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mirror of https://gitlab.nic.cz/labs/bird.git synced 2024-12-22 09:41:54 +00:00
bird/proto/bgp/attrs.c
Ondrej Zajicek 48bc232f08 Implements 'next hop keep' option for BGP.
This option allows to keep the received next hop even in cases when
the route is sent to an interface with a different subnet.
2013-04-16 17:27:34 +02:00

1798 lines
48 KiB
C

/*
* BIRD -- BGP Attributes
*
* (c) 2000 Martin Mares <mj@ucw.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#undef LOCAL_DEBUG
#include <stdlib.h>
#include "nest/bird.h"
#include "nest/iface.h"
#include "nest/protocol.h"
#include "nest/route.h"
#include "nest/attrs.h"
#include "conf/conf.h"
#include "lib/resource.h"
#include "lib/string.h"
#include "lib/unaligned.h"
#include "bgp.h"
/*
* UPDATE message error handling
*
* All checks from RFC 4271 6.3 are done as specified with these exceptions:
* - The semantic check of an IP address from NEXT_HOP attribute is missing.
* - Checks of some optional attribute values are missing.
* - Syntactic and semantic checks of NLRIs (done in DECODE_PREFIX())
* are probably inadequate.
*
* Loop detection based on AS_PATH causes updates to be withdrawn. RFC
* 4271 does not explicitly specifiy the behavior in that case.
*
* Loop detection related to route reflection (based on ORIGINATOR_ID
* and CLUSTER_LIST) causes updates to be withdrawn. RFC 4456 8
* specifies that such updates should be ignored, but that is generally
* a bad idea.
*
* Error checking of optional transitive attributes is done according to
* draft-ietf-idr-optional-transitive-03, but errors are handled always
* as withdraws.
*
* Unexpected AS_CONFED_* segments in AS_PATH are logged and removed,
* but unknown segments cause a session drop with Malformed AS_PATH
* error (see validate_path()). The behavior in such case is not
* explicitly specified by RFC 4271. RFC 5065 specifies that
* inconsistent AS_CONFED_* segments should cause a session drop, but
* implementations that pass invalid AS_CONFED_* segments are
* widespread.
*
* Error handling of AS4_* attributes is done as specified by
* draft-ietf-idr-rfc4893bis-03. There are several possible
* inconsistencies between AGGREGATOR and AS4_AGGREGATOR that are not
* handled by that draft, these are logged and ignored (see
* bgp_reconstruct_4b_attrs()).
*/
static byte bgp_mandatory_attrs[] = { BA_ORIGIN, BA_AS_PATH
#ifndef IPV6
,BA_NEXT_HOP
#endif
};
struct attr_desc {
char *name;
int expected_length;
int expected_flags;
int type;
int allow_in_ebgp;
int (*validate)(struct bgp_proto *p, byte *attr, int len);
void (*format)(eattr *ea, byte *buf, int buflen);
};
#define IGNORE -1
#define WITHDRAW -2
static int
bgp_check_origin(struct bgp_proto *p UNUSED, byte *a, int len UNUSED)
{
if (*a > 2)
return 6;
return 0;
}
static void
bgp_format_origin(eattr *a, byte *buf, int buflen UNUSED)
{
static char *bgp_origin_names[] = { "IGP", "EGP", "Incomplete" };
bsprintf(buf, bgp_origin_names[a->u.data]);
}
static int
path_segment_contains(byte *p, int bs, u32 asn)
{
int i;
int len = p[1];
p += 2;
for(i=0; i<len; i++)
{
u32 asn2 = (bs == 4) ? get_u32(p) : get_u16(p);
if (asn2 == asn)
return 1;
p += bs;
}
return 0;
}
/* Validates path attribute, removes AS_CONFED_* segments, and also returns path length */
static int
validate_path(struct bgp_proto *p, int as_path, int bs, byte *idata, unsigned int *ilength)
{
int res = 0;
u8 *a, *dst;
int len, plen, copy;
dst = a = idata;
len = *ilength;
while (len)
{
if (len < 2)
return -1;
plen = 2 + bs * a[1];
if (len < plen)
return -1;
switch (a[0])
{
case AS_PATH_SET:
copy = 1;
res++;
break;
case AS_PATH_SEQUENCE:
copy = 1;
res += a[1];
break;
case AS_PATH_CONFED_SEQUENCE:
case AS_PATH_CONFED_SET:
if (as_path && path_segment_contains(a, bs, p->remote_as))
{
log(L_WARN "%s: AS_CONFED_* segment with peer ASN found, misconfigured confederation?", p->p.name);
return -1;
}
log(L_WARN "%s: %s_PATH attribute contains AS_CONFED_* segment, skipping segment",
p->p.name, as_path ? "AS" : "AS4");
copy = 0;
break;
default:
return -1;
}
if (copy)
{
if (dst != a)
memmove(dst, a, plen);
dst += plen;
}
len -= plen;
a += plen;
}
*ilength = dst - idata;
return res;
}
static inline int
validate_as_path(struct bgp_proto *p, byte *a, int *len)
{
return validate_path(p, 1, p->as4_session ? 4 : 2, a, len);
}
static inline int
validate_as4_path(struct bgp_proto *p, struct adata *path)
{
return validate_path(p, 0, 4, path->data, &path->length);
}
static int
bgp_check_next_hop(struct bgp_proto *p UNUSED, byte *a, int len)
{
#ifdef IPV6
return IGNORE;
#else
ip_addr addr;
memcpy(&addr, a, len);
ipa_ntoh(addr);
if (ipa_classify(addr) & IADDR_HOST)
return 0;
else
return 8;
#endif
}
static void
bgp_format_next_hop(eattr *a, byte *buf, int buflen UNUSED)
{
ip_addr *ipp = (ip_addr *) a->u.ptr->data;
#ifdef IPV6
/* in IPv6, we might have two addresses in NEXT HOP */
if ((a->u.ptr->length == NEXT_HOP_LENGTH) && ipa_nonzero(ipp[1]))
{
bsprintf(buf, "%I %I", ipp[0], ipp[1]);
return;
}
#endif
bsprintf(buf, "%I", ipp[0]);
}
static int
bgp_check_aggregator(struct bgp_proto *p, byte *a UNUSED, int len)
{
int exp_len = p->as4_session ? 8 : 6;
return (len == exp_len) ? 0 : WITHDRAW;
}
static void
bgp_format_aggregator(eattr *a, byte *buf, int buflen UNUSED)
{
struct adata *ad = a->u.ptr;
byte *data = ad->data;
u32 as;
as = get_u32(data);
data += 4;
bsprintf(buf, "%d.%d.%d.%d AS%u", data[0], data[1], data[2], data[3], as);
}
static int
bgp_check_community(struct bgp_proto *p UNUSED, byte *a UNUSED, int len)
{
return ((len % 4) == 0) ? 0 : WITHDRAW;
}
