faux-folly/folly/ExceptionWrapper.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.
  */

 #ifndef FOLLY_EXCEPTIONWRAPPER_H
 #define FOLLY_EXCEPTIONWRAPPER_H

 #include <cassert>
 #include <exception>
 #include <memory>
 #include <folly/String.h>
 #include <folly/detail/ExceptionWrapper.h>

 namespace folly {

 /*
  * Throwing exceptions can be a convenient way to handle errors. Storing
  * exceptions in an exception_ptr makes it easy to handle exceptions in a
  * different thread or at a later time. exception_ptr can also be used in a very
  * generic result/exception wrapper.
  *
  * However, there are some issues with throwing exceptions and
  * std::exception_ptr. These issues revolve around throw being expensive,
  * particularly in a multithreaded environment (see
  * ExceptionWrapperBenchmark.cpp).
  *
  * Imagine we have a library that has an API which returns a result/exception
  * wrapper. Let's consider some approaches for implementing this wrapper.
  * First, we could store a std::exception. This approach loses the derived
  * exception type, which can make exception handling more difficult for users
  * that prefer rethrowing the exception. We could use a folly::dynamic for every
  * possible type of exception. This is not very flexible - adding new types of
  * exceptions requires a change to the result/exception wrapper. We could use an
  * exception_ptr. However, constructing an exception_ptr as well as accessing
  * the error requires a call to throw. That means that there will be two calls
  * to throw in order to process the exception. For performance sensitive
  * applications, this may be unacceptable.
  *
  * exception_wrapper is designed to handle exception management for both
  * convenience and high performance use cases. make_exception_wrapper is
  * templated on derived type, allowing us to rethrow the exception properly for
  * users that prefer convenience. These explicitly named exception types can
  * therefore be handled without any peformance penalty.  exception_wrapper is
  * also flexible enough to accept any type. If a caught exception is not of an
  * explicitly named type, then std::exception_ptr is used to preserve the
  * exception state. For performance sensitive applications, the accessor methods
  * can test or extract a pointer to a specific exception type with very little
  * overhead.
  *
  * Example usage:
  *
  * exception_wrapper globalExceptionWrapper;
  *
  * // Thread1
  * void doSomethingCrazy() {
  *   int rc = doSomethingCrazyWithLameReturnCodes();
  *   if (rc == NAILED_IT) {
  *     globalExceptionWrapper = exception_wrapper();
  *   } else if (rc == FACE_PLANT) {
  *     globalExceptionWrapper = make_exception_wrapper<FacePlantException>();
  *   } else if (rc == FAIL_WHALE) {
  *     globalExceptionWrapper = make_exception_wrapper<FailWhaleException>();
  *   }
  * }
  *
  * // Thread2: Exceptions are ok!
  * void processResult() {
  *   try {
  *     globalExceptionWrapper.throwException();
  *   } catch (const FacePlantException& e) {
  *     LOG(ERROR) << "FACEPLANT!";
  *   } catch (const FailWhaleException& e) {
  *     LOG(ERROR) << "FAILWHALE!";
  *   }
  * }
  *
  * // Thread2: Exceptions are bad!
  * void processResult() {
  *   auto ep = globalExceptionWrapper.get();
  *   if (!ep.with_exception<FacePlantException>([&](
  *     FacePlantException& faceplant) {
  *       LOG(ERROR) << "FACEPLANT";
  *     })) {
  *     ep.with_exception<FailWhaleException>([&](
  *       FailWhaleException& failwhale) {
  *         LOG(ERROR) << "FAILWHALE!";
  *       });
  *   }
  * }
  *
  */
 class exception_wrapper {
  protected:
   template <typename Ex>
   struct optimize;

  public:
   exception_wrapper() = default;

