bird/proto/ospf/lsalib.c

/*
 *	BIRD -- OSPF
 *
 *	(c) 1999--2004 Ondrej Filip <feela@network.cz>
 *	(c) 2009--2015 Ondrej Zajicek <santiago@crfreenet.org>
 *	(c) 2009--2015 CZ.NIC z.s.p.o.
 *
 *	Can be freely distributed and used under the terms of the GNU GPL.
 */

#include "ospf.h"

#include "lib/fletcher16.h"

#ifndef CPU_BIG_ENDIAN
void
lsa_hton_hdr(struct ospf_lsa_header *h, struct ospf_lsa_header *n)
{
  n->age = htons(h->age);
  n->type_raw = htons(h->type_raw);
  n->id = htonl(h->id);
  n->rt = htonl(h->rt);
  n->sn = htonl(h->sn);
  n->checksum = htons(h->checksum);
  n->length = htons(h->length);
}

void
lsa_ntoh_hdr(struct ospf_lsa_header *n, struct ospf_lsa_header *h)
{
  h->age = ntohs(n->age);
  h->type_raw = ntohs(n->type_raw);
  h->id = ntohl(n->id);
  h->rt = ntohl(n->rt);
  h->sn = ntohl(n->sn);
  h->checksum = ntohs(n->checksum);
  h->length = ntohs(n->length);
}

void
lsa_hton_body(void *h, void *n, u16 len)
{
  u32 *hid = h;
  u32 *nid = n;
  uint i;

  for (i = 0; i < (len / sizeof(u32)); i++)
    nid[i] = htonl(hid[i]);
}

void
lsa_ntoh_body(void *n, void *h, u16 len)
{
  u32 *nid = n;
  u32 *hid = h;
  uint i;

  for (i = 0; i < (len / sizeof(u32)); i++)
    hid[i] = ntohl(nid[i]);
}
#endif /* little endian */



int
lsa_flooding_allowed(u32 type, u32 domain, struct ospf_iface *ifa)
{
  /* Handle inactive vlinks */
  if (ifa->state == OSPF_IS_DOWN)
    return 0;

  /* 4.5.2 (Case 2) */
  switch (LSA_SCOPE(type))
  {
  case LSA_SCOPE_LINK:
    return ifa->iface_id == domain;

  case LSA_SCOPE_AREA:
    return ifa->oa->areaid == domain;

  case LSA_SCOPE_AS:
    if (ifa->type == OSPF_IT_VLINK)
      return 0;
    if (!oa_is_ext(ifa->oa))
      return 0;
    return 1;

  default:
    log(L_ERR "OSPF: LSA with invalid scope");
    return 0;
  }
}

int
lsa_is_acceptable(u32 type, struct ospf_neighbor *n, struct ospf_proto *p)
{
  if (ospf_is_v2(p))
  {
    if (type == LSA_T_NSSA)
      return !!(n->options & OPT_N);

    if (lsa_is_opaque(type))
      return !!(n->options & OPT_O);

    return 1;
  }
  else
  {
    /*
     * There should be check whether receiving router understands that type
     * of LSA (for LSA types with U-bit == 0). But as we do not support any
     * optional LSA types, this is not needed yet.
     */

    return 1;
  }
}

static int
unknown_lsa_type(u32 type)
{
  switch (type)
  {
  case LSA_T_RT:
  case LSA_T_NET:
  case LSA_T_SUM_NET:
  case LSA_T_SUM_RT:
  case LSA_T_EXT:
  case LSA_T_NSSA:
  case LSA_T_LINK:
  case LSA_T_PREFIX:
  case LSA_T_RI_LINK:
  case LSA_T_RI_AREA:
  case LSA_T_RI_AS:
    return 0;

  default:
    return 1;
  }
}

/* Maps OSPFv2 types to OSPFv3 types */
static const u16 lsa_v2_types[] = {
  0, LSA_T_RT, LSA_T_NET, LSA_T_SUM_NET, LSA_T_SUM_RT, LSA_T_EXT, 0, LSA_T_NSSA,
  0, LSA_T_OPAQUE_LINK, LSA_T_OPAQUE_AREA, LSA_T_OPAQUE_AS
};

/* Maps OSPFv2 opaque types to OSPFv3 function codes */
static const u16 opaque_lsa_types[] = {
  [LSA_OT_RI] = LSA_T_RI_,
};

