/* * Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013, 2014 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-provider.h" #include #include #include #include #include #include "coverage.h" #include "dynamic-string.h" #include "flow.h" #include "netdev.h" #include "netlink.h" #include "odp-execute.h" #include "odp-util.h" #include "ofp-errors.h" #include "ofp-print.h" #include "ofp-util.h" #include "ofpbuf.h" #include "packets.h" #include "poll-loop.h" #include "shash.h" #include "sset.h" #include "timeval.h" #include "util.h" #include "valgrind.h" #include "vlog.h" VLOG_DEFINE_THIS_MODULE(dpif); COVERAGE_DEFINE(dpif_destroy); COVERAGE_DEFINE(dpif_port_add); COVERAGE_DEFINE(dpif_port_del); COVERAGE_DEFINE(dpif_flow_flush); COVERAGE_DEFINE(dpif_flow_get); COVERAGE_DEFINE(dpif_flow_put); COVERAGE_DEFINE(dpif_flow_del); COVERAGE_DEFINE(dpif_execute); COVERAGE_DEFINE(dpif_purge); COVERAGE_DEFINE(dpif_execute_with_help); static const struct dpif_class *base_dpif_classes[] = { #ifdef __linux__ &dpif_linux_class, #endif &dpif_netdev_class, &dpif_planetlab_class, }; struct registered_dpif_class { const struct dpif_class *dpif_class; int refcount; }; static struct shash dpif_classes = SHASH_INITIALIZER(&dpif_classes); static struct sset dpif_blacklist = SSET_INITIALIZER(&dpif_blacklist); /* Protects 'dpif_classes', including the refcount, and 'dpif_blacklist'. */ static struct ovs_mutex dpif_mutex = OVS_MUTEX_INITIALIZER; /* Rate limit for individual messages going to or from the datapath, output at * DBG level. This is very high because, if these are enabled, it is because * we really need to see them. */ static struct vlog_rate_limit dpmsg_rl = VLOG_RATE_LIMIT_INIT(600, 600); /* Not really much point in logging many dpif errors. */ static struct vlog_rate_limit error_rl = VLOG_RATE_LIMIT_INIT(60, 5); static void log_flow_message(const struct dpif *dpif, int error, const char *operation, const struct nlattr *key, size_t key_len, const struct nlattr *mask, size_t mask_len, const struct dpif_flow_stats *stats, const struct nlattr *actions, size_t actions_len); static void log_operation(const struct dpif *, const char *operation, int error); static bool should_log_flow_message(int error); static void log_flow_put_message(struct dpif *, const struct dpif_flow_put *, int error); static void log_flow_del_message(struct dpif *, const struct dpif_flow_del *, int error); static void log_execute_message(struct dpif *, const struct dpif_execute *, int error); static void dp_initialize(void) { static struct ovsthread_once once = OVSTHREAD_ONCE_INITIALIZER; if (ovsthread_once_start(&once)) { int i; for (i = 0; i < ARRAY_SIZE(base_dpif_classes); i++) { dp_register_provider(base_dpif_classes[i]); } ovsthread_once_done(&once); } } static int dp_register_provider__(const struct dpif_class *new_class) { struct registered_dpif_class *registered_class; if (sset_contains(&dpif_blacklist, new_class->type)) { VLOG_DBG("attempted to register blacklisted provider: %s", new_class->type); return EINVAL; } if (shash_find(&dpif_classes, new_class->type)) { VLOG_WARN("attempted to register duplicate datapath provider: %s", new_class->type); return EEXIST; } registered_class = xmalloc(sizeof *registered_class); registered_class->dpif_class = new_class; registered_class->refcount = 0; shash_add(&dpif_classes, new_class->type, registered_class); return 0; } /* Registers a new datapath provider. After successful registration, new * datapaths of that type can be opened using dpif_open(). */ int dp_register_provider(const struct dpif_class *new_class) { int error; ovs_mutex_lock(&dpif_mutex); error = dp_register_provider__(new_class); ovs_mutex_unlock(&dpif_mutex); return error; } /* Unregisters a datapath provider. 'type' must have been previously * registered and not currently be in use by any dpifs. After unregistration * new datapaths of that type cannot be opened using dpif_open(). */ static int dp_unregister_provider__(const char *type) { struct shash_node *node; struct registered_dpif_class *registered_class; node = shash_find(&dpif_classes, type); if (!node) { VLOG_WARN("attempted to unregister a datapath provider that is not " "registered: %s", type); return EAFNOSUPPORT; } registered_class = node->data; if (registered_class->refcount) { VLOG_WARN("attempted to unregister in use datapath provider: %s", type); return EBUSY; } shash_delete(&dpif_classes, node); free(registered_class); return 0; } /* Unregisters a datapath provider. 'type' must have been previously * registered and not currently be in use by any dpifs. After unregistration * new datapaths of that type cannot be opened using dpif_open(). */ int dp_unregister_provider(const char *type) { int error; dp_initialize(); ovs_mutex_lock(&dpif_mutex); error = dp_unregister_provider__(type); ovs_mutex_unlock(&dpif_mutex); return error; } /* Blacklists a provider. Causes future calls of dp_register_provider() with * a dpif_class which implements 'type' to fail. */ void dp_blacklist_provider(const char *type) { ovs_mutex_lock(&dpif_mutex); sset_add(&dpif_blacklist, type); ovs_mutex_unlock(&dpif_mutex); } /* Clears 'types' and enumerates the types of all currently registered datapath * providers into it. The caller must first initialize the sset. */ void dp_enumerate_types(struct sset *types) { struct shash_node *node; dp_initialize(); sset_clear(types); ovs_mutex_lock(&dpif_mutex); SHASH_FOR_EACH(node, &dpif_classes) { const struct registered_dpif_class *registered_class = node->data; sset_add(types, registered_class->dpif_class->type); } ovs_mutex_unlock(&dpif_mutex); } static void dp_class_unref(struct registered_dpif_class *rc) { ovs_mutex_lock(&dpif_mutex); ovs_assert(rc->refcount); rc->refcount--; ovs_mutex_unlock(&dpif_mutex); } static struct registered_dpif_class * dp_class_lookup(const char *type) { struct registered_dpif_class *rc; ovs_mutex_lock(&dpif_mutex); rc = shash_find_data(&dpif_classes, type); if (rc) { rc->refcount++; } ovs_mutex_unlock(&dpif_mutex); return rc; } /* Clears 'names' and enumerates the names of all known created datapaths with * the given 'type'. The caller must first initialize the sset. Returns 0 if * successful, otherwise a positive errno value. * * Some kinds of datapaths might not be practically enumerable. This is not * considered an error. */ int dp_enumerate_names(const char *type, struct sset *names) { struct registered_dpif_class *registered_class; const struct dpif_class *dpif_class; int error; dp_initialize(); sset_clear(names); registered_class = dp_class_lookup(type); if (!registered_class) { VLOG_WARN("could not enumerate unknown type: %s", type); return EAFNOSUPPORT; } dpif_class = registered_class->dpif_class; error = dpif_class->enumerate ? dpif_class->enumerate(names) : 0; if (error) { VLOG_WARN("failed to enumerate %s datapaths: %s", dpif_class->type, ovs_strerror(error)); } dp_class_unref(registered_class); return error; } /* Parses 'datapath_name_', which is of the form [type@]name into its * component pieces. 'name' and 'type' must be freed by the caller. * * The returned 'type' is normalized, as if by dpif_normalize_type(). */ void dp_parse_name(const char *datapath_name_, char **name, char **type) { char *datapath_name = xstrdup(datapath_name_); char *separator; separator = strchr(datapath_name, '@'); if (separator) { *separator = '\0'; *type = datapath_name; *name = xstrdup(dpif_normalize_type(separator + 1)); } else { *name = datapath_name; *type = xstrdup(dpif_normalize_type(NULL)); } } static int do_open(const char *name, const char *type, bool create, struct dpif **dpifp) { struct dpif *dpif = NULL; int error; struct registered_dpif_class *registered_class; dp_initialize(); type = dpif_normalize_type(type); registered_class = dp_class_lookup(type); if (!registered_class) { VLOG_WARN("could not create datapath %s of unknown type %s", name, type); error = EAFNOSUPPORT; goto exit; } error = registered_class->dpif_class->open(registered_class->dpif_class, name, create, &dpif); if (!error) { ovs_assert(dpif->dpif_class == registered_class->dpif_class); } else { dp_class_unref(registered_class); } exit: *dpifp = error ? NULL : dpif; return error; } /* Tries to open an existing datapath named 'name' and type 'type'. Will fail * if no datapath with 'name' and 'type' exists. 'type' may be either NULL or * the empty string to specify the default system type. Returns 0 if * successful, otherwise a positive errno value. On success stores a pointer * to the datapath in '*dpifp', otherwise a null pointer. */ int dpif_open(const char *name, const char *type, struct dpif **dpifp) { return do_open(name, type, false, dpifp); } /* Tries to create and open a new datapath with the given 'name' and 'type'. * 'type' may be either NULL or the empty string to specify the default system * type. Will fail if a datapath with 'name' and 'type' already exists. * Returns 0 if successful, otherwise a positive errno value. On success * stores a pointer to the datapath in '*dpifp', otherwise a null pointer. */ int dpif_create(const char *name, const char *type, struct dpif **dpifp) { return do_open(name, type, true, dpifp); } /* Tries to open a datapath with the given 'name' and 'type', creating it if it * does not exist. 'type' may be either NULL or the empty string to specify * the default system type. Returns 0 if successful, otherwise a positive * errno value. On success stores a pointer to the datapath in '*dpifp', * otherwise a null pointer. */ int dpif_create_and_open(const char *name, const char *type, struct dpif **dpifp) { int error; error = dpif_create(name, type, dpifp); if (error == EEXIST || error == EBUSY) { error = dpif_open(name, type, dpifp); if (error) { VLOG_WARN("datapath %s already exists but cannot be opened: %s", name, ovs_strerror(error)); } } else if (error) { VLOG_WARN("failed to create datapath %s: %s", name, ovs_strerror(error)); } return error; } /* Closes and frees the connection to 'dpif'. Does not destroy the datapath * itself; call dpif_delete() first, instead, if that is desirable. */ void dpif_close(struct dpif *dpif) { if (dpif) { struct registered_dpif_class *rc; rc = shash_find_data(&dpif_classes, dpif->dpif_class->type); dpif_uninit(dpif, true); dp_class_unref(rc); } } /* Performs periodic work needed by 'dpif'. */ void dpif_run(struct dpif *dpif) { if (dpif->dpif_class->run) { dpif->dpif_class->run(dpif); } } /* Arranges for poll_block() to wake up when dp_run() needs to be called for * 'dpif'. */ void dpif_wait(struct dpif *dpif) { if (dpif->dpif_class->wait) { dpif->dpif_class->wait(dpif); } } /* Returns the name of datapath 'dpif' prefixed with the type * (for use in log messages). */ const char * dpif_name(const struct dpif *dpif) { return dpif->full_name; } /* Returns the name of datapath 'dpif' without the type * (for use in device names). */ const char * dpif_base_name(const struct dpif *dpif) { return dpif->base_name; } /* Returns the type of datapath 'dpif'. */ const char * dpif_type(const struct dpif *dpif) { return dpif->dpif_class->type; } /* Returns the fully spelled out name for the given datapath 'type'. * * Normalized type string can be compared with strcmp(). Unnormalized type * string might be the same even if they have different spellings. */ const char * dpif_normalize_type(const char *type) { return type && type[0] ? type : "system"; } /* Destroys the datapath that 