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ee2f2c23ca
mirror_frr/lib/if.c
Thibaut Collet ee2f2c23ca zebra: fix crash when interface vrf changes 
This crash occurs only with netns implementation.
vrf meaning is different regarging its implementation (netns or
vrf-lite)

- With vrf-lite implementation vrf is a property of the interface that
  can be changed as the speed or the state (iproute2 command: "ip link
  set dev IF_NAME master VRF_NAME"). All interfaces of the system are in
  the same netns and so interface name is unique.
- With netns implementation vrf is a characteristic of the interface
  that CANNOT be changed: it is the id of the netns where the interface
  is located. To change the vrf of an interface (iproute2 command to
  move an interface "ip netns exec VRF_NAME1 ip link set dev IF_NAME
  netns VRF_NAME2") the interface is deleted from the old vrf and
  created in the new vrf.
  Interface name is not unique, the same name can be present in the
  different netns (typically the lo interface) and search of interface
  must be done by the tuple (interface name, netns id).

Current tests on the vrf implementation (vrf-lite or netns) are not
sufficient. In some cases (for example when an interface is moved from
a vrf X to the default vrf and then move back to VRF X) we can have a
corruption message and then a crash of zebra.

To avoid this corruption test on the vrf implementation, needed when an
interface changes, has been rewritten:
- For all interface changes except deletion the if_get_by_name function,
  that checks if an interface exists and creates or updates it if
  needed, is changed:
    * The vrf-lite implementation is unchanged: search of the interface
      is based only on the name and update the vrf-id if needed.
    * The netns implementation search of the interface is based on the
      (name, vrf-id) tuple and interface is created if not found, the
      vrf-id is never updated.
- deletion of an interface (reception of a RTM_DELLINK netlink message):
    * The vrf-lite implementation is unchanged: the interface
      information are cleared and the interface is moved to the default
      vrf if it does not belong to (to allow vrf deletion)
    * The netns implementation is changed: only the interface
      information are cleared and the interface stays in its vrf to
      avoid conflict with interface with the same name in the default
      vrf.

This implementation reverts (partially or totally):
commit 393ec5424e ("zebra: fix missing node attribute set in ifp")
commit e9e9b1150f ("lib: create interface even if name is the same")
commit 9373219c67 ("zebra: improve logs when replacing interface to an
other netns")
Fixes: b53686c52a ("zebra: delete interface that disappeared")

Signed-off-by: Thibaut Collet <thibaut.collet@6wind.com>
Signed-off-by: Philippe Guibert <philippe.guibert@6wind.com>
2018-08-30 14:37:59 +02:00

1212 lines
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/*
* Interface functions.
* Copyright (C) 1997, 98 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>
#include "linklist.h"
#include "vector.h"
#include "lib_errors.h"
#include "vty.h"
#include "command.h"
#include "vrf.h"
#include "if.h"
#include "sockunion.h"
#include "prefix.h"
#include "memory.h"
#include "table.h"
#include "buffer.h"
#include "log.h"
DEFINE_MTYPE(LIB, IF, "Interface")
DEFINE_MTYPE_STATIC(LIB, CONNECTED, "Connected")
DEFINE_MTYPE_STATIC(LIB, NBR_CONNECTED, "Neighbor Connected")
DEFINE_MTYPE(LIB, CONNECTED_LABEL, "Connected interface label")
DEFINE_MTYPE_STATIC(LIB, IF_LINK_PARAMS, "Informational Link Parameters")
static int if_cmp_func(const struct interface *, const struct interface *);
static int if_cmp_index_func(const struct interface *ifp1,
const struct interface *ifp2);
RB_GENERATE(if_name_head, interface, name_entry, if_cmp_func);
RB_GENERATE(if_index_head, interface, index_entry, if_cmp_index_func);
DEFINE_QOBJ_TYPE(interface)
DEFINE_HOOK(if_add, (struct interface * ifp), (ifp))
DEFINE_KOOH(if_del, (struct interface * ifp), (ifp))
/* List of interfaces in only the default VRF */
int ptm_enable = 0;
/* Compare interface names, returning an integer greater than, equal to, or
* less than 0, (following the strcmp convention), according to the
* relationship between ifp1 and ifp2. Interface names consist of an
* alphabetic prefix and a numeric suffix. The primary sort key is
* lexicographic by name, and then numeric by number. No number sorts
* before all numbers. Examples: de0 < de1, de100 < fxp0 < xl0, devpty <
* devpty0, de0 < del0
*/
int if_cmp_name_func(char *p1, char *p2)
{
unsigned int l1, l2;
long int x1, x2;
int res;
while (*p1 && *p2) {
/* look up to any number */
l1 = strcspn(p1, "0123456789");
l2 = strcspn(p2, "0123456789");
/* name lengths are different -> compare names */
if (l1 != l2)
return (strcmp(p1, p2));
/* Note that this relies on all numbers being less than all
* letters, so
* that de0 < del0.
