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MisterMiyagi
MisterMiyagi
06:11
@polcott I am really at a loss what to say. A proper halting solver does derive one of true or false result in finite time for its input. That's practically the definition. If you rely on the halting solver candidate H inside P never reaching a result it is not a general halting solver, again by definition.
The conventional proof is based on using an oracle of a general halting solver. Again, that's it's definition. If you plug in a non-general halting solver then you are not actually looking at the convention proof.
I'm not sure whether this is a communication problem or some other misunderstanding. If you want to go on here, I recommend we go through the conventional proof together.
polcott
polcott
@MisterMiyagi H(P,P) returns 0 to main().
MisterMiyagi
MisterMiyagi
@polcott It also has to return something to P, though.
As you claim, it does not.
Therefore, H is incapable of deriving a result for any arbitrary input. That makes it not a general halting solver.
polcott
polcott
@MisterMiyagi This explains why no H ever returns a value to any simulated P: If you understand that a function called in infinite recursion cannot possibly return to its caller then you should understand that recursive simulation has the same result.
MisterMiyagi
MisterMiyagi
I understand the technical reason very much.
That does not change that a general halting solver has to derive a result for any input in finite time.
If for technical reasons your candidate does not, that still means it is not a general halting solver.
polcott
polcott
@MisterMiyagi Then you should be able to see why the P that H simulates never stops running until H aborts its simulation of P. I have to go to bed now
MisterMiyagi
MisterMiyagi
06:20
@polcott Again, I have no issue understanding the technical reason why the solution does not work. The problem is that it has to work to allow the conclusions you want to derive.
polcott
polcott
06:36
@MisterMiyagi It only has to work for the conventional "impossible" input to refute all of the conventional proofs.
@MisterMiyagi I spent the last four full time years in this.
@MisterMiyagi "I have no issue understanding the technical reason why the solution does not work." I have addressed thousands of reviews by dozens of reviewers. All of the rebuttals had false assumptions.
@MisterMiyagi Complete halt deciding system (Visual Studio Project)
(a) x86utm operating system
(b) x86 emulator adapted from libx86emu to compile under Windows
(c) Several halt deciders and their sample inputs contained within Halt7.c
https://liarparadox.org/2022_09_07.zip
MisterMiyagi
MisterMiyagi
06:57
@polcott Look, every time you are going to reiterate how much time you spent on this and how many reviews you have dismissed, this is not making you convincing. It only suggests that you have too much personal stakes in this to listen to input.
polcott
polcott
@MisterMiyagi I have always thought of credibility as a fake measure of truth. It is no amount of believe or fail to believe. It is a matter of comprehend or fail to comprehend.
MisterMiyagi
MisterMiyagi
07:14
@polcott Then please try and comprehend that others have not spent your four years on the matter and have not seen your rebuttals. Presenting your findings in a comprehensible way is an integral part of science. If people fail to comprehend your presentation of your findings, you will have to go towards their current point instead of further away from it.
For me that would for example mean walking through the "conventional proof" and showing where my assumption (that a general halting solver is required) is wrong. Only then am I at a point where you can convince me that your non-general halting solver disproves the proof.
 
8 hours later…
polcott
polcott
15:10
In computability theory, the halting problem is the problem
of determining, from a description of an arbitrary computer
program and an input, whether the program will finish running,
or continue to run forever. Alan Turing proved in 1936 that a
general algorithm to solve the halting problem for all possible
program-input pairs cannot exist.

For any program H that might determine if programs halt, a
"pathological" program P, called with some input, can pass its own
source and its input to H and then specifically do the opposite of
typedef void (*ptr)();
int H(ptr p, ptr i); // simulating halt decider

// P does the opposite of whatever H decides
void P(ptr x)
{
int Halt_Status = H(x, x);
if (Halt_Status) // if H(P,P) reports that its input halts
HERE: goto HERE; // P loops and never halts
return; // else P halts
}

