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On 6/15/24 12:22 PM, olcott wrote:When we can see that D correctly simulated by H cannot possiblyOn 6/13/2024 8:24 PM, Richard Damon wrote:Nope, the steps of D correctly simulated by H will EXACTLY match the steps of D directly executed, until H just gives up and guesses.
> On 6/13/24 11:32 AM, olcott wrote:
>>
>> It is contingent upon you to show the exact steps of how H computes
>> the mapping from the x86 machine language finite string input to
>> H(D,D) using the finite string transformation rules specified by
>> the semantics of the x86 programming language that reaches the
>> behavior of the directly executed D(D)
>>
>
> Why? I don't claim it can.
>
The first six steps of this mapping are when instructions
at the machine address range of [00000cfc] to [00000d06]
are simulated/executed.
>
After that the behavior of D correctly simulated by H diverges
from the behavior of D(D) because the call to H(D,D) by D
correctly simulated by H cannot possibly return to D.
By your defintions, the ONLY correct simulation of D by H MUST follow the call H into the instructions of H, and then continue there forever until H either gives up simulating, or it happens to simulate the return from H to D (which doesn't look like it will ever happen).Yes and when I say 2 + 3 = 5 you are not free to disagree and be
This is the ONLY thing that matches your definition of Correct Simulation.The x86 language defines the semantics of correct simulation that
And that means that you definition of the "Input" is shown to be incorrect (or insufficient for H to do what it needs to do). The input CAN NOT be just those instructions shown below, but must include the contents of ALL the memory used by the program.It is the sequence of x86 instructions specified by the machine
And this comes out naturally, because to ask about the program represented by the input, the input needs to represent a FULL PROGRAM, which includes ALL of the algorithm used by the code, so ALL of the program.That D calls H in recursive simulation is what makes D correctly
Thus, the input "D", includes its copy of H that was DEFINED by Linz and Sipser to be part of the machine, and when you do your logic, you can't change that code.When Ĥ is applied to ⟨Ĥ⟩
If this means that you can't do your imagining of different Hs, then you can't do that operation.--
Any H you imagine being given the same input as this H, must see the code for that original H, not the new hypothetical H you are imagining.
Which sort of blows you your whole argument.
>
_D()
[00000cfc](01) 55 push ebp
[00000cfd](02) 8bec mov ebp,esp
[00000cff](03) 8b4508 mov eax,[ebp+08]
[00000d02](01) 50 push eax ; push D
[00000d03](03) 8b4d08 mov ecx,[ebp+08]
[00000d06](01) 51 push ecx ; push D
[00000d07](05) e800feffff call 00000b0c ; call H
[00000d0c](03) 83c408 add esp,+08
[00000d0f](02) 85c0 test eax,eax
[00000d11](02) 7404 jz 00000d17
[00000d13](02) 33c0 xor eax,eax
[00000d15](02) eb05 jmp 00000d1c
[00000d17](05) b801000000 mov eax,00000001
[00000d1c](01) 5d pop ebp
[00000d1d](01) c3 ret
Size in bytes:(0034) [00000d1d]
>
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