///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2022 Jon Beniston, M7RCE //
// //
// This program is free software; you can redistribute it and/or modify //
// it under the terms of the GNU General Public License as published by //
// the Free Software Foundation as version 3 of the License, or //
// (at your option) any later version. //
// //
// This program is distributed in the hope that it will be useful, //
// but WITHOUT ANY WARRANTY; without even the implied warranty of //
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the //
// GNU General Public License V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see . //
///////////////////////////////////////////////////////////////////////////////////
#include
#include
#include
#include
#include
#include
#include
#include "util/iot/visa.h"
#include "util/visa.h"
#include "util/simpleserializer.h"
VISADevice::VISADevice(const QHash settings, const QString &deviceId,
const QStringList &controls, const QStringList &sensors,
DeviceDiscoverer::DeviceInfo *info) :
Device(info),
m_deviceId(deviceId),
m_session(0),
m_controls(controls),
m_sensors(sensors)
{
m_visa.openDefault();
QHashIterator itr(settings);
while (itr.hasNext())
{
itr.next();
QString key = itr.key();
QVariant value = itr.value();
if ((key == "deviceId") || (key == "controlIds") || (key == "sensorIds"))
{
// Nothing to do here
}
else if (key == "logIO")
{
m_visa.setDebugIO(value.toBool());
}
else
{
qDebug() << "VISADevice::VISADevice: Unsupported setting key: " << key << " value: " << value;
}
}
open();
}
VISADevice::~VISADevice()
{
m_visa.close(m_session);
m_visa.closeDefault();
}
bool VISADevice::open()
{
if (!m_session) {
m_session = m_visa.open(m_deviceId);
}
if (!m_session) {
emit deviceUnavailable();
}
return m_session != 0;
}
bool VISADevice::convertToBool(const QString &string, bool &ok)
{
QString lower = string.trimmed().toLower();
if ((lower == "0") || (lower == "false") || (lower == "off"))
{
ok = true;
return false;
}
else if ((lower == "1") || (lower == "true") || (lower == "on"))
{
ok = true;
return true;
}
else
{
ok = false;
return false;
}
}
void VISADevice::convert(QHash &status, const QString &id, DeviceDiscoverer::Type type, const QString &state)
{
if (type == DeviceDiscoverer::BOOL)
{
bool ok;
bool value = convertToBool(state, ok);
if (ok) {
status.insert(id, value);
} else {
status.insert(id, "error");
}
}
else if (type == DeviceDiscoverer::INT)
{
bool ok;
int value = state.toInt(&ok);
if (ok) {
status.insert(id, value);
} else {
status.insert(id, "error");
}
}
else if (type == DeviceDiscoverer::FLOAT)
{
bool ok;
float value = state.toFloat(&ok);
if (ok) {
status.insert(id, value);
} else {
status.insert(id, "error");
}
}
else
{
status.insert(id, state);
}
}
void VISADevice::getState()
{
if (open())
{
QHash status;
for (auto c : m_info.m_controls)
{
if (m_controls.contains(c->m_id))
{
VISAControl *control = reinterpret_cast(c);
QString cmds = control->m_getState.trimmed();
if (!cmds.isEmpty())
{
bool error;
QStringList results = m_visa.processCommands(m_session, cmds, &error);
if (!error && (results.size() > 0))
{
// Take last returned value as the state
QString state = results[results.size()-1].trimmed();
convert(status, control->m_id, control->m_type, state);
}
else
{
status.insert(control->m_id, "error");
}
}
}
}
for (auto s : m_info.m_sensors)
{
if (m_sensors.contains(s->m_id))
{
VISASensor *sensor = reinterpret_cast(s);
QString cmds = sensor->m_getState.trimmed();
if (!cmds.isEmpty())
{
bool error;
QStringList results = m_visa.processCommands(m_session, cmds, &error);
if (!error && (results.size() > 0))
{
// Take last returned value as the state
QString state = results[results.size()-1].trimmed();
convert(status, sensor->m_id, sensor->m_type, state);
}
else
{
status.insert(sensor->m_id, "error");
}
}
}
}
emit deviceUpdated(status);
