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/*
* 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.
*/
#ifndef __included_session_h__
#define __included_session_h__
#include <vppinfra/llist.h>
#include <vnet/session/session_types.h>
#include <vnet/session/session_lookup.h>
#include <vnet/session/session_debug.h>
#include <svm/message_queue.h>
#include <svm/fifo_segment.h>
#include <vlib/dma/dma.h>
#define foreach_session_input_error \
_(NO_SESSION, "No session drops") \
_(NO_LISTENER, "No listener for dst port drops") \
_(ENQUEUED, "Packets pushed into rx fifo") \
_(NOT_READY, "Session not ready packets") \
_(FIFO_FULL, "Packets dropped for lack of rx fifo space") \
_(EVENT_FIFO_FULL, "Events not sent for lack of event fifo space") \
_(API_QUEUE_FULL, "Sessions not created for lack of API queue space") \
typedef enum
{
#define _(sym,str) SESSION_ERROR_##sym,
foreach_session_input_error
#undef _
SESSION_N_ERROR,
} session_input_error_t;
typedef struct session_tx_context_
{
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
session_t *s;
transport_proto_vft_t *transport_vft;
transport_connection_t *tc;
transport_send_params_t sp;
u32 max_dequeue;
u32 left_to_snd;
u32 max_len_to_snd;
u16 deq_per_first_buf;
u16 deq_per_buf;
u16 n_segs_per_evt;
u16 n_bufs_needed;
u8 n_bufs_per_seg;
CLIB_CACHE_LINE_ALIGN_MARK (cacheline1);
session_dgram_hdr_t hdr;
/** Vector of tx buffer free lists */
u32 *tx_buffers;
vlib_buffer_t **transport_pending_bufs;
} session_tx_context_t;
typedef struct session_evt_elt
{
clib_llist_anchor_t evt_list;
session_event_t evt;
} session_evt_elt_t;
typedef struct session_ctrl_evt_data_
{
u8 data[SESSION_CTRL_MSG_MAX_SIZE];
} session_evt_ctrl_data_t;
typedef enum session_wrk_state_
{
SESSION_WRK_POLLING,
SESSION_WRK_INTERRUPT,
SESSION_WRK_IDLE,
} __clib_packed session_wrk_state_t;
typedef enum session_wrk_flags_
{
SESSION_WRK_F_ADAPTIVE = 1 << 0,
} __clib_packed session_wrk_flag_t;
#define DMA_TRANS_SIZE 1024
typedef struct
{
u32 *pending_tx_buffers;
u16 *pending_tx_nexts;
} session_dma_transfer;
typedef struct session_worker_
{
CLIB_CACHE_LINE_ALIGN_MARK (cacheline0);
/** Worker session pool */
session_t *sessions;
/** vpp event message queue for worker */
svm_msg_q_t *vpp_event_queue;
/** vlib_time_now last time around the track */
clib_time_type_t last_vlib_time;
/** vlib_time_now rounded to us precision and as u64 */
clib_us_time_t last_vlib_us_time;
/** Convenience pointer to this worker's vlib_main */
vlib_main_t *vm;
/** Per-proto vector of sessions to enqueue */
u32 **session_to_enqueue;
/** Timerfd used to periodically signal wrk session queue node */
int timerfd;
/** Worker flags */
session_wrk_flag_t flags;
/** Worker state */
session_wrk_state_t state;
/** Context for session tx */
session_tx_context_t ctx;
/** Pool of session event list elements */
session_evt_elt_t *event_elts;
/** Pool of ctrl events data buffers */
session_evt_ctrl_data_t *ctrl_evts_data;
/** Head of control events list */
clib_llist_index_t ctrl_head;
/** Head of list of elements */
clib_llist_index_t new_head;
/** Head of list of pending events */
clib_llist_index_t old_head;
/** Vector of buffers to be sent */
u32 *pending_tx_buffers;
/** Vector of nexts for the pending tx buffers */
u16 *pending_tx_nexts;
/** Clib file for timerfd. Used only if adaptive mode is on */
uword timerfd_file;
/** List of pending connects for first worker */
clib_llist_index_t pending_connects;
/** Flag that is set if main thread signaled to handle connects */
u32 n_pending_connects;
