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/******************************************************************************
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    OpenAirInterface
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    Copyright(c) 1999 - 2014 Eurecom
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    OpenAirInterface 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.
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    OpenAirInterface 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.
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    You should have received a copy of the GNU General Public License
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    along with OpenAirInterface.The full GNU General Public License is
   included in this distribution in the file called "COPYING". If not,
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   see <http://www.gnu.org/licenses/>.
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  Contact Information
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  OpenAirInterface Admin: openair_admin@eurecom.fr
  OpenAirInterface Tech : openair_tech@eurecom.fr
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  OpenAirInterface Dev  : openair4g-devel@lists.eurecom.fr
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  Address      : Eurecom, Campus SophiaTech, 450 Route des Chappes, CS 50193 - 06904 Biot Sophia Antipolis cedex, FRANCE
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 *******************************************************************************/
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/*! \file PHY/LTE_TRANSPORT/proto.h
 * \brief Function prototypes for PHY physical/transport channel processing and generation V8.6 2009-03
 * \author R. Knopp, F. Kaltenberger
 * \date 2011
 * \version 0.1
 * \company Eurecom
 * \email: knopp@eurecom.fr
 * \note
 * \warning
 */
#ifndef __LTE_TRANSPORT_PROTO__H__
#define __LTE_TRANSPORT_PROTO__H__
#include "PHY/defs.h"
#include <math.h>

// Functions below implement 36-211 and 36-212

/** @addtogroup _PHY_TRANSPORT_
 * @{
 */

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/** \fn free_eNB_dlsch(LTE_eNB_DLSCH_t *dlsch,unsigned char N_RB_DL)
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    \brief This function frees memory allocated for a particular DLSCH at eNB
    @param dlsch Pointer to DLSCH to be removed
*/
void free_eNB_dlsch(LTE_eNB_DLSCH_t *dlsch);

void clean_eNb_dlsch(LTE_eNB_DLSCH_t *dlsch, uint8_t abstraction_flag);

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/** \fn new_eNB_dlsch(uint8_t Kmimo,uint8_t Mdlharq,uint32_t Nsoft,uint8_t abstraction_flag, LTE_DL_FRAME_PARMS* frame_parms)
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    \brief This function allocates structures for a particular DLSCH at eNB
    @returns Pointer to DLSCH to be removed
    @param Kmimo Kmimo factor from 36-212/36-213
    @param Mdlharq Maximum number of HARQ rounds (36-212/36-213)
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    @param Nsoft Soft-LLR buffer size from UE-Category
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    @params N_RB_DL total number of resource blocks (determine the operating BW)
    @param abstraction_flag Flag to indicate abstracted interface
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    @param frame_parms Pointer to frame descriptor structure
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*/
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LTE_eNB_DLSCH_t *new_eNB_dlsch(uint8_t Kmimo,uint8_t Mdlharq,uint32_t Nsoft,uint8_t N_RB_DL, uint8_t abstraction_flag, LTE_DL_FRAME_PARMS* frame_parms);
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/** \fn free_ue_dlsch(LTE_UE_DLSCH_t *dlsch)
    \brief This function frees memory allocated for a particular DLSCH at UE
    @param dlsch Pointer to DLSCH to be removed
*/
void free_ue_dlsch(LTE_UE_DLSCH_t *dlsch);

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/** \fn new_ue_dlsch(uint8_t Kmimo,uint8_t Mdlharq,uint32_t Nsoft,uint8_t abstraction_flag)
    \brief This function allocates structures for a particular DLSCH at eNB
    @returns Pointer to DLSCH to be removed
    @param Kmimo Kmimo factor from 36-212/36-213
    @param Mdlharq Maximum number of HARQ rounds (36-212/36-213)
    @param Nsoft Soft-LLR buffer size from UE-Category
    @params N_RB_DL total number of resource blocks (determine the operating BW)
    @param abstraction_flag Flag to indicate abstracted interface
*/
LTE_UE_DLSCH_t *new_ue_dlsch(uint8_t Kmimo,uint8_t Mdlharq,uint32_t Nsoft,uint8_t max_turbo_iterations,uint8_t N_RB_DL, uint8_t abstraction_flag);
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void clean_eNb_ulsch(LTE_eNB_ULSCH_t *ulsch, uint8_t abstraction_flag);

void free_ue_ulsch(LTE_UE_ULSCH_t *ulsch);

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LTE_eNB_ULSCH_t *new_eNB_ulsch(uint8_t Mdlharq,uint8_t max_turbo_iterations,uint8_t N_RB_UL, uint8_t abstraction_flag);
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LTE_UE_ULSCH_t *new_ue_ulsch(uint8_t Mdlharq, unsigned char N_RB_UL, uint8_t abstraction_flag);

