net/npf/lpm.c

1.3.2.2  pgoyette /*-
1.3.2.2  pgoyette  * Copyright (c) 2016 Mindaugas Rasiukevicius <rmind at noxt eu>
1.3.2.2  pgoyette  * All rights reserved.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * Redistribution and use in source and binary forms, with or without
1.3.2.2  pgoyette  * modification, are permitted provided that the following conditions
1.3.2.2  pgoyette  * are met:
1.3.2.2  pgoyette  * 1. Redistributions of source code must retain the above copyright
1.3.2.2  pgoyette  *    notice, this list of conditions and the following disclaimer.
1.3.2.2  pgoyette  * 2. Redistributions in binary form must reproduce the above copyright
1.3.2.2  pgoyette  *    notice, this list of conditions and the following disclaimer in the
1.3.2.2  pgoyette  *    documentation and/or other materials provided with the distribution.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
1.3.2.2  pgoyette  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.3.2.2  pgoyette  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.3.2.2  pgoyette  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
1.3.2.2  pgoyette  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.3.2.2  pgoyette  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.3.2.2  pgoyette  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.3.2.2  pgoyette  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.3.2.2  pgoyette  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.3.2.2  pgoyette  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.3.2.2  pgoyette  * SUCH DAMAGE.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * TODO: Simple linear scan for now (works just well with a few prefixes).
1.3.2.2  pgoyette  * TBD on a better algorithm.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette
1.3.2.2  pgoyette #if defined(_KERNEL)
1.3.2.2  pgoyette #include <sys/cdefs.h>
1.3.2.2  pgoyette __KERNEL_RCSID(0, "$NetBSD: lpm.c,v 1.3.2.2 2017/01/07 08:56:50 pgoyette Exp $");
1.3.2.2  pgoyette
1.3.2.2  pgoyette #include <sys/param.h>
1.3.2.2  pgoyette #include <sys/types.h>
1.3.2.2  pgoyette #include <sys/malloc.h>
1.3.2.2  pgoyette #include <sys/kmem.h>
1.3.2.2  pgoyette #else
1.3.2.2  pgoyette #include <sys/socket.h>
1.3.2.2  pgoyette #include <arpa/inet.h>
1.3.2.2  pgoyette
1.3.2.2  pgoyette #include <stdio.h>
1.3.2.2  pgoyette #include <stdlib.h>
1.3.2.2  pgoyette #include <stdbool.h>
1.3.2.2  pgoyette #include <stddef.h>
1.3.2.2  pgoyette #include <string.h>
1.3.2.2  pgoyette #include <strings.h>
1.3.2.2  pgoyette #include <errno.h>
1.3.2.2  pgoyette #include <assert.h>
1.3.2.2  pgoyette #define kmem_alloc(a, b) malloc(a)
1.3.2.2  pgoyette #define kmem_free(a, b) free(a)
1.3.2.2  pgoyette #define kmem_zalloc(a, b) calloc(a, 1)
1.3.2.2  pgoyette #endif
1.3.2.2  pgoyette
1.3.2.2  pgoyette #include "lpm.h"
1.3.2.2  pgoyette
1.3.2.2  pgoyette #define	LPM_MAX_PREFIX		(128)
1.3.2.2  pgoyette #define	LPM_MAX_WORDS		(LPM_MAX_PREFIX >> 5)
1.3.2.2  pgoyette #define	LPM_TO_WORDS(x)		((x) >> 2)
1.3.2.2  pgoyette #define	LPM_HASH_STEP		(8)
1.3.2.2  pgoyette
1.3.2.2  pgoyette #ifdef DEBUG
1.3.2.2  pgoyette #define	ASSERT	assert
1.3.2.2  pgoyette #else
1.3.2.2  pgoyette #define	ASSERT
1.3.2.2  pgoyette #endif
1.3.2.2  pgoyette
1.3.2.2  pgoyette typedef struct lpm_ent {
1.3.2.2  pgoyette 	struct lpm_ent *next;
1.3.2.2  pgoyette 	void *		val;
1.3.2.2  pgoyette 	unsigned	len;
1.3.2.2  pgoyette 	uint8_t		key[];
1.3.2.2  pgoyette } lpm_ent_t;
1.3.2.2  pgoyette
1.3.2.2  pgoyette typedef struct {
1.3.2.2  pgoyette 	uint32_t	hashsize;
1.3.2.2  pgoyette 	uint32_t	nitems;
1.3.2.2  pgoyette 	lpm_ent_t **bucket;
1.3.2.2  pgoyette } lpm_hmap_t;
1.3.2.2  pgoyette
1.3.2.2  pgoyette struct lpm {
1.3.2.2  pgoyette 	uint32_t	bitmask[LPM_MAX_WORDS];
1.3.2.2  pgoyette 	void *		defval;
1.3.2.2  pgoyette 	lpm_hmap_t	prefix[LPM_MAX_PREFIX + 1];
1.3.2.2  pgoyette };
1.3.2.2  pgoyette
1.3.2.2  pgoyette lpm_t *
1.3.2.2  pgoyette lpm_create(void)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	return kmem_zalloc(sizeof(lpm_t), KM_SLEEP);
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette void
