} // namespace futures
template <class T>
-Future<T> Future<T>::makeEmpty() {
- return Future<T>(futures::detail::EmptyConstruct{});
+SemiFuture<typename std::decay<T>::type> makeSemiFuture(T&& t) {
+ return makeSemiFuture(Try<typename std::decay<T>::type>(std::forward<T>(t)));
+}
+
+inline SemiFuture<Unit> makeSemiFuture() {
+ return makeSemiFuture(Unit{});
+}
+
+// makeSemiFutureWith(SemiFuture<T>()) -> SemiFuture<T>
+template <class F>
+typename std::enable_if<
+ isSemiFuture<typename std::result_of<F()>::type>::value,
+ typename std::result_of<F()>::type>::type
+makeSemiFutureWith(F&& func) {
+ using InnerType =
+ typename isSemiFuture<typename std::result_of<F()>::type>::Inner;
+ try {
+ return std::forward<F>(func)();
+ } catch (std::exception& e) {
+ return makeSemiFuture<InnerType>(
+ exception_wrapper(std::current_exception(), e));
+ } catch (...) {
+ return makeSemiFuture<InnerType>(
+ exception_wrapper(std::current_exception()));
+ }
+}
+
+// makeSemiFutureWith(T()) -> SemiFuture<T>
+// makeSemiFutureWith(void()) -> SemiFuture<Unit>
+template <class F>
+typename std::enable_if<
+ !(isSemiFuture<typename std::result_of<F()>::type>::value),
+ SemiFuture<Unit::LiftT<typename std::result_of<F()>::type>>>::type
+makeSemiFutureWith(F&& func) {
+ using LiftedResult = Unit::LiftT<typename std::result_of<F()>::type>;
+ return makeSemiFuture<LiftedResult>(
+ makeTryWith([&func]() mutable { return std::forward<F>(func)(); }));
+}
+
+template <class T>
+SemiFuture<T> makeSemiFuture(std::exception_ptr const& e) {
+ return makeSemiFuture(Try<T>(e));
+}
+
+template <class T>
+SemiFuture<T> makeSemiFuture(exception_wrapper ew) {
+ return makeSemiFuture(Try<T>(std::move(ew)));
+}
+
+template <class T, class E>
+typename std::
+ enable_if<std::is_base_of<std::exception, E>::value, SemiFuture<T>>::type
+ makeSemiFuture(E const& e) {
+ return makeSemiFuture(Try<T>(make_exception_wrapper<E>(e)));
}
template <class T>
-Future<T>::Future(Future<T>&& other) noexcept : core_(other.core_) {
+SemiFuture<T> makeSemiFuture(Try<T>&& t) {
+ return SemiFuture<T>(new futures::detail::Core<T>(std::move(t)));
+}
+
+template <class T>
+SemiFuture<T> SemiFuture<T>::makeEmpty() {
+ return SemiFuture<T>(futures::detail::EmptyConstruct{});
+}
+
+template <class T>
+SemiFuture<T>::SemiFuture(SemiFuture<T>&& other) noexcept : core_(other.core_) {
other.core_ = nullptr;
}
template <class T>
-Future<T>& Future<T>::operator=(Future<T>&& other) noexcept {
+SemiFuture<T>& SemiFuture<T>::operator=(SemiFuture<T>&& other) noexcept {
std::swap(core_, other.core_);
return *this;
}
+template <class T>
+SemiFuture<T>::SemiFuture(Future<T>&& other) noexcept : core_(other.core_) {
+ other.core_ = nullptr;
+}
+
+template <class T>
+SemiFuture<T>& SemiFuture<T>::operator=(Future<T>&& other) noexcept {
+ std::swap(core_, other.core_);
+ return *this;
+}
+
+template <class T>
+template <class T2, typename>
+SemiFuture<T>::SemiFuture(T2&& val)
+ : core_(new futures::detail::Core<T>(Try<T>(std::forward<T2>(val)))) {}
+
+template <class T>
+template <typename T2>
+SemiFuture<T>::SemiFuture(
+ typename std::enable_if<std::is_same<Unit, T2>::value>::type*)
+ : core_(new futures::detail::Core<T>(Try<T>(T()))) {}
+
+template <class T>
+template <
+ class... Args,
