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GNU GENERAL PUBLIC LICENSE
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Public License instead of this License. But first, please read
<http://www.gnu.org/philosophy/why-not-lgpl.html>.
openair2/LAYER2/RLC/AM/rlc_am.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
#include "platform_constants.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_mux_proto_extern.h"
#include "rlc_am_segment_proto_extern.h"
#include "rlc_am_receiver_proto_extern.h"
#include "rlc_am_demux_proto_extern.h"
#include "rlc_am_reset_proto_extern.h"
#include "rlc_am_status_proto_extern.h"
#include "rlc_am_errno.h"
#include "umts_timer_proto_extern.h"
#include "rlc_am_discard_rx_proto_extern.h"
#include "rlc_am_discard_tx_proto_extern.h"
#include "rlc_am_discard_notif_proto_extern.h"
#include "mac_primitives.h"
#include "rlc_primitives.h"
#include "rlc_am_control_primitives_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "list.h"
#include "LAYER2/MAC/extern.h"
//#define DEBUG_RLC_AM_DATA_REQUEST
//#define DEBUG_RLC_AM_TX
//#define DEBUG_RLC_AM_RX
//#define DEBUG_RLC_AM_BO
//-----------------------------------------------------------------------------
void display_protocol_vars_rlc_am (struct rlc_am_entity *rlcP);
uint32_t rlc_am_get_buffer_occupancy_in_pdus_for_ch1 (struct rlc_am_entity *rlcP);
uint32_t rlc_am_get_buffer_occupancy_in_pdus_for_ch2 (struct rlc_am_entity *rlcP);
void *rlc_am_tx (void *argP);
void rlc_am_rx (void *argP, struct mac_data_ind data_indP);
//-----------------------------------------------------------------------------
uint32_t
rlc_am_get_buffer_occupancy_in_bytes_ch1 (struct rlc_am_entity *rlcP)
{
//-----------------------------------------------------------------------------
uint32_t sum = 0;
if (rlcP->buffer_occupancy > 0) {
sum += (rlcP->pdus_to_mac_layer_ch1.nb_elements * rlcP->pdu_size);
sum += (rlcP->buffer_occupancy_retransmission_buffer * rlcP->pdu_size);
sum += rlcP->control.nb_elements * rlcP->pdu_size; // TEST LG + HA 23/10/2008
sum += rlcP->buffer_occupancy; // approximation because of headers of pdus
} else {
if ((rlcP->li_one_byte_short_to_add_in_next_pdu) ||
(rlcP->li_exactly_filled_to_add_in_next_pdu)) {
// WARNING LG WE ASSUME TRANSPORT BLOCKS ARE < 125 bytes
sum = rlcP->pdu_size; // 4 bytes; // so this is the exact size of the next TB to be sent (SN + 2LIs)
}
}
#ifdef DEBUG_RLC_AM_BO
msg ("[RLC_AM][RB %d] DTCH BO: %d bytes \n", rlcP->rb_id,sum);
#endif
return sum;
}
//-----------------------------------------------------------------------------
uint32_t
rlc_am_get_buffer_occupancy_in_bytes_ch2 (struct rlc_am_entity * rlcP)
{
//-----------------------------------------------------------------------------
#ifdef DEBUG_RLC_AM_BO
msg ("[RLC_AM][RB %d] DCCH BO: CONTROL %d DCCH %d\n", rlcP->rb_id, rlcP->control.nb_elements * rlcP->pdu_size,
rlcP->pdus_to_mac_layer_ch2.nb_elements * rlcP->pdu_size);
#endif
return rlcP->control.nb_elements * rlcP->pdu_size + rlcP->pdus_to_mac_layer_ch2.nb_elements * rlcP->pdu_size;
}
//-----------------------------------------------------------------------------
uint32_t
rlc_am_get_buffer_occupancy_in_pdus_ch1 (struct rlc_am_entity * rlcP)
{
//-----------------------------------------------------------------------------
uint32_t sum = 0;
sum += rlcP->pdus_to_mac_layer_ch1.nb_elements;
sum += rlcP->buffer_occupancy_retransmission_buffer;
sum += rlcP->control.nb_elements; // TEST LG + HA 23/10/2008
sum += (rlcP->buffer_occupancy / (rlcP->pdu_size - 2)); // minus 2 = size min for pdu header
#ifdef DEBUG_RLC_AM_BO
msg ("[RLC_AM][RB %d] BO : CH1 %d blocks \n", rlcP->rb_id, rlcP->pdus_to_mac_layer_ch1.nb_elements);
msg ("[RLC_AM][RB %d] BO : RETRANS BUFFER %d blocks \n", rlcP->rb_id, rlcP->buffer_occupancy_retransmission_buffer);
msg ("[RLC_AM][RB %d] BO : BUFFER SDU %d blocks \n", rlcP->rb_id, rlcP->buffer_occupancy / (rlcP->pdu_size - 2));
#endif
return sum;
}
//-----------------------------------------------------------------------------
uint32_t
rlc_am_get_buffer_occupancy_in_pdus_ch2 (struct rlc_am_entity * rlcP)
{
//-----------------------------------------------------------------------------
#ifdef DEBUG_RLC_AM_BO
msg ("[RLC_AM][RB %d] BO : CH2 CONTROL %d DCCH %d\n", rlcP->rb_id, rlcP->control.nb_elements, rlcP->pdus_to_mac_layer_ch2.nb_elements);
#endif
return rlcP->control.nb_elements + rlcP->pdus_to_mac_layer_ch2.nb_elements;
}
//-----------------------------------------------------------------------------
void
rlc_am_get_pdus (void *argP, uint8_t traffic_typeP)
{
//-----------------------------------------------------------------------------
struct rlc_am_entity *rlc = (struct rlc_am_entity *) argP;
switch (rlc->protocol_state) {
case RLC_NULL_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the NULL state the RLC entity does not exist and therefore it is not possible to transfer any data through it.
// Upon reception of a CRLC-CONFIG-Req from upper layer indicating establishment, the RLC entity:
// - is created; and
// - enters the DATA_TRANSFER_READY state.
break;
case RLC_DATA_TRANSFER_READY_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the DATA_TRANSFER_READY state, acknowledged mode data can be exchanged between the entities according to subclause 11.3.
// Upon reception of a CRLC-CONFIG-Req from upper layer indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon detection of an initiating condition for the RLC reset procedure described in subclause 11.4.2, the RLC entity:
// - initiates the RLC reset procedure (see subclause 11.4); and
// - enters the RESET_PENDING state.
// Upon reception of a RESET PDU, the RLC entity responds according to subclause 11.4.3.
// Upon reception of a RESET ACK PDU, the RLC entity takes no action.
// Upon reception of CRLC-SUSPEND-Req from upper layer, the RLC entity is suspended and enters the LOCAL_SUSPEND state.
// SEND DATA TO MAC
umts_timer_check_time_out (&rlc->rlc_am_timer_list, *rlc->frame_tick_milliseconds);
if ((rlc->send_status_pdu_requested)) {
// may be timer status prohibit
if (rlc_am_send_status (rlc) > 0) {
rlc->send_status_pdu_requested = 0;
}
} else if ((rlc->timer_status_periodic) && ((Mac_rlc_xface->frame % (rlc->timer_status_periodic / 10)) == 0)
&& (rlc->last_tx_status_frame != Mac_rlc_xface->frame)) {
// may be MAC can poll RLC more than once in a time frame
//msg ("[RLC_AM][RB %d] SEND STATUS PERIODIC frame %d\n", rlc->rb_id, Mac_rlc_xface->frame);
if (rlc_am_send_status (rlc) > 0) {
rlc->send_status_pdu_requested = 0;
}
rlc->last_tx_status_frame = Mac_rlc_xface->frame;
}
#ifdef NODE_MT
rlc_am_mux_ue (rlc, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS | RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
#else
rlc_am_mux_rg (rlc, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS | RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
#endif
break;
case RLC_RESET_PENDING_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the RESET_PENDING state the entity waits for a response from its peer entity and no data can be exchanged between the entities.
// Upon reception of a CRLC-CONFIG-Req from upper layer indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon reception of a RESET ACK PDU with the same RSN value as in the corresponding RESET PDU, the RLC entity:
// - acts according to subclause 11.4.4; and
// - enters the DATA_TRANSFER_READY state.
// Upon reception of a RESET ACK PDU with a different RSN value as in the corresponding RESET PDU, the RLC entity:
// - discards the RESET ACK PDU (see subclause 11.4.4); and
// - stays in the RESET_PENDING state.
// Upon reception of a RESET PDU, the RLC entity:
// - responds according to subclause 11.4.3; and
// - stays in the RESET_PENDING state.
// Upon reception of CRLC-SUSPEND-Req from upper layer, the RLC entity:
// - enters the RESET_AND_SUSPEND state.
umts_timer_check_time_out (&rlc->rlc_am_timer_list, *rlc->frame_tick_milliseconds);
#ifdef NODE_MT
rlc_am_mux_ue (rlc, RLC_AM_TRAFFIC_NOT_ALLOWED);
#else
rlc_am_mux_rg (rlc, RLC_AM_TRAFFIC_NOT_ALLOWED);
#endif
break;
case RLC_RESET_AND_SUSPEND_STATE:
// In the RESET_ AND_SUSPEND state, the entity waits for a response from its peer entity or a primitive (CRLC-RESUME-Req) from its upper layer and no data can be exchanged between the entities.
// Upon reception of CRLC-CONFIG-Req from upper layer indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon reception of a RESET ACK PDU with the same RSN value as in the corresponding RESET PDU, the RLC entity:
// - acts according to subclause 11.4.4; and
// - enters the LOCAL_SUSPEND state.
// Upon reception of CRLC-RESUME-Req from upper layer in this state, the RLC entity:
// - is resumed, i.e. releases the suspend constraint; and
// - enters the RESET_PENDING state.
#ifdef NODE_MT
rlc_am_mux_ue (rlc, RLC_AM_TRAFFIC_NOT_ALLOWED);
#else
rlc_am_mux_rg (rlc, RLC_AM_TRAFFIC_NOT_ALLOWED);
#endif
break;
case RLC_LOCAL_SUSPEND_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the LOCAL_SUSPEND state, the RLC entity is suspended, i.e. it does not send AMD PDUs with SN greater than or equal to certain specified value (see subclause 9.7.5).
// Upon reception of CRLC-RESUME-Req from upper layers in this state, the RLC entity:
// - resumes the data transmission; and
// - enters the DATA_TRANSFER_READY state.
// Upon reception of CRLC-CONFIG-Req from upper layers indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon detection of an initiating condition for RLC reset procedure described in subclause 11.4.2, the RLC entity:
// - initiates the RLC reset procedure (see subclause 11.4); and
// - enters the RESET_AND_SUSPEND state.
// TO DO TAKE CARE OF SN : THE IMPLEMENTATION OF THIS FUNCTIONNALITY IS NOT CRITICAL
if ((rlc->send_status_pdu_requested)) {
rlc_am_send_status (rlc);
rlc->send_status_pdu_requested = 0;
}
#ifdef NODE_MT
rlc_am_mux_ue (rlc, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS);
#else
rlc_am_mux_rg (rlc, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS);
#endif
break;
default:
msg ("[RLC_AM][RB %d] MAC_DATA_REQ UNKNOWN PROTOCOL STATE 0x%02X\n", rlc->rb_id, rlc->protocol_state);
}
}
//-----------------------------------------------------------------------------
void
rlc_am_rx (void *argP, struct mac_data_ind data_indP)
{
//-----------------------------------------------------------------------------
struct rlc_am_entity *rlc = (struct rlc_am_entity *) argP;
#ifdef DEBUG_RLC_AM_RX
msg("[RLC][AM] In rlc_am_rx\n");
#endif
switch (rlc->protocol_state) {
case RLC_NULL_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the NULL state the RLC entity does not exist and therefore it is not possible to transfer any data through it.
// Upon reception of a CRLC-CONFIG-Req from upper layer indicating establishment, the RLC entity:
// - is created; and
// - enters the DATA_TRANSFER_READY state.
msg ("[RLC_AM %p] ERROR MAC_DATA_IND IN RLC_NULL_STATE\n", argP);
list_free (&data_indP.data);
break;
case RLC_DATA_TRANSFER_READY_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the DATA_TRANSFER_READY state, acknowledged mode data can be exchanged between the entities according to subclause 11.3.
// Upon reception of a CRLC-CONFIG-Req from upper layer indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon detection of an initiating condition for the RLC reset procedure described in subclause 11.4.2, the RLC entity:
// - initiates the RLC reset procedure (see subclause 11.4); and
// - enters the RESET_PENDING state.
// Upon reception of a RESET PDU, the RLC entity responds according to subclause 11.4.3.
// Upon reception of a RESET ACK PDU, the RLC entity takes no action.
// Upon reception of CRLC-SUSPEND-Req from upper layer, the RLC entity is suspended and enters the LOCAL_SUSPEND state.
if ((rlc->rlc_am_timer_list.head)) {
umts_timer_check_time_out (&rlc->rlc_am_timer_list, *rlc->frame_tick_milliseconds);
}
rlc_am_demux_routing (rlc, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS | RLC_AM_TRAFFIC_ALLOWED_FOR_DATA, data_indP);
break;
case RLC_RESET_PENDING_STATE:
case RLC_RESET_AND_SUSPEND_STATE:
case RLC_LOCAL_SUSPEND_STATE:
// from 3GPP TS 25.322 V4.2.0
// In the RESET_PENDING state the entity waits for a response from its peer entity and no data can be exchanged between the entities.
// Upon reception of a CRLC-CONFIG-Req from upper layer indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon reception of a RESET ACK PDU with the same RSN value as in the corresponding RESET PDU, the RLC entity:
// - acts according to subclause 11.4.4; and
// - enters the DATA_TRANSFER_READY state.
// Upon reception of a RESET ACK PDU with a different RSN value as in the corresponding RESET PDU, the RLC entity:
// - discards the RESET ACK PDU (see subclause 11.4.4); and
// - stays in the RESET_PENDING state.
// Upon reception of a RESET PDU, the RLC entity:
// - responds according to subclause 11.4.3; and
// - stays in the RESET_PENDING state.
// Upon reception of CRLC-SUSPEND-Req from upper layer, the RLC entity:
// - enters the RESET_AND_SUSPEND state.
// In the RESET_ AND_SUSPEND state, the entity waits for a response from its peer entity or a primitive (CRLC-RESUME-Req) from its upper layer and no data can be exchanged between the entities.
// Upon reception of CRLC-CONFIG-Req from upper layer indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon reception of a RESET ACK PDU with the same RSN value as in the corresponding RESET PDU, the RLC entity:
// - acts according to subclause 11.4.4; and
// - enters the LOCAL_SUSPEND state.
// Upon reception of CRLC-RESUME-Req from upper layer in this state, the RLC entity:
// - is resumed, i.e. releases the suspend constraint; and
// - enters the RESET_PENDING state.
// from 3GPP TS 25.322 V4.2.0
// In the LOCAL_SUSPEND state, the RLC entity is suspended, i.e. it does not send AMD PDUs with SN greater than or equal to certain specified value (see subclause 9.7.5).
// Upon reception of CRLC-RESUME-Req from upper layers in this state, the RLC entity:
// - resumes the data transmission; and
// - enters the DATA_TRANSFER_READY state.
// Upon reception of CRLC-CONFIG-Req from upper layers indicating release, the RLC entity:
// - enters the NULL state; and
// - is considered as being terminated.
// Upon detection of an initiating condition for RLC reset procedure described in subclause 11.4.2, the RLC entity:
// - initiates the RLC reset procedure (see subclause 11.4); and
// - enters the RESET_AND_SUSPEND state.
if ((rlc->rlc_am_timer_list.head)) {
umts_timer_check_time_out (&rlc->rlc_am_timer_list, *rlc->frame_tick_milliseconds);
}
rlc_am_demux_routing (rlc, RLC_AM_TRAFFIC_NOT_ALLOWED, data_indP);
break;
default:
msg ("[RLC_AM %p] TX UNKNOWN PROTOCOL STATE 0x%02X\n", rlc, rlc->protocol_state);
}
}
//-----------------------------------------------------------------------------
struct mac_status_resp
rlc_am_mac_status_indication (void *rlcP, uint16_t no_tbP, uint16_t tb_sizeP, struct mac_status_ind tx_statusP)
{
//-----------------------------------------------------------------------------
struct mac_status_resp status_resp;
struct rlc_am_entity *rlc = (struct rlc_am_entity *) rlcP;
rlc_am_discard_check_sdu_time_out (rlc);
// call only for knowing if control pdu to transmit
// special case: no data at startup on this side, but peer entity tx full sspeed
// peer entity wqit for acks
rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS);
rlc->nb_pdu_requested_by_mac_on_ch1 = no_tbP;
//((struct rlc_am_entity*)rlcP)->rlc_pdu_size = tb_sizeP; no modification of pdu_size for RLC AM
status_resp.buffer_occupancy_in_pdus = rlc_am_get_buffer_occupancy_in_pdus_ch1 (rlc);
status_resp.buffer_occupancy_in_pdus += rlc_am_get_buffer_occupancy_in_pdus_ch2 (rlc);
status_resp.buffer_occupancy_in_pdus += rlc->control.nb_elements;
status_resp.buffer_occupancy_in_bytes = status_resp.buffer_occupancy_in_pdus * (rlc)->pdu_size;
status_resp.rlc_info.rlc_protocol_state = (rlc)->protocol_state;
#ifdef DEBUG_RLC_AM_TX
msg ("[RLC_AM][RB %d] MAC_STATUS_INDICATION %d TBs -> MAC_STATUS_RESPONSE %d TBs FRAME %d\n", rlc->rb_id, no_tbP, status_resp.buffer_occupancy_in_pdus,
Mac_rlc_xface->frame);
#endif
return status_resp;
}
//-----------------------------------------------------------------------------
struct mac_status_resp
rlc_am_mac_status_indication_on_first_channel (void *rlcP, uint16_t no_tbP, uint16_t tb_sizeP, struct mac_status_ind tx_statusP)
{
//-----------------------------------------------------------------------------
struct mac_status_resp status_resp;
rlc_am_discard_check_sdu_time_out ((struct rlc_am_entity *) rlcP);
((struct rlc_am_entity *) rlcP)->nb_pdu_requested_by_mac_on_ch1 = no_tbP;
//((struct rlc_am_entity*)rlcP)->rlc_pdu_size = tb_sizeP; no modification of pdu_size for RLC AM
status_resp.buffer_occupancy_in_pdus = rlc_am_get_buffer_occupancy_in_pdus_ch1 ((struct rlc_am_entity *) rlcP);
status_resp.buffer_occupancy_in_bytes = status_resp.buffer_occupancy_in_pdus * ((struct rlc_am_entity *) rlcP)->pdu_size;
status_resp.rlc_info.rlc_protocol_state = ((struct rlc_am_entity *) rlcP)->protocol_state;
#ifdef DEBUG_RLC_AM_TX
msg ("[RLC_AM][RB %d] CHANNEL 1 MAC_STATUS_INDICATION (DATA) %d TBs -> MAC_STATUS_RESPONSE %d TBs\n", ((struct rlc_am_entity*) rlcP)->rb_id, no_tbP,
status_resp.buffer_occupancy_in_pdus);
#endif
return status_resp;
}
//-----------------------------------------------------------------------------
struct mac_status_resp
rlc_am_mac_status_indication_on_second_channel (void *rlcP, uint16_t no_tbP, uint16_t tb_sizeP, struct mac_status_ind tx_statusP)
{
//-----------------------------------------------------------------------------
struct mac_status_resp status_resp;
rlc_am_discard_check_sdu_time_out ((struct rlc_am_entity *) rlcP);
((struct rlc_am_entity *) rlcP)->nb_pdu_requested_by_mac_on_ch2 = no_tbP;
//((struct rlc_am_entity*)rlcP)->rlc_pdu_size = tb_sizeP; no modification of pdu_size for RLC AM
status_resp.buffer_occupancy_in_pdus = rlc_am_get_buffer_occupancy_in_pdus_ch2 ((struct rlc_am_entity *) rlcP);
status_resp.buffer_occupancy_in_bytes = status_resp.buffer_occupancy_in_pdus * ((struct rlc_am_entity *) rlcP)->pdu_size;
status_resp.rlc_info.rlc_protocol_state = ((struct rlc_am_entity *) rlcP)->protocol_state;
#ifdef DEBUG_RLC_AM_TX
msg ("[RLC_AM][RB %d] CHANNEL 2 MAC_STATUS_INDICATION (CONTROL) %d TBs -> MAC_STATUS_RESPONSE %d TBs\n", ((struct rlc_am_entity*) rlcP)->rb_id, no_tbP,
status_resp.buffer_occupancy_in_pdus);
#endif
return status_resp;
}
//-----------------------------------------------------------------------------
struct mac_data_req
rlc_am_mac_data_request (void *rlcP)
{
//-----------------------------------------------------------------------------
struct mac_data_req data_req;
mem_block_t *pdu;
signed int nb_pdu_to_transmit = ((struct rlc_am_entity *) rlcP)->nb_pdu_requested_by_mac_on_ch1 ;
//rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS | RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
list_init (&data_req.data, NULL);
//list_add_list (&((struct rlc_am_entity *) rlcP)->pdus_to_mac_layer_ch1, &data_req.data);
while (nb_pdu_to_transmit > 0 ) {
pdu = list_remove_head (&((struct rlc_am_entity *) rlcP)->pdus_to_mac_layer_ch1);
if (pdu != null) {
list_add_tail_eurecom (pdu, &data_req.data);
} else {
//msg ("[RLC_AM][RB %d] WARNING MAC_DATA_REQUEST CANNOT GIVE A PDU REQUESTED BY MAC\n", ((struct rlc_am_entity *) rlcP)->rb_id);
}
nb_pdu_to_transmit = nb_pdu_to_transmit - 1;
}
//list_add_list (&((struct rlc_am_entity *) rlcP)->pdus_to_mac_layer_ch2, &data_req.data);
#ifdef DEBUG_RLC_AM_TX
msg ("[RLC_AM][RB %d] MAC_DATA_REQUEST %d TBs (REQUESTED %d) Frame %d\n", ((struct rlc_am_entity *) rlcP)->rb_id, data_req.data.nb_elements,
((struct rlc_am_entity *) rlcP)->nb_pdu_requested_by_mac_on_ch1 , Mac_rlc_xface->frame);
#endif
data_req.buffer_occupancy_in_pdus = rlc_am_get_buffer_occupancy_in_pdus_ch1 ((struct rlc_am_entity *) rlcP);
data_req.buffer_occupancy_in_pdus += rlc_am_get_buffer_occupancy_in_pdus_ch2 ((struct rlc_am_entity *) rlcP);
data_req.buffer_occupancy_in_bytes = data_req.buffer_occupancy_in_pdus * ((struct rlc_am_entity *) rlcP)->pdu_size;
data_req.rlc_info.rlc_protocol_state = ((struct rlc_am_entity *) rlcP)->protocol_state;
return data_req;
}
//-----------------------------------------------------------------------------
struct mac_data_req
rlc_am_mac_data_request_on_first_channel (void *rlcP)
{
//-----------------------------------------------------------------------------
struct mac_data_req data_req;
// from TS25.322 V4.2.0 p13
// In case two logical channels are configured in the uplink, AMD PDUs are transmitted
// on the first logical channel, and control PDUs are transmitted on the second logical
// channel. In case two logical channels are configured in the downlink, AMD and Control
// PDUs can be transmitted on any of the two logical channels.
#ifdef NODE_RG
rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS | RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
#else
rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
#endif
list_init (&data_req.data, NULL);
list_add_list (&((struct rlc_am_entity *) rlcP)->pdus_to_mac_layer_ch1, &data_req.data);
#ifdef DEBUG_RLC_AM_TX
msg ("[RLC_AM][RB %d] MAC_DATA_REQUEST (DATA) %d TBs\n", ((struct rlc_am_entity *) rlcP)->rb_id, data_req.data.nb_elements);
#endif
data_req.buffer_occupancy_in_pdus = rlc_am_get_buffer_occupancy_in_pdus_ch1 ((struct rlc_am_entity *) rlcP);
data_req.buffer_occupancy_in_bytes = rlc_am_get_buffer_occupancy_in_bytes_ch1 ((struct rlc_am_entity *) rlcP);
data_req.rlc_info.rlc_protocol_state = ((struct rlc_am_entity *) rlcP)->protocol_state;
return data_req;
}
//-----------------------------------------------------------------------------
struct mac_data_req
rlc_am_mac_data_request_on_second_channel (void *rlcP)
{
//-----------------------------------------------------------------------------
struct mac_data_req data_req;
// from TS25.322 V4.2.0 p13
// In case two logical channels are configured in the uplink, AMD PDUs are transmitted
// on the first logical channel, and control PDUs are transmitted on the second logical
// channel. In case two logical channels are configured in the downlink, AMD and Control
// PDUs can be transmitted on any of the two logical channels.
#ifdef NODE_RG
rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS | RLC_AM_TRAFFIC_ALLOWED_FOR_DATA);
#else
rlc_am_get_pdus (rlcP, RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS);
#endif
list_init (&data_req.data, NULL);
list_add_list (&((struct rlc_am_entity *) rlcP)->pdus_to_mac_layer_ch2, &data_req.data);
#ifdef DEBUG_RLC_AM_TX
msg ("[RLC_AM][RB %d] MAC_DATA_REQUEST (CONTROL) %d TBs\n", ((struct rlc_am_entity *) rlcP)->rb_id, data_req.data.nb_elements);
#endif
data_req.buffer_occupancy_in_pdus = rlc_am_get_buffer_occupancy_in_pdus_ch2 ((struct rlc_am_entity *) rlcP);
data_req.buffer_occupancy_in_bytes = rlc_am_get_buffer_occupancy_in_bytes_ch2 ((struct rlc_am_entity *) rlcP);
data_req.rlc_info.rlc_protocol_state = ((struct rlc_am_entity *) rlcP)->protocol_state;
return data_req;
}
//-----------------------------------------------------------------------------
void
rlc_am_mac_data_indication (void *rlcP, struct mac_data_ind data_indP)
{
//-----------------------------------------------------------------------------
rlc_am_rx (rlcP, data_indP);
}
//-----------------------------------------------------------------------------
void
rlc_am_data_req (void *rlcP, mem_block_t * sduP)
{
//-----------------------------------------------------------------------------
struct rlc_am_entity *rlc = (struct rlc_am_entity *) rlcP;
uint32_t mui;
uint16_t data_offset;
uint16_t data_size;
uint8_t conf;
if ((rlc->input_sdus[rlc->next_sdu_index] == NULL) && (((rlc->next_sdu_index + 1) % rlc->size_input_sdus_buffer) != rlc->current_sdu_index)) {
rlc->stat_tx_pdcp_sdu += 1;
rlc->input_sdus[rlc->next_sdu_index] = sduP;
mui = ((struct rlc_am_data_req *) (sduP->data))->mui;
data_offset = ((struct rlc_am_data_req *) (sduP->data))->data_offset;
data_size = ((struct rlc_am_data_req *) (sduP->data))->data_size;
conf = ((struct rlc_am_data_req *) (sduP->data))->conf;
((struct rlc_am_tx_sdu_management *) (sduP->data))->mui = mui;
((struct rlc_am_tx_sdu_management *) (sduP->data))->sdu_size = data_size;
((struct rlc_am_tx_sdu_management *) (sduP->data))->confirm = conf;
rlc->buffer_occupancy += ((struct rlc_am_tx_sdu_management *) (sduP->data))->sdu_size;
rlc->nb_sdu += 1;
((struct rlc_am_tx_sdu_management *) (sduP->data))->first_byte = &sduP->data[data_offset];
((struct rlc_am_tx_sdu_management *) (sduP->data))->sdu_remaining_size = ((struct rlc_am_tx_sdu_management *) (sduP->data))->sdu_size;
((struct rlc_am_tx_sdu_management *) (sduP->data))->sdu_segmented_size = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->sdu_creation_time = *rlc->frame_tick_milliseconds;
((struct rlc_am_tx_sdu_management *) (sduP->data))->nb_pdus = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->nb_pdus_ack = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->nb_pdus_time = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->nb_pdus_internal_use = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->segmented = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->discarded = 0;
((struct rlc_am_tx_sdu_management *) (sduP->data))->li_index_for_discard = -1;
((struct rlc_am_tx_sdu_management *) (sduP->data))->no_new_sdu_segmented_in_last_pdu = 0;
rlc->next_sdu_index = (rlc->next_sdu_index + 1) % rlc->size_input_sdus_buffer;
#ifdef DEBUG_RLC_AM_DATA_REQUEST
msg ("[RLC_AM][RB %d] RLC_AM_DATA_REQ size %d Bytes, NB SDU %d current_sdu_index=%d next_sdu_index=%d conf %d mui %d ",
rlc->rb_id, data_size, rlc->nb_sdu, rlc->current_sdu_index, rlc->next_sdu_index, conf, mui);
msg ("BO=%ld Bytes\n", rlc->buffer_occupancy);
#endif
} else {
#ifdef DEBUG_RLC_AM_DATA_REQUEST
msg ("[RLC_AM][RB %d] RLC_AM_DATA_REQ BUFFER FULL, NB SDU %d current_sdu_index=%d next_sdu_index=%d size_input_sdus_buffer=%d\n",
rlc->rb_id, rlc->nb_sdu, rlc->current_sdu_index, rlc->next_sdu_index, rlc->size_input_sdus_buffer);
#endif
rlc->stat_tx_pdcp_sdu_discarded += 1;
free_mem_block (sduP);
}
}
openair2/LAYER2/RLC/AM/rlc_am_constants.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_constant.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_CONSTANT_H__
# define __RLC_AM_CONSTANT_H__
# define RLC_AM_LOCATION_UTRAN 0xBA
# define RLC_AM_LOCATION_UE 0x01
//----------------------------------------------------------
// AMD DATA, CONTROL PDU parameters
//----------------------------------------------------------
# define NB_MAX_SUFI 30
# define SUFI_MAX_SIZE 40
// SUFI field (4 bits)
# define RLC_AM_SUFI_NO_MORE 0x0
# define RLC_AM_SUFI_WINDOW 0x1
# define RLC_AM_SUFI_ACK 0x2
# define RLC_AM_SUFI_LIST 0x3
# define RLC_AM_SUFI_BITMAP 0x4
# define RLC_AM_SUFI_RLIST 0x5
# define RLC_AM_SUFI_MRW 0x6
# define RLC_AM_SUFI_MRW_ACK 0x7
# define RLC_AM_SUFI_NO_MORE_SIZE 4
//in bits
# define RLC_AM_SUFI_ACK_SIZE 16
//in bits
# define RLC_AM_SUFI_LIST_SIZE_MIN 24
//in bits
# define RLC_AM_SUFI_BITMAP_SIZE_MIN 28
//in bits
//----------------------------------------------------------
// values for ack field of struct rlc_am_tx_pdu_management
// this struct is mapped on the misc field of each pdu
# define RLC_AM_PDU_ACK_NO_EVENT 0
# define RLC_AM_PDU_ACK_EVENT 1
# define RLC_AM_PDU_NACK_EVENT -1
//----------------------------------------------------------
# define RLC_AM_SEND_MRW_OFF 0x0F
# define RLC_AM_SEND_MRW_ON 0xF0
//----------------------------------------------------------
// SN Field
# define RLC_AM_SN_1ST_PART_MASK 0x7F
# define RLC_AM_SN_2ND_PART_MASK 0xF8
//----------------------------------------------------------
// Polling bit (values shifted 2 bits left)
# define RLC_AM_P_STATUS_REPORT_NOT_REQUESTED 0
# define RLC_AM_P_STATUS_REPORT_REQUESTED 4
# define RLC_AM_P_STATUS_REPORT_MASK 4
//----------------------------------------------------------
// li field (values shifted 1 bit left)
# define RLC_AM_SEGMENT_NB_MAX_LI_PER_PDU 32
//----------------------------------------------------------
// shifted 3 bits left
# define RLC_AM_RESET_SEQUENCE_NUMBER_MASK 0x08
# define RLC_AM_TIMER_POLL_TIME_OUT_EVENT 0x001
# define RLC_AM_TIMER_POLL_PROHIBIT_TIME_OUT_EVENT 0x002
# define RLC_AM_TIMER_EPC_TIME_OUT_EVENT 0x004
# define RLC_AM_TIMER_DISCARD_TIME_OUT_EVENT 0x008
# define RLC_AM_TIMER_POLL_PERIODIC_TIME_OUT_EVENT 0x010
# define RLC_AM_TIMER_STATUS_PROHIBIT_TIME_OUT_EVENT 0x020
# define RLC_AM_TIMER_STATUS_PERIODIC_TIME_OUT_EVENT 0x040
# define RLC_AM_TIMER_RST_TIME_OUT_EVENT 0x080
# define RLC_AM_TIMER_MRW_TIME_OUT_EVENT 0x100
//----------------------------------------------------------
# define RLC_AM_SDU_SEGMENTS_SUBMITTED_TO_LOWER_LAYER 0xFF
// for sdu_header_copy
# define RLC_AM_SN_INVALID 0xFFFF
// PDU transmission
# define RLC_AM_PDU_COPY_LOCATION_RETRANSMISSION_BUFFER_TO_SEND 0x10
# define RLC_AM_PDU_COPY_LOCATION_PDUS_TO_MAC_LAYER 0x20
# define RLC_AM_PDU_COPY_LOCATION_MASK 0xF0
//----------------------------------------------------------
// Events defined for state model of the acknowledged mode entity
# define RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_NULL_STATE_EVENT 0x00
# define RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_DATA_TRANSFER_READY_STATE_EVENT 0x01
# define RLC_AM_RECEIVE_CRLC_SUSPEND_REQ_EVENT 0x10
# define RLC_AM_TRANSMIT_CRLC_SUSPEND_CNF_EVENT 0x11
# define RLC_AM_RECEIVE_CRLC_RESUME_REQ_EVENT 0x12
# define RLC_AM_RECEIVE_RESET_EVENT 0x20
# define RLC_AM_TRANSMIT_RESET_EVENT 0x21
# define RLC_AM_RECEIVE_RESET_ACK_EVENT 0x22
# define RLC_AM_TRANSMIT_RESET_ACK_EVENT 0x23
//----------------------------------------------------------
# define RLC_AM_TRAFFIC_NOT_ALLOWED 0x00
# define RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS 0xC0
// mutual exclusion of set bits with next value
# define RLC_AM_TRAFFIC_ALLOWED_FOR_DATA 0x0D
// mutual exclusion of set bits with previous value
# define RLC_AM_DCCH_ID 0xC0
// mutual exclusion of set bits with next value
# define RLC_AM_DTCH_ID 0x0D
// mutual exclusion of set bits with previous value
//----------------------------------------------------------
// for status report of transmission by MAC layer
# define RLC_AM_STATUS_PDU_TYPE 0x0001
# define RLC_AM_FIRST_STATUS_PDU_TYPE 0x0011
# define RLC_AM_LAST_STATUS_PDU_TYPE 0x0021
# define RLC_AM_MRW_STATUS_PDU_TYPE 0x0040
# define RLC_AM_RESET_PDU_TYPE 0x0080
# define RLC_AM_RESET_ACK_PDU_TYPE 0x0100
# define RLC_AM_DATA_POLL_PDU_TYPE 0x1800
# define RLC_AM_DATA_PDU_TYPE 0x1000
//----------------------------------------------------------
// TIMER EPC
# define TIMER_EPC_STATE_IDLE 0x00
# define TIMER_EPC_STATE_TIMER_ARMED 0x01
# define TIMER_EPC_STATE_TIMED_OUT 0x02
# define TIMER_EPC_STATE_VR_EP_COUNTING_DOWN 0x04
# define TIMER_EPC_STATE_VR_EP_EQUAL_ZERO 0x08
# define TIMER_EPC_PDU_STATUS_SUBMITTED_LOWER_LAYER_EVENT 0x01
# define TIMER_EPC_PDU_STATUS_TRANSMITED_EVENT 0x02
# define TIMER_EPC_TIMER_TIMED_OUT_EVENT 0x04
# define TIMER_EPC_VR_EP_EQUAL_ZERO_EVENT 0x08
# endif
openair2/LAYER2/RLC/AM/rlc_am_control_primitives.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_control_primitives.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_reset_proto_extern.h"
#include "rlc_am_errno.h"
#include "umts_timer_proto_extern.h"
#include "rlc_primitives.h"
#include "rlc_am_fsm_proto_extern.h"
#include "rlc_am_segment_proto_extern.h"
#include "rrm_config_structs.h"
#include "LAYER2/MAC/extern.h"
//-----------------------------------------------------------------------------
void config_req_rlc_am (struct rlc_am_entity* rlcP, module_id_t module_idP, rlc_am_info_t* config_amP, uint8_t rb_idP, rb_type_t rb_typeP);
void send_rlc_am_control_primitive (struct rlc_am_entity* rlcP, module_id_t module_idP, mem_block_t* cprimitiveP);
void init_rlc_am (struct rlc_am_entity* rlcP);
void rlc_am_reset_state_variables (struct rlc_am_entity* rlcP);
void rlc_am_alloc_buffers_after_establishment (struct rlc_am_entity* rlcP);
void rlc_am_discard_all_pdus (struct rlc_am_entity* rlcP);
void rlc_am_stop_all_timers (struct rlc_am_entity* rlcP);
void rlc_am_free_all_resources (struct rlc_am_entity* rlcP);
void rlc_am_set_configured_parameters (struct rlc_am_entity* rlcP, mem_block_t* cprimitiveP);
//void rlc_am_probing_get_buffer_occupancy_measurements (struct rlc_am_entity *rlcP, probing_report_traffic_rb_parameters *reportP, int measurement_indexP);
//-----------------------------------------------------------------------------
/*void
rlc_am_probing_get_buffer_occupancy_measurements (struct rlc_am_entity *rlcP, probing_report_traffic_rb_parameters *reportP, int measurement_indexP)
{
//-----------------------------------------------------------------------------
if (rlcP->protocol_state != RLC_NULL_STATE) {
reportP->incoming_sdu[measurement_indexP] = rlcP->buffer_occupancy;
reportP->retransmission[measurement_indexP] = rlcP->buffer_occupancy_retransmission_buffer * rlcP->pdu_size;
reportP->ready_to_send[measurement_indexP] = (rlcP->pdus_to_mac_layer_ch1.nb_elements + rlcP->pdus_to_mac_layer_ch2.nb_elements) * rlcP->pdu_size;
}
}*/
//-----------------------------------------------------------------------------
void
config_req_rlc_am (struct rlc_am_entity* rlcP, module_id_t module_idP, rlc_am_info_t* config_amP, uint8_t rb_idP, rb_type_t rb_typeP)
{
//-----------------------------------------------------------------------------
mem_block_t* mb;
mb = get_free_mem_block (sizeof (struct crlc_primitive));
((struct crlc_primitive*) mb->data)->type = CRLC_CONFIG_REQ;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.e_r = RLC_E_R_ESTABLISHMENT;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.stop = 0;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.cont = 1;
// timers
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_poll = config_amP->timer_poll;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_poll_prohibit = config_amP->timer_poll_prohibit;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_discard = config_amP->timer_discard;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_poll_periodic = config_amP->timer_poll_periodic;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_status_prohibit = config_amP->timer_status_prohibit;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_status_periodic = config_amP->timer_status_periodic;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_rst = config_amP->timer_rst;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.max_rst = config_amP->max_rst;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.timer_mrw = config_amP->timer_mrw;
// protocol_parameters
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.pdu_size = config_amP->pdu_size;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.max_dat = config_amP->max_dat;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.poll_pdu = config_amP->poll_pdu;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.poll_sdu = config_amP->poll_sdu;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.poll_window = config_amP->poll_window;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.configured_tx_window_size = config_amP->tx_window_size;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.configured_rx_window_size = config_amP->rx_window_size;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.max_mrw = config_amP->max_mrw;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.last_transmission_pdu_poll_trigger =
config_amP->last_transmission_pdu_poll_trigger;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.last_retransmission_pdu_poll_trigger =
config_amP->last_retransmission_pdu_poll_trigger;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.sdu_discard_mode = config_amP->sdu_discard_mode;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.send_mrw = config_amP->send_mrw;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.frame_tick_milliseconds = &mac_xface->frame;
((struct crlc_primitive*) mb->data)->primitive.c_config_req.parameters.am_parameters.rb_id = rb_idP;
send_rlc_am_control_primitive (rlcP, module_idP, mb);
if (rb_typeP != SIGNALLING_RADIO_BEARER) {
rlcP->data_plane = 1;
msg ("[RLC AM][RB %d] DATA PLANE\n", rlcP->rb_id);
} else {
rlcP->data_plane = 0;
msg ("[RLC AM][RB %d] CONTROL PLANE\n", rlcP->rb_id);
}
}
//-----------------------------------------------------------------------------
void
send_rlc_am_control_primitive (struct rlc_am_entity* rlcP, module_id_t module_idP, mem_block_t* cprimitiveP)
{
//-----------------------------------------------------------------------------
rlcP->module_id = module_idP;
switch (((struct crlc_primitive*) cprimitiveP->data)->type) {
case CRLC_CONFIG_REQ:
switch (((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.e_r) {
case RLC_E_R_ESTABLISHMENT:
if (rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_DATA_TRANSFER_READY_STATE_EVENT)) {
rlc_am_set_configured_parameters (rlcP, cprimitiveP); // the order of the calling of procedures...
rlc_am_reset_state_variables (rlcP); // ...must not ...
rlc_am_alloc_buffers_after_establishment (rlcP); // ...be changed
}
break;
case RLC_E_R_RE_ESTABLISHMENT:
// from 3GPP TS 25.322 V4.2.0(2001-09)
// The RLC re-establishment function is applicable for AM and UM and is used when upper layers request an RLC entity to be re-established.
