Procedural generator for 2D space scenes. Try it out live here.
npm i space-scene-2d
import { Space2D } from "space-scene-2d";
const space2d = new Space2D();
const canvas = space2d.render(512, 512, {
nebulaAlbedoLow: [0.1, 0.25, 0.5],
nebulaAlbedoHigh: [0.5, 0.25, 0.1],
nebulaFalloff: 512,
nebulaAbsorption: 1.0,
nebulaDensity: 0.1,
nebulaAlbedoScale: 5,
stars: [
{
position: [256, 256, 350],
color: [0.1375, 0.1375, 0.25],
falloff: 256,
diffractionSpikeFalloff: 1024,
diffractionSpikeScale: 8,
},
],
});
document.body.appendChild(canvas);
const space2d = new Space2D();space2d.render(width: number, height: number, parameters: RenderParameters): HTMLCanvasElementRenders the space scene. Returns an HTMLCanvasElement with the rendered scene.
| Parameter | Type | Description |
|---|---|---|
| width | number | The width of the rendered scene in pixels. |
| height | number | The height of the rendered scene in pixels. |
| parameters? | RenderParameters | Optional. See definition of RenderParameters |
| Field | Type | Default | Description |
|---|---|---|---|
| scale? | number | 0.002 | How zoomed out the camera is. Larger value is zoomed out more. |
| offset? | [number, number] | [0, 0] | The location of the lower-left corner of the scene. |
| backgroundColor? | [number, number, number] | [0.125, 0.125, 0.25] | The color of the background noise pattern. |
| backgroundDepth? | number | 137.0 | How far in the z-direction the background noise pattern is sliced out of 3D noise. |
| backgroundLacunarity? | number | 2.0 | The frequency multiplier for each octave of background noise. Numbers closer to one result in smoother noise. |
| backgroundGain? | number | 0.5 | The magnitude multiplier for each octave of background noise. Numbers closer to one result in smoother noise. |
| backgroundOctaves? | number | 8 | The number of octaves of background noise. |
| backgroundDensity? | number | 2.0 | A scaling factor applied after the background noise is calculated. Larger numbers result in greater density. |
| backgroundFalloff? | number | 8.0 | An exponential factor applied after the background noise is calculated. Larger numbers result in a more rapid falloff in density. |
| backgroundScale? | number | 0.003 | How zoomed out the camera is for the background noise. |
| backgroundStarDensity? | number | 0.05 | The density of the background stars. |
| backgroundStarBrightness? | number | 0.125 | How bright the background stars are. |
| nebulaNear? | number | 0.0 | The near plane of the nebula noise layers. |
| nebulaFar? | number | 500.0 | The far plane of the nebula noise layers. |
| nebulaLayers? | number | 1000 | The number of nebula noise layers. |
| nebulaAbsorption? | number | 1.0 | How much light is absorbed by each layer as a function of the density at each point. |
| nebulaLacunarity? | number | 2.0 | The frequency multiplier for each octave of nebula noise. Numbers closer to one result in smoother noise. |
| nebulaGain? | number | 0.5 | The magnitude multiplier for each octave of nebula noise. Numbers closer to one result in smoother noise. |
| nebulaOctaves? | number | 7 | The number of octaves of nebula noise. |
| nebulaDensity? | number | 0.1 | A scaling factor applied after the nebula noise is calculated. Larger numbers result in greater density. |
| nebulaFalloff? | number | 4.0 | An exponential factor applied after the nebula noise is calculated. Larger numbers result in a more rapid falloff in density. |
| nebulaEmissiveLow? | [number, number, number] | [0, 0, 0] | One of two colors mixed to calculate a final emissive color for the nebula. All zeros disables emissivity. |
| nebulaEmissiveHigh? | [number, number, number] | [0, 0, 0] | One of two colors mixed to calculate a final emissive color for the nebula. All zeros disables emissivity. |
| nebulaEmissiveOffset? | [number, number, number] | [0, 0, 0] | The offset into the perlin noise function used to determine a mixing coefficient for the emissive color. |
| nebulaEmissiveScale? | number | 1.0 | The frequency multiplier applied to the perlin noise function used to determine a mixing coefficient for the emissive color. |
| nebulaAlbedoLow? | [number, number, number] | [1, 1, 1] | One of two colors mixed to calculate a final albedo color for the nebula. |
| nebulaAlbedoHigh? | [number, number, number] | [1, 1, 1] | One of two colors mixed to calculate a final albedo color for the nebula. |
| nebulaAlbedoOffset? | [number, number, number] | [0, 0, 0] | The offset into the perlin noise function used to determine a mixing coefficient for the albedo color. |
| nebulaAlbedoScale? | number | 1.0 | The frequency multiplier applied to the perlin noise function used to determine a mixing coefficient for the albedo color. |
| stars? | Star[] | [] | A list of Star objects to use during this render. See definition of Star. |
| Field | Type | Description |
|---|---|---|
| position? | [number, number, number] | The x, y, and z coordinates of the star. These values are relative to the offset, nebulaNear and nebulaFar values of RenderParameters. |
| color? | [number, number, number] | The red, green, and blue components of the star color. |
| falloff? | number | An exponential factor applied to the body of the star. Larger values result in smaller star radii. |
| diffractionSpikeFalloff? | number | An exponential factor applied to the width of the star diffraction spikes. Larger values result in narrower spikes. |
| diffractionSpikeScale? | number | A scaling factor applied to the length of the star diffraction spikes. Larger values result in longer spikes. |