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gerrit.nordix.org / fdio / vpp / c31dc31f84961033ecb6354811e0c360b6cf5f79 / . / src / vnet / session / transport.c
blob: 8f7e30c86025a5f30c4be27aae565dc348de263f [file] [log] [blame]
/*
* 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 <vnet/session/transport.h>
#include <vnet/session/session.h>
#include <vnet/fib/fib.h>
/**
* Per-type vector of transport protocol virtual function tables
*/
transport_proto_vft_t *tp_vfts;
/*
* Port allocator seed
*/
static u32 port_allocator_seed;
/*
* Local endpoints table
*/
static transport_endpoint_table_t local_endpoints_table;
/*
* Pool of local endpoints
*/
static transport_endpoint_t *local_endpoints;
/*
* Local endpoints pool lock
*/
static clib_spinlock_t local_endpoints_lock;
/*
* Period used by transport pacers. Initialized by session layer
*/
static double transport_pacer_period;
u8 *
format_transport_proto (u8 * s, va_list * args)
{
u32 transport_proto = va_arg (*args, u32);
switch (transport_proto)
{
#define _(sym, str, sstr) \
case TRANSPORT_PROTO_ ## sym: \
s = format (s, str); \
break;
foreach_transport_proto
#undef _
default:
s = format (s, "UNKNOWN");
break;
}
return s;
}
u8 *
format_transport_proto_short (u8 * s, va_list * args)
{
u32 transport_proto = va_arg (*args, u32);
switch (transport_proto)
{
#define _(sym, str, sstr) \
case TRANSPORT_PROTO_ ## sym: \
s = format (s, sstr); \
break;
foreach_transport_proto
#undef _
default:
s = format (s, "?");
break;
}
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 && transport_connection_is_tx_paced (tc) && verbose > 1)
{
indent = format_get_indent (s) + 1;
s = format (s, "%Upacer: %U\n", format_white_space, indent,
format_transport_pacer, &tc->pacer);
}
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 listen_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, listen_index);
return s;
}
uword
unformat_transport_proto (unformat_input_t * input, va_list * args)
{
u32 *proto = va_arg (*args, u32 *);
#define _(sym, str, sstr) \
if (unformat (input, str)) \
{ \
*proto = TRANSPORT_PROTO_ ## sym; \
return 1; \
}
foreach_transport_proto
#undef _
return 0;
}
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);
}
/**
* Register transport virtual function table.
*
* @param transport_proto - transport protocol type (i.e., TCP, UDP ..)
* @param vft - virtual function table for transport proto
* @param fib_proto - network layer protocol
* @param output_node - output node index that session layer will hand off
* buffers to, for requested fib proto
*/
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);
}
/**
* 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];
}
u8
transport_half_open_has_fifos (transport_proto_t tp)
{
return tp_vfts[tp].transport_options.half_open_has_fifos;
}
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);
}
int
transport_connect (transport_proto_t tp, transport_endpoint_cfg_t * tep)
{
return tp_vfts[tp].connect (tep);
}
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_t * tep)
{
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);
}
}
#define PORT_MASK ((1 << 16)- 1)
void
transport_endpoint_del (u32 tepi)
{
clib_spinlock_lock_if_init (&local_endpoints_lock);
pool_put_index (local_endpoints, tepi);
clib_spinlock_unlock_if_init (&local_endpoints_lock);
}
always_inline transport_endpoint_t *
transport_endpoint_new (void)
{
transport_endpoint_t *tep;
pool_get_zero (local_endpoints, tep);
return tep;
}
void
transport_endpoint_cleanup (u8 proto, ip46_address_t * lcl_ip, u16 port)
{
u32 tepi;
transport_endpoint_t *tep;
/* Cleanup local endpoint if this was an active connect */
tepi = transport_endpoint_lookup (&local_endpoints_table, proto, lcl_ip,
clib_net_to_host_u16 (port));
if (tepi != ENDPOINT_INVALID_INDEX)
{
tep = pool_elt_at_index (local_endpoints, tepi);
transport_endpoint_table_del (&local_endpoints_table, proto, tep);
transport_endpoint_del (tepi);
}
}
static void
transport_endpoint_mark_used (u8 proto, ip46_address_t * ip, u16 port)
{
transport_endpoint_t *tep;
clib_spinlock_lock_if_init (&local_endpoints_lock);
tep = transport_endpoint_new ();
clib_memcpy_fast (&tep->ip, ip, sizeof (*ip));
tep->port = port;
transport_endpoint_table_add (&local_endpoints_table, proto, tep,
tep - local_endpoints);
clib_spinlock_unlock_if_init (&local_endpoints_lock);
}
/**
* 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 ? */
int tries, limit;
u32 tei;
limit = max - min;
/* Only support active opens from thread 0 */
ASSERT (vlib_get_thread_index () == 0);
/* 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 (&port_allocator_seed) & PORT_MASK;
if (PREDICT_TRUE (port >= min && port < max))
break;
}
/* Look it up. If not found, we're done */
tei = transport_endpoint_lookup (&local_endpoints_table, proto, ip,
port);
if (tei == ENDPOINT_INVALID_INDEX)
{
transport_endpoint_mark_used (proto, ip, port);
return port;
}
}
return -1;
}
static clib_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 clib_error_return (0, "no routable ip4 address on %U",
format_vnet_sw_if_index_name,
vnet_get_main (), sw_if_index);
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 clib_error_return (0, "no routable ip6 addresses on %U",
format_vnet_sw_if_index_name,
vnet_get_main (), sw_if_index);
clib_memcpy_fast (&addr->ip6, ip6, sizeof (*ip6));
}
return 0;
}
static clib_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 clib_error_return (0, "no route to %U", format_ip46_address,
&rmt->ip, (rmt->is_ip4 == 0) + 1);
sw_if_index = fib_entry_get_resolving_interface (fei);
if (sw_if_index == ENDPOINT_INVALID_INDEX)
return clib_error_return (0, "no resolving interface for %U",
format_ip46_address, &rmt->ip,
(rmt->is_ip4 == 0) + 1);
}
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;
clib_error_t *error;
int port;
u32 tei;
/*
* 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)
{
clib_error_report (error);
return -1;
}
}
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)
{
clib_warning ("Failed to allocate src port");
return -1;
}
*lcl_port = port;
}
else
{
port = clib_net_to_host_u16 (rmt_cfg->peer.port);
tei = transport_endpoint_lookup (&local_endpoints_table, proto,
lcl_addr, port);
if (tei != ENDPOINT_INVALID_INDEX)
return -1;
transport_endpoint_mark_used (proto, lcl_addr, port);
*lcl_port = port;
}
return 0;
}
#define SPACER_CPU_TICKS_PER_PERIOD_SHIFT 10
#define SPACER_CPU_TICKS_PER_PERIOD (1 << SPACER_CPU_TICKS_PER_PERIOD_SHIFT)
u8 *
format_transport_pacer (u8 * s, va_list * args)
{
spacer_t *pacer = va_arg (*args, spacer_t *);
vlib_main_t *vm = vlib_get_main ();
u64 now, diff;
now = vm->clib_time.last_cpu_time;
diff = now - (pacer->last_update << SPACER_CPU_TICKS_PER_PERIOD_SHIFT);
s = format (s, "rate %u bucket %u t/p %.3f last_update %.3f",
pacer->bytes_per_sec, pacer->bucket, pacer->tokens_per_period,
diff * vm->clib_time.seconds_per_clock);
return s;
}
static inline u32
spacer_max_burst (spacer_t * pacer, u64 norm_time_now)
{
u64 n_periods = norm_time_now - pacer->last_update;
u64 inc;
