faux-folly/folly/Traits.h - nest-cam/4320010/faux-folly - Git at Google

 /*
  * Copyright 2015 Facebook, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 // @author: Andrei Alexandrescu

 #ifndef FOLLY_BASE_TRAITS_H_
 #define FOLLY_BASE_TRAITS_H_

 #include <memory>
 #include <limits>
 #include <type_traits>
 #include <functional>

 #include <folly/Portability.h>

 // libc++ doesn't provide this header, nor does msvc
 #ifdef FOLLY_HAVE_BITS_CXXCONFIG_H
 // This file appears in two locations: inside fbcode and in the
 // libstdc++ source code (when embedding fbstring as std::string).
 // To aid in this schizophrenic use, two macros are defined in
 // c++config.h:
 //   _LIBSTDCXX_FBSTRING - Set inside libstdc++.  This is useful to
 //      gate use inside fbcode v. libstdc++
 #include <bits/c++config.h>
 #endif

 #include <boost/type_traits.hpp>
 #include <boost/mpl/and.hpp>
 #include <boost/mpl/has_xxx.hpp>
 #include <boost/mpl/not.hpp>

 namespace folly {

 /**
  * IsRelocatable<T>::value describes the ability of moving around
  * memory a value of type T by using memcpy (as opposed to the
  * conservative approach of calling the copy constructor and then
  * destroying the old temporary. Essentially for a relocatable type,
  * the following two sequences of code should be semantically
  * equivalent:
  *
  * void move1(T * from, T * to) {
  *   new(to) T(from);
  *   (*from).~T();
  * }
  *
  * void move2(T * from, T * to) {
  *   memcpy(to, from, sizeof(T));
  * }
  *
  * Most C++ types are relocatable; the ones that aren't would include
  * internal pointers or (very rarely) would need to update remote
  * pointers to pointers tracking them. All C++ primitive types and
  * type constructors are relocatable.
  *
  * This property can be used in a variety of optimizations. Currently
  * fbvector uses this property intensively.
  *
  * The default conservatively assumes the type is not
  * relocatable. Several specializations are defined for known
  * types. You may want to add your own specializations. Do so in
  * namespace folly and make sure you keep the specialization of
  * IsRelocatable<SomeStruct> in the same header as SomeStruct.
  *
  * You may also declare a type to be relocatable by including
  *    `typedef std::true_type IsRelocatable;`
  * in the class header.
  *
  * It may be unset in a base class by overriding the typedef to false_type.
  */
 /*
  * IsTriviallyCopyable describes the value semantics property. C++11 contains
  * the type trait is_trivially_copyable; however, it is not yet implemented
  * in gcc (as of 4.7.1), and the user may wish to specify otherwise.
  */
 /*
  * IsZeroInitializable describes the property that default construction is the
  * same as memset(dst, 0, sizeof(T)).
  */

 namespace traits_detail {

 #define FOLLY_HAS_TRUE_XXX(name)                          \
   BOOST_MPL_HAS_XXX_TRAIT_DEF(name);                      \
   template <class T> struct name ## _is_true              \
     : std::is_same<typename T::name, std::true_type> {};  \
   template <class T> struct has_true_ ## name             \
     : std::conditional<                                   \
         has_ ## name <T>::value,                          \
         name ## _is_true<T>,                              \
         std::false_type                                   \
       >:: type {};

 FOLLY_HAS_TRUE_XXX(IsRelocatable)
 FOLLY_HAS_TRUE_XXX(IsZeroInitializable)
 FOLLY_HAS_TRUE_XXX(IsTriviallyCopyable)

 #undef FOLLY_HAS_TRUE_XXX
 }

 template <class T> struct IsTriviallyCopyable
   : std::integral_constant<bool,
       !std::is_class<T>::value ||
       // TODO: add alternate clause is_trivially_copyable, when available
       traits_detail::has_true_IsTriviallyCopyable<T>::value
     > {};

 template <class T> struct IsRelocatable
   : std::integral_constant<bool,
       !std::is_class<T>::value ||
       // TODO add this line (and some tests for it) when we upgrade to gcc 4.7
       //std::is_trivially_move_constructible<T>::value ||
       IsTriviallyCopyable<T>::value ||
       traits_detail::has_true_IsRelocatable<T>::value
     > {};

 template <class T> struct IsZeroInitializable
   : std::integral_constant<bool,
       !std::is_class<T>::value ||
       traits_detail::has_true_IsZeroInitializable<T>::value
     > {};

