libc/gen/radixtree.c

1.17.2.3  yamt /*	$NetBSD: radixtree.c,v 1.17.2.3 2012/06/13 14:18:49 yamt Exp $	*/
     1.1  yamt
     1.1  yamt /*-
1.17.2.2  yamt  * Copyright (c)2011,2012 YAMAMOTO Takashi,
     1.1  yamt  * All rights reserved.
     1.1  yamt  *
     1.1  yamt  * Redistribution and use in source and binary forms, with or without
     1.1  yamt  * modification, are permitted provided that the following conditions
     1.1  yamt  * are met:
     1.1  yamt  * 1. Redistributions of source code must retain the above copyright
     1.1  yamt  *    notice, this list of conditions and the following disclaimer.
     1.1  yamt  * 2. Redistributions in binary form must reproduce the above copyright
     1.1  yamt  *    notice, this list of conditions and the following disclaimer in the
     1.1  yamt  *    documentation and/or other materials provided with the distribution.
     1.1  yamt  *
     1.1  yamt  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
     1.1  yamt  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
     1.1  yamt  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
     1.1  yamt  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
     1.1  yamt  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
     1.1  yamt  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
     1.1  yamt  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
     1.1  yamt  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
     1.1  yamt  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
     1.1  yamt  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
     1.1  yamt  * SUCH DAMAGE.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt /*
    1.17  yamt  * radixtree.c
     1.1  yamt  *
1.17.2.2  yamt  * Overview:
1.17.2.2  yamt  *
1.17.2.2  yamt  * This is an implementation of radix tree, whose keys are uint64_t and leafs
    1.17  yamt  * are user provided pointers.
    1.17  yamt  *
1.17.2.2  yamt  * Leaf nodes are just void * and this implementation doesn't care about
1.17.2.2  yamt  * what they actually point to.  However, this implementation has an assumption
1.17.2.2  yamt  * about their alignment.  Specifically, this implementation assumes that their
1.17.2.2  yamt  * 2 LSBs are always zero and uses them for internal accounting.
1.17.2.2  yamt  *
1.17.2.2  yamt  * Intermediate nodes and memory allocation:
1.17.2.2  yamt  *
1.17.2.2  yamt  * Intermediate nodes are automatically allocated and freed internally and
1.17.2.2  yamt  * basically users don't need to care about them.  The allocation is done via
1.17.2.2  yamt  * pool_cache_get(9) for _KERNEL, malloc(3) for userland, and alloc() for
1.17.2.2  yamt  * _STANDALONE environment.  Only radix_tree_insert_node function can allocatei
1.17.2.2  yamt  * memory for intermediate nodes and thus can fail for ENOMEM.
1.17.2.2  yamt  *
1.17.2.2  yamt  * Efficiency:
1.17.2.2  yamt  *
1.17.2.2  yamt  * It's designed to work efficiently with dense index distribution.
1.17.2.2  yamt  * The memory consumption (number of necessary intermediate nodes) heavily
1.17.2.2  yamt  * depends on the index distribution.  Basically, more dense index distribution
1.17.2.2  yamt  * consumes less nodes per item.  Approximately,
1.17.2.2  yamt  *  - the best case: about RADIX_TREE_PTR_PER_NODE items per intermediate node.
1.17.2.2  yamt  *  - the worst case: RADIX_TREE_MAX_HEIGHT intermediate nodes per item.
1.17.2.2  yamt  *
1.17.2.3  yamt  * The height of tree is dynamic.  It's smaller if only small index values are
1.17.2.3  yamt  * used.  As an extreme case, if only index 0 is used, the corresponding value
1.17.2.3  yamt  * is directly stored in the root of the tree (struct radix_tree) without
1.17.2.3  yamt  * allocating any intermediate nodes.
1.17.2.3  yamt  *
1.17.2.2  yamt  * Gang lookup:
    1.17  yamt  *
1.17.2.2  yamt  * This implementation provides a way to scan many nodes quickly via
    1.17  yamt  * radix_tree_gang_lookup_node function and its varients.
    1.17  yamt  *
1.17.2.2  yamt  * Tags:
1.17.2.2  yamt  *
1.17.2.2  yamt  * This implementation provides tagging functionality, which allows quick
1.17.2.2  yamt  * scanning of a subset of leaf nodes.  Leaf nodes are untagged when inserted
1.17.2.2  yamt  * into the tree and can be tagged by radix_tree_set_tag function.
1.17.2.2  yamt  * radix_tree_gang_lookup_tagged_node function and its variants returns only
1.17.2.2  yamt  * leaf nodes with the given tag.  To reduce amount of nodes to visit for
    1.17  yamt  * these functions, this implementation keeps tagging information in internal
    1.17  yamt  * intermediate nodes and quickly skips uninterested parts of a tree.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt #include <sys/cdefs.h>
     1.1  yamt
     1.2  yamt #if defined(_KERNEL) || defined(_STANDALONE)
1.17.2.3  yamt __KERNEL_RCSID(0, "$NetBSD: radixtree.c,v 1.17.2.3 2012/06/13 14:18:49 yamt Exp $");
     1.1  yamt #include <sys/param.h>
     1.3  yamt #include <sys/errno.h>
     1.1  yamt #include <sys/pool.h>
     1.1  yamt #include <sys/radixtree.h>
     1.3  yamt #include <lib/libkern/libkern.h>
     1.3  yamt #if defined(_STANDALONE)
     1.3  yamt #include <lib/libsa/stand.h>
     1.3  yamt #endif /* defined(_STANDALONE) */
     1.2  yamt #else /* defined(_KERNEL) || defined(_STANDALONE) */
1.17.2.3  yamt __RCSID("$NetBSD: radixtree.c,v 1.17.2.3 2012/06/13 14:18:49 yamt Exp $");
     1.1  yamt #include <assert.h>
     1.1  yamt #include <errno.h>
     1.1  yamt #include <stdbool.h>
     1.1  yamt #include <stdlib.h>
     1.8  yamt #include <string.h>
     1.1  yamt #if 1
     1.1  yamt #define KASSERT assert
     1.1  yamt #else
     1.1  yamt #define KASSERT(a)	/* nothing */
     1.1  yamt #endif
     1.2  yamt #endif /* defined(_KERNEL) || defined(_STANDALONE) */
     1.1  yamt
     1.1  yamt #include <sys/radixtree.h>
     1.1  yamt
     1.1  yamt #define	RADIX_TREE_BITS_PER_HEIGHT	4	/* XXX tune */
     1.1  yamt #define	RADIX_TREE_PTR_PER_NODE		(1 << RADIX_TREE_BITS_PER_HEIGHT)
     1.1  yamt #define	RADIX_TREE_MAX_HEIGHT		(64 / RADIX_TREE_BITS_PER_HEIGHT)
    1.15  yamt #define	RADIX_TREE_INVALID_HEIGHT	(RADIX_TREE_MAX_HEIGHT + 1)
     1.2  yamt __CTASSERT((64 % RADIX_TREE_BITS_PER_HEIGHT) == 0);
     1.1  yamt
     1.2  yamt __CTASSERT(((1 << RADIX_TREE_TAG_ID_MAX) & (sizeof(int) - 1)) == 0);
     1.1  yamt #define	RADIX_TREE_TAG_MASK	((1 << RADIX_TREE_TAG_ID_MAX) - 1)
     1.1  yamt
     1.1  yamt static inline void *
     1.1  yamt entry_ptr(void *p)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	return (void *)((uintptr_t)p & ~RADIX_TREE_TAG_MASK);
     1.1  yamt }
     1.1  yamt
     1.1  yamt static inline unsigned int
     1.1  yamt entry_tagmask(void *p)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	return (uintptr_t)p & RADIX_TREE_TAG_MASK;
     1.1  yamt }
     1.1  yamt
     1.1  yamt static inline void *
     1.1  yamt entry_compose(void *p, unsigned int tagmask)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	return (void *)((uintptr_t)p | tagmask);
     1.1  yamt }
     1.1  yamt
     1.1  yamt static inline bool
     1.1  yamt entry_match_p(void *p, unsigned int tagmask)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	KASSERT(entry_ptr(p) != NULL || entry_tagmask(p) == 0);
     1.1  yamt 	if (p == NULL) {
     1.1  yamt 		return false;
     1.1  yamt 	}
     1.1  yamt 	if (tagmask == 0) {
     1.1  yamt 		return true;
     1.1  yamt 	}
     1.1  yamt 	return (entry_tagmask(p) & tagmask) != 0;
     1.1  yamt }
     1.1  yamt
     1.1  yamt static inline unsigned int
     1.1  yamt tagid_to_mask(radix_tree_tagid_t id)
     1.1  yamt {
     1.1  yamt
     1.6  yamt 	KASSERT(id >= 0);
     1.6  yamt 	KASSERT(id < RADIX_TREE_TAG_ID_MAX);
     1.1  yamt 	return 1U << id;
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_node: an intermediate node
     1.1  yamt  *
     1.1  yamt  * we don't care the type of leaf nodes.  they are just void *.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt struct radix_tree_node {
     1.1  yamt 	void *n_ptrs[RADIX_TREE_PTR_PER_NODE];
     1.1  yamt 	unsigned int n_nptrs;	/* # of non-NULL pointers in n_ptrs */
     1.1  yamt };
     1.1  yamt
     1.7  yamt /*
     1.7  yamt  * any_children_tagmask:
     1.7  yamt  *
     1.7  yamt  * return OR'ed tagmask of the given node's children.
