/* * Copyright (c) 2016-2019 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. */ #ifndef _vnet_tcp_h_ #define _vnet_tcp_h_ #include #include #include #include #include #include #include #define TCP_TICK 0.001 /**< TCP tick period (s) */ #define THZ (u32) (1/TCP_TICK) /**< TCP tick frequency */ #define TCP_TSTAMP_RESOLUTION TCP_TICK /**< Time stamp resolution */ #define TCP_PAWS_IDLE 24 * 24 * 60 * 60 * THZ /**< 24 days */ #define TCP_FIB_RECHECK_PERIOD 1 * THZ /**< Recheck every 1s */ #define TCP_MAX_OPTION_SPACE 40 #define TCP_CC_DATA_SZ 24 #define TCP_MAX_GSO_SZ 65536 #define TCP_RXT_MAX_BURST 10 #define TCP_DUPACK_THRESHOLD 3 #define TCP_IW_N_SEGMENTS 10 #define TCP_ALWAYS_ACK 1 /**< On/off delayed acks */ #define TCP_USE_SACKS 1 /**< Disable only for testing */ /** TCP FSM state definitions as per RFC793. */ #define foreach_tcp_fsm_state \ _(CLOSED, "CLOSED") \ _(LISTEN, "LISTEN") \ _(SYN_SENT, "SYN_SENT") \ _(SYN_RCVD, "SYN_RCVD") \ _(ESTABLISHED, "ESTABLISHED") \ _(CLOSE_WAIT, "CLOSE_WAIT") \ _(FIN_WAIT_1, "FIN_WAIT_1") \ _(LAST_ACK, "LAST_ACK") \ _(CLOSING, "CLOSING") \ _(FIN_WAIT_2, "FIN_WAIT_2") \ _(TIME_WAIT, "TIME_WAIT") typedef enum _tcp_state { #define _(sym, str) TCP_STATE_##sym, foreach_tcp_fsm_state #undef _ TCP_N_STATES } tcp_state_t; format_function_t format_tcp_state; format_function_t format_tcp_flags; format_function_t format_tcp_sacks; format_function_t format_tcp_rcv_sacks; /** TCP timers */ #define foreach_tcp_timer \ _(RETRANSMIT, "RETRANSMIT") \ _(DELACK, "DELAYED ACK") \ _(PERSIST, "PERSIST") \ _(WAITCLOSE, "WAIT CLOSE") \ _(RETRANSMIT_SYN, "RETRANSMIT SYN") \ typedef enum _tcp_timers { #define _(sym, str) TCP_TIMER_##sym, foreach_tcp_timer #undef _ TCP_N_TIMERS } tcp_timers_e; #define TCP_TIMER_HANDLE_INVALID ((u32) ~0) #define TCP_TIMER_TICK 0.1 /**< Timer tick in seconds */ #define TCP_TO_TIMER_TICK TCP_TICK*10 /**< Factor for converting ticks to timer ticks */ #define TCP_RTO_MAX 60 * THZ /* Min max RTO (60s) as per RFC6298 */ #define TCP_RTO_MIN 0.2 * THZ /* Min RTO (200ms) - lower than standard */ #define TCP_RTT_MAX 30 * THZ /* 30s (probably too much) */ #define TCP_RTO_SYN_RETRIES 3 /* SYN retries without doubling RTO */ #define TCP_RTO_INIT 1 * THZ /* Initial retransmit timer */ #define TCP_RTO_BOFF_MAX 8 /* Max number of retries before reset */ #define TCP_ESTABLISH_TIME (60 * THZ) /* Connection establish timeout */ /** Connection configuration flags */ #define foreach_tcp_cfg_flag \ _(RATE_SAMPLE, "Rate sampling") \ _(NO_CSUM_OFFLOAD, "No csum offload") \ _(NO_TSO, "TSO off") \ _(TSO, "TSO") \ _(NO_ENDPOINT,"No endpoint") \ typedef enum tcp_cfg_flag_bits_ { #define _(sym, str) TCP_CFG_F_##sym##_BIT, foreach_tcp_cfg_flag #undef _ TCP_CFG_N_FLAG_BITS } tcp_cfg_flag_bits_e; typedef enum tcp_cfg_flag_ { #define _(sym, str) TCP_CFG_F_##sym = 1 << TCP_CFG_F_##sym##_BIT, foreach_tcp_cfg_flag #undef _ TCP_CFG_N_FLAGS } tcp_cfg_flags_e; /** TCP connection flags */ #define foreach_tcp_connection_flag \ _(SNDACK, "Send ACK") \ _(FINSNT, "FIN sent") \ _(RECOVERY, "Recovery") \ _(FAST_RECOVERY, "Fast Recovery") \ _(DCNT_PENDING, "Disconnect pending") \ _(HALF_OPEN_DONE, "Half-open completed") \ _(FINPNDG, "FIN pending") \ _(RXT_PENDING, "Retransmit pending") \ _(FRXT_FIRST, "Retransmit first") \ _(DEQ_PENDING, "Dequeue pending ") \ _(PSH_PENDING, "PSH pending") \ _(FINRCVD, "FIN received") \ _(ZERO_RWND_SENT, "Zero RWND sent") \ typedef enum tcp_connection_flag_bits_ { #define _(sym, str) TCP_CONN_##sym##_BIT, foreach_tcp_connection_flag #undef _ TCP_CONN_N_FLAG_BITS } tcp_connection_flag_bits_e; typedef enum tcp_connection_flag_ { #define _(sym, str) TCP_CONN_##sym = 1 << TCP_CONN_##sym##_BIT, foreach_tcp_connection_flag #undef _ TCP_CONN_N_FLAGS } tcp_connection_flags_e; #define TCP_SCOREBOARD_TRACE (0) #define TCP_MAX_SACK_BLOCKS 256 /**< Max number of SACK blocks stored */ #define TCP_INVALID_SACK_HOLE_INDEX ((u32)~0) typedef struct _scoreboard_trace_elt { u32 start; u32 end; u32 ack; u32 snd_una_max; u32 group; } scoreboard_trace_elt_t; typedef struct _sack_scoreboard_hole { u32 next; /**< Index for next entry in linked list */ u32 prev; /**< Index for previous entry in linked list */ u32 start; /**< Start sequence number */ u32 end; /**< End sequence number */ u8 is_lost; /**< Mark hole as lost */ } sack_scoreboard_hole_t; typedef struct _sack_scoreboard { sack_scoreboard_hole_t *holes; /**< Pool of holes */ u32 head; /**< Index of first entry */ u32 tail; /**< Index of last entry */ u32 sacked_bytes; /**< Number of bytes sacked in sb */ u32 last_sacked_bytes; /**< Number of bytes last sacked */ u32 last_bytes_delivered; /**< Sack bytes delivered to app */ u32 rxt_sacked; /**< Rxt bytes last delivered */ u32 high_sacked; /**< Highest byte sacked (fack) */ u32 high_rxt; /**< Highest retransmitted sequence */ u32 rescue_rxt; /**< Rescue sequence number */ u32 lost_bytes; /**< Bytes lost as per RFC6675 */ u32 last_lost_bytes; /**< Number of bytes last lost */ u32 cur_rxt_hole; /**< Retransmitting from this hole */ u8 is_reneging; #if TCP_SCOREBOARD_TRACE scoreboard_trace_elt_t *trace; #endif } sack_scoreboard_t; #if TCP_SCOREBOARD_TRACE #define tcp_scoreboard_trace_add(_tc, _ack) \ { \ static u64 _group = 0; \ sack_scoreboard_t *_sb = &_tc->sack_sb; \ sack_block_t *_sack, *_sacks; \ scoreboard_trace_elt_t *_elt; \ int i; \ _group++; \ _sacks = _tc->rcv_opts.sacks; \ for (i = 0; i < vec_len (_sacks); i++) \ { \ _sack = &_sacks[i]; \ vec_add2 (_sb->trace, _elt, 1); \ _elt->start = _sack->start; \ _elt->end = _sack->end; \ _elt->ack = _elt->end == _ack ? _ack : 0;
/*
 * Copyright (c) 2017 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.
 */

/**
 * @file
 * @brief IPv4 shallow virtual reassembly.
 *
 * This file contains the source code for IPv4 shallow virtual reassembly.