}
}
void VISADevice::setState(const QString &controlId, bool state)
{
if (open())
{
for (auto c : m_info.m_controls)
{
VISAControl *control = reinterpret_cast(c);
if (control->m_id == controlId)
{
QString commands = QString::asprintf(control->m_setState.toUtf8(), (int)state);
bool error;
m_visa.processCommands(m_session, commands, &error);
if (error) {
qDebug() << "VISADevice::setState: Failed to set state of " << controlId;
}
}
}
}
}
void VISADevice::setState(const QString &controlId, int state)
{
if (open())
{
for (auto c : m_info.m_controls)
{
VISAControl *control = reinterpret_cast(c);
if (control->m_id == controlId)
{
QString commands = QString::asprintf(control->m_setState.toUtf8(), state);
bool error;
m_visa.processCommands(m_session, commands, &error);
if (error) {
qDebug() << "VISADevice::setState: Failed to set state of " << controlId;
}
}
}
}
}
void VISADevice::setState(const QString &controlId, float state)
{
if (open())
{
for (auto c : m_info.m_controls)
{
VISAControl *control = reinterpret_cast(c);
if (control->m_id == controlId)
{
QString commands = QString::asprintf(control->m_setState.toUtf8(), state);
bool error;
m_visa.processCommands(m_session, commands, &error);
if (error) {
qDebug() << "VISADevice::setState: Failed to set state of " << controlId;
}
}
}
}
}
void VISADevice::setState(const QString &controlId, const QString &state)
{
if (open())
{
for (auto c : m_info.m_controls)
{
VISAControl *control = reinterpret_cast(c);
if (control->m_id == controlId)
{
QString commands = QString::asprintf(control->m_setState.toUtf8(), state.toUtf8().data());
bool error;
m_visa.processCommands(m_session, commands, &error);
if (error) {
qDebug() << "VISADevice::setState: Failed to set state of " << controlId;
}
}
}
}
}
VISADeviceDiscoverer::VISADeviceDiscoverer(const QString& resourceFilter) :
m_resourceFilter(resourceFilter)
{
m_session = m_visa.openDefault();
}
VISADeviceDiscoverer::~VISADeviceDiscoverer()
{
m_visa.closeDefault();
}
void VISADeviceDiscoverer::getDevices()
{
QRegularExpression *filterP = nullptr;
QRegularExpression filter(m_resourceFilter);
if (!m_resourceFilter.trimmed().isEmpty()) {
filterP = &filter;
}
// Get list of VISA instruments
QList instruments = m_visa.instruments(filterP);
// Convert to list of devices
QList devices;
for (auto const &instrument : instruments)
{
DeviceInfo info;
info.m_name = instrument.m_model;
info.m_id = instrument.m_resource;
info.m_model = instrument.m_model;
if ((info.m_name == "DP832") || (info.m_name == "DP832A"))
{
for (int i = 1; i <= 3; i++)
{
VISADevice::VISAControl *output = new VISADevice::VISAControl();
output->m_name = QString("CH%1").arg(i);
output->m_id = QString("control.ch%1").arg(i);
output->m_type = BOOL;
output->m_getState = QString(":OUTPUT? CH%1").arg(i);
output->m_setState = QString(":OUTPUT CH%1,%d").arg(i);
info.m_controls.append(output);
VISADevice::VISAControl *setVoltage = new VISADevice::VISAControl();
setVoltage->m_name = QString("V%1").arg(i);
setVoltage->m_id = QString("control.voltage%1").arg(i);
setVoltage->m_type = FLOAT;
setVoltage->m_min = 0.0f;
setVoltage->m_max = i == 3 ? 5.0f : 30.0f;
setVoltage->m_scale = 1.0f;
setVoltage->m_precision = 3;
setVoltage->m_widgetType = SPIN_BOX;
setVoltage->m_units = "V";
setVoltage->m_getState = QString(":SOURCE%1:VOLTage?").arg(i);
setVoltage->m_setState = QString(":SOURCE%1:VOLTage %f").arg(i);
info.m_controls.append(setVoltage);
VISADevice::VISAControl *setCurrent = new VISADevice::VISAControl();
setCurrent->m_name = QString("i%1").arg(i);
setCurrent->m_id = QString("control.current%1").arg(i);
setCurrent->m_type = FLOAT;
setCurrent->m_min = 0.0f;
setCurrent->m_max = 3.0f;
setCurrent->m_scale = 1.0f;
setCurrent->m_precision = 3;
setCurrent->m_widgetType = SPIN_BOX;
setCurrent->m_units = "A";
setCurrent->m_getState = QString(":SOURCE%1:CURRent?").arg(i);
