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// SPDX-FileCopyrightText: 2021 Linus Jahn <lnj@kaidan.im>
//
// SPDX-License-Identifier: LGPL-2.1-or-later
#ifndef QXMPPFUTUREUTILS_P_H
#define QXMPPFUTUREUTILS_P_H
//
// W A R N I N G
// -------------
//
// This file is not part of the QXmpp API. This header file may change from
// version to version without notice, or even be removed.
//
// We mean it.
//
#include "QXmppIq.h"
#include "QXmppPromise.h"
#include "QXmppSendResult.h"
#include <memory>
#include <variant>
#include <QFutureWatcher>
#include <QObject>
namespace QXmpp::Private {
// helper for std::visit
template<class... Ts>
struct overloaded : Ts...
{
using Ts::operator()...;
};
// explicit deduction guide (not needed as of C++20)
template<class... Ts>
overloaded(Ts...) -> overloaded<Ts...>;
// Variation of std::visit allowing to forward unhandled types
template<typename ReturnType, typename T, typename Visitor>
auto visitForward(T variant, Visitor visitor)
{
return std::visit([&](auto &&value) -> ReturnType {
using ValueType = std::decay_t<decltype(value)>;
if constexpr (std::is_invocable_v<Visitor, ValueType>) {
return visitor(std::move(value));
} else {
return value;
}
},
std::forward<T>(variant));
}
template<typename F, typename Ret, typename A, typename... Rest>
A lambda_helper(Ret (F::*)(A, Rest...));
template<typename F, typename Ret, typename A, typename... Rest>
A lambda_helper(Ret (F::*)(A, Rest...) const);
template<typename F>
struct first_argument
{
using type = decltype(lambda_helper(&F::operator()));
};
template<typename F>
using first_argument_t = typename first_argument<F>::type;
#if QT_VERSION >= QT_VERSION_CHECK(6, 1, 0)
using QtFuture::makeReadyFuture;
#else
template<typename T>
QFuture<T> makeReadyFuture(T &&value)
{
QFutureInterface<T> interface(QFutureInterfaceBase::Started);
interface.reportResult(std::move(value));
interface.reportFinished();
return interface.future();
}
inline QFuture<void> makeReadyFuture()
{
using State = QFutureInterfaceBase::State;
return QFutureInterface<void>(State(State::Started | State::Finished)).future();
}
#endif
template<typename T>
QXmppTask<T> makeReadyTask(T &&value)
{
QXmppPromise<T> promise;
promise.finish(std::move(value));
return promise.task();
}
inline QXmppTask<void> makeReadyTask()
{
QXmppPromise<void> promise;
promise.finish();
return promise.task();
}
template<typename T, typename Handler>
void awaitLast(const QFuture<T> &future, QObject *context, Handler handler)
{
auto *watcher = new QFutureWatcher<T>(context);
QObject::connect(watcher, &QFutureWatcherBase::finished,
context, [watcher, handler = std::move(handler)]() mutable {
auto future = watcher->future();
handler(future.resultAt(future.resultCount() - 1));
watcher->deleteLater();
});
watcher->setFuture(future);
}
template<typename T, typename Handler>
void await(const QFuture<T> &future, QObject *context, Handler handler)
{
auto *watcher = new QFutureWatcher<T>(context);
QObject::connect(watcher, &QFutureWatcherBase::finished,
context, [watcher, handler = std::move(handler)]() mutable {
handler(watcher->result());
watcher->deleteLater();
});
watcher->setFuture(future);
}
template<typename Handler>
void await(const QFuture<void> &future, QObject *context, Handler handler)
{
auto *watcher = new QFutureWatcher<void>(context);
QObject::connect(watcher, &QFutureWatcherBase::finished,
context, [watcher, handler = std::move(handler)]() mutable {
handler();
watcher->deleteLater();
});
watcher->setFuture(future);
}
template<typename Result, typename Input, typename Converter>
auto chain(QXmppTask<Input> &&source, QObject *context, Converter task) -> QXmppTask<Result>
{
QXmppPromise<Result> promise;
source.then(context, [=](Input &&input) mutable {
promise.finish(task(std::move(input)));
});
return promise.task();
}
template<typename IqType, typename Input, typename Converter>
auto parseIq(Input &&sendResult, Converter convert) -> decltype(convert({}))
{
using Result = decltype(convert({}));
return std::visit(overloaded {
[convert = std::move(convert)](const QDomElement &element) -> Result {
IqType iq;
iq.parse(element);
if (iq.type() == QXmppIq::Error) {
if (auto err = iq.errorOptional()) {
return QXmppError { err->text(), std::move(*err) };
}
return QXmppError { QStringLiteral("Unknown error.") };
}
return convert(std::move(iq));
},
[](QXmppError error) -> Result {
return error;
},
},
sendResult);
}
template<typename IqType, typename Result, typename Input>
auto parseIq(Input &&sendResult) -> Result
{
return parseIq<IqType>(std::move(sendResult), [](IqType &&iq) -> Result {
// no conversion
return iq;
});
}
template<typename Input, typename Converter>
auto chainIq(QXmppTask<Input> &&input, QObject *context, Converter convert) -> QXmppTask<decltype(convert({}))>
{
using Result = decltype(convert({}));
using IqType = std::decay_t<first_argument_t<Converter>>;
return chain<Result>(std::move(input), context, [convert = std::move(convert)](Input &&input) -> Result {
return parseIq<IqType>(std::move(input), convert);
});
}
template<typename Result, typename Input>
auto chainIq(QXmppTask<Input> &&input, QObject *context) -> QXmppTask<Result>
{
// IQ type is first std::variant parameter
using IqType = std::decay_t<decltype(std::get<0>(Result {}))>;
return chain<Result>(std::move(input), context, [](Input &&sendResult) mutable {
return parseIq<IqType, Result>(sendResult);
});
}
template<typename T>
void reportFinishedResult(QFutureInterface<T> &interface, const T &result)
{
interface.reportResult(result);
interface.reportFinished();
}
template<typename T, typename Err, typename Function>
auto mapSuccess(std::variant<T, Err> var, Function lambda)
{
using MapResult = std::decay_t<decltype(lambda({}))>;
using MappedVariant = std::variant<MapResult, Err>;
return std::visit(overloaded {
[lambda = std::move(lambda)](T val) -> MappedVariant {
return lambda(std::move(val));
},
[](Err err) -> MappedVariant {
return err;
} },
std::move(var));
}
template<typename T>
static auto taskFromFuture(QFuture<T> &&future) -> QXmppTask<T>
{
QXmppPromise<T> promise;
auto *watcher = new QFutureWatcher<T>();
QObject::connect(watcher, &QFutureWatcher<T>::finished, [promise = std::move(promise), watcher]() mutable {
if constexpr (std::is_void_v<T>) {
promise.finish();
} else {
promise.finish(watcher->result());
}
watcher->deleteLater();
});
watcher->setFuture(future);
return promise.task();
}
} // namespace QXmpp::Private
#endif // QXMPPFUTUREUTILS_P_H
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