--- slug: 2024/11/playing-with-fire title: "Playing with fire: The fractal flame algorithm" date: 2024-11-15 12:00:00 authors: [bspeice] tags: [] --- Wikipedia describes [fractal flames](https://en.wikipedia.org/wiki/Fractal_flame) as: > a member of the iterated function system class of fractals It's tedious, but technically correct. I choose to think of them a different way: beauty in mathematics. import isDarkMode from '@site/src/isDarkMode' import banner from '../banner.png'
I don't remember when exactly I first learned about fractal flames, but I do remember being entranced by the images they created. I also remember their unique appeal to my young engineering mind; this was an art form I could participate in. The [Fractal Flame Algorithm paper](https://flam3.com/flame_draves.pdf) describing their structure was too much for me to handle at the time (I was ~12 years old), so I was content to play around and enjoy the pictures. But the desire to understand it stuck around. Now, with a graduate degree under my belt, I wanted to revisit it. This guide is my attempt to explain how fractal flames work so that younger me — and others interested in the art — can understand without too much prior knowledge. --- ## Iterated function systems :::note This post covers section 2 of the Fractal Flame Algorithm paper ::: As mentioned, fractal flames are a type of "[iterated function system](https://en.wikipedia.org/wiki/Iterated_function_system)," or IFS. The formula for an IFS is short, but takes some time to work through: $$ S = \bigcup_{i=0}^{n-1} F_i(S) $$ ### Solution set First, $S$. $S$ is the set of points in two dimensions (in math terms, $S \in \mathbb{R}^2$) that represent a "solution" of some kind to our equation. Our goal is to find all the points in $S$, plot them, and display that image. For example, if we say $S = \{(0,0), (1, 1), (2, 2)\}$, there are three points to plot: import {VictoryChart, VictoryTheme, VictoryScatter, VictoryLegend} from "victory"; export const simpleData = [ {x: 0, y: 0}, {x: 1, y: 1}, {x: 2, y: 2} ] With fractal flames, rather than listing individual points, we use functions to describe the solution. This means there are an infinite number of points, but if we find _enough_ points to plot, we get a nice picture. And if the functions change, the solution also changes, and we get something new. ### Transform functions Second, the $F_i(S)$ functions, also known as "transforms." Each transform takes in a 2-dimensional point and gives a new point back (in math terms, $F_i \in \mathbb{R}^2 \rightarrow \mathbb{R}^2$). While you could theoretically use any function, we'll focus on a specific kind of function called an "[affine transformation](https://en.wikipedia.org/wiki/Affine_transformation)." Every transform uses the same formula: $$ F_i(a_i x + b_i y + c_i, d_i x + e_i y + f_i) $$ import transformSource from "!!raw-loader!../src/transform" import CodeBlock from '@theme/CodeBlock' {transformSource} The parameters ($a_i$, $b_i$, etc.) are values we choose. For example, we can define a "shift" function like this: $$ \begin{align*} a &= 1 \\ b &= 0 \\ c &= 0.5 \\ d &= 0 \\ e &= 1 \\ f &= 1.5 \\ F_{shift}(x, y) &= (1 \cdot x + 0.5, 1 \cdot y + 1.5) \end{align*} $$ Applying this transform to the original points gives us a new set of points: import {applyCoefs} from "../src/transform" export const coefs = {a: 1, b: 0, c: 0.5, d: 0, e: 1, f: 1.5} export const toData = ([x, y]) => ({x, y}) export const shiftData = simpleData.map(({x, y}) => toData(applyCoefs(x, y, coefs))) Fractal flames use more complex functions, but they all start with this structure. ### Fixed set With those definitions in place, let's revisit the initial problem: $$ S = \bigcup_{i=0}^{n-1} F_i(S) $$ Or, in English, we might say: > Our solution, $S$, is the union of all sets produced by applying each function, $F_i$, > to points in the solution. There's just one small problem: to find the solution, we must already know which points are in the solution. What? John E. Hutchinson provides an explanation in the [original paper](https://maths-people.anu.edu.au/~john/Assets/Research%20Papers/fractals_self-similarity.pdf) defining the mathematics of iterated function systems: > Furthermore, $S$ is compact and is the closure of the set of fixed points $s_{i_1...i_p}$ > of finite compositions $F_{i_1...i_p}$ of members of $F$. Before your eyes glaze over, let's unpack this: - **Furthermore, $S$ is [compact](https://en.wikipedia.org/wiki/Compact_space)...**: All points in our solution will be in a finite range - **...and is the [closure](https://en.wikipedia.org/wiki/Closure_(mathematics)) of the set of [fixed points](https://en.wikipedia.org/wiki/Fixed_point_(mathematics))**: Applying our functions to points in the solution will give us other points that are in the solution - **...of finite compositions $F_{i_1...i_p}$ of members of $F$**: By composing our functions (that is, using the output of one function as input to the next), we will arrive at the points in the solution Thus, by applying the functions to fixed points of our system, we will find the other points we care about.