+ typename std::enable_if<std::is_constructible<T, Args&&...>::value, int>::
+ type>
+SemiFuture<T>::SemiFuture(in_place_t, Args&&... args)
+ : core_(
+ new futures::detail::Core<T>(in_place, std::forward<Args>(args)...)) {
+}
+
+template <class T>
+SemiFuture<T>::~SemiFuture() {
+ detach();
+}
+
+template <class T>
+typename std::add_lvalue_reference<T>::type SemiFuture<T>::value() {
+ throwIfInvalid();
+
+ return core_->getTry().value();
+}
+
+template <class T>
+typename std::add_lvalue_reference<const T>::type SemiFuture<T>::value() const {
+ throwIfInvalid();
+
+ return core_->getTry().value();
+}
+
+template <class T>
+inline Future<T> SemiFuture<T>::via(Executor* executor, int8_t priority) && {
+ throwIfInvalid();
+
+ setExecutor(executor, priority);
+
+ auto newFuture = Future<T>(core_);
+ core_ = nullptr;
+ return newFuture;
+}
+
+template <class T>
+inline Future<T> SemiFuture<T>::via(Executor* executor, int8_t priority) & {
+ throwIfInvalid();
+ Promise<T> p;
+ auto f = p.getFuture();
+ auto func = [p = std::move(p)](Try<T>&& t) mutable {
+ p.setTry(std::move(t));
+ };
+ using R = futures::detail::callableResult<T, decltype(func)>;
+ thenImplementation<decltype(func), R>(std::move(func), typename R::Arg());
+ return std::move(f).via(executor, priority);
+}
+
+template <class T>
+bool SemiFuture<T>::isReady() const {
+ throwIfInvalid();
+ return core_->ready();
+}
+
+template <class T>
+bool SemiFuture<T>::hasValue() {
+ return getTry().hasValue();
+}
+
+template <class T>
+bool SemiFuture<T>::hasException() {
+ return getTry().hasException();
+}
+
+template <class T>
+void SemiFuture<T>::detach() {
+ if (core_) {
+ core_->detachFuture();
+ core_ = nullptr;
+ }
+}
+
+template <class T>
+Try<T>& SemiFuture<T>::getTry() {
+ throwIfInvalid();
+
+ return core_->getTry();
+}
+
+template <class T>
+void SemiFuture<T>::throwIfInvalid() const {
+ if (!core_)
+ throwNoState();
+}
+
+template <class T>
+Optional<Try<T>> SemiFuture<T>::poll() {
+ Optional<Try<T>> o;
+ if (core_->ready()) {
+ o = std::move(core_->getTry());
+ }
+ return o;
+}
+
+template <class T>
+void SemiFuture<T>::raise(exception_wrapper exception) {
+ core_->raise(std::move(exception));
+}
+
+template <class T>
+template <class F>
+void SemiFuture<T>::setCallback_(F&& func) {
+ throwIfInvalid();
+ core_->setCallback(std::forward<F>(func));
+}
+
+template <class T>
+SemiFuture<T>::SemiFuture(futures::detail::EmptyConstruct) noexcept
+ : core_(nullptr) {}
+
+template <class T>
+Future<T> Future<T>::makeEmpty() {
+ return Future<T>(futures::detail::EmptyConstruct{});
+}
+
+template <class T>
+Future<T>::Future(Future<T>&& other) noexcept
+ : SemiFuture<T>(std::move(other)) {}
+
+template <class T>
+Future<T>& Future<T>::operator=(Future<T>&& other) noexcept {
+ SemiFuture<T>::operator=(SemiFuture<T>{std::move(other)});
+ return *this;
+}
+
template <class T>
template <
class T2,
std::move(other).then([](T2&& v) { return T(std::move(v)); }));
}
+// TODO: isSemiFuture
template <class T>
template <class T2, typename>
-Future<T>::Future(T2&& val)
- : core_(new futures::detail::Core<T>(Try<T>(std::forward<T2>(val)))) {}
+Future<T>::Future(T2&& val) : SemiFuture<T>(std::forward<T2>(val)) {}
template <class T>
template <typename T2>
