This module calculates a two-dimensional beeswarm arrangement of a one-dimensional dataset. For example, suppose you have this collection of data points:

The module calculates y-positions avoiding overlap so that the dataset can be viewed more clearly:

The main design goals of the module are to:

• represent values precisely (unlike some force-directed beeswarm layouts)
• pack the points together tightly without overlap
• run quickly

The module does not plot the points; you can use any plotting library to do this.

First, npm install accurate-beeswarm-plot and import the module:

import { AccurateBeeswarm } from 'accurate-beeswarm-plot';

The latest release has a non-module version of the script accurate-beeswarm-plot.nomodule.js that does not require the import statement.

It is assumed that the data (x) axis of the plot will be horizontal. For a vertical beeswarm, simply swap x and y axes when plotting.

To calculate a beeswarm arrangement, you need an array of items data and a function fn that takes an element of data and returns its x position. Construct an AccurateBeeswarm objects using new AccurateBeeswarm(data, radius, fn). The calculateYPositions() method returns an array of objects; each object contains fields datum (an element of data), x (the x position given by fn(datum)), and y (the computed y position).

let data = [{value: 2, name: "A"}, {value: 3, name: "B"}];
let radius = 5;
let fn = d => d.value;
let result = new AccurateBeeswarm(data, radius, fn)
        .calculateYPositions();

The gives a result of

[
  {"datum":{"value":2,"name":"A"},"x":2,"y":0},
  {"datum":{"value":3,"name":"B"},"x":3,"y":9.9498743710662}
]

A one-sided layout with only positive y-values can be obtained by calling the oneSided method before calculateYPositions.

let result = new AccurateBeeswarm(data, radius, fn)
        .oneSided()
        .calculateYPositions();

An alternative arrangement with ties broken randomly rather than preferring points with low values (this sometimes reduces the "honeycomb" appearance):

let result = new AccurateBeeswarm(data, radius, fn)
        .withTiesBrokenRandomly()
        .calculateYPositions();

You can also break ties by preferring items that occur early in the data array.

let result = new AccurateBeeswarm(data, radius, fn)
        .withTiesBrokenByArrayOrder()
        .calculateYPositions();

You can view an example using the Layer Cake framework on the Svelte REPL.

The algorithm places data points one by one. At each step, a point that can be placed as close to the y=0 line as possible is chosen and placed. By default, ties are broken by choosing points with low x values; if withTiesBrokenRandomly() is used, ties are broken using a random tie breaker which is given to each point before running the algorithm.

The algorithm uses a priority queue to quickly select the next point to be placed at each step.

If you have more than about 1000 data points, it's helpful to run the algorithm on the server side to avoid a long-running computation in the browser.

d3-beeswarm is another library with similar goals. The figure below uses d3-beeswarm to calculate the layout. To the best of my understanding, d3-beeswarm places the points in the order given, rather than using a dynamic strategy at each step to choose which point to place.

Beeswarms can also be produced using force layout, for example using d3-force, as in the example below and this Layer Cake example. A disadvantage of this approach is that it tends to represent values imprecisely. In the figure below, orange points have x-values that are incorrect by at least 0.5.

The beeswarm package for R implements a number of beeswarm strategies.

And of course, you could just use a histogram!

Issues and discussions are on GitHub.