/*************************************************************************** ** ** ** QCustomPlot, an easy to use, modern plotting widget for Qt ** ** Copyright (C) 2011-2017 Emanuel Eichhammer ** ** ** ** 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, either 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 for more details. ** ** ** ** You should have received a copy of the GNU General Public License ** ** along with this program. If not, see http://www.gnu.org/licenses/. ** ** ** **************************************************************************** ** Author: Emanuel Eichhammer ** ** Website/Contact: http://www.qcustomplot.com/ ** ** Date: 04.09.17 ** ** Version: 2.0.0 ** ****************************************************************************/ #ifndef QCUSTOMPLOT_H #define QCUSTOMPLOT_H #include // some Qt version/configuration dependent macros to include or exclude certain code paths: #ifdef QCUSTOMPLOT_USE_OPENGL # if QT_VERSION < QT_VERSION_CHECK(5, 0, 0) # define QCP_OPENGL_PBUFFER # else # define QCP_OPENGL_FBO # endif # if QT_VERSION >= QT_VERSION_CHECK(5, 3, 0) # define QCP_OPENGL_OFFSCREENSURFACE # endif #endif #if QT_VERSION >= QT_VERSION_CHECK(5, 4, 0) # define QCP_DEVICEPIXELRATIO_SUPPORTED # if QT_VERSION >= QT_VERSION_CHECK(5, 6, 0) # define QCP_DEVICEPIXELRATIO_FLOAT # endif #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef QCP_OPENGL_FBO # include # include # ifdef QCP_OPENGL_OFFSCREENSURFACE # include # else # include # endif #endif #ifdef QCP_OPENGL_PBUFFER # include #endif #if QT_VERSION < QT_VERSION_CHECK(5, 0, 0) # include # include # include # include #else # include # include # include #endif class QCPPainter; class QCustomPlot; class QCPLayerable; class QCPLayoutElement; class QCPLayout; class QCPAxis; class QCPAxisRect; class QCPAxisPainterPrivate; class QCPAbstractPlottable; class QCPGraph; class QCPAbstractItem; class QCPPlottableInterface1D; class QCPLegend; class QCPItemPosition; class QCPLayer; class QCPAbstractLegendItem; class QCPSelectionRect; class QCPColorMap; class QCPColorScale; class QCPBars; /* including file 'src/global.h', size 16225 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ // decl definitions for shared library compilation/usage: #if defined(QCUSTOMPLOT_COMPILE_LIBRARY) # define QCP_LIB_DECL Q_DECL_EXPORT #elif defined(QCUSTOMPLOT_USE_LIBRARY) # define QCP_LIB_DECL Q_DECL_IMPORT #else # define QCP_LIB_DECL #endif // define empty macro for Q_DECL_OVERRIDE if it doesn't exist (Qt < 5) #ifndef Q_DECL_OVERRIDE # define Q_DECL_OVERRIDE #endif /*! The QCP Namespace contains general enums, QFlags and functions used throughout the QCustomPlot library. It provides QMetaObject-based reflection of its enums and flags via \a QCP::staticMetaObject. */ #ifndef Q_MOC_RUN namespace QCP { #else class QCP { // when in moc-run, make it look like a class, so we get Q_GADGET, Q_ENUMS/Q_FLAGS features in namespace Q_GADGET Q_ENUMS(ExportPen) Q_ENUMS(ResolutionUnit) Q_ENUMS(SignDomain) Q_ENUMS(MarginSide) Q_FLAGS(MarginSides) Q_ENUMS(AntialiasedElement) Q_FLAGS(AntialiasedElements) Q_ENUMS(PlottingHint) Q_FLAGS(PlottingHints) Q_ENUMS(Interaction) Q_FLAGS(Interactions) Q_ENUMS(SelectionRectMode) Q_ENUMS(SelectionType) public: #endif /*! Defines the different units in which the image resolution can be specified in the export functions. \see QCustomPlot::savePng, QCustomPlot::saveJpg, QCustomPlot::saveBmp, QCustomPlot::saveRastered */ enum ResolutionUnit { ruDotsPerMeter ///< Resolution is given in dots per meter (dpm) ,ruDotsPerCentimeter ///< Resolution is given in dots per centimeter (dpcm) ,ruDotsPerInch ///< Resolution is given in dots per inch (DPI/PPI) }; /*! Defines how cosmetic pens (pens with numerical width 0) are handled during export. \see QCustomPlot::savePdf */ enum ExportPen { epNoCosmetic ///< Cosmetic pens are converted to pens with pixel width 1 when exporting ,epAllowCosmetic ///< Cosmetic pens are exported normally (e.g. in PDF exports, cosmetic pens always appear as 1 pixel on screen, independent of viewer zoom level) }; /*! Represents negative and positive sign domain, e.g. for passing to \ref QCPAbstractPlottable::getKeyRange and \ref QCPAbstractPlottable::getValueRange. This is primarily needed when working with logarithmic axis scales, since only one of the sign domains can be visible at a time. */ enum SignDomain { sdNegative ///< The negative sign domain, i.e. numbers smaller than zero ,sdBoth ///< Both sign domains, including zero, i.e. all numbers ,sdPositive ///< The positive sign domain, i.e. numbers greater than zero }; /*! Defines the sides of a rectangular entity to which margins can be applied. \see QCPLayoutElement::setAutoMargins, QCPAxisRect::setAutoMargins */ enum MarginSide { msLeft = 0x01 ///< 0x01 left margin ,msRight = 0x02 ///< 0x02 right margin ,msTop = 0x04 ///< 0x04 top margin ,msBottom = 0x08 ///< 0x08 bottom margin ,msAll = 0xFF ///< 0xFF all margins ,msNone = 0x00 ///< 0x00 no margin }; Q_DECLARE_FLAGS(MarginSides, MarginSide) /*! Defines what objects of a plot can be forcibly drawn antialiased/not antialiased. If an object is neither forcibly drawn antialiased nor forcibly drawn not antialiased, it is up to the respective element how it is drawn. Typically it provides a \a setAntialiased function for this. \c AntialiasedElements is a flag of or-combined elements of this enum type. \see QCustomPlot::setAntialiasedElements, QCustomPlot::setNotAntialiasedElements */ enum AntialiasedElement { aeAxes = 0x0001 ///< 0x0001 Axis base line and tick marks ,aeGrid = 0x0002 ///< 0x0002 Grid lines ,aeSubGrid = 0x0004 ///< 0x0004 Sub grid lines ,aeLegend = 0x0008 ///< 0x0008 Legend box ,aeLegendItems = 0x0010 ///< 0x0010 Legend items ,aePlottables = 0x0020 ///< 0x0020 Main lines of plottables ,aeItems = 0x0040 ///< 0x0040 Main lines of items ,aeScatters = 0x0080 ///< 0x0080 Scatter symbols of plottables (excluding scatter symbols of type ssPixmap) ,aeFills = 0x0100 ///< 0x0100 Borders of fills (e.g. under or between graphs) ,aeZeroLine = 0x0200 ///< 0x0200 Zero-lines, see \ref QCPGrid::setZeroLinePen ,aeOther = 0x8000 ///< 0x8000 Other elements that don't fit into any of the existing categories ,aeAll = 0xFFFF ///< 0xFFFF All elements ,aeNone = 0x0000 ///< 0x0000 No elements }; Q_DECLARE_FLAGS(AntialiasedElements, AntialiasedElement) /*! Defines plotting hints that control various aspects of the quality and speed of plotting. \see QCustomPlot::setPlottingHints */ enum PlottingHint { phNone = 0x000 ///< 0x000 No hints are set ,phFastPolylines = 0x001 ///< 0x001 Graph/Curve lines are drawn with a faster method. This reduces the quality especially of the line segment ///< joins, thus is most effective for pen sizes larger than 1. It is only used for solid line pens. ,phImmediateRefresh = 0x002 ///< 0x002 causes an immediate repaint() instead of a soft update() when QCustomPlot::replot() is called with parameter \ref QCustomPlot::rpRefreshHint. ///< This is set by default to prevent the plot from freezing on fast consecutive replots (e.g. user drags ranges with mouse). ,phCacheLabels = 0x004 ///< 0x004 axis (tick) labels will be cached as pixmaps, increasing replot performance. }; Q_DECLARE_FLAGS(PlottingHints, PlottingHint) /*! Defines the mouse interactions possible with QCustomPlot. \c Interactions is a flag of or-combined elements of this enum type. \see QCustomPlot::setInteractions */ enum Interaction { iRangeDrag = 0x001 ///< 0x001 Axis ranges are draggable (see \ref QCPAxisRect::setRangeDrag, \ref QCPAxisRect::setRangeDragAxes) ,iRangeZoom = 0x002 ///< 0x002 Axis ranges are zoomable with the mouse wheel (see \ref QCPAxisRect::setRangeZoom, \ref QCPAxisRect::setRangeZoomAxes) ,iMultiSelect = 0x004 ///< 0x004 The user can select multiple objects by holding the modifier set by \ref QCustomPlot::setMultiSelectModifier while clicking ,iSelectPlottables = 0x008 ///< 0x008 Plottables are selectable (e.g. graphs, curves, bars,... see QCPAbstractPlottable) ,iSelectAxes = 0x010 ///< 0x010 Axes are selectable (or parts of them, see QCPAxis::setSelectableParts) ,iSelectLegend = 0x020 ///< 0x020 Legends are selectable (or their child items, see QCPLegend::setSelectableParts) ,iSelectItems = 0x040 ///< 0x040 Items are selectable (Rectangles, Arrows, Textitems, etc. see \ref QCPAbstractItem) ,iSelectOther = 0x080 ///< 0x080 All other objects are selectable (e.g. your own derived layerables, other layout elements,...) }; Q_DECLARE_FLAGS(Interactions, Interaction) /*! Defines the behaviour of the selection rect. \see QCustomPlot::setSelectionRectMode, QCustomPlot::selectionRect, QCPSelectionRect */ enum SelectionRectMode { srmNone ///< The selection rect is disabled, and all mouse events are forwarded to the underlying objects, e.g. for axis range dragging ,srmZoom ///< When dragging the mouse, a selection rect becomes active. Upon releasing, the axes that are currently set as range zoom axes (\ref QCPAxisRect::setRangeZoomAxes) will have their ranges zoomed accordingly. ,srmSelect ///< When dragging the mouse, a selection rect becomes active. Upon releasing, plottable data points that were within the selection rect are selected, if the plottable's selectability setting permits. (See \ref dataselection "data selection mechanism" for details.) ,srmCustom ///< When dragging the mouse, a selection rect becomes active. It is the programmer's responsibility to connect according slots to the selection rect's signals (e.g. \ref QCPSelectionRect::accepted) in order to process the user interaction. }; /*! Defines the different ways a plottable can be selected. These images show the effect of the different selection types, when the indicated selection rect was dragged:

\image html selectiontype-none.png stNone

\image html selectiontype-whole.png stWhole

\image html selectiontype-singledata.png stSingleData

\image html selectiontype-datarange.png stDataRange

\image html selectiontype-multipledataranges.png stMultipleDataRanges

\see QCPAbstractPlottable::setSelectable, QCPDataSelection::enforceType */ enum SelectionType { stNone ///< The plottable is not selectable ,stWhole ///< Selection behaves like \ref stMultipleDataRanges, but if there are any data points selected, the entire plottable is drawn as selected. ,stSingleData ///< One individual data point can be selected at a time ,stDataRange ///< Multiple contiguous data points (a data range) can be selected ,stMultipleDataRanges ///< Any combination of data points/ranges can be selected }; /*! \internal Returns whether the specified \a value is considered an invalid data value for plottables (i.e. is \e nan or \e +/-inf). This function is used to check data validity upon replots, when the compiler flag \c QCUSTOMPLOT_CHECK_DATA is set. */ inline bool isInvalidData(double value) { return qIsNaN(value) || qIsInf(value); } /*! \internal \overload Checks two arguments instead of one. */ inline bool isInvalidData(double value1, double value2) { return isInvalidData(value1) || isInvalidData(value2); } /*! \internal Sets the specified \a side of \a margins to \a value \see getMarginValue */ inline void setMarginValue(QMargins &margins, QCP::MarginSide side, int value) { switch (side) { case QCP::msLeft: margins.setLeft(value); break; case QCP::msRight: margins.setRight(value); break; case QCP::msTop: margins.setTop(value); break; case QCP::msBottom: margins.setBottom(value); break; case QCP::msAll: margins = QMargins(value, value, value, value); break; default: break; } } /*! \internal Returns the value of the specified \a side of \a margins. If \a side is \ref QCP::msNone or \ref QCP::msAll, returns 0. \see setMarginValue */ inline int getMarginValue(const QMargins &margins, QCP::MarginSide side) { switch (side) { case QCP::msLeft: return margins.left(); case QCP::msRight: return margins.right(); case QCP::msTop: return margins.top(); case QCP::msBottom: return margins.bottom(); default: break; } return 0; } extern const QMetaObject staticMetaObject; // in moc-run we create a static meta object for QCP "fake" object. This line is the link to it via QCP::staticMetaObject in normal operation as namespace } // end of namespace QCP Q_DECLARE_OPERATORS_FOR_FLAGS(QCP::AntialiasedElements) Q_DECLARE_OPERATORS_FOR_FLAGS(QCP::PlottingHints) Q_DECLARE_OPERATORS_FOR_FLAGS(QCP::MarginSides) Q_DECLARE_OPERATORS_FOR_FLAGS(QCP::Interactions) Q_DECLARE_METATYPE(QCP::ExportPen) Q_DECLARE_METATYPE(QCP::ResolutionUnit) Q_DECLARE_METATYPE(QCP::SignDomain) Q_DECLARE_METATYPE(QCP::MarginSide) Q_DECLARE_METATYPE(QCP::AntialiasedElement) Q_DECLARE_METATYPE(QCP::PlottingHint) Q_DECLARE_METATYPE(QCP::Interaction) Q_DECLARE_METATYPE(QCP::SelectionRectMode) Q_DECLARE_METATYPE(QCP::SelectionType) /* end of 'src/global.h' */ /* including file 'src/vector2d.h', size 4928 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPVector2D { public: QCPVector2D(); QCPVector2D(double x, double y); QCPVector2D(const QPoint &point); QCPVector2D(const QPointF &point); // getters: double x() const { return mX; } double y() const { return mY; } double &rx() { return mX; } double &ry() { return mY; } // setters: void setX(double x) { mX = x; } void setY(double y) { mY = y; } // non-virtual methods: double length() const { return qSqrt(mX*mX+mY*mY); } double lengthSquared() const { return mX*mX+mY*mY; } QPoint toPoint() const { return QPoint(mX, mY); } QPointF toPointF() const { return QPointF(mX, mY); } bool isNull() const { return qIsNull(mX) && qIsNull(mY); } void normalize(); QCPVector2D normalized() const; QCPVector2D perpendicular() const { return QCPVector2D(-mY, mX); } double dot(const QCPVector2D &vec) const { return mX*vec.mX+mY*vec.mY; } double distanceSquaredToLine(const QCPVector2D &start, const QCPVector2D &end) const; double distanceSquaredToLine(const QLineF &line) const; double distanceToStraightLine(const QCPVector2D &base, const QCPVector2D &direction) const; QCPVector2D &operator*=(double factor); QCPVector2D &operator/=(double divisor); QCPVector2D &operator+=(const QCPVector2D &vector); QCPVector2D &operator-=(const QCPVector2D &vector); private: // property members: double mX, mY; friend inline const QCPVector2D operator*(double factor, const QCPVector2D &vec); friend inline const QCPVector2D operator*(const QCPVector2D &vec, double factor); friend inline const QCPVector2D operator/(const QCPVector2D &vec, double divisor); friend inline const QCPVector2D operator+(const QCPVector2D &vec1, const QCPVector2D &vec2); friend inline const QCPVector2D operator-(const QCPVector2D &vec1, const QCPVector2D &vec2); friend inline const QCPVector2D operator-(const QCPVector2D &vec); }; Q_DECLARE_TYPEINFO(QCPVector2D, Q_MOVABLE_TYPE); inline const QCPVector2D operator*(double factor, const QCPVector2D &vec) { return QCPVector2D(vec.mX*factor, vec.mY*factor); } inline const QCPVector2D operator*(const QCPVector2D &vec, double factor) { return QCPVector2D(vec.mX*factor, vec.mY*factor); } inline const QCPVector2D operator/(const QCPVector2D &vec, double divisor) { return QCPVector2D(vec.mX/divisor, vec.mY/divisor); } inline const QCPVector2D operator+(const QCPVector2D &vec1, const QCPVector2D &vec2) { return QCPVector2D(vec1.mX+vec2.mX, vec1.mY+vec2.mY); } inline const QCPVector2D operator-(const QCPVector2D &vec1, const QCPVector2D &vec2) { return QCPVector2D(vec1.mX-vec2.mX, vec1.mY-vec2.mY); } inline const QCPVector2D operator-(const QCPVector2D &vec) { return QCPVector2D(-vec.mX, -vec.mY); } /*! \relates QCPVector2D Prints \a vec in a human readable format to the qDebug output. */ inline QDebug operator<< (QDebug d, const QCPVector2D &vec) { d.nospace() << "QCPVector2D(" << vec.x() << ", " << vec.y() << ")"; return d.space(); } /* end of 'src/vector2d.h' */ /* including file 'src/painter.h', size 4035 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPPainter : public QPainter { Q_GADGET public: /*! Defines special modes the painter can operate in. They disable or enable certain subsets of features/fixes/workarounds, depending on whether they are wanted on the respective output device. */ enum PainterMode { pmDefault = 0x00 ///< 0x00 Default mode for painting on screen devices ,pmVectorized = 0x01 ///< 0x01 Mode for vectorized painting (e.g. PDF export). For example, this prevents some antialiasing fixes. ,pmNoCaching = 0x02 ///< 0x02 Mode for all sorts of exports (e.g. PNG, PDF,...). For example, this prevents using cached pixmap labels ,pmNonCosmetic = 0x04 ///< 0x04 Turns pen widths 0 to 1, i.e. disables cosmetic pens. (A cosmetic pen is always drawn with width 1 pixel in the vector image/pdf viewer, independent of zoom.) }; Q_ENUMS(PainterMode) Q_FLAGS(PainterModes) Q_DECLARE_FLAGS(PainterModes, PainterMode) QCPPainter(); explicit QCPPainter(QPaintDevice *device); // getters: bool antialiasing() const { return testRenderHint(QPainter::Antialiasing); } PainterModes modes() const { return mModes; } // setters: void setAntialiasing(bool enabled); void setMode(PainterMode mode, bool enabled=true); void setModes(PainterModes modes); // methods hiding non-virtual base class functions (QPainter bug workarounds): bool begin(QPaintDevice *device); void setPen(const QPen &pen); void setPen(const QColor &color); void setPen(Qt::PenStyle penStyle); void drawLine(const QLineF &line); void drawLine(const QPointF &p1, const QPointF &p2) {drawLine(QLineF(p1, p2));} void save(); void restore(); // non-virtual methods: void makeNonCosmetic(); protected: // property members: PainterModes mModes; bool mIsAntialiasing; // non-property members: QStack mAntialiasingStack; }; Q_DECLARE_OPERATORS_FOR_FLAGS(QCPPainter::PainterModes) Q_DECLARE_METATYPE(QCPPainter::PainterMode) /* end of 'src/painter.h' */ /* including file 'src/paintbuffer.h', size 4958 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAbstractPaintBuffer { public: explicit QCPAbstractPaintBuffer(const QSize &size, double devicePixelRatio); virtual ~QCPAbstractPaintBuffer(); // getters: QSize size() const { return mSize; } bool invalidated() const { return mInvalidated; } double devicePixelRatio() const { return mDevicePixelRatio; } // setters: void setSize(const QSize &size); void setInvalidated(bool invalidated=true); void setDevicePixelRatio(double ratio); // introduced virtual methods: virtual QCPPainter *startPainting() = 0; virtual void donePainting() {} virtual void draw(QCPPainter *painter) const = 0; virtual void clear(const QColor &color) = 0; protected: // property members: QSize mSize; double mDevicePixelRatio; // non-property members: bool mInvalidated; // introduced virtual methods: virtual void reallocateBuffer() = 0; }; class QCP_LIB_DECL QCPPaintBufferPixmap : public QCPAbstractPaintBuffer { public: explicit QCPPaintBufferPixmap(const QSize &size, double devicePixelRatio); virtual ~QCPPaintBufferPixmap(); // reimplemented virtual methods: virtual QCPPainter *startPainting() Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) const Q_DECL_OVERRIDE; void clear(const QColor &color) Q_DECL_OVERRIDE; protected: // non-property members: QPixmap mBuffer; // reimplemented virtual methods: virtual void reallocateBuffer() Q_DECL_OVERRIDE; }; #ifdef QCP_OPENGL_PBUFFER class QCP_LIB_DECL QCPPaintBufferGlPbuffer : public QCPAbstractPaintBuffer { public: explicit QCPPaintBufferGlPbuffer(const QSize &size, double devicePixelRatio, int multisamples); virtual ~QCPPaintBufferGlPbuffer(); // reimplemented virtual methods: virtual QCPPainter *startPainting() Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) const Q_DECL_OVERRIDE; void clear(const QColor &color) Q_DECL_OVERRIDE; protected: // non-property members: QGLPixelBuffer *mGlPBuffer; int mMultisamples; // reimplemented virtual methods: virtual void reallocateBuffer() Q_DECL_OVERRIDE; }; #endif // QCP_OPENGL_PBUFFER #ifdef QCP_OPENGL_FBO class QCP_LIB_DECL QCPPaintBufferGlFbo : public QCPAbstractPaintBuffer { public: explicit QCPPaintBufferGlFbo(const QSize &size, double devicePixelRatio, QWeakPointer glContext, QWeakPointer glPaintDevice); virtual ~QCPPaintBufferGlFbo(); // reimplemented virtual methods: virtual QCPPainter *startPainting() Q_DECL_OVERRIDE; virtual void donePainting() Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) const Q_DECL_OVERRIDE; void clear(const QColor &color) Q_DECL_OVERRIDE; protected: // non-property members: QWeakPointer mGlContext; QWeakPointer mGlPaintDevice; QOpenGLFramebufferObject *mGlFrameBuffer; // reimplemented virtual methods: virtual void reallocateBuffer() Q_DECL_OVERRIDE; }; #endif // QCP_OPENGL_FBO /* end of 'src/paintbuffer.h' */ /* including file 'src/layer.h', size 6885 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPLayer : public QObject { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QCustomPlot* parentPlot READ parentPlot) Q_PROPERTY(QString name READ name) Q_PROPERTY(int index READ index) Q_PROPERTY(QList children READ children) Q_PROPERTY(bool visible READ visible WRITE setVisible) Q_PROPERTY(LayerMode mode READ mode WRITE setMode) /// \endcond public: /*! Defines the different rendering modes of a layer. Depending on the mode, certain layers can be replotted individually, without the need to replot (possibly complex) layerables on other layers. \see setMode */ enum LayerMode { lmLogical ///< Layer is used only for rendering order, and shares paint buffer with all other adjacent logical layers. ,lmBuffered ///< Layer has its own paint buffer and may be replotted individually (see \ref replot). }; Q_ENUMS(LayerMode) QCPLayer(QCustomPlot* parentPlot, const QString &layerName); virtual ~QCPLayer(); // getters: QCustomPlot *parentPlot() const { return mParentPlot; } QString name() const { return mName; } int index() const { return mIndex; } QList children() const { return mChildren; } bool visible() const { return mVisible; } LayerMode mode() const { return mMode; } // setters: void setVisible(bool visible); void setMode(LayerMode mode); // non-virtual methods: void replot(); protected: // property members: QCustomPlot *mParentPlot; QString mName; int mIndex; QList mChildren; bool mVisible; LayerMode mMode; // non-property members: QWeakPointer mPaintBuffer; // non-virtual methods: void draw(QCPPainter *painter); void drawToPaintBuffer(); void addChild(QCPLayerable *layerable, bool prepend); void removeChild(QCPLayerable *layerable); private: Q_DISABLE_COPY(QCPLayer) friend class QCustomPlot; friend class QCPLayerable; }; Q_DECLARE_METATYPE(QCPLayer::LayerMode) class QCP_LIB_DECL QCPLayerable : public QObject { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(bool visible READ visible WRITE setVisible) Q_PROPERTY(QCustomPlot* parentPlot READ parentPlot) Q_PROPERTY(QCPLayerable* parentLayerable READ parentLayerable) Q_PROPERTY(QCPLayer* layer READ layer WRITE setLayer NOTIFY layerChanged) Q_PROPERTY(bool antialiased READ antialiased WRITE setAntialiased) /// \endcond public: QCPLayerable(QCustomPlot *plot, QString targetLayer=QString(), QCPLayerable *parentLayerable=0); virtual ~QCPLayerable(); // getters: bool visible() const { return mVisible; } QCustomPlot *parentPlot() const { return mParentPlot; } QCPLayerable *parentLayerable() const { return mParentLayerable.data(); } QCPLayer *layer() const { return mLayer; } bool antialiased() const { return mAntialiased; } // setters: void setVisible(bool on); Q_SLOT bool setLayer(QCPLayer *layer); bool setLayer(const QString &layerName); void setAntialiased(bool enabled); // introduced virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const; // non-property methods: bool realVisibility() const; signals: void layerChanged(QCPLayer *newLayer); protected: // property members: bool mVisible; QCustomPlot *mParentPlot; QPointer mParentLayerable; QCPLayer *mLayer; bool mAntialiased; // introduced virtual methods: virtual void parentPlotInitialized(QCustomPlot *parentPlot); virtual QCP::Interaction selectionCategory() const; virtual QRect clipRect() const; virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const = 0; virtual void draw(QCPPainter *painter) = 0; // selection events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged); virtual void deselectEvent(bool *selectionStateChanged); // low-level mouse events: virtual void mousePressEvent(QMouseEvent *event, const QVariant &details); virtual void mouseMoveEvent(QMouseEvent *event, const QPointF &startPos); virtual void mouseReleaseEvent(QMouseEvent *event, const QPointF &startPos); virtual void mouseDoubleClickEvent(QMouseEvent *event, const QVariant &details); virtual void wheelEvent(QWheelEvent *event); // non-property methods: void initializeParentPlot(QCustomPlot *parentPlot); void setParentLayerable(QCPLayerable* parentLayerable); bool moveToLayer(QCPLayer *layer, bool prepend); void applyAntialiasingHint(QCPPainter *painter, bool localAntialiased, QCP::AntialiasedElement overrideElement) const; private: Q_DISABLE_COPY(QCPLayerable) friend class QCustomPlot; friend class QCPLayer; friend class QCPAxisRect; }; /* end of 'src/layer.h' */ /* including file 'src/axis/range.h', size 5280 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPRange { public: double lower, upper; QCPRange(); QCPRange(double lower, double upper); bool operator==(const QCPRange& other) const { return lower == other.lower && upper == other.upper; } bool operator!