ecency-mobile/ios/Pods/Folly/folly/ExceptionWrapper.h
2019-05-29 14:32:35 +03:00

715 lines
27 KiB
C++

/*
* Copyright 2014-present 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: Eric Niebler <eniebler@fb.com>
*/
#pragma once
#include <cassert>
#include <cstdint>
#include <exception>
#include <iosfwd>
#include <memory>
#include <new>
#include <type_traits>
#include <typeinfo>
#include <utility>
#include <folly/CPortability.h>
#include <folly/Demangle.h>
#include <folly/ExceptionString.h>
#include <folly/FBString.h>
#include <folly/Portability.h>
#include <folly/Traits.h>
#include <folly/Utility.h>
#include <folly/lang/Assume.h>
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpragmas"
#pragma GCC diagnostic ignored "-Wpotentially-evaluated-expression"
// GCC gets confused about lambda scopes and issues shadow-local warnings for
// parameters in totally different functions.
FOLLY_GCC_DISABLE_NEW_SHADOW_WARNINGS
#endif
#define FOLLY_EXCEPTION_WRAPPER_H_INCLUDED
namespace folly {
#define FOLLY_REQUIRES_DEF(...) \
_t<std::enable_if<static_cast<bool>(__VA_ARGS__), long>>
#define FOLLY_REQUIRES(...) FOLLY_REQUIRES_DEF(__VA_ARGS__) = __LINE__
namespace exception_wrapper_detail {
template <template <class> class T, class... As>
using AllOf = StrictConjunction<T<As>...>;
template <bool If, class T>
using AddConstIf = _t<std::conditional<If, const T, T>>;
template <class Fn, class A>
FOLLY_ALWAYS_INLINE FOLLY_ATTR_VISIBILITY_HIDDEN auto fold(Fn&&, A&& a) {
return static_cast<A&&>(a);
}
template <class Fn, class A, class B, class... Bs>
FOLLY_ALWAYS_INLINE FOLLY_ATTR_VISIBILITY_HIDDEN auto
fold(Fn&& fn, A&& a, B&& b, Bs&&... bs) {
return fold(
// This looks like a use of fn after a move of fn, but in reality, this is
// just a cast and not a move. That's because regardless of which fold
// overload is selected, fn gets bound to a &&. Had fold taken fn by value
// there would indeed be a problem here.
static_cast<Fn&&>(fn),
static_cast<Fn&&>(fn)(static_cast<A&&>(a), static_cast<B&&>(b)),
static_cast<Bs&&>(bs)...);
}
} // namespace exception_wrapper_detail
//! 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.
//!
//! \par Example usage:
//! \par
//! \code
//! 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.throw_exception();
//! } catch (const FacePlantException& e) {
//! LOG(ERROR) << "FACEPLANT!";
//! } catch (const FailWhaleException& e) {
//! LOG(ERROR) << "FAILWHALE!";
//! }
//! }
//!
//! // Thread2: Exceptions are bad!
//! void processResult() {
//! globalExceptionWrapper.handle(
//! [&](FacePlantException& faceplant) {
//! LOG(ERROR) << "FACEPLANT";
//! },
//! [&](FailWhaleException& failwhale) {
//! LOG(ERROR) << "FAILWHALE!";
//! },
//! [](...) {
//! LOG(FATAL) << "Unrecognized exception";
//! });
//! }
//! \endcode
class exception_wrapper final {
private:
struct FOLLY_EXPORT AnyException : std::exception {
std::type_info const* typeinfo_;
template <class T>
/* implicit */ AnyException(T&& t) noexcept : typeinfo_(&typeid(t)) {}
};
template <class Fn>
struct arg_type_;
template <class Fn>
using arg_type = _t<arg_type_<Fn>>;
// exception_wrapper is implemented as a simple variant over four
// different representations:
// 0. Empty, no exception.
// 1. An small object stored in-situ.
// 2. A larger object stored on the heap and referenced with a
// std::shared_ptr.
// 3. A std::exception_ptr, together with either:
// a. A pointer to the referenced std::exception object, or
// b. A pointer to a std::type_info object for the referenced exception,
// or for an unspecified type if the type is unknown.
// This is accomplished with the help of a union and a pointer to a hand-
// rolled virtual table. This virtual table contains pointers to functions
// that know which field of the union is active and do the proper action.
