2 * Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013, 2014, 2015 Nicira, Inc.
4 * Licensed under the Apache License, Version 2.0 (the "License");
5 * you may not use this file except in compliance with the License.
6 * You may obtain a copy of the License at:
8 * http://www.apache.org/licenses/LICENSE-2.0
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS,
12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 * See the License for the specific language governing permissions and
14 * limitations under the License.
17 #include <sys/types.h>
22 #include <netinet/in.h>
23 #include <netinet/icmp6.h>
24 #include <netinet/ip6.h>
28 #include "byte-order.h"
31 #include "dynamic-string.h"
35 #include "dp-packet.h"
36 #include "openflow/openflow.h"
40 #include "unaligned.h"
42 COVERAGE_DEFINE(flow_extract);
43 COVERAGE_DEFINE(miniflow_malloc);
45 /* U64 indices for segmented flow classification. */
46 const uint8_t flow_segment_u64s[4] = {
47 FLOW_SEGMENT_1_ENDS_AT / sizeof(uint64_t),
48 FLOW_SEGMENT_2_ENDS_AT / sizeof(uint64_t),
49 FLOW_SEGMENT_3_ENDS_AT / sizeof(uint64_t),
53 /* Asserts that field 'f1' follows immediately after 'f0' in struct flow,
54 * without any intervening padding. */
55 #define ASSERT_SEQUENTIAL(f0, f1) \
56 BUILD_ASSERT_DECL(offsetof(struct flow, f0) \
57 + MEMBER_SIZEOF(struct flow, f0) \
58 == offsetof(struct flow, f1))
60 /* Asserts that fields 'f0' and 'f1' are in the same 32-bit aligned word within
62 #define ASSERT_SAME_WORD(f0, f1) \
63 BUILD_ASSERT_DECL(offsetof(struct flow, f0) / 4 \
64 == offsetof(struct flow, f1) / 4)
66 /* Asserts that 'f0' and 'f1' are both sequential and within the same 32-bit
67 * aligned word in struct flow. */
68 #define ASSERT_SEQUENTIAL_SAME_WORD(f0, f1) \
69 ASSERT_SEQUENTIAL(f0, f1); \
70 ASSERT_SAME_WORD(f0, f1)
72 /* miniflow_extract() assumes the following to be true to optimize the
73 * extraction process. */
74 ASSERT_SEQUENTIAL_SAME_WORD(dl_type, vlan_tci);
76 ASSERT_SEQUENTIAL_SAME_WORD(nw_frag, nw_tos);
77 ASSERT_SEQUENTIAL_SAME_WORD(nw_tos, nw_ttl);
78 ASSERT_SEQUENTIAL_SAME_WORD(nw_ttl, nw_proto);
80 /* TCP flags in the middle of a BE64, zeroes in the other half. */
81 BUILD_ASSERT_DECL(offsetof(struct flow, tcp_flags) % 8 == 4);
84 #define TCP_FLAGS_BE32(tcp_ctl) ((OVS_FORCE ovs_be32)TCP_FLAGS_BE16(tcp_ctl) \
87 #define TCP_FLAGS_BE32(tcp_ctl) ((OVS_FORCE ovs_be32)TCP_FLAGS_BE16(tcp_ctl))
90 ASSERT_SEQUENTIAL_SAME_WORD(tp_src, tp_dst);
92 /* Removes 'size' bytes from the head end of '*datap', of size '*sizep', which
93 * must contain at least 'size' bytes of data. Returns the first byte of data
95 static inline const void *
96 data_pull(const void **datap, size_t *sizep, size_t size)
98 const char *data = *datap;
104 /* If '*datap' has at least 'size' bytes of data, removes that many bytes from
105 * the head end of '*datap' and returns the first byte removed. Otherwise,
106 * returns a null pointer without modifying '*datap'. */
107 static inline const void *
108 data_try_pull(const void **datap, size_t *sizep, size_t size)
110 return OVS_LIKELY(*sizep >= size) ? data_pull(datap, sizep, size) : NULL;
113 /* Context for pushing data to a miniflow. */
117 uint64_t * const end;
120 /* miniflow_push_* macros allow filling in a miniflow data values in order.
121 * Assertions are needed only when the layout of the struct flow is modified.
122 * 'ofs' is a compile-time constant, which allows most of the code be optimized
123 * away. Some GCC versions gave warnings on ALWAYS_INLINE, so these are
124 * defined as macros. */
126 #if (FLOW_WC_SEQ != 31)
127 #define MINIFLOW_ASSERT(X) ovs_assert(X)
128 BUILD_MESSAGE("FLOW_WC_SEQ changed: miniflow_extract() will have runtime "
129 "assertions enabled. Consider updating FLOW_WC_SEQ after "
132 #define MINIFLOW_ASSERT(X)
135 #define miniflow_push_uint64_(MF, OFS, VALUE) \
137 MINIFLOW_ASSERT(MF.data < MF.end && (OFS) % 8 == 0 \
138 && !(MF.map & (UINT64_MAX << (OFS) / 8))); \
139 *MF.data++ = VALUE; \
140 MF.map |= UINT64_C(1) << (OFS) / 8; \
143 #define miniflow_push_be64_(MF, OFS, VALUE) \
144 miniflow_push_uint64_(MF, OFS, (OVS_FORCE uint64_t)(VALUE))
146 #define miniflow_push_uint32_(MF, OFS, VALUE) \
148 MINIFLOW_ASSERT(MF.data < MF.end && \
149 (((OFS) % 8 == 0 && !(MF.map & (UINT64_MAX << (OFS) / 8))) \
150 || ((OFS) % 8 == 4 && MF.map & (UINT64_C(1) << (OFS) / 8) \
151 && !(MF.map & (UINT64_MAX << ((OFS) / 8 + 1)))))); \
153 if ((OFS) % 8 == 0) { \
154 *(uint32_t *)MF.data = VALUE; \
155 MF.map |= UINT64_C(1) << (OFS) / 8; \
156 } else if ((OFS) % 8 == 4) { \
157 *((uint32_t *)MF.data + 1) = VALUE; \
162 #define miniflow_push_be32_(MF, OFS, VALUE) \
163 miniflow_push_uint32_(MF, OFS, (OVS_FORCE uint32_t)(VALUE))
165 #define miniflow_push_uint16_(MF, OFS, VALUE) \
167 MINIFLOW_ASSERT(MF.data < MF.end && \
168 (((OFS) % 8 == 0 && !(MF.map & (UINT64_MAX << (OFS) / 8))) \
169 || ((OFS) % 2 == 0 && MF.map & (UINT64_C(1) << (OFS) / 8) \
170 && !(MF.map & (UINT64_MAX << ((OFS) / 8 + 1)))))); \
172 if ((OFS) % 8 == 0) { \
173 *(uint16_t *)MF.data = VALUE; \
174 MF.map |= UINT64_C(1) << (OFS) / 8; \
175 } else if ((OFS) % 8 == 2) { \
176 *((uint16_t *)MF.data + 1) = VALUE; \
177 } else if ((OFS) % 8 == 4) { \
178 *((uint16_t *)MF.data + 2) = VALUE; \
179 } else if ((OFS) % 8 == 6) { \
180 *((uint16_t *)MF.data + 3) = VALUE; \
185 #define miniflow_pad_to_64_(MF, OFS) \
187 MINIFLOW_ASSERT((OFS) % 8 != 0); \
188 MINIFLOW_ASSERT(MF.map & (UINT64_C(1) << (OFS) / 8)); \
189 MINIFLOW_ASSERT(!(MF.map & (UINT64_MAX << ((OFS) / 8 + 1)))); \
191 memset((uint8_t *)MF.data + (OFS) % 8, 0, 8 - (OFS) % 8); \
195 #define miniflow_push_be16_(MF, OFS, VALUE) \
196 miniflow_push_uint16_(MF, OFS, (OVS_FORCE uint16_t)VALUE);
198 /* Data at 'valuep' may be unaligned. */
199 #define miniflow_push_words_(MF, OFS, VALUEP, N_WORDS) \
201 int ofs64 = (OFS) / 8; \
203 MINIFLOW_ASSERT(MF.data + (N_WORDS) <= MF.end && (OFS) % 8 == 0 \
204 && !(MF.map & (UINT64_MAX << ofs64))); \
206 memcpy(MF.data, (VALUEP), (N_WORDS) * sizeof *MF.data); \
207 MF.data += (N_WORDS); \
208 MF.map |= ((UINT64_MAX >> (64 - (N_WORDS))) << ofs64); \
211 /* Push 32-bit words padded to 64-bits. */
212 #define miniflow_push_words_32_(MF, OFS, VALUEP, N_WORDS) \
214 int ofs64 = (OFS) / 8; \
216 MINIFLOW_ASSERT(MF.data + DIV_ROUND_UP(N_WORDS, 2) <= MF.end \
218 && !(MF.map & (UINT64_MAX << ofs64))); \
220 memcpy(MF.data, (VALUEP), (N_WORDS) * sizeof(uint32_t)); \
221 MF.data += DIV_ROUND_UP(N_WORDS, 2); \
222 MF.map |= ((UINT64_MAX >> (64 - DIV_ROUND_UP(N_WORDS, 2))) << ofs64); \
223 if ((N_WORDS) & 1) { \
224 *((uint32_t *)MF.data - 1) = 0; \
228 /* Data at 'valuep' may be unaligned. */
229 /* MACs start 64-aligned, and must be followed by other data or padding. */
230 #define miniflow_push_macs_(MF, OFS, VALUEP) \
232 int ofs64 = (OFS) / 8; \
234 MINIFLOW_ASSERT(MF.data + 2 <= MF.end && (OFS) % 8 == 0 \
235 && !(MF.map & (UINT64_MAX << ofs64))); \
237 memcpy(MF.data, (VALUEP), 2 * ETH_ADDR_LEN); \
238 MF.data += 1; /* First word only. */ \
239 MF.map |= UINT64_C(3) << ofs64; /* Both words. */ \
242 #define miniflow_push_uint32(MF, FIELD, VALUE) \
243 miniflow_push_uint32_(MF, offsetof(struct flow, FIELD), VALUE)
245 #define miniflow_push_be32(MF, FIELD, VALUE) \
246 miniflow_push_be32_(MF, offsetof(struct flow, FIELD), VALUE)
248 #define miniflow_push_uint16(MF, FIELD, VALUE) \
249 miniflow_push_uint16_(MF, offsetof(struct flow, FIELD), VALUE)
251 #define miniflow_push_be16(MF, FIELD, VALUE) \
252 miniflow_push_be16_(MF, offsetof(struct flow, FIELD), VALUE)
254 #define miniflow_pad_to_64(MF, FIELD) \
255 miniflow_pad_to_64_(MF, offsetof(struct flow, FIELD))