/* Maps (subset of) OSPFv3 function codes to OSPFv2 opaque types */
static const u8 opaque_lsa_types_inv[] = {
  [LSA_T_RI_] = LSA_OT_RI,
};

#define LOOKUP(a, i) ({ uint _i = (i); (_i < ARRAY_SIZE(a)) ? a[_i] : 0; })

void
lsa_get_type_domain_(u32 type, u32 id, struct ospf_iface *ifa, u32 *otype, u32 *domain)
{
  if (ospf_is_v2(ifa->oa->po))
  {
    type = type & LSA_T_V2_MASK;
    type = LOOKUP(lsa_v2_types, type);

    uint code;
    if (LSA_FUNCTION(type) == LSA_T_OPAQUE_)
      if (code = LOOKUP(opaque_lsa_types, id >> 24))
	type = code | LSA_UBIT | LSA_SCOPE(type);
  }
  else
  {
    /* For unkown LSAs without U-bit change scope to LSA_SCOPE_LINK */
    if (unknown_lsa_type(type) && !(type & LSA_UBIT))
      type = type & ~LSA_SCOPE_MASK;
  }

  *otype = type;

  switch (LSA_SCOPE(type))
  {
  case LSA_SCOPE_LINK:
    *domain = ifa->iface_id;
    return;

  case LSA_SCOPE_AREA:
    *domain = ifa->oa->areaid;
    return;

  case LSA_SCOPE_AS:
  default:
    *domain = 0;
    return;
  }
}

u32
lsa_get_opaque_type(u32 type)
{
  return LOOKUP(opaque_lsa_types_inv, LSA_FUNCTION(type));
}


void
lsa_generate_checksum(struct ospf_lsa_header *lsa, const u8 *body)
{
  struct fletcher16_context ctx;
  struct ospf_lsa_header hdr;
  u16 len = lsa->length;

  /*
   * lsa and body are in the host order, we need to compute Fletcher-16 checksum
   * for data in the network order. We also skip the initial age field.
   */

  lsa_hton_hdr(lsa, &hdr);
  hdr.checksum = 0;

  fletcher16_init(&ctx);
  fletcher16_update(&ctx, (u8 *) &hdr + 2, sizeof(struct ospf_lsa_header) - 2);
  fletcher16_update_n32(&ctx, body, len - sizeof(struct ospf_lsa_header));
  lsa->checksum = fletcher16_final(&ctx, len, OFFSETOF(struct ospf_lsa_header, checksum));
}

u16
lsa_verify_checksum(const void *lsa_n, int lsa_len)
{
  struct fletcher16_context ctx;

  /* The whole LSA is at lsa_n in net order, we just skip initial age field */

  fletcher16_init(&ctx);
  fletcher16_update(&ctx, (u8 *) lsa_n + 2, lsa_len - 2);

  return fletcher16_compute(&ctx) == 0;
}


int
lsa_comp(struct ospf_lsa_header *l1, struct ospf_lsa_header *l2)
			/* Return codes from point of view of l1 */
{
  u32 sn1, sn2;

  sn1 = l1->sn - LSA_INITSEQNO + 1;
  sn2 = l2->sn - LSA_INITSEQNO + 1;

  if (sn1 > sn2)
    return CMP_NEWER;
  if (sn1 < sn2)
    return CMP_OLDER;

  if (l1->checksum != l2->checksum)
    return l1->checksum < l2->checksum ? CMP_OLDER : CMP_NEWER;

  if ((l1->age == LSA_MAXAGE) && (l2->age != LSA_MAXAGE))
    return CMP_NEWER;
  if ((l2->age == LSA_MAXAGE) && (l1->age != LSA_MAXAGE))
    return CMP_OLDER;

  if (ABS(l1->age - l2->age) > LSA_MAXAGEDIFF)
    return l1->age < l2->age ? CMP_NEWER : CMP_OLDER;

  return CMP_SAME;
}


static inline int
lsa_walk_rt2(struct ospf_lsa_rt_walk *rt)
{
  if (rt->buf >= rt->bufend)
    return 0;

  struct ospf_lsa_rt2_link *l = rt->buf;
  rt->buf += sizeof(struct ospf_lsa_rt2_link) + l->no_tos * sizeof(struct ospf_lsa_rt2_tos);