=(const QCPRange& other) const { return !(*this == other); } QCPRange &operator+=(const double& value) { lower+=value; upper+=value; return *this; } QCPRange &operator-=(const double& value) { lower-=value; upper-=value; return *this; } QCPRange &operator*=(const double& value) { lower*=value; upper*=value; return *this; } QCPRange &operator/=(const double& value) { lower/=value; upper/=value; return *this; } friend inline const QCPRange operator+(const QCPRange&, double); friend inline const QCPRange operator+(double, const QCPRange&); friend inline const QCPRange operator-(const QCPRange& range, double value); friend inline const QCPRange operator*(const QCPRange& range, double value); friend inline const QCPRange operator*(double value, const QCPRange& range); friend inline const QCPRange operator/(const QCPRange& range, double value); double size() const { return upper-lower; } double center() const { return (upper+lower)*0.5; } void normalize() { if (lower > upper) qSwap(lower, upper); } void expand(const QCPRange &otherRange); void expand(double includeCoord); QCPRange expanded(const QCPRange &otherRange) const; QCPRange expanded(double includeCoord) const; QCPRange bounded(double lowerBound, double upperBound) const; QCPRange sanitizedForLogScale() const; QCPRange sanitizedForLinScale() const; bool contains(double value) const { return value >= lower && value <= upper; } static bool validRange(double lower, double upper); static bool validRange(const QCPRange &range); static const double minRange; static const double maxRange; }; Q_DECLARE_TYPEINFO(QCPRange, Q_MOVABLE_TYPE); /*! \relates QCPRange Prints \a range in a human readable format to the qDebug output. */ inline QDebug operator<< (QDebug d, const QCPRange &range) { d.nospace() << "QCPRange(" << range.lower << ", " << range.upper << ")"; return d.space(); } /*! Adds \a value to both boundaries of the range. */ inline const QCPRange operator+(const QCPRange& range, double value) { QCPRange result(range); result += value; return result; } /*! Adds \a value to both boundaries of the range. */ inline const QCPRange operator+(double value, const QCPRange& range) { QCPRange result(range); result += value; return result; } /*! Subtracts \a value from both boundaries of the range. */ inline const QCPRange operator-(const QCPRange& range, double value) { QCPRange result(range); result -= value; return result; } /*! Multiplies both boundaries of the range by \a value. */ inline const QCPRange operator*(const QCPRange& range, double value) { QCPRange result(range); result *= value; return result; } /*! Multiplies both boundaries of the range by \a value. */ inline const QCPRange operator*(double value, const QCPRange& range) { QCPRange result(range); result *= value; return result; } /*! Divides both boundaries of the range by \a value. */ inline const QCPRange operator/(const QCPRange& range, double value) { QCPRange result(range); result /= value; return result; } /* end of 'src/axis/range.h' */ /* including file 'src/selection.h', size 8579 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPDataRange { public: QCPDataRange(); QCPDataRange(int begin, int end); bool operator==(const QCPDataRange& other) const { return mBegin == other.mBegin && mEnd == other.mEnd; } bool operator!=(const QCPDataRange& other) const { return !(*this == other); } // getters: int begin() const { return mBegin; } int end() const { return mEnd; } int size() const { return mEnd-mBegin; } int length() const { return size(); } // setters: void setBegin(int begin) { mBegin = begin; } void setEnd(int end) { mEnd = end; } // non-property methods: bool isValid() const { return (mEnd >= mBegin) && (mBegin >= 0); } bool isEmpty() const { return length() == 0; } QCPDataRange bounded(const QCPDataRange &other) const; QCPDataRange expanded(const QCPDataRange &other) const; QCPDataRange intersection(const QCPDataRange &other) const; QCPDataRange adjusted(int changeBegin, int changeEnd) const { return QCPDataRange(mBegin+changeBegin, mEnd+changeEnd); } bool intersects(const QCPDataRange &other) const; bool contains(const QCPDataRange &other) const; private: // property members: int mBegin, mEnd; }; Q_DECLARE_TYPEINFO(QCPDataRange, Q_MOVABLE_TYPE); class QCP_LIB_DECL QCPDataSelection { public: explicit QCPDataSelection(); explicit QCPDataSelection(const QCPDataRange &range); bool operator==(const QCPDataSelection& other) const; bool operator!=(const QCPDataSelection& other) const { return !(*this == other); } QCPDataSelection &operator+=(const QCPDataSelection& other); QCPDataSelection &operator+=(const QCPDataRange& other); QCPDataSelection &operator-=(const QCPDataSelection& other); QCPDataSelection &operator-=(const QCPDataRange& other); friend inline const QCPDataSelection operator+(const QCPDataSelection& a, const QCPDataSelection& b); friend inline const QCPDataSelection operator+(const QCPDataRange& a, const QCPDataSelection& b); friend inline const QCPDataSelection operator+(const QCPDataSelection& a, const QCPDataRange& b); friend inline const QCPDataSelection operator+(const QCPDataRange& a, const QCPDataRange& b); friend inline const QCPDataSelection operator-(const QCPDataSelection& a, const QCPDataSelection& b); friend inline const QCPDataSelection operator-(const QCPDataRange& a, const QCPDataSelection& b); friend inline const QCPDataSelection operator-(const QCPDataSelection& a, const QCPDataRange& b); friend inline const QCPDataSelection operator-(const QCPDataRange& a, const QCPDataRange& b); // getters: int dataRangeCount() const { return mDataRanges.size(); } int dataPointCount() const; QCPDataRange dataRange(int index=0) const; QList dataRanges() const { return mDataRanges; } QCPDataRange span() const; // non-property methods: void addDataRange(const QCPDataRange &dataRange, bool simplify=true); void clear(); bool isEmpty() const { return mDataRanges.isEmpty(); } void simplify(); void enforceType(QCP::SelectionType type); bool contains(const QCPDataSelection &other) const; QCPDataSelection intersection(const QCPDataRange &other) const; QCPDataSelection intersection(const QCPDataSelection &other) const; QCPDataSelection inverse(const QCPDataRange &outerRange) const; private: // property members: QList mDataRanges; inline static bool lessThanDataRangeBegin(const QCPDataRange &a, const QCPDataRange &b) { return a.begin() < b.begin(); } }; Q_DECLARE_METATYPE(QCPDataSelection) /*! Return a \ref QCPDataSelection with the data points in \a a joined with the data points in \a b. The resulting data selection is already simplified (see \ref QCPDataSelection::simplify). */ inline const QCPDataSelection operator+(const QCPDataSelection& a, const QCPDataSelection& b) { QCPDataSelection result(a); result += b; return result; } /*! Return a \ref QCPDataSelection with the data points in \a a joined with the data points in \a b. The resulting data selection is already simplified (see \ref QCPDataSelection::simplify). */ inline const QCPDataSelection operator+(const QCPDataRange& a, const QCPDataSelection& b) { QCPDataSelection result(a); result += b; return result; } /*! Return a \ref QCPDataSelection with the data points in \a a joined with the data points in \a b. The resulting data selection is already simplified (see \ref QCPDataSelection::simplify). */ inline const QCPDataSelection operator+(const QCPDataSelection& a, const QCPDataRange& b) { QCPDataSelection result(a); result += b; return result; } /*! Return a \ref QCPDataSelection with the data points in \a a joined with the data points in \a b. The resulting data selection is already simplified (see \ref QCPDataSelection::simplify). */ inline const QCPDataSelection operator+(const QCPDataRange& a, const QCPDataRange& b) { QCPDataSelection result(a); result += b; return result; } /*! Return a \ref QCPDataSelection with the data points which are in \a a but not in \a b. */ inline const QCPDataSelection operator-(const QCPDataSelection& a, const QCPDataSelection& b) { QCPDataSelection result(a); result -= b; return result; } /*! Return a \ref QCPDataSelection with the data points which are in \a a but not in \a b. */ inline const QCPDataSelection operator-(const QCPDataRange& a, const QCPDataSelection& b) { QCPDataSelection result(a); result -= b; return result; } /*! Return a \ref QCPDataSelection with the data points which are in \a a but not in \a b. */ inline const QCPDataSelection operator-(const QCPDataSelection& a, const QCPDataRange& b) { QCPDataSelection result(a); result -= b; return result; } /*! Return a \ref QCPDataSelection with the data points which are in \a a but not in \a b. */ inline const QCPDataSelection operator-(const QCPDataRange& a, const QCPDataRange& b) { QCPDataSelection result(a); result -= b; return result; } /*! \relates QCPDataRange Prints \a dataRange in a human readable format to the qDebug output. */ inline QDebug operator<< (QDebug d, const QCPDataRange &dataRange) { d.nospace() << "[" << dataRange.begin() << ".." << dataRange.end()-1 << "]"; return d.space(); } /*! \relates QCPDataSelection Prints \a selection in a human readable format to the qDebug output. */ inline QDebug operator<< (QDebug d, const QCPDataSelection &selection) { d.nospace() << "QCPDataSelection("; for (int i=0; i elements(QCP::MarginSide side) const { return mChildren.value(side); } bool isEmpty() const; void clear(); protected: // non-property members: QCustomPlot *mParentPlot; QHash > mChildren; // introduced virtual methods: virtual int commonMargin(QCP::MarginSide side) const; // non-virtual methods: void addChild(QCP::MarginSide side, QCPLayoutElement *element); void removeChild(QCP::MarginSide side, QCPLayoutElement *element); private: Q_DISABLE_COPY(QCPMarginGroup) friend class QCPLayoutElement; }; class QCP_LIB_DECL QCPLayoutElement : public QCPLayerable { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QCPLayout* layout READ layout) Q_PROPERTY(QRect rect READ rect) Q_PROPERTY(QRect outerRect READ outerRect WRITE setOuterRect) Q_PROPERTY(QMargins margins READ margins WRITE setMargins) Q_PROPERTY(QMargins minimumMargins READ minimumMargins WRITE setMinimumMargins) Q_PROPERTY(QSize minimumSize READ minimumSize WRITE setMinimumSize) Q_PROPERTY(QSize maximumSize READ maximumSize WRITE setMaximumSize) Q_PROPERTY(SizeConstraintRect sizeConstraintRect READ sizeConstraintRect WRITE setSizeConstraintRect) /// \endcond public: /*! Defines the phases of the update process, that happens just before a replot. At each phase, \ref update is called with the according UpdatePhase value. */ enum UpdatePhase { upPreparation ///< Phase used for any type of preparation that needs to be done before margin calculation and layout ,upMargins ///< Phase in which the margins are calculated and set ,upLayout ///< Final phase in which the layout system places the rects of the elements }; Q_ENUMS(UpdatePhase) /*! Defines to which rect of a layout element the size constraints that can be set via \ref setMinimumSize and \ref setMaximumSize apply. The outer rect (\ref outerRect) includes the margins (e.g. in the case of a QCPAxisRect the axis labels), whereas the inner rect (\ref rect) does not. \see setSizeConstraintRect */ enum SizeConstraintRect { scrInnerRect ///< Minimum/Maximum size constraints apply to inner rect , scrOuterRect ///< Minimum/Maximum size constraints apply to outer rect, thus include layout element margins }; Q_ENUMS(SizeConstraintRect) explicit QCPLayoutElement(QCustomPlot *parentPlot=0); virtual ~QCPLayoutElement(); // getters: QCPLayout *layout() const { return mParentLayout; } QRect rect() const { return mRect; } QRect outerRect() const { return mOuterRect; } QMargins margins() const { return mMargins; } QMargins minimumMargins() const { return mMinimumMargins; } QCP::MarginSides autoMargins() const { return mAutoMargins; } QSize minimumSize() const { return mMinimumSize; } QSize maximumSize() const { return mMaximumSize; } SizeConstraintRect sizeConstraintRect() const { return mSizeConstraintRect; } QCPMarginGroup *marginGroup(QCP::MarginSide side) const { return mMarginGroups.value(side, (QCPMarginGroup*)0); } QHash marginGroups() const { return mMarginGroups; } // setters: void setOuterRect(const QRect &rect); void setMargins(const QMargins &margins); void setMinimumMargins(const QMargins &margins); void setAutoMargins(QCP::MarginSides sides); void setMinimumSize(const QSize &size); void setMinimumSize(int width, int height); void setMaximumSize(const QSize &size); void setMaximumSize(int width, int height); void setSizeConstraintRect(SizeConstraintRect constraintRect); void setMarginGroup(QCP::MarginSides sides, QCPMarginGroup *group); // introduced virtual methods: virtual void update(UpdatePhase phase); virtual QSize minimumOuterSizeHint() const; virtual QSize maximumOuterSizeHint() const; virtual QList elements(bool recursive) const; // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; protected: // property members: QCPLayout *mParentLayout; QSize mMinimumSize, mMaximumSize; SizeConstraintRect mSizeConstraintRect; QRect mRect, mOuterRect; QMargins mMargins, mMinimumMargins; QCP::MarginSides mAutoMargins; QHash mMarginGroups; // introduced virtual methods: virtual int calculateAutoMargin(QCP::MarginSide side); virtual void layoutChanged(); // reimplemented virtual methods: virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE { Q_UNUSED(painter) } virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE { Q_UNUSED(painter) } virtual void parentPlotInitialized(QCustomPlot *parentPlot) Q_DECL_OVERRIDE; private: Q_DISABLE_COPY(QCPLayoutElement) friend class QCustomPlot; friend class QCPLayout; friend class QCPMarginGroup; }; Q_DECLARE_METATYPE(QCPLayoutElement::UpdatePhase) class QCP_LIB_DECL QCPLayout : public QCPLayoutElement { Q_OBJECT public: explicit QCPLayout(); // reimplemented virtual methods: virtual void update(UpdatePhase phase) Q_DECL_OVERRIDE; virtual QList elements(bool recursive) const Q_DECL_OVERRIDE; // introduced virtual methods: virtual int elementCount() const = 0; virtual QCPLayoutElement* elementAt(int index) const = 0; virtual QCPLayoutElement* takeAt(int index) = 0; virtual bool take(QCPLayoutElement* element) = 0; virtual void simplify(); // non-virtual methods: bool removeAt(int index); bool remove(QCPLayoutElement* element); void clear(); protected: // introduced virtual methods: virtual void updateLayout(); // non-virtual methods: void sizeConstraintsChanged() const; void adoptElement(QCPLayoutElement *el); void releaseElement(QCPLayoutElement *el); QVector getSectionSizes(QVector maxSizes, QVector minSizes, QVector stretchFactors, int totalSize) const; static QSize getFinalMinimumOuterSize(const QCPLayoutElement *el); static QSize getFinalMaximumOuterSize(const QCPLayoutElement *el); private: Q_DISABLE_COPY(QCPLayout) friend class QCPLayoutElement; }; class QCP_LIB_DECL QCPLayoutGrid : public QCPLayout { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(int rowCount READ rowCount) Q_PROPERTY(int columnCount READ columnCount) Q_PROPERTY(QList columnStretchFactors READ columnStretchFactors WRITE setColumnStretchFactors) Q_PROPERTY(QList rowStretchFactors READ rowStretchFactors WRITE setRowStretchFactors) Q_PROPERTY(int columnSpacing READ columnSpacing WRITE setColumnSpacing) Q_PROPERTY(int rowSpacing READ rowSpacing WRITE setRowSpacing) Q_PROPERTY(FillOrder fillOrder READ fillOrder WRITE setFillOrder) Q_PROPERTY(int wrap READ wrap WRITE setWrap) /// \endcond public: /*! Defines in which direction the grid is filled when using \ref addElement(QCPLayoutElement*). The column/row at which wrapping into the next row/column occurs can be specified with \ref setWrap. \see setFillOrder */ enum FillOrder { foRowsFirst ///< Rows are filled first, and a new element is wrapped to the next column if the row count would exceed \ref setWrap. ,foColumnsFirst ///< Columns are filled first, and a new element is wrapped to the next row if the column count would exceed \ref setWrap. }; Q_ENUMS(FillOrder) explicit QCPLayoutGrid(); virtual ~QCPLayoutGrid(); // getters: int rowCount() const { return mElements.size(); } int columnCount() const { return mElements.size() > 0 ? mElements.first().size() : 0; } QList columnStretchFactors() const { return mColumnStretchFactors; } QList rowStretchFactors() const { return mRowStretchFactors; } int columnSpacing() const { return mColumnSpacing; } int rowSpacing() const { return mRowSpacing; } int wrap() const { return mWrap; } FillOrder fillOrder() const { return mFillOrder; } // setters: void setColumnStretchFactor(int column, double factor); void setColumnStretchFactors(const QList &factors); void setRowStretchFactor(int row, double factor); void setRowStretchFactors(const QList &factors); void setColumnSpacing(int pixels); void setRowSpacing(int pixels); void setWrap(int count); void setFillOrder(FillOrder order, bool rearrange=true); // reimplemented virtual methods: virtual void updateLayout() Q_DECL_OVERRIDE; virtual int elementCount() const Q_DECL_OVERRIDE { return rowCount()*columnCount(); } virtual QCPLayoutElement* elementAt(int index) const Q_DECL_OVERRIDE; virtual QCPLayoutElement* takeAt(int index) Q_DECL_OVERRIDE; virtual bool take(QCPLayoutElement* element) Q_DECL_OVERRIDE; virtual QList elements(bool recursive) const Q_DECL_OVERRIDE; virtual void simplify() Q_DECL_OVERRIDE; virtual QSize minimumOuterSizeHint() const Q_DECL_OVERRIDE; virtual QSize maximumOuterSizeHint() const Q_DECL_OVERRIDE; // non-virtual methods: QCPLayoutElement *element(int row, int column) const; bool addElement(int row, int column, QCPLayoutElement *element); bool addElement(QCPLayoutElement *element); bool hasElement(int row, int column); void expandTo(int newRowCount, int newColumnCount); void insertRow(int newIndex); void insertColumn(int newIndex); int rowColToIndex(int row, int column) const; void indexToRowCol(int index, int &row, int &column) const; protected: // property members: QList > mElements; QList mColumnStretchFactors; QList mRowStretchFactors; int mColumnSpacing, mRowSpacing; int mWrap; FillOrder mFillOrder; // non-virtual methods: void getMinimumRowColSizes(QVector *minColWidths, QVector *minRowHeights) const; void getMaximumRowColSizes(QVector *maxColWidths, QVector *maxRowHeights) const; private: Q_DISABLE_COPY(QCPLayoutGrid) }; Q_DECLARE_METATYPE(QCPLayoutGrid::FillOrder) class QCP_LIB_DECL QCPLayoutInset : public QCPLayout { Q_OBJECT public: /*! Defines how the placement and sizing is handled for a certain element in a QCPLayoutInset. */ enum InsetPlacement { ipFree ///< The element may be positioned/sized arbitrarily, see \ref setInsetRect ,ipBorderAligned ///< The element is aligned to one of the layout sides, see \ref setInsetAlignment }; Q_ENUMS(InsetPlacement) explicit QCPLayoutInset(); virtual ~QCPLayoutInset(); // getters: InsetPlacement insetPlacement(int index) const; Qt::Alignment insetAlignment(int index) const; QRectF insetRect(int index) const; // setters: void setInsetPlacement(int index, InsetPlacement placement); void setInsetAlignment(int index, Qt::Alignment alignment); void setInsetRect(int index, const QRectF &rect); // reimplemented virtual methods: virtual void updateLayout() Q_DECL_OVERRIDE; virtual int elementCount() const Q_DECL_OVERRIDE; virtual QCPLayoutElement* elementAt(int index) const Q_DECL_OVERRIDE; virtual QCPLayoutElement* takeAt(int index) Q_DECL_OVERRIDE; virtual bool take(QCPLayoutElement* element) Q_DECL_OVERRIDE; virtual void simplify() Q_DECL_OVERRIDE {} virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; // non-virtual methods: void addElement(QCPLayoutElement *element, Qt::Alignment alignment); void addElement(QCPLayoutElement *element, const QRectF &rect); protected: // property members: QList mElements; QList mInsetPlacement; QList mInsetAlignment; QList mInsetRect; private: Q_DISABLE_COPY(QCPLayoutInset) }; Q_DECLARE_METATYPE(QCPLayoutInset::InsetPlacement) /* end of 'src/layout.h' */ /* including file 'src/lineending.h', size 4426 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPLineEnding { Q_GADGET public: /*! Defines the type of ending decoration for line-like items, e.g. an arrow. \image html QCPLineEnding.png The width and length of these decorations can be controlled with the functions \ref setWidth and \ref setLength. Some decorations like \ref esDisc, \ref esSquare, \ref esDiamond and \ref esBar only support a width, the length property is ignored. \see QCPItemLine::setHead, QCPItemLine::setTail, QCPItemCurve::setHead, QCPItemCurve::setTail, QCPAxis::setLowerEnding, QCPAxis::setUpperEnding */ enum EndingStyle { esNone ///< No ending decoration ,esFlatArrow ///< A filled arrow head with a straight/flat back (a triangle) ,esSpikeArrow ///< A filled arrow head with an indented back ,esLineArrow ///< A non-filled arrow head with open back ,esDisc ///< A filled circle ,esSquare ///< A filled square ,esDiamond ///< A filled diamond (45 degrees rotated square) ,esBar ///< A bar perpendicular to the line ,esHalfBar ///< A bar perpendicular to the line, pointing out to only one side (to which side can be changed with \ref setInverted) ,esSkewedBar ///< A bar that is skewed (skew controllable via \ref setLength) }; Q_ENUMS(EndingStyle) QCPLineEnding(); QCPLineEnding(EndingStyle style, double width=8, double length=10, bool inverted=false); // getters: EndingStyle style() const { return mStyle; } double width() const { return mWidth; } double length() const { return mLength; } bool inverted() const { return mInverted; } // setters: void setStyle(EndingStyle style); void setWidth(double width); void setLength(double length); void setInverted(bool inverted); // non-property methods: double boundingDistance() const; double realLength() const; void draw(QCPPainter *painter, const QCPVector2D &pos, const QCPVector2D &dir) const; void draw(QCPPainter *painter, const QCPVector2D &pos, double angle) const; protected: // property members: EndingStyle mStyle; double mWidth, mLength; bool mInverted; }; Q_DECLARE_TYPEINFO(QCPLineEnding, Q_MOVABLE_TYPE); Q_DECLARE_METATYPE(QCPLineEnding::EndingStyle) /* end of 'src/lineending.h' */ /* including file 'src/axis/axisticker.h', size 4177 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTicker { Q_GADGET public: /*! Defines the strategies that the axis ticker may follow when choosing the size of the tick step. \see setTickStepStrategy */ enum TickStepStrategy { tssReadability ///< A nicely readable tick step is prioritized over matching the requested number of ticks (see \ref setTickCount) ,tssMeetTickCount ///< Less readable tick steps are allowed which in turn facilitates getting closer to the requested tick count }; Q_ENUMS(TickStepStrategy) QCPAxisTicker(); virtual ~QCPAxisTicker(); // getters: TickStepStrategy tickStepStrategy() const { return mTickStepStrategy; } int tickCount() const { return mTickCount; } double tickOrigin() const { return mTickOrigin; } // setters: void setTickStepStrategy(TickStepStrategy strategy); void setTickCount(int count); void setTickOrigin(double origin); // introduced virtual methods: virtual void generate(const QCPRange &range, const QLocale &locale, QChar formatChar, int precision, QVector &ticks, QVector *subTicks, QVector *tickLabels); protected: // property members: TickStepStrategy mTickStepStrategy; int mTickCount; double mTickOrigin; // introduced virtual methods: virtual double getTickStep(const QCPRange &range); virtual int getSubTickCount(double tickStep); virtual QString getTickLabel(double tick, const QLocale &locale, QChar formatChar, int precision); virtual QVector createTickVector(double tickStep, const QCPRange &range); virtual QVector createSubTickVector(int subTickCount, const QVector &ticks); virtual QVector createLabelVector(const QVector &ticks, const QLocale &locale, QChar formatChar, int precision); // non-virtual methods: void trimTicks(const QCPRange &range, QVector &ticks, bool keepOneOutlier) const; double pickClosest(double target, const QVector &candidates) const; double getMantissa(double input, double *magnitude=0) const; double