Securing the CoAP client and using it with a Qt Quick user interface.
Quick Secure CoAP Client demonstrates how to create a secure CoAP client and use it in a Qt Quick application.
Note: Qt CoAP does not provide a QML API in its current version. However, you can make the C++ classes of the module available to QML as it is shown in the example.
To run the example application, you first need to set up a secure CoAP server. You can run the example with any secure CoAP server supporting one of the pre-shared key (PSK) or certificate authentication modes. For more information about setting up a secure CoAP server, see Setting Up a Secure CoAP Server.
QmlCoapSecureClient
wraps the functionality of QCoapClient to make it available to QML. It also holds the selected security mode and security configuration parameters.
class QmlCoapSecureClient : public QObject { Q_OBJECT public: QmlCoapSecureClient(QObject *parent = nullptr); ~QmlCoapSecureClient() override; Q_INVOKABLE void setSecurityMode(QtCoap::SecurityMode mode); Q_INVOKABLE void sendGetRequest(const QString &host, const QString &path, int port); Q_INVOKABLE void setSecurityConfiguration(const QString &preSharedKey, const QString &identity); Q_INVOKABLE void setSecurityConfiguration(const QString &localCertificatePath, const QString &caCertificatePath, const QString &privateKeyPath); Q_INVOKABLE void disconnect(); Q_SIGNALS: void finished(const QString &result); private: QCoapClient *m_coapClient; QCoapSecurityConfiguration m_configuration; QtCoap::SecurityMode m_securityMode; };
In the main.cpp file, we register the QmlCoapSecureClient
class as a QML type:
qmlRegisterType<QmlCoapSecureClient>("CoapSecureClient", 1, 0, "CoapSecureClient");
We also register the QtCoap namespace, to be able to use it in QML code:
qmlRegisterUncreatableMetaObject(QtCoap::staticMetaObject, "qtcoap.example.namespace", 1, 0, "QtCoap", "Access to enums is read-only");
The instance of QCoapClient is created when the user selects or changes the security mode in the UI. The QmlCoapSecureClient::setSecurityMode()
method is invoked from the QML
code, when one of the security modes is selected:
ButtonGroup { id: securityModeGroup onClicked: { if (securityModeGroup.checkedButton === preSharedMode) client.setSecurityMode(QtCoap.SecurityMode.PreSharedKey); else client.setSecurityMode(QtCoap.SecurityMode.Certificate); } }
And in the .cpp
file:
void QmlCoapSecureClient::setSecurityMode(QtCoap::SecurityMode mode) { // Create a new client, if the security mode has changed if (m_coapClient && mode != m_securityMode) { delete m_coapClient; m_coapClient = nullptr; } if (!m_coapClient) { m_coapClient = new QCoapClient(mode); m_securityMode = mode; ...
Then we connect the signals of the client, to get notified when a CoAP reply is received or a request has failed:
... connect(m_coapClient, &QCoapClient::finished, this, [this](QCoapReply *reply) { if (!reply) emit finished("Something went wrong, received a null reply"); else if (reply->errorReceived() != QtCoap::Error::Ok) emit finished(errorMessage(reply->errorReceived())); else emit finished(reply->message().payload()); }); connect(m_coapClient, &QCoapClient::error, this, [this](QCoapReply *, QtCoap::Error errorCode) { emit finished(errorMessage(errorCode)); }); ...
The QmlCoapSecureClient::finished()
signal triggers the onFinished
signal handler of CoapSecureClient
, which handles the output:
CoapSecureClient { id: client onFinished: { outputView.text = result; statusLabel.text = ""; disconnectButton.enabled = true; } } ...
When the user clicks on the Send Request button, we set the security configuration based on the selected security mode and send a GET
request:
... Button { id: requestButton text: qsTr("Send Request") enabled: securityModeGroup.checkState !== Qt.Unchecked onClicked: { outputView.text = ""; if (securityModeGroup.checkedButton === preSharedMode) client.setSecurityConfiguration(pskField.text, identityField.text); else client.setSecurityConfiguration(localCertificatePicker.selectedFile, caCertificatePicker.selectedFile, privateKeyPicker.selectedFile); client.sendGetRequest(hostComboBox.editText, resourceField.text, ...
