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osmo-pcu/src/tbf_dl.cpp

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/* Copied from tbf.cpp
*
* Copyright (C) 2012 Ivan Klyuchnikov
* Copyright (C) 2012 Andreas Eversberg <jolly@eversberg.eu>
* Copyright (C) 2013 by Holger Hans Peter Freyther
*
* This program 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 2
* of the License, or (at your option) any later version.
*
* This program 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.
*/
#include <bts.h>
#include <tbf.h>
#include <tbf_dl.h>
#include <tbf_ul.h>
#include <rlc.h>
#include <gprs_rlcmac.h>
#include <gprs_debug.h>
#include <gprs_bssgp_pcu.h>
#include <gprs_codel.h>
#include <decoding.h>
#include <encoding.h>
#include <gprs_ms.h>
#include <llc.h>
#include "pcu_utils.h"
#include "alloc_algo.h"
extern "C" {
#include <osmocom/core/msgb.h>
#include <osmocom/core/talloc.h>
#include <osmocom/gprs/gprs_bssgp_bss.h>
#include <osmocom/core/bitvec.h>
#include <osmocom/core/linuxlist.h>
#include <osmocom/core/logging.h>
#include <osmocom/core/rate_ctr.h>
#include <osmocom/core/stats.h>
#include <osmocom/core/timer.h>
#include <osmocom/core/utils.h>
#include <osmocom/gsm/gsm_utils.h>
#include <osmocom/gsm/protocol/gsm_04_08.h>
#include "coding_scheme.h"
}
#include <errno.h>
#include <string.h>
/* After sending these frames, we poll for ack/nack. */
#define POLL_ACK_AFTER_FRAMES 20
extern void *tall_pcu_ctx;
static const struct rate_ctr_desc tbf_dl_gprs_ctr_description[] = {
{ "gprs:downlink:cs1", "CS1 " },
{ "gprs:downlink:cs2", "CS2 " },
{ "gprs:downlink:cs3", "CS3 " },
{ "gprs:downlink:cs4", "CS4 " },
};
static const struct rate_ctr_desc tbf_dl_egprs_ctr_description[] = {
{ "egprs:downlink:mcs1", "MCS1 " },
{ "egprs:downlink:mcs2", "MCS2 " },
{ "egprs:downlink:mcs3", "MCS3 " },
{ "egprs:downlink:mcs4", "MCS4 " },
{ "egprs:downlink:mcs5", "MCS5 " },
{ "egprs:downlink:mcs6", "MCS6 " },
{ "egprs:downlink:mcs7", "MCS7 " },
{ "egprs:downlink:mcs8", "MCS8 " },
{ "egprs:downlink:mcs9", "MCS9 " },
};
static const struct rate_ctr_group_desc tbf_dl_gprs_ctrg_desc = {
"tbf:gprs",
"Data Blocks",
OSMO_STATS_CLASS_SUBSCRIBER,
ARRAY_SIZE(tbf_dl_gprs_ctr_description),
tbf_dl_gprs_ctr_description,
};
static const struct rate_ctr_group_desc tbf_dl_egprs_ctrg_desc = {
"tbf:egprs",
"Data Blocks",
OSMO_STATS_CLASS_SUBSCRIBER,
ARRAY_SIZE(tbf_dl_egprs_ctr_description),
tbf_dl_egprs_ctr_description,
};
gprs_rlcmac_dl_tbf::BandWidth::BandWidth() :
dl_bw_octets(0),
dl_throughput(0),
dl_loss_lost(0),
dl_loss_received(0)
{
osmo_clock_gettime(CLOCK_MONOTONIC, &dl_bw_tv);
osmo_clock_gettime(CLOCK_MONOTONIC, &dl_loss_tv);
}
static int dl_tbf_dtor(struct gprs_rlcmac_dl_tbf *tbf)
{
tbf->~gprs_rlcmac_dl_tbf();
return 0;
}
struct gprs_rlcmac_dl_tbf *dl_tbf_alloc(struct gprs_rlcmac_bts *bts, struct GprsMs *ms)
{
struct gprs_rlcmac_dl_tbf *tbf;
OSMO_ASSERT(ms != NULL);
LOGPMS(ms, DTBF, LOGL_DEBUG, "********** DL-TBF starts here **********\n");
LOGPMS(ms, DTBF, LOGL_INFO, "Allocating DL TBF\n");
tbf = talloc(tall_pcu_ctx, struct gprs_rlcmac_dl_tbf);
if (!tbf)
return NULL;
talloc_set_destructor(tbf, dl_tbf_dtor);
new (tbf) gprs_rlcmac_dl_tbf(bts, ms);
if (tbf->is_egprs_enabled()) {
tbf->m_dl_egprs_ctrs = rate_ctr_group_alloc(tbf,
&tbf_dl_egprs_ctrg_desc,
tbf->m_ctrs->idx);
if (!tbf->m_dl_egprs_ctrs) {
LOGPTBF(tbf, LOGL_ERROR, "Couldn't allocate EGPRS DL counters\n");
talloc_free(tbf);
return NULL;
}
} else {
tbf->m_dl_gprs_ctrs = rate_ctr_group_alloc(tbf,
&tbf_dl_gprs_ctrg_desc,
tbf->m_ctrs->idx);
if (!tbf->m_dl_gprs_ctrs) {
LOGPTBF(tbf, LOGL_ERROR, "Couldn't allocate GPRS DL counters\n");
talloc_free(tbf);
return NULL;
}
}
bts_do_rate_ctr_inc(tbf->bts, CTR_TBF_DL_ALLOCATED);
return tbf;
}
gprs_rlcmac_dl_tbf::~gprs_rlcmac_dl_tbf()
{
if (is_egprs_enabled()) {
rate_ctr_group_free(m_dl_egprs_ctrs);
} else {
rate_ctr_group_free(m_dl_gprs_ctrs);
}
/* ~gprs_rlcmac_tbf() is called automatically upon return */
}
gprs_rlcmac_dl_tbf::gprs_rlcmac_dl_tbf(struct gprs_rlcmac_bts *bts_, GprsMs *ms) :
gprs_rlcmac_tbf(bts_, ms, GPRS_RLCMAC_DL_TBF),
m_tx_counter(0),
m_dl_ack_requested(false),
m_last_dl_poll_fn(-1),
m_last_dl_poll_ack_lost(false),
m_last_dl_drained_fn(-1),
m_first_dl_ack_rcvd(false),
m_dl_gprs_ctrs(NULL),
m_dl_egprs_ctrs(NULL)
{
memset(&state_fsm, 0, sizeof(state_fsm));
state_fsm.dl_tbf = this;
state_fi = osmo_fsm_inst_alloc(&tbf_dl_fsm, this, &state_fsm, LOGL_INFO, NULL);
OSMO_ASSERT(state_fi);
INIT_LLIST_HEAD(&this->tx_llc_until_first_dl_ack_rcvd);
/* This has to be called in child constructor because enable_egprs()
* uses the window() virtual function which is dependent on subclass. */
if (ms_mode(m_ms) != GPRS)
enable_egprs();
}
/**
* TODO: split into unit test-able parts...