cleanMantissa(double input) const; }; Q_DECLARE_METATYPE(QCPAxisTicker::TickStepStrategy) Q_DECLARE_METATYPE(QSharedPointer) /* end of 'src/axis/axisticker.h' */ /* including file 'src/axis/axistickerdatetime.h', size 3289 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTickerDateTime : public QCPAxisTicker { public: QCPAxisTickerDateTime(); // getters: QString dateTimeFormat() const { return mDateTimeFormat; } Qt::TimeSpec dateTimeSpec() const { return mDateTimeSpec; } // setters: void setDateTimeFormat(const QString &format); void setDateTimeSpec(Qt::TimeSpec spec); void setTickOrigin(double origin); // hides base class method but calls baseclass implementation ("using" throws off IDEs and doxygen) void setTickOrigin(const QDateTime &origin); // static methods: static QDateTime keyToDateTime(double key); static double dateTimeToKey(const QDateTime dateTime); static double dateTimeToKey(const QDate date); protected: // property members: QString mDateTimeFormat; Qt::TimeSpec mDateTimeSpec; // non-property members: enum DateStrategy {dsNone, dsUniformTimeInDay, dsUniformDayInMonth} mDateStrategy; // reimplemented virtual methods: virtual double getTickStep(const QCPRange &range) Q_DECL_OVERRIDE; virtual int getSubTickCount(double tickStep) Q_DECL_OVERRIDE; virtual QString getTickLabel(double tick, const QLocale &locale, QChar formatChar, int precision) Q_DECL_OVERRIDE; virtual QVector createTickVector(double tickStep, const QCPRange &range) Q_DECL_OVERRIDE; }; /* end of 'src/axis/axistickerdatetime.h' */ /* including file 'src/axis/axistickertime.h', size 3542 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTickerTime : public QCPAxisTicker { Q_GADGET public: /*! Defines the logical units in which fractions of time spans can be expressed. \see setFieldWidth, setTimeFormat */ enum TimeUnit { tuMilliseconds ///< Milliseconds, one thousandth of a second (%%z in \ref setTimeFormat) ,tuSeconds ///< Seconds (%%s in \ref setTimeFormat) ,tuMinutes ///< Minutes (%%m in \ref setTimeFormat) ,tuHours ///< Hours (%%h in \ref setTimeFormat) ,tuDays ///< Days (%%d in \ref setTimeFormat) }; Q_ENUMS(TimeUnit) QCPAxisTickerTime(); // getters: QString timeFormat() const { return mTimeFormat; } int fieldWidth(TimeUnit unit) const { return mFieldWidth.value(unit); } // setters: void setTimeFormat(const QString &format); void setFieldWidth(TimeUnit unit, int width); protected: // property members: QString mTimeFormat; QHash mFieldWidth; // non-property members: TimeUnit mSmallestUnit, mBiggestUnit; QHash mFormatPattern; // reimplemented virtual methods: virtual double getTickStep(const QCPRange &range) Q_DECL_OVERRIDE; virtual int getSubTickCount(double tickStep) Q_DECL_OVERRIDE; virtual QString getTickLabel(double tick, const QLocale &locale, QChar formatChar, int precision) Q_DECL_OVERRIDE; // non-virtual methods: void replaceUnit(QString &text, TimeUnit unit, int value) const; }; Q_DECLARE_METATYPE(QCPAxisTickerTime::TimeUnit) /* end of 'src/axis/axistickertime.h' */ /* including file 'src/axis/axistickerfixed.h', size 3308 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTickerFixed : public QCPAxisTicker { Q_GADGET public: /*! Defines how the axis ticker may modify the specified tick step (\ref setTickStep) in order to control the number of ticks in the axis range. \see setScaleStrategy */ enum ScaleStrategy { ssNone ///< Modifications are not allowed, the specified tick step is absolutely fixed. This might cause a high tick density and overlapping labels if the axis range is zoomed out. ,ssMultiples ///< An integer multiple of the specified tick step is allowed. The used factor follows the base class properties of \ref setTickStepStrategy and \ref setTickCount. ,ssPowers ///< An integer power of the specified tick step is allowed. }; Q_ENUMS(ScaleStrategy) QCPAxisTickerFixed(); // getters: double tickStep() const { return mTickStep; } ScaleStrategy scaleStrategy() const { return mScaleStrategy; } // setters: void setTickStep(double step); void setScaleStrategy(ScaleStrategy strategy); protected: // property members: double mTickStep; ScaleStrategy mScaleStrategy; // reimplemented virtual methods: virtual double getTickStep(const QCPRange &range) Q_DECL_OVERRIDE; }; Q_DECLARE_METATYPE(QCPAxisTickerFixed::ScaleStrategy) /* end of 'src/axis/axistickerfixed.h' */ /* including file 'src/axis/axistickertext.h', size 3085 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTickerText : public QCPAxisTicker { public: QCPAxisTickerText(); // getters: QMap &ticks() { return mTicks; } int subTickCount() const { return mSubTickCount; } // setters: void setTicks(const QMap &ticks); void setTicks(const QVector &positions, const QVector labels); void setSubTickCount(int subTicks); // non-virtual methods: void clear(); void addTick(double position, QString label); void addTicks(const QMap &ticks); void addTicks(const QVector &positions, const QVector &labels); protected: // property members: QMap mTicks; int mSubTickCount; // reimplemented virtual methods: virtual double getTickStep(const QCPRange &range) Q_DECL_OVERRIDE; virtual int getSubTickCount(double tickStep) Q_DECL_OVERRIDE; virtual QString getTickLabel(double tick, const QLocale &locale, QChar formatChar, int precision) Q_DECL_OVERRIDE; virtual QVector createTickVector(double tickStep, const QCPRange &range) Q_DECL_OVERRIDE; }; /* end of 'src/axis/axistickertext.h' */ /* including file 'src/axis/axistickerpi.h', size 3911 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTickerPi : public QCPAxisTicker { Q_GADGET public: /*! Defines how fractions should be displayed in tick labels. \see setFractionStyle */ enum FractionStyle { fsFloatingPoint ///< Fractions are displayed as regular decimal floating point numbers, e.g. "0.25" or "0.125". ,fsAsciiFractions ///< Fractions are written as rationals using ASCII characters only, e.g. "1/4" or "1/8" ,fsUnicodeFractions ///< Fractions are written using sub- and superscript UTF-8 digits and the fraction symbol. }; Q_ENUMS(FractionStyle) QCPAxisTickerPi(); // getters: QString piSymbol() const { return mPiSymbol; } double piValue() const { return mPiValue; } bool periodicity() const { return mPeriodicity; } FractionStyle fractionStyle() const { return mFractionStyle; } // setters: void setPiSymbol(QString symbol); void setPiValue(double pi); void setPeriodicity(int multiplesOfPi); void setFractionStyle(FractionStyle style); protected: // property members: QString mPiSymbol; double mPiValue; int mPeriodicity; FractionStyle mFractionStyle; // non-property members: double mPiTickStep; // size of one tick step in units of mPiValue // reimplemented virtual methods: virtual double getTickStep(const QCPRange &range) Q_DECL_OVERRIDE; virtual int getSubTickCount(double tickStep) Q_DECL_OVERRIDE; virtual QString getTickLabel(double tick, const QLocale &locale, QChar formatChar, int precision) Q_DECL_OVERRIDE; // non-virtual methods: void simplifyFraction(int &numerator, int &denominator) const; QString fractionToString(int numerator, int denominator) const; QString unicodeFraction(int numerator, int denominator) const; QString unicodeSuperscript(int number) const; QString unicodeSubscript(int number) const; }; Q_DECLARE_METATYPE(QCPAxisTickerPi::FractionStyle) /* end of 'src/axis/axistickerpi.h' */ /* including file 'src/axis/axistickerlog.h', size 2663 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisTickerLog : public QCPAxisTicker { public: QCPAxisTickerLog(); // getters: double logBase() const { return mLogBase; } int subTickCount() const { return mSubTickCount; } // setters: void setLogBase(double base); void setSubTickCount(int subTicks); protected: // property members: double mLogBase; int mSubTickCount; // non-property members: double mLogBaseLnInv; // reimplemented virtual methods: virtual double getTickStep(const QCPRange &range) Q_DECL_OVERRIDE; virtual int getSubTickCount(double tickStep) Q_DECL_OVERRIDE; virtual QVector createTickVector(double tickStep, const QCPRange &range) Q_DECL_OVERRIDE; }; /* end of 'src/axis/axistickerlog.h' */ /* including file 'src/axis/axis.h', size 20634 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPGrid :public QCPLayerable { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(bool subGridVisible READ subGridVisible WRITE setSubGridVisible) Q_PROPERTY(bool antialiasedSubGrid READ antialiasedSubGrid WRITE setAntialiasedSubGrid) Q_PROPERTY(bool antialiasedZeroLine READ antialiasedZeroLine WRITE setAntialiasedZeroLine) Q_PROPERTY(QPen pen READ pen WRITE setPen) Q_PROPERTY(QPen subGridPen READ subGridPen WRITE setSubGridPen) Q_PROPERTY(QPen zeroLinePen READ zeroLinePen WRITE setZeroLinePen) /// \endcond public: explicit QCPGrid(QCPAxis *parentAxis); // getters: bool subGridVisible() const { return mSubGridVisible; } bool antialiasedSubGrid() const { return mAntialiasedSubGrid; } bool antialiasedZeroLine() const { return mAntialiasedZeroLine; } QPen pen() const { return mPen; } QPen subGridPen() const { return mSubGridPen; } QPen zeroLinePen() const { return mZeroLinePen; } // setters: void setSubGridVisible(bool visible); void setAntialiasedSubGrid(bool enabled); void setAntialiasedZeroLine(bool enabled); void setPen(const QPen &pen); void setSubGridPen(const QPen &pen); void setZeroLinePen(const QPen &pen); protected: // property members: bool mSubGridVisible; bool mAntialiasedSubGrid, mAntialiasedZeroLine; QPen mPen, mSubGridPen, mZeroLinePen; // non-property members: QCPAxis *mParentAxis; // reimplemented virtual methods: virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; // non-virtual methods: void drawGridLines(QCPPainter *painter) const; void drawSubGridLines(QCPPainter *painter) const; friend class QCPAxis; }; class QCP_LIB_DECL QCPAxis : public QCPLayerable { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(AxisType axisType READ axisType) Q_PROPERTY(QCPAxisRect* axisRect READ axisRect) Q_PROPERTY(ScaleType scaleType READ scaleType WRITE setScaleType NOTIFY scaleTypeChanged) Q_PROPERTY(QCPRange range READ range WRITE setRange NOTIFY rangeChanged) Q_PROPERTY(bool rangeReversed READ rangeReversed WRITE setRangeReversed) Q_PROPERTY(QSharedPointer ticker READ ticker WRITE setTicker) Q_PROPERTY(bool ticks READ ticks WRITE setTicks) Q_PROPERTY(bool tickLabels READ tickLabels WRITE setTickLabels) Q_PROPERTY(int tickLabelPadding READ tickLabelPadding WRITE setTickLabelPadding) Q_PROPERTY(QFont tickLabelFont READ tickLabelFont WRITE setTickLabelFont) Q_PROPERTY(QColor tickLabelColor READ tickLabelColor WRITE setTickLabelColor) Q_PROPERTY(double tickLabelRotation READ tickLabelRotation WRITE setTickLabelRotation) Q_PROPERTY(LabelSide tickLabelSide READ tickLabelSide WRITE setTickLabelSide) Q_PROPERTY(QString numberFormat READ numberFormat WRITE setNumberFormat) Q_PROPERTY(int numberPrecision READ numberPrecision WRITE setNumberPrecision) Q_PROPERTY(QVector tickVector READ tickVector) Q_PROPERTY(QVector tickVectorLabels READ tickVectorLabels) Q_PROPERTY(int tickLengthIn READ tickLengthIn WRITE setTickLengthIn) Q_PROPERTY(int tickLengthOut READ tickLengthOut WRITE setTickLengthOut) Q_PROPERTY(bool subTicks READ subTicks WRITE setSubTicks) Q_PROPERTY(int subTickLengthIn READ subTickLengthIn WRITE setSubTickLengthIn) Q_PROPERTY(int subTickLengthOut READ subTickLengthOut WRITE setSubTickLengthOut) Q_PROPERTY(QPen basePen READ basePen WRITE setBasePen) Q_PROPERTY(QPen tickPen READ tickPen WRITE setTickPen) Q_PROPERTY(QPen subTickPen READ subTickPen WRITE setSubTickPen) Q_PROPERTY(QFont labelFont READ labelFont WRITE setLabelFont) Q_PROPERTY(QColor labelColor READ labelColor WRITE setLabelColor) Q_PROPERTY(QString label READ label WRITE setLabel) Q_PROPERTY(int labelPadding READ labelPadding WRITE setLabelPadding) Q_PROPERTY(int padding READ padding WRITE setPadding) Q_PROPERTY(int offset READ offset WRITE setOffset) Q_PROPERTY(SelectableParts selectedParts READ selectedParts WRITE setSelectedParts NOTIFY selectionChanged) Q_PROPERTY(SelectableParts selectableParts READ selectableParts WRITE setSelectableParts NOTIFY selectableChanged) Q_PROPERTY(QFont selectedTickLabelFont READ selectedTickLabelFont WRITE setSelectedTickLabelFont) Q_PROPERTY(QFont selectedLabelFont READ selectedLabelFont WRITE setSelectedLabelFont) Q_PROPERTY(QColor selectedTickLabelColor READ selectedTickLabelColor WRITE setSelectedTickLabelColor) Q_PROPERTY(QColor selectedLabelColor READ selectedLabelColor WRITE setSelectedLabelColor) Q_PROPERTY(QPen selectedBasePen READ selectedBasePen WRITE setSelectedBasePen) Q_PROPERTY(QPen selectedTickPen READ selectedTickPen WRITE setSelectedTickPen) Q_PROPERTY(QPen selectedSubTickPen READ selectedSubTickPen WRITE setSelectedSubTickPen) Q_PROPERTY(QCPLineEnding lowerEnding READ lowerEnding WRITE setLowerEnding) Q_PROPERTY(QCPLineEnding upperEnding READ upperEnding WRITE setUpperEnding) Q_PROPERTY(QCPGrid* grid READ grid) /// \endcond public: /*! Defines at which side of the axis rect the axis will appear. This also affects how the tick marks are drawn, on which side the labels are placed etc. */ enum AxisType { atLeft = 0x01 ///< 0x01 Axis is vertical and on the left side of the axis rect ,atRight = 0x02 ///< 0x02 Axis is vertical and on the right side of the axis rect ,atTop = 0x04 ///< 0x04 Axis is horizontal and on the top side of the axis rect ,atBottom = 0x08 ///< 0x08 Axis is horizontal and on the bottom side of the axis rect }; Q_ENUMS(AxisType) Q_FLAGS(AxisTypes) Q_DECLARE_FLAGS(AxisTypes, AxisType) /*! Defines on which side of the axis the tick labels (numbers) shall appear. \see setTickLabelSide */ enum LabelSide { lsInside ///< Tick labels will be displayed inside the axis rect and clipped to the inner axis rect ,lsOutside ///< Tick labels will be displayed outside the axis rect }; Q_ENUMS(LabelSide) /*! Defines the scale of an axis. \see setScaleType */ enum ScaleType { stLinear ///< Linear scaling ,stLogarithmic ///< Logarithmic scaling with correspondingly transformed axis coordinates (possibly also \ref setTicker to a \ref QCPAxisTickerLog instance). }; Q_ENUMS(ScaleType) /*! Defines the selectable parts of an axis. \see setSelectableParts, setSelectedParts */ enum SelectablePart { spNone = 0 ///< None of the selectable parts ,spAxis = 0x001 ///< The axis backbone and tick marks ,spTickLabels = 0x002 ///< Tick labels (numbers) of this axis (as a whole, not individually) ,spAxisLabel = 0x004 ///< The axis label }; Q_ENUMS(SelectablePart) Q_FLAGS(SelectableParts) Q_DECLARE_FLAGS(SelectableParts, SelectablePart) explicit QCPAxis(QCPAxisRect *parent, AxisType type); virtual ~QCPAxis(); // getters: AxisType axisType() const { return mAxisType; } QCPAxisRect *axisRect() const { return mAxisRect; } ScaleType scaleType() const { return mScaleType; } const QCPRange range() const { return mRange; } bool rangeReversed() const { return mRangeReversed; } QSharedPointer ticker() const { return mTicker; } bool ticks() const { return mTicks; } bool tickLabels() const { return mTickLabels; } int tickLabelPadding() const; QFont tickLabelFont() const { return mTickLabelFont; } QColor tickLabelColor() const { return mTickLabelColor; } double tickLabelRotation() const; LabelSide tickLabelSide() const; QString numberFormat() const; int numberPrecision() const { return mNumberPrecision; } QVector tickVector() const { return mTickVector; } QVector tickVectorLabels() const { return mTickVectorLabels; } int tickLengthIn() const; int tickLengthOut() const; bool subTicks() const { return mSubTicks; } int subTickLengthIn() const; int subTickLengthOut() const; QPen basePen() const { return mBasePen; } QPen tickPen() const { return mTickPen; } QPen subTickPen() const { return mSubTickPen; } QFont labelFont() const { return mLabelFont; } QColor labelColor() const { return mLabelColor; } QString label() const { return mLabel; } int labelPadding() const; int padding() const { return mPadding; } int offset() const; SelectableParts selectedParts() const { return mSelectedParts; } SelectableParts selectableParts() const { return mSelectableParts; } QFont selectedTickLabelFont() const { return mSelectedTickLabelFont; } QFont selectedLabelFont() const { return mSelectedLabelFont; } QColor selectedTickLabelColor() const { return mSelectedTickLabelColor; } QColor selectedLabelColor() const { return mSelectedLabelColor; } QPen selectedBasePen() const { return mSelectedBasePen; } QPen selectedTickPen() const { return mSelectedTickPen; } QPen selectedSubTickPen() const { return mSelectedSubTickPen; } QCPLineEnding lowerEnding() const; QCPLineEnding upperEnding() const; QCPGrid *grid() const { return mGrid; } // setters: Q_SLOT void setScaleType(QCPAxis::ScaleType type); Q_SLOT void setRange(const QCPRange &range); void setRange(double lower, double upper); void setRange(double position, double size, Qt::AlignmentFlag alignment); void setRangeLower(double lower); void setRangeUpper(double upper); void setRangeReversed(bool reversed); void setTicker(QSharedPointer ticker); void setTicks(bool show); void setTickLabels(bool show); void setTickLabelPadding(int padding); void setTickLabelFont(const QFont &font); void setTickLabelColor(const QColor &color); void setTickLabelRotation(double degrees); void setTickLabelSide(LabelSide side); void setNumberFormat(const QString &formatCode); void setNumberPrecision(int precision); void setTickLength(int inside, int outside=0); void setTickLengthIn(int inside); void setTickLengthOut(int outside); void setSubTicks(bool show); void setSubTickLength(int inside, int outside=0); void setSubTickLengthIn(int inside); void setSubTickLengthOut(int outside); void setBasePen(const QPen &pen); void setTickPen(const QPen &pen); void setSubTickPen(const QPen &pen); void setLabelFont(const QFont &font); void setLabelColor(const QColor &color); void setLabel(const QString &str); void setLabelPadding(int padding); void setPadding(int padding); void setOffset(int offset); void setSelectedTickLabelFont(const QFont &font); void setSelectedLabelFont(const QFont &font); void setSelectedTickLabelColor(const QColor &color); void setSelectedLabelColor(const QColor &color); void setSelectedBasePen(const QPen &pen); void setSelectedTickPen(const QPen &pen); void setSelectedSubTickPen(const QPen &pen); Q_SLOT void setSelectableParts(const QCPAxis::SelectableParts &selectableParts); Q_SLOT void setSelectedParts(const QCPAxis::SelectableParts &selectedParts); void setLowerEnding(const QCPLineEnding &ending); void setUpperEnding(const QCPLineEnding &ending); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; // non-property methods: Qt::Orientation orientation() const { return mOrientation; } int pixelOrientation() const { return rangeReversed() != (orientation()==Qt::Vertical) ? -1 : 1; } void moveRange(double diff); void scaleRange(double factor); void scaleRange(double factor, double center); void setScaleRatio(const QCPAxis *otherAxis, double ratio=1.0); void rescale(bool onlyVisiblePlottables=false); double pixelToCoord(double value) const; double coordToPixel(double value) const; SelectablePart getPartAt(const QPointF &pos) const; QList plottables() const; QList graphs() const; QList items() const; static AxisType marginSideToAxisType(QCP::MarginSide side); static Qt::Orientation orientation(AxisType type) { return type==atBottom||type==atTop ? Qt::Horizontal : Qt::Vertical; } static AxisType opposite(AxisType type); signals: void rangeChanged(const QCPRange &newRange); void rangeChanged(const QCPRange &newRange, const QCPRange &oldRange); void scaleTypeChanged(QCPAxis::ScaleType scaleType); void selectionChanged(const QCPAxis::SelectableParts &parts); void selectableChanged(const QCPAxis::SelectableParts &parts); protected: // property members: // axis base: AxisType mAxisType; QCPAxisRect *mAxisRect; //int mOffset; // in QCPAxisPainter int mPadding; Qt::Orientation mOrientation; SelectableParts mSelectableParts, mSelectedParts; QPen mBasePen, mSelectedBasePen; //QCPLineEnding mLowerEnding, mUpperEnding; // in QCPAxisPainter // axis label: //int mLabelPadding; // in QCPAxisPainter QString mLabel; QFont mLabelFont, mSelectedLabelFont; QColor mLabelColor, mSelectedLabelColor; // tick labels: //int mTickLabelPadding; // in QCPAxisPainter bool mTickLabels; //double mTickLabelRotation; // in QCPAxisPainter QFont mTickLabelFont, mSelectedTickLabelFont; QColor mTickLabelColor, mSelectedTickLabelColor; int mNumberPrecision; QLatin1Char mNumberFormatChar; bool mNumberBeautifulPowers; //bool mNumberMultiplyCross; // QCPAxisPainter // ticks and subticks: bool mTicks; bool mSubTicks; //int mTickLengthIn, mTickLengthOut, mSubTickLengthIn, mSubTickLengthOut; // QCPAxisPainter QPen mTickPen, mSelectedTickPen; QPen mSubTickPen, mSelectedSubTickPen; // scale and range: QCPRange mRange; bool mRangeReversed; ScaleType mScaleType; // non-property members: QCPGrid *mGrid; QCPAxisPainterPrivate *mAxisPainter; QSharedPointer mTicker; QVector mTickVector; QVector mTickVectorLabels; QVector mSubTickVector; bool mCachedMarginValid; int mCachedMargin; bool mDragging; QCPRange mDragStartRange; QCP::AntialiasedElements mAADragBackup, mNotAADragBackup; // introduced virtual methods: virtual int calculateMargin(); // reimplemented virtual methods: virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual QCP::Interaction selectionCategory() const Q_DECL_OVERRIDE; // events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged) Q_DECL_OVERRIDE; virtual void deselectEvent(bool *selectionStateChanged) Q_DECL_OVERRIDE; // mouse events: virtual void mousePressEvent(QMouseEvent *event, const QVariant &details); virtual void mouseMoveEvent(QMouseEvent *event, const QPointF &startPos); virtual void mouseReleaseEvent(QMouseEvent *event, const QPointF &startPos); virtual void wheelEvent(QWheelEvent *event); // non-virtual methods: void setupTickVectors(); QPen getBasePen() const; QPen getTickPen() const; QPen getSubTickPen() const; QFont getTickLabelFont() const; QFont getLabelFont() const; QColor getTickLabelColor() const; QColor getLabelColor() const; private: Q_DISABLE_COPY(QCPAxis) friend class QCustomPlot; friend class QCPGrid; friend class QCPAxisRect; }; Q_DECLARE_OPERATORS_FOR_FLAGS(QCPAxis::SelectableParts) Q_DECLARE_OPERATORS_FOR_FLAGS(QCPAxis::AxisTypes) Q_DECLARE_METATYPE(QCPAxis::AxisType) Q_DECLARE_METATYPE(QCPAxis::LabelSide) Q_DECLARE_METATYPE(QCPAxis::ScaleType) Q_DECLARE_METATYPE(QCPAxis::SelectablePart) class QCPAxisPainterPrivate { public: explicit QCPAxisPainterPrivate(QCustomPlot *parentPlot); virtual ~QCPAxisPainterPrivate(); virtual void draw(QCPPainter *painter); virtual int size() const; void clearCache(); QRect axisSelectionBox() const { return mAxisSelectionBox; } QRect tickLabelsSelectionBox() const { return mTickLabelsSelectionBox; } QRect labelSelectionBox() const { return mLabelSelectionBox; } // public property members: QCPAxis::AxisType type; QPen basePen; QCPLineEnding lowerEnding, upperEnding; // directly accessed by QCPAxis setters/getters int labelPadding; // directly accessed by QCPAxis setters/getters QFont labelFont; QColor labelColor; QString label; int tickLabelPadding; // directly accessed by QCPAxis setters/getters double tickLabelRotation; // directly accessed by QCPAxis setters/getters QCPAxis::LabelSide tickLabelSide; // directly accessed by QCPAxis setters/getters bool substituteExponent; bool numberMultiplyCross; // directly accessed by QCPAxis setters/getters int tickLengthIn, tickLengthOut, subTickLengthIn, subTickLengthOut; // directly accessed by QCPAxis setters/getters QPen tickPen, subTickPen; QFont tickLabelFont; QColor tickLabelColor; QRect axisRect, viewportRect; double offset; // directly accessed by QCPAxis setters/getters bool abbreviateDecimalPowers; bool reversedEndings; QVector subTickPositions; QVector tickPositions; QVector tickLabels; protected: struct CachedLabel { QPointF offset; QPixmap pixmap; }; struct TickLabelData { QString basePart, expPart, suffixPart; QRect baseBounds, expBounds, suffixBounds, totalBounds, rotatedTotalBounds; QFont baseFont, expFont; }; QCustomPlot *mParentPlot; QByteArray mLabelParameterHash; // to determine whether mLabelCache needs to be cleared due to changed parameters QCache mLabelCache; QRect mAxisSelectionBox, mTickLabelsSelectionBox, mLabelSelectionBox; virtual QByteArray generateLabelParameterHash() const; virtual void placeTickLabel(QCPPainter *painter, double position, int distanceToAxis, const QString &text, QSize *tickLabelsSize); virtual void drawTickLabel(QCPPainter *painter, double x, double y, const TickLabelData &labelData) const; virtual TickLabelData getTickLabelData(const QFont &font, const QString &text) const; virtual