// When an RLC entity is re-established by upper layers, the RLC entity shall:
// - reset the state variables to their initial value;
// - set the configurable parameters to their configured value;
// - set the hyper frame number (HFN) in UL and DL to the value configured by upper layers;
// - if the RLC entity is operating in unacknowledged mode:
// - if it is a receiving UM RLC entity:
// - discard all UMD PDUs;
// - if it is a transmitting UM RLC entity:
// - discard the RLC SDUs for which one or more segments have been submitted to a lower layer;
// - otherwise if the RLC entity is operating in acknowledged mode:
// - discard all AMD PDUs in the Receiver and Sender.
if (rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_DATA_TRANSFER_READY_STATE_EVENT)) {
rlc_am_free_all_resources (rlcP);
rlc_am_set_configured_parameters (rlcP, cprimitiveP); // the order of the calling of procedures...
rlc_am_reset_state_variables (rlcP); // ...must not ...
rlc_am_alloc_buffers_after_establishment (rlcP); // ...be changed
}
break;
case RLC_E_R_MODIFICATION:
msg ("[RLC_AM][RB %d] WARNING CRLC_CONFIG_REQ:RLC_AM_E_R_MODIFICATION NOT IMPLEMENTED AT ALL: MAY BE BUGGY IF CHANGING WINDOWS SIZE\n", rlcP->rb_id);
rlc_am_set_configured_parameters (rlcP, cprimitiveP);
break;
case RLC_E_R_RELEASE:
if (rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_NULL_STATE_EVENT)) {
rlc_am_free_all_resources (rlcP);
}
break;
default:
msg ("[RLC_AM][ERROR] control_rlc_am(CRLC_CONFIG_REQ) unknown parameter E_R\n");
}
break;
case CRLC_SUSPEND_REQ:
// from 3GPP TS 25.322 V4.2.0(2001-09)
// When an RLC entity operating in acknowledged mode is suspended by upper layers with the parameter N, the RLC entity shall:
// - acknowledge the suspend request with a confirmation containing the current value of VT(S);
// - not send AMD PDUs with sequence number SNVT(S)+N.
if (rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_CRLC_SUSPEND_REQ_EVENT)) {
if ((rlcP->protocol_state == RLC_LOCAL_SUSPEND_STATE) || (rlcP->protocol_state == RLC_LOCAL_SUSPEND_STATE)) {
// TO DO IN FUTURE, BUT IT SEEMS THERE IS NO NEED TO IMPLEMENT THIS FUNCTION IN THE CURRENTLY DEFINED ARCHITECTURE
// SO DISPLAY ERROR MESSAGE
msg ("[RLC_AM[RB %d] ERROR RECEIVED CRLC_SUSPEND_REQ NOT IMPLEMENTED AT ALL, RLC_AM MAY NOT WORK AS EXPECTED IN THE 3GPP SPECIFICATION\n", rlcP->rb_id);
}
}
break;
case CRLC_RESUME_REQ:
// from 3GPP TS 25.322 V4.2.0(2001-09)
// When an RLC entity operating in acknowledged mode is resumed by upper layers, the RLC entity shall:
// - if the RLC entity is suspended and a RLC Reset procedure is not ongoing:
// - resume data transfer procedure.
// - otherwise, if the RLC entity is suspended and a RLC Reset procedure is ongoing:
// - remove the suspend constraint;
// - resume the RLC reset procedure according to subclause 11.4.
if (rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_CRLC_RESUME_REQ_EVENT)) {
if ((rlcP->protocol_state == RLC_RESET_PENDING_STATE) || (rlcP->protocol_state == RLC_DATA_TRANSFER_READY_STATE)) {
// TO DO IN FUTURE, BUT IT SEEMS THERE IS NO NEED TO IMPLEMENT THIS FUNCTION IN THE CURRENTLY DEFINED ARCHITECTURE
// SO DISPLAY ERROR MESSAGE
msg ("[RLC_AM][RB %d] ERROR RECEIVED CRLC_RESUME_REQ NOT IMPLEMENTED AT ALL, RLC_AM MAY NOT WORK AS EXPECTED IN THE 3GPP SPECIFICATION\n", rlcP->rb_id);
}
}
break;
default:
msg ("[RLC_AM][RB %d][ERROR] control_rlc_am(UNKNOWN CPRIMITIVE)\n", rlcP->rb_id);
}
free_mem_block (cprimitiveP);
}
//-----------------------------------------------------------------------------
void
init_rlc_am (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
memset (rlcP, 0, sizeof (struct rlc_am_entity));
list2_init (&rlcP->retransmission_buffer_to_send, NULL);
list_init (&rlcP->pdus_to_mac_layer_ch1, NULL);
list_init (&rlcP->pdus_to_mac_layer_ch2, NULL);
list_init (&rlcP->pdus_from_mac_layer_ch1, NULL);
list_init (&rlcP->pdus_from_mac_layer_ch2, NULL);
list_init (&rlcP->control, NULL);
list2_init (&rlcP->sdu_conf_segmented, NULL);
list2_init (&rlcP->sdu_discard_segmented, NULL);
list2_init (&rlcP->sdu_discarded, NULL);
list2_init (&rlcP->rlc_am_timer_list, NULL);
rlcP->protocol_state = RLC_NULL_STATE;
rlcP->next_sdu_index = 0;
rlcP->current_sdu_index = 0;
rlcP->last_received_rsn = 0xFF;
//--------------------------------------------------------------------------
rlcP->discard_reassembly_after_li = RLC_AM_DISCARD_REASSEMBLY_AT_LI_INDEX_0;
rlcP->discard_reassembly_start_sn = RLC_AM_SN_INVALID; // =>not activated
rlcP->stat_tx_pdcp_sdu = 0;
rlcP->stat_tx_pdcp_sdu_discarded = 0;
rlcP->stat_tx_retransmit_pdu_unblock = 0;
rlcP->stat_tx_retransmit_pdu_by_status = 0;
rlcP->stat_tx_data_pdu = 0;
rlcP->stat_tx_control_pdu = 0;
rlcP->stat_rx_sdu = 0;
rlcP->stat_rx_error_pdu = 0;
rlcP->stat_rx_data_pdu = 0;
rlcP->stat_rx_data_pdu_out_of_window = 0;
rlcP->stat_rx_control_pdu = 0;
}
//-----------------------------------------------------------------------------
void
rlc_am_alloc_buffers_after_establishment (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
rlcP->recomputed_configured_tx_window_size = 1;
while (rlcP->recomputed_configured_tx_window_size < rlcP->configured_tx_window_size) {
rlcP->recomputed_configured_tx_window_size = rlcP->recomputed_configured_tx_window_size << 1;
}
rlcP->retransmission_buffer_alloc = get_free_mem_block (rlcP->recomputed_configured_tx_window_size * sizeof (mem_block_t*));
rlcP->retransmission_buffer = (mem_block_t**) (rlcP->retransmission_buffer_alloc->data);
//memset (rlcP->retransmission_buffer, 0, rlcP->recomputed_configured_tx_window_size * sizeof (mem_block_t *));
rlcP->recomputed_configured_rx_window_size = 1;
while (rlcP->recomputed_configured_rx_window_size < rlcP->configured_rx_window_size) {
rlcP->recomputed_configured_rx_window_size = rlcP->recomputed_configured_rx_window_size << 1;
}
rlcP->receiver_buffer_alloc = get_free_mem_block (rlcP->recomputed_configured_rx_window_size * sizeof (mem_block_t*));
rlcP->receiver_buffer = (mem_block_t**) (rlcP->receiver_buffer_alloc->data);
msg("[RLC AM][RB %d] Window size %d\n",rlcP->rb_id,rlcP->recomputed_configured_rx_window_size);
//memset (rlcP->receiver_buffer, 0, rlcP->recomputed_configured_rx_window_size * sizeof (mem_block_t *));
rlcP->holes_alloc = get_free_mem_block ((rlcP->recomputed_configured_rx_window_size * sizeof (struct rlc_am_hole)) >> 1);
rlcP->holes = (struct rlc_am_hole*) (rlcP->holes_alloc->data);
//memset (rlcP->holes_alloc->data, 0, (rlcP->recomputed_configured_rx_window_size * sizeof (mem_block_t *)) >> 1);
rlcP->size_input_sdus_buffer = rlcP->recomputed_configured_tx_window_size * 4;
if ((rlcP->input_sdus_alloc == NULL)) {
rlcP->input_sdus_alloc = get_free_mem_block (rlcP->size_input_sdus_buffer * sizeof (void*));
rlcP->input_sdus = (mem_block_t**) (rlcP->input_sdus_alloc->data);
//memset (rlcP->input_sdus, 0, rlcP->size_input_sdus_buffer * sizeof (void *));
}
}
//-----------------------------------------------------------------------------
void
rlc_am_reset_state_variables (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
rlcP->vt_s = 0;
rlcP->vt_a = 0;
rlcP->vt_pdu = 0;
//................................................................
rlcP->vt_sdu = 0;
rlcP->vt_mrw = 0;
rlcP->vt_ms = rlcP->configured_tx_window_size - 1;
//................................................................
rlcP->vt_ws = rlcP->configured_tx_window_size;
rlcP->vr_r = 0;
rlcP->vr_h = 0;
//................................................................
rlcP->vr_mr = rlcP->configured_rx_window_size - 1;
rlcP->vt_rst = 0;
//................................................................
rlcP->send_status_pdu_requested = 0;
rlcP->first_li_in_next_pdu = RLC_LI_UNDEFINED;
rlcP->last_reassemblied_sn = SN_12BITS_MASK;
rlcP->li_exactly_filled_to_add_in_next_pdu = 0;
rlcP->li_one_byte_short_to_add_in_next_pdu = 0;
//................................................................
rlcP->sufi_to_insert_index = 0;
rlcP->ack.vr_r_modified = 0;
rlcP->ack.ack_other_vr_r = 0;
//................................................................
rlcP->output_sdu_size_to_write = 0;
rlcP->discard_reassembly_after_li = RLC_AM_DISCARD_REASSEMBLY_AT_LI_INDEX_0;
rlcP->discard_reassembly_start_sn = RLC_AM_SN_INVALID; // =>not activated
//................................................................
rlcP->timer_mrw = NULL;
//................................................................
rlcP->buffer_occupancy = 0;
rlcP->nb_sdu = 0;
rlcP->buffer_occupancy_retransmission_buffer = 0;
rlcP->next_sdu_index = 0;
rlcP->current_sdu_index = 0;
rlcP->nb_pdu_requested_by_mac_on_ch1 = 0;
rlcP->nb_pdu_requested_by_mac_on_ch2 = 0;
rlcP->running_timer_status_prohibit = rlcP->timer_status_prohibit/10;
}
//-----------------------------------------------------------------------------
void
rlc_am_stop_all_timers (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
list2_free (&rlcP->rlc_am_timer_list);
}
//-----------------------------------------------------------------------------
void
rlc_am_discard_all_pdus (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t index;
index = 0;
while (index < rlcP->recomputed_configured_rx_window_size) {
if (rlcP->receiver_buffer[index] != NULL) {
free_mem_block (rlcP->receiver_buffer[index]);
rlcP->receiver_buffer[index] = NULL;
}
index++;
}
index = 0;
while (index < rlcP->recomputed_configured_tx_window_size) {
if (rlcP->retransmission_buffer[index] != NULL) {
free_mem_block (rlcP->retransmission_buffer[index]);
rlcP->retransmission_buffer[index] = NULL;
}
index++;
}
list2_free (&rlcP->retransmission_buffer_to_send);
list_free (&rlcP->pdus_to_mac_layer_ch1);
list_free (&rlcP->pdus_to_mac_layer_ch2);
list_free (&rlcP->control);
if ((rlcP->output_sdu_in_construction)) {
free_mem_block (rlcP->output_sdu_in_construction);
rlcP->output_sdu_in_construction = NULL;
}
}
//-----------------------------------------------------------------------------
void
rlc_am_free_all_resources (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
int index;
for (index = 0; index < rlcP->size_input_sdus_buffer; index++) {
if (rlcP->input_sdus[index]) {
free_mem_block (rlcP->input_sdus[index]);
rlcP->input_sdus[index] = NULL;
}
}
rlc_am_discard_all_pdus (rlcP);
if (rlcP->retransmission_buffer_alloc) {
free_mem_block (rlcP->retransmission_buffer_alloc);
}
if (rlcP->receiver_buffer_alloc) {
free_mem_block (rlcP->receiver_buffer_alloc);
}
if (rlcP->input_sdus_alloc) {
free_mem_block (rlcP->input_sdus_alloc);
}
if (rlcP->holes_alloc) {
free_mem_block (rlcP->holes_alloc);
}
rlcP->holes_alloc = NULL;
rlcP->input_sdus_alloc = NULL;
rlcP->receiver_buffer_alloc = NULL;
rlcP->retransmission_buffer_alloc = NULL;
rlc_am_stop_all_timers (rlcP);
}
//-----------------------------------------------------------------------------
void
rlc_am_set_configured_parameters (struct rlc_am_entity* rlcP, mem_block_t* cprimitiveP)
{
//-----------------------------------------------------------------------------
// timers
//rlcP->timer_poll_trigger = ((struct crlc_primitive *)cprimitiveP->data)->cprimitive.c_config_req.parameters.am_parameters.timer_poll;
//rlcP-> = ((struct crlc_primitive *)cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_poll_prohibit;
rlcP->timer_discard_init = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_discard;
rlcP->timer_poll_periodic_init = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_poll_periodic;
rlcP-> timer_status_prohibit = ((struct crlc_primitive*)cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_status_prohibit;
rlcP->timer_status_periodic = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_status_periodic;
rlcP->timer_rst_init = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_rst;
rlcP->max_rst = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.max_rst;
rlcP->timer_mrw_init = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.timer_mrw;
// protocol_parameters
rlcP->pdu_size = (((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.pdu_size + 7) >> 3;
rlcP->max_dat = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.max_dat;
rlcP->missing_pdu_indicator = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.missing_pdu_indicator;
rlcP->poll_pdu_trigger = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.poll_pdu;
rlcP->poll_sdu_trigger = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.poll_sdu;
rlcP->last_transmission_pdu_poll_trigger = ((struct crlc_primitive*)
cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.last_transmission_pdu_poll_trigger;
rlcP->last_retransmission_pdu_poll_trigger = ((struct crlc_primitive*)
cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.last_retransmission_pdu_poll_trigger;
rlcP->poll_window_trigger = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.poll_window;
rlcP->configured_tx_window_size = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.configured_tx_window_size;
rlcP->configured_rx_window_size = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.configured_rx_window_size;
rlcP->max_mrw = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.max_mrw;
rlcP->sdu_discard_mode = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.sdu_discard_mode;
rlcP->send_mrw = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.send_mrw;
// SPARE : not 3GPP
rlcP->rb_id = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.rb_id;
rlcP->frame_tick_milliseconds = ((struct crlc_primitive*) cprimitiveP->data)->primitive.c_config_req.parameters.am_parameters.frame_tick_milliseconds;
rlcP->nb_logical_channels_per_rlc =1;
if (rlcP->pdu_size > 126) {
rlcP->rlc_segment = rlc_am_segment_15;
} else {
rlcP->rlc_segment = rlc_am_segment_7;
}
if (rlcP->sdu_discard_mode == SDU_DISCARD_MODE_RESET) {
msg ("[RLC AM][RB %d] SDU DISCARD RESET CONFIGURED\n", rlcP->rb_id);
} else if (rlcP->sdu_discard_mode == SDU_DISCARD_MODE_TIMER_BASED_EXPLICIT) {
msg ("[RLC AM][RB %d] SDU DISCARD TIMER BASED EXPLICIT SIGNALING CONFIGURED\n", rlcP->rb_id);
} else if (rlcP->sdu_discard_mode == SDU_DISCARD_MODE_MAX_DAT_RETRANSMISSION) {
msg ("[RLC AM][RB %d] SDU DISCARD MAX RETRANSMISSION CONFIGURED\n", rlcP->rb_id);
} else if (rlcP->sdu_discard_mode == SDU_DISCARD_MODE_NOT_CONFIGURED) {
msg ("[RLC AM][RB %d] SDU DISCARD NOT CONFIGURED\n", rlcP->rb_id);
}
}
openair2/LAYER2/RLC/AM/rlc_am_control_primitives_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_control_primitives_proto_extern.h -
-------------------
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_CONTROL_PRIMITIVES_H__
# define __RLC_AM_CONTROL_PRIMITIVES_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "mem_block.h"
# include "rrm_config_structs.h"
//-----------------------------------------------------------------------------
extern void config_req_rlc_am (struct rlc_am_entity *rlcP, module_id_t module_idP, rlc_am_info_t * config_amP, uint8_t rb_idP, rb_type_t rb_typeP);
extern void send_rlc_am_control_primitive (struct rlc_am_entity *rlcP, module_id_t module_idP, mem_block_t * cprimitiveP);
extern void init_rlc_am (struct rlc_am_entity *rlcP);
extern void rlc_am_reset_state_variables (struct rlc_am_entity *rlcP);
extern void rlc_am_alloc_buffers_after_establishment (struct rlc_am_entity *rlcP);
extern void rlc_am_discard_all_pdus (struct rlc_am_entity *rlcP);
extern void rlc_am_stop_all_timers (struct rlc_am_entity *rlcP);
extern void rlc_am_free_all_resources (struct rlc_am_entity *rlcP);
extern void rlc_am_set_configured_parameters (struct rlc_am_entity *rlcP, mem_block_t * cprimitiveP);
//extern void rlc_am_probing_get_buffer_occupancy_measurements (struct rlc_am_entity *rlcP, probing_report_traffic_rb_parameters *reportP, int measurement_indexP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_demux.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_demux.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
//#include "mac_log_interface_struct.h"
#include "LAYER2/RLC/rlc.h"
#include "mac_primitives.h"
#include "list.h"
#include "rlc_am_entity.h"
#include "rlc_am_structs.h"
#include "rlc_am_constants.h"
#include "rlc_am_receiver_proto_extern.h"
#include "rlc_am_reset_proto_extern.h"
#include "rlc_am_status_proto_extern.h"
#include "rlc_am_timers_proto_extern.h"
#include "LAYER2/MAC/extern.h"
#define DEBUG_DEMUX_RESET
#define DEBUG_DEMUX
//-----------------------------------------------------------------------------
void
rlc_am_demux_routing (struct rlc_am_entity *rlcP, unsigned int traffic_typeP, struct mac_data_ind data_indP)
{
//-----------------------------------------------------------------------------
struct rlc_am_pdu_header *data;
struct rlc_am_reset_header *control;
mem_block_t *tb;
uint8_t *first_byte;
uint16_t tb_size_in_bytes;
uint8_t first_bit;
uint8_t bits_to_shift;
uint8_t bits_to_shift_last_loop;
uint8_t data_received;
int index;
//-------------------------------------------------------
// D A T A P D U
//-------------------------------------------------------
data_received = 0;
while ((tb = list_remove_head (&data_indP.data))) {
if (!(((struct mac_tb_ind *) (tb->data))->error_indication)) {
first_byte = ((struct mac_tb_ind *) (tb->data))->data_ptr;
tb_size_in_bytes = data_indP.tb_size >> 3;
first_bit = ((struct mac_tb_ind *) (tb->data))->first_bit;
if (first_bit > 0) {
// shift data of transport_block TO CHECK
bits_to_shift_last_loop = 0;
while ((tb_size_in_bytes)) {
bits_to_shift = first_byte[tb_size_in_bytes] >> (8 - first_bit);
first_byte[tb_size_in_bytes] = (first_byte[tb_size_in_bytes] << first_bit) | (bits_to_shift_last_loop);
tb_size_in_bytes -= 1;
bits_to_shift_last_loop = bits_to_shift;
}
first_byte[0] = (first_byte[0] << first_bit) | (bits_to_shift_last_loop);
}
((struct rlc_am_rx_pdu_management *) (tb->data))->first_byte = first_byte;
data = (struct rlc_am_pdu_header *) (first_byte);
if ((data->byte1 & RLC_DC_MASK) == RLC_DC_DATA_PDU) {
#ifdef DEBUG_DEMUX
msg ("[RLC_AM][RB %d][DEMUX] RX AMD PDU Frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
for (index=0; index < rlcP->pdu_size ; index++) {
msg("%02X.",first_byte[index]);
}
msg("\n");
#endif
rlcP->stat_rx_data_pdu += 1;
if (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_DATA) {
((struct rlc_am_rx_pdu_management *) (tb->data))->piggybacked_processed = 0;
receiver_retransmission_management (rlcP, tb, data);
// pdu is data;
data_received = 1;
} else {
#ifdef DEBUG_DEMUX
msg ("[RLC_AM][RB %d][DEMUX] DROP DATA TB NOT ALLOWED IN PROTOCOL STATE 0x%02X\n", rlcP->rb_id, rlcP->protocol_state);
#endif
free_mem_block (tb);
}
} else {
rlcP->stat_rx_control_pdu += 1;
control = (struct rlc_am_reset_header *) first_byte;
if ((control->byte1 & RLC_PDU_TYPE_MASK) == RLC_PDU_TYPE_STATUS) {
if (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_DATA) {
#ifdef DEBUG_DEMUX
msg ("[RLC_AM][RB %d][DEMUX] RX STATUS PDU ON DTCH Frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlc_am_process_status_info (rlcP, &(control->byte1));
}
} else if ((control->byte1 & RLC_PDU_TYPE_MASK) == RLC_PDU_TYPE_RESET) {
#ifdef DEBUG_DEMUX_RESET
msg ("[RLC_AM][RB %d][DEMUX] RX RESET PDU Frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
process_reset (tb, control, rlcP);
} else if ((control->byte1 & RLC_PDU_TYPE_MASK) == RLC_PDU_TYPE_RESET_ACK) {
#ifdef DEBUG_DEMUX_RESET
msg ("[RLC_AM][RB %d][DEMUX] RX RESET ACK PDU Frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
process_reset_ack (tb, control, rlcP);
#ifndef USER_MODE
rlc_info_t Rlc_info_am_config1;
Rlc_info_am_config1.rlc_mode=RLC_AM;
Rlc_info_am_config1.rlc.rlc_am_info.sdu_discard_mode = SDU_DISCARD_MODE_RESET;//SDU_DISCARD_MODE_MAX_DAT_RETRANSMISSION;//
Rlc_info_am_config1.rlc.rlc_am_info.timer_poll = 0;
Rlc_info_am_config1.rlc.rlc_am_info.timer_poll_prohibit = 0;
Rlc_info_am_config1.rlc.rlc_am_info.timer_discard = 500;
Rlc_info_am_config1.rlc.rlc_am_info.timer_poll_periodic = 0;
Rlc_info_am_config1.rlc.rlc_am_info.timer_status_prohibit = 250;
Rlc_info_am_config1.rlc.rlc_am_info.timer_status_periodic = 500;
Rlc_info_am_config1.rlc.rlc_am_info.timer_rst = 250;//250
Rlc_info_am_config1.rlc.rlc_am_info.max_rst = 500;//500
Rlc_info_am_config1.rlc.rlc_am_info.timer_mrw = 0;
Rlc_info_am_config1.rlc.rlc_am_info.pdu_size = 32; //416; // in bits
//Rlc_info_am.rlc.rlc_am_info.in_sequence_delivery = 1;//boolean
Rlc_info_am_config1.rlc.rlc_am_info.max_dat = 32;//127;
Rlc_info_am_config1.rlc.rlc_am_info.poll_pdu = 0;
Rlc_info_am_config1.rlc.rlc_am_info.poll_sdu = 0;//256;/
Rlc_info_am_config1.rlc.rlc_am_info.poll_window = 80;//128
Rlc_info_am_config1.rlc.rlc_am_info.tx_window_size = 512;
Rlc_info_am_config1.rlc.rlc_am_info.rx_window_size = 512;
Rlc_info_am_config1.rlc.rlc_am_info.max_mrw = 8;
Rlc_info_am_config1.rlc.rlc_am_info.last_transmission_pdu_poll_trigger = 1;//boolean
Rlc_info_am_config1.rlc.rlc_am_info.last_retransmission_pdu_poll_trigger = 1;//boolean
Rlc_info_am_config1.rlc.rlc_am_info.send_mrw = 1;//boolean*
Mac_rlc_xface->rrc_rlc_config_req(0,CONFIG_ACTION_REMOVE,rlcP->rb_id,RADIO_ACCESS_BEARER,Rlc_info_am_config1);
Mac_rlc_xface->rrc_rlc_config_req(0,CONFIG_ACTION_ADD,rlcP->rb_id,RADIO_ACCESS_BEARER,Rlc_info_am_config1);
#endif
}
free_mem_block (tb);
}
} else {
#ifdef BENCH_QOS_L2
fprintf (bench_l2, "[PDU RX ERROR] FRAME %d RLC-AM %p\n", Mac_rlc_xface->frame, rlcP);
#endif
#ifdef DEBUG_DEMUX
msg ("[RLC_AM][RB %d][DEMUX] RX PDU WITH ERROR INDICATION\n", rlcP->rb_id);
#endif
rlcP->stat_rx_error_pdu += 1;
free_mem_block (tb);
}
}
if ((data_received)) { //avoid call
if (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_DATA) {
if (rlcP->pdu_size <= 126) {
#ifdef DEBUG_DEMUX
msg("[RLC_AM][RB %d] Calling process_receiver_buffer_7\n",rlcP->rb_id);
#endif
process_receiver_buffer_7 (rlcP);
} else {
#ifdef DEBUG_DEMUX
msg("[RLC_AM][RB %d] Calling process_receiver_buffer_15\n",rlcP->rb_id);
#endif
process_receiver_buffer_15 (rlcP);
}
}
}
}
openair2/LAYER2/RLC/AM/rlc_am_demux_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_demux_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_DEMUX_PROTO_EXTERN_H__
# define __RLC_AM_DEMUX_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "mac_primitives.h"
//-----------------------------------------------------------------------------
extern void rlc_am_demux_routing (struct rlc_am_entity *rlcP, unsigned int traffic_typeP, struct mac_data_ind data_indP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_discard_notif.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_notif.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#define RLC_AM_C
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc.h"
#include "rlc_primitives.h"
#include "rlc_am_status_proto_extern.h"
#include "umts_timer_struct.h"
#include "umts_timer_proto_extern.h"
#include "rlc_am_discard_tx_proto_extern.h"
#include "rlc_am_reset_proto_extern.h"
#include "LAYER2/MAC/extern.h"
//-----------------------------------------------------------------------------
void rlc_am_discard_notify_mrw_ack_time_out (struct rlc_am_entity* rlcP, mem_block_t* discard_procedureP);
void rlc_am_discard_notify_sdu_time_out (struct rlc_am_entity* rlcP, mem_block_t* sduP);
void rlc_am_discard_notify_max_dat_pdu (struct rlc_am_entity* rlcP, mem_block_t* mbP);
//-----------------------------------------------------------------------------
// handler for timer
//-----------------------------------------------------------------------------
void
rlc_am_discard_notify_mrw_ack_time_out (struct rlc_am_entity* rlcP, mem_block_t* discard_procedureP)
{
//-----------------------------------------------------------------------------
/* from 3GPP TS 25.322 V5.5.0
If Timer_MRW expires before the discard procedure is terminated, the Sender shall:
- if VT(MRW)<MaxMRW-1:
- set the MRW SUFI as previously transmitted (even if additional SDUs were discarded in the mean-time);
- include the MRW SUFI in a new status report (if other SUFIs are included, their contents shall be updated);
- transmit the status report by either including it in a STATUS PDU or piggybacked in an AMD PDU;
- increment VT(MRW) by one;
- restart Timer_MRW for this discard procedure.
If the number of retransmission of an MRW SUFI (i.e. VT(MRW)) equals MaxMRW, the Sender shall:
- terminate the SDU discard with explicit signalling procedure;
- stop the timer Timer_MRW;
- deliver an error indication to upper layers;
- initiate the RLC RESET procedure */
rlcP->timer_mrw = NULL;
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d][DISCARD] NOTIF MRW_ACK TIME OUT VT(MRW) %d PROCEDURE %p\n", rlcP->rb_id, rlcP->vt_mrw, discard_procedureP);
#endif
if ((rlcP->protocol_state & (RLC_RESET_PENDING_STATE | RLC_RESET_AND_SUSPEND_STATE)) == 0) {
// check the number of retransmission of the status pdu
if (rlcP->vt_mrw < (rlcP->max_mrw - 1)) {
rlc_am_schedule_procedure (rlcP);
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM %p][DISCARD] NOTIF MRW_ACK TIME OUT REARM TIMER\n", rlcP);
#endif
rlcP->vt_mrw += 1;
} else {
// TO DO : "deliver an error indication to upper layers"
#ifdef DEBUG_RESET
msg ("\n[RLC_AM][RB %d][DISCARD] NOTIF MRW_ACK TIME OUT MAX_MRW REACHED -> RESET\n", rlcP->rb_id);
#endif
send_reset_pdu (rlcP);
}
}
}
// handler for timer
//-----------------------------------------------------------------------------
void
rlc_am_discard_check_sdu_time_out (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
mem_block_t* sdu;
mem_block_t* pdu;
int discard_go_on;
int last_removed_pdu_sn;
int sn;
// TIMER BASED DISCARD
if ((rlcP->sdu_discard_mode & RLC_SDU_DISCARD_TIMER_BASED_EXPLICIT)
&& ((rlcP->protocol_state & (RLC_RESET_PENDING_STATE | RLC_RESET_AND_SUSPEND_STATE)) == 0)) {
/* from 3GPP TS 25.322 V5.0.0 p68
- if "Timer based SDU discard with explicit signalling" is configured:
- discard all SDUs up to and including the SDU for which the timer Timer_Discard expired.
- discard all AMD PDUs including segments of the discarded SDUs, unless they also carry a segment of a SDU
whose timer has not expired;
- if more than 15 discarded SDUs are to be informed to the Receiver:
- if "Send MRW" is not configured:
- assemble an MRW SUFI with the discard information of the SDUs.
- otherwise ("Send MRW" is configured):
- assemble an MRW SUFI with the discard information of the first 15 SDUs; and
- include the discard information of the rest SDUs in another MRW SUFI which shall be sent by the next
SDU discard with explicit signalling procedure (after the current SDU discard with explicit signalling
procedure is terminated).
- otherwise (less than or equal to 15 discarded SDUs are to be informed to the Receiver):
- assemble an MRW SUFI with the discard information of the SDUs.
- schedule and submit to lower layer a STATUS PDU/piggybacked STATUS PDU containing the MRW SUFI;
- if SN_MRWLENGTH in the MRW SUFI >VT(S):
- update VT(S) to SN_MRWLENGTH.
- start a timer Timer_MRW
If a new SDU discard with explicit signalling procedure is triggered when the timer Timer_MRW is active, no new
MRW SUFIs shall be sent before the current SDU discard with explicit signalling procedure is terminated by one of the
termination criteria.
*/
discard_go_on = 1;
last_removed_pdu_sn = -1;
while ((sdu = rlcP->input_sdus[rlcP->current_sdu_index]) && discard_go_on) {
if ((*rlcP->frame_tick_milliseconds - ((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_creation_time) >= rlcP->timer_discard_init) {
// buffer occupancy is not updated at each generation of pdu, it is only updated for a sdu when the
// segmentation of this one is finished.
rlcP->buffer_occupancy -= ((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_remaining_size;
rlcP->nb_sdu -= 1;
if ((rlcP->send_mrw & RLC_AM_SEND_MRW_ON) ||
// the condition says if the sdu has generated one or more pdus
(((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_size != ((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_remaining_size)) {
((struct rlc_am_tx_sdu_management*) (sdu->data))->last_pdu_sn = rlcP->vt_s;
((struct rlc_am_tx_sdu_management*) (sdu->data))->no_new_sdu_segmented_in_last_pdu = 1;
rlcP->vt_s = (rlcP->vt_s + 1) & SN_12BITS_MASK;
list2_add_tail (sdu, &rlcP->sdu_discarded);
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] SDU DISCARDED SIGNALLING YES, TIMED OUT %ld ms frame %d ", rlcP->rb_id,
(*rlcP->frame_tick_milliseconds - ((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_creation_time), Mac_rlc_xface->frame);
msg ("BO %d, NB SDU %d\n", rlcP->buffer_occupancy, rlcP->nb_sdu);
display_protocol_vars_rlc_am (rlcP);
#endif
if (((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_size != ((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_remaining_size) {
// some pdu have to be removed if a sdu discarded generated almost one pdu
if (last_removed_pdu_sn == -1) {
sn = rlcP->vt_a;
} else {
sn = last_removed_pdu_sn;
}
while (sn != rlcP->vt_s) {
pdu = rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size];
if ((pdu)) {
// now check if a copy of the pdu is not present in the retransmission_buffer_to_send
if ((((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy)) {
list2_remove_element (((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy, &rlcP->retransmission_buffer_to_send);
free_mem_block (((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy);
}
// if this pdu has been retransmitted, remove its size from buffer occupancy
if (((struct rlc_am_tx_data_pdu_management*) (pdu->data))->vt_dat > 0) {
rlcP->buffer_occupancy_retransmission_buffer -= 1;
}
free_mem_block (rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size]);
rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size] = NULL;
}
sn = (sn + 1) & SN_12BITS_MASK;
}
last_removed_pdu_sn = sn;
}
} else {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] SDU DISCARDED SIGNALLING NO, TIMED OUT %ld ms ", rlcP->rb_id,
(*rlcP->frame_tick_milliseconds - ((struct rlc_am_tx_sdu_management*) (sdu->data))->sdu_creation_time));
msg ("BO %d, NB SDU %d\n", rlcP->buffer_occupancy, rlcP->nb_sdu);
#endif
free_mem_block (sdu);
}
if (!(rlcP->data_plane)) {
#ifdef DEBUG_RLC_AM_SEND_CONFIRM
msg ("[RLC_AM][RB %d][CONFIRM] SDU MUI %d LOST IN DISCARD\n", rlcP->rb_id,
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[rlcP->current_sdu_index]->data))->mui);
#endif
rlc_data_conf (0, rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[rlcP->current_sdu_index]->data))->mui, RLC_TX_CONFIRM_FAILURE,
rlcP->data_plane);
}
rlcP->input_sdus[rlcP->current_sdu_index] = NULL;
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
// reset variables for segmentation
rlcP->li_exactly_filled_to_add_in_next_pdu = 0;
rlcP->li_one_byte_short_to_add_in_next_pdu = 0;
} else {
discard_go_on = 0;
}
}
}
}
//-----------------------------------------------------------------------------
void
rlc_am_discard_notify_max_dat_pdu (struct rlc_am_entity* rlcP, mem_block_t* pduP)
{
//-----------------------------------------------------------------------------
struct rlc_am_tx_data_pdu_management* pdu_mngt;
struct rlc_am_tx_sdu_management* sdu_mngt;
mem_block_t* pdu;
mem_block_t* pdu2;
mem_block_t* sdu;
int sdu_index;
int sdu_index2;
int pdu_index;
int last_sdu_index;
int sn;
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) pduP->data;
// should never occur
//if (pdu_mngt->nb_sdu == 0) return;
// discard previous SDUS
#ifdef DEBUG_RLC_AM_DISCARD_MAX_DAT
msg ("[RLC_AM][RB %d] DISCARD MAX DAT PDU FRAME %d SN 0x%03X CONTAINS SDU INDEX ", rlcP->rb_id, Mac_rlc_xface->frame, pdu_mngt->sn);
sdu_index = 0;
while (sdu_index < pdu_mngt->nb_sdu) {
msg ("%d ", pdu_mngt->sdu[sdu_index]);
sdu_index += 1;
}
msg ("\n");
#endif
// From 3GPP TS25.322 V5.0.0 (2002-03) page 68
// - if "SDU discard after MaxDAT number of retransmissions" is configured:
// - discard all SDUs that have segments in AMD PDUs with SN inside the interval
// VT(A) <= SN <= X, where X is the value of the SN of the AMD PDU with VT(DAT) >= MaxDAT;
// - if requested
// - inform the upper layers of the discarded SDUs.
//---------------------------------------------------------------
// here delete all SDUs before the last sdu that have segments in the pdu discarded
sdu_index = rlcP->next_sdu_index;
last_sdu_index = pdu_mngt->sdu[pdu_mngt->nb_sdu - 1];
while (sdu_index != last_sdu_index) {
if ((sdu = rlcP->input_sdus[sdu_index])) {
list2_add_tail (sdu, &rlcP->sdu_discarded);
if (!(rlcP->data_plane)) {
#ifdef DEBUG_RLC_AM_SEND_CONFIRM
msg ("[RLC_AM][RB %d][CONFIRM] SDU MUI %d LOST IN DISCARD\n", rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[sdu_index]->data))->mui);
#endif
rlc_data_conf (0, rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[sdu_index]->data))->mui, RLC_TX_CONFIRM_FAILURE, rlcP->data_plane);
}
rlcP->input_sdus[sdu_index] = NULL;
rlcP->nb_sdu -= 1;
#ifdef DEBUG_RLC_AM_FREE_SDU
msg ("[RLC_AM][RB %d] DISCARD MAX DAT FREE_SDU INDEX %d\n", rlcP->rb_id, sdu_index);
#endif
}
sdu_index = (sdu_index + 1) % rlcP->size_input_sdus_buffer;
}
//---------------------------------------------------------------
// here delete all PDUs up to and except the last of the last sdu discarded
sdu = rlcP->input_sdus[sdu_index];
sdu_mngt = (struct rlc_am_tx_sdu_management*) (sdu->data);
sn = rlcP->vt_a;
while (sn != sdu_mngt->last_pdu_sn) {
if ((pdu2 = rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size])) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD FREE PDU SN 0x%03X\n", rlcP->rb_id, sn);
#endif
// check if a copy of the pdu is not present in the retransmission_buffer_to_send
if ((((struct rlc_am_tx_data_pdu_management*) (pdu2->data))->copy)) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] FREE PDU COPY ALSO\n", rlcP->rb_id);
#endif
list2_remove_element (((struct rlc_am_tx_data_pdu_management*) (pdu2->data))->copy, &rlcP->retransmission_buffer_to_send);
free_mem_block (((struct rlc_am_tx_data_pdu_management*) (pdu2->data))->copy);
}
// if this pdu has been retransmitted, remove its size from buffer occupancy
if (((struct rlc_am_tx_data_pdu_management*) (pdu2->data))->vt_dat > 0) {
rlcP->buffer_occupancy_retransmission_buffer -= 1;
}
free_mem_block (pdu2);
rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size] = NULL;
}
sn = (sn + 1) & SN_12BITS_MASK;
}
//----------------------------------------------
// Now for the last pdu of the last sdu discarded, check if it contains other segments of
// sdu newer than the discarded
// if the pdu cannot be found : it is OK, nothing to do
pdu = rlcP->retransmission_buffer[sdu_mngt->last_pdu_sn % rlcP->recomputed_configured_tx_window_size];
if ((pdu)) {
// search the index of the sdu passed in parameter
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) pdu->data;
if (pdu_mngt->sdu[pdu_mngt->nb_sdu - 1] == sdu_index) {
//----------------------------------------------
// now check if a copy of the pdu is not present in the retransmission_buffer_to_send
if ((pdu_mngt->copy)) {
list2_remove_element (pdu_mngt->copy, &rlcP->retransmission_buffer_to_send);
free_mem_block (pdu_mngt->copy);
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD LAST PDU SN 0x%03X\n", rlcP->rb_id, sn);
rlc_am_display_data_pdu7 (pdu);
#endif
//----------------
// discard the pdu
// if this pdu has been retransmitted, remove its size from buffer occupancy
if (((struct rlc_am_tx_data_pdu_management*) (pdu->data))->vt_dat > 0) {
rlcP->buffer_occupancy_retransmission_buffer -= 1;
}
pdu_index = pdu_mngt->sn % rlcP->recomputed_configured_tx_window_size;
free_mem_block (rlcP->retransmission_buffer[pdu_index]);
rlcP->retransmission_buffer[pdu_index] = NULL;
} else {
// if this pdu is not discarded, mark the sdu discarded by writing "-1" for their index : used in retransmission
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD LAST PDU SN 0x%03X, CONTAINS OTHER SDUS (LAST SDU INDEX=%d): NOT CLEARED\n", rlcP->rb_id, sdu_mngt->last_pdu_sn,
pdu_mngt->sdu[pdu_mngt->nb_sdu - 1]);
#endif
sdu_index2 = 0;
while (pdu_mngt->sdu[sdu_index2] != sdu_index) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD LAST PDU SN 0x%03X, MARK SDU index % AS DISCARDED\n", rlcP->rb_id, pdu_mngt->sn, pdu_mngt->sdu[sdu_index2]);
#endif
pdu_mngt->sdu[sdu_index2] = -1;
sdu_index2 += 1;
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD LAST PDU SN 0x%03X, MARK SDU index %d AS DISCARDED\n", rlcP->rb_id, pdu_mngt->sn, pdu_mngt->sdu[sdu_index2]);
#endif
pdu_mngt->sdu[sdu_index2] = -1;
}
}
#ifdef DEBUG_RLC_AM_DISCARD
else {
msg ("[RLC_AM][RB %d] DISCARD LAST PDU SN 0x%03X, ALREADY CLEARED\n", rlcP->rb_id, sdu_mngt->last_pdu_sn);
}
#endif
//----------------
// discard the sdu
if ((rlcP->input_sdus[sdu_index])) { // may be removed by "free_retransmission_buffer_no_confirmation"
if (sdu_index == rlcP->current_sdu_index) {
// sdu under segmentation
rlcP->buffer_occupancy -= ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[sdu_index]->data))->sdu_remaining_size;
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[sdu_index]->data))->no_new_sdu_segmented_in_last_pdu = 1;
rlcP->li_exactly_filled_to_add_in_next_pdu = 0;
rlcP->li_one_byte_short_to_add_in_next_pdu = 0;
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD THE SDU DISCARDED WAS UNDER SEGMENTATION (index %d)\n", rlcP->rb_id, sdu_index);
#endif
}
list2_add_tail (rlcP->input_sdus[sdu_index], &rlcP->sdu_discarded);
#ifdef DEBUG_RLC_AM_FREE_SDU
msg ("[RLC_AM][RB %d] DISCARD MAX DAT FREE_SDU INDEX %d\n", rlcP - rb_id, sdu_index);
#endif
rlcP->input_sdus[sdu_index] = NULL;
rlcP->nb_sdu -= 1;
}
}
openair2/LAYER2/RLC/AM/rlc_am_discard_notif_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_notif_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_DISCARD_NOTIF_PROTO_EXTERN_H__
# define __RLC_AM_DISCARD_NOTIF_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "rlc_am_constants.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern void rlc_am_discard_notify_mrw_ack_time_out (struct rlc_am_entity *rlcP, mem_block_t * discard_procedureP);
extern void rlc_am_discard_check_sdu_time_out (struct rlc_am_entity *rlcP);
extern void rlc_am_discard_notify_max_dat_pdu (struct rlc_am_entity *rlcP, mem_block_t * pduP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_discard_rx.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_rx.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_receiver_proto_extern.h"
#include "rlc_primitives.h"
#include "rlc_am_status_proto_extern.h"
#include "rlc_am_receiver_proto_extern.h"
#include "rlc_am_discard_tx_proto_extern.h"
#include "rlc_am_discard_notif_proto_extern.h"
#include "rlc_am_retrans_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "rlc_am_proto_extern.h"
#include "umts_timer_struct.h"
#include "umts_timer_proto_extern.h"
#include "mem_block.h"
//-----------------------------------------------------------------------------
void rlc_am_received_sufi_ack_check_discard_procedures (struct rlc_am_entity* rlcP);
void rlc_am_free_discard_procedure (mem_block_t* mb_current_procedureP);
inline void rlc_am_discard_free_receiver_buffer (struct rlc_am_entity* rlcP, uint16_t sn_mrw_iP, uint8_t nlengthP);
uint8_t* retransmission_buffer_management_mrw (struct rlc_am_entity* rlcP, uint8_t* byte1P, uint8_t* byte_alignedP);
uint8_t* retransmission_buffer_management_mrw_ack (struct rlc_am_entity* rlcP, uint8_t* byte1P, uint8_t* byte_alignedP);
//-----------------------------------------------------------------------------
void
rlc_am_received_sufi_ack_check_discard_procedures (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
mem_block_t* mb_proc;
mem_block_t* tmp_proc;
struct rlc_am_discard_procedure* procedure;
/* From 3GPP 25.322 V5.0.0 (2002-03)
The Sender shall terminate the SDU discard with explicit signalling procedure if one of the
following criteria is fulfilled:
- a STATUS PDU/piggybacked STATUS PDU containing an MRW_ACK SUFI is received, and the SN_ACK : DONE in retransmission_buffer_management_mrw_ack(..)
field in the received MRW_ACK SUFI > the SN_MRWLENGTH field in the transmitted MRW_SUFI,
and the N field in the received MRW_ACK SUFI is set equal to "0000";
- a STATUS PDU/piggybacked STATUS PDU containing an MRW_ACK SUFI is received, and the SN_ACK : DONE in retransmission_buffer_management_mrw_ack(..)
field in the received MRW_ACK SUFI = the SN_MRWLENGTH field in the transmitted MRW_SUFI,
and the N field in the received MRW_ACK SUFI is set equal to the NLENGTH field in the
transmitted MRW SUFI;
- a STATUS PDU/piggybacked STATUS PDU containing an ACK SUFI is received, and the LSN field : DONE HERE
in the received ACK SUFI > the SN_MRWLENGTH field in the transmitted MRW SUFI.