'dpif' is connected to, first removing all of its * ports. After calling this function, it does not make sense to pass 'dpif' * to any functions other than dpif_name() or dpif_close(). */ int dpif_delete(struct dpif *dpif) { int error; COVERAGE_INC(dpif_destroy); error = dpif->dpif_class->destroy(dpif); log_operation(dpif, "delete", error); return error; } /* Retrieves statistics for 'dpif' into 'stats'. Returns 0 if successful, * otherwise a positive errno value. */ int dpif_get_dp_stats(const struct dpif *dpif, struct dpif_dp_stats *stats) { int error = dpif->dpif_class->get_stats(dpif, stats); if (error) { memset(stats, 0, sizeof *stats); } log_operation(dpif, "get_stats", error); return error; } const char * dpif_port_open_type(const char *datapath_type, const char *port_type) { struct registered_dpif_class *rc; datapath_type = dpif_normalize_type(datapath_type); ovs_mutex_lock(&dpif_mutex); rc = shash_find_data(&dpif_classes, datapath_type); if (rc && rc->dpif_class->port_open_type) { port_type = rc->dpif_class->port_open_type(rc->dpif_class, port_type); } ovs_mutex_unlock(&dpif_mutex); return port_type; } /* Attempts to add 'netdev' as a port on 'dpif'. If 'port_nop' is * non-null and its value is not ODPP_NONE, then attempts to use the * value as the port number. * * If successful, returns 0 and sets '*port_nop' to the new port's port * number (if 'port_nop' is non-null). On failure, returns a positive * errno value and sets '*port_nop' to ODPP_NONE (if 'port_nop' is * non-null). */ int dpif_port_add(struct dpif *dpif, struct netdev *netdev, odp_port_t *port_nop) { const char *netdev_name = netdev_get_name(netdev); odp_port_t port_no = ODPP_NONE; int error; COVERAGE_INC(dpif_port_add); if (port_nop) { port_no = *port_nop; } error = dpif->dpif_class->port_add(dpif, netdev, &port_no); if (!error) { VLOG_DBG_RL(&dpmsg_rl, "%s: added %s as port %"PRIu32, dpif_name(dpif), netdev_name, port_no); } else { VLOG_WARN_RL(&error_rl, "%s: failed to add %s as port: %s", dpif_name(dpif), netdev_name, ovs_strerror(error)); port_no = ODPP_NONE; } if (port_nop) { *port_nop = port_no; } return error; } /* Attempts to remove 'dpif''s port number 'port_no'. Returns 0 if successful, * otherwise a positive errno value. */ int dpif_port_del(struct dpif *dpif, odp_port_t port_no) { int error; COVERAGE_INC(dpif_port_del); error = dpif->dpif_class->port_del(dpif, port_no); if (!error) { VLOG_DBG_RL(&dpmsg_rl, "%s: port_del(%"PRIu32")", dpif_name(dpif), port_no); } else { log_operation(dpif, "port_del", error); } return error; } /* Makes a deep copy of 'src' into 'dst'. */ void dpif_port_clone(struct dpif_port *dst, const struct dpif_port *src) { dst->name = xstrdup(src->name); dst->type = xstrdup(src->type); dst->port_no = src->port_no; } /* Frees memory allocated to members of 'dpif_port'. * * Do not call this function on a dpif_port obtained from * dpif_port_dump_next(): that function retains ownership of the data in the * dpif_port. */ void dpif_port_destroy(struct dpif_port *dpif_port) { free(dpif_port->name); free(dpif_port->type); } /* Checks if port named 'devname' exists in 'dpif'. If so, returns * true; otherwise, returns false. */ bool dpif_port_exists(const struct dpif *dpif, const char *devname) { int error = dpif->dpif_class->port_query_by_name(dpif, devname, NULL); if (error != 0 && error != ENOENT && error != ENODEV) { VLOG_WARN_RL(&error_rl, "%s: failed to query port %s: %s", dpif_name(dpif), devname, ovs_strerror(error)); } return !error; } /* Looks up port number 'port_no' in 'dpif'. On success, returns 0 and * initializes '*port' appropriately; on failure, returns a positive errno * value. * * The caller owns the data in 'port' and must free it with * dpif_port_destroy() when it is no longer needed. */ int dpif_port_query_by_number(const struct dpif *dpif, odp_port_t port_no, struct dpif_port *port) { int error = dpif->dpif_class->port_query_by_number(dpif, port_no, port); if (!error) { VLOG_DBG_RL(&dpmsg_rl, "%s: port %"PRIu32" is device %s", dpif_name(dpif), port_no, port->name); } else { memset(port, 0, sizeof *port); VLOG_WARN_RL(&error_rl, "%s: failed to query port %"PRIu32": %s", dpif_name(dpif), port_no, ovs_strerror(error)); } return error; } /* Looks up port named 'devname' in 'dpif'. On success, returns 0 and * initializes '*port' appropriately; on failure, returns a positive errno * value. * * The caller owns the data in 'port' and must free it with * dpif_port_destroy() when it is no longer needed. */ int dpif_port_query_by_name(const struct dpif *dpif, const char *devname, struct dpif_port *port) { int error = dpif->dpif_class->port_query_by_name(dpif, devname, port); if (!error) { VLOG_DBG_RL(&dpmsg_rl, "%s: device %s is on port %"PRIu32, dpif_name(dpif), devname, port->port_no); } else { memset(port, 0, sizeof *port); /* For ENOENT or ENODEV we use DBG level because the caller is probably * interested in whether 'dpif' actually has a port 'devname', so that * it's not an issue worth logging if it doesn't. Other errors are * uncommon and more likely to indicate a real problem. */ VLOG_RL(&error_rl, error == ENOENT || error == ENODEV ? VLL_DBG : VLL_WARN, "%s: failed to query port %s: %s", dpif_name(dpif), devname, ovs_strerror(error)); } return error; } /* Returns the Netlink PID value to supply in OVS_ACTION_ATTR_USERSPACE * actions as the OVS_USERSPACE_ATTR_PID attribute's value, for use in * flows whose packets arrived on port 'port_no'. In the case where the * provider allocates multiple Netlink PIDs to a single port, it may use * 'hash' to spread load among them. The caller need not use a particular * hash function; a 5-tuple hash is suitable. * * (The datapath implementation