfill('0')
	<< static_cast<int>(bytes[i]);
	}
	*os << "]>";
	}

	// As a final back-up, just print the contents of the objcets byte-wise.
	template <typename T>
	typename std::enable_if<!HasOstreamOperator<T>::value && !HasPrintTo<T>::value,
	void>::type
	OptionalPrintToHelper(const T& value, std::ostream* os) {
	OptionalPrintObjectBytes(reinterpret_cast<const unsigned char*>(&value),
	sizeof(value), os);
	}

	} // namespace optional_internal

	// PrintTo is used by gtest to print out the results of tests. We want to ensure
	// the object contained in an Optional can be printed out if it's set, while
	// avoiding touching the object's storage if it is undefined.
	template <typename T>
	void PrintTo(const rtc::Optional<T>& opt, std::ostream* os) {
	if (opt) {
	optional_internal::OptionalPrintToHelper(*opt, os);
	} else {
	*os << "<empty optional>";
	}
	}

	#endif // UNIT_TEST

	} // namespace rtc

	#endif // API_OPTIONAL_H_