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/*
* Copyright (c) 2016 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/**
* @file
* @brief Common utility functions for IPv4, IPv6 and L2 LISP-GPE adjacencys.
*
*/
#include <vnet/dpo/load_balance.h>
#include <vnet/lisp-cp/control.h>
#include <vnet/lisp-cp/lisp_types.h>
#include <vnet/lisp-gpe/lisp_gpe_sub_interface.h>
#include <vnet/lisp-gpe/lisp_gpe_adjacency.h>
#include <vnet/lisp-gpe/lisp_gpe_tunnel.h>
#include <vnet/fib/fib_entry.h>
#include <vnet/adj/adj_midchain.h>
#include <vppinfra/bihash_24_8.h>
#include <vppinfra/bihash_template.h>
/**
* Memory pool of all adjacencies
*/
static lisp_gpe_adjacency_t *lisp_adj_pool;
/**
* Hash table of all adjacencies. key:{nh, itf}
* We never have an all zeros address since the interfaces are multi-access,
* therefore there is no ambiguity between a v4 and v6 next-hop, so we don't
* need to add the protocol to the key.
*/
static
BVT (clib_bihash)
lisp_adj_db;
#define LISP_ADJ_SET_KEY(_key, _itf, _nh) \
{ \
_key.key[0] = ip_addr_v6((_nh)).as_u64[0]; \
_key.key[1] = ip_addr_v6((_nh)).as_u64[1]; \
_key.key[2] = (_itf); \
}
static index_t lisp_adj_find (const ip_address_t * addr, u32 sw_if_index)
{
BVT (clib_bihash_kv) kv;
LISP_ADJ_SET_KEY (kv, sw_if_index, addr);
if (BV (clib_bihash_search) (&lisp_adj_db, &kv, &kv) < 0)
{
return (INDEX_INVALID);
}
else
{
return (kv.value);
}
}
static void
lisp_adj_insert (const ip_address_t * addr, u32 sw_if_index, index_t ai)
{
BVT (clib_bihash_kv) kv;
LISP_ADJ_SET_KEY (kv, sw_if_index, addr);
kv.value = ai;
BV (clib_bihash_add_del) (&lisp_adj_db, &kv, 1);
}
static void
lisp_adj_remove (const ip_address_t * addr, u32 sw_if_index)
{
BVT (clib_bihash_kv) kv;
LISP_ADJ_SET_KEY (kv, sw_if_index, addr);
BV (clib_bihash_add_del) (&lisp_adj_db, &kv, 0);
}
static lisp_gpe_adjacency_t *
lisp_gpe_adjacency_get_i (index_t lai)
{
return (pool_elt_at_index (lisp_adj_pool, lai));
}
fib_forward_chain_type_t
lisp_gpe_adj_get_fib_chain_type (const lisp_gpe_adjacency_t * ladj)
{
switch (ip_addr_version (&ladj->remote_rloc))
{
case AF_IP4:
return (FIB_FORW_CHAIN_TYPE_UNICAST_IP4);
case AF_IP6:
return (FIB_FORW_CHAIN_TYPE_UNICAST_IP6);
default:
ASSERT (0);
break;
}
return (FIB_FORW_CHAIN_TYPE_UNICAST_IP4);
}
static void
ip46_address_to_ip_address (const ip46_address_t * a, ip_address_t * b)
{
if (ip46_address_is_ip4 (a))
{
clib_memset (b, 0, sizeof (*b));
ip_address_set (b, &a->ip4, AF_IP4);
}
else
{
ip_address_set (b, &a->ip6, AF_IP6);
}
}
/**
* @brief Stack the tunnel's midchain on the IP forwarding chain of the via
*/
static void
lisp_gpe_adj_stack_one (lisp_gpe_adjacency_t * ladj, adj_index_t ai)
{
const lisp_gpe_tunnel_t *lgt;
lgt = lisp_gpe_tunnel_get (ladj->tunnel_index);
adj_nbr_midchain_stack_on_fib_entry (ai,
lgt->fib_entry_index,
lisp_gpe_adj_get_fib_chain_type
(ladj));
}
/**
* @brief Call back when restacking all adjacencies on a GRE interface
*/
static adj_walk_rc_t
lisp_gpe_adj_walk_cb (adj_index_t ai, void *ctx)
{
lisp_gpe_adjacency_t *ladj = ctx;
lisp_gpe_adj_stack_one (ladj, ai);
return (ADJ_WALK_RC_CONTINUE);
}
static void
lisp_gpe_adj_stack (lisp_gpe_adjacency_t * ladj)
{
fib_protocol_t nh_proto;
ip46_address_t nh;
nh_proto = ip_address_to_46 (&ladj->remote_rloc, &nh);
/*
* walk all the adjacencies on th lisp interface and restack them
*/
adj_nbr_walk_nh (ladj->sw_if_index,
nh_proto, &nh, lisp_gpe_adj_walk_cb, ladj);
}
static lisp_gpe_next_protocol_e
lisp_gpe_adj_proto_from_vnet_link_type (vnet_link_t linkt)
{
switch (linkt)
{
case VNET_LINK_IP4:
return (LISP_GPE_NEXT_PROTO_IP4);
case VNET_LINK_IP6:
return (LISP_GPE_NEXT_PROTO_IP6);
case VNET_LINK_ETHERNET:
return (LISP_GPE_NEXT_PROTO_ETHERNET);
case VNET_LINK_NSH:
return (LISP_GPE_NEXT_PROTO_NSH);
default:
ASSERT (0);
}
return (LISP_GPE_NEXT_PROTO_IP4);
}
#define is_v4_packet(_h) ((*(u8*) _h) & 0xF0) == 0x40
static lisp_afi_e
lisp_afi_from_vnet_link_type (vnet_link_t link)
{
switch (link)
{
case VNET_LINK_IP4:
return LISP_AFI_IP;
case VNET_LINK_IP6:
return LISP_AFI_IP6;
case VNET_LINK_ETHERNET:
return LISP_AFI_MAC;
default:
return LISP_AFI_NO_ADDR;
}
}
static void
lisp_gpe_increment_stats_counters (lisp_cp_main_t * lcm,
const ip_adjacency_t * adj,
vlib_buffer_t * b)
{
lisp_gpe_main_t *lgm = vnet_lisp_gpe_get_main ();
lisp_gpe_adjacency_t *ladj;
ip_address_t rloc;
index_t lai;
u32 si, di;
gid_address_t src, dst;
uword *feip;
ip46_address_to_ip_address (&adj->sub_type.nbr.next_hop, &rloc);
si = vnet_buffer (b)->sw_if_index[VLIB_TX];
lai = lisp_adj_find (&rloc, si);
ASSERT (INDEX_INVALID != lai);
ladj = pool_elt_at_index (lisp_adj_pool, lai);
u8 *lisp_data = (u8 *) vlib_buffer_get_current (b);
/* skip IP header */
if (is_v4_packet (lisp_data))
lisp_data += sizeof (ip4_header_t);
else
lisp_data += sizeof (ip6_header_t);
/* skip UDP header */
lisp_data += sizeof (udp_header_t);
// TODO: skip TCP?