if (PREDICT_FALSE (n_periods > 5e5))
{
pacer->last_update = norm_time_now;
pacer->bucket = TRANSPORT_PACER_MIN_BURST;
return TRANSPORT_PACER_MIN_BURST;
}
if (n_periods > 0
&& (inc = (f32) n_periods * pacer->tokens_per_period) > 10)
{
pacer->last_update = norm_time_now;
pacer->bucket = clib_min (pacer->bucket + inc, pacer->bytes_per_sec);
}
return clib_min (pacer->bucket, TRANSPORT_PACER_MAX_BURST);
}
static inline void
spacer_update_bucket (spacer_t * pacer, u32 bytes)
{
ASSERT (pacer->bucket >= bytes);
pacer->bucket -= bytes;
}
static inline void
spacer_set_pace_rate (spacer_t * pacer, u64 rate_bytes_per_sec)
{
ASSERT (rate_bytes_per_sec != 0);
pacer->bytes_per_sec = rate_bytes_per_sec;
pacer->tokens_per_period = rate_bytes_per_sec / transport_pacer_period;
}
static inline u64
spacer_pace_rate (spacer_t * pacer)
{
return pacer->bytes_per_sec;
}
static inline void
spacer_reset_bucket (spacer_t * pacer, u64 norm_time_now)
{
pacer->last_update = norm_time_now;
pacer->bucket = 0;
}
void
transport_connection_tx_pacer_reset (transport_connection_t * tc,
u32 rate_bytes_per_sec,
u32 start_bucket, u64 time_now)
{
spacer_t *pacer = &tc->pacer;
spacer_set_pace_rate (&tc->pacer, rate_bytes_per_sec);
pacer->last_update = time_now >> SPACER_CPU_TICKS_PER_PERIOD_SHIFT;
pacer->bucket = start_bucket;
}
void
transport_connection_tx_pacer_init (transport_connection_t * tc,
u32 rate_bytes_per_sec,
u32 initial_bucket)
{
vlib_main_t *vm = vlib_get_main ();
tc->flags |= TRANSPORT_CONNECTION_F_IS_TX_PACED;
transport_connection_tx_pacer_reset (tc, rate_bytes_per_sec,
initial_bucket,
vm->clib_time.last_cpu_time);
}
void
transport_connection_tx_pacer_update (transport_connection_t * tc,
u64 bytes_per_sec)
{
spacer_set_pace_rate (&tc->pacer, bytes_per_sec);
}
u32
transport_connection_tx_pacer_burst (transport_connection_t * tc,
u64 time_now)
{
time_now >>= SPACER_CPU_TICKS_PER_PERIOD_SHIFT;
return spacer_max_burst (&tc->pacer, time_now);
}
void
transport_connection_tx_pacer_reset_bucket (transport_connection_t * tc,
u64 time_now)
{
time_now >>= SPACER_CPU_TICKS_PER_PERIOD_SHIFT;
spacer_reset_bucket (&tc->pacer, time_now);
}
u32
transport_connection_snd_space (transport_connection_t * tc, u64 time_now,
u16 mss)
{
u32 snd_space, max_paced_burst;
snd_space = tp_vfts[tc->proto].send_space (tc);
if (snd_space && transport_connection_is_tx_paced (tc))
{
time_now >>= SPACER_CPU_TICKS_PER_PERIOD_SHIFT;
max_paced_burst = spacer_max_burst (&tc->pacer, time_now);
max_paced_burst =
(max_paced_burst < TRANSPORT_PACER_MIN_BURST) ? 0 : max_paced_burst;
snd_space = clib_min (snd_space, max_paced_burst);
return snd_space >= mss ? snd_space - snd_space % mss : snd_space;
}
return snd_space;
}
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_init_tx_pacers_period (void)
{
f64 cpu_freq = os_cpu_clock_frequency ();
transport_pacer_period = cpu_freq / SPACER_CPU_TICKS_PER_PERIOD;
}
void
transport_update_time (f64 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);
}
}
void
transport_init (void)
{
vlib_thread_main_t *vtm = vlib_get_thread_main ();
session_main_t *smm = vnet_get_session_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 */
port_allocator_seed = (u32) clib_cpu_time_now ();
clib_bihash_init_24_8 (&local_endpoints_table, "local endpoints table",
smm->local_endpoints_table_buckets,
smm->local_endpoints_table_memory);
num_threads = 1 /* main thread */ + vtm->n_threads;
if (num_threads > 1)
clib_spinlock_init (&local_endpoints_lock);
}
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/