/** Main thread loops in poll mode without a connect */
u32 no_connect_loops;
/** List head for first worker evts pending handling on main */
clib_llist_index_t evts_pending_main;
int config_index;
u8 dma_enabled;
session_dma_transfer *dma_trans;
u16 trans_head;
u16 trans_tail;
u16 trans_size;
u16 batch_num;
vlib_dma_batch_t *batch;
#if SESSION_DEBUG
/** last event poll time by thread */
clib_time_type_t last_event_poll;
#endif
} session_worker_t;
typedef int (session_fifo_rx_fn) (session_worker_t * wrk,
vlib_node_runtime_t * node,
session_evt_elt_t * e, int *n_tx_packets);
extern session_fifo_rx_fn session_tx_fifo_peek_and_snd;
extern session_fifo_rx_fn session_tx_fifo_dequeue_and_snd;
extern session_fifo_rx_fn session_tx_fifo_dequeue_internal;
u8 session_node_lookup_fifo_event (svm_fifo_t * f, session_event_t * e);
typedef void (*session_update_time_fn) (f64 time_now, u8 thread_index);
typedef struct session_main_
{
/** Worker contexts */
session_worker_t *wrk;
/** Vector of transport update time functions */
session_update_time_fn *update_time_fns;
/** Event queues memfd segment */
fifo_segment_t wrk_mqs_segment;
/** Unique segment name counter */
u32 unique_segment_name_counter;
/** Per transport rx function that can either dequeue or peek */
session_fifo_rx_fn **session_tx_fns;
/** Per session type output nodes. Could optimize to group nodes by
* fib but lookup would then require session type parsing in session node.
* Trade memory for speed, for now */
u32 *session_type_to_next;
/** Thread for cl and ho that rely on cl allocs */
u32 transport_cl_thread;
transport_proto_t last_transport_proto_type;
/** Number of workers at pool realloc barrier */
volatile u32 pool_realloc_at_barrier;
/** Number of workers doing reallocs */
volatile u32 pool_realloc_doing_work;
/** Lock to synchronize parallel forced reallocs */
clib_spinlock_t pool_realloc_lock;
/*
* Config parameters
*/
/** Session manager is enabled */
u8 is_enabled;
/** Session manager initialized (not necessarily enabled) */
u8 is_initialized;
/** Enable session manager at startup */
u8 session_enable_asap;
/** Poll session node in main thread */
u8 poll_main;
/** Allocate private rx mqs for external apps */
u8 use_private_rx_mqs;
/** Do not enable session queue node adaptive mode */
u8 no_adaptive;
/** vpp fifo event queue configured length */
u32 configured_wrk_mq_length;
/** Session ssvm segment configs*/
uword wrk_mqs_segment_size;
/** Session enable dma*/
u8 dma_enabled;
/** Session table size parameters */
u32 configured_v4_session_table_buckets;
u32 configured_v4_session_table_memory;
u32 configured_v4_halfopen_table_buckets;
u32 configured_v4_halfopen_table_memory;
u32 configured_v6_session_table_buckets;
u32 configured_v6_session_table_memory;
u32 configured_v6_halfopen_table_buckets;
u32 configured_v6_halfopen_table_memory;
/** Transport table (preallocation) size parameters */
u32 local_endpoints_table_memory;
u32 local_endpoints_table_buckets;
/** Preallocate session config parameter */
u32 preallocated_sessions;
u16 msg_id_base;
} session_main_t;
extern session_main_t session_main;
extern vlib_node_registration_t session_queue_node;
extern vlib_node_registration_t session_queue_process_node;
extern vlib_node_registration_t session_queue_pre_input_node;
typedef enum session_q_process_evt_
{
SESSION_Q_PROCESS_RUN_ON_MAIN = 1,
SESSION_Q_PROCESS_STOP
} session_q_process_evt_t;
#define TRANSPORT_PROTO_INVALID (session_main.last_transport_proto_type + 1)
#define TRANSPORT_N_PROTOS (session_main.last_transport_proto_type + 1)
