/* sl_malloc.c - malloc routines using a per-thread slab */
/* $OpenLDAP$ */
/* This work is part of OpenLDAP Software <http://www.openldap.org/>.
 *
 * Copyright 2003-2024 The OpenLDAP Foundation.
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted only as authorized by the OpenLDAP
 * Public License.
 *
 * A copy of this license is available in the file LICENSE in the
 * top-level directory of the distribution or, alternatively, at
 * <http://www.OpenLDAP.org/license.html>.
 */

#include "portable.h"

#include <stdio.h>
#include <ac/string.h>

#include "slap.h"

#ifdef USE_VALGRIND
/* Get debugging help from Valgrind */
#include <valgrind/memcheck.h>
#define	VGMEMP_MARK(m,s)	VALGRIND_MAKE_MEM_NOACCESS(m,s)
#define VGMEMP_CREATE(h,r,z)	VALGRIND_CREATE_MEMPOOL(h,r,z)
#define VGMEMP_TRIM(h,a,s)	VALGRIND_MEMPOOL_TRIM(h,a,s)
#define VGMEMP_ALLOC(h,a,s)	VALGRIND_MEMPOOL_ALLOC(h,a,s)
#define VGMEMP_CHANGE(h,a,b,s)	VALGRIND_MEMPOOL_CHANGE(h,a,b,s)
#else
#define	VGMEMP_MARK(m,s)
#define VGMEMP_CREATE(h,r,z)
#define VGMEMP_TRIM(h,a,s)
#define VGMEMP_ALLOC(h,a,s)
#define VGMEMP_CHANGE(h,a,b,s)
#endif

/*
 * This allocator returns temporary memory from a slab in a given memory
 * context, aligned on a 2-int boundary.  It cannot be used for data
 * which will outlive the task allocating it.
 *
 * A new memory context attaches to the creator's thread context, if any.
 * Threads cannot use other threads' memory contexts; there are no locks.
 *
 * The caller of slap_sl_malloc, usually a thread pool task, must
 * slap_sl_free the memory before finishing: New tasks reuse the context
 * and normally reset it, reclaiming memory left over from last task.
 *
 * The allocator helps memory fragmentation, speed and memory leaks.
 * It is not (yet) reliable as a garbage collector:
 *
 * It falls back to context NULL - plain ber_memalloc() - when the
 * context's slab is full.  A reset does not reclaim such memory.
 * Conversely, free/realloc of data not from the given context assumes
 * context NULL.  The data must not belong to another memory context.
 *
 * Code which has lost track of the current memory context can try
 * slap_sl_context() or ch_malloc.c:ch_free/ch_realloc().
 *
 * Allocations cannot yet return failure.  Like ch_malloc, they succeed
 * or abort slapd.  This will change, do fix code which assumes success.
 */

/*
 * The stack-based allocator stores (ber_len_t)sizeof(head+block) at
 * allocated blocks' head - and in freed blocks also at the tail, marked
 * by ORing *next* block's head with 1.  Freed blocks are only reclaimed
 * from the last block forward.  This is fast, but when a block is never
 * freed, older blocks will not be reclaimed until the slab is reset...
 */

#ifdef SLAP_NO_SL_MALLOC /* Useful with memory debuggers like Valgrind */
enum { No_sl_malloc = 1 };
#else
enum { No_sl_malloc = 0 };
#endif

#define SLAP_SLAB_SOBLOCK 64

struct slab_object {
    void *so_ptr;
	int so_blockhead;
    LDAP_LIST_ENTRY(slab_object) so_link;
};

struct slab_heap {
    void *sh_base;
    void *sh_last;
    void *sh_end;
	int sh_stack;
	int sh_maxorder;
    unsigned char **sh_map;
    LDAP_LIST_HEAD(sh_freelist, slab_object) *sh_free;
	LDAP_LIST_HEAD(sh_so, slab_object) sh_sopool;
};

enum {
	Align = sizeof(ber_len_t) > 2*sizeof(int)
		? sizeof(ber_len_t) : 2*sizeof(int),
	Align_log2 = 1 + (Align>2) + (Align>4) + (Align>8) + (Align>16),
	order_start = Align_log2 - 1,
	pad = Align - 1
};

static struct slab_object * slap_replenish_sopool(struct slab_heap* sh);
#ifdef SLAPD_UNUSED
static void print_slheap(int level, void *ctx);
#endif

