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/* Copyright (c) 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 <config.h>
#include "ofproto-dpif-upcall.h"
#include <errno.h>
#include <stdbool.h>
#include <inttypes.h>
#include "connmgr.h"
#include "coverage.h"
#include "cmap.h"
#include "dpif.h"
#include "openvswitch/dynamic-string.h"
#include "fail-open.h"
#include "guarded-list.h"
#include "latch.h"
#include "openvswitch/list.h"
#include "netlink.h"
#include "openvswitch/ofpbuf.h"
#include "ofproto-dpif-ipfix.h"
#include "ofproto-dpif-sflow.h"
#include "ofproto-dpif-xlate.h"
#include "ovs-rcu.h"
#include "packets.h"
#include "poll-loop.h"
#include "seq.h"
#include "unixctl.h"
#include "openvswitch/vlog.h"
#define MAX_QUEUE_LENGTH 512
#define UPCALL_MAX_BATCH 64
#define REVALIDATE_MAX_BATCH 50
VLOG_DEFINE_THIS_MODULE(ofproto_dpif_upcall);
COVERAGE_DEFINE(dumped_duplicate_flow);
COVERAGE_DEFINE(dumped_new_flow);
COVERAGE_DEFINE(handler_duplicate_upcall);
COVERAGE_DEFINE(upcall_ukey_contention);
COVERAGE_DEFINE(revalidate_missed_dp_flow);
/* A thread that reads upcalls from dpif, forwards each upcall's packet,
* and possibly sets up a kernel flow as a cache. */
struct handler {
struct udpif *udpif; /* Parent udpif. */
pthread_t thread; /* Thread ID. */
uint32_t handler_id; /* Handler id. */
};
/* In the absence of a multiple-writer multiple-reader datastructure for
* storing udpif_keys ("ukeys"), we use a large number of cmaps, each with its
* own lock for writing. */
#define N_UMAPS 512 /* per udpif. */
struct umap {
struct ovs_mutex mutex; /* Take for writing to the following. */
struct cmap cmap; /* Datapath flow keys. */
};
/* A thread that processes datapath flows, updates OpenFlow statistics, and
* updates or removes them if necessary.
*
* Revalidator threads operate in two phases: "dump" and "sweep". In between
* each phase, all revalidators sync up so that all revalidator threads are
* either in one phase or the other, but not a combination.
*
* During the dump phase, revalidators fetch flows from the datapath and
* attribute the statistics to OpenFlow rules. Each datapath flow has a
* corresponding ukey which caches the most recently seen statistics. If
* a flow needs to be deleted (for example, because it is unused over a
* period of time), revalidator threads may delete the flow during the
* dump phase. The datapath is not guaranteed to reliably dump all flows
* from the datapath, and there is no mapping between datapath flows to
* revalidators, so a particular flow may be handled by zero or more
* revalidators during a single dump phase. To avoid duplicate attribution
* of statistics, ukeys are never deleted during this phase.
*
* During the sweep phase, each revalidator takes ownership of a different
* slice of umaps and sweeps through all ukeys in those umaps to figure out
* whether they need to be deleted. During this phase, revalidators may
* fetch individual flows which were not dumped during the dump phase to
* validate them and attribute statistics.
*/
struct revalidator {
struct udpif *udpif; /* Parent udpif. */
pthread_t thread; /* Thread ID. */
unsigned int id; /* ovsthread_id_self(). */
};
/* An upcall handler for ofproto_dpif.
*
* udpif keeps records of two kind of logically separate units:
*
* upcall handling
* ---------------
*
* - An array of 'struct handler's for upcall handling and flow
* installation.
*
* flow revalidation
* -----------------
*
* - Revalidation threads which read the datapath flow table and maintains
* them.
*/
struct udpif {
struct ovs_list list_node; /* In all_udpifs list. */
struct dpif *dpif; /* Datapath handle. */
struct dpif_backer *backer; /* Opaque dpif_backer pointer. */
struct handler *handlers; /* Upcall handlers. */
size_t n_handlers;
struct revalidator *revalidators; /* Flow revalidators. */
size_t n_revalidators;
struct latch exit_latch; /* Tells child threads to exit. */
/* Revalidation. */
struct seq *reval_seq; /* Incremented to force revalidation. */
bool reval_exit; /* Set by leader on 'exit_latch. */
struct ovs_barrier reval_barrier; /* Barrier used by revalidators. */
struct dpif_flow_dump *dump; /* DPIF flow dump state. */
long long int dump_duration; /* Duration of the last flow dump. */
struct seq *dump_seq; /* Increments each dump iteration. */
atomic_bool enable_ufid; /* If true, skip dumping flow attrs. */
/* These variables provide a mechanism for the main thread to pause
* all revalidation without having to completely shut the threads down.
* 'pause_latch' is shared between the main thread and the lead
* revalidator thread, so when it is desirable to halt revalidation, the
* main thread will set the latch. 'pause' and 'pause_barrier' are shared
* by revalidator threads. The lead revalidator will set 'pause' when it
* observes the latch has been set, and this will cause all revalidator
* threads to wait on 'pause_barrier' at the beginning of the next
* revalidation round. */
bool pause; /* Set by leader on 'pause_latch. */
struct latch pause_latch; /* Set to force revalidators pause. */
struct ovs_barrier pause_barrier; /* Barrier used to pause all */
/* revalidators by main thread. */
/* There are 'N_UMAPS' maps containing 'struct udpif_key' elements.
*
* During the flow dump phase, revalidators insert into these with a random
* distribution. During the garbage collection phase, each revalidator
* takes care of garbage collecting a slice of these maps. */
struct umap *ukeys;
/* Datapath flow statistics. */
unsigned int max_n_flows;
unsigned int avg_n_flows;
/* Following fields are accessed and modified by different threads. */
atomic_uint flow_limit; /* Datapath flow hard limit. */
/* n_flows_mutex prevents multiple threads updating these concurrently. */
atomic_uint n_flows; /* Number of flows in the datapath. */
atomic_llong n_flows_timestamp; /* Last time n_flows was updated. */
struct ovs_mutex n_flows_mutex;
/* Following fields are accessed and modified only from the main thread. */
struct unixctl_conn **conns; /* Connections waiting on dump_seq. */
uint64_t conn_seq; /* Corresponds to 'dump_seq' when
conns[n_conns-1] was stored. */
size_t n_conns; /* Number of connections waiting. */
};
enum upcall_type {
BAD_UPCALL, /* Some kind of bug somewhere. */
MISS_UPCALL, /* A flow miss. */
SFLOW_UPCALL, /* sFlow sample. */
FLOW_SAMPLE_UPCALL, /* Per-flow sampling. */
IPFIX_UPCALL /* Per-bridge sampling. */
};
enum reval_result {
UKEY_KEEP,
UKEY_DELETE,
UKEY_MODIFY
};
struct upcall {
struct ofproto_dpif *ofproto; /* Parent ofproto. */
const struct recirc_id_node *recirc; /* Recirculation context. */
bool have_recirc_ref; /* Reference held on recirc ctx? */
/* The flow and packet are only required to be constant when using
* dpif-netdev. If a modification is absolutely necessary, a const cast
* may be used with other datapaths. */
const struct flow *flow; /* Parsed representation of the packet. */
const ovs_u128 *ufid; /* Unique identifier for 'flow'. */
unsigned pmd_id; /* Datapath poll mode driver id. */
const struct dp_packet *packet; /* Packet associated with this upcall. */
ofp_port_t in_port; /* OpenFlow in port, or OFPP_NONE. */
uint16_t mru; /* If !0, Maximum receive unit of
fragmented IP packet */
enum dpif_upcall_type type; /* Datapath type of the upcall. */
const struct nlattr *userdata; /* Userdata for DPIF_UC_ACTION Upcalls. */
const struct nlattr *actions; /* Flow actions in DPIF_UC_ACTION Upcalls. */
bool xout_initialized; /* True if 'xout' must be uninitialized. */
struct xlate_out xout; /* Result of xlate_actions(). */
struct ofpbuf odp_actions; /* Datapath actions from xlate_actions(). */
struct flow_wildcards wc; /* Dependencies that megaflow must match. */
struct ofpbuf put_actions; /* Actions 'put' in the fastpath. */
struct dpif_ipfix *ipfix; /* IPFIX pointer or NULL. */
struct dpif_sflow *sflow; /* SFlow pointer or NULL. */
struct udpif_key *ukey; /* Revalidator flow cache. */
bool ukey_persists; /* Set true to keep 'ukey' beyond the
lifetime of this upcall. */
uint64_t dump_seq; /* udpif->dump_seq at translation time. */
uint64_t reval_seq; /* udpif->reval_seq at translation time. */
/* Not used by the upcall callback interface. */
const struct nlattr *key; /* Datapath flow key. */
size_t key_len; /* Datapath flow key length. */
const struct nlattr *out_tun_key; /* Datapath output tunnel key. */
uint64_t odp_actions_stub[1024 / 8]; /* Stub for odp_actions. */
};
/* 'udpif_key's are responsible for tracking the little bit of state udpif
* needs to do flow expiration which can't be pulled directly from the
* datapath. They may be created by any handler or revalidator thread at any
* time, and read by any revalidator during the dump phase. They are however
* each owned by a single revalidator which takes care of destroying them
* during the garbage-collection phase.
*
* The mutex within the ukey protects some members of the ukey. The ukey
* itself is protected by RCU and is held within a umap in the parent udpif.
* Adding or removing a ukey from a umap is only safe when holding the
* corresponding umap lock. */
struct udpif_key {
struct cmap_node cmap_node; /* In parent revalidator 'ukeys' map. */
/* These elements are read only once created, and therefore aren't
* protected by a mutex. */
const struct nlattr *key; /* Datapath flow key. */
size_t key_len; /* Length of 'key'. */
const struct nlattr *mask; /* Datapath flow mask. */
size_t mask_len; /* Length of 'mask'. */
ovs_u128 ufid; /* Unique flow identifier. */
bool ufid_present; /* True if 'ufid' is in datapath. */
uint32_t hash; /* Pre-computed hash for 'key'. */
unsigned pmd_id; /* Datapath poll mode driver id. */
struct ovs_mutex mutex; /* Guards the following. */
struct dpif_flow_stats stats OVS_GUARDED; /* Last known stats.*/
long long int created OVS_GUARDED; /* Estimate of creation time. */
uint64_t dump_seq OVS_GUARDED; /* Tracks udpif->dump_seq. */
uint64_t reval_seq OVS_GUARDED; /* Tracks udpif->reval_seq. */
bool flow_exists OVS_GUARDED; /* Ensures flows are only deleted
once. */
/* Datapath flow actions as nlattrs. Protected by RCU. Read with
* ukey_get_actions(), and write with ukey_set_actions(). */
OVSRCU_TYPE(struct ofpbuf *) actions;
struct xlate_cache *xcache OVS_GUARDED; /* Cache for xlate entries that
* are affected by this ukey.
