Build & share delightful machine learning apps easily
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Gradio is an open-source Python library that is used to build machine learning and data science demos and web applications.
With Gradio, you can quickly create a beautiful user interface around your machine learning models or data science workflow and let people "try it out" by dragging-and-dropping in their own images, pasting text, recording their own voice, and interacting with your demo, all through the browser.
Gradio is useful for:
-
Demoing your machine learning models for clients/collaborators/users/students.
-
Deploying your models quickly with automatic shareable links and getting feedback on model performance.
-
Debugging your model interactively during development using built-in manipulation and interpretation tools.
Prerequisite: Gradio requires Python 3.7 or higher, that's all!
One of the best ways to share your machine learning model, API, or data science workflow with others is to create an interactive app that allows your users or colleagues to try out the demo in their browsers.
Gradio allows you to build demos and share them, all in Python. And usually in just a few lines of code! So let's get started.
To get Gradio running with a simple "Hello, World" example, follow these three steps:
1. Install Gradio using pip:
pip install gradio
2. Run the code below as a Python script or in a Jupyter Notebook (or Google Colab):
import gradio as gr
def greet(name):
return "Hello " + name + "!"
demo = gr.Interface(fn=greet, inputs="text", outputs="text")
demo.launch()
3. The demo below will appear automatically within the Jupyter Notebook, or pop in a browser on http://localhost:7860 if running from a script:
You'll notice that in order to make the demo, we created a gradio.Interface
. This Interface
class can wrap any Python function with a user interface. In the example above, we saw a simple text-based function, but the function could be anything from music generator to a tax calculator to the prediction function of a pretrained machine learning model.
The core Interface
class is initialized with three required parameters:
fn
: the function to wrap a UI aroundinputs
: which component(s) to use for the input (e.g."text"
,"image"
or"audio"
)outputs
: which component(s) to use for the output (e.g."text"
,"image"
or"label"
)
Let's take a closer look at these components used to provide input and output.
We saw some simple Textbox
components in the previous examples, but what if you want to change how the UI components look or behave?
Let's say you want to customize the input text field β for example, you wanted it to be larger and have a text placeholder. If we use the actual class for Textbox
instead of using the string shortcut, you have access to much more customizability through component attributes.
import gradio as gr
def greet(name):
return "Hello " + name + "!"
demo = gr.Interface(
fn=greet,
inputs=gr.Textbox(lines=2, placeholder="Name Here..."),
outputs="text",
)
demo.launch()
Suppose you had a more complex function, with multiple inputs and outputs. In the example below, we define a function that takes a string, boolean, and number, and returns a string and number. Take a look how you pass a list of input and output components.
import gradio as gr
def greet(name, is_morning, temperature):
salutation = "Good morning" if is_morning else "Good evening"
greeting = f"{salutation} {name}. It is {temperature} degrees today"
celsius = (temperature - 32) * 5 / 9
return greeting, round(celsius, 2)
demo = gr.Interface(
fn=greet,
inputs=["text", "checkbox", gr.Slider(0, 100)],
outputs=["text", "number"],
)
demo.launch()
You simply wrap the components in a list. Each component in the inputs
list corresponds to one of the parameters of the function, in order. Each component in the outputs
list corresponds to one of the values returned by the function, again in order.
Gradio supports many types of components, such as Image
, DataFrame
, Video
, or Label
. Let's try an image-to-image function to get a feel for these!
import numpy as np
import gradio as gr
def sepia(input_img):
sepia_filter = np.array([
[0.393, 0.769, 0.189],
[0.349, 0.686, 0.168],
[0.272, 0.534, 0.131]
])
sepia_img = input_img.dot(sepia_filter.T)
sepia_img /= sepia_img.max()
return sepia_img
demo = gr.Interface(sepia, gr.Image(shape=(200, 200)), "image")
demo.launch()
When using the Image
component as input, your function will receive a NumPy array with the shape (width, height, 3)
, where the last dimension represents the RGB values. We'll return an image as well in the form of a NumPy array.
You can also set the datatype used by the component with the type=
keyword argument. For example, if you wanted your function to take a file path to an image instead of a NumPy array, the input Image
component could be written as:
gr.Image(type="filepath", shape=...)
Also note that our input Image
component comes with an edit button π, which allows for cropping and zooming into images. Manipulating images in this way can help reveal biases or hidden flaws in a machine learning model!
You can read more about the many components and how to use them in the Gradio docs.
Gradio offers two classes to build apps:
1. Interface, that provides a high-level abstraction for creating demos that we've been discussing so far.
2. Blocks, a low-level API for designing web apps with more flexible layouts and data flows. Blocks allows you to do things like feature multiple data flows and demos, control where components appear on the page, handle complex data flows (e.g. outputs can serve as inputs to other functions), and update properties/visibility of components based on user interaction β still all in Python. If this customizability is what you need, try Blocks
instead!
Let's take a look at a simple example. Note how the API here differs from Interface
.
import gradio as gr
def greet(name):
return "Hello " + name + "!"
with gr.Blocks() as demo:
name = gr.Textbox(label="Name")
output = gr.Textbox(label="Output Box")
greet_btn = gr.Button("Greet")
greet_btn.click(fn=greet, inputs=name, outputs=output)
demo.launch()
Things to note:
Blocks
are made with awith
clause, and any component created inside this clause is automatically added to the app.- Components appear vertically in the app in the order they are created. (Later we will cover customizing layouts!)
- A
Button
was created, and then aclick
event-listener was added to this button. The API for this should look familiar! Like anInterface
, theclick
method takes a Python function, input components, and output components.
Here's an app to give you a taste of what's possible with Blocks
:
import numpy as np
import gradio as gr
def flip_text(x):
return x[::-1]
def flip_image(x):
return np.fliplr(x)
with gr.Blocks() as demo:
gr.Markdown("Flip text or image files using this demo.")
with gr.Tabs():
with gr.TabItem("Flip Text"):
text_input = gr.Textbox()
text_output = gr.Textbox()
text_button = gr.Button("Flip")
with gr.TabItem("Flip Image"):
with gr.Row():
image_input = gr.Image()
image_output = gr.Image()
image_button = gr.Button("Flip")
text_button.click(flip_text, inputs=text_input, outputs=text_output)
image_button.click(flip_image, inputs=image_input, outputs=image_output)
demo.launch()
A lot more going on here! We'll cover how to create complex Blocks
apps like this in the building with blocks section for you.
Congrats, you're now familiar with the basics of Gradio! π₯³ Go to our next guide to learn more about the key features of Gradio.
Gradio is built with many wonderful open-source libraries, please support them as well!
Gradio is licensed under the Apache License 2.0 found in the LICENSE file in the root directory of this repository.
Also check out the paper Gradio: Hassle-Free Sharing and Testing of ML Models in the Wild, ICML HILL 2019, and please cite it if you use Gradio in your work.
@article{abid2019gradio,
title = {Gradio: Hassle-Free Sharing and Testing of ML Models in the Wild},
author = {Abid, Abubakar and Abdalla, Ali and Abid, Ali and Khan, Dawood and Alfozan, Abdulrahman and Zou, James},
journal = {arXiv preprint arXiv:1906.02569},
year = {2019},
}