   // Implicitly construct an exception_wrapper from a qualifying exception.
   // See the optimize struct for details.
   template <typename Ex, typename =
     typename std::enable_if<optimize<typename std::decay<Ex>::type>::value>
     ::type>
   /* implicit */ exception_wrapper(Ex&& exn) {
     typedef typename std::decay<Ex>::type DEx;
     item_ = std::make_shared<DEx>(std::forward<Ex>(exn));
     throwfn_ = folly::detail::Thrower<DEx>::doThrow;
   }

   // The following two constructors are meant to emulate the behavior of
   // try_and_catch in performance sensitive code as well as to be flexible
   // enough to wrap exceptions of unknown type. There is an overload that
   // takes an exception reference so that the wrapper can extract and store
   // the exception's type and what() when possible.
   //
   // The canonical use case is to construct an all-catching exception wrapper
   // with minimal overhead like so:
   //
   //   try {
   //     // some throwing code
   //   } catch (const std::exception& e) {
   //     // won't lose e's type and what()
   //     exception_wrapper ew{std::current_exception(), e};
   //   } catch (...) {
   //     // everything else
   //     exception_wrapper ew{std::current_exception()};
   //   }
   //
   // try_and_catch is cleaner and preferable. Use it unless you're sure you need
   // something like this instead.
   template <typename Ex>
   explicit exception_wrapper(std::exception_ptr eptr, Ex& exn) {
     assign_eptr(eptr, exn);
   }

   explicit exception_wrapper(std::exception_ptr eptr) {
     assign_eptr(eptr);
   }

   void throwException() const {
     if (throwfn_) {
       throwfn_(item_.get());
     } else if (eptr_) {
       std::rethrow_exception(eptr_);
     }
   }

   explicit operator bool() const {
     return item_ || eptr_;
   }

   // This implementation is similar to std::exception_ptr's implementation
   // where two exception_wrappers are equal when the address in the underlying
   // reference field both point to the same exception object.  The reference
   // field remains the same when the exception_wrapper is copied or when
   // the exception_wrapper is "rethrown".
   bool operator==(const exception_wrapper& a) const {
     if (item_) {
       return a.item_ && item_.get() == a.item_.get();
     } else {
       return eptr_ == a.eptr_;
     }
   }

   bool operator!=(const exception_wrapper& a) const {
     return !(*this == a);
   }

   // This will return a non-nullptr only if the exception is held as a
   // copy.  It is the only interface which will distinguish between an
   // exception held this way, and by exception_ptr.  You probably
   // shouldn't use it at all.
   std::exception* getCopied() { return item_.get(); }
   const std::exception* getCopied() const { return item_.get(); }

   fbstring what() const {
     if (item_) {
       return exceptionStr(*item_);
     } else if (eptr_) {
       return estr_;
     } else {
       return fbstring();
     }
   }

   fbstring class_name() const {
     if (item_) {
       auto& i = *item_;
       return demangle(typeid(i));
     } else if (eptr_) {
       return ename_;
     } else {
       return fbstring();
     }
   }

   template <class Ex>
   bool is_compatible_with() const {
     if (item_) {
       return dynamic_cast<const Ex*>(item_.get());
     } else if (eptr_) {
       try {
         std::rethrow_exception(eptr_);
       } catch (std::exception& e) {
         return dynamic_cast<const Ex*>(&e);
       } catch (...) {
         // fall through
       }
     }
     return false;
   }

   // If this exception wrapper wraps an exception of type Ex, with_exception
   // will call f with the wrapped exception as an argument and return true, and
   // will otherwise return false.
   template <class Ex, class F>
   typename std::enable_if<
     std::is_base_of<std::exception, typename std::decay<Ex>::type>::value,
     bool>::type
   with_exception(F f) {
     return with_exception1<typename std::decay<Ex>::type>(f, this);
   }

   // Const overload
   template <class Ex, class F>
   typename std::enable_if<
     std::is_base_of<std::exception, typename std::decay<Ex>::type>::value,
     bool>::type
   with_exception(F f) const {
     return with_exception1<const typename std::decay<Ex>::type>(f, this);
   }

