Or is it controlled by the operating system? I hear the new Go language from Google has built-in features for a programmer to go that granular, or have I understood it wrong?
For linux os, sched_setaffinity is your answer. It's supported since linux kernel 2.5.8.
sched_setaffinity, sched_getaffinity — set and get a process's CPU affinity mask
It is determined by the operating system.
You can set hints for it with
But the operating system can override you. The call above is only a suggestion your program makes to the OS.
As for Go, I haven't worked with it yet or even looked at it too deeply, but my understanding of Go is that a lot of the parallelism is rather implicit. You have co-routines (they say "go-routines", very punny) and communication between them. It seems like CPU affinity and the concept of threading itself is separate from that. That is, the language runtime could even decide to do it all on 1 CPU if it decides that's best... But again, I caution that I haven't looked at it too deeply, so I could be wrong. :-)
The answer is yes, you can programmatically choose which core a process runs on. As arsane mentioned, the answer lies with sched_set_affinity(), and then pthread_setaffinity_np() for pthreads.
Basically, this is done using a bitmask. This means that there is an integer (say, 32 bits), and if the first bit == 1, then that process is allowed to run on processor 1. If the second bit == 1, then that process is allowed to run on processor 2. etc.
So by default, the affinity bitmask = 1...111 (32 times.) This means that "The process may run on processor 1, 2, 3, ..., 32." Of course, if you only have 2 cores, then the extra 30 bits won't apply.
However, if you set that bitmask to be: 0...010 then only "processor 2" is allowed to execute that process.
Which also explains why the maximum number of processors supported by linux is 32. (out of the box, without tweaking, x86, on much of commonly-found hardware, without clustering, etc etc).