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path: root/jni/ruby/ext/fiddle/libffi-3.2.1/testsuite/libffi.call/stret_large.c
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/* Area:                ffi_call, closure_call
   Purpose:             Check structure returning with different structure size.
                                Depending on the ABI. Check bigger struct which overlaps
                                the gp and fp register count on Darwin/AIX/ppc64.
   Limitations: none.
   PR:                  none.
   Originator:  Blake Chaffin   6/21/2007       */

/* { dg-do run { xfail strongarm*-*-* xscale*-*-*  } } */
#include "ffitest.h"

/* 13 FPRs: 104 bytes */
/* 14 FPRs: 112 bytes */

typedef struct struct_108byte {
        double a;
        double b;
        double c;
        double d;
        double e;
        double f;
        double g;
        double h;
        double i;
        double j;
        double k;
        double l;
        double m;
        int n;
} struct_108byte;

struct_108byte cls_struct_108byte_fn(
        struct_108byte b0,
        struct_108byte b1,
        struct_108byte b2,
        struct_108byte b3)
{
        struct_108byte  result;

        result.a = b0.a + b1.a + b2.a + b3.a;
        result.b = b0.b + b1.b + b2.b + b3.b;
        result.c = b0.c + b1.c + b2.c + b3.c;
        result.d = b0.d + b1.d + b2.d + b3.d;
        result.e = b0.e + b1.e + b2.e + b3.e;
        result.f = b0.f + b1.f + b2.f + b3.f;
        result.g = b0.g + b1.g + b2.g + b3.g;
        result.h = b0.h + b1.h + b2.h + b3.h;
        result.i = b0.i + b1.i + b2.i + b3.i;
        result.j = b0.j + b1.j + b2.j + b3.j;
        result.k = b0.k + b1.k + b2.k + b3.k;
        result.l = b0.l + b1.l + b2.l + b3.l;
        result.m = b0.m + b1.m + b2.m + b3.m;
        result.n = b0.n + b1.n + b2.n + b3.n;

        printf("%g %g %g %g %g %g %g %g %g %g %g %g %g %d\n", result.a, result.b, result.c,
                result.d, result.e, result.f, result.g, result.h, result.i,
                result.j, result.k, result.l, result.m, result.n);

        return result;
}

static void
cls_struct_108byte_gn(ffi_cif* cif __UNUSED__, void* resp, void** args, void* userdata __UNUSED__)
{
        struct_108byte  b0, b1, b2, b3;

        b0 = *(struct_108byte*)(args[0]);
        b1 = *(struct_108byte*)(args[1]);
        b2 = *(struct_108byte*)(args[2]);
        b3 = *(struct_108byte*)(args[3]);

        *(struct_108byte*)resp = cls_struct_108byte_fn(b0, b1, b2, b3);
}

int main (void)
{
        ffi_cif cif;
        void *code;
        ffi_closure *pcl = ffi_closure_alloc(sizeof(ffi_closure), &code);
        void* args_dbl[5];
        ffi_type* cls_struct_fields[15];
        ffi_type cls_struct_type;
        ffi_type* dbl_arg_types[5];

        struct_108byte e_dbl = { 9.02.06.05.03.04.08.01.01.02.03.07.02.07 };
        struct_108byte f_dbl = { 1.02.03.07.02.05.06.07.04.05.07.09.01.04 };
        struct_108byte g_dbl = { 4.05.07.09.01.01.02.09.08.06.01.04.00.03 };
        struct_108byte h_dbl = { 8.06.01.04.00.03.03.01.09.02.06.05.03.02 };
        struct_108byte res_dbl;

        cls_struct_type.size = 0;
        cls_struct_type.alignment = 0;
        cls_struct_type.type = FFI_TYPE_STRUCT;
        cls_struct_type.elements = cls_struct_fields;

        cls_struct_fields[0] = &ffi_type_double;
        cls_struct_fields[1] = &ffi_type_double;
        cls_struct_fields[2] = &ffi_type_double;
        cls_struct_fields[3] = &ffi_type_double;
        cls_struct_fields[4] = &ffi_type_double;
        cls_struct_fields[5] = &ffi_type_double;
        cls_struct_fields[6] = &ffi_type_double;
        cls_struct_fields[7] = &ffi_type_double;
        cls_struct_fields[8] = &ffi_type_double;
        cls_struct_fields[9] = &ffi_type_double;
        cls_struct_fields[10] = &ffi_type_double;
        cls_struct_fields[11] = &ffi_type_double;
        cls_struct_fields[12] = &ffi_type_double;
        cls_struct_fields[13] = &ffi_type_sint32;
        cls_struct_fields[14] = NULL;

        dbl_arg_types[0] = &cls_struct_type;
        dbl_arg_types[1] = &cls_struct_type;
        dbl_arg_types[2] = &cls_struct_type;
        dbl_arg_types[3] = &cls_struct_type;
        dbl_arg_types[4] = NULL;

        CHECK(ffi_prep_cif(&cif, FFI_DEFAULT_ABI, 4, &cls_struct_type,
                dbl_arg_types) == FFI_OK);

        args_dbl[0] = &e_dbl;
        args_dbl[1] = &f_dbl;
        args_dbl[2] = &g_dbl;
        args_dbl[3] = &h_dbl;
        args_dbl[4] = NULL;

        ffi_call(&cif, FFI_FN(cls_struct_108byte_fn), &res_dbl, args_dbl);
        /* { dg-output "22 15 17 25 6 13 19 18 22 15 17 25 6 16" } */
        printf("res: %g %g %g %g %g %g %g %g %g %g %g %g %g %d\n", res_dbl.a, res_dbl.b,
                res_dbl.c, res_dbl.d, res_dbl.e, res_dbl.f, res_dbl.g, res_dbl.h, res_dbl.i,
                res_dbl.j, res_dbl.k, res_dbl.l, res_dbl.m, res_dbl.n);
        /* { dg-output "\nres: 22 15 17 25 6 13 19 18 22 15 17 25 6 16" } */

        CHECK(ffi_prep_closure_loc(pcl, &cif, cls_struct_108byte_gn, NULL, code) == FFI_OK);

        res_dbl = ((struct_108byte(*)(struct_108byte, struct_108byte,
                struct_108byte, struct_108byte))(code))(e_dbl, f_dbl, g_dbl, h_dbl);
        /* { dg-output "\n22 15 17 25 6 13 19 18 22 15 17 25 6 16" } */
        printf("res: %g %g %g %g %g %g %g %g %g %g %g %g %g %d\n", res_dbl.a, res_dbl.b,
                res_dbl.c, res_dbl.d, res_dbl.e, res_dbl.f, res_dbl.g, res_dbl.h, res_dbl.i,
                res_dbl.j, res_dbl.k, res_dbl.l, res_dbl.m, res_dbl.n);
        /* { dg-output "\nres: 22 15 17 25 6 13 19 18 22 15 17 25 6 16" } */

        exit(0);
}