*/
int dl_tbf_handle(struct gprs_rlcmac_bts *bts,
const uint32_t tlli, const uint32_t tlli_old, const char *imsi,
uint8_t ms_class, uint8_t egprs_ms_class,
const uint16_t delay_csec,
const uint8_t *data, const uint16_t len)
{
int rc;
GprsMs *ms, *ms_old;
bool ms_allocated = false;
/* check for existing TBF */
ms = bts_get_ms(bts, tlli, tlli_old, imsi);
/* If we got MS by TLLI above let's see if we already have another MS
* object identified by IMSI and merge them */
if (ms) {
if (!ms_imsi_is_valid(ms) && imsi) {
ms_old = bts_get_ms_by_imsi(bts, imsi);
if (ms_old && ms_old != ms) {
/* The TLLI has changed (RAU), so there are two MS
* objects for the same MS */
LOGP(DTBF, LOGL_NOTICE,
"There is a new MS object for the same MS: (0x%08x, '%s') -> (0x%08x, '%s')\n",
ms_tlli(ms_old), ms_imsi(ms_old), ms_tlli(ms), ms_imsi(ms));
ms_merge_and_clear_ms(ms, ms_old);
/* old_ms may no longer be available here */
}
}
} else {
ms = ms_alloc(bts, __func__);
/* Remember we have to unref the alloc reference at the end: */
ms_allocated = true;
}
if (imsi)
ms_set_imsi(ms, imsi);
ms_confirm_tlli(ms, tlli);
if (!ms_ms_class(ms) && ms_class) {
ms_set_ms_class(ms, ms_class);
}
if (!ms_egprs_ms_class(ms) && egprs_ms_class) {
ms_set_egprs_ms_class(ms, egprs_ms_class);
}
rc = ms_append_llc_dl_data(ms, delay_csec, data, len);
if (ms_allocated) {
ms_unref(ms, __func__);
/* Here "ms" may be freed if ms_append_llc_dl_data() failed to
* allocate a DL TBF and it has no more TBFs attached */
}
return rc;
}
bool gprs_rlcmac_dl_tbf::restart_bsn_cycle()
{
/* If V(S) == V(A) and finished state, we would have received
* acknowledgement of all transmitted block. In this case we would
* have transmitted the final block, and received ack from MS. But in
* this case we did not receive the final ack indication from MS. This
* should never happen if MS works correctly.
*/
if (m_window.window_empty()) {
LOGPTBFDL(this, LOGL_DEBUG, "MS acked all blocks\n");
return false;
}
/* cycle through all unacked blocks */
int resend = m_window.mark_for_resend();
/* At this point there should be at least one unacked block
* to be resent. If not, this is an software error. */
if (resend == 0) {
LOGPTBFDL(this, LOGL_ERROR,
"FIXME: Software error: There are no unacknowledged blocks, but V(A) != V(S). PLEASE FIX!\n");
return false;
}
return true;
}
int gprs_rlcmac_dl_tbf::take_next_bsn(uint32_t fn,
int previous_bsn, enum mcs_kind req_mcs_kind, bool *may_combine)
{
int bsn;
int data_len2, force_data_len = -1;
enum CodingScheme tx_cs;
/* Scheduler may be fine with sending any kind of data, but if
the selected TBF is GPRS-only, then let's filter out EGPRS
here */
if (!is_egprs_enabled())
req_mcs_kind = GPRS;
/* search for a nacked or resend marked bsn */
bsn = m_window.resend_needed();
if (previous_bsn >= 0) {
tx_cs = m_rlc.block(previous_bsn)->cs_current_trans;
if (!mcs_is_edge(tx_cs))
return -1;
force_data_len = m_rlc.block(previous_bsn)->len;
} else {
tx_cs = ms_current_cs_dl(ms(), req_mcs_kind);
}
if (bsn >= 0) {
/* resend an unacked bsn or resend bsn. */
if (previous_bsn == bsn)
return -1;
if (previous_bsn >= 0 &&
m_window.mod_sns(bsn - previous_bsn) > RLC_EGPRS_MAX_BSN_DELTA)
return -1;
if (is_egprs_enabled()) {
/* Table 8.1.1.2 and Table 8.1.1.1 of 44.060 */
m_rlc.block(bsn)->cs_current_trans = get_retx_mcs(m_rlc.block(bsn)->cs_init, tx_cs,
bts->pcu->vty.dl_arq_type == EGPRS_ARQ1);
LOGPTBFDL(this, LOGL_DEBUG,
"initial_cs_dl(%s) last_mcs(%s) demanded_mcs(%s) cs_trans(%s) arq_type(%d) bsn(%d)\n",
mcs_name(m_rlc.block(bsn)->cs_init),
mcs_name(m_rlc.block(bsn)->cs_last),
mcs_name(tx_cs),
mcs_name(m_rlc.block(bsn)->cs_current_trans),
the_pcu->vty.dl_arq_type, bsn);
/* TODO: Need to remove this check when MCS-8 -> MCS-6
* transistion is handled.
* Refer commit be881c028fc4da00c4046ecd9296727975c206a3
*/
if (m_rlc.block(bsn)->cs_init == MCS8)
m_rlc.block(bsn)->cs_current_trans =
MCS8;
} else {
/* gprs */
m_rlc.block(bsn)->cs_current_trans =
m_rlc.block(bsn)->cs_last;
}
data_len2 = m_rlc.block(bsn)->len;
if (force_data_len > 0 && force_data_len != data_len2)
return -1;
LOGPTBFDL(this, LOGL_DEBUG, "Resending BSN %d\n", bsn);
/* re-send block with negative aknowlegement */
m_window.m_v_b.mark_unacked(bsn);
bts_do_rate_ctr_inc(bts, CTR_RLC_RESENT);
} else if (state_is(TBF_ST_FINISHED)) {
/* If the TBF is in finished, we already sent all packages at least once.
* If any packages could have been sent (because of unacked) it should have
* been catched up by the upper if(bsn >= 0) */
LOGPTBFDL(this, LOGL_DEBUG,
"Restarting at BSN %d, because all blocks have been transmitted.\n",
m_window.v_a());
bts_do_rate_ctr_inc(bts, CTR_RLC_RESTARTED);
if (restart_bsn_cycle())
return take_next_bsn(fn, previous_bsn, req_mcs_kind, may_combine);
} else if (dl_window_stalled()) {
/* There are no more packages to send, but the window is stalled.
* Restart the bsn_cycle to resend all unacked messages */
LOGPTBFDL(this, LOGL_NOTICE,
"Restarting at BSN %d, because the window is stalled.\n",
m_window.v_a());
bts_do_rate_ctr_inc(bts, CTR_RLC_STALLED);
if (restart_bsn_cycle())
return take_next_bsn(fn, previous_bsn, req_mcs_kind, may_combine);
} else if (have_data()) {
/* The window has space left, generate new bsn */
LOGPTBFDL(this, LOGL_DEBUG,
"Sending new block at BSN %d, CS=%s%s\n",
m_window.v_s(), mcs_name(tx_cs),
force_data_len != -1 ? " (forced)" : "");
bsn = create_new_bsn(fn, tx_cs);
} else if (bts->pcu->vty.dl_tbf_preemptive_retransmission && !m_window.window_empty()) {
/* The window contains unacked packages, but not acked.
* Mark unacked bsns as RESEND */
LOGPTBFDL(this, LOGL_DEBUG,
"Restarting at BSN %d, because all blocks have been transmitted (FLOW).\n",
m_window.v_a());
bts_do_rate_ctr_inc(bts, CTR_RLC_RESTARTED);
if (restart_bsn_cycle())
return take_next_bsn(fn, previous_bsn, req_mcs_kind, may_combine);
} else {
/* Nothing left to send, create dummy LLC commands */
LOGPTBFDL(this, LOGL_DEBUG,
"Sending new dummy block at BSN %d, CS=%s\n",
m_window.v_s(), mcs_name(tx_cs));
bsn = create_new_bsn(fn, tx_cs);
/* Don't send a second block, so don't set cs_current_trans */
}
if (bsn < 0) {
/* we just send final block again */
LOGPTBFDL(this, LOGL_DEBUG,
"Nothing else to send, Re-transmit final block!\n");
bsn = m_window.v_s_mod(-1);
bts_do_rate_ctr_inc(bts, CTR_RLC_FINAL_BLOCK_RESENT);
bts_do_rate_ctr_inc(bts, CTR_RLC_RESENT);
}
*may_combine = num_data_blocks(mcs_header_type(m_rlc.block(bsn)->cs_current_trans)) > 1;
return bsn;
}
/*
* Create DL data block
* The messages are fragmented and forwarded as data blocks.
*/
struct msgb *gprs_rlcmac_dl_tbf::create_dl_acked_block(uint32_t fn, const struct gprs_rlcmac_pdch *pdch, enum mcs_kind req_mcs_kind)
{
int bsn, bsn2 = -1;
bool may_combine;
LOGPTBFDL(this, LOGL_DEBUG, "downlink (V(A)==%d .. V(S)==%d) mcs_mode_restrict=%s\n",
m_window.v_a(), m_window.v_s(), mode_name(req_mcs_kind));
bsn = take_next_bsn(fn, -1, req_mcs_kind, &may_combine);
if (bsn < 0)
return NULL;
if (may_combine)
bsn2 = take_next_bsn(fn, bsn, req_mcs_kind, &may_combine);
return create_dl_acked_block(fn, pdch, bsn, bsn2);
}
void gprs_rlcmac_dl_tbf::apply_allocated_resources(const struct alloc_resources_res *res)
{
uint8_t ts;
if (this->trx)
llist_del(&this->m_trx_list.list);
llist_add(&this->m_trx_list.list, &res->trx->dl_tbfs);
this->trx = res->trx;
this->upgrade_to_multislot = res->upgrade_to_multislot;
for (ts = 0; ts < ARRAY_SIZE(trx->pdch); ts++) {
struct gprs_rlcmac_pdch *pdch = &trx->pdch[ts];
OSMO_ASSERT(!this->pdch[pdch->ts_no]);
if (!(res->ass_slots_mask & (1 << ts)))
continue;
LOGPTBFDL(this, LOGL_DEBUG, "Assigning TS=%u TFI=%d\n",
ts, res->tfi);
this->m_tfi = res->tfi;
this->pdch[pdch->ts_no] = pdch;
pdch->attach_tbf(this);
}
/* assign initial control ts */
tbf_assign_control_ts(this);
LOGPTBF(this, LOGL_INFO,
"Allocated: trx = %d, ul_slots = %02x, dl_slots = %02x\n",
this->trx->trx_no, ul_slots(), dl_slots());
if (tbf_is_egprs_enabled(this))
this->set_window_size();
tbf_update_state_fsm_name(this);
}
void dl_tbf_apply_allocated_resources(struct gprs_rlcmac_dl_tbf *dl_tbf, const struct alloc_resources_res *res)
{
dl_tbf->apply_allocated_resources(res);
}
/* old_tbf (UL TBF or DL TBF) will send a Pkt Dl Ass on PACCH to assign tbf.
* Note: It is possible that "tbf == old_tbf" if the TBF is being updated. This can
* happen when we first assign over PCH (only single slot is possible) and we want
* to upgrade the DL-TBF to be multislot. See code calling tbf_update() for more
* information.
*/
void dl_tbf_trigger_ass_on_pacch(struct gprs_rlcmac_dl_tbf *tbf, struct gprs_rlcmac_tbf *old_tbf)
{
OSMO_ASSERT(tbf);
OSMO_ASSERT(old_tbf);
/* stop pending timer */
tbf_stop_timers(tbf, "DL assignment (PACCH)");
LOGPTBFDL(tbf, LOGL_DEBUG, "Send downlink assignment on PACCH, because %s exists\n", old_tbf->name());
osmo_fsm_inst_dispatch(old_tbf->dl_ass_fsm.fi, TBF_DL_ASS_EV_SCHED_ASS, NULL);
/* change state */
osmo_fsm_inst_dispatch(tbf->state_fi, TBF_EV_ASSIGN_ADD_PACCH, NULL);
}
void dl_tbf_trigger_ass_on_pch(struct gprs_rlcmac_dl_tbf *tbf)
{
/* stop pending timer */
struct GprsMs *ms = tbf_ms(tbf);
tbf_stop_timers(tbf, "DL assignment (PCH)");
LOGPTBFDL(tbf, LOGL_DEBUG, "Send downlink assignment on PCH, no TBF exist (IMSI=%s)\n", ms_imsi(ms));
/* change state */
osmo_fsm_inst_dispatch(tbf->state_fi, TBF_EV_ASSIGN_ADD_CCCH, NULL);
}
int dl_tbf_upgrade_to_multislot(struct gprs_rlcmac_dl_tbf *dl_tbf)
{
int rc;
struct gprs_rlcmac_tbf *tbf = dl_tbf_as_tbf(dl_tbf);
struct gprs_rlcmac_trx *trx = tbf_get_trx(dl_tbf);
struct gprs_rlcmac_bts *bts = trx->bts;
struct GprsMs *ms = tbf->ms();
LOGPTBFDL(dl_tbf, LOGL_DEBUG, "Upgrade to multislot\n");
tbf_unlink_pdch(dl_tbf);
const struct alloc_resources_req req = {
.bts = bts,
.ms = ms,
.direction = tbf_direction(tbf),
.single = false,
.use_trx = -1,
};
struct alloc_resources_res res = {};
rc = the_pcu->alloc_algorithm(&req, &res);
/* if no resource */
if (rc < 0) {
LOGPTBFDL(dl_tbf, LOGL_ERROR, "No resources allocated during upgrade to multislot!\n");
bts_do_rate_ctr_inc(bts, CTR_TBF_ALLOC_FAIL);
return rc;
}
/* Update MS, really allocate the resources */
if (res.reserved_ul_slots != ms_reserved_ul_slots(ms) ||
res.reserved_dl_slots != ms_reserved_dl_slots(ms)) {
/* The reserved slots have changed, update the MS */
ms_set_reserved_slots(ms, res.trx, res.reserved_ul_slots, res.reserved_dl_slots);
}
ms_set_first_common_ts(ms, res.first_common_ts);
/* Apply allocated resources to TBF: */
dl_tbf_apply_allocated_resources(dl_tbf, &res);
/* Note: No need to call ms_attach_tbf(), tbf is already attached to the MS */
/* Now trigger the assignment using the pre-existing TBF: */
