From 6a850596d34703ae65e346d72ad88b5da0732183 Mon Sep 17 00:00:00 2001 From: Alex Date: Fri, 20 May 2011 17:08:11 +1000 Subject: Add the first version of QtSensors to Qt 5 --- src/sensors/qsensor.cpp | 982 ++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 982 insertions(+) create mode 100644 src/sensors/qsensor.cpp (limited to 'src/sensors/qsensor.cpp') diff --git a/src/sensors/qsensor.cpp b/src/sensors/qsensor.cpp new file mode 100644 index 00000000..28cbd20f --- /dev/null +++ b/src/sensors/qsensor.cpp @@ -0,0 +1,982 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the Qt Mobility Components. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#include "qsensor.h" +#include "qsensor_p.h" +#include "qsensorbackend.h" +#include "qsensormanager.h" +#include +#include +#include + +QT_BEGIN_NAMESPACE + +/*! + \typedef qtimestamp + \relates QSensor + + Sensor timestamps are represented by this typedef which is a 64 bit unsigned integer. + + Timestamps values are microseconds since a fixed point. + You can use timestamps to see how far apart two sensor readings are. + + Note that sensor timestamps from different sensors may not be directly + comparable (as they may choose different fixed points for their reference). + + \bold{Note that some platforms do not deliver timestamps correctly}. + Applications should be prepared for occasional issues that cause timestamps to jump + forwards or backwards. The \l{sensors-api.html#platform-notes}{platform notes} have + more details. +*/ + +/*! + \typedef qrange + \relates QSensor + + This type is defined as a QPair. + + \code + typedef QPair qrange; + \endcode + + \sa QPair, qrangelist, QSensor::availableDataRates +*/ + +/*! + \typedef qrangelist + \relates QSensor + + This type is defined as a list of qrange values. + + \code + typedef QList qrangelist; + \endcode + + \sa QList, qrange, QSensor::availableDataRates +*/ + +/*! + \class qoutputrange + \relates QSensor + \brief The qoutputrange class holds the specifics of an output range. + + The class is defined as a simple struct. + + \code + struct qoutputrange + { + qreal maximum; + qreal minimum; + qreal accuracy; + }; + \endcode + + Each output range specifies a minimum and maximum value as well as an accuracy value. + The accuracy value represents the resolution of the sensor. It is the smallest change + the sensor can detect and is expressed using the same units as the minimum and maximum. + + Sensors must often trade off range for accuracy. To allow the user to determine which of + these are more important the sensor may offer several output ranges. One output + range may have reduced minimum and maximum values and increased sensitivity. Another output + range may have higher minimum and maximum values with reduced sensitivity. Note that higher + sensitivities will be represented by smaller accuracy values. + + An example of this tradeoff can be seen by examining the LIS302DL accelerometer. It has only + 256 possible values to report with. These values are scaled so that they can represent either + -2G to +2G (with an accuracy value of 0.015G) or -8G to +8G (with an accuracy value of 0.06G). + + \sa qoutputrangelist, QSensor::outputRanges +*/ + +/*! + \variable qoutputrange::maximum + + This is the maximum value for this output range. + The units are defined by the sensor. +*/ + +/*! + \variable qoutputrange::minimum + + This is the minimum value for this output range. + The units are defined by the sensor. +*/ + +/*! + \variable qoutputrange::accuracy + + The accuracy value represents the resolution of the sensor. It is the smallest change + the sensor can detect and is expressed using the same units as the minimum and maximum. +*/ + +/*! + \typedef qoutputrangelist + \relates QSensor + + This type is defined as a list of qoutputrange values. + + \code + typedef QList qoutputrangelist; + \endcode + + \sa QList, qoutputrange, QSensor::outputRanges +*/ + +// A bit of a hack to call qRegisterMetaType when the library is loaded. +static int qtimestamp_id = qRegisterMetaType("qtimestamp"); +static int qrange_id = qRegisterMetaType("qrange"); +static int qrangelist_id = qRegisterMetaType("qrangelist"); +static