I am preparing some training materials in C and I want my examples to fit the typical stack model.

What direction does a C stack grow in Linux, Windows, Mac OSX (PPC and x86), Solaris, and most recent Unixes?


Stack growth doesn't usually depend on the operating system itself, but on the processor it's running on. Solaris, for example, runs on x86 and SPARC. Mac OSX (as you mentioned) runs on PPC and x86. Linux runs on everything from my big honkin' System z at work to a puny little wristwatch.

If the CPU provides any kind of choice, the ABI / calling convention used by the OS specifies which choice you need to make if you want your code to call everyone else's code.

The processors and their direction are:

  • x86: down.
  • SPARC: selectable. The standard ABI uses down.
  • PPC: down, I think.
  • System z: in a linked list, I kid you not (but still down, at least for zLinux).
  • ARM: selectable, but Thumb2 has compact encodings only for down (LDMIA = increment after, STMDB = decrement before).
  • 6502: down (but only 256 bytes).
  • RCA 1802A: any way you want, subject to SCRT implementation.
  • PDP11: down.
  • 8051: up.

Showing my age on those last few, the 1802 was the chip used to control the early shuttles (sensing if the doors were open, I suspect, based on the processing power it had :-) and my second computer, the COMX-35 (following my ZX80).

PDP11 details gleaned from here, 8051 details from here.

The SPARC architecture uses a sliding window register model. The architecturally visible details also include a circular buffer of register-windows that are valid and cached internally, with traps when that over/underflows. See here for details. As the SPARCv8 manual explains, SAVE and RESTORE instructions are like ADD instructions plus register-window rotation. Using a positive constant instead of the usual negative would give an upward-growing stack.

The afore-mentioned SCRT technique is another - the 1802 used some or it's sixteen 16-bit registers for SCRT (standard call and return technique). One was the program counter, you could use any register as the PC with the SEP Rn instruction. One was the stack pointer and two were set always to point to the SCRT code address, one for call, one for return. No register was treated in a special way. Keep in mind these details are from memory, they may not be totally correct.

For example, if R3 was the PC, R4 was the SCRT call address, R5 was the SCRT return address and R2 was the "stack" (quotes as it's implemented in software), SEP R4 would set R4 to be the PC and start running the SCRT call code.

It would then store R3 on the R2 "stack" (I think R6 was used for temp storage), adjusting it up or down, grab the two bytes following R3, load them into R3, then do SEP R3 and be running at the new address.

To return, it would SEP R5 which would pull the old address off the R2 stack, add two to it (to skip the address bytes of the call), load it into R3 and SEP R3 to start running the previous code.

Very hard to wrap your head around initially after all the 6502/6809/z80 stack-based code but still elegant in a bang-your-head-against-the-wall sort of way. Also one of the big selling features of the chip was a full suite of 16 16-bit registers, despite the fact you immediately lost 7 of those (5 for SCRT, two for DMA and interrupts from memory). Ahh, the triumph of marketing over reality :-)

System z is actually quite similar, using its R14 and R15 registers for call/return.

  • 3
    To add to the list, ARM can grow in either direction, but can be set to one or the other by a particular silicon implementation (or can be left selectable by software). The few I've dealt with have always been in grow-down mode. – Michael Burr Mar 20 '09 at 2:20
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    In the little bit of the ARM world I've seen so far (ARM7TDMI) the stack is entirely handled in software. Return addresses are stored in a register which is saved by software if needed, and pre-/post-increment/decrement instructions allow to put it and other stuff on the stack in either direction. – starblue Mar 20 '09 at 7:27
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    One the HPPA, the stack grew up! Fairly rare among reasonably modern architectures. – tml Jun 5 '11 at 22:38
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    For the curious, here is a good resource on how the stack works on z/OS: www-03.ibm.com/systems/resources/Stack+and+Heap.pdf – Dillon Cower Aug 22 '13 at 18:55
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    Thanks @paxdiablo for your understanding. Sometimes people take it as a personal affront when you make such a comment, especially when it is an older one. I only know there is a difference because I've made the same mistake myself in the past. Take care. – CasaDeRobison Jun 3 '18 at 3:40

