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mirror_frr/zebra/if_netlink.c
David Lamparter 3efd0893d0 *: un-split strings across lines 
Remove mid-string line breaks, cf. workflow doc:

  .. [#tool_style_conflicts] For example, lines over 80 characters are allowed
     for text strings to make it possible to search the code for them: please
     see `Linux kernel style (breaking long lines and strings)
     <https://www.kernel.org/doc/html/v4.10/process/coding-style.html#breaking-long-lines-and-strings>`_
     and `Issue #1794 <https://github.com/FRRouting/frr/issues/1794>`_.

Scripted commit, idempotent to running:
```
python3 tools/stringmangle.py --unwrap `git ls-files | egrep '\.[ch]$'`
```

Signed-off-by: David Lamparter <equinox@diac24.net>
2020-07-14 10:37:25 +02:00

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/*
* Interface looking up by netlink.
* Copyright (C) 1998 Kunihiro Ishiguro
*
* This file is part of GNU Zebra.
*
* GNU Zebra is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 2, or (at your option) any
* later version.
*
* GNU Zebra is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; see the file COPYING; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <zebra.h>
#ifdef GNU_LINUX
/* The following definition is to workaround an issue in the Linux kernel
* header files with redefinition of 'struct in6_addr' in both
* netinet/in.h and linux/in6.h.
* Reference - https://sourceware.org/ml/libc-alpha/2013-01/msg00599.html
*/
#define _LINUX_IN6_H
#include <netinet/if_ether.h>
#include <linux/if_bridge.h>
#include <linux/if_link.h>
#include <net/if_arp.h>
#include <linux/sockios.h>
#include <linux/ethtool.h>
#include "linklist.h"
#include "if.h"
#include "log.h"
#include "prefix.h"
#include "connected.h"
#include "table.h"
#include "memory.h"
#include "zebra_memory.h"
#include "rib.h"
#include "thread.h"
#include "privs.h"
#include "nexthop.h"
#include "vrf.h"
#include "vrf_int.h"
#include "mpls.h"
#include "lib_errors.h"
#include "vty.h"
#include "zebra/zserv.h"
#include "zebra/zebra_ns.h"
#include "zebra/zebra_vrf.h"
#include "zebra/rt.h"
#include "zebra/redistribute.h"
#include "zebra/interface.h"
#include "zebra/debug.h"
#include "zebra/rtadv.h"
#include "zebra/zebra_ptm.h"
#include "zebra/zebra_mpls.h"
#include "zebra/kernel_netlink.h"
#include "zebra/rt_netlink.h"
#include "zebra/if_netlink.h"
#include "zebra/zebra_errors.h"
#include "zebra/zebra_vxlan.h"
extern struct zebra_privs_t zserv_privs;
/* Note: on netlink systems, there should be a 1-to-1 mapping between interface
names and ifindex values. */
static void set_ifindex(struct interface *ifp, ifindex_t ifi_index,
struct zebra_ns *zns)
{
struct interface *oifp;
if (((oifp = if_lookup_by_index_per_ns(zns, ifi_index)) != NULL)
&& (oifp != ifp)) {
if (ifi_index == IFINDEX_INTERNAL)
flog_err(
EC_LIB_INTERFACE,
"Netlink is setting interface %s ifindex to reserved internal value %u",
ifp->name, ifi_index);
else {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"interface index %d was renamed from %s to %s",
ifi_index, oifp->name, ifp->name);
if (if_is_up(oifp))
flog_err(
EC_LIB_INTERFACE,
"interface rename detected on up interface: index %d was renamed from %s to %s, results are uncertain!",
ifi_index, oifp->name, ifp->name);
if_delete_update(oifp);
}
}
if_set_index(ifp, ifi_index);
}
/* Utility function to parse hardware link-layer address and update ifp */
static void netlink_interface_update_hw_addr(struct rtattr **tb,
struct interface *ifp)
{
int i;
if (tb[IFLA_ADDRESS]) {
int hw_addr_len;
hw_addr_len = RTA_PAYLOAD(tb[IFLA_ADDRESS]);
if (hw_addr_len > INTERFACE_HWADDR_MAX)
zlog_debug("Hardware address is too large: %d",
hw_addr_len);
else {
ifp->hw_addr_len = hw_addr_len;
memcpy(ifp->hw_addr, RTA_DATA(tb[IFLA_ADDRESS]),
hw_addr_len);
for (i = 0; i < hw_addr_len; i++)
if (ifp->hw_addr[i] != 0)
break;
if (i == hw_addr_len)
ifp->hw_addr_len = 0;
else
ifp->hw_addr_len = hw_addr_len;
}
}
}
static enum zebra_link_type netlink_to_zebra_link_type(unsigned int hwt)
{
switch (hwt) {
case ARPHRD_ETHER:
return ZEBRA_LLT_ETHER;
case ARPHRD_EETHER:
return ZEBRA_LLT_EETHER;
case ARPHRD_AX25:
return ZEBRA_LLT_AX25;
case ARPHRD_PRONET:
return ZEBRA_LLT_PRONET;
case ARPHRD_IEEE802:
return ZEBRA_LLT_IEEE802;
case ARPHRD_ARCNET:
return ZEBRA_LLT_ARCNET;
case ARPHRD_APPLETLK:
return ZEBRA_LLT_APPLETLK;
case ARPHRD_DLCI:
return ZEBRA_LLT_DLCI;
case ARPHRD_ATM:
return ZEBRA_LLT_ATM;
case ARPHRD_METRICOM:
return ZEBRA_LLT_METRICOM;
case ARPHRD_IEEE1394:
return ZEBRA_LLT_IEEE1394;
case ARPHRD_EUI64:
return ZEBRA_LLT_EUI64;
case ARPHRD_INFINIBAND:
return ZEBRA_LLT_INFINIBAND;
case ARPHRD_SLIP:
return ZEBRA_LLT_SLIP;
case ARPHRD_CSLIP:
return ZEBRA_LLT_CSLIP;
case ARPHRD_SLIP6:
return ZEBRA_LLT_SLIP6;
case ARPHRD_CSLIP6:
return ZEBRA_LLT_CSLIP6;
case ARPHRD_RSRVD:
return ZEBRA_LLT_RSRVD;
case ARPHRD_ADAPT:
return ZEBRA_LLT_ADAPT;
case ARPHRD_ROSE:
return ZEBRA_LLT_ROSE;
case ARPHRD_X25:
return ZEBRA_LLT_X25;
case ARPHRD_PPP:
return ZEBRA_LLT_PPP;
case ARPHRD_CISCO:
return ZEBRA_LLT_CHDLC;
case ARPHRD_LAPB:
return ZEBRA_LLT_LAPB;
case ARPHRD_RAWHDLC:
return ZEBRA_LLT_RAWHDLC;
case ARPHRD_TUNNEL:
return ZEBRA_LLT_IPIP;
case ARPHRD_TUNNEL6:
return ZEBRA_LLT_IPIP6;
case ARPHRD_FRAD:
return ZEBRA_LLT_FRAD;
case ARPHRD_SKIP:
return ZEBRA_LLT_SKIP;
case ARPHRD_LOOPBACK:
return ZEBRA_LLT_LOOPBACK;
case ARPHRD_LOCALTLK:
return ZEBRA_LLT_LOCALTLK;
case ARPHRD_FDDI:
return ZEBRA_LLT_FDDI;
case ARPHRD_SIT:
return ZEBRA_LLT_SIT;
case ARPHRD_IPDDP:
return ZEBRA_LLT_IPDDP;
case ARPHRD_IPGRE:
return ZEBRA_LLT_IPGRE;
case ARPHRD_PIMREG:
return ZEBRA_LLT_PIMREG;
case ARPHRD_HIPPI:
return ZEBRA_LLT_HIPPI;
case ARPHRD_ECONET:
return ZEBRA_LLT_ECONET;
case ARPHRD_IRDA:
return ZEBRA_LLT_IRDA;
case ARPHRD_FCPP:
return ZEBRA_LLT_FCPP;
case ARPHRD_FCAL:
return ZEBRA_LLT_FCAL;
case ARPHRD_FCPL:
return ZEBRA_LLT_FCPL;
case ARPHRD_FCFABRIC:
return ZEBRA_LLT_FCFABRIC;
case ARPHRD_IEEE802_TR:
return ZEBRA_LLT_IEEE802_TR;
case ARPHRD_IEEE80211:
return ZEBRA_LLT_IEEE80211;
#ifdef ARPHRD_IEEE802154
case ARPHRD_IEEE802154:
return ZEBRA_LLT_IEEE802154;
#endif
#ifdef ARPHRD_IP6GRE
case ARPHRD_IP6GRE:
return ZEBRA_LLT_IP6GRE;
#endif
#ifdef ARPHRD_IEEE802154_PHY
case ARPHRD_IEEE802154_PHY:
return ZEBRA_LLT_IEEE802154_PHY;
#endif
default:
return ZEBRA_LLT_UNKNOWN;
}
}
static void netlink_determine_zebra_iftype(const char *kind,
zebra_iftype_t *zif_type)
{
*zif_type = ZEBRA_IF_OTHER;
if (!kind)
return;
if (strcmp(kind, "vrf") == 0)
*zif_type = ZEBRA_IF_VRF;
else if (strcmp(kind, "bridge") == 0)
*zif_type = ZEBRA_IF_BRIDGE;
else if (strcmp(kind, "vlan") == 0)
*zif_type = ZEBRA_IF_VLAN;
else if (strcmp(kind, "vxlan") == 0)
*zif_type = ZEBRA_IF_VXLAN;
else if (strcmp(kind, "macvlan") == 0)
*zif_type = ZEBRA_IF_MACVLAN;
else if (strcmp(kind, "veth") == 0)
*zif_type = ZEBRA_IF_VETH;
else if (strcmp(kind, "bond") == 0)
*zif_type = ZEBRA_IF_BOND;
else if (strcmp(kind, "bond_slave") == 0)
*zif_type = ZEBRA_IF_BOND_SLAVE;
}
#define parse_rtattr_nested(tb, max, rta) \
netlink_parse_rtattr((tb), (max), RTA_DATA(rta), RTA_PAYLOAD(rta))
static void netlink_vrf_change(struct nlmsghdr *h, struct rtattr *tb,
uint32_t ns_id, const char *name)
{
struct ifinfomsg *ifi;
struct rtattr *linkinfo[IFLA_INFO_MAX + 1];
struct rtattr *attr[IFLA_VRF_MAX + 1];
struct vrf *vrf;
struct zebra_vrf *zvrf;
uint32_t nl_table_id;
ifi = NLMSG_DATA(h);
memset(linkinfo, 0, sizeof(linkinfo));
parse_rtattr_nested(linkinfo, IFLA_INFO_MAX, tb);
if (!linkinfo[IFLA_INFO_DATA]) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"%s: IFLA_INFO_DATA missing from VRF message: %s",
__func__, name);
return;
}
memset(attr, 0, sizeof(attr));
parse_rtattr_nested(attr, IFLA_VRF_MAX, linkinfo[IFLA_INFO_DATA]);
if (!attr[IFLA_VRF_TABLE]) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"%s: IFLA_VRF_TABLE missing from VRF message: %s",
__func__, name);
return;
}
nl_table_id = *(uint32_t *)RTA_DATA(attr[IFLA_VRF_TABLE]);
if (h->nlmsg_type == RTM_NEWLINK) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("RTM_NEWLINK for VRF %s(%u) table %u", name,
ifi->ifi_index, nl_table_id);
if (!vrf_lookup_by_id((vrf_id_t)ifi->ifi_index)) {
vrf_id_t exist_id;
exist_id = vrf_lookup_by_table(nl_table_id, ns_id);
if (exist_id != VRF_DEFAULT) {
vrf = vrf_lookup_by_id(exist_id);
flog_err(
EC_ZEBRA_VRF_MISCONFIGURED,
"VRF %s id %u table id overlaps existing vrf %s, misconfiguration exiting",
name, ifi->ifi_index, vrf->name);
exit(-1);
}
}
/*
* vrf_get is implied creation if it does not exist
*/
vrf = vrf_get((vrf_id_t)ifi->ifi_index,
name); // It would create vrf
if (!vrf) {
flog_err(EC_LIB_INTERFACE, "VRF %s id %u not created",
name, ifi->ifi_index);
return;
}
/*
* This is the only place that we get the actual kernel table_id
* being used. We need it to set the table_id of the routes
* we are passing to the kernel.... And to throw some totally
* awesome parties. that too.
*
* At this point we *must* have a zvrf because the vrf_create
* callback creates one. We *must* set the table id
* before the vrf_enable because of( at the very least )
* static routes being delayed for installation until
* during the vrf_enable callbacks.
*/
zvrf = (struct zebra_vrf *)vrf->info;
zvrf->table_id = nl_table_id;
/* Enable the created VRF. */
if (!vrf_enable(vrf)) {
flog_err(EC_LIB_INTERFACE,
"Failed to enable VRF %s id %u", name,
ifi->ifi_index);
return;
}
} else // h->nlmsg_type == RTM_DELLINK
{
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("RTM_DELLINK for VRF %s(%u)", name,
ifi->ifi_index);
vrf = vrf_lookup_by_id((vrf_id_t)ifi->ifi_index);
if (!vrf) {
flog_warn(EC_ZEBRA_VRF_NOT_FOUND, "%s: vrf not found",
__func__);
return;
}
vrf_delete(vrf);
}
}
static uint32_t get_iflink_speed(struct interface *interface, int *error)
{
struct ifreq ifdata;
struct ethtool_cmd ecmd;
int sd;
int rc;
const char *ifname = interface->name;
if (error)
*error = 0;
/* initialize struct */
memset(&ifdata, 0, sizeof(ifdata));
/* set interface name */
strlcpy(ifdata.ifr_name, ifname, sizeof(ifdata.ifr_name));
/* initialize ethtool interface */
memset(&ecmd, 0, sizeof(ecmd));
ecmd.cmd = ETHTOOL_GSET; /* ETHTOOL_GLINK */
ifdata.ifr_data = (caddr_t)&ecmd;
/* use ioctl to get IP address of an interface */
frr_with_privs(&zserv_privs) {
sd = vrf_socket(PF_INET, SOCK_DGRAM, IPPROTO_IP,
interface->vrf_id,
NULL);
if (sd < 0) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("Failure to read interface %s speed: %d %s",
ifname, errno, safe_strerror(errno));
/* no vrf socket creation may probably mean vrf issue */
if (error)
*error = -1;
return 0;
}
/* Get the current link state for the interface */
rc = vrf_ioctl(interface->vrf_id, sd, SIOCETHTOOL,
(char *)&ifdata);
}
if (rc < 0) {
if (errno != EOPNOTSUPP && IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"IOCTL failure to read interface %s speed: %d %s",
ifname, errno, safe_strerror(errno));
/* no device means interface unreachable */
if (errno == ENODEV && error)
*error = -1;
ecmd.speed_hi = 0;
ecmd.speed = 0;
}
close(sd);
return ((uint32_t)ecmd.speed_hi << 16) | ecmd.speed;
}
uint32_t kernel_get_speed(struct interface *ifp, int *error)
{
return get_iflink_speed(ifp, error);
}
static int netlink_extract_bridge_info(struct rtattr *link_data,
struct zebra_l2info_bridge *bridge_info)
{
struct rtattr *attr[IFLA_BR_MAX + 1];
memset(bridge_info, 0, sizeof(*bridge_info));
memset(attr, 0, sizeof(attr));
parse_rtattr_nested(attr, IFLA_BR_MAX, link_data);
if (attr[IFLA_BR_VLAN_FILTERING])
bridge_info->vlan_aware =
*(uint8_t *)RTA_DATA(attr[IFLA_BR_VLAN_FILTERING]);
return 0;
}
static int netlink_extract_vlan_info(struct rtattr *link_data,
struct zebra_l2info_vlan *vlan_info)
{
struct rtattr *attr[IFLA_VLAN_MAX + 1];
vlanid_t vid_in_msg;
memset(vlan_info, 0, sizeof(*vlan_info));
memset(attr, 0, sizeof(attr));
parse_rtattr_nested(attr, IFLA_VLAN_MAX, link_data);
if (!attr[IFLA_VLAN_ID]) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("IFLA_VLAN_ID missing from VLAN IF message");
return -1;
}
vid_in_msg = *(vlanid_t *)RTA_DATA(attr[IFLA_VLAN_ID]);
vlan_info->vid = vid_in_msg;
return 0;
}
static int netlink_extract_vxlan_info(struct rtattr *link_data,
struct zebra_l2info_vxlan *vxl_info)
{
struct rtattr *attr[IFLA_VXLAN_MAX + 1];
vni_t vni_in_msg;
struct in_addr vtep_ip_in_msg;
ifindex_t ifindex_link;
memset(vxl_info, 0, sizeof(*vxl_info));
memset(attr, 0, sizeof(attr));
parse_rtattr_nested(attr, IFLA_VXLAN_MAX, link_data);
if (!attr[IFLA_VXLAN_ID]) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"IFLA_VXLAN_ID missing from VXLAN IF message");
return -1;
}
vni_in_msg = *(vni_t *)RTA_DATA(attr[IFLA_VXLAN_ID]);
vxl_info->vni = vni_in_msg;
if (!attr[IFLA_VXLAN_LOCAL]) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"IFLA_VXLAN_LOCAL missing from VXLAN IF message");
} else {
vtep_ip_in_msg =
*(struct in_addr *)RTA_DATA(attr[IFLA_VXLAN_LOCAL]);
vxl_info->vtep_ip = vtep_ip_in_msg;
}
if (attr[IFLA_VXLAN_GROUP]) {
vxl_info->mcast_grp =
*(struct in_addr *)RTA_DATA(attr[IFLA_VXLAN_GROUP]);
}
if (!attr[IFLA_VXLAN_LINK]) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("IFLA_VXLAN_LINK missing from VXLAN IF message");
} else {
ifindex_link =
*(ifindex_t *)RTA_DATA(attr[IFLA_VXLAN_LINK]);
vxl_info->ifindex_link = ifindex_link;
}
return 0;
}
/*
* Extract and save L2 params (of interest) for an interface. When a
* bridge interface is added or updated, take further actions to map
* its members. Likewise, for VxLAN interface.
*/
static void netlink_interface_update_l2info(struct interface *ifp,
struct rtattr *link_data, int add,
ns_id_t link_nsid)
{
if (!link_data)
return;
if (IS_ZEBRA_IF_BRIDGE(ifp)) {
struct zebra_l2info_bridge bridge_info;
netlink_extract_bridge_info(link_data, &bridge_info);
zebra_l2_bridge_add_update(ifp, &bridge_info, add);
} else if (IS_ZEBRA_IF_VLAN(ifp)) {
struct zebra_l2info_vlan vlan_info;
netlink_extract_vlan_info(link_data, &vlan_info);
zebra_l2_vlanif_update(ifp, &vlan_info);
} else if (IS_ZEBRA_IF_VXLAN(ifp)) {
struct zebra_l2info_vxlan vxlan_info;
netlink_extract_vxlan_info(link_data, &vxlan_info);
vxlan_info.link_nsid = link_nsid;
zebra_l2_vxlanif_add_update(ifp, &vxlan_info, add);
if (link_nsid != NS_UNKNOWN &&
vxlan_info.ifindex_link)
zebra_if_update_link(ifp, vxlan_info.ifindex_link,
link_nsid);
}
}
static int netlink_bridge_interface(struct nlmsghdr *h, int len, ns_id_t ns_id,
int startup)
{
char *name = NULL;
struct ifinfomsg *ifi;
struct rtattr *tb[IFLA_MAX + 1];
struct interface *ifp;
struct rtattr *aftb[IFLA_BRIDGE_MAX + 1];
struct {
uint16_t flags;
uint16_t vid;
} * vinfo;
vlanid_t access_vlan;
/* Fetch name and ifindex */
ifi = NLMSG_DATA(h);
memset(tb, 0, sizeof(tb));
netlink_parse_rtattr(tb, IFLA_MAX, IFLA_RTA(ifi), len);
if (tb[IFLA_IFNAME] == NULL)
return -1;
name = (char *)RTA_DATA(tb[IFLA_IFNAME]);
/* The interface should already be known, if not discard. */
ifp = if_lookup_by_index_per_ns(zebra_ns_lookup(ns_id), ifi->ifi_index);
if (!ifp) {
zlog_debug("Cannot find bridge IF %s(%u)", name,
ifi->ifi_index);
return 0;
}
if (!IS_ZEBRA_IF_VXLAN(ifp))
return 0;
/* We are only interested in the access VLAN i.e., AF_SPEC */
if (!tb[IFLA_AF_SPEC])
return 0;
/* There is a 1-to-1 mapping of VLAN to VxLAN - hence
* only 1 access VLAN is accepted.
*/
memset(aftb, 0, sizeof(aftb));
parse_rtattr_nested(aftb, IFLA_BRIDGE_MAX, tb[IFLA_AF_SPEC]);
if (!aftb[IFLA_BRIDGE_VLAN_INFO])
return 0;
vinfo = RTA_DATA(aftb[IFLA_BRIDGE_VLAN_INFO]);
if (!(vinfo->flags & BRIDGE_VLAN_INFO_PVID))
return 0;
access_vlan = (vlanid_t)vinfo->vid;
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("Access VLAN %u for VxLAN IF %s(%u)", access_vlan,
name, ifi->ifi_index);
zebra_l2_vxlanif_update_access_vlan(ifp, access_vlan);
return 0;
}
/*
* Called from interface_lookup_netlink(). This function is only used
* during bootstrap.
*/
static int netlink_interface(struct nlmsghdr *h, ns_id_t ns_id, int startup)
{
int len;
struct ifinfomsg *ifi;
struct rtattr *tb[IFLA_MAX + 1];
struct rtattr *linkinfo[IFLA_MAX + 1];
struct interface *ifp;
char *name = NULL;
char *kind = NULL;
char *desc = NULL;
char *slave_kind = NULL;
struct zebra_ns *zns = NULL;
vrf_id_t vrf_id = VRF_DEFAULT;
zebra_iftype_t zif_type = ZEBRA_IF_OTHER;
zebra_slave_iftype_t zif_slave_type = ZEBRA_IF_SLAVE_NONE;
ifindex_t bridge_ifindex = IFINDEX_INTERNAL;
ifindex_t link_ifindex = IFINDEX_INTERNAL;
ifindex_t bond_ifindex = IFINDEX_INTERNAL;
struct zebra_if *zif;
ns_id_t link_nsid = ns_id;
zns = zebra_ns_lookup(ns_id);
ifi = NLMSG_DATA(h);
if (h->nlmsg_type != RTM_NEWLINK)
return 0;
len = h->nlmsg_len - NLMSG_LENGTH(sizeof(struct ifinfomsg));
if (len < 0) {
zlog_err(
"%s: Message received from netlink is of a broken size: %d %zu",
__func__, h->nlmsg_len,
(size_t)NLMSG_LENGTH(sizeof(struct ifinfomsg)));
return -1;
}
/* We are interested in some AF_BRIDGE notifications. */
if (ifi->ifi_family == AF_BRIDGE)
return netlink_bridge_interface(h, len, ns_id, startup);
/* Looking up interface name. */
memset(tb, 0, sizeof(tb));
memset(linkinfo, 0, sizeof(linkinfo));
netlink_parse_rtattr(tb, IFLA_MAX, IFLA_RTA(ifi), len);
/* check for wireless messages to ignore */
if ((tb[IFLA_WIRELESS] != NULL) && (ifi->ifi_change == 0)) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("%s: ignoring IFLA_WIRELESS message",
__func__);
return 0;
}
if (tb[IFLA_IFNAME] == NULL)
return -1;
name = (char *)RTA_DATA(tb[IFLA_IFNAME]);
if (tb[IFLA_IFALIAS])
desc = (char *)RTA_DATA(tb[IFLA_IFALIAS]);
if (tb[IFLA_LINKINFO]) {
parse_rtattr_nested(linkinfo, IFLA_INFO_MAX, tb[IFLA_LINKINFO]);
if (linkinfo[IFLA_INFO_KIND])
kind = RTA_DATA(linkinfo[IFLA_INFO_KIND]);
if (linkinfo[IFLA_INFO_SLAVE_KIND])
slave_kind = RTA_DATA(linkinfo[IFLA_INFO_SLAVE_KIND]);
if ((slave_kind != NULL) && strcmp(slave_kind, "bond") == 0)
netlink_determine_zebra_iftype("bond_slave", &zif_type);
else
netlink_determine_zebra_iftype(kind, &zif_type);
}
/* If VRF, create the VRF structure itself. */
if (zif_type == ZEBRA_IF_VRF && !vrf_is_backend_netns()) {
netlink_vrf_change(h, tb[IFLA_LINKINFO], ns_id, name);
vrf_id = (vrf_id_t)ifi->ifi_index;
}
if (tb[IFLA_MASTER]) {
if (slave_kind && (strcmp(slave_kind, "vrf") == 0)
&& !vrf_is_backend_netns()) {
zif_slave_type = ZEBRA_IF_SLAVE_VRF;
vrf_id = *(uint32_t *)RTA_DATA(tb[IFLA_MASTER]);
} else if (slave_kind && (strcmp(slave_kind, "bridge") == 0)) {
zif_slave_type = ZEBRA_IF_SLAVE_BRIDGE;
bridge_ifindex =
*(ifindex_t *)RTA_DATA(tb[IFLA_MASTER]);
} else if (slave_kind && (strcmp(slave_kind, "bond") == 0)) {
zif_slave_type = ZEBRA_IF_SLAVE_BOND;
bond_ifindex = *(ifindex_t *)RTA_DATA(tb[IFLA_MASTER]);
} else
zif_slave_type = ZEBRA_IF_SLAVE_OTHER;
}
if (vrf_is_backend_netns())
vrf_id = (vrf_id_t)ns_id;
/* If linking to another interface, note it. */
if (tb[IFLA_LINK])
link_ifindex = *(ifindex_t *)RTA_DATA(tb[IFLA_LINK]);
if (tb[IFLA_LINK_NETNSID]) {
link_nsid = *(ns_id_t *)RTA_DATA(tb[IFLA_LINK_NETNSID]);
link_nsid = ns_id_get_absolute(ns_id, link_nsid);
}
/* Add interface.
* We add by index first because in some cases such as the master
* interface, we have the index before we have the name. Fixing
* back references on the slave interfaces is painful if not done
* this way, i.e. by creating by ifindex.
*/
ifp = if_get_by_ifindex(ifi->ifi_index, vrf_id, name);
set_ifindex(ifp, ifi->ifi_index, zns); /* add it to ns struct */
ifp->flags = ifi->ifi_flags & 0x0000fffff;
ifp->mtu6 = ifp->mtu = *(uint32_t *)RTA_DATA(tb[IFLA_MTU]);
ifp->metric = 0;
ifp->speed = get_iflink_speed(ifp, NULL);
ifp->ptm_status = ZEBRA_PTM_STATUS_UNKNOWN;
/* Set zebra interface type */
zebra_if_set_ziftype(ifp, zif_type, zif_slave_type);
if (IS_ZEBRA_IF_VRF(ifp))
SET_FLAG(ifp->status, ZEBRA_INTERFACE_VRF_LOOPBACK);
/*
* Just set the @link/lower-device ifindex. During nldump interfaces are
* not ordered in any fashion so we may end up getting upper devices
* before lower devices. We will setup the real linkage once the dump
* is complete.
*/
zif = (struct zebra_if *)ifp->info;
zif->link_ifindex = link_ifindex;
if (desc) {
XFREE(MTYPE_TMP, zif->desc);
zif->desc = XSTRDUP(MTYPE_TMP, desc);
}
/* Hardware type and address. */
ifp->ll_type = netlink_to_zebra_link_type(ifi->ifi_type);
netlink_interface_update_hw_addr(tb, ifp);
if_add_update(ifp);
/* Extract and save L2 interface information, take additional actions.
