xref: /freebsd/contrib/unbound/edns-subnet/addrtree.c (revision e1c4c8dd8d2d10b6104f06856a77bd5b4813a801)
1 /*
2  * edns-subnet/addrtree.c -- radix tree for edns subnet cache.
3  *
4  * Copyright (c) 2013, NLnet Labs. All rights reserved.
5  *
6  * This software is open source.
7  *
8  * Redistribution and use in source and binary forms, with or without
9  * modification, are permitted provided that the following conditions
10  * are met:
11  *
12  * Redistributions of source code must retain the above copyright notice,
13  * this list of conditions and the following disclaimer.
14  *
15  * Redistributions in binary form must reproduce the above copyright notice,
16  * this list of conditions and the following disclaimer in the documentation
17  * and/or other materials provided with the distribution.
18  *
19  * Neither the name of the NLNET LABS nor the names of its contributors may
20  * be used to endorse or promote products derived from this software without
21  * specific prior written permission.
22  *
23  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
24  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
25  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
26  * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
27  * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
28  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
29  * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
30  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
31  * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
32  * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
33  * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
34  */
35 /** \file
36  * addrtree -- radix tree for edns subnet cache.
37  */
38 
39 #include "config.h"
40 #include "util/log.h"
41 #include "util/data/msgreply.h"
42 #include "util/module.h"
43 #include "addrtree.h"
44 
45 /**
46  * Create a new edge
47  * @param node: Child node this edge will connect to.
48  * @param addr: full key to this edge.
49  * @param addrlen: length of relevant part of key for this node
50  * @param parent_node: Parent node for node
51  * @param parent_index: Index of child node at parent node
52  * @return new addredge or NULL on failure
53  */
54 static struct addredge *
55 edge_create(struct addrnode *node, const addrkey_t *addr,
56 	addrlen_t addrlen, struct addrnode *parent_node, int parent_index)
57 {
58 	size_t n;
59 	struct addredge *edge = (struct addredge *)malloc( sizeof (*edge) );
60 	if (!edge)
61 		return NULL;
62 	edge->node = node;
63 	edge->len = addrlen;
64 	edge->parent_index = parent_index;
65 	edge->parent_node = parent_node;
66 	/* ceil() */
67 	n = (size_t)((addrlen / KEYWIDTH) + ((addrlen % KEYWIDTH != 0)?1:0));
68 	edge->str = (addrkey_t *)calloc(n, sizeof (addrkey_t));
69 	if (!edge->str) {
70 		free(edge);
71 		return NULL;
72 	}
73 	memcpy(edge->str, addr, n * sizeof (addrkey_t));
74 	/* Only manipulate other objects after successful alloc */
75 	node->parent_edge = edge;
76 	log_assert(parent_node->edge[parent_index] == NULL);
77 	parent_node->edge[parent_index] = edge;
78 	return edge;
79 }
80 
81 /**
82  * Create a new node
83  * @param tree: Tree the node lives in.
84  * @param elem: Element to store at this node
85  * @param scope: Scopemask from server reply
86  * @param ttl: Element is valid up to this time. Absolute, seconds
87  * @return new addrnode or NULL on failure
88  */
89 static struct addrnode *
90 node_create(struct addrtree *tree, void *elem, addrlen_t scope,
91 	time_t ttl)
92 {
93 	struct addrnode* node = (struct addrnode *)malloc( sizeof (*node) );
94 	if (!node)
95 		return NULL;
96 	node->elem = elem;
97 	tree->node_count++;
98 	node->scope = scope;
99 	node->ttl = ttl;
100 	node->only_match_scope_zero = 0;
101 	node->edge[0] = NULL;
102 	node->edge[1] = NULL;
103 	node->parent_edge = NULL;
104 	node->next = NULL;
105 	node->prev = NULL;
106 	return node;
107 }
108 
109 /** Size in bytes of node and parent edge
110  * @param tree: tree the node lives in
111  * @param n: node which size must be calculated
112  * @return size in bytes.