/** \fn dlsch_encoding(uint8_t *input_buffer,
    LTE_DL_FRAME_PARMS *frame_parms,
    uint8_t num_pdcch_symbols,
    LTE_eNB_DLSCH_t *dlsch,
    int frame,
    uint8_t subframe)
    \brief This function performs a subset of the bit-coding functions for LTE as described in 36-212, Release 8.Support is limited to turbo-coded channels (DLSCH/ULSCH). The implemented functions are:
    - CRC computation and addition
    - Code block segmentation and sub-block CRC addition
    - Channel coding (Turbo coding)
    - Rate matching (sub-block interleaving, bit collection, selection and transmission
    - Code block concatenation
    @param input_buffer Pointer to input buffer for sub-frame
    @param frame_parms Pointer to frame descriptor structure
    @param num_pdcch_symbols Number of PDCCH symbols in this subframe
    @param dlsch Pointer to dlsch to be encoded
    @param frame Frame number
    @param subframe Subframe number
    @param rm_stats Time statistics for rate-matching
    @param te_stats Time statistics for turbo-encoding
    @param i_stats Time statistics for interleaving
    @returns status
*/
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int32_t dlsch_encoding(uint8_t *a,
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                       LTE_DL_FRAME_PARMS *frame_parms,
                       uint8_t num_pdcch_symbols,
                       LTE_eNB_DLSCH_t *dlsch,
                       int frame,
                       uint8_t subframe,
                       time_stats_t *rm_stats,
                       time_stats_t *te_stats,
                       time_stats_t *i_stats);
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void dlsch_encoding_emul(PHY_VARS_eNB *phy_vars_eNB,
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                         uint8_t *DLSCH_pdu,
                         LTE_eNB_DLSCH_t *dlsch);
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// Functions below implement 36-211

/** \fn allocate_REs_in_RB(mod_sym_t **txdataF,
    uint32_t *jj,
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    uint32_t *jj2,
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    uint16_t re_offset,
    uint32_t symbol_offset,
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    LTE_DL_eNB_HARQ_t *dlsch0_harq,
    LTE_DL_eNB_HARQ_t *dlsch1_harq,
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    uint8_t pilots,
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    int16_t amp,
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    int16_t *qam_table_s,
    uint32_t *re_allocated,
    uint8_t skip_dc,
    uint8_t skip_half,
    uint8_t use2ndpilots,
    LTE_DL_FRAME_PARMS *frame_parms);

    \brief Fills RB with data
    \param txdataF pointer to output data (frequency domain signal)
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    \param jj index to output (from CW 1)
    \param jj index to output (from CW 2)
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    \param re_offset index of the first RE of the RB
    \param symbol_offset index to the OFDM symbol
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    \param dlsch0_harq Pointer to Transport block 0 HARQ structure
    \param dlsch0_harq Pointer to Transport block 1 HARQ structure
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    \param pilots =1 if symbol_offset is an OFDM symbol that contains pilots, 0 otherwise
    \param amp Amplitude for symbols
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    \param qam_table_s0 pointer to scaled QAM table for Transport Block 0 (by rho_a or rho_b)
    \param qam_table_s1 pointer to scaled QAM table for Transport Block 1 (by rho_a or rho_b)
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    \param re_allocated pointer to allocation counter
    \param skip_dc offset for positive RBs
    \param skip_half indicate that first or second half of RB must be skipped for PBCH/PSS/SSS
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    \param ue_spec_rs UE specific RS indicator 
    \param nb_antennas_tx_phy Physical antenna elements which can be different with antenna port number, especially in beamforming case
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    \param use2ndpilots Set to use the pilots from antenna port 1 for PDSCH
    \param frame_parms Frame parameter descriptor
*/

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int32_t allocate_REs_in_RB(PHY_VARS_eNB* phy_vars_eNB,
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                           mod_sym_t **txdataF,
                           uint32_t *jj,
                           uint32_t *jj2,
                           uint16_t re_offset,
                           uint32_t symbol_offset,
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                           LTE_eNB_DLSCH_t *dlsch0,
                           LTE_eNB_DLSCH_t *dlsch1,
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                           uint8_t pilots,
                           int16_t amp,
                           uint8_t precoder_index,
                           int16_t *qam_table_s0,
                           int16_t *qam_table_s1,
                           uint32_t *re_allocated,
                           uint8_t skip_dc,
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                           uint8_t skip_half,
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                           uint8_t lprime,
		           uint8_t mprime,
		           uint8_t Ns);
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/** \fn int32_t dlsch_modulation(mod_sym_t **txdataF,
    int16_t amp,
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    uint32_t sub_frame_offset,
    LTE_DL_FRAME_PARMS *frame_parms,
    uint8_t num_pdcch_symbols,
    LTE_eNB_DLSCH_t *dlsch);

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    \brief This function is the top-level routine for generation of the sub-frame signal (frequency-domain) for DLSCH.
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    @param txdataF Table of pointers for frequency-domain TX signals
    @param amp Amplitude of signal
    @param sub_frame_offset Offset of this subframe in units of subframes (usually 0)
    @param frame_parms Pointer to frame descriptor
    @param num_pdcch_symbols Number of PDCCH symbols in this subframe
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    @param dlsch0 Pointer to Transport Block 0 DLSCH descriptor for this allocation
    @param dlsch1 Pointer to Transport Block 0 DLSCH descriptor for this allocation
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*/
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int32_t dlsch_modulation(PHY_VARS_eNB* phy_vars_eNB,
                         mod_sym_t **txdataF,
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                         int16_t amp,
                         uint32_t sub_frame_offset,
                         uint8_t num_pdcch_symbols,
                         LTE_eNB_DLSCH_t *dlsch0,
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                         LTE_eNB_DLSCH_t *dlsch1);
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/*
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  \brief This function is the top-level routine for generation of the sub-frame signal (frequency-domain) for MCH.
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  @param txdataF Table of pointers for frequency-domain TX signals
  @param amp Amplitude of signal
  @param subframe_offset Offset of this subframe in units of subframes (usually 0)
  @param frame_parms Pointer to frame descriptor
  @param dlsch Pointer to DLSCH descriptor for this allocation
*/
int mch_modulation(mod_sym_t **txdataF,
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                   int16_t amp,
                   uint32_t subframe_offset,
                   LTE_DL_FRAME_PARMS *frame_parms,
                   LTE_eNB_DLSCH_t *dlsch);
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/** \brief Top-level generation function for eNB TX of MBSFN
    @param phy_vars_eNB Pointer to eNB variables
    @param subframe Subframe for PMCH
    @param a Pointer to transport block
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    @param abstraction_flag
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*/
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void generate_mch(PHY_VARS_eNB *phy_vars_eNB,int subframe,uint8_t *a,int abstraction_flag);
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/** \brief This function generates the frequency-domain pilots (cell-specific downlink reference signals)
    @param phy_vars_eNB Pointer to eNB variables
    @param mcs MCS for MBSFN
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    @param ndi new data indicator
    @param rdvix
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    @param abstraction_flag
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*/
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void fill_eNB_dlsch_MCH(PHY_VARS_eNB *phy_vars_eNB,int mcs,int ndi,int rvidx,int abstraction_flag);
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/** \brief This function generates the frequency-domain pilots (cell-specific downlink reference signals)
    @param phy_vars_ue Pointer to UE variables
    @param mcs MCS for MBSFN
    @param eNB_id index of eNB in ue variables
*/
void fill_UE_dlsch_MCH(PHY_VARS_UE *phy_vars_ue,int mcs,int ndi,int rvidx,int eNB_id);

/** \brief Receiver processing for MBSFN, symbols can be done separately for time/CPU-scheduling purposes
    @param phy_vars_ue Pointer to UE variables
    @param eNB_id index of eNB in ue variables
    @param subframe Subframe index of PMCH
    @param symbol Symbol index on which to act
*/
int rx_pmch(PHY_VARS_UE *phy_vars_ue,
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            unsigned char eNB_id,
            uint8_t subframe,
            unsigned char symbol);
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/** \brief Dump OCTAVE/MATLAB files for PMCH debugging
    @param phy_vars_ue Pointer to UE variables
    @param eNB_id index of eNB in ue variables
    @param coded_bits_per_codeword G from 36.211
    @param subframe Index of subframe
    @returns 0 on success
*/
void dump_mch(PHY_VARS_UE *phy_vars_ue,uint8_t eNB_id,uint16_t coded_bits_per_codeword,int subframe);


/** \brief This function generates the frequency-domain pilots (cell-specific downlink reference signals)
    for N subframes.
    @param phy_vars_eNB Pointer to eNB variables
    @param txdataF Table of pointers for frequency-domain TX signals
    @param amp Amplitude of signal
    @param N Number of sub-frames to generate
*/
void generate_pilots(PHY_VARS_eNB *phy_vars_eNB,
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                     mod_sym_t **txdataF,
                     int16_t amp,
                     uint16_t N);
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/**
   \brief This function generates the frequency-domain pilots (cell-specific downlink reference signals) for one slot only
   @param phy_vars_eNB Pointer to eNB variables
   @param txdataF Table of pointers for frequency-domain TX signals
   @param amp Amplitude of signal
   @param slot index (0..19)
   @param first_pilot_only (0 no)
*/
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int32_t generate_pilots_slot(PHY_VARS_eNB *phy_vars_eNB,
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                             mod_sym_t **txdataF,
                             int16_t amp,
                             uint16_t slot,
                             int first_pilot_only);

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int32_t generate_mbsfn_pilot(PHY_VARS_eNB *phy_vars_eNB,
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                             mod_sym_t **txdataF,
                             int16_t amp,
                             uint16_t subframe);
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void generate_ue_spec_pilots(PHY_VARS_eNB *phy_vars_eNB,
                             uint8_t UE_id,
                             mod_sym_t **txdataF,
                             int16_t amp,
                             uint16_t Ntti,
		             uint8_t beamforming_mode);

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int32_t generate_pss(mod_sym_t **txdataF,
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                     int16_t amp,
                     LTE_DL_FRAME_PARMS *frame_parms,
                     uint16_t l,
                     uint16_t Ns);
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int32_t generate_pss_emul(PHY_VARS_eNB *phy_vars_eNB,uint8_t sect_id);
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int32_t generate_sss(mod_sym_t **txdataF,
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                     short amp,
                     LTE_DL_FRAME_PARMS *frame_parms,
                     unsigned short symbol,
                     unsigned short slot_offset);
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int32_t generate_pbch(LTE_eNB_PBCH *eNB_pbch,
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                      mod_sym_t **txdataF,
                      int32_t amp,
                      LTE_DL_FRAME_PARMS *frame_parms,
                      uint8_t *pbch_pdu,
                      uint8_t frame_mod4);
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int32_t generate_pbch_emul(PHY_VARS_eNB *phy_vars_eNB,uint8_t *pbch_pdu);
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/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream QPSK/QPSK reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
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void qpsk_qpsk(int16_t *stream0_in,
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               int16_t *stream1_in,
               int16_t *stream0_out,
               int16_t *rho01,
               int32_t length);
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/** \brief This function perform LLR computation for dual-stream (QPSK/QPSK) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr128p pointer to pointer to symbol in dlsch_llr*/
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int32_t dlsch_qpsk_qpsk_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                            int32_t **rxdataF_comp,
                            int32_t **rxdataF_comp_i,
                            int32_t **rho_i,
                            int16_t *dlsch_llr,
                            uint8_t symbol,
                            uint8_t first_symbol_flag,
                            uint16_t nb_rb,
                            uint16_t pbch_pss_sss_adj,
                            int16_t **llr128p);
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/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream QPSK/16QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
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void qpsk_qam16(int16_t *stream0_in,
                int16_t *stream1_in,
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                short *ch_mag_i,
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                int16_t *stream0_out,
                int16_t *rho01,
                int32_t length);
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/** \brief This function perform LLR computation for dual-stream (QPSK/16QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr128p pointer to pointer to symbol in dlsch_llr*/
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int32_t dlsch_qpsk_16qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                             int32_t **rxdataF_comp,
                             int32_t **rxdataF_comp_i,
                             int **dl_ch_mag_i, //|h_1|^2*(2/sqrt{10})
                             int32_t **rho_i,
                             int16_t *dlsch_llr,
                             uint8_t symbol,
                             uint8_t first_symbol_flag,
                             uint16_t nb_rb,
                             uint16_t pbch_pss_sss_adj,
                             int16_t **llr128p);
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/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream QPSK/64QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
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void qpsk_qam64(int16_t *stream0_in,
                int16_t *stream1_in,
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                short *ch_mag_i,
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                int16_t *stream0_out,
                int16_t *rho01,
                int32_t length);
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/** \brief This function perform LLR computation for dual-stream (QPSK/64QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr128p pointer to pointer to symbol in dlsch_llr*/
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int32_t dlsch_qpsk_64qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                             int32_t **rxdataF_comp,
                             int32_t **rxdataF_comp_i,
                             int **dl_ch_mag_i, //|h_1|^2*(2/sqrt{10})
                             int32_t **rho_i,
                             int16_t *dlsch_llr,
                             uint8_t symbol,
                             uint8_t first_symbol_flag,
                             uint16_t nb_rb,
                             uint16_t pbch_pss_sss_adj,
                             int16_t **llr128p);
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/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream 16QAM/QPSK reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
void qam16_qpsk(short *stream0_in,
                short *stream1_in,
                short *ch_mag,
                short *stream0_out,
                short *rho01,
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/** \brief This function perform LLR computation for dual-stream (16QAM/QPSK) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr16p pointer to pointer to symbol in dlsch_llr*/
int dlsch_16qam_qpsk_llr(LTE_DL_FRAME_PARMS *frame_parms,
                         int **rxdataF_comp,
                         int **rxdataF_comp_i,
                         int **dl_ch_mag,   //|h_0|^2*(2/sqrt{10})
                         int **rho_i,
                         short *dlsch_llr,
                         unsigned char symbol,
                         unsigned char first_symbol_flag,
                         unsigned short nb_rb,
                         uint16_t pbch_pss_sss_adjust,
                         short **llr16p);

/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream 16QAM/16QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
void qam16_qam16(short *stream0_in,
                 short *stream1_in,
                 short *ch_mag,
                 short *ch_mag_i,
                 short *stream0_out,
                 short *rho01,
                 int length);

/** \brief This function perform LLR computation for dual-stream (16QAM/16QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr16p pointer to pointer to symbol in dlsch_llr*/
int dlsch_16qam_16qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
                          int **rxdataF_comp,
                          int **rxdataF_comp_i,
                          int **dl_ch_mag,   //|h_0|^2*(2/sqrt{10})
                          int **dl_ch_mag_i, //|h_1|^2*(2/sqrt{10})
                          int **rho_i,
                          short *dlsch_llr,
                          unsigned char symbol,
                          unsigned char first_symbol_flag,
                          unsigned short nb_rb,
                          uint16_t pbch_pss_sss_adjust,
                          short **llr16p);

/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream 16QAM/64QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
void qam16_qam64(short *stream0_in,
                 short *stream1_in,
                 short *ch_mag,
                 short *ch_mag_i,
                 short *stream0_out,
                 short *rho01,
                 int length);

/** \brief This function perform LLR computation for dual-stream (16QAM/64QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr16p pointer to pointer to symbol in dlsch_llr*/
int dlsch_16qam_64qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
                          int **rxdataF_comp,
                          int **rxdataF_comp_i,
                          int **dl_ch_mag,   //|h_0|^2*(2/sqrt{10})
                          int **dl_ch_mag_i, //|h_1|^2*(2/sqrt{10})
                          int **rho_i,
                          short *dlsch_llr,
                          unsigned char symbol,
                          unsigned char first_symbol_flag,
                          unsigned short nb_rb,
                          uint16_t pbch_pss_sss_adjust,
                          short **llr16p);

/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream 64QAM/64QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
void qam64_qpsk(short *stream0_in,
                short *stream1_in,
                short *ch_mag,
                short *stream0_out,
                short *rho01,
                int length);

/** \brief This function perform LLR computation for dual-stream (64QAM/64QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr16p pointer to pointer to symbol in dlsch_llr*/
int dlsch_64qam_qpsk_llr(LTE_DL_FRAME_PARMS *frame_parms,
                         int **rxdataF_comp,
                         int **rxdataF_comp_i,
                         int **dl_ch_mag,
                         int **rho_i,
                         short *dlsch_llr,
                         unsigned char symbol,
                         unsigned char first_symbol_flag,
                         unsigned short nb_rb,
                         uint16_t pbch_pss_sss_adjust,
                         short **llr16p);

/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream 64QAM/16QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
void qam64_qam16(short *stream0_in,
                 short *stream1_in,
                 short *ch_mag,
                 short *ch_mag_i,
                 short *stream0_out,
                 short *rho01,
                 int length);

/** \brief This function perform LLR computation for dual-stream (64QAM/16QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr16p pointer to pointer to symbol in dlsch_llr*/
int dlsch_64qam_16qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
                          int **rxdataF_comp,
                          int **rxdataF_comp_i,
                          int **dl_ch_mag,
                          int **dl_ch_mag_i,
                          int **rho_i,
                          short *dlsch_llr,
                          unsigned char symbol,
                          unsigned char first_symbol_flag,
                          unsigned short nb_rb,
                          uint16_t pbch_pss_sss_adjust,
                          short **llr16p);

/** \brief This function computes the LLRs for ML (max-logsum approximation) dual-stream 64QAM/64QAM reception.
    @param stream0_in Input from channel compensated (MR combined) stream 0
    @param stream1_in Input from channel compensated (MR combined) stream 1
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param stream0_out Output from LLR unit for stream0
    @param rho01 Cross-correlation between channels (MR combined)
    @param length in complex channel outputs*/
void qam64_qam64(short *stream0_in,
                 short *stream1_in,
                 short *ch_mag,
                 short *ch_mag_i,
                 short *stream0_out,
                 short *rho01,
                 int length);

/** \brief This function perform LLR computation for dual-stream (64QAM/64QAM) transmission.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param ch_mag   Input from scaled channel magnitude square of h0'*g0
    @param ch_mag_i Input from scaled channel magnitude square of h0'*g1
    @param rho_i Correlation between channel of signal and inteference
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
    @param first_symbol_flag flag to indicate this is the first symbol of the dlsch
    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr16p pointer to pointer to symbol in dlsch_llr*/
int dlsch_64qam_64qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
                          int **rxdataF_comp,
                          int **rxdataF_comp_i,
                          int **dl_ch_mag,
                          int **dl_ch_mag_i,
                          int **rho_i,
                          short *dlsch_llr,
                          unsigned char symbol,
                          unsigned char first_symbol_flag,
                          unsigned short nb_rb,
                          uint16_t pbch_pss_sss_adjust,
                          short **llr16p);