     1.7  yamt  */
     1.7  yamt
     1.1  yamt static unsigned int
    1.13  yamt any_children_tagmask(const struct radix_tree_node *n)
     1.1  yamt {
     1.1  yamt 	unsigned int mask;
     1.1  yamt 	int i;
     1.1  yamt
     1.1  yamt 	mask = 0;
     1.1  yamt 	for (i = 0; i < RADIX_TREE_PTR_PER_NODE; i++) {
     1.1  yamt 		mask |= (unsigned int)(uintptr_t)n->n_ptrs[i];
     1.1  yamt 	}
     1.1  yamt 	return mask & RADIX_TREE_TAG_MASK;
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * p_refs[0].pptr == &t->t_root
     1.1  yamt  *	:
     1.1  yamt  * p_refs[n].pptr == &(*p_refs[n-1])->n_ptrs[x]
     1.1  yamt  *	:
     1.1  yamt  *	:
     1.1  yamt  * p_refs[t->t_height].pptr == &leaf_pointer
     1.1  yamt  */
     1.1  yamt
     1.1  yamt struct radix_tree_path {
     1.1  yamt 	struct radix_tree_node_ref {
     1.1  yamt 		void **pptr;
     1.1  yamt 	} p_refs[RADIX_TREE_MAX_HEIGHT + 1]; /* +1 for the root ptr */
    1.15  yamt 	/*
    1.15  yamt 	 * p_lastidx is either the index of the last valid element of p_refs[]
    1.15  yamt 	 * or RADIX_TREE_INVALID_HEIGHT.
    1.15  yamt 	 * RADIX_TREE_INVALID_HEIGHT means that radix_tree_lookup_ptr found
    1.15  yamt 	 * that the height of the tree is not enough to cover the given index.
    1.15  yamt 	 */
    1.10  yamt 	unsigned int p_lastidx;
     1.1  yamt };
     1.1  yamt
     1.1  yamt static inline void **
    1.13  yamt path_pptr(const struct radix_tree *t, const struct radix_tree_path *p,
     1.1  yamt     unsigned int height)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	KASSERT(height <= t->t_height);
     1.1  yamt 	return p->p_refs[height].pptr;
     1.1  yamt }
     1.1  yamt
     1.1  yamt static inline struct radix_tree_node *
    1.13  yamt path_node(const struct radix_tree * t, const struct radix_tree_path *p,
    1.13  yamt     unsigned int height)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	KASSERT(height <= t->t_height);
     1.1  yamt 	return entry_ptr(*path_pptr(t, p, height));
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_init_tree:
     1.1  yamt  *
1.17.2.2  yamt  * Initialize a tree.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt void
     1.1  yamt radix_tree_init_tree(struct radix_tree *t)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	t->t_height = 0;
     1.1  yamt 	t->t_root = NULL;
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
1.17.2.2  yamt  * radix_tree_fini_tree:
     1.1  yamt  *
1.17.2.2  yamt  * Finish using a tree.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt void
     1.1  yamt radix_tree_fini_tree(struct radix_tree *t)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	KASSERT(t->t_root == NULL);
     1.1  yamt 	KASSERT(t->t_height == 0);
     1.1  yamt }
     1.1  yamt
1.17.2.2  yamt /*
1.17.2.2  yamt  * radix_tree_empty_tree_p:
1.17.2.2  yamt  *
1.17.2.2  yamt  * Return if the tree is empty.
1.17.2.2  yamt  */
1.17.2.2  yamt
     1.9  yamt bool
     1.9  yamt radix_tree_empty_tree_p(struct radix_tree *t)
     1.9  yamt {
     1.9  yamt
     1.9  yamt 	return t->t_root == NULL;
     1.9  yamt }
     1.9  yamt
1.17.2.2  yamt /*
1.17.2.2  yamt  * radix_tree_empty_tree_p:
1.17.2.2  yamt  *
1.17.2.2  yamt  * Return true if the tree has any nodes with the given tag.  Otherwise
1.17.2.2  yamt  * return false.
1.17.2.2  yamt  */
1.17.2.2  yamt
    1.16  yamt bool
    1.16  yamt radix_tree_empty_tagged_tree_p(struct radix_tree *t, radix_tree_tagid_t tagid)
    1.16  yamt {
    1.16  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
    1.16  yamt
    1.16  yamt 	return (entry_tagmask(t->t_root) & tagmask) == 0;
    1.16  yamt }
    1.16  yamt
     1.3  yamt static void
     1.3  yamt radix_tree_node_init(struct radix_tree_node *n)
     1.3  yamt {
     1.3  yamt
     1.3  yamt 	memset(n, 0, sizeof(*n));
     1.3  yamt }
     1.3  yamt
     1.1  yamt #if defined(_KERNEL)
     1.2  yamt pool_cache_t radix_tree_node_cache __read_mostly;
     1.1  yamt
     1.1  yamt static int
     1.1  yamt radix_tree_node_ctor(void *dummy, void *item, int flags)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_node *n = item;
     1.1  yamt
     1.1  yamt 	KASSERT(dummy == NULL);
     1.3  yamt 	radix_tree_node_init(n);
     1.1  yamt 	return 0;
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_init:
     1.1  yamt  *
     1.1  yamt  * initialize the subsystem.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt void
     1.1  yamt radix_tree_init(void)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	radix_tree_node_cache = pool_cache_init(sizeof(struct radix_tree_node),
     1.1  yamt 	    0, 0, 0, "radix_tree_node", NULL, IPL_NONE, radix_tree_node_ctor,
     1.1  yamt 	    NULL, NULL);
     1.1  yamt 	KASSERT(radix_tree_node_cache != NULL);
     1.1  yamt }
     1.1  yamt #endif /* defined(_KERNEL) */
     1.1  yamt
     1.1  yamt static bool __unused
     1.1  yamt radix_tree_node_clean_p(const struct radix_tree_node *n)
     1.1  yamt {
     1.1  yamt 	unsigned int i;
     1.1  yamt
     1.1  yamt 	if (n->n_nptrs != 0) {
     1.1  yamt 		return false;
     1.1  yamt 	}
     1.1  yamt 	for (i = 0; i < RADIX_TREE_PTR_PER_NODE; i++) {
     1.1  yamt 		if (n->n_ptrs[i] != NULL) {
     1.1  yamt 			return false;
     1.1  yamt 		}
     1.1  yamt 	}
     1.1  yamt 	return true;
     1.1  yamt }
     1.1  yamt
     1.1  yamt static struct radix_tree_node *
     1.1  yamt radix_tree_alloc_node(void)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_node *n;
     1.1  yamt
     1.1  yamt #if defined(_KERNEL)
1.17.2.2  yamt 	/*
1.17.2.2  yamt 	 * note that pool_cache_get can block.
1.17.2.2  yamt 	 */
     1.1  yamt 	n = pool_cache_get(radix_tree_node_cache, PR_NOWAIT);
     1.1  yamt #else /* defined(_KERNEL) */
     1.3  yamt #if defined(_STANDALONE)
     1.3  yamt 	n = alloc(sizeof(*n));
     1.3  yamt #else /* defined(_STANDALONE) */
     1.3  yamt 	n = malloc(sizeof(*n));
     1.3  yamt #endif /* defined(_STANDALONE) */
     1.3  yamt 	if (n != NULL) {
     1.3  yamt 		radix_tree_node_init(n);
     1.3  yamt 	}
     1.1  yamt #endif /* defined(_KERNEL) */
     1.1  yamt 	KASSERT(n == NULL || radix_tree_node_clean_p(n));
     1.1  yamt 	return n;
     1.1  yamt }
     1.1  yamt
     1.1  yamt static void
     1.1  yamt radix_tree_free_node(struct radix_tree_node *n)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	KASSERT(radix_tree_node_clean_p(n));
     1.1  yamt #if defined(_KERNEL)
     1.1  yamt 	pool_cache_put(radix_tree_node_cache, n);
     1.3  yamt #elif defined(_STANDALONE)
     1.3  yamt 	dealloc(n, sizeof(*n));
     1.3  yamt #else
     1.1  yamt 	free(n);
     1.3  yamt #endif
     1.1  yamt }
     1.1  yamt
     1.1  yamt static int
     1.1  yamt radix_tree_grow(struct radix_tree *t, unsigned int newheight)
     1.1  yamt {
     1.1  yamt 	const unsigned int tagmask = entry_tagmask(t->t_root);
     1.1  yamt
     1.1  yamt 	KASSERT(newheight <= 64 / RADIX_TREE_BITS_PER_HEIGHT);
     1.1  yamt 	if (t->t_root == NULL) {
     1.1  yamt 		t->t_height = newheight;
     1.1  yamt 		return 0;
     1.1  yamt 	}
     1.1  yamt 	while (t->t_height < newheight) {
     1.1  yamt 		struct radix_tree_node *n;
     1.1  yamt
     1.1  yamt 		n = radix_tree_alloc_node();
     1.1  yamt 		if (n == NULL) {
     1.1  yamt 			/*
     1.1  yamt 			 * don't bother to revert our changes.
     1.1  yamt 			 * the caller will likely retry.
     1.1  yamt 			 */
     1.1  yamt 			return ENOMEM;
     1.1  yamt 		}
     1.1  yamt 		n->n_nptrs = 1;
     1.1  yamt 		n->n_ptrs[0] = t->t_root;
     1.1  yamt 		t->t_root = entry_compose(n, tagmask);
     1.1  yamt 		t->t_height++;
     1.1  yamt 	}
     1.1  yamt 	return 0;
     1.1  yamt }
     1.1  yamt
     1.5  yamt /*
     1.5  yamt  * radix_tree_lookup_ptr:
     1.5  yamt  *
     1.5  yamt  * an internal helper function used for various exported functions.
     1.5  yamt  *
     1.5  yamt  * return the pointer to store the node for the given index.
     1.5  yamt  *
     1.5  yamt  * if alloc is true, try to allocate the storage.  (note for _KERNEL:
     1.5  yamt  * in that case, this function can block.)  if the allocation failed or
     1.5  yamt  * alloc is false, return NULL.
     1.5  yamt  *
     1.5  yamt  * if path is not NULL, fill it for the caller's investigation.
     1.5  yamt  *
     1.5  yamt  * if tagmask is not zero, search only for nodes with the tag set.