dl_tbf_trigger_ass_on_pacch(dl_tbf, tbf);
return 0;
}
void gprs_rlcmac_dl_tbf::schedule_next_frame()
{
struct msgb *msg;
if (llc_frame_length(&m_llc) != 0)
return;
/* dequeue next LLC frame, if any */
msg = llc_queue_dequeue(llc_queue(), &m_llc.prio, &m_llc.meta_info);
if (!msg)
return;
LOGPTBFDL(this, LOGL_DEBUG, "Dequeue next LLC (len=%d)\n", msg->len);
llc_put_frame(&m_llc, msg->data, msg->len);
bts_do_rate_ctr_inc(bts, CTR_LLC_FRAME_SCHED);
msgb_free(msg);
m_last_dl_drained_fn = -1;
}
int gprs_rlcmac_dl_tbf::create_new_bsn(const uint32_t fn, enum CodingScheme cs)
{
uint8_t *data;
gprs_rlc_data *rlc_data;
const uint16_t bsn = m_window.v_s();
gprs_rlc_data_block_info *rdbi;
int num_chunks = 0;
int write_offset = 0;
Encoding::AppendResult ar;
if (llc_frame_length(&m_llc) == 0)
schedule_next_frame();
OSMO_ASSERT(mcs_is_valid(cs));
/* length of usable data block (single data unit w/o header) */
const uint8_t block_data_len = mcs_max_data_block_bytes(cs);
/* now we still have untransmitted LLC data, so we fill mac block */
rlc_data = m_rlc.block(bsn);
data = prepare(rlc_data, block_data_len);
rlc_data->cs_last = cs;
rlc_data->cs_current_trans = cs;
/* Initialise the variable related to DL SPB */
rlc_data->spb_status.block_status_dl = EGPRS_RESEG_DL_DEFAULT;
rlc_data->cs_init = cs;
rlc_data->len = block_data_len;
rdbi = &(rlc_data->block_info);
memset(rdbi, 0, sizeof(*rdbi));
rdbi->data_len = block_data_len;
rdbi->cv = 15; /* Final Block Indicator, set late, if true */
rdbi->bsn = bsn; /* Block Sequence Number */
rdbi->e = 1; /* Extension bit, maybe set later (1: no extension) */
do {
bool is_final;
int payload_written = 0;
if (llc_frame_length(&m_llc) == 0) {
/* The data just drained, store the current fn */
if (m_last_dl_drained_fn < 0)
m_last_dl_drained_fn = fn;
/* It is not clear, when the next real data will
* arrive, so request a DL ack/nack now */
request_dl_ack();
int space = block_data_len - write_offset;
if (num_chunks != 0) {
/* Nothing to send, and we already put some data in
* rlcmac data block, we are done */
LOGPTBFDL(this, LOGL_DEBUG,
"LLC queue completely drained and there's "
"still %d free bytes in rlcmac data block\n", space);
/* We may need to update fbi in header here
* since m_last_dl_drained_fn was updated above
* Specially important when X2031 is 0. */
is_final = llc_queue_size(llc_queue()) == 0 && !keep_open(fn);
if (is_final) {
rdbi->cv = 0;
osmo_fsm_inst_dispatch(this->state_fi, TBF_EV_LAST_DL_DATA_SENT, NULL);
}
if (mcs_is_edge(cs)) {
/* in EGPRS there's no M bit, so we need
* to flag padding with LI=127 */
Encoding::rlc_data_to_dl_append_egprs_li_padding(rdbi,
&write_offset,
&num_chunks,
data);
}
break;
}
/* Nothing to send from upper layers (LLC), but still
* requested to send something to MS to delay the
* release of the TBF. See 3GPP TS 44.060 9.3.1a
* "Delayed release of downlink Temporary Block Flow" */
/* A header will need to by added, so we just need
* space-1 octets */
llc_put_dummy_frame(&m_llc, space - 1);
LOGPTBFDL(this, LOGL_DEBUG,
"Empty chunk, added LLC dummy command of size %d, drained_since=%d\n",
llc_frame_length(&m_llc), frames_since_last_drain(fn));
}
is_final = llc_queue_size(llc_queue()) == 0 && !keep_open(fn);
ar = Encoding::rlc_data_to_dl_append(rdbi, cs,
&m_llc, &write_offset, &num_chunks, data, is_final, &payload_written);
if (payload_written > 0)
bts_do_rate_ctr_add(bts, CTR_RLC_DL_PAYLOAD_BYTES, payload_written);
if (ar == Encoding::AR_NEED_MORE_BLOCKS)
break;
LOGPTBFDL(this, LOGL_DEBUG, "Complete DL frame, len=%d\n", llc_frame_length(&m_llc));
gprs_rlcmac_dl_bw(this, llc_frame_length(&m_llc));
bts_do_rate_ctr_add(bts, CTR_LLC_DL_BYTES, llc_frame_length(&m_llc));
/* Keep transmitted LLC PDUs until first ACK to avoid lossing them if MS is not there. */
if (!this->m_first_dl_ack_rcvd) {
struct gprs_dl_llc_llist_item *llc_it = talloc(this, struct gprs_dl_llc_llist_item);
memcpy(&llc_it->llc, &m_llc, sizeof(llc_it->llc));
/* Prepend to list to store them in inverse order of transmission, see
* dl_tbf_copy_unacked_pdus_to_llc_queue() for the complete picture. */
llist_add(&llc_it->list, &this->tx_llc_until_first_dl_ack_rcvd);
}
llc_reset(&m_llc);
if (is_final) {
request_dl_ack();
osmo_fsm_inst_dispatch(this->state_fi, TBF_EV_LAST_DL_DATA_SENT, NULL);
}
/* dequeue next LLC frame, if any */
schedule_next_frame();
} while (ar == Encoding::AR_COMPLETED_SPACE_LEFT);
LOGPTBFDL(this, LOGL_DEBUG, "data block (BSN %d, %s): %s\n",
bsn, mcs_name(rlc_data->cs_last),
osmo_hexdump(rlc_data->block, block_data_len));
/* raise send state and set ack state array */
m_window.m_v_b.mark_unacked(bsn);
m_window.increment_send();
return bsn;
}
struct msgb *gprs_rlcmac_dl_tbf::create_dl_acked_block(
const uint32_t fn, const struct gprs_rlcmac_pdch *pdch,
int index, int index2)
{
uint8_t *msg_data;
struct msgb *dl_msg;
unsigned msg_len;
/* TODO: support MCS-7 - MCS-9, where data_block_idx can be 1 */
uint8_t data_block_idx = 0;
unsigned int rrbp;
uint32_t new_poll_fn;
int rc;
bool is_final = false;
gprs_rlc_data_info rlc;
enum CodingScheme cs;
int bsns[ARRAY_SIZE(rlc.block_info)];
unsigned num_bsns;
bool need_padding = false;
enum egprs_rlcmac_dl_spb spb = EGPRS_RLCMAC_DL_NO_RETX;
unsigned int spb_status = get_egprs_dl_spb_status(index);
enum egprs_puncturing_values punct[2] = {
EGPRS_PS_INVALID, EGPRS_PS_INVALID
};
osmo_static_assert(ARRAY_SIZE(rlc.block_info) == 2,
rlc_block_info_size_is_two);
/*
* TODO: This is an experimental work-around to put 2 BSN into
* MSC-7 to MCS-9 encoded messages. It just sends the same BSN
* twice in the block. The cs should be derived from the TBF's
* current CS such that both BSNs (that must be compatible) can
* be put into the data area, even if the resulting CS is higher than
* the current limit.
*/
cs = m_rlc.block(index)->cs_current_trans;
enum CodingScheme cs_init = m_rlc.block(index)->cs_init;
bsns[0] = index;
num_bsns = 1;
if (index2 >= 0) {
bsns[num_bsns] = index2;
num_bsns += 1;
}
update_coding_scheme_counter_dl(cs);
/*
* if the intial mcs is 8 and retransmission mcs is either 6 or 3
* we have to include the padding of 6 octets in first segment
*/
if ((cs_init == MCS8) &&
(cs == MCS6 || cs == MCS3)) {
if (spb_status == EGPRS_RESEG_DL_DEFAULT ||
spb_status == EGPRS_RESEG_SECOND_SEG_SENT)
need_padding = true;
} else if (num_bsns == 1) {
/* TODO: remove the conditional when MCS-6 padding isn't
* failing to be decoded by MEs anymore */
/* TODO: support of MCS-8 -> MCS-6 transition should be
* handled
* Refer commit be881c028fc4da00c4046ecd9296727975c206a3
* dated 2016-02-07 23:45:40 (UTC)
*/
if (cs != MCS8)
mcs_dec_to_single_block(&cs, &need_padding);
}
spb = get_egprs_dl_spb(index);
LOGPTBFDL(this, LOGL_DEBUG, "need_padding %d spb_status %d spb %d (BSN1 %d BSN2 %d)\n",
need_padding, spb_status, spb, index, index2);
gprs_rlc_data_info_init_dl(&rlc, cs, need_padding, spb);
rlc.usf = 7; /* will be set at scheduler */
rlc.pr = 0; /* FIXME: power reduction */
rlc.tfi = m_tfi; /* TFI */
/* return data block(s) as message */
msg_len = mcs_size_dl(cs);
dl_msg = msgb_alloc(msg_len, "rlcmac_dl_data");
if (!dl_msg)
return NULL;
msg_data = msgb_put(dl_msg, msg_len);
OSMO_ASSERT(rlc.num_data_blocks <= ARRAY_SIZE(rlc.block_info));
OSMO_ASSERT(rlc.num_data_blocks > 0);
LOGPTBFDL(this, LOGL_DEBUG, "Copying %u RLC blocks, %u BSNs\n", rlc.num_data_blocks, num_bsns);
/* Copy block(s) to RLC message: the num_data_blocks cannot be more than 2 - see assert above */
for (data_block_idx = 0; data_block_idx < OSMO_MIN(rlc.num_data_blocks, 2);
data_block_idx++)
{
int bsn;
uint8_t *block_data;
gprs_rlc_data_block_info *rdbi, *block_info;
enum egprs_rlc_dl_reseg_bsn_state reseg_status;
/* Check if there are more blocks than BSNs */
if (data_block_idx < num_bsns)
bsn = bsns[data_block_idx];
else
bsn = bsns[0];
/* Get current puncturing scheme from block */
m_rlc.block(bsn)->next_ps = gprs_get_punct_scheme(
m_rlc.block(bsn)->next_ps,
m_rlc.block(bsn)->cs_last, cs, spb);
if (mcs_is_edge(cs)) {
OSMO_ASSERT(m_rlc.block(bsn)->next_ps >= EGPRS_PS_1);
OSMO_ASSERT(m_rlc.block(bsn)->next_ps <= EGPRS_PS_3);
}
punct[data_block_idx] = m_rlc.block(bsn)->next_ps;
rdbi = &rlc.block_info[data_block_idx];
block_info = &m_rlc.block(bsn)->block_info;
/*
* get data and header from current block
* function returns the reseg status
*/
reseg_status = egprs_dl_get_data(bsn, &block_data);
m_rlc.block(bsn)->spb_status.block_status_dl = reseg_status;
/*
* If it is first segment of the split block set the state of
* bsn to nacked. If it is the first segment dont update the
* next ps value of bsn. since next segment also needs same cps
*/
if (spb == EGPRS_RLCMAC_DL_FIRST_SEG)
m_window.m_v_b.mark_nacked(bsn);
else {
/*
* TODO: Need to handle 2 same bsns
* in header type 1
*/
gprs_update_punct_scheme(&m_rlc.block(bsn)->next_ps,
cs);
}
m_rlc.block(bsn)->cs_last = cs;
rdbi->e = block_info->e;
rdbi->cv = block_info->cv;
rdbi->bsn = bsn;
is_final = is_final || rdbi->cv == 0;
LOGPTBFDL(this, LOGL_DEBUG, "Copying data unit %d (BSN %d)\n",
data_block_idx, bsn);
Encoding::rlc_copy_from_aligned_buffer(&rlc, data_block_idx,
msg_data, block_data);
}
/* Calculate CPS only for EGPRS case */
if (mcs_is_edge(cs))
rlc.cps = gprs_rlc_mcs_cps(cs, punct[0], punct[1], need_padding);
/* If the TBF has just started, relate frames_since_last_poll to the
* current fn */
if (m_last_dl_poll_fn < 0)
m_last_dl_poll_fn = fn;
/* poll after POLL_ACK_AFTER_FRAMES frames, or when final block is tx or
* when last polled DL ACK/NACK was lost. Always do so in the control TS. */
if (tbf_is_control_ts(dl_tbf_as_tbf(this), pdch) &&
need_poll_for_dl_ack_nack()) {
if (m_dl_ack_requested) {
LOGPTBFDL(this, LOGL_DEBUG,
"Scheduling Ack/Nack polling, because it was requested explicitly "
"(e.g. first final block sent).\n");
} else if (m_last_dl_poll_ack_lost) {
LOGPTBFDL(this, LOGL_DEBUG,
"Scheduling Ack/Nack polling, because polling timed out.\n");
} else {
LOGPTBFDL(this, LOGL_DEBUG,
"Scheduling Ack/Nack polling, because %d blocks sent.\n",
POLL_ACK_AFTER_FRAMES);
}
rc = tbf_check_polling(this, pdch, fn, &new_poll_fn, &rrbp);
if (rc >= 0) {
tbf_set_polling(this, pdch, new_poll_fn, PDCH_ULC_POLL_DL_ACK);
LOGPTBFDL(this, LOGL_DEBUG,
"Scheduled DL Acknowledgement polling on PACCH (FN=%d, TS=%d)\n",
