Surface Example#

Using Q3DSurface in a widget application.

The surface example shows how to make a simple 3D surface graph using Q3DSurface and combining the use of widgets for adjusting several adjustable qualities. This example demonstrates the following features:

  • How to set up a basic QSurfaceDataProxy and set data for it.

  • How to use QHeightMapSurfaceDataProxy for showing 3D height maps.

  • Three different selection modes for studying the graph.

  • Axis range usage for displaying selected portions of the graph.

  • Changing theme.

  • How to set a custom surface gradient.

For instructions about how to interact with the graph, see this page .


Running the Example#

To run the example from Qt Creator, open the Welcome mode and select the example from Examples. For more information, visit Building and Running an Example.

Creating the Application#

First, in main.cpp, we create a QApplication , instantiate Q3DSurface , and a window container for it:

app = QApplication([])
graph = Q3DSurface()
container = QWidget.createWindowContainer(graph)

The call to createWindowContainer is required, as all data visualization graph classes ( Q3DBars , Q3DScatter , and Q3DSurface ) inherit QWindow . Any class inheriting QWindow cannot be used as a widget any other way.

Then we’ll create horizontal and vertical layouts. We’ll add the graph with the container and the vertical layout into the horizontal one:

widget = QWidget()
hLayout = QHBoxLayout(widget)
vLayout = QVBoxLayout()
hLayout.addWidget(container, 1)

The rest of the code in main.cpp is creating control widgets for features in Q3DSurface . We have separated code for changing these features into surfacegraph.cpp and only connect signals from widgets into methods in surfacegraph.cpp. Next chapter explains more about using Q3DSurface .

Setting up Proxies and Data#

First we instantiate a new QSurfaceDataProxy and attach it to a new QSurface3DSeries :

m_sqrtSinProxy = QSurfaceDataProxy()
m_sqrtSinSeries = QSurface3DSeries(m_sqrtSinProxy)

Then we fill the proxy with a simple square root and sine wave data. This is done by creating a new QSurfaceDataArray instance and adding QSurfaceDataRow elements to it. The created QSurfaceDataArray is set to be the data array for the QSurfaceDataProxy .

def fillSqrtSinProxy(self):

    stepX = (sampleMax - sampleMin) / float(sampleCountX - 1)
    stepZ = (sampleMax - sampleMin) / float(sampleCountZ - 1)
    dataArray = QSurfaceDataArray()
    for i in range(0, sampleCountZ ):
        newRow = QSurfaceDataRow(sampleCountX)
        # Keep values within range bounds, since just adding step can cause minor drift due
        # to the rounding errors.
        z = qMin(sampleMax, (i * stepZ + sampleMin))
        index = 0
        for j in range(0, sampleCountX):
            x = qMin(sampleMax, (j * stepX + sampleMin))
            R = qSqrt(z * z + x * x) + 0.01f
            y = (qSin(R) / R + 0.24f) * 1.61f
            (newRow)[index++].setPosition(QVector3D(x, y, z))

        dataArray << newRow


The height map is created by instantiating a QHeightMapSurfaceDataProxy with a QImage containing the height data. The method setValueRanges() is used to define the value range of the map. In our example the map is from imaginary position of 34.0° N - 40.0° N and 18.0° E - 24.0° E. These values are used to show and position the map to the axis.

heightMapImage = QImage(":/maps/mountain")
m_heightMapProxy = QHeightMapSurfaceDataProxy(heightMapImage)
m_heightMapSeries = QSurface3DSeries(m_heightMapProxy)
m_heightMapSeries.setItemLabelFormat(QStringLiteral("(@xLabel, @zLabel): @yLabel"))
m_heightMapProxy.setValueRanges(34.0f, 40.0f, 18.0f, 24.0f)

For demonstrating different proxies this example has two radio buttons which the user can use to switch between the series. When the user selects the Sqrt & Sin radio button, the selected series is activated with the following code. First we set the decorative issues like enable the grid for the surface and select the flat shading mode. Next lines define the axis label format and value ranges. Automatic label rotation is set to improve label readability at low camera angles. Finally we make sure the correct series is added to the graph:

m_graph.axisX().setRange(sampleMin, sampleMax)
m_graph.axisY().setRange(0.0f, 2.0f)
m_graph.axisZ().setRange(sampleMin, sampleMax)

When the Height Map radio button is activated, the following code sets the correct series active. The axis label format is set to show N and E letters and ranges are set to the imaginary coordinates. Auto adjusting Y-axis range is fine for our height map surface, so we ensure it is set.

m_graph.axisX().setLabelFormat("%.1f N")
m_graph.axisZ().setLabelFormat("%.1f E")
m_graph.axisX().setRange(34.0f, 40.0f)
m_graph.axisZ().setRange(18.0f, 24.0f)

Selection Modes#

Q3Dsurface supports three different selection modes. These are demonstrated in the example with radio buttons, which the user can use to activate a suitable selection mode. The following inline methods are connected to radio buttons to activate the selected mode.

def toggleModeNone(m_graph.setSelectionMode(QAbstract3DGraph.SelectionNone):
def toggleModeItem(m_graph.setSelectionMode(QAbstract3DGraph.SelectionItem):
def toggleModeSliceRow():
                                                      | QAbstract3DGraph.SelectionSlice); }
def toggleModeSliceColumn():
                                                         | QAbstract3DGraph.SelectionSlice); }

Axis Ranges for Studying the Graph#

The example has four slider controls for adjusting the min and max values for X and Z axis. When selecting the proxy these sliders are adjusted so that one step on the slider moves the range by one segment step:

# Reset range sliders for Sqrt&Sin
m_rangeMinX = sampleMin
m_rangeMinZ = sampleMin
m_stepX = (sampleMax - sampleMin) / float(sampleCountX - 1)
m_stepZ = (sampleMax - sampleMin) / float(sampleCountZ - 1)
m_axisMinSliderX.setMaximum(sampleCountX - 2)
m_axisMaxSliderX.setMaximum(sampleCountX - 1)
m_axisMaxSliderX.setValue(sampleCountX - 1)
m_axisMinSliderZ.setMaximum(sampleCountZ - 2)
m_axisMaxSliderZ.setMaximum(sampleCountZ - 1)
m_axisMaxSliderZ.setValue(sampleCountZ - 1)

The ranges are set for the axes like this:

def setAxisXRange(self, min, max):

    m_graph.axisX().setRange(min, max)

def setAxisZRange(self, min, max):

    m_graph.axisZ().setRange(min, max)


Q3DSurface supports all the themes Qt Data Visualization has. The example has a pull down menu for selecting the theme. The following method is connected to the menu to activate the selected theme. The theme type is changed to another predefined theme, which overwrites all theme properties to predefined values:

def changeTheme(self, theme):


Custom Surface Gradients#

The example demonstrates the custom surface gradients with two push buttons. The gradient can be defined with QLinearGradient where the desired colors are set to positions. The following code shows how to create an example gradient and set it to the series. Note that you also need to change the color style to ColorStyleRangeGradient to actually use the gradient.

gr = QLinearGradient()
gr.setColorAt(1.0, Qt.yellow)

Example project @