/** \brief This function generates log-likelihood ratios (decoder input) for single-stream QPSK received waveforms.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param dlsch_llr llr output
    @param symbol OFDM symbol index in sub-frame
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    @param first_symbol_flag
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    @param nb_rb number of RBs for this allocation
    @param pbch_pss_sss_adj Number of channel bits taken by PBCH/PSS/SSS
    @param llr128p pointer to pointer to symbol in dlsch_llr
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    @param beamforming_mode beamforming mode
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*/
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int32_t dlsch_qpsk_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                       int32_t **rxdataF_comp,
                       int16_t *dlsch_llr,
                       uint8_t symbol,
                       uint8_t first_symbol_flag,
                       uint16_t nb_rb,
                       uint16_t pbch_pss_sss_adj,
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                       int16_t **llr128p,
                       uint8_t beamforming_mode);
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/**
   \brief This function generates log-likelihood ratios (decoder input) for single-stream 16QAM received waveforms
   @param frame_parms Frame descriptor structure
   @param rxdataF_comp Compensated channel output
   @param dlsch_llr llr output
   @param dl_ch_mag Squared-magnitude of channel in each resource element position corresponding to allocation and weighted for mid-point in 16QAM constellation
   @param symbol OFDM symbol index in sub-frame
   @param first_symbol_flag
   @param nb_rb number of RBs for this allocation
   @param pbch_pss_sss_adjust  Adjustment factor in RE for PBCH/PSS/SSS allocations
   @param llr128p pointer to pointer to symbol in dlsch_llr
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   @param beamforming_mode beamforming mode
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*/

void dlsch_16qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                     int32_t **rxdataF_comp,
                     int16_t *dlsch_llr,
                     int32_t **dl_ch_mag,
                     uint8_t symbol,
                     uint8_t first_symbol_flag,
                     uint16_t nb_rb,
                     uint16_t pbch_pss_sss_adjust,
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                     int16_t **llr128p,
                     uint8_t beamforming_mode);
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/**
   \brief This function generates log-likelihood ratios (decoder input) for single-stream 16QAM received waveforms
   @param frame_parms Frame descriptor structure
   @param rxdataF_comp Compensated channel output
   @param dlsch_llr llr output
   @param dl_ch_mag Squared-magnitude of channel in each resource element position corresponding to allocation, weighted by first mid-point of 64-QAM constellation
   @param dl_ch_magb Squared-magnitude of channel in each resource element position corresponding to allocation, weighted by second mid-point of 64-QAM constellation
   @param symbol OFDM symbol index in sub-frame
   @param first_symbol_flag
   @param nb_rb number of RBs for this allocation
   @param pbch_pss_sss_adjust PBCH/PSS/SSS RE adjustment (in REs)
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   @param beamforming_mode beamforming mode
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*/
void dlsch_64qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                     int32_t **rxdataF_comp,
                     int16_t *dlsch_llr,
                     int32_t **dl_ch_mag,
                     int32_t **dl_ch_magb,
                     uint8_t symbol,
                     uint8_t first_symbol_flag,
                     uint16_t nb_rb,
                     uint16_t pbch_pss_sss_adjust,
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                     int16_t **llr_save,
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                     uint8_t beamforming_mode);
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/** \fn dlsch_siso(LTE_DL_FRAME_PARMS *frame_parms,
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    int32_t **rxdataF_comp,
    int32_t **rxdataF_comp_i,
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    uint8_t l,
    uint16_t nb_rb)
    \brief This function does the first stage of llr computation for SISO, by just extracting the pilots, PBCH and primary/secondary synchronization sequences.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param l symbol in sub-frame
    @param nb_rb Number of RBs in this allocation
*/

void dlsch_siso(LTE_DL_FRAME_PARMS *frame_parms,
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                int32_t **rxdataF_comp,
                int32_t **rxdataF_comp_i,
                uint8_t l,
                uint16_t nb_rb);
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/** \fn dlsch_alamouti(LTE_DL_FRAME_PARMS *frame_parms,
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    int32_t **rxdataF_comp,
    int32_t **dl_ch_mag,
    int32_t **dl_ch_magb,
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    uint8_t symbol,
    uint16_t nb_rb)
    \brief This function does Alamouti combining on RX and prepares LLR inputs by skipping pilots, PBCH and primary/secondary synchronization signals.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param dl_ch_mag First squared-magnitude of channel (16QAM and 64QAM) for LLR computation.  Alamouti combining should be performed on this as well. Result is stored in first antenna position
    @param dl_ch_magb Second squared-magnitude of channel (64QAM only) for LLR computation.  Alamouti combining should be performed on this as well. Result is stored in first antenna position
    @param symbol Symbol in sub-frame
    @param nb_rb Number of RBs in this allocation
*/
void dlsch_alamouti(LTE_DL_FRAME_PARMS *frame_parms,
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                    int32_t **rxdataF_comp,
                    int32_t **dl_ch_mag,
                    int32_t **dl_ch_magb,
                    uint8_t symbol,
                    uint16_t nb_rb);
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/** \fn dlsch_antcyc(LTE_DL_FRAME_PARMS *frame_parms,
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    int32_t **rxdataF_comp,
    int32_t **dl_ch_mag,
    int32_t **dl_ch_magb,
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    uint8_t symbol,
    uint16_t nb_rb)
    \brief This function does antenna selection (based on antenna cycling pattern) on RX and prepares LLR inputs by skipping pilots, PBCH and primary/secondary synchronization signals.  Note that this is not LTE, it is just included for comparison purposes.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param dl_ch_mag First squared-magnitude of channel (16QAM and 64QAM) for LLR computation.  Alamouti combining should be performed on this as well. Result is stored in first antenna position
    @param dl_ch_magb Second squared-magnitude of channel (64QAM only) for LLR computation.  Alamouti combining should be performed on this as well. Result is stored in first antenna position
    @param symbol Symbol in sub-frame
    @param nb_rb Number of RBs in this allocation
*/
void dlsch_antcyc(LTE_DL_FRAME_PARMS *frame_parms,
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                  int32_t **rxdataF_comp,
                  int32_t **dl_ch_mag,
                  int32_t **dl_ch_magb,
                  uint8_t symbol,
                  uint16_t nb_rb);
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/** \fn dlsch_detection_mrc(LTE_DL_FRAME_PARMS *frame_parms,
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    int32_t **rxdataF_comp,
    int32_t **rxdataF_comp_i,
    int32_t **rho,
    int32_t **rho_i,
    int32_t **dl_ch_mag,
    int32_t **dl_ch_magb,
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    uint8_t symbol,
    uint16_t nb_rb,
    uint8_t dual_stream_UE)