might use some different hash function for * distributing packets received via flow misses among PIDs. This means * that packets received via flow misses might be reordered relative to * packets received via userspace actions. This is not ordinarily a * problem.) * * A 'port_no' of ODPP_NONE is a special case: it returns a reserved PID, not * allocated to any port, that the client may use for special purposes. * * The return value is only meaningful when DPIF_UC_ACTION has been enabled in * the 'dpif''s listen mask. It is allowed to change when DPIF_UC_ACTION is * disabled and then re-enabled, so a client that does that must be prepared to * update all of the flows that it installed that contain * OVS_ACTION_ATTR_USERSPACE actions. */ uint32_t dpif_port_get_pid(const struct dpif *dpif, odp_port_t port_no, uint32_t hash) { return (dpif->dpif_class->port_get_pid ? (dpif->dpif_class->port_get_pid)(dpif, port_no, hash) : 0); } /* Looks up port number 'port_no' in 'dpif'. On success, returns 0 and copies * the port's name into the 'name_size' bytes in 'name', ensuring that the * result is null-terminated. On failure, returns a positive errno value and * makes 'name' the empty string. */ int dpif_port_get_name(struct dpif *dpif, odp_port_t port_no, char *name, size_t name_size) { struct dpif_port port; int error; ovs_assert(name_size > 0); error = dpif_port_query_by_number(dpif, port_no, &port); if (!error) { ovs_strlcpy(name, port.name, name_size); dpif_port_destroy(&port); } else { *name = '\0'; } return error; } /* Initializes 'dump' to begin dumping the ports in a dpif. * * This function provides no status indication. An error status for the entire * dump operation is provided when it is completed by calling * dpif_port_dump_done(). */ void dpif_port_dump_start(struct dpif_port_dump *dump, const struct dpif *dpif) { dump->dpif = dpif; dump->error = dpif->dpif_class->port_dump_start(dpif, &dump->state); log_operation(dpif, "port_dump_start", dump->error); } /* Attempts to retrieve another port from 'dump', which must have been * initialized with dpif_port_dump_start(). On success, stores a new dpif_port * into 'port' and returns true. On failure, returns false. * * Failure might indicate an actual error or merely that the last port has been * dumped. An error status for the entire dump operation is provided when it * is completed by calling dpif_port_dump_done(). * * The dpif owns the data stored in 'port'. It will remain valid until at * least the next time 'dump' is passed to dpif_port_dump_next() or * dpif_port_dump_done(). */ bool dpif_port_dump_next(struct dpif_port_dump *dump, struct dpif_port *port) { const struct dpif *dpif = dump->dpif; if (dump->error) { return false; } dump->error = dpif->dpif_class->port_dump_next(dpif, dump->state, port); if (dump->error == EOF) { VLOG_DBG_RL(&dpmsg_rl, "%s: dumped all ports", dpif_name(dpif)); } else { log_operation(dpif, "port_dump_next", dump->error); } if (dump->error) { dpif->dpif_class->port_dump_done(dpif, dump->state); return false; } return true; } /* Completes port table dump operation 'dump', which must have been initialized * with dpif_port_dump_start(). Returns 0 if the dump operation was * error-free, otherwise a positive errno value describing the problem. */ int dpif_port_dump_done(struct dpif_port_dump *dump) { const struct dpif *dpif = dump->dpif; if (!dump->error) { dump->error = dpif->dpif_class->port_dump_done(dpif, dump->state); log_operation(dpif, "port_dump_done", dump->error); } return dump->error == EOF ? 0 : dump->error; } /* Polls for changes in the set of ports in 'dpif'. If the set of ports in * 'dpif' has changed, this function does one of the following: * * - Stores the name of the device that was added to or deleted from 'dpif' in * '*devnamep' and returns 0. The caller is responsible for freeing * '*devnamep' (with free()) when it no longer needs it. * * - Returns ENOBUFS and sets '*devnamep' to NULL. * * This function may also return 'false positives', where it returns 0 and * '*devnamep' names a device that was not actually added or deleted or it * returns ENOBUFS without any change. * * Returns EAGAIN if the set of ports in 'dpif' has not changed. May also * return other positive errno values to indicate that something has gone * wrong. */ int dpif_port_poll(const struct dpif *dpif, char **devnamep) { int error = dpif->dpif_class->port_poll(dpif, devnamep); if (error) { *devnamep = NULL; } return error; } /* Arranges for the poll loop to wake up when port_poll(dpif) will return a * value other than EAGAIN. */ void dpif_port_poll_wait(const struct dpif *dpif) { dpif->dpif_class->port_poll_wait(dpif); } /* Extracts the flow stats for a packet. The 'flow' and 'packet' * arguments must have been initialized through a call to flow_extract(). * 'used' is stored into stats->used. */ void dpif_flow_stats_extract(const struct flow *flow, const struct ofpbuf *packet, long long int used, struct dpif_flow_stats *stats) { stats->tcp_flags = ntohs(flow->tcp_flags); stats->n_bytes = ofpbuf_size(packet); stats->n_packets = 1; stats->used = used; } /* Appends a human-readable representation of 'stats' to 's'. */ void dpif_flow_stats_format(const struct dpif_flow_stats *stats, struct ds *s) { ds_put_format(s, "packets:%"PRIu64", bytes:%"PRIu64", used:", stats->n_packets, stats->n_bytes); if (stats->used) { ds_put_format(s, "%.3fs", (time_msec() - stats->used) / 1000.0); } else { ds_put_format(s, "never"); } if (stats->tcp_flags) { ds_put_cstr(s, ", flags:"); packet_format_tcp_flags(s, stats->tcp_flags); } } /* Deletes all flows from 'dpif'. Returns 0 if successful, otherwise a * positive errno value. */ int dpif_flow_flush(struct