Sujet : Re: Two dozen people were simply wrong --- Try to prove otherwise --- pinned down
De : polcott333 (at) *nospam* gmail.com (olcott)
Groupes : comp.theory sci.logicDate : 02. Jun 2024, 20:13:26
Autres entêtes
Organisation : A noiseless patient Spider
Message-ID : <v3ico6$3f830$2@dont-email.me>
References : 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33
User-Agent : Mozilla Thunderbird
On 6/2/2024 1:02 PM, Fred. Zwarts wrote:
Op 02.jun.2024 om 16:37 schreef olcott:
On 6/2/2024 3:56 AM, Fred. Zwarts wrote:
Op 01.jun.2024 om 22:11 schreef olcott:
On 6/1/2024 2:04 PM, Fred. Zwarts wrote:
Op 01.jun.2024 om 20:44 schreef olcott:
On 6/1/2024 1:40 PM, Fred. Zwarts wrote:
Op 01.jun.2024 om 18:24 schreef olcott:
On 6/1/2024 11:19 AM, Fred. Zwarts wrote:
Op 01.jun.2024 om 18:13 schreef olcott:
On 6/1/2024 10:56 AM, Richard Damon wrote:
On 6/1/24 11:30 AM, olcott wrote:
>
*I will not discuss any other points with you until after you either*
(a) Acknowledge that DD correctly simulated by HH and ⟨Ĥ⟩ ⟨Ĥ⟩ correctly
simulated by embedded_H remain stuck in recursive simulation for
1 to ∞ of correct simulation or
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(b) Correctly prove otherwise.
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And until you answer the question of what that actually means, I will reply WHO CARES.
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typedef int (*ptr)(); // ptr is pointer to int function in C
00 int HH(ptr p, ptr i);
01 int DD(ptr p)
02 {
03 int Halt_Status = HH(p, p);
04 if (Halt_Status)
05 HERE: goto HERE;
06 return Halt_Status;
07 }
08
09 int main()
10 {
11 HH(DD,DD);
12 return 0;
13 }
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Every DD correctly simulated by any HH of the infinite set of HH/DD
pairs that match the above template never reaches past its own simulated
line 03 in 1 to ∞ steps of correct simulation of DD by HH.
>
In this case HH is either a pure simulator that never halts or
HH is a pure function that stops simulating after some finite number
of simulated lines. The line count is stored in a local variable.
The pure function HH always returns the meaningless value of 56
after it stops simulating.
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The simulated D never reaches past line 03, because the simulated HH never halts in 1 to ∞ steps of correct simulation of HH by HH.
I have told you that so many times.
HH is required to halt, thus HH does not match the requirement.
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HH correctly reports that because DD calls HH(DD,DD) in
recursive simulation that DD never halts.
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HHH(HH,DD,DD) would report that HH halts.
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Maybe. And H1 (DD,DD) would report that DD halts.
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In the recursive simulation by HH, neither the simulation of DD, nor the simulation of HH halts. If one of them would halt, the other one would halt as well.
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So HH 'correctly' reports that both DD and HH do not halt, because they both keep starting an instance of each other.
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I will not respond to any of your replies while you continue to play
head games.
>
*Changing the subject away from this is construed as a head game*
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Bad excuse. I am not changing the subject. I show that the requirements of HH in the subject are contradictory.
>
DD correctly simulated by pure function HH cannot possibly reach
past its own line 03 in any finite number of steps of correct
simulation.
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Only, because the simulation of HH did not halt.
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In case you didn't know pure functions must halt because they must
return a value.
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I know that HH is required to halt, but your own words implies that it doesn't. So apparently your HH does not match its requirements.
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Correct me if I am wrong and show the trace of the simulated HH that reaches its final state and the next 10 instructions.
>
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Pages 4-5 of
*The 2021-09-26 version of my first paper on simulating halt deciders*
*Halting problem undecidability and infinitely nested simulation*
https://www.researchgate.net/publication/351947980_Halting_problem_undecidability_and_infinitely_nested_simulation
>
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I looked at it, but I could not find where the ret instruction of the simulated H simulated by itself was printed. Could you please tell the page number? I want to know how the simulation proceeds after this return.
I only see the ret instruction simulated by another H. I hope it is not an attempt to change the subject.
>
P correctly simulated by H cannot possibly reach its "ret" instruction.
All of the instructions of H are screened out otherwise the execution
trace of P would be mixed into with hundreds of other pages of P.
So, we agree that there is no proof that H correctly simulated by itself reaches its ret instruction.
You just might not understand the subject matter will enough.
As far as this proof goes (Maybe you need to read it again)
Pages 4-5 of
*The 2021-09-26 version of my first paper on simulating halt deciders*
*Halting problem undecidability and infinitely nested simulation*
https://www.researchgate.net/publication/351947980_Halting_problem_undecidability_and_infinitely_nested_simulation We can tell that H has returned to main() because we see that after
main() has called H(P,P) at its machine address [00000c63] the next
instruction of main() [00000c68] is executed.
So, I think we should also agree on the fact that HH above, when 'correctly' simulated by itself cannot possibly reach its own final state, because HH demonstrates a repeating state.
DD calling HH(DD,DD) demonstrates a repeating state that the executed
HH recognizes and reports.
-- Copyright 2024 Olcott "Talent hits a target no one else can hit; Geniushits a target no one else can see." Arthur Schopenhauer
D correctly simulated by H cannot possibly halt --- templates and infinite sets
Re: D correctly simulated by H cannot possibly halt --- templates and infinite sets