1.3.2.2  pgoyette lpm_clear(lpm_t *lpm, lpm_dtor_t dtor, void *arg)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	for (unsigned n = 0; n <= LPM_MAX_PREFIX; n++) {
1.3.2.2  pgoyette 		lpm_hmap_t *hmap = &lpm->prefix[n];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		if (!hmap->hashsize) {
1.3.2.2  pgoyette 			KASSERT(!hmap->bucket);
1.3.2.2  pgoyette 			continue;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		for (unsigned i = 0; i < hmap->hashsize; i++) {
1.3.2.2  pgoyette 			lpm_ent_t *entry = hmap->bucket[i];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 			while (entry) {
1.3.2.2  pgoyette 				lpm_ent_t *next = entry->next;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 				if (dtor) {
1.3.2.2  pgoyette 					dtor(arg, entry->key,
1.3.2.2  pgoyette 					    entry->len, entry->val);
1.3.2.2  pgoyette 				}
1.3.2.2  pgoyette 				kmem_free(entry,
1.3.2.2  pgoyette 				    offsetof(lpm_ent_t, key[entry->len]));
1.3.2.2  pgoyette 				entry = next;
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		kmem_free(hmap->bucket, hmap->hashsize * sizeof(lpm_ent_t *));
1.3.2.2  pgoyette 		hmap->bucket = NULL;
1.3.2.2  pgoyette 		hmap->hashsize = 0;
1.3.2.2  pgoyette 		hmap->nitems = 0;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	memset(lpm->bitmask, 0, sizeof(lpm->bitmask));
1.3.2.2  pgoyette 	lpm->defval = NULL;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette void
1.3.2.2  pgoyette lpm_destroy(lpm_t *lpm)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	lpm_clear(lpm, NULL, NULL);
1.3.2.2  pgoyette 	kmem_free(lpm, sizeof(*lpm));
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * fnv1a_hash: Fowler-Noll-Vo hash function (FNV-1a variant).
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette static uint32_t
1.3.2.2  pgoyette fnv1a_hash(const void *buf, size_t len)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	uint32_t hash = 2166136261UL;
1.3.2.2  pgoyette 	const uint8_t *p = buf;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	while (len--) {
1.3.2.2  pgoyette 		hash ^= *p++;
1.3.2.2  pgoyette 		hash *= 16777619U;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return hash;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static bool
1.3.2.2  pgoyette hashmap_rehash(lpm_hmap_t *hmap, uint32_t size)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	lpm_ent_t **bucket;
1.3.2.2  pgoyette 	uint32_t hashsize;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	for (hashsize = 1; hashsize < size; hashsize <<= 1) {
1.3.2.2  pgoyette 		continue;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	bucket = kmem_zalloc(hashsize * sizeof(lpm_ent_t *), KM_SLEEP);
1.3.2.2  pgoyette 	if (bucket == NULL)
1.3.2.2  pgoyette 		return false;
1.3.2.2  pgoyette 	for (unsigned n = 0; n < hmap->hashsize; n++) {
1.3.2.2  pgoyette 		lpm_ent_t *list = hmap->bucket[n];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		while (list) {
1.3.2.2  pgoyette 			lpm_ent_t *entry = list;
1.3.2.2  pgoyette 			uint32_t hash = fnv1a_hash(entry->key, entry->len);
1.3.2.2  pgoyette 			const size_t i = hash & (hashsize - 1);
1.3.2.2  pgoyette
1.3.2.2  pgoyette 			list = entry->next;
1.3.2.2  pgoyette 			entry->next = bucket[i];
1.3.2.2  pgoyette 			bucket[i] = entry;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (hmap->bucket)
1.3.2.2  pgoyette 		kmem_free(hmap->bucket, hmap->hashsize * sizeof(lpm_ent_t *));
1.3.2.2  pgoyette 	hmap->bucket = bucket;
1.3.2.2  pgoyette 	hmap->hashsize = hashsize;
1.3.2.2  pgoyette 	return true;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static lpm_ent_t *
1.3.2.2  pgoyette hashmap_insert(lpm_hmap_t *hmap, const void *key, size_t len)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const uint32_t target = hmap->nitems + LPM_HASH_STEP;
1.3.2.2  pgoyette 	const size_t entlen = offsetof(lpm_ent_t, key[len]);
1.3.2.2  pgoyette 	uint32_t hash, i;
1.3.2.2  pgoyette 	lpm_ent_t *entry;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (hmap->hashsize < target && !hashmap_rehash(hmap, target)) {
1.3.2.2  pgoyette 		return NULL;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	hash = fnv1a_hash(key, len);
1.3.2.2  pgoyette 	i = hash & (hmap->hashsize - 1);
1.3.2.2  pgoyette 	entry = hmap->bucket[i];