    \brief This function does maximal-ratio combining for dual-antenna receivers.
    @param frame_parms Frame descriptor structure
    @param rxdataF_comp Compensated channel output
    @param rxdataF_comp_i Compensated channel output for interference
    @param rho Cross correlation between spatial channels
    @param rho_i Cross correlation between signal and inteference channels
    @param dl_ch_mag First squared-magnitude of channel (16QAM and 64QAM) for LLR computation.  Alamouti combining should be performed on this as well. Result is stored in first antenna position
    @param dl_ch_magb Second squared-magnitude of channel (64QAM only) for LLR computation.  Alamouti combining should be performed on this as well. Result is stored in first antenna position
    @param symbol Symbol in sub-frame
    @param nb_rb Number of RBs in this allocation
    @param dual_stream_UE Flag to indicate dual-stream detection
*/
void dlsch_detection_mrc(LTE_DL_FRAME_PARMS *frame_parms,
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                         int32_t **rxdataF_comp,
                         int32_t **rxdataF_comp_i,
                         int32_t **rho,
                         int32_t **rho_i,
                         int32_t **dl_ch_mag,
                         int32_t **dl_ch_magb,
                         int32_t **dl_ch_mag_i,
                         int32_t **dl_ch_magb_i,
                         uint8_t symbol,
                         uint16_t nb_rb,
                         uint8_t dual_stream_UE);
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/** \fn dlsch_extract_rbs_single(int32_t **rxdataF,
    int32_t **dl_ch_estimates,
    int32_t **rxdataF_ext,
    int32_t **dl_ch_estimates_ext,
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    uint16_t pmi,
    uint8_t *pmi_ext,
    uint32_t *rb_alloc,
    uint8_t symbol,
    uint8_t subframe,
    LTE_DL_FRAME_PARMS *frame_parms)
    \brief This function extracts the received resource blocks, both channel estimates and data symbols,
    for the current allocation and for single antenna eNB transmission.
    @param rxdataF Raw FFT output of received signal
    @param dl_ch_estimates Channel estimates of current slot
    @param rxdataF_ext FFT output for RBs in this allocation
    @param dl_ch_estimates_ext Channel estimates for RBs in this allocation
    @param pmi subband Precoding matrix indicator
    @param pmi_ext Extracted PMI for chosen RBs
    @param rb_alloc RB allocation vector
    @param symbol Symbol to extract
    @param subframe Subframe number
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    @param vrb_type Flag to indicate distributed VRB type
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    @param high_speed_flag
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    @param frame_parms Pointer to frame descriptor
*/
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uint16_t dlsch_extract_rbs_single(int32_t **rxdataF,
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                                  int32_t **dl_ch_estimates,
                                  int32_t **rxdataF_ext,
                                  int32_t **dl_ch_estimates_ext,
                                  uint16_t pmi,
                                  uint8_t *pmi_ext,
                                  uint32_t *rb_alloc,
                                  uint8_t symbol,
                                  uint8_t subframe,
                                  uint32_t high_speed_flag,
                                  LTE_DL_FRAME_PARMS *frame_parms);
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/** \fn dlsch_extract_rbs_dual(int32_t **rxdataF,
    int32_t **dl_ch_estimates,
    int32_t **rxdataF_ext,
    int32_t **dl_ch_estimates_ext,
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    uint16_t pmi,
    uint8_t *pmi_ext,
    uint32_t *rb_alloc,
    uint8_t symbol,
    LTE_DL_FRAME_PARMS *frame_parms)
    \brief This function extracts the received resource blocks, both channel estimates and data symbols,
    for the current allocation and for dual antenna eNB transmission.
    @param rxdataF Raw FFT output of received signal
    @param dl_ch_estimates Channel estimates of current slot
    @param rxdataF_ext FFT output for RBs in this allocation
    @param dl_ch_estimates_ext Channel estimates for RBs in this allocation
    @param pmi subband Precoding matrix indicator
    @param pmi_ext Extracted PMI for chosen RBs
    @param rb_alloc RB allocation vector
    @param symbol Symbol to extract
    @param subframe Subframe index
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    @param high_speed_flag
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    @param frame_parms Pointer to frame descriptor
*/
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uint16_t dlsch_extract_rbs_dual(int32_t **rxdataF,
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                                int32_t **dl_ch_estimates,
                                int32_t **rxdataF_ext,
                                int32_t **dl_ch_estimates_ext,
                                uint16_t pmi,
                                uint8_t *pmi_ext,
                                uint32_t *rb_alloc,
                                uint8_t symbol,
                                uint8_t subframe,
                                uint32_t high_speed_flag,
                                LTE_DL_FRAME_PARMS *frame_parms);
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/** \fn dlsch_extract_rbs_TM7(int32_t **rxdataF,
    int32_t **dl_bf_ch_estimates,
    int32_t **rxdataF_ext,
    int32_t **dl_bf_ch_estimates_ext,
    uint32_t *rb_alloc,
    uint8_t symbol,
    uint8_t subframe,
    uint32_t high_speed_flag,
    LTE_DL_FRAME_PARMS *frame_parms)
    \brief This function extracts the received resource blocks, both channel estimates and data symbols,
    for the current allocation and for single antenna eNB transmission.
    @param rxdataF Raw FFT output of received signal
    @param dl_bf_ch_estimates Beamforming channel estimates of current slot
    @param rxdataF_ext FFT output for RBs in this allocation
    @param dl_bf_ch_estimates_ext Beamforming channel estimates for RBs in this allocation
    @param rb_alloc RB allocation vector
    @param symbol Symbol to extract
    @param subframe Subframe number
    @param high_speed_flag
    @param frame_parms Pointer to frame descriptor
*/
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uint16_t dlsch_extract_rbs_TM7(int32_t **rxdataF,
                               int32_t **dl_bf_ch_estimates,
                               int32_t **rxdataF_ext,
                               int32_t **dl_bf_ch_estimates_ext,
                               uint32_t *rb_alloc,
                               uint8_t symbol,
                               uint8_t subframe,
                               uint32_t high_speed_flag,
                               LTE_DL_FRAME_PARMS *frame_parms);

