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I'm currently working on an embedded project (STM32F103RB, CooCox CoIDE v.1.7.6 with arm-none-eabi-gcc 4.8 2013q4). I have a plain project:

int main(void)
{
    return 0;
}

I'm using the following code (excerpt from startup_stm32f10x_md.c) to set the stack size

#define STACK_SIZE       0x00001000 
__attribute__ ((section(".co_stack")))
unsigned long pulStack[STACK_SIZE];    

In my understanding .bss is a section in the RAM after .text but before .heap and .stack holding uninitialized data. So .bss should NOT be affected by increasing the stack size. But .bss IS in this case. So maybe the .co_stack is a kind of user defined stack? But what I really don't get: Which does .bss grow 4 times the stack size? e.g.

#define STACK_SIZE       0x00001000 
.bss 16384 = 0x4000

or

#define STACK_SIZE       0x00000100 
.bss 1024 = 0x400
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1 Answer 1

up vote 1 down vote accepted

The copy of startup_stm32f10x_md.c I found on the net defines the stack as array of longs (which is advisable to keep it long word aligned).

static unsigned long pulStack[STACK_SIZE];

0x1000 longs add up to 4096 x 4 = 16K.

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that matches the line unsigned long pulStack[STACK_SIZE]; but doesn't explain why the stack increases .bss –  Ben Mar 16 '14 at 17:24
1  
This depends of the contents of the linker script. I'm not familiar with the platform, but I wouldn't expect an embedded system to implement a full featured ELF loader, so it's pretty likely that the stack is located in the .bss segment. –  mfro Mar 16 '14 at 17:39

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