dlsch_llr_computation.c 425 KB
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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
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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
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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/dlsch_llr_computation.c
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 * \brief Top-level routines for LLR computation of the PDSCH physical channel from 36-211, V8.6 2009-03
 * \author R. Knopp, F. Kaltenberger,A. Bhamri, S. Aubert, S. Wagner
 * \date 2011
 * \version 0.1
 * \company Eurecom
 * \email: knopp@eurecom.fr,florian.kaltenberger@eurecom.fr,ankit.bhamri@eurecom.fr,sebastien.aubert@eurecom.fr, sebastian.wagner@eurecom.fr
 * \note
 * \warning
 */
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#include "PHY/defs.h"
#include "PHY/extern.h"
#include "defs.h"
#include "extern.h"
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#include "PHY/sse_intrin.h"
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int16_t zero[8] __attribute__ ((aligned(16))) = {0,0,0,0,0,0,0,0};
int16_t ones[8] __attribute__ ((aligned(16))) = {0xffff,0xffff,0xffff,0xffff,0xffff,0xffff,0xffff,0xffff};
#if defined(__x86_64__) || defined(__i386__)
__m128i rho_rpi __attribute__ ((aligned(16)));
__m128i rho_rmi __attribute__ ((aligned(16)));
__m128i rho_rpi_1_1 __attribute__ ((aligned(16)));
__m128i rho_rpi_1_3 __attribute__ ((aligned(16)));
__m128i rho_rpi_1_5 __attribute__ ((aligned(16)));
__m128i rho_rpi_1_7 __attribute__ ((aligned(16)));
__m128i rho_rpi_3_1 __attribute__ ((aligned(16)));
__m128i rho_rpi_3_3 __attribute__ ((aligned(16)));
__m128i rho_rpi_3_5 __attribute__ ((aligned(16)));
__m128i rho_rpi_3_7 __attribute__ ((aligned(16)));
__m128i rho_rpi_5_1 __attribute__ ((aligned(16)));
__m128i rho_rpi_5_3 __attribute__ ((aligned(16)));
__m128i rho_rpi_5_5 __attribute__ ((aligned(16)));
__m128i rho_rpi_5_7 __attribute__ ((aligned(16)));
__m128i rho_rpi_7_1 __attribute__ ((aligned(16)));
__m128i rho_rpi_7_3 __attribute__ ((aligned(16)));
__m128i rho_rpi_7_5 __attribute__ ((aligned(16)));
__m128i rho_rpi_7_7 __attribute__ ((aligned(16)));
__m128i rho_rmi_1_1 __attribute__ ((aligned(16)));
__m128i rho_rmi_1_3 __attribute__ ((aligned(16)));
__m128i rho_rmi_1_5 __attribute__ ((aligned(16)));
__m128i rho_rmi_1_7 __attribute__ ((aligned(16)));
__m128i rho_rmi_3_1 __attribute__ ((aligned(16)));
__m128i rho_rmi_3_3 __attribute__ ((aligned(16)));
__m128i rho_rmi_3_5 __attribute__ ((aligned(16)));
__m128i rho_rmi_3_7 __attribute__ ((aligned(16)));
__m128i rho_rmi_5_1 __attribute__ ((aligned(16)));
__m128i rho_rmi_5_3 __attribute__ ((aligned(16)));
__m128i rho_rmi_5_5 __attribute__ ((aligned(16)));
__m128i rho_rmi_5_7 __attribute__ ((aligned(16)));
__m128i rho_rmi_7_1 __attribute__ ((aligned(16)));
__m128i rho_rmi_7_3 __attribute__ ((aligned(16)));
__m128i rho_rmi_7_5 __attribute__ ((aligned(16)));
__m128i rho_rmi_7_7 __attribute__ ((aligned(16)));