   // Overload for non-exceptions. Always rethrows.
   template <class Ex, class F>
   typename std::enable_if<
     !std::is_base_of<std::exception, typename std::decay<Ex>::type>::value,
     bool>::type
   with_exception(F f) const {
     try {
       throwException();
     } catch (typename std::decay<Ex>::type& e) {
       f(e);
       return true;
     } catch (...) {
       // fall through
     }
     return false;
   }

   std::exception_ptr getExceptionPtr() const {
     if (eptr_) {
       return eptr_;
     }

     try {
       throwException();
     } catch (...) {
       return std::current_exception();
     }
     return std::exception_ptr();
   }

 protected:
   template <typename Ex>
   struct optimize {
     static const bool value =
       std::is_base_of<std::exception, Ex>::value &&
       std::is_copy_assignable<Ex>::value &&
       !std::is_abstract<Ex>::value;
   };

   template <typename Ex>
   void assign_eptr(std::exception_ptr eptr, Ex& e) {
     this->eptr_ = eptr;
     this->estr_ = exceptionStr(e).toStdString();
     this->ename_ = demangle(typeid(e)).toStdString();
   }

   void assign_eptr(std::exception_ptr eptr) {
     this->eptr_ = eptr;
   }

   // Optimized case: if we know what type the exception is, we can
   // store a copy of the concrete type, and a helper function so we
   // can rethrow it.
   std::shared_ptr<std::exception> item_;
   void (*throwfn_)(std::exception*){nullptr};
   // Fallback case: store the library wrapper, which is less efficient
   // but gets the job done.  Also store exceptionPtr() the name of the
   // exception type, so we can at least get those back out without
   // having to rethrow.
   std::exception_ptr eptr_;
   std::string estr_;
   std::string ename_;

   template <class T, class... Args>
   friend exception_wrapper make_exception_wrapper(Args&&... args);

 private:
   // What makes this useful is that T can be exception_wrapper* or
   // const exception_wrapper*, and the compiler will use the
   // instantiation which works with F.
   template <class Ex, class F, class T>
   static bool with_exception1(F f, T* that) {
     if (that->item_) {
       if (auto ex = dynamic_cast<Ex*>(that->item_.get())) {
         f(*ex);
         return true;
       }
     } else if (that->eptr_) {
       try {
         std::rethrow_exception(that->eptr_);
       } catch (std::exception& e) {
         if (auto ex = dynamic_cast<Ex*>(&e)) {
           f(*ex);
           return true;
         }
       } catch (...) {
         // fall through
       }
     }
     return false;
   }
 };

 template <class T, class... Args>
 exception_wrapper make_exception_wrapper(Args&&... args) {
   exception_wrapper ew;
   ew.item_ = std::make_shared<T>(std::forward<Args>(args)...);
   ew.throwfn_ = folly::detail::Thrower<T>::doThrow;
   return ew;
 }

 // For consistency with exceptionStr() functions in String.h
 inline fbstring exceptionStr(const exception_wrapper& ew) {
   return ew.what();
 }

 /*
  * try_and_catch is a simple replacement for try {} catch(){} that allows you to
  * specify which derived exceptions you would like to catch and store in an
  * exception_wrapper.
  *
  * Because we cannot build an equivalent of std::current_exception(), we need
  * to catch every derived exception that we are interested in catching.
  *
  * Exceptions should be listed in the reverse order that you would write your
  * catch statements (that is, std::exception& should be first).
  *
  * NOTE: Although implemented as a derived class (for syntactic delight), don't
  * be confused - you should not pass around try_and_catch objects!
  *
  * Example Usage:
  *
  * // This catches my runtime_error and if I call throwException() on ew, it
  * // will throw a runtime_error
  * auto ew = folly::try_and_catch<std::exception, std::runtime_error>([=]() {
  *   if (badThingHappens()) {
  *     throw std::runtime_error("ZOMG!");
  *   }
  * });
  *
  * // This will catch the exception and if I call throwException() on ew, it
  * // will throw a std::exception
  * auto ew = folly::try_and_catch<std::exception, std::runtime_error>([=]() {
  *   if (badThingHappens()) {
  *     throw std::exception();
  *   }
  * });
  *
  * // This will not catch the exception and it will be thrown.
  * auto ew = folly::try_and_catch<std::runtime_error>([=]() {
  *   if (badThingHappens()) {
  *     throw std::exception();
  *   }
  * });
  */