*/
res = strncmp(p1, p2, l1);
/* names are different -> compare them */
if (res)
return res;
/* with identical name part, go to numeric part */
p1 += l1;
p2 += l1;
if (!*p1 && !*p2)
return 0;
if (!*p1)
return -1;
if (!*p2)
return 1;
x1 = strtol(p1, &p1, 10);
x2 = strtol(p2, &p2, 10);
/* let's compare numbers now */
if (x1 < x2)
return -1;
if (x1 > x2)
return 1;
/* numbers were equal, lets do it again..
(it happens with name like "eth123.456:789") */
}
if (*p1)
return 1;
if (*p2)
return -1;
return 0;
}
static int if_cmp_func(const struct interface *ifp1,
const struct interface *ifp2)
{
return if_cmp_name_func((char *)ifp1->name, (char *)ifp2->name);
}
static int if_cmp_index_func(const struct interface *ifp1,
const struct interface *ifp2)
{
return ifp1->ifindex - ifp2->ifindex;
}
/* Create new interface structure. */
struct interface *if_create(const char *name, vrf_id_t vrf_id)
{
struct vrf *vrf = vrf_get(vrf_id, NULL);
struct interface *ifp;
ifp = XCALLOC(MTYPE_IF, sizeof(struct interface));
ifp->ifindex = IFINDEX_INTERNAL;
assert(name);
strlcpy(ifp->name, name, sizeof(ifp->name));
ifp->vrf_id = vrf_id;
IFNAME_RB_INSERT(vrf, ifp);
ifp->connected = list_new();
ifp->connected->del = (void (*)(void *))connected_free;
ifp->nbr_connected = list_new();
ifp->nbr_connected->del = (void (*)(void *))nbr_connected_free;
/* Enable Link-detection by default */
SET_FLAG(ifp->status, ZEBRA_INTERFACE_LINKDETECTION);
QOBJ_REG(ifp, interface);
hook_call(if_add, ifp);
return ifp;
}
/* Create new interface structure. */
void if_update_to_new_vrf(struct interface *ifp, vrf_id_t vrf_id)
{
struct vrf *vrf;
/* remove interface from old master vrf list */
vrf = vrf_lookup_by_id(ifp->vrf_id);
if (vrf) {
IFNAME_RB_REMOVE(vrf, ifp);
if (ifp->ifindex != IFINDEX_INTERNAL)
IFINDEX_RB_REMOVE(vrf, ifp);
}
ifp->vrf_id = vrf_id;
vrf = vrf_get(ifp->vrf_id, NULL);
IFNAME_RB_INSERT(vrf, ifp);
if (ifp->ifindex != IFINDEX_INTERNAL)
IFINDEX_RB_INSERT(vrf, ifp);
}
/* Delete interface structure. */
void if_delete_retain(struct interface *ifp)
{
hook_call(if_del, ifp);
QOBJ_UNREG(ifp);
/* Free connected address list */
list_delete_all_node(ifp->connected);
/* Free connected nbr address list */
list_delete_all_node(ifp->nbr_connected);
}
/* Delete and free interface structure. */
void if_delete(struct interface *ifp)
{
struct vrf *vrf;
vrf = vrf_lookup_by_id(ifp->vrf_id);
assert(vrf);
IFNAME_RB_REMOVE(vrf, ifp);
if (ifp->ifindex != IFINDEX_INTERNAL)
IFINDEX_RB_REMOVE(vrf, ifp);
if_delete_retain(ifp);
list_delete_and_null(&ifp->connected);
list_delete_and_null(&ifp->nbr_connected);
if_link_params_free(ifp);
if (ifp->desc)
XFREE(MTYPE_TMP, ifp->desc);
XFREE(MTYPE_IF, ifp);
}
/* Interface existance check by index. */
struct interface *if_lookup_by_index(ifindex_t ifindex, vrf_id_t vrf_id)
{
struct vrf *vrf;
struct interface if_tmp;
vrf = vrf_lookup_by_id(vrf_id);
if (!vrf)
return NULL;
if_tmp.ifindex = ifindex;
return RB_FIND(if_index_head, &vrf->ifaces_by_index, &if_tmp);
}
const char *ifindex2ifname(ifindex_t ifindex, vrf_id_t vrf_id)
{
struct interface *ifp;
return ((ifp = if_lookup_by_index(ifindex, vrf_id)) != NULL)
? ifp->name
: "unknown";
}
ifindex_t ifname2ifindex(const char *name, vrf_id_t vrf_id)
{
struct interface *ifp;
return ((ifp = if_lookup_by_name(name, vrf_id)) != NULL)
? ifp->ifindex
: IFINDEX_INTERNAL;
}
/* Interface existance check by interface name. */
struct interface *if_lookup_by_name(const char *name, vrf_id_t vrf_id)
{
struct vrf *vrf = vrf_lookup_by_id(vrf_id);
struct interface if_tmp;
if (!vrf || !name
|| strnlen(name, INTERFACE_NAMSIZ) == INTERFACE_NAMSIZ)
return NULL;
strlcpy(if_tmp.name, name, sizeof(if_tmp.name));
return RB_FIND(if_name_head, &vrf->ifaces_by_name, &if_tmp);
}
struct interface *if_lookup_by_name_all_vrf(const char *name)
{
struct vrf *vrf;
struct interface *ifp;
if (!name || strnlen(name, INTERFACE_NAMSIZ) == INTERFACE_NAMSIZ)
return NULL;
RB_FOREACH (vrf, vrf_id_head, &vrfs_by_id) {
ifp = if_lookup_by_name(name, vrf->vrf_id);
if (ifp)
return ifp;
}
return NULL;
}
/* Lookup interface by IPv4 address. */
struct interface *if_lookup_exact_address(void *src, int family,
vrf_id_t vrf_id)
{
struct vrf *vrf = vrf_lookup_by_id(vrf_id);
struct listnode *cnode;
struct interface *ifp;
struct prefix *p;
struct connected *c;
FOR_ALL_INTERFACES (vrf, ifp) {
for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, c)) {
p = c->address;
if (p && (p->family == family)) {
if (family == AF_INET) {
if (IPV4_ADDR_SAME(
&p->u.prefix4,
(struct in_addr *)src))
return ifp;
} else if (family == AF_INET6) {
if (IPV6_ADDR_SAME(
&p->u.prefix6,
(struct in6_addr *)src))
return ifp;
}
}
}
}
return NULL;
}
/* Lookup interface by IPv4 address. */
struct connected *if_lookup_address(void *matchaddr, int family,
vrf_id_t vrf_id)
{
struct vrf *vrf = vrf_lookup_by_id(vrf_id);
struct prefix addr;
int bestlen = 0;
struct listnode *cnode;
struct interface *ifp;
struct connected *c;
struct connected *match;
if (family == AF_INET) {
addr.family = AF_INET;
addr.u.prefix4 = *((struct in_addr *)matchaddr);
addr.prefixlen = IPV4_MAX_BITLEN;
} else if (family == AF_INET6) {
addr.family = AF_INET6;
addr.u.prefix6 = *((struct in6_addr *)matchaddr);
addr.prefixlen = IPV6_MAX_BITLEN;
}
match = NULL;
FOR_ALL_INTERFACES (vrf, ifp) {
for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, c)) {
if (c->address && (c->address->family == AF_INET)
&& prefix_match(CONNECTED_PREFIX(c), &addr)
&& (c->address->prefixlen > bestlen)) {
bestlen = c->address->prefixlen;
match = c;
}
}
}
return match;
}
/* Lookup interface by prefix */
struct interface *if_lookup_prefix(struct prefix *prefix, vrf_id_t vrf_id)
{
struct vrf *vrf = vrf_lookup_by_id(vrf_id);
struct listnode *cnode;
struct interface *ifp;
struct connected *c;
FOR_ALL_INTERFACES (vrf, ifp) {
for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, c)) {
if (prefix_cmp(c->address, prefix) == 0) {
return ifp;
}
}
}
return NULL;
}
/* Get interface by name if given name interface doesn't exist create
one. */
struct interface *if_get_by_name(const char *name, vrf_id_t vrf_id, int vty)
{
struct interface *ifp = NULL;
if (vrf_is_mapped_on_netns(vrf_lookup_by_id(vrf_id))) {
ifp = if_lookup_by_name(name, vrf_id);
if (ifp)
return ifp;
if (vty) {
/* If the interface command was entered in vty without a
* VRF (passed as VRF_DEFAULT), search an interface with
* this name in all VRs
*/
if (vrf_id == VRF_DEFAULT)
return if_lookup_by_name_all_vrf(name);
return NULL;
}
return if_create(name, vrf_id);
} else {
ifp = if_lookup_by_name_all_vrf(name);
if (ifp) {
if (ifp->vrf_id == vrf_id)
return ifp;
/* Found a match on a different VRF. If the interface
* command was entered in vty without a VRF (passed as
* VRF_DEFAULT), accept the ifp we found. If a vrf was
* entered and there is a mismatch, reject it if from
* vty. If it came from the kernel or by way of zclient,
* believe it and update the ifp accordingly.
*/
if (vty) {
if (vrf_id == VRF_DEFAULT)
return ifp;
return NULL;
}
/* If it came from the kernel or by way of zclient,
* believe it and update the ifp accordingly.
