Each thread/process has its own register values. The user-space "architectural state" (register values) is saved on entering the kernel via a system call or interrupt. (This is true on all OSes).
See What happens if you use the 32-bit int 0x80 Linux ABI in 64-bit code? for a look at Linux's system-call entry points, with the hand-written asm that actually saves registers on the process's kernel stack. (Each thread has its own kernel stack, in Linux).
In multi-tasking OSes in general, every process/thread has its own memory space for saving state, so context switches work by restoring the saved state from the thread being switched to. This is a bit of a simplification, because there's kernel state vs. saved user-space. state1
So any time a process isn't actually running on a CPU core, its register values are saved in memory.
The OS provides an API for reading/writing the saved register state, and memory, of other processes.
In Linux, this API is the
ptrace(2) system call; it's what GDB uses to read register values and to single-step. Thus, GDB reads saved register values of the target process from memory, indirectly via the kernel. GDB's own code doesn't use any special x86 instructions, or even load / store from any special addresses; it just makes system calls because access to another process's state has to go through the kernel. (Well I think a process could map another process's memory into its own address space, if Linux even has a system call for that, but I think memory reads/writes actually go through ptrace just like register accesses.)
(I think) If the target process was currently executing (instead of suspended) when another process made a
ptrace system call that read or wrote one of its register values, the kernel would have to interrupt it so its current state would be saved to memory. This doesn't normally happen with GDB: it only tries to read register values when it's suspended the target process.
ptrace is also what
strace uses to trace system calls. See Playing with ptrace, Part I from Linux Journal.
strace ./my_program is fantastically useful for systems programming, especially when making system calls from hand-written asm, to decode the args you're actually passing, and the return values.
- In Linux, the actual switch to a new thread happens inside the kernel, from kernel context to kernel context. This saves "only" the integer registers on the kernel stack, sets
rsp to the right place in the other thread's kernel stack, then restores the saved registers. So there's a function call that, when it returns, is executing in kernel mode for the new thread, with per-CPU kernel variables set appropriately. User-space state for the new thread is eventually restored the same way it would have been if the system call or interrupt that originally entered the kernel from user-space had returned without calling the scheduler. i.e. from the state saved by the system call or interrupt kernel entry point. Lazy / eager FPU state saving is another complication; the kernel generally avoids touching the FPU so it can avoid saving/restoring FPU state when just entering the kernel and returning back to the same user-space process.