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First of all, I apologize for sending yet another question about this seeing as there are so many related posts. After reading through them and related sites I'm still not clear on a few points.

  1. Browser connects to server through secure socket
  2. Server responds with its public key with its certificate. This is the step I have the most trouble with. In this message from server to client, can the certificate be easily separated from the server's public key? If it's a root certificate (one which is already included in the browser) then a man-in-the-middle can't fake it, but what if it's not? Can't whatever this online mechanism the client uses to verify the certificate be hijacked? Furthermore, if the client's computer is compromised, the root CA's can be compromised, right? Any steps that avoid this? One last thing: It is said that a certificate is insecure until signed. I can't figure out what this means, especially since a certificate can sign itself. I think it's supposed to mean that someone is assuring the authenticity of the message, so a certificate signing itself sounds insecure ("Are you a REAL certificate?"..."ummm, sure, sure I am"). If the mechanism for authenticating a certificate is the internet, I'm wondering how is that secure. Is signing a certificate the same as thing (literally) as saying the client verifies the certificate?
  3. Session key is encrypted with public key and sent to server. This session key is a symmetric key that both server and client will use for remainder of encrypted communication.

I must say, most information online is so vague. So many holes in explanations and hand-waving going on. My guess is that very few people know the actual mechanisms very well?

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1 Answer 1

You've left out several steps. One of them is that the server sends a digital signature over the entire handshake so far, signed with its private key. Only the server can do that, with its own certificate. Nobody else's. The client verifies the digital signature using the public key in the certificate that was sent. That proves that the server owns the certificate. It also proves that the server is the same entity that sent all the other handshake messages.

BTW your step 3 is imaginary. The session key is never sent at all. It is computed independently at both ends.

EDIT Comments on your answer:

Server (from JoesGoods) gets a certificate from the CA via?

Usually via an Internet browser.

Can this be hijacked?

No more than any other secure SSL session can be.

The certificate is "signed"


which means a bit of it is encrypted using the CA's private key.

No. You made that up.

Specifically the bit that has the web server's info (JoesGoods' server info)

No. You made that up.

The entire certificate is signed, and that does not mean 'encrypted', with the CA's private key.

Bob's browser connects to server through a secure socket and sends a "hello" packet.

The socket isn't secure at this point. It's just plaintext.

The server sends its public key and certificate to Bob.

No. The server sends its certificate. The public key is already inside the certificate.

the browser checks that the webserver (JoesGoods) matches what's in the signed portion of the certificate

The entire certificate is signed. The client checks that the server it is connecting to matches the subjectDN of the certificate.

The webserver's public key is also signed with the CA's private key

Because it's in the certificate. Otherwise there is no other way this can be accomplished. That's why it isn't sent separately, and it's also why the entire certificate is signed, not just the bits you like.

The browser sends a client key exchange packet to the webserver (JoesGoods) using the webserver's public key included in step (2).

This part is cipher suite-dependent. What you have described applies to RSA cipher suites. Diffie-Hellman is a different story, and there is room for expansion to include others.

This client key is used to generate symmetric keys to conduct the remainder of the exchange. This client key is called a "premaster secret" and is a random key. Since the symmetric keys are created using this key, I wonder why not just send the symmetric key itself since the connection is encrypted and validated at this point.

Because it wouldn't be nearly as secure.

You also have some of these steps out of order.

I really don't see the point of enumerating all these steps informally when they are already completely specified in RFC 2246. There's enough misinformation about TLS floating around the Internet already, such as this piece of unmaintained drivel.

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I'll pose a man-in-the-middle attack and people can tell me why it wouldn't work: 1. Server responds to client with public key and its certificate. The certificate is signed (which means encrypted?) by a CA private key? 2. Enter Mallory, the man-in-the-middle server. I intercept this message and remove the server's certificate and put my own fake one, not based on a root certificate. My fake certificate is either self-signed or accompanied by certification info that points to my own man-in-the-middle server. 3. Send to client. 4. Take client's responses and apply the server's cert. –  Roberto Anthony Nov 12 '13 at 20:47
@Roberto But how does the attacker fake the signature by the CA with the description of what host it applies to? In HTTPS (and maybe other SSL-based systems) the client checks that the server's certificate applies to what it is supposed to, i.e. that the certificate's host name is what is expected. (At this point, the attacker hasn't been told the hostname for the server; that's only passed along later…) –  Donal Fellows Nov 12 '13 at 21:26
@Donal I'm posing a scenario where Mallory doesn't have to fake it. The man-in-the-middle makes his own cert with the correct host info in it. The man-in-the-middle fakes being a CA. –  Roberto Anthony Nov 12 '13 at 21:36
It is up to the application to verify that the authenticated peer is authorized to connect to it. SSL can't possibly know that. It's an often neglected part of SSL. HTTPS hostname verification is an example: the subject DN in the certificate must match the host being connected to, and the CA takes offline steps to ensure it only issues such certificates to entities that own the corresponding hostname. The MITM can't do what you describe. He can't 'fake being a CA' and he can't get a real CA to sign his certificate containing someone else's hostname. –  EJP Nov 12 '13 at 21:42
@EJP Thanks for the response. I'm simplifying the steps to the point I can process them at my current experience level. If I could get through the RFC2246 unassisted, I'd be a happy guy. Every source seems to skip over what "signing" means. Seems like they all assume everyone knows what that means. I surmised it has to be some sort of encoding, otherwise it could be modified/faked and the contents manipulated. Why couldn't the MITM put his own public key in the certificate in place of the server's then? –  Roberto Anthony Nov 13 '13 at 3:28

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