mergesort.h - git - Git at Google

 #ifndef MERGESORT_H
 #define MERGESORT_H

 /* Combine two sorted lists.  Take from `list` on equality. */
 #define DEFINE_LIST_MERGE_INTERNAL(name, type)				\
 static type *name##__merge(type *list, type *other,			\
 			   int (*compare_fn)(const type *, const type *))\
 {									\
 	type *result = list, *tail;					\
 	int prefer_list = compare_fn(list, other) <= 0;			\
 									\
 	if (!prefer_list) {						\
 		result = other;						\
 		SWAP(list, other);					\
 	}								\
 	for (;;) {							\
 		do {							\
 			tail = list;					\
 			list = name##__get_next(list);			\
 			if (!list) {					\
 				name##__set_next(tail, other);		\
 				return result;				\
 			}						\
 		} while (compare_fn(list, other) < prefer_list);	\
 		name##__set_next(tail, other);				\
 		prefer_list ^= 1;					\
 		SWAP(list, other);					\
 	}								\
 }

 /*
  * Perform an iterative mergesort using an array of sublists.
  *
  * n is the number of items.
  * ranks[i] is undefined if n & 2^i == 0, and assumed empty.
  * ranks[i] contains a sublist of length 2^i otherwise.
  *
  * The number of bits in a void pointer limits the number of objects
  * that can be created, and thus the number of array elements necessary
  * to be able to sort any valid list.
  *
  * Adding an item to this array is like incrementing a binary number;
  * positional values for set bits correspond to sublist lengths.
  */
 #define DEFINE_LIST_SORT_INTERNAL(scope, name, type)			\
 scope void name(type **listp,						\
 		int (*compare_fn)(const type *, const type *))		\
 {									\
 	type *list = *listp;						\
 	type *ranks[bitsizeof(type *)];					\
 	size_t n = 0;							\
 									\
 	if (!list)							\
 		return;							\
 									\
 	for (;;) {							\
 		int i;							\
 		size_t m;						\
 		type *next = name##__get_next(list);			\
 		if (next)						\
 			name##__set_next(list, NULL);			\
 		for (i = 0, m = n;; i++, m >>= 1) {			\
 			if (m & 1) {					\
 				list = name##__merge(ranks[i], list,	\
 						    compare_fn);	\
 			} else if (next) {				\
 				break;					\
 			} else if (!m) {				\
 				*listp = list;				\
 				return;					\
 			}						\
 		}							\
 		n++;							\
 		ranks[i] = list;					\
 		list = next;						\
 	}								\
 }

 #define DECLARE_LIST_SORT(scope, name, type)			\
 scope void name(type **listp,					\
 		int (*compare_fn)(const type *, const type *))

 #define DEFINE_LIST_SORT_DEBUG(scope, name, type, next_member,	\
 			       on_get_next, on_set_next)	\
 								\
 static inline type *name##__get_next(const type *elem)		\
 {								\
 	on_get_next;						\
 	return elem->next_member;				\
 }								\
 								\
 static inline void name##__set_next(type *elem, type *next)	\
 {								\
 	on_set_next;						\
 	elem->next_member = next;				\
 }								\
 								\
 DEFINE_LIST_MERGE_INTERNAL(name, type)				\
 DEFINE_LIST_SORT_INTERNAL(scope, name, type)			\
 DECLARE_LIST_SORT(scope, name, type)

 #define DEFINE_LIST_SORT(scope, name, type, next_member) \
 DEFINE_LIST_SORT_DEBUG(scope, name, type, next_member, (void)0, (void)0)

 #endif
	#ifndef MERGESORT_H
	#define MERGESORT_H

	/* Combine two sorted lists. Take from `list` on equality. */
	#define DEFINE_LIST_MERGE_INTERNAL(name, type) \
	static type name##__merge(type list, type *other, \
	int (compare_fn)(const type , const type *))\
	{ \
	type result = list, tail; \
	int prefer_list = compare_fn(list, other) <= 0; \
	\
	if (!prefer_list) { \
	result = other; \
	SWAP(list, other); \
	} \
	for (;;) { \
	do { \
	tail = list; \
	list = name##__get_next(list); \
	if (!list) { \
	name##__set_next(tail, other); \
	return result; \
	} \
	} while (compare_fn(list, other) < prefer_list); \
	name##__set_next(tail, other); \
	prefer_list ^= 1; \
	SWAP(list, other); \
	} \
	}

	/*
	* Perform an iterative mergesort using an array of sublists.
	*
	* n is the number of items.
	* ranks[i] is undefined if n & 2^i == 0, and assumed empty.
	* ranks[i] contains a sublist of length 2^i otherwise.
	*
	* The number of bits in a void pointer limits the number of objects
	* that can be created, and thus the number of array elements necessary
	* to be able to sort any valid list.
	*
	* Adding an item to this array is like incrementing a binary number;
	* positional values for set bits correspond to sublist lengths.
	*/
	#define DEFINE_LIST_SORT_INTERNAL(scope, name, type) \
	scope void name(type **listp, \
	int (compare_fn)(const type , const type *)) \
	{ \
	type list = listp; \
	type ranks[bitsizeof(type )]; \
	size_t n = 0; \
	\
	if (!list) \
	return; \
	\
	for (;;) { \
	int i; \
	size_t m; \
	type *next = name##__get_next(list); \
	if (next) \
	name##__set_next(list, NULL); \
	for (i = 0, m = n;; i++, m >>= 1) { \
	if (m & 1) { \
	list = name##__merge(ranks[i], list, \
	compare_fn); \
	} else if (next) { \
	break; \
	} else if (!m) { \
	*listp = list; \
	return; \
	} \
	} \
	n++; \
	ranks[i] = list; \
	list = next; \
	} \
	}

	#define DECLARE_LIST_SORT(scope, name, type) \
	scope void name(type **listp, \
	int (compare_fn)(const type , const type *))

	#define DEFINE_LIST_SORT_DEBUG(scope, name, type, next_member, \
	on_get_next, on_set_next) \
	\
	static inline type name##__get_next(const type elem) \
	{ \
	on_get_next; \
	return elem->next_member; \
	} \
	\
	static inline void name##__set_next(type elem, type next) \
	{ \
	on_set_next; \
	elem->next_member = next; \
	} \
	\
	DEFINE_LIST_MERGE_INTERNAL(name, type) \
	DEFINE_LIST_SORT_INTERNAL(scope, name, type) \
	DECLARE_LIST_SORT(scope, name, type)

	#define DEFINE_LIST_SORT(scope, name, type, next_member) \
	DEFINE_LIST_SORT_DEBUG(scope, name, type, next_member, (void)0, (void)0)

	#endif