A Node library for Squoosh
$ gnpm install @squoosh/lib
Unfortunately, due to a few people leaving the team, and staffing issues resulting from the current economic climate (ugh), this package is no longer actively maintained. I know that sucks, but there simply isn't the time & people to work on this. If anyone from the community wants to fork it, you have my blessing. The squoosh.app web app will continue to be supported and improved.
libSquoosh is an experimental way to run all the codecs you know from the Squoosh web app directly inside your own JavaScript program. libSquoosh uses a worker pool to parallelize processing images. This way you can apply the same codec to many images at once.
libSquoosh is currently not the fastest image compression tool in town and doesn’t aim to be. It is, however, fast enough to compress many images sufficiently quick at once.
libSquoosh can be installed to your local project with the following command:
$ npm install @squoosh/lib
You can start using the libSquoosh by adding these lines to the top of your JS program:
import { ImagePool } from '@squoosh/lib';
import { cpus } from 'os';
const imagePool = new ImagePool(cpus().length);
This will create an image pool with an underlying processing pipeline that you can use to ingest and encode images. The ImagePool constructor takes one argument that defines how many parallel operations it is allowed to run at any given time.
:warning: Important! Make sure to only create 1 ImagePool
when performing parallel image processing. If you create multiple pools, the ImagePool
can run out of memory and crash. By reusing a single ImagePool
, you can ensure that the backing worker queue and processing pipeline releases memory prior to processing the next image.
You can ingest a new image like so:
import fs from 'fs/promises';
const file = await fs.readFile('./path/to/image.png');
const image = imagePool.ingestImage(file);
The ingestImage
function can accept any ArrayBuffer
whether that is from readFile()
or fetch()
.
The returned image
object is a representation of the original image, that you can now preprocess, encode, and extract information about.
When an image has been ingested, you can start preprocessing it and encoding it to other formats. This example will resize the image and then encode it to a .jpg
and .jxl
image:
const preprocessOptions = {
//When both width and height are specified, the image resized to specified size.
resize: {
width: 100,
height: 50,
},
/*
//When either width or height is specified, the image resized to specified size keeping aspect ratio.
resize: {
width: 100,
}
*/
};
await image.preprocess(preprocessOptions);
const encodeOptions = {
mozjpeg: {}, //an empty object means 'use default settings'
jxl: {
quality: 90,
},
};
const result = await image.encode(encodeOptions);
The default values for each option can be found in the codecs.ts
file under defaultEncoderOptions
. Every unspecified value will use the default value specified there. Better documentation is needed here.
You can run your own code inbetween the different steps, if, for example, you want to change how much the image should be resized based on its original height. (See Extracting image information to learn how to get the image dimensions).
When you have encoded everything you need, it is recommended to close the processing pipeline in the ImagePool. This will not delete the images you have already encoded, but it will prevent you from ingesting and encoding new images.
Close the ImagePool pipeline with this line:
await imagePool.close();
When you have encoded an image, you normally want to write it to a file.
This example takes an image that has been encoded as a jpg
and writes it to a file:
const rawEncodedImage = image.encodedWith.mozjpeg.binary;
fs.writeFile('/path/to/new/image.jpg', rawEncodedImage);
This example iterates through all encoded versions of the image and writes them to a specific path:
const newImagePath = '/path/to/image.'; //extension is added automatically
for (const encodedImage of Object.values(image.encodedWith)) {
fs.writeFile(newImagePath + encodedImage.extension, encodedImage.binary);
}
Information about a decoded image is available at Image.decoded
. It looks something like this:
console.log(await image.decoded);
// Returns:
{
bitmap: {
data: Uint8ClampedArray(47736584) [
225, 228, 237, 255, 225, 228, 237, 255, 225, 228, 237, 255,
225, 228, 237, 255, 225, 228, 237, 255, 225, 228, 237, 255,
225, 228, 237, 255,
... //the entire raw image
],
width: 4606, //pixels
height: 2591 //pixels
},
size: 2467795 //bytes
}
Information about an encoded image can be found at Image.encodedWith[encoderName]
. It looks something like this:
console.log(image.encodedWith.jxl);
// Returns:
{
optionsUsed: {
quality: 75,
baseline: false,
arithmetic: false,
progressive: true,
... //all the possible options for this encoder
},
binary: Uint8Array(1266975) [
1, 0, 0, 1, 0, 1, 0, 0, 255, 219, 0, 132,
113, 119, 156, 156, 209, 1, 8, 8, 8, 8, 9, 8,
9, 10, 10, 9,
... //the entire raw encoded image
],
extension: 'jxl',
size: 1266975 //bytes
}
libSquoosh has an experimental auto optimizer that compresses an image as much as possible, trying to hit a specific Butteraugli target value. The higher the Butteraugli target value, the more artifacts can be introduced.
You can make use of the auto optimizer by using “auto” as the config object.
const encodeOptions: {
mozjpeg: 'auto',
}
Copyright 2013 - present © cnpmjs.org | Home |