1.3.2.2  pgoyette 	while (entry) {
1.3.2.2  pgoyette 		if (entry->len == len && memcmp(entry->key, key, len) == 0) {
1.3.2.2  pgoyette 			return entry;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		entry = entry->next;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if ((entry = kmem_alloc(entlen, KM_SLEEP)) == NULL)
1.3.2.2  pgoyette 		return NULL;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	memcpy(entry->key, key, len);
1.3.2.2  pgoyette 	entry->next = hmap->bucket[i];
1.3.2.2  pgoyette 	entry->len = len;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	hmap->bucket[i] = entry;
1.3.2.2  pgoyette 	hmap->nitems++;
1.3.2.2  pgoyette 	return entry;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static lpm_ent_t *
1.3.2.2  pgoyette hashmap_lookup(lpm_hmap_t *hmap, const void *key, size_t len)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const uint32_t hash = fnv1a_hash(key, len);
1.3.2.2  pgoyette 	const uint32_t i = hash & (hmap->hashsize - 1);
1.3.2.2  pgoyette 	lpm_ent_t *entry = hmap->bucket[i];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	while (entry) {
1.3.2.2  pgoyette 		if (entry->len == len && memcmp(entry->key, key, len) == 0) {
1.3.2.2  pgoyette 			return entry;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		entry = entry->next;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return NULL;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette static int
1.3.2.2  pgoyette hashmap_remove(lpm_hmap_t *hmap, const void *key, size_t len)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const uint32_t hash = fnv1a_hash(key, len);
1.3.2.2  pgoyette 	const uint32_t i = hash & (hmap->hashsize - 1);
1.3.2.2  pgoyette 	lpm_ent_t *prev = NULL, *entry = hmap->bucket[i];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	while (entry) {
1.3.2.2  pgoyette 		if (entry->len == len && memcmp(entry->key, key, len) == 0) {
1.3.2.2  pgoyette 			if (prev) {
1.3.2.2  pgoyette 				prev->next = entry->next;
1.3.2.2  pgoyette 			} else {
1.3.2.2  pgoyette 				hmap->bucket[i] = entry->next;
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 			kmem_free(entry, offsetof(lpm_ent_t, key[len]));
1.3.2.2  pgoyette 			return 0;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		prev = entry;
1.3.2.2  pgoyette 		entry = entry->next;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return -1;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * compute_prefix: given the address and prefix length, compute and
1.3.2.2  pgoyette  * return the address prefix.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette static inline void
1.3.2.2  pgoyette compute_prefix(const unsigned nwords, const uint32_t *addr,
1.3.2.2  pgoyette     unsigned preflen, uint32_t *prefix)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	uint32_t addr2[4];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if ((uintptr_t)addr & 3) {
1.3.2.2  pgoyette 		/* Unaligned address: just copy for now. */
1.3.2.2  pgoyette 		memcpy(addr2, addr, nwords * 4);
1.3.2.2  pgoyette 		addr = addr2;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	for (unsigned i = 0; i < nwords; i++) {
1.3.2.2  pgoyette 		if (preflen == 0) {
1.3.2.2  pgoyette 			prefix[i] = 0;
1.3.2.2  pgoyette 			continue;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		if (preflen < 32) {
1.3.2.2  pgoyette 			uint32_t mask = htonl(0xffffffff << (32 - preflen));
1.3.2.2  pgoyette 			prefix[i] = addr[i] & mask;
1.3.2.2  pgoyette 			preflen = 0;
1.3.2.2  pgoyette 		} else {
1.3.2.2  pgoyette 			prefix[i] = addr[i];
1.3.2.2  pgoyette 			preflen -= 32;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * lpm_insert: insert the CIDR into the LPM table.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * => Returns zero on success and -1 on failure.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette int
1.3.2.2  pgoyette lpm_insert(lpm_t *lpm, const void *addr,
1.3.2.2  pgoyette     size_t len, unsigned preflen, void *val)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const unsigned nwords = LPM_TO_WORDS(len);
1.3.2.2  pgoyette 	uint32_t prefix[LPM_MAX_WORDS];
1.3.2.2  pgoyette 	lpm_ent_t *entry;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (preflen == 0) {