static int
bgp_check_cluster_list(struct bgp_proto *p UNUSED, byte *a UNUSED, int len)
{
return ((len % 4) == 0) ? 0 : 5;
}
static void
bgp_format_cluster_list(eattr *a, byte *buf, int buflen)
{
/* Truncates cluster lists larger than buflen, probably not a problem */
int_set_format(a->u.ptr, 0, -1, buf, buflen);
}
static int
bgp_check_reach_nlri(struct bgp_proto *p UNUSED, byte *a UNUSED, int len UNUSED)
{
#ifdef IPV6
p->mp_reach_start = a;
p->mp_reach_len = len;
#endif
return IGNORE;
}
static int
bgp_check_unreach_nlri(struct bgp_proto *p UNUSED, byte *a UNUSED, int len UNUSED)
{
#ifdef IPV6
p->mp_unreach_start = a;
p->mp_unreach_len = len;
#endif
return IGNORE;
}
static int
bgp_check_ext_community(struct bgp_proto *p UNUSED, byte *a UNUSED, int len)
{
return ((len % 8) == 0) ? 0 : WITHDRAW;
}
static struct attr_desc bgp_attr_table[] = {
{ NULL, -1, 0, 0, 0, /* Undefined */
NULL, NULL },
{ "origin", 1, BAF_TRANSITIVE, EAF_TYPE_INT, 1, /* BA_ORIGIN */
bgp_check_origin, bgp_format_origin },
{ "as_path", -1, BAF_TRANSITIVE, EAF_TYPE_AS_PATH, 1, /* BA_AS_PATH */
NULL, NULL }, /* is checked by validate_as_path() as a special case */
{ "next_hop", 4, BAF_TRANSITIVE, EAF_TYPE_IP_ADDRESS, 1, /* BA_NEXT_HOP */
bgp_check_next_hop, bgp_format_next_hop },
{ "med", 4, BAF_OPTIONAL, EAF_TYPE_INT, 1, /* BA_MULTI_EXIT_DISC */
NULL, NULL },
{ "local_pref", 4, BAF_TRANSITIVE, EAF_TYPE_INT, 0, /* BA_LOCAL_PREF */
NULL, NULL },
{ "atomic_aggr", 0, BAF_TRANSITIVE, EAF_TYPE_OPAQUE, 1, /* BA_ATOMIC_AGGR */
NULL, NULL },
{ "aggregator", -1, BAF_OPTIONAL | BAF_TRANSITIVE, EAF_TYPE_OPAQUE, 1, /* BA_AGGREGATOR */
bgp_check_aggregator, bgp_format_aggregator },
{ "community", -1, BAF_OPTIONAL | BAF_TRANSITIVE, EAF_TYPE_INT_SET, 1, /* BA_COMMUNITY */
bgp_check_community, NULL },
{ "originator_id", 4, BAF_OPTIONAL, EAF_TYPE_ROUTER_ID, 0, /* BA_ORIGINATOR_ID */
NULL, NULL },
{ "cluster_list", -1, BAF_OPTIONAL, EAF_TYPE_INT_SET, 0, /* BA_CLUSTER_LIST */
bgp_check_cluster_list, bgp_format_cluster_list },
{ .name = NULL }, /* BA_DPA */
{ .name = NULL }, /* BA_ADVERTISER */
{ .name = NULL }, /* BA_RCID_PATH */
{ "mp_reach_nlri", -1, BAF_OPTIONAL, EAF_TYPE_OPAQUE, 1, /* BA_MP_REACH_NLRI */
bgp_check_reach_nlri, NULL },
{ "mp_unreach_nlri", -1, BAF_OPTIONAL, EAF_TYPE_OPAQUE, 1, /* BA_MP_UNREACH_NLRI */
bgp_check_unreach_nlri, NULL },
{ "ext_community", -1, BAF_OPTIONAL | BAF_TRANSITIVE, EAF_TYPE_EC_SET, 1, /* BA_EXT_COMMUNITY */
bgp_check_ext_community, NULL },
{ "as4_path", -1, BAF_OPTIONAL | BAF_TRANSITIVE, EAF_TYPE_OPAQUE, 1, /* BA_AS4_PATH */
NULL, NULL },
{ "as4_aggregator", -1, BAF_OPTIONAL | BAF_TRANSITIVE, EAF_TYPE_OPAQUE, 1, /* BA_AS4_PATH */
NULL, NULL }
};
/* BA_AS4_PATH is type EAF_TYPE_OPAQUE and not type EAF_TYPE_AS_PATH.
* It does not matter as this attribute does not appear on routes in the routing table.
*/
#define ATTR_KNOWN(code) ((code) < ARRAY_SIZE(bgp_attr_table) && bgp_attr_table[code].name)
static inline struct adata *
bgp_alloc_adata(struct linpool *pool, unsigned len)
{
struct adata *ad = lp_alloc(pool, sizeof(struct adata) + len);
ad->length = len;
return ad;
}
static void
bgp_set_attr(eattr *e, unsigned attr, uintptr_t val)
{
ASSERT(ATTR_KNOWN(attr));
e->id = EA_CODE(EAP_BGP, attr);
e->type = bgp_attr_table[attr].type;
e->flags = bgp_attr_table[attr].expected_flags;
if (e->type & EAF_EMBEDDED)
e->u.data = val;
else
e->u.ptr = (struct adata *) val;
}
static byte *
bgp_set_attr_wa(eattr *e, struct linpool *pool, unsigned attr, unsigned len)
{
struct adata *ad = bgp_alloc_adata(pool, len);
bgp_set_attr(e, attr, (uintptr_t) ad);
return ad->data;
}
void
bgp_attach_attr(ea_list **to, struct linpool *pool, unsigned attr, uintptr_t val)
{
ea_list *a = lp_alloc(pool, sizeof(ea_list) + sizeof(eattr));
a->next = *to;
*to = a;
a->flags = EALF_SORTED;
a->count = 1;
bgp_set_attr(a->attrs, attr, val);
}
byte *
bgp_attach_attr_wa(ea_list **to, struct linpool *pool, unsigned attr, unsigned len)
{
struct adata *ad = bgp_alloc_adata(pool, len);
bgp_attach_attr(to, pool, attr, (uintptr_t) ad);
return ad->data;
}
static int
bgp_encode_attr_hdr(byte *dst, unsigned int flags, unsigned code, int len)
{
int wlen;
DBG("\tAttribute %02x (%d bytes, flags %02x)\n", code, len, flags);
if (len < 256)
{
*dst++ = flags;
*dst++ = code;
*dst++ = len;
wlen = 3;
}
else
{
*dst++ = flags | BAF_EXT_LEN;
*dst++ = code;
put_u16(dst, len);
wlen = 4;
}
return wlen;
}
static void
aggregator_convert_to_old(struct adata *aggr, byte *dst, int *new_used)
{
byte *src = aggr->data;
*new_used = 0;
u32 as = get_u32(src);
if (as > 0xFFFF)
{
as = AS_TRANS;
*new_used = 1;
}
put_u16(dst, as);
/* Copy IPv4 address */
memcpy(dst + 2, src + 4, 4);
}
static void
aggregator_convert_to_new(struct adata *aggr, byte *dst)
{
byte *src = aggr->data;
u32 as = get_u16(src);
put_u32(dst, as);
/* Copy IPv4 address */
memcpy(dst + 4, src + 2, 4);
}
static int
bgp_get_attr_len(eattr *a)
{
int len;
if (ATTR_KNOWN(EA_ID(a->id)))
{
int code = EA_ID(a->id);
struct attr_desc *desc = &bgp_attr_table[code];
len = desc->expected_length;
if (len < 0)
{
ASSERT(!(a->type & EAF_EMBEDDED));
len = a->u.ptr->length;
}
}
else
{
ASSERT((a->type & EAF_TYPE_MASK) == EAF_TYPE_OPAQUE);
len = a->u.ptr->length;
}
return len;
}
#define ADVANCE(w, r, l) do { r -= l; w += l; } while (0)
/**
* bgp_encode_attrs - encode BGP attributes
* @p: BGP instance
* @w: buffer
* @attrs: a list of extended attributes
* @remains: remaining space in the buffer
*
* The bgp_encode_attrs() function takes a list of extended attributes
* and converts it to its BGP representation (a part of an Update message).