* Used for stats and learning.*/
union {
struct odputil_keybuf buf;
struct nlattr nla;
} keybuf, maskbuf;
uint32_t key_recirc_id; /* Non-zero if reference is held by the ukey. */
struct recirc_refs recircs; /* Action recirc IDs with references held. */
};
/* Datapath operation with optional ukey attached. */
struct ukey_op {
struct udpif_key *ukey;
struct dpif_flow_stats stats; /* Stats for 'op'. */
struct dpif_op dop; /* Flow operation. */
};
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5);
static struct ovs_list all_udpifs = OVS_LIST_INITIALIZER(&all_udpifs);
static size_t recv_upcalls(struct handler *);
static int process_upcall(struct udpif *, struct upcall *,
struct ofpbuf *odp_actions, struct flow_wildcards *);
static void handle_upcalls(struct udpif *, struct upcall *, size_t n_upcalls);
static void udpif_stop_threads(struct udpif *);
static void udpif_start_threads(struct udpif *, size_t n_handlers,
size_t n_revalidators);
static void udpif_pause_revalidators(struct udpif *);
static void udpif_resume_revalidators(struct udpif *);
static void *udpif_upcall_handler(void *);
static void *udpif_revalidator(void *);
static unsigned long udpif_get_n_flows(struct udpif *);
static void revalidate(struct revalidator *);
static void revalidator_pause(struct revalidator *);
static void revalidator_sweep(struct revalidator *);
static void revalidator_purge(struct revalidator *);
static void upcall_unixctl_show(struct unixctl_conn *conn, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_disable_megaflows(struct unixctl_conn *, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_enable_megaflows(struct unixctl_conn *, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_disable_ufid(struct unixctl_conn *, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_enable_ufid(struct unixctl_conn *, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_set_flow_limit(struct unixctl_conn *conn, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_dump_wait(struct unixctl_conn *conn, int argc,
const char *argv[], void *aux);
static void upcall_unixctl_purge(struct unixctl_conn *conn, int argc,
const char *argv[], void *aux);
static struct udpif_key *ukey_create_from_upcall(struct upcall *,
struct flow_wildcards *);
static int ukey_create_from_dpif_flow(const struct udpif *,
const struct dpif_flow *,
struct udpif_key **);
static void ukey_get_actions(struct udpif_key *, const struct nlattr **actions,
size_t *size);
static bool ukey_install_start(struct udpif *, struct udpif_key *ukey);
static bool ukey_install_finish(struct udpif_key *ukey, int error);
static bool ukey_install(struct udpif *udpif, struct udpif_key *ukey);
static struct udpif_key *ukey_lookup(struct udpif *udpif,
const ovs_u128 *ufid,
const unsigned pmd_id);
static int ukey_acquire(struct udpif *, const struct dpif_flow *,
struct udpif_key **result, int *error);
static void ukey_delete__(struct udpif_key *);
static void ukey_delete(struct umap *, struct udpif_key *);
static enum upcall_type classify_upcall(enum dpif_upcall_type type,
const struct nlattr *userdata);
static int upcall_receive(struct upcall *, const struct dpif_backer *,
const struct dp_packet *packet, enum dpif_upcall_type,
const struct nlattr *userdata, const struct flow *,
const unsigned int mru,
const ovs_u128 *ufid, const unsigned pmd_id);
static void upcall_uninit(struct upcall *);
static upcall_callback upcall_cb;
static dp_purge_callback dp_purge_cb;
static atomic_bool enable_megaflows = ATOMIC_VAR_INIT(true);
static atomic_bool enable_ufid = ATOMIC_VAR_INIT(true);
void
udpif_init(void)
{
static struct ovsthread_once once = OVSTHREAD_ONCE_INITIALIZER;
if (ovsthread_once_start(&once)) {
unixctl_command_register("upcall/show", "", 0, 0, upcall_unixctl_show,
NULL);
unixctl_command_register("upcall/disable-megaflows", "", 0, 0,
upcall_unixctl_disable_megaflows, NULL);
unixctl_command_register("upcall/enable-megaflows", "", 0, 0,
upcall_unixctl_enable_megaflows, NULL);
unixctl_command_register("upcall/disable-ufid", "", 0, 0,
upcall_unixctl_disable_ufid, NULL);
unixctl_command_register("upcall/enable-ufid", "", 0, 0,
upcall_unixctl_enable_ufid, NULL);
unixctl_command_register("upcall/set-flow-limit", "", 1, 1,
upcall_unixctl_set_flow_limit, NULL);
unixctl_command_register("revalidator/wait", "", 0, 0,
upcall_unixctl_dump_wait, NULL);
unixctl_command_register("revalidator/purge", "", 0, 0,
upcall_unixctl_purge, NULL);
ovsthread_once_done(&once);
}
}
struct udpif *
udpif_create(struct dpif_backer *backer, struct dpif *dpif)
{
struct udpif *udpif = xzalloc(sizeof *udpif);
udpif->dpif = dpif;
udpif->backer = backer;
atomic_init(&udpif->flow_limit, MIN(ofproto_flow_limit, 10000));
udpif->reval_seq = seq_create();
udpif->dump_seq = seq_create();
latch_init(&udpif->exit_latch);
latch_init(&udpif->pause_latch);
ovs_list_push_back(&all_udpifs, &udpif->list_node);
atomic_init(&udpif->enable_ufid, false);
atomic_init(&udpif->n_flows, 0);
atomic_init(&udpif->n_flows_timestamp, LLONG_MIN);
ovs_mutex_init(&udpif->n_flows_mutex);
udpif->ukeys = xmalloc(N_UMAPS * sizeof *udpif->ukeys);
for (int i = 0; i < N_UMAPS; i++) {
cmap_init(&udpif->ukeys[i].cmap);
ovs_mutex_init(&udpif->ukeys[i].mutex);
}
dpif_register_upcall_cb(dpif, upcall_cb, udpif);
dpif_register_dp_purge_cb(dpif, dp_purge_cb, udpif);
return udpif;
}
void
udpif_run(struct udpif *udpif)
{
if (udpif->conns && udpif->conn_seq != seq_read(udpif->dump_seq)) {
int i;
for (i = 0; i < udpif->n_conns; i++) {
unixctl_command_reply(udpif->conns[i], NULL);
}
free(udpif->conns);
udpif->conns = NULL;
udpif->n_conns = 0;
}
}
void
udpif_destroy(struct udpif *udpif)
{
udpif_stop_threads(udpif);
dpif_register_dp_purge_cb(udpif->dpif, NULL, udpif);
dpif_register_upcall_cb(udpif->dpif, NULL, udpif);
for (int i = 0; i < N_UMAPS; i++) {
cmap_destroy(&udpif->ukeys[i].cmap);
ovs_mutex_destroy(&udpif->ukeys[i].mutex);
}
free(udpif->ukeys);
udpif->ukeys = NULL;
ovs_list_remove(&udpif->list_node);
latch_destroy(&udpif->exit_latch);
latch_destroy(&udpif->pause_latch);
seq_destroy(udpif->reval_seq);
seq_destroy(udpif->dump_seq);
ovs_mutex_destroy(&udpif->n_flows_mutex);
free(udpif);
}
/* Stops the handler and revalidator threads, must be enclosed in
* ovsrcu quiescent state unless when destroying udpif. */
static void
udpif_stop_threads(struct udpif *udpif)
{
if (udpif && (udpif->n_handlers != 0 || udpif->n_revalidators != 0)) {
size_t i;
latch_set(&udpif->exit_latch);
for (i = 0; i < udpif->n_handlers; i++) {
struct handler *handler = &udpif->handlers[i];
xpthread_join(handler->thread, NULL);
}
for (i = 0; i < udpif->n_revalidators; i++) {
xpthread_join(udpif->revalidators[i].thread, NULL);
}
dpif_disable_upcall(udpif->dpif);
for (i = 0; i < udpif->n_revalidators; i++) {
struct revalidator *revalidator = &udpif->revalidators[i];
/* Delete ukeys, and delete all flows from the datapath to prevent
* double-counting stats. */
revalidator_purge(revalidator);
}
latch_poll(&udpif->exit_latch);
ovs_barrier_destroy(&udpif->reval_barrier);
ovs_barrier_destroy(&udpif->pause_barrier);
free(udpif->revalidators);
udpif->revalidators = NULL;
udpif->n_revalidators = 0;
free(udpif->handlers);
udpif->handlers = NULL;
udpif->n_handlers = 0;
}
}
/* Starts the handler and revalidator threads, must be enclosed in
* ovsrcu quiescent state. */
static void
udpif_start_threads(struct udpif *udpif, size_t n_handlers,
size_t n_revalidators)
{
if (udpif && n_handlers && n_revalidators) {
size_t i;
bool enable_ufid;
udpif->n_handlers = n_handlers;
udpif->n_revalidators = n_revalidators;
udpif->handlers = xzalloc(udpif->n_handlers * sizeof *udpif->handlers);
for (i = 0; i < udpif->n_handlers; i++) {
struct handler *handler = &udpif->handlers[i];
handler->udpif = udpif;
handler->handler_id = i;
handler->thread = ovs_thread_create(
"handler", udpif_upcall_handler, handler);
}
enable_ufid = ofproto_dpif_get_enable_ufid(udpif->backer);
atomic_init(&udpif->enable_ufid, enable_ufid);
dpif_enable_upcall(udpif->dpif);
ovs_barrier_init(&udpif->reval_barrier, udpif->n_revalidators);
ovs_barrier_init(&udpif->pause_barrier, udpif->n_revalidators + 1);
udpif->reval_exit = false;
udpif->pause = false;
udpif->revalidators = xzalloc(udpif->n_revalidators
* sizeof *udpif->revalidators);
for (i = 0; i < udpif->n_revalidators; i++) {
struct revalidator *revalidator = &udpif->revalidators[i];
revalidator->udpif = udpif;
revalidator->thread = ovs_thread_create(
"revalidator", udpif_revalidator, revalidator);
}
}
}
/* Pauses all revalidators. Should only be called by the main thread.
* When function returns, all revalidators are paused and will proceed
* only after udpif_resume_revalidators() is called. */
static void
udpif_pause_revalidators(struct udpif *udpif)
{
if (ofproto_dpif_backer_enabled(udpif->backer)) {
latch_set(&udpif->pause_latch);
ovs_barrier_block(&udpif->pause_barrier);
}
}
/* Resumes the pausing of revalidators. Should only be called by the
* main thread. */
static void
udpif_resume_revalidators(struct udpif *udpif)
{
if (ofproto_dpif_backer_enabled(udpif->backer)) {
latch_poll(&udpif->pause_latch);
ovs_barrier_block(&udpif->pause_barrier);
}
}
/* Tells 'udpif' how many threads it should use to handle upcalls.
