boost_1_45_0/libs/preprocessor/doc/examples/linear_fib.c - nest-learning-thermostat/5.0/boost - Git at Google

 # /* Copyright (C) 2002
 #  * Housemarque Oy
 #  * http://www.housemarque.com
 #  *
 #  * Distributed under the Boost Software License, Version 1.0. (See
 #  * accompanying file LICENSE_1_0.txt or copy at
 #  * http://www.boost.org/LICENSE_1_0.txt)
 #  */
 #
 # /* Revised by Paul Mensonides (2002) */
 #
 # /* See http://www.boost.org for most recent version. */
 #
 # /* This example shows how BOOST_PP_WHILE() can be used for implementing macros. */
 #
 # include <stdio.h>
 #
 # include <boost/preprocessor/arithmetic/add.hpp>
 # include <boost/preprocessor/arithmetic/sub.hpp>
 # include <boost/preprocessor/comparison/less_equal.hpp>
 # include <boost/preprocessor/control/while.hpp>
 # include <boost/preprocessor/list/adt.hpp>
 # include <boost/preprocessor/tuple/elem.hpp>
 #
 # /* First consider the following C implementation of Fibonacci. */

 typedef struct linear_fib_state {
    int a0, a1, n;
 } linear_fib_state;

 static int linear_fib_c(linear_fib_state p) {
    return p.n;
 }

 static linear_fib_state linear_fib_f(linear_fib_state p) {
    linear_fib_state r = { p.a1, p.a0 + p.a1, p.n - 1 };
    return r;
 }

 static int linear_fib(int n) {
    linear_fib_state p = { 0, 1, n };
    while (linear_fib_c(p)) {
       p = linear_fib_f(p);
    }
    return p.a0;
 }

 # /* Then consider the following preprocessor implementation of Fibonacci. */
 #
 # define LINEAR_FIB(n) LINEAR_FIB_D(1, n)
 # /* Since the macro is implemented using BOOST_PP_WHILE, the actual
 #  * implementation takes a depth as a parameters so that it can be called
 #  * inside a BOOST_PP_WHILE.  The above easy-to-use version simply uses 1
 #  * as the depth and cannot be called inside a BOOST_PP_WHILE.
 #  */
 #
 # define LINEAR_FIB_D(d, n) \
    BOOST_PP_TUPLE_ELEM(3, 0, BOOST_PP_WHILE_ ## d(LINEAR_FIB_C, LINEAR_FIB_F, (0, 1, n)))
 # /*                   ^^^^                 ^^^^^           ^^            ^^   ^^^^^^^
 #  *                    #1                   #2             #3            #3     #4
 #  *
 #  * 1) The state is a 3-element tuple.  After the iteration is finished, the first
 #  *    element of the tuple is the result.
 #  *
 #  * 2) The WHILE primitive is "invoked" directly.  BOOST_PP_WHILE(D, ...)
 #  *    can't be used because it would not be expanded by the preprocessor.
 #  *
 #  * 3) ???_C is the condition and ???_F is the iteration macro.
 #  */
 #
 # define LINEAR_FIB_C(d, p) \
    /* p.n */ BOOST_PP_TUPLE_ELEM(3, 2, p) \
    /**/
 #
 # define LINEAR_FIB_F(d, p) \
    ( \
       /* p.a1 */ BOOST_PP_TUPLE_ELEM(3, 1, p), \
       /* p.a0 + p.a1 */ BOOST_PP_ADD_D(d, BOOST_PP_TUPLE_ELEM(3, 0, p), BOOST_PP_TUPLE_ELEM(3, 1, p)), \
                         /*          ^^ ^ \
                          * BOOST_PP_ADD() uses BOOST_PP_WHILE().  Therefore we \
                          * pass the recursion depth explicitly to BOOST_PP_ADD_D(). \
                          */ \
       /* p.n - 1 */ BOOST_PP_DEC(BOOST_PP_TUPLE_ELEM(3, 2, p)) \
    ) \
    /**/

