Features?
Why?
Imagine trying to explore a dataset of millions of data points as a 2D scatter. Besides plotting, the exploration typically involves three things: First, we want to interactively adjust the view (e.g., via panning & zooming) and the visual point encoding (e.g., the point color, opacity, or size). Second, we want to be able to select and highlight data points. And third, we want to compare multiple datasets or views of the same dataset (e.g., via synchronized interactions). The goal of jupyter-scatter is to support all three requirements and scale to millions of points.
How?
Internally, Jupyter Scatter uses regl-scatterplot for WebGL rendering, traitlets for two-way communication between the JS and iPython kernels, and anywidget for composing the widget.
Docs
Visit https://jupyter-scatter.dev for detailed documentation including examples and a complete API description.
Index
pip install jupyter-scatter
If you want to use Jupyter Scatter in JupyterLab <=2 you need to manually install it as an extension as follows:
jupyter labextension install @jupyter-widgets/jupyterlab-manager jupyter-scatter
If you want to instal Jupyter Scatter from source, make sure to have Node installed. While several version might work, we're primarily testing against the Active LTS and Maintenance LTS releases.
For a minimal working example, take a look at test-environments.
[!TIP] Visit jupyter-scatter.dev for details on all essential features of Jupyter Scatter and check out our full-blown tutorial from SciPy '23.
In the simplest case, you can pass the x/y coordinates to the plot function as follows:
import jscatter
import numpy as np
x = np.random.rand(500)
y = np.random.rand(500)
jscatter.plot(x, y)
Say your data is stored in a Pandas dataframe like the following:
import pandas as pd
# Just some random float and int values
data = np.random.rand(500, 4)
df = pd.DataFrame(data, columns=['mass', 'speed', 'pval', 'group'])
# We'll convert the `group` column to strings to ensure it's recognized as
# categorical data. This will come in handy in the advanced example.
df['group'] = df['group'].map(lambda c: chr(65 + round(c)), na_action=None)
x | y | value | group | |
---|---|---|---|---|
0 | 0.13 | 0.27 | 0.51 | G |
1 | 0.87 | 0.93 | 0.80 | B |
2 | 0.10 | 0.25 | 0.25 | F |
3 | 0.03 | 0.90 | 0.01 | G |
4 | 0.19 | 0.78 | 0.65 | D |
You can then visualize this data by referencing column names:
jscatter.plot(data=df, x='mass', y='speed')
Often you want to customize the visual encoding, such as the point color, size, and opacity.
jscatter.plot(
data=df,
x='mass',
y='speed',
size=8, # static encoding
color_by='group', # data-driven encoding
opacity_by='density', # view-driven encoding
)
In the above example, we chose a static point size of 8
. In contrast, the point color is data-driven and assigned based on the categorical group
value. The point opacity is view-driven and defined dynamically by the number of points currently visible in the view.
Also notice how jscatter uses an appropriate color map by default based on the data type used for color encoding. In this examples, jscatter uses the color blindness safe color map from Okabe and Ito as the data type is categorical
and the number of categories is less than 9
.
Important: in order for jscatter to recognize categorical data, the dtype
of the corresponding column needs to be category
!
You can, of course, customize the color map and many other parameters of the visual encoding as shown next.
The flat API can get overwhelming when you want to customize a lot of properties. Therefore, jscatter provides a functional API that groups properties by type and exposes them via meaningfully-named methods.
scatter = jscatter.Scatter(data=df, x='mass', y='speed')
scatter.selection(df.query('mass < 0.5').index)
scatter.color(by='mass', map='plasma', order='reverse')
scatter.opacity(by='density')
scatter.size(by='pval', map=[2, 4, 6, 8, 10])
scatter.height(480)
scatter.background('black')
scatter.show()
When you update properties dynamically, i.e., after having called scatter.show()
, the plot will update automatically. For instance, try calling scatter.xy('speed', 'mass')
and you will see how the points are mirrored along the diagonal.
Moreover, all arguments are optional. If you specify arguments, the methods will act as setters and change the properties. If you call a method without any arguments it will act as a getter and return the property (or properties). For example, scatter.selection()
will return the currently selected points.
Finally, the scatter plot is interactive and supports two-way communication. Hence, if you select some point with the lasso tool and then call scatter.selection()
you will get the current selection.
To explore multiple scatter plots and have their view, selection, and hover interactions link, use jscatter.link()
.
jscatter.link([
jscatter.Scatter(data=embeddings, x='pcaX', y='pcaY', **config),
jscatter.Scatter(data=embeddings, x='tsneX', y='tsneY', **config),
jscatter.Scatter(data=embeddings, x='umapX', y='umapY', **config),
jscatter.Scatter(data=embeddings, x='caeX', y='caeY', **config)
], rows=2)
https://user-images.githubusercontent.com/932103/162584133-85789d40-04f5-428d-b12c-7718f324fb39.mp4
See notebooks/linking.ipynb for more details.
With jupyter-scatter
you can easily visualize and interactively explore datasets with millions of points.
In the following we're visualizing 5 million points generated with the Rössler attractor.
points = np.asarray(roesslerAttractor(5000000))
jscatter.plot(points[:,0], points[:,1], height=640)
https://user-images.githubusercontent.com/932103/162586987-0b5313b0-befd-4bd1-8ef5-13332d8b15d1.mp4
See notebooks/examples.ipynb for more details.
While jscatter is primarily developed for Jupyter Lab and Notebook, it also runs just fine in Google Colab. See jupyter-scatter-colab-test.ipynb for an example.
**Requirements:** - [uv](https://astral.sh/uv) >= v0.4.0 - [Node](https://nodejs.org) [Active LTS or Maintenance LTS release](https://nodejs.org/en/about/previous-releases) **Installation:** ```bash git clone https://github.com/flekschas/jupyter-scatter/ jscatter && cd jscatter uv run jupyter lab ``` **After Changing Python code:** restart the kernel. Alternatively, you can enable auto reloading by enabling the `autoreload` extension. To do so, run the following code at the beginning of a notebook: ```py %load_ext autoreload %autoreload 2 ``` **After Changing JavaScript code:** do `cd js && npm run build`. Alternatively, you can enable anywidgets hot-module-reloading (HMR) as follows and run `npm run watch` to rebundle the JS code on the fly. ```py %env ANYWIDGET_HMR=1 ```
Go to [test-environments](test-environments) and follow the instructions.
Run `uv run pytest`.
If you use Jupyter Scatter in your research, please cite our JOSS paper:
@article{lekschas2024jupyter,
title = {{Jupyter Scatter}: Interactive Exploration of Large-Scale Datasets},
author = {Fritz Lekschas and Trevor Manz},
journal = {Journal of Open Source Software},
publisher = {The Open Journal},
year = {2024},
volume = {9},
number = {101},
pages = {7059},
doi = {10.21105/joss.07059},
url = {https://doi.org/10.21105/joss.07059},
}