blob: 75c7e20372a601fa16ad310be744de4ceafcbb62 [file] [log] [blame]
/*
* ethernet/arp.c: IP v4 ARP node
*
* Copyright (c) 2010 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.
*/
#include <vnet/ip/ip.h>
#include <vnet/ip/ip6.h>
#include <vnet/ethernet/ethernet.h>
#include <vnet/ethernet/arp_packet.h>
#include <vnet/l2/l2_input.h>
#include <vppinfra/mhash.h>
#include <vnet/fib/ip4_fib.h>
#include <vnet/adj/adj_nbr.h>
#include <vnet/adj/adj_mcast.h>
#include <vnet/mpls/mpls.h>
/**
* @file
* @brief IPv4 ARP.
*
* This file contains code to manage the IPv4 ARP tables (IP Address
* to MAC Address lookup).
*/
void vl_api_rpc_call_main_thread (void *fp, u8 * data, u32 data_length);
/**
* @brief Per-interface ARP configuration and state
*/
typedef struct ethernet_arp_interface_t_
{
/**
* Hash table of ARP entries.
* Since this hash table is per-interface, the key is only the IPv4 address.
*/
uword *arp_entries;
} ethernet_arp_interface_t;
typedef struct
{
u32 lo_addr;
u32 hi_addr;
u32 fib_index;
} ethernet_proxy_arp_t;
typedef struct
{
u32 next_index;
uword node_index;
uword type_opaque;
uword data;
/* Used for arp event notification only */
void *data_callback;
u32 pid;
} pending_resolution_t;
typedef struct
{
/* Hash tables mapping name to opcode. */
uword *opcode_by_name;
/* lite beer "glean" adjacency handling */
uword *pending_resolutions_by_address;
pending_resolution_t *pending_resolutions;
/* Mac address change notification */
uword *mac_changes_by_address;
pending_resolution_t *mac_changes;
ethernet_arp_ip4_entry_t *ip4_entry_pool;
/* ARP attack mitigation */
u32 arp_delete_rotor;
u32 limit_arp_cache_size;
/** Per interface state */
ethernet_arp_interface_t *ethernet_arp_by_sw_if_index;
/* Proxy arp vector */
ethernet_proxy_arp_t *proxy_arps;
} ethernet_arp_main_t;
static ethernet_arp_main_t ethernet_arp_main;
typedef struct
{
u32 sw_if_index;
ethernet_arp_ip4_over_ethernet_address_t a;
int is_static;
int is_no_fib_entry;
int flags;
#define ETHERNET_ARP_ARGS_REMOVE (1<<0)
#define ETHERNET_ARP_ARGS_FLUSH (1<<1)
#define ETHERNET_ARP_ARGS_POPULATE (1<<2)
} vnet_arp_set_ip4_over_ethernet_rpc_args_t;
static void
set_ip4_over_ethernet_rpc_callback (vnet_arp_set_ip4_over_ethernet_rpc_args_t
* a);
static u8 *
format_ethernet_arp_hardware_type (u8 * s, va_list * va)
{
ethernet_arp_hardware_type_t h = va_arg (*va, ethernet_arp_hardware_type_t);
char *t = 0;
switch (h)
{
#define _(n,f) case n: t = #f; break;
foreach_ethernet_arp_hardware_type;
#undef _
default:
return format (s, "unknown 0x%x", h);
}
return format (s, "%s", t);
}
static u8 *
format_ethernet_arp_opcode (u8 * s, va_list * va)
{
ethernet_arp_opcode_t o = va_arg (*va, ethernet_arp_opcode_t);
char *t = 0;
switch (o)
{
#define _(f) case ETHERNET_ARP_OPCODE_##f: t = #f; break;
foreach_ethernet_arp_opcode;
#undef _
default:
return format (s, "unknown 0x%x", o);
}
return format (s, "%s", t);
}
static uword
unformat_ethernet_arp_opcode_host_byte_order (unformat_input_t * input,
va_list * args)
{
int *result = va_arg (*args, int *);
ethernet_arp_main_t *am = &ethernet_arp_main;
int x, i;
/* Numeric opcode. */
if (unformat (input, "0x%x", &x) || unformat (input, "%d", &x))
{
if (x >= (1 << 16))
return 0;
*result = x;
return 1;
}
/* Named type. */
if (unformat_user (input, unformat_vlib_number_by_name,
am->opcode_by_name, &i))
{
*result = i;
return 1;
}
return 0;
}
static uword
unformat_ethernet_arp_opcode_net_byte_order (unformat_input_t * input,
va_list * args)
{
int *result = va_arg (*args, int *);
if (!unformat_user
(input, unformat_ethernet_arp_opcode_host_byte_order, result))
return 0;
*result = clib_host_to_net_u16 ((u16) * result);
return 1;
}
static u8 *
format_ethernet_arp_header (u8 * s, va_list * va)
{
ethernet_arp_header_t *a = va_arg (*va, ethernet_arp_header_t *);
u32 max_header_bytes = va_arg (*va, u32);
uword indent;
u16 l2_type, l3_type;
if (max_header_bytes != 0 && sizeof (a[0]) > max_header_bytes)
return format (s, "ARP header truncated");
l2_type = clib_net_to_host_u16 (a->l2_type);
l3_type = clib_net_to_host_u16 (a->l3_type);
indent = format_get_indent (s);
s = format (s, "%U, type %U/%U, address size %d/%d",
format_ethernet_arp_opcode, clib_net_to_host_u16 (a->opcode),
format_ethernet_arp_hardware_type, l2_type,
format_ethernet_type, l3_type,
a->n_l2_address_bytes, a->n_l3_address_bytes);
if (l2_type == ETHERNET_ARP_HARDWARE_TYPE_ethernet
&& l3_type == ETHERNET_TYPE_IP4)
{
s = format (s, "\n%U%U/%U -> %U/%U",
format_white_space, indent,
format_ethernet_address, a->ip4_over_ethernet[0].ethernet,
format_ip4_address, &a->ip4_over_ethernet[0].ip4,
format_ethernet_address, a->ip4_over_ethernet[1].ethernet,
format_ip4_address, &a->ip4_over_ethernet[1].ip4);
}
else
{
uword n2 = a->n_l2_address_bytes;
uword n3 = a->n_l3_address_bytes;
s = format (s, "\n%U%U/%U -> %U/%U",
format_white_space, indent,
format_hex_bytes, a->data + 0 * n2 + 0 * n3, n2,
format_hex_bytes, a->data + 1 * n2 + 0 * n3, n3,
format_hex_bytes, a->data + 1 * n2 + 1 * n3, n2,
format_hex_bytes, a->data + 2 * n2 + 1 * n3, n3);
}
return s;
}
u8 *
format_ethernet_arp_ip4_entry (u8 * s, va_list * va)
{
vnet_main_t *vnm = va_arg (*va, vnet_main_t *);
ethernet_arp_ip4_entry_t *e = va_arg (*va, ethernet_arp_ip4_entry_t *);
vnet_sw_interface_t *si;
u8 *flags = 0;
if (!e)
return format (s, "%=12s%=16s%=6s%=20s%=24s", "Time", "IP4",
"Flags", "Ethernet", "Interface");
si = vnet_get_sw_interface (vnm, e->sw_if_index);
if (e->flags & ETHERNET_ARP_IP4_ENTRY_FLAG_STATIC)
flags = format (flags, "S");
if (e->flags & ETHERNET_ARP_IP4_ENTRY_FLAG_DYNAMIC)
flags = format (flags, "D");
if (e->flags & ETHERNET_ARP_IP4_ENTRY_FLAG_NO_FIB_ENTRY)
flags = format (flags, "N");
s = format (s, "%=12U%=16U%=6s%=20U%=24U",
format_vlib_cpu_time, vnm->vlib_main, e->cpu_time_last_updated,
format_ip4_address, &e->ip4_address,
flags ? (char *) flags : "",
format_ethernet_address, e->ethernet_address,
format_vnet_sw_interface_name, vnm, si);
vec_free (flags);
return s;
}
typedef struct
{
u8 packet_data[64];
} ethernet_arp_input_trace_t;
static u8 *
format_ethernet_arp_input_trace (u8 * s, va_list * va)
{
CLIB_UNUSED (vlib_main_t * vm) = va_arg (*va, vlib_main_t *);
CLIB_UNUSED (vlib_node_t * node) = va_arg (*va, vlib_node_t *);
ethernet_arp_input_trace_t *t = va_arg (*va, ethernet_arp_input_trace_t *);
s = format (s, "%U",
format_ethernet_arp_header,
t->packet_data, sizeof (t->packet_data));
return s;
}
static u8 *
format_arp_term_input_trace (u8 * s, va_list * va)
{
CLIB_UNUSED (vlib_main_t * vm) = va_arg (*va, vlib_main_t *);
CLIB_UNUSED (vlib_node_t * node) = va_arg (*va, vlib_node_t *);
ethernet_arp_input_trace_t *t = va_arg (*va, ethernet_arp_input_trace_t *);
/* arp-term trace data saved is either arp or ip6/icmp6 packet:
- for arp, the 1st 16-bit field is hw type of value of 0x0001.
- for ip6, the first nibble has value of 6. */
s = format (s, "%U", t->packet_data[0] == 0 ?
format_ethernet_arp_header : format_ip6_header,
t->packet_data, sizeof (t->packet_data));
return s;
}
static void
arp_nbr_probe (ip_adjacency_t * adj)
{
vnet_main_t *vnm = vnet_get_main ();
ip4_main_t *im = &ip4_main;
ip_interface_address_t *ia;
ethernet_arp_header_t *h;
vnet_hw_interface_t *hi;
vnet_sw_interface_t *si;
ip4_address_t *src;
vlib_buffer_t *b;
vlib_main_t *vm;
u32 bi = 0;
vm = vlib_get_main ();
si = vnet_get_sw_interface (vnm, adj->rewrite_header.sw_if_index);
if (!(si->flags & VNET_SW_INTERFACE_FLAG_ADMIN_UP))
{
return;
}
src =
ip4_interface_address_matching_destination (im,
&adj->sub_type.nbr.next_hop.
ip4,
adj->rewrite_header.
sw_if_index, &ia);
if (!src)
{
return;
}
h =
vlib_packet_template_get_packet (vm, &im->ip4_arp_request_packet_template,
&bi);
hi = vnet_get_sup_hw_interface (vnm, adj->rewrite_header.sw_if_index);
clib_memcpy (h->ip4_over_ethernet[0].ethernet,
hi->hw_address, sizeof (h->ip4_over_ethernet[0].ethernet));
h->ip4_over_ethernet[0].ip4 = src[0];
h->ip4_over_ethernet[1].ip4 = adj->sub_type.nbr.next_hop.ip4;
b = vlib_get_buffer (vm, bi);
vnet_buffer (b)->sw_if_index[VLIB_RX] =
vnet_buffer (b)->sw_if_index[VLIB_TX] = adj->rewrite_header.sw_if_index;
/* Add encapsulation string for software interface (e.g. ethernet header). */
vnet_rewrite_one_header (adj[0], h, sizeof (ethernet_header_t));
vlib_buffer_advance (b, -adj->rewrite_header.data_bytes);
{
vlib_frame_t *f = vlib_get_frame_to_node (vm, hi->output_node_index);
u32 *to_next = vlib_frame_vector_args (f);
to_next[0] = bi;
f->n_vectors = 1;
vlib_put_frame_to_node (vm, hi->output_node_index, f);
}
}
static void
arp_mk_complete (adj_index_t ai, ethernet_arp_ip4_entry_t * e)
{
adj_nbr_update_rewrite
(ai, ADJ_NBR_REWRITE_FLAG_COMPLETE,
ethernet_build_rewrite (vnet_get_main (),
e->sw_if_index,
adj_get_link_type (ai), e->ethernet_address));
}
static void
arp_mk_incomplete (adj_index_t ai)
{
ip_adjacency_t *adj = adj_get (ai);
adj_nbr_update_rewrite
(ai,
ADJ_NBR_REWRITE_FLAG_INCOMPLETE,
ethernet_build_rewrite (vnet_get_main (),
adj->rewrite_header.sw_if_index,
VNET_LINK_ARP,
VNET_REWRITE_FOR_SW_INTERFACE_ADDRESS_BROADCAST));
}
static ethernet_arp_ip4_entry_t *
arp_entry_find (ethernet_arp_interface_t * eai, const ip4_address_t * addr)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e = NULL;
uword *p;
if (NULL != eai->arp_entries)
{
p = hash_get (eai->arp_entries, addr->as_u32);
if (!p)
return (NULL);
e = pool_elt_at_index (am->ip4_entry_pool, p[0]);
}
return (e);
}
static adj_walk_rc_t
arp_mk_complete_walk (adj_index_t ai, void *ctx)
{
ethernet_arp_ip4_entry_t *e = ctx;
arp_mk_complete (ai, e);
return (ADJ_WALK_RC_CONTINUE);
}
static adj_walk_rc_t
arp_mk_incomplete_walk (adj_index_t ai, void *ctx)
{
arp_mk_incomplete (ai);
return (ADJ_WALK_RC_CONTINUE);
}
void
arp_update_adjacency (vnet_main_t * vnm, u32 sw_if_index, u32 ai)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_interface_t *arp_int;
ethernet_arp_ip4_entry_t *e;
ip_adjacency_t *adj;
adj = adj_get (ai);
vec_validate (am->ethernet_arp_by_sw_if_index, sw_if_index);
arp_int = &am->ethernet_arp_by_sw_if_index[sw_if_index];
e = arp_entry_find (arp_int, &adj->sub_type.nbr.next_hop.ip4);
switch (adj->lookup_next_index)
{
case IP_LOOKUP_NEXT_ARP:
case IP_LOOKUP_NEXT_GLEAN:
if (NULL != e)
{
adj_nbr_walk_nh4 (sw_if_index,
&e->ip4_address, arp_mk_complete_walk, e);
}
else
{
/*
* no matching ARP entry.
* construct the rewrite required to for an ARP packet, and stick
* that in the adj's pipe to smoke.
*/
adj_nbr_update_rewrite
(ai,
ADJ_NBR_REWRITE_FLAG_INCOMPLETE,
ethernet_build_rewrite
(vnm,
sw_if_index,
VNET_LINK_ARP,
VNET_REWRITE_FOR_SW_INTERFACE_ADDRESS_BROADCAST));
/*
* since the FIB has added this adj for a route, it makes sense it
* may want to forward traffic sometime soon. Let's send a
* speculative ARP. just one. If we were to do periodically that
* wouldn't be bad either, but that's more code than i'm prepared to
* write at this time for relatively little reward.
*/
arp_nbr_probe (adj);
}
break;
case IP_LOOKUP_NEXT_MCAST:
/*
* Construct a partial rewrite from the known ethernet mcast dest MAC
*/
adj_mcast_update_rewrite
(ai,
ethernet_build_rewrite (vnm,
sw_if_index,
adj->ia_link,
ethernet_ip4_mcast_dst_addr ()));
/*
* Complete the remaining fields of the adj's rewrite to direct the
* complete of the rewrite at switch time by copying in the IP
* dst address's bytes.
* Ofset is 11 bytes from the end of the MAC header - which is three
* bytes into the desintation address. And we write 3 bytes.
*/
adj->rewrite_header.dst_mcast_offset = 11;
adj->rewrite_header.dst_mcast_n_bytes = 3;
break;
case IP_LOOKUP_NEXT_DROP:
case IP_LOOKUP_NEXT_PUNT:
case IP_LOOKUP_NEXT_LOCAL:
case IP_LOOKUP_NEXT_REWRITE:
case IP_LOOKUP_NEXT_LOAD_BALANCE:
case IP_LOOKUP_NEXT_MIDCHAIN:
case IP_LOOKUP_NEXT_ICMP_ERROR:
case IP_LOOKUP_N_NEXT:
ASSERT (0);
break;
}
}
int
vnet_arp_set_ip4_over_ethernet_internal (vnet_main_t * vnm,
vnet_arp_set_ip4_over_ethernet_rpc_args_t
* args)
{
ethernet_arp_ip4_entry_t *e = 0;
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_over_ethernet_address_t *a = &args->a;
vlib_main_t *vm = vlib_get_main ();
int make_new_arp_cache_entry = 1;
uword *p;
pending_resolution_t *pr, *mc;
ethernet_arp_interface_t *arp_int;
int is_static = args->is_static;
u32 sw_if_index = args->sw_if_index;
int is_no_fib_entry = args->is_no_fib_entry;
vec_validate (am->ethernet_arp_by_sw_if_index, sw_if_index);
arp_int = &am->ethernet_arp_by_sw_if_index[sw_if_index];
if (NULL != arp_int->arp_entries)
{
p = hash_get (arp_int->arp_entries, a->ip4.as_u32);
if (p)
{
e = pool_elt_at_index (am->ip4_entry_pool, p[0]);
/* Refuse to over-write static arp. */
if (!is_static && (e->flags & ETHERNET_ARP_IP4_ENTRY_FLAG_STATIC))
return -2;
make_new_arp_cache_entry = 0;
}
}
if (make_new_arp_cache_entry)
{
pool_get (am->ip4_entry_pool, e);
if (NULL == arp_int->arp_entries)
{
arp_int->arp_entries = hash_create (0, sizeof (u32));
}
hash_set (arp_int->arp_entries, a->ip4.as_u32, e - am->ip4_entry_pool);
e->sw_if_index = sw_if_index;
e->ip4_address = a->ip4;
clib_memcpy (e->ethernet_address,
a->ethernet, sizeof (e->ethernet_address));
if (!is_no_fib_entry)
{
fib_prefix_t pfx = {
.fp_len = 32,
.fp_proto = FIB_PROTOCOL_IP4,
.fp_addr.ip4 = a->ip4,
};
u32 fib_index;
fib_index =
ip4_fib_table_get_index_for_sw_if_index (e->sw_if_index);
e->fib_entry_index =
fib_table_entry_update_one_path (fib_index, &pfx, FIB_SOURCE_ADJ,
FIB_ENTRY_FLAG_ATTACHED,
FIB_PROTOCOL_IP4, &pfx.fp_addr,
e->sw_if_index, ~0, 1, NULL,
FIB_ROUTE_PATH_FLAG_NONE);
e->flags |= ETHERNET_ARP_IP4_ENTRY_FLAG_NO_FIB_ENTRY;
}
}
else
{
/*
* prevent a DoS attack from the data-plane that
* spams us with no-op updates to the MAC address
*/
if (0 == memcmp (e->ethernet_address,
a->ethernet, sizeof (e->ethernet_address)))
return -1;
/* Update time stamp and ethernet address. */
clib_memcpy (e->ethernet_address, a->ethernet,
sizeof (e->ethernet_address));
}
e->cpu_time_last_updated = clib_cpu_time_now ();
if (is_static)
e->flags |= ETHERNET_ARP_IP4_ENTRY_FLAG_STATIC;
else
e->flags |= ETHERNET_ARP_IP4_ENTRY_FLAG_DYNAMIC;
adj_nbr_walk_nh4 (sw_if_index, &e->ip4_address, arp_mk_complete_walk, e);
/* Customer(s) waiting for this address to be resolved? */
p = hash_get (am->pending_resolutions_by_address, a->ip4.as_u32);
if (p)
{
u32 next_index;
next_index = p[0];
while (next_index != (u32) ~ 0)
{
pr = pool_elt_at_index (am->pending_resolutions, next_index);
vlib_process_signal_event (vm, pr->node_index,
pr->type_opaque, pr->data);
next_index = pr->next_index;
pool_put (am->pending_resolutions, pr);
}
hash_unset (am->pending_resolutions_by_address, a->ip4.as_u32);
}
/* Customer(s) requesting ARP event for this address? */
p = hash_get (am->mac_changes_by_address, a->ip4.as_u32);
if (p)
{