*
* Result: Length of the attribute block generated or -1 if not enough space.
*/
unsigned int
bgp_encode_attrs(struct bgp_proto *p, byte *w, ea_list *attrs, int remains)
{
unsigned int i, code, type, flags;
byte *start = w;
int len, rv;
for(i=0; i<attrs->count; i++)
{
eattr *a = &attrs->attrs[i];
ASSERT(EA_PROTO(a->id) == EAP_BGP);
code = EA_ID(a->id);
#ifdef IPV6
/* When talking multiprotocol BGP, the NEXT_HOP attributes are used only temporarily. */
if (code == BA_NEXT_HOP)
continue;
#endif
/* When AS4-aware BGP speaker is talking to non-AS4-aware BGP speaker,
* we have to convert our 4B AS_PATH to 2B AS_PATH and send our AS_PATH
* as optional AS4_PATH attribute.
*/
if ((code == BA_AS_PATH) && (! p->as4_session))
{
len = a->u.ptr->length;
if (remains < (len + 4))
goto err_no_buffer;
/* Using temporary buffer because don't know a length of created attr
* and therefore a length of a header. Perhaps i should better always
* use BAF_EXT_LEN. */
byte buf[len];
int new_used;
int nl = as_path_convert_to_old(a->u.ptr, buf, &new_used);
DBG("BGP: Encoding old AS_PATH\n");
rv = bgp_encode_attr_hdr(w, BAF_TRANSITIVE, BA_AS_PATH, nl);
ADVANCE(w, remains, rv);
memcpy(w, buf, nl);
ADVANCE(w, remains, nl);
if (! new_used)
continue;
if (remains < (len + 4))
goto err_no_buffer;
/* We should discard AS_CONFED_SEQUENCE or AS_CONFED_SET path segments
* here but we don't support confederations and such paths we already
* discarded in bgp_check_as_path().
*/
DBG("BGP: Encoding AS4_PATH\n");
rv = bgp_encode_attr_hdr(w, BAF_OPTIONAL | BAF_TRANSITIVE, BA_AS4_PATH, len);
ADVANCE(w, remains, rv);
memcpy(w, a->u.ptr->data, len);
ADVANCE(w, remains, len);
continue;
}
/* The same issue with AGGREGATOR attribute */
if ((code == BA_AGGREGATOR) && (! p->as4_session))
{
int new_used;
len = 6;
if (remains < (len + 3))
goto err_no_buffer;
rv = bgp_encode_attr_hdr(w, BAF_OPTIONAL | BAF_TRANSITIVE, BA_AGGREGATOR, len);
ADVANCE(w, remains, rv);
aggregator_convert_to_old(a->u.ptr, w, &new_used);
ADVANCE(w, remains, len);
if (! new_used)
continue;
len = 8;
if (remains < (len + 3))
goto err_no_buffer;
rv = bgp_encode_attr_hdr(w, BAF_OPTIONAL | BAF_TRANSITIVE, BA_AS4_AGGREGATOR, len);
ADVANCE(w, remains, rv);
memcpy(w, a->u.ptr->data, len);
ADVANCE(w, remains, len);
continue;
}
/* Standard path continues here ... */
type = a->type & EAF_TYPE_MASK;
flags = a->flags & (BAF_OPTIONAL | BAF_TRANSITIVE | BAF_PARTIAL);
len = bgp_get_attr_len(a);
/* Skip empty sets */
if (((type == EAF_TYPE_INT_SET) || (type == EAF_TYPE_EC_SET)) && (len == 0))
continue;
if (remains < len + 4)
goto err_no_buffer;
rv = bgp_encode_attr_hdr(w, flags, code, len);
ADVANCE(w, remains, rv);
switch (type)
{
case EAF_TYPE_INT:
case EAF_TYPE_ROUTER_ID:
if (len == 4)
put_u32(w, a->u.data);
else
*w = a->u.data;
break;
case EAF_TYPE_IP_ADDRESS:
{
ip_addr ip = *(ip_addr *)a->u.ptr->data;
ipa_hton(ip);
memcpy(w, &ip, len);
break;
}
case EAF_TYPE_INT_SET:
case EAF_TYPE_EC_SET:
{
u32 *z = int_set_get_data(a->u.ptr);
int i;
for(i=0; i<len; i+=4)
put_u32(w+i, *z++);
break;
}
case EAF_TYPE_OPAQUE:
case EAF_TYPE_AS_PATH:
memcpy(w, a->u.ptr->data, len);
break;
default:
bug("bgp_encode_attrs: unknown attribute type %02x", a->type);
}
ADVANCE(w, remains, len);
}
return w - start;
err_no_buffer:
return -1;
}
static void
bgp_init_prefix(struct fib_node *N)
{
struct bgp_prefix *p = (struct bgp_prefix *) N;
p->bucket_node.next = NULL;
}
static int
bgp_compare_u32(const u32 *x, const u32 *y)
{
return (*x < *y) ? -1 : (*x > *y) ? 1 : 0;
}
static inline void
bgp_normalize_int_set(u32 *dest, u32 *src, unsigned cnt)
{
memcpy(dest, src, sizeof(u32) * cnt);
qsort(dest, cnt, sizeof(u32), (int(*)(const void *, const void *)) bgp_compare_u32);
}
static int
bgp_compare_ec(const u32 *xp, const u32 *yp)
{
u64 x = ec_get(xp, 0);
u64 y = ec_get(yp, 0);
return (x < y) ? -1 : (x > y) ? 1 : 0;
}
static inline void
bgp_normalize_ec_set(struct adata *ad, u32 *src, int internal)
{
u32 *dst = int_set_get_data(ad);
/* Remove non-transitive communities (EC_TBIT active) on external sessions */
if (! internal)
{
int len = int_set_get_size(ad);
u32 *t = dst;
int i;
for (i=0; i < len; i += 2)
{
if (src[i] & EC_TBIT)
continue;
*t++ = src[i];
*t++ = src[i+1];
}
ad->length = (t - dst) * 4;
}
else
memcpy(dst, src, ad->length);
qsort(dst, ad->length / 8, 8, (int(*)(const void *, const void *)) bgp_compare_ec);
}
static void
bgp_rehash_buckets(struct bgp_proto *p)
{
struct bgp_bucket **old = p->bucket_hash;
struct bgp_bucket **new;
unsigned oldn = p->hash_size;
unsigned i, e, mask;
struct bgp_bucket *b;
p->hash_size = p->hash_limit;
DBG("BGP: Rehashing bucket table from %d to %d\n", oldn, p->hash_size);
p->hash_limit *= 4;
if (p->hash_limit >= 65536)
p->hash_limit = ~0;
new = p->bucket_hash = mb_allocz(p->p.pool, p->hash_size * sizeof(struct bgp_bucket *));
mask = p->hash_size - 1;
for (i=0; i<oldn; i++)
while (b = old[i])
{
old[i] = b->hash_next;
e = b->hash & mask;
b->hash_next = new[e];
if (b->hash_next)
b->hash_next->hash_prev = b;
b->hash_prev = NULL;
new[e] = b;
}
mb_free(old);
}
static struct bgp_bucket *
bgp_new_bucket(struct bgp_proto *p, ea_list *new, unsigned hash)
{
struct bgp_bucket *b;
unsigned ea_size = sizeof(ea_list) + new->count * sizeof(eattr);
unsigned ea_size_aligned = BIRD_ALIGN(ea_size, CPU_STRUCT_ALIGN);
unsigned size = sizeof(struct bgp_bucket) + ea_size;
unsigned i;
byte *dest;
unsigned index = hash & (p->hash_size - 1);
/* Gather total size of non-inline attributes */
for (i=0; i<new->count; i++)
{
eattr *a = &new->attrs[i];
if (!(a->type & EAF_EMBEDDED))
size += BIRD_ALIGN(sizeof(struct adata) + a->u.ptr->length, CPU_STRUCT_ALIGN);