113  **/
114 static inline size_t
115 node_size(const struct addrtree *tree, const struct addrnode *n)
116 {
117 	return sizeof *n + sizeof *n->parent_edge + n->parent_edge->len +
118 		(n->elem?tree->sizefunc(n->elem):0);
119 }
120 
121 struct addrtree *
122 addrtree_create(addrlen_t max_depth, void (*delfunc)(void *, void *),
123 	size_t (*sizefunc)(void *), void *env, uint32_t max_node_count)
124 {
125 	struct addrtree *tree;
126 	log_assert(delfunc != NULL);
127 	log_assert(sizefunc != NULL);
128 	tree = (struct addrtree *)calloc(1, sizeof(*tree));
129 	if (!tree)
130 		return NULL;
131 	tree->root = node_create(tree, NULL, 0, 0);
132 	if (!tree->root) {
133 		free(tree);
134 		return NULL;
135 	}
136 	tree->size_bytes = sizeof *tree + sizeof *tree->root;
137 	tree->first = NULL;
138 	tree->last = NULL;
139 	tree->max_depth = max_depth;
140 	tree->delfunc = delfunc;
141 	tree->sizefunc = sizefunc;
142 	tree->env = env;
143 	tree->node_count = 0;
144 	tree->max_node_count = max_node_count;
145 	return tree;
146 }
147 
148 /**
149  * Scrub a node clean of elem
150  * @param tree: tree the node lives in.
151  * @param node: node to be cleaned.
152  */
153 static void
154 clean_node(struct addrtree *tree, struct addrnode *node)
155 {
156 	if (!node->elem) return;
157 	tree->size_bytes -= tree->sizefunc(node->elem);
158 	tree->delfunc(tree->env, node->elem);
159 	node->only_match_scope_zero = 0;
160 	node->elem = NULL;
161 }
162 
163 /** Remove specified node from LRU list */
164 static void
165 lru_pop(struct addrtree *tree, struct addrnode *node)
166 {
167 	if (node == tree->first) {
168 		if (!node->next) { /* it is the last as well */
169 			tree->first = NULL;
170 			tree->last = NULL;
171 		} else {
172 			tree->first = node->next;
173 			tree->first->prev = NULL;
174 		}
175 	} else if (node == tree->last) { /* but not the first */
176 		tree->last = node->prev;
177 		tree->last->next = NULL;
178 	} else {
179 		node->prev->next = node->next;
180 		node->next->prev = node->prev;
181 	}
182 }
183 
184 /** Add node to LRU list as most recently used. */
185 static void
186 lru_push(struct addrtree *tree, struct addrnode *node)
187 {
188 	if (!tree->first) {
189 		tree->first = node;
190 		node->prev = NULL;
191 	} else {
192 		tree->last->next = node;
193 		node->prev = tree->last;
194 	}
195 	tree->last = node;
196 	node->next = NULL;
197 }
198 
199 /** Move node to the end of LRU list */
200 static void
201 lru_update(struct addrtree *tree, struct addrnode *node)
202 {
203 	if (tree->root == node) return;
204 	lru_pop(tree, node);
205 	lru_push(tree, node);
206 }
207 
208 /**
209  * Purge a node from the tree. Node and parentedge are cleaned and
210  * free'd.
211  * @param tree: Tree the node lives in.