__m128i psi_r_m7_m7 __attribute__ ((aligned(16)));
__m128i psi_r_m7_m5 __attribute__ ((aligned(16)));
__m128i psi_r_m7_m3 __attribute__ ((aligned(16)));
__m128i psi_r_m7_m1 __attribute__ ((aligned(16)));
__m128i psi_r_m7_p1 __attribute__ ((aligned(16)));
__m128i psi_r_m7_p3 __attribute__ ((aligned(16)));
__m128i psi_r_m7_p5 __attribute__ ((aligned(16)));
__m128i psi_r_m7_p7 __attribute__ ((aligned(16)));
__m128i psi_r_m5_m7 __attribute__ ((aligned(16)));
__m128i psi_r_m5_m5 __attribute__ ((aligned(16)));
__m128i psi_r_m5_m3 __attribute__ ((aligned(16)));
__m128i psi_r_m5_m1 __attribute__ ((aligned(16)));
__m128i psi_r_m5_p1 __attribute__ ((aligned(16)));
__m128i psi_r_m5_p3 __attribute__ ((aligned(16)));
__m128i psi_r_m5_p5 __attribute__ ((aligned(16)));
__m128i psi_r_m5_p7 __attribute__ ((aligned(16)));
__m128i psi_r_m3_m7 __attribute__ ((aligned(16)));
__m128i psi_r_m3_m5 __attribute__ ((aligned(16)));
__m128i psi_r_m3_m3 __attribute__ ((aligned(16)));
__m128i psi_r_m3_m1 __attribute__ ((aligned(16)));
__m128i psi_r_m3_p1 __attribute__ ((aligned(16)));
__m128i psi_r_m3_p3 __attribute__ ((aligned(16)));
__m128i psi_r_m3_p5 __attribute__ ((aligned(16)));
__m128i psi_r_m3_p7 __attribute__ ((aligned(16)));
__m128i psi_r_m1_m7 __attribute__ ((aligned(16)));
__m128i psi_r_m1_m5 __attribute__ ((aligned(16)));
__m128i psi_r_m1_m3 __attribute__ ((aligned(16)));
__m128i psi_r_m1_m1 __attribute__ ((aligned(16)));
__m128i psi_r_m1_p1 __attribute__ ((aligned(16)));
__m128i psi_r_m1_p3 __attribute__ ((aligned(16)));
__m128i psi_r_m1_p5 __attribute__ ((aligned(16)));
__m128i psi_r_m1_p7 __attribute__ ((aligned(16)));
__m128i psi_r_p1_m7 __attribute__ ((aligned(16)));
__m128i psi_r_p1_m5 __attribute__ ((aligned(16)));
__m128i psi_r_p1_m3 __attribute__ ((aligned(16)));
__m128i psi_r_p1_m1 __attribute__ ((aligned(16)));
__m128i psi_r_p1_p1 __attribute__ ((aligned(16)));
__m128i psi_r_p1_p3 __attribute__ ((aligned(16)));
__m128i psi_r_p1_p5 __attribute__ ((aligned(16)));
__m128i psi_r_p1_p7 __attribute__ ((aligned(16)));
__m128i psi_r_p3_m7 __attribute__ ((aligned(16)));
__m128i psi_r_p3_m5 __attribute__ ((aligned(16)));
__m128i psi_r_p3_m3 __attribute__ ((aligned(16)));
__m128i psi_r_p3_m1 __attribute__ ((aligned(16)));
__m128i psi_r_p3_p1 __attribute__ ((aligned(16)));
__m128i psi_r_p3_p3 __attribute__ ((aligned(16)));
__m128i psi_r_p3_p5 __attribute__ ((aligned(16)));
__m128i psi_r_p3_p7 __attribute__ ((aligned(16)));
__m128i psi_r_p5_m7 __attribute__ ((aligned(16)));
__m128i psi_r_p5_m5 __attribute__ ((aligned(16)));
__m128i psi_r_p5_m3 __attribute__ ((aligned(16)));
__m128i psi_r_p5_m1 __attribute__ ((aligned(16)));
__m128i psi_r_p5_p1 __attribute__ ((aligned(16)));
__m128i psi_r_p5_p3 __attribute__ ((aligned(16)));
__m128i psi_r_p5_p5 __attribute__ ((aligned(16)));
__m128i psi_r_p5_p7 __attribute__ ((aligned(16)));
__m128i psi_r_p7_m7 __attribute__ ((aligned(16)));
__m128i psi_r_p7_m5 __attribute__ ((aligned(16)));
__m128i psi_r_p7_m3 __attribute__ ((aligned(16)));
__m128i psi_r_p7_m1 __attribute__ ((aligned(16)));
__m128i psi_r_p7_p1 __attribute__ ((aligned(16)));
__m128i psi_r_p7_p3 __attribute__ ((aligned(16)));
__m128i psi_r_p7_p5 __attribute__ ((aligned(16)));
__m128i psi_r_p7_p7 __attribute__ ((aligned(16)));

__m128i psi_i_m7_m7 __attribute__ ((aligned(16)));
__m128i psi_i_m7_m5 __attribute__ ((aligned(16)));
__m128i psi_i_m7_m3 __attribute__ ((aligned(16)));
__m128i psi_i_m7_m1 __attribute__ ((aligned(16)));
__m128i psi_i_m7_p1 __attribute__ ((aligned(16)));
__m128i psi_i_m7_p3 __attribute__ ((aligned(16)));
__m128i psi_i_m7_p5 __attribute__ ((aligned(16)));
__m128i psi_i_m7_p7 __attribute__ ((aligned(16)));
__m128i psi_i_m5_m7 __attribute__ ((aligned(16)));
__m128i psi_i_m5_m5 __attribute__ ((aligned(16)));
__m128i psi_i_m5_m3 __attribute__ ((aligned(16)));
__m128i psi_i_m5_m1 __attribute__ ((aligned(16)));
__m128i psi_i_m5_p1 __attribute__ ((aligned(16)));
__m128i psi_i_m5_p3 __attribute__ ((aligned(16)));
__m128i psi_i_m5_p5 __attribute__ ((aligned(16)));
__m128i psi_i_m5_p7 __attribute__ ((aligned(16)));
__m128i psi_i_m3_m7 __attribute__ ((aligned(16)));
__m128i psi_i_m3_m5 __attribute__ ((aligned(16)));
__m128i psi_i_m3_m3 __attribute__ ((aligned(16)));
__m128i psi_i_m3_m1 __attribute__ ((aligned(16)));
__m128i psi_i_m3_p1 __attribute__ ((aligned(16)));
__m128i psi_i_m3_p3 __attribute__ ((aligned(16)));
__m128i psi_i_m3_p5 __attribute__ ((aligned(16)));
__m128i psi_i_m3_p7 __attribute__ ((aligned(16)));
__m128i psi_i_m1_m7 __attribute__ ((aligned(16)));
__m128i psi_i_m1_m5 __attribute__ ((aligned(16)));
__m128i psi_i_m1_m3 __attribute__ ((aligned(16)));
__m128i psi_i_m1_m1 __attribute__ ((aligned(16)));
__m128i psi_i_m1_p1 __attribute__ ((aligned(16)));
__m128i psi_i_m1_p3 __attribute__ ((aligned(16)));
__m128i psi_i_m1_p5 __attribute__ ((aligned(16)));
__m128i psi_i_m1_p7 __attribute__ ((aligned(16)));
__m128i psi_i_p1_m7 __attribute__ ((aligned(16)));
__m128i psi_i_p1_m5 __attribute__ ((aligned(16)));
__m128i psi_i_p1_m3 __attribute__ ((aligned(16)));
__m128i psi_i_p1_m1 __attribute__ ((aligned(16)));
__m128i psi_i_p1_p1 __attribute__ ((aligned(16)));
__m128i psi_i_p1_p3 __attribute__ ((aligned(16)));
__m128i psi_i_p1_p5 __attribute__ ((aligned(16)));
__m128i psi_i_p1_p7 __attribute__ ((aligned(16)));
__m128i psi_i_p3_m7 __attribute__ ((aligned(16)));
__m128i psi_i_p3_m5 __attribute__ ((aligned(16)));
__m128i psi_i_p3_m3 __attribute__ ((aligned(16)));
__m128i psi_i_p3_m1 __attribute__ ((aligned(16)));
__m128i psi_i_p3_p1 __attribute__ ((aligned(16)));
__m128i psi_i_p3_p3 __attribute__ ((aligned(16)));
__m128i psi_i_p3_p5 __attribute__ ((aligned(16)));
__m128i psi_i_p3_p7 __attribute__ ((aligned(16)));
__m128i psi_i_p5_m7 __attribute__ ((aligned(16)));
__m128i psi_i_p5_m5 __attribute__ ((aligned(16)));
__m128i psi_i_p5_m3 __attribute__ ((aligned(16)));
__m128i psi_i_p5_m1 __attribute__ ((aligned(16)));
__m128i psi_i_p5_p1 __attribute__ ((aligned(16)));
__m128i psi_i_p5_p3 __attribute__ ((aligned(16)));
__m128i psi_i_p5_p5 __attribute__ ((aligned(16)));
__m128i psi_i_p5_p7 __attribute__ ((aligned(16)));
__m128i psi_i_p7_m7 __attribute__ ((aligned(16)));
__m128i psi_i_p7_m5 __attribute__ ((aligned(16)));
__m128i psi_i_p7_m3 __attribute__ ((aligned(16)));
__m128i psi_i_p7_m1 __attribute__ ((aligned(16)));
__m128i psi_i_p7_p1 __attribute__ ((aligned(16)));
__m128i psi_i_p7_p3 __attribute__ ((aligned(16)));
__m128i psi_i_p7_p5 __attribute__ ((aligned(16)));
__m128i psi_i_p7_p7 __attribute__ ((aligned(16)));

