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gerrit.nordix.org / fdio / vpp / 0d60a0f8280fa7c902230a38956b1653e1ec7f3e / . / src / vnet / session / session.c
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/*
* 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 Session and session manager
*/
#include <vnet/session/session.h>
#include <vnet/session/session_debug.h>
#include <vnet/session/application.h>
#include <vlibmemory/api.h>
#include <vnet/dpo/load_balance.h>
#include <vnet/fib/ip4_fib.h>
session_manager_main_t session_manager_main;
extern transport_proto_vft_t *tp_vfts;
static void
session_send_evt_to_thread (u64 session_handle, fifo_event_type_t evt_type,
u32 thread_index, void *fp, void *rpc_args)
{
session_fifo_event_t evt = { {0}, };
svm_queue_t *q;
u32 tries = 0, max_tries;
evt.event_type = evt_type;
if (evt_type == FIFO_EVENT_RPC)
{
evt.rpc_args.fp = fp;
evt.rpc_args.arg = rpc_args;
}
else
evt.session_handle = session_handle;
q = session_manager_get_vpp_event_queue (thread_index);
while (svm_queue_add (q, (u8 *) & evt, 1))
{
max_tries = vlib_get_current_process (vlib_get_main ())? 1e6 : 3;
if (tries++ == max_tries)
{
SESSION_DBG ("failed to enqueue evt");
break;
}
}
}
void
session_send_session_evt_to_thread (u64 session_handle,
fifo_event_type_t evt_type,
u32 thread_index)
{
session_send_evt_to_thread (session_handle, evt_type, thread_index, 0, 0);
}
void
session_send_rpc_evt_to_thread (u32 thread_index, void *fp, void *rpc_args)
{
if (thread_index != vlib_get_thread_index ())
session_send_evt_to_thread (0, FIFO_EVENT_RPC, thread_index, fp,
rpc_args);
else
{
void (*fnp) (void *) = fp;
fnp (rpc_args);
}
}
stream_session_t *
session_alloc (u32 thread_index)
{
session_manager_main_t *smm = &session_manager_main;
stream_session_t *s;
u8 will_expand = 0;
pool_get_aligned_will_expand (smm->sessions[thread_index], will_expand,
CLIB_CACHE_LINE_BYTES);
/* If we have peekers, let them finish */
if (PREDICT_FALSE (will_expand && vlib_num_workers ()))
{
clib_rwlock_writer_lock (&smm->peekers_rw_locks[thread_index]);
pool_get_aligned (session_manager_main.sessions[thread_index], s,
CLIB_CACHE_LINE_BYTES);
clib_rwlock_writer_unlock (&smm->peekers_rw_locks[thread_index]);
}
else
{
pool_get_aligned (session_manager_main.sessions[thread_index], s,
CLIB_CACHE_LINE_BYTES);
}
memset (s, 0, sizeof (*s));
s->session_index = s - session_manager_main.sessions[thread_index];
s->thread_index = thread_index;
return s;
}
void
session_free (stream_session_t * s)
{
pool_put (session_manager_main.sessions[s->thread_index], s);
if (CLIB_DEBUG)
memset (s, 0xFA, sizeof (*s));
}
int
session_alloc_fifos (segment_manager_t * sm, stream_session_t * s)
{
svm_fifo_t *server_rx_fifo = 0, *server_tx_fifo = 0;
u32 fifo_segment_index;
int rv;
if ((rv = segment_manager_alloc_session_fifos (sm, &server_rx_fifo,
&server_tx_fifo,
&fifo_segment_index)))
return rv;
/* Initialize backpointers */
server_rx_fifo->master_session_index = s->session_index;
server_rx_fifo->master_thread_index = s->thread_index;
server_tx_fifo->master_session_index = s->session_index;
server_tx_fifo->master_thread_index = s->thread_index;
s->server_rx_fifo = server_rx_fifo;
s->server_tx_fifo = server_tx_fifo;
s->svm_segment_index = fifo_segment_index;
return 0;
}
static stream_session_t *
session_alloc_for_connection (transport_connection_t * tc)
{
stream_session_t *s;
u32 thread_index = tc->thread_index;
ASSERT (thread_index == vlib_get_thread_index ()
|| transport_protocol_is_cl (tc->proto));
s = session_alloc (thread_index);
s->session_type = session_type_from_proto_and_ip (tc->proto, tc->is_ip4);
s->session_state = SESSION_STATE_CONNECTING;
s->enqueue_epoch = ~0;
/* Attach transport to session and vice versa */
s->connection_index = tc->c_index;
tc->s_index = s->session_index;
return s;
}
static int
session_alloc_and_init (segment_manager_t * sm, transport_connection_t * tc,
u8 alloc_fifos, stream_session_t ** ret_s)
{
stream_session_t *s;
int rv;
s = session_alloc_for_connection (tc);
if (alloc_fifos && (rv = session_alloc_fifos (sm, s)))
{
session_free (s);
*ret_s = 0;
return rv;
}
/* Add to the main lookup table */
session_lookup_add_connection (tc, session_handle (s));
*ret_s = s;
return 0;
}
/**
* Discards bytes from buffer chain
*
* It discards n_bytes_to_drop starting at first buffer after chain_b
*/
always_inline void
session_enqueue_discard_chain_bytes (vlib_main_t * vm, vlib_buffer_t * b,
vlib_buffer_t ** chain_b,
u32 n_bytes_to_drop)
{
vlib_buffer_t *next = *chain_b;
u32 to_drop = n_bytes_to_drop;
ASSERT (b->flags & VLIB_BUFFER_NEXT_PRESENT);
while (to_drop && (next->flags & VLIB_BUFFER_NEXT_PRESENT))
{
next = vlib_get_buffer (vm, next->next_buffer);
if (next->current_length > to_drop)
{
vlib_buffer_advance (next, to_drop);
to_drop = 0;
}
else
{
to_drop -= next->current_length;
next->current_length = 0;
}
}
*chain_b = next;
if (to_drop == 0)
b->total_length_not_including_first_buffer -= n_bytes_to_drop;
}
/**
* Enqueue buffer chain tail
*/
always_inline int
session_enqueue_chain_tail (stream_session_t * s, vlib_buffer_t * b,
u32 offset, u8 is_in_order)
{
vlib_buffer_t *chain_b;
u32 chain_bi, len, diff;
vlib_main_t *vm = vlib_get_main ();
u8 *data;
u32 written = 0;
int rv = 0;
if (is_in_order && offset)
{
diff = offset - b->current_length;
if (diff > b->total_length_not_including_first_buffer)
return 0;
chain_b = b;