 template <typename... Exceptions>
 class try_and_catch;

 template <typename LastException, typename... Exceptions>
 class try_and_catch<LastException, Exceptions...> :
     public try_and_catch<Exceptions...> {
  public:
   template <typename F>
   explicit try_and_catch(F&& fn) : Base() {
     call_fn(fn);
   }

  protected:
   typedef try_and_catch<Exceptions...> Base;

   try_and_catch() : Base() {}

   template <typename Ex>
   typename std::enable_if<!exception_wrapper::optimize<Ex>::value>::type
   assign_exception(Ex& e, std::exception_ptr eptr) {
     exception_wrapper::assign_eptr(eptr, e);
   }

   template <typename Ex>
   typename std::enable_if<exception_wrapper::optimize<Ex>::value>::type
   assign_exception(Ex& e, std::exception_ptr /*eptr*/) {
     this->item_ = std::make_shared<Ex>(e);
     this->throwfn_ = folly::detail::Thrower<Ex>::doThrow;
   }

   template <typename F>
   void call_fn(F&& fn) {
     try {
       Base::call_fn(std::move(fn));
     } catch (LastException& e) {
       if (typeid(e) == typeid(LastException&)) {
         assign_exception(e, std::current_exception());
       } else {
         exception_wrapper::assign_eptr(std::current_exception(), e);
       }
     }
   }
 };

 template<>
 class try_and_catch<> : public exception_wrapper {
  public:
   try_and_catch() = default;

  protected:
   template <typename F>
   void call_fn(F&& fn) {
     fn();
   }
 };
 }
 #endif
	/*
	* 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.
	*/

	#ifndef FOLLY_EXCEPTIONWRAPPER_H
	#define FOLLY_EXCEPTIONWRAPPER_H

	#include <cassert>
	#include <exception>
	#include <memory>
	#include <folly/String.h>
	#include <folly/detail/ExceptionWrapper.h>