There are two overloads for the setSecurityConfiguration
method. For the PSK mode we simply set the client identity and the pre-shared key:
QmlCoapSecureClient::setSecurityConfiguration(const QString &preSharedKey, const QString &identity) { QCoapSecurityConfiguration configuration; configuration.setPreSharedKey(preSharedKey.toUtf8()); configuration.setPreSharedKeyIdentity(identity.toUtf8()); m_configuration = configuration; }
And for X.509 certificates, we read the certificate files and the private key, and set the security configuration:
void QmlCoapSecureClient::setSecurityConfiguration(const QString &localCertificatePath, const QString &caCertificatePath, const QString &privateKeyPath) { QCoapSecurityConfiguration configuration; const auto localCerts = QSslCertificate::fromPath(QUrl(localCertificatePath).toLocalFile(), QSsl::Pem, QSslCertificate::PatternSyntax::FixedString); if (localCerts.isEmpty()) qCWarning(lcCoapClient, "The specified local certificate file is not valid."); else configuration.setLocalCertificateChain(localCerts.toVector()); const auto caCerts = QSslCertificate::fromPath(QUrl(caCertificatePath).toLocalFile(), QSsl::Pem, QSslCertificate::PatternSyntax::FixedString); if (caCerts.isEmpty()) qCWarning(lcCoapClient, "The specified CA certificate file is not valid."); else configuration.setCaCertificates(caCerts.toVector()); QFile privateKey(QUrl(privateKeyPath).toLocalFile()); if (privateKey.open(QIODevice::ReadOnly)) { QCoapPrivateKey key(privateKey.readAll(), QSsl::Ec); configuration.setPrivateKey(key); } else { qCWarning(lcCoapClient) << "Unable to read the specified private key file" << privateKeyPath; } m_configuration = configuration; }
After setting the security configuration, the sendGetRequest
method sets the request URL and sends a GET
request:
void QmlCoapSecureClient::sendGetRequest(const QString &host, const QString &path, int port) { if (!m_coapClient) return; m_coapClient->setSecurityConfiguration(m_configuration); QUrl url; url.setHost(host); url.setPath(path); url.setPort(port); m_coapClient->get(url); }
When sending the first request, a handshake with the CoAP server is performed. After the handshake is successfully done, all the subsequent messages are encrypted, and changing the security configuration after a successful handshake won't have any effect. If you want to change it, or change the host, you need to disconnect first.
void QmlCoapSecureClient::disconnect() { if (m_coapClient) m_coapClient->disconnect(); }
This will abort the handshake and close the open sockets.
For the authentication using X.509 certificates, we need to specify the certificate files. The FilePicker
component is used for this purpose. It combines a text field and a button for opening a file dialog when
the button is pressed:
Item { id: filePicker property string dialogText property alias selectedFile: filePathField.text height: addFileButton.height FileDialog { id: fileDialog title: qsTr("Please Choose %1").arg(dialogText) folder: StandardPaths.writableLocation(StandardPaths.HomeLocation) fileMode: FileDialog.OpenFile onAccepted: filePathField.text = fileDialog.file } RowLayout { anchors.fill: parent TextField { id: filePathField placeholderText: qsTr("<%1>").arg(dialogText) inputMethodHints: Qt.ImhUrlCharactersOnly selectByMouse: true Layout.fillWidth: true } Button { id: addFileButton text: qsTr("Add %1").arg(dialogText) onClicked: fileDialog.open() } } }
In the main.qml
file FilePicker
is instantiated several times for creating input fields for certificates and the private key:
... FilePicker { id: localCertificatePicker dialogText: "Local Certificate" enabled: securityModeGroup.checkedButton === certificateMode Layout.columnSpan: 2 Layout.fillWidth: true } FilePicker { id: caCertificatePicker dialogText: "CA Certificate" enabled: securityModeGroup.checkedButton === certificateMode Layout.columnSpan: 2 Layout.fillWidth: true } FilePicker { id: privateKeyPicker dialogText: "Private Key" enabled: securityModeGroup.checkedButton === certificateMode Layout.columnSpan: 2 Layout.fillWidth: true } ...
To run this example, you need to have a secure CoAP server supporting either PSK or Certificate modes (or both). You have the following options:
The following command pulls the docker container for a secure CoAP server based on Californium plugtest (which is not secure by default) from the Docker Hub and starts it:
docker run --name coap-test-server -d --rm -p 5683:5683/udp -p 5684:5684/udp sokurazy/coap-secure-test-server:californium.1.1.0
The CoAP test server will be reachable on ports 5683 (non-secure) and 5684 (secure). For instructions on retrieving the IP address see Getting The IP Address.
To run the example with this server, you need to set the pre-shared key to secretPSK
and the identity to Client_identity
.
The docker image of the secure server using authentication with X.509 certificates is based on the time server example from the FreeCoAP library. The following command pulls the container from Docker Hub and starts it:
docker run --name coap-time-server -d --rm -p 5684:5684/udp sokurazy/coap-secure-time-sever:freecoap
For instructions on retrieving the IP address see Getting The IP Address. The CoAP test server will be reachable by the retrieved IP address on
port 5684 and resource path /time
.
To run the example with this server, you need to specify the certificate files required by the server. They are located in the docker container, under /root/certs
directory. To copy them to a local directory,
use the following command:
docker cp <container_id>:/root/certs <local_directory_path>
For example:
$ docker cp 5e46502df88f:/root/certs ~/
The instructions for getting the container ID are described below.
To find out the IP address of a docker container, first retrieve the container ID by running the docker ps
command, which will output something like:
$ docker ps CONTAINER ID IMAGE 5e46502df88f sokurazy/coap-secure-test-server:californium.1.1.0
Then you can obtain the IP address with the following command:
docker inspect <container_id> | grep IPAddress
For example:
$ docker inspect 5e46502df88f | grep IPAddress ... "IPAddress": "172.17.0.2", ...
Files: