/*! * \file viterbi_decoder.h * \brief Interface of a Viterbi decoder class based on the Iterative Solutions * Coded Modulation Library by Matthew C. Valenti * \author Daniel Fehr 2013. daniel.co(at)bluewin.ch * * ------------------------------------------------------------------------- * * Copyright (C) 2010-2015 (see AUTHORS file for a list of contributors) * * GNSS-SDR is a software defined Global Navigation * Satellite Systems receiver * * This file is part of GNSS-SDR. * * GNSS-SDR 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. * * GNSS-SDR 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 GNSS-SDR. If not, see . * * ------------------------------------------------------------------------- */ #ifndef GNSS_SDR_VITERBI_DECODER_H_ #define GNSS_SDR_VITERBI_DECODER_H_ #include #include /*! * \brief Class that implements a Viterbi decoder */ class Viterbi_Decoder { public: Viterbi_Decoder(const int g_encoder[], const int KK, const int nn); ~Viterbi_Decoder(); void reset(); /*! * \brief Uses the Viterbi algorithm to perform hard-decision decoding of a convolutional code. * * \param[in] input_c[] The received signal in LLR-form. For BPSK, must be in form r = 2*a*y/(sigma^2). * \param[in] LL The number of data bits to be decoded (does not include the mm zero-tail-bits) * * \return output_u_int[] Hard decisions on the data bits (without the mm zero-tail-bits) */ float decode_block(const double input_c[], int* output_u_int, const int LL); float decode_continuous(const double sym[], const int traceback_depth, int output_u_int[], const int nbits_requested, int &nbits_decoded); private: class Prev { public: Prev(int states, int t); Prev(const Prev& prev); Prev& operator=(const Prev& other); ~Prev(); int get_anchestor_state_of_current_state(int current_state); int get_bit_of_current_state(int current_state); float get_metric_of_current_state(int current_state); int get_t(); void set_current_state_as_ancestor_of_next_state(int next_state, int current_state); void set_decoded_bit_for_next_state(int next_state, int bit); void set_survivor_branch_metric_of_next_state(int next_state, float metric); private: int t; int * state; int * bit; float * metric; int * refcount; }; // code properties int d_KK; int d_nn; // derived code properties int d_mm; int d_states; int d_number_symbols; // trellis definition int* d_out0; int* d_state0; int* d_out1; int* d_state1; // trellis state float *d_pm_t; std::deque d_trellis_paths; float *d_metric_c; /* Set of all possible branch metrics */ float *d_rec_array; /* Received values for one trellis section */ bool d_trellis_state_is_initialised; // measures float d_indicator_metric; // operations on the trellis (change decoder state) void init_trellis_state(); int do_acs(const double sym[], int nbits); int do_traceback(size_t traceback_length); int do_tb_and_decode(int traceback_length, int requested_decoding_length, int state, int bits[], float& indicator_metric); // branch metric function float gamma(float rec_array[], int symbol, int nn); // trellis generation void nsc_transit(int output_p[], int trans_p[], int input, const int g[], int KK, int nn); int nsc_enc_bit(int state_out_p[], int input, int state_in, const int g[], int KK, int nn); int parity_counter(int symbol, int length); }; #endif /* GNSS_SDR_VITERBI_DECODER_H_ */