include/zephyr/sys/util_macro.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2011-2014, Wind River Systems, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  * @brief Macro utilities
  *
  * Macro utilities are the public interface for C/C++ code and device tree
  * related implementation.  In general, C/C++ will include <sys/util.h>
  * instead this file directly.  For device tree implementation, this file
  * should be include instead <sys/util_internal.h>
  */

 #ifndef ZEPHYR_INCLUDE_SYS_UTIL_MACROS_H_
 #define ZEPHYR_INCLUDE_SYS_UTIL_MACROS_H_

 #ifdef __cplusplus
 extern "C" {
 #endif

 /**
  * @addtogroup sys-util
  * @{
  */

 /*
  * Most of the eldritch implementation details for all the macrobatics
  * below (APIs like IS_ENABLED(), COND_CODE_1(), etc.) are hidden away
  * in this file.
  */
 #include <zephyr/sys/util_internal.h>

 #ifndef BIT
 #if defined(_ASMLANGUAGE)
 #define BIT(n)  (1 << (n))
 #else
 /**
  * @brief Unsigned integer with bit position @p n set (signed in
  * assembly language).
  */
 #define BIT(n)  (1UL << (n))
 #endif
 #endif

 /** @brief 64-bit unsigned integer with bit position @p _n set. */
 #define BIT64(_n) (1ULL << (_n))

 /**
  * @brief Set or clear a bit depending on a boolean value
  *
  * The argument @p var is a variable whose value is written to as a
  * side effect.
  *
  * @param var Variable to be altered
  * @param bit Bit number
  * @param set if 0, clears @p bit in @p var; any other value sets @p bit
  */
 #define WRITE_BIT(var, bit, set) \
 	((var) = (set) ? ((var) | BIT(bit)) : ((var) & ~BIT(bit)))

 /**
  * @brief Bit mask with bits 0 through <tt>n-1</tt> (inclusive) set,
  * or 0 if @p n is 0.
  */
 #define BIT_MASK(n) (BIT(n) - 1UL)

 /**
  * @brief 64-bit bit mask with bits 0 through <tt>n-1</tt> (inclusive) set,
  * or 0 if @p n is 0.
  */
 #define BIT64_MASK(n) (BIT64(n) - 1ULL)

 /**
  * @brief Check for macro definition in compiler-visible expressions
  *
  * This trick was pioneered in Linux as the config_enabled() macro. It
  * has the effect of taking a macro value that may be defined to "1"
  * or may not be defined at all and turning it into a literal
  * expression that can be handled by the C compiler instead of just
  * the preprocessor. It is often used with a @p CONFIG_FOO macro which
  * may be defined to 1 via Kconfig, or left undefined.
  *
  * That is, it works similarly to <tt>\#if defined(CONFIG_FOO)</tt>
  * except that its expansion is a C expression. Thus, much <tt>\#ifdef</tt>
  * usage can be replaced with equivalents like:
  *
  *     if (IS_ENABLED(CONFIG_FOO)) {
  *             do_something_with_foo
  *     }
  *
  * This is cleaner since the compiler can generate errors and warnings
  * for @p do_something_with_foo even when @p CONFIG_FOO is undefined.
  *
  * @param config_macro Macro to check
  * @return 1 if @p config_macro is defined to 1, 0 otherwise (including
  *         if @p config_macro is not defined)
  */
 #define IS_ENABLED(config_macro) Z_IS_ENABLED1(config_macro)
 /* INTERNAL: the first pass above is just to expand any existing
  * macros, we need the macro value to be e.g. a literal "1" at
  * expansion time in the next macro, not "(1)", etc... Standard
  * recursive expansion does not work.
  */

 /**
  * @brief Insert code depending on whether @p _flag expands to 1 or not.
  *
  * This relies on similar tricks as IS_ENABLED(), but as the result of
  * @p _flag expansion, results in either @p _if_1_code or @p
  * _else_code is expanded.
  *
  * To prevent the preprocessor from treating commas as argument
  * separators, the @p _if_1_code and @p _else_code expressions must be
  * inside brackets/parentheses: <tt>()</tt>. These are stripped away
  * during macro expansion.
  *
  * Example:
  *
  *     COND_CODE_1(CONFIG_FLAG, (uint32_t x;), (there_is_no_flag();))
  *
  * If @p CONFIG_FLAG is defined to 1, this expands to:
  *
  *     uint32_t x;
  *
  * It expands to <tt>there_is_no_flag();</tt> otherwise.
  *
  * This could be used as an alternative to:
  *
  *     #if defined(CONFIG_FLAG) && (CONFIG_FLAG == 1)
  *     #define MAYBE_DECLARE(x) uint32_t x
  *     #else
  *     #define MAYBE_DECLARE(x) there_is_no_flag()
  *     #endif
  *
  *     MAYBE_DECLARE(x);
  *
  * However, the advantage of COND_CODE_1() is that code is resolved in
  * place where it is used, while the @p \#if method defines @p
  * MAYBE_DECLARE on two lines and requires it to be invoked again on a
  * separate line. This makes COND_CODE_1() more concise and also
  * sometimes more useful when used within another macro's expansion.
  *
  * @note @p _flag can be the result of preprocessor expansion, e.g.
  *	 an expression involving <tt>NUM_VA_ARGS_LESS_1(...)</tt>.
  *	 However, @p _if_1_code is only expanded if @p _flag expands
  *	 to the integer literal 1. Integer expressions that evaluate
  *	 to 1, e.g. after doing some arithmetic, will not work.
  *
  * @param _flag evaluated flag
  * @param _if_1_code result if @p _flag expands to 1; must be in parentheses
  * @param _else_code result otherwise; must be in parentheses
  */
 #define COND_CODE_1(_flag, _if_1_code, _else_code) \
 	Z_COND_CODE_1(_flag, _if_1_code, _else_code)

