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osmo-pcu
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osmo-pcu/src/pcu_vty.c

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/* OsmoBTS VTY interface */
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <osmocom/vty/logging.h>
#include <osmocom/vty/stats.h>
#include <osmocom/vty/misc.h>
#include <osmocom/core/linuxlist.h>
#include <osmocom/core/rate_ctr.h>
#include <osmocom/pcu/pcuif_proto.h>
#include "pcu_vty.h"
#include "gprs_rlcmac.h"
#include "bts.h"
#include "tbf.h"
#include "pcu_vty_functions.h"
extern void *tall_pcu_ctx;
static const struct value_string pcu_gsmtap_categ_names[] = {
{ PCU_GSMTAP_C_DL_UNKNOWN, "dl-unknown" },
{ PCU_GSMTAP_C_DL_DUMMY, "dl-dummy" },
{ PCU_GSMTAP_C_DL_CTRL, "dl-ctrl" },
{ PCU_GSMTAP_C_DL_DATA_GPRS, "dl-data-gprs" },
{ PCU_GSMTAP_C_DL_DATA_EGPRS, "dl-data-egprs" },
{ PCU_GSMTAP_C_DL_PTCCH, "dl-ptcch" },
{ PCU_GSMTAP_C_UL_UNKNOWN, "ul-unknown" },
{ PCU_GSMTAP_C_UL_DUMMY, "ul-dummy" },
{ PCU_GSMTAP_C_UL_CTRL, "ul-ctrl" },
{ PCU_GSMTAP_C_UL_DATA_GPRS, "ul-data-gprs" },
{ PCU_GSMTAP_C_UL_DATA_EGPRS, "ul-data-egprs" },
{ 0, NULL }
};
static const struct value_string pcu_gsmtap_categ_help[] = {
{ PCU_GSMTAP_C_DL_UNKNOWN, "Unknown / Unparseable / Erroneous Downlink Blocks" },
{ PCU_GSMTAP_C_DL_DUMMY, "Downlink Dummy Blocks" },
{ PCU_GSMTAP_C_DL_CTRL, "Downlink Control Blocks" },
{ PCU_GSMTAP_C_DL_DATA_GPRS, "Downlink Data Blocks (GPRS)" },
{ PCU_GSMTAP_C_DL_DATA_EGPRS, "Downlink Data Blocks (EGPRS)" },
{ PCU_GSMTAP_C_DL_PTCCH, "Downlink PTCCH Blocks" },
{ PCU_GSMTAP_C_UL_UNKNOWN, "Unknown / Unparseable / Erroneous Downlink Blocks" },
{ PCU_GSMTAP_C_UL_DUMMY, "Uplink Dummy Blocks" },
{ PCU_GSMTAP_C_UL_CTRL, "Uplink Control Blocks" },
{ PCU_GSMTAP_C_UL_DATA_GPRS, "Uplink Data Blocks (GPRS)" },
{ PCU_GSMTAP_C_UL_DATA_EGPRS, "Uplink Data Blocks (EGPRS)" },
{ 0, NULL }
};
DEFUN(cfg_pcu_gsmtap_categ, cfg_pcu_gsmtap_categ_cmd, "HIDDEN", "HIDDEN")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
int categ;
categ = get_string_value(pcu_gsmtap_categ_names, argv[0]);
if (categ < 0)
return CMD_WARNING;
bts->gsmtap_categ_mask |= (1 << categ);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_gsmtap_categ, cfg_pcu_no_gsmtap_categ_cmd, "HIDDEN", "HIDDEN")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
int categ;
categ = get_string_value(pcu_gsmtap_categ_names, argv[0]);
if (categ < 0)
return CMD_WARNING;
bts->gsmtap_categ_mask &= ~(1 << categ);
return CMD_SUCCESS;
}
int pcu_vty_go_parent(struct vty *vty)
{
switch (vty->node) {
#if 0
case TRX_NODE:
vty->node = PCU_NODE;
{
struct gsm_bts_trx *trx = vty->index;
vty->index = trx->bts;
}
break;
#endif
default:
vty->node = CONFIG_NODE;
}
return (enum node_type) vty->node;
}
int pcu_vty_is_config_node(struct vty *vty, int node)
{
switch (node) {
case PCU_NODE:
return 1;
default:
return 0;
}
}
static struct cmd_node pcu_node = {
(enum node_type) PCU_NODE,
"%s(config-pcu)# ",
1,
};
static int config_write_pcu(struct vty *vty)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
unsigned int i;
vty_out(vty, "pcu%s", VTY_NEWLINE);
if (bts->egprs_enabled)
vty_out(vty, " egprs only%s", VTY_NEWLINE);
vty_out(vty, " flow-control-interval %d%s", bts->fc_interval,
VTY_NEWLINE);
if (bts->fc_bvc_bucket_size)
vty_out(vty, " flow-control force-bvc-bucket-size %d%s",
bts->fc_bvc_bucket_size, VTY_NEWLINE);
if (bts->fc_bvc_leak_rate)
vty_out(vty, " flow-control force-bvc-leak-rate %d%s",
bts->fc_bvc_leak_rate, VTY_NEWLINE);
if (bts->fc_ms_bucket_size)
vty_out(vty, " flow-control force-ms-bucket-size %d%s",
bts->fc_ms_bucket_size, VTY_NEWLINE);
if (bts->fc_ms_leak_rate)
vty_out(vty, " flow-control force-ms-leak-rate %d%s",
bts->fc_ms_leak_rate, VTY_NEWLINE);
if (bts->force_cs) {
if (bts->initial_cs_ul == bts->initial_cs_dl)
vty_out(vty, " cs %d%s", bts->initial_cs_dl,