212  * @param node: Node to be freed
213  */
214 static void
215 purge_node(struct addrtree *tree, struct addrnode *node)
216 {
217 	struct addredge *parent_edge, *child_edge = NULL;
218 	int index;
219 	int keep = node->edge[0] && node->edge[1];
220 
221 	clean_node(tree, node);
222 	parent_edge = node->parent_edge;
223 	if (keep || !parent_edge) return;
224 	tree->node_count--;
225 	index = parent_edge->parent_index;
226 	child_edge = node->edge[!node->edge[0]];
227 	if (child_edge) {
228 		child_edge->parent_node  = parent_edge->parent_node;
229 		child_edge->parent_index = index;
230 	}
231 	parent_edge->parent_node->edge[index] = child_edge;
232 	tree->size_bytes -= node_size(tree, node);
233 	free(parent_edge->str);
234 	free(parent_edge);
235 	lru_pop(tree, node);
236 	free(node);
237 }
238 
239 /**
240  * If a limit is set remove old nodes while above that limit.
241  * @param tree: Tree to be cleaned up.
242  */
243 static void
244 lru_cleanup(struct addrtree *tree)
245 {
246 	struct addrnode *n, *p;
247 	int children;
248 	if (tree->max_node_count == 0) return;
249 	while (tree->node_count > tree->max_node_count) {
250 		n = tree->first;
251 		if (!n) break;
252 		children = (n->edge[0] != NULL) + (n->edge[1] != NULL);
253 		/** Don't remove this node, it is either the root or we can't
254 		 * do without it because it has 2 children */
255 		if (children == 2 || !n->parent_edge) {
256 			lru_update(tree, n);
257 			continue;
258 		}
259 		p = n->parent_edge->parent_node;
260 		purge_node(tree, n);
261 		/** Since we removed n, n's parent p is eligible for deletion
262 		 * if it is not the root node, caries no data and has only 1
263 		 * child */
264 		children = (p->edge[0] != NULL) + (p->edge[1] != NULL);
265 		if (!p->elem && children == 1 && p->parent_edge) {
266 			purge_node(tree, p);
267 		}
268 	}
269 }
270 
271 inline size_t
272 addrtree_size(const struct addrtree *tree)
273 {
274 	return tree?tree->size_bytes:0;
275 }
276 
277 void addrtree_delete(struct addrtree *tree)
278 {
279 	struct addrnode *n;
280 	if (!tree) return;
281 	clean_node(tree, tree->root);
282 	free(tree->root);
283 	tree->size_bytes -= sizeof(struct addrnode);
284 	while ((n = tree->first)) {
285 		tree->first = n->next;
286 		clean_node(tree, n);
287 		tree->size_bytes -= node_size(tree, n);
288 		free(n->parent_edge->str);
289 		free(n->parent_edge);
290 		free(n);
291 	}
292 	log_assert(sizeof *tree == addrtree_size(tree));
293 	free(tree);
294 }
295 
296 /**
297  * Get N'th bit from address
298  * @param addr: address to inspect
299  * @param addrlen: length of addr in bits
300  * @param n: index of bit to test. Must be in range [0, addrlen)
301  * @return 0 or 1
302  */
303 static int
304 getbit(const addrkey_t *addr, addrlen_t addrlen, addrlen_t n)
305 {
306 	log_assert(addrlen > n);
307 	(void)addrlen;
308 	return (int)(addr[n/KEYWIDTH]>>((KEYWIDTH-1)-(n%KEYWIDTH))) & 1;
309 }
310 
311 /**
312  * Test for equality on N'th bit.
313  * @return 0 for equal, 1 otherwise
314  */
315 static inline int
316 cmpbit(const addrkey_t *key1, const addrkey_t *key2, addrlen_t n)
317 {
318 	addrkey_t c = key1[n/KEYWIDTH] ^ key2[n/KEYWIDTH];
319 	return (int)(c >> ((KEYWIDTH-1)-(n%KEYWIDTH))) & 1;
320 }
321 
322 /**
323  * Common number of bits in prefix.
324  * @param s1: first prefix.
325  * @param l1: length of s1 in bits.
326  * @param s2: second prefix.
327  * @param l2: length of s2 in bits.
328  * @param skip: nr of bits already checked.
329  * @return common number of bits.