new_poll_fn, pdch->ts_no);
m_tx_counter = 0;
/* start timer whenever we send the final block */
if (is_final)
T_START(this, T3191, 3191, "final block (DL-TBF)", true);
/* Clear request flag */
m_dl_ack_requested = false;
/* clear poll timeout flag */
m_last_dl_poll_ack_lost = false;
/* set polling in header */
rlc.rrbp = rrbp;
rlc.es_p = 1; /* Polling */
m_last_dl_poll_fn = new_poll_fn;
LOGPTBFDL(this, LOGL_INFO,
"Scheduled Ack/Nack polling on FN=%d, TS=%d\n",
new_poll_fn, pdch->ts_no);
}
}
Encoding::rlc_write_dl_data_header(&rlc, msg_data);
LOGPTBFDL(this, LOGL_DEBUG, "msg block (BSN %d, %s%s): %s\n",
index, mcs_name(cs),
need_padding ? ", padded" : "",
msgb_hexdump(dl_msg));
/* Increment TX-counter */
m_tx_counter++;
return dl_msg;
}
static uint16_t bitnum_to_bsn(int bitnum, uint16_t ssn)
{
return ssn - 1 - bitnum;
}
int gprs_rlcmac_dl_tbf::analyse_errors(char *show_rbb, uint8_t ssn,
ana_result *res)
{
gprs_rlc_data *rlc_data;
uint16_t lost = 0, received = 0, skipped = 0;
char info[RLC_MAX_WS + 1];
memset(info, '.', m_window.ws());
info[m_window.ws()] = 0;
uint16_t bsn = 0;
unsigned received_bytes = 0, lost_bytes = 0;
unsigned received_packets = 0, lost_packets = 0;
unsigned num_blocks = strlen(show_rbb);
unsigned distance = m_window.distance();
num_blocks = num_blocks > distance
? distance : num_blocks;
/* SSN - 1 is in range V(A)..V(S)-1 */
for (unsigned int bitpos = 0; bitpos < num_blocks; bitpos++) {
bool is_received;
int index = num_blocks - 1 - bitpos;
is_received = (index >= 0 && show_rbb[index] == 'R');
bsn = m_window.mod_sns(bitnum_to_bsn(bitpos, ssn));
if (bsn == m_window.mod_sns(m_window.v_a() - 1)) {
info[bitpos] = '$';
break;
}
rlc_data = m_rlc.block(bsn);
if (!rlc_data) {
info[bitpos] = '0';
continue;
}
/* Get general statistics */
if (is_received && !m_window.m_v_b.is_acked(bsn)) {
received_packets += 1;
received_bytes += rlc_data->len;
} else if (!is_received && !m_window.m_v_b.is_nacked(bsn)) {
lost_packets += 1;
lost_bytes += rlc_data->len;
}
/* Get statistics for current CS */
if (rlc_data->cs_last != current_cs()) {
/* This block has already been encoded with a different
* CS, so it doesn't help us to decide, whether the
* current CS is ok. Ignore it. */
info[bitpos] = 'x';
skipped += 1;
continue;
}
if (is_received) {
if (!m_window.m_v_b.is_acked(bsn)) {
received += 1;
info[bitpos] = 'R';
} else {
info[bitpos] = 'r';
}
} else {
info[bitpos] = 'L';
lost += 1;
}
}
LOGPTBFDL(this, LOGL_DEBUG,
"DL analysis, range=%d:%d, lost=%d, recv=%d, skipped=%d, bsn=%d, info='%s'\n",
m_window.v_a(), m_window.v_s(), lost, received, skipped, bsn, info);
res->received_packets = received_packets;
res->lost_packets = lost_packets;
res->received_bytes = received_bytes;
res->lost_bytes = lost_bytes;
if (lost + received <= 1)
return -1;
return lost * 100 / (lost + received);
}
gprs_rlc_window *gprs_rlcmac_dl_tbf::window()
{
return &m_window;
}
int gprs_rlcmac_dl_tbf::update_window(unsigned first_bsn,
const struct bitvec *rbb)
{
unsigned dist;
uint16_t lost = 0, received = 0;
char show_v_b[RLC_MAX_SNS + 1];
char show_rbb[RLC_MAX_SNS + 1];
int error_rate;
struct ana_result ana_res;
dist = m_window.distance();
unsigned num_blocks = rbb->cur_bit > dist
? dist : rbb->cur_bit;
unsigned behind_last_bsn = m_window.mod_sns(first_bsn + num_blocks);
Decoding::extract_rbb(rbb, show_rbb);
/* show received array in debug */
LOGPTBFDL(this, LOGL_DEBUG,
"ack: (BSN=%d)\"%s\"(BSN=%d) R=ACK I=NACK\n",
first_bsn, show_rbb, m_window.mod_sns(behind_last_bsn - 1));
error_rate = analyse_errors(show_rbb, behind_last_bsn, &ana_res);
if (the_pcu->vty.cs_adj_enabled && ms())
ms_update_error_rate(ms(), this, error_rate);
m_window.update(bts, rbb, first_bsn, &lost, &received);
rate_ctr_add(rate_ctr_group_get_ctr(m_ctrs, TBF_CTR_RLC_NACKED), lost);
/* report lost and received packets */
gprs_rlcmac_received_lost(this, received, lost);
/* Used to measure the leak rate */
gprs_bssgp_update_bytes_received(ana_res.received_bytes,
ana_res.received_packets + ana_res.lost_packets);
/* raise V(A), if possible */
m_window.raise(m_window.move_window());
/* show receive state array in debug (V(A)..V(S)-1) */
m_window.show_state(show_v_b);
LOGPTBFDL(this, LOGL_DEBUG,
"V(B): (V(A)=%d)\"%s\"(V(S)-1=%d) A=Acked N=Nacked U=Unacked X=Resend-Unacked I=Invalid\n",
m_window.v_a(), show_v_b, m_window.v_s_mod(-1));
return 0;
}
int gprs_rlcmac_dl_tbf::rcvd_dl_final_ack()
{
uint16_t received;
int rc;