static inline void
session_evt_add_old (session_worker_t * wrk, session_evt_elt_t * elt)
{
clib_llist_add_tail (wrk->event_elts, evt_list, elt,
clib_llist_elt (wrk->event_elts, wrk->old_head));
}
static inline void
session_evt_add_head_old (session_worker_t * wrk, session_evt_elt_t * elt)
{
clib_llist_add (wrk->event_elts, evt_list, elt,
clib_llist_elt (wrk->event_elts, wrk->old_head));
}
static inline u32
session_evt_ctrl_data_alloc (session_worker_t * wrk)
{
session_evt_ctrl_data_t *data;
pool_get (wrk->ctrl_evts_data, data);
return (data - wrk->ctrl_evts_data);
}
static inline session_evt_elt_t *
session_evt_alloc_ctrl (session_worker_t * wrk)
{
session_evt_elt_t *elt;
clib_llist_get (wrk->event_elts, elt);
clib_llist_add_tail (wrk->event_elts, evt_list, elt,
clib_llist_elt (wrk->event_elts, wrk->ctrl_head));
return elt;
}
static inline void *
session_evt_ctrl_data (session_worker_t * wrk, session_evt_elt_t * elt)
{
return (void *) (pool_elt_at_index (wrk->ctrl_evts_data,
elt->evt.ctrl_data_index));
}
static inline void
session_evt_ctrl_data_free (session_worker_t * wrk, session_evt_elt_t * elt)
{
ASSERT (elt->evt.event_type > SESSION_IO_EVT_BUILTIN_TX);
pool_put_index (wrk->ctrl_evts_data, elt->evt.ctrl_data_index);
}
static inline session_evt_elt_t *
session_evt_alloc_new (session_worker_t * wrk)
{
session_evt_elt_t *elt;
clib_llist_get (wrk->event_elts, elt);
clib_llist_add_tail (wrk->event_elts, evt_list, elt,
clib_llist_elt (wrk->event_elts, wrk->new_head));
return elt;
}
static inline session_evt_elt_t *
session_evt_alloc_old (session_worker_t * wrk)
{
session_evt_elt_t *elt;
clib_llist_get (wrk->event_elts, elt);
clib_llist_add_tail (wrk->event_elts, evt_list, elt,
clib_llist_elt (wrk->event_elts, wrk->old_head));
return elt;
}
int session_wrk_handle_mq (session_worker_t *wrk, svm_msg_q_t *mq);
session_t *session_alloc (u32 thread_index);
void session_free (session_t * s);
void session_free_w_fifos (session_t * s);
void session_cleanup_half_open (session_handle_t ho_handle);
u8 session_is_valid (u32 si, u8 thread_index);
always_inline session_t *
session_get (u32 si, u32 thread_index)
{
ASSERT (session_is_valid (si, thread_index));
return pool_elt_at_index (session_main.wrk[thread_index].sessions, si);
}
always_inline session_t *
session_get_if_valid (u64 si, u32 thread_index)
{
if (thread_index >= vec_len (session_main.wrk))
return 0;
if (pool_is_free_index (session_main.wrk[thread_index].sessions, si))
return 0;
ASSERT (session_is_valid (si, thread_index));
return pool_elt_at_index (session_main.wrk[thread_index].sessions, si);
}
always_inline session_t *
session_get_from_handle (session_handle_t handle)
{
session_main_t *smm = &session_main;
u32 session_index, thread_index;
session_parse_handle (handle, &session_index, &thread_index);
return pool_elt_at_index (smm->wrk[thread_index].sessions, session_index);
}
always_inline session_t *
session_get_from_handle_if_valid (session_handle_t handle)
{
u32 session_index, thread_index;
session_parse_handle (handle, &session_index, &thread_index);
return session_get_if_valid (session_index, thread_index);
}
u64 session_segment_handle (session_t * s);
/**
* Get session from handle and avoid pool validation if no same thread
*
* Peekers are fine because pool grows with barrier (see @ref session_alloc)
*/
always_inline session_t *
session_get_from_handle_safe (u64 handle)
{
u32 thread_index = session_thread_from_handle (handle);
session_worker_t *wrk = &session_main.wrk[thread_index];
if (thread_index == vlib_get_thread_index ())
