Which is Better React Visibility Detection Libraries?
react-intersection-observer vs react-waypoint vs react-visibility-sensor
1 Year
react-intersection-observerreact-waypointreact-visibility-sensorSimilar Packages:
What's React Visibility Detection Libraries?

Visibility detection libraries in React are essential tools that help developers determine when a component enters or exits the viewport. These libraries enhance user experience by enabling features such as lazy loading, animations, and analytics tracking based on visibility. They leverage the browser's Intersection Observer API or similar techniques to efficiently monitor element visibility without performance overhead, making them suitable for modern web applications. By integrating these libraries, developers can create more interactive and responsive applications that react to user behavior and viewport changes effectively.

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react-intersection-observer1,781,8805,047129 kB1a month agoMIT
react-waypoint222,9794,07960.7 kB61-MIT
react-visibility-sensor213,1902,322-835 years agoMIT
Feature Comparison: react-intersection-observer vs react-waypoint vs react-visibility-sensor

Performance Optimization

  • react-intersection-observer: This package is built on the Intersection Observer API, which is designed for high performance. It minimizes layout thrashing and reduces the number of reflows by batching visibility changes, making it suitable for applications with many components that need visibility detection.
  • react-waypoint: React-waypoint is efficient for triggering events based on scroll position but may introduce some overhead due to the need for scroll event listeners. It is best used in scenarios where precise control over scroll-triggered events is required.
  • react-visibility-sensor: While it provides a simple API, react-visibility-sensor may not be as performant as react-intersection-observer for large lists or complex UIs, as it relies on polling to detect visibility changes, which can lead to performance bottlenecks in high-frequency updates.

Ease of Use

  • react-intersection-observer: This library offers a clean and straightforward API that integrates seamlessly with React components. It allows developers to easily manage visibility states without extensive boilerplate code, making it user-friendly for developers familiar with hooks.
  • react-waypoint: React-waypoint provides a declarative API that makes it intuitive to use for scroll-based interactions. Its straightforward setup allows developers to quickly implement scroll-triggered behavior without much overhead.
  • react-visibility-sensor: React-visibility-sensor is designed for simplicity, providing a very easy-to-use interface that abstracts away the complexities of the Intersection Observer API. It is ideal for developers who want quick implementation without diving deep into the underlying mechanics.

Use Cases

  • react-intersection-observer: Best suited for lazy loading images, infinite scrolling, and triggering animations when elements come into view. It is versatile and can be used in various scenarios where visibility detection is critical.
  • react-waypoint: Perfect for implementing scroll-triggered animations and events, such as triggering animations when a user scrolls to a certain section of the page or loading more content as the user scrolls down.
  • react-visibility-sensor: Ideal for tracking visibility for analytics purposes, such as determining how often users view specific components or ads. It is also useful for simple lazy loading and basic visibility detection needs.

Community and Support

  • react-intersection-observer: This package has a strong community and is actively maintained, ensuring that it stays up-to-date with the latest React features and best practices. It has comprehensive documentation and examples, making it easier for developers to adopt.
  • react-waypoint: React-waypoint has a solid community and good documentation, making it a reliable choice for developers. Its popularity ensures that it receives updates and support, but it may not be as widely used as react-intersection-observer.
  • react-visibility-sensor: While it has a decent user base, it may not be as actively maintained as react-intersection-observer, which could lead to potential issues with compatibility in future React versions. Documentation is available but may not be as extensive.

Flexibility

  • react-intersection-observer: Highly flexible, allowing for customization of thresholds and root margins, enabling developers to fine-tune when visibility changes are detected. This flexibility makes it suitable for a wide range of applications.
  • react-waypoint: Offers flexibility in defining when to trigger events based on scroll position, allowing developers to specify offsets and thresholds. This makes it adaptable for various scroll-based interactions.
  • react-visibility-sensor: Less flexible compared to react-intersection-observer, as it abstracts many details away. It is suitable for simpler use cases but may not provide the level of customization needed for complex scenarios.
How to Choose: react-intersection-observer vs react-waypoint vs react-visibility-sensor
  • react-intersection-observer: Choose react-intersection-observer if you need a lightweight solution that utilizes the Intersection Observer API for optimal performance and supports a wide range of use cases, including lazy loading images and triggering animations when elements come into view. It is ideal for developers looking for a modern, efficient approach to visibility detection.
  • react-waypoint: Select react-waypoint if you want to create scroll-based animations or trigger events when a user scrolls to a specific point in the page. It provides a more declarative approach to handling scroll events and is particularly useful for implementing features like infinite scrolling or triggering animations at specific scroll positions.
  • react-visibility-sensor: Opt for react-visibility-sensor if you require a simple and straightforward way to track visibility changes with minimal setup. It offers a higher-level abstraction over the Intersection Observer API, making it easier to implement but potentially less performant for complex scenarios. This package is suitable for projects where ease of use is prioritized over fine-tuned performance.
README for react-intersection-observer

react-intersection-observer

Version Badge GZipped size Test License Downloads

React implementation of the Intersection Observer API to tell you when an element enters or leaves the viewport. Contains both a Hooks, render props and plain children implementation.