/* range V(A)..V(S)-1 */
received = m_window.count_unacked();
/* report all outstanding packets as received */
gprs_rlcmac_received_lost(this, received, 0);
m_tx_counter = 0;
m_window.reset();
rc = osmo_fsm_inst_dispatch(this->state_fi, TBF_EV_FINAL_ACK_RECVD, NULL);
return rc;
}
int gprs_rlcmac_dl_tbf::rcvd_dl_ack(bool final_ack, unsigned first_bsn,
struct bitvec *rbb)
{
int rc;
LOGPTBFDL(this, LOGL_DEBUG, "downlink acknowledge\n");
if (m_first_dl_ack_rcvd == false) {
/* MS is there, free temporarily stored transmitted LLC PDUs */
struct gprs_dl_llc_llist_item *llc_it;
while ((llc_it = llist_first_entry_or_null(&this->tx_llc_until_first_dl_ack_rcvd, struct gprs_dl_llc_llist_item, list))) {
llist_del(&llc_it->list);
talloc_free(llc_it);
}
m_first_dl_ack_rcvd = true;
}
m_last_dl_poll_ack_lost = false;
/* reset N3105 */
n_reset(N3105);
t_stop(T3191, "ACK/NACK received");
rc = update_window(first_bsn, rbb);
if (final_ack) {
LOGPTBFDL(this, LOGL_DEBUG, "Final ACK received.\n");
rc = rcvd_dl_final_ack();
} else if (state_is(TBF_ST_FINISHED) && m_window.window_empty()) {
LOGPTBFDL(this, LOGL_NOTICE,
"Received acknowledge of all blocks, but without final ack indication (don't worry)\n");
}
return rc;
}
bool gprs_rlcmac_dl_tbf::dl_window_stalled() const
{
return m_window.window_stalled();
}
void gprs_rlcmac_dl_tbf::request_dl_ack()
{
m_dl_ack_requested = true;
}
void dl_tbf_request_dl_ack(struct gprs_rlcmac_dl_tbf *dl_tbf) {
dl_tbf->request_dl_ack();
}
bool dl_tbf_first_dl_ack_rcvd(const struct gprs_rlcmac_dl_tbf *tbf)
{
return tbf->m_first_dl_ack_rcvd;
}
/* Copy back to GprsMs' llc_queue the LLC PDUs previously dequeued and never
* fully ACKED at the MS side.
* FIXME: For now, only blocks transmitted and without first ever DL ACK are
* copied, because we have no way yet to track LLC PDUs once they are converted
* to RLC blocks. This is however enough to cover the case where a DL TBF is
* assigned over PCH and the MS never answers.
*/
void dl_tbf_copy_unacked_pdus_to_llc_queue(struct gprs_rlcmac_dl_tbf *tbf)
{
struct GprsMs *ms = tbf_ms(dl_tbf_as_tbf(tbf));
struct gprs_dl_llc_llist_item *llc_it;
/* If we have LLC PDU still being transmitted, prepend it first to the queue: */
if (llc_frame_length(&tbf->m_llc) > 0)
llc_queue_merge_prepend(&ms->llc_queue, &tbf->m_llc);
/* Iterate over the list of totally transmitted LLC PDUs and merge them
* into the queue. The items in the list are in inverse order of
* transmission, hence when popping from here and enqueueing (prepending)
* back to the llc_queue it ends up in the exact same initial order. */
while ((llc_it = llist_first_entry_or_null(&tbf->tx_llc_until_first_dl_ack_rcvd, struct gprs_dl_llc_llist_item, list))) {
llist_del(&llc_it->list);
llc_queue_merge_prepend(&ms->llc_queue, &llc_it->llc);
talloc_free(llc_it);
}
}
/* Does this DL TBF require to poll the MS for DL ACK/NACK? */
bool gprs_rlcmac_dl_tbf::need_poll_for_dl_ack_nack() const
{
/* poll after POLL_ACK_AFTER_FRAMES frames, or when final block is tx or
* when last polled DL ACK/NACK was lost. */
return m_last_dl_poll_ack_lost ||
m_tx_counter >= POLL_ACK_AFTER_FRAMES ||
m_dl_ack_requested;
}
bool gprs_rlcmac_dl_tbf::have_data() const
{
return llc_chunk_size(&m_llc) > 0 ||
(llc_queue_size(llc_queue()) > 0);
}
static inline int frames_since_last(int32_t last, unsigned fn)
{
unsigned wrapped = (fn + GSM_MAX_FN - last) % GSM_MAX_FN;
if (last < 0)
return -1;
if (wrapped < GSM_MAX_FN/2)
return wrapped;
return wrapped - GSM_MAX_FN;
}
int gprs_rlcmac_dl_tbf::frames_since_last_poll(unsigned fn) const
{
return frames_since_last(m_last_dl_poll_fn, fn);
}
int gprs_rlcmac_dl_tbf::frames_since_last_drain(unsigned fn) const
{
return frames_since_last(m_last_dl_drained_fn, fn);
}
bool gprs_rlcmac_dl_tbf::keep_open(unsigned fn) const
{
int keep_time_frames;
unsigned long dl_tbf_idle_msec;
int since_last_drain;
bool keep;
dl_tbf_idle_msec = osmo_tdef_get(the_pcu->T_defs, -2031, OSMO_TDEF_MS, -1);
if (dl_tbf_idle_msec == 0)
return false;
keep_time_frames = msecs_to_frames(dl_tbf_idle_msec);
since_last_drain = frames_since_last_drain(fn);
keep = since_last_drain <= keep_time_frames;
if (since_last_drain >= 0)
LOGPTBFDL(this, LOGL_DEBUG, "Keep idle TBF open: %d/%d -> %s\n",
since_last_drain, keep_time_frames, keep ? "yes" : "no");
return keep;
}
/*
* This function returns the pointer to data which needs
* to be copied. Also updates the status of the block related to
* Split block handling in the RLC/MAC block.