int qoutputrangelist_id = qRegisterMetaType("qoutputrangelist"); + +// ===================================================================== + +/*! + \class QSensor + \ingroup sensors_main + \inmodule QtSensors + + \brief The QSensor class represents a single hardware sensor. + + The life cycle of a sensor is typically: + + \list + \o Create a sub-class of QSensor on the stack or heap. + \o Setup as required by the application. + \o Start receiving values. + \o Sensor data is used by the application. + \o Stop receiving values. + \endlist + + The sensor data is delivered via QSensorData and its sub-classes. + + \sa QSensorReading +*/ + +/*! + Construct the \a type sensor as a child of \a parent. +*/ +QSensor::QSensor(const QByteArray &type, QObject *parent) + : QObject(parent) + , d(new QSensorPrivate) +{ + d->type = type; + registerInstance(); // so the availableSensorsChanged() signal works +} + +/*! + Destroy the sensor. Stops the sensor if it has not already been stopped. +*/ +QSensor::~QSensor() +{ + stop(); + Q_FOREACH (QSensorFilter *filter, d->filters) + filter->setSensor(0); + delete d->backend; + d->backend = 0; + // owned by the backend + d->device_reading = 0; + d->filter_reading = 0; + d->cache_reading = 0; +} + +/*! + \property QSensor::connectedToBackend + \brief a value indicating if the sensor has connected to a backend. + + A sensor that has not been connected to a backend cannot do anything useful. + + Call the connectToBackend() method to force the sensor to connect to a backend + immediately. This is automatically called if you call start() so you only need + to do this if you need access to sensor properties (ie. to poll the sensor's + meta-data before you use it). +*/ + +bool QSensor::isConnectedToBackend() const +{ + return (d->backend != 0); +} + +/*! + \property QSensor::sensorid + \brief the backend identifier for the sensor. + + Note that the identifier is filled out automatically + when the sensor is connected to a backend. If you want + to connect a specific backend, you should call + setIdentifier() before connectToBackend(). +*/ + +QByteArray QSensor::identifier() const +{ + return d->identifier; +} + +void QSensor::setIdentifier(const QByteArray &identifier) +{ + if (isConnectedToBackend()) { + qWarning() << "ERROR: Cannot call QSensor::setIdentifier while connected to a backend!"; + return; + } + d->identifier = identifier; +} + +/*! + \property QSensor::type + \brief the type of the sensor. +*/ + +QByteArray QSensor::type() const +{ + return d->type; +} + +/*! + Try to connect to a sensor backend. + + Returns true if a suitable backend could be found, false otherwise. + + The type must be set before calling this method if you are using QSensor directly. + + \sa isConnectedToBackend() +*/ +bool QSensor::connectToBackend() +{ + if (isConnectedToBackend()) + return true; + + d->backend = QSensorManager::createBackend(this); + + // Reset the properties to their default values and re-set them now so + // that the logic we've put into the setters gets called. + if (d->dataRate != 0) { + int tmp = d->dataRate; + d->dataRate = 0; + setDataRate(tmp); + } + if (d->outputRange != -1) { + int tmp = d->outputRange; + d->outputRange = -1; + setOutputRange(tmp); + } + + return isConnectedToBackend(); +} + +/*! + \property QSensor::busy + \brief a value to indicate if the sensor is busy. + + Some sensors may be on the system but unavailable for use. + This function will return true if the sensor is busy. You + will not be able to start() the sensor. + + Note that this function does not return true if you + are using the sensor, only if another process is using + the sensor. + + \sa busyChanged() +*/ + +bool QSensor::isBusy() const +{ + return d->busy; +} + +/*! + \fn QSensor::busyChanged() + + This signal is emitted when the sensor is no longer busy. + This can be used to grab a sensor when it becomes available. + + \code + sensor.start(); + if (sensor.isBusy()) { + // need to wait for busyChanged signal and try again + } + \endcode +*/ + +/*! + \property QSensor::active + \brief a value to indicate if the sensor is active. + + This is true if the sensor is active (returning values). This