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0c43ad9a7501774ba33e55e8b5367e611ff0057f
openvswitch/vswitchd/bridge.c
Ben Pfaff cf3fad8a1b ofproto: Change ofproto_add_flow(), ofproto_delete_flow() to take cls_rule. 
This is a small cleanup that will make later changes to wildcards easier.
2010-11-08 10:43:31 -08:00

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/* Copyright (c) 2008, 2009, 2010 Nicira Networks
*
* 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 "bridge.h"
#include "byte-order.h"
#include <assert.h>
#include <errno.h>
#include <arpa/inet.h>
#include <ctype.h>
#include <inttypes.h>
#include <sys/socket.h>
#include <net/if.h>
#include <openflow/openflow.h>
#include <signal.h>
#include <stdlib.h>
#include <strings.h>
#include <sys/stat.h>
#include <sys/socket.h>
#include <sys/types.h>
#include <unistd.h>
#include "bitmap.h"
#include "classifier.h"
#include "coverage.h"
#include "dirs.h"
#include "dpif.h"
#include "dynamic-string.h"
#include "flow.h"
#include "hash.h"
#include "hmap.h"
#include "jsonrpc.h"
#include "list.h"
#include "mac-learning.h"
#include "netdev.h"
#include "odp-util.h"
#include "ofp-print.h"
#include "ofpbuf.h"
#include "ofproto/netflow.h"
#include "ofproto/ofproto.h"
#include "ovsdb-data.h"
#include "packets.h"
#include "poll-loop.h"
#include "proc-net-compat.h"
#include "process.h"
#include "sha1.h"
#include "shash.h"
#include "socket-util.h"
#include "stream-ssl.h"
#include "svec.h"
#include "system-stats.h"
#include "timeval.h"
#include "util.h"
#include "unixctl.h"
#include "vconn.h"
#include "vswitchd/vswitch-idl.h"
#include "xenserver.h"
#include "vlog.h"
#include "sflow_api.h"
VLOG_DEFINE_THIS_MODULE(bridge);
struct dst {
uint16_t vlan;
uint16_t dp_ifidx;
};
struct iface {
/* These members are always valid. */
struct port *port; /* Containing port. */
size_t port_ifidx; /* Index within containing port. */
char *name; /* Host network device name. */
tag_type tag; /* Tag associated with this interface. */
long long delay_expires; /* Time after which 'enabled' may change. */
/* These members are valid only after bridge_reconfigure() causes them to
* be initialized. */
struct hmap_node dp_ifidx_node; /* In struct bridge's "ifaces" hmap. */
int dp_ifidx; /* Index within kernel datapath. */
struct netdev *netdev; /* Network device. */
bool enabled; /* May be chosen for flows? */
const char *type; /* Usually same as cfg->type. */
const struct ovsrec_interface *cfg;
};
#define BOND_MASK 0xff
struct bond_entry {
int iface_idx; /* Index of assigned iface, or -1 if none. */
uint64_t tx_bytes; /* Count of bytes recently transmitted. */
tag_type iface_tag; /* Tag associated with iface_idx. */
};
#define MAX_MIRRORS 32
typedef uint32_t mirror_mask_t;
#define MIRROR_MASK_C(X) UINT32_C(X)
BUILD_ASSERT_DECL(sizeof(mirror_mask_t) * CHAR_BIT >= MAX_MIRRORS);
struct mirror {
struct bridge *bridge;
size_t idx;
char *name;
struct uuid uuid; /* UUID of this "mirror" record in database. */
/* Selection criteria. */
struct shash src_ports; /* Name is port name; data is always NULL. */
struct shash dst_ports; /* Name is port name; data is always NULL. */
int *vlans;
size_t n_vlans;
/* Output. */
struct port *out_port;
int out_vlan;
};
#define FLOOD_PORT ((struct port *) 1) /* The 'flood' output port. */
struct port {
struct bridge *bridge;
size_t port_idx;
int vlan; /* -1=trunk port, else a 12-bit VLAN ID. */
unsigned long *trunks; /* Bitmap of trunked VLANs, if 'vlan' == -1.
* NULL if all VLANs are trunked. */
const struct ovsrec_port *cfg;
char *name;
/* An ordinary bridge port has 1 interface.
* A bridge port for bonding has at least 2 interfaces. */
struct iface **ifaces;
size_t n_ifaces, allocated_ifaces;
/* Bonding info. */
struct bond_entry *bond_hash; /* An array of (BOND_MASK + 1) elements. */
int active_iface; /* Ifidx on which bcasts accepted, or -1. */
tag_type active_iface_tag; /* Tag for bcast flows. */
tag_type no_ifaces_tag; /* Tag for flows when all ifaces disabled. */
int updelay, downdelay; /* Delay before iface goes up/down, in ms. */
bool bond_compat_is_stale; /* Need to call port_update_bond_compat()? */
bool bond_fake_iface; /* Fake a bond interface for legacy compat? */
long long int bond_next_fake_iface_update; /* Time of next update. */
int bond_rebalance_interval; /* Interval between rebalances, in ms. */
long long int bond_next_rebalance; /* Next rebalancing time. */
struct netdev_monitor *monitor; /* Tracks carrier up/down status. */
/* Port mirroring info. */
mirror_mask_t src_mirrors; /* Mirrors triggered when packet received. */
mirror_mask_t dst_mirrors; /* Mirrors triggered when packet sent. */
bool is_mirror_output_port; /* Does port mirroring send frames here? */
};
#define DP_MAX_PORTS 255
struct bridge {
struct list node; /* Node in global list of bridges. */
char *name; /* User-specified arbitrary name. */
struct mac_learning *ml; /* MAC learning table. */
uint8_t default_ea[ETH_ADDR_LEN]; /* Default MAC. */
const struct ovsrec_bridge *cfg;
/* OpenFlow switch processing. */
struct ofproto *ofproto; /* OpenFlow switch. */
/* Kernel datapath information. */
struct dpif *dpif; /* Datapath. */
struct hmap ifaces; /* Contains "struct iface"s. */
/* Bridge ports. */
struct port **ports;
size_t n_ports, allocated_ports;
struct shash iface_by_name; /* "struct iface"s indexed by name. */
struct shash port_by_name; /* "struct port"s indexed by name. */
/* Bonding. */
bool has_bonded_ports;
/* Flow tracking. */
bool flush;
/* Port mirroring. */
struct mirror *mirrors[MAX_MIRRORS];
};
/* List of all bridges. */
static struct list all_bridges = LIST_INITIALIZER(&all_bridges);
/* OVSDB IDL used to obtain configuration. */
static struct ovsdb_idl *idl;
/* Each time this timer expires, the bridge fetches systems and interface
* statistics and pushes them into the database. */
#define STATS_INTERVAL (5 * 1000) /* In milliseconds. */
static long long int stats_timer = LLONG_MIN;
static struct bridge *bridge_create(const struct ovsrec_bridge *br_cfg);
static void bridge_destroy(struct bridge *);
static struct bridge *bridge_lookup(const char *name);
static unixctl_cb_func bridge_unixctl_dump_flows;
static unixctl_cb_func bridge_unixctl_reconnect;
static int bridge_run_one(struct bridge *);
static size_t bridge_get_controllers(const struct bridge *br,
struct ovsrec_controller ***controllersp);
static void bridge_reconfigure_one(struct bridge *);
static void bridge_reconfigure_remotes(struct bridge *,
const struct sockaddr_in *managers,
size_t n_managers);
static void bridge_get_all_ifaces(const struct bridge *, struct shash *ifaces);
static void bridge_fetch_dp_ifaces(struct bridge *);
static void bridge_flush(struct bridge *);
static void bridge_pick_local_hw_addr(struct bridge *,
uint8_t ea[ETH_ADDR_LEN],
struct iface **hw_addr_iface);
static uint64_t bridge_pick_datapath_id(struct bridge *,
const uint8_t bridge_ea[ETH_ADDR_LEN],
struct iface *hw_addr_iface);
static struct iface *bridge_get_local_iface(struct bridge *);
static uint64_t dpid_from_hash(const void *, size_t nbytes);
static unixctl_cb_func bridge_unixctl_fdb_show;
static void bond_init(void);
static void bond_run(struct bridge *);
static void bond_wait(struct bridge *);
static void bond_rebalance_port(struct port *);
static void bond_send_learning_packets(struct port *);
static void bond_enable_slave(struct iface *iface, bool enable);
static struct port *port_create(struct bridge *, const char *name);
static void port_reconfigure(struct port *, const struct ovsrec_port *);
static void port_del_ifaces(struct port *, const struct ovsrec_port *);
static void port_destroy(struct port *);
static struct port *port_lookup(const struct bridge *, const char *name);
static struct iface *port_lookup_iface(const struct port *, const char *name);
static struct port *port_from_dp_ifidx(const struct bridge *,
uint16_t dp_ifidx);
static void port_update_bond_compat(struct port *);
static void port_update_vlan_compat(struct port *);
static void port_update_bonding(struct port *);
static void mirror_create(struct bridge *, struct ovsrec_mirror *);
static void mirror_destroy(struct mirror *);
static void mirror_reconfigure(struct bridge *);
static void mirror_reconfigure_one(struct mirror *, struct ovsrec_mirror *);
static bool vlan_is_mirrored(const struct mirror *, int vlan);
static struct iface *iface_create(struct port *port,
const struct ovsrec_interface *if_cfg);
static void iface_destroy(struct iface *);
static struct iface *iface_lookup(const struct bridge *, const char *name);
static struct iface *iface_from_dp_ifidx(const struct bridge *,
uint16_t dp_ifidx);
static void iface_set_mac(struct iface *);
static void iface_set_ofport(const struct ovsrec_interface *, int64_t ofport);
static void iface_update_qos(struct iface *, const struct ovsrec_qos *);
static void shash_from_ovs_idl_map(char **keys, char **values, size_t n,
struct shash *);
/* Hooks into ofproto processing. */
static struct ofhooks bridge_ofhooks;
/* Public functions. */
/* Initializes the bridge module, configuring it to obtain its configuration
* from an OVSDB server accessed over 'remote', which should be a string in a
* form acceptable to ovsdb_idl_create(). */
void
bridge_init(const char *remote)
{
/* Create connection to database. */
idl = ovsdb_idl_create(remote, &ovsrec_idl_class);
ovsdb_idl_set_write_only(idl, &ovsrec_open_vswitch_col_cur_cfg);
ovsdb_idl_set_write_only(idl, &ovsrec_open_vswitch_col_statistics);
ovsdb_idl_omit(idl, &ovsrec_open_vswitch_col_external_ids);
ovsdb_idl_omit(idl, &ovsrec_bridge_col_external_ids);
ovsdb_idl_omit(idl, &ovsrec_port_col_external_ids);
ovsdb_idl_omit(idl, &ovsrec_port_col_fake_bridge);
ovsdb_idl_set_write_only(idl, &ovsrec_interface_col_ofport);
ovsdb_idl_set_write_only(idl, &ovsrec_interface_col_statistics);
ovsdb_idl_omit(idl, &ovsrec_interface_col_external_ids);
/* Register unixctl commands. */
unixctl_command_register("fdb/show", bridge_unixctl_fdb_show, NULL);
unixctl_command_register("bridge/dump-flows", bridge_unixctl_dump_flows,
NULL);
unixctl_command_register("bridge/reconnect", bridge_unixctl_reconnect,
NULL);
bond_init();
}
/* Performs configuration that is only necessary once at ovs-vswitchd startup,
* but for which the ovs-vswitchd configuration 'cfg' is required. */
static void
bridge_configure_once(const struct ovsrec_open_vswitch *cfg)
{
static bool already_configured_once;
struct svec bridge_names;
struct svec dpif_names, dpif_types;
size_t i;
/* Only do this once per ovs-vswitchd run. */
if (already_configured_once) {
return;
}
already_configured_once = true;
stats_timer = time_msec() + STATS_INTERVAL;
/* Get all the configured bridges' names from 'cfg' into 'bridge_names'. */
svec_init(&bridge_names);
for (i = 0; i < cfg->n_bridges; i++) {
svec_add(&bridge_names, cfg->bridges[i]->name);
}
svec_sort(&bridge_names);
/* Iterate over all system dpifs and delete any of them that do not appear
* in 'cfg'. */
svec_init(&dpif_names);
svec_init(&dpif_types);
dp_enumerate_types(&dpif_types);
for (i = 0; i < dpif_types.n; i++) {
struct dpif *dpif;
int retval;
size_t j;
dp_enumerate_names(dpif_types.names[i], &dpif_names);
/* For each dpif... */
for (j = 0; j < dpif_names.n; j++) {
retval = dpif_open(dpif_names.names[j], dpif_types.names[i], &dpif);
if (!retval) {
struct svec all_names;
size_t k;
/* ...check whether any of its names is in 'bridge_names'. */
svec_init(&all_names);
dpif_get_all_names(dpif, &all_names);
for (k = 0; k < all_names.n; k++) {
if (svec_contains(&bridge_names, all_names.names[k])) {
goto found;
}
}
/* No. Delete the dpif. */
dpif_delete(dpif);
found:
svec_destroy(&all_names);
dpif_close(dpif);
}
}
}
svec_destroy(&bridge_names);
svec_destroy(&dpif_names);
svec_destroy(&dpif_types);
}
/* Initializes 'options' and fills it with the options for 'if_cfg'. Merges
* keys from "options" and "other_config", preferring "options" keys over
* "other_config" keys.
*
* The value strings in '*options' are taken directly from if_cfg, not copied,
* so the caller should not modify or free them. */
static void
iface_get_options(const struct ovsrec_interface *if_cfg, struct shash *options)
{
size_t i;
shash_from_ovs_idl_map(if_cfg->key_options, if_cfg->value_options,
if_cfg->n_options, options);
for (i = 0; i < if_cfg->n_other_config; i++) {
char *key = if_cfg->key_other_config[i];
char *value = if_cfg->value_other_config[i];
if (!shash_find_data(options, key)) {
shash_add(options, key, value);
} else {
VLOG_WARN("%s: ignoring \"other_config\" key %s that conflicts "
"with \"options\" key %s", if_cfg->name, key, key);
}
}
}
/* Returns the type of network device that 'iface' should have. (This is
* ordinarily the same type as the interface, but the network devices for
* "internal" ports have type "system".) */
static const char *
iface_get_netdev_type(const struct iface *iface)
{
return !strcmp(iface->type, "internal") ? "system" : iface->type;
}
/* Attempt to create the network device for 'iface' through the netdev
* library. */
static int
create_iface_netdev(struct iface *iface)
{
struct netdev_options netdev_options;
struct shash options;
int error;
memset(&netdev_options, 0, sizeof netdev_options);
netdev_options.name = iface->cfg->name;
netdev_options.type = iface_get_netdev_type(iface);
netdev_options.args = &options;
netdev_options.ethertype = NETDEV_ETH_TYPE_NONE;
iface_get_options(iface->cfg, &options);
error = netdev_open(&netdev_options, &iface->netdev);
if (iface->netdev) {
iface->enabled = netdev_get_carrier(iface->netdev);
}
shash_destroy(&options);
return error;
}
static int
reconfigure_iface_netdev(struct iface *iface)
{
const char *netdev_type, *iface_type;
struct shash options;
int error;
/* Skip reconfiguration if the device has the wrong type. This shouldn't
* happen, but... */
iface_type = iface_get_netdev_type(iface);
netdev_type = netdev_get_type(iface->netdev);
if (iface_type && strcmp(netdev_type, iface_type)) {
VLOG_WARN("%s: attempting change device type from %s to %s",
iface->cfg->name, netdev_type, iface_type);
return EINVAL;
}
/* Reconfigure device. */
iface_get_options(iface->cfg, &options);
error = netdev_reconfigure(iface->netdev, &options);
shash_destroy(&options);
return error;
}
/* Callback for iterate_and_prune_ifaces(). */
static bool
check_iface(struct bridge *br, struct iface *iface, void *aux OVS_UNUSED)
{
if (!iface->netdev) {
/* We already reported a related error, don't bother duplicating it. */
return false;
}
if (iface->dp_ifidx < 0) {
VLOG_ERR("%s interface not in %s, dropping",
iface->name, dpif_name(br->dpif));
return false;
}
VLOG_DBG("%s has interface %s on port %d", dpif_name(br->dpif),
iface->name, iface->dp_ifidx);
return true;
}
/* Callback for iterate_and_prune_ifaces(). */
static bool
set_iface_properties(struct bridge *br OVS_UNUSED, struct iface *iface,
void *aux OVS_UNUSED)
{
/* Set policing attributes. */
netdev_set_policing(iface->netdev,
iface->cfg->ingress_policing_rate,
iface->cfg->ingress_policing_burst);
/* Set MAC address of internal interfaces other than the local
* interface. */
if (iface->dp_ifidx != ODPP_LOCAL && !strcmp(iface->type, "internal")) {
iface_set_mac(iface);
}
return true;
}
/* Calls 'cb' for each interfaces in 'br', passing along the 'aux' argument.
* Deletes from 'br' all the interfaces for which 'cb' returns false, and then
* deletes from 'br' any ports that no longer have any interfaces. */
static void
iterate_and_prune_ifaces(struct bridge *br,
bool (*cb)(struct bridge *, struct iface *,
void *aux),
void *aux)
{
size_t i, j;
for (i = 0; i < br->n_ports; ) {
struct port *port = br->ports[i];
for (j = 0; j < port->n_ifaces; ) {
struct iface *iface = port->ifaces[j];
if (cb(br, iface, aux)) {
j++;
} else {
iface_set_ofport(iface->cfg, -1);
iface_destroy(iface);
}
}
if (port->n_ifaces) {
i++;
} else {
VLOG_ERR("%s port has no interfaces, dropping", port->name);
port_destroy(port);
}
}
}
/* Looks at the list of managers in 'ovs_cfg' and extracts their remote IP
* addresses and ports into '*managersp' and '*n_managersp'. The caller is
* responsible for freeing '*managersp' (with free()).
*
* You may be asking yourself "why does ovs-vswitchd care?", because
* ovsdb-server is responsible for connecting to the managers, and ovs-vswitchd
* should not be and in fact is not directly involved in that. But
* ovs-vswitchd needs to make sure that ovsdb-server can reach the managers, so
* it has to tell in-band control where the managers are to enable that.
* (Thus, only managers connected in-band are collected.)
*/
static void
collect_in_band_managers(const struct ovsrec_open_vswitch *ovs_cfg,
struct sockaddr_in **managersp, size_t *n_managersp)
{
struct sockaddr_in *managers = NULL;
size_t n_managers = 0;
struct shash targets;
size_t i;
/* Collect all of the potential targets, as the union of the "managers"
* column and the "targets" columns of the rows pointed to by
* "manager_options", excluding any that are out-of-band. */
shash_init(&targets);
for (i = 0; i < ovs_cfg->n_managers; i++) {
shash_add_once(&targets, ovs_cfg->managers[i], NULL);
}
for (i = 0; i < ovs_cfg->n_manager_options; i++) {
struct ovsrec_manager *m = ovs_cfg->manager_options[i];
if (m->connection_mode && !strcmp(m->connection_mode, "out-of-band")) {
shash_find_and_delete(&targets, m->target);
} else {
shash_add_once(&targets, m->target, NULL);
}
}
/* Now extract the targets' IP addresses. */
if (!shash_is_empty(&targets)) {
struct shash_node *node;
managers = xmalloc(shash_count(&targets) * sizeof *managers);
SHASH_FOR_EACH (node, &targets) {
const char *target = node->name;
struct sockaddr_in *sin = &managers[n_managers];
if ((!strncmp(target, "tcp:", 4)
&& inet_parse_active(target + 4, JSONRPC_TCP_PORT, sin)) ||
(!strncmp(target, "ssl:", 4)
&& inet_parse_active(target + 4, JSONRPC_SSL_PORT, sin))) {
n_managers++;
}
}
}
shash_destroy(&targets);
*managersp = managers;
*n_managersp = n_managers;
}
static void
bridge_reconfigure(const struct ovsrec_open_vswitch *ovs_cfg)
{
struct shash old_br, new_br;
struct shash_node *node;
struct bridge *br, *next;
struct sockaddr_in *managers;
size_t n_managers;
size_t i;
int sflow_bridge_number;
COVERAGE_INC(bridge_reconfigure);
collect_in_band_managers(ovs_cfg, &managers, &n_managers);
/* Collect old and new bridges. */
shash_init(&old_br);
shash_init(&new_br);
LIST_FOR_EACH (br, node, &all_bridges) {
shash_add(&old_br, br->name, br);
}
for (i = 0; i < ovs_cfg->n_bridges; i++) {
const struct ovsrec_bridge *br_cfg = ovs_cfg->bridges[i];
if (!shash_add_once(&new_br, br_cfg->name, br_cfg)) {
VLOG_WARN("more than one bridge named %s", br_cfg->name);
}
}
/* Get rid of deleted bridges and add new bridges. */
LIST_FOR_EACH_SAFE (br, next, node, &all_bridges) {
struct ovsrec_bridge *br_cfg = shash_find_data(&new_br, br->name);
if (br_cfg) {
br->cfg = br_cfg;
} else {
bridge_destroy(br);
}
}
SHASH_FOR_EACH (node, &new_br) {
const char *br_name = node->name;
const struct ovsrec_bridge *br_cfg = node->data;
br = shash_find_data(&old_br, br_name);
if (br) {
/* If the bridge datapath type has changed, we need to tear it
* down and recreate. */
if (strcmp(br->cfg->datapath_type, br_cfg->datapath_type)) {
bridge_destroy(br);
bridge_create(br_cfg);
}
} else {
bridge_create(br_cfg);
}
}
shash_destroy(&old_br);
shash_destroy(&new_br);
/* Reconfigure all bridges. */
LIST_FOR_EACH (br, node, &all_bridges) {
bridge_reconfigure_one(br);
}
/* Add and delete ports on all datapaths.
*
* The kernel will reject any attempt to add a given port to a datapath if
* that port already belongs to a different datapath, so we must do all
* port deletions before any port additions. */
LIST_FOR_EACH (br, node, &all_bridges) {
struct odp_port *dpif_ports;
size_t n_dpif_ports;
struct shash want_ifaces;
dpif_port_list(br->dpif, &dpif_ports, &n_dpif_ports);
bridge_get_all_ifaces(br, &want_ifaces);
for (i = 0; i < n_dpif_ports; i++) {
const struct odp_port *p = &dpif_ports[i];
if (!shash_find(&want_ifaces, p->devname)
&& strcmp(p->devname, br->name)) {
int retval = dpif_port_del(br->dpif, p->port);
if (retval) {
VLOG_ERR("failed to remove %s interface from %s: %s",
p->devname, dpif_name(br->dpif),
strerror(retval));
}
}
}
shash_destroy(&want_ifaces);
free(dpif_ports);
}
LIST_FOR_EACH (br, node, &all_bridges) {
struct odp_port *dpif_ports;
size_t n_dpif_ports;
struct shash cur_ifaces, want_ifaces;
/* Get the set of interfaces currently in this datapath. */
dpif_port_list(br->dpif, &dpif_ports, &n_dpif_ports);
shash_init(&cur_ifaces);
for (i = 0; i < n_dpif_ports; i++) {
const char *name = dpif_ports[i].devname;
shash_add_once(&cur_ifaces, name, &dpif_ports[i]);
}
/* Get the set of interfaces we want on this datapath. */
bridge_get_all_ifaces(br, &want_ifaces);
hmap_clear(&br->ifaces);
SHASH_FOR_EACH (node, &want_ifaces) {
const char *if_name = node->name;
struct iface *iface = node->data;
bool internal = !iface || !strcmp(iface->type, "internal");
struct odp_port *dpif_port = shash_find_data(&cur_ifaces, if_name);
int error;
/* If we have a port or a netdev already, and it's not the type we
* want, then delete the port (if any) and close the netdev (if
* any). */
if (internal
? dpif_port && !(dpif_port->flags & ODP_PORT_INTERNAL)
: (iface->netdev
&& strcmp(iface->type, netdev_get_type(iface->netdev))))
{
if (dpif_port) {
error = ofproto_port_del(br->ofproto, dpif_port->port);
if (error) {
continue;
}
dpif_port = NULL;
}
if (iface) {
netdev_close(iface->netdev);
iface->netdev = NULL;
}
}
/* If it's not an internal port, open (possibly create) the
* netdev. */
if (!internal) {
if (!iface->netdev) {
error = create_iface_netdev(iface);
if (error) {
VLOG_WARN("could not create iface %s: %s", iface->name,
strerror(error));
continue;
}
} else {
reconfigure_iface_netdev(iface);
}
}
/* If it's not part of the datapath, add it. */
if (!dpif_port) {
error = dpif_port_add(br->dpif, if_name,
internal ? ODP_PORT_INTERNAL : 0, NULL);
if (error == EFBIG) {
VLOG_ERR("ran out of valid port numbers on %s",
dpif_name(br->dpif));
break;
} else if (error) {
VLOG_ERR("failed to add %s interface to %s: %s",
if_name, dpif_name(br->dpif), strerror(error));
continue;
}
}
/* If it's an internal port, open the netdev. */
if (internal) {
if (iface && !iface->netdev) {
error = create_iface_netdev(iface);
if (error) {
VLOG_WARN("could not create iface %s: %s", iface->name,
strerror(error));
continue;
}
}
} else {
assert(iface->netdev != NULL);
}
}
free(dpif_ports);
shash_destroy(&cur_ifaces);
shash_destroy(&want_ifaces);
}
sflow_bridge_number = 0;
LIST_FOR_EACH (br, node, &all_bridges) {
uint8_t ea[8];
uint64_t dpid;
struct iface *local_iface;
struct iface *hw_addr_iface;
char *dpid_string;
bridge_fetch_dp_ifaces(br);
iterate_and_prune_ifaces(br, check_iface, NULL);
/* Pick local port hardware address, datapath ID. */
bridge_pick_local_hw_addr(br, ea, &hw_addr_iface);
local_iface = bridge_get_local_iface(br);
if (local_iface) {
int error = netdev_set_etheraddr(local_iface->netdev, ea);
if (error) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_ERR_RL(&rl, "bridge %s: failed to set bridge "
"Ethernet address: %s",
br->name, strerror(error));
}
}
dpid = bridge_pick_datapath_id(br, ea, hw_addr_iface);
ofproto_set_datapath_id(br->ofproto, dpid);
dpid_string = xasprintf("%016"PRIx64, dpid);
ovsrec_bridge_set_datapath_id(br->cfg, dpid_string);
free(dpid_string);
/* Set NetFlow configuration on this bridge. */
if (br->cfg->netflow) {
struct ovsrec_netflow *nf_cfg = br->cfg->netflow;
struct netflow_options opts;
memset(&opts, 0, sizeof opts);
dpif_get_netflow_ids(br->dpif, &opts.engine_type, &opts.engine_id);
if (nf_cfg->engine_type) {
opts.engine_type = *nf_cfg->engine_type;
}
if (nf_cfg->engine_id) {
opts.engine_id = *nf_cfg->engine_id;
}
opts.active_timeout = nf_cfg->active_timeout;
if (!opts.active_timeout) {
opts.active_timeout = -1;
} else if (opts.active_timeout < 0) {
VLOG_WARN("bridge %s: active timeout interval set to negative "
"value, using default instead (%d seconds)", br->name,
NF_ACTIVE_TIMEOUT_DEFAULT);
opts.active_timeout = -1;
}
opts.add_id_to_iface = nf_cfg->add_id_to_interface;
if (opts.add_id_to_iface) {
if (opts.engine_id > 0x7f) {
VLOG_WARN("bridge %s: netflow port mangling may conflict "
"with another vswitch, choose an engine id less "
"than 128", br->name);
}
if (br->n_ports > 508) {
VLOG_WARN("bridge %s: netflow port mangling will conflict "
"with another port when more than 508 ports are "
"used", br->name);
}
}
opts.collectors.n = nf_cfg->n_targets;
opts.collectors.names = nf_cfg->targets;
if (ofproto_set_netflow(br->ofproto, &opts)) {
VLOG_ERR("bridge %s: problem setting netflow collectors",
br->name);
}
} else {
ofproto_set_netflow(br->ofproto, NULL);
}
/* Set sFlow configuration on this bridge. */
if (br->cfg->sflow) {
const struct ovsrec_sflow *sflow_cfg = br->cfg->sflow;
struct ovsrec_controller **controllers;
struct ofproto_sflow_options oso;
size_t n_controllers;
memset(&oso, 0, sizeof oso);
oso.targets.n = sflow_cfg->n_targets;
oso.targets.names = sflow_cfg->targets;
oso.sampling_rate = SFL_DEFAULT_SAMPLING_RATE;
if (sflow_cfg->sampling) {
oso.sampling_rate = *sflow_cfg->sampling;
}
oso.polling_interval = SFL_DEFAULT_POLLING_INTERVAL;
if (sflow_cfg->polling) {
oso.polling_interval = *sflow_cfg->polling;
}
oso.header_len = SFL_DEFAULT_HEADER_SIZE;
if (sflow_cfg->header) {
oso.header_len = *sflow_cfg->header;
}
oso.sub_id = sflow_bridge_number++;
oso.agent_device = sflow_cfg->agent;
oso.control_ip = NULL;
n_controllers = bridge_get_controllers(br, &controllers);
for (i = 0; i < n_controllers; i++) {
if (controllers[i]->local_ip) {
oso.control_ip = controllers[i]->local_ip;
break;
}
}
ofproto_set_sflow(br->ofproto, &oso);
/* Do not destroy oso.targets because it is owned by sflow_cfg. */
} else {
ofproto_set_sflow(br->ofproto, NULL);
}
/* Update the controller and related settings. It would be more
* straightforward to call this from bridge_reconfigure_one(), but we
* can't do it there for two reasons. First, and most importantly, at
* that point we don't know the dp_ifidx of any interfaces that have
* been added to the bridge (because we haven't actually added them to
* the datapath). Second, at that point we haven't set the datapath ID
* yet; when a controller is configured, resetting the datapath ID will
* immediately disconnect from the controller, so it's better to set
* the datapath ID before the controller. */
bridge_reconfigure_remotes(br, managers, n_managers);
}
LIST_FOR_EACH (br, node, &all_bridges) {
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
int j;
port_update_vlan_compat(port);
port_update_bonding(port);
for (j = 0; j < port->n_ifaces; j++) {
iface_update_qos(port->ifaces[j], port->cfg->qos);
}
}
}
LIST_FOR_EACH (br, node, &all_bridges) {
iterate_and_prune_ifaces(br, set_iface_properties, NULL);
}
free(managers);
}
static const char *
get_ovsrec_key_value(const struct ovsdb_idl_row *row,
const struct ovsdb_idl_column *column,
const char *key)
{
const struct ovsdb_datum *datum;
union ovsdb_atom atom;
unsigned int idx;
datum = ovsdb_idl_get(row, column, OVSDB_TYPE_STRING, OVSDB_TYPE_STRING);
atom.string = (char *) key;
idx = ovsdb_datum_find_key(datum, &atom, OVSDB_TYPE_STRING);
return idx == UINT_MAX ? NULL : datum->values[idx].string;
}
static const char *
bridge_get_other_config(const struct ovsrec_bridge *br_cfg, const char *key)
{
return get_ovsrec_key_value(&br_cfg->header_,
&ovsrec_bridge_col_other_config, key);
}
static void
bridge_pick_local_hw_addr(struct bridge *br, uint8_t ea[ETH_ADDR_LEN],
struct iface **hw_addr_iface)
{
const char *hwaddr;
size_t i, j;
int error;
*hw_addr_iface = NULL;
/* Did the user request a particular MAC? */
hwaddr = bridge_get_other_config(br->cfg, "hwaddr");
if (hwaddr && eth_addr_from_string(hwaddr, ea)) {
if (eth_addr_is_multicast(ea)) {
VLOG_ERR("bridge %s: cannot set MAC address to multicast "
"address "ETH_ADDR_FMT, br->name, ETH_ADDR_ARGS(ea));
} else if (eth_addr_is_zero(ea)) {
VLOG_ERR("bridge %s: cannot set MAC address to zero", br->name);
} else {
return;
}
}
/* Otherwise choose the minimum non-local MAC address among all of the
* interfaces. */
memset(ea, 0xff, sizeof ea);
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
uint8_t iface_ea[ETH_ADDR_LEN];
struct iface *iface;
/* Mirror output ports don't participate. */
if (port->is_mirror_output_port) {
continue;
}
/* Choose the MAC address to represent the port. */
if (port->cfg->mac && eth_addr_from_string(port->cfg->mac, iface_ea)) {
/* Find the interface with this Ethernet address (if any) so that
* we can provide the correct devname to the caller. */
iface = NULL;
for (j = 0; j < port->n_ifaces; j++) {
struct iface *candidate = port->ifaces[j];
uint8_t candidate_ea[ETH_ADDR_LEN];
if (!netdev_get_etheraddr(candidate->netdev, candidate_ea)
&& eth_addr_equals(iface_ea, candidate_ea)) {
iface = candidate;
}
}
} else {
/* Choose the interface whose MAC address will represent the port.
