# What makes the trapdoor function in elliptic curve cryptography hard to reverse?

In the article, they state:

It turns out that if you have two points [on an elliptic curve], an initial point "dotted" with itself n times to arrive at a final point [on the curve], finding out n when you only know the final point and the first point is hard.

It goes on to state that the only way to find out n (if you only have the first and final points, and you know the curve eqn), is to repeatedly dot the initial point until you finally have the matching final point.

I think I understand all this - but what confuses me is - if n is the private key, and the final point corresponds to the public key (which I think is the case), then doesn't it take the exact same amount of work to compute the public key from the private, as it does the private from the public (both just have to recursively dot a point on the curve)? am I misunderstanding something about what the article is saying?

• Cryptography is much better suited for this type of question. This is particularly off-topic for StackOverflow, because it doesn't directly involve programming. – Artjom B. Mar 24 '15 at 19:52
• I'm voting to close this question as off-topic because it belongs on crypto.stackexchange.com – erickson Mar 24 '15 at 19:57
• If you naively computed B+B+B+... n times, it'd be indeed too expensive. But you can Compute 2B=B+B and then 4B=2B+2B etc. reducing the number of point additions to the logarithm of the exponent. See en.wikipedia.org/wiki/Exponentiation_by_squaring – CodesInChaos Mar 24 '15 at 22:22
• @ArtjomB - sorry - I didn't know there was a crypto based stack exchange! I can search and maybe re-ask over there. Thanks - and my bad. – user1971524 Mar 25 '15 at 2:08

EDIT: I previously stated that n is not the private key. In your example, n is either server or client private key.

How it works is that there is a starting point known to anybody.

• You select random integer k and do the "dotting operation" k-times. Then you send this new point to the server. (k is your private key)
• Server does the same with the starting point, but q-times and sends it to you. (q is server's private key)
• You take the point you got from server and "dot" it k-times. The final point would be the starting point "dotted" k*q-times.
• Server does the same with point it got from you. And again its final point would be the starting point "dotted" q*k-times.

That means the final point (= the starting point "dotted" k*q-times) is the shared secret since all what any attacker would know is the starting point, the starting point dotted k-times and the starting point dotted q-times. And given only those data, it's practically impossible to find the final point as a product of k*q unless any of those known.

EDIT: No, it doesn't take the same time to compute k from G = kP given known values of G (sent point) and P (starting point). More in comment section and:

• This sounds like Elliptic-Curve Diffie-Hellman - is there also an elliptic curve asymmetric key crypto algorithm? - Also, maybe I didn't phrase my question totally clearly - but I guess what I mean to ask is: in your example - what is to prevent an attacker from simply listening in to the first transmission from me to the server, and then just dotting the known starting point until they hit the correct ending point? doesn't it still just take k operations? – user1971524 Mar 25 '15 at 2:07
• 1) There is no pure ECC algorithm (at least that's what I know), because to decrypt any message, you need to do the "inverse dotting", but look at ElGamal ES. – user2781994 Mar 25 '15 at 19:18
• @user1971524 2) Imagine k being similarly sized as the point itself. Given computational power of today's computers (approx. 10^9 operations per second), just trying to determine k from G = kP given known values of G (sent point) and P (starting point) would take more time than what is the lifespan of the Earth; this is called elliptic curve discrete logarithm problem. If you know the power you want to raise to (your private key), you can use 2P=P+P; 4P=2P+2P... – user2781994 Mar 25 '15 at 19:46