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ovs/lib/ofp-util.c
Ben Pfaff c1c9c9c4b6 Implement QoS framework. 
ovs-vswitchd doesn't declare its QoS capabilities in the database yet,
so the controller has to know what they are.  We can add that later.

The linux-htb QoS class has been tested to the extent that I can see that
it sets up the queues I expect when I run "tc qdisc show" and "tc class
show".  I haven't tested that the effects on flows are what we expect them
to be.  I am sure that there will be problems in that area that we will
have to fix.
2010-06-17 15:04:12 -07:00

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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 "ofp-print.h"
#include <inttypes.h>
#include <stdlib.h>
#include "ofp-util.h"
#include "ofpbuf.h"
#include "packets.h"
#include "random.h"
#include "xtoxll.h"
#define THIS_MODULE VLM_ofp_util
#include "vlog.h"
/* Rate limit for OpenFlow message parse errors. These always indicate a bug
* in the peer and so there's not much point in showing a lot of them. */
static struct vlog_rate_limit bad_ofmsg_rl = VLOG_RATE_LIMIT_INIT(1, 5);
/* XXX we should really use consecutive xids to avoid probabilistic
* failures. */
static inline uint32_t
alloc_xid(void)
{
return random_uint32();
}
/* Allocates and stores in '*bufferp' a new ofpbuf with a size of
* 'openflow_len', starting with an OpenFlow header with the given 'type' and
* an arbitrary transaction id. Allocated bytes beyond the header, if any, are
* zeroed.
*
* The caller is responsible for freeing '*bufferp' when it is no longer
* needed.
*
* The OpenFlow header length is initially set to 'openflow_len'; if the
* message is later extended, the length should be updated with
* update_openflow_length() before sending.
*
* Returns the header. */
void *
make_openflow(size_t openflow_len, uint8_t type, struct ofpbuf **bufferp)
{
*bufferp = ofpbuf_new(openflow_len);
return put_openflow_xid(openflow_len, type, alloc_xid(), *bufferp);
}
/* Allocates and stores in '*bufferp' a new ofpbuf with a size of
* 'openflow_len', starting with an OpenFlow header with the given 'type' and
* transaction id 'xid'. Allocated bytes beyond the header, if any, are
* zeroed.
*
* The caller is responsible for freeing '*bufferp' when it is no longer
* needed.
*
* The OpenFlow header length is initially set to 'openflow_len'; if the
* message is later extended, the length should be updated with
* update_openflow_length() before sending.
*
* Returns the header. */
void *
make_openflow_xid(size_t openflow_len, uint8_t type, uint32_t xid,
struct ofpbuf **bufferp)
{
*bufferp = ofpbuf_new(openflow_len);
return put_openflow_xid(openflow_len, type, xid, *bufferp);
}
/* Appends 'openflow_len' bytes to 'buffer', starting with an OpenFlow header
* with the given 'type' and an arbitrary transaction id. Allocated bytes
* beyond the header, if any, are zeroed.
*
* The OpenFlow header length is initially set to 'openflow_len'; if the
* message is later extended, the length should be updated with
* update_openflow_length() before sending.
*
* Returns the header. */
void *
put_openflow(size_t openflow_len, uint8_t type, struct ofpbuf *buffer)
{
return put_openflow_xid(openflow_len, type, alloc_xid(), buffer);
}
/* Appends 'openflow_len' bytes to 'buffer', starting with an OpenFlow header
* with the given 'type' and an transaction id 'xid'. Allocated bytes beyond
* the header, if any, are zeroed.
*
* The OpenFlow header length is initially set to 'openflow_len'; if the
* message is later extended, the length should be updated with
* update_openflow_length() before sending.
