ecency-mobile/ios/Pods/Folly/folly/Expected.h

1385 lines
44 KiB
C++

/*
* Copyright 2016 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.
*/
/**
* Like folly::Optional, but can store a value *or* and error.
*
* @author Eric Niebler (eniebler@fb.com)
*/
#pragma once
#include <cstddef>
#include <initializer_list>
#include <new>
#include <stdexcept>
#include <type_traits>
#include <utility>
#include <folly/Likely.h>
#include <folly/Portability.h>
#include <folly/Preprocessor.h>
#include <folly/Traits.h> // for construct_in_place_t
#include <folly/Unit.h>
#define FOLLY_EXPECTED_ID(X) FB_CONCATENATE(FB_CONCATENATE(Folly, X), __LINE__)
#define FOLLY_REQUIRES_IMPL(...) \
bool FOLLY_EXPECTED_ID(Requires) = false, \
typename std::enable_if< \
(FOLLY_EXPECTED_ID(Requires) || static_cast<bool>(__VA_ARGS__)), \
int>::type = 0
#define FOLLY_REQUIRES_TRAILING(...) , FOLLY_REQUIRES_IMPL(__VA_ARGS__)
#define FOLLY_REQUIRES(...) template <FOLLY_REQUIRES_IMPL(__VA_ARGS__)>
/**
* gcc-4.7 warns about use of uninitialized memory around the use of storage_
* even though this is explicitly initialized at each point.
*/
#if defined(__GNUC__) && !defined(__clang__)
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wuninitialized"
#pragma GCC diagnostic ignored "-Wpragmas"
#pragma GCC diagnostic ignored "-Wmaybe-uninitialized"
#endif // __GNUC__
namespace folly {
/**
* Forward declarations
*/
template <class Error>
class Unexpected;
template <class Error>
constexpr Unexpected<typename std::decay<Error>::type> makeUnexpected(Error&&);
template <class Value, class Error>
class Expected;
template <class Error, class Value>
constexpr Expected<typename std::decay<Value>::type, Error> makeExpected(
Value&&);
/**
* Alias for an Expected type's assiciated value_type
*/
template <class Expected>
using ExpectedValueType =
typename std::remove_reference<Expected>::type::value_type;
/**
* Alias for an Expected type's assiciated error_type
*/
template <class Expected>
using ExpectedErrorType =
typename std::remove_reference<Expected>::type::error_type;
// Details...
namespace expected_detail {
#ifdef _MSC_VER
// MSVC 2015 can't handle the StrictConjunction, so we have
// to use std::conjunction instead.
template <template <class...> class Trait, class... Ts>
using StrictAllOf = std::conjunction<Trait<Ts>...>;
#else
template <template <class...> class Trait, class... Ts>
using StrictAllOf = StrictConjunction<Trait<Ts>...>;
#endif
template <class T>
using IsCopyable = StrictConjunction<
std::is_copy_constructible<T>,
std::is_copy_assignable<T>>;
template <class T>
using IsMovable = StrictConjunction<
std::is_move_constructible<T>,
std::is_move_assignable<T>>;
template <class T>
using IsNothrowCopyable = StrictConjunction<
std::is_nothrow_copy_constructible<T>,
std::is_nothrow_copy_assignable<T>>;
template <class T>
using IsNothrowMovable = StrictConjunction<
std::is_nothrow_move_constructible<T>,
std::is_nothrow_move_assignable<T>>;
template <class From, class To>
using IsConvertible = StrictConjunction<
std::is_constructible<To, From>,
std::is_assignable<To&, From>>;
template <class T, class U>
auto doEmplaceAssign(int, T& t, U&& u) -> decltype(void(t = (U &&)u)) {
t = (U &&)u;
}
template <class T, class U>
auto doEmplaceAssign(long, T& t, U&& u) -> decltype(void(T((U &&)u))) {
t.~T();
::new ((void*)std::addressof(t)) T((U &&)u);
}
template <class T, class... Us>
auto doEmplaceAssign(int, T& t, Us&&... us)
-> decltype(void(t = T((Us &&)us...))) {
t = T((Us &&)us...);
}
template <class T, class... Us>
auto doEmplaceAssign(long, T& t, Us&&... us)
-> decltype(void(T((Us &&)us...))) {
t.~T();
::new ((void*)std::addressof(t)) T((Us &&)us...);
}
struct EmptyTag {};
struct ValueTag {};
struct ErrorTag {};
enum class Which : unsigned char { eEmpty, eValue, eError };
enum class StorageType { ePODStruct, ePODUnion, eUnion };
template <class Value, class Error>
constexpr StorageType getStorageType() {
return StrictAllOf<IsTriviallyCopyable, Value, Error>::value
? (sizeof(std::pair<Value, Error>) <= sizeof(void * [2]) &&
StrictAllOf<std::is_trivial, Value, Error>::value
? StorageType::ePODStruct
: StorageType::ePODUnion)
: StorageType::eUnion;
}
template <
class Value,
class Error,
StorageType = expected_detail::getStorageType<Value, Error>()> // ePODUnion
struct ExpectedStorage {
using value_type = Value;
using error_type = Error;
union {
Value value_;
Error error_;
char ch_;
};
Which which_;
template <class E = Error, class = decltype(E{})>
constexpr ExpectedStorage() noexcept(noexcept(E{}))
: error_{}, which_(Which::eError) {}
explicit constexpr ExpectedStorage(EmptyTag) noexcept
: ch_{}, which_(Which::eEmpty) {}
template <class... Vs>
explicit constexpr ExpectedStorage(ValueTag, Vs&&... vs) noexcept(
noexcept(Value(static_cast<Vs&&>(vs)...)))
