With the Qt NFC API typical use cases are:
The following sections describe how to use Qt NFC C++ classes and QML types for the above use cases.
注意: On Android, Qt Nfc only works in foreground applications. Android services are not supported which is due to API limitations on the Android side.
The C++ API provides access to the full feature set of the Qt NFC API. This section introduces the major features available to developers.
The QNearFieldManager class is responsible for the detection of new NFC tags coming into range of the device. The QNearFieldManager::targetDetected () 和 QNearFieldManager::targetLost () signals are emitted when a tag comes into or leaves the range. The passed QNearFieldTarget parameter acts as primary interaction point for each detected tag. The detection does not actually start though until QNearFieldManager::startTargetDetection () 被调用。
m_manager = new QNearFieldManager(this); connect(m_manager, &QNearFieldManager::targetDetected, this, &MainWindow::targetDetected); connect(m_manager, &QNearFieldManager::targetLost, this, &MainWindow::targetLost); m_manager->startTargetDetection();
Finally the detection can be stopped:
m_manager->stopTargetDetection();
Although each QNearFieldTarget instance is owned by its related QNearFieldManager instance it can be beneficial to manually delete each instance. Otherwise they would continue to exist until the QNearFieldManager instance is deleted. The best way to do that would be in response to the QNearFieldManager::targetLost () signal:
void MainWindow::targetLost(QNearFieldTarget *target) { target->deleteLater(); }
注意: The target object should only be deleted via deleteLater() if it is deleted inside the slot.
The QNearFieldTarget instance returned by QNearFieldManager::targetDetected () signal is used to interact with the tag. Reading and writing a message is an asynchronous operation. The QNearFieldTarget::RequestId class associates individual operations and their results.
void MainWindow::targetDetected(QNearFieldTarget *target) { switch (m_touchAction) { case NoAction: break; case ReadNdef: connect(target, &QNearFieldTarget::ndefMessageRead, this, &MainWindow::ndefMessageRead); connect(target, &QNearFieldTarget::error, this, &MainWindow::targetError); m_request = target->readNdefMessages(); if (!m_request.isValid()) // cannot read messages targetError(QNearFieldTarget::NdefReadError, m_request); break; case WriteNdef: connect(target, &QNearFieldTarget::ndefMessagesWritten, this, &MainWindow::ndefMessageWritten); connect(target, &QNearFieldTarget::error, this, &MainWindow::targetError); m_request = target->writeNdefMessages(QList<QNdefMessage>() << ndefMessage()); if (!m_request.isValid()) // cannot write messages targetError(QNearFieldTarget::NdefWriteError, m_request); break; } }
Once the QNearFieldTarget::readNdefMessages () request was successfully processed, the QNearFieldTarget::ndefMessageRead () signal is emitted. Each returned QNdefMessage may consist of zero or more QNdefRecord entries, which can be identified by their type. For more information about processing of records, see the QNdefRecord class documentation. As the above code demonstrates, writing of NDEF messages is triggered via QNearFieldTarget::writeNdefMessages (). The successful completion of the write operation is indicated by the emission of the QNearFieldTarget::ndefMessagesWritten () signal. Any type of error during read or write is indicated via QNearFieldTarget::error ().
The above described method (of reading NDEF messages) directly connects to the platform's NFC infrastructure. However on some platforms (in particular mobile platforms) this may not actually trigger the target slot if the application is currently running in the background. This is not desirable in cases where an application wants to be activated if the platform detects a tag of particular type. For this purpose the Qt NFC API provides the possibility to register an NDEF message handler. The handler is called by the operating system, when the detected NDEF message matches the given filter criteria. Depending on the platform it may even be possible to start the application that registered the handler.
注意: This feature is not available on all platforms and, in addition to the code snippets below, may require further platform specific setup.
manager = new QNearFieldManager(this); if (!manager->isAvailable()) { qWarning() << "NFC not available"; return; } QNdefFilter filter; filter.setOrderMatch(false); filter.appendRecord<QNdefNfcTextRecord>(1, UINT_MAX); filter.appendRecord<QNdefNfcUriRecord>(); // type parameter cannot specify substring so filter for "image/" below filter.appendRecord(QNdefRecord::Mime, QByteArray(), 0, 1); int result = manager->registerNdefMessageHandler(filter, this, SLOT(handleMessage(QNdefMessage,QNearFieldTarget*)));
For comparison an application that uses an empty NDEF filter (match all behavior) in combination with QNearFieldManager::registerNdefMessageHandler () would behave similarly to another application that uses QNearFieldTarget::readNdefMessages () while being in the forground. For more information about registration details of NDEF message handlers, see the QNearFieldManager class description.
The content of
handleMessage()
may look like the snippet below. Any incoming NDEF message of type
text
or
uri
will be processed:
void AnnotatedUrl::handleMessage(const QNdefMessage &message, QNearFieldTarget *target) { for (const QNdefRecord &record : message) { if (record.isRecordType<QNdefNfcTextRecord>()) { QNdefNfcTextRecord textRecord(record); title = textRecord.text(); QLocale locale(textRecord.locale()); } else if (record.isRecordType<QNdefNfcUriRecord>()) { QNdefNfcUriRecord uriRecord(record); url = uriRecord.uri(); } else if (record.typeNameFormat() == QNdefRecord::Mime && record.type().startsWith("image/")) { pixmap = QPixmap::fromImage(QImage::fromData(record.payload())); } } emit annotatedUrl(url, title, pixmap); }
Since Qt 5.3, Qt NFC provides a generic NFC share feature. If both devices support the same protocol, the feature can be used to share files or NDEF messages. The advantage is that the two involved partners can quickly establish a connection via NFC but transfer the data through, for example, Bluetooth or Wifi. Effectively, this combines the low configuration effort of NFC with high data rate communication bearers which usually require a much more complex setup.
注意: The API does not make any guarantees about the actual communication bearer used during the transfer. The bearer is chosen based on the device's capabilities and the properties of the to-be-shared data.
QNearFieldShareManager and QNearFieldShareTarget are responsible for accessing the NFC share feature.
The QML API only supports a very small subset of the Qt NFC feature set. This section outlines the available QML features.
The user can specify NDEF filters and use those filters to register for the automatic reception of NDEF messages which match those filters. The NearField::messageRecords property contains the list of NDEF records of the last NDEF message read matching the given filters.
NearField { filter: [ NdefFilter { type: "U"; typeNameFormat: NdefRecord.NfcRtd; minimum: 1; maximum: 1 } ] orderMatch: false onMessageRecordsChanged: displayMessage() }
If no filter is set, the message handler will match all incoming NDEF messages.