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QtFuture Namespace

Contains miscellaneous identifiers used by the QFuture class. More...

Header: #include <QFuture>
CMake: find_package(Qt6 REQUIRED COMPONENTS Core)
target_link_libraries(mytarget PRIVATE Qt6::Core)
qmake: QT += core

Classes

struct WhenAnyResult

Types

enum class Launch { Sync, Async, Inherit }

Functions

QFuture<ArgsType<Signal>> connect(Sender *sender, Signal signal)
QFuture<T> makeExceptionalFuture(const QException &exception)
QFuture<T> makeExceptionalFuture(std::exception_ptr exception)
QFuture<std::decay_t<T>> makeReadyFuture(T &&value)
QFuture<void> makeReadyFuture()
QFuture<T> makeReadyFuture(const QList<T> &values)
QFuture<OutputSequence> whenAll(InputIt first, InputIt last)
QFuture<OutputSequence> whenAll(Futures &&... futures)
QFuture<QtFuture::WhenAnyResult<T>> whenAny(InputIt first, InputIt last)
QFuture<std::variant<std::decay_t<Futures>...>> whenAny(Futures &&... futures)

Detailed Description

Classes

class WhenAnyResult

QtFuture::WhenAnyResult is used to represent the result of QtFuture::whenAny(). More...

Type Documentation

[since 6.0] enum class QtFuture::Launch

Represents execution policies for running a QFuture continuation.

Constant Value Description
QtFuture::Launch::Sync 0 The continuation will be launched in the same thread that fulfills the promise associated with the future to which the continuation was attached, or if it has already finished, the continuation will be invoked immediately, in the thread that executes then().
QtFuture::Launch::Async 1 The continuation will be launched in a separate thread taken from the global QThreadPool.
QtFuture::Launch::Inherit 2 The continuation will inherit the launch policy or thread pool of the future to which it is attached.

Sync is used as a default launch policy.

This enum was introduced or modified in Qt 6.0.

See also QFuture::then() and QThreadPool::globalInstance().

Function Documentation

template <typename Sender, typename Signal, typename> QFuture<ArgsType<Signal>> QtFuture::connect(Sender *sender, Signal signal)

Creates and returns a QFuture which will become available when the sender emits the signal. If the signal takes no arguments, a QFuture<void> is returned. If the signal takes a single argument, the resulted QFuture will be filled with the signal's argument value. If the signal takes multiple arguments, the resulted QFuture is filled with std::tuple storing the values of signal's arguments. If the sender is destroyed before the signal is emitted, the resulted QFuture will be canceled.

For example, let's say we have the following object:

class Object : public QObject
{
    Q_OBJECT
    ...
signals:
    void noArgSignal();
    void singleArgSignal(int value);
    void multipleArgs(int value1, double value2, const QString &value3);
};

We can connect its signals to QFuture objects in the following way:

Object object;
QFuture<void> voidFuture = QtFuture::connect(&object, &Object::noArgSignal);
QFuture<int> intFuture = QtFuture::connect(&object, &Object::singleArgSignal);

using Args = std::tuple<int, double, QString>;
QFuture<Args> tupleFuture = QtFuture::connect(&object, &Object::multipleArgs)

We can also chain continuations to be run when a signal is emitted:

QtFuture::connect(&object, &Object::singleArgSignal).then([](int value) {
    // do something with the value
});

You can also start the continuation in a new thread or a custom thread pool using QtFuture::Launch policies. For example:

QtFuture::connect(&object, &Object::singleArgSignal).then(QtFuture::Launch::Async, [](int value) {
    // this will run in a new thread
});

Throwing an exception from a slot invoked by Qt's signal-slot connection is considered to be an undefined behavior, if it is not handled within the slot. But with QFuture::connect(), you can throw and handle exceptions from the continuations:

QtFuture::connect(&object, &Object::singleArgSignal).then([](int value) {
    ...
    throw std::exception();
    ...
}).onFailed([](const std::exception &e) {
    // handle the exception
}).onFailed([] {
    // handle other exceptions
});

Note: The connected future will be fulfilled only once, when the signal is emitted for the first time.

See also QFuture and QFuture::then().

[since 6.1] template <typename T> QFuture<T> QtFuture::makeExceptionalFuture(const QException &exception)

Creates and returns a QFuture which already has an exception exception.

QException e;
auto f = QtFuture::makeExceptionalFuture<int>(e);
...
try {
    f.result(); // throws QException
} catch (QException &) {
    // handle exception here
}

This function was introduced in Qt 6.1.

See also QFuture, QException, and QtFuture::makeReadyFuture().

