/// var __extends = (this && this.__extends) || (function () { var extendStatics = function (d, b) { extendStatics = Object.setPrototypeOf || ({ __proto__: [] } instanceof Array && function (d, b) { d.__proto__ = b; }) || function (d, b) { for (var p in b) if (b.hasOwnProperty(p)) d[p] = b[p]; }; return extendStatics(d, b); } return function (d, b) { extendStatics(d, b); function __() { this.constructor = d; } d.prototype = b === null ? Object.create(b) : (__.prototype = b.prototype, new __()); }; })(); var __decorate = (this && this.__decorate) || function (decorators, target, key, desc) { var c = arguments.length, r = c < 3 ? target : desc === null ? desc = Object.getOwnPropertyDescriptor(target, key) : desc, d; if (typeof Reflect === "object" && typeof Reflect.decorate === "function") r = Reflect.decorate(decorators, target, key, desc); else for (var i = decorators.length - 1; i >= 0; i--) if (d = decorators[i]) r = (c < 3 ? d(r) : c > 3 ? d(target, key, r) : d(target, key)) || r; return c > 3 && r && Object.defineProperty(target, key, r), r; }; var BABYLON; (function (BABYLON) { var PerlinNoiseProceduralTexture = /** @class */ (function (_super) { __extends(PerlinNoiseProceduralTexture, _super); function PerlinNoiseProceduralTexture(name, size, scene, fallbackTexture, generateMipMaps) { var _this = _super.call(this, name, size, "perlinNoiseProceduralTexture", scene, fallbackTexture, generateMipMaps) || this; _this.time = 0.0; _this.timeScale = 1.0; _this.translationSpeed = 1.0; _this._currentTranslation = 0; _this.updateShaderUniforms(); return _this; } PerlinNoiseProceduralTexture.prototype.updateShaderUniforms = function () { this.setFloat("size", this.getRenderSize()); var scene = this.getScene(); if (!scene) { return; } var deltaTime = scene.getEngine().getDeltaTime(); this.time += deltaTime; this.setFloat("time", this.time * this.timeScale / 1000); this._currentTranslation += deltaTime * this.translationSpeed / 1000.0; this.setFloat("translationSpeed", this._currentTranslation); }; PerlinNoiseProceduralTexture.prototype.render = function (useCameraPostProcess) { this.updateShaderUniforms(); _super.prototype.render.call(this, useCameraPostProcess); }; PerlinNoiseProceduralTexture.prototype.resize = function (size, generateMipMaps) { _super.prototype.resize.call(this, size, generateMipMaps); }; /** * Serializes this perlin noise procedural texture * @returns a serialized perlin noise procedural texture object */ PerlinNoiseProceduralTexture.prototype.serialize = function () { var serializationObject = BABYLON.SerializationHelper.Serialize(this, _super.prototype.serialize.call(this)); serializationObject.customType = "BABYLON.PerlinNoiseProceduralTexture"; return serializationObject; }; /** * Creates a Perlin Noise Procedural Texture from parsed perlin noise procedural texture data * @param parsedTexture defines parsed texture data * @param scene defines the current scene * @param rootUrl defines the root URL containing perlin noise procedural texture information * @returns a parsed Perlin Noise Procedural Texture */ PerlinNoiseProceduralTexture.Parse = function (parsedTexture, scene, rootUrl) { var texture = BABYLON.SerializationHelper.Parse(function () { return new PerlinNoiseProceduralTexture(parsedTexture.name, parsedTexture._size, scene, undefined, parsedTexture._generateMipMaps); }, parsedTexture, scene, rootUrl); return texture; }; __decorate([ BABYLON.serialize() ], PerlinNoiseProceduralTexture.prototype, "time", void 0); __decorate([ BABYLON.serialize() ], PerlinNoiseProceduralTexture.prototype, "timeScale", void 0); __decorate([ BABYLON.serialize() ], PerlinNoiseProceduralTexture.prototype, "translationSpeed", void 0); return PerlinNoiseProceduralTexture; }(BABYLON.ProceduralTexture)); BABYLON.PerlinNoiseProceduralTexture = PerlinNoiseProceduralTexture; })(BABYLON || (BABYLON = {})); //# sourceMappingURL=babylon.perlinNoiseProceduralTexture.js.map BABYLON.Effect.ShadersStore['perlinNoiseProceduralTexturePixelShader'] = "\nprecision highp float;\n\nuniform float size;\nuniform float time;\nuniform float translationSpeed;\n\nvarying vec2 vUV;\n\nfloat r(float n)\n{\nreturn fract(cos(n*89.42)*343.42);\n}\nvec2 r(vec2 n)\n{\nreturn vec2(r(n.x*23.62-300.0+n.y*34.35),r(n.x*45.13+256.0+n.y*38.89)); \n}\nfloat worley(vec2 n,float s)\n{\nfloat dis=1.0;\nfor(int x=-1; x<=1; x++)\n{\nfor(int y=-1; y<=1; y++)\n{\nvec2 p=floor(n/s)+vec2(x,y);\nfloat d=length(r(p)+vec2(x,y)-fract(n/s));\nif (dis>d)\ndis=d;\n}\n}\nreturn 1.0-dis;\n}\nvec3 hash33(vec3 p3)\n{\np3=fract(p3*vec3(0.1031,0.11369,0.13787));\np3+=dot(p3,p3.yxz+19.19);\nreturn -1.0+2.0*fract(vec3((p3.x+p3.y)*p3.z,(p3.x+p3.z)*p3.y,(p3.y+p3.z)*p3.x));\n}\nfloat perlinNoise(vec3 p)\n{\nvec3 pi=floor(p);\nvec3 pf=p-pi;\nvec3 w=pf*pf*(3.0-2.0*pf);\nreturn mix(\nmix(\nmix(\ndot(pf-vec3(0,0,0),hash33(pi+vec3(0,0,0))),\ndot(pf-vec3(1,0,0),hash33(pi+vec3(1,0,0))),\nw.x\n),\nmix(\ndot(pf-vec3(0,0,1),hash33(pi+vec3(0,0,1))),\ndot(pf-vec3(1,0,1),hash33(pi+vec3(1,0,1))),\nw.x\n),\nw.z\n),\nmix(\nmix(\ndot(pf-vec3(0,1,0),hash33(pi+vec3(0,1,0))),\ndot(pf-vec3(1,1,0),hash33(pi+vec3(1,1,0))),\nw.x\n),\nmix(\ndot(pf-vec3(0,1,1),hash33(pi+vec3(0,1,1))),\ndot(pf-vec3(1,1,1),hash33(pi+vec3(1,1,1))),\nw.x\n),\nw.z\n),\nw.y\n);\n}\n\nvoid main(void)\n{\nvec2 uv=gl_FragCoord.xy+translationSpeed;\nfloat dis=(\n1.0+perlinNoise(vec3(uv/vec2(size,size),time*0.05)*8.0))\n*(1.0+(worley(uv,32.0)+ 0.5*worley(2.0*uv,32.0)+0.25*worley(4.0*uv,32.0))\n);\ngl_FragColor=vec4(vec3(dis/4.0),1.0);\n}\n";