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I'm trying to add global constructor support on an embedded target (ARM Cortex-M3). Lets say I've the following code:

class foobar
    int i;

        i = 100;

    void inc()

foobar foo;

int main()
    for (;;);

I compile it like this:

arm-none-eabi-g++ -O0 -gdwarf-2 -mcpu=cortex-m3 -mthumb -c foo.cpp -o foo.o

When I look at the .init_array section with objdump it shows the .init_section has a zero size.

I do get an symbol named _Z41__static_initialization_and_destruction_0ii. When I disassemble the object file I see that the global construction is done in the static_initialization_and_destruction symbol.

Why isn't a pointer added to this symbol in the .init_section?

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You don't think gcc is smart enough to 1) see that the value is 100, or 2) see that the value is just incremented but never used? –  Bo Persson Jun 14 '11 at 17:34
@Bo Persson: That's why I added the -O0 option, so gcc won't optimize that out. –  Ingmar Blonk Jun 15 '11 at 7:20

5 Answers 5

I know it has been almost two years since this question was asked, but I just had to figure out the mechanics of bare-metal C++ initialization with GCC myself, so I thought I'd share the details here. There turns out to be a lot of out-of-date or confusing information on the web. For example, the oft-mentioned collect2 wrapper does not appear to be used for ARM ELF targets, since its arbitrary section support enables the approach described below.

First, when I compile the code above with the given command line using Sourcery CodeBench Lite 2012.09-63, I do see the correct .init_array section size of 4:

$ arm-none-eabi-objdump -h foo.o

foo.o:     file format elf32-littlearm

Idx Name          Size      VMA       LMA       File off  Algn
 13 .init_array   00000004  00000000  00000000  0000010c  2**2
                  CONTENTS, ALLOC, LOAD, RELOC, DATA

When I look at the section contents, it just contains 0:

$ arm-none-eabi-objdump -j .init_array -s foo.o
Contents of section .init_array:
 0000 00000000                             ....

However, there is also a relocation section that sets it correctly to _GLOBAL__sub_I_foo:

$ arm-none-eabi-objdump -x foo.o
OFFSET   TYPE              VALUE
00000000 R_ARM_TARGET1     _GLOBAL__sub_I_foo

In general, .init_array points to all of your _GLOBAL__sub_I_XXX initializer stubs, each of which calls its own copy of _Z41__static_initialization_and_destruction_0ii (yes, it is multiply-defined), which calls the constructor with the appropriate arguments.

Because I'm using -nostdlib in my build, I can't use CodeSourcery's __libc_init_array to execute the .init_array for me, so I need to call the static initializers myself:

extern "C"
    extern void (**__init_array_start)();
    extern void (**__init_array_end)();

    inline void static_init()
        for (void (**p)() = __init_array_start; p < __init_array_end; ++p)

__init_array_start and __init_array_end are defined by the linker script:

. = ALIGN(4);
.init_array :
__init_array_start = .;
KEEP (*(.init_array*))
__init_array_end = .;

This approach seems to work with both the CodeSourcery cross-compiler and native ARM GCC, e.g. in Ubuntu 12.10 for ARM. Supporting both compilers is one reason for using -nostdlib and not relying on the CodeSourcery CS3 bare-metal support.

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I don't know if things have changed since Feb 2013, but I found that I had to treat __init_array_start and __init_array_end as function pointers, not pointers to function pointers: typedef void (InitFunc)(void); extern InitFunc __init_array_start; extern InitFunc __init_array_end; InitFunc pFunc = &__init_array_start; for ( ; pFunc < &__init_array_end; ++pFunc ) { (*pFunc)(); } –  Timma Mar 11 at 2:43

You have only produced an object file, due to the -c argument to gcc. To create the .init section, I believe that you need to link that .o into an actual executable or shared library. Try removing the -c argument and renaming the output file to "foo", and then check the resulting executable with the disassembler.

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When I do that I still have the same issue. –  Ingmar Blonk Jun 14 '11 at 13:15
OK, so with the caveat that I know essentially nothing about ARM, I would say that it means that you have another step to perform in implementing support for global ctor's and dtors for ARM. The fact that you are getting the Z41... symbol is encouraging, because it suggests to me that the .o file is correct. But clearly something isn't happening at link time. On x86 GCC, a link time process called collect2 handles merging all of the various static constructors into the .init section before handing off to ld (or something like that). I think linker support is your next step. –  acm Jun 14 '11 at 13:32

If you look carefully _Z41__static_initialization_and_destruction_0ii would be called inside global constructor. Which inturn would be linked in .init_array section (in arm-none-eabi- from CodeSourcery.) or some other function (__main() if you are using Linux g++). () This should be called at startup or at main(). See also this link.

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I had a similar issue where my constructors were not being called (nRF51822 Cortex-M0 with GCC). The problem turned out to be due to this linker flag:


Don't ask me why! I thought it only removed dead code.

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I just had the same issue on the nRF51822 and solved it by adding KEEP() around a couple lines in the stock Nordic .ld file:


While at it, I did the same to the fini_array area too. Solved my problem and the linker can still remove other unused sections...

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