: value_(static_cast<Vs&&>(vs)...), which_(Which::eValue) {}
template <class... Es>
explicit constexpr ExpectedStorage(ErrorTag, Es&&... es) noexcept(
noexcept(Error(static_cast<Es&&>(es)...)))
: error_(static_cast<Es&&>(es)...), which_(Which::eError) {}
void clear() noexcept {}
static constexpr bool uninitializedByException() noexcept {
// Although which_ may temporarily be eEmpty during construction, it
// is always either eValue or eError for a fully-constructed Expected.
return false;
}
template <class... Vs>
void assignValue(Vs&&... vs) {
expected_detail::doEmplaceAssign(0, value_, static_cast<Vs&&>(vs)...);
which_ = Which::eValue;
}
template <class... Es>
void assignError(Es&&... es) {
expected_detail::doEmplaceAssign(0, error_, static_cast<Es&&>(es)...);
which_ = Which::eError;
}
template <class Other>
void assign(Other&& that) {
switch (that.which_) {
case Which::eValue:
this->assignValue(static_cast<Other&&>(that).value());
break;
case Which::eError:
this->assignError(static_cast<Other&&>(that).error());
break;
default:
this->clear();
break;
}
}
Value& value() & {
return value_;
}
const Value& value() const& {
return value_;
}
Value&& value() && {
return std::move(value_);
}
Error& error() & {
return error_;
}
const Error& error() const& {
return error_;
}
Error&& error() && {
return std::move(error_);
}
};
template <class Value, class Error>
struct ExpectedUnion {
union {
Value value_;
Error error_;
char ch_{};
};
Which which_ = Which::eEmpty;
explicit constexpr ExpectedUnion(EmptyTag) noexcept {}
template <class... Vs>
explicit constexpr ExpectedUnion(ValueTag, Vs&&... vs) noexcept(
noexcept(Value(static_cast<Vs&&>(vs)...)))
: value_(static_cast<Vs&&>(vs)...), which_(Which::eValue) {}
template <class... Es>
explicit constexpr ExpectedUnion(ErrorTag, Es&&... es) noexcept(
noexcept(Error(static_cast<Es&&>(es)...)))
: error_(static_cast<Es&&>(es)...), which_(Which::eError) {}
ExpectedUnion(const ExpectedUnion&) {}
ExpectedUnion(ExpectedUnion&&) noexcept {}
ExpectedUnion& operator=(const ExpectedUnion&) {
return *this;
}
ExpectedUnion& operator=(ExpectedUnion&&) noexcept {
return *this;
}
~ExpectedUnion() {}
Value& value() & {
return value_;
}
const Value& value() const& {
return value_;
}
Value&& value() && {
return std::move(value_);
}
Error& error() & {
return error_;
}
const Error& error() const& {
return error_;
}
Error&& error() && {
return std::move(error_);
}
};
template <class Derived, bool, bool Noexcept>
struct CopyConstructible {
constexpr CopyConstructible() = default;
CopyConstructible(const CopyConstructible& that) noexcept(Noexcept) {
static_cast<Derived*>(this)->assign(static_cast<const Derived&>(that));
}
constexpr CopyConstructible(CopyConstructible&&) = default;
CopyConstructible& operator=(const CopyConstructible&) = default;
CopyConstructible& operator=(CopyConstructible&&) = default;
};
template <class Derived, bool Noexcept>
struct CopyConstructible<Derived, false, Noexcept> {
constexpr CopyConstructible() = default;
CopyConstructible(const CopyConstructible&) = delete;
constexpr CopyConstructible(CopyConstructible&&) = default;
CopyConstructible& operator=(const CopyConstructible&) = default;
CopyConstructible& operator=(CopyConstructible&&) = default;
};
template <class Derived, bool, bool Noexcept>
struct MoveConstructible {
constexpr MoveConstructible() = default;
constexpr MoveConstructible(const MoveConstructible&) = default;
MoveConstructible(MoveConstructible&& that) noexcept(Noexcept) {
static_cast<Derived*>(this)->assign(std::move(static_cast<Derived&>(that)));
}
MoveConstructible& operator=(const MoveConstructible&) = default;
MoveConstructible& operator=(MoveConstructible&&) = default;
};
template <class Derived, bool Noexcept>
struct MoveConstructible<Derived, false, Noexcept> {
constexpr MoveConstructible() = default;
constexpr MoveConstructible(const MoveConstructible&) = default;
MoveConstructible(MoveConstructible&&) = delete;
MoveConstructible& operator=(const MoveConstructible&) = default;
MoveConstructible& operator=(MoveConstructible&&) = default;
};
template <class Derived, bool, bool Noexcept>
struct CopyAssignable {
constexpr CopyAssignable() = default;
constexpr CopyAssignable(const CopyAssignable&) = default;
constexpr CopyAssignable(CopyAssignable&&) = default;
CopyAssignable& operator=(const CopyAssignable& that) noexcept(Noexcept) {
static_cast<Derived*>(this)->assign(static_cast<const Derived&>(that));
return *this;
}
CopyAssignable& operator=(CopyAssignable&&) = default;
};
template <class Derived, bool Noexcept>
struct CopyAssignable<Derived, false, Noexcept> {