Upon termination of the SDU discard with explicit signalling procedure, the Sender shall:
- stop the timer Timer_MRW;
- update VT(A) and VT(MS) according to the received STATUS PDU/piggybacked STATUS PDU;
The Sender shall not confirm to upper layers the SDUs that are requested to be discarded.
*/
mb_proc = rlcP->discard_procedures.head;
while ((mb_proc)) {
procedure = (struct rlc_am_discard_procedure*) (mb_proc->data);
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, rlcP->vt_a, procedure->last_pdu_sn) > 0) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT NEW VT(A) 0x%04X REMOVE PROCEDURE SN_MRWlength 0x%04X\n", rlcP->rb_id, rlcP->vt_a, procedure->last_pdu_sn);
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ACK\n", rlcP->rb_id);
#endif
tmp_proc = mb_proc->next;
list2_remove_element (mb_proc, &rlcP->discard_procedures);
// if procedure is running, free timer resources
if ((procedure->running) && (rlcP->timer_mrw)) {
if (rlcP->timer_mrw == list2_remove_element (rlcP->timer_mrw, &rlcP->rlc_am_timer_list)) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ACK->TERMINATE PROCEDURE: REMOVE TIMER mrw id %p\n", rlcP->rb_id,
((struct timer_unit*) (rlcP->timer_mrw->data))->timer_id);
#endif
free_mem_block (rlcP->timer_mrw);
rlcP->timer_mrw = NULL;
} else {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT REMOVE TIMER FAILED\n", rlcP->rb_id);
#endif
}
}
rlc_am_free_discard_procedure (mb_proc);
mb_proc = tmp_proc;
rlcP->vt_mrw = 0;
} else {
mb_proc = mb_proc->next;
}
}
// may be other discard procedures to run
rlc_am_schedule_procedure (rlcP);
}
//-----------------------------------------------------------------------------
void
rlc_am_free_discard_procedure (mem_block_t* mb_current_procedureP)
{
//-----------------------------------------------------------------------------
// be carefull : the timer is not free here, it should be done before
struct rlc_am_discard_procedure* procedure;
if (mb_current_procedureP) {
procedure = (struct rlc_am_discard_procedure*) (mb_current_procedureP->data);
list_free (&procedure->sdu_list);
if (procedure->control_pdu) {
free_mem_block (procedure->control_pdu);
}
free_mem_block (mb_current_procedureP);
}
}
//-----------------------------------------------------------------------------
inline void
rlc_am_discard_free_receiver_buffer (struct rlc_am_entity* rlcP, uint16_t sn_mrw_iP, uint8_t nlengthP)
{
//-----------------------------------------------------------------------------
uint16_t working_sn;
uint16_t working_sn_index; // index in buffer
// should start reassembly with sn working_sn
working_sn = rlcP->last_reassemblied_sn;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
#ifdef DEBUG_RLC_AM_DISCARD
display_receiver_buffer (rlcP);
#endif
while (working_sn != sn_mrw_iP) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER FREE RECEIVER BUFFER pdu sn 0x%04X VR(R) 0x%04X\n", rlcP->rb_id, working_sn, rlcP->vr_r);
#endif
free_receiver_buffer (rlcP, working_sn_index);
rlcP->last_reassemblied_sn = working_sn;
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
}
// From 3GPP TS 25.322 V5.0.0 (2002-03) page 35
// NLENGTH is used together with SN_MRWLENGTH to indicate the end of the last SDU to be discarded in the receiver.
// NLENGTH indicates which LI in the PDU with sequence number SN_MRWLENGTH corresponds to the last SDU to be discarded in the receiver.
// NLENGTH = 0 indicates that the last SDU ended in the PDU with sequence number SN_MRWLENGTH -1 and that the first data octet
// in the PDU with sequence number SN_MRWLENGTH is the first data octet to be reassembled next.
// erase previous sdu in construction
rlcP->output_sdu_size_to_write = 0;
if ((nlengthP)) {
rlcP->discard_reassembly_after_li = nlengthP; // will be used by process_receiver_buffer
} else {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER rlc_am_discard_free_receiver_buffer pdu sn 0x%04X (nlength=0)\n", rlcP->rb_id, working_sn);
#endif
free_receiver_buffer (rlcP, working_sn_index);
rlcP->discard_reassembly_after_li = RLC_AM_DISCARD_REASSEMBLY_AT_LI_INDEX_0;
rlcP->last_reassemblied_sn = working_sn;
}
}
//-----------------------------------------------------------------------------
uint8_t*
retransmission_buffer_management_mrw (struct rlc_am_entity* rlcP, uint8_t* byte1P, uint8_t* byte_alignedP)
{
//-----------------------------------------------------------------------------
mem_block_t* mb;
uint8_t* p8;
uint16_t sn_mrw_i[15];
uint16_t new_vr_r;
uint16_t working_sn;
uint16_t working_sn_index; // index in buffer
uint8_t sn_mrw_i_index;
uint8_t mrw_length;
uint8_t nlength;
#ifdef DEBUG_RLC_AM_DISCARD
uint8_t i;
#endif
/* From 3GPP TS 25.322 V5.0.0 (2002-03)
Upon reception of the STATUS PDU/piggybacked STATUS PDU containing an MRW SUFI, the Receiver shall:
- if the LENGTH field in the received MRW SUFI is "0000":
- consider SN_MRW1 to be above or equal to VR(R).
- otherwise:
- consider SN_MRW1 to be less than VR(MR);
- consider all the SN_MRWis other than SN_MRW1 to be in sequential order within the list and
sequentially above or equal to SN_MRWi-1.
- discard AMD PDUs up to and including the PDU with sequence number SN_MRWLENGTH-1;
- if the NLENGTH field in the received MRW SUFI is "0000":
- reassemble from the first data octet of the AMD PDU with sequence number SN_MRWLENGTH
after the discard.
- otherwise:
- discard further the data octets in the AMD PDU with sequence number SN_MRWLENGTH up to and
including the octet indicated by the NLENGTH:th LI field of the PDU with sequence number
SN_MRWLENGTH;
- reassemble from the succeeding data octet in the AMD PDU with sequence number SN_MRWLENGTH
after the discard;
- if "Send MRW" is configured:
- inform upper layers about all of the discarded SDUs that were not previously delivered to
upper layer or discarded by other MRW SUFIs;
- update the state variables VR(R), VR(H) and VR(MR) according to the received
STATUS PDU/piggybacked STATUS PDU;
- assemble a MRW_ACK SUFI
- schedule and submit to lower layer a STATUS PDU/piggybacked STATUS PDU containing the MRW_ACK
SUFI.
The Receiver shall:
- set the SN_ACK field in the MRW_ACK SUFI to the new value of VR(R), updated after reception
of the MRW SUFI;
- if the SN_ACK field in the MRW_ACK SUFI is set equal to the SN_MRWLENGTH field in the
received MRW SUFI:
- set the N field in the MRW_ACK SUFI to the NLENGTH field in the received MRW SUFI.
- otherwise:
- set the N field in the MRW_ACK SUFI to "0000";
- include the MRW_ACK SUFI in the next STATUS PDU/piggybacked STATUS PDU to be transmitted,
according to subclause 11.5.2.
*/
p8 = byte1P;
sn_mrw_i_index = 0;
if (*byte_alignedP) {
mrw_length = *p8++ & 0X0F; // number of SN_MRWi
} else {
p8 = p8 + 1;
mrw_length = (*p8 & 0XF0) >> 4; // number of SN_MRWi
}
if (!(mrw_length)) {
if (*byte_alignedP) {
// sn_mrw_i is SN_MRW length
sn_mrw_i[0] = (*p8++) << 4;
sn_mrw_i[0] += (*p8) >> 4;
*byte_alignedP = 0;
} else {
// sn_mrw_i is SN_MRW length
sn_mrw_i[0] = (*p8++) << 8;
sn_mrw_i[0] += *p8++;
nlength = (*p8 & 0xF0) >> 4;
*byte_alignedP = 1;
}
sn_mrw_i_index += 1;
} else {
// get all sn_mrw_i
while (mrw_length != sn_mrw_i_index) {
if (*byte_alignedP) {
sn_mrw_i[sn_mrw_i_index] = (*p8++) << 4;
sn_mrw_i[sn_mrw_i_index] += (*p8) >> 4;
*byte_alignedP = 0;
} else {
sn_mrw_i[sn_mrw_i_index] = ((*p8++) & 0x0F) << 8;
sn_mrw_i[sn_mrw_i_index] += (*p8++);
*byte_alignedP = 1;
}
sn_mrw_i_index += 1;
}
}
// get nlength
if (*byte_alignedP) {
nlength = (*p8 & 0xF0) >> 4;
*byte_alignedP = 0;
} else {
nlength = *p8++ & 0x0F;
*byte_alignedP = 1;
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER RECEIVED MRW LENGTH %d ", rlcP->rb_id, mrw_length);
for (i = 0; i < sn_mrw_i_index; i++) {
msg ("sn_mrw%d 0x%04X ", i + 1, sn_mrw_i[i]);
}
msg ("Nlength %d\n", nlength);
#endif
/********************************************************************
* M R W D I S C A R D E D *
********************************************************************/
/* From 3GPP TS 25.322 V5.0.0
Reception of obsolete/corrupted MRW SUFI by the Receiver
If the received MRW SUFI contains outdated information about the receiving window
(receiving window already moved further than MRW SUFI is indicating), the Receiver shall:
- discard the MRW SUFI;
- set the SN_ACK field in the MRW_ACK SUFI to the current value of VR(R);
- set the N field in the MRW_ACK SUFI to "0000";
- include the MRW_ACK SUFI in the next STATUS PDU/piggybacked STATUS PDU to be transmitted.
*/
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, sn_mrw_i[sn_mrw_i_index - 1], rlcP->vr_r) < 0) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER ERROR received OBSOLETE/CORRUPTED MRW command VR(R) 0x%04X VR(H) 0x%04X VR(MR) 0x%04X SN_MRWlength 0x%04X\n",
rlcP->rb_id, rlcP->vr_r, rlcP->vr_h, rlcP->vr_mr, sn_mrw_i[sn_mrw_i_index - 1]);
#endif
// send status pdu mrw_ack
if ((mb = rlc_am_create_status_pdu_mrw_ack (rlcP, 0, rlcP->vr_r))) {
list_add_tail_eurecom (mb, &rlcP->control);
}
return p8;
} else {
/********************************************************************
* M R W N O T D I S C A R D E D *
********************************************************************/
new_vr_r = sn_mrw_i[sn_mrw_i_index - 1];
/***********************************
* DISCARD PDUS IN THE RECEIVER *
***********************************/
// should start discard with sn working_sn
working_sn = rlcP->last_reassemblied_sn;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
// discard all pdus except the last one
#ifdef DEBUG_RLC_AM_DISCARD
display_receiver_buffer (rlcP);
#endif
while (working_sn != new_vr_r) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER FREE RECEIVER BUFFER pdu sn 0x%04X VR(R) 0x%04X\n", rlcP->rb_id, working_sn, rlcP->vr_r);
#endif
free_receiver_buffer (rlcP, working_sn_index);
rlcP->last_reassemblied_sn = working_sn;
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
}
// From 3GPP TS 25.322 V5.0.0 (2002-03) page 35
// NLENGTH is used together with SN_MRWLENGTH to indicate the end of the last SDU to be discarded in the receiver.
// NLENGTH indicates which LI in the PDU with sequence number SN_MRWLENGTH corresponds to the last SDU to be discarded in the receiver.
// NLENGTH = 0 indicates that the last SDU ended in the PDU with sequence number SN_MRWLENGTH -1 and that the first data octet
// in the PDU with sequence number SN_MRWLENGTH is the first data octet to be reassembled next.
// erase previous sdu in construction
rlcP->output_sdu_size_to_write = 0;
rlcP->discard_reassembly_start_sn = new_vr_r;
rlcP->discard_reassembly_after_li = nlength; // will be used by process_receiver_buffer
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, new_vr_r, rlcP->vr_r) > 0) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER... VR(R) : 0x%04X -> 0x%04X (VR(H)=0x%04X)\n", rlcP->rb_id, rlcP->vr_r, new_vr_r, rlcP->vr_h);
#endif
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, new_vr_r, rlcP->vr_h) > 0) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD RECEIVER... VR(H) : 0x%04X -> 0x%04X\n", rlcP->rb_id, rlcP->vr_h, new_vr_r);
#endif
rlcP->vr_h = new_vr_r;
}
rlcP->vr_r = new_vr_r;
rlcP->ack.vr_r_modified = 1; // for status generation
rlcP->vr_mr = (rlcP->vr_r + rlcP->configured_rx_window_size - 1) & SN_12BITS_MASK;
}
if ((rlcP->send_mrw & RLC_AM_SEND_MRW_ON)) {
//send tu upper layers discarded sdus infos !!
// TO DO !!!!!!!!
}
if (rlcP->pdu_size <= 126) {
process_receiver_buffer_7 (rlcP);
} else {
process_receiver_buffer_15 (rlcP);
}
/* From 3GPP 25.322 V5.0.0 (2002-03)
The Receiver shall:
- set the SN_ACK field in the MRW_ACK SUFI to the new value of VR(R), updated after reception
of the MRW SUFI;
- if the SN_ACK field in the MRW_ACK SUFI is set equal to the SN_MRWLENGTH field in the
received MRW SUFI:
- set the N field in the MRW_ACK SUFI to the NLENGTH field in the received MRW SUFI.
- otherwise:
- set the N field in the MRW_ACK SUFI to "0000";
- include the MRW_ACK SUFI in the next STATUS PDU/piggybacked STATUS PDU to be transmitted,
according to subclause 11.5.2. */
if (sn_mrw_i[sn_mrw_i_index - 1] == rlcP->vr_r) {
mb = rlc_am_create_status_pdu_mrw_ack (rlcP, nlength, rlcP->vr_r);
} else {
mb = rlc_am_create_status_pdu_mrw_ack (rlcP, 0, rlcP->vr_r);
}
/* SEND STATUS PDU MRW ACK */
if (mb) {
list_add_tail_eurecom (mb, &rlcP->control);
}
return p8;
}
}
//-----------------------------------------------------------------------------
uint8_t*
retransmission_buffer_management_mrw_ack (struct rlc_am_entity* rlcP, uint8_t* byte1P, uint8_t* byte_alignedP)
{
//-----------------------------------------------------------------------------
mem_block_t* mb;
mem_block_t* mb_current_procedure;
struct rlc_am_tx_data_pdu_management* rlc_header;
struct rlc_am_discard_procedure* procedure;
uint8_t* p8;
uint16_t sn_ack;
uint16_t index;
uint8_t n; // field of mrw_ack sufi
//-------------------------------------
// DECODE SUFI MRW_ACK
//-------------------------------------
p8 = byte1P;
if (*byte_alignedP) {
n = *p8++ & 0X0F;
// sn_mrw_i is SN_MRW length
sn_ack = (*p8++) << 4;
sn_ack += (*p8) >> 4;
*byte_alignedP = 0;
} else {
p8 = p8 + 1;
n = (*p8 & 0XF0) >> 4;
// sn_mrw_i is SN_MRW length
sn_ack = ((*p8++) & 0x0F) << 8;
sn_ack += *p8++;
*byte_alignedP = 1;
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("\n[RLC_AM][RB %d] DISCARD TRANSMIT RX MRW_ACK N %d SN_ACK 0x%04X VT(A) 0x%04X VT(S) 0x%04X\n", rlcP->rb_id, n, sn_ack, rlcP->vt_a, rlcP->vt_s);
//display_retransmission_buffer(rlcP);
#endif
// compare to current running procedure
if ((mb_current_procedure = rlcP->discard_procedures.head)) {
procedure = (struct rlc_am_discard_procedure*) (mb_current_procedure->data);
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ... procedure->last_pdu_sn 0x%04X procedure->nlength 0x%04X \n", rlcP->rb_id, procedure->last_pdu_sn,
procedure->nlength);
#endif
/* From 3GPP TS 25.322 V5.0.0
The Sender shall discard the received MRW_ACK SUFI if one of the following cases occurs:
- the timer Timer_MRW is not active;
or
- the SN_ACK field in the received MRW_ACK SUFI < the SN_MRWLENGTH field in the transmitted MRW SUFI;
or
- the SN_ACK field in the received MRW_ACK SUFI = the SN_MRWLENGTH field in the transmitted MRW SUFI,
and the N field in the received MRW_ACK SUFI is not equal to the NLENGTH field in the transmitted MRW SUFI;
or
- the SN_ACK field in the received MRW_ACK SUFI > the SN_MRWLENGTH field in the transmitted MRW SUFI,
and the N field in the received MRW_ACK SUFI is not equal to "0000".
*/
if ((rlcP->timer_mrw == NULL) || // if timer_MRW is not active
(rlc_am_comp_sn (rlcP, rlcP->vt_a, procedure->last_pdu_sn, sn_ack) > 0) ||
((rlc_am_comp_sn (rlcP, rlcP->vt_a, procedure->last_pdu_sn, sn_ack) == 0) && (n != procedure->nlength)) ||
((rlc_am_comp_sn (rlcP, rlcP->vt_a, procedure->last_pdu_sn, sn_ack) < 0) && (n != 0))) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ERROR RX OBSOLETE MRW_ACK VT(A) 0x%04X VT(S) 0x%04X SN_MRWlength 0x%04X N %d SN_ACK 0x%04X\n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, procedure->last_pdu_sn, n, sn_ack);
#endif
} else if (
/* From 3GPP 25.322 V5.0.0 (2002-03)
The Sender shall terminate the SDU discard with explicit signalling procedure if one of the
following criteria is fulfilled:
- a STATUS PDU/piggybacked STATUS PDU containing an MRW_ACK SUFI is received, and the SN_ACK : DONE HERE
field in the received MRW_ACK SUFI > the SN_MRWLENGTH field in the transmitted MRW_SUFI,
and the N field in the received MRW_ACK SUFI is set equal to "0000";
- a STATUS PDU/piggybacked STATUS PDU containing an MRW_ACK SUFI is received, and the SN_ACK : DONE HERE
field in the received MRW_ACK SUFI = the SN_MRWLENGTH field in the transmitted MRW_SUFI,
and the N field in the received MRW_ACK SUFI is set equal to the NLENGTH field in the
transmitted MRW SUFI;
- a STATUS PDU/piggybacked STATUS PDU containing an ACK SUFI is received, and the LSN field : DONE in rlc_am_received_sufi_ack_check_discard_procedures(...)
in the received ACK SUFI > the SN_MRWLENGTH field in the transmitted MRW SUFI.
Upon termination of the SDU discard with explicit signalling procedure, the Sender shall:
- stop the timer Timer_MRW;
- update VT(A) and VT(MS) according to the received STATUS PDU/piggybacked STATUS PDU;
The Sender shall not confirm to upper layers the SDUs that are requested to be discarded.
*/
(rlc_am_comp_sn (rlcP, rlcP->vt_a, sn_ack, procedure->last_pdu_sn) > 0) || ((sn_ack == procedure->last_pdu_sn) && (n == procedure->nlength))
) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD PROCEDURE %p TERMINATED\n", rlcP->rb_id, mb_current_procedure);
#endif
rlcP->vt_mrw = 0;
// remove timer
if ((rlcP->timer_mrw)) {
if (rlcP->timer_mrw == list2_remove_element (rlcP->timer_mrw, &rlcP->rlc_am_timer_list)) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT TERMINATE PROCEDURE: REMOVE TIMER mrw id %p\n", rlcP->rb_id, ((struct timer_unit*) (rlcP->timer_mrw->data))->timer_id);
#endif
free_mem_block (rlcP->timer_mrw);
rlcP->timer_mrw = NULL;
}
#ifdef DEBUG_RLC_AM_DISCARD
else {
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ERROR TERMINATION PROCEDURE : TIMER MRW IS WRONG\n",
rlcP->rb_id); // in fact : no, the lists are not protected against an element that is not inside the list
}
#endif
}
#ifdef DEBUG_RLC_AM_DISCARD
else {
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ERROR TERMINATION PROCEDURE : NO TIMER MRW WAS FOUND\n", rlcP->rb_id);
}
#endif
mb_current_procedure = list2_remove_head (&rlcP->discard_procedures);
//update VT(A)
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, sn_ack, rlcP->vt_a) > 0) {
// free resources that may be in retransmission buffer
while (rlcP->vt_a != sn_ack) {
index = rlcP->vt_a % rlcP->recomputed_configured_tx_window_size;
if ((mb = rlcP->retransmission_buffer[index])) {
rlc_header = (struct rlc_am_tx_data_pdu_management*) (mb->data);
if (rlc_header->nb_sdu > 0) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT CASE 1 MRW_ACK\n", rlcP->rb_id);
#endif
// the sender of MRW_ACK changed sn_mrw_length to vr_r, so it is normal to free
// pdus that are linked with sdus
free_retransmission_buffer_no_confirmation (rlcP, index);
} else {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT CASE 2 MRW_ACK FREE REMAINING RETRANS PDU 0x%04X\n", rlcP->rb_id, rlcP->vt_a);
#endif
// if this pdu has been retransmitted, remove its size from buffer occupancy
if (rlc_header->vt_dat > 0) {
rlcP->buffer_occupancy_retransmission_buffer -= 1;
}
free_mem_block (mb);
rlcP->retransmission_buffer[index] = NULL;
}
}
rlcP->vt_a = (rlcP->vt_a + 1) & SN_12BITS_MASK;
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT MRW_ACK VT(A) UPDATED 0x%04X VT(S) 0x%04X\n", rlcP->rb_id, rlcP->vt_a, rlcP->vt_s);
#endif
}
rlc_am_free_discard_procedure (mb_current_procedure);
rlc_am_schedule_procedure (rlcP);
} else {
msg ("[RLC_AM][RB %d] DISCARD TRANSMIT ERROR RX MRW_ACK CASE NOT TAKEN IN ACCOUNT : NO ACTION !\n", rlcP->rb_id);
}
}
#ifdef DEBUG_RLC_AM_DISCARD
//display_mem_load();
//display_retransmission_buffer(rlcP);
#endif
return p8;
}
openair2/LAYER2/RLC/AM/rlc_am_discard_rx_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_rx_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_DISCARD_RX_PROTO_EXTERN_H__
# define __RLC_AM_DISCARD_RX_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern void rlc_am_received_sufi_ack_check_discard_procedures (struct rlc_am_entity *rlcP);
extern void rlc_am_free_discard_procedure (mem_block_t * mb_current_procedureP);
extern inline void rlc_am_discard_free_receiver_buffer (struct rlc_am_entity *rlcP, uint16_t sn_mrw_iP, uint8_t nlengthP);
extern uint8_t *retransmission_buffer_management_mrw (struct rlc_am_entity *rlcP, uint8_t * byte1P, uint8_t * byte_alignedP);
extern uint8_t *retransmission_buffer_management_mrw_ack (struct rlc_am_entity *rlcP, uint8_t * byte1P, uint8_t * byte_alignedP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_discard_tx.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_tx.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_discard_notif_proto_extern.h"
#include "rlc_am_discard_rx_proto_extern.h"
#include "rlc_primitives.h"
#include "rlc_am_status_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "rlc_am_constants.h"
#include "rlc_am_structs.h"
#include "umts_timer_proto_extern.h"
//-----------------------------------------------------------------------------
void rlc_am_schedule_procedure (struct rlc_am_entity* rlcP);
void rlc_am_process_sdu_discarded (struct rlc_am_entity* rlcP);
void rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_configured (struct rlc_am_entity* rlcP);
void rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_not_configured (struct rlc_am_entity* rlcP);
//-----------------------------------------------------------------------------
void
rlc_am_schedule_procedure (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
mem_block_t* pdu_status;
struct rlc_am_discard_procedure* procedure;
// if a procedure is running do nothing
if (!(rlcP->timer_mrw) && (rlcP->discard_procedures.head)) {
// launch remaining procedures (only 1 procedure running)
procedure = (struct rlc_am_discard_procedure*) ((rlcP->discard_procedures.head)->data);
/* sn_mrw_length = procedure->last_pdu_sn;
if (rlc_am_comp_sn(rlcP, rlcP->vt_s, sn_mrw_length, rlcP->vt_s) > 0) {
#ifdef DEBUG_RLC_AM_DISCARD
msg("[RLC_AM %p][DISCARD] SCHEDULE PROCEDURE %p UPDATE VT(S) %04X -> %04X\n", rlcP, rlcP->discard_procedures.head, rlcP->vt_s, sn_mrw_length);
#endif
rlcP->vt_s = sn_mrw_length;
}
*/
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD SCHEDULE PROCEDURE %p vt_s 0x%04X vt_a 0x%04X\n", rlcP->rb_id, rlcP->discard_procedures.head, rlcP->vt_s, rlcP->vt_a);
#endif
procedure->running = 0xFF;
pdu_status = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE);
memcpy (pdu_status->data, procedure->control_pdu->data, rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation));
list_add_tail_eurecom (pdu_status, &rlcP->control);
}
}
//-----------------------------------------------------------------------------
void
rlc_am_process_sdu_discarded (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
// We assume that the list sdu_discarded contains sdu(s)
/* From 3GPP TS 25.322 V4.3.0 (2001-12)
The Sender shall initiate the SDU discard with explicit signalling procedure if one of the
following triggers is detected:
- "Timer based SDU discard with explicit signalling" is configured, Timer_Discard expires
for an SDU, and one or more segments of the SDU have been submitted to a lower layer;
- "Timer based SDU discard with explicit signalling" is configured, Timer_Discard expires
for an SDU, and Send MRW is configured;
- "SDU discard after MaxDAT number of transmissions" is configured, and MaxDAT number of
transmissions is reached (i.e. VT(DAT) � MaxDAT) for an AMD PDU.
*/
// discard procedure
if ((rlcP->send_mrw & RLC_AM_SEND_MRW_ON)) {
rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_configured (rlcP);
} else { // RLC_AM_SEND_MRW_OFF
rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_not_configured (rlcP);
}
rlc_am_schedule_procedure (rlcP);
}
//-----------------------------------------------------------------------------
void
rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_configured (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
/* From 3GPP TS 25.322 V5.0.0 (2002-03)
The Sender shall:
- if "Send MRW" is configured:
- if the last discarded SDU ended in an AMD PDU, and its "Length Indicator" is present in the same AMD
PDU, and no new SDU is present inside this AMD PDU:
- set the last SN_MRWi field in the MRW SUFI to 1 + "Sequence Number" of the AMD PDU which
contains the "Length Indicator" of the last discarded SDU;
- set the NLENGTH field in the MRW SUFI to "0000".
- otherwise:
- set the last SN_MRWi field in the MRW SUFI to the "Sequence Number" of the AMD PDU which
contains the "Length Indicator" of the last discarded SDU;
- set the NLENGTH field in the MRW SUFI so that the last data octet to be discarded in the Receiver shall be
the octet indicated by the NLENGTH:th "Length Indicator" field of the AMD PDU which contains the
"Length Indicator" of the last discarded SDU;
- set each of the other SN_MRWi fields in the MRW SUFI to the "Sequence Number" of the AMD PDU which
contains the "Length Indicator" of the i:th discarded SDU.
- if the MRW SUFI contains only one SN_MRWi field and the value of SN_MRWi field
VT(A)+Configured_Tx_Window_Size:
- set the LENGTH field in the MRW SUFI to "0000".
- otherwise:
- set the LENGTH field in the MRW SUFI to the number of SN_MRWi fields in the same MRW SUFI. In this
case, SN_MRW1 shall be in the interval VT(A) SN_MRW1 < VT(A)+Configured_Tx_Window_Size.
*/
mem_block_t* mb_discard_procedure = NULL;
mem_block_t* sdu_discarded;
struct rlc_am_tx_sdu_management* last_sdu_discarded_mngt;
mem_block_t* le;
struct rlc_am_status_header* pdu;
uint8_t* p8;
int last_sn_mrw_length;
uint8_t count_sdu_discarded;
uint8_t byte_aligned;
#ifdef DEBUG_RLC_AM_DISCARD
uint16_t sn_mrw_length;
#endif
while (rlcP->sdu_discarded.head) {
// alloc a discard procedure
mb_discard_procedure = get_free_mem_block (sizeof (struct rlc_am_discard_procedure));
memset (mb_discard_procedure->data, 0, sizeof (struct rlc_am_discard_procedure));
list_init (&((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->sdu_list, NULL);
count_sdu_discarded = 0;
// assign sdu discarded to discard procedure
// sdu headers are registered in discard procedure
last_sn_mrw_length = -1;
while ((rlcP->sdu_discarded.head) && (count_sdu_discarded < 15)) { // max 15 sdu discarded per procedure
sdu_discarded = list2_remove_head (&rlcP->sdu_discarded);
// this test is done to avoid signalling n times the same SN_MRW_length if a pdu contains n sdu
// so it can save some discard procedures.
if (last_sn_mrw_length != ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD IN PROCEDURE %p ADD SDU SN_MRWlength 0x%03X\n", rlcP->rb_id, mb_discard_procedure,
((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn);
#endif
list_add_tail_eurecom (sdu_discarded, &((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->sdu_list);
last_sn_mrw_length = ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn;
count_sdu_discarded += 1;
} else {
free_mem_block (sdu_discarded);
}
}
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->length = count_sdu_discarded;
//((struct rlc_am_discard_procedure*)(mb_discard_procedure->data))->nlength = ((struct rlc_am_sdu_discard_management*)((mem_block_t*)(sdu_header_copy_copy->data))->data)->li_index_for_discard;
last_sdu_discarded_mngt = (struct rlc_am_tx_sdu_management*) (sdu_discarded->data);
if ((last_sdu_discarded_mngt->no_new_sdu_segmented_in_last_pdu)) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD NO NEW SDU SEGMENTED IN LAST PDU DISCARDED\n", rlcP->rb_id);
#endif
last_sdu_discarded_mngt->last_pdu_sn = (last_sdu_discarded_mngt->last_pdu_sn + 1) & SN_12BITS_MASK;
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength = 0;
} else {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD OTHER SDU(s) SEGMENTED IN LAST PDU DISCARDED\n", rlcP->rb_id);
#endif
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength = last_sdu_discarded_mngt->li_index_for_discard +
1; // +1 since numerotation begins at 1
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD SET SN_MRW_LENGTH 0x%04X NLENGTH = %d \n", rlcP->rb_id, last_sdu_discarded_mngt->last_pdu_sn,
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength);
sn_mrw_length = last_sdu_discarded_mngt->last_pdu_sn;
#endif
// make status pdu
le = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (le == NULL) {
// be carefull : lost resources in mb_discard : TO DO
msg ("[RLC_AM][RB %d] FATAL ERROR : OUT OF MEMORY\n", rlcP->rb_id);
return;
} else {
((struct rlc_am_tx_control_pdu_management*) (le->data))->rlc_tb_type = RLC_AM_MRW_STATUS_PDU_TYPE;
pdu = (struct rlc_am_status_header*) (&le->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
pdu->byte1 = RLC_PDU_TYPE_STATUS;
p8 = &(pdu->byte1);
*p8 = *p8 | RLC_AM_SUFI_MRW;
p8 = p8 + 1;
// fill field LENGTH
*p8 = (count_sdu_discarded << 4);
byte_aligned = 0;
// fill fields SN_MRWi
sdu_discarded = (((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->sdu_list.head); // reuse of var sdu_discarded
while ((count_sdu_discarded)) {
count_sdu_discarded -= 1;
if (byte_aligned) {
*p8 = ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn >> 4;
p8 = p8 + 1;
*p8 = ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn << 4;
byte_aligned = 0;
} else {
//*p8 = 0 << 4 | (temp_sn >> 8);
*p8 |= (((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn >> 8);
p8 = p8 + 1;
*p8 = ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn;
p8 = p8 + 1;
byte_aligned = 1;
}
sdu_discarded = sdu_discarded->next;
}
// fill field Nlength
if (byte_aligned) {
*p8 = (((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength << 4) | RLC_AM_SUFI_NO_MORE;
} else {
*p8 |= (((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength);
p8 = p8 + 1;
*p8 = (RLC_AM_SUFI_NO_MORE << 4);
}
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->control_pdu = le;
list2_add_tail (mb_discard_procedure, &rlcP->discard_procedures);
}
}
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD QUEUED NEW PROCEDURE SEND_MRW IS CONFIGURED SN_MRW_length = 0x%04X length %d nlength %d\n",
rlcP->rb_id, sn_mrw_length, ((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->length,
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength);
#endif
}
//-----------------------------------------------------------------------------
void
rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_not_configured (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
/* From 3GPP TS 25.322 V5.0.0 (2002-03)
The Sender shall:
- if "Send MRW" is NOT configured:
- if the last SDU to be discarded in the Receiver ended in an AMD PDU, and its "Length Indicator" is present
in the same AMD PDU, and no new SDU is present inside this AMD PDU:
- set the last SN_MRWi field in the MRW SUFI to 1 + "Sequence Number" of the AMD PDU which
contains the "Length Indicator" of the last SDU to be discarded in the Receiver;
- set the NLENGTH field in the MRW SUFI to "0000".
- otherwise:
- set the last SN_MRWi field in the MRW SUFI to the "Sequence Number" of the AMD PDU which
contains the "Length Indicator" of the last SDU to be discarded in the Receiver;
- set the NLENGTH field in the MRW SUFI so that the last data octet to be discarded in the Receiver shall be
the octet indicated by the NLENGTH:th "Length Indicator" field of the AMD PDU which contains the
"Length Indicator" of the last SDU to be discarded in the Receiver;
- optionally set each of the other SN_MRWi fields in the MRW SUFI to the "Sequence Number" of the AMD
PDU which contains the "Length Indicator" of the i:th SDU to be discarded in the Receiver;
- if the MRW SUFI contains only one SN_MRWi field and the value of SN_MRWi field
VT(A)+Configured_Tx_Window_Size:
- set the LENGTH field in the MRW SUFI to "0000".
- otherwise:
- set the LENGTH field in the MRW SUFI to the number of SN_MRWi fields in the same MRW SUFI. In this
case, SN_MRW1 shall be in the interval VT(A) SN_MRW1 < VT(A)+Configured_Tx_Window_Size.
*/
mem_block_t* mb_discard_procedure = NULL;
mem_block_t* sdu_discarded;
struct rlc_am_tx_sdu_management* last_sdu_discarded_mngt;
mem_block_t* le;
struct rlc_am_status_header* pdu;
int last_sn_mrw_length;
uint8_t* p8;
uint8_t count_sdu_discarded;
uint8_t byte_aligned;
#ifdef DEBUG_RLC_AM_DISCARD
uint16_t sn_mrw_length;
#endif
while (rlcP->sdu_discarded.head) {
// alloc a discard procedure
mb_discard_procedure = get_free_mem_block (sizeof (struct rlc_am_discard_procedure));
memset (mb_discard_procedure->data, 0, sizeof (struct rlc_am_discard_procedure));
list_init (&((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->sdu_list, NULL);
count_sdu_discarded = 0;
// assign sdu discarded to discard procedure
// sdu headers are registered in discard procedure
last_sn_mrw_length = -1;
while ((rlcP->sdu_discarded.head) && (count_sdu_discarded < 15)) { // max 15 sdu discarded per procedure
sdu_discarded = list2_remove_head (&rlcP->sdu_discarded);
// this test is done to avoid signalling n times the same SN_MRW_length if a pdu contains n sdu
// so it can save some discard procedures.
if (last_sn_mrw_length != ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn) {
#ifdef DEBUG_RLC_AM_DISCARD
msg ("[RLC_AM][RB %d] DISCARD IN PROCEDURE %p ADD SDU SN_MRWlength %03X hex\n", rlcP->rb_id, mb_discard_procedure,
((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn);
#endif
list_add_tail_eurecom (sdu_discarded, &((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->sdu_list);
last_sn_mrw_length = ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn;
count_sdu_discarded = 1;
} else {
free_mem_block (sdu_discarded);
}
}
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->length = count_sdu_discarded;
//((struct rlc_am_discard_procedure*)(mb_discard_procedure->data))->nlength = ((struct rlc_am_sdu_discard_management*)((mem_block_t*)(sdu_header_copy_copy->data))->data)->li_index_for_discard;
last_sdu_discarded_mngt = (struct rlc_am_tx_sdu_management*) (sdu_discarded->data);
if ((last_sdu_discarded_mngt->no_new_sdu_segmented_in_last_pdu)) {
last_sdu_discarded_mngt->last_pdu_sn = (last_sdu_discarded_mngt->last_pdu_sn + 1) & SN_12BITS_MASK;
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength = 0;
} else {
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength = last_sdu_discarded_mngt->li_index_for_discard;
}
#ifdef DEBUG_RLC_AM_DISCARD
sn_mrw_length = last_sdu_discarded_mngt->last_pdu_sn;
#endif
// make status pdu
if ((le = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE))) {
((struct rlc_am_tx_control_pdu_management*) (le->data))->rlc_tb_type = RLC_AM_MRW_STATUS_PDU_TYPE;
pdu = (struct rlc_am_status_header*) (&le->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
pdu->byte1 = RLC_PDU_TYPE_STATUS;
p8 = &(pdu->byte1);
*p8 = *p8 | RLC_AM_SUFI_MRW;
p8 = p8 + 1;
// fill field LENGTH
*p8 = (count_sdu_discarded << 4);
byte_aligned = 0;
// fill fields SN_MRWi
sdu_discarded = (((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->sdu_list.head); // reuse of var sdu_discarded
//*p8 = 0 << 4 | (temp_sn >> 8);
*p8 |= (((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn >> 8);
p8 = p8 + 1;
*p8 = ((struct rlc_am_tx_sdu_management*) (sdu_discarded->data))->last_pdu_sn;
p8 = p8 + 1;
byte_aligned = 1;
// fill field Nlength
*p8 = (((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->nlength << 4) | RLC_AM_SUFI_NO_MORE;
((struct rlc_am_discard_procedure*) (mb_discard_procedure->data))->control_pdu = le;
list2_add_tail (mb_discard_procedure, &rlcP->discard_procedures);
} else {
// out of memory
return;
}
}
}
openair2/LAYER2/RLC/AM/rlc_am_discard_tx_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_tx_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_DISCARD_TX_PROTO_EXTERN_H__
# define __RLC_AM_DISCARD_TX_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern void rlc_am_schedule_procedure (struct rlc_am_entity *rlcP);
extern void rlc_am_process_sdu_discarded (struct rlc_am_entity *rlcP);
extern void rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_configured (struct rlc_am_entity *rlcP);
extern void rlc_am_sdu_discard_with_explicit_signalling_procedure_send_mrw_not_configured (struct rlc_am_entity *rlcP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_entity.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_entity.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_ENTITY_H__
# define __RLC_AM_ENTITY_H__
//-----------------------------------------------------------------------------
# include "mem_block.h"
# include "rlc_am_structs.h"
# include "rlc_def.h"
# include "platform_types.h"
# include "platform_constants.h"
//-----------------------------------------------------------------------------
struct rlc_am_entity {
module_id_t module_id;
// for stats and trace purpose :
uint16_t data_plane; // act as a boolean
uint16_t rb_id;
//-----------------------------
// polling info
//-----------------------------
uint16_t poll_pdu_trigger;
uint16_t poll_sdu_trigger;
uint16_t timer_poll_trigger;
uint16_t timer_poll_prohibit_trigger;
uint8_t last_transmission_pdu_poll_trigger;
uint8_t last_retransmission_pdu_poll_trigger;
uint8_t poll_window_trigger;
//-----------------------------
// timers
//-----------------------------
list2_t rlc_am_timer_list;
//uint16_t timer_poll;
//uint16_t timer_poll_prohibit;
uint16_t timer_poll_periodic;
//uint16_t timer_status_prohibit;
uint16_t timer_status_periodic;
signed int timer_status_prohibit;
signed int running_timer_status_prohibit;
mem_block_t *timer_rst;
uint16_t time_out_events;
mem_block_t *timer_mrw; // if NULL : no timer is running
//uint8_t timer_mrw_is_running;
uint8_t max_mrw;
//uint16_t timer_poll_init;
//uint16_t timer_poll_prohibit_init;
//uint16_t timer_epc_init;
uint16_t timer_discard_init;
uint16_t timer_poll_periodic_init;
//uint16_t timer_status_prohibit_init;
//uint16_t timer_status_periodic_init;
uint16_t timer_rst_init;
uint16_t timer_mrw_init;
uint32_t transmitted_pdu_types;
int last_tx_status_frame;
uint32_t *frame_tick_milliseconds; // pointer on this tick variable handled by RRC : READ ONLY
uint8_t missing_pdu_indicator;
//-----------------------------
// tranmission
//-----------------------------
//struct cnt_dbl_lk_list_up segmentation_buffer; // output of segmentation/concatenation function
list2_t sdu_conf_segmented; // contain sdu_headers:sdu processed by the segmentation unit. (we keep them for confirm)
list2_t sdu_discard_segmented; // contain sdu_headers:sdu processed by the segmentation unit. (we keep them for discard)
list2_t sdu_discarded; // contain sdu_headers
list2_t discard_procedures; // contain procedures (struct rlc_am_discard_procedure)
//struct cnt_dbl_lk_list_up transmission_buffer; // output of mux module
//uint16_t data_pdu_size;
//uint16_t control_pdu_size;
//struct cnt_list_up dcch_pdus_to_mac_layer;
//struct cnt_list_up dtch_pdus_to_mac_layer;
//struct list_up dcch_pdus_from_mac_layer;
//struct list_up dtch_pdus_from_mac_layer;
// implementation specific: our transmiter buffer is an array whose size must be a power of 2
# define RLC_AM_DISCARD_REASSEMBLY_AT_LI_INDEX_0 0x00
uint8_t discard_reassembly_after_li; // when received mrw sufi
uint16_t discard_reassembly_start_sn;
//-----------------------------
// management of received PDU for piggybacked status PDU and status PDU
//-----------------------------
struct sufi_to_insert_in_status status_in_construction[NB_MAX_SUFI];
struct sufi_ack ack;
uint8_t sufi_to_insert_index;
//-----------------------------
// Reset
//-----------------------------
uint8_t send_status_pdu_requested;
uint8_t reset_sequence_number;
uint8_t last_received_rsn;
uint8_t max_rst;
//-----------------------------
// Mapping info
//-----------------------------
uint8_t dcch_logical_channel_identity;
uint8_t dtch_logical_channel_identity;
uint8_t nb_logical_channels_per_rlc;
//-----------------------------
// buffer occupancy measurements sent to MAC
//-----------------------------
// note occupancy of other buffers is deducted from nb elements in lists
uint32_t buffer_occupancy_retransmission_buffer; // nb of pdus
//**************************************************************
// new members
//**************************************************************
uint8_t allocation;
uint8_t location; // UTRAN/UE
uint8_t protocol_state;
//-----------------------------
// protocol variables
//-----------------------------
uint16_t first_li_in_next_pdu; // indicates :
// value = 000000000000000 that the previous PDU was exactly
// with the last segment of an RLC SDU and there is no LI that
// indicates the end of the SDU in the previous RLC PDU.
