Transformers.js documentation
Building a Vanilla JavaScript Application
Building a Vanilla JavaScript Application
In this tutorial, you’ll build a simple web application that detects objects in images using Transformers.js! To follow along, all you need is a code editor, a browser, and a simple server (e.g., VS Code Live Server).
Here’s how it works: the user clicks “Upload image” and selects an image using an input dialog. After analysing the image with an object detection model, the predicted bounding boxes are overlaid on top of the image, like this:
Useful links:
Step 1: HTML and CSS setup
Before we start building with Transformers.js, we first need to lay the groundwork with some markup and styling. Create an index.html file with a basic HTML skeleton, and add the following tag to the :
<main class="container">
<label class="custom-file-upload">
<input id="file-upload" type="file" accept="image/*" />
<img class="upload-icon" src="https://huggingface.co/datasets/Xenova/transformers.js-docs/resolve/main/upload-icon.png" />
Upload image
label>
<div id="image-container">div>
<p id="status">p>
main>Click here to see a breakdown of this markup.
We’re adding an element with type="file" that accepts images. This allows the user to select an image from their local file system using a popup dialog. The default styling for this element looks quite bad, so let’s add some styling. The easiest way to achieve this is to wrap the element in a , hide the input, and then style the label as a button.
We’re also adding an empty Next, add the following CSS rules in a Here’s how the UI looks at this point: With the boring part out of the way, let’s start writing some JavaScript code! Create a file called The Moving into Since we will be downloading the model from the Hugging Face Hub, we can skip the local model check by setting: Next, let’s create references to the various DOM elements we will access later: We’re finally ready to create our object detection pipeline! As a reminder, a pipeline. is a high-level interface provided by the library to perform a specific task. In our case, we will instantiate an object detection pipeline with the Since this can take some time (especially the first time when we have to download the ~40MB model), we first update the To keep this tutorial simple, we’ll be loading and running the model in the main (UI) thread. This is not recommended for production applications, since the UI will freeze when we’re performing these actions. This is because JavaScript is a single-threaded language. To overcome this, you can use a web worker to download and run the model in the background. However, we’re not going to do cover that in this tutorial… We can now call the We’re passing two arguments into the The first tells Transformers.js what kind of task we want to perform. In our case, that is The second argument specifies which model we would like to use to solve the given task. We will use Once the function returns, we’ll tell the user that the app is ready to be used. The next step is to support uploading/selection of images. To achieve this, we will listen for “change” events from the Once the image has been loaded into the browser, the Don’t worry about the We’re finally ready to start interacting with Transformers.js! Let’s uncomment the NOTE: The Once we’ve updated the The second argument is an options object: If you now try to run the app and upload an image, you should see the following output logged to the console: In the example above, we uploaded an image of two elephants, so the The final step is to display the At the end of our Here’s the code for the The bounding box and label span also need some styling, so add the following to the And that’s it! You’ve now built your own fully-functional AI application that detects objects in images, which runns completely in your browser: no external server, APIs, or build tools. Pretty cool! 🥳 The app is live at the following URL: https://huggingface.co/spaces/Scrimba/vanilla-js-object-detector tag that we’ll use to give status updates to the user while we download and run the model, since both of these operations take some time. style.css file and link it to the HTML:html,
body {
font-family: Arial, Helvetica, sans-serif;
}
.container {
margin: 40px auto;
width: max(50vw, 400px);
display: flex;
flex-direction: column;
align-items: center;
}
.custom-file-upload {
display: flex;
align-items: center;
gap: 10px;
border: 2px solid black;
padding: 8px 16px;
cursor: pointer;
border-radius: 6px;
}
#file-upload {
display: none;
}
.upload-icon {
width: 30px;
}
#image-container {
width: 100%;
margin-top: 20px;
position: relative;
}
#image-container>img {
width: 100%;
}
Step 2: JavaScript setup
