blob: a13a30dcb728d59612d1efafed700fc668dec08a [file] [log] [blame]
/*
* 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 <vnet/vnet.h>
#include <vnet/ip/ip.h>
#include <vnet/tcp/tcp_packet.h>
#include <vnet/tcp/tcp_timer.h>
#include <vnet/session/transport.h>
#include <vnet/session/session.h>
#include <vnet/tcp/tcp_debug.h>
#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_DUPACK_THRESHOLD 3
#define TCP_MAX_RX_FIFO_SIZE 32 << 20
#define TCP_MIN_RX_FIFO_SIZE 4 << 10
#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") \
_(KEEP, "KEEP") \
_(WAITCLOSE, "WAIT CLOSE") \
_(RETRANSMIT_SYN, "RETRANSMIT SYN") \
_(ESTABLISH, "ESTABLISH") \
_(ESTABLISH_AO, "ESTABLISH_AO") \
typedef enum _tcp_timers
{
#define _(sym, str) TCP_TIMER_##sym,
foreach_tcp_timer
#undef _
TCP_N_TIMERS
} tcp_timers_e;
typedef void (timer_expiration_handler) (u32 index);
extern timer_expiration_handler tcp_timer_delack_handler;
extern timer_expiration_handler tcp_timer_retransmit_handler;
extern timer_expiration_handler tcp_timer_persist_handler;
extern timer_expiration_handler tcp_timer_retransmit_syn_handler;
#define TCP_TIMER_HANDLE_INVALID ((u32) ~0)
/* Timer delays as multiples of 100ms */
#define TCP_TO_TIMER_TICK TCP_TICK*10 /* Period for converting from TCP
* ticks to timer units */
#define TCP_DELACK_TIME 1 /* 0.1s */
#define TCP_ESTABLISH_TIME 750 /* 75s */
#define TCP_SYN_RCVD_TIME 600 /* 60s */
#define TCP_2MSL_TIME 300 /* 30s */
#define TCP_CLOSEWAIT_TIME 20 /* 2s */
#define TCP_TIMEWAIT_TIME 100 /* 10s */
#define TCP_FINWAIT1_TIME 600 /* 60s */
#define TCP_CLEANUP_TIME 1 /* 0.1s */
#define TCP_TIMER_PERSIST_MIN 2 /* 0.2s */
#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 */
/** 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") \
_(FRXT_PENDING, "Fast-retransmit pending") \
_(FRXT_FIRST, "Fast-retransmit first again") \
_(DEQ_PENDING, "Pending dequeue acked") \
_(PSH_PENDING, "PSH pending") \
_(FINRCVD, "FIN received") \
_(RATE_SAMPLE, "Conn does rate sampling") \
_(TRACK_BURST, "Track burst") \
_(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 snd_una_adv; /**< Bytes to add to snd_una */
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 cur_rxt_hole; /**< Retransmitting from this hole */
#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; \
_elt->snd_una_max = _elt->end == _ack ? _tc->snd_una_max : 0; \
_elt->group = _group; \
} \
}
#else
#define tcp_scoreboard_trace_add(_tc, _ack)
#endif
sack_scoreboard_hole_t *scoreboard_next_rxt_hole (sack_scoreboard_t * sb,
sack_scoreboard_hole_t *
start, u8 have_sent_1_smss,
u8 * can_rescue,
u8 * snd_limited);
sack_scoreboard_hole_t *scoreboard_get_hole (sack_scoreboard_t * sb,
u32 index);
sack_scoreboard_hole_t *scoreboard_next_hole (sack_scoreboard_t * sb,
sack_scoreboard_hole_t * hole);
sack_scoreboard_hole_t *scoreboard_prev_hole (sack_scoreboard_t * sb,
sack_scoreboard_hole_t * hole);
sack_scoreboard_hole_t *scoreboard_first_hole (sack_scoreboard_t * sb);
sack_scoreboard_hole_t *scoreboard_last_hole (sack_scoreboard_t * sb);
void scoreboard_clear (sack_scoreboard_t * sb);
void scoreboard_init (sack_scoreboard_t * sb);
u8 *format_tcp_scoreboard (u8 * s, va_list * args);
#define TCP_BTS_INVALID_INDEX ((u32)~0)
typedef enum tcp_bts_flags_
{
TCP_BTS_IS_RXT = 1,
TCP_BTS_IS_APP_LIMITED = 1 << 1,
} __clib_packed tcp_bts_flags_t;
typedef struct tcp_bt_sample_
{
