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On 6/15/24 8:48 PM, olcott wrote:Sure it is you are just clueless.On 6/15/2024 7:13 PM, Richard Damon wrote:But it isn't an infinite set.On 6/15/24 8:05 PM, olcott wrote:>On 6/15/2024 6:37 PM, Richard Damon wrote:>On 6/15/24 7:30 PM, olcott wrote:>On 6/15/2024 6:01 PM, Richard Damon wrote:WHAT "Mathematical Induction"?On 6/15/24 5:56 PM, olcott wrote:>On 6/15/2024 11:33 AM, Richard Damon wrote:>On 6/15/24 12:22 PM, olcott wrote:>On 6/13/2024 8:24 PM, Richard Damon wrote:>
> 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.
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.
>
When we can see that D correctly simulated by H cannot possibly
reach its simulated final state at machine address [00000d1d]
after one recursive simulation and the same applies for 2,3,...N
recursive simulations then we can abort the simulated input and
correctly report that D correctly simulated by H DOES NOT HALT.
Nope. Because an aborted simulation doesn't say anything about Halting,
>
It is the mathematical induction that says this.
>
>
A proof by induction consists of two cases. The first, the base
case, proves the statement for n = 0 without assuming any knowledge
of other cases. The second case, the induction step, proves that
if the statement holds for any given case n = k then it must also
hold for the next case n = k + 1 These two steps establish that the
statement holds for every natural number n.
https://en.wikipedia.org/wiki/Mathematical_induction
Ok, so you can parrot to words.
>>>
It is true that after one recursive simulation of D correctly
simulated by H that D does not reach its simulated final state
at machine address [00000d1d].
Which means you consider that D has been bound to that first H, so you have instruciton to simulate in the call H.
>>>
*We directly see this is true for every N thus no assumption needed*
It is true that after N recursive simulations of D correctly
simulated by H that D does not reach its simulated final state
at machine address [00000d1d].
Nope, because to do the first step, you had to bind the definition of the first H to D, and thus can not change it.
So infinite sets are permanently beyond your grasp.
The above D simulated by any H has the same property
of never reaching its own simulated machine address
at [00000d1d].
>
What I mistook for dishonestly is simply a lack
of comprehension.
>
We don't ask an infinite set a question, or give a decider an infinite set of inputs.Yes we do and this is simply over your head.
We can pose the same question to an infinite set of machines, but we judge each of them individually.--
I thought you finally caught on that Linz is talking about taking *A* Turing Machine H that is assumed to be a Halt Decider, and building for it *AN* input H^ that he shows creates an impossible situation, so that H could not exist.
You are just trying to obfuscate things by throwing in "infinte sets" but we still need to process them each individually.
Yes, we can do that in parallel, but in individual problem units.
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