dpif *dpif) { int error; COVERAGE_INC(dpif_flow_flush); error = dpif->dpif_class->flow_flush(dpif); log_operation(dpif, "flow_flush", error); return error; } /* Queries 'dpif' for a flow entry. The flow is specified by the Netlink * attributes with types OVS_KEY_ATTR_* in the 'key_len' bytes starting at * 'key'. * * Returns 0 if successful. If no flow matches, returns ENOENT. On other * failure, returns a positive errno value. * * If 'actionsp' is nonnull, then on success '*actionsp' will be set to an * ofpbuf owned by the caller that contains the Netlink attributes for the * flow's actions. The caller must free the ofpbuf (with ofpbuf_delete()) when * it is no longer needed. * * If 'stats' is nonnull, then on success it will be updated with the flow's * statistics. */ int dpif_flow_get(const struct dpif *dpif, const struct nlattr *key, size_t key_len, struct ofpbuf **actionsp, struct dpif_flow_stats *stats) { int error; COVERAGE_INC(dpif_flow_get); error = dpif->dpif_class->flow_get(dpif, key, key_len, actionsp, stats); if (error) { if (actionsp) { *actionsp = NULL; } if (stats) { memset(stats, 0, sizeof *stats); } } if (should_log_flow_message(error)) { const struct nlattr *actions; size_t actions_len; if (!error && actionsp) { actions = ofpbuf_data(*actionsp); actions_len = ofpbuf_size(*actionsp); } else { actions = NULL; actions_len = 0; } log_flow_message(dpif, error, "flow_get", key, key_len, NULL, 0, stats, actions, actions_len); } return error; } static int dpif_flow_put__(struct dpif *dpif, const struct dpif_flow_put *put) { int error; COVERAGE_INC(dpif_flow_put); ovs_assert(!(put->flags & ~(DPIF_FP_CREATE | DPIF_FP_MODIFY | DPIF_FP_ZERO_STATS))); error = dpif->dpif_class->flow_put(dpif, put); if (error && put->stats) { memset(put->stats, 0, sizeof *put->stats); } log_flow_put_message(dpif, put, error); return error; } /* Adds or modifies a flow in 'dpif'. The flow is specified by the Netlink * attribute OVS_FLOW_ATTR_KEY with types OVS_KEY_ATTR_* in the 'key_len' bytes * starting at 'key', and OVS_FLOW_ATTR_MASK with types of OVS_KEY_ATTR_* in * the 'mask_len' bytes starting at 'mask'. The associated actions are * specified by the Netlink attributes with types OVS_ACTION_ATTR_* in the * 'actions_len' bytes starting at 'actions'. * * - If the flow's key does not exist in 'dpif', then the flow will be added if * 'flags' includes DPIF_FP_CREATE. Otherwise the operation will fail with * ENOENT. * * The datapath may reject attempts to insert overlapping flows with EINVAL * or EEXIST, but clients should not rely on this: avoiding overlapping flows * is primarily the client's responsibility. * * If the operation succeeds, then 'stats', if nonnull, will be zeroed. * * - If the flow's key does exist in 'dpif', then the flow's actions will be * updated if 'flags' includes DPIF_FP_MODIFY. Otherwise the operation will * fail with EEXIST. If the flow's actions are updated, then its statistics * will be zeroed if 'flags' includes DPIF_FP_ZERO_STATS, and left as-is * otherwise. * * If the operation succeeds, then 'stats', if nonnull, will be set to the * flow's statistics before the update. */ int dpif_flow_put(struct dpif *dpif, enum dpif_flow_put_flags flags, const struct nlattr *key, size_t key_len, const struct nlattr *mask, size_t mask_len, const struct nlattr *actions, size_t actions_len, struct dpif_flow_stats *stats) { struct dpif_flow_put put; put.flags = flags; put.key = key; put.key_len = key_len; put.mask = mask; put.mask_len = mask_len; put.actions = actions; put.actions_len = actions_len; put.stats = stats; return dpif_flow_put__(dpif, &put); } static int dpif_flow_del__(struct dpif *dpif, struct dpif_flow_del *del) { int error; COVERAGE_INC(dpif_flow_del); error = dpif->dpif_class->flow_del(dpif, del); if (error && del->stats) { memset(del->stats, 0, sizeof *del->stats); } log_flow_del_message(dpif, del, error); return error; } /* Deletes a flow from 'dpif' and returns 0, or returns ENOENT if 'dpif' does * not contain such a flow. The flow is specified by the Netlink attributes * with types OVS_KEY_ATTR_* in the 'key_len' bytes starting at 'key'. * * If the operation succeeds, then 'stats', if nonnull, will be set to the * flow's statistics before its deletion. */ int dpif_flow_del(struct dpif *dpif, const struct nlattr *key, size_t key_len, struct dpif_flow_stats *stats) { struct dpif_flow_del del; del.key = key; del.key_len = key_len; del.stats = stats; return dpif_flow_del__(dpif, &del); } /* Allocates thread-local state for use with the 'flow_dump_next' function for * 'dpif'. On return, initializes '*statep' with any private data needed for * iteration. */ void dpif_flow_dump_state_init(const struct dpif *dpif, void **statep) { dpif->dpif_class->flow_dump_state_init(statep); } /* Releases 'state' which was initialized by a call to the * 'flow_dump_state_init' function for 'dpif'. */ void dpif_flow_dump_state_uninit(const struct dpif *dpif, void *state) { dpif->dpif_class->flow_dump_state_uninit(state); } /* Initializes 'dump' to begin dumping the flows in a dpif. On sucess, * initializes 'dump' with any data needed for iteration and returns 0. * Otherwise, returns a positive errno value describing the problem. */ int dpif_flow_dump_start(struct dpif_flow_dump *dump, const struct dpif *dpif) { int error; dump->dpif = dpif; error = dpif->dpif_class->flow_dump_start(dpif, &dump->iter); log_operation(dpif, "flow_dump_start", error); return error; } /* Attempts to retrieve another flow from 'dump', using 'state' for * thread-local storage. 