__m128i a_r_m7_m7 __attribute__ ((aligned(16)));
__m128i a_r_m7_m5 __attribute__ ((aligned(16)));
__m128i a_r_m7_m3 __attribute__ ((aligned(16)));
__m128i a_r_m7_m1 __attribute__ ((aligned(16)));
__m128i a_r_m7_p1 __attribute__ ((aligned(16)));
__m128i a_r_m7_p3 __attribute__ ((aligned(16)));
__m128i a_r_m7_p5 __attribute__ ((aligned(16)));
__m128i a_r_m7_p7 __attribute__ ((aligned(16)));
__m128i a_r_m5_m7 __attribute__ ((aligned(16)));
__m128i a_r_m5_m5 __attribute__ ((aligned(16)));
__m128i a_r_m5_m3 __attribute__ ((aligned(16)));
__m128i a_r_m5_m1 __attribute__ ((aligned(16)));
__m128i a_r_m5_p1 __attribute__ ((aligned(16)));
__m128i a_r_m5_p3 __attribute__ ((aligned(16)));
__m128i a_r_m5_p5 __attribute__ ((aligned(16)));
__m128i a_r_m5_p7 __attribute__ ((aligned(16)));
__m128i a_r_m3_m7 __attribute__ ((aligned(16)));
__m128i a_r_m3_m5 __attribute__ ((aligned(16)));
__m128i a_r_m3_m3 __attribute__ ((aligned(16)));
__m128i a_r_m3_m1 __attribute__ ((aligned(16)));
__m128i a_r_m3_p1 __attribute__ ((aligned(16)));
__m128i a_r_m3_p3 __attribute__ ((aligned(16)));
__m128i a_r_m3_p5 __attribute__ ((aligned(16)));
__m128i a_r_m3_p7 __attribute__ ((aligned(16)));
__m128i a_r_m1_m7 __attribute__ ((aligned(16)));
__m128i a_r_m1_m5 __attribute__ ((aligned(16)));
__m128i a_r_m1_m3 __attribute__ ((aligned(16)));
__m128i a_r_m1_m1 __attribute__ ((aligned(16)));
__m128i a_r_m1_p1 __attribute__ ((aligned(16)));
__m128i a_r_m1_p3 __attribute__ ((aligned(16)));
__m128i a_r_m1_p5 __attribute__ ((aligned(16)));
__m128i a_r_m1_p7 __attribute__ ((aligned(16)));
__m128i a_r_p1_m7 __attribute__ ((aligned(16)));
__m128i a_r_p1_m5 __attribute__ ((aligned(16)));
__m128i a_r_p1_m3 __attribute__ ((aligned(16)));
__m128i a_r_p1_m1 __attribute__ ((aligned(16)));
__m128i a_r_p1_p1 __attribute__ ((aligned(16)));
__m128i a_r_p1_p3 __attribute__ ((aligned(16)));
__m128i a_r_p1_p5 __attribute__ ((aligned(16)));
__m128i a_r_p1_p7 __attribute__ ((aligned(16)));
__m128i a_r_p3_m7 __attribute__ ((aligned(16)));
__m128i a_r_p3_m5 __attribute__ ((aligned(16)));
__m128i a_r_p3_m3 __attribute__ ((aligned(16)));
__m128i a_r_p3_m1 __attribute__ ((aligned(16)));
__m128i a_r_p3_p1 __attribute__ ((aligned(16)));
__m128i a_r_p3_p3 __attribute__ ((aligned(16)));
__m128i a_r_p3_p5 __attribute__ ((aligned(16)));
__m128i a_r_p3_p7 __attribute__ ((aligned(16)));
__m128i a_r_p5_m7 __attribute__ ((aligned(16)));
__m128i a_r_p5_m5 __attribute__ ((aligned(16)));
__m128i a_r_p5_m3 __attribute__ ((aligned(16)));
__m128i a_r_p5_m1 __attribute__ ((aligned(16)));
__m128i a_r_p5_p1 __attribute__ ((aligned(16)));
__m128i a_r_p5_p3 __attribute__ ((aligned(16)));
__m128i a_r_p5_p5 __attribute__ ((aligned(16)));
__m128i a_r_p5_p7 __attribute__ ((aligned(16)));
__m128i a_r_p7_m7 __attribute__ ((aligned(16)));
__m128i a_r_p7_m5 __attribute__ ((aligned(16)));
__m128i a_r_p7_m3 __attribute__ ((aligned(16)));
__m128i a_r_p7_m1 __attribute__ ((aligned(16)));
__m128i a_r_p7_p1 __attribute__ ((aligned(16)));
__m128i a_r_p7_p3 __attribute__ ((aligned(16)));
__m128i a_r_p7_p5 __attribute__ ((aligned(16)));
__m128i a_r_p7_p7 __attribute__ ((aligned(16)));

__m128i a_i_m7_m7 __attribute__ ((aligned(16)));
__m128i a_i_m7_m5 __attribute__ ((aligned(16)));
__m128i a_i_m7_m3 __attribute__ ((aligned(16)));
__m128i a_i_m7_m1 __attribute__ ((aligned(16)));
__m128i a_i_m7_p1 __attribute__ ((aligned(16)));
__m128i a_i_m7_p3 __attribute__ ((aligned(16)));
__m128i a_i_m7_p5 __attribute__ ((aligned(16)));
__m128i a_i_m7_p7 __attribute__ ((aligned(16)));
__m128i a_i_m5_m7 __attribute__ ((aligned(16)));
__m128i a_i_m5_m5 __attribute__ ((aligned(16)));
__m128i a_i_m5_m3 __attribute__ ((aligned(16)));
__m128i a_i_m5_m1 __attribute__ ((aligned(16)));
__m128i a_i_m5_p1 __attribute__ ((aligned(16)));
__m128i a_i_m5_p3 __attribute__ ((aligned(16)));
__m128i a_i_m5_p5 __attribute__ ((aligned(16)));
__m128i a_i_m5_p7 __attribute__ ((aligned(16)));
__m128i a_i_m3_m7 __attribute__ ((aligned(16)));
__m128i a_i_m3_m5 __attribute__ ((aligned(16)));
__m128i a_i_m3_m3 __attribute__ ((aligned(16)));
__m128i a_i_m3_m1 __attribute__ ((aligned(16)));
__m128i a_i_m3_p1 __attribute__ ((aligned(16)));
__m128i a_i_m3_p3 __attribute__ ((aligned(16)));
__m128i a_i_m3_p5 __attribute__ ((aligned(16)));
__m128i a_i_m3_p7 __attribute__ ((aligned(16)));
__m128i a_i_m1_m7 __attribute__ ((aligned(16)));
__m128i a_i_m1_m5 __attribute__ ((aligned(16)));
__m128i a_i_m1_m3 __attribute__ ((aligned(16)));
__m128i a_i_m1_m1 __attribute__ ((aligned(16)));
__m128i a_i_m1_p1 __attribute__ ((aligned(16)));
__m128i a_i_m1_p3 __attribute__ ((aligned(16)));
__m128i a_i_m1_p5 __attribute__ ((aligned(16)));
__m128i a_i_m1_p7 __attribute__ ((aligned(16)));
__m128i a_i_p1_m7 __attribute__ ((aligned(16)));
__m128i a_i_p1_m5 __attribute__ ((aligned(16)));
__m128i a_i_p1_m3 __attribute__ ((aligned(16)));
__m128i a_i_p1_m1 __attribute__ ((aligned(16)));
__m128i a_i_p1_p1 __attribute__ ((aligned(16)));
__m128i a_i_p1_p3 __attribute__ ((aligned(16)));
__m128i a_i_p1_p5 __attribute__ ((aligned(16)));
__m128i a_i_p1_p7 __attribute__ ((aligned(16)));
__m128i a_i_p3_m7 __attribute__ ((aligned(16)));
__m128i a_i_p3_m5 __attribute__ ((aligned(16)));
__m128i a_i_p3_m3 __attribute__ ((aligned(16)));
__m128i a_i_p3_m1 __attribute__ ((aligned(16)));
__m128i a_i_p3_p1 __attribute__ ((aligned(16)));
__m128i a_i_p3_p3 __attribute__ ((aligned(16)));
__m128i a_i_p3_p5 __attribute__ ((aligned(16)));
__m128i a_i_p3_p7 __attribute__ ((aligned(16)));
__m128i a_i_p5_m7 __attribute__ ((aligned(16)));
__m128i a_i_p5_m5 __attribute__ ((aligned(16)));
__m128i a_i_p5_m3 __attribute__ ((aligned(16)));
__m128i a_i_p5_m1 __attribute__ ((aligned(16)));
__m128i a_i_p5_p1 __attribute__ ((aligned(16)));
__m128i a_i_p5_p3 __attribute__ ((aligned(16)));
__m128i a_i_p5_p5 __attribute__ ((aligned(16)));
__m128i a_i_p5_p7 __attribute__ ((aligned(16)));
__m128i a_i_p7_m7 __attribute__ ((aligned(16)));
__m128i a_i_p7_m5 __attribute__ ((aligned(16)));
__m128i a_i_p7_m3 __attribute__ ((aligned(16)));
__m128i a_i_p7_m1 __attribute__ ((aligned(16)));
__m128i a_i_p7_p1 __attribute__ ((aligned(16)));
__m128i a_i_p7_p3 __attribute__ ((aligned(16)));
__m128i a_i_p7_p5 __attribute__ ((aligned(16)));
__m128i a_i_p7_p7 __attribute__ ((aligned(16)));

__m128i psi_a_m7_m7 __attribute__ ((aligned(16)));
__m128i psi_a_m7_m5 __attribute__ ((aligned(16)));
__m128i psi_a_m7_m3 __attribute__ ((aligned(16)));
__m128i psi_a_m7_m1 __attribute__ ((aligned(16)));
__m128i psi_a_m7_p1 __attribute__ ((aligned(16)));
__m128i psi_a_m7_p3 __attribute__ ((aligned(16)));
__m128i psi_a_m7_p5 __attribute__ ((aligned(16)));
__m128i psi_a_m7_p7 __attribute__ ((aligned(16)));
__m128i psi_a_m5_m7 __attribute__ ((aligned(16)));
__m128i psi_a_m5_m5 __attribute__ ((aligned(16)));
__m128i psi_a_m5_m3 __attribute__ ((aligned(16)));
__m128i psi_a_m5_m1 __attribute__ ((aligned(16)));
__m128i psi_a_m5_p1 __attribute__ ((aligned(16)));
__m128i psi_a_m5_p3 __attribute__ ((aligned(16)));
__m128i psi_a_m5_p5 __attribute__ ((aligned(16)));
__m128i psi_a_m5_p7 __attribute__ ((aligned(16)));
__m128i psi_a_m3_m7 __attribute__ ((aligned(16)));
__m128i psi_a_m3_m5 __attribute__ ((aligned(16)));
__m128i psi_a_m3_m3 __attribute__ ((aligned(16)));
__m128i psi_a_m3_m1 __attribute__ ((aligned(16)));
__m128i psi_a_m3_p1 __attribute__ ((aligned(16)));
__m128i psi_a_m3_p3 __attribute__ ((aligned(16)));
__m128i psi_a_m3_p5 __attribute__ ((aligned(16)));
__m128i psi_a_m3_p7 __attribute__ ((aligned(16)));
__m128i psi_a_m1_m7 __attribute__ ((aligned(16)));
__m128i psi_a_m1_m5 __attribute__ ((aligned(16)));
__m128i psi_a_m1_m3 __attribute__ ((aligned(16)));
__m128i psi_a_m1_m1 __attribute__ ((aligned(16)));
__m128i psi_a_m1_p1 __attribute__ ((aligned(16)));
__m128i psi_a_m1_p3 __attribute__ ((aligned(16)));
__m128i psi_a_m1_p5 __attribute__ ((aligned(16)));
__m128i psi_a_m1_p7 __attribute__ ((aligned(16)));
__m128i psi_a_p1_m7 __attribute__ ((aligned(16)));
__m128i psi_a_p1_m5 __attribute__ ((aligned(16)));
__m128i psi_a_p1_m3 __attribute__ ((aligned(16)));
__m128i psi_a_p1_m1 __attribute__ ((aligned(16)));
__m128i psi_a_p1_p1 __attribute__ ((aligned(16)));
__m128i psi_a_p1_p3 __attribute__ ((aligned(16)));
__m128i psi_a_p1_p5 __attribute__ ((aligned(16)));
__m128i psi_a_p1_p7 __attribute__ ((aligned(16)));
__m128i psi_a_p3_m7 __attribute__ ((aligned(16)));
__m128i psi_a_p3_m5 __attribute__ ((aligned(16)));
__m128i psi_a_p3_m3 __attribute__ ((aligned(16)));
__m128i psi_a_p3_m1 __attribute__ ((aligned(16)));
__m128i psi_a_p3_p1 __attribute__ ((aligned(16)));
__m128i psi_a_p3_p3 __attribute__ ((aligned(16)));
__m128i psi_a_p3_p5 __attribute__ ((aligned(16)));
__m128i psi_a_p3_p7 __attribute__ ((aligned(16)));
__m128i psi_a_p5_m7 __attribute__ ((aligned(16)));
__m128i psi_a_p5_m5 __attribute__ ((aligned(16)));
__m128i psi_a_p5_m3 __attribute__ ((aligned(16)));
__m128i psi_a_p5_m1 __attribute__ ((aligned(16)));
__m128i psi_a_p5_p1 __attribute__ ((aligned(16)));
__m128i psi_a_p5_p3 __attribute__ ((aligned(16)));
__m128i psi_a_p5_p5 __attribute__ ((aligned(16)));
__m128i psi_a_p5_p7 __attribute__ ((aligned(16)));
__m128i psi_a_p7_m7 __attribute__ ((aligned(16)));
__m128i psi_a_p7_m5 __attribute__ ((aligned(16)));
__m128i psi_a_p7_m3 __attribute__ ((aligned(16)));
__m128i psi_a_p7_m1 __attribute__ ((aligned(16)));
__m128i psi_a_p7_p1 __attribute__ ((aligned(16)));
__m128i psi_a_p7_p3 __attribute__ ((aligned(16)));
__m128i psi_a_p7_p5 __attribute__ ((aligned(16)));
__m128i psi_a_p7_p7 __attribute__ ((aligned(16)));