*/
netlink_interface_update_l2info(ifp, linkinfo[IFLA_INFO_DATA],
1, link_nsid);
if (IS_ZEBRA_IF_BRIDGE_SLAVE(ifp))
zebra_l2if_update_bridge_slave(ifp, bridge_ifindex, ns_id);
else if (IS_ZEBRA_IF_BOND_SLAVE(ifp))
zebra_l2if_update_bond_slave(ifp, bond_ifindex);
return 0;
}
/* Request for specific interface or address information from the kernel */
static int netlink_request_intf_addr(struct nlsock *netlink_cmd, int family,
int type, uint32_t filter_mask)
{
struct {
struct nlmsghdr n;
struct ifinfomsg ifm;
char buf[256];
} req;
/* Form the request, specifying filter (rtattr) if needed. */
memset(&req, 0, sizeof(req));
req.n.nlmsg_type = type;
req.n.nlmsg_flags = NLM_F_ROOT | NLM_F_MATCH | NLM_F_REQUEST;
req.n.nlmsg_len = NLMSG_LENGTH(sizeof(struct ifinfomsg));
req.ifm.ifi_family = family;
/* Include filter, if specified. */
if (filter_mask)
nl_attr_put32(&req.n, sizeof(req), IFLA_EXT_MASK, filter_mask);
return netlink_request(netlink_cmd, &req);
}
/* Interface lookup by netlink socket. */
int interface_lookup_netlink(struct zebra_ns *zns)
{
int ret;
struct zebra_dplane_info dp_info;
struct nlsock *netlink_cmd = &zns->netlink_cmd;
/* Capture key info from ns struct */
zebra_dplane_info_from_zns(&dp_info, zns, true /*is_cmd*/);
/* Get interface information. */
ret = netlink_request_intf_addr(netlink_cmd, AF_PACKET, RTM_GETLINK, 0);
if (ret < 0)
return ret;
ret = netlink_parse_info(netlink_interface, netlink_cmd, &dp_info, 0,
1);
if (ret < 0)
return ret;
/* Get interface information - for bridge interfaces. */
ret = netlink_request_intf_addr(netlink_cmd, AF_BRIDGE, RTM_GETLINK,
RTEXT_FILTER_BRVLAN);
if (ret < 0)
return ret;
ret = netlink_parse_info(netlink_interface, netlink_cmd, &dp_info, 0,
0);
if (ret < 0)
return ret;
/* Get interface information - for bridge interfaces. */
ret = netlink_request_intf_addr(netlink_cmd, AF_BRIDGE, RTM_GETLINK,
RTEXT_FILTER_BRVLAN);
if (ret < 0)
return ret;
ret = netlink_parse_info(netlink_interface, netlink_cmd, &dp_info, 0,
0);
if (ret < 0)
return ret;
/* fixup linkages */
zebra_if_update_all_links();
return 0;
}
/**
* interface_addr_lookup_netlink() - Look up interface addresses
*
* @zns: Zebra netlink socket
* Return: Result status
*/
static int interface_addr_lookup_netlink(struct zebra_ns *zns)
{
int ret;
struct zebra_dplane_info dp_info;
struct nlsock *netlink_cmd = &zns->netlink_cmd;
/* Capture key info from ns struct */
zebra_dplane_info_from_zns(&dp_info, zns, true /*is_cmd*/);
/* Get IPv4 address of the interfaces. */
ret = netlink_request_intf_addr(netlink_cmd, AF_INET, RTM_GETADDR, 0);
if (ret < 0)
return ret;
ret = netlink_parse_info(netlink_interface_addr, netlink_cmd, &dp_info,
0, 1);
if (ret < 0)
return ret;
/* Get IPv6 address of the interfaces. */
ret = netlink_request_intf_addr(netlink_cmd, AF_INET6, RTM_GETADDR, 0);
if (ret < 0)
return ret;
ret = netlink_parse_info(netlink_interface_addr, netlink_cmd, &dp_info,
0, 1);
if (ret < 0)
return ret;
return 0;
}
int kernel_interface_set_master(struct interface *master,
struct interface *slave)
{
struct zebra_ns *zns = zebra_ns_lookup(NS_DEFAULT);
struct {
struct nlmsghdr n;
struct ifinfomsg ifa;
char buf[NL_PKT_BUF_SIZE];
} req;
memset(&req, 0, sizeof(req));
req.n.nlmsg_len = NLMSG_LENGTH(sizeof(struct ifinfomsg));
req.n.nlmsg_flags = NLM_F_REQUEST;
req.n.nlmsg_type = RTM_SETLINK;
req.n.nlmsg_pid = zns->netlink_cmd.snl.nl_pid;
req.ifa.ifi_index = slave->ifindex;
nl_attr_put32(&req.n, sizeof(req), IFLA_MASTER, master->ifindex);
nl_attr_put32(&req.n, sizeof(req), IFLA_LINK, slave->ifindex);
return netlink_talk(netlink_talk_filter, &req.n, &zns->netlink_cmd, zns,
0);
}
/* Interface address modification. */
static int netlink_address_ctx(const struct zebra_dplane_ctx *ctx)
{
int bytelen;
const struct prefix *p;
int cmd;
const char *label;
struct {
struct nlmsghdr n;
struct ifaddrmsg ifa;
char buf[NL_PKT_BUF_SIZE];
} req;
p = dplane_ctx_get_intf_addr(ctx);
memset(&req, 0, sizeof(req) - NL_PKT_BUF_SIZE);
bytelen = (p->family == AF_INET ? 4 : 16);
req.n.nlmsg_len = NLMSG_LENGTH(sizeof(struct ifaddrmsg));
req.n.nlmsg_flags = NLM_F_REQUEST;
if (dplane_ctx_get_op(ctx) == DPLANE_OP_ADDR_INSTALL)
cmd = RTM_NEWADDR;
else
cmd = RTM_DELADDR;
req.n.nlmsg_type = cmd;
req.ifa.ifa_family = p->family;
req.ifa.ifa_index = dplane_ctx_get_ifindex(ctx);
nl_attr_put(&req.n, sizeof(req), IFA_LOCAL, &p->u.prefix, bytelen);
if (p->family == AF_INET) {
if (dplane_ctx_intf_is_connected(ctx)) {
p = dplane_ctx_get_intf_dest(ctx);
nl_attr_put(&req.n, sizeof(req), IFA_ADDRESS,
&p->u.prefix, bytelen);
} else if (cmd == RTM_NEWADDR) {
struct in_addr broad = {
.s_addr = ipv4_broadcast_addr(p->u.prefix4.s_addr,
p->prefixlen)
};
nl_attr_put(&req.n, sizeof(req), IFA_BROADCAST, &broad,
bytelen);
}
}
/* p is now either address or destination/bcast addr */
req.ifa.ifa_prefixlen = p->prefixlen;
if (dplane_ctx_intf_is_secondary(ctx))
SET_FLAG(req.ifa.ifa_flags, IFA_F_SECONDARY);
if (dplane_ctx_intf_has_label(ctx)) {
label = dplane_ctx_get_intf_label(ctx);
nl_attr_put(&req.n, sizeof(req), IFA_LABEL, label,
strlen(label) + 1);
}
return netlink_talk_info(netlink_talk_filter, &req.n,
dplane_ctx_get_ns(ctx), 0);
}
enum zebra_dplane_result kernel_address_update_ctx(struct zebra_dplane_ctx *ctx)
{
return (netlink_address_ctx(ctx) == 0 ?