constexpr CopyAssignable() = default;
constexpr CopyAssignable(const CopyAssignable&) = default;
constexpr CopyAssignable(CopyAssignable&&) = default;
CopyAssignable& operator=(const CopyAssignable&) = delete;
CopyAssignable& operator=(CopyAssignable&&) = default;
};
template <class Derived, bool, bool Noexcept>
struct MoveAssignable {
constexpr MoveAssignable() = default;
constexpr MoveAssignable(const MoveAssignable&) = default;
constexpr MoveAssignable(MoveAssignable&&) = default;
MoveAssignable& operator=(const MoveAssignable&) = default;
MoveAssignable& operator=(MoveAssignable&& that) noexcept(Noexcept) {
static_cast<Derived*>(this)->assign(std::move(static_cast<Derived&>(that)));
return *this;
}
};
template <class Derived, bool Noexcept>
struct MoveAssignable<Derived, false, Noexcept> {
constexpr MoveAssignable() = default;
constexpr MoveAssignable(const MoveAssignable&) = default;
constexpr MoveAssignable(MoveAssignable&&) = default;
MoveAssignable& operator=(const MoveAssignable&) = default;
MoveAssignable& operator=(MoveAssignable&& that) = delete;
};
template <class Value, class Error>
struct ExpectedStorage<Value, Error, StorageType::eUnion>
: ExpectedUnion<Value, Error>,
CopyConstructible<
ExpectedStorage<Value, Error, StorageType::eUnion>,
StrictAllOf<std::is_copy_constructible, Value, Error>::value,
StrictAllOf<std::is_nothrow_copy_constructible, Value, Error>::value>,
MoveConstructible<
ExpectedStorage<Value, Error, StorageType::eUnion>,
StrictAllOf<std::is_move_constructible, Value, Error>::value,
StrictAllOf<std::is_nothrow_move_constructible, Value, Error>::value>,
CopyAssignable<
ExpectedStorage<Value, Error, StorageType::eUnion>,
StrictAllOf<IsCopyable, Value, Error>::value,
StrictAllOf<IsNothrowCopyable, Value, Error>::value>,
MoveAssignable<
ExpectedStorage<Value, Error, StorageType::eUnion>,
StrictAllOf<IsMovable, Value, Error>::value,
StrictAllOf<IsNothrowMovable, Value, Error>::value> {
using value_type = Value;
using error_type = Error;
using Base = ExpectedUnion<Value, Error>;
template <class E = Error, class = decltype(E{})>
constexpr ExpectedStorage() noexcept(noexcept(E{})) : Base{ErrorTag{}} {}
ExpectedStorage(const ExpectedStorage&) = default;
ExpectedStorage(ExpectedStorage&&) = default;
ExpectedStorage& operator=(const ExpectedStorage&) = default;
ExpectedStorage& operator=(ExpectedStorage&&) = default;
using ExpectedUnion<Value, Error>::ExpectedUnion;
~ExpectedStorage() {
clear();
}
void clear() noexcept {
switch (this->which_) {
case Which::eValue:
this->value().~Value();
break;
case Which::eError:
this->error().~Error();
break;
default:
break;
}
this->which_ = Which::eEmpty;
}
bool uninitializedByException() const noexcept {
return this->which_ == Which::eEmpty;
}
template <class... Vs>
void assignValue(Vs&&... vs) {
if (this->which_ == Which::eValue) {
expected_detail::doEmplaceAssign(
0, this->value(), static_cast<Vs&&>(vs)...);
} else {
this->clear();
::new ((void*)std::addressof(this->value()))
Value(static_cast<Vs&&>(vs)...);
this->which_ = Which::eValue;
}
}
template <class... Es>
void assignError(Es&&... es) {
if (this->which_ == Which::eError) {
expected_detail::doEmplaceAssign(
0, this->error(), static_cast<Es&&>(es)...);
} else {
this->clear();
::new ((void*)std::addressof(this->error()))
Error(static_cast<Es&&>(es)...);
this->which_ = Which::eError;
}
}
bool isThis(const ExpectedStorage* that) const {
return this == that;
}
constexpr bool isSelfAssign(const void*) const {
return false;
}
template <class Other>
void assign(Other&& that) {
if (isSelfAssign(&that))
return;
switch (that.which_) {
case Which::eValue:
this->assignValue(static_cast<Other&&>(that).value());
break;
case Which::eError:
this->assignError(static_cast<Other&&>(that).error());
break;
default:
this->clear();
break;
}
}
};
// For small (pointer-sized) trivial types, a struct is faster than a union.
template <class Value, class Error>
struct ExpectedStorage<Value, Error, StorageType::ePODStruct> {
using value_type = Value;
using error_type = Error;
Which which_;
Error error_;
Value value_;
constexpr ExpectedStorage() noexcept
: which_(Which::eError), error_{}, value_{} {}
explicit constexpr ExpectedStorage(EmptyTag) noexcept
: which_(Which::eEmpty), error_{}, value_{} {}
template <class... Vs>
explicit constexpr ExpectedStorage(ValueTag, Vs&&... vs) noexcept(
noexcept(Value(static_cast<Vs&&>(vs)...)))
: which_(Which::eValue), error_{}, value_(static_cast<Vs&&>(vs)...) {}
template <class... Es>
explicit constexpr ExpectedStorage(ErrorTag, Es&&... es) noexcept(
noexcept(Error(static_cast<Es&&>(es)...)))
