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|
/*
* 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 <config.h>
#include <getopt.h>
#include <stdlib.h>
#include <stdio.h>
#include "bitmap.h"
#include "command-line.h"
#include "daemon.h"
#include "dirs.h"
#include "openvswitch/dynamic-string.h"
#include "fatal-signal.h"
#include "hash.h"
#include "openvswitch/hmap.h"
#include "openvswitch/json.h"
#include "ovn/lex.h"
#include "ovn/lib/chassis-index.h"
#include "ovn/lib/logical-fields.h"
#include "ovn/lib/ovn-dhcp.h"
#include "ovn/lib/ovn-nb-idl.h"
#include "ovn/lib/ovn-sb-idl.h"
#include "ovn/lib/ovn-util.h"
#include "ovn/actions.h"
#include "packets.h"
#include "poll-loop.h"
#include "smap.h"
#include "sset.h"
#include "stream.h"
#include "stream-ssl.h"
#include "unixctl.h"
#include "util.h"
#include "uuid.h"
#include "openvswitch/vlog.h"
VLOG_DEFINE_THIS_MODULE(ovn_northd);
static unixctl_cb_func ovn_northd_exit;
struct northd_context {
struct ovsdb_idl *ovnnb_idl;
struct ovsdb_idl *ovnsb_idl;
struct ovsdb_idl_txn *ovnnb_txn;
struct ovsdb_idl_txn *ovnsb_txn;
};
static const char *ovnnb_db;
static const char *ovnsb_db;
#define MAC_ADDR_PREFIX 0x0A0000000000ULL
#define MAC_ADDR_SPACE 0xffffff
/* MAC address management (macam) table of "struct eth_addr"s, that holds the
* MAC addresses allocated by the OVN ipam module. */
static struct hmap macam = HMAP_INITIALIZER(&macam);
#define MAX_OVN_TAGS 4096
/* Pipeline stages. */
/* The two pipelines in an OVN logical flow table. */
enum ovn_pipeline {
P_IN, /* Ingress pipeline. */
P_OUT /* Egress pipeline. */
};
/* The two purposes for which ovn-northd uses OVN logical datapaths. */
enum ovn_datapath_type {
DP_SWITCH, /* OVN logical switch. */
DP_ROUTER /* OVN logical router. */
};
/* Returns an "enum ovn_stage" built from the arguments.
*
* (It's better to use ovn_stage_build() for type-safety reasons, but inline
* functions can't be used in enums or switch cases.) */
#define OVN_STAGE_BUILD(DP_TYPE, PIPELINE, TABLE) \
(((DP_TYPE) << 9) | ((PIPELINE) << 8) | (TABLE))
/* A stage within an OVN logical switch or router.
*
* An "enum ovn_stage" indicates whether the stage is part of a logical switch
* or router, whether the stage is part of the ingress or egress pipeline, and
* the table within that pipeline. The first three components are combined to
* form the stage's full name, e.g. S_SWITCH_IN_PORT_SEC_L2,
* S_ROUTER_OUT_DELIVERY. */
enum ovn_stage {
#define PIPELINE_STAGES \
/* Logical switch ingress stages. */ \
PIPELINE_STAGE(SWITCH, IN, PORT_SEC_L2, 0, "ls_in_port_sec_l2") \
PIPELINE_STAGE(SWITCH, IN, PORT_SEC_IP, 1, "ls_in_port_sec_ip") \
PIPELINE_STAGE(SWITCH, IN, PORT_SEC_ND, 2, "ls_in_port_sec_nd") \
PIPELINE_STAGE(SWITCH, IN, PRE_ACL, 3, "ls_in_pre_acl") \
PIPELINE_STAGE(SWITCH, IN, PRE_LB, 4, "ls_in_pre_lb") \
PIPELINE_STAGE(SWITCH, IN, PRE_STATEFUL, 5, "ls_in_pre_stateful") \
PIPELINE_STAGE(SWITCH, IN, ACL, 6, "ls_in_acl") \
PIPELINE_STAGE(SWITCH, IN, QOS_MARK, 7, "ls_in_qos_mark") \
PIPELINE_STAGE(SWITCH, IN, LB, 8, "ls_in_lb") \
PIPELINE_STAGE(SWITCH, IN, STATEFUL, 9, "ls_in_stateful") \
PIPELINE_STAGE(SWITCH, IN, ARP_ND_RSP, 10, "ls_in_arp_rsp") \
PIPELINE_STAGE(SWITCH, IN, DHCP_OPTIONS, 11, "ls_in_dhcp_options") \
PIPELINE_STAGE(SWITCH, IN, DHCP_RESPONSE, 12, "ls_in_dhcp_response") \
PIPELINE_STAGE(SWITCH, IN, DNS_LOOKUP, 13, "ls_in_dns_lookup") \
PIPELINE_STAGE(SWITCH, IN, DNS_RESPONSE, 14, "ls_in_dns_response") \
PIPELINE_STAGE(SWITCH, IN, L2_LKUP, 15, "ls_in_l2_lkup") \
\
/* Logical switch egress stages. */ \
PIPELINE_STAGE(SWITCH, OUT, PRE_LB, 0, "ls_out_pre_lb") \
PIPELINE_STAGE(SWITCH, OUT, PRE_ACL, 1, "ls_out_pre_acl") \
PIPELINE_STAGE(SWITCH, OUT, PRE_STATEFUL, 2, "ls_out_pre_stateful") \
PIPELINE_STAGE(SWITCH, OUT, LB, 3, "ls_out_lb") \
PIPELINE_STAGE(SWITCH, OUT, ACL, 4, "ls_out_acl") \
PIPELINE_STAGE(SWITCH, OUT, QOS_MARK, 5, "ls_out_qos_mark") \
PIPELINE_STAGE(SWITCH, OUT, STATEFUL, 6, "ls_out_stateful") \
PIPELINE_STAGE(SWITCH, OUT, PORT_SEC_IP, 7, "ls_out_port_sec_ip") \
PIPELINE_STAGE(SWITCH, OUT, PORT_SEC_L2, 8, "ls_out_port_sec_l2") \
\
/* Logical router ingress stages. */ \
PIPELINE_STAGE(ROUTER, IN, ADMISSION, 0, "lr_in_admission") \
PIPELINE_STAGE(ROUTER, IN, IP_INPUT, 1, "lr_in_ip_input") \
PIPELINE_STAGE(ROUTER, IN, DEFRAG, 2, "lr_in_defrag") \
PIPELINE_STAGE(ROUTER, IN, UNSNAT, 3, "lr_in_unsnat") \
PIPELINE_STAGE(ROUTER, IN, DNAT, 4, "lr_in_dnat") \
PIPELINE_STAGE(ROUTER, IN, IP_ROUTING, 5, "lr_in_ip_routing") \
PIPELINE_STAGE(ROUTER, IN, ARP_RESOLVE, 6, "lr_in_arp_resolve") \
PIPELINE_STAGE(ROUTER, IN, GW_REDIRECT, 7, "lr_in_gw_redirect") \
PIPELINE_STAGE(ROUTER, IN, ARP_REQUEST, 8, "lr_in_arp_request") \
\
/* Logical router egress stages. */ \
PIPELINE_STAGE(ROUTER, OUT, UNDNAT, 0, "lr_out_undnat") \
PIPELINE_STAGE(ROUTER, OUT, SNAT, 1, "lr_out_snat") \
PIPELINE_STAGE(ROUTER, OUT, EGR_LOOP, 2, "lr_out_egr_loop") \
PIPELINE_STAGE(ROUTER, OUT, DELIVERY, 3, "lr_out_delivery")
#define PIPELINE_STAGE(DP_TYPE, PIPELINE, STAGE, TABLE, NAME) \
S_##DP_TYPE##_##PIPELINE##_##STAGE \
= OVN_STAGE_BUILD(DP_##DP_TYPE, P_##PIPELINE, TABLE),
PIPELINE_STAGES
#undef PIPELINE_STAGE
};
/* Due to various hard-coded priorities need to implement ACLs, the
* northbound database supports a smaller range of ACL priorities than
* are available to logical flows. This value is added to an ACL
* priority to determine the ACL's logical flow priority. */
#define OVN_ACL_PRI_OFFSET 1000
/* Register definitions specific to switches. */
#define REGBIT_CONNTRACK_DEFRAG "reg0[0]"
#define REGBIT_CONNTRACK_COMMIT "reg0[1]"
#define REGBIT_CONNTRACK_NAT "reg0[2]"
#define REGBIT_DHCP_OPTS_RESULT "reg0[3]"
#define REGBIT_DNS_LOOKUP_RESULT "reg0[4]"
/* Register definitions for switches and routers. */
#define REGBIT_NAT_REDIRECT "reg9[0]"
/* Indicate that this packet has been recirculated using egress
* loopback. This allows certain checks to be bypassed, such as a
* logical router dropping packets with source IP address equals
* one of the logical router's own IP addresses. */
#define REGBIT_EGRESS_LOOPBACK "reg9[1]"
/* Returns an "enum ovn_stage" built from the arguments. */
static enum ovn_stage
ovn_stage_build(enum ovn_datapath_type dp_type, enum ovn_pipeline pipeline,
uint8_t table)
{
return OVN_STAGE_BUILD(dp_type, pipeline, table);
}
/* Returns the pipeline to which 'stage' belongs. */
static enum ovn_pipeline
ovn_stage_get_pipeline(enum ovn_stage stage)
{
return (stage >> 8) & 1;
}
/* Returns the table to which 'stage' belongs. */
static uint8_t
ovn_stage_get_table(enum ovn_stage stage)
{
return stage & 0xff;
}
/* Returns a string name for 'stage'. */
static const char *
ovn_stage_to_str(enum ovn_stage stage)
{
switch (stage) {
#define PIPELINE_STAGE(DP_TYPE, PIPELINE, STAGE, TABLE, NAME) \
case S_##DP_TYPE##_##PIPELINE##_##STAGE: return NAME;
PIPELINE_STAGES
#undef PIPELINE_STAGE
default: return "<unknown>";
}
}
/* Returns the type of the datapath to which a flow with the given 'stage' may
* be added. */
static enum ovn_datapath_type
ovn_stage_to_datapath_type(enum ovn_stage stage)
{
switch (stage) {
#define PIPELINE_STAGE(DP_TYPE, PIPELINE, STAGE, TABLE, NAME) \
case S_##DP_TYPE##_##PIPELINE##_##STAGE: return DP_##DP_TYPE;
PIPELINE_STAGES
#undef PIPELINE_STAGE
default: OVS_NOT_REACHED();
}
}
static void
usage(void)
{
printf("\
%s: OVN northbound management daemon\n\
usage: %s [OPTIONS]\n\
\n\
Options:\n\
--ovnnb-db=DATABASE connect to ovn-nb database at DATABASE\n\
(default: %s)\n\
--ovnsb-db=DATABASE connect to ovn-sb database at DATABASE\n\
(default: %s)\n\
-h, --help display this help message\n\
-o, --options list available options\n\
-V, --version display version information\n\
", program_name, program_name, default_nb_db(), default_sb_db());
daemon_usage();
vlog_usage();
stream_usage("database", true, true, false);
}
struct tnlid_node {
struct hmap_node hmap_node;
uint32_t tnlid;
};
static void
destroy_tnlids(struct hmap *tnlids)
{
struct tnlid_node *node;
HMAP_FOR_EACH_POP (node, hmap_node, tnlids) {
free(node);
}
hmap_destroy(tnlids);
}
static void
add_tnlid(struct hmap *set, uint32_t tnlid)
{
struct tnlid_node *node = xmalloc(sizeof *node);
hmap_insert(set, &node->hmap_node, hash_int(tnlid, 0));
node->tnlid = tnlid;
}
static bool
tnlid_in_use(const struct hmap *set, uint32_t tnlid)
{
const struct tnlid_node *node;
HMAP_FOR_EACH_IN_BUCKET (node, hmap_node, hash_int(tnlid, 0), set) {
if (node->tnlid == tnlid) {
return true;
}
}
return false;
}
static uint32_t
allocate_tnlid(struct hmap *set, const char *name, uint32_t max,
uint32_t *hint)
{
for (uint32_t tnlid = *hint + 1; tnlid != *hint;
tnlid = tnlid + 1 <= max ? tnlid + 1 : 1) {
if (!tnlid_in_use(set, tnlid)) {
add_tnlid(set, tnlid);
*hint = tnlid;
return tnlid;
}
}
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "all %s tunnel ids exhausted", name);
return 0;
}
struct ovn_chassis_qdisc_queues {
struct hmap_node key_node;
uint32_t queue_id;
struct uuid chassis_uuid;
};
static void
destroy_chassis_queues(struct hmap *set)
{
struct ovn_chassis_qdisc_queues *node;
HMAP_FOR_EACH_POP (node, key_node, set) {
free(node);
}
hmap_destroy(set);
}
static void
add_chassis_queue(struct hmap *set, struct uuid *chassis_uuid,
uint32_t queue_id)
{
struct ovn_chassis_qdisc_queues *node = xmalloc(sizeof *node);
node->queue_id = queue_id;
memcpy(&node->chassis_uuid, chassis_uuid, sizeof node->chassis_uuid);
hmap_insert(set, &node->key_node, uuid_hash(chassis_uuid));
}
static bool
chassis_queueid_in_use(const struct hmap *set, struct uuid *chassis_uuid,
uint32_t queue_id)
{
const struct ovn_chassis_qdisc_queues *node;
HMAP_FOR_EACH_WITH_HASH (node, key_node, uuid_hash(chassis_uuid), set) {
if (uuid_equals(chassis_uuid, &node->chassis_uuid)
&& node->queue_id == queue_id) {
return true;
}
}
return false;
}
static uint32_t
allocate_chassis_queueid(struct hmap *set, struct sbrec_chassis *chassis)
{
for (uint32_t queue_id = QDISC_MIN_QUEUE_ID + 1;
queue_id <= QDISC_MAX_QUEUE_ID;
queue_id++) {
if (!chassis_queueid_in_use(set, &chassis->header_.uuid, queue_id)) {
add_chassis_queue(set, &chassis->header_.uuid, queue_id);
return queue_id;
}
}
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "all %s queue ids exhausted", chassis->name);
return 0;
}
static void
free_chassis_queueid(struct hmap *set, struct sbrec_chassis *chassis,
uint32_t queue_id)
{
struct ovn_chassis_qdisc_queues *node;
HMAP_FOR_EACH_WITH_HASH (node, key_node,
uuid_hash(&chassis->header_.uuid),
set) {
if (uuid_equals(&chassis->header_.uuid, &node->chassis_uuid)
&& node->queue_id == queue_id) {
hmap_remove(set, &node->key_node);
break;
}
}
}
static inline bool
port_has_qos_params(const struct smap *opts)
{
return (smap_get(opts, "qos_max_rate") ||
smap_get(opts, "qos_burst"));
}
struct ipam_info {
uint32_t start_ipv4;
size_t total_ipv4s;
unsigned long *allocated_ipv4s; /* A bitmap of allocated IPv4s */
bool ipv6_prefix_set;
struct in6_addr ipv6_prefix;
};
/* The 'key' comes from nbs->header_.uuid or nbr->header_.uuid or
* sb->external_ids:logical-switch. */
struct ovn_datapath {
struct hmap_node key_node; /* Index on 'key'. */
struct uuid key; /* (nbs/nbr)->header_.uuid. */
const struct nbrec_logical_switch *nbs; /* May be NULL. */
const struct nbrec_logical_router *nbr; /* May be NULL. */
const struct sbrec_datapath_binding *sb; /* May be NULL. */
struct ovs_list list; /* In list of similar records. */
/* Logical switch data. */
struct ovn_port **router_ports;
size_t n_router_ports;
struct hmap port_tnlids;
uint32_t port_key_hint;
bool has_unknown;
/* IPAM data. */
struct ipam_info *ipam_info;
/* OVN northd only needs to know about the logical router gateway port for
* NAT on a distributed router. This "distributed gateway port" is
* populated only when there is a "redirect-chassis" specified for one of
* the ports on the logical router. Otherwise this will be NULL. */
struct ovn_port *l3dgw_port;
/* The "derived" OVN port representing the instance of l3dgw_port on
* the "redirect-chassis". */
struct ovn_port *l3redirect_port;
struct ovn_port *localnet_port;
};
struct macam_node {
struct hmap_node hmap_node;
struct eth_addr mac_addr; /* Allocated MAC address. */
};
static void
cleanup_macam(struct hmap *macam)
{
struct macam_node *node;
HMAP_FOR_EACH_POP (node, hmap_node, macam) {
free(node);
}
}
static struct ovn_datapath *
ovn_datapath_create(struct hmap *datapaths, const struct uuid *key,
const struct nbrec_logical_switch *nbs,
const struct nbrec_logical_router *nbr,
const struct sbrec_datapath_binding *sb)
{
struct ovn_datapath *od = xzalloc(sizeof *od);
od->key = *key;
od->sb = sb;
od->nbs = nbs;
od->nbr = nbr;
hmap_init(&od->port_tnlids);
od->port_key_hint = 0;
hmap_insert(datapaths, &od->key_node, uuid_hash(&od->key));
return od;
}
static void
ovn_datapath_destroy(struct hmap *datapaths, struct ovn_datapath *od)
{
if (od) {
/* Don't remove od->list. It is used within build_datapaths() as a
* private list and once we've exited that function it is not safe to
* use it. */
hmap_remove(datapaths, &od->key_node);
destroy_tnlids(&od->port_tnlids);
if (od->ipam_info) {
bitmap_free(od->ipam_info->allocated_ipv4s);
free(od->ipam_info);
}
free(od->router_ports);
free(od);
}
}
/* Returns 'od''s datapath type. */
static enum ovn_datapath_type
ovn_datapath_get_type(const struct ovn_datapath *od)
{
return od->nbs ? DP_SWITCH : DP_ROUTER;
}
static struct ovn_datapath *
ovn_datapath_find(struct hmap *datapaths, const struct uuid *uuid)
{
struct ovn_datapath *od;
HMAP_FOR_EACH_WITH_HASH (od, key_node, uuid_hash(uuid), datapaths) {
if (uuid_equals(uuid, &od->key)) {
return od;
}
}
return NULL;
}
static struct ovn_datapath *
ovn_datapath_from_sbrec(struct hmap *datapaths,
const struct sbrec_datapath_binding *sb)
{
struct uuid key;
if (!smap_get_uuid(&sb->external_ids, "logical-switch", &key) &&
!smap_get_uuid(&sb->external_ids, "logical-router", &key)) {
return NULL;
}
return ovn_datapath_find(datapaths, &key);
}
static bool
lrouter_is_enabled(const struct nbrec_logical_router *lrouter)
{
return !lrouter->enabled || *lrouter->enabled;
}
static void
init_ipam_info_for_datapath(struct ovn_datapath *od)
{
if (!od->nbs) {
return;
}
const char *subnet_str = smap_get(&od->nbs->other_config, "subnet");
const char *ipv6_prefix = smap_get(&od->nbs->other_config, "ipv6_prefix");
if (ipv6_prefix) {
od->ipam_info = xzalloc(sizeof *od->ipam_info);
od->ipam_info->ipv6_prefix_set = ipv6_parse(
ipv6_prefix, &od->ipam_info->ipv6_prefix);
}
if (!subnet_str) {
return;
}
ovs_be32 subnet, mask;
char *error = ip_parse_masked(subnet_str, &subnet, &mask);
if (error || mask == OVS_BE32_MAX || !ip_is_cidr(mask)) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad 'subnet' %s", subnet_str);
free(error);
return;
}
if (!od->ipam_info) {
od->ipam_info = xzalloc(sizeof *od->ipam_info);
}
od->ipam_info->start_ipv4 = ntohl(subnet) + 1;
od->ipam_info->total_ipv4s = ~ntohl(mask);
od->ipam_info->allocated_ipv4s =
bitmap_allocate(od->ipam_info->total_ipv4s);
/* Mark first IP as taken */
bitmap_set1(od->ipam_info->allocated_ipv4s, 0);
/* Check if there are any reserver IPs (list) to be excluded from IPAM */
const char *exclude_ip_list = smap_get(&od->nbs->other_config,
"exclude_ips");
if (!exclude_ip_list) {
return;
}
struct lexer lexer;
lexer_init(&lexer, exclude_ip_list);
/* exclude_ip_list could be in the format -
* "10.0.0.4 10.0.0.10 10.0.0.20..10.0.0.50 10.0.0.100..10.0.0.110".
*/
lexer_get(&lexer);
while (lexer.token.type != LEX_T_END) {
if (lexer.token.type != LEX_T_INTEGER) {
lexer_syntax_error(&lexer, "expecting address");
break;
}
uint32_t start = ntohl(lexer.token.value.ipv4);
lexer_get(&lexer);
uint32_t end = start + 1;
if (lexer_match(&lexer, LEX_T_ELLIPSIS)) {
if (lexer.token.type != LEX_T_INTEGER) {
lexer_syntax_error(&lexer, "expecting address range");
break;
}
end = ntohl(lexer.token.value.ipv4) + 1;
lexer_get(&lexer);
}
/* Clamp start...end to fit the subnet. */
start = MAX(od->ipam_info->start_ipv4, start);
end = MIN(od->ipam_info->start_ipv4 + od->ipam_info->total_ipv4s, end);
if (end > start) {
bitmap_set_multiple(od->ipam_info->allocated_ipv4s,
start - od->ipam_info->start_ipv4,
end - start, 1);
} else {
lexer_error(&lexer, "excluded addresses not in subnet");
}
}
if (lexer.error) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "logical switch "UUID_FMT": bad exclude_ips (%s)",
UUID_ARGS(&od->key), lexer.error);
}
lexer_destroy(&lexer);
}
static void
ovn_datapath_update_external_ids(struct ovn_datapath *od)
{
/* Get the logical-switch or logical-router UUID to set in
* external-ids. */
char uuid_s[UUID_LEN + 1];
sprintf(uuid_s, UUID_FMT, UUID_ARGS(&od->key));
const char *key = od->nbs ? "logical-switch" : "logical-router";
/* Get names to set in external-ids. */
const char *name = od->nbs ? od->nbs->name : od->nbr->name;
const char *name2 = (od->nbs
? smap_get(&od->nbs->external_ids,
"neutron:network_name")
: smap_get(&od->nbr->external_ids,
"neutron:router_name"));
/* Set external-ids. */
struct smap ids = SMAP_INITIALIZER(&ids);
smap_add(&ids, key, uuid_s);
smap_add(&ids, "name", name);
if (name2 && name2[0]) {
smap_add(&ids, "name2", name2);
}
sbrec_datapath_binding_set_external_ids(od->sb, &ids);
smap_destroy(&ids);
}
static void
join_datapaths(struct northd_context *ctx, struct hmap *datapaths,
struct ovs_list *sb_only, struct ovs_list *nb_only,
struct ovs_list *both)
{
hmap_init(datapaths);
ovs_list_init(sb_only);
ovs_list_init(nb_only);
ovs_list_init(both);
const struct sbrec_datapath_binding *sb, *sb_next;
SBREC_DATAPATH_BINDING_FOR_EACH_SAFE (sb, sb_next, ctx->ovnsb_idl) {
struct uuid key;
if (!smap_get_uuid(&sb->external_ids, "logical-switch", &key) &&
!smap_get_uuid(&sb->external_ids, "logical-router", &key)) {
ovsdb_idl_txn_add_comment(
ctx->ovnsb_txn,
"deleting Datapath_Binding "UUID_FMT" that lacks "
"external-ids:logical-switch and "
"external-ids:logical-router",
UUID_ARGS(&sb->header_.uuid));
sbrec_datapath_binding_delete(sb);
continue;
}
if (ovn_datapath_find(datapaths, &key)) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_INFO_RL(
&rl, "deleting Datapath_Binding "UUID_FMT" with "
"duplicate external-ids:logical-switch/router "UUID_FMT,
UUID_ARGS(&sb->header_.uuid), UUID_ARGS(&key));
sbrec_datapath_binding_delete(sb);
continue;
}
struct ovn_datapath *od = ovn_datapath_create(datapaths, &key,
NULL, NULL, sb);
ovs_list_push_back(sb_only, &od->list);
}
const struct nbrec_logical_switch *nbs;
NBREC_LOGICAL_SWITCH_FOR_EACH (nbs, ctx->ovnnb_idl) {
struct ovn_datapath *od = ovn_datapath_find(datapaths,
&nbs->header_.uuid);
if (od) {
od->nbs = nbs;
ovs_list_remove(&od->list);
ovs_list_push_back(both, &od->list);
ovn_datapath_update_external_ids(od);
} else {
od = ovn_datapath_create(datapaths, &nbs->header_.uuid,
nbs, NULL, NULL);
ovs_list_push_back(nb_only, &od->list);
}
init_ipam_info_for_datapath(od);
}
const struct nbrec_logical_router *nbr;
NBREC_LOGICAL_ROUTER_FOR_EACH (nbr, ctx->ovnnb_idl) {
if (!lrouter_is_enabled(nbr)) {
continue;
}
struct ovn_datapath *od = ovn_datapath_find(datapaths,
&nbr->header_.uuid);
if (od) {
if (!od->nbs) {
od->nbr = nbr;
ovs_list_remove(&od->list);
ovs_list_push_back(both, &od->list);
ovn_datapath_update_external_ids(od);
} else {
/* Can't happen! */
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl,
"duplicate UUID "UUID_FMT" in OVN_Northbound",
UUID_ARGS(&nbr->header_.uuid));
continue;
}
} else {
od = ovn_datapath_create(datapaths, &nbr->header_.uuid,
NULL, nbr, NULL);
ovs_list_push_back(nb_only, &od->list);
}
}
}
static uint32_t
ovn_datapath_allocate_key(struct hmap *dp_tnlids)
{
static uint32_t hint;
return allocate_tnlid(dp_tnlids, "datapath", (1u << 24) - 1, &hint);
}
/* Updates the southbound Datapath_Binding table so that it contains the
* logical switches and routers specified by the northbound database.
*
* Initializes 'datapaths' to contain a "struct ovn_datapath" for every logical
* switch and router. */
static void
build_datapaths(struct northd_context *ctx, struct hmap *datapaths)
{
struct ovs_list sb_only, nb_only, both;
join_datapaths(ctx, datapaths, &sb_only, &nb_only, &both);
if (!ovs_list_is_empty(&nb_only)) {
/* First index the in-use datapath tunnel IDs. */
struct hmap dp_tnlids = HMAP_INITIALIZER(&dp_tnlids);
struct ovn_datapath *od;
LIST_FOR_EACH (od, list, &both) {
add_tnlid(&dp_tnlids, od->sb->tunnel_key);
}
/* Add southbound record for each unmatched northbound record. */
LIST_FOR_EACH (od, list, &nb_only) {
uint16_t tunnel_key = ovn_datapath_allocate_key(&dp_tnlids);
if (!tunnel_key) {
break;
}
od->sb = sbrec_datapath_binding_insert(ctx->ovnsb_txn);
ovn_datapath_update_external_ids(od);
sbrec_datapath_binding_set_tunnel_key(od->sb, tunnel_key);
}
destroy_tnlids(&dp_tnlids);
}
/* Delete southbound records without northbound matches. */
struct ovn_datapath *od, *next;
LIST_FOR_EACH_SAFE (od, next, list, &sb_only) {
ovs_list_remove(&od->list);
sbrec_datapath_binding_delete(od->sb);
ovn_datapath_destroy(datapaths, od);
}
}
struct ovn_port {
struct hmap_node key_node; /* Index on 'key'. */
char *key; /* nbs->name, nbr->name, sb->logical_port. */
char *json_key; /* 'key', quoted for use in JSON. */
const struct sbrec_port_binding *sb; /* May be NULL. */
/* Logical switch port data. */
const struct nbrec_logical_switch_port *nbsp; /* May be NULL. */
struct lport_addresses *lsp_addrs; /* Logical switch port addresses. */
unsigned int n_lsp_addrs;
struct lport_addresses *ps_addrs; /* Port security addresses. */
unsigned int n_ps_addrs;
/* Logical router port data. */
const struct nbrec_logical_router_port *nbrp; /* May be NULL. */
struct lport_addresses lrp_networks;
bool derived; /* Indicates whether this is an additional port
* derived from nbsp or nbrp. */
/* The port's peer:
*
* - A switch port S of type "router" has a router port R as a peer,
* and R in turn has S has its peer.