* The Linux kernel bonding code always chooses the MAC address of
* the first slave added to a bond, and the Fedora networking
* scripts always add slaves to a bond in alphabetical order, so
* for compatibility we choose the interface with the name that is
* first in alphabetical order. */
iface = port->ifaces[0];
for (j = 1; j < port->n_ifaces; j++) {
struct iface *candidate = port->ifaces[j];
if (strcmp(candidate->name, iface->name) < 0) {
iface = candidate;
}
}
/* The local port doesn't count (since we're trying to choose its
* MAC address anyway). */
if (iface->dp_ifidx == ODPP_LOCAL) {
continue;
}
/* Grab MAC. */
error = netdev_get_etheraddr(iface->netdev, iface_ea);
if (error) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_ERR_RL(&rl, "failed to obtain Ethernet address of %s: %s",
iface->name, strerror(error));
continue;
}
}
/* Compare against our current choice. */
if (!eth_addr_is_multicast(iface_ea) &&
!eth_addr_is_local(iface_ea) &&
!eth_addr_is_reserved(iface_ea) &&
!eth_addr_is_zero(iface_ea) &&
memcmp(iface_ea, ea, ETH_ADDR_LEN) < 0)
{
memcpy(ea, iface_ea, ETH_ADDR_LEN);
*hw_addr_iface = iface;
}
}
if (eth_addr_is_multicast(ea)) {
memcpy(ea, br->default_ea, ETH_ADDR_LEN);
*hw_addr_iface = NULL;
VLOG_WARN("bridge %s: using default bridge Ethernet "
"address "ETH_ADDR_FMT, br->name, ETH_ADDR_ARGS(ea));
} else {
VLOG_DBG("bridge %s: using bridge Ethernet address "ETH_ADDR_FMT,
br->name, ETH_ADDR_ARGS(ea));
}
}
/* Choose and returns the datapath ID for bridge 'br' given that the bridge
* Ethernet address is 'bridge_ea'. If 'bridge_ea' is the Ethernet address of
* an interface on 'br', then that interface must be passed in as
* 'hw_addr_iface'; if 'bridge_ea' was derived some other way, then
* 'hw_addr_iface' must be passed in as a null pointer. */
static uint64_t
bridge_pick_datapath_id(struct bridge *br,
const uint8_t bridge_ea[ETH_ADDR_LEN],
struct iface *hw_addr_iface)
{
/*
* The procedure for choosing a bridge MAC address will, in the most
* ordinary case, also choose a unique MAC that we can use as a datapath
* ID. In some special cases, though, multiple bridges will end up with
* the same MAC address. This is OK for the bridges, but it will confuse
* the OpenFlow controller, because each datapath needs a unique datapath
* ID.
*
* Datapath IDs must be unique. It is also very desirable that they be
* stable from one run to the next, so that policy set on a datapath
* "sticks".
*/
const char *datapath_id;
uint64_t dpid;
datapath_id = bridge_get_other_config(br->cfg, "datapath-id");
if (datapath_id && dpid_from_string(datapath_id, &dpid)) {
return dpid;
}
if (hw_addr_iface) {
int vlan;
if (!netdev_get_vlan_vid(hw_addr_iface->netdev, &vlan)) {
/*
* A bridge whose MAC address is taken from a VLAN network device
* (that is, a network device created with vconfig(8) or similar
* tool) will have the same MAC address as a bridge on the VLAN
* device's physical network device.
*
* Handle this case by hashing the physical network device MAC
* along with the VLAN identifier.
*/
uint8_t buf[ETH_ADDR_LEN + 2];
memcpy(buf, bridge_ea, ETH_ADDR_LEN);
buf[ETH_ADDR_LEN] = vlan >> 8;
buf[ETH_ADDR_LEN + 1] = vlan;
return dpid_from_hash(buf, sizeof buf);
} else {
/*
* Assume that this bridge's MAC address is unique, since it
* doesn't fit any of the cases we handle specially.
*/
}
} else {
/*
* A purely internal bridge, that is, one that has no non-virtual
* network devices on it at all, is more difficult because it has no
* natural unique identifier at all.
*
* When the host is a XenServer, we handle this case by hashing the
* host's UUID with the name of the bridge. Names of bridges are
* persistent across XenServer reboots, although they can be reused if
* an internal network is destroyed and then a new one is later
* created, so this is fairly effective.
*
* When the host is not a XenServer, we punt by using a random MAC
* address on each run.
*/
const char *host_uuid = xenserver_get_host_uuid();
if (host_uuid) {
char *combined = xasprintf("%s,%s", host_uuid, br->name);
dpid = dpid_from_hash(combined, strlen(combined));
free(combined);
return dpid;
}
}
return eth_addr_to_uint64(bridge_ea);
}
static uint64_t
dpid_from_hash(const void *data, size_t n)
{
uint8_t hash[SHA1_DIGEST_SIZE];
BUILD_ASSERT_DECL(sizeof hash >= ETH_ADDR_LEN);
sha1_bytes(data, n, hash);
eth_addr_mark_random(hash);
return eth_addr_to_uint64(hash);
}
static void
iface_refresh_stats(struct iface *iface)
{
struct iface_stat {
char *name;
int offset;
};
static const struct iface_stat iface_stats[] = {
{ "rx_packets", offsetof(struct netdev_stats, rx_packets) },
{ "tx_packets", offsetof(struct netdev_stats, tx_packets) },
{ "rx_bytes", offsetof(struct netdev_stats, rx_bytes) },
{ "tx_bytes", offsetof(struct netdev_stats, tx_bytes) },
{ "rx_dropped", offsetof(struct netdev_stats, rx_dropped) },
{ "tx_dropped", offsetof(struct netdev_stats, tx_dropped) },
{ "rx_errors", offsetof(struct netdev_stats, rx_errors) },
{ "tx_errors", offsetof(struct netdev_stats, tx_errors) },
{ "rx_frame_err", offsetof(struct netdev_stats, rx_frame_errors) },
{ "rx_over_err", offsetof(struct netdev_stats, rx_over_errors) },
{ "rx_crc_err", offsetof(struct netdev_stats, rx_crc_errors) },
{ "collisions", offsetof(struct netdev_stats, collisions) },
};
enum { N_STATS = ARRAY_SIZE(iface_stats) };
const struct iface_stat *s;
char *keys[N_STATS];
int64_t values[N_STATS];
int n;
struct netdev_stats stats;
/* Intentionally ignore return value, since errors will set 'stats' to
* all-1s, and we will deal with that correctly below. */
netdev_get_stats(iface->netdev, &stats);
n = 0;
for (s = iface_stats; s < &iface_stats[N_STATS]; s++) {
uint64_t value = *(uint64_t *) (((char *) &stats) + s->offset);
if (value != UINT64_MAX) {
keys[n] = s->name;
values[n] = value;
n++;
}
}
ovsrec_interface_set_statistics(iface->cfg, keys, values, n);
}
static void
refresh_system_stats(const struct ovsrec_open_vswitch *cfg)
{
struct ovsdb_datum datum;
struct shash stats;
shash_init(&stats);
get_system_stats(&stats);
ovsdb_datum_from_shash(&datum, &stats);
ovsdb_idl_txn_write(&cfg->header_, &ovsrec_open_vswitch_col_statistics,
&datum);
}
void
bridge_run(void)
{
const struct ovsrec_open_vswitch *cfg;
bool datapath_destroyed;
bool database_changed;
struct bridge *br;
/* Let each bridge do the work that it needs to do. */
datapath_destroyed = false;
LIST_FOR_EACH (br, node, &all_bridges) {
int error = bridge_run_one(br);
if (error) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_ERR_RL(&rl, "bridge %s: datapath was destroyed externally, "
"forcing reconfiguration", br->name);
datapath_destroyed = true;
}
}
/* (Re)configure if necessary. */
database_changed = ovsdb_idl_run(idl);
cfg = ovsrec_open_vswitch_first(idl);
if (database_changed || datapath_destroyed) {
if (cfg) {
struct ovsdb_idl_txn *txn = ovsdb_idl_txn_create(idl);
bridge_configure_once(cfg);
bridge_reconfigure(cfg);
ovsrec_open_vswitch_set_cur_cfg(cfg, cfg->next_cfg);
ovsdb_idl_txn_commit(txn);
ovsdb_idl_txn_destroy(txn); /* XXX */
} else {
/* We still need to reconfigure to avoid dangling pointers to
* now-destroyed ovsrec structures inside bridge data. */
static const struct ovsrec_open_vswitch null_cfg;
bridge_reconfigure(&null_cfg);
}
}
#ifdef HAVE_OPENSSL
/* Re-configure SSL. We do this on every trip through the main loop,
* instead of just when the database changes, because the contents of the
* key and certificate files can change without the database changing. */
if (cfg && cfg->ssl) {
const struct ovsrec_ssl *ssl = cfg->ssl;
stream_ssl_set_key_and_cert(ssl->private_key, ssl->certificate);
stream_ssl_set_ca_cert_file(ssl->ca_cert, ssl->bootstrap_ca_cert);
}
#endif
/* Refresh system and interface stats if necessary. */
if (time_msec() >= stats_timer) {
if (cfg) {
struct ovsdb_idl_txn *txn;
txn = ovsdb_idl_txn_create(idl);
LIST_FOR_EACH (br, node, &all_bridges) {
size_t i;
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
size_t j;
for (j = 0; j < port->n_ifaces; j++) {
struct iface *iface = port->ifaces[j];
iface_refresh_stats(iface);
}
}
}
refresh_system_stats(cfg);
ovsdb_idl_txn_commit(txn);
ovsdb_idl_txn_destroy(txn); /* XXX */
}
stats_timer = time_msec() + STATS_INTERVAL;
}
}
void
bridge_wait(void)
{
struct bridge *br;
LIST_FOR_EACH (br, node, &all_bridges) {
ofproto_wait(br->ofproto);
if (ofproto_has_primary_controller(br->ofproto)) {
continue;
}
mac_learning_wait(br->ml);
bond_wait(br);
}
ovsdb_idl_wait(idl);
poll_timer_wait_until(stats_timer);
}
/* Forces 'br' to revalidate all of its flows. This is appropriate when 'br''s
* configuration changes. */
static void
bridge_flush(struct bridge *br)
{
COVERAGE_INC(bridge_flush);
br->flush = true;
mac_learning_flush(br->ml);
}
/* Returns the 'br' interface for the ODPP_LOCAL port, or null if 'br' has no
* such interface. */
static struct iface *
bridge_get_local_iface(struct bridge *br)
{
size_t i, j;
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
for (j = 0; j < port->n_ifaces; j++) {
struct iface *iface = port->ifaces[j];
if (iface->dp_ifidx == ODPP_LOCAL) {
return iface;
}
}
}
return NULL;
}
/* Bridge unixctl user interface functions. */
static void
bridge_unixctl_fdb_show(struct unixctl_conn *conn,
const char *args, void *aux OVS_UNUSED)
{
struct ds ds = DS_EMPTY_INITIALIZER;
const struct bridge *br;
const struct mac_entry *e;
br = bridge_lookup(args);
if (!br) {
unixctl_command_reply(conn, 501, "no such bridge");
return;
}
ds_put_cstr(&ds, " port VLAN MAC Age\n");
LIST_FOR_EACH (e, lru_node, &br->ml->lrus) {
if (e->port < 0 || e->port >= br->n_ports) {
continue;
}
ds_put_format(&ds, "%5d %4d "ETH_ADDR_FMT" %3d\n",
br->ports[e->port]->ifaces[0]->dp_ifidx,
e->vlan, ETH_ADDR_ARGS(e->mac), mac_entry_age(e));
}
unixctl_command_reply(conn, 200, ds_cstr(&ds));
ds_destroy(&ds);
}
/* Bridge reconfiguration functions. */
static struct bridge *
bridge_create(const struct ovsrec_bridge *br_cfg)
{
struct bridge *br;
int error;
assert(!bridge_lookup(br_cfg->name));
br = xzalloc(sizeof *br);
error = dpif_create_and_open(br_cfg->name, br_cfg->datapath_type,
&br->dpif);
if (error) {
free(br);
return NULL;
}
dpif_flow_flush(br->dpif);
error = ofproto_create(br_cfg->name, br_cfg->datapath_type, &bridge_ofhooks,
br, &br->ofproto);
if (error) {
VLOG_ERR("failed to create switch %s: %s", br_cfg->name,
strerror(error));
dpif_delete(br->dpif);
dpif_close(br->dpif);
free(br);
return NULL;
}
br->name = xstrdup(br_cfg->name);
br->cfg = br_cfg;
br->ml = mac_learning_create();
eth_addr_nicira_random(br->default_ea);
hmap_init(&br->ifaces);
shash_init(&br->port_by_name);
shash_init(&br->iface_by_name);
br->flush = false;
list_push_back(&all_bridges, &br->node);
VLOG_INFO("created bridge %s on %s", br->name, dpif_name(br->dpif));
return br;
}
static void
bridge_destroy(struct bridge *br)
{
if (br) {
int error;
while (br->n_ports > 0) {
port_destroy(br->ports[br->n_ports - 1]);
}
list_remove(&br->node);
error = dpif_delete(br->dpif);
if (error && error != ENOENT) {
VLOG_ERR("failed to delete %s: %s",
dpif_name(br->dpif), strerror(error));
}
dpif_close(br->dpif);
ofproto_destroy(br->ofproto);
mac_learning_destroy(br->ml);
hmap_destroy(&br->ifaces);
shash_destroy(&br->port_by_name);
shash_destroy(&br->iface_by_name);
free(br->ports);
free(br->name);
free(br);
}
}
static struct bridge *
bridge_lookup(const char *name)
{
struct bridge *br;
LIST_FOR_EACH (br, node, &all_bridges) {
if (!strcmp(br->name, name)) {
return br;
}
}
return NULL;
}
/* Handle requests for a listing of all flows known by the OpenFlow
* stack, including those normally hidden. */
static void
bridge_unixctl_dump_flows(struct unixctl_conn *conn,
const char *args, void *aux OVS_UNUSED)
{
struct bridge *br;
struct ds results;
br = bridge_lookup(args);
if (!br) {
unixctl_command_reply(conn, 501, "Unknown bridge");
return;
}
ds_init(&results);
ofproto_get_all_flows(br->ofproto, &results);
unixctl_command_reply(conn, 200, ds_cstr(&results));
ds_destroy(&results);
}
/* "bridge/reconnect [BRIDGE]": makes BRIDGE drop all of its controller
* connections and reconnect. If BRIDGE is not specified, then all bridges
* drop their controller connections and reconnect. */
static void
bridge_unixctl_reconnect(struct unixctl_conn *conn,
const char *args, void *aux OVS_UNUSED)
{
struct bridge *br;
if (args[0] != '\0') {
br = bridge_lookup(args);
if (!br) {
unixctl_command_reply(conn, 501, "Unknown bridge");
return;
}
ofproto_reconnect_controllers(br->ofproto);
} else {
LIST_FOR_EACH (br, node, &all_bridges) {
ofproto_reconnect_controllers(br->ofproto);
}
}
unixctl_command_reply(conn, 200, NULL);
}
static int
bridge_run_one(struct bridge *br)
{
int error;
error = ofproto_run1(br->ofproto);
if (error) {
return error;
}
mac_learning_run(br->ml, ofproto_get_revalidate_set(br->ofproto));
bond_run(br);
error = ofproto_run2(br->ofproto, br->flush);
br->flush = false;
return error;
}
static size_t
bridge_get_controllers(const struct bridge *br,
struct ovsrec_controller ***controllersp)
{
struct ovsrec_controller **controllers;
size_t n_controllers;
controllers = br->cfg->controller;
n_controllers = br->cfg->n_controller;
if (n_controllers == 1 && !strcmp(controllers[0]->target, "none")) {
controllers = NULL;
n_controllers = 0;
}
if (controllersp) {
*controllersp = controllers;
}
return n_controllers;
}
static void
bridge_reconfigure_one(struct bridge *br)
{
struct shash old_ports, new_ports;
struct svec snoops, old_snoops;
struct shash_node *node;
enum ofproto_fail_mode fail_mode;
size_t i;
/* Collect old ports. */
shash_init(&old_ports);
for (i = 0; i < br->n_ports; i++) {
shash_add(&old_ports, br->ports[i]->name, br->ports[i]);
}
/* Collect new ports. */
shash_init(&new_ports);
for (i = 0; i < br->cfg->n_ports; i++) {
const char *name = br->cfg->ports[i]->name;
if (!shash_add_once(&new_ports, name, br->cfg->ports[i])) {
VLOG_WARN("bridge %s: %s specified twice as bridge port",
br->name, name);
}
}
/* If we have a controller, then we need a local port. Complain if the
* user didn't specify one.