int main()
{
Output("Input_Halts = ", H(P, P));
}
@MisterMiyagi Then the proofs simply says that H cannot return 0(false) or 1(true) because P will do the opposite of this thus making H wrong.
MisterMiyagi
MisterMiyagi
@polcott The proof says that H must return false or true (since it is a general halting solver) and that is wrong because P will do the opposite of this thus making H wrong.
polcott
polcott
@MisterMiyagi Yes that is it in its simplest form.
@MisterMiyagi When H is a simulating halt decider then P remains stuck in recursive simulation until H aborts its simulation of P. This P correctly simulated by H cannot reach any code in its own body past its call to H. This prevents its from doing the opposite of whatever H returns. It cannot reach this return value. This defeats all of the conventional proofs.
@MisterMiyagi The code in my projects does better than this. H actually correctly recognizes that the P that it is simulating cannot possibly reach its own final state and halt. H examines several dynamic behavior pattern (a) infinite loop (b) infinite recursion (c) recursive simulation.
@MisterMiyagi
void Infinite_Recursion(u32 N)
{
Infinite_Recursion(N);
}
@MisterMiyagi once my code is examined to see that it does correctly determine that the above is non-halting because it specifies infinite recursion, then this same reasoning can be applied to H and P. Recursive simulation has the same behavior pattern as infinite recursion. H correctly matches these patterns.
@MisterMiyagi **Complete halt deciding system (Visual Studio Project)**
(a) x86utm operating system
(b) x86 emulator adapted from libx86emu to compile under Windows
(c) Several halt deciders and their sample inputs contained within Halt7.c
https://liarparadox.org/2022_09_07.zip
MisterMiyagi
MisterMiyagi
16:12
@polcott Yet that means that H does not return false or true in some conditions, meaning it is not a general halting solver.
So any examples using just this H do not demonstrate anything about the behaviour of a general halting solver (since there is none involved).
So, one way or another you would have to explain either why a) a general halting solver is not required for the conventional proof (difficult since that's how it is defined) or b) how the behaviour of a non-general halting solver generalises to a general halting solver.
Can you explain that to me?
polcott
polcott
@MisterMiyagi As soon as the conventional "impossible" input has its halt status correctly determined then all of the conventional halting proofs that depend on this impossibility lose their basis and fail.
MisterMiyagi
MisterMiyagi
@polcott Since you are not running on the conventional input (since it would use a general halting solver, not your non-general one) I don't see how you can claim you are determining its halt status at all, let alone correctly.
If you say "not halting" is the correct output for any solver, then we can replace the recursive call to H by this output. But then "not halting" is the wrong output...
polcott
polcott
16:27
@MisterMiyagi "Since you are not running on the conventional input" I just proved that I am. The C source code that I posted exactly meets the Wikipedia specs.
MisterMiyagi
MisterMiyagi
@polcott No. The Wikipedia specs has requirements on H that yours does not meet.
Specifically, that it provides an output of either true or false for any input.
Yours specifically does not when its input is already being evaluated.
polcott
polcott
16:42
@MisterMiyagi Do you understand that a function called in infinite recursion cannot possibly correctly return any value to its caller?
polcott
polcott
17:06
@MisterMiyagi If you don't understand this then you do not have the mandatory prerequisite knowledge to understand what I would say next.
MisterMiyagi
MisterMiyagi
17:20
@polcott yes.
Do you understand that a general halting solver must correctly return a value even when called in infinite recursion?
That your simulating solver cannot only shows that it is not appropriate as a general solver.
polcott
polcott
@MisterMiyagi Then you should be able to understand that recursive simulation has essentially the same behavior pattern. No P correctly simulated by H can possibly correctly receive any return value from any H.
MisterMiyagi
MisterMiyagi
@polcott Again, I do understand that.
In case you haven’t noticed, that proves that you cannot solve the halting problem.
polcott
polcott
@MisterMiyagi If you do sufficiently understand that then you would also understand that no H can correctly return any value to any P simulated by any H.
@MisterMiyagi H returns a value of 0 to main() indicating that its input is stuck in infinitely recursive simulation.
@MisterMiyagi H aborts its simulation of P before P ever invokes H once. A function that was never invoked must not return any value.
MisterMiyagi
MisterMiyagi
@polcott well, yes. That is exactly what the halting problem says.
@polcott but a general halting solver must return a value for any input.
polcott
polcott
@MisterMiyagi Thus H is a Turing computable function that meets the definition of a decider.
MisterMiyagi
MisterMiyagi
17:30
@polcott then it would be able to return a value Inside P
polcott
polcott
@MisterMiyagi When a halting function is not invoked it must not return any value.
MisterMiyagi
MisterMiyagi
@polcott it is invoked by P
polcott
polcott