// value = 111111111111011 The last segment of an RLC SDU was one octet
// short of exactly filling the previous RLC PDU and there is no LI that
// indicates the end of the SDU in the previous RLC PDU. The remaining one
// octet in the previous RLC PDU is ignored.
// value = 111111111111110 AMD PDU: The rest of the RLC PDU includes a
// piggybacked STATUS PDU.
// value = 111111111111111 The rest of the RLC PDU is padding. The padding
// length can be zero.
uint16_t vt_s; // send state variable
// The sequence number of the next PDU to be transmitted for the
// first time(i.e. excluding retransmission). It is updated after
// transmission of a PDU, which includes not earlier transmitted
// PDUs and after transmission of a MRW SUFI which includes SN_MRW
// length > VT(S).
uint16_t vt_a; // Acknowledged state variable
// The sequence number of the next in sequence PDU expected to be
// acknowledged, which forms the lower edge of the window of acceptable
// acknowledgments. VT(A) is updated based on a receipt of a STATUS
// PDU including an ACK and/or MRW_ACK super field.
uint16_t max_dat; // This state variable counts the number of times a PDU has been transmited
// There is one vt(dat) for each PDU and it is incremented each time the pdu
// is transmited. The initial value of this variable is 0;
uint16_t vt_ms; // Maximun send state variable
// The sequence number of the first PDU not allowed by the receiver
// [the receiver will allow up to VT(MS)-1], VT(MS) = VT(A)+VT(WS).
// This value represents the upper edge of the transmit window. The
// transmitter shall not transmit a PDU with SN>=VT(MS). VT(MS) is
// updated when either VT(A) or VT(WS) is updated. The PDU with SN
// VT(S)-1 can be transmitted also when VT(S) >= VT(MS).
uint16_t vt_pdu; // not used
uint16_t vt_sdu; // this state variable is used when the poll every Poll_SDU SDU
// function is used. It is incremented with 1 each SDU is
// transmitted. When it reaches Poll_SDU a new poll is transmitted
// the state variable is set to 0. The poll bit should be set in the
// PDU that contains the last segment of the SDU.
uint16_t vt_rst; // Reset state variable
// it is used to count the number of times a RESET PDU is transmitted.
// vt(rst) is incremented with 1 each time a RESET PDU is transmitted. VT(rst) is
// reset only upon the reception of a RESET ACK PDU, i.e. VT(RST) is not reset when
// an RLC RESET occurs which was initiated from the peer RLC entity. The initial value
// of this variable is 0.
uint16_t vt_mrw; // MRW command send state variable
// It is used to count the number of times a MRW command is transmitted.
// VT(MRW) is reset when the discard procedure is terminated.
uint16_t vt_ws; // transmitter window size state variable
// The size that should be used for the transmitter window. VT(WS)
//is set equal to the WSN field when the transmitter receives a
// STATUS PDU including a WindowSize super-field.
uint16_t vr_r; // Receive state variable
// The sequence number of the next in sequence PDU expected to be
// received. It is equal to SNmax+1 upon receipt of the next in
// sequence PDU, where SNmax is the sequence number of the highest
// received in sequence PDU. The initial value of this variable is 0
uint16_t vr_h; // Highest expected state variable
// The sequence number of the highest expected PDU. this state
// variable is set equal to SN+1 only when a new PDU is received
// with VR(MR)>SN>=VR(H). The initial value of this variable is 0.
uint16_t vr_mr; // Maximum acceptable Receive state variable
// The sequence number of the first PDU not allowed by the receiver.
// It shall be set equal to SN+1 upon reception of a PDU. The
// initial value of this variable is 0.
int16_t vr_ep; // Estimated PDU counter state variable
// The number of PDUs that should be received yet as a consequence
// of the transmission of the latest status report. In acknowledged
// mode, this state variable is updated at the end of each TTI. It
// is decremented by the number of PDUs that should have been
// received during the TTI. If VR(EP) is equal to 0, then check if
// all PDUs requested for retransmission in the latest status report
// have been received.
//-----------------------------
// C-SAP
//-----------------------------
list_t c_sap;
//-----------------------------
// discard
//-----------------------------
uint8_t sdu_discard_mode;
uint8_t send_mrw;
//-----------------------------
// tranmission
//-----------------------------
mem_block_t **input_sdus; // should be accessed as an array
mem_block_t *input_sdus_alloc; // allocation of the array
uint16_t size_input_sdus_buffer;
uint16_t nb_sdu;
uint16_t next_sdu_index; // next location of incoming sdu
uint16_t current_sdu_index;
uint32_t buffer_occupancy;
// for segmentation procedures (optimization save space on stack)
uint16_t li[RLC_AM_SEGMENT_NB_MAX_LI_PER_PDU];
uint16_t configured_tx_window_size;
// implementation specific: our transmiter buffer is an array whose size must be a power of 2
uint16_t recomputed_configured_tx_window_size;
mem_block_t *(*rlc_segment) (struct rlc_am_entity * rlcP);
mem_block_t *retransmission_buffer_alloc;
mem_block_t **retransmission_buffer;
list2_t retransmission_buffer_to_send; // contains PDUs that must be immediatly retransmitted
list_t control; // contains control pdus
uint16_t nb_pdu_requested_by_mac_on_ch1;
uint16_t nb_pdu_requested_by_mac_on_ch2;
uint16_t pdu_size;
uint8_t li_one_byte_short_to_add_in_next_pdu;
uint8_t li_exactly_filled_to_add_in_next_pdu;
list_t pdus_to_mac_layer_ch1;
list_t pdus_to_mac_layer_ch2;
//-----------------------------
// receiver
//-----------------------------
sdu_size_t output_sdu_size_to_write;
mem_block_t *output_sdu_in_construction;
mem_block_t *receiver_buffer_alloc;
mem_block_t **receiver_buffer;
uint16_t last_reassemblied_sn;
uint16_t configured_rx_window_size;
uint16_t recomputed_configured_rx_window_size;
list_t pdus_from_mac_layer_ch1;
list_t pdus_from_mac_layer_ch2;
//-----------------------------
// status generation
//-----------------------------
mem_block_t *holes_alloc;
struct rlc_am_hole *holes;
uint16_t nb_missing_pdus;
uint16_t ack_sn;
uint16_t nb_holes;
# ifdef BYPASS_L1
unsigned int pdu_counter;
# endif
unsigned int stat_tx_pdcp_sdu;
unsigned int stat_tx_pdcp_sdu_discarded;
unsigned int stat_tx_retransmit_pdu_unblock;
unsigned int stat_tx_retransmit_pdu_by_status;
unsigned int stat_tx_retransmit_pdu;
unsigned int stat_tx_data_pdu;
unsigned int stat_tx_control_pdu;
unsigned int stat_rx_sdu;
unsigned int stat_rx_error_pdu;
unsigned int stat_rx_data_pdu;
unsigned int stat_rx_data_pdu_out_of_window;
unsigned int stat_rx_control_pdu;
};
# endif
openair2/LAYER2/RLC/AM/rlc_am_errno.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
# ifndef __RLC_AM_ERRNO_H__
# define __RLC_AM_ERRNO_H__
# endif
# define RLC_AM_OUT_OF_MEMORY_ERROR 1
# define RLC_AM_VT_S_OVERFLOW_ERROR 2
# define RLC_AM_RETRANS_REQ_PDU_NULL 3
# define RLC_AM_RETRANS_REQ_PDU_DONE_BEFORE 4
openair2/LAYER2/RLC/AM/rlc_am_fsm.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_fsm.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_constants.h"
#include "rlc_def.h"
#include "LAYER2/MAC/extern.h"
//-----------------------------------------------------------------------------
int
rlc_am_fsm_notify_event (struct rlc_am_entity* rlcP, uint8_t eventP)
{
//-----------------------------------------------------------------------------
switch (rlcP->protocol_state) {
//-------------------------------
// RLC_NULL_STATE
//-------------------------------
case RLC_NULL_STATE:
switch (eventP) {
case RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_DATA_TRANSFER_READY_STATE_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_NULL_STATE -> RLC_DATA_TRANSFER_READY_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_DATA_TRANSFER_READY_STATE;
return 1;
break;
default:
msg ("[RLC_AM][RB %d][FSM] WARNING PROTOCOL ERROR - EVENT %02X hex NOT EXPECTED FROM NULL_STATE frame %d\n", rlcP->rb_id, eventP, Mac_rlc_xface->frame);
return 0;
}
break;
//-------------------------------
// RLC_DATA_TRANSFER_READY_STATE
//-------------------------------
case RLC_DATA_TRANSFER_READY_STATE:
switch (eventP) {
case RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_NULL_STATE_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_DATA_TRANSFER_READY_STATE -> RLC_NULL_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_NULL_STATE;
return 1;
break;
case RLC_AM_RECEIVE_RESET_EVENT:
case RLC_AM_TRANSMIT_RESET_ACK_EVENT:
return 1;
break;
case RLC_AM_TRANSMIT_RESET_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_DATA_TRANSFER_READY_STATE -> RLC_RESET_PENDING_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_RESET_PENDING_STATE;
return 1;
break;
case RLC_AM_RECEIVE_CRLC_SUSPEND_REQ_EVENT:
case RLC_AM_TRANSMIT_CRLC_SUSPEND_CNF_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_DATA_TRANSFER_READY_STATE -> RLC_LOCAL_SUSPEND_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_LOCAL_SUSPEND_STATE;
return 1;
break;
default:
msg ("[RLC_AM][RB %d][FSM] WARNING PROTOCOL ERROR - EVENT 0x%02X NOT EXPECTED FROM DATA_TRANSFER_READY_STATE frame %d\n", rlcP->rb_id, eventP,
Mac_rlc_xface->frame);
return 0;
}
break;
//-------------------------------
// RLC_RESET_PENDING_STATE
//-------------------------------
case RLC_RESET_PENDING_STATE:
switch (eventP) {
case RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_NULL_STATE_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_RESET_PENDING_STATE -> RLC_NULL_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_NULL_STATE;
return 1;
break;
case RLC_AM_RECEIVE_RESET_EVENT:
case RLC_AM_TRANSMIT_RESET_ACK_EVENT:
case RLC_AM_TRANSMIT_RESET_EVENT: // WARNING: THIS EVENT IS NOT IN SPECS BUT MAY BE AN OMISSION ????
return 1;
break;
case RLC_AM_RECEIVE_RESET_ACK_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_RESET_PENDING_STATE -> RLC_DATA_TRANSFER_READY_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_DATA_TRANSFER_READY_STATE;
return 1;
break;
case RLC_AM_RECEIVE_CRLC_SUSPEND_REQ_EVENT:
case RLC_AM_TRANSMIT_CRLC_SUSPEND_CNF_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_RESET_PENDING_STATE -> RLC_RESET_AND_SUSPEND_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_RESET_AND_SUSPEND_STATE;
return 1;
break;
default:
msg ("[RLC_AM][RB %d][FSM] WARNING PROTOCOL ERROR - EVENT 0x%02X NOT EXPECTED FROM RLC_RESET_PENDING_STATE frame %d\n", rlcP->rb_id, eventP,
Mac_rlc_xface->frame);
return 0;
}
break;
//-------------------------------
// RLC_RESET_AND_SUSPEND_STATE
//-------------------------------
case RLC_RESET_AND_SUSPEND_STATE:
switch (eventP) {
case RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_NULL_STATE_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_RESET_AND_SUSPEND_STATE -> RLC_NULL_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_NULL_STATE;
return 1;
break;
case RLC_AM_RECEIVE_RESET_ACK_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_RESET_AND_SUSPEND_STATE -> RLC_LOCAL_SUSPEND_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_LOCAL_SUSPEND_STATE;
return 1;
break;
case RLC_AM_RECEIVE_CRLC_RESUME_REQ_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_RESET_AND_SUSPEND_STATE -> RLC_RESET_PENDING_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_RESET_PENDING_STATE;
return 1;
break;
default:
msg ("[RLC_AM][RB %d][FSM] WARNING PROTOCOL ERROR - EVENT 0x%02X NOT EXPECTED FROM RLC_RESET_AND_SUSPEND_STATE frame %d\n", rlcP->rb_id, eventP,
Mac_rlc_xface->frame);
return 0;
}
break;
//-------------------------------
// RLC_LOCAL_SUSPEND_STATE
//-------------------------------
case RLC_LOCAL_SUSPEND_STATE:
switch (eventP) {
case RLC_AM_RECEIVE_CRLC_CONFIG_REQ_ENTER_NULL_STATE_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_LOCAL_SUSPEND_STATE -> RLC_NULL_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_NULL_STATE;
return 1;
break;
case RLC_AM_RECEIVE_CRLC_RESUME_REQ_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_LOCAL_SUSPEND_STATE -> RLC_DATA_TRANSFER_READY_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_DATA_TRANSFER_READY_STATE;
return 1;
break;
case RLC_AM_TRANSMIT_RESET_EVENT:
#ifdef DEBUG_RLC_AM_FSM
msg ("[RLC_AM][RB %d][FSM] RLC_LOCAL_SUSPEND_STATE -> RLC_RESET_AND_SUSPEND_STATE frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
#endif
rlcP->protocol_state = RLC_RESET_AND_SUSPEND_STATE;
return 1;
break;
default:
msg ("[RLC_AM][RB %d][FSM] WARNING PROTOCOL ERROR - EVENT 0x%02X NOT EXPECTED FROM RLC_LOCAL_SUSPEND_STATE frame %d\n", rlcP->rb_id, eventP,
Mac_rlc_xface->frame);
return 0;
}
break;
default:
msg ("[RLC_AM][RB %d][FSM] ERROR UNKNOWN STATE %d\n", rlcP->rb_id, rlcP->protocol_state);
return 0;
}
}
openair2/LAYER2/RLC/AM/rlc_am_fsm_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_fsm_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_FSM_PROTO_EXTERN_H__
# define __RLC_AM_FSM_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "platform_types.h"
# include "rlc_am_entity.h"
//-----------------------------------------------------------------------------
extern int rlc_am_fsm_notify_event (struct rlc_am_entity *rlcP, uint8_t eventP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_mac_status.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_mac_status.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_timers_proto_extern.h"
#include "rlc_am_discard_notif_proto_extern.h"
#include "rlc_am_reset_proto_extern.h"
#include "rlc_am_fsm_proto_extern.h"
#include "umts_timer_proto_extern.h"
//-----------------------------------------------------------------------------
void
rlc_am_status_report_from_mac (void* rlcP, uint16_t eventP)
{
//-----------------------------------------------------------------------------
struct rlc_am_entity* rlc = (struct rlc_am_entity*) rlcP;
//----------------------------------------
// STATUS
//----------------------------------------
if ((eventP & RLC_AM_FIRST_STATUS_PDU_TYPE) == RLC_AM_FIRST_STATUS_PDU_TYPE) {
#ifdef DEBUG_RLC_AM_MAC_STATUS
msg ("[RLC_AM %p][MAC_STATUS] EVENT RLC_AM_FIRST_STATUS_PDU_TYPE\n", rlcP);
#endif
return;
}
//----------------------------------------
// DISCARD
//----------------------------------------
if ((eventP & RLC_AM_MRW_STATUS_PDU_TYPE)) {
#ifdef DEBUG_RLC_AM_MAC_STATUS
msg ("[RLC_AM %p][MAC_STATUS] EVENT RLC_AM_MRW_STATUS_PDU_TYPE\n", rlcP);
#endif
// rearm the timer
if (!(rlc->timer_mrw) && (rlc->discard_procedures.head)) {
rlc->timer_mrw = umts_add_timer_list_up (&rlc->rlc_am_timer_list, rlc_am_discard_notify_mrw_ack_time_out, rlc,
rlc->discard_procedures.head, (uint32_t) rlc->timer_mrw_init, *rlc->frame_tick_milliseconds);
}
return;
}
//----------------------------------------
// RESET
//----------------------------------------
if ((eventP & RLC_AM_RESET_PDU_TYPE)) {
#ifdef DEBUG_RESET
msg ("[RLC_AM %p][MAC_STATUS] EVENT RLC_AM_RESET_PDU_TYPE SENT ARMING RESET TIMER %d frames frame %d\n", rlcP, (uint32_t) rlc->timer_rst_init,
*rlc->frame_tick_milliseconds);
#endif
rlc->timer_rst = umts_add_timer_list_up (&rlc->rlc_am_timer_list, rlc_am_reset_time_out, rlcP, NULL, (uint32_t) rlc->timer_rst_init,
*rlc->frame_tick_milliseconds);
return;
}
//----------------------------------------
// RESET ACK
//----------------------------------------
if ((eventP & RLC_AM_RESET_ACK_PDU_TYPE)) {
#ifdef DEBUG_RLC_AM_MAC_STATUS
msg ("[RLC_AM %p][MAC_STATUS] EVENT RLC_AM_RESET_ACK_PDU_TYPE\n", rlcP);
#endif
rlc_am_fsm_notify_event (rlc, RLC_AM_TRANSMIT_RESET_ACK_EVENT);
return;
}
}
openair2/LAYER2/RLC/AM/rlc_am_mac_status_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_mac_status_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_MAC_STATUS_PROTO_EXTERN_H__
# define __RLC_AM_MAC_STATUS_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "platform_types.h"
//-----------------------------------------------------------------------------
extern void rlc_am_status_report_from_mac (void *rlcP, uint16_t eventP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_mux.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_mux.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_constants.h"
#include "list.h"
#include "mem_block.h"
#include "rlc_am_retrans_proto_extern.h"
#include "rlc_am_mac_status_proto_extern.h"
#include "rlc_am_discard_tx_proto_extern.h"
#include "rlc_am_proto_extern.h"
#include "LAYER2/MAC/extern.h"
//#define DEBUG_MUX
//#define DEBUG_RLC_AM_POLL
#ifdef NODE_MT
/*
* mux PDUs from segmentation buffer and PDUs from retransmission buffer
* onto transmission buffer
*/
//-----------------------------------------------------------------------------
void
rlc_am_mux_ue (struct rlc_am_entity* rlcP, unsigned int traffic_typeP)
{
//-----------------------------------------------------------------------------
mem_block_t* pdu;
mem_block_t* sdu;
mem_block_t* copy_pdu;
struct rlc_am_pdu_header* rlc_header;
int pool_is_set;
int index;
int sdu_index;
unsigned int j, segmentation_returned_pdu;
unsigned int data_pdu_tx; // data pdu effectively transmitted
unsigned int tx_pdu;
int16_t nb_pdu_to_transmit_ch1;
int16_t nb_pdu_to_transmit_ch2;
# ifdef DEBUG_MUX
uint16_t id;
# endif
data_pdu_tx = 0;
nb_pdu_to_transmit_ch1 = rlcP->nb_pdu_requested_by_mac_on_ch1;
nb_pdu_to_transmit_ch2 = rlcP->nb_pdu_requested_by_mac_on_ch2;
// discard
if ((rlcP->sdu_discarded.head) && (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
rlc_am_process_sdu_discarded (rlcP);
}
/******************************************
* CONTROL PDU *
******************************************/
// from TS25.322 V4.2.0 p13
// In case two logical channels are configured in the uplink, AMD PDUs are transmitted
// on the first logical channel, and control PDUs are transmitted on the second logical
// channel.
if (rlcP->nb_logical_channels_per_rlc == 1) {
while ((rlcP->control.head) && (nb_pdu_to_transmit_ch1)) {
pdu = list_remove_head (&rlcP->control);
if ((traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
tx_pdu = 1;
} else {
if (((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type & (RLC_AM_RESET_PDU_TYPE | RLC_AM_RESET_ACK_PDU_TYPE)) {
tx_pdu = 1;
} else {
tx_pdu = 0;
}
}
if ((tx_pdu)) {
nb_pdu_to_transmit_ch1--;
// for polling
rlcP->vt_pdu++;
((struct mac_tb_req*) (pdu->data))->rlc_tb_type = ((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (pdu->data))->data_ptr = &pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)];
((struct mac_tb_req*) (pdu->data))->first_bit = 0;
((struct mac_tb_req*) (pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (pdu, &rlcP->pdus_to_mac_layer_ch1);
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d][MUX] TX CONTROL PDU CH1 VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
} else {
free_mem_block (pdu);
}
}
} else if (rlcP->nb_logical_channels_per_rlc == 2) {
while ((rlcP->control.head) && (nb_pdu_to_transmit_ch2)) {
pdu = list_remove_head (&rlcP->control);
if ((traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
tx_pdu = 1;
} else {
if (((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type & (RLC_AM_RESET_PDU_TYPE | RLC_AM_RESET_ACK_PDU_TYPE)) {
tx_pdu = 1;
} else {
tx_pdu = 0;
}
}
if ((tx_pdu)) {
nb_pdu_to_transmit_ch2--;
// for polling
rlcP->vt_pdu++;
((struct mac_tb_req*) (pdu->data))->rlc_tb_type = ((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (pdu->data))->data_ptr = &pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)];
((struct mac_tb_req*) (pdu->data))->first_bit = 0;
((struct mac_tb_req*) (pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (pdu, &rlcP->pdus_to_mac_layer_ch2);
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d][MUX] TX CONTROL PDU CH2 VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X \n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
} else {
free_mem_block (pdu);
}
}
}
if (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_DATA) {
/******************************************
* RETRANSMITED DATA PDU *
******************************************/
// priority is then made at retransmitted PDUs
while ((rlcP->retransmission_buffer_to_send.head) && (nb_pdu_to_transmit_ch1) && !(rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
// each retransmission may send RLC in RESET STATE if no discard is configured
copy_pdu = list2_remove_head (&rlcP->retransmission_buffer_to_send);
// unlink the pdu in retransmission buffer and its copy (mechanism avoiding multi-retransmission of the same
// pdu in the same queue)
pdu = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->copy;
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(copy_pdu);
# endif
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy = NULL;
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch1);
nb_pdu_to_transmit_ch1--;
data_pdu_tx++;
// for polling
if (rlcP->poll_pdu_trigger) {
rlcP->vt_pdu++;
if (rlcP->vt_pdu >= rlcP->poll_pdu_trigger) {
// set poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_pdu = 0;
} else {
// reset poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 =
(((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2) & ~RLC_AM_P_STATUS_REPORT_REQUESTED;
}
}
# ifdef DEBUG_MUX
id = (((uint16_t) (((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) |
((((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] RETRANSMIT DATA PDU %04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
}
/******************************************
* DATA PDU *
******************************************/
if (!(rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
segmentation_returned_pdu = 1;
while ((nb_pdu_to_transmit_ch1) && (rlcP->vt_s != rlcP->vt_ms) && (segmentation_returned_pdu) && !(rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
if ((pdu = rlcP->rlc_segment (rlcP))) {
rlc_header = (struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]);
// check polling
pool_is_set = 0;
if (rlcP->poll_pdu_trigger) {
rlcP->vt_pdu++;
// test every poll_PDU trigger
if (rlcP->vt_pdu >= rlcP->poll_pdu_trigger) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
rlc_header->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_pdu = 0;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY poll_pdu trigger\n", rlcP);
# endif
}
}
// test every poll_SDU trigger
if ((rlcP->poll_sdu_trigger) && (((struct rlc_am_tx_data_pdu_management*) (pdu->data))->last_pdu_of_sdu)) {
if (rlcP->vt_sdu >= rlcP->poll_sdu_trigger) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
rlc_header->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_sdu = 0;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY poll_sdu trigger\n", rlcP);
# endif
} else {
rlcP->vt_sdu += ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->last_pdu_of_sdu;
}
}
if (!pool_is_set) {
// test last pdu in transmission buffer trigger == last sdu in input buffer in this implementation of RLC AM
if ((rlcP->last_transmission_pdu_poll_trigger > 0) && (rlcP->nb_sdu == 0)) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
rlc_header->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY last pdu in tr buffer trigger\n", rlcP);
# endif
}
if (!pool_is_set) {
// test last pdu in retransmission buffer trigger
if ((rlcP->retransmission_buffer_to_send.head) && (rlcP->retransmission_buffer_to_send.head == rlcP->retransmission_buffer_to_send.tail)
&& (rlcP->last_retransmission_pdu_poll_trigger)) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
rlc_header->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY last pdu in retrans buffer trigger\n", rlcP);
# endif
}
if (!pool_is_set) {
// test window based trigger
if (rlcP->poll_window_trigger) {
j = (unsigned int) (((rlcP->vt_s + 4096) - rlcP->vt_a) % 4096) * 100 / rlcP->vt_ws;
if (j >= rlcP->poll_window_trigger) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
rlc_header->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p][POOL] POOL SET BY window based trigger j=%d\n", rlcP, j);
# endif
}
}
}
}
}
rlc_header->byte1 |= (rlcP->vt_s >> 5);
rlc_header->byte2 |= ((uint8_t) rlcP->vt_s << 3);
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sn = rlcP->vt_s;
insert_into_retransmission_buffer (rlcP, rlcP->vt_s % rlcP->recomputed_configured_tx_window_size, pdu);
// check if timer based discard configured
if ((rlcP->sdu_discard_mode & RLC_SDU_DISCARD_TIMER_BASED_EXPLICIT)) {
for (index = 0; index < ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->nb_sdu; index++) {
sdu_index = ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index];
sdu = rlcP->input_sdus[sdu_index];
// mark the sdu as invalid except if confirm requested
if (!((struct rlc_am_tx_sdu_management*) (sdu->data))->confirm) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index] = -1; // tag sdu as non valid
}
((struct rlc_am_tx_sdu_management*) (sdu->data))->nb_pdus_time += 1;
if ((((struct rlc_am_tx_sdu_management*) (sdu->data))->nb_pdus_time ==
((struct rlc_am_tx_sdu_management*) (sdu->data))->nb_pdus) &&
!(((struct rlc_am_tx_sdu_management*) (sdu->data))->confirm) && (((struct rlc_am_tx_sdu_management*) (sdu->data))->segmented)
) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index] = -1; // tag sdu as non valid
// we can remove the sdu if timer based discard and all pdus submitted to lower layers and no confirm running
free_mem_block (sdu);
rlcP->input_sdus[sdu_index] = NULL;
# ifdef DEBUG_RLC_AM_FREE_SDU
msg ("[RLC_AM][RB %d] MUX FREE_SDU INDEX %d\n", rlcP->rb_id, sdu_index);
# endif
} else {
((struct rlc_am_tx_sdu_management*) (sdu->data))->last_pdu_sn = rlcP->vt_s;
}
}
} else if ((rlcP->sdu_discard_mode & RLC_SDU_DISCARD_MAX_DAT_RETRANSMISSION)) {
for (index = 0; index < ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->nb_sdu; index++) {
// update the sn of the last transmitted pdu were this sdu was segmented
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index]]->data))->last_pdu_sn = rlcP->vt_s;
// register the sn of the pdus where the sdu was segmented
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index]]->data))->
pdus_index[((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[((struct rlc_am_tx_data_pdu_management*) (
pdu->data))->sdu[index]]->data))->nb_pdus_internal_use++] = rlcP->vt_s;
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d] MUX SDU INDEX %d LINK PDU SN 0x%04X\n", rlcP->rb_id, ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index], rlcP->vt_s);
# endif
}
}
rlcP->vt_s = (rlcP->vt_s + 1) & SN_12BITS_MASK;
copy_pdu = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (copy_pdu) {
memcpy (copy_pdu->data, pdu->data, rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation));
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(pdu);
# endif
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch1);
nb_pdu_to_transmit_ch1--;
data_pdu_tx++;
# ifdef DEBUG_MUX
id = (((uint16_t) (rlc_header->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) | ((rlc_header->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] TX DATA PDU 0x%04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
/* for (index = 0; index < 32 ; index++) {
msg("%02X.", pdu->data[index]);
}
msg("\n");
*/
# endif
} else {
msg ("[RLC_AM][RB %d][MUX] OUT OF MEMORY \n", rlcP->rb_id);
}
} else { // segmentation returned no PDU
segmentation_returned_pdu = 0;
}
}
}
// From 3GPP TS 25.322 V5.0.0 (2002-03)
// - if a poll has been triggered by either the poll triggers "Poll timer" or "Timer based" (see subclause 9.7.1);
// AND
// - if no AMD PDU is scheduled for transmission or retransmission:
// - if the value of "Configured_Tx_Window_Size" is larger than or equal to "2048":
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1.
// - otherwise if the "Configured_Tx_Window_Size" is less than "2048";
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1; or
// - select an AMD PDU that has not yet been acknowledged by the peer entity;
// - schedule the selected AMD PDU for retransmission (in order to transmit a poll).
// The Sender may also schedule an AMD PDU for retransmission even if none of the criteria above is fulfilled. In this case, the Sender may:
// - if the value of "Configured_Tx_Window_Size" is larger than or equal to "2048":
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1.
// - otherwise if the "Configured_Tx_Window_Size" is less than "2048":
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1; or
// - select an AMD PDU that has not yet been acknowledged by the peer entity;
// - schedule the selected AMD PDU for retransmission.
// TO DO : triggers "Poll timer" or "Timer based"
if (!(data_pdu_tx)) {
if (rlcP->configured_tx_window_size < 2048) {
rlc_am_get_not_acknowledged_pdu_optimized (rlcP);
} else if (rlcP->vt_s != rlcP->vt_a) {
rlc_am_get_not_acknowledged_pdu_optimized (rlcP);//rlc_am_get_not_acknowledged_pdu_vt_s_minus_1 (rlcP);
}
// each retransmission may send RLC in RESET STATE if no discard is configured
copy_pdu = list2_remove_head (&rlcP->retransmission_buffer_to_send);
if ((copy_pdu)) {
// unlink the pdu in retransmission buffer and its copy (mechanism avoiding multi-retransmission of the same
// pdu in the same queue)
pdu = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->copy;
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(copy_pdu);
# endif
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy = NULL;
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch1);
nb_pdu_to_transmit_ch1--;
data_pdu_tx++;
// for polling
rlcP->vt_pdu++;
// set poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
# ifdef DEBUG_MUX
id = (((uint16_t) (((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) |
((((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] RETRANSMIT DATA PDU 0x%04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
}
}
}
}
#endif
#ifdef NODE_RG
//#define DEBUG_MUX
/*
* mux PDUs from segmentation buffer and PDUs from retransmission buffer
* onto transmission buffer
*/
//-----------------------------------------------------------------------------
void
rlc_am_mux_rg (struct rlc_am_entity* rlcP, unsigned int traffic_typeP)
{
//-----------------------------------------------------------------------------
mem_block_t* pdu;
mem_block_t* sdu;
mem_block_t* copy_pdu = NULL;
struct rlc_am_pdu_header* rlc_header;
int pool_is_set;
int index;
int sdu_index;
unsigned int j, segmentation_returned_pdu;
unsigned int data_pdu_tx; // data pdu effectively transmitted
unsigned int tx_pdu;
static unsigned int last_scheduled;
int16_t nb_pdu_to_transmit_ch1;
int16_t nb_pdu_to_transmit_ch2;
# ifdef DEBUG_MUX
uint16_t id;
# endif
data_pdu_tx = 0;
nb_pdu_to_transmit_ch1 = rlcP->nb_pdu_requested_by_mac_on_ch1;
nb_pdu_to_transmit_ch2 = rlcP->nb_pdu_requested_by_mac_on_ch2;
// discard
if ((rlcP->sdu_discarded.head) && (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
rlc_am_process_sdu_discarded (rlcP);
}
// from TS25.322 V4.2.0 p13
// In case two logical channels are configured in the downlink, AMD and Control
// PDUs can be transmitted on any of the two logical channels.
/******************************************
* CONTROL PDU *
******************************************/
if (rlcP->nb_logical_channels_per_rlc == 1) {
while ((rlcP->control.head) && (nb_pdu_to_transmit_ch1)) {
pdu = list_remove_head (&rlcP->control);
if ((traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
tx_pdu = 1;
} else {
if (((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type & (RLC_AM_RESET_PDU_TYPE | RLC_AM_RESET_ACK_PDU_TYPE)) {
tx_pdu = 1;
} else {
tx_pdu = 0;
}
}
if ((tx_pdu)) {
nb_pdu_to_transmit_ch1--;
// for polling
rlcP->vt_pdu++;
((struct mac_tb_req*) (pdu->data))->rlc_tb_type = ((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (pdu->data))->data_ptr = &pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)];
((struct mac_tb_req*) (pdu->data))->first_bit = 0;
((struct mac_tb_req*) (pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (pdu, &rlcP->pdus_to_mac_layer_ch1);
rlcP->stat_tx_control_pdu += 1;
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d][MUX] TX CONTROL PDU CH1 VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
} else {
free_mem_block (pdu);
}
}
} else if (rlcP->nb_logical_channels_per_rlc == 2) {
while ((rlcP->control.head) && (nb_pdu_to_transmit_ch2)) {
pdu = list_remove_head (&rlcP->control);
if ((traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
tx_pdu = 1;
} else {
if (((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type & (RLC_AM_RESET_PDU_TYPE | RLC_AM_RESET_ACK_PDU_TYPE)) {
tx_pdu = 1;
} else {
tx_pdu = 0;
}
}
if ((tx_pdu)) {
nb_pdu_to_transmit_ch2--;
// for polling
rlcP->vt_pdu++;
((struct mac_tb_req*) (pdu->data))->rlc_tb_type = ((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (pdu->data))->data_ptr = &pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)];
((struct mac_tb_req*) (pdu->data))->first_bit = 0;
((struct mac_tb_req*) (pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (pdu, &rlcP->pdus_to_mac_layer_ch2);
rlcP->stat_tx_control_pdu += 1;
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d][MUX] TX CONTROL PDU CH2 VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
} else {
free_mem_block (pdu);
}
}
while ((rlcP->control.head) && (nb_pdu_to_transmit_ch1)) {
pdu = list_remove_head (&rlcP->control);
if ((traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_STATUS)) {
tx_pdu = 1;
} else {
if (((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type & (RLC_AM_RESET_PDU_TYPE | RLC_AM_RESET_ACK_PDU_TYPE)) {
tx_pdu = 1;
} else {
tx_pdu = 0;
}
}
if ((tx_pdu)) {
nb_pdu_to_transmit_ch1--;
// for polling
rlcP->vt_pdu++;
((struct mac_tb_req*) (pdu->data))->rlc_tb_type = ((struct rlc_am_tx_control_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (pdu->data))->data_ptr = &pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)];
((struct mac_tb_req*) (pdu->data))->first_bit = 0;
((struct mac_tb_req*) (pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (pdu, &rlcP->pdus_to_mac_layer_ch1);
rlcP->stat_tx_control_pdu += 1;
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d][MUX] TX CONTROL PDU CH1 VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
} else {
free_mem_block (pdu);
}
}
}
if (traffic_typeP & RLC_AM_TRAFFIC_ALLOWED_FOR_DATA) {
/******************************************
* RETRANSMITED DATA PDU *
******************************************/
while ((rlcP->retransmission_buffer_to_send.head) && (nb_pdu_to_transmit_ch1) && !(rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
// each retransmission may send RLC in RESET STATE if no discard is configured
copy_pdu = list2_remove_head (&rlcP->retransmission_buffer_to_send);
// unlink the pdu in retransmission buffer and its copy (mechanism avoiding multi-retransmission of the same
// pdu in the same queue)
pdu = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->copy;
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(copy_pdu);
# endif
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy = NULL;
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch1);
rlcP->stat_tx_retransmit_pdu += 1;
nb_pdu_to_transmit_ch1--;
data_pdu_tx++;
// for polling
if (rlcP->poll_pdu_trigger) {
rlcP->vt_pdu++;
if (rlcP->vt_pdu >= rlcP->poll_pdu_trigger) {
// set poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_pdu = 0;
} else {
// reset poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 =
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & ~RLC_AM_P_STATUS_REPORT_REQUESTED;
}
}
# ifdef DEBUG_MUX
id = (((uint16_t) (((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) |
((((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] RETRANSMIT DATA PDU %04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
}
while ((rlcP->retransmission_buffer_to_send.head) && (nb_pdu_to_transmit_ch2) && !(rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
// each retransmission may send RLC in RESET STATE if no discard is configured
copy_pdu = list2_remove_head (&rlcP->retransmission_buffer_to_send);
// unlink the pdu in retransmission buffer and its copy (mechanism avoiding multi-retransmission of the same
// pdu in the same queue)
pdu = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->copy;
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(copy_pdu);
# endif
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy = NULL;
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch2);
rlcP->stat_tx_retransmit_pdu += 1;
nb_pdu_to_transmit_ch2--;
data_pdu_tx++;
// for polling
if (rlcP->poll_pdu_trigger) {
rlcP->vt_pdu++;
if (rlcP->vt_pdu >= rlcP->poll_pdu_trigger) {
// set poll bit
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY poll_pdu trigger RETRANS PDU\n", rlcP);
# endif
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_pdu = 0;
} else {
// reset poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 =
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & ~RLC_AM_P_STATUS_REPORT_REQUESTED;
}
}
# ifdef DEBUG_MUX
id = (((uint16_t) (((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) |
((((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] RETRANSMIT DATA PDU 0x%04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
}
/******************************************
* DATA PDU *
******************************************/
if (!(rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
segmentation_returned_pdu = 1;
while (((nb_pdu_to_transmit_ch1) || (nb_pdu_to_transmit_ch2)) && (rlcP->vt_s != rlcP->vt_ms) && (segmentation_returned_pdu)) {
if ((pdu = rlcP->rlc_segment (rlcP))) {
rlc_header = (struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]);
// check polling
pool_is_set = 0;
if (rlcP->poll_pdu_trigger) {
rlcP->vt_pdu++;
// test every poll_PDU trigger
if (rlcP->vt_pdu >= rlcP->poll_pdu_trigger) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_pdu = 0;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY poll_pdu trigger\n", rlcP);
# endif
}
}
// test every poll_SDU trigger
if ((rlcP->poll_sdu_trigger) && (((struct rlc_am_tx_data_pdu_management*) (pdu->data))->last_pdu_of_sdu)) {
if (rlcP->vt_sdu >= rlcP->poll_sdu_trigger) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
rlcP->vt_sdu = 0;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY poll_sdu trigger\n", rlcP);
# endif
} else {
rlcP->vt_sdu += ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->last_pdu_of_sdu;
}
}
if (!pool_is_set) {
// test last pdu in transmission buffer trigger == last sdu in input buffer in this implementation of RLC AM
if ((rlcP->last_transmission_pdu_poll_trigger > 0) && (rlcP->nb_sdu == 0)) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY last pdu in tr buffer trigger\n", rlcP);
# endif
}
if (!pool_is_set) {
// test last pdu in retransmission buffer trigger
if ((rlcP->retransmission_buffer_to_send.head) && (rlcP->retransmission_buffer_to_send.head == rlcP->retransmission_buffer_to_send.tail)
&& (rlcP->last_retransmission_pdu_poll_trigger)) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY last pdu in retrans buffer trigger\n", rlcP);
# endif
}
if (!pool_is_set) {
// test window based trigger
if (rlcP->poll_window_trigger) {
j = (unsigned int) (((rlcP->vt_s + 4096) - rlcP->vt_a) % 4096) * 100 / rlcP->vt_ws;
if (j >= rlcP->poll_window_trigger) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_DATA_POLL_PDU_TYPE;
((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
pool_is_set = 1;
# ifdef DEBUG_RLC_AM_POLL
msg ("[RLC_AM %p] POOL SET BY window based trigger J=%d\n", rlcP, j);
# endif
}
}
}
}
}
rlc_header->byte1 |= (rlcP->vt_s >> 5);
rlc_header->byte2 |= ((uint8_t) rlcP->vt_s << 3);
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sn = rlcP->vt_s;
insert_into_retransmission_buffer (rlcP, rlcP->vt_s % rlcP->recomputed_configured_tx_window_size, pdu);
// check if timer based discard configured
if ((rlcP->sdu_discard_mode & RLC_SDU_DISCARD_TIMER_BASED_EXPLICIT)) {
for (index = 0; index < ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->nb_sdu; index++) {
sdu_index = ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index];
sdu = rlcP->input_sdus[sdu_index];
// mark the sdu as invalid except if confirm requested
if (!((struct rlc_am_tx_sdu_management*) (sdu->data))->confirm) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index] = -1; // tag sdu as non valid
}
((struct rlc_am_tx_sdu_management*) (sdu->data))->nb_pdus_time += 1;
if ((((struct rlc_am_tx_sdu_management*) (sdu->data))->nb_pdus_time ==
((struct rlc_am_tx_sdu_management*) (sdu->data))->nb_pdus) &&
!(((struct rlc_am_tx_sdu_management*) (sdu->data))->confirm) && (((struct rlc_am_tx_sdu_management*) (sdu->data))->segmented)
) {
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index] = -1; // tag sdu as non valid
// we can remove the sdu if timer based discard and all pdus submitted to lower layers and no confirm running
free_mem_block (sdu);
rlcP->input_sdus[sdu_index] = NULL;
# ifdef DEBUG_RLC_AM_FREE_SDU
msg ("[RLC_AM][RB %d] MUX FREE_SDU INDEX %d\n", rlcP->rb_id, sdu_index);
# endif
} else {
((struct rlc_am_tx_sdu_management*) (sdu->data))->last_pdu_sn = rlcP->vt_s;
}
}
} else if ((rlcP->sdu_discard_mode & RLC_SDU_DISCARD_MAX_DAT_RETRANSMISSION)) {
for (index = 0; index < ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->nb_sdu; index++) {
// update the sn of the last transmitted pdu were this sdu was segmented
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index]]->data))->last_pdu_sn = rlcP->vt_s;
// register the sn of the pdus where the sdu was segmented
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index]]->data))->
pdus_index[((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[((struct rlc_am_tx_data_pdu_management*) (
pdu->data))->sdu[index]]->data))->nb_pdus_internal_use++] = rlcP->vt_s;
# ifdef DEBUG_MUX
msg ("[RLC_AM][RB %d] MUX SDU INDEX %d LINK PDU SN 0x%04X\n", rlcP->rb_id, ((struct rlc_am_tx_data_pdu_management*) (pdu->data))->sdu[index], rlcP->vt_s);
# endif
}
}
rlcP->vt_s = (rlcP->vt_s + 1) & SN_12BITS_MASK;
copy_pdu = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (copy_pdu) {
memcpy (copy_pdu->data, pdu->data, rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation));
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(copy_pdu);
# endif
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
if ((nb_pdu_to_transmit_ch1)) {
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch1);
rlcP->stat_tx_data_pdu += 1;
nb_pdu_to_transmit_ch1--;
} else if ((nb_pdu_to_transmit_ch2)) {
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch2);
rlcP->stat_tx_data_pdu += 1;
nb_pdu_to_transmit_ch2--;
}
data_pdu_tx++;
# ifdef DEBUG_MUX
id = (((uint16_t) (((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) |
((((struct rlc_am_pdu_header*) (&pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] TX DATA PDU 0x%04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
/* for (index = 0; index < 32 ; index++) {
msg("%02X.", pdu->data[index]);
}
msg("\n");
*/
# endif
} else {
msg ("[RLC_AM][RB %d][MUX] OUT OF MEMORY \n", rlcP->rb_id);
}
} else { // segmentation returned no PDU
segmentation_returned_pdu = 0;
}
}
}
// From 3GPP TS 25.322 V5.0.0 (2001-09)
// - if a poll has been triggered by either the poll triggers "Poll timer" or "Timer based" (see subclause 9.7.1);
// AND
// - if no AMD PDU is scheduled for transmission or retransmission:
// - if the value of "Configured_Tx_Window_Size" is larger than or equal to "2048":
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1.
