bpf: indent one space for better visibility
[netsniff-ng.git] / src / patricia.c
blobc56cea71f1671a01e6bfbc291c77e506d5e474f2
1 /*
2 * netsniff-ng - the packet sniffing beast
3 * By Daniel Borkmann <daniel@netsniff-ng.org>
4 * Copyright 2011 Daniel Borkmann, rewritten
5 * Copyright 1991-2007 Kawahara Lab., Kyoto University
6 * Copyright 2000-2005 Shikano Lab., Nara Institute of Science and Technology
7 * Copyright 2005-2007 Julius project team, Nagoya Institute of Technology
8 * All rights reserved
9 * Subject to the GPL, version 2.
12 #include <stdio.h>
13 #include <string.h>
14 #include <errno.h>
16 #include "patricia.h"
17 #include "built_in.h"
18 #include "xmalloc.h"
20 static unsigned char mbit[] = {0x80, 0x40, 0x20, 0x10, 0x08, 0x04, 0x02, 0x01};
22 static inline int testbit(char *str, size_t slen, int bitplace)
24 int maskptr;
25 if ((maskptr = bitplace >> 3) > slen)
26 return 0;
27 return (str[maskptr] & mbit[bitplace & 7]);
30 static inline int testbit_max(char *str, int bitplace, int maxbitplace)
32 if (bitplace >= maxbitplace)
33 return 0;
34 return (str[bitplace >> 3] & mbit[bitplace & 7]);
37 static int where_the_bit_differ(char *str1, size_t l1, char *str2, size_t l2)
39 int p = 0, bitloc;
40 while (str1[p] == str2[p])
41 p++;
42 bitloc = p * 8;
43 while (testbit(str1, l1, bitloc) ==
44 testbit(str2, l2, bitloc))
45 bitloc++;
46 return bitloc;
49 static struct patricia_node *new_node(void)
51 struct patricia_node *n = xzmalloc(sizeof(*n));
52 n->l = n->r = NULL;
53 return n;
56 static void free_node(struct patricia_node *n)
58 if (n->key)
59 xfree(n->key);
60 if (n->addr)
61 xfree(n->addr);
62 xfree(n);
65 void ptree_display(struct patricia_node *node, int level)
67 int i;
68 for (i = 0; i < level; ++i)
69 printf("-");
70 if (node->l == NULL && node->r == NULL)
71 printf("leaf: (%s -> %d)\n", (char *) node->key, node->value.data);
72 else {
73 printf("thres: %d\n", node->value.thres_bit);
74 if (node->l != NULL)
75 ptree_display(node->l, level + 1);
76 if (node->r != NULL)
77 ptree_display(node->r, level + 1);
81 void ptree_get_key(int data, struct patricia_node *node,
82 struct patricia_node **wanted)
84 if (!node)
85 return;
86 if (node->l == NULL && node->r == NULL) {
87 if (node->value.data == data)
88 (*wanted) = node;
89 } else {
90 if (node->l != NULL)
91 ptree_get_key(data, node->l, wanted);
92 if (node->r != NULL)
93 ptree_get_key(data, node->r, wanted);
97 void ptree_get_key_addr(struct sockaddr_storage *addr, size_t alen,
98 struct patricia_node *node, struct patricia_node **wanted)
100 if (!node)
101 return;
102 if (node->l == NULL && node->r == NULL) {
103 if (!memcmp(node->addr, addr, node->alen))
104 (*wanted) = node;
105 } else {
106 if (node->l != NULL)
107 ptree_get_key_addr(addr, alen, node->l, wanted);
108 if (node->r != NULL)
109 ptree_get_key_addr(addr, alen, node->r, wanted);
113 static int ptree_search_data_r(struct patricia_node *node, char *str,
114 size_t slen, struct sockaddr_storage *addr,
115 size_t *alen, int maxbitplace)
117 if (node->l == NULL && node->r == NULL) {
118 if (node->addr && addr)
119 memcpy(addr, node->addr, node->alen);
120 (*alen) = node->alen;
121 return node->value.data;
123 if (testbit_max(str, node->value.thres_bit, maxbitplace) != 0)
124 return ptree_search_data_r(node->r, str, slen, addr,
125 alen, maxbitplace);
126 else
127 return ptree_search_data_r(node->l, str, slen, addr,
128 alen, maxbitplace);
131 static int *ptree_search_data_r_p(struct patricia_node *node, char *str,
132 size_t slen, int maxbitplace)
134 if (node->l == NULL && node->r == NULL)
135 return &(node->value.data);
136 if (testbit_max(str, node->value.thres_bit, maxbitplace) != 0)
137 return ptree_search_data_r_p(node->r, str, slen, maxbitplace);
138 else
139 return ptree_search_data_r_p(node->l, str, slen, maxbitplace);
142 static int ptree_search_data_r_x(struct patricia_node *node, char *str,
143 size_t slen, struct sockaddr_storage *addr,
144 size_t *alen, int maxbitplace)
146 if (node->l == NULL && node->r == NULL) {
147 if (node->klen == slen && !memcmp(str, node->key, node->klen)) {
148 if (node->addr && addr)
149 memcpy(addr, node->addr, node->alen);
150 (*alen) = node->alen;
151 return node->value.data;
152 } else
153 return -ENOENT;
155 if (testbit_max(str, node->value.thres_bit, maxbitplace) != 0)
156 return ptree_search_data_r_x(node->r, str, slen, addr,
157 alen, maxbitplace);
158 else
159 return ptree_search_data_r_x(node->l, str, slen, addr,