session_enqueue_discard_chain_bytes (vm, b, &chain_b, diff);
chain_bi = vlib_get_buffer_index (vm, chain_b);
}
else
chain_bi = b->next_buffer;
do
{
chain_b = vlib_get_buffer (vm, chain_bi);
data = vlib_buffer_get_current (chain_b);
len = chain_b->current_length;
if (!len)
continue;
if (is_in_order)
{
rv = svm_fifo_enqueue_nowait (s->server_rx_fifo, len, data);
if (rv == len)
{
written += rv;
}
else if (rv < len)
{
return (rv > 0) ? (written + rv) : written;
}
else if (rv > len)
{
written += rv;
/* written more than what was left in chain */
if (written > b->total_length_not_including_first_buffer)
return written;
/* drop the bytes that have already been delivered */
session_enqueue_discard_chain_bytes (vm, b, &chain_b, rv - len);
}
}
else
{
rv = svm_fifo_enqueue_with_offset (s->server_rx_fifo, offset, len,
data);
if (rv)
{
clib_warning ("failed to enqueue multi-buffer seg");
return -1;
}
offset += len;
}
}
while ((chain_bi = (chain_b->flags & VLIB_BUFFER_NEXT_PRESENT)
? chain_b->next_buffer : 0));
if (is_in_order)
return written;
return 0;
}
/*
* Enqueue data for delivery to session peer. Does not notify peer of enqueue
* event but on request can queue notification events for later delivery by
* calling stream_server_flush_enqueue_events().
*
* @param tc Transport connection which is to be enqueued data
* @param b Buffer to be enqueued
* @param offset Offset at which to start enqueueing if out-of-order
* @param queue_event Flag to indicate if peer is to be notified or if event
* is to be queued. The former is useful when more data is
* enqueued and only one event is to be generated.
* @param is_in_order Flag to indicate if data is in order
* @return Number of bytes enqueued or a negative value if enqueueing failed.
*/
int
session_enqueue_stream_connection (transport_connection_t * tc,
vlib_buffer_t * b, u32 offset,
u8 queue_event, u8 is_in_order)
{
stream_session_t *s;
int enqueued = 0, rv, in_order_off;
s = session_get (tc->s_index, tc->thread_index);
if (is_in_order)
{
enqueued = svm_fifo_enqueue_nowait (s->server_rx_fifo,
b->current_length,
vlib_buffer_get_current (b));
if (PREDICT_FALSE ((b->flags & VLIB_BUFFER_NEXT_PRESENT)
&& enqueued >= 0))
{
in_order_off = enqueued > b->current_length ? enqueued : 0;
rv = session_enqueue_chain_tail (s, b, in_order_off, 1);
if (rv > 0)
enqueued += rv;
}
}
else
{
rv = svm_fifo_enqueue_with_offset (s->server_rx_fifo, offset,
b->current_length,
vlib_buffer_get_current (b));
if (PREDICT_FALSE ((b->flags & VLIB_BUFFER_NEXT_PRESENT) && !rv))
session_enqueue_chain_tail (s, b, offset + b->current_length, 0);
/* if something was enqueued, report even this as success for ooo
* segment handling */
return rv;
}
if (queue_event)
{
/* Queue RX event on this fifo. Eventually these will need to be flushed
* by calling stream_server_flush_enqueue_events () */
session_manager_main_t *smm = vnet_get_session_manager_main ();
u32 thread_index = s->thread_index;
u32 enqueue_epoch = smm->current_enqueue_epoch[tc->proto][thread_index];
if (s->enqueue_epoch != enqueue_epoch)
{
s->enqueue_epoch = enqueue_epoch;
vec_add1 (smm->session_to_enqueue[tc->proto][thread_index],
s - smm->sessions[thread_index]);
}
}
return enqueued;
}
int
session_enqueue_dgram_connection (stream_session_t * s,
session_dgram_hdr_t * hdr,
vlib_buffer_t * b, u8 proto, u8 queue_event)
{
int enqueued = 0, rv, in_order_off;
ASSERT (svm_fifo_max_enqueue (s->server_rx_fifo)
>= b->current_length + sizeof (*hdr));
svm_fifo_enqueue_nowait (s->server_rx_fifo, sizeof (session_dgram_hdr_t),
(u8 *) hdr);
enqueued = svm_fifo_enqueue_nowait (s->server_rx_fifo, b->current_length,
vlib_buffer_get_current (b));
if (PREDICT_FALSE ((b->flags & VLIB_BUFFER_NEXT_PRESENT) && enqueued >= 0))
{
in_order_off = enqueued > b->current_length ? enqueued : 0;
rv = session_enqueue_chain_tail (s, b, in_order_off, 1);
if (rv > 0)
enqueued += rv;
}
if (queue_event)
{
/* Queue RX event on this fifo. Eventually these will need to be flushed
* by calling stream_server_flush_enqueue_events () */
session_manager_main_t *smm = vnet_get_session_manager_main ();
u32 thread_index = s->thread_index;
u32 enqueue_epoch = smm->current_enqueue_epoch[proto][thread_index];
if (s->enqueue_epoch != enqueue_epoch)
{
s->enqueue_epoch = enqueue_epoch;
vec_add1 (smm->session_to_enqueue[proto][thread_index],
s - smm->sessions[thread_index]);
}
}
return enqueued;
}
/** Check if we have space in rx fifo to push more bytes */
u8
stream_session_no_space (transport_connection_t * tc, u32 thread_index,
u16 data_len)
{
stream_session_t *s = session_get (tc->s_index, thread_index);
if (PREDICT_FALSE (s->session_state != SESSION_STATE_READY))
return 1;
if (data_len > svm_fifo_max_enqueue (s->server_rx_fifo))
return 1;
return 0;
}
u32
session_tx_fifo_max_dequeue (transport_connection_t * tc)
{
stream_session_t *s = session_get (tc->s_index, tc->thread_index);
if (!s->server_tx_fifo)
return 0;
return svm_fifo_max_dequeue (s->server_tx_fifo);
}
int
stream_session_peek_bytes (transport_connection_t * tc, u8 * buffer,
u32 offset, u32 max_bytes)
{
stream_session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_peek (s->server_tx_fifo, offset, max_bytes, buffer);
}
u32
stream_session_dequeue_drop (transport_connection_t * tc, u32 max_bytes)
{
stream_session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_dequeue_drop (s->server_tx_fifo, max_bytes);
}
/**
* Notify session peer that new data has been enqueued.