// The class invariant ensures that the vtable ptr and the union stay in sync.
struct VTable {
void (*copy_)(exception_wrapper const*, exception_wrapper*);
void (*move_)(exception_wrapper*, exception_wrapper*);
void (*delete_)(exception_wrapper*);
void (*throw_)(exception_wrapper const*);
std::type_info const* (*type_)(exception_wrapper const*);
std::exception const* (*get_exception_)(exception_wrapper const*);
exception_wrapper (*get_exception_ptr_)(exception_wrapper const*);
};
[[noreturn]] static void onNoExceptionError(char const* name);
template <class Ret, class... Args>
static Ret noop_(Args...);
static std::type_info const* uninit_type_(exception_wrapper const*);
static VTable const uninit_;
template <class Ex>
using IsStdException = std::is_base_of<std::exception, _t<std::decay<Ex>>>;
template <bool B, class T>
using AddConstIf = exception_wrapper_detail::AddConstIf<B, T>;
template <class CatchFn>
using IsCatchAll =
std::is_same<arg_type<_t<std::decay<CatchFn>>>, AnyException>;
struct Unknown {};
// Sadly, with the gcc-4.9 platform, std::logic_error and std::runtime_error
// do not fit here. They also don't have noexcept copy-ctors, so the internal
// storage wouldn't be used anyway. For the gcc-5 platform, both logic_error
// and runtime_error can be safely stored internally.
struct Buffer {
using Storage =
_t<std::aligned_storage<2 * sizeof(void*), alignof(std::exception)>>;
Storage buff_;
Buffer() : buff_{} {}
template <class Ex, typename... As>
Buffer(in_place_type_t<Ex>, As&&... as_);
template <class Ex>
Ex& as() noexcept;
template <class Ex>
Ex const& as() const noexcept;
};
struct ThrownTag {};
struct InSituTag {};
struct OnHeapTag {};
template <class T>
using PlacementOf = _t<std::conditional<
!IsStdException<T>::value,
ThrownTag,
_t<std::conditional<
sizeof(T) <= sizeof(Buffer::Storage) &&
alignof(T) <= alignof(Buffer::Storage) &&
noexcept(T(std::declval<T&&>())) &&
noexcept(T(std::declval<T const&>())),
InSituTag,
OnHeapTag>>>>;
static std::exception const* as_exception_or_null_(std::exception const& ex);
static std::exception const* as_exception_or_null_(AnyException);
struct ExceptionPtr {
std::exception_ptr ptr_;
std::uintptr_t exception_or_type_; // odd for type_info
static_assert(
1 < alignof(std::exception) && 1 < alignof(std::type_info),
"Surprise! std::exception and std::type_info don't have alignment "
"greater than one. as_int_ below will not work!");
static std::uintptr_t as_int_(
std::exception_ptr const& ptr,
std::exception const& e) noexcept;
static std::uintptr_t as_int_(
std::exception_ptr const& ptr,
AnyException e) noexcept;
bool has_exception_() const;
std::exception const* as_exception_() const;
std::type_info const* as_type_() const;
static void copy_(exception_wrapper const* from, exception_wrapper* to);
static void move_(exception_wrapper* from, exception_wrapper* to);
static void delete_(exception_wrapper* that);
[[noreturn]] static void throw_(exception_wrapper const* that);
static std::type_info const* type_(exception_wrapper const* that);
static std::exception const* get_exception_(exception_wrapper const* that);
static exception_wrapper get_exception_ptr_(exception_wrapper const* that);
static VTable const ops_;
};
template <class Ex>
struct InPlace {
static_assert(IsStdException<Ex>::value, "only deriving std::exception");
static void copy_(exception_wrapper const* from, exception_wrapper* to);
static void move_(exception_wrapper* from, exception_wrapper* to);
static void delete_(exception_wrapper* that);
[[noreturn]] static void throw_(exception_wrapper const* that);
static std::type_info const* type_(exception_wrapper const*);
static std::exception const* get_exception_(exception_wrapper const* that);
static exception_wrapper get_exception_ptr_(exception_wrapper const* that);
static constexpr VTable const ops_{copy_,
move_,
delete_,
throw_,
type_,
get_exception_,
get_exception_ptr_};
};
struct SharedPtr {
struct Base {
std::type_info const* info_;
Base() = default;
explicit Base(std::type_info const& info) : info_(&info) {}
virtual ~Base() {}
virtual void throw_() const = 0;
virtual std::exception const* get_exception_() const noexcept = 0;
virtual exception_wrapper get_exception_ptr_() const noexcept = 0;
};
template <class Ex>
struct Impl final : public Base {
static_assert(IsStdException<Ex>::value, "only deriving std::exception");