u32 next_index;
next_index = p[0];
while (next_index != (u32) ~ 0)
{
int (*fp) (u32, u8 *, u32, u32);
int rv = 1;
mc = pool_elt_at_index (am->mac_changes, next_index);
fp = mc->data_callback;
/* Call the user's data callback, return 1 to suppress dup events */
if (fp)
rv = (*fp) (mc->data, a->ethernet, sw_if_index, 0);
/*
* Signal the resolver process, as long as the user
* says they want to be notified
*/
if (rv == 0)
vlib_process_signal_event (vm, mc->node_index,
mc->type_opaque, mc->data);
next_index = mc->next_index;
}
}
return 0;
}
void
vnet_register_ip4_arp_resolution_event (vnet_main_t * vnm,
void *address_arg,
uword node_index,
uword type_opaque, uword data)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ip4_address_t *address = address_arg;
uword *p;
pending_resolution_t *pr;
pool_get (am->pending_resolutions, pr);
pr->next_index = ~0;
pr->node_index = node_index;
pr->type_opaque = type_opaque;
pr->data = data;
pr->data_callback = 0;
p = hash_get (am->pending_resolutions_by_address, address->as_u32);
if (p)
{
/* Insert new resolution at the head of the list */
pr->next_index = p[0];
hash_unset (am->pending_resolutions_by_address, address->as_u32);
}
hash_set (am->pending_resolutions_by_address, address->as_u32,
pr - am->pending_resolutions);
}
int
vnet_add_del_ip4_arp_change_event (vnet_main_t * vnm,
void *data_callback,
u32 pid,
void *address_arg,
uword node_index,
uword type_opaque, uword data, int is_add)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ip4_address_t *address = address_arg;
uword *p;
pending_resolution_t *mc;
void (*fp) (u32, u8 *) = data_callback;
if (is_add)
{
pool_get (am->mac_changes, mc);
mc->next_index = ~0;
mc->node_index = node_index;
mc->type_opaque = type_opaque;
mc->data = data;
mc->data_callback = data_callback;
mc->pid = pid;
p = hash_get (am->mac_changes_by_address, address->as_u32);
if (p)
{
/* Insert new resolution at the head of the list */
mc->next_index = p[0];
hash_unset (am->mac_changes_by_address, address->as_u32);
}
hash_set (am->mac_changes_by_address, address->as_u32,
mc - am->mac_changes);
return 0;
}
else
{
u32 index;
pending_resolution_t *mc_last = 0;
p = hash_get (am->mac_changes_by_address, address->as_u32);
if (p == 0)
return VNET_API_ERROR_NO_SUCH_ENTRY;
index = p[0];
while (index != (u32) ~ 0)
{
mc = pool_elt_at_index (am->mac_changes, index);
if (mc->node_index == node_index &&
mc->type_opaque == type_opaque && mc->pid == pid)
{
/* Clients may need to clean up pool entries, too */
if (fp)
(*fp) (mc->data, 0 /* no new mac addrs */ );
if (index == p[0])
{
hash_unset (am->mac_changes_by_address, address->as_u32);
if (mc->next_index != ~0)
hash_set (am->mac_changes_by_address, address->as_u32,
mc->next_index);
pool_put (am->mac_changes, mc);
return 0;
}
else
{
ASSERT (mc_last);
mc_last->next_index = mc->next_index;
pool_put (am->mac_changes, mc);
return 0;
}
}
mc_last = mc;
index = mc->next_index;
}
return VNET_API_ERROR_NO_SUCH_ENTRY;
}
}
/* Either we drop the packet or we send a reply to the sender. */
typedef enum
{
ARP_INPUT_NEXT_DROP,
ARP_INPUT_NEXT_REPLY_TX,
ARP_INPUT_N_NEXT,
} arp_input_next_t;
#define foreach_ethernet_arp_error \
_ (replies_sent, "ARP replies sent") \
_ (l2_type_not_ethernet, "L2 type not ethernet") \
_ (l3_type_not_ip4, "L3 type not IP4") \
_ (l3_src_address_not_local, "IP4 source address not local to subnet") \
_ (l3_dst_address_not_local, "IP4 destination address not local to subnet") \
_ (l3_src_address_is_local, "IP4 source address matches local interface") \
_ (l3_src_address_learned, "ARP request IP4 source address learned") \
_ (replies_received, "ARP replies received") \
_ (opcode_not_request, "ARP opcode not request") \
_ (proxy_arp_replies_sent, "Proxy ARP replies sent") \
_ (l2_address_mismatch, "ARP hw addr does not match L2 frame src addr") \
_ (missing_interface_address, "ARP missing interface address") \
_ (gratuitous_arp, "ARP probe or announcement dropped") \
_ (interface_no_table, "Interface is not mapped to an IP table") \
_ (interface_not_ip_enabled, "Interface is not IP enabled") \
typedef enum
{
#define _(sym,string) ETHERNET_ARP_ERROR_##sym,
foreach_ethernet_arp_error
#undef _
ETHERNET_ARP_N_ERROR,
} ethernet_arp_input_error_t;
static void
unset_random_arp_entry (void)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
vnet_main_t *vnm = vnet_get_main ();
ethernet_arp_ip4_over_ethernet_address_t delme;
u32 index;
index = pool_next_index (am->ip4_entry_pool, am->arp_delete_rotor);
am->arp_delete_rotor = index;
/* Try again from elt 0, could happen if an intfc goes down */
if (index == ~0)
{
index = pool_next_index (am->ip4_entry_pool, am->arp_delete_rotor);
am->arp_delete_rotor = index;
}
/* Nothing left in the pool */
if (index == ~0)
return;
e = pool_elt_at_index (am->ip4_entry_pool, index);
clib_memcpy (&delme.ethernet, e->ethernet_address, 6);
delme.ip4.as_u32 = e->ip4_address.as_u32;
vnet_arp_unset_ip4_over_ethernet (vnm, e->sw_if_index, &delme);
}
static int
arp_unnumbered (vlib_buffer_t * p0,
u32 pi0, ethernet_header_t * eth0, u32 sw_if_index)
{
vlib_main_t *vm = vlib_get_main ();
vnet_main_t *vnm = vnet_get_main ();
vnet_interface_main_t *vim = &vnm->interface_main;
vnet_sw_interface_t *si;
vnet_hw_interface_t *hi;
u32 unnum_src_sw_if_index;
u32 *broadcast_swifs = 0;
u32 *buffers = 0;
u32 n_alloc = 0;
vlib_buffer_t *b0;
int i;
u8 dst_mac_address[6];
i16 header_size;
ethernet_arp_header_t *arp0;
/* Save the dst mac address */
clib_memcpy (dst_mac_address, eth0->dst_address, sizeof (dst_mac_address));
/* Figure out which sw_if_index supplied the address */
unnum_src_sw_if_index = sw_if_index;
/* Track down all users of the unnumbered source */
/* *INDENT-OFF* */
pool_foreach (si, vim->sw_interfaces,
({
if (si->flags & VNET_SW_INTERFACE_FLAG_UNNUMBERED &&
(si->unnumbered_sw_if_index == unnum_src_sw_if_index))
{
vec_add1 (broadcast_swifs, si->sw_if_index);
}
}));
/* *INDENT-ON* */
/* If there are no interfaces un-unmbered to this interface,
we are done here. */
if (0 == vec_len (broadcast_swifs))
return 0;
/* Allocate buffering if we need it */
if (vec_len (broadcast_swifs) > 1)
{
vec_validate (buffers, vec_len (broadcast_swifs) - 2);
n_alloc = vlib_buffer_alloc (vm, buffers, vec_len (buffers));
_vec_len (buffers) = n_alloc;
for (i = 0; i < n_alloc; i++)
{
b0 = vlib_get_buffer (vm, buffers[i]);
/* xerox (partially built) ARP pkt */
clib_memcpy (b0->data, p0->data,
p0->current_length + p0->current_data);
b0->current_data = p0->current_data;
b0->current_length = p0->current_length;
vnet_buffer (b0)->sw_if_index[VLIB_RX] =
vnet_buffer (p0)->sw_if_index[VLIB_RX];
}
}
vec_insert (buffers, 1, 0);
buffers[0] = pi0;
for (i = 0; i < vec_len (buffers); i++)
{
b0 = vlib_get_buffer (vm, buffers[i]);
arp0 = vlib_buffer_get_current (b0);
hi = vnet_get_sup_hw_interface (vnm, broadcast_swifs[i]);
si = vnet_get_sw_interface (vnm, broadcast_swifs[i]);
/* For decoration, most likely */
vnet_buffer (b0)->sw_if_index[VLIB_TX] = hi->sw_if_index;
/* Fix ARP pkt src address */
clib_memcpy (arp0->ip4_over_ethernet[0].ethernet, hi->hw_address, 6);
/* Build L2 encaps for this swif */
header_size = sizeof (ethernet_header_t);
if (si->sub.eth.flags.one_tag)
header_size += 4;
else if (si->sub.eth.flags.two_tags)
header_size += 8;
vlib_buffer_advance (b0, -header_size);
eth0 = vlib_buffer_get_current (b0);
if (si->sub.eth.flags.one_tag)
{
ethernet_vlan_header_t *outer = (void *) (eth0 + 1);
eth0->type = si->sub.eth.flags.dot1ad ?
clib_host_to_net_u16 (ETHERNET_TYPE_DOT1AD) :
clib_host_to_net_u16 (ETHERNET_TYPE_VLAN);
outer->priority_cfi_and_id =
clib_host_to_net_u16 (si->sub.eth.outer_vlan_id);
outer->type = clib_host_to_net_u16 (ETHERNET_TYPE_ARP);
}
else if (si->sub.eth.flags.two_tags)
{
ethernet_vlan_header_t *outer = (void *) (eth0 + 1);
ethernet_vlan_header_t *inner = (void *) (outer + 1);
eth0->type = si->sub.eth.flags.dot1ad ?
