The Unofficial SMP FAQ
Once upon a time, to write x86 assembler, for example, you would have instructions stating "load the EDX register with the value 5", "increment the EDX" register, etc. With modern CPUs that have 4 cores (or even more), at the machine code level does it just look like there are 4 separate CPUs (i.e. are there just 4 distinct "EDX" registers) ?
Exactly. There are 4 sets of registers, including 4 separate instruction pointers.
If so, when you say "increment the EDX register", what determines which CPU's EDX register is incremented?
The CPU that executed that instruction, naturally. Think of it as 4 entirely different microprocessors that are simply sharing the same memory.
Is there a "CPU context" or "thread" concept in x86 assembler now?
No. The assembler just translates instructions like it always did. No changes there.
How does communication/synchronization between the cores work?
Since they share the same memory, it's mostly a matter of program logic. Although there now is an inter-processor interrupt mechanism, it's not necessary and was not originally present in the first dual-CPU x86 systems.
If you were writing an operating system, what mechanism is exposed via hardware to allow you to schedule execution on different cores?
The scheduler actually doesn't change, except that it is slightly more carefully about critical sections and the types of locks used. Before SMP, kernel code would eventually call the scheduler, which would look at the run queue and pick a process to run as the next thread. (Processes to the kernel look a lot like threads.) The SMP kernel runs the exact same code, one thread at a time, it's just that now critical section locking needs to be SMP-safe to be sure two cores can't accidentally pick the same PID.
Is it some special privileged instruction(s)?
No. The cores are just all running in the same memory with the same old instructions.
If you were writing an optimizing compiler/bytecode VM for a multicore CPU, what would you need to know specifically about, say, x86 to make it generate code that runs efficiently across all the cores?
You run the same code as before. It's the Unix or Windows kernel that needed to change.
You could summarize my question as "What changes have been made to x86 machine code to support multi-core functionality?"
Nothing was necessary. The first SMP systems used the exact same instruction set as uniprocessors. Now, there has been a great deal of x86 architecture evolution and zillions of new instructions to make things go faster, but none were necessary for SMP.
For more information, see the Intel Multiprocessor Specification.
all the follow-up questions can be answered by just completely accepting that an n
-way multicore CPU is almost1
exactly the same thing as n
separate processors that just share the same memory.2
There was an important question not asked: how is a program written to run on more than one core for more performance?
And the answer is: it is written using a thread library like Pthreads.
Some thread libraries use "green threads" that are not visible to the OS, and those won't get separate cores, but as long as the thread library uses kernel thread features then your threaded program will automatically be multicore.
1. For backwards compatibility, only the first core starts up at reset, and a few driver-type things need to be done to fire up the remaining ones.
2. They also share all the peripherals, naturally.