/* $OpenBSD: rde_attr.c,v 1.77 2009/01/13 21:35:16 sthen Exp $ */ /* * Copyright (c) 2004 Claudio Jeker * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include "bgpd.h" #include "rde.h" int attr_write(void *p, u_int16_t p_len, u_int8_t flags, u_int8_t type, void *data, u_int16_t data_len) { u_char *b = p; u_int16_t tmp, tot_len = 2; /* attribute header (without len) */ if (data_len > 255) { tot_len += 2 + data_len; flags |= ATTR_EXTLEN; } else { tot_len += 1 + data_len; flags &= ~ATTR_EXTLEN; } if (tot_len > p_len) return (-1); *b++ = flags; *b++ = type; if (data_len > 255) { tmp = htons(data_len); memcpy(b, &tmp, sizeof(tmp)); b += 2; } else *b++ = (u_char)data_len; if (data_len != 0) memcpy(b, data, data_len); return (tot_len); } /* optional attribute specific functions */ int attr_diff(struct attr *, struct attr *); struct attr *attr_alloc(u_int8_t, u_int8_t, const void *, u_int16_t); struct attr *attr_lookup(u_int8_t, u_int8_t, const void *, u_int16_t); void attr_put(struct attr *); struct attr_table { struct attr_list *hashtbl; u_int32_t hashmask; } attrtable; #define ATTR_HASH(x) \ &attrtable.hashtbl[(x) & attrtable.hashmask] void attr_init(u_int32_t hashsize) { u_int32_t hs, i; for (hs = 1; hs < hashsize; hs <<= 1) ; attrtable.hashtbl = calloc(hs, sizeof(struct attr_list)); if (attrtable.hashtbl == NULL) fatal("attr_init"); for (i = 0; i < hs; i++) LIST_INIT(&attrtable.hashtbl[i]); attrtable.hashmask = hs - 1; } void attr_shutdown(void) { u_int32_t i; for (i = 0; i <= attrtable.hashmask; i++) if (!LIST_EMPTY(&attrtable.hashtbl[i])) log_warnx("attr_shutdown: free non-free table"); free(attrtable.hashtbl); } int attr_optadd(struct rde_aspath *asp, u_int8_t flags, u_int8_t type, void *data, u_int16_t len) { u_int8_t l; struct attr *a, *t; void *p; /* known optional attributes were validated previously */ if ((a = attr_lookup(flags, type, data, len)) == NULL) a = attr_alloc(flags, type, data, len); /* attribute allowed only once */ for (l = 0; l < asp->others_len; l++) { if (asp->others[l] == NULL) break; if (type == asp->others[l]->type) return (-1); } /* add attribute to the table but first bump refcnt */ a->refcnt++; rdemem.attr_refs++; for (l = 0; l < asp->others_len; l++) { if (asp->others[l] == NULL) { asp->others[l] = a; return (0); } /* list is sorted */ if (a->type < asp->others[l]->type) { t = asp->others[l]; asp->others[l] = a; a = t; } } /* no empty slot found, need to realloc */ if (asp->others_len == UCHAR_MAX) fatalx("attr_optadd: others_len overflow"); asp->others_len++; if ((p = realloc(asp->others, asp->others_len * sizeof(struct attr *))) == NULL) fatal("attr_optadd"); asp->others = p; /* l stores the size of others before resize */ asp->others[l] = a; return (0); } struct attr * attr_optget(const struct rde_aspath *asp, u_int8_t type) { u_int8_t l; for (l = 0; l < asp->others_len; l++) { if (asp->others[l] == NULL) break; if (type == asp->others[l]->type) return (asp->others[l]); if (type < asp->others[l]->type) break; } return (NULL); } void attr_copy(struct rde_aspath *t, struct rde_aspath *s) { u_int8_t l; if (t->others != NULL) attr_freeall(t); t->others_len = s->others_len; if (t->others_len == 0) { t->others = NULL; return; } if ((t->others = calloc(s->others_len, sizeof(struct attr *))) == 0) fatal("attr_copy"); for (l = 0; l < t->others_len; l++) { if (s->others[l] == NULL) break; s->others[l]->refcnt++; rdemem.attr_refs++; t->others[l] = s->others[l]; } } int attr_diff(struct attr *oa, struct attr *ob) { int r; if (ob == NULL) return (1); if (oa == NULL) return (-1); if (oa->flags > ob->flags) return (1); if (oa->flags < ob->flags) return (-1); if (oa->type > ob->type) return (1); if (oa->type < ob->type) return (-1); if (oa->len > ob->len) return (1); if (oa->len < ob->len) return (-1); r = memcmp(oa->data, ob->data, oa->len); if (r > 0) return (1); if (r < 0) return (-1); fatalx("attr_diff: equal attributes encountered"); return (0); } int attr_compare(struct rde_aspath *a, struct rde_aspath *b) { u_int8_t l, min; min = a->others_len < b->others_len ? a->others_len : b->others_len; for (l = 0; l < min; l++) if (a->others[l] != b->others[l]) return (attr_diff(a->others[l], b->others[l])); if (a->others_len < b->others_len) { for (; l < b->others_len; l++) if (b->others[l] != NULL) return (-1); } else if (a->others_len > b->others_len) { for (; l < a->others_len; l++) if (a->others[l] != NULL) return (1); } return (0); } void attr_free(struct rde_aspath *asp, struct attr *attr) { u_int8_t l; for (l = 0; l < asp->others_len; l++) if (asp->others[l] == attr) { attr_put(asp->others[l]); for (++l; l < asp->others_len; l++) asp->others[l - 1] = asp->others[l]; asp->others[asp->others_len - 1] = NULL; return; } /* no realloc() because the slot may be reused soon */ } void attr_freeall(struct rde_aspath *asp) { u_int8_t l; for (l = 0; l < asp->others_len; l++) attr_put(asp->others[l]); free(asp->others); asp->others = NULL; asp->others_len = 0; } struct attr * attr_alloc(u_int8_t flags, u_int8_t type, const void *data, u_int16_t len) { struct attr *a; a = calloc(1, sizeof(struct attr)); if (a == NULL) fatal("attr_optadd"); rdemem.attr_cnt++; a->flags = flags; a->hash = hash32_buf(&flags, sizeof(flags), HASHINIT); a->type = type; a->hash = hash32_buf(&type, sizeof(type), a->hash); a->len = len; if (len != 0) { if ((a->data = malloc(len)) == NULL) fatal("attr_optadd"); rdemem.attr_dcnt++; rdemem.attr_data += len; memcpy(a->data, data, len); } else a->data = NULL; a->hash = hash32_buf(&len, sizeof(len), a->hash); a->hash = hash32_buf(a->data, a->len, a->hash); LIST_INSERT_HEAD(ATTR_HASH(a->hash), a, entry); return (a); } struct attr * attr_lookup(u_int8_t flags, u_int8_t type, const void *data, u_int16_t len) { struct attr_list *head; struct attr *a; u_int32_t hash; hash = hash32_buf(&flags, sizeof(flags), HASHINIT); hash = hash32_buf(&type, sizeof(type), hash); hash = hash32_buf(&len, sizeof(len), hash); hash = hash32_buf(data, len, hash); head = ATTR_HASH(hash); LIST_FOREACH(a, head, entry) { if (hash == a->hash && type == a->type && flags == a->flags && len == a->len && memcmp(data, a->data, len) == 0) return (a); } return (NULL); } void attr_put(struct attr *a) { if (a == NULL) return; rdemem.attr_refs--; if (--a->refcnt > 0) /* somebody still holds a reference */ return; /* unlink */ LIST_REMOVE(a, entry); if (a->len != 0) rdemem.attr_dcnt--; rdemem.attr_data -= a->len; rdemem.attr_cnt--; free(a->data); free(a); } /* aspath specific functions */ u_int16_t aspath_countlength(struct aspath *, u_int16_t, int); void aspath_countcopy(struct aspath *, u_int16_t, u_int8_t *, u_int16_t, int); struct aspath *aspath_lookup(const void *, u_int16_t); struct aspath_table { struct aspath_list *hashtbl; u_int32_t hashmask; } astable; #define ASPATH_HASH(x) \ &astable.hashtbl[(x) & astable.hashmask] int aspath_verify(void *data, u_int16_t len, int as4byte) { u_int8_t *seg = data; u_int16_t seg_size, as_size = 2; u_int8_t seg_len, seg_type; if (len & 1) /* odd length aspath are invalid */ return (AS_ERR_BAD); if (as4byte) as_size = 4; for (; len > 0; len -= seg_size, seg += seg_size) { if (len < 2) /* header length check */ return (AS_ERR_BAD); seg_type = seg[0]; seg_len = seg[1]; if (seg_type != AS_SET && seg_type != AS_SEQUENCE) return (AS_ERR_TYPE); seg_size = 2 + as_size * seg_len; if (seg_size > len) return (AS_ERR_LEN); if (seg_size == 0) /* empty aspath segments are not allowed */ return (AS_ERR_BAD); } return (0); /* aspath is valid but probably not loop free */ } void aspath_init(u_int32_t hashsize) { u_int32_t hs, i; for (hs = 1; hs < hashsize; hs <<= 1) ; astable.hashtbl = calloc(hs, sizeof(struct aspath_list)); if (astable.hashtbl == NULL) fatal("aspath_init"); for (i = 0; i < hs; i++) LIST_INIT(&astable.hashtbl[i]); astable.hashmask = hs - 1; } void aspath_shutdown(void) { u_int32_t i; for (i = 0; i <= astable.hashmask; i++) if (!LIST_EMPTY(&astable.hashtbl[i])) log_warnx("aspath_shutdown: free non-free table"); free(astable.hashtbl); } struct aspath * aspath_get(void *data, u_int16_t len) { struct aspath_list *head; struct aspath *aspath; /* The aspath must already have been checked for correctness. */ aspath = aspath_lookup(data, len); if (aspath == NULL) { aspath = malloc(ASPATH_HEADER_SIZE + len); if (aspath == NULL) fatal("aspath_get"); rdemem.aspath_cnt++; rdemem.aspath_size += ASPATH_HEADER_SIZE + len; aspath->refcnt = 0; aspath->len = len; aspath->ascnt = aspath_count(data, len); memcpy(aspath->data, data, len); /* link */ head = ASPATH_HASH(hash32_buf(aspath->data, aspath->len, HASHINIT)); LIST_INSERT_HEAD(head, aspath, entry); } aspath->refcnt++; rdemem.aspath_refs++; return (aspath); } void aspath_put(struct aspath *aspath) { if (aspath == NULL) return; rdemem.aspath_refs--; if (--aspath->refcnt > 0) { /* somebody still holds a reference */ return; } /* unlink */ LIST_REMOVE(aspath, entry); rdemem.aspath_cnt--; rdemem.aspath_size -= ASPATH_HEADER_SIZE + aspath->len; free(aspath); } u_char * aspath_inflate(void *data, u_int16_t len, u_int16_t *newlen) { u_int8_t *seg, *nseg, *ndata; u_int16_t seg_size, olen, nlen; u_int8_t seg_len; /* first calculate the length of the aspath */ seg = data; nlen = 0; for (olen = len; olen > 0; olen -= seg_size, seg += seg_size) { seg_len = seg[1]; seg_size = 2 + sizeof(u_int16_t) * seg_len; nlen += 2 + sizeof(u_int32_t) * seg_len; if (seg_size > olen) fatalx("aspath_inflate: would overflow"); } *newlen = nlen; if ((ndata = malloc(nlen)) == NULL) fatal("aspath_inflate"); /* then copy the aspath */ seg = data; for (nseg = ndata; nseg < ndata + nlen; ) { *nseg++ = *seg++; *nseg++ = seg_len = *seg++; for (; seg_len > 0; seg_len--) { *nseg++ = 0; *nseg++ = 0; *nseg++ = *seg++; *nseg++ = *seg++; } } return (ndata); } /* convert a 4 byte aspath to a 2byte one. data is freed by aspath_deflate */ u_char * aspath_deflate(u_char *data, u_int16_t *len, int *flagnew) { u_int8_t *seg, *nseg, *ndata; u_int32_t as; int i; u_int16_t seg_size, olen, nlen; u_int8_t seg_len; /* first calculate the length of the aspath */ nlen = 0; seg = data; olen = *len; for (; olen > 0; olen -= seg_size, seg += seg_size) { seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; nlen += 2 + sizeof(u_int16_t) * seg_len; if (seg_size > olen) fatalx("aspath_deflate: would overflow"); } if ((ndata = malloc(nlen)) == NULL) fatal("aspath_deflate"); /* then copy the aspath */ seg = data; olen = *len; for (nseg = ndata; seg < data + olen; seg += seg_size) { *nseg++ = seg[0]; *nseg++ = seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; for (i = 0; i < seg_len; i++) { as = aspath_extract(seg, i); if (as > USHRT_MAX) { as = AS_TRANS; *flagnew = 1; } *nseg++ = (as >> 8) & 0xff; *nseg++ = as & 0xff; } } free(data); *len = nlen; return (ndata); } void aspath_merge(struct rde_aspath *a, struct attr *attr) { u_int8_t *np; u_int16_t ascnt, diff, nlen, difflen; int hroom = 0; ascnt = aspath_count(attr->data, attr->len); if (ascnt > a->aspath->ascnt) { /* ASPATH is shorter then AS4_PATH no way to merge */ attr_free(a, attr); return; } diff = a->aspath->ascnt - ascnt; if (diff && attr->len > 2 && attr->data[0] == AS_SEQUENCE) hroom = attr->data[1]; difflen = aspath_countlength(a->aspath, diff, hroom); nlen = attr->len + difflen; if ((np = malloc(nlen)) == NULL) fatal("aspath_merge"); /* copy head from old aspath */ aspath_countcopy(a->aspath, diff, np, difflen, hroom); /* copy tail from new aspath */ if (hroom > 0) memcpy(np + nlen - attr->len + 2, attr->data + 2, attr->len - 2); else memcpy(np + nlen - attr->len, attr->data, attr->len); aspath_put(a->aspath); a->aspath = aspath_get(np, nlen); free(np); attr_free(a, attr); } u_char * aspath_dump(struct aspath *aspath) { return (aspath->data); } u_int16_t aspath_length(struct aspath *aspath) { return (aspath->len); } u_int16_t aspath_count(const void *data, u_int16_t len) { const u_int8_t *seg; u_int16_t cnt, seg_size; u_int8_t seg_type, seg_len; cnt = 0; seg = data; for (; len > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; if (seg_type == AS_SET) cnt += 1; else cnt += seg_len; if (seg_size > len) fatalx("aspath_count: would overflow"); } return (cnt); } u_int16_t aspath_countlength(struct aspath *aspath, u_int16_t cnt, int headcnt) { const u_int8_t *seg; u_int16_t seg_size, len, clen; u_int8_t seg_type = 0, seg_len = 0; seg = aspath->data; clen = 0; for (len = aspath->len; len > 0 && cnt > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; if (seg_type == AS_SET) cnt -= 1; else if (seg_len > cnt) { seg_len = cnt; clen += 2 + sizeof(u_int32_t) * cnt; break; } else cnt -= seg_len; clen += seg_size; if (seg_size > len) fatalx("aspath_countlength: would overflow"); } if (headcnt > 0 && seg_type == AS_SEQUENCE && headcnt + seg_len < 256) /* no need for additional header from the new aspath. */ clen -= 2; return (clen); } void aspath_countcopy(struct aspath *aspath, u_int16_t cnt, u_int8_t *buf, u_int16_t size, int headcnt) { const u_int8_t *seg; u_int16_t seg_size, len; u_int8_t seg_type, seg_len; if (headcnt > 0) /* * additional room because we steal the segment header * from the other aspath */ size += 2; seg = aspath->data; for (len = aspath->len; len > 0 && cnt > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; if (seg_type == AS_SET) cnt -= 1; else if (seg_len > cnt) { seg_len = cnt + headcnt; seg_size = 2 + sizeof(u_int32_t) * cnt; cnt = 0; } else { cnt -= seg_len; if (cnt == 0) seg_len += headcnt; } memcpy(buf, seg, seg_size); buf[0] = seg_type; buf[1] = seg_len; buf += seg_size; if (size < seg_size) fatalx("aspath_countlength: would overflow"); size -= seg_size; } } u_int32_t aspath_neighbor(struct aspath *aspath) { /* * Empty aspath is OK -- internal as route. * But what is the neighbor? For now let's return 0. * That should not break anything. */ if (aspath->len == 0) return (0); return (aspath_extract(aspath->data, 0)); } int aspath_loopfree(struct aspath *aspath, u_int32_t myAS) { u_int8_t *seg; u_int16_t len, seg_size; u_int8_t i, seg_len, seg_type; seg = aspath->data; for (len = aspath->len; len > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; for (i = 0; i < seg_len; i++) { if (myAS == aspath_extract(seg, i)) return (0); } if (seg_size > len) fatalx("aspath_loopfree: would overflow"); } return (1); } int aspath_compare(struct aspath *a1, struct aspath *a2) { int r; if (a1->len > a2->len) return (1); if (a1->len < a2->len) return (-1); r = memcmp(a1->data, a2->data, a1->len); if (r > 0) return (1); if (r < 0) return (-1); return (0); } struct aspath * aspath_lookup(const void *data, u_int16_t len) { struct aspath_list *head; struct aspath *aspath; u_int32_t hash; hash = hash32_buf(data, len, HASHINIT); head = ASPATH_HASH(hash); LIST_FOREACH(aspath, head, entry) { if (len == aspath->len && memcmp(data, aspath->data, len) == 0) return (aspath); } return (NULL); } /* * Returns a new prepended aspath. Old needs to be freed by caller. */ u_char * aspath_prepend(struct aspath *asp, u_int32_t as, int quantum, u_int16_t *len) { u_char *p; int l, overflow = 0, shift = 0, size, wpos = 0; u_int8_t type; /* lunatic prepends are blocked in the parser and limited */ /* first calculate new size */ if (asp->len > 0) { if (asp->len < 2) fatalx("aspath_prepend: bad aspath length"); type = asp->data[0]; size = asp->data[1]; } else { /* empty as path */ type = AS_SET; size = 0; } if (quantum == 0) { /* no change needed but return a copy */ p = malloc(asp->len); if (p == NULL) fatal("aspath_prepend"); memcpy(p, asp->data, asp->len); *len = asp->len; return (p); } else if (type == AS_SET || size + quantum > 255) { /* need to attach a new AS_SEQUENCE */ l = 2 + quantum * sizeof(u_int32_t) + asp->len; overflow = type == AS_SET ? quantum : (size + quantum) & 0xff; } else l = quantum * sizeof(u_int32_t) + asp->len; quantum -= overflow; p = malloc(l); if (p == NULL) fatal("aspath_prepend"); /* first prepends */ as = htonl(as); if (overflow > 0) { p[wpos++] = AS_SEQUENCE; p[wpos++] = overflow; for (; overflow > 0; overflow--) { memcpy(p + wpos, &as, sizeof(u_int32_t)); wpos += sizeof(u_int32_t); } } if (quantum > 0) { shift = 2; p[wpos++] = AS_SEQUENCE; p[wpos++] = quantum + size; for (; quantum > 0; quantum--) { memcpy(p + wpos, &as, sizeof(u_int32_t)); wpos += sizeof(u_int32_t); } } memcpy(p + wpos, asp->data + shift, asp->len - shift); *len = l; return (p); } /* we need to be able to search more than one as */ int aspath_match(struct aspath *a, enum as_spec type, u_int32_t as) { u_int8_t *seg; int