*
* @param s Stream session for which the event is to be generated.
* @param block Flag to indicate if call should block if event queue is full.
*
* @return 0 on succes or negative number if failed to send notification.
*/
static int
session_enqueue_notify (stream_session_t * s, u8 block)
{
application_t *app;
session_fifo_event_t evt;
svm_queue_t *q;
if (PREDICT_FALSE (s->session_state == SESSION_STATE_CLOSED))
{
/* Session is closed so app will never clean up. Flush rx fifo */
svm_fifo_dequeue_drop_all (s->server_rx_fifo);
return 0;
}
/* Get session's server */
app = application_get_if_valid (s->app_index);
if (PREDICT_FALSE (app == 0))
{
clib_warning ("invalid s->app_index = %d", s->app_index);
return 0;
}
/* Built-in app? Hand event to the callback... */
if (app->cb_fns.builtin_app_rx_callback)
return app->cb_fns.builtin_app_rx_callback (s);
/* If no event, send one */
if (svm_fifo_set_event (s->server_rx_fifo))
{
/* Fabricate event */
evt.fifo = s->server_rx_fifo;
evt.event_type = FIFO_EVENT_APP_RX;
/* Add event to server's event queue */
q = app->event_queue;
/* Based on request block (or not) for lack of space */
if (block || PREDICT_TRUE (q->cursize < q->maxsize))
svm_queue_add (app->event_queue, (u8 *) & evt,
0 /* do wait for mutex */ );
else
{
clib_warning ("fifo full");
return -1;
}
}
/* *INDENT-OFF* */
SESSION_EVT_DBG(SESSION_EVT_ENQ, s, ({
ed->data[0] = evt.event_type;
ed->data[1] = svm_fifo_max_dequeue (s->server_rx_fifo);
}));
/* *INDENT-ON* */
return 0;
}
int
session_dequeue_notify (stream_session_t * s)
{
application_t *app;
svm_queue_t *q;
app = application_get (s->app_index);
if (application_is_builtin (app))
return 0;
q = app->event_queue;
if (PREDICT_TRUE (q->cursize < q->maxsize))
{
session_fifo_event_t evt = {
.event_type = FIFO_EVENT_APP_TX,
.fifo = s->server_tx_fifo
};
svm_queue_add (app->event_queue, (u8 *) & evt, SVM_Q_WAIT);
}
else
{
return -1;
}
return 0;
}
/**
* Flushes queue of sessions that are to be notified of new data
* enqueued events.
*
* @param thread_index Thread index for which the flush is to be performed.
* @return 0 on success or a positive number indicating the number of
* failures due to API queue being full.
*/
int
session_manager_flush_enqueue_events (u8 transport_proto, u32 thread_index)
{
session_manager_main_t *smm = &session_manager_main;
u32 *indices;
stream_session_t *s;
int i, errors = 0;
indices = smm->session_to_enqueue[transport_proto][thread_index];
for (i = 0; i < vec_len (indices); i++)
{
s = session_get_if_valid (indices[i], thread_index);
if (s == 0 || session_enqueue_notify (s, 0 /* don't block */ ))
errors++;
}
vec_reset_length (indices);
smm->session_to_enqueue[transport_proto][thread_index] = indices;
smm->current_enqueue_epoch[transport_proto][thread_index]++;
return errors;
}
int
session_manager_flush_all_enqueue_events (u8 transport_proto)
{
vlib_thread_main_t *vtm = vlib_get_thread_main ();
int i, errors = 0;
for (i = 0; i < 1 + vtm->n_threads; i++)
errors += session_manager_flush_enqueue_events (transport_proto, i);
return errors;
}
/**
* Init fifo tail and head pointers
*
* Useful if transport uses absolute offsets for tracking ooo segments.