*/
if_update_to_new_vrf(ifp, vrf_id);
return ifp;
}
return if_create(name, vrf_id);
}
}
void if_set_index(struct interface *ifp, ifindex_t ifindex)
{
struct vrf *vrf;
vrf = vrf_lookup_by_id(ifp->vrf_id);
assert(vrf);
if (ifp->ifindex == ifindex)
return;
if (ifp->ifindex != IFINDEX_INTERNAL)
IFINDEX_RB_REMOVE(vrf, ifp)
ifp->ifindex = ifindex;
if (ifp->ifindex != IFINDEX_INTERNAL)
IFINDEX_RB_INSERT(vrf, ifp)
}
/* Does interface up ? */
int if_is_up(struct interface *ifp)
{
return ifp->flags & IFF_UP;
}
/* Is interface running? */
int if_is_running(struct interface *ifp)
{
return ifp->flags & IFF_RUNNING;
}
/* Is the interface operative, eg. either UP & RUNNING
or UP & !ZEBRA_INTERFACE_LINK_DETECTION and
if ptm checking is enabled, then ptm check has passed */
int if_is_operative(struct interface *ifp)
{
return ((ifp->flags & IFF_UP)
&& (((ifp->flags & IFF_RUNNING)
&& (ifp->ptm_status || !ifp->ptm_enable))
|| !CHECK_FLAG(ifp->status,
ZEBRA_INTERFACE_LINKDETECTION)));
}
/* Is the interface operative, eg. either UP & RUNNING
or UP & !ZEBRA_INTERFACE_LINK_DETECTION, without PTM check */
int if_is_no_ptm_operative(struct interface *ifp)
{
return ((ifp->flags & IFF_UP)
&& ((ifp->flags & IFF_RUNNING)
|| !CHECK_FLAG(ifp->status,
ZEBRA_INTERFACE_LINKDETECTION)));
}
/* Is this loopback interface ? */
int if_is_loopback(struct interface *ifp)
{
/* XXX: Do this better, eg what if IFF_WHATEVER means X on platform M
* but Y on platform N?
*/
return (ifp->flags & (IFF_LOOPBACK | IFF_NOXMIT | IFF_VIRTUAL));
}
/* Check interface is VRF */
int if_is_vrf(struct interface *ifp)
{
return CHECK_FLAG(ifp->status, ZEBRA_INTERFACE_VRF_LOOPBACK);
}
bool if_is_loopback_or_vrf(struct interface *ifp)
{
if (if_is_loopback(ifp) || if_is_vrf(ifp))
return true;
return false;
}
/* Does this interface support broadcast ? */
int if_is_broadcast(struct interface *ifp)
{
return ifp->flags & IFF_BROADCAST;
}
/* Does this interface support broadcast ? */
int if_is_pointopoint(struct interface *ifp)
{
return ifp->flags & IFF_POINTOPOINT;
}
/* Does this interface support multicast ? */
int if_is_multicast(struct interface *ifp)
{
return ifp->flags & IFF_MULTICAST;
}
/* Printout flag information into log */
const char *if_flag_dump(unsigned long flag)
{
int separator = 0;
static char logbuf[BUFSIZ];
#define IFF_OUT_LOG(X, STR) \
if (flag & (X)) { \
if (separator) \
strlcat(logbuf, ",", BUFSIZ); \
else \
separator = 1; \
strlcat(logbuf, STR, BUFSIZ); \
}
strlcpy(logbuf, "<", BUFSIZ);
IFF_OUT_LOG(IFF_UP, "UP");
IFF_OUT_LOG(IFF_BROADCAST, "BROADCAST");
IFF_OUT_LOG(IFF_DEBUG, "DEBUG");
IFF_OUT_LOG(IFF_LOOPBACK, "LOOPBACK");
IFF_OUT_LOG(IFF_POINTOPOINT, "POINTOPOINT");
IFF_OUT_LOG(IFF_NOTRAILERS, "NOTRAILERS");
IFF_OUT_LOG(IFF_RUNNING, "RUNNING");
IFF_OUT_LOG(IFF_NOARP, "NOARP");
IFF_OUT_LOG(IFF_PROMISC, "PROMISC");
IFF_OUT_LOG(IFF_ALLMULTI, "ALLMULTI");
IFF_OUT_LOG(IFF_OACTIVE, "OACTIVE");
IFF_OUT_LOG(IFF_SIMPLEX, "SIMPLEX");
IFF_OUT_LOG(IFF_LINK0, "LINK0");
IFF_OUT_LOG(IFF_LINK1, "LINK1");
IFF_OUT_LOG(IFF_LINK2, "LINK2");
IFF_OUT_LOG(IFF_MULTICAST, "MULTICAST");
IFF_OUT_LOG(IFF_NOXMIT, "NOXMIT");
IFF_OUT_LOG(IFF_NORTEXCH, "NORTEXCH");
IFF_OUT_LOG(IFF_VIRTUAL, "VIRTUAL");
IFF_OUT_LOG(IFF_IPV4, "IPv4");
IFF_OUT_LOG(IFF_IPV6, "IPv6");
strlcat(logbuf, ">", BUFSIZ);
return logbuf;
#undef IFF_OUT_LOG
}
/* For debugging */
static void if_dump(const struct interface *ifp)
{
struct listnode *node;
struct connected *c __attribute__((unused));
for (ALL_LIST_ELEMENTS_RO(ifp->connected, node, c))
zlog_info(
"Interface %s vrf %u index %d metric %d mtu %d "
"mtu6 %d %s",
ifp->name, ifp->vrf_id, ifp->ifindex, ifp->metric,
ifp->mtu, ifp->mtu6, if_flag_dump(ifp->flags));
}
/* Interface printing for all interface. */
void if_dump_all(void)
{
struct vrf *vrf;
void *ifp;
RB_FOREACH (vrf, vrf_id_head, &vrfs_by_id)
FOR_ALL_INTERFACES (vrf, ifp)
if_dump(ifp);
}
DEFUN (interface_desc,
interface_desc_cmd,
"description LINE...",
"Interface specific description\n"
"Characters describing this interface\n")
{
int idx_line = 1;
VTY_DECLVAR_CONTEXT(interface, ifp);
if (ifp->desc)
XFREE(MTYPE_TMP, ifp->desc);
ifp->desc = argv_concat(argv, argc, idx_line);
return CMD_SUCCESS;
}
DEFUN (no_interface_desc,
no_interface_desc_cmd,
"no description",
NO_STR
"Interface specific description\n")
{
VTY_DECLVAR_CONTEXT(interface, ifp);
if (ifp->desc)
XFREE(MTYPE_TMP, ifp->desc);
ifp->desc = NULL;
return CMD_SUCCESS;
}
#ifdef SUNOS_5
/* Need to handle upgrade from SUNWzebra to Quagga. SUNWzebra created
* a seperate struct interface for each logical interface, so config
* file may be full of 'interface fooX:Y'. Solaris however does not
* expose logical interfaces via PF_ROUTE, so trying to track logical
* interfaces can be fruitless, for that reason Quagga only tracks
* the primary IP interface.