 /**
  * @brief Like COND_CODE_1() except tests if @p _flag is 0.
  *
  * This is like COND_CODE_1(), except that it tests whether @p _flag
  * expands to the integer literal 0. It expands to @p _if_0_code if
  * so, and @p _else_code otherwise; both of these must be enclosed in
  * parentheses.
  *
  * @param _flag evaluated flag
  * @param _if_0_code result if @p _flag expands to 0; must be in parentheses
  * @param _else_code result otherwise; must be in parentheses
  * @see COND_CODE_1()
  */
 #define COND_CODE_0(_flag, _if_0_code, _else_code) \
 	Z_COND_CODE_0(_flag, _if_0_code, _else_code)

 /**
  * @brief Insert code if @p _flag is defined and equals 1.
  *
  * Like COND_CODE_1(), this expands to @p _code if @p _flag is defined to 1;
  * it expands to nothing otherwise.
  *
  * Example:
  *
  *     IF_ENABLED(CONFIG_FLAG, (uint32_t foo;))
  *
  * If @p CONFIG_FLAG is defined to 1, this expands to:
  *
  *     uint32_t foo;
  *
  * and to nothing otherwise.
  *
  * It can be considered as a more compact alternative to:
  *
  *     #if defined(CONFIG_FLAG) && (CONFIG_FLAG == 1)
  *     uint32_t foo;
  *     #endif
  *
  * @param _flag evaluated flag
  * @param _code result if @p _flag expands to 1; must be in parentheses
  */
 #define IF_ENABLED(_flag, _code) \
 	COND_CODE_1(_flag, _code, ())

 /**
  * @brief Check if a macro has a replacement expression
  *
  * If @p a is a macro defined to a nonempty value, this will return
  * true, otherwise it will return false. It only works with defined
  * macros, so an additional @p \#ifdef test may be needed in some cases.
  *
  * This macro may be used with COND_CODE_1() and COND_CODE_0() while
  * processing <tt>__VA_ARGS__</tt> to avoid processing empty arguments.
  *
  * Example:
  *
  *	#define EMPTY
  *	#define NON_EMPTY	1
  *	#undef  UNDEFINED
  *	IS_EMPTY(EMPTY)
  *	IS_EMPTY(NON_EMPTY)
  *	IS_EMPTY(UNDEFINED)
  *	#if defined(EMPTY) && IS_EMPTY(EMPTY) == true
  *	some_conditional_code
  *	#endif
  *
  * In above examples, the invocations of IS_EMPTY(...) return @p true,
  * @p false, and @p true; @p some_conditional_code is included.
  *
  * @param ... macro to check for emptiness (may be <tt>__VA_ARGS__</tt>)
  */
 #define IS_EMPTY(...) Z_IS_EMPTY_(__VA_ARGS__)

 /**
  * @brief Like <tt>a == b</tt>, but does evaluation and
  * short-circuiting at C preprocessor time.
  *
  * This however only works for integer literal from 0 to 255.
  *
  */
 #define IS_EQ(a, b) Z_IS_EQ(a, b)

 /**
  * @brief Remove empty arguments from list.
  *
  * During macro expansion, <tt>__VA_ARGS__</tt> and other preprocessor
  * generated lists may contain empty elements, e.g.:
  *
  *	#define LIST ,a,b,,d,
  *
  * Using EMPTY to show each empty element, LIST contains:
  *
  *      EMPTY, a, b, EMPTY, d
  *
  * When processing such lists, e.g. using FOR_EACH(), all empty elements
  * will be processed, and may require filtering out.
  * To make that process easier, it is enough to invoke LIST_DROP_EMPTY
  * which will remove all empty elements.
  *
  * Example:
  *
  *	LIST_DROP_EMPTY(LIST)
  *
  * expands to:
  *
  *	a, b, d
  *
  * @param ... list to be processed
  */
 #define LIST_DROP_EMPTY(...) \
 	Z_LIST_DROP_FIRST(FOR_EACH(Z_LIST_NO_EMPTIES, (), __VA_ARGS__))

 /**
  * @brief Macro with an empty expansion
  *
  * This trivial definition is provided for readability when a macro
  * should expand to an empty result, which e.g. is sometimes needed to
  * silence checkpatch.
  *
  * Example:
  *
  *	#define LIST_ITEM(n) , item##n
  *
  * The above would cause checkpatch to complain, but:
  *
  *	#define LIST_ITEM(n) EMPTY, item##n
  *
  * would not.
  */
 #define EMPTY

 /**
  * @brief Macro that expands to its argument
  *
  * This is useful in macros like @c FOR_EACH() when there is no
  * transformation required on the list elements.
  *
  * @param V any value
  */
 #define IDENTITY(V) V

 /**
  * @brief Get nth argument from argument list.
  *
  * @param N Argument index to fetch. Counter from 1.
  * @param ... Variable list of arguments from which one argument is returned.
  *
  * @return Nth argument.
  */
 #define GET_ARG_N(N, ...) Z_GET_ARG_##N(__VA_ARGS__)

 /**
  * @brief Strips n first arguments from the argument list.
  *
  * @param N Number of arguments to discard.
  * @param ... Variable list of arguments.
  *
  * @return argument list without N first arguments.
  */
 #define GET_ARGS_LESS_N(N, ...) Z_GET_ARGS_LESS_##N(__VA_ARGS__)

 /**
  * @brief Like <tt>a || b</tt>, but does evaluation and
  * short-circuiting at C preprocessor time.
  *
  * This is not the same as the binary @p || operator; in particular,
  * @p a should expand to an integer literal 0 or 1. However, @p b
  * can be any value.
  *
  * This can be useful when @p b is an expression that would cause a
  * build error when @p a is 1.
  */
 #define UTIL_OR(a, b) COND_CODE_1(UTIL_BOOL(a), (a), (b))

 /**
  * @brief Like <tt>a && b</tt>, but does evaluation and
  * short-circuiting at C preprocessor time.
  *
  * This is not the same as the binary @p &&, however; in particular,
  * @p a should expand to an integer literal 0 or 1. However, @p b
  * can be any value.
  *
  * This can be useful when @p b is an expression that would cause a
  * build error when @p a is 0.
  */
 #define UTIL_AND(a, b) COND_CODE_1(UTIL_BOOL(a), (b), (0))

