I tried logging in on browser and I had inspected the request. My password was sent in plaintext. Is this a infosec.pub issue or a Lemmy one?
I tried logging in on browser and I had inspected the request. My password was sent in plaintext. Is this a infosec.pub issue or a Lemmy one?
Why not hash it client side? Edit: Isn’t SSL vulnerable to MITM attacks? (I am a noob in this field)
Figured I’d expand on something Alex said in response to you.
Basically hashing it on the client doesn’t solve the problem it just shifts it a bit. Instead of needing to capture and then send the plaintext password to the server. An attacker would simply need to capture and send the hash as generated by the client to the server. In both cases an attacker with access to the plain communication between client and server would have all the information necessary.
Basically if you hash it on the client-side, you’ve just made the hash the password that needs to be protected as an attacker only needs to “pass the hash” to the server.
That said you are raising a legitimate concern and its a great question that shows you’re starting to think about the issues at hand. Because, you’re right. When we send the password in plaintext at the application layer we are simply trusting that the communication channel is secure, and that is not a safe assumption.
There is a bit of a rabbit hole regarding authentication schemes you can dive into and there is a scheme that adds a bit more onto the simple idea of just hashing the password on the client-side. Basically, the server provides a nonce (a one-time use value) to the client. The client hashes their password with this nonce included and sends the resultant hash back to the server to be validated. It kinda solves the issue of someone being able to read the communication as the hash being sent over the wire is only useful in response to that specific nonce for that specific user.
The trade-off on this is that in-order for the server to be able to validate the response from the client, the server must have access to that same key-data the client hashed with the nonce, AKA passwords needs to be stored in a recoverable way. You increase security against a compromised communication channel, but also increased the damage that an attacker could do if they could leak the database.
Going further down the rabbit hole, there is Salted Challenge-Response Authentication which takes a step towards alleviating this by storing a salted and hashed version of the password. And then providing the client the nonce as usual along with the salt and other information needed for the client to reproduce the version of the hash the server is storing. This does mean passwords are not in “plaintext” but it has in effect made the hashed version the password that should be protected. Anyone who compromises the database still has all the information necessary to generate the response for any nonce. They just couldn’t try for password reuse stuff like one could if it was actually recoverable.
Ultimately, this comes down to what is the bigger threat. You can (somewhat) secure against a compromised communication channel (which is generally a targeted attack against only one user at a time), but it means that some server side vulnerabilities will be able to compromise every user account. In general, for web-apps I think you’re better off hardening the server-side and having mitigations like 2FA around sensitive actions to limit the damage just compromising the password could do.
Also, if you really wanted to be more secure against communication channel issues, public key cryptography is a better tool for that, but has generally not be well supported for web-apps.
First of all thanks for the very detailed response. I have a few questions.
Like you said, why not use public key cryptography? Why is it not well supported for web-apps?
Why not use something like Diffie-Hellman algorithm to share the password? Signal protocol uses ECDHE so I am assuming that it’s safe against mitm which the base Diffie-Hellman is vulnerable to (I might be wrong. I couldn’t find if it waa vulnerable or not).
You are describing TLS, which is commonly used for websites and web apps.
Try the following command:
openssl s_client -connect infosec.pub:443The public key, the authority that signed the certificate, and the cypher used will all be visible.
For me, the cipher used is
ECDHE-RSA-AES256-GCM-SHA384.Oh. Okay. I’ll check it out once. I’m pretty new to all this so I didn’t know this is how SSL works.
Most of the comments are misconceptions. SSL/TLS is supposed to create a tunnel on top of TCP. If implented correctly, it is supposed to connect, establish a session key, and anything going back and forth from server to client will be using the tunnel using a symmetric encryption. On client side usually your password will be sent plaintext before the server hashes it and checks against a db of hashes. Client side should not hash the password which I am fairly sure would allow pass-the-hash, but don’t quote me on that. Also, there is possiblity of MITM, but it requires specific conditions and isn’t like with how sslstrip or whatever was a while ago.
I’m tired so I might be wrong about some of this stuff, but The cryptography SO has a lot of questions on how SSL/TLS works and I suggest googling how TLS works.
I will check it out. Thanks!
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The first paragraph is correct, but your second paragraph is not. A cryptographic hash function is a lossy one-way function. Knowing exactly how something was hashed does not mean you can turn the hash back into the starting value again.
Oh okay makes sense thanks!
Why would the hash be reversible? SHA256 is public and it’s not reversible