Ex ex_;
Impl() = default;
// clang-format off
template <typename... As>
explicit Impl(As&&... as)
: Base{typeid(Ex)}, ex_(std::forward<As>(as)...) {}
[[noreturn]] void throw_() const override;
// clang-format on
std::exception const* get_exception_() const noexcept override;
exception_wrapper get_exception_ptr_() const noexcept override;
};
std::shared_ptr<Base> ptr_;
static void copy_(exception_wrapper const* from, exception_wrapper* to);
static void move_(exception_wrapper* from, exception_wrapper* to);
static void delete_(exception_wrapper* that);
[[noreturn]] static void throw_(exception_wrapper const* that);
static std::type_info const* type_(exception_wrapper const* that);
static std::exception const* get_exception_(exception_wrapper const* that);
static exception_wrapper get_exception_ptr_(exception_wrapper const* that);
static VTable const ops_;
};
union {
Buffer buff_{};
ExceptionPtr eptr_;
SharedPtr sptr_;
};
VTable const* vptr_{&uninit_};
template <class Ex, typename... As>
exception_wrapper(ThrownTag, in_place_type_t<Ex>, As&&... as);
template <class Ex, typename... As>
exception_wrapper(OnHeapTag, in_place_type_t<Ex>, As&&... as);
template <class Ex, typename... As>
exception_wrapper(InSituTag, in_place_type_t<Ex>, As&&... as);
template <class T>
struct IsRegularExceptionType
: StrictConjunction<
std::is_copy_constructible<T>,
Negation<std::is_base_of<exception_wrapper, T>>,
Negation<std::is_abstract<T>>> {};
template <class CatchFn, bool IsConst = false>
struct ExceptionTypeOf;
template <bool IsConst>
struct HandleReduce;
template <bool IsConst>
struct HandleStdExceptReduce;
template <class This, class... CatchFns>
static void handle_(std::false_type, This& this_, CatchFns&... fns);
template <class This, class... CatchFns>
static void handle_(std::true_type, This& this_, CatchFns&... fns);
template <class Ex, class This, class Fn>
static bool with_exception_(This& this_, Fn fn_);
public:
static exception_wrapper from_exception_ptr(
std::exception_ptr const& eptr) noexcept;
//! Default-constructs an empty `exception_wrapper`
//! \post `type() == none()`
exception_wrapper() noexcept {}
//! Move-constructs an `exception_wrapper`
//! \post `*this` contains the value of `that` prior to the move
//! \post `that.type() == none()`
exception_wrapper(exception_wrapper&& that) noexcept;
//! Copy-constructs an `exception_wrapper`
//! \post `*this` contains a copy of `that`, and `that` is unmodified
//! \post `type() == that.type()`
exception_wrapper(exception_wrapper const& that) noexcept;
//! Move-assigns an `exception_wrapper`
//! \pre `this != &that`
//! \post `*this` contains the value of `that` prior to the move
//! \post `that.type() == none()`
exception_wrapper& operator=(exception_wrapper&& that) noexcept;
//! Copy-assigns an `exception_wrapper`
//! \post `*this` contains a copy of `that`, and `that` is unmodified
//! \post `type() == that.type()`
exception_wrapper& operator=(exception_wrapper const& that) noexcept;
~exception_wrapper();
//! \pre `ptr` is empty, or it holds a reference to an exception that is not
//! derived from `std::exception`.
//! \post `!ptr || bool(*this)`
//! \post `hasThrownException() == true`
//! \post `type() == unknown()`
explicit exception_wrapper(std::exception_ptr ptr) noexcept;
//! \pre `ptr` holds a reference to `ex`.
//! \post `hasThrownException() == true`
//! \post `bool(*this)`
//! \post `type() == typeid(ex)`
template <class Ex>
exception_wrapper(std::exception_ptr ptr, Ex& ex) noexcept;
//! \pre `typeid(ex) == typeid(typename decay<Ex>::type)`
//! \post `bool(*this)`
//! \post `hasThrownException() == false`
//! \post `type() == typeid(ex)`
//! \note Exceptions of types derived from `std::exception` can be implicitly
//! converted to an `exception_wrapper`.
template <
class Ex,
class Ex_ = _t<std::decay<Ex>>,
FOLLY_REQUIRES(
Conjunction<IsStdException<Ex_>, IsRegularExceptionType<Ex_>>::value)>
/* implicit */ exception_wrapper(Ex&& ex);
//! \pre `typeid(ex) == typeid(typename decay<Ex>::type)`
//! \post `bool(*this)`
//! \post `hasThrownException() == false`
//! \post `type() == typeid(ex)`
//! \note Exceptions of types not derived from `std::exception` can still be
//! used to construct an `exception_wrapper`, but you must specify
//! `folly::in_place` as the first parameter.