 /**
  * @brief Generates a sequence of code with configurable separator.
  *
  * Example:
  *
  *     #define FOO(i, _) MY_PWM ## i
  *     { LISTIFY(PWM_COUNT, FOO, (,)) }
  *
  * The above two lines expand to:
  *
  *    { MY_PWM0 , MY_PWM1 }
  *
  * @param LEN The length of the sequence. Must be an integer literal less
  *            than 255.
  * @param F A macro function that accepts at least two arguments:
  *          <tt>F(i, ...)</tt>. @p F is called repeatedly in the expansion.
  *          Its first argument @p i is the index in the sequence, and
  *          the variable list of arguments passed to LISTIFY are passed
  *          through to @p F.
  *
  * @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
  *            this is required to enable providing a comma as separator.
  *
  * @note Calling LISTIFY with undefined arguments has undefined
  * behavior.
  */
 #define LISTIFY(LEN, F, sep, ...) UTIL_CAT(Z_UTIL_LISTIFY_, LEN)(F, sep, __VA_ARGS__)

 /**
  * @brief Generates a sequence of code. Deprecated, use @ref LISTIFY.
  *
  * @deprecated Use @ref LISTIFY instead.
  *
  * Example:
  *
  *     #define FOO(i, _) MY_PWM ## i ,
  *     { UTIL_LISTIFY(PWM_COUNT, FOO) }
  *
  * The above two lines expand to:
  *
  *    { MY_PWM0 , MY_PWM1 , }
  *
  * @param LEN The length of the sequence. Must be an integer literal less
  *            than 255.
  * @param F A macro function that accepts at least two arguments:
  *          <tt>F(i, ...)</tt>. @p F is called repeatedly in the expansion.
  *          Its first argument @p i is the index in the sequence, and
  *          the variable list of arguments passed to UTIL_LISTIFY are passed
  *          through to @p F.
  *
  * @note Calling UTIL_LISTIFY with undefined arguments has undefined
  * behavior.
  */
 #define UTIL_LISTIFY(LEN, F, ...) LISTIFY(LEN, F, (), __VA_ARGS__) __DEPRECATED_MACRO

 /**
  * @brief Call a macro @p F on each provided argument with a given
  *        separator between each call.
  *
  * Example:
  *
  *     #define F(x) int a##x
  *     FOR_EACH(F, (;), 4, 5, 6);
  *
  * This expands to:
  *
  *     int a4;
  *     int a5;
  *     int a6;
  *
  * @param F Macro to invoke
  * @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
  *            this is required to enable providing a comma as separator.
  * @param ... Variable argument list. The macro @p F is invoked as
  *            <tt>F(element)</tt> for each element in the list.
  */
 #define FOR_EACH(F, sep, ...) \
 	Z_FOR_EACH(F, sep, REVERSE_ARGS(__VA_ARGS__))

 /**
  * @brief Like FOR_EACH(), but with a terminator instead of a separator,
  *        and drops empty elements from the argument list
  *
  * The @p sep argument to <tt>FOR_EACH(F, (sep), a, b)</tt> is a
  * separator which is placed between calls to @p F, like this:
  *
  *     FOR_EACH(F, (sep), a, b) // F(a) sep F(b)
  *                              //               ^^^ no sep here!
  *
  * By contrast, the @p term argument to <tt>FOR_EACH_NONEMPTY_TERM(F, (term),
  * a, b)</tt> is added after each time @p F appears in the expansion:
  *
  *     FOR_EACH_NONEMPTY_TERM(F, (term), a, b) // F(a) term F(b) term
  *                                             //                ^^^^
  *
  * Further, any empty elements are dropped:
  *
  *     FOR_EACH_NONEMPTY_TERM(F, (term), a, EMPTY, b) // F(a) term F(b) term
  *
  * This is more convenient in some cases, because FOR_EACH_NONEMPTY_TERM()
  * expands to nothing when given an empty argument list, and it's
  * often cumbersome to write a macro @p F that does the right thing
  * even when given an empty argument.
  *
  * One example is when <tt>__VA_ARGS__</tt> may or may not be empty,
  * and the results are embedded in a larger initializer:
  *
  *     #define SQUARE(x) ((x)*(x))
  *
  *     int my_array[] = {
  *             FOR_EACH_NONEMPTY_TERM(SQUARE, (,), FOO(...))
  *             FOR_EACH_NONEMPTY_TERM(SQUARE, (,), BAR(...))
  *             FOR_EACH_NONEMPTY_TERM(SQUARE, (,), BAZ(...))
  *     };
  *
  * This is more convenient than:
  *
  * 1. figuring out whether the @p FOO, @p BAR, and @p BAZ expansions
  *    are empty and adding a comma manually (or not) between FOR_EACH()
  *    calls
  * 2. rewriting SQUARE so it reacts appropriately when "x" is empty
  *    (which would be necessary if e.g. @p FOO expands to nothing)
  *
  * @param F Macro to invoke on each nonempty element of the variable
  *          arguments
  * @param term Terminator (e.g. comma or semicolon) placed after each
  *             invocation of F. Must be in parentheses; this is required
  *             to enable providing a comma as separator.
  * @param ... Variable argument list. The macro @p F is invoked as
  *            <tt>F(element)</tt> for each nonempty element in the list.
  */
 #define FOR_EACH_NONEMPTY_TERM(F, term, ...)				\
 	COND_CODE_0(							\
 		/* are there zero non-empty arguments ? */		\
 		NUM_VA_ARGS_LESS_1(LIST_DROP_EMPTY(__VA_ARGS__, _)),	\
 		/* if so, expand to nothing */				\
 		(),							\
 		/* otherwise, expand to: */				\
 		(/* FOR_EACH() on nonempty elements, */		\
 			FOR_EACH(F, term, LIST_DROP_EMPTY(__VA_ARGS__))	\
 			/* plus a final terminator */			\
 			__DEBRACKET term				\
 		))