QPointF getTickLabelDrawOffset(const TickLabelData &labelData) const; virtual void getMaxTickLabelSize(const QFont &font, const QString &text, QSize *tickLabelsSize) const; }; /* end of 'src/axis/axis.h' */ /* including file 'src/scatterstyle.h', size 7275 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPScatterStyle { Q_GADGET public: /*! Represents the various properties of a scatter style instance. For example, this enum is used to specify which properties of \ref QCPSelectionDecorator::setScatterStyle will be used when highlighting selected data points. Specific scatter properties can be transferred between \ref QCPScatterStyle instances via \ref setFromOther. */ enum ScatterProperty { spNone = 0x00 ///< 0x00 None ,spPen = 0x01 ///< 0x01 The pen property, see \ref setPen ,spBrush = 0x02 ///< 0x02 The brush property, see \ref setBrush ,spSize = 0x04 ///< 0x04 The size property, see \ref setSize ,spShape = 0x08 ///< 0x08 The shape property, see \ref setShape ,spAll = 0xFF ///< 0xFF All properties }; Q_ENUMS(ScatterProperty) Q_FLAGS(ScatterProperties) Q_DECLARE_FLAGS(ScatterProperties, ScatterProperty) /*! Defines the shape used for scatter points. On plottables/items that draw scatters, the sizes of these visualizations (with exception of \ref ssDot and \ref ssPixmap) can be controlled with the \ref setSize function. Scatters are drawn with the pen and brush specified with \ref setPen and \ref setBrush. */ enum ScatterShape { ssNone ///< no scatter symbols are drawn (e.g. in QCPGraph, data only represented with lines) ,ssDot ///< \enumimage{ssDot.png} a single pixel (use \ref ssDisc or \ref ssCircle if you want a round shape with a certain radius) ,ssCross ///< \enumimage{ssCross.png} a cross ,ssPlus ///< \enumimage{ssPlus.png} a plus ,ssCircle ///< \enumimage{ssCircle.png} a circle ,ssDisc ///< \enumimage{ssDisc.png} a circle which is filled with the pen's color (not the brush as with ssCircle) ,ssSquare ///< \enumimage{ssSquare.png} a square ,ssDiamond ///< \enumimage{ssDiamond.png} a diamond ,ssStar ///< \enumimage{ssStar.png} a star with eight arms, i.e. a combination of cross and plus ,ssTriangle ///< \enumimage{ssTriangle.png} an equilateral triangle, standing on baseline ,ssTriangleInverted ///< \enumimage{ssTriangleInverted.png} an equilateral triangle, standing on corner ,ssCrossSquare ///< \enumimage{ssCrossSquare.png} a square with a cross inside ,ssPlusSquare ///< \enumimage{ssPlusSquare.png} a square with a plus inside ,ssCrossCircle ///< \enumimage{ssCrossCircle.png} a circle with a cross inside ,ssPlusCircle ///< \enumimage{ssPlusCircle.png} a circle with a plus inside ,ssPeace ///< \enumimage{ssPeace.png} a circle, with one vertical and two downward diagonal lines ,ssPixmap ///< a custom pixmap specified by \ref setPixmap, centered on the data point coordinates ,ssCustom ///< custom painter operations are performed per scatter (As QPainterPath, see \ref setCustomPath) }; Q_ENUMS(ScatterShape) QCPScatterStyle(); QCPScatterStyle(ScatterShape shape, double size=6); QCPScatterStyle(ScatterShape shape, const QColor &color, double size); QCPScatterStyle(ScatterShape shape, const QColor &color, const QColor &fill, double size); QCPScatterStyle(ScatterShape shape, const QPen &pen, const QBrush &brush, double size); QCPScatterStyle(const QPixmap &pixmap); QCPScatterStyle(const QPainterPath &customPath, const QPen &pen, const QBrush &brush=Qt::NoBrush, double size=6); // getters: double size() const { return mSize; } ScatterShape shape() const { return mShape; } QPen pen() const { return mPen; } QBrush brush() const { return mBrush; } QPixmap pixmap() const { return mPixmap; } QPainterPath customPath() const { return mCustomPath; } // setters: void setFromOther(const QCPScatterStyle &other, ScatterProperties properties); void setSize(double size); void setShape(ScatterShape shape); void setPen(const QPen &pen); void setBrush(const QBrush &brush); void setPixmap(const QPixmap &pixmap); void setCustomPath(const QPainterPath &customPath); // non-property methods: bool isNone() const { return mShape == ssNone; } bool isPenDefined() const { return mPenDefined; } void undefinePen(); void applyTo(QCPPainter *painter, const QPen &defaultPen) const; void drawShape(QCPPainter *painter, const QPointF &pos) const; void drawShape(QCPPainter *painter, double x, double y) const; protected: // property members: double mSize; ScatterShape mShape; QPen mPen; QBrush mBrush; QPixmap mPixmap; QPainterPath mCustomPath; // non-property members: bool mPenDefined; }; Q_DECLARE_TYPEINFO(QCPScatterStyle, Q_MOVABLE_TYPE); Q_DECLARE_OPERATORS_FOR_FLAGS(QCPScatterStyle::ScatterProperties) Q_DECLARE_METATYPE(QCPScatterStyle::ScatterProperty) Q_DECLARE_METATYPE(QCPScatterStyle::ScatterShape) /* end of 'src/scatterstyle.h' */ /* including file 'src/datacontainer.h', size 4596 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ /*! \relates QCPDataContainer Returns whether the sort key of \a a is less than the sort key of \a b. \see QCPDataContainer::sort */ template inline bool qcpLessThanSortKey(const DataType &a, const DataType &b) { return a.sortKey() < b.sortKey(); } template class QCPDataContainer // no QCP_LIB_DECL, template class ends up in header (cpp included below) { public: typedef typename QVector::const_iterator const_iterator; typedef typename QVector::iterator iterator; QCPDataContainer(); // getters: int size() const { return mData.size()-mPreallocSize; } bool isEmpty() const { return size() == 0; } bool autoSqueeze() const { return mAutoSqueeze; } // setters: void setAutoSqueeze(bool enabled); // non-virtual methods: void set(const QCPDataContainer &data); void set(const QVector &data, bool alreadySorted=false); void add(const QCPDataContainer &data); void add(const QVector &data, bool alreadySorted=false); void add(const DataType &data); void removeBefore(double sortKey); void removeAfter(double sortKey); void remove(double sortKeyFrom, double sortKeyTo); void remove(double sortKey); void clear(); void sort(); void squeeze(bool preAllocation=true, bool postAllocation=true); const_iterator constBegin() const { return mData.constBegin()+mPreallocSize; } const_iterator constEnd() const { return mData.constEnd(); } iterator begin() { return mData.begin()+mPreallocSize; } iterator end() { return mData.end(); } const_iterator findBegin(double sortKey, bool expandedRange=true) const; const_iterator findEnd(double sortKey, bool expandedRange=true) const; const_iterator at(int index) const { return constBegin()+qBound(0, index, size()); } QCPRange keyRange(bool &foundRange, QCP::SignDomain signDomain=QCP::sdBoth); QCPRange valueRange(bool &foundRange, QCP::SignDomain signDomain=QCP::sdBoth, const QCPRange &inKeyRange=QCPRange()); QCPDataRange dataRange() const { return QCPDataRange(0, size()); } void limitIteratorsToDataRange(const_iterator &begin, const_iterator &end, const QCPDataRange &dataRange) const; protected: // property members: bool mAutoSqueeze; // non-property memebers: QVector mData; int mPreallocSize; int mPreallocIteration; // non-virtual methods: void preallocateGrow(int minimumPreallocSize); void performAutoSqueeze(); }; // include implementation in header since it is a class template: /* including file 'src/datacontainer.cpp', size 31349 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ //////////////////////////////////////////////////////////////////////////////////////////////////// //////////////////// QCPDataContainer //////////////////////////////////////////////////////////////////////////////////////////////////// /*! \class QCPDataContainer \brief The generic data container for one-dimensional plottables This class template provides a fast container for data storage of one-dimensional data. The data type is specified as template parameter (called \a DataType in the following) and must provide some methods as described in the \ref qcpdatacontainer-datatype "next section". The data is stored in a sorted fashion, which allows very quick lookups by the sorted key as well as retrieval of ranges (see \ref findBegin, \ref findEnd, \ref keyRange) using binary search. The container uses a preallocation and a postallocation scheme, such that appending and prepending data (with respect to the sort key) is very fast and minimizes reallocations. If data is added which needs to be inserted between existing keys, the merge usually can be done quickly too, using the fact that existing data is always sorted. The user can further improve performance by specifying that added data is already itself sorted by key, if he can guarantee that this is the case (see for example \ref add(const QVector &data, bool alreadySorted)). The data can be accessed with the provided const iterators (\ref constBegin, \ref constEnd). If it is necessary to alter existing data in-place, the non-const iterators can be used (\ref begin, \ref end). Changing data members that are not the sort key (for most data types called \a key) is safe from the container's perspective. Great care must be taken however if the sort key is modified through the non-const iterators. For performance reasons, the iterators don't automatically cause a re-sorting upon their manipulation. It is thus the responsibility of the user to leave the container in a sorted state when finished with the data manipulation, before calling any other methods on the container. A complete re-sort (e.g. after finishing all sort key manipulation) can be done by calling \ref sort. Failing to do so can not be detected by the container efficiently and will cause both rendering artifacts and potential data loss. Implementing one-dimensional plottables that make use of a \ref QCPDataContainer is usually done by subclassing from \ref QCPAbstractPlottable1D "QCPAbstractPlottable1D", which introduces an according \a mDataContainer member and some convenience methods. \section qcpdatacontainer-datatype Requirements for the DataType template parameter The template parameter DataType is the type of the stored data points. It must be trivially copyable and have the following public methods, preferably inline: \li double sortKey() const\n Returns the member variable of this data point that is the sort key, defining the ordering in the container. Often this variable is simply called \a key. \li static DataType fromSortKey(double sortKey)\n Returns a new instance of the data type initialized with its sort key set to \a sortKey. \li static bool sortKeyIsMainKey()\n Returns true if the sort key is equal to the main key (see method \c mainKey below). For most plottables this is the case. It is not the case for example for \ref QCPCurve, which uses \a t as sort key and \a key as main key. This is the reason why QCPCurve unlike QCPGraph can display parametric curves with loops. \li double mainKey() const\n Returns the variable of this data point considered the main key. This is commonly the variable that is used as the coordinate of this data point on the key axis of the plottable. This method is used for example when determining the automatic axis rescaling of key axes (\ref QCPAxis::rescale). \li double mainValue() const\n Returns the variable of this data point considered the main value. This is commonly the variable that is used as the coordinate of this data point on the value axis of the plottable. \li QCPRange valueRange() const\n Returns the range this data point spans in the value axis coordinate. If the data is single-valued (e.g. QCPGraphData), this is simply a range with both lower and upper set to the main data point value. However if the data points can represent multiple values at once (e.g QCPFinancialData with its \a high, \a low, \a open and \a close values at each \a key) this method should return the range those values span. This method is used for example when determining the automatic axis rescaling of value axes (\ref QCPAxis::rescale). */ /* start documentation of inline functions */ /*! \fn int QCPDataContainer::size() const Returns the number of data points in the container. */ /*! \fn bool QCPDataContainer::isEmpty() const Returns whether this container holds no data points. */ /*! \fn QCPDataContainer::const_iterator QCPDataContainer::constBegin() const Returns a const iterator to the first data point in this container. */ /*! \fn QCPDataContainer::const_iterator QCPDataContainer::constEnd() const Returns a const iterator to the element past the last data point in this container. */ /*! \fn QCPDataContainer::iterator QCPDataContainer::begin() const Returns a non-const iterator to the first data point in this container. You can manipulate the data points in-place through the non-const iterators, but great care must be taken when manipulating the sort key of a data point, see \ref sort, or the detailed description of this class. */ /*! \fn QCPDataContainer::iterator QCPDataContainer::end() const Returns a non-const iterator to the element past the last data point in this container. You can manipulate the data points in-place through the non-const iterators, but great care must be taken when manipulating the sort key of a data point, see \ref sort, or the detailed description of this class. */ /*! \fn QCPDataContainer::const_iterator QCPDataContainer::at(int index) const Returns a const iterator to the element with the specified \a index. If \a index points beyond the available elements in this container, returns \ref constEnd, i.e. an iterator past the last valid element. You can use this method to easily obtain iterators from a \ref QCPDataRange, see the \ref dataselection-accessing "data selection page" for an example. */ /*! \fn QCPDataRange QCPDataContainer::dataRange() const Returns a \ref QCPDataRange encompassing the entire data set of this container. This means the begin index of the returned range is 0, and the end index is \ref size. */ /* end documentation of inline functions */ /*! Constructs a QCPDataContainer used for plottable classes that represent a series of key-sorted data */ template QCPDataContainer::QCPDataContainer() : mAutoSqueeze(true), mPreallocSize(0), mPreallocIteration(0) { } /*! Sets whether the container automatically decides when to release memory from its post- and preallocation pools when data points are removed. By default this is enabled and for typical applications shouldn't be changed. If auto squeeze is disabled, you can manually decide when to release pre-/postallocation with \ref squeeze. */ template void QCPDataContainer::setAutoSqueeze(bool enabled) { if (mAutoSqueeze != enabled) { mAutoSqueeze = enabled; if (mAutoSqueeze) performAutoSqueeze(); } } /*! \overload Replaces the current data in this container with the provided \a data. \see add, remove */ template void QCPDataContainer::set(const QCPDataContainer &data) { clear(); add(data); } /*! \overload Replaces the current data in this container with the provided \a data If you can guarantee that the data points in \a data have ascending order with respect to the DataType's sort key, set \a alreadySorted to true to avoid an unnecessary sorting run. \see add, remove */ template void QCPDataContainer::set(const QVector &data, bool alreadySorted) { mData = data; mPreallocSize = 0; mPreallocIteration = 0; if (!alreadySorted) sort(); } /*! \overload Adds the provided \a data to the current data in this container. \see set, remove */ template void QCPDataContainer::add(const QCPDataContainer &data) { if (data.isEmpty()) return; const int n = data.size(); const int oldSize = size(); if (oldSize > 0 && !qcpLessThanSortKey(*constBegin(), *(data.constEnd()-1))) // prepend if new data keys are all smaller than or equal to existing ones { if (mPreallocSize < n) preallocateGrow(n); mPreallocSize -= n; std::copy(data.constBegin(), data.constEnd(), begin()); } else // don't need to prepend, so append and merge if necessary { mData.resize(mData.size()+n); std::copy(data.constBegin(), data.constEnd(), end()-n); if (oldSize > 0 && !qcpLessThanSortKey(*(constEnd()-n-1), *(constEnd()-n))) // if appended range keys aren't all greater than existing ones, merge the two partitions std::inplace_merge(begin(), end()-n, end(), qcpLessThanSortKey); } } /*! Adds the provided data points in \a data to the current data. If you can guarantee that the data points in \a data have ascending order with respect to the DataType's sort key, set \a alreadySorted to true to avoid an unnecessary sorting run. \see set, remove */ template void QCPDataContainer::add(const QVector &data, bool alreadySorted) { if (data.isEmpty()) return; if (isEmpty()) { set(data, alreadySorted); return; } const int n = data.size(); const int oldSize = size(); if (alreadySorted && oldSize > 0 && !qcpLessThanSortKey(*constBegin(), *(data.constEnd()-1))) // prepend if new data is sorted and keys are all smaller than or equal to existing ones { if (mPreallocSize < n) preallocateGrow(n); mPreallocSize -= n; std::copy(data.constBegin(), data.constEnd(), begin()); } else // don't need to prepend, so append and then sort and merge if necessary { mData.resize(mData.size()+n); std::copy(data.constBegin(), data.constEnd(), end()-n); if (!alreadySorted) // sort appended subrange if it wasn't already sorted std::sort(end()-n, end(), qcpLessThanSortKey); if (oldSize > 0 && !qcpLessThanSortKey(*(constEnd()-n-1), *(constEnd()-n))) // if appended range keys aren't all greater than existing ones, merge the two partitions std::inplace_merge(begin(), end()-n, end(), qcpLessThanSortKey); } } /*! \overload Adds the provided single data point to the current data. \see remove */ template void QCPDataContainer::add(const DataType &data) { if (isEmpty() || !qcpLessThanSortKey(data, *(constEnd()-1))) // quickly handle appends if new data key is greater or equal to existing ones { mData.append(data); } else if (qcpLessThanSortKey(data, *constBegin())) // quickly handle prepends using preallocated space { if (mPreallocSize < 1) preallocateGrow(1); --mPreallocSize; *begin() = data; } else // handle inserts, maintaining sorted keys { QCPDataContainer::iterator insertionPoint = std::lower_bound(begin(), end(), data, qcpLessThanSortKey); mData.insert(insertionPoint, data); } } /*! Removes all data points with (sort-)keys smaller than or equal to \a sortKey. \see removeAfter, remove, clear */ template void QCPDataContainer::removeBefore(double sortKey) { QCPDataContainer::iterator it = begin(); QCPDataContainer::iterator itEnd = std::lower_bound(begin(), end(), DataType::fromSortKey(sortKey), qcpLessThanSortKey); mPreallocSize += itEnd-it; // don't actually delete, just add it to the preallocated block (if it gets too large, squeeze will take care of it) if (mAutoSqueeze) performAutoSqueeze(); } /*! Removes all data points with (sort-)keys greater than or equal to \a sortKey. \see removeBefore, remove, clear */ template void QCPDataContainer::removeAfter(double sortKey) { QCPDataContainer::iterator it = std::upper_bound(begin(), end(), DataType::fromSortKey(sortKey), qcpLessThanSortKey); QCPDataContainer::iterator itEnd = end(); mData.erase(it, itEnd); // typically adds it to the postallocated block if (mAutoSqueeze) performAutoSqueeze(); } /*! Removes all data points with (sort-)keys between \a sortKeyFrom and \a sortKeyTo. if \a sortKeyFrom is greater or equal to \a sortKeyTo, the function does nothing. To remove a single data point with known (sort-)key, use \ref remove(double sortKey). \see removeBefore, removeAfter, clear */ template void QCPDataContainer::remove(double sortKeyFrom, double sortKeyTo) { if (sortKeyFrom >= sortKeyTo || isEmpty()) return; QCPDataContainer::iterator it = std::lower_bound(begin(), end(), DataType::fromSortKey(sortKeyFrom), qcpLessThanSortKey); QCPDataContainer::iterator itEnd = std::upper_bound(it, end(), DataType::fromSortKey(sortKeyTo), qcpLessThanSortKey); mData.erase(it, itEnd); if (mAutoSqueeze) performAutoSqueeze(); } /*! \overload Removes a single data point at \a sortKey. If the position is not known with absolute (binary) precision, consider using \ref remove(double sortKeyFrom, double sortKeyTo) with a small fuzziness interval around the suspected position, depeding on the precision with which the (sort-)key is known. \see removeBefore, removeAfter, clear */ template void QCPDataContainer::remove(double sortKey) { QCPDataContainer::iterator it = std::lower_bound(begin(), end(), DataType::fromSortKey(sortKey), qcpLessThanSortKey); if (it != end() && it->sortKey() == sortKey) { if (it == begin()) ++mPreallocSize; // don't actually delete, just add it to the preallocated block (if it gets too large, squeeze will take care of it) else mData.erase(it); } if (mAutoSqueeze) performAutoSqueeze(); } /*! Removes all data points. \see remove, removeAfter, removeBefore */ template void QCPDataContainer::clear() { mData.clear(); mPreallocIteration = 0; mPreallocSize = 0; } /*! Re-sorts all data points in the container by their sort key. When setting, adding or removing points using the QCPDataContainer interface (\ref set, \ref add, \ref remove, etc.), the container makes sure to always stay in a sorted state such that a full resort is never necessary. However, if you choose to directly manipulate the sort key on data points by accessing and modifying it through the non-const iterators (\ref begin, \ref end), it is your responsibility to bring the container back into a sorted state before any other methods are called on it. This can be achieved by calling this method immediately after finishing the sort key manipulation. */ template void QCPDataContainer::sort() { std::sort(begin(), end(), qcpLessThanSortKey); } /*! Frees all unused memory that is currently in the preallocation and postallocation pools. Note that QCPDataContainer automatically decides whether squeezing is necessary, if \ref setAutoSqueeze is left enabled. It should thus not be necessary to use this method for typical applications. The parameters \a preAllocation and \a postAllocation control whether pre- and/or post allocation should be freed, respectively. */ template void QCPDataContainer::squeeze(bool preAllocation, bool postAllocation) { if (preAllocation) { if (mPreallocSize > 0) { std::copy(begin(), end(), mData.begin()); mData.resize(size()); mPreallocSize = 0; } mPreallocIteration = 0; } if (postAllocation) mData.squeeze(); } /*! Returns an iterator to the data point with a (sort-)key that is equal to, just below, or just above \a sortKey. If \a expandedRange is true, the data point just below \a sortKey will be considered, otherwise the one just above. This can be used in conjunction with \ref findEnd to iterate over data points within a given key range, including or excluding the bounding data points that are just beyond the specified range. If \a expandedRange is true but there are no data points below \a sortKey, \ref constBegin is returned. If the container is empty, returns \ref constEnd. \see findEnd, QCPPlottableInterface1D::findBegin */ template typename QCPDataContainer::const_iterator QCPDataContainer::findBegin(double sortKey, bool expandedRange) const { if (isEmpty()) return constEnd(); QCPDataContainer::const_iterator it = std::lower_bound(constBegin(), constEnd(), DataType::fromSortKey(sortKey), qcpLessThanSortKey); if (expandedRange && it != constBegin()) // also covers it == constEnd case, and we know --constEnd is valid because mData isn't empty --it; return it; } /*! Returns an iterator to the element after the data point with a (sort-)key that is equal to, just above or just below \a sortKey. If \a expandedRange is true, the data point just above \a sortKey will be considered, otherwise the one just below. This can be used in conjunction with \ref findBegin to iterate over data points within a given key range, including the bounding data points that are just below and above the specified range. If \a expandedRange is true but there are no data points above \a sortKey, \ref constEnd is returned. If the container is empty, \ref constEnd is returned. \see findBegin, QCPPlottableInterface1D::findEnd */ template typename QCPDataContainer::const_iterator QCPDataContainer::findEnd(double sortKey, bool expandedRange) const { if (isEmpty()) return constEnd(); QCPDataContainer::const_iterator it = std::upper_bound(constBegin(), constEnd(), DataType::fromSortKey(sortKey), qcpLessThanSortKey); if (expandedRange && it != constEnd()) ++it; return it; } /*! Returns the range encompassed by the (main-)key coordinate of all data points. The output parameter \a foundRange indicates whether a sensible range was found. If this is false, you should not use the returned QCPRange (e.g. the data container is empty or all points have the same key). Use \a signDomain to control