u32 next; /**< Next sample index in list */
u32 prev; /**< Previous sample index in list */
u32 min_seq; /**< Min seq number in sample */
u32 max_seq; /**< Max seq number. Set for rxt samples */
u64 delivered; /**< Total delivered when sample taken */
f64 delivered_time; /**< Delivered time when sample taken */
u64 tx_rate; /**< Tx pacing rate */
tcp_bts_flags_t flags; /**< Sample flag */
} tcp_bt_sample_t;
typedef struct tcp_rate_sample_
{
u64 sample_delivered; /**< Delivered of sample used for rate */
u32 delivered; /**< Bytes delivered in ack time */
f64 ack_time; /**< Time to ack the bytes delivered */
u64 tx_rate; /**< Tx pacing rate */
tcp_bts_flags_t flags; /**< Rate sample flags from bt sample */
} tcp_rate_sample_t;
typedef struct tcp_byte_tracker_
{
tcp_bt_sample_t *samples; /**< Pool of samples */
rb_tree_t sample_lookup; /**< Rbtree for sample lookup by min_seq */
u32 head; /**< Head of samples linked list */
u32 tail; /**< Tail of samples linked list */
u32 last_ooo; /**< Cached last ooo sample */
} tcp_byte_tracker_t;
typedef enum _tcp_cc_algorithm_type
{
TCP_CC_NEWRENO,
TCP_CC_CUBIC,
TCP_CC_LAST = TCP_CC_CUBIC
} tcp_cc_algorithm_type_e;
typedef struct _tcp_cc_algorithm tcp_cc_algorithm_t;
typedef enum _tcp_cc_ack_t
{
TCP_CC_ACK,
TCP_CC_DUPACK,
TCP_CC_PARTIALACK
} tcp_cc_ack_t;
typedef enum tcp_cc_event_
{
TCP_CC_EVT_START_TX,
} tcp_cc_event_t;
typedef struct _tcp_connection
{
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
transport_connection_t connection; /**< Common transport data. First! */
u8 state; /**< TCP state as per tcp_state_t */
u16 flags; /**< Connection flags (see tcp_conn_flags_e) */
u32 timers[TCP_N_TIMERS]; /**< Timer handles into timer wheel */
/* TODO RFC4898 */
/** Send sequence variables RFC793 */
u32 snd_una; /**< oldest unacknowledged sequence number */
u32 snd_una_max; /**< newest unacknowledged sequence number + 1*/
u32 snd_wnd; /**< send window */
u32 snd_wl1; /**< seq number used for last snd.wnd update */
u32 snd_wl2; /**< ack number used for last snd.wnd update */
u32 snd_nxt; /**< next seq number to be sent */
u16 snd_mss; /**< Effective send max seg (data) size */
/** Receive sequence variables RFC793 */
u32 rcv_nxt; /**< next sequence number expected */
u32 rcv_wnd; /**< receive window we expect */
u32 rcv_las; /**< rcv_nxt at last ack sent/rcv_wnd update */
u32 iss; /**< initial sent sequence */
u32 irs; /**< initial remote sequence */
/* Options */
u8 snd_opts_len; /**< Tx options len */
u8 rcv_wscale; /**< Window scale to advertise to peer */
u8 snd_wscale; /**< Window scale to use when sending */
u32 tsval_recent; /**< Last timestamp received */
u32 tsval_recent_age; /**< When last updated tstamp_recent*/
tcp_options_t snd_opts; /**< Tx options for connection */
tcp_options_t rcv_opts; /**< Rx options for connection */
sack_block_t *snd_sacks; /**< Vector of SACKs to send. XXX Fixed size? */
u8 snd_sack_pos; /**< Position in vec of first block to send */
sack_block_t *snd_sacks_fl; /**< Vector for building new list */
sack_scoreboard_t sack_sb; /**< SACK "scoreboard" that tracks holes */
u16 rcv_dupacks; /**< Number of DUPACKs received */
u8 pending_dupacks; /**< Number of DUPACKs to be sent */
/* Congestion control */
u32 cwnd; /**< Congestion window */
u32 cwnd_acc_bytes; /**< Bytes accumulated for cwnd increment */
u32 ssthresh; /**< Slow-start threshold */