{
return pool_elt_at_index (wrk->sessions,
session_index_from_handle (handle));
}
else
{
/* Don't use pool_elt_at index to avoid pool bitmap reallocs */
return wrk->sessions + session_index_from_handle (handle);
}
}
always_inline session_t *
session_clone_safe (u32 session_index, u32 thread_index)
{
u32 current_thread_index = vlib_get_thread_index (), new_index;
session_t *old_s, *new_s;
new_s = session_alloc (current_thread_index);
new_index = new_s->session_index;
/* Session pools are reallocated with barrier (see @ref session_alloc) */
old_s = session_main.wrk[thread_index].sessions + session_index;
clib_memcpy_fast (new_s, old_s, sizeof (*new_s));
new_s->thread_index = current_thread_index;
new_s->session_index = new_index;
return new_s;
}
int session_open (session_endpoint_cfg_t *sep, session_handle_t *rsh);
int session_listen (session_t * s, session_endpoint_cfg_t * sep);
int session_stop_listen (session_t * s);
void session_half_close (session_t *s);
void session_close (session_t * s);
void session_reset (session_t * s);
void session_transport_half_close (session_t *s);
void session_transport_close (session_t * s);
void session_transport_reset (session_t * s);
void session_transport_cleanup (session_t * s);
int session_send_io_evt_to_thread (svm_fifo_t * f,
session_evt_type_t evt_type);
int session_enqueue_notify (session_t * s);
int session_dequeue_notify (session_t * s);
int session_send_io_evt_to_thread_custom (void *data, u32 thread_index,
session_evt_type_t evt_type);
void session_send_rpc_evt_to_thread (u32 thread_index, void *fp,
void *rpc_args);
void session_send_rpc_evt_to_thread_force (u32 thread_index, void *fp,
void *rpc_args);
void session_add_self_custom_tx_evt (transport_connection_t * tc,
u8 has_prio);
void sesssion_reschedule_tx (transport_connection_t * tc);
transport_connection_t *session_get_transport (session_t * s);
void session_get_endpoint (session_t * s, transport_endpoint_t * tep,
u8 is_lcl);
int session_transport_attribute (session_t *s, u8 is_get,
transport_endpt_attr_t *attr);
u8 *format_session (u8 * s, va_list * args);
uword unformat_session (unformat_input_t * input, va_list * args);
uword unformat_transport_connection (unformat_input_t * input,
va_list * args);
/*
* Interface to transport protos
*/
int session_enqueue_stream_connection (transport_connection_t * tc,
vlib_buffer_t * b, u32 offset,
u8 queue_event, u8 is_in_order);
int session_enqueue_dgram_connection (session_t * s,
session_dgram_hdr_t * hdr,
vlib_buffer_t * b, u8 proto,
u8 queue_event);
int session_stream_connect_notify (transport_connection_t * tc,
session_error_t err);
int session_dgram_connect_notify (transport_connection_t * tc,
u32 old_thread_index,
session_t ** new_session);
int session_stream_accept_notify (transport_connection_t * tc);
void session_transport_closing_notify (transport_connection_t * tc);
void session_transport_delete_notify (transport_connection_t * tc);
void session_half_open_delete_notify (transport_connection_t *tc);
void session_half_open_migrate_notify (transport_connection_t *tc);
int session_half_open_migrated_notify (transport_connection_t *tc);
void session_transport_closed_notify (transport_connection_t * tc);
void session_transport_reset_notify (transport_connection_t * tc);
int session_stream_accept (transport_connection_t * tc, u32 listener_index,
u32 thread_index, u8 notify);
int session_dgram_accept (transport_connection_t * tc, u32 listener_index,
u32 thread_index);
/**
* 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.