[since 6.1] template <typename T> QFuture<T> QtFuture::makeExceptionalFuture(std::exception_ptr exception)

This is an overloaded function.

Creates and returns a QFuture which already has an exception exception.

struct TestException
{
};
...
auto exception = std::make_exception_ptr(TestException());
auto f = QtFuture::makeExceptionalFuture<int>(exception);
...
try {
    f.result(); // throws TestException
} catch (TestException &) {
    // handle exception here
}

This function was introduced in Qt 6.1.

See also QFuture, QException, and QtFuture::makeReadyFuture().

[since 6.1] template <typename T, typename> QFuture<std::decay_t<T>> QtFuture::makeReadyFuture(T &&value)

This is an overloaded function.

Creates and returns a QFuture which already has a result value. The returned QFuture has a type of std::decay_t<T>, where T is not void.

auto f = QtFuture::makeReadyFuture(std::make_unique<int>(42));
...
const int result = *f.takeResult(); // result == 42

This function was introduced in Qt 6.1.

See also QFuture and QtFuture::makeExceptionalFuture().

[since 6.1] QFuture<void> QtFuture::makeReadyFuture()

This is an overloaded function.

Creates and returns a void QFuture. Such QFuture can't store any result. One can use it to query the state of the computation. The returned QFuture will always be in the finished state.

auto f = QtFuture::makeReadyFuture();
...
const bool started = f.isStarted(); // started == true
const bool running = f.isRunning(); // running == false
const bool finished = f.isFinished(); // finished == true

This function was introduced in Qt 6.1.

See also QFuture, QFuture::isStarted(), QFuture::isRunning(), QFuture::isFinished(), and QtFuture::makeExceptionalFuture().

[since 6.1] template <typename T> QFuture<T> QtFuture::makeReadyFuture(const QList<T> &values)

This is an overloaded function.

Creates and returns a QFuture which already has multiple results set from values.

const QList<int> values { 1, 2, 3 };
auto f = QtFuture::makeReadyFuture(values);
...
const int count = f.resultCount(); // count == 3
const auto results = f.results(); // results == { 1, 2, 3 }

This function was introduced in Qt 6.1.

See also QFuture and QtFuture::makeExceptionalFuture().

[since 6.3] template <typename OutputSequence, typename InputIt> QFuture<OutputSequence> QtFuture::whenAll(InputIt first, InputIt last)

Returns a new QFuture that succeeds when all futures from first to last complete. first and last are iterators to a sequence of futures packaging type T. OutputSequence is a sequence containing all completed futures from first to last, appearing in the same order as in the input. If the type of OutputSequence is not specified, the resulting futures will be returned in a QList of QFuture<T>. For example:

QList<QFuture<int>> inputFutures {...};

// whenAll has type QFuture<QList<QFuture<int>>>
auto whenAll = QtFuture::whenAll(inputFutures.begin(), inputFutures.end());

// whenAllVector has type QFuture<std::vector<QFuture<int>>>
auto whenAllVector =
        QtFuture::whenAll<std::vector<QFuture<int>>>(inputFutures.begin(), inputFutures.end());

Note: The output sequence must support random access and the resize() operation.

If first equals last, this function returns a ready QFuture that contains an empty OutputSequence.

The returned future always completes successfully after all the specified futures complete. It doesn't matter if any of these futures completes with error or is canceled. You can use .then() to process the completed futures after the future returned by whenAll() succeeds:

QList<QFuture<int>> inputFutures {...};

QtFuture::whenAll(inputFutures.begin(), inputFutures.end())
        .then([](const QList<QFuture<int>> &results) {
            for (auto future : results) {
                if (future.isCanceled())
                    // handle the cancellation (possibly due to an exception)
                else
                    // do something with the result
            }
        });

Note: If the input futures complete on different threads, the future returned by this method will complete in the thread that the last future completes in. Therefore, the continuations attached to the future returned by whenAll() cannot always make assumptions about which thread they will be run on. Use the overload of .then() that takes a context object if you want to control which thread the continuations are invoked on.

This function was introduced in Qt 6.3.

