| blob | 1ff446d0fa8bca4121b1436b778b830202cd9b09 |
1 /*
2 * This program is free software; you can redistribute it and/or
3 * modify it under the terms of the GNU General Public License
4 * as published by the Free Software Foundation; either version
5 * 2 of the License, or (at your option) any later version.
6 *
7 * Robert Olsson <robert.olsson@its.uu.se> Uppsala Universitet
8 * & Swedish University of Agricultural Sciences.
9 *
10 * Jens Laas <jens.laas@data.slu.se> Swedish University of
11 * Agricultural Sciences.
12 *
13 * Hans Liss <hans.liss@its.uu.se> Uppsala Universitet
14 *
15 * This work is based on the LPC-trie which is originally descibed in:
16 *
17 * An experimental study of compression methods for dynamic tries
18 * Stefan Nilsson and Matti Tikkanen. Algorithmica, 33(1):19-33, 2002.
19 * http://www.nada.kth.se/~snilsson/public/papers/dyntrie2/
20 *
21 *
22 * IP-address lookup using LC-tries. Stefan Nilsson and Gunnar Karlsson
23 * IEEE Journal on Selected Areas in Communications, 17(6):1083-1092, June 1999
24 *
25 * Version: $Id: fib_trie.c,v 1.3 2005/06/08 14:20:01 robert Exp $
26 *
27 *
28 * Code from fib_hash has been reused which includes the following header:
29 *
30 *
31 * INET An implementation of the TCP/IP protocol suite for the LINUX
32 * operating system. INET is implemented using the BSD Socket
33 * interface as the means of communication with the user level.
34 *
35 * IPv4 FIB: lookup engine and maintenance routines.
36 *
37 *
38 * Authors: Alexey Kuznetsov, <kuznet@ms2.inr.ac.ru>
39 *
40 * This program is free software; you can redistribute it and/or
41 * modify it under the terms of the GNU General Public License
42 * as published by the Free Software Foundation; either version
43 * 2 of the License, or (at your option) any later version.
44 *
45 * Substantial contributions to this work comes from:
46 *
47 * David S. Miller, <davem@davemloft.net>
48 * Stephen Hemminger <shemminger@osdl.org>
49 * Paul E. McKenney <paulmck@us.ibm.com>
50 * Patrick McHardy <kaber@trash.net>
51 */
55 #include <asm/uaccess.h>
56 #include <asm/system.h>
57 #include <linux/bitops.h>
58 #include <linux/types.h>
59 #include <linux/kernel.h>
60 #include <linux/mm.h>
61 #include <linux/string.h>
62 #include <linux/socket.h>
63 #include <linux/sockios.h>
64 #include <linux/errno.h>
65 #include <linux/in.h>
66 #include <linux/inet.h>
67 #include <linux/inetdevice.h>
68 #include <linux/netdevice.h>
69 #include <linux/if_arp.h>
70 #include <linux/proc_fs.h>
71 #include <linux/rcupdate.h>
72 #include <linux/skbuff.h>
73 #include <linux/netlink.h>
74 #include <linux/init.h>
75 #include <linux/list.h>
76 #include <net/net_namespace.h>
77 #include <net/ip.h>
78 #include <net/protocol.h>
79 #include <net/route.h>
80 #include <net/tcp.h>
81 #include <net/sock.h>
82 #include <net/ip_fib.h>
85 #define MAX_STAT_DEPTH 32
87 #define KEYLENGTH (8*sizeof(t_key))
91 #define T_TNODE 0
92 #define T_LEAF 1
93 #define NODE_TYPE_MASK 0x1UL
94 #define NODE_TYPE(node) ((node)->parent & NODE_TYPE_MASK)
96 #define IS_TNODE(n) (!(n->parent & T_LEAF))
97 #define IS_LEAF(n) (n->parent & T_LEAF)
101 t_key key;
102 };
106 t_key key;
109 };
116 };
120 t_key key;
127 };
129 #ifdef CONFIG_IP_FIB_TRIE_STATS
137 };
138 #endif
148 };
152 #ifdef CONFIG_IP_FIB_TRIE_STATS
154 #endif
155 };
169 {
171 }
174 {
178 }
181 {
184 }
187 {
191 }
194 {
198 }
201 {
203 }
206 {
208 }
211 {
214 else
216 }
219 {
221 }
224 {
229 }
232 {
239 i++;
241 }
243 /*
244 To understand this stuff, an understanding of keys and all their bits is
245 necessary. Every node in the trie has a key associated with it, but not
246 all of the bits in that key are significant.
