/* * Copyright (c) 2017-2019 Cisco and/or its affiliates. * 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 #include /** * Per-type vector of transport protocol virtual function tables */ transport_proto_vft_t *tp_vfts; typedef struct local_endpoint_ { transport_endpoint_t ep; transport_proto_t proto; int refcnt; } local_endpoint_t; typedef struct transport_main_ { transport_endpoint_table_t local_endpoints_table; local_endpoint_t *local_endpoints; u32 *lcl_endpts_freelist; u32 port_allocator_seed; u8 lcl_endpts_cleanup_pending; clib_spinlock_t local_endpoints_lock; } transport_main_t; static transport_main_t tp_main; u8 * format_transport_proto (u8 * s, va_list * args) { u32 transport_proto = va_arg (*args, u32); if (tp_vfts[transport_proto].transport_options.name) s = format (s, "%s", tp_vfts[transport_proto].transport_options.name); else s = format (s, "n/a"); return s; } u8 * format_transport_proto_short (u8 * s, va_list * args) { u32 transport_proto = va_arg (*args, u32); char *short_name; short_name = tp_vfts[transport_proto].transport_options.short_name; if (short_name) s = format (s, "%s", short_name); else s = format (s, "NA"); return s; } u8 * format_transport_connection (u8 * s, va_list * args) { u32 transport_proto = va_arg (*args, u32); u32 conn_index = va_arg (*args, u32); u32 thread_index = va_arg (*args, u32); u32 verbose = va_arg (*args, u32); transport_proto_vft_t *tp_vft; transport_connection_t *tc; u32 indent; tp_vft = transport_protocol_get_vft (transport_proto); if (!tp_vft) return s; s = format (s, "%U", tp_vft->format_connection, conn_index, thread_index, verbose); tc = tp_vft->get_connection (conn_index, thread_index); if (tc && verbose > 1) { indent = format_get_indent (s) + 1; if (transport_connection_is_tx_paced (tc)) s = format (s, "%Upacer: %U\n", format_white_space, indent, format_transport_pacer, &tc->pacer, tc->thread_index); s = format (s, "%Utransport: flags 0x%x\n", format_white_space, indent, tc->flags); } return s; } u8 * format_transport_listen_connection (u8 * s, va_list * args) { u32 transport_proto = va_arg (*args, u32); transport_proto_vft_t *tp_vft; tp_vft = transport_protocol_get_vft (transport_proto); if (!tp_vft) return s; s = (tp_vft->format_listener) (s, args); return s; } u8 * format_transport_half_open_connection (u8 * s, va_list * args) { u32 transport_proto = va_arg (*args, u32); u32 ho_index = va_arg (*args, u32); transport_proto_vft_t *tp_vft; tp_vft = transport_protocol_get_vft (transport_proto); if (!tp_vft) return s; s = format (s, "%U", tp_vft->format_half_open, ho_index); return s; } static u8 unformat_transport_str_match (unformat_input_t * input, const char *str) { int i; if (strlen (str) > vec_len (input->buffer) - input->index) return 0; for (i = 0; i < strlen (str); i++) { if (input->buffer[i + input->index] != str[i]) return 0; } return 1; } uword unformat_transport_proto (unformat_input_t * input, va_list * args) { u32 *proto = va_arg (*args, u32 *); transport_proto_vft_t *tp_vft; u8 longest_match = 0, match; char *str, *str_match = 0; transport_proto_t tp; for (tp = 0; tp < vec_len (tp_vfts); tp++) { tp_vft = &tp_vfts[tp]; str = tp_vft->transport_options.name; if (!str) continue; if (unformat_transport_str_match (input, str)) { match = strlen (str); if (match > longest_match) { *proto = tp; longest_match = match; str_match = str; } } } if (longest_match) { (void) unformat (input, str_match); return 1; } return 0; } u8 * format_transport_protos (u8 * s, va_list * args) { transport_proto_vft_t *tp_vft; vec_foreach (tp_vft, tp_vfts) s = format (s, "%s\n", tp_vft->transport_options.name); return s; } u32 transport_endpoint_lookup (transport_endpoint_table_t * ht, u8 proto, ip46_address_t * ip, u16 port) { clib_bihash_kv_24_8_t kv; int rv; kv.key[0] = ip->as_u64[0]; kv.key[1] = ip->as_u64[1]; kv.key[2] = (u64) port << 8 | (u64) proto; rv = clib_bihash_search_inline_24_8 (ht, &kv); if (rv == 0) return kv.value; return ENDPOINT_INVALID_INDEX; } void transport_endpoint_table_add (transport_endpoint_table_t * ht, u8 proto, transport_endpoint_t * te, u32 value) { clib_bihash_kv_24_8_t kv; kv.key[0] = te->ip.as_u64[0]; kv.key[1] = te->ip.as_u64[1]; kv.key[2] = (u64) te->port << 8 | (u64) proto; kv.value = value; clib_bihash_add_del_24_8 (ht, &kv, 1); } void transport_endpoint_table_del (transport_endpoint_table_t * ht, u8 proto, transport_endpoint_t * te) { clib_bihash_kv_24_8_t kv; kv.key[0] = te->ip.as_u64[0]; kv.key[1] = te->ip.as_u64[1]; kv.key[2] = (u64) te->port << 8 | (u64) proto; clib_bihash_add_del_24_8 (ht, &kv, 0); } void transport_register_protocol (transport_proto_t transport_proto, const transport_proto_vft_t * vft, fib_protocol_t fib_proto, u32 output_node) { u8 is_ip4 = fib_proto == FIB_PROTOCOL_IP4; vec_validate (tp_vfts, transport_proto); tp_vfts[transport_proto] = *vft; session_register_transport (transport_proto, vft, is_ip4, output_node); } transport_proto_t transport_register_new_protocol (const transport_proto_vft_t * vft, fib_protocol_t fib_proto, u32 output_node) { transport_proto_t transport_proto; u8 is_ip4; transport_proto = session_add_transport_proto (); is_ip4 = fib_proto == FIB_PROTOCOL_IP4; vec_validate (tp_vfts, transport_proto); tp_vfts[transport_proto] = *vft; session_register_transport (transport_proto, vft, is_ip4, output_node); return transport_proto; } /** * Get transport virtual function table * * @param type - session type (not protocol type) */ transport_proto_vft_t * transport_protocol_get_vft (transport_proto_t transport_proto) { if (transport_proto >= vec_len (tp_vfts)) return 0; return &tp_vfts[transport_proto]; } transport_service_type_t transport_protocol_service_type (transport_proto_t tp) { return tp_vfts[tp].transport_options.service_type; } transport_tx_fn_type_t transport_protocol_tx_fn_type (transport_proto_t tp) { return tp_vfts[tp].transport_options.tx_type; } void transport_cleanup (transport_proto_t tp, u32 conn_index, u8 thread_index) { tp_vfts[tp].cleanup (conn_index, thread_index); } void transport_cleanup_half_open (transport_proto_t tp, u32 conn_index) { if (tp_vfts[tp].cleanup_ho) tp_vfts[tp].cleanup_ho (conn_index); } int transport_connect (transport_proto_t tp, transport_endpoint_cfg_t * tep) { if (PREDICT_FALSE (!tp_vfts[tp].connect)) return SESSION_E_TRANSPORT_NO_REG; return tp_vfts[tp].connect (tep); } void transport_half_close (transport_proto_t tp, u32 conn_index, u8 thread_index) { if (tp_vfts[tp].half_close) tp_vfts[tp].half_close (conn_index, thread_index); } void transport_close (transport_proto_t tp, u32 conn_index, u8 thread_index) { tp_vfts[tp].close (conn_index, thread_index); } void transport_reset (transport_proto_t tp, u32 conn_index, u8 thread_index) { if (tp_vfts[tp].reset) tp_vfts[tp].reset (conn_index, thread_index); else tp_vfts[tp].close (conn_index, thread_index); } u32 transport_start_listen (transport_proto_t tp, u32 session_index, transport_endpoint_cfg_t *tep) { if (PREDICT_FALSE (!tp_vfts[tp].start_listen)) return SESSION_E_TRANSPORT_NO_REG; return tp_vfts[tp].start_listen (session_index, tep); } u32 transport_stop_listen (transport_proto_t tp, u32 