__m128i a_sq_m7_m7 __attribute__ ((aligned(16)));
__m128i a_sq_m7_m5 __attribute__ ((aligned(16)));
__m128i a_sq_m7_m3 __attribute__ ((aligned(16)));
__m128i a_sq_m7_m1 __attribute__ ((aligned(16)));
__m128i a_sq_m7_p1 __attribute__ ((aligned(16)));
__m128i a_sq_m7_p3 __attribute__ ((aligned(16)));
__m128i a_sq_m7_p5 __attribute__ ((aligned(16)));
__m128i a_sq_m7_p7 __attribute__ ((aligned(16)));
__m128i a_sq_m5_m7 __attribute__ ((aligned(16)));
__m128i a_sq_m5_m5 __attribute__ ((aligned(16)));
__m128i a_sq_m5_m3 __attribute__ ((aligned(16)));
__m128i a_sq_m5_m1 __attribute__ ((aligned(16)));
__m128i a_sq_m5_p1 __attribute__ ((aligned(16)));
__m128i a_sq_m5_p3 __attribute__ ((aligned(16)));
__m128i a_sq_m5_p5 __attribute__ ((aligned(16)));
__m128i a_sq_m5_p7 __attribute__ ((aligned(16)));
__m128i a_sq_m3_m7 __attribute__ ((aligned(16)));
__m128i a_sq_m3_m5 __attribute__ ((aligned(16)));
__m128i a_sq_m3_m3 __attribute__ ((aligned(16)));
__m128i a_sq_m3_m1 __attribute__ ((aligned(16)));
__m128i a_sq_m3_p1 __attribute__ ((aligned(16)));
__m128i a_sq_m3_p3 __attribute__ ((aligned(16)));
__m128i a_sq_m3_p5 __attribute__ ((aligned(16)));
__m128i a_sq_m3_p7 __attribute__ ((aligned(16)));
__m128i a_sq_m1_m7 __attribute__ ((aligned(16)));
__m128i a_sq_m1_m5 __attribute__ ((aligned(16)));
__m128i a_sq_m1_m3 __attribute__ ((aligned(16)));
__m128i a_sq_m1_m1 __attribute__ ((aligned(16)));
__m128i a_sq_m1_p1 __attribute__ ((aligned(16)));
__m128i a_sq_m1_p3 __attribute__ ((aligned(16)));
__m128i a_sq_m1_p5 __attribute__ ((aligned(16)));
__m128i a_sq_m1_p7 __attribute__ ((aligned(16)));
__m128i a_sq_p1_m7 __attribute__ ((aligned(16)));
__m128i a_sq_p1_m5 __attribute__ ((aligned(16)));
__m128i a_sq_p1_m3 __attribute__ ((aligned(16)));
__m128i a_sq_p1_m1 __attribute__ ((aligned(16)));
__m128i a_sq_p1_p1 __attribute__ ((aligned(16)));
__m128i a_sq_p1_p3 __attribute__ ((aligned(16)));
__m128i a_sq_p1_p5 __attribute__ ((aligned(16)));
__m128i a_sq_p1_p7 __attribute__ ((aligned(16)));
__m128i a_sq_p3_m7 __attribute__ ((aligned(16)));
__m128i a_sq_p3_m5 __attribute__ ((aligned(16)));
__m128i a_sq_p3_m3 __attribute__ ((aligned(16)));
__m128i a_sq_p3_m1 __attribute__ ((aligned(16)));
__m128i a_sq_p3_p1 __attribute__ ((aligned(16)));
__m128i a_sq_p3_p3 __attribute__ ((aligned(16)));
__m128i a_sq_p3_p5 __attribute__ ((aligned(16)));
__m128i a_sq_p3_p7 __attribute__ ((aligned(16)));
__m128i a_sq_p5_m7 __attribute__ ((aligned(16)));
__m128i a_sq_p5_m5 __attribute__ ((aligned(16)));
__m128i a_sq_p5_m3 __attribute__ ((aligned(16)));
__m128i a_sq_p5_m1 __attribute__ ((aligned(16)));
__m128i a_sq_p5_p1 __attribute__ ((aligned(16)));
__m128i a_sq_p5_p3 __attribute__ ((aligned(16)));
__m128i a_sq_p5_p5 __attribute__ ((aligned(16)));
__m128i a_sq_p5_p7 __attribute__ ((aligned(16)));
__m128i a_sq_p7_m7 __attribute__ ((aligned(16)));
__m128i a_sq_p7_m5 __attribute__ ((aligned(16)));
__m128i a_sq_p7_m3 __attribute__ ((aligned(16)));
__m128i a_sq_p7_m1 __attribute__ ((aligned(16)));
__m128i a_sq_p7_p1 __attribute__ ((aligned(16)));
__m128i a_sq_p7_p3 __attribute__ ((aligned(16)));
__m128i a_sq_p7_p5 __attribute__ ((aligned(16)));
__m128i a_sq_p7_p7 __attribute__ ((aligned(16)));