330  */
331 static addrlen_t
332 bits_common(const addrkey_t *s1, addrlen_t l1,
333 	const addrkey_t *s2, addrlen_t l2, addrlen_t skip)
334 {
335 	addrlen_t len, i;
336 	len = (l1 > l2) ? l2 : l1;
337 	log_assert(skip < len);
338 	for (i = skip; i < len; i++) {
339 		if (cmpbit(s1, s2, i)) return i;
340 	}
341 	return len;
342 }
343 
344 /**
345  * Tests if s1 is a substring of s2
346  * @param s1: first prefix.
347  * @param l1: length of s1 in bits.
348  * @param s2: second prefix.
349  * @param l2: length of s2 in bits.
350  * @param skip: nr of bits already checked.
351  * @return 1 for substring, 0 otherwise
352  */
353 static int
354 issub(const addrkey_t *s1, addrlen_t l1,
355 	const addrkey_t *s2, addrlen_t l2,  addrlen_t skip)
356 {
357 	return bits_common(s1, l1, s2, l2, skip) == l1;
358 }
359 
360 void
361 addrtree_insert(struct addrtree *tree, const addrkey_t *addr,
362 	addrlen_t sourcemask, addrlen_t scope, void *elem, time_t ttl,
363 	time_t now, int only_match_scope_zero)
364 {
365 	struct addrnode *newnode, *node;
366 	struct addredge *edge;
367 	int index;
368 	addrlen_t common, depth;
369 
370 	node = tree->root;
371 	log_assert(node != NULL);
372 
373 	/* Protect our cache against too much fine-grained data */
374 	if (tree->max_depth < scope) scope = tree->max_depth;
375 	/* Server answer was less specific than question */
376 	if (scope < sourcemask) sourcemask = scope;
377 
378 	depth = 0;
379 	while (1) {
380 		log_assert(depth <= sourcemask);
381 		/* Case 1: update existing node */
382 		if (depth == sourcemask) {
383 			/* update this node's scope and data */
384 			clean_node(tree, node);
385 			node->ttl = ttl;
386 			node->only_match_scope_zero = only_match_scope_zero;
387 			node->elem = elem;
388 			node->scope = scope;
389 			tree->size_bytes += tree->sizefunc(elem);
390 			return;
391 		}
392 		index = getbit(addr, sourcemask, depth);
393 		/* Get an edge to an unexpired node */
394 		edge = node->edge[index];
395 		while (edge) {
396 			/* Purge all expired nodes on path */
397 			if (!edge->node->elem || edge->node->ttl >= now)
398 				break;
399 			purge_node(tree, edge->node);
400 			edge = node->edge[index];
401 		}
402 		/* Case 2: New leafnode */
403 		if (!edge) {
404 			newnode = node_create(tree, elem, scope, ttl);
405 			if (!newnode) return;
406 			if (!edge_create(newnode, addr, sourcemask, node,
407 				index)) {
408 				clean_node(tree, newnode);
409 				tree->node_count--;
410 				free(newnode);
411 				return;
412 			}
413 			tree->size_bytes += node_size(tree, newnode);
414 			lru_push(tree, newnode);
415 			lru_cleanup(tree);
416 			return;
417 		}
418 		/* Case 3: Traverse edge */
419 		common = bits_common(edge->str, edge->len, addr, sourcemask,
420 			depth);
421 		if (common == edge->len) {
422 			/* We update the scope of intermediate nodes. Apparently
423 			 * the * authority changed its mind. If we would not do
424 			 * this we might not be able to reach our new node. */
425 			node->scope = scope;
426 			depth = edge->len;
427 			node = edge->node;
428 			continue;
429 		}
430 		/* Case 4: split. */
431 		if (!(newnode = node_create(tree, NULL, 0, 0)))
432 			return;
433 		node->edge[index] = NULL;
434 		if (!edge_create(newnode, addr, common, node, index)) {
435 			node->edge[index] = edge;