248 Consider a node 'n' and its parent 'tp'.
250 If n is a leaf, every bit in its key is significant. Its presence is
251 necessitated by path compression, since during a tree traversal (when
252 searching for a leaf - unless we are doing an insertion) we will completely
253 ignore all skipped bits we encounter. Thus we need to verify, at the end of
254 a potentially successful search, that we have indeed been walking the
255 correct key path.
257 Note that we can never "miss" the correct key in the tree if present by
258 following the wrong path. Path compression ensures that segments of the key
259 that are the same for all keys with a given prefix are skipped, but the
260 skipped part *is* identical for each node in the subtrie below the skipped
261 bit! trie_insert() in this implementation takes care of that - note the
262 call to tkey_sub_equals() in trie_insert().
264 if n is an internal node - a 'tnode' here, the various parts of its key
265 have many different meanings.
267 Example:
268 _________________________________________________________________
269 | i | i | i | i | i | i | i | N | N | N | S | S | S | S | S | C |
270 -----------------------------------------------------------------
271 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
273 _________________________________________________________________
274 | C | C | C | u | u | u | u | u | u | u | u | u | u | u | u | u |
275 -----------------------------------------------------------------
276 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31
278 tp->pos = 7
279 tp->bits = 3
280 n->pos = 15
281 n->bits = 4
283 First, let's just ignore the bits that come before the parent tp, that is
284 the bits from 0 to (tp->pos-1). They are *known* but at this point we do
285 not use them for anything.
287 The bits from (tp->pos) to (tp->pos + tp->bits - 1) - "N", above - are the
288 index into the parent's child array. That is, they will be used to find
289 'n' among tp's children.
291 The bits from (tp->pos + tp->bits) to (n->pos - 1) - "S" - are skipped bits
292 for the node n.
294 All the bits we have seen so far are significant to the node n. The rest
295 of the bits are really not needed or indeed known in n->key.
297 The bits from (n->pos) to (n->pos + n->bits - 1) - "C" - are the index into
298 n's child array, and will of course be different for each child.
301 The rest of the bits, from (n->pos + n->bits) onward, are completely unknown
302 at this point.
304 */
307 {
309 }
318 {
321 }
324 {
326 }
329 {
332 }
335 {
337 }
340 {
342 }
345 {
356 }
359 {
366 else
368 }
371 {
377 }
380 {
385 }
387 }
390 {
395 }
397 }
400 {
411 }
416 }
418 /*
419 * Check whether a tnode 'n' is "full", i.e. it is an internal node
420 * and no bits are skipped. See discussion in dyntree paper p. 6
421 */
424 {
429 }
433 {
435 }
437 /*
438 * Add a child at position i overwriting the old value.
439 * Update the value of full_children and empty_children.
440 */
444 {
450 /* update emptyChildren */
456 /* update fullChildren */
470 }
473 {
487 /* No children */
491 }
492 /* One child */
501 /* compress one level */
505 }
506 /*
507 * Double as long as the resulting node has a number of
508 * nonempty nodes that are above the threshold.
509 */
511 /*
512 * From "Implementing a dynamic compressed trie" by Stefan Nilsson of
513 * the Helsinki University of Technology and Matti Tikkanen of Nokia
514 * Telecommunications, page 6:
515 * "A node is doubled if the ratio of non-empty children to all
516 * children in the *doubled* node is at least 'high'."
517 *
518 * 'high' in this instance is the variable 'inflate_threshold'. It
519 * is expressed as a percentage, so we multiply it with
520 * tnode_child_length() and instead of multiplying by 2 (since the
521 * child array will be doubled by inflate()) and multiplying
522 * the left-hand side by 100 (to handle the percentage thing) we
523 * multiply the left-hand side by 50.
524 *
525 * The left-hand side may look a bit weird: tnode_child_length(tn)
526 * - tn->empty_children is of course the number of non-null children
527 * in the current node. tn->full_children is the number of "full"
528 * children, that is non-null tnodes with a skip value of 0.
529 * All of those will be doubled in the resulting inflated tnode, so
530 * we just count them one extra time here.
531 *
532 * A clearer way to write this would be:
533 *
534 * to_be_doubled = tn->full_children;
535 * not_to_be_doubled = tnode_child_length(tn) - tn->empty_children -
536 * tn->full_children;
537 *
538 * new_child_length = tnode_child_length(tn) * 2;
539 *
540 * new_fill_factor = 100 * (not_to_be_doubled + 2*to_be_doubled) /
541 * new_child_length;
542 * if (new_fill_factor >= inflate_threshold)
543 *
544 * ...and so on, tho it would mess up the while () loop.