*/
void
stream_session_init_fifos_pointers (transport_connection_t * tc,
u32 rx_pointer, u32 tx_pointer)
{
stream_session_t *s;
s = session_get (tc->s_index, tc->thread_index);
svm_fifo_init_pointers (s->server_rx_fifo, rx_pointer);
svm_fifo_init_pointers (s->server_tx_fifo, tx_pointer);
}
int
session_stream_connect_notify (transport_connection_t * tc, u8 is_fail)
{
u32 opaque = 0, new_ti, new_si;
stream_session_t *new_s = 0;
segment_manager_t *sm;
application_t *app;
u8 alloc_fifos;
int error = 0;
u64 handle;
/*
* Find connection handle and cleanup half-open table
*/
handle = session_lookup_half_open_handle (tc);
if (handle == HALF_OPEN_LOOKUP_INVALID_VALUE)
{
SESSION_DBG ("half-open was removed!");
return -1;
}
session_lookup_del_half_open (tc);
/* Get the app's index from the handle we stored when opening connection
* and the opaque (api_context for external apps) from transport session
* index */
app = application_get_if_valid (handle >> 32);
if (!app)
return -1;
opaque = tc->s_index;
/*
* Allocate new session with fifos (svm segments are allocated if needed)
*/
if (!is_fail)
{
sm = application_get_connect_segment_manager (app);
alloc_fifos = !application_is_builtin_proxy (app);
if (session_alloc_and_init (sm, tc, alloc_fifos, &new_s))
{
is_fail = 1;
error = -1;
}
else
{
new_s->app_index = app->index;
new_si = new_s->session_index;
new_ti = new_s->thread_index;
}
}
/*
* Notify client application
*/
if (app->cb_fns.session_connected_callback (app->index, opaque, new_s,
is_fail))
{
SESSION_DBG ("failed to notify app");
if (!is_fail)
{
new_s = session_get (new_si, new_ti);
stream_session_disconnect_transport (new_s);
}
}
else
{
if (!is_fail)
{
new_s = session_get (new_si, new_ti);
new_s->session_state = SESSION_STATE_READY;
}
}
return error;
}
typedef struct _session_switch_pool_args
{
u32 session_index;
u32 thread_index;
u32 new_thread_index;
u32 new_session_index;
} session_switch_pool_args_t;
static void
session_switch_pool (void *cb_args)
{
session_switch_pool_args_t *args = (session_switch_pool_args_t *) cb_args;
transport_proto_t tp;
stream_session_t *s;
ASSERT (args->thread_index == vlib_get_thread_index ());
s = session_get (args->session_index, args->thread_index);
s->server_tx_fifo->master_session_index = args->new_session_index;
s->server_tx_fifo->master_thread_index = args->new_thread_index;
tp = session_get_transport_proto (s);
tp_vfts[tp].cleanup (s->connection_index, s->thread_index);
session_free (s);
clib_mem_free (cb_args);
}
/**
* Move dgram session to the right thread
*/
int
session_dgram_connect_notify (transport_connection_t * tc,
u32 old_thread_index,
stream_session_t ** new_session)
{
stream_session_t *new_s;
session_switch_pool_args_t *rpc_args;
/*
* Clone half-open session to the right thread.
*/
new_s = session_clone_safe (tc->s_index, old_thread_index);
new_s->connection_index = tc->c_index;
new_s->server_rx_fifo->master_session_index = new_s->session_index;
new_s->server_rx_fifo->master_thread_index = new_s->thread_index;
new_s->session_state = SESSION_STATE_READY;
session_lookup_add_connection (tc, session_handle (new_s));
/*
* Ask thread owning the old session to clean it up and make us the tx
* fifo owner
*/
rpc_args = clib_mem_alloc (sizeof (*rpc_args));
rpc_args->new_session_index = new_s->session_index;
rpc_args->new_thread_index = new_s->thread_index;
rpc_args->session_index = tc->s_index;
rpc_args->thread_index = old_thread_index;
session_send_rpc_evt_to_thread (rpc_args->thread_index, session_switch_pool,
rpc_args);
tc->s_index = new_s->session_index;
new_s->connection_index = tc->c_index;
*new_session = new_s;
return 0;
}
void
stream_session_accept_notify (transport_connection_t * tc)
{
application_t *server;
stream_session_t *s;
s = session_get (tc->s_index, tc->thread_index);
server = application_get (s->app_index);
server->cb_fns.session_accept_callback (s);
}
/**
* Notification from transport that connection is being closed.
*
* A disconnect is sent to application but state is not removed. Once
* disconnect is acknowledged by application, session disconnect is called.
* Ultimately this leads to close being called on transport (passive close).
*/
void
stream_session_disconnect_notify (transport_connection_t * tc)
{
application_t *server;
stream_session_t *s;
s = session_get (tc->s_index, tc->thread_index);
server = application_get (s->app_index);
server->cb_fns.session_disconnect_callback (s);
s->session_state = SESSION_STATE_CLOSING;
}
/**
* Cleans up session and lookup table.
*
* Transport connection must still be valid.
*/
void
stream_session_delete (stream_session_t * s)
{
int rv;
/* Delete from the main lookup table. */
if ((rv = session_lookup_del_session (s)))
clib_warning ("hash delete error, rv %d", rv);
/* Cleanup fifo segments */
segment_manager_dealloc_fifos (s->svm_segment_index, s->server_rx_fifo,
s->server_tx_fifo);
session_free (s);
}
/**
* Notification from transport that connection is being deleted
*
* This removes the session if it is still valid. It should be called only on
* previously fully established sessions. For instance failed connects should
* call stream_session_connect_notify and indicate that the connect has
* failed.
*/
void
stream_session_delete_notify (transport_connection_t * tc)
{
stream_session_t *s;
/* App might've been removed already */
s = session_get_if_valid (tc->s_index, tc->thread_index);
if (!s)
return;
stream_session_delete (s);
}
/**
* Notify application that connection has been reset.
*/
void
stream_session_reset_notify (transport_connection_t * tc)
{
stream_session_t *s;
application_t *app;
s = session_get (tc->s_index, tc->thread_index);
s->session_state = SESSION_STATE_CLOSED;
app = application_get (s->app_index);
app->cb_fns.session_reset_callback (s);
}
/**
* Accept a stream session. Optionally ping the server by callback.