  rt->type = l->type;
  rt->metric = l->metric;
  rt->id = l->id;
  rt->data = l->data;
  return 1;
}

static inline int
lsa_walk_rt3(struct ospf_lsa_rt_walk *rt)
{
  while (rt->buf >= rt->bufend)
  {
    rt->en = ospf_hash_find_rt3_next(rt->en);
    if (!rt->en)
      return 0;

    rt->buf = rt->en->lsa_body;
    rt->bufend = rt->buf + rt->en->lsa.length - sizeof(struct ospf_lsa_header);
    rt->buf += sizeof(struct ospf_lsa_rt);
  }

  struct ospf_lsa_rt3_link *l = rt->buf;
  rt->buf += sizeof(struct ospf_lsa_rt3_link);

  rt->type = l->type;
  rt->metric = l->metric;
  rt->lif = l->lif;
  rt->nif = l->nif;
  rt->id = l->id;
  return 1;
}

void
lsa_walk_rt_init(struct ospf_proto *p, struct top_hash_entry *act, struct ospf_lsa_rt_walk *rt)
{
  rt->ospf2 = ospf_is_v2(p);
  rt->id = rt->data = rt->lif = rt->nif = 0;

  if (rt->ospf2)
    rt->en = act;
  else
    rt->en = ospf_hash_find_rt3_first(p->gr, act->domain, act->lsa.rt);

  rt->buf = rt->en->lsa_body;
  rt->bufend = rt->buf + rt->en->lsa.length - sizeof(struct ospf_lsa_header);
  rt->buf += sizeof(struct ospf_lsa_rt);
}

int
lsa_walk_rt(struct ospf_lsa_rt_walk *rt)
{
  return rt->ospf2 ? lsa_walk_rt2(rt) : lsa_walk_rt3(rt);
}


void
lsa_parse_sum_net(struct top_hash_entry *en, int ospf2, int af, net_addr *net, u8 *pxopts, u32 *metric)
{
  if (ospf2)
  {
    struct ospf_lsa_sum2 *ls = en->lsa_body;
    net_fill_ip4(net, ip4_from_u32(en->lsa.id & ls->netmask), u32_masklen(ls->netmask));
    *pxopts = 0;
    *metric = ls->metric & LSA_METRIC_MASK;
  }
  else
  {
    struct ospf_lsa_sum3_net *ls = en->lsa_body;
    ospf3_get_prefix(ls->prefix, af, net, pxopts, NULL);
    *metric = ls->metric & LSA_METRIC_MASK;
  }
}

void
lsa_parse_sum_rt(struct top_hash_entry *en, int ospf2, u32 *drid, u32 *metric, u32 *options)
{
  if (ospf2)
  {
    struct ospf_lsa_sum2 *ls = en->lsa_body;
    *drid = en->lsa.id;
    *metric = ls->metric & LSA_METRIC_MASK;
    *options = 0;
  }
  else
  {
    struct ospf_lsa_sum3_rt *ls = en->lsa_body;
    *drid = ls->drid;
    *metric = ls->metric & LSA_METRIC_MASK;
    *options = ls->options & LSA_OPTIONS_MASK;
  }
}

void
lsa_parse_ext(struct top_hash_entry *en, int ospf2, int af, struct ospf_lsa_ext_local *rt)
{
  if (ospf2)
  {
    struct ospf_lsa_ext2 *ext = en->lsa_body;
    net_fill_ip4(&rt->net,
		 ip4_from_u32(en->lsa.id & ext->netmask),
		 u32_masklen(ext->netmask));
    rt->pxopts = 0;
    rt->metric = ext->metric & LSA_METRIC_MASK;
    rt->ebit = ext->metric & LSA_EXT2_EBIT;

    rt->fbit = ext->fwaddr;
    rt->fwaddr = ipa_from_u32(ext->fwaddr);

    rt->tag = ext->tag;
    rt->propagate = lsa_get_options(&en->lsa) & OPT_P;
  }
  else
  {
    struct ospf_lsa_ext3 *ext = en->lsa_body;
    u32 *buf = ospf3_get_prefix(ext->rest, af, &rt->net, &rt->pxopts, NULL);
    rt->metric = ext->metric & LSA_METRIC_MASK;
    rt->ebit = ext->metric & LSA_EXT3_EBIT;

    rt->fbit = ext->metric & LSA_EXT3_FBIT;
    if (rt->fbit)
      buf = ospf3_get_addr(buf, af, &rt->fwaddr);
    else
      rt->fwaddr = IPA_NONE;

    rt->tag = (ext->metric & LSA_EXT3_TBIT) ? *buf++ : 0;
    rt->propagate = rt->pxopts & OPT_PX_P;
  }
}