template <
class Ex,
class Ex_ = _t<std::decay<Ex>>,
FOLLY_REQUIRES(IsRegularExceptionType<Ex_>::value)>
exception_wrapper(in_place_t, Ex&& ex);
template <
class Ex,
typename... As,
FOLLY_REQUIRES(IsRegularExceptionType<Ex>::value)>
exception_wrapper(in_place_type_t<Ex>, As&&... as);
//! Swaps the value of `*this` with the value of `that`
void swap(exception_wrapper& that) noexcept;
//! \return `true` if `*this` is holding an exception.
explicit operator bool() const noexcept;
//! \return `!bool(*this)`
bool operator!() const noexcept;
//! Make this `exception_wrapper` empty
//! \post `!*this`
void reset();
//! \return `true` if this `exception_wrapper` holds a reference to an
//! exception that was thrown (i.e., if it was constructed with
//! a `std::exception_ptr`, or if `to_exception_ptr()` was called on a
//! (non-const) reference to `*this`).
bool has_exception_ptr() const noexcept;
//! \return a pointer to the `std::exception` held by `*this`, if it holds
//! one; otherwise, returns `nullptr`.
//! \note This function does not mutate the `exception_wrapper` object.
//! \note This function never causes an exception to be thrown.
std::exception* get_exception() noexcept;
//! \overload
std::exception const* get_exception() const noexcept;
//! \returns a pointer to the `Ex` held by `*this`, if it holds an object
//! whose type `From` permits `std::is_convertible<From*, Ex*>`;
//! otherwise, returns `nullptr`.
//! \note This function does not mutate the `exception_wrapper` object.
//! \note This function may cause an exception to be thrown and immediately
//! caught internally, affecting runtime performance.
template <typename Ex>
Ex* get_exception() noexcept;
//! \overload
template <typename Ex>
Ex const* get_exception() const noexcept;
//! \return A `std::exception_ptr` that references either the exception held
//! by `*this`, or a copy of same.
//! \note This function may need to throw an exception to complete the action.
//! \note The non-const overload of this function mutates `*this` to cache the
//! computed `std::exception_ptr`; that is, this function may cause
//! `has_exception_ptr()` to change from `false` to `true`.
std::exception_ptr const& to_exception_ptr() noexcept;
//! \overload
std::exception_ptr to_exception_ptr() const noexcept;
//! \return the `typeid` of an unspecified type used by
//! `exception_wrapper::type()` to denote an empty `exception_wrapper`.
static std::type_info const& none() noexcept;
//! \return the `typeid` of an unspecified type used by
//! `exception_wrapper::type()` to denote an `exception_wrapper` that
//! holds an exception of unknown type.
static std::type_info const& unknown() noexcept;
//! Returns the `typeid` of the wrapped exception object. If there is no
//! wrapped exception object, returns `exception_wrapper::none()`. If
//! this instance wraps an exception of unknown type not derived from
//! `std::exception`, returns `exception_wrapper::unknown()`.
std::type_info const& type() const noexcept;
//! \return If `get_exception() != nullptr`, `class_name() + ": " +
//! get_exception()->what()`; otherwise, `class_name()`.
folly::fbstring what() const;
//! \return If `!*this`, the empty string; otherwise, if
//! `type() == unknown()`, the string `"<unknown exception>"`; otherwise,
//! the result of `type().name()` after demangling.
folly::fbstring class_name() const;
//! \tparam Ex The expression type to check for compatibility with.
//! \return `true` if and only if `*this` wraps an exception that would be
//! caught with a `catch(Ex const&)` clause.
//! \note If `*this` is empty, this function returns `false`.
template <class Ex>
bool is_compatible_with() const noexcept;
//! Throws the wrapped expression.
//! \pre `bool(*this)`
[[noreturn]] void throw_exception() const;
//! Throws the wrapped expression nested into another exception.
//! \pre `bool(*this)`
//! \tparam ex Exception in *this will be thrown nested into ex;
// see std::throw_with_nested() for details on this semantic.
template <class Ex>
[[noreturn]] void throw_with_nested(Ex&& ex) const;
//! Call `fn` with the wrapped exception (if any), if `fn` can accept it.
//! \par Example
//! \code
//! exception_wrapper ew{std::runtime_error("goodbye cruel world")};
//!
//! assert( ew.with_exception([](std::runtime_error& e){/*...*/}) );
//!
//! assert( !ew.with_exception([](int& e){/*...*/}) );
//!
