Stack space for a new thread is created by the parent thread with
mmap(MAP_ANONYMOUS|MAP_STACK). So they're in the "memory map segment", as your diagram labels it. It can end up anywhere that a large
malloc() could go. (glibc
mmap(MAP_ANONYMOUS) for large allocations.)
MAP_STACK is currently a no-op, and exists in case some future architecture needs special handling).
You pass a pointer to the new thread's stack space to the
clone(2) system call which actually creates the thread. (Try using
strace -f on a multi-threaded process sometime). See also this blog post about creating a thread using raw Linux syscalls.
See this answer on a related question for some more details about mmaping stacks. e.g.
MAP_GROWSDOWN doesn't prevent another
mmap() from picking the address right below the thread stack, so you can't depend on it to dynamically grow a small stack the way you can for the main thread's stack (where the kernel reserves the address space even though it's not mapped yet).
So even though
mmap(MAP_GROWSDOWN) was designed for allocating stacks, it's so bad that Ulrich Drepper proposed removing it in 2.6.29.
Also, note that your memory-map diagram is for a 32-bit kernel. A 64-bit kernel doesn't have to reserve any user virtual-address space for mapping kernel memory, so a 32-bit process running on an amd64 kernel can use the full 4GB of virtual address space. (Except for the low 64k by default (sysctl
vm.mmap_min_addr = 65536), so NULL-pointer dereference does actually fault. And the top page is also reserved as error codes, not valid pointers.)
See Relation between stack limit and threads for more about stack-size for pthreads.
getrlimit(RLIMIT_STACK) is the main thread's stack size. Linux pthreads uses
RLIMIT_STACK as the stack size for new threads, too.