Let T = {<M> | M is a TM that accepts w

^{r}whenever it accepts w}.

Show that T is undecidable.

I have two answers to this question - San Diego:

5.9

Let T = { <M> | M is a TM that accepts w^{r}whenever it accepts w }.Assume T is decidable and let decider R decide T. Reduce from A

_{TM}by constructing a TM S as follows:

- S: on input <M,w>

- create a TM Q as follows:

On input x:

- if x does not have the form 01 or 10 reject.
- if x has the form 01, then accept.
- else (x has the form 10), Run M on w and accept if M accepts w.
- Run R on
- Accept if R accepts, reject if R rejects.
Because S decides A

_{TM}, which is known to be undecidable, we then know that T is not decidable

Undisclosed source:

5.12We show thatA_{TM}≤_{m}Sby mapping ‹M,w› to ‹M'› whereM'is the following TM:

M'= “On inputx:

- If
x= 01 thenaccept.- If
x≠ 10 thenreject.- If
x= 10 simulateMonw.

IfMacceptswthenaccept; ifMhalts and rejects thenreject.”If ‹

M,w› ∈A_{TM}thenMacceptswandL(M') = {01,10}, so ‹M'› ∈S.

Conversely, if ‹M,w› ∉A_{TM}thenL(M') = {01}, so ‹M'› ∉S. Therefore,

‹M,w› ∈A_{TM}⇔ ‹M'› ∈S.

But I do not understand the following:

1- what is the relation between x and w?

2- why we consider the 2 cases ‹*M*, *w*› ∈ *A*_{TM} and ‹*M*, *w*› ∉ *A*_{TM}?

3- why if A is mapping reducible to S this makes S undecidable?

could anyone clarify these points for me?