*
* XXX perhaps we should synthesize a port ourselves in this case. */
if (bridge_get_controllers(br, NULL)) {
char local_name[IF_NAMESIZE];
int error;
error = dpif_port_get_name(br->dpif, ODPP_LOCAL,
local_name, sizeof local_name);
if (!error && !shash_find(&new_ports, local_name)) {
VLOG_WARN("bridge %s: controller specified but no local port "
"(port named %s) defined",
br->name, local_name);
}
}
/* Get rid of deleted ports.
* Get rid of deleted interfaces on ports that still exist. */
SHASH_FOR_EACH (node, &old_ports) {
struct port *port = node->data;
const struct ovsrec_port *port_cfg;
port_cfg = shash_find_data(&new_ports, node->name);
if (!port_cfg) {
port_destroy(port);
} else {
port_del_ifaces(port, port_cfg);
}
}
/* Create new ports.
* Add new interfaces to existing ports.
* Reconfigure existing ports. */
SHASH_FOR_EACH (node, &new_ports) {
struct port *port = shash_find_data(&old_ports, node->name);
if (!port) {
port = port_create(br, node->name);
}
port_reconfigure(port, node->data);
if (!port->n_ifaces) {
VLOG_WARN("bridge %s: port %s has no interfaces, dropping",
br->name, port->name);
port_destroy(port);
}
}
shash_destroy(&old_ports);
shash_destroy(&new_ports);
/* Set the fail-mode */
fail_mode = !br->cfg->fail_mode
|| !strcmp(br->cfg->fail_mode, "standalone")
? OFPROTO_FAIL_STANDALONE
: OFPROTO_FAIL_SECURE;
if (ofproto_get_fail_mode(br->ofproto) != fail_mode
&& !ofproto_has_primary_controller(br->ofproto)) {
ofproto_flush_flows(br->ofproto);
}
ofproto_set_fail_mode(br->ofproto, fail_mode);
/* Delete all flows if we're switching from connected to standalone or vice
* versa. (XXX Should we delete all flows if we are switching from one
* controller to another?) */
/* Configure OpenFlow controller connection snooping. */
svec_init(&snoops);
svec_add_nocopy(&snoops, xasprintf("punix:%s/%s.snoop",
ovs_rundir, br->name));
svec_init(&old_snoops);
ofproto_get_snoops(br->ofproto, &old_snoops);
if (!svec_equal(&snoops, &old_snoops)) {
ofproto_set_snoops(br->ofproto, &snoops);
}
svec_destroy(&snoops);
svec_destroy(&old_snoops);
mirror_reconfigure(br);
}
/* Initializes 'oc' appropriately as a management service controller for
* 'br'.
*
* The caller must free oc->target when it is no longer needed. */
static void
bridge_ofproto_controller_for_mgmt(const struct bridge *br,
struct ofproto_controller *oc)
{
oc->target = xasprintf("punix:%s/%s.mgmt", ovs_rundir, br->name);
oc->max_backoff = 0;
oc->probe_interval = 60;
oc->band = OFPROTO_OUT_OF_BAND;
oc->accept_re = NULL;
oc->update_resolv_conf = false;
oc->rate_limit = 0;
oc->burst_limit = 0;
}
/* Converts ovsrec_controller 'c' into an ofproto_controller in 'oc'. */
static void
bridge_ofproto_controller_from_ovsrec(const struct ovsrec_controller *c,
struct ofproto_controller *oc)
{
oc->target = c->target;
oc->max_backoff = c->max_backoff ? *c->max_backoff / 1000 : 8;
oc->probe_interval = c->inactivity_probe ? *c->inactivity_probe / 1000 : 5;
oc->band = (!c->connection_mode || !strcmp(c->connection_mode, "in-band")
? OFPROTO_IN_BAND : OFPROTO_OUT_OF_BAND);
oc->accept_re = c->discover_accept_regex;
oc->update_resolv_conf = c->discover_update_resolv_conf;
oc->rate_limit = c->controller_rate_limit ? *c->controller_rate_limit : 0;
oc->burst_limit = (c->controller_burst_limit
? *c->controller_burst_limit : 0);
}
/* Configures the IP stack for 'br''s local interface properly according to the
* configuration in 'c'. */
static void
bridge_configure_local_iface_netdev(struct bridge *br,
struct ovsrec_controller *c)
{
struct netdev *netdev;
struct in_addr mask, gateway;
struct iface *local_iface;
struct in_addr ip;
/* Controller discovery does its own TCP/IP configuration later. */
if (strcmp(c->target, "discover")) {
return;
}
/* If there's no local interface or no IP address, give up. */
local_iface = bridge_get_local_iface(br);
if (!local_iface || !c->local_ip || !inet_aton(c->local_ip, &ip)) {
return;
}
/* Bring up the local interface. */
netdev = local_iface->netdev;
netdev_turn_flags_on(netdev, NETDEV_UP, true);
/* Configure the IP address and netmask. */
if (!c->local_netmask
|| !inet_aton(c->local_netmask, &mask)
|| !mask.s_addr) {
mask.s_addr = guess_netmask(ip.s_addr);
}
if (!netdev_set_in4(netdev, ip, mask)) {
VLOG_INFO("bridge %s: configured IP address "IP_FMT", netmask "IP_FMT,
br->name, IP_ARGS(&ip.s_addr), IP_ARGS(&mask.s_addr));
}
/* Configure the default gateway. */
if (c->local_gateway
&& inet_aton(c->local_gateway, &gateway)
&& gateway.s_addr) {
if (!netdev_add_router(netdev, gateway)) {
VLOG_INFO("bridge %s: configured gateway "IP_FMT,
br->name, IP_ARGS(&gateway.s_addr));
}
}
}
static void
bridge_reconfigure_remotes(struct bridge *br,
const struct sockaddr_in *managers,
size_t n_managers)
{
struct ovsrec_controller **controllers;
size_t n_controllers;
bool had_primary;
const char *disable_ib_str;
bool disable_in_band = false;
struct ofproto_controller *ocs;
size_t n_ocs;
size_t i;
/* Check if we should disable in-band control on this bridge. */
disable_ib_str = bridge_get_other_config(br->cfg, "disable-in-band");
if (disable_ib_str && !strcmp(disable_ib_str, "true")) {
disable_in_band = true;
}
if (disable_in_band) {
ofproto_set_extra_in_band_remotes(br->ofproto, NULL, 0);
} else {
ofproto_set_extra_in_band_remotes(br->ofproto, managers, n_managers);
}
had_primary = ofproto_has_primary_controller(br->ofproto);
n_controllers = bridge_get_controllers(br, &controllers);
ocs = xmalloc((n_controllers + 1) * sizeof *ocs);
n_ocs = 0;
bridge_ofproto_controller_for_mgmt(br, &ocs[n_ocs++]);
for (i = 0; i < n_controllers; i++) {
struct ovsrec_controller *c = controllers[i];
if (!strncmp(c->target, "punix:", 6)
|| !strncmp(c->target, "unix:", 5)) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
/* Prevent remote ovsdb-server users from accessing arbitrary Unix
* domain sockets and overwriting arbitrary local files. */
VLOG_ERR_RL(&rl, "%s: not adding Unix domain socket controller "
"\"%s\" due to possibility for remote exploit",
dpif_name(br->dpif), c->target);
continue;
}
bridge_configure_local_iface_netdev(br, c);
bridge_ofproto_controller_from_ovsrec(c, &ocs[n_ocs]);
if (disable_in_band) {
ocs[n_ocs].band = OFPROTO_OUT_OF_BAND;
}
n_ocs++;
}
ofproto_set_controllers(br->ofproto, ocs, n_ocs);
free(ocs[0].target); /* From bridge_ofproto_controller_for_mgmt(). */
free(ocs);
if (had_primary != ofproto_has_primary_controller(br->ofproto)) {
ofproto_flush_flows(br->ofproto);
}
/* If there are no controllers and the bridge is in standalone
* mode, set up a flow that matches every packet and directs
* them to OFPP_NORMAL (which goes to us). Otherwise, the
* switch is in secure mode and we won't pass any traffic until
* a controller has been defined and it tells us to do so. */
if (!n_controllers
&& ofproto_get_fail_mode(br->ofproto) == OFPROTO_FAIL_STANDALONE) {
union ofp_action action;
struct cls_rule rule;
memset(&action, 0, sizeof action);
action.type = htons(OFPAT_OUTPUT);
action.output.len = htons(sizeof action);
action.output.port = htons(OFPP_NORMAL);
cls_rule_init_catchall(&rule, 0);
ofproto_add_flow(br->ofproto, &rule, &action, 1, 0);
}
}
static void
bridge_get_all_ifaces(const struct bridge *br, struct shash *ifaces)
{
size_t i, j;
shash_init(ifaces);
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
for (j = 0; j < port->n_ifaces; j++) {
struct iface *iface = port->ifaces[j];
shash_add_once(ifaces, iface->name, iface);
}
if (port->n_ifaces > 1 && port->cfg->bond_fake_iface) {
shash_add_once(ifaces, port->name, NULL);
}
}
}
/* For robustness, in case the administrator moves around datapath ports behind
* our back, we re-check all the datapath port numbers here.
*
* This function will set the 'dp_ifidx' members of interfaces that have
* disappeared to -1, so only call this function from a context where those
* 'struct iface's will be removed from the bridge. Otherwise, the -1
* 'dp_ifidx'es will cause trouble later when we try to send them to the
* datapath, which doesn't support UINT16_MAX+1 ports. */
static void
bridge_fetch_dp_ifaces(struct bridge *br)
{
struct odp_port *dpif_ports;
size_t n_dpif_ports;
size_t i, j;
/* Reset all interface numbers. */
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
for (j = 0; j < port->n_ifaces; j++) {
struct iface *iface = port->ifaces[j];
iface->dp_ifidx = -1;
}
}
hmap_clear(&br->ifaces);
dpif_port_list(br->dpif, &dpif_ports, &n_dpif_ports);
for (i = 0; i < n_dpif_ports; i++) {
struct odp_port *p = &dpif_ports[i];
struct iface *iface = iface_lookup(br, p->devname);
if (iface) {
if (iface->dp_ifidx >= 0) {
VLOG_WARN("%s reported interface %s twice",
dpif_name(br->dpif), p->devname);
} else if (iface_from_dp_ifidx(br, p->port)) {
VLOG_WARN("%s reported interface %"PRIu16" twice",
dpif_name(br->dpif), p->port);
} else {
iface->dp_ifidx = p->port;
hmap_insert(&br->ifaces, &iface->dp_ifidx_node,
hash_int(iface->dp_ifidx, 0));
}
iface_set_ofport(iface->cfg,
(iface->dp_ifidx >= 0
? odp_port_to_ofp_port(iface->dp_ifidx)
: -1));
}
}
free(dpif_ports);
}
/* Bridge packet processing functions. */
static int
bond_hash(const uint8_t mac[ETH_ADDR_LEN])
{
return hash_bytes(mac, ETH_ADDR_LEN, 0) & BOND_MASK;
}
static struct bond_entry *
lookup_bond_entry(const struct port *port, const uint8_t mac[ETH_ADDR_LEN])
{
return &port->bond_hash[bond_hash(mac)];
}
static int
bond_choose_iface(const struct port *port)
{
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 20);
size_t i, best_down_slave = -1;
long long next_delay_expiration = LLONG_MAX;
for (i = 0; i < port->n_ifaces; i++) {
struct iface *iface = port->ifaces[i];
if (iface->enabled) {
return i;
} else if (iface->delay_expires < next_delay_expiration) {
best_down_slave = i;
next_delay_expiration = iface->delay_expires;
}
}
if (best_down_slave != -1) {
struct iface *iface = port->ifaces[best_down_slave];
VLOG_INFO_RL(&rl, "interface %s: skipping remaining %lli ms updelay "
"since no other interface is up", iface->name,
iface->delay_expires - time_msec());
bond_enable_slave(iface, true);
}
return best_down_slave;
}
static bool
choose_output_iface(const struct port *port, const uint8_t *dl_src,
uint16_t *dp_ifidx, tag_type *tags)
{
struct iface *iface;
assert(port->n_ifaces);
if (port->n_ifaces == 1) {
iface = port->ifaces[0];
} else {
struct bond_entry *e = lookup_bond_entry(port, dl_src);
if (e->iface_idx < 0 || e->iface_idx >= port->n_ifaces
|| !port->ifaces[e->iface_idx]->enabled) {
/* XXX select interface properly. The current interface selection
* is only good for testing the rebalancing code. */
e->iface_idx = bond_choose_iface(port);
if (e->iface_idx < 0) {
*tags |= port->no_ifaces_tag;
return false;
}
e->iface_tag = tag_create_random();
((struct port *) port)->bond_compat_is_stale = true;
}
*tags |= e->iface_tag;
iface = port->ifaces[e->iface_idx];
}
*dp_ifidx = iface->dp_ifidx;
*tags |= iface->tag; /* Currently only used for bonding. */
return true;
}
static void
bond_link_status_update(struct iface *iface, bool carrier)
{
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 20);
struct port *port = iface->port;
if ((carrier == iface->enabled) == (iface->delay_expires == LLONG_MAX)) {
/* Nothing to do. */
return;
}
VLOG_INFO_RL(&rl, "interface %s: carrier %s",
iface->name, carrier ? "detected" : "dropped");
if (carrier == iface->enabled) {
iface->delay_expires = LLONG_MAX;
VLOG_INFO_RL(&rl, "interface %s: will not be %s",
iface->name, carrier ? "disabled" : "enabled");
} else if (carrier && port->active_iface < 0) {
bond_enable_slave(iface, true);
if (port->updelay) {
VLOG_INFO_RL(&rl, "interface %s: skipping %d ms updelay since no "
"other interface is up", iface->name, port->updelay);
}
} else {
int delay = carrier ? port->updelay : port->downdelay;
iface->delay_expires = time_msec() + delay;
if (delay) {
VLOG_INFO_RL(&rl,
"interface %s: will be %s if it stays %s for %d ms",
iface->name,
carrier ? "enabled" : "disabled",
carrier ? "up" : "down",
delay);
}
}
}
static void
bond_choose_active_iface(struct port *port)
{
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 20);
port->active_iface = bond_choose_iface(port);
port->active_iface_tag = tag_create_random();
if (port->active_iface >= 0) {
VLOG_INFO_RL(&rl, "port %s: active interface is now %s",
port->name, port->ifaces[port->active_iface]->name);
} else {
VLOG_WARN_RL(&rl, "port %s: all ports disabled, no active interface",
port->name);
}
}
static void
bond_enable_slave(struct iface *iface, bool enable)
{
struct port *port = iface->port;
struct bridge *br = port->bridge;
/* This acts as a recursion check. If the act of disabling a slave
* causes a different slave to be enabled, the flag will allow us to
* skip redundant work when we reenter this function. It must be
* cleared on exit to keep things safe with multiple bonds. */
static bool moving_active_iface = false;
iface->delay_expires = LLONG_MAX;
if (enable == iface->enabled) {
return;
}
iface->enabled = enable;
if (!iface->enabled) {
VLOG_WARN("interface %s: disabled", iface->name);
ofproto_revalidate(br->ofproto, iface->tag);
if (iface->port_ifidx == port->active_iface) {
ofproto_revalidate(br->ofproto,
port->active_iface_tag);
/* Disabling a slave can lead to another slave being immediately
* enabled if there will be no active slaves but one is waiting
* on an updelay. In this case we do not need to run most of the
* code for the newly enabled slave since there was no period
* without an active slave and it is redundant with the disabling
* path. */
moving_active_iface = true;
bond_choose_active_iface(port);
}
bond_send_learning_packets(port);
} else {
VLOG_WARN("interface %s: enabled", iface->name);
if (port->active_iface < 0 && !moving_active_iface) {
ofproto_revalidate(br->ofproto, port->no_ifaces_tag);
bond_choose_active_iface(port);
bond_send_learning_packets(port);
}
iface->tag = tag_create_random();
}
moving_active_iface = false;
port->bond_compat_is_stale = true;
}
/* Attempts to make the sum of the bond slaves' statistics appear on the fake
* bond interface. */
static void
bond_update_fake_iface_stats(struct port *port)
{
struct netdev_stats bond_stats;
struct netdev *bond_dev;
size_t i;
memset(&bond_stats, 0, sizeof bond_stats);
for (i = 0; i < port->n_ifaces; i++) {
struct netdev_stats slave_stats;
if (!netdev_get_stats(port->ifaces[i]->netdev, &slave_stats)) {
/* XXX: We swap the stats here because they are swapped back when
* reported by the internal device. The reason for this is
* internal devices normally represent packets going into the system
* but when used as fake bond device they represent packets leaving
* the system. We really should do this in the internal device
* itself because changing it here reverses the counts from the
* perspective of the switch. However, the internal device doesn't
* know what type of device it represents so we have to do it here
* for now. */
bond_stats.tx_packets += slave_stats.rx_packets;
bond_stats.tx_bytes += slave_stats.rx_bytes;
bond_stats.rx_packets += slave_stats.tx_packets;
bond_stats.rx_bytes += slave_stats.tx_bytes;
}
}
if (!netdev_open_default(port->name, &bond_dev)) {
netdev_set_stats(bond_dev, &bond_stats);
netdev_close(bond_dev);
}
}
static void
bond_run(struct bridge *br)
{
size_t i, j;
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
if (port->n_ifaces >= 2) {
char *devname;
/* Track carrier going up and down on interfaces. */
while (!netdev_monitor_poll(port->monitor, &devname)) {
struct iface *iface;
iface = port_lookup_iface(port, devname);
if (iface) {
bool carrier = netdev_get_carrier(iface->netdev);
bond_link_status_update(iface, carrier);
port_update_bond_compat(port);
}
free(devname);
}
for (j = 0; j < port->n_ifaces; j++) {
struct iface *iface = port->ifaces[j];
if (time_msec() >= iface->delay_expires) {
bond_enable_slave(iface, !iface->enabled);
}
}
if (port->bond_fake_iface
&& time_msec() >= port->bond_next_fake_iface_update) {
bond_update_fake_iface_stats(port);
port->bond_next_fake_iface_update = time_msec() + 1000;
}
}
if (port->bond_compat_is_stale) {
port->bond_compat_is_stale = false;
port_update_bond_compat(port);
}
}
}
static void
bond_wait(struct bridge *br)
{
size_t i, j;
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
if (port->n_ifaces < 2) {
continue;
}
netdev_monitor_poll_wait(port->monitor);
for (j = 0; j < port->n_ifaces; j++) {
struct iface *iface = port->ifaces[j];
if (iface->delay_expires != LLONG_MAX) {
poll_timer_wait_until(iface->delay_expires);
}
}
if (port->bond_fake_iface) {
poll_timer_wait_until(port->bond_next_fake_iface_update);
}
}
}
static bool
set_dst(struct dst *p, const struct flow *flow,
const struct port *in_port, const struct port *out_port,
tag_type *tags)
{
p->vlan = (out_port->vlan >= 0 ? OFP_VLAN_NONE
: in_port->vlan >= 0 ? in_port->vlan
: ntohs(flow->dl_vlan));
return choose_output_iface(out_port, flow->dl_src, &p->dp_ifidx, tags);
}
static void
swap_dst(struct dst *p, struct dst *q)
{
struct dst tmp = *p;
*p = *q;
*q = tmp;
}
/* Moves all the dsts with vlan == 'vlan' to the front of the 'n_dsts' in
* 'dsts'. (This may help performance by reducing the number of VLAN changes
* that we push to the datapath. We could in fact fully sort the array by
* vlan, but in most cases there are at most two different vlan tags so that's
* possibly overkill.) */
static void
partition_dsts(struct dst *dsts, size_t n_dsts, int vlan)
{
struct dst *first = dsts;
struct dst *last = dsts + n_dsts;
while (first != last) {
/* Invariants:
* - All dsts < first have vlan == 'vlan'.
