/* * Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013 Nicira, Inc. * * 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 #include "ofp-print.h" #include #include #include #include #include #include #include #include "bundle.h" #include "byte-order.h" #include "classifier.h" #include "dynamic-string.h" #include "learn.h" #include "meta-flow.h" #include "multipath.h" #include "netdev.h" #include "nx-match.h" #include "ofp-actions.h" #include "ofp-errors.h" #include "ofp-msgs.h" #include "ofp-util.h" #include "ofpbuf.h" #include "packets.h" #include "random.h" #include "unaligned.h" #include "type-props.h" #include "vlog.h" VLOG_DEFINE_THIS_MODULE(ofp_util); /* 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); /* Given the wildcard bit count in the least-significant 6 of 'wcbits', returns * an IP netmask with a 1 in each bit that must match and a 0 in each bit that * is wildcarded. * * The bits in 'wcbits' are in the format used in enum ofp_flow_wildcards: 0 * is exact match, 1 ignores the LSB, 2 ignores the 2 least-significant bits, * ..., 32 and higher wildcard the entire field. This is the *opposite* of the * usual convention where e.g. /24 indicates that 8 bits (not 24 bits) are * wildcarded. */ ovs_be32 ofputil_wcbits_to_netmask(int wcbits) { wcbits &= 0x3f; return wcbits < 32 ? htonl(~((1u << wcbits) - 1)) : 0; } /* Given the IP netmask 'netmask', returns the number of bits of the IP address * that it wildcards, that is, the number of 0-bits in 'netmask', a number * between 0 and 32 inclusive. * * If 'netmask' is not a CIDR netmask (see ip_is_cidr()), the return value will * still be in the valid range but isn't otherwise meaningful. */ int ofputil_netmask_to_wcbits(ovs_be32 netmask) { return 32 - ip_count_cidr_bits(netmask); } /* Converts the OpenFlow 1.0 wildcards in 'ofpfw' (OFPFW10_*) into a * flow_wildcards in 'wc' for use in struct match. It is the caller's * responsibility to handle the special case where the flow match's dl_vlan is * set to OFP_VLAN_NONE. */ void ofputil_wildcard_from_ofpfw10(uint32_t ofpfw, struct flow_wildcards *wc) { BUILD_ASSERT_DECL(FLOW_WC_SEQ == 20); /* Initialize most of wc. */ flow_wildcards_init_catchall(wc); if (!(ofpfw & OFPFW10_IN_PORT)) { wc->masks.in_port.ofp_port = u16_to_ofp(UINT16_MAX); } if (!(ofpfw & OFPFW10_NW_TOS)) { wc->masks.nw_tos |= IP_DSCP_MASK; } if (!(ofpfw & OFPFW10_NW_PROTO)) { wc->masks.nw_proto = UINT8_MAX; } wc->masks.nw_src = ofputil_wcbits_to_netmask(ofpfw >> OFPFW10_NW_SRC_SHIFT); wc->masks.nw_dst = ofputil_wcbits_to_netmask(ofpfw >> OFPFW10_NW_DST_SHIFT); if (!(ofpfw & OFPFW10_TP_SRC)) { wc->masks.tp_src = htons(UINT16_MAX); } if (!(ofpfw & OFPFW10_TP_DST)) { wc->masks.tp_dst = htons(UINT16_MAX); } if (!(ofpfw & OFPFW10_DL_SRC)) { memset(wc->masks.dl_src, 0xff, ETH_ADDR_LEN); } if (!(ofpfw & OFPFW10_DL_DST)) { memset(wc->masks.dl_dst, 0xff, ETH_ADDR_LEN); } if (!(ofpfw & OFPFW10_DL_TYPE)) { wc->masks.dl_type = htons(UINT16_MAX); } /* VLAN TCI mask. */ if (!(ofpfw & OFPFW10_DL_VLAN_PCP)) { wc->masks.vlan_tci |= htons(VLAN_PCP_MASK | VLAN_CFI); } if (!(ofpfw & OFPFW10_DL_VLAN)) { wc->masks.vlan_tci |= htons(VLAN_VID_MASK | VLAN_CFI); } } /* Converts the ofp10_match in 'ofmatch' into a struct match in 'match'. */ void ofputil_match_from_ofp10_match(const struct ofp10_match *ofmatch, struct match *match) { uint32_t ofpfw = ntohl(ofmatch->wildcards) & OFPFW10_ALL; /* Initialize match->wc. */ memset(&match->flow, 0, sizeof match->flow); ofputil_wildcard_from_ofpfw10(ofpfw, &match->wc); /* Initialize most of match->flow. */ match->flow.nw_src = ofmatch->nw_src; match->flow.nw_dst = ofmatch->nw_dst; match->flow.in_port.ofp_port = u16_to_ofp(ntohs(ofmatch->in_port)); match->flow.dl_type = ofputil_dl_type_from_openflow(ofmatch->dl_type); match->flow.tp_src = ofmatch->tp_src; match->flow.tp_dst = ofmatch->tp_dst; memcpy(match->flow.dl_src, ofmatch->dl_src, ETH_ADDR_LEN); memcpy(match->flow.dl_dst, ofmatch->dl_dst, ETH_ADDR_LEN); match->flow.nw_tos = ofmatch->nw_tos & IP_DSCP_MASK; match->flow.nw_proto = ofmatch->nw_proto; /* Translate VLANs. */ if (!(ofpfw & OFPFW10_DL_VLAN) && ofmatch->dl_vlan == htons(OFP10_VLAN_NONE)) { /* Match only packets without 802.1Q header. * * When OFPFW10_DL_VLAN_PCP is wildcarded, this is obviously correct. * * If OFPFW10_DL_VLAN_PCP is matched, the flow match is contradictory, * because we can't have a specific PCP without an 802.1Q header. * However, older versions of OVS treated this as matching packets * withut an 802.1Q header, so we do here too. */ match->flow.vlan_tci = htons(0); match->wc.masks.vlan_tci = htons(0xffff); } else { ovs_be16 vid, pcp, tci; vid = ofmatch->dl_vlan & htons(VLAN_VID_MASK); pcp = htons((ofmatch->dl_vlan_pcp << VLAN_PCP_SHIFT) & VLAN_PCP_MASK); tci = vid | pcp | htons(VLAN_CFI); match->flow.vlan_tci = tci & match->wc.masks.vlan_tci; } /* Clean up. */ match_zero_wildcarded_fields(match); } /* Convert 'match' into the OpenFlow 1.0 match structure 'ofmatch'. */ void ofputil_match_to_ofp10_match(const struct match *match, struct ofp10_match *ofmatch) { const struct flow_wildcards *wc = &match->wc; uint32_t ofpfw; /* Figure out most OpenFlow wildcards. */ ofpfw = 0; if (!wc->masks.in_port.ofp_port) { ofpfw |= OFPFW10_IN_PORT; } if (!wc->masks.dl_type) { ofpfw |= OFPFW10_DL_TYPE; } if (!wc->masks.nw_proto) { ofpfw |= OFPFW10_NW_PROTO; } ofpfw |= (ofputil_netmask_to_wcbits(wc->masks.nw_src) << OFPFW10_NW_SRC_SHIFT); ofpfw |= (ofputil_netmask_to_wcbits(wc->masks.nw_dst) << OFPFW10_NW_DST_SHIFT); if (!(wc->masks.nw_tos & IP_DSCP_MASK)) { ofpfw |= OFPFW10_NW_TOS; } if (!wc->masks.tp_src) { ofpfw |= OFPFW10_TP_SRC; } if (!wc->masks.tp_dst) { ofpfw |= OFPFW10_TP_DST; } if (eth_addr_is_zero(wc->masks.dl_src)) { ofpfw |= OFPFW10_DL_SRC; } if (eth_addr_is_zero(wc->masks.dl_dst)) { ofpfw |= OFPFW10_DL_DST; } /* Translate VLANs. */ ofmatch->dl_vlan = htons(0); ofmatch->dl_vlan_pcp = 0; if (match->wc.masks.vlan_tci == htons(0)) { ofpfw |= OFPFW10_DL_VLAN | OFPFW10_DL_VLAN_PCP; } else if (match->wc.masks.vlan_tci & htons(VLAN_CFI) && !(match->flow.vlan_tci & htons(VLAN_CFI))) { ofmatch->dl_vlan = htons(OFP10_VLAN_NONE); ofpfw |= OFPFW10_DL_VLAN_PCP; } else { if (!(match->wc.masks.vlan_tci & htons(VLAN_VID_MASK))) { ofpfw |= OFPFW10_DL_VLAN; } else { ofmatch->dl_vlan = htons(vlan_tci_to_vid(match->flow.vlan_tci)); } if (!(match->wc.masks.vlan_tci & htons(VLAN_PCP_MASK))) { ofpfw |= OFPFW10_DL_VLAN_PCP; } else { ofmatch->dl_vlan_pcp = vlan_tci_to_pcp(match->flow.vlan_tci); } } /* Compose most of the match structure. */ ofmatch->wildcards = htonl(ofpfw); ofmatch->in_port = htons(ofp_to_u16(match->flow.in_port.ofp_port)); memcpy(ofmatch->dl_src, match->flow.dl_src, ETH_ADDR_LEN); memcpy(ofmatch->dl_dst, match->flow.dl_dst, ETH_ADDR_LEN); ofmatch->dl_type = ofputil_dl_type_to_openflow(match->flow.dl_type); ofmatch->nw_src = match->flow.nw_src; ofmatch->nw_dst = match->flow.nw_dst; ofmatch->nw_tos = match->flow.nw_tos & IP_DSCP_MASK; ofmatch->nw_proto = match->flow.nw_proto; ofmatch->tp_src = match->flow.tp_src; ofmatch->tp_dst = match->flow.tp_dst; memset(ofmatch->pad1, '\0', sizeof ofmatch->pad1); memset(ofmatch->pad2, '\0', sizeof ofmatch->pad2); } enum ofperr ofputil_pull_ofp11_match(struct ofpbuf *buf, struct match *match, uint16_t *padded_match_len) { struct ofp11_match_header *omh = buf->data; uint16_t match_len; if (buf->size < sizeof *omh) { return OFPERR_OFPBMC_BAD_LEN; } match_len = ntohs(omh->length); switch (ntohs(omh->type)) { case OFPMT_STANDARD: { struct ofp11_match *om; if (match_len != sizeof *om || buf->size < sizeof *om) { return OFPERR_OFPBMC_BAD_LEN; } om = ofpbuf_pull(buf, sizeof *om); if (padded_match_len) { *padded_match_len = match_len; } return ofputil_match_from_ofp11_match(om, match); } case OFPMT_OXM: if (padded_match_len) { *padded_match_len = ROUND_UP(match_len, 8); } return oxm_pull_match(buf, match); default: return OFPERR_OFPBMC_BAD_TYPE; } } /* Converts the ofp11_match in 'match' into a struct match in 'match. Returns * 0 if successful, otherwise an OFPERR_* value. */ enum ofperr ofputil_match_from_ofp11_match(const struct ofp11_match *ofmatch, struct match *match) { uint16_t wc = ntohl(ofmatch->wildcards); uint8_t dl_src_mask[ETH_ADDR_LEN]; uint8_t dl_dst_mask[ETH_ADDR_LEN]; bool ipv4, arp, rarp; int i; match_init_catchall(match); if (!(wc & OFPFW11_IN_PORT)) { ofp_port_t ofp_port; enum ofperr error; error = ofputil_port_from_ofp11(ofmatch->in_port, &ofp_port); if (error) { return OFPERR_OFPBMC_BAD_VALUE; } match_set_in_port(match, ofp_port); } for (i = 0; i < ETH_ADDR_LEN; i++) { dl_src_mask[i] = ~ofmatch->dl_src_mask[i]; } match_set_dl_src_masked(match, ofmatch->dl_src, dl_src_mask); for (i = 0; i < ETH_ADDR_LEN; i++) { dl_dst_mask[i] = ~ofmatch->dl_dst_mask[i]; } match_set_dl_dst_masked(match, ofmatch->dl_dst, dl_dst_mask); if (!(wc & OFPFW11_DL_VLAN)) { if (ofmatch->dl_vlan == htons(OFPVID11_NONE)) { /* Match only packets without a VLAN tag. */ match->flow.vlan_tci = htons(0); match->wc.masks.vlan_tci = htons(UINT16_MAX); } else { if (ofmatch->dl_vlan == htons(OFPVID11_ANY)) { /* Match any packet with a VLAN tag regardless of VID. */ match->flow.vlan_tci = htons(VLAN_CFI); match->wc.masks.vlan_tci = htons(VLAN_CFI); } else if (ntohs(ofmatch->dl_vlan) < 4096) { /* Match only packets with the specified VLAN VID. */ match->flow.vlan_tci = htons(VLAN_CFI) | ofmatch->dl_vlan; match->wc.masks.vlan_tci = htons(VLAN_CFI | VLAN_VID_MASK); } else { /* Invalid VID. */ return OFPERR_OFPBMC_BAD_VALUE; } if (!(wc & OFPFW11_DL_VLAN_PCP)) { if (ofmatch->dl_vlan_pcp <= 7) { match->flow.vlan_tci |= htons(ofmatch->dl_vlan_pcp << VLAN_PCP_SHIFT); match->wc.masks.vlan_tci |= htons(VLAN_PCP_MASK); } else { /* Invalid PCP. */ return OFPERR_OFPBMC_BAD_VALUE; } } } } if (!(wc & OFPFW11_DL_TYPE)) { match_set_dl_type(match, ofputil_dl_type_from_openflow(ofmatch->dl_type)); } ipv4 = match->flow.dl_type == htons(ETH_TYPE_IP); arp = match->flow.dl_type == htons(ETH_TYPE_ARP); rarp = match->flow.dl_type == htons(ETH_TYPE_RARP); if (ipv4 && !(wc & OFPFW11_NW_TOS)) { if (ofmatch->nw_tos & ~IP_DSCP_MASK) { /* Invalid TOS. */ return OFPERR_OFPBMC_BAD_VALUE; } match_set_nw_dscp(match, ofmatch->nw_tos); } if (ipv4 || arp || rarp) { if (!(wc & OFPFW11_NW_PROTO)) { match_set_nw_proto(match, ofmatch->nw_proto); } match_set_nw_src_masked(match, ofmatch->nw_src, ~ofmatch->nw_src_mask); match_set_nw_dst_masked(match, ofmatch->nw_dst, ~ofmatch->nw_dst_mask); } #define OFPFW11_TP_ALL (OFPFW11_TP_SRC | OFPFW11_TP_DST) if (ipv4 && (wc & OFPFW11_TP_ALL) != OFPFW11_TP_ALL) { switch (match->flow.nw_proto) { case IPPROTO_ICMP: /* "A.2.3 Flow Match Structures" in OF1.1 says: * * The tp_src and tp_dst fields will be ignored unless the * network protocol specified is as TCP, UDP or SCTP. * * but I'm pretty sure we should support ICMP too, otherwise * that's a regression from OF1.0. */ if (!(wc & OFPFW11_TP_SRC)) { uint16_t icmp_type = ntohs(ofmatch->tp_src); if (icmp_type < 0x100) { match_set_icmp_type(match, icmp_type); } else { return OFPERR_OFPBMC_BAD_FIELD; } } if (!(wc & OFPFW11_TP_DST)) { uint16_t icmp_code = ntohs(ofmatch->tp_dst); if (icmp_code < 0x100) { match_set_icmp_code(match, icmp_code); } else { return OFPERR_OFPBMC_BAD_FIELD; } } break; case IPPROTO_TCP: case IPPROTO_UDP: if (!(wc & (OFPFW11_TP_SRC))) { match_set_tp_src(match, ofmatch->tp_src); } if (!(wc & (OFPFW11_TP_DST))) { match_set_tp_dst(match, ofmatch->tp_dst); } break; case IPPROTO_SCTP: /* We don't support SCTP and it seems that we should tell the * controller, since OF1.1 implementations are supposed to. */ return OFPERR_OFPBMC_BAD_FIELD; default: /* OF1.1 says explicitly to ignore this. */ break; } } if (eth_type_mpls(match->flow.dl_type)) { enum { OFPFW11_MPLS_ALL = OFPFW11_MPLS_LABEL | OFPFW11_MPLS_TC }; if ((wc & OFPFW11_MPLS_ALL) != OFPFW11_MPLS_ALL) { /* MPLS not supported. */ return OFPERR_OFPBMC_BAD_TAG; } } match_set_metadata_masked(match, ofmatch->metadata, ~ofmatch->metadata_mask); return 0; } /* Convert 'match' into the OpenFlow 1.1 match structure 'ofmatch'. */ void ofputil_match_to_ofp11_match(const struct match *match, struct ofp11_match *ofmatch) { uint32_t wc = 0; int i; memset(ofmatch, 0, sizeof *ofmatch); ofmatch->omh.type = htons(OFPMT_STANDARD); ofmatch->omh.length = htons(OFPMT11_STANDARD_LENGTH); if (!match->wc.masks.in_port.ofp_port) { wc |= OFPFW11_IN_PORT; } else { ofmatch->in_port = ofputil_port_to_ofp11(match->flow.in_port.ofp_port); } memcpy(ofmatch->dl_src, match->flow.dl_src, ETH_ADDR_LEN); for (i = 0; i < ETH_ADDR_LEN; i++) { ofmatch->dl_src_mask[i] = ~match->wc.masks.dl_src[i]; } memcpy(ofmatch->dl_dst, match->flow.dl_dst, ETH_ADDR_LEN); for (i = 0; i < ETH_ADDR_LEN; i++) { ofmatch->dl_dst_mask[i] = ~match->wc.masks.dl_dst[i]; } if (match->wc.masks.vlan_tci == htons(0)) { wc |= OFPFW11_DL_VLAN | OFPFW11_DL_VLAN_PCP; } else if (match->wc.masks.vlan_tci & htons(VLAN_CFI) && !(match->flow.vlan_tci & htons(VLAN_CFI))) { ofmatch->dl_vlan = htons(OFPVID11_NONE); wc |= OFPFW11_DL_VLAN_PCP; } else { if (!(match->wc.masks.vlan_tci & htons(VLAN_VID_MASK))) { ofmatch->dl_vlan = htons(OFPVID11_ANY); } else { ofmatch->dl_vlan = htons(vlan_tci_to_vid(match->flow.vlan_tci)); } if (!(match->wc.masks.vlan_tci & htons(VLAN_PCP_MASK))) { wc |= OFPFW11_DL_VLAN_PCP; } else { ofmatch->dl_vlan_pcp = vlan_tci_to_pcp(match->flow.vlan_tci); } } if (!match->wc.masks.dl_type) { wc |= OFPFW11_DL_TYPE; } else { ofmatch->dl_type = ofputil_dl_type_to_openflow(match->flow.dl_type); } if (!(match->wc.masks.nw_tos & IP_DSCP_MASK)) { wc |= OFPFW11_NW_TOS; } else { ofmatch->nw_tos = match->flow.nw_tos & IP_DSCP_MASK; } if (!match->wc.masks.nw_proto) { wc |= OFPFW11_NW_PROTO; } else { ofmatch->nw_proto = match->flow.nw_proto; } ofmatch->nw_src = match->flow.nw_src; ofmatch->nw_src_mask = ~match->wc.masks.nw_src; ofmatch->nw_dst = match->flow.nw_dst; ofmatch->nw_dst_mask = ~match->wc.masks.nw_dst; if (!match->wc.masks.tp_src) { wc |= OFPFW11_TP_SRC; } else { ofmatch->tp_src = match->flow.tp_src; } if (!match->wc.masks.tp_dst) { wc |= OFPFW11_TP_DST; } else { ofmatch->tp_dst = match->flow.tp_dst; } /* MPLS not supported. */ wc |= OFPFW11_MPLS_LABEL; wc |= OFPFW11_MPLS_TC; ofmatch->metadata = match->flow.metadata; ofmatch->metadata_mask = ~match->wc.masks.metadata; ofmatch->wildcards = htonl(wc); } /* Given a 'dl_type' value in the format used in struct flow, returns the * corresponding 'dl_type' value for use in an ofp10_match or ofp11_match * structure. */ ovs_be16 ofputil_dl_type_to_openflow(ovs_be16 flow_dl_type) { return (flow_dl_type == htons(FLOW_DL_TYPE_NONE) ? htons(OFP_DL_TYPE_NOT_ETH_TYPE) : flow_dl_type); } /* Given a 'dl_type' value in the format used in an ofp10_match or ofp11_match * structure, returns the corresponding 'dl_type' value for use in struct * flow. */ ovs_be16 ofputil_dl_type_from_openflow(ovs_be16 ofp_dl_type) { return (ofp_dl_type == htons(OFP_DL_TYPE_NOT_ETH_TYPE) ? htons(FLOW_DL_TYPE_NONE) : ofp_dl_type); } /* Protocols. */ struct proto_abbrev { enum ofputil_protocol protocol; const char *name; }; /* Most users really don't care about some of the differences between * protocols. These abbreviations help with that. */ static const struct proto_abbrev proto_abbrevs[] = { { OFPUTIL_P_ANY, "any" }, { OFPUTIL_P_OF10_STD_ANY, "OpenFlow10" }, { OFPUTIL_P_OF10_NXM_ANY, "NXM" }, { OFPUTIL_P_ANY_OXM, "OXM" }, }; #define N_PROTO_ABBREVS ARRAY_SIZE(proto_abbrevs) enum ofputil_protocol ofputil_flow_dump_protocols[] = { OFPUTIL_P_OF13_OXM, OFPUTIL_P_OF12_OXM, OFPUTIL_P_OF10_NXM, OFPUTIL_P_OF10_STD, }; size_t ofputil_n_flow_dump_protocols = ARRAY_SIZE(ofputil_flow_dump_protocols); /* Returns the set of ofputil_protocols that are supported with the given * OpenFlow 'version'. 'version' should normally be an 8-bit OpenFlow version * identifier (e.g. 0x01 for OpenFlow 1.0, 0x02 for OpenFlow 1.1). Returns 0 * if 'version' is not supported or outside the valid range. */ enum ofputil_protocol ofputil_protocols_from_ofp_version(enum ofp_version version) { switch (version) { case OFP10_VERSION: return OFPUTIL_P_OF10_STD_ANY | OFPUTIL_P_OF10_NXM_ANY; case OFP12_VERSION: return OFPUTIL_P_OF12_OXM; case OFP13_VERSION: return OFPUTIL_P_OF13_OXM; case OFP11_VERSION: default: return 0; } } /* Returns the ofputil_protocol that is initially in effect on an OpenFlow * connection that has negotiated the given 'version'. 'version' should * normally be an 8-bit OpenFlow version identifier (e.g. 0x01 for OpenFlow * 1.0, 0x02 for OpenFlow 1.1). Returns 0 if 'version' is not supported or * outside the valid range. */ enum ofputil_protocol ofputil_protocol_from_ofp_version(enum ofp_version version) { return rightmost_1bit(ofputil_protocols_from_ofp_version(version)); } /* Returns the OpenFlow protocol version number (e.g. OFP10_VERSION, * etc.) that corresponds to 'protocol'. */ enum ofp_version ofputil_protocol_to_ofp_version(enum ofputil_protocol protocol) { switch (protocol) { case OFPUTIL_P_OF10_STD: case OFPUTIL_P_OF10_STD_TID: case OFPUTIL_P_OF10_NXM: case OFPUTIL_P_OF10_NXM_TID: return OFP10_VERSION; case OFPUTIL_P_OF12_OXM: return OFP12_VERSION; case OFPUTIL_P_OF13_OXM: return OFP13_VERSION; } NOT_REACHED(); } /* Returns a bitmap of OpenFlow versions that are supported by at * least one of the 'protocols'. */ uint32_t ofputil_protocols_to_version_bitmap(enum ofputil_protocol protocols) { uint32_t bitmap = 0; for (; protocols; protocols = zero_rightmost_1bit(protocols)) { enum ofputil_protocol protocol = rightmost_1bit(protocols); bitmap |= 1u << ofputil_protocol_to_ofp_version(protocol); } return bitmap; } /* Returns the set of protocols that are supported on top of the * OpenFlow versions included in 'bitmap'. */ enum ofputil_protocol ofputil_protocols_from_version_bitmap(uint32_t bitmap) { enum ofputil_protocol protocols = 0; for (; bitmap; bitmap = zero_rightmost_1bit(bitmap)) { enum ofp_version version = rightmost_1bit_idx(bitmap); protocols |= ofputil_protocols_from_ofp_version(version); } return protocols; } /* Returns true if 'protocol' is a single OFPUTIL_P_* value, false * otherwise. */ bool ofputil_protocol_is_valid(enum ofputil_protocol protocol) { return protocol & OFPUTIL_P_ANY && is_pow2(protocol); } /* Returns the equivalent of 'protocol' with the Nicira flow_mod_table_id * extension turned on or off if 'enable' is true or false, respectively. * * This extension is only useful for protocols whose "standard" version does * not allow specific tables to be modified. In particular, this is true of * OpenFlow 1.0. In later versions of OpenFlow, a flow_mod request always * specifies a table ID and so there is no need for such an extension. When * 'protocol' is such a protocol that doesn't need a flow_mod_table_id * extension, this function just returns its 'protocol' argument unchanged * regardless of the value of 'enable'. */ enum ofputil_protocol ofputil_protocol_set_tid(enum ofputil_protocol protocol, bool enable) { switch (protocol) { case OFPUTIL_P_OF10_STD: case OFPUTIL_P_OF10_STD_TID: return enable ? OFPUTIL_P_OF10_STD_TID : OFPUTIL_P_OF10_STD; case OFPUTIL_P_OF10_NXM: case OFPUTIL_P_OF10_NXM_TID: return enable ? OFPUTIL_P_OF10_NXM_TID : OFPUTIL_P_OF10_NXM; case OFPUTIL_P_OF12_OXM: return OFPUTIL_P_OF12_OXM; case OFPUTIL_P_OF13_OXM: return OFPUTIL_P_OF13_OXM; default: NOT_REACHED(); } } /* Returns the "base" version of 'protocol'. That is, if 'protocol' includes * some extension to a standard protocol version, the return value is the * standard version of that protocol without any extension. If 'protocol' is a * standard protocol version, returns 'protocol' unchanged. */ enum ofputil_protocol ofputil_protocol_to_base(enum ofputil_protocol protocol) { return ofputil_protocol_set_tid(protocol, false); } /* Returns 'new_base' with any extensions taken from 'cur'. */ enum ofputil_protocol ofputil_protocol_set_base(enum ofputil_protocol cur, enum ofputil_protocol new_base) { bool tid = (cur & OFPUTIL_P_TID) != 0; switch (new_base) { case OFPUTIL_P_OF10_STD: case OFPUTIL_P_OF10_STD_TID: return ofputil_protocol_set_tid(OFPUTIL_P_OF10_STD, tid); case OFPUTIL_P_OF10_NXM: case OFPUTIL_P_OF10_NXM_TID: return ofputil_protocol_set_tid(OFPUTIL_P_OF10_NXM, tid); case OFPUTIL_P_OF12_OXM: return ofputil_protocol_set_tid(OFPUTIL_P_OF12_OXM, tid); case OFPUTIL_P_OF13_OXM: return ofputil_protocol_set_tid(OFPUTIL_P_OF13_OXM, tid); default: NOT_REACHED(); } } /* Returns a string form of 'protocol', if a simple form exists (that is, if * 'protocol' is either a single protocol or it is a combination of protocols * that have a single abbreviation). Otherwise, returns NULL. */ const char * ofputil_protocol_to_string(enum ofputil_protocol protocol) { const struct proto_abbrev *p; /* Use a "switch" statement for single-bit names so that we get a compiler * warning if we forget any. */ switch (protocol) { case OFPUTIL_P_OF10_NXM: return "NXM-table_id"; case OFPUTIL_P_OF10_NXM_TID: return "NXM+table_id"; case OFPUTIL_P_OF10_STD: return "OpenFlow10-table_id"; case OFPUTIL_P_OF10_STD_TID: return "OpenFlow10+table_id"; case OFPUTIL_P_OF12_OXM: return "OXM-OpenFlow12"; case OFPUTIL_P_OF13_OXM: return "OXM-OpenFlow13"; } /* Check abbreviations. */ for (p = proto_abbrevs; p < &proto_abbrevs[N_PROTO_ABBREVS]; p++) { if (protocol == p->protocol) { return p->name; } } return NULL; } /* Returns a string that represents 'protocols'. The return value might be a * comma-separated list if 'protocols' doesn't have a simple name. The return * value is "none" if 'protocols' is 0. * * The caller must free the returned string (with free()). */ char * ofputil_protocols_to_string(enum ofputil_protocol protocols) { struct ds s; ovs_assert(!(protocols & ~OFPUTIL_P_ANY)); if (protocols == 0) { return xstrdup("none"); } ds_init(&s); while (protocols) { const struct proto_abbrev *p; int i; if (s.length) { ds_put_char(&s, ','); } for (p = proto_abbrevs; p < &proto_abbrevs[N_PROTO_ABBREVS]; p++) { if ((protocols & p->protocol) == p->protocol) { ds_put_cstr(&s, p->name); protocols &= ~p->protocol; goto match; } } for (i = 0; i < CHAR_BIT * sizeof(enum ofputil_protocol); i++) { enum ofputil_protocol bit = 1u << i; if (protocols & bit) { ds_put_cstr(&s, ofputil_protocol_to_string(bit)); protocols &= ~bit; goto match; } } NOT_REACHED(); match: ; } return ds_steal_cstr(&s); } static enum ofputil_protocol ofputil_protocol_from_string__(const char *s, size_t n) { const struct proto_abbrev *p; int i; for (i = 0; i < CHAR_BIT * sizeof(enum ofputil_protocol); i++) { enum ofputil_protocol bit = 1u << i; const char *name = ofputil_protocol_to_string(bit); if (name && n == strlen(name) && !strncasecmp(s, name, n)) { return bit; } } for (p = proto_abbrevs; p < &proto_abbrevs[N_PROTO_ABBREVS]; p++) { if (n == strlen(p->name) && !strncasecmp(s, p->name, n)) { return p->protocol; } } return 0; } /* Returns the nonempty set of protocols represented by 's', which can be a * single protocol name or abbreviation or a comma-separated list of them. * * Aborts the program with an error message if 's' is invalid. */ enum ofputil_protocol ofputil_protocols_from_string(const char *s) { const char *orig_s = s; enum ofputil_protocol protocols; protocols = 0; while (*s) { enum ofputil_protocol p; size_t n; n = strcspn(s, ","); if (n == 0) { s++; continue; } p = ofputil_protocol_from_string__(s, n); if (!p) { ovs_fatal(0, "%.*s: unknown flow protocol", (int) n, s); } protocols |= p; s += n; } if (!protocols) { ovs_fatal(0, "%s: no flow protocol specified", orig_s); } return protocols; } static int ofputil_version_from_string(const char *s) { if (!strcasecmp(s, "OpenFlow10")) { return OFP10_VERSION; } if (!strcasecmp(s, "OpenFlow11")) { return OFP11_VERSION; } if (!strcasecmp(s, "OpenFlow12")) { return OFP12_VERSION; } if (!strcasecmp(s, "OpenFlow13")) { return OFP13_VERSION; } return 0; } static bool is_delimiter(unsigned char c) { return isspace(c) || c == ','; } uint32_t ofputil_versions_from_string(const char *s) { size_t i = 0; uint32_t bitmap = 0; while (s[i]) { size_t j; int version; char *key; if (is_delimiter(s[i])) { i++; continue; } j = 0; while (s[i + j] && !is_delimiter(s[i + j])) { j++; } key = xmemdup0(s + i, j); version = ofputil_version_from_string(key); if (!version) { VLOG_FATAL("Unknown OpenFlow version: \"%s\"", key); } free(key); bitmap |= 1u << version; i += j; } return bitmap; } uint32_t ofputil_versions_from_strings(char ** const s, size_t count) { uint32_t bitmap = 0; while (count--) { int version = ofputil_version_from_string(s[count]); if (!version) { VLOG_WARN("Unknown OpenFlow version: \"%s\"", s[count]); } else { bitmap |= 1u << version; } } return bitmap; } const char * ofputil_version_to_string(enum ofp_version ofp_version) { switch (ofp_version) { case OFP10_VERSION: return "OpenFlow10"; case OFP11_VERSION: return "OpenFlow11"; case OFP12_VERSION: return "OpenFlow12"; case OFP13_VERSION: return "OpenFlow13"; default: NOT_REACHED(); } } bool ofputil_packet_in_format_is_valid(enum nx_packet_in_format packet_in_format) { switch (packet_in_format) { case NXPIF_OPENFLOW10: case NXPIF_NXM: return true; } return false; } const char * ofputil_packet_in_format_to_string(enum nx_packet_in_format packet_in_format) { switch (packet_in_format) { case NXPIF_OPENFLOW10: return "openflow10"; case NXPIF_NXM: return "nxm"; default: NOT_REACHED(); } } int ofputil_packet_in_format_from_string(const char *s) { return (!strcmp(s, "openflow10") ? NXPIF_OPENFLOW10 : !strcmp(s, "nxm") ? NXPIF_NXM : -1); } static bool regs_fully_wildcarded(const struct flow_wildcards *wc) { int i; for (i = 0; i < FLOW_N_REGS; i++) { if (wc->masks.regs[i] != 0) { return false; } } return true; } /* Returns a bit-mask of ofputil_protocols that can be used for sending 'match' * to a switch (e.g. to add or remove a flow). Only NXM can handle tunnel IDs, * registers, or fixing the Ethernet multicast bit. Otherwise, it's better to * use OpenFlow 1.0 protocol for backward compatibility. */ enum ofputil_protocol ofputil_usable_protocols(const struct match *match) { const struct flow_wildcards *wc = &match->wc; BUILD_ASSERT_DECL(FLOW_WC_SEQ == 20); /* These tunnel params can't be sent in a flow_mod */ if (wc->masks.tunnel.ip_ttl || wc->masks.tunnel.ip_tos || wc->masks.tunnel.flags) { return OFPUTIL_P_NONE; } /* skb_mark and skb_priority can't be sent in a flow_mod */ if (wc->masks.skb_mark || wc->masks.skb_priority) { return OFPUTIL_P_NONE; } /* NXM, OXM, and OF1.1 support bitwise matching on ethernet addresses. */ if (!eth_mask_is_exact(wc->masks.dl_src) && !eth_addr_is_zero(wc->masks.dl_src)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } if (!eth_mask_is_exact(wc->masks.dl_dst) && !eth_addr_is_zero(wc->masks.dl_dst)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM, OXM, and OF1.1+ support matching metadata. */ if (wc->masks.metadata != htonll(0)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching ARP hardware addresses. */ if (!eth_addr_is_zero(wc->masks.arp_sha) || !eth_addr_is_zero(wc->masks.arp_tha)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching L3 and L4 fields within IPv6. * * (arp_sha, arp_tha, nw_frag, and nw_ttl are covered elsewhere so they * don't need to be included in this test too.) */ if (match->flow.dl_type == htons(ETH_TYPE_IPV6) && (!ipv6_mask_is_any(&wc->masks.ipv6_src) || !ipv6_mask_is_any(&wc->masks.ipv6_dst) || !ipv6_mask_is_any(&wc->masks.nd_target) || wc->masks.ipv6_label || wc->masks.tp_src || wc->masks.tp_dst || wc->masks.nw_proto || wc->masks.nw_tos)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching registers. */ if (!regs_fully_wildcarded(wc)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching tun_id, tun_src, and tun_dst. */ if (wc->masks.tunnel.tun_id != htonll(0) || wc->masks.tunnel.ip_src != htonl(0) || wc->masks.tunnel.ip_dst != htonl(0)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching fragments. */ if (wc->masks.nw_frag) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching IP ECN bits. */ if (wc->masks.nw_tos & IP_ECN_MASK) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support matching IP TTL/hop limit. */ if (wc->masks.nw_ttl) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support non-CIDR IPv4 address masks. */ if (!ip_is_cidr(wc->masks.nw_src) || !ip_is_cidr(wc->masks.nw_dst)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OXM support bitwise matching on transport port. */ if ((wc->masks.tp_src && wc->masks.tp_src != htons(UINT16_MAX)) || (wc->masks.tp_dst && wc->masks.tp_dst != htons(UINT16_MAX))) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OF1.1+ support matching MPLS label */ if (wc->masks.mpls_lse & htonl(MPLS_LABEL_MASK)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OF1.1+ support matching MPLS TC */ if (wc->masks.mpls_lse & htonl(MPLS_TC_MASK)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* NXM and OF1.3+ support matching MPLS stack flag */ /* Allow for OF1.2 as there doesn't seem to be a * particularly good reason not to */ if (wc->masks.mpls_lse & htonl(MPLS_BOS_MASK)) { return OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } /* Other formats can express this rule. */ return OFPUTIL_P_ANY; } void ofputil_format_version(struct ds *msg, enum ofp_version version) { ds_put_format(msg, "0x%02x", version); } void ofputil_format_version_name(struct ds *msg, enum ofp_version version) { ds_put_cstr(msg, ofputil_version_to_string(version)); } static void ofputil_format_version_bitmap__(struct ds *msg, uint32_t bitmap, void (*format_version)(struct ds *msg, enum ofp_version)) { while (bitmap) { format_version(msg, raw_ctz(bitmap)); bitmap = zero_rightmost_1bit(bitmap); if (bitmap) { ds_put_cstr(msg, ", "); } } } void ofputil_format_version_bitmap(struct ds *msg, uint32_t bitmap) { ofputil_format_version_bitmap__(msg, bitmap, ofputil_format_version); } void ofputil_format_version_bitmap_names(struct ds *msg, uint32_t bitmap) { ofputil_format_version_bitmap__(msg, bitmap, ofputil_format_version_name); } static bool ofputil_decode_hello_bitmap(const struct ofp_hello_elem_header *oheh, uint32_t *allowed_versionsp) { uint16_t bitmap_len = ntohs(oheh->length) - sizeof *oheh; const ovs_be32 *bitmap = (const ovs_be32 *) (oheh + 1); uint32_t allowed_versions; if (!bitmap_len || bitmap_len % sizeof *bitmap) { return false; } /* Only use the first 32-bit element of the bitmap as that is all the * current implementation supports. Subsequent elements are ignored which * should have no effect on session negotiation until Open vSwtich supports * wire-protocol versions greater than 31. */ allowed_versions = ntohl(bitmap[0]); if (allowed_versions & 1) { /* There's no OpenFlow version 0. */ VLOG_WARN_RL(&bad_ofmsg_rl, "peer claims to support invalid OpenFlow " "version 0x00"); allowed_versions &= ~1u; } if (!allowed_versions) { VLOG_WARN_RL(&bad_ofmsg_rl, "peer does not support any OpenFlow " "version (between 0x01 and 0x1f)"); return false; } *allowed_versionsp = allowed_versions; return true; } static uint32_t version_bitmap_from_version(uint8_t ofp_version) { return ((ofp_version < 32 ? 1u << ofp_version : 0) - 1) << 1; } /* Decodes OpenFlow OFPT_HELLO message 'oh', storing into '*allowed_versions' * the set of OpenFlow versions for which 'oh' announces support. * * Because of how OpenFlow defines OFPT_HELLO messages, this function is always * successful, and thus '*allowed_versions' is always initialized. However, it * returns false if 'oh' contains some data that could not be fully understood, * true if 'oh' was completely parsed. */ bool ofputil_decode_hello(const struct ofp_header *oh, uint32_t *allowed_versions) { struct ofpbuf msg; bool ok = true; ofpbuf_use_const(&msg, oh, ntohs(oh->length)); ofpbuf_pull(&msg, sizeof *oh); *allowed_versions = version_bitmap_from_version(oh->version); while (msg.size) { const struct ofp_hello_elem_header *oheh; unsigned int len; if (msg.size < sizeof *oheh) { return false; } oheh = msg.data; len = ntohs(oheh->length); if (len < sizeof *oheh || !ofpbuf_try_pull(&msg, ROUND_UP(len, 8))) { return false; } if (oheh->type != htons(OFPHET_VERSIONBITMAP) || !ofputil_decode_hello_bitmap(oheh, allowed_versions)) { ok = false; } } return ok; } /* Returns true if 'allowed_versions' needs to be accompanied by a version * bitmap to be correctly expressed in an OFPT_HELLO message. */ static inline bool should_send_version_bitmap(uint32_t allowed_versions) { return !is_pow2((allowed_versions >> 1) + 1); } /* Create an OFPT_HELLO message that expresses support for the OpenFlow * versions in the 'allowed_versions' bitmaps and returns the message. */ struct ofpbuf * ofputil_encode_hello(uint32_t allowed_versions) { enum ofp_version ofp_version; struct ofpbuf *msg; ofp_version = leftmost_1bit_idx(allowed_versions); msg = ofpraw_alloc(OFPRAW_OFPT_HELLO, ofp_version, 0); if (should_send_version_bitmap(allowed_versions)) { struct ofp_hello_elem_header *oheh; uint16_t map_len; map_len = sizeof allowed_versions; oheh = ofpbuf_put_zeros(msg, ROUND_UP(map_len + sizeof *oheh, 8)); oheh->type = htons(OFPHET_VERSIONBITMAP); oheh->length = htons(map_len + sizeof *oheh); *(ovs_be32 *)(oheh + 1) = htonl(allowed_versions); ofpmsg_update_length(msg); } return msg; } /* Returns an OpenFlow message that, sent on an OpenFlow connection whose * protocol is 'current', at least partly transitions the protocol to 'want'. * Stores in '*next' the protocol that will be in effect on the OpenFlow * connection if the switch processes the returned message correctly. (If * '*next != want' then the caller will have to iterate.) * * If 'current == want', or if it is not possible to transition from 'current' * to 'want' (because, for example, 'current' and 'want' use different OpenFlow * protocol versions), returns NULL and stores 'current' in '*next'. */ struct ofpbuf * ofputil_encode_set_protocol(enum ofputil_protocol current, enum ofputil_protocol want, enum ofputil_protocol *next) { enum ofp_version cur_version, want_version; enum ofputil_protocol cur_base, want_base; bool cur_tid, want_tid; cur_version = ofputil_protocol_to_ofp_version(current); want_version = ofputil_protocol_to_ofp_version(want); if (cur_version != want_version) { *next = current; return NULL; } cur_base = ofputil_protocol_to_base(current); want_base = ofputil_protocol_to_base(want); if (cur_base != want_base) { *next = ofputil_protocol_set_base(current, want_base); switch (want_base) { case OFPUTIL_P_OF10_NXM: return ofputil_encode_nx_set_flow_format(NXFF_NXM); case OFPUTIL_P_OF10_STD: return ofputil_encode_nx_set_flow_format(NXFF_OPENFLOW10); case OFPUTIL_P_OF12_OXM: case OFPUTIL_P_OF13_OXM: /* There are only one of each OpenFlow 1.2+ protocols and we already * verified above that we're not trying to change versions. */ NOT_REACHED(); case OFPUTIL_P_OF10_STD_TID: case OFPUTIL_P_OF10_NXM_TID: NOT_REACHED(); } } cur_tid = (current & OFPUTIL_P_TID) != 0; want_tid = (want & OFPUTIL_P_TID) != 0; if (cur_tid != want_tid) { *next = ofputil_protocol_set_tid(current, want_tid); return ofputil_make_flow_mod_table_id(want_tid); } ovs_assert(current == want); *next = current; return NULL; } /* Returns an NXT_SET_FLOW_FORMAT message that can be used to set the flow * format to 'nxff'. */ struct ofpbuf * ofputil_encode_nx_set_flow_format(enum nx_flow_format nxff) { struct nx_set_flow_format *sff; struct ofpbuf *msg; ovs_assert(ofputil_nx_flow_format_is_valid(nxff)); msg = ofpraw_alloc(OFPRAW_NXT_SET_FLOW_FORMAT, OFP10_VERSION, 0); sff = ofpbuf_put_zeros(msg, sizeof *sff); sff->format = htonl(nxff); return msg; } /* Returns the base protocol if 'flow_format' is a valid NXFF_* value, false * otherwise. */ enum ofputil_protocol ofputil_nx_flow_format_to_protocol(enum nx_flow_format flow_format) { switch (flow_format) { case NXFF_OPENFLOW10: return OFPUTIL_P_OF10_STD; case NXFF_NXM: return OFPUTIL_P_OF10_NXM; default: return 0; } } /* Returns true if 'flow_format' is a valid NXFF_* value, false otherwise. */ bool ofputil_nx_flow_format_is_valid(enum nx_flow_format flow_format) { return ofputil_nx_flow_format_to_protocol(flow_format) != 0; } /* Returns a string version of 'flow_format', which must be a valid NXFF_* * value. */ const char * ofputil_nx_flow_format_to_string(enum nx_flow_format flow_format) { switch (flow_format) { case NXFF_OPENFLOW10: return "openflow10"; case NXFF_NXM: return "nxm"; default: NOT_REACHED(); } } struct ofpbuf * ofputil_make_set_packet_in_format(enum ofp_version ofp_version, enum nx_packet_in_format packet_in_format) { struct nx_set_packet_in_format *spif; struct ofpbuf *msg; msg = ofpraw_alloc(OFPRAW_NXT_SET_PACKET_IN_FORMAT, ofp_version, 0); spif = ofpbuf_put_zeros(msg, sizeof *spif); spif->format = htonl(packet_in_format); return msg; } /* Returns an OpenFlow message that can be used to turn the flow_mod_table_id * extension on or off (according to 'flow_mod_table_id'). */ struct ofpbuf * ofputil_make_flow_mod_table_id(bool flow_mod_table_id) { struct nx_flow_mod_table_id *nfmti; struct ofpbuf *msg; msg = ofpraw_alloc(OFPRAW_NXT_FLOW_MOD_TABLE_ID, OFP10_VERSION, 0); nfmti = ofpbuf_put_zeros(msg, sizeof *nfmti); nfmti->set = flow_mod_table_id; return msg; } /* Converts an OFPT_FLOW_MOD or NXT_FLOW_MOD message 'oh' into an abstract * flow_mod in 'fm'. Returns 0 if successful, otherwise an OpenFlow error * code. * * Uses 'ofpacts' to store the abstract OFPACT_* version of 'oh''s actions. * The caller must initialize 'ofpacts' and retains ownership of it. * 'fm->ofpacts' will point into the 'ofpacts' buffer. * * Does not validate the flow_mod actions. The caller should do that, with * ofpacts_check(). */ enum ofperr ofputil_decode_flow_mod(struct ofputil_flow_mod *fm, const struct ofp_header *oh, enum ofputil_protocol protocol, struct ofpbuf *ofpacts) { uint16_t command; struct ofpbuf b; enum ofpraw raw; ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); if (raw == OFPRAW_OFPT11_FLOW_MOD) { /* Standard OpenFlow 1.1 flow_mod. */ const struct ofp11_flow_mod *ofm; enum ofperr error; ofm = ofpbuf_pull(&b, sizeof *ofm); error = ofputil_pull_ofp11_match(&b, &fm->match, NULL); if (error) { return error; } error = ofpacts_pull_openflow11_instructions(&b, b.size, ofpacts); if (error) { return error; } /* Translate the message. */ fm->priority = ntohs(ofm->priority); if (ofm->command == OFPFC_ADD) { fm->cookie = htonll(0); fm->cookie_mask = htonll(0); fm->new_cookie = ofm->cookie; } else { fm->cookie = ofm->cookie; fm->cookie_mask = ofm->cookie_mask; fm->new_cookie = htonll(UINT64_MAX); } fm->command = ofm->command; fm->table_id = ofm->table_id; fm->idle_timeout = ntohs(ofm->idle_timeout); fm->hard_timeout = ntohs(ofm->hard_timeout); fm->buffer_id = ntohl(ofm->buffer_id); error = ofputil_port_from_ofp11(ofm->out_port, &fm->out_port); if (error) { return error; } if ((ofm->command == OFPFC_DELETE || ofm->command == OFPFC_DELETE_STRICT) && ofm->out_group != htonl(OFPG_ANY)) { return OFPERR_OFPFMFC_UNKNOWN; } fm->flags = ntohs(ofm->flags); } else { if (raw == OFPRAW_OFPT10_FLOW_MOD) { /* Standard OpenFlow 1.0 flow_mod. */ const struct ofp10_flow_mod *ofm; enum ofperr error; /* Get the ofp10_flow_mod. */ ofm = ofpbuf_pull(&b, sizeof *ofm); /* Translate the rule. */ ofputil_match_from_ofp10_match(&ofm->match, &fm->match); ofputil_normalize_match(&fm->match); /* Now get the actions. */ error = ofpacts_pull_openflow10(&b, b.size, ofpacts); if (error) { return error; } /* OpenFlow 1.0 says that exact-match rules have to have the * highest possible priority. */ fm->priority = (ofm->match.wildcards & htonl(OFPFW10_ALL) ? ntohs(ofm->priority) : UINT16_MAX); /* Translate the message. */ command = ntohs(ofm->command); fm->cookie = htonll(0); fm->cookie_mask = htonll(0); fm->new_cookie = ofm->cookie; fm->idle_timeout = ntohs(ofm->idle_timeout); fm->hard_timeout = ntohs(ofm->hard_timeout); fm->buffer_id = ntohl(ofm->buffer_id); fm->out_port = u16_to_ofp(ntohs(ofm->out_port)); fm->flags = ntohs(ofm->flags); } else if (raw == OFPRAW_NXT_FLOW_MOD) { /* Nicira extended flow_mod. */ const struct nx_flow_mod *nfm; enum ofperr error; /* Dissect the message. */ nfm = ofpbuf_pull(&b, sizeof *nfm); error = nx_pull_match(&b, ntohs(nfm->match_len), &fm->match, &fm->cookie, &fm->cookie_mask); if (error) { return error; } error = ofpacts_pull_openflow10(&b, b.size, ofpacts); if (error) { return error; } /* Translate the message. */ command = ntohs(nfm->command); if ((command & 0xff) == OFPFC_ADD && fm->cookie_mask) { /* Flow additions may only set a new cookie, not match an * existing cookie. */ return OFPERR_NXBRC_NXM_INVALID; } fm->priority = ntohs(nfm->priority); fm->new_cookie = nfm->cookie; fm->idle_timeout = ntohs(nfm->idle_timeout); fm->hard_timeout = ntohs(nfm->hard_timeout); fm->buffer_id = ntohl(nfm->buffer_id); fm->out_port = u16_to_ofp(ntohs(nfm->out_port)); fm->flags = ntohs(nfm->flags); } else { NOT_REACHED(); } if (fm->flags & OFPFF10_EMERG) { /* We do not support the OpenFlow 1.0 emergency flow cache, which * is not required in OpenFlow 1.0.1 and removed from OpenFlow 1.1. * * OpenFlow 1.0 specifies the error code to use when idle_timeout * or hard_timeout is nonzero. Otherwise, there is no good error * code, so just state that the flow table is full. */ return (fm->hard_timeout || fm->idle_timeout ? OFPERR_OFPFMFC_BAD_EMERG_TIMEOUT : OFPERR_OFPFMFC_TABLE_FULL); } if (protocol & OFPUTIL_P_TID) { fm->command = command & 0xff; fm->table_id = command >> 8; } else { fm->command = command; fm->table_id = 0xff; } } fm->ofpacts = ofpacts->data; fm->ofpacts_len = ofpacts->size; return 0; } static enum ofperr ofputil_pull_bands(struct ofpbuf *msg, size_t len, uint16_t *n_bands, struct ofpbuf *bands) { const struct ofp13_meter_band_header *ombh; struct ofputil_meter_band *mb; uint16_t n = 0; ombh = ofpbuf_try_pull(msg, len); if (!ombh) { return OFPERR_OFPBRC_BAD_LEN; } while (len >= sizeof (struct ofp13_meter_band_drop)) { size_t ombh_len = ntohs(ombh->len); /* All supported band types have the same length. */ if (ombh_len != sizeof (struct ofp13_meter_band_drop)) { return OFPERR_OFPBRC_BAD_LEN; } mb = ofpbuf_put_uninit(bands, sizeof *mb); mb->type = ntohs(ombh->type); mb->rate = ntohl(ombh->rate); mb->burst_size = ntohl(ombh->burst_size); mb->prec_level = (mb->type == OFPMBT13_DSCP_REMARK) ? ((struct ofp13_meter_band_dscp_remark *)ombh)->prec_level : 0; n++; len -= ombh_len; ombh = (struct ofp13_meter_band_header *)(((char *)ombh) + ombh_len); } if (len) { return OFPERR_OFPBRC_BAD_LEN; } *n_bands = n; return 0; } enum ofperr ofputil_decode_meter_mod(const struct ofp_header *oh, struct ofputil_meter_mod *mm, struct ofpbuf *bands) { const struct ofp13_meter_mod *omm; struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); ofpraw_pull_assert(&b); omm = ofpbuf_pull(&b, sizeof *omm); /* Translate the message. */ mm->command = ntohs(omm->command); mm->meter.meter_id = ntohl(omm->meter_id); if (mm->command == OFPMC13_DELETE) { mm->meter.flags = 0; mm->meter.n_bands = 0; mm->meter.bands = NULL; } else { enum ofperr error; mm->meter.flags = ntohs(omm->flags); mm->meter.bands = bands->data; error = ofputil_pull_bands(&b, b.size, &mm->meter.n_bands, bands); if (error) { return error; } } return 0; } void ofputil_decode_meter_request(const struct ofp_header *oh, uint32_t *meter_id) { const struct ofp13_meter_multipart_request *omr = ofpmsg_body(oh); *meter_id = ntohl(omr->meter_id); } struct ofpbuf * ofputil_encode_meter_request(enum ofp_version ofp_version, enum ofputil_meter_request_type type, uint32_t meter_id) { struct ofpbuf *msg; enum ofpraw raw; switch (type) { case OFPUTIL_METER_CONFIG: raw = OFPRAW_OFPST13_METER_CONFIG_REQUEST; break; case OFPUTIL_METER_STATS: raw = OFPRAW_OFPST13_METER_REQUEST; break; default: case OFPUTIL_METER_FEATURES: raw = OFPRAW_OFPST13_METER_FEATURES_REQUEST; break; } msg = ofpraw_alloc(raw, ofp_version, 0); if (type != OFPUTIL_METER_FEATURES) { struct ofp13_meter_multipart_request *omr; omr = ofpbuf_put_zeros(msg, sizeof *omr); omr->meter_id = htonl(meter_id); } return msg; } static void ofputil_put_bands(uint16_t n_bands, const struct ofputil_meter_band *mb, struct ofpbuf *msg) { uint16_t n = 0; for (n = 0; n < n_bands; ++n) { /* Currently all band types have same size. */ struct ofp13_meter_band_dscp_remark *ombh; size_t ombh_len = sizeof *ombh; ombh = ofpbuf_put_zeros(msg, ombh_len); ombh->type = htons(mb->type); ombh->len = htons(ombh_len); ombh->rate = htonl(mb->rate); ombh->burst_size = htonl(mb->burst_size); ombh->prec_level = mb->prec_level; mb++; } } /* Encode a meter stat for 'mc' and append it to 'replies'. */ void ofputil_append_meter_config(struct list *replies, const struct ofputil_meter_config *mc) { struct ofpbuf *msg = ofpbuf_from_list(list_back(replies)); size_t start_ofs = msg->size; struct ofp13_meter_config *reply = ofpbuf_put_uninit(msg, sizeof *reply); reply->flags = htons(mc->flags); reply->meter_id = htonl(mc->meter_id); ofputil_put_bands(mc->n_bands, mc->bands, msg); reply->length = htons(msg->size - start_ofs); ofpmp_postappend(replies, start_ofs); } /* Encode a meter stat for 'ms' and append it to 'replies'. */ void ofputil_append_meter_stats(struct list *replies, const struct ofputil_meter_stats *ms) { struct ofp13_meter_stats *reply; uint16_t n = 0; uint16_t len; len = sizeof *reply + ms->n_bands * sizeof(struct ofp13_meter_band_stats); reply = ofpmp_append(replies, len); reply->meter_id = htonl(ms->meter_id); reply->len = htons(len); memset(reply->pad, 0, sizeof reply->pad); reply->flow_count = htonl(ms->flow_count); reply->packet_in_count = htonll(ms->packet_in_count); reply->byte_in_count = htonll(ms->byte_in_count); reply->duration_sec = htonl(ms->duration_sec); reply->duration_nsec = htonl(ms->duration_nsec); for (n = 0; n < ms->n_bands; ++n) { const struct ofputil_meter_band_stats *src = &ms->bands[n]; struct ofp13_meter_band_stats *dst = &reply->band_stats[n]; dst->packet_band_count = htonll(src->packet_count); dst->byte_band_count = htonll(src->byte_count); } } /* Converts an OFPMP_METER_CONFIG reply in 'msg' into an abstract * ofputil_meter_config in 'mc', with mc->bands pointing to bands decoded into * 'bands'. The caller must have initialized 'bands' and retains ownership of * it across the call. * * Multiple OFPST13_METER_CONFIG replies can be packed into a single OpenFlow * message. Calling this function multiple times for a single 'msg' iterates * through the replies. 'bands' is cleared for each reply. * * Returns 0 if successful, EOF if no replies were left in this 'msg', * otherwise a positive errno value. */ int ofputil_decode_meter_config(struct ofpbuf *msg, struct ofputil_meter_config *mc, struct ofpbuf *bands) { const struct ofp13_meter_config *omc; enum ofperr err; /* Pull OpenFlow headers for the first call. */ if (!msg->l2) { ofpraw_pull_assert(msg); } if (!msg->size) { return EOF; } omc = ofpbuf_try_pull(msg, sizeof *omc); if (!omc) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPMP_METER_CONFIG reply has %zu leftover bytes at end", msg->size); return OFPERR_OFPBRC_BAD_LEN; } ofpbuf_clear(bands); err = ofputil_pull_bands(msg, ntohs(omc->length) - sizeof *omc, &mc->n_bands, bands); if (err) { return err; } mc->meter_id = ntohl(omc->meter_id); mc->flags = ntohs(omc->flags); mc->bands = bands->data; return 0; } static enum ofperr ofputil_pull_band_stats(struct ofpbuf *msg, size_t len, uint16_t *n_bands, struct ofpbuf *bands) { const struct ofp13_meter_band_stats *ombs; struct ofputil_meter_band_stats *mbs; uint16_t n, i; ombs = ofpbuf_try_pull(msg, len); if (!ombs) { return OFPERR_OFPBRC_BAD_LEN; } n = len / sizeof *ombs; if (len != n * sizeof *ombs) { return OFPERR_OFPBRC_BAD_LEN; } mbs = ofpbuf_put_uninit(bands, len); for (i = 0; i < n; ++i) { mbs[i].packet_count = ntohll(ombs[i].packet_band_count); mbs[i].byte_count = ntohll(ombs[i].byte_band_count); } *n_bands = n; return 0; } /* Converts an OFPMP_METER reply in 'msg' into an abstract * ofputil_meter_stats in 'ms', with ms->bands pointing to band stats * decoded into 'bands'. * * Multiple OFPMP_METER replies can be packed into a single OpenFlow * message. Calling this function multiple times for a single 'msg' iterates * through the replies. 'bands' is cleared for each reply. * * Returns 0 if successful, EOF if no replies were left in this 'msg', * otherwise a positive errno value. */ int ofputil_decode_meter_stats(struct ofpbuf *msg, struct ofputil_meter_stats *ms, struct ofpbuf *bands) { const struct ofp13_meter_stats *oms; enum ofperr err; /* Pull OpenFlow headers for the first call. */ if (!msg->l2) { ofpraw_pull_assert(msg); } if (!msg->size) { return EOF; } oms = ofpbuf_try_pull(msg, sizeof *oms); if (!oms) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPMP_METER reply has %zu leftover bytes at end", msg->size); return OFPERR_OFPBRC_BAD_LEN; } ofpbuf_clear(bands); err = ofputil_pull_band_stats(msg, ntohs(oms->len) - sizeof *oms, &ms->n_bands, bands); if (err) { return err; } ms->meter_id = ntohl(oms->meter_id); ms->flow_count = ntohl(oms->flow_count); ms->packet_in_count = ntohll(oms->packet_in_count); ms->byte_in_count = ntohll(oms->byte_in_count); ms->duration_sec = ntohl(oms->duration_sec); ms->duration_nsec = ntohl(oms->duration_nsec); ms->bands = bands->data; return 0; } void ofputil_decode_meter_features(const struct ofp_header *oh, struct ofputil_meter_features *mf) { const struct ofp13_meter_features *omf = ofpmsg_body(oh); mf->max_meters = ntohl(omf->max_meter); mf->band_types = ntohl(omf->band_types); mf->capabilities = ntohl(omf->capabilities); mf->max_bands = omf->max_bands; mf->max_color = omf->max_color; } struct ofpbuf * ofputil_encode_meter_features_reply(const struct ofputil_meter_features *mf, const struct ofp_header *request) { struct ofpbuf *reply; struct ofp13_meter_features *omf; reply = ofpraw_alloc_stats_reply(request, 0); omf = ofpbuf_put_zeros(reply, sizeof *omf); omf->max_meter = htonl(mf->max_meters); omf->band_types = htonl(mf->band_types); omf->capabilities = htonl(mf->capabilities); omf->max_bands = mf->max_bands; omf->max_color = mf->max_color; return reply; } struct ofpbuf * ofputil_encode_meter_mod(enum ofp_version ofp_version, const struct ofputil_meter_mod *mm) { struct ofpbuf *msg; struct ofp13_meter_mod *omm; msg = ofpraw_alloc(OFPRAW_OFPT13_METER_MOD, ofp_version, NXM_TYPICAL_LEN + mm->meter.n_bands * 16); omm = ofpbuf_put_zeros(msg, sizeof *omm); omm->command = htons(mm->command); if (mm->command != OFPMC13_DELETE) { omm->flags = htons(mm->meter.flags); } omm->meter_id = htonl(mm->meter.meter_id); ofputil_put_bands(mm->meter.n_bands, mm->meter.bands, msg); ofpmsg_update_length(msg); return msg; } static ovs_be16 ofputil_tid_command(const struct ofputil_flow_mod *fm, enum ofputil_protocol protocol) { return htons(protocol & OFPUTIL_P_TID ? (fm->command & 0xff) | (fm->table_id << 8) : fm->command); } /* Converts 'fm' into an OFPT_FLOW_MOD or NXT_FLOW_MOD message according to * 'protocol' and returns the message. */ struct ofpbuf * ofputil_encode_flow_mod(const struct ofputil_flow_mod *fm, enum ofputil_protocol protocol) { struct ofpbuf *msg; switch (protocol) { case OFPUTIL_P_OF12_OXM: case OFPUTIL_P_OF13_OXM: { struct ofp11_flow_mod *ofm; msg = ofpraw_alloc(OFPRAW_OFPT11_FLOW_MOD, ofputil_protocol_to_ofp_version(protocol), NXM_TYPICAL_LEN + fm->ofpacts_len); ofm = ofpbuf_put_zeros(msg, sizeof *ofm); if (fm->command == OFPFC_ADD) { ofm->cookie = fm->new_cookie; } else { ofm->cookie = fm->cookie; } ofm->cookie_mask = fm->cookie_mask; ofm->table_id = fm->table_id; ofm->command = fm->command; ofm->idle_timeout = htons(fm->idle_timeout); ofm->hard_timeout = htons(fm->hard_timeout); ofm->priority = htons(fm->priority); ofm->buffer_id = htonl(fm->buffer_id); ofm->out_port = ofputil_port_to_ofp11(fm->out_port); ofm->out_group = htonl(OFPG11_ANY); ofm->flags = htons(fm->flags); oxm_put_match(msg, &fm->match); ofpacts_put_openflow11_instructions(fm->ofpacts, fm->ofpacts_len, msg); break; } case OFPUTIL_P_OF10_STD: case OFPUTIL_P_OF10_STD_TID: { struct ofp10_flow_mod *ofm; msg = ofpraw_alloc(OFPRAW_OFPT10_FLOW_MOD, OFP10_VERSION, fm->ofpacts_len); ofm = ofpbuf_put_zeros(msg, sizeof *ofm); ofputil_match_to_ofp10_match(&fm->match, &ofm->match); ofm->cookie = fm->new_cookie; ofm->command = ofputil_tid_command(fm, protocol); ofm->idle_timeout = htons(fm->idle_timeout); ofm->hard_timeout = htons(fm->hard_timeout); ofm->priority = htons(fm->priority); ofm->buffer_id = htonl(fm->buffer_id); ofm->out_port = htons(ofp_to_u16(fm->out_port)); ofm->flags = htons(fm->flags); ofpacts_put_openflow10(fm->ofpacts, fm->ofpacts_len, msg); break; } case OFPUTIL_P_OF10_NXM: case OFPUTIL_P_OF10_NXM_TID: { struct nx_flow_mod *nfm; int match_len; msg = ofpraw_alloc(OFPRAW_NXT_FLOW_MOD, OFP10_VERSION, NXM_TYPICAL_LEN + fm->ofpacts_len); nfm = ofpbuf_put_zeros(msg, sizeof *nfm); nfm->command = ofputil_tid_command(fm, protocol); nfm->cookie = fm->new_cookie; match_len = nx_put_match(msg, &fm->match, fm->cookie, fm->cookie_mask); nfm = msg->l3; nfm->idle_timeout = htons(fm->idle_timeout); nfm->hard_timeout = htons(fm->hard_timeout); nfm->priority = htons(fm->priority); nfm->buffer_id = htonl(fm->buffer_id); nfm->out_port = htons(ofp_to_u16(fm->out_port)); nfm->flags = htons(fm->flags); nfm->match_len = htons(match_len); ofpacts_put_openflow10(fm->ofpacts, fm->ofpacts_len, msg); break; } default: NOT_REACHED(); } ofpmsg_update_length(msg); return msg; } /* Returns a bitmask with a 1-bit for each protocol that could be used to * send all of the 'n_fm's flow table modification requests in 'fms', and a * 0-bit for each protocol that is inadequate. * * (The return value will have at least one 1-bit.) */ enum ofputil_protocol ofputil_flow_mod_usable_protocols(const struct ofputil_flow_mod *fms, size_t n_fms) { enum ofputil_protocol usable_protocols; size_t i; usable_protocols = OFPUTIL_P_ANY; for (i = 0; i < n_fms; i++) { const struct ofputil_flow_mod *fm = &fms[i]; usable_protocols &= ofputil_usable_protocols(&fm->match); if (fm->table_id != 0xff) { usable_protocols &= OFPUTIL_P_TID; } /* Matching of the cookie is only supported through NXM or OF1.1+. */ if (fm->cookie_mask != htonll(0)) { usable_protocols &= OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } } return usable_protocols; } static enum ofperr ofputil_decode_ofpst10_flow_request(struct ofputil_flow_stats_request *fsr, const struct ofp10_flow_stats_request *ofsr, bool aggregate) { fsr->aggregate = aggregate; ofputil_match_from_ofp10_match(&ofsr->match, &fsr->match); fsr->out_port = u16_to_ofp(ntohs(ofsr->out_port)); fsr->table_id = ofsr->table_id; fsr->cookie = fsr->cookie_mask = htonll(0); return 0; } static enum ofperr ofputil_decode_ofpst11_flow_request(struct ofputil_flow_stats_request *fsr, struct ofpbuf *b, bool aggregate) { const struct ofp11_flow_stats_request *ofsr; enum ofperr error; ofsr = ofpbuf_pull(b, sizeof *ofsr); fsr->aggregate = aggregate; fsr->table_id = ofsr->table_id; error = ofputil_port_from_ofp11(ofsr->out_port, &fsr->out_port); if (error) { return error; } if (ofsr->out_group != htonl(OFPG11_ANY)) { return OFPERR_OFPFMFC_UNKNOWN; } fsr->cookie = ofsr->cookie; fsr->cookie_mask = ofsr->cookie_mask; error = ofputil_pull_ofp11_match(b, &fsr->match, NULL); if (error) { return error; } return 0; } static enum ofperr ofputil_decode_nxst_flow_request(struct ofputil_flow_stats_request *fsr, struct ofpbuf *b, bool aggregate) { const struct nx_flow_stats_request *nfsr; enum ofperr error; nfsr = ofpbuf_pull(b, sizeof *nfsr); error = nx_pull_match(b, ntohs(nfsr->match_len), &fsr->match, &fsr->cookie, &fsr->cookie_mask); if (error) { return error; } if (b->size) { return OFPERR_OFPBRC_BAD_LEN; } fsr->aggregate = aggregate; fsr->out_port = u16_to_ofp(ntohs(nfsr->out_port)); fsr->table_id = nfsr->table_id; return 0; } /* Converts an OFPST_FLOW, OFPST_AGGREGATE, NXST_FLOW, or NXST_AGGREGATE * request 'oh', into an abstract flow_stats_request in 'fsr'. Returns 0 if * successful, otherwise an OpenFlow error code. */ enum ofperr ofputil_decode_flow_stats_request(struct ofputil_flow_stats_request *fsr, const struct ofp_header *oh) { enum ofpraw raw; struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); switch ((int) raw) { case OFPRAW_OFPST10_FLOW_REQUEST: return ofputil_decode_ofpst10_flow_request(fsr, b.data, false); case OFPRAW_OFPST10_AGGREGATE_REQUEST: return ofputil_decode_ofpst10_flow_request(fsr, b.data, true); case OFPRAW_OFPST11_FLOW_REQUEST: return ofputil_decode_ofpst11_flow_request(fsr, &b, false); case OFPRAW_OFPST11_AGGREGATE_REQUEST: return ofputil_decode_ofpst11_flow_request(fsr, &b, true); case OFPRAW_NXST_FLOW_REQUEST: return ofputil_decode_nxst_flow_request(fsr, &b, false); case OFPRAW_NXST_AGGREGATE_REQUEST: return ofputil_decode_nxst_flow_request(fsr, &b, true); default: /* Hey, the caller lied. */ NOT_REACHED(); } } /* Converts abstract flow_stats_request 'fsr' into an OFPST_FLOW, * OFPST_AGGREGATE, NXST_FLOW, or NXST_AGGREGATE request 'oh' according to * 'protocol', and returns the message. */ struct ofpbuf * ofputil_encode_flow_stats_request(const struct ofputil_flow_stats_request *fsr, enum ofputil_protocol protocol) { struct ofpbuf *msg; enum ofpraw raw; switch (protocol) { case OFPUTIL_P_OF12_OXM: case OFPUTIL_P_OF13_OXM: { struct ofp11_flow_stats_request *ofsr; raw = (fsr->aggregate ? OFPRAW_OFPST11_AGGREGATE_REQUEST : OFPRAW_OFPST11_FLOW_REQUEST); msg = ofpraw_alloc(raw, ofputil_protocol_to_ofp_version(protocol), NXM_TYPICAL_LEN); ofsr = ofpbuf_put_zeros(msg, sizeof *ofsr); ofsr->table_id = fsr->table_id; ofsr->out_port = ofputil_port_to_ofp11(fsr->out_port); ofsr->out_group = htonl(OFPG11_ANY); ofsr->cookie = fsr->cookie; ofsr->cookie_mask = fsr->cookie_mask; oxm_put_match(msg, &fsr->match); break; } case OFPUTIL_P_OF10_STD: case OFPUTIL_P_OF10_STD_TID: { struct ofp10_flow_stats_request *ofsr; raw = (fsr->aggregate ? OFPRAW_OFPST10_AGGREGATE_REQUEST : OFPRAW_OFPST10_FLOW_REQUEST); msg = ofpraw_alloc(raw, OFP10_VERSION, 0); ofsr = ofpbuf_put_zeros(msg, sizeof *ofsr); ofputil_match_to_ofp10_match(&fsr->match, &ofsr->match); ofsr->table_id = fsr->table_id; ofsr->out_port = htons(ofp_to_u16(fsr->out_port)); break; } case OFPUTIL_P_OF10_NXM: case OFPUTIL_P_OF10_NXM_TID: { struct nx_flow_stats_request *nfsr; int match_len; raw = (fsr->aggregate ? OFPRAW_NXST_AGGREGATE_REQUEST : OFPRAW_NXST_FLOW_REQUEST); msg = ofpraw_alloc(raw, OFP10_VERSION, NXM_TYPICAL_LEN); ofpbuf_put_zeros(msg, sizeof *nfsr); match_len = nx_put_match(msg, &fsr->match, fsr->cookie, fsr->cookie_mask); nfsr = msg->l3; nfsr->out_port = htons(ofp_to_u16(fsr->out_port)); nfsr->match_len = htons(match_len); nfsr->table_id = fsr->table_id; break; } default: NOT_REACHED(); } return msg; } /* Returns a bitmask with a 1-bit for each protocol that could be used to * accurately encode 'fsr', and a 0-bit for each protocol that is inadequate. * * (The return value will have at least one 1-bit.) */ enum ofputil_protocol ofputil_flow_stats_request_usable_protocols( const struct ofputil_flow_stats_request *fsr) { enum ofputil_protocol usable_protocols; usable_protocols = ofputil_usable_protocols(&fsr->match); if (fsr->cookie_mask != htonll(0)) { usable_protocols &= OFPUTIL_P_OF10_NXM_ANY | OFPUTIL_P_OF12_OXM | OFPUTIL_P_OF13_OXM; } return usable_protocols; } /* Converts an OFPST_FLOW or NXST_FLOW reply in 'msg' into an abstract * ofputil_flow_stats in 'fs'. * * Multiple OFPST_FLOW or NXST_FLOW replies can be packed into a single * OpenFlow message. Calling this function multiple times for a single 'msg' * iterates through the replies. The caller must initially leave 'msg''s layer * pointers null and not modify them between calls. * * Most switches don't send the values needed to populate fs->idle_age and * fs->hard_age, so those members will usually be set to 0. If the switch from * which 'msg' originated is known to implement NXT_FLOW_AGE, then pass * 'flow_age_extension' as true so that the contents of 'msg' determine the * 'idle_age' and 'hard_age' members in 'fs'. * * Uses 'ofpacts' to store the abstract OFPACT_* version of the flow stats * reply's actions. The caller must initialize 'ofpacts' and retains ownership * of it. 'fs->ofpacts' will point into the 'ofpacts' buffer. * * Returns 0 if successful, EOF if no replies were left in this 'msg', * otherwise a positive errno value. */ int ofputil_decode_flow_stats_reply(struct ofputil_flow_stats *fs, struct ofpbuf *msg, bool flow_age_extension, struct ofpbuf *ofpacts) { enum ofperr error; enum ofpraw raw; error = (msg->l2 ? ofpraw_decode(&raw, msg->l2) : ofpraw_pull(&raw, msg)); if (error) { return error; } if (!msg->size) { return EOF; } else if (raw == OFPRAW_OFPST11_FLOW_REPLY || raw == OFPRAW_OFPST13_FLOW_REPLY) { const struct ofp11_flow_stats *ofs; size_t length; uint16_t padded_match_len; ofs = ofpbuf_try_pull(msg, sizeof *ofs); if (!ofs) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_FLOW reply has %zu leftover " "bytes at end", msg->size); return EINVAL; } length = ntohs(ofs->length); if (length < sizeof *ofs) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_FLOW reply claims invalid " "length %zu", length); return EINVAL; } if (ofputil_pull_ofp11_match(msg, &fs->match, &padded_match_len)) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_FLOW reply bad match"); return EINVAL; } if (ofpacts_pull_openflow11_instructions(msg, length - sizeof *ofs - padded_match_len, ofpacts)) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_FLOW reply bad instructions"); return EINVAL; } fs->priority = ntohs(ofs->priority); fs->table_id = ofs->table_id; fs->duration_sec = ntohl(ofs->duration_sec); fs->duration_nsec = ntohl(ofs->duration_nsec); fs->idle_timeout = ntohs(ofs->idle_timeout); fs->hard_timeout = ntohs(ofs->hard_timeout); fs->flags = (raw == OFPRAW_OFPST13_FLOW_REPLY) ? ntohs(ofs->flags) : 0; fs->idle_age = -1; fs->hard_age = -1; fs->cookie = ofs->cookie; fs->packet_count = ntohll(ofs->packet_count); fs->byte_count = ntohll(ofs->byte_count); } else if (raw == OFPRAW_OFPST10_FLOW_REPLY) { const struct ofp10_flow_stats *ofs; size_t length; ofs = ofpbuf_try_pull(msg, sizeof *ofs); if (!ofs) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_FLOW reply has %zu leftover " "bytes at end", msg->size); return EINVAL; } length = ntohs(ofs->length); if (length < sizeof *ofs) { VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_FLOW reply claims invalid " "length %zu", length); return EINVAL; } if (ofpacts_pull_openflow10(msg, length - sizeof *ofs, ofpacts)) { return EINVAL; } fs->cookie = get_32aligned_be64(&ofs->cookie); ofputil_match_from_ofp10_match(&ofs->match, &fs->match); fs->priority = ntohs(ofs->priority); fs->table_id = ofs->table_id; fs->duration_sec = ntohl(ofs->duration_sec); fs->duration_nsec = ntohl(ofs->duration_nsec); fs->idle_timeout = ntohs(ofs->idle_timeout); fs->hard_timeout = ntohs(ofs->hard_timeout); fs->idle_age = -1; fs->hard_age = -1; fs->packet_count = ntohll(get_32aligned_be64(&ofs->packet_count)); fs->byte_count = ntohll(get_32aligned_be64(&ofs->byte_count)); fs->flags = 0; } else if (raw == OFPRAW_NXST_FLOW_REPLY) { const struct nx_flow_stats *nfs; size_t match_len, actions_len, length; nfs = ofpbuf_try_pull(msg, sizeof *nfs); if (!nfs) { VLOG_WARN_RL(&bad_ofmsg_rl, "NXST_FLOW reply has %zu leftover " "bytes at end", msg->size); return EINVAL; } length = ntohs(nfs->length); match_len = ntohs(nfs->match_len); if (length < sizeof *nfs + ROUND_UP(match_len, 8)) { VLOG_WARN_RL(&bad_ofmsg_rl, "NXST_FLOW reply with match_len=%zu " "claims invalid length %zu", match_len, length); return EINVAL; } if (nx_pull_match(msg, match_len, &fs->match, NULL, NULL)) { return EINVAL; } actions_len = length - sizeof *nfs - ROUND_UP(match_len, 8); if (ofpacts_pull_openflow10(msg, actions_len, ofpacts)) { return EINVAL; } fs->cookie = nfs->cookie; fs->table_id = nfs->table_id; fs->duration_sec = ntohl(nfs->duration_sec); fs->duration_nsec = ntohl(nfs->duration_nsec); fs->priority = ntohs(nfs->priority); fs->idle_timeout = ntohs(nfs->idle_timeout); fs->hard_timeout = ntohs(nfs->hard_timeout); fs->idle_age = -1; fs->hard_age = -1; if (flow_age_extension) { if (nfs->idle_age) { fs->idle_age = ntohs(nfs->idle_age) - 1; } if (nfs->hard_age) { fs->hard_age = ntohs(nfs->hard_age) - 1; } } fs->packet_count = ntohll(nfs->packet_count); fs->byte_count = ntohll(nfs->byte_count); fs->flags = 0; } else { NOT_REACHED(); } fs->ofpacts = ofpacts->data; fs->ofpacts_len = ofpacts->size; return 0; } /* Returns 'count' unchanged except that UINT64_MAX becomes 0. * * We use this in situations where OVS internally uses UINT64_MAX to mean * "value unknown" but OpenFlow 1.0 does not define any unknown value. */ static uint64_t unknown_to_zero(uint64_t count) { return count != UINT64_MAX ? count : 0; } /* Appends an OFPST_FLOW or NXST_FLOW reply that contains the data in 'fs' to * those already present in the list of ofpbufs in 'replies'. 'replies' should * have been initialized with ofputil_start_stats_reply(). */ void ofputil_append_flow_stats_reply(const struct ofputil_flow_stats *fs, struct list *replies) { struct ofpbuf *reply = ofpbuf_from_list(list_back(replies)); size_t start_ofs = reply->size; enum ofpraw raw; ofpraw_decode_partial(&raw, reply->data, reply->size); if (raw == OFPRAW_OFPST11_FLOW_REPLY || raw == OFPRAW_OFPST13_FLOW_REPLY) { struct ofp11_flow_stats *ofs; ofpbuf_put_uninit(reply, sizeof *ofs); oxm_put_match(reply, &fs->match); ofpacts_put_openflow11_instructions(fs->ofpacts, fs->ofpacts_len, reply); ofs = ofpbuf_at_assert(reply, start_ofs, sizeof *ofs); ofs->length = htons(reply->size - start_ofs); ofs->table_id = fs->table_id; ofs->pad = 0; ofs->duration_sec = htonl(fs->duration_sec); ofs->duration_nsec = htonl(fs->duration_nsec); ofs->priority = htons(fs->priority); ofs->idle_timeout = htons(fs->idle_timeout); ofs->hard_timeout = htons(fs->hard_timeout); ofs->flags = (raw == OFPRAW_OFPST13_FLOW_REPLY) ? htons(fs->flags) : 0; memset(ofs->pad2, 0, sizeof ofs->pad2); ofs->cookie = fs->cookie; ofs->packet_count = htonll(unknown_to_zero(fs->packet_count)); ofs->byte_count = htonll(unknown_to_zero(fs->byte_count)); } else if (raw == OFPRAW_OFPST10_FLOW_REPLY) { struct ofp10_flow_stats *ofs; ofpbuf_put_uninit(reply, sizeof *ofs); ofpacts_put_openflow10(fs->ofpacts, fs->ofpacts_len, reply); ofs = ofpbuf_at_assert(reply, start_ofs, sizeof *ofs); ofs->length = htons(reply->size - start_ofs); ofs->table_id = fs->table_id; ofs->pad = 0; ofputil_match_to_ofp10_match(&fs->match, &ofs->match); ofs->duration_sec = htonl(fs->duration_sec); ofs->duration_nsec = htonl(fs->duration_nsec); ofs->priority = htons(fs->priority); ofs->idle_timeout = htons(fs->idle_timeout); ofs->hard_timeout = htons(fs->hard_timeout); memset(ofs->pad2, 0, sizeof ofs->pad2); put_32aligned_be64(&ofs->cookie, fs->cookie); put_32aligned_be64(&ofs->packet_count, htonll(unknown_to_zero(fs->packet_count))); put_32aligned_be64(&ofs->byte_count, htonll(unknown_to_zero(fs->byte_count))); } else if (raw == OFPRAW_NXST_FLOW_REPLY) { struct nx_flow_stats *nfs; int match_len; ofpbuf_put_uninit(reply, sizeof *nfs); match_len = nx_put_match(reply, &fs->match, 0, 0); ofpacts_put_openflow10(fs->ofpacts, fs->ofpacts_len, reply); nfs = ofpbuf_at_assert(reply, start_ofs, sizeof *nfs); nfs->length = htons(reply->size - start_ofs); nfs->table_id = fs->table_id; nfs->pad = 0; nfs->duration_sec = htonl(fs->duration_sec); nfs->duration_nsec = htonl(fs->duration_nsec); nfs->priority = htons(fs->priority); nfs->idle_timeout = htons(fs->idle_timeout); nfs->hard_timeout = htons(fs->hard_timeout); nfs->idle_age = htons(fs->idle_age < 0 ? 0 : fs->idle_age < UINT16_MAX ? fs->idle_age + 1 : UINT16_MAX); nfs->hard_age = htons(fs->hard_age < 0 ? 0 : fs->hard_age < UINT16_MAX ? fs->hard_age + 1 : UINT16_MAX); nfs->match_len = htons(match_len); nfs->cookie = fs->cookie; nfs->packet_count = htonll(fs->packet_count); nfs->byte_count = htonll(fs->byte_count); } else { NOT_REACHED(); } ofpmp_postappend(replies, start_ofs); } /* Converts abstract ofputil_aggregate_stats 'stats' into an OFPST_AGGREGATE or * NXST_AGGREGATE reply matching 'request', and returns the message. */ struct ofpbuf * ofputil_encode_aggregate_stats_reply( const struct ofputil_aggregate_stats *stats, const struct ofp_header *request) { struct ofp_aggregate_stats_reply *asr; uint64_t packet_count; uint64_t byte_count; struct ofpbuf *msg; enum ofpraw raw; ofpraw_decode(&raw, request); if (raw == OFPRAW_OFPST10_AGGREGATE_REQUEST) { packet_count = unknown_to_zero(stats->packet_count); byte_count = unknown_to_zero(stats->byte_count); } else { packet_count = stats->packet_count; byte_count = stats->byte_count; } msg = ofpraw_alloc_stats_reply(request, 0); asr = ofpbuf_put_zeros(msg, sizeof *asr); put_32aligned_be64(&asr->packet_count, htonll(packet_count)); put_32aligned_be64(&asr->byte_count, htonll(byte_count)); asr->flow_count = htonl(stats->flow_count); return msg; } enum ofperr ofputil_decode_aggregate_stats_reply(struct ofputil_aggregate_stats *stats, const struct ofp_header *reply) { struct ofp_aggregate_stats_reply *asr; struct ofpbuf msg; ofpbuf_use_const(&msg, reply, ntohs(reply->length)); ofpraw_pull_assert(&msg); asr = msg.l3; stats->packet_count = ntohll(get_32aligned_be64(&asr->packet_count)); stats->byte_count = ntohll(get_32aligned_be64(&asr->byte_count)); stats->flow_count = ntohl(asr->flow_count); return 0; } /* Converts an OFPT_FLOW_REMOVED or NXT_FLOW_REMOVED message 'oh' into an * abstract ofputil_flow_removed in 'fr'. Returns 0 if successful, otherwise * an OpenFlow error code. */ enum ofperr ofputil_decode_flow_removed(struct ofputil_flow_removed *fr, const struct ofp_header *oh) { enum ofpraw raw; struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); if (raw == OFPRAW_OFPT11_FLOW_REMOVED) { const struct ofp12_flow_removed *ofr; enum ofperr error; ofr = ofpbuf_pull(&b, sizeof *ofr); error = ofputil_pull_ofp11_match(&b, &fr->match, NULL); if (error) { return error; } fr->priority = ntohs(ofr->priority); fr->cookie = ofr->cookie; fr->reason = ofr->reason; fr->table_id = ofr->table_id; fr->duration_sec = ntohl(ofr->duration_sec); fr->duration_nsec = ntohl(ofr->duration_nsec); fr->idle_timeout = ntohs(ofr->idle_timeout); fr->hard_timeout = ntohs(ofr->hard_timeout); fr->packet_count = ntohll(ofr->packet_count); fr->byte_count = ntohll(ofr->byte_count); } else if (raw == OFPRAW_OFPT10_FLOW_REMOVED) { const struct ofp10_flow_removed *ofr; ofr = ofpbuf_pull(&b, sizeof *ofr); ofputil_match_from_ofp10_match(&ofr->match, &fr->match); fr->priority = ntohs(ofr->priority); fr->cookie = ofr->cookie; fr->reason = ofr->reason; fr->table_id = 255; fr->duration_sec = ntohl(ofr->duration_sec); fr->duration_nsec = ntohl(ofr->duration_nsec); fr->idle_timeout = ntohs(ofr->idle_timeout); fr->hard_timeout = 0; fr->packet_count = ntohll(ofr->packet_count); fr->byte_count = ntohll(ofr->byte_count); } else if (raw == OFPRAW_NXT_FLOW_REMOVED) { struct nx_flow_removed *nfr; enum ofperr error; nfr = ofpbuf_pull(&b, sizeof *nfr); error = nx_pull_match(&b, ntohs(nfr->match_len), &fr->match, NULL, NULL); if (error) { return error; } if (b.size) { return OFPERR_OFPBRC_BAD_LEN; } fr->priority = ntohs(nfr->priority); fr->cookie = nfr->cookie; fr->reason = nfr->reason; fr->table_id = nfr->table_id ? nfr->table_id - 1 : 255; fr->duration_sec = ntohl(nfr->duration_sec); fr->duration_nsec = ntohl(nfr->duration_nsec); fr->idle_timeout = ntohs(nfr->idle_timeout); fr->hard_timeout = 0; fr->packet_count = ntohll(nfr->packet_count); fr->byte_count = ntohll(nfr->byte_count); } else { NOT_REACHED(); } return 0; } /* Converts abstract ofputil_flow_removed 'fr' into an OFPT_FLOW_REMOVED or * NXT_FLOW_REMOVED message 'oh' according to 'protocol', and returns the * message. */ struct ofpbuf * ofputil_encode_flow_removed(const struct ofputil_flow_removed *fr, enum ofputil_protocol protocol) { struct ofpbuf *msg; switch (protocol) { case OFPUTIL_P_OF12_OXM: case OFPUTIL_P_OF13_OXM: { struct ofp12_flow_removed *ofr; msg = ofpraw_alloc_xid(OFPRAW_OFPT11_FLOW_REMOVED, ofputil_protocol_to_ofp_version(protocol), htonl(0), NXM_TYPICAL_LEN); ofr = ofpbuf_put_zeros(msg, sizeof *ofr); ofr->cookie = fr->cookie; ofr->priority = htons(fr->priority); ofr->reason = fr->reason; ofr->table_id = fr->table_id; ofr->duration_sec = htonl(fr->duration_sec); ofr->duration_nsec = htonl(fr->duration_nsec); ofr->idle_timeout = htons(fr->idle_timeout); ofr->hard_timeout = htons(fr->hard_timeout); ofr->packet_count = htonll(fr->packet_count); ofr->byte_count = htonll(fr->byte_count); oxm_put_match(msg, &fr->match); break; } case OFPUTIL_P_OF10_STD: case OFPUTIL_P_OF10_STD_TID: { struct ofp10_flow_removed *ofr; msg = ofpraw_alloc_xid(OFPRAW_OFPT10_FLOW_REMOVED, OFP10_VERSION, htonl(0), 0); ofr = ofpbuf_put_zeros(msg, sizeof *ofr); ofputil_match_to_ofp10_match(&fr->match, &ofr->match); ofr->cookie = fr->cookie; ofr->priority = htons(fr->priority); ofr->reason = fr->reason; ofr->duration_sec = htonl(fr->duration_sec); ofr->duration_nsec = htonl(fr->duration_nsec); ofr->idle_timeout = htons(fr->idle_timeout); ofr->packet_count = htonll(unknown_to_zero(fr->packet_count)); ofr->byte_count = htonll(unknown_to_zero(fr->byte_count)); break; } case OFPUTIL_P_OF10_NXM: case OFPUTIL_P_OF10_NXM_TID: { struct nx_flow_removed *nfr; int match_len; msg = ofpraw_alloc_xid(OFPRAW_NXT_FLOW_REMOVED, OFP10_VERSION, htonl(0), NXM_TYPICAL_LEN); nfr = ofpbuf_put_zeros(msg, sizeof *nfr); match_len = nx_put_match(msg, &fr->match, 0, 0); nfr = msg->l3; nfr->cookie = fr->cookie; nfr->priority = htons(fr->priority); nfr->reason = fr->reason; nfr->table_id = fr->table_id + 1; nfr->duration_sec = htonl(fr->duration_sec); nfr->duration_nsec = htonl(fr->duration_nsec); nfr->idle_timeout = htons(fr->idle_timeout); nfr->match_len = htons(match_len); nfr->packet_count = htonll(fr->packet_count); nfr->byte_count = htonll(fr->byte_count); break; } default: NOT_REACHED(); } return msg; } static void ofputil_decode_packet_in_finish(struct ofputil_packet_in *pin, struct match *match, struct ofpbuf *b) { pin->packet = b->data; pin->packet_len = b->size; pin->fmd.in_port = match->flow.in_port.ofp_port; pin->fmd.tun_id = match->flow.tunnel.tun_id; pin->fmd.tun_src = match->flow.tunnel.ip_src; pin->fmd.tun_dst = match->flow.tunnel.ip_dst; pin->fmd.metadata = match->flow.metadata; memcpy(pin->fmd.regs, match->flow.regs, sizeof pin->fmd.regs); } enum ofperr ofputil_decode_packet_in(struct ofputil_packet_in *pin, const struct ofp_header *oh) { enum ofpraw raw; struct ofpbuf b; memset(pin, 0, sizeof *pin); ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); if (raw == OFPRAW_OFPT13_PACKET_IN || raw == OFPRAW_OFPT12_PACKET_IN) { const struct ofp13_packet_in *opi; struct match match; int error; size_t packet_in_size; if (raw == OFPRAW_OFPT12_PACKET_IN) { packet_in_size = sizeof (struct ofp12_packet_in); } else { packet_in_size = sizeof (struct ofp13_packet_in); } opi = ofpbuf_pull(&b, packet_in_size); error = oxm_pull_match_loose(&b, &match); if (error) { return error; } if (!ofpbuf_try_pull(&b, 2)) { return OFPERR_OFPBRC_BAD_LEN; } pin->reason = opi->pi.reason; pin->table_id = opi->pi.table_id; pin->buffer_id = ntohl(opi->pi.buffer_id); pin->total_len = ntohs(opi->pi.total_len); if (raw == OFPRAW_OFPT13_PACKET_IN) { pin->cookie = opi->cookie; } ofputil_decode_packet_in_finish(pin, &match, &b); } else if (raw == OFPRAW_OFPT10_PACKET_IN) { const struct ofp10_packet_in *opi; opi = ofpbuf_pull(&b, offsetof(struct ofp10_packet_in, data)); pin->packet = opi->data; pin->packet_len = b.size; pin->fmd.in_port = u16_to_ofp(ntohs(opi->in_port)); pin->reason = opi->reason; pin->buffer_id = ntohl(opi->buffer_id); pin->total_len = ntohs(opi->total_len); } else if (raw == OFPRAW_NXT_PACKET_IN) { const struct nx_packet_in *npi; struct match match; int error; npi = ofpbuf_pull(&b, sizeof *npi); error = nx_pull_match_loose(&b, ntohs(npi->match_len), &match, NULL, NULL); if (error) { return error; } if (!ofpbuf_try_pull(&b, 2)) { return OFPERR_OFPBRC_BAD_LEN; } pin->reason = npi->reason; pin->table_id = npi->table_id; pin->cookie = npi->cookie; pin->buffer_id = ntohl(npi->buffer_id); pin->total_len = ntohs(npi->total_len); ofputil_decode_packet_in_finish(pin, &match, &b); } else { NOT_REACHED(); } return 0; } static void ofputil_packet_in_to_match(const struct ofputil_packet_in *pin, struct match *match) { int i; match_init_catchall(match); if (pin->fmd.tun_id != htonll(0)) { match_set_tun_id(match, pin->fmd.tun_id); } if (pin->fmd.tun_src != htonl(0)) { match_set_tun_src(match, pin->fmd.tun_src); } if (pin->fmd.tun_dst != htonl(0)) { match_set_tun_dst(match, pin->fmd.tun_dst); } if (pin->fmd.metadata != htonll(0)) { match_set_metadata(match, pin->fmd.metadata); } for (i = 0; i < FLOW_N_REGS; i++) { if (pin->fmd.regs[i]) { match_set_reg(match, i, pin->fmd.regs[i]); } } match_set_in_port(match, pin->fmd.in_port); } /* Converts abstract ofputil_packet_in 'pin' into a PACKET_IN message * in the format specified by 'packet_in_format'. */ struct ofpbuf * ofputil_encode_packet_in(const struct ofputil_packet_in *pin, enum ofputil_protocol protocol, enum nx_packet_in_format packet_in_format) { size_t send_len = MIN(pin->send_len, pin->packet_len); struct ofpbuf *packet; /* Add OFPT_PACKET_IN. */ if (protocol == OFPUTIL_P_OF13_OXM || protocol == OFPUTIL_P_OF12_OXM) { struct ofp13_packet_in *opi; struct match match; enum ofpraw packet_in_raw; enum ofp_version packet_in_version; size_t packet_in_size; if (protocol == OFPUTIL_P_OF12_OXM) { packet_in_raw = OFPRAW_OFPT12_PACKET_IN; packet_in_version = OFP12_VERSION; packet_in_size = sizeof (struct ofp12_packet_in); } else { packet_in_raw = OFPRAW_OFPT13_PACKET_IN; packet_in_version = OFP13_VERSION; packet_in_size = sizeof (struct ofp13_packet_in); } ofputil_packet_in_to_match(pin, &match); /* The final argument is just an estimate of the space required. */ packet = ofpraw_alloc_xid(packet_in_raw, packet_in_version, htonl(0), (sizeof(struct flow_metadata) * 2 + 2 + send_len)); ofpbuf_put_zeros(packet, packet_in_size); oxm_put_match(packet, &match); ofpbuf_put_zeros(packet, 2); ofpbuf_put(packet, pin->packet, send_len); opi = packet->l3; opi->pi.buffer_id = htonl(pin->buffer_id); opi->pi.total_len = htons(pin->total_len); opi->pi.reason = pin->reason; opi->pi.table_id = pin->table_id; if (protocol == OFPUTIL_P_OF13_OXM) { opi->cookie = pin->cookie; } } else if (packet_in_format == NXPIF_OPENFLOW10) { struct ofp10_packet_in *opi; packet = ofpraw_alloc_xid(OFPRAW_OFPT10_PACKET_IN, OFP10_VERSION, htonl(0), send_len); opi = ofpbuf_put_zeros(packet, offsetof(struct ofp10_packet_in, data)); opi->total_len = htons(pin->total_len); opi->in_port = htons(ofp_to_u16(pin->fmd.in_port)); opi->reason = pin->reason; opi->buffer_id = htonl(pin->buffer_id); ofpbuf_put(packet, pin->packet, send_len); } else if (packet_in_format == NXPIF_NXM) { struct nx_packet_in *npi; struct match match; size_t match_len; ofputil_packet_in_to_match(pin, &match); /* The final argument is just an estimate of the space required. */ packet = ofpraw_alloc_xid(OFPRAW_NXT_PACKET_IN, OFP10_VERSION, htonl(0), (sizeof(struct flow_metadata) * 2 + 2 + send_len)); ofpbuf_put_zeros(packet, sizeof *npi); match_len = nx_put_match(packet, &match, 0, 0); ofpbuf_put_zeros(packet, 2); ofpbuf_put(packet, pin->packet, send_len); npi = packet->l3; npi->buffer_id = htonl(pin->buffer_id); npi->total_len = htons(pin->total_len); npi->reason = pin->reason; npi->table_id = pin->table_id; npi->cookie = pin->cookie; npi->match_len = htons(match_len); } else { NOT_REACHED(); } ofpmsg_update_length(packet); return packet; } /* Returns a string form of 'reason'. The return value is either a statically * allocated constant string or the 'bufsize'-byte buffer 'reasonbuf'. * 'bufsize' should be at least OFPUTIL_PACKET_IN_REASON_BUFSIZE. */ const char * ofputil_packet_in_reason_to_string(enum ofp_packet_in_reason reason, char *reasonbuf, size_t bufsize) { switch (reason) { case OFPR_NO_MATCH: return "no_match"; case OFPR_ACTION: return "action"; case OFPR_INVALID_TTL: return "invalid_ttl"; case OFPR_N_REASONS: default: snprintf(reasonbuf, bufsize, "%d", (int) reason); return reasonbuf; } } bool ofputil_packet_in_reason_from_string(const char *s, enum ofp_packet_in_reason *reason) { int i; for (i = 0; i < OFPR_N_REASONS; i++) { char reasonbuf[OFPUTIL_PACKET_IN_REASON_BUFSIZE]; const char *reason_s; reason_s = ofputil_packet_in_reason_to_string(i, reasonbuf, sizeof reasonbuf); if (!strcasecmp(s, reason_s)) { *reason = i; return true; } } return false; } /* Converts an OFPT_PACKET_OUT in 'opo' into an abstract ofputil_packet_out in * 'po'. * * Uses 'ofpacts' to store the abstract OFPACT_* version of the packet out * message's actions. The caller must initialize 'ofpacts' and retains * ownership of it. 'po->ofpacts' will point into the 'ofpacts' buffer. * * Returns 0 if successful, otherwise an OFPERR_* value. */ enum ofperr ofputil_decode_packet_out(struct ofputil_packet_out *po, const struct ofp_header *oh, struct ofpbuf *ofpacts) { enum ofpraw raw; struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); if (raw == OFPRAW_OFPT11_PACKET_OUT) { enum ofperr error; const struct ofp11_packet_out *opo = ofpbuf_pull(&b, sizeof *opo); po->buffer_id = ntohl(opo->buffer_id); error = ofputil_port_from_ofp11(opo->in_port, &po->in_port); if (error) { return error; } error = ofpacts_pull_openflow11_actions(&b, ntohs(opo->actions_len), ofpacts); if (error) { return error; } } else if (raw == OFPRAW_OFPT10_PACKET_OUT) { enum ofperr error; const struct ofp10_packet_out *opo = ofpbuf_pull(&b, sizeof *opo); po->buffer_id = ntohl(opo->buffer_id); po->in_port = u16_to_ofp(ntohs(opo->in_port)); error = ofpacts_pull_openflow10(&b, ntohs(opo->actions_len), ofpacts); if (error) { return error; } } else { NOT_REACHED(); } if (ofp_to_u16(po->in_port) >= ofp_to_u16(OFPP_MAX) && po->in_port != OFPP_LOCAL && po->in_port != OFPP_NONE && po->in_port != OFPP_CONTROLLER) { VLOG_WARN_RL(&bad_ofmsg_rl, "packet-out has bad input port %#"PRIx16, po->in_port); return OFPERR_OFPBRC_BAD_PORT; } po->ofpacts = ofpacts->data; po->ofpacts_len = ofpacts->size; if (po->buffer_id == UINT32_MAX) { po->packet = b.data; po->packet_len = b.size; } else { po->packet = NULL; po->packet_len = 0; } return 0; } /* ofputil_phy_port */ /* NETDEV_F_* to and from OFPPF_* and OFPPF10_*. */ BUILD_ASSERT_DECL((int) NETDEV_F_10MB_HD == OFPPF_10MB_HD); /* bit 0 */ BUILD_ASSERT_DECL((int) NETDEV_F_10MB_FD == OFPPF_10MB_FD); /* bit 1 */ BUILD_ASSERT_DECL((int) NETDEV_F_100MB_HD == OFPPF_100MB_HD); /* bit 2 */ BUILD_ASSERT_DECL((int) NETDEV_F_100MB_FD == OFPPF_100MB_FD); /* bit 3 */ BUILD_ASSERT_DECL((int) NETDEV_F_1GB_HD == OFPPF_1GB_HD); /* bit 4 */ BUILD_ASSERT_DECL((int) NETDEV_F_1GB_FD == OFPPF_1GB_FD); /* bit 5 */ BUILD_ASSERT_DECL((int) NETDEV_F_10GB_FD == OFPPF_10GB_FD); /* bit 6 */ /* NETDEV_F_ bits 11...15 are OFPPF10_ bits 7...11: */ BUILD_ASSERT_DECL((int) NETDEV_F_COPPER == (OFPPF10_COPPER << 4)); BUILD_ASSERT_DECL((int) NETDEV_F_FIBER == (OFPPF10_FIBER << 4)); BUILD_ASSERT_DECL((int) NETDEV_F_AUTONEG == (OFPPF10_AUTONEG << 4)); BUILD_ASSERT_DECL((int) NETDEV_F_PAUSE == (OFPPF10_PAUSE << 4)); BUILD_ASSERT_DECL((int) NETDEV_F_PAUSE_ASYM == (OFPPF10_PAUSE_ASYM << 4)); static enum netdev_features netdev_port_features_from_ofp10(ovs_be32 ofp10_) { uint32_t ofp10 = ntohl(ofp10_); return (ofp10 & 0x7f) | ((ofp10 & 0xf80) << 4); } static ovs_be32 netdev_port_features_to_ofp10(enum netdev_features features) { return htonl((features & 0x7f) | ((features & 0xf800) >> 4)); } BUILD_ASSERT_DECL((int) NETDEV_F_10MB_HD == OFPPF_10MB_HD); /* bit 0 */ BUILD_ASSERT_DECL((int) NETDEV_F_10MB_FD == OFPPF_10MB_FD); /* bit 1 */ BUILD_ASSERT_DECL((int) NETDEV_F_100MB_HD == OFPPF_100MB_HD); /* bit 2 */ BUILD_ASSERT_DECL((int) NETDEV_F_100MB_FD == OFPPF_100MB_FD); /* bit 3 */ BUILD_ASSERT_DECL((int) NETDEV_F_1GB_HD == OFPPF_1GB_HD); /* bit 4 */ BUILD_ASSERT_DECL((int) NETDEV_F_1GB_FD == OFPPF_1GB_FD); /* bit 5 */ BUILD_ASSERT_DECL((int) NETDEV_F_10GB_FD == OFPPF_10GB_FD); /* bit 6 */ BUILD_ASSERT_DECL((int) NETDEV_F_40GB_FD == OFPPF11_40GB_FD); /* bit 7 */ BUILD_ASSERT_DECL((int) NETDEV_F_100GB_FD == OFPPF11_100GB_FD); /* bit 8 */ BUILD_ASSERT_DECL((int) NETDEV_F_1TB_FD == OFPPF11_1TB_FD); /* bit 9 */ BUILD_ASSERT_DECL((int) NETDEV_F_OTHER == OFPPF11_OTHER); /* bit 10 */ BUILD_ASSERT_DECL((int) NETDEV_F_COPPER == OFPPF11_COPPER); /* bit 11 */ BUILD_ASSERT_DECL((int) NETDEV_F_FIBER == OFPPF11_FIBER); /* bit 12 */ BUILD_ASSERT_DECL((int) NETDEV_F_AUTONEG == OFPPF11_AUTONEG); /* bit 13 */ BUILD_ASSERT_DECL((int) NETDEV_F_PAUSE == OFPPF11_PAUSE); /* bit 14 */ BUILD_ASSERT_DECL((int) NETDEV_F_PAUSE_ASYM == OFPPF11_PAUSE_ASYM);/* bit 15 */ static enum netdev_features netdev_port_features_from_ofp11(ovs_be32 ofp11) { return ntohl(ofp11) & 0xffff; } static ovs_be32 netdev_port_features_to_ofp11(enum netdev_features features) { return htonl(features & 0xffff); } static enum ofperr ofputil_decode_ofp10_phy_port(struct ofputil_phy_port *pp, const struct ofp10_phy_port *opp) { memset(pp, 0, sizeof *pp); pp->port_no = u16_to_ofp(ntohs(opp->port_no)); memcpy(pp->hw_addr, opp->hw_addr, OFP_ETH_ALEN); ovs_strlcpy(pp->name, opp->name, OFP_MAX_PORT_NAME_LEN); pp->config = ntohl(opp->config) & OFPPC10_ALL; pp->state = ntohl(opp->state) & OFPPS10_ALL; pp->curr = netdev_port_features_from_ofp10(opp->curr); pp->advertised = netdev_port_features_from_ofp10(opp->advertised); pp->supported = netdev_port_features_from_ofp10(opp->supported); pp->peer = netdev_port_features_from_ofp10(opp->peer); pp->curr_speed = netdev_features_to_bps(pp->curr, 0) / 1000; pp->max_speed = netdev_features_to_bps(pp->supported, 0) / 1000; return 0; } static enum ofperr ofputil_decode_ofp11_port(struct ofputil_phy_port *pp, const struct ofp11_port *op) { enum ofperr error; memset(pp, 0, sizeof *pp); error = ofputil_port_from_ofp11(op->port_no, &pp->port_no); if (error) { return error; } memcpy(pp->hw_addr, op->hw_addr, OFP_ETH_ALEN); ovs_strlcpy(pp->name, op->name, OFP_MAX_PORT_NAME_LEN); pp->config = ntohl(op->config) & OFPPC11_ALL; pp->state = ntohl(op->state) & OFPPC11_ALL; pp->curr = netdev_port_features_from_ofp11(op->curr); pp->advertised = netdev_port_features_from_ofp11(op->advertised); pp->supported = netdev_port_features_from_ofp11(op->supported); pp->peer = netdev_port_features_from_ofp11(op->peer); pp->curr_speed = ntohl(op->curr_speed); pp->max_speed = ntohl(op->max_speed); return 0; } static size_t ofputil_get_phy_port_size(enum ofp_version ofp_version) { switch (ofp_version) { case OFP10_VERSION: return sizeof(struct ofp10_phy_port); case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: return sizeof(struct ofp11_port); default: NOT_REACHED(); } } static void ofputil_encode_ofp10_phy_port(const struct ofputil_phy_port *pp, struct ofp10_phy_port *opp) { memset(opp, 0, sizeof *opp); opp->port_no = htons(ofp_to_u16(pp->port_no)); memcpy(opp->hw_addr, pp->hw_addr, ETH_ADDR_LEN); ovs_strlcpy(opp->name, pp->name, OFP_MAX_PORT_NAME_LEN); opp->config = htonl(pp->config & OFPPC10_ALL); opp->state = htonl(pp->state & OFPPS10_ALL); opp->curr = netdev_port_features_to_ofp10(pp->curr); opp->advertised = netdev_port_features_to_ofp10(pp->advertised); opp->supported = netdev_port_features_to_ofp10(pp->supported); opp->peer = netdev_port_features_to_ofp10(pp->peer); } static void ofputil_encode_ofp11_port(const struct ofputil_phy_port *pp, struct ofp11_port *op) { memset(op, 0, sizeof *op); op->port_no = ofputil_port_to_ofp11(pp->port_no); memcpy(op->hw_addr, pp->hw_addr, ETH_ADDR_LEN); ovs_strlcpy(op->name, pp->name, OFP_MAX_PORT_NAME_LEN); op->config = htonl(pp->config & OFPPC11_ALL); op->state = htonl(pp->state & OFPPS11_ALL); op->curr = netdev_port_features_to_ofp11(pp->curr); op->advertised = netdev_port_features_to_ofp11(pp->advertised); op->supported = netdev_port_features_to_ofp11(pp->supported); op->peer = netdev_port_features_to_ofp11(pp->peer); op->curr_speed = htonl(pp->curr_speed); op->max_speed = htonl(pp->max_speed); } static void ofputil_put_phy_port(enum ofp_version ofp_version, const struct ofputil_phy_port *pp, struct ofpbuf *b) { switch (ofp_version) { case OFP10_VERSION: { struct ofp10_phy_port *opp; if (b->size + sizeof *opp <= UINT16_MAX) { opp = ofpbuf_put_uninit(b, sizeof *opp); ofputil_encode_ofp10_phy_port(pp, opp); } break; } case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { struct ofp11_port *op; if (b->size + sizeof *op <= UINT16_MAX) { op = ofpbuf_put_uninit(b, sizeof *op); ofputil_encode_ofp11_port(pp, op); } break; } default: NOT_REACHED(); } } void ofputil_append_port_desc_stats_reply(enum ofp_version ofp_version, const struct ofputil_phy_port *pp, struct list *replies) { switch (ofp_version) { case OFP10_VERSION: { struct ofp10_phy_port *opp; opp = ofpmp_append(replies, sizeof *opp); ofputil_encode_ofp10_phy_port(pp, opp); break; } case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { struct ofp11_port *op; op = ofpmp_append(replies, sizeof *op); ofputil_encode_ofp11_port(pp, op); break; } default: NOT_REACHED(); } } /* ofputil_switch_features */ #define OFPC_COMMON (OFPC_FLOW_STATS | OFPC_TABLE_STATS | OFPC_PORT_STATS | \ OFPC_IP_REASM | OFPC_QUEUE_STATS) BUILD_ASSERT_DECL((int) OFPUTIL_C_FLOW_STATS == OFPC_FLOW_STATS); BUILD_ASSERT_DECL((int) OFPUTIL_C_TABLE_STATS == OFPC_TABLE_STATS); BUILD_ASSERT_DECL((int) OFPUTIL_C_PORT_STATS == OFPC_PORT_STATS); BUILD_ASSERT_DECL((int) OFPUTIL_C_IP_REASM == OFPC_IP_REASM); BUILD_ASSERT_DECL((int) OFPUTIL_C_QUEUE_STATS == OFPC_QUEUE_STATS); BUILD_ASSERT_DECL((int) OFPUTIL_C_ARP_MATCH_IP == OFPC_ARP_MATCH_IP); struct ofputil_action_bit_translation { enum ofputil_action_bitmap ofputil_bit; int of_bit; }; static const struct ofputil_action_bit_translation of10_action_bits[] = { { OFPUTIL_A_OUTPUT, OFPAT10_OUTPUT }, { OFPUTIL_A_SET_VLAN_VID, OFPAT10_SET_VLAN_VID }, { OFPUTIL_A_SET_VLAN_PCP, OFPAT10_SET_VLAN_PCP }, { OFPUTIL_A_STRIP_VLAN, OFPAT10_STRIP_VLAN }, { OFPUTIL_A_SET_DL_SRC, OFPAT10_SET_DL_SRC }, { OFPUTIL_A_SET_DL_DST, OFPAT10_SET_DL_DST }, { OFPUTIL_A_SET_NW_SRC, OFPAT10_SET_NW_SRC }, { OFPUTIL_A_SET_NW_DST, OFPAT10_SET_NW_DST }, { OFPUTIL_A_SET_NW_TOS, OFPAT10_SET_NW_TOS }, { OFPUTIL_A_SET_TP_SRC, OFPAT10_SET_TP_SRC }, { OFPUTIL_A_SET_TP_DST, OFPAT10_SET_TP_DST }, { OFPUTIL_A_ENQUEUE, OFPAT10_ENQUEUE }, { 0, 0 }, }; static enum ofputil_action_bitmap decode_action_bits(ovs_be32 of_actions, const struct ofputil_action_bit_translation *x) { enum ofputil_action_bitmap ofputil_actions; ofputil_actions = 0; for (; x->ofputil_bit; x++) { if (of_actions & htonl(1u << x->of_bit)) { ofputil_actions |= x->ofputil_bit; } } return ofputil_actions; } static uint32_t ofputil_capabilities_mask(enum ofp_version ofp_version) { /* Handle capabilities whose bit is unique for all Open Flow versions */ switch (ofp_version) { case OFP10_VERSION: case OFP11_VERSION: return OFPC_COMMON | OFPC_ARP_MATCH_IP; case OFP12_VERSION: case OFP13_VERSION: return OFPC_COMMON | OFPC12_PORT_BLOCKED; default: /* Caller needs to check osf->header.version itself */ return 0; } } /* Decodes an OpenFlow 1.0 or 1.1 "switch_features" structure 'osf' into an * abstract representation in '*features'. Initializes '*b' to iterate over * the OpenFlow port structures following 'osf' with later calls to * ofputil_pull_phy_port(). Returns 0 if successful, otherwise an * OFPERR_* value. */ enum ofperr ofputil_decode_switch_features(const struct ofp_header *oh, struct ofputil_switch_features *features, struct ofpbuf *b) { const struct ofp_switch_features *osf; enum ofpraw raw; ofpbuf_use_const(b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(b); osf = ofpbuf_pull(b, sizeof *osf); features->datapath_id = ntohll(osf->datapath_id); features->n_buffers = ntohl(osf->n_buffers); features->n_tables = osf->n_tables; features->auxiliary_id = 0; features->capabilities = ntohl(osf->capabilities) & ofputil_capabilities_mask(oh->version); if (b->size % ofputil_get_phy_port_size(oh->version)) { return OFPERR_OFPBRC_BAD_LEN; } if (raw == OFPRAW_OFPT10_FEATURES_REPLY) { if (osf->capabilities & htonl(OFPC10_STP)) { features->capabilities |= OFPUTIL_C_STP; } features->actions = decode_action_bits(osf->actions, of10_action_bits); } else if (raw == OFPRAW_OFPT11_FEATURES_REPLY || raw == OFPRAW_OFPT13_FEATURES_REPLY) { if (osf->capabilities & htonl(OFPC11_GROUP_STATS)) { features->capabilities |= OFPUTIL_C_GROUP_STATS; } features->actions = 0; if (raw == OFPRAW_OFPT13_FEATURES_REPLY) { features->auxiliary_id = osf->auxiliary_id; } } else { return OFPERR_OFPBRC_BAD_VERSION; } return 0; } /* Returns true if the maximum number of ports are in 'oh'. */ static bool max_ports_in_features(const struct ofp_header *oh) { size_t pp_size = ofputil_get_phy_port_size(oh->version); return ntohs(oh->length) + pp_size > UINT16_MAX; } /* Given a buffer 'b' that contains a Features Reply message, checks if * it contains the maximum number of ports that will fit. If so, it * returns true and removes the ports from the message. The caller * should then send an OFPST_PORT_DESC stats request to get the ports, * since the switch may have more ports than could be represented in the * Features Reply. Otherwise, returns false. */ bool ofputil_switch_features_ports_trunc(struct ofpbuf *b) { struct ofp_header *oh = b->data; if (max_ports_in_features(oh)) { /* Remove all the ports. */ b->size = (sizeof(struct ofp_header) + sizeof(struct ofp_switch_features)); ofpmsg_update_length(b); return true; } return false; } static ovs_be32 encode_action_bits(enum ofputil_action_bitmap ofputil_actions, const struct ofputil_action_bit_translation *x) { uint32_t of_actions; of_actions = 0; for (; x->ofputil_bit; x++) { if (ofputil_actions & x->ofputil_bit) { of_actions |= 1 << x->of_bit; } } return htonl(of_actions); } /* Returns a buffer owned by the caller that encodes 'features' in the format * required by 'protocol' with the given 'xid'. The caller should append port * information to the buffer with subsequent calls to * ofputil_put_switch_features_port(). */ struct ofpbuf * ofputil_encode_switch_features(const struct ofputil_switch_features *features, enum ofputil_protocol protocol, ovs_be32 xid) { struct ofp_switch_features *osf; struct ofpbuf *b; enum ofp_version version; enum ofpraw raw; version = ofputil_protocol_to_ofp_version(protocol); switch (version) { case OFP10_VERSION: raw = OFPRAW_OFPT10_FEATURES_REPLY; break; case OFP11_VERSION: case OFP12_VERSION: raw = OFPRAW_OFPT11_FEATURES_REPLY; break; case OFP13_VERSION: raw = OFPRAW_OFPT13_FEATURES_REPLY; break; default: NOT_REACHED(); } b = ofpraw_alloc_xid(raw, version, xid, 0); osf = ofpbuf_put_zeros(b, sizeof *osf); osf->datapath_id = htonll(features->datapath_id); osf->n_buffers = htonl(features->n_buffers); osf->n_tables = features->n_tables; osf->capabilities = htonl(features->capabilities & OFPC_COMMON); osf->capabilities = htonl(features->capabilities & ofputil_capabilities_mask(version)); switch (version) { case OFP10_VERSION: if (features->capabilities & OFPUTIL_C_STP) { osf->capabilities |= htonl(OFPC10_STP); } osf->actions = encode_action_bits(features->actions, of10_action_bits); break; case OFP13_VERSION: osf->auxiliary_id = features->auxiliary_id; /* fall through */ case OFP11_VERSION: case OFP12_VERSION: if (features->capabilities & OFPUTIL_C_GROUP_STATS) { osf->capabilities |= htonl(OFPC11_GROUP_STATS); } break; default: NOT_REACHED(); } return b; } /* Encodes 'pp' into the format required by the switch_features message already * in 'b', which should have been returned by ofputil_encode_switch_features(), * and appends the encoded version to 'b'. */ void ofputil_put_switch_features_port(const struct ofputil_phy_port *pp, struct ofpbuf *b) { const struct ofp_header *oh = b->data; if (oh->version < OFP13_VERSION) { ofputil_put_phy_port(oh->version, pp, b); } } /* ofputil_port_status */ /* Decodes the OpenFlow "port status" message in '*ops' into an abstract form * in '*ps'. Returns 0 if successful, otherwise an OFPERR_* value. */ enum ofperr ofputil_decode_port_status(const struct ofp_header *oh, struct ofputil_port_status *ps) { const struct ofp_port_status *ops; struct ofpbuf b; int retval; ofpbuf_use_const(&b, oh, ntohs(oh->length)); ofpraw_pull_assert(&b); ops = ofpbuf_pull(&b, sizeof *ops); if (ops->reason != OFPPR_ADD && ops->reason != OFPPR_DELETE && ops->reason != OFPPR_MODIFY) { return OFPERR_NXBRC_BAD_REASON; } ps->reason = ops->reason; retval = ofputil_pull_phy_port(oh->version, &b, &ps->desc); ovs_assert(retval != EOF); return retval; } /* Converts the abstract form of a "port status" message in '*ps' into an * OpenFlow message suitable for 'protocol', and returns that encoded form in * a buffer owned by the caller. */ struct ofpbuf * ofputil_encode_port_status(const struct ofputil_port_status *ps, enum ofputil_protocol protocol) { struct ofp_port_status *ops; struct ofpbuf *b; enum ofp_version version; enum ofpraw raw; version = ofputil_protocol_to_ofp_version(protocol); switch (version) { case OFP10_VERSION: raw = OFPRAW_OFPT10_PORT_STATUS; break; case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: raw = OFPRAW_OFPT11_PORT_STATUS; break; default: NOT_REACHED(); } b = ofpraw_alloc_xid(raw, version, htonl(0), 0); ops = ofpbuf_put_zeros(b, sizeof *ops); ops->reason = ps->reason; ofputil_put_phy_port(version, &ps->desc, b); ofpmsg_update_length(b); return b; } /* ofputil_port_mod */ /* Decodes the OpenFlow "port mod" message in '*oh' into an abstract form in * '*pm'. Returns 0 if successful, otherwise an OFPERR_* value. */ enum ofperr ofputil_decode_port_mod(const struct ofp_header *oh, struct ofputil_port_mod *pm) { enum ofpraw raw; struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); if (raw == OFPRAW_OFPT10_PORT_MOD) { const struct ofp10_port_mod *opm = b.data; pm->port_no = u16_to_ofp(ntohs(opm->port_no)); memcpy(pm->hw_addr, opm->hw_addr, ETH_ADDR_LEN); pm->config = ntohl(opm->config) & OFPPC10_ALL; pm->mask = ntohl(opm->mask) & OFPPC10_ALL; pm->advertise = netdev_port_features_from_ofp10(opm->advertise); } else if (raw == OFPRAW_OFPT11_PORT_MOD) { const struct ofp11_port_mod *opm = b.data; enum ofperr error; error = ofputil_port_from_ofp11(opm->port_no, &pm->port_no); if (error) { return error; } memcpy(pm->hw_addr, opm->hw_addr, ETH_ADDR_LEN); pm->config = ntohl(opm->config) & OFPPC11_ALL; pm->mask = ntohl(opm->mask) & OFPPC11_ALL; pm->advertise = netdev_port_features_from_ofp11(opm->advertise); } else { return OFPERR_OFPBRC_BAD_TYPE; } pm->config &= pm->mask; return 0; } /* Converts the abstract form of a "port mod" message in '*pm' into an OpenFlow * message suitable for 'protocol', and returns that encoded form in a buffer * owned by the caller. */ struct ofpbuf * ofputil_encode_port_mod(const struct ofputil_port_mod *pm, enum ofputil_protocol protocol) { enum ofp_version ofp_version = ofputil_protocol_to_ofp_version(protocol); struct ofpbuf *b; switch (ofp_version) { case OFP10_VERSION: { struct ofp10_port_mod *opm; b = ofpraw_alloc(OFPRAW_OFPT10_PORT_MOD, ofp_version, 0); opm = ofpbuf_put_zeros(b, sizeof *opm); opm->port_no = htons(ofp_to_u16(pm->port_no)); memcpy(opm->hw_addr, pm->hw_addr, ETH_ADDR_LEN); opm->config = htonl(pm->config & OFPPC10_ALL); opm->mask = htonl(pm->mask & OFPPC10_ALL); opm->advertise = netdev_port_features_to_ofp10(pm->advertise); break; } case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { struct ofp11_port_mod *opm; b = ofpraw_alloc(OFPRAW_OFPT11_PORT_MOD, ofp_version, 0); opm = ofpbuf_put_zeros(b, sizeof *opm); opm->port_no = ofputil_port_to_ofp11(pm->port_no); memcpy(opm->hw_addr, pm->hw_addr, ETH_ADDR_LEN); opm->config = htonl(pm->config & OFPPC11_ALL); opm->mask = htonl(pm->mask & OFPPC11_ALL); opm->advertise = netdev_port_features_to_ofp11(pm->advertise); break; } default: NOT_REACHED(); } return b; } /* ofputil_role_request */ /* Decodes the OpenFlow "role request" or "role reply" message in '*oh' into * an abstract form in '*rr'. Returns 0 if successful, otherwise an * OFPERR_* value. */ enum ofperr ofputil_decode_role_message(const struct ofp_header *oh, struct ofputil_role_request *rr) { struct ofpbuf b; enum ofpraw raw; ofpbuf_use_const(&b, oh, ntohs(oh->length)); raw = ofpraw_pull_assert(&b); if (raw == OFPRAW_OFPT12_ROLE_REQUEST || raw == OFPRAW_OFPT12_ROLE_REPLY) { const struct ofp12_role_request *orr = b.l3; if (orr->role != htonl(OFPCR12_ROLE_NOCHANGE) && orr->role != htonl(OFPCR12_ROLE_EQUAL) && orr->role != htonl(OFPCR12_ROLE_MASTER) && orr->role != htonl(OFPCR12_ROLE_SLAVE)) { return OFPERR_OFPRRFC_BAD_ROLE; } rr->role = ntohl(orr->role); if (raw == OFPRAW_OFPT12_ROLE_REQUEST ? orr->role == htonl(OFPCR12_ROLE_NOCHANGE) : orr->generation_id == htonll(UINT64_MAX)) { rr->have_generation_id = false; rr->generation_id = 0; } else { rr->have_generation_id = true; rr->generation_id = ntohll(orr->generation_id); } } else if (raw == OFPRAW_NXT_ROLE_REQUEST || raw == OFPRAW_NXT_ROLE_REPLY) { const struct nx_role_request *nrr = b.l3; BUILD_ASSERT(NX_ROLE_OTHER + 1 == OFPCR12_ROLE_EQUAL); BUILD_ASSERT(NX_ROLE_MASTER + 1 == OFPCR12_ROLE_MASTER); BUILD_ASSERT(NX_ROLE_SLAVE + 1 == OFPCR12_ROLE_SLAVE); if (nrr->role != htonl(NX_ROLE_OTHER) && nrr->role != htonl(NX_ROLE_MASTER) && nrr->role != htonl(NX_ROLE_SLAVE)) { return OFPERR_OFPRRFC_BAD_ROLE; } rr->role = ntohl(nrr->role) + 1; rr->have_generation_id = false; rr->generation_id = 0; } else { NOT_REACHED(); } return 0; } /* Returns an encoded form of a role reply suitable for the "request" in a * buffer owned by the caller. */ struct ofpbuf * ofputil_encode_role_reply(const struct ofp_header *request, const struct ofputil_role_request *rr) { struct ofpbuf *buf; enum ofpraw raw; raw = ofpraw_decode_assert(request); if (raw == OFPRAW_OFPT12_ROLE_REQUEST) { struct ofp12_role_request *orr; buf = ofpraw_alloc_reply(OFPRAW_OFPT12_ROLE_REPLY, request, 0); orr = ofpbuf_put_zeros(buf, sizeof *orr); orr->role = htonl(rr->role); orr->generation_id = htonll(rr->have_generation_id ? rr->generation_id : UINT64_MAX); } else if (raw == OFPRAW_NXT_ROLE_REQUEST) { struct nx_role_request *nrr; BUILD_ASSERT(NX_ROLE_OTHER == OFPCR12_ROLE_EQUAL - 1); BUILD_ASSERT(NX_ROLE_MASTER == OFPCR12_ROLE_MASTER - 1); BUILD_ASSERT(NX_ROLE_SLAVE == OFPCR12_ROLE_SLAVE - 1); buf = ofpraw_alloc_reply(OFPRAW_NXT_ROLE_REPLY, request, 0); nrr = ofpbuf_put_zeros(buf, sizeof *nrr); nrr->role = htonl(rr->role - 1); } else { NOT_REACHED(); } return buf; } /* Table stats. */ static void ofputil_put_ofp10_table_stats(const struct ofp12_table_stats *in, struct ofpbuf *buf) { struct wc_map { enum ofp10_flow_wildcards wc10; enum oxm12_ofb_match_fields mf12; }; static const struct wc_map wc_map[] = { { OFPFW10_IN_PORT, OFPXMT12_OFB_IN_PORT }, { OFPFW10_DL_VLAN, OFPXMT12_OFB_VLAN_VID }, { OFPFW10_DL_SRC, OFPXMT12_OFB_ETH_SRC }, { OFPFW10_DL_DST, OFPXMT12_OFB_ETH_DST}, { OFPFW10_DL_TYPE, OFPXMT12_OFB_ETH_TYPE }, { OFPFW10_NW_PROTO, OFPXMT12_OFB_IP_PROTO }, { OFPFW10_TP_SRC, OFPXMT12_OFB_TCP_SRC }, { OFPFW10_TP_DST, OFPXMT12_OFB_TCP_DST }, { OFPFW10_NW_SRC_MASK, OFPXMT12_OFB_IPV4_SRC }, { OFPFW10_NW_DST_MASK, OFPXMT12_OFB_IPV4_DST }, { OFPFW10_DL_VLAN_PCP, OFPXMT12_OFB_VLAN_PCP }, { OFPFW10_NW_TOS, OFPXMT12_OFB_IP_DSCP }, }; struct ofp10_table_stats *out; const struct wc_map *p; out = ofpbuf_put_zeros(buf, sizeof *out); out->table_id = in->table_id; ovs_strlcpy(out->name, in->name, sizeof out->name); out->wildcards = 0; for (p = wc_map; p < &wc_map[ARRAY_SIZE(wc_map)]; p++) { if (in->wildcards & htonll(1ULL << p->mf12)) { out->wildcards |= htonl(p->wc10); } } out->max_entries = in->max_entries; out->active_count = in->active_count; put_32aligned_be64(&out->lookup_count, in->lookup_count); put_32aligned_be64(&out->matched_count, in->matched_count); } static ovs_be32 oxm12_to_ofp11_flow_match_fields(ovs_be64 oxm12) { struct map { enum ofp11_flow_match_fields fmf11; enum oxm12_ofb_match_fields mf12; }; static const struct map map[] = { { OFPFMF11_IN_PORT, OFPXMT12_OFB_IN_PORT }, { OFPFMF11_DL_VLAN, OFPXMT12_OFB_VLAN_VID }, { OFPFMF11_DL_VLAN_PCP, OFPXMT12_OFB_VLAN_PCP }, { OFPFMF11_DL_TYPE, OFPXMT12_OFB_ETH_TYPE }, { OFPFMF11_NW_TOS, OFPXMT12_OFB_IP_DSCP }, { OFPFMF11_NW_PROTO, OFPXMT12_OFB_IP_PROTO }, { OFPFMF11_TP_SRC, OFPXMT12_OFB_TCP_SRC }, { OFPFMF11_TP_DST, OFPXMT12_OFB_TCP_DST }, { OFPFMF11_MPLS_LABEL, OFPXMT12_OFB_MPLS_LABEL }, { OFPFMF11_MPLS_TC, OFPXMT12_OFB_MPLS_TC }, /* I don't know what OFPFMF11_TYPE means. */ { OFPFMF11_DL_SRC, OFPXMT12_OFB_ETH_SRC }, { OFPFMF11_DL_DST, OFPXMT12_OFB_ETH_DST }, { OFPFMF11_NW_SRC, OFPXMT12_OFB_IPV4_SRC }, { OFPFMF11_NW_DST, OFPXMT12_OFB_IPV4_DST }, { OFPFMF11_METADATA, OFPXMT12_OFB_METADATA }, }; const struct map *p; uint32_t fmf11; fmf11 = 0; for (p = map; p < &map[ARRAY_SIZE(map)]; p++) { if (oxm12 & htonll(1ULL << p->mf12)) { fmf11 |= p->fmf11; } } return htonl(fmf11); } static void ofputil_put_ofp11_table_stats(const struct ofp12_table_stats *in, struct ofpbuf *buf) { struct ofp11_table_stats *out; out = ofpbuf_put_zeros(buf, sizeof *out); out->table_id = in->table_id; ovs_strlcpy(out->name, in->name, sizeof out->name); out->wildcards = oxm12_to_ofp11_flow_match_fields(in->wildcards); out->match = oxm12_to_ofp11_flow_match_fields(in->match); out->instructions = in->instructions; out->write_actions = in->write_actions; out->apply_actions = in->apply_actions; out->config = in->config; out->max_entries = in->max_entries; out->active_count = in->active_count; out->lookup_count = in->lookup_count; out->matched_count = in->matched_count; } static void ofputil_put_ofp13_table_stats(const struct ofp12_table_stats *in, struct ofpbuf *buf) { struct ofp13_table_stats *out; /* OF 1.3 splits table features off the ofp_table_stats, * so there is not much here. */ out = ofpbuf_put_uninit(buf, sizeof *out); out->table_id = in->table_id; out->active_count = in->active_count; out->lookup_count = in->lookup_count; out->matched_count = in->matched_count; } struct ofpbuf * ofputil_encode_table_stats_reply(const struct ofp12_table_stats stats[], int n, const struct ofp_header *request) { struct ofpbuf *reply; int i; reply = ofpraw_alloc_stats_reply(request, n * sizeof *stats); switch ((enum ofp_version) request->version) { case OFP10_VERSION: for (i = 0; i < n; i++) { ofputil_put_ofp10_table_stats(&stats[i], reply); } break; case OFP11_VERSION: for (i = 0; i < n; i++) { ofputil_put_ofp11_table_stats(&stats[i], reply); } break; case OFP12_VERSION: ofpbuf_put(reply, stats, n * sizeof *stats); break; case OFP13_VERSION: for (i = 0; i < n; i++) { ofputil_put_ofp13_table_stats(&stats[i], reply); } break; default: NOT_REACHED(); } return reply; } /* ofputil_flow_monitor_request */ /* Converts an NXST_FLOW_MONITOR request in 'msg' into an abstract * ofputil_flow_monitor_request in 'rq'. * * Multiple NXST_FLOW_MONITOR requests can be packed into a single OpenFlow * message. Calling this function multiple times for a single 'msg' iterates * through the requests. The caller must initially leave 'msg''s layer * pointers null and not modify them between calls. * * Returns 0 if successful, EOF if no requests were left in this 'msg', * otherwise an OFPERR_* value. */ int ofputil_decode_flow_monitor_request(struct ofputil_flow_monitor_request *rq, struct ofpbuf *msg) { struct nx_flow_monitor_request *nfmr; uint16_t flags; if (!msg->l2) { msg->l2 = msg->data; ofpraw_pull_assert(msg); } if (!msg->size) { return EOF; } nfmr = ofpbuf_try_pull(msg, sizeof *nfmr); if (!nfmr) { VLOG_WARN_RL(&bad_ofmsg_rl, "NXST_FLOW_MONITOR request has %zu " "leftover bytes at end", msg->size); return OFPERR_OFPBRC_BAD_LEN; } flags = ntohs(nfmr->flags); if (!(flags & (NXFMF_ADD | NXFMF_DELETE | NXFMF_MODIFY)) || flags & ~(NXFMF_INITIAL | NXFMF_ADD | NXFMF_DELETE | NXFMF_MODIFY | NXFMF_ACTIONS | NXFMF_OWN)) { VLOG_WARN_RL(&bad_ofmsg_rl, "NXST_FLOW_MONITOR has bad flags %#"PRIx16, flags); return OFPERR_NXBRC_FM_BAD_FLAGS; } if (!is_all_zeros(nfmr->zeros, sizeof nfmr->zeros)) { return OFPERR_NXBRC_MUST_BE_ZERO; } rq->id = ntohl(nfmr->id); rq->flags = flags; rq->out_port = u16_to_ofp(ntohs(nfmr->out_port)); rq->table_id = nfmr->table_id; return nx_pull_match(msg, ntohs(nfmr->match_len), &rq->match, NULL, NULL); } void ofputil_append_flow_monitor_request( const struct ofputil_flow_monitor_request *rq, struct ofpbuf *msg) { struct nx_flow_monitor_request *nfmr; size_t start_ofs; int match_len; if (!msg->size) { ofpraw_put(OFPRAW_NXST_FLOW_MONITOR_REQUEST, OFP10_VERSION, msg); } start_ofs = msg->size; ofpbuf_put_zeros(msg, sizeof *nfmr); match_len = nx_put_match(msg, &rq->match, htonll(0), htonll(0)); nfmr = ofpbuf_at_assert(msg, start_ofs, sizeof *nfmr); nfmr->id = htonl(rq->id); nfmr->flags = htons(rq->flags); nfmr->out_port = htons(ofp_to_u16(rq->out_port)); nfmr->match_len = htons(match_len); nfmr->table_id = rq->table_id; } /* Converts an NXST_FLOW_MONITOR reply (also known as a flow update) in 'msg' * into an abstract ofputil_flow_update in 'update'. The caller must have * initialized update->match to point to space allocated for a match. * * Uses 'ofpacts' to store the abstract OFPACT_* version of the update's * actions (except for NXFME_ABBREV, which never includes actions). The caller * must initialize 'ofpacts' and retains ownership of it. 'update->ofpacts' * will point into the 'ofpacts' buffer. * * Multiple flow updates can be packed into a single OpenFlow message. Calling * this function multiple times for a single 'msg' iterates through the * updates. The caller must initially leave 'msg''s layer pointers null and * not modify them between calls. * * Returns 0 if successful, EOF if no updates were left in this 'msg', * otherwise an OFPERR_* value. */ int ofputil_decode_flow_update(struct ofputil_flow_update *update, struct ofpbuf *msg, struct ofpbuf *ofpacts) { struct nx_flow_update_header *nfuh; unsigned int length; if (!msg->l2) { msg->l2 = msg->data; ofpraw_pull_assert(msg); } if (!msg->size) { return EOF; } if (msg->size < sizeof(struct nx_flow_update_header)) { goto bad_len; } nfuh = msg->data; update->event = ntohs(nfuh->event); length = ntohs(nfuh->length); if (length > msg->size || length % 8) { goto bad_len; } if (update->event == NXFME_ABBREV) { struct nx_flow_update_abbrev *nfua; if (length != sizeof *nfua) { goto bad_len; } nfua = ofpbuf_pull(msg, sizeof *nfua); update->xid = nfua->xid; return 0; } else if (update->event == NXFME_ADDED || update->event == NXFME_DELETED || update->event == NXFME_MODIFIED) { struct nx_flow_update_full *nfuf; unsigned int actions_len; unsigned int match_len; enum ofperr error; if (length < sizeof *nfuf) { goto bad_len; } nfuf = ofpbuf_pull(msg, sizeof *nfuf); match_len = ntohs(nfuf->match_len); if (sizeof *nfuf + match_len > length) { goto bad_len; } update->reason = ntohs(nfuf->reason); update->idle_timeout = ntohs(nfuf->idle_timeout); update->hard_timeout = ntohs(nfuf->hard_timeout); update->table_id = nfuf->table_id; update->cookie = nfuf->cookie; update->priority = ntohs(nfuf->priority); error = nx_pull_match(msg, match_len, update->match, NULL, NULL); if (error) { return error; } actions_len = length - sizeof *nfuf - ROUND_UP(match_len, 8); error = ofpacts_pull_openflow10(msg, actions_len, ofpacts); if (error) { return error; } update->ofpacts = ofpacts->data; update->ofpacts_len = ofpacts->size; return 0; } else { VLOG_WARN_RL(&bad_ofmsg_rl, "NXST_FLOW_MONITOR reply has bad event %"PRIu16, ntohs(nfuh->event)); return OFPERR_NXBRC_FM_BAD_EVENT; } bad_len: VLOG_WARN_RL(&bad_ofmsg_rl, "NXST_FLOW_MONITOR reply has %zu " "leftover bytes at end", msg->size); return OFPERR_OFPBRC_BAD_LEN; } uint32_t ofputil_decode_flow_monitor_cancel(const struct ofp_header *oh) { const struct nx_flow_monitor_cancel *cancel = ofpmsg_body(oh); return ntohl(cancel->id); } struct ofpbuf * ofputil_encode_flow_monitor_cancel(uint32_t id) { struct nx_flow_monitor_cancel *nfmc; struct ofpbuf *msg; msg = ofpraw_alloc(OFPRAW_NXT_FLOW_MONITOR_CANCEL, OFP10_VERSION, 0); nfmc = ofpbuf_put_uninit(msg, sizeof *nfmc); nfmc->id = htonl(id); return msg; } void ofputil_start_flow_update(struct list *replies) { struct ofpbuf *msg; msg = ofpraw_alloc_xid(OFPRAW_NXST_FLOW_MONITOR_REPLY, OFP10_VERSION, htonl(0), 1024); list_init(replies); list_push_back(replies, &msg->list_node); } void ofputil_append_flow_update(const struct ofputil_flow_update *update, struct list *replies) { struct nx_flow_update_header *nfuh; struct ofpbuf *msg; size_t start_ofs; msg = ofpbuf_from_list(list_back(replies)); start_ofs = msg->size; if (update->event == NXFME_ABBREV) { struct nx_flow_update_abbrev *nfua; nfua = ofpbuf_put_zeros(msg, sizeof *nfua); nfua->xid = update->xid; } else { struct nx_flow_update_full *nfuf; int match_len; ofpbuf_put_zeros(msg, sizeof *nfuf); match_len = nx_put_match(msg, update->match, htonll(0), htonll(0)); ofpacts_put_openflow10(update->ofpacts, update->ofpacts_len, msg); nfuf = ofpbuf_at_assert(msg, start_ofs, sizeof *nfuf); nfuf->reason = htons(update->reason); nfuf->priority = htons(update->priority); nfuf->idle_timeout = htons(update->idle_timeout); nfuf->hard_timeout = htons(update->hard_timeout); nfuf->match_len = htons(match_len); nfuf->table_id = update->table_id; nfuf->cookie = update->cookie; } nfuh = ofpbuf_at_assert(msg, start_ofs, sizeof *nfuh); nfuh->length = htons(msg->size - start_ofs); nfuh->event = htons(update->event); ofpmp_postappend(replies, start_ofs); } struct ofpbuf * ofputil_encode_packet_out(const struct ofputil_packet_out *po, enum ofputil_protocol protocol) { enum ofp_version ofp_version = ofputil_protocol_to_ofp_version(protocol); struct ofpbuf *msg; size_t size; size = po->ofpacts_len; if (po->buffer_id == UINT32_MAX) { size += po->packet_len; } switch (ofp_version) { case OFP10_VERSION: { struct ofp10_packet_out *opo; size_t actions_ofs; msg = ofpraw_alloc(OFPRAW_OFPT10_PACKET_OUT, OFP10_VERSION, size); ofpbuf_put_zeros(msg, sizeof *opo); actions_ofs = msg->size; ofpacts_put_openflow10(po->ofpacts, po->ofpacts_len, msg); opo = msg->l3; opo->buffer_id = htonl(po->buffer_id); opo->in_port = htons(ofp_to_u16(po->in_port)); opo->actions_len = htons(msg->size - actions_ofs); break; } case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { struct ofp11_packet_out *opo; size_t len; msg = ofpraw_alloc(OFPRAW_OFPT11_PACKET_OUT, ofp_version, size); ofpbuf_put_zeros(msg, sizeof *opo); len = ofpacts_put_openflow11_actions(po->ofpacts, po->ofpacts_len, msg); opo = msg->l3; opo->buffer_id = htonl(po->buffer_id); opo->in_port = ofputil_port_to_ofp11(po->in_port); opo->actions_len = htons(len); break; } default: NOT_REACHED(); } if (po->buffer_id == UINT32_MAX) { ofpbuf_put(msg, po->packet, po->packet_len); } ofpmsg_update_length(msg); return msg; } /* Creates and returns an OFPT_ECHO_REQUEST message with an empty payload. */ struct ofpbuf * make_echo_request(enum ofp_version ofp_version) { return ofpraw_alloc_xid(OFPRAW_OFPT_ECHO_REQUEST, ofp_version, htonl(0), 0); } /* 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) { struct ofpbuf rq_buf; struct ofpbuf *reply; ofpbuf_use_const(&rq_buf, rq, ntohs(rq->length)); ofpraw_pull_assert(&rq_buf); reply = ofpraw_alloc_reply(OFPRAW_OFPT_ECHO_REPLY, rq, rq_buf.size); ofpbuf_put(reply, rq_buf.data, rq_buf.size); return reply; } struct ofpbuf * ofputil_encode_barrier_request(enum ofp_version ofp_version) { enum ofpraw type; switch (ofp_version) { case OFP13_VERSION: case OFP12_VERSION: case OFP11_VERSION: type = OFPRAW_OFPT11_BARRIER_REQUEST; break; case OFP10_VERSION: type = OFPRAW_OFPT10_BARRIER_REQUEST; break; default: NOT_REACHED(); } return ofpraw_alloc(type, ofp_version, 0); } const char * ofputil_frag_handling_to_string(enum ofp_config_flags flags) { switch (flags & OFPC_FRAG_MASK) { case OFPC_FRAG_NORMAL: return "normal"; case OFPC_FRAG_DROP: return "drop"; case OFPC_FRAG_REASM: return "reassemble"; case OFPC_FRAG_NX_MATCH: return "nx-match"; } NOT_REACHED(); } bool ofputil_frag_handling_from_string(const char *s, enum ofp_config_flags *flags) { if (!strcasecmp(s, "normal")) { *flags = OFPC_FRAG_NORMAL; } else if (!strcasecmp(s, "drop")) { *flags = OFPC_FRAG_DROP; } else if (!strcasecmp(s, "reassemble")) { *flags = OFPC_FRAG_REASM; } else if (!strcasecmp(s, "nx-match")) { *flags = OFPC_FRAG_NX_MATCH; } else { return false; } return true; } /* Converts the OpenFlow 1.1+ port number 'ofp11_port' into an OpenFlow 1.0 * port number and stores the latter in '*ofp10_port', for the purpose of * decoding OpenFlow 1.1+ protocol messages. Returns 0 if successful, * otherwise an OFPERR_* number. On error, stores OFPP_NONE in '*ofp10_port'. * * See the definition of OFP11_MAX for an explanation of the mapping. */ enum ofperr ofputil_port_from_ofp11(ovs_be32 ofp11_port, ofp_port_t *ofp10_port) { uint32_t ofp11_port_h = ntohl(ofp11_port); if (ofp11_port_h < ofp_to_u16(OFPP_MAX)) { *ofp10_port = u16_to_ofp(ofp11_port_h); return 0; } else if (ofp11_port_h >= ofp11_to_u32(OFPP11_MAX)) { *ofp10_port = u16_to_ofp(ofp11_port_h - OFPP11_OFFSET); return 0; } else { *ofp10_port = OFPP_NONE; VLOG_WARN_RL(&bad_ofmsg_rl, "port %"PRIu32" is outside the supported " "range 0 through %d or 0x%"PRIx32" through 0x%"PRIx32, ofp11_port_h, ofp_to_u16(OFPP_MAX) - 1, ofp11_to_u32(OFPP11_MAX), UINT32_MAX); return OFPERR_OFPBAC_BAD_OUT_PORT; } } /* Returns the OpenFlow 1.1+ port number equivalent to the OpenFlow 1.0 port * number 'ofp10_port', for encoding OpenFlow 1.1+ protocol messages. * * See the definition of OFP11_MAX for an explanation of the mapping. */ ovs_be32 ofputil_port_to_ofp11(ofp_port_t ofp10_port) { return htonl(ofp_to_u16(ofp10_port) < ofp_to_u16(OFPP_MAX) ? ofp_to_u16(ofp10_port) : ofp_to_u16(ofp10_port) + OFPP11_OFFSET); } /* Checks that 'port' is a valid output port for the OFPAT10_OUTPUT action, given * that the switch will never have more than 'max_ports' ports. Returns 0 if * 'port' is valid, otherwise an OpenFlow return code. */ enum ofperr ofputil_check_output_port(ofp_port_t port, ofp_port_t 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_NONE: case OFPP_LOCAL: return 0; default: if (ofp_to_u16(port) < ofp_to_u16(max_ports)) { return 0; } return OFPERR_OFPBAC_BAD_OUT_PORT; } } #define OFPUTIL_NAMED_PORTS \ OFPUTIL_NAMED_PORT(IN_PORT) \ OFPUTIL_NAMED_PORT(TABLE) \ OFPUTIL_NAMED_PORT(NORMAL) \ OFPUTIL_NAMED_PORT(FLOOD) \ OFPUTIL_NAMED_PORT(ALL) \ OFPUTIL_NAMED_PORT(CONTROLLER) \ OFPUTIL_NAMED_PORT(LOCAL) \ OFPUTIL_NAMED_PORT(ANY) /* For backwards compatibility, so that "none" is recognized as OFPP_ANY */ #define OFPUTIL_NAMED_PORTS_WITH_NONE \ OFPUTIL_NAMED_PORTS \ OFPUTIL_NAMED_PORT(NONE) /* Stores the port number represented by 's' into '*portp'. 's' may be an * integer or, for reserved ports, the standard OpenFlow name for the port * (e.g. "LOCAL"). * * Returns true if successful, false if 's' is not a valid OpenFlow port number * or name. The caller should issue an error message in this case, because * this function usually does not. (This gives the caller an opportunity to * look up the port name another way, e.g. by contacting the switch and listing * the names of all its ports). * * This function accepts OpenFlow 1.0 port numbers. It also accepts a subset * of OpenFlow 1.1+ port numbers, mapping those port numbers into the 16-bit * range as described in include/openflow/openflow-1.1.h. */ bool ofputil_port_from_string(const char *s, ofp_port_t *portp) { uint32_t port32; *portp = 0; if (str_to_uint(s, 10, &port32)) { if (port32 < ofp_to_u16(OFPP_MAX)) { /* Pass. */ } else if (port32 < ofp_to_u16(OFPP_FIRST_RESV)) { VLOG_WARN("port %u is a reserved OF1.0 port number that will " "be translated to %u when talking to an OF1.1 or " "later controller", port32, port32 + OFPP11_OFFSET); } else if (port32 <= ofp_to_u16(OFPP_LAST_RESV)) { char name[OFP_MAX_PORT_NAME_LEN]; ofputil_port_to_string(u16_to_ofp(port32), name, sizeof name); VLOG_WARN_ONCE("referring to port %s as %"PRIu32" is deprecated " "for compatibility with OpenFlow 1.1 and later", name, port32); } else if (port32 < ofp11_to_u32(OFPP11_MAX)) { VLOG_WARN("port %u is outside the supported range 0 through " "%"PRIx16" or 0x%x through 0x%"PRIx32, port32, UINT16_MAX, ofp11_to_u32(OFPP11_MAX), UINT32_MAX); return false; } else { port32 -= OFPP11_OFFSET; } *portp = u16_to_ofp(port32); return true; } else { struct pair { const char *name; ofp_port_t value; }; static const struct pair pairs[] = { #define OFPUTIL_NAMED_PORT(NAME) {#NAME, OFPP_##NAME}, OFPUTIL_NAMED_PORTS_WITH_NONE #undef OFPUTIL_NAMED_PORT }; const struct pair *p; for (p = pairs; p < &pairs[ARRAY_SIZE(pairs)]; p++) { if (!strcasecmp(s, p->name)) { *portp = p->value; return true; } } return false; } } /* Appends to 's' a string representation of the OpenFlow port number 'port'. * Most ports' string representation is just the port number, but for special * ports, e.g. OFPP_LOCAL, it is the name, e.g. "LOCAL". */ void ofputil_format_port(ofp_port_t port, struct ds *s) { char name[OFP_MAX_PORT_NAME_LEN]; ofputil_port_to_string(port, name, sizeof name); ds_put_cstr(s, name); } /* Puts in the 'bufsize' byte in 'namebuf' a null-terminated string * representation of OpenFlow port number 'port'. Most ports are represented * as just the port number, but special ports, e.g. OFPP_LOCAL, are represented * by name, e.g. "LOCAL". */ void ofputil_port_to_string(ofp_port_t port, char namebuf[OFP_MAX_PORT_NAME_LEN], size_t bufsize) { switch (port) { #define OFPUTIL_NAMED_PORT(NAME) \ case OFPP_##NAME: \ ovs_strlcpy(namebuf, #NAME, bufsize); \ break; OFPUTIL_NAMED_PORTS #undef OFPUTIL_NAMED_PORT default: snprintf(namebuf, bufsize, "%"PRIu16, port); break; } } /* Given a buffer 'b' that contains an array of OpenFlow ports of type * 'ofp_version', tries to pull the first element from the array. If * successful, initializes '*pp' with an abstract representation of the * port and returns 0. If no ports remain to be decoded, returns EOF. * On an error, returns a positive OFPERR_* value. */ int ofputil_pull_phy_port(enum ofp_version ofp_version, struct ofpbuf *b, struct ofputil_phy_port *pp) { switch (ofp_version) { case OFP10_VERSION: { const struct ofp10_phy_port *opp = ofpbuf_try_pull(b, sizeof *opp); return opp ? ofputil_decode_ofp10_phy_port(pp, opp) : EOF; } case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { const struct ofp11_port *op = ofpbuf_try_pull(b, sizeof *op); return op ? ofputil_decode_ofp11_port(pp, op) : EOF; } default: NOT_REACHED(); } } /* Given a buffer 'b' that contains an array of OpenFlow ports of type * 'ofp_version', returns the number of elements. */ size_t ofputil_count_phy_ports(uint8_t ofp_version, struct ofpbuf *b) { return b->size / ofputil_get_phy_port_size(ofp_version); } /* Returns the 'enum ofputil_action_code' corresponding to 'name' (e.g. if * 'name' is "output" then the return value is OFPUTIL_OFPAT10_OUTPUT), or -1 if * 'name' is not the name of any action. * * ofp-util.def lists the mapping from names to action. */ int ofputil_action_code_from_name(const char *name) { static const char *const names[OFPUTIL_N_ACTIONS] = { NULL, #define OFPAT10_ACTION(ENUM, STRUCT, NAME) NAME, #define OFPAT11_ACTION(ENUM, STRUCT, EXTENSIBLE, NAME) NAME, #define NXAST_ACTION(ENUM, STRUCT, EXTENSIBLE, NAME) NAME, #include "ofp-util.def" }; const char *const *p; for (p = names; p < &names[ARRAY_SIZE(names)]; p++) { if (*p && !strcasecmp(name, *p)) { return p - names; } } return -1; } /* Appends an action of the type specified by 'code' to 'buf' and returns the * action. Initializes the parts of 'action' that identify it as having type * and length 'sizeof *action' and zeros the rest. For actions that * have variable length, the length used and cleared is that of struct * . */ void * ofputil_put_action(enum ofputil_action_code code, struct ofpbuf *buf) { switch (code) { case OFPUTIL_ACTION_INVALID: NOT_REACHED(); #define OFPAT10_ACTION(ENUM, STRUCT, NAME) \ case OFPUTIL_##ENUM: return ofputil_put_##ENUM(buf); #define OFPAT11_ACTION(ENUM, STRUCT, EXTENSIBLE, NAME) \ case OFPUTIL_##ENUM: return ofputil_put_##ENUM(buf); #define NXAST_ACTION(ENUM, STRUCT, EXTENSIBLE, NAME) \ case OFPUTIL_##ENUM: return ofputil_put_##ENUM(buf); #include "ofp-util.def" } NOT_REACHED(); } #define OFPAT10_ACTION(ENUM, STRUCT, NAME) \ void \ ofputil_init_##ENUM(struct STRUCT *s) \ { \ memset(s, 0, sizeof *s); \ s->type = htons(ENUM); \ s->len = htons(sizeof *s); \ } \ \ struct STRUCT * \ ofputil_put_##ENUM(struct ofpbuf *buf) \ { \ struct STRUCT *s = ofpbuf_put_uninit(buf, sizeof *s); \ ofputil_init_##ENUM(s); \ return s; \ } #define OFPAT11_ACTION(ENUM, STRUCT, EXTENSIBLE, NAME) \ OFPAT10_ACTION(ENUM, STRUCT, NAME) #define NXAST_ACTION(ENUM, STRUCT, EXTENSIBLE, NAME) \ void \ ofputil_init_##ENUM(struct STRUCT *s) \ { \ memset(s, 0, sizeof *s); \ s->type = htons(OFPAT10_VENDOR); \ s->len = htons(sizeof *s); \ s->vendor = htonl(NX_VENDOR_ID); \ s->subtype = htons(ENUM); \ } \ \ struct STRUCT * \ ofputil_put_##ENUM(struct ofpbuf *buf) \ { \ struct STRUCT *s = ofpbuf_put_uninit(buf, sizeof *s); \ ofputil_init_##ENUM(s); \ return s; \ } #include "ofp-util.def" static void ofputil_normalize_match__(struct match *match, bool may_log) { enum { MAY_NW_ADDR = 1 << 0, /* nw_src, nw_dst */ MAY_TP_ADDR = 1 << 1, /* tp_src, tp_dst */ MAY_NW_PROTO = 1 << 2, /* nw_proto */ MAY_IPVx = 1 << 3, /* tos, frag, ttl */ MAY_ARP_SHA = 1 << 4, /* arp_sha */ MAY_ARP_THA = 1 << 5, /* arp_tha */ MAY_IPV6 = 1 << 6, /* ipv6_src, ipv6_dst, ipv6_label */ MAY_ND_TARGET = 1 << 7, /* nd_target */ MAY_MPLS = 1 << 8, /* mpls label and tc */ } may_match; struct flow_wildcards wc; /* Figure out what fields may be matched. */ if (match->flow.dl_type == htons(ETH_TYPE_IP)) { may_match = MAY_NW_PROTO | MAY_IPVx | MAY_NW_ADDR; if (match->flow.nw_proto == IPPROTO_TCP || match->flow.nw_proto == IPPROTO_UDP || match->flow.nw_proto == IPPROTO_ICMP) { may_match |= MAY_TP_ADDR; } } else if (match->flow.dl_type == htons(ETH_TYPE_IPV6)) { may_match = MAY_NW_PROTO | MAY_IPVx | MAY_IPV6; if (match->flow.nw_proto == IPPROTO_TCP || match->flow.nw_proto == IPPROTO_UDP) { may_match |= MAY_TP_ADDR; } else if (match->flow.nw_proto == IPPROTO_ICMPV6) { may_match |= MAY_TP_ADDR; if (match->flow.tp_src == htons(ND_NEIGHBOR_SOLICIT)) { may_match |= MAY_ND_TARGET | MAY_ARP_SHA; } else if (match->flow.tp_src == htons(ND_NEIGHBOR_ADVERT)) { may_match |= MAY_ND_TARGET | MAY_ARP_THA; } } } else if (match->flow.dl_type == htons(ETH_TYPE_ARP) || match->flow.dl_type == htons(ETH_TYPE_RARP)) { may_match = MAY_NW_PROTO | MAY_NW_ADDR | MAY_ARP_SHA | MAY_ARP_THA; } else if (eth_type_mpls(match->flow.dl_type)) { may_match = MAY_MPLS; } else { may_match = 0; } /* Clear the fields that may not be matched. */ wc = match->wc; if (!(may_match & MAY_NW_ADDR)) { wc.masks.nw_src = wc.masks.nw_dst = htonl(0); } if (!(may_match & MAY_TP_ADDR)) { wc.masks.tp_src = wc.masks.tp_dst = htons(0); } if (!(may_match & MAY_NW_PROTO)) { wc.masks.nw_proto = 0; } if (!(may_match & MAY_IPVx)) { wc.masks.nw_tos = 0; wc.masks.nw_ttl = 0; } if (!(may_match & MAY_ARP_SHA)) { memset(wc.masks.arp_sha, 0, ETH_ADDR_LEN); } if (!(may_match & MAY_ARP_THA)) { memset(wc.masks.arp_tha, 0, ETH_ADDR_LEN); } if (!(may_match & MAY_IPV6)) { wc.masks.ipv6_src = wc.masks.ipv6_dst = in6addr_any; wc.masks.ipv6_label = htonl(0); } if (!(may_match & MAY_ND_TARGET)) { wc.masks.nd_target = in6addr_any; } if (!(may_match & MAY_MPLS)) { wc.masks.mpls_lse = htonl(0); wc.masks.mpls_depth = 0; } /* Log any changes. */ if (!flow_wildcards_equal(&wc, &match->wc)) { bool log = may_log && !VLOG_DROP_INFO(&bad_ofmsg_rl); char *pre = log ? match_to_string(match, OFP_DEFAULT_PRIORITY) : NULL; match->wc = wc; match_zero_wildcarded_fields(match); if (log) { char *post = match_to_string(match, OFP_DEFAULT_PRIORITY); VLOG_INFO("normalization changed ofp_match, details:"); VLOG_INFO(" pre: %s", pre); VLOG_INFO("post: %s", post); free(pre); free(post); } } } /* "Normalizes" the wildcards in 'match'. That means: * * 1. If the type of level N is known, then only the valid fields for that * level may be specified. For example, ARP does not have a TOS field, * so nw_tos must be wildcarded if 'match' specifies an ARP flow. * Similarly, IPv4 does not have any IPv6 addresses, so ipv6_src and * ipv6_dst (and other fields) must be wildcarded if 'match' specifies an * IPv4 flow. * * 2. If the type of level N is not known (or not understood by Open * vSwitch), then no fields at all for that level may be specified. For * example, Open vSwitch does not understand SCTP, an L4 protocol, so the * L4 fields tp_src and tp_dst must be wildcarded if 'match' specifies an * SCTP flow. * * If this function changes 'match', it logs a rate-limited informational * message. */ void ofputil_normalize_match(struct match *match) { ofputil_normalize_match__(match, true); } /* Same as ofputil_normalize_match() without the logging. Thus, this function * is suitable for a program's internal use, whereas ofputil_normalize_match() * sense for use on flows received from elsewhere (so that a bug in the program * that sent them can be reported and corrected). */ void ofputil_normalize_match_quiet(struct match *match) { ofputil_normalize_match__(match, false); } /* Parses a key or a key-value pair from '*stringp'. * * On success: Stores the key into '*keyp'. Stores the value, if present, into * '*valuep', otherwise an empty string. Advances '*stringp' past the end of * the key-value pair, preparing it for another call. '*keyp' and '*valuep' * are substrings of '*stringp' created by replacing some of its bytes by null * terminators. Returns true. * * If '*stringp' is just white space or commas, sets '*keyp' and '*valuep' to * NULL and returns false. */ bool ofputil_parse_key_value(char **stringp, char **keyp, char **valuep) { char *pos, *key, *value; size_t key_len; pos = *stringp; pos += strspn(pos, ", \t\r\n"); if (*pos == '\0') { *keyp = *valuep = NULL; return false; } key = pos; key_len = strcspn(pos, ":=(, \t\r\n"); if (key[key_len] == ':' || key[key_len] == '=') { /* The value can be separated by a colon. */ size_t value_len; value = key + key_len + 1; value_len = strcspn(value, ", \t\r\n"); pos = value + value_len + (value[value_len] != '\0'); value[value_len] = '\0'; } else if (key[key_len] == '(') { /* The value can be surrounded by balanced parentheses. The outermost * set of parentheses is removed. */ int level = 1; size_t value_len; value = key + key_len + 1; for (value_len = 0; level > 0; value_len++) { switch (value[value_len]) { case '\0': level = 0; break; case '(': level++; break; case ')': level--; break; } } value[value_len - 1] = '\0'; pos = value + value_len; } else { /* There might be no value at all. */ value = key + key_len; /* Will become the empty string below. */ pos = key + key_len + (key[key_len] != '\0'); } key[key_len] = '\0'; *stringp = pos; *keyp = key; *valuep = value; return true; } /* Encode a dump ports request for 'port', the encoded message * will be for Open Flow version 'ofp_version'. Returns message * as a struct ofpbuf. Returns encoded message on success, NULL on error */ struct ofpbuf * ofputil_encode_dump_ports_request(enum ofp_version ofp_version, ofp_port_t port) { struct ofpbuf *request; switch (ofp_version) { case OFP10_VERSION: { struct ofp10_port_stats_request *req; request = ofpraw_alloc(OFPRAW_OFPST10_PORT_REQUEST, ofp_version, 0); req = ofpbuf_put_zeros(request, sizeof *req); req->port_no = htons(ofp_to_u16(port)); break; } case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { struct ofp11_port_stats_request *req; request = ofpraw_alloc(OFPRAW_OFPST11_PORT_REQUEST, ofp_version, 0); req = ofpbuf_put_zeros(request, sizeof *req); req->port_no = ofputil_port_to_ofp11(port); break; } default: NOT_REACHED(); } return request; } static void ofputil_port_stats_to_ofp10(const struct ofputil_port_stats *ops, struct ofp10_port_stats *ps10) { ps10->port_no = htons(ofp_to_u16(ops->port_no)); memset(ps10->pad, 0, sizeof ps10->pad); put_32aligned_be64(&ps10->rx_packets, htonll(ops->stats.rx_packets)); put_32aligned_be64(&ps10->tx_packets, htonll(ops->stats.tx_packets)); put_32aligned_be64(&ps10->rx_bytes, htonll(ops->stats.rx_bytes)); put_32aligned_be64(&ps10->tx_bytes, htonll(ops->stats.tx_bytes)); put_32aligned_be64(&ps10->rx_dropped, htonll(ops->stats.rx_dropped)); put_32aligned_be64(&ps10->tx_dropped, htonll(ops->stats.tx_dropped)); put_32aligned_be64(&ps10->rx_errors, htonll(ops->stats.rx_errors)); put_32aligned_be64(&ps10->tx_errors, htonll(ops->stats.tx_errors)); put_32aligned_be64(&ps10->rx_frame_err, htonll(ops->stats.rx_frame_errors)); put_32aligned_be64(&ps10->rx_over_err, htonll(ops->stats.rx_over_errors)); put_32aligned_be64(&ps10->rx_crc_err, htonll(ops->stats.rx_crc_errors)); put_32aligned_be64(&ps10->collisions, htonll(ops->stats.collisions)); } static void ofputil_port_stats_to_ofp11(const struct ofputil_port_stats *ops, struct ofp11_port_stats *ps11) { ps11->port_no = ofputil_port_to_ofp11(ops->port_no); memset(ps11->pad, 0, sizeof ps11->pad); ps11->rx_packets = htonll(ops->stats.rx_packets); ps11->tx_packets = htonll(ops->stats.tx_packets); ps11->rx_bytes = htonll(ops->stats.rx_bytes); ps11->tx_bytes = htonll(ops->stats.tx_bytes); ps11->rx_dropped = htonll(ops->stats.rx_dropped); ps11->tx_dropped = htonll(ops->stats.tx_dropped); ps11->rx_errors = htonll(ops->stats.rx_errors); ps11->tx_errors = htonll(ops->stats.tx_errors); ps11->rx_frame_err = htonll(ops->stats.rx_frame_errors); ps11->rx_over_err = htonll(ops->stats.rx_over_errors); ps11->rx_crc_err = htonll(ops->stats.rx_crc_errors); ps11->collisions = htonll(ops->stats.collisions); } static void ofputil_port_stats_to_ofp13(const struct ofputil_port_stats *ops, struct ofp13_port_stats *ps13) { ofputil_port_stats_to_ofp11(ops, &ps13->ps); ps13->duration_sec = htonl(ops->duration_sec); ps13->duration_nsec = htonl(ops->duration_nsec); } /* Encode a ports stat for 'ops' and append it to 'replies'. */ void ofputil_append_port_stat(struct list *replies, const struct ofputil_port_stats *ops) { struct ofpbuf *msg = ofpbuf_from_list(list_back(replies)); struct ofp_header *oh = msg->data; switch ((enum ofp_version)oh->version) { case OFP13_VERSION: { struct ofp13_port_stats *reply = ofpmp_append(replies, sizeof *reply); ofputil_port_stats_to_ofp13(ops, reply); break; } case OFP12_VERSION: case OFP11_VERSION: { struct ofp11_port_stats *reply = ofpmp_append(replies, sizeof *reply); ofputil_port_stats_to_ofp11(ops, reply); break; } case OFP10_VERSION: { struct ofp10_port_stats *reply = ofpmp_append(replies, sizeof *reply); ofputil_port_stats_to_ofp10(ops, reply); break; } default: NOT_REACHED(); } } static enum ofperr ofputil_port_stats_from_ofp10(struct ofputil_port_stats *ops, const struct ofp10_port_stats *ps10) { memset(ops, 0, sizeof *ops); ops->port_no = u16_to_ofp(ntohs(ps10->port_no)); ops->stats.rx_packets = ntohll(get_32aligned_be64(&ps10->rx_packets)); ops->stats.tx_packets = ntohll(get_32aligned_be64(&ps10->tx_packets)); ops->stats.rx_bytes = ntohll(get_32aligned_be64(&ps10->rx_bytes)); ops->stats.tx_bytes = ntohll(get_32aligned_be64(&ps10->tx_bytes)); ops->stats.rx_dropped = ntohll(get_32aligned_be64(&ps10->rx_dropped)); ops->stats.tx_dropped = ntohll(get_32aligned_be64(&ps10->tx_dropped)); ops->stats.rx_errors = ntohll(get_32aligned_be64(&ps10->rx_errors)); ops->stats.tx_errors = ntohll(get_32aligned_be64(&ps10->tx_errors)); ops->stats.rx_frame_errors = ntohll(get_32aligned_be64(&ps10->rx_frame_err)); ops->stats.rx_over_errors = ntohll(get_32aligned_be64(&ps10->rx_over_err)); ops->stats.rx_crc_errors = ntohll(get_32aligned_be64(&ps10->rx_crc_err)); ops->stats.collisions = ntohll(get_32aligned_be64(&ps10->collisions)); ops->duration_sec = ops->duration_nsec = UINT32_MAX; return 0; } static enum ofperr ofputil_port_stats_from_ofp11(struct ofputil_port_stats *ops, const struct ofp11_port_stats *ps11) { enum ofperr error; memset(ops, 0, sizeof *ops); error = ofputil_port_from_ofp11(ps11->port_no, &ops->port_no); if (error) { return error; } ops->stats.rx_packets = ntohll(ps11->rx_packets); ops->stats.tx_packets = ntohll(ps11->tx_packets); ops->stats.rx_bytes = ntohll(ps11->rx_bytes); ops->stats.tx_bytes = ntohll(ps11->tx_bytes); ops->stats.rx_dropped = ntohll(ps11->rx_dropped); ops->stats.tx_dropped = ntohll(ps11->tx_dropped); ops->stats.rx_errors = ntohll(ps11->rx_errors); ops->stats.tx_errors = ntohll(ps11->tx_errors); ops->stats.rx_frame_errors = ntohll(ps11->rx_frame_err); ops->stats.rx_over_errors = ntohll(ps11->rx_over_err); ops->stats.rx_crc_errors = ntohll(ps11->rx_crc_err); ops->stats.collisions = ntohll(ps11->collisions); ops->duration_sec = ops->duration_nsec = UINT32_MAX; return 0; } static enum ofperr ofputil_port_stats_from_ofp13(struct ofputil_port_stats *ops, const struct ofp13_port_stats *ps13) { enum ofperr error = ofputil_port_stats_from_ofp11(ops, &ps13->ps); if (!error) { ops->duration_sec = ntohl(ps13->duration_sec); ops->duration_nsec = ntohl(ps13->duration_nsec); } return error; } /* Returns the number of port stats elements in OFPTYPE_PORT_STATS_REPLY * message 'oh'. */ size_t ofputil_count_port_stats(const struct ofp_header *oh) { struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); ofpraw_pull_assert(&b); BUILD_ASSERT(sizeof(struct ofp10_port_stats) == sizeof(struct ofp11_port_stats)); return b.size / sizeof(struct ofp10_port_stats); } /* Converts an OFPST_PORT_STATS reply in 'msg' into an abstract * ofputil_port_stats in 'ps'. * * Multiple OFPST_PORT_STATS replies can be packed into a single OpenFlow * message. Calling this function multiple times for a single 'msg' iterates * through the replies. The caller must initially leave 'msg''s layer pointers * null and not modify them between calls. * * Returns 0 if successful, EOF if no replies were left in this 'msg', * otherwise a positive errno value. */ int ofputil_decode_port_stats(struct ofputil_port_stats *ps, struct ofpbuf *msg) { enum ofperr error; enum ofpraw raw; error = (msg->l2 ? ofpraw_decode(&raw, msg->l2) : ofpraw_pull(&raw, msg)); if (error) { return error; } if (!msg->size) { return EOF; } else if (raw == OFPRAW_OFPST13_PORT_REPLY) { const struct ofp13_port_stats *ps13; ps13 = ofpbuf_try_pull(msg, sizeof *ps13); if (!ps13) { goto bad_len; } return ofputil_port_stats_from_ofp13(ps, ps13); } else if (raw == OFPRAW_OFPST11_PORT_REPLY) { const struct ofp11_port_stats *ps11; ps11 = ofpbuf_try_pull(msg, sizeof *ps11); if (!ps11) { goto bad_len; } return ofputil_port_stats_from_ofp11(ps, ps11); } else if (raw == OFPRAW_OFPST10_PORT_REPLY) { const struct ofp10_port_stats *ps10; ps10 = ofpbuf_try_pull(msg, sizeof *ps10); if (!ps10) { goto bad_len; } return ofputil_port_stats_from_ofp10(ps, ps10); } else { NOT_REACHED(); } bad_len: VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_PORT reply has %zu leftover " "bytes at end", msg->size); return OFPERR_OFPBRC_BAD_LEN; } /* Parse a port status request message into a 16 bit OpenFlow 1.0 * port number and stores the latter in '*ofp10_port'. * Returns 0 if successful, otherwise an OFPERR_* number. */ enum ofperr ofputil_decode_port_stats_request(const struct ofp_header *request, ofp_port_t *ofp10_port) { switch ((enum ofp_version)request->version) { case OFP13_VERSION: case OFP12_VERSION: case OFP11_VERSION: { const struct ofp11_port_stats_request *psr11 = ofpmsg_body(request); return ofputil_port_from_ofp11(psr11->port_no, ofp10_port); } case OFP10_VERSION: { const struct ofp10_port_stats_request *psr10 = ofpmsg_body(request); *ofp10_port = u16_to_ofp(ntohs(psr10->port_no)); return 0; } default: NOT_REACHED(); } } /* Parse a queue status request message into 'oqsr'. * Returns 0 if successful, otherwise an OFPERR_* number. */ enum ofperr ofputil_decode_queue_stats_request(const struct ofp_header *request, struct ofputil_queue_stats_request *oqsr) { switch ((enum ofp_version)request->version) { case OFP13_VERSION: case OFP12_VERSION: case OFP11_VERSION: { const struct ofp11_queue_stats_request *qsr11 = ofpmsg_body(request); oqsr->queue_id = ntohl(qsr11->queue_id); return ofputil_port_from_ofp11(qsr11->port_no, &oqsr->port_no); } case OFP10_VERSION: { const struct ofp10_queue_stats_request *qsr10 = ofpmsg_body(request); oqsr->queue_id = ntohl(qsr10->queue_id); oqsr->port_no = u16_to_ofp(ntohs(qsr10->port_no)); /* OF 1.0 uses OFPP_ALL for OFPP_ANY */ if (oqsr->port_no == OFPP_ALL) { oqsr->port_no = OFPP_ANY; } return 0; } default: NOT_REACHED(); } } /* Encode a queue statsrequest for 'oqsr', the encoded message * will be fore Open Flow version 'ofp_version'. Returns message * as a struct ofpbuf. Returns encoded message on success, NULL on error */ struct ofpbuf * ofputil_encode_queue_stats_request(enum ofp_version ofp_version, const struct ofputil_queue_stats_request *oqsr) { struct ofpbuf *request; switch (ofp_version) { case OFP11_VERSION: case OFP12_VERSION: case OFP13_VERSION: { struct ofp11_queue_stats_request *req; request = ofpraw_alloc(OFPRAW_OFPST11_QUEUE_REQUEST, ofp_version, 0); req = ofpbuf_put_zeros(request, sizeof *req); req->port_no = ofputil_port_to_ofp11(oqsr->port_no); req->queue_id = htonl(oqsr->queue_id); break; } case OFP10_VERSION: { struct ofp10_queue_stats_request *req; request = ofpraw_alloc(OFPRAW_OFPST10_QUEUE_REQUEST, ofp_version, 0); req = ofpbuf_put_zeros(request, sizeof *req); /* OpenFlow 1.0 needs OFPP_ALL instead of OFPP_ANY */ req->port_no = htons(ofp_to_u16(oqsr->port_no == OFPP_ANY ? OFPP_ALL : oqsr->port_no)); req->queue_id = htonl(oqsr->queue_id); break; } default: NOT_REACHED(); } return request; } /* Returns the number of queue stats elements in OFPTYPE_QUEUE_STATS_REPLY * message 'oh'. */ size_t ofputil_count_queue_stats(const struct ofp_header *oh) { struct ofpbuf b; ofpbuf_use_const(&b, oh, ntohs(oh->length)); ofpraw_pull_assert(&b); BUILD_ASSERT(sizeof(struct ofp10_queue_stats) == sizeof(struct ofp11_queue_stats)); return b.size / sizeof(struct ofp10_queue_stats); } static enum ofperr ofputil_queue_stats_from_ofp10(struct ofputil_queue_stats *oqs, const struct ofp10_queue_stats *qs10) { oqs->port_no = u16_to_ofp(ntohs(qs10->port_no)); oqs->queue_id = ntohl(qs10->queue_id); oqs->stats.tx_bytes = ntohll(get_32aligned_be64(&qs10->tx_bytes)); oqs->stats.tx_packets = ntohll(get_32aligned_be64(&qs10->tx_packets)); oqs->stats.tx_errors = ntohll(get_32aligned_be64(&qs10->tx_errors)); return 0; } static enum ofperr ofputil_queue_stats_from_ofp11(struct ofputil_queue_stats *oqs, const struct ofp11_queue_stats *qs11) { enum ofperr error; error = ofputil_port_from_ofp11(qs11->port_no, &oqs->port_no); if (error) { return error; } oqs->queue_id = ntohl(qs11->queue_id); oqs->stats.tx_bytes = ntohll(qs11->tx_bytes); oqs->stats.tx_packets = ntohll(qs11->tx_packets); oqs->stats.tx_errors = ntohll(qs11->tx_errors); return 0; } static enum ofperr ofputil_queue_stats_from_ofp13(struct ofputil_queue_stats *oqs, const struct ofp13_queue_stats *qs13) { enum ofperr error = ofputil_queue_stats_from_ofp11(oqs, &qs13->qs); if (!error) { /* FIXME: Get qs13->duration_sec and qs13->duration_nsec, * Add to netdev_queue_stats? */ } return error; } /* Converts an OFPST_QUEUE_STATS reply in 'msg' into an abstract * ofputil_queue_stats in 'qs'. * * Multiple OFPST_QUEUE_STATS replies can be packed into a single OpenFlow * message. Calling this function multiple times for a single 'msg' iterates * through the replies. The caller must initially leave 'msg''s layer pointers * null and not modify them between calls. * * Returns 0 if successful, EOF if no replies were left in this 'msg', * otherwise a positive errno value. */ int ofputil_decode_queue_stats(struct ofputil_queue_stats *qs, struct ofpbuf *msg) { enum ofperr error; enum ofpraw raw; error = (msg->l2 ? ofpraw_decode(&raw, msg->l2) : ofpraw_pull(&raw, msg)); if (error) { return error; } if (!msg->size) { return EOF; } else if (raw == OFPRAW_OFPST13_QUEUE_REPLY) { const struct ofp13_queue_stats *qs13; qs13 = ofpbuf_try_pull(msg, sizeof *qs13); if (!qs13) { goto bad_len; } return ofputil_queue_stats_from_ofp13(qs, qs13); } else if (raw == OFPRAW_OFPST11_QUEUE_REPLY) { const struct ofp11_queue_stats *qs11; qs11 = ofpbuf_try_pull(msg, sizeof *qs11); if (!qs11) { goto bad_len; } return ofputil_queue_stats_from_ofp11(qs, qs11); } else if (raw == OFPRAW_OFPST10_QUEUE_REPLY) { const struct ofp10_queue_stats *qs10; qs10 = ofpbuf_try_pull(msg, sizeof *qs10); if (!qs10) { goto bad_len; } return ofputil_queue_stats_from_ofp10(qs, qs10); } else { NOT_REACHED(); } bad_len: VLOG_WARN_RL(&bad_ofmsg_rl, "OFPST_QUEUE reply has %zu leftover " "bytes at end", msg->size); return OFPERR_OFPBRC_BAD_LEN; } static void ofputil_queue_stats_to_ofp10(const struct ofputil_queue_stats *oqs, struct ofp10_queue_stats *qs10) { qs10->port_no = htons(ofp_to_u16(oqs->port_no)); memset(qs10->pad, 0, sizeof qs10->pad); qs10->queue_id = htonl(oqs->queue_id); put_32aligned_be64(&qs10->tx_bytes, htonll(oqs->stats.tx_bytes)); put_32aligned_be64(&qs10->tx_packets, htonll(oqs->stats.tx_packets)); put_32aligned_be64(&qs10->tx_errors, htonll(oqs->stats.tx_errors)); } static void ofputil_queue_stats_to_ofp11(const struct ofputil_queue_stats *oqs, struct ofp11_queue_stats *qs11) { qs11->port_no = ofputil_port_to_ofp11(oqs->port_no); qs11->queue_id = htonl(oqs->queue_id); qs11->tx_bytes = htonll(oqs->stats.tx_bytes); qs11->tx_packets = htonll(oqs->stats.tx_packets); qs11->tx_errors = htonll(oqs->stats.tx_errors); } static void ofputil_queue_stats_to_ofp13(const struct ofputil_queue_stats *oqs, struct ofp13_queue_stats *qs13) { ofputil_queue_stats_to_ofp11(oqs, &qs13->qs); /* OF 1.3 adds duration fields */ /* FIXME: Need to implement queue alive duration (sec + nsec) */ qs13->duration_sec = htonl(~0); qs13->duration_nsec = htonl(~0); } /* Encode a queue stat for 'oqs' and append it to 'replies'. */ void ofputil_append_queue_stat(struct list *replies, const struct ofputil_queue_stats *oqs) { struct ofpbuf *msg = ofpbuf_from_list(list_back(replies)); struct ofp_header *oh = msg->data; switch ((enum ofp_version)oh->version) { case OFP13_VERSION: { struct ofp13_queue_stats *reply = ofpmp_append(replies, sizeof *reply); ofputil_queue_stats_to_ofp13(oqs, reply); break; } case OFP12_VERSION: case OFP11_VERSION: { struct ofp11_queue_stats *reply = ofpmp_append(replies, sizeof *reply); ofputil_queue_stats_to_ofp11(oqs, reply); break; } case OFP10_VERSION: { struct ofp10_queue_stats *reply = ofpmp_append(replies, sizeof *reply); ofputil_queue_stats_to_ofp10(oqs, reply); break; } default: NOT_REACHED(); } }