which sign of the key coordinates should be considered. This is relevant e.g. for logarithmic plots which can mathematically only display one sign domain at a time. If the DataType reports that its main key is equal to the sort key (\a sortKeyIsMainKey), as is the case for most plottables, this method uses this fact and finds the range very quickly. \see valueRange */ template QCPRange QCPDataContainer::keyRange(bool &foundRange, QCP::SignDomain signDomain) { if (isEmpty()) { foundRange = false; return QCPRange(); } QCPRange range; bool haveLower = false; bool haveUpper = false; double current; QCPDataContainer::const_iterator it = constBegin(); QCPDataContainer::const_iterator itEnd = constEnd(); if (signDomain == QCP::sdBoth) // range may be anywhere { if (DataType::sortKeyIsMainKey()) // if DataType is sorted by main key (e.g. QCPGraph, but not QCPCurve), use faster algorithm by finding just first and last key with non-NaN value { while (it != itEnd) // find first non-nan going up from left { if (!qIsNaN(it->mainValue())) { range.lower = it->mainKey(); haveLower = true; break; } ++it; } it = itEnd; while (it != constBegin()) // find first non-nan going down from right { --it; if (!qIsNaN(it->mainValue())) { range.upper = it->mainKey(); haveUpper = true; break; } } } else // DataType is not sorted by main key, go through all data points and accordingly expand range { while (it != itEnd) { if (!qIsNaN(it->mainValue())) { current = it->mainKey(); if (current < range.lower || !haveLower) { range.lower = current; haveLower = true; } if (current > range.upper || !haveUpper) { range.upper = current; haveUpper = true; } } ++it; } } } else if (signDomain == QCP::sdNegative) // range may only be in the negative sign domain { while (it != itEnd) { if (!qIsNaN(it->mainValue())) { current = it->mainKey(); if ((current < range.lower || !haveLower) && current < 0) { range.lower = current; haveLower = true; } if ((current > range.upper || !haveUpper) && current < 0) { range.upper = current; haveUpper = true; } } ++it; } } else if (signDomain == QCP::sdPositive) // range may only be in the positive sign domain { while (it != itEnd) { if (!qIsNaN(it->mainValue())) { current = it->mainKey(); if ((current < range.lower || !haveLower) && current > 0) { range.lower = current; haveLower = true; } if ((current > range.upper || !haveUpper) && current > 0) { range.upper = current; haveUpper = true; } } ++it; } } foundRange = haveLower && haveUpper; return range; } /*! Returns the range encompassed by the value coordinates of the data points in the specified key range (\a inKeyRange), using the full \a DataType::valueRange reported by the data points. The output parameter \a foundRange indicates whether a sensible range was found. If this is false, you should not use the returned QCPRange (e.g. the data container is empty or all points have the same value). If \a inKeyRange has both lower and upper bound set to zero (is equal to QCPRange()), all data points are considered, without any restriction on the keys. Use \a signDomain to control which sign of the value coordinates should be considered. This is relevant e.g. for logarithmic plots which can mathematically only display one sign domain at a time. \see keyRange */ template QCPRange QCPDataContainer::valueRange(bool &foundRange, QCP::SignDomain signDomain, const QCPRange &inKeyRange) { if (isEmpty()) { foundRange = false; return QCPRange(); } QCPRange range; const bool restrictKeyRange = inKeyRange != QCPRange(); bool haveLower = false; bool haveUpper = false; QCPRange current; QCPDataContainer::const_iterator itBegin = constBegin(); QCPDataContainer::const_iterator itEnd = constEnd(); if (DataType::sortKeyIsMainKey() && restrictKeyRange) { itBegin = findBegin(inKeyRange.lower); itEnd = findEnd(inKeyRange.upper); } if (signDomain == QCP::sdBoth) // range may be anywhere { for (QCPDataContainer::const_iterator it = itBegin; it != itEnd; ++it) { if (restrictKeyRange && (it->mainKey() < inKeyRange.lower || it->mainKey() > inKeyRange.upper)) continue; current = it->valueRange(); if ((current.lower < range.lower || !haveLower) && !qIsNaN(current.lower)) { range.lower = current.lower; haveLower = true; } if ((current.upper > range.upper || !haveUpper) && !qIsNaN(current.upper)) { range.upper = current.upper; haveUpper = true; } } } else if (signDomain == QCP::sdNegative) // range may only be in the negative sign domain { for (QCPDataContainer::const_iterator it = itBegin; it != itEnd; ++it) { if (restrictKeyRange && (it->mainKey() < inKeyRange.lower || it->mainKey() > inKeyRange.upper)) continue; current = it->valueRange(); if ((current.lower < range.lower || !haveLower) && current.lower < 0 && !qIsNaN(current.lower)) { range.lower = current.lower; haveLower = true; } if ((current.upper > range.upper || !haveUpper) && current.upper < 0 && !qIsNaN(current.upper)) { range.upper = current.upper; haveUpper = true; } } } else if (signDomain == QCP::sdPositive) // range may only be in the positive sign domain { for (QCPDataContainer::const_iterator it = itBegin; it != itEnd; ++it) { if (restrictKeyRange && (it->mainKey() < inKeyRange.lower || it->mainKey() > inKeyRange.upper)) continue; current = it->valueRange(); if ((current.lower < range.lower || !haveLower) && current.lower > 0 && !qIsNaN(current.lower)) { range.lower = current.lower; haveLower = true; } if ((current.upper > range.upper || !haveUpper) && current.upper > 0 && !qIsNaN(current.upper)) { range.upper = current.upper; haveUpper = true; } } } foundRange = haveLower && haveUpper; return range; } /*! Makes sure \a begin and \a end mark a data range that is both within the bounds of this data container's data, as well as within the specified \a dataRange. The initial range described by the passed iterators \a begin and \a end is never expanded, only contracted if necessary. This function doesn't require for \a dataRange to be within the bounds of this data container's valid range. */ template void QCPDataContainer::limitIteratorsToDataRange(const_iterator &begin, const_iterator &end, const QCPDataRange &dataRange) const { QCPDataRange iteratorRange(begin-constBegin(), end-constBegin()); iteratorRange = iteratorRange.bounded(dataRange.bounded(this->dataRange())); begin = constBegin()+iteratorRange.begin(); end = constBegin()+iteratorRange.end(); } /*! \internal Increases the preallocation pool to have a size of at least \a minimumPreallocSize. Depending on the preallocation history, the container will grow by more than requested, to speed up future consecutive size increases. if \a minimumPreallocSize is smaller than or equal to the current preallocation pool size, this method does nothing. */ template void QCPDataContainer::preallocateGrow(int minimumPreallocSize) { if (minimumPreallocSize <= mPreallocSize) return; int newPreallocSize = minimumPreallocSize; newPreallocSize += (1u< void QCPDataContainer::performAutoSqueeze() { const int totalAlloc = mData.capacity(); const int postAllocSize = totalAlloc-mData.size(); const int usedSize = size(); bool shrinkPostAllocation = false; bool shrinkPreAllocation = false; if (totalAlloc > 650000) // if allocation is larger, shrink earlier with respect to total used size { shrinkPostAllocation = postAllocSize > usedSize*1.5; // QVector grow strategy is 2^n for static data. Watch out not to oscillate! shrinkPreAllocation = mPreallocSize*10 > usedSize; } else if (totalAlloc > 1000) // below 10 MiB raw data be generous with preallocated memory, below 1k points don't even bother { shrinkPostAllocation = postAllocSize > usedSize*5; shrinkPreAllocation = mPreallocSize > usedSize*1.5; // preallocation can grow into postallocation, so can be smaller } if (shrinkPreAllocation || shrinkPostAllocation) squeeze(shrinkPreAllocation, shrinkPostAllocation); } /* end of 'src/datacontainer.cpp' */ /* end of 'src/datacontainer.h' */ /* including file 'src/plottable.h', size 8312 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPSelectionDecorator { Q_GADGET public: QCPSelectionDecorator(); virtual ~QCPSelectionDecorator(); // getters: QPen pen() const { return mPen; } QBrush brush() const { return mBrush; } QCPScatterStyle scatterStyle() const { return mScatterStyle; } QCPScatterStyle::ScatterProperties usedScatterProperties() const { return mUsedScatterProperties; } // setters: void setPen(const QPen &pen); void setBrush(const QBrush &brush); void setScatterStyle(const QCPScatterStyle &scatterStyle, QCPScatterStyle::ScatterProperties usedProperties=QCPScatterStyle::spPen); void setUsedScatterProperties(const QCPScatterStyle::ScatterProperties &properties); // non-virtual methods: void applyPen(QCPPainter *painter) const; void applyBrush(QCPPainter *painter) const; QCPScatterStyle getFinalScatterStyle(const QCPScatterStyle &unselectedStyle) const; // introduced virtual methods: virtual void copyFrom(const QCPSelectionDecorator *other); virtual void drawDecoration(QCPPainter *painter, QCPDataSelection selection); protected: // property members: QPen mPen; QBrush mBrush; QCPScatterStyle mScatterStyle; QCPScatterStyle::ScatterProperties mUsedScatterProperties; // non-property members: QCPAbstractPlottable *mPlottable; // introduced virtual methods: virtual bool registerWithPlottable(QCPAbstractPlottable *plottable); private: Q_DISABLE_COPY(QCPSelectionDecorator) friend class QCPAbstractPlottable; }; Q_DECLARE_METATYPE(QCPSelectionDecorator*) class QCP_LIB_DECL QCPAbstractPlottable : public QCPLayerable { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QString name READ name WRITE setName) Q_PROPERTY(bool antialiasedFill READ antialiasedFill WRITE setAntialiasedFill) Q_PROPERTY(bool antialiasedScatters READ antialiasedScatters WRITE setAntialiasedScatters) Q_PROPERTY(QPen pen READ pen WRITE setPen) Q_PROPERTY(QBrush brush READ brush WRITE setBrush) Q_PROPERTY(QCPAxis* keyAxis READ keyAxis WRITE setKeyAxis) Q_PROPERTY(QCPAxis* valueAxis READ valueAxis WRITE setValueAxis) Q_PROPERTY(QCP::SelectionType selectable READ selectable WRITE setSelectable NOTIFY selectableChanged) Q_PROPERTY(QCPDataSelection selection READ selection WRITE setSelection NOTIFY selectionChanged) Q_PROPERTY(QCPSelectionDecorator* selectionDecorator READ selectionDecorator WRITE setSelectionDecorator) /// \endcond public: QCPAbstractPlottable(QCPAxis *keyAxis, QCPAxis *valueAxis); virtual ~QCPAbstractPlottable(); // getters: QString name() const { return mName; } bool antialiasedFill() const { return mAntialiasedFill; } bool antialiasedScatters() const { return mAntialiasedScatters; } QPen pen() const { return mPen; } QBrush brush() const { return mBrush; } QCPAxis *keyAxis() const { return mKeyAxis.data(); } QCPAxis *valueAxis() const { return mValueAxis.data(); } QCP::SelectionType selectable() const { return mSelectable; } bool selected() const { return !mSelection.isEmpty(); } QCPDataSelection selection() const { return mSelection; } QCPSelectionDecorator *selectionDecorator() const { return mSelectionDecorator; } // setters: void setName(const QString &name); void setAntialiasedFill(bool enabled); void setAntialiasedScatters(bool enabled); void setPen(const QPen &pen); void setBrush(const QBrush &brush); void setKeyAxis(QCPAxis *axis); void setValueAxis(QCPAxis *axis); Q_SLOT void setSelectable(QCP::SelectionType selectable); Q_SLOT void setSelection(QCPDataSelection selection); void setSelectionDecorator(QCPSelectionDecorator *decorator); // introduced virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const = 0; virtual QCPPlottableInterface1D *interface1D() { return 0; } virtual QCPRange getKeyRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth) const = 0; virtual QCPRange getValueRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth, const QCPRange &inKeyRange=QCPRange()) const = 0; // non-property methods: void coordsToPixels(double key, double value, double &x, double &y) const; const QPointF coordsToPixels(double key, double value) const; void pixelsToCoords(double x, double y, double &key, double &value) const; void pixelsToCoords(const QPointF &pixelPos, double &key, double &value) const; void rescaleAxes(bool onlyEnlarge=false) const; void rescaleKeyAxis(bool onlyEnlarge=false) const; void rescaleValueAxis(bool onlyEnlarge=false, bool inKeyRange=false) const; bool addToLegend(QCPLegend *legend); bool addToLegend(); bool removeFromLegend(QCPLegend *legend) const; bool removeFromLegend() const; signals: void selectionChanged(bool selected); void selectionChanged(const QCPDataSelection &selection); void selectableChanged(QCP::SelectionType selectable); protected: // property members: QString mName; bool mAntialiasedFill, mAntialiasedScatters; QPen mPen; QBrush mBrush; QPointer mKeyAxis, mValueAxis; QCP::SelectionType mSelectable; QCPDataSelection mSelection; QCPSelectionDecorator *mSelectionDecorator; // reimplemented virtual methods: virtual QRect clipRect() const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE = 0; virtual QCP::Interaction selectionCategory() const Q_DECL_OVERRIDE; void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; // events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged) Q_DECL_OVERRIDE; virtual void deselectEvent(bool *selectionStateChanged) Q_DECL_OVERRIDE; // introduced virtual methods: virtual void drawLegendIcon(QCPPainter *painter, const QRectF &rect) const = 0; // non-virtual methods: void applyFillAntialiasingHint(QCPPainter *painter) const; void applyScattersAntialiasingHint(QCPPainter *painter) const; private: Q_DISABLE_COPY(QCPAbstractPlottable) friend class QCustomPlot; friend class QCPAxis; friend class QCPPlottableLegendItem; }; /* end of 'src/plottable.h' */ /* including file 'src/item.h', size 9384 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPItemAnchor { Q_GADGET public: QCPItemAnchor(QCustomPlot *parentPlot, QCPAbstractItem *parentItem, const QString &name, int anchorId=-1); virtual ~QCPItemAnchor(); // getters: QString name() const { return mName; } virtual QPointF pixelPosition() const; protected: // property members: QString mName; // non-property members: QCustomPlot *mParentPlot; QCPAbstractItem *mParentItem; int mAnchorId; QSet mChildrenX, mChildrenY; // introduced virtual methods: virtual QCPItemPosition *toQCPItemPosition() { return 0; } // non-virtual methods: void addChildX(QCPItemPosition* pos); // called from pos when this anchor is set as parent void removeChildX(QCPItemPosition *pos); // called from pos when its parent anchor is reset or pos deleted void addChildY(QCPItemPosition* pos); // called from pos when this anchor is set as parent void removeChildY(QCPItemPosition *pos); // called from pos when its parent anchor is reset or pos deleted private: Q_DISABLE_COPY(QCPItemAnchor) friend class QCPItemPosition; }; class QCP_LIB_DECL QCPItemPosition : public QCPItemAnchor { Q_GADGET public: /*! Defines the ways an item position can be specified. Thus it defines what the numbers passed to \ref setCoords actually mean. \see setType */ enum PositionType { ptAbsolute ///< Static positioning in pixels, starting from the top left corner of the viewport/widget. ,ptViewportRatio ///< Static positioning given by a fraction of the viewport size. For example, if you call setCoords(0, 0), the position will be at the top ///< left corner of the viewport/widget. setCoords(1, 1) will be at the bottom right corner, setCoords(0.5, 0) will be horizontally centered and ///< vertically at the top of the viewport/widget, etc. ,ptAxisRectRatio ///< Static positioning given by a fraction of the axis rect size (see \ref setAxisRect). For example, if you call setCoords(0, 0), the position will be at the top ///< left corner of the axis rect. setCoords(1, 1) will be at the bottom right corner, setCoords(0.5, 0) will be horizontally centered and ///< vertically at the top of the axis rect, etc. You can also go beyond the axis rect by providing negative coordinates or coordinates larger than 1. ,ptPlotCoords ///< Dynamic positioning at a plot coordinate defined by two axes (see \ref setAxes). }; Q_ENUMS(PositionType) QCPItemPosition(QCustomPlot *parentPlot, QCPAbstractItem *parentItem, const QString &name); virtual ~QCPItemPosition(); // getters: PositionType type() const { return typeX(); } PositionType typeX() const { return mPositionTypeX; } PositionType typeY() const { return mPositionTypeY; } QCPItemAnchor *parentAnchor() const { return parentAnchorX(); } QCPItemAnchor *parentAnchorX() const { return mParentAnchorX; } QCPItemAnchor *parentAnchorY() const { return mParentAnchorY; } double key() const { return mKey; } double value() const { return mValue; } QPointF coords() const { return QPointF(mKey, mValue); } QCPAxis *keyAxis() const { return mKeyAxis.data(); } QCPAxis *valueAxis() const { return mValueAxis.data(); } QCPAxisRect *axisRect() const; virtual QPointF pixelPosition() const Q_DECL_OVERRIDE; // setters: void setType(PositionType type); void setTypeX(PositionType type); void setTypeY(PositionType type); bool setParentAnchor(QCPItemAnchor *parentAnchor, bool keepPixelPosition=false); bool setParentAnchorX(QCPItemAnchor *parentAnchor, bool keepPixelPosition=false); bool setParentAnchorY(QCPItemAnchor *parentAnchor, bool keepPixelPosition=false); void setCoords(double key, double value); void setCoords(const QPointF &coords); void setAxes(QCPAxis* keyAxis, QCPAxis* valueAxis); void setAxisRect(QCPAxisRect *axisRect); void setPixelPosition(const QPointF &pixelPosition); protected: // property members: PositionType mPositionTypeX, mPositionTypeY; QPointer mKeyAxis, mValueAxis; QPointer mAxisRect; double mKey, mValue; QCPItemAnchor *mParentAnchorX, *mParentAnchorY; // reimplemented virtual methods: virtual QCPItemPosition *toQCPItemPosition() Q_DECL_OVERRIDE { return this; } private: Q_DISABLE_COPY(QCPItemPosition) }; Q_DECLARE_METATYPE(QCPItemPosition::PositionType) class QCP_LIB_DECL QCPAbstractItem : public QCPLayerable { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(bool clipToAxisRect READ clipToAxisRect WRITE setClipToAxisRect) Q_PROPERTY(QCPAxisRect* clipAxisRect READ clipAxisRect WRITE setClipAxisRect) Q_PROPERTY(bool selectable READ selectable WRITE setSelectable NOTIFY selectableChanged) Q_PROPERTY(bool selected READ selected WRITE setSelected NOTIFY selectionChanged) /// \endcond public: explicit QCPAbstractItem(QCustomPlot *parentPlot); virtual ~QCPAbstractItem(); // getters: bool clipToAxisRect() const { return mClipToAxisRect; } QCPAxisRect *clipAxisRect() const; bool selectable() const { return mSelectable; } bool selected() const { return mSelected; } // setters: void setClipToAxisRect(bool clip); void setClipAxisRect(QCPAxisRect *rect); Q_SLOT void setSelectable(bool selectable); Q_SLOT void setSelected(bool selected); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE = 0; // non-virtual methods: QList positions() const { return mPositions; } QList anchors() const { return mAnchors; } QCPItemPosition *position(const QString &name) const; QCPItemAnchor *anchor(const QString &name) const; bool hasAnchor(const QString &name) const; signals: void selectionChanged(bool selected); void selectableChanged(bool selectable); protected: // property members: bool mClipToAxisRect; QPointer mClipAxisRect; QList mPositions; QList mAnchors; bool mSelectable, mSelected; // reimplemented virtual methods: virtual QCP::Interaction selectionCategory() const Q_DECL_OVERRIDE; virtual QRect clipRect() const Q_DECL_OVERRIDE; virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE = 0; // events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged) Q_DECL_OVERRIDE; virtual void deselectEvent(bool *selectionStateChanged) Q_DECL_OVERRIDE; // introduced virtual methods: virtual QPointF anchorPixelPosition(int anchorId) const; // non-virtual methods: double rectDistance(const QRectF &rect, const QPointF &pos, bool filledRect) const; QCPItemPosition *createPosition(const QString &name); QCPItemAnchor *createAnchor(const QString &name, int anchorId); private: Q_DISABLE_COPY(QCPAbstractItem) friend class QCustomPlot; friend class QCPItemAnchor; }; /* end of 'src/item.h' */ /* including file 'src/core.h', size 14886 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCustomPlot : public QWidget { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QRect viewport READ viewport WRITE setViewport) Q_PROPERTY(QPixmap background READ background WRITE setBackground) Q_PROPERTY(bool backgroundScaled READ backgroundScaled WRITE setBackgroundScaled) Q_PROPERTY(Qt::AspectRatioMode backgroundScaledMode READ backgroundScaledMode WRITE setBackgroundScaledMode) Q_PROPERTY(QCPLayoutGrid* plotLayout READ plotLayout) Q_PROPERTY(bool autoAddPlottableToLegend READ autoAddPlottableToLegend WRITE setAutoAddPlottableToLegend) Q_PROPERTY(int selectionTolerance READ selectionTolerance WRITE setSelectionTolerance) Q_PROPERTY(bool noAntialiasingOnDrag READ noAntialiasingOnDrag WRITE setNoAntialiasingOnDrag) Q_PROPERTY(Qt::KeyboardModifier multiSelectModifier READ multiSelectModifier WRITE setMultiSelectModifier) Q_PROPERTY(bool openGl READ openGl WRITE setOpenGl) /// \endcond public: /*! Defines how a layer should be inserted relative to an other layer. \see addLayer, moveLayer */ enum LayerInsertMode { limBelow ///< Layer is inserted below other layer ,limAbove ///< Layer is inserted above other layer }; Q_ENUMS(LayerInsertMode) /*! Defines with what timing the QCustomPlot surface is refreshed after a replot. \see replot */ enum RefreshPriority { rpImmediateRefresh ///< Replots immediately and repaints the widget immediately by calling QWidget::repaint() after the replot ,rpQueuedRefresh ///< Replots immediately, but queues the widget repaint, by calling QWidget::update() after the replot. This way multiple redundant widget repaints can be avoided. ,rpRefreshHint ///< Whether to use immediate or queued refresh depends on whether the plotting hint \ref QCP::phImmediateRefresh is set, see \ref setPlottingHints. ,rpQueuedReplot ///< Queues the entire replot for the next event loop iteration. This way multiple redundant replots can be avoided. The actual replot is then done with \ref rpRefreshHint priority. }; Q_ENUMS(RefreshPriority) explicit QCustomPlot(QWidget *parent = 0); virtual ~QCustomPlot(); // getters: QRect viewport() const { return mViewport; } double bufferDevicePixelRatio() const { return mBufferDevicePixelRatio; } QPixmap background() const { return mBackgroundPixmap; } bool backgroundScaled() const { return mBackgroundScaled; } Qt::AspectRatioMode backgroundScaledMode() const { return mBackgroundScaledMode; } QCPLayoutGrid *plotLayout() const { return mPlotLayout; } QCP::AntialiasedElements antialiasedElements() const { return mAntialiasedElements; } QCP::AntialiasedElements notAntialiasedElements() const { return mNotAntialiasedElements; } bool autoAddPlottableToLegend() const { return mAutoAddPlottableToLegend; } const QCP::Interactions interactions() const { return mInteractions; } int selectionTolerance() const { return mSelectionTolerance; } bool noAntialiasingOnDrag() const { return mNoAntialiasingOnDrag; } QCP::PlottingHints plottingHints() const { return mPlottingHints; } Qt::KeyboardModifier multiSelectModifier() const { return mMultiSelectModifier; } QCP::SelectionRectMode selectionRectMode() const { return mSelectionRectMode; } QCPSelectionRect *selectionRect() const { return mSelectionRect; } bool openGl() const { return mOpenGl; } // setters: void setViewport(const QRect &rect); void setBufferDevicePixelRatio(double ratio); void setBackground(const QPixmap &pm); void setBackground(const QPixmap &pm, bool scaled, Qt::AspectRatioMode mode=Qt::KeepAspectRatioByExpanding); void setBackground(const QBrush &brush); void setBackgroundScaled(bool scaled); void setBackgroundScaledMode(Qt::AspectRatioMode mode); void setAntialiasedElements(const QCP::AntialiasedElements &antialiasedElements); void setAntialiasedElement(QCP::AntialiasedElement antialiasedElement, bool enabled=true); void setNotAntialiasedElements(const QCP::AntialiasedElements ¬AntialiasedElements); void setNotAntialiasedElement(QCP::AntialiasedElement notAntialiasedElement, bool enabled=true); void setAutoAddPlottableToLegend(bool on); void setInteractions(const QCP::Interactions &interactions); void setInteraction(const QCP::Interaction &interaction, bool enabled=true); void setSelectionTolerance(int pixels); void setNoAntialiasingOnDrag(bool enabled); void setPlottingHints(const QCP::PlottingHints &hints); void setPlottingHint(QCP::PlottingHint hint, bool enabled=true); void setMultiSelectModifier(Qt::KeyboardModifier modifier); void setSelectionRectMode(QCP::SelectionRectMode mode); void