* 'n_handlers' and 'n_revalidators' can never be zero. 'udpif''s
* datapath handle must have packet reception enabled before starting
* threads. */
void
udpif_set_threads(struct udpif *udpif, size_t n_handlers,
size_t n_revalidators)
{
ovs_assert(udpif);
ovs_assert(n_handlers && n_revalidators);
ovsrcu_quiesce_start();
if (udpif->n_handlers != n_handlers
|| udpif->n_revalidators != n_revalidators) {
udpif_stop_threads(udpif);
}
if (!udpif->handlers && !udpif->revalidators) {
int error;
error = dpif_handlers_set(udpif->dpif, n_handlers);
if (error) {
VLOG_ERR("failed to configure handlers in dpif %s: %s",
dpif_name(udpif->dpif), ovs_strerror(error));
return;
}
udpif_start_threads(udpif, n_handlers, n_revalidators);
}
ovsrcu_quiesce_end();
}
/* Waits for all ongoing upcall translations to complete. This ensures that
* there are no transient references to any removed ofprotos (or other
* objects). In particular, this should be called after an ofproto is removed
* (e.g. via xlate_remove_ofproto()) but before it is destroyed. */
void
udpif_synchronize(struct udpif *udpif)
{
/* This is stronger than necessary. It would be sufficient to ensure
* (somehow) that each handler and revalidator thread had passed through
* its main loop once. */
size_t n_handlers = udpif->n_handlers;
size_t n_revalidators = udpif->n_revalidators;
ovsrcu_quiesce_start();
udpif_stop_threads(udpif);
udpif_start_threads(udpif, n_handlers, n_revalidators);
ovsrcu_quiesce_end();
}
/* Notifies 'udpif' that something changed which may render previous
* xlate_actions() results invalid. */
void
udpif_revalidate(struct udpif *udpif)
{
seq_change(udpif->reval_seq);
}
/* Returns a seq which increments every time 'udpif' pulls stats from the
* datapath. Callers can use this to get a sense of when might be a good time
* to do periodic work which relies on relatively up to date statistics. */
struct seq *
udpif_dump_seq(struct udpif *udpif)
{
return udpif->dump_seq;
}
void
udpif_get_memory_usage(struct udpif *udpif, struct simap *usage)
{
size_t i;
simap_increase(usage, "handlers", udpif->n_handlers);
simap_increase(usage, "revalidators", udpif->n_revalidators);
for (i = 0; i < N_UMAPS; i++) {
simap_increase(usage, "udpif keys", cmap_count(&udpif->ukeys[i].cmap));
}
}
/* Remove flows from a single datapath. */
void
udpif_flush(struct udpif *udpif)
{
size_t n_handlers, n_revalidators;
n_handlers = udpif->n_handlers;
n_revalidators = udpif->n_revalidators;
ovsrcu_quiesce_start();
udpif_stop_threads(udpif);
dpif_flow_flush(udpif->dpif);
udpif_start_threads(udpif, n_handlers, n_revalidators);
ovsrcu_quiesce_end();
}
/* Removes all flows from all datapaths. */
static void
udpif_flush_all_datapaths(void)
{
struct udpif *udpif;
LIST_FOR_EACH (udpif, list_node, &all_udpifs) {
udpif_flush(udpif);
}
}
static bool
udpif_use_ufid(struct udpif *udpif)
{
bool enable;
atomic_read_relaxed(&enable_ufid, &enable);
return enable && ofproto_dpif_get_enable_ufid(udpif->backer);
}
static unsigned long
udpif_get_n_flows(struct udpif *udpif)
{
long long int time, now;
unsigned long flow_count;
now = time_msec();
atomic_read_relaxed(&udpif->n_flows_timestamp, &time);
if (time < now - 100 && !ovs_mutex_trylock(&udpif->n_flows_mutex)) {
struct dpif_dp_stats stats;
atomic_store_relaxed(&udpif->n_flows_timestamp, now);
dpif_get_dp_stats(udpif->dpif, &stats);
flow_count = stats.n_flows;
atomic_store_relaxed(&udpif->n_flows, flow_count);
ovs_mutex_unlock(&udpif->n_flows_mutex);
} else {
atomic_read_relaxed(&udpif->n_flows, &flow_count);
}
return flow_count;
}
/* The upcall handler thread tries to read a batch of UPCALL_MAX_BATCH
* upcalls from dpif, processes the batch and installs corresponding flows
* in dpif. */
static void *
udpif_upcall_handler(void *arg)
{
struct handler *handler = arg;
struct udpif *udpif = handler->udpif;
while (!latch_is_set(&handler->udpif->exit_latch)) {
if (recv_upcalls(handler)) {
poll_immediate_wake();
} else {
dpif_recv_wait(udpif->dpif, handler->handler_id);
latch_wait(&udpif->exit_latch);
}
poll_block();
}
return NULL;
}
static size_t
recv_upcalls(struct handler *handler)
{
struct udpif *udpif = handler->udpif;
uint64_t recv_stubs[UPCALL_MAX_BATCH][512 / 8];
struct ofpbuf recv_bufs[UPCALL_MAX_BATCH];
struct dpif_upcall dupcalls[UPCALL_MAX_BATCH];
struct upcall upcalls[UPCALL_MAX_BATCH];
struct flow flows[UPCALL_MAX_BATCH];
size_t n_upcalls, i;
n_upcalls = 0;
while (n_upcalls < UPCALL_MAX_BATCH) {
struct ofpbuf *recv_buf = &recv_bufs[n_upcalls];
struct dpif_upcall *dupcall = &dupcalls[n_upcalls];
struct upcall *upcall = &upcalls[n_upcalls];
struct flow *flow = &flows[n_upcalls];
unsigned int mru;
int error;
ofpbuf_use_stub(recv_buf, recv_stubs[n_upcalls],
sizeof recv_stubs[n_upcalls]);
if (dpif_recv(udpif->dpif, handler->handler_id, dupcall, recv_buf)) {
ofpbuf_uninit(recv_buf);
break;
}
if (odp_flow_key_to_flow(dupcall->key, dupcall->key_len, flow)
== ODP_FIT_ERROR) {
goto free_dupcall;
}
if (dupcall->mru) {
mru = nl_attr_get_u16(dupcall->mru);
} else {
mru = 0;
}
error = upcall_receive(upcall, udpif->backer, &dupcall->packet,
dupcall->type, dupcall->userdata, flow, mru,
&dupcall->ufid, PMD_ID_NULL);
if (error) {
if (error == ENODEV) {
/* Received packet on datapath port for which we couldn't
* associate an ofproto. This can happen if a port is removed
* while traffic is being received. Print a rate-limited
* message in case it happens frequently. */
dpif_flow_put(udpif->dpif, DPIF_FP_CREATE, dupcall->key,
dupcall->key_len, NULL, 0, NULL, 0,
&dupcall->ufid, PMD_ID_NULL, NULL);
VLOG_INFO_RL(&rl, "received packet on unassociated datapath "
"port %"PRIu32, flow->in_port.odp_port);
}
goto free_dupcall;
}
upcall->key = dupcall->key;
upcall->key_len = dupcall->key_len;
upcall->ufid = &dupcall->ufid;
upcall->out_tun_key = dupcall->out_tun_key;
upcall->actions = dupcall->actions;
pkt_metadata_from_flow(&dupcall->packet.md, flow);
flow_extract(&dupcall->packet, flow);
error = process_upcall(udpif, upcall,
&upcall->odp_actions, &upcall->wc);
if (error) {
goto cleanup;
}
n_upcalls++;
continue;
cleanup:
upcall_uninit(upcall);
free_dupcall:
dp_packet_uninit(&dupcall->packet);
ofpbuf_uninit(recv_buf);
}
if (n_upcalls) {
handle_upcalls(handler->udpif, upcalls, n_upcalls);
for (i = 0; i < n_upcalls; i++) {
dp_packet_uninit(&dupcalls[i].packet);
ofpbuf_uninit(&recv_bufs[i]);
upcall_uninit(&upcalls[i]);
}
}
return n_upcalls;
}
static void *
udpif_revalidator(void *arg)
{
/* Used by all revalidators. */
struct revalidator *revalidator = arg;
struct udpif *udpif = revalidator->udpif;
bool leader = revalidator == &udpif->revalidators[0];
/* Used only by the leader. */
long long int start_time = 0;
uint64_t last_reval_seq = 0;
size_t n_flows = 0;
revalidator->id = ovsthread_id_self();
for (;;) {
if (leader) {
uint64_t reval_seq;
recirc_run(); /* Recirculation cleanup. */
reval_seq = seq_read(udpif->reval_seq);
last_reval_seq = reval_seq;
n_flows = udpif_get_n_flows(udpif);
udpif->max_n_flows = MAX(n_flows, udpif->max_n_flows);
udpif->avg_n_flows = (udpif->avg_n_flows + n_flows) / 2;
/* Only the leader checks the pause latch to prevent a race where
* some threads think it's false and proceed to block on
* reval_barrier and others think it's true and block indefinitely
* on the pause_barrier */
udpif->pause = latch_is_set(&udpif->pause_latch);
/* Only the leader checks the exit latch to prevent a race where
* some threads think it's true and exit and others think it's
* false and block indefinitely on the reval_barrier */
udpif->reval_exit = latch_is_set(&udpif->exit_latch);
start_time = time_msec();
if (!udpif->reval_exit) {
bool terse_dump;
terse_dump = udpif_use_ufid(udpif);
udpif->dump = dpif_flow_dump_create(udpif->dpif, terse_dump);
}
}
/* Wait for the leader to start the flow dump. */
ovs_barrier_block(&udpif->reval_barrier);
if (udpif->pause) {
revalidator_pause(revalidator);
}
if (udpif->reval_exit) {
break;
}
revalidate(revalidator);
/* Wait for all flows to have been dumped before we garbage collect. */
ovs_barrier_block(&udpif->reval_barrier);
revalidator_sweep(revalidator);
/* Wait for all revalidators to finish garbage collection. */
ovs_barrier_block(&udpif->reval_barrier);
if (leader) {
unsigned int flow_limit;
long long int duration;
atomic_read_relaxed(&udpif->flow_limit, &flow_limit);
dpif_flow_dump_destroy(udpif->dump);
seq_change(udpif->dump_seq);
duration = MAX(time_msec() - start_time, 1);
udpif->dump_duration = duration;
if (duration > 2000) {
flow_limit /= duration / 1000;
} else if (duration > 1300) {
flow_limit = flow_limit * 3 / 4;
} else if (duration < 1000 && n_flows > 2000
&& flow_limit < n_flows * 1000 / duration) {
flow_limit += 1000;
}
flow_limit = MIN(ofproto_flow_limit, MAX(flow_limit, 1000));
atomic_store_relaxed(&udpif->flow_limit, flow_limit);
if (duration > 2000) {
VLOG_INFO("Spent an unreasonably long %lldms dumping flows",
duration);
}
poll_timer_wait_until(start_time + MIN(ofproto_max_idle, 500));
seq_wait(udpif->reval_seq, last_reval_seq);
latch_wait(&udpif->exit_latch);
latch_wait(&udpif->pause_latch);
poll_block();
}
}
return NULL;
}
static enum upcall_type
classify_upcall(enum dpif_upcall_type type, const struct nlattr *userdata)
{
union user_action_cookie cookie;
size_t userdata_len;
/* First look at the upcall type. */
switch (type) {
case DPIF_UC_ACTION:
break;