*
* Returns the header. */
void *
put_openflow_xid(size_t openflow_len, uint8_t type, uint32_t xid,
struct ofpbuf *buffer)
{
struct ofp_header *oh;
assert(openflow_len >= sizeof *oh);
assert(openflow_len <= UINT16_MAX);
oh = ofpbuf_put_uninit(buffer, openflow_len);
oh->version = OFP_VERSION;
oh->type = type;
oh->length = htons(openflow_len);
oh->xid = xid;
memset(oh + 1, 0, openflow_len - sizeof *oh);
return oh;
}
/* Updates the 'length' field of the OpenFlow message in 'buffer' to
* 'buffer->size'. */
void
update_openflow_length(struct ofpbuf *buffer)
{
struct ofp_header *oh = ofpbuf_at_assert(buffer, 0, sizeof *oh);
oh->length = htons(buffer->size);
}
struct ofpbuf *
make_flow_mod(uint16_t command, const flow_t *flow, size_t actions_len)
{
struct ofp_flow_mod *ofm;
size_t size = sizeof *ofm + actions_len;
struct ofpbuf *out = ofpbuf_new(size);
ofm = ofpbuf_put_zeros(out, sizeof *ofm);
ofm->header.version = OFP_VERSION;
ofm->header.type = OFPT_FLOW_MOD;
ofm->header.length = htons(size);
ofm->cookie = 0;
ofm->match.wildcards = htonl(0);
ofm->match.in_port = htons(flow->in_port == ODPP_LOCAL ? OFPP_LOCAL
: flow->in_port);
memcpy(ofm->match.dl_src, flow->dl_src, sizeof ofm->match.dl_src);
memcpy(ofm->match.dl_dst, flow->dl_dst, sizeof ofm->match.dl_dst);
ofm->match.dl_vlan = flow->dl_vlan;
ofm->match.dl_vlan_pcp = flow->dl_vlan_pcp;
ofm->match.dl_type = flow->dl_type;
ofm->match.nw_src = flow->nw_src;
ofm->match.nw_dst = flow->nw_dst;
ofm->match.nw_proto = flow->nw_proto;
ofm->match.nw_tos = flow->nw_tos;
ofm->match.tp_src = flow->tp_src;
ofm->match.tp_dst = flow->tp_dst;
ofm->command = htons(command);
return out;
}
struct ofpbuf *
make_add_flow(const flow_t *flow, uint32_t buffer_id,
uint16_t idle_timeout, size_t actions_len)
{
struct ofpbuf *out = make_flow_mod(OFPFC_ADD, flow, actions_len);
struct ofp_flow_mod *ofm = out->data;
ofm->idle_timeout = htons(idle_timeout);
ofm->hard_timeout = htons(OFP_FLOW_PERMANENT);
ofm->buffer_id = htonl(buffer_id);
return out;
}
struct ofpbuf *
make_del_flow(const flow_t *flow)
{
struct ofpbuf *out = make_flow_mod(OFPFC_DELETE_STRICT, flow, 0);
struct ofp_flow_mod *ofm = out->data;
ofm->out_port = htons(OFPP_NONE);
return out;
}
struct ofpbuf *
make_add_simple_flow(const flow_t *flow,
uint32_t buffer_id, uint16_t out_port,
uint16_t idle_timeout)
{
struct ofp_action_output *oao;
struct ofpbuf *buffer = make_add_flow(flow, buffer_id, idle_timeout,
sizeof *oao);
oao = ofpbuf_put_zeros(buffer, sizeof *oao);
oao->type = htons(OFPAT_OUTPUT);
oao->len = htons(sizeof *oao);
oao->port = htons(out_port);
return buffer;
}
struct ofpbuf *
make_packet_in(uint32_t buffer_id, uint16_t in_port, uint8_t reason,
const struct ofpbuf *payload, int max_send_len)
{
struct ofp_packet_in *opi;
struct ofpbuf *buf;
int send_len;
send_len = MIN(max_send_len, payload->size);
buf = ofpbuf_new(sizeof *opi + send_len);
opi = put_openflow_xid(offsetof(struct ofp_packet_in, data),
OFPT_PACKET_IN, 0, buf);
opi->buffer_id = htonl(buffer_id);
opi->total_len = htons(payload->size);
opi->in_port = htons(in_port);
opi->reason = reason;
ofpbuf_put(buf, payload->data, send_len);
update_openflow_length(buf);
return buf;
}
struct ofpbuf *
make_packet_out(const struct ofpbuf *packet, uint32_t buffer_id,
uint16_t in_port,
const struct ofp_action_header *actions, size_t n_actions)
{
size_t actions_len = n_actions * sizeof *actions;
struct ofp_packet_out *opo;
size_t size = sizeof *opo + actions_len + (packet ? packet->size : 0);
struct ofpbuf *out = ofpbuf_new(size);
opo = ofpbuf_put_uninit(out, sizeof *opo);
opo->header.version = OFP_VERSION;
opo->header.type = OFPT_PACKET_OUT;
opo->header.length = htons(size);
opo->header.xid = htonl(0);
opo->buffer_id = htonl(buffer_id);
opo->in_port = htons(in_port == ODPP_LOCAL ? OFPP_LOCAL : in_port);
opo->actions_len = htons(actions_len);
ofpbuf_put(out, actions, actions_len);
if (packet) {
ofpbuf_put(out, packet->data, packet->size);
}
return out;
}
struct ofpbuf *
make_unbuffered_packet_out(const struct ofpbuf *packet,
uint16_t in_port, uint16_t out_port)
{
struct ofp_action_output action;
action.type = htons(OFPAT_OUTPUT);
action.len = htons(sizeof action);
action.port = htons(out_port);
return make_packet_out(packet, UINT32_MAX, in_port,
(struct ofp_action_header *) &action, 1);
}
struct ofpbuf *
make_buffered_packet_out(uint32_t buffer_id,
uint16_t in_port, uint16_t out_port)
{
struct ofp_action_output action;
action.type = htons(OFPAT_OUTPUT);
action.len = htons(sizeof action);
action.port = htons(out_port);
return make_packet_out(NULL, buffer_id, in_port,
(struct ofp_action_header *) &action, 1);
}
/* Creates and returns an OFPT_ECHO_REQUEST message with an empty payload. */
struct ofpbuf *
make_echo_request(void)
{
struct ofp_header *rq;
struct ofpbuf *out = ofpbuf_new(sizeof *rq);
rq = ofpbuf_put_uninit(out, sizeof *rq);
rq->version = OFP_VERSION;
rq->type = OFPT_ECHO_REQUEST;
rq->length = htons(sizeof *rq);
rq->xid = 0;
return out;
}
/* Creates and returns an OFPT_ECHO_REPLY message matching the
* OFPT_ECHO_REQUEST message in 'rq'. */
struct ofpbuf *
make_echo_reply(const struct ofp_header *rq)
{
size_t size = ntohs(rq->length);
struct ofpbuf *out = ofpbuf_new(size);
struct ofp_header *reply = ofpbuf_put(out, rq, size);
reply->type = OFPT_ECHO_REPLY;
return out;
}
static int
check_message_type(uint8_t got_type, uint8_t want_type)
{
if (got_type != want_type) {
char *want_type_name = ofp_message_type_to_string(want_type);
char *got_type_name = ofp_message_type_to_string(got_type);
VLOG_WARN_RL(&bad_ofmsg_rl,
"received bad message type %s (expected %s)",
got_type_name, want_type_name);
free(want_type_name);
free(got_type_name);
return ofp_mkerr(OFPET_BAD_REQUEST, OFPBRC_BAD_TYPE);
}
return 0;
}
/* Checks that 'msg' has type 'type' and that it is exactly 'size' bytes long.
* Returns 0 if the checks pass, otherwise an OpenFlow error code (produced
* with ofp_mkerr()). */
int
check_ofp_message(const struct ofp_header *msg, uint8_t type, size_t size)
{
size_t got_size;
int error;
error = check_message_type(msg->type, type);
if (error) {
return error;
}
got_size = ntohs(msg->length);
if (got_size != size) {
char *type_name = ofp_message_type_to_string(type);
VLOG_WARN_RL(&bad_ofmsg_rl,
"received %s message of length %zu (expected %zu)",
type_name, got_size, size);
free(type_name);
return ofp_mkerr(OFPET_BAD_REQUEST, OFPBRC_BAD_LEN);
}
return 0;
}
/* Checks that 'msg' has type 'type' and that 'msg' is 'size' plus a
* nonnegative integer multiple of 'array_elt_size' bytes long. Returns 0 if
* the checks pass, otherwise an OpenFlow error code (produced with
* ofp_mkerr()).
*
* If 'n_array_elts' is nonnull, then '*n_array_elts' is set to the number of
* 'array_elt_size' blocks in 'msg' past the first 'min_size' bytes, when
* successful. */
int
check_ofp_message_array(const struct ofp_header *msg, uint8_t type,
size_t min_size, size_t array_elt_size,
size_t *n_array_elts)
{
size_t got_size;
int error;
assert(array_elt_size);
error = check_message_type(msg->type, type);
if (error) {
return error;
}
got_size = ntohs(msg->length);
if (got_size < min_size) {
char *type_name = ofp_message_type_to_string(type);
VLOG_WARN_RL(&bad_ofmsg_rl, "received %s message of length %zu "
"(expected at least %zu)",
type_name, got_size, min_size);
free(type_name);
return ofp_mkerr(OFPET_BAD_REQUEST, OFPBRC_BAD_LEN);
}
if ((got_size - min_size) % array_elt_size) {
char *type_name = ofp_message_type_to_string(type);
VLOG_WARN_RL(&bad_ofmsg_rl,
"received %s message of bad length %zu: the "
"excess over %zu (%zu) is not evenly divisible by %zu "
"(remainder is %zu)",
type_name, got_size, min_size, got_size - min_size,
array_elt_size, (got_size - min_size) % array_elt_size);
free(type_name);
return ofp_mkerr(OFPET_BAD_REQUEST, OFPBRC_BAD_LEN);
}
if (n_array_elts) {
*n_array_elts = (got_size - min_size) / array_elt_size;
}
return 0;
}
int
check_ofp_packet_out(const struct ofp_header *oh, struct ofpbuf *data,
int *n_actionsp, int max_ports)
{
const struct ofp_packet_out *opo;
unsigned int actions_len, n_actions;
size_t extra;
int error;
*n_actionsp = 0;
error = check_ofp_message_array(oh, OFPT_PACKET_OUT,
sizeof *opo, 1, &extra);
if (error) {
return error;
}
opo = (const struct ofp_packet_out *) oh;
actions_len = ntohs(opo->actions_len);
if (actions_len > extra) {
VLOG_WARN_RL(&bad_ofmsg_rl, "packet-out claims %u bytes of actions "
"but message has room for only %zu bytes",
actions_len, extra);
return ofp_mkerr(OFPET_BAD_REQUEST, OFPBRC_BAD_LEN);
}
if (actions_len % sizeof(union ofp_action)) {
VLOG_WARN_RL(&bad_ofmsg_rl, "packet-out claims %u bytes of actions, "
"which is not a multiple of %zu",
actions_len, sizeof(union ofp_action));
return ofp_mkerr(OFPET_BAD_REQUEST, OFPBRC_BAD_LEN);
}
n_actions = actions_len / sizeof(union ofp_action);
error = validate_actions((const union ofp_action *) opo->actions,
n_actions, max_ports);
if (error) {
return error;
}
data->data = (void *) &opo->actions[n_actions];
data->size = extra - actions_len;
*n_actionsp = n_actions;
return 0;
}
const struct ofp_flow_stats *
flow_stats_first(struct flow_stats_iterator *iter,
const struct ofp_stats_reply *osr)
{
iter->pos = osr->body;
iter->end = osr->body + (ntohs(osr->header.length)
- offsetof(struct ofp_stats_reply, body));
return flow_stats_next(iter);
}
const struct ofp_flow_stats *
flow_stats_next(struct flow_stats_iterator *iter)
{
ptrdiff_t bytes_left = iter->end - iter->pos;
const struct ofp_flow_stats *fs;
size_t length;
if (bytes_left < sizeof *fs) {
if (bytes_left != 0) {
VLOG_WARN_RL(&bad_ofmsg_rl,
"%td leftover bytes in flow stats reply", bytes_left);
}
return NULL;
}
fs = (const void *) iter->pos;
length = ntohs(fs->length);
if (length < sizeof *fs) {
VLOG_WARN_RL(&bad_ofmsg_rl, "flow stats length %zu is shorter than "
"min %zu", length, sizeof *fs);
return NULL;
} else if (length > bytes_left) {
VLOG_WARN_RL(&bad_ofmsg_rl, "flow stats length %zu but only %td "
"bytes left", length, bytes_left);
return NULL;
} else if ((length - sizeof *fs) % sizeof fs->actions[0]) {
VLOG_WARN_RL(&bad_ofmsg_rl, "flow stats length %zu has %zu bytes "
"left over in final action", length,
(length - sizeof *fs) % sizeof fs->actions[0]);
return NULL;
}
iter->pos += length;
return fs;
}
/* Alignment of ofp_actions. */
#define ACTION_ALIGNMENT 8
static int
check_action_exact_len(const union ofp_action *a, unsigned int len,
unsigned int required_len)
{
if (len != required_len) {
VLOG_DBG_RL(&bad_ofmsg_rl,
"action %u has invalid length %"PRIu16" (must be %u)\n",
a->type, ntohs(a->header.len), required_len);
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_LEN);
}
return 0;
}
/* Checks that 'port' is a valid output port for the OFPAT_OUTPUT action, given
* that the switch will never have more than 'max_ports' ports. Returns 0 if
* 'port' is valid, otherwise an ofp_mkerr() return code. */
static int
check_output_port(uint16_t port, int max_ports)
{
switch (port) {
case OFPP_IN_PORT:
case OFPP_TABLE:
case OFPP_NORMAL:
case OFPP_FLOOD:
case OFPP_ALL:
case OFPP_CONTROLLER:
case OFPP_LOCAL:
return 0;
default:
if (port < max_ports) {
return 0;
}
VLOG_WARN_RL(&bad_ofmsg_rl, "unknown output port %x", port);
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_OUT_PORT);
}
}
/* Checks that 'action' is a valid OFPAT_ENQUEUE action, given that the switch
* will never have more than 'max_ports' ports. Returns 0 if 'port' is valid,
* otherwise an ofp_mkerr() return code. */
static int
check_enqueue_action(const union ofp_action *a, unsigned int len,
int max_ports)
{
const struct ofp_action_enqueue *oae;
uint16_t port;
int error;
error = check_action_exact_len(a, len, 16);
if (error) {
return error;
}
oae = (const struct ofp_action_enqueue *) a;
port = ntohs(oae->port);
if (port < max_ports || port == OFPP_IN_PORT) {
return 0;
}
VLOG_WARN_RL(&bad_ofmsg_rl, "unknown enqueue port %x", port);
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_OUT_PORT);
}
static int
check_nicira_action(const union ofp_action *a, unsigned int len)
{
const struct nx_action_header *nah;
if (len < 16) {
VLOG_DBG_RL(&bad_ofmsg_rl,
"Nicira vendor action only %u bytes", len);
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_LEN);
}
nah = (const struct nx_action_header *) a;
switch (ntohs(nah->subtype)) {
case NXAST_RESUBMIT:
case NXAST_SET_TUNNEL:
return check_action_exact_len(a, len, 16);
default:
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_VENDOR_TYPE);
}
}
static int
check_action(const union ofp_action *a, unsigned int len, int max_ports)
{
int error;
switch (ntohs(a->type)) {
case OFPAT_OUTPUT:
error = check_action_exact_len(a, len, 8);
if (error) {
return error;
}
return check_output_port(ntohs(a->output.port), max_ports);
case OFPAT_SET_VLAN_VID:
case OFPAT_SET_VLAN_PCP:
case OFPAT_STRIP_VLAN:
case OFPAT_SET_NW_SRC:
case OFPAT_SET_NW_DST:
case OFPAT_SET_NW_TOS:
case OFPAT_SET_TP_SRC:
case OFPAT_SET_TP_DST:
return check_action_exact_len(a, len, 8);
case OFPAT_SET_DL_SRC:
case OFPAT_SET_DL_DST:
return check_action_exact_len(a, len, 16);
case OFPAT_VENDOR:
return (a->vendor.vendor == htonl(NX_VENDOR_ID)
? check_nicira_action(a, len)
: ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_VENDOR));
case OFPAT_ENQUEUE:
return check_enqueue_action(a, len, max_ports);
default:
VLOG_WARN_RL(&bad_ofmsg_rl, "unknown action type %"PRIu16,
ntohs(a->type));
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_TYPE);
}
}
int
validate_actions(const union ofp_action *actions, size_t n_actions,
int max_ports)
{
const union ofp_action *a;
for (a = actions; a < &actions[n_actions]; ) {
unsigned int len = ntohs(a->header.len);
unsigned int n_slots = len / ACTION_ALIGNMENT;
unsigned int slots_left = &actions[n_actions] - a;
int error;
if (n_slots > slots_left) {
VLOG_DBG_RL(&bad_ofmsg_rl,
"action requires %u slots but only %u remain",
n_slots, slots_left);
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_LEN);
} else if (!len) {
VLOG_DBG_RL(&bad_ofmsg_rl, "action has invalid length 0");
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_LEN);
} else if (len % ACTION_ALIGNMENT) {
VLOG_DBG_RL(&bad_ofmsg_rl, "action length %u is not a multiple "
"of %d", len, ACTION_ALIGNMENT);
return ofp_mkerr(OFPET_BAD_ACTION, OFPBAC_BAD_LEN);
}
error = check_action(a, len, max_ports);
if (error) {
return error;
}
a += n_slots;
}
return 0;
}
/* Returns true if 'action' outputs to 'port' (which must be in network byte
* order), false otherwise. */
bool
action_outputs_to_port(const union ofp_action *action, uint16_t port)
{
switch (ntohs(action->type)) {
case OFPAT_OUTPUT:
return action->output.port == port;
case OFPAT_ENQUEUE:
return ((const struct ofp_action_enqueue *) action)->port == port;
default:
return false;
}
}
/* The set of actions must either come from a trusted source or have been
* previously validated with validate_actions(). */
const union ofp_action *
actions_first(struct actions_iterator *iter,
const union ofp_action *oa, size_t n_actions)
{
iter->pos = oa;
iter->end = oa + n_actions;
return actions_next(iter);
}
const union ofp_action *
actions_next(struct actions_iterator *iter)
{
if (iter->pos < iter->end) {
const union ofp_action *a = iter->pos;
unsigned int len = ntohs(a->header.len);
iter->pos += len / ACTION_ALIGNMENT;
return a;
} else {
return NULL;
}
}
void
normalize_match(struct ofp_match *m)
{
enum { OFPFW_NW = OFPFW_NW_SRC_MASK | OFPFW_NW_DST_MASK | OFPFW_NW_PROTO };
enum { OFPFW_TP = OFPFW_TP_SRC | OFPFW_TP_DST };
uint32_t wc;
wc = ntohl(m->wildcards) & OVSFW_ALL;
if (wc & OFPFW_DL_TYPE) {
m->dl_type = 0;
/* Can't sensibly match on network or transport headers if the
* data link type is unknown. */
wc |= OFPFW_NW | OFPFW_TP;
m->nw_src = m->nw_dst = m->nw_proto = 0;
m->tp_src = m->tp_dst = 0;
} else if (m->dl_type == htons(ETH_TYPE_IP)) {
if (wc & OFPFW_NW_PROTO) {
m->nw_proto = 0;
/* Can't sensibly match on transport headers if the network
* protocol is unknown. */
wc |= OFPFW_TP;
m->tp_src = m->tp_dst = 0;
} else if (m->nw_proto == IPPROTO_TCP ||
m->nw_proto == IPPROTO_UDP ||
m->nw_proto == IPPROTO_ICMP) {
if (wc & OFPFW_TP_SRC) {
m->tp_src = 0;
}
if (wc & OFPFW_TP_DST) {
m->tp_dst = 0;
}
} else {
/* Transport layer fields will always be extracted as zeros, so we
* can do an exact-match on those values. */
wc &= ~OFPFW_TP;
m->tp_src = m->tp_dst = 0;
}
if (wc & OFPFW_NW_SRC_MASK) {
m->nw_src &= flow_nw_bits_to_mask(wc, OFPFW_NW_SRC_SHIFT);
}
if (wc & OFPFW_NW_DST_MASK) {
m->nw_dst &= flow_nw_bits_to_mask(wc, OFPFW_NW_DST_SHIFT);
}
} else if (m->dl_type == htons(ETH_TYPE_ARP)) {
if (wc & OFPFW_NW_PROTO) {
m->nw_proto = 0;
}
if (wc & OFPFW_NW_SRC_MASK) {
m->nw_src &= flow_nw_bits_to_mask(wc, OFPFW_NW_SRC_SHIFT);
}
if (wc & OFPFW_NW_DST_MASK) {
m->nw_dst &= flow_nw_bits_to_mask(wc, OFPFW_NW_DST_SHIFT);
}
m->tp_src = m->tp_dst = 0;
} else {
/* Network and transport layer fields will always be extracted as
* zeros, so we can do an exact-match on those values. */
wc &= ~(OFPFW_NW | OFPFW_TP);
m->nw_proto = m->nw_src = m->nw_dst = 0;
m->tp_src = m->tp_dst = 0;
}
if (wc & OFPFW_DL_SRC) {
memset(m->dl_src, 0, sizeof m->dl_src);
}
if (wc & OFPFW_DL_DST) {
memset(m->dl_dst, 0, sizeof m->dl_dst);
}
m->wildcards = htonl(wc);
}
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