轻量封装WebGPU渲染系统示例<44>- 材质组装流水线(MaterialPipeline)之灯光和阴影(源码)
目标: 数据化,模块化,自动化
备注: 从这个节点开始整体设计往系统规范的方向靠拢。之前的都算作是若干准备。所以会和之前的版本实现有些差异。
当前示例源码github地址:
https://github.com/vilyLei/voxwebgpu/blob/feature/material/src/voxgpu/sample/MaterialPipelineTest.ts
当前示例运行效果:
此示例基于此渲染系统实现,当前示例TypeScript源码如下:
export class MaterialPipelineTest {
private mRscene = new RendererScene();
initialize(): void {
this.mRscene.initialize({
canvasWith: 512,
canvasHeight: 512,
mtplEnabled: true,
rpassparam: { multisampled: true }
});
this.initScene();
this.initEvent();
}
private initScene(): void {
let rc = this.mRscene;
let mtpl = rc.renderer.mtpl;
mtpl.light.data = createLightData([0, 300, 0], 600, 5.0);
mtpl.shadow.param.intensity = 0.7;
let position = [-230.0, 100.0, -200.0];
let materials = this.createMaterials(true);
let sph = new SphereEntity({
radius: 80,
transform: {
position
},
materials
});
rc.addEntity(sph);
position = [10.0, 100.0, -180.0];
materials = this.createMaterials(true);
let box = new BoxEntity({
minPos: [-30, -30, -30],
maxPos: [130, 230, 80],
transform: {
position,
rotation: [50, 130, 80]
},
materials
});
rc.addEntity(box);
position = [160.0, 100.0, 210.0];
materials = this.createMaterials(true);
let torus = new TorusEntity({
transform: {
position,
rotation: [50, 30, 80]
},
materials
});
rc.addEntity(torus);
position = [130.0, 220.0, 180.0];
materials = this.createMaterials(true);
torus = new TorusEntity({
transform: {
position,
rotation: [50, 30, 80]
},
materials
});
rc.addEntity(torus);
position = [0, -1, 0];
materials = this.createMaterials(true, false);
let plane = new PlaneEntity({
axisType: 1,
materials,
extent: [-600, -600, 1200, 1200],
transform: { position }
});
rc.addEntity(plane);
}
private initEvent(): void {
const rc = this.mRscene;
rc.addEventListener(MouseEvent.MOUSE_DOWN, this.mouseDown);
new MouseInteraction().initialize(rc, 0, false).setAutoRunning(true);
}
private hdrEnvtex = new SpecularEnvBrnTexture();
private createBaseTextures(): WGTextureDataDescriptor[] {
const albedoTex = { albedo: { url: `static/assets/pbrtex/rough_plaster_broken_diff_1k.jpg` } };
const normalTex = { normal: { url: `static/assets/pbrtex/rough_plaster_broken_nor_1k.jpg` } };
const armTex = { arm: { url: `static/assets/pbrtex/rough_plaster_broken_arm_1k.jpg` } };
let textures = [
this.hdrEnvtex,
albedoTex,
normalTex,
armTex
] as WGTextureDataDescriptor[];
return textures;
}
private createMaterials(shadowReceived = false, shadow = true, uvParam?: number[]): BaseMaterial[] {
let textures0 = this.createBaseTextures();
let material0 = this.createMaterial(textures0);
this.applyMaterialPPt(material0, shadowReceived, shadow);
let list = [material0];
if (uvParam) {
for (let i = 0; i < list.length; ++i) {
list[i].property.uvParam.value = uvParam;
}
}
return list;
}
private applyMaterialPPt(material: BaseMaterial, shadowReceived = false, shadow = true): void {
let property = material.property;
property.ambient.value = [0.0, 0.2, 0.2];
property.albedo.value = [0.7, 0.7, 0.3];
property.arms.roughness = 0.8;
property.armsBase.value = [0, 0, 0];
property.param.scatterIntensity = 32;
property.shadow = shadow;
property.lighting = true;
property.shadowReceived = shadowReceived;
}
private createMaterial(textures: WGTextureDataDescriptor[]): BaseMaterial {
let pipelineDefParam = {
depthWriteEnabled: true
};
let material = new BaseMaterial({ pipelineDefParam });
material.addTextures(textures);
return material;
}
private mouseDown = (evt: MouseEvent): void => {}
run(): void {
this.mRscene.run();
}
}