/* Keep memory context in a thread-local var */
# define memctx_key ((void *) slap_sl_mem_init)
# define SET_MEMCTX(thrctx, memctx, kfree) \
	ldap_pvt_thread_pool_setkey(thrctx,memctx_key, memctx,kfree, NULL,NULL)
# define GET_MEMCTX(thrctx, memctxp) \
	((void) (*(memctxp) = NULL), \
	 (void) ldap_pvt_thread_pool_getkey(thrctx,memctx_key, memctxp,NULL), \
	 *(memctxp))

/* Destroy the context, or if key==NULL clean it up for reuse. */
void
slap_sl_mem_destroy(
	void *key,
	void *data
)
{
	struct slab_heap *sh = data;
	struct slab_object *so;
	int i;

	if (!sh)
		return;

	if (!sh->sh_stack) {
		for (i = 0; i <= sh->sh_maxorder - order_start; i++) {
			so = LDAP_LIST_FIRST(&sh->sh_free[i]);
			while (so) {
				struct slab_object *so_tmp = so;
				so = LDAP_LIST_NEXT(so, so_link);
				LDAP_LIST_INSERT_HEAD(&sh->sh_sopool, so_tmp, so_link);
			}
			ch_free(sh->sh_map[i]);
		}
		ch_free(sh->sh_free);
		ch_free(sh->sh_map);

		so = LDAP_LIST_FIRST(&sh->sh_sopool);
		while (so) {
			struct slab_object *so_tmp = so;
			so = LDAP_LIST_NEXT(so, so_link);
			if (!so_tmp->so_blockhead) {
				LDAP_LIST_REMOVE(so_tmp, so_link);
			}
		}
		so = LDAP_LIST_FIRST(&sh->sh_sopool);
		while (so) {
			struct slab_object *so_tmp = so;
			so = LDAP_LIST_NEXT(so, so_link);
			ch_free(so_tmp);
		}
	}

	if (key != NULL) {
		ber_memfree_x(sh->sh_base, NULL);
		ber_memfree_x(sh, NULL);
	}
}

BerMemoryFunctions slap_sl_mfuncs =
	{ slap_sl_malloc, slap_sl_calloc, slap_sl_realloc, slap_sl_free };

void
slap_sl_mem_init()
{
	assert( Align == 1 << Align_log2 );

	ber_set_option( NULL, LBER_OPT_MEMORY_FNS, &slap_sl_mfuncs );
}

/* Create, reset or just return the memory context of the current thread. */
void *
slap_sl_mem_create(
	ber_len_t size,
	int stack,
	void *thrctx,
	int new
)
{
	void *memctx;
	struct slab_heap *sh;
	ber_len_t size_shift;
	struct slab_object *so;
	char *base, *newptr;
	enum { Base_offset = (unsigned) -sizeof(ber_len_t) % Align };

	sh = GET_MEMCTX(thrctx, &memctx);
	if ( sh && !new )
		return sh;

	/* Round up to doubleword boundary, then make room for initial
	 * padding, preserving expected available size for pool version */
	size = ((size + Align-1) & -Align) + Base_offset;

	if (!sh) {
		sh = ch_malloc(sizeof(struct slab_heap));
		base = ch_malloc(size);
		SET_MEMCTX(thrctx, sh, slap_sl_mem_destroy);
		VGMEMP_MARK(base, size);
		VGMEMP_CREATE(sh, 0, 0);
	} else {
		slap_sl_mem_destroy(NULL, sh);
		base = sh->sh_base;
		if (size > (ber_len_t) ((char *) sh->sh_end - base)) {
			newptr = ch_realloc(base, size);
			if ( newptr == NULL ) return NULL;
			VGMEMP_CHANGE(sh, base, newptr, size);
			base = newptr;
		}
		VGMEMP_TRIM(sh, base, 0);
	}
	sh->sh_base = base;
	sh->sh_end = base + size;

	/* Align (base + head of first block) == first returned block */
	base += Base_offset;
	size -= Base_offset;

	sh->sh_stack = stack;
	if (stack) {
		sh->sh_last = base;

