The "storage by immediate in code" variant:
; handle bits 0 and 7
; handle bits 1 and 6
; handle bits 2 and 5
; handle bits 3 and 4
EDIT: About my comment under question and general answer whether there's a way.
You should always just ask the math theory first. In your case you are deterministically changing 8 bit information into other 8 bit information result, and the minimal modification step needed is "swap of two bits", which is impossible to do without third bit for temporary storage, so you are now looking for a way to supplement temporary storage without extra register ("and memory" I did add to myself).
Thus if you want to mirror
al without changing other register (not counting
eflags, as that would be 99% impossible completely), you need to "borrow" this extra bit elsewhere.
As the digital computers are turing-like machines, you can exchange missing bits in registers/storage by using bits of code instructions, so theoretically it is possible => QED.
After that basic "validation" of question it was just question to find out, what kind of code structure does provide that extra information bit storage and swap bits.
The most direct brutal way is to have branching per bit-value, ie.
; else bit_0_set branch follows (each branch can then do the correct set/reset of target bits to make it look like it did swap them)... I wouldn't dare to write the complete code like that (too long, too tedious), but this is one root of the solution above.
The other root of solution was to put this code idea against the "what has to be really done", and that is "swapping bits on particular positions". But that can be optimized out, when the bits already have the same value = no swap needed. And "swapping" two bits when they are different can be achieved by simple
xor flipping both of them.
After I merged all those idea-trains to single solution, I got almost what is above, then I just cleaned it a bit (like figuring out the "two bits are same" test can be simplified down to single
test + jpe) and verified it works.
But whenever in doubt, just remember how Turing machine works :))) (semi-joke, I wouldn't really want to write any medium-sized algorithm in Turing machine-like language, even a short one would be probably annoying after being used to complex machines/languages like x86 or C++. But it's still good to verify the task at the base level, whether it makes sense turing-wise).