diff options
author | Rob Landley <rob@landley.net> | 2007-02-10 04:46:20 -0500 |
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committer | Linus Torvalds <torvalds@woody.linux-foundation.org> | 2007-02-11 13:51:35 -0500 |
commit | c742b53114f8d1535608dafb6a5690103a0748b5 (patch) | |
tree | d03fd8f9456542b9c7b6dc39ba4a6ba4de198d9e /Documentation | |
parent | 82ddcb040570411fc2d421d96b3e69711c670328 (diff) |
[PATCH] Documentation/rbtree.txt
Documentation for lib/rbtree.c.
Signed-off-by: Rob Landley <rob@landley.net>
Cc: "Randy.Dunlap" <rdunlap@xenotime.net>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Diffstat (limited to 'Documentation')
-rw-r--r-- | Documentation/rbtree.txt | 192 |
1 files changed, 192 insertions, 0 deletions
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1 | Red-black Trees (rbtree) in Linux | ||
2 | January 18, 2007 | ||
3 | Rob Landley <rob@landley.net> | ||
4 | ============================= | ||
5 | |||
6 | What are red-black trees, and what are they for? | ||
7 | ------------------------------------------------ | ||
8 | |||
9 | Red-black trees are a type of self-balancing binary search tree, used for | ||
10 | storing sortable key/value data pairs. This differs from radix trees (which | ||
11 | are used to efficiently store sparse arrays and thus use long integer indexes | ||
12 | to insert/access/delete nodes) and hash tables (which are not kept sorted to | ||
13 | be easily traversed in order, and must be tuned for a specific size and | ||
14 | hash function where rbtrees scale gracefully storing arbitrary keys). | ||
15 | |||
16 | Red-black trees are similar to AVL trees, but provide faster real-time bounded | ||
17 | worst case performance for insertion and deletion (at most two rotations and | ||
18 | three rotations, respectively, to balance the tree), with slightly slower | ||
19 | (but still O(log n)) lookup time. | ||
20 | |||
21 | To quote Linux Weekly News: | ||
22 | |||
23 | There are a number of red-black trees in use in the kernel. | ||
24 | The anticipatory, deadline, and CFQ I/O schedulers all employ | ||
25 | rbtrees to track requests; the packet CD/DVD driver does the same. | ||
26 | The high-resolution timer code uses an rbtree to organize outstanding | ||
27 | timer requests. The ext3 filesystem tracks directory entries in a | ||
28 | red-black tree. Virtual memory areas (VMAs) are tracked with red-black | ||
29 | trees, as are epoll file descriptors, cryptographic keys, and network | ||
30 | packets in the "hierarchical token bucket" scheduler. | ||
31 | |||
32 | This document covers use of the Linux rbtree implementation. For more | ||
33 | information on the nature and implementation of Red Black Trees, see: | ||
34 | |||
35 | Linux Weekly News article on red-black trees | ||
36 | http://lwn.net/Articles/184495/ | ||
37 | |||
38 | Wikipedia entry on red-black trees | ||
39 | http://en.wikipedia.org/wiki/Red-black_tree | ||
40 | |||
41 | Linux implementation of red-black trees | ||
42 | --------------------------------------- | ||
43 | |||
44 | Linux's rbtree implementation lives in the file "lib/rbtree.c". To use it, | ||
45 | "#include <linux/rbtree.h>". | ||
46 | |||
47 | The Linux rbtree implementation is optimized for speed, and thus has one | ||
48 | less layer of indirection (and better cache locality) than more traditional | ||
49 | tree implementations. Instead of using pointers to separate rb_node and data | ||
50 | structures, each instance of struct rb_node is embedded in the data structure | ||
51 | it organizes. And instead of using a comparison callback function pointer, | ||
52 | users are expected to write their own tree search and insert functions | ||
53 | which call the provided rbtree functions. Locking is also left up to the | ||
54 | user of the rbtree code. | ||
55 | |||
56 | Creating a new rbtree | ||
57 | --------------------- | ||
58 | |||
59 | Data nodes in an rbtree tree are structures containing a struct rb_node member: | ||
60 | |||
61 | struct mytype { | ||
62 | struct rb_node node; | ||
63 | char *keystring; | ||
64 | }; | ||
65 | |||
66 | When dealing with a pointer to the embedded struct rb_node, the containing data | ||
67 | structure may be accessed with the standard container_of() macro. In addition, | ||
68 | individual members may be accessed directly via rb_entry(node, type, member). | ||
69 | |||
70 | At the root of each rbtree is an rb_root structure, which is initialized to be | ||
71 | empty via: | ||
72 | |||
73 | struct rb_root mytree = RB_ROOT; | ||
74 | |||
75 | Searching for a value in an rbtree | ||