__m128i bit_met_m7_m7 __attribute__ ((aligned(16)));
__m128i bit_met_m7_m5 __attribute__ ((aligned(16)));
__m128i bit_met_m7_m3 __attribute__ ((aligned(16)));
__m128i bit_met_m7_m1 __attribute__ ((aligned(16)));
__m128i bit_met_m7_p1 __attribute__ ((aligned(16)));
__m128i bit_met_m7_p3 __attribute__ ((aligned(16)));
__m128i bit_met_m7_p5 __attribute__ ((aligned(16)));
__m128i bit_met_m7_p7 __attribute__ ((aligned(16)));
__m128i bit_met_m5_m7 __attribute__ ((aligned(16)));
__m128i bit_met_m5_m5 __attribute__ ((aligned(16)));
__m128i bit_met_m5_m3 __attribute__ ((aligned(16)));
__m128i bit_met_m5_m1 __attribute__ ((aligned(16)));
__m128i bit_met_m5_p1 __attribute__ ((aligned(16)));
__m128i bit_met_m5_p3 __attribute__ ((aligned(16)));
__m128i bit_met_m5_p5 __attribute__ ((aligned(16)));
__m128i bit_met_m5_p7 __attribute__ ((aligned(16)));
__m128i bit_met_m3_m7 __attribute__ ((aligned(16)));
__m128i bit_met_m3_m5 __attribute__ ((aligned(16)));
__m128i bit_met_m3_m3 __attribute__ ((aligned(16)));
__m128i bit_met_m3_m1 __attribute__ ((aligned(16)));
__m128i bit_met_m3_p1 __attribute__ ((aligned(16)));
__m128i bit_met_m3_p3 __attribute__ ((aligned(16)));
__m128i bit_met_m3_p5 __attribute__ ((aligned(16)));
__m128i bit_met_m3_p7 __attribute__ ((aligned(16)));
__m128i bit_met_m1_m7 __attribute__ ((aligned(16)));
__m128i bit_met_m1_m5 __attribute__ ((aligned(16)));
__m128i bit_met_m1_m3 __attribute__ ((aligned(16)));
__m128i bit_met_m1_m1 __attribute__ ((aligned(16)));
__m128i bit_met_m1_p1 __attribute__ ((aligned(16)));
__m128i bit_met_m1_p3 __attribute__ ((aligned(16)));
__m128i bit_met_m1_p5 __attribute__ ((aligned(16)));
__m128i bit_met_m1_p7 __attribute__ ((aligned(16)));
__m128i bit_met_p1_m7 __attribute__ ((aligned(16)));
__m128i bit_met_p1_m5 __attribute__ ((aligned(16)));
__m128i bit_met_p1_m3 __attribute__ ((aligned(16)));
__m128i bit_met_p1_m1 __attribute__ ((aligned(16)));
__m128i bit_met_p1_p1 __attribute__ ((aligned(16)));
__m128i bit_met_p1_p3 __attribute__ ((aligned(16)));
__m128i bit_met_p1_p5 __attribute__ ((aligned(16)));
__m128i bit_met_p1_p7 __attribute__ ((aligned(16)));
__m128i bit_met_p3_m7 __attribute__ ((aligned(16)));
__m128i bit_met_p3_m5 __attribute__ ((aligned(16)));
__m128i bit_met_p3_m3 __attribute__ ((aligned(16)));
__m128i bit_met_p3_m1 __attribute__ ((aligned(16)));
__m128i bit_met_p3_p1 __attribute__ ((aligned(16)));
__m128i bit_met_p3_p3 __attribute__ ((aligned(16)));
__m128i bit_met_p3_p5 __attribute__ ((aligned(16)));
__m128i bit_met_p3_p7 __attribute__ ((aligned(16)));
__m128i bit_met_p5_m7 __attribute__ ((aligned(16)));
__m128i bit_met_p5_m5 __attribute__ ((aligned(16)));
__m128i bit_met_p5_m3 __attribute__ ((aligned(16)));
__m128i bit_met_p5_m1 __attribute__ ((aligned(16)));
__m128i bit_met_p5_p1 __attribute__ ((aligned(16)));
__m128i bit_met_p5_p3 __attribute__ ((aligned(16)));
__m128i bit_met_p5_p5 __attribute__ ((aligned(16)));
__m128i bit_met_p5_p7 __attribute__ ((aligned(16)));
__m128i bit_met_p7_m7 __attribute__ ((aligned(16)));
__m128i bit_met_p7_m5 __attribute__ ((aligned(16)));
__m128i bit_met_p7_m3 __attribute__ ((aligned(16)));
__m128i bit_met_p7_m1 __attribute__ ((aligned(16)));
__m128i bit_met_p7_p1 __attribute__ ((aligned(16)));
__m128i bit_met_p7_p3 __attribute__ ((aligned(16)));
__m128i bit_met_p7_p5 __attribute__ ((aligned(16)));
__m128i bit_met_p7_p7 __attribute__ ((aligned(16)));

__m128i  y0_p_1_1 __attribute__ ((aligned(16)));
__m128i  y0_p_1_3 __attribute__ ((aligned(16)));
__m128i  y0_p_1_5 __attribute__ ((aligned(16)));
__m128i  y0_p_1_7 __attribute__ ((aligned(16)));
__m128i  y0_p_3_1 __attribute__ ((aligned(16)));
__m128i  y0_p_3_3 __attribute__ ((aligned(16)));
__m128i  y0_p_3_5 __attribute__ ((aligned(16)));
__m128i  y0_p_3_7 __attribute__ ((aligned(16)));
__m128i  y0_p_5_1 __attribute__ ((aligned(16)));
__m128i  y0_p_5_3 __attribute__ ((aligned(16)));
__m128i  y0_p_5_5 __attribute__ ((aligned(16)));
__m128i  y0_p_5_7 __attribute__ ((aligned(16)));
__m128i  y0_p_7_1 __attribute__ ((aligned(16)));
__m128i  y0_p_7_3 __attribute__ ((aligned(16)));
__m128i  y0_p_7_5 __attribute__ ((aligned(16)));
__m128i  y0_p_7_7 __attribute__ ((aligned(16)));
__m128i  y0_m_1_1 __attribute__ ((aligned(16)));
__m128i  y0_m_1_3 __attribute__ ((aligned(16)));
__m128i  y0_m_1_5 __attribute__ ((aligned(16)));
__m128i  y0_m_1_7 __attribute__ ((aligned(16)));
__m128i  y0_m_3_1 __attribute__ ((aligned(16)));
__m128i  y0_m_3_3 __attribute__ ((aligned(16)));
__m128i  y0_m_3_5 __attribute__ ((aligned(16)));
__m128i  y0_m_3_7 __attribute__ ((aligned(16)));
__m128i  y0_m_5_1 __attribute__ ((aligned(16)));
__m128i  y0_m_5_3 __attribute__ ((aligned(16)));
__m128i  y0_m_5_5 __attribute__ ((aligned(16)));
__m128i  y0_m_5_7 __attribute__ ((aligned(16)));
__m128i  y0_m_7_1 __attribute__ ((aligned(16)));
__m128i  y0_m_7_3 __attribute__ ((aligned(16)));
__m128i  y0_m_7_5 __attribute__ ((aligned(16)));
__m128i  y0_m_7_7 __attribute__ ((aligned(16)));