case DPIF_UC_MISS:
return MISS_UPCALL;
case DPIF_N_UC_TYPES:
default:
VLOG_WARN_RL(&rl, "upcall has unexpected type %"PRIu32, type);
return BAD_UPCALL;
}
/* "action" upcalls need a closer look. */
if (!userdata) {
VLOG_WARN_RL(&rl, "action upcall missing cookie");
return BAD_UPCALL;
}
userdata_len = nl_attr_get_size(userdata);
if (userdata_len < sizeof cookie.type
|| userdata_len > sizeof cookie) {
VLOG_WARN_RL(&rl, "action upcall cookie has unexpected size %"PRIuSIZE,
userdata_len);
return BAD_UPCALL;
}
memset(&cookie, 0, sizeof cookie);
memcpy(&cookie, nl_attr_get(userdata), userdata_len);
if (userdata_len == MAX(8, sizeof cookie.sflow)
&& cookie.type == USER_ACTION_COOKIE_SFLOW) {
return SFLOW_UPCALL;
} else if (userdata_len == MAX(8, sizeof cookie.slow_path)
&& cookie.type == USER_ACTION_COOKIE_SLOW_PATH) {
return MISS_UPCALL;
} else if (userdata_len == MAX(8, sizeof cookie.flow_sample)
&& cookie.type == USER_ACTION_COOKIE_FLOW_SAMPLE) {
return FLOW_SAMPLE_UPCALL;
} else if (userdata_len == MAX(8, sizeof cookie.ipfix)
&& cookie.type == USER_ACTION_COOKIE_IPFIX) {
return IPFIX_UPCALL;
} else {
VLOG_WARN_RL(&rl, "invalid user cookie of type %"PRIu16
" and size %"PRIuSIZE, cookie.type, userdata_len);
return BAD_UPCALL;
}
}
/* Calculates slow path actions for 'xout'. 'buf' must statically be
* initialized with at least 128 bytes of space. */
static void
compose_slow_path(struct udpif *udpif, struct xlate_out *xout,
const struct flow *flow, odp_port_t odp_in_port,
struct ofpbuf *buf)
{
union user_action_cookie cookie;
odp_port_t port;
uint32_t pid;
cookie.type = USER_ACTION_COOKIE_SLOW_PATH;
cookie.slow_path.unused = 0;
cookie.slow_path.reason = xout->slow;
port = xout->slow & (SLOW_CFM | SLOW_BFD | SLOW_LACP | SLOW_STP)
? ODPP_NONE
: odp_in_port;
pid = dpif_port_get_pid(udpif->dpif, port, flow_hash_5tuple(flow, 0));
odp_put_userspace_action(pid, &cookie, sizeof cookie.slow_path,
ODPP_NONE, false, buf);
}
/* If there is no error, the upcall must be destroyed with upcall_uninit()
* before quiescing, as the referred objects are guaranteed to exist only
* until the calling thread quiesces. Otherwise, do not call upcall_uninit()
* since the 'upcall->put_actions' remains uninitialized. */
static int
upcall_receive(struct upcall *upcall, const struct dpif_backer *backer,
const struct dp_packet *packet, enum dpif_upcall_type type,
const struct nlattr *userdata, const struct flow *flow,
const unsigned int mru,
const ovs_u128 *ufid, const unsigned pmd_id)
{
int error;
error = xlate_lookup(backer, flow, &upcall->ofproto, &upcall->ipfix,
&upcall->sflow, NULL, &upcall->in_port);
if (error) {
return error;
}
upcall->recirc = NULL;
upcall->have_recirc_ref = false;
upcall->flow = flow;
upcall->packet = packet;
upcall->ufid = ufid;
upcall->pmd_id = pmd_id;
upcall->type = type;
upcall->userdata = userdata;
ofpbuf_use_stub(&upcall->odp_actions, upcall->odp_actions_stub,
sizeof upcall->odp_actions_stub);
ofpbuf_init(&upcall->put_actions, 0);
upcall->xout_initialized = false;
upcall->ukey_persists = false;
upcall->ukey = NULL;
upcall->key = NULL;
upcall->key_len = 0;
upcall->mru = mru;
upcall->out_tun_key = NULL;
upcall->actions = NULL;
return 0;
}
static void
upcall_xlate(struct udpif *udpif, struct upcall *upcall,
struct ofpbuf *odp_actions, struct flow_wildcards *wc)
{
struct dpif_flow_stats stats;
struct xlate_in xin;
stats.n_packets = 1;
stats.n_bytes = dp_packet_size(upcall->packet);
stats.used = time_msec();
stats.tcp_flags = ntohs(upcall->flow->tcp_flags);
xlate_in_init(&xin, upcall->ofproto, upcall->flow, upcall->in_port, NULL,
stats.tcp_flags, upcall->packet, wc, odp_actions);
if (upcall->type == DPIF_UC_MISS) {
xin.resubmit_stats = &stats;
if (xin.frozen_state) {
/* We may install a datapath flow only if we get a reference to the
* recirculation context (otherwise we could have recirculation
* upcalls using recirculation ID for which no context can be
* found). We may still execute the flow's actions even if we
* don't install the flow. */
upcall->recirc = recirc_id_node_from_state(xin.frozen_state);
upcall->have_recirc_ref = recirc_id_node_try_ref_rcu(upcall->recirc);
}
} else {
/* For non-miss upcalls, we are either executing actions (one of which
* is an userspace action) for an upcall, in which case the stats have
* already been taken care of, or there's a flow in the datapath which
* this packet was accounted to. Presumably the revalidators will deal
* with pushing its stats eventually. */
}
upcall->dump_seq = seq_read(udpif->dump_seq);
upcall->reval_seq = seq_read(udpif->reval_seq);
xlate_actions(&xin, &upcall->xout);
if (wc) {
/* Convert the input port wildcard from OFP to ODP format. There's no
* real way to do this for arbitrary bitmasks since the numbering spaces
* aren't the same. However, flow translation always exact matches the
* whole thing, so we can do the same here. */
WC_MASK_FIELD(wc, in_port.odp_port);
}
upcall->xout_initialized = true;
if (!upcall->xout.slow) {
ofpbuf_use_const(&upcall->put_actions,
odp_actions->data, odp_actions->size);
} else {
/* upcall->put_actions already initialized by upcall_receive(). */
compose_slow_path(udpif, &upcall->xout, upcall->flow,
upcall->flow->in_port.odp_port,
&upcall->put_actions);
}
/* This function is also called for slow-pathed flows. As we are only
* going to create new datapath flows for actual datapath misses, there is
* no point in creating a ukey otherwise. */
if (upcall->type == DPIF_UC_MISS) {
upcall->ukey = ukey_create_from_upcall(upcall, wc);
}
}
static void
upcall_uninit(struct upcall *upcall)
{
if (upcall) {
if (upcall->xout_initialized) {
xlate_out_uninit(&upcall->xout);
}
ofpbuf_uninit(&upcall->odp_actions);
ofpbuf_uninit(&upcall->put_actions);
if (upcall->ukey) {
if (!upcall->ukey_persists) {
ukey_delete__(upcall->ukey);
}
} else if (upcall->have_recirc_ref) {
/* The reference was transferred to the ukey if one was created. */
recirc_id_node_unref(upcall->recirc);
}
}
}
static int
upcall_cb(const struct dp_packet *packet, const struct flow *flow, ovs_u128 *ufid,
unsigned pmd_id, enum dpif_upcall_type type,
const struct nlattr *userdata, struct ofpbuf *actions,
struct flow_wildcards *wc, struct ofpbuf *put_actions, void *aux)
{
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1);
struct udpif *udpif = aux;
unsigned int flow_limit;
struct upcall upcall;
bool megaflow;
int error;
atomic_read_relaxed(&enable_megaflows, &megaflow);
atomic_read_relaxed(&udpif->flow_limit, &flow_limit);
error = upcall_receive(&upcall, udpif->backer, packet, type, userdata,
flow, 0, ufid, pmd_id);
if (error) {
return error;
}
error = process_upcall(udpif, &upcall, actions, wc);
if (error) {
goto out;
}
if (upcall.xout.slow && put_actions) {
ofpbuf_put(put_actions, upcall.put_actions.data,
upcall.put_actions.size);
}
if (OVS_UNLIKELY(!megaflow)) {
flow_wildcards_init_for_packet(wc, flow);
}
if (udpif_get_n_flows(udpif) >= flow_limit) {
VLOG_WARN_RL(&rl, "upcall_cb failure: datapath flow limit reached");
error = ENOSPC;
goto out;
}
/* Prevent miss flow installation if the key has recirculation ID but we
* were not able to get a reference on it. */
if (type == DPIF_UC_MISS && upcall.recirc && !upcall.have_recirc_ref) {
VLOG_WARN_RL(&rl, "upcall_cb failure: no reference for recirc flow");
error = ENOSPC;
goto out;
}
if (upcall.ukey && !ukey_install(udpif, upcall.ukey)) {
VLOG_WARN_RL(&rl, "upcall_cb failure: ukey installation fails");
error = ENOSPC;
}
out:
if (!error) {
upcall.ukey_persists = true;
}
upcall_uninit(&upcall);
return error;
}
static int
process_upcall(struct udpif *udpif, struct upcall *upcall,
struct ofpbuf *odp_actions, struct flow_wildcards *wc)
{
const struct nlattr *userdata = upcall->userdata;
const struct dp_packet *packet = upcall->packet;
const struct flow *flow = upcall->flow;
switch (classify_upcall(upcall->type, userdata)) {
case MISS_UPCALL:
upcall_xlate(udpif, upcall, odp_actions, wc);
return 0;
case SFLOW_UPCALL:
if (upcall->sflow) {
union user_action_cookie cookie;
const struct nlattr *actions;
size_t actions_len = 0;
struct dpif_sflow_actions sflow_actions;
memset(&sflow_actions, 0, sizeof sflow_actions);
memset(&cookie, 0, sizeof cookie);
memcpy(&cookie, nl_attr_get(userdata), sizeof cookie.sflow);
if (upcall->actions) {
/* Actions were passed up from datapath. */
actions = nl_attr_get(upcall->actions);
actions_len = nl_attr_get_size(upcall->actions);
if (actions && actions_len) {
dpif_sflow_read_actions(flow, actions, actions_len,
&sflow_actions);
}
}
if (actions_len == 0) {
/* Lookup actions in userspace cache. */
struct udpif_key *ukey = ukey_lookup(udpif, upcall->ufid,
upcall->pmd_id);
if (ukey) {
ukey_get_actions(ukey, &actions, &actions_len);
dpif_sflow_read_actions(flow, actions, actions_len,
&sflow_actions);
}
}
dpif_sflow_received(upcall->sflow, packet, flow,
flow->in_port.odp_port, &cookie,
actions_len > 0 ? &sflow_actions : NULL);
}
break;
case IPFIX_UPCALL:
if (upcall->ipfix) {
union user_action_cookie cookie;
struct flow_tnl output_tunnel_key;
memset(&cookie, 0, sizeof cookie);
memcpy(&cookie, nl_attr_get(userdata), sizeof cookie.ipfix);
if (upcall->out_tun_key) {
odp_tun_key_from_attr(upcall->out_tun_key, false,
&output_tunnel_key);
}
dpif_ipfix_bridge_sample(upcall->ipfix, packet, flow,
flow->in_port.odp_port,
cookie.ipfix.output_odp_port,
upcall->out_tun_key ?