Future<T>::Future(typename std::enable_if<std::is_same<Unit, T2>::value>::type*)
- : core_(new futures::detail::Core<T>(Try<T>(T()))) {}
+ : SemiFuture<T>() {}
template <class T>
template <
typename std::enable_if<std::is_constructible<T, Args&&...>::value, int>::
type>
Future<T>::Future(in_place_t, Args&&... args)
- : core_(
- new futures::detail::Core<T>(in_place, std::forward<Args>(args)...)) {
-}
+ : SemiFuture<T>(in_place, std::forward<Args>(args)...) {}
template <class T>
Future<T>::~Future() {
- detach();
-}
-
-template <class T>
-void Future<T>::detach() {
- if (core_) {
- core_->detachFuture();
- core_ = nullptr;
- }
-}
-
-template <class T>
-void Future<T>::throwIfInvalid() const {
- if (!core_)
- throwNoState();
-}
-
-template <class T>
-template <class F>
-void Future<T>::setCallback_(F&& func) {
- throwIfInvalid();
- core_->setCallback(std::forward<F>(func));
}
// unwrap
template <class T>
template <typename F, typename R, bool isTry, typename... Args>
typename std::enable_if<!R::ReturnsFuture::value, typename R::Return>::type
-Future<T>::thenImplementation(
+SemiFuture<T>::thenImplementation(
F&& func,
futures::detail::argResult<isTry, F, Args...>) {
static_assert(sizeof...(Args) <= 1, "Then must take zero/one argument");
typedef typename R::ReturnsFuture::Inner B;
- throwIfInvalid();
+ this->throwIfInvalid();
Promise<B> p;
- p.core_->setInterruptHandlerNoLock(core_->getInterruptHandler());
+ p.core_->setInterruptHandlerNoLock(this->core_->getInterruptHandler());
// grab the Future now before we lose our handle on the Promise
auto f = p.getFuture();
- f.core_->setExecutorNoLock(getExecutor());
+ f.core_->setExecutorNoLock(this->getExecutor());
/* This is a bit tricky.
in some circumstances, but I think it should be explicit not implicit
in the destruction of the Future used to create it.
*/
- setCallback_(
+ this->setCallback_(
[state = futures::detail::makeCoreCallbackState(
- std::move(p), std::forward<F>(func))](Try<T> && t) mutable {
+ std::move(p), std::forward<F>(func))](Try<T>&& t) mutable {
+
if (!isTry && t.hasException()) {
state.setException(std::move(t.exception()));
} else {
[&] { return state.invoke(t.template get<isTry, Args>()...); }));
}
});
-
return f;
}
template <class T>
template <typename F, typename R, bool isTry, typename... Args>
typename std::enable_if<R::ReturnsFuture::value, typename R::Return>::type
-Future<T>::thenImplementation(
+SemiFuture<T>::thenImplementation(
F&& func,
futures::detail::argResult<isTry, F, Args...>) {
static_assert(sizeof...(Args) <= 1, "Then must take zero/one argument");
typedef typename R::ReturnsFuture::Inner B;
-
- throwIfInvalid();
+ this->throwIfInvalid();
Promise<B> p;
- p.core_->setInterruptHandlerNoLock(core_->getInterruptHandler());
+ p.core_->setInterruptHandlerNoLock(this->core_->getInterruptHandler());
// grab the Future now before we lose our handle on the Promise
auto f = p.getFuture();
- f.core_->setExecutorNoLock(getExecutor());
+ f.core_->setExecutorNoLock(this->getExecutor());
- setCallback_(
+ this->setCallback_(
[state = futures::detail::makeCoreCallbackState(
- std::move(p), std::forward<F>(func))](Try<T> && t) mutable {
+ std::move(p), std::forward<F>(func))](Try<T>&& t) mutable {
if (!isTry && t.hasException()) {
state.setException(std::move(t.exception()));