In C++ (adaptable to C) stack.cc:

static int
find_stack_direction ()
    static char *addr = 0;
    auto char dummy;
    if (addr == 0)
        addr = &dummy;
        return find_stack_direction ();
        return ((&dummy > addr) ? 1 : -1);
  • 13
    Wow, it's been a long time since I've seen the "auto" keyword. – paxdiablo Mar 20 '09 at 2:54
  • 7
    (&dummy > addr) is undefined. The result of feeding two pointers to a relational operator is defined only if the two pointers point within the same array or structure. – sigjuice Mar 23 '09 at 7:59
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    Trying to investigate the layout of your own stack -- something which C/C++ don't specify at all -- is "unportable" to begin with, so I wouldn't really care about that. It looks like this function will only work correctly once, though. – ephemient Mar 26 '09 at 14:59
  • 7
    There's no need to use a static for this. Instead you could pass the address as an argument to a recursive call. – R.. May 19 '11 at 1:33
  • 4
    plus, by using a static, if you call this more than once, the subsequent calls may fail... – Chris Dodd Aug 1 '12 at 21:02

The advantage of growing down is in older systems the stack was typically at the top of memory. Programs typically filled memory starting from the bottom thus this sort of memory management minimized the need to measure and place the bottom of the stack somewhere sensible.

  • 2
    Not an 'advantage', a tautology really. – user207421 Oct 8 '16 at 0:24

Stack grows down on x86 (defined by the architecture, pop increments stack pointer, push decrements.)


In MIPS there's no push/pop instruction. All pushes/pops are explicitly done by load/store relatively to the stack pointer and then manually adjust the $sp pointer. However as all registers (except $0) are general purpose, in theory any register can be a stack pointer, and the stack can grow in any direction the programmer wants. MIPS ABIs typically grow downwards.

In Intel 8051 the stack grows up, probably because the memory space is so tiny (128 bytes in original version) that there's no heap and you don't need to put the stack on top so that it'll be separated from the heap growing from bottom.


It grows down because the memory allocated to the program has the "permanent data" i.e. code for the program itself at the bottom, then the heap in the middle. You need another fixed point from which to reference the stack, so that leaves you the top. This means the stack grows down, until it is potentially adjacent to objects on the heap.


On most systems, stack grows down, and my article at https://gist.github.com/cpq/8598782 explains WHY it grows down. The reason is that is the optimal layout of two growing memory regions (heap and stack).

  • that gist seems to be dead now :( – Ven Sep 29 '15 at 20:00
  • 1
    @Ven, I've corrected the link – valenok Sep 30 '15 at 20:36

This macro should detect it at runtime without UB:

#define stk_grows_up_eh() stk_grows_up__(&(char){0})
_Bool stk_grows_up__(char *ParentsLocal);

_Bool stk_grows_up__(char *ParentsLocal) { 
    return (uintptr_t)ParentsLocal < (uintptr_t)&ParentsLocal;

Just a small addition to the other answers, which as far as I can see have not touched this point:

Having the stack grow downwards makes all addresses within the stack have a positive offset relative to the stack pointer. There's no need for negative offsets, as they would only point to unused stack space. This simplifies accessing stack locations when the processor supports stackpointer-relative addressing.

Many processors have instructions that allow accesses with a positive-only offset relative to some register. Those include many modern architectures, as well as some old ones. For example, the ARM Thumb ABI provides for stackpointer-relative accesses with a positive offset encoded within a single 16-bit instruction word.

If the stack grew upwards, all useful offsets relative to the stackpointer would be negative, which is less intuitive and less convenient. It also is at odds with other applications of register-relative addressing, for example for accessing fields of a struct.

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