I mean what I'm saying, by the way. As long as you're OK with assuming you can have a logical prior in the first place, I don't see any issue with representing LCM with the diagram I made.
Yes, it means the LCM is no different to the CM, but I don't see an issue with that. Apart from the question of involving different kinds of priors (logical vs non-logical) the two problems are indeed identical.
If I'm missing something, please tell me what it is; I'd like to know!
I agree that your diagram gives the right answer to logical Counterfactual Mugging. The problem is that it's not formal enough, because you don't really explain what a "logical prior" is. For example, if we have logical Counterfactual Mugging based on a digit of pi, then one of the two possible worlds is logically inconsistent. How do we know that calculating the digit of pi by a different method will give the same result in that world, rather than blow up the calculator or something? And once you give a precise definition of "logical prior", the problems begin to look more like programs or logical formulas than causal diagrams.
This post was inspired by Benja's SUDT post. I'm going to describe another simplified model of UDT which is equivalent to Benja's proposal, and is based on standard game theory concepts as described in this Wikipedia article.
First let's define what is a "single player extensive-form game with chance moves and imperfect information":
Now let's try using that to solve some UDT problems:
Absent-Minded Driver is the simplest case, since it's already discussed in the literature as a game of the above form. It's strange that not everyone agrees that the best strategy is indeed the best, but let's skip that and move on.
Psy-Kosh's non-anthropic problem is more tricky, because it has multiple players. We will model it as a single-player game anyway, putting the decision nodes of the different players in sequence and grouping them together into information sets in the natural way. The resulting game tree is complicated, but the solution is the same as UDT's. As a bonus, we see that our model does not need any kind of anthropic probabilities, because it doesn't specify or use the probabilities of individual nodes within an information set.
Wei Dai's coordination problem is similar to the previous one, but with multiple players choosing different actions based on different information. If we use the same trick of folding all players into one, and group the decision nodes into information sets in the natural way, we get the right solution again. It's nice to see that our model automatically solves problems that require Wei's "explicit optimization of global strategy".
Counterfactual Mugging is even more tricky, because writing it as an extensive-form game must include a decision node for Omega's simulation of the player. Some people are okay with that, and our model gives the right solution. But others feel that it leads to confusing questions about the nature of observation. For example, what if Omega used a logical coin, and the player could actually check which way the coin came up by doing a long calculation? Paying up is probably the right decision, but our model here doesn't have enough detail.
Finally, Agent Simulates Predictor is the kind of problem that cannot be captured by our model at all, because logical uncertainty is the whole point of ASP.
It's instructive to see the difference between the kind of UDT problems that fit our model and those that require something more. Also it would be easy to implement the model as a computer program, and solve some UDT problems automatically. (Though the exercise wouldn't have much scientific value, because extensive-form games are a well known idea.) In this way it's a little similar to Patrick's work on modal agents, which made certain problems solvable on the computer by using modal logic instead of enumerating proofs. Now I wonder if other problems that involve logical uncertainty could also be solved by some simplified model?