@MisterMiyagi "then it would be able to return a value Inside P" When a function called in infinite recursion or infinitely recursive simulation returns a value to its caller IT IS WRONG
@MisterMiyagi The very first invocation of H by P is terminated before it occurs.
MisterMiyagi
MisterMiyagi
If your solver cannot simulate that, it is a deficiency of the solver. P would invoke H and by definition H would have to return a value.
polcott
polcott
@MisterMiyagi In other words you insist that a function called in infinite recursion must return a value to its caller even though this is impossible by definition. Thus making your view incoherent and rejected on the basis of this incoherence.
MisterMiyagi
MisterMiyagi
17:35
@polcott no! I insist that a general halting solver has to return a value.
polcott
polcott
@MisterMiyagi H does return 0 to main();
MisterMiyagi
MisterMiyagi
If your H does not-because it uses recursion and this cannot- it is not suitable as a general halting solver.
polcott
polcott
@MisterMiyagi The simulated instances of H do not return any value to any of the simulated instances of P.
MisterMiyagi
MisterMiyagi
That you chose an implementation that is inappropriate to meet the requirements does not change the requirements.
@polcott And that is the problem: it has to in order to satisfy the requirements.
polcott
polcott
@MisterMiyagi So basically you do not understand that it is always incorrect for any function called in infinite recursion to return a value to its caller, thus you do not have the mandatory prerequisite knowledge that you claimed to have.
MisterMiyagi
MisterMiyagi
17:40
@polcott No, I have repeatedly acknowledged that this is correct for a recursive function.
polcott
polcott
@MisterMiyagi And you agreed that this equally applies to recursive simulation?
MisterMiyagi
MisterMiyagi
Yes!
Finally we are at yes/no…
polcott
polcott
@MisterMiyagi Then any requirement that a simulated H return any value to a simulated P is understood to be incorrect? (otherwise you just contradicted yourself).
MisterMiyagi
MisterMiyagi
No.
polcott
polcott
@MisterMiyagi If you say that all X are Y and then say that some Y are not X you contradicted yourself.
MisterMiyagi
MisterMiyagi
17:43
There are requirements for any H. That your choice of simulation is incapable of meeting them does not change these requirements.
polcott
polcott
@MisterMiyagi H need not return any value to P if this instance of H is never invoked.
MisterMiyagi
MisterMiyagi
@polcott a requirements is something other than a feature. That the feature (does not return) does not meet the requirement (does return) changes neither the feature nor requirements.
polcott
polcott
@MisterMiyagi So you insist that a function that was never invoked must still return a value?
MisterMiyagi
MisterMiyagi
No. I insist that H must be able to return a value.
If your implementation does not, or your simulation of your implementation does not, then that is the failure of your code to meet the requirements.
polcott
polcott
@MisterMiyagi That is a contradiction you already agreed that it cannot possibly correctly return a value: "you agreed that this equally applies to recursive simulation?"
MisterMiyagi
MisterMiyagi
17:49
I am not questioning that your implementation cannot. I am questioning that you follow from this that your implementation does not have to do so.
Note again that the conventional proof is a proof by contradiction: that requirements and behaviour lead to contradiction is exactly what the proof says.
polcott
polcott
@MisterMiyagi All of the thousands of reviews by dozens of reviewers in the last 12 months that attempted any rebuttal of my work were always self-contradictory as your view is self-contradictory.
MisterMiyagi
MisterMiyagi
@polcott that is the proof of the halting problem: that any proper approach leads to a self contradiction.
polcott
polcott
@MisterMiyagi When I show that a simulating halt decider H correctly determines that its input P is stuck in infinitely recursive simulation then it is necessarily correct for H to report that its input specifies non-halting behavior.
MisterMiyagi
MisterMiyagi
But H has to do more than that!
polcott
polcott
@MisterMiyagi The HP proofs must derive a contradiction they cannot themselves be self-contradictory. I show that they do not actually derive a contradiction.
@MisterMiyagi a halt decider H must compute the mapping from its input finite string P to an accept or reject state based on the actual behavior that P specifies.
@MisterMiyagi The definition of a UTM specifies that the correct simulation of a machine description does show that actual behavior that this machine description specifies, thus when H correctly simulates 1 to ∞ steps of P this is the actual behavior of P.
@MisterMiyagi When H must do X (return a value to a simulated P) and H must not do X (return a value to a simulated P) the specification of the problem is incoherent and is rejected on that basis.
 
2 hours later…
polcott
polcott
20:04
@PM2Ring "If the Halting Oracle halts, the program-under-test can access its return value." It is not an oracle. No function called in infinite recursion or infinitely recursive simulation can correctly return any value to their caller. In the case of P and H, H aborts its simulation of P before the simulated P invokes its first call to H.

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