final; u_int16_t len, seg_size; u_int8_t i, seg_type, seg_len; if (type == AS_EMPTY) { if (a->len == 0) return (1); else return (0); } final = 0; seg = a->data; for (len = a->len; len > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; final = (len == seg_size); /* just check the first (leftmost) AS */ if (type == AS_PEER) { if (as == aspath_extract(seg, 0)) return (1); else return (0); } /* just check the final (rightmost) AS */ if (type == AS_SOURCE) { /* not yet in the final segment */ if (!final) continue; if (as == aspath_extract(seg, seg_len - 1)) return (1); else return (0); } /* AS_TRANSIT or AS_ALL */ for (i = 0; i < seg_len; i++) { if (as == aspath_extract(seg, i)) { /* * the source (rightmost) AS is excluded from * AS_TRANSIT matches. */ if (final && i == seg_len - 1 && type == AS_TRANSIT) return (0); return (1); } } } return (0); } int community_match(void *data, u_int16_t len, int as, int type) { u_int8_t *p = data; u_int16_t eas, etype; len >>= 2; /* divide by four */ for (; len > 0; len--) { eas = *p++; eas <<= 8; eas |= *p++; etype = *p++; etype <<= 8; etype |= *p++; if ((as == COMMUNITY_ANY || (u_int16_t)as == eas) && (type == COMMUNITY_ANY || (u_int16_t)type == etype)) return (1); } return (0); } int community_set(struct rde_aspath *asp, int as, int type) { struct attr *attr; u_int8_t *p = NULL; unsigned int i, ncommunities = 0; u_int8_t f = ATTR_OPTIONAL|ATTR_TRANSITIVE; u_int8_t t = ATTR_COMMUNITIES; attr = attr_optget(asp, ATTR_COMMUNITIES); if (attr != NULL) { p = attr->data; ncommunities = attr->len >> 2; /* divide by four */ } /* first check if the community is not already set */ for (i = 0; i < ncommunities; i++) { if (as >> 8 == p[0] && (as & 0xff) == p[1] && type >> 8 == p[2] && (type & 0xff) == p[3]) /* already present, nothing todo */ return (1); p += 4; } if (ncommunities++ >= 0x3fff) /* overflow */ return (0); if ((p = malloc(ncommunities << 2)) == NULL) fatal("community_set"); p[0] = as >> 8; p[1] = as & 0xff; p[2] = type >> 8; p[3] = type & 0xff; if (attr != NULL) { memcpy(p + 4, attr->data, attr->len); f = attr->flags; t = attr->type; attr_free(asp, attr); } attr_optadd(asp, f, t, p, ncommunities << 2); free(p); return (1); } void community_delete(struct rde_aspath *asp, int as, int type) { struct attr *attr; u_int8_t *p, *n; u_int16_t l, len = 0; u_int16_t eas, etype; u_int8_t f, t; attr = attr_optget(asp, ATTR_COMMUNITIES); if (attr == NULL) /* no attr nothing to do */ return; p = attr->data; for (l = 0; l < attr->len; l += 4) { eas = *p++; eas <<= 8; eas |= *p++; etype = *p++; etype <<= 8; etype |= *p++; if ((as == COMMUNITY_ANY || (u_int16_t)as == eas) && (type == COMMUNITY_ANY || (u_int16_t)type == etype)) /* match */ continue; len += 4; } if (len == 0) { attr_free(asp, attr); return; } if ((n = malloc(len)) == NULL) fatal("community_delete"); p = attr->data; for (l = 0; l < len && p < attr->data + attr->len; ) { eas = *p++; eas <<= 8; eas |= *p++; etype = *p++; etype <<= 8; etype |= *p++; if ((as == COMMUNITY_ANY || (u_int16_t)as == eas) && (type == COMMUNITY_ANY || (u_int16_t)type == etype)) /* match */ continue; n[l++] = eas >> 8; n[l++] = eas & 0xff; n[l++] = etype >> 8; n[l++] = etype & 0xff; } f = attr->flags; t = attr->type; attr_free(asp, attr); attr_optadd(asp, f, t, n, len); free(n); }