VTY_NEWLINE);
else
vty_out(vty, " cs %d %d%s", bts->initial_cs_dl,
bts->initial_cs_ul, VTY_NEWLINE);
}
if (bts->max_cs_dl && bts->max_cs_ul) {
if (bts->max_cs_ul == bts->max_cs_dl)
vty_out(vty, " cs max %d%s", bts->max_cs_dl,
VTY_NEWLINE);
else
vty_out(vty, " cs max %d %d%s", bts->max_cs_dl,
bts->max_cs_ul, VTY_NEWLINE);
}
if (bts->cs_adj_enabled)
vty_out(vty, " cs threshold %d %d%s",
bts->cs_adj_lower_limit, bts->cs_adj_upper_limit,
VTY_NEWLINE);
else
vty_out(vty, " no cs threshold%s", VTY_NEWLINE);
if (bts->cs_downgrade_threshold)
vty_out(vty, " cs downgrade-threshold %d%s",
bts->cs_downgrade_threshold, VTY_NEWLINE);
else
vty_out(vty, " no cs downgrade-threshold%s", VTY_NEWLINE);
vty_out(vty, " cs link-quality-ranges cs1 %d cs2 %d %d cs3 %d %d cs4 %d%s",
bts->cs_lqual_ranges[0].high,
bts->cs_lqual_ranges[1].low,
bts->cs_lqual_ranges[1].high,
bts->cs_lqual_ranges[2].low,
bts->cs_lqual_ranges[2].high,
bts->cs_lqual_ranges[3].low,
VTY_NEWLINE);
vty_out(vty, " mcs link-quality-ranges mcs1 %d mcs2 %d %d mcs3 %d %d mcs4 %d %d mcs5 %d %d mcs6 %d %d mcs7 %d %d mcs8 %d %d mcs9 %d%s",
bts->mcs_lqual_ranges[0].high,
bts->mcs_lqual_ranges[1].low,
bts->mcs_lqual_ranges[1].high,
bts->mcs_lqual_ranges[2].low,
bts->mcs_lqual_ranges[2].high,
bts->mcs_lqual_ranges[3].low,
bts->mcs_lqual_ranges[3].high,
bts->mcs_lqual_ranges[4].low,
bts->mcs_lqual_ranges[4].high,
bts->mcs_lqual_ranges[5].low,
bts->mcs_lqual_ranges[5].high,
bts->mcs_lqual_ranges[6].low,
bts->mcs_lqual_ranges[6].high,
bts->mcs_lqual_ranges[7].low,
bts->mcs_lqual_ranges[7].high,
bts->mcs_lqual_ranges[8].low,
VTY_NEWLINE);
if (bts->initial_mcs_dl != 1 && bts->initial_mcs_ul != 1) {
if (bts->initial_mcs_ul == bts->initial_mcs_dl)
vty_out(vty, " mcs %d%s", bts->initial_mcs_dl,
VTY_NEWLINE);
else
vty_out(vty, " mcs %d %d%s", bts->initial_mcs_dl,
bts->initial_mcs_ul, VTY_NEWLINE);
}
if (bts->max_mcs_dl && bts->max_mcs_ul) {
if (bts->max_mcs_ul == bts->max_mcs_dl)
vty_out(vty, " mcs max %d%s", bts->max_mcs_dl,
VTY_NEWLINE);
else
vty_out(vty, " mcs max %d %d%s", bts->max_mcs_dl,
bts->max_mcs_ul, VTY_NEWLINE);
}
vty_out(vty, " window-size %d %d%s", bts->ws_base, bts->ws_pdch,
VTY_NEWLINE);
if (bts->dl_arq_type)
vty_out(vty, " egprs dl arq-type arq2%s",
VTY_NEWLINE);
if (bts->force_llc_lifetime == 0xffff)
vty_out(vty, " queue lifetime infinite%s", VTY_NEWLINE);
else if (bts->force_llc_lifetime)
vty_out(vty, " queue lifetime %d%s", bts->force_llc_lifetime,
VTY_NEWLINE);
if (bts->llc_discard_csec)
vty_out(vty, " queue hysteresis %d%s", bts->llc_discard_csec,
VTY_NEWLINE);
if (bts->llc_idle_ack_csec)
vty_out(vty, " queue idle-ack-delay %d%s", bts->llc_idle_ack_csec,
VTY_NEWLINE);
if (bts->llc_codel_interval_msec == LLC_CODEL_USE_DEFAULT)
vty_out(vty, " queue codel%s", VTY_NEWLINE);
else if (bts->llc_codel_interval_msec == LLC_CODEL_DISABLE)
vty_out(vty, " no queue codel%s", VTY_NEWLINE);
else
vty_out(vty, " queue codel interval %d%s",
bts->llc_codel_interval_msec/10, VTY_NEWLINE);
if (bts->alloc_algorithm == alloc_algorithm_a)
vty_out(vty, " alloc-algorithm a%s", VTY_NEWLINE);
if (bts->alloc_algorithm == alloc_algorithm_b)
vty_out(vty, " alloc-algorithm b%s", VTY_NEWLINE);
if (bts->alloc_algorithm == alloc_algorithm_dynamic)
vty_out(vty, " alloc-algorithm dynamic%s", VTY_NEWLINE);
if (bts->force_two_phase)
vty_out(vty, " two-phase-access%s", VTY_NEWLINE);
vty_out(vty, " alpha %d%s", bts->alpha, VTY_NEWLINE);
vty_out(vty, " gamma %d%s", bts->gamma * 2, VTY_NEWLINE);
if (bts->dl_tbf_idle_msec)
vty_out(vty, " dl-tbf-idle-time %d%s", bts->dl_tbf_idle_msec,
VTY_NEWLINE);
if (strcmp(bts->pcu_sock_path, PCU_SOCK_DEFAULT))
vty_out(vty, " pcu-socket %s%s", bts->pcu_sock_path, VTY_NEWLINE);
for (i = 0; i < 32; i++) {
unsigned int cs = (1 << i);
if (bts->gsmtap_categ_mask & cs) {
vty_out(vty, " gsmtap-category %s%s",
get_value_string(pcu_gsmtap_categ_names, i), VTY_NEWLINE);