 /**
  * @brief Call macro @p F on each provided argument, with the argument's index
  *        as an additional parameter.
  *
  * This is like FOR_EACH(), except @p F should be a macro which takes two
  * arguments: <tt>F(index, variable_arg)</tt>.
  *
  * Example:
  *
  *     #define F(idx, x) int a##idx = x
  *     FOR_EACH_IDX(F, (;), 4, 5, 6);
  *
  * This expands to:
  *
  *     int a0 = 4;
  *     int a1 = 5;
  *     int a2 = 6;
  *
  * @param F Macro to invoke
  * @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
  *            this is required to enable providing a comma as separator.
  * @param ... Variable argument list. The macro @p F is invoked as
  *            <tt>F(index, element)</tt> for each element in the list.
  */
 #define FOR_EACH_IDX(F, sep, ...) \
 	Z_FOR_EACH_IDX(F, sep, REVERSE_ARGS(__VA_ARGS__))

 /**
  * @brief Call macro @p F on each provided argument, with an additional fixed
  *	  argument as a parameter.
  *
  * This is like FOR_EACH(), except @p F should be a macro which takes two
  * arguments: <tt>F(variable_arg, fixed_arg)</tt>.
  *
  * Example:
  *
  *     static void func(int val, void *dev);
  *     FOR_EACH_FIXED_ARG(func, (;), dev, 4, 5, 6);
  *
  * This expands to:
  *
  *     func(4, dev);
  *     func(5, dev);
  *     func(6, dev);
  *
  * @param F Macro to invoke
  * @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
  *            this is required to enable providing a comma as separator.
  * @param fixed_arg Fixed argument passed to @p F as the second macro parameter.
  * @param ... Variable argument list. The macro @p F is invoked as
  *            <tt>F(element, fixed_arg)</tt> for each element in the list.
  */
 #define FOR_EACH_FIXED_ARG(F, sep, fixed_arg, ...) \
 	Z_FOR_EACH_FIXED_ARG(F, sep, fixed_arg, REVERSE_ARGS(__VA_ARGS__))

 /**
  * @brief Calls macro @p F for each variable argument with an index and fixed
  *        argument
  *
  * This is like the combination of FOR_EACH_IDX() with FOR_EACH_FIXED_ARG().
  *
  * Example:
  *
  *     #define F(idx, x, fixed_arg) int fixed_arg##idx = x
  *     FOR_EACH_IDX_FIXED_ARG(F, (;), a, 4, 5, 6);
  *
  * This expands to:
  *
  *     int a0 = 4;
  *     int a1 = 5;
  *     int a2 = 6;
  *
  * @param F Macro to invoke
  * @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
  *            This is required to enable providing a comma as separator.
  * @param fixed_arg Fixed argument passed to @p F as the third macro parameter.
  * @param ... Variable list of arguments. The macro @p F is invoked as
  *            <tt>F(index, element, fixed_arg)</tt> for each element in
  *            the list.
  */
 #define FOR_EACH_IDX_FIXED_ARG(F, sep, fixed_arg, ...) \
 	Z_FOR_EACH_IDX_FIXED_ARG(F, sep, fixed_arg, REVERSE_ARGS(__VA_ARGS__))

 /** @brief Reverse arguments order.
  *
  * @param ... Variable argument list.
  */
 #define REVERSE_ARGS(...) \
 	Z_FOR_EACH_ENGINE(Z_FOR_EACH_EXEC, (,), Z_BYPASS, _, __VA_ARGS__)

 /**
  * @brief Number of arguments in the variable arguments list minus one.
  *
  * @param ... List of arguments
  * @return  Number of variadic arguments in the argument list, minus one
  */
 #define NUM_VA_ARGS_LESS_1(...) \
 	NUM_VA_ARGS_LESS_1_IMPL(__VA_ARGS__, 63, 62, 61, \
 	60, 59, 58, 57, 56, 55, 54, 53, 52, 51,		 \
 	50, 49, 48, 47, 46, 45, 44, 43, 42, 41,		 \
 	40, 39, 38, 37, 36, 35, 34, 33, 32, 31,		 \
 	30, 29, 28, 27, 26, 25, 24, 23, 22, 21,		 \
 	20, 19, 18, 17, 16, 15, 14, 13, 12, 11,		 \
 	10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0, ~)

 /**
  * @brief Mapping macro that pastes results together
  *
  * This is similar to FOR_EACH() in that it invokes a macro repeatedly
  * on each element of <tt>__VA_ARGS__</tt>. However, unlike FOR_EACH(),
  * MACRO_MAP_CAT() pastes the results together into a single token.
  *
  * For example, with this macro FOO:
  *
  *     #define FOO(x) item_##x##_
  *
  * <tt>MACRO_MAP_CAT(FOO, a, b, c),</tt> expands to the token:
  *
  *     item_a_item_b_item_c_
  *
  * @param ... Macro to expand on each argument, followed by its
  *            arguments. (The macro should take exactly one argument.)
  * @return The results of expanding the macro on each argument, all pasted
  *         together
  */
 #define MACRO_MAP_CAT(...) MACRO_MAP_CAT_(__VA_ARGS__)

 /**
  * @brief Mapping macro that pastes a fixed number of results together
  *
  * Similar to @ref MACRO_MAP_CAT(), but expects a fixed number of
  * arguments. If more arguments are given than are expected, the rest
  * are ignored.
  *
  * @param N   Number of arguments to map
  * @param ... Macro to expand on each argument, followed by its
  *            arguments. (The macro should take exactly one argument.)
  * @return The results of expanding the macro on each argument, all pasted
  *         together
  */
 #define MACRO_MAP_CAT_N(N, ...) MACRO_MAP_CAT_N_(N, __VA_ARGS__)