/* skip LISP GPE header */
lisp_data += sizeof (lisp_gpe_header_t);
i16 saved_current_data = b->current_data;
b->current_data = lisp_data - b->data;
lisp_afi_e afi = lisp_afi_from_vnet_link_type (adj->ia_link);
get_src_and_dst_eids_from_buffer (lcm, b, &src, &dst, afi);
b->current_data = saved_current_data;
di = gid_dictionary_sd_lookup (&lcm->mapping_index_by_gid, &dst, &src);
if (PREDICT_FALSE (~0 == di))
{
clib_warning ("dst mapping not found (%U, %U)", format_gid_address,
&src, format_gid_address, &dst);
return;
}
feip = hash_get (lcm->fwd_entry_by_mapping_index, di);
if (PREDICT_FALSE (!feip))
return;
lisp_stats_key_t key;
clib_memset (&key, 0, sizeof (key));
key.fwd_entry_index = feip[0];
key.tunnel_index = ladj->tunnel_index;
uword *p = hash_get_mem (lgm->lisp_stats_index_by_key, &key);
ALWAYS_ASSERT (p);
/* compute payload length starting after GPE */
u32 bytes = b->current_length - (lisp_data - b->data - b->current_data);
vlib_increment_combined_counter (&lgm->counters, vlib_get_thread_index (),
p[0], 1, bytes);
}
static void
lisp_gpe_fixup (vlib_main_t * vm,
const ip_adjacency_t * adj,
vlib_buffer_t * b, const void *data)
{
lisp_cp_main_t *lcm = vnet_lisp_cp_get_main ();
if (lcm->flags & LISP_FLAG_STATS_ENABLED)
lisp_gpe_increment_stats_counters (lcm, adj, b);
/* Fixup the checksum and len fields in the LISP tunnel encap
* that was applied at the midchain node */
ip_udp_fixup_one (vm, b, is_v4_packet (vlib_buffer_get_current (b)));
}
/**
* @brief The LISP-GPE interface registered function to update, i.e.
* provide an rewrite string for, an adjacency.
*/
void
lisp_gpe_update_adjacency (vnet_main_t * vnm, u32 sw_if_index, adj_index_t ai)
{
const lisp_gpe_tunnel_t *lgt;
lisp_gpe_adjacency_t *ladj;
ip_adjacency_t *adj;
ip_address_t rloc;
vnet_link_t linkt;
adj_flags_t af;
index_t lai;
adj = adj_get (ai);
ip46_address_to_ip_address (&adj->sub_type.nbr.next_hop, &rloc);
/*
* find an existing or create a new adj
*/
lai = lisp_adj_find (&rloc, sw_if_index);
ASSERT (INDEX_INVALID != lai);
ladj = pool_elt_at_index (lisp_adj_pool, lai);
lgt = lisp_gpe_tunnel_get (ladj->tunnel_index);
linkt = adj_get_link_type (ai);
af = ADJ_FLAG_MIDCHAIN_IP_STACK;
if (VNET_LINK_ETHERNET == linkt)
af |= ADJ_FLAG_MIDCHAIN_NO_COUNT;
adj_nbr_midchain_update_rewrite
(ai, lisp_gpe_fixup, NULL, af,
lisp_gpe_tunnel_build_rewrite (lgt, ladj,
lisp_gpe_adj_proto_from_vnet_link_type
(linkt)));
lisp_gpe_adj_stack_one (ladj, ai);
}
u8 *
lisp_gpe_build_rewrite (vnet_main_t * vnm,
u32 sw_if_index,
vnet_link_t link_type, const void *dst_address)
{
ASSERT (0);
return (NULL);
}
index_t
lisp_gpe_adjacency_find_or_create_and_lock (const locator_pair_t * pair,
u32 overlay_table_id, u32 vni)
{
const lisp_gpe_sub_interface_t *l3s;
const lisp_gpe_tunnel_t *lgt;
lisp_gpe_adjacency_t *ladj;
index_t lai, l3si;
/*
* first find the L3 sub-interface that corresponds to the loacl-rloc and vni
*/
l3si = lisp_gpe_sub_interface_find_or_create_and_lock (&pair->lcl_loc,
overlay_table_id,
vni);
l3s = lisp_gpe_sub_interface_get (l3si);
/*
* find an existing or create a new adj
*/
lai = lisp_adj_find (&pair->rmt_loc, l3s->sw_if_index);
if (INDEX_INVALID == lai)
{
pool_get (lisp_adj_pool, ladj);
clib_memset (ladj, 0, sizeof (*ladj));
lai = (ladj - lisp_adj_pool);
ip_address_copy (&ladj->remote_rloc, &pair->rmt_loc);
ladj->vni = vni;
/* transfer the lock to the adj */
ladj->lisp_l3_sub_index = l3si;
ladj->sw_if_index = l3s->sw_if_index;
/* if vni is non-default */
if (ladj->vni)
ladj->flags = LISP_GPE_FLAGS_I;
/* work in lisp-gpe not legacy mode */
ladj->flags |= LISP_GPE_FLAGS_P;
/*
* find the tunnel that will provide the underlying transport
* and hence the rewrite.