is false otherwise. + + Note that setting this value to true will not have an immediate effect. Instead, + the sensor will be started once the event loop has been reached. +*/ +void QSensor::setActive(bool active) +{ + if (active == isActive()) + return; + + if (active) + QTimer::singleShot(0, this, SLOT(start())); // delay ensures all properties have been set if using QML + else + stop(); +} + +bool QSensor::isActive() const +{ + return d->active; +} + +/*! + \property QSensor::availableDataRates + \brief the data rates that the sensor supports. + + This is a list of the data rates that the sensor supports. + Measured in Hertz. + + Entries in the list can represent discrete rates or a + continuous range of rates. + A discrete rate is noted by having both values the same. + + See the sensor_explorer example for an example of how to interpret and use + this information. + + Note that this information is not mandatory as not all sensors have a rate at which + they run. In such cases, the list will be empty. + + \sa QSensor::dataRate, qrangelist +*/ + +qrangelist QSensor::availableDataRates() const +{ + return d->availableDataRates; +} + +/*! + \property QSensor::dataRate + \brief the data rate that the sensor should be run at. + + Measured in Hertz. + + The data rate is the maximum frequency at which the sensor can detect changes. + + Setting this property is not portable and can cause conflicts with other + applications. Check with the sensor backend and platform documentation for + any policy regarding multiple applications requesting a data rate. + + The default value (0) means that the app does not care what the data rate is. + Applications should consider using a timer-based poll of the current value or + ensure that the code that processes values can run very quickly as the platform + may provide updates hundreds of times each second. + + This should be set before calling start() because the sensor may not + notice changes to this value while it is running. + + Note that there is no mechanism to determine the current data rate in use by the + platform. + + \sa QSensor::availableDataRates +*/ + +int QSensor::dataRate() const +{ + return d->dataRate; +} + +void QSensor::setDataRate(int rate) +{ + if (rate == 0 || !isConnectedToBackend()) { + d->dataRate = rate; + return; + } + bool warn = true; + Q_FOREACH (const qrange &range, d->availableDataRates) { + if (rate >= range.first && rate <= range.second) { + warn = false; + d->dataRate = rate; + break; + } + } + if (warn) { + qWarning() << "setDataRate:" << rate << "is not supported by the sensor."; + } +} + +/*! + Start retrieving values from the sensor. + Returns true if the sensor was started, false otherwise. + + The sensor may fail to start for several reasons. + + Once an application has started a sensor it must wait until the sensor receives a + new value before it can query the sensor's values. This is due to how the sensor + receives values from the system. Sensors do not (in general) poll for new values, + rather new values are pushed to the sensors as they happen. + + For example, this code will not work as intended. + + \badcode + sensor->start(); + sensor->reading()->x(); // no data available + \endcode + + To work correctly, the code that accesses the reading should ensure the + readingChanged() signal has been emitted. + + \code + connect(sensor, SIGNAL(readingChanged()), this, SLOT(checkReading())); + sensor->start(); + } + void MyClass::checkReading() { + sensor->reading()->x(); + \endcode + + \sa QSensor::busy +*/ +bool QSensor::start() +{ + if (isActive()) + return true; + if (!connectToBackend()) + return false; + // Set these flags to their defaults + d->active = true; + d->busy = false; + // Backend will update the flags appropriately + d->backend->start(); + Q_EMIT activeChanged(); + return isActive(); +} + +/*! + Stop retrieving values from the sensor. + + This releases the sensor so that other processes can use it. + + \sa QSensor::busy +*/ +void QSensor::stop() +{ + if (!isConnectedToBackend() || !isActive()) + return; + d->active = false; + d->backend->stop(); + Q_EMIT activeChanged(); +} + +/*! + \property QSensor::reading + \brief the reading class. + + The reading class provides access to sensor readings. The reading object + is a volatile cache of the most recent sensor reading that has been received + so the application should process readings immediately or save the values + somewhere for later processing. + + Note that this will return 0 until a sensor backend is connected to a backend. + + Also note that readings are not immediately available after start() is called. + Applications must wait for the readingChanged() signal to be emitted. + + \sa isConnectedToBackend(), start() +*/ + +QSensorReading *QSensor::reading() const +{ + return d->cache_reading; +} + +/*! + Add a \a filter to the sensor. + + The sensor does not take ownership of the filter. + QSensorFilter will inform the sensor if it is destroyed. + + \sa QSensorFilter +*/ +void QSensor::addFilter(QSensorFilter *filter) +{ + if (!filter) { + qWarning() << "addFilter: passed a null filter!"; + return; + } + filter->setSensor(this); + d->filters << filter; +} + +/*! + Remove \a filter from the sensor. + + \sa QSensorFilter +*/ +void QSensor::removeFilter(QSensorFilter *filter) +{ + if (!filter) { + qWarning() << "removeFilter: passed a null filter!"; + return; + } + d->filters.removeOne(filter); + filter->setSensor(0); +} + +/*! + Returns the filters currently attached to the sensor. + + \sa QSensorFilter +*/ +QList QSensor::filters() const +{ + return d->filters; +} + +/*! + \fn QSensor::d_func() const + \internal +*/ + +/*! + \fn QSensor::readingChanged() + + This signal is emitted when a new sensor reading is received. + + The sensor reading can be found in the QSensor::reading property. Note that the + reading object is a volatile cache of the most recent sensor reading that has + been received so the application should process the reading immediately or + save the values somewhere for later processing. + + Before this signal has been emitted for the first time, the reading object will + have uninitialized data. + + \sa start() +*/ + +/*! + \fn QSensor::activeChanged() + + This signal is emitted when the QSensor::active property has changed. + + \sa QSensor::active +*/ + +/*! + \property QSensor::outputRanges + \brief a list of output ranges the sensor supports. + + A sensor may have more than one output range. Typically this is done + to give a greater measurement range at the cost of lowering accuracy. + + Note that this information is not mandatory. This information is typically only + available for sensors that have selectable output ranges (such as typical + accelerometers). + + \sa QSensor::outputRange, qoutputrangelist +*/ + +qoutputrangelist QSensor::outputRanges() const +{ + return d->outputRanges; +} + +/*! + \property QSensor::outputRange + \brief the output range in use by the sensor. + + This value represents the index in the QSensor::outputRanges list to use. + + Setting this property is not portable and can cause conflicts with other + applications. Check with the sensor backend and platform documentation for + any policy regarding multiple applications requesting an output range. + + The default value (-1) means that the app does not care what the output range is. + + Note that there is no mechanism to determine the current output range in use by the + platform. + + \sa QSensor::outputRanges +*/ + +int QSensor::outputRange() const +{ + return d->outputRange; +} + +void QSensor::setOutputRange(int index) +{ + if (index == -1 || !isConnectedToBackend()) { + d->outputRange = index; + return; + } + bool warn = true; + if (index >= 0 && index < d->outputRanges.count()) { + warn = false; + d->outputRange = index; + } + if (warn) { + qWarning() << "setOutputRange:" << index << "is not supported by the sensor."; + } +} + +/*! + \property QSensor::description + \brief a descriptive string for the sensor. +*/ + +QString QSensor::description() const +{ + return d->description; +} + +/*! + \property QSensor::error + \brief the last error code set on the sensor. + + Note that error codes are sensor-specific. +*/ + +int QSensor::error() const +{ + return d->error; +} + +/*! + \fn QSensor::sensorError(int error) + + This signal is emitted when an \a error