	} else {
		int i, order = -1, order_end = -1;

		size_shift = size - 1;
		do {
			order_end++;
		} while (size_shift >>= 1);
		order = order_end - order_start + 1;
		sh->sh_maxorder = order_end;

		sh->sh_free = (struct sh_freelist *)
						ch_malloc(order * sizeof(struct sh_freelist));
		for (i = 0; i < order; i++) {
			LDAP_LIST_INIT(&sh->sh_free[i]);
		}

		LDAP_LIST_INIT(&sh->sh_sopool);

		if (LDAP_LIST_EMPTY(&sh->sh_sopool)) {
			slap_replenish_sopool(sh);
		}
		so = LDAP_LIST_FIRST(&sh->sh_sopool);
		LDAP_LIST_REMOVE(so, so_link);
		so->so_ptr = base;

		LDAP_LIST_INSERT_HEAD(&sh->sh_free[order-1], so, so_link);

		sh->sh_map = (unsigned char **)
					ch_malloc(order * sizeof(unsigned char *));
		for (i = 0; i < order; i++) {
			int shiftamt = order_start + 1 + i;
			int nummaps = size >> shiftamt;
			assert(nummaps);
			nummaps >>= 3;
			if (!nummaps) nummaps = 1;
			sh->sh_map[i] = (unsigned char *) ch_malloc(nummaps);
			memset(sh->sh_map[i], 0, nummaps);
		}
	}

	return sh;
}

/*
 * Assign memory context to thread context. Use NULL to detach
 * current memory context from thread. Future users must
 * know the context, since ch_free/slap_sl_context() cannot find it.
 */
void
slap_sl_mem_setctx(
	void *thrctx,
	void *memctx
)
{
	SET_MEMCTX(thrctx, memctx, slap_sl_mem_destroy);
}

void *
slap_sl_malloc(
    ber_len_t	size,
    void *ctx
)
{
	struct slab_heap *sh = ctx;
	ber_len_t *ptr, *newptr;

	/* ber_set_option calls us like this */
	if (No_sl_malloc || !ctx) {
		newptr = ber_memalloc_x( size, NULL );
		if ( newptr ) return newptr;
		Debug(LDAP_DEBUG_ANY, "slap_sl_malloc of %lu bytes failed\n",
			(unsigned long) size );
		assert( 0 );
		exit( EXIT_FAILURE );
	}

	/* Add room for head, ensure room for tail when freed, and
	 * round up to doubleword boundary. */
	size = (size + sizeof(ber_len_t) + Align-1 + !size) & -Align;

	if (sh->sh_stack) {
		if (size < (ber_len_t) ((char *) sh->sh_end - (char *) sh->sh_last)) {
			newptr = sh->sh_last;
			sh->sh_last = (char *) sh->sh_last + size;
			VGMEMP_ALLOC(sh, newptr, size);
			*newptr++ = size;
			return( (void *)newptr );
		}

		size -= sizeof(ber_len_t);

	} else {
		struct slab_object *so_new, *so_left, *so_right;
		ber_len_t size_shift;
		unsigned long diff;
		int i, j, order = -1;

		size_shift = size - 1;
		do {
			order++;
		} while (size_shift >>= 1);

		size -= sizeof(ber_len_t);

		for (i = order; i <= sh->sh_maxorder &&
				LDAP_LIST_EMPTY(&sh->sh_free[i-order_start]); i++);

		if (i == order) {
			so_new = LDAP_LIST_FIRST(&sh->sh_free[i-order_start]);
			LDAP_LIST_REMOVE(so_new, so_link);
			ptr = so_new->so_ptr;
			diff = (unsigned long)((char*)ptr -
					(char*)sh->sh_base) >> (order + 1);
			sh->sh_map[order-order_start][diff>>3] |= (1 << (diff & 0x7));
			*ptr++ = size;
			LDAP_LIST_INSERT_HEAD(&sh->sh_sopool, so_new, so_link);
			return((void*)ptr);
		} else if (i <= sh->sh_maxorder) {
			for (j = i; j > order; j--) {
				so_left = LDAP_LIST_FIRST(&sh->sh_free[j-order_start]);
				LDAP_LIST_REMOVE(so_left, so_link);
				if (LDAP_LIST_EMPTY(&sh->sh_sopool)) {
					slap_replenish_sopool(sh);
				}
				so_right = LDAP_LIST_FIRST(&sh->sh_sopool);
				LDAP_LIST_REMOVE(so_right, so_link);
				so_right->so_ptr = (void *)((char *)so_left->so_ptr + (1 << j));
				if (j == order + 1) {
					ptr = so_left->so_ptr;
					diff = (unsigned long)((char*)ptr -
							(char*)sh->sh_base) >> (order+1);
					sh->sh_map[order-order_start][diff>>3] |=
							(1 << (diff & 0x7));
					*ptr++ = size;
					LDAP_LIST_INSERT_HEAD(
							&sh->sh_free[j-1-order_start], so_right, so_link);
					LDAP_LIST_INSERT_HEAD(&sh->sh_sopool, so_left, so_link);
					return((void*)ptr);
				} else {
					LDAP_LIST_INSERT_HEAD(
							&sh->sh_free[j-1-order_start], so_right, so_link);
					LDAP_LIST_INSERT_HEAD(
							&sh->sh_free[j-1-order_start], so_left, so_link);
				}
			}
		}
		/* FIXME: missing return; guessing we failed... */
	}