index.js and link to it in index.html by adding the following to the end of the :<script src="./index.js" type="module">script>type="module" attribute is important, as it turns our file into a JavaScript module, meaning that we’ll be able to use imports and exports.index.js, let’s import Transformers.js by adding the following line to the top of the file:import { pipeline, env } from "https://cdn.jsdelivr.net/npm/@huggingface/transformers";env.allowLocalModels = false;const fileUpload = document.getElementById("file-upload");
const imageContainer = document.getElementById("image-container");
const status = document.getElementById("status"); Step 3: Create an object detection pipeline
pipeline() helper function.status paragraph so that the user knows that we’re about to load the model.status.textContent = "Loading model...";pipeline() function that we imported at the top of our file, to create our object detection pipeline:const detector = await pipeline("object-detection", "Xenova/detr-resnet-50");pipeline() function: (1) task and (2) model.object-detection, but there are many other tasks that the library supports, including text-generation, sentiment-analysis, summarization, or automatic-speech-recognition. See here for the full list.Xenova/detr-resnet-50, as it is a relatively small (~40MB) but powerful model for detecting objects in an image.status.textContent = "Ready"; Step 4: Create the image uploader
fileUpload element. In the callback function, we use a FileReader() to read the contents of the image if one is selected (and nothing otherwise).fileUpload.addEventListener("change", function (e) {
const file = e.target.files[0];
if (!file) {
return;
}
const reader = new FileReader();
// Set up a callback when the file is loaded
reader.onload = function (e2) {
imageContainer.innerHTML = "";
const image = document.createElement("img");
image.src = e2.target.result;
imageContainer.appendChild(image);
// detect(image); // Uncomment this line to run the model
};
reader.readAsDataURL(file);
});reader.onload callback function will be invoked. In it, we append the new imageContainer to be displayed to the user.detect(image) function call (which is commented out) - we will explain it later! For now, try to run the app and upload an image to the browser. You should see your image displayed under the button like this:
Step 5: Run the model
detect(image) function call from the snippet above. Then we’ll define the function itself:async function detect(img) {
status.textContent = "Analysing...";
const output = await detector(img.src, {
threshold: 0.5,
percentage: true,
});
status.textContent = "";
console.log("output", output);
// ...
}detect function needs to be asynchronous, since we’ll await the result of the the model.status to “Analysing”, we’re ready to perform inference, which simply means to run the model with some data. This is done via the detector() function that was returned from pipeline(). The first argument we’re passing is the image data (img.src).threshold property to 0.5. This means that we want the model to be at least 50% confident before claiming it has detected an object in the image. The lower the threshold, the more objects it’ll detect (but may misidentify objects); the higher the threshold, the fewer objects it’ll detect (but may miss objects in the scene).percentage: true, which means that we want the bounding box for the objects to be returned as percentages (instead of pixels).
output variable holds an array with two objects, each containing a label (the string “elephant”), a score (indicating the model’s confidence in its prediction) and a box object (representing the bounding box of the detected entity). Step 6: Render the boxes
box coordinates as rectangles around each of the elephants.detect() function, we’ll run the renderBox function on each object in the output array, using .forEach().output.forEach(renderBox);renderBox() function with comments to help you understand what’s going on:// Render a bounding box and label on the image
function renderBox({ box, label }) {
const { xmax, xmin, ymax, ymin } = box;
// Generate a random color for the box
const color = "#" + Math.floor(Math.random() * 0xffffff).toString(16).padStart(6, 0);
// Draw the box
const boxElement = document.createElement("div");
boxElement.className = "bounding-box";
Object.assign(boxElement.style, {
borderColor: color,
left: 100 * xmin + "%",
top: 100 * ymin + "%",
width: 100 * (xmax - xmin) + "%",
height: 100 * (ymax - ymin) + "%",
});
// Draw the label
const labelElement = document.createElement("span");
labelElement.textContent = label;
labelElement.className = "bounding-box-label";
labelElement.style.backgroundColor = color;
boxElement.appendChild(labelElement);
imageContainer.appendChild(boxElement);
}style.css file:.bounding-box {
position: absolute;
box-sizing: border-box;
border-width: 2px;
border-style: solid;
}
.bounding-box-label {
color: white;
position: absolute;
font-size: 12px;
margin-top: -16px;
margin-left: -2px;
padding: 1px;
}