This fork is a port of the React-Particles-Experiment by @swizec to MobX. It's purpose is mainly to show the difference between different architectural styles. Each style has it's own branch
- The original Redux powered implementation
- An implementation MobX and Flux style actions and dispatchers. This branch uses mainly plain objects
- An implementation with MobX and MVC like store. Uses classes and decorators extensively.
Diffs: Redux - MobX Flux // Redux - MobX MVC // MobX Flux - MobX MVC
This project isn't intended to compare the performance of Redux and Mobx, it's setup is too simple to do that. But a simple test will reveal that MobX is ~20-30% slower. The reason for this is that the usage @observer does simplify the code of this project, but beyond that doesn't do anything for performance, because on each ticks all particles will always be re-rendered, since all of them are moving. However, if only a subset of the particles is updated per tick, MobX performs better then Redux. Roughly 30% faster if only 25% of the particles is updated. This is because MobX doesn't need to shallowly copy the particles list on each change and will skip the rendering of the App(Container) component, which needs to reinstantiate all of the ParticleView components in the Redux approach. The MobX Flux and MobX MVC approaches should not show significant performance differences.
(original Readme)
That's a particle generator. It makes tiny circles fly out of where you click. Hold down your mouse and move around. The particles keep flying out of your cursor.
On mobile and only have a finger? That works, too.
I'm a nerd, so this is what I consider fun. Your mileage may vary. Please do click in the embed and look at those circles fly. Ain't it cool?
The whole thing is built with React, Redux, and d3. No tricks for animation; just a bit of cleverness.
Here's the general approach:
We use React to render everything: the page, the SVG element, the particles inside. All of it is built with React components that take some props and return some DOM. This lets us tap into React's algorithms that decide which nodes to update and when to garbage collect old nodes.
Then we use some d3 calculations and event detection. D3 has great random generators, so we take advantage of that. D3's mouse and touch event handlers calculate coordinates relative to our SVG. We need those, and React can't do it. React's click handlers are based on DOM nodes, which don't correspond to (x, y) coordinates. D3 looks at real cursor position on screen.
All particle coordinates are in a Redux store. Each particle also has a movement vector. The store holds some useful flags and general parameters, too. This lets us treat animation as data transformations. I'll show you what I mean in a bit.
We use actions to communicate user events like creating particles, starting the animation, changing mouse position, and so on. On each requestAnimationFrame, we dispatch an "advance animation" action.
On each action, the reducer calculates a new state for the whole app. This includes new particle positions for each step of the animation.
When the store updates, React flushes changes via props and because coordinates are state, the particles move.
The result is smooth animation.
Keep reading to learn the details.
A version of this article will be featured as a chapter in my upcoming React+d3js ES6 book.