	Debug(LDAP_DEBUG_TRACE,
		"sl_malloc %lu: ch_malloc\n",
		(unsigned long) size );
	return ch_malloc(size);
}

#define LIM_SQRT(t) /* some value < sqrt(max value of unsigned type t) */ \
	((0UL|(t)-1) >>31>>31 > 1 ? ((t)1 <<32) - 1 : \
	 (0UL|(t)-1) >>31 ? 65535U : (0UL|(t)-1) >>15 ? 255U : 15U)

void *
slap_sl_calloc( ber_len_t n, ber_len_t size, void *ctx )
{
	void *newptr;
	ber_len_t total = n * size;

	/* The sqrt test is a slight optimization: often avoids the division */
	if ((n | size) <= LIM_SQRT(ber_len_t) || n == 0 || total/n == size) {
		newptr = slap_sl_malloc( total, ctx );
		memset( newptr, 0, n*size );
	} else {
		Debug(LDAP_DEBUG_ANY, "slap_sl_calloc(%lu,%lu) out of range\n",
			(unsigned long) n, (unsigned long) size );
		assert(0);
		exit(EXIT_FAILURE);
	}
	return newptr;
}

void *
slap_sl_realloc(void *ptr, ber_len_t size, void *ctx)
{
	struct slab_heap *sh = ctx;
	ber_len_t oldsize, *p = (ber_len_t *) ptr, *nextp;
	void *newptr;

	if (ptr == NULL)
		return slap_sl_malloc(size, ctx);

	/* Not our memory? */
	if (No_sl_malloc || !sh || ptr < sh->sh_base || ptr >= sh->sh_end) {
		/* Like ch_realloc(), except not trying a new context */
		newptr = ber_memrealloc_x(ptr, size, NULL);
		if (newptr) {
			return newptr;
		}
		Debug(LDAP_DEBUG_ANY, "slap_sl_realloc of %lu bytes failed\n",
			(unsigned long) size );
		assert(0);
		exit( EXIT_FAILURE );
	}

	if (size == 0) {
		slap_sl_free(ptr, ctx);
		return NULL;
	}

	oldsize = p[-1];

	if (sh->sh_stack) {
		/* Add room for head, round up to doubleword boundary */
		size = (size + sizeof(ber_len_t) + Align-1) & -Align;

		p--;

		/* Never shrink blocks */
		if (size <= oldsize) {
			return ptr;
		}
	
		oldsize &= -2;
		nextp = (ber_len_t *) ((char *) p + oldsize);

		/* If reallocing the last block, try to grow it */
		if (nextp == sh->sh_last) {
			if (size < (ber_len_t) ((char *) sh->sh_end - (char *) p)) {
				sh->sh_last = (char *) p + size;
				p[0] = (p[0] & 1) | size;
				return ptr;
			}

		/* Nowhere to grow, need to alloc and copy */
		} else {
			/* Slight optimization of the final realloc variant */
			newptr = slap_sl_malloc(size-sizeof(ber_len_t), ctx);
			AC_MEMCPY(newptr, ptr, oldsize-sizeof(ber_len_t));
			/* Not last block, can just mark old region as free */
			nextp[-1] = oldsize;
			nextp[0] |= 1;
			return newptr;
		}

		size -= sizeof(ber_len_t);
		oldsize -= sizeof(ber_len_t);