}
}
return pcu_vty_config_write_pcu_ext(vty);
}
/* per-BTS configuration */
DEFUN(cfg_pcu,
cfg_pcu_cmd,
"pcu",
"BTS specific configure")
{
vty->node = PCU_NODE;
return CMD_SUCCESS;
}
#define EGPRS_STR "EGPRS configuration\n"
DEFUN(cfg_pcu_egprs,
cfg_pcu_egprs_cmd,
"egprs only",
EGPRS_STR "Use EGPRS and disable plain GPRS\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->egprs_enabled = 1;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_egprs,
cfg_pcu_no_egprs_cmd,
"no egprs",
NO_STR EGPRS_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->egprs_enabled = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_fc_interval,
cfg_pcu_fc_interval_cmd,
"flow-control-interval <1-10>",
"Interval between sending subsequent Flow Control PDUs\n"
"Interval time in seconds\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_interval = atoi(argv[0]);
return CMD_SUCCESS;
}
#define FC_STR "BSSGP Flow Control configuration\n"
#define FC_BMAX_STR(who) "Force a fixed value for the " who " bucket size\n"
#define FC_LR_STR(who) "Force a fixed value for the " who " leak rate\n"
DEFUN(cfg_pcu_fc_bvc_bucket_size,
cfg_pcu_fc_bvc_bucket_size_cmd,
"flow-control force-bvc-bucket-size <1-6553500>",
FC_STR FC_BMAX_STR("BVC") "Bucket size in octets\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_bvc_bucket_size = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_fc_bvc_bucket_size,
cfg_pcu_no_fc_bvc_bucket_size_cmd,
"no flow-control force-bvc-bucket-size",
NO_STR FC_STR FC_BMAX_STR("BVC"))
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_bvc_bucket_size = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_fc_bvc_leak_rate,
cfg_pcu_fc_bvc_leak_rate_cmd,
"flow-control force-bvc-leak-rate <1-6553500>",
FC_STR FC_LR_STR("BVC") "Leak rate in bit/s\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_bvc_leak_rate = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_fc_bvc_leak_rate,
cfg_pcu_no_fc_bvc_leak_rate_cmd,
"no flow-control force-bvc-leak-rate",
NO_STR FC_STR FC_LR_STR("BVC"))
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_bvc_leak_rate = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_fc_ms_bucket_size,
cfg_pcu_fc_ms_bucket_size_cmd,
"flow-control force-ms-bucket-size <1-6553500>",
FC_STR FC_BMAX_STR("default MS") "Bucket size in octets\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_ms_bucket_size = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_fc_ms_bucket_size,
cfg_pcu_no_fc_ms_bucket_size_cmd,
"no flow-control force-ms-bucket-size",
NO_STR FC_STR FC_BMAX_STR("default MS"))
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_ms_bucket_size = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_fc_ms_leak_rate,
cfg_pcu_fc_ms_leak_rate_cmd,
"flow-control force-ms-leak-rate <1-6553500>",
FC_STR FC_LR_STR("default MS") "Leak rate in bit/s\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_ms_leak_rate = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_fc_ms_leak_rate,
cfg_pcu_no_fc_ms_leak_rate_cmd,
"no flow-control force-ms-leak-rate",
NO_STR FC_STR FC_LR_STR("default MS"))
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_ms_leak_rate = 0;
return CMD_SUCCESS;
}
#define FC_BTIME_STR "Set target downlink maximum queueing time (only affects the advertised bucket size)\n"
DEFUN(cfg_pcu_fc_bucket_time,
cfg_pcu_fc_bucket_time_cmd,
"flow-control bucket-time <1-65534>",
FC_STR FC_BTIME_STR "Time in centi-seconds\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_bucket_time = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_fc_bucket_time,
cfg_pcu_no_fc_bucket_time_cmd,
"no flow-control bucket-time",
NO_STR FC_STR FC_BTIME_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->fc_bucket_time = 0;
return CMD_SUCCESS;
}
#define CS_STR "Coding Scheme configuration\n"
DEFUN(cfg_pcu_cs,
cfg_pcu_cs_cmd,
"cs <1-4> [<1-4>]",
CS_STR