&output_tunnel_key : NULL);
}
break;
case FLOW_SAMPLE_UPCALL:
if (upcall->ipfix) {
union user_action_cookie cookie;
struct flow_tnl output_tunnel_key;
memset(&cookie, 0, sizeof cookie);
memcpy(&cookie, nl_attr_get(userdata), sizeof cookie.flow_sample);
if (upcall->out_tun_key) {
odp_tun_key_from_attr(upcall->out_tun_key, false,
&output_tunnel_key);
}
/* The flow reflects exactly the contents of the packet.
* Sample the packet using it. */
dpif_ipfix_flow_sample(upcall->ipfix, packet, flow,
&cookie, flow->in_port.odp_port,
upcall->out_tun_key ?
&output_tunnel_key : NULL);
}
break;
case BAD_UPCALL:
break;
}
return EAGAIN;
}
static void
handle_upcalls(struct udpif *udpif, struct upcall *upcalls,
size_t n_upcalls)
{
struct dpif_op *opsp[UPCALL_MAX_BATCH * 2];
struct ukey_op ops[UPCALL_MAX_BATCH * 2];
unsigned int flow_limit;
size_t n_ops, n_opsp, i;
bool may_put;
atomic_read_relaxed(&udpif->flow_limit, &flow_limit);
may_put = udpif_get_n_flows(udpif) < flow_limit;
/* Handle the packets individually in order of arrival.
*
* - For SLOW_CFM, SLOW_LACP, SLOW_STP, and SLOW_BFD, translation is what
* processes received packets for these protocols.
*
* - For SLOW_CONTROLLER, translation sends the packet to the OpenFlow
* controller.
*
* The loop fills 'ops' with an array of operations to execute in the
* datapath. */
n_ops = 0;
for (i = 0; i < n_upcalls; i++) {
struct upcall *upcall = &upcalls[i];
const struct dp_packet *packet = upcall->packet;
struct ukey_op *op;
/* Do not install a flow into the datapath if:
*
* - The datapath already has too many flows.
*
* - We received this packet via some flow installed in the kernel
* already.
*
* - Upcall was a recirculation but we do not have a reference to
* to the recirculation ID. */
if (may_put && upcall->type == DPIF_UC_MISS &&
(!upcall->recirc || upcall->have_recirc_ref)) {
struct udpif_key *ukey = upcall->ukey;
upcall->ukey_persists = true;
op = &ops[n_ops++];
op->ukey = ukey;
op->dop.type = DPIF_OP_FLOW_PUT;
op->dop.u.flow_put.flags = DPIF_FP_CREATE;
op->dop.u.flow_put.key = ukey->key;
op->dop.u.flow_put.key_len = ukey->key_len;
op->dop.u.flow_put.mask = ukey->mask;
op->dop.u.flow_put.mask_len = ukey->mask_len;
op->dop.u.flow_put.ufid = upcall->ufid;
op->dop.u.flow_put.stats = NULL;
ukey_get_actions(ukey, &op->dop.u.flow_put.actions,
&op->dop.u.flow_put.actions_len);
}
if (upcall->odp_actions.size) {
op = &ops[n_ops++];
op->ukey = NULL;
op->dop.type = DPIF_OP_EXECUTE;
op->dop.u.execute.packet = CONST_CAST(struct dp_packet *, packet);
op->dop.u.execute.flow = upcall->flow;
odp_key_to_pkt_metadata(upcall->key, upcall->key_len,
&op->dop.u.execute.packet->md);
op->dop.u.execute.actions = upcall->odp_actions.data;
op->dop.u.execute.actions_len = upcall->odp_actions.size;
op->dop.u.execute.needs_help = (upcall->xout.slow & SLOW_ACTION) != 0;
op->dop.u.execute.probe = false;
op->dop.u.execute.mtu = upcall->mru;
}
}
/* Execute batch.
*
* We install ukeys before installing the flows, locking them for exclusive
* access by this thread for the period of installation. This ensures that
* other threads won't attempt to delete the flows as we are creating them.
*/
n_opsp = 0;
for (i = 0; i < n_ops; i++) {
struct udpif_key *ukey = ops[i].ukey;
if (ukey) {
/* If we can't install the ukey, don't install the flow. */
if (!ukey_install_start(udpif, ukey)) {
ukey_delete__(ukey);
ops[i].ukey = NULL;
continue;
}
}
opsp[n_opsp++] = &ops[i].dop;
}
dpif_operate(udpif->dpif, opsp, n_opsp);
for (i = 0; i < n_ops; i++) {
if (ops[i].ukey) {
ukey_install_finish(ops[i].ukey, ops[i].dop.error);
}
}
}
static uint32_t
get_ukey_hash(const ovs_u128 *ufid, const unsigned pmd_id)
{
return hash_2words(ufid->u32[0], pmd_id);
}
static struct udpif_key *
ukey_lookup(struct udpif *udpif, const ovs_u128 *ufid, const unsigned pmd_id)
{
struct udpif_key *ukey;
int idx = get_ukey_hash(ufid, pmd_id) % N_UMAPS;
struct cmap *cmap = &udpif->ukeys[idx].cmap;
CMAP_FOR_EACH_WITH_HASH (ukey, cmap_node,
get_ukey_hash(ufid, pmd_id), cmap) {
if (ovs_u128_equals(ukey->ufid, *ufid)) {
return ukey;
}
}
return NULL;
}
/* Provides safe lockless access of RCU protected 'ukey->actions'. Callers may
* alternatively access the field directly if they take 'ukey->mutex'. */
static void
ukey_get_actions(struct udpif_key *ukey, const struct nlattr **actions, size_t *size)
{
const struct ofpbuf *buf = ovsrcu_get(struct ofpbuf *, &ukey->actions);
*actions = buf->data;
*size = buf->size;
}
static void
ukey_set_actions(struct udpif_key *ukey, const struct ofpbuf *actions)
{
ovsrcu_postpone(ofpbuf_delete,
ovsrcu_get_protected(struct ofpbuf *, &ukey->actions));
ovsrcu_set(&ukey->actions, ofpbuf_clone(actions));
}
static struct udpif_key *
ukey_create__(const struct nlattr *key, size_t key_len,
const struct nlattr *mask, size_t mask_len,
bool ufid_present, const ovs_u128 *ufid,
const unsigned pmd_id, const struct ofpbuf *actions,
uint64_t dump_seq, uint64_t reval_seq, long long int used,
uint32_t key_recirc_id, struct xlate_out *xout)
OVS_NO_THREAD_SAFETY_ANALYSIS
{
struct udpif_key *ukey = xmalloc(sizeof *ukey);
memcpy(&ukey->keybuf, key, key_len);
ukey->key = &ukey->keybuf.nla;
ukey->key_len = key_len;
memcpy(&ukey->maskbuf, mask, mask_len);
ukey->mask = &ukey->maskbuf.nla;
ukey->mask_len = mask_len;
ukey->ufid_present = ufid_present;
ukey->ufid = *ufid;
ukey->pmd_id = pmd_id;
ukey->hash = get_ukey_hash(&ukey->ufid, pmd_id);
ovsrcu_init(&ukey->actions, NULL);
ukey_set_actions(ukey, actions);
ovs_mutex_init(&ukey->mutex);
ukey->dump_seq = dump_seq;
ukey->reval_seq = reval_seq;
ukey->flow_exists = false;
ukey->created = time_msec();
memset(&ukey->stats, 0, sizeof ukey->stats);
ukey->stats.used = used;
ukey->xcache = NULL;
ukey->key_recirc_id = key_recirc_id;
recirc_refs_init(&ukey->recircs);
if (xout) {
/* Take ownership of the action recirc id references. */
recirc_refs_swap(&ukey->recircs, &xout->recircs);
}
return ukey;
}
static struct udpif_key *
ukey_create_from_upcall(struct upcall *upcall, struct flow_wildcards *wc)
{
struct odputil_keybuf keystub, maskstub;
struct ofpbuf keybuf, maskbuf;
bool megaflow;
struct odp_flow_key_parms odp_parms = {
.flow = upcall->flow,
.mask = &wc->masks,
};
odp_parms.support = ofproto_dpif_get_support(upcall->ofproto)->odp;
if (upcall->key_len) {
ofpbuf_use_const(&keybuf, upcall->key, upcall->key_len);
} else {
/* dpif-netdev doesn't provide a netlink-formatted flow key in the
* upcall, so convert the upcall's flow here. */
ofpbuf_use_stack(&keybuf, &keystub, sizeof keystub);
odp_flow_key_from_flow(&odp_parms, &keybuf);
}
atomic_read_relaxed(&enable_megaflows, &megaflow);
ofpbuf_use_stack(&maskbuf, &maskstub, sizeof maskstub);
if (megaflow) {
odp_parms.key_buf = &keybuf;
odp_flow_key_from_mask(&odp_parms, &maskbuf);
}
return ukey_create__(keybuf.data, keybuf.size, maskbuf.data, maskbuf.size,
true, upcall->ufid, upcall->pmd_id,
&upcall->put_actions, upcall->dump_seq,
upcall->reval_seq, 0,
upcall->have_recirc_ref ? upcall->recirc->id : 0,
&upcall->xout);
}
static int
ukey_create_from_dpif_flow(const struct udpif *udpif,
const struct dpif_flow *flow,
struct udpif_key **ukey)
{
struct dpif_flow full_flow;
struct ofpbuf actions;
uint64_t dump_seq, reval_seq;
uint64_t stub[DPIF_FLOW_BUFSIZE / 8];
const struct nlattr *a;
unsigned int left;
if (!flow->key_len || !flow->actions_len) {
struct ofpbuf buf;
int err;
/* If the key or actions were not provided by the datapath, fetch the
* full flow. */
ofpbuf_use_stack(&buf, &stub, sizeof stub);
err = dpif_flow_get(udpif->dpif, flow->key, flow->key_len,
flow->ufid_present ? &flow->ufid : NULL,
flow->pmd_id, &buf, &full_flow);
if (err) {
return err;
}
flow = &full_flow;
}
/* Check the flow actions for recirculation action. As recirculation
* relies on OVS userspace internal state, we need to delete all old
* datapath flows with either a non-zero recirc_id in the key, or any
* recirculation actions upon OVS restart. */
NL_ATTR_FOR_EACH_UNSAFE (a, left, flow->key, flow->key_len) {
if (nl_attr_type(a) == OVS_KEY_ATTR_RECIRC_ID
&& nl_attr_get_u32(a) != 0) {
return EINVAL;
}
}
NL_ATTR_FOR_EACH_UNSAFE (a, left, flow->actions, flow->actions_len) {
if (nl_attr_type(a) == OVS_ACTION_ATTR_RECIRC) {
return EINVAL;
}
}
dump_seq = seq_read(udpif->dump_seq);
reval_seq = seq_read(udpif->reval_seq);
ofpbuf_use_const(&actions, &flow->actions, flow->actions_len);
*ukey = ukey_create__(flow->key, flow->key_len,
flow->mask, flow->mask_len, flow->ufid_present,
&flow->ufid, flow->pmd_id, &actions, dump_seq,
reval_seq, flow->stats.used, 0, NULL);
return 0;
}
/* Attempts to insert a ukey into the shared ukey maps.