conn_index) { return tp_vfts[tp].stop_listen (conn_index); } u8 transport_protocol_is_cl (transport_proto_t tp) { return (tp_vfts[tp].transport_options.service_type == TRANSPORT_SERVICE_CL); } always_inline void default_get_transport_endpoint (transport_connection_t * tc, transport_endpoint_t * tep, u8 is_lcl) { if (is_lcl) { tep->port = tc->lcl_port; tep->is_ip4 = tc->is_ip4; clib_memcpy_fast (&tep->ip, &tc->lcl_ip, sizeof (tc->lcl_ip)); } else { tep->port = tc->rmt_port; tep->is_ip4 = tc->is_ip4; clib_memcpy_fast (&tep->ip, &tc->rmt_ip, sizeof (tc->rmt_ip)); } } void transport_get_endpoint (transport_proto_t tp, u32 conn_index, u32 thread_index, transport_endpoint_t * tep, u8 is_lcl) { if (tp_vfts[tp].get_transport_endpoint) tp_vfts[tp].get_transport_endpoint (conn_index, thread_index, tep, is_lcl); else { transport_connection_t *tc; tc = transport_get_connection (tp, conn_index, thread_index); default_get_transport_endpoint (tc, tep, is_lcl); } } void transport_get_listener_endpoint (transport_proto_t tp, u32 conn_index, transport_endpoint_t * tep, u8 is_lcl) { if (tp_vfts[tp].get_transport_listener_endpoint) tp_vfts[tp].get_transport_listener_endpoint (conn_index, tep, is_lcl); else { transport_connection_t *tc; tc = transport_get_listener (tp, conn_index); default_get_transport_endpoint (tc, tep, is_lcl); } } int transport_connection_attribute (transport_proto_t tp, u32 conn_index, u8 thread_index, u8 is_get, transport_endpt_attr_t *attr) { if (!tp_vfts[tp].attribute) return -1; return tp_vfts[tp].attribute (conn_index, thread_index, is_get, attr); } #define PORT_MASK ((1 << 16)- 1) void transport_endpoint_free (u32 tepi) { transport_main_t *tm = &tp_main; pool_put_index (tm->local_endpoints, tepi); } always_inline local_endpoint_t * transport_endpoint_alloc (void) { transport_main_t *tm = &tp_main; local_endpoint_t *lep; ASSERT (vlib_get_thread_index () <= transport_cl_thread ()); pool_get_aligned_safe (tm->local_endpoints, lep, 0); return lep; } static void transport_cleanup_freelist (void) { transport_main_t *tm = &tp_main; local_endpoint_t *lep; u32 *lep_indexp; clib_spinlock_lock (&tm->local_endpoints_lock); vec_foreach (lep_indexp, tm->lcl_endpts_freelist) { lep = pool_elt_at_index (tm->local_endpoints, *lep_indexp); /* Port re-shared after attempt to cleanup */ if (lep->refcnt > 0) continue; transport_endpoint_table_del (&tm->local_endpoints_table, lep->proto, &lep->ep); transport_endpoint_free (*lep_indexp); } vec_reset_length (tm->lcl_endpts_freelist); tm->lcl_endpts_cleanup_pending = 0; clib_spinlock_unlock (&tm->local_endpoints_lock); } void transport_program_endpoint_cleanup (u32 lepi) { transport_main_t *tm = &tp_main; u8 flush_fl = 0; /* All workers can free connections. Synchronize access to freelist */ clib_spinlock_lock (&tm->local_endpoints_lock); vec_add1 (tm->lcl_endpts_freelist, lepi); /* Avoid accumulating lots of endpoints for cleanup */ if (!tm->lcl_endpts_cleanup_pending && vec_len (tm->lcl_endpts_freelist) > 32) { tm->lcl_endpts_cleanup_pending = 1; flush_fl = 1; } clib_spinlock_unlock (&tm->local_endpoints_lock); if (flush_fl) session_send_rpc_evt_to_thread_force (transport_cl_thread (), transport_cleanup_freelist, 0); } int transport_release_local_endpoint (u8 proto, ip46_address_t *lcl_ip, u16 port) { transport_main_t *tm = &tp_main; local_endpoint_t *lep; u32 lepi; lepi = transport_endpoint_lookup (&tm->local_endpoints_table, proto, lcl_ip, clib_net_to_host_u16 (port)); if (lepi == ENDPOINT_INVALID_INDEX) return -1; lep = pool_elt_at_index (tm->local_endpoints, lepi); /* Local