: which_(Which::eError), error_(static_cast<Es&&>(es)...), value_{} {}
void clear() noexcept {}
constexpr static bool uninitializedByException() noexcept {
return false;
}
template <class... Vs>
void assignValue(Vs&&... vs) {
expected_detail::doEmplaceAssign(0, value_, static_cast<Vs&&>(vs)...);
which_ = Which::eValue;
}
template <class... Es>
void assignError(Es&&... es) {
expected_detail::doEmplaceAssign(0, error_, static_cast<Es&&>(es)...);
which_ = Which::eError;
}
template <class Other>
void assign(Other&& that) {
switch (that.which_) {
case Which::eValue:
this->assignValue(static_cast<Other&&>(that).value());
break;
case Which::eError:
this->assignError(static_cast<Other&&>(that).error());
break;
default:
this->clear();
break;
}
}
Value& value() & {
return value_;
}
const Value& value() const& {
return value_;
}
Value&& value() && {
return std::move(value_);
}
Error& error() & {
return error_;
}
const Error& error() const& {
return error_;
}
Error&& error() && {
return std::move(error_);
}
};
namespace expected_detail_ExpectedHelper {
// Tricky hack so that Expected::then can handle lambdas that return void
template <class T>
inline T&& operator,(T&& t, Unit) noexcept {
return static_cast<T&&>(t);
}
struct ExpectedHelper {
template <class Error, class T>
static constexpr Expected<T, Error> return_(T t) {
return folly::makeExpected<Error>(t);
}
template <
class Error,
class T,
class U FOLLY_REQUIRES_TRAILING(
expected_detail::IsConvertible<U&&, Error>::value)>
static constexpr Expected<T, Error> return_(Expected<T, U> t) {
return t;
}
template <class This>
static typename std::decay<This>::type then_(This&& ex) {
return static_cast<This&&>(ex);
}
FOLLY_PUSH_WARNING
// Don't warn about not using the overloaded comma operator.
FOLLY_MSVC_DISABLE_WARNING(4913)
template <
class This,
class Fn,
class... Fns,
class E = ExpectedErrorType<This>,
class T = ExpectedHelper>
static auto then_(This&& ex, Fn&& fn, Fns&&... fns) -> decltype(T::then_(
T::template return_<E>(
(std::declval<Fn>()(std::declval<This>().value()), unit)),
std::declval<Fns>()...)) {
if (LIKELY(ex.which_ == expected_detail::Which::eValue))
return T::then_(
T::template return_<E>(
// Uses the comma operator defined above IFF the lambda
// returns non-void.
(static_cast<Fn&&>(fn)(static_cast<This&&>(ex).value()), unit)),
static_cast<Fns&&>(fns)...);
return makeUnexpected(static_cast<This&&>(ex).error());
}
template <
class This,
class Yes,
class No,
class Ret = decltype(std::declval<Yes>()(std::declval<This>().value())),
class Err = decltype(std::declval<No>()(std::declval<This>().error()))
FOLLY_REQUIRES_TRAILING(!std::is_void<Err>::value)>
static Ret thenOrThrow_(This&& ex, Yes&& yes, No&& no) {
if (LIKELY(ex.which_ == expected_detail::Which::eValue))
return Ret(static_cast<Yes&&>(yes)(static_cast<This&&>(ex).value()));
throw static_cast<No&&>(no)(static_cast<This&&>(ex).error());
}
template <
class This,
class Yes,
class No,
class Ret = decltype(std::declval<Yes>()(std::declval<This>().value())),
class Err = decltype(std::declval<No>()(std::declval<This&>().error()))
FOLLY_REQUIRES_TRAILING(std::is_void<Err>::value)>
static Ret thenOrThrow_(This&& ex, Yes&& yes, No&& no) {
if (LIKELY(ex.which_ == expected_detail::Which::eValue))
return Ret(static_cast<Yes&&>(yes)(static_cast<This&&>(ex).value()));
static_cast<No&&>(no)(ex.error());
throw typename Unexpected<ExpectedErrorType<This>>::MakeBadExpectedAccess()(
static_cast<This&&>(ex).error());
}
FOLLY_POP_WARNING
};
}
/* using override */ using expected_detail_ExpectedHelper::ExpectedHelper;
struct UnexpectedTag {};
} // namespace expected_detail
using unexpected_t =
expected_detail::UnexpectedTag (&)(expected_detail::UnexpectedTag);
inline expected_detail::UnexpectedTag unexpected(
expected_detail::UnexpectedTag = {}) {
return {};
}
/**
* An exception type thrown by Expected on catastrophic logic errors.
*/
class BadExpectedAccess : public std::logic_error {
public:
BadExpectedAccess() : std::logic_error("bad Expected access") {}
};
/**
* Unexpected - a helper type used to disambiguate the construction of
* Expected objects in the error state.
*/
template <class Error>
class Unexpected final {
template <class E>
friend class Unexpected;
template <class V, class E>
friend class Expected;
friend struct expected_detail::ExpectedHelper;
public:
/**
* Unexpected::BadExpectedAccess - An exception type thrown by Expected
* when the user tries to access the nested value but the Expected object is
* actually storing an error code.
*/
class BadExpectedAccess : public folly::BadExpectedAccess {
public:
explicit BadExpectedAccess(Error err)
: folly::BadExpectedAccess{}, error_(std::move(err)) {}
/**
* The error code that was held by the Expected object when the user
* erroneously requested the value.