setCurrent->m_setState = QString(":SOURCE%1:CURRent %f").arg(i);
info.m_controls.append(setCurrent);
VISADevice::VISASensor *voltage = new VISADevice::VISASensor();
voltage->m_name = QString("V%1").arg(i);
voltage->m_id = QString("sensor.voltage%1").arg(i);
voltage->m_type = FLOAT;
voltage->m_units = "V";
voltage->m_getState = QString(":MEASure:VOLTage? CH%1").arg(i);
info.m_sensors.append(voltage);
VISADevice::VISASensor *current = new VISADevice::VISASensor();
current->m_name = QString("i%1").arg(i);
current->m_id = QString("sensor.current%1").arg(i);
current->m_type = FLOAT;
current->m_units = "A";
current->m_getState = QString(":MEASure:CURRent? CH%1").arg(i);
info.m_sensors.append(current);
VISADevice::VISASensor *power = new VISADevice::VISASensor();
power->m_name = QString("P%1").arg(i);
power->m_id = QString("sensor.power%1").arg(i);
power->m_type = FLOAT;
power->m_units = "W";
power->m_getState = QString(":MEASure:POWEr? CH%1").arg(i);
info.m_sensors.append(power);
}
}
else if (info.m_name == "SSA3032X")
{
VISADevice::VISAControl *frequency = new VISADevice::VISAControl();
frequency->m_name = "Frequency";
frequency->m_id = "control.frequency";
frequency->m_type = FLOAT;
frequency->m_min = 0.0f;
frequency->m_max = 3.2e3f;
frequency->m_scale = 1e6f;
frequency->m_precision = 6;
frequency->m_widgetType = SPIN_BOX;
frequency->m_units = "MHz";
frequency->m_getState = ":FREQuency:CENTer?";
frequency->m_setState = ":FREQuency:CENTer %f";
info.m_controls.append(frequency);
VISADevice::VISAControl *span = new VISADevice::VISAControl();
span->m_name = "Span";
span->m_id = "control.span";
span->m_type = FLOAT;
span->m_min = 0.0f;
span->m_max = 3.2e3f;
span->m_scale = 1e6;
span->m_precision = 3;
span->m_widgetType = SPIN_BOX;
span->m_units = "MHz";
span->m_getState = ":FREQuency:SPAN?";
span->m_setState = ":FREQuency:SPAN %f";
info.m_controls.append(span);
VISADevice::VISAControl *markerX = new VISADevice::VISAControl();
markerX->m_name = "Marker X";
markerX->m_id = "control.markerx";
markerX->m_type = FLOAT;
markerX->m_min = 0.0f;
markerX->m_max = 3.2e3f;
markerX->m_scale = 1e6;
markerX->m_precision = 6;
markerX->m_widgetType = SPIN_BOX;
markerX->m_units = "MHz";
markerX->m_getState = ":CALCulate:MARKer1:X?";
markerX->m_setState = ":CALCulate:MARKer1:X %f";
info.m_controls.append(markerX);
VISADevice::VISASensor *markerY = new VISADevice::VISASensor();
markerY->m_name = "Marker Y";
markerY->m_id = "sensor.markery";
markerY->m_type = FLOAT;
markerY->m_units = "dBm";
markerY->m_getState = ":CALCulate:MARKer1:Y?";
info.m_sensors.append(markerY);
}
devices.append(info);
}
emit deviceList(devices);
}
DeviceDiscoverer::ControlInfo *VISADevice::VISAControl::clone() const
{
return new VISAControl(*this);
}
QByteArray VISADevice::VISAControl::serialize() const
{
SimpleSerializer s(1);
s.writeBlob(1, ControlInfo::serialize());
s.writeString(2, m_getState);
s.writeString(3, m_setState);
return s.final();
}
bool VISADevice::VISAControl::deserialize(const QByteArray& data)
{
SimpleDeserializer d(data);
if (!d.isValid()) {
return false;
}
if (d.getVersion() == 1)
{
QByteArray blob;
d.readBlob(1, &blob);
ControlInfo::deserialize(blob);
d.readString(2, &m_getState);
d.readString(3, &m_setState);
return true;
}
else
{
return false;
}
}
DeviceDiscoverer::SensorInfo *VISADevice::VISASensor::clone() const
{
return new VISASensor(*this);
}
QByteArray VISADevice::VISASensor::serialize() const
{
SimpleSerializer s(1);
s.writeBlob(1, SensorInfo::serialize());
s.writeString(2, m_getState);
return s.final();
}
bool VISADevice::VISASensor::deserialize(const QByteArray& data)
{
SimpleDeserializer d(data);
if (!d.isValid()) {
return false;
}
if (d.getVersion() == 1)
{
QByteArray blob;
d.readBlob(1, &blob);
SensorInfo::deserialize(blob);
d.readString(2, &m_getState);
return true;
}
else
{
return false;
}
}