	namespace folly {

	/*
	* Throwing exceptions can be a convenient way to handle errors. Storing
	* exceptions in an exception_ptr makes it easy to handle exceptions in a
	* different thread or at a later time. exception_ptr can also be used in a very
	* generic result/exception wrapper.
	*
	* However, there are some issues with throwing exceptions and
	* std::exception_ptr. These issues revolve around throw being expensive,
	* particularly in a multithreaded environment (see
	* ExceptionWrapperBenchmark.cpp).
	*
	* Imagine we have a library that has an API which returns a result/exception
	* wrapper. Let's consider some approaches for implementing this wrapper.
	* First, we could store a std::exception. This approach loses the derived
	* exception type, which can make exception handling more difficult for users
	* that prefer rethrowing the exception. We could use a folly::dynamic for every
	* possible type of exception. This is not very flexible - adding new types of
	* exceptions requires a change to the result/exception wrapper. We could use an
	* exception_ptr. However, constructing an exception_ptr as well as accessing
	* the error requires a call to throw. That means that there will be two calls
	* to throw in order to process the exception. For performance sensitive
	* applications, this may be unacceptable.
	*
	* exception_wrapper is designed to handle exception management for both
	* convenience and high performance use cases. make_exception_wrapper is
	* templated on derived type, allowing us to rethrow the exception properly for
	* users that prefer convenience. These explicitly named exception types can
	* therefore be handled without any peformance penalty. exception_wrapper is
	* also flexible enough to accept any type. If a caught exception is not of an
	* explicitly named type, then std::exception_ptr is used to preserve the
	* exception state. For performance sensitive applications, the accessor methods
	* can test or extract a pointer to a specific exception type with very little
	* overhead.
	*
	* Example usage:
	*
	* exception_wrapper globalExceptionWrapper;
	*
	* // Thread1
	* void doSomethingCrazy() {
	* int rc = doSomethingCrazyWithLameReturnCodes();
	* if (rc == NAILED_IT) {
	* globalExceptionWrapper = exception_wrapper();
	* } else if (rc == FACE_PLANT) {
	* globalExceptionWrapper = make_exception_wrapper<FacePlantException>();
	* } else if (rc == FAIL_WHALE) {
	* globalExceptionWrapper = make_exception_wrapper<FailWhaleException>();
	* }
	* }
	*
	* // Thread2: Exceptions are ok!
	* void processResult() {
	* try {
	* globalExceptionWrapper.throwException();
	* } catch (const FacePlantException& e) {
	* LOG(ERROR) << "FACEPLANT!";
	* } catch (const FailWhaleException& e) {
	* LOG(ERROR) << "FAILWHALE!";
	* }
	* }
	*
	* // Thread2: Exceptions are bad!
	* void processResult() {
	* auto ep = globalExceptionWrapper.get();
	* if (!ep.with_exception<FacePlantException>([&](
	* FacePlantException& faceplant) {
	* LOG(ERROR) << "FACEPLANT";
	* })) {
	* ep.with_exception<FailWhaleException>([&](
	* FailWhaleException& failwhale) {
	* LOG(ERROR) << "FAILWHALE!";
	* });
	* }
	* }
	*
	*/
	class exception_wrapper {
	protected:
	template <typename Ex>
	struct optimize;

	public:
	exception_wrapper() = default;

	// Implicitly construct an exception_wrapper from a qualifying exception.
	// See the optimize struct for details.
	template <typename Ex, typename =
	typename std::enable_if<optimize<typename std::decay<Ex>::type>::value>
	::type>
	/* implicit */ exception_wrapper(Ex&& exn) {
	typedef typename std::decay<Ex>::type DEx;
	item_ = std::make_shared<DEx>(std::forward<Ex>(exn));
	throwfn_ = folly::detail::Thrower<DEx>::doThrow;
	}

	// The following two constructors are meant to emulate the behavior of
	// try_and_catch in performance sensitive code as well as to be flexible
	// enough to wrap exceptions of unknown type. There is an overload that
	// takes an exception reference so that the wrapper can extract and store
	// the exception's type and what() when possible.
	//
	// The canonical use case is to construct an all-catching exception wrapper
	// with minimal overhead like so:
	//
	// try {
	// // some throwing code
	// } catch (const std::exception& e) {
	// // won't lose e's type and what()
	// exception_wrapper ew{std::current_exception(), e};
	// } catch (...) {
	// // everything else
	// exception_wrapper ew{std::current_exception()};
	// }
	//
	// try_and_catch is cleaner and preferable. Use it unless you're sure you need
	// something like this instead.
	template <typename Ex>
	explicit exception_wrapper(std::exception_ptr eptr, Ex& exn) {
	assign_eptr(eptr, exn);
	}

	explicit exception_wrapper(std::exception_ptr eptr) {
	assign_eptr(eptr);
	}

	void throwException() const {
	if (throwfn_) {
	throwfn_(item_.get());
	} else if (eptr_) {
	std::rethrow_exception(eptr_);
	}
	}

	explicit operator bool() const {
	return item_ \|\| eptr_;
	}

	// This implementation is similar to std::exception_ptr's implementation
	// where two exception_wrappers are equal when the address in the underlying
	// reference field both point to the same exception object. The reference
	// field remains the same when the exception_wrapper is copied or when
	// the exception_wrapper is "rethrown".
	bool operator==(const exception_wrapper& a) const {
	if (item_) {
	return a.item_ && item_.get() == a.item_.get();
	} else {
	return eptr_ == a.eptr_;
	}
	}