*/
Error error() const {
return error_;
}
private:
Error error_;
};
/**
* Constructors
*/
Unexpected() = default;
Unexpected(const Unexpected&) = default;
Unexpected(Unexpected&&) = default;
Unexpected& operator=(const Unexpected&) = default;
Unexpected& operator=(Unexpected&&) = default;
constexpr /* implicit */ Unexpected(const Error& err) : error_(err) {}
constexpr /* implicit */ Unexpected(Error&& err) : error_(std::move(err)) {}
template <class Other FOLLY_REQUIRES_TRAILING(
std::is_constructible<Error, Other&&>::value)>
constexpr /* implicit */ Unexpected(Unexpected<Other> that)
: error_(std::move(that.error())) {}
/**
* Assignment
*/
template <class Other FOLLY_REQUIRES_TRAILING(
std::is_assignable<Error&, Other&&>::value)>
Unexpected& operator=(Unexpected<Other> that) {
error_ = std::move(that.error());
}
/**
* Observers
*/
Error& error() & {
return error_;
}
const Error& error() const& {
return error_;
}
Error&& error() && {
return std::move(error_);
}
private:
struct MakeBadExpectedAccess {
template <class E>
BadExpectedAccess operator()(E&& err) const {
return BadExpectedAccess(static_cast<E&&>(err));
}
};
Error error_;
};
template <
class Error FOLLY_REQUIRES_TRAILING(IsEqualityComparable<Error>::value)>
inline bool operator==(
const Unexpected<Error>& lhs,
const Unexpected<Error>& rhs) {
return lhs.error() == rhs.error();
}
template <
class Error FOLLY_REQUIRES_TRAILING(IsEqualityComparable<Error>::value)>
inline bool operator!=(
const Unexpected<Error>& lhs,
const Unexpected<Error>& rhs) {
return !(lhs == rhs);
}
/**
* For constructing an Unexpected object from an error code. Unexpected objects
* are implicitly convertible to Expected object in the error state. Usage is
* as follows:
*
* enum class MyErrorCode { BAD_ERROR, WORSE_ERROR };
* Expected<int, MyErrorCode> myAPI() {
* int i = // ...;
* return i ? makeExpected<MyErrorCode>(i)
* : makeUnexpected(MyErrorCode::BAD_ERROR);
* }
*/
template <class Error>
constexpr Unexpected<typename std::decay<Error>::type> makeUnexpected(
Error&& err) {
return Unexpected<typename std::decay<Error>::type>{
static_cast<Error&&>(err)};
}
/**
* Expected - For holding a value or an error. Useful as an alternative to
* exceptions, for APIs where throwing on failure would be too expensive.
*
* Expected<Value, Error> is a variant over the types Value and Error.
*
* Expected does not offer support for references. Use
* Expected<std::reference_wrapper<T>, Error> if your API needs to return a
* reference or an error.
*
* Expected offers a continuation-based interface to reduce the boilerplate
* of checking error codes. The Expected::then member function takes a lambda
* that is to execute should the Expected object contain a value. The return
* value of the lambda is wrapped in an Expected and returned. If the lambda is
* not executed because the Expected contains an error, the error is returned
* immediately in a new Expected object.
*
* Expected<int, Error> funcTheFirst();
* Expected<std::string, Error> funcTheSecond() {
* return funcTheFirst().then([](int i) { return std::to_string(i); });
* }
*
* The above line of code could more verbosely written as:
*
* Expected<std::string, Error> funcTheSecond() {
* if (auto ex = funcTheFirst()) {
* return std::to_string(*ex);
* }
* return makeUnexpected(ex.error());
* }
*
* Continuations can chain, like:
*
* Expected<D, Error> maybeD = someFunc()
* .then([](A a){return B(a);})
* .then([](B b){return C(b);})
* .then([](C c){return D(c);});
*
* To avoid the redundant error checking that would happen if a call at the
* front of the chain returns an error, these call chains can be collaped into
* a single call to .then:
*
* Expected<D, Error> maybeD = someFunc()
* .then([](A a){return B(a);},
* [](B b){return C(b);},
* [](C c){return D(c);});
*
* The result of .then() is wrapped into Expected< ~, Error > if it isn't
* of that form already. Consider the following code:
*
* extern Expected<std::string, Error> readLineFromIO();
* extern Expected<int, Error> parseInt(std::string);
* extern int increment(int);
*
* Expected<int, Error> x = readLineFromIO().then(parseInt).then(increment);
*
* From the code above, we see that .then() works both with functions that
* return an Expected< ~, Error > (like parseInt) and with ones that return
* a plain value (like increment). In the case of parseInt, .then() returns
* the result of parseInt as-is. In the case of increment, it wraps the int
* that increment returns into an Expected< int, Error >.
*
* Sometimes when using a continuation you would prefer an exception to be
* thrown for a value-less Expected. For that you can use .thenOrThrow, as
* follows:
*
* B b = someFunc()
* .thenOrThrow([](A a){return B(a);});
*
* The above call to thenOrThrow will invoke the lambda if the Expected returned
* by someFunc() contains a value. Otherwise, it will throw an exception of type
* Unexpected<Error>::BadExpectedAccess. If you prefer it throw an exception of
* a different type, you can pass a second lambda to thenOrThrow:
*
* B b = someFunc()
* .thenOrThrow([](A a){return B(a);},
* [](Error e) {throw MyException(e);});
*
* Like C++17's std::variant, Expected offers the almost-never-empty guarantee;
* that is, an Expected<Value, Error> almost always contains either a Value or
* and Error. Partially-formed Expected objects occur when an assignment to
* an Expected object that would change the type of the contained object (Value-
* to-Error or vice versa) throws. Trying to access either the contained value
* or error object causes Expected to throw folly::BadExpectedAccess.