 */

#ifndef __included_ip4_sv_reass_h__
#define __included_ip4_sv_reass_h__

#include <vnet/api_errno.h>
#include <vnet/vnet.h>

/**
 * @brief set ip4 reassembly configuration
 */
vnet_api_error_t ip4_sv_reass_set (u32 timeout_ms, u32 max_reassemblies,
				   u32 max_reassembly_length,
				   u32 expire_walk_interval_ms);

/**
 * @brief get ip4 reassembly configuration
 */
vnet_api_error_t ip4_sv_reass_get (u32 * timeout_ms, u32 * max_reassemblies,
				   u32 * max_reassembly_length,
				   u32 * expire_walk_interval_ms);

vnet_api_error_t ip4_sv_reass_enable_disable (u32 sw_if_index,
					      u8 enable_disable);


int ip4_sv_reass_enable_disable_with_refcnt (u32 sw_if_index, int is_enable);
int ip4_sv_reass_output_enable_disable_with_refcnt (u32 sw_if_index,
						    int is_enable);

uword ip4_sv_reass_custom_register_next_node (uword node_index);

#endif /* __included_ip4_sv_reass_h__ */

/*
 * fd.io coding-style-patch-verification: ON
 *
 * Local Variables:
 * eval: (c-set-style "gnu")
 * End:
 */
fifo for a session (in bytes) */ u32 min_rx_fifo; /** Default MTU to be used when establishing connections */ u16 default_mtu; /** Initial CWND multiplier, which multiplies MSS to determine initial CWND. * Set 0 to determine the initial CWND by another way */ u16 initial_cwnd_multiplier; /** Enable tx pacing for new connections */ u8 enable_tx_pacing; /** Allow use of TSO whenever available */ u8 allow_tso; /** Set if csum offloading is enabled */ u8 csum_offload; /** Default congestion control algorithm type */ tcp_cc_algorithm_type_e cc_algo; /** Min rwnd, as number of snd_mss segments, for update ack to be sent after * a zero rwnd advertisement */ u32 rwnd_min_update_ack; /** Delayed ack time (disabled) */ u16 delack_time; /** Timer ticks to wait for close from app */ u16 closewait_time; /** Timer ticks to wait in time-wait. Also known as 2MSL */ u16 timewait_time; /** Timer ticks to wait in fin-wait1 to send fin and rcv fin-ack */ u16 finwait1_time; /** Timer ticks to wait in last ack for ack */ u16 lastack_time; /** Timer ticks to wait in fin-wait2 for fin */ u16 finwait2_time; /** Timer ticks to wait in closing for fin ack */ u16 closing_time; /** Time to wait (sec) before cleaning up the connection */ f32 cleanup_time; /** Number of preallocated connections */ u32 preallocated_connections; /** Number of preallocated half-open connections */ u32 preallocated_half_open_connections; /** Vectors of src addresses. Optional unless one needs > 63K active-opens */ ip4_address_t *ip4_src_addrs; ip6_address_t *ip6_src_addrs; /** Fault-injection. Debug only */ f64 buffer_fail_fraction; } tcp_configuration_t; typedef struct _tcp_main { /** per-worker context */ tcp_worker_ctx_t *wrk_ctx; /* Pool of listeners. */ tcp_connection_t *listener_pool; f64 tstamp_ticks_per_clock; /** vlib buffer size */ u32 bytes_per_buffer; /** Dispatch table by state and flags */ tcp_lookup_dispatch_t dispatch_table[TCP_N_STATES][64]; clib_spinlock_t half_open_lock; /** Pool of half-open connections on which we've sent a SYN */ tcp_connection_t *half_open_connections; /** Seed used to generate random iss */ tcp_iss_seed_t iss_seed; /** Congestion control algorithms registered */ tcp_cc_algorithm_t *cc_algos; /** Hash table of cc algorithms by name */ uword *cc_algo_by_name; /** Last cc algo registered */ tcp_cc_algorithm_type_e cc_last_type; /** Flag that indicates if stack is on or off */ u8 is_enabled; /** Flag that indicates if v4 punting is enabled */ u8 punt_unknown4; /** Flag that indicates if v6 punting