}
/* Create the bucket and hash it */
b = mb_alloc(p->p.pool, size);
b->hash_next = p->bucket_hash[index];
if (b->hash_next)
b->hash_next->hash_prev = b;
p->bucket_hash[index] = b;
b->hash_prev = NULL;
b->hash = hash;
add_tail(&p->bucket_queue, &b->send_node);
init_list(&b->prefixes);
memcpy(b->eattrs, new, ea_size);
dest = ((byte *)b->eattrs) + ea_size_aligned;
/* Copy values of non-inline attributes */
for (i=0; i<new->count; i++)
{
eattr *a = &b->eattrs->attrs[i];
if (!(a->type & EAF_EMBEDDED))
{
struct adata *oa = a->u.ptr;
struct adata *na = (struct adata *) dest;
memcpy(na, oa, sizeof(struct adata) + oa->length);
a->u.ptr = na;
dest += BIRD_ALIGN(sizeof(struct adata) + na->length, CPU_STRUCT_ALIGN);
}
}
/* If needed, rehash */
p->hash_count++;
if (p->hash_count > p->hash_limit)
bgp_rehash_buckets(p);
return b;
}
static struct bgp_bucket *
bgp_get_bucket(struct bgp_proto *p, net *n, ea_list *attrs, int originate)
{
ea_list *new;
unsigned i, cnt, hash, code;
eattr *a, *d;
u32 seen = 0;
struct bgp_bucket *b;
/* Merge the attribute list */
new = alloca(ea_scan(attrs));
ea_merge(attrs, new);
ea_sort(new);
/* Normalize attributes */
d = new->attrs;
cnt = new->count;
new->count = 0;
for(i=0; i<cnt; i++)
{
a = &new->attrs[i];
if (EA_PROTO(a->id) != EAP_BGP)
continue;
code = EA_ID(a->id);
if (ATTR_KNOWN(code))
{
if (!bgp_attr_table[code].allow_in_ebgp && !p->is_internal)
continue;
/* The flags might have been zero if the attr was added by filters */
a->flags = (a->flags & BAF_PARTIAL) | bgp_attr_table[code].expected_flags;
if (code < 32)
seen |= 1 << code;
}
else
{
/* Don't re-export unknown non-transitive attributes */
if (!(a->flags & BAF_TRANSITIVE))
continue;
}
*d = *a;
if ((d->type & EAF_ORIGINATED) && !originate && (d->flags & BAF_TRANSITIVE) && (d->flags & BAF_OPTIONAL))
d->flags |= BAF_PARTIAL;
switch (d->type & EAF_TYPE_MASK)
{
case EAF_TYPE_INT_SET:
{
struct adata *z = alloca(sizeof(struct adata) + d->u.ptr->length);
z->length = d->u.ptr->length;
bgp_normalize_int_set((u32 *) z->data, (u32 *) d->u.ptr->data, z->length / 4);
d->u.ptr = z;
break;
}
case EAF_TYPE_EC_SET:
{
struct adata *z = alloca(sizeof(struct adata) + d->u.ptr->length);
z->length = d->u.ptr->length;
bgp_normalize_ec_set(z, (u32 *) d->u.ptr->data, p->is_internal);
d->u.ptr = z;
break;
}
default: ;
}
d++;
new->count++;
}
/* Hash */
hash = ea_hash(new);
for(b=p->bucket_hash[hash & (p->hash_size - 1)]; b; b=b->hash_next)
if (b->hash == hash && ea_same(b->eattrs, new))
{
DBG("Found bucket.\n");
return b;
}
/* Ensure that there are all mandatory attributes */
for(i=0; i<ARRAY_SIZE(bgp_mandatory_attrs); i++)
if (!(seen & (1 << bgp_mandatory_attrs[i])))
{
log(L_ERR "%s: Mandatory attribute %s missing in route %I/%d", p->p.name, bgp_attr_table[bgp_mandatory_attrs[i]].name, n->n.prefix, n->n.pxlen);
return NULL;
}
/* Check if next hop is valid */
a = ea_find(new, EA_CODE(EAP_BGP, BA_NEXT_HOP));
if (!a || ipa_equal(p->cf->remote_ip, *(ip_addr *)a->u.ptr->data))
{
log(L_ERR "%s: Invalid NEXT_HOP attribute in route %I/%d", p->p.name, n->n.prefix, n->n.pxlen);
return NULL;
}
/* Create new bucket */
DBG("Creating bucket.\n");
return bgp_new_bucket(p, new, hash);
}
void
bgp_free_bucket(struct bgp_proto *p, struct bgp_bucket *buck)
{
if (buck->hash_next)
buck->hash_next->hash_prev = buck->hash_prev;
if (buck->hash_prev)
buck->hash_prev->hash_next = buck->hash_next;
else
p->bucket_hash[buck->hash & (p->hash_size-1)] = buck->hash_next;
mb_free(buck);
}
void
bgp_rt_notify(struct proto *P, rtable *tbl UNUSED, net *n, rte *new, rte *old UNUSED, ea_list *attrs)
{
struct bgp_proto *p = (struct bgp_proto *) P;
struct bgp_bucket *buck;
struct bgp_prefix *px;
DBG("BGP: Got route %I/%d %s\n", n->n.prefix, n->n.pxlen, new ? "up" : "down");
if (new)
{
buck = bgp_get_bucket(p, n, attrs, new->attrs->source != RTS_BGP);
if (!buck) /* Inconsistent attribute list */
return;
}
else
{
if (!(buck = p->withdraw_bucket))
{
buck = p->withdraw_bucket = mb_alloc(P->pool, sizeof(struct bgp_bucket));
init_list(&buck->prefixes);
}
}
px = fib_get(&p->prefix_fib, &n->n.prefix, n->n.pxlen);
if (px->bucket_node.next)
{
DBG("\tRemoving old entry.\n");
rem_node(&px->bucket_node);
}
add_tail(&buck->prefixes, &px->bucket_node);
bgp_schedule_packet(p->conn, PKT_UPDATE);
}
static int
bgp_create_attrs(struct bgp_proto *p, rte *e, ea_list **attrs, struct linpool *pool)
{
ea_list *ea = lp_alloc(pool, sizeof(ea_list) + 4*sizeof(eattr));
rta *rta = e->attrs;
byte *z;
ea->next = *attrs;
*attrs = ea;
ea->flags = EALF_SORTED;
ea->count = 4;
bgp_set_attr(ea->attrs, BA_ORIGIN,
((rta->source == RTS_OSPF_EXT1) || (rta->source == RTS_OSPF_EXT2)) ? ORIGIN_INCOMPLETE : ORIGIN_IGP);
if (p->is_internal)
bgp_set_attr_wa(ea->attrs+1, pool, BA_AS_PATH, 0);
else
{
z = bgp_set_attr_wa(ea->attrs+1, pool, BA_AS_PATH, 6);
z[0] = AS_PATH_SEQUENCE;
z[1] = 1; /* 1 AS */
put_u32(z+2, p->local_as);
}
/* iBGP -> use gw, eBGP multi-hop -> use source_addr,
eBGP single-hop -> use gw if on the same iface */
z = bgp_set_attr_wa(ea->attrs+2, pool, BA_NEXT_HOP, NEXT_HOP_LENGTH);
if (p->cf->next_hop_self ||
rta->dest != RTD_ROUTER ||
ipa_equal(rta->gw, IPA_NONE) ||
ipa_has_link_scope(rta->gw) ||
(!p->is_internal && !p->cf->next_hop_keep &&
(!p->neigh || (rta->iface != p->neigh->iface))))
set_next_hop(z, p->source_addr);
else
set_next_hop(z, rta->gw);
bgp_set_attr(ea->attrs+3, BA_LOCAL_PREF, p->cf->default_local_pref);
return 0; /* Leave decision to the filters */
}
static inline int
bgp_as_path_loopy(struct bgp_proto *p, rta *a)
{
eattr *e = ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_AS_PATH));