    1.15  yamt  * note that, however, this function doesn't check the tagmask for the leaf
    1.15  yamt  * pointer.  it's a caller's responsibility to investigate the value which
    1.15  yamt  * is pointed by the returned pointer if necessary.
     1.5  yamt  *
     1.5  yamt  * while this function is a bit large, as it's called with some constant
     1.5  yamt  * arguments, inlining might have benefits.  anyway, a compiler will decide.
     1.5  yamt  */
     1.5  yamt
     1.1  yamt static inline void **
     1.1  yamt radix_tree_lookup_ptr(struct radix_tree *t, uint64_t idx,
     1.1  yamt     struct radix_tree_path *path, bool alloc, const unsigned int tagmask)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_node *n;
     1.1  yamt 	int hshift = RADIX_TREE_BITS_PER_HEIGHT * t->t_height;
     1.1  yamt 	int shift;
     1.1  yamt 	void **vpp;
     1.1  yamt 	const uint64_t mask = (UINT64_C(1) << RADIX_TREE_BITS_PER_HEIGHT) - 1;
     1.1  yamt 	struct radix_tree_node_ref *refs = NULL;
     1.1  yamt
     1.5  yamt 	/*
     1.5  yamt 	 * check unsupported combinations
     1.5  yamt 	 */
     1.1  yamt 	KASSERT(tagmask == 0 || !alloc);
     1.1  yamt 	KASSERT(path == NULL || !alloc);
     1.1  yamt 	vpp = &t->t_root;
     1.1  yamt 	if (path != NULL) {
     1.1  yamt 		refs = path->p_refs;
     1.1  yamt 		refs->pptr = vpp;
     1.1  yamt 	}
     1.1  yamt 	n = NULL;
     1.1  yamt 	for (shift = 64 - RADIX_TREE_BITS_PER_HEIGHT; shift >= 0;) {
     1.1  yamt 		struct radix_tree_node *c;
     1.1  yamt 		void *entry;
     1.1  yamt 		const uint64_t i = (idx >> shift) & mask;
     1.1  yamt
     1.1  yamt 		if (shift >= hshift) {
     1.1  yamt 			unsigned int newheight;
     1.1  yamt
     1.1  yamt 			KASSERT(vpp == &t->t_root);
     1.1  yamt 			if (i == 0) {
     1.1  yamt 				shift -= RADIX_TREE_BITS_PER_HEIGHT;
     1.1  yamt 				continue;
     1.1  yamt 			}
     1.1  yamt 			if (!alloc) {
     1.1  yamt 				if (path != NULL) {
     1.1  yamt 					KASSERT((refs - path->p_refs) == 0);
    1.15  yamt 					path->p_lastidx =
    1.15  yamt 					    RADIX_TREE_INVALID_HEIGHT;
     1.1  yamt 				}
     1.1  yamt 				return NULL;
     1.1  yamt 			}
     1.1  yamt 			newheight = shift / RADIX_TREE_BITS_PER_HEIGHT + 1;
     1.1  yamt 			if (radix_tree_grow(t, newheight)) {
     1.1  yamt 				return NULL;
     1.1  yamt 			}
     1.1  yamt 			hshift = RADIX_TREE_BITS_PER_HEIGHT * t->t_height;
     1.1  yamt 		}
     1.1  yamt 		entry = *vpp;
     1.1  yamt 		c = entry_ptr(entry);
     1.1  yamt 		if (c == NULL ||
     1.1  yamt 		    (tagmask != 0 &&
     1.1  yamt 		    (entry_tagmask(entry) & tagmask) == 0)) {
     1.1  yamt 			if (!alloc) {
     1.1  yamt 				if (path != NULL) {
     1.1  yamt 					path->p_lastidx = refs - path->p_refs;
     1.1  yamt 				}
     1.1  yamt 				return NULL;
     1.1  yamt 			}
     1.1  yamt 			c = radix_tree_alloc_node();
     1.1  yamt 			if (c == NULL) {
     1.1  yamt 				return NULL;
     1.1  yamt 			}
     1.1  yamt 			*vpp = c;
     1.1  yamt 			if (n != NULL) {
     1.1  yamt 				KASSERT(n->n_nptrs < RADIX_TREE_PTR_PER_NODE);
     1.1  yamt 				n->n_nptrs++;
     1.1  yamt 			}
     1.1  yamt 		}
     1.1  yamt 		n = c;
     1.1  yamt 		vpp = &n->n_ptrs[i];
     1.1  yamt 		if (path != NULL) {
     1.1  yamt 			refs++;
     1.1  yamt 			refs->pptr = vpp;
     1.1  yamt 		}
     1.1  yamt 		shift -= RADIX_TREE_BITS_PER_HEIGHT;
     1.1  yamt 	}
     1.1  yamt 	if (alloc) {
     1.1  yamt 		KASSERT(*vpp == NULL);
     1.1  yamt 		if (n != NULL) {
     1.1  yamt 			KASSERT(n->n_nptrs < RADIX_TREE_PTR_PER_NODE);
     1.1  yamt 			n->n_nptrs++;
     1.1  yamt 		}
     1.1  yamt 	}
     1.1  yamt 	if (path != NULL) {
     1.1  yamt 		path->p_lastidx = refs - path->p_refs;
     1.1  yamt 	}
     1.1  yamt 	return vpp;
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_insert_node:
     1.1  yamt  *
1.17.2.2  yamt  * Insert the node at the given index.
     1.1  yamt  *
1.17.2.2  yamt  * It's illegal to insert NULL.  It's illegal to insert a non-aligned pointer.
     1.1  yamt  *
1.17.2.2  yamt  * This function returns ENOMEM if necessary memory allocation failed.
1.17.2.2  yamt  * Otherwise, this function returns 0.
     1.4  yamt  *
1.17.2.2  yamt  * Note that inserting a node can involves memory allocation for intermediate
1.17.2.2  yamt  * nodes.  If _KERNEL, it's done with no-sleep IPL_NONE memory allocation.
1.17.2.2  yamt  *
1.17.2.2  yamt  * For the newly inserted node, all tags are cleared.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt int
     1.1  yamt radix_tree_insert_node(struct radix_tree *t, uint64_t idx, void *p)
     1.1  yamt {
     1.1  yamt 	void **vpp;
     1.1  yamt
     1.1  yamt 	KASSERT(p != NULL);
1.17.2.1  yamt 	KASSERT(entry_tagmask(entry_compose(p, 0)) == 0);
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, NULL, true, 0);
     1.1  yamt 	if (vpp == NULL) {
     1.1  yamt 		return ENOMEM;
     1.1  yamt 	}
     1.1  yamt 	KASSERT(*vpp == NULL);
     1.1  yamt 	*vpp = p;
     1.1  yamt 	return 0;
     1.1  yamt }
     1.1  yamt
     1.4  yamt /*
     1.4  yamt  * radix_tree_replace_node:
     1.4  yamt  *
1.17.2.2  yamt  * Replace a node at the given index with the given node and return the
1.17.2.2  yamt  * replaced one.
1.17.2.2  yamt  *
1.17.2.2  yamt  * It's illegal to try to replace a node which has not been inserted.
     1.4  yamt  *
1.17.2.2  yamt  * This function keeps tags intact.
     1.4  yamt  */
     1.4  yamt
     1.1  yamt void *
     1.1  yamt radix_tree_replace_node(struct radix_tree *t, uint64_t idx, void *p)
     1.1  yamt {
     1.1  yamt 	void **vpp;
     1.1  yamt 	void *oldp;
     1.1  yamt
     1.1  yamt 	KASSERT(p != NULL);
1.17.2.1  yamt 	KASSERT(entry_tagmask(entry_compose(p, 0)) == 0);
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, NULL, false, 0);
     1.1  yamt 	KASSERT(vpp != NULL);
     1.1  yamt 	oldp = *vpp;
     1.1  yamt 	KASSERT(oldp != NULL);
     1.1  yamt 	*vpp = entry_compose(p, entry_tagmask(*vpp));
     1.1  yamt 	return entry_ptr(oldp);
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_remove_node:
     1.1  yamt  *
1.17.2.2  yamt  * Remove the node at the given index.
1.17.2.2  yamt  *
1.17.2.2  yamt  * It's illegal to try to remove a node which has not been inserted.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt void *
     1.1  yamt radix_tree_remove_node(struct radix_tree *t, uint64_t idx)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_path path;
     1.1  yamt 	void **vpp;
     1.1  yamt 	void *oldp;
     1.1  yamt 	int i;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, &path, false, 0);
     1.1  yamt 	KASSERT(vpp != NULL);
     1.1  yamt 	oldp = *vpp;
     1.1  yamt 	KASSERT(oldp != NULL);
     1.1  yamt 	KASSERT(path.p_lastidx == t->t_height);
     1.1  yamt 	KASSERT(vpp == path_pptr(t, &path, path.p_lastidx));
     1.1  yamt 	*vpp = NULL;
     1.1  yamt 	for (i = t->t_height - 1; i >= 0; i--) {
     1.1  yamt 		void *entry;
     1.1  yamt 		struct radix_tree_node ** const pptr =
     1.1  yamt 		    (struct radix_tree_node **)path_pptr(t, &path, i);
     1.1  yamt 		struct radix_tree_node *n;
     1.1  yamt
     1.1  yamt 		KASSERT(pptr != NULL);
     1.1  yamt 		entry = *pptr;
     1.1  yamt 		n = entry_ptr(entry);
     1.1  yamt 		KASSERT(n != NULL);
     1.1  yamt 		KASSERT(n->n_nptrs > 0);
     1.1  yamt 		n->n_nptrs--;
     1.1  yamt 		if (n->n_nptrs > 0) {
     1.1  yamt 			break;
     1.1  yamt 		}
     1.1  yamt 		radix_tree_free_node(n);
     1.1  yamt 		*pptr = NULL;
     1.1  yamt 	}
     1.1  yamt 	/*
     1.1  yamt 	 * fix up height
     1.1  yamt 	 */
     1.1  yamt 	if (i < 0) {
     1.1  yamt 		KASSERT(t->t_root == NULL);
     1.1  yamt 		t->t_height = 0;
     1.1  yamt 	}
     1.1  yamt 	/*
     1.1  yamt 	 * update tags
     1.1  yamt 	 */
     1.1  yamt 	for (; i >= 0; i--) {
     1.1  yamt 		void *entry;
     1.1  yamt 		struct radix_tree_node ** const pptr =
     1.1  yamt 		    (struct radix_tree_node **)path_pptr(t, &path, i);
     1.1  yamt 		struct radix_tree_node *n;
     1.1  yamt 		unsigned int newmask;
     1.1  yamt
     1.1  yamt 		KASSERT(pptr != NULL);
     1.1  yamt 		entry = *pptr;
     1.1  yamt 		n = entry_ptr(entry);
     1.1  yamt 		KASSERT(n != NULL);
     1.1  yamt 		KASSERT(n->n_nptrs > 0);
     1.1  yamt 		newmask = any_children_tagmask(n);
     1.1  yamt 		if (newmask == entry_tagmask(entry)) {
     1.1  yamt 			break;
     1.1  yamt 		}
     1.1  yamt 		*pptr = entry_compose(n, newmask);
     1.1  yamt 	}
     1.1  yamt 	/*
     1.1  yamt 	 * XXX is it worth to try to reduce height?
