@polcott "It is common knowledge that the correct simulation of a machine description provides its actual behavior." That's exactly why I am asking you this question: because it would verify that your simulation is actually correct.
You are making a pretty strong claim here: That H(P, P) correctly describes the halting behaviour of P(P) when the currently accepted consensus in Computer Science is that there is no such correct description possible.
So before claiming that H(P, P) correctly describes P(P), you should first show that the description is possible.
That's trivially done by executing P(P) and observing whether it halts.
("MisterMiyagi, why don't you do it yourself if it is so trivial?" you might ask? A) Because the setup of your proof is highly non-portable and won't run on my system, and B) Because we should agree on the result before going on another tangent; your refusal to provide such an obvious reference point seems fishy.)
@MisterMiyagi for laughs I ran it (both P(P) and the "Strachey" version) and in what I'm sure will come as no surprise to you they both halt, contradicting the result of both the corresponding halt deciders and therefore neatly supporting that both proofs of the halting problem hold.
Once one accepts the notion of a simulating halt decider that continues to correctly simulate its input until it correctly determines that this simulated input would never stop running then the conventional halting problem proofs are refuted because their "impossible" input becomes correctly construed as specifying recursive simulation (same idea as infinite recursion).
@MisterMiyagi --- int sum(int x int y) { return x + y; }
H(P,P) is not allowed to report on int main() { P(P); } in the same way that sum(3,4); is not allowed to report on sum(5,6); Computable functions are only allowed to report on their actual inputs.
@MisterMiyagi It can be seen from an execution trace that int main() { P(P); } is not the behavior that H is reporting on. The correct simulation by H of its input has different behavior.
@polcott You really should start by saying you've changed the definition of halting, and by extension the question that a halt decider is asking, to fit the results that H is able to come up with.
@MisterMiyagi He thinks that H(P,P) should be answering the question "does there exist an implementation of the function H that can simulate the function call P(P) to a final state"
@dbush Yes, I know that since I looked at their paper... It's getting really frustrating to make them see that the two questions are not interchangeable.
@polcott I am. I understand exactly what you've been saying all this time. You just don't like that being clear about what you're saying also makes it clear you're not working on the halting problem.
@polcott It must be correctly simulated line by line. If the real execution goes through the lines differently than the simulation, the simulation is not correct.
@MisterMiyagi If you understand the x86 language you can easily verify that the simulation of P by H is correct by comparing the execution trace of the simulation P to its x86 source code.
@dbush When on examines every element of the infinite set of possible encodings for H such that elements of this set correctly simulate 1 to ∞ steps of P, one finds that none of the correctly simulated P ever reach their "return" instruction final state.
@polcott And each of those H's is reporting on a different P. The exact H that P calls count as part of P. You can't just pretend that P calls H because that changes what you're deciding on.
@MisterMiyagi A simulation is NECESSARILY correct if the line-by-line execution trace of the simulated input exactly matches what its x86 source-code specifies.
@MisterMiyagi It can't be wrong. The measure of a correct simulation is always whether or not the execution trace of the simulated input matches what is specified by the source-code.
@MisterMiyagi A simulating halt decider computes the mapping from its input finite string to an accept or reject state on the basis of the actual behavior specified by this input as measured by its correct simulation of this input.
@dbush You are measuring at the wrong place in the execution trace. It must be its can cannot be the when the input and the halt decider are defined to have a pathological relationship to each other. In every other case its and the have the same behavior.
Because if H is a halt decider as per the definition:
For *any* algorithm (i.e. a fixed immutable sequence of instructions) X and input Y, an algrothim H(x,y) is a halt decider if: H(X,Y)==1 if and only if X(Y) halts, and H(X,Y)==0 if and only if X(Y) does not halt
@polcott That input maps to halting, which means it's in the domain of the halting function. Therefore, the halting function is not a computable function.
@polcott Well done. You've, once again, validated the proof you were trying to refute.
@dbush My ultimate purpose is to refute the Tarski Undefinabilty theorem to anchor Davidson's truth conditional semantics in a formal notion of truth. I must do that indirectly because only computations comprise correct formal systems. The notion of other formal systems have well hidden false assumptions.
@dbush The definition of a simulating halt decider proves itself to be correct entirely on the basis of the meaning of its words.
@polcott And your definition of a simulating halt decider makes it clear it is not a halt decider.
@polcott Because if it was, it would fit the definition of one:
For *any* algorithm (i.e. a fixed immutable sequence of instructions) X and input Y, an algrothim H(x,y) is a halt decider if: H(X,Y)==1 if and only if X(Y) halts, and H(X,Y)==0 if and only if X(Y) does not halt
@polcott I don't see how that is the case. The point of simulation is to simulate execution of source, so it should match that execution instead of just the source code.
At the very least, if the source code accurately describes its execution as well then both source code and source code execution should come to the same conclusion.
The entire discussion here seems to have gone downhill, so I'm putting an end to it. @polcott: you've already been told to stop (by another mod, even), and you seem to have chosen to disregard that, and escalated it further. Enough is enough