 /**
  * @}
  */

 #ifdef __cplusplus
 }
 #endif

 #endif /* ZEPHYR_INCLUDE_SYS_UTIL_MACROS_H_ */
	/*
	* Copyright (c) 2011-2014, Wind River Systems, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	* @brief Macro utilities
	*
	* Macro utilities are the public interface for C/C++ code and device tree
	* related implementation. In general, C/C++ will include <sys/util.h>
	* instead this file directly. For device tree implementation, this file
	* should be include instead <sys/util_internal.h>
	*/

	#ifndef ZEPHYR_INCLUDE_SYS_UTIL_MACROS_H_
	#define ZEPHYR_INCLUDE_SYS_UTIL_MACROS_H_

	#ifdef __cplusplus
	extern "C" {
	#endif

	/**
	* @addtogroup sys-util
	* @{
	*/

	/*
	* Most of the eldritch implementation details for all the macrobatics
	* below (APIs like IS_ENABLED(), COND_CODE_1(), etc.) are hidden away
	* in this file.
	*/
	#include <zephyr/sys/util_internal.h>

	#ifndef BIT
	#if defined(_ASMLANGUAGE)
	#define BIT(n) (1 << (n))
	#else
	/**
	* @brief Unsigned integer with bit position @p n set (signed in
	* assembly language).
	*/
	#define BIT(n) (1UL << (n))
	#endif
	#endif

	/** @brief 64-bit unsigned integer with bit position @p _n set. */
	#define BIT64(_n) (1ULL << (_n))

	/**
	* @brief Set or clear a bit depending on a boolean value
	*
	* The argument @p var is a variable whose value is written to as a
	* side effect.
	*
	* @param var Variable to be altered
	* @param bit Bit number
	* @param set if 0, clears @p bit in @p var; any other value sets @p bit
	*/
	#define WRITE_BIT(var, bit, set) \
	((var) = (set) ? ((var) \| BIT(bit)) : ((var) & ~BIT(bit)))

	/**
	* @brief Bit mask with bits 0 through <tt>n-1</tt> (inclusive) set,
	* or 0 if @p n is 0.
	*/
	#define BIT_MASK(n) (BIT(n) - 1UL)

	/**
	* @brief 64-bit bit mask with bits 0 through <tt>n-1</tt> (inclusive) set,
	* or 0 if @p n is 0.
	*/
	#define BIT64_MASK(n) (BIT64(n) - 1ULL)

	/**
	* @brief Check for macro definition in compiler-visible expressions
	*
	* This trick was pioneered in Linux as the config_enabled() macro. It
	* has the effect of taking a macro value that may be defined to "1"
	* or may not be defined at all and turning it into a literal
	* expression that can be handled by the C compiler instead of just
	* the preprocessor. It is often used with a @p CONFIG_FOO macro which
	* may be defined to 1 via Kconfig, or left undefined.
	*
	* That is, it works similarly to <tt>\#if defined(CONFIG_FOO)</tt>
	* except that its expansion is a C expression. Thus, much <tt>\#ifdef</tt>
	* usage can be replaced with equivalents like:
	*
	* if (IS_ENABLED(CONFIG_FOO)) {
	* do_something_with_foo
	* }
	*
	* This is cleaner since the compiler can generate errors and warnings
	* for @p do_something_with_foo even when @p CONFIG_FOO is undefined.
	*
	* @param config_macro Macro to check
	* @return 1 if @p config_macro is defined to 1, 0 otherwise (including
	* if @p config_macro is not defined)
	*/
	#define IS_ENABLED(config_macro) Z_IS_ENABLED1(config_macro)
	/* INTERNAL: the first pass above is just to expand any existing
	* macros, we need the macro value to be e.g. a literal "1" at
	* expansion time in the next macro, not "(1)", etc... Standard
	* recursive expansion does not work.
	*/

	/**
	* @brief Insert code depending on whether @p _flag expands to 1 or not.
	*
	* This relies on similar tricks as IS_ENABLED(), but as the result of
	* @p _flag expansion, results in either @p _if_1_code or @p
	* _else_code is expanded.
	*
	* To prevent the preprocessor from treating commas as argument
	* separators, the @p _if_1_code and @p _else_code expressions must be
	* inside brackets/parentheses: <tt>()</tt>. These are stripped away
	* during macro expansion.
	*
	* Example:
	*
	* COND_CODE_1(CONFIG_FLAG, (uint32_t x;), (there_is_no_flag();))
	*
	* If @p CONFIG_FLAG is defined to 1, this expands to:
	*
	* uint32_t x;
	*
	* It expands to <tt>there_is_no_flag();</tt> otherwise.
	*
	* This could be used as an alternative to:
	*
	* #if defined(CONFIG_FLAG) && (CONFIG_FLAG == 1)
	* #define MAYBE_DECLARE(x) uint32_t x
	* #else
	* #define MAYBE_DECLARE(x) there_is_no_flag()
	* #endif
	*
	* MAYBE_DECLARE(x);
	*
	* However, the advantage of COND_CODE_1() is that code is resolved in
	* place where it is used, while the @p \#if method defines @p
	* MAYBE_DECLARE on two lines and requires it to be invoked again on a
	* separate line. This makes COND_CODE_1() more concise and also
	* sometimes more useful when used within another macro's expansion.
	*
	* @note @p _flag can be the result of preprocessor expansion, e.g.
	* an expression involving <tt>NUM_VA_ARGS_LESS_1(...)</tt>.
	* However, @p _if_1_code is only expanded if @p _flag expands
	* to the integer literal 1. Integer expressions that evaluate
	* to 1, e.g. after doing some arithmetic, will not work.
	*
	* @param _flag evaluated flag
	* @param _if_1_code result if @p _flag expands to 1; must be in parentheses
	* @param _else_code result otherwise; must be in parentheses
	*/
	#define COND_CODE_1(_flag, _if_1_code, _else_code) \
	Z_COND_CODE_1(_flag, _if_1_code, _else_code)