 } // namespace folly

 /**
  * Use this macro ONLY inside namespace folly. When using it with a
  * regular type, use it like this:
  *
  * // Make sure you're at namespace ::folly scope
  * template<> FOLLY_ASSUME_RELOCATABLE(MyType)
  *
  * When using it with a template type, use it like this:
  *
  * // Make sure you're at namespace ::folly scope
  * template<class T1, class T2>
  * FOLLY_ASSUME_RELOCATABLE(MyType<T1, T2>)
  */
 #define FOLLY_ASSUME_RELOCATABLE(...) \
   struct IsRelocatable<  __VA_ARGS__ > : std::true_type {};

 /**
  * Use this macro ONLY inside namespace boost. When using it with a
  * regular type, use it like this:
  *
  * // Make sure you're at namespace ::boost scope
  * template<> FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(MyType)
  *
  * When using it with a template type, use it like this:
  *
  * // Make sure you're at namespace ::boost scope
  * template<class T1, class T2>
  * FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(MyType<T1, T2>)
  */
 #define FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(...) \
   struct has_nothrow_constructor<  __VA_ARGS__ > : ::boost::true_type {};

 /**
  * The FOLLY_ASSUME_FBVECTOR_COMPATIBLE* macros below encode two
  * assumptions: first, that the type is relocatable per IsRelocatable
  * above, and that it has a nothrow constructor. Most types can be
  * assumed to satisfy both conditions, but it is the responsibility of
  * the user to state that assumption. User-defined classes will not
  * work with fbvector (see FBVector.h) unless they state this
  * combination of properties.
  *
  * Use FOLLY_ASSUME_FBVECTOR_COMPATIBLE with regular types like this:
  *
  * FOLLY_ASSUME_FBVECTOR_COMPATIBLE(MyType)
  *
  * The versions FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1, _2, _3, and _4
  * allow using the macro for describing templatized classes with 1, 2,
  * 3, and 4 template parameters respectively. For template classes
  * just use the macro with the appropriate number and pass the name of
  * the template to it. Example:
  *
  * template <class T1, class T2> class MyType { ... };
  * ...
  * // Make sure you're at global scope
  * FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(MyType)
  */

 // Use this macro ONLY at global level (no namespace)
 #define FOLLY_ASSUME_FBVECTOR_COMPATIBLE(...)                           \
   namespace folly { template<> FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__) }   \
   namespace boost { \
   template<> FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__) }
 // Use this macro ONLY at global level (no namespace)
 #define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(...)                         \
   namespace folly {                                                     \
   template <class T1> FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1>) }       \
     namespace boost {                                                   \
     template <class T1> FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1>) }
 // Use this macro ONLY at global level (no namespace)
 #define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(...)                 \
   namespace folly {                                             \
   template <class T1, class T2>                                 \
   FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1, T2>) }               \
     namespace boost {                                           \
     template <class T1, class T2>                               \
     FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1, T2>) }
 // Use this macro ONLY at global level (no namespace)
 #define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_3(...)                         \
   namespace folly {                                                     \
   template <class T1, class T2, class T3>                               \
   FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1, T2, T3>) }                   \
     namespace boost {                                                   \
     template <class T1, class T2, class T3>                             \
     FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1, T2, T3>) }
 // Use this macro ONLY at global level (no namespace)
 #define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_4(...)                         \
   namespace folly {                                                     \
   template <class T1, class T2, class T3, class T4>                     \
   FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1, T2, T3, T4>) }               \
     namespace boost {                                                   \
     template <class T1, class T2, class T3, class T4>                   \
     FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1, T2, T3, T4>) }

 /**
  * Instantiate FOLLY_ASSUME_FBVECTOR_COMPATIBLE for a few types. It is
  * safe to assume that pair is compatible if both of its components
  * are. Furthermore, all STL containers can be assumed to comply,
  * although that is not guaranteed by the standard.
  */