Features

  • 🪝 Hooks or Component API - With useInView it's easier than ever to monitor elements
  • ⚡️ Optimized performance - Reuses Intersection Observer instances where possible
  • ⚙️ Matches native API - Intuitive to use
  • 🛠 Written in TypeScript - It'll fit right into your existing TypeScript project
  • 🧪 Ready to test - Mocks the Intersection Observer for easy testing with Jest or Vitest
  • 🌳 Tree-shakeable - Only include the parts you use
  • 💥 Tiny bundle - Around ~1.15kB for useInView and ~1.6kB for <InView>

Open in StackBlitz

Installation

Install the package with your package manager of choice:

npm install react-intersection-observer --save

Usage

useInView hook

// Use object destructuring, so you don't need to remember the exact order
const { ref, inView, entry } = useInView(options);

// Or array destructuring, making it easy to customize the field names
const [ref, inView, entry] = useInView(options);

The useInView hook makes it easy to monitor the inView state of your components. Call the useInView hook with the (optional) options you need. It will return an array containing a ref, the inView status and the current entry. Assign the ref to the DOM element you want to monitor, and the hook will report the status.

import React from "react";
import { useInView } from "react-intersection-observer";

const Component = () => {
  const { ref, inView, entry } = useInView({
    /* Optional options */
    threshold: 0,
  });

  return (
    <div ref={ref}>
      <h2>{`Header inside viewport ${inView}.`}</h2>
    </div>
  );
};

Render props

To use the <InView> component, you pass it a function. It will be called whenever the state changes, with the new value of inView. In addition to the inView prop, children also receive a ref that should be set on the containing DOM element. This is the element that the Intersection Observer will monitor.

If you need it, you can also access the IntersectionObserverEntry on entry, giving you access to all the details about the current intersection state.

import { InView } from "react-intersection-observer";

const Component = () => (
  <InView>
    {({ inView, ref, entry }) => (
      <div ref={ref}>
        <h2>{`Header inside viewport ${inView}.`}</h2>
      </div>
    )}
  </InView>
);

export default Component;

Plain children

You can pass any element to the <InView />, and it will handle creating the wrapping DOM element. Add a handler to the onChange method, and control the state in your own component. Any extra props you add to <InView> will be passed to the HTML element, allowing you set the className, style, etc.

import { InView } from "react-intersection-observer";

const Component = () => (
  <InView as="div" onChange={(inView, entry) => console.log("Inview:", inView)}>
    <h2>Plain children are always rendered. Use onChange to monitor state.</h2>
  </InView>
);

export default Component;

[!NOTE] When rendering a plain child, make sure you keep your HTML output semantic. Change the as to match the context, and add a className to style the <InView />. The component does not support Ref Forwarding, so if you need a ref to the HTML element, use the Render Props version instead.

API

Options

Provide these as the options argument in the useInView hook or as props on the <InView /> component.

| Name | Type | Default | Description | | ---------------------- | ------------------------- | ----------- | ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- | | root | Element | document | The Intersection Observer interface's read-only root property identifies the Element or Document whose bounds are treated as the bounding box of the viewport for the element which is the observer's target. If the root is null, then the bounds of the actual document viewport are used. | | rootMargin | string | '0px' | Margin around the root. Can have values similar to the CSS margin property, e.g. "10px 20px 30px 40px" (top, right, bottom, left). Also supports percentages, to check if an element intersects with the center of the viewport for example "-50% 0% -50% 0%". | | threshold | number or number[] | 0 | Number between 0 and 1 indicating the percentage that should be visible before triggering. Can also be an array of numbers, to create multiple trigger points. | | onChange | (inView, entry) => void | undefined | Call this function whenever the in view state changes. It will receive the inView boolean, alongside the current IntersectionObserverEntry. | | trackVisibility 🧪 | boolean | false | A boolean indicating whether this Intersection Observer will track visibility changes on the target. | | delay 🧪 | number | undefined | A number indicating the minimum delay in milliseconds between notifications from this observer for a given target. This must be set to at least 100 if trackVisibility is true. | | skip | boolean | false | Skip creating the IntersectionObserver. You can use this to enable and disable the observer as needed. If skip is set while inView, the current state will still be kept. | | triggerOnce | boolean | false | Only trigger the observer once. | | initialInView | boolean | false | Set the initial value of the inView boolean. This can be used if you expect the element to be in the viewport to start with, and you want to trigger something when it leaves. | | fallbackInView | boolean | undefined | If the IntersectionObserver API isn't available in the client, the default behavior is to throw an Error. You can set a specific fallback behavior, and the inView value will be set to this instead of failing. To set a global default, you can set it with the defaultFallbackInView() |