//! assert( !exception_wrapper{}.with_exception([](int& e){/*...*/}) );
//! \endcode
//! \tparam Ex Optionally, the type of the exception that `fn` accepts.
//! \tparam Fn The type of a monomophic function object.
//! \param fn A function object to call with the wrapped exception
//! \return `true` if and only if `fn` was called.
//! \note Optionally, you may explicitly specify the type of the exception
//! that `fn` expects, as in
//! \code
//! ew.with_exception<std::runtime_error>([](auto&& e) { /*...*/; });
//! \endcode
//! \note The handler may or may not be invoked with an active exception.
//! **Do not try to rethrow the exception with `throw;` from within your
//! handler -- that is, a throw expression with no operand.** This may
//! cause your process to terminate. (It is perfectly ok to throw from
//! a handler so long as you specify the exception to throw, as in
//! `throw e;`.)
template <class Ex = void const, class Fn>
bool with_exception(Fn fn);
//! \overload
template <class Ex = void const, class Fn>
bool with_exception(Fn fn) const;
//! Handle the wrapped expression as if with a series of `catch` clauses,
//! propagating the exception if no handler matches.
//! \par Example
//! \code
//! exception_wrapper ew{std::runtime_error("goodbye cruel world")};
//!
//! ew.handle(
//! [&](std::logic_error const& e) {
//! LOG(DFATAL) << "ruh roh";
//! ew.throw_exception(); // rethrow the active exception without
//! // slicing it. Will not be caught by other
//! // handlers in this call.
//! },
//! [&](std::exception const& e) {
//! LOG(ERROR) << ew.what();
//! });
//! \endcode
//! In the above example, any exception _not_ derived from `std::exception`
//! will be propagated. To specify a catch-all clause, pass a lambda that
//! takes a C-style elipses, as in:
//! \code
//! ew.handle(/*...* /, [](...) { /* handle unknown exception */ } )
//! \endcode
//! \pre `!*this`
//! \tparam CatchFns... A pack of unary monomorphic function object types.
//! \param fns A pack of unary monomorphic function objects to be treated as
//! an ordered list of potential exception handlers.
//! \note The handlers may or may not be invoked with an active exception.
//! **Do not try to rethrow the exception with `throw;` from within your
//! handler -- that is, a throw expression with no operand.** This may
//! cause your process to terminate. (It is perfectly ok to throw from
//! a handler so long as you specify the exception to throw, as in
//! `throw e;`.)
template <class... CatchFns>
void handle(CatchFns... fns);
//! \overload
template <class... CatchFns>
void handle(CatchFns... fns) const;
};
template <class Ex>
constexpr exception_wrapper::VTable exception_wrapper::InPlace<Ex>::ops_;
/**
* \return An `exception_wrapper` that wraps an instance of type `Ex`
* that has been constructed with arguments `std::forward<As>(as)...`.
*/
template <class Ex, typename... As>
exception_wrapper make_exception_wrapper(As&&... as) {
return exception_wrapper{in_place_type<Ex>, std::forward<As>(as)...};
}
/**
* Inserts `ew.what()` into the ostream `sout`.
* \return `sout`
*/
template <class Ch>
std::basic_ostream<Ch>& operator<<(
std::basic_ostream<Ch>& sout,
exception_wrapper const& ew) {
return sout << ew.what();
}
/**
* Swaps the value of `a` with the value of `b`.
*/
inline void swap(exception_wrapper& a, exception_wrapper& b) noexcept {
a.swap(b);
}
// For consistency with exceptionStr() functions in ExceptionString.h
fbstring exceptionStr(exception_wrapper const& ew);
namespace detail {
template <typename F>
inline exception_wrapper try_and_catch_(F&& f) {
return (f(), exception_wrapper());
}
template <typename F, typename Ex, typename... Exs>
inline exception_wrapper try_and_catch_(F&& f) {
try {
return try_and_catch_<F, Exs...>(std::forward<F>(f));
} catch (Ex& ex) {
return exception_wrapper(std::current_exception(), ex);
}
}
} // namespace detail
//! `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).
//!
//! \par Example Usage:
//! \code
//! // This catches my runtime_error and if I call throw_exception() 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 throw_exception() 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();
//! }
//! });
//! \endcode
template <typename... Exceptions, typename F>
exception_wrapper try_and_catch(F&& fn) {
return detail::try_and_catch_<F, Exceptions...>(std::forward<F>(fn));
}
} // namespace folly
#include <folly/ExceptionWrapper-inl.h>
#undef FOLLY_REQUIRES
#undef FOLLY_REQUIRES_DEF
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif