Qt Quick 3D - Procedural Texture Example

Demonstrates how to provide custom texture data from C++ or QML.

This example makes use of QQuick3DTextureData and the textureData property of Texture to provide texture data generated dynamically at runtime instead of loading it from a static asset. For demonstration purposes this example generates two gradient textures in C++ and QML respectively.

First we define a C++ class for our texture data. We make it a subclass of QQuick3DTextureData. This is not strictly necessary, since there are no virtual functions, but it is much more convenient to have everything in one class. We define the properties we are going to use, and add QML_NAMED_ELEMENT to make it available from QML:

 class GradientTexture : public QQuick3DTextureData
 {
     Q_OBJECT
     Q_PROPERTY(int height READ height WRITE setHeight NOTIFY heightChanged)
     Q_PROPERTY(int width READ width WRITE setWidth NOTIFY widthChanged)
     Q_PROPERTY(QColor startColor READ startColor WRITE setStartColor NOTIFY startColorChanged)
     Q_PROPERTY(QColor endColor READ endColor WRITE setEndColor NOTIFY endColorChanged)
     QML_NAMED_ELEMENT(GradientTexture)
     ...

We add a function to update the texture. It uses setSize, and setFormat to configure the texture, and setTextureData to set the image data:

 void GradientTexture::updateTexture()
 {
     setSize(QSize(m_width, m_height));
     setFormat(QQuick3DTextureData::RGBA8);
     setHasTransparency(false);
     setTextureData(generateTexture());
 }

The function generateTexture creates a QByteArray of the correct size, and fills it with image data:

 QByteArray GradientTexture::generateTexture()
 {
     QByteArray imageData;
     // Create a horizontal gradient between startColor and endColor

     // Create a single scanline and reuse that data for each
     QByteArray gradientScanline;
     gradientScanline.resize(m_width * 4); // RGBA8

     for (int x = 0; x < m_width; ++x) {
         QColor color = linearInterpolate(m_startColor, m_endColor, x / float(m_width));
         int offset = x * 4;
         gradientScanline.data()[offset + 0] = char(color.red());
         gradientScanline.data()[offset + 1] = char(color.green());
         gradientScanline.data()[offset + 2] = char(color.blue());
         gradientScanline.data()[offset + 3] = char(255);
     }

     for (int y = 0; y < m_height; ++y)
         imageData += gradientScanline;

     return imageData;
 }

We call updateTexture each time a property is changed:

 void GradientTexture::setStartColor(QColor startColor)
 {
     if (m_startColor == startColor)
         return;

     m_startColor = startColor;
     emit startColorChanged(m_startColor);
     updateTexture();
 }

Finally, we can use our new texture from QML:

 Texture {
     id: textureFromCpp

     minFilter: applicationState.filterMode
     magFilter: applicationState.filterMode
     textureData: gradientTexture

     GradientTexture {
         id: gradientTexture
         startColor: applicationState.startColor
         endColor: applicationState.endColor
         width: applicationState.size
         height: width
     }
 }

It is also possible to generate the same texture data in QML. In this case we use the ProceduralTextureData component:

 Texture {
     id: textureFromQML
     minFilter: applicationState.filterMode
     magFilter: applicationState.filterMode
     textureData: gradientTextureDataQML

     ProceduralTextureData {
         id: gradientTextureDataQML

         property color startColor: applicationState.startColor
         property color endColor: applicationState.endColor
         width: applicationState.size
         height: width
         textureData: generateTextureData()

         function linearInterpolate(startColor : color, endColor : color, fraction : real) : color{
             return Qt.rgba(
                         startColor.r + (endColor.r - startColor.r) * fraction,
                         startColor.g + (endColor.g - startColor.g) * fraction,
                         startColor.b + (endColor.b - startColor.b) * fraction,
                         startColor.a + (endColor.a - startColor.a) * fraction
                         );
         }

         function generateTextureData() {
             let dataBuffer = new ArrayBuffer(width * height * 4)
             let data = new Uint8Array(dataBuffer)

             let gradientScanline = new Uint8Array(width * 4);

             for (let x = 0; x < width; ++x) {
                 let color = linearInterpolate(startColor, endColor, x / width);
                 let offset = x * 4;
                 gradientScanline[offset + 0] = color.r * 255;
                 gradientScanline[offset + 1] = color.g * 255;
                 gradientScanline[offset + 2] = color.b * 255;
                 gradientScanline[offset + 3] = color.a * 255;
             }

             for (let y = 0; y < height; ++y) {
                 data.set(gradientScanline, y * width * 4);
             }

             return dataBuffer;
         }
     }
 }

Just like in C++ we fill a QByteArray with image data that reflects the size and format of the texture. When doing this from QML use the ArrayBuffer type to avoid unnecessary type conversion.

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