*/
int
stream_session_accept (transport_connection_t * tc, u32 listener_index,
u8 notify)
{
application_t *server;
stream_session_t *s, *listener;
segment_manager_t *sm;
int rv;
/* Find the server */
listener = listen_session_get (listener_index);
server = application_get (listener->app_index);
sm = application_get_listen_segment_manager (server, listener);
if ((rv = session_alloc_and_init (sm, tc, 1, &s)))
return rv;
s->app_index = server->index;
s->listener_index = listener_index;
s->session_state = SESSION_STATE_ACCEPTING;
/* Shoulder-tap the server */
if (notify)
{
server->cb_fns.session_accept_callback (s);
}
return 0;
}
int
session_open_cl (u32 app_index, session_endpoint_t * rmt, u32 opaque)
{
transport_connection_t *tc;
transport_endpoint_t *tep;
segment_manager_t *sm;
stream_session_t *s;
application_t *app;
int rv;
tep = session_endpoint_to_transport (rmt);
rv = tp_vfts[rmt->transport_proto].open (tep);
if (rv < 0)
{
SESSION_DBG ("Transport failed to open connection.");
return VNET_API_ERROR_SESSION_CONNECT;
}
tc = tp_vfts[rmt->transport_proto].get_half_open ((u32) rv);
/* For dgram type of service, allocate session and fifos now.
*/
app = application_get (app_index);
sm = application_get_connect_segment_manager (app);
if (session_alloc_and_init (sm, tc, 1, &s))
return -1;
s->app_index = app->index;
s->session_state = SESSION_STATE_OPENED;
/* Tell the app about the new event fifo for this session */
app->cb_fns.session_connected_callback (app->index, opaque, s, 0);
return 0;
}
int
session_open_vc (u32 app_index, session_endpoint_t * rmt, u32 opaque)
{
transport_connection_t *tc;
transport_endpoint_t *tep;
u64 handle;
int rv;
tep = session_endpoint_to_transport (rmt);
rv = tp_vfts[rmt->transport_proto].open (tep);
if (rv < 0)
{
SESSION_DBG ("Transport failed to open connection.");
return VNET_API_ERROR_SESSION_CONNECT;
}
tc = tp_vfts[rmt->transport_proto].get_half_open ((u32) rv);
/* If transport offers a stream service, only allocate session once the
* connection has been established.
* Add connection to half-open table and save app and tc index. The
* latter is needed to help establish the connection while the former
* is needed when the connect notify comes and we have to notify the
* external app
*/
handle = (((u64) app_index) << 32) | (u64) tc->c_index;
session_lookup_add_half_open (tc, handle);
/* Store api_context (opaque) for when the reply comes. Not the nicest
* thing but better than allocating a separate half-open pool.
*/
tc->s_index = opaque;
return 0;
}
int
session_open_app (u32 app_index, session_endpoint_t * rmt, u32 opaque)
{
session_endpoint_extended_t *sep = (session_endpoint_extended_t *) rmt;
sep->app_index = app_index;
sep->opaque = opaque;
return tp_vfts[rmt->transport_proto].open ((transport_endpoint_t *) sep);
}
typedef int (*session_open_service_fn) (u32, session_endpoint_t *, u32);
/* *INDENT-OFF* */
static session_open_service_fn session_open_srv_fns[TRANSPORT_N_SERVICES] = {
session_open_vc,
session_open_cl,
session_open_app,
};
/* *INDENT-ON* */
/**
* Ask transport to open connection to remote transport endpoint.
*
* Stores handle for matching request with reply since the call can be
* asynchronous. For instance, for TCP the 3-way handshake must complete
* before reply comes. Session is only created once connection is established.
*
* @param app_index Index of the application requesting the connect
* @param st Session type requested.
* @param tep Remote transport endpoint
* @param opaque Opaque data (typically, api_context) the application expects
* on open completion.
*/
int
session_open (u32 app_index, session_endpoint_t * rmt, u32 opaque)
{
transport_service_type_t tst = tp_vfts[rmt->transport_proto].service_type;
return session_open_srv_fns[tst] (app_index, rmt, opaque);
}
int
session_listen_vc (stream_session_t * s, session_endpoint_t * sep)
{
transport_connection_t *tc;
u32 tci;
/* Transport bind/listen */
tci = tp_vfts[sep->transport_proto].bind (s->session_index,
session_endpoint_to_transport
(sep));
if (tci == (u32) ~ 0)
return -1;
/* Attach transport to session */
s->connection_index = tci;
tc = tp_vfts[sep->transport_proto].get_listener (tci);
/* Weird but handle it ... */
if (tc == 0)
return -1;
/* Add to the main lookup table */
session_lookup_add_connection (tc, s->session_index);
return 0;
}
int
session_listen_cl (stream_session_t * s, session_endpoint_t * sep)
{
transport_connection_t *tc;
application_t *server;
segment_manager_t *sm;
u32 tci;
/* Transport bind/listen */
tci = tp_vfts[sep->transport_proto].bind (s->session_index,
session_endpoint_to_transport
(sep));
if (tci == (u32) ~ 0)
return -1;
/* Attach transport to session */
s->connection_index = tci;
tc = tp_vfts[sep->transport_proto].get_listener (tci);
/* Weird but handle it ... */
if (tc == 0)
return -1;
server = application_get (s->app_index);
sm = application_get_listen_segment_manager (server, s);
if (session_alloc_fifos (sm, s))
return -1;
/* Add to the main lookup table */
session_lookup_add_connection (tc, s->session_index);
return 0;
}
int
session_listen_app (stream_session_t * s, session_endpoint_t * sep)
{
session_endpoint_extended_t esep;
clib_memcpy (&esep, sep, sizeof (*sep));
esep.app_index = s->app_index;
return tp_vfts[sep->transport_proto].bind (s->session_index,
(transport_endpoint_t *) & esep);
}
typedef int (*session_listen_service_fn) (stream_session_t *,
session_endpoint_t *);
/* *INDENT-OFF* */
static session_listen_service_fn
session_listen_srv_fns[TRANSPORT_N_SERVICES] = {
session_listen_vc,
session_listen_cl,
session_listen_app,
};
/* *INDENT-ON* */
/**
* Ask transport to listen on local transport endpoint.