     1.1  yamt 	 * if we do that, make radix_tree_grow rollback its change as well.
     1.1  yamt 	 */
     1.1  yamt 	return entry_ptr(oldp);
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_lookup_node:
     1.1  yamt  *
1.17.2.2  yamt  * Returns the node at the given index.
1.17.2.2  yamt  * Returns NULL if nothing is found at the given index.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt void *
     1.1  yamt radix_tree_lookup_node(struct radix_tree *t, uint64_t idx)
     1.1  yamt {
     1.1  yamt 	void **vpp;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, NULL, false, 0);
     1.1  yamt 	if (vpp == NULL) {
     1.1  yamt 		return NULL;
     1.1  yamt 	}
     1.1  yamt 	return entry_ptr(*vpp);
     1.1  yamt }
     1.1  yamt
     1.1  yamt static inline void
     1.1  yamt gang_lookup_init(struct radix_tree *t, uint64_t idx,
     1.1  yamt     struct radix_tree_path *path, const unsigned int tagmask)
     1.1  yamt {
     1.1  yamt 	void **vpp;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, path, false, tagmask);
     1.1  yamt 	KASSERT(vpp == NULL ||
     1.1  yamt 	    vpp == path_pptr(t, path, path->p_lastidx));
     1.1  yamt 	KASSERT(&t->t_root == path_pptr(t, path, 0));
    1.15  yamt 	KASSERT(path->p_lastidx == RADIX_TREE_INVALID_HEIGHT ||
    1.15  yamt 	   path->p_lastidx == t->t_height ||
    1.15  yamt 	   !entry_match_p(*path_pptr(t, path, path->p_lastidx), tagmask));
     1.1  yamt }
     1.1  yamt
    1.15  yamt /*
    1.15  yamt  * gang_lookup_scan:
    1.15  yamt  *
    1.15  yamt  * a helper routine for radix_tree_gang_lookup_node and its variants.
    1.15  yamt  */
    1.15  yamt
     1.1  yamt static inline unsigned int
    1.15  yamt __attribute__((__always_inline__))
     1.1  yamt gang_lookup_scan(struct radix_tree *t, struct radix_tree_path *path,
1.17.2.1  yamt     void **results, const unsigned int maxresults, const unsigned int tagmask,
1.17.2.1  yamt     const bool reverse, const bool dense)
     1.1  yamt {
    1.15  yamt
    1.15  yamt 	/*
    1.15  yamt 	 * we keep the path updated only for lastidx-1.
    1.15  yamt 	 * vpp is what path_pptr(t, path, lastidx) would be.
    1.15  yamt 	 */
     1.1  yamt 	void **vpp;
    1.10  yamt 	unsigned int nfound;
     1.1  yamt 	unsigned int lastidx;
    1.15  yamt 	/*
    1.15  yamt 	 * set up scan direction dependant constants so that we can iterate
    1.15  yamt 	 * n_ptrs as the following.
    1.15  yamt 	 *
    1.15  yamt 	 *	for (i = first; i != guard; i += step)
    1.15  yamt 	 *		visit n->n_ptrs[i];
    1.15  yamt 	 */
    1.15  yamt 	const int step = reverse ? -1 : 1;
    1.15  yamt 	const unsigned int first = reverse ? RADIX_TREE_PTR_PER_NODE - 1 : 0;
    1.15  yamt 	const unsigned int last = reverse ? 0 : RADIX_TREE_PTR_PER_NODE - 1;
    1.15  yamt 	const unsigned int guard = last + step;
     1.1  yamt
     1.1  yamt 	KASSERT(maxresults > 0);
    1.15  yamt 	KASSERT(&t->t_root == path_pptr(t, path, 0));
     1.1  yamt 	lastidx = path->p_lastidx;
    1.15  yamt 	KASSERT(lastidx == RADIX_TREE_INVALID_HEIGHT ||
    1.15  yamt 	   lastidx == t->t_height ||
    1.15  yamt 	   !entry_match_p(*path_pptr(t, path, lastidx), tagmask));
    1.15  yamt 	nfound = 0;
    1.15  yamt 	if (lastidx == RADIX_TREE_INVALID_HEIGHT) {
1.17.2.1  yamt 		/*
1.17.2.1  yamt 		 * requested idx is beyond the right-most node.
1.17.2.1  yamt 		 */
1.17.2.1  yamt 		if (reverse && !dense) {
    1.15  yamt 			lastidx = 0;
    1.15  yamt 			vpp = path_pptr(t, path, lastidx);
    1.15  yamt 			goto descend;
    1.15  yamt 		}
     1.1  yamt 		return 0;
     1.1  yamt 	}
     1.1  yamt 	vpp = path_pptr(t, path, lastidx);
     1.1  yamt 	while (/*CONSTCOND*/true) {
     1.1  yamt 		struct radix_tree_node *n;
    1.10  yamt 		unsigned int i;
     1.1  yamt
     1.1  yamt 		if (entry_match_p(*vpp, tagmask)) {
     1.1  yamt 			KASSERT(lastidx == t->t_height);
     1.1  yamt 			/*
    1.15  yamt 			 * record the matching non-NULL leaf.
     1.1  yamt 			 */
     1.1  yamt 			results[nfound] = entry_ptr(*vpp);
     1.1  yamt 			nfound++;
     1.1  yamt 			if (nfound == maxresults) {
     1.1  yamt 				return nfound;
     1.1  yamt 			}
1.17.2.1  yamt 		} else if (dense) {
1.17.2.1  yamt 			return nfound;
     1.1  yamt 		}
     1.1  yamt scan_siblings:
     1.1  yamt 		/*
    1.15  yamt 		 * try to find the next matching non-NULL sibling.
     1.1  yamt 		 */
    1.15  yamt 		if (lastidx == 0) {
    1.15  yamt 			/*
    1.15  yamt 			 * the root has no siblings.
    1.15  yamt 			 * we've done.
    1.15  yamt 			 */
    1.15  yamt 			KASSERT(vpp == &t->t_root);
    1.15  yamt 			break;
    1.15  yamt 		}
     1.1  yamt 		n = path_node(t, path, lastidx - 1);
     1.1  yamt 		if (*vpp != NULL && n->n_nptrs == 1) {
     1.1  yamt 			/*
    1.15  yamt 			 * optimization; if the node has only a single pointer
    1.15  yamt 			 * and we've already visited it, there's no point to
    1.15  yamt 			 * keep scanning in this node.
     1.1  yamt 			 */
     1.1  yamt 			goto no_siblings;
     1.1  yamt 		}
    1.15  yamt 		for (i = vpp - n->n_ptrs + step; i != guard; i += step) {
    1.15  yamt 			KASSERT(i < RADIX_TREE_PTR_PER_NODE);
     1.1  yamt 			if (entry_match_p(n->n_ptrs[i], tagmask)) {
     1.1  yamt 				vpp = &n->n_ptrs[i];
     1.1  yamt 				break;
     1.1  yamt 			}
     1.1  yamt 		}
    1.15  yamt 		if (i == guard) {
     1.1  yamt no_siblings:
     1.1  yamt 			/*
     1.1  yamt 			 * not found.  go to parent.
     1.1  yamt 			 */
     1.1  yamt 			lastidx--;
     1.1  yamt 			vpp = path_pptr(t, path, lastidx);
     1.1  yamt 			goto scan_siblings;
     1.1  yamt 		}
    1.15  yamt descend:
     1.1  yamt 		/*
    1.15  yamt 		 * following the left-most (or right-most in the case of
    1.15  yamt 		 * reverse scan) child node, decend until reaching the leaf or
    1.15  yamt 		 * an non-matching entry.
     1.1  yamt 		 */
     1.1  yamt 		while (entry_match_p(*vpp, tagmask) && lastidx < t->t_height) {
    1.15  yamt 			/*
    1.15  yamt 			 * save vpp in the path so that we can come back to this
    1.15  yamt 			 * node after finishing visiting children.
    1.15  yamt 			 */
    1.15  yamt 			path->p_refs[lastidx].pptr = vpp;
     1.1  yamt 			n = entry_ptr(*vpp);
    1.15  yamt 			vpp = &n->n_ptrs[first];
     1.1  yamt 			lastidx++;
     1.1  yamt 		}
     1.1  yamt 	}
    1.15  yamt 	return nfound;
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_gang_lookup_node:
     1.1  yamt  *
1.17.2.2  yamt  * Scan the tree starting from the given index in the ascending order and
1.17.2.2  yamt  * return found nodes.