[since 6.3] template <typename OutputSequence, typename Futures> QFuture<OutputSequence> QtFuture::whenAll(Futures &&... futures)

Returns a new QFuture that succeeds when all futures packaging arbitrary types complete. OutputSequence is a sequence of completed futures. The type of its entries is std::variant<Futures...>. For each QFuture<T> passed to whenAll(), the entry at the corresponding position in OutputSequence will be a std::variant holding that QFuture<T>, in its completed state. If the type of OutputSequence is not specified, the resulting futures will be returned in a QList of std::variant<Futures...>. For example:

QFuture<int> intFuture = ...;
QFuture<QString> stringFuture = ...;
QFuture<void> voidFuture = ...;

using FuturesVariant = std::variant<QFuture<int>, QFuture<QString>, QFuture<void>>;

// whenAll has type QFuture<QList<FuturesVariant>>
auto whenAll = QtFuture::whenAll(intFuture, stringFuture, voidFuture);

// whenAllVector has type QFuture<std::vector<FuturesVariant>>
auto whenAllVector =
        QtFuture::whenAll<std::vector<FuturesVariant>>(intFuture, stringFuture, voidFuture);

Note: The output sequence should support random access and the resize() operation.

The returned future always completes successfully after all the specified futures complete. It doesn't matter if any of these futures completes with error or is canceled. You can use .then() to process the completed futures after the future returned by whenAll() succeeds:

QFuture<int> intFuture = ...;
QFuture<QString> stringFuture = ...;
QFuture<void> voidFuture = ...;

using FuturesVariant = std::variant<QFuture<int>, QFuture<QString>, QFuture<void>>;

QtFuture::whenAll(intFuture, stringFuture, voidFuture)
        .then([](const QList<FuturesVariant> &results) {
            ...
            for (auto result : results)
            {
                // assuming handleResult() is overloaded based on the QFuture type
                std::visit([](auto &&future) { handleResult(future); }, result);
            }
            ...
        });

Note: If the input futures complete on different threads, the future returned by this method will complete in the thread that the last future completes in. Therefore, the continuations attached to the future returned by whenAll() cannot always make assumptions about which thread they will be run on. Use the overload of .then() that takes a context object if you want to control which thread the continuations are invoked on.

This function was introduced in Qt 6.3.

[since 6.3] template <typename T, typename InputIt> QFuture<QtFuture::WhenAnyResult<T>> QtFuture::whenAny(InputIt first, InputIt last)

Returns a new QFuture that succeeds when any of the futures from first to last completes. first and last are iterators to a sequence of futures packaging type T. The returned future packages a value of type QtFuture::WhenAnyResult<T> which in turn packages the index of the first completed QFuture and the QFuture itself. If first equals last, this function returns a ready QFuture that has -1 for the index field in the QtFuture::WhenAnyResult struct and a default-constructed QFuture<T> for the future field. Note that a default-constructed QFuture is a completed future in a cancelled state.

The returned future always completes successfully after the first future from the specified futures completes. It doesn't matter if the first future completes with error or is canceled. You can use .then() to process the result after the future returned by whenAny() succeeds:

QList<QFuture<int>> inputFutures = ...;

QtFuture::whenAny(inputFutures.begin(), inputFutures.end())
        .then([](const QtFuture::WhenAnyResult<int> &result) {
            qsizetype index = result.index;
            QFuture<int> future = result.future;
            // ...
        });

Note: If the input futures complete on different threads, the future returned by this method will complete in the thread that the first future completes in. Therefore, the continuations attached to the future returned by whenAny() cannot always make assumptions about which thread they will be run on. Use the overload of .then() that takes a context object if you want to control which thread the continuations are invoked on.

This function was introduced in Qt 6.3.

See also QtFuture::WhenAnyResult.

[since 6.3] template <typename Futures> QFuture<std::variant<std::decay_t<Futures>...>> QtFuture::whenAny(Futures &&... futures)

Returns a new QFuture that succeeds when any of the futures completes. futures can package arbitrary types. The returned future packages the value of type std::variant<Futures...> which in turn packages the first completed QFuture from futures. You can use std::variant::index() to find out the index of the future in the sequence of futures that finished first.

The returned future always completes successfully after the first future from the specified futures completes. It doesn't matter if the first future completes with error or is canceled. You can use .then() to process the result after the future returned by whenAny() succeeds:

QFuture<int> intFuture = ...;
QFuture<QString> stringFuture = ...;
QFuture<void> voidFuture = ...;

using FuturesVariant = std::variant<QFuture<int>, QFuture<QString>, QFuture<void>>;

QtFuture::whenAny(intFuture, stringFuture, voidFuture).then([](const FuturesVariant &result) {
    ...
    // assuming handleResult() is overloaded based on the QFuture type
    std::visit([](auto &&future) { handleResult(future); }, result);
    ...
});

Note: If the input futures complete on different threads, the future returned by this method will complete in the thread that the first future completes in. Therefore, the continuations attached to the future returned by whenAny() cannot always make assumptions about which thread they will be run on. Use the overload of .then() that takes a context object if you want to control which thread the continuations are invoked on.

This function was introduced in Qt 6.3.

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