// - otherwise if the "Configured_Tx_Window_Size" is less than "2048";
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1; or
// - select an AMD PDU that has not yet been acknowledged by the peer entity;
// - schedule the selected AMD PDU for retransmission (in order to transmit a poll).
// The Sender may also schedule an AMD PDU for retransmission even if none of the criteria above is fulfilled. In this case, the Sender may:
// - if the value of "Configured_Tx_Window_Size" is larger than or equal to "2048":
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1.
// - otherwise if the "Configured_Tx_Window_Size" is less than "2048":
// - select the AMD PDU with "Sequence Number" equal to VT(S)-1; or
// - select an AMD PDU that has not yet been acknowledged by the peer entity;
// - schedule the selected AMD PDU for retransmission.
// TO DO : triggers "Poll timer" or "Timer based"
if (!(data_pdu_tx)) {
// this variable last_scheduled is used because a RLC may be scheduled
// when several DSCH are configured in the RG
if ((last_scheduled != (unsigned int) Mac_rlc_xface->frame) && (((unsigned int) Mac_rlc_xface->frame) % 48 == 0) ) {
if (rlcP->configured_tx_window_size < 2048) {
// rlc_am_get_not_acknowledged_pdu(rlcP);
rlc_am_get_not_acknowledged_pdu_optimized (rlcP);
//rlc_am_get_not_acknowledged_pdu_vt_s_minus_1 (rlcP); // LG JUST FOR TEST
} else if (rlcP->vt_s != rlcP->vt_a) {
rlc_am_get_not_acknowledged_pdu_optimized (rlcP);//rlc_am_get_not_acknowledged_pdu_vt_s_minus_1 (rlcP);
}
}
last_scheduled = (unsigned int) Mac_rlc_xface->frame;
// each retransmission may send RLC in RESET STATE if no discard is configured
copy_pdu = list2_remove_head (&rlcP->retransmission_buffer_to_send);
if ((copy_pdu)) {
// unlink the pdu in retransmission buffer and its copy (mechanism avoiding multi-retransmission of the same
// pdu in the same queue)
pdu = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->copy;
# ifdef DEBUG_MUX
rlc_am_display_data_pdu7(copy_pdu);
# endif
((struct rlc_am_tx_data_pdu_management*) (pdu->data))->copy = NULL;
((struct mac_tb_req*) (copy_pdu->data))->rlc_tb_type = ((struct rlc_am_tx_data_pdu_management*) (copy_pdu->data))->rlc_tb_type;
((struct mac_tb_req*) (copy_pdu->data))->rlc = rlcP;
((struct mac_tb_req*) (copy_pdu->data))->rlc_callback = rlc_am_status_report_from_mac;
((struct mac_tb_req*) (copy_pdu->data))->data_ptr = &copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
((struct mac_tb_req*) (copy_pdu->data))->first_bit = 0;
((struct mac_tb_req*) (copy_pdu->data))->tb_size_in_bits = rlcP->pdu_size << 3;
list_add_tail_eurecom (copy_pdu, &rlcP->pdus_to_mac_layer_ch1);
rlcP->stat_tx_retransmit_pdu += 1;
nb_pdu_to_transmit_ch1--;
data_pdu_tx++;
// for polling
rlcP->vt_pdu++;
// set poll bit
((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 |= RLC_AM_P_STATUS_REPORT_REQUESTED;
# ifdef DEBUG_MUX
id = (((uint16_t) (((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) |
((((struct rlc_am_pdu_header*) (&copy_pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)]))->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
msg ("[RLC_AM][RB %d][MUX] RETRANSMIT DATA PDU 0x%04X VT(A) 0x%03X VT(S) 0x%03X VT(MS) 0x%03X VR(R) 0x%03X VR(MR) 0x%03X\n",
rlcP->rb_id, id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vr_r, rlcP->vr_mr);
# endif
}
}
}
}
#endif
openair2/LAYER2/RLC/AM/rlc_am_mux_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_mux_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_MUX_PROTO_EXTERN_H__
# define __RLC_AM_MUX_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "rlc_am_constants.h"
//-----------------------------------------------------------------------------
# ifdef NODE_MT
extern void rlc_am_mux_ue (struct rlc_am_entity *rlcP, unsigned int traffic_typeP);
# endif
# ifdef NODE_RG
extern void rlc_am_mux_rg (struct rlc_am_entity *rlcP, unsigned int traffic_typeP);
# endif
# endif
openair2/LAYER2/RLC/AM/rlc_am_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_PROTO_EXTERN_H__
# define __RLC_AM_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "platform_types.h"
# include "platform_constants.h"
# include "list.h"
# include "rlc_am_entity.h"
# include "mac_primitives.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern void display_protocol_vars_rlc_am (struct rlc_am_entity *rlcP);
extern uint32_t rlc_am_get_buffer_occupancy (struct rlc_am_entity *rlcP, uint8_t logical_channelsP);
extern void init_rlc_am (struct rlc_am_entity *rlcP);
extern void *rlc_am_tx (void *argP);
extern void rlc_am_rx (void *argP, struct mac_data_ind data_indP);
extern void *init_code_rlc_am (void *t);
extern void send_rlc_am_control_primitive (struct rlc_am_entity *rlcP, module_id_t module_idP, mem_block_t * cprimitiveP);
extern void rlc_am_send_mac_data_request (void *macP, uint8_t logical_channel_identityP, list_t * pduP);
extern struct mac_status_resp rlc_am_mac_status_indication (void *rlcP, uint16_t no_tbP, uint16_t tb_sizeP, struct mac_status_ind tx_statusP);
extern struct mac_status_resp rlc_am_mac_status_indication_on_first_channel (void *rlcP, uint16_t no_tbP, uint16_t tb_sizeP, struct mac_status_ind tx_statusP);
extern struct mac_status_resp rlc_am_mac_status_indication_on_second_channel (void *rlcP, uint16_t no_tbP, uint16_t tb_sizeP, struct mac_status_ind tx_statusP);
extern struct mac_data_req rlc_am_mac_data_request (void *rlcP);
extern struct mac_data_req rlc_am_mac_data_request_on_first_channel (void *rlcP);
extern struct mac_data_req rlc_am_mac_data_request_on_second_channel (void *rlcP);
extern void rlc_am_mac_data_indication (void *rlcP, struct mac_data_ind data_indP);
extern void rlc_am_data_req (void *rlcP, mem_block_t * sduP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_reassembly.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_reassembly.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#define RLC_AM_C
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc.h"
#include "rlc_am_entity.h"
#include "rlc_am_structs.h"
#include "rlc_primitives.h"
#include "rlc_am_constants.h"
#include "list.h"
#include "LAYER2/MAC/extern.h"
#define DEBUG_RLC_AM_SEND_SDU
//#define DEBUG_REASSEMBLY
//#define DEBUG_RLC_AM_DISPLAY_ASCII_DATA
//-----------------------------------------------------------------------------
void
reassembly (uint8_t* srcP, uint16_t lengthP, struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
int sdu_max_size_allowed;
#ifdef DEBUG_RLC_AM_DISPLAY_ASCII_DATA
int index;
#endif
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] reassembly() %d bytes\n", rlcP->rb_id, lengthP);
#endif
if ((rlcP->data_plane)) {
sdu_max_size_allowed = RLC_SDU_MAX_SIZE_DATA_PLANE;
} else {
sdu_max_size_allowed = RLC_SDU_MAX_SIZE_CONTROL_PLANE;
}
if (rlcP->output_sdu_in_construction == NULL) {
rlcP->output_sdu_in_construction = get_free_mem_block (sdu_max_size_allowed);
rlcP->output_sdu_size_to_write = 0;
}
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] reassembly() %d bytes sdu_max_size allowed %d\n", rlcP->rb_id, lengthP, sdu_max_size_allowed);
#endif
if ((rlcP->output_sdu_in_construction)) {
#ifdef DEBUG_RLC_AM_DISPLAY_ASCII_DATA
msg ("[RLC_AM][RB %d][REASSEMBLY] DATA :", rlcP->rb_id);
for (index = 0; index < lengthP; index++) {
//msg ("%c", srcP[index]);
msg ("%02X.", srcP[index]);
}
msg ("\n");
#endif
// OOOPS
if ((lengthP + rlcP->output_sdu_size_to_write) <= sdu_max_size_allowed) {
memcpy (&rlcP->output_sdu_in_construction->data[rlcP->output_sdu_size_to_write], srcP, lengthP);
rlcP->output_sdu_size_to_write += lengthP;
} else {
rlcP->output_sdu_size_to_write = 0;
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM %p][REASSEMBLY] ERROR SDU IN CONSTRUCTION TOO BIG %d Bytes MAX SIZE ALLOWED %d\n", rlcP, lengthP + rlcP->output_sdu_size_to_write,
sdu_max_size_allowed);
#endif
}
}
#ifdef DEBUG_REASSEMBLY
else {
msg ("[RLC_AM %p][REASSEMBLY] ERROR OUTPUT SDU IS NULL\n", rlcP);
}
#endif
}
//-----------------------------------------------------------------------------
void
send_sdu (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
if ((rlcP->output_sdu_in_construction) && (rlcP->output_sdu_size_to_write)) {
#ifdef DEBUG_RLC_AM_SEND_SDU
msg ("[RLC_AM][RB %d][SEND_SDU] send_SDU() %d bytes\n", rlcP->rb_id, rlcP->output_sdu_size_to_write);
#endif
#ifdef BENCH_QOS_L2
fprintf (bench_l2, "[SDU DELIVERY] FRAME %d SIZE %d RB %d RLC-AM %p\n", Mac_rlc_xface->frame, rlcP->output_sdu_size_to_write, rlcP->rb_id, rlcP);
#endif
rlc_data_ind (rlcP->module_id, rlcP->rb_id, rlcP->output_sdu_size_to_write, rlcP->output_sdu_in_construction, rlcP->data_plane);
rlcP->output_sdu_in_construction = NULL;
rlcP->output_sdu_size_to_write = 0;
rlcP->stat_rx_sdu += 1;
}
}
openair2/LAYER2/RLC/AM/rlc_am_reassembly_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_reassembly_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_REASSEMBLY_PROTO_EXTERN_H__
# define __RLC_AM_REASSEMBLY_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
//-----------------------------------------------------------------------------
extern void reassembly (uint8_t * srcP, uint16_t lengthP, struct rlc_am_entity *rlcP);
extern void send_sdu (struct rlc_am_entity *rlcP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_receiver.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_receiver.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_def.h"
#include "rlc_am_structs.h"
#include "rlc_am_constants.h"
#include "rlc_am_reassembly_proto_extern.h"
#include "rlc_am_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "mem_block.h"
//#define DEBUG_RECEIVER_BUFFER
//#define DEBUG_REASSEMBLY
//#define DEBUG_STATUS
//-----------------------------------------------------------------------------
void receiver_retransmission_management (struct rlc_am_entity* rlcP, mem_block_t* pduP, struct rlc_am_pdu_header* rlc_headerP);
void free_receiver_buffer (struct rlc_am_entity* rlcP, uint16_t indexP);
void insert_into_receiver_buffer (struct rlc_am_entity* rlcP, uint16_t indexP, mem_block_t* pduP);
void process_receiver_buffer_15 (struct rlc_am_entity* rlcP);
void process_receiver_buffer_7 (struct rlc_am_entity* rlcP);
//-----------------------------------------------------------------------------
void
receiver_retransmission_management (struct rlc_am_entity* rlcP, mem_block_t* pduP, struct rlc_am_pdu_header* rlc_headerP)
{
//-----------------------------------------------------------------------------
uint16_t id;
uint16_t id_index;
/* From TS25.3222 V5.0.0
Upon reception of an AMD PDU, the Receiver shall:
- update VR(R), VR(H) and VR(MR) state variables for each received AMD PDU (see clause 9.4);
- if a received AMD PDU includes a "Polling bit" set to "1", or "Missing PDU Indicator" is configured and the
Receiver detects that a PDU is missing:
- initiate the STATUS PDU transfer procedure;
- reassemble the received AMD PDUs into RLC SDUs;
- if "In-Sequence Delivery" is configured:
- deliver the RLC SDUs in-sequence (i.e. in the same order as the RLC SDUs were originally transmitted by
the peer entity) to upper layers through the AM-SAP.
- otherwise: (NOT IMPLEMENTED)
- deliver the RLC SDUs in arbitrary order to upper layers through the AM-SAP. */
#ifdef DEBUG_RECEIVER_BUFFER
msg("[RLC_AM][DEBUG] receiver_retransmission_management() received PDU %p\n", pduP);
display_protocol_vars_rlc_am(rlcP);
#endif
id = (((uint16_t) (rlc_headerP->byte1 & RLC_AM_SN_1ST_PART_MASK)) << 5) | ((rlc_headerP->byte2 & RLC_AM_SN_2ND_PART_MASK) >> 3);
// general case
((struct rlc_am_rx_pdu_management*) (pduP->data))->sn = id;
id_index = id % rlcP->recomputed_configured_rx_window_size;
#ifdef DEBUG_RECEIVER_BUFFER
msg("[RLC][RB %d][DEBUG] receiver_retransmission_management() received PDU %04X :\n", rlcP->rb_id, id);
//display_protocol_vars_rlc_am(rlcP);
#endif
// test poll bit for status pdu transmission;
if ((rlc_headerP->byte2 & RLC_AM_P_STATUS_REPORT_MASK) == RLC_AM_P_STATUS_REPORT_REQUESTED) {
rlcP->send_status_pdu_requested = 1;
#ifdef DEBUG_STATUS
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] STATUS REQUESTED BY PEER\n", rlcP->rb_id);
#endif
}
if (id == rlcP->vr_r) {
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p VR(R)=0x%04X id_index=0x%02X VR(H)=0x%04X\n", rlcP->rb_id, pduP, rlcP->vr_r, id_index, rlcP->vr_h);
#endif
insert_into_receiver_buffer (rlcP, id_index, pduP);
// update vr_h;
if (rlcP->vr_h == id) {
rlcP->vr_h = (id + 1) & SN_12BITS_MASK;
}
adjust_vr_r_mr (rlcP);
} else {
rlcP->send_status_pdu_requested = 1;
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn=0x%04X id_index=0x%02X VR(R)=0x%04X VR(H)=0x%04X WILL SEND STATUS\n", rlcP->rb_id, pduP, id, id_index,
rlcP->vr_r, rlcP->vr_h);
#endif
//------------------------------------;
// CASE VR(R)<VR(H)<VR(MR);
//------------------------------------;
if ((rlcP->vr_r <= rlcP->vr_h) && (rlcP->vr_h <= rlcP->vr_mr) && (id < rlcP->vr_mr) && (id > rlcP->vr_r)) {
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn 0x%04X IN WINDOW\n", rlcP->rb_id, pduP, id);
#endif
insert_into_receiver_buffer (rlcP, id_index, pduP);
// CASE VR(R)<VR(H)<id<VR(MR);
if (id >= rlcP->vr_h) {
rlcP->vr_h = (id + 1) & SN_12BITS_MASK;
}
//------------------------------------;
// CASE id<VR(MR)<VR(R)<VR(H);
//------------------------------------;
// CASE VR(MR)<VR(R)<VR(H)<id;
} else if (((rlcP->vr_mr < rlcP->vr_r) && (rlcP->vr_h >= rlcP->vr_r) && (id < rlcP->vr_mr)) || ((rlcP->vr_mr < rlcP->vr_r) && (rlcP->vr_h >= rlcP->vr_r)
&& (id > rlcP->vr_r))) {
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn 0x%04X IN REVERSED WINDOW\n", rlcP->rb_id, pduP, id);
#endif
insert_into_receiver_buffer (rlcP, id_index, pduP);
if ((id >= rlcP->vr_h) || (id < rlcP->vr_mr)) {
rlcP->vr_h = (id + 1) & SN_12BITS_MASK;
}
//------------------------------------;
// CASE VR(H)<VR(MR)<VR(R);
//------------------------------------;
} else if ((rlcP->vr_h <= rlcP->vr_mr) && (rlcP->vr_mr < rlcP->vr_r)) {
if (id < rlcP->vr_mr) {
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn 0x%04X IN REVERSED WINDOW\n", rlcP->rb_id, pduP, id);
#endif
insert_into_receiver_buffer (rlcP, id_index, pduP);
if (id >= rlcP->vr_h) {
rlcP->vr_h = (id + 1) & SN_12BITS_MASK;
}
} else if (id > rlcP->vr_r) {
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn 0x%04X IN REVERSED WINDOW\n", rlcP->rb_id, pduP, id);
#endif
insert_into_receiver_buffer (rlcP, id_index, pduP);
} else {
// discard this PDU;
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn 0x%04X OUT OF WINDOW\n", rlcP->rb_id, pduP, id);
#endif
rlcP->stat_rx_data_pdu_out_of_window += 1;
free_mem_block (pduP);
}
//------------------------------------;
// REJECT;
//------------------------------------;
} else {
// discard this PDU;
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] RECEIVED %p sn 0x%04X OUT OF WINDOW\n", rlcP->rb_id, pduP, id);
#endif
rlcP->stat_rx_data_pdu_out_of_window += 1;
free_mem_block (pduP);
}
}
}
//-----------------------------------------------------------------------------
void
free_receiver_buffer (struct rlc_am_entity* rlcP, uint16_t indexP)
{
//-----------------------------------------------------------------------------
if (indexP < rlcP->recomputed_configured_rx_window_size) {
if (rlcP->receiver_buffer[indexP]) {
#ifdef DEBUG_FREE_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] FREE PDU %p index 0x%4X\n", rlcP->rb_id, rlcP->receiver_buffer[indexP], indexP);
#endif
free_mem_block (rlcP->receiver_buffer[indexP]);
rlcP->receiver_buffer[indexP] = NULL;
}
return;
}
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] ERROR free_receiver_buffer() invalid index in array 0x%2X\n", rlcP->rb_id, indexP);
}
//-----------------------------------------------------------------------------
void
insert_into_receiver_buffer (struct rlc_am_entity* rlcP, uint16_t indexP, mem_block_t* pduP)
{
//-----------------------------------------------------------------------------
if (pduP) {
if (indexP < rlcP->recomputed_configured_rx_window_size) {
#ifdef DEBUG_RECEIVER_BUFFER
if (rlcP->receiver_buffer[indexP] != NULL) {
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] ERROR insert_into_receiver_buffer() location is not NULL, index in array = 0x%2X\n", rlcP->rb_id, indexP);
display_protocol_vars_rlc_am (rlcP);
}
#endif
// last received is good
if (rlcP->receiver_buffer[indexP] != NULL) {
free_mem_block (rlcP->receiver_buffer[indexP]);
}
rlcP->receiver_buffer[indexP] = pduP;
return;
}
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] ERROR insert_into_receiver_buffer() invalid index in array 0x%2X\n", rlcP->rb_id, indexP);
return;
}
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] ERROR insert_into_receiver_buffer() pdu is NULL index 0x%2X\n", rlcP->rb_id, indexP);
}
//-----------------------------------------------------------------------------
void
process_receiver_buffer_15 (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
struct rlc_am_pdu_header* rlc_header;
mem_block_t* pdu;
uint16_t vr_r;
uint16_t working_sn;
uint16_t working_sn_index; // index in buffer
uint8_t* data_pdu;
uint16_t li[RLC_AM_SEGMENT_NB_MAX_LI_PER_PDU];
uint16_t remaining_data_size;
uint8_t nb_li;
uint8_t li_index;
uint8_t li_start_index;
uint8_t reassembly_after_discard;
// should start reassembly with sn working_sn
working_sn = (rlcP->last_reassemblied_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
vr_r = rlcP->vr_r;
reassembly_after_discard = 0;
while (rlcP->receiver_buffer[working_sn_index]) {
pdu = rlcP->receiver_buffer[working_sn_index];
nb_li = 0;
li_index = 0;
rlc_header = (struct rlc_am_pdu_header*) (((struct rlc_am_rx_pdu_management*) (pdu->data))->first_byte);
if ((rlcP->discard_reassembly_start_sn == ((struct rlc_am_rx_pdu_management*) (pdu->data))->sn)) {
rlcP->output_sdu_size_to_write = 0;
reassembly_after_discard = 1; // keep trace of entering in this block
if (!(rlc_header->byte2 & RLC_HE_MASK) == RLC_HE_SUCC_BYTE_CONTAINS_DATA) {
while ((li[nb_li] = ((((uint16_t) rlc_header->li_data_7[nb_li << 1]) << 8) + rlc_header->li_data_7[(nb_li << 1) + 1])) & RLC_E_NEXT_FIELD_IS_LI_E) {
li[nb_li] = li[nb_li] & (~(uint16_t) RLC_E_NEXT_FIELD_IS_LI_E);
nb_li++;
}
nb_li++; // count the first li
}
// this variable may be changed by the reception of a mrw sufi
//li_start_index = rlcP->discard_reassembly_after_li + 1; // reassembly will start at this index
li_start_index = rlcP->discard_reassembly_after_li; // reassembly will start at this index
// after reception of sufi mrw the starting index for li will be 0
rlcP->discard_reassembly_after_li = RLC_AM_DISCARD_REASSEMBLY_AT_LI_INDEX_0; // =-1
remaining_data_size = rlcP->pdu_size - 2 - (nb_li << 1);
data_pdu = (uint8_t*) (&rlc_header->li_data_7[nb_li << 1]);
while (li_index < nb_li) {
switch (li[li_index]) {
case RLC_LI_LAST_PDU_EXACTLY_FILLED:
if (li_index >= li_start_index) {
send_sdu (rlcP);
}
break;
case RLC_LI_LAST_PDU_ONE_BYTE_SHORT:
if (li_index >= li_start_index) {
rlcP->output_sdu_size_to_write -= 1;
send_sdu (rlcP);
}
break;
case RLC_LI_PDU_PIGGY_BACKED_STATUS: // ignore
case RLC_LI_PDU_PADDING:
remaining_data_size = 0;
break;
default: // li is length
remaining_data_size = remaining_data_size - (li[li_index] >> 1);
if (li_index >= li_start_index) {
reassembly (data_pdu, (li[li_index] >> 1), rlcP);
send_sdu (rlcP);
}
data_pdu = (uint8_t*) ((uint32_t) data_pdu + (li[li_index] >> 1));
}
li_index++;
}
if ((remaining_data_size)) {
reassembly (data_pdu, remaining_data_size, rlcP);
remaining_data_size = 0;
}
free_receiver_buffer (rlcP, working_sn_index);
rlcP->discard_reassembly_start_sn = RLC_AM_SN_INVALID;
rlcP->last_reassemblied_sn = working_sn;
working_sn = (rlcP->last_reassemblied_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
// patch to make the protocol working
// return 1 if sn1 > sn2
// return 0 if sn1 = sn2
// return -1 if sn1 < sn2
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, rlcP->vr_r, working_sn) < 0) {
rlcP->vr_r = working_sn;
rlcP->vr_mr = (rlcP->vr_r + rlcP->configured_rx_window_size - 1) & SN_12BITS_MASK;
}
} else {
// exploit HE field info
if ((rlc_header->byte2 & RLC_HE_MASK) == RLC_HE_SUCC_BYTE_CONTAINS_DATA) {
reassembly ((uint8_t*) (rlc_header->li_data_7), rlcP->pdu_size - 2, rlcP);
} else {
while ((li[nb_li] = ((((uint16_t) rlc_header->li_data_7[nb_li << 1]) << 8) + rlc_header->li_data_7[(nb_li << 1) + 1])) & RLC_E_NEXT_FIELD_IS_LI_E) {
//while ((li[nb_li] = (rlc_header->li.li_data_15[nb_li].optional)) & RLC_E_NEXT_FIELD_IS_LI_E) {
li[nb_li] = li[nb_li] & (~(uint16_t) RLC_E_NEXT_FIELD_IS_LI_E);
nb_li++;
}
nb_li++;
remaining_data_size = rlcP->pdu_size - 2 - (nb_li << 1);
data_pdu = (uint8_t*) (&rlc_header->li_data_7[nb_li << 1]);
while (li_index < nb_li) {
switch (li[li_index]) {
case RLC_LI_LAST_PDU_EXACTLY_FILLED:
send_sdu (rlcP);
break;
case RLC_LI_LAST_PDU_ONE_BYTE_SHORT:
rlcP->output_sdu_size_to_write -= 1;
send_sdu (rlcP);
break;
case RLC_LI_PDU_PIGGY_BACKED_STATUS: // ignore
case RLC_LI_PDU_PADDING:
remaining_data_size = 0;
break;
default: // li is length
remaining_data_size = remaining_data_size - (li[li_index] >> 1);
reassembly (data_pdu, (li[li_index] >> 1), rlcP);
data_pdu = (uint8_t*) ((uint32_t) data_pdu + (li[li_index] >> 1));
send_sdu (rlcP);
}
li_index++;
}
if ((remaining_data_size)) {
reassembly (data_pdu, remaining_data_size, rlcP);
remaining_data_size = 0;
}
}
free_receiver_buffer (rlcP, working_sn_index);
rlcP->last_reassemblied_sn = working_sn;
working_sn = (rlcP->last_reassemblied_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
if ((reassembly_after_discard)) {
// return 1 if vr_r > working_sn
// return 0 if vr_r = working_sn
// return -1 if vr_r < working_sn
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, rlcP->vr_r, working_sn) < 0) {
rlcP->vr_r = working_sn;
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] DETECTED PDU AFTER DISCARD ADJUST VR(R) 0x%04X\n", rlcP->rb_id, rlcP->vr_r);
#endif
rlcP->vr_mr = (rlcP->vr_r + rlcP->configured_rx_window_size - 1) & SN_12BITS_MASK;
}
}
}
}
}
//-----------------------------------------------------------------------------
void
process_receiver_buffer_7 (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
struct rlc_am_pdu_header* rlc_header;
mem_block_t* pdu;
uint16_t vr_r;
uint16_t working_sn;
uint16_t working_sn_index; // index in buffer
uint8_t* data_pdu;
uint8_t li[RLC_AM_SEGMENT_NB_MAX_LI_PER_PDU];
uint16_t remaining_data_size;
int8_t nb_li;
int8_t li_index;
int8_t li_start_index;
uint8_t reassembly_after_discard;
uint8_t sdu_sent=0;
// should start reassembly with sn working_sn
working_sn = (rlcP->last_reassemblied_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
vr_r = rlcP->vr_r;
reassembly_after_discard = 0;
while (rlcP->receiver_buffer[working_sn_index]) {
pdu = rlcP->receiver_buffer[working_sn_index];
nb_li = 0;
li_index = 0;
rlc_header = (struct rlc_am_pdu_header*) (((struct rlc_am_rx_pdu_management*) (pdu->data))->first_byte);
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU %p SN 0x%04X (sdu_sent %d)\n", rlcP->rb_id, pdu, working_sn,sdu_sent);
#endif
if ((rlcP->discard_reassembly_start_sn == ((struct rlc_am_rx_pdu_management*) (pdu->data))->sn)) {
rlcP->output_sdu_size_to_write = 0;
reassembly_after_discard = 1; // keep trace of entering in this block
if (!(rlc_header->byte2 & RLC_HE_MASK) == RLC_HE_SUCC_BYTE_CONTAINS_DATA) {
while ((li[nb_li] = (rlc_header->li_data_7[nb_li])) & RLC_E_NEXT_FIELD_IS_LI_E) {
li[nb_li] = li[nb_li] & (~(uint8_t) RLC_E_NEXT_FIELD_IS_LI_E);
nb_li++;
}
nb_li++; // count the first li
}
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] DETECTED PDU TO BE REASSEMBLIED AFTER DISCARD, START SN 0x%04X hex VR(R) 0x%04X\n", rlcP->rb_id,
rlcP->discard_reassembly_start_sn, rlcP->vr_r);
#endif
// this variable may be changed by the reception of a mrw sufi
//li_start_index = rlcP->discard_reassembly_after_li + 1; // reassembly will start at this index
li_start_index = rlcP->discard_reassembly_after_li; // reassembly will start at this index
// after reception of sufi mrw the starting index for li will be 0
rlcP->discard_reassembly_after_li = RLC_AM_DISCARD_REASSEMBLY_AT_LI_INDEX_0; // =-1
remaining_data_size = rlcP->pdu_size - 2 - (nb_li);
data_pdu = (uint8_t*) (&rlc_header->li_data_7[nb_li]);
while (li_index < nb_li) {
switch (li[li_index]) {
case (uint8_t) RLC_LI_LAST_PDU_EXACTLY_FILLED:
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU SN 0x%04X GET LI RLC_LI_LAST_PDU_EXACTLY_FILLED REMAINING DATA SIZE %d, li_index %d, li_start_index %d\n", rlcP->rb_id,
working_sn, remaining_data_size, li_index, li_start_index);
#endif
if (li_index >= li_start_index) {
send_sdu (rlcP);
sdu_sent=1;
}
break;
case (uint8_t) RLC_LI_PDU_PIGGY_BACKED_STATUS: // ignore
case (uint8_t) RLC_LI_PDU_PADDING:
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU SN 0x%04X GET LI RLC_LI_PDU_PADDING\n", rlcP->rb_id, working_sn);
#endif
remaining_data_size = 0;
break;
default: // li is length
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU SN 0x%04X GET LI SIZE %d\n", rlcP->rb_id, working_sn, li[li_index] >> 1);
#endif
remaining_data_size = remaining_data_size - (li[li_index] >> 1);
if (li_index >= li_start_index) {
reassembly (data_pdu, (li[li_index] >> 1), rlcP);
send_sdu (rlcP);
sdu_sent=1;
}
data_pdu = (uint8_t*) ((uint32_t) data_pdu + (li[li_index] >> 1));
}
li_index++;
}
if ((remaining_data_size)) {
reassembly (data_pdu, remaining_data_size, rlcP);
remaining_data_size = 0;
}
free_receiver_buffer (rlcP, working_sn_index);
rlcP->discard_reassembly_start_sn = RLC_AM_SN_INVALID;
rlcP->last_reassemblied_sn = working_sn;
working_sn = (rlcP->last_reassemblied_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
// return 1 if vr_r > working_sn
// return 0 if vr_r = working_sn
// return -1 if vr_r < working_sn
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, rlcP->vr_r, working_sn) < 0) {
rlcP->vr_r = working_sn;
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] DETECTED PDU AFTER DISCARD ADJUST VR(R) 0x%04X hex\n", rlcP->rb_id, rlcP->vr_r);
#endif
rlcP->vr_mr = (rlcP->vr_r + rlcP->configured_rx_window_size - 1) & SN_12BITS_MASK;
}
} else {
#ifdef DEBUG_REASSEMBLY
msg("[RLC][AM] Reassembly, No discard. rlc_header->byte2 %d\n");
#endif
// exploit HE field info
if ((rlc_header->byte2 & RLC_HE_MASK) == RLC_HE_SUCC_BYTE_CONTAINS_DATA) {
msg("WILL REASSEMBLY INDEX %04X\n", working_sn_index);
reassembly ((uint8_t*) (rlc_header->li_data_7), rlcP->pdu_size - 2, rlcP);
} else {
while ((li[nb_li] = (rlc_header->li_data_7[nb_li])) & RLC_E_NEXT_FIELD_IS_LI_E) {
li[nb_li] = li[nb_li] & (~(uint8_t) RLC_E_NEXT_FIELD_IS_LI_E);
nb_li++;
}
nb_li++;
remaining_data_size = rlcP->pdu_size - 2 - nb_li;
data_pdu = (uint8_t*) (&rlc_header->li_data_7[nb_li]);
while (li_index < nb_li) {
switch (li[li_index]) {
case (uint8_t) RLC_LI_LAST_PDU_EXACTLY_FILLED:
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU SN 0x%04X GET LI RLC_LI_LAST_PDU_EXACTLY_FILLED NUM LI %d\n", rlcP->rb_id, working_sn,nb_li);
#endif
send_sdu (rlcP);
sdu_sent=1;
break;
case (uint8_t) RLC_LI_PDU_PIGGY_BACKED_STATUS: // ignore
case (uint8_t) RLC_LI_PDU_PADDING:
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU SN 0x%04X GET LI RLC_LI_PDU_PADDING\n", rlcP->rb_id, working_sn);
#endif
remaining_data_size = 0;
break;
default: // li is length
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] PDU SN 0x%04X GET LI SIZE %d Bytes\n", rlcP->rb_id, working_sn, li[li_index] >> 1);
#endif
remaining_data_size = remaining_data_size - (li[li_index] >> 1);
reassembly (data_pdu, (li[li_index] >> 1), rlcP);
data_pdu = (uint8_t*) ((uint32_t) data_pdu + (li[li_index] >> 1));
send_sdu (rlcP);
sdu_sent=1;
}
li_index++;
}
if ((remaining_data_size)) {
//msg("WILL REASSEMBLY INDEX %04X\n", working_sn_index);
reassembly (data_pdu, remaining_data_size, rlcP);
remaining_data_size = 0;
}
}
free_receiver_buffer (rlcP, working_sn_index);
rlcP->last_reassemblied_sn = working_sn;
working_sn = (rlcP->last_reassemblied_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
if ((reassembly_after_discard)) {
// return 1 if vr_r > working_sn
// return 0 if vr_r = working_sn
// return -1 if vr_r < working_sn
if (rlc_am_comp_sn (rlcP, rlcP->vr_r, rlcP->vr_r, working_sn) < 0) {
rlcP->vr_r = working_sn;
#ifdef DEBUG_REASSEMBLY
msg ("[RLC_AM][RB %d][REASSEMBLY] DETECTED PDU AFTER DISCARD ADJUST VR(R) 0x%04X\n", rlcP->rb_id, rlcP->vr_r);
#endif
rlcP->vr_mr = (rlcP->vr_r + rlcP->configured_rx_window_size - 1) & SN_12BITS_MASK;
}
}
}
msg("receiver_buffer[%d] %p (sdu_sent %d)\n",working_sn_index,rlcP->receiver_buffer[working_sn_index],sdu_sent);
}
// if (sdu_sent == 0) {
// msg("[RLC_AM][RB %d][REASSEMBLY] Forcing send_sdu (sent_sdu == 0)\n",rlcP->rb_id);
// send_sdu(rlcP);
// }
}
openair2/LAYER2/RLC/AM/rlc_am_receiver_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_receiver_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_RECEIVER_PROTO_EXTERN_H__
# define __RLC_AM_RECEIVER_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern void receiver_retransmission_management (struct rlc_am_entity *rlcP, mem_block_t * pduP, struct rlc_am_pdu_header *rlc_headerP);
extern void free_receiver_buffer (struct rlc_am_entity *rlcP, uint16_t indexP);
extern void insert_into_receiver_buffer (struct rlc_am_entity *rlcP, uint16_t indexP, mem_block_t * pduP);
extern void process_receiver_buffer_15 (struct rlc_am_entity *rlcP);
extern void process_receiver_buffer_7 (struct rlc_am_entity *rlcP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_reset.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_reset.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
/* From 3GPP TS 25.322 V5.0.0 (2002-03)
The RLC reset procedure is used to reset two RLC peer entities, which are operating in acknowledged mode.
During the reset procedure the hyper frame numbers (HFN) in UTRAN and UE are synchronised. Two HFNs
used for ciphering needs to be synchronised, DL HFN in downlink and UL HFN in uplink.
In the reset procedure, the highest UL HFN and DL HFN used by the RLC
entity in the transmitting sides, i.e. the HFNs associated with AMD PDUs of "Sequence Number"=VT(S)-1 if at least
one AMD PDU had been transmitted or of "Sequence Number"=0 if no AMD PDU had been transmitted, are
exchanged between UE and UTRAN.
The RESET PDUs and the RESET ACK PDUs have higher priority than AMD PDUs.
*/
#define RLC_AM_C
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc.h"
#include "rlc_am_entity.h"
#include "rlc_am_structs.h"
#include "rlc_am_constants.h"
#include "rlc_am_control_primitives_proto_extern.h"
#include "rlc_am_fsm_proto_extern.h"
#include "list.h"
#include "mem_block.h"
#include "umts_timer_proto_extern.h"
#include "LAYER2/MAC/extern.h"
#define DEBUG_RESET
//-----------------------------------------------------------------------------
void send_reset_ack_pdu (uint8_t rsnP, struct rlc_am_entity* rlcP);
void send_reset_pdu (struct rlc_am_entity* rlcP);
void reset_rlc_am (struct rlc_am_entity* rlcP);
void process_reset_ack (mem_block_t* pduP, struct rlc_am_reset_header* controlP, struct rlc_am_entity* rlcP);
void process_reset (mem_block_t* pduP, struct rlc_am_reset_header* controlP, struct rlc_am_entity* rlcP);
//-----------------------------------------------------------------------------
void
rlc_am_reset_time_out (struct rlc_am_entity* rlcP, mem_block_t* not_usedP)
{
//-----------------------------------------------------------------------------
/* from 3GPP TS 25.322 V5.0.0 (2002-03)
If Timer_RST expires before the reset procedure is terminated, the Sender shall:
- if VT(RST)<MaxRST-1:
- set the RESET PDU as previously transmitted (even if additional SDUs were discarded in the mean-time);
- transmit RESET PDU;
- increment VT(RST) by one;
- restart Timer_RST.
Unrecoverable error (VT(RST) MaxRST)
The Sender shall:
- if VT(RST) becomes larger than or equal to MaxRST:
- indicate unrecoverable error to upper layer.
*/
rlcP->timer_rst = NULL;
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RESET TIME OUT VT(RST) = %d frame %d\n", rlcP->rb_id, rlcP->vt_rst, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
if (rlcP->protocol_state & RLC_RESET_PENDING_STATE) {
if (rlcP->vt_rst < rlcP->max_rst - 1) {
send_reset_pdu (rlcP);
rlcP->vt_rst += 1;
} else {
//rrc_indication_unrecoverable_error_from_rlc_am(rlcP);
// notification not raised to RRC, continue. (TO DO)
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RESET TIME OUT VT(RST) >= max_rst frame %d REPORT TO RRC\n", rlcP->rb_id, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
send_reset_pdu (rlcP);
rlcP->vt_rst += 1;
rlc_data_conf (0, rlcP->rb_id, 0,RLC_TX_CONFIRM_FAILURE, rlcP->data_plane); // mui, rb_ib, status
#ifdef NODE_MT
#warning rrc_ue_CPHY_Out_Synch_rx should be called
//rrc_ue_CPHY_Out_Synch_rx (1); // Temporary hack to disconnect mobile upon RLC AM timeout
#endif /* NODE_MT */
}
}
}
//-----------------------------------------------------------------------------
void
send_reset_pdu (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
mem_block_t* pdu;
struct rlc_am_reset_header* header;
/* From TS 25.322 V5.0.0 (2002-03)
RESET PDU contents to set
The Sender shall:
- set the HFNI field to the currently highest used HFN (DL HFN when the RESET PDU is sent by UTRAN or UL
HFN when the RESET PDU is sent by the UE);
- set the RSN field to the sequence number of the RESET PDU. The sequence number of the first RESET PDU
after the AM entity is established or re-established shall be "0". This sequence number is incremented every time
a new RESET PDU is transmitted, but not when a RESET PDU is retransmitted.