return (e && as_path_is_member(e->u.ptr, p->local_as));
}
static inline int
bgp_originator_id_loopy(struct bgp_proto *p, rta *a)
{
eattr *e = ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_ORIGINATOR_ID));
return (e && (e->u.data == p->local_id));
}
static inline int
bgp_cluster_list_loopy(struct bgp_proto *p, rta *a)
{
eattr *e = ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_CLUSTER_LIST));
return (e && p->rr_client && int_set_contains(e->u.ptr, p->rr_cluster_id));
}
static inline void
bgp_path_prepend(rte *e, ea_list **attrs, struct linpool *pool, u32 as)
{
eattr *a = ea_find(e->attrs->eattrs, EA_CODE(EAP_BGP, BA_AS_PATH));
bgp_attach_attr(attrs, pool, BA_AS_PATH, (uintptr_t) as_path_prepend(pool, a->u.ptr, as));
}
static inline void
bgp_cluster_list_prepend(rte *e, ea_list **attrs, struct linpool *pool, u32 cid)
{
eattr *a = ea_find(e->attrs->eattrs, EA_CODE(EAP_BGP, BA_CLUSTER_LIST));
bgp_attach_attr(attrs, pool, BA_CLUSTER_LIST, (uintptr_t) int_set_add(pool, a ? a->u.ptr : NULL, cid));
}
static int
bgp_update_attrs(struct bgp_proto *p, rte *e, ea_list **attrs, struct linpool *pool, int rr)
{
eattr *a;
if (!p->is_internal && !p->rs_client)
{
bgp_path_prepend(e, attrs, pool, p->local_as);
/* The MULTI_EXIT_DISC attribute received from a neighboring AS MUST NOT be
* propagated to other neighboring ASes.
* Perhaps it would be better to undefine it.
*/
a = ea_find(e->attrs->eattrs, EA_CODE(EAP_BGP, BA_MULTI_EXIT_DISC));
if (a)
bgp_attach_attr(attrs, pool, BA_MULTI_EXIT_DISC, 0);
}
/* iBGP -> keep next_hop, eBGP multi-hop -> use source_addr,
* eBGP single-hop -> keep next_hop if on the same iface.
* If the next_hop is zero (i.e. link-local), keep only if on the same iface.
*
* Note that same-iface-check uses iface from route, which is based on gw.
*/
a = ea_find(e->attrs->eattrs, EA_CODE(EAP_BGP, BA_NEXT_HOP));
if (a && !p->cf->next_hop_self &&
(p->cf->next_hop_keep ||
(p->is_internal && ipa_nonzero(*((ip_addr *) a->u.ptr->data))) ||
(p->neigh && (e->attrs->iface == p->neigh->iface))))
{
/* Leave the original next hop attribute, will check later where does it point */
}
else
{
/* Need to create new one */
byte *b = bgp_attach_attr_wa(attrs, pool, BA_NEXT_HOP, NEXT_HOP_LENGTH);
set_next_hop(b, p->source_addr);
}
if (rr)
{
/* Handling route reflection, RFC 4456 */
struct bgp_proto *src = (struct bgp_proto *) e->attrs->proto;
a = ea_find(e->attrs->eattrs, EA_CODE(EAP_BGP, BA_ORIGINATOR_ID));
if (!a)
bgp_attach_attr(attrs, pool, BA_ORIGINATOR_ID, src->remote_id);
/* We attach proper cluster ID according to whether the route is entering or leaving the cluster */
bgp_cluster_list_prepend(e, attrs, pool, src->rr_client ? src->rr_cluster_id : p->rr_cluster_id);
/* Two RR clients with different cluster ID, hmmm */
if (src->rr_client && p->rr_client && (src->rr_cluster_id != p->rr_cluster_id))
bgp_cluster_list_prepend(e, attrs, pool, p->rr_cluster_id);
}
return 0; /* Leave decision to the filters */
}
static int
bgp_community_filter(struct bgp_proto *p, rte *e)
{
eattr *a;
struct adata *d;
/* Check if we aren't forbidden to export the route by communities */
a = ea_find(e->attrs->eattrs, EA_CODE(EAP_BGP, BA_COMMUNITY));
if (a)
{
d = a->u.ptr;
if (int_set_contains(d, BGP_COMM_NO_ADVERTISE))
{
DBG("\tNO_ADVERTISE\n");
return 1;
}
if (!p->is_internal &&
(int_set_contains(d, BGP_COMM_NO_EXPORT) ||
int_set_contains(d, BGP_COMM_NO_EXPORT_SUBCONFED)))
{
DBG("\tNO_EXPORT\n");
return 1;
}
}
return 0;
}
int
bgp_import_control(struct proto *P, rte **new, ea_list **attrs, struct linpool *pool)
{
rte *e = *new;
struct bgp_proto *p = (struct bgp_proto *) P;
struct bgp_proto *new_bgp = (e->attrs->proto->proto == &proto_bgp) ? (struct bgp_proto *) e->attrs->proto : NULL;
if (p == new_bgp) /* Poison reverse updates */
return -1;
if (new_bgp)
{
/* We should check here for cluster list loop, because the receiving BGP instance
might have different cluster ID */
if (bgp_cluster_list_loopy(p, e->attrs))
return -1;
if (p->cf->interpret_communities && bgp_community_filter(p, e))
return -1;
if (p->local_as == new_bgp->local_as && p->is_internal && new_bgp->is_internal)
{
/* Redistribution of internal routes with IBGP */
if (p->rr_client || new_bgp->rr_client)
/* Route reflection, RFC 4456 */
return bgp_update_attrs(p, e, attrs, pool, 1);
else
return -1;
}
else
return bgp_update_attrs(p, e, attrs, pool, 0);
}
else
return bgp_create_attrs(p, e, attrs, pool);
}
static inline u32
bgp_get_neighbor(rte *r)
{
eattr *e = ea_find(r->attrs->eattrs, EA_CODE(EAP_BGP, BA_AS_PATH));
u32 as;
if (e && as_path_get_first(e->u.ptr, &as))
return as;
else
return ((struct bgp_proto *) r->attrs->proto)->remote_as;
}
static inline int
rte_resolvable(rte *rt)
{
int rd = rt->attrs->dest;
return (rd == RTD_ROUTER) || (rd == RTD_DEVICE) || (rd == RTD_MULTIPATH);
}
int
bgp_rte_better(rte *new, rte *old)
{
struct bgp_proto *new_bgp = (struct bgp_proto *) new->attrs->proto;
struct bgp_proto *old_bgp = (struct bgp_proto *) old->attrs->proto;
eattr *x, *y;
u32 n, o;
/* Skip suppressed routes (see bgp_rte_recalculate()) */
n = new->u.bgp.suppressed;
o = old->u.bgp.suppressed;
if (n > o)
return 0;
if (n < o)
return 1;
/* RFC 4271 9.1.2.1. Route resolvability test */
n = rte_resolvable(new);
o = rte_resolvable(old);
if (n > o)
return 1;
if (n < o)
return 0;
/* Start with local preferences */
x = ea_find(new->attrs->eattrs, EA_CODE(EAP_BGP, BA_LOCAL_PREF));
y = ea_find(old->attrs->eattrs, EA_CODE(EAP_BGP, BA_LOCAL_PREF));
n = x ? x->u.data : new_bgp->cf->default_local_pref;
o = y ? y->u.data : old_bgp->cf->default_local_pref;
if (n > o)
return 1;
if (n < o)
return 0;