436 			clean_node(tree, newnode);
437 			tree->node_count--;
438 			free(newnode);
439 			return;
440 		}
441 		lru_push(tree, newnode);
442 		/* connect existing child to our new node */
443 		index = getbit(edge->str, edge->len, common);
444 		newnode->edge[index] = edge;
445 		edge->parent_node = newnode;
446 		edge->parent_index = (int)index;
447 
448 		if (common == sourcemask) {
449 			/* Data is stored in the node */
450 			newnode->elem = elem;
451 			newnode->scope = scope;
452 			newnode->ttl = ttl;
453 			newnode->only_match_scope_zero = only_match_scope_zero;
454 		}
455 
456 		tree->size_bytes += node_size(tree, newnode);
457 
458 		if (common != sourcemask) {
459 			/* Data is stored in other leafnode */
460 			node = newnode;
461 			newnode = node_create(tree, elem, scope, ttl);
462 			if (!edge_create(newnode, addr, sourcemask, node,
463 				index^1)) {
464 				clean_node(tree, newnode);
465 				tree->node_count--;
466 				free(newnode);
467 				return;
468 			}
469 			tree->size_bytes += node_size(tree, newnode);
470 			lru_push(tree, newnode);
471 		}
472 		lru_cleanup(tree);
473 		return;
474 	}
475 }
476 
477 struct addrnode *
478 addrtree_find(struct addrtree *tree, const addrkey_t *addr,
479 	addrlen_t sourcemask, time_t now)
480 {
481 	struct addrnode *node = tree->root;
482 	struct addredge *edge = NULL;
483 	addrlen_t depth = 0;
484 
485 	log_assert(node != NULL);
486 	while (1) {
487 		/* Current node more specific then question. */
488 		log_assert(depth <= sourcemask);
489 		/* does this node have data? if yes, see if we have a match */
490 		if (node->elem && node->ttl >= now &&
491 			!(sourcemask != 0 && node->only_match_scope_zero)) {
492 			/* saved at wrong depth */;
493 			log_assert(node->scope >= depth);
494 			if (depth == node->scope ||
495 				(node->scope > sourcemask &&
496 				 depth == sourcemask)) {
497 				/* Authority indicates it does not have a more
498 				 * precise answer or we cannot ask a more
499 				 * specific question. */
500 				lru_update(tree, node);
501 				return node;
502 			}
503 		}
504 		/* This is our final depth, but we haven't found an answer. */
505 		if (depth == sourcemask)
506 			return NULL;
507 		/* Find an edge to traverse */
508 		edge = node->edge[getbit(addr, sourcemask, depth)];
509 		if (!edge || !edge->node)
510 			return NULL;
511 		if (edge->len > sourcemask )
512 			return NULL;
513 		if (!issub(edge->str, edge->len, addr, sourcemask, depth))
514 			return NULL;
515 		log_assert(depth < edge->len);
516 		depth = edge->len;
517 		node = edge->node;
518 	}
519 }
520 
521 /** Wrappers for static functions to unit test */
522 int unittest_wrapper_addrtree_cmpbit(const addrkey_t *key1,
523 	const addrkey_t *key2, addrlen_t n) {
524 	return cmpbit(key1, key2, n);
525 }
526 addrlen_t unittest_wrapper_addrtree_bits_common(const addrkey_t *s1,
527 	addrlen_t l1, const addrkey_t *s2, addrlen_t l2, addrlen_t skip) {
528 	return bits_common(s1, l1, s2, l2, skip);
529 }
530 int unittest_wrapper_addrtree_getbit(const addrkey_t *addr,
531 	addrlen_t addrlen, addrlen_t n) {
532 	return getbit(addr, addrlen, n);
533 }
534 int unittest_wrapper_addrtree_issub(const addrkey_t *s1, addrlen_t l1,
535 	const addrkey_t *s2, addrlen_t l2,  addrlen_t skip) {
536 	return issub(s1, l1, s2, l2, skip);
537 }
538