endpoint no longer in use, program cleanup */ if (!clib_atomic_sub_fetch (&lep->refcnt, 1)) { transport_program_endpoint_cleanup (lepi); return 0; } /* Not an error, just in idication that endpoint was not cleaned up */ return -1; } static int transport_endpoint_mark_used (u8 proto, ip46_address_t *ip, u16 port) { transport_main_t *tm = &tp_main; local_endpoint_t *lep; u32 tei; ASSERT (vlib_get_thread_index () <= transport_cl_thread ()); tei = transport_endpoint_lookup (&tm->local_endpoints_table, proto, ip, port); if (tei != ENDPOINT_INVALID_INDEX) return SESSION_E_PORTINUSE; /* Pool reallocs with worker barrier */ lep = transport_endpoint_alloc (); clib_memcpy_fast (&lep->ep.ip, ip, sizeof (*ip)); lep->ep.port = port; lep->proto = proto; lep->refcnt = 1; transport_endpoint_table_add (&tm->local_endpoints_table, proto, &lep->ep, lep - tm->local_endpoints); return 0; } void transport_share_local_endpoint (u8 proto, ip46_address_t * lcl_ip, u16 port) { transport_main_t *tm = &tp_main; local_endpoint_t *lep; u32 lepi; /* Active opens should call this only from a control thread, which are also * used to allocate and free ports. So, pool has only one writer and * potentially many readers. Listeners are allocated with barrier */ lepi = transport_endpoint_lookup (&tm->local_endpoints_table, proto, lcl_ip, clib_net_to_host_u16 (port)); if (lepi != ENDPOINT_INVALID_INDEX) { lep = pool_elt_at_index (tm->local_endpoints, lepi); clib_atomic_add_fetch (&lep->refcnt, 1); } } /** * Allocate local port and add if successful add entry to local endpoint * table to mark the pair as used. */ int transport_alloc_local_port (u8 proto, ip46_address_t * ip) { u16 min = 1024, max = 65535; /* XXX configurable ? */ transport_main_t *tm = &tp_main; int tries, limit; limit = max - min; /* Only support active opens from one of ctrl threads */ ASSERT (vlib_get_thread_index () <= transport_cl_thread ()); /* Cleanup freelist if need be */ if (vec_len (tm->lcl_endpts_freelist)) transport_cleanup_freelist (); /* Search for first free slot */ for (tries = 0; tries < limit; tries++) { u16 port = 0; /* Find a port in the specified range */ while (1) { port = random_u32 (&tm->port_allocator_seed) & PORT_MASK; if (PREDICT_TRUE (port >= min && port < max)) break; } if (!transport_endpoint_mark_used (proto, ip, port)) return port; } return -1; } static session_error_t transport_get_interface_ip (u32 sw_if_index, u8 is_ip4, ip46_address_t * addr) { if (is_ip4) { ip4_address_t *ip4; ip4 = ip_interface_get_first_ip (sw_if_index, 1); if (!ip4) return SESSION_E_NOIP; addr->ip4.as_u32 = ip4->as_u32; } else { ip6_address_t *ip6; ip6 = ip_interface_get_first_ip (sw_if_index, 0); if (ip6 == 0) return SESSION_E_NOIP; clib_memcpy_fast (&addr->ip6, ip6, sizeof (*ip6)); } return 0; } static session_error_t transport_find_local_ip_for_remote (u32 *sw_if_index, transport_endpoint_t *rmt, ip46_address_t *lcl_addr) { fib_node_index_t fei; fib_prefix_t prefix; if (*sw_if_index == ENDPOINT_INVALID_INDEX) { /* Find a FIB path to the destination */ clib_memcpy_fast (&prefix.fp_addr, &rmt->ip, sizeof (rmt->ip)); prefix.fp_proto = rmt->is_ip4 ? FIB_PROTOCOL_IP4 : FIB_PROTOCOL_IP6; prefix.fp_len = rmt->is_ip4 ? 