/* RFC 4271 9.1.2.2. a) Use AS path lengths */
if (new_bgp->cf->compare_path_lengths || old_bgp->cf->compare_path_lengths)
{
x = ea_find(new->attrs->eattrs, EA_CODE(EAP_BGP, BA_AS_PATH));
y = ea_find(old->attrs->eattrs, EA_CODE(EAP_BGP, BA_AS_PATH));
n = x ? as_path_getlen(x->u.ptr) : AS_PATH_MAXLEN;
o = y ? as_path_getlen(y->u.ptr) : AS_PATH_MAXLEN;
if (n < o)
return 1;
if (n > o)
return 0;
}
/* RFC 4271 9.1.2.2. b) Use origins */
x = ea_find(new->attrs->eattrs, EA_CODE(EAP_BGP, BA_ORIGIN));
y = ea_find(old->attrs->eattrs, EA_CODE(EAP_BGP, BA_ORIGIN));
n = x ? x->u.data : ORIGIN_INCOMPLETE;
o = y ? y->u.data : ORIGIN_INCOMPLETE;
if (n < o)
return 1;
if (n > o)
return 0;
/* RFC 4271 9.1.2.2. c) Compare MED's */
/* Proper RFC 4271 path selection cannot be interpreted as finding
* the best path in some ordering. It is implemented partially in
* bgp_rte_recalculate() when deterministic_med option is
* active. Without that option, the behavior is just an
* approximation, which in specific situations may lead to
* persistent routing loops, because it is nondeterministic - it
* depends on the order in which routes appeared. But it is also the
* same behavior as used by default in Cisco routers, so it is
* probably not a big issue.
*/
if (new_bgp->cf->med_metric || old_bgp->cf->med_metric ||
(bgp_get_neighbor(new) == bgp_get_neighbor(old)))
{
x = ea_find(new->attrs->eattrs, EA_CODE(EAP_BGP, BA_MULTI_EXIT_DISC));
y = ea_find(old->attrs->eattrs, EA_CODE(EAP_BGP, BA_MULTI_EXIT_DISC));
n = x ? x->u.data : new_bgp->cf->default_med;
o = y ? y->u.data : old_bgp->cf->default_med;
if (n < o)
return 1;
if (n > o)
return 0;
}
/* RFC 4271 9.1.2.2. d) Prefer external peers */
if (new_bgp->is_internal > old_bgp->is_internal)
return 0;
if (new_bgp->is_internal < old_bgp->is_internal)
return 1;
/* RFC 4271 9.1.2.2. e) Compare IGP metrics */
n = new_bgp->cf->igp_metric ? new->attrs->igp_metric : 0;
o = old_bgp->cf->igp_metric ? old->attrs->igp_metric : 0;
if (n < o)
return 1;
if (n > o)
return 0;
/* RFC 4271 9.1.2.2. f) Compare BGP identifiers */
/* RFC 4456 9. a) Use ORIGINATOR_ID instead of local neighor ID */
x = ea_find(new->attrs->eattrs, EA_CODE(EAP_BGP, BA_ORIGINATOR_ID));
y = ea_find(old->attrs->eattrs, EA_CODE(EAP_BGP, BA_ORIGINATOR_ID));
n = x ? x->u.data : new_bgp->remote_id;
o = y ? y->u.data : old_bgp->remote_id;
/* RFC 5004 - prefer older routes */
/* (if both are external and from different peer) */
if ((new_bgp->cf->prefer_older || old_bgp->cf->prefer_older) &&
!new_bgp->is_internal && n != o)
return 0;
/* rest of RFC 4271 9.1.2.2. f) */
if (n < o)
return 1;
if (n > o)
return 0;
/* RFC 4456 9. b) Compare cluster list lengths */
x = ea_find(new->attrs->eattrs, EA_CODE(EAP_BGP, BA_CLUSTER_LIST));
y = ea_find(old->attrs->eattrs, EA_CODE(EAP_BGP, BA_CLUSTER_LIST));
n = x ? int_set_get_size(x->u.ptr) : 0;
o = y ? int_set_get_size(y->u.ptr) : 0;
if (n < o)
return 1;
if (n > o)
return 0;
/* RFC 4271 9.1.2.2. g) Compare peer IP adresses */
return (ipa_compare(new_bgp->cf->remote_ip, old_bgp->cf->remote_ip) < 0);
}
static inline int
same_group(rte *r, u32 lpref, u32 lasn)
{
return (r->pref == lpref) && (bgp_get_neighbor(r) == lasn);
}
static inline int
use_deterministic_med(rte *r)
{
struct proto *P = r->attrs->proto;
return (P->proto == &proto_bgp) && ((struct bgp_proto *) P)->cf->deterministic_med;
}
int
bgp_rte_recalculate(rtable *table, net *net, rte *new, rte *old, rte *old_best)
{
rte *r, *s;
rte *key = new ? new : old;
u32 lpref = key->pref;
u32 lasn = bgp_get_neighbor(key);
int old_is_group_best = 0;
/*
* Proper RFC 4271 path selection is a bit complicated, it cannot be
* implemented just by rte_better(), because it is not a linear
* ordering. But it can be splitted to two levels, where the lower
* level chooses the best routes in each group of routes from the
* same neighboring AS and higher level chooses the best route (with
* a slightly different ordering) between the best-in-group routes.
*
* When deterministic_med is disabled, we just ignore this issue and
* choose the best route by bgp_rte_better() alone. If enabled, the
* lower level of the route selection is done here (for the group
* to which the changed route belongs), all routes in group are
* marked as suppressed, just chosen best-in-group is not.
*
* Global best route selection then implements higher level by
* choosing between non-suppressed routes (as they are always
* preferred over suppressed routes). Routes from BGP protocols
* that do not set deterministic_med are just never suppressed. As
* they do not participate in the lower level selection, it is OK
* that this fn is not called for them.
*
* The idea is simple, the implementation is more problematic,
* mostly because of optimizations in rte_recalculate() that
* avoids full recalculation in most cases.
*
* We can assume that at least one of new, old is non-NULL and both
* are from the same protocol with enabled deterministic_med. We
* group routes by both neighbor AS (lasn) and preference (lpref),
* because bgp_rte_better() does not handle preference itself.
*/
/* If new and old are from different groups, we just process that
as two independent events */
if (new && old && !same_group(old, lpref, lasn))
{
int i1, i2;
i1 = bgp_rte_recalculate(table, net, NULL, old, old_best);
i2 = bgp_rte_recalculate(table, net, new, NULL, old_best);
return i1 || i2;
}
/*
* We could find the best-in-group and then make some shortcuts like
* in rte_recalculate, but as we would have to walk through all
* net->routes just to find it, it is probably not worth. So we
* just have two simpler fast cases that use just the old route.