*
* We try accomodate SUNWzebra by:
* - looking up the interface name, to see whether it exists, if so
* its useable
* - for protocol daemons, this could only because zebra told us of
* the interface
* - for zebra, only because it learnt from kernel
* - if not:
* - search the name to see if it contains a sub-ipif / logical interface
* seperator, the ':' char. If it does:
* - text up to that char must be the primary name - get that name.
* if not:
* - no idea, just get the name in its entirety.
*/
static struct interface *if_sunwzebra_get(char *name, vrf_id_t vrf_id)
{
struct interface *ifp;
char *cp;
if ((ifp = if_lookup_by_name(name, vrf_id)) != NULL)
return ifp;
/* hunt the primary interface name... */
cp = strchr(name, ':');
if (cp)
*cp = '\0';
return if_get_by_name(name, vrf_id, 1);
}
#endif /* SUNOS_5 */
DEFUN_NOSH (interface,
interface_cmd,
"interface IFNAME [vrf NAME]",
"Select an interface to configure\n"
"Interface's name\n"
VRF_CMD_HELP_STR)
{
int idx_ifname = 1;
int idx_vrf = 3;
const char *ifname = argv[idx_ifname]->arg;
const char *vrfname = (argc > 2) ? argv[idx_vrf]->arg : NULL;
struct interface *ifp;
vrf_id_t vrf_id = VRF_DEFAULT;
if (strlen(ifname) > INTERFACE_NAMSIZ) {
vty_out(vty,
"%% Interface name %s is invalid: length exceeds "
"%d characters\n",
ifname, INTERFACE_NAMSIZ);
return CMD_WARNING_CONFIG_FAILED;
}
/*Pending: need proper vrf name based lookup/(possible creation of VRF)
Imagine forward reference of a vrf by name in this interface config */
if (vrfname)
VRF_GET_ID(vrf_id, vrfname, false);
#ifdef SUNOS_5
ifp = if_sunwzebra_get(ifname, vrf_id);
#else
ifp = if_get_by_name(ifname, vrf_id, 1);
#endif /* SUNOS_5 */
if (!ifp) {
vty_out(vty, "%% interface %s not in %s\n", ifname, vrfname);
return CMD_WARNING_CONFIG_FAILED;
}
VTY_PUSH_CONTEXT(INTERFACE_NODE, ifp);
return CMD_SUCCESS;
}
DEFUN (no_interface,
no_interface_cmd,
"no interface IFNAME [vrf NAME]",
NO_STR
"Delete a pseudo interface's configuration\n"
"Interface's name\n"
VRF_CMD_HELP_STR)
{
int idx_vrf = 4;
const char *ifname = argv[2]->arg;
const char *vrfname = (argc > 3) ? argv[idx_vrf]->arg : NULL;
// deleting interface
struct interface *ifp;
vrf_id_t vrf_id = VRF_DEFAULT;
if (argc > 3)
VRF_GET_ID(vrf_id, vrfname, false);
ifp = if_lookup_by_name(ifname, vrf_id);
if (ifp == NULL) {
vty_out(vty, "%% Interface %s does not exist\n", ifname);
return CMD_WARNING_CONFIG_FAILED;
}
if (CHECK_FLAG(ifp->status, ZEBRA_INTERFACE_ACTIVE)) {
vty_out(vty, "%% Only inactive interfaces can be deleted\n");
return CMD_WARNING_CONFIG_FAILED;
}
if_delete(ifp);
return CMD_SUCCESS;
}
static void if_autocomplete(vector comps, struct cmd_token *token)
{
struct interface *ifp;
struct vrf *vrf = NULL;
RB_FOREACH (vrf, vrf_name_head, &vrfs_by_name) {
FOR_ALL_INTERFACES (vrf, ifp) {
vector_set(comps, XSTRDUP(MTYPE_COMPLETION, ifp->name));
}
}
}
static const struct cmd_variable_handler if_var_handlers[] = {
{/* "interface NAME" */
.varname = "interface",
.completions = if_autocomplete},
{.tokenname = "IFNAME", .completions = if_autocomplete},
{.tokenname = "INTERFACE", .completions = if_autocomplete},
{.completions = NULL}};
void if_cmd_init(void)
{
cmd_variable_handler_register(if_var_handlers);
install_element(CONFIG_NODE, &interface_cmd);
install_element(CONFIG_NODE, &no_interface_cmd);
install_default(INTERFACE_NODE);
install_element(INTERFACE_NODE, &interface_desc_cmd);
install_element(INTERFACE_NODE, &no_interface_desc_cmd);
}
#if 0
/* For debug purpose. */
DEFUN (show_address,
show_address_cmd,