*
* @param s Session for which listen will be called. Note that unlike
* established sessions, listen sessions are not associated to a
* thread.
* @param tep Local endpoint to be listened on.
*/
int
stream_session_listen (stream_session_t * s, session_endpoint_t * sep)
{
transport_service_type_t tst = tp_vfts[sep->transport_proto].service_type;
return session_listen_srv_fns[tst] (s, sep);
}
/**
* Ask transport to stop listening on local transport endpoint.
*
* @param s Session to stop listening on. It must be in state LISTENING.
*/
int
stream_session_stop_listen (stream_session_t * s)
{
transport_proto_t tp = session_get_transport_proto (s);
transport_connection_t *tc;
if (s->session_state != SESSION_STATE_LISTENING)
{
clib_warning ("not a listening session");
return -1;
}
tc = tp_vfts[tp].get_listener (s->connection_index);
if (!tc)
{
clib_warning ("no transport");
return VNET_API_ERROR_ADDRESS_NOT_IN_USE;
}
session_lookup_del_connection (tc);
tp_vfts[tp].unbind (s->connection_index);
return 0;
}
/**
* Initialize session disconnect.
*
* Request is always sent to session node to ensure that all outstanding
* requests are served before transport is notified.
*/
void
stream_session_disconnect (stream_session_t * s)
{
u32 thread_index = vlib_get_thread_index ();
session_manager_main_t *smm = &session_manager_main;
session_fifo_event_t *evt;
if (!s)
return;
if (s->session_state >= SESSION_STATE_CLOSING)
{
/* Session already closed. Clear the tx fifo */
if (s->session_state == SESSION_STATE_CLOSED)
svm_fifo_dequeue_drop_all (s->server_tx_fifo);
return;
}
s->session_state = SESSION_STATE_CLOSING;
/* If we are in the handler thread, or being called with the worker barrier
* held (api/cli), just append a new event to pending disconnects vector. */
if ((thread_index == 0 && !vlib_get_current_process (vlib_get_main ()))
|| thread_index == s->thread_index)
{
ASSERT (s->thread_index == thread_index || thread_index == 0);
vec_add2 (smm->pending_disconnects[s->thread_index], evt, 1);
memset (evt, 0, sizeof (*evt));
evt->session_handle = session_handle (s);
evt->event_type = FIFO_EVENT_DISCONNECT;
}
else
session_send_session_evt_to_thread (session_handle (s),
FIFO_EVENT_DISCONNECT,
s->thread_index);
}
/**
* Notify transport the session can be disconnected. This should eventually
* result in a delete notification that allows us to cleanup session state.
* Called for both active/passive disconnects.
*
* Must be called from the session's thread.
*/
void
stream_session_disconnect_transport (stream_session_t * s)
{
s->session_state = SESSION_STATE_CLOSED;
tp_vfts[session_get_transport_proto (s)].close (s->connection_index,
s->thread_index);
}
/**
* Cleanup transport and session state.
*
* Notify transport of the cleanup and free the session. This should
* be called only if transport reported some error and is already
* closed.
*/
void
stream_session_cleanup (stream_session_t * s)
{
s->session_state = SESSION_STATE_CLOSED;
/* Delete from main lookup table before we axe the the transport */
session_lookup_del_session (s);
tp_vfts[session_get_transport_proto (s)].cleanup (s->connection_index,
s->thread_index);
/* Since we called cleanup, no delete notification will come. So, make
* sure the session is properly freed. */
segment_manager_dealloc_fifos (s->svm_segment_index, s->server_rx_fifo,
s->server_tx_fifo);
session_free (s);
}
transport_service_type_t
session_transport_service_type (stream_session_t * s)
{
transport_proto_t tp;
tp = session_get_transport_proto (s);
return transport_protocol_service_type (tp);
}
transport_tx_fn_type_t
session_transport_tx_fn_type (stream_session_t * s)
{
transport_proto_t tp;
tp = session_get_transport_proto (s);
return transport_protocol_tx_fn_type (tp);
}
u8
session_tx_is_dgram (stream_session_t * s)
{
return (session_transport_tx_fn_type (s) == TRANSPORT_TX_DGRAM);
}
/**
* Allocate event queues in the shared-memory segment
*
* That can either be a newly created memfd segment, that will need to be
* mapped by all stack users, or the binary api's svm region. The latter is
* assumed to be already mapped. NOTE that this assumption DOES NOT hold if
* api clients bootstrap shm api over sockets (i.e. use memfd segments) and
* vpp uses api svm region for event queues.