setSelectionRect(QCPSelectionRect *selectionRect); void setOpenGl(bool enabled, int multisampling=16); // non-property methods: // plottable interface: QCPAbstractPlottable *plottable(int index); QCPAbstractPlottable *plottable(); bool removePlottable(QCPAbstractPlottable *plottable); bool removePlottable(int index); int clearPlottables(); int plottableCount() const; QList selectedPlottables() const; QCPAbstractPlottable *plottableAt(const QPointF &pos, bool onlySelectable=false) const; bool hasPlottable(QCPAbstractPlottable *plottable) const; // specialized interface for QCPGraph: QCPGraph *graph(int index) const; QCPGraph *graph() const; QCPGraph *addGraph(QCPAxis *keyAxis=0, QCPAxis *valueAxis=0); bool removeGraph(QCPGraph *graph); bool removeGraph(int index); int clearGraphs(); int graphCount() const; QList selectedGraphs() const; // item interface: QCPAbstractItem *item(int index) const; QCPAbstractItem *item() const; bool removeItem(QCPAbstractItem *item); bool removeItem(int index); int clearItems(); int itemCount() const; QList selectedItems() const; QCPAbstractItem *itemAt(const QPointF &pos, bool onlySelectable=false) const; bool hasItem(QCPAbstractItem *item) const; // layer interface: QCPLayer *layer(const QString &name) const; QCPLayer *layer(int index) const; QCPLayer *currentLayer() const; bool setCurrentLayer(const QString &name); bool setCurrentLayer(QCPLayer *layer); int layerCount() const; bool addLayer(const QString &name, QCPLayer *otherLayer=0, LayerInsertMode insertMode=limAbove); bool removeLayer(QCPLayer *layer); bool moveLayer(QCPLayer *layer, QCPLayer *otherLayer, LayerInsertMode insertMode=limAbove); // axis rect/layout interface: int axisRectCount() const; QCPAxisRect* axisRect(int index=0) const; QList axisRects() const; QCPLayoutElement* layoutElementAt(const QPointF &pos) const; QCPAxisRect* axisRectAt(const QPointF &pos) const; Q_SLOT void rescaleAxes(bool onlyVisiblePlottables=false); QList selectedAxes() const; QList selectedLegends() const; Q_SLOT void deselectAll(); bool savePdf(const QString &fileName, int width=0, int height=0, QCP::ExportPen exportPen=QCP::epAllowCosmetic, const QString &pdfCreator=QString(), const QString &pdfTitle=QString()); bool savePng(const QString &fileName, int width=0, int height=0, double scale=1.0, int quality=-1, int resolution=96, QCP::ResolutionUnit resolutionUnit=QCP::ruDotsPerInch); bool saveJpg(const QString &fileName, int width=0, int height=0, double scale=1.0, int quality=-1, int resolution=96, QCP::ResolutionUnit resolutionUnit=QCP::ruDotsPerInch); bool saveBmp(const QString &fileName, int width=0, int height=0, double scale=1.0, int resolution=96, QCP::ResolutionUnit resolutionUnit=QCP::ruDotsPerInch); bool saveRastered(const QString &fileName, int width, int height, double scale, const char *format, int quality=-1, int resolution=96, QCP::ResolutionUnit resolutionUnit=QCP::ruDotsPerInch); QPixmap toPixmap(int width=0, int height=0, double scale=1.0); void toPainter(QCPPainter *painter, int width=0, int height=0); Q_SLOT void replot(QCustomPlot::RefreshPriority refreshPriority=QCustomPlot::rpRefreshHint); QCPAxis *xAxis, *yAxis, *xAxis2, *yAxis2; QCPLegend *legend; signals: void mouseDoubleClick(QMouseEvent *event); void mousePress(QMouseEvent *event); void mouseMove(QMouseEvent *event); void mouseRelease(QMouseEvent *event); void mouseWheel(QWheelEvent *event); void plottableClick(QCPAbstractPlottable *plottable, int dataIndex, QMouseEvent *event); void plottableDoubleClick(QCPAbstractPlottable *plottable, int dataIndex, QMouseEvent *event); void itemClick(QCPAbstractItem *item, QMouseEvent *event); void itemDoubleClick(QCPAbstractItem *item, QMouseEvent *event); void axisClick(QCPAxis *axis, QCPAxis::SelectablePart part, QMouseEvent *event); void axisDoubleClick(QCPAxis *axis, QCPAxis::SelectablePart part, QMouseEvent *event); void legendClick(QCPLegend *legend, QCPAbstractLegendItem *item, QMouseEvent *event); void legendDoubleClick(QCPLegend *legend, QCPAbstractLegendItem *item, QMouseEvent *event); void selectionChangedByUser(); void beforeReplot(); void afterReplot(); protected: // property members: QRect mViewport; double mBufferDevicePixelRatio; QCPLayoutGrid *mPlotLayout; bool mAutoAddPlottableToLegend; QList mPlottables; QList mGraphs; // extra list of plottables also in mPlottables that are of type QCPGraph QList mItems; QList mLayers; QCP::AntialiasedElements mAntialiasedElements, mNotAntialiasedElements; QCP::Interactions mInteractions; int mSelectionTolerance; bool mNoAntialiasingOnDrag; QBrush mBackgroundBrush; QPixmap mBackgroundPixmap; QPixmap mScaledBackgroundPixmap; bool mBackgroundScaled; Qt::AspectRatioMode mBackgroundScaledMode; QCPLayer *mCurrentLayer; QCP::PlottingHints mPlottingHints; Qt::KeyboardModifier mMultiSelectModifier; QCP::SelectionRectMode mSelectionRectMode; QCPSelectionRect *mSelectionRect; bool mOpenGl; // non-property members: QList > mPaintBuffers; QPoint mMousePressPos; bool mMouseHasMoved; QPointer mMouseEventLayerable; QPointer mMouseSignalLayerable; QVariant mMouseEventLayerableDetails; QVariant mMouseSignalLayerableDetails; bool mReplotting; bool mReplotQueued; int mOpenGlMultisamples; QCP::AntialiasedElements mOpenGlAntialiasedElementsBackup; bool mOpenGlCacheLabelsBackup; #ifdef QCP_OPENGL_FBO QSharedPointer mGlContext; QSharedPointer mGlSurface; QSharedPointer mGlPaintDevice; #endif // reimplemented virtual methods: virtual QSize minimumSizeHint() const Q_DECL_OVERRIDE; virtual QSize sizeHint() const Q_DECL_OVERRIDE; virtual void paintEvent(QPaintEvent *event) Q_DECL_OVERRIDE; virtual void resizeEvent(QResizeEvent *event) Q_DECL_OVERRIDE; virtual void mouseDoubleClickEvent(QMouseEvent *event) Q_DECL_OVERRIDE; virtual void mousePressEvent(QMouseEvent *event) Q_DECL_OVERRIDE; virtual void mouseMoveEvent(QMouseEvent *event) Q_DECL_OVERRIDE; virtual void mouseReleaseEvent(QMouseEvent *event) Q_DECL_OVERRIDE; virtual void wheelEvent(QWheelEvent *event) Q_DECL_OVERRIDE; // introduced virtual methods: virtual void draw(QCPPainter *painter); virtual void updateLayout(); virtual void axisRemoved(QCPAxis *axis); virtual void legendRemoved(QCPLegend *legend); Q_SLOT virtual void processRectSelection(QRect rect, QMouseEvent *event); Q_SLOT virtual void processRectZoom(QRect rect, QMouseEvent *event); Q_SLOT virtual void processPointSelection(QMouseEvent *event); // non-virtual methods: bool registerPlottable(QCPAbstractPlottable *plottable); bool registerGraph(QCPGraph *graph); bool registerItem(QCPAbstractItem* item); void updateLayerIndices() const; QCPLayerable *layerableAt(const QPointF &pos, bool onlySelectable, QVariant *selectionDetails=0) const; QList layerableListAt(const QPointF &pos, bool onlySelectable, QList *selectionDetails=0) const; void drawBackground(QCPPainter *painter); void setupPaintBuffers(); QCPAbstractPaintBuffer *createPaintBuffer(); bool hasInvalidatedPaintBuffers(); bool setupOpenGl(); void freeOpenGl(); friend class QCPLegend; friend class QCPAxis; friend class QCPLayer; friend class QCPAxisRect; friend class QCPAbstractPlottable; friend class QCPGraph; friend class QCPAbstractItem; }; Q_DECLARE_METATYPE(QCustomPlot::LayerInsertMode) Q_DECLARE_METATYPE(QCustomPlot::RefreshPriority) /* end of 'src/core.h' */ /* including file 'src/plottable1d.h', size 4544 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCPPlottableInterface1D { public: virtual ~QCPPlottableInterface1D() {} // introduced pure virtual methods: virtual int dataCount() const = 0; virtual double dataMainKey(int index) const = 0; virtual double dataSortKey(int index) const = 0; virtual double dataMainValue(int index) const = 0; virtual QCPRange dataValueRange(int index) const = 0; virtual QPointF dataPixelPosition(int index) const = 0; virtual bool sortKeyIsMainKey() const = 0; virtual QCPDataSelection selectTestRect(const QRectF &rect, bool onlySelectable) const = 0; virtual int findBegin(double sortKey, bool expandedRange=true) const = 0; virtual int findEnd(double sortKey, bool expandedRange=true) const = 0; }; template class QCPAbstractPlottable1D : public QCPAbstractPlottable, public QCPPlottableInterface1D // no QCP_LIB_DECL, template class ends up in header (cpp included below) { // No Q_OBJECT macro due to template class public: QCPAbstractPlottable1D(QCPAxis *keyAxis, QCPAxis *valueAxis); virtual ~QCPAbstractPlottable1D(); // virtual methods of 1d plottable interface: virtual int dataCount() const Q_DECL_OVERRIDE; virtual double dataMainKey(int index) const Q_DECL_OVERRIDE; virtual double dataSortKey(int index) const Q_DECL_OVERRIDE; virtual double dataMainValue(int index) const Q_DECL_OVERRIDE; virtual QCPRange dataValueRange(int index) const Q_DECL_OVERRIDE; virtual QPointF dataPixelPosition(int index) const Q_DECL_OVERRIDE; virtual bool sortKeyIsMainKey() const Q_DECL_OVERRIDE; virtual QCPDataSelection selectTestRect(const QRectF &rect, bool onlySelectable) const Q_DECL_OVERRIDE; virtual int findBegin(double sortKey, bool expandedRange=true) const Q_DECL_OVERRIDE; virtual int findEnd(double sortKey, bool expandedRange=true) const Q_DECL_OVERRIDE; // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; virtual QCPPlottableInterface1D *interface1D() Q_DECL_OVERRIDE { return this; } protected: // property members: QSharedPointer > mDataContainer; // helpers for subclasses: void getDataSegments(QList &selectedSegments, QList &unselectedSegments) const; void drawPolyline(QCPPainter *painter, const QVector &lineData) const; private: Q_DISABLE_COPY(QCPAbstractPlottable1D) }; // include implementation in header since it is a class template: /* including file 'src/plottable1d.cpp', size 22240 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ //////////////////////////////////////////////////////////////////////////////////////////////////// //////////////////// QCPPlottableInterface1D //////////////////////////////////////////////////////////////////////////////////////////////////// /*! \class QCPPlottableInterface1D \brief Defines an abstract interface for one-dimensional plottables This class contains only pure virtual methods which define a common interface to the data of one-dimensional plottables. For example, it is implemented by the template class \ref QCPAbstractPlottable1D (the preferred base class for one-dimensional plottables). So if you use that template class as base class of your one-dimensional plottable, you won't have to care about implementing the 1d interface yourself. If your plottable doesn't derive from \ref QCPAbstractPlottable1D but still wants to provide a 1d interface (e.g. like \ref QCPErrorBars does), you should inherit from both \ref QCPAbstractPlottable and \ref QCPPlottableInterface1D and accordingly reimplement the pure virtual methods of the 1d interface, matching your data container. Also, reimplement \ref QCPAbstractPlottable::interface1D to return the \c this pointer. If you have a \ref QCPAbstractPlottable pointer, you can check whether it implements this interface by calling \ref QCPAbstractPlottable::interface1D and testing it for a non-zero return value. If it indeed implements this interface, you may use it to access the plottable's data without needing to know the exact type of the plottable or its data point type. */ /* start documentation of pure virtual functions */ /*! \fn virtual int QCPPlottableInterface1D::dataCount() const = 0; Returns the number of data points of the plottable. */ /*! \fn virtual QCPDataSelection QCPPlottableInterface1D::selectTestRect(const QRectF &rect, bool onlySelectable) const = 0; Returns a data selection containing all the data points of this plottable which are contained (or hit by) \a rect. This is used mainly in the selection rect interaction for data selection (\ref dataselection "data selection mechanism"). If \a onlySelectable is true, an empty QCPDataSelection is returned if this plottable is not selectable (i.e. if \ref QCPAbstractPlottable::setSelectable is \ref QCP::stNone). \note \a rect must be a normalized rect (positive or zero width and height). This is especially important when using the rect of \ref QCPSelectionRect::accepted, which is not necessarily normalized. Use QRect::normalized() when passing a rect which might not be normalized. */ /*! \fn virtual double QCPPlottableInterface1D::dataMainKey(int index) const = 0 Returns the main key of the data point at the given \a index. What the main key is, is defined by the plottable's data type. See the \ref qcpdatacontainer-datatype "QCPDataContainer DataType" documentation for details about this naming convention. */ /*! \fn virtual double QCPPlottableInterface1D::dataSortKey(int index) const = 0 Returns the sort key of the data point at the given \a index. What the sort key is, is defined by the plottable's data type. See the \ref qcpdatacontainer-datatype "QCPDataContainer DataType" documentation for details about this naming convention. */ /*! \fn virtual double QCPPlottableInterface1D::dataMainValue(int index) const = 0 Returns the main value of the data point at the given \a index. What the main value is, is defined by the plottable's data type. See the \ref qcpdatacontainer-datatype "QCPDataContainer DataType" documentation for details about this naming convention. */ /*! \fn virtual QCPRange QCPPlottableInterface1D::dataValueRange(int index) const = 0 Returns the value range of the data point at the given \a index. What the value range is, is defined by the plottable's data type. See the \ref qcpdatacontainer-datatype "QCPDataContainer DataType" documentation for details about this naming convention. */ /*! \fn virtual QPointF QCPPlottableInterface1D::dataPixelPosition(int index) const = 0 Returns the pixel position on the widget surface at which the data point at the given \a index appears. Usually this corresponds to the point of \ref dataMainKey/\ref dataMainValue, in pixel coordinates. However, depending on the plottable, this might be a different apparent position than just a coord-to-pixel transform of those values. For example, \ref QCPBars apparent data values can be shifted depending on their stacking, bar grouping or configured base value. */ /*! \fn virtual bool QCPPlottableInterface1D::sortKeyIsMainKey() const = 0 Returns whether the sort key (\ref dataSortKey) is identical to the main key (\ref dataMainKey). What the sort and main keys are, is defined by the plottable's data type. See the \ref qcpdatacontainer-datatype "QCPDataContainer DataType" documentation for details about this naming convention. */ /*! \fn virtual int QCPPlottableInterface1D::findBegin(double sortKey, bool expandedRange) const = 0 Returns the index of the data point with a (sort-)key that is equal to, just below, or just above \a sortKey. If \a expandedRange is true, the data point just below \a sortKey will be considered, otherwise the one just above. This can be used in conjunction with \ref findEnd to iterate over data points within a given key range, including or excluding the bounding data points that are just beyond the specified range. If \a expandedRange is true but there are no data points below \a sortKey, 0 is returned. If the container is empty, returns 0 (in that case, \ref findEnd will also return 0, so a loop using these methods will not iterate over the index 0). \see findEnd, QCPDataContainer::findBegin */ /*! \fn virtual int QCPPlottableInterface1D::findEnd(double sortKey, bool expandedRange) const = 0 Returns the index one after the data point with a (sort-)key that is equal to, just above, or just below \a sortKey. If \a expandedRange is true, the data point just above \a sortKey will be considered, otherwise the one just below. This can be used in conjunction with \ref findBegin to iterate over data points within a given key range, including the bounding data points that are just below and above the specified range. If \a expandedRange is true but there are no data points above \a sortKey, the index just above the highest data point is returned. If the container is empty, returns 0. \see findBegin, QCPDataContainer::findEnd */ /* end documentation of pure virtual functions */ //////////////////////////////////////////////////////////////////////////////////////////////////// //////////////////// QCPAbstractPlottable1D //////////////////////////////////////////////////////////////////////////////////////////////////// /*! \class QCPAbstractPlottable1D \brief A template base class for plottables with one-dimensional data This template class derives from \ref QCPAbstractPlottable and from the abstract interface \ref QCPPlottableInterface1D. It serves as a base class for all one-dimensional data (i.e. data with one key dimension), such as \ref QCPGraph and QCPCurve. The template parameter \a DataType is the type of the data points of this plottable (e.g. \ref QCPGraphData or \ref QCPCurveData). The main purpose of this base class is to provide the member \a mDataContainer (a shared pointer to a \ref QCPDataContainer "QCPDataContainer") and implement the according virtual methods of the \ref QCPPlottableInterface1D, such that most subclassed plottables don't need to worry about this anymore. Further, it provides a convenience method for retrieving selected/unselected data segments via \ref getDataSegments. This is useful when subclasses implement their \ref draw method and need to draw selected segments with a different pen/brush than unselected segments (also see \ref QCPSelectionDecorator). This class implements basic functionality of \ref QCPAbstractPlottable::selectTest and \ref QCPPlottableInterface1D::selectTestRect, assuming point-like data points, based on the 1D data interface. In spite of that, most plottable subclasses will want to reimplement those methods again, to provide a more accurate hit test based on their specific data visualization geometry. */ /* start documentation of inline functions */ /*! \fn QCPPlottableInterface1D *QCPAbstractPlottable1D::interface1D() Returns a \ref QCPPlottableInterface1D pointer to this plottable, providing access to its 1D interface. \seebaseclassmethod */ /* end documentation of inline functions */ /*! Forwards \a keyAxis and \a valueAxis to the \ref QCPAbstractPlottable::QCPAbstractPlottable "QCPAbstractPlottable" constructor and allocates the \a mDataContainer. */ template QCPAbstractPlottable1D::QCPAbstractPlottable1D(QCPAxis *keyAxis, QCPAxis *valueAxis) : QCPAbstractPlottable(keyAxis, valueAxis), mDataContainer(new QCPDataContainer) { } template QCPAbstractPlottable1D::~QCPAbstractPlottable1D() { } /*! \copydoc QCPPlottableInterface1D::dataCount */ template int QCPAbstractPlottable1D::dataCount() const { return mDataContainer->size(); } /*! \copydoc QCPPlottableInterface1D::dataMainKey */ template double QCPAbstractPlottable1D::dataMainKey(int index) const { if (index >= 0 && index < mDataContainer->size()) { return (mDataContainer->constBegin()+index)->mainKey(); } else { qDebug() << Q_FUNC_INFO << "Index out of bounds" << index; return 0; } } /*! \copydoc QCPPlottableInterface1D::dataSortKey */ template double QCPAbstractPlottable1D::dataSortKey(int index) const { if (index >= 0 && index < mDataContainer->size()) { return (mDataContainer->constBegin()+index)->sortKey(); } else { qDebug() << Q_FUNC_INFO << "Index out of bounds" << index; return 0; } } /*! \copydoc QCPPlottableInterface1D::dataMainValue */ template double QCPAbstractPlottable1D::dataMainValue(int index) const { if (index >= 0 && index < mDataContainer->size()) { return (mDataContainer->constBegin()+index)->mainValue(); } else { qDebug() << Q_FUNC_INFO << "Index out of bounds" << index; return 0; } } /*! \copydoc QCPPlottableInterface1D::dataValueRange */ template QCPRange QCPAbstractPlottable1D::dataValueRange(int index) const { if (index >= 0 && index < mDataContainer->size()) { return (mDataContainer->constBegin()+index)->valueRange(); } else { qDebug() << Q_FUNC_INFO << "Index out of bounds" << index; return QCPRange(0, 0); } } /*! \copydoc QCPPlottableInterface1D::dataPixelPosition */ template QPointF QCPAbstractPlottable1D::dataPixelPosition(int index) const { if (index >= 0 && index < mDataContainer->size()) { const typename QCPDataContainer::const_iterator it = mDataContainer->constBegin()+index; return coordsToPixels(it->mainKey(), it->mainValue()); } else { qDebug() << Q_FUNC_INFO << "Index out of bounds" << index; return QPointF(); } } /*! \copydoc QCPPlottableInterface1D::sortKeyIsMainKey */ template bool QCPAbstractPlottable1D::sortKeyIsMainKey() const { return DataType::sortKeyIsMainKey(); } /*! Implements a rect-selection algorithm assuming the data (accessed via the 1D data interface) is point-like. Most subclasses will want to reimplement this method again, to provide a more accurate hit test based on the true data visualization geometry. \seebaseclassmethod */ template QCPDataSelection QCPAbstractPlottable1D::selectTestRect(const QRectF &rect, bool onlySelectable) const { QCPDataSelection result; if ((onlySelectable && mSelectable == QCP::stNone) || mDataContainer->isEmpty()) return result; if (!mKeyAxis || !mValueAxis) return result; // convert rect given in pixels to ranges given in plot coordinates: double key1, value1, key2, value2; pixelsToCoords(rect.topLeft(), key1, value1); pixelsToCoords(rect.bottomRight(), key2, value2); QCPRange keyRange(key1, key2); // QCPRange normalizes internally so we don't have to care about whether key1 < key2 QCPRange valueRange(value1, value2); typename QCPDataContainer::const_iterator begin = mDataContainer->constBegin(); typename QCPDataContainer::const_iterator end = mDataContainer->constEnd(); if (DataType::sortKeyIsMainKey()) // we can assume that data is sorted by main key, so can reduce the searched key interval: { begin = mDataContainer->findBegin(keyRange.lower, false); end = mDataContainer->findEnd(keyRange.upper, false); } if (begin == end) return result; int currentSegmentBegin = -1; // -1 means we're currently not in a segment that's contained in rect for (typename QCPDataContainer::const_iterator it=begin; it!=end; ++it) { if (currentSegmentBegin == -1) { if (valueRange.contains(it->mainValue()) && keyRange.contains(it->mainKey())) // start segment currentSegmentBegin = it-mDataContainer->constBegin(); } else if (!valueRange.contains(it->mainValue()) || !keyRange.contains(it->mainKey())) // segment just ended { result.addDataRange(QCPDataRange(currentSegmentBegin, it-mDataContainer->constBegin()), false); currentSegmentBegin = -1; } } // process potential last segment: if (currentSegmentBegin != -1) result.addDataRange(QCPDataRange(currentSegmentBegin, end-mDataContainer->constBegin()), false); result.simplify(); return result; } /*! \copydoc QCPPlottableInterface1D::findBegin */ template int QCPAbstractPlottable1D::findBegin(double sortKey, bool expandedRange) const { return mDataContainer->findBegin(sortKey, expandedRange)-mDataContainer->constBegin(); } /*! \copydoc QCPPlottableInterface1D::findEnd */ template int QCPAbstractPlottable1D::findEnd(double sortKey, bool expandedRange) const { return mDataContainer->findEnd(sortKey, expandedRange)-mDataContainer->constBegin(); } /*! Implements a point-selection algorithm assuming the data (accessed via the 1D data interface) is point-like. Most subclasses will want to reimplement this method again, to provide a more accurate hit test based on the true data visualization geometry. \seebaseclassmethod */ template double QCPAbstractPlottable1D::selectTest(const QPointF &pos, bool onlySelectable, QVariant *details) const { if ((onlySelectable && mSelectable == QCP::stNone) || mDataContainer->isEmpty()) return -1; if (!mKeyAxis || !mValueAxis) return -1; QCPDataSelection selectionResult; double minDistSqr = std::numeric_limits::max(); int minDistIndex = mDataContainer->size(); typename QCPDataContainer::const_iterator begin = mDataContainer->constBegin(); typename QCPDataContainer::const_iterator end = mDataContainer->constEnd(); if (DataType::sortKeyIsMainKey()) // we can assume that data is sorted by main key, so can reduce the searched key interval: { // determine which key range comes into question, taking selection tolerance around pos into account: double posKeyMin, posKeyMax, dummy; pixelsToCoords(pos-QPointF(mParentPlot->selectionTolerance(), mParentPlot->selectionTolerance()), posKeyMin, dummy); pixelsToCoords(pos+QPointF(mParentPlot->selectionTolerance(), mParentPlot->selectionTolerance()), posKeyMax, dummy); if (posKeyMin > posKeyMax) qSwap(posKeyMin, posKeyMax); begin = mDataContainer->findBegin(posKeyMin, true); end = mDataContainer->findEnd(posKeyMax, true); } if (begin == end) return -1; QCPRange keyRange(mKeyAxis->range()); QCPRange valueRange(mValueAxis->range()); for (typename QCPDataContainer::const_iterator it=begin; it!