"show address [vrf NAME]",
SHOW_STR
"address\n"
VRF_CMD_HELP_STR)
{
int idx_vrf = 3;
struct listnode *node;
struct interface *ifp;
struct connected *ifc;
struct prefix *p;
vrf_id_t vrf_id = VRF_DEFAULT;
if (argc > 2)
VRF_GET_ID (vrf_id, argv[idx_vrf]->arg);
FOR_ALL_INTERFACES (vrf, ifp)
{
for (ALL_LIST_ELEMENTS_RO (ifp->connected, node, ifc))
{
p = ifc->address;
if (p->family == AF_INET)
vty_out (vty, "%s/%d\n", inet_ntoa (p->u.prefix4), p->prefixlen);
}
}
return CMD_SUCCESS;
}
DEFUN (show_address_vrf_all,
show_address_vrf_all_cmd,
"show address vrf all",
SHOW_STR
"address\n"
VRF_ALL_CMD_HELP_STR)
{
struct vrf *vrf;
struct listnode *node;
struct interface *ifp;
struct connected *ifc;
struct prefix *p;
RB_FOREACH (vrf, vrf_name_head, &vrfs_by_name)
{
if (RB_EMPTY (if_name_head, &vrf->ifaces_by_name))
continue;
vty_out (vty, "\nVRF %u\n\n", vrf->vrf_id);
FOR_ALL_INTERFACES (vrf, ifp)
{
for (ALL_LIST_ELEMENTS_RO (ifp->connected, node, ifc))
{
p = ifc->address;
if (p->family == AF_INET)
vty_out (vty, "%s/%d\n", inet_ntoa (p->u.prefix4), p->prefixlen);
}
}
}
return CMD_SUCCESS;
}
#endif
/* Allocate connected structure. */
struct connected *connected_new(void)
{
return XCALLOC(MTYPE_CONNECTED, sizeof(struct connected));
}
/* Allocate nbr connected structure. */
struct nbr_connected *nbr_connected_new(void)
{
return XCALLOC(MTYPE_NBR_CONNECTED, sizeof(struct nbr_connected));
}
/* Free connected structure. */
void connected_free(struct connected *connected)
{
if (connected->address)
prefix_free(connected->address);
if (connected->destination)
prefix_free(connected->destination);
if (connected->label)
XFREE(MTYPE_CONNECTED_LABEL, connected->label);
XFREE(MTYPE_CONNECTED, connected);
}
/* Free nbr connected structure. */
void nbr_connected_free(struct nbr_connected *connected)
{
if (connected->address)
prefix_free(connected->address);
XFREE(MTYPE_NBR_CONNECTED, connected);
}
/* If same interface nbr address already exists... */
struct nbr_connected *nbr_connected_check(struct interface *ifp,
struct prefix *p)
{
struct nbr_connected *ifc;
struct listnode *node;
for (ALL_LIST_ELEMENTS_RO(ifp->nbr_connected, node, ifc))
if (prefix_same(ifc->address, p))
return ifc;
return NULL;
}
/* Print if_addr structure. */
static void __attribute__((unused))
connected_log(struct connected *connected, char *str)
{
struct prefix *p;
struct interface *ifp;
char logbuf[BUFSIZ];
char buf[BUFSIZ];
ifp = connected->ifp;
p = connected->address;
snprintf(logbuf, BUFSIZ, "%s interface %s vrf %u %s %s/%d ", str,
ifp->name, ifp->vrf_id, prefix_family_str(p),
inet_ntop(p->family, &p->u.prefix, buf, BUFSIZ), p->prefixlen);
p = connected->destination;
if (p) {
strncat(logbuf, inet_ntop(p->family, &p->u.prefix, buf, BUFSIZ),
BUFSIZ - strlen(logbuf));
}
zlog_info("%s", logbuf);
}
/* Print if_addr structure. */
static void __attribute__((unused))
nbr_connected_log(struct nbr_connected *connected, char *str)
{
struct prefix *p;
struct interface *ifp;
char logbuf[BUFSIZ];
char buf[BUFSIZ];
ifp = connected->ifp;
p = connected->address;
snprintf(logbuf, BUFSIZ, "%s interface %s %s %s/%d ", str, ifp->name,
prefix_family_str(p),
inet_ntop(p->family, &p->u.prefix, buf, BUFSIZ), p->prefixlen);
zlog_info("%s", logbuf);
}
/* If two connected address has same prefix return 1. */
static int connected_same_prefix(struct prefix *p1, struct prefix *p2)
{
if (p1->family == p2->family) {
if (p1->family == AF_INET
&& IPV4_ADDR_SAME(&p1->u.prefix4, &p2->u.prefix4))
return 1;
if (p1->family == AF_INET6
&& IPV6_ADDR_SAME(&p1->u.prefix6, &p2->u.prefix6))
return 1;
}
return 0;
}
struct connected *connected_lookup_prefix_exact(struct interface *ifp,
struct prefix *p)
{
struct listnode *node;
struct listnode *next;
struct connected *ifc;
for (node = listhead(ifp->connected); node; node = next) {
ifc = listgetdata(node);
next = node->next;
if (connected_same_prefix(ifc->address, p))
return ifc;
}
return NULL;
}
struct connected *connected_delete_by_prefix(struct interface *ifp,
struct prefix *p)
{
struct listnode *node;
struct listnode *next;
struct connected *ifc;
/* In case of same prefix come, replace it with new one. */
for (node = listhead(ifp->connected); node; node = next) {
ifc = listgetdata(node);
next = node->next;
if (connected_same_prefix(ifc->address, p)) {
listnode_delete(ifp->connected, ifc);
return ifc;
}
}
return NULL;
}
/* Find the address on our side that will be used when packets
are sent to dst. */
struct connected *connected_lookup_prefix(struct interface *ifp,
struct prefix *addr)
{
struct listnode *cnode;
struct connected *c;
struct connected *match;
match = NULL;
for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, c)) {
if (c->address && (c->address->family == addr->family)
&& prefix_match(CONNECTED_PREFIX(c), addr)
&& (!match
|| (c->address->prefixlen > match->address->prefixlen)))
match = c;
}
return match;
}
struct connected *connected_add_by_prefix(struct interface *ifp,
struct prefix *p,
struct prefix *destination)
{
struct connected *ifc;
/* Allocate new connected address. */
ifc = connected_new();
ifc->ifp = ifp;
/* Fetch interface address */
ifc->address = prefix_new();
memcpy(ifc->address, p, sizeof(struct prefix));
/* Fetch dest address */
if (destination) {
ifc->destination = prefix_new();
memcpy(ifc->destination, destination, sizeof(struct prefix));
}
/* Add connected address to the interface. */
listnode_add(ifp->connected, ifc);
return ifc;
}
#if 0 /* this route_table of struct connected's is unused \
* however, it would be good to use a route_table rather than \
* a list.. \
*/
/* Interface looking up by interface's address. */
/* Interface's IPv4 address reverse lookup table. */
struct route_table *ifaddr_ipv4_table;
/* struct route_table *ifaddr_ipv6_table; */
static void
ifaddr_ipv4_add (struct in_addr *ifaddr, struct interface *ifp)
{
struct route_node *rn;
struct prefix_ipv4 p;
p.family = AF_INET;
p.prefixlen = IPV4_MAX_PREFIXLEN;
p.prefix = *ifaddr;
rn = route_node_get (ifaddr_ipv4_table, (struct prefix *) &p);
if (rn)
{
route_unlock_node (rn);
zlog_info ("ifaddr_ipv4_add(): address %s is already added",
inet_ntoa (*ifaddr));
return;
}
rn->info = ifp;
}
static void
ifaddr_ipv4_delete (struct in_addr *ifaddr, struct interface *ifp)
{
struct route_node *rn;
struct prefix_ipv4 p;
p.family = AF_INET;
p.prefixlen = IPV4_MAX_PREFIXLEN;
p.prefix = *ifaddr;
rn = route_node_lookup (ifaddr_ipv4_table, (struct prefix *) &p);
if (! rn)
{
zlog_info ("ifaddr_ipv4_delete(): can't find address %s",
inet_ntoa (*ifaddr));
return;
}
rn->info = NULL;
route_unlock_node (rn);
route_unlock_node (rn);
}
/* Lookup interface by interface's IP address or interface index. */
static struct interface *
ifaddr_ipv4_lookup (struct in_addr *addr, ifindex_t ifindex)
{
struct prefix_ipv4 p;
struct route_node *rn;
struct interface *ifp;
if (addr)
{
p.family = AF_INET;
p.prefixlen = IPV4_MAX_PREFIXLEN;
p.prefix = *addr;
rn = route_node_lookup (ifaddr_ipv4_table, (struct prefix *) &p);
if (! rn)
return NULL;
ifp = rn->info;
route_unlock_node (rn);
return ifp;
}