* We also set suppressed flag to avoid using it in bgp_rte_better().
*/
if (new)
new->u.bgp.suppressed = 1;
if (old)
{
old_is_group_best = !old->u.bgp.suppressed;
old->u.bgp.suppressed = 1;
int new_is_better = new && bgp_rte_better(new, old);
/* The first case - replace not best with worse (or remove not best) */
if (!old_is_group_best && !new_is_better)
return 0;
/* The second case - replace the best with better */
if (old_is_group_best && new_is_better)
{
/* new is best-in-group, the see discussion below - this is
a special variant of NBG && OBG. From OBG we can deduce
that same_group(old_best) iff (old == old_best) */
new->u.bgp.suppressed = 0;
return (old == old_best);
}
}
/* The default case - find a new best-in-group route */
r = new; /* new may not be in the list */
for (s=net->routes; rte_is_valid(s); s=s->next)
if (use_deterministic_med(s) && same_group(s, lpref, lasn))
{
s->u.bgp.suppressed = 1;
if (!r || bgp_rte_better(s, r))
r = s;
}
/* Simple case - the last route in group disappears */
if (!r)
return 0;
/* Found best-in-group */
r->u.bgp.suppressed = 0;
/*
* There are generally two reasons why we have to force
* recalculation (return 1): First, the new route may be wrongfully
* chosen to be the best in the first case check in
* rte_recalculate(), this may happen only if old_best is from the
* same group. Second, another (different than new route)
* best-in-group is chosen and that may be the proper best (although
* rte_recalculate() without ignore that possibility).
*
* There are three possible cases according to whether the old route
* was the best in group (OBG, stored in old_is_group_best) and
* whether the new route is the best in group (NBG, tested by r == new).
* These cases work even if old or new is NULL.
*
* NBG -> new is a possible candidate for the best route, so we just
* check for the first reason using same_group().
*
* !NBG && OBG -> Second reason applies, return 1
*
* !NBG && !OBG -> Best in group does not change, old != old_best,
* rte_better(new, old_best) is false and therefore
* the first reason does not apply, return 0
*/
if (r == new)
return old_best && same_group(old_best, lpref, lasn);
else
return old_is_group_best;
}
static struct adata *
bgp_aggregator_convert_to_new(struct adata *old, struct linpool *pool)
{
struct adata *newa = lp_alloc(pool, sizeof(struct adata) + 8);
newa->length = 8;
aggregator_convert_to_new(old, newa->data);
return newa;
}
/* Take last req_as ASNs from path old2 (in 2B format), convert to 4B format
* and append path old4 (in 4B format).
*/
static struct adata *
bgp_merge_as_paths(struct adata *old2, struct adata *old4, int req_as, struct linpool *pool)
{
byte buf[old2->length * 2];
int ol = as_path_convert_to_new(old2, buf, req_as);
int nl = ol + (old4 ? old4->length : 0);
struct adata *newa = lp_alloc(pool, sizeof(struct adata) + nl);
newa->length = nl;
memcpy(newa->data, buf, ol);
if (old4) memcpy(newa->data + ol, old4->data, old4->length);
return newa;
}
static int
as4_aggregator_valid(struct adata *aggr)
{
return aggr->length == 8;
}
/* Reconstruct 4B AS_PATH and AGGREGATOR according to RFC 4893 4.2.3 */
static void
bgp_reconstruct_4b_atts(struct bgp_proto *p, rta *a, struct linpool *pool)
{
eattr *p2 =ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_AS_PATH));
eattr *p4 =ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_AS4_PATH));
eattr *a2 =ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_AGGREGATOR));
eattr *a4 =ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_AS4_AGGREGATOR));
int a4_removed = 0;
if (a4 && !as4_aggregator_valid(a4->u.ptr))
{
log(L_WARN "%s: AS4_AGGREGATOR attribute is invalid, skipping attribute", p->p.name);
a4 = NULL;
a4_removed = 1;
}
if (a2)
{
u32 a2_as = get_u16(a2->u.ptr->data);
if (a4)
{
if (a2_as != AS_TRANS)
{
/* Routes were aggregated by old router and therefore AS4_PATH
* and AS4_AGGREGATOR is invalid
*
* Convert AS_PATH and AGGREGATOR to 4B format and finish.
*/
a2->u.ptr = bgp_aggregator_convert_to_new(a2->u.ptr, pool);
p2->u.ptr = bgp_merge_as_paths(p2->u.ptr, NULL, AS_PATH_MAXLEN, pool);
return;
}
else
{
/* Common case, use AS4_AGGREGATOR attribute */
a2->u.ptr = a4->u.ptr;
}
}
else
{
/* Common case, use old AGGREGATOR attribute */
a2->u.ptr = bgp_aggregator_convert_to_new(a2->u.ptr, pool);
if ((a2_as == AS_TRANS) && !a4_removed)
log(L_WARN "%s: AGGREGATOR attribute contain AS_TRANS, but AS4_AGGREGATOR is missing", p->p.name);
}
}
else
if (a4)
log(L_WARN "%s: AS4_AGGREGATOR attribute received, but AGGREGATOR attribute is missing", p->p.name);
int p2_len = as_path_getlen_int(p2->u.ptr, 2);
int p4_len = p4 ? validate_as4_path(p, p4->u.ptr) : -1;
if (p4 && (p4_len < 0))
log(L_WARN "%s: AS4_PATH attribute is malformed, skipping attribute", p->p.name);
if ((p4_len <= 0) || (p2_len < p4_len))
p2->u.ptr = bgp_merge_as_paths(p2->u.ptr, NULL, AS_PATH_MAXLEN, pool);
else
p2->u.ptr = bgp_merge_as_paths(p2->u.ptr, p4->u.ptr, p2_len - p4_len, pool);
}
static void
bgp_remove_as4_attrs(struct bgp_proto *p, rta *a)
{
unsigned id1 = EA_CODE(EAP_BGP, BA_AS4_PATH);
unsigned id2 = EA_CODE(EAP_BGP, BA_AS4_AGGREGATOR);
ea_list **el = &(a->eattrs);
/* We know that ea_lists constructed in bgp_decode attrs have one attribute per ea_list struct */
while (*el != NULL)
{
unsigned fid = (*el)->attrs[0].id;
if ((fid == id1) || (fid == id2))
{
*el = (*el)->next;
if (p->as4_session)
log(L_WARN "%s: Unexpected AS4_* attributes received", p->p.name);
}
else
el = &((*el)->next);
}
}
/**
* bgp_decode_attrs - check and decode BGP attributes
* @conn: connection
* @attr: start of attribute block
* @len: length of attribute block
* @pool: linear pool to make all the allocations in
* @mandatory: 1 iff presence of mandatory attributes has to be checked
*
* This function takes a BGP attribute block (a part of an Update message), checks
* its consistency and converts it to a list of BIRD route attributes represented
* by a &rta.