*/
void
session_vpp_event_queues_allocate (session_manager_main_t * smm)
{
u32 evt_q_length = 2048, evt_size = sizeof (session_fifo_event_t);
ssvm_private_t *eqs = &smm->evt_qs_segment;
api_main_t *am = &api_main;
u64 eqs_size = 64 << 20;
pid_t vpp_pid = getpid ();
void *oldheap;
int i;
if (smm->configured_event_queue_length)
evt_q_length = smm->configured_event_queue_length;
if (smm->evt_qs_use_memfd_seg)
{
if (smm->evt_qs_segment_size)
eqs_size = smm->evt_qs_segment_size;
eqs->ssvm_size = eqs_size;
eqs->i_am_master = 1;
eqs->my_pid = vpp_pid;
eqs->name = format (0, "%s%c", "evt-qs-segment", 0);
eqs->requested_va = smm->session_baseva;
ssvm_master_init (eqs, SSVM_SEGMENT_MEMFD);
}
if (smm->evt_qs_use_memfd_seg)
oldheap = ssvm_push_heap (eqs->sh);
else
oldheap = svm_push_data_heap (am->vlib_rp);
for (i = 0; i < vec_len (smm->vpp_event_queues); i++)
{
smm->vpp_event_queues[i] = svm_queue_init (evt_q_length, evt_size,
vpp_pid, 0);
}
if (smm->evt_qs_use_memfd_seg)
ssvm_pop_heap (oldheap);
else
svm_pop_heap (oldheap);
}
ssvm_private_t *
session_manager_get_evt_q_segment (void)
{
session_manager_main_t *smm = &session_manager_main;
if (smm->evt_qs_use_memfd_seg)
return &smm->evt_qs_segment;
return 0;
}
/* *INDENT-OFF* */
static session_fifo_rx_fn *session_tx_fns[TRANSPORT_TX_N_FNS] = {
session_tx_fifo_peek_and_snd,
session_tx_fifo_dequeue_and_snd,
session_tx_fifo_dequeue_internal,
session_tx_fifo_dequeue_and_snd
};
/* *INDENT-ON* */
/**
* Initialize session layer for given transport proto and ip version
*
* Allocates per session type (transport proto + ip version) data structures
* and adds arc from session queue node to session type output node.
*/
void
session_register_transport (transport_proto_t transport_proto,
const transport_proto_vft_t * vft, u8 is_ip4,
u32 output_node)
{
session_manager_main_t *smm = &session_manager_main;
session_type_t session_type;
u32 next_index = ~0;
session_type = session_type_from_proto_and_ip (transport_proto, is_ip4);
vec_validate (smm->session_type_to_next, session_type);
vec_validate (smm->session_tx_fns, session_type);
/* *INDENT-OFF* */
if (output_node != ~0)
{
foreach_vlib_main (({
next_index = vlib_node_add_next (this_vlib_main,
session_queue_node.index,
output_node);
}));
}
/* *INDENT-ON* */
smm->session_type_to_next[session_type] = next_index;
smm->session_tx_fns[session_type] = session_tx_fns[vft->tx_type];
}
transport_connection_t *
session_get_transport (stream_session_t * s)
{
transport_proto_t tp;
if (s->session_state != SESSION_STATE_LISTENING)
{
tp = session_get_transport_proto (s);
return tp_vfts[tp].get_connection (s->connection_index,
s->thread_index);
}
return 0;
}
transport_connection_t *
listen_session_get_transport (stream_session_t * s)
{
transport_proto_t tp = session_get_transport_proto (s);
return tp_vfts[tp].get_listener (s->connection_index);
}
int
listen_session_get_local_session_endpoint (stream_session_t * listener,
session_endpoint_t * sep)
{
transport_proto_t tp = session_get_transport_proto (listener);
transport_connection_t *tc;
tc = tp_vfts[tp].get_listener (listener->connection_index);
if (!tc)
{
clib_warning ("no transport");
return -1;
}
/* N.B. The ip should not be copied because this is the local endpoint */
sep->port = tc->lcl_port;
sep->transport_proto = tc->proto;
sep->is_ip4 = tc->is_ip4;
return 0;
}
void
session_flush_frames_main_thread (vlib_main_t * vm)
{
ASSERT (vlib_get_thread_index () == 0);
vlib_process_signal_event_mt (vm, session_queue_process_node.index,
SESSION_Q_PROCESS_FLUSH_FRAMES, 0);
}
static clib_error_t *
session_manager_main_enable (vlib_main_t * vm)
{
segment_manager_main_init_args_t _sm_args = { 0 }, *sm_args = &_sm_args;
session_manager_main_t *smm = &session_manager_main;
vlib_thread_main_t *vtm = vlib_get_thread_main ();
u32 num_threads, preallocated_sessions_per_worker;
int i, j;
num_threads = 1 /* main thread */ + vtm->n_threads;
if (num_threads < 1)
return clib_error_return (0, "n_thread_stacks not set");
/* configure per-thread ** vectors */
vec_validate (smm->sessions, num_threads - 1);
vec_validate (smm->tx_buffers, num_threads - 1);
vec_validate (smm->pending_event_vector, num_threads - 1);
vec_validate (smm->pending_disconnects, num_threads - 1);
vec_validate (smm->free_event_vector, num_threads - 1);
vec_validate (smm->vpp_event_queues, num_threads - 1);
vec_validate (smm->peekers_rw_locks, num_threads - 1);
vec_validate_aligned (smm->ctx, num_threads - 1, CLIB_CACHE_LINE_BYTES);
for (i = 0; i < TRANSPORT_N_PROTO; i++)
{
vec_validate (smm->current_enqueue_epoch[i], num_threads - 1);
vec_validate (smm->session_to_enqueue[i], num_threads - 1);
for (j = 0; j < num_threads; j++)
smm->current_enqueue_epoch[i][j] = 1;
}
for (i = 0; i < num_threads; i++)
{
vec_validate (smm->free_event_vector[i], 0);
_vec_len (smm->free_event_vector[i]) = 0;
vec_validate (smm->pending_event_vector[i], 0);
_vec_len (smm->pending_event_vector[i]) = 0;
vec_validate (smm->pending_disconnects[i], 0);