1.17.2.2  yamt  *
     1.1  yamt  * results should be an array large enough to hold maxresults pointers.
1.17.2.2  yamt  * This function returns the number of nodes found, up to maxresults.
1.17.2.2  yamt  * Returning less than maxresults means there are no more nodes in the tree.
     1.1  yamt  *
1.17.2.2  yamt  * If dense == true, this function stops scanning when it founds a hole of
1.17.2.2  yamt  * indexes.  I.e. an index for which radix_tree_lookup_node would returns NULL.
1.17.2.2  yamt  * If dense == false, this function skips holes and continue scanning until
1.17.2.1  yamt  * maxresults nodes are found or it reaches the limit of the index range.
1.17.2.1  yamt  *
1.17.2.2  yamt  * The result of this function is semantically equivalent to what could be
     1.1  yamt  * obtained by repeated calls of radix_tree_lookup_node with increasing index.
1.17.2.1  yamt  * but this function is expected to be computationally cheaper when looking up
1.17.2.2  yamt  * multiple nodes at once.  Especially, it's expected to be much cheaper when
1.17.2.1  yamt  * node indexes are distributed sparsely.
1.17.2.1  yamt  *
1.17.2.2  yamt  * Note that this function doesn't return index values of found nodes.
1.17.2.2  yamt  * Thus, in the case of dense == false, if index values are important for
1.17.2.1  yamt  * a caller, it's the caller's responsibility to check them, typically
1.17.2.1  yamt  * by examinining the returned nodes using some caller-specific knowledge
1.17.2.1  yamt  * about them.
1.17.2.2  yamt  * In the case of dense == true, a node returned via results[N] is always for
1.17.2.1  yamt  * the index (idx + N).
     1.1  yamt  */
     1.1  yamt
     1.1  yamt unsigned int
     1.1  yamt radix_tree_gang_lookup_node(struct radix_tree *t, uint64_t idx,
1.17.2.1  yamt     void **results, unsigned int maxresults, bool dense)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_path path;
     1.1  yamt
     1.1  yamt 	gang_lookup_init(t, idx, &path, 0);
1.17.2.1  yamt 	return gang_lookup_scan(t, &path, results, maxresults, 0, false, dense);
    1.15  yamt }
    1.15  yamt
    1.15  yamt /*
    1.15  yamt  * radix_tree_gang_lookup_node_reverse:
    1.15  yamt  *
1.17.2.2  yamt  * Same as radix_tree_gang_lookup_node except that this one scans the
1.17.2.2  yamt  * tree in the reverse order.  I.e. descending index values.
    1.15  yamt  */
    1.15  yamt
    1.15  yamt unsigned int
    1.15  yamt radix_tree_gang_lookup_node_reverse(struct radix_tree *t, uint64_t idx,
1.17.2.1  yamt     void **results, unsigned int maxresults, bool dense)
    1.15  yamt {
    1.15  yamt 	struct radix_tree_path path;
    1.15  yamt
    1.15  yamt 	gang_lookup_init(t, idx, &path, 0);
1.17.2.1  yamt 	return gang_lookup_scan(t, &path, results, maxresults, 0, true, dense);
     1.1  yamt }
     1.1  yamt
     1.1  yamt /*
     1.1  yamt  * radix_tree_gang_lookup_tagged_node:
     1.1  yamt  *
1.17.2.2  yamt  * Same as radix_tree_gang_lookup_node except that this one only returns
     1.1  yamt  * nodes tagged with tagid.
     1.1  yamt  */
     1.1  yamt
     1.1  yamt unsigned int
     1.1  yamt radix_tree_gang_lookup_tagged_node(struct radix_tree *t, uint64_t idx,
1.17.2.1  yamt     void **results, unsigned int maxresults, bool dense,
1.17.2.1  yamt     radix_tree_tagid_t tagid)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_path path;
     1.1  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
     1.1  yamt
     1.1  yamt 	gang_lookup_init(t, idx, &path, tagmask);
1.17.2.1  yamt 	return gang_lookup_scan(t, &path, results, maxresults, tagmask, false,
1.17.2.1  yamt 	    dense);
    1.15  yamt }
    1.15  yamt
    1.15  yamt /*
    1.15  yamt  * radix_tree_gang_lookup_tagged_node_reverse:
    1.15  yamt  *
1.17.2.2  yamt  * Same as radix_tree_gang_lookup_tagged_node except that this one scans the
1.17.2.2  yamt  * tree in the reverse order.  I.e. descending index values.
    1.15  yamt  */
    1.15  yamt
    1.15  yamt unsigned int
    1.15  yamt radix_tree_gang_lookup_tagged_node_reverse(struct radix_tree *t, uint64_t idx,
1.17.2.1  yamt     void **results, unsigned int maxresults, bool dense,
1.17.2.1  yamt     radix_tree_tagid_t tagid)
    1.15  yamt {
    1.15  yamt 	struct radix_tree_path path;
    1.15  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
    1.15  yamt
    1.15  yamt 	gang_lookup_init(t, idx, &path, tagmask);
1.17.2.1  yamt 	return gang_lookup_scan(t, &path, results, maxresults, tagmask, true,
1.17.2.1  yamt 	    dense);
     1.1  yamt }
     1.1  yamt
     1.4  yamt /*
     1.4  yamt  * radix_tree_get_tag:
     1.4  yamt  *
1.17.2.2  yamt  * Return if the tag is set for the node at the given index.  (true if set)
1.17.2.2  yamt  *
1.17.2.2  yamt  * It's illegal to call this function for a node which has not been inserted.
     1.4  yamt  */
     1.4  yamt
     1.1  yamt bool
     1.1  yamt radix_tree_get_tag(struct radix_tree *t, uint64_t idx,
     1.1  yamt     radix_tree_tagid_t tagid)
     1.1  yamt {
1.17.2.1  yamt 	/*
1.17.2.1  yamt 	 * the following two implementations should behave same.
1.17.2.1  yamt 	 * the former one was chosen because it seems faster.
1.17.2.1  yamt 	 */
     1.1  yamt #if 1
     1.1  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
     1.1  yamt 	void **vpp;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, NULL, false, tagmask);
     1.1  yamt 	if (vpp == NULL) {
     1.1  yamt 		return false;
     1.1  yamt 	}
     1.1  yamt 	KASSERT(*vpp != NULL);
     1.1  yamt 	return (entry_tagmask(*vpp) & tagmask) != 0;
     1.1  yamt #else
     1.1  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
     1.1  yamt 	void **vpp;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, NULL, false, 0);
     1.1  yamt 	KASSERT(vpp != NULL);
     1.1  yamt 	return (entry_tagmask(*vpp) & tagmask) != 0;
     1.1  yamt #endif
     1.1  yamt }
     1.1  yamt
     1.4  yamt /*
     1.4  yamt  * radix_tree_set_tag:
     1.4  yamt  *
1.17.2.2  yamt  * Set the tag for the node at the given index.
1.17.2.2  yamt  *
1.17.2.2  yamt  * It's illegal to call this function for a node which has not been inserted.
     1.4  yamt  */
     1.4  yamt
     1.1  yamt void
     1.1  yamt radix_tree_set_tag(struct radix_tree *t, uint64_t idx,
     1.1  yamt     radix_tree_tagid_t tagid)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_path path;
     1.1  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
     1.1  yamt 	void **vpp;
     1.1  yamt 	int i;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, &path, false, 0);
     1.1  yamt 	KASSERT(vpp != NULL);
     1.1  yamt 	KASSERT(*vpp != NULL);
     1.1  yamt 	KASSERT(path.p_lastidx == t->t_height);
     1.1  yamt 	KASSERT(vpp == path_pptr(t, &path, path.p_lastidx));
     1.1  yamt 	for (i = t->t_height; i >= 0; i--) {
     1.1  yamt 		void ** const pptr = (void **)path_pptr(t, &path, i);
     1.1  yamt 		void *entry;
     1.1  yamt
     1.1  yamt 		KASSERT(pptr != NULL);
     1.1  yamt 		entry = *pptr;
     1.1  yamt 		if ((entry_tagmask(entry) & tagmask) != 0) {
     1.1  yamt 			break;
     1.1  yamt 		}
     1.1  yamt 		*pptr = (void *)((uintptr_t)entry | tagmask);
     1.1  yamt 	}
     1.1  yamt }
     1.1  yamt
     1.4  yamt /*
     1.4  yamt  * radix_tree_clear_tag:
     1.4  yamt  *
1.17.2.2  yamt  * Clear the tag for the node at the given index.
1.17.2.2  yamt  *
1.17.2.2  yamt  * It's illegal to call this function for a node which has not been inserted.
     1.4  yamt  */
     1.4  yamt
     1.1  yamt void
     1.1  yamt radix_tree_clear_tag(struct radix_tree *t, uint64_t idx,
     1.1  yamt     radix_tree_tagid_t tagid)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_path path;
     1.1  yamt 	const unsigned int tagmask = tagid_to_mask(tagid);
     1.1  yamt 	void **vpp;
     1.1  yamt 	int i;
     1.1  yamt
     1.1  yamt 	vpp = radix_tree_lookup_ptr(t, idx, &path, false, 0);
     1.1  yamt 	KASSERT(vpp != NULL);
     1.1  yamt 	KASSERT(*vpp != NULL);
     1.1  yamt 	KASSERT(path.p_lastidx == t->t_height);
     1.1  yamt 	KASSERT(vpp == path_pptr(t, &path, path.p_lastidx));
     1.7  yamt 	/*
     1.7  yamt 	 * if already cleared, nothing to do
     1.7  yamt 	 */
     1.1  yamt 	if ((entry_tagmask(*vpp) & tagmask) == 0) {
     1.1  yamt 		return;
     1.1  yamt 	}
     1.7  yamt 	/*
     1.7  yamt 	 * clear the tag only if no children have the tag.
