Waterpump Example

/**************************************************************************** ** ** Copyright (C) 2018 basysKom GmbH, opensource@basyskom.com ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the examples of the QtOpcUa module. ** ** $QT_BEGIN_LICENSE:BSD$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and The Qt Company. For licensing terms ** and conditions see https://www.qt.io/terms-conditions. For further ** information use the contact form at https://www.qt.io/contact-us. ** ** BSD License Usage ** Alternatively, you may use this file under the terms of the BSD license ** as follows: ** ** "Redistribution and use in source and binary forms, with or without ** modification, are permitted provided that the following conditions are ** met: ** * Redistributions of source code must retain the above copyright ** notice, this list of conditions and the following disclaimer. ** * Redistributions in binary form must reproduce the above copyright ** notice, this list of conditions and the following disclaimer in ** the documentation and/or other materials provided with the ** distribution. ** * Neither the name of The Qt Company Ltd nor the names of its ** contributors may be used to endorse or promote products derived ** from this software without specific prior written permission. ** ** ** THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ** "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT ** LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ** A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT ** OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, ** SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT ** LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, ** DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY ** THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE ** OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE." ** ** $QT_END_LICENSE$ ** ****************************************************************************/
#include "opcuamachinebackend.h" #include <QtQml> OpcUaMachineBackend::OpcUaMachineBackend(QObject *parent) : QObject(parent) , m_percentFilledTank1(0) , m_percentFilledTank2(0) , m_tank2TargetPercent(0) , m_tank2ValveState(false) , m_machineState(MachineState::Idle) , m_connected(false) , m_message("Ready to connect") , m_successfullyCreated(false) { qRegisterMetaType<OpcUaMachineBackend::MachineState>(); qmlRegisterType<OpcUaMachineBackend>("OpcUaMachineBackend", 1, 0, "OpcUaMachineBackend"); QOpcUaProvider provider; setBackends(provider.availableBackends()); } OpcUaMachineBackend::~OpcUaMachineBackend() { if (m_client && m_client->state() == QOpcUaClient::Connected) m_client->disconnectFromEndpoint(); } void OpcUaMachineBackend::clientStateHandler(QOpcUaClient::ClientState state) { m_connected = (state == QOpcUaClient::ClientState::Connected); emit connectedChanged(m_connected); if (state == QOpcUaClient::ClientState::Connected) { setMessage("Connected"); // Create node objects for reading, writing and subscriptions m_machineNode.reset(m_client->node("ns=2;s=Machine")); m_machineStateNode.reset(m_client->node("ns=2;s=Machine.State")); m_percentFilledTank1Node.reset(m_client->node("ns=2;s=Machine.Tank1.PercentFilled")); m_percentFilledTank2Node.reset(m_client->node("ns=2;s=Machine.Tank2.PercentFilled")); m_tank2TargetPercentNode.reset(m_client->node("ns=2;s=Machine.Tank2.TargetPercent")); m_tank2ValveStateNode.reset(m_client->node("ns=2;s=Machine.Tank2.ValveState")); m_machineDesignationNode.reset(m_client->node("ns=2;s=Machine.Designation")); // Connect signal handlers for subscribed values QObject::connect(m_machineStateNode.data(), &QOpcUaNode::dataChangeOccurred, this, &OpcUaMachineBackend::machineStateUpdated); QObject::connect(m_percentFilledTank1Node.data(), &QOpcUaNode::dataChangeOccurred, this, &OpcUaMachineBackend::percentFilledTank1Updated); QObject::connect(m_percentFilledTank2Node.data(), &QOpcUaNode::dataChangeOccurred, this, &OpcUaMachineBackend::percentFilledTank2Updated); QObject::connect(m_tank2TargetPercentNode.data(), &QOpcUaNode::dataChangeOccurred, this, &OpcUaMachineBackend::tank2TargetPercentUpdated); QObject::connect(m_tank2ValveStateNode.data(), &QOpcUaNode::dataChangeOccurred, this, &OpcUaMachineBackend::tank2ValveStateUpdated); // Subscribe