 FOLLY_NAMESPACE_STD_BEGIN

 template <class T, class U>
   struct pair;
 #ifndef _GLIBCXX_USE_FB
 template <class T, class R, class A>
   class basic_string;
 #else
 template <class T, class R, class A, class S>
   class basic_string;
 #endif
 template <class T, class A>
   class vector;
 template <class T, class A>
   class deque;
 template <class T, class A>
   class list;
 template <class T, class C, class A>
   class set;
 template <class K, class V, class C, class A>
   class map;
 template <class T>
   class shared_ptr;

 FOLLY_NAMESPACE_STD_END

 namespace boost {

 template <class T> class shared_ptr;

 template <class T, class U>
 struct has_nothrow_constructor< std::pair<T, U> >
     : ::boost::mpl::and_< has_nothrow_constructor<T>,
                           has_nothrow_constructor<U> > {};

 } // namespace boost

 namespace folly {

 // STL commonly-used types
 template <class T, class U>
 struct IsRelocatable<  std::pair<T, U> >
     : ::boost::mpl::and_< IsRelocatable<T>, IsRelocatable<U> > {};

 // Is T one of T1, T2, ..., Tn?
 template <class T, class... Ts>
 struct IsOneOf {
   enum { value = false };
 };

 template <class T, class T1, class... Ts>
 struct IsOneOf<T, T1, Ts...> {
   enum { value = std::is_same<T, T1>::value || IsOneOf<T, Ts...>::value };
 };

 /*
  * Complementary type traits for integral comparisons.
  *
  * For instance, `if(x < 0)` yields an error in clang for unsigned types
  *  when -Werror is used due to -Wtautological-compare
  *
  *
  * @author: Marcelo Juchem <marcelo@fb.com>
  */

 namespace detail {

 template <typename T, bool>
 struct is_negative_impl {
   constexpr static bool check(T x) { return x < 0; }
 };

 template <typename T>
 struct is_negative_impl<T, false> {
   constexpr static bool check(T) { return false; }
 };

 // folly::to integral specializations can end up generating code
 // inside what are really static ifs (not executed because of the templated
 // types) that violate -Wsign-compare so suppress them in order to not prevent
 // all calling code from using it.
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wsign-compare"

 template <typename RHS, RHS rhs, typename LHS>
 bool less_than_impl(
   typename std::enable_if<
     (rhs <= std::numeric_limits<LHS>::max()
       && rhs > std::numeric_limits<LHS>::min()),
     LHS
   >::type const lhs
 ) {
   return lhs < rhs;
 }

 template <typename RHS, RHS rhs, typename LHS>
 bool less_than_impl(
   typename std::enable_if<
     (rhs > std::numeric_limits<LHS>::max()),
     LHS
   >::type const
 ) {
   return true;
 }

 template <typename RHS, RHS rhs, typename LHS>
 bool less_than_impl(
   typename std::enable_if<
     (rhs <= std::numeric_limits<LHS>::min()),
     LHS
   >::type const
 ) {
   return false;
 }

 #pragma GCC diagnostic pop

 template <typename RHS, RHS rhs, typename LHS>
 bool greater_than_impl(
   typename std::enable_if<
     (rhs <= std::numeric_limits<LHS>::max()
       && rhs >= std::numeric_limits<LHS>::min()),
     LHS
   >::type const lhs
 ) {
   return lhs > rhs;
 }

 template <typename RHS, RHS rhs, typename LHS>
 bool greater_than_impl(
   typename std::enable_if<
     (rhs > std::numeric_limits<LHS>::max()),
     LHS
   >::type const
 ) {
   return false;
 }

 template <typename RHS, RHS rhs, typename LHS>
 bool greater_than_impl(
   typename std::enable_if<
     (rhs < std::numeric_limits<LHS>::min()),
     LHS
   >::type const
 ) {
   return true;
 }

 } // namespace detail {

 // same as `x < 0`
 template <typename T>
 constexpr bool is_negative(T x) {
   return folly::detail::is_negative_impl<T, std::is_signed<T>::value>::check(x);
 }

 // same as `x <= 0`
 template <typename T>
 constexpr bool is_non_positive(T x) { return !x || folly::is_negative(x); }

 // same as `x > 0`
 template <typename T>
 constexpr bool is_positive(T x) { return !is_non_positive(x); }

 // same as `x >= 0`
 template <typename T>
 constexpr bool is_non_negative(T x) {
   return !x || is_positive(x);
 }

 template <typename RHS, RHS rhs, typename LHS>
 bool less_than(LHS const lhs) {
   return detail::less_than_impl<
     RHS, rhs, typename std::remove_reference<LHS>::type
   >(lhs);
 }

 template <typename RHS, RHS rhs, typename LHS>
 bool greater_than(LHS const lhs) {
   return detail::greater_than_impl<
     RHS, rhs, typename std::remove_reference<LHS>::type
   >(lhs);
 }

 } // namespace folly

 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_3(std::basic_string);
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::vector);
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::list);
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::deque);
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::unique_ptr);
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(std::shared_ptr);
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(std::function);

 // Boost
 FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(boost::shared_ptr);

 #define FOLLY_CREATE_HAS_MEMBER_TYPE_TRAITS(classname, type_name) \
   template <typename T> \
   struct classname { \
     template <typename C> \
     constexpr static bool test(typename C::type_name*) { return true; } \
     template <typename> \
     constexpr static bool test(...) { return false; } \
     constexpr static bool value = test<T>(nullptr); \
   }

 #define FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL(classname, func_name, cv_qual) \
   template <typename TTheClass_, typename RTheReturn_, typename... TTheArgs_> \
   class classname<TTheClass_, RTheReturn_(TTheArgs_...) cv_qual> { \
     template < \
       typename UTheClass_, RTheReturn_ (UTheClass_::*)(TTheArgs_...) cv_qual \
     > struct sfinae {}; \
     template <typename UTheClass_> \
     constexpr static bool test(sfinae<UTheClass_, &UTheClass_::func_name>*) \
     { return true; } \
     template <typename> \
     constexpr static bool test(...) { return false; } \
   public: \
     constexpr static bool value = test<TTheClass_>(nullptr); \
   }

 /*
  * The FOLLY_CREATE_HAS_MEMBER_FN_TRAITS is used to create traits
  * classes that check for the existence of a member function with
  * a given name and signature. It currently does not support
  * checking for inherited members.
  *
  * Such classes receive two template parameters: the class to be checked
  * and the signature of the member function. A static boolean field
  * named `value` (which is also constexpr) tells whether such member
  * function exists.
  *
  * Each traits class created is bound only to the member name, not to
  * its signature nor to the type of the class containing it.
  *
  * Say you need to know if a given class has a member function named
  * `test` with the following signature:
  *
  *    int test() const;
  *
  * You'd need this macro to create a traits class to check for a member
  * named `test`, and then use this traits class to check for the signature:
  *
  * namespace {
  *
  * FOLLY_CREATE_HAS_MEMBER_FN_TRAITS(has_test_traits, test);
  *
  * } // unnamed-namespace
  *
  * void some_func() {
  *   cout << "Does class Foo have a member int test() const? "
  *     << boolalpha << has_test_traits<Foo, int() const>::value;
  * }
  *
  * You can use the same traits class to test for a completely different
  * signature, on a completely different class, as long as the member name
  * is the same:
  *
  * void some_func() {
  *   cout << "Does class Foo have a member int test()? "
  *     << boolalpha << has_test_traits<Foo, int()>::value;
  *   cout << "Does class Foo have a member int test() const? "
  *     << boolalpha << has_test_traits<Foo, int() const>::value;
  *   cout << "Does class Bar have a member double test(const string&, long)? "
  *     << boolalpha << has_test_traits<Bar, double(const string&, long)>::value;
  * }
  *
  * @author: Marcelo Juchem <marcelo@fb.com>
  */
 #define FOLLY_CREATE_HAS_MEMBER_FN_TRAITS(classname, func_name) \
   template <typename, typename> class classname; \
   FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL(classname, func_name, ); \
   FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL(classname, func_name, const); \
   FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL( \
       classname, func_name, /* nolint */ volatile); \
   FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL( \
       classname, func_name, /* nolint */ volatile const)

 #endif //FOLLY_BASE_TRAITS_H_
	/*
	* Copyright 2015 Facebook, Inc.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	// @author: Andrei Alexandrescu

