lib/verify.h - platform/external/bison - Git at Google

 /* Compile-time assert-like macros.

    Copyright (C) 2005, 2006 Free Software Foundation, Inc.

    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2, or (at your option)
    any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program; if not, write to the Free Software Foundation,
    Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.  */

 /* Written by Paul Eggert, Bruno Haible, and Jim Meyering.  */

 #ifndef VERIFY_H
 # define VERIFY_H 1

 /* Each of these macros verifies that its argument R is nonzero.  To
    be portable, R should be an integer constant expression.  Unlike
    assert (R), there is no run-time overhead.

    There are two macros, since no single macro can be used in all
    contexts in C.  verify_true (R) is for scalar contexts, including
    integer constant expression contexts.  verify (R) is for declaration
    contexts, e.g., the top level.

    Symbols ending in "__" are private to this header.

    The code below uses several ideas.

    * The first step is ((R) ? 1 : -1).  Given an expression R, of
      integral or boolean or floating-point type, this yields an
      expression of integral type, whose value is later verified to be
      constant and nonnegative.

    * Next this expression W is wrapped in a type
      struct verify_type__ { unsigned int verify_error_if_negative_size__: W; }.
      If W is negative, this yields a compile-time error.  No compiler can
      deal with a bit-field of negative size.

      One might think that an array size check would have the same
      effect, that is, that the type struct { unsigned int dummy[W]; }
      would work as well.  However, inside a function, some compilers
      (such as C++ compilers and GNU C) allow local parameters and
      variables inside array size expressions.  With these compilers,
      an array size check would not properly diagnose this misuse of
      the verify macro:

        void function (int n) { verify (n < 0); }

    * For the verify macro, the struct verify_type__ will need to
      somehow be embedded into a declaration.  To be portable, this
      declaration must declare an object, a constant, a function, or a
      typedef name.  If the declared entity uses the type directly,
      such as in

        struct dummy {...};
        typedef struct {...} dummy;
        extern struct {...} *dummy;
        extern void dummy (struct {...} *);
        extern struct {...} *dummy (void);

      two uses of the verify macro would yield colliding declarations
      if the entity names are not disambiguated.  A workaround is to
      attach the current line number to the entity name:

        #define GL_CONCAT0(x, y) x##y
        #define GL_CONCAT(x, y) GL_CONCAT0 (x, y)
        extern struct {...} * GL_CONCAT(dummy,__LINE__);

      But this has the problem that two invocations of verify from
      within the same macro would collide, since the __LINE__ value
      would be the same for both invocations.

      A solution is to use the sizeof operator.  It yields a number,
      getting rid of the identity of the type.  Declarations like

        extern int dummy [sizeof (struct {...})];
        extern void dummy (int [sizeof (struct {...})]);
        extern int (*dummy (void)) [sizeof (struct {...})];

      can be repeated.

    * Should the implementation use a named struct or an unnamed struct?
      Which of the following alternatives can be used?

        extern int dummy [sizeof (struct {...})];
        extern int dummy [sizeof (struct verify_type__ {...})];
        extern void dummy (int [sizeof (struct {...})]);
        extern void dummy (int [sizeof (struct verify_type__ {...})]);
        extern int (*dummy (void)) [sizeof (struct {...})];
        extern int (*dummy (void)) [sizeof (struct verify_type__ {...})];

      In the second and sixth case, the struct type is exported to the
      outer scope; two such declarations therefore collide.  GCC warns
      about the first, third, and fourth cases.  So the only remaining
      possibility is the fifth case:

        extern int (*dummy (void)) [sizeof (struct {...})];

    * This implementation exploits the fact that GCC does not warn about
      the last declaration mentioned above.  If a future version of GCC
      introduces a warning for this, the problem could be worked around
      by using code specialized to GCC, e.g.,:

        #if 4 <= __GNUC__
        # define verify(R) \
 	   extern int (* verify_function__ (void)) \
 		      [__builtin_constant_p (R) && (R) ? 1 : -1]
        #endif

    * In C++, any struct definition inside sizeof is invalid.
      Use a template type to work around the problem.  */


 /* Verify requirement R at compile-time, as an integer constant expression.
    Return 1.  */

 # ifdef __cplusplus
 template <int w>
   struct verify_type__ { unsigned int verify_error_if_negative_size__: w; };
 #  define verify_true(R) \
      (!!sizeof (verify_type__<(R) ? 1 : -1>))
 # else
 #  define verify_true(R) \
      (!!sizeof \
       (struct { unsigned int verify_error_if_negative_size__: (R) ? 1 : -1; }))
 # endif

 /* Verify requirement R at compile-time, as a declaration without a
    trailing ';'.  */

 # define verify(R) extern int (* verify_function__ (void)) [verify_true (R)]

 #endif
	/* Compile-time assert-like macros.