* - All dsts >= last have vlan != 'vlan'.
* - first < last. */
while (first->vlan == vlan) {
if (++first == last) {
return;
}
}
/* Same invariants, plus one additional:
* - first->vlan != vlan.
*/
while (last[-1].vlan != vlan) {
if (--last == first) {
return;
}
}
/* Same invariants, plus one additional:
* - last[-1].vlan == vlan.*/
swap_dst(first++, --last);
}
}
static int
mirror_mask_ffs(mirror_mask_t mask)
{
BUILD_ASSERT_DECL(sizeof(unsigned int) >= sizeof(mask));
return ffs(mask);
}
static bool
dst_is_duplicate(const struct dst *dsts, size_t n_dsts,
const struct dst *test)
{
size_t i;
for (i = 0; i < n_dsts; i++) {
if (dsts[i].vlan == test->vlan && dsts[i].dp_ifidx == test->dp_ifidx) {
return true;
}
}
return false;
}
static bool
port_trunks_vlan(const struct port *port, uint16_t vlan)
{
return (port->vlan < 0
&& (!port->trunks || bitmap_is_set(port->trunks, vlan)));
}
static bool
port_includes_vlan(const struct port *port, uint16_t vlan)
{
return vlan == port->vlan || port_trunks_vlan(port, vlan);
}
static bool
port_is_floodable(const struct port *port)
{
int i;
for (i = 0; i < port->n_ifaces; i++) {
if (!ofproto_port_is_floodable(port->bridge->ofproto,
port->ifaces[i]->dp_ifidx)) {
return false;
}
}
return true;
}
static size_t
compose_dsts(const struct bridge *br, const struct flow *flow, uint16_t vlan,
const struct port *in_port, const struct port *out_port,
struct dst dsts[], tag_type *tags, uint16_t *nf_output_iface)
{
mirror_mask_t mirrors = in_port->src_mirrors;
struct dst *dst = dsts;
size_t i;
if (out_port == FLOOD_PORT) {
/* XXX use ODP_FLOOD if no vlans or bonding. */
/* XXX even better, define each VLAN as a datapath port group */
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
if (port != in_port
&& port_is_floodable(port)
&& port_includes_vlan(port, vlan)
&& !port->is_mirror_output_port
&& set_dst(dst, flow, in_port, port, tags)) {
mirrors |= port->dst_mirrors;
dst++;
}
}
*nf_output_iface = NF_OUT_FLOOD;
} else if (out_port && set_dst(dst, flow, in_port, out_port, tags)) {
*nf_output_iface = dst->dp_ifidx;
mirrors |= out_port->dst_mirrors;
dst++;
}
while (mirrors) {
struct mirror *m = br->mirrors[mirror_mask_ffs(mirrors) - 1];
if (!m->n_vlans || vlan_is_mirrored(m, vlan)) {
if (m->out_port) {
if (set_dst(dst, flow, in_port, m->out_port, tags)
&& !dst_is_duplicate(dsts, dst - dsts, dst)) {
dst++;
}
} else {
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
if (port_includes_vlan(port, m->out_vlan)
&& set_dst(dst, flow, in_port, port, tags))
{
int flow_vlan;
if (port->vlan < 0) {
dst->vlan = m->out_vlan;
}
if (dst_is_duplicate(dsts, dst - dsts, dst)) {
continue;
}
/* Use the vlan tag on the original flow instead of
* the one passed in the vlan parameter. This ensures
* that we compare the vlan from before any implicit
* tagging tags place. This is necessary because
* dst->vlan is the final vlan, after removing implicit
* tags. */
flow_vlan = ntohs(flow->dl_vlan);
if (flow_vlan == 0) {
flow_vlan = OFP_VLAN_NONE;
}
if (port == in_port && dst->vlan == flow_vlan) {
/* Don't send out input port on same VLAN. */
continue;
}
dst++;
}
}
}
}
mirrors &= mirrors - 1;
}
partition_dsts(dsts, dst - dsts, ntohs(flow->dl_vlan));
return dst - dsts;
}
static void OVS_UNUSED
print_dsts(const struct dst *dsts, size_t n)
{
for (; n--; dsts++) {
printf(">p%"PRIu16, dsts->dp_ifidx);
if (dsts->vlan != OFP_VLAN_NONE) {
printf("v%"PRIu16, dsts->vlan);
}
}
}
static void
compose_actions(struct bridge *br, const struct flow *flow, uint16_t vlan,
const struct port *in_port, const struct port *out_port,
tag_type *tags, struct odp_actions *actions,
uint16_t *nf_output_iface)
{
struct dst dsts[DP_MAX_PORTS * (MAX_MIRRORS + 1)];
size_t n_dsts;
const struct dst *p;
uint16_t cur_vlan;
n_dsts = compose_dsts(br, flow, vlan, in_port, out_port, dsts, tags,
nf_output_iface);
cur_vlan = ntohs(flow->dl_vlan);
for (p = dsts; p < &dsts[n_dsts]; p++) {
union odp_action *a;
if (p->vlan != cur_vlan) {
if (p->vlan == OFP_VLAN_NONE) {
odp_actions_add(actions, ODPAT_STRIP_VLAN);
} else {
a = odp_actions_add(actions, ODPAT_SET_DL_TCI);
a->dl_tci.tci = htons(p->vlan & VLAN_VID_MASK);
a->dl_tci.tci |= htons(flow->dl_vlan_pcp << VLAN_PCP_SHIFT);
}
cur_vlan = p->vlan;
}
a = odp_actions_add(actions, ODPAT_OUTPUT);
a->output.port = p->dp_ifidx;
}
}
/* Returns the effective vlan of a packet, taking into account both the
* 802.1Q header and implicitly tagged ports. A value of 0 indicates that
* the packet is untagged and -1 indicates it has an invalid header and
* should be dropped. */
static int flow_get_vlan(struct bridge *br, const struct flow *flow,
struct port *in_port, bool have_packet)
{
/* Note that dl_vlan of 0 and of OFP_VLAN_NONE both mean that the packet
* belongs to VLAN 0, so we should treat both cases identically. (In the
* former case, the packet has an 802.1Q header that specifies VLAN 0,
* presumably to allow a priority to be specified. In the latter case, the
* packet does not have any 802.1Q header.) */
int vlan = ntohs(flow->dl_vlan);
if (vlan == OFP_VLAN_NONE) {
vlan = 0;
}
if (in_port->vlan >= 0) {
if (vlan) {
/* XXX support double tagging? */
if (have_packet) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_WARN_RL(&rl, "bridge %s: dropping VLAN %"PRIu16" tagged "
"packet received on port %s configured with "
"implicit VLAN %"PRIu16,
br->name, ntohs(flow->dl_vlan),
in_port->name, in_port->vlan);
}
return -1;
}
vlan = in_port->vlan;
} else {
if (!port_includes_vlan(in_port, vlan)) {
if (have_packet) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_WARN_RL(&rl, "bridge %s: dropping VLAN %d tagged "
"packet received on port %s not configured for "
"trunking VLAN %d",
br->name, vlan, in_port->name, vlan);
}
return -1;
}
}
return vlan;
}
/* A VM broadcasts a gratuitous ARP to indicate that it has resumed after
* migration. Older Citrix-patched Linux DomU used gratuitous ARP replies to
* indicate this; newer upstream kernels use gratuitous ARP requests. */
static bool
is_gratuitous_arp(const struct flow *flow)
{
return (flow->dl_type == htons(ETH_TYPE_ARP)
&& eth_addr_is_broadcast(flow->dl_dst)
&& (flow->nw_proto == ARP_OP_REPLY
|| (flow->nw_proto == ARP_OP_REQUEST
&& flow->nw_src == flow->nw_dst)));
}
static void
update_learning_table(struct bridge *br, const struct flow *flow, int vlan,
struct port *in_port)
{
enum grat_arp_lock_type lock_type;
tag_type rev_tag;
/* We don't want to learn from gratuitous ARP packets that are reflected
* back over bond slaves so we lock the learning table. */
lock_type = !is_gratuitous_arp(flow) ? GRAT_ARP_LOCK_NONE :
(in_port->n_ifaces == 1) ? GRAT_ARP_LOCK_SET :
GRAT_ARP_LOCK_CHECK;
rev_tag = mac_learning_learn(br->ml, flow->dl_src, vlan, in_port->port_idx,
lock_type);
if (rev_tag) {
/* The log messages here could actually be useful in debugging,
* so keep the rate limit relatively high. */
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(30,
300);
VLOG_DBG_RL(&rl, "bridge %s: learned that "ETH_ADDR_FMT" is "
"on port %s in VLAN %d",
br->name, ETH_ADDR_ARGS(flow->dl_src),
in_port->name, vlan);
ofproto_revalidate(br->ofproto, rev_tag);
}
}
/* Determines whether packets in 'flow' within 'br' should be forwarded or
* dropped. Returns true if they may be forwarded, false if they should be
* dropped.
*
* If 'have_packet' is true, it indicates that the caller is processing a
* received packet. If 'have_packet' is false, then the caller is just
* revalidating an existing flow because configuration has changed. Either
* way, 'have_packet' only affects logging (there is no point in logging errors
* during revalidation).
*
* Sets '*in_portp' to the input port. This will be a null pointer if
* flow->in_port does not designate a known input port (in which case
* is_admissible() returns false).
*
* When returning true, sets '*vlanp' to the effective VLAN of the input
* packet, as returned by flow_get_vlan().
*
* May also add tags to '*tags', although the current implementation only does
* so in one special case.
*/
static bool
is_admissible(struct bridge *br, const struct flow *flow, bool have_packet,
tag_type *tags, int *vlanp, struct port **in_portp)
{
struct iface *in_iface;
struct port *in_port;
int vlan;
/* Find the interface and port structure for the received packet. */
in_iface = iface_from_dp_ifidx(br, flow->in_port);
if (!in_iface) {
/* No interface? Something fishy... */
if (have_packet) {
/* Odd. A few possible reasons here:
*
* - We deleted an interface but there are still a few packets
* queued up from it.
*
* - Someone externally added an interface (e.g. with "ovs-dpctl
* add-if") that we don't know about.
*
* - Packet arrived on the local port but the local port is not
* one of our bridge ports.
*/
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_WARN_RL(&rl, "bridge %s: received packet on unknown "
"interface %"PRIu16, br->name, flow->in_port);
}
*in_portp = NULL;
return false;
}
*in_portp = in_port = in_iface->port;
*vlanp = vlan = flow_get_vlan(br, flow, in_port, have_packet);
if (vlan < 0) {
return false;
}
/* Drop frames for reserved multicast addresses. */
if (eth_addr_is_reserved(flow->dl_dst)) {
return false;
}
/* Drop frames on ports reserved for mirroring. */
if (in_port->is_mirror_output_port) {
if (have_packet) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_WARN_RL(&rl, "bridge %s: dropping packet received on port "
"%s, which is reserved exclusively for mirroring",
br->name, in_port->name);
}
return false;
}
/* Packets received on bonds need special attention to avoid duplicates. */
if (in_port->n_ifaces > 1) {
int src_idx;
bool is_grat_arp_locked;
if (eth_addr_is_multicast(flow->dl_dst)) {
*tags |= in_port->active_iface_tag;
if (in_port->active_iface != in_iface->port_ifidx) {
/* Drop all multicast packets on inactive slaves. */
return false;
}
}
/* Drop all packets for which we have learned a different input
* port, because we probably sent the packet on one slave and got
* it back on the other. Gratuitous ARP packets are an exception
* to this rule: the host has moved to another switch. The exception
* to the exception is if we locked the learning table to avoid
* reflections on bond slaves. If this is the case, just drop the
* packet now. */
src_idx = mac_learning_lookup(br->ml, flow->dl_src, vlan,
&is_grat_arp_locked);
if (src_idx != -1 && src_idx != in_port->port_idx &&
(!is_gratuitous_arp(flow) || is_grat_arp_locked)) {
return false;
}
}
return true;
}
/* If the composed actions may be applied to any packet in the given 'flow',
* returns true. Otherwise, the actions should only be applied to 'packet', or
* not at all, if 'packet' was NULL. */
static bool
process_flow(struct bridge *br, const struct flow *flow,
const struct ofpbuf *packet, struct odp_actions *actions,
tag_type *tags, uint16_t *nf_output_iface)
{
struct port *in_port;
struct port *out_port;
int vlan;
int out_port_idx;
/* Check whether we should drop packets in this flow. */
if (!is_admissible(br, flow, packet != NULL, tags, &vlan, &in_port)) {
out_port = NULL;
goto done;
}
/* Learn source MAC (but don't try to learn from revalidation). */
if (packet) {
update_learning_table(br, flow, vlan, in_port);
}
/* Determine output port. */
out_port_idx = mac_learning_lookup_tag(br->ml, flow->dl_dst, vlan, tags,
NULL);
if (out_port_idx >= 0 && out_port_idx < br->n_ports) {
out_port = br->ports[out_port_idx];
} else if (!packet && !eth_addr_is_multicast(flow->dl_dst)) {
/* If we are revalidating but don't have a learning entry then
* eject the flow. Installing a flow that floods packets opens
* up a window of time where we could learn from a packet reflected
* on a bond and blackhole packets before the learning table is
* updated to reflect the correct port. */
return false;
} else {
out_port = FLOOD_PORT;
}
/* Don't send packets out their input ports. */
if (in_port == out_port) {
out_port = NULL;
}
done:
if (in_port) {
compose_actions(br, flow, vlan, in_port, out_port, tags, actions,
nf_output_iface);
}
return true;
}
static bool
bridge_normal_ofhook_cb(const struct flow *flow, const struct ofpbuf *packet,
struct odp_actions *actions, tag_type *tags,
uint16_t *nf_output_iface, void *br_)
{
struct bridge *br = br_;
COVERAGE_INC(bridge_process_flow);
return process_flow(br, flow, packet, actions, tags, nf_output_iface);
}
static void
bridge_account_flow_ofhook_cb(const struct flow *flow, tag_type tags,
const union odp_action *actions,
size_t n_actions, unsigned long long int n_bytes,
void *br_)
{
struct bridge *br = br_;
const union odp_action *a;
struct port *in_port;
tag_type dummy = 0;
int vlan;
/* Feed information from the active flows back into the learning table to
* ensure that table is always in sync with what is actually flowing
* through the datapath.
*
* We test that 'tags' is nonzero to ensure that only flows that include an
* OFPP_NORMAL action are used for learning. This works because
* bridge_normal_ofhook_cb() always sets a nonzero tag value. */
if (tags && is_admissible(br, flow, false, &dummy, &vlan, &in_port)) {
update_learning_table(br, flow, vlan, in_port);
}
/* Account for bond slave utilization. */
if (!br->has_bonded_ports) {
return;
}
for (a = actions; a < &actions[n_actions]; a++) {
if (a->type == ODPAT_OUTPUT) {
struct port *out_port = port_from_dp_ifidx(br, a->output.port);
if (out_port && out_port->n_ifaces >= 2) {
struct bond_entry *e = lookup_bond_entry(out_port,
flow->dl_src);
e->tx_bytes += n_bytes;
}
}
}
}
static void
bridge_account_checkpoint_ofhook_cb(void *br_)
{
struct bridge *br = br_;
long long int now;
size_t i;
if (!br->has_bonded_ports) {
return;
}
now = time_msec();
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
if (port->n_ifaces > 1 && now >= port->bond_next_rebalance) {
port->bond_next_rebalance = now + port->bond_rebalance_interval;
bond_rebalance_port(port);
}
}
}
static struct ofhooks bridge_ofhooks = {
bridge_normal_ofhook_cb,
bridge_account_flow_ofhook_cb,
bridge_account_checkpoint_ofhook_cb,
};
/* Bonding functions. */
/* Statistics for a single interface on a bonded port, used for load-based
* bond rebalancing. */
struct slave_balance {
struct iface *iface; /* The interface. */
uint64_t tx_bytes; /* Sum of hashes[*]->tx_bytes. */
/* All the "bond_entry"s that are assigned to this interface, in order of
* increasing tx_bytes. */
struct bond_entry **hashes;
size_t n_hashes;
};
/* Sorts pointers to pointers to bond_entries in ascending order by the
* interface to which they are assigned, and within a single interface in
* ascending order of bytes transmitted. */
static int
compare_bond_entries(const void *a_, const void *b_)
{
const struct bond_entry *const *ap = a_;
const struct bond_entry *const *bp = b_;
const struct bond_entry *a = *ap;
const struct bond_entry *b = *bp;
if (a->iface_idx != b->iface_idx) {
return a->iface_idx > b->iface_idx ? 1 : -1;
} else if (a->tx_bytes != b->tx_bytes) {
return a->tx_bytes > b->tx_bytes ? 1 : -1;
} else {
return 0;
}
}
/* Sorts slave_balances so that enabled ports come first, and otherwise in
* *descending* order by number of bytes transmitted. */
static int
compare_slave_balance(const void *a_, const void *b_)
{
const struct slave_balance *a = a_;
const struct slave_balance *b = b_;
if (a->iface->enabled != b->iface->enabled) {
return a->iface->enabled ? -1 : 1;
} else if (a->tx_bytes != b->tx_bytes) {
return a->tx_bytes > b->tx_bytes ? -1 : 1;
} else {
return 0;
}
}
static void
swap_bals(struct slave_balance *a, struct slave_balance *b)
{
struct slave_balance tmp = *a;
*a = *b;
*b = tmp;
}
/* Restores the 'n_bals' slave_balance structures in 'bals' to sorted order
* given that 'p' (and only 'p') might be in the wrong location.
*
* This function invalidates 'p', since it might now be in a different memory
* location. */
static void
resort_bals(struct slave_balance *p,
struct slave_balance bals[], size_t n_bals)
{
if (n_bals > 1) {
for (; p > bals && p->tx_bytes > p[-1].tx_bytes; p--) {
swap_bals(p, p - 1);
}
for (; p < &bals[n_bals - 1] && p->tx_bytes < p[1].tx_bytes; p++) {
swap_bals(p, p + 1);
}
}
}
static void
log_bals(const struct slave_balance *bals, size_t n_bals, struct port *port)
{
if (VLOG_IS_DBG_ENABLED()) {
struct ds ds = DS_EMPTY_INITIALIZER;
const struct slave_balance *b;
for (b = bals; b < bals + n_bals; b++) {
size_t i;
if (b > bals) {
ds_put_char(&ds, ',');
}
ds_put_format(&ds, " %s %"PRIu64"kB",
b->iface->name, b->tx_bytes / 1024);
if (!b->iface->enabled) {
ds_put_cstr(&ds, " (disabled)");
}
if (b->n_hashes > 0) {
ds_put_cstr(&ds, " (");
for (i = 0; i < b->n_hashes; i++) {
const struct bond_entry *e = b->hashes[i];
if (i > 0) {
ds_put_cstr(&ds, " + ");
}
ds_put_format(&ds, "h%td: %"PRIu64"kB",
e - port->bond_hash, e->tx_bytes / 1024);
}
ds_put_cstr(&ds, ")");
}
}
VLOG_DBG("bond %s:%s", port->name, ds_cstr(&ds));
ds_destroy(&ds);
}
}
/* Shifts 'hash' from 'from' to 'to' within 'port'. */
static void
bond_shift_load(struct slave_balance *from, struct slave_balance *to,
int hash_idx)
{
struct bond_entry *hash = from->hashes[hash_idx];
struct port *port = from->iface->port;
uint64_t delta = hash->tx_bytes;
VLOG_INFO("bond %s: shift %"PRIu64"kB of load (with hash %td) "
"from %s to %s (now carrying %"PRIu64"kB and "
"%"PRIu64"kB load, respectively)",
port->name, delta / 1024, hash - port->bond_hash,
from->iface->name, to->iface->name,
(from->tx_bytes - delta) / 1024,
(to->tx_bytes + delta) / 1024);
/* Delete element from from->hashes.
*
* We don't bother to add the element to to->hashes because not only would
* it require more work, the only purpose it would be to allow that hash to
* be migrated to another slave in this rebalancing run, and there is no
* point in doing that. */
if (hash_idx == 0) {
from->hashes++;
} else {
memmove(from->hashes + hash_idx, from->hashes + hash_idx + 1,
(from->n_hashes - (hash_idx + 1)) * sizeof *from->hashes);
}
from->n_hashes--;
/* Shift load away from 'from' to 'to'. */
from->tx_bytes -= delta;
to->tx_bytes += delta;
/* Arrange for flows to be revalidated. */
ofproto_revalidate(port->bridge->ofproto, hash->iface_tag);
hash->iface_idx = to->iface->port_ifidx;
hash->iface_tag = tag_create_random();
}
static void
bond_rebalance_port(struct port *port)
{
struct slave_balance bals[DP_MAX_PORTS];
size_t n_bals;
struct bond_entry *hashes[BOND_MASK + 1];
struct slave_balance *b, *from, *to;
struct bond_entry *e;
size_t i;
/* Sets up 'bals' to describe each of the port's interfaces, sorted in
* descending order of tx_bytes, so that bals[0] represents the most
* heavily loaded slave and bals[n_bals - 1] represents the least heavily
* loaded slave.
*
* The code is a bit tricky: to avoid dynamically allocating a 'hashes'
* array for each slave_balance structure, we sort our local array of
* hashes in order by slave, so that all of the hashes for a given slave
* become contiguous in memory, and then we point each 'hashes' members of
* a slave_balance structure to the start of a contiguous group. */
n_bals = port->n_ifaces;
for (b = bals; b < &bals[n_bals]; b++) {
b->iface = port->ifaces[b - bals];
b->tx_bytes = 0;
b->hashes = NULL;
b->n_hashes = 0;
}
for (i = 0; i <= BOND_MASK; i++) {
hashes[i] = &port->bond_hash[i];
}
qsort(hashes, BOND_MASK + 1, sizeof *hashes, compare_bond_entries);
for (i = 0; i <= BOND_MASK; i++) {
e = hashes[i];
if (e->iface_idx >= 0 && e->iface_idx < port->n_ifaces) {
b = &bals[e->iface_idx];
b->tx_bytes += e->tx_bytes;
if (!b->hashes) {
b->hashes = &hashes[i];
}
b->n_hashes++;
}
}
qsort(bals, n_bals, sizeof *bals, compare_slave_balance);
log_bals(bals, n_bals, port);
/* Discard slaves that aren't enabled (which were sorted to the back of the
* array earlier). */
while (!bals[n_bals - 1].iface->enabled) {
n_bals--;
if (!n_bals) {
return;
}
}
/* Shift load from the most-loaded slaves to the least-loaded slaves. */
to = &bals[n_bals - 1];
for (from = bals; from < to; ) {
uint64_t overload = from->tx_bytes - to->tx_bytes;
if (overload < to->tx_bytes >> 5 || overload < 100000) {
/* The extra load on 'from' (and all less-loaded slaves), compared
* to that of 'to' (the least-loaded slave), is less than ~3%, or
* it is less than ~1Mbps. No point in rebalancing. */
break;
} else if (from->n_hashes == 1) {
/* 'from' only carries a single MAC hash, so we can't shift any
* load away from it, even though we want to. */
from++;
} else {
/* 'from' is carrying significantly more load than 'to', and that
* load is split across at least two different hashes. Pick a hash
* to migrate to 'to' (the least-loaded slave), given that doing so
* must decrease the ratio of the load on the two slaves by at
* least 0.1.
*
* The sort order we use means that we prefer to shift away the
* smallest hashes instead of the biggest ones. There is little
* reason behind this decision; we could use the opposite sort
* order to shift away big hashes ahead of small ones. */
bool order_swapped;
for (i = 0; i < from->n_hashes; i++) {
double old_ratio, new_ratio;
uint64_t delta = from->hashes[i]->tx_bytes;
if (delta == 0 || from->tx_bytes - delta == 0) {
/* Pointless move. */
continue;
}
order_swapped = from->tx_bytes - delta < to->tx_bytes + delta;
if (to->tx_bytes == 0) {
/* Nothing on the new slave, move it. */
break;
}
old_ratio = (double)from->tx_bytes / to->tx_bytes;
new_ratio = (double)(from->tx_bytes - delta) /
(to->tx_bytes + delta);
if (new_ratio == 0) {
/* Should already be covered but check to prevent division
* by zero. */
continue;
}
if (new_ratio < 1) {
new_ratio = 1 / new_ratio;
}
if (old_ratio - new_ratio > 0.1) {
/* Would decrease the ratio, move it. */
break;
}
}
if (i < from->n_hashes) {
bond_shift_load(from, to, i);
port->bond_compat_is_stale = true;
/* If the result of the migration changed the relative order of
* 'from' and 'to' swap them back to maintain invariants. */
if (order_swapped) {
swap_bals(from, to);
}
/* Re-sort 'bals'. Note that this may make 'from' and 'to'
* point to different slave_balance structures. It is only
* valid to do these two operations in a row at all because we
* know that 'from' will not move past 'to' and vice versa. */
resort_bals(from, bals, n_bals);
resort_bals(to, bals, n_bals);
} else {
from++;
}
}
}
/* Implement exponentially weighted moving average. A weight of 1/2 causes
* historical data to decay to <1% in 7 rebalancing runs. */
for (e = &port->bond_hash[0]; e <= &port->bond_hash[BOND_MASK]; e++) {
e->tx_bytes /= 2;
}
}
static void
bond_send_learning_packets(struct port *port)
{
struct bridge *br = port->bridge;
struct mac_entry *e;
struct ofpbuf packet;
int error, n_packets, n_errors;
if (!port->n_ifaces || port->active_iface < 0) {
return;
}
ofpbuf_init(&packet, 128);
error = n_packets = n_errors = 0;
LIST_FOR_EACH (e, lru_node, &br->ml->lrus) {
union ofp_action actions[2], *a;
uint16_t dp_ifidx;
tag_type tags = 0;
struct flow flow;
int retval;
if (e->port == port->port_idx
|| !choose_output_iface(port, e->mac, &dp_ifidx, &tags)) {
continue;
}
/* Compose actions. */
memset(actions, 0, sizeof actions);
a = actions;
if (e->vlan) {
a->vlan_vid.type = htons(OFPAT_SET_VLAN_VID);
a->vlan_vid.len = htons(sizeof *a);
a->vlan_vid.vlan_vid = htons(e->vlan);
a++;
}
a->output.type = htons(OFPAT_OUTPUT);
a->output.len = htons(sizeof *a);
a->output.port = htons(odp_port_to_ofp_port(dp_ifidx));
a++;
/* Send packet. */
n_packets++;
compose_benign_packet(&packet, "Open vSwitch Bond Failover", 0xf177,
e->mac);
flow_extract(&packet, 0, ODPP_NONE, &flow);
retval = ofproto_send_packet(br->ofproto, &flow, actions, a - actions,
&packet);
if (retval) {
error = retval;
n_errors++;
}
}
ofpbuf_uninit(&packet);
if (n_errors) {
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
VLOG_WARN_RL(&rl, "bond %s: %d errors sending %d gratuitous learning "
"packets, last error was: %s",
port->name, n_errors, n_packets, strerror(error));
} else {
VLOG_DBG("bond %s: sent %d gratuitous learning packets",
port->name, n_packets);
}
}
/* Bonding unixctl user interface functions. */
static void
bond_unixctl_list(struct unixctl_conn *conn,
const char *args OVS_UNUSED, void *aux OVS_UNUSED)
{
struct ds ds = DS_EMPTY_INITIALIZER;
const struct bridge *br;
ds_put_cstr(&ds, "bridge\tbond\tslaves\n");
LIST_FOR_EACH (br, node, &all_bridges) {
size_t i;
for (i = 0; i < br->n_ports; i++) {
const struct port *port = br->ports[i];
if (port->n_ifaces > 1) {
size_t j;
ds_put_format(&ds, "%s\t%s\t", br->name, port->name);
for (j = 0; j < port->n_ifaces; j++) {
const struct iface *iface = port->ifaces[j];
if (j) {
ds_put_cstr(&ds, ", ");
}
ds_put_cstr(&ds, iface->name);
}
ds_put_char(&ds, '\n');
}
}
}
unixctl_command_reply(conn, 200, ds_cstr(&ds));
ds_destroy(&ds);
}
static struct port *
bond_find(const char *name)
{
const struct bridge *br;
LIST_FOR_EACH (br, node, &all_bridges) {
size_t i;
for (i = 0; i < br->n_ports; i++) {
struct port *port = br->ports[i];
if (!strcmp(port->name, name) && port->n_ifaces > 1) {
return port;
}
}
}
return NULL;
}
static void
bond_unixctl_show(struct unixctl_conn *conn,
const char *args, void *aux OVS_UNUSED)
{
struct ds ds = DS_EMPTY_INITIALIZER;
const struct port *port;
size_t j;
port = bond_find(args);
if (!port) {
unixctl_command_reply(conn, 501, "no such bond");
return;
}
ds_put_format(&ds, "updelay: %d ms\n", port->updelay);
ds_put_format(&ds, "downdelay: %d ms\n", port->downdelay);
ds_put_format(&ds, "next rebalance: %lld ms\n",
port->bond_next_rebalance - time_msec());
for (j = 0; j < port->n_ifaces; j++) {
const struct iface *iface = port->ifaces[j];
struct bond_entry *be;
/* Basic info. */
ds_put_format(&ds, "slave %s: %s\n",
iface->name, iface->enabled ? "enabled" : "disabled");
if (j == port->active_iface) {
ds_put_cstr(&ds, "\tactive slave\n");
}
if (iface->delay_expires != LLONG_MAX) {
ds_put_format(&ds, "\t%s expires in %lld ms\n",
iface->enabled ? "downdelay" : "updelay",
iface->delay_expires - time_msec());
}
/* Hashes. */
for (be = port->bond_hash; be <= &port->bond_hash[BOND_MASK]; be++) {
int hash = be - port->bond_hash;
struct mac_entry *me;
if (be->iface_idx != j) {
continue;
}
ds_put_format(&ds, "\thash %d: %"PRIu64" kB load\n",
hash, be->tx_bytes / 1024);
/* MACs. */
LIST_FOR_EACH (me, lru_node, &port->bridge->ml->lrus) {
uint16_t dp_ifidx;
tag_type tags = 0;
if (bond_hash(me->mac) == hash
&& me->port != port->port_idx
&& choose_output_iface(port, me->mac, &dp_ifidx, &tags)
&& dp_ifidx == iface->dp_ifidx)
{
ds_put_format(&ds, "\t\t"ETH_ADDR_FMT"\n",
ETH_ADDR_ARGS(me->mac));
}
}
}
}
unixctl_command_reply(conn, 200, ds_cstr(&ds));
ds_destroy(&ds);
}
static void
bond_unixctl_migrate(struct unixctl_conn *conn, const char *args_,
void *aux OVS_UNUSED)
{
char *args = (char *) args_;
char *save_ptr = NULL;
char *bond_s, *hash_s, *slave_s;
uint8_t mac[ETH_ADDR_LEN];
struct port *port;
struct iface *iface;
struct bond_entry *entry;
int hash;
bond_s = strtok_r(args, " ", &save_ptr);
hash_s = strtok_r(NULL, " ", &save_ptr);
slave_s = strtok_r(NULL, " ", &save_ptr);
if (!slave_s) {
unixctl_command_reply(conn, 501,
"usage: bond/migrate BOND HASH SLAVE");
return;
}
port = bond_find(bond_s);
if (!port) {
unixctl_command_reply(conn, 501, "no such bond");
return;
}
if (sscanf(hash_s, ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(mac))
== ETH_ADDR_SCAN_COUNT) {
hash = bond_hash(mac);
} else if (strspn(hash_s, "0123456789") == strlen(hash_s)) {
hash = atoi(hash_s) & BOND_MASK;
} else {
unixctl_command_reply(conn, 501, "bad hash");
return;
}
iface = port_lookup_iface(port, slave_s);
if (!iface) {
unixctl_command_reply(conn, 501, "no such slave");
return;
}
if (!iface->enabled) {
unixctl_command_reply(conn, 501, "cannot migrate to disabled slave");
return;
}
entry = &port->bond_hash[hash];
ofproto_revalidate(port->bridge->ofproto, entry->iface_tag);
entry->iface_idx = iface->port_ifidx;
entry->iface_tag = tag_create_random();
port->bond_compat_is_stale = true;
unixctl_command_reply(conn, 200, "migrated");
}
static void
bond_unixctl_set_active_slave(struct unixctl_conn *conn, const char *args_,
void *aux OVS_UNUSED)
{
char *args = (char *) args_;
char *save_ptr = NULL;
char *bond_s, *slave_s;
struct port *port;
struct iface *iface;
bond_s = strtok_r(args, " ", &save_ptr);
slave_s = strtok_r(NULL, " ", &save_ptr);
if (!slave_s) {
unixctl_command_reply(conn, 501,
"usage: bond/set-active-slave BOND SLAVE");
return;
}
port = bond_find(bond_s);
if (!port) {
unixctl_command_reply(conn, 501, "no such bond");
return;
}
iface = port_lookup_iface(port, slave_s);
if (!iface) {
unixctl_command_reply(conn, 501, "no such slave");
return;
}
if (!iface->enabled) {
unixctl_command_reply(conn, 501, "cannot make disabled slave active");
return;
}
if (port->active_iface != iface->port_ifidx) {
ofproto_revalidate(port->bridge->ofproto, port->active_iface_tag);
port->active_iface = iface->port_ifidx;
port->active_iface_tag = tag_create_random();
VLOG_INFO("port %s: active interface is now %s",
port->name, iface->name);
bond_send_learning_packets(port);
unixctl_command_reply(conn, 200, "done");
} else {
unixctl_command_reply(conn, 200, "no change");
}
}
static void
enable_slave(struct unixctl_conn *conn, const char *args_, bool enable)
{
char *args = (char *) args_;
char *save_ptr = NULL;
char *bond_s, *slave_s;
struct port *port;
struct iface *iface;
bond_s = strtok_r(args, " ", &save_ptr);
slave_s = strtok_r(NULL, " ", &save_ptr);
if (!slave_s) {
unixctl_command_reply(conn, 501,
"usage: bond/enable/disable-slave BOND SLAVE");
return;
}
port = bond_find(bond_s);
if (!port) {
unixctl_command_reply(conn, 501, "no such bond");
return;
}
iface = port_lookup_iface(port, slave_s);
if (!iface) {
unixctl_command_reply(conn, 501, "no such slave");
return;
}
bond_enable_slave(iface, enable);
unixctl_command_reply(conn, 501, enable ? "enabled" : "disabled");
}
static void
bond_unixctl_enable_slave(struct unixctl_conn *conn, const char *args,
void *aux OVS_UNUSED)
{
enable_slave(conn, args, true);
}
static void
bond_unixctl_disable_slave(struct unixctl_conn *conn, const char *args,
void *aux OVS_UNUSED)
{
enable_slave(conn, args, false);
}
static void
bond_unixctl_hash(struct unixctl_conn *conn, const char *args,
void *aux OVS_UNUSED)
{
uint8_t mac[ETH_ADDR_LEN];
uint8_t hash;
char *hash_cstr;
if (sscanf(args, ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(mac))
== ETH_ADDR_SCAN_COUNT) {
hash = bond_hash(mac);
hash_cstr = xasprintf("%u", hash);
unixctl_command_reply(conn, 200, hash_cstr);
free(hash_cstr);
} else {
unixctl_command_reply(conn, 501, "invalid mac");
}
}
static void
bond_init(void)
{
unixctl_command_register("bond/list", bond_unixctl_list, NULL);
unixctl_command_register("bond/show", bond_unixctl_show, NULL);
unixctl_command_register("bond/migrate", bond_unixctl_migrate, NULL);
unixctl_command_register("bond/set-active-slave",
bond_unixctl_set_active_slave, NULL);
unixctl_command_register("bond/enable-slave", bond_unixctl_enable_slave,
NULL);
unixctl_command_register("bond/disable-slave", bond_unixctl_disable_slave,
NULL);
unixctl_command_register("bond/hash", bond_unixctl_hash, NULL);
}
/* Port functions. */
static struct port *
port_create(struct bridge *br, const char *name)
{
struct port *port;
port = xzalloc(sizeof *port);
port->bridge = br;
port->port_idx = br->n_ports;
port->vlan = -1;
port->trunks = NULL;
port->name = xstrdup(name);
port->active_iface = -1;
if (br->n_ports >= br->allocated_ports) {
br->ports = x2nrealloc(br->ports, &br->allocated_ports,
sizeof *br->ports);
}
br->ports[br->n_ports++] = port;
shash_add_assert(&br->port_by_name, port->name, port);
VLOG_INFO("created port %s on bridge %s", port->name, br->name);
bridge_flush(br);
return port;
}
static const char *
get_port_other_config(const struct ovsrec_port *port, const char *key,
const char *default_value)
{
const char *value;
value = get_ovsrec_key_value(&port->header_, &ovsrec_port_col_other_config,
key);
return value ? value : default_value;
}
static void
port_del_ifaces(struct port *port, const struct ovsrec_port *cfg)
{
struct shash new_ifaces;
size_t i;
/* Collect list of new interfaces. */
shash_init(&new_ifaces);
for (i = 0; i < cfg->n_interfaces; i++) {
const char *name = cfg->interfaces[i]->name;
shash_add_once(&new_ifaces, name, NULL);
}
/* Get rid of deleted interfaces. */
for (i = 0; i < port->n_ifaces; ) {
if (!shash_find(&new_ifaces, cfg->interfaces[i]->name)) {
iface_destroy(port->ifaces[i]);
} else {
i++;
}
}
shash_destroy(&new_ifaces);
}
static void
port_reconfigure(struct port *port, const struct ovsrec_port *cfg)
{
struct shash new_ifaces;
long long int next_rebalance;
unsigned long *trunks;
int vlan;
size_t i;
port->cfg = cfg;
/* Update settings. */
port->updelay = cfg->bond_updelay;
if (port->updelay < 0) {
port->updelay = 0;
}
port->downdelay = cfg->bond_downdelay;
if (port->downdelay < 0) {
port->downdelay = 0;
}
port->bond_rebalance_interval = atoi(
get_port_other_config(cfg, "bond-rebalance-interval", "10000"));
if (port->bond_rebalance_interval < 1000) {
port->bond_rebalance_interval = 1000;
}
next_rebalance = time_msec() + port->bond_rebalance_interval;
if (port->bond_next_rebalance > next_rebalance) {
port->bond_next_rebalance = next_rebalance;
}
/* Add new interfaces and update 'cfg' member of existing ones. */
shash_init(&new_ifaces);
for (i = 0; i < cfg->n_interfaces; i++) {
const struct ovsrec_interface *if_cfg = cfg->interfaces[i];
struct iface *iface;
if (!shash_add_once(&new_ifaces, if_cfg->name, NULL)) {
VLOG_WARN("port %s: %s specified twice as port interface",
port->name, if_cfg->name);
iface_set_ofport(if_cfg, -1);
continue;
}
iface = iface_lookup(port->bridge, if_cfg->name);
if (iface) {
if (iface->port != port) {
VLOG_ERR("bridge %s: %s interface is on multiple ports, "
"removing from %s",
port->bridge->name, if_cfg->name, iface->port->name);
continue;
}
iface->cfg = if_cfg;
} else {
iface = iface_create(port, if_cfg);
}
/* Determine interface type. The local port always has type
* "internal". Other ports take their type from the database and
* default to "system" if none is specified. */
iface->type = (!strcmp(if_cfg->name, port->bridge->name) ? "internal"
: if_cfg->type[0] ? if_cfg->type
: "system");
}
shash_destroy(&new_ifaces);
/* Get VLAN tag. */
vlan = -1;
if (cfg->tag) {
if (port->n_ifaces < 2) {
vlan = *cfg->tag;
if (vlan >= 0 && vlan <= 4095) {
VLOG_DBG("port %s: assigning VLAN tag %d", port->name, vlan);
} else {
vlan = -1;
}
} else {
/* It's possible that bonded, VLAN-tagged ports make sense. Maybe
* they even work as-is. But they have not been tested. */
VLOG_WARN("port %s: VLAN tags not supported on bonded ports",
port->name);
}
}
if (port->vlan != vlan) {
port->vlan = vlan;
bridge_flush(port->bridge);
}
/* Get trunked VLANs. */
trunks = NULL;
if (vlan < 0 && cfg->n_trunks) {
size_t n_errors;
trunks = bitmap_allocate(4096);
n_errors = 0;
for (i = 0; i < cfg->n_trunks; i++) {
int trunk = cfg->trunks[i];
if (trunk >= 0) {
bitmap_set1(trunks, trunk);
} else {
n_errors++;
}
}
if (n_errors) {
VLOG_ERR("port %s: invalid values for %zu trunk VLANs",
port->name, cfg->n_trunks);
}
if (n_errors == cfg->n_trunks) {
VLOG_ERR("port %s: no valid trunks, trunking all VLANs",
port->name);
bitmap_free(trunks);
trunks = NULL;
}
} else if (vlan >= 0 && cfg->n_trunks) {
VLOG_ERR("port %s: ignoring trunks in favor of implicit vlan",
port->name);
}
if (trunks == NULL
? port->trunks != NULL
: port->trunks == NULL || !bitmap_equal(trunks, port->trunks, 4096)) {
bridge_flush(port->bridge);
}
bitmap_free(port->trunks);
port->trunks = trunks;
}
static void
port_destroy(struct port *port)
{
if (port) {
struct bridge *br = port->bridge;
struct port *del;
int i;
proc_net_compat_update_vlan(port->name, NULL, 0);
proc_net_compat_update_bond(port->name, NULL);
for (i = 0; i < MAX_MIRRORS; i++) {
struct mirror *m = br->mirrors[i];
if (m && m->out_port == port) {
mirror_destroy(m);
}
}
while (port->n_ifaces > 0) {
iface_destroy(port->ifaces[port->n_ifaces - 1]);
}
shash_find_and_delete_assert(&br->port_by_name, port->name);
del = br->ports[port->port_idx] = br->ports[--br->n_ports];
del->port_idx = port->port_idx;
VLOG_INFO("destroyed port %s on bridge %s", port->name, br->name);
netdev_monitor_destroy(port->monitor);
free(port->ifaces);
bitmap_free(port->trunks);
free(port->name);
free(port);
bridge_flush(br);
}
}
static struct port *
port_from_dp_ifidx(const struct bridge *br, uint16_t dp_ifidx)
{
struct iface *iface = iface_from_dp_ifidx(br, dp_ifidx);
return iface ? iface->port : NULL;
}
static struct port *
port_lookup(const struct bridge *br, const char *name)
{
return shash_find_data(&br->port_by_name, name);
}
static struct iface *
port_lookup_iface(const struct port *port, const char *name)
{
struct iface *iface = iface_lookup(port->bridge, name);
return iface && iface->port == port ? iface : NULL;
}
static void
port_update_bonding(struct port *port)
{
if (port->monitor) {
netdev_monitor_destroy(port->monitor);
port->monitor = NULL;
}
if (port->n_ifaces < 2) {
/* Not a bonded port. */
if (port->bond_hash) {
free(port->bond_hash);
port->bond_hash = NULL;
port->bond_compat_is_stale = true;
port->bond_fake_iface = false;
}
} else {
size_t i;
if (!port->bond_hash) {
port->bond_hash = xcalloc(BOND_MASK + 1, sizeof *port->bond_hash);
for (i = 0; i <= BOND_MASK; i++) {
struct bond_entry *e = &port->bond_hash[i];
e->iface_idx = -1;
e->tx_bytes = 0;
}
port->no_ifaces_tag = tag_create_random();
bond_choose_active_iface(port);
port->bond_next_rebalance
= time_msec() + port->bond_rebalance_interval;
if (port->cfg->bond_fake_iface) {
port->bond_next_fake_iface_update = time_msec();
}
}
port->bond_compat_is_stale = true;
port->bond_fake_iface = port->cfg->bond_fake_iface;
port->monitor = netdev_monitor_create();
for (i = 0; i < port->n_ifaces; i++) {
netdev_monitor_add(port->monitor, port->ifaces[i]->netdev);
}
}
}
static void
port_update_bond_compat(struct port *port)
{
struct compat_bond_hash compat_hashes[BOND_MASK + 1];
struct compat_bond bond;
size_t i;
if (port->n_ifaces < 2) {
proc_net_compat_update_bond(port->name, NULL);
return;
}
bond.up = false;
bond.updelay = port->updelay;
bond.downdelay = port->downdelay;
bond.n_hashes = 0;
bond.hashes = compat_hashes;
if (port->bond_hash) {
const struct bond_entry *e;
for (e = port->bond_hash; e <= &port->bond_hash[BOND_MASK]; e++) {
if (e->iface_idx >= 0 && e->iface_idx < port->n_ifaces) {
struct compat_bond_hash *cbh = &bond.hashes[bond.n_hashes++];
cbh->hash = e - port->bond_hash;
cbh->netdev_name = port->ifaces[e->iface_idx]->name;
}
}
}
bond.n_slaves = port->n_ifaces;
bond.slaves = xmalloc(port->n_ifaces * sizeof *bond.slaves);
for (i = 0; i < port->n_ifaces; i++) {
struct iface *iface = port->ifaces[i];
struct compat_bond_slave *slave = &bond.slaves[i];
slave->name = iface->name;
/* We need to make the same determination as the Linux bonding
* code to determine whether a slave should be consider "up".
* The Linux function bond_miimon_inspect() supports four
* BOND_LINK_* states:
*
* - BOND_LINK_UP: carrier detected, updelay has passed.
* - BOND_LINK_FAIL: carrier lost, downdelay in progress.
* - BOND_LINK_DOWN: carrier lost, downdelay has passed.
* - BOND_LINK_BACK: carrier detected, updelay in progress.
*
* The function bond_info_show_slave() only considers BOND_LINK_UP
* to be "up" and anything else to be "down".
*/
slave->up = iface->enabled && iface->delay_expires == LLONG_MAX;
if (slave->up) {
bond.up = true;
}
netdev_get_etheraddr(iface->netdev, slave->mac);
}
if (port->bond_fake_iface) {
struct netdev *bond_netdev;
if (!netdev_open_default(port->name, &bond_netdev)) {
if (bond.up) {
netdev_turn_flags_on(bond_netdev, NETDEV_UP, true);
} else {
netdev_turn_flags_off(bond_netdev, NETDEV_UP, true);
}
netdev_close(bond_netdev);
}
}
proc_net_compat_update_bond(port->name, &bond);
free(bond.slaves);
}
static void
port_update_vlan_compat(struct port *port)
{
struct bridge *br = port->bridge;
char *vlandev_name = NULL;
if (port->vlan > 0) {
/* Figure out the name that the VLAN device should actually have, if it
* existed. This takes some work because the VLAN device would not
* have port->name in its name; rather, it would have the trunk port's
* name, and 'port' would be attached to a bridge that also had the
* VLAN device one of its ports. So we need to find a trunk port that
* includes port->vlan.
*
* There might be more than one candidate. This doesn't happen on
* XenServer, so if it happens we just pick the first choice in
* alphabetical order instead of creating multiple VLAN devices. */
size_t i;
for (i = 0; i < br->n_ports; i++) {
struct port *p = br->ports[i];
if (port_trunks_vlan(p, port->vlan)
&& p->n_ifaces
&& (!vlandev_name || strcmp(p->name, vlandev_name) <= 0))
{
uint8_t ea[ETH_ADDR_LEN];
netdev_get_etheraddr(p->ifaces[0]->netdev, ea);
if (!eth_addr_is_multicast(ea) &&
!eth_addr_is_reserved(ea) &&
!eth_addr_is_zero(ea)) {
vlandev_name = p->name;
}
}
}
}
proc_net_compat_update_vlan(port->name, vlandev_name, port->vlan);
}
/* Interface functions. */
static struct iface *
iface_create(struct port *port, const struct ovsrec_interface *if_cfg)
{
struct bridge *br = port->bridge;
struct iface *iface;
char *name = if_cfg->name;
iface = xzalloc(sizeof *iface);
iface->port = port;
iface->port_ifidx = port->n_ifaces;
iface->name = xstrdup(name);
iface->dp_ifidx = -1;
iface->tag = tag_create_random();
iface->delay_expires = LLONG_MAX;
iface->netdev = NULL;
iface->cfg = if_cfg;
shash_add_assert(&br->iface_by_name, iface->name, iface);
if (port->n_ifaces >= port->allocated_ifaces) {
port->ifaces = x2nrealloc(port->ifaces, &port->allocated_ifaces,
sizeof *port->ifaces);
}
port->ifaces[port->n_ifaces++] = iface;
if (port->n_ifaces > 1) {
br->has_bonded_ports = true;
}
VLOG_DBG("attached network device %s to port %s", iface->name, port->name);
bridge_flush(br);
return iface;
}
static void
iface_destroy(struct iface *iface)
{
if (iface) {
struct port *port = iface->port;
struct bridge *br = port->bridge;
bool del_active = port->active_iface == iface->port_ifidx;
struct iface *del;
shash_find_and_delete_assert(&br->iface_by_name, iface->name);
if (iface->dp_ifidx >= 0) {
hmap_remove(&br->ifaces, &iface->dp_ifidx_node);
}
del = port->ifaces[iface->port_ifidx] = port->ifaces[--port->n_ifaces];
del->port_ifidx = iface->port_ifidx;
netdev_close(iface->netdev);
if (del_active) {
ofproto_revalidate(port->bridge->ofproto, port->active_iface_tag);
bond_choose_active_iface(port);
bond_send_learning_packets(port);
}
free(iface->name);
free(iface);
bridge_flush(port->bridge);
}
}
static struct iface *
iface_lookup(const struct bridge *br, const char *name)
{
return shash_find_data(&br->iface_by_name, name);
}
static struct iface *
iface_from_dp_ifidx(const struct bridge *br, uint16_t dp_ifidx)
{
struct iface *iface;
HMAP_FOR_EACH_IN_BUCKET (iface, dp_ifidx_node,
hash_int(dp_ifidx, 0), &br->ifaces) {
if (iface->dp_ifidx == dp_ifidx) {
return iface;
}
}
return NULL;
}
/* Set Ethernet address of 'iface', if one is specified in the configuration
* file. */
static void
iface_set_mac(struct iface *iface)
{
uint8_t ea[ETH_ADDR_LEN];
if (iface->cfg->mac && eth_addr_from_string(iface->cfg->mac, ea)) {
if (eth_addr_is_multicast(ea)) {
VLOG_ERR("interface %s: cannot set MAC to multicast address",
iface->name);
} else if (iface->dp_ifidx == ODPP_LOCAL) {
VLOG_ERR("ignoring iface.%s.mac; use bridge.%s.mac instead",
iface->name, iface->name);
} else {
int error = netdev_set_etheraddr(iface->netdev, ea);
if (error) {
VLOG_ERR("interface %s: setting MAC failed (%s)",
iface->name, strerror(error));
}
}
}
}
/* Sets the ofport column of 'if_cfg' to 'ofport'. */
static void
iface_set_ofport(const struct ovsrec_interface *if_cfg, int64_t ofport)
{
if (if_cfg) {
ovsrec_interface_set_ofport(if_cfg, &ofport, 1);
}
}
/* Adds the 'n' key-value pairs in 'keys' in 'values' to 'shash'.
*
* The value strings in '*shash' are taken directly from values[], not copied,
* so the caller should not modify or free them. */
static void
shash_from_ovs_idl_map(char **keys, char **values, size_t n,
struct shash *shash)
{
size_t i;
shash_init(shash);
for (i = 0; i < n; i++) {
shash_add(shash, keys[i], values[i]);
}
}
struct iface_delete_queues_cbdata {
struct netdev *netdev;
const struct ovsdb_datum *queues;
};
static bool
queue_ids_include(const struct ovsdb_datum *queues, int64_t target)
{
union ovsdb_atom atom;
atom.integer = target;
return ovsdb_datum_find_key(queues, &atom, OVSDB_TYPE_INTEGER) != UINT_MAX;
}
static void
iface_delete_queues(unsigned int queue_id,
const struct shash *details OVS_UNUSED, void *cbdata_)
{
struct iface_delete_queues_cbdata *cbdata = cbdata_;
if (!queue_ids_include(cbdata->queues, queue_id)) {
netdev_delete_queue(cbdata->netdev, queue_id);
}
}
static void
iface_update_qos(struct iface *iface, const struct ovsrec_qos *qos)
{
if (!qos || qos->type[0] == '\0') {
netdev_set_qos(iface->netdev, NULL, NULL);
} else {
struct iface_delete_queues_cbdata cbdata;
struct shash details;
size_t i;
/* Configure top-level Qos for 'iface'. */
shash_from_ovs_idl_map(qos->key_other_config, qos->value_other_config,
qos->n_other_config, &details);
netdev_set_qos(iface->netdev, qos->type, &details);
shash_destroy(&details);
/* Deconfigure queues that were deleted. */
cbdata.netdev = iface->netdev;
cbdata.queues = ovsrec_qos_get_queues(qos, OVSDB_TYPE_INTEGER,
OVSDB_TYPE_UUID);
netdev_dump_queues(iface->netdev, iface_delete_queues, &cbdata);
/* Configure queues for 'iface'. */
for (i = 0; i < qos->n_queues; i++) {
const struct ovsrec_queue *queue = qos->value_queues[i];
unsigned int queue_id = qos->key_queues[i];
shash_from_ovs_idl_map(queue->key_other_config,
queue->value_other_config,
queue->n_other_config, &details);
netdev_set_queue(iface->netdev, queue_id, &details);
shash_destroy(&details);
}
}
}
/* Port mirroring. */
static struct mirror *
mirror_find_by_uuid(struct bridge *br, const struct uuid *uuid)
{
int i;
for (i = 0; i < MAX_MIRRORS; i++) {
struct mirror *m = br->mirrors[i];
if (m && uuid_equals(uuid, &m->uuid)) {
return m;
}
}
return NULL;
}
static void
mirror_reconfigure(struct bridge *br)
{
unsigned long *rspan_vlans;
int i;
/* Get rid of deleted mirrors. */
for (i = 0; i < MAX_MIRRORS; i++) {
struct mirror *m = br->mirrors[i];
if (m) {
const struct ovsdb_datum *mc;
union ovsdb_atom atom;
mc = ovsrec_bridge_get_mirrors(br->cfg, OVSDB_TYPE_UUID);
atom.uuid = br->mirrors[i]->uuid;
if (ovsdb_datum_find_key(mc, &atom, OVSDB_TYPE_UUID) == UINT_MAX) {
mirror_destroy(m);
}
}
}
/* Add new mirrors and reconfigure existing ones. */
for (i = 0; i < br->cfg->n_mirrors; i++) {
struct ovsrec_mirror *cfg = br->cfg->mirrors[i];
struct mirror *m = mirror_find_by_uuid(br, &cfg->header_.uuid);
if (m) {
mirror_reconfigure_one(m, cfg);
} else {
mirror_create(br, cfg);
}
}
/* Update port reserved status. */
for (i = 0; i < br->n_ports; i++) {
br->ports[i]->is_mirror_output_port = false;
}
for (i = 0; i < MAX_MIRRORS; i++) {
struct mirror *m = br->mirrors[i];
if (m && m->out_port) {
m->out_port->is_mirror_output_port = true;
}
}
/* Update flooded vlans (for RSPAN). */
rspan_vlans = NULL;
if (br->cfg->n_flood_vlans) {
rspan_vlans = bitmap_allocate(4096);
for (i = 0; i < br->cfg->n_flood_vlans; i++) {
int64_t vlan = br->cfg->flood_vlans[i];
if (vlan >= 0 && vlan < 4096) {
bitmap_set1(rspan_vlans, vlan);
VLOG_INFO("bridge %s: disabling learning on vlan %"PRId64,
br->name, vlan);
} else {
VLOG_ERR("bridge %s: invalid value %"PRId64 "for flood VLAN",
br->name, vlan);
}
}
}
if (mac_learning_set_flood_vlans(br->ml, rspan_vlans)) {
bridge_flush(br);
}
}
static void
mirror_create(struct bridge *br, struct ovsrec_mirror *cfg)
{
struct mirror *m;
size_t i;
for (i = 0; ; i++) {
if (i >= MAX_MIRRORS) {
VLOG_WARN("bridge %s: maximum of %d port mirrors reached, "
"cannot create %s", br->name, MAX_MIRRORS, cfg->name);
return;
}
if (!br->mirrors[i]) {
break;
}
}
VLOG_INFO("created port mirror %s on bridge %s", cfg->name, br->name);
bridge_flush(br);
br->mirrors[i] = m = xzalloc(sizeof *m);
m->bridge = br;
m->idx = i;
m->name = xstrdup(cfg->name);
shash_init(&m->src_ports);
shash_init(&m->dst_ports);
m->vlans = NULL;
m->n_vlans = 0;
m->out_vlan = -1;
m->out_port = NULL;
mirror_reconfigure_one(m, cfg);
}
static void
mirror_destroy(struct mirror *m)
{
if (m) {
struct bridge *br = m->bridge;
size_t i;
for (i = 0; i < br->n_ports; i++) {
br->ports[i]->src_mirrors &= ~(MIRROR_MASK_C(1) << m->idx);
br->ports[i]->dst_mirrors &= ~(MIRROR_MASK_C(1) << m->idx);
}
shash_destroy(&m->src_ports);
shash_destroy(&m->dst_ports);
free(m->vlans);
m->bridge->mirrors[m->idx] = NULL;
free(m->name);
free(m);
bridge_flush(br);
}
}
static void
mirror_collect_ports(struct mirror *m, struct ovsrec_port **ports, int n_ports,
struct shash *names)
{
size_t i;
for (i = 0; i < n_ports; i++) {
const char *name = ports[i]->name;
if (port_lookup(m->bridge, name)) {
shash_add_once(names, name, NULL);
} else {
VLOG_WARN("bridge %s: mirror %s cannot match on nonexistent "
"port %s", m->bridge->name, m->name, name);
}
}
}
static size_t
mirror_collect_vlans(struct mirror *m, const struct ovsrec_mirror *cfg,
int **vlans)
{
size_t n_vlans;
size_t i;
*vlans = xmalloc(sizeof **vlans * cfg->n_select_vlan);
n_vlans = 0;
for (i = 0; i < cfg->n_select_vlan; i++) {
int64_t vlan = cfg->select_vlan[i];
if (vlan < 0 || vlan > 4095) {
VLOG_WARN("bridge %s: mirror %s selects invalid VLAN %"PRId64,
m->bridge->name, m->name, vlan);
} else {
(*vlans)[n_vlans++] = vlan;
}
}
return n_vlans;
}
static bool
vlan_is_mirrored(const struct mirror *m, int vlan)
{
size_t i;
for (i = 0; i < m->n_vlans; i++) {
if (m->vlans[i] == vlan) {
return true;
}
}
return false;
}
static bool
port_trunks_any_mirrored_vlan(const struct mirror *m, const struct port *p)
{
size_t i;
for (i = 0; i < m->n_vlans; i++) {
if (port_trunks_vlan(p, m->vlans[i])) {
return true;
}
}
return false;
}
static void
mirror_reconfigure_one(struct mirror *m, struct ovsrec_mirror *cfg)
{
struct shash src_ports, dst_ports;
mirror_mask_t mirror_bit;
struct port *out_port;
int out_vlan;
size_t n_vlans;
int *vlans;
size_t i;
/* Set name. */
if (strcmp(cfg->name, m->name)) {
free(m->name);
m->name = xstrdup(cfg->name);
}
/* Get output port. */
if (cfg->output_port) {
out_port = port_lookup(m->bridge, cfg->output_port->name);
if (!out_port) {
VLOG_ERR("bridge %s: mirror %s outputs to port not on bridge",
m->bridge->name, m->name);
mirror_destroy(m);
return;
}
out_vlan = -1;
if (cfg->output_vlan) {
VLOG_ERR("bridge %s: mirror %s specifies both output port and "
"output vlan; ignoring output vlan",
m->bridge->name, m->name);
}
} else if (cfg->output_vlan) {
out_port = NULL;
out_vlan = *cfg->output_vlan;
} else {
VLOG_ERR("bridge %s: mirror %s does not specify output; ignoring",
m->bridge->name, m->name);
mirror_destroy(m);
return;
}
shash_init(&src_ports);
shash_init(&dst_ports);
if (cfg->select_all) {
for (i = 0; i < m->bridge->n_ports; i++) {
const char *name = m->bridge->ports[i]->name;
shash_add_once(&src_ports, name, NULL);
shash_add_once(&dst_ports, name, NULL);
}
vlans = NULL;
n_vlans = 0;
} else {
/* Get ports, and drop duplicates and ports that don't exist. */
mirror_collect_ports(m, cfg->select_src_port, cfg->n_select_src_port,
&src_ports);
mirror_collect_ports(m, cfg->select_dst_port, cfg->n_select_dst_port,
&dst_ports);
/* Get all the vlans, and drop duplicate and invalid vlans. */
n_vlans = mirror_collect_vlans(m, cfg, &vlans);
}
/* Update mirror data. */
if (!shash_equal_keys(&m->src_ports, &src_ports)
|| !shash_equal_keys(&m->dst_ports, &dst_ports)
|| m->n_vlans != n_vlans
|| memcmp(m->vlans, vlans, sizeof *vlans * n_vlans)
|| m->out_port != out_port
|| m->out_vlan != out_vlan) {
bridge_flush(m->bridge);
}
shash_swap(&m->src_ports, &src_ports);
shash_swap(&m->dst_ports, &dst_ports);
free(m->vlans);
m->vlans = vlans;
m->n_vlans = n_vlans;
m->out_port = out_port;
m->out_vlan = out_vlan;
/* Update ports. */
mirror_bit = MIRROR_MASK_C(1) << m->idx;
for (i = 0; i < m->bridge->n_ports; i++) {
struct port *port = m->bridge->ports[i];
if (shash_find(&m->src_ports, port->name)
|| (m->n_vlans
&& (!port->vlan
? port_trunks_any_mirrored_vlan(m, port)
: vlan_is_mirrored(m, port->vlan)))) {
port->src_mirrors |= mirror_bit;
} else {
port->src_mirrors &= ~mirror_bit;
}
if (shash_find(&m->dst_ports, port->name)) {
port->dst_mirrors |= mirror_bit;
} else {
port->dst_mirrors &= ~mirror_bit;
}
}
/* Clean up. */
shash_destroy(&src_ports);
shash_destroy(&dst_ports);
}
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