Segmented stack allows stack space to be allocated incrementally than as a
monolithic chunk (of some worst case size) at thread initialization. This is
done by allocating stack blocks (henceforth called stacklets) and linking them
into a doubly linked list. The function prologue is responsible for checking if
the current stacklet has enough space for the function to execute; and if not,
call into the libgcc runtime to allocate more stack space. When using llc
,
segmented stacks can be enabled by adding -segmented-stacks
to the command
line.
The runtime functionality is already there in libgcc.
As mentioned above, the function prologue checks if the current stacklet has
enough space. The current approach is to use a slot in the TCB to store the
current stack limit (minus the amount of space needed to allocate a new block) -
this slot's offset is again dictated by libgcc
. The generated
assembly looks like this on x86-64:
leaq -8(%rsp), %r10
cmpq %fs:112, %r10
jg .LBB0_2
# More stack space needs to be allocated
movabsq $8, %r10 # The amount of space needed
movabsq $0, %r11 # The total size of arguments passed on stack
callq __morestack
ret # The reason for this extra return is explained below
.LBB0_2:
# Usual prologue continues here
The size of function arguments on the stack needs to be passed to
__morestack
(this function is implemented in libgcc
) since that number
of bytes has to be copied from the previous stacklet to the current one. This is
so that SP (and FP) relative addressing of function arguments work as expected.
The unusual ret
is needed to have the function which made a call to
__morestack
return correctly. __morestack
, instead of returning, calls
into .LBB0_2
. This is possible since both, the size of the ret
instruction and the PC of call to __morestack
are known. When the function
body returns, control is transferred back to __morestack
. __morestack
then de-allocates the new stacklet, restores the correct SP value, and does a
second return, which returns control to the correct caller.
The section on allocating stacklets automatically assumes that every stack
frame will be of fixed size. However, LLVM allows the use of the llvm.alloca
intrinsic to allocate dynamically sized blocks of memory on the stack. When
faced with such a variable-sized alloca, code is generated to:
- Check if the current stacklet has enough space. If yes, just bump the SP, like in the normal case.
- If not, generate a call to
libgcc
, which allocates the memory from the heap.
The memory allocated from the heap is linked into a list in the current stacklet, and freed along with the same. This prevents a memory leak.