*
* - Two connected logical router ports have each other as peer. */
struct ovn_port *peer;
struct ovn_datapath *od;
struct ovs_list list; /* In list of similar records. */
};
static struct ovn_port *
ovn_port_create(struct hmap *ports, const char *key,
const struct nbrec_logical_switch_port *nbsp,
const struct nbrec_logical_router_port *nbrp,
const struct sbrec_port_binding *sb)
{
struct ovn_port *op = xzalloc(sizeof *op);
struct ds json_key = DS_EMPTY_INITIALIZER;
json_string_escape(key, &json_key);
op->json_key = ds_steal_cstr(&json_key);
op->key = xstrdup(key);
op->sb = sb;
op->nbsp = nbsp;
op->nbrp = nbrp;
op->derived = false;
hmap_insert(ports, &op->key_node, hash_string(op->key, 0));
return op;
}
static void
ovn_port_destroy(struct hmap *ports, struct ovn_port *port)
{
if (port) {
/* Don't remove port->list. It is used within build_ports() as a
* private list and once we've exited that function it is not safe to
* use it. */
hmap_remove(ports, &port->key_node);
for (int i = 0; i < port->n_lsp_addrs; i++) {
destroy_lport_addresses(&port->lsp_addrs[i]);
}
free(port->lsp_addrs);
for (int i = 0; i < port->n_ps_addrs; i++) {
destroy_lport_addresses(&port->ps_addrs[i]);
}
free(port->ps_addrs);
destroy_lport_addresses(&port->lrp_networks);
free(port->json_key);
free(port->key);
free(port);
}
}
static struct ovn_port *
ovn_port_find(struct hmap *ports, const char *name)
{
struct ovn_port *op;
HMAP_FOR_EACH_WITH_HASH (op, key_node, hash_string(name, 0), ports) {
if (!strcmp(op->key, name)) {
return op;
}
}
return NULL;
}
static uint32_t
ovn_port_allocate_key(struct ovn_datapath *od)
{
return allocate_tnlid(&od->port_tnlids, "port",
(1u << 15) - 1, &od->port_key_hint);
}
static char *
chassis_redirect_name(const char *port_name)
{
return xasprintf("cr-%s", port_name);
}
static bool
ipam_is_duplicate_mac(struct eth_addr *ea, uint64_t mac64, bool warn)
{
struct macam_node *macam_node;
HMAP_FOR_EACH_WITH_HASH (macam_node, hmap_node, hash_uint64(mac64),
&macam) {
if (eth_addr_equals(*ea, macam_node->mac_addr)) {
if (warn) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "Duplicate MAC set: "ETH_ADDR_FMT,
ETH_ADDR_ARGS(macam_node->mac_addr));
}
return true;
}
}
return false;
}
static void
ipam_insert_mac(struct eth_addr *ea, bool check)
{
if (!ea) {
return;
}
uint64_t mac64 = eth_addr_to_uint64(*ea);
/* If the new MAC was not assigned by this address management system or
* check is true and the new MAC is a duplicate, do not insert it into the
* macam hmap. */
if (((mac64 ^ MAC_ADDR_PREFIX) >> 24)
|| (check && ipam_is_duplicate_mac(ea, mac64, true))) {
return;
}
struct macam_node *new_macam_node = xmalloc(sizeof *new_macam_node);
new_macam_node->mac_addr = *ea;
hmap_insert(&macam, &new_macam_node->hmap_node, hash_uint64(mac64));
}
static void
ipam_insert_ip(struct ovn_datapath *od, uint32_t ip)
{
if (!od || !od->ipam_info || !od->ipam_info->allocated_ipv4s) {
return;
}
if (ip >= od->ipam_info->start_ipv4 &&
ip < (od->ipam_info->start_ipv4 + od->ipam_info->total_ipv4s)) {
bitmap_set1(od->ipam_info->allocated_ipv4s,
ip - od->ipam_info->start_ipv4);
}
}
static void
ipam_insert_lsp_addresses(struct ovn_datapath *od, struct ovn_port *op,
char *address)
{
if (!od || !op || !address || !strcmp(address, "unknown")
|| !strcmp(address, "router") || is_dynamic_lsp_address(address)) {
return;
}
struct lport_addresses laddrs;
if (!extract_lsp_addresses(address, &laddrs)) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "Extract addresses failed.");
return;
}
ipam_insert_mac(&laddrs.ea, true);
/* IP is only added to IPAM if the switch's subnet option
* is set, whereas MAC is always added to MACAM. */
if (!od->ipam_info || !od->ipam_info->allocated_ipv4s) {
destroy_lport_addresses(&laddrs);
return;
}
for (size_t j = 0; j < laddrs.n_ipv4_addrs; j++) {
uint32_t ip = ntohl(laddrs.ipv4_addrs[j].addr);
ipam_insert_ip(od, ip);
}
destroy_lport_addresses(&laddrs);
}
static void
ipam_add_port_addresses(struct ovn_datapath *od, struct ovn_port *op)
{
if (!od || !op) {
return;
}
if (op->nbsp) {
/* Add all the port's addresses to address data structures. */
for (size_t i = 0; i < op->nbsp->n_addresses; i++) {
ipam_insert_lsp_addresses(od, op, op->nbsp->addresses[i]);
}
if (op->nbsp->dynamic_addresses) {
ipam_insert_lsp_addresses(od, op, op->nbsp->dynamic_addresses);
}
} else if (op->nbrp) {
struct lport_addresses lrp_networks;
if (!extract_lrp_networks(op->nbrp, &lrp_networks)) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "Extract addresses failed.");
return;
}
ipam_insert_mac(&lrp_networks.ea, true);
if (!op->peer || !op->peer->nbsp || !op->peer->od || !op->peer->od->nbs
|| !smap_get(&op->peer->od->nbs->other_config, "subnet")) {
destroy_lport_addresses(&lrp_networks);
return;
}
for (size_t i = 0; i < lrp_networks.n_ipv4_addrs; i++) {
uint32_t ip = ntohl(lrp_networks.ipv4_addrs[i].addr);
ipam_insert_ip(op->peer->od, ip);
}
destroy_lport_addresses(&lrp_networks);
}
}
static uint64_t
ipam_get_unused_mac(void)
{
/* Stores the suffix of the most recently ipam-allocated MAC address. */
static uint32_t last_mac;
uint64_t mac64;
struct eth_addr mac;
uint32_t mac_addr_suffix, i;
for (i = 0; i < MAC_ADDR_SPACE - 1; i++) {
/* The tentative MAC's suffix will be in the interval (1, 0xfffffe). */
mac_addr_suffix = ((last_mac + i) % (MAC_ADDR_SPACE - 1)) + 1;
mac64 = MAC_ADDR_PREFIX | mac_addr_suffix;
eth_addr_from_uint64(mac64, &mac);
if (!ipam_is_duplicate_mac(&mac, mac64, false)) {
last_mac = mac_addr_suffix;
break;
}
}
if (i == MAC_ADDR_SPACE) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "MAC address space exhausted.");
mac64 = 0;
}
return mac64;
}
static uint32_t
ipam_get_unused_ip(struct ovn_datapath *od)
{
if (!od || !od->ipam_info || !od->ipam_info->allocated_ipv4s) {
return 0;
}
size_t new_ip_index = bitmap_scan(od->ipam_info->allocated_ipv4s, 0, 0,
od->ipam_info->total_ipv4s - 1);
if (new_ip_index == od->ipam_info->total_ipv4s - 1) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL( &rl, "Subnet address space has been exhausted.");
return 0;
}
return od->ipam_info->start_ipv4 + new_ip_index;
}
static bool
ipam_allocate_addresses(struct ovn_datapath *od, struct ovn_port *op,
const char *addrspec)
{
if (!op->nbsp || !od->ipam_info) {
return false;
}
/* Get or generate MAC address. */
struct eth_addr mac;
bool dynamic_mac;
int n = 0;
if (ovs_scan(addrspec, ETH_ADDR_SCAN_FMT" dynamic%n",
ETH_ADDR_SCAN_ARGS(mac), &n)
&& addrspec[n] == '\0') {
dynamic_mac = false;
} else {
uint64_t mac64 = ipam_get_unused_mac();
if (!mac64) {
return false;
}
eth_addr_from_uint64(mac64, &mac);
dynamic_mac = true;
}
/* Generate IPv4 address, if desirable. */
bool dynamic_ip4 = od->ipam_info->allocated_ipv4s != NULL;
uint32_t ip4 = dynamic_ip4 ? ipam_get_unused_ip(od) : 0;
/* Generate IPv6 address, if desirable. */
bool dynamic_ip6 = od->ipam_info->ipv6_prefix_set;
struct in6_addr ip6;
if (dynamic_ip6) {
in6_generate_eui64(mac, &od->ipam_info->ipv6_prefix, &ip6);
}
/* If we didn't generate anything, bail out. */
if (!dynamic_ip4 && !dynamic_ip6) {
return false;
}
/* Save the dynamic addresses. */
struct ds new_addr = DS_EMPTY_INITIALIZER;
ds_put_format(&new_addr, ETH_ADDR_FMT, ETH_ADDR_ARGS(mac));
if (dynamic_ip4 && ip4) {
ipam_insert_ip(od, ip4);
ds_put_format(&new_addr, " "IP_FMT, IP_ARGS(htonl(ip4)));
}
if (dynamic_ip6) {
char ip6_s[INET6_ADDRSTRLEN + 1];
ipv6_string_mapped(ip6_s, &ip6);
ds_put_format(&new_addr, " %s", ip6_s);
}
ipam_insert_mac(&mac, !dynamic_mac);
nbrec_logical_switch_port_set_dynamic_addresses(op->nbsp,
ds_cstr(&new_addr));
ds_destroy(&new_addr);
return true;
}
static void
build_ipam(struct hmap *datapaths, struct hmap *ports)
{
/* IPAM generally stands for IP address management. In non-virtualized
* world, MAC addresses come with the hardware. But, with virtualized
* workloads, they need to be assigned and managed. This function
* does both IP address management (ipam) and MAC address management
* (macam). */
/* If the switch's other_config:subnet is set, allocate new addresses for
* ports that have the "dynamic" keyword in their addresses column. */
struct ovn_datapath *od;
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs || !od->ipam_info) {
continue;
}
struct ovn_port *op;
for (size_t i = 0; i < od->nbs->n_ports; i++) {
const struct nbrec_logical_switch_port *nbsp =
od->nbs->ports[i];
if (!nbsp) {
continue;
}
op = ovn_port_find(ports, nbsp->name);
if (!op || (op->nbsp && op->peer)) {
/* Do not allocate addresses for logical switch ports that
* have a peer. */
continue;
}
for (size_t j = 0; j < nbsp->n_addresses; j++) {
if (is_dynamic_lsp_address(nbsp->addresses[j])
&& !nbsp->dynamic_addresses) {
if (!ipam_allocate_addresses(od, op, nbsp->addresses[j])
|| !extract_lsp_addresses(nbsp->dynamic_addresses,
&op->lsp_addrs[op->n_lsp_addrs])) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_INFO_RL(&rl, "Failed to allocate address.");
} else {
op->n_lsp_addrs++;
}
break;
}
}
if (!nbsp->n_addresses && nbsp->dynamic_addresses) {
nbrec_logical_switch_port_set_dynamic_addresses(op->nbsp,
NULL);
}
}
}
}
/* Tag allocation for nested containers.
*
* For a logical switch port with 'parent_name' and a request to allocate tags,
* keeps a track of all allocated tags. */
struct tag_alloc_node {
struct hmap_node hmap_node;
char *parent_name;
unsigned long *allocated_tags; /* A bitmap to track allocated tags. */
};
static void
tag_alloc_destroy(struct hmap *tag_alloc_table)
{
struct tag_alloc_node *node;
HMAP_FOR_EACH_POP (node, hmap_node, tag_alloc_table) {
bitmap_free(node->allocated_tags);
free(node->parent_name);
free(node);
}
hmap_destroy(tag_alloc_table);
}
static struct tag_alloc_node *
tag_alloc_get_node(struct hmap *tag_alloc_table, const char *parent_name)
{
/* If a node for the 'parent_name' exists, return it. */
struct tag_alloc_node *tag_alloc_node;
HMAP_FOR_EACH_WITH_HASH (tag_alloc_node, hmap_node,
hash_string(parent_name, 0),
tag_alloc_table) {
if (!strcmp(tag_alloc_node->parent_name, parent_name)) {
return tag_alloc_node;
}
}
/* Create a new node. */
tag_alloc_node = xmalloc(sizeof *tag_alloc_node);
tag_alloc_node->parent_name = xstrdup(parent_name);
tag_alloc_node->allocated_tags = bitmap_allocate(MAX_OVN_TAGS);
/* Tag 0 is invalid for nested containers. */
bitmap_set1(tag_alloc_node->allocated_tags, 0);
hmap_insert(tag_alloc_table, &tag_alloc_node->hmap_node,
hash_string(parent_name, 0));
return tag_alloc_node;
}
static void
tag_alloc_add_existing_tags(struct hmap *tag_alloc_table,
const struct nbrec_logical_switch_port *nbsp)
{
/* Add the tags of already existing nested containers. If there is no
* 'nbsp->parent_name' or no 'nbsp->tag' set, there is nothing to do. */
if (!nbsp->parent_name || !nbsp->parent_name[0] || !nbsp->tag) {
return;
}
struct tag_alloc_node *tag_alloc_node;
tag_alloc_node = tag_alloc_get_node(tag_alloc_table, nbsp->parent_name);
bitmap_set1(tag_alloc_node->allocated_tags, *nbsp->tag);
}
static void
tag_alloc_create_new_tag(struct hmap *tag_alloc_table,
const struct nbrec_logical_switch_port *nbsp)
{
if (!nbsp->tag_request) {
return;
}
if (nbsp->parent_name && nbsp->parent_name[0]
&& *nbsp->tag_request == 0) {
/* For nested containers that need allocation, do the allocation. */
if (nbsp->tag) {
/* This has already been allocated. */
return;
}
struct tag_alloc_node *tag_alloc_node;
int64_t tag;
tag_alloc_node = tag_alloc_get_node(tag_alloc_table,
nbsp->parent_name);
tag = bitmap_scan(tag_alloc_node->allocated_tags, 0, 1, MAX_OVN_TAGS);
if (tag == MAX_OVN_TAGS) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_ERR_RL(&rl, "out of vlans for logical switch ports with "
"parent %s", nbsp->parent_name);
return;
}
bitmap_set1(tag_alloc_node->allocated_tags, tag);
nbrec_logical_switch_port_set_tag(nbsp, &tag, 1);
} else if (*nbsp->tag_request != 0) {
/* For everything else, copy the contents of 'tag_request' to 'tag'. */
nbrec_logical_switch_port_set_tag(nbsp, nbsp->tag_request, 1);
}
}
/*
* This function checks if the MAC in "address" parameter (if present) is
* different from the one stored in Logical_Switch_Port.dynamic_addresses
* and updates it.
*/
static void
check_and_update_mac_in_dynamic_addresses(
const char *address,
const struct nbrec_logical_switch_port *nbsp)
{
if (!nbsp->dynamic_addresses) {
return;
}
int buf_index = 0;
struct eth_addr ea;
if (!ovs_scan_len(address, &buf_index,
ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(ea))) {
return;
}
struct eth_addr present_ea;
buf_index = 0;
if (ovs_scan_len(nbsp->dynamic_addresses, &buf_index,
ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(present_ea))
&& !eth_addr_equals(ea, present_ea)) {
/* MAC address has changed. Update it */
char *new_addr = xasprintf(
ETH_ADDR_FMT"%s", ETH_ADDR_ARGS(ea),
 ->dynamic_addresses[buf_index]);
nbrec_logical_switch_port_set_dynamic_addresses(
nbsp, new_addr);
free(new_addr);
}
}
static void
join_logical_ports(struct northd_context *ctx,
struct hmap *datapaths, struct hmap *ports,
struct hmap *chassis_qdisc_queues,
struct hmap *tag_alloc_table, struct ovs_list *sb_only,
struct ovs_list *nb_only, struct ovs_list *both)
{
hmap_init(ports);
ovs_list_init(sb_only);
ovs_list_init(nb_only);
ovs_list_init(both);
const struct sbrec_port_binding *sb;
SBREC_PORT_BINDING_FOR_EACH (sb, ctx->ovnsb_idl) {
struct ovn_port *op = ovn_port_create(ports, sb->logical_port,
NULL, NULL, sb);
ovs_list_push_back(sb_only, &op->list);
}
struct ovn_datapath *od;
HMAP_FOR_EACH (od, key_node, datapaths) {
if (od->nbs) {
for (size_t i = 0; i < od->nbs->n_ports; i++) {
const struct nbrec_logical_switch_port *nbsp
= od->nbs->ports[i];
struct ovn_port *op = ovn_port_find(ports, nbsp->name);
if (op) {
if (op->nbsp || op->nbrp) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "duplicate logical port %s",
nbsp->name);
continue;
}
op->nbsp = nbsp;
ovs_list_remove(&op->list);
uint32_t queue_id = smap_get_int(&op->sb->options,
"qdisc_queue_id", 0);
if (queue_id && op->sb->chassis) {
add_chassis_queue(
chassis_qdisc_queues, &op->sb->chassis->header_.uuid,
queue_id);
}
ovs_list_push_back(both, &op->list);
/* This port exists due to a SB binding, but should
* not have been initialized fully. */
ovs_assert(!op->n_lsp_addrs && !op->n_ps_addrs);
} else {
op = ovn_port_create(ports, nbsp->name, nbsp, NULL, NULL);
ovs_list_push_back(nb_only, &op->list);
}
if (!strcmp(nbsp->type, "localnet")) {
od->localnet_port = op;
}
op->lsp_addrs
= xmalloc(sizeof *op->lsp_addrs * nbsp->n_addresses);
for (size_t j = 0; j < nbsp->n_addresses; j++) {
if (!strcmp(nbsp->addresses[j], "unknown")
|| !strcmp(nbsp->addresses[j], "router")) {
continue;
}
if (is_dynamic_lsp_address(nbsp->addresses[j])) {
if (nbsp->dynamic_addresses) {
check_and_update_mac_in_dynamic_addresses(
nbsp->addresses[j], nbsp);
if (!extract_lsp_addresses(nbsp->dynamic_addresses,
&op->lsp_addrs[op->n_lsp_addrs])) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_INFO_RL(&rl, "invalid syntax '%s' in "
"logical switch port "
"dynamic_addresses. No "
"MAC address found",
op->nbsp->dynamic_addresses);
continue;
}
} else {
continue;
}
} else if (!extract_lsp_addresses(nbsp->addresses[j],
&op->lsp_addrs[op->n_lsp_addrs])) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_INFO_RL(&rl, "invalid syntax '%s' in logical "
"switch port addresses. No MAC "
"address found",
op->nbsp->addresses[j]);
continue;
}
op->n_lsp_addrs++;
}
op->ps_addrs
= xmalloc(sizeof *op->ps_addrs * nbsp->n_port_security);
for (size_t j = 0; j < nbsp->n_port_security; j++) {
if (!extract_lsp_addresses(nbsp->port_security[j],
&op->ps_addrs[op->n_ps_addrs])) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_INFO_RL(&rl, "invalid syntax '%s' in port "
"security. No MAC address found",
op->nbsp->port_security[j]);
continue;
}
op->n_ps_addrs++;
}
op->od = od;
ipam_add_port_addresses(od, op);
tag_alloc_add_existing_tags(tag_alloc_table, nbsp);
}
} else {
for (size_t i = 0; i < od->nbr->n_ports; i++) {
const struct nbrec_logical_router_port *nbrp
= od->nbr->ports[i];
struct lport_addresses lrp_networks;
if (!extract_lrp_networks(nbrp, &lrp_networks)) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad 'mac' %s", nbrp->mac);
continue;
}
if (!lrp_networks.n_ipv4_addrs && !lrp_networks.n_ipv6_addrs) {
continue;
}
struct ovn_port *op = ovn_port_find(ports, nbrp->name);
if (op) {
if (op->nbsp || op->nbrp) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "duplicate logical router port %s",
nbrp->name);
continue;
}
op->nbrp = nbrp;
ovs_list_remove(&op->list);
ovs_list_push_back(both, &op->list);
/* This port exists but should not have been
* initialized fully. */
ovs_assert(!op->lrp_networks.n_ipv4_addrs
&& !op->lrp_networks.n_ipv6_addrs);
} else {
op = ovn_port_create(ports, nbrp->name, NULL, nbrp, NULL);
ovs_list_push_back(nb_only, &op->list);
}
op->lrp_networks = lrp_networks;
op->od = od;
ipam_add_port_addresses(op->od, op);
const char *redirect_chassis = smap_get(&op->nbrp->options,
"redirect-chassis");
if (redirect_chassis || op->nbrp->n_gateway_chassis) {
/* Additional "derived" ovn_port crp represents the
* instance of op on the "redirect-chassis". */
const char *gw_chassis = smap_get(&op->od->nbr->options,
"chassis");
if (gw_chassis) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "Bad configuration: "
"redirect-chassis configured on port %s "
"on L3 gateway router", nbrp->name);
continue;
}
if (od->l3dgw_port || od->l3redirect_port) {
static struct vlog_rate_limit rl
= VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "Bad configuration: multiple ports "
"with redirect-chassis on same logical "
"router %s", od->nbr->name);
continue;
}
char *redirect_name = chassis_redirect_name(nbrp->name);
struct ovn_port *crp = ovn_port_find(ports, redirect_name);
if (crp) {
crp->derived = true;
crp->nbrp = nbrp;
ovs_list_remove(&crp->list);
ovs_list_push_back(both, &crp->list);
} else {
crp = ovn_port_create(ports, redirect_name,
NULL, nbrp, NULL);
crp->derived = true;
ovs_list_push_back(nb_only, &crp->list);
}
crp->od = od;
free(redirect_name);
/* Set l3dgw_port and l3redirect_port in od, for later
* use during flow creation. */
od->l3dgw_port = op;
od->l3redirect_port = crp;
}
}
}
}
/* Connect logical router ports, and logical switch ports of type "router",
* to their peers. */
struct ovn_port *op;
HMAP_FOR_EACH (op, key_node, ports) {
if (op->nbsp && !strcmp(op->nbsp->type, "router") && !op->derived) {
const char *peer_name = smap_get(&op->nbsp->options, "router-port");
if (!peer_name) {
continue;
}
struct ovn_port *peer = ovn_port_find(ports, peer_name);
if (!peer || !peer->nbrp) {
continue;
}
peer->peer = op;
op->peer = peer;
op->od->router_ports = xrealloc(
op->od->router_ports,
sizeof *op->od->router_ports * (op->od->n_router_ports + 1));
op->od->router_ports[op->od->n_router_ports++] = op;
/* Fill op->lsp_addrs for op->nbsp->addresses[] with
* contents "router", which was skipped in the loop above. */
for (size_t j = 0; j < op->nbsp->n_addresses; j++) {
if (!strcmp(op->nbsp->addresses[j], "router")) {
if (extract_lrp_networks(peer->nbrp,
&op->lsp_addrs[op->n_lsp_addrs])) {
op->n_lsp_addrs++;
}
break;
}
}
} else if (op->nbrp && op->nbrp->peer && !op->derived) {
struct ovn_port *peer = ovn_port_find(ports, op->nbrp->peer);
if (peer) {
if (peer->nbrp) {
op->peer = peer;
} else if (peer->nbsp) {
/* An ovn_port for a switch port of type "router" does have
* a router port as its peer (see the case above for
* "router" ports), but this is set via options:router-port
* in Logical_Switch_Port and does not involve the
* Logical_Router_Port's 'peer' column. */
static struct vlog_rate_limit rl =
VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "Bad configuration: The peer of router "
"port %s is a switch port", op->key);
}
}
}
}
}
static void
ip_address_and_port_from_lb_key(const char *key, char **ip_address,
uint16_t *port);
static void
get_router_load_balancer_ips(const struct ovn_datapath *od,
struct sset *all_ips)
{
if (!od->nbr) {
return;
}
for (int i = 0; i < od->nbr->n_load_balancer; i++) {
struct nbrec_load_balancer *lb = od->nbr->load_balancer[i];
struct smap *vips = &lb->vips;
struct smap_node *node;
SMAP_FOR_EACH (node, vips) {
/* node->key contains IP:port or just IP. */
char *ip_address = NULL;
uint16_t port;
ip_address_and_port_from_lb_key(node->key, &ip_address, &port);
if (!ip_address) {
continue;
}
if (!sset_contains(all_ips, ip_address)) {
sset_add(all_ips, ip_address);
}
free(ip_address);
}
}
}
/* Returns an array of strings, each consisting of a MAC address followed
* by one or more IP addresses, and if the port is a distributed gateway
* port, followed by 'is_chassis_resident("LPORT_NAME")', where the
* LPORT_NAME is the name of the L3 redirect port or the name of the
* logical_port specified in a NAT rule. These strings include the
* external IP addresses of all NAT rules defined on that router, and all
* of the IP addresses used in load balancer VIPs defined on that router.
*
* The caller must free each of the n returned strings with free(),
* and must free the returned array when it is no longer needed. */
static char **
get_nat_addresses(const struct ovn_port *op, size_t *n)
{
size_t n_nats = 0;
struct eth_addr mac;
if (!op->nbrp || !op->od || !op->od->nbr
|| (!op->od->nbr->n_nat && !op->od->nbr->n_load_balancer)
|| !eth_addr_from_string(op->nbrp->mac, &mac)) {
*n = n_nats;
return NULL;
}
struct ds c_addresses = DS_EMPTY_INITIALIZER;
ds_put_format(&c_addresses, ETH_ADDR_FMT, ETH_ADDR_ARGS(mac));
bool central_ip_address = false;
char **addresses;
addresses = xmalloc(sizeof *addresses * (op->od->nbr->n_nat + 1));
/* Get NAT IP addresses. */
for (size_t i = 0; i < op->od->nbr->n_nat; i++) {
const struct nbrec_nat *nat = op->od->nbr->nat[i];
ovs_be32 ip, mask;
char *error = ip_parse_masked(nat->external_ip, &ip, &mask);
if (error || mask != OVS_BE32_MAX) {
free(error);
continue;
}
/* Determine whether this NAT rule satisfies the conditions for
* distributed NAT processing. */
if (op->od->l3redirect_port && !strcmp(nat->type, "dnat_and_snat")
&& nat->logical_port && nat->external_mac) {
/* Distributed NAT rule. */
if (eth_addr_from_string(nat->external_mac, &mac)) {
struct ds address = DS_EMPTY_INITIALIZER;
ds_put_format(&address, ETH_ADDR_FMT, ETH_ADDR_ARGS(mac));
ds_put_format(&address, " %s", nat->external_ip);
ds_put_format(&address, " is_chassis_resident(\"%s\")",
nat->logical_port);
addresses[n_nats++] = ds_steal_cstr(&address);
}
} else {
/* Centralized NAT rule, either on gateway router or distributed
* router. */
ds_put_format(&c_addresses, " %s", nat->external_ip);
central_ip_address = true;
}
}
/* A set to hold all load-balancer vips. */
struct sset all_ips = SSET_INITIALIZER(&all_ips);
get_router_load_balancer_ips(op->od, &all_ips);
const char *ip_address;
SSET_FOR_EACH (ip_address, &all_ips) {
ds_put_format(&c_addresses, " %s", ip_address);
central_ip_address = true;
}
sset_destroy(&all_ips);
if (central_ip_address) {
/* Gratuitous ARP for centralized NAT rules on distributed gateway
* ports should be restricted to the "redirect-chassis". */
if (op->od->l3redirect_port) {
ds_put_format(&c_addresses, " is_chassis_resident(%s)",
op->od->l3redirect_port->json_key);
}
addresses[n_nats++] = ds_steal_cstr(&c_addresses);
}
*n = n_nats;
return addresses;
}
static bool
gateway_chassis_equal(const struct nbrec_gateway_chassis *nb_gwc,
const struct sbrec_chassis *nb_gwc_c,
const struct sbrec_gateway_chassis *sb_gwc)
{
bool equal = !strcmp(nb_gwc->name, sb_gwc->name)
&& nb_gwc->priority == sb_gwc->priority
&& smap_equal(&nb_gwc->options, &sb_gwc->options)
&& smap_equal(&nb_gwc->external_ids, &sb_gwc->external_ids);
if (!equal) {
return false;
}
/* If everything else matched and we were unable to find the SBDB
* Chassis entry at this time, assume a match and return true.
