As with most systems that have grown over time, it is somewhat complicated. Different things are done at different levels. For example: do you remember IRQs? We don't worry about them much today in our higher level programs, but a decade or two ago you had to make sure your hardware didn't use conflicting IRQs. These were literally a hardware callback setup (still are in updated form (I can't post enough links but the previous wikipedia article has a link to APIC architecture), but I haven't had to deal with them in years.). The system would have some small routine and the CPU (this was on x86 CPUs) would assign the address of that code to an "interrupt request line". Then when the hardware on the other end of that line signaled, the CPU would drop everything and jump to that bit of code.
There are more complicated cases though, for example question (i). There obviously is no hardware interrupt for your mouse cursor entering the Chrome window. What happens is that the OS catches hardware interrupts for mouse movement and uses that information to update the cursor position (of course there are libraries like Allegro which can give you hardware cursors, and further muddy the waters of inquiry). Then the OS has a list of programs that have requested to be notified (and how to notify each) about various mouse movement events, and the OS goes through that list and calculates which programs should be told.
(ii) is actually simpler because one of the most common interrupts is a timer. Generally the OS still acts as a buffer between the hardware and the program as in (i).
(1) While you will often want to do something at regular intervals your programs generally won't need to poll repeatedly. However the OS may do things differently. For example: those interrupt routines that I mentioned earlier have to be very fast to avoid having the interrupt interrupted or ignoring other events. So one common strategy was to have the interrupt routine just set some memory saying something happened and then have the normal portion of the OS loop poll those memory locations regularly. This however is a systems issue not an applications one.
(2) Most Operating Systems I am familiar with offer event callback APIs. Some, like the old MS-DOS, really didn't give you much API and just let you assign your own interrupt handlers, (for both hardware and software interrupts.) Most modern OSs expose this functionality through the scheduler. A program will give up control while waiting for a specific event or set of events. Various libraries hide this inside their own internal event loop. Callback functions are a common way of dealing with these library's internal event loops. I am not entirely qualified to speak to Objective C, but since it is a strict superset of C (according to Wikipedia) it can use callbacks in the same manner C does (I imagine may be considered bad style though).
I hope that that gives you some of the information you are looking for.