545 *
546 * anyway,
547 * 100 * (not_to_be_doubled + 2*to_be_doubled) / new_child_length >=
548 * inflate_threshold
549 *
550 * avoid a division:
551 * 100 * (not_to_be_doubled + 2*to_be_doubled) >=
552 * inflate_threshold * new_child_length
553 *
554 * expand not_to_be_doubled and to_be_doubled, and shorten:
555 * 100 * (tnode_child_length(tn) - tn->empty_children +
556 * tn->full_children) >= inflate_threshold * new_child_length
557 *
558 * expand new_child_length:
559 * 100 * (tnode_child_length(tn) - tn->empty_children +
560 * tn->full_children) >=
561 * inflate_threshold * tnode_child_length(tn) * 2
562 *
563 * shorten again:
564 * 50 * (tn->full_children + tnode_child_length(tn) -
565 * tn->empty_children) >= inflate_threshold *
566 * tnode_child_length(tn)
567 *
568 */
572 /* Keep root node larger */
576 else
591 #ifdef CONFIG_IP_FIB_TRIE_STATS
593 #endif
595 }
596 }
603 else
607 }
611 /*
612 * Halve as long as the number of empty children in this
613 * node is above threshold.
614 */
617 /* Keep root node larger */
621 else
634 #ifdef CONFIG_IP_FIB_TRIE_STATS
636 #endif
638 }
639 }
646 else
650 }
652 /* Only one child remains */
661 /* compress one level */
666 }
669 }
672 {
684 /*
685 * Preallocate and store tnodes before the actual work so we
686 * don't get into an inconsistent state if memory allocation
687 * fails. In case of failure we return the oldnode and inflate
688 * of tnode is ignored.
689 */
713 }
717 }
718 }
726 /* An empty child */
730 /* A leaf or an internal node with skipped bits */
738 else
741 }
743 /* An internal node with two children */
752 }
754 /* An internal node with more than two children */
756 /* We will replace this node 'inode' with two new
757 * ones, 'left' and 'right', each with half of the
758 * original children. The two new nodes will have
759 * a position one bit further down the key and this
760 * means that the "significant" part of their keys
761 * (see the discussion near the top of this file)
762 * will differ by one bit, which will be "0" in
763 * left's key and "1" in right's key. Since we are
764 * moving the key position by one step, the bit that
765 * we are moving away from - the bit at position
766 * (inode->pos) - is the one that will differ between
767 * left and right. So... we synthesize that bit in the
768 * two new keys.
769 * The mask 'm' below will be a single "one" bit at
770 * the position (inode->pos)
771 */
773 /* Use the old key, but set the new significant
774 * bit to zero.
775 */
791 }
796 }
799 nomem:
800 {
811 }
812 }
815 {
828 /*
829 * Preallocate and store tnodes before the actual work so we
830 * don't get into an inconsistent state if memory allocation
831 * fails. In case of failure we return the oldnode and halve
832 * of tnode is ignored.
833 */
839 /* Two nonempty children */
849 }
851 }
859 /* At least one of the children is empty */
865 }
870 }
872 /* Two nonempty children */
878 }
881 nomem:
882 {
893 }
894 }
896 /* readside must use rcu_read_lock currently dump routines
897 via get_fa_head and dump */
900 {
910 }
913 {
920 }
923 {
935 }
938 else
940 }
941 }
943 /* rcu_read_lock needs to be hold by caller from readside */
947 {
968 }
969 /* Case we have found a leaf. Compare prefixes */
975 }
978 {
995 }
997 /* Handle last (top) tnode */
1002 }
1004 /* only used from updater-side */
1007 {
1015 t_key cindex;
1020 /* If we point to NULL, stop. Either the tree is empty and we should
1021 * just put a new leaf in if, or we have reached an empty child slot,
1022 * and we should just put our new leaf in that.
1023 * If we point to a T_TNODE, check if it matches our key. Note that
1024 * a T_TNODE might be skipping any number of bits - its 'pos' need
1025 * not be the parent's 'pos'+'bits'!
1026 *
1027 * If it does match the current key, get pos/bits from it, extract
1028 * the index from our key, push the T_TNODE and walk the tree.
1029 *
1030 * If it doesn't, we have to replace it with a new T_TNODE.
1031 *
1032 * If we point to a T_LEAF, it might or might not have the same key
1033 * as we do. If it does, just change the value, update the T_LEAF's
1034 * value, and return it.
1035 * If it doesn't, we need to replace it with a T_TNODE.
