/** * Copyright 2013-2021 Software Radio Systems Limited * * This file is part of srsLTE. * * srsLTE 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. * * srsLTE 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. * * A copy of the GNU Affero General Public License can be found in * the LICENSE file in the top-level directory of this distribution * and at http://www.gnu.org/licenses/. * */ #ifndef SRSLTE_CHANNEL_MAPPING_H #define SRSLTE_CHANNEL_MAPPING_H #include #include #include #include namespace srslte { /** * This class manages the mapping between logical and physical channels. * A physical channel in this class is a carrier index in the radio class, which * has multiple antenna ports all tuned to the same frequency. * * Every group of channels tuned associated with a carrier go through the same band-pass filter. This * class then manages the allocation of frequencies to these group of channels. * * The same object is reused for the reception and transmission. * * When the UE wants to tune a logical channel to a new frequency it requests this class * to provide an available channel that supports this frequency. At that point, * that channel can not be used anymore until a call to release(). * */ class channel_mapping { public: /** Configures a band. A band is defined by an upper and lower frequency boundaries. * If the upper and lower frequencies are not configured (default is zero), it means * that they support any frequency */ class band_cfg { public: void set(float low_freq_, float high_freq_) { low_freq = low_freq_; high_freq = high_freq_; } bool contains(float freq) const { if (low_freq == 0 && high_freq == 0) { return true; } else { return freq >= low_freq && freq <= high_freq; } } float get_low() const { return low_freq; } float get_high() const { return high_freq; } private: float low_freq = 0; float high_freq = 0; }; /** Each channel is defined by the band it supports and the physical carrier index in the radio */ typedef struct { band_cfg band; uint32_t carrier_idx; } channel_cfg_t; typedef struct { uint32_t carrier_idx; // Physical channel index of all channels uint32_t device_idx; // RF Device index uint32_t channel_idx; // Channel index in the RF Device } device_mapping_t; /** * Sets the number of the RF device channels and antennas per carrier * @param nof_channels_x_dev_ Number of RF channels per device * @param nof_antennas_ number of antennas per carrrier */ void set_config(const uint32_t& nof_channels_x_dev_, const uint32_t& nof_antennas_); /** * Sets the channel configuration. If no channels are configured no physical channels can be allocated * @param channels_ */ void set_channels(const std::list& channels_) { available_channels = channels_; } /** * Finds an unused physical channel that supports the provided frequency and assigns it to logical channel * logical_ch * @param logical_ch logical channel index * @param freq Frequency (in Hz) that we want to receive/transmitt * @return true if a physical channel supporting this frequency was found or false otherwise */ bool allocate_freq(const uint32_t& logical_ch, const float& freq); /** * Releases the allocation of a logical channel allowing to be used in the next call to allocate_freq * @param logical_ch logical channel index * @return false if logical_ch is not allocated, true otherwise */ bool release_freq(const uint32_t& logical_ch); /** * Obtains the physical information configured in set_channels() in the radio to which the logical channel logical_ch * has been mapped to * @param logical_ch logical channel index * @return A device mapping structure carrying the mapping information * * @see channel_cfg_t */ device_mapping_t get_device_mapping(const uint32_t& logical_ch, const uint32_t& antenna_idx = 0) const; /** * Checks if the channel has been allocated using allocate_freq() * * @param logical_ch logical channel index * @return true if the channel is allocated, false otherwise */ bool is_allocated(const uint32_t& logical_ch) const; /** * Represents the channel mapping into a string * @return a string representing the current channel mapping */ std::string to_string() const; private: std::list available_channels = {}; std::map allocated_channels = {}; mutable std::mutex mutex = {}; uint32_t nof_antennas = 1; uint32_t nof_channels_x_dev = 1; }; } // namespace srslte #endif // SRSLTE_CHANNEL_MAPPING_H