	} else if (oldsize > size) {
		oldsize = size;
	}

	newptr = slap_sl_malloc(size, ctx);
	AC_MEMCPY(newptr, ptr, oldsize);
	slap_sl_free(ptr, ctx);
	return newptr;
}

void
slap_sl_free(void *ptr, void *ctx)
{
	struct slab_heap *sh = ctx;
	ber_len_t size;
	ber_len_t *p = ptr, *nextp, *tmpp;

	if (!ptr)
		return;

	if (No_sl_malloc || !sh || ptr < sh->sh_base || ptr >= sh->sh_end) {
		ber_memfree_x(ptr, NULL);
		return;
	}

	size = *(--p);

	if (sh->sh_stack) {
		size &= -2;
		nextp = (ber_len_t *) ((char *) p + size);
		if (sh->sh_last != nextp) {
			/* Mark it free: tail = size, head of next block |= 1 */
			nextp[-1] = size;
			nextp[0] |= 1;
			/* We can't tell Valgrind about it yet, because we
			 * still need read/write access to this block for
			 * when we eventually get to reclaim it.
			 */
		} else {
			/* Reclaim freed block(s) off tail */
			while (*p & 1) {
				p = (ber_len_t *) ((char *) p - p[-1]);
			}
			sh->sh_last = p;
			VGMEMP_TRIM(sh, sh->sh_base,
				(char *) sh->sh_last - (char *) sh->sh_base);
		}

	} else {
		int size_shift, order_size;
		struct slab_object *so;
		unsigned long diff;
		int i, inserted = 0, order = -1;

		size_shift = size + sizeof(ber_len_t) - 1;
		do {
			order++;
		} while (size_shift >>= 1);

		for (i = order, tmpp = p; i <= sh->sh_maxorder; i++) {
			order_size = 1 << (i+1);
			diff = (unsigned long)((char*)tmpp - (char*)sh->sh_base) >> (i+1);
			sh->sh_map[i-order_start][diff>>3] &= (~(1 << (diff & 0x7)));
			if (diff == ((diff>>1)<<1)) {
				if (!(sh->sh_map[i-order_start][(diff+1)>>3] &
						(1<<((diff+1)&0x7)))) {
					so = LDAP_LIST_FIRST(&sh->sh_free[i-order_start]);
					while (so) {
						if ((char*)so->so_ptr == (char*)tmpp) {
							LDAP_LIST_REMOVE( so, so_link );
						} else if ((char*)so->so_ptr ==
								(char*)tmpp + order_size) {
							LDAP_LIST_REMOVE(so, so_link);
							break;
						}
						so = LDAP_LIST_NEXT(so, so_link);
					}
					if (so) {
						if (i < sh->sh_maxorder) {
							inserted = 1;
							so->so_ptr = tmpp;
							LDAP_LIST_INSERT_HEAD(&sh->sh_free[i-order_start+1],
									so, so_link);
						}
						continue;
					} else {
						if (LDAP_LIST_EMPTY(&sh->sh_sopool)) {
							slap_replenish_sopool(sh);
						}
						so = LDAP_LIST_FIRST(&sh->sh_sopool);
						LDAP_LIST_REMOVE(so, so_link);
						so->so_ptr = tmpp;
						LDAP_LIST_INSERT_HEAD(&sh->sh_free[i-order_start],
								so, so_link);
						break;

						Debug(LDAP_DEBUG_TRACE, "slap_sl_free: "
							"free object not found while bit is clear.\n" );
						assert(so != NULL);