"Initial CS value to be used (overrides BTS config)\n"
"Use a different initial CS value for the uplink")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint8_t cs = atoi(argv[0]);
bts->force_cs = 1;
bts->initial_cs_dl = cs;
if (argc > 1)
bts->initial_cs_ul = atoi(argv[1]);
else
bts->initial_cs_ul = cs;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_cs,
cfg_pcu_no_cs_cmd,
"no cs",
NO_STR CS_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->force_cs = 0;
return CMD_SUCCESS;
}
#define CS_MAX_STR "Set maximum values for adaptive CS selection (overrides BTS config)\n"
DEFUN(cfg_pcu_cs_max,
cfg_pcu_cs_max_cmd,
"cs max <1-4> [<1-4>]",
CS_STR
CS_MAX_STR
"Maximum CS value to be used\n"
"Use a different maximum CS value for the uplink")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint8_t cs = atoi(argv[0]);
bts->max_cs_dl = cs;
if (argc > 1)
bts->max_cs_ul = atoi(argv[1]);
else
bts->max_cs_ul = cs;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_cs_max,
cfg_pcu_no_cs_max_cmd,
"no cs max",
NO_STR CS_STR CS_MAX_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->max_cs_dl = 0;
bts->max_cs_ul = 0;
return CMD_SUCCESS;
}
#define MCS_STR "Modulation and Coding Scheme configuration (EGPRS)\n"
DEFUN(cfg_pcu_mcs,
cfg_pcu_mcs_cmd,
"mcs <1-9> [<1-9>]",
MCS_STR
"Initial MCS value to be used (default 1)\n"
"Use a different initial MCS value for the uplink")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint8_t cs = atoi(argv[0]);
bts->initial_mcs_dl = cs;
if (argc > 1)
bts->initial_mcs_ul = atoi(argv[1]);
else
bts->initial_mcs_ul = cs;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_mcs,
cfg_pcu_no_mcs_cmd,
"no mcs",
NO_STR MCS_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->initial_mcs_dl = 1;
bts->initial_mcs_ul = 1;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_mcs_max,
cfg_pcu_mcs_max_cmd,
"mcs max <1-9> [<1-9>]",
MCS_STR
CS_MAX_STR
"Maximum MCS value to be used\n"
"Use a different maximum MCS value for the uplink")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint8_t mcs = atoi(argv[0]);
bts->max_mcs_dl = mcs;
if (argc > 1)
bts->max_mcs_ul = atoi(argv[1]);
else
bts->max_mcs_ul = mcs;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_mcs_max,
cfg_pcu_no_mcs_max_cmd,
"no mcs max",
NO_STR MCS_STR CS_MAX_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->max_mcs_dl = 0;
bts->max_mcs_ul = 0;
return CMD_SUCCESS;
}
#define DL_STR "downlink specific configuration\n"
DEFUN(cfg_pcu_dl_arq_type,
cfg_pcu_dl_arq_cmd,
"egprs dl arq-type (spb|arq2)",
EGPRS_STR DL_STR "ARQ options\n"
"enable SPB(ARQ1) support\n"
"enable ARQ2 support")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
if (!strcmp(argv[0], "arq2"))
bts->dl_arq_type = 1;
else
bts->dl_arq_type = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_window_size,
cfg_pcu_window_size_cmd,
"window-size <0-1024> [<0-256>]",
"Window size configuration (b + N_PDCH * f)\n"
"Base value (b)\n"
"Factor for number of PDCH (f)")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint16_t b = atoi(argv[0]);
bts->ws_base = b;
if (argc > 1) {
uint16_t f = atoi(argv[1]);
bts->ws_pdch = f;
}
return CMD_SUCCESS;
}
#define QUEUE_STR "Packet queue options\n"
#define LIFETIME_STR "Set lifetime limit of LLC frame in centi-seconds " \
"(overrides the value given by SGSN)\n"
DEFUN(cfg_pcu_queue_lifetime,
cfg_pcu_queue_lifetime_cmd,
"queue lifetime <1-65534>",
QUEUE_STR LIFETIME_STR "Lifetime in centi-seconds")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint16_t csec = atoi(argv[0]);
bts->force_llc_lifetime = csec;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_queue_lifetime_inf,
cfg_pcu_queue_lifetime_inf_cmd,
"queue lifetime infinite",
QUEUE_STR LIFETIME_STR "Infinite lifetime")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->force_llc_lifetime = 0xffff;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_queue_lifetime,