} else {
typedef typename std::remove_cv<typename std::remove_reference<
typename futures::detail::ArgType<Args...>::FirstArg>::type>::type
FirstArg;
+
return then([instance, func](Try<T>&& t){
return (instance->*func)(t.template get<isTry<FirstArg>::value, Args>()...);
});
"Return type of onError callback must be T or Future<T>");
Promise<T> p;
- p.core_->setInterruptHandlerNoLock(core_->getInterruptHandler());
+ p.core_->setInterruptHandlerNoLock(this->core_->getInterruptHandler());
auto f = p.getFuture();
- setCallback_(
+ this->setCallback_(
[state = futures::detail::makeCoreCallbackState(
- std::move(p), std::forward<F>(func))](Try<T> && t) mutable {
+ std::move(p), std::forward<F>(func))](Try<T>&& t) mutable {
if (auto e = t.template tryGetExceptionObject<Exn>()) {
state.setTry(makeTryWith([&] { return state.invoke(*e); }));
} else {
Promise<T> p;
auto f = p.getFuture();
- setCallback_(
+ this->setCallback_(
[state = futures::detail::makeCoreCallbackState(
- std::move(p), std::forward<F>(func))](Try<T> && t) mutable {
+ std::move(p), std::forward<F>(func))](Try<T>&& t) mutable {
if (auto e = t.template tryGetExceptionObject<Exn>()) {
auto tf2 = state.tryInvoke(*e);
if (tf2.hasException()) {
Promise<T> p;
auto f = p.getFuture();
- setCallback_(
+ this->setCallback_(
[state = futures::detail::makeCoreCallbackState(
std::move(p), std::forward<F>(func))](Try<T> t) mutable {
if (t.hasException()) {
Promise<T> p;
auto f = p.getFuture();
- setCallback_(
+ this->setCallback_(
[state = futures::detail::makeCoreCallbackState(
- std::move(p), std::forward<F>(func))](Try<T> && t) mutable {
+ std::move(p), std::forward<F>(func))](Try<T>&& t) mutable {
if (t.hasException()) {
state.setTry(makeTryWith(
[&] { return state.invoke(std::move(t.exception())); }));
return f;
}
-template <class T>
-typename std::add_lvalue_reference<T>::type Future<T>::value() {
- throwIfInvalid();
-
- return core_->getTry().value();
-}
-
-template <class T>
-typename std::add_lvalue_reference<const T>::type Future<T>::value() const {
- throwIfInvalid();
-
- return core_->getTry().value();
-}
-
-template <class T>
-Try<T>& Future<T>::getTry() {
- throwIfInvalid();
-
- return core_->getTry();
-}
-
template <class T>
Try<T>& Future<T>::getTryVia(DrivableExecutor* e) {
return waitVia(e).getTry();
}
-template <class T>
-Optional<Try<T>> Future<T>::poll() {
- Optional<Try<T>> o;
- if (core_->ready()) {
- o = std::move(core_->getTry());
- }
- return o;
-}
-
-template <class T>
-inline Future<T> Future<T>::via(Executor* executor, int8_t priority) && {
- throwIfInvalid();
-
- setExecutor(executor, priority);
-
- return std::move(*this);
-}
-
-template <class T>
-inline Future<T> Future<T>::via(Executor* executor, int8_t priority) & {
- throwIfInvalid();
-
- Promise<T> p;
- auto f = p.getFuture();
- then([p = std::move(p)](Try<T> && t) mutable { p.setTry(std::move(t)); });
- return std::move(f).via(executor, priority);
-}
-
template <class Func>
auto via(Executor* x, Func&& func)
-> Future<typename isFuture<decltype(std::declval<Func>()())>::Inner> {
}
template <class T>
-bool Future<T>::isReady() const {
- throwIfInvalid();
- return core_->ready();
-}
-
-template <class T>
-bool Future<T>::hasValue() {
- return getTry().hasValue();
-}
-
-template <class T>