*
* On success, returns true, installs the ukey and returns it in a locked
* state. Otherwise, returns false. */
static bool
ukey_install_start(struct udpif *udpif, struct udpif_key *new_ukey)
OVS_TRY_LOCK(true, new_ukey->mutex)
{
struct umap *umap;
struct udpif_key *old_ukey;
uint32_t idx;
bool locked = false;
idx = new_ukey->hash % N_UMAPS;
umap = &udpif->ukeys[idx];
ovs_mutex_lock(&umap->mutex);
old_ukey = ukey_lookup(udpif, &new_ukey->ufid, new_ukey->pmd_id);
if (old_ukey) {
/* Uncommon case: A ukey is already installed with the same UFID. */
if (old_ukey->key_len == new_ukey->key_len
&& !memcmp(old_ukey->key, new_ukey->key, new_ukey->key_len)) {
COVERAGE_INC(handler_duplicate_upcall);
} else {
struct ds ds = DS_EMPTY_INITIALIZER;
odp_format_ufid(&old_ukey->ufid, &ds);
ds_put_cstr(&ds, " ");
odp_flow_key_format(old_ukey->key, old_ukey->key_len, &ds);
ds_put_cstr(&ds, "\n");
odp_format_ufid(&new_ukey->ufid, &ds);
ds_put_cstr(&ds, " ");
odp_flow_key_format(new_ukey->key, new_ukey->key_len, &ds);
VLOG_WARN_RL(&rl, "Conflicting ukey for flows:\n%s", ds_cstr(&ds));
ds_destroy(&ds);
}
} else {
ovs_mutex_lock(&new_ukey->mutex);
cmap_insert(&umap->cmap, &new_ukey->cmap_node, new_ukey->hash);
locked = true;
}
ovs_mutex_unlock(&umap->mutex);
return locked;
}
static void
ukey_install_finish__(struct udpif_key *ukey) OVS_REQUIRES(ukey->mutex)
{
ukey->flow_exists = true;
}
static bool
ukey_install_finish(struct udpif_key *ukey, int error)
OVS_RELEASES(ukey->mutex)
{
if (!error) {
ukey_install_finish__(ukey);
}
ovs_mutex_unlock(&ukey->mutex);
return !error;
}
static bool
ukey_install(struct udpif *udpif, struct udpif_key *ukey)
{
/* The usual way to keep 'ukey->flow_exists' in sync with the datapath is
* to call ukey_install_start(), install the corresponding datapath flow,
* then call ukey_install_finish(). The netdev interface using upcall_cb()
* doesn't provide a function to separately finish the flow installation,
* so we perform the operations together here.
*
* This is fine currently, as revalidator threads will only delete this
* ukey during revalidator_sweep() and only if the dump_seq is mismatched.
* It is unlikely for a revalidator thread to advance dump_seq and reach
* the next GC phase between ukey creation and flow installation. */
return ukey_install_start(udpif, ukey) && ukey_install_finish(ukey, 0);
}
/* Searches for a ukey in 'udpif->ukeys' that matches 'flow' and attempts to
* lock the ukey. If the ukey does not exist, create it.
*
* Returns 0 on success, setting *result to the matching ukey and returning it
* in a locked state. Otherwise, returns an errno and clears *result. EBUSY
* indicates that another thread is handling this flow. Other errors indicate
* an unexpected condition creating a new ukey.
*
* *error is an output parameter provided to appease the threadsafety analyser,
* and its value matches the return value. */
static int
ukey_acquire(struct udpif *udpif, const struct dpif_flow *flow,
struct udpif_key **result, int *error)
OVS_TRY_LOCK(0, (*result)->mutex)
{
struct udpif_key *ukey;
int retval;
ukey = ukey_lookup(udpif, &flow->ufid, flow->pmd_id);
if (ukey) {
retval = ovs_mutex_trylock(&ukey->mutex);
} else {
/* Usually we try to avoid installing flows from revalidator threads,
* because locking on a umap may cause handler threads to block.
* However there are certain cases, like when ovs-vswitchd is
* restarted, where it is desirable to handle flows that exist in the
* datapath gracefully (ie, don't just clear the datapath). */
bool install;
retval = ukey_create_from_dpif_flow(udpif, flow, &ukey);
if (retval) {
goto done;
}
install = ukey_install_start(udpif, ukey);
if (install) {
ukey_install_finish__(ukey);
retval = 0;
} else {
ukey_delete__(ukey);
retval = EBUSY;
}
}
done:
*error = retval;
if (retval) {
*result = NULL;
} else {
*result = ukey;
}
return retval;
}
static void
ukey_delete__(struct udpif_key *ukey)
OVS_NO_THREAD_SAFETY_ANALYSIS
{
if (ukey) {
if (ukey->key_recirc_id) {
recirc_free_id(ukey->key_recirc_id);
}
recirc_refs_unref(&ukey->recircs);
xlate_cache_delete(ukey->xcache);
ofpbuf_delete(ovsrcu_get(struct ofpbuf *, &ukey->actions));
ovs_mutex_destroy(&ukey->mutex);
free(ukey);
}
}
static void
ukey_delete(struct umap *umap, struct udpif_key *ukey)
OVS_REQUIRES(umap->mutex)
{
cmap_remove(&umap->cmap, &ukey->cmap_node, ukey->hash);
ovsrcu_postpone(ukey_delete__, ukey);
}
static bool
should_revalidate(const struct udpif *udpif, uint64_t packets,
long long int used)
{
long long int metric, now, duration;
if (udpif->dump_duration < 200) {
/* We are likely to handle full revalidation for the flows. */
return true;
}
/* Calculate the mean time between seeing these packets. If this
* exceeds the threshold, then delete the flow rather than performing
* costly revalidation for flows that aren't being hit frequently.
*
* This is targeted at situations where the dump_duration is high (~1s),
* and revalidation is triggered by a call to udpif_revalidate(). In
* these situations, revalidation of all flows causes fluctuations in the
* flow_limit due to the interaction with the dump_duration and max_idle.
* This tends to result in deletion of low-throughput flows anyway, so
* skip the revalidation and just delete those flows. */
packets = MAX(packets, 1);
now = MAX(used, time_msec());
duration = now - used;
metric = duration / packets;
if (metric < 200) {
/* The flow is receiving more than ~5pps, so keep it. */
return true;
}
return false;
}
/* Verifies that the datapath actions of 'ukey' are still correct, and pushes
* 'stats' for it.
*
* Returns a recommended action for 'ukey', options include:
* UKEY_DELETE The ukey should be deleted.
* UKEY_KEEP The ukey is fine as is.
* UKEY_MODIFY The ukey's actions should be changed but is otherwise
* fine. Callers should change the actions to those found
* in the caller supplied 'odp_actions' buffer. The
* recirculation references can be found in 'recircs' and
* must be handled by the caller.
*
* If the result is UKEY_MODIFY, then references to all recirc_ids used by the
* new flow will be held within 'recircs' (which may be none).
*
* The caller is responsible for both initializing 'recircs' prior this call,
* and ensuring any references are eventually freed.
*/
static enum reval_result
revalidate_ukey(struct udpif *udpif, struct udpif_key *ukey,
const struct dpif_flow_stats *stats,
struct ofpbuf *odp_actions, uint64_t reval_seq,
struct recirc_refs *recircs)
OVS_REQUIRES(ukey->mutex)
{
struct xlate_out xout, *xoutp;
struct netflow *netflow;
struct ofproto_dpif *ofproto;
struct dpif_flow_stats push;
struct flow flow;
struct flow_wildcards dp_mask, wc;
enum reval_result result;
ofp_port_t ofp_in_port;
struct xlate_in xin;
long long int last_used;
int error;
bool need_revalidate;
result = UKEY_DELETE;
xoutp = NULL;
netflow = NULL;
ofpbuf_clear(odp_actions);
need_revalidate = (ukey->reval_seq != reval_seq);
last_used = ukey->stats.used;
push.used = stats->used;
push.tcp_flags = stats->tcp_flags;
push.n_packets = (stats->n_packets > ukey->stats.n_packets
? stats->n_packets - ukey->stats.n_packets
: 0);
push.n_bytes = (stats->n_bytes > ukey->stats.n_bytes
? stats->n_bytes - ukey->stats.n_bytes
: 0);
if (need_revalidate && last_used
&& !should_revalidate(udpif, push.n_packets, last_used)) {
goto exit;
}
/* We will push the stats, so update the ukey stats cache. */
ukey->stats = *stats;
if (!push.n_packets && !need_revalidate) {
result = UKEY_KEEP;
goto exit;
}
if (ukey->xcache && !need_revalidate) {
xlate_push_stats(ukey->xcache, &push);
result = UKEY_KEEP;
goto exit;
}
if (odp_flow_key_to_flow(ukey->key, ukey->key_len, &flow)
== ODP_FIT_ERROR) {
goto exit;
}
error = xlate_lookup(udpif->backer, &flow, &ofproto, NULL, NULL, &netflow,
&ofp_in_port);
if (error) {
goto exit;
}
if (need_revalidate) {
xlate_cache_clear(ukey->xcache);
}
if (!ukey->xcache) {
ukey->xcache = xlate_cache_new();
}
xlate_in_init(&xin, ofproto, &flow, ofp_in_port, NULL, push.tcp_flags,
NULL, need_revalidate ? &wc : NULL, odp_actions);
if (push.n_packets) {
xin.resubmit_stats = &push;
xin.may_learn = true;
}
xin.xcache = ukey->xcache;
xlate_actions(&xin, &xout);
xoutp = &xout;
if (!need_revalidate) {
result = UKEY_KEEP;
goto exit;
}
if (xout.slow) {
ofpbuf_clear(odp_actions);
compose_slow_path(udpif, &xout, &flow, flow.in_port.odp_port,
odp_actions);
}
if (odp_flow_key_to_mask(ukey->mask, ukey->mask_len, ukey->key,
ukey->key_len, &dp_mask, &flow)
== ODP_FIT_ERROR) {
goto exit;
}
/* Do not modify if any bit is wildcarded by the installed datapath flow,
* but not the newly revalidated wildcard mask (wc), i.e., if revalidation
* tells that the datapath flow is now too generic and must be narrowed
* down. Note that we do not know if the datapath has ignored any of the
* wildcarded bits, so we may be overtly conservative here. */
if (flow_wildcards_has_extra(&dp_mask, &wc)) {
goto exit;
}
if (!ofpbuf_equal(odp_actions,
ovsrcu_get(struct ofpbuf *, &ukey->actions))) {
/* The datapath mask was OK, but the actions seem to have changed.