* This happens when an ovn-controller is restarting and the Chassis
* entry is gone away momentarily */
return !nb_gwc_c
|| (sb_gwc->chassis && !strcmp(nb_gwc_c->name,
sb_gwc->chassis->name));
}
static bool
sbpb_gw_chassis_needs_update(
const struct sbrec_port_binding *port_binding,
const struct nbrec_logical_router_port *lrp,
const struct chassis_index *chassis_index)
{
if (!lrp || !port_binding) {
return false;
}
/* These arrays are used to collect valid Gateway_Chassis and valid
* Chassis records from the Logical_Router_Port Gateway_Chassis list,
* we ignore the ones we can't match on the SBDB */
struct nbrec_gateway_chassis **lrp_gwc = xzalloc(lrp->n_gateway_chassis *
sizeof *lrp_gwc);
const struct sbrec_chassis **lrp_gwc_c = xzalloc(lrp->n_gateway_chassis *
sizeof *lrp_gwc_c);
/* Count the number of gateway chassis chassis names from the logical
* router port that we are able to match on the southbound database */
int lrp_n_gateway_chassis = 0;
int n;
for (n = 0; n < lrp->n_gateway_chassis; n++) {
if (!lrp->gateway_chassis[n]->chassis_name) {
continue;
}
const struct sbrec_chassis *chassis =
chassis_lookup_by_name(chassis_index,
lrp->gateway_chassis[n]->chassis_name);
lrp_gwc_c[lrp_n_gateway_chassis] = chassis;
lrp_gwc[lrp_n_gateway_chassis] = lrp->gateway_chassis[n];
lrp_n_gateway_chassis++;
if (!chassis) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(
&rl, "Chassis name %s referenced in NBDB via Gateway_Chassis "
"on logical router port %s does not exist in SBDB",
lrp->gateway_chassis[n]->chassis_name, lrp->name);
}
}
/* Basic check, different amount of Gateway_Chassis means that we
* need to update southbound database Port_Binding */
if (lrp_n_gateway_chassis != port_binding->n_gateway_chassis) {
free(lrp_gwc_c);
free(lrp_gwc);
return true;
}
for (n = 0; n < lrp_n_gateway_chassis; n++) {
int i;
/* For each of the valid gw chassis on the lrp, check if there's
* a match on the Port_Binding list, we assume order is not
* persisted */
for (i = 0; i < port_binding->n_gateway_chassis; i++) {
if (gateway_chassis_equal(lrp_gwc[n],
lrp_gwc_c[n],
port_binding->gateway_chassis[i])) {
break; /* we found a match */
}
}
/* if no Port_Binding gateway chassis matched for the entry... */
if (i == port_binding->n_gateway_chassis) {
free(lrp_gwc_c);
free(lrp_gwc);
return true; /* found no match for this gateway chassis on lrp */
}
}
/* no need for update, all ports matched */
free(lrp_gwc_c);
free(lrp_gwc);
return false;
}
/* This functions translates the gw chassis on the nb database
* to sb database entries, the only difference is that SB database
* Gateway_Chassis table references the chassis directly instead
* of using the name */
static void
copy_gw_chassis_from_nbrp_to_sbpb(
struct northd_context *ctx,
const struct nbrec_logical_router_port *lrp,
const struct chassis_index *chassis_index,
const struct sbrec_port_binding *port_binding) {
if (!lrp || !port_binding || !lrp->n_gateway_chassis) {
return;
}
struct sbrec_gateway_chassis **gw_chassis = NULL;
int n_gwc = 0;
int n;
/* XXX: This can be improved. This code will generate a set of new
* Gateway_Chassis and push them all in a single transaction, instead
* this would be more optimal if we just add/update/remove the rows in
* the southbound db that need to change. We don't expect lots of
* changes to the Gateway_Chassis table, but if that proves to be wrong
* we should optimize this. */
for (n = 0; n < lrp->n_gateway_chassis; n++) {
struct nbrec_gateway_chassis *lrp_gwc = lrp->gateway_chassis[n];
if (!lrp_gwc->chassis_name) {
continue;
}
const struct sbrec_chassis *chassis =
chassis_lookup_by_name(chassis_index, lrp_gwc->chassis_name);
gw_chassis = xrealloc(gw_chassis, (n_gwc + 1) * sizeof *gw_chassis);
struct sbrec_gateway_chassis *pb_gwc =
sbrec_gateway_chassis_insert(ctx->ovnsb_txn);
sbrec_gateway_chassis_set_name(pb_gwc, lrp_gwc->name);
sbrec_gateway_chassis_set_priority(pb_gwc, lrp_gwc->priority);
sbrec_gateway_chassis_set_chassis(pb_gwc, chassis);
sbrec_gateway_chassis_set_options(pb_gwc, &lrp_gwc->options);
sbrec_gateway_chassis_set_external_ids(pb_gwc, &lrp_gwc->external_ids);
gw_chassis[n_gwc++] = pb_gwc;
}
sbrec_port_binding_set_gateway_chassis(port_binding, gw_chassis, n_gwc);
free(gw_chassis);
}
static void
ovn_port_update_sbrec(struct northd_context *ctx,
const struct ovn_port *op,
const struct chassis_index *chassis_index,
struct hmap *chassis_qdisc_queues)
{
sbrec_port_binding_set_datapath(op->sb, op->od->sb);
if (op->nbrp) {
/* If the router is for l3 gateway, it resides on a chassis
* and its port type is "l3gateway". */
const char *chassis = smap_get(&op->od->nbr->options, "chassis");
if (op->derived) {
sbrec_port_binding_set_type(op->sb, "chassisredirect");
} else if (chassis) {
sbrec_port_binding_set_type(op->sb, "l3gateway");
} else {
sbrec_port_binding_set_type(op->sb, "patch");
}
struct smap new;
smap_init(&new);
if (op->derived) {
const char *redirect_chassis = smap_get(&op->nbrp->options,
"redirect-chassis");
if (op->nbrp->n_gateway_chassis && redirect_chassis) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(
&rl, "logical router port %s has both options:"
"redirect-chassis and gateway_chassis populated "
"redirect-chassis will be ignored in favour of "
"gateway chassis", op->nbrp->name);
}
if (op->nbrp->n_gateway_chassis) {
if (sbpb_gw_chassis_needs_update(op->sb, op->nbrp,
chassis_index)) {
copy_gw_chassis_from_nbrp_to_sbpb(ctx, op->nbrp,
chassis_index, op->sb);
}
} else if (redirect_chassis) {
/* Handle ports that had redirect-chassis option attached
* to them, and for backwards compatibility convert them
* to a single Gateway_Chassis entry */
const struct sbrec_chassis *chassis =
chassis_lookup_by_name(chassis_index, redirect_chassis);
if (chassis) {
/* If we found the chassis, and the gw chassis on record
* differs from what we expect go ahead and update */
if (op->sb->n_gateway_chassis !=1
|| strcmp(op->sb->gateway_chassis[0]->chassis->name,
chassis->name)
|| op->sb->gateway_chassis[0]->priority != 0) {
/* Construct a single Gateway_Chassis entry on the
* Port_Binding attached to the redirect_chassis
* name */
struct sbrec_gateway_chassis *gw_chassis =
sbrec_gateway_chassis_insert(ctx->ovnsb_txn);
char *gwc_name = xasprintf("%s_%s", op->nbrp->name,
chassis->name);
/* XXX: Again, here, we could just update an existing
* Gateway_Chassis, instead of creating a new one
* and replacing it */
sbrec_gateway_chassis_set_name(gw_chassis, gwc_name);
sbrec_gateway_chassis_set_priority(gw_chassis, 0);
sbrec_gateway_chassis_set_chassis(gw_chassis, chassis);
sbrec_gateway_chassis_set_external_ids(gw_chassis,
&op->nbrp->external_ids);
sbrec_port_binding_set_gateway_chassis(op->sb,
&gw_chassis, 1);
free(gwc_name);
}
} else {
VLOG_WARN("chassis name '%s' from redirect from logical "
" router port '%s' redirect-chassis not found",
redirect_chassis, op->nbrp->name);
if (op->sb->n_gateway_chassis) {
sbrec_port_binding_set_gateway_chassis(op->sb, NULL,
0);
}
}
}
smap_add(&new, "distributed-port", op->nbrp->name);
} else {
const char *peer = op->peer ? op->peer->key : "<error>";
smap_add(&new, "peer", peer);
if (chassis) {
smap_add(&new, "l3gateway-chassis", chassis);
}
}
sbrec_port_binding_set_options(op->sb, &new);
smap_destroy(&new);
sbrec_port_binding_set_parent_port(op->sb, NULL);
sbrec_port_binding_set_tag(op->sb, NULL, 0);
sbrec_port_binding_set_mac(op->sb, NULL, 0);
struct smap ids = SMAP_INITIALIZER(&ids);
sbrec_port_binding_set_external_ids(op->sb, &ids);
} else {
if (strcmp(op->nbsp->type, "router")) {
uint32_t queue_id = smap_get_int(
&op->sb->options, "qdisc_queue_id", 0);
bool has_qos = port_has_qos_params(&op->nbsp->options);
struct smap options;
if (op->sb->chassis && has_qos && !queue_id) {
queue_id = allocate_chassis_queueid(chassis_qdisc_queues,
op->sb->chassis);
} else if (!has_qos && queue_id) {
free_chassis_queueid(chassis_qdisc_queues,
op->sb->chassis,
queue_id);
queue_id = 0;
}
smap_clone(&options, &op->nbsp->options);
if (queue_id) {
smap_add_format(&options,
"qdisc_queue_id", "%d", queue_id);
}
sbrec_port_binding_set_options(op->sb, &options);
smap_destroy(&options);
sbrec_port_binding_set_type(op->sb, op->nbsp->type);
} else {
const char *chassis = NULL;
if (op->peer && op->peer->od && op->peer->od->nbr) {
chassis = smap_get(&op->peer->od->nbr->options, "chassis");
}
/* A switch port connected to a gateway router is also of
* type "l3gateway". */
if (chassis) {
sbrec_port_binding_set_type(op->sb, "l3gateway");
} else {
sbrec_port_binding_set_type(op->sb, "patch");
}
const char *router_port = smap_get_def(&op->nbsp->options,
"router-port", "<error>");
struct smap new;
smap_init(&new);
smap_add(&new, "peer", router_port);
if (chassis) {
smap_add(&new, "l3gateway-chassis", chassis);
}
sbrec_port_binding_set_options(op->sb, &new);
smap_destroy(&new);
const char *nat_addresses = smap_get(&op->nbsp->options,
"nat-addresses");
if (nat_addresses && !strcmp(nat_addresses, "router")) {
if (op->peer && op->peer->od
&& (chassis || op->peer->od->l3redirect_port)) {
size_t n_nats;
char **nats = get_nat_addresses(op->peer, &n_nats);
if (n_nats) {
sbrec_port_binding_set_nat_addresses(op->sb,
(const char **) nats, n_nats);
for (size_t i = 0; i < n_nats; i++) {
free(nats[i]);
}
free(nats);
} else {
sbrec_port_binding_set_nat_addresses(op->sb, NULL, 0);
}
} else {
sbrec_port_binding_set_nat_addresses(op->sb, NULL, 0);
}
/* Only accept manual specification of ethernet address
* followed by IPv4 addresses on type "l3gateway" ports. */
} else if (nat_addresses && chassis) {
struct lport_addresses laddrs;
if (!extract_lsp_addresses(nat_addresses, &laddrs)) {
static struct vlog_rate_limit rl =
VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_WARN_RL(&rl, "Error extracting nat-addresses.");
sbrec_port_binding_set_nat_addresses(op->sb, NULL, 0);
} else {
sbrec_port_binding_set_nat_addresses(op->sb,
&nat_addresses, 1);
destroy_lport_addresses(&laddrs);
}
} else {
sbrec_port_binding_set_nat_addresses(op->sb, NULL, 0);
}
}
sbrec_port_binding_set_parent_port(op->sb, op->nbsp->parent_name);
sbrec_port_binding_set_tag(op->sb, op->nbsp->tag, op->nbsp->n_tag);
sbrec_port_binding_set_mac(op->sb, (const char **) op->nbsp->addresses,
op->nbsp->n_addresses);
struct smap ids = SMAP_INITIALIZER(&ids);
smap_clone(&ids, &op->nbsp->external_ids);
const char *name = smap_get(&ids, "neutron:port_name");
if (name && name[0]) {
smap_add(&ids, "name", name);
}
sbrec_port_binding_set_external_ids(op->sb, &ids);
smap_destroy(&ids);
}
}
/* Remove mac_binding entries that refer to logical_ports which are
* deleted. */
static void
cleanup_mac_bindings(struct northd_context *ctx, struct hmap *ports)
{
const struct sbrec_mac_binding *b, *n;
SBREC_MAC_BINDING_FOR_EACH_SAFE (b, n, ctx->ovnsb_idl) {
if (!ovn_port_find(ports, b->logical_port)) {
sbrec_mac_binding_delete(b);
}
}
}
/* Updates the southbound Port_Binding table so that it contains the logical
* switch ports specified by the northbound database.
*
* Initializes 'ports' to contain a "struct ovn_port" for every logical port,
* using the "struct ovn_datapath"s in 'datapaths' to look up logical
* datapaths. */
static void
build_ports(struct northd_context *ctx, struct hmap *datapaths,
const struct chassis_index *chassis_index, struct hmap *ports)
{
struct ovs_list sb_only, nb_only, both;
struct hmap tag_alloc_table = HMAP_INITIALIZER(&tag_alloc_table);
struct hmap chassis_qdisc_queues = HMAP_INITIALIZER(&chassis_qdisc_queues);
join_logical_ports(ctx, datapaths, ports, &chassis_qdisc_queues,
&tag_alloc_table, &sb_only, &nb_only, &both);
struct ovn_port *op, *next;
/* For logical ports that are in both databases, update the southbound
* record based on northbound data. Also index the in-use tunnel_keys.
* For logical ports that are in NB database, do any tag allocation
* needed. */
LIST_FOR_EACH_SAFE (op, next, list, &both) {
if (op->nbsp) {
tag_alloc_create_new_tag(&tag_alloc_table, op->nbsp);
}
ovn_port_update_sbrec(ctx, op, chassis_index, &chassis_qdisc_queues);
add_tnlid(&op->od->port_tnlids, op->sb->tunnel_key);
if (op->sb->tunnel_key > op->od->port_key_hint) {
op->od->port_key_hint = op->sb->tunnel_key;
}
}
/* Add southbound record for each unmatched northbound record. */
LIST_FOR_EACH_SAFE (op, next, list, &nb_only) {
uint16_t tunnel_key = ovn_port_allocate_key(op->od);
if (!tunnel_key) {
continue;
}
op->sb = sbrec_port_binding_insert(ctx->ovnsb_txn);
ovn_port_update_sbrec(ctx, op, chassis_index, &chassis_qdisc_queues);
sbrec_port_binding_set_logical_port(op->sb, op->key);
sbrec_port_binding_set_tunnel_key(op->sb, tunnel_key);
}
bool remove_mac_bindings = false;
if (!ovs_list_is_empty(&sb_only)) {
remove_mac_bindings = true;
}
/* Delete southbound records without northbound matches. */
LIST_FOR_EACH_SAFE(op, next, list, &sb_only) {
ovs_list_remove(&op->list);
sbrec_port_binding_delete(op->sb);
ovn_port_destroy(ports, op);
}
if (remove_mac_bindings) {
cleanup_mac_bindings(ctx, ports);
}
tag_alloc_destroy(&tag_alloc_table);
destroy_chassis_queues(&chassis_qdisc_queues);
}
#define OVN_MIN_MULTICAST 32768
#define OVN_MAX_MULTICAST 65535
struct multicast_group {
const char *name;
uint16_t key; /* OVN_MIN_MULTICAST...OVN_MAX_MULTICAST. */
};
#define MC_FLOOD "_MC_flood"
static const struct multicast_group mc_flood = { MC_FLOOD, 65535 };
#define MC_UNKNOWN "_MC_unknown"
static const struct multicast_group mc_unknown = { MC_UNKNOWN, 65534 };
static bool
multicast_group_equal(const struct multicast_group *a,
const struct multicast_group *b)
{
return !strcmp(a->name, b->name) && a->key == b->key;
}
/* Multicast group entry. */
struct ovn_multicast {
struct hmap_node hmap_node; /* Index on 'datapath' and 'key'. */
struct ovn_datapath *datapath;
const struct multicast_group *group;
struct ovn_port **ports;
size_t n_ports, allocated_ports;
};
static uint32_t
ovn_multicast_hash(const struct ovn_datapath *datapath,
const struct multicast_group *group)
{
return hash_pointer(datapath, group->key);
}
static struct ovn_multicast *
ovn_multicast_find(struct hmap *mcgroups, struct ovn_datapath *datapath,
const struct multicast_group *group)
{
struct ovn_multicast *mc;
HMAP_FOR_EACH_WITH_HASH (mc, hmap_node,
ovn_multicast_hash(datapath, group), mcgroups) {
if (mc->datapath == datapath
&& multicast_group_equal(mc->group, group)) {
return mc;
}
}
return NULL;
}
static void
ovn_multicast_add(struct hmap *mcgroups, const struct multicast_group *group,
struct ovn_port *port)
{
struct ovn_datapath *od = port->od;
struct ovn_multicast *mc = ovn_multicast_find(mcgroups, od, group);
if (!mc) {
mc = xmalloc(sizeof *mc);
hmap_insert(mcgroups, &mc->hmap_node, ovn_multicast_hash(od, group));
mc->datapath = od;
mc->group = group;
mc->n_ports = 0;
mc->allocated_ports = 4;
mc->ports = xmalloc(mc->allocated_ports * sizeof *mc->ports);
}
if (mc->n_ports >= mc->allocated_ports) {
mc->ports = x2nrealloc(mc->ports, &mc->allocated_ports,
sizeof *mc->ports);
}
mc->ports[mc->n_ports++] = port;
}
static void
ovn_multicast_destroy(struct hmap *mcgroups, struct ovn_multicast *mc)
{
if (mc) {
hmap_remove(mcgroups, &mc->hmap_node);
free(mc->ports);
free(mc);
}
}
static void
ovn_multicast_update_sbrec(const struct ovn_multicast *mc,
const struct sbrec_multicast_group *sb)
{
struct sbrec_port_binding **ports = xmalloc(mc->n_ports * sizeof *ports);
for (size_t i = 0; i < mc->n_ports; i++) {
ports[i] = CONST_CAST(struct sbrec_port_binding *, mc->ports[i]->sb);
}
sbrec_multicast_group_set_ports(sb, ports, mc->n_ports);
free(ports);
}
/* Logical flow generation.
*
* This code generates the Logical_Flow table in the southbound database, as a
* function of most of the northbound database.
*/
struct ovn_lflow {
struct hmap_node hmap_node;
struct ovn_datapath *od;
enum ovn_stage stage;
uint16_t priority;
char *match;
char *actions;
char *stage_hint;
const char *where;
};
static size_t
ovn_lflow_hash(const struct ovn_lflow *lflow)
{
size_t hash = uuid_hash(&lflow->od->key);
hash = hash_2words((lflow->stage << 16) | lflow->priority, hash);
hash = hash_string(lflow->match, hash);
return hash_string(lflow->actions, hash);
}
static bool
ovn_lflow_equal(const struct ovn_lflow *a, const struct ovn_lflow *b)
{
return (a->od == b->od
&& a->stage == b->stage
&& a->priority == b->priority
&& !strcmp(a->match, b->match)
&& !strcmp(a->actions, b->actions));
}
static void
ovn_lflow_init(struct ovn_lflow *lflow, struct ovn_datapath *od,
enum ovn_stage stage, uint16_t priority,
char *match, char *actions, char *stage_hint,
const char *where)
{
lflow->od = od;
lflow->stage = stage;
lflow->priority = priority;
lflow->match = match;
lflow->actions = actions;
lflow->stage_hint = stage_hint;
lflow->where = where;
}
/* Adds a row with the specified contents to the Logical_Flow table. */
static void
ovn_lflow_add_at(struct hmap *lflow_map, struct ovn_datapath *od,
enum ovn_stage stage, uint16_t priority,
const char *match, const char *actions,
const char *stage_hint, const char *where)
{
ovs_assert(ovn_stage_to_datapath_type(stage) == ovn_datapath_get_type(od));
struct ovn_lflow *lflow = xmalloc(sizeof *lflow);
ovn_lflow_init(lflow, od, stage, priority,
xstrdup(match), xstrdup(actions),
nullable_xstrdup(stage_hint), where);
hmap_insert(lflow_map, &lflow->hmap_node, ovn_lflow_hash(lflow));
}
/* Adds a row with the specified contents to the Logical_Flow table. */
#define ovn_lflow_add_with_hint(LFLOW_MAP, OD, STAGE, PRIORITY, MATCH, \
ACTIONS, STAGE_HINT) \
ovn_lflow_add_at(LFLOW_MAP, OD, STAGE, PRIORITY, MATCH, ACTIONS, \
STAGE_HINT, OVS_SOURCE_LOCATOR)
#define ovn_lflow_add(LFLOW_MAP, OD, STAGE, PRIORITY, MATCH, ACTIONS) \
ovn_lflow_add_with_hint(LFLOW_MAP, OD, STAGE, PRIORITY, MATCH, \
ACTIONS, NULL)
static struct ovn_lflow *
ovn_lflow_find(struct hmap *lflows, struct ovn_datapath *od,
enum ovn_stage stage, uint16_t priority,
const char *match, const char *actions)
{
struct ovn_lflow target;
ovn_lflow_init(&target, od, stage, priority,
CONST_CAST(char *, match), CONST_CAST(char *, actions),
NULL, NULL);
struct ovn_lflow *lflow;
HMAP_FOR_EACH_WITH_HASH (lflow, hmap_node, ovn_lflow_hash(&target),
lflows) {
if (ovn_lflow_equal(lflow, &target)) {
return lflow;
}
}
return NULL;
}
static void
ovn_lflow_destroy(struct hmap *lflows, struct ovn_lflow *lflow)
{
if (lflow) {
hmap_remove(lflows, &lflow->hmap_node);
free(lflow->match);
free(lflow->actions);
free(lflow->stage_hint);
free(lflow);
}
}
/* Appends port security constraints on L2 address field 'eth_addr_field'
* (e.g. "eth.src" or "eth.dst") to 'match'. 'ps_addrs', with 'n_ps_addrs'
* elements, is the collection of port_security constraints from an
* OVN_NB Logical_Switch_Port row generated by extract_lsp_addresses(). */
static void
build_port_security_l2(const char *eth_addr_field,
struct lport_addresses *ps_addrs,
unsigned int n_ps_addrs,
struct ds *match)
{
if (!n_ps_addrs) {
return;
}
ds_put_format(match, " && %s == {", eth_addr_field);
for (size_t i = 0; i < n_ps_addrs; i++) {
ds_put_format(match, "%s ", ps_addrs[i].ea_s);
}
ds_chomp(match, ' ');
ds_put_cstr(match, "}");
}
static void
build_port_security_ipv6_nd_flow(
struct ds *match, struct eth_addr ea, struct ipv6_netaddr *ipv6_addrs,
int n_ipv6_addrs)
{
ds_put_format(match, " && ip6 && nd && ((nd.sll == "ETH_ADDR_FMT" || "
"nd.sll == "ETH_ADDR_FMT") || ((nd.tll == "ETH_ADDR_FMT" || "
"nd.tll == "ETH_ADDR_FMT")", ETH_ADDR_ARGS(eth_addr_zero),
ETH_ADDR_ARGS(ea), ETH_ADDR_ARGS(eth_addr_zero),
ETH_ADDR_ARGS(ea));
if (!n_ipv6_addrs) {
ds_put_cstr(match, "))");
return;
}
char ip6_str[INET6_ADDRSTRLEN + 1];
struct in6_addr lla;
in6_generate_lla(ea, &lla);
memset(ip6_str, 0, sizeof(ip6_str));
ipv6_string_mapped(ip6_str, &lla);
ds_put_format(match, " && (nd.target == %s", ip6_str);
for(int i = 0; i < n_ipv6_addrs; i++) {
memset(ip6_str, 0, sizeof(ip6_str));
ipv6_string_mapped(ip6_str, &ipv6_addrs[i].addr);
ds_put_format(match, " || nd.target == %s", ip6_str);
}
ds_put_format(match, ")))");
}
static void
build_port_security_ipv6_flow(
enum ovn_pipeline pipeline, struct ds *match, struct eth_addr ea,
struct ipv6_netaddr *ipv6_addrs, int n_ipv6_addrs)
{
char ip6_str[INET6_ADDRSTRLEN + 1];
ds_put_format(match, " && %s == {",
pipeline == P_IN ? "ip6.src" : "ip6.dst");
/* Allow link-local address. */
struct in6_addr lla;
in6_generate_lla(ea, &lla);
ipv6_string_mapped(ip6_str, &lla);
ds_put_format(match, "%s, ", ip6_str);
/* Allow ip6.dst=ff00::/8 for multicast packets */
if (pipeline == P_OUT) {
ds_put_cstr(match, "ff00::/8, ");
}
for(int i = 0; i < n_ipv6_addrs; i++) {
ipv6_string_mapped(ip6_str, &ipv6_addrs[i].addr);
ds_put_format(match, "%s, ", ip6_str);
}
/* Replace ", " by "}". */
ds_chomp(match, ' ');
ds_chomp(match, ',');
ds_put_cstr(match, "}");
}
/**
* Build port security constraints on ARP and IPv6 ND fields
* and add logical flows to S_SWITCH_IN_PORT_SEC_ND stage.
*
* For each port security of the logical port, following
* logical flows are added
* - If the port security has no IP (both IPv4 and IPv6) or
* if it has IPv4 address(es)
* - Priority 90 flow to allow ARP packets for known MAC addresses
* in the eth.src and arp.spa fields. If the port security
* has IPv4 addresses, allow known IPv4 addresses in the arp.tpa field.
*
* - If the port security has no IP (both IPv4 and IPv6) or
* if it has IPv6 address(es)
* - Priority 90 flow to allow IPv6 ND packets for known MAC addresses
* in the eth.src and nd.sll/nd.tll fields. If the port security
* has IPv6 addresses, allow known IPv6 addresses in the nd.target field
* for IPv6 Neighbor Advertisement packet.
*
* - Priority 80 flow to drop ARP and IPv6 ND packets.
*/
static void
build_port_security_nd(struct ovn_port *op, struct hmap *lflows)
{
struct ds match = DS_EMPTY_INITIALIZER;
for (size_t i = 0; i < op->n_ps_addrs; i++) {
struct lport_addresses *ps = &op->ps_addrs[i];
bool no_ip = !(ps->n_ipv4_addrs || ps->n_ipv6_addrs);
ds_clear(&match);
if (ps->n_ipv4_addrs || no_ip) {
ds_put_format(&match,
"inport == %s && eth.src == %s && arp.sha == %s",
op->json_key, ps->ea_s, ps->ea_s);
if (ps->n_ipv4_addrs) {
ds_put_cstr(&match, " && arp.spa == {");
for (size_t j = 0; j < ps->n_ipv4_addrs; j++) {
/* When the netmask is applied, if the host portion is
* non-zero, the host can only use the specified
* address in the arp.spa. If zero, the host is allowed
* to use any address in the subnet. */
if (ps->ipv4_addrs[j].plen == 32
|| ps->ipv4_addrs[j].addr & ~ps->ipv4_addrs[j].mask) {
ds_put_cstr(&match, ps->ipv4_addrs[j].addr_s);
} else {
ds_put_format(&match, "%s/%d",
ps->ipv4_addrs[j].network_s,
ps->ipv4_addrs[j].plen);
}
ds_put_cstr(&match, ", ");
}
ds_chomp(&match, ' ');
ds_chomp(&match, ',');
ds_put_cstr(&match, "}");
}
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_PORT_SEC_ND, 90,
ds_cstr(&match), "next;");
}
if (ps->n_ipv6_addrs || no_ip) {
ds_clear(&match);
ds_put_format(&match, "inport == %s && eth.src == %s",
op->json_key, ps->ea_s);
build_port_security_ipv6_nd_flow(&match, ps->ea, ps->ipv6_addrs,
ps->n_ipv6_addrs);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_PORT_SEC_ND, 90,
ds_cstr(&match), "next;");
}
}
ds_clear(&match);
ds_put_format(&match, "inport == %s && (arp || nd)", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_PORT_SEC_ND, 80,
ds_cstr(&match), "drop;");
ds_destroy(&match);
}
/**
* Build port security constraints on IPv4 and IPv6 src and dst fields
* and add logical flows to S_SWITCH_(IN/OUT)_PORT_SEC_IP stage.
*
* For each port security of the logical port, following
* logical flows are added
* - If the port security has IPv4 addresses,
* - Priority 90 flow to allow IPv4 packets for known IPv4 addresses
*
* - If the port security has IPv6 addresses,
* - Priority 90 flow to allow IPv6 packets for known IPv6 addresses
*
* - If the port security has IPv4 addresses or IPv6 addresses or both
* - Priority 80 flow to drop all IPv4 and IPv6 traffic
*/
static void
build_port_security_ip(enum ovn_pipeline pipeline, struct ovn_port *op,
struct hmap *lflows)
{
char *port_direction;
enum ovn_stage stage;
if (pipeline == P_IN) {
port_direction = "inport";
stage = S_SWITCH_IN_PORT_SEC_IP;
} else {
port_direction = "outport";
stage = S_SWITCH_OUT_PORT_SEC_IP;
}
for (size_t i = 0; i < op->n_ps_addrs; i++) {
struct lport_addresses *ps = &op->ps_addrs[i];
if (!(ps->n_ipv4_addrs || ps->n_ipv6_addrs)) {
continue;
}
if (ps->n_ipv4_addrs) {
struct ds match = DS_EMPTY_INITIALIZER;
if (pipeline == P_IN) {
/* Permit use of the unspecified address for DHCP discovery */
struct ds dhcp_match = DS_EMPTY_INITIALIZER;
ds_put_format(&dhcp_match, "inport == %s"
" && eth.src == %s"
" && ip4.src == 0.0.0.0"
" && ip4.dst == 255.255.255.255"
" && udp.src == 68 && udp.dst == 67",
op->json_key, ps->ea_s);
ovn_lflow_add(lflows, op->od, stage, 90,
ds_cstr(&dhcp_match), "next;");
ds_destroy(&dhcp_match);
ds_put_format(&match, "inport == %s && eth.src == %s"
" && ip4.src == {", op->json_key,
ps->ea_s);
} else {
ds_put_format(&match, "outport == %s && eth.dst == %s"
" && ip4.dst == {255.255.255.255, 224.0.0.0/4, ",
op->json_key, ps->ea_s);
}
for (int j = 0; j < ps->n_ipv4_addrs; j++) {
ovs_be32 mask = ps->ipv4_addrs[j].mask;
/* When the netmask is applied, if the host portion is
* non-zero, the host can only use the specified
* address. If zero, the host is allowed to use any
* address in the subnet.
*/
if (ps->ipv4_addrs[j].plen == 32
|| ps->ipv4_addrs[j].addr & ~mask) {
ds_put_format(&match, "%s", ps->ipv4_addrs[j].addr_s);
if (pipeline == P_OUT && ps->ipv4_addrs[j].plen != 32) {
/* Host is also allowed to receive packets to the
* broadcast address in the specified subnet. */
ds_put_format(&match, ", %s",
ps->ipv4_addrs[j].bcast_s);
}
} else {
/* host portion is zero */
ds_put_format(&match, "%s/%d", ps->ipv4_addrs[j].network_s,
ps->ipv4_addrs[j].plen);
}
ds_put_cstr(&match, ", ");
}
/* Replace ", " by "}". */
ds_chomp(&match, ' ');
ds_chomp(&match, ',');
ds_put_cstr(&match, "}");
ovn_lflow_add(lflows, op->od, stage, 90, ds_cstr(&match), "next;");
ds_destroy(&match);
}
if (ps->n_ipv6_addrs) {
struct ds match = DS_EMPTY_INITIALIZER;
if (pipeline == P_IN) {
/* Permit use of unspecified address for duplicate address
* detection */
struct ds dad_match = DS_EMPTY_INITIALIZER;
ds_put_format(&dad_match, "inport == %s"
" && eth.src == %s"
" && ip6.src == ::"
" && ip6.dst == ff02::/16"
" && icmp6.type == {131, 135, 143}", op->json_key,
ps->ea_s);
ovn_lflow_add(lflows, op->od, stage, 90,
ds_cstr(&dad_match), "next;");
ds_destroy(&dad_match);
}
ds_put_format(&match, "%s == %s && %s == %s",
port_direction, op->json_key,
pipeline == P_IN ? "eth.src" : "eth.dst", ps->ea_s);
build_port_security_ipv6_flow(pipeline, &match, ps->ea,
ps->ipv6_addrs, ps->n_ipv6_addrs);
ovn_lflow_add(lflows, op->od, stage, 90,
ds_cstr(&match), "next;");
ds_destroy(&match);
}
char *match = xasprintf("%s == %s && %s == %s && ip",
port_direction, op->json_key,
pipeline == P_IN ? "eth.src" : "eth.dst",
ps->ea_s);
ovn_lflow_add(lflows, op->od, stage, 80, match, "drop;");
free(match);
}
}
static bool
lsp_is_enabled(const struct nbrec_logical_switch_port *lsp)
{
return !lsp->enabled || *lsp->enabled;
}
static bool
lsp_is_up(const struct nbrec_logical_switch_port *lsp)
{
return !lsp->up || *lsp->up;
}
static bool
build_dhcpv4_action(struct ovn_port *op, ovs_be32 offer_ip,
struct ds *options_action, struct ds *response_action,
struct ds *ipv4_addr_match)
{
if (!op->nbsp->dhcpv4_options) {
/* CMS has disabled native DHCPv4 for this lport. */
return false;
}
ovs_be32 host_ip, mask;
char *error = ip_parse_masked(op->nbsp->dhcpv4_options->cidr, &host_ip,
&mask);
if (error || ((offer_ip ^ host_ip) & mask)) {
/* Either
* - cidr defined is invalid or
* - the offer ip of the logical port doesn't belong to the cidr
* defined in the DHCPv4 options.
* */
free(error);
return false;
}
const char *server_ip = smap_get(
&op->nbsp->dhcpv4_options->options, "server_id");
const char *server_mac = smap_get(
&op->nbsp->dhcpv4_options->options, "server_mac");
const char *lease_time = smap_get(
&op->nbsp->dhcpv4_options->options, "lease_time");
if (!(server_ip && server_mac && lease_time)) {
/* "server_id", "server_mac" and "lease_time" should be
* present in the dhcp_options. */
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_WARN_RL(&rl, "Required DHCPv4 options not defined for lport - %s",
op->json_key);
return false;
}
struct smap dhcpv4_options = SMAP_INITIALIZER(&dhcpv4_options);
smap_clone(&dhcpv4_options, &op->nbsp->dhcpv4_options->options);
/* server_mac is not DHCPv4 option, delete it from the smap. */
smap_remove(&dhcpv4_options, "server_mac");
char *netmask = xasprintf(IP_FMT, IP_ARGS(mask));
smap_add(&dhcpv4_options, "netmask", netmask);
free(netmask);
ds_put_format(options_action,
REGBIT_DHCP_OPTS_RESULT" = put_dhcp_opts(offerip = "
IP_FMT", ", IP_ARGS(offer_ip));
/* We're not using SMAP_FOR_EACH because we want a consistent order of the
* options on different architectures (big or little endian, SSE4.2) */
const struct smap_node **sorted_opts = smap_sort(&dhcpv4_options);
for (size_t i = 0; i < smap_count(&dhcpv4_options); i++) {
const struct smap_node *node = sorted_opts[i];
ds_put_format(options_action, "%s = %s, ", node->key, node->value);
}
free(sorted_opts);
ds_chomp(options_action, ' ');
ds_chomp(options_action, ',');
ds_put_cstr(options_action, "); next;");
ds_put_format(response_action, "eth.dst = eth.src; eth.src = %s; "
"ip4.dst = "IP_FMT"; ip4.src = %s; udp.src = 67; "
"udp.dst = 68; outport = inport; flags.loopback = 1; "
"output;",
server_mac, IP_ARGS(offer_ip), server_ip);
ds_put_format(ipv4_addr_match,
"ip4.src == "IP_FMT" && ip4.dst == {%s, 255.255.255.255}",
IP_ARGS(offer_ip), server_ip);
smap_destroy(&dhcpv4_options);
return true;
}
static bool
build_dhcpv6_action(struct ovn_port *op, struct in6_addr *offer_ip,
struct ds *options_action, struct ds *response_action)
{
if (!op->nbsp->dhcpv6_options) {
/* CMS has disabled native DHCPv6 for this lport. */
return false;
}
struct in6_addr host_ip, mask;
char *error = ipv6_parse_masked(op->nbsp->dhcpv6_options->cidr, &host_ip,
&mask);
if (error) {
free(error);
return false;
}
struct in6_addr ip6_mask = ipv6_addr_bitxor(offer_ip, &host_ip);
ip6_mask = ipv6_addr_bitand(&ip6_mask, &mask);
if (!ipv6_mask_is_any(&ip6_mask)) {
/* offer_ip doesn't belongs to the cidr defined in lport's DHCPv6
* options.*/
return false;
}
const struct smap *options_map = &op->nbsp->dhcpv6_options->options;
/* "server_id" should be the MAC address. */
const char *server_mac = smap_get(options_map, "server_id");
struct eth_addr ea;
if (!server_mac || !eth_addr_from_string(server_mac, &ea)) {
/* "server_id" should be present in the dhcpv6_options. */
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "server_id not present in the DHCPv6 options"
" for lport %s", op->json_key);
return false;
}
/* Get the link local IP of the DHCPv6 server from the server MAC. */
struct in6_addr lla;
in6_generate_lla(ea, &lla);
char server_ip[INET6_ADDRSTRLEN + 1];
ipv6_string_mapped(server_ip, &lla);
char ia_addr[INET6_ADDRSTRLEN + 1];
ipv6_string_mapped(ia_addr, offer_ip);
ds_put_format(options_action,
REGBIT_DHCP_OPTS_RESULT" = put_dhcpv6_opts(");
/* Check whether the dhcpv6 options should be configured as stateful.
* Only reply with ia_addr option for dhcpv6 stateful address mode. */
if (!smap_get_bool(options_map, "dhcpv6_stateless", false)) {
char ia_addr[INET6_ADDRSTRLEN + 1];
ipv6_string_mapped(ia_addr, offer_ip);
ds_put_format(options_action, "ia_addr = %s, ", ia_addr);
}
/* We're not using SMAP_FOR_EACH because we want a consistent order of the
* options on different architectures (big or little endian, SSE4.2) */
const struct smap_node **sorted_opts = smap_sort(options_map);
for (size_t i = 0; i < smap_count(options_map); i++) {
const struct smap_node *node = sorted_opts[i];
if (strcmp(node->key, "dhcpv6_stateless")) {
ds_put_format(options_action, "%s = %s, ", node->key, node->value);
}
}
free(sorted_opts);
ds_chomp(options_action, ' ');
ds_chomp(options_action, ',');
ds_put_cstr(options_action, "); next;");
ds_put_format(response_action, "eth.dst = eth.src; eth.src = %s; "
"ip6.dst = ip6.src; ip6.src = %s; udp.src = 547; "
"udp.dst = 546; outport = inport; flags.loopback = 1; "
"output;",
server_mac, server_ip);
return true;
}
static bool
has_stateful_acl(struct ovn_datapath *od)
{
for (size_t i = 0; i < od->nbs->n_acls; i++) {
struct nbrec_acl *acl = od->nbs->acls[i];
if (!strcmp(acl->action, "allow-related")) {
return true;
}
}
return false;
}
static void
build_pre_acls(struct ovn_datapath *od, struct hmap *lflows)
{
bool has_stateful = has_stateful_acl(od);
/* Ingress and Egress Pre-ACL Table (Priority 0): Packets are
* allowed by default. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_ACL, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_ACL, 0, "1", "next;");
/* If there are any stateful ACL rules in this datapath, we must
* send all IP packets through the conntrack action, which handles
* defragmentation, in order to match L4 headers. */
if (has_stateful) {
for (size_t i = 0; i < od->n_router_ports; i++) {
struct ovn_port *op = od->router_ports[i];
/* Can't use ct() for router ports. Consider the
* following configuration: lp1(10.0.0.2) on
* hostA--ls1--lr0--ls2--lp2(10.0.1.2) on hostB, For a
* ping from lp1 to lp2, First, the response will go
* through ct() with a zone for lp2 in the ls2 ingress
* pipeline on hostB. That ct zone knows about this
* connection. Next, it goes through ct() with the zone
* for the router port in the egress pipeline of ls2 on
* hostB. This zone does not know about the connection,
* as the icmp request went through the logical router
* on hostA, not hostB. This would only work with
* distributed conntrack state across all chassis. */
struct ds match_in = DS_EMPTY_INITIALIZER;
struct ds match_out = DS_EMPTY_INITIALIZER;
ds_put_format(&match_in, "ip && inport == %s", op->json_key);
ds_put_format(&match_out, "ip && outport == %s", op->json_key);
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_ACL, 110,
ds_cstr(&match_in), "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_ACL, 110,
ds_cstr(&match_out), "next;");
ds_destroy(&match_in);
ds_destroy(&match_out);
}
if (od->localnet_port) {
struct ds match_in = DS_EMPTY_INITIALIZER;
struct ds match_out = DS_EMPTY_INITIALIZER;
ds_put_format(&match_in, "ip && inport == %s",
od->localnet_port->json_key);
ds_put_format(&match_out, "ip && outport == %s",
od->localnet_port->json_key);
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_ACL, 110,
ds_cstr(&match_in), "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_ACL, 110,
ds_cstr(&match_out), "next;");
ds_destroy(&match_in);
ds_destroy(&match_out);
}
/* Ingress and Egress Pre-ACL Table (Priority 110).
*
* Not to do conntrack on ND packets. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_ACL, 110, "nd", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_ACL, 110, "nd", "next;");
/* Ingress and Egress Pre-ACL Table (Priority 100).
*
* Regardless of whether the ACL is "from-lport" or "to-lport",
* we need rules in both the ingress and egress table, because
* the return traffic needs to be followed.
*
* 'REGBIT_CONNTRACK_DEFRAG' is set to let the pre-stateful table send
* it to conntrack for tracking and defragmentation. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_ACL, 100, "ip",
REGBIT_CONNTRACK_DEFRAG" = 1; next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_ACL, 100, "ip",
REGBIT_CONNTRACK_DEFRAG" = 1; next;");
}
}
/* For a 'key' of the form "IP:port" or just "IP", sets 'port' and
* 'ip_address'. The caller must free() the memory allocated for
* 'ip_address'. */
static void
ip_address_and_port_from_lb_key(const char *key, char **ip_address,
uint16_t *port)
{
char *ip_str, *start, *next;
*ip_address = NULL;
*port = 0;
next = start = xstrdup(key);
ip_str = strsep(&next, ":");
if (!ip_str || !ip_str[0]) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip address for load balancer key %s", key);
free(start);
return;
}
ovs_be32 ip, mask;
char *error = ip_parse_masked(ip_str, &ip, &mask);
if (error || mask != OVS_BE32_MAX) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip address for load balancer key %s", key);
free(start);
free(error);
return;
}
int l4_port = 0;
if (next && next[0]) {
if (!str_to_int(next, 0, &l4_port) || l4_port < 0 || l4_port > 65535) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip port for load balancer key %s", key);
free(start);
return;
}
}
*port = l4_port;
*ip_address = strdup(ip_str);
free(start);
}
/*
* Returns true if logical switch is configured with DNS records, false
* otherwise.
*/
static bool
ls_has_dns_records(const struct nbrec_logical_switch *nbs)
{
for (size_t i = 0; i < nbs->n_dns_records; i++) {
if (!smap_is_empty(&nbs->dns_records[i]->records)) {
return true;
}
}
return false;
}
static void
build_pre_lb(struct ovn_datapath *od, struct hmap *lflows)
{
/* Allow all packets to go to next tables by default. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_LB, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_LB, 0, "1", "next;");
struct sset all_ips = SSET_INITIALIZER(&all_ips);
bool vip_configured = false;
for (int i = 0; i < od->nbs->n_load_balancer; i++) {
struct nbrec_load_balancer *lb = od->nbs->load_balancer[i];
struct smap *vips = &lb->vips;
struct smap_node *node;
SMAP_FOR_EACH (node, vips) {
vip_configured = true;
/* node->key contains IP:port or just IP. */
char *ip_address = NULL;
uint16_t port;
ip_address_and_port_from_lb_key(node->key, &ip_address, &port);
if (!ip_address) {
continue;
}
if (!sset_contains(&all_ips, ip_address)) {
sset_add(&all_ips, ip_address);
}
free(ip_address);
/* Ignore L4 port information in the key because fragmented packets
* may not have L4 information. The pre-stateful table will send
* the packet through ct() action to de-fragment. In stateful
* table, we will eventually look at L4 information. */
}
}
/* 'REGBIT_CONNTRACK_DEFRAG' is set to let the pre-stateful table send
* packet to conntrack for defragmentation. */
const char *ip_address;
SSET_FOR_EACH(ip_address, &all_ips) {
char *match = xasprintf("ip && ip4.dst == %s", ip_address);
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_LB,
100, match, REGBIT_CONNTRACK_DEFRAG" = 1; next;");
free(match);
}
sset_destroy(&all_ips);
if (vip_configured) {
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_LB,
100, "ip", REGBIT_CONNTRACK_DEFRAG" = 1; next;");
}
}
static void
build_pre_stateful(struct ovn_datapath *od, struct hmap *lflows)
{
/* Ingress and Egress pre-stateful Table (Priority 0): Packets are
* allowed by default. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_STATEFUL, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_STATEFUL, 0, "1", "next;");
/* If REGBIT_CONNTRACK_DEFRAG is set as 1, then the packets should be
* sent to conntrack for tracking and defragmentation. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PRE_STATEFUL, 100,
REGBIT_CONNTRACK_DEFRAG" == 1", "ct_next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PRE_STATEFUL, 100,
REGBIT_CONNTRACK_DEFRAG" == 1", "ct_next;");
}
static void
build_acl_log(struct ds *actions, const struct nbrec_acl *acl)
{
if (!acl->log) {
return;
}
ds_put_cstr(actions, "log(");
if (acl->name) {
ds_put_format(actions, "name=\"%s\", ", acl->name);
}
/* If a severity level isn't specified, default to "info". */
if (acl->severity) {
ds_put_format(actions, "severity=%s, ", acl->severity);
} else {
ds_put_format(actions, "severity=info, ");
}
if (!strcmp(acl->action, "drop")) {
ds_put_cstr(actions, "verdict=drop, ");
} else if (!strcmp(acl->action, "reject")) {
ds_put_cstr(actions, "verdict=reject, ");
} else if (!strcmp(acl->action, "allow")
|| !strcmp(acl->action, "allow-related")) {
ds_put_cstr(actions, "verdict=allow, ");
}
ds_chomp(actions, ' ');
ds_chomp(actions, ',');
ds_put_cstr(actions, "); ");
}
static void
build_acls(struct ovn_datapath *od, struct hmap *lflows)
{
bool has_stateful = has_stateful_acl(od);
/* Ingress and Egress ACL Table (Priority 0): Packets are allowed by
* default. A related rule at priority 1 is added below if there
* are any stateful ACLs in this datapath. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_ACL, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_ACL, 0, "1", "next;");
if (has_stateful) {
/* Ingress and Egress ACL Table (Priority 1).
*
* By default, traffic is allowed. This is partially handled by
* the Priority 0 ACL flows added earlier, but we also need to
* commit IP flows. This is because, while the initiater's
* direction may not have any stateful rules, the server's may
* and then its return traffic would not have an associated
* conntrack entry and would return "+invalid".
*
* We use "ct_commit" for a connection that is not already known
* by the connection tracker. Once a connection is committed,
* subsequent packets will hit the flow at priority 0 that just
* uses "next;"
*
* We also check for established connections that have ct_label.blocked
* set on them. That's a connection that was disallowed, but is
* now allowed by policy again since it hit this default-allow flow.
* We need to set ct_label.blocked=0 to let the connection continue,
* which will be done by ct_commit() in the "stateful" stage.
* Subsequent packets will hit the flow at priority 0 that just
* uses "next;". */
ovn_lflow_add(lflows, od, S_SWITCH_IN_ACL, 1,
"ip && (!ct.est || (ct.est && ct_label.blocked == 1))",
REGBIT_CONNTRACK_COMMIT" = 1; next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_ACL, 1,
"ip && (!ct.est || (ct.est && ct_label.blocked == 1))",
REGBIT_CONNTRACK_COMMIT" = 1; next;");
/* Ingress and Egress ACL Table (Priority 65535).
*
* Always drop traffic that's in an invalid state. Also drop
* reply direction packets for connections that have been marked
* for deletion (bit 0 of ct_label is set).
*
* This is enforced at a higher priority than ACLs can be defined. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_ACL, UINT16_MAX,
"ct.inv || (ct.est && ct.rpl && ct_label.blocked == 1)",
"drop;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_ACL, UINT16_MAX,
"ct.inv || (ct.est && ct.rpl && ct_label.blocked == 1)",
"drop;");
/* Ingress and Egress ACL Table (Priority 65535).
*
* Allow reply traffic that is part of an established
* conntrack entry that has not been marked for deletion
* (bit 0 of ct_label). We only match traffic in the
* reply direction because we want traffic in the request
* direction to hit the currently defined policy from ACLs.
*
* This is enforced at a higher priority than ACLs can be defined. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_ACL, UINT16_MAX,
"ct.est && !ct.rel && !ct.new && !ct.inv "
"&& ct.rpl && ct_label.blocked == 0",
"next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_ACL, UINT16_MAX,
"ct.est && !ct.rel && !ct.new && !ct.inv "
"&& ct.rpl && ct_label.blocked == 0",
"next;");
/* Ingress and Egress ACL Table (Priority 65535).
*
* Allow traffic that is related to an existing conntrack entry that
* has not been marked for deletion (bit 0 of ct_label).
*
* This is enforced at a higher priority than ACLs can be defined.
*
* NOTE: This does not support related data sessions (eg,
* a dynamically negotiated FTP data channel), but will allow
* related traffic such as an ICMP Port Unreachable through
* that's generated from a non-listening UDP port. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_ACL, UINT16_MAX,
"!ct.est && ct.rel && !ct.new && !ct.inv "
"&& ct_label.blocked == 0",
"next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_ACL, UINT16_MAX,
"!ct.est && ct.rel && !ct.new && !ct.inv "
"&& ct_label.blocked == 0",
"next;");
/* Ingress and Egress ACL Table (Priority 65535).
*
* Not to do conntrack on ND packets. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_ACL, UINT16_MAX, "nd", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_ACL, UINT16_MAX, "nd", "next;");
}
/* Ingress or Egress ACL Table (Various priorities). */
for (size_t i = 0; i < od->nbs->n_acls; i++) {
struct nbrec_acl *acl = od->nbs->acls[i];
bool ingress = !strcmp(acl->direction, "from-lport") ? true :false;
enum ovn_stage stage = ingress ? S_SWITCH_IN_ACL : S_SWITCH_OUT_ACL;
char *stage_hint = xasprintf("%08x", acl->header_.uuid.parts[0]);
if (!strcmp(acl->action, "allow")
|| !strcmp(acl->action, "allow-related")) {
/* If there are any stateful flows, we must even commit "allow"
* actions. This is because, while the initiater's
* direction may not have any stateful rules, the server's
* may and then its return traffic would not have an
* associated conntrack entry and would return "+invalid". */
if (!has_stateful) {
struct ds actions = DS_EMPTY_INITIALIZER;
build_acl_log(&actions, acl);
ds_put_cstr(&actions, "next;");
ovn_lflow_add_with_hint(lflows, od, stage,
acl->priority + OVN_ACL_PRI_OFFSET,
acl->match, ds_cstr(&actions),
stage_hint);
ds_destroy(&actions);
} else {
struct ds match = DS_EMPTY_INITIALIZER;
struct ds actions = DS_EMPTY_INITIALIZER;
/* Commit the connection tracking entry if it's a new
* connection that matches this ACL. After this commit,
* the reply traffic is allowed by a flow we create at
* priority 65535, defined earlier.
*
* It's also possible that a known connection was marked for
* deletion after a policy was deleted, but the policy was
* re-added while that connection is still known. We catch
* that case here and un-set ct_label.blocked (which will be done
* by ct_commit in the "stateful" stage) to indicate that the
* connection should be allowed to resume.
*/
ds_put_format(&match, "((ct.new && !ct.est)"
" || (!ct.new && ct.est && !ct.rpl "
"&& ct_label.blocked == 1)) "
"&& (%s)", acl->match);
ds_put_cstr(&actions, REGBIT_CONNTRACK_COMMIT" = 1; ");
build_acl_log(&actions, acl);
ds_put_cstr(&actions, "next;");
ovn_lflow_add_with_hint(lflows, od, stage,
acl->priority + OVN_ACL_PRI_OFFSET,
ds_cstr(&match),
ds_cstr(&actions),
stage_hint);
/* Match on traffic in the request direction for an established
* connection tracking entry that has not been marked for
* deletion. There is no need to commit here, so we can just
* proceed to the next table. We use this to ensure that this
* connection is still allowed by the currently defined
* policy. */
ds_clear(&match);
ds_clear(&actions);
ds_put_format(&match,
"!ct.new && ct.est && !ct.rpl"
" && ct_label.blocked == 0 && (%s)",
acl->match);
build_acl_log(&actions, acl);
ds_put_cstr(&actions, "next;");
ovn_lflow_add_with_hint(lflows, od, stage,
acl->priority + OVN_ACL_PRI_OFFSET,
ds_cstr(&match), ds_cstr(&actions),
stage_hint);
ds_destroy(&match);
ds_destroy(&actions);
}
} else if (!strcmp(acl->action, "drop")
|| !strcmp(acl->action, "reject")) {
struct ds match = DS_EMPTY_INITIALIZER;
struct ds actions = DS_EMPTY_INITIALIZER;
/* XXX Need to support "reject", treat it as "drop;" for now. */
if (!strcmp(acl->action, "reject")) {
VLOG_INFO("reject is not a supported action");
}
/* The implementation of "drop" differs if stateful ACLs are in
* use for this datapath. In that case, the actions differ
* depending on whether the connection was previously committed
* to the connection tracker with ct_commit. */
if (has_stateful) {
/* If the packet is not part of an established connection, then
* we can simply drop it. */
ds_put_format(&match,
"(!ct.est || (ct.est && ct_label.blocked == 1)) "
"&& (%s)",
acl->match);
ds_clear(&actions);
build_acl_log(&actions, acl);
ds_put_cstr(&actions, "/* drop */");
ovn_lflow_add_with_hint(lflows, od, stage,
acl->priority + OVN_ACL_PRI_OFFSET,
ds_cstr(&match), ds_cstr(&actions),
stage_hint);
/* For an existing connection without ct_label set, we've
* encountered a policy change. ACLs previously allowed
* this connection and we committed the connection tracking
* entry. Current policy says that we should drop this
* connection. First, we set bit 0 of ct_label to indicate
* that this connection is set for deletion. By not
* specifying "next;", we implicitly drop the packet after
* updating conntrack state. We would normally defer
* ct_commit() to the "stateful" stage, but since we're
* dropping the packet, we go ahead and do it here. */
ds_clear(&match);
ds_clear(&actions);
ds_put_format(&match,
"ct.est && ct_label.blocked == 0 && (%s)",
acl->match);
ds_put_cstr(&actions, "ct_commit(ct_label=1/1); ");
build_acl_log(&actions, acl);
ds_put_cstr(&actions, "/* drop */");
ovn_lflow_add_with_hint(lflows, od, stage,
acl->priority + OVN_ACL_PRI_OFFSET,
ds_cstr(&match), ds_cstr(&actions),
stage_hint);
} else {
/* There are no stateful ACLs in use on this datapath,
* so a "drop" ACL is simply the "drop" logical flow action
* in all cases. */
ds_clear(&actions);
build_acl_log(&actions, acl);
ds_put_cstr(&actions, "/* drop */");
ovn_lflow_add_with_hint(lflows, od, stage,
acl->priority + OVN_ACL_PRI_OFFSET,
acl->match, ds_cstr(&actions),
stage_hint);
}
ds_destroy(&match);
ds_destroy(&actions);
}
free(stage_hint);
}
/* Add 34000 priority flow to allow DHCP reply from ovn-controller to all
* logical ports of the datapath if the CMS has configured DHCPv4 options.