1.3.2.2  pgoyette 		/* Default is a special case. */
1.3.2.2  pgoyette 		lpm->defval = val;
1.3.2.2  pgoyette 		return 0;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	compute_prefix(nwords, addr, preflen, prefix);
1.3.2.2  pgoyette 	entry = hashmap_insert(&lpm->prefix[preflen], prefix, len);
1.3.2.2  pgoyette 	if (entry) {
1.3.2.2  pgoyette 		const unsigned n = --preflen >> 5;
1.3.2.2  pgoyette 		lpm->bitmask[n] |= 0x80000000U >> (preflen & 31);
1.3.2.2  pgoyette 		entry->val = val;
1.3.2.2  pgoyette 		return 0;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return -1;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * lpm_remove: remove the specified prefix.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette int
1.3.2.2  pgoyette lpm_remove(lpm_t *lpm, const void *addr, size_t len, unsigned preflen)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const unsigned nwords = LPM_TO_WORDS(len);
1.3.2.2  pgoyette 	uint32_t prefix[LPM_MAX_WORDS];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (preflen == 0) {
1.3.2.2  pgoyette 		lpm->defval = NULL;
1.3.2.2  pgoyette 		return 0;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	compute_prefix(nwords, addr, preflen, prefix);
1.3.2.2  pgoyette 	return hashmap_remove(&lpm->prefix[preflen], prefix, len);
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * lpm_lookup: find the longest matching prefix given the IP address.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * => Returns the associated value on success or NULL on failure.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette void *
1.3.2.2  pgoyette lpm_lookup(lpm_t *lpm, const void *addr, size_t len)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	const unsigned nwords = LPM_TO_WORDS(len);
1.3.2.2  pgoyette 	unsigned i, n = nwords;
1.3.2.2  pgoyette 	uint32_t prefix[LPM_MAX_WORDS];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	while (n--) {
1.3.2.2  pgoyette 		uint32_t bitmask = lpm->bitmask[n];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 		while ((i = ffs(bitmask)) != 0) {
1.3.2.2  pgoyette 			const unsigned preflen = (32 * n) + (32 - --i);
1.3.2.2  pgoyette 			lpm_hmap_t *hmap = &lpm->prefix[preflen];
1.3.2.2  pgoyette 			lpm_ent_t *entry;
1.3.2.2  pgoyette
1.3.2.2  pgoyette 			compute_prefix(nwords, addr, preflen, prefix);
1.3.2.2  pgoyette 			entry = hashmap_lookup(hmap, prefix, len);
1.3.2.2  pgoyette 			if (entry) {
1.3.2.2  pgoyette 				return entry->val;
1.3.2.2  pgoyette 			}
1.3.2.2  pgoyette 			bitmask &= ~(1U << i);
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return lpm->defval;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette
1.3.2.2  pgoyette #if !defined(_KERNEL)
1.3.2.2  pgoyette /*
1.3.2.2  pgoyette  * lpm_strtobin: convert CIDR string to the binary IP address and mask.
1.3.2.2  pgoyette  *
1.3.2.2  pgoyette  * => The address will be in the network byte order.
1.3.2.2  pgoyette  * => Returns 0 on success or -1 on failure.
1.3.2.2  pgoyette  */
1.3.2.2  pgoyette int
1.3.2.2  pgoyette lpm_strtobin(const char *cidr, void *addr, size_t *len, unsigned *preflen)
1.3.2.2  pgoyette {
1.3.2.2  pgoyette 	char *p, buf[INET6_ADDRSTRLEN];
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	strncpy(buf, cidr, sizeof(buf));
1.3.2.2  pgoyette 	buf[sizeof(buf) - 1] = '\0';
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if ((p = strchr(buf, '/')) != NULL) {
1.3.2.2  pgoyette 		const ptrdiff_t off = p - buf;
1.3.2.2  pgoyette 		*preflen = atoi(&buf[off + 1]);
1.3.2.2  pgoyette 		buf[off] = '\0';
1.3.2.2  pgoyette 	} else {
1.3.2.2  pgoyette 		*preflen = LPM_MAX_PREFIX;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette
1.3.2.2  pgoyette 	if (inet_pton(AF_INET6, buf, addr) == 1) {
1.3.2.2  pgoyette 		*len = 16;
1.3.2.2  pgoyette 		return 0;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	if (inet_pton(AF_INET, buf, addr) == 1) {
1.3.2.2  pgoyette 		if (*preflen == LPM_MAX_PREFIX) {
1.3.2.2  pgoyette 			*preflen = 32;
1.3.2.2  pgoyette 		}
1.3.2.2  pgoyette 		*len = 4;
1.3.2.2  pgoyette 		return 0;
1.3.2.2  pgoyette 	}
1.3.2.2  pgoyette 	return -1;
1.3.2.2  pgoyette }
1.3.2.2  pgoyette #endif