257 #define miniflow_push_words(MF, FIELD, VALUEP, N_WORDS) \
258 miniflow_push_words_(MF, offsetof(struct flow, FIELD), VALUEP, N_WORDS)
260 #define miniflow_push_words_32(MF, FIELD, VALUEP, N_WORDS) \
261 miniflow_push_words_32_(MF, offsetof(struct flow, FIELD), VALUEP, N_WORDS)
263 #define miniflow_push_macs(MF, FIELD, VALUEP) \
264 miniflow_push_macs_(MF, offsetof(struct flow, FIELD), VALUEP)
266 /* Pulls the MPLS headers at '*datap' and returns the count of them. */
268 parse_mpls(const void **datap, size_t *sizep)
270 const struct mpls_hdr *mh;
273 while ((mh = data_try_pull(datap, sizep, sizeof *mh))) {
275 if (mh->mpls_lse.lo & htons(1 << MPLS_BOS_SHIFT)) {
279 return MIN(count, FLOW_MAX_MPLS_LABELS);
282 static inline ovs_be16
283 parse_vlan(const void **datap, size_t *sizep)
285 const struct eth_header *eth = *datap;
288 ovs_be16 eth_type; /* ETH_TYPE_VLAN */
292 data_pull(datap, sizep, ETH_ADDR_LEN * 2);
294 if (eth->eth_type == htons(ETH_TYPE_VLAN)) {
295 if (OVS_LIKELY(*sizep
296 >= sizeof(struct qtag_prefix) + sizeof(ovs_be16))) {
297 const struct qtag_prefix *qp = data_pull(datap, sizep, sizeof *qp);
298 return qp->tci | htons(VLAN_CFI);
304 static inline ovs_be16
305 parse_ethertype(const void **datap, size_t *sizep)
307 const struct llc_snap_header *llc;
310 proto = *(ovs_be16 *) data_pull(datap, sizep, sizeof proto);
311 if (OVS_LIKELY(ntohs(proto) >= ETH_TYPE_MIN)) {
315 if (OVS_UNLIKELY(*sizep < sizeof *llc)) {
316 return htons(FLOW_DL_TYPE_NONE);
320 if (OVS_UNLIKELY(llc->llc.llc_dsap != LLC_DSAP_SNAP
321 || llc->llc.llc_ssap != LLC_SSAP_SNAP
322 || llc->llc.llc_cntl != LLC_CNTL_SNAP
323 || memcmp(llc->snap.snap_org, SNAP_ORG_ETHERNET,
324 sizeof llc->snap.snap_org))) {
325 return htons(FLOW_DL_TYPE_NONE);
328 data_pull(datap, sizep, sizeof *llc);
330 if (OVS_LIKELY(ntohs(llc->snap.snap_type) >= ETH_TYPE_MIN)) {
331 return llc->snap.snap_type;
334 return htons(FLOW_DL_TYPE_NONE);
338 parse_icmpv6(const void **datap, size_t *sizep, const struct icmp6_hdr *icmp,
339 const struct in6_addr **nd_target,
340 uint8_t arp_buf[2][ETH_ADDR_LEN])
342 if (icmp->icmp6_code == 0 &&
343 (icmp->icmp6_type == ND_NEIGHBOR_SOLICIT ||
344 icmp->icmp6_type == ND_NEIGHBOR_ADVERT)) {
346 *nd_target = data_try_pull(datap, sizep, sizeof **nd_target);
347 if (OVS_UNLIKELY(!*nd_target)) {
351 while (*sizep >= 8) {
352 /* The minimum size of an option is 8 bytes, which also is
353 * the size of Ethernet link-layer options. */
354 const struct nd_opt_hdr *nd_opt = *datap;
355 int opt_len = nd_opt->nd_opt_len * 8;
357 if (!opt_len || opt_len > *sizep) {
361 /* Store the link layer address if the appropriate option is
362 * provided. It is considered an error if the same link
363 * layer option is specified twice. */
364 if (nd_opt->nd_opt_type == ND_OPT_SOURCE_LINKADDR
366 if (OVS_LIKELY(eth_addr_is_zero(arp_buf[0]))) {
367 memcpy(arp_buf[0], nd_opt + 1, ETH_ADDR_LEN);
371 } else if (nd_opt->nd_opt_type == ND_OPT_TARGET_LINKADDR
373 if (OVS_LIKELY(eth_addr_is_zero(arp_buf[1]))) {
374 memcpy(arp_buf[1], nd_opt + 1, ETH_ADDR_LEN);
380 if (OVS_UNLIKELY(!data_try_pull(datap, sizep, opt_len))) {
392 /* Initializes 'flow' members from 'packet' and 'md'
394 * Initializes 'packet' header l2 pointer to the start of the Ethernet
395 * header, and the layer offsets as follows:
397 * - packet->l2_5_ofs to the start of the MPLS shim header, or UINT16_MAX
398 * when there is no MPLS shim header.
400 * - packet->l3_ofs to just past the Ethernet header, or just past the
401 * vlan_header if one is present, to the first byte of the payload of the
402 * Ethernet frame. UINT16_MAX if the frame is too short to contain an
405 * - packet->l4_ofs to just past the IPv4 header, if one is present and
406 * has at least the content used for the fields of interest for the flow,
407 * otherwise UINT16_MAX.
410 flow_extract(struct dp_packet *packet, struct flow *flow)
414 uint64_t buf[FLOW_U64S];
417 COVERAGE_INC(flow_extract);
419 miniflow_initialize(&m.mf, m.buf);
420 miniflow_extract(packet, &m.mf);
421 miniflow_expand(&m.mf, flow);
424 /* Caller is responsible for initializing 'dst' with enough storage for
425 * FLOW_U64S * 8 bytes. */
427 miniflow_extract(struct dp_packet *packet, struct miniflow *dst)
429 const struct pkt_metadata *md = &packet->md;
430 const void *data = dp_packet_data(packet);
431 size_t size = dp_packet_size(packet);
432 uint64_t *values = miniflow_values(dst);
433 struct mf_ctx mf = { 0, values, values + FLOW_U64S };
436 uint8_t nw_frag, nw_tos, nw_ttl, nw_proto;
439 if (md->tunnel.ip_dst) {
440 miniflow_push_words(mf, tunnel, &md->tunnel,
441 sizeof md->tunnel / sizeof(uint64_t));
443 if (md->skb_priority || md->pkt_mark) {
444 miniflow_push_uint32(mf, skb_priority, md->skb_priority);
445 miniflow_push_uint32(mf, pkt_mark, md->pkt_mark);
447 miniflow_push_uint32(mf, dp_hash, md->dp_hash);
448 miniflow_push_uint32(mf, in_port, odp_to_u32(md->in_port.odp_port));
450 miniflow_push_uint32(mf, recirc_id, md->recirc_id);
451 miniflow_pad_to_64(mf, conj_id);
454 /* Initialize packet's layer pointer and offsets. */
456 dp_packet_reset_offsets(packet);
458 /* Must have full Ethernet header to proceed. */
459 if (OVS_UNLIKELY(size < sizeof(struct eth_header))) {
465 ASSERT_SEQUENTIAL(dl_dst, dl_src);
466 miniflow_push_macs(mf, dl_dst, data);
467 /* dl_type, vlan_tci. */
468 vlan_tci = parse_vlan(&data, &size);
469 dl_type = parse_ethertype(&data, &size);
470 miniflow_push_be16(mf, dl_type, dl_type);
471 miniflow_push_be16(mf, vlan_tci, vlan_tci);
475 if (OVS_UNLIKELY(eth_type_mpls(dl_type))) {
477 const void *mpls = data;
479 packet->l2_5_ofs = (char *)data - l2;
480 count = parse_mpls(&data, &size);
481 miniflow_push_words_32(mf, mpls_lse, mpls, count);
485 packet->l3_ofs = (char *)data - l2;
488 if (OVS_LIKELY(dl_type == htons(ETH_TYPE_IP))) {
489 const struct ip_header *nh = data;
493 if (OVS_UNLIKELY(size < IP_HEADER_LEN)) {
496 ip_len = IP_IHL(nh->ip_ihl_ver) * 4;
498 if (OVS_UNLIKELY(ip_len < IP_HEADER_LEN)) {
501 if (OVS_UNLIKELY(size < ip_len)) {
504 tot_len = ntohs(nh->ip_tot_len);
505 if (OVS_UNLIKELY(tot_len > size)) {
508 if (OVS_UNLIKELY(size - tot_len > UINT8_MAX)) {
511 dp_packet_set_l2_pad_size(packet, size - tot_len);
512 size = tot_len; /* Never pull padding. */
514 /* Push both source and destination address at once. */
515 miniflow_push_words(mf, nw_src, &nh->ip_src, 1);
517 miniflow_push_be32(mf, ipv6_label, 0); /* Padding for IPv4. */
521 nw_proto = nh->ip_proto;
522 if (OVS_UNLIKELY(IP_IS_FRAGMENT(nh->ip_frag_off))) {
523 nw_frag = FLOW_NW_FRAG_ANY;
524 if (nh->ip_frag_off & htons(IP_FRAG_OFF_MASK)) {
525 nw_frag |= FLOW_NW_FRAG_LATER;
528 data_pull(&data, &size, ip_len);
529 } else if (dl_type == htons(ETH_TYPE_IPV6)) {
530 const struct ovs_16aligned_ip6_hdr *nh;
534 if (OVS_UNLIKELY(size < sizeof *nh)) {
537 nh = data_pull(&data, &size, sizeof *nh);
539 plen = ntohs(nh->ip6_plen);
540 if (OVS_UNLIKELY(plen > size)) {
543 /* Jumbo Payload option not supported yet. */
544 if (OVS_UNLIKELY(size - plen > UINT8_MAX)) {
547 dp_packet_set_l2_pad_size(packet, size - plen);
548 size = plen; /* Never pull padding. */
550 miniflow_push_words(mf, ipv6_src, &nh->ip6_src,
551 sizeof nh->ip6_src / 8);
552 miniflow_push_words(mf, ipv6_dst, &nh->ip6_dst,
553 sizeof nh->ip6_dst / 8);
555 tc_flow = get_16aligned_be32(&nh->ip6_flow);
557 ovs_be32 label = tc_flow & htonl(IPV6_LABEL_MASK);
558 miniflow_push_be32(mf, ipv6_label, label);
561 nw_tos = ntohl(tc_flow) >> 20;
562 nw_ttl = nh->ip6_hlim;
563 nw_proto = nh->ip6_nxt;
566 if (OVS_LIKELY((nw_proto != IPPROTO_HOPOPTS)
567 && (nw_proto != IPPROTO_ROUTING)
568 && (nw_proto != IPPROTO_DSTOPTS)
569 && (nw_proto != IPPROTO_AH)
570 && (nw_proto != IPPROTO_FRAGMENT))) {
571 /* It's either a terminal header (e.g., TCP, UDP) or one we
572 * don't understand. In either case, we're done with the
573 * packet, so use it to fill in 'nw_proto'. */
577 /* We only verify that at least 8 bytes of the next header are
578 * available, but many of these headers are longer. Ensure that
579 * accesses within the extension header are within those first 8
580 * bytes. All extension headers are required to be at least 8
582 if (OVS_UNLIKELY(size < 8)) {
586 if ((nw_proto == IPPROTO_HOPOPTS)
587 || (nw_proto == IPPROTO_ROUTING)
588 || (nw_proto == IPPROTO_DSTOPTS)) {
589 /* These headers, while different, have the fields we care
590 * about in the same location and with the same
592 const struct ip6_ext *ext_hdr = data;
593 nw_proto = ext_hdr->ip6e_nxt;
594 if (OVS_UNLIKELY(!data_try_pull(&data, &size,
595 (ext_hdr->ip6e_len + 1) * 8))) {
598 } else if (nw_proto == IPPROTO_AH) {
599 /* A standard AH definition isn't available, but the fields
600 * we care about are in the same location as the generic
601 * option header--only the header length is calculated
603 const struct ip6_ext *ext_hdr = data;
604 nw_proto = ext_hdr->ip6e_nxt;
605 if (OVS_UNLIKELY(!data_try_pull(&data, &size,
606 (ext_hdr->ip6e_len + 2) * 4))) {
609 } else if (nw_proto == IPPROTO_FRAGMENT) {
610 const struct ovs_16aligned_ip6_frag *frag_hdr = data;
612 nw_proto = frag_hdr->ip6f_nxt;
613 if (!data_try_pull(&data, &size, sizeof *frag_hdr)) {
617 /* We only process the first fragment. */
618 if (frag_hdr->ip6f_offlg != htons(0)) {
619 nw_frag = FLOW_NW_FRAG_ANY;
620 if ((frag_hdr->ip6f_offlg & IP6F_OFF_MASK) != htons(0)) {
621 nw_frag |= FLOW_NW_FRAG_LATER;
622 nw_proto = IPPROTO_FRAGMENT;
629 if (dl_type == htons(ETH_TYPE_ARP) ||
630 dl_type == htons(ETH_TYPE_RARP)) {
631 uint8_t arp_buf[2][ETH_ADDR_LEN];
632 const struct arp_eth_header *arp = (const struct arp_eth_header *)
633 data_try_pull(&data, &size, ARP_ETH_HEADER_LEN);
635 if (OVS_LIKELY(arp) && OVS_LIKELY(arp->ar_hrd == htons(1))
636 && OVS_LIKELY(arp->ar_pro == htons(ETH_TYPE_IP))
637 && OVS_LIKELY(arp->ar_hln == ETH_ADDR_LEN)
638 && OVS_LIKELY(arp->ar_pln == 4)) {
639 miniflow_push_be32(mf, nw_src,
640 get_16aligned_be32(&arp->ar_spa));
641 miniflow_push_be32(mf, nw_dst,
642 get_16aligned_be32(&arp->ar_tpa));
644 /* We only match on the lower 8 bits of the opcode. */
645 if (OVS_LIKELY(ntohs(arp->ar_op) <= 0xff)) {
646 miniflow_push_be32(mf, ipv6_label, 0); /* Pad with ARP. */
647 miniflow_push_be32(mf, nw_frag, htonl(ntohs(arp->ar_op)));
650 /* Must be adjacent. */
651 ASSERT_SEQUENTIAL(arp_sha, arp_tha);
653 memcpy(arp_buf[0], arp->ar_sha, ETH_ADDR_LEN);
654 memcpy(arp_buf[1], arp->ar_tha, ETH_ADDR_LEN);
655 miniflow_push_macs(mf, arp_sha, arp_buf);
656 miniflow_pad_to_64(mf, tcp_flags);
662 packet->l4_ofs = (char *)data - l2;
663 miniflow_push_be32(mf, nw_frag,
664 BYTES_TO_BE32(nw_frag, nw_tos, nw_ttl, nw_proto));
666 if (OVS_LIKELY(!(nw_frag & FLOW_NW_FRAG_LATER))) {
667 if (OVS_LIKELY(nw_proto == IPPROTO_TCP)) {
668 if (OVS_LIKELY(size >= TCP_HEADER_LEN)) {
669 const struct tcp_header *tcp = data;
671 miniflow_push_be32(mf, arp_tha[2], 0);
672 miniflow_push_be32(mf, tcp_flags,
673 TCP_FLAGS_BE32(tcp->tcp_ctl));
674 miniflow_push_be16(mf, tp_src, tcp->tcp_src);
675 miniflow_push_be16(mf, tp_dst, tcp->tcp_dst);
676 miniflow_pad_to_64(mf, igmp_group_ip4);
678 } else if (OVS_LIKELY(nw_proto == IPPROTO_UDP)) {
679 if (OVS_LIKELY(size >= UDP_HEADER_LEN)) {
680 const struct udp_header *udp = data;
682 miniflow_push_be16(mf, tp_src, udp->udp_src);
683 miniflow_push_be16(mf, tp_dst, udp->udp_dst);
684 miniflow_pad_to_64(mf, igmp_group_ip4);
686 } else if (OVS_LIKELY(nw_proto == IPPROTO_SCTP)) {
687 if (OVS_LIKELY(size >= SCTP_HEADER_LEN)) {
688 const struct sctp_header *sctp = data;
690 miniflow_push_be16(mf, tp_src, sctp->sctp_src);
691 miniflow_push_be16(mf, tp_dst, sctp->sctp_dst);
692 miniflow_pad_to_64(mf, igmp_group_ip4);
694 } else if (OVS_LIKELY(nw_proto == IPPROTO_ICMP)) {
695 if (OVS_LIKELY(size >= ICMP_HEADER_LEN)) {
696 const struct icmp_header *icmp = data;
698 miniflow_push_be16(mf, tp_src, htons(icmp->icmp_type));
699 miniflow_push_be16(mf, tp_dst, htons(icmp->icmp_code));
700 miniflow_pad_to_64(mf, igmp_group_ip4);
702 } else if (OVS_LIKELY(nw_proto == IPPROTO_IGMP)) {
703 if (OVS_LIKELY(size >= IGMP_HEADER_LEN)) {
704 const struct igmp_header *igmp = data;
706 miniflow_push_be16(mf, tp_src, htons(igmp->igmp_type));
707 miniflow_push_be16(mf, tp_dst, htons(igmp->igmp_code));
708 miniflow_push_be32(mf, igmp_group_ip4,
709 get_16aligned_be32(&igmp->group));
711 } else if (OVS_LIKELY(nw_proto == IPPROTO_ICMPV6)) {
712 if (OVS_LIKELY(size >= sizeof(struct icmp6_hdr))) {
713 const struct in6_addr *nd_target = NULL;
714 uint8_t arp_buf[2][ETH_ADDR_LEN];
715 const struct icmp6_hdr *icmp = data_pull(&data, &size,
717 memset(arp_buf, 0, sizeof arp_buf);
718 if (OVS_LIKELY(parse_icmpv6(&data, &size, icmp, &nd_target,
721 miniflow_push_words(mf, nd_target, nd_target,
722 sizeof *nd_target / 8);
724 miniflow_push_macs(mf, arp_sha, arp_buf);
725 miniflow_pad_to_64(mf, tcp_flags);
726 miniflow_push_be16(mf, tp_src, htons(icmp->icmp6_type));
727 miniflow_push_be16(mf, tp_dst, htons(icmp->icmp6_code));
728 miniflow_pad_to_64(mf, igmp_group_ip4);
737 /* For every bit of a field that is wildcarded in 'wildcards', sets the
738 * corresponding bit in 'flow' to zero. */
740 flow_zero_wildcards(struct flow *flow, const struct flow_wildcards *wildcards)
742 uint64_t *flow_u64 = (uint64_t *) flow;
743 const uint64_t *wc_u64 = (const uint64_t *) &wildcards->masks;
746 for (i = 0; i < FLOW_U64S; i++) {
747 flow_u64[i] &= wc_u64[i];
752 flow_unwildcard_tp_ports(const struct flow *flow, struct flow_wildcards *wc)
754 if (flow->nw_proto != IPPROTO_ICMP) {
755 memset(&wc->masks.tp_src, 0xff, sizeof wc->masks.tp_src);
756 memset(&wc->masks.tp_dst, 0xff, sizeof wc->masks.tp_dst);
758 wc->masks.tp_src = htons(0xff);
759 wc->masks.tp_dst = htons(0xff);
763 /* Initializes 'flow_metadata' with the metadata found in 'flow'. */
765 flow_get_metadata(const struct flow *flow, struct match *flow_metadata)
769 BUILD_ASSERT_DECL(FLOW_WC_SEQ == 31);
771 match_init_catchall(flow_metadata);
772 if (flow->tunnel.tun_id != htonll(0)) {
773 match_set_tun_id(flow_metadata, flow->tunnel.tun_id);
775 if (flow->tunnel.ip_src != htonl(0)) {
776 match_set_tun_src(flow_metadata, flow->tunnel.ip_src);
778 if (flow->tunnel.ip_dst != htonl(0)) {
779 match_set_tun_dst(flow_metadata, flow->tunnel.ip_dst);
781 if (flow->tunnel.gbp_id != htons(0)) {
782 match_set_tun_gbp_id(flow_metadata, flow->tunnel.gbp_id);
784 if (flow->tunnel.gbp_flags) {
785 match_set_tun_gbp_flags(flow_metadata, flow->tunnel.gbp_flags);
787 if (flow->metadata != htonll(0)) {
788 match_set_metadata(flow_metadata, flow->metadata);
791 for (i = 0; i < FLOW_N_REGS; i++) {
793 match_set_reg(flow_metadata, i, flow->regs[i]);
797 if (flow->pkt_mark != 0) {
798 match_set_pkt_mark(flow_metadata, flow->pkt_mark);
801 match_set_in_port(flow_metadata, flow->in_port.ofp_port);
805 flow_to_string(const struct flow *flow)
807 struct ds ds = DS_EMPTY_INITIALIZER;
808 flow_format(&ds, flow);
813 flow_tun_flag_to_string(uint32_t flags)
816 case FLOW_TNL_F_DONT_FRAGMENT:
818 case FLOW_TNL_F_CSUM:
830 format_flags(struct ds *ds, const char *(*bit_to_string)(uint32_t),
831 uint32_t flags, char del)
839 uint32_t bit = rightmost_1bit(flags);
842 s = bit_to_string(bit);
844 ds_put_format(ds, "%s%c", s, del);
853 ds_put_format(ds, "0x%"PRIx32"%c", bad, del);
859 format_flags_masked(struct ds *ds, const char *name,
860 const char *(*bit_to_string)(uint32_t), uint32_t flags,
864 ds_put_format(ds, "%s=", name);
867 uint32_t bit = rightmost_1bit(mask);
868 const char *s = bit_to_string(bit);
870 ds_put_format(ds, "%s%s", (flags & bit) ? "+" : "-",
871 s ? s : "[Unknown]");
877 flow_format(struct ds *ds, const struct flow *flow)
880 struct flow_wildcards *wc = &match.wc;
882 match_wc_init(&match, flow);
884 /* As this function is most often used for formatting a packet in a
885 * packet-in message, skip formatting the packet context fields that are
886 * all-zeroes to make the print-out easier on the eyes. This means that a
887 * missing context field implies a zero value for that field. This is
888 * similar to OpenFlow encoding of these fields, as the specification
889 * states that all-zeroes context fields should not be encoded in the
890 * packet-in messages. */
891 if (!flow->in_port.ofp_port) {
892 WC_UNMASK_FIELD(wc, in_port);
894 if (!flow->skb_priority) {
895 WC_UNMASK_FIELD(wc, skb_priority);
897 if (!flow->pkt_mark) {
898 WC_UNMASK_FIELD(wc, pkt_mark);
900 if (!flow->recirc_id) {
901 WC_UNMASK_FIELD(wc, recirc_id);
903 if (!flow->dp_hash) {
904 WC_UNMASK_FIELD(wc, dp_hash);
906 for (int i = 0; i < FLOW_N_REGS; i++) {
907 if (!flow->regs[i]) {
908 WC_UNMASK_FIELD(wc, regs[i]);
911 if (!flow->metadata) {
912 WC_UNMASK_FIELD(wc, metadata);
915 match_format(&match, ds, OFP_DEFAULT_PRIORITY);
919 flow_print(FILE *stream, const struct flow *flow)
921 char *s = flow_to_string(flow);
926 /* flow_wildcards functions. */
928 /* Initializes 'wc' as a set of wildcards that matches every packet. */
930 flow_wildcards_init_catchall(struct flow_wildcards *wc)
932 memset(&wc->masks, 0, sizeof wc->masks);
935 /* Converts a flow into flow wildcards. It sets the wildcard masks based on
936 * the packet headers extracted to 'flow'. It will not set the mask for fields
937 * that do not make sense for the packet type. OpenFlow-only metadata is
938 * wildcarded, but other metadata is unconditionally exact-matched. */
939 void flow_wildcards_init_for_packet(struct flow_wildcards *wc,
940 const struct flow *flow)
942 memset(&wc->masks, 0x0, sizeof wc->masks);
944 /* Update this function whenever struct flow changes. */
945 BUILD_ASSERT_DECL(FLOW_WC_SEQ == 31);
947 if (flow->tunnel.ip_dst) {
948 if (flow->tunnel.flags & FLOW_TNL_F_KEY) {
949 WC_MASK_FIELD(wc, tunnel.tun_id);
951 WC_MASK_FIELD(wc, tunnel.ip_src);
952 WC_MASK_FIELD(wc, tunnel.ip_dst);
953 WC_MASK_FIELD(wc, tunnel.flags);
954 WC_MASK_FIELD(wc, tunnel.ip_tos);
955 WC_MASK_FIELD(wc, tunnel.ip_ttl);
956 WC_MASK_FIELD(wc, tunnel.tp_src);
957 WC_MASK_FIELD(wc, tunnel.tp_dst);
958 WC_MASK_FIELD(wc, tunnel.gbp_id);
959 WC_MASK_FIELD(wc, tunnel.gbp_flags);
960 } else if (flow->tunnel.tun_id) {
961 WC_MASK_FIELD(wc, tunnel.tun_id);
964 /* metadata, regs, and conj_id wildcarded. */
966 WC_MASK_FIELD(wc, skb_priority);
967 WC_MASK_FIELD(wc, pkt_mark);
968 WC_MASK_FIELD(wc, recirc_id);
969 WC_MASK_FIELD(wc, dp_hash);
970 WC_MASK_FIELD(wc, in_port);
972 /* actset_output wildcarded. */
974 WC_MASK_FIELD(wc, dl_dst);
975 WC_MASK_FIELD(wc, dl_src);
976 WC_MASK_FIELD(wc, dl_type);
977 WC_MASK_FIELD(wc, vlan_tci);
979 if (flow->dl_type == htons(ETH_TYPE_IP)) {
980 WC_MASK_FIELD(wc, nw_src);
981 WC_MASK_FIELD(wc, nw_dst);
982 } else if (flow->dl_type == htons(ETH_TYPE_IPV6)) {
983 WC_MASK_FIELD(wc, ipv6_src);
984 WC_MASK_FIELD(wc, ipv6_dst);
985 WC_MASK_FIELD(wc, ipv6_label);
986 } else if (flow->dl_type == htons(ETH_TYPE_ARP) ||
987 flow->dl_type == htons(ETH_TYPE_RARP)) {
988 WC_MASK_FIELD(wc, nw_src);
989 WC_MASK_FIELD(wc, nw_dst);
990 WC_MASK_FIELD(wc, nw_proto);
991 WC_MASK_FIELD(wc, arp_sha);
992 WC_MASK_FIELD(wc, arp_tha);
994 } else if (eth_type_mpls(flow->dl_type)) {
995 for (int i = 0; i < FLOW_MAX_MPLS_LABELS; i++) {
996 WC_MASK_FIELD(wc, mpls_lse[i]);
997 if (flow->mpls_lse[i] & htonl(MPLS_BOS_MASK)) {
1003 return; /* Unknown ethertype. */
1007 WC_MASK_FIELD(wc, nw_frag);
1008 WC_MASK_FIELD(wc, nw_tos);
1009 WC_MASK_FIELD(wc, nw_ttl);
1010 WC_MASK_FIELD(wc, nw_proto);
1012 /* No transport layer header in later fragments. */
1013 if (!(flow->nw_frag & FLOW_NW_FRAG_LATER) &&
1014 (flow->nw_proto == IPPROTO_ICMP ||
1015 flow->nw_proto == IPPROTO_ICMPV6 ||
1016 flow->nw_proto == IPPROTO_TCP ||
1017 flow->nw_proto == IPPROTO_UDP ||
1018 flow->nw_proto == IPPROTO_SCTP ||
1019 flow->nw_proto == IPPROTO_IGMP)) {
1020 WC_MASK_FIELD(wc, tp_src);
1021 WC_MASK_FIELD(wc, tp_dst);
1023 if (flow->nw_proto == IPPROTO_TCP) {
1024 WC_MASK_FIELD(wc, tcp_flags);
1025 } else if (flow->nw_proto == IPPROTO_ICMPV6) {
1026 WC_MASK_FIELD(wc, arp_sha);
1027 WC_MASK_FIELD(wc, arp_tha);
1028 WC_MASK_FIELD(wc, nd_target);
1029 } else if (flow->nw_proto == IPPROTO_IGMP) {
1030 WC_MASK_FIELD(wc, igmp_group_ip4);
1035 /* Return a map of possible fields for a packet of the same type as 'flow'.
1036 * Including extra bits in the returned mask is not wrong, it is just less
1039 * This is a less precise version of flow_wildcards_init_for_packet() above. */
1041 flow_wc_map(const struct flow *flow)
1043 /* Update this function whenever struct flow changes. */
1044 BUILD_ASSERT_DECL(FLOW_WC_SEQ == 31);
1046 uint64_t map = (flow->tunnel.ip_dst) ? MINIFLOW_MAP(tunnel) : 0;
1048 /* Metadata fields that can appear on packet input. */
1049 map |= MINIFLOW_MAP(skb_priority) | MINIFLOW_MAP(pkt_mark)
1050 | MINIFLOW_MAP(recirc_id) | MINIFLOW_MAP(dp_hash)
1051 | MINIFLOW_MAP(in_port)
1052 | MINIFLOW_MAP(dl_dst) | MINIFLOW_MAP(dl_src)
1053 | MINIFLOW_MAP(dl_type) | MINIFLOW_MAP(vlan_tci);
1055 /* Ethertype-dependent fields. */
1056 if (OVS_LIKELY(flow->dl_type == htons(ETH_TYPE_IP))) {
1057 map |= MINIFLOW_MAP(nw_src) | MINIFLOW_MAP(nw_dst)
1058 | MINIFLOW_MAP(nw_proto) | MINIFLOW_MAP(nw_frag)
1059 | MINIFLOW_MAP(nw_tos) | MINIFLOW_MAP(nw_ttl);
1060 if (OVS_UNLIKELY(flow->nw_proto == IPPROTO_IGMP)) {
1061 map |= MINIFLOW_MAP(igmp_group_ip4);
1063 map |= MINIFLOW_MAP(tcp_flags)
1064 | MINIFLOW_MAP(tp_src) | MINIFLOW_MAP(tp_dst);
1066 } else if (flow->dl_type == htons(ETH_TYPE_IPV6)) {
1067 map |= MINIFLOW_MAP(ipv6_src) | MINIFLOW_MAP(ipv6_dst)
1068 | MINIFLOW_MAP(ipv6_label)
1069 | MINIFLOW_MAP(nw_proto) | MINIFLOW_MAP(nw_frag)
1070 | MINIFLOW_MAP(nw_tos) | MINIFLOW_MAP(nw_ttl);
1071 if (OVS_UNLIKELY(flow->nw_proto == IPPROTO_ICMPV6)) {
1072 map |= MINIFLOW_MAP(nd_target)
1073 | MINIFLOW_MAP(arp_sha) | MINIFLOW_MAP(arp_tha);
1075 map |= MINIFLOW_MAP(tcp_flags)
1076 | MINIFLOW_MAP(tp_src) | MINIFLOW_MAP(tp_dst);
1078 } else if (eth_type_mpls(flow->dl_type)) {
1079 map |= MINIFLOW_MAP(mpls_lse);
1080 } else if (flow->dl_type == htons(ETH_TYPE_ARP) ||
1081 flow->dl_type == htons(ETH_TYPE_RARP)) {
1082 map |= MINIFLOW_MAP(nw_src) | MINIFLOW_MAP(nw_dst)
1083 | MINIFLOW_MAP(nw_proto)
1084 | MINIFLOW_MAP(arp_sha) | MINIFLOW_MAP(arp_tha);
1090 /* Clear the metadata and register wildcard masks. They are not packet
1093 flow_wildcards_clear_non_packet_fields(struct flow_wildcards *wc)
1095 /* Update this function whenever struct flow changes. */
1096 BUILD_ASSERT_DECL(FLOW_WC_SEQ == 31);
1098 memset(&wc->masks.metadata, 0, sizeof wc->masks.metadata);
1099 memset(&wc->masks.regs, 0, sizeof wc->masks.regs);
1100 wc->masks.actset_output = 0;
1101 wc->masks.conj_id = 0;
1104 /* Returns true if 'wc' matches every packet, false if 'wc' fixes any bits or
1107 flow_wildcards_is_catchall(const struct flow_wildcards *wc)
1109 const uint64_t *wc_u64 = (const uint64_t *) &wc->masks;
1112 for (i = 0; i < FLOW_U64S; i++) {
1120 /* Sets 'dst' as the bitwise AND of wildcards in 'src1' and 'src2'.
1121 * That is, a bit or a field is wildcarded in 'dst' if it is wildcarded
1122 * in 'src1' or 'src2' or both. */
1124 flow_wildcards_and(struct flow_wildcards *dst,
1125 const struct flow_wildcards *src1,
1126 const struct flow_wildcards *src2)
1128 uint64_t *dst_u64 = (uint64_t *) &dst->masks;
1129 const uint64_t *src1_u64 = (const uint64_t *) &src1->masks;
1130 const uint64_t *src2_u64 = (const uint64_t *) &src2->masks;
1133 for (i = 0; i < FLOW_U64S; i++) {
1134 dst_u64[i] = src1_u64[i] & src2_u64[i];
1138 /* Sets 'dst' as the bitwise OR of wildcards in 'src1' and 'src2'. That
1139 * is, a bit or a field is wildcarded in 'dst' if it is neither
1140 * wildcarded in 'src1' nor 'src2'. */
1142 flow_wildcards_or(struct flow_wildcards *dst,
1143 const struct flow_wildcards *src1,
1144 const struct flow_wildcards *src2)
1146 uint64_t *dst_u64 = (uint64_t *) &dst->masks;
1147 const uint64_t *src1_u64 = (const uint64_t *) &src1->masks;
1148 const uint64_t *src2_u64 = (const uint64_t *) &src2->masks;
1151 for (i = 0; i < FLOW_U64S; i++) {
1152 dst_u64[i] = src1_u64[i] | src2_u64[i];
1156 /* Returns a hash of the wildcards in 'wc'. */
1158 flow_wildcards_hash(const struct flow_wildcards *wc, uint32_t basis)
1160 return flow_hash(&wc->masks, basis);
1163 /* Returns true if 'a' and 'b' represent the same wildcards, false if they are
1166 flow_wildcards_equal(const struct flow_wildcards *a,
1167 const struct flow_wildcards *b)
1169 return flow_equal(&a->masks, &b->masks);
1172 /* Returns true if at least one bit or field is wildcarded in 'a' but not in
1173 * 'b', false otherwise. */
1175 flow_wildcards_has_extra(const struct flow_wildcards *a,
1176 const struct flow_wildcards *b)
1178 const uint64_t *a_u64 = (const uint64_t *) &a->masks;
1179 const uint64_t *b_u64 = (const uint64_t *) &b->masks;
1182 for (i = 0; i < FLOW_U64S; i++) {
1183 if ((a_u64[i] & b_u64[i]) != b_u64[i]) {
1190 /* Returns true if 'a' and 'b' are equal, except that 0-bits (wildcarded bits)
1191 * in 'wc' do not need to be equal in 'a' and 'b'. */
1193 flow_equal_except(const struct flow *a, const struct flow *b,
1194 const struct flow_wildcards *wc)
1196 const uint64_t *a_u64 = (const uint64_t *) a;
1197 const uint64_t *b_u64 = (const uint64_t *) b;
1198 const uint64_t *wc_u64 = (const uint64_t *) &wc->masks;
1201 for (i = 0; i < FLOW_U64S; i++) {
1202 if ((a_u64[i] ^ b_u64[i]) & wc_u64[i]) {
1209 /* Sets the wildcard mask for register 'idx' in 'wc' to 'mask'.
1210 * (A 0-bit indicates a wildcard bit.) */
1212 flow_wildcards_set_reg_mask(struct flow_wildcards *wc, int idx, uint32_t mask)
1214 wc->masks.regs[idx] = mask;
1217 /* Sets the wildcard mask for register 'idx' in 'wc' to 'mask'.
1218 * (A 0-bit indicates a wildcard bit.) */
1220 flow_wildcards_set_xreg_mask(struct flow_wildcards *wc, int idx, uint64_t mask)
1222 flow_set_xreg(&wc->masks, idx, mask);
1225 /* Calculates the 5-tuple hash from the given miniflow.
1226 * This returns the same value as flow_hash_5tuple for the corresponding
1229 miniflow_hash_5tuple(const struct miniflow *flow, uint32_t basis)
1231 uint32_t hash = basis;
1234 ovs_be16 dl_type = MINIFLOW_GET_BE16(flow, dl_type);
1236 hash = hash_add(hash, MINIFLOW_GET_U8(flow, nw_proto));
1238 /* Separate loops for better optimization. */
1239 if (dl_type == htons(ETH_TYPE_IPV6)) {
1240 uint64_t map = MINIFLOW_MAP(ipv6_src) | MINIFLOW_MAP(ipv6_dst);
1243 MINIFLOW_FOR_EACH_IN_MAP(value, flow, map) {
1244 hash = hash_add64(hash, value);
1247 hash = hash_add(hash, MINIFLOW_GET_U32(flow, nw_src));
1248 hash = hash_add(hash, MINIFLOW_GET_U32(flow, nw_dst));
1250 /* Add both ports at once. */
1251 hash = hash_add(hash, MINIFLOW_GET_U32(flow, tp_src));
1252 hash = hash_finish(hash, 42); /* Arbitrary number. */
1257 ASSERT_SEQUENTIAL_SAME_WORD(tp_src, tp_dst);
1258 ASSERT_SEQUENTIAL(ipv6_src, ipv6_dst);
1260 /* Calculates the 5-tuple hash from the given flow. */
1262 flow_hash_5tuple(const struct flow *flow, uint32_t basis)
1264 uint32_t hash = basis;
1267 hash = hash_add(hash, flow->nw_proto);
1269 if (flow->dl_type == htons(ETH_TYPE_IPV6)) {
1270 const uint64_t *flow_u64 = (const uint64_t *)flow;
1271 int ofs = offsetof(struct flow, ipv6_src) / 8;
1272 int end = ofs + 2 * sizeof flow->ipv6_src / 8;
1274 for (;ofs < end; ofs++) {
1275 hash = hash_add64(hash, flow_u64[ofs]);
1278 hash = hash_add(hash, (OVS_FORCE uint32_t) flow->nw_src);
1279 hash = hash_add(hash, (OVS_FORCE uint32_t) flow->nw_dst);
1281 /* Add both ports at once. */
1282 hash = hash_add(hash,
1283 ((const uint32_t *)flow)[offsetof(struct flow, tp_src)
1284 / sizeof(uint32_t)]);
1285 hash = hash_finish(hash, 42); /* Arbitrary number. */
1290 /* Hashes 'flow' based on its L2 through L4 protocol information. */
1292 flow_hash_symmetric_l4(const struct flow *flow, uint32_t basis)
1297 struct in6_addr ipv6_addr;
1302 uint8_t eth_addr[ETH_ADDR_LEN];
1308 memset(&fields, 0, sizeof fields);
1309 for (i = 0; i < ETH_ADDR_LEN; i++) {
1310 fields.eth_addr[i] = flow->dl_src[i] ^ flow->dl_dst[i];
1312 fields.vlan_tci = flow->vlan_tci & htons(VLAN_VID_MASK);
1313 fields.eth_type = flow->dl_type;
1315 /* UDP source and destination port are not taken into account because they
1316 * will not necessarily be symmetric in a bidirectional flow. */
1317 if (fields.eth_type == htons(ETH_TYPE_IP)) {
1318 fields.ipv4_addr = flow->nw_src ^ flow->nw_dst;
1319 fields.ip_proto = flow->nw_proto;
1320 if (fields.ip_proto == IPPROTO_TCP || fields.ip_proto == IPPROTO_SCTP) {
1321 fields.tp_port = flow->tp_src ^ flow->tp_dst;
1323 } else if (fields.eth_type == htons(ETH_TYPE_IPV6)) {
1324 const uint8_t *a = &flow->ipv6_src.s6_addr[0];
1325 const uint8_t *b = &flow->ipv6_dst.s6_addr[0];
1326 uint8_t *ipv6_addr = &fields.ipv6_addr.s6_addr[0];
1328 for (i=0; i<16; i++) {
1329 ipv6_addr[i] = a[i] ^ b[i];
1331 fields.ip_proto = flow->nw_proto;
1332 if (fields.ip_proto == IPPROTO_TCP || fields.ip_proto == IPPROTO_SCTP) {
1333 fields.tp_port = flow->tp_src ^ flow->tp_dst;
1336 return jhash_bytes(&fields, sizeof fields, basis);
1339 /* Initialize a flow with random fields that matter for nx_hash_fields. */
1341 flow_random_hash_fields(struct flow *flow)
1343 uint16_t rnd = random_uint16();
1345 /* Initialize to all zeros. */
1346 memset(flow, 0, sizeof *flow);
1348 eth_addr_random(flow->dl_src);
1349 eth_addr_random(flow->dl_dst);
1351 flow->vlan_tci = (OVS_FORCE ovs_be16) (random_uint16() & VLAN_VID_MASK);
1353 /* Make most of the random flows IPv4, some IPv6, and rest random. */
1354 flow->dl_type = rnd < 0x8000 ? htons(ETH_TYPE_IP) :
1355 rnd < 0xc000 ? htons(ETH_TYPE_IPV6) : (OVS_FORCE ovs_be16)rnd;
1357 if (dl_type_is_ip_any(flow->dl_type)) {
1358 if (flow->dl_type == htons(ETH_TYPE_IP)) {
1359 flow->nw_src = (OVS_FORCE ovs_be32)random_uint32();
1360 flow->nw_dst = (OVS_FORCE ovs_be32)random_uint32();
1362 random_bytes(&flow->ipv6_src, sizeof flow->ipv6_src);
1363 random_bytes(&flow->ipv6_dst, sizeof flow->ipv6_dst);
1365 /* Make most of IP flows TCP, some UDP or SCTP, and rest random. */
1366 rnd = random_uint16();
1367 flow->nw_proto = rnd < 0x8000 ? IPPROTO_TCP :
1368 rnd < 0xc000 ? IPPROTO_UDP :
1369 rnd < 0xd000 ? IPPROTO_SCTP : (uint8_t)rnd;
1370 if (flow->nw_proto == IPPROTO_TCP ||
1371 flow->nw_proto == IPPROTO_UDP ||
1372 flow->nw_proto == IPPROTO_SCTP) {
1373 flow->tp_src = (OVS_FORCE ovs_be16)random_uint16();
1374 flow->tp_dst = (OVS_FORCE ovs_be16)random_uint16();
1379 /* Masks the fields in 'wc' that are used by the flow hash 'fields'. */
1381 flow_mask_hash_fields(const struct flow *flow, struct flow_wildcards *wc,
1382 enum nx_hash_fields fields)
1385 case NX_HASH_FIELDS_ETH_SRC:
1386 memset(&wc->masks.dl_src, 0xff, sizeof wc->masks.dl_src);
1389 case NX_HASH_FIELDS_SYMMETRIC_L4:
1390 memset(&wc->masks.dl_src, 0xff, sizeof wc->masks.dl_src);
1391 memset(&wc->masks.dl_dst, 0xff, sizeof wc->masks.dl_dst);
1392 if (flow->dl_type == htons(ETH_TYPE_IP)) {
1393 memset(&wc->masks.nw_src, 0xff, sizeof wc->masks.nw_src);
1394 memset(&wc->masks.nw_dst, 0xff, sizeof wc->masks.nw_dst);
1395 } else if (flow->dl_type == htons(ETH_TYPE_IPV6)) {
1396 memset(&wc->masks.ipv6_src, 0xff, sizeof wc->masks.ipv6_src);
1397 memset(&wc->masks.ipv6_dst, 0xff, sizeof wc->masks.ipv6_dst);
1399 if (is_ip_any(flow)) {
1400 memset(&wc->masks.nw_proto, 0xff, sizeof wc->masks.nw_proto);
1401 flow_unwildcard_tp_ports(flow, wc);
1403 wc->masks.vlan_tci |= htons(VLAN_VID_MASK | VLAN_CFI);
1411 /* Hashes the portions of 'flow' designated by 'fields'. */
1413 flow_hash_fields(const struct flow *flow, enum nx_hash_fields fields,
1418 case NX_HASH_FIELDS_ETH_SRC:
1419 return jhash_bytes(flow->dl_src, sizeof flow->dl_src, basis);
1421 case NX_HASH_FIELDS_SYMMETRIC_L4:
1422 return flow_hash_symmetric_l4(flow, basis);
1428 /* Returns a string representation of 'fields'. */
1430 flow_hash_fields_to_str(enum nx_hash_fields fields)
1433 case NX_HASH_FIELDS_ETH_SRC: return "eth_src";
1434 case NX_HASH_FIELDS_SYMMETRIC_L4: return "symmetric_l4";
1435 default: return "<unknown>";
1439 /* Returns true if the value of 'fields' is supported. Otherwise false. */
1441 flow_hash_fields_valid(enum nx_hash_fields fields)
1443 return fields == NX_HASH_FIELDS_ETH_SRC
1444 || fields == NX_HASH_FIELDS_SYMMETRIC_L4;
1447 /* Returns a hash value for the bits of 'flow' that are active based on
1448 * 'wc', given 'basis'. */
1450 flow_hash_in_wildcards(const struct flow *flow,
1451 const struct flow_wildcards *wc, uint32_t basis)
1453 const uint64_t *wc_u64 = (const uint64_t *) &wc->masks;
1454 const uint64_t *flow_u64 = (const uint64_t *) flow;
1459 for (i = 0; i < FLOW_U64S; i++) {
1460 hash = hash_add64(hash, flow_u64[i] & wc_u64[i]);
1462 return hash_finish(hash, 8 * FLOW_U64S);
1465 /* Sets the VLAN VID that 'flow' matches to 'vid', which is interpreted as an
1466 * OpenFlow 1.0 "dl_vlan" value:
1468 * - If it is in the range 0...4095, 'flow->vlan_tci' is set to match
1469 * that VLAN. Any existing PCP match is unchanged (it becomes 0 if
1470 * 'flow' previously matched packets without a VLAN header).
1472 * - If it is OFP_VLAN_NONE, 'flow->vlan_tci' is set to match a packet
1473 * without a VLAN tag.
1475 * - Other values of 'vid' should not be used. */
1477 flow_set_dl_vlan(struct flow *flow, ovs_be16 vid)
1479 if (vid == htons(OFP10_VLAN_NONE)) {
1480 flow->vlan_tci = htons(0);
1482 vid &= htons(VLAN_VID_MASK);
1483 flow->vlan_tci &= ~htons(VLAN_VID_MASK);
1484 flow->vlan_tci |= htons(VLAN_CFI) | vid;
1488 /* Sets the VLAN VID that 'flow' matches to 'vid', which is interpreted as an
1489 * OpenFlow 1.2 "vlan_vid" value, that is, the low 13 bits of 'vlan_tci' (VID
1492 flow_set_vlan_vid(struct flow *flow, ovs_be16 vid)
1494 ovs_be16 mask = htons(VLAN_VID_MASK | VLAN_CFI);
1495 flow->vlan_tci &= ~mask;
1496 flow->vlan_tci |= vid & mask;
1499 /* Sets the VLAN PCP that 'flow' matches to 'pcp', which should be in the
1502 * This function has no effect on the VLAN ID that 'flow' matches.
1504 * After calling this function, 'flow' will not match packets without a VLAN
1507 flow_set_vlan_pcp(struct flow *flow, uint8_t pcp)
1510 flow->vlan_tci &= ~htons(VLAN_PCP_MASK);
1511 flow->vlan_tci |= htons((pcp << VLAN_PCP_SHIFT) | VLAN_CFI);
1514 /* Returns the number of MPLS LSEs present in 'flow'
1516 * Returns 0 if the 'dl_type' of 'flow' is not an MPLS ethernet type.
1517 * Otherwise traverses 'flow''s MPLS label stack stopping at the
1518 * first entry that has the BoS bit set. If no such entry exists then
1519 * the maximum number of LSEs that can be stored in 'flow' is returned.
1522 flow_count_mpls_labels(const struct flow *flow, struct flow_wildcards *wc)
1524 /* dl_type is always masked. */
1525 if (eth_type_mpls(flow->dl_type)) {
1530 for (i = 0; i < FLOW_MAX_MPLS_LABELS; i++) {
1532 wc->masks.mpls_lse[i] |= htonl(MPLS_BOS_MASK);
1534 if (flow->mpls_lse[i] & htonl(MPLS_BOS_MASK)) {
1537 if (flow->mpls_lse[i]) {
1547 /* Returns the number consecutive of MPLS LSEs, starting at the
1548 * innermost LSE, that are common in 'a' and 'b'.
1550 * 'an' must be flow_count_mpls_labels(a).
1551 * 'bn' must be flow_count_mpls_labels(b).
1554 flow_count_common_mpls_labels(const struct flow *a, int an,
1555 const struct flow *b, int bn,
1556 struct flow_wildcards *wc)
1558 int min_n = MIN(an, bn);
1563 int a_last = an - 1;
1564 int b_last = bn - 1;
1567 for (i = 0; i < min_n; i++) {
1569 wc->masks.mpls_lse[a_last - i] = OVS_BE32_MAX;
1570 wc->masks.mpls_lse[b_last - i] = OVS_BE32_MAX;
1572 if (a->mpls_lse[a_last - i] != b->mpls_lse[b_last - i]) {
1583 /* Adds a new outermost MPLS label to 'flow' and changes 'flow''s Ethernet type
1584 * to 'mpls_eth_type', which must be an MPLS Ethertype.
1586 * If the new label is the first MPLS label in 'flow', it is generated as;
1588 * - label: 2, if 'flow' is IPv6, otherwise 0.
1590 * - TTL: IPv4 or IPv6 TTL, if present and nonzero, otherwise 64.
1592 * - TC: IPv4 or IPv6 TOS, if present, otherwise 0.
1596 * If the new label is the second or later label MPLS label in 'flow', it is
1599 * - label: Copied from outer label.
1601 * - TTL: Copied from outer label.
1603 * - TC: Copied from outer label.
1607 * 'n' must be flow_count_mpls_labels(flow). 'n' must be less than
1608 * FLOW_MAX_MPLS_LABELS (because otherwise flow->mpls_lse[] would overflow).
1611 flow_push_mpls(struct flow *flow, int n, ovs_be16 mpls_eth_type,
1612 struct flow_wildcards *wc)
1614 ovs_assert(eth_type_mpls(mpls_eth_type));
1615 ovs_assert(n < FLOW_MAX_MPLS_LABELS);
1621 memset(&wc->masks.mpls_lse, 0xff, sizeof *wc->masks.mpls_lse * n);
1623 for (i = n; i >= 1; i--) {
1624 flow->mpls_lse[i] = flow->mpls_lse[i - 1];
1626 flow->mpls_lse[0] = (flow->mpls_lse[1] & htonl(~MPLS_BOS_MASK));
1628 int label = 0; /* IPv4 Explicit Null. */
1632 if (flow->dl_type == htons(ETH_TYPE_IPV6)) {
1636 if (is_ip_any(flow)) {
1637 tc = (flow->nw_tos & IP_DSCP_MASK) >> 2;
1639 wc->masks.nw_tos |= IP_DSCP_MASK;
1640 wc->masks.nw_ttl = 0xff;
1648 flow->mpls_lse[0] = set_mpls_lse_values(ttl, tc, 1, htonl(label));
1650 /* Clear all L3 and L4 fields and dp_hash. */
1651 BUILD_ASSERT(FLOW_WC_SEQ == 31);
1652 memset((char *) flow + FLOW_SEGMENT_2_ENDS_AT, 0,
1653 sizeof(struct flow) - FLOW_SEGMENT_2_ENDS_AT);
1656 flow->dl_type = mpls_eth_type;
1659 /* Tries to remove the outermost MPLS label from 'flow'. Returns true if
1660 * successful, false otherwise. On success, sets 'flow''s Ethernet type to
1663 * 'n' must be flow_count_mpls_labels(flow). */
1665 flow_pop_mpls(struct flow *flow, int n, ovs_be16 eth_type,
1666 struct flow_wildcards *wc)
1671 /* Nothing to pop. */
1673 } else if (n == FLOW_MAX_MPLS_LABELS) {
1675 wc->masks.mpls_lse[n - 1] |= htonl(MPLS_BOS_MASK);
1677 if (!(flow->mpls_lse[n - 1] & htonl(MPLS_BOS_MASK))) {
1678 /* Can't pop because don't know what to fill in mpls_lse[n - 1]. */
1684 memset(&wc->masks.mpls_lse[1], 0xff,
1685 sizeof *wc->masks.mpls_lse * (n - 1));
1687 for (i = 1; i < n; i++) {
1688 flow->mpls_lse[i - 1] = flow->mpls_lse[i];
1690 flow->mpls_lse[n - 1] = 0;
1691 flow->dl_type = eth_type;
1695 /* Sets the MPLS Label that 'flow' matches to 'label', which is interpreted
1696 * as an OpenFlow 1.1 "mpls_label" value. */
1698 flow_set_mpls_label(struct flow *flow, int idx, ovs_be32 label)
1700 set_mpls_lse_label(&flow->mpls_lse[idx], label);
1703 /* Sets the MPLS TTL that 'flow' matches to 'ttl', which should be in the
1706 flow_set_mpls_ttl(struct flow *flow, int idx, uint8_t ttl)
1708 set_mpls_lse_ttl(&flow->mpls_lse[idx], ttl);
1711 /* Sets the MPLS TC that 'flow' matches to 'tc', which should be in the
1714 flow_set_mpls_tc(struct flow *flow, int idx, uint8_t tc)
1716 set_mpls_lse_tc(&flow->mpls_lse[idx], tc);
1719 /* Sets the MPLS BOS bit that 'flow' matches to which should be 0 or 1. */
1721 flow_set_mpls_bos(struct flow *flow, int idx, uint8_t bos)
1723 set_mpls_lse_bos(&flow->mpls_lse[idx], bos);
1726 /* Sets the entire MPLS LSE. */
1728 flow_set_mpls_lse(struct flow *flow, int idx, ovs_be32 lse)
1730 flow->mpls_lse[idx] = lse;
1734 flow_compose_l4(struct dp_packet *p, const struct flow *flow)
1738 if (!(flow->nw_frag & FLOW_NW_FRAG_ANY)
1739 || !(flow->nw_frag & FLOW_NW_FRAG_LATER)) {
1740 if (flow->nw_proto == IPPROTO_TCP) {
1741 struct tcp_header *tcp;
1743 l4_len = sizeof *tcp;
1744 tcp = dp_packet_put_zeros(p, l4_len);
1745 tcp->tcp_src = flow->tp_src;
1746 tcp->tcp_dst = flow->tp_dst;
1747 tcp->tcp_ctl = TCP_CTL(ntohs(flow->tcp_flags), 5);
1748 } else if (flow->nw_proto == IPPROTO_UDP) {
1749 struct udp_header *udp;
1751 l4_len = sizeof *udp;
1752 udp = dp_packet_put_zeros(p, l4_len);
1753 udp->udp_src = flow->tp_src;
1754 udp->udp_dst = flow->tp_dst;
1755 } else if (flow->nw_proto == IPPROTO_SCTP) {
1756 struct sctp_header *sctp;
1758 l4_len = sizeof *sctp;
1759 sctp = dp_packet_put_zeros(p, l4_len);
1760 sctp->sctp_src = flow->tp_src;
1761 sctp->sctp_dst = flow->tp_dst;
1762 } else if (flow->nw_proto == IPPROTO_ICMP) {
1763 struct icmp_header *icmp;
1765 l4_len = sizeof *icmp;
1766 icmp = dp_packet_put_zeros(p, l4_len);
1767 icmp->icmp_type = ntohs(flow->tp_src);
1768 icmp->icmp_code = ntohs(flow->tp_dst);
1769 icmp->icmp_csum = csum(icmp, ICMP_HEADER_LEN);
1770 } else if (flow->nw_proto == IPPROTO_IGMP) {
1771 struct igmp_header *igmp;
1773 l4_len = sizeof *igmp;
1774 igmp = dp_packet_put_zeros(p, l4_len);
1775 igmp->igmp_type = ntohs(flow->tp_src);
1776 igmp->igmp_code = ntohs(flow->tp_dst);
1777 put_16aligned_be32(&igmp->group, flow->igmp_group_ip4);
1778 igmp->igmp_csum = csum(igmp, IGMP_HEADER_LEN);
1779 } else if (flow->nw_proto == IPPROTO_ICMPV6) {
1780 struct icmp6_hdr *icmp;
1782 l4_len = sizeof *icmp;
1783 icmp = dp_packet_put_zeros(p, l4_len);
1784 icmp->icmp6_type = ntohs(flow->tp_src);
1785 icmp->icmp6_code = ntohs(flow->tp_dst);
1787 if (icmp->icmp6_code == 0 &&
1788 (icmp->icmp6_type == ND_NEIGHBOR_SOLICIT ||
1789 icmp->icmp6_type == ND_NEIGHBOR_ADVERT)) {
1790 struct in6_addr *nd_target;
1791 struct nd_opt_hdr *nd_opt;
1793 l4_len += sizeof *nd_target;
1794 nd_target = dp_packet_put_zeros(p, sizeof *nd_target);
1795 *nd_target = flow->nd_target;
1797 if (!eth_addr_is_zero(flow->arp_sha)) {
1799 nd_opt = dp_packet_put_zeros(p, 8);
1800 nd_opt->nd_opt_len = 1;
1801 nd_opt->nd_opt_type = ND_OPT_SOURCE_LINKADDR;
1802 memcpy(nd_opt + 1, flow->arp_sha, ETH_ADDR_LEN);
1804 if (!eth_addr_is_zero(flow->arp_tha)) {
1806 nd_opt = dp_packet_put_zeros(p, 8);
1807 nd_opt->nd_opt_len = 1;
1808 nd_opt->nd_opt_type = ND_OPT_TARGET_LINKADDR;
1809 memcpy(nd_opt + 1, flow->arp_tha, ETH_ADDR_LEN);
1812 icmp->icmp6_cksum = (OVS_FORCE uint16_t)
1813 csum(icmp, (char *)dp_packet_tail(p) - (char *)icmp);
1819 /* Puts into 'b' a packet that flow_extract() would parse as having the given
1822 * (This is useful only for testing, obviously, and the packet isn't really
1823 * valid. It hasn't got some checksums filled in, for one, and lots of fields
1824 * are just zeroed.) */
1826 flow_compose(struct dp_packet *p, const struct flow *flow)
1830 /* eth_compose() sets l3 pointer and makes sure it is 32-bit aligned. */
1831 eth_compose(p, flow->dl_dst, flow->dl_src, ntohs(flow->dl_type), 0);
1832 if (flow->dl_type == htons(FLOW_DL_TYPE_NONE)) {
1833 struct eth_header *eth = dp_packet_l2(p);
1834 eth->eth_type = htons(dp_packet_size(p));
1838 if (flow->vlan_tci & htons(VLAN_CFI)) {
1839 eth_push_vlan(p, htons(ETH_TYPE_VLAN), flow->vlan_tci);
1842 if (flow->dl_type == htons(ETH_TYPE_IP)) {
1843 struct ip_header *ip;
1845 ip = dp_packet_put_zeros(p, sizeof *ip);
1846 ip->ip_ihl_ver = IP_IHL_VER(5, 4);
1847 ip->ip_tos = flow->nw_tos;
1848 ip->ip_ttl = flow->nw_ttl;
1849 ip->ip_proto = flow->nw_proto;
1850 put_16aligned_be32(&ip->ip_src, flow->nw_src);
1851 put_16aligned_be32(&ip->ip_dst, flow->nw_dst);
1853 if (flow->nw_frag & FLOW_NW_FRAG_ANY) {
1854 ip->ip_frag_off |= htons(IP_MORE_FRAGMENTS);
1855 if (flow->nw_frag & FLOW_NW_FRAG_LATER) {
1856 ip->ip_frag_off |= htons(100);
1860 dp_packet_set_l4(p, dp_packet_tail(p));
1862 l4_len = flow_compose_l4(p, flow);
1864 ip = dp_packet_l3(p);
1865 ip->ip_tot_len = htons(p->l4_ofs - p->l3_ofs + l4_len);
1866 ip->ip_csum = csum(ip, sizeof *ip);
1867 } else if (flow->dl_type == htons(ETH_TYPE_IPV6)) {
1868 struct ovs_16aligned_ip6_hdr *nh;
1870 nh = dp_packet_put_zeros(p, sizeof *nh);
1871 put_16aligned_be32(&nh->ip6_flow, htonl(6 << 28) |
1872 htonl(flow->nw_tos << 20) | flow->ipv6_label);
1873 nh->ip6_hlim = flow->nw_ttl;
1874 nh->ip6_nxt = flow->nw_proto;
1876 memcpy(&nh->ip6_src, &flow->ipv6_src, sizeof(nh->ip6_src));
1877 memcpy(&nh->ip6_dst, &flow->ipv6_dst, sizeof(nh->ip6_dst));
1879 dp_packet_set_l4(p, dp_packet_tail(p));
1881 l4_len = flow_compose_l4(p, flow);
1883 nh = dp_packet_l3(p);
1884 nh->ip6_plen = htons(l4_len);
1885 } else if (flow->dl_type == htons(ETH_TYPE_ARP) ||
1886 flow->dl_type == htons(ETH_TYPE_RARP)) {
1887 struct arp_eth_header *arp;
1889 arp = dp_packet_put_zeros(p, sizeof *arp);
1890 dp_packet_set_l3(p, arp);
1891 arp->ar_hrd = htons(1);
1892 arp->ar_pro = htons(ETH_TYPE_IP);
1893 arp->ar_hln = ETH_ADDR_LEN;
1895 arp->ar_op = htons(flow->nw_proto);
1897 if (flow->nw_proto == ARP_OP_REQUEST ||
1898 flow->nw_proto == ARP_OP_REPLY) {
1899 put_16aligned_be32(&arp->ar_spa, flow->nw_src);
1900 put_16aligned_be32(&arp->ar_tpa, flow->nw_dst);
1901 memcpy(arp->ar_sha, flow->arp_sha, ETH_ADDR_LEN);
1902 memcpy(arp->ar_tha, flow->arp_tha, ETH_ADDR_LEN);
1906 if (eth_type_mpls(flow->dl_type)) {
1909 p->l2_5_ofs = p->l3_ofs;
1910 for (n = 1; n < FLOW_MAX_MPLS_LABELS; n++) {
1911 if (flow->mpls_lse[n - 1] & htonl(MPLS_BOS_MASK)) {
1916 push_mpls(p, flow->dl_type, flow->mpls_lse[--n]);
1921 /* Compressed flow. */
1924 miniflow_n_values(const struct miniflow *flow)
1926 return count_1bits(flow->map);
1930 miniflow_alloc_values(struct miniflow *flow, int n)
1932 int size = MINIFLOW_VALUES_SIZE(n);
1934 if (size <= sizeof flow->inline_values) {
1935 flow->values_inline = true;
1936 return flow->inline_values;
1938 COVERAGE_INC(miniflow_malloc);
1939 flow->values_inline = false;
1940 flow->offline_values = xmalloc(size);
1941 return flow->offline_values;
1945 /* Completes an initialization of 'dst' as a miniflow copy of 'src' begun by
1946 * the caller. The caller must have already initialized 'dst->map' properly
1947 * to indicate the significant uint64_t elements of 'src'. 'n' must be the
1948 * number of 1-bits in 'dst->map'.
1950 * Normally the significant elements are the ones that are non-zero. However,
1951 * when a miniflow is initialized from a (mini)mask, the values can be zeroes,
1952 * so that the flow and mask always have the same maps.
1954 * This function initializes values (either inline if possible or with
1955 * malloc() otherwise) and copies the uint64_t elements of 'src' indicated by
1956 * 'dst->map' into it. */
1958 miniflow_init__(struct miniflow *dst, const struct flow *src, int n)
1960 const uint64_t *src_u64 = (const uint64_t *) src;
1961 uint64_t *dst_u64 = miniflow_alloc_values(dst, n);
1964 MAP_FOR_EACH_INDEX(idx, dst->map) {
1965 *dst_u64++ = src_u64[idx];
1969 /* Initializes 'dst' as a copy of 'src'. The caller must eventually free 'dst'
1970 * with miniflow_destroy().
1971 * Always allocates offline storage. */
1973 miniflow_init(struct miniflow *dst, const struct flow *src)
1975 const uint64_t *src_u64 = (const uint64_t *) src;
1979 /* Initialize dst->map, counting the number of nonzero elements. */
1983 for (i = 0; i < FLOW_U64S; i++) {
1985 dst->map |= UINT64_C(1) << i;
1990 miniflow_init__(dst, src, n);
1993 /* Initializes 'dst' as a copy of 'src', using 'mask->map' as 'dst''s map. The
1994 * caller must eventually free 'dst' with miniflow_destroy(). */
1996 miniflow_init_with_minimask(struct miniflow *dst, const struct flow *src,
1997 const struct minimask *mask)
1999 dst->map = mask->masks.map;
2000 miniflow_init__(dst, src, miniflow_n_values(dst));
2003 /* Initializes 'dst' as a copy of 'src'. The caller must eventually free 'dst'
2004 * with miniflow_destroy(). */
2006 miniflow_clone(struct miniflow *dst, const struct miniflow *src)
2008 int size = MINIFLOW_VALUES_SIZE(miniflow_n_values(src));
2011 dst->map = src->map;
2012 if (size <= sizeof dst->inline_values) {
2013 dst->values_inline = true;
2014 values = dst->inline_values;
2016 dst->values_inline = false;
2017 COVERAGE_INC(miniflow_malloc);
2018 dst->offline_values = xmalloc(size);
2019 values = dst->offline_values;
2021 memcpy(values, miniflow_get_values(src), size);
2024 /* Initializes 'dst' as a copy of 'src'. The caller must have allocated
2025 * 'dst' to have inline space all data in 'src'. */
2027 miniflow_clone_inline(struct miniflow *dst, const struct miniflow *src,
2030 dst->values_inline = true;
2031 dst->map = src->map;
2032 memcpy(dst->inline_values, miniflow_get_values(src),
2033 MINIFLOW_VALUES_SIZE(n_values));
2036 /* Initializes 'dst' with the data in 'src', destroying 'src'.
2037 * The caller must eventually free 'dst' with miniflow_destroy().
2038 * 'dst' must be regularly sized miniflow, but 'src' can have
2039 * storage for more than the default MINI_N_INLINE inline
2042 miniflow_move(struct miniflow *dst, struct miniflow *src)
2044 int size = MINIFLOW_VALUES_SIZE(miniflow_n_values(src));
2046 dst->map = src->map;
2047 if (size <= sizeof dst->inline_values) {
2048 dst->values_inline = true;
2049 memcpy(dst->inline_values, miniflow_get_values(src), size);
2050 miniflow_destroy(src);
2051 } else if (src->values_inline) {
2052 dst->values_inline = false;
2053 COVERAGE_INC(miniflow_malloc);
2054 dst->offline_values = xmalloc(size);
2055 memcpy(dst->offline_values, src->inline_values, size);
2057 dst->values_inline = false;
2058 dst->offline_values = src->offline_values;
2062 /* Frees any memory owned by 'flow'. Does not free the storage in which 'flow'
2063 * itself resides; the caller is responsible for that. */
2065 miniflow_destroy(struct miniflow *flow)
2067 if (!flow->values_inline) {
2068 free(flow->offline_values);
2072 /* Initializes 'dst' as a copy of 'src'. */
2074 miniflow_expand(const struct miniflow *src, struct flow *dst)
2076 memset(dst, 0, sizeof *dst);
2077 flow_union_with_miniflow(dst, src);
2080 /* Returns true if 'a' and 'b' are the equal miniflow, false otherwise. */
2082 miniflow_equal(const struct miniflow *a, const struct miniflow *b)
2084 const uint64_t *ap = miniflow_get_values(a);
2085 const uint64_t *bp = miniflow_get_values(b);
2087 if (OVS_LIKELY(a->map == b->map)) {
2088 int count = miniflow_n_values(a);
2090 return !memcmp(ap, bp, count * sizeof *ap);
2094 for (map = a->map | b->map; map; map = zero_rightmost_1bit(map)) {
2095 uint64_t bit = rightmost_1bit(map);
2097 if ((a->map & bit ? *ap++ : 0) != (b->map & bit ? *bp++ : 0)) {
2106 /* Returns false if 'a' and 'b' differ at the places where there are 1-bits
2107 * in 'mask', true otherwise. */
2109 miniflow_equal_in_minimask(const struct miniflow *a, const struct miniflow *b,
2110 const struct minimask *mask)
2112 const uint64_t *p = miniflow_get_values(&mask->masks);
2115 MAP_FOR_EACH_INDEX(idx, mask->masks.map) {
2116 if ((miniflow_get(a, idx) ^ miniflow_get(b, idx)) & *p++) {
2124 /* Returns true if 'a' and 'b' are equal at the places where there are 1-bits
2125 * in 'mask', false if they differ. */
2127 miniflow_equal_flow_in_minimask(const struct miniflow *a, const struct flow *b,
2128 const struct minimask *mask)
2130 const uint64_t *b_u64 = (const uint64_t *) b;
2131 const uint64_t *p = miniflow_get_values(&mask->masks);
2134 MAP_FOR_EACH_INDEX(idx, mask->masks.map) {
2135 if ((miniflow_get(a, idx) ^ b_u64[idx]) & *p++) {
2144 /* Initializes 'dst' as a copy of 'src'. The caller must eventually free 'dst'
2145 * with minimask_destroy(). */
2147 minimask_init(struct minimask *mask, const struct flow_wildcards *wc)
2149 miniflow_init(&mask->masks, &wc->masks);
2152 /* Initializes 'dst' as a copy of 'src'. The caller must eventually free 'dst'
2153 * with minimask_destroy(). */
2155 minimask_clone(struct minimask *dst, const struct minimask *src)
2157 miniflow_clone(&dst->masks, &src->masks);
2160 /* Initializes 'dst' with the data in 'src', destroying 'src'.
2161 * The caller must eventually free 'dst' with minimask_destroy(). */
2163 minimask_move(struct minimask *dst, struct minimask *src)
2165 miniflow_move(&dst->masks, &src->masks);
2168 /* Initializes 'dst_' as the bit-wise "and" of 'a_' and 'b_'.
2170 * The caller must provide room for FLOW_U64S "uint64_t"s in 'storage', for use
2171 * by 'dst_'. The caller must *not* free 'dst_' with minimask_destroy(). */
2173 minimask_combine(struct minimask *dst_,
2174 const struct minimask *a_, const struct minimask *b_,
2175 uint64_t storage[FLOW_U64S])
2177 struct miniflow *dst = &dst_->masks;
2178 uint64_t *dst_values = storage;
2179 const struct miniflow *a = &a_->masks;
2180 const struct miniflow *b = &b_->masks;
2183 dst->values_inline = false;
2184 dst->offline_values = storage;
2187 MAP_FOR_EACH_INDEX(idx, a->map & b->map) {
2188 /* Both 'a' and 'b' have non-zero data at 'idx'. */
2189 uint64_t mask = miniflow_get__(a, idx) & miniflow_get__(b, idx);
2192 dst->map |= UINT64_C(1) << idx;
2193 *dst_values++ = mask;
2198 /* Frees any memory owned by 'mask'. Does not free the storage in which 'mask'
2199 * itself resides; the caller is responsible for that. */
2201 minimask_destroy(struct minimask *mask)
2203 miniflow_destroy(&mask->masks);
2206 /* Initializes 'dst' as a copy of 'src'. */
2208 minimask_expand(const struct minimask *mask, struct flow_wildcards *wc)
2210 miniflow_expand(&mask->masks, &wc->masks);
2213 /* Returns true if 'a' and 'b' are the same flow mask, false otherwise.
2214 * Minimasks may not have zero data values, so for the minimasks to be the
2215 * same, they need to have the same map and the same data values. */
2217 minimask_equal(const struct minimask *a, const struct minimask *b)
2219 return a->masks.map == b->masks.map &&
2220 !memcmp(miniflow_get_values(&a->masks),
2221 miniflow_get_values(&b->masks),
2222 count_1bits(a->masks.map) * sizeof *a->masks.inline_values);
2225 /* Returns true if at least one bit matched by 'b' is wildcarded by 'a',
2226 * false otherwise. */
2228 minimask_has_extra(const struct minimask *a, const struct minimask *b)
2230 const uint64_t *ap = miniflow_get_values(&a->masks);
2231 const uint64_t *bp = miniflow_get_values(&b->masks);
2234 MAP_FOR_EACH_INDEX(idx, b->masks.map) {
2235 uint64_t b_u64 = *bp++;
2237 /* 'b_u64' is non-zero, check if the data in 'a' is either zero
2238 * or misses some of the bits in 'b_u64'. */
2239 if (!(a->masks.map & (UINT64_C(1) << idx))
2240 || ((miniflow_values_get__(ap, a->masks.map, idx) & b_u64)
2242 return true; /* 'a' wildcards some bits 'b' doesn't. */