In the x86-64 System V ABI it is specified that the space behind the $rsp - 128 is the so-called red zone which is not touched by any signal handlers. On my machine

$ ulimit -s

I expected there is only 2 pages in the stack. So I wrote the following program to test till which size red zone can expand:

PAGE_SIZE equ 0x1000
SYS_exit equ 0x3C

section .text
global _start 

    lea rcx, [rsp - 0x1f * PAGE_SIZE]
    mov rax, rsp
    sub rax, PAGE_SIZE
    mov qword [rax], -1
    cmp rax, rcx
    jne loop

    mov rax, SYS_exit
    mov rdi, 0x20

So I expected the program always fails. But the program sometimes fails with SEGV, sometimes finishes fine.

The behavior is exactly as what MAP_GROWSDOWN documents:

This flag is used for stacks. It indicates to the kernel virtual memory system that the mapping should extend downward in memory. The return address is one page lower than the memory area that is actually created in the process's virtual address space. Touching an address in the "guard" page below the mapping will cause the mapping to grow by a page. This growth can be repeated until the mapping grows to within a page of the high end of the next lower mapping, at which point touching the "guard" page will result in a SIGSEGV signal.

As discussed in this question mappings created with MAP_GROWSDOWN and PROT_GROWSDOWN does not grow that way:

volatile char *mapped_ptr = mmap(NULL, 4096,
                        PROT_READ | PROT_WRITE | PROT_GROWSDOWN,
                        MAP_GROWSDOWN | MAP_ANONYMOUS | MAP_PRIVATE,
                        -1, 0); 

mapped_ptr[4095] = 'a';  //OK!
mapped_ptr[0]    = 'b';  //OK!
mapped_ptr[-1]   = 'c';  //SEGV

QUESTION: Combining the reasoning above is it true that the only mapping that uses MAP_GROWSDOWN is the main thread's [stack] mapping ?

  • 2
    The red zone is always the 128 bytes beneath the current value of RSP. It is not based on the size of the stack at all. – Michael Petch Jul 6 '19 at 15:33
  • 1
    @MichaelPetch The red zone is always the 128 bytes - is that the same red zone Raymond Chen discussed? – GSerg Jul 6 '19 at 15:42
  • 4
    Note that the ulimit builtin prints sizes in 1024 byte increments. So when ulimit -s print 8192, it means that your stack limit is 8MiB -- 2048 pages. – Chris Dodd Jul 6 '19 at 17:12
  • 2
    Since the OS is not tagged, it should be noted that Windows does not have a red zone. – rcgldr Jul 6 '19 at 20:27
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    Why is the loop so over-complicated, vs. sub rax, 4096? I think you're doing the equivalent by redoing the multiply every time, but it's harder to follow. – Peter Cordes Jul 6 '19 at 23:47

None of this has anything to do with the red-zone because you aren't moving RSP. Memory protection works with page granularity, but the red-zone is always only 128 bytes below RSP that's safe to read/write as well as safe from async clobber.

No, nothing uses MAP_GROWSDOWN unless you use it manually. The main thread's stack uses a non-broken mechanism that doesn't let other mmap calls randomly steal its growth space. See my answer on Analyzing memory mapping of a process with pmap. [stack]

The sometimes-success of your asm code is an exact duplicate of Why does this code crash with address randomization on? - you're touching memory up to 124 kiB below RSP, so the initial allocation of 132 kiB happens to be enough sometimes, depending on ASLR and how much space args + env takes on the stack.

Why is MAP_GROWSDOWN mapping does not grow? is the interesting part: MAP_GROWSDOWN may not work with a 1-page mapping. But again, this has nothing to do with stacks. The man page saying "This flag is used for stacks." is 100% wrong. That was the intent when adding the feature, but the design isn't actually usable so the implementation may be buggy even vs. the documentation.

  • To summarize. Kernel is ok with growing the stack as long as ulimit -s is preserved, but failure occurs if we touch a page outside of the initially mapped 132KiB and the normal #PF handling mechanism sends SIGSEGV to the process since we tried to get access to the memory not mapped by the process. I checked sub rsp, 0x10000 * PAGE_SIZE\n mov qword [rsp], -1 with ulimit -s unlimited and it worked just fine even without intermediate pages being touched while touching the page without adjusting the rsp results in SIGSEGV. – St.Antario Jul 7 '19 at 11:43
  • 1
    @St.Antario: yes, the kernel will treat #PF as valid and grow the stack mapping up to ulimit -s, as long as the bottom of the red-zone (or RSP) is below or inside the page that faulted. Otherwise it's just an invalid #PF -> SIGSEGV. (The first sentence of your comment left out the part about RSP having to move, so it's not a great summary.) – Peter Cordes Jul 7 '19 at 11:52

You are confusing 2 different concepts, except that they both involve the stack the red zone and the extension of the stack memory area are unrelated. Memory locations below the red zone but within the stack will be altered if a signal handler is called and no alternative signal handler stack is specified.

I suspect the failure of the mmap allocated MAP_GROWSDOWN area to grow is that another area is shortly below, mmap will typically allocate virtual addresses consecutively downwards.

  • Thanks for the explanation of the red zone area. As per MAP_GROWSDON failure, I checked the memory mapping of the process and found that the pointer returned by the mmap call was equal to 0x7fb361abc000, but the closest mapped region below it was 7fb361aa2000 so this is unlikely to be the case. I also tried to specify a specific address as an argument to the mmap, but the same error was the result. – St.Antario Jul 6 '19 at 19:58
  • @St.Antario: the main thread's stack is not MAP_GROWSDOWN. It can grow as far as the max stack size in one step without "stack probes" that touch guard pages (but only if RSP is decremented first), and the potential stack-growth area is reserved so other allocations don't accidentally steal it. (Neither of these are true for MAP_GROWSDOWN, which is why it's not safe for thread stacks. pthreads allocates full-size thread stacks because Linux does lazy alloc of physical pages anyway. See this. – Peter Cordes Jul 6 '19 at 20:50

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