u32 prev_ssthresh; /**< ssthresh before congestion */
u32 prev_cwnd; /**< ssthresh before congestion */
u32 bytes_acked; /**< Bytes acknowledged by current segment */
u32 burst_acked; /**< Bytes acknowledged in current burst */
u32 snd_rxt_bytes; /**< Retransmitted bytes */
u32 snd_rxt_ts; /**< Timestamp when first packet is retransmitted */
u32 tsecr_last_ack; /**< Timestamp echoed to us in last healthy ACK */
u32 snd_congestion; /**< snd_una_max when congestion is detected */
u32 tx_fifo_size; /**< Tx fifo size. Used to constrain cwnd */
tcp_cc_algorithm_t *cc_algo; /**< Congestion control algorithm */
u8 cc_data[TCP_CC_DATA_SZ]; /**< Congestion control algo private data */
/* RTT and RTO */
u32 rto; /**< Retransmission timeout */
u32 rto_boff; /**< Index for RTO backoff */
u32 srtt; /**< Smoothed RTT */
u32 rttvar; /**< Smoothed mean RTT difference. Approximates variance */
u32 rtt_seq; /**< Sequence number for tracked ACK */
f64 rtt_ts; /**< Timestamp for tracked ACK */
f64 mrtt_us; /**< High precision mrtt from tracked acks */
u32 psh_seq; /**< Add psh header for seg that includes this */
u32 next_node_index; /**< Can be used to control next node in output */
u32 next_node_opaque; /**< Opaque to pass to next node */
u32 limited_transmit; /**< snd_nxt when limited transmit starts */
u32 sw_if_index; /**< Interface for the connection */
/* Delivery rate estimation */
u64 delivered; /**< Total bytes delivered to peer */
u64 app_limited; /**< Delivered when app-limited detected */
f64 delivered_time; /**< Time last bytes were acked */
tcp_byte_tracker_t *bt; /**< Tx byte tracker */
u32 last_fib_check; /**< Last time we checked fib route for peer */
u16 mss; /**< Our max seg size that includes options */
u32 timestamp_delta;
} tcp_connection_t;
/* *INDENT-OFF* */
struct _tcp_cc_algorithm
{
const char *name;
uword (*unformat_cfg) (unformat_input_t * input);
void (*init) (tcp_connection_t * tc);
void (*cleanup) (tcp_connection_t * tc);
void (*rcv_ack) (tcp_connection_t * tc, tcp_rate_sample_t *rs);
void (*rcv_cong_ack) (tcp_connection_t * tc, tcp_cc_ack_t ack,
tcp_rate_sample_t *rs);
void (*congestion) (tcp_connection_t * tc);
void (*loss) (tcp_connection_t * tc);
void (*recovered) (tcp_connection_t * tc);
void (*undo_recovery) (tcp_connection_t * tc);
void (*event) (tcp_connection_t *tc, tcp_cc_event_t evt);
};
/* *INDENT-ON* */
#define tcp_fastrecovery_on(tc) (tc)->flags |= TCP_CONN_FAST_RECOVERY
#define tcp_fastrecovery_off(tc) (tc)->flags &= ~TCP_CONN_FAST_RECOVERY
#define tcp_recovery_on(tc) (tc)->flags |= TCP_CONN_RECOVERY
#define tcp_recovery_off(tc) (tc)->flags &= ~TCP_CONN_RECOVERY
#define tcp_in_fastrecovery(tc) ((tc)->flags & TCP_CONN_FAST_RECOVERY)
#define tcp_in_recovery(tc) ((tc)->flags & (TCP_CONN_RECOVERY))
#define tcp_in_slowstart(tc) (tc->cwnd < tc->ssthresh)
#define tcp_disconnect_pending(tc) ((tc)->flags & TCP_CONN_DCNT_PENDING)
#define tcp_disconnect_pending_on(tc) ((tc)->flags |= TCP_CONN_DCNT_PENDING)
#define tcp_disconnect_pending_off(tc) ((tc)->flags &= ~TCP_CONN_DCNT_PENDING)
#define tcp_fastrecovery_first(tc) ((tc)->flags & TCP_CONN_FRXT_FIRST)
#define tcp_fastrecovery_first_on(tc) ((tc)->flags |= TCP_CONN_FRXT_FIRST)
#define tcp_fastrecovery_first_off(tc) ((tc)->flags &= ~TCP_CONN_FRXT_FIRST)
#define tcp_in_cong_recovery(tc) ((tc)->flags & \
(TCP_CONN_FAST_RECOVERY | TCP_CONN_RECOVERY))
always_inline void