* Let's modify it in place. */
result = UKEY_MODIFY;
/* Transfer recirc action ID references to the caller. */
recirc_refs_swap(recircs, &xoutp->recircs);
goto exit;
}
result = UKEY_KEEP;
exit:
if (result != UKEY_DELETE) {
ukey->reval_seq = reval_seq;
}
if (netflow && result == UKEY_DELETE) {
netflow_flow_clear(netflow, &flow);
}
xlate_out_uninit(xoutp);
return result;
}
static void
delete_op_init__(struct udpif *udpif, struct ukey_op *op,
const struct dpif_flow *flow)
{
op->ukey = NULL;
op->dop.type = DPIF_OP_FLOW_DEL;
op->dop.u.flow_del.key = flow->key;
op->dop.u.flow_del.key_len = flow->key_len;
op->dop.u.flow_del.ufid = flow->ufid_present ? &flow->ufid : NULL;
op->dop.u.flow_del.pmd_id = flow->pmd_id;
op->dop.u.flow_del.stats = &op->stats;
op->dop.u.flow_del.terse = udpif_use_ufid(udpif);
}
static void
delete_op_init(struct udpif *udpif, struct ukey_op *op, struct udpif_key *ukey)
{
op->ukey = ukey;
op->dop.type = DPIF_OP_FLOW_DEL;
op->dop.u.flow_del.key = ukey->key;
op->dop.u.flow_del.key_len = ukey->key_len;
op->dop.u.flow_del.ufid = ukey->ufid_present ? &ukey->ufid : NULL;
op->dop.u.flow_del.pmd_id = ukey->pmd_id;
op->dop.u.flow_del.stats = &op->stats;
op->dop.u.flow_del.terse = udpif_use_ufid(udpif);
}
static void
modify_op_init(struct ukey_op *op, struct udpif_key *ukey)
{
op->ukey = ukey;
op->dop.type = DPIF_OP_FLOW_PUT;
op->dop.u.flow_put.flags = DPIF_FP_MODIFY;
op->dop.u.flow_put.key = ukey->key;
op->dop.u.flow_put.key_len = ukey->key_len;
op->dop.u.flow_put.mask = ukey->mask;
op->dop.u.flow_put.mask_len = ukey->mask_len;
op->dop.u.flow_put.ufid = ukey->ufid_present ? &ukey->ufid : NULL;
op->dop.u.flow_put.pmd_id = ukey->pmd_id;
op->dop.u.flow_put.stats = NULL;
ukey_get_actions(ukey, &op->dop.u.flow_put.actions,
&op->dop.u.flow_put.actions_len);
}
/* Executes datapath operations 'ops' and attributes stats retrieved from the
* datapath as part of those operations. */
static void
push_dp_ops(struct udpif *udpif, struct ukey_op *ops, size_t n_ops)
{
struct dpif_op *opsp[REVALIDATE_MAX_BATCH];
size_t i;
ovs_assert(n_ops <= REVALIDATE_MAX_BATCH);
for (i = 0; i < n_ops; i++) {
opsp[i] = &ops[i].dop;
}
dpif_operate(udpif->dpif, opsp, n_ops);
for (i = 0; i < n_ops; i++) {
struct ukey_op *op = &ops[i];
struct dpif_flow_stats *push, *stats, push_buf;
stats = op->dop.u.flow_del.stats;
push = &push_buf;
if (op->dop.type != DPIF_OP_FLOW_DEL) {
/* Only deleted flows need their stats pushed. */
continue;
}
if (op->dop.error) {
/* flow_del error, 'stats' is unusable. */
continue;
}
if (op->ukey) {
ovs_mutex_lock(&op->ukey->mutex);
push->used = MAX(stats->used, op->ukey->stats.used);
push->tcp_flags = stats->tcp_flags | op->ukey->stats.tcp_flags;
push->n_packets = stats->n_packets - op->ukey->stats.n_packets;
push->n_bytes = stats->n_bytes - op->ukey->stats.n_bytes;
ovs_mutex_unlock(&op->ukey->mutex);
} else {
push = stats;
}
if (push->n_packets || netflow_exists()) {
const struct nlattr *key = op->dop.u.flow_del.key;
size_t key_len = op->dop.u.flow_del.key_len;
struct ofproto_dpif *ofproto;
struct netflow *netflow;
ofp_port_t ofp_in_port;
struct flow flow;
int error;
if (op->ukey) {
ovs_mutex_lock(&op->ukey->mutex);
if (op->ukey->xcache) {
xlate_push_stats(op->ukey->xcache, push);
ovs_mutex_unlock(&op->ukey->mutex);
continue;
}
ovs_mutex_unlock(&op->ukey->mutex);
key = op->ukey->key;
key_len = op->ukey->key_len;
}
if (odp_flow_key_to_flow(key, key_len, &flow)
== ODP_FIT_ERROR) {
continue;
}
error = xlate_lookup(udpif->backer, &flow, &ofproto, NULL, NULL,
&netflow, &ofp_in_port);
if (!error) {
struct xlate_in xin;
xlate_in_init(&xin, ofproto, &flow, ofp_in_port, NULL,
push->tcp_flags, NULL, NULL, NULL);
xin.resubmit_stats = push->n_packets ? push : NULL;
xin.may_learn = push->n_packets > 0;
xlate_actions_for_side_effects(&xin);
if (netflow) {
netflow_flow_clear(netflow, &flow);
}
}
}
}
}
/* Executes datapath operations 'ops', attributes stats retrieved from the
* datapath, and deletes ukeys corresponding to deleted flows. */
static void
push_ukey_ops(struct udpif *udpif, struct umap *umap,
struct ukey_op *ops, size_t n_ops)
{
int i;
push_dp_ops(udpif, ops, n_ops);
ovs_mutex_lock(&umap->mutex);
for (i = 0; i < n_ops; i++) {
if (ops[i].dop.type == DPIF_OP_FLOW_DEL) {
ukey_delete(umap, ops[i].ukey);
}
}
ovs_mutex_unlock(&umap->mutex);
}
static void
log_unexpected_flow(const struct dpif_flow *flow, int error)
{
static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(10, 60);
struct ds ds = DS_EMPTY_INITIALIZER;
ds_put_format(&ds, "Failed to acquire udpif_key corresponding to "
"unexpected flow (%s): ", ovs_strerror(error));
odp_format_ufid(&flow->ufid, &ds);
VLOG_WARN_RL(&rl, "%s", ds_cstr(&ds));
ds_destroy(&ds);
}
static void
reval_op_init(struct ukey_op *op, enum reval_result result,
struct udpif *udpif, struct udpif_key *ukey,
struct recirc_refs *recircs, struct ofpbuf *odp_actions)
{
if (result == UKEY_DELETE) {
delete_op_init(udpif, op, ukey);
} else if (result == UKEY_MODIFY) {
/* Store the new recircs. */
recirc_refs_swap(&ukey->recircs, recircs);
/* Release old recircs. */
recirc_refs_unref(recircs);
/* ukey->key_recirc_id remains, as the key is the same as before. */
ukey_set_actions(ukey, odp_actions);
modify_op_init(op, ukey);
}
}
static void
revalidate(struct revalidator *revalidator)
{
uint64_t odp_actions_stub[1024 / 8];
struct ofpbuf odp_actions = OFPBUF_STUB_INITIALIZER(odp_actions_stub);
struct udpif *udpif = revalidator->udpif;
struct dpif_flow_dump_thread *dump_thread;
uint64_t dump_seq, reval_seq;
unsigned int flow_limit;
dump_seq = seq_read(udpif->dump_seq);
reval_seq = seq_read(udpif->reval_seq);
atomic_read_relaxed(&udpif->flow_limit, &flow_limit);
dump_thread = dpif_flow_dump_thread_create(udpif->dump);
for (;;) {
struct ukey_op ops[REVALIDATE_MAX_BATCH];
int n_ops = 0;
struct dpif_flow flows[REVALIDATE_MAX_BATCH];
const struct dpif_flow *f;
int n_dumped;
long long int max_idle;
long long int now;
size_t n_dp_flows;
bool kill_them_all;
n_dumped = dpif_flow_dump_next(dump_thread, flows, ARRAY_SIZE(flows));
if (!n_dumped) {
break;
}
now = time_msec();
/* In normal operation we want to keep flows around until they have
* been idle for 'ofproto_max_idle' milliseconds. However:
*
* - If the number of datapath flows climbs above 'flow_limit',
* drop that down to 100 ms to try to bring the flows down to
* the limit.
