[bpt/guile.git] / lib / verify.h

/* Compile-time assert-like macros.

   Copyright (C) 2005-2006, 2009-2011 Free Software Foundation, Inc.

   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU Lesser General Public License as published by
   the Free Software Foundation; either version 3 of the License, 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 Lesser General Public License for more details.

   You should have received a copy of the GNU Lesser General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.  */

/* 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.  (The GCC __COUNTER__
     macro solves this problem, but is not portable.)

     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 {...})];

   * GCC warns about duplicate declarations of the dummy function if
     -Wredundant_decls is used.  GCC 4.3 and later have a builtin
     __COUNTER__ macro that can let us generate unique identifiers for
     each dummy function, to suppress this warning.

   * 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, just as __COUNTER__ is already
     being used if available.

       #if 4 <= __GNUC__
       # define verify(R) [another version to keep GCC happy]
       #endif

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

/* Concatenate two preprocessor tokens.  */
# define _GL_CONCAT(x, y) _GL_CONCAT0 (x, y)
# define _GL_CONCAT0(x, y) x##y

/* _GL_COUNTER is an integer, preferably one that changes each time we
   use it.  Use __COUNTER__ if it works, falling back on __LINE__
   otherwise.  __LINE__ isn't perfect, but it's better than a
   constant.  */
# if defined __COUNTER__ && __COUNTER__ != __COUNTER__
#  define _GL_COUNTER __COUNTER__
# else
#  define _GL_COUNTER __LINE__
# endif

/* Generate a symbol with the given prefix, making it unique if
   possible.  */
# define _GL_GENSYM(prefix) _GL_CONCAT (prefix, _GL_COUNTER)

/* 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 (* _GL_GENSYM (verify_function) (void)) [verify_true (R)]