#define HDRLEN sizeof(struct ospf_lsa_header)

static int
lsa_validate_rt2(struct ospf_lsa_header *lsa, struct ospf_lsa_rt *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_rt)))
    return 0;

  uint i = 0;
  void *buf = body;
  void *bufend = buf + lsa->length - HDRLEN;
  buf += sizeof(struct ospf_lsa_rt);

  while (buf < bufend)
  {
    struct ospf_lsa_rt2_link *l = buf;
    buf += sizeof(struct ospf_lsa_rt2_link) + l->no_tos * sizeof(struct ospf_lsa_rt2_tos);
    i++;

    if (buf > bufend)
      return 0;

    if (!((l->type == LSART_PTP) ||
	  (l->type == LSART_NET) ||
	  (l->type == LSART_STUB) ||
	  (l->type == LSART_VLNK)))
      return 0;
  }

  if ((body->options & LSA_RT2_LINKS) != i)
    return 0;

  return 1;
}


static int
lsa_validate_rt3(struct ospf_lsa_header *lsa, struct ospf_lsa_rt *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_rt)))
    return 0;

  void *buf = body;
  void *bufend = buf + lsa->length - HDRLEN;
  buf += sizeof(struct ospf_lsa_rt);

  while (buf < bufend)
  {
    struct ospf_lsa_rt3_link *l = buf;
    buf += sizeof(struct ospf_lsa_rt3_link);

    if (buf > bufend)
      return 0;

    if (!((l->type == LSART_PTP) ||
	  (l->type == LSART_NET) ||
	  (l->type == LSART_VLNK)))
      return 0;
  }
  return 1;
}

static int
lsa_validate_net(struct ospf_lsa_header *lsa, struct ospf_lsa_net *body UNUSED)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_net)))
    return 0;

  return 1;
}

static int
lsa_validate_sum2(struct ospf_lsa_header *lsa, struct ospf_lsa_sum2 *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_sum2)))
    return 0;

  /* First field should have TOS = 0, we ignore other TOS fields */
  if ((body->metric & LSA_SUM2_TOS) != 0)
    return 0;

  return 1;
}

static inline int
pxlen(u32 *buf)
{
  return *buf >> 24;
}

static int
lsa_validate_sum3_net(struct ospf_lsa_header *lsa, struct ospf_lsa_sum3_net *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_sum3_net) + 4))
    return 0;

  u8 pxl = pxlen(body->prefix);
  if (pxl > IP6_MAX_PREFIX_LENGTH)
    return 0;

  if (lsa->length != (HDRLEN + sizeof(struct ospf_lsa_sum3_net) +
		      IPV6_PREFIX_SPACE(pxl)))
    return 0;

  return 1;
}

static int
lsa_validate_sum3_rt(struct ospf_lsa_header *lsa, struct ospf_lsa_sum3_rt *body UNUSED)
{
  if (lsa->length != (HDRLEN + sizeof(struct ospf_lsa_sum3_rt)))
    return 0;

  return 1;
}

static int
lsa_validate_ext2(struct ospf_lsa_header *lsa, struct ospf_lsa_ext2 *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_ext2)))
    return 0;