*
* @param transport_proto transport proto to be registered
* @param vft virtual function table for transport
* @param is_ip4 flag that indicates if transports uses ipv4
* as underlying network layer
* @param output_node output node for transport
*/
void session_register_transport (transport_proto_t transport_proto,
const transport_proto_vft_t * vft, u8 is_ip4,
u32 output_node);
transport_proto_t session_add_transport_proto (void);
void session_register_update_time_fn (session_update_time_fn fn, u8 is_add);
int session_tx_fifo_peek_bytes (transport_connection_t * tc, u8 * buffer,
u32 offset, u32 max_bytes);
u32 session_tx_fifo_dequeue_drop (transport_connection_t * tc, u32 max_bytes);
always_inline void
session_set_state (session_t *s, session_state_t session_state)
{
s->session_state = session_state;
SESSION_EVT (SESSION_EVT_STATE_CHANGE, s);
}
always_inline u32
transport_max_rx_enqueue (transport_connection_t * tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_max_enqueue_prod (s->rx_fifo);
}
always_inline u32
transport_max_tx_dequeue (transport_connection_t * tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_max_dequeue_cons (s->tx_fifo);
}
always_inline u32
transport_max_rx_dequeue (transport_connection_t * tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_max_dequeue (s->rx_fifo);
}
always_inline u32
transport_rx_fifo_size (transport_connection_t * tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_size (s->rx_fifo);
}
always_inline u32
transport_tx_fifo_size (transport_connection_t * tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
return svm_fifo_size (s->tx_fifo);
}
always_inline u8
transport_rx_fifo_has_ooo_data (transport_connection_t * tc)
{
session_t *s = session_get (tc->c_index, tc->thread_index);
return svm_fifo_has_ooo_data (s->rx_fifo);
}
always_inline void
transport_rx_fifo_req_deq_ntf (transport_connection_t *tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
svm_fifo_add_want_deq_ntf (s->rx_fifo, SVM_FIFO_WANT_DEQ_NOTIF);
}
always_inline clib_time_type_t
transport_time_now (u32 thread_index)
{
return session_main.wrk[thread_index].last_vlib_time;
}
always_inline clib_us_time_t
transport_us_time_now (u32 thread_index)
{
return session_main.wrk[thread_index].last_vlib_us_time;
}
always_inline clib_time_type_t
transport_seconds_per_loop (u32 thread_index)
{
return session_main.wrk[thread_index].vm->seconds_per_loop;
}
always_inline void
transport_add_tx_event (transport_connection_t * tc)
{
session_t *s = session_get (tc->s_index, tc->thread_index);
if (svm_fifo_has_event (s->tx_fifo))
return;
session_send_io_evt_to_thread (s->tx_fifo, SESSION_IO_EVT_TX);
}
always_inline u32
transport_cl_thread (void)
{
return session_main.transport_cl_thread;
}
/*
* Listen sessions
*/
always_inline u64
listen_session_get_handle (session_t * s)
{
ASSERT (s->session_state == SESSION_STATE_LISTENING ||
session_get_transport_proto (s) == TRANSPORT_PROTO_QUIC);
return session_handle (s);
}
always_inline session_t *
listen_session_get_from_handle (session_handle_t handle)
{
return session_get_from_handle (handle);
}