     1.7  yamt 	 */
     1.1  yamt 	for (i = t->t_height; i >= 0; i--) {
     1.1  yamt 		void ** const pptr = (void **)path_pptr(t, &path, i);
     1.1  yamt 		void *entry;
     1.1  yamt
     1.1  yamt 		KASSERT(pptr != NULL);
     1.1  yamt 		entry = *pptr;
     1.1  yamt 		KASSERT((entry_tagmask(entry) & tagmask) != 0);
     1.1  yamt 		*pptr = entry_compose(entry_ptr(entry),
     1.1  yamt 		    entry_tagmask(entry) & ~tagmask);
     1.7  yamt 		/*
     1.7  yamt 		 * check if we should proceed to process the next level.
     1.7  yamt 		 */
     1.7  yamt 		if (0 < i) {
     1.1  yamt 			struct radix_tree_node *n = path_node(t, &path, i - 1);
     1.1  yamt
     1.1  yamt 			if ((any_children_tagmask(n) & tagmask) != 0) {
     1.1  yamt 				break;
     1.1  yamt 			}
     1.1  yamt 		}
     1.1  yamt 	}
     1.1  yamt }
     1.1  yamt
     1.1  yamt #if defined(UNITTEST)
     1.1  yamt
     1.1  yamt #include <inttypes.h>
     1.1  yamt #include <stdio.h>
     1.1  yamt
     1.1  yamt static void
     1.1  yamt radix_tree_dump_node(const struct radix_tree *t, void *vp,
     1.1  yamt     uint64_t offset, unsigned int height)
     1.1  yamt {
     1.1  yamt 	struct radix_tree_node *n;
     1.1  yamt 	unsigned int i;
     1.1  yamt
     1.1  yamt 	for (i = 0; i < t->t_height - height; i++) {
     1.1  yamt 		printf(" ");
     1.1  yamt 	}
     1.1  yamt 	if (entry_tagmask(vp) == 0) {
     1.1  yamt 		printf("[%" PRIu64 "] %p", offset, entry_ptr(vp));
     1.1  yamt 	} else {
     1.1  yamt 		printf("[%" PRIu64 "] %p (tagmask=0x%x)", offset, entry_ptr(vp),
     1.1  yamt 		    entry_tagmask(vp));
     1.1  yamt 	}
     1.1  yamt 	if (height == 0) {
     1.1  yamt 		printf(" (leaf)\n");
     1.1  yamt 		return;
     1.1  yamt 	}
     1.1  yamt 	n = entry_ptr(vp);
     1.1  yamt 	assert(any_children_tagmask(n) == entry_tagmask(vp));
     1.1  yamt 	printf(" (%u children)\n", n->n_nptrs);
     1.1  yamt 	for (i = 0; i < __arraycount(n->n_ptrs); i++) {
     1.1  yamt 		void *c;
     1.1  yamt
     1.1  yamt 		c = n->n_ptrs[i];
     1.1  yamt 		if (c == NULL) {
     1.1  yamt 			continue;
     1.1  yamt 		}
     1.1  yamt 		radix_tree_dump_node(t, c,
     1.1  yamt 		    offset + i * (UINT64_C(1) <<
     1.1  yamt 		    (RADIX_TREE_BITS_PER_HEIGHT * (height - 1))), height - 1);
     1.1  yamt 	}
     1.1  yamt }
     1.1  yamt
     1.1  yamt void radix_tree_dump(const struct radix_tree *);
     1.1  yamt
     1.1  yamt void
     1.1  yamt radix_tree_dump(const struct radix_tree *t)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	printf("tree %p height=%u\n", t, t->t_height);
     1.1  yamt 	radix_tree_dump_node(t, t->t_root, 0, t->t_height);
     1.1  yamt }
     1.1  yamt
     1.1  yamt static void
     1.1  yamt test1(void)
     1.1  yamt {
     1.1  yamt 	struct radix_tree s;
     1.1  yamt 	struct radix_tree *t = &s;
     1.1  yamt 	void *results[3];
     1.1  yamt
     1.1  yamt 	radix_tree_init_tree(t);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 0) == NULL);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 1000) == NULL);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, false) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, true) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1000, results, 3, false) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1000, results, 3, true) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 0, results, 3, false) ==
1.17.2.1  yamt 	    0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 0, results, 3, true) ==
1.17.2.1  yamt 	    0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 1000, results, 3, false)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 1000, results, 3, true)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 3, false, 0)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 3, true, 0)
    1.15  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 1000, results, 3, false, 0)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 1000, results, 3, true, 0)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 0, results, 3,
1.17.2.1  yamt 	    false, 0) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 0, results, 3,
1.17.2.1  yamt 	    true, 0) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 1000, results, 3,
1.17.2.1  yamt 	    false, 0) == 0);
    1.15  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 1000, results, 3,
1.17.2.1  yamt 	    true, 0) == 0);
    1.15  yamt 	assert(radix_tree_empty_tree_p(t));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 0));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 1));
    1.15  yamt 	assert(radix_tree_insert_node(t, 0, (void *)0xdeadbea0) == 0);
    1.15  yamt 	assert(!radix_tree_empty_tree_p(t));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 0));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 1));
    1.15  yamt 	assert(radix_tree_lookup_node(t, 0) == (void *)0xdeadbea0);
    1.15  yamt 	assert(radix_tree_lookup_node(t, 1000) == NULL);
    1.15  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, false) == 1);
1.17.2.1  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, true) == 1);
    1.15  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1000, results, 3, false) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1000, results, 3, true) == 0);
    1.15  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 0, results, 3, false) ==
1.17.2.1  yamt 	    1);
    1.15  yamt 	assert(results[0] == (void *)0xdeadbea0);
    1.15  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 0, results, 3, true) ==
1.17.2.1  yamt 	    1);
    1.15  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 1000, results, 3, false)
1.17.2.1  yamt 	    == 1);
1.17.2.1  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 1000, results, 3, true)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 3, false, 0)
    1.15  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 3, true, 0)
    1.15  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 0, results, 3,
1.17.2.1  yamt 	    false, 0) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 0, results, 3,
1.17.2.1  yamt 	    true, 0) == 0);
     1.1  yamt 	assert(radix_tree_insert_node(t, 1000, (void *)0xdeadbea0) == 0);
    1.15  yamt 	assert(radix_tree_remove_node(t, 0) == (void *)0xdeadbea0);
    1.15  yamt 	assert(!radix_tree_empty_tree_p(t));
     1.1  yamt 	radix_tree_dump(t);
    1.15  yamt 	assert(radix_tree_lookup_node(t, 0) == NULL);
    1.15  yamt 	assert(radix_tree_lookup_node(t, 1000) == (void *)0xdeadbea0);
    1.15  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, false) == 1);
1.17.2.1  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, true) == 0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1000, results, 3, false) == 1);
    1.15  yamt 	assert(results[0] == (void *)0xdeadbea0);
    1.15  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1000, results, 3, true) == 1);
    1.15  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 0, results, 3, false)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 0, results, 3, true)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 1000, results, 3, false)
1.17.2.1  yamt 	    == 1);
    1.15  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, 1000, results, 3, true)
1.17.2.1  yamt 	    == 1);
    1.15  yamt 	assert(results[0] == (void *)0xdeadbea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 3, false, 0)
    1.15  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 3, true, 0)
    1.15  yamt 	    == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 0, results, 3,
1.17.2.1  yamt 	    false, 0) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node_reverse(t, 0, results, 3,
1.17.2.1  yamt 	    true, 0) == 0);
     1.1  yamt 	assert(!radix_tree_get_tag(t, 1000, 0));
     1.1  yamt 	assert(!radix_tree_get_tag(t, 1000, 1));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 0));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 1));
     1.1  yamt 	radix_tree_set_tag(t, 1000, 1);
     1.1  yamt 	assert(!radix_tree_get_tag(t, 1000, 0));
     1.1  yamt 	assert(radix_tree_get_tag(t, 1000, 1));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 0));
    1.16  yamt 	assert(!radix_tree_empty_tagged_tree_p(t, 1));
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 1000) == (void *)0xdeadbea0);