  /* First field should have TOS = 0, we ignore other TOS fields */
  if ((body->metric & LSA_EXT2_TOS) != 0)
    return 0;

  return 1;
}

static int
lsa_validate_ext3(struct ospf_lsa_header *lsa, struct ospf_lsa_ext3 *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_ext3) + 4))
    return 0;

  u8 pxl = pxlen(body->rest);
  if (pxl > IP6_MAX_PREFIX_LENGTH)
    return 0;

  int len = IPV6_PREFIX_SPACE(pxl);
  if (body->metric & LSA_EXT3_FBIT) // forwarding address
    len += 16;
  if (body->metric & LSA_EXT3_TBIT) // route tag
    len += 4;
  if (*body->rest & 0xFFFF) // referenced LS type field
    len += 4;

  if (lsa->length != (HDRLEN + sizeof(struct ospf_lsa_ext3) + len))
    return 0;

  return 1;
}

static int
lsa_validate_pxlist(struct ospf_lsa_header *lsa, u32 pxcount, uint offset, u8 *pbuf)
{
  uint bound = lsa->length - HDRLEN - 4;
  u32 i;

  for (i = 0; i < pxcount; i++)
    {
      if (offset > bound)
	return 0;

      u8 pxl = pxlen((u32 *) (pbuf + offset));
      if (pxl > IP6_MAX_PREFIX_LENGTH)
	return 0;

      offset += IPV6_PREFIX_SPACE(pxl);
    }

  if (lsa->length != (HDRLEN + offset))
    return 0;

  return 1;
}

static int
lsa_validate_link(struct ospf_lsa_header *lsa, struct ospf_lsa_link *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_link)))
    return 0;

  return lsa_validate_pxlist(lsa, body->pxcount, sizeof(struct ospf_lsa_link), (u8 *) body);
}

static int
lsa_validate_prefix(struct ospf_lsa_header *lsa, struct ospf_lsa_prefix *body)
{
  if (lsa->length < (HDRLEN + sizeof(struct ospf_lsa_prefix)))
    return 0;

  return lsa_validate_pxlist(lsa, body->pxcount, sizeof(struct ospf_lsa_prefix), (u8 *) body);
}

static int
lsa_validate_ri(struct ospf_lsa_header *lsa UNUSED, struct ospf_lsa_net *body UNUSED)
{
  /*
   * There should be proper validation. But we do not really process RI LSAs, so
   * we can just accept them like another unknown opaque LSAs.
   */

  return 1;
}


/**
 * lsa_validate - check whether given LSA is valid
 * @lsa: LSA header
 * @lsa_type: internal LSA type (%LSA_T_xxx)
 * @ospf2: %true for OSPFv2, %false for OSPFv3
 * @body: pointer to LSA body
 *
 * Checks internal structure of given LSA body (minimal length,
 * consistency). Returns true if valid.
 */
int
lsa_validate(struct ospf_lsa_header *lsa, u32 lsa_type, int ospf2, void *body)
{
  if (ospf2)
  {
    switch (lsa_type)
    {
    case LSA_T_RT:
      return lsa_validate_rt2(lsa, body);
    case LSA_T_NET:
      return lsa_validate_net(lsa, body);
    case LSA_T_SUM_NET:
      return lsa_validate_sum2(lsa, body);
    case LSA_T_SUM_RT:
      return lsa_validate_sum2(lsa, body);
    case LSA_T_EXT:
    case LSA_T_NSSA:
      return lsa_validate_ext2(lsa, body);
    case LSA_T_RI_LINK:
    case LSA_T_RI_AREA:
    case LSA_T_RI_AS:
      return lsa_validate_ri(lsa, body);
    case LSA_T_OPAQUE_LINK:
    case LSA_T_OPAQUE_AREA:
    case LSA_T_OPAQUE_AS:
      return 1;	/* Unknown Opaque LSAs */
    default:
      return 0;	/* Should not happen, unknown LSAs are already rejected */
    }
  }
  else
  {
    switch (lsa_type)
    {
    case LSA_T_RT:
      return lsa_validate_rt3(lsa, body);
    case LSA_T_NET:
      return lsa_validate_net(lsa, body);
    case LSA_T_SUM_NET:
      return lsa_validate_sum3_net(lsa, body);
    case LSA_T_SUM_RT:
      return lsa_validate_sum3_rt(lsa, body);
    case LSA_T_EXT:
    case LSA_T_NSSA:
      return lsa_validate_ext3(lsa, body);
    case LSA_T_LINK:
      return lsa_validate_link(lsa, body);
    case LSA_T_PREFIX:
      return lsa_validate_prefix(lsa, body);
    case LSA_T_RI_LINK:
    case LSA_T_RI_AREA:
    case LSA_T_RI_AS:
      return lsa_validate_ri(lsa, body);
    default:
      return 1;	/* Unknown LSAs are OK in OSPFv3 */
    }
  }
}