NP problems look like they are suitable for use as trapdoor functions or proofs of work, since they are difficult to solve, but easy to verify. Unfortunately, they seem a little hard to use in adversarial settings where an opponent can control problem selection because while worst-case problems are NP, particular instances can be solved very quickly.

So: is there any algorithm which can take instances and estimate - more efficiently than trying to solve them - how hard or close to worst-case they are?

(The context is musing about a Bitcoin protocol where the proofs-of-work were reusable and not useless hash checks. The obvious approach is to have a central authority issue, for each transaction block, a NP instance which corresponds to a real-world problem. But the central authority could be subverted, and start issuing easy problems which would render the network vulnerable to double-spends. One could accept problems from multiple authorities, or anyone, but the chosen-easy problem remains. If there were some way to *estimate* the difficulty of any problem presented to the network, then 'too easy' problems could simply be ignored, falling back to the hash race if necessary.)

EDIT: jaxtr links me to "Predicting Satisfiability at the Phase Transition", which gives algorithms which estimate hardness at 70% accuracy - but they don't seem to investigate whether the algorithm can be deliberately fooled. (As well, one can apparently generate SAT problems with specified probabilities of being satisfiable.)