to data changes m_machineStateNode->enableMonitoring(QOpcUa::NodeAttribute::Value, QOpcUaMonitoringParameters(100)); m_percentFilledTank1Node->enableMonitoring(QOpcUa::NodeAttribute::Value, QOpcUaMonitoringParameters(100)); m_percentFilledTank2Node->enableMonitoring(QOpcUa::NodeAttribute::Value, QOpcUaMonitoringParameters(100)); m_tank2TargetPercentNode->enableMonitoring(QOpcUa::NodeAttribute::Value, QOpcUaMonitoringParameters(100)); m_tank2ValveStateNode->enableMonitoring(QOpcUa::NodeAttribute::Value, QOpcUaMonitoringParameters(100)); // Connect the handler for async reading QObject::connect(m_machineDesignationNode.data(), &QOpcUaNode::attributeRead, this, &OpcUaMachineBackend::machineDesignationRead); // Request the value attribute of the machine designation node m_machineDesignationNode->readAttributes(QOpcUa::NodeAttribute::Value); // Add handlers for write and call results QObject::connect(m_tank2TargetPercentNode.data(), &QOpcUaNode::attributeWritten, this, &OpcUaMachineBackend::setpointWritten); QObject::connect(m_machineNode.data(), &QOpcUaNode::methodCallFinished, this, &OpcUaMachineBackend::handleMethodResult); // Add handlers for enableMonitoring results QObject::connect(m_machineStateNode.data(), &QOpcUaNode::enableMonitoringFinished, this, &OpcUaMachineBackend::enableMonitoringFinished); QObject::connect(m_percentFilledTank1Node.data(), &QOpcUaNode::enableMonitoringFinished, this, &OpcUaMachineBackend::enableMonitoringFinished); QObject::connect(m_percentFilledTank2Node.data(), &QOpcUaNode::enableMonitoringFinished, this, &OpcUaMachineBackend::enableMonitoringFinished); QObject::connect(m_tank2TargetPercentNode.data(), &QOpcUaNode::enableMonitoringFinished, this, &OpcUaMachineBackend::enableMonitoringFinished); QObject::connect(m_tank2ValveStateNode.data(), &QOpcUaNode::enableMonitoringFinished, this, &OpcUaMachineBackend::enableMonitoringFinished); } if (state == QOpcUaClient::ClientState::Connecting) setMessage(QStringLiteral("Connecting")); if (state == QOpcUaClient::ClientState::Disconnected) setMessage(QString("Disconnected: %1").arg(QMetaEnum::fromType<QOpcUaClient::ClientError>().valueToKey(static_cast<int>(m_client->error())))); } void OpcUaMachineBackend::machineStateUpdated(QOpcUa::NodeAttribute attr, const QVariant &value) { Q_UNUSED(attr); MachineState newState = static_cast<MachineState>(value.toUInt()); if (newState != m_machineState) { m_machineState = newState; emit machineStateChanged(m_machineState); } } void OpcUaMachineBackend::percentFilledTank1Updated(QOpcUa::NodeAttribute attr, const QVariant &value) { Q_UNUSED(attr); m_percentFilledTank1 = value.toDouble(); emit percentFilledTank1Changed(m_percentFilledTank1); } void OpcUaMachineBackend::percentFilledTank2Updated(QOpcUa::NodeAttribute attr, const QVariant &value) { Q_UNUSED(attr); m_percentFilledTank2 = value.toDouble(); emit percentFilledTank2Changed(m_percentFilledTank2); } void OpcUaMachineBackend::tank2TargetPercentUpdated(QOpcUa::NodeAttribute attr, const QVariant &value) { Q_UNUSED(attr); m_tank2TargetPercent = value.toDouble(); emit tank2TargetPercentChanged(m_tank2TargetPercent); } void OpcUaMachineBackend::tank2ValveStateUpdated(QOpcUa::NodeAttribute attr, const QVariant &value) { Q_UNUSED(attr); m_tank2ValveState = value.toBool(); emit tank2ValveStateChanged(m_tank2ValveState); } void OpcUaMachineBackend::machineDesignationRead(QOpcUa::NodeAttributes attr) { if (attr & QOpcUa::NodeAttribute::Value) { // Make sure the value attribute has been read if (m_machineDesignationNode->attributeError(QOpcUa::NodeAttribute::Value) == QOpcUa::UaStatusCode::Good) { // Make sure there was no error m_machineDesignation = m_machineDesignationNode->attribute(QOpcUa::NodeAttribute::Value).toString(); // Get the attribute from the cache emit machineDesignationChanged(m_machineDesignation); } } } void OpcUaMachineBackend::setpointWritten(QOpcUa::NodeAttribute attr, QOpcUa::UaStatusCode status) { if (attr == QOpcUa::NodeAttribute::Value && status == QOpcUa::UaStatusCode::Good) setMessage("Setpoint successfully set"); else if (attr == QOpcUa::NodeAttribute::Value && status != QOpcUa::UaStatusCode::Good) setMessage("Failed to set setpoint"); } void