	bool operator!=(const exception_wrapper& a) const {
	return !(*this == a);
	}

	// This will return a non-nullptr only if the exception is held as a
	// copy. It is the only interface which will distinguish between an
	// exception held this way, and by exception_ptr. You probably
	// shouldn't use it at all.
	std::exception* getCopied() { return item_.get(); }
	const std::exception* getCopied() const { return item_.get(); }

	fbstring what() const {
	if (item_) {
	return exceptionStr(*item_);
	} else if (eptr_) {
	return estr_;
	} else {
	return fbstring();
	}
	}

	fbstring class_name() const {
	if (item_) {
	auto& i = *item_;
	return demangle(typeid(i));
	} else if (eptr_) {
	return ename_;
	} else {
	return fbstring();
	}
	}

	template <class Ex>
	bool is_compatible_with() const {
	if (item_) {
	return dynamic_cast<const Ex*>(item_.get());
	} else if (eptr_) {
	try {
	std::rethrow_exception(eptr_);
	} catch (std::exception& e) {
	return dynamic_cast<const Ex*>(&e);
	} catch (...) {
	// fall through
	}
	}
	return false;
	}

	// If this exception wrapper wraps an exception of type Ex, with_exception
	// will call f with the wrapped exception as an argument and return true, and
	// will otherwise return false.
	template <class Ex, class F>
	typename std::enable_if<
	std::is_base_of<std::exception, typename std::decay<Ex>::type>::value,
	bool>::type
	with_exception(F f) {
	return with_exception1<typename std::decay<Ex>::type>(f, this);
	}

	// Const overload
	template <class Ex, class F>
	typename std::enable_if<
	std::is_base_of<std::exception, typename std::decay<Ex>::type>::value,
	bool>::type
	with_exception(F f) const {
	return with_exception1<const typename std::decay<Ex>::type>(f, this);
	}

	// Overload for non-exceptions. Always rethrows.
	template <class Ex, class F>
	typename std::enable_if<
	!std::is_base_of<std::exception, typename std::decay<Ex>::type>::value,
	bool>::type
	with_exception(F f) const {
	try {
	throwException();
	} catch (typename std::decay<Ex>::type& e) {
	f(e);
	return true;
	} catch (...) {
	// fall through
	}
	return false;
	}

	std::exception_ptr getExceptionPtr() const {
	if (eptr_) {
	return eptr_;
	}

	try {
	throwException();
	} catch (...) {
	return std::current_exception();
	}
	return std::exception_ptr();
	}

	protected:
	template <typename Ex>
	struct optimize {
	static const bool value =
	std::is_base_of<std::exception, Ex>::value &&
	std::is_copy_assignable<Ex>::value &&
	!std::is_abstract<Ex>::value;
	};

	template <typename Ex>
	void assign_eptr(std::exception_ptr eptr, Ex& e) {
	this->eptr_ = eptr;
	this->estr_ = exceptionStr(e).toStdString();
	this->ename_ = demangle(typeid(e)).toStdString();
	}

	void assign_eptr(std::exception_ptr eptr) {
	this->eptr_ = eptr;
	}

	// Optimized case: if we know what type the exception is, we can
	// store a copy of the concrete type, and a helper function so we
	// can rethrow it.
	std::shared_ptr<std::exception> item_;
	void (throwfn_)(std::exception){nullptr};
	// Fallback case: store the library wrapper, which is less efficient
	// but gets the job done. Also store exceptionPtr() the name of the
	// exception type, so we can at least get those back out without
	// having to rethrow.
	std::exception_ptr eptr_;
	std::string estr_;
	std::string ename_;

	template <class T, class... Args>
	friend exception_wrapper make_exception_wrapper(Args&&... args);