     1.1  yamt 	assert(radix_tree_insert_node(t, 0, (void *)0xbea0) == 0);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 0) == (void *)0xbea0);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 1000) == (void *)0xdeadbea0);
     1.1  yamt 	assert(radix_tree_insert_node(t, UINT64_C(10000000000), (void *)0xdea0)
     1.1  yamt 	    == 0);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 0) == (void *)0xbea0);
     1.1  yamt 	assert(radix_tree_lookup_node(t, 1000) == (void *)0xdeadbea0);
     1.1  yamt 	assert(radix_tree_lookup_node(t, UINT64_C(10000000000)) ==
     1.1  yamt 	    (void *)0xdea0);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(!radix_tree_get_tag(t, 0, 1));
     1.1  yamt 	assert(radix_tree_get_tag(t, 1000, 1));
     1.1  yamt 	assert(!radix_tree_get_tag(t, UINT64_C(10000000000), 1));
     1.1  yamt 	radix_tree_set_tag(t, 0, 1);;
     1.1  yamt 	radix_tree_set_tag(t, UINT64_C(10000000000), 1);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_get_tag(t, 0, 1));
     1.1  yamt 	assert(radix_tree_get_tag(t, 1000, 1));
     1.1  yamt 	assert(radix_tree_get_tag(t, UINT64_C(10000000000), 1));
     1.1  yamt 	radix_tree_clear_tag(t, 0, 1);;
     1.1  yamt 	radix_tree_clear_tag(t, UINT64_C(10000000000), 1);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(!radix_tree_get_tag(t, 0, 1));
     1.1  yamt 	assert(radix_tree_get_tag(t, 1000, 1));
     1.1  yamt 	assert(!radix_tree_get_tag(t, UINT64_C(10000000000), 1));
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_replace_node(t, 1000, (void *)0x12345678) ==
     1.1  yamt 	    (void *)0xdeadbea0);
     1.1  yamt 	assert(!radix_tree_get_tag(t, 1000, 0));
     1.1  yamt 	assert(radix_tree_get_tag(t, 1000, 1));
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, false) == 3);
     1.1  yamt 	assert(results[0] == (void *)0xbea0);
     1.1  yamt 	assert(results[1] == (void *)0x12345678);
     1.1  yamt 	assert(results[2] == (void *)0xdea0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 0, results, 3, true) == 1);
1.17.2.1  yamt 	assert(results[0] == (void *)0xbea0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1, results, 3, false) == 2);
     1.1  yamt 	assert(results[0] == (void *)0x12345678);
     1.1  yamt 	assert(results[1] == (void *)0xdea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1, results, 3, true) == 0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1001, results, 3, false) == 1);
     1.1  yamt 	assert(results[0] == (void *)0xdea0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, 1001, results, 3, true) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, UINT64_C(10000000001), results, 3,
1.17.2.1  yamt 	    false) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, UINT64_C(10000000001), results, 3,
1.17.2.1  yamt 	    true) == 0);
     1.1  yamt 	assert(radix_tree_gang_lookup_node(t, UINT64_C(1000000000000), results,
1.17.2.1  yamt 	    3, false) == 0);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, UINT64_C(1000000000000), results,
1.17.2.1  yamt 	    3, true) == 0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 100, false, 1)
1.17.2.1  yamt 	    == 1);
     1.1  yamt 	assert(results[0] == (void *)0x12345678);
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_tagged_node(t, 0, results, 100, true, 1)
1.17.2.1  yamt 	    == 0);
     1.1  yamt 	assert(entry_tagmask(t->t_root) != 0);
     1.1  yamt 	assert(radix_tree_remove_node(t, 1000) == (void *)0x12345678);
     1.1  yamt 	assert(entry_tagmask(t->t_root) == 0);
     1.1  yamt 	radix_tree_dump(t);
1.17.2.1  yamt 	assert(radix_tree_insert_node(t, UINT64_C(10000000001), (void *)0xfff0)
1.17.2.1  yamt 	    == 0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, UINT64_C(10000000000), results, 3,
1.17.2.1  yamt 	    false) == 2);
1.17.2.1  yamt 	assert(results[0] == (void *)0xdea0);
1.17.2.1  yamt 	assert(results[1] == (void *)0xfff0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node(t, UINT64_C(10000000000), results, 3,
1.17.2.1  yamt 	    true) == 2);
1.17.2.1  yamt 	assert(results[0] == (void *)0xdea0);
1.17.2.1  yamt 	assert(results[1] == (void *)0xfff0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, UINT64_C(10000000001),
1.17.2.1  yamt 	    results, 3, false) == 3);
1.17.2.1  yamt 	assert(results[0] == (void *)0xfff0);
1.17.2.1  yamt 	assert(results[1] == (void *)0xdea0);
1.17.2.1  yamt 	assert(results[2] == (void *)0xbea0);
1.17.2.1  yamt 	memset(results, 0, sizeof(results));
1.17.2.1  yamt 	assert(radix_tree_gang_lookup_node_reverse(t, UINT64_C(10000000001),
1.17.2.1  yamt 	    results, 3, true) == 2);
1.17.2.1  yamt 	assert(results[0] == (void *)0xfff0);
1.17.2.1  yamt 	assert(results[1] == (void *)0xdea0);
     1.1  yamt 	assert(radix_tree_remove_node(t, UINT64_C(10000000000)) ==
     1.1  yamt 	    (void *)0xdea0);
1.17.2.1  yamt 	assert(radix_tree_remove_node(t, UINT64_C(10000000001)) ==
1.17.2.1  yamt 	    (void *)0xfff0);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	assert(radix_tree_remove_node(t, 0) == (void *)0xbea0);
     1.1  yamt 	radix_tree_dump(t);
     1.1  yamt 	radix_tree_fini_tree(t);
     1.1  yamt }
     1.1  yamt
     1.1  yamt #include <sys/time.h>
     1.1  yamt
     1.1  yamt struct testnode {
     1.1  yamt 	uint64_t idx;
    1.12  yamt 	bool tagged[RADIX_TREE_TAG_ID_MAX];
     1.1  yamt };
     1.1  yamt
     1.1  yamt static void
    1.11  yamt printops(const char *title, const char *name, int tag, unsigned int n,
    1.11  yamt     const struct timeval *stv, const struct timeval *etv)
     1.1  yamt {
     1.1  yamt 	uint64_t s = stv->tv_sec * 1000000 + stv->tv_usec;
     1.1  yamt 	uint64_t e = etv->tv_sec * 1000000 + etv->tv_usec;
     1.1  yamt
    1.11  yamt 	printf("RESULT %s %s %d %lf op/s\n", title, name, tag,
    1.11  yamt 	    (double)n / (e - s) * 1000000);
     1.1  yamt }
     1.1  yamt
     1.1  yamt #define	TEST2_GANG_LOOKUP_NODES	16
     1.1  yamt
     1.1  yamt static bool
     1.1  yamt test2_should_tag(unsigned int i, radix_tree_tagid_t tagid)
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	if (tagid == 0) {
    1.11  yamt 		return (i & 0x3) == 0;	/* 25% */
     1.1  yamt 	} else {
    1.11  yamt 		return (i % 7) == 0;	/* 14% */
     1.1  yamt 	}
     1.1  yamt }
     1.1  yamt
     1.1  yamt static void
    1.11  yamt test2(const char *title, bool dense)
     1.1  yamt {
     1.1  yamt 	struct radix_tree s;
     1.1  yamt 	struct radix_tree *t = &s;
     1.1  yamt 	struct testnode *n;
     1.1  yamt 	unsigned int i;
     1.1  yamt 	unsigned int nnodes = 100000;
     1.1  yamt 	unsigned int removed;
     1.1  yamt 	radix_tree_tagid_t tag;
     1.1  yamt 	unsigned int ntagged[RADIX_TREE_TAG_ID_MAX];
     1.1  yamt 	struct testnode *nodes;
     1.1  yamt 	struct timeval stv;
     1.1  yamt 	struct timeval etv;
     1.1  yamt
     1.1  yamt 	nodes = malloc(nnodes * sizeof(*nodes));
     1.1  yamt 	for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
     1.1  yamt 		ntagged[tag] = 0;
     1.1  yamt 	}
     1.1  yamt 	radix_tree_init_tree(t);
     1.1  yamt 	for (i = 0; i < nnodes; i++) {
     1.1  yamt 		n = &nodes[i];
     1.1  yamt 		n->idx = random();
     1.1  yamt 		if (sizeof(long) == 4) {
     1.1  yamt 			n->idx <<= 32;
     1.1  yamt 			n->idx |= (uint32_t)random();
     1.1  yamt 		}
     1.1  yamt 		if (dense) {
     1.1  yamt 			n->idx %= nnodes * 2;
     1.1  yamt 		}
     1.1  yamt 		while (radix_tree_lookup_node(t, n->idx) != NULL) {
     1.1  yamt 			n->idx++;
     1.1  yamt 		}
     1.1  yamt 		radix_tree_insert_node(t, n->idx, n);
     1.1  yamt 		for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
    1.12  yamt 			n->tagged[tag] = test2_should_tag(i, tag);
    1.12  yamt 			if (n->tagged[tag]) {
     1.1  yamt 				radix_tree_set_tag(t, n->idx, tag);
     1.1  yamt 				ntagged[tag]++;
     1.1  yamt 			}
    1.12  yamt 			assert(n->tagged[tag] ==
     1.1  yamt 			    radix_tree_get_tag(t, n->idx, tag));
     1.1  yamt 		}
     1.1  yamt 	}
     1.1  yamt
     1.1  yamt 	gettimeofday(&stv, NULL);
     1.1  yamt 	for (i = 0; i < nnodes; i++) {
     1.1  yamt 		n = &nodes[i];
     1.1  yamt 		assert(radix_tree_lookup_node(t, n->idx) == n);
     1.1  yamt 	}
     1.1  yamt 	gettimeofday(&etv, NULL);
    1.11  yamt 	printops(title, "lookup", 0, nnodes, &stv, &etv);
     1.1  yamt
     1.1  yamt 	for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
    1.12  yamt 		unsigned int count = 0;
    1.12  yamt
     1.1  yamt 		gettimeofday(&stv, NULL);