cfg_pcu_no_queue_lifetime_cmd,
"no queue lifetime",
NO_STR QUEUE_STR "Disable lifetime limit of LLC frame (use value given "
"by SGSN)\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->force_llc_lifetime = 0;
return CMD_SUCCESS;
}
#define QUEUE_HYSTERESIS_STR "Set lifetime hysteresis of LLC frame in centi-seconds " \
"(continue discarding until lifetime-hysteresis is reached)\n"
DEFUN(cfg_pcu_queue_hysteresis,
cfg_pcu_queue_hysteresis_cmd,
"queue hysteresis <1-65535>",
QUEUE_STR QUEUE_HYSTERESIS_STR "Hysteresis in centi-seconds")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint16_t csec = atoi(argv[0]);
bts->llc_discard_csec = csec;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_queue_hysteresis,
cfg_pcu_no_queue_hysteresis_cmd,
"no queue hysteresis",
NO_STR QUEUE_STR QUEUE_HYSTERESIS_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->llc_discard_csec = 0;
return CMD_SUCCESS;
}
#define QUEUE_CODEL_STR "Set CoDel queue management\n"
DEFUN(cfg_pcu_queue_codel,
cfg_pcu_queue_codel_cmd,
"queue codel",
QUEUE_STR QUEUE_CODEL_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->llc_codel_interval_msec = LLC_CODEL_USE_DEFAULT;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_queue_codel_interval,
cfg_pcu_queue_codel_interval_cmd,
"queue codel interval <1-1000>",
QUEUE_STR QUEUE_CODEL_STR "Specify interval\n" "Interval in centi-seconds")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint16_t csec = atoi(argv[0]);
bts->llc_codel_interval_msec = 10*csec;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_queue_codel,
cfg_pcu_no_queue_codel_cmd,
"no queue codel",
NO_STR QUEUE_STR QUEUE_CODEL_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->llc_codel_interval_msec = LLC_CODEL_DISABLE;
return CMD_SUCCESS;
}
#define QUEUE_IDLE_ACK_STR "Request an ACK after the last DL LLC frame in centi-seconds\n"
DEFUN(cfg_pcu_queue_idle_ack_delay,
cfg_pcu_queue_idle_ack_delay_cmd,
"queue idle-ack-delay <1-65535>",
QUEUE_STR QUEUE_IDLE_ACK_STR "Idle ACK delay in centi-seconds")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint16_t csec = atoi(argv[0]);
bts->llc_idle_ack_csec = csec;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_queue_idle_ack_delay,
cfg_pcu_no_queue_idle_ack_delay_cmd,
"no queue idle-ack-delay",
NO_STR QUEUE_STR QUEUE_IDLE_ACK_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->llc_idle_ack_csec = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_alloc,
cfg_pcu_alloc_cmd,
"alloc-algorithm (a|b|dynamic)",
"Select slot allocation algorithm to use when assigning timeslots on "
"PACCH\n"
"Single slot is assigned only\n"
"Multiple slots are assigned for semi-duplex operation\n"
"Dynamically select the algorithm based on the system state\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
switch (argv[0][0]) {
case 'a':
bts->alloc_algorithm = alloc_algorithm_a;
break;
case 'b':
bts->alloc_algorithm = alloc_algorithm_b;
break;
default:
bts->alloc_algorithm = alloc_algorithm_dynamic;
break;
}
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_two_phase,
cfg_pcu_two_phase_cmd,
"two-phase-access",
"Force two phase access when MS requests single phase access\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->force_two_phase = 1;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_two_phase,
cfg_pcu_no_two_phase_cmd,
"no two-phase-access",
NO_STR "Only use two phase access when requested my MS\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->force_two_phase = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_alpha,
cfg_pcu_alpha_cmd,
"alpha <0-10>",
"Alpha parameter for MS power control in units of 0.1 (see TS 05.08) "
"NOTE: Be sure to set Alpha value at System information 13 too.\n"
"Alpha in units of 0.1\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->alpha = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_gamma,