always_inline void
listen_session_parse_handle (session_handle_t handle, u32 * index,
u32 * thread_index)
{
session_parse_handle (handle, index, thread_index);
}
always_inline session_t *
listen_session_alloc (u8 thread_index, session_type_t type)
{
session_t *s;
s = session_alloc (thread_index);
s->session_type = type;
s->session_state = SESSION_STATE_LISTENING;
return s;
}
always_inline session_t *
listen_session_get (u32 ls_index)
{
return session_get (ls_index, 0);
}
always_inline void
listen_session_free (session_t * s)
{
ASSERT (!s->rx_fifo);
session_free (s);
}
always_inline session_t *
ho_session_alloc (void)
{
session_t *s;
ASSERT (vlib_get_thread_index () == 0);
s = session_alloc (0);
s->session_state = SESSION_STATE_CONNECTING;
s->flags |= SESSION_F_HALF_OPEN;
/* Not ideal. Half-opens are only allocated from main with worker barrier
* but can be cleaned up, i.e., session_half_open_free, from main without
* a barrier. In debug images, the free_bitmap can grow while workers peek
* the sessions pool, e.g., session_half_open_migrate_notify, and as a
* result crash while validating the session. To avoid this, grow the bitmap
* now. */
if (CLIB_DEBUG)
{
session_t *sp = session_main.wrk[0].sessions;
clib_bitmap_validate (pool_header (sp)->free_bitmap,
s->session_index + 1);
}
return s;
}
always_inline session_t *
ho_session_get (u32 ho_index)
{
return session_get (ho_index, 0 /* half-open thread */);
}
always_inline void
ho_session_free (session_t *s)
{
ASSERT (!s->rx_fifo && s->thread_index == 0);
session_free (s);
}
transport_connection_t *listen_session_get_transport (session_t * s);
/*
* Session layer functions
*/
always_inline session_main_t *
vnet_get_session_main ()
{
return &session_main;
}
always_inline session_worker_t *
session_main_get_worker (u32 thread_index)
{
return &session_main.wrk[thread_index];
}
static inline session_worker_t *
session_main_get_worker_if_valid (u32 thread_index)
{
if (thread_index > vec_len (session_main.wrk))
return 0;
return &session_main.wrk[thread_index];
}
always_inline svm_msg_q_t *
session_main_get_vpp_event_queue (u32 thread_index)
{
return session_main.wrk[thread_index].vpp_event_queue;
}
always_inline u8
session_main_is_enabled ()
{
return session_main.is_enabled == 1;
}
#define session_cli_return_if_not_enabled() \
do { \
if (!session_main.is_enabled) \
return clib_error_return (0, "session layer is not enabled"); \
} while (0)
int session_main_flush_enqueue_events (u8 proto, u32 thread_index);
int session_main_flush_all_enqueue_events (u8 transport_proto);
void session_queue_run_on_main_thread (vlib_main_t * vm);
/**
* Add session node pending buffer with custom node
*
* @param thread_index worker thread expected to send the buffer
* @param bi buffer index
* @param next_node next node edge index for buffer. Edge to next node
* must exist
*/
always_inline void
session_add_pending_tx_buffer (u32 thread_index, u32 bi, u32 next_node)
{
session_worker_t *wrk = session_main_get_worker (thread_index);
vec_add1 (wrk->pending_tx_buffers, bi);
vec_add1 (wrk->pending_tx_nexts, next_node);