     1.1  yamt 		for (i = 0; i < nnodes; i++) {
    1.12  yamt 			bool tagged;
    1.12  yamt
     1.1  yamt 			n = &nodes[i];
    1.12  yamt 			tagged = radix_tree_get_tag(t, n->idx, tag);
    1.12  yamt 			assert(n->tagged[tag] == tagged);
    1.12  yamt 			if (tagged) {
    1.12  yamt 				count++;
    1.12  yamt 			}
     1.1  yamt 		}
     1.1  yamt 		gettimeofday(&etv, NULL);
    1.12  yamt 		assert(ntagged[tag] == count);
    1.12  yamt 		printops(title, "get_tag", tag, nnodes, &stv, &etv);
     1.1  yamt 	}
     1.1  yamt
     1.1  yamt 	gettimeofday(&stv, NULL);
     1.1  yamt 	for (i = 0; i < nnodes; i++) {
     1.1  yamt 		n = &nodes[i];
     1.1  yamt 		radix_tree_remove_node(t, n->idx);
     1.1  yamt 	}
     1.1  yamt 	gettimeofday(&etv, NULL);
    1.11  yamt 	printops(title, "remove", 0, nnodes, &stv, &etv);
     1.1  yamt
     1.1  yamt 	gettimeofday(&stv, NULL);
     1.1  yamt 	for (i = 0; i < nnodes; i++) {
     1.1  yamt 		n = &nodes[i];
     1.1  yamt 		radix_tree_insert_node(t, n->idx, n);
     1.1  yamt 	}
     1.1  yamt 	gettimeofday(&etv, NULL);
    1.11  yamt 	printops(title, "insert", 0, nnodes, &stv, &etv);
     1.1  yamt
     1.1  yamt 	for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
     1.1  yamt 		ntagged[tag] = 0;
     1.1  yamt 		gettimeofday(&stv, NULL);
     1.1  yamt 		for (i = 0; i < nnodes; i++) {
     1.1  yamt 			n = &nodes[i];
    1.12  yamt 			if (n->tagged[tag]) {
     1.1  yamt 				radix_tree_set_tag(t, n->idx, tag);
     1.1  yamt 				ntagged[tag]++;
     1.1  yamt 			}
     1.1  yamt 		}
     1.1  yamt 		gettimeofday(&etv, NULL);
    1.11  yamt 		printops(title, "set_tag", tag, ntagged[tag], &stv, &etv);
     1.1  yamt 	}
     1.1  yamt
     1.1  yamt 	gettimeofday(&stv, NULL);
     1.1  yamt 	{
     1.1  yamt 		struct testnode *results[TEST2_GANG_LOOKUP_NODES];
     1.1  yamt 		uint64_t nextidx;
     1.1  yamt 		unsigned int nfound;
     1.1  yamt 		unsigned int total;
     1.1  yamt
     1.1  yamt 		nextidx = 0;
     1.1  yamt 		total = 0;
     1.1  yamt 		while ((nfound = radix_tree_gang_lookup_node(t, nextidx,
1.17.2.1  yamt 		    (void *)results, __arraycount(results), false)) > 0) {
     1.1  yamt 			nextidx = results[nfound - 1]->idx + 1;
     1.1  yamt 			total += nfound;
    1.15  yamt 			if (nextidx == 0) {
    1.15  yamt 				break;
    1.15  yamt 			}
     1.1  yamt 		}
     1.1  yamt 		assert(total == nnodes);
     1.1  yamt 	}
     1.1  yamt 	gettimeofday(&etv, NULL);
    1.11  yamt 	printops(title, "ganglookup", 0, nnodes, &stv, &etv);
     1.1  yamt
    1.15  yamt 	gettimeofday(&stv, NULL);
    1.15  yamt 	{
    1.15  yamt 		struct testnode *results[TEST2_GANG_LOOKUP_NODES];
    1.15  yamt 		uint64_t nextidx;
    1.15  yamt 		unsigned int nfound;
    1.15  yamt 		unsigned int total;
    1.15  yamt
    1.15  yamt 		nextidx = UINT64_MAX;
    1.15  yamt 		total = 0;
    1.15  yamt 		while ((nfound = radix_tree_gang_lookup_node_reverse(t, nextidx,
1.17.2.1  yamt 		    (void *)results, __arraycount(results), false)) > 0) {
    1.15  yamt 			nextidx = results[nfound - 1]->idx - 1;
    1.15  yamt 			total += nfound;
    1.15  yamt 			if (nextidx == UINT64_MAX) {
    1.15  yamt 				break;
    1.15  yamt 			}
    1.15  yamt 		}
    1.15  yamt 		assert(total == nnodes);
    1.15  yamt 	}
    1.15  yamt 	gettimeofday(&etv, NULL);
    1.15  yamt 	printops(title, "ganglookup_reverse", 0, nnodes, &stv, &etv);
    1.15  yamt
     1.1  yamt 	for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
     1.1  yamt 		gettimeofday(&stv, NULL);
     1.1  yamt 		{
     1.1  yamt 			struct testnode *results[TEST2_GANG_LOOKUP_NODES];
     1.1  yamt 			uint64_t nextidx;
     1.1  yamt 			unsigned int nfound;
     1.1  yamt 			unsigned int total;
     1.1  yamt
     1.1  yamt 			nextidx = 0;
     1.1  yamt 			total = 0;
     1.1  yamt 			while ((nfound = radix_tree_gang_lookup_tagged_node(t,
     1.1  yamt 			    nextidx, (void *)results, __arraycount(results),
1.17.2.1  yamt 			    false, tag)) > 0) {
     1.1  yamt 				nextidx = results[nfound - 1]->idx + 1;
     1.1  yamt 				total += nfound;
     1.1  yamt 			}
     1.1  yamt 			assert(total == ntagged[tag]);
     1.1  yamt 		}
     1.1  yamt 		gettimeofday(&etv, NULL);
    1.11  yamt 		printops(title, "ganglookup_tag", tag, ntagged[tag], &stv,
    1.11  yamt 		    &etv);
     1.1  yamt 	}
     1.1  yamt
    1.15  yamt 	for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
    1.15  yamt 		gettimeofday(&stv, NULL);
    1.15  yamt 		{
    1.15  yamt 			struct testnode *results[TEST2_GANG_LOOKUP_NODES];
    1.15  yamt 			uint64_t nextidx;
    1.15  yamt 			unsigned int nfound;
    1.15  yamt 			unsigned int total;
    1.15  yamt
    1.15  yamt 			nextidx = UINT64_MAX;
    1.15  yamt 			total = 0;
    1.15  yamt 			while ((nfound =
    1.15  yamt 			    radix_tree_gang_lookup_tagged_node_reverse(t,
    1.15  yamt 			    nextidx, (void *)results, __arraycount(results),
1.17.2.1  yamt 			    false, tag)) > 0) {
    1.15  yamt 				nextidx = results[nfound - 1]->idx - 1;
    1.15  yamt 				total += nfound;
    1.15  yamt 				if (nextidx == UINT64_MAX) {
    1.15  yamt 					break;
    1.15  yamt 				}
    1.15  yamt 			}
    1.15  yamt 			assert(total == ntagged[tag]);
    1.15  yamt 		}
    1.15  yamt 		gettimeofday(&etv, NULL);
    1.15  yamt 		printops(title, "ganglookup_tag_reverse", tag, ntagged[tag],
    1.15  yamt 		    &stv, &etv);
    1.15  yamt 	}
    1.15  yamt
     1.1  yamt 	removed = 0;
     1.1  yamt 	for (tag = 0; tag < RADIX_TREE_TAG_ID_MAX; tag++) {
     1.1  yamt 		unsigned int total;
     1.1  yamt
     1.1  yamt 		total = 0;
     1.1  yamt 		gettimeofday(&stv, NULL);
     1.1  yamt 		{
     1.1  yamt 			struct testnode *results[TEST2_GANG_LOOKUP_NODES];
     1.1  yamt 			uint64_t nextidx;
     1.1  yamt 			unsigned int nfound;
     1.1  yamt
     1.1  yamt 			nextidx = 0;
     1.1  yamt 			while ((nfound = radix_tree_gang_lookup_tagged_node(t,
     1.1  yamt 			    nextidx, (void *)results, __arraycount(results),
1.17.2.1  yamt 			    false, tag)) > 0) {
     1.1  yamt 				for (i = 0; i < nfound; i++) {
     1.1  yamt 					radix_tree_remove_node(t,
     1.1  yamt 					    results[i]->idx);
     1.1  yamt 				}
     1.1  yamt 				nextidx = results[nfound - 1]->idx + 1;
     1.1  yamt 				total += nfound;
    1.15  yamt 				if (nextidx == 0) {
    1.15  yamt 					break;
    1.15  yamt 				}
     1.1  yamt 			}
     1.1  yamt 			assert(tag != 0 || total == ntagged[tag]);
     1.1  yamt 			assert(total <= ntagged[tag]);
     1.1  yamt 		}
     1.1  yamt 		gettimeofday(&etv, NULL);
    1.11  yamt 		printops(title, "ganglookup_tag+remove", tag, total, &stv,
    1.11  yamt 		    &etv);
     1.1  yamt 		removed += total;
     1.1  yamt 	}
     1.1  yamt
     1.1  yamt 	gettimeofday(&stv, NULL);
     1.1  yamt 	{
     1.1  yamt 		struct testnode *results[TEST2_GANG_LOOKUP_NODES];
     1.1  yamt 		uint64_t nextidx;
     1.1  yamt 		unsigned int nfound;
     1.1  yamt 		unsigned int total;
     1.1  yamt
     1.1  yamt 		nextidx = 0;
     1.1  yamt 		total = 0;
     1.1  yamt 		while ((nfound = radix_tree_gang_lookup_node(t, nextidx,
1.17.2.1  yamt 		    (void *)results, __arraycount(results), false)) > 0) {
     1.1  yamt 			for (i = 0; i < nfound; i++) {
     1.1  yamt 				assert(results[i] == radix_tree_remove_node(t,
     1.1  yamt 				    results[i]->idx));
     1.1  yamt 			}
     1.1  yamt 			nextidx = results[nfound - 1]->idx + 1;
     1.1  yamt 			total += nfound;
    1.15  yamt 			if (nextidx == 0) {
    1.15  yamt 				break;
    1.15  yamt 			}
     1.1  yamt 		}
     1.1  yamt 		assert(total == nnodes - removed);
     1.1  yamt 	}
     1.1  yamt 	gettimeofday(&etv, NULL);
    1.11  yamt 	printops(title, "ganglookup+remove", 0, nnodes - removed, &stv, &etv);
     1.1  yamt
    1.16  yamt 	assert(radix_tree_empty_tree_p(t));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 0));
    1.16  yamt 	assert(radix_tree_empty_tagged_tree_p(t, 1));
     1.1  yamt 	radix_tree_fini_tree(t);
     1.1  yamt 	free(nodes);
     1.1  yamt }
     1.1  yamt
     1.1  yamt int
     1.1  yamt main(int argc, char *argv[])
     1.1  yamt {
     1.1  yamt
     1.1  yamt 	test1();
    1.11  yamt 	test2("dense", true);
    1.11  yamt 	test2("sparse", false);
     1.1  yamt 	return 0;
     1.1  yamt }
     1.1  yamt
     1.1  yamt #endif /* defined(UNITTEST) */