import { randomBiUnit, weightedChoice } from "./0-utility"; export type Variation = ( x: number, y: number, transformCoefs: Coefs ) => [number, number]; export type Coefs = { a: number; b: number; c: number; d: number; e: number; f: number; }; function r(x: number, y: number) { return Math.sqrt(Math.pow(x, 2) + Math.pow(y, 2)); } function theta(x: number, y: number) { return Math.atan2(x, y); } function omega(): number { return Math.random() > 0.5 ? Math.PI : 0; } export const linear: Variation = (x, y) => [x, y]; export const julia: Variation = (x, y) => { const sqrtR = Math.sqrt(r(x, y)); const thetaVal = theta(x, y) / 2 + omega(); return [sqrtR * Math.cos(thetaVal), sqrtR * Math.sin(thetaVal)]; }; export const popcorn: Variation = (x, y, transformCoefs) => { return [ x + transformCoefs.c * Math.sin(Math.tan(3 * y)), y + transformCoefs.f * Math.sin(Math.tan(3 * x)), ]; }; export const pdj: ( pdjA: number, pdjB: number, pdjC: number, pdjD: number ) => Variation = (pdjA, pdjB, pdjC, pdjD) => { return (x, y) => [ Math.sin(pdjA * y) - Math.cos(pdjB * x), Math.sin(pdjC * x) - Math.cos(pdjD * y), ]; }; export class Transform { constructor( public readonly coefs: Coefs, public readonly variations: [number, Variation][] ) {} apply(x: number, y: number) { const xformX = this.coefs.a * x + this.coefs.b * y + this.coefs.c; const xformY = this.coefs.d * x + this.coefs.e * y + this.coefs.f; var [curX, curY] = [0, 0]; this.variations.forEach(([blend, variation]) => { const [varX, varY] = variation(xformX, xformY, this.coefs); curX += blend * varX; curY += blend * varY; }); return [curX, curY]; } } export class Flame { protected x: number = randomBiUnit(); protected y: number = randomBiUnit(); constructor(public readonly transforms: [number, Transform][]) {} step(): void { const [_index, transform] = weightedChoice(this.transforms); [this.x, this.y] = transform.apply(this.x, this.y); } current(): [number, number] { return [this.x, this.y]; } } export function camera(x: number, y: number, size: number): [number, number] { // Assuming both: // - The origin is the intended center of the output image // - The output image is square // ...then map points in the range (-scale, scale) to pixel coordinates. // // The way `flam3` actually calculates the "camera" for taking a point // and determining which pixel to update is fairly involved. The example // fractal was designed in Apophysis (which shows points in the range // [-2, 2] by default) so we use that assumption to simplify the math here. return [Math.floor(((x + 2) * size) / 4), Math.floor(((y + 2) * size) / 4)]; } export function plot(x: number, y: number, image: ImageData) { const [pixelX, pixelY] = camera(x, y, image.width); if ( pixelX < 0 || pixelX >= image.width || pixelY < 0 || pixelY >= image.height ) { return; } const index = pixelY * (image.width * 4) + pixelX * 4; image.data[index + 0] = 0; image.data[index + 1] = 0; image.data[index + 2] = 0; image.data[index + 3] = 0xff; } export function render(flame: Flame, quality: number, image: ImageData) { const iterations = quality * image.width * image.height; for (var i = 0; i < iterations; i++) { flame.step(); if (i > 20) { const [flameX, flameY] = flame.current(); plot(flameX, flameY, image); } } } export const transform1Weight = 0.56453495; export const transform1 = new Transform( { a: -1.381068, b: -1.381068, c: 0, d: 1.381068, e: -1.381068, f: 0, }, [[1, julia]] ); export const transform2Weight = 0.013135; export const transform2 = new Transform( { a: 0.031393, b: 0.031367, c: 0, d: -0.031367, e: 0.031393, f: 0, }, [ [1, linear], [1, popcorn], ] ); export const transform3Weight = 0.42233; export const transform3 = new Transform( { a: 1.51523, b: -3.048677, c: 0.724135, d: 0.740356, e: -1.455964, f: -0.362059, }, [[1, pdj(1.09358, 2.13048, 2.54127, 2.37267)]] ); export function renderBaseline(image: ImageData) { const flame = new Flame([ [transform1Weight, transform1], [transform2Weight, transform2], [transform3Weight, transform3], ]); render(flame, 1, image); }