-bool Future<T>::hasException() {
- return getTry().hasException();
-}
-
-template <class T>
-void Future<T>::raise(exception_wrapper exception) {
- core_->raise(std::move(exception));
-}
-
-template <class T>
-Future<T>::Future(futures::detail::EmptyConstruct) noexcept : core_(nullptr) {}
+Future<T>::Future(futures::detail::EmptyConstruct) noexcept
+ : SemiFuture<T>(futures::detail::EmptyConstruct{}) {}
// makeFuture
return makeFuture(Try<typename std::decay<T>::type>(std::forward<T>(t)));
}
-inline // for multiple translation units
-Future<Unit> makeFuture() {
+inline Future<Unit> makeFuture() {
return makeFuture(Unit{});
}
template <class F>
typename std::enable_if<
!(isFuture<typename std::result_of<F()>::type>::value),
- Future<typename Unit::Lift<typename std::result_of<F()>::type>::type>>::type
+ Future<Unit::LiftT<typename std::result_of<F()>::type>>>::type
makeFutureWith(F&& func) {
- using LiftedResult =
- typename Unit::Lift<typename std::result_of<F()>::type>::type;
+ using LiftedResult = Unit::LiftT<typename std::result_of<F()>::type>;
return makeFuture<LiftedResult>(
makeTryWith([&func]() mutable { return std::forward<F>(func)(); }));
}
}
});
- return ctx->promise.getFuture().via(getExecutor());
+ return ctx->promise.getFuture().via(this->getExecutor());
}
// delayed
namespace futures {
namespace detail {
-template <class T>
-void waitImpl(Future<T>& f) {
+template <class FutureType, typename T = typename FutureType::value_type>
+void waitImpl(FutureType& f) {
// short-circuit if there's nothing to do
if (f.isReady()) return;
assert(f.isReady());
}
-template <class T>
-void waitImpl(Future<T>& f, Duration dur) {
+template <class FutureType, typename T = typename FutureType::value_type>
+void waitImpl(FutureType& f, Duration dur) {
// short-circuit if there's nothing to do
if (f.isReady()) {
return;
} // namespace detail
} // namespace futures
+template <class T>
+SemiFuture<T>& SemiFuture<T>::wait() & {
+ futures::detail::waitImpl(*this);
+ return *this;
+}
+
+template <class T>
+SemiFuture<T>&& SemiFuture<T>::wait() && {
+ futures::detail::waitImpl(*this);
+ return std::move(*this);
+}
+
+template <class T>
+SemiFuture<T>& SemiFuture<T>::wait(Duration dur) & {
+ futures::detail::waitImpl(*this, dur);
+ return *this;
+}
+
+template <class T>
+SemiFuture<T>&& SemiFuture<T>::wait(Duration dur) && {
+ futures::detail::waitImpl(*this, dur);
+ return std::move(*this);
+}
+
+template <class T>
+T SemiFuture<T>::get() {
+ return std::move(wait().value());
+}
+
+template <class T>
+T SemiFuture<T>::get(Duration dur) {
+ wait(dur);
+ if (this->isReady()) {
+ return std::move(this->value());
+ } else {
+ throwTimedOut();
+ }
+}
+
template <class T>
Future<T>& Future<T>::wait() & {
futures::detail::waitImpl(*this);
return std::move(*this);
}
-template <class T>
-T Future<T>::get() {
- return std::move(wait().value());
-}
-
-template <class T>
-T Future<T>::get(Duration dur) {
- wait(dur);
- if (isReady()) {
- return std::move(value());
- } else {
- throwTimedOut();
- }
-}
-
template <class T>
T Future<T>::getVia(DrivableExecutor* e) {
return std::move(waitVia(e).value());
extern template class Future<int64_t>;
extern template class Future<std::string>;
extern template class Future<double>;
-
} // namespace folly