160 alen, maxbitplace);
163 int ptree_search_data_nearest(void *str, size_t sstr, struct sockaddr_storage *addr,
164 size_t *alen, struct patricia_node *root)
166 if (!root)
167 return -ENOENT;
168 return ptree_search_data_r(root, str, sstr, addr, alen, sstr * 8);
171 static int *ptree_search_data_nearest_ptr(char *str, size_t sstr,
172 struct patricia_node *root)
174 return ptree_search_data_r_p(root, str, sstr, sstr * 8);
177 int ptree_search_data_exact(void *str, size_t sstr, struct sockaddr_storage *addr,
178 size_t *alen, struct patricia_node *root)
180 if (!root)
181 return -ENOENT;
182 return ptree_search_data_r_x(root, str, sstr, addr, alen, sstr * 8);
185 static struct patricia_node *ptree_make_root_node(char *str, size_t sstr,
186 int data, struct sockaddr_storage *addr,
187 size_t alen)
189 struct patricia_node *n = new_node();
190 n->value.data = data;
191 n->key = xmemdupz(str, sstr);
192 n->klen = sstr;
193 if (addr)
194 n->addr = xmemdupz(addr, alen);
195 else
196 n->addr = NULL;
197 n->alen = alen;
198 return n;
201 static void ptree_add_entry_at(char *str, size_t slen, int bitloc, int data,
202 struct sockaddr_storage *addr, size_t alen,
203 struct patricia_node **parentlink)
205 struct patricia_node *node = (*parentlink);
206 if (node->value.thres_bit > bitloc ||
207 (node->l == NULL && node->r == NULL)) {
208 struct patricia_node *newleaf, *newbranch;
210 newleaf = new_node();
211 newleaf->value.data = data;
212 newleaf->key = xmemdupz(str, slen);
213 newleaf->klen = slen;
214 if (addr)
215 newleaf->addr = xmemdupz(addr, alen);
216 else
217 newleaf->addr = NULL;
218 newleaf->alen = alen;
220 newbranch = new_node();
221 newbranch->value.thres_bit = bitloc;
222 (*parentlink) = newbranch;
223 if (testbit(str, slen, bitloc) ==0) {
224 newbranch->l = newleaf;
225 newbranch->r = node;
226 } else {
227 newbranch->l = node;
228 newbranch->r = newleaf;
230 return;
231 } else {
232 if (testbit(str, slen, node->value.thres_bit) != 0)
233 ptree_add_entry_at(str, slen, bitloc, data,
234 addr, alen, &(node->r));
235 else
236 ptree_add_entry_at(str, slen, bitloc, data,
237 addr, alen, &(node->l));
241 int ptree_add_entry(void *str, size_t sstr, int data, struct sockaddr_storage *addr,
242 size_t alen, struct patricia_node **root)
244 int *ptr, bitloc, malicious = 0;
245 struct patricia_node *n;
247 if (!(*root))
248 (*root) = ptree_make_root_node(str, sstr, data, addr, alen);
249 else {
250 ptr = ptree_search_data_nearest_ptr(str, sstr, (*root));
251 n = container_of(ptr, struct patricia_node, value.data);
252 if (n->klen == sstr && !memcmp(str, n->key, n->klen)) {
253 /* Make sure if entry exists, that we also have the
254 * same data, otherwise, we drop the packet */
255 if (n->value.data != data)
256 malicious = 1;
257 else if (n->alen != alen)
258 malicious = 1;
259 else if ((n->addr && !addr) || (!n->addr && addr))
260 malicious = 1;
261 else if (n->alen == alen && n->addr && addr) {
262 if (memcmp(n->addr, addr, alen))
263 malicious = 1;
265 return malicious;
267 bitloc = where_the_bit_differ(str, sstr, n->key, n->klen);
268 ptree_add_entry_at(str, sstr, bitloc, data, addr, alen, root);
271 return malicious;
274 static void ptree_remove_entry_r(struct patricia_node *now,
275 struct patricia_node *up,
276 struct patricia_node *up2,
277 char *str, size_t slen, int maxbitplace,
278 struct patricia_node **root)
280 struct patricia_node *b;
282 if (now->l == NULL && now->r == NULL) {
283 if (now->klen != slen)
284 return;
285 if (memcmp(now->key, str, slen))
286 return;
287 if (up == NULL) {
288 *root = NULL;
289 free_node(now);
290 return;
292 b = (up->r == now) ? up->l : up->r;
293 if (up2 == NULL) {
294 *root = b;
295 free_node(now);
296 free_node(up);
297 return;
299 if (up2->l == up)
300 up2->l = b;
301 else
302 up2->r = b;
303 free_node(now);
304 free_node(up);
305 return;
306 } else {
307 if (testbit_max(str, now->value.thres_bit, maxbitplace) != 0)
308 ptree_remove_entry_r(now->r, now, up, str, slen,
309 maxbitplace, root);
310 else
311 ptree_remove_entry_r(now->l, now, up, str, slen,
312 maxbitplace, root);
316 void ptree_del_entry(void *str, size_t sstr, struct patricia_node **root)
318 if (!(*root))
319 return;
320 ptree_remove_entry_r(*root, NULL, NULL, str, sstr, sstr * 8, root);
323 void ptree_free(struct patricia_node *node)
325 if (!node)
326 return;
327 if (node->l)
328 ptree_free(node->l);
329 if (node->r)
330 ptree_free(node->r);
331 free_node(node);