	#ifndef FOLLY_BASE_TRAITS_H_
	#define FOLLY_BASE_TRAITS_H_

	#include <memory>
	#include <limits>
	#include <type_traits>
	#include <functional>

	#include <folly/Portability.h>

	// libc++ doesn't provide this header, nor does msvc
	#ifdef FOLLY_HAVE_BITS_CXXCONFIG_H
	// This file appears in two locations: inside fbcode and in the
	// libstdc++ source code (when embedding fbstring as std::string).
	// To aid in this schizophrenic use, two macros are defined in
	// c++config.h:
	// _LIBSTDCXX_FBSTRING - Set inside libstdc++. This is useful to
	// gate use inside fbcode v. libstdc++
	#include <bits/c++config.h>
	#endif

	#include <boost/type_traits.hpp>
	#include <boost/mpl/and.hpp>
	#include <boost/mpl/has_xxx.hpp>
	#include <boost/mpl/not.hpp>

	namespace folly {

	/**
	* IsRelocatable<T>::value describes the ability of moving around
	* memory a value of type T by using memcpy (as opposed to the
	* conservative approach of calling the copy constructor and then
	* destroying the old temporary. Essentially for a relocatable type,
	* the following two sequences of code should be semantically
	* equivalent:
	*
	* void move1(T * from, T * to) {
	* new(to) T(from);
	* (*from).~T();
	* }
	*
	* void move2(T * from, T * to) {
	* memcpy(to, from, sizeof(T));
	* }
	*
	* Most C++ types are relocatable; the ones that aren't would include
	* internal pointers or (very rarely) would need to update remote
	* pointers to pointers tracking them. All C++ primitive types and
	* type constructors are relocatable.
	*
	* This property can be used in a variety of optimizations. Currently
	* fbvector uses this property intensively.
	*
	* The default conservatively assumes the type is not
	* relocatable. Several specializations are defined for known
	* types. You may want to add your own specializations. Do so in
	* namespace folly and make sure you keep the specialization of
	* IsRelocatable<SomeStruct> in the same header as SomeStruct.
	*
	* You may also declare a type to be relocatable by including
	* `typedef std::true_type IsRelocatable;`
	* in the class header.
	*
	* It may be unset in a base class by overriding the typedef to false_type.
	*/
	/*
	* IsTriviallyCopyable describes the value semantics property. C++11 contains
	* the type trait is_trivially_copyable; however, it is not yet implemented
	* in gcc (as of 4.7.1), and the user may wish to specify otherwise.
	*/
	/*
	* IsZeroInitializable describes the property that default construction is the
	* same as memset(dst, 0, sizeof(T)).
	*/

	namespace traits_detail {

	#define FOLLY_HAS_TRUE_XXX(name) \
	BOOST_MPL_HAS_XXX_TRAIT_DEF(name); \
	template <class T> struct name ## _is_true \
	: std::is_same<typename T::name, std::true_type> {}; \
	template <class T> struct has_true_ ## name \
	: std::conditional< \
	has_ ## name <T>::value, \
	name ## _is_true<T>, \
	std::false_type \
	>:: type {};

	FOLLY_HAS_TRUE_XXX(IsRelocatable)
	FOLLY_HAS_TRUE_XXX(IsZeroInitializable)
	FOLLY_HAS_TRUE_XXX(IsTriviallyCopyable)

	#undef FOLLY_HAS_TRUE_XXX
	}

	template <class T> struct IsTriviallyCopyable
	: std::integral_constant<bool,
	!std::is_class<T>::value \|\|
	// TODO: add alternate clause is_trivially_copyable, when available
	traits_detail::has_true_IsTriviallyCopyable<T>::value
	> {};

	template <class T> struct IsRelocatable
	: std::integral_constant<bool,
	!std::is_class<T>::value \|\|
	// TODO add this line (and some tests for it) when we upgrade to gcc 4.7
	//std::is_trivially_move_constructible<T>::value \|\|
	IsTriviallyCopyable<T>::value \|\|
	traits_detail::has_true_IsRelocatable<T>::value
	> {};

	template <class T> struct IsZeroInitializable
	: std::integral_constant<bool,
	!std::is_class<T>::value \|\|
	traits_detail::has_true_IsZeroInitializable<T>::value
	> {};

	} // namespace folly

	/**
	* Use this macro ONLY inside namespace folly. When using it with a
	* regular type, use it like this:
	*
	* // Make sure you're at namespace ::folly scope
	* template<> FOLLY_ASSUME_RELOCATABLE(MyType)
	*
	* When using it with a template type, use it like this:
	*
	* // Make sure you're at namespace ::folly scope
	* template<class T1, class T2>
	* FOLLY_ASSUME_RELOCATABLE(MyType<T1, T2>)
	*/
	#define FOLLY_ASSUME_RELOCATABLE(...) \
	struct IsRelocatable< __VA_ARGS__ > : std::true_type {};

	/**
	* Use this macro ONLY inside namespace boost. When using it with a
	* regular type, use it like this:
	*
	* // Make sure you're at namespace ::boost scope
	* template<> FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(MyType)
	*
	* When using it with a template type, use it like this:
	*
	* // Make sure you're at namespace ::boost scope
	* template<class T1, class T2>
	* FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(MyType<T1, T2>)
	*/
	#define FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(...) \
	struct has_nothrow_constructor< __VA_ARGS__ > : ::boost::true_type {};

	/**
	* The FOLLY_ASSUME_FBVECTOR_COMPATIBLE* macros below encode two
	* assumptions: first, that the type is relocatable per IsRelocatable
	* above, and that it has a nothrow constructor. Most types can be
	* assumed to satisfy both conditions, but it is the responsibility of
	* the user to state that assumption. User-defined classes will not
	* work with fbvector (see FBVector.h) unless they state this
	* combination of properties.
	*
	* Use FOLLY_ASSUME_FBVECTOR_COMPATIBLE with regular types like this:
	*
	* FOLLY_ASSUME_FBVECTOR_COMPATIBLE(MyType)
	*
	* The versions FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1, _2, _3, and _4
	* allow using the macro for describing templatized classes with 1, 2,
	* 3, and 4 template parameters respectively. For template classes
	* just use the macro with the appropriate number and pass the name of
	* the template to it. Example:
	*
	* template <class T1, class T2> class MyType { ... };
	* ...
	* // Make sure you're at global scope
	* FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(MyType)
	*/

	// Use this macro ONLY at global level (no namespace)
	#define FOLLY_ASSUME_FBVECTOR_COMPATIBLE(...) \
	namespace folly { template<> FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__) } \
	namespace boost { \
	template<> FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__) }
	// Use this macro ONLY at global level (no namespace)
	#define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(...) \
	namespace folly { \
	template <class T1> FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1>) } \
	namespace boost { \
	template <class T1> FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1>) }
	// Use this macro ONLY at global level (no namespace)
	#define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(...) \
	namespace folly { \
	template <class T1, class T2> \
	FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1, T2>) } \
	namespace boost { \
	template <class T1, class T2> \
	FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1, T2>) }
	// Use this macro ONLY at global level (no namespace)
	#define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_3(...) \
	namespace folly { \
	template <class T1, class T2, class T3> \
	FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1, T2, T3>) } \
	namespace boost { \
	template <class T1, class T2, class T3> \
	FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1, T2, T3>) }
	// Use this macro ONLY at global level (no namespace)
	#define FOLLY_ASSUME_FBVECTOR_COMPATIBLE_4(...) \
	namespace folly { \
	template <class T1, class T2, class T3, class T4> \
	FOLLY_ASSUME_RELOCATABLE(__VA_ARGS__<T1, T2, T3, T4>) } \
	namespace boost { \
	template <class T1, class T2, class T3, class T4> \
	FOLLY_ASSUME_HAS_NOTHROW_CONSTRUCTOR(__VA_ARGS__<T1, T2, T3, T4>) }

	/**
	* Instantiate FOLLY_ASSUME_FBVECTOR_COMPATIBLE for a few types. It is
	* safe to assume that pair is compatible if both of its components
	* are. Furthermore, all STL containers can be assumed to comply,
	* although that is not guaranteed by the standard.
	*/