=end; ++it) { const double mainKey = it->mainKey(); const double mainValue = it->mainValue(); if (keyRange.contains(mainKey) && valueRange.contains(mainValue)) // make sure data point is inside visible range, for speedup in cases where sort key isn't main key and we iterate over all points { const double currentDistSqr = QCPVector2D(coordsToPixels(mainKey, mainValue)-pos).lengthSquared(); if (currentDistSqr < minDistSqr) { minDistSqr = currentDistSqr; minDistIndex = it-mDataContainer->constBegin(); } } } if (minDistIndex != mDataContainer->size()) selectionResult.addDataRange(QCPDataRange(minDistIndex, minDistIndex+1), false); selectionResult.simplify(); if (details) details->setValue(selectionResult); return qSqrt(minDistSqr); } /*! Splits all data into selected and unselected segments and outputs them via \a selectedSegments and \a unselectedSegments, respectively. This is useful when subclasses implement their \ref draw method and need to draw selected segments with a different pen/brush than unselected segments (also see \ref QCPSelectionDecorator). \see setSelection */ template void QCPAbstractPlottable1D::getDataSegments(QList &selectedSegments, QList &unselectedSegments) const { selectedSegments.clear(); unselectedSegments.clear(); if (mSelectable == QCP::stWhole) // stWhole selection type draws the entire plottable with selected style if mSelection isn't empty { if (selected()) selectedSegments << QCPDataRange(0, dataCount()); else unselectedSegments << QCPDataRange(0, dataCount()); } else { QCPDataSelection sel(selection()); sel.simplify(); selectedSegments = sel.dataRanges(); unselectedSegments = sel.inverse(QCPDataRange(0, dataCount())).dataRanges(); } } /*! A helper method which draws a line with the passed \a painter, according to the pixel data in \a lineData. NaN points create gaps in the line, as expected from QCustomPlot's plottables (this is the main difference to QPainter's regular drawPolyline, which handles NaNs by lagging or crashing). Further it uses a faster line drawing technique based on \ref QCPPainter::drawLine rather than \c QPainter::drawPolyline if the configured \ref QCustomPlot::setPlottingHints() and \a painter style allows. */ template void QCPAbstractPlottable1D::drawPolyline(QCPPainter *painter, const QVector &lineData) const { // if drawing solid line and not in PDF, use much faster line drawing instead of polyline: if (mParentPlot->plottingHints().testFlag(QCP::phFastPolylines) && painter->pen().style() == Qt::SolidLine && !painter->modes().testFlag(QCPPainter::pmVectorized) && !painter->modes().testFlag(QCPPainter::pmNoCaching)) { int i = 0; bool lastIsNan = false; const int lineDataSize = lineData.size(); while (i < lineDataSize && (qIsNaN(lineData.at(i).y()) || qIsNaN(lineData.at(i).x()))) // make sure first point is not NaN ++i; ++i; // because drawing works in 1 point retrospect while (i < lineDataSize) { if (!qIsNaN(lineData.at(i).y()) && !qIsNaN(lineData.at(i).x())) // NaNs create a gap in the line { if (!lastIsNan) painter->drawLine(lineData.at(i-1), lineData.at(i)); else lastIsNan = false; } else lastIsNan = true; ++i; } } else { int segmentStart = 0; int i = 0; const int lineDataSize = lineData.size(); while (i < lineDataSize) { if (qIsNaN(lineData.at(i).y()) || qIsNaN(lineData.at(i).x()) || qIsInf(lineData.at(i).y())) // NaNs create a gap in the line. Also filter Infs which make drawPolyline block { painter->drawPolyline(lineData.constData()+segmentStart, i-segmentStart); // i, because we don't want to include the current NaN point segmentStart = i+1; } ++i; } // draw last segment: painter->drawPolyline(lineData.constData()+segmentStart, lineDataSize-segmentStart); } } /* end of 'src/plottable1d.cpp' */ /* end of 'src/plottable1d.h' */ /* including file 'src/colorgradient.h', size 6243 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPColorGradient { Q_GADGET public: /*! Defines the color spaces in which color interpolation between gradient stops can be performed. \see setColorInterpolation */ enum ColorInterpolation { ciRGB ///< Color channels red, green and blue are linearly interpolated ,ciHSV ///< Color channels hue, saturation and value are linearly interpolated (The hue is interpolated over the shortest angle distance) }; Q_ENUMS(ColorInterpolation) /*! Defines the available presets that can be loaded with \ref loadPreset. See the documentation there for an image of the presets. */ enum GradientPreset { gpGrayscale ///< Continuous lightness from black to white (suited for non-biased data representation) ,gpHot ///< Continuous lightness from black over firey colors to white (suited for non-biased data representation) ,gpCold ///< Continuous lightness from black over icey colors to white (suited for non-biased data representation) ,gpNight ///< Continuous lightness from black over weak blueish colors to white (suited for non-biased data representation) ,gpCandy ///< Blue over pink to white ,gpGeography ///< Colors suitable to represent different elevations on geographical maps ,gpIon ///< Half hue spectrum from black over purple to blue and finally green (creates banding illusion but allows more precise magnitude estimates) ,gpThermal ///< Colors suitable for thermal imaging, ranging from dark blue over purple to orange, yellow and white ,gpPolar ///< Colors suitable to emphasize polarity around the center, with blue for negative, black in the middle and red for positive values ,gpSpectrum ///< An approximation of the visible light spectrum (creates banding illusion but allows more precise magnitude estimates) ,gpJet ///< Hue variation similar to a spectrum, often used in numerical visualization (creates banding illusion but allows more precise magnitude estimates) ,gpHues ///< Full hue cycle, with highest and lowest color red (suitable for periodic data, such as angles and phases, see \ref setPeriodic) }; Q_ENUMS(GradientPreset) QCPColorGradient(); QCPColorGradient(GradientPreset preset); bool operator==(const QCPColorGradient &other) const; bool operator!=(const QCPColorGradient &other) const { return !(*this == other); } // getters: int levelCount() const { return mLevelCount; } QMap colorStops() const { return mColorStops; } ColorInterpolation colorInterpolation() const { return mColorInterpolation; } bool periodic() const { return mPeriodic; } // setters: void setLevelCount(int n); void setColorStops(const QMap &colorStops); void setColorStopAt(double position, const QColor &color); void setColorInterpolation(ColorInterpolation interpolation); void setPeriodic(bool enabled); // non-property methods: void colorize(const double *data, const QCPRange &range, QRgb *scanLine, int n, int dataIndexFactor=1, bool logarithmic=false); void colorize(const double *data, const unsigned char *alpha, const QCPRange &range, QRgb *scanLine, int n, int dataIndexFactor=1, bool logarithmic=false); QRgb color(double position, const QCPRange &range, bool logarithmic=false); void loadPreset(GradientPreset preset); void clearColorStops(); QCPColorGradient inverted() const; protected: // property members: int mLevelCount; QMap mColorStops; ColorInterpolation mColorInterpolation; bool mPeriodic; // non-property members: QVector mColorBuffer; // have colors premultiplied with alpha (for usage with QImage::Format_ARGB32_Premultiplied) bool mColorBufferInvalidated; // non-virtual methods: bool stopsUseAlpha() const; void updateColorBuffer(); }; Q_DECLARE_METATYPE(QCPColorGradient::ColorInterpolation) Q_DECLARE_METATYPE(QCPColorGradient::GradientPreset) /* end of 'src/colorgradient.h' */ /* including file 'src/selectiondecorator-bracket.h', size 4442 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPSelectionDecoratorBracket : public QCPSelectionDecorator { Q_GADGET public: /*! Defines which shape is drawn at the boundaries of selected data ranges. Some of the bracket styles further allow specifying a height and/or width, see \ref setBracketHeight and \ref setBracketWidth. */ enum BracketStyle { bsSquareBracket ///< A square bracket is drawn. ,bsHalfEllipse ///< A half ellipse is drawn. The size of the ellipse is given by the bracket width/height properties. ,bsEllipse ///< An ellipse is drawn. The size of the ellipse is given by the bracket width/height properties. ,bsPlus ///< A plus is drawn. ,bsUserStyle ///< Start custom bracket styles at this index when subclassing and reimplementing \ref drawBracket. }; Q_ENUMS(BracketStyle) QCPSelectionDecoratorBracket(); virtual ~QCPSelectionDecoratorBracket(); // getters: QPen bracketPen() const { return mBracketPen; } QBrush bracketBrush() const { return mBracketBrush; } int bracketWidth() const { return mBracketWidth; } int bracketHeight() const { return mBracketHeight; } BracketStyle bracketStyle() const { return mBracketStyle; } bool tangentToData() const { return mTangentToData; } int tangentAverage() const { return mTangentAverage; } // setters: void setBracketPen(const QPen &pen); void setBracketBrush(const QBrush &brush); void setBracketWidth(int width); void setBracketHeight(int height); void setBracketStyle(BracketStyle style); void setTangentToData(bool enabled); void setTangentAverage(int pointCount); // introduced virtual methods: virtual void drawBracket(QCPPainter *painter, int direction) const; // virtual methods: virtual void drawDecoration(QCPPainter *painter, QCPDataSelection selection) Q_DECL_OVERRIDE; protected: // property members: QPen mBracketPen; QBrush mBracketBrush; int mBracketWidth; int mBracketHeight; BracketStyle mBracketStyle; bool mTangentToData; int mTangentAverage; // non-virtual methods: double getTangentAngle(const QCPPlottableInterface1D *interface1d, int dataIndex, int direction) const; QPointF getPixelCoordinates(const QCPPlottableInterface1D *interface1d, int dataIndex) const; }; Q_DECLARE_METATYPE(QCPSelectionDecoratorBracket::BracketStyle) /* end of 'src/selectiondecorator-bracket.h' */ /* including file 'src/layoutelements/layoutelement-axisrect.h', size 7507 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAxisRect : public QCPLayoutElement { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QPixmap background READ background WRITE setBackground) Q_PROPERTY(bool backgroundScaled READ backgroundScaled WRITE setBackgroundScaled) Q_PROPERTY(Qt::AspectRatioMode backgroundScaledMode READ backgroundScaledMode WRITE setBackgroundScaledMode) Q_PROPERTY(Qt::Orientations rangeDrag READ rangeDrag WRITE setRangeDrag) Q_PROPERTY(Qt::Orientations rangeZoom READ rangeZoom WRITE setRangeZoom) /// \endcond public: explicit QCPAxisRect(QCustomPlot *parentPlot, bool setupDefaultAxes=true); virtual ~QCPAxisRect(); // getters: QPixmap background() const { return mBackgroundPixmap; } QBrush backgroundBrush() const { return mBackgroundBrush; } bool backgroundScaled() const { return mBackgroundScaled; } Qt::AspectRatioMode backgroundScaledMode() const { return mBackgroundScaledMode; } Qt::Orientations rangeDrag() const { return mRangeDrag; } Qt::Orientations rangeZoom() const { return mRangeZoom; } QCPAxis *rangeDragAxis(Qt::Orientation orientation); QCPAxis *rangeZoomAxis(Qt::Orientation orientation); QList rangeDragAxes(Qt::Orientation orientation); QList rangeZoomAxes(Qt::Orientation orientation); double rangeZoomFactor(Qt::Orientation orientation); // setters: void setBackground(const QPixmap &pm); void setBackground(const QPixmap &pm, bool scaled, Qt::AspectRatioMode mode=Qt::KeepAspectRatioByExpanding); void setBackground(const QBrush &brush); void setBackgroundScaled(bool scaled); void setBackgroundScaledMode(Qt::AspectRatioMode mode); void setRangeDrag(Qt::Orientations orientations); void setRangeZoom(Qt::Orientations orientations); void setRangeDragAxes(QCPAxis *horizontal, QCPAxis *vertical); void setRangeDragAxes(QList axes); void setRangeDragAxes(QList horizontal, QList vertical); void setRangeZoomAxes(QCPAxis *horizontal, QCPAxis *vertical); void setRangeZoomAxes(QList axes); void setRangeZoomAxes(QList horizontal, QList vertical); void setRangeZoomFactor(double horizontalFactor, double verticalFactor); void setRangeZoomFactor(double factor); // non-property methods: int axisCount(QCPAxis::AxisType type) const; QCPAxis *axis(QCPAxis::AxisType type, int index=0) const; QList axes(QCPAxis::AxisTypes types) const; QList axes() const; QCPAxis *addAxis(QCPAxis::AxisType type, QCPAxis *axis=0); QList addAxes(QCPAxis::AxisTypes types); bool removeAxis(QCPAxis *axis); QCPLayoutInset *insetLayout() const { return mInsetLayout; } void zoom(const QRectF &pixelRect); void zoom(const QRectF &pixelRect, const QList &affectedAxes); void setupFullAxesBox(bool connectRanges=false); QList plottables() const; QList graphs() const; QList items() const; // read-only interface imitating a QRect: int left() const { return mRect.left(); } int right() const { return mRect.right(); } int top() const { return mRect.top(); } int bottom() const { return mRect.bottom(); } int width() const { return mRect.width(); } int height() const { return mRect.height(); } QSize size() const { return mRect.size(); } QPoint topLeft() const { return mRect.topLeft(); } QPoint topRight() const { return mRect.topRight(); } QPoint bottomLeft() const { return mRect.bottomLeft(); } QPoint bottomRight() const { return mRect.bottomRight(); } QPoint center() const { return mRect.center(); } // reimplemented virtual methods: virtual void update(UpdatePhase phase) Q_DECL_OVERRIDE; virtual QList elements(bool recursive) const Q_DECL_OVERRIDE; protected: // property members: QBrush mBackgroundBrush; QPixmap mBackgroundPixmap; QPixmap mScaledBackgroundPixmap; bool mBackgroundScaled; Qt::AspectRatioMode mBackgroundScaledMode; QCPLayoutInset *mInsetLayout; Qt::Orientations mRangeDrag, mRangeZoom; QList > mRangeDragHorzAxis, mRangeDragVertAxis; QList > mRangeZoomHorzAxis, mRangeZoomVertAxis; double mRangeZoomFactorHorz, mRangeZoomFactorVert; // non-property members: QList mDragStartHorzRange, mDragStartVertRange; QCP::AntialiasedElements mAADragBackup, mNotAADragBackup; bool mDragging; QHash > mAxes; // reimplemented virtual methods: virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual int calculateAutoMargin(QCP::MarginSide side) Q_DECL_OVERRIDE; virtual void layoutChanged() Q_DECL_OVERRIDE; // events: virtual void mousePressEvent(QMouseEvent *event, const QVariant &details) Q_DECL_OVERRIDE; virtual void mouseMoveEvent(QMouseEvent *event, const QPointF &startPos) Q_DECL_OVERRIDE; virtual void mouseReleaseEvent(QMouseEvent *event, const QPointF &startPos) Q_DECL_OVERRIDE; virtual void wheelEvent(QWheelEvent *event) Q_DECL_OVERRIDE; // non-property methods: void drawBackground(QCPPainter *painter); void updateAxesOffset(QCPAxis::AxisType type); private: Q_DISABLE_COPY(QCPAxisRect) friend class QCustomPlot; }; /* end of 'src/layoutelements/layoutelement-axisrect.h' */ /* including file 'src/layoutelements/layoutelement-legend.h', size 10397 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPAbstractLegendItem : public QCPLayoutElement { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QCPLegend* parentLegend READ parentLegend) Q_PROPERTY(QFont font READ font WRITE setFont) Q_PROPERTY(QColor textColor READ textColor WRITE setTextColor) Q_PROPERTY(QFont selectedFont READ selectedFont WRITE setSelectedFont) Q_PROPERTY(QColor selectedTextColor READ selectedTextColor WRITE setSelectedTextColor) Q_PROPERTY(bool selectable READ selectable WRITE setSelectable NOTIFY selectionChanged) Q_PROPERTY(bool selected READ selected WRITE setSelected NOTIFY selectableChanged) /// \endcond public: explicit QCPAbstractLegendItem(QCPLegend *parent); // getters: QCPLegend *parentLegend() const { return mParentLegend; } QFont font() const { return mFont; } QColor textColor() const { return mTextColor; } QFont selectedFont() const { return mSelectedFont; } QColor selectedTextColor() const { return mSelectedTextColor; } bool selectable() const { return mSelectable; } bool selected() const { return mSelected; } // setters: void setFont(const QFont &font); void setTextColor(const QColor &color); void setSelectedFont(const QFont &font); void setSelectedTextColor(const QColor &color); Q_SLOT void setSelectable(bool selectable); Q_SLOT void setSelected(bool selected); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; signals: void selectionChanged(bool selected); void selectableChanged(bool selectable); protected: // property members: QCPLegend *mParentLegend; QFont mFont; QColor mTextColor; QFont mSelectedFont; QColor mSelectedTextColor; bool mSelectable, mSelected; // reimplemented virtual methods: virtual QCP::Interaction selectionCategory() const Q_DECL_OVERRIDE; virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual QRect clipRect() const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE = 0; // events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged) Q_DECL_OVERRIDE; virtual void deselectEvent(bool *selectionStateChanged) Q_DECL_OVERRIDE; private: Q_DISABLE_COPY(QCPAbstractLegendItem) friend class QCPLegend; }; class QCP_LIB_DECL QCPPlottableLegendItem : public QCPAbstractLegendItem { Q_OBJECT public: QCPPlottableLegendItem(QCPLegend *parent, QCPAbstractPlottable *plottable); // getters: QCPAbstractPlottable *plottable() { return mPlottable; } protected: // property members: QCPAbstractPlottable *mPlottable; // reimplemented virtual methods: virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual QSize minimumOuterSizeHint() const Q_DECL_OVERRIDE; // non-virtual methods: QPen getIconBorderPen() const; QColor getTextColor() const; QFont getFont() const; }; class QCP_LIB_DECL QCPLegend : public QCPLayoutGrid { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QPen borderPen READ borderPen WRITE setBorderPen) Q_PROPERTY(QBrush brush READ brush WRITE setBrush) Q_PROPERTY(QFont font READ font WRITE setFont) Q_PROPERTY(QColor textColor READ textColor WRITE setTextColor) Q_PROPERTY(QSize iconSize READ iconSize WRITE setIconSize) Q_PROPERTY(int iconTextPadding READ iconTextPadding WRITE setIconTextPadding) Q_PROPERTY(QPen iconBorderPen READ iconBorderPen WRITE setIconBorderPen) Q_PROPERTY(SelectableParts selectableParts READ selectableParts WRITE setSelectableParts NOTIFY selectionChanged) Q_PROPERTY(SelectableParts selectedParts READ selectedParts WRITE setSelectedParts NOTIFY selectableChanged) Q_PROPERTY(QPen selectedBorderPen READ selectedBorderPen WRITE setSelectedBorderPen) Q_PROPERTY(QPen selectedIconBorderPen READ selectedIconBorderPen WRITE setSelectedIconBorderPen) Q_PROPERTY(QBrush selectedBrush READ selectedBrush WRITE setSelectedBrush) Q_PROPERTY(QFont selectedFont READ selectedFont WRITE setSelectedFont) Q_PROPERTY(QColor selectedTextColor READ selectedTextColor WRITE setSelectedTextColor) /// \endcond public: /*! Defines the selectable parts of a legend \see setSelectedParts, setSelectableParts */ enum SelectablePart { spNone = 0x000 ///< 0x000 None ,spLegendBox = 0x001 ///< 0x001 The legend box (frame) ,spItems = 0x002 ///< 0x002 Legend items individually (see \ref selectedItems) }; Q_ENUMS(SelectablePart) Q_FLAGS(SelectableParts) Q_DECLARE_FLAGS(SelectableParts, SelectablePart) explicit QCPLegend(); virtual ~QCPLegend(); // getters: QPen borderPen() const { return mBorderPen; } QBrush brush() const { return mBrush; } QFont font() const { return mFont; } QColor textColor() const { return mTextColor; } QSize iconSize() const { return mIconSize; } int iconTextPadding() const { return mIconTextPadding; } QPen iconBorderPen() const { return mIconBorderPen; } SelectableParts selectableParts() const { return mSelectableParts; } SelectableParts selectedParts() const; QPen selectedBorderPen() const { return mSelectedBorderPen; } QPen selectedIconBorderPen() const { return mSelectedIconBorderPen; } QBrush selectedBrush() const { return mSelectedBrush; } QFont selectedFont() const { return mSelectedFont; } QColor selectedTextColor() const { return mSelectedTextColor; } // setters: void setBorderPen(const QPen &pen); void setBrush(const QBrush &brush); void setFont(const QFont &font); void setTextColor(const QColor &color); void setIconSize(const QSize &size); void setIconSize(int width, int height); void setIconTextPadding(int padding); void setIconBorderPen(const QPen &pen); Q_SLOT void setSelectableParts(const SelectableParts &selectableParts); Q_SLOT void setSelectedParts(const SelectableParts &selectedParts); void setSelectedBorderPen(const QPen &pen); void setSelectedIconBorderPen(const QPen &pen); void setSelectedBrush(const QBrush &brush); void setSelectedFont(const QFont &font); void setSelectedTextColor(const QColor &color); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; // non-virtual methods: QCPAbstractLegendItem *item(int index) const; QCPPlottableLegendItem *itemWithPlottable(const QCPAbstractPlottable *plottable) const; int itemCount() const; bool hasItem(QCPAbstractLegendItem *item) const; bool hasItemWithPlottable(const QCPAbstractPlottable *plottable) const; bool addItem(QCPAbstractLegendItem *item); bool removeItem(int index); bool removeItem(QCPAbstractLegendItem *item); void clearItems(); QList selectedItems() const; signals: void selectionChanged(QCPLegend::SelectableParts parts); void selectableChanged(QCPLegend::SelectableParts parts); protected: // property members: QPen mBorderPen, mIconBorderPen; QBrush mBrush; QFont mFont; QColor mTextColor; QSize mIconSize; int mIconTextPadding; SelectableParts mSelectedParts, mSelectableParts; QPen mSelectedBorderPen, mSelectedIconBorderPen; QBrush mSelectedBrush; QFont mSelectedFont; QColor mSelectedTextColor; // reimplemented virtual methods: virtual void parentPlotInitialized(QCustomPlot *parentPlot) Q_DECL_OVERRIDE; virtual QCP::Interaction selectionCategory() const Q_DECL_OVERRIDE; virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; // events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged) Q_DECL_OVERRIDE; virtual void deselectEvent(bool *selectionStateChanged) Q_DECL_OVERRIDE; // non-virtual methods: QPen getBorderPen() const; QBrush getBrush() const; private: Q_DISABLE_COPY(QCPLegend) friend class QCustomPlot; friend class QCPAbstractLegendItem; }; Q_DECLARE_OPERATORS_FOR_FLAGS(QCPLegend::SelectableParts) Q_DECLARE_METATYPE(QCPLegend::SelectablePart) /* end of 'src/layoutelements/layoutelement-legend.h' */ /* including file 'src/layoutelements/layoutelement-textelement.h', size 5353 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPTextElement : public QCPLayoutElement { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QString text READ text WRITE setText) Q_PROPERTY(QFont font READ font WRITE setFont) Q_PROPERTY(QColor textColor READ textColor WRITE setTextColor) Q_PROPERTY(QFont selectedFont READ selectedFont WRITE setSelectedFont) Q_PROPERTY(QColor selectedTextColor READ selectedTextColor WRITE setSelectedTextColor) Q_PROPERTY(bool selectable READ selectable WRITE setSelectable NOTIFY selectableChanged) Q_PROPERTY(bool selected READ selected WRITE setSelected NOTIFY selectionChanged) /// \endcond public: explicit QCPTextElement(QCustomPlot *parentPlot); QCPTextElement(QCustomPlot *parentPlot, const QString &text); QCPTextElement(QCustomPlot *parentPlot, const QString &text, double pointSize); QCPTextElement(QCustomPlot *parentPlot, const QString &text, const QString &fontFamily, double pointSize); QCPTextElement(QCustomPlot *parentPlot, const QString &text, const QFont &font); // getters: QString text() const { return mText; } int textFlags() const { return mTextFlags; } QFont font() const { return mFont; } QColor textColor() const { return mTextColor; } QFont selectedFont() const { return mSelectedFont; } QColor selectedTextColor() const { return mSelectedTextColor; } bool selectable() const { return mSelectable; } bool selected() const { return mSelected; } // setters: void setText(const QString &text); void setTextFlags(int flags); void setFont(const QFont &font); void setTextColor(const QColor &color); void setSelectedFont(const QFont &font); void setSelectedTextColor(const QColor &color); Q_SLOT void setSelectable(bool selectable); Q_SLOT void setSelected(bool selected); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; virtual void mousePressEvent(QMouseEvent *event, const QVariant &details) Q_DECL_OVERRIDE; virtual void mouseReleaseEvent(QMouseEvent *event, const QPointF &startPos) Q_DECL_OVERRIDE; virtual void mouseDoubleClickEvent(QMouseEvent *event, const QVariant &details) Q_DECL_OVERRIDE; signals: void selectionChanged(bool selected); void selectableChanged(bool selectable); void clicked(QMouseEvent *event); void doubleClicked(QMouseEvent *event); protected: // property members: QString mText; int mTextFlags; QFont mFont; QColor mTextColor; QFont mSelectedFont; QColor mSelectedTextColor; QRect mTextBoundingRect; bool mSelectable, mSelected; // reimplemented virtual methods: virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual QSize minimumOuterSizeHint() const Q_DECL_OVERRIDE; virtual QSize maximumOuterSizeHint() const Q_DECL_OVERRIDE; // events: virtual void selectEvent(QMouseEvent *event, bool additive, const QVariant &details, bool *selectionStateChanged) Q_DECL_OVERRIDE; virtual void deselectEvent(bool *selectionStateChanged) Q_DECL_OVERRIDE; // non-virtual methods: QFont mainFont() const; QColor mainTextColor() const; private: Q_DISABLE_COPY(QCPTextElement) }; /* end of 'src/layoutelements/layoutelement-textelement.h' */ /* including file 'src/layoutelements/layoutelement-colorscale.h', size 5923 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCPColorScaleAxisRectPrivate : public QCPAxisRect { Q_OBJECT public: explicit QCPColorScaleAxisRectPrivate(QCPColorScale *parentColorScale); protected: QCPColorScale *mParentColorScale; QImage mGradientImage; bool mGradientImageInvalidated; // re-using some methods of QCPAxisRect to make them available to friend class QCPColorScale using QCPAxisRect::calculateAutoMargin; using QCPAxisRect::mousePressEvent; using QCPAxisRect::mouseMoveEvent; using QCPAxisRect::mouseReleaseEvent; using QCPAxisRect::wheelEvent; using QCPAxisRect::update; virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; void updateGradientImage(); Q_SLOT void axisSelectionChanged(QCPAxis::SelectableParts selectedParts); Q_SLOT void axisSelectableChanged(QCPAxis::SelectableParts selectableParts); friend class QCPColorScale; }; class QCP_LIB_DECL QCPColorScale : public QCPLayoutElement { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QCPAxis::AxisType type READ type WRITE setType) Q_PROPERTY(QCPRange dataRange READ dataRange WRITE setDataRange NOTIFY dataRangeChanged) Q_PROPERTY(QCPAxis::ScaleType dataScaleType READ dataScaleType WRITE setDataScaleType NOTIFY dataScaleTypeChanged) Q_PROPERTY(QCPColorGradient gradient READ gradient WRITE setGradient NOTIFY gradientChanged) Q_PROPERTY(QString label READ label WRITE setLabel) Q_PROPERTY(int barWidth READ barWidth WRITE setBarWidth) Q_PROPERTY(bool rangeDrag READ rangeDrag WRITE setRangeDrag) Q_PROPERTY(bool rangeZoom READ rangeZoom WRITE setRangeZoom) /// \endcond public: explicit QCPColorScale(QCustomPlot *parentPlot); virtual ~QCPColorScale(); // getters: QCPAxis *axis() const { return mColorAxis.data(); } QCPAxis::AxisType type() const { return mType; } QCPRange dataRange() const { return mDataRange; } QCPAxis::ScaleType dataScaleType() const { return mDataScaleType; } QCPColorGradient gradient() const { return mGradient; } QString label() const; int barWidth () const { return mBarWidth; } bool rangeDrag() const; bool rangeZoom() const; // setters: void setType(QCPAxis::AxisType type); Q_SLOT void setDataRange(const QCPRange &dataRange); Q_SLOT void setDataScaleType(QCPAxis::ScaleType scaleType); Q_SLOT void setGradient(const QCPColorGradient &gradient); void setLabel(const QString &str); void setBarWidth(int width); void setRangeDrag(bool enabled); void setRangeZoom(bool enabled); // non-property methods: QList colorMaps() const; void rescaleDataRange(bool onlyVisibleMaps); // reimplemented virtual methods: virtual void update(UpdatePhase phase) Q_DECL_OVERRIDE; signals: void dataRangeChanged(const QCPRange &newRange); void dataScaleTypeChanged(QCPAxis::ScaleType scaleType); void gradientChanged(const QCPColorGradient &newGradient); protected: // property members: QCPAxis::AxisType mType; QCPRange mDataRange; QCPAxis::ScaleType mDataScaleType; QCPColorGradient mGradient; int mBarWidth; // non-property members: QPointer mAxisRect; QPointer mColorAxis; // reimplemented virtual methods: virtual void applyDefaultAntialiasingHint(QCPPainter *painter) const Q_DECL_OVERRIDE; // events: virtual void mousePressEvent(QMouseEvent *event, const QVariant &details) Q_DECL_OVERRIDE; virtual void mouseMoveEvent(QMouseEvent *event, const QPointF &startPos) Q_DECL_OVERRIDE; virtual void mouseReleaseEvent(QMouseEvent *event, const QPointF &startPos) Q_DECL_OVERRIDE; virtual void wheelEvent(QWheelEvent *event) Q_DECL_OVERRIDE; private: Q_DISABLE_COPY(QCPColorScale) friend class QCPColorScaleAxisRectPrivate; }; /* end of 'src/layoutelements/layoutelement-colorscale.h' */ /* including file 'src/plottables/plottable-graph.h', size 9294 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPGraphData { public: QCPGraphData(); QCPGraphData(double key, double value); inline double sortKey() const { return key; } inline static QCPGraphData fromSortKey(double sortKey) { return QCPGraphData(sortKey, 0); } inline static bool sortKeyIsMainKey() { return true; } inline double mainKey() const { return key; } inline double mainValue() const { return value; } inline QCPRange valueRange() const { return QCPRange(value, value); } double key, value; }; Q_DECLARE_TYPEINFO(QCPGraphData, Q_PRIMITIVE_TYPE); /*! \typedef QCPGraphDataContainer Container for storing \ref QCPGraphData points. The data is stored sorted by \a key. This template instantiation is the container in which QCPGraph holds its data. For details about the generic container, see the documentation of the class template \ref QCPDataContainer. \see QCPGraphData, QCPGraph::setData */ typedef QCPDataContainer QCPGraphDataContainer; class QCP_LIB_DECL QCPGraph : public QCPAbstractPlottable1D { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(LineStyle lineStyle READ lineStyle WRITE setLineStyle) Q_PROPERTY(QCPScatterStyle scatterStyle READ scatterStyle WRITE setScatterStyle) Q_PROPERTY(int scatterSkip READ scatterSkip WRITE setScatterSkip) Q_PROPERTY(QCPGraph* channelFillGraph READ channelFillGraph WRITE setChannelFillGraph) Q_PROPERTY(bool adaptiveSampling READ adaptiveSampling WRITE setAdaptiveSampling) /// \endcond public: /*! Defines how the graph's line is represented visually in the plot. The line is drawn with the current pen of the graph (\ref setPen). \see setLineStyle */ enum LineStyle { lsNone ///< data points are not connected with any lines (e.g. data only represented ///< with symbols according to the scatter style, see \ref setScatterStyle) ,lsLine ///< data points are connected by a straight line ,lsStepLeft ///< line is drawn as steps where the step height is the value of the left data point ,lsStepRight ///< line is drawn as steps where the step height is the value of the right data point ,lsStepCenter ///< line is drawn as steps where the step is in between two data points ,lsImpulse ///< each data point is represented by a line parallel to the value axis, which reaches from the data point to the zero-value-line }; Q_ENUMS(LineStyle) explicit QCPGraph(QCPAxis *keyAxis, QCPAxis *valueAxis); virtual ~QCPGraph(); // getters: QSharedPointer data() const { return mDataContainer; } LineStyle lineStyle() const { return mLineStyle; } QCPScatterStyle scatterStyle() const { return mScatterStyle; } int scatterSkip() const { return mScatterSkip; } QCPGraph *channelFillGraph() const { return mChannelFillGraph.data(); } bool adaptiveSampling() const { return mAdaptiveSampling; } // setters: void setData(QSharedPointer data); void setData(const QVector &keys, const QVector &values, bool alreadySorted=false); void setLineStyle(LineStyle ls); void setScatterStyle(const QCPScatterStyle &style); void setScatterSkip(int skip); void setChannelFillGraph(QCPGraph *targetGraph); void setAdaptiveSampling(bool enabled); // non-property methods: void addData(const QVector &keys, const QVector &values, bool alreadySorted=false); void addData(double key, double value); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; virtual QCPRange getKeyRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth) const Q_DECL_OVERRIDE; virtual QCPRange getValueRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth, const QCPRange &inKeyRange=QCPRange()) const Q_DECL_OVERRIDE; protected: // property members: LineStyle mLineStyle; QCPScatterStyle mScatterStyle; int mScatterSkip; QPointer mChannelFillGraph; bool mAdaptiveSampling; // reimplemented virtual methods: virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual void drawLegendIcon(QCPPainter *painter, const QRectF &rect) const Q_DECL_OVERRIDE; // introduced virtual methods: virtual void drawFill(QCPPainter *painter, QVector *lines) const; virtual void drawScatterPlot(QCPPainter *painter, const QVector &scatters, const QCPScatterStyle &style) const; virtual void drawLinePlot(QCPPainter *painter, const QVector &lines) const; virtual void drawImpulsePlot(QCPPainter *painter, const QVector &lines) const; virtual void getOptimizedLineData(QVector *lineData, const QCPGraphDataContainer::const_iterator &begin, const QCPGraphDataContainer::const_iterator &end) const; virtual void getOptimizedScatterData(QVector *scatterData, QCPGraphDataContainer::const_iterator begin, QCPGraphDataContainer::const_iterator end) const; // non-virtual methods: void getVisibleDataBounds(QCPGraphDataContainer::const_iterator &begin, QCPGraphDataContainer::const_iterator &end, const QCPDataRange &rangeRestriction) const; void getLines(QVector *lines, const QCPDataRange &dataRange) const; void getScatters(QVector *scatters, const QCPDataRange &dataRange) const; QVector dataToLines(const QVector &data) const; QVector dataToStepLeftLines(const QVector &data) const; QVector dataToStepRightLines(const QVector &data) const; QVector dataToStepCenterLines(const QVector &data) const; QVector dataToImpulseLines(const QVector &data) const; QVector getNonNanSegments(const QVector *lineData, Qt::Orientation keyOrientation) const; QVector > getOverlappingSegments(QVector thisSegments, const QVector *thisData, QVector otherSegments, const QVector *otherData) const; bool segmentsIntersect(double aLower, double aUpper, double bLower, double bUpper, int &bPrecedence) const; QPointF getFillBasePoint(QPointF matchingDataPoint) const; const QPolygonF getFillPolygon(const QVector *lineData, QCPDataRange segment) const; const QPolygonF getChannelFillPolygon(const QVector *lineData, QCPDataRange thisSegment, const QVector *otherData, QCPDataRange otherSegment) const; int findIndexBelowX(const QVector *data, double x) const; int findIndexAboveX(const QVector *data, double x) const; int findIndexBelowY(const QVector *data, double y) const; int findIndexAboveY(const QVector *data, double y) const; double pointDistance(const QPointF &pixelPoint, QCPGraphDataContainer::const_iterator &closestData) const; friend class QCustomPlot; friend class QCPLegend; }; Q_DECLARE_METATYPE(QCPGraph::LineStyle) /* end of 'src/plottables/plottable-graph.h' */ /* including file 'src/plottables/plottable-curve.h', size 7409 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPCurveData { public: QCPCurveData(); QCPCurveData(double t, double key, double value); inline double sortKey() const { return t; } inline static QCPCurveData fromSortKey(double sortKey) { return QCPCurveData(sortKey, 0, 0); } inline static bool sortKeyIsMainKey() { return false; } inline double mainKey() const { return key; } inline double mainValue() const { return value; } inline QCPRange valueRange() const { return QCPRange(value, value); } double t, key, value; }; Q_DECLARE_TYPEINFO(QCPCurveData, Q_PRIMITIVE_TYPE); /*! \typedef QCPCurveDataContainer Container for storing \ref QCPCurveData points. The data is stored sorted by \a t, so the \a sortKey() (returning \a t) is different from \a mainKey() (returning \a key). This template instantiation is the container in which QCPCurve holds its data. For details about the generic container, see the documentation of the class template \ref QCPDataContainer. \see QCPCurveData, QCPCurve::setData */ typedef QCPDataContainer QCPCurveDataContainer; class QCP_LIB_DECL QCPCurve : public QCPAbstractPlottable1D { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(QCPScatterStyle scatterStyle READ scatterStyle WRITE setScatterStyle) Q_PROPERTY(int scatterSkip READ scatterSkip WRITE setScatterSkip) Q_PROPERTY(LineStyle lineStyle READ lineStyle WRITE setLineStyle) /// \endcond public: /*! Defines how the curve's line is represented visually in the plot. The line is drawn with the current pen of the curve (\ref setPen). \see setLineStyle */ enum LineStyle { lsNone ///< No line is drawn between data points (e.g. only scatters) ,lsLine ///< Data points are connected with a straight line }; Q_ENUMS(LineStyle) explicit QCPCurve(QCPAxis *keyAxis, QCPAxis *valueAxis); virtual ~QCPCurve(); // getters: QSharedPointer data() const { return mDataContainer; } QCPScatterStyle scatterStyle() const { return mScatterStyle; } int scatterSkip() const { return mScatterSkip; } LineStyle lineStyle() const { return mLineStyle; } // setters: void setData(QSharedPointer data); void setData(const QVector &t, const QVector &keys, const QVector &values, bool alreadySorted=false); void setData(const QVector &keys, const QVector &values); void setScatterStyle(const QCPScatterStyle &style); void setScatterSkip(int skip); void setLineStyle(LineStyle style); // non-property methods: void addData(const QVector &t, const QVector &keys, const QVector &values, bool alreadySorted=false); void addData(const QVector &keys, const QVector &values); void addData(double t, double key, double value); void addData(double key, double value); // reimplemented virtual methods: virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; virtual QCPRange getKeyRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth) const Q_DECL_OVERRIDE; virtual QCPRange getValueRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth, const QCPRange &inKeyRange=QCPRange()) const Q_DECL_OVERRIDE; protected: // property members: QCPScatterStyle mScatterStyle; int mScatterSkip; LineStyle mLineStyle; // reimplemented virtual methods: virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual void drawLegendIcon(QCPPainter *painter, const QRectF &rect) const Q_DECL_OVERRIDE; // introduced virtual methods: virtual void drawCurveLine(QCPPainter *painter, const QVector &lines) const; virtual void drawScatterPlot(QCPPainter *painter, const QVector &points, const QCPScatterStyle &style) const; // non-virtual methods: void getCurveLines(QVector *lines, const QCPDataRange &dataRange, double penWidth) const; void getScatters(QVector *scatters, const QCPDataRange &dataRange, double scatterWidth) const; int getRegion(double key, double value, double keyMin, double valueMax, double keyMax, double valueMin) const; QPointF getOptimizedPoint(int prevRegion, double prevKey, double prevValue, double key, double value, double keyMin, double valueMax, double keyMax, double valueMin) const; QVector getOptimizedCornerPoints(int prevRegion, int currentRegion, double prevKey, double prevValue, double key, double value, double keyMin, double valueMax, double keyMax, double valueMin) const; bool mayTraverse(int prevRegion, int currentRegion) const; bool getTraverse(double prevKey, double prevValue, double key, double value, double keyMin, double valueMax, double keyMax, double valueMin, QPointF &crossA, QPointF &crossB) const; void getTraverseCornerPoints(int prevRegion, int currentRegion, double keyMin, double valueMax, double keyMax, double valueMin, QVector &beforeTraverse, QVector &afterTraverse) const; double pointDistance(const QPointF &pixelPoint, QCPCurveDataContainer::const_iterator &closestData) const; friend class QCustomPlot; friend class QCPLegend; }; Q_DECLARE_METATYPE(QCPCurve::LineStyle) /* end of 'src/plottables/plottable-curve.h' */ /* including file 'src/plottables/plottable-bars.h', size 8924 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPBarsGroup : public QObject { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(SpacingType spacingType READ spacingType WRITE setSpacingType) Q_PROPERTY(double spacing READ spacing WRITE setSpacing) /// \endcond public: /*! Defines the ways the spacing between bars in the group can be specified. Thus it defines what the number passed to \ref setSpacing actually means. \see setSpacingType, setSpacing */ enum SpacingType { stAbsolute ///< Bar spacing is in absolute pixels ,stAxisRectRatio ///< Bar spacing is given by a fraction of the axis rect size ,stPlotCoords ///< Bar spacing is in key coordinates and thus scales with the key axis range }; Q_ENUMS(SpacingType) QCPBarsGroup(QCustomPlot *parentPlot); virtual ~QCPBarsGroup(); // getters: SpacingType spacingType() const { return mSpacingType; } double spacing() const { return mSpacing; } // setters: void setSpacingType(SpacingType spacingType); void setSpacing(double spacing); // non-virtual methods: QList bars() const { return mBars; } QCPBars* bars(int index) const; int size() const { return mBars.size(); } bool isEmpty() const { return mBars.isEmpty(); } void clear(); bool contains(QCPBars *bars) const { return mBars.contains(bars); } void append(QCPBars *bars); void insert(int i, QCPBars *bars); void remove(QCPBars *bars); protected: // non-property members: QCustomPlot *mParentPlot; SpacingType mSpacingType; double mSpacing; QList mBars; // non-virtual methods: void registerBars(QCPBars *bars); void unregisterBars(QCPBars *bars); // virtual methods: double keyPixelOffset(const QCPBars *bars, double keyCoord); double getPixelSpacing(const QCPBars *bars, double keyCoord); private: Q_DISABLE_COPY(QCPBarsGroup) friend class QCPBars; }; Q_DECLARE_METATYPE(QCPBarsGroup::SpacingType) class QCP_LIB_DECL QCPBarsData { public: QCPBarsData(); QCPBarsData(double key, double value); inline double sortKey() const { return key; } inline static QCPBarsData fromSortKey(double sortKey) { return QCPBarsData(sortKey, 0); } inline static bool sortKeyIsMainKey() { return true; } inline double mainKey() const { return key; } inline double mainValue() const { return value; } inline QCPRange valueRange() const { return QCPRange(value, value); } // note that bar base value isn't held in each QCPBarsData and thus can't/shouldn't be returned here double key, value; }; Q_DECLARE_TYPEINFO(QCPBarsData, Q_PRIMITIVE_TYPE); /*! \typedef QCPBarsDataContainer Container for storing \ref QCPBarsData points. The data is stored sorted by \a key. This template instantiation is the container in which QCPBars holds its data. For details about the generic container, see the documentation of the class template \ref QCPDataContainer. \see QCPBarsData, QCPBars::setData */ typedef QCPDataContainer QCPBarsDataContainer; class QCP_LIB_DECL QCPBars : public QCPAbstractPlottable1D { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(double width READ width WRITE setWidth) Q_PROPERTY(WidthType widthType READ widthType WRITE setWidthType) Q_PROPERTY(QCPBarsGroup* barsGroup READ barsGroup WRITE setBarsGroup) Q_PROPERTY(double baseValue READ baseValue WRITE setBaseValue) Q_PROPERTY(double stackingGap READ stackingGap WRITE setStackingGap) Q_PROPERTY(QCPBars* barBelow READ barBelow) Q_PROPERTY(QCPBars* barAbove READ barAbove) /// \endcond public: /*! Defines the ways the width of the bar can be specified. Thus it defines what the number passed to \ref setWidth actually means. \see setWidthType, setWidth */ enum WidthType { wtAbsolute ///< Bar width is in absolute pixels ,wtAxisRectRatio ///< Bar width is given by a fraction of the axis rect size ,wtPlotCoords ///< Bar width is in key coordinates and thus scales with the key axis range }; Q_ENUMS(WidthType) explicit QCPBars(QCPAxis *keyAxis, QCPAxis *valueAxis); virtual ~QCPBars(); // getters: double width() const { return mWidth; } WidthType widthType() const { return mWidthType; } QCPBarsGroup *barsGroup() const { return mBarsGroup; } double baseValue() const { return mBaseValue; } double stackingGap() const { return mStackingGap; } QCPBars *barBelow() const { return mBarBelow.data(); } QCPBars *barAbove() const { return mBarAbove.data(); } QSharedPointer data() const { return mDataContainer; } // setters: void setData(QSharedPointer data); void setData(const QVector &keys, const QVector &values, bool alreadySorted=false); void setWidth(double width); void setWidthType(WidthType widthType); void setBarsGroup(QCPBarsGroup *barsGroup); void setBaseValue(double baseValue); void setStackingGap(double pixels); // non-property methods: void addData(const QVector &keys, const QVector &values, bool alreadySorted=false); void addData(double key, double value); void moveBelow(QCPBars *bars); void moveAbove(QCPBars *bars); // reimplemented virtual methods: virtual QCPDataSelection selectTestRect(const QRectF &rect, bool onlySelectable) const Q_DECL_OVERRIDE; virtual double selectTest(const QPointF &pos, bool onlySelectable, QVariant *details=0) const Q_DECL_OVERRIDE; virtual QCPRange getKeyRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth) const Q_DECL_OVERRIDE; virtual QCPRange getValueRange(bool &foundRange, QCP::SignDomain inSignDomain=QCP::sdBoth, const QCPRange &inKeyRange=QCPRange()) const Q_DECL_OVERRIDE; virtual QPointF dataPixelPosition(int index) const Q_DECL_OVERRIDE; protected: // property members: double mWidth; WidthType mWidthType; QCPBarsGroup *mBarsGroup; double mBaseValue; double mStackingGap; QPointer mBarBelow, mBarAbove; // reimplemented virtual methods: virtual void draw(QCPPainter *painter) Q_DECL_OVERRIDE; virtual void drawLegendIcon(QCPPainter *painter, const QRectF &rect) const Q_DECL_OVERRIDE; // non-virtual methods: void getVisibleDataBounds(QCPBarsDataContainer::const_iterator &begin, QCPBarsDataContainer::const_iterator &end) const; QRectF getBarRect(double key, double value) const; void getPixelWidth(double key, double &lower, double &upper) const; double getStackedBaseValue(double key, bool positive) const; static void connectBars(QCPBars* lower, QCPBars* upper); friend class QCustomPlot; friend class QCPLegend; friend class QCPBarsGroup; }; Q_DECLARE_METATYPE(QCPBars::WidthType) /* end of 'src/plottables/plottable-bars.h' */ /* including file 'src/plottables/plottable-statisticalbox.h', size 7516 */ /* commit 9868e55d3b412f2f89766bb482fcf299e93a0988 2017-09-04 01:56:22 +0200 */ class QCP_LIB_DECL QCPStatisticalBoxData { public: QCPStatisticalBoxData(); QCPStatisticalBoxData(double key, double minimum, double lowerQuartile, double median, double upperQuartile, double maximum, const QVector& outliers=QVector()); inline double sortKey() const { return key; } inline static QCPStatisticalBoxData fromSortKey(double sortKey) { return QCPStatisticalBoxData(sortKey, 0, 0, 0, 0, 0); } inline static bool sortKeyIsMainKey() { return true; } inline double mainKey() const { return key; } inline double mainValue() const { return median; } inline QCPRange valueRange() const { QCPRange result(minimum, maximum); for (QVector::const_iterator it = outliers.constBegin(); it != outliers.constEnd(); ++it) result.expand(*it); return result; } double key, minimum, lowerQuartile, median, upperQuartile, maximum; QVector outliers; }; Q_DECLARE_TYPEINFO(QCPStatisticalBoxData, Q_MOVABLE_TYPE); /*! \typedef QCPStatisticalBoxDataContainer Container for storing \ref QCPStatisticalBoxData points. The data is stored sorted by \a key. This template instantiation is the container in which QCPStatisticalBox holds its data. For details about the generic container, see the documentation of the class template \ref QCPDataContainer. \see QCPStatisticalBoxData, QCPStatisticalBox::setData */ typedef QCPDataContainer QCPStatisticalBoxDataContainer; class QCP_LIB_DECL QCPStatisticalBox : public QCPAbstractPlottable1D { Q_OBJECT /// \cond INCLUDE_QPROPERTIES Q_PROPERTY(double width READ width WRITE setWidth) Q_PROPERTY(double whiskerWidth READ whiskerWidth WRITE setWhiskerWidth) Q_PROPERTY(QPen whiskerPen READ whiskerPen WRITE setWhiskerPen) Q_PROPERTY(QPen whiskerBarPen READ whiskerBarPen WRITE setWhiskerBarPen) Q_PROPERTY(bool whiskerAntialiased READ whiskerAntialiased WRITE setWhiskerAntialiased) Q_PROPERTY(QPen medianPen READ medianPen WRITE setMedianPen) Q_PROPERTY(QCPScatterStyle outlierStyle READ outlierStyle WRITE setOutlierStyle) /// \endcond public: explicit QCPStatisticalBox(QCPAxis *keyAxis, QCPAxis *valueAxis); // getters: QSharedPointer data() const { return mDataContainer; } double width() const { return mWidth; } double whiskerWidth() const { return mWhiskerWidth; } QPen whiskerPen() const { return mWhiskerPen; } QPen whiskerBarPen() const { return mWhiskerBarPen; } bool whiskerAntialiased() const { return mWhiskerAntialiased; } QPen medianPen() const { return mMedianPen; } QCPScatterStyle outlierStyle() const { return mOutlierStyle; } // setters: void setData(QSharedPointer