'dump' must have been initialized with a successful * call to dpif_flow_dump_start(), and 'state' must have been initialized with * dpif_flow_state_init(). * * On success, updates the output parameters as described below and returns * true. Otherwise, returns false. Failure might indicate an actual error or * merely the end of the flow table. An error status for the entire dump * operation is provided when it is completed by calling dpif_flow_dump_done(). * Multiple threads may use the same 'dump' with this function, but all other * parameters must not be shared. * * On success, if 'key' and 'key_len' are nonnull then '*key' and '*key_len' * will be set to Netlink attributes with types OVS_KEY_ATTR_* representing the * dumped flow's key. If 'actions' and 'actions_len' are nonnull then they are * set to Netlink attributes with types OVS_ACTION_ATTR_* representing the * dumped flow's actions. If 'stats' is nonnull then it will be set to the * dumped flow's statistics. * * All of the returned data is owned by 'dpif', not by the caller, and the * caller must not modify or free it. 'dpif' guarantees that it remains * accessible and unchanging until at least the next call to 'flow_dump_next' * or 'flow_dump_done' for 'dump' and 'state'. */ bool dpif_flow_dump_next(struct dpif_flow_dump *dump, void *state, const struct nlattr **key, size_t *key_len, const struct nlattr **mask, size_t *mask_len, const struct nlattr **actions, size_t *actions_len, const struct dpif_flow_stats **stats) { const struct dpif *dpif = dump->dpif; int error; error = dpif->dpif_class->flow_dump_next(dpif, dump->iter, state, key, key_len, mask, mask_len, actions, actions_len, stats); if (error) { if (key) { *key = NULL; *key_len = 0; } if (mask) { *mask = NULL; *mask_len = 0; } if (actions) { *actions = NULL; *actions_len = 0; } if (stats) { *stats = NULL; } } if (error == EOF) { VLOG_DBG_RL(&dpmsg_rl, "%s: dumped all flows", dpif_name(dpif)); } else if (should_log_flow_message(error)) { log_flow_message(dpif, error, "flow_dump", key ? *key : NULL, key ? *key_len : 0, mask ? *mask : NULL, mask ? *mask_len : 0, stats ? *stats : NULL, actions ? *actions : NULL, actions ? *actions_len : 0); } return !error; } /* Determines whether the next call to 'dpif_flow_dump_next' for 'dump' and * 'state' will modify or free the keys that it previously returned. 'state' * must have been initialized by a call to 'dpif_flow_dump_state_init' for * 'dump'. * * 'dpif' guarantees that data returned by flow_dump_next() will remain * accessible and unchanging until the next call. This function provides a way * for callers to determine whether that guarantee extends beyond the next * call. * * Returns true if the next call to flow_dump_next() is expected to be * destructive to previously returned keys for 'state', false otherwise. */ bool dpif_flow_dump_next_may_destroy_keys(struct dpif_flow_dump *dump, void *state) { const struct dpif *dpif = dump->dpif; return (dpif->dpif_class->flow_dump_next_may_destroy_keys ? dpif->dpif_class->flow_dump_next_may_destroy_keys(state) : true); } /* Completes flow table dump operation 'dump', which must have been initialized * with a successful call to dpif_flow_dump_start(). Returns 0 if the dump * operation was error-free, otherwise a positive errno value describing the * problem. */ int dpif_flow_dump_done(struct dpif_flow_dump *dump) { const struct dpif *dpif = dump->dpif; int error = dpif->dpif_class->flow_dump_done(dpif, dump->iter); log_operation(dpif, "flow_dump_done", error); return error == EOF ? 0 : error; } struct dpif_execute_helper_aux { struct dpif *dpif; int error; }; /* This is called for actions that need the context of the datapath to be * meaningful. */ static void dpif_execute_helper_cb(void *aux_, struct ofpbuf *packet, struct pkt_metadata *md, const struct nlattr *action, bool may_steal OVS_UNUSED) { struct dpif_execute_helper_aux *aux = aux_; struct dpif_execute execute; int type = nl_attr_type(action); switch ((enum ovs_action_attr)type) { case OVS_ACTION_ATTR_OUTPUT: case OVS_ACTION_ATTR_USERSPACE: execute.actions = action; execute.actions_len = NLA_ALIGN(action->nla_len); execute.packet = packet; execute.md = *md; execute.needs_help = false; aux->error = aux->dpif->dpif_class->execute(aux->dpif, &execute); break; case OVS_ACTION_ATTR_PUSH_VLAN: case OVS_ACTION_ATTR_POP_VLAN: case OVS_ACTION_ATTR_PUSH_MPLS: case OVS_ACTION_ATTR_POP_MPLS: case OVS_ACTION_ATTR_SET: case OVS_ACTION_ATTR_SAMPLE: case OVS_ACTION_ATTR_UNSPEC: case OVS_ACTION_ATTR_RECIRC: case OVS_ACTION_ATTR_HASH: case __OVS_ACTION_ATTR_MAX: OVS_NOT_REACHED(); } } /* Executes 'execute' by performing most of the actions in userspace and * passing the fully constructed packets to 'dpif' for output and userspace * actions. * * This helps with actions that a given 'dpif' doesn't implement directly. */ static int dpif_execute_with_help(struct dpif *dpif, struct dpif_execute *execute) { struct dpif_execute_helper_aux aux = {dpif, 0}; COVERAGE_INC(dpif_execute_with_help); odp_execute_actions(&aux, execute->packet, false, &execute->md, execute->actions, execute->actions_len, dpif_execute_helper_cb); return aux.error; } /* Causes 'dpif' to perform the 'execute->actions_len' bytes of actions in * 'execute->actions' on the Ethernet frame in 'execute->packet' and on packet * metadata in 'execute->md'. The implementation is allowed to modify both the * '*execute->packet' and 'execute->md'. * * Some dpif providers do not implement every action. The Linux kernel * datapath, in particular, does not implement ARP field modification. If * 'needs_help' is true, the dpif layer executes in userspace all of the * actions that it can, and for OVS_ACTION_ATTR_OUTPUT and * OVS_ACTION_ATTR_USERSPACE actions it passes the packet through to the dpif * implementation. * * This works even if 