clib_host_to_net_u16 (ETHERNET_TYPE_DOT1AD) :
clib_host_to_net_u16 (ETHERNET_TYPE_VLAN);
outer->priority_cfi_and_id =
clib_host_to_net_u16 (si->sub.eth.outer_vlan_id);
outer->type = clib_host_to_net_u16 (ETHERNET_TYPE_VLAN);
inner->priority_cfi_and_id =
clib_host_to_net_u16 (si->sub.eth.inner_vlan_id);
inner->type = clib_host_to_net_u16 (ETHERNET_TYPE_ARP);
}
else
{
eth0->type = clib_host_to_net_u16 (ETHERNET_TYPE_ARP);
}
/* Restore the original dst address, set src address */
clib_memcpy (eth0->dst_address, dst_mac_address,
sizeof (eth0->dst_address));
clib_memcpy (eth0->src_address, hi->hw_address,
sizeof (eth0->src_address));
/* Transmit replicas */
if (i > 0)
{
vlib_frame_t *f =
vlib_get_frame_to_node (vm, hi->output_node_index);
u32 *to_next = vlib_frame_vector_args (f);
to_next[0] = buffers[i];
f->n_vectors = 1;
vlib_put_frame_to_node (vm, hi->output_node_index, f);
}
}
/* The regular path outputs the original pkt.. */
vnet_buffer (p0)->sw_if_index[VLIB_TX] = broadcast_swifs[0];
vec_free (broadcast_swifs);
vec_free (buffers);
return !0;
}
static uword
arp_input (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * frame)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
vnet_main_t *vnm = vnet_get_main ();
ip4_main_t *im4 = &ip4_main;
u32 n_left_from, next_index, *from, *to_next;
u32 n_replies_sent = 0, n_proxy_arp_replies_sent = 0;
from = vlib_frame_vector_args (frame);
n_left_from = frame->n_vectors;
next_index = node->cached_next_index;
if (node->flags & VLIB_NODE_FLAG_TRACE)
vlib_trace_frame_buffers_only (vm, node, from, frame->n_vectors,
/* stride */ 1,
sizeof (ethernet_arp_input_trace_t));
while (n_left_from > 0)
{
u32 n_left_to_next;
vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next);
while (n_left_from > 0 && n_left_to_next > 0)
{
vlib_buffer_t *p0;
vnet_hw_interface_t *hw_if0;
ethernet_arp_header_t *arp0;
ethernet_header_t *eth0;
ip4_address_t *if_addr0, proxy_src;
u32 pi0, error0, next0, sw_if_index0, conn_sw_if_index0, fib_index0;
u8 is_request0, dst_is_local0, is_unnum0;
ethernet_proxy_arp_t *pa;
fib_node_index_t dst_fei, src_fei;
fib_prefix_t pfx0;
fib_entry_flag_t src_flags, dst_flags;
pi0 = from[0];
to_next[0] = pi0;
from += 1;
to_next += 1;
n_left_from -= 1;
n_left_to_next -= 1;
pa = 0;
p0 = vlib_get_buffer (vm, pi0);
arp0 = vlib_buffer_get_current (p0);
is_request0 = arp0->opcode
== clib_host_to_net_u16 (ETHERNET_ARP_OPCODE_request);
error0 = ETHERNET_ARP_ERROR_replies_sent;
error0 =
(arp0->l2_type !=
clib_net_to_host_u16 (ETHERNET_ARP_HARDWARE_TYPE_ethernet) ?
ETHERNET_ARP_ERROR_l2_type_not_ethernet : error0);
error0 =
(arp0->l3_type !=
clib_net_to_host_u16 (ETHERNET_TYPE_IP4) ?
ETHERNET_ARP_ERROR_l3_type_not_ip4 : error0);
sw_if_index0 = vnet_buffer (p0)->sw_if_index[VLIB_RX];
/* not playing the ARP game if the interface is not IPv4 enabled */
error0 =
(im4->ip_enabled_by_sw_if_index[sw_if_index0] == 0 ?
ETHERNET_ARP_ERROR_interface_not_ip_enabled : error0);
if (error0)
goto drop2;
/* Check that IP address is local and matches incoming interface. */
fib_index0 = ip4_fib_table_get_index_for_sw_if_index (sw_if_index0);
if (~0 == fib_index0)
{
error0 = ETHERNET_ARP_ERROR_interface_no_table;
goto drop2;
}
dst_fei = ip4_fib_table_lookup (ip4_fib_get (fib_index0),
&arp0->ip4_over_ethernet[1].ip4,
32);
dst_flags = fib_entry_get_flags (dst_fei);
src_fei = ip4_fib_table_lookup (ip4_fib_get (fib_index0),
&arp0->ip4_over_ethernet[0].ip4,
32);
src_flags = fib_entry_get_flags (src_fei);
conn_sw_if_index0 = fib_entry_get_resolving_interface (dst_fei);
if (!(FIB_ENTRY_FLAG_CONNECTED & dst_flags))
{
error0 = ETHERNET_ARP_ERROR_l3_dst_address_not_local;
goto drop1;
}
/* Honor unnumbered interface, if any */
is_unnum0 = sw_if_index0 != conn_sw_if_index0;
/* Source must also be local to subnet of matching interface address. */
if (!((FIB_ENTRY_FLAG_ATTACHED & src_flags) ||
(FIB_ENTRY_FLAG_CONNECTED & src_flags)))
{
/*
* The packet was sent from an address that is not connected nor attached
* i.e. it is not from an address that is covered by a link's sub-net,
* nor is it a already learned host resp.
*/
error0 = ETHERNET_ARP_ERROR_l3_src_address_not_local;
goto drop2;
}
if (sw_if_index0 != fib_entry_get_resolving_interface (src_fei))
{
/*
* The interface the ARP was received on is not the interface
* on which the covering prefix is configured. Maybe this is a case
* for unnumbered.
*/
is_unnum0 = 1;
}
/* Reject requests/replies with our local interface address. */
if (FIB_ENTRY_FLAG_LOCAL & src_flags)
{
error0 = ETHERNET_ARP_ERROR_l3_src_address_is_local;
goto drop2;
}
dst_is_local0 = (FIB_ENTRY_FLAG_LOCAL & dst_flags);
fib_entry_get_prefix (dst_fei, &pfx0);
if_addr0 = &pfx0.fp_addr.ip4;
/* Fill in ethernet header. */
eth0 = ethernet_buffer_get_header (p0);
/* Trash ARP packets whose ARP-level source addresses do not
match their L2-frame-level source addresses */
if (memcmp (eth0->src_address, arp0->ip4_over_ethernet[0].ethernet,
sizeof (eth0->src_address)))
{
error0 = ETHERNET_ARP_ERROR_l2_address_mismatch;
goto drop2;
}
/* Learn or update sender's mapping only for requests or unicasts
that don't match local interface address. */
if (ethernet_address_cast (eth0->dst_address) ==
ETHERNET_ADDRESS_UNICAST || is_request0)
{
if (am->limit_arp_cache_size &&
pool_elts (am->ip4_entry_pool) >= am->limit_arp_cache_size)
unset_random_arp_entry ();
vnet_arp_set_ip4_over_ethernet (vnm, sw_if_index0,
&arp0->ip4_over_ethernet[0],
0 /* is_static */ , 0);
error0 = ETHERNET_ARP_ERROR_l3_src_address_learned;
}
/* Only send a reply for requests sent which match a local interface. */
if (!(is_request0 && dst_is_local0))
{
error0 =
(arp0->opcode ==
clib_host_to_net_u16 (ETHERNET_ARP_OPCODE_reply) ?
ETHERNET_ARP_ERROR_replies_received : error0);
goto drop1;
}
/* Send a reply. */
send_reply:
vnet_buffer (p0)->sw_if_index[VLIB_TX] = sw_if_index0;
hw_if0 = vnet_get_sup_hw_interface (vnm, sw_if_index0);
/* Send reply back through input interface */
vnet_buffer (p0)->sw_if_index[VLIB_TX] = sw_if_index0;
next0 = ARP_INPUT_NEXT_REPLY_TX;
arp0->opcode = clib_host_to_net_u16 (ETHERNET_ARP_OPCODE_reply);
arp0->ip4_over_ethernet[1] = arp0->ip4_over_ethernet[0];
clib_memcpy (arp0->ip4_over_ethernet[0].ethernet,
hw_if0->hw_address, 6);
clib_mem_unaligned (&arp0->ip4_over_ethernet[0].ip4.data_u32, u32) =
if_addr0->data_u32;
/* Hardware must be ethernet-like. */
ASSERT (vec_len (hw_if0->hw_address) == 6);
clib_memcpy (eth0->dst_address, eth0->src_address, 6);
clib_memcpy (eth0->src_address, hw_if0->hw_address, 6);
/* Figure out how much to rewind current data from adjacency. */
/* get the adj from the destination's covering connected */
if (NULL == pa)
{
if (is_unnum0)
{
if (!arp_unnumbered (p0, pi0, eth0, conn_sw_if_index0))
goto drop2;
}
else
{
ip_adjacency_t *adj0 = NULL;
adj_index_t ai;
if (FIB_ENTRY_FLAG_ATTACHED & src_flags)
{
/*
* If the source is attached use the adj from that source.
*/
ai = fib_entry_get_adj (src_fei);
if (ADJ_INDEX_INVALID != ai)
{
adj0 = adj_get (ai);
}
}
else
{
/*
* Get the glean adj from the cover. This is presumably interface
* sourced, and therefre needs to be a glean adj.
*/
ai = fib_entry_get_adj_for_source
(ip4_fib_table_lookup
(ip4_fib_get (fib_index0),
&arp0->ip4_over_ethernet[1].ip4, 31),
FIB_SOURCE_INTERFACE);
if (ADJ_INDEX_INVALID != ai)
{
adj0 = adj_get (ai);
if (adj0->lookup_next_index == IP_LOOKUP_NEXT_GLEAN)
{
adj0 = NULL;
}
}
}
if (NULL != adj0)
{
vlib_buffer_advance (p0,
-adj0->rewrite_header.data_bytes);
}
else
{
error0 = ETHERNET_ARP_ERROR_missing_interface_address;
goto drop2;
}
}
}
vlib_validate_buffer_enqueue_x1 (vm, node, next_index, to_next,
n_left_to_next, pi0, next0);
n_replies_sent += 1;
continue;
drop1:
if (0 == arp0->ip4_over_ethernet[0].ip4.as_u32 ||
(arp0->ip4_over_ethernet[0].ip4.as_u32 ==
arp0->ip4_over_ethernet[1].ip4.as_u32))
{
error0 = ETHERNET_ARP_ERROR_gratuitous_arp;
goto drop2;
}
/* See if proxy arp is configured for the address */
if (is_request0)
{
vnet_sw_interface_t *si;
u32 this_addr = clib_net_to_host_u32
(arp0->ip4_over_ethernet[1].ip4.as_u32);
u32 fib_index0;
si = vnet_get_sw_interface (vnm, sw_if_index0);
if (!(si->flags & VNET_SW_INTERFACE_FLAG_PROXY_ARP))
goto drop2;
fib_index0 = vec_elt (im4->fib_index_by_sw_if_index,
sw_if_index0);
vec_foreach (pa, am->proxy_arps)
{
u32 lo_addr = clib_net_to_host_u32 (pa->lo_addr);
u32 hi_addr = clib_net_to_host_u32 (pa->hi_addr);
/* an ARP request hit in the proxy-arp table? */
if ((this_addr >= lo_addr && this_addr <= hi_addr) &&
(fib_index0 == pa->fib_index))
{
eth0 = ethernet_buffer_get_header (p0);
proxy_src.as_u32 =
arp0->ip4_over_ethernet[1].ip4.data_u32;
/*
* Rewind buffer, direct code above not to
* think too hard about it.
*/
if_addr0 = &proxy_src;
is_unnum0 = 0;
i32 ethernet_start =
vnet_buffer (p0)->ethernet.start_of_ethernet_header;
i32 rewind = p0->current_data - ethernet_start;
vlib_buffer_advance (p0, -rewind);
n_proxy_arp_replies_sent++;
goto send_reply;
}
}
}
drop2:
next0 = ARP_INPUT_NEXT_DROP;
p0->error = node->errors[error0];
vlib_validate_buffer_enqueue_x1 (vm, node, next_index, to_next,
n_left_to_next, pi0, next0);
}
vlib_put_next_frame (vm, node, next_index, n_left_to_next);
}
vlib_error_count (vm, node->node_index,
ETHERNET_ARP_ERROR_replies_sent,
n_replies_sent - n_proxy_arp_replies_sent);
vlib_error_count (vm, node->node_index,
ETHERNET_ARP_ERROR_proxy_arp_replies_sent,
n_proxy_arp_replies_sent);
return frame->n_vectors;
}
static char *ethernet_arp_error_strings[] = {
#define _(sym,string) string,
foreach_ethernet_arp_error
#undef _
};
/* *INDENT-OFF* */
VLIB_REGISTER_NODE (arp_input_node, static) =
{
.function = arp_input,
.name = "arp-input",
.vector_size = sizeof (u32),
.n_errors = ETHERNET_ARP_N_ERROR,
.error_strings = ethernet_arp_error_strings,
.n_next_nodes = ARP_INPUT_N_NEXT,
.next_nodes = {
[ARP_INPUT_NEXT_DROP] = "error-drop",
[ARP_INPUT_NEXT_REPLY_TX] = "interface-output",
},
.format_buffer = format_ethernet_arp_header,
.format_trace = format_ethernet_arp_input_trace,
};
/* *INDENT-ON* */
static int
ip4_arp_entry_sort (void *a1, void *a2)
{
ethernet_arp_ip4_entry_t *e1 = a1;
ethernet_arp_ip4_entry_t *e2 = a2;
int cmp;
vnet_main_t *vnm = vnet_get_main ();
cmp = vnet_sw_interface_compare (vnm, e1->sw_if_index, e2->sw_if_index);
if (!cmp)
cmp = ip4_address_compare (&e1->ip4_address, &e2->ip4_address);
return cmp;
}
ethernet_arp_ip4_entry_t *
ip4_neighbor_entries (u32 sw_if_index)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *n, *ns = 0;
/* *INDENT-OFF* */
pool_foreach (n, am->ip4_entry_pool, ({
if (sw_if_index != ~0 && n->sw_if_index != sw_if_index)
continue;
vec_add1 (ns, n[0]);
}));
/* *INDENT-ON* */
if (ns)
vec_sort_with_function (ns, ip4_arp_entry_sort);
return ns;
}
static clib_error_t *
show_ip4_arp (vlib_main_t * vm,
unformat_input_t * input, vlib_cli_command_t * cmd)
{
vnet_main_t *vnm = vnet_get_main ();
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e, *es;
ethernet_proxy_arp_t *pa;
clib_error_t *error = 0;
u32 sw_if_index;
/* Filter entries by interface if given. */
sw_if_index = ~0;
(void) unformat_user (input, unformat_vnet_sw_interface, vnm, &sw_if_index);
es = ip4_neighbor_entries (sw_if_index);
if (es)
{
vlib_cli_output (vm, "%U", format_ethernet_arp_ip4_entry, vnm, 0);
vec_foreach (e, es)
{
vlib_cli_output (vm, "%U", format_ethernet_arp_ip4_entry, vnm, e);
}
vec_free (es);
}
if (vec_len (am->proxy_arps))
{
vlib_cli_output (vm, "Proxy arps enabled for:");
vec_foreach (pa, am->proxy_arps)
{
vlib_cli_output (vm, "Fib_index %d %U - %U ",
pa->fib_index,
format_ip4_address, &pa->lo_addr,
format_ip4_address, &pa->hi_addr);
}
}
return error;
}
/*?
* Display all the IPv4 ARP entries.
*
* @cliexpar
* Example of how to display the IPv4 ARP table:
* @cliexstart{show ip arp}
* Time FIB IP4 Flags Ethernet Interface
* 346.3028 0 6.1.1.3 de:ad:be:ef:ba:be GigabitEthernet2/0/0
* 3077.4271 0 6.1.1.4 S de:ad:be:ef:ff:ff GigabitEthernet2/0/0
* 2998.6409 1 6.2.2.3 de:ad:be:ef:00:01 GigabitEthernet2/0/0
* Proxy arps enabled for:
* Fib_index 0 6.0.0.1 - 6.0.0.11
* @cliexend
?*/
/* *INDENT-OFF* */
VLIB_CLI_COMMAND (show_ip4_arp_command, static) = {
.path = "show ip arp",
.function = show_ip4_arp,
.short_help = "show ip arp",
};
/* *INDENT-ON* */
typedef struct
{
pg_edit_t l2_type, l3_type;
pg_edit_t n_l2_address_bytes, n_l3_address_bytes;
pg_edit_t opcode;
struct
{
pg_edit_t ethernet;
pg_edit_t ip4;
} ip4_over_ethernet[2];
} pg_ethernet_arp_header_t;
static inline void
pg_ethernet_arp_header_init (pg_ethernet_arp_header_t * p)
{
/* Initialize fields that are not bit fields in the IP header. */
#define _(f) pg_edit_init (&p->f, ethernet_arp_header_t, f);
_(l2_type);
_(l3_type);
_(n_l2_address_bytes);
_(n_l3_address_bytes);
_(opcode);
_(ip4_over_ethernet[0].ethernet);
_(ip4_over_ethernet[0].ip4);
_(ip4_over_ethernet[1].ethernet);
_(ip4_over_ethernet[1].ip4);
#undef _
}
uword
unformat_pg_arp_header (unformat_input_t * input, va_list * args)
{
pg_stream_t *s = va_arg (*args, pg_stream_t *);
pg_ethernet_arp_header_t *p;
u32 group_index;
p = pg_create_edit_group (s, sizeof (p[0]), sizeof (ethernet_arp_header_t),
&group_index);
pg_ethernet_arp_header_init (p);
/* Defaults. */
pg_edit_set_fixed (&p->l2_type, ETHERNET_ARP_HARDWARE_TYPE_ethernet);
pg_edit_set_fixed (&p->l3_type, ETHERNET_TYPE_IP4);
pg_edit_set_fixed (&p->n_l2_address_bytes, 6);
pg_edit_set_fixed (&p->n_l3_address_bytes, 4);
if (!unformat (input, "%U: %U/%U -> %U/%U",
unformat_pg_edit,
unformat_ethernet_arp_opcode_net_byte_order, &p->opcode,
unformat_pg_edit,
unformat_ethernet_address, &p->ip4_over_ethernet[0].ethernet,
unformat_pg_edit,
unformat_ip4_address, &p->ip4_over_ethernet[0].ip4,
unformat_pg_edit,
unformat_ethernet_address, &p->ip4_over_ethernet[1].ethernet,
unformat_pg_edit,
unformat_ip4_address, &p->ip4_over_ethernet[1].ip4))
{
/* Free up any edits we may have added. */
pg_free_edit_group (s);
return 0;
}
return 1;
}
clib_error_t *
ip4_set_arp_limit (u32 arp_limit)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
am->limit_arp_cache_size = arp_limit;
return 0;
}
/**
* @brief Control Plane hook to remove an ARP entry
*/
int
vnet_arp_unset_ip4_over_ethernet (vnet_main_t * vnm,
u32 sw_if_index, void *a_arg)
{
ethernet_arp_ip4_over_ethernet_address_t *a = a_arg;
vnet_arp_set_ip4_over_ethernet_rpc_args_t args;
args.sw_if_index = sw_if_index;
args.flags = ETHERNET_ARP_ARGS_REMOVE;
clib_memcpy (&args.a, a, sizeof (*a));
vl_api_rpc_call_main_thread (set_ip4_over_ethernet_rpc_callback,
(u8 *) & args, sizeof (args));
return 0;
}
/**
* @brief Internally generated event to flush the ARP cache on an
* interface state change event.
* A flush will remove dynamic ARP entries, and for statics remove the MAC
* address from the corresponding adjacencies.