cfg_pcu_gamma_cmd,
"gamma <0-62>",
"Gamma parameter for MS power control in units of dB (see TS 05.08)\n"
"Gamma in even unit of dBs\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->gamma = atoi(argv[0]) / 2;
return CMD_SUCCESS;
}
DEFUN(show_bts_stats,
show_bts_stats_cmd,
"show bts statistics",
SHOW_STR "BTS related functionality\nStatistics\n")
{
vty_out_rate_ctr_group(vty, "", bts_main_data_stats());
return CMD_SUCCESS;
}
#define IDLE_TIME_STR "keep an idle DL TBF alive for the time given\n"
DEFUN(cfg_pcu_dl_tbf_idle_time,
cfg_pcu_dl_tbf_idle_time_cmd,
"dl-tbf-idle-time <1-5000>",
IDLE_TIME_STR "idle time in msec")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->dl_tbf_idle_msec = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_dl_tbf_idle_time,
cfg_pcu_no_dl_tbf_idle_time_cmd,
"no dl-tbf-idle-time",
NO_STR IDLE_TIME_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->dl_tbf_idle_msec = 0;
return CMD_SUCCESS;
}
#define MS_IDLE_TIME_STR "keep an idle MS object alive for the time given\n"
DEFUN(cfg_pcu_ms_idle_time,
cfg_pcu_ms_idle_time_cmd,
"ms-idle-time <1-7200>",
MS_IDLE_TIME_STR "idle time in sec")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->ms_idle_sec = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_ms_idle_time,
cfg_pcu_no_ms_idle_time_cmd,
"no ms-idle-time",
NO_STR MS_IDLE_TIME_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->ms_idle_sec = 0;
return CMD_SUCCESS;
}
#define CS_ERR_LIMITS_STR "set thresholds for error rate based CS adjustment\n"
DEFUN(cfg_pcu_cs_err_limits,
cfg_pcu_cs_err_limits_cmd,
"cs threshold <0-100> <0-100>",
CS_STR CS_ERR_LIMITS_STR "lower limit in %\n" "upper limit in %\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint8_t lower_limit = atoi(argv[0]);
uint8_t upper_limit = atoi(argv[1]);
if (lower_limit > upper_limit) {
vty_out(vty,
"The lower limit must be less than or equal to the "
"upper limit.%s", VTY_NEWLINE);
return CMD_WARNING;
}
bts->cs_adj_enabled = 1;
bts->cs_adj_upper_limit = upper_limit;
bts->cs_adj_lower_limit = lower_limit;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_cs_err_limits,
cfg_pcu_no_cs_err_limits_cmd,
"no cs threshold",
NO_STR CS_STR CS_ERR_LIMITS_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->cs_adj_enabled = 0;
bts->cs_adj_upper_limit = 100;
bts->cs_adj_lower_limit = 0;
return CMD_SUCCESS;
}
#define CS_DOWNGRADE_STR "set threshold for data size based CS downgrade\n"
DEFUN(cfg_pcu_cs_downgrade_thrsh,
cfg_pcu_cs_downgrade_thrsh_cmd,
"cs downgrade-threshold <1-10000>",
CS_STR CS_DOWNGRADE_STR "downgrade if less octets left\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->cs_downgrade_threshold = atoi(argv[0]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_no_cs_downgrade_thrsh,
cfg_pcu_no_cs_downgrade_thrsh_cmd,
"no cs downgrade-threshold",
NO_STR CS_STR CS_DOWNGRADE_STR)
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->cs_downgrade_threshold = 0;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_cs_lqual_ranges,
cfg_pcu_cs_lqual_ranges_cmd,
"cs link-quality-ranges cs1 <0-35> cs2 <0-35> <0-35> cs3 <0-35> <0-35> cs4 <0-35>",
CS_STR "Set link quality ranges\n"
"Set quality range for CS-1 (high value only)\n"
"CS-1 high (dB)\n"
"Set quality range for CS-2\n"
"CS-2 low (dB)\n"
"CS-2 high (dB)\n"
"Set quality range for CS-3\n"
"CS-3 low (dB)\n"
"CS-3 high (dB)\n"
"Set quality range for CS-4 (low value only)\n"
"CS-4 low (dB)\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
uint8_t cs1_high = atoi(argv[0]);
uint8_t cs2_low = atoi(argv[1]);
uint8_t cs2_high = atoi(argv[2]);
uint8_t cs3_low = atoi(argv[3]);
uint8_t cs3_high = atoi(argv[4]);
uint8_t cs4_low = atoi(argv[5]);
bts->cs_lqual_ranges[0].high = cs1_high;
bts->cs_lqual_ranges[1].low = cs2_low;
bts->cs_lqual_ranges[1].high = cs2_high;
bts->cs_lqual_ranges[2].low = cs3_low;