OpcUaMachineBackend::handleMethodResult(QString methodNodeId, const QVariant &result, QOpcUa::UaStatusCode statusCode) { Q_UNUSED(result); if (methodNodeId == "ns=2;s=Machine.Start") { if (statusCode == QOpcUa::UaStatusCode::Good) setMessage("Pump successfully started"); else setMessage("Unable to start pump"); } else if (methodNodeId == "ns=2;s=Machine.Stop") { if (statusCode == QOpcUa::UaStatusCode::Good) setMessage("Pump successfully stopped"); else setMessage("Unable to stop pump"); } else if (methodNodeId == "ns=2;s=Machine.FlushTank2") { if (statusCode == QOpcUa::UaStatusCode::Good) setMessage("Flushing tank 2 successfully started"); else setMessage("Unable to flush tank 2"); } else if (methodNodeId == "ns=2;s=Machine.Reset") { if (statusCode == QOpcUa::UaStatusCode::Good) setMessage("Simulation successfully reset"); else setMessage("Unable to reset simulation"); } } void OpcUaMachineBackend::enableMonitoringFinished(QOpcUa::NodeAttribute attr, QOpcUa::UaStatusCode status) { Q_UNUSED(attr); if (!sender()) return; if (status == QOpcUa::UaStatusCode::Good) qDebug() << "Monitoring successfully enabled for" << qobject_cast<QOpcUaNode *>(sender())->nodeId(); else { qDebug() << "Failed to enable monitoring for" << qobject_cast<QOpcUaNode *>(sender())->nodeId() << ":" << status; setMessage("Failed to enable monitoring"); } } void OpcUaMachineBackend::setBackends(const QStringList &backends) { if (m_backends != backends) { m_backends = backends; emit backendsChanged(m_backends); } } QStringList OpcUaMachineBackend::backends() const { return m_backends; } double OpcUaMachineBackend::percentFilledTank1() const { return m_percentFilledTank1; } double OpcUaMachineBackend::percentFilledTank2() const { return m_percentFilledTank2; } OpcUaMachineBackend::MachineState OpcUaMachineBackend::machineState() const { return m_machineState; } void OpcUaMachineBackend::machineWriteTank2TargetPercent(double value) { if (m_tank2TargetPercentNode) m_tank2TargetPercentNode->writeAttribute(QOpcUa::NodeAttribute::Value, value); } void OpcUaMachineBackend::startPump() { m_machineNode->callMethod("ns=2;s=Machine.Start"); } void OpcUaMachineBackend::stopPump() { if (m_machineNode) m_machineNode->callMethod("ns=2;s=Machine.Stop"); } void OpcUaMachineBackend::flushTank2() { if (m_machineNode) m_machineNode->callMethod("ns=2;s=Machine.FlushTank2"); } void OpcUaMachineBackend::resetSimulation() { if (m_machineNode) m_machineNode->callMethod("ns=2;s=Machine.Reset"); } void OpcUaMachineBackend::requestEndpointsFinished(const QVector<QOpcUaEndpointDescription> &endpoints) { if (endpoints.isEmpty()) { qWarning() << "The server did not return any endpoints"; clientStateHandler(QOpcUaClient::ClientState::Disconnected); return; } m_client->connectToEndpoint(endpoints.at(0)); } void OpcUaMachineBackend::setMessage(const QString &message) { if (message != m_message) { m_message = message; emit messageChanged(m_message); } } bool OpcUaMachineBackend::successfullyCreated() const { return m_successfullyCreated; } QString OpcUaMachineBackend::message() const { return m_message; } QString OpcUaMachineBackend::machineDesignation() const { return m_machineDesignation; } bool OpcUaMachineBackend::connected() const { return m_connected; } void OpcUaMachineBackend::connectToEndpoint(const QString &url, qint32 index) { if (m_connected) return; QOpcUaProvider provider; if (index < 0 || index >= m_backends.size()) return; // Invalid index if (!m_client || (m_client && m_client->backend() != m_backends.at(index))) { m_client.reset(provider.createClient(m_backends.at(index))); if (m_client) { QObject::connect(m_client.data(), &QOpcUaClient::endpointsRequestFinished, this, &OpcUaMachineBackend::requestEndpointsFinished); QObject::connect(m_client.data(), &QOpcUaClient::stateChanged, this, &OpcUaMachineBackend::clientStateHandler); } } if (!m_client) { qWarning() << "Could not create client"; m_successfullyCreated = false; return; } m_successfullyCreated = true; m_client->requestEndpoints(url); } void OpcUaMachineBackend::disconnectFromEndpoint() { if (m_connected) m_client->disconnectFromEndpoint(); } bool OpcUaMachineBackend::tank2ValveState() const { return m_tank2ValveState; } double OpcUaMachineBackend::tank2TargetPercent() const { return m_tank2TargetPercent; }