gdb/testsuite/gdb.base/callfuncs2.c - binutils-gdb - Git at Google

 /* Support program for testing gdb's ability to call functions
    in an inferior which doesn't itself call malloc, pass appropriate
    arguments to those functions, and get the returned result. */

 #ifdef NO_PROTOTYPES
 #define PARAMS(paramlist) ()
 #else
 #define PARAMS(paramlist) paramlist
 #endif

 char char_val1 = 'a';
 char char_val2 = 'b';

 short short_val1 = 10;
 short short_val2 = -23;

 int int_val1 = 87;
 int int_val2 = -26;

 long long_val1 = 789;
 long long_val2 = -321;

 float float_val1 = 3.14159;
 float float_val2 = -2.3765;

 double double_val1 = 45.654;
 double double_val2 = -67.66;

 #define DELTA (0.001)

 char *string_val1 = "string 1";
 char *string_val2 = "string 2";

 char char_array_val1[] = "carray 1";
 char char_array_val2[] = "carray 2";

 struct struct1 {
   char c;
   short s;
   int i;
   long l;
   float f;
   double d;
   char a[4];
 } struct_val1 = { 'x', 87, 76, 51, 2.1234, 9.876, "foo" };

 /* Some functions that can be passed as arguments to other test
    functions, or called directly. */

 int add (a, b)
 int a, b;
 {
   return (a + b);
 }

 int doubleit (a)
 int a;
 {
   return (a + a);
 }

 int (*func_val1) PARAMS((int,int)) = add;
 int (*func_val2) PARAMS((int)) = doubleit;

 /* An enumeration and functions that test for specific values. */

 enum enumtype { enumval1, enumval2, enumval3 };
 enum enumtype enum_val1 = enumval1;
 enum enumtype enum_val2 = enumval2;
 enum enumtype enum_val3 = enumval3;

 t_enum_value1 (enum_arg)
 enum enumtype enum_arg;
 {
   return (enum_arg == enum_val1);
 }

 t_enum_value2 (enum_arg)
 enum enumtype enum_arg;
 {
   return (enum_arg == enum_val2);
 }

 t_enum_value3 (enum_arg)
 enum enumtype enum_arg;
 {
   return (enum_arg == enum_val3);
 }

 /* A function that takes a vector of integers (along with an explicit
    count) and returns their sum. */

 int sum_args (argc, argv)
 int argc;
 int argv[];
 {
   int sumval = 0;
   int idx;

   for (idx = 0; idx < argc; idx++)
     {
       sumval += argv[idx];
     }
   return (sumval);
 }

 /* Test that we can call functions that take structs and return
    members from that struct */

 char   t_structs_c (tstruct) struct struct1 tstruct; { return (tstruct.c); }
 short  t_structs_s (tstruct) struct struct1 tstruct; { return (tstruct.s); }
 int    t_structs_i (tstruct) struct struct1 tstruct; { return (tstruct.i); }
 long   t_structs_l (tstruct) struct struct1 tstruct; { return (tstruct.l); }
 float  t_structs_f (tstruct) struct struct1 tstruct; { return (tstruct.f); }
 double t_structs_d (tstruct) struct struct1 tstruct; { return (tstruct.d); }
 char  *t_structs_a (tstruct) struct struct1 tstruct; { return (tstruct.a); }

 /* Test that calling functions works if there are a lot of arguments.  */
 int
 sum10 (i0, i1, i2, i3, i4, i5, i6, i7, i8, i9)
      int i0, i1, i2, i3, i4, i5, i6, i7, i8, i9;
 {
   return i0 + i1 + i2 + i3 + i4 + i5 + i6 + i7 + i8 + i9;
 }

 /* Gotta have a main to be able to generate a linked, runnable
    executable, and also provide a useful place to set a breakpoint. */

 main ()
 {
 #ifdef usestubs
   set_debug_traps();
   breakpoint();
 #endif
   t_structs_c(struct_val1);
 }