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/** \brief This function performs channel compensation (matched filtering) on the received RBs for this allocation.  In addition, it computes the squared-magnitude of the channel with weightings for 16QAM/64QAM detection as well as dual-stream detection (cross-correlation)
    @param rxdataF_ext Frequency-domain received signal in RBs to be demodulated
    @param dl_ch_estimates_ext Frequency-domain channel estimates in RBs to be demodulated
    @param dl_ch_mag First Channel magnitudes (16QAM/64QAM)
    @param dl_ch_magb Second weighted Channel magnitudes (64QAM)
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    @param rxdataF_comp Compensated received waveform
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    @param rho Cross-correlation between two spatial channels on each RX antenna
    @param frame_parms Pointer to frame descriptor
    @param symbol Symbol on which to operate
    @param first_symbol_flag set to 1 on first DLSCH symbol
    @param mod_order Modulation order of allocation
    @param nb_rb Number of RBs in allocation
    @param output_shift Rescaling for compensated output (should be energy-normalizing)
    @param phy_measurements Pointer to UE PHY measurements
*/
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void dlsch_channel_compensation(int32_t **rxdataF_ext,
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                                int32_t **dl_ch_estimates_ext,
                                int32_t **dl_ch_mag,
                                int32_t **dl_ch_magb,
                                int32_t **rxdataF_comp,
                                int32_t **rho,
                                LTE_DL_FRAME_PARMS *frame_parms,
                                uint8_t symbol,
                                uint8_t first_symbol_flag,
                                uint8_t mod_order,
                                uint16_t nb_rb,
                                uint8_t output_shift,
                                PHY_MEASUREMENTS *phy_measurements);
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void dlsch_dual_stream_correlation(LTE_DL_FRAME_PARMS *frame_parms,
                                   unsigned char symbol,
                                   unsigned short nb_rb,
                                   int **dl_ch_estimates_ext,
                                   int **dl_ch_estimates_ext_i,
                                   int **dl_ch_rho_ext,
                                   unsigned char output_shift);

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void dlsch_channel_compensation_TM56(int **rxdataF_ext,
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