*
* - If the number of datapath flows climbs above twice
* 'flow_limit', delete all the datapath flows as an emergency
* measure. (We reassess this condition for the next batch of
* datapath flows, so we will recover before all the flows are
* gone.) */
n_dp_flows = udpif_get_n_flows(udpif);
kill_them_all = n_dp_flows > flow_limit * 2;
max_idle = n_dp_flows > flow_limit ? 100 : ofproto_max_idle;
for (f = flows; f < &flows[n_dumped]; f++) {
long long int used = f->stats.used;
struct recirc_refs recircs = RECIRC_REFS_EMPTY_INITIALIZER;
enum reval_result result;
struct udpif_key *ukey;
bool already_dumped;
int error;
if (ukey_acquire(udpif, f, &ukey, &error)) {
if (error == EBUSY) {
/* Another thread is processing this flow, so don't bother
* processing it.*/
COVERAGE_INC(upcall_ukey_contention);
} else {
log_unexpected_flow(f, error);
if (error != ENOENT) {
delete_op_init__(udpif, &ops[n_ops++], f);
}
}
continue;
}
already_dumped = ukey->dump_seq == dump_seq;
if (already_dumped) {
/* The flow has already been handled during this flow dump
* operation. Skip it. */
if (ukey->xcache) {
COVERAGE_INC(dumped_duplicate_flow);
} else {
COVERAGE_INC(dumped_new_flow);
}
ovs_mutex_unlock(&ukey->mutex);
continue;
}
if (!used) {
used = ukey->created;
}
if (kill_them_all || (used && used < now - max_idle)) {
result = UKEY_DELETE;
} else {
result = revalidate_ukey(udpif, ukey, &f->stats, &odp_actions,
reval_seq, &recircs);
}
ukey->dump_seq = dump_seq;
ukey->flow_exists = result != UKEY_DELETE;
if (result != UKEY_KEEP) {
/* Takes ownership of 'recircs'. */
reval_op_init(&ops[n_ops++], result, udpif, ukey, &recircs,
&odp_actions);
}
ovs_mutex_unlock(&ukey->mutex);
}
if (n_ops) {
/* Push datapath ops but defer ukey deletion to 'sweep' phase. */
push_dp_ops(udpif, ops, n_ops);
}
ovsrcu_quiesce();
}
dpif_flow_dump_thread_destroy(dump_thread);
ofpbuf_uninit(&odp_actions);
}
/* Pauses the 'revalidator', can only proceed after main thread
* calls udpif_resume_revalidators(). */
static void
revalidator_pause(struct revalidator *revalidator)
{
/* The first block is for sync'ing the pause with main thread. */
ovs_barrier_block(&revalidator->udpif->pause_barrier);
/* The second block is for pausing until main thread resumes. */
ovs_barrier_block(&revalidator->udpif->pause_barrier);
}
static void
revalidator_sweep__(struct revalidator *revalidator, bool purge)
{
struct udpif *udpif;
uint64_t dump_seq, reval_seq;
int slice;
udpif = revalidator->udpif;
dump_seq = seq_read(udpif->dump_seq);
reval_seq = seq_read(udpif->reval_seq);
slice = revalidator - udpif->revalidators;
ovs_assert(slice < udpif->n_revalidators);
for (int i = slice; i < N_UMAPS; i += udpif->n_revalidators) {
uint64_t odp_actions_stub[1024 / 8];
struct ofpbuf odp_actions = OFPBUF_STUB_INITIALIZER(odp_actions_stub);
struct ukey_op ops[REVALIDATE_MAX_BATCH];
struct udpif_key *ukey;
struct umap *umap = &udpif->ukeys[i];
size_t n_ops = 0;
CMAP_FOR_EACH(ukey, cmap_node, &umap->cmap) {
bool flow_exists;
/* Handler threads could be holding a ukey lock while it installs a
* new flow, so don't hang around waiting for access to it. */
if (ovs_mutex_trylock(&ukey->mutex)) {
continue;
}
flow_exists = ukey->flow_exists;
if (flow_exists) {
struct recirc_refs recircs = RECIRC_REFS_EMPTY_INITIALIZER;
bool seq_mismatch = (ukey->dump_seq != dump_seq
&& ukey->reval_seq != reval_seq);
enum reval_result result;
if (purge) {
result = UKEY_DELETE;
} else if (!seq_mismatch) {
result = UKEY_KEEP;
} else {
struct dpif_flow_stats stats;
COVERAGE_INC(revalidate_missed_dp_flow);
memset(&stats, 0, sizeof stats);
result = revalidate_ukey(udpif, ukey, &stats, &odp_actions,
reval_seq, &recircs);
}
if (result != UKEY_KEEP) {
/* Clears 'recircs' if filled by revalidate_ukey(). */
reval_op_init(&ops[n_ops++], result, udpif, ukey, &recircs,
&odp_actions);
}
}
ovs_mutex_unlock(&ukey->mutex);
if (!flow_exists) {
/* The common flow deletion case involves deletion of the flow
* during the dump phase and ukey deletion here. */
ovs_mutex_lock(&umap->mutex);
ukey_delete(umap, ukey);
ovs_mutex_unlock(&umap->mutex);
}
if (n_ops == REVALIDATE_MAX_BATCH) {
/* Update/delete missed flows and clean up corresponding ukeys
* if necessary. */
push_ukey_ops(udpif, umap, ops, n_ops);
n_ops = 0;
}
}
if (n_ops) {
push_ukey_ops(udpif, umap, ops, n_ops);
}
ofpbuf_uninit(&odp_actions);
ovsrcu_quiesce();
}
}
static void
revalidator_sweep(struct revalidator *revalidator)
{
revalidator_sweep__(revalidator, false);
}
static void
revalidator_purge(struct revalidator *revalidator)
{
revalidator_sweep__(revalidator, true);
}
/* In reaction to dpif purge, purges all 'ukey's with same 'pmd_id'. */
static void
dp_purge_cb(void *aux, unsigned pmd_id)
{
struct udpif *udpif = aux;
size_t i;
udpif_pause_revalidators(udpif);
for (i = 0; i < N_UMAPS; i++) {
struct ukey_op ops[REVALIDATE_MAX_BATCH];
struct udpif_key *ukey;
struct umap *umap = &udpif->ukeys[i];
size_t n_ops = 0;
CMAP_FOR_EACH(ukey, cmap_node, &umap->cmap) {
if (ukey->pmd_id == pmd_id) {
delete_op_init(udpif, &ops[n_ops++], ukey);
if (n_ops == REVALIDATE_MAX_BATCH) {
push_ukey_ops(udpif, umap, ops, n_ops);
n_ops = 0;
}
}
}
if (n_ops) {
push_ukey_ops(udpif, umap, ops, n_ops);
}
ovsrcu_quiesce();
}
udpif_resume_revalidators(udpif);
}
static void
upcall_unixctl_show(struct unixctl_conn *conn, int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED, void *aux OVS_UNUSED)
{
struct ds ds = DS_EMPTY_INITIALIZER;
struct udpif *udpif;
LIST_FOR_EACH (udpif, list_node, &all_udpifs) {
unsigned int flow_limit;
bool ufid_enabled;
size_t i;
atomic_read_relaxed(&udpif->flow_limit, &flow_limit);
ufid_enabled = udpif_use_ufid(udpif);
ds_put_format(&ds, "%s:\n", dpif_name(udpif->dpif));
ds_put_format(&ds, "\tflows : (current %lu)"
" (avg %u) (max %u) (limit %u)\n", udpif_get_n_flows(udpif),
udpif->avg_n_flows, udpif->max_n_flows, flow_limit);
ds_put_format(&ds, "\tdump duration : %lldms\n", udpif->dump_duration);
ds_put_format(&ds, "\tufid enabled : ");
if (ufid_enabled) {
ds_put_format(&ds, "true\n");
} else {
ds_put_format(&ds, "false\n");
}
ds_put_char(&ds, '\n');
for (i = 0; i < n_revalidators; i++) {
struct revalidator *revalidator = &udpif->revalidators[i];
int j, elements = 0;
for (j = i; j < N_UMAPS; j += n_revalidators) {
elements += cmap_count(&udpif->ukeys[j].cmap);
}
ds_put_format(&ds, "\t%u: (keys %d)\n", revalidator->id, elements);
}
}
unixctl_command_reply(conn, ds_cstr(&ds));
ds_destroy(&ds);
}
/* Disable using the megaflows.
*
* This command is only needed for advanced debugging, so it's not
* documented in the man page. */
static void
upcall_unixctl_disable_megaflows(struct unixctl_conn *conn,
int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED,
void *aux OVS_UNUSED)
{
atomic_store_relaxed(&enable_megaflows, false);
udpif_flush_all_datapaths();
unixctl_command_reply(conn, "megaflows disabled");
}
/* Re-enable using megaflows.
*
* This command is only needed for advanced debugging, so it's not
* documented in the man page. */
static void
upcall_unixctl_enable_megaflows(struct unixctl_conn *conn,
int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED,
void *aux OVS_UNUSED)
{
atomic_store_relaxed(&enable_megaflows, true);
udpif_flush_all_datapaths();
unixctl_command_reply(conn, "megaflows enabled");
}
/* Disable skipping flow attributes during flow dump.
*
* This command is only needed for advanced debugging, so it's not
* documented in the man page. */
static void
upcall_unixctl_disable_ufid(struct unixctl_conn *conn, int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED, void *aux OVS_UNUSED)
{
atomic_store_relaxed(&enable_ufid, false);
unixctl_command_reply(conn, "Datapath dumping tersely using UFID disabled");
}
/* Re-enable skipping flow attributes during flow dump.
*
* This command is only needed for advanced debugging, so it's not documented
* in the man page. */
static void
upcall_unixctl_enable_ufid(struct unixctl_conn *conn, int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED, void *aux OVS_UNUSED)
{
atomic_store_relaxed(&enable_ufid, true);
unixctl_command_reply(conn, "Datapath dumping tersely using UFID enabled "
"for supported datapaths");
}
/* Set the flow limit.
*
* This command is only needed for advanced debugging, so it's not
* documented in the man page. */
static void
upcall_unixctl_set_flow_limit(struct unixctl_conn *conn,
int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED,
void *aux OVS_UNUSED)
{
struct ds ds = DS_EMPTY_INITIALIZER;
struct udpif *udpif;
unsigned int flow_limit = atoi(argv[1]);
LIST_FOR_EACH (udpif, list_node, &all_udpifs) {
atomic_store_relaxed(&udpif->flow_limit, flow_limit);
}
ds_put_format(&ds, "set flow_limit to %u\n", flow_limit);
unixctl_command_reply(conn, ds_cstr(&ds));
ds_destroy(&ds);
}
static void
upcall_unixctl_dump_wait(struct unixctl_conn *conn,
int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED,
void *aux OVS_UNUSED)
{
if (ovs_list_is_singleton(&all_udpifs)) {
struct udpif *udpif = NULL;
size_t len;
udpif = OBJECT_CONTAINING(ovs_list_front(&all_udpifs), udpif, list_node);
len = (udpif->n_conns + 1) * sizeof *udpif->conns;
udpif->conn_seq = seq_read(udpif->dump_seq);
udpif->conns = xrealloc(udpif->conns, len);
udpif->conns[udpif->n_conns++] = conn;
} else {
unixctl_command_reply_error(conn, "can't wait on multiple udpifs.");
}
}
static void
upcall_unixctl_purge(struct unixctl_conn *conn, int argc OVS_UNUSED,
const char *argv[] OVS_UNUSED, void *aux OVS_UNUSED)
{
struct udpif *udpif;
LIST_FOR_EACH (udpif, list_node, &all_udpifs) {
int n;
for (n = 0; n < udpif->n_revalidators; n++) {
revalidator_purge(&udpif->revalidators[n]);
}
}
unixctl_command_reply(conn, "");
}
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