'execute->actions_len' is too long for a Netlink * attribute. * * Returns 0 if successful, otherwise a positive errno value. */ int dpif_execute(struct dpif *dpif, struct dpif_execute *execute) { int error; COVERAGE_INC(dpif_execute); if (execute->actions_len > 0) { error = (execute->needs_help || nl_attr_oversized(execute->actions_len) ? dpif_execute_with_help(dpif, execute) : dpif->dpif_class->execute(dpif, execute)); } else { error = 0; } log_execute_message(dpif, execute, error); return error; } /* Executes each of the 'n_ops' operations in 'ops' on 'dpif', in the order in * which they are specified, placing each operation's results in the "output" * members documented in comments. * * This function exists because some datapaths can perform batched operations * faster than individual operations. */ void dpif_operate(struct dpif *dpif, struct dpif_op **ops, size_t n_ops) { if (dpif->dpif_class->operate) { while (n_ops > 0) { size_t chunk; /* Count 'chunk', the number of ops that can be executed without * needing any help. Ops that need help should be rare, so we * expect this to ordinarily be 'n_ops', that is, all the ops. */ for (chunk = 0; chunk < n_ops; chunk++) { struct dpif_op *op = ops[chunk]; if (op->type == DPIF_OP_EXECUTE && op->u.execute.needs_help) { break; } } if (chunk) { /* Execute a chunk full of ops that the dpif provider can * handle itself, without help. */ size_t i; dpif->dpif_class->operate(dpif, ops, chunk); for (i = 0; i < chunk; i++) { struct dpif_op *op = ops[i]; switch (op->type) { case DPIF_OP_FLOW_PUT: log_flow_put_message(dpif, &op->u.flow_put, op->error); break; case DPIF_OP_FLOW_DEL: log_flow_del_message(dpif, &op->u.flow_del, op->error); break; case DPIF_OP_EXECUTE: log_execute_message(dpif, &op->u.execute, op->error); break; } } ops += chunk; n_ops -= chunk; } else { /* Help the dpif provider to execute one op. */ struct dpif_op *op = ops[0]; op->error = dpif_execute(dpif, &op->u.execute); ops++; n_ops--; } } } else { size_t i; for (i = 0; i < n_ops; i++) { struct dpif_op *op = ops[i]; switch (op->type) { case DPIF_OP_FLOW_PUT: op->error = dpif_flow_put__(dpif, &op->u.flow_put); break; case DPIF_OP_FLOW_DEL: op->error = dpif_flow_del__(dpif, &op->u.flow_del); break; case DPIF_OP_EXECUTE: op->error = dpif_execute(dpif, &op->u.execute); break; default: OVS_NOT_REACHED(); } } } } /* Returns a string that represents 'type', for use in log messages. */ const char * dpif_upcall_type_to_string(enum dpif_upcall_type type) { switch (type) { case DPIF_UC_MISS: return "miss"; case DPIF_UC_ACTION: return "action"; case DPIF_N_UC_TYPES: default: return ""; } } /* Enables or disables receiving packets with dpif_recv() on 'dpif'. Returns 0 * if successful, otherwise a positive errno value. * * Turning packet receive off and then back on may change the Netlink PID * assignments returned by dpif_port_get_pid(). If the client does this, it * must update all of the flows that have OVS_ACTION_ATTR_USERSPACE actions * using the new PID assignment. */ int dpif_recv_set(struct dpif *dpif, bool enable) { int error = dpif->dpif_class->recv_set(dpif, enable); log_operation(dpif, "recv_set", error); return error; } /* Refreshes the poll loops and Netlink sockets associated to each port, * when the number of upcall handlers (upcall receiving thread) is changed * to 'n_handlers' and receiving packets for 'dpif' is enabled by * recv_set(). * * Since multiple upcall handlers can read upcalls simultaneously from * 'dpif', each port can have multiple Netlink sockets, one per upcall * handler. So, handlers_set() is responsible for the following tasks: * * When receiving upcall is enabled, extends or creates the * configuration to support: * * - 'n_handlers' Netlink sockets for each port. * * - 'n_handlers' poll loops, one for each upcall handler. * * - registering the Netlink sockets for the same upcall handler to * the corresponding poll loop. * * Returns 0 if successful, otherwise a positive errno value. */ int dpif_handlers_set(struct dpif *dpif, uint32_t n_handlers) { int error = dpif->dpif_class->handlers_set(dpif, n_handlers); log_operation(dpif, "handlers_set", error); return error; } /* Polls for an upcall from 'dpif' for an upcall handler. Since there * there can be multiple poll loops, 'handler_id' is needed as index to * identify the corresponding poll loop. If successful, stores the upcall * into '*upcall', using 'buf' for storage. Should only be called if * 'recv_set' has been used to enable receiving packets from 'dpif'. * * 'upcall->key' and 'upcall->userdata' point into data in the caller-provided * 'buf', so their memory cannot be freed separately from 'buf'. * * The caller owns the data of 'upcall->packet' and may modify it. If * packet's headroom is exhausted as it is manipulated, 'upcall->packet' * will be reallocated. This requires the data of 'upcall->packet' to be * released with ofpbuf_uninit() before 'upcall' is destroyed. However, * when an error is returned, the 'upcall->packet' may be uninitialized * and should not be released. * * Returns 0 if successful, otherwise a positive errno value. Returns EAGAIN * if no upcall is immediately available. */ int dpif_recv(struct dpif *dpif, uint32_t handler_id, struct dpif_upcall *upcall, struct ofpbuf *buf) { int error = dpif->dpif_class->recv(dpif, handler_id, upcall, buf); if (!error && !VLOG_DROP_DBG(&dpmsg_rl)) { struct ds flow; char *packet; packet = ofp_packet_to_string(ofpbuf_data(&upcall->packet), ofpbuf_size(&upcall->packet)); ds_init(&flow); odp_flow_key_format(upcall->key, upcall->key_len, &flow); VLOG_DBG("%s: %s upcall:\n%s\n%s", dpif_name(dpif), dpif_upcall_type_to_string(upcall->type), ds_cstr(&flow), packet); ds_destroy(&flow); free(packet); } else