InView Props

The <InView /> component also accepts the following props:

| Name | Type | Default | Description | | ------------ | ---------------------------------------------------- | ----------- | ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ | | as | IntrinsicElement | 'div' | Render the wrapping element as this element. Defaults to div. If you want to use a custom component, please use the useInView hook or a render prop instead to manage the reference explictly. | | children | ({ref, inView, entry}) => ReactNode or ReactNode | undefined | Children expects a function that receives an object containing the inView boolean and a ref that should be assigned to the element root. Alternatively pass a plain child, to have the <InView /> deal with the wrapping element. You will also get the IntersectionObserverEntry as entry, giving you more details. |

Intersection Observer v2 🧪

The new v2 implementation of IntersectionObserver extends the original API, so you can track if the element is covered by another element or has filters applied to it. Useful for blocking clickjacking attempts or tracking ad exposure.

To use it, you'll need to add the new trackVisibility and delay options. When you get the entry back, you can then monitor if isVisible is true.

const TrackVisible = () => {
  const { ref, entry } = useInView({ trackVisibility: true, delay: 100 });
  return <div ref={ref}>{entry?.isVisible}</div>;
};

This is still a very new addition, so check caniuse for current browser support. If trackVisibility has been set, and the current browser doesn't support it, a fallback has been added to always report isVisible as true.

It's not added to the TypeScript lib.d.ts file yet, so you will also have to extend the IntersectionObserverEntry with the isVisible boolean.

Recipes

The IntersectionObserver itself is just a simple but powerful tool. Here's a few ideas for how you can use it.

FAQ

How can I assign multiple refs to a component?

You can wrap multiple ref assignments in a single useCallback:

import React, { useRef, useCallback } from "react";
import { useInView } from "react-intersection-observer";

function Component(props) {
  const ref = useRef();
  const { ref: inViewRef, inView } = useInView();

  // Use `useCallback` so we don't recreate the function on each render
  const setRefs = useCallback(
    (node) => {
      // Ref's from useRef needs to have the node assigned to `current`
      ref.current = node;
      // Callback refs, like the one from `useInView`, is a function that takes the node as an argument
      inViewRef(node);
    },
    [inViewRef],
  );

  return <div ref={setRefs}>Shared ref is visible: {inView}</div>;
}

rootMargin isn't working as expected

When using rootMargin, the margin gets added to the current root - If your application is running inside a <iframe>, or you have defined a custom root this will not be the current viewport.

You can read more about this on these links:

Testing

In order to write meaningful tests, the IntersectionObserver needs to be mocked. You can use the included react-intersection-observer/test-utils to help with this. It mocks the IntersectionObserver, and includes a few methods to assist with faking the inView state. When setting the isIntersecting value you can pass either a boolean value or a threshold between 0 and 1. It will emulate the real IntersectionObserver, allowing you to validate that your components are behaving as expected.

| Method | Description | | --------------------------------------------- | --------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- | | mockAllIsIntersecting(isIntersecting) | Set isIntersecting on all current Intersection Observer instances. The value of isIntersecting should be either a boolean or a threshold between 0 and 1. | | mockIsIntersecting(element, isIntersecting) | Set isIntersecting for the Intersection Observer of a specific element. The value of isIntersecting should be either a boolean or a threshold between 0 and 1. | | intersectionMockInstance(element) | Call the intersectionMockInstance method with an element, to get the (mocked) IntersectionObserver instance. You can use this to spy on the observe andunobserve methods. | | setupIntersectionMocking(mockFn) | Mock the IntersectionObserver, so we can interact with them in tests - Should be called in beforeEach. (Done automatically in Jest environment) | | resetIntersectionMocking() | Reset the mocks on IntersectionObserver - Should be called in afterEach. (Done automatically in Jest environment) |

Testing Libraries

This library comes with built-in support for writing tests in both Jest and Vitest

Jest

Testing with Jest should work out of the box. Just import the react-intersection-observer/test-utils in your test files, and you can use the mocking methods.

Vitest

If you're running Vitest with globals, then it'll automatically mock the IntersectionObserver, just like running with Jest. Otherwise, you'll need to manually setup/reset the mocking in either the individual tests, or a setup file.

import { vi, beforeEach, afterEach } from "vitest";
import {
  setupIntersectionMocking,
  resetIntersectionMocking,
} from "react-intersection-observer/test-utils";

beforeEach(() => {
  setupIntersectionMocking(vi.fn);
});

afterEach(() => {
  resetIntersectionMocking();
});

You only need to do this if the test environment does not support beforeEach globally, alongside either jest.fn or vi.fn.