ZEBRA_DPLANE_REQUEST_SUCCESS : ZEBRA_DPLANE_REQUEST_FAILURE);
}
int netlink_interface_addr(struct nlmsghdr *h, ns_id_t ns_id, int startup)
{
int len;
struct ifaddrmsg *ifa;
struct rtattr *tb[IFA_MAX + 1];
struct interface *ifp;
void *addr;
void *broad;
uint8_t flags = 0;
char *label = NULL;
struct zebra_ns *zns;
uint32_t metric = METRIC_MAX;
uint32_t kernel_flags = 0;
zns = zebra_ns_lookup(ns_id);
ifa = NLMSG_DATA(h);
if (ifa->ifa_family != AF_INET && ifa->ifa_family != AF_INET6) {
flog_warn(
EC_ZEBRA_UNKNOWN_FAMILY,
"Invalid address family: %u received from kernel interface addr change: %s",
ifa->ifa_family, nl_msg_type_to_str(h->nlmsg_type));
return 0;
}
if (h->nlmsg_type != RTM_NEWADDR && h->nlmsg_type != RTM_DELADDR)
return 0;
len = h->nlmsg_len - NLMSG_LENGTH(sizeof(struct ifaddrmsg));
if (len < 0) {
zlog_err(
"%s: Message received from netlink is of a broken size: %d %zu",
__func__, h->nlmsg_len,
(size_t)NLMSG_LENGTH(sizeof(struct ifaddrmsg)));
return -1;
}
memset(tb, 0, sizeof(tb));
netlink_parse_rtattr(tb, IFA_MAX, IFA_RTA(ifa), len);
ifp = if_lookup_by_index_per_ns(zns, ifa->ifa_index);
if (ifp == NULL) {
flog_err(
EC_LIB_INTERFACE,
"netlink_interface_addr can't find interface by index %d",
ifa->ifa_index);
return -1;
}
/* Flags passed through */
if (tb[IFA_FLAGS])
kernel_flags = *(int *)RTA_DATA(tb[IFA_FLAGS]);
else
kernel_flags = ifa->ifa_flags;
if (IS_ZEBRA_DEBUG_KERNEL) /* remove this line to see initial ifcfg */
{
char buf[BUFSIZ];
zlog_debug("netlink_interface_addr %s %s flags 0x%x:",
nl_msg_type_to_str(h->nlmsg_type), ifp->name,
kernel_flags);
if (tb[IFA_LOCAL])
zlog_debug(" IFA_LOCAL %s/%d",
inet_ntop(ifa->ifa_family,
RTA_DATA(tb[IFA_LOCAL]), buf,
BUFSIZ),
ifa->ifa_prefixlen);
if (tb[IFA_ADDRESS])
zlog_debug(" IFA_ADDRESS %s/%d",
inet_ntop(ifa->ifa_family,
RTA_DATA(tb[IFA_ADDRESS]), buf,
BUFSIZ),
ifa->ifa_prefixlen);
if (tb[IFA_BROADCAST])
zlog_debug(" IFA_BROADCAST %s/%d",
inet_ntop(ifa->ifa_family,
RTA_DATA(tb[IFA_BROADCAST]), buf,
BUFSIZ),
ifa->ifa_prefixlen);
if (tb[IFA_LABEL] && strcmp(ifp->name, RTA_DATA(tb[IFA_LABEL])))
zlog_debug(" IFA_LABEL %s",
(char *)RTA_DATA(tb[IFA_LABEL]));
if (tb[IFA_CACHEINFO]) {
struct ifa_cacheinfo *ci = RTA_DATA(tb[IFA_CACHEINFO]);
zlog_debug(" IFA_CACHEINFO pref %d, valid %d",
ci->ifa_prefered, ci->ifa_valid);
}
}
/* logic copied from iproute2/ip/ipaddress.c:print_addrinfo() */
if (tb[IFA_LOCAL] == NULL)
tb[IFA_LOCAL] = tb[IFA_ADDRESS];
if (tb[IFA_ADDRESS] == NULL)
tb[IFA_ADDRESS] = tb[IFA_LOCAL];
/* local interface address */
addr = (tb[IFA_LOCAL] ? RTA_DATA(tb[IFA_LOCAL]) : NULL);
/* is there a peer address? */
if (tb[IFA_ADDRESS]
&& memcmp(RTA_DATA(tb[IFA_ADDRESS]), RTA_DATA(tb[IFA_LOCAL]),
RTA_PAYLOAD(tb[IFA_ADDRESS]))) {
broad = RTA_DATA(tb[IFA_ADDRESS]);
SET_FLAG(flags, ZEBRA_IFA_PEER);
} else
/* seeking a broadcast address */
broad = (tb[IFA_BROADCAST] ? RTA_DATA(tb[IFA_BROADCAST])
: NULL);
/* addr is primary key, SOL if we don't have one */
if (addr == NULL) {
zlog_debug("%s: Local Interface Address is NULL for %s",
__func__, ifp->name);
return -1;
}
/* Flags. */
if (kernel_flags & IFA_F_SECONDARY)
SET_FLAG(flags, ZEBRA_IFA_SECONDARY);
/* Label */
if (tb[IFA_LABEL])
label = (char *)RTA_DATA(tb[IFA_LABEL]);
if (label && strcmp(ifp->name, label) == 0)
label = NULL;
if (tb[IFA_RT_PRIORITY])
metric = *(uint32_t *)RTA_DATA(tb[IFA_RT_PRIORITY]);
/* Register interface address to the interface. */
if (ifa->ifa_family == AF_INET) {
if (ifa->ifa_prefixlen > IPV4_MAX_BITLEN) {
zlog_err(
"Invalid prefix length: %u received from kernel interface addr change: %s",
ifa->ifa_prefixlen,
nl_msg_type_to_str(h->nlmsg_type));
return -1;
}
if (h->nlmsg_type == RTM_NEWADDR)
connected_add_ipv4(ifp, flags, (struct in_addr *)addr,
ifa->ifa_prefixlen,
(struct in_addr *)broad, label,
metric);
else if (CHECK_FLAG(flags, ZEBRA_IFA_PEER)) {
/* Delete with a peer address */
connected_delete_ipv4(
ifp, flags, (struct in_addr *)addr,
ifa->ifa_prefixlen, broad);
} else
connected_delete_ipv4(
ifp, flags, (struct in_addr *)addr,
ifa->ifa_prefixlen, NULL);
}
if (ifa->ifa_family == AF_INET6) {
if (ifa->ifa_prefixlen > IPV6_MAX_BITLEN) {
zlog_err(
"Invalid prefix length: %u received from kernel interface addr change: %s",
ifa->ifa_prefixlen,
nl_msg_type_to_str(h->nlmsg_type));
return -1;
}
if (h->nlmsg_type == RTM_NEWADDR) {
/* Only consider valid addresses; we'll not get a
* notification from
* the kernel till IPv6 DAD has completed, but at init
* time, Quagga
* does query for and will receive all addresses.