	Copyright (C) 2005, 2006 Free Software Foundation, Inc.

	This program is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 2, or (at your option)
	any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program; if not, write to the Free Software Foundation,
	Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */

	/* Written by Paul Eggert, Bruno Haible, and Jim Meyering. */

	#ifndef VERIFY_H
	# define VERIFY_H 1

	/* Each of these macros verifies that its argument R is nonzero. To
	be portable, R should be an integer constant expression. Unlike
	assert (R), there is no run-time overhead.

	There are two macros, since no single macro can be used in all
	contexts in C. verify_true (R) is for scalar contexts, including
	integer constant expression contexts. verify (R) is for declaration
	contexts, e.g., the top level.

	Symbols ending in "__" are private to this header.

	The code below uses several ideas.

	* The first step is ((R) ? 1 : -1). Given an expression R, of
	integral or boolean or floating-point type, this yields an
	expression of integral type, whose value is later verified to be
	constant and nonnegative.

	* Next this expression W is wrapped in a type
	struct verify_type__ { unsigned int verify_error_if_negative_size__: W; }.
	If W is negative, this yields a compile-time error. No compiler can
	deal with a bit-field of negative size.

	One might think that an array size check would have the same
	effect, that is, that the type struct { unsigned int dummy[W]; }
	would work as well. However, inside a function, some compilers
	(such as C++ compilers and GNU C) allow local parameters and
	variables inside array size expressions. With these compilers,
	an array size check would not properly diagnose this misuse of
	the verify macro:

	void function (int n) { verify (n < 0); }

	* For the verify macro, the struct verify_type__ will need to
	somehow be embedded into a declaration. To be portable, this
	declaration must declare an object, a constant, a function, or a
	typedef name. If the declared entity uses the type directly,
	such as in

	struct dummy {...};
	typedef struct {...} dummy;
	extern struct {...} *dummy;
	extern void dummy (struct {...} *);
	extern struct {...} *dummy (void);

	two uses of the verify macro would yield colliding declarations
	if the entity names are not disambiguated. A workaround is to
	attach the current line number to the entity name:

	#define GL_CONCAT0(x, y) x##y
	#define GL_CONCAT(x, y) GL_CONCAT0 (x, y)
	extern struct {...} * GL_CONCAT(dummy,__LINE__);

	But this has the problem that two invocations of verify from
	within the same macro would collide, since the __LINE__ value
	would be the same for both invocations.

	A solution is to use the sizeof operator. It yields a number,
	getting rid of the identity of the type. Declarations like

	extern int dummy [sizeof (struct {...})];
	extern void dummy (int [sizeof (struct {...})]);
	extern int (*dummy (void)) [sizeof (struct {...})];

	can be repeated.

	* Should the implementation use a named struct or an unnamed struct?
	Which of the following alternatives can be used?

	extern int dummy [sizeof (struct {...})];
	extern int dummy [sizeof (struct verify_type__ {...})];
	extern void dummy (int [sizeof (struct {...})]);
	extern void dummy (int [sizeof (struct verify_type__ {...})]);
	extern int (*dummy (void)) [sizeof (struct {...})];
	extern int (*dummy (void)) [sizeof (struct verify_type__ {...})];

	In the second and sixth case, the struct type is exported to the
	outer scope; two such declarations therefore collide. GCC warns
	about the first, third, and fourth cases. So the only remaining
	possibility is the fifth case:

	extern int (*dummy (void)) [sizeof (struct {...})];

	* This implementation exploits the fact that GCC does not warn about
	the last declaration mentioned above. If a future version of GCC
	introduces a warning for this, the problem could be worked around
	by using code specialized to GCC, e.g.,:

	#if 4 <= __GNUC__
	# define verify(R) \
	extern int (* verify_function__ (void)) \
	[__builtin_constant_p (R) && (R) ? 1 : -1]
	#endif

	* In C++, any struct definition inside sizeof is invalid.
	Use a template type to work around the problem. */


	/* Verify requirement R at compile-time, as an integer constant expression.
	Return 1. */

	# ifdef __cplusplus
	template <int w>
	struct verify_type__ { unsigned int verify_error_if_negative_size__: w; };
	# define verify_true(R) \
	(!!sizeof (verify_type__<(R) ? 1 : -1>))
	# else
	# define verify_true(R) \
	(!!sizeof \
	(struct { unsigned int verify_error_if_negative_size__: (R) ? 1 : -1; }))
	# endif

	/* Verify requirement R at compile-time, as a declaration without a
	trailing ';'. */

	# define verify(R) extern int (* verify_function__ (void)) [verify_true (R)]

	#endif