If you want a bit more math... ...then there are some extra details I've glossed over so far. First, the Hutchinson paper requires that the functions $F_i$ be _contractive_ for the solution set to exist. That is, applying the function to a point must bring it closer to other points. However, as the fractal flame algorithm demonstrates, we only need functions to be contractive _on average_. At worst, the system will degenerate and produce a bad image. Second, we're focused on $\mathbb{R}^2$ because we're generating images, but the math allows for arbitrary dimensions; you could also have 3-dimensional fractal flames. Finally, there's a close relationship between fractal flames and [attractors](https://en.wikipedia.org/wiki/Attractor). Specifically, the fixed points of $S$ act as attractors for the chaos game (explained below).
This is still a bit vague, so let's work through an example. ## [Sierpinski's gasket](https://www.britannica.com/biography/Waclaw-Sierpinski) The Fractal Flame paper gives three functions to use for a first IFS: $$ F_0(x, y) = \left({x \over 2}, {y \over 2} \right) \\ ~\\ F_1(x, y) = \left({{x + 1} \over 2}, {y \over 2} \right) \\ ~\\ F_2(x, y) = \left({x \over 2}, {{y + 1} \over 2} \right) $$ ### The chaos game Now, how do we find the "fixed points" mentioned earlier? The paper lays out an algorithm called the "[chaos game](https://en.wikipedia.org/wiki/Chaos_game)" that gives us points in the solution: $$ \begin{align*} &(x, y) = \text{random point in the bi-unit square} \\ &\text{iterate } \{ \\ &\hspace{1cm} i = \text{random integer from 0 to } n - 1 \\ &\hspace{1cm} (x,y) = F_i(x,y) \\ &\hspace{1cm} \text{plot}(x,y) \text{ if iterations} > 20 \\ \} \end{align*} $$ :::note The chaos game algorithm is effectively the "finite compositions of $F_{i_1..i_p}$" mentioned earlier. ::: Let's turn this into code, one piece at a time. To start, we need to generate some random numbers. The "bi-unit square" is the range $[-1, 1]$, and we can do this using an existing API: import biunitSource from '!!raw-loader!../src/randomBiUnit' {biunitSource} Next, we need to choose a random integer from $0$ to $n - 1$: import randintSource from '!!raw-loader!../src/randomInteger' {randintSource} ### Plotting Finally, implementing the `plot` function. This blog series is interactive, so everything displays directly in the browser. As an alternative, software like `flam3` and Apophysis can "plot" by saving an image to disk. To see the results, we'll use the [Canvas API](https://developer.mozilla.org/en-US/docs/Web/API/Canvas_API). This allows us to manipulate individual pixels in an image and show it on screen. First, we need to convert from fractal flame coordinates to pixel coordinates. To simplify things, we'll assume that we're plotting a square image with range $[0, 1]$ for both $x$ and $y$: import cameraSource from "!!raw-loader!./cameraGasket" {cameraSource} Next, we'll store the pixel data in an [`ImageData` object](https://developer.mozilla.org/en-US/docs/Web/API/ImageData). Each pixel on screen has a corresponding index in the `data` array. To plot a point, we set that pixel to be black: import plotSource from '!!raw-loader!./plot' {plotSource} Putting it all together, we have our first image: import Playground from '@theme/Playground' import Scope from './scope' import chaosGameSource from '!!raw-loader!./chaosGame' {chaosGameSource}
The image here is slightly different than in the paper. I think the paper has an error, so I'm plotting the image like the [reference implementation](https://github.com/scottdraves/flam3/blob/7fb50c82e90e051f00efcc3123d0e06de26594b2/rect.c#L440-L441). ### Weights There's one last step before we finish the introduction. So far, each transform has the same chance of being picked in the chaos game. We can change that by giving them a "weight" ($w_i$) instead: import randomChoiceSource from '!!raw-loader!../src/randomChoice' {randomChoiceSource} If we let the chaos game run forever, these weights wouldn't matter. But because the iteration count is limited, changing the weights means we don't plot some parts of the image: import chaosGameWeightedSource from "!!raw-loader!./chaosGameWeighted"; {chaosGameWeightedSource} :::tip Double-click the image if you want to save a copy! ::: import GasketWeighted from "./GasketWeighted"; import {SquareCanvas} from "../src/Canvas"; ## Summary Studying the foundations of fractal flames is challenging, but we now have an understanding of the mathematics and the implementation of iterated function systems. In the next post, we'll look at the first innovation of fractal flame algorithm: variations.