code is set on the sensor. + Note that some errors will cause the sensor to stop working. + You should call isActive() to determine if the sensor is still running. +*/ + +/*! + \fn QSensor::availableSensorsChanged() + + This signal is emitted when the list of available sensors has changed. + The sensors available to a program will not generally change over time + however some of the avilable sensors may represent hardware that is not + permanently connected. For example, a game controller that is connected + via bluetooth would become available when it was on and would become + unavailable when it was off. + + \sa QSensor::sensorTypes(), QSensor::sensorsForType() +*/ + +/*! + \property QSensor::maxBufferSize + + The property holds the maximum buffer size. + + Note that this may be undefined, in which case the sensor does not support any form of buffering. + + \sa QSensor::bufferSize, QSensor::efficientBufferSize +*/ + +/*! + \property QSensor::efficientBufferSize + + The property holds the most efficient buffer size. Normally this is 1 (which means + no particular size is most efficient). Some sensor drivers have a FIFO buffer which + makes it more efficient to deliver the FIFO's size worth of readings at one time. + + Note that this may be undefined, in which case the sensor does not support any form of buffering. + + \sa QSensor::bufferSize, QSensor::maxBufferSize +*/ + +/*! + \property QSensor::bufferSize + + This property holds the size of the buffer. By default (and if the property + is left undefined), the buffer size is 1, which means no buffering. + If the maximum buffer size is 1 (or undefined), then buffering is not supported + by the sensor. + + Setting bufferSize greater than maxBufferSize will cause maxBufferSize to be used. + + Buffering is turned on when bufferSize is greater than 1. The sensor will collect + the requested number of samples and deliver them all to the application at one time. + They will be delivered to the application as a burst of changed readings so it is + particularly important that the application processes each reading immediately or + saves the values somewhere else. + + If stop() is called when buffering is on-going, the partial buffer is not delivered. + + When the sensor is started with buffering option, values are collected from that + moment onwards. There is no pre-existing buffer that can be utilized. + + The buffer size can only be changed while the sensor is not active. + + \sa QSensor::maxBufferSize, QSensor::efficientBufferSize +*/ + +// ===================================================================== + +/*! + \class QSensorFilter + \ingroup sensors_main + \inmodule QtSensors + + \brief The QSensorFilter class provides an efficient + callback facility for asynchronous notifications of + sensor changes. + + Some sensors (eg. the accelerometer) are often accessed very frequently. + This may be slowed down by the use of signals and slots. + The QSensorFilter interface provides a more efficient way for the + sensor to notify your class that the sensor has changed. + + Additionally, multiple filters can be added to a sensor. They are called + in order and each filter has the option to modify the values in the reading + or to suppress the reading altogether. + + Note that the values in the class returned by QSensor::reading() will + not be updated until after the filters have been run. + + \sa filter() +*/ + +/*! + \internal +*/ +QSensorFilter::QSensorFilter() + : m_sensor(0) +{ +} + +/*! + Notifies the attached sensor (if any) that the filter is being destroyed. +*/ +QSensorFilter::~QSensorFilter() +{ + if (m_sensor) + m_sensor->removeFilter(this); +} + +/*! + \fn QSensorFilter::filter(QSensorReading *reading) + + This function is called when the sensor \a reading changes. + + The filter can modify the reading. + + Returns true to allow the next filter to receive the value. + If this is the last filter, returning true causes the signal + to be emitted and the value is stored in the sensor. + + Returns false to drop the reading. +*/ + +/*! + \internal +*/ +void QSensorFilter::setSensor(QSensor *sensor) +{ + m_sensor = sensor; +} + +// ===================================================================== + +/*! + \class QSensorReading + \ingroup sensors_main + \inmodule QtSensors + + \brief The QSensorReading class holds the readings from the sensor. + + Note that QSensorReading is not particularly useful by itself. The interesting + data for each sensor is defined in a sub-class of QSensorReading. +*/ + +/*! + \internal +*/ +QSensorReading::QSensorReading(QObject *parent, QSensorReadingPrivate *_d) + : QObject(parent) + , d(_d?