	/**
	* @brief Like COND_CODE_1() except tests if @p _flag is 0.
	*
	* This is like COND_CODE_1(), except that it tests whether @p _flag
	* expands to the integer literal 0. It expands to @p _if_0_code if
	* so, and @p _else_code otherwise; both of these must be enclosed in
	* parentheses.
	*
	* @param _flag evaluated flag
	* @param _if_0_code result if @p _flag expands to 0; must be in parentheses
	* @param _else_code result otherwise; must be in parentheses
	* @see COND_CODE_1()
	*/
	#define COND_CODE_0(_flag, _if_0_code, _else_code) \
	Z_COND_CODE_0(_flag, _if_0_code, _else_code)

	/**
	* @brief Insert code if @p _flag is defined and equals 1.
	*
	* Like COND_CODE_1(), this expands to @p _code if @p _flag is defined to 1;
	* it expands to nothing otherwise.
	*
	* Example:
	*
	* IF_ENABLED(CONFIG_FLAG, (uint32_t foo;))
	*
	* If @p CONFIG_FLAG is defined to 1, this expands to:
	*
	* uint32_t foo;
	*
	* and to nothing otherwise.
	*
	* It can be considered as a more compact alternative to:
	*
	* #if defined(CONFIG_FLAG) && (CONFIG_FLAG == 1)
	* uint32_t foo;
	* #endif
	*
	* @param _flag evaluated flag
	* @param _code result if @p _flag expands to 1; must be in parentheses
	*/
	#define IF_ENABLED(_flag, _code) \
	COND_CODE_1(_flag, _code, ())

	/**
	* @brief Check if a macro has a replacement expression
	*
	* If @p a is a macro defined to a nonempty value, this will return
	* true, otherwise it will return false. It only works with defined
	* macros, so an additional @p \#ifdef test may be needed in some cases.
	*
	* This macro may be used with COND_CODE_1() and COND_CODE_0() while
	* processing <tt>__VA_ARGS__</tt> to avoid processing empty arguments.
	*
	* Example:
	*
	* #define EMPTY
	* #define NON_EMPTY 1
	* #undef UNDEFINED
	* IS_EMPTY(EMPTY)
	* IS_EMPTY(NON_EMPTY)
	* IS_EMPTY(UNDEFINED)
	* #if defined(EMPTY) && IS_EMPTY(EMPTY) == true
	* some_conditional_code
	* #endif
	*
	* In above examples, the invocations of IS_EMPTY(...) return @p true,
	* @p false, and @p true; @p some_conditional_code is included.
	*
	* @param ... macro to check for emptiness (may be <tt>__VA_ARGS__</tt>)
	*/
	#define IS_EMPTY(...) Z_IS_EMPTY_(__VA_ARGS__)

	/**
	* @brief Like <tt>a == b</tt>, but does evaluation and
	* short-circuiting at C preprocessor time.
	*
	* This however only works for integer literal from 0 to 255.
	*
	*/
	#define IS_EQ(a, b) Z_IS_EQ(a, b)

	/**
	* @brief Remove empty arguments from list.
	*
	* During macro expansion, <tt>__VA_ARGS__</tt> and other preprocessor
	* generated lists may contain empty elements, e.g.:
	*
	* #define LIST ,a,b,,d,
	*
	* Using EMPTY to show each empty element, LIST contains:
	*
	* EMPTY, a, b, EMPTY, d
	*
	* When processing such lists, e.g. using FOR_EACH(), all empty elements
	* will be processed, and may require filtering out.
	* To make that process easier, it is enough to invoke LIST_DROP_EMPTY
	* which will remove all empty elements.
	*
	* Example:
	*
	* LIST_DROP_EMPTY(LIST)
	*
	* expands to:
	*
	* a, b, d
	*
	* @param ... list to be processed
	*/
	#define LIST_DROP_EMPTY(...) \
	Z_LIST_DROP_FIRST(FOR_EACH(Z_LIST_NO_EMPTIES, (), __VA_ARGS__))

	/**
	* @brief Macro with an empty expansion
	*
	* This trivial definition is provided for readability when a macro
	* should expand to an empty result, which e.g. is sometimes needed to
	* silence checkpatch.
	*
	* Example:
	*
	* #define LIST_ITEM(n) , item##n
	*
	* The above would cause checkpatch to complain, but:
	*
	* #define LIST_ITEM(n) EMPTY, item##n
	*
	* would not.
	*/
	#define EMPTY

	/**
	* @brief Macro that expands to its argument
	*
	* This is useful in macros like @c FOR_EACH() when there is no
	* transformation required on the list elements.
	*
	* @param V any value
	*/
	#define IDENTITY(V) V

	/**
	* @brief Get nth argument from argument list.
	*
	* @param N Argument index to fetch. Counter from 1.
	* @param ... Variable list of arguments from which one argument is returned.
	*
	* @return Nth argument.
	*/
	#define GET_ARG_N(N, ...) Z_GET_ARG_##N(__VA_ARGS__)

	/**
	* @brief Strips n first arguments from the argument list.
	*
	* @param N Number of arguments to discard.
	* @param ... Variable list of arguments.
	*
	* @return argument list without N first arguments.
	*/
	#define GET_ARGS_LESS_N(N, ...) Z_GET_ARGS_LESS_##N(__VA_ARGS__)

	/**
	* @brief Like <tt>a \|\| b</tt>, but does evaluation and
	* short-circuiting at C preprocessor time.
	*
	* This is not the same as the binary @p \|\| operator; in particular,
	* @p a should expand to an integer literal 0 or 1. However, @p b
	* can be any value.
	*
	* This can be useful when @p b is an expression that would cause a
	* build error when @p a is 1.
	*/
	#define UTIL_OR(a, b) COND_CODE_1(UTIL_BOOL(a), (a), (b))