*
* Expected models OptionalPointee, so calling 'get_pointer(ex)' will return a
* pointer to nullptr if the 'ex' is in the error state, and a pointer to the
* value otherwise:
*
* Expected<int, Error> maybeInt = ...;
* if (int* v = get_pointer(maybeInt)) {
* cout << *v << endl;
* }
*/
template <class Value, class Error>
class Expected final : expected_detail::ExpectedStorage<Value, Error> {
template <class, class>
friend class Expected;
template <class, class, expected_detail::StorageType>
friend struct expected_detail::ExpectedStorage;
friend struct expected_detail::ExpectedHelper;
using Base = expected_detail::ExpectedStorage<Value, Error>;
using MakeBadExpectedAccess =
typename Unexpected<Error>::MakeBadExpectedAccess;
Base& base() & {
return *this;
}
const Base& base() const& {
return *this;
}
Base&& base() && {
return std::move(*this);
}
public:
using value_type = Value;
using error_type = Error;
using IsTriviallyCopyable = typename expected_detail::
StrictAllOf<IsTriviallyCopyable, Value, Error>::type;
template <class U>
using rebind = Expected<U, Error>;
static_assert(
!std::is_reference<Value>::value,
"Expected may not be used with reference types");
static_assert(
!std::is_abstract<Value>::value,
"Expected may not be used with abstract types");
/*
* Constructors
*/
template <class B = Base, class = decltype(B{})>
Expected() noexcept(noexcept(B{})) : Base{} {}
Expected(const Expected& that) = default;
Expected(Expected&& that) = default;
template <
class V,
class E FOLLY_REQUIRES_TRAILING(
!std::is_same<Expected<V, E>, Expected>::value &&
std::is_constructible<Value, V&&>::value &&
std::is_constructible<Error, E&&>::value)>
Expected(Expected<V, E> that) : Base{expected_detail::EmptyTag{}} {
*this = std::move(that);
}
FOLLY_REQUIRES(std::is_copy_constructible<Value>::value)
constexpr /* implicit */ Expected(const Value& val) noexcept(
noexcept(Value(val)))
: Base{expected_detail::ValueTag{}, val} {}
FOLLY_REQUIRES(std::is_move_constructible<Value>::value)
constexpr /* implicit */ Expected(Value&& val) noexcept(
noexcept(Value(std::move(val))))
: Base{expected_detail::ValueTag{}, std::move(val)} {}
template <class T FOLLY_REQUIRES_TRAILING(
std::is_convertible<T, Value>::value &&
!std::is_convertible<T, Error>::value)>
constexpr /* implicit */ Expected(T&& val) noexcept(
noexcept(Value(static_cast<T&&>(val))))
: Base{expected_detail::ValueTag{}, static_cast<T&&>(val)} {}
template <class... Ts FOLLY_REQUIRES_TRAILING(
std::is_constructible<Value, Ts&&...>::value)>
explicit constexpr Expected(in_place_t, Ts&&... ts) noexcept(
noexcept(Value(std::declval<Ts>()...)))
: Base{expected_detail::ValueTag{}, static_cast<Ts&&>(ts)...} {}
template <
class U,
class... Ts FOLLY_REQUIRES_TRAILING(
std::is_constructible<Value, std::initializer_list<U>&, Ts&&...>::
value)>
explicit constexpr Expected(
in_place_t,
std::initializer_list<U> il,
Ts&&... ts) noexcept(noexcept(Value(std::declval<Ts>()...)))
: Base{expected_detail::ValueTag{}, il, static_cast<Ts&&>(ts)...} {}
// If overload resolution selects one of these deleted functions, that
// means you need to use makeUnexpected
/* implicit */ Expected(const Error&) = delete;
/* implicit */ Expected(Error&&) = delete;
FOLLY_REQUIRES(std::is_copy_constructible<Error>::value)
constexpr Expected(unexpected_t, const Error& err) noexcept(
noexcept(Error(err)))
: Base{expected_detail::ErrorTag{}, err} {}
FOLLY_REQUIRES(std::is_move_constructible<Error>::value)
constexpr Expected(unexpected_t, Error&& err) noexcept(
noexcept(Error(std::move(err))))
: Base{expected_detail::ErrorTag{}, std::move(err)} {}
FOLLY_REQUIRES(std::is_copy_constructible<Error>::value)
constexpr /* implicit */ Expected(const Unexpected<Error>& err) noexcept(
noexcept(Error(err.error())))
: Base{expected_detail::ErrorTag{}, err.error()} {}
FOLLY_REQUIRES(std::is_move_constructible<Error>::value)
constexpr /* implicit */ Expected(Unexpected<Error>&& err) noexcept(
noexcept(Error(std::move(err.error()))))
: Base{expected_detail::ErrorTag{}, std::move(err.error())} {}
/*
* Assignment operators
*/
Expected& operator=(const Expected& that) = default;
Expected& operator=(Expected&& that) = default;
template <
class V,
class E FOLLY_REQUIRES_TRAILING(
!std::is_same<Expected<V, E>, Expected>::value &&
expected_detail::IsConvertible<V&&, Value>::value &&
expected_detail::IsConvertible<E&&, Error>::value)>
Expected& operator=(Expected<V, E> that) {
this->assign(std::move(that));
return *this;
}
FOLLY_REQUIRES(expected_detail::IsCopyable<Value>::value)
Expected& operator=(const Value& val) noexcept(
expected_detail::IsNothrowCopyable<Value>::value) {
this->assignValue(val);
return *this;
}
FOLLY_REQUIRES(expected_detail::IsMovable<Value>::value)
Expected& operator=(Value&& val) noexcept(
expected_detail::IsNothrowMovable<Value>::value) {
this->assignValue(std::move(val));
return *this;
}
template <class T FOLLY_REQUIRES_TRAILING(
std::is_convertible<T, Value>::value &&
!std::is_convertible<T, Error>::value)>
Expected& operator=(T&& val) {
this->assignValue(static_cast<T&&>(val));
return *this;
}
FOLLY_REQUIRES(expected_detail::IsCopyable<Error>::value)
Expected& operator=(const Unexpected<Error>& err) noexcept(
expected_detail::IsNothrowCopyable<Error>::value) {