*/
static int
vnet_arp_flush_ip4_over_ethernet (vnet_main_t * vnm,
u32 sw_if_index, void *a_arg)
{
ethernet_arp_ip4_over_ethernet_address_t *a = a_arg;
vnet_arp_set_ip4_over_ethernet_rpc_args_t args;
args.sw_if_index = sw_if_index;
args.flags = ETHERNET_ARP_ARGS_FLUSH;
clib_memcpy (&args.a, a, sizeof (*a));
vl_api_rpc_call_main_thread (set_ip4_over_ethernet_rpc_callback,
(u8 *) & args, sizeof (args));
return 0;
}
/**
* @brief Internally generated event to populate the ARP cache on an
* interface state change event.
* For static entries this will re-source the adjacencies.
*
* @param sw_if_index The interface on which the ARP entires are acted
*/
static int
vnet_arp_populate_ip4_over_ethernet (vnet_main_t * vnm,
u32 sw_if_index, void *a_arg)
{
ethernet_arp_ip4_over_ethernet_address_t *a = a_arg;
vnet_arp_set_ip4_over_ethernet_rpc_args_t args;
args.sw_if_index = sw_if_index;
args.flags = ETHERNET_ARP_ARGS_POPULATE;
clib_memcpy (&args.a, a, sizeof (*a));
vl_api_rpc_call_main_thread (set_ip4_over_ethernet_rpc_callback,
(u8 *) & args, sizeof (args));
return 0;
}
/*
* arp_add_del_interface_address
*
* callback when an interface address is added or deleted
*/
static void
arp_add_del_interface_address (ip4_main_t * im,
uword opaque,
u32 sw_if_index,
ip4_address_t * address,
u32 address_length,
u32 if_address_index, u32 is_del)
{
/*
* Flush the ARP cache of all entries covered by the address
* that is being removed.
*/
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
if (vec_len (am->ethernet_arp_by_sw_if_index) <= sw_if_index)
return;
if (is_del)
{
ethernet_arp_interface_t *eai;
u32 i, *to_delete = 0;
hash_pair_t *pair;
eai = &am->ethernet_arp_by_sw_if_index[sw_if_index];
/* *INDENT-OFF* */
hash_foreach_pair (pair, eai->arp_entries,
({
e = pool_elt_at_index(am->ip4_entry_pool,
pair->value[0]);
if (ip4_destination_matches_route (im, &e->ip4_address,
address, address_length))
{
vec_add1 (to_delete, e - am->ip4_entry_pool);
}
}));
/* *INDENT-ON* */
for (i = 0; i < vec_len (to_delete); i++)
{
ethernet_arp_ip4_over_ethernet_address_t delme;
e = pool_elt_at_index (am->ip4_entry_pool, to_delete[i]);
clib_memcpy (&delme.ethernet, e->ethernet_address, 6);
delme.ip4.as_u32 = e->ip4_address.as_u32;
vnet_arp_flush_ip4_over_ethernet (vnet_get_main (),
e->sw_if_index, &delme);
}
vec_free (to_delete);
}
}
static clib_error_t *
ethernet_arp_init (vlib_main_t * vm)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ip4_main_t *im = &ip4_main;
clib_error_t *error;
pg_node_t *pn;
if ((error = vlib_call_init_function (vm, ethernet_init)))
return error;
ethernet_register_input_type (vm, ETHERNET_TYPE_ARP, arp_input_node.index);
pn = pg_get_node (arp_input_node.index);
pn->unformat_edit = unformat_pg_arp_header;
am->opcode_by_name = hash_create_string (0, sizeof (uword));
#define _(o) hash_set_mem (am->opcode_by_name, #o, ETHERNET_ARP_OPCODE_##o);
foreach_ethernet_arp_opcode;
#undef _
/* $$$ configurable */
am->limit_arp_cache_size = 50000;
am->pending_resolutions_by_address = hash_create (0, sizeof (uword));
am->mac_changes_by_address = hash_create (0, sizeof (uword));
/* don't trace ARP error packets */
{
vlib_node_runtime_t *rt =
vlib_node_get_runtime (vm, arp_input_node.index);
#define _(a,b) \
vnet_pcap_drop_trace_filter_add_del \
(rt->errors[ETHERNET_ARP_ERROR_##a], \
1 /* is_add */);
foreach_ethernet_arp_error
#undef _
}
ip4_add_del_interface_address_callback_t cb;
cb.function = arp_add_del_interface_address;
cb.function_opaque = 0;
vec_add1 (im->add_del_interface_address_callbacks, cb);
return 0;
}
VLIB_INIT_FUNCTION (ethernet_arp_init);
static void
arp_entry_free (ethernet_arp_interface_t * eai, ethernet_arp_ip4_entry_t * e)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
/* it's safe to delete the ADJ source on the FIB entry, even if it
* was added */
fib_table_entry_delete_index (e->fib_entry_index, FIB_SOURCE_ADJ);
hash_unset (eai->arp_entries, e->ip4_address.as_u32);
pool_put (am->ip4_entry_pool, e);
}
static inline int
vnet_arp_unset_ip4_over_ethernet_internal (vnet_main_t * vnm,
vnet_arp_set_ip4_over_ethernet_rpc_args_t
* args)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
ethernet_arp_interface_t *eai;
eai = &am->ethernet_arp_by_sw_if_index[args->sw_if_index];
e = arp_entry_find (eai, &args->a.ip4);
if (NULL != e)
{
arp_entry_free (eai, e);
adj_nbr_walk_nh4 (e->sw_if_index,
&e->ip4_address, arp_mk_incomplete_walk, NULL);
}
return 0;
}
static int
vnet_arp_flush_ip4_over_ethernet_internal (vnet_main_t * vnm,
vnet_arp_set_ip4_over_ethernet_rpc_args_t
* args)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
ethernet_arp_interface_t *eai;
eai = &am->ethernet_arp_by_sw_if_index[args->sw_if_index];
e = arp_entry_find (eai, &args->a.ip4);
if (NULL != e)
{
adj_nbr_walk_nh4 (e->sw_if_index,
&e->ip4_address, arp_mk_incomplete_walk, e);
/*
* The difference between flush and unset, is that an unset
* means delete for static and dynamic entries. A flush
* means delete only for dynamic. Flushing is what the DP
* does in response to interface events. unset is only done
* by the control plane.
*/
if (e->flags & ETHERNET_ARP_IP4_ENTRY_FLAG_DYNAMIC)
{
arp_entry_free (eai, e);
}
}
return (0);
}
static int
vnet_arp_populate_ip4_over_ethernet_internal (vnet_main_t * vnm,
vnet_arp_set_ip4_over_ethernet_rpc_args_t
* args)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
ethernet_arp_interface_t *eai;
eai = &am->ethernet_arp_by_sw_if_index[args->sw_if_index];
e = arp_entry_find (eai, &args->a.ip4);
if (NULL != e)
{
adj_nbr_walk_nh4 (e->sw_if_index,
&e->ip4_address, arp_mk_complete_walk, e);
}
return (0);
}
static void
set_ip4_over_ethernet_rpc_callback (vnet_arp_set_ip4_over_ethernet_rpc_args_t
* a)
{
vnet_main_t *vm = vnet_get_main ();
ASSERT (os_get_cpu_number () == 0);
if (a->flags & ETHERNET_ARP_ARGS_REMOVE)
vnet_arp_unset_ip4_over_ethernet_internal (vm, a);
else if (a->flags & ETHERNET_ARP_ARGS_FLUSH)
vnet_arp_flush_ip4_over_ethernet_internal (vm, a);
else if (a->flags & ETHERNET_ARP_ARGS_POPULATE)
vnet_arp_populate_ip4_over_ethernet_internal (vm, a);
else
vnet_arp_set_ip4_over_ethernet_internal (vm, a);
}
/**
* @brief Invoked when the interface's admin state changes
*/
static clib_error_t *
ethernet_arp_sw_interface_up_down (vnet_main_t * vnm,
u32 sw_if_index, u32 flags)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
u32 i, *to_delete = 0;
/* *INDENT-OFF* */
pool_foreach (e, am->ip4_entry_pool,
({
if (e->sw_if_index == sw_if_index)
vec_add1 (to_delete,
e - am->ip4_entry_pool);
}));
/* *INDENT-ON* */
for (i = 0; i < vec_len (to_delete); i++)
{
ethernet_arp_ip4_over_ethernet_address_t delme;
e = pool_elt_at_index (am->ip4_entry_pool, to_delete[i]);
clib_memcpy (&delme.ethernet, e->ethernet_address, 6);
delme.ip4.as_u32 = e->ip4_address.as_u32;
if (flags & VNET_SW_INTERFACE_FLAG_ADMIN_UP)
{
vnet_arp_populate_ip4_over_ethernet (vnm, e->sw_if_index, &delme);
}
else
{
vnet_arp_flush_ip4_over_ethernet (vnm, e->sw_if_index, &delme);
}
}
vec_free (to_delete);
return 0;
}
VNET_SW_INTERFACE_ADMIN_UP_DOWN_FUNCTION (ethernet_arp_sw_interface_up_down);
static void
increment_ip4_and_mac_address (ethernet_arp_ip4_over_ethernet_address_t * a)
{
u8 old;
int i;
for (i = 3; i >= 0; i--)
{
old = a->ip4.as_u8[i];
a->ip4.as_u8[i] += 1;
if (old < a->ip4.as_u8[i])
break;
}
for (i = 5; i >= 0; i--)
{
old = a->ethernet[i];
a->ethernet[i] += 1;
if (old < a->ethernet[i])
break;
}
}
int
vnet_arp_set_ip4_over_ethernet (vnet_main_t * vnm,
u32 sw_if_index, void *a_arg,
int is_static, int is_no_fib_entry)
{
ethernet_arp_ip4_over_ethernet_address_t *a = a_arg;
vnet_arp_set_ip4_over_ethernet_rpc_args_t args;
args.sw_if_index = sw_if_index;
args.is_static = is_static;
args.is_no_fib_entry = is_no_fib_entry;
args.flags = 0;
clib_memcpy (&args.a, a, sizeof (*a));
vl_api_rpc_call_main_thread (set_ip4_over_ethernet_rpc_callback,
(u8 *) & args, sizeof (args));
return 0;
}
int
vnet_proxy_arp_add_del (ip4_address_t * lo_addr,
ip4_address_t * hi_addr, u32 fib_index, int is_del)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_proxy_arp_t *pa;
u32 found_at_index = ~0;
vec_foreach (pa, am->proxy_arps)
{
if (pa->lo_addr == lo_addr->as_u32
&& pa->hi_addr == hi_addr->as_u32 && pa->fib_index == fib_index)
{
found_at_index = pa - am->proxy_arps;
break;
}
}
if (found_at_index != ~0)
{
/* Delete, otherwise it's already in the table */
if (is_del)
vec_delete (am->proxy_arps, 1, found_at_index);
return 0;
}
/* delete, no such entry */
if (is_del)
return VNET_API_ERROR_NO_SUCH_ENTRY;
/* add, not in table */
vec_add2 (am->proxy_arps, pa, 1);
pa->lo_addr = lo_addr->as_u32;
pa->hi_addr = hi_addr->as_u32;
pa->fib_index = fib_index;
return 0;
}
/*
* Remove any proxy arp entries asdociated with the
* specificed fib.