	private:
	// What makes this useful is that T can be exception_wrapper* or
	// const exception_wrapper*, and the compiler will use the
	// instantiation which works with F.
	template <class Ex, class F, class T>
	static bool with_exception1(F f, T* that) {
	if (that->item_) {
	if (auto ex = dynamic_cast<Ex*>(that->item_.get())) {
	f(*ex);
	return true;
	}
	} else if (that->eptr_) {
	try {
	std::rethrow_exception(that->eptr_);
	} catch (std::exception& e) {
	if (auto ex = dynamic_cast<Ex*>(&e)) {
	f(*ex);
	return true;
	}
	} catch (...) {
	// fall through
	}
	}
	return false;
	}
	};

	template <class T, class... Args>
	exception_wrapper make_exception_wrapper(Args&&... args) {
	exception_wrapper ew;
	ew.item_ = std::make_shared<T>(std::forward<Args>(args)...);
	ew.throwfn_ = folly::detail::Thrower<T>::doThrow;
	return ew;
	}

	// For consistency with exceptionStr() functions in String.h
	inline fbstring exceptionStr(const exception_wrapper& ew) {
	return ew.what();
	}

	/*
	* try_and_catch is a simple replacement for try {} catch(){} that allows you to
	* specify which derived exceptions you would like to catch and store in an
	* exception_wrapper.
	*
	* Because we cannot build an equivalent of std::current_exception(), we need
	* to catch every derived exception that we are interested in catching.
	*
	* Exceptions should be listed in the reverse order that you would write your
	* catch statements (that is, std::exception& should be first).
	*
	* NOTE: Although implemented as a derived class (for syntactic delight), don't
	* be confused - you should not pass around try_and_catch objects!
	*
	* Example Usage:
	*
	* // This catches my runtime_error and if I call throwException() on ew, it
	* // will throw a runtime_error
	* auto ew = folly::try_and_catch<std::exception, std::runtime_error>([=]() {
	* if (badThingHappens()) {
	* throw std::runtime_error("ZOMG!");
	* }
	* });
	*
	* // This will catch the exception and if I call throwException() on ew, it
	* // will throw a std::exception
	* auto ew = folly::try_and_catch<std::exception, std::runtime_error>([=]() {
	* if (badThingHappens()) {
	* throw std::exception();
	* }
	* });
	*
	* // This will not catch the exception and it will be thrown.
	* auto ew = folly::try_and_catch<std::runtime_error>([=]() {
	* if (badThingHappens()) {
	* throw std::exception();
	* }
	* });
	*/

	template <typename... Exceptions>
	class try_and_catch;

	template <typename LastException, typename... Exceptions>
	class try_and_catch<LastException, Exceptions...> :
	public try_and_catch<Exceptions...> {
	public:
	template <typename F>
	explicit try_and_catch(F&& fn) : Base() {
	call_fn(fn);
	}

	protected:
	typedef try_and_catch<Exceptions...> Base;

	try_and_catch() : Base() {}

	template <typename Ex>
	typename std::enable_if<!exception_wrapper::optimize<Ex>::value>::type
	assign_exception(Ex& e, std::exception_ptr eptr) {
	exception_wrapper::assign_eptr(eptr, e);
	}

	template <typename Ex>
	typename std::enable_if<exception_wrapper::optimize<Ex>::value>::type
	assign_exception(Ex& e, std::exception_ptr /eptr/) {
	this->item_ = std::make_shared<Ex>(e);
	this->throwfn_ = folly::detail::Thrower<Ex>::doThrow;
	}

	template <typename F>
	void call_fn(F&& fn) {
	try {
	Base::call_fn(std::move(fn));
	} catch (LastException& e) {
	if (typeid(e) == typeid(LastException&)) {
	assign_exception(e, std::current_exception());
	} else {
	exception_wrapper::assign_eptr(std::current_exception(), e);
	}
	}
	}
	};

	template<>
	class try_and_catch<> : public exception_wrapper {
	public:
	try_and_catch() = default;

	protected:
	template <typename F>
	void call_fn(F&& fn) {
	fn();
	}
	};
	}
	#endif