					}
				} else {
					if (!inserted) {
						if (LDAP_LIST_EMPTY(&sh->sh_sopool)) {
							slap_replenish_sopool(sh);
						}
						so = LDAP_LIST_FIRST(&sh->sh_sopool);
						LDAP_LIST_REMOVE(so, so_link);
						so->so_ptr = tmpp;
						LDAP_LIST_INSERT_HEAD(&sh->sh_free[i-order_start],
								so, so_link);
					}
					break;
				}
			} else {
				if (!(sh->sh_map[i-order_start][(diff-1)>>3] &
						(1<<((diff-1)&0x7)))) {
					so = LDAP_LIST_FIRST(&sh->sh_free[i-order_start]);
					while (so) {
						if ((char*)so->so_ptr == (char*)tmpp) {
							LDAP_LIST_REMOVE(so, so_link);
						} else if ((char*)tmpp == (char *)so->so_ptr + order_size) {
							LDAP_LIST_REMOVE(so, so_link);
							tmpp = so->so_ptr;
							break;
						}
						so = LDAP_LIST_NEXT(so, so_link);
					}
					if (so) {
						if (i < sh->sh_maxorder) {
							inserted = 1;
							LDAP_LIST_INSERT_HEAD(&sh->sh_free[i-order_start+1],									so, so_link);
							continue;
						}
					} else {
						if (LDAP_LIST_EMPTY(&sh->sh_sopool)) {
							slap_replenish_sopool(sh);
						}
						so = LDAP_LIST_FIRST(&sh->sh_sopool);
						LDAP_LIST_REMOVE(so, so_link);
						so->so_ptr = tmpp;
						LDAP_LIST_INSERT_HEAD(&sh->sh_free[i-order_start],
								so, so_link);
						break;

						Debug(LDAP_DEBUG_TRACE, "slap_sl_free: "
							"free object not found while bit is clear.\n" );
						assert(so != NULL);

					}
				} else {
					if ( !inserted ) {
						if (LDAP_LIST_EMPTY(&sh->sh_sopool)) {
							slap_replenish_sopool(sh);
						}
						so = LDAP_LIST_FIRST(&sh->sh_sopool);
						LDAP_LIST_REMOVE(so, so_link);
						so->so_ptr = tmpp;
						LDAP_LIST_INSERT_HEAD(&sh->sh_free[i-order_start],
								so, so_link);
					}
					break;
				}
			}
		}
	}
}

void
slap_sl_release( void *ptr, void *ctx )
{
	struct slab_heap *sh = ctx;
	if ( sh && ptr >= sh->sh_base && ptr <= sh->sh_end )
		sh->sh_last = ptr;
}

void *
slap_sl_mark( void *ctx )
{
	struct slab_heap *sh = ctx;
	return sh->sh_last;
}

/*
 * Return the memory context of the current thread if the given block of
 * memory belongs to it, otherwise return NULL.
 */
void *
slap_sl_context( void *ptr )
{
	void *memctx;
	struct slab_heap *sh;

	if ( slapMode & SLAP_TOOL_MODE ) return NULL;

	sh = GET_MEMCTX(ldap_pvt_thread_pool_context(), &memctx);
	if (sh && ptr >= sh->sh_base && ptr <= sh->sh_end) {
		return sh;
	}
	return NULL;
}

static struct slab_object *
slap_replenish_sopool(
    struct slab_heap* sh
)
{
    struct slab_object *so_block;
    int i;

    so_block = (struct slab_object *)ch_malloc(
                    SLAP_SLAB_SOBLOCK * sizeof(struct slab_object));

    if ( so_block == NULL ) {
        return NULL;
    }

    so_block[0].so_blockhead = 1;
    LDAP_LIST_INSERT_HEAD(&sh->sh_sopool, &so_block[0], so_link);
    for (i = 1; i < SLAP_SLAB_SOBLOCK; i++) {
        so_block[i].so_blockhead = 0;
        LDAP_LIST_INSERT_HEAD(&sh->sh_sopool, &so_block[i], so_link );
    }

    return so_block;
}

#ifdef SLAPD_UNUSED
static void
print_slheap(int level, void *ctx)
{
	struct slab_heap *sh = ctx;
	struct slab_object *so;
	int i, j, once = 0;

	if (!ctx) {
		Debug(level, "NULL memctx\n" );
		return;
	}

	Debug(level, "sh->sh_maxorder=%d\n", sh->sh_maxorder );

	for (i = order_start; i <= sh->sh_maxorder; i++) {
		once = 0;
		Debug(level, "order=%d\n", i );
		for (j = 0; j < (1<<(sh->sh_maxorder-i))/8; j++) {
			Debug(level, "%02x ", sh->sh_map[i-order_start][j] );
			once = 1;
		}
		if (!once) {
			Debug(level, "%02x ", sh->sh_map[i-order_start][0] );
		}
		Debug(level, "\n" );
		Debug(level, "free list:\n" );
		so = LDAP_LIST_FIRST(&sh->sh_free[i-order_start]);
		while (so) {
			Debug(level, "%p\n", so->so_ptr );
			so = LDAP_LIST_NEXT(so, so_link);
		}
	}
}
#endif