 /* Functions that expect specific values to be passed and return
    either 0 or 1, depending upon whether the values were
    passed incorrectly or correctly, respectively. */

 int t_char_values (char_arg1, char_arg2)
 char char_arg1, char_arg2;
 {
   return ((char_arg1 == char_val1) && (char_arg2 == char_val2));
 }

 int
 #ifdef NO_PROTOTYPES
 t_small_values (arg1, arg2, arg3, arg4, arg5, arg6, arg7, arg8, arg9, arg10)
      char arg1;
      short arg2;
      int arg3;
      char arg4;
      short arg5;
      char arg6;
      short arg7;
      int arg8;
      short arg9;
      short arg10;
 #else
 t_small_values (char arg1, short arg2, int arg3, char arg4, short arg5,
 		char arg6, short arg7, int arg8, short arg9, short arg10)
 #endif
 {
   return arg1 + arg2 + arg3 + arg4 + arg5 + arg6 + arg7 + arg8 + arg9 + arg10;
 }

 int t_short_values (short_arg1, short_arg2)
 short short_arg1, short_arg2;
 {
   return ((short_arg1 == short_val1) && (short_arg2 == short_val2));
 }

 int t_int_values (int_arg1, int_arg2)
 int int_arg1, int_arg2;
 {
   return ((int_arg1 == int_val1) && (int_arg2 == int_val2));
 }

 int t_long_values (long_arg1, long_arg2)
 long long_arg1, long_arg2;
 {
   return ((long_arg1 == long_val1) && (long_arg2 == long_val2));
 }

 int t_float_values (float_arg1, float_arg2)
 float float_arg1, float_arg2;
 {
   return ((float_arg1 - float_val1) < DELTA
 	  && (float_arg1 - float_val1) > -DELTA
 	  && (float_arg2 - float_val2) < DELTA
 	  && (float_arg2 - float_val2) > -DELTA);
 }

 int
 #ifdef NO_PROTOTYPES
 /* In this case we are just duplicating t_float_values, but that is the
    easiest way to deal with either ANSI or non-ANSI.  */
 t_float_values2 (float_arg1, float_arg2)
      float float_arg1, float_arg2;
 #else
 t_float_values2 (float float_arg1, float float_arg2)
 #endif
 {
   return ((float_arg1 - float_val1) < DELTA
 	  && (float_arg1 - float_val1) > -DELTA
 	  && (float_arg2 - float_val2) < DELTA
 	  && (float_arg2 - float_val2) > -DELTA);
 }

 int t_double_values (double_arg1, double_arg2)
 double double_arg1, double_arg2;
 {
   return ((double_arg1 - double_val1) < DELTA
 	  && (double_arg1 - double_val1) > -DELTA
 	  && (double_arg2 - double_val2) < DELTA
 	  && (double_arg2 - double_val2) > -DELTA);
 }

 int t_string_values (string_arg1, string_arg2)
 char *string_arg1, *string_arg2;
 {
   return (!strcmp (string_arg1, string_val1) &&
 	  !strcmp (string_arg2, string_val2));
 }

 int t_char_array_values (char_array_arg1, char_array_arg2)
 char char_array_arg1[], char_array_arg2[];
 {
   return (!strcmp (char_array_arg1, char_array_val1) &&
 	  !strcmp (char_array_arg2, char_array_val2));
 }


 /* This used to simply compare the function pointer arguments with
    known values for func_val1 and func_val2.  Doing so is valid ANSI
    code, but on some machines (RS6000, HPPA, others?) it may fail when
    called directly by GDB.

    In a nutshell, it's not possible for GDB to determine when the address
    of a function or the address of the function's stub/trampoline should
    be passed.

    So, to avoid GDB lossage in the common case, we perform calls through the
    various function pointers and compare the return values.  For the HPPA
    at least, this allows the common case to work.