*/
if (!(kernel_flags
& (IFA_F_DADFAILED | IFA_F_TENTATIVE)))
connected_add_ipv6(ifp, flags,
(struct in6_addr *)addr,
(struct in6_addr *)broad,
ifa->ifa_prefixlen, label,
metric);
} else
connected_delete_ipv6(ifp, (struct in6_addr *)addr,
NULL, ifa->ifa_prefixlen);
}
/*
* Linux kernel does not send route delete on interface down/addr del
* so we have to re-process routes it owns (i.e. kernel routes)
*/
if (h->nlmsg_type != RTM_NEWADDR)
rib_update(RIB_UPDATE_KERNEL);
return 0;
}
int netlink_link_change(struct nlmsghdr *h, ns_id_t ns_id, int startup)
{
int len;
struct ifinfomsg *ifi;
struct rtattr *tb[IFLA_MAX + 1];
struct rtattr *linkinfo[IFLA_MAX + 1];
struct interface *ifp;
char *name = NULL;
char *kind = NULL;
char *desc = NULL;
char *slave_kind = NULL;
struct zebra_ns *zns;
vrf_id_t vrf_id = VRF_DEFAULT;
zebra_iftype_t zif_type = ZEBRA_IF_OTHER;
zebra_slave_iftype_t zif_slave_type = ZEBRA_IF_SLAVE_NONE;
ifindex_t bridge_ifindex = IFINDEX_INTERNAL;
ifindex_t bond_ifindex = IFINDEX_INTERNAL;
ifindex_t link_ifindex = IFINDEX_INTERNAL;
uint8_t old_hw_addr[INTERFACE_HWADDR_MAX];
struct zebra_if *zif;
ns_id_t link_nsid = ns_id;
zns = zebra_ns_lookup(ns_id);
ifi = NLMSG_DATA(h);
/* assume if not default zns, then new VRF */
if (!(h->nlmsg_type == RTM_NEWLINK || h->nlmsg_type == RTM_DELLINK)) {
/* If this is not link add/delete message so print warning. */
zlog_debug("netlink_link_change: wrong kernel message %s",
nl_msg_type_to_str(h->nlmsg_type));
return 0;
}
if (!(ifi->ifi_family == AF_UNSPEC || ifi->ifi_family == AF_BRIDGE
|| ifi->ifi_family == AF_INET6)) {
flog_warn(
EC_ZEBRA_UNKNOWN_FAMILY,
"Invalid address family: %u received from kernel link change: %s",
ifi->ifi_family, nl_msg_type_to_str(h->nlmsg_type));
return 0;
}
len = h->nlmsg_len - NLMSG_LENGTH(sizeof(struct ifinfomsg));
if (len < 0) {
zlog_err(
"%s: Message received from netlink is of a broken size %d %zu",
__func__, h->nlmsg_len,
(size_t)NLMSG_LENGTH(sizeof(struct ifinfomsg)));
return -1;
}
/* We are interested in some AF_BRIDGE notifications. */
if (ifi->ifi_family == AF_BRIDGE)
return netlink_bridge_interface(h, len, ns_id, startup);
/* Looking up interface name. */
memset(tb, 0, sizeof(tb));
memset(linkinfo, 0, sizeof(linkinfo));
netlink_parse_rtattr(tb, IFLA_MAX, IFLA_RTA(ifi), len);
/* check for wireless messages to ignore */
if ((tb[IFLA_WIRELESS] != NULL) && (ifi->ifi_change == 0)) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("%s: ignoring IFLA_WIRELESS message",
__func__);
return 0;
}
if (tb[IFLA_IFNAME] == NULL)
return -1;
name = (char *)RTA_DATA(tb[IFLA_IFNAME]);
if (tb[IFLA_LINKINFO]) {
parse_rtattr_nested(linkinfo, IFLA_INFO_MAX, tb[IFLA_LINKINFO]);
if (linkinfo[IFLA_INFO_KIND])
kind = RTA_DATA(linkinfo[IFLA_INFO_KIND]);
if (linkinfo[IFLA_INFO_SLAVE_KIND])
slave_kind = RTA_DATA(linkinfo[IFLA_INFO_SLAVE_KIND]);
netlink_determine_zebra_iftype(kind, &zif_type);
}
/* If linking to another interface, note it. */
if (tb[IFLA_LINK])
link_ifindex = *(ifindex_t *)RTA_DATA(tb[IFLA_LINK]);
if (tb[IFLA_LINK_NETNSID]) {
link_nsid = *(ns_id_t *)RTA_DATA(tb[IFLA_LINK_NETNSID]);
link_nsid = ns_id_get_absolute(ns_id, link_nsid);
}
if (tb[IFLA_IFALIAS]) {
desc = (char *)RTA_DATA(tb[IFLA_IFALIAS]);
}
/* If VRF, create or update the VRF structure itself. */
if (zif_type == ZEBRA_IF_VRF && !vrf_is_backend_netns()) {
netlink_vrf_change(h, tb[IFLA_LINKINFO], ns_id, name);
vrf_id = (vrf_id_t)ifi->ifi_index;
}
/* See if interface is present. */
ifp = if_lookup_by_name_per_ns(zns, name);
if (h->nlmsg_type == RTM_NEWLINK) {
if (tb[IFLA_MASTER]) {
if (slave_kind && (strcmp(slave_kind, "vrf") == 0)
&& !vrf_is_backend_netns()) {
zif_slave_type = ZEBRA_IF_SLAVE_VRF;
vrf_id = *(uint32_t *)RTA_DATA(tb[IFLA_MASTER]);
} else if (slave_kind
&& (strcmp(slave_kind, "bridge") == 0)) {
zif_slave_type = ZEBRA_IF_SLAVE_BRIDGE;
bridge_ifindex =
*(ifindex_t *)RTA_DATA(tb[IFLA_MASTER]);
} else if (slave_kind
&& (strcmp(slave_kind, "bond") == 0)) {
zif_slave_type = ZEBRA_IF_SLAVE_BOND;
bond_ifindex =
*(ifindex_t *)RTA_DATA(tb[IFLA_MASTER]);
} else
zif_slave_type = ZEBRA_IF_SLAVE_OTHER;
}
if (vrf_is_backend_netns())
vrf_id = (vrf_id_t)ns_id;
if (ifp == NULL
|| !CHECK_FLAG(ifp->status, ZEBRA_INTERFACE_ACTIVE)) {
/* Add interface notification from kernel */
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"RTM_NEWLINK ADD for %s(%u) vrf_id %u type %d sl_type %d master %u flags 0x%x",
name, ifi->ifi_index, vrf_id, zif_type,
zif_slave_type, bridge_ifindex,
ifi->ifi_flags);
if (ifp == NULL) {
/* unknown interface */
ifp = if_get_by_name(name, vrf_id);
} else {
/* pre-configured interface, learnt now */
if (ifp->vrf_id != vrf_id)
if_update_to_new_vrf(ifp, vrf_id);
}
/* Update interface information. */
set_ifindex(ifp, ifi->ifi_index, zns);
ifp->flags = ifi->ifi_flags & 0x0000fffff;
if (!tb[IFLA_MTU]) {
zlog_debug(
"RTM_NEWLINK for interface %s(%u) without MTU set",
name, ifi->ifi_index);
return 0;
}
ifp->mtu6 = ifp->mtu = *(int *)RTA_DATA(tb[IFLA_MTU]);
ifp->metric = 0;
ifp->ptm_status = ZEBRA_PTM_STATUS_UNKNOWN;