#endif
Commit	Line	Data
d7014610 LC	1	/* Compile-time assert-like macros.
d7014610 LC	2
49114fd4	3	Copyright (C) 2005-2006, 2009-2011 Free Software Foundation, Inc.
d7014610 LC	4
	5	This program is free software: you can redistribute it and/or modify
	6	it under the terms of the GNU Lesser General Public License as published by
	7	the Free Software Foundation; either version 3 of the License, or
	8	(at your option) any later version.
	9
	10	This program is distributed in the hope that it will be useful,
	11	but WITHOUT ANY WARRANTY; without even the implied warranty of
	12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	13	GNU Lesser General Public License for more details.
	14
	15	You should have received a copy of the GNU Lesser General Public License
	16	along with this program. If not, see <http://www.gnu.org/licenses/>. */
	17
	18	/* Written by Paul Eggert, Bruno Haible, and Jim Meyering. */
	19
	20	#ifndef VERIFY_H
	21	# define VERIFY_H 1
	22
	23	/* Each of these macros verifies that its argument R is nonzero. To
	24	be portable, R should be an integer constant expression. Unlike
	25	assert (R), there is no run-time overhead.
	26
	27	There are two macros, since no single macro can be used in all
	28	contexts in C. verify_true (R) is for scalar contexts, including
	29	integer constant expression contexts. verify (R) is for declaration
	30	contexts, e.g., the top level.
	31
	32	Symbols ending in "__" are private to this header.
	33
	34	The code below uses several ideas.
	35
	36	* The first step is ((R) ? 1 : -1). Given an expression R, of
	37	integral or boolean or floating-point type, this yields an
	38	expression of integral type, whose value is later verified to be
	39	constant and nonnegative.
	40
	41	* Next this expression W is wrapped in a type
	42	struct verify_type__ { unsigned int verify_error_if_negative_size__: W; }.
	43	If W is negative, this yields a compile-time error. No compiler can
	44	deal with a bit-field of negative size.
	45
	46	One might think that an array size check would have the same
	47	effect, that is, that the type struct { unsigned int dummy[W]; }
	48	would work as well. However, inside a function, some compilers
	49	(such as C++ compilers and GNU C) allow local parameters and
	50	variables inside array size expressions. With these compilers,
	51	an array size check would not properly diagnose this misuse of
	52	the verify macro:
	53
	54	void function (int n) { verify (n < 0); }
	55
	56	* For the verify macro, the struct verify_type__ will need to
	57	somehow be embedded into a declaration. To be portable, this
	58	declaration must declare an object, a constant, a function, or a
	59	typedef name. If the declared entity uses the type directly,
	60	such as in
	61
	62	struct dummy {...};
	63	typedef struct {...} dummy;
	64	extern struct {...} *dummy;
	65	extern void dummy (struct {...} *);
	66	extern struct {...} *dummy (void);
	67
68	two uses of the verify macro would yield colliding declarations
69	if the entity names are not disambiguated. A workaround is to
70	attach the current line number to the entity name:
71
a927b6c1 LC	72	#define _GL_CONCAT0(x, y) x##y
	73	#define _GL_CONCAT(x, y) _GL_CONCAT0 (x, y)
	74	extern struct {...} * _GL_CONCAT (dummy, __LINE__);
d7014610 LC	75
	76	But this has the problem that two invocations of verify from
	77	within the same macro would collide, since the __LINE__ value
a927b6c1 LC	78	would be the same for both invocations. (The GCC __COUNTER__
a927b6c1 LC	79	macro solves this problem, but is not portable.)
d7014610 LC	80
	81	A solution is to use the sizeof operator. It yields a number,
	82	getting rid of the identity of the type. Declarations like
	83
	84	extern int dummy [sizeof (struct {...})];
	85	extern void dummy (int [sizeof (struct {...})]);
	86	extern int (*dummy (void)) [sizeof (struct {...})];
	87
	88	can be repeated.
	89
	90	* Should the implementation use a named struct or an unnamed struct?
	91	Which of the following alternatives can be used?
	92
	93	extern int dummy [sizeof (struct {...})];
	94	extern int dummy [sizeof (struct verify_type__ {...})];
	95	extern void dummy (int [sizeof (struct {...})]);
	96	extern void dummy (int [sizeof (struct verify_type__ {...})]);
	97	extern int (*dummy (void)) [sizeof (struct {...})];
	98	extern int (*dummy (void)) [sizeof (struct verify_type__ {...})];
	99
	100	In the second and sixth case, the struct type is exported to the
	101	outer scope; two such declarations therefore collide. GCC warns
	102	about the first, third, and fourth cases. So the only remaining
	103	possibility is the fifth case:
	104
	105	extern int (*dummy (void)) [sizeof (struct {...})];
	106
a927b6c1 LC	107	* GCC warns about duplicate declarations of the dummy function if
	108	-Wredundant_decls is used. GCC 4.3 and later have a builtin
	109	__COUNTER__ macro that can let us generate unique identifiers for
	110	each dummy function, to suppress this warning.
	111
d7014610 LC	112	* This implementation exploits the fact that GCC does not warn about
	113	the last declaration mentioned above. If a future version of GCC
	114	introduces a warning for this, the problem could be worked around
a927b6c1 LC	115	by using code specialized to GCC, just as __COUNTER__ is already
a927b6c1 LC	116	being used if available.
d7014610 LC	117
d7014610 LC	118	#if 4 <= __GNUC__
a927b6c1	119	# define verify(R) [another version to keep GCC happy]
d7014610 LC	120	#endif
	121
	122	* In C++, any struct definition inside sizeof is invalid.
	123	Use a template type to work around the problem. */
	124
a927b6c1 LC	125	/* Concatenate two preprocessor tokens. */
	126	# define _GL_CONCAT(x, y) _GL_CONCAT0 (x, y)
	127	# define _GL_CONCAT0(x, y) x##y
	128
	129	/* _GL_COUNTER is an integer, preferably one that changes each time we
	130	use it. Use __COUNTER__ if it works, falling back on __LINE__
	131	otherwise. __LINE__ isn't perfect, but it's better than a
	132	constant. */
	133	# if defined __COUNTER__ && __COUNTER__ != __COUNTER__
	134	# define _GL_COUNTER __COUNTER__
	135	# else
	136	# define _GL_COUNTER __LINE__
	137	# endif
	138
	139	/* Generate a symbol with the given prefix, making it unique if
	140	possible. */
	141	# define _GL_GENSYM(prefix) _GL_CONCAT (prefix, _GL_COUNTER)
d7014610 LC	142
	143	/* Verify requirement R at compile-time, as an integer constant expression.
	144	Return 1. */
	145
	146	# ifdef __cplusplus
	147	template <int w>
	148	struct verify_type__ { unsigned int verify_error_if_negative_size__: w; };
	149	# define verify_true(R) \
	150	(!!sizeof (verify_type__<(R) ? 1 : -1>))
	151	# else
	152	# define verify_true(R) \
	153	(!!sizeof \
	154	(struct { unsigned int verify_error_if_negative_size__: (R) ? 1 : -1; }))
	155	# endif
	156
	157	/* Verify requirement R at compile-time, as a declaration without a
	158	trailing ';'. */
	159
a927b6c1 LC	160	# define verify(R) \
a927b6c1 LC	161	extern int (* _GL_GENSYM (verify_function) (void)) [verify_true (R)]
d7014610 LC	162
d7014610 LC	163	#endif