_vec_len (smm->pending_disconnects[i]) = 0;
if (num_threads > 1)
clib_rwlock_init (&smm->peekers_rw_locks[i]);
}
#if SESSION_DEBUG
vec_validate (smm->last_event_poll_by_thread, num_threads - 1);
#endif
/* Allocate vpp event queues segment and queue */
session_vpp_event_queues_allocate (smm);
/* Initialize fifo segment main baseva and timeout */
sm_args->baseva = smm->session_baseva + smm->evt_qs_segment_size;
sm_args->size = smm->session_va_space_size;
segment_manager_main_init (sm_args);
/* Preallocate sessions */
if (smm->preallocated_sessions)
{
if (num_threads == 1)
{
pool_init_fixed (smm->sessions[0], smm->preallocated_sessions);
}
else
{
int j;
preallocated_sessions_per_worker =
(1.1 * (f64) smm->preallocated_sessions /
(f64) (num_threads - 1));
for (j = 1; j < num_threads; j++)
{
pool_init_fixed (smm->sessions[j],
preallocated_sessions_per_worker);
}
}
}
session_lookup_init ();
app_namespaces_init ();
transport_init ();
smm->is_enabled = 1;
/* Enable transports */
transport_enable_disable (vm, 1);
return 0;
}
void
session_node_enable_disable (u8 is_en)
{
u8 state = is_en ? VLIB_NODE_STATE_POLLING : VLIB_NODE_STATE_DISABLED;
vlib_thread_main_t *vtm = vlib_get_thread_main ();
u8 have_workers = vtm->n_threads != 0;
/* *INDENT-OFF* */
foreach_vlib_main (({
if (have_workers && ii == 0)
{
vlib_node_set_state (this_vlib_main, session_queue_process_node.index,
state);
if (is_en)
{
vlib_node_t *n = vlib_get_node (this_vlib_main,
session_queue_process_node.index);
vlib_start_process (this_vlib_main, n->runtime_index);
}
else
{
vlib_process_signal_event_mt (this_vlib_main,
session_queue_process_node.index,
SESSION_Q_PROCESS_STOP, 0);
}
continue;
}
vlib_node_set_state (this_vlib_main, session_queue_node.index,
state);
}));
/* *INDENT-ON* */
}
clib_error_t *
vnet_session_enable_disable (vlib_main_t * vm, u8 is_en)
{
clib_error_t *error = 0;
if (is_en)
{
if (session_manager_main.is_enabled)
return 0;
session_node_enable_disable (is_en);
error = session_manager_main_enable (vm);
}
else
{
session_manager_main.is_enabled = 0;
session_node_enable_disable (is_en);
}
return error;
}
clib_error_t *
session_manager_main_init (vlib_main_t * vm)
{
session_manager_main_t *smm = &session_manager_main;
smm->session_baseva = 0x200000000ULL;
smm->session_va_space_size = (u64) 128 << 30;
smm->evt_qs_segment_size = 64 << 20;
smm->is_enabled = 0;
return 0;
}
VLIB_INIT_FUNCTION (session_manager_main_init);
static clib_error_t *
session_config_fn (vlib_main_t * vm, unformat_input_t * input)
{
session_manager_main_t *smm = &session_manager_main;
u32 nitems;
uword tmp;
while (unformat_check_input (input) != UNFORMAT_END_OF_INPUT)
{
if (unformat (input, "event-queue-length %d", &nitems))
{
if (nitems >= 2048)
smm->configured_event_queue_length = nitems;
else
clib_warning ("event queue length %d too small, ignored", nitems);
}
else if (unformat (input, "preallocated-sessions %d",
&smm->preallocated_sessions))
;
else if (unformat (input, "v4-session-table-buckets %d",
&smm->configured_v4_session_table_buckets))
;
else if (unformat (input, "v4-halfopen-table-buckets %d",
&smm->configured_v4_halfopen_table_buckets))
;
else if (unformat (input, "v6-session-table-buckets %d",
&smm->configured_v6_session_table_buckets))
;
else if (unformat (input, "v6-halfopen-table-buckets %d",
&smm->configured_v6_halfopen_table_buckets))
;
else if (unformat (input, "v4-session-table-memory %U",
unformat_memory_size, &tmp))
{
if (tmp >= 0x100000000)
return clib_error_return (0, "memory size %llx (%lld) too large",
tmp, tmp);
smm->configured_v4_session_table_memory = tmp;
}
else if (unformat (input, "v4-halfopen-table-memory %U",
unformat_memory_size, &tmp))
{
if (tmp >= 0x100000000)
return clib_error_return (0, "memory size %llx (%lld) too large",
tmp, tmp);
smm->configured_v4_halfopen_table_memory = tmp;
}
else if (unformat (input, "v6-session-table-memory %U",
unformat_memory_size, &tmp))
{
if (tmp >= 0x100000000)
return clib_error_return (0, "memory size %llx (%lld) too large",
tmp, tmp);
smm->configured_v6_session_table_memory = tmp;
}
else if (unformat (input, "v6-halfopen-table-memory %U",
unformat_memory_size, &tmp))
{
if (tmp >= 0x100000000)
return clib_error_return (0, "memory size %llx (%lld) too large",
tmp, tmp);
smm->configured_v6_halfopen_table_memory = tmp;
}
else if (unformat (input, "local-endpoints-table-memory %U",
unformat_memory_size, &tmp))
{
if (tmp >= 0x100000000)
return clib_error_return (0, "memory size %llx (%lld) too large",
tmp, tmp);
smm->local_endpoints_table_memory = tmp;
}
else if (unformat (input, "local-endpoints-table-buckets %d",
&smm->local_endpoints_table_buckets))
;
else if (unformat (input, "evt_qs_memfd_seg"))
smm->evt_qs_use_memfd_seg = 1;
else
return clib_error_return (0, "unknown input `%U'",
format_unformat_error, input);
}
return 0;
}
VLIB_CONFIG_FUNCTION (session_config_fn, "session");
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/