1036 */
1054 }
1056 /*
1057 * n ----> NULL, LEAF or TNODE
1058 *
1059 * tp is n's (parent) ----> NULL or TNODE
1060 */
1064 /* Case 1: n is a leaf. Compare prefixes */
1076 }
1088 }
1094 /* Case 2: n is NULL, and will just insert a new leaf */
1101 /* Case 3: n is a LEAF or a TNODE and the key doesn't match. */
1102 /*
1103 * Add a new tnode here
1104 * first tnode need some special handling
1105 */
1109 else
1118 }
1124 }
1139 }
1140 }
1147 /* Rebalance the trie */
1150 done:
1152 }
1154 /*
1155 * Caller must hold RTNL.
1156 */
1158 {
1187 }
1195 }
1197 /* Now fa, if non-NULL, points to the first fib alias
1198 * with the same keys [prefix,tos,priority], if such key already
1199 * exists or to the node before which we will insert new one.
1200 *
1201 * If fa is NULL, we will need to allocate a new one and
1202 * insert to the head of f.
1203 *
1204 * If f is NULL, no fib node matched the destination key
1205 * and we need to allocate a new one of those as well.
1206 */
1216 /* We have 2 goals:
1217 * 1. Find exact match for type, scope, fib_info to avoid
1218 * duplicate routes
1219 * 2. Find next 'fa' (or head), NLM_F_APPEND inserts before it
1220 */
1234 }
1235 }
1239 u8 state;
1246 }
1270 }
1271 /* Error if we find a perfect match which
1272 * uses the same scope, type, and nexthop
1273 * information.
1274 */
1280 }
1295 /*
1296 * Insert new entry to the list.
1297 */
1304 }
1305 }
1313 succeeded:
1316 out_free_new_fa:
1318 out:
1320 err:
1322 }
1324 /* should be called with rcu_read_lock */
1328 {
1344 #ifdef CONFIG_IP_FIB_TRIE_STATS
1347 else
1349 #endif
1352 }
1355 }
1359 {
1379 #ifdef CONFIG_IP_FIB_TRIE_STATS
1381 #endif
1383 /* Just a leaf? */
1390 }
1406 #ifdef CONFIG_IP_FIB_TRIE_STATS
1408 #endif
1410 }
1419 }
1423 /*
1424 * It's a tnode, and we can do some extra checks here if we
1425 * like, to avoid descending into a dead-end branch.
1426 * This tnode is in the parent's child array at index
1427 * key[p_pos..p_pos+p_bits] but potentially with some bits
1428 * chopped off, so in reality the index may be just a
1429 * subprefix, padded with zero at the end.
1430 * We can also take a look at any skipped bits in this
1431 * tnode - everything up to p_pos is supposed to be ok,
1432 * and the non-chopped bits of the index (se previous
1433 * paragraph) are also guaranteed ok, but the rest is
1434 * considered unknown.
1435 *
1436 * The skipped bits are key[pos+bits..cn->pos].
1437 */
1439 /* If current_prefix_length < pos+bits, we are already doing
1440 * actual prefix matching, which means everything from
1441 * pos+(bits-chopped_off) onward must be zero along some
1442 * branch of this subtree - otherwise there is *no* valid
1443 * prefix present. Here we can only check the skipped
1444 * bits. Remember, since we have already indexed into the
1445 * parent's child array, we know that the bits we chopped of
1446 * *are* zero.
1447 */
1449 /* NOTA BENE: Checking only skipped bits
1450 for the new node here */
1457 }
1459 /*
1460 * If chopped_off=0, the index is fully validated and we
1461 * only need to look at the skipped bits for this, the new,
1462 * tnode. What we actually want to do is to find out if
1463 * these skipped bits match our key perfectly, or if we will
1464 * have to count on finding a matching prefix further down,
1465 * because if we do, we would like to have some way of
1466 * verifying the existence of such a prefix at this point.
1467 */
1469 /* The only thing we can do at this point is to verify that
1470 * any such matching prefix can indeed be a prefix to our
1471 * key, and if the bits in the node we are inspecting that
1472 * do not match our key are not ZERO, this cannot be true.
1473 * Thus, find out where there is a mismatch (before cn->pos)
1474 * and verify that all the mismatching bits are zero in the
1475 * new tnode's key.
1476 */
1478 /*
1479 * Note: We aren't very concerned about the piece of
1480 * the key that precede pn->pos+pn->bits, since these
1481 * have already been checked. The bits after cn->pos
1482 * aren't checked since these are by definition
1483 * "unknown" at this point. Thus, what we want to see
1484 * is if we are about to enter the "prefix matching"
1485 * state, and in that case verify that the skipped
1486 * bits that will prevail throughout this subtree are
1487 * zero, as they have to be if we are to find a
1488 * matching prefix.
1489 */
1496 /*
1497 * In short: If skipped bits in this node do not match
1498 * the search key, enter the "prefix matching"
1499 * state.directly.