_d:new QSensorReadingPrivate) +{ +} + +/*! + \internal +*/ +QSensorReading::~QSensorReading() +{ +} + +/*! + \property QSensorReading::timestamp + \brief the timestamp of the reading. + + \sa qtimestamp +*/ + +/*! + Returns the timestamp of the reading. +*/ +qtimestamp QSensorReading::timestamp() const +{ + return d->timestamp; +} + +/*! + Sets the \a timestamp of the reading. +*/ +void QSensorReading::setTimestamp(qtimestamp timestamp) +{ + d->timestamp = timestamp; +} + +/*! + Returns the number of extra properties that the reading has. + + Note that this does not count properties declared in QSensorReading. + + As an example, this returns 3 for QAccelerometerReading because + there are 3 properties defined in that class. +*/ +int QSensorReading::valueCount() const +{ + const QMetaObject *mo = metaObject(); + return mo->propertyCount() - mo->propertyOffset(); +} + +/*! + Returns the value of the property at \a index. + + Note that this function is slower than calling the data function directly. + + Here is an example of getting a property via the different mechanisms available. + + Accessing directly provides the best performance but requires compile-time knowledge + of the data you are accessing. + + \code + QAccelerometerReading *reading = ...; + qreal x = reading->x(); + \endcode + + You can also access a property by name. To do this you must call QObject::property(). + + \code + qreal x = reading->property("x").value(); + \endcode + + Finally, you can access values via numeric index. + + \code + qreal x = reading->value(0).value(); + \endcode + + Note that value() can only access properties declared with Q_PROPERTY() in sub-classes + of QSensorReading. + + \sa valueCount(), QObject::property() +*/ +QVariant QSensorReading::value(int index) const +{ + // get them meta-object + const QMetaObject *mo = metaObject(); + + // determine the index of the property we want + index += mo->propertyOffset(); + + // get the meta-property + QMetaProperty property = mo->property(index); + + // read the property + return property.read(this); +} + +/*! + \fn QSensorReading::copyValuesFrom(QSensorReading *other) + \internal + + Copy values from other into this reading. Implemented by sub-classes + using the DECLARE_READING() and IMPLEMENT_READING() macros. + + Note that this method should only be called by QSensorBackend. +*/ +void QSensorReading::copyValuesFrom(QSensorReading *other) +{ + QSensorReadingPrivate *my_ptr = d.data(); + QSensorReadingPrivate *other_ptr = other->d.data(); + /* Do a direct copy of the private class */ + *(my_ptr) = *(other_ptr); +} + +/*! + \fn QSensorReading::d_ptr() + \internal + No longer used. Exists to keep the winscw build happy. +*/ + +/*! + \macro DECLARE_READING(classname) + \relates QSensorReading + \brief The DECLARE_READING macro adds some required methods to a reading class. + + This macro should be used for all reading classes. Pass the \a classname of your reading class. + + \code + class MyReading : public QSensorReading + { + Q_OBJECT + Q_PROPERTY(qreal myprop READ myprop) + DECLARE_READING(MyReading) + public: + qreal myprop() const; + vod setMyprop(qreal myprop); + }; + \endcode + + \sa IMPLEMENT_READING() +*/ + +/*! + \macro IMPLEMENT_READING(classname) + \relates QSensorReading + \brief The IMPLEMENT_READING macro implements the required methods for a reading class. + + This macro should be used for all reading classes. It should be placed into a single compilation + unit (source file), not into a header file. Pass the \a classname of your reading class. + + \code + IMPLEMENT_READING(MyReading) + \endcode + + \sa DECLARE_READING() +*/ + +#include "moc_qsensor.cpp" +QT_END_NAMESPACE + -- cgit v1.2.3