* */
for (size_t i = 0; i < od->nbs->n_ports; i++) {
if (od->nbs->ports[i]->dhcpv4_options) {
const char *server_id = smap_get(
&od->nbs->ports[i]->dhcpv4_options->options, "server_id");
const char *server_mac = smap_get(
&od->nbs->ports[i]->dhcpv4_options->options, "server_mac");
const char *lease_time = smap_get(
&od->nbs->ports[i]->dhcpv4_options->options, "lease_time");
if (server_id && server_mac && lease_time) {
struct ds match = DS_EMPTY_INITIALIZER;
const char *actions =
has_stateful ? "ct_commit; next;" : "next;";
ds_put_format(&match, "outport == \"%s\" && eth.src == %s "
"&& ip4.src == %s && udp && udp.src == 67 "
"&& udp.dst == 68", od->nbs->ports[i]->name,
server_mac, server_id);
ovn_lflow_add(
lflows, od, S_SWITCH_OUT_ACL, 34000, ds_cstr(&match),
actions);
ds_destroy(&match);
}
}
if (od->nbs->ports[i]->dhcpv6_options) {
const char *server_mac = smap_get(
&od->nbs->ports[i]->dhcpv6_options->options, "server_id");
struct eth_addr ea;
if (server_mac && eth_addr_from_string(server_mac, &ea)) {
/* Get the link local IP of the DHCPv6 server from the
* server MAC. */
struct in6_addr lla;
in6_generate_lla(ea, &lla);
char server_ip[INET6_ADDRSTRLEN + 1];
ipv6_string_mapped(server_ip, &lla);
struct ds match = DS_EMPTY_INITIALIZER;
const char *actions = has_stateful ? "ct_commit; next;" :
"next;";
ds_put_format(&match, "outport == \"%s\" && eth.src == %s "
"&& ip6.src == %s && udp && udp.src == 547 "
"&& udp.dst == 546", od->nbs->ports[i]->name,
server_mac, server_ip);
ovn_lflow_add(
lflows, od, S_SWITCH_OUT_ACL, 34000, ds_cstr(&match),
actions);
ds_destroy(&match);
}
}
}
/* Add a 34000 priority flow to advance the DNS reply from ovn-controller,
* if the CMS has configured DNS records for the datapath.
*/
if (ls_has_dns_records(od->nbs)) {
const char *actions = has_stateful ? "ct_commit; next;" : "next;";
ovn_lflow_add(
lflows, od, S_SWITCH_OUT_ACL, 34000, "udp.src == 53",
actions);
}
}
static void
build_qos(struct ovn_datapath *od, struct hmap *lflows) {
ovn_lflow_add(lflows, od, S_SWITCH_IN_QOS_MARK, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_QOS_MARK, 0, "1", "next;");
for (size_t i = 0; i < od->nbs->n_qos_rules; i++) {
struct nbrec_qos *qos = od->nbs->qos_rules[i];
bool ingress = !strcmp(qos->direction, "from-lport") ? true :false;
enum ovn_stage stage = ingress ? S_SWITCH_IN_QOS_MARK : S_SWITCH_OUT_QOS_MARK;
if (!strcmp(qos->key_action, "dscp")) {
struct ds dscp_action = DS_EMPTY_INITIALIZER;
ds_put_format(&dscp_action, "ip.dscp = %d; next;",
(uint8_t)qos->value_action);
ovn_lflow_add(lflows, od, stage,
qos->priority,
qos->match, ds_cstr(&dscp_action));
ds_destroy(&dscp_action);
}
}
}
static void
build_lb(struct ovn_datapath *od, struct hmap *lflows)
{
/* Ingress and Egress LB Table (Priority 0): Packets are allowed by
* default. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_LB, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_LB, 0, "1", "next;");
if (od->nbs->load_balancer) {
/* Ingress and Egress LB Table (Priority 65535).
*
* Send established traffic through conntrack for just NAT. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_LB, UINT16_MAX,
"ct.est && !ct.rel && !ct.new && !ct.inv",
REGBIT_CONNTRACK_NAT" = 1; next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_LB, UINT16_MAX,
"ct.est && !ct.rel && !ct.new && !ct.inv",
REGBIT_CONNTRACK_NAT" = 1; next;");
}
}
static void
build_stateful(struct ovn_datapath *od, struct hmap *lflows)
{
/* Ingress and Egress stateful Table (Priority 0): Packets are
* allowed by default. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_STATEFUL, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_STATEFUL, 0, "1", "next;");
/* If REGBIT_CONNTRACK_COMMIT is set as 1, then the packets should be
* committed to conntrack. We always set ct_label.blocked to 0 here as
* any packet that makes it this far is part of a connection we
* want to allow to continue. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_STATEFUL, 100,
REGBIT_CONNTRACK_COMMIT" == 1", "ct_commit(ct_label=0/1); next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_STATEFUL, 100,
REGBIT_CONNTRACK_COMMIT" == 1", "ct_commit(ct_label=0/1); next;");
/* If REGBIT_CONNTRACK_NAT is set as 1, then packets should just be sent
* through nat (without committing).
*
* REGBIT_CONNTRACK_COMMIT is set for new connections and
* REGBIT_CONNTRACK_NAT is set for established connections. So they
* don't overlap.
*/
ovn_lflow_add(lflows, od, S_SWITCH_IN_STATEFUL, 100,
REGBIT_CONNTRACK_NAT" == 1", "ct_lb;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_STATEFUL, 100,
REGBIT_CONNTRACK_NAT" == 1", "ct_lb;");
/* Load balancing rules for new connections get committed to conntrack
* table. So even if REGBIT_CONNTRACK_COMMIT is set in a previous table
* a higher priority rule for load balancing below also commits the
* connection, so it is okay if we do not hit the above match on
* REGBIT_CONNTRACK_COMMIT. */
for (int i = 0; i < od->nbs->n_load_balancer; i++) {
struct nbrec_load_balancer *lb = od->nbs->load_balancer[i];
struct smap *vips = &lb->vips;
struct smap_node *node;
SMAP_FOR_EACH (node, vips) {
uint16_t port = 0;
/* node->key contains IP:port or just IP. */
char *ip_address = NULL;
ip_address_and_port_from_lb_key(node->key, &ip_address, &port);
if (!ip_address) {
continue;
}
/* New connections in Ingress table. */
char *action = xasprintf("ct_lb(%s);", node->value);
struct ds match = DS_EMPTY_INITIALIZER;
ds_put_format(&match, "ct.new && ip4.dst == %s", ip_address);
if (port) {
if (lb->protocol && !strcmp(lb->protocol, "udp")) {
ds_put_format(&match, " && udp.dst == %d", port);
} else {
ds_put_format(&match, " && tcp.dst == %d", port);
}
ovn_lflow_add(lflows, od, S_SWITCH_IN_STATEFUL,
120, ds_cstr(&match), action);
} else {
ovn_lflow_add(lflows, od, S_SWITCH_IN_STATEFUL,
110, ds_cstr(&match), action);
}
free(ip_address);
ds_destroy(&match);
free(action);
}
}
}
static void
build_lswitch_flows(struct hmap *datapaths, struct hmap *ports,
struct hmap *lflows, struct hmap *mcgroups)
{
/* This flow table structure is documented in ovn-northd(8), so please
* update ovn-northd.8.xml if you change anything. */
struct ds match = DS_EMPTY_INITIALIZER;
struct ds actions = DS_EMPTY_INITIALIZER;
/* Build pre-ACL and ACL tables for both ingress and egress.
* Ingress tables 3 through 9. Egress tables 0 through 6. */
struct ovn_datapath *od;
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
build_pre_acls(od, lflows);
build_pre_lb(od, lflows);
build_pre_stateful(od, lflows);
build_acls(od, lflows);
build_qos(od, lflows);
build_lb(od, lflows);
build_stateful(od, lflows);
}
/* Logical switch ingress table 0: Admission control framework (priority
* 100). */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
/* Logical VLANs not supported. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PORT_SEC_L2, 100, "vlan.present",
"drop;");
/* Broadcast/multicast source address is invalid. */
ovn_lflow_add(lflows, od, S_SWITCH_IN_PORT_SEC_L2, 100, "eth.src[40]",
"drop;");
/* Port security flows have priority 50 (see below) and will continue
* to the next table if packet source is acceptable. */
}
/* Logical switch ingress table 0: Ingress port security - L2
* (priority 50).
* Ingress table 1: Ingress port security - IP (priority 90 and 80)
* Ingress table 2: Ingress port security - ND (priority 90 and 80)
*/
struct ovn_port *op;
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
if (!lsp_is_enabled(op->nbsp)) {
/* Drop packets from disabled logical ports (since logical flow
* tables are default-drop). */
continue;
}
ds_clear(&match);
ds_clear(&actions);
ds_put_format(&match, "inport == %s", op->json_key);
build_port_security_l2("eth.src", op->ps_addrs, op->n_ps_addrs,
&match);
const char *queue_id = smap_get(&op->sb->options, "qdisc_queue_id");
if (queue_id) {
ds_put_format(&actions, "set_queue(%s); ", queue_id);
}
ds_put_cstr(&actions, "next;");
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_PORT_SEC_L2, 50,
ds_cstr(&match), ds_cstr(&actions));
if (op->nbsp->n_port_security) {
build_port_security_ip(P_IN, op, lflows);
build_port_security_nd(op, lflows);
}
}
/* Ingress table 1 and 2: Port security - IP and ND, by default goto next.
* (priority 0)*/
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
ovn_lflow_add(lflows, od, S_SWITCH_IN_PORT_SEC_ND, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_PORT_SEC_IP, 0, "1", "next;");
}
/* Ingress table 10: ARP/ND responder, skip requests coming from localnet
* and vtep ports. (priority 100); see ovn-northd.8.xml for the
* rationale. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
if ((!strcmp(op->nbsp->type, "localnet")) ||
(!strcmp(op->nbsp->type, "vtep"))) {
ds_clear(&match);
ds_put_format(&match, "inport == %s", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_ARP_ND_RSP, 100,
ds_cstr(&match), "next;");
}
}
/* Ingress table 10: ARP/ND responder, reply for known IPs.
* (priority 50). */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
/*
* Add ARP/ND reply flows if either the
* - port is up or
* - port type is router or
* - port type is localport
*/
if (!lsp_is_up(op->nbsp) && strcmp(op->nbsp->type, "router") &&
strcmp(op->nbsp->type, "localport")) {
continue;
}
for (size_t i = 0; i < op->n_lsp_addrs; i++) {
for (size_t j = 0; j < op->lsp_addrs[i].n_ipv4_addrs; j++) {
ds_clear(&match);
ds_put_format(&match, "arp.tpa == %s && arp.op == 1",
op->lsp_addrs[i].ipv4_addrs[j].addr_s);
ds_clear(&actions);
ds_put_format(&actions,
"eth.dst = eth.src; "
"eth.src = %s; "
"arp.op = 2; /* ARP reply */ "
"arp.tha = arp.sha; "
"arp.sha = %s; "
"arp.tpa = arp.spa; "
"arp.spa = %s; "
"outport = inport; "
"flags.loopback = 1; "
"output;",
op->lsp_addrs[i].ea_s, op->lsp_addrs[i].ea_s,
op->lsp_addrs[i].ipv4_addrs[j].addr_s);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_ARP_ND_RSP, 50,
ds_cstr(&match), ds_cstr(&actions));
/* Do not reply to an ARP request from the port that owns the
* address (otherwise a DHCP client that ARPs to check for a
* duplicate address will fail). Instead, forward it the usual
* way.
*
* (Another alternative would be to simply drop the packet. If
* everything is working as it is configured, then this would
* produce equivalent results, since no one should reply to the
* request. But ARPing for one's own IP address is intended to
* detect situations where the network is not working as
* configured, so dropping the request would frustrate that
* intent.) */
ds_put_format(&match, " && inport == %s", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_ARP_ND_RSP, 100,
ds_cstr(&match), "next;");
}
/* For ND solicitations, we need to listen for both the
* unicast IPv6 address and its all-nodes multicast address,
* but always respond with the unicast IPv6 address. */
for (size_t j = 0; j < op->lsp_addrs[i].n_ipv6_addrs; j++) {
ds_clear(&match);
ds_put_format(&match,
"nd_ns && ip6.dst == {%s, %s} && nd.target == %s",
op->lsp_addrs[i].ipv6_addrs[j].addr_s,
op->lsp_addrs[i].ipv6_addrs[j].sn_addr_s,
op->lsp_addrs[i].ipv6_addrs[j].addr_s);
ds_clear(&actions);
ds_put_format(&actions,
"nd_na { "
"eth.src = %s; "
"ip6.src = %s; "
"nd.target = %s; "
"nd.tll = %s; "
"outport = inport; "
"flags.loopback = 1; "
"output; "
"};",
op->lsp_addrs[i].ea_s,
op->lsp_addrs[i].ipv6_addrs[j].addr_s,
op->lsp_addrs[i].ipv6_addrs[j].addr_s,
op->lsp_addrs[i].ea_s);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_ARP_ND_RSP, 50,
ds_cstr(&match), ds_cstr(&actions));
/* Do not reply to a solicitation from the port that owns the
* address (otherwise DAD detection will fail). */
ds_put_format(&match, " && inport == %s", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_ARP_ND_RSP, 100,
ds_cstr(&match), "next;");
}
}
}
/* Ingress table 10: ARP/ND responder, by default goto next.
* (priority 0)*/
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
ovn_lflow_add(lflows, od, S_SWITCH_IN_ARP_ND_RSP, 0, "1", "next;");
}
/* Logical switch ingress table 11 and 12: DHCP options and response
* priority 100 flows. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
if (!lsp_is_enabled(op->nbsp) || !strcmp(op->nbsp->type, "router")) {
/* Don't add the DHCP flows if the port is not enabled or if the
* port is a router port. */
continue;
}
if (!op->nbsp->dhcpv4_options && !op->nbsp->dhcpv6_options) {
/* CMS has disabled both native DHCPv4 and DHCPv6 for this lport.
*/
continue;
}
for (size_t i = 0; i < op->n_lsp_addrs; i++) {
for (size_t j = 0; j < op->lsp_addrs[i].n_ipv4_addrs; j++) {
struct ds options_action = DS_EMPTY_INITIALIZER;
struct ds response_action = DS_EMPTY_INITIALIZER;
struct ds ipv4_addr_match = DS_EMPTY_INITIALIZER;
if (build_dhcpv4_action(
op, op->lsp_addrs[i].ipv4_addrs[j].addr,
&options_action, &response_action, &ipv4_addr_match)) {
struct ds match = DS_EMPTY_INITIALIZER;
ds_put_format(
&match, "inport == %s && eth.src == %s && "
"ip4.src == 0.0.0.0 && ip4.dst == 255.255.255.255 && "
"udp.src == 68 && udp.dst == 67", op->json_key,
op->lsp_addrs[i].ea_s);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_DHCP_OPTIONS,
100, ds_cstr(&match),
ds_cstr(&options_action));
ds_clear(&match);
/* Allow ip4.src = OFFER_IP and
* ip4.dst = {SERVER_IP, 255.255.255.255} for the below
* cases
* - When the client wants to renew the IP by sending
* the DHCPREQUEST to the server ip.
* - When the client wants to renew the IP by
* broadcasting the DHCPREQUEST.
*/
ds_put_format(
&match, "inport == %s && eth.src == %s && "
"%s && udp.src == 68 && udp.dst == 67", op->json_key,
op->lsp_addrs[i].ea_s, ds_cstr(&ipv4_addr_match));
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_DHCP_OPTIONS,
100, ds_cstr(&match),
ds_cstr(&options_action));
ds_clear(&match);
/* If REGBIT_DHCP_OPTS_RESULT is set, it means the
* put_dhcp_opts action is successful. */
ds_put_format(
&match, "inport == %s && eth.src == %s && "
"ip4 && udp.src == 68 && udp.dst == 67"
" && "REGBIT_DHCP_OPTS_RESULT, op->json_key,
op->lsp_addrs[i].ea_s);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_DHCP_RESPONSE,
100, ds_cstr(&match),
ds_cstr(&response_action));
ds_destroy(&match);
ds_destroy(&options_action);
ds_destroy(&response_action);
ds_destroy(&ipv4_addr_match);
break;
}
}
for (size_t j = 0; j < op->lsp_addrs[i].n_ipv6_addrs; j++) {
struct ds options_action = DS_EMPTY_INITIALIZER;
struct ds response_action = DS_EMPTY_INITIALIZER;
if (build_dhcpv6_action(
op, &op->lsp_addrs[i].ipv6_addrs[j].addr,
&options_action, &response_action)) {
struct ds match = DS_EMPTY_INITIALIZER;
ds_put_format(
&match, "inport == %s && eth.src == %s"
" && ip6.dst == ff02::1:2 && udp.src == 546 &&"
" udp.dst == 547", op->json_key,
op->lsp_addrs[i].ea_s);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_DHCP_OPTIONS, 100,
ds_cstr(&match), ds_cstr(&options_action));
/* If REGBIT_DHCP_OPTS_RESULT is set to 1, it means the
* put_dhcpv6_opts action is successful */
ds_put_cstr(&match, " && "REGBIT_DHCP_OPTS_RESULT);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_DHCP_RESPONSE, 100,
ds_cstr(&match), ds_cstr(&response_action));
ds_destroy(&match);
ds_destroy(&options_action);
ds_destroy(&response_action);
break;
}
}
}
}
/* Logical switch ingress table 13 and 14: DNS lookup and response
* priority 100 flows.
*/
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs || !ls_has_dns_records(od->nbs)) {
continue;
}
struct ds match;
struct ds action;
ds_init(&match);
ds_init(&action);
ds_put_cstr(&match, "udp.dst == 53");
ds_put_format(&action,
REGBIT_DNS_LOOKUP_RESULT" = dns_lookup(); next;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_DNS_LOOKUP, 100,
ds_cstr(&match), ds_cstr(&action));
ds_clear(&action);
ds_put_cstr(&match, " && "REGBIT_DNS_LOOKUP_RESULT);
ds_put_format(&action, "eth.dst <-> eth.src; ip4.src <-> ip4.dst; "
"udp.dst = udp.src; udp.src = 53; outport = inport; "
"flags.loopback = 1; output;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_DNS_RESPONSE, 100,
ds_cstr(&match), ds_cstr(&action));
ds_clear(&action);
ds_put_format(&action, "eth.dst <-> eth.src; ip6.src <-> ip6.dst; "
"udp.dst = udp.src; udp.src = 53; outport = inport; "
"flags.loopback = 1; output;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_DNS_RESPONSE, 100,
ds_cstr(&match), ds_cstr(&action));
ds_destroy(&match);
ds_destroy(&action);
}
/* Ingress table 11 and 12: DHCP options and response, by default goto next.
* (priority 0).
* Ingress table 13 and 14: DNS lookup and response, by default goto next.
* (priority 0).*/
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
ovn_lflow_add(lflows, od, S_SWITCH_IN_DHCP_OPTIONS, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_DHCP_RESPONSE, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_DNS_LOOKUP, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_IN_DNS_RESPONSE, 0, "1", "next;");
}
/* Ingress table 15: Destination lookup, broadcast and multicast handling
* (priority 100). */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
if (lsp_is_enabled(op->nbsp)) {
ovn_multicast_add(mcgroups, &mc_flood, op);
}
}
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
ovn_lflow_add(lflows, od, S_SWITCH_IN_L2_LKUP, 100, "eth.mcast",
"outport = \""MC_FLOOD"\"; output;");
}
/* Ingress table 13: Destination lookup, unicast handling (priority 50), */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
for (size_t i = 0; i < op->nbsp->n_addresses; i++) {
/* Addresses are owned by the logical port.
* Ethernet address followed by zero or more IPv4
* or IPv6 addresses (or both). */
struct eth_addr mac;
if (ovs_scan(op->nbsp->addresses[i],
ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(mac))) {
ds_clear(&match);
ds_put_format(&match, "eth.dst == "ETH_ADDR_FMT,
ETH_ADDR_ARGS(mac));
ds_clear(&actions);
ds_put_format(&actions, "outport = %s; output;", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_L2_LKUP, 50,
ds_cstr(&match), ds_cstr(&actions));
} else if (!strcmp(op->nbsp->addresses[i], "unknown")) {
if (lsp_is_enabled(op->nbsp)) {
ovn_multicast_add(mcgroups, &mc_unknown, op);
op->od->has_unknown = true;
}
} else if (is_dynamic_lsp_address(op->nbsp->addresses[i])) {
if (!op->nbsp->dynamic_addresses
|| !ovs_scan(op->nbsp->dynamic_addresses,
ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(mac))) {
continue;
}
ds_clear(&match);
ds_put_format(&match, "eth.dst == "ETH_ADDR_FMT,
ETH_ADDR_ARGS(mac));
ds_clear(&actions);
ds_put_format(&actions, "outport = %s; output;", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_L2_LKUP, 50,
ds_cstr(&match), ds_cstr(&actions));
} else if (!strcmp(op->nbsp->addresses[i], "router")) {
if (!op->peer || !op->peer->nbrp
|| !ovs_scan(op->peer->nbrp->mac,
ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(mac))) {
continue;
}
ds_clear(&match);
ds_put_format(&match, "eth.dst == "ETH_ADDR_FMT,
ETH_ADDR_ARGS(mac));
if (op->peer->od->l3dgw_port
&& op->peer == op->peer->od->l3dgw_port
&& op->peer->od->l3redirect_port) {
/* The destination lookup flow for the router's
* distributed gateway port MAC address should only be
* programmed on the "redirect-chassis". */
ds_put_format(&match, " && is_chassis_resident(%s)",
op->peer->od->l3redirect_port->json_key);
}
ds_clear(&actions);
ds_put_format(&actions, "outport = %s; output;", op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_L2_LKUP, 50,
ds_cstr(&match), ds_cstr(&actions));
/* Add ethernet addresses specified in NAT rules on
* distributed logical routers. */
if (op->peer->od->l3dgw_port
&& op->peer == op->peer->od->l3dgw_port) {
for (int i = 0; i < op->peer->od->nbr->n_nat; i++) {
const struct nbrec_nat *nat
= op->peer->od->nbr->nat[i];
if (!strcmp(nat->type, "dnat_and_snat")
&& nat->logical_port && nat->external_mac
&& eth_addr_from_string(nat->external_mac, &mac)) {
ds_clear(&match);
ds_put_format(&match, "eth.dst == "ETH_ADDR_FMT
" && is_chassis_resident(\"%s\")",
ETH_ADDR_ARGS(mac),
nat->logical_port);
ds_clear(&actions);
ds_put_format(&actions, "outport = %s; output;",
op->json_key);
ovn_lflow_add(lflows, op->od, S_SWITCH_IN_L2_LKUP,
50, ds_cstr(&match),
ds_cstr(&actions));
}
}
}
} else {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
VLOG_INFO_RL(&rl,
"%s: invalid syntax '%s' in addresses column",
op->nbsp->name, op->nbsp->addresses[i]);
}
}
}
/* Ingress table 13: Destination lookup for unknown MACs (priority 0). */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
if (od->has_unknown) {
ovn_lflow_add(lflows, od, S_SWITCH_IN_L2_LKUP, 0, "1",
"outport = \""MC_UNKNOWN"\"; output;");
}
}
/* Egress tables 6: Egress port security - IP (priority 0)
* Egress table 7: Egress port security L2 - multicast/broadcast
* (priority 100). */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs) {
continue;
}
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PORT_SEC_IP, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_SWITCH_OUT_PORT_SEC_L2, 100, "eth.mcast",
"output;");
}
/* Egress table 6: Egress port security - IP (priorities 90 and 80)
* if port security enabled.
*
* Egress table 7: Egress port security - L2 (priorities 50 and 150).
*
* Priority 50 rules implement port security for enabled logical port.
*
* Priority 150 rules drop packets to disabled logical ports, so that they
* don't even receive multicast or broadcast packets. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbsp) {
continue;
}
ds_clear(&match);
ds_put_format(&match, "outport == %s", op->json_key);
if (lsp_is_enabled(op->nbsp)) {
build_port_security_l2("eth.dst", op->ps_addrs, op->n_ps_addrs,
&match);
ovn_lflow_add(lflows, op->od, S_SWITCH_OUT_PORT_SEC_L2, 50,
ds_cstr(&match), "output;");
} else {
ovn_lflow_add(lflows, op->od, S_SWITCH_OUT_PORT_SEC_L2, 150,
ds_cstr(&match), "drop;");
}
if (op->nbsp->n_port_security) {
build_port_security_ip(P_OUT, op, lflows);
}
}
ds_destroy(&match);
ds_destroy(&actions);
}
static bool
lrport_is_enabled(const struct nbrec_logical_router_port *lrport)
{
return !lrport->enabled || *lrport->enabled;
}
/* Returns a string of the IP address of the router port 'op' that
* overlaps with 'ip_s". If one is not found, returns NULL.