 int main() {
    printf("linear_fib(10) = %d\n", linear_fib(10));
    printf("LINEAR_FIB(10) = %d\n", LINEAR_FIB(10));
    return 0;
 }
	# /* Copyright (C) 2002
	# * Housemarque Oy
	# * http://www.housemarque.com
	# *
	# * Distributed under the Boost Software License, Version 1.0. (See
	# * accompanying file LICENSE_1_0.txt or copy at
	# * http://www.boost.org/LICENSE_1_0.txt)
	# */
	#
	# /* Revised by Paul Mensonides (2002) */
	#
	# /* See http://www.boost.org for most recent version. */
	#
	# /* This example shows how BOOST_PP_WHILE() can be used for implementing macros. */
	#
	# include <stdio.h>
	#
	# include <boost/preprocessor/arithmetic/add.hpp>
	# include <boost/preprocessor/arithmetic/sub.hpp>
	# include <boost/preprocessor/comparison/less_equal.hpp>
	# include <boost/preprocessor/control/while.hpp>
	# include <boost/preprocessor/list/adt.hpp>
	# include <boost/preprocessor/tuple/elem.hpp>
	#
	# /* First consider the following C implementation of Fibonacci. */

	typedef struct linear_fib_state {
	int a0, a1, n;
	} linear_fib_state;

	static int linear_fib_c(linear_fib_state p) {
	return p.n;
	}

	static linear_fib_state linear_fib_f(linear_fib_state p) {
	linear_fib_state r = { p.a1, p.a0 + p.a1, p.n - 1 };
	return r;
	}

	static int linear_fib(int n) {
	linear_fib_state p = { 0, 1, n };
	while (linear_fib_c(p)) {
	p = linear_fib_f(p);
	}
	return p.a0;
	}

	# /* Then consider the following preprocessor implementation of Fibonacci. */
	#
	# define LINEAR_FIB(n) LINEAR_FIB_D(1, n)
	# /* Since the macro is implemented using BOOST_PP_WHILE, the actual
	# * implementation takes a depth as a parameters so that it can be called
	# * inside a BOOST_PP_WHILE. The above easy-to-use version simply uses 1
	# * as the depth and cannot be called inside a BOOST_PP_WHILE.
	# */
	#
	# define LINEAR_FIB_D(d, n) \
	BOOST_PP_TUPLE_ELEM(3, 0, BOOST_PP_WHILE_ ## d(LINEAR_FIB_C, LINEAR_FIB_F, (0, 1, n)))
	# /* ^^^^ ^^^^^ ^^ ^^ ^^^^^^^
	# * #1 #2 #3 #3 #4
	# *
	# * 1) The state is a 3-element tuple. After the iteration is finished, the first
	# * element of the tuple is the result.
	# *
	# * 2) The WHILE primitive is "invoked" directly. BOOST_PP_WHILE(D, ...)
	# * can't be used because it would not be expanded by the preprocessor.
	# *
	# * 3) ???_C is the condition and ???_F is the iteration macro.
	# */
	#
	# define LINEAR_FIB_C(d, p) \
	/* p.n */ BOOST_PP_TUPLE_ELEM(3, 2, p) \
	/**/
	#
	# define LINEAR_FIB_F(d, p) \
	( \
	/* p.a1 */ BOOST_PP_TUPLE_ELEM(3, 1, p), \
	/* p.a0 + p.a1 */ BOOST_PP_ADD_D(d, BOOST_PP_TUPLE_ELEM(3, 0, p), BOOST_PP_TUPLE_ELEM(3, 1, p)), \
	/* ^^ ^ \
	* BOOST_PP_ADD() uses BOOST_PP_WHILE(). Therefore we \
	* pass the recursion depth explicitly to BOOST_PP_ADD_D(). \
	*/ \
	/* p.n - 1 */ BOOST_PP_DEC(BOOST_PP_TUPLE_ELEM(3, 2, p)) \
	) \
	/**/

	int main() {
	printf("linear_fib(10) = %d\n", linear_fib(10));
	printf("LINEAR_FIB(10) = %d\n", LINEAR_FIB(10));
	return 0;
	}