	FOLLY_NAMESPACE_STD_BEGIN

	template <class T, class U>
	struct pair;
	#ifndef _GLIBCXX_USE_FB
	template <class T, class R, class A>
	class basic_string;
	#else
	template <class T, class R, class A, class S>
	class basic_string;
	#endif
	template <class T, class A>
	class vector;
	template <class T, class A>
	class deque;
	template <class T, class A>
	class list;
	template <class T, class C, class A>
	class set;
	template <class K, class V, class C, class A>
	class map;
	template <class T>
	class shared_ptr;

	FOLLY_NAMESPACE_STD_END

	namespace boost {

	template <class T> class shared_ptr;

	template <class T, class U>
	struct has_nothrow_constructor< std::pair<T, U> >
	: ::boost::mpl::and_< has_nothrow_constructor<T>,
	has_nothrow_constructor<U> > {};

	} // namespace boost

	namespace folly {

	// STL commonly-used types
	template <class T, class U>
	struct IsRelocatable< std::pair<T, U> >
	: ::boost::mpl::and_< IsRelocatable<T>, IsRelocatable<U> > {};

	// Is T one of T1, T2, ..., Tn?
	template <class T, class... Ts>
	struct IsOneOf {
	enum { value = false };
	};

	template <class T, class T1, class... Ts>
	struct IsOneOf<T, T1, Ts...> {
	enum { value = std::is_same<T, T1>::value \|\| IsOneOf<T, Ts...>::value };
	};

	/*
	* Complementary type traits for integral comparisons.
	*
	* For instance, `if(x < 0)` yields an error in clang for unsigned types
	* when -Werror is used due to -Wtautological-compare
	*
	*
	* @author: Marcelo Juchem <marcelo@fb.com>
	*/

	namespace detail {

	template <typename T, bool>
	struct is_negative_impl {
	constexpr static bool check(T x) { return x < 0; }
	};

	template <typename T>
	struct is_negative_impl<T, false> {
	constexpr static bool check(T) { return false; }
	};

	// folly::to integral specializations can end up generating code
	// inside what are really static ifs (not executed because of the templated
	// types) that violate -Wsign-compare so suppress them in order to not prevent
	// all calling code from using it.
	#pragma GCC diagnostic push
	#pragma GCC diagnostic ignored "-Wsign-compare"

	template <typename RHS, RHS rhs, typename LHS>
	bool less_than_impl(
	typename std::enable_if<
	(rhs <= std::numeric_limits<LHS>::max()
	&& rhs > std::numeric_limits<LHS>::min()),
	LHS
	>::type const lhs
	) {
	return lhs < rhs;
	}

	template <typename RHS, RHS rhs, typename LHS>
	bool less_than_impl(
	typename std::enable_if<
	(rhs > std::numeric_limits<LHS>::max()),
	LHS
	>::type const
	) {
	return true;
	}

	template <typename RHS, RHS rhs, typename LHS>
	bool less_than_impl(
	typename std::enable_if<
	(rhs <= std::numeric_limits<LHS>::min()),
	LHS
	>::type const
	) {
	return false;
	}

	#pragma GCC diagnostic pop

	template <typename RHS, RHS rhs, typename LHS>
	bool greater_than_impl(
	typename std::enable_if<
	(rhs <= std::numeric_limits<LHS>::max()
	&& rhs >= std::numeric_limits<LHS>::min()),
	LHS
	>::type const lhs
	) {
	return lhs > rhs;
	}

	template <typename RHS, RHS rhs, typename LHS>
	bool greater_than_impl(
	typename std::enable_if<
	(rhs > std::numeric_limits<LHS>::max()),
	LHS
	>::type const
	) {
	return false;
	}

	template <typename RHS, RHS rhs, typename LHS>
	bool greater_than_impl(
	typename std::enable_if<
	(rhs < std::numeric_limits<LHS>::min()),
	LHS
	>::type const
	) {
	return true;
	}

	} // namespace detail {

	// same as `x < 0`
	template <typename T>
	constexpr bool is_negative(T x) {
	return folly::detail::is_negative_impl<T, std::is_signed<T>::value>::check(x);
	}

	// same as `x <= 0`
	template <typename T>
	constexpr bool is_non_positive(T x) { return !x \|\| folly::is_negative(x); }

	// same as `x > 0`
	template <typename T>
	constexpr bool is_positive(T x) { return !is_non_positive(x); }