*
* The caller must not free the returned string. */
static const char *
find_lrp_member_ip(const struct ovn_port *op, const char *ip_s)
{
bool is_ipv4 = strchr(ip_s, '.') ? true : false;
if (is_ipv4) {
ovs_be32 ip;
if (!ip_parse(ip_s, &ip)) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip address %s", ip_s);
return NULL;
}
for (int i = 0; i < op->lrp_networks.n_ipv4_addrs; i++) {
const struct ipv4_netaddr *na = &op->lrp_networks.ipv4_addrs[i];
if (!((na->network ^ ip) & na->mask)) {
/* There should be only 1 interface that matches the
* supplied IP. Otherwise, it's a configuration error,
* because subnets of a router's interfaces should NOT
* overlap. */
return na->addr_s;
}
}
} else {
struct in6_addr ip6;
if (!ipv6_parse(ip_s, &ip6)) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ipv6 address %s", ip_s);
return NULL;
}
for (int i = 0; i < op->lrp_networks.n_ipv6_addrs; i++) {
const struct ipv6_netaddr *na = &op->lrp_networks.ipv6_addrs[i];
struct in6_addr xor_addr = ipv6_addr_bitxor(&na->network, &ip6);
struct in6_addr and_addr = ipv6_addr_bitand(&xor_addr, &na->mask);
if (ipv6_is_zero(&and_addr)) {
/* There should be only 1 interface that matches the
* supplied IP. Otherwise, it's a configuration error,
* because subnets of a router's interfaces should NOT
* overlap. */
return na->addr_s;
}
}
}
return NULL;
}
static void
add_route(struct hmap *lflows, const struct ovn_port *op,
const char *lrp_addr_s, const char *network_s, int plen,
const char *gateway, const char *policy)
{
bool is_ipv4 = strchr(network_s, '.') ? true : false;
struct ds match = DS_EMPTY_INITIALIZER;
const char *dir;
uint16_t priority;
if (policy && !strcmp(policy, "src-ip")) {
dir = "src";
priority = plen * 2;
} else {
dir = "dst";
priority = (plen * 2) + 1;
}
/* IPv6 link-local addresses must be scoped to the local router port. */
if (!is_ipv4) {
struct in6_addr network;
ovs_assert(ipv6_parse(network_s, &network));
if (in6_is_lla(&network)) {
ds_put_format(&match, "inport == %s && ", op->json_key);
}
}
ds_put_format(&match, "ip%s.%s == %s/%d", is_ipv4 ? "4" : "6", dir,
network_s, plen);
struct ds actions = DS_EMPTY_INITIALIZER;
ds_put_format(&actions, "ip.ttl--; %sreg0 = ", is_ipv4 ? "" : "xx");
if (gateway) {
ds_put_cstr(&actions, gateway);
} else {
ds_put_format(&actions, "ip%s.dst", is_ipv4 ? "4" : "6");
}
ds_put_format(&actions, "; "
"%sreg1 = %s; "
"eth.src = %s; "
"outport = %s; "
"flags.loopback = 1; "
"next;",
is_ipv4 ? "" : "xx",
lrp_addr_s,
op->lrp_networks.ea_s,
op->json_key);
/* The priority here is calculated to implement longest-prefix-match
* routing. */
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_ROUTING, priority,
ds_cstr(&match), ds_cstr(&actions));
ds_destroy(&match);
ds_destroy(&actions);
}
static void
build_static_route_flow(struct hmap *lflows, struct ovn_datapath *od,
struct hmap *ports,
const struct nbrec_logical_router_static_route *route)
{
ovs_be32 nexthop;
const char *lrp_addr_s = NULL;
unsigned int plen;
bool is_ipv4;
/* Verify that the next hop is an IP address with an all-ones mask. */
char *error = ip_parse_cidr(route->nexthop, &nexthop, &plen);
if (!error) {
if (plen != 32) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad next hop mask %s", route->nexthop);
return;
}
is_ipv4 = true;
} else {
free(error);
struct in6_addr ip6;
char *error = ipv6_parse_cidr(route->nexthop, &ip6, &plen);
if (!error) {
if (plen != 128) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad next hop mask %s", route->nexthop);
return;
}
is_ipv4 = false;
} else {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad next hop ip address %s", route->nexthop);
free(error);
return;
}
}
char *prefix_s;
if (is_ipv4) {
ovs_be32 prefix;
/* Verify that ip prefix is a valid IPv4 address. */
error = ip_parse_cidr(route->ip_prefix, &prefix, &plen);
if (error) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad 'ip_prefix' in static routes %s",
route->ip_prefix);
free(error);
return;
}
prefix_s = xasprintf(IP_FMT, IP_ARGS(prefix & be32_prefix_mask(plen)));
} else {
/* Verify that ip prefix is a valid IPv6 address. */
struct in6_addr prefix;
error = ipv6_parse_cidr(route->ip_prefix, &prefix, &plen);
if (error) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad 'ip_prefix' in static routes %s",
route->ip_prefix);
free(error);
return;
}
struct in6_addr mask = ipv6_create_mask(plen);
struct in6_addr network = ipv6_addr_bitand(&prefix, &mask);
prefix_s = xmalloc(INET6_ADDRSTRLEN);
inet_ntop(AF_INET6, &network, prefix_s, INET6_ADDRSTRLEN);
}
/* Find the outgoing port. */
struct ovn_port *out_port = NULL;
if (route->output_port) {
out_port = ovn_port_find(ports, route->output_port);
if (!out_port) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "Bad out port %s for static route %s",
route->output_port, route->ip_prefix);
goto free_prefix_s;
}
lrp_addr_s = find_lrp_member_ip(out_port, route->nexthop);
if (!lrp_addr_s) {
/* There are no IP networks configured on the router's port via
* which 'route->nexthop' is theoretically reachable. But since
* 'out_port' has been specified, we honor it by trying to reach
* 'route->nexthop' via the first IP address of 'out_port'.
* (There are cases, e.g in GCE, where each VM gets a /32 IP
* address and the default gateway is still reachable from it.) */
if (is_ipv4) {
if (out_port->lrp_networks.n_ipv4_addrs) {
lrp_addr_s = out_port->lrp_networks.ipv4_addrs[0].addr_s;
}
} else {
if (out_port->lrp_networks.n_ipv6_addrs) {
lrp_addr_s = out_port->lrp_networks.ipv6_addrs[0].addr_s;
}
}
}
} else {
/* output_port is not specified, find the
* router port matching the next hop. */
int i;
for (i = 0; i < od->nbr->n_ports; i++) {
struct nbrec_logical_router_port *lrp = od->nbr->ports[i];
out_port = ovn_port_find(ports, lrp->name);
if (!out_port) {
/* This should not happen. */
continue;
}
lrp_addr_s = find_lrp_member_ip(out_port, route->nexthop);
if (lrp_addr_s) {
break;
}
}
}
if (!out_port || !lrp_addr_s) {
/* There is no matched out port. */
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "No path for static route %s; next hop %s",
route->ip_prefix, route->nexthop);
goto free_prefix_s;
}
char *policy = route->policy ? route->policy : "dst-ip";
add_route(lflows, out_port, lrp_addr_s, prefix_s, plen, route->nexthop,
policy);
free_prefix_s:
free(prefix_s);
}
static void
op_put_v4_networks(struct ds *ds, const struct ovn_port *op, bool add_bcast)
{
if (!add_bcast && op->lrp_networks.n_ipv4_addrs == 1) {
ds_put_format(ds, "%s", op->lrp_networks.ipv4_addrs[0].addr_s);
return;
}
ds_put_cstr(ds, "{");
for (int i = 0; i < op->lrp_networks.n_ipv4_addrs; i++) {
ds_put_format(ds, "%s, ", op->lrp_networks.ipv4_addrs[i].addr_s);
if (add_bcast) {
ds_put_format(ds, "%s, ", op->lrp_networks.ipv4_addrs[i].bcast_s);
}
}
ds_chomp(ds, ' ');
ds_chomp(ds, ',');
ds_put_cstr(ds, "}");
}
static void
op_put_v6_networks(struct ds *ds, const struct ovn_port *op)
{
if (op->lrp_networks.n_ipv6_addrs == 1) {
ds_put_format(ds, "%s", op->lrp_networks.ipv6_addrs[0].addr_s);
return;
}
ds_put_cstr(ds, "{");
for (int i = 0; i < op->lrp_networks.n_ipv6_addrs; i++) {
ds_put_format(ds, "%s, ", op->lrp_networks.ipv6_addrs[i].addr_s);
}
ds_chomp(ds, ' ');
ds_chomp(ds, ',');
ds_put_cstr(ds, "}");
}
static const char *
get_force_snat_ip(struct ovn_datapath *od, const char *key_type, ovs_be32 *ip)
{
char *key = xasprintf("%s_force_snat_ip", key_type);
const char *ip_address = smap_get(&od->nbr->options, key);
free(key);
if (ip_address) {
ovs_be32 mask;
char *error = ip_parse_masked(ip_address, ip, &mask);
if (error || mask != OVS_BE32_MAX) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip %s in options of router "UUID_FMT"",
ip_address, UUID_ARGS(&od->key));
free(error);
*ip = 0;
return NULL;
}
return ip_address;
}
*ip = 0;
return NULL;
}
static void
add_router_lb_flow(struct hmap *lflows, struct ovn_datapath *od,
struct ds *match, struct ds *actions, int priority,
const char *lb_force_snat_ip)
{
/* A match and actions for new connections. */
char *new_match = xasprintf("ct.new && %s", ds_cstr(match));
if (lb_force_snat_ip) {
char *new_actions = xasprintf("flags.force_snat_for_lb = 1; %s",
ds_cstr(actions));
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, priority, new_match,
new_actions);
free(new_actions);
} else {
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, priority, new_match,
ds_cstr(actions));
}
/* A match and actions for established connections. */
char *est_match = xasprintf("ct.est && %s", ds_cstr(match));
if (lb_force_snat_ip) {
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, priority, est_match,
"flags.force_snat_for_lb = 1; ct_dnat;");
} else {
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, priority, est_match,
"ct_dnat;");
}
free(new_match);
free(est_match);
}
static void
build_lrouter_flows(struct hmap *datapaths, struct hmap *ports,
struct hmap *lflows)
{
/* This flow table structure is documented in ovn-northd(8), so please
* update ovn-northd.8.xml if you change anything. */
struct ds match = DS_EMPTY_INITIALIZER;
struct ds actions = DS_EMPTY_INITIALIZER;
/* Logical router ingress table 0: Admission control framework. */
struct ovn_datapath *od;
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
/* Logical VLANs not supported.
* Broadcast/multicast source address is invalid. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_ADMISSION, 100,
"vlan.present || eth.src[40]", "drop;");
}
/* Logical router ingress table 0: match (priority 50). */
struct ovn_port *op;
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbrp) {
continue;
}
if (!lrport_is_enabled(op->nbrp)) {
/* Drop packets from disabled logical ports (since logical flow
* tables are default-drop). */
continue;
}
if (op->derived) {
/* No ingress packets should be received on a chassisredirect
* port. */
continue;
}
ds_clear(&match);
ds_put_format(&match, "eth.mcast && inport == %s", op->json_key);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_ADMISSION, 50,
ds_cstr(&match), "next;");
ds_clear(&match);
ds_put_format(&match, "eth.dst == %s && inport == %s",
op->lrp_networks.ea_s, op->json_key);
if (op->od->l3dgw_port && op == op->od->l3dgw_port
&& op->od->l3redirect_port) {
/* Traffic with eth.dst = l3dgw_port->lrp_networks.ea_s
* should only be received on the "redirect-chassis". */
ds_put_format(&match, " && is_chassis_resident(%s)",
op->od->l3redirect_port->json_key);
}
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_ADMISSION, 50,
ds_cstr(&match), "next;");
}
/* Logical router ingress table 1: IP Input. */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
/* L3 admission control: drop multicast and broadcast source, localhost
* source or destination, and zero network source or destination
* (priority 100). */
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 100,
"ip4.mcast || "
"ip4.src == 255.255.255.255 || "
"ip4.src == 127.0.0.0/8 || "
"ip4.dst == 127.0.0.0/8 || "
"ip4.src == 0.0.0.0/8 || "
"ip4.dst == 0.0.0.0/8",
"drop;");
/* ARP reply handling. Use ARP replies to populate the logical
* router's ARP table. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 90, "arp.op == 2",
"put_arp(inport, arp.spa, arp.sha);");
/* Drop Ethernet local broadcast. By definition this traffic should
* not be forwarded.*/
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 50,
"eth.bcast", "drop;");
/* TTL discard.
*
* XXX Need to send ICMP time exceeded if !ip.later_frag. */
ds_clear(&match);
ds_put_cstr(&match, "ip4 && ip.ttl == {0, 1}");
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 30,
ds_cstr(&match), "drop;");
/* ND advertisement handling. Use advertisements to populate
* the logical router's ARP/ND table. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 90, "nd_na",
"put_nd(inport, nd.target, nd.tll);");
/* Lean from neighbor solicitations that were not directed at
* us. (A priority-90 flow will respond to requests to us and
* learn the sender's mac address. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 80, "nd_ns",
"put_nd(inport, ip6.src, nd.sll);");
/* Pass other traffic not already handled to the next table for
* routing. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_INPUT, 0, "1", "next;");
}
/* Logical router ingress table 1: IP Input for IPv4. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbrp) {
continue;
}
if (op->derived) {
/* No ingress packets are accepted on a chassisredirect
* port, so no need to program flows for that port. */
continue;
}
if (op->lrp_networks.n_ipv4_addrs) {
/* L3 admission control: drop packets that originate from an
* IPv4 address owned by the router or a broadcast address
* known to the router (priority 100). */
ds_clear(&match);
ds_put_cstr(&match, "ip4.src == ");
op_put_v4_networks(&match, op, true);
ds_put_cstr(&match, " && "REGBIT_EGRESS_LOOPBACK" == 0");
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 100,
ds_cstr(&match), "drop;");
/* ICMP echo reply. These flows reply to ICMP echo requests
* received for the router's IP address. Since packets only
* get here as part of the logical router datapath, the inport
* (i.e. the incoming locally attached net) does not matter.
* The ip.ttl also does not matter (RFC1812 section 4.2.2.9) */
ds_clear(&match);
ds_put_cstr(&match, "ip4.dst == ");
op_put_v4_networks(&match, op, false);
ds_put_cstr(&match, " && icmp4.type == 8 && icmp4.code == 0");
ds_clear(&actions);
ds_put_format(&actions,
"ip4.dst <-> ip4.src; "
"ip.ttl = 255; "
"icmp4.type = 0; "
"flags.loopback = 1; "
"next; ");
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 90,
ds_cstr(&match), ds_cstr(&actions));
}
/* ARP reply. These flows reply to ARP requests for the router's own
* IP address. */
for (int i = 0; i < op->lrp_networks.n_ipv4_addrs; i++) {
ds_clear(&match);
ds_put_format(&match,
"inport == %s && arp.tpa == %s && arp.op == 1",
op->json_key, op->lrp_networks.ipv4_addrs[i].addr_s);
if (op->od->l3dgw_port && op == op->od->l3dgw_port
&& op->od->l3redirect_port) {
/* Traffic with eth.src = l3dgw_port->lrp_networks.ea_s
* should only be sent from the "redirect-chassis", so that
* upstream MAC learning points to the "redirect-chassis".
* Also need to avoid generation of multiple ARP responses
* from different chassis. */
ds_put_format(&match, " && is_chassis_resident(%s)",
op->od->l3redirect_port->json_key);
}
ds_clear(&actions);
ds_put_format(&actions,
"eth.dst = eth.src; "
"eth.src = %s; "
"arp.op = 2; /* ARP reply */ "
"arp.tha = arp.sha; "
"arp.sha = %s; "
"arp.tpa = arp.spa; "
"arp.spa = %s; "
"outport = %s; "
"flags.loopback = 1; "
"output;",
op->lrp_networks.ea_s,
op->lrp_networks.ea_s,
op->lrp_networks.ipv4_addrs[i].addr_s,
op->json_key);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 90,
ds_cstr(&match), ds_cstr(&actions));
}
/* A set to hold all load-balancer vips that need ARP responses. */
struct sset all_ips = SSET_INITIALIZER(&all_ips);
get_router_load_balancer_ips(op->od, &all_ips);
const char *ip_address;
SSET_FOR_EACH(ip_address, &all_ips) {
ovs_be32 ip;
if (!ip_parse(ip_address, &ip) || !ip) {
continue;
}
ds_clear(&match);
ds_put_format(&match,
"inport == %s && arp.tpa == "IP_FMT" && arp.op == 1",
op->json_key, IP_ARGS(ip));
ds_clear(&actions);
ds_put_format(&actions,
"eth.dst = eth.src; "
"eth.src = %s; "
"arp.op = 2; /* ARP reply */ "
"arp.tha = arp.sha; "
"arp.sha = %s; "
"arp.tpa = arp.spa; "
"arp.spa = "IP_FMT"; "
"outport = %s; "
"flags.loopback = 1; "
"output;",
op->lrp_networks.ea_s,
op->lrp_networks.ea_s,
IP_ARGS(ip),
op->json_key);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 90,
ds_cstr(&match), ds_cstr(&actions));
}
sset_destroy(&all_ips);
/* A gateway router can have 2 SNAT IP addresses to force DNATed and
* LBed traffic respectively to be SNATed. In addition, there can be
* a number of SNAT rules in the NAT table. */
ovs_be32 *snat_ips = xmalloc(sizeof *snat_ips *
(op->od->nbr->n_nat + 2));
size_t n_snat_ips = 0;
ovs_be32 snat_ip;
const char *dnat_force_snat_ip = get_force_snat_ip(op->od, "dnat",
&snat_ip);
if (dnat_force_snat_ip) {
snat_ips[n_snat_ips++] = snat_ip;
}
const char *lb_force_snat_ip = get_force_snat_ip(op->od, "lb",
&snat_ip);
if (lb_force_snat_ip) {
snat_ips[n_snat_ips++] = snat_ip;
}
for (int i = 0; i < op->od->nbr->n_nat; i++) {
const struct nbrec_nat *nat;
nat = op->od->nbr->nat[i];
ovs_be32 ip;
if (!ip_parse(nat->external_ip, &ip) || !ip) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip address %s in nat configuration "
"for router %s", nat->external_ip, op->key);
continue;
}
if (!strcmp(nat->type, "snat")) {
snat_ips[n_snat_ips++] = ip;
continue;
}
/* ARP handling for external IP addresses.
*
* DNAT IP addresses are external IP addresses that need ARP
* handling. */
ds_clear(&match);
ds_put_format(&match,
"inport == %s && arp.tpa == "IP_FMT" && arp.op == 1",
op->json_key, IP_ARGS(ip));
ds_clear(&actions);
ds_put_format(&actions,
"eth.dst = eth.src; "
"arp.op = 2; /* ARP reply */ "
"arp.tha = arp.sha; ");
if (op->od->l3dgw_port && op == op->od->l3dgw_port) {
struct eth_addr mac;
if (nat->external_mac &&
eth_addr_from_string(nat->external_mac, &mac)
&& nat->logical_port) {
/* distributed NAT case, use nat->external_mac */
ds_put_format(&actions,
"eth.src = "ETH_ADDR_FMT"; "
"arp.sha = "ETH_ADDR_FMT"; ",
ETH_ADDR_ARGS(mac),
ETH_ADDR_ARGS(mac));
/* Traffic with eth.src = nat->external_mac should only be
* sent from the chassis where nat->logical_port is
* resident, so that upstream MAC learning points to the
* correct chassis. Also need to avoid generation of
* multiple ARP responses from different chassis. */
ds_put_format(&match, " && is_chassis_resident(\"%s\")",
nat->logical_port);
} else {
ds_put_format(&actions,
"eth.src = %s; "
"arp.sha = %s; ",
op->lrp_networks.ea_s,
op->lrp_networks.ea_s);
/* Traffic with eth.src = l3dgw_port->lrp_networks.ea_s
* should only be sent from the "redirect-chassis", so that
* upstream MAC learning points to the "redirect-chassis".
* Also need to avoid generation of multiple ARP responses
* from different chassis. */
if (op->od->l3redirect_port) {
ds_put_format(&match, " && is_chassis_resident(%s)",
op->od->l3redirect_port->json_key);
}
}
} else {
ds_put_format(&actions,
"eth.src = %s; "
"arp.sha = %s; ",
op->lrp_networks.ea_s,
op->lrp_networks.ea_s);
}
ds_put_format(&actions,
"arp.tpa = arp.spa; "
"arp.spa = "IP_FMT"; "
"outport = %s; "
"flags.loopback = 1; "
"output;",
IP_ARGS(ip),
op->json_key);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 90,
ds_cstr(&match), ds_cstr(&actions));
}
ds_clear(&match);
ds_put_cstr(&match, "ip4.dst == {");
bool has_drop_ips = false;
for (int i = 0; i < op->lrp_networks.n_ipv4_addrs; i++) {
bool snat_ip_is_router_ip = false;
for (int j = 0; j < n_snat_ips; j++) {
/* Packets to SNAT IPs should not be dropped. */
if (op->lrp_networks.ipv4_addrs[i].addr == snat_ips[j]) {
snat_ip_is_router_ip = true;
break;
}
}
if (snat_ip_is_router_ip) {
continue;
}
ds_put_format(&match, "%s, ",
op->lrp_networks.ipv4_addrs[i].addr_s);
has_drop_ips = true;
}
ds_chomp(&match, ' ');
ds_chomp(&match, ',');
ds_put_cstr(&match, "}");
if (has_drop_ips) {
/* Drop IP traffic to this router. */
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 60,
ds_cstr(&match), "drop;");
}
free(snat_ips);
}
/* Logical router ingress table 1: IP Input for IPv6. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbrp) {
continue;
}
if (op->derived) {
/* No ingress packets are accepted on a chassisredirect
* port, so no need to program flows for that port. */
continue;
}
if (op->lrp_networks.n_ipv6_addrs) {
/* L3 admission control: drop packets that originate from an
* IPv6 address owned by the router (priority 100). */
ds_clear(&match);
ds_put_cstr(&match, "ip6.src == ");
op_put_v6_networks(&match, op);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 100,
ds_cstr(&match), "drop;");
/* ICMPv6 echo reply. These flows reply to echo requests
* received for the router's IP address. */
ds_clear(&match);
ds_put_cstr(&match, "ip6.dst == ");
op_put_v6_networks(&match, op);
ds_put_cstr(&match, " && icmp6.type == 128 && icmp6.code == 0");
ds_clear(&actions);
ds_put_cstr(&actions,
"ip6.dst <-> ip6.src; "
"ip.ttl = 255; "
"icmp6.type = 129; "
"flags.loopback = 1; "
"next; ");
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 90,
ds_cstr(&match), ds_cstr(&actions));
/* Drop IPv6 traffic to this router. */
ds_clear(&match);
ds_put_cstr(&match, "ip6.dst == ");
op_put_v6_networks(&match, op);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 60,
ds_cstr(&match), "drop;");
}
/* ND reply. These flows reply to ND solicitations for the
* router's own IP address. */
for (int i = 0; i < op->lrp_networks.n_ipv6_addrs; i++) {
ds_clear(&match);
ds_put_format(&match,
"inport == %s && nd_ns && ip6.dst == {%s, %s} "
"&& nd.target == %s",
op->json_key,
op->lrp_networks.ipv6_addrs[i].addr_s,
op->lrp_networks.ipv6_addrs[i].sn_addr_s,
op->lrp_networks.ipv6_addrs[i].addr_s);
if (op->od->l3dgw_port && op == op->od->l3dgw_port
&& op->od->l3redirect_port) {
/* Traffic with eth.src = l3dgw_port->lrp_networks.ea_s
* should only be sent from the "redirect-chassis", so that
* upstream MAC learning points to the "redirect-chassis".
* Also need to avoid generation of multiple ND replies
* from different chassis. */
ds_put_format(&match, " && is_chassis_resident(%s)",
op->od->l3redirect_port->json_key);
}
ds_clear(&actions);
ds_put_format(&actions,
"put_nd(inport, ip6.src, nd.sll); "
"nd_na { "
"eth.src = %s; "
"ip6.src = %s; "
"nd.target = %s; "
"nd.tll = %s; "
"outport = inport; "
"flags.loopback = 1; "
"output; "
"};",
op->lrp_networks.ea_s,
op->lrp_networks.ipv6_addrs[i].addr_s,
op->lrp_networks.ipv6_addrs[i].addr_s,
op->lrp_networks.ea_s);
ovn_lflow_add(lflows, op->od, S_ROUTER_IN_IP_INPUT, 90,
ds_cstr(&match), ds_cstr(&actions));
}
}
/* NAT, Defrag and load balancing. */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
/* Packets are allowed by default. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_DEFRAG, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_ROUTER_IN_UNSNAT, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_ROUTER_OUT_SNAT, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_ROUTER_OUT_UNDNAT, 0, "1", "next;");
ovn_lflow_add(lflows, od, S_ROUTER_OUT_EGR_LOOP, 0, "1", "next;");
/* NAT rules are only valid on Gateway routers and routers with
* l3dgw_port (router has a port with "redirect-chassis"
* specified). */
if (!smap_get(&od->nbr->options, "chassis") && !od->l3dgw_port) {
continue;
}
ovs_be32 snat_ip;
const char *dnat_force_snat_ip = get_force_snat_ip(od, "dnat",
&snat_ip);
const char *lb_force_snat_ip = get_force_snat_ip(od, "lb",
&snat_ip);
for (int i = 0; i < od->nbr->n_nat; i++) {
const struct nbrec_nat *nat;
nat = od->nbr->nat[i];
ovs_be32 ip, mask;
char *error = ip_parse_masked(nat->external_ip, &ip, &mask);
if (error || mask != OVS_BE32_MAX) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad external ip %s for nat",
nat->external_ip);
free(error);
continue;
}
/* Check the validity of nat->logical_ip. 'logical_ip' can
* be a subnet when the type is "snat". */
error = ip_parse_masked(nat->logical_ip, &ip, &mask);
if (!strcmp(nat->type, "snat")) {
if (error) {
static struct vlog_rate_limit rl =
VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip network or ip %s for snat "
"in router "UUID_FMT"",
nat->logical_ip, UUID_ARGS(&od->key));
free(error);
continue;
}
} else {
if (error || mask != OVS_BE32_MAX) {
static struct vlog_rate_limit rl =
VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad ip %s for dnat in router "
""UUID_FMT"", nat->logical_ip, UUID_ARGS(&od->key));
free(error);
continue;
}
}
/* For distributed router NAT, determine whether this NAT rule
* satisfies the conditions for distributed NAT processing. */
bool distributed = false;
struct eth_addr mac;
if (od->l3dgw_port && !strcmp(nat->type, "dnat_and_snat") &&
nat->logical_port && nat->external_mac) {
if (eth_addr_from_string(nat->external_mac, &mac)) {
distributed = true;
} else {
static struct vlog_rate_limit rl =
VLOG_RATE_LIMIT_INIT(5, 1);
VLOG_WARN_RL(&rl, "bad mac %s for dnat in router "
""UUID_FMT"", nat->external_mac, UUID_ARGS(&od->key));
continue;
}
}
/* Ingress UNSNAT table: It is for already established connections'
* reverse traffic. i.e., SNAT has already been done in egress
* pipeline and now the packet has entered the ingress pipeline as
* part of a reply. We undo the SNAT here.
*
* Undoing SNAT has to happen before DNAT processing. This is
* because when the packet was DNATed in ingress pipeline, it did
* not know about the possibility of eventual additional SNAT in
* egress pipeline. */
if (!strcmp(nat->type, "snat")
|| !strcmp(nat->type, "dnat_and_snat")) {
if (!od->l3dgw_port) {
/* Gateway router. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s",
nat->external_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_UNSNAT, 90,
ds_cstr(&match), "ct_snat; next;");
} else {
/* Distributed router. */
/* Traffic received on l3dgw_port is subject to NAT. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s"
" && inport == %s",
nat->external_ip,
od->l3dgw_port->json_key);
if (!distributed && od->l3redirect_port) {
/* Flows for NAT rules that are centralized are only
* programmed on the "redirect-chassis". */
ds_put_format(&match, " && is_chassis_resident(%s)",
od->l3redirect_port->json_key);
}
ovn_lflow_add(lflows, od, S_ROUTER_IN_UNSNAT, 100,
ds_cstr(&match), "ct_snat;");
/* Traffic received on other router ports must be
* redirected to the central instance of the l3dgw_port
* for NAT processing. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s",
nat->external_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_UNSNAT, 50,
ds_cstr(&match),
REGBIT_NAT_REDIRECT" = 1; next;");
}
}
/* Ingress DNAT table: Packets enter the pipeline with destination
* IP address that needs to be DNATted from a external IP address
* to a logical IP address. */
if (!strcmp(nat->type, "dnat")
|| !strcmp(nat->type, "dnat_and_snat")) {
if (!od->l3dgw_port) {
/* Gateway router. */
/* Packet when it goes from the initiator to destination.
