@c GNU verify module documentation @c Copyright (C) 2006, 2009--2020 Free Software Foundation, Inc. @c Permission is granted to copy, distribute and/or modify this document @c under the terms of the GNU Free Documentation License, Version 1.3 or @c any later version published by the Free Software Foundation; with no @c Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A @c copy of the license is at . @node Compile-time Assertions @section Compile-time Assertions @cindex assertion @findex verify @findex verify_expr This module provides a header file @file{verify.h} that defines macros related to compile-time verification. Two of these macros are @code{verify (@var{V})} and @code{verify_expr (@var{V}, @var{EXPR})}. Both accept an integer constant expression argument @var{V} and verify that it is nonzero. If not, a compile-time error results. These two macros implement compile-time tests, as opposed to the standard @code{assert} macro which supports only runtime tests. Since the tests occur at compile-time, they are more reliable, and they require no runtime overhead. @code{verify (@var{V});} is a declaration; it can occur outside of functions. In contrast, @code{verify_expr (@var{V}, @var{EXPR})} is an expression that returns the value of @var{EXPR}; it can be used in macros that expand to expressions. If @var{EXPR} is an integer constant expression, then @code{verify_expr (@var{V}, @var{EXPR})} is also an integer constant expression. Although @var{EXPR} and @code{verify_expr (@var{V}, @var{EXPR})}@ are guaranteed to have the same side effects and value and type (after integer promotion), they need not have the same type if @var{EXPR}'s type is an integer that is narrower than @code{int} or @code{unsigned int}. @var{V} should be an integer constant expression in the sense of the C standard. Its leaf operands should be integer, enumeration, or character constants; or @code{sizeof} expressions that return constants; or floating constants that are the immediate operands of casts. Outside a @code{sizeof} subexpression, @var{V} should not contain any assignments, function calls, comma operators, casts to non-integer types, or subexpressions whose values are outside the representable ranges for their types. If @var{V} is not an integer constant expression, then a compiler might reject a usage like @samp{verify (@var{V});} even when @var{V} is nonzero. Although the standard @code{assert} macro is a runtime test, C2X specifies a builtin @code{_Static_assert (@var{V})}, its @file{assert.h} header has a similar macro named @code{static_assert}, and C++17 has a similar @code{static_assert} builtin. These builtins and macros differ from @code{verify} in two major ways. First, they can also be used within a @code{struct} or @code{union} specifier, in place of an ordinary member declaration. Second, they allow the programmer to specify, as an optional second argument, a compile-time diagnostic as a string literal. If your program is not intended to be portable to compilers that lack C2X or C++17 @code{static_assert}, the only advantage of @code{verify} is that its name is a bit shorter. The @file{verify.h} header defines one more macro, @code{assume (@var{E})}, which expands to an expression of type @code{void} that causes the compiler to assume that @var{E} yields a nonzero value. @var{E} should be a scalar expression, and should not have side effects; it may or may not be evaluated. The behavior is undefined if @var{E} would yield zero. The main use of @code{assume} is optimization, as the compiler may be able to generate better code if it assumes @var{E}. For best results, @var{E} should be simple enough that a compiler can determine that it has no side effects: if @var{E} calls an external function or accesses volatile storage the compiler may not be able to optimize @var{E} away and @code{assume (@var{E})} may therefore slow down the program. Here are some example uses of these macros. @example #include #include #include /* Verify that time_t is an integer type. */ verify ((time_t) 1.5 == 1); /* Verify that time_t is no smaller than int. */ verify (sizeof (int) <= sizeof (time_t)); /* Verify that time_t is signed. */ verify ((time_t) -1 < 0); /* Verify that time_t uses two's complement representation. */ verify (~ (time_t) -1 == 0); /* Return the maximum value of the integer type T, verifying that T is an unsigned integer type. The cast to (T) is outside the call to verify_expr so that the result is of type T even when T is narrower than unsigned int. */ #define MAX_UNSIGNED_VAL(t) \ ((T) verify_expr (0 < (T) -1, -1)) /* Return T divided by CHAR_MAX + 1, where behavior is undefined if T < 0. In the common case where CHAR_MAX is 127 the compiler can therefore implement the division by shifting T right 7 bits, an optimization that would not be valid if T were negative. */ time_t time_index (time_t t) @{ assume (0 <= t); return t / (CHAR_MAX + 1); @} @end example