tcp_cong_recovery_off (tcp_connection_t * tc)
{
tc->flags &= ~(TCP_CONN_FAST_RECOVERY | TCP_CONN_RECOVERY);
tcp_fastrecovery_first_off (tc);
}
#define tcp_zero_rwnd_sent(tc) (tc)->flags &= TCP_CONN_ZERO_RWND_SENT
#define tcp_zero_rwnd_sent_on(tc) (tc)->flags |= TCP_CONN_ZERO_RWND_SENT
#define tcp_zero_rwnd_sent_off(tc) (tc)->flags &= ~TCP_CONN_ZERO_RWND_SENT
typedef enum _tcp_error
{
#define tcp_error(n,s) TCP_ERROR_##n,
#include <vnet/tcp/tcp_error.def>
#undef tcp_error
TCP_N_ERROR,
} tcp_error_t;
typedef struct _tcp_lookup_dispatch
{
u8 next, error;
} tcp_lookup_dispatch_t;
typedef struct tcp_worker_ctx_
{
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
/** worker time */
u32 time_now;
/** worker timer wheel */
tw_timer_wheel_16t_2w_512sl_t timer_wheel;
/** tx buffer free list */
u32 *tx_buffers;
/** tx frames for tcp 4/6 output nodes */
vlib_frame_t *tx_frames[2];
/** tx frames for ip 4/6 lookup nodes */
vlib_frame_t *ip_lookup_tx_frames[2];
/** vector of connections needing fast rxt */
u32 *pending_fast_rxt;
/** vector of connections now doing fast rxt */
u32 *ongoing_fast_rxt;
/** vector of connections that will do fast rxt */
u32 *postponed_fast_rxt;
/** vector of pending ack dequeues */
u32 *pending_deq_acked;
/** vector of pending acks */
u32 *pending_acks;
/** vector of pending disconnect notifications */
u32 *pending_disconnects;
/** convenience pointer to this thread's vlib main */
vlib_main_t *vm;
CLIB_CACHE_LINE_ALIGN_MARK (cacheline1);
/** cached 'on the wire' options for bursts */
u8 cached_opts[40];
} tcp_worker_ctx_t;
typedef struct tcp_iss_seed_
{
u64 first;
u64 second;
} tcp_iss_seed_t;
typedef struct _tcp_main
{
/* Per-worker thread tcp connection pools */
tcp_connection_t **connections;
/* Pool of listeners. */
tcp_connection_t *listener_pool;
/** Dispatch table by state and flags */
tcp_lookup_dispatch_t dispatch_table[TCP_N_STATES][64];
u8 log2_tstamp_clocks_per_tick;
f64 tstamp_ticks_per_clock;
/** per-worker context */
tcp_worker_ctx_t *wrk_ctx;
/* Pool of half-open connections on which we've sent a SYN */
tcp_connection_t *half_open_connections;
clib_spinlock_t half_open_lock;
/** vlib buffer size */
u32 bytes_per_buffer;
/* 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;
/*
* Configuration
*/
/* Flag that indicates if stack is on or off */
u8 is_enabled;
/** Max rx fifo size for a session. It is used in to compute the
* rfc 7323 window scaling factor */
u32 max_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;
/** Number of preallocated connections */
u32 preallocated_connections;
u32 preallocated_half_open_connections;
/** Vectors of src addresses. Optional unless one needs > 63K active-opens */
ip4_address_t *ip4_src_addresses;
u32 last_v4_address_rotor;
u32 last_v6_address_rotor;
ip6_address_t *ip6_src_addresses;
/** Enable tx pacing for new connections */
u8 tx_pacing;
u8 punt_unknown4;
u8 punt_unknown6;
/** fault-injection */
f64 buffer_fail_fraction;
/** Default congestion control algorithm type */
tcp_cc_algorithm_type_e cc_algo;
} 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;
always_inline tcp_main_t *
vnet_get_tcp_main ()
{
return &tcp_main;
}
always_inline tcp_worker_ctx_t *
tcp_get_worker (u32 thread_index)
{
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)
{
if (PREDICT_FALSE
(pool_is_free_index (tcp_main.connections[thread_index], conn_index)))
return 0;