76 | ---------------------------------- | ||
77 | |||
78 | Writing a search function for your tree is fairly straightforward: start at the | ||
79 | root, compare each value, and follow the left or right branch as necessary. | ||
80 | |||
81 | Example: | ||
82 | |||
83 | struct mytype *my_search(struct rb_root *root, char *string) | ||
84 | { | ||
85 | struct rb_node *node = root->rb_node; | ||
86 | |||
87 | while (node) { | ||
88 | struct mytype *data = container_of(node, struct mytype, node); | ||
89 | int result; | ||
90 | |||
91 | result = strcmp(string, data->keystring); | ||
92 | |||
93 | if (result < 0) | ||
94 | node = node->rb_left; | ||
95 | else if (result > 0) | ||
96 | node = node->rb_right; | ||
97 | else | ||
98 | return data; | ||
99 | } | ||
100 | return NULL; | ||
101 | } | ||
102 | |||
103 | Inserting data into an rbtree | ||
104 | ----------------------------- | ||
105 | |||
106 | Inserting data in the tree involves first searching for the place to insert the | ||
107 | new node, then inserting the node and rebalancing ("recoloring") the tree. | ||
108 | |||
109 | The search for insertion differs from the previous search by finding the | ||
110 | location of the pointer on which to graft the new node. The new node also | ||
111 | needs a link to its parent node for rebalancing purposes. | ||
112 | |||
113 | Example: | ||
114 | |||
115 | int my_insert(struct rb_root *root, struct mytype *data) | ||
116 | { | ||
117 | struct rb_node **new = &(root->rb_node), *parent = NULL; | ||
118 | |||
119 | /* Figure out where to put new node */ | ||
120 | while (*new) { | ||
121 | struct mytype *this = container_of(*new, struct mytype, node); | ||
122 | int result = strcmp(data->keystring, this->keystring); | ||
123 | |||
124 | parent = *new; | ||
125 | if (result < 0) | ||
126 | new = &((*new)->rb_left); | ||
127 | else if (result > 0) | ||
128 | new = &((*new)->rb_right); | ||
129 | else | ||
130 | return FALSE; | ||
131 | } | ||
132 | |||
133 | /* Add new node and rebalance tree. */ | ||
134 | rb_link_node(data->node, parent, new); | ||
135 | rb_insert_color(data->node, root); | ||
136 | |||
137 | return TRUE; | ||
138 | } | ||
139 | |||
140 | Removing or replacing existing data in an rbtree | ||
141 | ------------------------------------------------ | ||
142 | |||
143 | To remove an existing node from a tree, call: | ||
144 | |||
145 | void rb_erase(struct rb_node *victim, struct rb_root *tree); | ||
146 | |||
147 | Example: | ||
148 | |||
149 | struct mytype *data = mysearch(mytree, "walrus"); | ||
150 | |||
151 | if (data) { | ||
152 | rb_erase(data->node, mytree); | ||
153 | myfree(data); | ||
154 | } | ||
155 | |||
156 | To replace an existing node in a tree with a new one with the same key, call: | ||
157 | |||
158 | void rb_replace_node(struct rb_node *old, struct rb_node *new, | ||
159 | struct rb_root *tree); | ||
160 | |||
161 | Replacing a node this way does not re-sort the tree: If the new node doesn't | ||
162 | have the same key as the old node, the rbtree will probably become corrupted. | ||
163 | |||
164 | Iterating through the elements stored in an rbtree (in sort order) | ||
165 | ------------------------------------------------------------------ | ||
166 | |||
167 | Four functions are provided for iterating through an rbtree's contents in | ||
168 | sorted order. These work on arbitrary trees, and should not need to be | ||
169 | modified or wrapped (except for locking purposes): | ||
170 | |||
171 | struct rb_node *rb_first(struct rb_root *tree); | ||
172 | struct rb_node *rb_last(struct rb_root *tree); | ||
173 | struct rb_node *rb_next(struct rb_node *node); | ||
174 | struct rb_node *rb_prev(struct rb_node *node); | ||
175 | |||
176 | To start iterating, call rb_first() or rb_last() with a pointer to the root | ||
177 | of the tree, which will return a pointer to the node structure contained in | ||
178 | the first or last element in the tree. To continue, fetch the next or previous | ||
179 | node by calling rb_next() or rb_prev() on the current node. This will return | ||
180 | NULL when there are no more nodes left. | ||
181 | |||
182 | The iterator functions return a pointer to the embedded struct rb_node, from | ||
183 | which the containing data structure may be accessed with the container_of() | ||
184 | macro, and individual members may be accessed directly via | ||
185 | rb_entry(node, type, member). | ||
186 | |||
187 | Example: | ||
188 | |||
189 | struct rb_node *node; | ||
190 | for (node = rb_first(&mytree); node; node = rb_next(node)) | ||
191 | printk("key=%s\n", rb_entry(node, int, keystring)); | ||
192 | |||