else
return if_lookup_by_index(ifindex, VRF_DEFAULT);
}
#endif /* ifaddr_ipv4_table */
void if_terminate(struct vrf *vrf)
{
struct interface *ifp;
while (!RB_EMPTY(if_name_head, &vrf->ifaces_by_name)) {
ifp = RB_ROOT(if_name_head, &vrf->ifaces_by_name);
if (ifp->node) {
ifp->node->info = NULL;
route_unlock_node(ifp->node);
}
if_delete(ifp);
}
}
const char *if_link_type_str(enum zebra_link_type llt)
{
switch (llt) {
#define llts(T,S) case (T): return (S)
llts(ZEBRA_LLT_UNKNOWN, "Unknown");
llts(ZEBRA_LLT_ETHER, "Ethernet");
llts(ZEBRA_LLT_EETHER, "Experimental Ethernet");
llts(ZEBRA_LLT_AX25, "AX.25 Level 2");
llts(ZEBRA_LLT_PRONET, "PROnet token ring");
llts(ZEBRA_LLT_IEEE802, "IEEE 802.2 Ethernet/TR/TB");
llts(ZEBRA_LLT_ARCNET, "ARCnet");
llts(ZEBRA_LLT_APPLETLK, "AppleTalk");
llts(ZEBRA_LLT_DLCI, "Frame Relay DLCI");
llts(ZEBRA_LLT_ATM, "ATM");
llts(ZEBRA_LLT_METRICOM, "Metricom STRIP");
llts(ZEBRA_LLT_IEEE1394, "IEEE 1394 IPv4");
llts(ZEBRA_LLT_EUI64, "EUI-64");
llts(ZEBRA_LLT_INFINIBAND, "InfiniBand");
llts(ZEBRA_LLT_SLIP, "SLIP");
llts(ZEBRA_LLT_CSLIP, "Compressed SLIP");
llts(ZEBRA_LLT_SLIP6, "SLIPv6");
llts(ZEBRA_LLT_CSLIP6, "Compressed SLIPv6");
llts(ZEBRA_LLT_ROSE, "ROSE packet radio");
llts(ZEBRA_LLT_X25, "CCITT X.25");
llts(ZEBRA_LLT_PPP, "PPP");
llts(ZEBRA_LLT_CHDLC, "Cisco HDLC");
llts(ZEBRA_LLT_RAWHDLC, "Raw HDLC");
llts(ZEBRA_LLT_LAPB, "LAPB");
llts(ZEBRA_LLT_IPIP, "IPIP Tunnel");
llts(ZEBRA_LLT_IPIP6, "IPIP6 Tunnel");
llts(ZEBRA_LLT_FRAD, "FRAD");
llts(ZEBRA_LLT_SKIP, "SKIP vif");
llts(ZEBRA_LLT_LOOPBACK, "Loopback");
llts(ZEBRA_LLT_LOCALTLK, "Localtalk");
llts(ZEBRA_LLT_FDDI, "FDDI");
llts(ZEBRA_LLT_SIT, "IPv6-in-IPv4 SIT");
llts(ZEBRA_LLT_IPDDP, "IP-in-DDP tunnel");
llts(ZEBRA_LLT_IPGRE, "GRE over IP");
llts(ZEBRA_LLT_PIMREG, "PIMSM registration");
llts(ZEBRA_LLT_HIPPI, "HiPPI");
llts(ZEBRA_LLT_IRDA, "IrDA");
llts(ZEBRA_LLT_FCPP, "Fibre-Channel PtP");
llts(ZEBRA_LLT_FCAL, "Fibre-Channel Arbitrated Loop");
llts(ZEBRA_LLT_FCPL, "Fibre-Channel Public Loop");
llts(ZEBRA_LLT_FCFABRIC, "Fibre-Channel Fabric");
llts(ZEBRA_LLT_IEEE802_TR, "IEEE 802.2 Token Ring");
llts(ZEBRA_LLT_IEEE80211, "IEEE 802.11");
llts(ZEBRA_LLT_IEEE80211_RADIOTAP, "IEEE 802.11 Radiotap");
llts(ZEBRA_LLT_IEEE802154, "IEEE 802.15.4");
llts(ZEBRA_LLT_IEEE802154_PHY, "IEEE 802.15.4 Phy");
default:
flog_err(LIB_ERR_DEVELOPMENT, "Unknown value %d", llt);
return "Unknown type!";
#undef llts
}
return NULL;
}
struct if_link_params *if_link_params_get(struct interface *ifp)
{
int i;
if (ifp->link_params != NULL)
return ifp->link_params;
struct if_link_params *iflp =
XCALLOC(MTYPE_IF_LINK_PARAMS, sizeof(struct if_link_params));
if (iflp == NULL)
return NULL;
/* Set TE metric equal to standard metric */
iflp->te_metric = ifp->metric;
/* Compute default bandwidth based on interface */
iflp->default_bw =
((ifp->bandwidth ? ifp->bandwidth : DEFAULT_BANDWIDTH)
* TE_KILO_BIT / TE_BYTE);
/* Set Max, Reservable and Unreserved Bandwidth */
iflp->max_bw = iflp->default_bw;
iflp->max_rsv_bw = iflp->default_bw;
for (i = 0; i < MAX_CLASS_TYPE; i++)
iflp->unrsv_bw[i] = iflp->default_bw;
/* Update Link parameters status */
iflp->lp_status =
LP_TE_METRIC | LP_MAX_BW | LP_MAX_RSV_BW | LP_UNRSV_BW;
/* Finally attach newly created Link Parameters */
ifp->link_params = iflp;
return iflp;
}
void if_link_params_free(struct interface *ifp)
{
if (ifp->link_params == NULL)
return;
XFREE(MTYPE_IF_LINK_PARAMS, ifp->link_params);
ifp->link_params = NULL;
}
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