32 : 128; ASSERT (rmt->fib_index != ENDPOINT_INVALID_INDEX); fei = fib_table_lookup (rmt->fib_index, &prefix); /* Couldn't find route to destination. Bail out. */ if (fei == FIB_NODE_INDEX_INVALID) return SESSION_E_NOROUTE; *sw_if_index = fib_entry_get_resolving_interface (fei); if (*sw_if_index == ENDPOINT_INVALID_INDEX) return SESSION_E_NOINTF; } clib_memset (lcl_addr, 0, sizeof (*lcl_addr)); return transport_get_interface_ip (*sw_if_index, rmt->is_ip4, lcl_addr); } int transport_alloc_local_endpoint (u8 proto, transport_endpoint_cfg_t * rmt_cfg, ip46_address_t * lcl_addr, u16 * lcl_port) { transport_endpoint_t *rmt = (transport_endpoint_t *) rmt_cfg; session_error_t error; int port; /* * Find the local address */ if (ip_is_zero (&rmt_cfg->peer.ip, rmt_cfg->peer.is_ip4)) { error = transport_find_local_ip_for_remote (&rmt_cfg->peer.sw_if_index, rmt, lcl_addr); if (error) return error; } else { /* Assume session layer vetted this address */ clib_memcpy_fast (lcl_addr, &rmt_cfg->peer.ip, sizeof (rmt_cfg->peer.ip)); } /* * Allocate source port */ if (rmt_cfg->peer.port == 0) { port = transport_alloc_local_port (proto, lcl_addr); if (port < 1) return SESSION_E_NOPORT; *lcl_port = port; } else { port = clib_net_to_host_u16 (rmt_cfg->peer.port); *lcl_port = port; return transport_endpoint_mark_used (proto, lcl_addr, port); } return 0; } u8 * format_clib_us_time (u8 * s, va_list * args) { clib_us_time_t t = va_arg (*args, clib_us_time_t); if (t < 1e3) s = format (s, "%u us", t); else s = format (s, "%.3f s", (f64) t * CLIB_US_TIME_PERIOD); return s; } u8 * format_transport_pacer (u8 * s, va_list * args) { spacer_t *pacer = va_arg (*args, spacer_t *); u32 thread_index = va_arg (*args, int); clib_us_time_t now, diff; now = transport_us_time_now (thread_index); diff = now - pacer->last_update; s = format (s, "rate %lu bucket %ld t/p %.3f last_update %U burst %u", pacer->bytes_per_sec, pacer->bucket, pacer->tokens_per_period, format_clib_us_time, diff, pacer->max_burst); return s; } static inline u32 spacer_max_burst (spacer_t * pacer, clib_us_time_t time_now) { u64 n_periods = (time_now - pacer->last_update); i64 inc; if ((inc = (f32) n_periods * pacer->tokens_per_period) > 10) { pacer->last_update = time_now; pacer->bucket = clib_min (pacer->bucket + inc, (i64) pacer->max_burst); } return pacer->bucket >= 0 ? pacer->max_burst : 0; } static inline void spacer_update_bucket (spacer_t * pacer, u32 bytes) { pacer->bucket -= bytes; } static inline void spacer_set_pace_rate (spacer_t * pacer, u64 rate_bytes_per_sec, clib_us_time_t rtt, clib_time_type_t sec_per_loop) { clib_us_time_t max_time; ASSERT (rate_bytes_per_sec != 0); pacer->bytes_per_sec = rate_bytes_per_sec; pacer->tokens_per_period = rate_bytes_per_sec * CLIB_US_TIME_PERIOD; /* Allow a min number of bursts per rtt, if their size is acceptable. Goal * is to spread the sending of data over the rtt but to also allow for some * coalescing that can potentially * 1) reduce load on session layer by reducing scheduling frequency for a * session and * 2) optimize sending when tso if available * * Max "time-length" of a burst cannot be less than 1us or more than 1ms. */ max_time = clib_max (rtt / TRANSPORT_PACER_BURSTS_PER_RTT, (clib_us_time_t) (sec_per_loop * CLIB_US_TIME_FREQ)); max_time = clib_clamp (max_time, 1 /* 1us */ , 1000 /* 1ms */ ); pacer->max_burst = (rate_bytes_per_sec * max_time) * CLIB_US_TIME_PERIOD; pacer->max_burst = clib_clamp (pacer->max_burst, TRANSPORT_PACER_MIN_BURST, TRANSPORT_PACER_MAX_BURST); } static inline u64 spacer_pace_rate (spacer_t * pacer) { return pacer->bytes_per_sec; } static inline void spacer_reset (spacer_t * pacer, clib_us_time_t time_now, u64 bucket) { pacer->last_update = time_now; pacer->bucket = bucket; } void transport_connection_tx_pacer_reset (transport_connection_t * tc, u64 rate_bytes_per_sec, u32 start_bucket, clib_us_time_t rtt) { spacer_set_pace_rate (&tc->pacer, rate_bytes_per_sec, rtt, transport_seconds_per_loop (tc->thread_index)); spacer_reset (&tc->pacer, transport_us_time_now (tc->thread_index), start_bucket); } void transport_connection_tx_pacer_reset_bucket (transport_connection_t * tc, u32 bucket) { spacer_reset (&tc->pacer, transport_us_time_now (tc->thread_index), bucket); } void transport_connection_tx_pacer_init (transport_connection_t * tc, u64 rate_bytes_per_sec, u32 initial_bucket) { tc->flags |= TRANSPORT_CONNECTION_F_IS_TX_PACED; transport_connection_tx_pacer_reset (tc, rate_bytes_per_sec, initial_bucket, 1e6); } void transport_connection_tx_pacer_update (transport_connection_t * tc, u64 bytes_per_sec, clib_us_time_t rtt) { spacer_set_pace_rate (&tc->pacer, bytes_per_sec, rtt, transport_seconds_per_loop (tc->thread_index)); } u32 transport_connection_tx_pacer_burst (transport_connection_t * tc) { return spacer_max_burst (&tc->pacer, transport_us_time_now (tc->thread_index)); } u64 transport_connection_tx_pacer_rate (transport_connection_t * tc) { return spacer_pace_rate (&tc->pacer); } void transport_connection_update_tx_bytes (transport_connection_t * tc, u32 bytes) { if (transport_connection_is_tx_paced (tc)) spacer_update_bucket (&tc->pacer, bytes); } void transport_connection_tx_pacer_update_bytes (transport_connection_t * tc, u32 bytes) { spacer_update_bucket (&tc->pacer, bytes); } void transport_update_pacer_time (u32 thread_index, clib_time_type_t now) { session_wrk_update_time (session_main_get_worker (thread_index), now); } void transport_connection_reschedule (transport_connection_t * tc) { tc->flags &= ~TRANSPORT_CONNECTION_F_DESCHED; transport_connection_tx_pacer_reset_bucket (tc, 0 /* bucket */); if (transport_max_tx_dequeue (tc)) sesssion_reschedule_tx (tc); else { session_t *s = session_get (tc->s_index, tc->thread_index); svm_fifo_unset_event (s->tx_fifo); if (svm_fifo_max_dequeue_cons (s->tx_fifo)) if (svm_fifo_set_event (s->tx_fifo)) sesssion_reschedule_tx (tc); } } void transport_fifos_init_ooo (transport_connection_t * tc) { session_t *s = session_get (tc->s_index, tc->thread_index); svm_fifo_init_ooo_lookup (s->rx_fifo, 0 /* ooo enq */ ); svm_fifo_init_ooo_lookup (s->tx_fifo, 1 /* ooo deq */ ); } void transport_update_time (clib_time_type_t time_now, u8 thread_index) { transport_proto_vft_t *vft; vec_foreach (vft, tp_vfts) { if (vft->update_time) (vft->update_time) (time_now, thread_index); } } void transport_enable_disable (vlib_main_t * vm, u8 is_en) { transport_proto_vft_t *vft; vec_foreach (vft, tp_vfts) { if (vft->enable) (vft->enable) (vm, is_en); if (vft->update_time) session_register_update_time_fn (vft->update_time, is_en); } } void transport_init (void) { vlib_thread_main_t *vtm = vlib_get_thread_main (); session_main_t *smm = vnet_get_session_main (); transport_main_t *tm = &tp_main; u32 num_threads; if (smm->local_endpoints_table_buckets == 0) smm->local_endpoints_table_buckets = 250000; if (smm->local_endpoints_table_memory == 0) smm->local_endpoints_table_memory = 512 << 20; /* Initialize [port-allocator] random number seed */ tm->port_allocator_seed = (u32) clib_cpu_time_now (); clib_bihash_init_24_8 (&tm->local_endpoints_table, "local endpoints table", smm->local_endpoints_table_buckets, smm->local_endpoints_table_memory); clib_spinlock_init (&tm->local_endpoints_lock); num_threads = 1 /* main thread */ + vtm->n_threads; if (num_threads > 1) { /* Main not polled if there are workers */ smm->transport_cl_thread = 1; } } /* * fd.io coding-style-patch-verification: ON * * Local Variables: * eval: (c-set-style "gnu") * End: */