Other Testing Libraries

See the instructions for Vitest. You should be able to use a similar setup/reset code, adapted to the testing library you are using. Failing that, copy the code from test-utils.ts, and make your own version.

Fallback Behavior

You can create a Jest setup file that leverages the unsupported fallback option. In this case, you can override the IntersectionObserver in test files were you actively import react-intersection-observer/test-utils.

test-setup.js

import { defaultFallbackInView } from "react-intersection-observer";

defaultFallbackInView(true); // or `false` - whichever consistent behavior makes the most sense for your use case.

Alternatively, you can mock the Intersection Observer in all tests with a global setup file. Add react-intersection-observer/test-utils to setupFilesAfterEnv in the Jest config, or setupFiles in Vitest.

module.exports = {
  setupFilesAfterEnv: ["react-intersection-observer/test-utils"],
};

Test Example

import React from "react";
import { screen, render } from "@testing-library/react";
import { useInView } from "react-intersection-observer";
import {
  mockAllIsIntersecting,
  mockIsIntersecting,
  intersectionMockInstance,
} from "react-intersection-observer/test-utils";

const HookComponent = ({ options }) => {
  const { ref, inView } = useInView(options);
  return (
    <div ref={ref} data-testid="wrapper">
      {inView.toString()}
    </div>
  );
};

test("should create a hook inView", () => {
  render(<HookComponent />);

  // This causes all (existing) IntersectionObservers to be set as intersecting
  mockAllIsIntersecting(true);
  screen.getByText("true");
});

test("should create a hook inView with threshold", () => {
  render(<HookComponent options={{ threshold: 0.3 }} />);

  mockAllIsIntersecting(0.1);
  screen.getByText("false");

  // Once the threshold has been passed, it will trigger inView.
  mockAllIsIntersecting(0.3);
  screen.getByText("true");
});

test("should mock intersecing on specific hook", () => {
  render(<HookComponent />);
  const wrapper = screen.getByTestId("wrapper");

  // Set the intersection state on the wrapper.
  mockIsIntersecting(wrapper, 0.5);
  screen.getByText("true");
});

test("should create a hook and call observe", () => {
  const { getByTestId } = render(<HookComponent />);
  const wrapper = getByTestId("wrapper");
  // Access the `IntersectionObserver` instance for the wrapper Element.
  const instance = intersectionMockInstance(wrapper);

  expect(instance.observe).toHaveBeenCalledWith(wrapper);
});

Intersection Observer

Intersection Observer is the API used to determine if an element is inside the viewport or not. Browser support is excellent - With Safari adding support in 12.1, all major browsers now support Intersection Observers natively. Add the polyfill, so it doesn't break on older versions of iOS and IE11.

Unsupported fallback

If the client doesn't have support for the IntersectionObserver, then the default behavior is to throw an error. This will crash the React application, unless you capture it with an Error Boundary.

If you prefer, you can set a fallback inView value to use if the IntersectionObserver doesn't exist. This will make react-intersection-observer fail gracefully, but you must ensure your application can correctly handle all your observers firing either true or false at the same time.

You can set the fallback globally:

import { defaultFallbackInView } from "react-intersection-observer";

defaultFallbackInView(true); // or 'false'

You can also define the fallback locally on useInView or <InView> as an option. This will override the global fallback value.

import React from "react";
import { useInView } from "react-intersection-observer";

const Component = () => {
  const { ref, inView, entry } = useInView({
    fallbackInView: true,
  });

  return (
    <div ref={ref}>
      <h2>{`Header inside viewport ${inView}.`}</h2>
    </div>
  );
};

Polyfill

You can import the polyfill directly or use a service like https://cdnjs.cloudflare.com/polyfill to add it when needed.

yarn add intersection-observer

Then import it in your app:

import "intersection-observer";

If you are using Webpack (or similar) you could use dynamic imports, to load the Polyfill only if needed. A basic implementation could look something like this:

/**
 * Do feature detection, to figure out which polyfills needs to be imported.
 **/
async function loadPolyfills() {
  if (typeof window.IntersectionObserver === "undefined") {
    await import("intersection-observer");
  }
}

Low level API

You can access the observe method, that react-intersection-observer uses internally to create and destroy IntersectionObserver instances. This allows you to handle more advanced use cases, where you need full control over when and how observers are created.

import { observe } from "react-intersection-observer";

const destroy = observe(element, callback, options);

| Name | Type | Required | Description | | ------------ | -------------------------- | -------- | ---------------------------------------------------------- | | element | Element | true | DOM element to observe | | callback | ObserverInstanceCallback | true | The callback function that Intersection Observer will call | | options | IntersectionObserverInit | false | The options for the Intersection Observer |

The observe method returns an unobserve function, that you must call in order to destroy the observer again.

[!IMPORTANT] You most likely won't need this, but it can be useful if you need to handle IntersectionObservers outside React, or need full control over how instances are created.