this->assignError(err.error());
return *this;
}
FOLLY_REQUIRES(expected_detail::IsMovable<Error>::value)
Expected& operator=(Unexpected<Error>&& err) noexcept(
expected_detail::IsNothrowMovable<Error>::value) {
this->assignError(std::move(err.error()));
return *this;
}
template <class... Ts FOLLY_REQUIRES_TRAILING(
std::is_constructible<Value, Ts&&...>::value)>
void emplace(Ts&&... ts) {
this->assignValue(static_cast<Ts&&>(ts)...);
}
/**
* swap
*/
void swap(Expected& that) noexcept(
expected_detail::StrictAllOf<IsNothrowSwappable, Value, Error>::value) {
if (this->uninitializedByException() || that.uninitializedByException())
throw BadExpectedAccess();
using std::swap;
if (*this) {
if (that) {
swap(this->value_, that.value_);
} else {
Error e(std::move(that.error_));
that.assignValue(std::move(this->value_));
this->assignError(std::move(e));
}
} else {
if (!that) {
swap(this->error_, that.error_);
} else {
Error e(std::move(this->error_));
this->assignValue(std::move(that.value_));
that.assignError(std::move(e));
}
}
}
// If overload resolution selects one of these deleted functions, that
// means you need to use makeUnexpected
/* implicit */ Expected& operator=(const Error&) = delete;
/* implicit */ Expected& operator=(Error&&) = delete;
/**
* Relational Operators
*/
template <class Val, class Err>
friend typename std::enable_if<IsEqualityComparable<Val>::value, bool>::type
operator==(const Expected<Val, Err>& lhs, const Expected<Val, Err>& rhs);
template <class Val, class Err>
friend typename std::enable_if<IsLessThanComparable<Val>::value, bool>::type
operator<(const Expected<Val, Err>& lhs, const Expected<Val, Err>& rhs);
/*
* Accessors
*/
constexpr bool hasValue() const noexcept {
return expected_detail::Which::eValue == this->which_;
}
constexpr bool hasError() const noexcept {
return expected_detail::Which::eError == this->which_;
}
using Base::uninitializedByException;
const Value& value() const& {
requireValue();
return this->Base::value();
}
Value& value() & {
requireValue();
return this->Base::value();
}
Value&& value() && {
requireValue();
return std::move(this->Base::value());
}
const Error& error() const& {
requireError();
return this->Base::error();
}
Error& error() & {
requireError();
return this->Base::error();
}
Error&& error() && {
requireError();
return std::move(this->Base::error());
}
// Return a copy of the value if set, or a given default if not.
template <class U>
Value value_or(U&& dflt) const& {
if (LIKELY(this->which_ == expected_detail::Which::eValue)) {
return this->value_;
}
return static_cast<U&&>(dflt);
}
template <class U>
Value value_or(U&& dflt) && {
if (LIKELY(this->which_ == expected_detail::Which::eValue)) {
return std::move(this->value_);
}
return static_cast<U&&>(dflt);
}
explicit constexpr operator bool() const noexcept {
return hasValue();
}
const Value& operator*() const& {
return this->value();
}
Value& operator*() & {
return this->value();
}
Value&& operator*() && {
return std::move(this->value());
}
const Value* operator->() const {
return std::addressof(this->value());
}
Value* operator->() {
return std::addressof(this->value());
}
const Value* get_pointer() const& noexcept {
return hasValue() ? std::addressof(this->value_) : nullptr;
}
Value* get_pointer() & noexcept {
return hasValue() ? std::addressof(this->value_) : nullptr;
}
Value* get_pointer() && = delete;
/**
* then
*/
template <class... Fns FOLLY_REQUIRES_TRAILING(sizeof...(Fns) >= 1)>
auto then(Fns&&... fns) const& -> decltype(
expected_detail::ExpectedHelper::then_(
std::declval<const Base&>(),
std::declval<Fns>()...)) {
if (this->uninitializedByException())
throw BadExpectedAccess();
return expected_detail::ExpectedHelper::then_(
base(), static_cast<Fns&&>(fns)...);
}
template <class... Fns FOLLY_REQUIRES_TRAILING(sizeof...(Fns) >= 1)>
auto then(Fns&&... fns) & -> decltype(expected_detail::ExpectedHelper::then_(
std::declval<Base&>(),
std::declval<Fns>()...)) {
if (this->uninitializedByException())
throw BadExpectedAccess();
return expected_detail::ExpectedHelper::then_(
base(), static_cast<Fns&&>(fns)...);
}
template <class... Fns FOLLY_REQUIRES_TRAILING(sizeof...(Fns) >= 1)>
auto then(Fns&&... fns) && -> decltype(expected_detail::ExpectedHelper::then_(
std::declval<Base&&>(),
std::declval<Fns>()...)) {
if (this->uninitializedByException())
throw BadExpectedAccess();
return expected_detail::ExpectedHelper::then_(
std::move(base()), static_cast<Fns&&>(fns)...);
}
/**
* thenOrThrow
*/
template <class Yes, class No = MakeBadExpectedAccess>
auto thenOrThrow(Yes&& yes, No&& no = No{}) const& -> decltype(
std::declval<Yes>()(std::declval<const Value&>())) {
using Ret = decltype(std::declval<Yes>()(std::declval<const Value&>()));
if (this->uninitializedByException())
throw BadExpectedAccess();
return Ret(expected_detail::ExpectedHelper::thenOrThrow_(
base(), static_cast<Yes&&>(yes), static_cast<No&&>(no)));
}
template <class Yes, class No = MakeBadExpectedAccess>
auto thenOrThrow(Yes&& yes, No&& no = No{}) & -> decltype(
std::declval<Yes>()(std::declval<Value&>())) {
using Ret = decltype(std::declval<Yes>()(std::declval<Value&>()));
if (this->uninitializedByException())
throw BadExpectedAccess();
return Ret(expected_detail::ExpectedHelper::thenOrThrow_(