is enabled */ u8 punt_unknown6; /** Rotor for v4 source addresses */ u32 last_v4_addr_rotor; /** Rotor for v6 source addresses */ u32 last_v6_addr_rotor; /** Protocol configuration */ tcp_configuration_t cfg; } tcp_main_t; extern tcp_main_t tcp_main; extern vlib_node_registration_t tcp4_input_node; extern vlib_node_registration_t tcp6_input_node; extern vlib_node_registration_t tcp4_output_node; extern vlib_node_registration_t tcp6_output_node; extern vlib_node_registration_t tcp4_established_node; extern vlib_node_registration_t tcp6_established_node; extern vlib_node_registration_t tcp4_syn_sent_node; extern vlib_node_registration_t tcp6_syn_sent_node; extern vlib_node_registration_t tcp4_rcv_process_node; extern vlib_node_registration_t tcp6_rcv_process_node; extern vlib_node_registration_t tcp4_listen_node; extern vlib_node_registration_t tcp6_listen_node; #define tcp_cfg tcp_main.cfg #define tcp_node_index(node_id, is_ip4) \ ((is_ip4) ? tcp4_##node_id##_node.index : tcp6_##node_id##_node.index) always_inline tcp_main_t * vnet_get_tcp_main () { return &tcp_main; } always_inline tcp_worker_ctx_t * tcp_get_worker (u32 thread_index) { ASSERT (thread_index < vec_len (tcp_main.wrk_ctx)); return &tcp_main.wrk_ctx[thread_index]; } always_inline tcp_header_t * tcp_buffer_hdr (vlib_buffer_t * b) { ASSERT ((signed) b->current_data >= (signed) -VLIB_BUFFER_PRE_DATA_SIZE); return (tcp_header_t *) (b->data + b->current_data + vnet_buffer (b)->tcp.hdr_offset); } #if (VLIB_BUFFER_TRACE_TRAJECTORY) #define tcp_trajectory_add_start(b, start) \ { \ (*vlib_buffer_trace_trajectory_cb) (b, start); \ } #else #define tcp_trajectory_add_start(b, start) #endif clib_error_t *vnet_tcp_enable_disable (vlib_main_t * vm, u8 is_en); void tcp_punt_unknown (vlib_main_t * vm, u8 is_ip4, u8 is_add); always_inline tcp_connection_t * tcp_connection_get (u32 conn_index, u32 thread_index) { tcp_worker_ctx_t *wrk = tcp_get_worker (thread_index); if (PREDICT_FALSE (pool_is_free_index (wrk->connections, conn_index))) return 0; return pool_elt_at_index (wrk->connections, conn_index); } always_inline tcp_connection_t * tcp_connection_get_if_valid (u32 conn_index, u32 thread_index) { tcp_worker_ctx_t *wrk; if (thread_index >= vec_len (tcp_main.wrk_ctx)) return 0; wrk = tcp_get_worker (thread_index); if (pool_is_free_index (wrk->connections, conn_index)) return 0; return pool_elt_at_index (wrk->connections, conn_index); } always_inline tcp_connection_t * tcp_get_connection_from_transport (transport_connection_t * tconn) { return (tcp_connection_t *) tconn; } always_inline void tcp_connection_set_state (tcp_connection_t * tc, tcp_state_t state) { tc->state = state; TCP_EVT (TCP_EVT_STATE_CHANGE, tc); } void tcp_connection_close (tcp_connection_t * tc); void tcp_connection_cleanup (tcp_connection_t * tc); void tcp_connection_del (tcp_connection_t * tc); int tcp_half_open_connection_cleanup (tcp_connection_t * tc); tcp_connection_t *tcp_connection_alloc (u8 thread_index); tcp_connection_t *tcp_connection_alloc_w_base (u8 thread_index, tcp_connection_t * base); void tcp_connection_free (tcp_connection_t * tc); int tcp_configure_v4_source_address_range (vlib_main_t * vm, ip4_address_t * start, ip4_address_t * end, u32 table_id); int tcp_configure_v6_source_address_range (vlib_main_t * vm, ip6_address_t * start, ip6_address_t * end, u32 table_id); void tcp_api_reference (void); u8 *format_tcp_connection (u8 * s, va_list * args); u8 *format_tcp_connection_id (u8 * s, va_list * args); always_inline tcp_connection_t * tcp_listener_get (u32 tli) { tcp_connection_t *tc = 0; if (!pool_is_free_index (tcp_main.listener_pool, tli)) tc = pool_elt_at_index (tcp_main.listener_pool, tli); return tc; } always_inline tcp_connection_t * tcp_half_open_connection_get (u32 conn_index) { tcp_connection_t *tc = 0; clib_spinlock_lock_if_init (&tcp_main.half_open_lock); if (!pool_is_free_index (tcp_main.half_open_connections, conn_index)) tc = pool_elt_at_index (tcp_main.half_open_connections, conn_index); clib_spinlock_unlock_if_init (&tcp_main.half_open_lock); return tc; } void tcp_make_fin (tcp_connection_t * tc, vlib_buffer_t * b); void tcp_make_synack (tcp_connection_t * ts, vlib_buffer_t * b); void tcp_send_reset_w_pkt (tcp_connection_t * tc, vlib_buffer_t * pkt, u32 thread_index, u8 is_ip4); void tcp_send_reset (tcp_connection_t * tc); void tcp_send_syn (tcp_connection_t * tc); void tcp_send_synack (tcp_connection_t * tc); void tcp_send_fin (tcp_connection_t * tc); void tcp_send_ack (tcp_connection_t * tc); void tcp_update_burst_snd_vars (tcp_connection_t * tc); void tcp_update_rto (tcp_connection_t * tc); void tcp_send_window_update_ack (tcp_connection_t * tc); void tcp_program_ack (tcp_connection_t * tc); void tcp_program_dupack (tcp_connection_t * tc); void tcp_program_retransmit (tcp_connection_t * tc); /* * Rate estimation */ /** * Byte tracker initialize * * @param tc connection for which the byte tracker should be allocated and * initialized */ void tcp_bt_init (tcp_connection_t * tc); /** * Byte tracker cleanup * * @param tc connection for which the byte tracker should be cleaned up */ void tcp_bt_cleanup (tcp_connection_t * tc); /** * Flush byte tracker samples * * @param tc tcp connection for which samples should be flushed */ void tcp_bt_flush_samples (tcp_connection_t * tc); /** * Track a tcp tx burst * * @param tc tcp connection */ void tcp_bt_track_tx (tcp_connection_t * tc, u32 len); /** * Track a tcp retransmission * * @param tc tcp connection * @param start start sequence number * @param end end sequence number */ void tcp_bt_track_rxt (tcp_connection_t * tc, u32 start, u32 end); /** * Generate a delivery rate sample from recently acked bytes * * @param tc tcp connection * @param rs resulting rate sample */ void tcp_bt_sample_delivery_rate (tcp_connection_t * tc, tcp_rate_sample_t * rs); /** * Check if sample to be generated is app limited * * @param tc tcp connection */ void tcp_bt_check_app_limited (tcp_connection_t * tc); /** * Check if the byte tracker is in sane state * * Should be used only for testing * * @param bt byte tracker */ int tcp_bt_is_sane (tcp_byte_tracker_t * bt); u8 *format_tcp_bt (u8 * s, va_list * args); always_inline u32 tcp_end_seq (tcp_header_t * th, u32 len) { return th->seq_number + tcp_is_syn (th) + tcp_is_fin (th) + len; } /* Modulo arithmetic for TCP sequence numbers */ #define seq_lt(_s1, _s2) ((i32)((_s1)-(_s2)) < 0) #define seq_leq(_s1, _s2) ((i32)((_s1)-(_s2)) <= 0) #define seq_gt(_s1, _s2) ((i32)((_s1)-(_s2)) > 0) #define seq_geq(_s1, _s2) ((i32)((_s1)-(_s2)) >= 0) #define seq_max(_s1, _s2) (seq_gt((_s1), (_s2)) ? (_s1) : (_s2)) /* Modulo arithmetic for timestamps */ #define timestamp_lt(_t1, _t2) ((i32)((_t1)-(_t2)) < 0) #define timestamp_leq(_t1, _t2) ((i32)((_t1)-(_t2)) <= 0) /** * Our estimate of the number of bytes that have left the network */ always_inline u32 tcp_bytes_out (const tcp_connection_t * tc) { if (tcp_opts_sack_permitted (&tc->rcv_opts)) return tc->sack_sb.sacked_bytes + tc->sack_sb.lost_bytes; else return clib_min (tc->rcv_dupacks * tc->snd_mss, tc->snd_nxt - tc->snd_una); } /** * Our estimate of the number of bytes in flight (pipe size) */ always_inline u32 tcp_flight_size (const tcp_connection_t * tc) { int flight_size; flight_size = (int) (tc->snd_nxt - tc->snd_una) - tcp_bytes_out (tc) + tc->snd_rxt_bytes - tc->rxt_delivered; ASSERT (flight_size >= 0); return flight_size; } /** * Initial cwnd as per RFC5681 */ always_inline u32 tcp_initial_cwnd (const tcp_connection_t * tc) { if (tcp_cfg.initial_cwnd_multiplier > 0) return tcp_cfg.initial_cwnd_multiplier * tc->snd_mss; if (tc->snd_mss > 2190) return 2 * tc->snd_mss; else if (tc->snd_mss > 1095) return 3 * tc->snd_mss; else return 4 * tc->snd_mss; } /* * Accumulate acked bytes for cwnd increase * * Once threshold bytes are accumulated, snd_mss bytes are added * to the cwnd. */ always_inline void tcp_cwnd_accumulate (tcp_connection_t * tc, u32 thresh, u32 bytes) { tc->cwnd_acc_bytes += bytes; if (tc->cwnd_acc_bytes >= thresh) { u32 inc = tc->cwnd_acc_bytes / thresh; tc->cwnd_acc_bytes -= inc * thresh; tc->cwnd += inc * tc->snd_mss; tc->cwnd = clib_min (tc->cwnd, tc->tx_fifo_size); } } always_inline u32 tcp_loss_wnd (const tcp_connection_t * tc) { /* Whatever we have in flight + the packet we're about to send */ return tcp_flight_size (tc) + tc->snd_mss; } always_inline u32 tcp_available_snd_wnd (const tcp_connection_t * tc) { return clib_min (tc->cwnd, tc->snd_wnd); } always_inline u32 tcp_available_output_snd_space (const tcp_connection_t * tc) { u32 available_wnd = tcp_available_snd_wnd (tc); int flight_size = (int) (tc->snd_nxt - tc->snd_una); if (available_wnd <= flight_size) return 0; return available_wnd - flight_size; } /** * Estimate of how many bytes we can still push into the network */ always_inline u32 tcp_available_cc_snd_space (const tcp_connection_t * tc) { u32 available_wnd = tcp_available_snd_wnd (tc); u32 flight_size = tcp_flight_size (tc); if (available_wnd <= flight_size) return 0; return available_wnd - flight_size; } static inline u8 tcp_is_descheduled (tcp_connection_t * tc) { return (transport_connection_is_descheduled (&tc->connection) ? 1 : 0); } always_inline u8 tcp_is_lost_fin (tcp_connection_t * tc) { if ((tc->flags & TCP_CONN_FINSNT) && (tc->snd_una_max - tc->snd_una == 1)) return 1; return 0; } u32 tcp_snd_space (tcp_connection_t * tc); int tcp_fastrecovery_prr_snd_space (tcp_connection_t * tc); void tcp_reschedule (tcp_connection_t * tc); fib_node_index_t tcp_lookup_rmt_in_fib (tcp_connection_t * tc); /* Made public for unit testing only */ void tcp_update_sack_list (tcp_connection_t * tc, u32 start, u32 end); u32 tcp_sack_list_bytes (tcp_connection_t * tc); always_inline u32 tcp_time_now (void) { return tcp_main.wrk_ctx[vlib_get_thread_index ()].time_now; } always_inline u32 tcp_time_now_w_thread (u32 thread_index) { return tcp_main.wrk_ctx[thread_index].time_now; } /** * Generate timestamp for tcp connection */ always_inline u32 tcp_tstamp (tcp_connection_t * tc) { return (tcp_main.wrk_ctx[tc->c_thread_index].time_now - tc->timestamp_delta); } always_inline f64 tcp_time_now_us (u32 thread_index) { return transport_time_now (thread_index); } always_inline u32 tcp_set_time_now (tcp_worker_ctx_t * wrk) { wrk->time_now = clib_cpu_time_now () * tcp_main.tstamp_ticks_per_clock; return wrk->time_now; } u32 tcp_session_push_header (transport_connection_t * tconn, vlib_buffer_t * b); int tcp_session_custom_tx (void *conn, u32 max_burst_size); void tcp_connection_timers_init (tcp_connection_t * tc); void tcp_connection_timers_reset (tcp_connection_t * tc); void tcp_init_snd_vars (tcp_connection_t * tc); void tcp_connection_init_vars (tcp_connection_t * tc); void tcp_connection_tx_pacer_update (tcp_connection_t * tc); void tcp_connection_tx_pacer_reset (tcp_connection_t * tc, u32 window, u32 start_bucket); void tcp_program_cleanup (tcp_worker_ctx_t * wrk, tcp_connection_t * tc); always_inline void tcp_cc_rcv_ack (tcp_connection_t * tc, tcp_rate_sample_t * rs) { tc->cc_algo->rcv_ack (tc, rs); tc->tsecr_last_ack = tc->rcv_opts.tsecr; } static inline void tcp_cc_rcv_cong_ack (tcp_connection_t * tc, tcp_cc_ack_t ack_type, tcp_rate_sample_t * rs) { tc->cc_algo->rcv_cong_ack (tc, ack_type, rs); } static inline void tcp_cc_congestion (tcp_connection_t * tc) { tc->cc_algo->congestion (tc); } static inline void tcp_cc_loss (tcp_connection_t * tc) { tc->cc_algo->loss (tc); } static inline void tcp_cc_recovered (tcp_connection_t * tc) { tc->cc_algo->recovered (tc); } static inline void tcp_cc_undo_recovery (tcp_connection_t * tc) { if (tc->cc_algo->undo_recovery) tc->cc_algo->undo_recovery (tc); } static inline void tcp_cc_event (tcp_connection_t * tc, tcp_cc_event_t evt) { if (tc->cc_algo->event) tc->cc_algo->event (tc, evt); } static inline u64 tcp_cc_get_pacing_rate (tcp_connection_t * tc) { if (tc->cc_algo->get_pacing_rate) return tc->cc_algo->get_pacing_rate (tc); f64 srtt = clib_min ((f64) tc->srtt * TCP_TICK, tc->mrtt_us); /* TODO should constrain to interface's max throughput but * we don't have link speeds for sw ifs ..*/ return ((f64) tc->cwnd / srtt); } always_inline void tcp_timer_set (tcp_connection_t * tc, u8 timer_id, u32 interval) { ASSERT (tc->c_thread_index == vlib_get_thread_index ()); ASSERT (tc->timers[timer_id] == TCP_TIMER_HANDLE_INVALID); tc->timers[timer_id] = tw_timer_start_16t_2w_512sl (&tcp_main. wrk_ctx[tc->c_thread_index].timer_wheel, tc->c_c_index, timer_id, interval); } always_inline void tcp_timer_reset (tcp_connection_t * tc, u8 timer_id) { ASSERT (tc->c_thread_index == vlib_get_thread_index ()); if (tc->timers[timer_id] == TCP_TIMER_HANDLE_INVALID) return; tw_timer_stop_16t_2w_512sl (&tcp_main. wrk_ctx[tc->c_thread_index].timer_wheel, tc->timers[timer_id]); tc->timers[timer_id] = TCP_TIMER_HANDLE_INVALID; } always_inline void tcp_timer_update (tcp_connection_t * tc, u8 timer_id, u32 interval) { ASSERT (tc->c_thread_index == vlib_get_thread_index ()); if (tc->timers[timer_id] != TCP_TIMER_HANDLE_INVALID) tw_timer_update_16t_2w_512sl (&tcp_main. wrk_ctx[tc->c_thread_index].timer_wheel, tc->timers[timer_id], interval); else tc->timers[timer_id] = tw_timer_start_16t_2w_512sl (&tcp_main. wrk_ctx[tc->c_thread_index].timer_wheel, tc->c_c_index, timer_id, interval); } always_inline void tcp_retransmit_timer_set (tcp_connection_t * tc) { ASSERT (tc->snd_una != tc->snd_una_max); tcp_timer_set (tc, TCP_TIMER_RETRANSMIT, clib_max (tc->rto * TCP_TO_TIMER_TICK, 1)); } always_inline void tcp_retransmit_timer_reset (tcp_connection_t * tc) { tcp_timer_reset (tc, TCP_TIMER_RETRANSMIT); } always_inline void tcp_retransmit_timer_force_update (tcp_connection_t * tc) { tcp_timer_update (tc, TCP_TIMER_RETRANSMIT, clib_max (tc->rto * TCP_TO_TIMER_TICK, 1)); } always_inline void tcp_persist_timer_set (tcp_connection_t * tc) { /* Reuse RTO. It's backed off in handler */ tcp_timer_set (tc, TCP_TIMER_PERSIST, clib_max (tc->rto * TCP_TO_TIMER_TICK, 1)); } always_inline void tcp_persist_timer_update (tcp_connection_t * tc) { u32 interval; if (seq_leq (tc->snd_una, tc->snd_congestion + tc->burst_acked)) interval = 1; else interval = clib_max (tc->rto * TCP_TO_TIMER_TICK, 1); tcp_timer_update (tc, TCP_TIMER_PERSIST, interval); } always_inline void tcp_persist_timer_reset (tcp_connection_t * tc) { tcp_timer_reset (tc, TCP_TIMER_PERSIST); } always_inline void tcp_retransmit_timer_update (tcp_connection_t * tc) { if (tc->snd_una == tc->snd_nxt) { tcp_retransmit_timer_reset (tc); if (tc->snd_wnd < tc->snd_mss) tcp_persist_timer_update (tc); } else tcp_timer_update (tc, TCP_TIMER_RETRANSMIT, clib_max (tc->rto * TCP_TO_TIMER_TICK, 1)); } always_inline u8 tcp_timer_is_active (tcp_connection_t * tc, tcp_timers_e timer) { return tc->timers[timer] != TCP_TIMER_HANDLE_INVALID; } #define tcp_validate_txf_size(_tc, _a) \ ASSERT(_tc->state != TCP_STATE_ESTABLISHED \ || transport_max_tx_dequeue (&_tc->connection) >= _a) void tcp_rcv_sacks (tcp_connection_t * tc, u32 ack); u8 *tcp_scoreboard_replay (u8 * s, tcp_connection_t * tc, u8 verbose); /** * Register exiting cc algo type */ void tcp_cc_algo_register (tcp_cc_algorithm_type_e type, const tcp_cc_algorithm_t * vft); /** * Register new cc algo type */ tcp_cc_algorithm_type_e tcp_cc_algo_new_type (const tcp_cc_algorithm_t * vft); tcp_cc_algorithm_t *tcp_cc_algo_get (tcp_cc_algorithm_type_e type); static inline void * tcp_cc_data (tcp_connection_t * tc) { return (void *) tc->cc_data; } void newreno_rcv_cong_ack (tcp_connection_t * tc, tcp_cc_ack_t ack_type, tcp_rate_sample_t * rs); /** * Initialize connection by gleaning network and rcv params from buffer * * @param tc connection to initialize * @param b buffer whose current data is pointing at ip * @param is_ip4 flag set to 1 if using ip4 */ void tcp_init_w_buffer (tcp_connection_t * tc, vlib_buffer_t * b, u8 is_ip4); /** * Push TCP header to buffer * * @param vm - vlib_main * @param b - buffer to write the header to * @param sp_net - source port net order * @param dp_net - destination port net order * @param seq - sequence number net order * @param ack - ack number net order * @param tcp_hdr_opts_len - header and options length in bytes * @param flags - header flags * @param wnd - window size * * @return - pointer to start of TCP header */ always_inline void * vlib_buffer_push_tcp_net_order (vlib_buffer_t * b, u16 sp, u16 dp, u32 seq, u32 ack, u8 tcp_hdr_opts_len, u8 flags, u16 wnd) { tcp_header_t *th; th = vlib_buffer_push_uninit (b, tcp_hdr_opts_len); th->src_port = sp; th->dst_port = dp; th->seq_number = seq; th->ack_number = ack; th->data_offset_and_reserved = (tcp_hdr_opts_len >> 2) << 4; th->flags = flags; th->window = wnd; th->checksum = 0; th->urgent_pointer = 0; vnet_buffer (b)->l4_hdr_offset = (u8 *) th - b->data; b->flags |= VNET_BUFFER_F_L4_HDR_OFFSET_VALID; return th; } /** * Push TCP header to buffer * * @param b - buffer to write the header to * @param sp_net - source port net order * @param dp_net - destination port net order * @param seq - sequence number host order * @param ack - ack number host order * @param tcp_hdr_opts_len - header and options length in bytes * @param flags - header flags * @param wnd - window size * * @return - pointer to start of TCP header */ always_inline void * vlib_buffer_push_tcp (vlib_buffer_t * b, u16 sp_net, u16 dp_net, u32 seq, u32 ack, u8 tcp_hdr_opts_len, u8 flags, u16 wnd) { return vlib_buffer_push_tcp_net_order (b, sp_net, dp_net, clib_host_to_net_u32 (seq), clib_host_to_net_u32 (ack), tcp_hdr_opts_len, flags, clib_host_to_net_u16 (wnd)); } #endif /* _vnet_tcp_h_ */ /* * fd.io coding-style-patch-verification: ON * * Local Variables: * eval: (c-set-style "gnu") * End: */