1500 */
1503 mp++;
1505 }
1513 }
1519 backtrace:
1520 chopped_off++;
1522 /* As zero don't change the child key (cindex) */
1525 chopped_off++;
1527 /* Decrease current_... with bits chopped off */
1532 /*
1533 * Either we do the actual chop off according or if we have
1534 * chopped off all bits in this tnode walk up to our parent.
1535 */
1544 /* Get Child's index */
1549 #ifdef CONFIG_IP_FIB_TRIE_STATS
1551 #endif
1553 }
1554 }
1555 failed:
1557 found:
1560 }
1562 /*
1563 * Remove the leaf and return parent.
1564 */
1566 {
1579 }
1581 /*
1582 * Caller must hold RTNL.
1583 */
1585 {
1634 }
1635 }
1652 }
1663 }
1666 {
1677 found++;
1678 }
1679 }
1681 }
1684 {
1696 }
1697 }
1699 }
1701 /*
1702 * Scan for the next right leaf starting at node p->child[idx]
1703 * Since we have back pointer, no recursion necessary.
1704 */
1706 {
1708 t_key idx;
1712 else
1723 }
1725 /* Rescan start scanning in new node */
1728 }
1730 /* Node empty, walk back up to parent */
1735 }
1738 {
1748 }
1751 {
1759 }
1762 {
1769 }
1772 /*
1773 * Caller must hold RTNL.
1774 */
1776 {
1787 }
1794 }
1799 {
1847 }
1849 order++;
1850 }
1854 }
1861 }
1865 out:
1867 }
1872 {
1880 /* rcu_read_lock is hold by caller */
1884 i++;
1886 }
1890 RTM_NEWROUTE,
1894 xkey,
1895 plen,
1900 }
1901 i++;
1902 }
1905 }
1909 {
1917 /* rcu_read_lock is hold by caller */
1920 i++;
1922 }
1933 }
1934 i++;
1935 }
1939 }
1943 {
1950 /* Dump starting at last key.
1951 * Note: 0.0.0.0/0 (ie default) is first key.
1952 */
1956 /* Normally, continue from last key, but if that is missing
1957 * fallback to using slow rescan
1958 */
1962 }
1970 }
1976 }
1981 }
1984 {
1993 }
1996 /* Fix more generic FIB names for init later */
1998 {
2003 GFP_KERNEL);
2023 }
2025 #ifdef CONFIG_PROC_FS
2026 /* Depth first Trie walk iterator */
2034 };
2037 {
2042 /* A single entry routing table */
2048 rescan:
2057 /* push down one level */
2061 }
2063 }
2066 }
2068 /* Current node exhausted, pop back up */
2075 }
2077 /* got root? */
2079 }
2083 {
2105 }
2107 }
2109 }
2112 {
2144 }
2145 }
2147 }
2149 /*
2150 * This outputs /proc/net/fib_triestats
2151 */
2153 {
2158 else
2176 max--;
2183 }
2190 }
2192 #ifdef CONFIG_IP_FIB_TRIE_STATS
2195 {
2206 }
2211 {
2217 #ifdef CONFIG_IP_FIB_TRIE_STATS
2219 #endif
2220 }
2223 {
2228 "Basic info: size of leaf:"
2241 }
2244 {
2255 }
2257 }
2260 {
2264 }
2272 };
2275 loff_t pos)
2276 {
2284 }
2290 }
2292 }
2296 {
2304 }
2309 }
2314 }
2317 {
2330 /* continue scan in next trie */
2335 }
2339 {
2341 }
2344 {
2346 }
2349 {
2359 }
2360 }
2375 };
2378 {
2383 }
2385 /* Pretty print the trie */
2387 {
2397 else
2399 }
2434 }
2435 }
2436 }
2439 }
2446 };
2449 {
2452 }
2460 };
2465 loff_t pos;
2466 t_key key;
2467 };
2470 {
2474 /* use cache location of last found key */
2480 }
2485 }
2489 else
2493 }
2497 {
2509 else
2511 }
2514 {
2525 }
2529 else
2532 }
2536 {
2538 }
2541 {
2544 };
2553 }
2555 /*
2556 * This outputs /proc/net/route.
2557 * The format of the file is not supposed to be changed
2558 * and needs to be same as fib_hash output to avoid breaking
2559 * legacy utilities
2560 */
2562 {
2572 }
2594 prefix,
2597 mask,
2602 else
2609 }
2610 }
2613 }
2620 };
2623 {
2626 }
2634 };
2637 {
2650 out3:
2652 out2:
2654 out1:
2656 }
2659 {
2663 }