bts->cs_lqual_ranges[2].high = cs3_high;
bts->cs_lqual_ranges[3].low = cs4_low;
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_mcs_lqual_ranges,
cfg_pcu_mcs_lqual_ranges_cmd,
"mcs link-quality-ranges mcs1 <0-35> mcs2 <0-35> <0-35> mcs3 <0-35> <0-35> mcs4 <0-35> <0-35> mcs5 <0-35> <0-35> mcs6 <0-35> <0-35> mcs7 <0-35> <0-35> mcs8 <0-35> <0-35> mcs9 <0-35>",
CS_STR "Set link quality ranges\n"
"Set quality range for MCS-1 (high value only)\n"
"MCS-1 high (dB)\n"
"Set quality range for MCS-2\n"
"MCS-2 high (dB)\n"
"MCS-2 low (dB)\n"
"Set quality range for MCS-3\n"
"MCS-3 high (dB)\n"
"MCS-3 low (dB)\n"
"Set quality range for MCS-4\n"
"MCS-4 high (dB)\n"
"MCS-4 low (dB)\n"
"Set quality range for MCS-5\n"
"MCS-5 high (dB)\n"
"MCS-5 low (dB)\n"
"Set quality range for MCS-6\n"
"MCS-6 low (dB)\n"
"MCS-6 high (dB)\n"
"Set quality range for MCS-7\n"
"MCS-7 low (dB)\n"
"MCS-7 high (dB)\n"
"Set quality range for MCS-8\n"
"MCS-8 low (dB)\n"
"MCS-8 high (dB)\n"
"Set quality range for MCS-9 (low value only)\n"
"MCS-9 low (dB)\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
bts->mcs_lqual_ranges[0].high = atoi(argv[0]);
bts->mcs_lqual_ranges[1].low = atoi(argv[1]);
bts->mcs_lqual_ranges[1].high = atoi(argv[2]);
bts->mcs_lqual_ranges[2].low = atoi(argv[3]);
bts->mcs_lqual_ranges[2].high = atoi(argv[4]);
bts->mcs_lqual_ranges[3].low = atoi(argv[5]);
bts->mcs_lqual_ranges[3].high = atoi(argv[6]);
bts->mcs_lqual_ranges[4].low = atoi(argv[7]);
bts->mcs_lqual_ranges[4].high = atoi(argv[8]);
bts->mcs_lqual_ranges[5].low = atoi(argv[9]);
bts->mcs_lqual_ranges[5].high = atoi(argv[10]);
bts->mcs_lqual_ranges[6].low = atoi(argv[11]);
bts->mcs_lqual_ranges[6].high = atoi(argv[12]);
bts->mcs_lqual_ranges[7].low = atoi(argv[13]);
bts->mcs_lqual_ranges[7].high = atoi(argv[14]);
bts->mcs_lqual_ranges[8].low = atoi(argv[15]);
return CMD_SUCCESS;
}
DEFUN(cfg_pcu_sock,
cfg_pcu_sock_cmd,
"pcu-socket PATH",
"Configure the osmo-bts PCU socket file/path name\n"
"Path of the socket to connect to\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
if (bts->pcu_sock_path) {
/* FIXME: close the interface? */
talloc_free(bts->pcu_sock_path);
}
bts->pcu_sock_path = talloc_strdup(tall_pcu_ctx, argv[0]);
/* FIXME: re-open the interface? */
return CMD_SUCCESS;
}
DEFUN(show_tbf,
show_tbf_cmd,
"show tbf all",
SHOW_STR "information about TBFs\n" "All TBFs\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
return pcu_vty_show_tbf_all(vty, bts);
}
DEFUN(show_ms_all,
show_ms_all_cmd,
"show ms all",
SHOW_STR "information about MSs\n" "All TBFs\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
return pcu_vty_show_ms_all(vty, bts);
}
DEFUN(show_ms_tlli,
show_ms_tlli_cmd,
"show ms tlli TLLI",
SHOW_STR "information about MSs\n" "Select MS by TLLI\n" "TLLI as hex\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
char *endp = NULL;
unsigned long long tlli = strtoll(argv[0], &endp, 16);
if ((endp != NULL && *endp != 0) || tlli > 0xffffffffULL) {
vty_out(vty, "Invalid TLLI.%s", VTY_NEWLINE);
return CMD_WARNING;
}
return pcu_vty_show_ms_by_tlli(vty, bts, (uint32_t)tlli);
}
DEFUN(show_ms_imsi,
show_ms_imsi_cmd,
"show ms imsi IMSI",
SHOW_STR "information about MSs\n" "Select MS by IMSI\n" "IMSI\n")
{
struct gprs_rlcmac_bts *bts = bts_main_data();
return pcu_vty_show_ms_by_imsi(vty, bts, argv[0]);
}
static const char pcu_copyright[] =
"Copyright (C) 2012 by Ivan Kluchnikov <kluchnikovi@gmail.com> and \r\n"
" Andreas Eversberg <jolly@eversberg.eu>\r\n"
"License GNU GPL version 2 or later\r\n"
"This is free software: you are free to change and redistribute it.\r\n"
"There is NO WARRANTY, to the extent permitted by law.\r\n";
struct vty_app_info pcu_vty_info = {
.name = "Osmo-PCU",
.version = PACKAGE_VERSION,
.copyright = pcu_copyright,
.go_parent_cb = pcu_vty_go_parent,
.is_config_node = pcu_vty_is_config_node,
};
int pcu_vty_init(const struct log_info *cat)