*/
int
vnet_proxy_arp_fib_reset (u32 fib_id)
{
ip4_main_t *im = &ip4_main;
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_proxy_arp_t *pa;
u32 *entries_to_delete = 0;
u32 fib_index;
uword *p;
int i;
p = hash_get (im->fib_index_by_table_id, fib_id);
if (!p)
return VNET_API_ERROR_NO_SUCH_ENTRY;
fib_index = p[0];
vec_foreach (pa, am->proxy_arps)
{
if (pa->fib_index == fib_index)
{
vec_add1 (entries_to_delete, pa - am->proxy_arps);
}
}
for (i = 0; i < vec_len (entries_to_delete); i++)
{
vec_delete (am->proxy_arps, 1, entries_to_delete[i]);
}
vec_free (entries_to_delete);
return 0;
}
static clib_error_t *
ip_arp_add_del_command_fn (vlib_main_t * vm,
unformat_input_t * input, vlib_cli_command_t * cmd)
{
vnet_main_t *vnm = vnet_get_main ();
u32 sw_if_index;
ethernet_arp_ip4_over_ethernet_address_t lo_addr, hi_addr, addr;
int addr_valid = 0;
int is_del = 0;
int count = 1;
u32 fib_index = 0;
u32 fib_id;
int is_static = 0;
int is_no_fib_entry = 0;
int is_proxy = 0;
while (unformat_check_input (input) != UNFORMAT_END_OF_INPUT)
{
/* set ip arp TenGigE1/1/0/1 1.2.3.4 aa:bb:... or aabb.ccdd... */
if (unformat (input, "%U %U %U",
unformat_vnet_sw_interface, vnm, &sw_if_index,
unformat_ip4_address, &addr.ip4,
unformat_ethernet_address, &addr.ethernet))
addr_valid = 1;
else if (unformat (input, "delete") || unformat (input, "del"))
is_del = 1;
else if (unformat (input, "static"))
is_static = 1;
else if (unformat (input, "no-fib-entry"))
is_no_fib_entry = 1;
else if (unformat (input, "count %d", &count))
;
else if (unformat (input, "fib-id %d", &fib_id))
{
ip4_main_t *im = &ip4_main;
uword *p = hash_get (im->fib_index_by_table_id, fib_id);
if (!p)
return clib_error_return (0, "fib ID %d doesn't exist\n", fib_id);
fib_index = p[0];
}
else if (unformat (input, "proxy %U - %U",
unformat_ip4_address, &lo_addr.ip4,
unformat_ip4_address, &hi_addr.ip4))
is_proxy = 1;
else
break;
}
if (is_proxy)
{
(void) vnet_proxy_arp_add_del (&lo_addr.ip4, &hi_addr.ip4,
fib_index, is_del);
return 0;
}
if (addr_valid)
{
int i;
for (i = 0; i < count; i++)
{
if (is_del == 0)
{
uword event_type, *event_data = 0;
/* Park the debug CLI until the arp entry is installed */
vnet_register_ip4_arp_resolution_event
(vnm, &addr.ip4, vlib_current_process (vm),
1 /* type */ , 0 /* data */ );
vnet_arp_set_ip4_over_ethernet
(vnm, sw_if_index, &addr, is_static, is_no_fib_entry);
vlib_process_wait_for_event (vm);
event_type = vlib_process_get_events (vm, &event_data);
vec_reset_length (event_data);
if (event_type != 1)
clib_warning ("event type %d unexpected", event_type);
}
else
vnet_arp_unset_ip4_over_ethernet (vnm, sw_if_index, &addr);
increment_ip4_and_mac_address (&addr);
}
}
else
{
return clib_error_return (0, "unknown input `%U'",
format_unformat_error, input);
}
return 0;
}
/* *INDENT-OFF* */
/*?
* Add or delete IPv4 ARP cache entries.
*
* @note 'set ip arp' options (e.g. delete, static, 'fib-id <id>',
* 'count <number>', 'interface ip4_addr mac_addr') can be added in
* any order and combination.
*
* @cliexpar
* @parblock
* Add or delete IPv4 ARP cache entries as follows. MAC Address can be in
* either aa:bb:cc:dd:ee:ff format or aabb.ccdd.eeff format.
* @cliexcmd{set ip arp GigabitEthernet2/0/0 6.0.0.3 dead.beef.babe}
* @cliexcmd{set ip arp delete GigabitEthernet2/0/0 6.0.0.3 de:ad:be:ef:ba:be}
*
* To add or delete an IPv4 ARP cache entry to or from a specific fib
* table:
* @cliexcmd{set ip arp fib-id 1 GigabitEthernet2/0/0 6.0.0.3 dead.beef.babe}
* @cliexcmd{set ip arp fib-id 1 delete GigabitEthernet2/0/0 6.0.0.3 dead.beef.babe}
*
* Add or delete IPv4 static ARP cache entries as follows:
* @cliexcmd{set ip arp static GigabitEthernet2/0/0 6.0.0.3 dead.beef.babe}
* @cliexcmd{set ip arp static delete GigabitEthernet2/0/0 6.0.0.3 dead.beef.babe}
*
* For testing / debugging purposes, the 'set ip arp' command can add or
* delete multiple entries. Supply the 'count N' parameter:
* @cliexcmd{set ip arp count 10 GigabitEthernet2/0/0 6.0.0.3 dead.beef.babe}
* @endparblock
?*/
VLIB_CLI_COMMAND (ip_arp_add_del_command, static) = {
.path = "set ip arp",
.short_help =
"set ip arp [del] <intfc> <ip-address> <mac-address> [static] [no-fib-entry] [count <count>] [fib-id <fib-id>] [proxy <lo-addr> - <hi-addr>]",
.function = ip_arp_add_del_command_fn,
};
/* *INDENT-ON* */
static clib_error_t *
set_int_proxy_arp_command_fn (vlib_main_t * vm,
unformat_input_t *
input, vlib_cli_command_t * cmd)
{
vnet_main_t *vnm = vnet_get_main ();
u32 sw_if_index;
vnet_sw_interface_t *si;
int enable = 0;
int intfc_set = 0;
while (unformat_check_input (input) != UNFORMAT_END_OF_INPUT)
{
if (unformat (input, "%U", unformat_vnet_sw_interface,
vnm, &sw_if_index))
intfc_set = 1;
else if (unformat (input, "enable") || unformat (input, "on"))
enable = 1;
else if (unformat (input, "disable") || unformat (input, "off"))
enable = 0;
else
break;
}
if (intfc_set == 0)
return clib_error_return (0, "unknown input '%U'",
format_unformat_error, input);
si = vnet_get_sw_interface (vnm, sw_if_index);
ASSERT (si);
if (enable)
si->flags |= VNET_SW_INTERFACE_FLAG_PROXY_ARP;
else
si->flags &= ~VNET_SW_INTERFACE_FLAG_PROXY_ARP;
return 0;
}
/* *INDENT-OFF* */
/*?
* Enable proxy-arp on an interface. The vpp stack will answer ARP
* requests for the indicated address range. Multiple proxy-arp
* ranges may be provisioned.
*
* @note Proxy ARP as a technology is infamous for blackholing traffic.
* Also, the underlying implementation has not been performance-tuned.
* Avoid creating an unnecessarily large set of ranges.
*
* @cliexpar
* To enable proxy arp on a range of addresses, use:
* @cliexcmd{set ip arp proxy 6.0.0.1 - 6.0.0.11}
* Append 'del' to delete a range of proxy ARP addresses:
* @cliexcmd{set ip arp proxy 6.0.0.1 - 6.0.0.11 del}
* You must then specifically enable proxy arp on individual interfaces:
* @cliexcmd{set interface proxy-arp GigabitEthernet0/8/0 enable}
* To disable proxy arp on an individual interface:
* @cliexcmd{set interface proxy-arp GigabitEthernet0/8/0 disable}
?*/
VLIB_CLI_COMMAND (set_int_proxy_enable_command, static) = {
.path = "set interface proxy-arp",
.short_help =
"set interface proxy-arp <intfc> [enable|disable]",
.function = set_int_proxy_arp_command_fn,
};
/* *INDENT-ON* */
/*
* ARP/ND Termination in a L2 Bridge Domain based on IP4/IP6 to MAC
* hash tables mac_by_ip4 and mac_by_ip6 for each BD.