if (PREDICT_FALSE (wrk->state == SESSION_WRK_INTERRUPT))
vlib_node_set_interrupt_pending (wrk->vm, session_queue_node.index);
}
always_inline void
session_wrk_update_time (session_worker_t *wrk, f64 now)
{
wrk->last_vlib_time = now;
wrk->last_vlib_us_time = wrk->last_vlib_time * CLIB_US_TIME_FREQ;
}
void session_wrk_enable_adaptive_mode (session_worker_t *wrk);
fifo_segment_t *session_main_get_wrk_mqs_segment (void);
void session_node_enable_disable (u8 is_en);
clib_error_t *vnet_session_enable_disable (vlib_main_t * vm, u8 is_en);
void session_wrk_handle_evts_main_rpc (void *);
session_t *session_alloc_for_connection (transport_connection_t * tc);
session_t *session_alloc_for_half_open (transport_connection_t *tc);
typedef void (pool_safe_realloc_rpc_fn) (void *rpc_args);
typedef struct
{
u8 ph[STRUCT_OFFSET_OF (pool_header_t, max_elts) + 4];
u32 flag;
} pool_safe_realloc_header_t;
STATIC_ASSERT_SIZEOF (pool_safe_realloc_header_t, sizeof (pool_header_t));
#define POOL_REALLOC_SAFE_ELT_THRESH 32
#define pool_realloc_flag(PH) \
((pool_safe_realloc_header_t *) pool_header (PH))->flag
typedef struct pool_realloc_rpc_args_
{
void **pool;
uword elt_size;
uword align;
} pool_realloc_rpc_args_t;
always_inline void
pool_program_safe_realloc_rpc (void *args)
{
vlib_main_t *vm = vlib_get_main ();
u32 free_elts, max_elts, n_alloc;
pool_realloc_rpc_args_t *pra;
ASSERT (vlib_get_thread_index () == 0);
pra = (pool_realloc_rpc_args_t *) args;
vlib_worker_thread_barrier_sync (vm);
free_elts = _pool_free_elts (*pra->pool, pra->elt_size);
if (free_elts < POOL_REALLOC_SAFE_ELT_THRESH)
{
max_elts = _vec_max_len (*pra->pool, pra->elt_size);
n_alloc = clib_max (2 * max_elts, POOL_REALLOC_SAFE_ELT_THRESH);
_pool_alloc (pra->pool, free_elts + n_alloc, pra->align, 0,
pra->elt_size);
}
pool_realloc_flag (*pra->pool) = 0;
clib_mem_free (args);
vlib_worker_thread_barrier_release (vm);
}
always_inline void
pool_program_safe_realloc (void **p, u32 elt_size, u32 align)
{
pool_realloc_rpc_args_t *pra;
/* Reuse pad as a realloc flag */
if (pool_realloc_flag (*p))
return;
pra = clib_mem_alloc (sizeof (*pra));
pra->pool = p;
pra->elt_size = elt_size;
pra->align = align;
pool_realloc_flag (*p) = 1;
session_send_rpc_evt_to_thread (0 /* thread index */,
pool_program_safe_realloc_rpc, pra);
}
#define pool_needs_realloc(P) \
((!P) || \
(vec_len (pool_header (P)->free_indices) < POOL_REALLOC_SAFE_ELT_THRESH && \
pool_free_elts (P) < POOL_REALLOC_SAFE_ELT_THRESH))
#define pool_get_aligned_safe(P, E, align) \
do \
{ \
if (PREDICT_FALSE (pool_needs_realloc (P))) \
{ \
if (PREDICT_FALSE (!(P))) \
{ \
pool_alloc_aligned (P, POOL_REALLOC_SAFE_ELT_THRESH, align); \
} \
else if (PREDICT_FALSE (!pool_free_elts (P))) \
{ \
vlib_workers_sync (); \
pool_alloc_aligned (P, pool_max_len (P), align); \
vlib_workers_continue (); \
ALWAYS_ASSERT (pool_free_elts (P) > 0); \
} \
else \
{ \
pool_program_safe_realloc ((void **) &(P), sizeof ((P)[0]), \
_vec_align (P, align)); \
} \
} \
pool_get_aligned (P, E, align); \
} \
while (0)
#endif /* __included_session_h__ */
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/