	/**
	* @brief Like <tt>a && b</tt>, but does evaluation and
	* short-circuiting at C preprocessor time.
	*
	* This is not the same as the binary @p &&, however; in particular,
	* @p a should expand to an integer literal 0 or 1. However, @p b
	* can be any value.
	*
	* This can be useful when @p b is an expression that would cause a
	* build error when @p a is 0.
	*/
	#define UTIL_AND(a, b) COND_CODE_1(UTIL_BOOL(a), (b), (0))

	/**
	* @brief Generates a sequence of code with configurable separator.
	*
	* Example:
	*
	* #define FOO(i, _) MY_PWM ## i
	* { LISTIFY(PWM_COUNT, FOO, (,)) }
	*
	* The above two lines expand to:
	*
	* { MY_PWM0 , MY_PWM1 }
	*
	* @param LEN The length of the sequence. Must be an integer literal less
	* than 255.
	* @param F A macro function that accepts at least two arguments:
	* <tt>F(i, ...)</tt>. @p F is called repeatedly in the expansion.
	* Its first argument @p i is the index in the sequence, and
	* the variable list of arguments passed to LISTIFY are passed
	* through to @p F.
	*
	* @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
	* this is required to enable providing a comma as separator.
	*
	* @note Calling LISTIFY with undefined arguments has undefined
	* behavior.
	*/
	#define LISTIFY(LEN, F, sep, ...) UTIL_CAT(Z_UTIL_LISTIFY_, LEN)(F, sep, __VA_ARGS__)

	/**
	* @brief Generates a sequence of code. Deprecated, use @ref LISTIFY.
	*
	* @deprecated Use @ref LISTIFY instead.
	*
	* Example:
	*
	* #define FOO(i, _) MY_PWM ## i ,
	* { UTIL_LISTIFY(PWM_COUNT, FOO) }
	*
	* The above two lines expand to:
	*
	* { MY_PWM0 , MY_PWM1 , }
	*
	* @param LEN The length of the sequence. Must be an integer literal less
	* than 255.
	* @param F A macro function that accepts at least two arguments:
	* <tt>F(i, ...)</tt>. @p F is called repeatedly in the expansion.
	* Its first argument @p i is the index in the sequence, and
	* the variable list of arguments passed to UTIL_LISTIFY are passed
	* through to @p F.
	*
	* @note Calling UTIL_LISTIFY with undefined arguments has undefined
	* behavior.
	*/
	#define UTIL_LISTIFY(LEN, F, ...) LISTIFY(LEN, F, (), __VA_ARGS__) __DEPRECATED_MACRO

	/**
	* @brief Call a macro @p F on each provided argument with a given
	* separator between each call.
	*
	* Example:
	*
	* #define F(x) int a##x
	* FOR_EACH(F, (;), 4, 5, 6);
	*
	* This expands to:
	*
	* int a4;
	* int a5;
	* int a6;
	*
	* @param F Macro to invoke
	* @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
	* this is required to enable providing a comma as separator.
	* @param ... Variable argument list. The macro @p F is invoked as
	* <tt>F(element)</tt> for each element in the list.
	*/
	#define FOR_EACH(F, sep, ...) \
	Z_FOR_EACH(F, sep, REVERSE_ARGS(__VA_ARGS__))

	/**
	* @brief Like FOR_EACH(), but with a terminator instead of a separator,
	* and drops empty elements from the argument list
	*
	* The @p sep argument to <tt>FOR_EACH(F, (sep), a, b)</tt> is a
	* separator which is placed between calls to @p F, like this:
	*
	* FOR_EACH(F, (sep), a, b) // F(a) sep F(b)
	* // ^^^ no sep here!
	*
	* By contrast, the @p term argument to <tt>FOR_EACH_NONEMPTY_TERM(F, (term),
	* a, b)</tt> is added after each time @p F appears in the expansion:
	*
	* FOR_EACH_NONEMPTY_TERM(F, (term), a, b) // F(a) term F(b) term
	* // ^^^^
	*
	* Further, any empty elements are dropped:
	*
	* FOR_EACH_NONEMPTY_TERM(F, (term), a, EMPTY, b) // F(a) term F(b) term
	*
	* This is more convenient in some cases, because FOR_EACH_NONEMPTY_TERM()
	* expands to nothing when given an empty argument list, and it's
	* often cumbersome to write a macro @p F that does the right thing
	* even when given an empty argument.
	*
	* One example is when <tt>__VA_ARGS__</tt> may or may not be empty,
	* and the results are embedded in a larger initializer:
	*
	* #define SQUARE(x) ((x)*(x))
	*
	* int my_array[] = {
	* FOR_EACH_NONEMPTY_TERM(SQUARE, (,), FOO(...))
	* FOR_EACH_NONEMPTY_TERM(SQUARE, (,), BAR(...))
	* FOR_EACH_NONEMPTY_TERM(SQUARE, (,), BAZ(...))
	* };
	*
	* This is more convenient than:
	*
	* 1. figuring out whether the @p FOO, @p BAR, and @p BAZ expansions
	* are empty and adding a comma manually (or not) between FOR_EACH()
	* calls
	* 2. rewriting SQUARE so it reacts appropriately when "x" is empty
	* (which would be necessary if e.g. @p FOO expands to nothing)
	*
	* @param F Macro to invoke on each nonempty element of the variable
	* arguments
	* @param term Terminator (e.g. comma or semicolon) placed after each
	* invocation of F. Must be in parentheses; this is required
	* to enable providing a comma as separator.
	* @param ... Variable argument list. The macro @p F is invoked as
	* <tt>F(element)</tt> for each nonempty element in the list.
	*/
	#define FOR_EACH_NONEMPTY_TERM(F, term, ...) \
	COND_CODE_0( \
	/* are there zero non-empty arguments ? */ \
	NUM_VA_ARGS_LESS_1(LIST_DROP_EMPTY(__VA_ARGS__, _)), \
	/* if so, expand to nothing */ \
	(), \
	/* otherwise, expand to: */ \
	(/* FOR_EACH() on nonempty elements, */ \
	FOR_EACH(F, term, LIST_DROP_EMPTY(__VA_ARGS__)) \
	/* plus a final terminator */ \
	__DEBRACKET term \
	))