base(), static_cast<Yes&&>(yes), static_cast<No&&>(no)));
}
template <class Yes, class No = MakeBadExpectedAccess>
auto thenOrThrow(Yes&& yes, No&& no = No{}) && -> decltype(
std::declval<Yes>()(std::declval<Value&&>())) {
using Ret = decltype(std::declval<Yes>()(std::declval<Value&&>()));
if (this->uninitializedByException())
throw BadExpectedAccess();
return Ret(expected_detail::ExpectedHelper::thenOrThrow_(
std::move(base()), static_cast<Yes&&>(yes), static_cast<No&&>(no)));
}
private:
void requireValue() const {
if (UNLIKELY(!hasValue())) {
if (LIKELY(hasError()))
throw typename Unexpected<Error>::BadExpectedAccess(this->error_);
throw BadExpectedAccess();
}
}
void requireError() const {
if (UNLIKELY(!hasError())) {
throw BadExpectedAccess();
}
}
expected_detail::Which which() const noexcept {
return this->which_;
}
};
template <class Value, class Error>
inline typename std::enable_if<IsEqualityComparable<Value>::value, bool>::type
operator==(
const Expected<Value, Error>& lhs,
const Expected<Value, Error>& rhs) {
if (UNLIKELY(lhs.which_ != rhs.which_))
return UNLIKELY(lhs.uninitializedByException()) ? false
: throw BadExpectedAccess();
if (UNLIKELY(lhs.uninitializedByException()))
throw BadExpectedAccess();
if (UNLIKELY(lhs.hasError()))
return true; // All error states are considered equal
return lhs.value_ == rhs.value_;
}
template <
class Value,
class Error FOLLY_REQUIRES_TRAILING(IsEqualityComparable<Value>::value)>
inline bool operator!=(
const Expected<Value, Error>& lhs,
const Expected<Value, Error>& rhs) {
return !(rhs == lhs);
}
template <class Value, class Error>
inline typename std::enable_if<IsLessThanComparable<Value>::value, bool>::type
operator<(
const Expected<Value, Error>& lhs,
const Expected<Value, Error>& rhs) {
if (UNLIKELY(
lhs.uninitializedByException() || rhs.uninitializedByException()))
throw BadExpectedAccess();
if (UNLIKELY(lhs.hasError()))
return !rhs.hasError();
if (UNLIKELY(rhs.hasError()))
return false;
return lhs.value_ < rhs.value_;
}
template <
class Value,
class Error FOLLY_REQUIRES_TRAILING(IsLessThanComparable<Value>::value)>
inline bool operator<=(
const Expected<Value, Error>& lhs,
const Expected<Value, Error>& rhs) {
return !(rhs < lhs);
}
template <
class Value,
class Error FOLLY_REQUIRES_TRAILING(IsLessThanComparable<Value>::value)>
inline bool operator>(
const Expected<Value, Error>& lhs,
const Expected<Value, Error>& rhs) {
return rhs < lhs;
}
template <
class Value,
class Error FOLLY_REQUIRES_TRAILING(IsLessThanComparable<Value>::value)>
inline bool operator>=(
const Expected<Value, Error>& lhs,
const Expected<Value, Error>& rhs) {
return !(lhs < rhs);
}
/**
* swap Expected values
*/
template <class Error, class Value>
void swap(Expected<Error, Value>& lhs, Expected<Value, Error>& rhs) noexcept(
expected_detail::StrictAllOf<IsNothrowSwappable, Value, Error>::value) {
lhs.swap(rhs);
}
template <class Value, class Error>
const Value* get_pointer(const Expected<Value, Error>& ex) noexcept {
return ex.get_pointer();
}
template <class Value, class Error>
Value* get_pointer(Expected<Value, Error>& ex) noexcept {
return ex.get_pointer();
}
/**
* For constructing an Expected object from a value, with the specified
* Error type. Usage is as follows:
*
* enum MyErrorCode { BAD_ERROR, WORSE_ERROR };
* Expected<int, MyErrorCode> myAPI() {
* int i = // ...;
* return i ? makeExpected<MyErrorCode>(i) : makeUnexpected(BAD_ERROR);
* }
*/
template <class Error, class Value>
constexpr Expected<typename std::decay<Value>::type, Error> makeExpected(
Value&& val) {
return Expected<typename std::decay<Value>::type, Error>{
in_place, static_cast<Value&&>(val)};
}
// Suppress comparability of Optional<T> with T, despite implicit conversion.
template <class Value, class Error>
bool operator==(const Expected<Value, Error>&, const Value& other) = delete;
template <class Value, class Error>
bool operator!=(const Expected<Value, Error>&, const Value& other) = delete;
template <class Value, class Error>
bool operator<(const Expected<Value, Error>&, const Value& other) = delete;
template <class Value, class Error>
bool operator<=(const Expected<Value, Error>&, const Value& other) = delete;
template <class Value, class Error>
bool operator>=(const Expected<Value, Error>&, const Value& other) = delete;
template <class Value, class Error>
bool operator>(const Expected<Value, Error>&, const Value& other) = delete;
template <class Value, class Error>
bool operator==(const Value& other, const Expected<Value, Error>&) = delete;
template <class Value, class Error>
bool operator!=(const Value& other, const Expected<Value, Error>&) = delete;
template <class Value, class Error>
bool operator<(const Value& other, const Expected<Value, Error>&) = delete;
template <class Value, class Error>
bool operator<=(const Value& other, const Expected<Value, Error>&) = delete;
template <class Value, class Error>
bool operator>=(const Value& other, const Expected<Value, Error>&) = delete;
template <class Value, class Error>
bool operator>(const Value& other, const Expected<Value, Error>&) = delete;
} // namespace folly
#if defined(__GNUC__) && !defined(__clang__)
#pragma GCC diagnostic pop
#endif
#undef FOLLY_REQUIRES
#undef FOLLY_REQUIRES_TRAILING