* We need to set flags.loopback because the router can
* send the packet back through the same interface. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s",
nat->external_ip);
ds_clear(&actions);
if (dnat_force_snat_ip) {
/* Indicate to the future tables that a DNAT has taken
* place and a force SNAT needs to be done in the
* Egress SNAT table. */
ds_put_format(&actions,
"flags.force_snat_for_dnat = 1; ");
}
ds_put_format(&actions, "flags.loopback = 1; ct_dnat(%s);",
nat->logical_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, 100,
ds_cstr(&match), ds_cstr(&actions));
} else {
/* Distributed router. */
/* Traffic received on l3dgw_port is subject to NAT. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s"
" && inport == %s",
nat->external_ip,
od->l3dgw_port->json_key);
if (!distributed && od->l3redirect_port) {
/* Flows for NAT rules that are centralized are only
* programmed on the "redirect-chassis". */
ds_put_format(&match, " && is_chassis_resident(%s)",
od->l3redirect_port->json_key);
}
ds_clear(&actions);
ds_put_format(&actions, "ct_dnat(%s);",
nat->logical_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, 100,
ds_cstr(&match), ds_cstr(&actions));
/* Traffic received on other router ports must be
* redirected to the central instance of the l3dgw_port
* for NAT processing. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s",
nat->external_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, 50,
ds_cstr(&match),
REGBIT_NAT_REDIRECT" = 1; next;");
}
}
/* Egress UNDNAT table: It is for already established connections'
* reverse traffic. i.e., DNAT has already been done in ingress
* pipeline and now the packet has entered the egress pipeline as
* part of a reply. We undo the DNAT here.
*
* Note that this only applies for NAT on a distributed router.
* Undo DNAT on a gateway router is done in the ingress DNAT
* pipeline stage. */
if (od->l3dgw_port && (!strcmp(nat->type, "dnat")
|| !strcmp(nat->type, "dnat_and_snat"))) {
ds_clear(&match);
ds_put_format(&match, "ip && ip4.src == %s"
" && outport == %s",
nat->logical_ip,
od->l3dgw_port->json_key);
if (!distributed && od->l3redirect_port) {
/* Flows for NAT rules that are centralized are only
* programmed on the "redirect-chassis". */
ds_put_format(&match, " && is_chassis_resident(%s)",
od->l3redirect_port->json_key);
}
ds_clear(&actions);
if (distributed) {
ds_put_format(&actions, "eth.src = "ETH_ADDR_FMT"; ",
ETH_ADDR_ARGS(mac));
}
ds_put_format(&actions, "ct_dnat;");
ovn_lflow_add(lflows, od, S_ROUTER_OUT_UNDNAT, 100,
ds_cstr(&match), ds_cstr(&actions));
}
/* Egress SNAT table: Packets enter the egress pipeline with
* source ip address that needs to be SNATted to a external ip
* address. */
if (!strcmp(nat->type, "snat")
|| !strcmp(nat->type, "dnat_and_snat")) {
if (!od->l3dgw_port) {
/* Gateway router. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.src == %s",
nat->logical_ip);
ds_clear(&actions);
ds_put_format(&actions, "ct_snat(%s);", nat->external_ip);
/* The priority here is calculated such that the
* nat->logical_ip with the longest mask gets a higher
* priority. */
ovn_lflow_add(lflows, od, S_ROUTER_OUT_SNAT,
count_1bits(ntohl(mask)) + 1,
ds_cstr(&match), ds_cstr(&actions));
} else {
/* Distributed router. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.src == %s"
" && outport == %s",
nat->logical_ip,
od->l3dgw_port->json_key);
if (!distributed && od->l3redirect_port) {
/* Flows for NAT rules that are centralized are only
* programmed on the "redirect-chassis". */
ds_put_format(&match, " && is_chassis_resident(%s)",
od->l3redirect_port->json_key);
}
ds_clear(&actions);
if (distributed) {
ds_put_format(&actions, "eth.src = "ETH_ADDR_FMT"; ",
ETH_ADDR_ARGS(mac));
}
ds_put_format(&actions, "ct_snat(%s);", nat->external_ip);
/* The priority here is calculated such that the
* nat->logical_ip with the longest mask gets a higher
* priority. */
ovn_lflow_add(lflows, od, S_ROUTER_OUT_SNAT,
count_1bits(ntohl(mask)) + 1,
ds_cstr(&match), ds_cstr(&actions));
}
}
/* Logical router ingress table 0:
* For NAT on a distributed router, add rules allowing
* ingress traffic with eth.dst matching nat->external_mac
* on the l3dgw_port instance where nat->logical_port is
* resident. */
if (distributed) {
ds_clear(&match);
ds_put_format(&match,
"eth.dst == "ETH_ADDR_FMT" && inport == %s"
" && is_chassis_resident(\"%s\")",
ETH_ADDR_ARGS(mac),
od->l3dgw_port->json_key,
nat->logical_port);
ovn_lflow_add(lflows, od, S_ROUTER_IN_ADMISSION, 50,
ds_cstr(&match), "next;");
}
/* Ingress Gateway Redirect Table: For NAT on a distributed
* router, add flows that are specific to a NAT rule. These
* flows indicate the presence of an applicable NAT rule that
* can be applied in a distributed manner. */
if (distributed) {
ds_clear(&match);
ds_put_format(&match, "ip4.src == %s && outport == %s",
nat->logical_ip,
od->l3dgw_port->json_key);
ovn_lflow_add(lflows, od, S_ROUTER_IN_GW_REDIRECT, 100,
ds_cstr(&match), "next;");
}
/* Egress Loopback table: For NAT on a distributed router.
* If packets in the egress pipeline on the distributed
* gateway port have ip.dst matching a NAT external IP, then
* loop a clone of the packet back to the beginning of the
* ingress pipeline with inport = outport. */
if (od->l3dgw_port) {
/* Distributed router. */
ds_clear(&match);
ds_put_format(&match, "ip4.dst == %s && outport == %s",
nat->external_ip,
od->l3dgw_port->json_key);
ds_clear(&actions);
ds_put_format(&actions,
"clone { ct_clear; "
"inport = outport; outport = \"\"; "
"flags = 0; flags.loopback = 1; ");
for (int i = 0; i < MFF_N_LOG_REGS; i++) {
ds_put_format(&actions, "reg%d = 0; ", i);
}
ds_put_format(&actions, REGBIT_EGRESS_LOOPBACK" = 1; "
"next(pipeline=ingress, table=0); };");
ovn_lflow_add(lflows, od, S_ROUTER_OUT_EGR_LOOP, 100,
ds_cstr(&match), ds_cstr(&actions));
}
}
/* Handle force SNAT options set in the gateway router. */
if (dnat_force_snat_ip && !od->l3dgw_port) {
/* If a packet with destination IP address as that of the
* gateway router (as set in options:dnat_force_snat_ip) is seen,
* UNSNAT it. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s", dnat_force_snat_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_UNSNAT, 110,
ds_cstr(&match), "ct_snat; next;");
/* Higher priority rules to force SNAT with the IP addresses
* configured in the Gateway router. This only takes effect
* when the packet has already been DNATed once. */
ds_clear(&match);
ds_put_format(&match, "flags.force_snat_for_dnat == 1 && ip");
ds_clear(&actions);
ds_put_format(&actions, "ct_snat(%s);", dnat_force_snat_ip);
ovn_lflow_add(lflows, od, S_ROUTER_OUT_SNAT, 100,
ds_cstr(&match), ds_cstr(&actions));
}
if (lb_force_snat_ip && !od->l3dgw_port) {
/* If a packet with destination IP address as that of the
* gateway router (as set in options:lb_force_snat_ip) is seen,
* UNSNAT it. */
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s", lb_force_snat_ip);
ovn_lflow_add(lflows, od, S_ROUTER_IN_UNSNAT, 100,
ds_cstr(&match), "ct_snat; next;");
/* Load balanced traffic will have flags.force_snat_for_lb set.
* Force SNAT it. */
ds_clear(&match);
ds_put_format(&match, "flags.force_snat_for_lb == 1 && ip");
ds_clear(&actions);
ds_put_format(&actions, "ct_snat(%s);", lb_force_snat_ip);
ovn_lflow_add(lflows, od, S_ROUTER_OUT_SNAT, 100,
ds_cstr(&match), ds_cstr(&actions));
}
if (!od->l3dgw_port) {
/* For gateway router, re-circulate every packet through
* the DNAT zone. This helps with two things.
*
* 1. Any packet that needs to be unDNATed in the reverse
* direction gets unDNATed. Ideally this could be done in
* the egress pipeline. But since the gateway router
* does not have any feature that depends on the source
* ip address being external IP address for IP routing,
* we can do it here, saving a future re-circulation.
*
* 2. Any packet that was sent through SNAT zone in the
* previous table automatically gets re-circulated to get
* back the new destination IP address that is needed for
* routing in the openflow pipeline. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_DNAT, 50,
"ip", "flags.loopback = 1; ct_dnat;");
} else {
/* For NAT on a distributed router, add flows to Ingress
* IP Routing table, Ingress ARP Resolution table, and
* Ingress Gateway Redirect Table that are not specific to a
* NAT rule. */
/* The highest priority IN_IP_ROUTING rule matches packets
* with REGBIT_NAT_REDIRECT (set in DNAT or UNSNAT stages),
* with action "ip.ttl--; next;". The IN_GW_REDIRECT table
* will take care of setting the outport. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_IP_ROUTING, 300,
REGBIT_NAT_REDIRECT" == 1", "ip.ttl--; next;");
/* The highest priority IN_ARP_RESOLVE rule matches packets
* with REGBIT_NAT_REDIRECT (set in DNAT or UNSNAT stages),
* then sets eth.dst to the distributed gateway port's
* ethernet address. */
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;",
od->l3dgw_port->lrp_networks.ea_s);
ovn_lflow_add(lflows, od, S_ROUTER_IN_ARP_RESOLVE, 200,
REGBIT_NAT_REDIRECT" == 1", ds_cstr(&actions));
/* The highest priority IN_GW_REDIRECT rule redirects packets
* with REGBIT_NAT_REDIRECT (set in DNAT or UNSNAT stages) to
* the central instance of the l3dgw_port for NAT processing. */
ds_clear(&actions);
ds_put_format(&actions, "outport = %s; next;",
od->l3redirect_port->json_key);
ovn_lflow_add(lflows, od, S_ROUTER_IN_GW_REDIRECT, 200,
REGBIT_NAT_REDIRECT" == 1", ds_cstr(&actions));
}
/* Load balancing and packet defrag are only valid on
* Gateway routers. */
if (!smap_get(&od->nbr->options, "chassis")) {
continue;
}
/* A set to hold all ips that need defragmentation and tracking. */
struct sset all_ips = SSET_INITIALIZER(&all_ips);
for (int i = 0; i < od->nbr->n_load_balancer; i++) {
struct nbrec_load_balancer *lb = od->nbr->load_balancer[i];
struct smap *vips = &lb->vips;
struct smap_node *node;
SMAP_FOR_EACH (node, vips) {
uint16_t port = 0;
/* node->key contains IP:port or just IP. */
char *ip_address = NULL;
ip_address_and_port_from_lb_key(node->key, &ip_address, &port);
if (!ip_address) {
continue;
}
if (!sset_contains(&all_ips, ip_address)) {
sset_add(&all_ips, ip_address);
}
/* Higher priority rules are added for load-balancing in DNAT
* table. For every match (on a VIP[:port]), we add two flows
* via add_router_lb_flow(). One flow is for specific matching
* on ct.new with an action of "ct_lb($targets);". The other
* flow is for ct.est with an action of "ct_dnat;". */
ds_clear(&actions);
ds_put_format(&actions, "ct_lb(%s);", node->value);
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s",
ip_address);
free(ip_address);
if (port) {
if (lb->protocol && !strcmp(lb->protocol, "udp")) {
ds_put_format(&match, " && udp && udp.dst == %d",
port);
} else {
ds_put_format(&match, " && tcp && tcp.dst == %d",
port);
}
add_router_lb_flow(lflows, od, &match, &actions, 120,
lb_force_snat_ip);
} else {
add_router_lb_flow(lflows, od, &match, &actions, 110,
lb_force_snat_ip);
}
}
}
/* If there are any load balancing rules, we should send the
* packet to conntrack for defragmentation and tracking. This helps
* with two things.
*
* 1. With tracking, we can send only new connections to pick a
* DNAT ip address from a group.
* 2. If there are L4 ports in load balancing rules, we need the
* defragmentation to match on L4 ports. */
const char *ip_address;
SSET_FOR_EACH(ip_address, &all_ips) {
ds_clear(&match);
ds_put_format(&match, "ip && ip4.dst == %s", ip_address);
ovn_lflow_add(lflows, od, S_ROUTER_IN_DEFRAG,
100, ds_cstr(&match), "ct_next;");
}
sset_destroy(&all_ips);
}
/* Logical router ingress table 5: IP Routing.
*
* A packet that arrives at this table is an IP packet that should be
* routed to the address in 'ip[46].dst'. This table sets outport to
* the correct output port, eth.src to the output port's MAC
* address, and '[xx]reg0' to the next-hop IP address (leaving
* 'ip[46].dst', the packet’s final destination, unchanged), and
* advances to the next table for ARP/ND resolution. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbrp) {
continue;
}
for (int i = 0; i < op->lrp_networks.n_ipv4_addrs; i++) {
add_route(lflows, op, op->lrp_networks.ipv4_addrs[i].addr_s,
op->lrp_networks.ipv4_addrs[i].network_s,
op->lrp_networks.ipv4_addrs[i].plen, NULL, NULL);
}
for (int i = 0; i < op->lrp_networks.n_ipv6_addrs; i++) {
add_route(lflows, op, op->lrp_networks.ipv6_addrs[i].addr_s,
op->lrp_networks.ipv6_addrs[i].network_s,
op->lrp_networks.ipv6_addrs[i].plen, NULL, NULL);
}
}
/* Convert the static routes to flows. */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
for (int i = 0; i < od->nbr->n_static_routes; i++) {
const struct nbrec_logical_router_static_route *route;
route = od->nbr->static_routes[i];
build_static_route_flow(lflows, od, ports, route);
}
}
/* XXX destination unreachable */
/* Local router ingress table 6: ARP Resolution.
*
* Any packet that reaches this table is an IP packet whose next-hop IP
* address is in reg0. (ip4.dst is the final destination.) This table
* resolves the IP address in reg0 into an output port in outport and an
* Ethernet address in eth.dst. */
HMAP_FOR_EACH (op, key_node, ports) {
if (op->nbrp) {
/* This is a logical router port. If next-hop IP address in
* '[xx]reg0' matches IP address of this router port, then
* the packet is intended to eventually be sent to this
* logical port. Set the destination mac address using this
* port's mac address.
*
* The packet is still in peer's logical pipeline. So the match
* should be on peer's outport. */
if (op->peer && op->nbrp->peer) {
if (op->lrp_networks.n_ipv4_addrs) {
ds_clear(&match);
ds_put_format(&match, "outport == %s && reg0 == ",
op->peer->json_key);
op_put_v4_networks(&match, op, false);
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;",
op->lrp_networks.ea_s);
ovn_lflow_add(lflows, op->peer->od, S_ROUTER_IN_ARP_RESOLVE,
100, ds_cstr(&match), ds_cstr(&actions));
}
if (op->lrp_networks.n_ipv6_addrs) {
ds_clear(&match);
ds_put_format(&match, "outport == %s && xxreg0 == ",
op->peer->json_key);
op_put_v6_networks(&match, op);
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;",
op->lrp_networks.ea_s);
ovn_lflow_add(lflows, op->peer->od, S_ROUTER_IN_ARP_RESOLVE,
100, ds_cstr(&match), ds_cstr(&actions));
}
}
} else if (op->od->n_router_ports && strcmp(op->nbsp->type, "router")) {
/* This is a logical switch port that backs a VM or a container.
* Extract its addresses. For each of the address, go through all
* the router ports attached to the switch (to which this port
* connects) and if the address in question is reachable from the
* router port, add an ARP/ND entry in that router's pipeline. */
for (size_t i = 0; i < op->n_lsp_addrs; i++) {
const char *ea_s = op->lsp_addrs[i].ea_s;
for (size_t j = 0; j < op->lsp_addrs[i].n_ipv4_addrs; j++) {
const char *ip_s = op->lsp_addrs[i].ipv4_addrs[j].addr_s;
for (size_t k = 0; k < op->od->n_router_ports; k++) {
/* Get the Logical_Router_Port that the
* Logical_Switch_Port is connected to, as
* 'peer'. */
const char *peer_name = smap_get(
&op->od->router_ports[k]->nbsp->options,
"router-port");
if (!peer_name) {
continue;
}
struct ovn_port *peer = ovn_port_find(ports, peer_name);
if (!peer || !peer->nbrp) {
continue;
}
if (!find_lrp_member_ip(peer, ip_s)) {
continue;
}
ds_clear(&match);
ds_put_format(&match, "outport == %s && reg0 == %s",
peer->json_key, ip_s);
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;", ea_s);
ovn_lflow_add(lflows, peer->od,
S_ROUTER_IN_ARP_RESOLVE, 100,
ds_cstr(&match), ds_cstr(&actions));
}
}
for (size_t j = 0; j < op->lsp_addrs[i].n_ipv6_addrs; j++) {
const char *ip_s = op->lsp_addrs[i].ipv6_addrs[j].addr_s;
for (size_t k = 0; k < op->od->n_router_ports; k++) {
/* Get the Logical_Router_Port that the
* Logical_Switch_Port is connected to, as
* 'peer'. */
const char *peer_name = smap_get(
&op->od->router_ports[k]->nbsp->options,
"router-port");
if (!peer_name) {
continue;
}
struct ovn_port *peer = ovn_port_find(ports, peer_name);
if (!peer || !peer->nbrp) {
continue;
}
if (!find_lrp_member_ip(peer, ip_s)) {
continue;
}
ds_clear(&match);
ds_put_format(&match, "outport == %s && xxreg0 == %s",
peer->json_key, ip_s);
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;", ea_s);
ovn_lflow_add(lflows, peer->od,
S_ROUTER_IN_ARP_RESOLVE, 100,
ds_cstr(&match), ds_cstr(&actions));
}
}
}
} else if (!strcmp(op->nbsp->type, "router")) {
/* This is a logical switch port that connects to a router. */
/* The peer of this switch port is the router port for which
* we need to add logical flows such that it can resolve
* ARP entries for all the other router ports connected to
* the switch in question. */
const char *peer_name = smap_get(&op->nbsp->options,
"router-port");
if (!peer_name) {
continue;
}
struct ovn_port *peer = ovn_port_find(ports, peer_name);
if (!peer || !peer->nbrp) {
continue;
}
for (size_t i = 0; i < op->od->n_router_ports; i++) {
const char *router_port_name = smap_get(
&op->od->router_ports[i]->nbsp->options,
"router-port");
struct ovn_port *router_port = ovn_port_find(ports,
router_port_name);
if (!router_port || !router_port->nbrp) {
continue;
}
/* Skip the router port under consideration. */
if (router_port == peer) {
continue;
}
if (router_port->lrp_networks.n_ipv4_addrs) {
ds_clear(&match);
ds_put_format(&match, "outport == %s && reg0 == ",
peer->json_key);
op_put_v4_networks(&match, router_port, false);
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;",
router_port->lrp_networks.ea_s);
ovn_lflow_add(lflows, peer->od, S_ROUTER_IN_ARP_RESOLVE,
100, ds_cstr(&match), ds_cstr(&actions));
}
if (router_port->lrp_networks.n_ipv6_addrs) {
ds_clear(&match);
ds_put_format(&match, "outport == %s && xxreg0 == ",
peer->json_key);
op_put_v6_networks(&match, router_port);
ds_clear(&actions);
ds_put_format(&actions, "eth.dst = %s; next;",
router_port->lrp_networks.ea_s);
ovn_lflow_add(lflows, peer->od, S_ROUTER_IN_ARP_RESOLVE,
100, ds_cstr(&match), ds_cstr(&actions));
}
}
}
}
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
ovn_lflow_add(lflows, od, S_ROUTER_IN_ARP_RESOLVE, 0, "ip4",
"get_arp(outport, reg0); next;");
ovn_lflow_add(lflows, od, S_ROUTER_IN_ARP_RESOLVE, 0, "ip6",
"get_nd(outport, xxreg0); next;");
}
/* Logical router ingress table 7: Gateway redirect.
*
* For traffic with outport equal to the l3dgw_port
* on a distributed router, this table redirects a subset
* of the traffic to the l3redirect_port which represents
* the central instance of the l3dgw_port.
*/
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
if (od->l3dgw_port && od->l3redirect_port) {
/* For traffic with outport == l3dgw_port, if the
* packet did not match any higher priority redirect
* rule, then the traffic is redirected to the central
* instance of the l3dgw_port. */
ds_clear(&match);
ds_put_format(&match, "outport == %s",
od->l3dgw_port->json_key);
ds_clear(&actions);
ds_put_format(&actions, "outport = %s; next;",
od->l3redirect_port->json_key);
ovn_lflow_add(lflows, od, S_ROUTER_IN_GW_REDIRECT, 50,
ds_cstr(&match), ds_cstr(&actions));
/* If the Ethernet destination has not been resolved,
* redirect to the central instance of the l3dgw_port.
* Such traffic will be replaced by an ARP request or ND
* Neighbor Solicitation in the ARP request ingress
* table, before being redirected to the central instance.
*/
ds_put_format(&match, " && eth.dst == 00:00:00:00:00:00");
ovn_lflow_add(lflows, od, S_ROUTER_IN_GW_REDIRECT, 150,
ds_cstr(&match), ds_cstr(&actions));
}
/* Packets are allowed by default. */
ovn_lflow_add(lflows, od, S_ROUTER_IN_GW_REDIRECT, 0, "1", "next;");
}
/* Local router ingress table 8: ARP request.
*
* In the common case where the Ethernet destination has been resolved,
* this table outputs the packet (priority 0). Otherwise, it composes
* and sends an ARP request (priority 100). */
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbr) {
continue;
}
ovn_lflow_add(lflows, od, S_ROUTER_IN_ARP_REQUEST, 100,
"eth.dst == 00:00:00:00:00:00",
"arp { "
"eth.dst = ff:ff:ff:ff:ff:ff; "
"arp.spa = reg1; "
"arp.tpa = reg0; "
"arp.op = 1; " /* ARP request */
"output; "
"};");
ovn_lflow_add(lflows, od, S_ROUTER_IN_ARP_REQUEST, 0, "1", "output;");
}
/* Logical router egress table 1: Delivery (priority 100).
*
* Priority 100 rules deliver packets to enabled logical ports. */
HMAP_FOR_EACH (op, key_node, ports) {
if (!op->nbrp) {
continue;
}
if (!lrport_is_enabled(op->nbrp)) {
/* Drop packets to disabled logical ports (since logical flow
* tables are default-drop). */
continue;
}
if (op->derived) {
/* No egress packets should be processed in the context of
* a chassisredirect port. The chassisredirect port should
* be replaced by the l3dgw port in the local output
* pipeline stage before egress processing. */
continue;
}
ds_clear(&match);
ds_put_format(&match, "outport == %s", op->json_key);
ovn_lflow_add(lflows, op->od, S_ROUTER_OUT_DELIVERY, 100,
ds_cstr(&match), "output;");
}
ds_destroy(&match);
ds_destroy(&actions);
}
/* Updates the Logical_Flow and Multicast_Group tables in the OVN_SB database,
* constructing their contents based on the OVN_NB database. */
static void
build_lflows(struct northd_context *ctx, struct hmap *datapaths,
struct hmap *ports)
{
struct hmap lflows = HMAP_INITIALIZER(&lflows);
struct hmap mcgroups = HMAP_INITIALIZER(&mcgroups);
build_lswitch_flows(datapaths, ports, &lflows, &mcgroups);
build_lrouter_flows(datapaths, ports, &lflows);
/* Push changes to the Logical_Flow table to database. */
const struct sbrec_logical_flow *sbflow, *next_sbflow;
SBREC_LOGICAL_FLOW_FOR_EACH_SAFE (sbflow, next_sbflow, ctx->ovnsb_idl) {
struct ovn_datapath *od
= ovn_datapath_from_sbrec(datapaths, sbflow->logical_datapath);
if (!od) {
sbrec_logical_flow_delete(sbflow);
continue;
}
enum ovn_datapath_type dp_type = od->nbs ? DP_SWITCH : DP_ROUTER;
enum ovn_pipeline pipeline
= !strcmp(sbflow->pipeline, "ingress") ? P_IN : P_OUT;
struct ovn_lflow *lflow = ovn_lflow_find(
&lflows, od, ovn_stage_build(dp_type, pipeline, sbflow->table_id),
sbflow->priority, sbflow->match, sbflow->actions);
if (lflow) {
ovn_lflow_destroy(&lflows, lflow);
} else {
sbrec_logical_flow_delete(sbflow);
}
}
struct ovn_lflow *lflow, *next_lflow;
HMAP_FOR_EACH_SAFE (lflow, next_lflow, hmap_node, &lflows) {
enum ovn_pipeline pipeline = ovn_stage_get_pipeline(lflow->stage);
uint8_t table = ovn_stage_get_table(lflow->stage);
sbflow = sbrec_logical_flow_insert(ctx->ovnsb_txn);
sbrec_logical_flow_set_logical_datapath(sbflow, lflow->od->sb);
sbrec_logical_flow_set_pipeline(
sbflow, pipeline == P_IN ? "ingress" : "egress");
sbrec_logical_flow_set_table_id(sbflow, table);
sbrec_logical_flow_set_priority(sbflow, lflow->priority);
sbrec_logical_flow_set_match(sbflow, lflow->match);
sbrec_logical_flow_set_actions(sbflow, lflow->actions);
/* Trim the source locator lflow->where, which looks something like
* "ovn/northd/ovn-northd.c:1234", down to just the part following the
* last slash, e.g. "ovn-northd.c:1234". */
const char *slash = strrchr(lflow->where, '/');
#if _WIN32
const char *backslash = strrchr(lflow->where, '\\');
if (!slash || backslash > slash) {
slash = backslash;
}
#endif
const char *where = slash ? slash + 1 : lflow->where;
struct smap ids = SMAP_INITIALIZER(&ids);
smap_add(&ids, "stage-name", ovn_stage_to_str(lflow->stage));
smap_add(&ids, "source", where);
if (lflow->stage_hint) {
smap_add(&ids, "stage-hint", lflow->stage_hint);
}
sbrec_logical_flow_set_external_ids(sbflow, &ids);
smap_destroy(&ids);
ovn_lflow_destroy(&lflows, lflow);
}
hmap_destroy(&lflows);
/* Push changes to the Multicast_Group table to database. */
const struct sbrec_multicast_group *sbmc, *next_sbmc;
SBREC_MULTICAST_GROUP_FOR_EACH_SAFE (sbmc, next_sbmc, ctx->ovnsb_idl) {
struct ovn_datapath *od = ovn_datapath_from_sbrec(datapaths,
sbmc->datapath);
if (!od) {
sbrec_multicast_group_delete(sbmc);
continue;
}
struct multicast_group group = { .name = sbmc->name,
.key = sbmc->tunnel_key };
struct ovn_multicast *mc = ovn_multicast_find(&mcgroups, od, &group);
if (mc) {
ovn_multicast_update_sbrec(mc, sbmc);
ovn_multicast_destroy(&mcgroups, mc);
} else {
sbrec_multicast_group_delete(sbmc);
}
}
struct ovn_multicast *mc, *next_mc;
HMAP_FOR_EACH_SAFE (mc, next_mc, hmap_node, &mcgroups) {
sbmc = sbrec_multicast_group_insert(ctx->ovnsb_txn);
sbrec_multicast_group_set_datapath(sbmc, mc->datapath->sb);
sbrec_multicast_group_set_name(sbmc, mc->group->name);
sbrec_multicast_group_set_tunnel_key(sbmc, mc->group->key);
ovn_multicast_update_sbrec(mc, sbmc);
ovn_multicast_destroy(&mcgroups, mc);
}
hmap_destroy(&mcgroups);
}
/* OVN_Northbound and OVN_Southbound have an identical Address_Set table.
