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I have an assembly routine that calls, in a generic way, a function known to use the stdcall convention and return a float. This function is being used by a marshalling framework to expose stdcall functions to a scripting language.


Here's the function using GNU inline assembly that compiles on MinGW 4.3, Win32:

inline uint64_t stdcall_invoke_return_float(int args_size_bytes,
                                            const char * args_ptr,
                                            void * func_ptr)
    uint64_t result;
        0 == args_size_bytes % 4
            || !"argument size must be a multiple of 4 bytes");
#if defined(__GNUC__)
        /* INPUT PARAMS:  %0 is the address where top of FP stack to be stored
         *                %1 is the number of BYTES to push onto the stack, */
        /*                   and during the copy loop it is the address of */
        /*                   the next word to push */
        /*                %2 is the base address of the array */
        /*                %3 is the address of the function to call */
            "testl %1, %1    # If zero argument bytes given, skip \n\t"
            "je    2f        # right to the function call.        \n\t"
            "addl  %2, %1\n"
            "subl  $4, %1    # Push arguments onto the stack in   \n\t"
            "pushl (%1)      # reverse order. Keep looping while  \n\t"
            "cmp   %2, %1    # addr to push (%1) > base addr (%2) \n\t"
            "jg    1b        # Callee cleans up b/c __stdcall.    \n"
            "call  * %3      # Callee will leave result in ST0    \n\t"
            "fsts  %0        # Copy 32-bit float from ST0->result"
        : "=m" (result)
        : "r" (args_size_bytes), "r" (args_ptr), "mr" (func_ptr)
        : "%eax", "%edx", "%ecx" /* eax, ecx, edx are caller-save */, "cc"
#pragma error "Replacement for inline assembler required"
    return result;

This is just a little glue to make it easier to write test cases:

template<typename FuncPtr, typename ArgType>
float float_invoke(FuncPtr f, int nargs, ArgType * args)
    uint64_t result = stdcall_invoke_return_float(
        nargs * sizeof(ArgType),
        reinterpret_cast<const char *>(args),
        reinterpret_cast<void *>(f)
    return *reinterpret_cast<float *>(&result);

Now I have some test cases that invoke this function:

__stdcall float TestReturn1_0Float()
{ return 1.0f; }

__stdcall float TestFloat(float a)
{ return a; }

__stdcall float TestSum2Floats(float a, float b)
{ return a + b; }

static const float args[2] = { 10.0f, -1.0f };

assert_equals(1.0f, float_invoke(TestReturn1_0Float, 0, args)); // test 1
assert_equals(10.0f, float_invoke(TestFloat, 1, args));         // test 2
assert_equals(-1.0f, float_invoke(TestFloat, 1, args + 1));     // test 3
assert_equals(9.0f, float_invoke(TestSumTwoFloats, 2, args));   // test 4


Randomly, test 3 is giving me garbage output instead of returning -1.0.

I'm wondering if I'm

  • failing to preserve some state before the call instruction?
  • messing up some state with the fsts instruction?
  • fundamentally misunderstanding how to get a float value from a stdcall function that returns float????

All help greatly appreciated.

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2 Answers 2

up vote 1 down vote accepted

Lacking a windows machine, I can't fully test this; on Linux, the following gets me the return code of a float function:

extern float something(int);


int main(int argc, char **argv)
    int val = atoi(argv[1]);
    float ret;

    asm("pushl %1\n\t"
        "call * %2\n\t"
        "addl $4, %%esp"
       : "=t"(ret)
       : "r"(val), "r"(something)
       : "%eax", "%ecx", "%edx", "memory", "cc");

    printf("something(%d) == %f\n", val, ret);
    return 0;

The key is the use of the "=t"(ret) constraint - that gets the top of the floating point stack, see Machine Constraints (from the gcc manual). If Windows stdcall returns float results in ST(0) as well, that should work, no need for fld/fst as the compiler can do those for you if necessary.

You also need to specify the memory and cc clobbers when you call functions from within inline assembly.

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It seems to work consistently with the =t constraint. I would still like to know why using the fsts instruction works inconsistently, however! Also, why do I need the memory clobber? –  0xbe5077ed Aug 12 '13 at 15:44
The memory "clobber" is actually a barrier. It means the compiler will order the inline asm() block in such a way with the remaining instructions generated that all loads/stores have completed before it, and are re-done after it. Same for cc, regarding condition codes, aka state from previous comparisions (so it will not, say, do a cmp before the asm block and test for the result after it). –  FrankH. Aug 13 '13 at 5:42

You are permitting a memory reference for the function pointer, GCC is liable to construct a reference relative the stack pointer on the incorrect assumption that the inline assembly does not change it.

share|improve this answer
That's a very good point; the disassembly would easily show whether that's the case. I don't think so though, in this case - because the compiler knows the code location for the function (that's a compile/link time constant) but not the offset between that and the current stackpointer (that's a runtime variable because the stackpointer varies depending on the calling context and/or calling thread). Stackpointer-relative function addresses are ... unusual, since executing code located on the stack has been ... "deprecated". –  FrankH. Aug 13 '13 at 5:51

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