Linux no longer schedules processes at all.
Within the kernel, threads are scheduled. The concept of a process is now an artificial construct seen mostly by things outside the kernel. Obviously, the kernel has to know how threads are tied together, but not for scheduling purposes.
Basically, the kernel maintains a whole lot of threads and each thread has a thread group leader, which is what's seen on the outside as the process. A thread has a thread ID and a thread group ID - it's a lot like the relationship between a PID and a PPID (process ID and parent process ID).
When you create a regular thread, the kernel gives it a brand new thread ID but its thread group ID is set identical to the group ID of the thread that created it. That way, it looks like a thread within a process to the outside world.
When you fork, the kernel gives it a brand new thread ID and sets its thread group ID to the same value as its thread ID. That way, it looks like a process to the outside world.
Most non-kernel utilities that report on processes are really just reporting on threads where the thread ID is the same as the thread group ID.
There are subtleties with other methods which are probably too complicated to go into here. What I've written above is (hopefully) a good medium level treatise.
Now, for your specific question, it would be neither case since
P1 only has one thread (there is no
Withing the kernel, the threads are
P2T2 and, assuming they have the same scheduling properties and behave the same (a), that's how they'll be scheduled.
for more information.
(a): Obviously that changes if the threads start blocking on I/O (kernel won't schedule them until I/O is available) or releasing their time quanta early (kernel will probably up their priority as a reward for playing nicely) but then they're not behaving the same.