return pool_elt_at_index (tcp_main.connections[thread_index], conn_index);
}
always_inline tcp_connection_t *
tcp_connection_get_if_valid (u32 conn_index, u32 thread_index)
{
if (tcp_main.connections[thread_index] == 0)
return 0;
if (pool_is_free_index (tcp_main.connections[thread_index], conn_index))
return 0;
return pool_elt_at_index (tcp_main.connections[thread_index], 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_DBG (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);
void tcp_connection_free (tcp_connection_t * tc);
void tcp_connection_reset (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);
always_inline tcp_connection_t *
tcp_listener_get (u32 tli)
{
return pool_elt_at_index (tcp_main.listener_pool, tli);
}
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_init_mss (tcp_connection_t * tc);
void tcp_update_burst_snd_vars (tcp_connection_t * tc);
void tcp_update_rto (tcp_connection_t * tc);
void tcp_flush_frame_to_output (tcp_worker_ctx_t * wrk, u8 is_ip4);
void tcp_flush_frames_to_output (tcp_worker_ctx_t * wrk);
void tcp_program_fastretransmit (tcp_worker_ctx_t * wrk,
tcp_connection_t * tc);
void tcp_do_fastretransmits (tcp_worker_ctx_t * wrk);
void tcp_program_ack (tcp_worker_ctx_t * wrk, tcp_connection_t * tc);
void tcp_program_dupack (tcp_worker_ctx_t * wrk, tcp_connection_t * tc);
void tcp_send_acks (tcp_worker_ctx_t * wrk);
void tcp_send_window_update_ack (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);
/**
* 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);
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 tc->rcv_dupacks * tc->snd_mss;
}
/**
* 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;
if (flight_size < 0)
{
if (0)
clib_warning
("Negative: %u %u %u dupacks %u sacked bytes %u flags %d",
tc->snd_una_max - tc->snd_una, tcp_bytes_out (tc),
tc->snd_rxt_bytes, tc->rcv_dupacks, tc->sack_sb.sacked_bytes,
tc->rcv_opts.flags);
return 0;
}
return flight_size;
}
/**
* Initial cwnd as per RFC5681
*/
always_inline u32
tcp_initial_cwnd (const tcp_connection_t * tc)
{
if (tcp_main.initial_cwnd_multiplier > 0)
return tcp_main.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)
{
return 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;
}
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_retransmit_first_unacked (tcp_worker_ctx_t * wrk,
tcp_connection_t * tc);
int tcp_fast_retransmit_no_sack (tcp_worker_ctx_t * wrk,
tcp_connection_t * tc, u32 burst_size);
int tcp_fast_retransmit_sack (tcp_worker_ctx_t * wrk, tcp_connection_t * tc,
u32 burst_size);
int tcp_fast_retransmit (tcp_worker_ctx_t * wrk, tcp_connection_t * tc,
u32 burst_size);
void tcp_cc_init_congestion (tcp_connection_t * tc);
void tcp_cc_fastrecovery_clear (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);
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);
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_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);
}
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,
TCP_TIMER_PERSIST_MIN));
}
always_inline void
tcp_persist_timer_update (tcp_connection_t * tc)
{
tcp_timer_update (tc, TCP_TIMER_PERSIST,
clib_max (tc->rto * TCP_TO_TIMER_TICK,
TCP_TIMER_PERSIST_MIN));
}
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);
/**
* 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;
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:
*/