if (error && error != EAGAIN) { log_operation(dpif, "recv", error); } return error; } /* Discards all messages that would otherwise be received by dpif_recv() on * 'dpif'. */ void dpif_recv_purge(struct dpif *dpif) { COVERAGE_INC(dpif_purge); if (dpif->dpif_class->recv_purge) { dpif->dpif_class->recv_purge(dpif); } } /* Arranges for the poll loop for an upcall handler to wake up when 'dpif' * 'dpif' has a message queued to be received with the recv member * function. Since there can be multiple poll loops, 'handler_id' is * needed as index to identify the corresponding poll loop. */ void dpif_recv_wait(struct dpif *dpif, uint32_t handler_id) { dpif->dpif_class->recv_wait(dpif, handler_id); } /* Obtains the NetFlow engine type and engine ID for 'dpif' into '*engine_type' * and '*engine_id', respectively. */ void dpif_get_netflow_ids(const struct dpif *dpif, uint8_t *engine_type, uint8_t *engine_id) { *engine_type = dpif->netflow_engine_type; *engine_id = dpif->netflow_engine_id; } /* Translates OpenFlow queue ID 'queue_id' (in host byte order) into a priority * value used for setting packet priority. * On success, returns 0 and stores the priority into '*priority'. * On failure, returns a positive errno value and stores 0 into '*priority'. */ int dpif_queue_to_priority(const struct dpif *dpif, uint32_t queue_id, uint32_t *priority) { int error = (dpif->dpif_class->queue_to_priority ? dpif->dpif_class->queue_to_priority(dpif, queue_id, priority) : EOPNOTSUPP); if (error) { *priority = 0; } log_operation(dpif, "queue_to_priority", error); return error; } void dpif_init(struct dpif *dpif, const struct dpif_class *dpif_class, const char *name, uint8_t netflow_engine_type, uint8_t netflow_engine_id) { dpif->dpif_class = dpif_class; dpif->base_name = xstrdup(name); dpif->full_name = xasprintf("%s@%s", dpif_class->type, name); dpif->netflow_engine_type = netflow_engine_type; dpif->netflow_engine_id = netflow_engine_id; } /* Undoes the results of initialization. * * Normally this function only needs to be called from dpif_close(). * However, it may be called by providers due to an error on opening * that occurs after initialization. It this case dpif_close() would * never be called. */ void dpif_uninit(struct dpif *dpif, bool close) { char *base_name = dpif->base_name; char *full_name = dpif->full_name; if (close) { dpif->dpif_class->close(dpif); } free(base_name); free(full_name); } static void log_operation(const struct dpif *dpif, const char *operation, int error) { if (!error) { VLOG_DBG_RL(&dpmsg_rl, "%s: %s success", dpif_name(dpif), operation); } else if (ofperr_is_valid(error)) { VLOG_WARN_RL(&error_rl, "%s: %s failed (%s)", dpif_name(dpif), operation, ofperr_get_name(error)); } else { VLOG_WARN_RL(&error_rl, "%s: %s failed (%s)", dpif_name(dpif), operation, ovs_strerror(error)); } } static enum vlog_level flow_message_log_level(int error) { /* If flows arrive in a batch, userspace may push down multiple * unique flow definitions that overlap when wildcards are applied. * Kernels that support flow wildcarding will reject these flows as * duplicates (EEXIST), so lower the log level to debug for these * types of messages. */ return (error && error != EEXIST) ? VLL_WARN : VLL_DBG; } static bool should_log_flow_message(int error) { return !vlog_should_drop(THIS_MODULE, flow_message_log_level(error), error ? &error_rl : &dpmsg_rl); } static void log_flow_message(const struct dpif *dpif, int error, const char *operation, const struct nlattr *key, size_t key_len, const struct nlattr *mask, size_t mask_len, const struct dpif_flow_stats *stats, const struct nlattr *actions, size_t actions_len) { struct ds ds = DS_EMPTY_INITIALIZER; ds_put_format(&ds, "%s: ", dpif_name(dpif)); if (error) { ds_put_cstr(&ds, "failed to "); } ds_put_format(&ds, "%s ", operation); if (error) { ds_put_format(&ds, "(%s) ", ovs_strerror(error)); } odp_flow_format(key, key_len, mask, mask_len, NULL, &ds, true); if (stats) { ds_put_cstr(&ds, ", "); dpif_flow_stats_format(stats, &ds); } if (actions || actions_len) { ds_put_cstr(&ds, ", actions:"); format_odp_actions(&ds, actions, actions_len); } vlog(THIS_MODULE, flow_message_log_level(error), "%s", ds_cstr(&ds)); ds_destroy(&ds); } static void log_flow_put_message(struct dpif *dpif, const struct dpif_flow_put *put, int error) { if (should_log_flow_message(error)) { struct ds s; ds_init(&s); ds_put_cstr(&s, "put"); if (put->flags & DPIF_FP_CREATE) { ds_put_cstr(&s, "[create]"); } if (put->flags & DPIF_FP_MODIFY) { ds_put_cstr(&s, "[modify]"); } if (put->flags & DPIF_FP_ZERO_STATS) { ds_put_cstr(&s, "[zero]"); } log_flow_message(dpif, error, ds_cstr(&s), put->key, put->key_len, put->mask, put->mask_len, put->stats, put->actions, put->actions_len); ds_destroy(&s); } } static void log_flow_del_message(struct dpif *dpif, const struct dpif_flow_del *del, int error) { if (should_log_flow_message(error)) { log_flow_message(dpif, error, "flow_del", del->key, del->key_len, NULL, 0, !error ? del->stats : NULL, NULL, 0); } } static void log_execute_message(struct dpif *dpif, const struct dpif_execute *execute, int error) { if (!(error ? VLOG_DROP_WARN(&error_rl) : VLOG_DROP_DBG(&dpmsg_rl))) { struct ds ds = DS_EMPTY_INITIALIZER; char *packet; packet = ofp_packet_to_string(ofpbuf_data(execute->packet), ofpbuf_size(execute->packet)); ds_put_format(&ds, "%s: execute ", dpif_name(dpif)); format_odp_actions(&ds, execute->actions, execute->actions_len); if (error) { ds_put_format(&ds, " failed (%s)", ovs_strerror(error)); } ds_put_format(&ds, " on packet %s", packet); vlog(THIS_MODULE, error ? VLL_WARN : VLL_DBG, "%s", ds_cstr(&ds)); ds_destroy(&ds); free(packet); } }