*/
enum egprs_rlc_dl_reseg_bsn_state
gprs_rlcmac_dl_tbf::egprs_dl_get_data(int bsn, uint8_t **block_data)
{
gprs_rlc_data *rlc_data = m_rlc.block(bsn);
egprs_rlc_dl_reseg_bsn_state *block_status_dl =
&rlc_data->spb_status.block_status_dl;
enum CodingScheme cs_init = rlc_data->cs_init;
enum CodingScheme cs_current_trans = rlc_data->cs_current_trans;
enum HeaderType ht_cs_init = mcs_header_type(rlc_data->cs_init);
enum HeaderType ht_cs_current_trans = mcs_header_type(rlc_data->cs_current_trans);
*block_data = &rlc_data->block[0];
/*
* Table 10.3a.0.1 of 44.060
* MCS6,9: second segment starts at 74/2 = 37
* MCS5,7: second segment starts at 56/2 = 28
* MCS8: second segment starts at 31
* MCS4: second segment starts at 44/2 = 22
*/
if (ht_cs_current_trans == HEADER_EGPRS_DATA_TYPE_3) {
if (*block_status_dl == EGPRS_RESEG_FIRST_SEG_SENT) {
switch (cs_init) {
case MCS6 :
case MCS9 :
*block_data = &rlc_data->block[37];
break;
case MCS7 :
case MCS5 :
*block_data = &rlc_data->block[28];
break;
case MCS8 :
*block_data = &rlc_data->block[31];
break;
case MCS4 :
*block_data = &rlc_data->block[22];
break;
default:
LOGPTBFDL(this, LOGL_ERROR,
"FIXME: Software error: hit invalid condition. "
"headerType(%d) blockstatus(%d) cs(%s) PLEASE FIX!\n",
ht_cs_current_trans,
*block_status_dl, mcs_name(cs_init));
break;
}
return EGPRS_RESEG_SECOND_SEG_SENT;
} else if ((ht_cs_init == HEADER_EGPRS_DATA_TYPE_1) ||
(ht_cs_init == HEADER_EGPRS_DATA_TYPE_2)) {
return EGPRS_RESEG_FIRST_SEG_SENT;
} else if ((cs_init == MCS4) &&
(cs_current_trans == MCS1)) {
return EGPRS_RESEG_FIRST_SEG_SENT;
}
}
return EGPRS_RESEG_DL_DEFAULT;
}
/*
* This function returns the status of split block
* for RLC/MAC block.
*/
unsigned int gprs_rlcmac_dl_tbf::get_egprs_dl_spb_status(const int bsn)
{
const gprs_rlc_data *rlc_data = m_rlc.block(bsn);
return rlc_data->spb_status.block_status_dl;
}
/*
* This function returns the spb value to be sent OTA
* for RLC/MAC block.
*/
enum egprs_rlcmac_dl_spb gprs_rlcmac_dl_tbf::get_egprs_dl_spb(const int bsn)
{
struct gprs_rlc_data *rlc_data = m_rlc.block(bsn);
egprs_rlc_dl_reseg_bsn_state block_status_dl = rlc_data->spb_status.block_status_dl;
enum CodingScheme cs_init = rlc_data->cs_init;
enum CodingScheme cs_current_trans = rlc_data->cs_current_trans;
enum HeaderType ht_cs_init = mcs_header_type(rlc_data->cs_init);
enum HeaderType ht_cs_current_trans = mcs_header_type(rlc_data->cs_current_trans);
/* Table 10.4.8b.1 of 44.060 */
if (ht_cs_current_trans == HEADER_EGPRS_DATA_TYPE_3) {
/*
* if we are sending the second segment the spb should be 3
* otherwise it should be 2
*/
if (block_status_dl == EGPRS_RESEG_FIRST_SEG_SENT) {
/* statistics */
bts_do_rate_ctr_inc(bts, CTR_SPB_DL_SECOND_SEGMENT);
return EGPRS_RLCMAC_DL_SEC_SEG;
} else if ((ht_cs_init == HEADER_EGPRS_DATA_TYPE_1) ||
(ht_cs_init == HEADER_EGPRS_DATA_TYPE_2)) {
bts_do_rate_ctr_inc(bts, CTR_SPB_DL_FIRST_SEGMENT);
return EGPRS_RLCMAC_DL_FIRST_SEG;
} else if ((cs_init == MCS4) &&
(cs_current_trans == MCS1)) {
bts_do_rate_ctr_inc(bts, CTR_SPB_DL_FIRST_SEGMENT);
return EGPRS_RLCMAC_DL_FIRST_SEG;
}
}
/* Non SPB cases 0 is reurned */
return EGPRS_RLCMAC_DL_NO_RETX;
}
void gprs_rlcmac_dl_tbf::set_window_size()
{
const struct gprs_rlcmac_bts *b = bts;
uint16_t ws = egprs_window_size(b, dl_slots());
LOGPTBFDL(this, LOGL_INFO, "setting EGPRS DL window size to %u, base(%u) slots(%u) ws_pdch(%u)\n",
ws, bts->pcu->vty.ws_base, pcu_bitcount(dl_slots()), bts->pcu->vty.ws_pdch);
m_window.set_ws(ws);
}
void gprs_rlcmac_dl_tbf::update_coding_scheme_counter_dl(enum CodingScheme cs)
{
switch (cs) {
case CS1:
bts_do_rate_ctr_inc(bts, CTR_GPRS_DL_CS1);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_gprs_ctrs, TBF_CTR_GPRS_DL_CS1));
break;
case CS2:
bts_do_rate_ctr_inc(bts, CTR_GPRS_DL_CS2);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_gprs_ctrs, TBF_CTR_GPRS_DL_CS2));
break;
case CS3:
bts_do_rate_ctr_inc(bts, CTR_GPRS_DL_CS3);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_gprs_ctrs, TBF_CTR_GPRS_DL_CS3));
break;
case CS4:
bts_do_rate_ctr_inc(bts, CTR_GPRS_DL_CS4);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_gprs_ctrs, TBF_CTR_GPRS_DL_CS4));
break;
case MCS1:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS1);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS1));
break;
case MCS2:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS2);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS2));
break;
case MCS3:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS3);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS3));
break;
case MCS4:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS4);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS4));
break;
case MCS5:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS5);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS5));
break;
case MCS6:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS6);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS6));
break;
case MCS7:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS7);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS7));
break;
case MCS8:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS8);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS8));
break;
case MCS9:
bts_do_rate_ctr_inc(bts, CTR_EGPRS_DL_MCS9);
rate_ctr_inc(rate_ctr_group_get_ctr(m_dl_egprs_ctrs, TBF_CTR_EGPRS_DL_MCS9));
break;
default:
LOGPTBFDL(this, LOGL_ERROR, "attempting to update rate counters for unsupported (M)CS %s\n",
mcs_name(cs));
}
}
struct gprs_rlcmac_dl_tbf *tbf_as_dl_tbf(struct gprs_rlcmac_tbf *tbf)
{
if (tbf && tbf->direction == GPRS_RLCMAC_DL_TBF)
return static_cast<gprs_rlcmac_dl_tbf *>(tbf);
else
return NULL;
}
const struct gprs_rlcmac_dl_tbf *tbf_as_dl_tbf_const(const struct gprs_rlcmac_tbf *tbf)
{
if (tbf && tbf->direction == GPRS_RLCMAC_DL_TBF)
return static_cast<const gprs_rlcmac_dl_tbf *>(tbf);
else
return NULL;
}
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