*/
struct rta *
bgp_decode_attrs(struct bgp_conn *conn, byte *attr, unsigned int len, struct linpool *pool, int mandatory)
{
struct bgp_proto *bgp = conn->bgp;
rta *a = lp_alloc(pool, sizeof(struct rta));
unsigned int flags, code, l, i, type;
int errcode;
byte *z, *attr_start;
byte seen[256/8];
ea_list *ea;
struct adata *ad;
int withdraw = 0;
bzero(a, sizeof(rta));
a->proto = &bgp->p;
a->source = RTS_BGP;
a->scope = SCOPE_UNIVERSE;
a->cast = RTC_UNICAST;
/* a->dest = RTD_ROUTER; -- set in bgp_set_next_hop() */
a->from = bgp->cf->remote_ip;
/* Parse the attributes */
bzero(seen, sizeof(seen));
DBG("BGP: Parsing attributes\n");
while (len)
{
if (len < 2)
goto malformed;
attr_start = attr;
flags = *attr++;
code = *attr++;
len -= 2;
if (flags & BAF_EXT_LEN)
{
if (len < 2)
goto malformed;
l = get_u16(attr);
attr += 2;
len -= 2;
}
else
{
if (len < 1)
goto malformed;
l = *attr++;
len--;
}
if (l > len)
goto malformed;
len -= l;
z = attr;
attr += l;
DBG("Attr %02x %02x %d\n", code, flags, l);
if (seen[code/8] & (1 << (code%8)))
goto malformed;
if (ATTR_KNOWN(code))
{
struct attr_desc *desc = &bgp_attr_table[code];
if (desc->expected_length >= 0 && desc->expected_length != (int) l)
{ errcode = 5; goto err; }
if ((desc->expected_flags ^ flags) & (BAF_OPTIONAL | BAF_TRANSITIVE))
{ errcode = 4; goto err; }
if (!desc->allow_in_ebgp && !bgp->is_internal)
continue;
if (desc->validate)
{
errcode = desc->validate(bgp, z, l);
if (errcode > 0)
goto err;
if (errcode == IGNORE)
continue;
if (errcode <= WITHDRAW)
{
log(L_WARN "%s: Attribute %s is malformed, withdrawing update",
bgp->p.name, desc->name);
withdraw = 1;
}
}
else if (code == BA_AS_PATH)
{
/* Special case as it might also trim the attribute */
if (validate_as_path(bgp, z, &l) < 0)
{ errcode = 11; goto err; }
}
type = desc->type;
}
else /* Unknown attribute */
{
if (!(flags & BAF_OPTIONAL))
{ errcode = 2; goto err; }
type = EAF_TYPE_OPAQUE;
}
// Only OPTIONAL and TRANSITIVE attributes may have non-zero PARTIAL flag
// if (!((flags & BAF_OPTIONAL) && (flags & BAF_TRANSITIVE)) && (flags & BAF_PARTIAL))
// { errcode = 4; goto err; }
seen[code/8] |= (1 << (code%8));
ea = lp_alloc(pool, sizeof(ea_list) + sizeof(eattr));
ea->next = a->eattrs;
a->eattrs = ea;
ea->flags = 0;
ea->count = 1;
ea->attrs[0].id = EA_CODE(EAP_BGP, code);
ea->attrs[0].flags = flags;
ea->attrs[0].type = type;
if (type & EAF_EMBEDDED)
ad = NULL;
else
{
ad = lp_alloc(pool, sizeof(struct adata) + l);
ea->attrs[0].u.ptr = ad;
ad->length = l;
memcpy(ad->data, z, l);
}
switch (type)
{
case EAF_TYPE_ROUTER_ID:
case EAF_TYPE_INT:
if (l == 1)
ea->attrs[0].u.data = *z;
else
ea->attrs[0].u.data = get_u32(z);
break;
case EAF_TYPE_IP_ADDRESS:
ipa_ntoh(*(ip_addr *)ad->data);
break;
case EAF_TYPE_INT_SET:
case EAF_TYPE_EC_SET:
{
u32 *z = (u32 *) ad->data;
for(i=0; i<ad->length/4; i++)
z[i] = ntohl(z[i]);
break;
}
}
}
if (withdraw)
goto withdraw;
#ifdef IPV6
/* If we received MP_REACH_NLRI we should check mandatory attributes */
if (bgp->mp_reach_len != 0)
mandatory = 1;
#endif
/* If there is no (reachability) NLRI, we should exit now */
if (! mandatory)
return a;
/* Check if all mandatory attributes are present */
for(i=0; i < ARRAY_SIZE(bgp_mandatory_attrs); i++)
{
code = bgp_mandatory_attrs[i];
if (!(seen[code/8] & (1 << (code%8))))
{
bgp_error(conn, 3, 3, &bgp_mandatory_attrs[i], 1);
return NULL;
}
}
/* When receiving attributes from non-AS4-aware BGP speaker,
* we have to reconstruct 4B AS_PATH and AGGREGATOR attributes
*/
if (! bgp->as4_session)
bgp_reconstruct_4b_atts(bgp, a, pool);
bgp_remove_as4_attrs(bgp, a);
/* If the AS path attribute contains our AS, reject the routes */
if (bgp_as_path_loopy(bgp, a))
goto withdraw;
/* Two checks for IBGP loops caused by route reflection, RFC 4456 */
if (bgp_originator_id_loopy(bgp, a) ||
bgp_cluster_list_loopy(bgp, a))
goto withdraw;
/* If there's no local preference, define one */
if (!(seen[0] & (1 << BA_LOCAL_PREF)))
bgp_attach_attr(&a->eattrs, pool, BA_LOCAL_PREF, bgp->cf->default_local_pref);
return a;
withdraw:
return NULL;
malformed:
bgp_error(conn, 3, 1, NULL, 0);
return NULL;
err:
bgp_error(conn, 3, errcode, attr_start, z+l-attr_start);
return NULL;
}
int
bgp_get_attr(eattr *a, byte *buf, int buflen)
{
unsigned int i = EA_ID(a->id);
struct attr_desc *d;
int len;
if (ATTR_KNOWN(i))
{
d = &bgp_attr_table[i];
len = bsprintf(buf, "%s", d->name);
buf += len;
if (d->format)
{
*buf++ = ':';
*buf++ = ' ';
d->format(a, buf, buflen - len - 2);
return GA_FULL;
}
return GA_NAME;
}
bsprintf(buf, "%02x%s", i, (a->flags & BAF_TRANSITIVE) ? " [t]" : "");
return GA_NAME;
}
void
bgp_attr_init(struct bgp_proto *p)
{
p->hash_size = 256;
p->hash_limit = p->hash_size * 4;
p->bucket_hash = mb_allocz(p->p.pool, p->hash_size * sizeof(struct bgp_bucket *));
init_list(&p->bucket_queue);
p->withdraw_bucket = NULL;
fib_init(&p->prefix_fib, p->p.pool, sizeof(struct bgp_prefix), 0, bgp_init_prefix);
}
void
bgp_get_route_info(rte *e, byte *buf, ea_list *attrs)
{
eattr *p = ea_find(attrs, EA_CODE(EAP_BGP, BA_AS_PATH));
eattr *o = ea_find(attrs, EA_CODE(EAP_BGP, BA_ORIGIN));
u32 origas;
buf += bsprintf(buf, " (%d", e->pref);
if (e->u.bgp.suppressed)
buf += bsprintf(buf, "-");
if (e->attrs->hostentry)
{
if (!rte_resolvable(e))
buf += bsprintf(buf, "/-");
else if (e->attrs->igp_metric >= IGP_METRIC_UNKNOWN)
buf += bsprintf(buf, "/?");
else
buf += bsprintf(buf, "/%d", e->attrs->igp_metric);
}
buf += bsprintf(buf, ") [");
if (p && as_path_get_last(p->u.ptr, &origas))
buf += bsprintf(buf, "AS%u", origas);
if (o)
buf += bsprintf(buf, "%c", "ie?"[o->u.data]);
strcpy(buf, "]");
}