* We always update OVN_Southbound to match the current data in
* OVN_Northbound, so that the address sets used in Logical_Flows in
* OVN_Southbound is checked against the proper set.*/
static void
sync_address_sets(struct northd_context *ctx)
{
struct shash sb_address_sets = SHASH_INITIALIZER(&sb_address_sets);
const struct sbrec_address_set *sb_address_set;
SBREC_ADDRESS_SET_FOR_EACH (sb_address_set, ctx->ovnsb_idl) {
shash_add(&sb_address_sets, sb_address_set->name, sb_address_set);
}
const struct nbrec_address_set *nb_address_set;
NBREC_ADDRESS_SET_FOR_EACH (nb_address_set, ctx->ovnnb_idl) {
sb_address_set = shash_find_and_delete(&sb_address_sets,
nb_address_set->name);
if (!sb_address_set) {
sb_address_set = sbrec_address_set_insert(ctx->ovnsb_txn);
sbrec_address_set_set_name(sb_address_set, nb_address_set->name);
}
sbrec_address_set_set_addresses(sb_address_set,
/* "char **" is not compatible with "const char **" */
(const char **) nb_address_set->addresses,
nb_address_set->n_addresses);
}
struct shash_node *node, *next;
SHASH_FOR_EACH_SAFE (node, next, &sb_address_sets) {
sbrec_address_set_delete(node->data);
shash_delete(&sb_address_sets, node);
}
shash_destroy(&sb_address_sets);
}
/*
* struct 'dns_info' is used to sync the DNS records between OVN Northbound db
* and Southbound db.
*/
struct dns_info {
struct hmap_node hmap_node;
const struct nbrec_dns *nb_dns; /* DNS record in the Northbound db. */
const struct sbrec_dns *sb_dns; /* DNS record in the Soutbound db. */
/* Datapaths to which the DNS entry is associated with it. */
const struct sbrec_datapath_binding **sbs;
size_t n_sbs;
};
static inline struct dns_info *
get_dns_info_from_hmap(struct hmap *dns_map, struct uuid *uuid)
{
struct dns_info *dns_info;
size_t hash = uuid_hash(uuid);
HMAP_FOR_EACH_WITH_HASH (dns_info, hmap_node, hash, dns_map) {
if (uuid_equals(&dns_info->nb_dns->header_.uuid, uuid)) {
return dns_info;
}
}
return NULL;
}
static void
sync_dns_entries(struct northd_context *ctx, struct hmap *datapaths)
{
struct hmap dns_map = HMAP_INITIALIZER(&dns_map);
struct ovn_datapath *od;
HMAP_FOR_EACH (od, key_node, datapaths) {
if (!od->nbs || !od->nbs->n_dns_records) {
continue;
}
for (size_t i = 0; i < od->nbs->n_dns_records; i++) {
struct dns_info *dns_info = get_dns_info_from_hmap(
&dns_map, &od->nbs->dns_records[i]->header_.uuid);
if (!dns_info) {
size_t hash = uuid_hash(
&od->nbs->dns_records[i]->header_.uuid);
dns_info = xzalloc(sizeof *dns_info);;
dns_info->nb_dns = od->nbs->dns_records[i];
hmap_insert(&dns_map, &dns_info->hmap_node, hash);
}
dns_info->n_sbs++;
dns_info->sbs = xrealloc(dns_info->sbs,
dns_info->n_sbs * sizeof *dns_info->sbs);
dns_info->sbs[dns_info->n_sbs - 1] = od->sb;
}
}
const struct sbrec_dns *sbrec_dns, *next;
SBREC_DNS_FOR_EACH_SAFE (sbrec_dns, next, ctx->ovnsb_idl) {
const char *nb_dns_uuid = smap_get(&sbrec_dns->external_ids, "dns_id");
struct uuid dns_uuid;
if (!nb_dns_uuid || !uuid_from_string(&dns_uuid, nb_dns_uuid)) {
sbrec_dns_delete(sbrec_dns);
continue;
}
struct dns_info *dns_info =
get_dns_info_from_hmap(&dns_map, &dns_uuid);
if (dns_info) {
dns_info->sb_dns = sbrec_dns;
} else {
sbrec_dns_delete(sbrec_dns);
}
}
struct dns_info *dns_info;
HMAP_FOR_EACH_POP (dns_info, hmap_node, &dns_map) {
if (!dns_info->sb_dns) {
struct sbrec_dns *sbrec_dns = sbrec_dns_insert(ctx->ovnsb_txn);
dns_info->sb_dns = sbrec_dns;
char *dns_id = xasprintf(
UUID_FMT, UUID_ARGS(&dns_info->nb_dns->header_.uuid));
const struct smap external_ids =
SMAP_CONST1(&external_ids, "dns_id", dns_id);
sbrec_dns_set_external_ids(sbrec_dns, &external_ids);
free(dns_id);
}
/* Set the datapaths and records. If nothing has changed, then
* this will be a no-op.
*/
sbrec_dns_set_datapaths(
dns_info->sb_dns,
(struct sbrec_datapath_binding **)dns_info->sbs,
dns_info->n_sbs);
sbrec_dns_set_records(dns_info->sb_dns, &dns_info->nb_dns->records);
free(dns_info->sbs);
free(dns_info);
}
hmap_destroy(&dns_map);
}
static void
ovnnb_db_run(struct northd_context *ctx, struct chassis_index *chassis_index,
struct ovsdb_idl_loop *sb_loop)
{
if (!ctx->ovnsb_txn || !ctx->ovnnb_txn) {
return;
}
struct hmap datapaths, ports;
build_datapaths(ctx, &datapaths);
build_ports(ctx, &datapaths, chassis_index, &ports);
build_ipam(&datapaths, &ports);
build_lflows(ctx, &datapaths, &ports);
sync_address_sets(ctx);
sync_dns_entries(ctx, &datapaths);
struct ovn_datapath *dp, *next_dp;
HMAP_FOR_EACH_SAFE (dp, next_dp, key_node, &datapaths) {
ovn_datapath_destroy(&datapaths, dp);
}
hmap_destroy(&datapaths);
struct ovn_port *port, *next_port;
HMAP_FOR_EACH_SAFE (port, next_port, key_node, &ports) {
ovn_port_destroy(&ports, port);
}
hmap_destroy(&ports);
/* Copy nb_cfg from northbound to southbound database.
*
* Also set up to update sb_cfg once our southbound transaction commits. */
const struct nbrec_nb_global *nb = nbrec_nb_global_first(ctx->ovnnb_idl);
if (!nb) {
nb = nbrec_nb_global_insert(ctx->ovnnb_txn);
}
const struct sbrec_sb_global *sb = sbrec_sb_global_first(ctx->ovnsb_idl);
if (!sb) {
sb = sbrec_sb_global_insert(ctx->ovnsb_txn);
}
sbrec_sb_global_set_nb_cfg(sb, nb->nb_cfg);
sb_loop->next_cfg = nb->nb_cfg;
cleanup_macam(&macam);
}
/* Handle changes to the 'chassis' column of the 'Port_Binding' table. When
* this column is not empty, it means we need to set the corresponding logical
* port as 'up' in the northbound DB. */
static void
update_logical_port_status(struct northd_context *ctx)
{
struct hmap lports_hmap;
const struct sbrec_port_binding *sb;
const struct nbrec_logical_switch_port *nbsp;
struct lport_hash_node {
struct hmap_node node;
const struct nbrec_logical_switch_port *nbsp;
} *hash_node;
hmap_init(&lports_hmap);
NBREC_LOGICAL_SWITCH_PORT_FOR_EACH(nbsp, ctx->ovnnb_idl) {
hash_node = xzalloc(sizeof *hash_node);
hash_node->nbsp = nbsp;
hmap_insert(&lports_hmap, &hash_node->node, hash_string(nbsp->name, 0));
}
SBREC_PORT_BINDING_FOR_EACH(sb, ctx->ovnsb_idl) {
nbsp = NULL;
HMAP_FOR_EACH_WITH_HASH(hash_node, node,
hash_string(sb->logical_port, 0),
&lports_hmap) {
if (!strcmp(sb->logical_port, hash_node->nbsp->name)) {
nbsp = hash_node->nbsp;
break;
}
}
if (!nbsp) {
/* The logical port doesn't exist for this port binding. This can
* happen under normal circumstances when ovn-northd hasn't gotten
* around to pruning the Port_Binding yet. */
continue;
}
if (sb->chassis && (!nbsp->up || !*nbsp->up)) {
bool up = true;
nbrec_logical_switch_port_set_up(nbsp, &up, 1);
} else if (!sb->chassis && (!nbsp->up || *nbsp->up)) {
bool up = false;
nbrec_logical_switch_port_set_up(nbsp, &up, 1);
}
}
HMAP_FOR_EACH_POP(hash_node, node, &lports_hmap) {
free(hash_node);
}
hmap_destroy(&lports_hmap);
}
static struct dhcp_opts_map supported_dhcp_opts[] = {
OFFERIP,
DHCP_OPT_NETMASK,
DHCP_OPT_ROUTER,
DHCP_OPT_DNS_SERVER,
DHCP_OPT_LOG_SERVER,
DHCP_OPT_LPR_SERVER,
DHCP_OPT_SWAP_SERVER,
DHCP_OPT_POLICY_FILTER,
DHCP_OPT_ROUTER_SOLICITATION,
DHCP_OPT_NIS_SERVER,
DHCP_OPT_NTP_SERVER,
DHCP_OPT_SERVER_ID,
DHCP_OPT_TFTP_SERVER,
DHCP_OPT_CLASSLESS_STATIC_ROUTE,
DHCP_OPT_MS_CLASSLESS_STATIC_ROUTE,
DHCP_OPT_IP_FORWARD_ENABLE,
DHCP_OPT_ROUTER_DISCOVERY,
DHCP_OPT_ETHERNET_ENCAP,
DHCP_OPT_DEFAULT_TTL,
DHCP_OPT_TCP_TTL,
DHCP_OPT_MTU,
DHCP_OPT_LEASE_TIME,
DHCP_OPT_T1,
DHCP_OPT_T2
};
static struct dhcp_opts_map supported_dhcpv6_opts[] = {
DHCPV6_OPT_IA_ADDR,
DHCPV6_OPT_SERVER_ID,
DHCPV6_OPT_DOMAIN_SEARCH,
DHCPV6_OPT_DNS_SERVER
};
static void
check_and_add_supported_dhcp_opts_to_sb_db(struct northd_context *ctx)
{
struct hmap dhcp_opts_to_add = HMAP_INITIALIZER(&dhcp_opts_to_add);
for (size_t i = 0; (i < sizeof(supported_dhcp_opts) /
sizeof(supported_dhcp_opts[0])); i++) {
hmap_insert(&dhcp_opts_to_add, &supported_dhcp_opts[i].hmap_node,
dhcp_opt_hash(supported_dhcp_opts[i].name));
}
const struct sbrec_dhcp_options *opt_row, *opt_row_next;
SBREC_DHCP_OPTIONS_FOR_EACH_SAFE(opt_row, opt_row_next, ctx->ovnsb_idl) {
struct dhcp_opts_map *dhcp_opt =
dhcp_opts_find(&dhcp_opts_to_add, opt_row->name);
if (dhcp_opt) {
hmap_remove(&dhcp_opts_to_add, &dhcp_opt->hmap_node);
} else {
sbrec_dhcp_options_delete(opt_row);
}
}
struct dhcp_opts_map *opt;
HMAP_FOR_EACH (opt, hmap_node, &dhcp_opts_to_add) {
struct sbrec_dhcp_options *sbrec_dhcp_option =
sbrec_dhcp_options_insert(ctx->ovnsb_txn);
sbrec_dhcp_options_set_name(sbrec_dhcp_option, opt->name);
sbrec_dhcp_options_set_code(sbrec_dhcp_option, opt->code);
sbrec_dhcp_options_set_type(sbrec_dhcp_option, opt->type);
}
hmap_destroy(&dhcp_opts_to_add);
}
static void
check_and_add_supported_dhcpv6_opts_to_sb_db(struct northd_context *ctx)
{
struct hmap dhcpv6_opts_to_add = HMAP_INITIALIZER(&dhcpv6_opts_to_add);
for (size_t i = 0; (i < sizeof(supported_dhcpv6_opts) /
sizeof(supported_dhcpv6_opts[0])); i++) {
hmap_insert(&dhcpv6_opts_to_add, &supported_dhcpv6_opts[i].hmap_node,
dhcp_opt_hash(supported_dhcpv6_opts[i].name));
}
const struct sbrec_dhcpv6_options *opt_row, *opt_row_next;
SBREC_DHCPV6_OPTIONS_FOR_EACH_SAFE(opt_row, opt_row_next, ctx->ovnsb_idl) {
struct dhcp_opts_map *dhcp_opt =
dhcp_opts_find(&dhcpv6_opts_to_add, opt_row->name);
if (dhcp_opt) {
hmap_remove(&dhcpv6_opts_to_add, &dhcp_opt->hmap_node);
} else {
sbrec_dhcpv6_options_delete(opt_row);
}
}
struct dhcp_opts_map *opt;
HMAP_FOR_EACH(opt, hmap_node, &dhcpv6_opts_to_add) {
struct sbrec_dhcpv6_options *sbrec_dhcpv6_option =
sbrec_dhcpv6_options_insert(ctx->ovnsb_txn);
sbrec_dhcpv6_options_set_name(sbrec_dhcpv6_option, opt->name);
sbrec_dhcpv6_options_set_code(sbrec_dhcpv6_option, opt->code);
sbrec_dhcpv6_options_set_type(sbrec_dhcpv6_option, opt->type);
}
hmap_destroy(&dhcpv6_opts_to_add);
}
static const char *rbac_chassis_auth[] =
{"name"};
static const char *rbac_chassis_update[] =
{"nb_cfg", "external_ids", "encaps", "vtep_logical_switches"};
static const char *rbac_encap_auth[] =
{"chassis_name"};
static const char *rbac_encap_update[] =
{"type", "options", "ip"};
static const char *rbac_port_binding_auth[] =
{""};
static const char *rbac_port_binding_update[] =
{"chassis"};
static const char *rbac_mac_binding_auth[] =
{""};
static const char *rbac_mac_binding_update[] =
{"logical_port", "ip", "mac", "datapath"};
static struct rbac_perm_cfg {
const char *table;
const char **auth;
int n_auth;
bool insdel;
const char **update;
int n_update;
const struct sbrec_rbac_permission *row;
} rbac_perm_cfg[] = {
{
.table = "Chassis",
.auth = rbac_chassis_auth,
.n_auth = ARRAY_SIZE(rbac_chassis_auth),
.insdel = true,
.update = rbac_chassis_update,
.n_update = ARRAY_SIZE(rbac_chassis_update),
.row = NULL
},{
.table = "Encap",
.auth = rbac_encap_auth,
.n_auth = ARRAY_SIZE(rbac_encap_auth),
.insdel = true,
.update = rbac_encap_update,
.n_update = ARRAY_SIZE(rbac_encap_update),
.row = NULL
},{
.table = "Port_Binding",
.auth = rbac_port_binding_auth,
.n_auth = ARRAY_SIZE(rbac_port_binding_auth),
.insdel = false,
.update = rbac_port_binding_update,
.n_update = ARRAY_SIZE(rbac_port_binding_update),
.row = NULL
},{
.table = "MAC_Binding",
.auth = rbac_mac_binding_auth,
.n_auth = ARRAY_SIZE(rbac_mac_binding_auth),
.insdel = true,
.update = rbac_mac_binding_update,
.n_update = ARRAY_SIZE(rbac_mac_binding_update),
.row = NULL
},{
.table = NULL,
.auth = NULL,
.n_auth = 0,
.insdel = false,
.update = NULL,
.n_update = 0,
.row = NULL
}
};
static bool
ovn_rbac_validate_perm(const struct sbrec_rbac_permission *perm)
{
struct rbac_perm_cfg *pcfg;
int i, j, n_found;
for (pcfg = rbac_perm_cfg; pcfg->table; pcfg++) {
if (!strcmp(perm->table, pcfg->table)) {
break;
}
}
if (!pcfg->table) {
return false;
}
if (perm->n_authorization != pcfg->n_auth ||
perm->n_update != pcfg->n_update) {
return false;
}
if (perm->insert_delete != pcfg->insdel) {
return false;
}
/* verify perm->authorization vs. pcfg->auth */
n_found = 0;
for (i = 0; i < pcfg->n_auth; i++) {
for (j = 0; j < perm->n_authorization; j++) {
if (!strcmp(pcfg->auth[i], perm->authorization[j])) {
n_found++;
break;
}
}
}
if (n_found != pcfg->n_auth) {
return false;
}
/* verify perm->update vs. pcfg->update */
n_found = 0;
for (i = 0; i < pcfg->n_update; i++) {
for (j = 0; j < perm->n_update; j++) {
if (!strcmp(pcfg->update[i], perm->update[j])) {
n_found++;
break;
}
}
}
if (n_found != pcfg->n_update) {
return false;
}
/* Success, db state matches expected state */
pcfg->row = perm;
return true;
}
static void
ovn_rbac_create_perm(struct rbac_perm_cfg *pcfg,
struct northd_context *ctx,
const struct sbrec_rbac_role *rbac_role)
{
struct sbrec_rbac_permission *rbac_perm;
rbac_perm = sbrec_rbac_permission_insert(ctx->ovnsb_txn);
sbrec_rbac_permission_set_table(rbac_perm, pcfg->table);
sbrec_rbac_permission_set_authorization(rbac_perm,
pcfg->auth,
pcfg->n_auth);
sbrec_rbac_permission_set_insert_delete(rbac_perm, pcfg->insdel);
sbrec_rbac_permission_set_update(rbac_perm,
pcfg->update,
pcfg->n_update);
sbrec_rbac_role_update_permissions_setkey(rbac_role, pcfg->table,
rbac_perm);
}
static void
check_and_update_rbac(struct northd_context *ctx)
{
const struct sbrec_rbac_role *rbac_role = NULL;
const struct sbrec_rbac_permission *perm_row, *perm_next;
const struct sbrec_rbac_role *role_row, *role_row_next;
struct rbac_perm_cfg *pcfg;
for (pcfg = rbac_perm_cfg; pcfg->table; pcfg++) {
pcfg->row = NULL;
}
SBREC_RBAC_PERMISSION_FOR_EACH_SAFE (perm_row, perm_next, ctx->ovnsb_idl) {
if (!ovn_rbac_validate_perm(perm_row)) {
sbrec_rbac_permission_delete(perm_row);
}
}
SBREC_RBAC_ROLE_FOR_EACH_SAFE (role_row, role_row_next, ctx->ovnsb_idl) {
if (strcmp(role_row->name, "ovn-controller")) {
sbrec_rbac_role_delete(role_row);
} else {
rbac_role = role_row;
}
}
if (!rbac_role) {
rbac_role = sbrec_rbac_role_insert(ctx->ovnsb_txn);
sbrec_rbac_role_set_name(rbac_role, "ovn-controller");
}
for (pcfg = rbac_perm_cfg; pcfg->table; pcfg++) {
if (!pcfg->row) {
ovn_rbac_create_perm(pcfg, ctx, rbac_role);
}
}
}
/* Updates the sb_cfg and hv_cfg columns in the northbound NB_Global table. */
static void
update_northbound_cfg(struct northd_context *ctx,
struct ovsdb_idl_loop *sb_loop)
{
/* Update northbound sb_cfg if appropriate. */
const struct nbrec_nb_global *nbg = nbrec_nb_global_first(ctx->ovnnb_idl);
int64_t sb_cfg = sb_loop->cur_cfg;
if (nbg && sb_cfg && nbg->sb_cfg != sb_cfg) {
nbrec_nb_global_set_sb_cfg(nbg, sb_cfg);
}
/* Update northbound hv_cfg if appropriate. */
if (nbg) {
/* Find minimum nb_cfg among all chassis. */
const struct sbrec_chassis *chassis;
int64_t hv_cfg = nbg->nb_cfg;
SBREC_CHASSIS_FOR_EACH (chassis, ctx->ovnsb_idl) {
if (chassis->nb_cfg < hv_cfg) {
hv_cfg = chassis->nb_cfg;
}
}
/* Update hv_cfg. */
if (nbg->hv_cfg != hv_cfg) {
nbrec_nb_global_set_hv_cfg(nbg, hv_cfg);
}
}
}
/* Handle a fairly small set of changes in the southbound database. */
static void
ovnsb_db_run(struct northd_context *ctx, struct ovsdb_idl_loop *sb_loop)
{
if (!ctx->ovnnb_txn || !ovsdb_idl_has_ever_connected(ctx->ovnsb_idl)) {
return;
}
update_logical_port_status(ctx);
update_northbound_cfg(ctx, sb_loop);
}
static void
parse_options(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
{
enum {
DAEMON_OPTION_ENUMS,
VLOG_OPTION_ENUMS,
SSL_OPTION_ENUMS,
};
static const struct option long_options[] = {
{"ovnsb-db", required_argument, NULL, 'd'},
{"ovnnb-db", required_argument, NULL, 'D'},
{"help", no_argument, NULL, 'h'},
{"options", no_argument, NULL, 'o'},
{"version", no_argument, NULL, 'V'},
DAEMON_LONG_OPTIONS,
VLOG_LONG_OPTIONS,
STREAM_SSL_LONG_OPTIONS,
{NULL, 0, NULL, 0},
};
char *short_options = ovs_cmdl_long_options_to_short_options(long_options);
for (;;) {
int c;
c = getopt_long(argc, argv, short_options, long_options, NULL);
if (c == -1) {
break;
}
switch (c) {
DAEMON_OPTION_HANDLERS;
VLOG_OPTION_HANDLERS;
STREAM_SSL_OPTION_HANDLERS;
case 'd':
ovnsb_db = optarg;
break;
case 'D':
ovnnb_db = optarg;
break;
case 'h':
usage();
exit(EXIT_SUCCESS);
case 'o':
ovs_cmdl_print_options(long_options);
exit(EXIT_SUCCESS);
case 'V':
ovs_print_version(0, 0);
exit(EXIT_SUCCESS);
default:
break;
}
}
if (!ovnsb_db) {
ovnsb_db = default_sb_db();
}
if (!ovnnb_db) {
ovnnb_db = default_nb_db();
}
free(short_options);
}
static void
add_column_noalert(struct ovsdb_idl *idl,
const struct ovsdb_idl_column *column)
{
ovsdb_idl_add_column(idl, column);
ovsdb_idl_omit_alert(idl, column);
}
int
main(int argc, char *argv[])
{
int res = EXIT_SUCCESS;
struct unixctl_server *unixctl;
int retval;
bool exiting;
fatal_ignore_sigpipe();
ovs_cmdl_proctitle_init(argc, argv);
set_program_name(argv[0]);
service_start(&argc, &argv);
parse_options(argc, argv);
daemonize_start(false);
retval = unixctl_server_create(NULL, &unixctl);
if (retval) {
exit(EXIT_FAILURE);
}
unixctl_command_register("exit", "", 0, 0, ovn_northd_exit, &exiting);
daemonize_complete();
/* We want to detect (almost) all changes to the ovn-nb db. */
struct ovsdb_idl_loop ovnnb_idl_loop = OVSDB_IDL_LOOP_INITIALIZER(
ovsdb_idl_create(ovnnb_db, &nbrec_idl_class, true, true));
ovsdb_idl_omit_alert(ovnnb_idl_loop.idl, &nbrec_nb_global_col_sb_cfg);
ovsdb_idl_omit_alert(ovnnb_idl_loop.idl, &nbrec_nb_global_col_hv_cfg);
/* We want to detect only selected changes to the ovn-sb db. */
struct ovsdb_idl_loop ovnsb_idl_loop = OVSDB_IDL_LOOP_INITIALIZER(
ovsdb_idl_create(ovnsb_db, &sbrec_idl_class, false, true));
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_sb_global);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_sb_global_col_nb_cfg);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_logical_flow);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_logical_flow_col_logical_datapath);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_logical_flow_col_pipeline);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_logical_flow_col_table_id);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_logical_flow_col_priority);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_logical_flow_col_match);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_logical_flow_col_actions);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_multicast_group);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_multicast_group_col_datapath);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_multicast_group_col_tunnel_key);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_multicast_group_col_name);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_multicast_group_col_ports);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_datapath_binding);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_datapath_binding_col_tunnel_key);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_datapath_binding_col_external_ids);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_port_binding);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_port_binding_col_datapath);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_port_binding_col_logical_port);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_port_binding_col_tunnel_key);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_port_binding_col_parent_port);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_port_binding_col_tag);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_port_binding_col_type);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_port_binding_col_options);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_port_binding_col_mac);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_port_binding_col_nat_addresses);
ovsdb_idl_add_column(ovnsb_idl_loop.idl, &sbrec_port_binding_col_chassis);
ovsdb_idl_add_column(ovnsb_idl_loop.idl,
&sbrec_port_binding_col_gateway_chassis);
ovsdb_idl_add_column(ovnsb_idl_loop.idl,
&sbrec_gateway_chassis_col_chassis);
ovsdb_idl_add_column(ovnsb_idl_loop.idl, &sbrec_gateway_chassis_col_name);
ovsdb_idl_add_column(ovnsb_idl_loop.idl,
&sbrec_gateway_chassis_col_priority);
ovsdb_idl_add_column(ovnsb_idl_loop.idl,
&sbrec_gateway_chassis_col_external_ids);
ovsdb_idl_add_column(ovnsb_idl_loop.idl,
&sbrec_gateway_chassis_col_options);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_port_binding_col_external_ids);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_mac_binding);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_mac_binding_col_datapath);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_mac_binding_col_ip);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_mac_binding_col_mac);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_mac_binding_col_logical_port);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_dhcp_options);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dhcp_options_col_code);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dhcp_options_col_type);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dhcp_options_col_name);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_dhcpv6_options);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dhcpv6_options_col_code);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dhcpv6_options_col_type);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dhcpv6_options_col_name);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_address_set);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_address_set_col_name);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_address_set_col_addresses);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_dns);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dns_col_datapaths);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dns_col_records);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_dns_col_external_ids);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_rbac_role);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_rbac_role_col_name);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_rbac_role_col_permissions);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_rbac_permission);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_rbac_permission_col_table);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_rbac_permission_col_authorization);
add_column_noalert(ovnsb_idl_loop.idl,
&sbrec_rbac_permission_col_insert_delete);
add_column_noalert(ovnsb_idl_loop.idl, &sbrec_rbac_permission_col_update);
ovsdb_idl_add_table(ovnsb_idl_loop.idl, &sbrec_table_chassis);
ovsdb_idl_add_column(ovnsb_idl_loop.idl, &sbrec_chassis_col_nb_cfg);
ovsdb_idl_add_column(ovnsb_idl_loop.idl, &sbrec_chassis_col_name);
/* Main loop. */
exiting = false;
while (!exiting) {
struct northd_context ctx = {
.ovnnb_idl = ovnnb_idl_loop.idl,
.ovnnb_txn = ovsdb_idl_loop_run(&ovnnb_idl_loop),
.ovnsb_idl = ovnsb_idl_loop.idl,
.ovnsb_txn = ovsdb_idl_loop_run(&ovnsb_idl_loop),
};
struct chassis_index chassis_index;
chassis_index_init(&chassis_index, ctx.ovnsb_idl);
ovnnb_db_run(&ctx, &chassis_index, &ovnsb_idl_loop);
ovnsb_db_run(&ctx, &ovnsb_idl_loop);
if (ctx.ovnsb_txn) {
check_and_add_supported_dhcp_opts_to_sb_db(&ctx);
check_and_add_supported_dhcpv6_opts_to_sb_db(&ctx);
check_and_update_rbac(&ctx);
}
unixctl_server_run(unixctl);
unixctl_server_wait(unixctl);
if (exiting) {
poll_immediate_wake();
}
ovsdb_idl_loop_commit_and_wait(&ovnnb_idl_loop);
ovsdb_idl_loop_commit_and_wait(&ovnsb_idl_loop);
poll_block();
if (should_service_stop()) {
exiting = true;
}
chassis_index_destroy(&chassis_index);
}
unixctl_server_destroy(unixctl);
ovsdb_idl_loop_destroy(&ovnnb_idl_loop);
ovsdb_idl_loop_destroy(&ovnsb_idl_loop);
service_stop();
exit(res);
}
static void
ovn_northd_exit(struct unixctl_conn *conn, int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED, void *exiting_)
{
bool *exiting = exiting_;
*exiting = true;
unixctl_command_reply(conn, NULL);
}
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