    If one wants to try something more complicated, pass the address of
    a function accepting a "double" as one of its first 4 arguments.  Call
    that function indirectly through the function pointer.  This would fail
    on the HPPA.  */

 int t_func_values (func_arg1, func_arg2)
 int (*func_arg1) PARAMS ((int, int));
 int (*func_arg2) PARAMS ((int));
 {
   return ((*func_arg1) (5,5)  == (*func_val1) (5,5)
           && (*func_arg2) (6) == (*func_val2) (6));
 }

 int t_call_add (func_arg1, a, b)
 int (*func_arg1) PARAMS ((int, int));
 int a, b;
 {
   return ((*func_arg1)(a, b));
 }
	/* Support program for testing gdb's ability to call functions
	in an inferior which doesn't itself call malloc, pass appropriate
	arguments to those functions, and get the returned result. */

	#ifdef NO_PROTOTYPES
	#define PARAMS(paramlist) ()
	#else
	#define PARAMS(paramlist) paramlist
	#endif

	char char_val1 = 'a';
	char char_val2 = 'b';

	short short_val1 = 10;
	short short_val2 = -23;

	int int_val1 = 87;
	int int_val2 = -26;

	long long_val1 = 789;
	long long_val2 = -321;

	float float_val1 = 3.14159;
	float float_val2 = -2.3765;

	double double_val1 = 45.654;
	double double_val2 = -67.66;

	#define DELTA (0.001)

	char *string_val1 = "string 1";
	char *string_val2 = "string 2";

	char char_array_val1[] = "carray 1";
	char char_array_val2[] = "carray 2";

	struct struct1 {
	char c;
	short s;
	int i;
	long l;
	float f;
	double d;
	char a[4];
	} struct_val1 = { 'x', 87, 76, 51, 2.1234, 9.876, "foo" };

	/* Some functions that can be passed as arguments to other test
	functions, or called directly. */

	int add (a, b)
	int a, b;
	{
	return (a + b);
	}

	int doubleit (a)
	int a;
	{
	return (a + a);
	}

	int (*func_val1) PARAMS((int,int)) = add;
	int (*func_val2) PARAMS((int)) = doubleit;

	/* An enumeration and functions that test for specific values. */

	enum enumtype { enumval1, enumval2, enumval3 };
	enum enumtype enum_val1 = enumval1;
	enum enumtype enum_val2 = enumval2;
	enum enumtype enum_val3 = enumval3;

	t_enum_value1 (enum_arg)
	enum enumtype enum_arg;
	{
	return (enum_arg == enum_val1);
	}

	t_enum_value2 (enum_arg)
	enum enumtype enum_arg;
	{
	return (enum_arg == enum_val2);
	}

	t_enum_value3 (enum_arg)
	enum enumtype enum_arg;
	{
	return (enum_arg == enum_val3);
	}

	/* A function that takes a vector of integers (along with an explicit
	count) and returns their sum. */

	int sum_args (argc, argv)
	int argc;
	int argv[];
	{
	int sumval = 0;
	int idx;

	for (idx = 0; idx < argc; idx++)
	{
	sumval += argv[idx];
	}
	return (sumval);
	}

	/* Test that we can call functions that take structs and return
	members from that struct */

	char t_structs_c (tstruct) struct struct1 tstruct; { return (tstruct.c); }
	short t_structs_s (tstruct) struct struct1 tstruct; { return (tstruct.s); }
	int t_structs_i (tstruct) struct struct1 tstruct; { return (tstruct.i); }
	long t_structs_l (tstruct) struct struct1 tstruct; { return (tstruct.l); }
	float t_structs_f (tstruct) struct struct1 tstruct; { return (tstruct.f); }
	double t_structs_d (tstruct) struct struct1 tstruct; { return (tstruct.d); }
	char *t_structs_a (tstruct) struct struct1 tstruct; { return (tstruct.a); }

	/* Test that calling functions works if there are a lot of arguments. */
	int
	sum10 (i0, i1, i2, i3, i4, i5, i6, i7, i8, i9)
	int i0, i1, i2, i3, i4, i5, i6, i7, i8, i9;
	{
	return i0 + i1 + i2 + i3 + i4 + i5 + i6 + i7 + i8 + i9;
	}

	/* Gotta have a main to be able to generate a linked, runnable
	executable, and also provide a useful place to set a breakpoint. */

	main ()
	{
	#ifdef usestubs
	set_debug_traps();
	breakpoint();
	#endif
	t_structs_c(struct_val1);
	}

