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Here the author makes the claim:

Formalizing the TLS specification and proving that an implementation is consistent with it only shows that the implementation is logically correct. However, it does NOT show that the implementation is secure. Your implementation can be vulnerable to side-channel attacks (particularly timing attacks) while still being logically correct.

My question is: Had a verified SSL/TLS implementation in a 'safe language' (ie Haskell, Idris) or checked with a theorem prover (Coq,Agda) would it still have been vulnerable be to the heartbleed attack?

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closed as unclear what you're asking by deceze, ScarletAmaranth, Nicolas, lunaryorn, bheklilr Apr 15 '14 at 15:55

Please clarify your specific problem or add additional details to highlight exactly what you need. As it's currently written, it’s hard to tell exactly what you're asking. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

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An OpenSSL implementation in a "safe language" would supposedly not be vulnerable to Heartbleed, which is specifically a giant flaw (not even a side channel attack) only possible in a language with direct raw memory access. Actual side channel attacks like timing attacks are certainly possible in any implementation. I'm not quite sure what the question really is. If you understand what a timing attack is, I think it's more opportune to ask for a proof that something isn't prone to it. –  deceze Apr 15 '14 at 13:14
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Using a language like Haskell or Agda would prevent whole classes of vulnerabilities and bugs like Heartbleed, but there is nothing to prevent a logically correct implementation from having other vulnerabilities. There's nothing preventing the TLS specification from having vulnerabilities itself. Someone just has to be smart (or lucky) enough to find a weak point if one exists, the problem is that it's very difficult to say whether or not one does exist. –  bheklilr Apr 15 '14 at 13:21
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Heartbleed is not a side channel attack. A side channel attack is something like this: an attacker connects and times how long it takes for the server to do operations during the SSL handshake. The exact amount of time could reveal something about what exponent is used in the server's private key, since the number of machine instructions used to do the operations may be dependent on that exponent. –  Warren Dew Apr 15 '14 at 14:22
    
@WarrenDew That is a very specific (though common and important) kind of side channel attack, namely a timing attack. Other side channel attacks use other "side channels" such as sounds, electromagnetic radiation, power consumption, supposedly erased data (cold boot attack), etc. -- the general definition of a side channel attack is anything which breaks the system without breaking the math or brute forcing, i.e. anything abusing on the physical implementation. Heartbleed falls under that definition, I would think. –  delnan Apr 15 '14 at 16:52
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Obviously my definition is narrower than yours. In general I don't count bugs in the implementation as a side channel attack; it's an implementation of something other than was specified. Even more generally, though, heartbleed isn't a cryptographic attack at all: it doesn't allow the attacker to break into encrypted communications, except as a side effect. Rather, heartbleed is a serious bug exploit, and it's mostly happenstance that the exploit appeared in cryptographic code. If it had been unencrypted TCP that was vulnerable, the vulnerability would still have been just as serious. –  Warren Dew Apr 15 '14 at 22:55

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Side channel attacks are for instance timing attacks, e.g. you can get information about the secrets by measuring timing differences when using different inputs. It is already hard to do this right in a low level language like C where you have lots of control about processor instructions, cache handling, compiler optimizations etc. It is much harder to do this correctly in higher level languages - and be still efficient enough to be usable in real-world applications.

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