	// same as `x >= 0`
	template <typename T>
	constexpr bool is_non_negative(T x) {
	return !x \|\| is_positive(x);
	}

	template <typename RHS, RHS rhs, typename LHS>
	bool less_than(LHS const lhs) {
	return detail::less_than_impl<
	RHS, rhs, typename std::remove_reference<LHS>::type
	>(lhs);
	}

	template <typename RHS, RHS rhs, typename LHS>
	bool greater_than(LHS const lhs) {
	return detail::greater_than_impl<
	RHS, rhs, typename std::remove_reference<LHS>::type
	>(lhs);
	}

	} // namespace folly

	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_3(std::basic_string);
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::vector);
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::list);
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::deque);
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_2(std::unique_ptr);
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(std::shared_ptr);
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(std::function);

	// Boost
	FOLLY_ASSUME_FBVECTOR_COMPATIBLE_1(boost::shared_ptr);

	#define FOLLY_CREATE_HAS_MEMBER_TYPE_TRAITS(classname, type_name) \
	template <typename T> \
	struct classname { \
	template <typename C> \
	constexpr static bool test(typename C::type_name*) { return true; } \
	template <typename> \
	constexpr static bool test(...) { return false; } \
	constexpr static bool value = test<T>(nullptr); \
	}

	#define FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL(classname, func_name, cv_qual) \
	template <typename TTheClass_, typename RTheReturn_, typename... TTheArgs_> \
	class classname<TTheClass_, RTheReturn_(TTheArgs_...) cv_qual> { \
	template < \
	typename UTheClass_, RTheReturn_ (UTheClass_::*)(TTheArgs_...) cv_qual \
	> struct sfinae {}; \
	template <typename UTheClass_> \
	constexpr static bool test(sfinae<UTheClass_, &UTheClass_::func_name>*) \
	{ return true; } \
	template <typename> \
	constexpr static bool test(...) { return false; } \
	public: \
	constexpr static bool value = test<TTheClass_>(nullptr); \
	}

	/*
	* The FOLLY_CREATE_HAS_MEMBER_FN_TRAITS is used to create traits
	* classes that check for the existence of a member function with
	* a given name and signature. It currently does not support
	* checking for inherited members.
	*
	* Such classes receive two template parameters: the class to be checked
	* and the signature of the member function. A static boolean field
	* named `value` (which is also constexpr) tells whether such member
	* function exists.
	*
	* Each traits class created is bound only to the member name, not to
	* its signature nor to the type of the class containing it.
	*
	* Say you need to know if a given class has a member function named
	* `test` with the following signature:
	*
	* int test() const;
	*
	* You'd need this macro to create a traits class to check for a member
	* named `test`, and then use this traits class to check for the signature:
	*
	* namespace {
	*
	* FOLLY_CREATE_HAS_MEMBER_FN_TRAITS(has_test_traits, test);
	*
	* } // unnamed-namespace
	*
	* void some_func() {
	* cout << "Does class Foo have a member int test() const? "
	* << boolalpha << has_test_traits<Foo, int() const>::value;
	* }
	*
	* You can use the same traits class to test for a completely different
	* signature, on a completely different class, as long as the member name
	* is the same:
	*
	* void some_func() {
	* cout << "Does class Foo have a member int test()? "
	* << boolalpha << has_test_traits<Foo, int()>::value;
	* cout << "Does class Foo have a member int test() const? "
	* << boolalpha << has_test_traits<Foo, int() const>::value;
	* cout << "Does class Bar have a member double test(const string&, long)? "
	* << boolalpha << has_test_traits<Bar, double(const string&, long)>::value;
	* }
	*
	* @author: Marcelo Juchem <marcelo@fb.com>
	*/
	#define FOLLY_CREATE_HAS_MEMBER_FN_TRAITS(classname, func_name) \
	template <typename, typename> class classname; \
	FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL(classname, func_name, ); \
	FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL(classname, func_name, const); \
	FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL( \
	classname, func_name, /* nolint */ volatile); \
	FOLLY_CREATE_HAS_MEMBER_FN_TRAITS_IMPL( \
	classname, func_name, /* nolint */ volatile const)

	#endif //FOLLY_BASE_TRAITS_H_