*/
typedef enum
{
ARP_TERM_NEXT_L2_OUTPUT,
ARP_TERM_NEXT_DROP,
ARP_TERM_N_NEXT,
} arp_term_next_t;
u32 arp_term_next_node_index[32];
static uword
arp_term_l2bd (vlib_main_t * vm,
vlib_node_runtime_t * node, vlib_frame_t * frame)
{
l2input_main_t *l2im = &l2input_main;
u32 n_left_from, next_index, *from, *to_next;
u32 n_replies_sent = 0;
u16 last_bd_index = ~0;
l2_bridge_domain_t *last_bd_config = 0;
l2_input_config_t *cfg0;
from = vlib_frame_vector_args (frame);
n_left_from = frame->n_vectors;
next_index = node->cached_next_index;
while (n_left_from > 0)
{
u32 n_left_to_next;
vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next);
while (n_left_from > 0 && n_left_to_next > 0)
{
vlib_buffer_t *p0;
ethernet_header_t *eth0;
ethernet_arp_header_t *arp0;
ip6_header_t *iph0;
u8 *l3h0;
u32 pi0, error0, next0, sw_if_index0;
u16 ethertype0;
u16 bd_index0;
u32 ip0;
u8 *macp0;
pi0 = from[0];
to_next[0] = pi0;
from += 1;
to_next += 1;
n_left_from -= 1;
n_left_to_next -= 1;
p0 = vlib_get_buffer (vm, pi0);
eth0 = vlib_buffer_get_current (p0);
l3h0 = (u8 *) eth0 + vnet_buffer (p0)->l2.l2_len;
ethertype0 = clib_net_to_host_u16 (*(u16 *) (l3h0 - 2));
arp0 = (ethernet_arp_header_t *) l3h0;
if (PREDICT_FALSE ((ethertype0 != ETHERNET_TYPE_ARP) ||
(arp0->opcode !=
clib_host_to_net_u16
(ETHERNET_ARP_OPCODE_request))))
goto check_ip6_nd;
/* Must be ARP request packet here */
if (PREDICT_FALSE ((node->flags & VLIB_NODE_FLAG_TRACE) &&
(p0->flags & VLIB_BUFFER_IS_TRACED)))
{
u8 *t0 = vlib_add_trace (vm, node, p0,
sizeof (ethernet_arp_input_trace_t));
clib_memcpy (t0, l3h0, sizeof (ethernet_arp_input_trace_t));
}
error0 = ETHERNET_ARP_ERROR_replies_sent;
error0 =
(arp0->l2_type !=
clib_net_to_host_u16 (ETHERNET_ARP_HARDWARE_TYPE_ethernet)
? ETHERNET_ARP_ERROR_l2_type_not_ethernet : error0);
error0 =
(arp0->l3_type !=
clib_net_to_host_u16 (ETHERNET_TYPE_IP4) ?
ETHERNET_ARP_ERROR_l3_type_not_ip4 : error0);
sw_if_index0 = vnet_buffer (p0)->sw_if_index[VLIB_RX];
if (error0)
goto drop;
/* Trash ARP packets whose ARP-level source addresses do not
match their L2-frame-level source addresses */
if (PREDICT_FALSE
(memcmp
(eth0->src_address, arp0->ip4_over_ethernet[0].ethernet,
sizeof (eth0->src_address))))
{
error0 = ETHERNET_ARP_ERROR_l2_address_mismatch;
goto drop;
}
/* Check if anyone want ARP request events for L2 BDs */
{
pending_resolution_t *mc;
ethernet_arp_main_t *am = &ethernet_arp_main;
uword *p = hash_get (am->mac_changes_by_address, 0);
if (p && (vnet_buffer (p0)->l2.shg == 0))
{ // Only SHG 0 interface which is more likely local
u32 next_index = p[0];
while (next_index != (u32) ~ 0)
{
int (*fp) (u32, u8 *, u32, u32);
int rv = 1;
mc = pool_elt_at_index (am->mac_changes, next_index);
fp = mc->data_callback;
/* Call the callback, return 1 to suppress dup events */
if (fp)
rv = (*fp) (mc->data,
arp0->ip4_over_ethernet[0].ethernet,
sw_if_index0,
arp0->ip4_over_ethernet[0].ip4.as_u32);
/* Signal the resolver process */
if (rv == 0)
vlib_process_signal_event (vm, mc->node_index,
mc->type_opaque, mc->data);
next_index = mc->next_index;
}
}
}
/* lookup BD mac_by_ip4 hash table for MAC entry */
ip0 = arp0->ip4_over_ethernet[1].ip4.as_u32;
bd_index0 = vnet_buffer (p0)->l2.bd_index;
if (PREDICT_FALSE ((bd_index0 != last_bd_index)
|| (last_bd_index == (u16) ~ 0)))
{
last_bd_index = bd_index0;
last_bd_config = vec_elt_at_index (l2im->bd_configs, bd_index0);
}
macp0 = (u8 *) hash_get (last_bd_config->mac_by_ip4, ip0);
if (PREDICT_FALSE (!macp0))
goto next_l2_feature; /* MAC not found */
/* MAC found, send ARP reply -
Convert ARP request packet to ARP reply */
arp0->opcode = clib_host_to_net_u16 (ETHERNET_ARP_OPCODE_reply);
arp0->ip4_over_ethernet[1] = arp0->ip4_over_ethernet[0];
arp0->ip4_over_ethernet[0].ip4.as_u32 = ip0;
clib_memcpy (arp0->ip4_over_ethernet[0].ethernet, macp0, 6);
clib_memcpy (eth0->dst_address, eth0->src_address, 6);
clib_memcpy (eth0->src_address, macp0, 6);
n_replies_sent += 1;
output_response:
/* For BVI, need to use l2-fwd node to send ARP reply as
l2-output node cannot output packet to BVI properly */
cfg0 = vec_elt_at_index (l2im->configs, sw_if_index0);
if (PREDICT_FALSE (cfg0->bvi))
{
vnet_buffer (p0)->l2.feature_bitmap |= L2INPUT_FEAT_FWD;
vnet_buffer (p0)->sw_if_index[VLIB_RX] = 0;
goto next_l2_feature;
}
/* Send ARP/ND reply back out input interface through l2-output */
vnet_buffer (p0)->sw_if_index[VLIB_TX] = sw_if_index0;
next0 = ARP_TERM_NEXT_L2_OUTPUT;
/* Note that output to VXLAN tunnel will fail due to SHG which
is probably desireable since ARP termination is not intended
for ARP requests from other hosts. If output to VXLAN tunnel is
required, however, can just clear the SHG in packet as follows:
vnet_buffer(p0)->l2.shg = 0; */
vlib_validate_buffer_enqueue_x1 (vm, node, next_index,
to_next, n_left_to_next, pi0,
next0);
continue;
check_ip6_nd:
/* IP6 ND event notification or solicitation handling to generate
local response instead of flooding */
iph0 = (ip6_header_t *) l3h0;
if (PREDICT_FALSE (ethertype0 == ETHERNET_TYPE_IP6 &&
iph0->protocol == IP_PROTOCOL_ICMP6 &&
!ip6_address_is_unspecified
(&iph0->src_address)))
{
sw_if_index0 = vnet_buffer (p0)->sw_if_index[VLIB_RX];
if (vnet_ip6_nd_term
(vm, node, p0, eth0, iph0, sw_if_index0,
vnet_buffer (p0)->l2.bd_index, vnet_buffer (p0)->l2.shg))
goto output_response;
}
next_l2_feature:
{
u32 feature_bitmap0 =
vnet_buffer (p0)->l2.feature_bitmap & ~L2INPUT_FEAT_ARP_TERM;
vnet_buffer (p0)->l2.feature_bitmap = feature_bitmap0;
next0 =
feat_bitmap_get_next_node_index (arp_term_next_node_index,
feature_bitmap0);
vlib_validate_buffer_enqueue_x1 (vm, node, next_index,
to_next, n_left_to_next,
pi0, next0);
continue;
}
drop:
if (0 == arp0->ip4_over_ethernet[0].ip4.as_u32 ||
(arp0->ip4_over_ethernet[0].ip4.as_u32 ==
arp0->ip4_over_ethernet[1].ip4.as_u32))
{
error0 = ETHERNET_ARP_ERROR_gratuitous_arp;
}
next0 = ARP_TERM_NEXT_DROP;
p0->error = node->errors[error0];
vlib_validate_buffer_enqueue_x1 (vm, node, next_index,
to_next, n_left_to_next, pi0,
next0);
}
vlib_put_next_frame (vm, node, next_index, n_left_to_next);
}
vlib_error_count (vm, node->node_index,
ETHERNET_ARP_ERROR_replies_sent, n_replies_sent);
return frame->n_vectors;
}
/* *INDENT-OFF* */
VLIB_REGISTER_NODE (arp_term_l2bd_node, static) = {
.function = arp_term_l2bd,
.name = "arp-term-l2bd",
.vector_size = sizeof (u32),
.n_errors = ETHERNET_ARP_N_ERROR,
.error_strings = ethernet_arp_error_strings,
.n_next_nodes = ARP_TERM_N_NEXT,
.next_nodes = {
[ARP_TERM_NEXT_L2_OUTPUT] = "l2-output",
[ARP_TERM_NEXT_DROP] = "error-drop",
},
.format_buffer = format_ethernet_arp_header,
.format_trace = format_arp_term_input_trace,
};
/* *INDENT-ON* */
clib_error_t *
arp_term_init (vlib_main_t * vm)
{
// Initialize the feature next-node indexes
feat_bitmap_init_next_nodes (vm,
arp_term_l2bd_node.index,
L2INPUT_N_FEAT,
l2input_get_feat_names (),
arp_term_next_node_index);
return 0;
}
VLIB_INIT_FUNCTION (arp_term_init);
void
change_arp_mac (u32 sw_if_index, ethernet_arp_ip4_entry_t * e)
{
if (e->sw_if_index == sw_if_index)
{
adj_nbr_walk_nh4 (e->sw_if_index,
&e->ip4_address, arp_mk_complete_walk, e);
}
}
void
ethernet_arp_change_mac (u32 sw_if_index)
{
ethernet_arp_main_t *am = &ethernet_arp_main;
ethernet_arp_ip4_entry_t *e;
/* *INDENT-OFF* */
pool_foreach (e, am->ip4_entry_pool,
({
change_arp_mac (sw_if_index, e);
}));
/* *INDENT-ON* */
}
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/