	/* Functions that expect specific values to be passed and return
	either 0 or 1, depending upon whether the values were
	passed incorrectly or correctly, respectively. */

	int t_char_values (char_arg1, char_arg2)
	char char_arg1, char_arg2;
	{
	return ((char_arg1 == char_val1) && (char_arg2 == char_val2));
	}

	int
	#ifdef NO_PROTOTYPES
	t_small_values (arg1, arg2, arg3, arg4, arg5, arg6, arg7, arg8, arg9, arg10)
	char arg1;
	short arg2;
	int arg3;
	char arg4;
	short arg5;
	char arg6;
	short arg7;
	int arg8;
	short arg9;
	short arg10;
	#else
	t_small_values (char arg1, short arg2, int arg3, char arg4, short arg5,
	char arg6, short arg7, int arg8, short arg9, short arg10)
	#endif
	{
	return arg1 + arg2 + arg3 + arg4 + arg5 + arg6 + arg7 + arg8 + arg9 + arg10;
	}

	int t_short_values (short_arg1, short_arg2)
	short short_arg1, short_arg2;
	{
	return ((short_arg1 == short_val1) && (short_arg2 == short_val2));
	}

	int t_int_values (int_arg1, int_arg2)
	int int_arg1, int_arg2;
	{
	return ((int_arg1 == int_val1) && (int_arg2 == int_val2));
	}

	int t_long_values (long_arg1, long_arg2)
	long long_arg1, long_arg2;
	{
	return ((long_arg1 == long_val1) && (long_arg2 == long_val2));
	}

	int t_float_values (float_arg1, float_arg2)
	float float_arg1, float_arg2;
	{
	return ((float_arg1 - float_val1) < DELTA
	&& (float_arg1 - float_val1) > -DELTA
	&& (float_arg2 - float_val2) < DELTA
	&& (float_arg2 - float_val2) > -DELTA);
	}

	int
	#ifdef NO_PROTOTYPES
	/* In this case we are just duplicating t_float_values, but that is the
	easiest way to deal with either ANSI or non-ANSI. */
	t_float_values2 (float_arg1, float_arg2)
	float float_arg1, float_arg2;
	#else
	t_float_values2 (float float_arg1, float float_arg2)
	#endif
	{
	return ((float_arg1 - float_val1) < DELTA
	&& (float_arg1 - float_val1) > -DELTA
	&& (float_arg2 - float_val2) < DELTA
	&& (float_arg2 - float_val2) > -DELTA);
	}

	int t_double_values (double_arg1, double_arg2)
	double double_arg1, double_arg2;
	{
	return ((double_arg1 - double_val1) < DELTA
	&& (double_arg1 - double_val1) > -DELTA
	&& (double_arg2 - double_val2) < DELTA
	&& (double_arg2 - double_val2) > -DELTA);
	}

	int t_string_values (string_arg1, string_arg2)
	char string_arg1, string_arg2;
	{
	return (!strcmp (string_arg1, string_val1) &&
	!strcmp (string_arg2, string_val2));
	}

	int t_char_array_values (char_array_arg1, char_array_arg2)
	char char_array_arg1[], char_array_arg2[];
	{
	return (!strcmp (char_array_arg1, char_array_val1) &&
	!strcmp (char_array_arg2, char_array_val2));
	}


	/* This used to simply compare the function pointer arguments with
	known values for func_val1 and func_val2. Doing so is valid ANSI
	code, but on some machines (RS6000, HPPA, others?) it may fail when
	called directly by GDB.

	In a nutshell, it's not possible for GDB to determine when the address
	of a function or the address of the function's stub/trampoline should
	be passed.

	So, to avoid GDB lossage in the common case, we perform calls through the
	various function pointers and compare the return values. For the HPPA
	at least, this allows the common case to work.

	If one wants to try something more complicated, pass the address of
	a function accepting a "double" as one of its first 4 arguments. Call
	that function indirectly through the function pointer. This would fail
	on the HPPA. */

	int t_func_values (func_arg1, func_arg2)
	int (*func_arg1) PARAMS ((int, int));
	int (*func_arg2) PARAMS ((int));
	{
	return ((func_arg1) (5,5) == (func_val1) (5,5)
	&& (func_arg2) (6) == (func_val2) (6));
	}

	int t_call_add (func_arg1, a, b)
	int (*func_arg1) PARAMS ((int, int));
	int a, b;
	{
	return ((*func_arg1)(a, b));
	}