src/bitmap.c - platform/external/jemalloc - Git at Google

 #define	JEMALLOC_BITMAP_C_
 #include "jemalloc/internal/jemalloc_internal.h"

 /******************************************************************************/

 #ifdef USE_TREE

 void
 bitmap_info_init(bitmap_info_t *binfo, size_t nbits)
 {
 	unsigned i;
 	size_t group_count;

 	assert(nbits > 0);
 	assert(nbits <= (ZU(1) << LG_BITMAP_MAXBITS));

 	/*
 	 * Compute the number of groups necessary to store nbits bits, and
 	 * progressively work upward through the levels until reaching a level
 	 * that requires only one group.
 	 */
 	binfo->levels[0].group_offset = 0;
 	group_count = BITMAP_BITS2GROUPS(nbits);
 	for (i = 1; group_count > 1; i++) {
 		assert(i < BITMAP_MAX_LEVELS);
 		binfo->levels[i].group_offset = binfo->levels[i-1].group_offset
 		    + group_count;
 		group_count = BITMAP_BITS2GROUPS(group_count);
 	}
 	binfo->levels[i].group_offset = binfo->levels[i-1].group_offset
 	    + group_count;
 	assert(binfo->levels[i].group_offset <= BITMAP_GROUPS_MAX);
 	binfo->nlevels = i;
 	binfo->nbits = nbits;
 }

 static size_t
 bitmap_info_ngroups(const bitmap_info_t *binfo)
 {

 	return (binfo->levels[binfo->nlevels].group_offset);
 }

 void
 bitmap_init(bitmap_t *bitmap, const bitmap_info_t *binfo)
 {
 	size_t extra;
 	unsigned i;

 	/*
 	 * Bits are actually inverted with regard to the external bitmap
 	 * interface, so the bitmap starts out with all 1 bits, except for
 	 * trailing unused bits (if any).  Note that each group uses bit 0 to
 	 * correspond to the first logical bit in the group, so extra bits
 	 * are the most significant bits of the last group.
 	 */
 	memset(bitmap, 0xffU, bitmap_size(binfo));
 	extra = (BITMAP_GROUP_NBITS - (binfo->nbits & BITMAP_GROUP_NBITS_MASK))
 	    & BITMAP_GROUP_NBITS_MASK;
 	if (extra != 0)
 		bitmap[binfo->levels[1].group_offset - 1] >>= extra;
 	for (i = 1; i < binfo->nlevels; i++) {
 		size_t group_count = binfo->levels[i].group_offset -
 		    binfo->levels[i-1].group_offset;
 		extra = (BITMAP_GROUP_NBITS - (group_count &
 		    BITMAP_GROUP_NBITS_MASK)) & BITMAP_GROUP_NBITS_MASK;
 		if (extra != 0)
 			bitmap[binfo->levels[i+1].group_offset - 1] >>= extra;
 	}
 }

 #else /* USE_TREE */

 void
 bitmap_info_init(bitmap_info_t *binfo, size_t nbits)
 {

 	assert(nbits > 0);
 	assert(nbits <= (ZU(1) << LG_BITMAP_MAXBITS));

 	binfo->ngroups = BITMAP_BITS2GROUPS(nbits);
 	binfo->nbits = nbits;
 }

 static size_t
 bitmap_info_ngroups(const bitmap_info_t *binfo)
 {

 	return (binfo->ngroups);
 }

 void
 bitmap_init(bitmap_t *bitmap, const bitmap_info_t *binfo)
 {
 	size_t extra;

 	memset(bitmap, 0xffU, bitmap_size(binfo));
 	extra = (BITMAP_GROUP_NBITS - (binfo->nbits & BITMAP_GROUP_NBITS_MASK))
 	    & BITMAP_GROUP_NBITS_MASK;
 	if (extra != 0)
 		bitmap[binfo->ngroups - 1] >>= extra;
 }