* The RLOC FIB index is default table - always.
*/
ladj->tunnel_index = lisp_gpe_tunnel_find_or_create_and_lock (pair, 0);
lgt = lisp_gpe_tunnel_get (ladj->tunnel_index);
/*
* become of child of the RLOC FIB entry so we are updated when
* its reachability changes, allowing us to re-stack the midcahins
*/
ladj->fib_entry_child_index = fib_entry_child_add (lgt->fib_entry_index,
FIB_NODE_TYPE_LISP_ADJ,
lai);
lisp_adj_insert (&ladj->remote_rloc, ladj->sw_if_index, lai);
}
else
{
/* unlock the interface from the find. */
lisp_gpe_sub_interface_unlock (l3si);
ladj = lisp_gpe_adjacency_get_i (lai);
}
ladj->locks++;
return (lai);
}
/**
* @brief Get a pointer to a tunnel from a pointer to a FIB node
*/
static lisp_gpe_adjacency_t *
lisp_gpe_adjacency_from_fib_node (const fib_node_t * node)
{
return ((lisp_gpe_adjacency_t *)
((char *) node -
STRUCT_OFFSET_OF (lisp_gpe_adjacency_t, fib_node)));
}
static void
lisp_gpe_adjacency_last_lock_gone (lisp_gpe_adjacency_t * ladj)
{
const lisp_gpe_tunnel_t *lgt;
/*
* no children so we are not counting locks. no-op.
* at least not counting
*/
lisp_adj_remove (&ladj->remote_rloc, ladj->sw_if_index);
/*
* unlock the resources this adj holds
*/
lgt = lisp_gpe_tunnel_get (ladj->tunnel_index);
fib_entry_child_remove (lgt->fib_entry_index, ladj->fib_entry_child_index);
lisp_gpe_tunnel_unlock (ladj->tunnel_index);
lisp_gpe_sub_interface_unlock (ladj->lisp_l3_sub_index);
pool_put (lisp_adj_pool, ladj);
}
void
lisp_gpe_adjacency_unlock (index_t lai)
{
lisp_gpe_adjacency_t *ladj;
ladj = lisp_gpe_adjacency_get_i (lai);
ladj->locks--;
if (0 == ladj->locks)
{
lisp_gpe_adjacency_last_lock_gone (ladj);
}
}
const lisp_gpe_adjacency_t *
lisp_gpe_adjacency_get (index_t lai)
{
return (lisp_gpe_adjacency_get_i (lai));
}
/**
* @brief LISP GPE tunnel back walk
*
* The FIB entry through which this tunnel resolves has been updated.
* re-stack the midchain on the new forwarding.
