A similar imperative (Python-like syntax) loop would be:
x = ()
Or without recursion:
x = ()
All this will do in any language is tell the CPU to keep executing instructions with no useful result, forever. Without specifically telling the program to do something other than keep executing these instructions (such as suspend for a while between loops), how could it do anything but use 100% CPU?
Control.Concurrent.yield allows any other thread in your program to "get a turn" at execution. If there are no other threads then it doesn't do anything. If all your other threads are executing such a loop, then it'll still use 100% CPU. If you have other threads that are sometimes IO bound rather than CPU bound, I do not know for certain, but I'm reasonably sure Haskell's runtime system switch back to something for the CPU to do (if possible) whenever threads are waiting for IO, so you'd probably see close to 100% CPU usage if you had this loop running and
yielding, even if you have loads of other threads that won't use 100% CPU on their own.
If other unrelated programs are also running, then almost all modern desktop hardware and operating systems will try to share the CPU resources between them, regardless of whether you're using
yield or not. Generally, this means that any time the other programs don't have work for the CPU your loop program will be run, plus it will also steal some of the CPU time that could have been used to execute other programs. This means that while this loop program is executing you would usually see close to 100% CPU usage regardless of what else is running, and using
yield won't particularly make a difference to how much CPU time is available to other programs.
Control.Concurrent.threadDelay puts the thread to sleep for (at least) a given amount of time. If that leaves the CPU with nothing to execute, then you'll see your system running at less than 100% CPU.