In cryptography and computer security, a length extension attack is a type of attack where an attacker can use Hash(message1) and the length of message1 to calculate Hash(message1 ‖ message2) for an attacker-controlled message2, without needing to know the content of message1. This is problematic when the hash is used as a message authentication code with construction Hash(secret ‖ message),[1] and message and the length of secret is known, because an attacker can include extra information at the end of the message and produce a valid hash without knowing the secret. Algorithms like MD5, SHA-1 and most of SHA-2 that are based on the Merkle–Damgård construction are susceptible to this kind of attack.[1][2][3] Truncated versions of SHA-2, including SHA-384 and SHA-512/256 are not susceptible,[4] nor is the SHA-3 algorithm.[5] HMAC also uses a different construction and so is not vulnerable to length extension attacks.[6] Lastly, just performing Hash(message ‖ secret) is enough to not be affected.
Explanation
editThe vulnerable hashing functions work by taking the input message, and using it to transform an internal state. After all of the input has been processed, the hash digest is generated by outputting the internal state of the function. It is possible to reconstruct the internal state from the hash digest, which can then be used to process the new data. In this way, one may extend the message and compute the hash that is a valid signature for the new message.
Example
editA server for delivering waffles of a specified type to a specific user at a location could be implemented to handle requests of the given format:
Original Data: count=10&lat=37.351&user_id=1&long=-119.827&waffle=eggo Original Signature: 6d5f807e23db210bc254a28be2d6759a0f5f5d99
The server would perform the request given (to deliver ten waffles of type eggo to the given location for user "1") only if the signature is valid for the user. The signature used here is a MAC, signed with a key not known to the attacker.[note 1]
It is possible for an attacker to modify the request in this example by switching the requested waffle from "eggo" to "liege." This can be done by taking advantage of a flexibility in the message format if duplicate content in the query string gives preference to the latter value. This flexibility does not indicate an exploit in the message format, because the message format was never designed to be cryptographically secure in the first place, without the signature algorithm to help it.
Desired New Data: count=10&lat=37.351&user_id=1&long=-119.827&waffle=eggo&waffle=liege
In order to sign this new message, typically the attacker would need to know the key the message was signed with, and generate a new signature by generating a new MAC. However, with a length extension attack, it is possible to feed the hash (the signature given above) into the state of the hashing function, and continue where the original request had left off, so long as the length of the original request is known. In this request, the original key's length was 14 bytes, which could be determined by trying forged requests with various assumed lengths, and checking which length results in a request that the server accepts as valid.
The message as fed into the hashing function is often padded, as many algorithms can only work on input messages whose lengths are a multiple of some given size. The content of this padding is always specified by the hash function used. The attacker must include all of these padding bits in their forged message before the internal states of their message and the original will line up. Thus, the attacker constructs a slightly different message using these padding rules:
New Data: count=10&lat=37.351&user_id=1&long=-119.827&waffle=eggo\x80\x00\x00 \x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00 \x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00 \x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00 \x00\x00\x00\x02\x28&waffle=liege
This message includes all of the padding that was appended to the original message inside of the hash function before their payload (in this case, a 0x80 followed by a number of 0x00s and a message length, 0x228 = 552 = (14+55)*8, which is the length of the key plus the original message, appended at the end). The attacker knows that the state behind the hashed key/message pair for the original message is identical to that of new message up to the final "&." The attacker also knows the hash digest at this point, which means he knows the internal state of the hashing function at that point. It is then trivial to initialize a hashing algorithm at that point, input the last few characters, and generate a new digest which can sign his new message without the original key.
New Signature: 0e41270260895979317fff3898ab85668953aaa2
By combining the new signature and new data into a new request, the server will see the forged request as a valid request due to the signature being the same as it would have been generated if the password was known.
Notes
edit- ^ This example is also vulnerable to a replay attack, by sending the same request and signature a second time.
References
edit- ^ a b Vũ, Hoàng (2012-03-30). "MD5 Length Extension Attack Revisited - Vũ's Inner Peace". Archived from the original on 2014-10-29. Retrieved 2017-10-27.
- ^ Duong, Thai; Rizzo, Juliano (2009-09-28). "Flickr's API Signature Forgery Vulnerability" (PDF). Retrieved 2023-03-18.
- ^ Meyer, Christopher (2012-07-30). "Hash Length Extension Attacks". Retrieved 2017-10-27.
- ^ Bostrom, Michael (2015-10-29). "size_t Does Matter: Hash Length Extension Attacks Explained" (PDF). Retrieved 2020-11-23.
- ^ Keccak Team. "Strengths of Keccak - Design and security". Retrieved 2017-10-27.
Unlike SHA-1 and SHA-2, Keccak does not have the length-extension weakness, hence does not need the HMAC nested construction. Instead, MAC computation can be performed by simply prepending the message with the key.
- ^ Lawson, Nate (2009-10-29). "Stop using unsafe keyed hashes, use HMAC". Retrieved 2017-10-27.