/* (C) 2018 by sysmocom s.f.m.c. GmbH * * Author: Stefan Sperling * * All Rights Reserved * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as published by * the Free Software Foundation; either version 3 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 Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . * */ #pragma once #include #include #include #include #define ACC_MGR_QUANTUM_DEFAULT 20 /* 20 seconds */ /* Manage rotating subset of allowed Access Class as per configuration */ struct acc_mgr { struct gsm_bts *bts; /*!< backpointer to BTS using this ACC manager */ /* Administrative Maximum Number of ACC 0-9 to be allowed at the same time. Configurable through VTY cmd "access-control-class-roundrobin", defaults to all allowed (10) */ uint8_t len_allowed_adm; /* Further limiting the number of ACC to use. It may be lower due to ramping, based for instance on channel or system load. */ uint8_t len_allowed_ramp; /* Time until next subset is generated */ uint32_t rotation_time_sec; struct osmo_timer_list rotate_timer; /* Bitmask containing subset of allowed ACC 0-9 on current rotation iteration */ uint16_t allowed_subset_mask; /* Number of bits (ACC) set in allowed_subset_mask: 0->min(len_allowed_ramp, len_allowed_adm) */ uint8_t allowed_subset_mask_count; /* Number of ACC 0-9 allowed as per adminsitrative (permanent) config. */ uint8_t allowed_permanent_count; }; void acc_mgr_init(struct acc_mgr *acc_mgr, struct gsm_bts *bts); uint8_t acc_mgr_get_len_allowed_adm(struct acc_mgr *acc_mgr); uint8_t acc_mgr_get_len_allowed_ramp(struct acc_mgr *acc_mgr); void acc_mgr_set_len_allowed_adm(struct acc_mgr *acc_mgr, uint8_t len_allowed_adm); void acc_mgr_set_len_allowed_ramp(struct acc_mgr *acc_mgr, uint8_t len_allowed_ramp); void acc_mgr_set_rotation_time(struct acc_mgr *acc_mgr, uint32_t rotation_time_sec); void acc_mgr_perm_subset_changed(struct acc_mgr *acc_mgr, struct gsm48_rach_control *rach_control); void acc_mgr_apply_acc(struct acc_mgr *acc_mgr, struct gsm48_rach_control *rach_control); /*! * Access control class (ACC) ramping is used to slowly make the cell available to * an increasing number of MS. This avoids overload at startup time in cases where * a lot of MS would discover the new cell and try to connect to it all at once. */ #define ACC_RAMP_STEP_SIZE_MIN 1 /* allow at most 1 new ACC per ramp step */ #define ACC_RAMP_STEP_SIZE_DEFAULT ACC_RAMP_STEP_SIZE_MIN #define ACC_RAMP_STEP_SIZE_MAX 10 /* allow all ACC in one step (effectively disables ramping) */ #define ACC_RAMP_STEP_INTERVAL_MIN 5 /* 5 seconds */ #define ACC_RAMP_STEP_INTERVAL_MAX 600 /* 10 minutes */ #define ACC_RAMP_CHAN_LOAD_THRESHOLD_LOW 71 #define ACC_RAMP_CHAN_LOAD_THRESHOLD_UP 89 /*! * Data structure used to manage ACC ramping. Please avoid setting or reading fields * in this structure directly. Use the accessor functions below instead. */ struct acc_ramp { struct gsm_bts *bts; /*!< backpointer to BTS using this ACC ramp */ bool acc_ramping_enabled; /*!< whether ACC ramping is enabled */ /*! * This controls the maximum number of ACCs to allow per ramping step (1 - 10). * The compile-time default value is ACC_RAMP_STEP_SIZE_DEFAULT. * This value can be changed by VTY configuration. * A value of ACC_RAMP_STEP_SIZE_MAX effectively disables ramping. */ unsigned int step_size; /*! * Ramping step interval in seconds. * This value depends on the current BTS channel load average, unless * it has been overridden by VTY configuration. */ unsigned int step_interval_sec; struct osmo_timer_list step_timer; /*! * Channel Load Upper/Lower Thresholds: * They control how ramping subset size of allowed ACCs changes in * relation to current channel load (%, 0-100): Under the lower * threshold, subset size may be increased; above the upper threshold, * subset size may be decreased. */ unsigned int chan_load_lower_threshold; unsigned int chan_load_upper_threshold; }; /*! * Enable or disable ACC ramping. * When enabled, ramping begins once acc_ramp_start() is called. * When disabled, an ACC ramping process in progress will continue * unless acc_ramp_abort() is called as well. * \param[in] acc_ramp Pointer to acc_ramp structure. */ static inline void acc_ramp_set_enabled(struct acc_ramp *acc_ramp, bool enable) { acc_ramp->acc_ramping_enabled = enable; } /*! * Return true if ACC ramping is currently enabled, else false. * \param[in] acc_ramp Pointer to acc_ramp structure. */ static inline bool acc_ramp_is_enabled(struct acc_ramp *acc_ramp) { return acc_ramp->acc_ramping_enabled; } /*! * Return the current ACC ramp step size. * \param[in] acc_ramp Pointer to acc_ramp structure. */ static inline unsigned int acc_ramp_get_step_size(struct acc_ramp *acc_ramp) { return acc_ramp->step_size; } /*! * Return the current ACC ramp step interval (in seconds) * \param[in] acc_ramp Pointer to acc_ramp structure. */ static inline unsigned int acc_ramp_get_step_interval(struct acc_ramp *acc_ramp) { return acc_ramp->step_interval_sec; } /*! * Return the current ACC ramp step interval (in seconds) * \param[in] acc_ramp Pointer to acc_ramp structure. */ static inline unsigned int acc_ramp_is_running(struct acc_ramp *acc_ramp) { return acc_ramp->step_interval_sec; } void acc_ramp_global_init(void); void acc_ramp_init(struct acc_ramp *acc_ramp, struct gsm_bts *bts); int acc_ramp_set_step_size(struct acc_ramp *acc_ramp, unsigned int step_size); int acc_ramp_set_step_interval(struct acc_ramp *acc_ramp, unsigned int step_interval); int acc_ramp_set_chan_load_thresholds(struct acc_ramp *acc_ramp, unsigned int low_threshold, unsigned int up_threshold); void acc_ramp_trigger(struct acc_ramp *acc_ramp); void acc_ramp_abort(struct acc_ramp *acc_ramp);