You seem to be talking about subroutine calls, so here's the lowdown on that.
When you call a subroutine, it looks something like this (the addresses will be different but I didn't want to confuse you with variable-length instructions):
1234 call 8888
1235 <next instruction>
What happens is that the
call first places the next instruction pointer
1235 onto the stack (a last-in-first-out data structure), then sets the instruction pointer to whatever you're calling,
8888 in this case.
Later on, a return is done at
8888 mov eax, 0
What the return does is simply pop the first value off the stack (ie,
1235, which was pushed by the call) and loads it into the instruction pointer. So it's not the return telling you where to go, it's the information that was pushed on the stack by the call.
If you had a
jmp instruction at the end of your subroutine, it would only be able to return to one point in the code (discounting all the wonderful things you could do with other addressing modes for now):
8889 jmp 1235
By using return, you return to wherever you came from, no matter where that was.
The assembler for an infinite loop can be as simple as:
As for the registers,
edx are considered the general purpose registers. This distinguishes them from the more special purpose registers like the stack pointer, base pointer, source and destination indexes and so on, which have specialised instructions depending on their use.
ax may have had some extra powers in very early iterations of the x86 architecture but I'm not sure that's still the case. If you're coding up your own stuff, you should be able to mostly use them interchangeably. If you're following an API or ABI, you'll need to follow the rules that it imposes (such as the Linux system call interface where
eax holds the system call number).