Simple Scatter Graph

Using Scatter3D in a QML application.

Simple Scatter Graph shows how to make a simple scatter graph visualization using Scatter3D and QML.

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

For instructions on how to create a new Qt Quick application of your own, see Qt Creator help.

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.

Setting up the Layout

Before diving into the QML code, main.cpp sets up the application. The main.qml file is read from resource (qrc:)

 viewer.setSource(QUrl("qrc:/qml/scatter/main.qml"));

This main.qml file is the starting point for the application's QML code. Firstly, import all the required QML modules:

 import QtQuick
 import QtQuick.Controls
 import QtQuick.Layouts
 import QtGraphs

Then, create a Data item which will be the item that holds the data for the graph.

 Data {
     id: seriesData
 }

Next, create two Theme3D items that define two different themes for the graph, a Qt theme and a retro theme.

 Theme3D {
     id: themeQt
     type: Theme3D.Theme.Qt
     font.pointSize: 40
 }

 Theme3D {
     id: themeRetro
     type: Theme3D.Theme.Retro
 }

The layout for this application is going to consist of five different buttons to toggle different visual options for the graph on and off, and of course the graph itself. There are many ways to organize these, one way is to have a GridLayout containing four buttons, the Graph, and the fifth button, all appearing in a ColumnLayout.

 ColumnLayout {
     id: mainLayout
     anchors.fill: parent
     anchors.margins: margin
     spacing: spacing

The GridLayout is responsive. What this means is that the number of columns used depend on the width of the application window. This is done by assigning the columns property a ternary operator, resolving to either 1, 2 or 4, depending on the window width.

 GridLayout {
     Layout.fillWidth: true
     rowSpacing: spacing
     columnSpacing: spacing

     columns: mainView.width < mainView.buttonMinWidth * 2 + mainView.spacing + mainView.margin * 2 // width of 2 buttons
              ? 1
              : (mainView.width < mainView.buttonMinWidth * 4 + mainView.spacing * 3 + mainView.margin * 2 // width of 4 buttons
                 ? 2
                 : 4)

In this GridLayout, four RoundButtons are instantiated. One for toggling shadows, one for mesh smoothing, one for camera position, and finally, one for changing the background of the graph. All the buttons follow the same structure. Rather than redefining this structure for all buttons, a custom component can be made.

 component CustomButton : RoundButton {
     id: buttonRoot

CustomButtom extends the RoundButton type, but adds a few additions. Properties such as Layout.minimumWidth, Layout.FillWidth, radius and background are set. These define the styling and layout of the button.

 property alias source: iconImage.source

 Layout.minimumWidth: buttonMinWidth
 Layout.fillWidth: true

 radius: mainView.radius

 background: Rectangle {
     radius: mainView.radius
     color: "white"
     border.color: "black"
 }

Whereas the contentItem defines the content of the button, in this case a Row type containing an icon and some text. The icon is imported using an IconImage type, and setting the source property. The text is created using a Label type and set using its text property. Two alliases are created for these two properties at the top of the custom component, this will allow them to be set when an instance of CustomButton is created.

 contentItem: Row {
     id :content
     IconImage {
         id: iconImage
         width: iconDimension
         height: iconDimension
         color: "transparent"
     }
     Label {
         text: buttonRoot.text
         horizontalAlignment: Text.AlignLeft
         anchors.verticalCenter: parent.verticalCenter
     }
 }

In the GridLayout, four CustomButtons are created. Three properties need to be set, the two alliases for the icon image and the text, and the signal onClicked.

 CustomButton {
     id: shadowButton
     text: graph.shadowQuality === AbstractGraph3D.ShadowQuality.None ?
               qsTr("Show Shadows") : qsTr("Hide Shadows")
     source: graph.shadowQuality === AbstractGraph3D.ShadowQuality.None ?
                 "qrc:/images/shadow.svg" : "qrc:/images/shadow_hide.svg"
     onClicked: {
         graph.shadowQuality = graph.shadowQuality === AbstractGraph3D.ShadowQuality.None ?
                     AbstractGraph3D.ShadowQuality.High :
                     AbstractGraph3D.ShadowQuality.None
     }
 }

For example, the shadow button sets the onClicked sign to toggle the shadow on and off.

Setting up the Graph

Next in the layout is the Graph, this is defined in its own QML file Graph.qml, and is instantiated as follows:

 Graph {
     id: graph
     Layout.fillWidth: true
     Layout.fillHeight: true
 }

Looking at its implementation in Graph.qml, the graph is of type Scatter3D, nested within an Item type.

 Scatter3D {
     id: scatterGraph

Before defining the data sets, some of the axes properties are configured.

 axisX.segmentCount: 3
 axisX.subSegmentCount: 2
 axisX.labelFormat: "%.2f"
 axisZ.segmentCount: 2
 axisZ.subSegmentCount: 2
 axisZ.labelFormat: "%.2f"
 axisY.segmentCount: 2
 axisY.subSegmentCount: 2
 axisY.labelFormat: "%.2f"

Setting up the Data

The graph shows three datasets, representing the data given in Data.qml. The datasets are stored in ListModel types

 ListModel {
     id: dataModel
     ListElement{ xPos: -10.0; yPos: 5.0; zPos: -5.0 }
     ...
 ListElement{ xPos: -7.54 ; yPos: 2.8 ; zPos: -3.68 }
 }

 ListModel {
 id: dataModelTwo
 ListElement{ xPos: 2.25 ; yPos: 1.36 ; zPos: -1.3 }
     ...
 ListElement{ xPos: -3.4 ; yPos: 0.6 ; zPos: 0.9 }
 }

 ListModel {
 id: dataModelThree
 ListElement{ xPos: 8.0; yPos: -2.0; zPos: 4.0 }
     ...
 ListElement{ xPos: 5.66 ; yPos: -4.98 ; zPos: 3.72 }
 }

and exposed to the other files using property aliases

 property alias model: dataModel
 property alias modelTwo: dataModelTwo
 property alias modelThree: dataModelThree

Before these aliases are used, create a Scatter3DSeries type, containing a ItemModelScatterDataProxy item.

 Scatter3DSeries {
     id: scatterSeries
     itemLabelFormat: "Series 1: X:@xLabel Y:@yLabel Z:@zLabel"

     ItemModelScatterDataProxy {
         itemModel: seriesData.model
         xPosRole: "xPos"
         yPosRole: "yPos"
         zPosRole: "zPos"
     }
 }

This data proxy refers to the datasets in Data.qml using its itemModel property. The aliases mentioned above are accessed through the id of the Data type instantiated in main.qml, seriesData.

 itemModel: seriesData.model

Repeat this for the remaining two datasets.

 Scatter3DSeries {
     id: scatterSeriesTwo
     ...
 ItemModelScatterDataProxy {
     itemModel: seriesData.modelTwo
     ...
 }
 }
 Scatter3DSeries {
 id: scatterSeriesThree
     ...
 ItemModelScatterDataProxy {
     itemModel: seriesData.modelThree
     ...
 }
 }

Great, the scatter graph is now pointing to the three datasets.

The only thing left to do is to add the remaining button, the theme button, to our ColumnLayout. The only difference with this button is it is positioned on the left-hand side of the layout. This is set by defining the Layout.alignment property to Qt.AlignLeft and Layout.fillWidth to false.

 CustomButton {
     id: themeButton
     Layout.alignment: Qt.AlignLeft
     Layout.fillWidth: false

Example Contents

Files: