/* * Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013, 2014, 2015, 2016 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 "dpif-netlink.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bitmap.h" #include "dpif-provider.h" #include "openvswitch/dynamic-string.h" #include "flow.h" #include "fat-rwlock.h" #include "netdev.h" #include "netdev-linux.h" #include "netdev-vport.h" #include "netlink-conntrack.h" #include "netlink-notifier.h" #include "netlink-socket.h" #include "netlink.h" #include "odp-util.h" #include "ofpbuf.h" #include "packets.h" #include "poll-loop.h" #include "random.h" #include "shash.h" #include "sset.h" #include "timeval.h" #include "unaligned.h" #include "util.h" #include "openvswitch/vlog.h" VLOG_DEFINE_THIS_MODULE(dpif_netlink); #ifdef _WIN32 enum { WINDOWS = 1 }; #else enum { WINDOWS = 0 }; #endif enum { MAX_PORTS = USHRT_MAX }; /* This ethtool flag was introduced in Linux 2.6.24, so it might be * missing if we have old headers. */ #define ETH_FLAG_LRO (1 << 15) /* LRO is enabled */ struct dpif_netlink_dp { /* Generic Netlink header. */ uint8_t cmd; /* struct ovs_header. */ int dp_ifindex; /* Attributes. */ const char *name; /* OVS_DP_ATTR_NAME. */ const uint32_t *upcall_pid; /* OVS_DP_ATTR_UPCALL_PID. */ uint32_t user_features; /* OVS_DP_ATTR_USER_FEATURES */ const struct ovs_dp_stats *stats; /* OVS_DP_ATTR_STATS. */ const struct ovs_dp_megaflow_stats *megaflow_stats; /* OVS_DP_ATTR_MEGAFLOW_STATS.*/ }; static void dpif_netlink_dp_init(struct dpif_netlink_dp *); static int dpif_netlink_dp_from_ofpbuf(struct dpif_netlink_dp *, const struct ofpbuf *); static void dpif_netlink_dp_dump_start(struct nl_dump *); static int dpif_netlink_dp_transact(const struct dpif_netlink_dp *request, struct dpif_netlink_dp *reply, struct ofpbuf **bufp); static int dpif_netlink_dp_get(const struct dpif *, struct dpif_netlink_dp *reply, struct ofpbuf **bufp); struct dpif_netlink_flow { /* Generic Netlink header. */ uint8_t cmd; /* struct ovs_header. */ unsigned int nlmsg_flags; int dp_ifindex; /* Attributes. * * The 'stats' member points to 64-bit data that might only be aligned on * 32-bit boundaries, so get_unaligned_u64() should be used to access its * values. * * If 'actions' is nonnull then OVS_FLOW_ATTR_ACTIONS will be included in * the Netlink version of the command, even if actions_len is zero. */ const struct nlattr *key; /* OVS_FLOW_ATTR_KEY. */ size_t key_len; const struct nlattr *mask; /* OVS_FLOW_ATTR_MASK. */ size_t mask_len; const struct nlattr *actions; /* OVS_FLOW_ATTR_ACTIONS. */ size_t actions_len; ovs_u128 ufid; /* OVS_FLOW_ATTR_FLOW_ID. */ bool ufid_present; /* Is there a UFID? */ bool ufid_terse; /* Skip serializing key/mask/acts? */ const struct ovs_flow_stats *stats; /* OVS_FLOW_ATTR_STATS. */ const uint8_t *tcp_flags; /* OVS_FLOW_ATTR_TCP_FLAGS. */ const ovs_32aligned_u64 *used; /* OVS_FLOW_ATTR_USED. */ bool clear; /* OVS_FLOW_ATTR_CLEAR. */ bool probe; /* OVS_FLOW_ATTR_PROBE. */ }; static void dpif_netlink_flow_init(struct dpif_netlink_flow *); static int dpif_netlink_flow_from_ofpbuf(struct dpif_netlink_flow *, const struct ofpbuf *); static void dpif_netlink_flow_to_ofpbuf(const struct dpif_netlink_flow *, struct ofpbuf *); static int dpif_netlink_flow_transact(struct dpif_netlink_flow *request, struct dpif_netlink_flow *reply, struct ofpbuf **bufp); static void dpif_netlink_flow_get_stats(const struct dpif_netlink_flow *, struct dpif_flow_stats *); static void dpif_netlink_flow_to_dpif_flow(struct dpif *, struct dpif_flow *, const struct dpif_netlink_flow *); /* One of the dpif channels between the kernel and userspace. */ struct dpif_channel { struct nl_sock *sock; /* Netlink socket. */ long long int last_poll; /* Last time this channel was polled. */ }; #ifdef _WIN32 #define VPORT_SOCK_POOL_SIZE 1 /* On Windows, there is no native support for epoll. There are equivalent * interfaces though, that are not used currently. For simpicity, a pool of * netlink sockets is used. Each socket is represented by 'struct * dpif_windows_vport_sock'. Since it is a pool, multiple OVS ports may be * sharing the same socket. In the future, we can add a reference count and * such fields. */ struct dpif_windows_vport_sock { struct nl_sock *nl_sock; /* netlink socket. */ }; #endif struct dpif_handler { struct dpif_channel *channels;/* Array of channels for each handler. */ struct epoll_event *epoll_events; int epoll_fd; /* epoll fd that includes channel socks. */ int n_events; /* Num events returned by epoll_wait(). */ int event_offset; /* Offset into 'epoll_events'. */ #ifdef _WIN32 /* Pool of sockets. */ struct dpif_windows_vport_sock *vport_sock_pool; size_t last_used_pool_idx; /* Index to aid in allocating a socket in the pool to a port. */ #endif }; /* Datapath interface for the openvswitch Linux kernel module. */ struct dpif_netlink { struct dpif dpif; int dp_ifindex; /* Upcall messages. */ struct fat_rwlock upcall_lock; struct dpif_handler *handlers; uint32_t n_handlers; /* Num of upcall handlers. */ int uc_array_size; /* Size of 'handler->channels' and */ /* 'handler->epoll_events'. */ /* Change notification. */ struct nl_sock *port_notifier; /* vport multicast group subscriber. */ bool refresh_channels; }; static void report_loss(struct dpif_netlink *, struct dpif_channel *, uint32_t ch_idx, uint32_t handler_id); static struct vlog_rate_limit error_rl = VLOG_RATE_LIMIT_INIT(9999, 5); /* Generic Netlink family numbers for OVS. * * Initialized by dpif_netlink_init(). */ static int ovs_datapath_family; static int ovs_vport_family; static int ovs_flow_family; static int ovs_packet_family; /* Generic Netlink multicast groups for OVS. * * Initialized by dpif_netlink_init(). */ static unsigned int ovs_vport_mcgroup; static int dpif_netlink_init(void); static int open_dpif(const struct dpif_netlink_dp *, struct dpif **); static uint32_t dpif_netlink_port_get_pid(const struct dpif *, odp_port_t port_no, uint32_t hash); static void dpif_netlink_handler_uninit(struct dpif_handler *handler); static int dpif_netlink_refresh_channels(struct dpif_netlink *, uint32_t n_handlers); static void dpif_netlink_vport_to_ofpbuf(const struct dpif_netlink_vport *, struct ofpbuf *); static int dpif_netlink_vport_from_ofpbuf(struct dpif_netlink_vport *, const struct ofpbuf *); static struct dpif_netlink * dpif_netlink_cast(const struct dpif *dpif) { dpif_assert_class(dpif, &dpif_netlink_class); return CONTAINER_OF(dpif, struct dpif_netlink, dpif); } static int dpif_netlink_enumerate(struct sset *all_dps, const struct dpif_class *dpif_class OVS_UNUSED) { struct nl_dump dump; uint64_t reply_stub[NL_DUMP_BUFSIZE / 8]; struct ofpbuf msg, buf; int error; error = dpif_netlink_init(); if (error) { return error; } ofpbuf_use_stub(&buf, reply_stub, sizeof reply_stub); dpif_netlink_dp_dump_start(&dump); while (nl_dump_next(&dump, &msg, &buf)) { struct dpif_netlink_dp dp; if (!dpif_netlink_dp_from_ofpbuf(&dp, &msg)) { sset_add(all_dps, dp.name); } } ofpbuf_uninit(&buf); return nl_dump_done(&dump); } static int dpif_netlink_open(const struct dpif_class *class OVS_UNUSED, const char *name, bool create, struct dpif **dpifp) { struct dpif_netlink_dp dp_request, dp; struct ofpbuf *buf; uint32_t upcall_pid; int error; error = dpif_netlink_init(); if (error) { return error; } /* Create or look up datapath. */ dpif_netlink_dp_init(&dp_request); if (create) { dp_request.cmd = OVS_DP_CMD_NEW; upcall_pid = 0; dp_request.upcall_pid = &upcall_pid; } else { /* Use OVS_DP_CMD_SET to report user features */ dp_request.cmd = OVS_DP_CMD_SET; } dp_request.name = name; dp_request.user_features |= OVS_DP_F_UNALIGNED; dp_request.user_features |= OVS_DP_F_VPORT_PIDS; error = dpif_netlink_dp_transact(&dp_request, &dp, &buf); if (error) { return error; } error = open_dpif(&dp, dpifp); ofpbuf_delete(buf); return error; } static int open_dpif(const struct dpif_netlink_dp *dp, struct dpif **dpifp) { struct dpif_netlink *dpif; dpif = xzalloc(sizeof *dpif); dpif->port_notifier = NULL; fat_rwlock_init(&dpif->upcall_lock); dpif_init(&dpif->dpif, &dpif_netlink_class, dp->name, dp->dp_ifindex, dp->dp_ifindex); dpif->dp_ifindex = dp->dp_ifindex; *dpifp = &dpif->dpif; return 0; } /* Destroys the netlink sockets pointed by the elements in 'socksp' * and frees the 'socksp'. */ static void vport_del_socksp__(struct nl_sock **socksp, uint32_t n_socks) { size_t i; for (i = 0; i < n_socks; i++) { nl_sock_destroy(socksp[i]); } free(socksp); } /* Creates an array of netlink sockets. Returns an array of the * corresponding pointers. Records the error in 'error'. */ static struct nl_sock ** vport_create_socksp__(uint32_t n_socks, int *error) { struct nl_sock **socksp = xzalloc(n_socks * sizeof *socksp); size_t i; for (i = 0; i < n_socks; i++) { *error = nl_sock_create(NETLINK_GENERIC, &socksp[i]); if (*error) { goto error; } } return socksp; error: vport_del_socksp__(socksp, n_socks); return NULL; } #ifdef _WIN32 static void vport_delete_sock_pool(struct dpif_handler *handler) OVS_REQ_WRLOCK(dpif->upcall_lock) { if (handler->vport_sock_pool) { uint32_t i; struct dpif_windows_vport_sock *sock_pool = handler->vport_sock_pool; for (i = 0; i < VPORT_SOCK_POOL_SIZE; i++) { if (sock_pool[i].nl_sock) { nl_sock_unsubscribe_packets(sock_pool[i].nl_sock); nl_sock_destroy(sock_pool[i].nl_sock); sock_pool[i].nl_sock = NULL; } } free(handler->vport_sock_pool); handler->vport_sock_pool = NULL; } } static int vport_create_sock_pool(struct dpif_handler *handler) OVS_REQ_WRLOCK(dpif->upcall_lock) { struct dpif_windows_vport_sock *sock_pool; size_t i; int error = 0; sock_pool = xzalloc(VPORT_SOCK_POOL_SIZE * sizeof *sock_pool); for (i = 0; i < VPORT_SOCK_POOL_SIZE; i++) { error = nl_sock_create(NETLINK_GENERIC, &sock_pool[i].nl_sock); if (error) { goto error; } /* Enable the netlink socket to receive packets. This is equivalent to * calling nl_sock_join_mcgroup() to receive events. */ error = nl_sock_subscribe_packets(sock_pool[i].nl_sock); if (error) { goto error; } } handler->vport_sock_pool = sock_pool; handler->last_used_pool_idx = 0; return 0; error: vport_delete_sock_pool(handler); return error; } /* Returns an array pointers to netlink sockets. The sockets are picked from a * pool. Records the error in 'error'. */ static struct nl_sock ** vport_create_socksp_windows(struct dpif_netlink *dpif, int *error) OVS_REQ_WRLOCK(dpif->upcall_lock) { uint32_t n_socks = dpif->n_handlers; struct nl_sock **socksp; size_t i; ovs_assert(n_socks <= 1); socksp = xzalloc(n_socks * sizeof *socksp); /* Pick netlink sockets to use in a round-robin fashion from each * handler's pool of sockets. */ for (i = 0; i < n_socks; i++) { struct dpif_handler *handler = &dpif->handlers[i]; struct dpif_windows_vport_sock *sock_pool = handler->vport_sock_pool; size_t index = handler->last_used_pool_idx; /* A pool of sockets is allocated when the handler is initialized. */ if (sock_pool == NULL) { free(socksp); *error = EINVAL; return NULL; } ovs_assert(index < VPORT_SOCK_POOL_SIZE); socksp[i] = sock_pool[index].nl_sock; socksp[i] = sock_pool[index].nl_sock; ovs_assert(socksp[i]); index = (index == VPORT_SOCK_POOL_SIZE - 1) ? 0 : index + 1; handler->last_used_pool_idx = index; } return socksp; } static void vport_del_socksp_windows(struct dpif_netlink *dpif, struct nl_sock **socksp) { free(socksp); } #endif /* _WIN32 */ static struct nl_sock ** vport_create_socksp(struct dpif_netlink *dpif, int *error) { #ifdef _WIN32 return vport_create_socksp_windows(dpif, error); #else return vport_create_socksp__(dpif->n_handlers, error); #endif } static void vport_del_socksp(struct dpif_netlink *dpif, struct nl_sock **socksp) { #ifdef _WIN32 vport_del_socksp_windows(dpif, socksp); #else vport_del_socksp__(socksp, dpif->n_handlers); #endif } /* Given the array of pointers to netlink sockets 'socksp', returns * the array of corresponding pids. If the 'socksp' is NULL, returns * a single-element array of value 0. */ static uint32_t * vport_socksp_to_pids(struct nl_sock **socksp, uint32_t n_socks) { uint32_t *pids; if (!socksp) { pids = xzalloc(sizeof *pids); } else { size_t i; pids = xzalloc(n_socks * sizeof *pids); for (i = 0; i < n_socks; i++) { pids[i] = nl_sock_pid(socksp[i]); } } return pids; } /* Given the port number 'port_idx', extracts the pids of netlink sockets * associated to the port and assigns it to 'upcall_pids'. */ static bool vport_get_pids(struct dpif_netlink *dpif, uint32_t port_idx, uint32_t **upcall_pids) { uint32_t *pids; size_t i; /* Since the nl_sock can only be assigned in either all * or none "dpif->handlers" channels, the following check * would suffice. */ if (!dpif->handlers[0].channels[port_idx].sock) { return false; } ovs_assert(!WINDOWS || dpif->n_handlers <= 1); pids = xzalloc(dpif->n_handlers * sizeof *pids); for (i = 0; i < dpif->n_handlers; i++) { pids[i] = nl_sock_pid(dpif->handlers[i].channels[port_idx].sock); } *upcall_pids = pids; return true; } static int vport_add_channels(struct dpif_netlink *dpif, odp_port_t port_no, struct nl_sock **socksp) { struct epoll_event event; uint32_t port_idx = odp_to_u32(port_no); size_t i, j; int error; if (dpif->handlers == NULL) { return 0; } /* We assume that the datapath densely chooses port numbers, which can * therefore be used as an index into 'channels' and 'epoll_events' of * 'dpif->handler'. */ if (port_idx >= dpif->uc_array_size) { uint32_t new_size = port_idx + 1; if (new_size > MAX_PORTS) { VLOG_WARN_RL(&error_rl, "%s: datapath port %"PRIu32" too big", dpif_name(&dpif->dpif), port_no); return EFBIG; } for (i = 0; i < dpif->n_handlers; i++) { struct dpif_handler *handler = &dpif->handlers[i]; handler->channels = xrealloc(handler->channels, new_size * sizeof *handler->channels); for (j = dpif->uc_array_size; j < new_size; j++) { handler->channels[j].sock = NULL; } handler->epoll_events = xrealloc(handler->epoll_events, new_size * sizeof *handler->epoll_events); } dpif->uc_array_size = new_size; } memset(&event, 0, sizeof event); event.events = EPOLLIN; event.data.u32 = port_idx; for (i = 0; i < dpif->n_handlers; i++) { struct dpif_handler *handler = &dpif->handlers[i]; #ifndef _WIN32 if (epoll_ctl(handler->epoll_fd, EPOLL_CTL_ADD, nl_sock_fd(socksp[i]), &event) < 0) { error = errno; goto error; } #endif dpif->handlers[i].channels[port_idx].sock = socksp[i]; dpif->handlers[i].channels[port_idx].last_poll = LLONG_MIN; } return 0; error: for (j = 0; j < i; j++) { #ifndef _WIN32 epoll_ctl(dpif->handlers[j].epoll_fd, EPOLL_CTL_DEL, nl_sock_fd(socksp[j]), NULL); #endif dpif->handlers[j].channels[port_idx].sock = NULL; } return error; } static void vport_del_channels(struct dpif_netlink *dpif, odp_port_t port_no) { uint32_t port_idx = odp_to_u32(port_no); size_t i; if (!dpif->handlers || port_idx >= dpif->uc_array_size) { return; } /* Since the sock can only be assigned in either all or none * of "dpif->handlers" channels, the following check would * suffice. */ if (!dpif->handlers[0].channels[port_idx].sock) { return; } for (i = 0; i < dpif->n_handlers; i++) { struct dpif_handler *handler = &dpif->handlers[i]; #ifndef _WIN32 epoll_ctl(handler->epoll_fd, EPOLL_CTL_DEL, nl_sock_fd(handler->channels[port_idx].sock), NULL); nl_sock_destroy(handler->channels[port_idx].sock); #endif handler->channels[port_idx].sock = NULL; handler->event_offset = handler->n_events = 0; } } static void destroy_all_channels(struct dpif_netlink *dpif) OVS_REQ_WRLOCK(dpif->upcall_lock) { unsigned int i; if (!dpif->handlers) { return; } for (i = 0; i < dpif->uc_array_size; i++ ) { struct dpif_netlink_vport vport_request; uint32_t upcall_pids = 0; /* Since the sock can only be assigned in either all or none * of "dpif->handlers" channels, the following check would * suffice. */ if (!dpif->handlers[0].channels[i].sock) { continue; } /* Turn off upcalls. */ dpif_netlink_vport_init(&vport_request); vport_request.cmd = OVS_VPORT_CMD_SET; vport_request.dp_ifindex = dpif->dp_ifindex; vport_request.port_no = u32_to_odp(i); vport_request.n_upcall_pids = 1; vport_request.upcall_pids = &upcall_pids; dpif_netlink_vport_transact(&vport_request, NULL, NULL); vport_del_channels(dpif, u32_to_odp(i)); } for (i = 0; i < dpif->n_handlers; i++) { struct dpif_handler *handler = &dpif->handlers[i]; dpif_netlink_handler_uninit(handler); free(handler->epoll_events); free(handler->channels); } free(dpif->handlers); dpif->handlers = NULL; dpif->n_handlers = 0; dpif->uc_array_size = 0; } static void dpif_netlink_close(struct dpif *dpif_) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); nl_sock_destroy(dpif->port_notifier); fat_rwlock_wrlock(&dpif->upcall_lock); destroy_all_channels(dpif); fat_rwlock_unlock(&dpif->upcall_lock); fat_rwlock_destroy(&dpif->upcall_lock); free(dpif); } static int dpif_netlink_destroy(struct dpif *dpif_) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); struct dpif_netlink_dp dp; dpif_netlink_dp_init(&dp); dp.cmd = OVS_DP_CMD_DEL; dp.dp_ifindex = dpif->dp_ifindex; return dpif_netlink_dp_transact(&dp, NULL, NULL); } static bool dpif_netlink_run(struct dpif *dpif_) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); if (dpif->refresh_channels) { dpif->refresh_channels = false; fat_rwlock_wrlock(&dpif->upcall_lock); dpif_netlink_refresh_channels(dpif, dpif->n_handlers); fat_rwlock_unlock(&dpif->upcall_lock); } return false; } static int dpif_netlink_get_stats(const struct dpif *dpif_, struct dpif_dp_stats *stats) { struct dpif_netlink_dp dp; struct ofpbuf *buf; int error; error = dpif_netlink_dp_get(dpif_, &dp, &buf); if (!error) { memset(stats, 0, sizeof *stats); if (dp.stats) { stats->n_hit = get_32aligned_u64(&dp.stats->n_hit); stats->n_missed = get_32aligned_u64(&dp.stats->n_missed); stats->n_lost = get_32aligned_u64(&dp.stats->n_lost); stats->n_flows = get_32aligned_u64(&dp.stats->n_flows); } if (dp.megaflow_stats) { stats->n_masks = dp.megaflow_stats->n_masks; stats->n_mask_hit = get_32aligned_u64( &dp.megaflow_stats->n_mask_hit); } else { stats->n_masks = UINT32_MAX; stats->n_mask_hit = UINT64_MAX; } ofpbuf_delete(buf); } return error; } static const char * get_vport_type(const struct dpif_netlink_vport *vport) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 20); switch (vport->type) { case OVS_VPORT_TYPE_NETDEV: { const char *type = netdev_get_type_from_name(vport->name); return type ? type : "system"; } case OVS_VPORT_TYPE_INTERNAL: return "internal"; case OVS_VPORT_TYPE_GENEVE: return "geneve"; case OVS_VPORT_TYPE_GRE: return "gre"; case OVS_VPORT_TYPE_VXLAN: return "vxlan"; case OVS_VPORT_TYPE_LISP: return "lisp"; case OVS_VPORT_TYPE_STT: return "stt"; case OVS_VPORT_TYPE_UNSPEC: case __OVS_VPORT_TYPE_MAX: break; } VLOG_WARN_RL(&rl, "dp%d: port `%s' has unsupported type %u", vport->dp_ifindex, vport->name, (unsigned int) vport->type); return "unknown"; } static enum ovs_vport_type netdev_to_ovs_vport_type(const struct netdev *netdev) { const char *type = netdev_get_type(netdev); if (!strcmp(type, "tap") || !strcmp(type, "system")) { return OVS_VPORT_TYPE_NETDEV; } else if (!strcmp(type, "internal")) { return OVS_VPORT_TYPE_INTERNAL; } else if (strstr(type, "stt")) { return OVS_VPORT_TYPE_STT; } else if (!strcmp(type, "geneve")) { return OVS_VPORT_TYPE_GENEVE; } else if (strstr(type, "gre")) { return OVS_VPORT_TYPE_GRE; } else if (!strcmp(type, "vxlan")) { return OVS_VPORT_TYPE_VXLAN; } else if (!strcmp(type, "lisp")) { return OVS_VPORT_TYPE_LISP; } else { return OVS_VPORT_TYPE_UNSPEC; } } static int dpif_netlink_port_add__(struct dpif_netlink *dpif, struct netdev *netdev, odp_port_t *port_nop) OVS_REQ_WRLOCK(dpif->upcall_lock) { const struct netdev_tunnel_config *tnl_cfg; char namebuf[NETDEV_VPORT_NAME_BUFSIZE]; const char *name = netdev_vport_get_dpif_port(netdev, namebuf, sizeof namebuf); const char *type = netdev_get_type(netdev); struct dpif_netlink_vport request, reply; struct ofpbuf *buf; uint64_t options_stub[64 / 8]; struct ofpbuf options; struct nl_sock **socksp = NULL; uint32_t *upcall_pids; int error = 0; if (dpif->handlers) { socksp = vport_create_socksp(dpif, &error); if (!socksp) { return error; } } dpif_netlink_vport_init(&request); request.cmd = OVS_VPORT_CMD_NEW; request.dp_ifindex = dpif->dp_ifindex; request.type = netdev_to_ovs_vport_type(netdev); if (request.type == OVS_VPORT_TYPE_UNSPEC) { VLOG_WARN_RL(&error_rl, "%s: cannot create port `%s' because it has " "unsupported type `%s'", dpif_name(&dpif->dpif), name, type); vport_del_socksp(dpif, socksp); return EINVAL; } request.name = name; if (request.type == OVS_VPORT_TYPE_NETDEV) { #ifdef _WIN32 /* XXX : Map appropiate Windows handle */ #else netdev_linux_ethtool_set_flag(netdev, ETH_FLAG_LRO, "LRO", false); #endif } tnl_cfg = netdev_get_tunnel_config(netdev); if (tnl_cfg && (tnl_cfg->dst_port != 0 || tnl_cfg->exts)) { ofpbuf_use_stack(&options, options_stub, sizeof options_stub); if (tnl_cfg->dst_port) { nl_msg_put_u16(&options, OVS_TUNNEL_ATTR_DST_PORT, ntohs(tnl_cfg->dst_port)); } if (tnl_cfg->exts) { size_t ext_ofs; int i; ext_ofs = nl_msg_start_nested(&options, OVS_TUNNEL_ATTR_EXTENSION); for (i = 0; i < 32; i++) { if (tnl_cfg->exts & (1 << i)) { nl_msg_put_flag(&options, i); } } nl_msg_end_nested(&options, ext_ofs); } request.options = options.data; request.options_len = options.size; } request.port_no = *port_nop; upcall_pids = vport_socksp_to_pids(socksp, dpif->n_handlers); request.n_upcall_pids = socksp ? dpif->n_handlers : 1; request.upcall_pids = upcall_pids; error = dpif_netlink_vport_transact(&request, &reply, &buf); if (!error) { *port_nop = reply.port_no; } else { if (error == EBUSY && *port_nop != ODPP_NONE) { VLOG_INFO("%s: requested port %"PRIu32" is in use", dpif_name(&dpif->dpif), *port_nop); } vport_del_socksp(dpif, socksp); goto exit; } if (socksp) { error = vport_add_channels(dpif, *port_nop, socksp); if (error) { VLOG_INFO("%s: could not add channel for port %s", dpif_name(&dpif->dpif), name); /* Delete the port. */ dpif_netlink_vport_init(&request); request.cmd = OVS_VPORT_CMD_DEL; request.dp_ifindex = dpif->dp_ifindex; request.port_no = *port_nop; dpif_netlink_vport_transact(&request, NULL, NULL); vport_del_socksp(dpif, socksp); goto exit; } } free(socksp); exit: ofpbuf_delete(buf); free(upcall_pids); return error; } static int dpif_netlink_port_add(struct dpif *dpif_, struct netdev *netdev, odp_port_t *port_nop) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); int error; fat_rwlock_wrlock(&dpif->upcall_lock); error = dpif_netlink_port_add__(dpif, netdev, port_nop); fat_rwlock_unlock(&dpif->upcall_lock); return error; } static int dpif_netlink_port_del__(struct dpif_netlink *dpif, odp_port_t port_no) OVS_REQ_WRLOCK(dpif->upcall_lock) { struct dpif_netlink_vport vport; int error; dpif_netlink_vport_init(&vport); vport.cmd = OVS_VPORT_CMD_DEL; vport.dp_ifindex = dpif->dp_ifindex; vport.port_no = port_no; error = dpif_netlink_vport_transact(&vport, NULL, NULL); vport_del_channels(dpif, port_no); return error; } static int dpif_netlink_port_del(struct dpif *dpif_, odp_port_t port_no) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); int error; fat_rwlock_wrlock(&dpif->upcall_lock); error = dpif_netlink_port_del__(dpif, port_no); fat_rwlock_unlock(&dpif->upcall_lock); return error; } static int dpif_netlink_port_query__(const struct dpif_netlink *dpif, odp_port_t port_no, const char *port_name, struct dpif_port *dpif_port) { struct dpif_netlink_vport request; struct dpif_netlink_vport reply; struct ofpbuf *buf; int error; dpif_netlink_vport_init(&request); request.cmd = OVS_VPORT_CMD_GET; request.dp_ifindex = dpif->dp_ifindex; request.port_no = port_no; request.name = port_name; error = dpif_netlink_vport_transact(&request, &reply, &buf); if (!error) { if (reply.dp_ifindex != request.dp_ifindex) { /* A query by name reported that 'port_name' is in some datapath * other than 'dpif', but the caller wants to know about 'dpif'. */ error = ENODEV; } else if (dpif_port) { dpif_port->name = xstrdup(reply.name); dpif_port->type = xstrdup(get_vport_type(&reply)); dpif_port->port_no = reply.port_no; } ofpbuf_delete(buf); } return error; } static int dpif_netlink_port_query_by_number(const struct dpif *dpif_, odp_port_t port_no, struct dpif_port *dpif_port) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); return dpif_netlink_port_query__(dpif, port_no, NULL, dpif_port); } static int dpif_netlink_port_query_by_name(const struct dpif *dpif_, const char *devname, struct dpif_port *dpif_port) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); return dpif_netlink_port_query__(dpif, 0, devname, dpif_port); } static uint32_t dpif_netlink_port_get_pid__(const struct dpif_netlink *dpif, odp_port_t port_no, uint32_t hash) OVS_REQ_RDLOCK(dpif->upcall_lock) { uint32_t port_idx = odp_to_u32(port_no); uint32_t pid = 0; if (dpif->handlers && dpif->uc_array_size > 0) { /* The ODPP_NONE "reserved" port number uses the "ovs-system"'s * channel, since it is not heavily loaded. */ uint32_t idx = port_idx >= dpif->uc_array_size ? 0 : port_idx; struct dpif_handler *h = &dpif->handlers[hash % dpif->n_handlers]; /* Needs to check in case the socket pointer is changed in between * the holding of upcall_lock. A known case happens when the main * thread deletes the vport while the handler thread is handling * the upcall from that port. */ if (h->channels[idx].sock) { pid = nl_sock_pid(h->channels[idx].sock); } } return pid; } static uint32_t dpif_netlink_port_get_pid(const struct dpif *dpif_, odp_port_t port_no, uint32_t hash) { const struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); uint32_t ret; fat_rwlock_rdlock(&dpif->upcall_lock); ret = dpif_netlink_port_get_pid__(dpif, port_no, hash); fat_rwlock_unlock(&dpif->upcall_lock); return ret; } static int dpif_netlink_flow_flush(struct dpif *dpif_) { const struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); struct dpif_netlink_flow flow; dpif_netlink_flow_init(&flow); flow.cmd = OVS_FLOW_CMD_DEL; flow.dp_ifindex = dpif->dp_ifindex; return dpif_netlink_flow_transact(&flow, NULL, NULL); } struct dpif_netlink_port_state { struct nl_dump dump; struct ofpbuf buf; }; static void dpif_netlink_port_dump_start__(const struct dpif_netlink *dpif, struct nl_dump *dump) { struct dpif_netlink_vport request; struct ofpbuf *buf; dpif_netlink_vport_init(&request); request.cmd = OVS_VPORT_CMD_GET; request.dp_ifindex = dpif->dp_ifindex; buf = ofpbuf_new(1024); dpif_netlink_vport_to_ofpbuf(&request, buf); nl_dump_start(dump, NETLINK_GENERIC, buf); ofpbuf_delete(buf); } static int dpif_netlink_port_dump_start(const struct dpif *dpif_, void **statep) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); struct dpif_netlink_port_state *state; *statep = state = xmalloc(sizeof *state); dpif_netlink_port_dump_start__(dpif, &state->dump); ofpbuf_init(&state->buf, NL_DUMP_BUFSIZE); return 0; } static int dpif_netlink_port_dump_next__(const struct dpif_netlink *dpif, struct nl_dump *dump, struct dpif_netlink_vport *vport, struct ofpbuf *buffer) { struct ofpbuf buf; int error; if (!nl_dump_next(dump, &buf, buffer)) { return EOF; } error = dpif_netlink_vport_from_ofpbuf(vport, &buf); if (error) { VLOG_WARN_RL(&error_rl, "%s: failed to parse vport record (%s)", dpif_name(&dpif->dpif), ovs_strerror(error)); } return error; } static int dpif_netlink_port_dump_next(const struct dpif *dpif_, void *state_, struct dpif_port *dpif_port) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); struct dpif_netlink_port_state *state = state_; struct dpif_netlink_vport vport; int error; error = dpif_netlink_port_dump_next__(dpif, &state->dump, &vport, &state->buf); if (error) { return error; } dpif_port->name = CONST_CAST(char *, vport.name); dpif_port->type = CONST_CAST(char *, get_vport_type(&vport)); dpif_port->port_no = vport.port_no; return 0; } static int dpif_netlink_port_dump_done(const struct dpif *dpif_ OVS_UNUSED, void *state_) { struct dpif_netlink_port_state *state = state_; int error = nl_dump_done(&state->dump); ofpbuf_uninit(&state->buf); free(state); return error; } static int dpif_netlink_port_poll(const struct dpif *dpif_, char **devnamep) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); /* Lazily create the Netlink socket to listen for notifications. */ if (!dpif->port_notifier) { struct nl_sock *sock; int error; error = nl_sock_create(NETLINK_GENERIC, &sock); if (error) { return error; } error = nl_sock_join_mcgroup(sock, ovs_vport_mcgroup); if (error) { nl_sock_destroy(sock); return error; } dpif->port_notifier = sock; /* We have no idea of the current state so report that everything * changed. */ return ENOBUFS; } for (;;) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5); uint64_t buf_stub[4096 / 8]; struct ofpbuf buf; int error; ofpbuf_use_stub(&buf, buf_stub, sizeof buf_stub); error = nl_sock_recv(dpif->port_notifier, &buf, false); if (!error) { struct dpif_netlink_vport vport; error = dpif_netlink_vport_from_ofpbuf(&vport, &buf); if (!error) { if (vport.dp_ifindex == dpif->dp_ifindex && (vport.cmd == OVS_VPORT_CMD_NEW || vport.cmd == OVS_VPORT_CMD_DEL || vport.cmd == OVS_VPORT_CMD_SET)) { VLOG_DBG("port_changed: dpif:%s vport:%s cmd:%"PRIu8, dpif->dpif.full_name, vport.name, vport.cmd); if (vport.cmd == OVS_VPORT_CMD_DEL && dpif->handlers) { dpif->refresh_channels = true; } *devnamep = xstrdup(vport.name); ofpbuf_uninit(&buf); return 0; } } } else if (error != EAGAIN) { VLOG_WARN_RL(&rl, "error reading or parsing netlink (%s)", ovs_strerror(error)); nl_sock_drain(dpif->port_notifier); error = ENOBUFS; } ofpbuf_uninit(&buf); if (error) { return error; } } } static void dpif_netlink_port_poll_wait(const struct dpif *dpif_) { const struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); if (dpif->port_notifier) { nl_sock_wait(dpif->port_notifier, POLLIN); } else { poll_immediate_wake(); } } static void dpif_netlink_flow_init_ufid(struct dpif_netlink_flow *request, const ovs_u128 *ufid, bool terse) { if (ufid) { request->ufid = *ufid; request->ufid_present = true; } else { request->ufid_present = false; } request->ufid_terse = terse; } static void dpif_netlink_init_flow_get__(const struct dpif_netlink *dpif, const struct nlattr *key, size_t key_len, const ovs_u128 *ufid, bool terse, struct dpif_netlink_flow *request) { dpif_netlink_flow_init(request); request->cmd = OVS_FLOW_CMD_GET; request->dp_ifindex = dpif->dp_ifindex; request->key = key; request->key_len = key_len; dpif_netlink_flow_init_ufid(request, ufid, terse); } static void dpif_netlink_init_flow_get(const struct dpif_netlink *dpif, const struct dpif_flow_get *get, struct dpif_netlink_flow *request) { dpif_netlink_init_flow_get__(dpif, get->key, get->key_len, get->ufid, false, request); } static int dpif_netlink_flow_get__(const struct dpif_netlink *dpif, const struct nlattr *key, size_t key_len, const ovs_u128 *ufid, bool terse, struct dpif_netlink_flow *reply, struct ofpbuf **bufp) { struct dpif_netlink_flow request; dpif_netlink_init_flow_get__(dpif, key, key_len, ufid, terse, &request); return dpif_netlink_flow_transact(&request, reply, bufp); } static int dpif_netlink_flow_get(const struct dpif_netlink *dpif, const struct dpif_netlink_flow *flow, struct dpif_netlink_flow *reply, struct ofpbuf **bufp) { return dpif_netlink_flow_get__(dpif, flow->key, flow->key_len, flow->ufid_present ? &flow->ufid : NULL, false, reply, bufp); } static void dpif_netlink_init_flow_put(struct dpif_netlink *dpif, const struct dpif_flow_put *put, struct dpif_netlink_flow *request) { static const struct nlattr dummy_action; dpif_netlink_flow_init(request); request->cmd = (put->flags & DPIF_FP_CREATE ? OVS_FLOW_CMD_NEW : OVS_FLOW_CMD_SET); request->dp_ifindex = dpif->dp_ifindex; request->key = put->key; request->key_len = put->key_len; request->mask = put->mask; request->mask_len = put->mask_len; dpif_netlink_flow_init_ufid(request, put->ufid, false); /* Ensure that OVS_FLOW_ATTR_ACTIONS will always be included. */ request->actions = (put->actions ? put->actions : CONST_CAST(struct nlattr *, &dummy_action)); request->actions_len = put->actions_len; if (put->flags & DPIF_FP_ZERO_STATS) { request->clear = true; } if (put->flags & DPIF_FP_PROBE) { request->probe = true; } request->nlmsg_flags = put->flags & DPIF_FP_MODIFY ? 0 : NLM_F_CREATE; } static void dpif_netlink_init_flow_del__(struct dpif_netlink *dpif, const struct nlattr *key, size_t key_len, const ovs_u128 *ufid, bool terse, struct dpif_netlink_flow *request) { dpif_netlink_flow_init(request); request->cmd = OVS_FLOW_CMD_DEL; request->dp_ifindex = dpif->dp_ifindex; request->key = key; request->key_len = key_len; dpif_netlink_flow_init_ufid(request, ufid, terse); } static void dpif_netlink_init_flow_del(struct dpif_netlink *dpif, const struct dpif_flow_del *del, struct dpif_netlink_flow *request) { dpif_netlink_init_flow_del__(dpif, del->key, del->key_len, del->ufid, del->terse, request); } struct dpif_netlink_flow_dump { struct dpif_flow_dump up; struct nl_dump nl_dump; atomic_int status; }; static struct dpif_netlink_flow_dump * dpif_netlink_flow_dump_cast(struct dpif_flow_dump *dump) { return CONTAINER_OF(dump, struct dpif_netlink_flow_dump, up); } static struct dpif_flow_dump * dpif_netlink_flow_dump_create(const struct dpif *dpif_, bool terse) { const struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); struct dpif_netlink_flow_dump *dump; struct dpif_netlink_flow request; struct ofpbuf *buf; dump = xmalloc(sizeof *dump); dpif_flow_dump_init(&dump->up, dpif_); dpif_netlink_flow_init(&request); request.cmd = OVS_FLOW_CMD_GET; request.dp_ifindex = dpif->dp_ifindex; request.ufid_present = false; request.ufid_terse = terse; buf = ofpbuf_new(1024); dpif_netlink_flow_to_ofpbuf(&request, buf); nl_dump_start(&dump->nl_dump, NETLINK_GENERIC, buf); ofpbuf_delete(buf); atomic_init(&dump->status, 0); dump->up.terse = terse; return &dump->up; } static int dpif_netlink_flow_dump_destroy(struct dpif_flow_dump *dump_) { struct dpif_netlink_flow_dump *dump = dpif_netlink_flow_dump_cast(dump_); unsigned int nl_status = nl_dump_done(&dump->nl_dump); int dump_status; /* No other thread has access to 'dump' at this point. */ atomic_read_relaxed(&dump->status, &dump_status); free(dump); return dump_status ? dump_status : nl_status; } struct dpif_netlink_flow_dump_thread { struct dpif_flow_dump_thread up; struct dpif_netlink_flow_dump *dump; struct dpif_netlink_flow flow; struct dpif_flow_stats stats; struct ofpbuf nl_flows; /* Always used to store flows. */ struct ofpbuf *nl_actions; /* Used if kernel does not supply actions. */ }; static struct dpif_netlink_flow_dump_thread * dpif_netlink_flow_dump_thread_cast(struct dpif_flow_dump_thread *thread) { return CONTAINER_OF(thread, struct dpif_netlink_flow_dump_thread, up); } static struct dpif_flow_dump_thread * dpif_netlink_flow_dump_thread_create(struct dpif_flow_dump *dump_) { struct dpif_netlink_flow_dump *dump = dpif_netlink_flow_dump_cast(dump_); struct dpif_netlink_flow_dump_thread *thread; thread = xmalloc(sizeof *thread); dpif_flow_dump_thread_init(&thread->up, &dump->up); thread->dump = dump; ofpbuf_init(&thread->nl_flows, NL_DUMP_BUFSIZE); thread->nl_actions = NULL; return &thread->up; } static void dpif_netlink_flow_dump_thread_destroy(struct dpif_flow_dump_thread *thread_) { struct dpif_netlink_flow_dump_thread *thread = dpif_netlink_flow_dump_thread_cast(thread_); ofpbuf_uninit(&thread->nl_flows); ofpbuf_delete(thread->nl_actions); free(thread); } static void dpif_netlink_flow_to_dpif_flow(struct dpif *dpif, struct dpif_flow *dpif_flow, const struct dpif_netlink_flow *datapath_flow) { dpif_flow->key = datapath_flow->key; dpif_flow->key_len = datapath_flow->key_len; dpif_flow->mask = datapath_flow->mask; dpif_flow->mask_len = datapath_flow->mask_len; dpif_flow->actions = datapath_flow->actions; dpif_flow->actions_len = datapath_flow->actions_len; dpif_flow->ufid_present = datapath_flow->ufid_present; dpif_flow->pmd_id = PMD_ID_NULL; if (datapath_flow->ufid_present) { dpif_flow->ufid = datapath_flow->ufid; } else { ovs_assert(datapath_flow->key && datapath_flow->key_len); dpif_flow_hash(dpif, datapath_flow->key, datapath_flow->key_len, &dpif_flow->ufid); } dpif_netlink_flow_get_stats(datapath_flow, &dpif_flow->stats); } static int dpif_netlink_flow_dump_next(struct dpif_flow_dump_thread *thread_, struct dpif_flow *flows, int max_flows) { struct dpif_netlink_flow_dump_thread *thread = dpif_netlink_flow_dump_thread_cast(thread_); struct dpif_netlink_flow_dump *dump = thread->dump; struct dpif_netlink *dpif = dpif_netlink_cast(thread->up.dpif); int n_flows; ofpbuf_delete(thread->nl_actions); thread->nl_actions = NULL; n_flows = 0; while (!n_flows || (n_flows < max_flows && thread->nl_flows.size)) { struct dpif_netlink_flow datapath_flow; struct ofpbuf nl_flow; int error; /* Try to grab another flow. */ if (!nl_dump_next(&dump->nl_dump, &nl_flow, &thread->nl_flows)) { break; } /* Convert the flow to our output format. */ error = dpif_netlink_flow_from_ofpbuf(&datapath_flow, &nl_flow); if (error) { atomic_store_relaxed(&dump->status, error); break; } if (dump->up.terse || datapath_flow.actions) { /* Common case: we don't want actions, or the flow includes * actions. */ dpif_netlink_flow_to_dpif_flow(&dpif->dpif, &flows[n_flows++], &datapath_flow); } else { /* Rare case: the flow does not include actions. Retrieve this * individual flow again to get the actions. */ error = dpif_netlink_flow_get(dpif, &datapath_flow, &datapath_flow, &thread->nl_actions); if (error == ENOENT) { VLOG_DBG("dumped flow disappeared on get"); continue; } else if (error) { VLOG_WARN("error fetching dumped flow: %s", ovs_strerror(error)); atomic_store_relaxed(&dump->status, error); break; } /* Save this flow. Then exit, because we only have one buffer to * handle this case. */ dpif_netlink_flow_to_dpif_flow(&dpif->dpif, &flows[n_flows++], &datapath_flow); break; } } return n_flows; } static void dpif_netlink_encode_execute(int dp_ifindex, const struct dpif_execute *d_exec, struct ofpbuf *buf) { struct ovs_header *k_exec; size_t key_ofs; ofpbuf_prealloc_tailroom(buf, (64 + dp_packet_size(d_exec->packet) + ODP_KEY_METADATA_SIZE + d_exec->actions_len)); nl_msg_put_genlmsghdr(buf, 0, ovs_packet_family, NLM_F_REQUEST, OVS_PACKET_CMD_EXECUTE, OVS_PACKET_VERSION); k_exec = ofpbuf_put_uninit(buf, sizeof *k_exec); k_exec->dp_ifindex = dp_ifindex; nl_msg_put_unspec(buf, OVS_PACKET_ATTR_PACKET, dp_packet_data(d_exec->packet), dp_packet_size(d_exec->packet)); key_ofs = nl_msg_start_nested(buf, OVS_PACKET_ATTR_KEY); odp_key_from_pkt_metadata(buf, &d_exec->packet->md); nl_msg_end_nested(buf, key_ofs); nl_msg_put_unspec(buf, OVS_PACKET_ATTR_ACTIONS, d_exec->actions, d_exec->actions_len); if (d_exec->probe) { nl_msg_put_flag(buf, OVS_PACKET_ATTR_PROBE); } if (d_exec->mtu) { nl_msg_put_u16(buf, OVS_PACKET_ATTR_MRU, d_exec->mtu); } } /* Executes, against 'dpif', up to the first 'n_ops' operations in 'ops'. * Returns the number actually executed (at least 1, if 'n_ops' is * positive). */ static size_t dpif_netlink_operate__(struct dpif_netlink *dpif, struct dpif_op **ops, size_t n_ops) { enum { MAX_OPS = 50 }; struct op_auxdata { struct nl_transaction txn; struct ofpbuf request; uint64_t request_stub[1024 / 8]; struct ofpbuf reply; uint64_t reply_stub[1024 / 8]; } auxes[MAX_OPS]; struct nl_transaction *txnsp[MAX_OPS]; size_t i; n_ops = MIN(n_ops, MAX_OPS); for (i = 0; i < n_ops; i++) { struct op_auxdata *aux = &auxes[i]; struct dpif_op *op = ops[i]; struct dpif_flow_put *put; struct dpif_flow_del *del; struct dpif_flow_get *get; struct dpif_netlink_flow flow; ofpbuf_use_stub(&aux->request, aux->request_stub, sizeof aux->request_stub); aux->txn.request = &aux->request; ofpbuf_use_stub(&aux->reply, aux->reply_stub, sizeof aux->reply_stub); aux->txn.reply = NULL; switch (op->type) { case DPIF_OP_FLOW_PUT: put = &op->u.flow_put; dpif_netlink_init_flow_put(dpif, put, &flow); if (put->stats) { flow.nlmsg_flags |= NLM_F_ECHO; aux->txn.reply = &aux->reply; } dpif_netlink_flow_to_ofpbuf(&flow, &aux->request); break; case DPIF_OP_FLOW_DEL: del = &op->u.flow_del; dpif_netlink_init_flow_del(dpif, del, &flow); if (del->stats) { flow.nlmsg_flags |= NLM_F_ECHO; aux->txn.reply = &aux->reply; } dpif_netlink_flow_to_ofpbuf(&flow, &aux->request); break; case DPIF_OP_EXECUTE: /* Can't execute a packet that won't fit in a Netlink attribute. */ if (OVS_UNLIKELY(nl_attr_oversized( dp_packet_size(op->u.execute.packet)))) { /* Report an error immediately if this is the first operation. * Otherwise the easiest thing to do is to postpone to the next * call (when this will be the first operation). */ if (i == 0) { VLOG_ERR_RL(&error_rl, "dropping oversized %"PRIu32"-byte packet", dp_packet_size(op->u.execute.packet)); op->error = ENOBUFS; return 1; } n_ops = i; } else { dpif_netlink_encode_execute(dpif->dp_ifindex, &op->u.execute, &aux->request); } break; case DPIF_OP_FLOW_GET: get = &op->u.flow_get; dpif_netlink_init_flow_get(dpif, get, &flow); aux->txn.reply = get->buffer; dpif_netlink_flow_to_ofpbuf(&flow, &aux->request); break; default: OVS_NOT_REACHED(); } } for (i = 0; i < n_ops; i++) { txnsp[i] = &auxes[i].txn; } nl_transact_multiple(NETLINK_GENERIC, txnsp, n_ops); for (i = 0; i < n_ops; i++) { struct op_auxdata *aux = &auxes[i]; struct nl_transaction *txn = &auxes[i].txn; struct dpif_op *op = ops[i]; struct dpif_flow_put *put; struct dpif_flow_del *del; struct dpif_flow_get *get; op->error = txn->error; switch (op->type) { case DPIF_OP_FLOW_PUT: put = &op->u.flow_put; if (put->stats) { if (!op->error) { struct dpif_netlink_flow reply; op->error = dpif_netlink_flow_from_ofpbuf(&reply, txn->reply); if (!op->error) { dpif_netlink_flow_get_stats(&reply, put->stats); } } } break; case DPIF_OP_FLOW_DEL: del = &op->u.flow_del; if (del->stats) { if (!op->error) { struct dpif_netlink_flow reply; op->error = dpif_netlink_flow_from_ofpbuf(&reply, txn->reply); if (!op->error) { dpif_netlink_flow_get_stats(&reply, del->stats); } } } break; case DPIF_OP_EXECUTE: break; case DPIF_OP_FLOW_GET: get = &op->u.flow_get; if (!op->error) { struct dpif_netlink_flow reply; op->error = dpif_netlink_flow_from_ofpbuf(&reply, txn->reply); if (!op->error) { dpif_netlink_flow_to_dpif_flow(&dpif->dpif, get->flow, &reply); } } break; default: OVS_NOT_REACHED(); } ofpbuf_uninit(&aux->request); ofpbuf_uninit(&aux->reply); } return n_ops; } static void dpif_netlink_operate(struct dpif *dpif_, struct dpif_op **ops, size_t n_ops) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); while (n_ops > 0) { size_t chunk = dpif_netlink_operate__(dpif, ops, n_ops); ops += chunk; n_ops -= chunk; } } #if _WIN32 static void dpif_netlink_handler_uninit(struct dpif_handler *handler) { vport_delete_sock_pool(handler); } static int dpif_netlink_handler_init(struct dpif_handler *handler) { return vport_create_sock_pool(handler); } #else static int dpif_netlink_handler_init(struct dpif_handler *handler) { handler->epoll_fd = epoll_create(10); return handler->epoll_fd < 0 ? errno : 0; } static void dpif_netlink_handler_uninit(struct dpif_handler *handler) { close(handler->epoll_fd); } #endif /* Synchronizes 'channels' in 'dpif->handlers' with the set of vports * currently in 'dpif' in the kernel, by adding a new set of channels for * any kernel vport that lacks one and deleting any channels that have no * backing kernel vports. */ static int dpif_netlink_refresh_channels(struct dpif_netlink *dpif, uint32_t n_handlers) OVS_REQ_WRLOCK(dpif->upcall_lock) { unsigned long int *keep_channels; struct dpif_netlink_vport vport; size_t keep_channels_nbits; struct nl_dump dump; uint64_t reply_stub[NL_DUMP_BUFSIZE / 8]; struct ofpbuf buf; int retval = 0; size_t i; ovs_assert(!WINDOWS || n_handlers <= 1); ovs_assert(!WINDOWS || dpif->n_handlers <= 1); if (dpif->n_handlers != n_handlers) { destroy_all_channels(dpif); dpif->handlers = xzalloc(n_handlers * sizeof *dpif->handlers); for (i = 0; i < n_handlers; i++) { int error; struct dpif_handler *handler = &dpif->handlers[i]; error = dpif_netlink_handler_init(handler); if (error) { size_t j; struct dpif_handler *tmp = &dpif->handlers[i]; for (j = 0; j < i; j++) { dpif_netlink_handler_uninit(tmp); } free(dpif->handlers); dpif->handlers = NULL; return error; } } dpif->n_handlers = n_handlers; } for (i = 0; i < n_handlers; i++) { struct dpif_handler *handler = &dpif->handlers[i]; handler->event_offset = handler->n_events = 0; } keep_channels_nbits = dpif->uc_array_size; keep_channels = bitmap_allocate(keep_channels_nbits); ofpbuf_use_stub(&buf, reply_stub, sizeof reply_stub); dpif_netlink_port_dump_start__(dpif, &dump); while (!dpif_netlink_port_dump_next__(dpif, &dump, &vport, &buf)) { uint32_t port_no = odp_to_u32(vport.port_no); uint32_t *upcall_pids = NULL; int error; if (port_no >= dpif->uc_array_size || !vport_get_pids(dpif, port_no, &upcall_pids)) { struct nl_sock **socksp = vport_create_socksp(dpif, &error); if (!socksp) { goto error; } error = vport_add_channels(dpif, vport.port_no, socksp); if (error) { VLOG_INFO("%s: could not add channels for port %s", dpif_name(&dpif->dpif), vport.name); vport_del_socksp(dpif, socksp); retval = error; goto error; } upcall_pids = vport_socksp_to_pids(socksp, dpif->n_handlers); free(socksp); } /* Configure the vport to deliver misses to 'sock'. */ if (vport.upcall_pids[0] == 0 || vport.n_upcall_pids != dpif->n_handlers || memcmp(upcall_pids, vport.upcall_pids, n_handlers * sizeof *upcall_pids)) { struct dpif_netlink_vport vport_request; dpif_netlink_vport_init(&vport_request); vport_request.cmd = OVS_VPORT_CMD_SET; vport_request.dp_ifindex = dpif->dp_ifindex; vport_request.port_no = vport.port_no; vport_request.n_upcall_pids = dpif->n_handlers; vport_request.upcall_pids = upcall_pids; error = dpif_netlink_vport_transact(&vport_request, NULL, NULL); if (error) { VLOG_WARN_RL(&error_rl, "%s: failed to set upcall pid on port: %s", dpif_name(&dpif->dpif), ovs_strerror(error)); if (error != ENODEV && error != ENOENT) { retval = error; } else { /* The vport isn't really there, even though the dump says * it is. Probably we just hit a race after a port * disappeared. */ } goto error; } } if (port_no < keep_channels_nbits) { bitmap_set1(keep_channels, port_no); } free(upcall_pids); continue; error: free(upcall_pids); vport_del_channels(dpif, vport.port_no); } nl_dump_done(&dump); ofpbuf_uninit(&buf); /* Discard any saved channels that we didn't reuse. */ for (i = 0; i < keep_channels_nbits; i++) { if (!bitmap_is_set(keep_channels, i)) { vport_del_channels(dpif, u32_to_odp(i)); } } free(keep_channels); return retval; } static int dpif_netlink_recv_set__(struct dpif_netlink *dpif, bool enable) OVS_REQ_WRLOCK(dpif->upcall_lock) { if ((dpif->handlers != NULL) == enable) { return 0; } else if (!enable) { destroy_all_channels(dpif); return 0; } else { return dpif_netlink_refresh_channels(dpif, 1); } } static int dpif_netlink_recv_set(struct dpif *dpif_, bool enable) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); int error; fat_rwlock_wrlock(&dpif->upcall_lock); error = dpif_netlink_recv_set__(dpif, enable); fat_rwlock_unlock(&dpif->upcall_lock); return error; } static int dpif_netlink_handlers_set(struct dpif *dpif_, uint32_t n_handlers) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); int error = 0; #ifdef _WIN32 /* Multiple upcall handlers will be supported once kernel datapath supports * it. */ if (n_handlers > 1) { return error; } #endif fat_rwlock_wrlock(&dpif->upcall_lock); if (dpif->handlers) { error = dpif_netlink_refresh_channels(dpif, n_handlers); } fat_rwlock_unlock(&dpif->upcall_lock); return error; } static int dpif_netlink_queue_to_priority(const struct dpif *dpif OVS_UNUSED, uint32_t queue_id, uint32_t *priority) { if (queue_id < 0xf000) { *priority = TC_H_MAKE(1 << 16, queue_id + 1); return 0; } else { return EINVAL; } } static int parse_odp_packet(const struct dpif_netlink *dpif, struct ofpbuf *buf, struct dpif_upcall *upcall, int *dp_ifindex) { static const struct nl_policy ovs_packet_policy[] = { /* Always present. */ [OVS_PACKET_ATTR_PACKET] = { .type = NL_A_UNSPEC, .min_len = ETH_HEADER_LEN }, [OVS_PACKET_ATTR_KEY] = { .type = NL_A_NESTED }, /* OVS_PACKET_CMD_ACTION only. */ [OVS_PACKET_ATTR_USERDATA] = { .type = NL_A_UNSPEC, .optional = true }, [OVS_PACKET_ATTR_EGRESS_TUN_KEY] = { .type = NL_A_NESTED, .optional = true }, [OVS_PACKET_ATTR_ACTIONS] = { .type = NL_A_NESTED, .optional = true }, [OVS_PACKET_ATTR_MRU] = { .type = NL_A_U16, .optional = true } }; struct ofpbuf b = ofpbuf_const_initializer(buf->data, buf->size); struct nlmsghdr *nlmsg = ofpbuf_try_pull(&b, sizeof *nlmsg); struct genlmsghdr *genl = ofpbuf_try_pull(&b, sizeof *genl); struct ovs_header *ovs_header = ofpbuf_try_pull(&b, sizeof *ovs_header); struct nlattr *a[ARRAY_SIZE(ovs_packet_policy)]; if (!nlmsg || !genl || !ovs_header || nlmsg->nlmsg_type != ovs_packet_family || !nl_policy_parse(&b, 0, ovs_packet_policy, a, ARRAY_SIZE(ovs_packet_policy))) { return EINVAL; } int type = (genl->cmd == OVS_PACKET_CMD_MISS ? DPIF_UC_MISS : genl->cmd == OVS_PACKET_CMD_ACTION ? DPIF_UC_ACTION : -1); if (type < 0) { return EINVAL; } /* (Re)set ALL fields of '*upcall' on successful return. */ upcall->type = type; upcall->key = CONST_CAST(struct nlattr *, nl_attr_get(a[OVS_PACKET_ATTR_KEY])); upcall->key_len = nl_attr_get_size(a[OVS_PACKET_ATTR_KEY]); dpif_flow_hash(&dpif->dpif, upcall->key, upcall->key_len, &upcall->ufid); upcall->userdata = a[OVS_PACKET_ATTR_USERDATA]; upcall->out_tun_key = a[OVS_PACKET_ATTR_EGRESS_TUN_KEY]; upcall->actions = a[OVS_PACKET_ATTR_ACTIONS]; upcall->mru = a[OVS_PACKET_ATTR_MRU]; /* Allow overwriting the netlink attribute header without reallocating. */ dp_packet_use_stub(&upcall->packet, CONST_CAST(struct nlattr *, nl_attr_get(a[OVS_PACKET_ATTR_PACKET])) - 1, nl_attr_get_size(a[OVS_PACKET_ATTR_PACKET]) + sizeof(struct nlattr)); dp_packet_set_data(&upcall->packet, (char *)dp_packet_data(&upcall->packet) + sizeof(struct nlattr)); dp_packet_set_size(&upcall->packet, nl_attr_get_size(a[OVS_PACKET_ATTR_PACKET])); *dp_ifindex = ovs_header->dp_ifindex; return 0; } #ifdef _WIN32 #define PACKET_RECV_BATCH_SIZE 50 static int dpif_netlink_recv_windows(struct dpif_netlink *dpif, uint32_t handler_id, struct dpif_upcall *upcall, struct ofpbuf *buf) OVS_REQ_RDLOCK(dpif->upcall_lock) { struct dpif_handler *handler; int read_tries = 0; struct dpif_windows_vport_sock *sock_pool; uint32_t i; if (!dpif->handlers) { return EAGAIN; } /* Only one handler is supported currently. */ if (handler_id >= 1) { return EAGAIN; } if (handler_id >= dpif->n_handlers) { return EAGAIN; } handler = &dpif->handlers[handler_id]; sock_pool = handler->vport_sock_pool; for (i = 0; i < VPORT_SOCK_POOL_SIZE; i++) { for (;;) { int dp_ifindex; int error; if (++read_tries > PACKET_RECV_BATCH_SIZE) { return EAGAIN; } error = nl_sock_recv(sock_pool[i].nl_sock, buf, false); if (error == ENOBUFS) { /* ENOBUFS typically means that we've received so many * packets that the buffer overflowed. Try again * immediately because there's almost certainly a packet * waiting for us. */ /* XXX: report_loss(dpif, ch, idx, handler_id); */ continue; } /* XXX: ch->last_poll = time_msec(); */ if (error) { if (error == EAGAIN) { break; } return error; } error = parse_odp_packet(dpif, buf, upcall, &dp_ifindex); if (!error && dp_ifindex == dpif->dp_ifindex) { return 0; } else if (error) { return error; } } } return EAGAIN; } #else static int dpif_netlink_recv__(struct dpif_netlink *dpif, uint32_t handler_id, struct dpif_upcall *upcall, struct ofpbuf *buf) OVS_REQ_RDLOCK(dpif->upcall_lock) { struct dpif_handler *handler; int read_tries = 0; if (!dpif->handlers || handler_id >= dpif->n_handlers) { return EAGAIN; } handler = &dpif->handlers[handler_id]; if (handler->event_offset >= handler->n_events) { int retval; handler->event_offset = handler->n_events = 0; do { retval = epoll_wait(handler->epoll_fd, handler->epoll_events, dpif->uc_array_size, 0); } while (retval < 0 && errno == EINTR); if (retval < 0) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1); VLOG_WARN_RL(&rl, "epoll_wait failed (%s)", ovs_strerror(errno)); } else if (retval > 0) { handler->n_events = retval; } } while (handler->event_offset < handler->n_events) { int idx = handler->epoll_events[handler->event_offset].data.u32; struct dpif_channel *ch = &dpif->handlers[handler_id].channels[idx]; handler->event_offset++; for (;;) { int dp_ifindex; int error; if (++read_tries > 50) { return EAGAIN; } error = nl_sock_recv(ch->sock, buf, false); if (error == ENOBUFS) { /* ENOBUFS typically means that we've received so many * packets that the buffer overflowed. Try again * immediately because there's almost certainly a packet * waiting for us. */ report_loss(dpif, ch, idx, handler_id); continue; } ch->last_poll = time_msec(); if (error) { if (error == EAGAIN) { break; } return error; } error = parse_odp_packet(dpif, buf, upcall, &dp_ifindex); if (!error && dp_ifindex == dpif->dp_ifindex) { return 0; } else if (error) { return error; } } } return EAGAIN; } #endif static int dpif_netlink_recv(struct dpif *dpif_, uint32_t handler_id, struct dpif_upcall *upcall, struct ofpbuf *buf) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); int error; fat_rwlock_rdlock(&dpif->upcall_lock); #ifdef _WIN32 error = dpif_netlink_recv_windows(dpif, handler_id, upcall, buf); #else error = dpif_netlink_recv__(dpif, handler_id, upcall, buf); #endif fat_rwlock_unlock(&dpif->upcall_lock); return error; } static void dpif_netlink_recv_wait__(struct dpif_netlink *dpif, uint32_t handler_id) OVS_REQ_RDLOCK(dpif->upcall_lock) { #ifdef _WIN32 uint32_t i; struct dpif_windows_vport_sock *sock_pool = dpif->handlers[handler_id].vport_sock_pool; /* Only one handler is supported currently. */ if (handler_id >= 1) { return; } for (i = 0; i < VPORT_SOCK_POOL_SIZE; i++) { nl_sock_wait(sock_pool[i].nl_sock, POLLIN); } #else if (dpif->handlers && handler_id < dpif->n_handlers) { struct dpif_handler *handler = &dpif->handlers[handler_id]; poll_fd_wait(handler->epoll_fd, POLLIN); } #endif } static void dpif_netlink_recv_wait(struct dpif *dpif_, uint32_t handler_id) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); fat_rwlock_rdlock(&dpif->upcall_lock); dpif_netlink_recv_wait__(dpif, handler_id); fat_rwlock_unlock(&dpif->upcall_lock); } static void dpif_netlink_recv_purge__(struct dpif_netlink *dpif) OVS_REQ_WRLOCK(dpif->upcall_lock) { if (dpif->handlers) { size_t i, j; for (i = 0; i < dpif->uc_array_size; i++ ) { if (!dpif->handlers[0].channels[i].sock) { continue; } for (j = 0; j < dpif->n_handlers; j++) { nl_sock_drain(dpif->handlers[j].channels[i].sock); } } } } static void dpif_netlink_recv_purge(struct dpif *dpif_) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); fat_rwlock_wrlock(&dpif->upcall_lock); dpif_netlink_recv_purge__(dpif); fat_rwlock_unlock(&dpif->upcall_lock); } static char * dpif_netlink_get_datapath_version(void) { char *version_str = NULL; #ifdef __linux__ #define MAX_VERSION_STR_SIZE 80 #define LINUX_DATAPATH_VERSION_FILE "/sys/module/openvswitch/version" FILE *f; f = fopen(LINUX_DATAPATH_VERSION_FILE, "r"); if (f) { char *newline; char version[MAX_VERSION_STR_SIZE]; if (fgets(version, MAX_VERSION_STR_SIZE, f)) { newline = strchr(version, '\n'); if (newline) { *newline = '\0'; } version_str = xstrdup(version); } fclose(f); } #endif return version_str; } #ifdef __linux__ struct dpif_netlink_ct_dump_state { struct ct_dpif_dump_state up; struct nl_ct_dump_state *nl_ct_dump; }; static int dpif_netlink_ct_dump_start(struct dpif *dpif OVS_UNUSED, struct ct_dpif_dump_state **dump_, const uint16_t *zone) { struct dpif_netlink_ct_dump_state *dump; int err; dump = xzalloc(sizeof *dump); err = nl_ct_dump_start(&dump->nl_ct_dump, zone); if (err) { free(dump); return err; } *dump_ = &dump->up; return 0; } static int dpif_netlink_ct_dump_next(struct dpif *dpif OVS_UNUSED, struct ct_dpif_dump_state *dump_, struct ct_dpif_entry *entry) { struct dpif_netlink_ct_dump_state *dump; INIT_CONTAINER(dump, dump_, up); return nl_ct_dump_next(dump->nl_ct_dump, entry); } static int dpif_netlink_ct_dump_done(struct dpif *dpif OVS_UNUSED, struct ct_dpif_dump_state *dump_) { struct dpif_netlink_ct_dump_state *dump; int err; INIT_CONTAINER(dump, dump_, up); err = nl_ct_dump_done(dump->nl_ct_dump); free(dump); return err; } static int dpif_netlink_ct_flush(struct dpif *dpif OVS_UNUSED, const uint16_t *zone) { if (zone) { return nl_ct_flush_zone(*zone); } else { return nl_ct_flush(); } } #endif const struct dpif_class dpif_netlink_class = { "system", NULL, /* init */ dpif_netlink_enumerate, NULL, dpif_netlink_open, dpif_netlink_close, dpif_netlink_destroy, dpif_netlink_run, NULL, /* wait */ dpif_netlink_get_stats, dpif_netlink_port_add, dpif_netlink_port_del, dpif_netlink_port_query_by_number, dpif_netlink_port_query_by_name, dpif_netlink_port_get_pid, dpif_netlink_port_dump_start, dpif_netlink_port_dump_next, dpif_netlink_port_dump_done, dpif_netlink_port_poll, dpif_netlink_port_poll_wait, dpif_netlink_flow_flush, dpif_netlink_flow_dump_create, dpif_netlink_flow_dump_destroy, dpif_netlink_flow_dump_thread_create, dpif_netlink_flow_dump_thread_destroy, dpif_netlink_flow_dump_next, dpif_netlink_operate, dpif_netlink_recv_set, dpif_netlink_handlers_set, NULL, /* poll_thread_set */ dpif_netlink_queue_to_priority, dpif_netlink_recv, dpif_netlink_recv_wait, dpif_netlink_recv_purge, NULL, /* register_dp_purge_cb */ NULL, /* register_upcall_cb */ NULL, /* enable_upcall */ NULL, /* disable_upcall */ dpif_netlink_get_datapath_version, /* get_datapath_version */ #ifdef __linux__ dpif_netlink_ct_dump_start, dpif_netlink_ct_dump_next, dpif_netlink_ct_dump_done, dpif_netlink_ct_flush, #else NULL, /* ct_dump_start */ NULL, /* ct_dump_next */ NULL, /* ct_dump_done */ NULL, /* ct_flush */ #endif }; static int dpif_netlink_init(void) { static struct ovsthread_once once = OVSTHREAD_ONCE_INITIALIZER; static int error; if (ovsthread_once_start(&once)) { error = nl_lookup_genl_family(OVS_DATAPATH_FAMILY, &ovs_datapath_family); if (error) { VLOG_ERR("Generic Netlink family '%s' does not exist. " "The Open vSwitch kernel module is probably not loaded.", OVS_DATAPATH_FAMILY); } if (!error) { error = nl_lookup_genl_family(OVS_VPORT_FAMILY, &ovs_vport_family); } if (!error) { error = nl_lookup_genl_family(OVS_FLOW_FAMILY, &ovs_flow_family); } if (!error) { error = nl_lookup_genl_family(OVS_PACKET_FAMILY, &ovs_packet_family); } if (!error) { error = nl_lookup_genl_mcgroup(OVS_VPORT_FAMILY, OVS_VPORT_MCGROUP, &ovs_vport_mcgroup); } ovsthread_once_done(&once); } return error; } bool dpif_netlink_is_internal_device(const char *name) { struct dpif_netlink_vport reply; struct ofpbuf *buf; int error; error = dpif_netlink_vport_get(name, &reply, &buf); if (!error) { ofpbuf_delete(buf); } else if (error != ENODEV && error != ENOENT) { VLOG_WARN_RL(&error_rl, "%s: vport query failed (%s)", name, ovs_strerror(error)); } return reply.type == OVS_VPORT_TYPE_INTERNAL; } /* Parses the contents of 'buf', which contains a "struct ovs_header" followed * by Netlink attributes, into 'vport'. Returns 0 if successful, otherwise a * positive errno value. * * 'vport' will contain pointers into 'buf', so the caller should not free * 'buf' while 'vport' is still in use. */ static int dpif_netlink_vport_from_ofpbuf(struct dpif_netlink_vport *vport, const struct ofpbuf *buf) { static const struct nl_policy ovs_vport_policy[] = { [OVS_VPORT_ATTR_PORT_NO] = { .type = NL_A_U32 }, [OVS_VPORT_ATTR_TYPE] = { .type = NL_A_U32 }, [OVS_VPORT_ATTR_NAME] = { .type = NL_A_STRING, .max_len = IFNAMSIZ }, [OVS_VPORT_ATTR_UPCALL_PID] = { .type = NL_A_UNSPEC }, [OVS_VPORT_ATTR_STATS] = { NL_POLICY_FOR(struct ovs_vport_stats), .optional = true }, [OVS_VPORT_ATTR_OPTIONS] = { .type = NL_A_NESTED, .optional = true }, }; dpif_netlink_vport_init(vport); struct ofpbuf b = ofpbuf_const_initializer(buf->data, buf->size); struct nlmsghdr *nlmsg = ofpbuf_try_pull(&b, sizeof *nlmsg); struct genlmsghdr *genl = ofpbuf_try_pull(&b, sizeof *genl); struct ovs_header *ovs_header = ofpbuf_try_pull(&b, sizeof *ovs_header); struct nlattr *a[ARRAY_SIZE(ovs_vport_policy)]; if (!nlmsg || !genl || !ovs_header || nlmsg->nlmsg_type != ovs_vport_family || !nl_policy_parse(&b, 0, ovs_vport_policy, a, ARRAY_SIZE(ovs_vport_policy))) { return EINVAL; } vport->cmd = genl->cmd; vport->dp_ifindex = ovs_header->dp_ifindex; vport->port_no = nl_attr_get_odp_port(a[OVS_VPORT_ATTR_PORT_NO]); vport->type = nl_attr_get_u32(a[OVS_VPORT_ATTR_TYPE]); vport->name = nl_attr_get_string(a[OVS_VPORT_ATTR_NAME]); if (a[OVS_VPORT_ATTR_UPCALL_PID]) { vport->n_upcall_pids = nl_attr_get_size(a[OVS_VPORT_ATTR_UPCALL_PID]) / (sizeof *vport->upcall_pids); vport->upcall_pids = nl_attr_get(a[OVS_VPORT_ATTR_UPCALL_PID]); } if (a[OVS_VPORT_ATTR_STATS]) { vport->stats = nl_attr_get(a[OVS_VPORT_ATTR_STATS]); } if (a[OVS_VPORT_ATTR_OPTIONS]) { vport->options = nl_attr_get(a[OVS_VPORT_ATTR_OPTIONS]); vport->options_len = nl_attr_get_size(a[OVS_VPORT_ATTR_OPTIONS]); } return 0; } /* Appends to 'buf' (which must initially be empty) a "struct ovs_header" * followed by Netlink attributes corresponding to 'vport'. */ static void dpif_netlink_vport_to_ofpbuf(const struct dpif_netlink_vport *vport, struct ofpbuf *buf) { struct ovs_header *ovs_header; nl_msg_put_genlmsghdr(buf, 0, ovs_vport_family, NLM_F_REQUEST | NLM_F_ECHO, vport->cmd, OVS_VPORT_VERSION); ovs_header = ofpbuf_put_uninit(buf, sizeof *ovs_header); ovs_header->dp_ifindex = vport->dp_ifindex; if (vport->port_no != ODPP_NONE) { nl_msg_put_odp_port(buf, OVS_VPORT_ATTR_PORT_NO, vport->port_no); } if (vport->type != OVS_VPORT_TYPE_UNSPEC) { nl_msg_put_u32(buf, OVS_VPORT_ATTR_TYPE, vport->type); } if (vport->name) { nl_msg_put_string(buf, OVS_VPORT_ATTR_NAME, vport->name); } if (vport->upcall_pids) { nl_msg_put_unspec(buf, OVS_VPORT_ATTR_UPCALL_PID, vport->upcall_pids, vport->n_upcall_pids * sizeof *vport->upcall_pids); } if (vport->stats) { nl_msg_put_unspec(buf, OVS_VPORT_ATTR_STATS, vport->stats, sizeof *vport->stats); } if (vport->options) { nl_msg_put_nested(buf, OVS_VPORT_ATTR_OPTIONS, vport->options, vport->options_len); } } /* Clears 'vport' to "empty" values. */ void dpif_netlink_vport_init(struct dpif_netlink_vport *vport) { memset(vport, 0, sizeof *vport); vport->port_no = ODPP_NONE; } /* Executes 'request' in the kernel datapath. If the command fails, returns a * positive errno value. Otherwise, if 'reply' and 'bufp' are null, returns 0 * without doing anything else. If 'reply' and 'bufp' are nonnull, then the * result of the command is expected to be an ovs_vport also, which is decoded * and stored in '*reply' and '*bufp'. The caller must free '*bufp' when the * reply is no longer needed ('reply' will contain pointers into '*bufp'). */ int dpif_netlink_vport_transact(const struct dpif_netlink_vport *request, struct dpif_netlink_vport *reply, struct ofpbuf **bufp) { struct ofpbuf *request_buf; int error; ovs_assert((reply != NULL) == (bufp != NULL)); error = dpif_netlink_init(); if (error) { if (reply) { *bufp = NULL; dpif_netlink_vport_init(reply); } return error; } request_buf = ofpbuf_new(1024); dpif_netlink_vport_to_ofpbuf(request, request_buf); error = nl_transact(NETLINK_GENERIC, request_buf, bufp); ofpbuf_delete(request_buf); if (reply) { if (!error) { error = dpif_netlink_vport_from_ofpbuf(reply, *bufp); } if (error) { dpif_netlink_vport_init(reply); ofpbuf_delete(*bufp); *bufp = NULL; } } return error; } /* Obtains information about the kernel vport named 'name' and stores it into * '*reply' and '*bufp'. The caller must free '*bufp' when the reply is no * longer needed ('reply' will contain pointers into '*bufp'). */ int dpif_netlink_vport_get(const char *name, struct dpif_netlink_vport *reply, struct ofpbuf **bufp) { struct dpif_netlink_vport request; dpif_netlink_vport_init(&request); request.cmd = OVS_VPORT_CMD_GET; request.name = name; return dpif_netlink_vport_transact(&request, reply, bufp); } /* Parses the contents of 'buf', which contains a "struct ovs_header" followed * by Netlink attributes, into 'dp'. Returns 0 if successful, otherwise a * positive errno value. * * 'dp' will contain pointers into 'buf', so the caller should not free 'buf' * while 'dp' is still in use. */ static int dpif_netlink_dp_from_ofpbuf(struct dpif_netlink_dp *dp, const struct ofpbuf *buf) { static const struct nl_policy ovs_datapath_policy[] = { [OVS_DP_ATTR_NAME] = { .type = NL_A_STRING, .max_len = IFNAMSIZ }, [OVS_DP_ATTR_STATS] = { NL_POLICY_FOR(struct ovs_dp_stats), .optional = true }, [OVS_DP_ATTR_MEGAFLOW_STATS] = { NL_POLICY_FOR(struct ovs_dp_megaflow_stats), .optional = true }, }; dpif_netlink_dp_init(dp); struct ofpbuf b = ofpbuf_const_initializer(buf->data, buf->size); struct nlmsghdr *nlmsg = ofpbuf_try_pull(&b, sizeof *nlmsg); struct genlmsghdr *genl = ofpbuf_try_pull(&b, sizeof *genl); struct ovs_header *ovs_header = ofpbuf_try_pull(&b, sizeof *ovs_header); struct nlattr *a[ARRAY_SIZE(ovs_datapath_policy)]; if (!nlmsg || !genl || !ovs_header || nlmsg->nlmsg_type != ovs_datapath_family || !nl_policy_parse(&b, 0, ovs_datapath_policy, a, ARRAY_SIZE(ovs_datapath_policy))) { return EINVAL; } dp->cmd = genl->cmd; dp->dp_ifindex = ovs_header->dp_ifindex; dp->name = nl_attr_get_string(a[OVS_DP_ATTR_NAME]); if (a[OVS_DP_ATTR_STATS]) { dp->stats = nl_attr_get(a[OVS_DP_ATTR_STATS]); } if (a[OVS_DP_ATTR_MEGAFLOW_STATS]) { dp->megaflow_stats = nl_attr_get(a[OVS_DP_ATTR_MEGAFLOW_STATS]); } return 0; } /* Appends to 'buf' the Generic Netlink message described by 'dp'. */ static void dpif_netlink_dp_to_ofpbuf(const struct dpif_netlink_dp *dp, struct ofpbuf *buf) { struct ovs_header *ovs_header; nl_msg_put_genlmsghdr(buf, 0, ovs_datapath_family, NLM_F_REQUEST | NLM_F_ECHO, dp->cmd, OVS_DATAPATH_VERSION); ovs_header = ofpbuf_put_uninit(buf, sizeof *ovs_header); ovs_header->dp_ifindex = dp->dp_ifindex; if (dp->name) { nl_msg_put_string(buf, OVS_DP_ATTR_NAME, dp->name); } if (dp->upcall_pid) { nl_msg_put_u32(buf, OVS_DP_ATTR_UPCALL_PID, *dp->upcall_pid); } if (dp->user_features) { nl_msg_put_u32(buf, OVS_DP_ATTR_USER_FEATURES, dp->user_features); } /* Skip OVS_DP_ATTR_STATS since we never have a reason to serialize it. */ } /* Clears 'dp' to "empty" values. */ static void dpif_netlink_dp_init(struct dpif_netlink_dp *dp) { memset(dp, 0, sizeof *dp); } static void dpif_netlink_dp_dump_start(struct nl_dump *dump) { struct dpif_netlink_dp request; struct ofpbuf *buf; dpif_netlink_dp_init(&request); request.cmd = OVS_DP_CMD_GET; buf = ofpbuf_new(1024); dpif_netlink_dp_to_ofpbuf(&request, buf); nl_dump_start(dump, NETLINK_GENERIC, buf); ofpbuf_delete(buf); } /* Executes 'request' in the kernel datapath. If the command fails, returns a * positive errno value. Otherwise, if 'reply' and 'bufp' are null, returns 0 * without doing anything else. If 'reply' and 'bufp' are nonnull, then the * result of the command is expected to be of the same form, which is decoded * and stored in '*reply' and '*bufp'. The caller must free '*bufp' when the * reply is no longer needed ('reply' will contain pointers into '*bufp'). */ static int dpif_netlink_dp_transact(const struct dpif_netlink_dp *request, struct dpif_netlink_dp *reply, struct ofpbuf **bufp) { struct ofpbuf *request_buf; int error; ovs_assert((reply != NULL) == (bufp != NULL)); request_buf = ofpbuf_new(1024); dpif_netlink_dp_to_ofpbuf(request, request_buf); error = nl_transact(NETLINK_GENERIC, request_buf, bufp); ofpbuf_delete(request_buf); if (reply) { dpif_netlink_dp_init(reply); if (!error) { error = dpif_netlink_dp_from_ofpbuf(reply, *bufp); } if (error) { ofpbuf_delete(*bufp); *bufp = NULL; } } return error; } /* Obtains information about 'dpif_' and stores it into '*reply' and '*bufp'. * The caller must free '*bufp' when the reply is no longer needed ('reply' * will contain pointers into '*bufp'). */ static int dpif_netlink_dp_get(const struct dpif *dpif_, struct dpif_netlink_dp *reply, struct ofpbuf **bufp) { struct dpif_netlink *dpif = dpif_netlink_cast(dpif_); struct dpif_netlink_dp request; dpif_netlink_dp_init(&request); request.cmd = OVS_DP_CMD_GET; request.dp_ifindex = dpif->dp_ifindex; return dpif_netlink_dp_transact(&request, reply, bufp); } /* Parses the contents of 'buf', which contains a "struct ovs_header" followed * by Netlink attributes, into 'flow'. Returns 0 if successful, otherwise a * positive errno value. * * 'flow' will contain pointers into 'buf', so the caller should not free 'buf' * while 'flow' is still in use. */ static int dpif_netlink_flow_from_ofpbuf(struct dpif_netlink_flow *flow, const struct ofpbuf *buf) { static const struct nl_policy ovs_flow_policy[__OVS_FLOW_ATTR_MAX] = { [OVS_FLOW_ATTR_KEY] = { .type = NL_A_NESTED, .optional = true }, [OVS_FLOW_ATTR_MASK] = { .type = NL_A_NESTED, .optional = true }, [OVS_FLOW_ATTR_ACTIONS] = { .type = NL_A_NESTED, .optional = true }, [OVS_FLOW_ATTR_STATS] = { NL_POLICY_FOR(struct ovs_flow_stats), .optional = true }, [OVS_FLOW_ATTR_TCP_FLAGS] = { .type = NL_A_U8, .optional = true }, [OVS_FLOW_ATTR_USED] = { .type = NL_A_U64, .optional = true }, [OVS_FLOW_ATTR_UFID] = { .type = NL_A_UNSPEC, .optional = true, .min_len = sizeof(ovs_u128) }, /* The kernel never uses OVS_FLOW_ATTR_CLEAR. */ /* The kernel never uses OVS_FLOW_ATTR_PROBE. */ /* The kernel never uses OVS_FLOW_ATTR_UFID_FLAGS. */ }; dpif_netlink_flow_init(flow); struct ofpbuf b = ofpbuf_const_initializer(buf->data, buf->size); struct nlmsghdr *nlmsg = ofpbuf_try_pull(&b, sizeof *nlmsg); struct genlmsghdr *genl = ofpbuf_try_pull(&b, sizeof *genl); struct ovs_header *ovs_header = ofpbuf_try_pull(&b, sizeof *ovs_header); struct nlattr *a[ARRAY_SIZE(ovs_flow_policy)]; if (!nlmsg || !genl || !ovs_header || nlmsg->nlmsg_type != ovs_flow_family || !nl_policy_parse(&b, 0, ovs_flow_policy, a, ARRAY_SIZE(ovs_flow_policy))) { return EINVAL; } if (!a[OVS_FLOW_ATTR_KEY] && !a[OVS_FLOW_ATTR_UFID]) { return EINVAL; } flow->nlmsg_flags = nlmsg->nlmsg_flags; flow->dp_ifindex = ovs_header->dp_ifindex; if (a[OVS_FLOW_ATTR_KEY]) { flow->key = nl_attr_get(a[OVS_FLOW_ATTR_KEY]); flow->key_len = nl_attr_get_size(a[OVS_FLOW_ATTR_KEY]); } if (a[OVS_FLOW_ATTR_UFID]) { const ovs_u128 *ufid; ufid = nl_attr_get_unspec(a[OVS_FLOW_ATTR_UFID], nl_attr_get_size(a[OVS_FLOW_ATTR_UFID])); flow->ufid = *ufid; flow->ufid_present = true; } if (a[OVS_FLOW_ATTR_MASK]) { flow->mask = nl_attr_get(a[OVS_FLOW_ATTR_MASK]); flow->mask_len = nl_attr_get_size(a[OVS_FLOW_ATTR_MASK]); } if (a[OVS_FLOW_ATTR_ACTIONS]) { flow->actions = nl_attr_get(a[OVS_FLOW_ATTR_ACTIONS]); flow->actions_len = nl_attr_get_size(a[OVS_FLOW_ATTR_ACTIONS]); } if (a[OVS_FLOW_ATTR_STATS]) { flow->stats = nl_attr_get(a[OVS_FLOW_ATTR_STATS]); } if (a[OVS_FLOW_ATTR_TCP_FLAGS]) { flow->tcp_flags = nl_attr_get(a[OVS_FLOW_ATTR_TCP_FLAGS]); } if (a[OVS_FLOW_ATTR_USED]) { flow->used = nl_attr_get(a[OVS_FLOW_ATTR_USED]); } return 0; } /* Appends to 'buf' (which must initially be empty) a "struct ovs_header" * followed by Netlink attributes corresponding to 'flow'. */ static void dpif_netlink_flow_to_ofpbuf(const struct dpif_netlink_flow *flow, struct ofpbuf *buf) { struct ovs_header *ovs_header; nl_msg_put_genlmsghdr(buf, 0, ovs_flow_family, NLM_F_REQUEST | flow->nlmsg_flags, flow->cmd, OVS_FLOW_VERSION); ovs_header = ofpbuf_put_uninit(buf, sizeof *ovs_header); ovs_header->dp_ifindex = flow->dp_ifindex; if (flow->ufid_present) { nl_msg_put_unspec(buf, OVS_FLOW_ATTR_UFID, &flow->ufid, sizeof flow->ufid); } if (flow->ufid_terse) { nl_msg_put_u32(buf, OVS_FLOW_ATTR_UFID_FLAGS, OVS_UFID_F_OMIT_KEY | OVS_UFID_F_OMIT_MASK | OVS_UFID_F_OMIT_ACTIONS); } if (!flow->ufid_terse || !flow->ufid_present) { if (flow->key_len) { nl_msg_put_unspec(buf, OVS_FLOW_ATTR_KEY, flow->key, flow->key_len); } if (flow->mask_len) { nl_msg_put_unspec(buf, OVS_FLOW_ATTR_MASK, flow->mask, flow->mask_len); } if (flow->actions || flow->actions_len) { nl_msg_put_unspec(buf, OVS_FLOW_ATTR_ACTIONS, flow->actions, flow->actions_len); } } /* We never need to send these to the kernel. */ ovs_assert(!flow->stats); ovs_assert(!flow->tcp_flags); ovs_assert(!flow->used); if (flow->clear) { nl_msg_put_flag(buf, OVS_FLOW_ATTR_CLEAR); } if (flow->probe) { nl_msg_put_flag(buf, OVS_FLOW_ATTR_PROBE); } } /* Clears 'flow' to "empty" values. */ static void dpif_netlink_flow_init(struct dpif_netlink_flow *flow) { memset(flow, 0, sizeof *flow); } /* Executes 'request' in the kernel datapath. If the command fails, returns a * positive errno value. Otherwise, if 'reply' and 'bufp' are null, returns 0 * without doing anything else. If 'reply' and 'bufp' are nonnull, then the * result of the command is expected to be a flow also, which is decoded and * stored in '*reply' and '*bufp'. The caller must free '*bufp' when the reply * is no longer needed ('reply' will contain pointers into '*bufp'). */ static int dpif_netlink_flow_transact(struct dpif_netlink_flow *request, struct dpif_netlink_flow *reply, struct ofpbuf **bufp) { struct ofpbuf *request_buf; int error; ovs_assert((reply != NULL) == (bufp != NULL)); if (reply) { request->nlmsg_flags |= NLM_F_ECHO; } request_buf = ofpbuf_new(1024); dpif_netlink_flow_to_ofpbuf(request, request_buf); error = nl_transact(NETLINK_GENERIC, request_buf, bufp); ofpbuf_delete(request_buf); if (reply) { if (!error) { error = dpif_netlink_flow_from_ofpbuf(reply, *bufp); } if (error) { dpif_netlink_flow_init(reply); ofpbuf_delete(*bufp); *bufp = NULL; } } return error; } static void dpif_netlink_flow_get_stats(const struct dpif_netlink_flow *flow, struct dpif_flow_stats *stats) { if (flow->stats) { stats->n_packets = get_32aligned_u64(&flow->stats->n_packets); stats->n_bytes = get_32aligned_u64(&flow->stats->n_bytes); } else { stats->n_packets = 0; stats->n_bytes = 0; } stats->used = flow->used ? get_32aligned_u64(flow->used) : 0; stats->tcp_flags = flow->tcp_flags ? *flow->tcp_flags : 0; } /* Logs information about a packet that was recently lost in 'ch' (in * 'dpif_'). */ static void report_loss(struct dpif_netlink *dpif, struct dpif_channel *ch, uint32_t ch_idx, uint32_t handler_id) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(5, 5); struct ds s; if (VLOG_DROP_WARN(&rl)) { return; } ds_init(&s); if (ch->last_poll != LLONG_MIN) { ds_put_format(&s, " (last polled %lld ms ago)", time_msec() - ch->last_poll); } VLOG_WARN("%s: lost packet on port channel %u of handler %u", dpif_name(&dpif->dpif), ch_idx, handler_id); ds_destroy(&s); }