/* Set interface type */
zebra_if_set_ziftype(ifp, zif_type, zif_slave_type);
if (IS_ZEBRA_IF_VRF(ifp))
SET_FLAG(ifp->status,
ZEBRA_INTERFACE_VRF_LOOPBACK);
/* Update link. */
zebra_if_update_link(ifp, link_ifindex, ns_id);
netlink_interface_update_hw_addr(tb, ifp);
/* Inform clients, install any configured addresses. */
if_add_update(ifp);
/* Extract and save L2 interface information, take
* additional actions. */
netlink_interface_update_l2info(
ifp, linkinfo[IFLA_INFO_DATA],
1, link_nsid);
if (IS_ZEBRA_IF_BRIDGE_SLAVE(ifp))
zebra_l2if_update_bridge_slave(ifp,
bridge_ifindex,
ns_id);
else if (IS_ZEBRA_IF_BOND_SLAVE(ifp))
zebra_l2if_update_bond_slave(ifp, bond_ifindex);
} else if (ifp->vrf_id != vrf_id) {
/* VRF change for an interface. */
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"RTM_NEWLINK vrf-change for %s(%u) vrf_id %u -> %u flags 0x%x",
name, ifp->ifindex, ifp->vrf_id, vrf_id,
ifi->ifi_flags);
if_handle_vrf_change(ifp, vrf_id);
} else {
bool was_bridge_slave, was_bond_slave;
/* Interface update. */
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"RTM_NEWLINK update for %s(%u) sl_type %d master %u flags 0x%x",
name, ifp->ifindex, zif_slave_type,
bridge_ifindex, ifi->ifi_flags);
set_ifindex(ifp, ifi->ifi_index, zns);
if (!tb[IFLA_MTU]) {
zlog_debug(
"RTM_NEWLINK for interface %s(%u) without MTU set",
name, ifi->ifi_index);
return 0;
}
ifp->mtu6 = ifp->mtu = *(int *)RTA_DATA(tb[IFLA_MTU]);
ifp->metric = 0;
/* Update interface type - NOTE: Only slave_type can
* change. */
was_bridge_slave = IS_ZEBRA_IF_BRIDGE_SLAVE(ifp);
was_bond_slave = IS_ZEBRA_IF_BOND_SLAVE(ifp);
zebra_if_set_ziftype(ifp, zif_type, zif_slave_type);
memcpy(old_hw_addr, ifp->hw_addr, INTERFACE_HWADDR_MAX);
netlink_interface_update_hw_addr(tb, ifp);
if (if_is_no_ptm_operative(ifp)) {
ifp->flags = ifi->ifi_flags & 0x0000fffff;
if (!if_is_no_ptm_operative(ifp)) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"Intf %s(%u) has gone DOWN",
name, ifp->ifindex);
if_down(ifp);
rib_update(RIB_UPDATE_KERNEL);
} else if (if_is_operative(ifp)) {
/* Must notify client daemons of new
* interface status. */
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"Intf %s(%u) PTM up, notifying clients",
name, ifp->ifindex);
zebra_interface_up_update(ifp);
/* Update EVPN VNI when SVI MAC change
*/
if (IS_ZEBRA_IF_VLAN(ifp) &&
memcmp(old_hw_addr, ifp->hw_addr,
INTERFACE_HWADDR_MAX)) {
struct interface *link_if;
link_if =
if_lookup_by_index_per_ns(
zebra_ns_lookup(NS_DEFAULT),
link_ifindex);
if (link_if)
zebra_vxlan_svi_up(ifp,
link_if);
}
}
} else {
ifp->flags = ifi->ifi_flags & 0x0000fffff;
if (if_is_operative(ifp)) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"Intf %s(%u) has come UP",
name, ifp->ifindex);
if_up(ifp);
} else {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"Intf %s(%u) has gone DOWN",
name, ifp->ifindex);
if_down(ifp);
rib_update(RIB_UPDATE_KERNEL);
}
}
/* Extract and save L2 interface information, take
* additional actions. */
netlink_interface_update_l2info(
ifp, linkinfo[IFLA_INFO_DATA],
0, link_nsid);
if (IS_ZEBRA_IF_BRIDGE_SLAVE(ifp) || was_bridge_slave)
zebra_l2if_update_bridge_slave(ifp,
bridge_ifindex,
ns_id);
else if (IS_ZEBRA_IF_BOND_SLAVE(ifp) || was_bond_slave)
zebra_l2if_update_bond_slave(ifp, bond_ifindex);
}
zif = ifp->info;
if (zif) {
XFREE(MTYPE_TMP, zif->desc);
if (desc)
zif->desc = XSTRDUP(MTYPE_TMP, desc);
}
} else {
/* Delete interface notification from kernel */
if (ifp == NULL) {
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug(
"RTM_DELLINK for unknown interface %s(%u)",
name, ifi->ifi_index);
return 0;
}
if (IS_ZEBRA_DEBUG_KERNEL)
zlog_debug("RTM_DELLINK for %s(%u)", name,
ifp->ifindex);
UNSET_FLAG(ifp->status, ZEBRA_INTERFACE_VRF_LOOPBACK);
/* Special handling for bridge or VxLAN interfaces. */
if (IS_ZEBRA_IF_BRIDGE(ifp))
zebra_l2_bridge_del(ifp);
else if (IS_ZEBRA_IF_VXLAN(ifp))
zebra_l2_vxlanif_del(ifp);
if (!IS_ZEBRA_IF_VRF(ifp))
if_delete_update(ifp);
}
return 0;
}
int netlink_protodown(struct interface *ifp, bool down)
{
struct zebra_ns *zns = zebra_ns_lookup(NS_DEFAULT);
struct {
struct nlmsghdr n;
struct ifinfomsg ifa;
char buf[NL_PKT_BUF_SIZE];
} req;
memset(&req, 0, sizeof(req));
req.n.nlmsg_len = NLMSG_LENGTH(sizeof(struct ifinfomsg));
req.n.nlmsg_flags = NLM_F_REQUEST;
req.n.nlmsg_type = RTM_SETLINK;
req.n.nlmsg_pid = zns->netlink_cmd.snl.nl_pid;
req.ifa.ifi_index = ifp->ifindex;
nl_attr_put(&req.n, sizeof(req), IFLA_PROTO_DOWN, &down, sizeof(down));
nl_attr_put32(&req.n, sizeof(req), IFLA_LINK, ifp->ifindex);
return netlink_talk(netlink_talk_filter, &req.n, &zns->netlink_cmd, zns,
0);
}
/* Interface information read by netlink. */
void interface_list(struct zebra_ns *zns)
{
interface_lookup_netlink(zns);
/* We add routes for interface address,
* so we need to get the nexthop info
* from the kernel before we can do that
*/
netlink_nexthop_read(zns);
interface_addr_lookup_netlink(zns);
}
#endif /* GNU_LINUX */
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