 #endif /* USE_TREE */

 size_t
 bitmap_size(const bitmap_info_t *binfo)
 {

 	return (bitmap_info_ngroups(binfo) << LG_SIZEOF_BITMAP);
 }
	#define JEMALLOC_BITMAP_C_
	#include "jemalloc/internal/jemalloc_internal.h"

	/******************************************************************************/

	#ifdef USE_TREE

	void
	bitmap_info_init(bitmap_info_t *binfo, size_t nbits)
	{
	unsigned i;
	size_t group_count;

	assert(nbits > 0);
	assert(nbits <= (ZU(1) << LG_BITMAP_MAXBITS));

	/*
	* Compute the number of groups necessary to store nbits bits, and
	* progressively work upward through the levels until reaching a level
	* that requires only one group.
	*/
	binfo->levels[0].group_offset = 0;
	group_count = BITMAP_BITS2GROUPS(nbits);
	for (i = 1; group_count > 1; i++) {
	assert(i < BITMAP_MAX_LEVELS);
	binfo->levels[i].group_offset = binfo->levels[i-1].group_offset
	+ group_count;
	group_count = BITMAP_BITS2GROUPS(group_count);
	}
	binfo->levels[i].group_offset = binfo->levels[i-1].group_offset
	+ group_count;
	assert(binfo->levels[i].group_offset <= BITMAP_GROUPS_MAX);
	binfo->nlevels = i;
	binfo->nbits = nbits;
	}

	static size_t
	bitmap_info_ngroups(const bitmap_info_t *binfo)
	{

	return (binfo->levels[binfo->nlevels].group_offset);
	}

	void
	bitmap_init(bitmap_t bitmap, const bitmap_info_t binfo)
	{
	size_t extra;
	unsigned i;

	/*
	* Bits are actually inverted with regard to the external bitmap
	* interface, so the bitmap starts out with all 1 bits, except for
	* trailing unused bits (if any). Note that each group uses bit 0 to
	* correspond to the first logical bit in the group, so extra bits
	* are the most significant bits of the last group.
	*/
	memset(bitmap, 0xffU, bitmap_size(binfo));
	extra = (BITMAP_GROUP_NBITS - (binfo->nbits & BITMAP_GROUP_NBITS_MASK))
	& BITMAP_GROUP_NBITS_MASK;
	if (extra != 0)
	bitmap[binfo->levels[1].group_offset - 1] >>= extra;
	for (i = 1; i < binfo->nlevels; i++) {
	size_t group_count = binfo->levels[i].group_offset -
	binfo->levels[i-1].group_offset;
	extra = (BITMAP_GROUP_NBITS - (group_count &
	BITMAP_GROUP_NBITS_MASK)) & BITMAP_GROUP_NBITS_MASK;
	if (extra != 0)
	bitmap[binfo->levels[i+1].group_offset - 1] >>= extra;
	}
	}

	#else /* USE_TREE */

	void
	bitmap_info_init(bitmap_info_t *binfo, size_t nbits)
	{

	assert(nbits > 0);
	assert(nbits <= (ZU(1) << LG_BITMAP_MAXBITS));

	binfo->ngroups = BITMAP_BITS2GROUPS(nbits);
	binfo->nbits = nbits;
	}

	static size_t
	bitmap_info_ngroups(const bitmap_info_t *binfo)
	{

	return (binfo->ngroups);
	}

	void
	bitmap_init(bitmap_t bitmap, const bitmap_info_t binfo)
	{
	size_t extra;

	memset(bitmap, 0xffU, bitmap_size(binfo));
	extra = (BITMAP_GROUP_NBITS - (binfo->nbits & BITMAP_GROUP_NBITS_MASK))
	& BITMAP_GROUP_NBITS_MASK;
	if (extra != 0)
	bitmap[binfo->ngroups - 1] >>= extra;
	}

	#endif /* USE_TREE */

	size_t
	bitmap_size(const bitmap_info_t *binfo)
	{

	return (bitmap_info_ngroups(binfo) << LG_SIZEOF_BITMAP);
	}