*/
if (!(rlcP->timer_rst)) {
if (rlcP->vt_rst == 0) { // first transmission of reset PDU
rlcP->reset_sequence_number ^= 1;
}
rlcP->vt_rst += 1;
pdu = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if ((pdu)) {
((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_RESET_PDU_TYPE;
header = (struct rlc_am_reset_header*) (&pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
header->byte1 = RLC_PDU_TYPE_RESET | (rlcP->reset_sequence_number << 3);
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] TX RESET RSN %d VT(RST) %d frame %d\n", rlcP->rb_id, rlcP->reset_sequence_number, rlcP->vt_rst, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
// HFNI NOT IMPLEMENTED NOW needed only for cyphering
/*header->hfni[0] = 0;
header->hfni[1] = 0;
header->hfni[2] = 0;
*/
list_add_head (pdu, &rlcP->control);
rlc_am_fsm_notify_event (rlcP, RLC_AM_TRANSMIT_RESET_EVENT); // not yet submitted to lower layers
} else {
msg ("[RLC_AM][RB %d] ERROR SEND RESET OUT OF MEMORY ERROR\n", rlcP->rb_id);
}
}
}
//-----------------------------------------------------------------------------
void
send_reset_ack_pdu (uint8_t rsnP, struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
mem_block_t* pdu;
struct rlc_am_reset_header* header;
/* From 3GPP TS 25.322 V5.0.0 (2002-03)
RESET ACK PDU contents to set
The Receiver shall:
- set the hyper frame number indicator field (HFNI) to the currently highest used HFN (DL HFN when the RESET
ACK PDU is sent by UTRAN or UL HFN when the RESET ACK PDU is sent by the UE);
- set the RSN field to the same value as in the corresponding received RESET PDU.
*/
if ((pdu = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE))) {
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] TX RESET ACK RSN %d frame %d\n", rlcP->rb_id, rsnP, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
((struct rlc_am_tx_control_pdu_management*) (pdu->data))->rlc_tb_type = RLC_AM_RESET_ACK_PDU_TYPE;
header = (struct rlc_am_reset_header*) (&pdu->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
header->byte1 = RLC_PDU_TYPE_RESET_ACK | (rsnP << 3);
list_add_head (pdu, &rlcP->control);
}
#ifdef DEBUG_RESET
else {
msg ("[RLC_AM][RB %d] SEND RESET ACK OUT OF MEMORY ERROR\n", rlcP->rb_id);
}
#endif
}
//-----------------------------------------------------------------------------
void
process_reset_ack (mem_block_t* pduP, struct rlc_am_reset_header* controlP, struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
/* from 3GPP TS 25.322 V5.0.0 (2002-03)
Upon reception of a RESET ACK PDU, the Sender shall:
- if the Sender has already transmitted a RESET PDU which has not been yet acknowledged by a RESET ACK
PDU:
- if the received RSN value is the same as the one in the corresponding RESET PDU:
- set the HFN value (DL HFN when the RESET ACK PDU is received in UE or UL HFN when the RESET
ACK PDU is received in UTRAN) to the HFNI field of the received RESET ACK PDU;
- reset the state variables described in subclause 9.4 to their initial values;
- stop all the timers described in subclause 9.5;
- reset configurable parameters to their configured values;
- discard all RLC PDUs in the receiving side of the AM RLC entity;
- discard all RLC SDUs that were transmitted before the reset in the transmitting side of the AM RLC
entity;
- increase with one the UL HFN and DL HFN, and the updated HFN values shall be used for the first
transmitted and received AMD PDUs after the reset procedure;
- otherwise (if the received RSN value is not the same as the one in the corresponding RESET PDU):
- discard the RESET ACK PDU;
- otherwise (if the Sender has not transmitted a RESET PDU which has not been yet acknowledged by a RESET
ACK PDU):
- discard the RESET ACK PDU.
NOTE: If the TFC selection exchange has been initiated by sending the RLC Entity Info parameter to MAC, the
RLC entity may delay the RLC SDUs discard in the transmitting side until the end of the next TTI.
*/
if (rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_RESET_ACK_EVENT)) {
if (((controlP->byte1 & RLC_AM_RESET_SEQUENCE_NUMBER_MASK) >> 3) == rlcP->reset_sequence_number) {
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RX RESET ACK RSN %d frame %d\n", rlcP->rb_id, ((controlP->byte1 & RLC_AM_RESET_SEQUENCE_NUMBER_MASK) >> 3), Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
rlc_am_reset_state_variables (rlcP);
reset_rlc_am (rlcP);
umts_stop_all_timers (&rlcP->rlc_am_timer_list);
rlcP->timer_rst = NULL;
}
#ifdef DEBUG_RESET
else {
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RX RESET ACK WRONG RSN %d != %d frame %d\n", rlcP->rb_id, (controlP->byte1 & RLC_AM_RESET_SEQUENCE_NUMBER_MASK) >> 3,
rlcP->reset_sequence_number, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
}
#endif
}
#ifdef DEBUG_RESET
else {
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RX RESET ACK NOT EXPECTED frame %d\n", rlcP->rb_id, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
}
#endif
msg("RLC AM RESET EXIT\n");
}
//-----------------------------------------------------------------------------
void
process_reset (mem_block_t* pduP, struct rlc_am_reset_header* controlP, struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint8_t rsn;
uint8_t saved_vt_rst;
/* From 25.322 V5.0.0 (2002-03)
Reception of the RESET PDU by the Receiver
Upon reception of a RESET PDU the Receiver shall:
- if the RSN value in the RESET PDU is the same as the RSN value in the last received RESET PDU:
- only submit a RESET ACK PDU to the lower layer with the contents set exactly as in the last transmitted
RESET ACK PDU (i.e., in this case the RLC entity is not reset).
- if the RESET PDU is the first RESET PDU received since the entity was (re-)established or the RSN value is
different from the RSN value in the last received RESET PDU:
- submit a RESET ACK PDU to the lower layer with the content set as specified in subclause 11.4.3.1;
- reset the state variables described in subclause 9.4 except VT(RST) to their initial values;
- stop all the timers described in subclause 9.5 except Timer_RST;
- reset configurable parameters to their configured values;
- discard all RLC PDUs in the receiving side of the AM RLC entity;
- discard all RLC SDUs that were transmitted before the reset in the transmitting side of the AM RLC entity;
- set the HFN (DL HFN when the RESET PDU is received in UE or UL HFN when the RESET PDU is
received in UTRAN) equal to the HFNI field in the received RESET PDU;
- increase with one the UL HFN and DL HFN, and the updated HFN values shall be used for the first
transmitted and received AMD PDUs after the reset procedure.
NOTE: If the TFC selection exchange has been initiated by sending the RLC Entity Info parameter to MAC, the
RLC entity may delay the RLC SDUs discard in the transmitting side of the AM RLC entity until the end
of the next TTI.
Reception of the RESET PDU by the Sender
Upon reception of a RESET PDU, the Sender shall:
- submit a RESET ACK PDU to the lower layer with the content set as specified in subclause 11.4.3.1;
- reset the state variables described in subclause 9.4 except VT(RST) to their initial values;
- stop all the timers described in subclause 9.5 except Timer_RST;
- reset configurable parameters to their configured values;
- discard all RLC PDUs in the receiving side of the AM RLC entity;
- discard all RLC SDUs that were transmitted before the reset in the transmitting side of the AM RLC entity;
- set the HFN (DL HFN when the RESET PDU is received in UE or UL HFN when the RESET PDU is received
in UTRAN) equal to the HFNI field in the received RESET PDU;
- increase with one the UL HFN and DL HFN, and the updated HFN values shall be used for the first transmitted
and received AMD PDUs after the reset procedure.
NOTE: If the TFC selection exchange has been initiated by sending the RLC Entity Info parameter to MAC, the
RLC entity may delay the RLC SDUs discard in the transmitting side until the end of the next TTI.
*/
rsn = (controlP->byte1 & RLC_AM_RESET_SEQUENCE_NUMBER_MASK) >> 3;
if ((rlcP->protocol_state & RLC_RESET_PENDING_STATE)) {
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RX RESET RSN %d frame %d\n", rlcP->rb_id, rsn, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_RESET_EVENT);
// sender
saved_vt_rst = rlcP->vt_rst;
reset_rlc_am (rlcP);
rlcP->vt_rst = saved_vt_rst;
rlcP->last_received_rsn = rsn;
send_reset_ack_pdu (rsn, rlcP);
// NOT IN SPECS, BUT IF SENDER RECEIVE A RESET, IT DISCARDS ALL CONTROL PDU IN ITS BUFFER
// SO IF THE RESET PDU WAS STILL IN THE RLC BUFFERS...IT IS DROPPED AND THE RESET TIMER CAN NOT
// BE STARTED (BY SUCCESSFULL TX ACK OF MAC LAYER), SO REARM THE TIMER AND SCHEDULE A NEW RESET
// PDU FOR TRANSMISSION
if (!(rlcP->timer_rst)) {
umts_stop_all_timers (&rlcP->rlc_am_timer_list);
rlc_am_reset_time_out (rlcP, NULL);
} else {
umts_stop_all_timers_except (&rlcP->rlc_am_timer_list, rlc_am_reset_time_out);
}
} else {
// receiver
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RX RESET RSN %d frame %d\n", rlcP->rb_id, rsn, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
if (rlcP->last_received_rsn == rsn) { //last_received_rsn initialized to -1 when RLC start
#ifdef DEBUG_RESET
msg ("\n******************************************************************\n");
msg ("[RLC_AM][RB %d] RX RESET RSN %d SAME RSN RECEIVED LAST RESET, SEND RESET ACK frame %d \n", rlcP->rb_id, rsn, Mac_rlc_xface->frame);
msg ("\n******************************************************************\n");
#endif
send_reset_ack_pdu (rsn, rlcP); // rsn start to zero
return;
}
rlc_am_fsm_notify_event (rlcP, RLC_AM_RECEIVE_RESET_EVENT);
saved_vt_rst = rlcP->vt_rst;
reset_rlc_am (rlcP);
rlcP->vt_rst = saved_vt_rst;
rlcP->last_received_rsn = rsn;
send_reset_ack_pdu (rsn, rlcP);
umts_stop_all_timers (&rlcP->rlc_am_timer_list);
rlcP->timer_rst = NULL;
}
}
//-----------------------------------------------------------------------------
void
reset_rlc_am (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
int index;
for (index = 0; index < rlcP->size_input_sdus_buffer; index++) {
if (rlcP->input_sdus[index]) {
if (!(rlcP->data_plane)) {
#ifdef DEBUG_RLC_AM_SEND_CONFIRM
msg ("[RLC_AM][RB %d][CONFIRM] SDU MUI %d LOST IN RESET\n", rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[index]->data))->mui);
#endif
rlc_data_conf (0, rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[index]->data))->mui, RLC_TX_CONFIRM_FAILURE, rlcP->data_plane);
}
free_mem_block (rlcP->input_sdus[index]);
rlcP->input_sdus[index] = NULL;
}
}
rlc_am_reset_state_variables (rlcP);
rlc_am_discard_all_pdus (rlcP);
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d] RESETED\n", rlcP->rb_id);
//display_mem_load();
//msg("sdu_conf_segmented : %p\n" , rlcP->sdu_conf_segmented.head);
//msg("sdu_discard_segmented : %p\n", rlcP->sdu_discard_segmented.head);
//msg("sdu_discarded : %p\n" , rlcP->sdu_discarded.head);
//msg("discard_procedures : %p\n" , rlcP->discard_procedures.head);
//check_mem_area(mem);
#endif
}
openair2/LAYER2/RLC/AM/rlc_am_reset_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_reset_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_RESET_PROTO_EXTERN_H__
# define __RLC_AM_RESET_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
//-----------------------------------------------------------------------------
extern void rlc_am_reset_time_out (struct rlc_am_entity *rlcP, mem_block_t * not_usedP);
extern void send_reset_ack_pdu (uint8_t rsnP, struct rlc_am_entity *rlcP);
extern void send_reset_pdu (struct rlc_am_entity *rlcP);
extern void reset_rlc_am (struct rlc_am_entity *rlcP);
extern void process_reset_ack (mem_block_t * pduP, struct rlc_am_reset_header *controlP, struct rlc_am_entity *rlcP);
extern void process_reset (mem_block_t * pduP, struct rlc_am_reset_header *controlP, struct rlc_am_entity *rlcP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_retrans.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_retrans.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#define RLC_AM_C
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc.h"
#include "rlc_am_entity.h"
#include "rlc_am_errno.h"
#include "rlc_am_constants.h"
#include "rlc_am_structs.h"
#include "rlc_am_discard_notif_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "rlc_am_reset_proto_extern.h"
#include "rlc_am_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "rlc_primitives.h"
#include "list.h"
#include "LAYER2/MAC/extern.h"
//#define DEBUG_RETRANSMISSION
//#define DEBUG_ACK
//#define DEBUG_RESET
//#define DEBUG_BITMAP
//#define DEBUG_LIST
//-----------------------------------------------------------------------------
inline int16_t retransmission_buffer_management_ack (struct rlc_am_entity* rlcP, uint8_t* sufiP, uint8_t byte_alignedP,
int16_t* first_error_indicated_snP);
inline uint8_t* retransmission_buffer_management_bitmap (struct rlc_am_entity* rlcP, uint8_t* bitmap_sufiP, uint8_t byte_alignedP,
int16_t* first_error_indicated_snP);
inline uint8_t* retransmission_buffer_management_list (struct rlc_am_entity* rlcP, uint8_t* bitmap_sufiP, uint8_t byte_alignedP,
int16_t* first_error_indicated_snP);
inline void free_retransmission_buffer (struct rlc_am_entity* rlcP, uint16_t indexP);
inline void free_retransmission_buffer_no_confirmation (struct rlc_am_entity* rlcP, uint16_t indexP);
inline void insert_into_retransmission_buffer (struct rlc_am_entity* rlcP, uint16_t indexP, mem_block_t* pduP);
inline uint8_t retransmit_pdu (struct rlc_am_entity* rlcP, uint16_t snP);
inline uint8_t add_to_transmission_buffer_unack_pdu (struct rlc_am_entity* rlcP, int16_t* nb_pdu_to_transmit);
//-----------------------------------------------------------------------------
/*
* remove all mem_block_t(s) having sn <= snP
*/
int16_t
retransmission_buffer_management_ack (struct rlc_am_entity* rlcP, uint8_t* sufiP, uint8_t byte_alignedP, int16_t* first_error_indicated_snP)
{
//-----------------------------------------------------------------------------
uint16_t lsn; // sequence number acknowledged
uint16_t current_sn;
uint16_t upper_bound;
int16_t current_index;
uint8_t tmp;
// get LSN field;
if (byte_alignedP) {
// get next 12 bits;
lsn = (*sufiP++ & 0x0F);
lsn = lsn << 8;
lsn += *sufiP;
} else {
// get next 12 bits;
sufiP++;
lsn = *sufiP++;
lsn = lsn << 4;
tmp = *sufiP;
lsn |= (tmp >> 4);
}
#ifdef DEBUG_ACK
msg ("[RLC_AM][RB %d][ACK] RX SUFI ACK 0x%04X VT(A) 0x%04X VT(S) 0x%04X VT(MS) 0x%04X\n", rlcP->rb_id, lsn, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms);
#endif
current_sn = rlcP->vt_a;
// From 3GPP TS 25.322 V4.3.0
// LSN acknowledges the reception of all PDUs with "Sequence Number" < LSN (Last Sequence Number)
// that are not indicated to be erroneous in earlier parts of the STATUS PDU.
// This means that if the LSN is set to a value greater than VR(R), all erroneous PDUs shall
// be included in the same STATUS PDU
// and if the LSN is set to VR(R), the erroneous PDUs can be split into several STATUS PDUs.
// At the transmitter, if the value of the LSN =< the value of the first error indicated
// in the STATUS PDU, VT(A) will be updated according to the LSN,
// otherwise VT(A) will be updated according to the first error indicated in the STATUS PDU.
// VT(A) is only updated based on STATUS PDUs where ACK SUFI (or MRW_ACK SUFI) is included.
// The LSN shall not be set to a value > VR(H) nor < VR(R).
//-------------------------;
// if ack lsn <= first error => vt_a = lsn;
// else vt_a = first error indicated;
// check lsn is valid
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, lsn, rlcP->vt_a) >= 0) {
if (*first_error_indicated_snP >= 0) {
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, lsn, (uint16_t) * first_error_indicated_snP) <= 0) {
#ifdef DEBUG_ACK
msg ("[RLC_AM][RB %d][ACK] VT(A) 0x%04X -> 0x%04X VT(S) 0x%04X CASE LSN <= FIRST PDU IN ERROR IN STATUS PDU\n", rlcP->rb_id, rlcP->vt_a, lsn, rlcP->vt_s);
#endif
rlcP->vt_a = lsn;
} else {
#ifdef DEBUG_ACK
msg ("[RLC_AM][RB %d][ACK] VT(A) 0x%04X -> 0x%04X VT(S) 0x%04X CASE LSN > FIRST PDU IN ERROR IN STATUS PDU \n", rlcP->rb_id, rlcP->vt_a,
(uint16_t) * first_error_indicated_snP, rlcP->vt_s);
#endif
rlcP->vt_a = (uint16_t) * first_error_indicated_snP;
}
} else {
#ifdef DEBUG_ACK
msg ("[RLC_AM][RB %d][ACK] VT(A) 0x%04X -> 0x%04X VT(S) 0x%04X CASE SUFI ACK ALONE IN CONTROL PDU\n", rlcP->rb_id, rlcP->vt_a, lsn, rlcP->vt_s);
#endif
rlcP->vt_a = lsn;
}
rlcP->vt_ms = (rlcP->vt_a + rlcP->vt_ws - 1) & SN_12BITS_MASK;
current_index = current_sn % (uint16_t) rlcP->recomputed_configured_tx_window_size;
upper_bound = lsn % (uint16_t) rlcP->recomputed_configured_tx_window_size;
// remove all matching pdus from retransmission buffer;
while (upper_bound != current_index) {
// free all pdus that have not been stamped as missing;
if (rlcP->retransmission_buffer[current_index] != NULL) {
if (((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[current_index]->data))->ack != RLC_AM_PDU_NACK_EVENT) {
#ifdef DEBUG_ACK
msg ("[RLC_AM][RB %d][ACK] FREE PDU SN 0x%04X BECAUSE FIELD ACK=%d\n", rlcP->rb_id, current_sn,
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[current_index]->data))->ack);
#endif
free_retransmission_buffer (rlcP, (uint16_t) current_index);
} else {
#ifdef DEBUG_ACK
msg ("[RLC_AM][RB %d][ACK] CLEAR NACK EVENT (%d) PDU SN 0x%04X\n", rlcP->rb_id,
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[current_index]->data))->ack,
current_sn);
#endif
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[current_index]->data))->ack = RLC_AM_PDU_ACK_NO_EVENT;
}
}
current_sn = (current_sn + 1) & SN_12BITS_MASK;
current_index = current_sn % (uint16_t) rlcP->recomputed_configured_tx_window_size;
}
/*if (rlcP->retransmission_buffer[current_index] != NULL) {
if (((struct rlc_am_tx_data_pdu_management*)(&rlcP->retransmission_buffer[current_index]->data[sizeof(struct rlc_am_tx_data_pdu_allocation)]))->ack
== RLC_AM_PDU_NACK_EVENT) {
#ifdef DEBUG_ACK
msg("[RLC_AM %p][ACK] CLEAR ACK EVENT PDU SN %04X\n",rlcP, current_sn);
#endif
((struct rlc_am_tx_data_pdu_management*)(&rlcP->retransmission_buffer[current_index]->data[sizeof(struct rlc_am_tx_data_pdu_allocation)]))->ack = RLC_AM_PDU_ACK_NO_EVENT;
}
}
*/
return lsn;
} else {
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][ACK] ERROR SUFI ACK INVALID lsn 0x%02X vt(a) 0x%04X vt(s) 0x%04X -> RESET\n", rlcP->rb_id, lsn, rlcP->vt_a, rlcP->vt_s);
//display_protocol_vars_rlc_am(rlcP);
#endif
send_reset_pdu (rlcP);
return (int16_t) (-1);
}
}
//-----------------------------------------------------------------------------
/*
* remove all mem_block_t(s) correctly received
* retransmit all mem_block_t(s) not correctly received
* @param bitmap_sufiP pointer on byte containing field "sufi type"
* @param byte_alignedP tells if sufi type quartet is on MSByte (1) or LSByte (0)
*/
inline uint8_t*
retransmission_buffer_management_bitmap (struct rlc_am_entity* rlcP, uint8_t* bitmap_sufiP, uint8_t byte_alignedP, int16_t* first_error_indicated_snP)
{
//-----------------------------------------------------------------------------
uint16_t id_index;
uint16_t fsn;
uint8_t length, tmp;
uint8_t one_pdu_removed = 0; //optim: update vt_a only at the end of the proc
uint8_t bit_mask;
uint8_t end_bit;
if (byte_alignedP) {
// get next 4 bits : length
length = (*bitmap_sufiP++ & 0x0F) + 1;
// get next 12 bits : FSN
fsn = *bitmap_sufiP++;
fsn = fsn << 4;
tmp = *bitmap_sufiP;
fsn += tmp >> 4;
bit_mask = 8;
} else {
bitmap_sufiP++;
// get 4 bits length
length = (*bitmap_sufiP >> 4) + 1;
// get next 12 bits : FSN
fsn = *bitmap_sufiP++ & 0x0F;
fsn = fsn << 8;
fsn = fsn + *bitmap_sufiP;
bitmap_sufiP++;
bit_mask = 128;
}
end_bit = length << 3; // *8
#ifdef DEBUG_BITMAP
msg ("[RLC_AM][RB %d][BITMAP] SUFI BITMAP fsn 0x%04X length 0x%04X\n", rlcP->rb_id, fsn, length);
#endif
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, fsn, rlcP->vt_a) >= 0) {
while (end_bit) {
id_index = fsn % (uint16_t) (rlcP->recomputed_configured_tx_window_size);
// found a matching pdu
if (*bitmap_sufiP & bit_mask) {
// pdu correctly received
// remove it from retransmission buffer
free_retransmission_buffer (rlcP, id_index);
one_pdu_removed = 1;
#ifdef DEBUG_BITMAP
msg ("[RLC_AM][RB %d][BITMAP] SUFI BITMAP ACK 0x%04x \n", rlcP->rb_id, fsn);
#endif
} else {
// pdu not correctly received;
// retransmit it;
#ifdef DEBUG_BITMAP
msg ("[RLC_AM][RB %d][BITMAP] SUFI BITMAP NACK 0x%04x\n", rlcP->rb_id, fsn);
#endif
if (rlcP->retransmission_buffer[id_index]) {
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[id_index]->data))->ack = RLC_AM_PDU_NACK_EVENT;
retransmit_pdu (rlcP, fsn);
rlcP->stat_tx_retransmit_pdu_by_status += 1;
/*
if (*first_error_indicated_snP == -1) {
*first_error_indicated_snP = fsn;
}
*/
}
if (*first_error_indicated_snP == -1) {
#ifdef DEBUG_BITMAP
msg ("[RLC_AM][RB %d][BITMAP] FIRST ERROR INDICATED 0x%04x\n", rlcP->rb_id, fsn);
#endif
*first_error_indicated_snP = fsn;
}
}
// inc searched sequence number
fsn++;
fsn = fsn & SN_12BITS_MASK;
bit_mask = bit_mask >> 1;
// remaining nb bits to process
end_bit--;
if (!bit_mask) {
bit_mask = 128;
bitmap_sufiP++;
}
}
return bitmap_sufiP;
} else {
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][BITMAP] ERROR SUFI BITMAP INVALID sn 0x%02X vt(a) 0x%04X vt(s) 0x%04X send RESET requested\n", rlcP->rb_id, fsn, rlcP->vt_a, rlcP->vt_s);
#endif
display_protocol_vars_rlc_am (rlcP);
send_reset_pdu (rlcP);
return bitmap_sufiP;
}
}
//-----------------------------------------------------------------------------
/*
* retransmit all mem_block_t(s) not correctly received
* @param bitmap_sufiP pointer on byte containing field "sufi type"
* @param byte_alignedP tells if sufi type quartet is on MSByte (1) or LSByte (0)
*/
inline uint8_t*
retransmission_buffer_management_list (struct rlc_am_entity* rlcP, uint8_t* bitmap_sufiP, uint8_t byte_alignedP, int16_t* first_error_indicated_snP)
{
//-----------------------------------------------------------------------------
uint8_t* p8;
uint16_t start_marking_sn;
uint8_t nb_missing_pdu;
uint8_t nb_pairs;
p8 = bitmap_sufiP;
if (byte_alignedP) {
nb_pairs = *p8++ & 0X0F; // number of (SNi, Li) pairs in the sufi type LIST the value 0000
// is invalid and the list is discarded
if (!nb_pairs) {
p8 = p8 + 2;
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][LIST] ERROR SUFI LIST nb pairs is 0 send RESET requested\n", rlcP->rb_id);
#endif
send_reset_pdu (rlcP);
#ifdef DEBUG_LIST
display_protocol_vars_rlc_am (rlcP);
#endif
return p8;
return p8;
} else {
while (nb_pairs) {
start_marking_sn = ((uint16_t) (*p8++)) << 4;
start_marking_sn = start_marking_sn | (*p8 >> 4);
nb_missing_pdu = *p8++ & 0X0F;
if (*first_error_indicated_snP == -1) {
*first_error_indicated_snP = start_marking_sn;
#ifdef DEBUG_LIST
msg ("[RLC_AM][RB %d][LIST] FIRST ERROR INDICATED 0x%04X VT(A) 0x%04X VT(S) 0x%04X\n", rlcP->rb_id, *first_error_indicated_snP, rlcP->vt_a, rlcP->vt_s);
#endif
}
#ifdef DEBUG_LIST
msg ("[RLC_AM][RB %d][LIST] SUFI LIST SN 0x%04X MISSING %d VT(A) 0x%04X VT(S) 0x%04X\n", rlcP->rb_id, start_marking_sn, nb_missing_pdu, rlcP->vt_a,
rlcP->vt_s);
#endif
while (nb_missing_pdu) {
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, start_marking_sn, rlcP->vt_a) >= 0) {
if (rlcP->retransmission_buffer[start_marking_sn % rlcP->recomputed_configured_tx_window_size] != NULL) {
#ifdef DEBUG_LIST
msg ("[RLC_AM][RB %d][LIST] MARK SN 0x%04X INDEX 0x%04X TO RLC_AM_PDU_NACK_EVENT\n", rlcP->rb_id, start_marking_sn,
start_marking_sn % rlcP->recomputed_configured_tx_window_size);
#endif
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[start_marking_sn % rlcP->recomputed_configured_tx_window_size]->data))->ack =
RLC_AM_PDU_NACK_EVENT;
retransmit_pdu (rlcP, start_marking_sn);
rlcP->stat_tx_retransmit_pdu_by_status += 1;
}
} else {
send_reset_pdu (rlcP);
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][LIST] ERROR SUFI LIST INVALID SN 0x%02X VT(A) 0x%04X VT(S) 0x%04X send RESET requested \n", rlcP->rb_id, start_marking_sn, rlcP->vt_a,
rlcP->vt_s);
#endif
#ifdef DEBUG_LIST
display_protocol_vars_rlc_am (rlcP);
#endif
return p8;
}
start_marking_sn = (start_marking_sn + 1) & SN_12BITS_MASK;
nb_missing_pdu--;
}
nb_pairs--;
}
return p8;
}
} else {
p8++;
nb_pairs = *p8 >> 4; // number of (SNi, Li) pairs in the sufi type LIST the value 0000
// is invalid and the list is discarded
if (!nb_pairs) {
p8 = p8 + 2;
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][LIST] ERROR SUFI LIST nb pairs is 0 send RESET requested vt(a) 0x%04X vt(s) 0x%04X\n", rlcP->rb_id, rlcP->vt_a, rlcP->vt_s);
#endif
send_reset_pdu (rlcP);
#ifdef DEBUG_LIST
display_protocol_vars_rlc_am (rlcP);
#endif
return p8;
} else {
while (nb_pairs) {
start_marking_sn = ((uint16_t) (*p8++) & 0x0F) << 8;
start_marking_sn = start_marking_sn | *p8++;
nb_missing_pdu = *p8 >> 4;
if (*first_error_indicated_snP == -1) {
*first_error_indicated_snP = start_marking_sn;
#ifdef DEBUG_LIST
msg ("[RLC_AM][RB %d][LIST] FIRST ERROR INDICATED 0x%04X VT(A) 0x%04X VT(S) 0x%04X\n", rlcP->rb_id, *first_error_indicated_snP, rlcP->vt_a, rlcP->vt_s);
#endif
}
#ifdef DEBUG_LIST
msg ("[RLC_AM][RB %d][RETRANSMISSION] SUFI LIST SN 0x%04X MISSING %d VT(A) 0x%04X VT(S) 0x%04X\n", rlcP->rb_id, start_marking_sn, nb_missing_pdu, rlcP->vt_a,
rlcP->vt_s);
#endif
while (nb_missing_pdu) {
if (rlc_am_comp_sn (rlcP, rlcP->vt_a, start_marking_sn, rlcP->vt_a) >= 0) {
if (rlcP->retransmission_buffer[start_marking_sn % rlcP->recomputed_configured_tx_window_size] != NULL) {
#ifdef DEBUG_LIST
msg ("[RLC_AM][RB %d][LIST] MARK SN 0x%04X INDEX 0x%04X TO RLC_AM_PDU_NACK_EVENT\n", rlcP->rb_id, start_marking_sn,
start_marking_sn % rlcP->recomputed_configured_tx_window_size);
#endif
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[start_marking_sn % rlcP->recomputed_configured_tx_window_size]->data))->ack =
RLC_AM_PDU_NACK_EVENT;
retransmit_pdu (rlcP, start_marking_sn);
rlcP->stat_tx_retransmit_pdu_by_status += 1;
}
} else {
send_reset_pdu (rlcP);
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][LIST] ERROR SUFI LIST invalid sn 0x%02X send RESET requested vt(a) 0x%04X vt(s) 0x%04X\n", rlcP->rb_id, start_marking_sn, rlcP->vt_a,
rlcP->vt_s);
#endif
#ifdef DEBUG_LIST
display_protocol_vars_rlc_am (rlcP);
#endif
return p8;
}
start_marking_sn = (start_marking_sn + 1) & SN_12BITS_MASK;
nb_missing_pdu--;
}
nb_pairs--;
}
return p8;
}
}
}
//-----------------------------------------------------------------------------
inline void
free_retransmission_buffer (struct rlc_am_entity* rlcP, uint16_t indexP)
{
//-----------------------------------------------------------------------------
mem_block_t* sdu_confirm;
struct rlc_am_tx_data_pdu_management* pdu;
mem_block_t* le = NULL;
unsigned int index;
unsigned int sdu_index;
index = indexP;
if (index < (uint16_t) rlcP->recomputed_configured_tx_window_size) {
le = rlcP->retransmission_buffer[index];
if (le != NULL) {
// ???
pdu = (struct rlc_am_tx_data_pdu_management*) (le->data);
// test if the sender of the sdu requested a confirmation of the reception of the sdu by the receiving RLC
// or if mode discard is on
for (sdu_index = 0; sdu_index < pdu->nb_sdu; sdu_index++) {
if (pdu->sdu[sdu_index] != -1) { // may be discarded
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->nb_pdus_ack += 1;
if ((((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->nb_pdus_ack ==
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->nb_pdus) &&
(((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->segmented)) {
if (((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->confirm) {
// send confirmation to upper layers
#ifdef DEBUG_RLC_AM_SEND_CONFIRM
msg ("[RLC_AM][RB %d][CONFIRM] SDU MUI %d ACK BY PEER\n", rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->mui);
#endif
rlc_data_conf (0, rlcP->rb_id, ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->mui, RLC_TX_CONFIRM_SUCCESSFULL,
rlcP->data_plane);
}
// FREE SDU : we can remove the sdu if timer based discard and all pdus submitted to lower layers and no confirm running
#ifdef DEBUG_RLC_AM_FREE_SDU
msg ("[RLC_AM][RB %d][RETRANS] FREE PDU INDEX 0x%04X FREE_SDU INDEX 0x%3X\n", rlcP->rb_id, indexP, pdu->sdu[sdu_index]);
#endif
free_mem_block (rlcP->input_sdus[pdu->sdu[sdu_index]]);
rlcP->input_sdus[pdu->sdu[sdu_index]] = NULL;
}
}
}
// now check if a copy of the pdu is not present in the retransmission_buffer_to_send
if ((pdu->copy)) {
list2_remove_element (pdu->copy, &rlcP->retransmission_buffer_to_send);
free_mem_block (pdu->copy);
}
#ifdef DEBUG_BUFFER_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] FREE PDU INDEX=0x%04X %p\n", rlcP->rb_id, index, le);
#endif
// if this pdu has been retransmitted, remove its size from buffer occupancy
if (pdu->vt_dat > 0) {
rlcP->buffer_occupancy_retransmission_buffer -= 1;
}
free_mem_block (le);
rlcP->retransmission_buffer[index] = NULL;
return;
}
#ifdef DEBUG_BUFFER_RETRANSMISSION
//msg("[RLC_AM %p][RETRANSMISSION] ERROR free_retransmission_buffer() pointer to free is NULL, index in array = %04X\n", rlcP,index);
#endif
return;
}
msg ("[RLC_AM][RB %d][RETRANSMISSION] ERROR free_retransmission_buffer() invalid index in array decimal %d \n", rlcP->rb_id, index);
}
//-----------------------------------------------------------------------------
inline void
free_retransmission_buffer_no_confirmation (struct rlc_am_entity* rlcP, uint16_t indexP)
{
//-----------------------------------------------------------------------------
struct rlc_am_tx_data_pdu_management* pdu;
mem_block_t* le = NULL;
unsigned int index;
unsigned int sdu_index;
index = indexP;
if (index < (uint16_t) rlcP->recomputed_configured_tx_window_size) {
le = rlcP->retransmission_buffer[index];
if (le != NULL) {
pdu = (struct rlc_am_tx_data_pdu_management*) (le->data);
// test if the sender of the sdu requested a confirmation of the reception of the sdu by the receiving RLC
// or if mode discard is on
for (sdu_index = 0; sdu_index < pdu->nb_sdu; sdu_index++) {
if (pdu->sdu[sdu_index] != -1) { // may be discarded
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->nb_pdus_ack += 1;
if ((((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->nb_pdus_ack ==
((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->nb_pdus) &&
(((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[pdu->sdu[sdu_index]]->data))->segmented)) {
// FREE SDU : we can remove the sdu if timer based discard and all pdus submitted to lower layers and no confirm running
#ifdef DEBUG_RLC_AM_FREE_SDU
msg ("[RLC_AM][RB %d][RETRANS] FREE PDU NO_CONF INDEX 0x%04X FREE_SDU INDEX %d\n", rlcP->rb_id, indexP, pdu->sdu[sdu_index]);
#endif
free_mem_block (rlcP->input_sdus[pdu->sdu[sdu_index]]);
rlcP->input_sdus[pdu->sdu[sdu_index]] = NULL;
}
}
}
// now check if a copy of the pdu is not present in the retransmission_buffer_to_send
if ((pdu->copy)) {
list2_remove_element (pdu->copy, &rlcP->retransmission_buffer_to_send);
free_mem_block (pdu->copy);
}
#ifdef DEBUG_BUFFER_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] FREE PDU NO_CONF INDEX=0x%04X %p\n", rlcP->rb_id, index, le);
#endif
// if this pdu has been retransmitted, remove its size from buffer occupancy
if (pdu->vt_dat > 0) {
rlcP->buffer_occupancy_retransmission_buffer -= 1;
}
free_mem_block (le);
rlcP->retransmission_buffer[index] = NULL;
return;
}
#ifdef DEBUG_BUFFER_RETRANSMISSION
//msg("[RLC_AM %p][RETRANSMISSION] ERROR free_retransmission_buffer() pointer to free is NULL, index in array = %04X\n", rlcP,index);
#endif
return;
}
msg ("[RLC_AM][RB %d][RETRANSMISSION] ERROR free_retransmission_buffer() invalid index in array decimal %d \n", rlcP->rb_id, index);
}
//-----------------------------------------------------------------------------
inline void
insert_into_retransmission_buffer (struct rlc_am_entity* rlcP, uint16_t indexP, mem_block_t* pduP)
{
//-----------------------------------------------------------------------------
uint16_t index;
index = indexP;
if (index < (uint16_t) (rlcP->recomputed_configured_tx_window_size)) {
if (rlcP->retransmission_buffer[index]) {
#ifdef DEBUG_BUFFER_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] INSERT PDU ERROR SLOT NOT EMPTY %d=0x%04X\n", rlcP->rb_id, index, index);
display_retransmission_buffer (rlcP);
#endif
free_mem_block (rlcP->retransmission_buffer[index]);
}
rlcP->retransmission_buffer[index] = pduP;
#ifdef DEBUG_BUFFER_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] INSERT PDU INDEX=0x%04X %p\n", rlcP->rb_id, indexP, pduP);
#endif
return;
}
free_mem_block (pduP);
//#ifdef DEBUG_BUFFER_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] ERROR INSERT RETRANS INVALID INDEX in array decimal %d\n", rlcP->rb_id, index);
//#endif
}
//-----------------------------------------------------------------------------
inline uint8_t
retransmit_pdu (struct rlc_am_entity* rlcP, uint16_t snP)
{
//-----------------------------------------------------------------------------
mem_block_t* pdu, *copy;
struct rlc_am_tx_data_pdu_management* pdu_mngt;
uint16_t index;
if ((rlcP->protocol_state & RLC_DATA_TRANSFER_READY_STATE)) {
index = snP % rlcP->recomputed_configured_tx_window_size;
pdu = rlcP->retransmission_buffer[index];
if (pdu) {
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) (pdu->data);
pdu_mngt->vt_dat += 1;
// if first retransmission, add to buffer occupancy
if (pdu_mngt->vt_dat == 1) {
rlcP->buffer_occupancy_retransmission_buffer += 1;
}
if ((pdu_mngt->vt_dat < rlcP->max_dat) || ((rlcP->sdu_discard_mode & SDU_DISCARD_MODE_TIMER_BASED_EXPLICIT))) {
// now check if a copy of the pdu is not already present in the retransmission buffer
if (pdu_mngt->copy == NULL) {
copy = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (copy) {
memcpy (copy->data, pdu->data, rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation));
list2_add_tail (copy, &rlcP->retransmission_buffer_to_send);
// make link between the original pdu and its copy
pdu_mngt->copy = copy;
((struct rlc_am_tx_data_pdu_management*) (copy->data))->copy = pdu;
#ifdef BENCH_QOS_L2
fprintf (bench_l2, "[PDU RETRANS] FRAME %d SN %d VT_DAT %d RLC-AM %p\n", Mac_rlc_xface->frame, snP, pdu_mngt->vt_dat, rlcP);
#endif
#ifdef DEBUG_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] PDU SN = 0x%04X hex VT(DAT) %d frame %d\n", rlcP->rb_id, snP, pdu_mngt->vt_dat, Mac_rlc_xface->frame);
#endif
return 0;
} else {
msg ("[RLC_AM][RB %d][RETRANSMISSION] ERROR retransmit_pdu() retransmited copy of pdu is NULL index in array %04X\n", rlcP->rb_id, index);
return RLC_AM_OUT_OF_MEMORY_ERROR;
}
} else {
#ifdef DEBUG_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] PDU SN = 0x%04X hex VT(DAT) %d already in retransmission buffer to send\n", rlcP->rb_id, snP, pdu_mngt->vt_dat);
#endif
return RLC_AM_RETRANS_REQ_PDU_DONE_BEFORE;
}
} else {
if ((rlcP->sdu_discard_mode & SDU_DISCARD_MODE_TIMER_BASED_EXPLICIT)) {
// DO NOTHING
} else if ((rlcP->sdu_discard_mode & RLC_SDU_DISCARD_MAX_DAT_RETRANSMISSION)) {
#ifdef DEBUG_RETRANSMISSION
msg ("[RLC_AM][RB %d][RETRANSMISSION] VT(DAT) %d REACHED MAX_DAT, DISCARD PROCEDURE WILL BE STARTED frame %d\n", rlcP->rb_id, pdu_mngt->vt_dat,
Mac_rlc_xface->frame);
#endif
rlc_am_discard_notify_max_dat_pdu (rlcP, pdu);
} else { // if No_discard after MaxDat number of retransmissions is used, the sender shall initiate the
// RLC reset procedure when VT(DAT) >= MaxDAT (from 3GPP TS 25.322 V5.0.0 )
// max transmission reached for this PDU, reset RLC entities
#ifdef DEBUG_RESET
msg ("[RLC_AM][RB %d][RETRANSMISSION] VT(DAT) %d REACHED MAX_DAT, RESET frame %d\n", rlcP->rb_id, pdu_mngt->vt_dat, Mac_rlc_xface->frame);
#endif
send_reset_pdu (rlcP);
}
return -1;
}
} else {
return RLC_AM_RETRANS_REQ_PDU_NULL;
}
}
return -1;
}
//-----------------------------------------------------------------------------
void
rlc_am_get_not_acknowledged_pdu_optimized (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t vt_dat_min = 255;
uint16_t sn;
uint16_t sn_min;
mem_block_t* pdu;
struct rlc_am_tx_data_pdu_management* pdu_mngt;
sn = rlcP->vt_s;
sn_min = sn;
while (sn != rlcP->vt_a) {
sn = (sn - 1) & SN_12BITS_MASK;
pdu = rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size];
if ((pdu)) {
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) (pdu->data);
if (pdu_mngt->vt_dat < vt_dat_min) {
sn_min = sn;
vt_dat_min = pdu_mngt->vt_dat;
}
}
}
if (rlcP->retransmission_buffer[sn_min % rlcP->recomputed_configured_tx_window_size]) {
retransmit_pdu (rlcP, sn_min);
rlcP->stat_tx_retransmit_pdu_unblock += 1;
}
}
//-----------------------------------------------------------------------------
void
rlc_am_get_not_acknowledged_pdu (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t sn;
sn = rlcP->vt_s;
while (sn != rlcP->vt_a) {
sn = (sn - 1) & SN_12BITS_MASK;
if (rlcP->retransmission_buffer[sn % rlcP->recomputed_configured_tx_window_size]) {
retransmit_pdu (rlcP, sn);
rlcP->stat_tx_retransmit_pdu_unblock += 1;
return;
}
}
}
//-----------------------------------------------------------------------------
void
rlc_am_get_not_acknowledged_pdu_vt_s_minus_1 (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
if (rlcP->retransmission_buffer[((rlcP->vt_s - 1) & SN_12BITS_MASK) % rlcP->recomputed_configured_tx_window_size]) {
retransmit_pdu (rlcP, (rlcP->vt_s - 1) & SN_12BITS_MASK);
rlcP->stat_tx_retransmit_pdu_unblock += 1;
}
}
openair2/LAYER2/RLC/AM/rlc_am_retrans_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_retrans_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_RETRANS_PROTO_EXTERN_H__
# define __RLC_AM_RETRANS_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "rlc_am_constants.h"
//-----------------------------------------------------------------------------
extern int16_t retransmission_buffer_management_ack (struct rlc_am_entity *rlcP, uint8_t * sufiP, uint8_t byte_alignedP, int16_t * first_error_indicated_snP);
extern uint8_t *retransmission_buffer_management_bitmap (struct rlc_am_entity *rlcP, uint8_t * bitmap_sufiP, uint8_t byte_alignedP, int16_t * first_error_indicated_snP);
extern uint8_t *retransmission_buffer_management_list (struct rlc_am_entity *rlcP, uint8_t * bitmap_sufiP, uint8_t byte_alignedP, int16_t * first_error_indicated_snP);
extern void free_retransmission_buffer (struct rlc_am_entity *rlcP, uint16_t indexP);
extern void free_retransmission_buffer_no_confirmation (struct rlc_am_entity *rlcP, uint16_t indexP);
extern void insert_into_retransmission_buffer (struct rlc_am_entity *rlcP, uint16_t indexP, mem_block_t * pduP);
extern uint8_t retransmit_pdu (struct rlc_am_entity *rlcP, uint16_t snP);
extern void rlc_am_get_not_acknowledged_pdu (struct rlc_am_entity *rlcP);
extern void rlc_am_get_not_acknowledged_pdu_vt_s_minus_1 (struct rlc_am_entity *rlcP);
extern void rlc_am_get_not_acknowledged_pdu_optimized (struct rlc_am_entity *rlcP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_segment.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_segment.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
//-----------------------------------------------------------------------------
#include "list.h"
#include "rlc_am_entity.h"
#include "rlc_am_structs.h"
#include "rlc_am_constants.h"
#include "rlc_primitives.h"
#include "mem_block.h"
//#define DEBUG_RLC_AM_SEGMENT
//#define DEBUG_RLC_AM_SEGMENT_FILL_DATA
//#define DEBUG_MEM_MNGT
//-----------------------------------------------------------------------------
mem_block_t* rlc_am_segment_15 (struct rlc_am_entity* rlcP);
mem_block_t* rlc_am_segment_7 (struct rlc_am_entity* rlcP);
//-----------------------------------------------------------------------------
inline void
rlc_am_encode_pdu_15 (struct rlc_am_pdu_header* rlc_headerP, struct rlc_am_tx_data_pdu_management* pdu_mngtP, uint16_t* li_arrayP, uint8_t nb_liP)
{
//-----------------------------------------------------------------------------
uint8_t li_index;
#ifdef DEBUG_RLC_AM_SEGMENT
int index;
msg ("[RLC_AM] SEGMENT_15 PDU SET LIs: ");
for (index = 0; index < nb_liP; index++) {
msg ("%04X ", li_arrayP[index]);
}
msg ("\n");
#endif
rlc_headerP->byte1 = RLC_DC_DATA_PDU;
rlc_headerP->byte2 = 0;
nb_liP = nb_liP << 1;
pdu_mngtP->payload = (uint8_t*) ((uint32_t) (&rlc_headerP->li_data_7[nb_liP]));
if (nb_liP) {
rlc_headerP->byte2 |= RLC_E_NEXT_FIELD_IS_LI_E;
li_index = 0;
// COPY LI
while (li_index < nb_liP) {
rlc_headerP->li_data_7[li_index] = li_arrayP[li_index >> 1] >> 8;
li_index += 1;
rlc_headerP->li_data_7[li_index] = li_arrayP[li_index >> 1] | RLC_E_NEXT_FIELD_IS_LI_E;
li_index += 1;
}
rlc_headerP->li_data_7[li_index - 1] = rlc_headerP->li_data_7[li_index - 1] ^ (uint8_t) RLC_E_NEXT_FIELD_IS_LI_E;
}
}
//-----------------------------------------------------------------------------
inline void
rlc_am_encode_pdu_7 (struct rlc_am_pdu_header* rlc_headerP, struct rlc_am_tx_data_pdu_management* pdu_mngtP, uint16_t* li_arrayP, uint8_t nb_liP)
{
//-----------------------------------------------------------------------------
uint8_t li_index;
#ifdef DEBUG_RLC_AM_SEGMENT
int index;
msg ("[RLC_AM] SEGMENT_7 PDU %p SET LIs: ", pdu_mngtP);
for (index = 0; index < nb_liP; index++) {
msg ("%04X ", li_arrayP[index]);
}
msg ("\n");
#endif
rlc_headerP->byte1 = RLC_DC_DATA_PDU;
rlc_headerP->byte2 = 0;
pdu_mngtP->payload = (uint8_t*) ((uint32_t) (&rlc_headerP->li_data_7[nb_liP]));
if (nb_liP) {
rlc_headerP->byte2 |= RLC_E_NEXT_FIELD_IS_LI_E;
li_index = 0;
// COPY LI
while (li_index < nb_liP) {
rlc_headerP->li_data_7[li_index] = (uint8_t) (li_arrayP[li_index]) | RLC_E_NEXT_FIELD_IS_LI_E;
li_index += 1;
}
rlc_headerP->li_data_7[li_index - 1] = rlc_headerP->li_data_7[li_index - 1] ^ (uint8_t) RLC_E_NEXT_FIELD_IS_LI_E;
}
}
//-----------------------------------------------------------------------------
inline void
rlc_am_fill_pdu (mem_block_t* pduP, list_t* segmented_sdusP)
{
//-----------------------------------------------------------------------------
mem_block_t* sdu;
uint8_t* data_sdu;
uint8_t* data_pdu;
struct rlc_am_pdu_header* rlc_header;
struct rlc_am_tx_data_pdu_management* pdu_mngt;
struct rlc_am_tx_sdu_management* sdu_mngt;
int continue_fill;
uint16_t pdu_remaining_size;
uint16_t sdu_available_size;
sdu = NULL;
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) (pduP->data);
rlc_header = (struct rlc_am_pdu_header*) (pdu_mngt->first_byte);
pdu_remaining_size = pdu_mngt->data_size;
data_pdu = (uint8_t*) pdu_mngt->payload;
#ifdef DEBUG_RLC_AM_SEGMENT_FILL_DATA
msg ("[RLC_AM] SEGMENT FILL GET PDU %p REMAINING SIZE=%d\n", pduP, pdu_remaining_size);
#endif
continue_fill = 1;
while ((continue_fill)) {
// fill the pdu with data of sdu
if (sdu == NULL) {
sdu = list_remove_head (segmented_sdusP);
if (sdu == NULL) {
return; // case pdu only 2 LIs : exactly_filled or one_byte_short + paddind
}
sdu_mngt = (struct rlc_am_tx_sdu_management*) (sdu->data);
data_sdu = &sdu->data[sizeof (struct rlc_am_tx_sdu_management) + sdu_mngt->sdu_segmented_size];
sdu_available_size = sdu_mngt->sdu_size - sdu_mngt->sdu_remaining_size - sdu_mngt->sdu_segmented_size;
#ifdef DEBUG_RLC_AM_SEGMENT_FILL_DATA
msg ("[RLC_AM] SEGMENT FILL GET SDU %p AVAILABLE_SZ=%d (SZ %d REMAIN_SZ %d SEGMENT_SZ %d)\n",
sdu, sdu_available_size, sdu_mngt->sdu_size, sdu_mngt->sdu_remaining_size, sdu_mngt->sdu_segmented_size);
#endif
}
// copy the whole remaining data of the sdu in the remaining area of the pdu
if (pdu_remaining_size >= sdu_available_size) {
memcpy (data_pdu, data_sdu, sdu_available_size);
#ifdef DEBUG_RLC_AM_SEGMENT_FILL_DATA
msg ("[RLC_AM] SEGMENT FILL PDU %p WITH SDU %p %p <- %p %d bytes (SZ %d REMAIN_SZ %d SEGMENT_SZ %d)\n",
pduP, sdu, data_pdu, data_sdu, sdu_available_size, sdu_mngt->sdu_size, sdu_mngt->sdu_remaining_size, sdu_mngt->sdu_segmented_size);
#endif
pdu_remaining_size -= sdu_available_size;
sdu_mngt->sdu_segmented_size += sdu_available_size;
data_pdu = (uint8_t*) ((uint32_t) data_pdu + sdu_available_size);
sdu_available_size = 0;
// dispatch the sdu
sdu = NULL;
// dispatch the pdu
if (pdu_remaining_size == 0) {
continue_fill = 0;
} else {
}
// copy some data of the sdu in the whole remaining area of the pdu
} else {
memcpy (data_pdu, data_sdu, pdu_remaining_size);
#ifdef DEBUG_RLC_AM_SEGMENT_FILL_DATA
msg ("[RLC_AM] SEGMENT FILL PDU %p WITH SDU %p %p <- %p %d bytes (SZ %d REMAIN_SZ %d SEGMENT_SZ %d)\n",
pduP, sdu, data_pdu, data_sdu, pdu_remaining_size, sdu_mngt->sdu_size, sdu_mngt->sdu_remaining_size, sdu_mngt->sdu_segmented_size);
#endif
sdu_mngt->sdu_segmented_size += pdu_remaining_size;
sdu_available_size -= pdu_remaining_size;
data_sdu = (uint8_t*) ((uint32_t) data_sdu + (uint32_t) pdu_remaining_size);
continue_fill = 0;
pdu_remaining_size = 0;
}
}
list_free (segmented_sdusP);
}
//-----------------------------------------------------------------------------
mem_block_t*
rlc_am_segment_15 (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
list_t segmented_sdus; // the copying of sdu data is done after identification of all LIs to put in pdu
struct rlc_am_tx_sdu_management* sdu_mngt;
struct rlc_am_tx_data_pdu_management* pdu_mngt;
struct rlc_am_pdu_header* rlc_header;
mem_block_t* pdu;
int continue_segment = 1;
int16_t pdu_remaining_size;
uint8_t li_index = 0;
pdu = NULL;
list_init (&segmented_sdus, NULL); // param string identifying the list is NULL
while ((rlcP->input_sdus[rlcP->current_sdu_index]) && (continue_segment)) {
sdu_mngt = ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[rlcP->current_sdu_index]->data));
if (!(sdu_mngt->segmented)) {
// pdu management
if (!(pdu)) {
if (!(pdu = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation) + GUARD_CRC_LIH_SIZE))) {
#ifdef DEBUG_MEM_MNGT
msg ("[RLC_AM][RB %d][SEGMENT] ERROR COULD NOT GET NEW PDU, EXIT\n", rlcP->rb_id);
#endif
return NULL;
}
li_index = 0;
pdu_remaining_size = rlcP->pdu_size - 2; // 2= size of header, minimum
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) (pdu->data);
memset (pdu->data, 0, sizeof (struct rlc_am_tx_data_pdu_allocation));
pdu_mngt->rlc_tb_type = RLC_AM_DATA_PDU_TYPE;
pdu_mngt->first_byte = &pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
rlc_header = (struct rlc_am_pdu_header*) (pdu_mngt->first_byte);
}
if (sdu_mngt->sdu_remaining_size > 0) { // think RLC_LI_LAST_PDU_ONE_BYTE_SHORT, RLC_LI_LAST_PDU_EXACTLY_FILLED
if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) < 0) {
pdu_mngt->data_size += pdu_remaining_size;
rlc_am_encode_pdu_15 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
sdu_mngt->sdu_remaining_size = sdu_mngt->sdu_remaining_size - pdu_remaining_size;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
} else {
// From 3GPP TS 25.322 V4.2.0 (2001-09) p28
// If "SDU discard with explicit signalling" is configured:
// - an AMD PDU can contain a maximum number of 15 "Length Indicators" indicating the end
// of 15 corresponding SDUs; and
// - the rest of the AMD PDU space shall be used as padding or as piggybacked STATUS PDU.