	/**
	* @brief Call macro @p F on each provided argument, with the argument's index
	* as an additional parameter.
	*
	* This is like FOR_EACH(), except @p F should be a macro which takes two
	* arguments: <tt>F(index, variable_arg)</tt>.
	*
	* Example:
	*
	* #define F(idx, x) int a##idx = x
	* FOR_EACH_IDX(F, (;), 4, 5, 6);
	*
	* This expands to:
	*
	* int a0 = 4;
	* int a1 = 5;
	* int a2 = 6;
	*
	* @param F Macro to invoke
	* @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
	* this is required to enable providing a comma as separator.
	* @param ... Variable argument list. The macro @p F is invoked as
	* <tt>F(index, element)</tt> for each element in the list.
	*/
	#define FOR_EACH_IDX(F, sep, ...) \
	Z_FOR_EACH_IDX(F, sep, REVERSE_ARGS(__VA_ARGS__))

	/**
	* @brief Call macro @p F on each provided argument, with an additional fixed
	* argument as a parameter.
	*
	* This is like FOR_EACH(), except @p F should be a macro which takes two
	* arguments: <tt>F(variable_arg, fixed_arg)</tt>.
	*
	* Example:
	*
	* static void func(int val, void *dev);
	* FOR_EACH_FIXED_ARG(func, (;), dev, 4, 5, 6);
	*
	* This expands to:
	*
	* func(4, dev);
	* func(5, dev);
	* func(6, dev);
	*
	* @param F Macro to invoke
	* @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
	* this is required to enable providing a comma as separator.
	* @param fixed_arg Fixed argument passed to @p F as the second macro parameter.
	* @param ... Variable argument list. The macro @p F is invoked as
	* <tt>F(element, fixed_arg)</tt> for each element in the list.
	*/
	#define FOR_EACH_FIXED_ARG(F, sep, fixed_arg, ...) \
	Z_FOR_EACH_FIXED_ARG(F, sep, fixed_arg, REVERSE_ARGS(__VA_ARGS__))

	/**
	* @brief Calls macro @p F for each variable argument with an index and fixed
	* argument
	*
	* This is like the combination of FOR_EACH_IDX() with FOR_EACH_FIXED_ARG().
	*
	* Example:
	*
	* #define F(idx, x, fixed_arg) int fixed_arg##idx = x
	* FOR_EACH_IDX_FIXED_ARG(F, (;), a, 4, 5, 6);
	*
	* This expands to:
	*
	* int a0 = 4;
	* int a1 = 5;
	* int a2 = 6;
	*
	* @param F Macro to invoke
	* @param sep Separator (e.g. comma or semicolon). Must be in parentheses;
	* This is required to enable providing a comma as separator.
	* @param fixed_arg Fixed argument passed to @p F as the third macro parameter.
	* @param ... Variable list of arguments. The macro @p F is invoked as
	* <tt>F(index, element, fixed_arg)</tt> for each element in
	* the list.
	*/
	#define FOR_EACH_IDX_FIXED_ARG(F, sep, fixed_arg, ...) \
	Z_FOR_EACH_IDX_FIXED_ARG(F, sep, fixed_arg, REVERSE_ARGS(__VA_ARGS__))

	/** @brief Reverse arguments order.
	*
	* @param ... Variable argument list.
	*/
	#define REVERSE_ARGS(...) \
	Z_FOR_EACH_ENGINE(Z_FOR_EACH_EXEC, (,), Z_BYPASS, _, __VA_ARGS__)

	/**
	* @brief Number of arguments in the variable arguments list minus one.
	*
	* @param ... List of arguments
	* @return Number of variadic arguments in the argument list, minus one
	*/
	#define NUM_VA_ARGS_LESS_1(...) \
	NUM_VA_ARGS_LESS_1_IMPL(__VA_ARGS__, 63, 62, 61, \
	60, 59, 58, 57, 56, 55, 54, 53, 52, 51, \
	50, 49, 48, 47, 46, 45, 44, 43, 42, 41, \
	40, 39, 38, 37, 36, 35, 34, 33, 32, 31, \
	30, 29, 28, 27, 26, 25, 24, 23, 22, 21, \
	20, 19, 18, 17, 16, 15, 14, 13, 12, 11, \
	10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0, ~)

	/**
	* @brief Mapping macro that pastes results together
	*
	* This is similar to FOR_EACH() in that it invokes a macro repeatedly
	* on each element of <tt>__VA_ARGS__</tt>. However, unlike FOR_EACH(),
	* MACRO_MAP_CAT() pastes the results together into a single token.
	*
	* For example, with this macro FOO:
	*
	* #define FOO(x) item_##x##_
	*
	* <tt>MACRO_MAP_CAT(FOO, a, b, c),</tt> expands to the token:
	*
	* item_a_item_b_item_c_
	*
	* @param ... Macro to expand on each argument, followed by its
	* arguments. (The macro should take exactly one argument.)
	* @return The results of expanding the macro on each argument, all pasted
	* together
	*/
	#define MACRO_MAP_CAT(...) MACRO_MAP_CAT_(__VA_ARGS__)

	/**
	* @brief Mapping macro that pastes a fixed number of results together
	*
	* Similar to @ref MACRO_MAP_CAT(), but expects a fixed number of
	* arguments. If more arguments are given than are expected, the rest
	* are ignored.
	*
	* @param N Number of arguments to map
	* @param ... Macro to expand on each argument, followed by its
	* arguments. (The macro should take exactly one argument.)
	* @return The results of expanding the macro on each argument, all pasted
	* together
	*/
	#define MACRO_MAP_CAT_N(N, ...) MACRO_MAP_CAT_N_(N, __VA_ARGS__)

	/**
	* @}
	*/

	#ifdef __cplusplus
	}
	#endif

	#endif /* ZEPHYR_INCLUDE_SYS_UTIL_MACROS_H_ */