{
// install_element_ve(&show_pcu_cmd);
cfg_pcu_gsmtap_categ_cmd.string = vty_cmd_string_from_valstr(tall_pcu_ctx, pcu_gsmtap_categ_names,
"gsmtap-category (",
"|",")", VTY_DO_LOWER);
cfg_pcu_gsmtap_categ_cmd.doc = vty_cmd_string_from_valstr(tall_pcu_ctx, pcu_gsmtap_categ_help,
"GSMTAP Category\n",
"\n", "", 0);
cfg_pcu_no_gsmtap_categ_cmd.string = vty_cmd_string_from_valstr(tall_pcu_ctx, pcu_gsmtap_categ_names,
"no gsmtap-category (",
"|",")", VTY_DO_LOWER);
cfg_pcu_no_gsmtap_categ_cmd.doc = vty_cmd_string_from_valstr(tall_pcu_ctx, pcu_gsmtap_categ_help,
NO_STR "GSMTAP Category\n",
"\n", "", 0);
logging_vty_add_cmds(cat);
osmo_stats_vty_add_cmds(cat);
install_node(&pcu_node, config_write_pcu);
install_element(CONFIG_NODE, &cfg_pcu_cmd);
vty_install_default(PCU_NODE);
install_element(PCU_NODE, &cfg_pcu_egprs_cmd);
install_element(PCU_NODE, &cfg_pcu_no_egprs_cmd);
install_element(PCU_NODE, &cfg_pcu_no_two_phase_cmd);
install_element(PCU_NODE, &cfg_pcu_cs_cmd);
install_element(PCU_NODE, &cfg_pcu_no_cs_cmd);
install_element(PCU_NODE, &cfg_pcu_cs_max_cmd);
install_element(PCU_NODE, &cfg_pcu_no_cs_max_cmd);
install_element(PCU_NODE, &cfg_pcu_cs_err_limits_cmd);
install_element(PCU_NODE, &cfg_pcu_no_cs_err_limits_cmd);
install_element(PCU_NODE, &cfg_pcu_cs_downgrade_thrsh_cmd);
install_element(PCU_NODE, &cfg_pcu_no_cs_downgrade_thrsh_cmd);
install_element(PCU_NODE, &cfg_pcu_cs_lqual_ranges_cmd);
install_element(PCU_NODE, &cfg_pcu_mcs_lqual_ranges_cmd);
install_element(PCU_NODE, &cfg_pcu_mcs_cmd);
install_element(PCU_NODE, &cfg_pcu_dl_arq_cmd);
install_element(PCU_NODE, &cfg_pcu_no_mcs_cmd);
install_element(PCU_NODE, &cfg_pcu_mcs_max_cmd);
install_element(PCU_NODE, &cfg_pcu_no_mcs_max_cmd);
install_element(PCU_NODE, &cfg_pcu_window_size_cmd);
install_element(PCU_NODE, &cfg_pcu_queue_lifetime_cmd);
install_element(PCU_NODE, &cfg_pcu_queue_lifetime_inf_cmd);
install_element(PCU_NODE, &cfg_pcu_no_queue_lifetime_cmd);
install_element(PCU_NODE, &cfg_pcu_queue_hysteresis_cmd);
install_element(PCU_NODE, &cfg_pcu_no_queue_hysteresis_cmd);
install_element(PCU_NODE, &cfg_pcu_queue_codel_cmd);
install_element(PCU_NODE, &cfg_pcu_queue_codel_interval_cmd);
install_element(PCU_NODE, &cfg_pcu_no_queue_codel_cmd);
install_element(PCU_NODE, &cfg_pcu_queue_idle_ack_delay_cmd);
install_element(PCU_NODE, &cfg_pcu_no_queue_idle_ack_delay_cmd);
install_element(PCU_NODE, &cfg_pcu_alloc_cmd);
install_element(PCU_NODE, &cfg_pcu_two_phase_cmd);
install_element(PCU_NODE, &cfg_pcu_fc_interval_cmd);
install_element(PCU_NODE, &cfg_pcu_fc_bucket_time_cmd);
install_element(PCU_NODE, &cfg_pcu_no_fc_bucket_time_cmd);
install_element(PCU_NODE, &cfg_pcu_fc_bvc_bucket_size_cmd);
install_element(PCU_NODE, &cfg_pcu_no_fc_bvc_bucket_size_cmd);
install_element(PCU_NODE, &cfg_pcu_fc_bvc_leak_rate_cmd);
install_element(PCU_NODE, &cfg_pcu_no_fc_bvc_leak_rate_cmd);
install_element(PCU_NODE, &cfg_pcu_fc_ms_bucket_size_cmd);
install_element(PCU_NODE, &cfg_pcu_no_fc_ms_bucket_size_cmd);
install_element(PCU_NODE, &cfg_pcu_fc_ms_leak_rate_cmd);
install_element(PCU_NODE, &cfg_pcu_no_fc_ms_leak_rate_cmd);
install_element(PCU_NODE, &cfg_pcu_alpha_cmd);
install_element(PCU_NODE, &cfg_pcu_gamma_cmd);
install_element(PCU_NODE, &cfg_pcu_dl_tbf_idle_time_cmd);
install_element(PCU_NODE, &cfg_pcu_no_dl_tbf_idle_time_cmd);
install_element(PCU_NODE, &cfg_pcu_ms_idle_time_cmd);
install_element(PCU_NODE, &cfg_pcu_no_ms_idle_time_cmd);
install_element(PCU_NODE, &cfg_pcu_gsmtap_categ_cmd);
install_element(PCU_NODE, &cfg_pcu_no_gsmtap_categ_cmd);
install_element(PCU_NODE, &cfg_pcu_sock_cmd);
install_element_ve(&show_bts_stats_cmd);
install_element_ve(&show_tbf_cmd);
install_element_ve(&show_ms_all_cmd);
install_element_ve(&show_ms_tlli_cmd);
install_element_ve(&show_ms_imsi_cmd);
return 0;
}
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