// implementation limitation : we limit the number of li to 15 even if
// no "SDU discard with explicit signalling" is configured.
if (li_index >= 14) {
rlcP->li[li_index++] = RLC_LI_PDU_PADDING;
rlc_am_encode_pdu_15 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
sdu_mngt->no_new_sdu_segmented_in_last_pdu = 1;
} else { // nb li have not reached the limit
if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) >= 2) {
pdu_remaining_size = pdu_remaining_size - sdu_mngt->sdu_remaining_size - 2; // size of li length
pdu_mngt->data_size += sdu_mngt->sdu_remaining_size;
sdu_mngt->li_index_for_discard = li_index;
rlcP->li[li_index++] = sdu_mngt->sdu_remaining_size << 1;
sdu_mngt->sdu_remaining_size = 0;
sdu_mngt->segmented = 1;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
pdu_mngt->last_pdu_of_sdu += 1;
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
rlcP->buffer_occupancy -= sdu_mngt->sdu_size;
rlcP->nb_sdu -= 1;
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
//} else the while loop continue with the same pdu
} else if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) == 0) {
// from 3GPP TS 25.322 V4.2.0
//In the case where the end of the last segment of an RLC SDU exactly ends at the end of
// a PDU and there is no "Length Indicator" that indicates the end of the RLC SDU:
// - if 7-bit "Length Indicator" is used:
// - a "Length Indicator" with value "000 0000" shall be placed as the first "Length
// Indicator" in the following PDU;
// - if 15-bit "Length Indicator" is used:
// - a "Length Indicator" with value "000 0000 0000 0000" shall be placed as the first
// "Length Indicator" in the following PDU.
pdu_mngt->data_size += pdu_remaining_size;
rlc_am_encode_pdu_15 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
sdu_mngt->sdu_remaining_size = 0;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
rlcP->li_exactly_filled_to_add_in_next_pdu = 1;
} else if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) == 1) { // one byte remaining
// from 3GPP TS 25.322 V4.2.0
// In the case where a PDU contains a 15-bit "Length Indicator" indicating that an RLC SDU ends with
// one octet left in the PDU, the last octet of this PDU shall:
// - be padded by the Sender and ignored by the Receiver though there is no "Length Indicator"
// indicating the existence of Padding; and
// - not be filled with the first octet of the next RLC SDU data.
// In the case where 15-bit "Length Indicators" are used for the previous PDU and
// the last segment of an RLC SDU is one octet short of exactly filling the PDU:
// - if a 15-bit "Length Indicator" is used for the following PDU:
// - the "Length Indicator" with value "111 1111 1111 1011" shall be placed as
// the first "Length Indicator" in the following PDU;
// - the remaining one octet in the previous PDU shall be padded by the Sender
// and ignored at the Receiver though there is no "Length Indicator" indicating
// the existence of Padding;
// - in case this SDU was the last one to be transmitted:
// - a RLC PDU consisting of an RLC Header with "Length Indicator"
// "111 1111 1111 1011" followed by a padding "Length Indicator" and padding
// may be transmitted;
pdu_mngt->data_size += pdu_remaining_size;
rlc_am_encode_pdu_15 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
sdu_mngt->sdu_remaining_size = 0;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
rlcP->li_one_byte_short_to_add_in_next_pdu = 1;
}
}
}
// management of previous pdu
// In the case where 15-bit "Length Indicators" are used for the previous PDU and
// the last segmentof an RLC SDU is one octet short of exactly filling the PDU:
// - if a 15-bit "Length Indicator" is used for the following PDU:
// - the "Length Indicator" with value "111 1111 1111 1011" shall be placed
// as the first "Length Indicator" in the following PDU;
// - the remaining one octet in the previous PDU shall be padded by the Sender
// and ignored at the Receiver though there is no "Length Indicator" indicating
// the existence of Padding;
// - in case this SDU was the last one to be transmitted:
// - a RLC PDU consisting of an RLC Header with "Length Indicator"
// "111 1111 1111 1011" followed by a padding "Length Indicator" and padding
// may be transmitted;
} else if ((rlcP->li_one_byte_short_to_add_in_next_pdu)) {
sdu_mngt->li_index_for_discard = li_index;
rlcP->li[li_index++] = RLC_LI_LAST_PDU_ONE_BYTE_SHORT;
rlcP->li_one_byte_short_to_add_in_next_pdu = 0;
sdu_mngt->segmented = 1;
pdu_remaining_size -= 2;
pdu_mngt->last_pdu_of_sdu += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
sdu_mngt->nb_pdus += 1;
rlcP->buffer_occupancy -= sdu_mngt->sdu_size;
rlcP->nb_sdu -= 1;
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
} else if ((rlcP->li_exactly_filled_to_add_in_next_pdu)) {
sdu_mngt->li_index_for_discard = li_index;
rlcP->li[li_index++] = RLC_LI_LAST_PDU_EXACTLY_FILLED;
rlcP->li_exactly_filled_to_add_in_next_pdu = 0;
sdu_mngt->segmented = 1;
pdu_remaining_size -= 2;
pdu_mngt->last_pdu_of_sdu += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
sdu_mngt->nb_pdus += 1;
rlcP->buffer_occupancy -= sdu_mngt->sdu_size;
rlcP->nb_sdu -= 1;
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
}
}
if (sdu_mngt->sdu_remaining_size > 0) {
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
}
}
if ((pdu)) {
if ((continue_segment > 0)) { // means pdu not totaly filled
if (pdu_remaining_size >= 2) {
rlcP->li[li_index++] = RLC_LI_PDU_PADDING;
sdu_mngt->no_new_sdu_segmented_in_last_pdu = 1;
} else if (pdu_remaining_size == 0) {
rlcP->li_exactly_filled_to_add_in_next_pdu = 1;
} else if (pdu_remaining_size == 1) {
rlcP->li_one_byte_short_to_add_in_next_pdu = 1;
}
rlc_am_encode_pdu_15 (rlc_header, pdu_mngt, rlcP->li, li_index);
}
rlc_am_fill_pdu (pdu, &segmented_sdus);
} else {
// patch for max dat discard : avoid waiting sdu pointed by current_sdu_index <> NULL
// (this sdu may have been segmented not at all then discarded)
while ((rlcP->next_sdu_index != rlcP->current_sdu_index) && (rlcP->input_sdus[rlcP->current_sdu_index] == NULL)) {
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
rlcP->nb_sdu -= 1;
}
}
return pdu;
}
//-----------------------------------------------------------------------------
mem_block_t*
rlc_am_segment_7 (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
list_t segmented_sdus; // the copying of sdu data is done after identification of all LIs to put in pdu
struct rlc_am_tx_sdu_management* sdu_mngt = NULL;
struct rlc_am_tx_data_pdu_management* pdu_mngt;
struct rlc_am_pdu_header* rlc_header;
mem_block_t* pdu = NULL;
int continue_segment = 1;
int16_t pdu_remaining_size;
uint8_t li_index = 0;
list_init (&segmented_sdus, NULL); // param string identifying the list is NULL
while ((rlcP->input_sdus[rlcP->current_sdu_index]) && (continue_segment)) {
sdu_mngt = ((struct rlc_am_tx_sdu_management*) (rlcP->input_sdus[rlcP->current_sdu_index]->data));
if (!(sdu_mngt->segmented)) {
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d] SEGMENT GET NEW SDU %p INDEX %d AVAILABLE SIZE %d Bytes\n", rlcP->rb_id, sdu_mngt, rlcP->current_sdu_index, sdu_mngt->sdu_remaining_size);
#endif
if (!(pdu)) {
// pdu management
if (!(pdu = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_data_pdu_allocation) + GUARD_CRC_LIH_SIZE))) {
#ifdef DEBUG_MEM_MNGT
msg ("[RLC_AM][RB %d][SEGMENT7] ERROR COULD NOT GET NEW PDU, EXIT\n", rlcP->rb_id);
#endif
return NULL;
}
li_index = 0;
pdu_remaining_size = rlcP->pdu_size - 2; // 2= size of header, minimum
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) (pdu->data);
memset (pdu->data, 0, sizeof (struct rlc_am_tx_data_pdu_allocation));
pdu_mngt->rlc_tb_type = RLC_AM_DATA_PDU_TYPE;
pdu_mngt->first_byte = &pdu->data[sizeof (struct rlc_am_tx_data_pdu_allocation)];
rlc_header = (struct rlc_am_pdu_header*) (pdu_mngt->first_byte);
if ((rlcP->li_exactly_filled_to_add_in_next_pdu)) {
pdu_remaining_size -= 1;
}
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d][SEGMENT7] CONSTRUCT NEW PDU %p %p\n", rlcP->rb_id, pdu, pdu_mngt);
#endif
}
if (sdu_mngt->sdu_remaining_size > 0) {
msg("sdu_mngt->sdu_remaining_size %d\n",sdu_mngt->sdu_remaining_size);
if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) < 0) {
pdu_mngt->data_size += pdu_remaining_size;
rlcP->buffer_occupancy -= pdu_remaining_size;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
rlc_am_encode_pdu_7 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
sdu_mngt->sdu_remaining_size = sdu_mngt->sdu_remaining_size - pdu_remaining_size;
pdu_remaining_size = 0;
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d][SEGMENT7] PDU %p %p FILLED WITH SDU index %d SDU REMAINING %d\n", rlcP->rb_id, pdu, pdu_mngt, rlcP->current_sdu_index,
sdu_mngt->sdu_remaining_size);
#endif
} else {
// From 3GPP TS 25.322 V4.2.0 (2001-09) p28
// If "SDU discard with explicit signalling" is configured:
// - an AMD PDU can contain a maximum number of 15 "Length Indicators" indicating the end
// of 15 corresponding SDUs; and
// - the rest of the AMD PDU space shall be used as padding or as piggybacked STATUS PDU.
// implementation limitation : we limit the number of li to 15 even if
// no "SDU discard with explicit signalling" is configured.
if (li_index >= 14) {
rlcP->li[li_index++] = RLC_LI_PDU_PADDING;
rlc_am_encode_pdu_7 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
sdu_mngt->no_new_sdu_segmented_in_last_pdu = 1;
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d][SEGMENT7] NB MAX LI REACHED\n", rlcP->rb_id);
#endif
} else { // nb li have not reached the limit
if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) >= 1) {
pdu_remaining_size = pdu_remaining_size - sdu_mngt->sdu_remaining_size - 1; // size of li length
pdu_mngt->data_size += sdu_mngt->sdu_remaining_size;
sdu_mngt->li_index_for_discard = li_index;
rlcP->li[li_index++] = sdu_mngt->sdu_remaining_size << 1;
rlcP->buffer_occupancy -= sdu_mngt->sdu_remaining_size;
sdu_mngt->sdu_remaining_size = 0;
sdu_mngt->segmented = 1;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
pdu_mngt->last_pdu_of_sdu += 1;
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
rlcP->nb_sdu -= 1;
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d][SEGMENT7] SDU index %d->%d ENDING IN PDU %p %p PDU REMAINING SIZE %d\n", rlcP->rb_id,
rlcP->current_sdu_index, (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer, pdu, pdu_mngt, pdu_remaining_size);
#endif
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
// case where Li length exactly ends the pdu
if (pdu_remaining_size == 0) {
continue_segment = 0;
rlc_am_encode_pdu_7 (rlc_header, pdu_mngt, rlcP->li, li_index);
}
/*
} else { // else:if (!last_sdu)
} // the while loop continue with the same pdu */
} else if ((pdu_remaining_size - sdu_mngt->sdu_remaining_size) == 0) {
// from 3GPP TS 25.322 V4.2.0
//In the case where the end of the last segment of an RLC SDU exactly ends at the end of
// a PDU and there is no "Length Indicator" that indicates the end of the RLC SDU:
// - if 7-bit "Length Indicator" is used:
// - a "Length Indicator" with value "000 0000" shall be placed as the first "Length
// Indicator" in the following PDU;
// - if 15-bit "Length Indicator" is used:
// - a "Length Indicator" with value "000 0000 0000 0000" shall be placed as the first
// "Length Indicator" in the following PDU.
pdu_mngt->data_size += pdu_remaining_size;
rlc_am_encode_pdu_7 (rlc_header, pdu_mngt, rlcP->li, li_index);
continue_segment = 0;
rlcP->buffer_occupancy -= sdu_mngt->sdu_remaining_size;
sdu_mngt->sdu_remaining_size = 0;
pdu_remaining_size = 0;
sdu_mngt->nb_pdus += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
rlcP->li_exactly_filled_to_add_in_next_pdu = 1;
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d][SEGMENT7] SDU index %d EXACTLY ENDING IN PDU %p %p\n", rlcP->rb_id, rlcP->current_sdu_index, pdu, pdu_mngt);
#endif
}
}
}
// management of previous pdu
// In the case where 15-bit "Length Indicators" are used for the previous PDU and the
// last segment of an RLC SDU is one octet short of exactly filling the PDU:
// - if a 15-bit "Length Indicator" is used for the following PDU:
// - the "Length Indicator" with value "111 1111 1111 1011" shall be placed as
// the first "Length Indicator" in the following PDU;
// - the remaining one octet in the previous PDU shall be padded by the Sender and
// ignored at the Receiver
// though there is no "Length Indicator" indicating the existence of Padding;
// - in case this SDU was the last one to be transmitted:
// - a RLC PDU consisting of an RLC Header with "Length Indicator"
// "111 1111 1111 1011" followed by a padding "Length Indicator" and padding
// may be transmitted;
// - if a 7-bit "Length Indicator" is used for the following PDU:
// - if RLC is configured for UM mode:
// - the "Length Indicator" with value "000 0000" shall be placed as the first
// "Length indicator" in the following PDU and its SN shall be incremented by 2
// before it is transmitted.
} else if ((rlcP->li_exactly_filled_to_add_in_next_pdu)) {
sdu_mngt->li_index_for_discard = li_index;
rlcP->li[li_index++] = RLC_LI_LAST_PDU_EXACTLY_FILLED;
rlcP->li_exactly_filled_to_add_in_next_pdu = 0;
sdu_mngt->segmented = 1;
//pdu_remaining_size -= 1;
pdu_mngt->last_pdu_of_sdu += 1;
pdu_mngt->sdu[pdu_mngt->nb_sdu++] = rlcP->current_sdu_index;
sdu_mngt->nb_pdus += 1;
//rlcP->buffer_occupancy -= sdu_mngt->sdu_size;
rlcP->nb_sdu -= 1;
#ifdef DEBUG_RLC_AM_SEGMENT
msg ("[RLC_AM][RB %d][SEGMENT7] RLC_LI_LAST_PDU_EXACTLY_FILLED -> PDU %p, %p, sdu index %d->%d \n", rlcP->rb_id, pdu, pdu_mngt,
rlcP->current_sdu_index, (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer);
#endif
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
}
}
if (sdu_mngt->sdu_remaining_size > 0) {
list_add_tail_eurecom (rlcP->input_sdus[rlcP->current_sdu_index], &segmented_sdus);
}
}
if ((pdu)) {
if ((continue_segment > 0)) { // means pdu not totaly filled
if (pdu_remaining_size >= 1) {
rlcP->li[li_index++] = RLC_LI_PDU_PADDING;
sdu_mngt->no_new_sdu_segmented_in_last_pdu = 1;
} else {
rlcP->li_exactly_filled_to_add_in_next_pdu = 1;
}
rlc_am_encode_pdu_7 (rlc_header, pdu_mngt, rlcP->li, li_index);
}
rlc_am_fill_pdu (pdu, &segmented_sdus);
} else {
// patch for max dat discard : avoid waiting sdu pointed by current_sdu_index <> NULL
// (this sdu may have been segmented not at all then discarded)
while ((rlcP->next_sdu_index != rlcP->current_sdu_index) && (rlcP->input_sdus[rlcP->current_sdu_index] == NULL)) {
rlcP->current_sdu_index = (rlcP->current_sdu_index + 1) % rlcP->size_input_sdus_buffer;
rlcP->nb_sdu -= 1;
}
}
return pdu;
}
openair2/LAYER2/RLC/AM/rlc_am_segment_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_segment_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_SEGMENT_PROTO_EXTERN_H__
# define __RLC_AM_SEGMENT_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "rlc_am_constants.h"
# include "list.h"
//-----------------------------------------------------------------------------
extern inline uint16_t rlc_am_get_next_sn (struct rlc_am_entity *rlcP, uint16_t snP);
extern inline int rlc_am_sn_in_tx_window (struct rlc_am_entity *rlcP, uint16_t snP);
extern inline void rlc_am_sdu_confirm_map_register_pdu (mem_block_t * pduP, struct rlc_am_pdu_header *rlc_headerP, mem_block_t * sdu_header_confirm_copyP);
extern inline void rlc_am_sdu_discard_map_register_pdu (mem_block_t * pduP, struct rlc_am_pdu_header *rlc_headerP, mem_block_t * sdu_header_discard_copyP);
extern mem_block_t *rlc_am_segment_15 (struct rlc_am_entity *rlcP);
extern mem_block_t *rlc_am_segment_7 (struct rlc_am_entity *rlcP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_status.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_status.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_retrans_proto_extern.h"
#include "rlc_am_status_proto_extern.h"
#include "rlc_am_discard_rx_proto_extern.h"
#include "rlc_am_proto_extern.h"
#include "rlc_am_util_proto_extern.h"
#include "LAYER2/MAC/extern.h"
//#define DEBUG_CREATE_STATUS
//#define DEBUG_CREATE_STATUS_SUFI
//#define PROCESS_STATUS
void rlc_am_write_sufi_no_more_in_control_pdu (uint8_t * dataP, uint8_t byte_alignedP);
void rlc_am_write_sufi_ack_in_control_pdu (uint8_t * dataP, uint16_t snP, uint8_t byte_alignedP);
int rlc_am_send_status (struct rlc_am_entity *rlcP);
int rlc_am_create_status_pdu (struct rlc_am_entity *rlcP, list_t* listP);
void rlc_am_find_holes (struct rlc_am_entity *rlcP);
//-----------------------------------------------------------------------------
void
rlc_am_write_sufi_no_more_in_control_pdu (uint8_t * dataP, uint8_t byte_alignedP)
{
//-----------------------------------------------------------------------------
#ifdef DEBUG_CREATE_STATUS_SUFI
msg ("[RLC_AM][STATUS] GENERATE SUFI NO_MORE\n");
#endif
if (!byte_alignedP) {
*dataP = (*dataP & 0xF0) | RLC_AM_SUFI_NO_MORE;
} else {
*dataP = RLC_AM_SUFI_NO_MORE << 4;
}
}
//-----------------------------------------------------------------------------
void
rlc_am_write_sufi_ack_in_control_pdu (uint8_t * dataP, uint16_t snP, uint8_t byte_alignedP)
{
//-----------------------------------------------------------------------------
#ifdef DEBUG_CREATE_STATUS_SUFI
msg ("[RLC_AM][STATUS] GENERATE SUFI ACK 0x%04X\n", snP);
#endif
if (!byte_alignedP) {
*dataP = (*dataP & 0xF0) | RLC_AM_SUFI_ACK;
dataP++;
*dataP++ = (uint8_t) (snP >> 4);
*dataP = (uint8_t) (snP << 4);
} else {
*dataP = RLC_AM_SUFI_ACK << 4;
*dataP = *dataP | (uint8_t) (snP >> 8);
dataP++;
*dataP = (uint8_t) (snP);
}
}
//-----------------------------------------------------------------------------
int
rlc_am_send_status (struct rlc_am_entity *rlcP)
{
//-----------------------------------------------------------------------------
#ifdef DEBUG_CREATE_STATUS
display_receiver_buffer (rlcP);
#endif
if (rlcP->timer_status_prohibit > 0) {
if (rlcP->running_timer_status_prohibit > Mac_rlc_xface->frame) {
//msg ("[RLC_AM][RB %d][STATUS] PREVENTED CREATE_STATUS_PDU %d %d\n", rlcP->rb_id, rlcP->running_timer_status_prohibit, Mac_rlc_xface->frame);
return 0;
} else {
//msg ("[RLC_AM][RB %d][STATUS] AUTHORIZE CREATE_STATUS_PDU frame %d timer %d timeout %d\n", rlcP->rb_id, Mac_rlc_xface->frame, rlcP->running_timer_status_prohibit, rlcP->timer_status_prohibit);
rlcP->running_timer_status_prohibit = rlcP->timer_status_prohibit/10 + Mac_rlc_xface->frame;
}
}
// sufis are created in a array of sufi in rlc struct;
rlc_am_find_holes (rlcP);
// create pdu with array of sufi previously generated;
return rlc_am_create_status_pdu (rlcP, &rlcP->control);
}
//-----------------------------------------------------------------------------
int
rlc_am_create_status_pdu (struct rlc_am_entity *rlcP, list_t * listP)
{
//-----------------------------------------------------------------------------
mem_block_t *mb = NULL;
struct rlc_am_status_header *pdu;
uint8_t *p8;
uint8_t *tmp;
int hole_index = 0;
signed int pdu_remaining_size; // remaining size for SUFIs BITMAP, LIST, RLIST, WINDOW
int current_sn;
signed int remaining_sn;
int pdu_status_count = 0;
int length_sufi;
int16_t last_hole_sn = -1;
uint8_t byte_aligned;
remaining_sn = rlcP->vr_h - rlcP->vr_r;
if (remaining_sn < 0) {
remaining_sn = remaining_sn + SN_12BITS_MASK + 1;
}
while ((rlcP->holes[hole_index].valid) && (remaining_sn)) {
if (!(mb)) {
mb = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (mb == NULL) {
msg ("[MEM_MNGT] ERROR create_status_pdu() no free blocks\n");
return 0;
} else {
pdu_status_count += 1;
#ifdef DEBUG_CREATE_STATUS
msg ("[RLC_AM][RB %d][STATUS] CREATE_STATUS_PDU %d\n", rlcP->rb_id, pdu_status_count);
#endif
memset (mb->data, 0, rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation));
if (pdu_status_count == 1) {
((struct rlc_am_tx_control_pdu_management *) (mb->data))->rlc_tb_type = RLC_AM_FIRST_STATUS_PDU_TYPE;
} else {
((struct rlc_am_tx_control_pdu_management *) (mb->data))->rlc_tb_type = RLC_AM_STATUS_PDU_TYPE;
}
pdu = (struct rlc_am_status_header *) (&mb->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
pdu->byte1 = RLC_PDU_TYPE_STATUS;
p8 = &(pdu->byte1);
// if first pdu of status include ack field
if (pdu_status_count == 1) {
pdu_remaining_size = (rlcP->pdu_size << 3) - 16; //-4(PDU_TYPE) -12(SUFI ACK)
current_sn = rlcP->ack_sn;
remaining_sn = rlcP->vr_h - rlcP->vr_r;
if (remaining_sn < 0) {
remaining_sn = remaining_sn + SN_12BITS_MASK + 1;
}
} else {
pdu_remaining_size = (rlcP->pdu_size << 3) - 8; //-4(PDU_TYPE) - 4(SUFI NO_MORE)
}
byte_aligned = 0;
}
}
// From 3GPP TS 25.322 V4.2.0 :
// Which SUFI fields to use is implementation dependent,...
// IMPLEMENTATION : KEEP GENERATION OF SUFI SIMPLE : GENERATE ONLY LIST
if (pdu_remaining_size >= RLC_AM_SUFI_LIST_SIZE_MIN) {
//----------------------------------
// generate LIST
//----------------------------------
if (!byte_aligned) {
*p8 = *p8 | RLC_AM_SUFI_LIST;
p8 = p8 + 1;
tmp = p8; //(*tmp = length_sufi << 4) when we will know length
length_sufi = 0;
pdu_remaining_size -= 8;
while ((length_sufi < 15) && (pdu_remaining_size >= 16) && (rlcP->holes[hole_index].valid) && (rlcP->nb_missing_pdus)) {
#ifdef DEBUG_CREATE_STATUS
msg ("[RLC_AM][RB %d][STATUS] GENERATE SUFI LIST HOLE START 0x%04X ", rlcP->rb_id, rlcP->holes[hole_index].fsn);
#endif
*p8 = *p8 | (rlcP->holes[hole_index].fsn >> 8);
p8 += 1;
*p8 = rlcP->holes[hole_index].fsn;
p8 += 1;
if (rlcP->holes[hole_index].length <= 15) {
*p8 = rlcP->holes[hole_index].length << 4;
#ifdef DEBUG_CREATE_STATUS
msg ("LENGTH %d\n", rlcP->holes[hole_index].length);
#endif
rlcP->nb_missing_pdus -= rlcP->holes[hole_index].length;
current_sn = (rlcP->holes[hole_index].fsn + rlcP->holes[hole_index].length) & SN_12BITS_MASK;
last_hole_sn = (rlcP->holes[hole_index].fsn + rlcP->holes[hole_index].length) & SN_12BITS_MASK;
hole_index += 1;
} else {
#ifdef DEBUG_CREATE_STATUS
msg ("LENGTH 15\n");
#endif
*p8 = 0xF0;
rlcP->nb_missing_pdus -= 15;
rlcP->holes[hole_index].length -= 15;
rlcP->holes[hole_index].fsn = (rlcP->holes[hole_index].fsn + 15) & SN_12BITS_MASK;
current_sn = rlcP->holes[hole_index].fsn;
}
length_sufi += 1;
pdu_remaining_size -= 16;
}
*tmp = *tmp | (length_sufi << 4);
} else {
*p8 = RLC_AM_SUFI_LIST << 4;
tmp = p8; //(*tmp = length_sufi) when we will know length
p8 = p8 + 1;
length_sufi = 0;
pdu_remaining_size -= 8;
while ((length_sufi < 15) && (pdu_remaining_size >= 16) && (rlcP->holes[hole_index].valid) && (rlcP->nb_missing_pdus)) {
#ifdef DEBUG_CREATE_STATUS
msg ("[RLC_AM][RB %d][STATUS] GENERATE SUFI LIST HOLE START 0x%04X ", rlcP->rb_id, rlcP->holes[hole_index].fsn);
#endif
*p8 = rlcP->holes[hole_index].fsn >> 4;
p8 += 1;
*p8 = rlcP->holes[hole_index].fsn << 4;
if (rlcP->holes[hole_index].length <= 15) {
#ifdef DEBUG_CREATE_STATUS
msg ("LENGTH %d\n", rlcP->holes[hole_index].length);
#endif
*p8 = *p8 | rlcP->holes[hole_index].length;
p8 += 1;
rlcP->nb_missing_pdus -= rlcP->holes[hole_index].length;
current_sn = (rlcP->holes[hole_index].fsn + rlcP->holes[hole_index].length) & SN_12BITS_MASK;
last_hole_sn = (rlcP->holes[hole_index].fsn + rlcP->holes[hole_index].length) & SN_12BITS_MASK;
hole_index += 1;
} else {
#ifdef DEBUG_CREATE_STATUS
msg ("LENGTH 15\n");
#endif
*p8 = *p8 | 15;
p8 += 1;
rlcP->nb_missing_pdus -= 15;
rlcP->holes[hole_index].length -= 15;
rlcP->holes[hole_index].fsn = (rlcP->holes[hole_index].fsn + 15) & SN_12BITS_MASK;
}
length_sufi += 1;
pdu_remaining_size -= 16;
}
*tmp = *tmp | length_sufi;
}
} else {
// it is not possible to write a sufi LIST in this control pdu, so close this pdu (write ACK or NO_MORE)
if (pdu_status_count == 1) {
//rlc_am_write_sufi_ack_in_control_pdu(p8, current_sn, byte_aligned);
if (last_hole_sn > 0) {
rlc_am_write_sufi_ack_in_control_pdu (p8, last_hole_sn, byte_aligned);
} else {
rlc_am_write_sufi_ack_in_control_pdu (p8, current_sn, byte_aligned);
}
} else {
rlc_am_write_sufi_no_more_in_control_pdu (p8, byte_aligned);
}
//hole_index += 1;
list_add_tail_eurecom (mb, listP);
mb = NULL;
}
remaining_sn = rlcP->vr_h - current_sn;
if (remaining_sn < 0) {
remaining_sn = remaining_sn + SN_12BITS_MASK + 1;
}
}
if ((mb == NULL) && !(pdu_status_count)) {
mb = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (mb == NULL) {
msg ("[MEM_MNGT] ERROR create_status_pdu() no free blocks\n");
return 0;
} else {
#ifdef DEBUG_CREATE_STATUS
msg ("[RLC_AM][RB %d][STATUS] CREATE_STATUS_PDU %d\n", rlcP->rb_id, pdu_status_count + 1);
#endif
memset (mb->data, 0, rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation));
((struct rlc_am_tx_control_pdu_management *) (mb->data))->rlc_tb_type = RLC_AM_FIRST_STATUS_PDU_TYPE | RLC_AM_LAST_STATUS_PDU_TYPE;
pdu = (struct rlc_am_status_header *) (&mb->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
pdu->byte1 = RLC_PDU_TYPE_STATUS;
p8 = &(pdu->byte1);
byte_aligned = 0;
rlc_am_write_sufi_ack_in_control_pdu (p8, rlcP->ack_sn, byte_aligned);
list_add_tail_eurecom (mb, listP);
}
} else if ((mb)) {
// if first pdu insert ack field updated to last sn referenced by a sufi in this pdu
// else insert no more field
((struct rlc_am_tx_control_pdu_management *) (mb->data))->rlc_tb_type |= RLC_AM_LAST_STATUS_PDU_TYPE;
if (pdu_status_count == 1) {
if (last_hole_sn > 0) {
rlc_am_write_sufi_ack_in_control_pdu (p8, last_hole_sn, byte_aligned);
} else {
rlc_am_write_sufi_ack_in_control_pdu (p8, current_sn, byte_aligned);
}
} else {
rlc_am_write_sufi_no_more_in_control_pdu (p8, byte_aligned);
}
list_add_tail_eurecom (mb, listP);
}
return 1;
}
//-----------------------------------------------------------------------------
void
rlc_am_find_holes (struct rlc_am_entity *rlcP)
{
//-----------------------------------------------------------------------------
uint16_t working_sn, working_sn_index;
uint16_t end_sn;
uint16_t distance;
int hole_index;
//--------------------------------------------------
// FIND HOLES
//--------------------------------------------------
hole_index = 0;
// ACK
rlcP->ack_sn = rlcP->vr_r;
// HOLES
rlcP->holes[0].valid = 0;
rlcP->nb_missing_pdus = 0;
working_sn = rlcP->vr_r;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
end_sn = rlcP->vr_h;
while (working_sn != end_sn) {
if ((rlcP->receiver_buffer[working_sn_index])) {
// UPDATE ACK FIELD :
if (rlcP->ack_sn == working_sn) {
rlcP->ack_sn = (working_sn + 1) & SN_12BITS_MASK;
}
// STOP PREVIOUS HOLE IF ANY
if (rlcP->holes[hole_index].valid) {
hole_index += 1;
rlcP->holes[hole_index].valid = 0;
}
} else {
// CONTINUE PREVIOUS HOLE IF ANY
if (rlcP->holes[hole_index].valid) {
rlcP->holes[hole_index].length += 1;
rlcP->nb_missing_pdus += 1;
// START HOLE IF ANY
} else {
#ifdef DEBUG_RLC_AM_FIND_HOLE
msg ("[RLC_AM %p] FOUND HOLE %d START 0x%04x(hex)\n", rlcP, hole_index, working_sn);
#endif
if (hole_index > 0) {
distance = working_sn - rlcP->holes[hole_index - 1].fsn;
if (distance & 0x8000) { // < 0
rlcP->holes[hole_index - 1].dist_to_next = distance + SN_12BITS_MASK + 1;
} else {
rlcP->holes[hole_index - 1].dist_to_next = distance;
}
}
rlcP->holes[hole_index].valid = 1;
rlcP->holes[hole_index + 1].valid = 0;
rlcP->holes[hole_index].fsn = working_sn;
rlcP->holes[hole_index].length = 1;
rlcP->nb_missing_pdus += 1;
}
}
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
}
// compute the number of holes
if (rlcP->holes[hole_index].valid) {
rlcP->nb_holes = hole_index;
} else {
if (hole_index > 0) {
rlcP->nb_holes = hole_index - 1;
} else {
rlcP->nb_holes = 0;
}
}
}
//-----------------------------------------------------------------------------
void
rlc_am_process_status_info (struct rlc_am_entity *rlcP, uint8_t * statusP)
{
//-----------------------------------------------------------------------------
uint8_t *byte1;
uint8_t byte_aligned; // 1: quartet starts on bit 7, 0: quartet starts on bit 3 (of a byte)
uint8_t sufi_type;
uint8_t end_process = 0;
int16_t ack_sn = -1;
int16_t first_error_indicated_sn = -1;
int16_t sn_index;
int16_t current_sn;
int16_t current_index;
byte1 = statusP;
#ifdef DEBUG_PROCESS_STATUS
display_retransmission_buffer (rlcP);
#endif
if ((*byte1 & RLC_PIGGY_PDU_TYPE_MASK) == RLC_PIGGY_PDU_TYPE_STATUS) {
sufi_type = *byte1 & 0x0F;
byte_aligned = 0;
// process all bytes of the PDU
while (!end_process) {
// reset may have been triggered during processing of status, so exit
//if (rlcP->protocol_state == RLC_DATA_TRANSFER_READY_STATE){
switch (sufi_type) {
case RLC_AM_SUFI_NO_MORE:
// end of pdu
end_process = 1;
break;
case RLC_AM_SUFI_WINDOW:
msg ("[RLC_AM %p]PROCESS_STATUS ERROR process_status_info() RLC_AM_SUFI_WINDOW not implemented\n", rlcP);
end_process = 1;
break;
case RLC_AM_SUFI_ACK:
#ifdef DEBUG_PROCESS_STATUS
msg ("[RLC_AM %p]PROCESS_STATUS ACK\n", rlcP);
#endif
ack_sn = retransmission_buffer_management_ack (rlcP, byte1, byte_aligned, &first_error_indicated_sn);
#ifdef DEBUG_PROCESS_STATUS
msg ("[RLC_AM %p]PROCESS_STATUS ACK WAS LSN %d(b10) %4X(b16)\n", rlcP, ack_sn, ack_sn);
#endif
// DISCARD : A discard procedure is terminated in the sender on the reception of a status pdu which contains
// an ACK SUFI indicating VR(R) > SN_MRWlength
rlc_am_received_sufi_ack_check_discard_procedures (rlcP);
// end of pdu, no NO_MORE sufi;
end_process = 1;
#ifdef DEBUG_PROCESS_STATUS
display_protocol_vars_rlc_am (rlcP);
#endif
break;
case RLC_AM_SUFI_LIST:
#ifdef DEBUG_PROCESS_STATUS
msg ("[RLC_AM %p]PROCESS_STATUS LIST\n", rlcP);
#endif
byte1 = retransmission_buffer_management_list (rlcP, byte1, byte_aligned, &first_error_indicated_sn);
if (byte1 == NULL) {
// error in processing;
end_process = 1;
break;
}
// byte aligned is not changed for this sufi;
if (!byte_aligned) {
sufi_type = *byte1 & 0X0F;
} else {
sufi_type = (*byte1 & 0xF0) >> 4;
}
break;
case RLC_AM_SUFI_BITMAP:
#ifdef DEBUG_PROCESS_STATUS
msg ("[RLC_AM %p]PROCESS_STATUS BITMAP %p 0x%02X\n", rlcP, byte1, *byte1);
#endif
byte1 = retransmission_buffer_management_bitmap (rlcP, byte1, byte_aligned, &first_error_indicated_sn);
if (byte1 == NULL) {
// error in processing;
end_process = 1;
break;
}
// the length of this sufi is always n bytes + 4;
// so invert byte_aligned;
if (byte_aligned) {
byte_aligned = 0;
sufi_type = *byte1 & 0X0F;
} else {
byte_aligned = 1;
sufi_type = (*byte1 & 0xF0) >> 4;
}
break;
case RLC_AM_SUFI_RLIST:
msg ("[RLC_AM %p]PROCESS_STATUS ERROR SUFI RLIST NOT IMPLEMENTED\n", rlcP);
end_process = 1;
break;
case RLC_AM_SUFI_MRW:
#ifdef DEBUG_PROCESS_STATUS
msg ("[RLC_AM %p]PROCESS_STATUS MRW %p 0x%02X\n", rlcP, byte1, *byte1);
#endif
byte1 = retransmission_buffer_management_mrw (rlcP, byte1, &byte_aligned);
if (byte1 == NULL) {
// error in processing;
end_process = 1;
break;
}
// the length of this sufi is always n bytes + 4;
// so invert byte_aligned;
if (byte_aligned) {
sufi_type = (*byte1 & 0xF0) >> 4;
} else {
sufi_type = *byte1 & 0X0F;
}
break;
case RLC_AM_SUFI_MRW_ACK:
#ifdef DEBUG_PROCESS_STATUS
msg ("[RLC_AM %p]PROCESS_STATUS MRW_ACK %p 0x%02X\n", rlcP, byte1, *byte1);
#endif
byte1 = retransmission_buffer_management_mrw_ack (rlcP, byte1, &byte_aligned);
if (byte1 == NULL) {
// error in processing;
end_process = 1;
break;
}
// the length of this sufi is always n bytes + 4;
// so invert byte_aligned;
if (byte_aligned) {
sufi_type = (*byte1 & 0xF0) >> 4;
} else {
sufi_type = *byte1 & 0X0F;
}
break;
default:
msg ("[RLC_AM %p]PROCESS_STATUS ERROR SUFI UNKNOWN 0x%02X\n", rlcP, *byte1);
end_process = 1;
}
/*} else {
return;
} */
}
//-------------------------
// CLEAR ALL EVENTS RECEIVED;
//-------------------------
current_sn = rlcP->vt_a;
current_index = rlcP->vt_a % rlcP->recomputed_configured_tx_window_size;
sn_index = rlcP->vt_s % rlcP->recomputed_configured_tx_window_size;
while (sn_index != current_index) {
if (rlcP->retransmission_buffer[current_index] != NULL) {
((struct rlc_am_tx_data_pdu_management *) (rlcP->retransmission_buffer[current_index]->data))->ack = RLC_AM_PDU_ACK_NO_EVENT;
}
current_sn = (current_sn + 1) & SN_12BITS_MASK;
current_index = current_sn % rlcP->recomputed_configured_tx_window_size;
}
} else {
msg ("[RLC_AM %p][PROCESS_STATUS] ERROR process_piggybacked_status_info() PDU type field is not STATUS\n", rlcP);
}
#ifdef DEBUG_PROCESS_STATUS
display_retransmission_buffer (rlcP);
#endif
}
//-----------------------------------------------------------------------------
mem_block_t *
rlc_am_create_status_pdu_mrw_ack (struct rlc_am_entity *rlcP, uint8_t nP, uint16_t sn_ackP)
{
//-----------------------------------------------------------------------------
mem_block_t *le;
struct rlc_am_status_header *pdu;
uint8_t *p8;
#ifdef DEBUG_STATUS
msg ("[RLC_AM %p][STATUS] rlc_am_mrw_send_ack(N=%d, sn_ack=0x%04X)\n", rlcP, nP, sn_ackP);
#endif
le = get_free_mem_block (rlcP->pdu_size + sizeof (struct rlc_am_tx_control_pdu_allocation) + GUARD_CRC_LIH_SIZE);
if (le == NULL) {
msg ("[MEM_MNGT][ERROR] rlc_am_mrw_send_ack() no free blocks\n");
return NULL;
} else {
((struct rlc_am_tx_control_pdu_management *) (le->data))->rlc_tb_type = RLC_AM_STATUS_PDU_TYPE;
pdu = (struct rlc_am_status_header *) (&le->data[sizeof (struct rlc_am_tx_control_pdu_allocation)]);
pdu->byte1 = RLC_PDU_TYPE_STATUS;
p8 = &(pdu->byte1);
*p8 = *p8 | RLC_AM_SUFI_MRW_ACK;
p8 = p8 + 1;
*p8 = (nP << 4) | (sn_ackP >> 8);
p8 = p8 + 1;
*p8 = sn_ackP;
p8 = p8 + 1;
*p8 = RLC_AM_SUFI_NO_MORE << 4;
return le;
}
}
openair2/LAYER2/RLC/AM/rlc_am_status_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_status_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_STATUS_PROTO_EXTERN_H__
# define __RLC_AM_STATUS_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "rlc_am_structs.h"
# include "rlc_am_constants.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern int rlc_am_send_status (struct rlc_am_entity *rlcP);
extern void rlc_am_process_status_info (struct rlc_am_entity *rlcP, uint8_t * statusP);
extern mem_block_t *rlc_am_create_status_pdu_mrw_ack (struct rlc_am_entity *rlcP, uint8_t nP, uint16_t sn_ackP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_structs.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_structs.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_STRUCTS_H__
# define __RLC_AM_STRUCTS_H__
# include "platform_types.h"
# include "platform_constants.h"
# include "list.h"
# include "mem_block.h"
# include "rlc_am_constants.h"
//#ifdef USER_MODE
# include "mac_rlc_primitives.h"
//#endif //USER_MODE
# include "mac_primitives.h"
# include "rlc_primitives.h"
//-----------------------------------------------------------------------------
// SDU MANAGEMENT
//-----------------------------------------------------------------------------
struct rlc_am_tx_sdu_management {
uint8_t *first_byte; // payload
int32_t sdu_creation_time;
uint32_t mui; // mui may be used only by radio access bearers
uint16_t sdu_remaining_size;
uint16_t sdu_segmented_size;
uint16_t sdu_size;
int16_t pdus_index[42]; // sn of pdus (is an array)
uint16_t last_pdu_sn;
uint8_t nb_pdus; // number of pdus were this sdu was segmented
uint8_t nb_pdus_internal_use; // count the number of pdus transmitted to lower layers (used in mux procedure)
uint8_t nb_pdus_ack; // counter used for confirm and discard MaxDAT
uint8_t nb_pdus_time; // counter used for timer based discard
uint8_t confirm; // confirm may be used only by signalling radio bearers
int8_t li_index_for_discard; // indicates the li index in the last pdu of the sdu, marking the end of the sdu
uint8_t discarded;
uint8_t segmented; // != 0 if segmentation running or achieved
uint8_t no_new_sdu_segmented_in_last_pdu;
};
//-----------------------------------------------------------------------------
// SDU DISCARD
//-----------------------------------------------------------------------------
struct rlc_am_discard_procedure {
// list of sdu discarded involved in this procedure
list_t sdu_list; // index of sdu (index in rlc_am_entity.input_sdus[])
uint8_t nb_sdu;
mem_block_t *control_pdu;
uint16_t last_pdu_sn; // for update of vt_s
uint8_t length;
uint8_t nlength;
uint8_t running;
};
//-----------------------------------------------------------------------------
// DATA PDU
//-----------------------------------------------------------------------------
struct rlc_am_rx_pdu_management {
uint8_t *first_byte;
uint16_t sn;
uint8_t piggybacked_processed; // the piggybacked info if any of the pdu has already been processed.
};
struct rlc_am_tx_data_pdu_management {
mem_block_t *copy; //pointer on pdu queued in retransmission_buffer_to_send in order
// not to insert the same pdu to retransmit twice, also to avoid the transmission of the pdu if acknowledged
// but previously was queued for retransmission in retransmission_buffer_to_send but not sent because of
// limited number of pdu delivered by TTI.
uint8_t *first_byte; // pointer on the pdu including header, LIs;
uint8_t *payload; // pointer on the data field of the pdu;
int16_t sdu[15]; // index of sdu having segments in this pdu (index in rlc_am_entity.input_sdus[])
uint16_t padding_size; // size of padding area if any in a data pdu(for piggybacking)
uint16_t data_size;
uint16_t sn;
uint8_t nb_sdu; // number of sdu having segments in this pdu
uint8_t vt_dat; // This state variable counts the number of times a PDU has been transmitted;
// there is one VT(DAT) for each PDU and it is incremented each time the PDU is transmitted;
int8_t ack; // used when pdu is in retransmission buffer;
// values are RLC_PDU_ACK_NO_EVENT, RLC_PDU_ACK_EVENT, RLC_PDU_NACK_EVENT
uint8_t last_pdu_of_sdu; // nb of sdus ending in this pdu (for polling trigger)
uint16_t rlc_tb_type; // mac will return this value with the tx status
uint8_t dummy[MAC_HEADER_MAX_SIZE]; // reserve area for mac header !!! always the last declaration in this struct !!!
};
struct rlc_am_tx_control_pdu_management {
uint16_t rlc_tb_type; // mac will return this value with the tx status
uint8_t dummy[MAC_HEADER_MAX_SIZE]; // reserve area for mac header !!! always the last declaration in this struct !!!
};
//-----------------------------------------------------------------------------
// HEADERS
//-----------------------------------------------------------------------------
struct rlc_am_pdu_header {
uint8_t byte1;
uint8_t byte2;
uint8_t li_data_7[1];
};
struct rlc_am_reset_header {
uint8_t byte1;
uint8_t hfni[3]; // is coded on 20 most significant bits of 24 bits
};
struct rlc_am_status_header {
uint8_t byte1;
uint8_t suffi[1]; // next suffi(s)
};
//-----------------------------------------------------------------------------
// interlayers optimizations
//-----------------------------------------------------------------------------
struct rlc_am_tx_data_pdu_allocation {
union {
struct rlc_am_tx_data_pdu_management rlc_am_tx_pdu_mngmnt;
struct mac_tb_req tb_req;
struct mac_tx_tb_management tb_mngt;
# ifdef BYPASS_L1
struct rlc_am_rx_pdu_management dummy;
struct mac_tb_ind dummy2;
struct mac_rx_tb_management dummy3;
struct rlc_indication dummy4;
# endif
} dummy;
};
struct rlc_am_tx_control_pdu_allocation {
union {
struct mac_tb_req tb_req;
struct mac_tx_tb_management tb_mngt;
struct rlc_am_tx_control_pdu_management rlc_am_tx_pdu_mngmnt;
# ifdef BYPASS_L1
struct mac_tb_ind dummy2;
struct mac_rx_tb_management dummy3;
struct rlc_indication dummy4;
# endif
} dummy;
};
struct rlc_am_data_req_alloc { // alloc enought bytes for sdu mngt also
union {
struct rlc_am_data_req dummy1;
struct rlc_am_tx_sdu_management dummy2;
} dummy;
};
//-----------------------------------------------------------------------------
// MISC
//-----------------------------------------------------------------------------
struct sufi_to_insert_in_status {
uint16_t sn;
uint8_t length; // in quartets, sufi invalid if length is zero
uint8_t type; // ACK, BITMAP, LIST, etc
uint8_t sufi[SUFI_MAX_SIZE];
};
struct sufi_bitmap {
uint16_t fsn;
uint8_t valid;
uint8_t length;
uint8_t mask;
uint8_t bitmap[16];
};
struct pair {
uint16_t sn;
uint8_t valid;
uint8_t length;
};
struct sufi_list {
struct pair pairs[15];
uint8_t valid;
uint8_t length;
};
struct sufi_ack {
uint16_t lsn;
uint8_t vr_r_modified; // generate ack with vr_r value;
uint8_t ack_other_vr_r; // generate ack with lsn value;
};
//-----------------------------------------------------------------------------
// STATUS GENERATION
//-----------------------------------------------------------------------------
struct rlc_am_hole {
uint16_t valid;
uint16_t fsn;
uint16_t length;
uint16_t dist_to_next; //count in sn
};
# endif
openair2/LAYER2/RLC/AM/rlc_am_timers.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_timers.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_am_entity.h"
#include "rlc_am_constants.h"
#include "rlc_am_structs.h"
#include "rlc_am_util_proto_extern.h"
#include "umts_timer_proto_extern.h"
/*
void rlc_am_timer_epc_notify_time_out (struct rlc_am_entity *rlcP, void *arg_not_usedP);
void rlc_am_timer_epc_fsm (struct rlc_am_entity *rlcP, uint8_t eventP);
//-----------------------------------------------------------------------------
void
rlc_am_timer_epc_notify_time_out (struct rlc_am_entity *rlcP, void *arg_not_usedP)
{
//-----------------------------------------------------------------------------
rlc_am_timer_epc_fsm (rlcP, TIMER_EPC_TIMER_TIMED_OUT_EVENT);
}
//-----------------------------------------------------------------------------
void
rlc_am_timer_epc_fsm (struct rlc_am_entity *rlcP, uint8_t eventP)
{
//-----------------------------------------------------------------------------
// from 25.322 V4.3.0
// The Estimated PDU Counter (EPC) is only applicable for RLC entities operating
// in acknowledged mode. The EPC is a mechanism configured by upper layers used
// for scheduling the retransmission of status reports in the Receiver. With this
// mechanism, the Receiver will send a new status report in which it requests for
// AMD PDUs not yet received. The time between two subsequent status report
// retransmissions is not fixed, but it is controlled by both the timer Timer_EPC
// and the state variable VR(EP), which adapt this time to the round trip delay
// and the current bit rate, indicated in the TFI, in order to minimise the delay
// of the status report retransmission.
//
// When a status report is triggered by some mechanisms and it is submitted to lower
// layer (in UTRAN) or the successful or unsuccessful transmission of it is indicated
// by lower layer (in UE) <<SEE CODE "Ref1">> to request for retransmitting one or more missing AMD PDUs,
// the variable VR(EP) is set equal to the number of requested AMD PDUs. At least
// one requested AMD PDU is needed to activate the EPC mechanism. The variable VR(EP)
// is a counter, which is decremented every transmission time interval with the
// estimated number of AMD PDUs that should have been received during that
// transmission time interval on the corresponding logical channel.
//
// The timer Timer_EPC controls the maximum time that the variable VR(EP) needs to
// wait before it will start counting down. This timer starts immediately after a
// transmission of a retransmission request from the Receiver (when the first
// STATUS PDU of the status report is submitted to lower layer (in UTRAN) or the
// successful or unsuccessful transmission of it is indicated by lower layer(in UE)).
// The initial value of the timer Timer_EPC is configured by upper layers. It typically
// depends on the roundtrip delay, which consists of the propagation delay, processing
// time in the transmitter and Receiver and the frame structure. This timer can also
// be implemented as a counter, which counts the number of 10 ms radio frames that
// could be expected to elapse before the first requested AMD PDU is received.
//
// If not all of these requested AMD PDUs have been received correctly when VR(EP)
// is equal to zero, a new status report will be transmitted and the EPC mechanism
// will be reset accordingly. The timer Timer_EPC will be started once more when the
// first STATUS PDU of the status report is submitted to lower layer (in UTRAN) or the
// successful or unsuccessful transmission of it is indicated by lower layer (in UE).
// If all of the requested AMD PDUs have been received correctly, the EPC mechanism ends.
switch (rlcP->epc_state) {
//--------------------------------------------
case TIMER_EPC_STATE_IDLE:
//--------------------------------------------
rlcP->epc_counting_down = 0;
switch (eventP) {
// Ref1
case TIMER_EPC_PDU_STATUS_SUBMITTED_LOWER_LAYER_EVENT: // for RG
case TIMER_EPC_PDU_STATUS_TRANSMITED_EVENT: // for UE
rlcP->vr_ep = rlcP->epc_nb_missing_pdus;
rlcP->epc_old_vr_h = rlcP->vr_h;
rlcP->epc_old_vr_r = rlcP->vr_r;
rlcP->epc_state = TIMER_EPC_STATE_TIMER_ARMED;
rlcP->timer_epc = umts_add_timer_list_up (&rlcP->rlc_am_timer_list, rlc_am_timer_epc_notify_time_out, rlcP, rlcP->discard_procedures.head, NULL, *rlcP->frame_tick_milliseconds);
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_IDLE -> TIMER_EPC_STATE_TIMER_ARMED\n", rlcP);
#endif
return;
break;
default:
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_IDLE EVENT %02X hex NOT EXPECTED\n", rlcP, eventP);
#endif
return;
}
break;
//--------------------------------------------
case TIMER_EPC_STATE_TIMER_ARMED:
//--------------------------------------------
switch (eventP) {
// Ref1
case TIMER_EPC_PDU_STATUS_TRANSMITED_EVENT:
return;
break;
case TIMER_EPC_TIMER_TIMED_OUT_EVENT:
rlcP->epc_counting_down = 1;
rlcP->timer_epc = NULL;
rlcP->epc_state = TIMER_EPC_STATE_TIMED_OUT;
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_TIMER_ARMED -> TIMER_EPC_STATE_TIMED_OUT\n", rlcP);
#endif
return;
break;
default:
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_TIMER_ARMED EVENT %02X hex NOT EXPECTED\n", rlcP, eventP);
#endif
return;
}
break;
//--------------------------------------------
case TIMER_EPC_STATE_TIMED_OUT:
//--------------------------------------------
switch (eventP) {
case TIMER_EPC_VR_EP_EQUAL_ZERO_EVENT:
rlcP->epc_counting_down = 0;
rlcP->epc_state = TIMER_EPC_STATE_IDLE;
// return 1 if sn1 > sn2
// return 0 if sn1 = sn2
// return -1 if sn1 < sn2
if (rlc_am_comp_sn (rlcP, rlcP->epc_old_vr_r, rlcP->epc_old_vr_h, rlcP->vr_r) > 0) {
// not all missing pdus have been received
// so generate a new status report
rlcP->send_status_pdu_requested = 1;
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_TIMED_OUT -> TIMER_EPC_STATE_IDLE GENERATION OF STATUS REQUESTED\n", rlcP);
#endif
}
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
else {
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_TIMED_OUT -> TIMER_EPC_STATE_IDLE\n", rlcP);
}
#endif
return;
break;
default:
#ifdef DEBUG_RLC_AM_TIMER_EPC_FSM
msg ("[RLC_AM %p][TIMER_EPC_FSM] TIMER_EPC_STATE_TIMED_OUT EVENT %02X hex NOT EXPECTED\n", rlcP, eventP);
#endif
return;
}
break;
default:;
}
}
*/
openair2/LAYER2/RLC/AM/rlc_am_timers_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_timers_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_TIMERS_H__
# define __RLC_AM_RIMERS_H__
# include "rlc_am_entity.h"
# include "platform_types.h"
extern void rlc_am_timer_epc_notify_time_out (struct rlc_am_entity *rlcP, void *arg_not_usedP);
extern void rlc_am_timer_epc_fsm (struct rlc_am_entity *rlcP, uint8_t eventP);
# endif
openair2/LAYER2/RLC/AM/rlc_am_util.c deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_discard_rx.c -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
#include "rtos_header.h"
#include "platform_types.h"
//-----------------------------------------------------------------------------
#include "rlc_primitives.h"
#include "rlc_am_entity.h"
#include "rlc_am_structs.h"
#include "mem_block.h"
//-----------------------------------------------------------------------------
inline int rlc_am_comp_sn (struct rlc_am_entity* rlcP, uint16_t low_boundaryP, uint16_t sn1P, uint16_t sn2P);
void adjust_vr_r_mr (struct rlc_am_entity* rlcP);
void adjust_vt_a_ms (struct rlc_am_entity* rlcP);
void display_protocol_vars_rlc_am (struct rlc_am_entity* rlcP);
void display_retransmission_buffer (struct rlc_am_entity* rlcP);
void display_receiver_buffer (struct rlc_am_entity* rlcP);
void rlc_am_check_retransmission_buffer (struct rlc_am_entity* rlcP, uint8_t* messageP);
void rlc_am_check_receiver_buffer (struct rlc_am_entity* rlcP, uint8_t* messageP);
void rlc_am_display_data_pdu7 (mem_block_t* pduP);
//-----------------------------------------------------------------------------
#ifdef DEBUG_RLC_AM_CONFIRM
//-----------------------------------------------------------------------------
void
debug_rlc_am_confirm (struct rlc_am_entity* rlcP, mem_block_t* confP)
{
//-----------------------------------------------------------------------------
msg ("[RLC_AM][RB %d] CONFIRM SDU MUI %d\n", rlcP->rb_id, ((struct rlc_output_primitive*) (confP->data))->primitive.conf.mui);
free_mem_block_t (confP);
}
#endif /* DEBUG_RLC_AM_CONFIRM */
// return 1 if sn1 > sn2
// return 0 if sn1 = sn2
// return -1 if sn1 < sn2
//-----------------------------------------------------------------------------
inline int
rlc_am_comp_sn (struct rlc_am_entity* rlcP, uint16_t low_boundaryP, uint16_t sn1P, uint16_t sn2P)
{
//-----------------------------------------------------------------------------
// we require that sn are in tx window, if they are not we consider that they are always
// before low_boundaryP (one loop over the max sn 0x0FFF), never above the boundary
uint16_t bound = (low_boundaryP + rlcP->configured_tx_window_size - 1) & SN_12BITS_MASK;
if (sn1P == sn2P) {
return 0;
}
if (low_boundaryP < bound) {
if ((sn1P >= low_boundaryP) && (sn1P <= bound)) {
if ((sn2P >= low_boundaryP) && (sn2P <= bound)) {
if (sn1P > sn2P) {
return 1;
} else {
return -1;
}
} else { // not in tx window
return 1;
}
} else { // not in tx window
if ((sn2P >= low_boundaryP) && (sn2P <= bound)) {
return -1;
} else {
if ((sn1P > sn2P) && (sn1P <= low_boundaryP)) {
return 1;
} else if ((sn2P > sn1P) && (sn2P <= low_boundaryP)) {
return -1;
} else if ((sn1P > sn2P) && (sn1P > bound)) {
return -1;
} else {
return 1;
}
}
}
} else {
if (sn1P >= low_boundaryP) {
if (sn2P <= bound) {
return -1;
} else if ((sn2P >= low_boundaryP)) {
if (sn1P > sn2P) {
return 1;
} else {
return -1;
}
} else { // not in tx window
return -1;
}
} else if (sn1P <= bound) {
if (sn2P > bound) {
return 1;
} else {
if (sn1P > sn2P) {
return 1;
} else {
return -1;
}
}
} else { // bound < sn1< vt_a
if (sn2P >= low_boundaryP) {
return -1;
} else if (sn2P <= bound) {
return -1;
} else {
if (sn1P > sn2P) {
return 1;
} else {
return -1;
}
}
}
}
}
//-----------------------------------------------------------------------------
void
adjust_vt_a_ms (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t vt_a_index, vt_s_index;
vt_a_index = rlcP->vt_a % rlcP->recomputed_configured_tx_window_size;
vt_s_index = rlcP->vt_s % rlcP->recomputed_configured_tx_window_size;
while ((rlcP->retransmission_buffer[vt_a_index] == NULL) && (vt_a_index != vt_s_index)) {
rlcP->vt_a = (rlcP->vt_a + 1) & SN_12BITS_MASK;
vt_a_index = rlcP->vt_a % rlcP->recomputed_configured_tx_window_size;
}
rlcP->vt_ms = (rlcP->vt_a + rlcP->vt_ws - 1) & SN_12BITS_MASK;
}
//-----------------------------------------------------------------------------
void
adjust_vr_r_mr (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t vr_r_index, vr_h_index;
vr_r_index = rlcP->vr_r % rlcP->recomputed_configured_rx_window_size;
vr_h_index = rlcP->vr_h % rlcP->recomputed_configured_rx_window_size;
while ((rlcP->receiver_buffer[vr_r_index] != NULL) && (vr_r_index != vr_h_index)) {
rlcP->vr_r = (rlcP->vr_r + 1) & SN_12BITS_MASK;
vr_r_index = rlcP->vr_r % rlcP->recomputed_configured_rx_window_size;
}
rlcP->ack.vr_r_modified = 1;
#ifdef DEBUG_RECEIVER_BUFFER
msg ("[RLC_AM][RB %d][RECEIVER_BUFFER] ADJUST VR(R)->0x%04X VR(H)=0x%04X\n", rlcP->rb_id, rlcP->vr_r, rlcP->vr_h);
#endif
rlcP->vr_mr = (rlcP->vr_r + rlcP->configured_rx_window_size - 1) & SN_12BITS_MASK;
}
//-----------------------------------------------------------------------------
void
display_protocol_vars_rlc_am (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
msg ("[RLC_AM][RB %d] VT(A) 0x%04X VT(S) 0x%04X VT(MS) 0x%04X VT(PDU) 0x%04X VT(SDU) 0x%04X VR(R) 0x%04X VR(H) 0x%04X VR(MR) 0x%04X\n",
rlcP->rb_id, rlcP->vt_a, rlcP->vt_s, rlcP->vt_ms, rlcP->vt_pdu, rlcP->vt_sdu, rlcP->vr_r, rlcP->vr_h, rlcP->vr_mr);
}
//-----------------------------------------------------------------------------
void
display_retransmission_buffer (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t working_sn, working_sn_index;
uint16_t end_sn, end_sn_index;
working_sn = rlcP->vt_a;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
end_sn = (rlcP->vt_a + rlcP->recomputed_configured_tx_window_size - 1) & SN_12BITS_MASK;
end_sn_index = end_sn % rlcP->recomputed_configured_tx_window_size;
msg ("-------------------------------------------\nRetrans Buf rlc %p: VT(A) 0x%04X VT(S) 0x%04X XXX = sn based on index, (XXX) = sn read from pdu\n", rlcP,
rlcP->vt_a, rlcP->vt_s);
while (working_sn_index != end_sn_index) {
if (rlcP->retransmission_buffer[working_sn_index] != NULL) {
msg ("%03X(%03X).", working_sn, ((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[working_sn_index]->data))->sn);
} else {
msg ("_.");
}
if ((working_sn_index % 32) == 0) {
msg ("\n");
}
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
}
msg ("\n------------------------------------------\n");
}
//-----------------------------------------------------------------------------
void
display_receiver_buffer (struct rlc_am_entity* rlcP)
{
//-----------------------------------------------------------------------------
uint16_t working_sn, working_sn_index;
uint16_t end_sn, end_sn_index;
working_sn = rlcP->vr_r;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
end_sn = rlcP->vr_mr;
end_sn_index = end_sn % rlcP->recomputed_configured_rx_window_size;
msg ("-------------------------------\nRec Buf rlc %p VR(R) 0x%04X: ", rlcP, rlcP->vr_r);
while (working_sn_index != end_sn_index) {
if (rlcP->receiver_buffer[working_sn_index] != NULL) {
msg ("%03X(%03X)", working_sn, ((struct rlc_am_rx_pdu_management*) (rlcP->receiver_buffer[working_sn_index]->data))->sn);
} else {
msg ("_.");
}
if ((working_sn_index % 32) == 0) {
msg ("\n");
}
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
}
msg ("\n--------------------------------------\n");
}
//-----------------------------------------------------------------------------
void
rlc_am_check_retransmission_buffer (struct rlc_am_entity* rlcP, uint8_t* messageP)
{
//-----------------------------------------------------------------------------
int error_found = 0;
uint16_t working_sn, working_sn_index;
uint16_t end_sn, end_sn_index;
//---------------------------------------------
// check if pdu remaining outside the window
//---------------------------------------------
working_sn = rlcP->vt_s;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
end_sn = rlcP->vt_a;
end_sn_index = end_sn % rlcP->recomputed_configured_tx_window_size;
while (working_sn_index != end_sn_index) {
if (rlcP->retransmission_buffer[working_sn_index] != NULL) {
msg ("[RLC_AM][RB %d] CHECK RETRANSMISSION BUFFER ERROR %s : REMAINING PDU INDEX %d=0x%04X\n", rlcP->rb_id, messageP, working_sn_index, working_sn_index);
rlc_am_display_data_pdu7 (rlcP->retransmission_buffer[working_sn_index]);
error_found = 1;
}
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
}
//---------------------------------------------
// check if pdu remaining inside the window have the correct value for ack field
//---------------------------------------------
end_sn = rlcP->vt_s;
end_sn_index = end_sn % rlcP->recomputed_configured_tx_window_size;
working_sn = rlcP->vt_a;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
while (working_sn_index != end_sn_index) {
if (rlcP->retransmission_buffer[working_sn_index] != NULL) {
if (((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[working_sn_index]->data))->ack != RLC_AM_PDU_ACK_NO_EVENT) {
msg ("[RLC_AM][RB %d] CHECK RETRANSMISSION BUFFER ERROR %s EVENT (%d) IN PDU SN 0x%04X\n", rlcP->rb_id, messageP,
((struct rlc_am_tx_data_pdu_management*) (rlcP->retransmission_buffer[working_sn_index]->data))->ack, working_sn);
rlc_am_display_data_pdu7 (rlcP->retransmission_buffer[working_sn_index]);
error_found = 1;
}
}
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
}
if ((error_found)) {
display_protocol_vars_rlc_am (rlcP);
while (1);
} else {
msg ("[RLC_AM][RB %d] CHECK RETRANSMISSION BUFFER OK\n", rlcP->rb_id);
}
}
//-----------------------------------------------------------------------------
void
rlc_am_check_receiver_buffer (struct rlc_am_entity* rlcP, uint8_t* messageP)
{
//-----------------------------------------------------------------------------
int error_found = 0;
uint16_t working_sn, working_sn_index;
uint16_t end_sn, end_sn_index;
working_sn = rlcP->vr_h;
working_sn_index = working_sn % rlcP->recomputed_configured_tx_window_size;
end_sn = rlcP->vr_r;
end_sn_index = end_sn % rlcP->recomputed_configured_tx_window_size;
while (working_sn_index != end_sn_index) {
if (rlcP->receiver_buffer[working_sn_index] != NULL) {
msg ("[RLC_AM][RB %d] CHECK RECEIVER BUFFER ERROR %s : REMAINING PDU INDEX %d=0x%04X\n", rlcP->rb_id, messageP, working_sn_index, working_sn_index);
error_found = 1;
}
working_sn = (working_sn + 1) & SN_12BITS_MASK;
working_sn_index = working_sn % rlcP->recomputed_configured_rx_window_size;
}
if ((error_found)) {
while (1);
}
}
//-----------------------------------------------------------------------------
void
rlc_am_display_data_pdu7 (mem_block_t* pduP)
{
//-----------------------------------------------------------------------------
struct rlc_am_tx_data_pdu_management* pdu_mngt;
struct rlc_am_pdu_header* rlc_header;
int index;
int nb_li = 0;
int li_index = 0;
uint16_t li[32];
if ((pduP)) {
pdu_mngt = (struct rlc_am_tx_data_pdu_management*) (pduP->data);
msg ("[RLC_AM] DISPLAY DATA PDU %p SN 0x%04X LAST_PDU_OF_SDU %d\n", pduP, pdu_mngt->sn, pdu_mngt->last_pdu_of_sdu);
msg ("[RLC_AM] DISPLAY DATA PDU HEADER ");
for (index = 0; index < 10; index++) {
msg ("%02X.", pdu_mngt->first_byte[index]);
}
msg ("\n");
//--------------------------------------
// LINKED SDUs
//--------------------------------------
msg ("[RLC_AM] DISPLAY DATA PDU CONTAINS SDU(s) INDEX ");
for (index = 0; index < pdu_mngt->nb_sdu; index++) {
msg ("%d", pdu_mngt->sdu[index]);
}
msg ("\n");
//--------------------------------------
// LENGTH INDICATORS
//--------------------------------------
rlc_header = (struct rlc_am_pdu_header*) (pdu_mngt->first_byte);
if ((rlc_header->byte2 & RLC_HE_MASK) != RLC_HE_SUCC_BYTE_CONTAINS_DATA) {
msg ("[RLC_AM] DISPLAY DATA PDU CONTAINS LI(s) ");
nb_li = 0;
while ((li[nb_li] = (rlc_header->li_data_7[nb_li])) & RLC_E_NEXT_FIELD_IS_LI_E) {
li[nb_li] = li[nb_li] & (~(uint8_t) RLC_E_NEXT_FIELD_IS_LI_E);
nb_li++;
}
nb_li++;
while (li_index < nb_li) {
switch (li[li_index]) {
case RLC_LI_LAST_PDU_EXACTLY_FILLED:
msg ("LAST_PDU_EXACTLY_FILLED ");
break;
case RLC_LI_LAST_PDU_ONE_BYTE_SHORT:
msg ("LAST_PDU_ONE_BYTE_SHORT ");
break;
case RLC_LI_PDU_PIGGY_BACKED_STATUS: // ignore
msg ("PDU_PIGGY_BACKED_STATUS ");
break;
case RLC_LI_PDU_PADDING:
msg ("PDU_PADDING ");
break;
default: // li is length
msg ("LENGTH %d ", li[li_index] >> 1);
}
li_index++;
}
} else {
msg ("[RLC_AM] DISPLAY DATA PDU CONTAINS NO LI(s) ");
}
msg ("\n");
//--------------------------------------
// DATA
//--------------------------------------
msg ("[RLC_AM] DISPLAY DATA PDU CONTENT <PDU>");
for (index = 0; index < pdu_mngt->data_size; index++) {
msg ("%02X.", pdu_mngt->payload[index]);
}
msg ("</PDU>\n");
} else {
msg ("[RLC_AM] DISPLAY DATA PDU : IS NULL\n");
}
}
//-----------------------------------------------------------------------------
void
rlc_am_stat_req (struct rlc_am_entity* rlcP,
unsigned int* tx_pdcp_sdu,
unsigned int* tx_pdcp_sdu_discarded,
unsigned int* tx_retransmit_pdu_unblock,
unsigned int* tx_retransmit_pdu_by_status,
unsigned int* tx_retransmit_pdu,
unsigned int* tx_data_pdu,
unsigned int* tx_control_pdu,
unsigned int* rx_sdu,
unsigned int* rx_error_pdu,
unsigned int* rx_data_pdu,
unsigned int* rx_data_pdu_out_of_window,
unsigned int* rx_control_pdu)
{
//-----------------------------------------------------------------------------
*tx_pdcp_sdu = rlcP->stat_tx_pdcp_sdu;
*tx_pdcp_sdu_discarded = rlcP->stat_tx_pdcp_sdu_discarded;
*tx_retransmit_pdu_unblock = rlcP->stat_tx_retransmit_pdu_unblock;
*tx_retransmit_pdu_by_status = rlcP->stat_tx_retransmit_pdu_by_status;
*tx_retransmit_pdu = rlcP->stat_tx_retransmit_pdu;
*tx_data_pdu = rlcP->stat_tx_data_pdu;
*tx_control_pdu = rlcP->stat_tx_control_pdu;
*rx_sdu = rlcP->stat_rx_sdu;
*rx_error_pdu = rlcP->stat_rx_error_pdu;
*rx_data_pdu = rlcP->stat_rx_data_pdu;
*rx_data_pdu_out_of_window = rlcP->stat_rx_data_pdu_out_of_window;
*rx_control_pdu = rlcP->stat_rx_control_pdu;
}
openair2/LAYER2/RLC/AM/rlc_am_util_proto_extern.h deleted 100755 → 0
View file @ 0bd3c9ec
/*******************************************************************************
OpenAirInterface
Copyright(c) 1999 - 2014 Eurecom
OpenAirInterface is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenAirInterface is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with OpenAirInterface.The full GNU General Public License is
included in this distribution in the file called "COPYING". If not,
see <http://www.gnu.org/licenses/>.
Contact Information
OpenAirInterface Admin: openair_admin@eurecom.fr
OpenAirInterface Tech : openair_tech@eurecom.fr
OpenAirInterface Dev : openair4g-devel@eurecom.fr
Address : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
*******************************************************************************/
/***************************************************************************
rlc_am_util_proto_extern.h -
-------------------
AUTHOR : Lionel GAUTHIER
COMPANY : EURECOM
EMAIL : Lionel.Gauthier@eurecom.fr
***************************************************************************/
# ifndef __RLC_AM_UTIL_PROTO_EXTERN_H__
# define __RLC_AM_UTIL_PROTO_EXTERN_H__
//-----------------------------------------------------------------------------
# include "rlc_am_entity.h"
# include "mem_block.h"
//-----------------------------------------------------------------------------
extern void rlc_am_stat_req (struct rlc_am_entity *rlcP,
unsigned int* tx_pdcp_sdu,
unsigned int* tx_pdcp_sdu_discarded,
unsigned int* tx_retransmit_pdu_unblock,
unsigned int* tx_retransmit_pdu_by_status,
unsigned int* tx_retransmit_pdu,
unsigned int* tx_data_pdu,
unsigned int* tx_control_pdu,
unsigned int* rx_sdu,
unsigned int* rx_error_pdu,
unsigned int* rx_data_pdu,
unsigned int* rx_data_pdu_out_of_window,
unsigned int* rx_control_pdu);
extern int rlc_am_comp_sn (struct rlc_am_entity *rlcP, uint16_t low_boundaryP, uint16_t sn1P, uint16_t sn2P);
extern void adjust_vr_r_mr (struct rlc_am_entity *rlcP);
extern void adjust_vt_a_ms (struct rlc_am_entity *rlcP);
extern void display_protocol_vars_rlc_am (struct rlc_am_entity *rlcP);
extern void display_retransmission_buffer (struct rlc_am_entity *rlcP);
extern void display_receiver_buffer (struct rlc_am_entity *rlcP);
extern void rlc_am_check_retransmission_buffer (struct rlc_am_entity *rlcP, uint8_t * messageP);
extern void rlc_am_check_receiver_buffer (struct rlc_am_entity *rlcP, uint8_t * messageP);
extern void rlc_am_display_data_pdu7 (mem_block_t * pduP);
# ifdef DEBUG_RLC_AM_CONFIRM
void debug_rlc_am_confirm (struct rlc_am_entity *rlcP, uint32_t muiP);
# endif
# endif
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