*/
static fib_node_back_walk_rc_t
lisp_gpe_adjacency_back_walk (fib_node_t * node,
fib_node_back_walk_ctx_t * ctx)
{
lisp_gpe_adj_stack (lisp_gpe_adjacency_from_fib_node (node));
return (FIB_NODE_BACK_WALK_CONTINUE);
}
static fib_node_t *
lisp_gpe_adjacency_get_fib_node (fib_node_index_t index)
{
lisp_gpe_adjacency_t *ladj;
ladj = pool_elt_at_index (lisp_adj_pool, index);
return (&ladj->fib_node);
}
static void
lisp_gpe_adjacency_last_fib_lock_gone (fib_node_t * node)
{
lisp_gpe_adjacency_last_lock_gone (lisp_gpe_adjacency_from_fib_node (node));
}
const static fib_node_vft_t lisp_gpe_tuennel_vft = {
.fnv_get = lisp_gpe_adjacency_get_fib_node,
.fnv_back_walk = lisp_gpe_adjacency_back_walk,
.fnv_last_lock = lisp_gpe_adjacency_last_fib_lock_gone,
};
u8 *
format_lisp_gpe_adjacency (u8 * s, va_list * args)
{
lisp_gpe_adjacency_t *ladj = va_arg (*args, lisp_gpe_adjacency_t *);
lisp_gpe_adjacency_format_flags_t flags =
va_arg (*args, lisp_gpe_adjacency_format_flags_t);
if (flags & LISP_GPE_ADJ_FORMAT_FLAG_DETAIL)
{
s =
format (s, "index %d locks:%d\n", ladj - lisp_adj_pool, ladj->locks);
}
s = format (s, " vni: %d,", ladj->vni);
s = format (s, " remote-RLOC: %U,", format_ip_address, &ladj->remote_rloc);
if (flags & LISP_GPE_ADJ_FORMAT_FLAG_DETAIL)
{
s = format (s, " %U\n",
format_lisp_gpe_sub_interface,
lisp_gpe_sub_interface_get (ladj->lisp_l3_sub_index));
s = format (s, " %U\n",
format_lisp_gpe_tunnel,
lisp_gpe_tunnel_get (ladj->tunnel_index));
}
else
{
s = format (s, " LISP L3 sub-interface index: %d,",
ladj->lisp_l3_sub_index);
s = format (s, " LISP tunnel index: %d", ladj->tunnel_index);
}
return (s);
}
static clib_error_t *
lisp_gpe_adjacency_show (vlib_main_t * vm,
unformat_input_t * input, vlib_cli_command_t * cmd)
{
lisp_gpe_adjacency_t *ladj;
index_t index;
if (pool_elts (lisp_adj_pool) == 0)
vlib_cli_output (vm, "No lisp-gpe Adjacencies");
if (unformat (input, "%d", &index))
{
ladj = lisp_gpe_adjacency_get_i (index);
vlib_cli_output (vm, "%U", format_lisp_gpe_adjacency, ladj,
LISP_GPE_ADJ_FORMAT_FLAG_DETAIL);
}
else
{
/* *INDENT-OFF* */
pool_foreach (ladj, lisp_adj_pool,
({
vlib_cli_output (vm, "[%d] %U\n",
ladj - lisp_adj_pool,
format_lisp_gpe_adjacency, ladj,
LISP_GPE_ADJ_FORMAT_FLAG_NONE);
}));
/* *INDENT-ON* */
}
return 0;
}
/* *INDENT-OFF* */
VLIB_CLI_COMMAND (show_lisp_gpe_tunnel_command, static) =
{
.path = "show gpe adjacency",
.function = lisp_gpe_adjacency_show,
};
/* *INDENT-ON* */
#define LISP_ADJ_NBR_DEFAULT_HASH_NUM_BUCKETS (256)
#define LISP_ADJ_NBR_DEFAULT_HASH_MEMORY_SIZE (1<<20)
static clib_error_t *
lisp_gpe_adj_module_init (vlib_main_t * vm)
{
BV (clib_bihash_init) (&lisp_adj_db,
"Adjacency Neighbour table",
LISP_ADJ_NBR_DEFAULT_HASH_NUM_BUCKETS,
LISP_ADJ_NBR_DEFAULT_HASH_MEMORY_SIZE);
fib_node_register_type (FIB_NODE_TYPE_LISP_ADJ, &lisp_gpe_tuennel_vft);
return (NULL);
}
VLIB_INIT_FUNCTION (lisp_gpe_adj_module_init);
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/