__m128i  xmm0 __attribute__ ((aligned(16)));
__m128i  xmm1 __attribute__ ((aligned(16)));
__m128i  xmm2 __attribute__ ((aligned(16)));
__m128i  xmm3 __attribute__ ((aligned(16)));
__m128i  xmm4 __attribute__ ((aligned(16)));
__m128i  xmm5 __attribute__ ((aligned(16)));
__m128i  xmm6 __attribute__ ((aligned(16)));
__m128i  xmm7 __attribute__ ((aligned(16)));
__m128i  xmm8 __attribute__ ((aligned(16)));

__m128i  y0r __attribute__ ((aligned(16)));
__m128i  y0i __attribute__ ((aligned(16)));
__m128i  y1r __attribute__ ((aligned(16)));
__m128i  y1i __attribute__ ((aligned(16)));
__m128i  y2r __attribute__ ((aligned(16)));
__m128i  y2i __attribute__ ((aligned(16)));

__m128i  logmax_num_re0 __attribute__ ((aligned(16)));
__m128i  logmax_num_im0 __attribute__ ((aligned(16)));
__m128i  logmax_den_re0 __attribute__ ((aligned(16)));
__m128i  logmax_den_im0 __attribute__ ((aligned(16)));
__m128i  logmax_num_re1 __attribute__ ((aligned(16)));
__m128i  logmax_num_im1 __attribute__ ((aligned(16)));
__m128i  logmax_den_re1 __attribute__ ((aligned(16)));
__m128i  logmax_den_im1 __attribute__ ((aligned(16)));

__m128i tmp_result  __attribute__ ((aligned(16)));
__m128i tmp_result2 __attribute__ ((aligned(16)));
__m128i tmp_result3 __attribute__ ((aligned(16)));
__m128i tmp_result4 __attribute__ ((aligned(16)));
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//==============================================================================================
// Auxiliary Makros

608
// calculates psi_a = psi_r*a_r + psi_i*a_i
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#define prodsum_psi_a_epi16(psi_r,a_r,psi_i,a_i,psi_a) tmp_result = _mm_mulhi_epi16(psi_r,a_r); tmp_result = _mm_slli_epi16(tmp_result,1); tmp_result2 = _mm_mulhi_epi16(psi_i,a_i); tmp_result2 = _mm_slli_epi16(tmp_result2,1); psi_a = _mm_adds_epi16(tmp_result,tmp_result2);

// calculate interference magnitude
612
#define interference_abs_epi16(psi,int_ch_mag,int_mag,c1,c2) tmp_result = _mm_cmplt_epi16(psi,int_ch_mag); tmp_result2 = _mm_xor_si128(tmp_result,(*(__m128i*)&ones[0])); tmp_result = _mm_and_si128(tmp_result,c1); tmp_result2 = _mm_and_si128(tmp_result2,c2); int_mag = _mm_or_si128(tmp_result,tmp_result2);
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// calculate interference magnitude
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// tmp_result = ones in shorts corr. to interval 2<=x<=4, tmp_result2 interval < 2, tmp_result3 interval 4<x<6 and tmp_result4 interval x>6
#define interference_abs_64qam_epi16(psi,int_ch_mag,int_two_ch_mag,int_three_ch_mag,a,c1,c3,c5,c7) tmp_result = _mm_cmplt_epi16(psi,int_two_ch_mag); tmp_result3 = _mm_xor_si128(tmp_result,(*(__m128i*)&ones[0])); tmp_result2 = _mm_cmplt_epi16(psi,int_ch_mag); tmp_result = _mm_xor_si128(tmp_result,tmp_result2); tmp_result4 = _mm_cmpgt_epi16(psi,int_three_ch_mag); tmp_result3 = _mm_xor_si128(tmp_result3,tmp_result4); tmp_result = _mm_and_si128(tmp_result,c3); tmp_result2 = _mm_and_si128(tmp_result2,c1); tmp_result3 = _mm_and_si128(tmp_result3,c5); tmp_result4 = _mm_and_si128(tmp_result4,c7); tmp_result = _mm_or_si128(tmp_result,tmp_result2); tmp_result3 = _mm_or_si128(tmp_result3,tmp_result4); a = _mm_or_si128(tmp_result,tmp_result3);
617

618
// calculates a_sq = int_ch_mag*(a_r^2 + a_i^2)*scale_factor
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#define square_a_epi16(a_r,a_i,int_ch_mag,scale_factor,a_sq) tmp_result = _mm_mulhi_epi16(a_r,a_r); tmp_result = _mm_slli_epi16(tmp_result,1); tmp_result = _mm_mulhi_epi16(tmp_result,scale_factor); tmp_result = _mm_slli_epi16(tmp_result,1); tmp_result = _mm_mulhi_epi16(tmp_result,int_ch_mag); tmp_result = _mm_slli_epi16(tmp_result,1); tmp_result2 = _mm_mulhi_epi16(a_i,a_i); tmp_result2 = _mm_slli_epi16(tmp_result2,1); tmp_result2 = _mm_mulhi_epi16(tmp_result2,scale_factor); tmp_result2 = _mm_slli_epi16(tmp_result2,1); tmp_result2 = _mm_mulhi_epi16(tmp_result2,int_ch_mag); tmp_result2 = _mm_slli_epi16(tmp_result2,1); a_sq = _mm_adds_epi16(tmp_result,tmp_result2);

// calculates a_sq = int_ch_mag*(a_r^2 + a_i^2)*scale_factor for 64-QAM
#define square_a_64qam_epi16(a_r,a_i,int_ch_mag,scale_factor,a_sq)  tmp_result = _mm_mulhi_epi16(a_r,a_r); tmp_result = _mm_slli_epi16(tmp_result,1); tmp_result = _mm_mulhi_epi16(tmp_result,scale_factor); tmp_result = _mm_slli_epi16(tmp_result,3); tmp_result = _mm_mulhi_epi16(tmp_result,int_ch_mag); tmp_result = _mm_slli_epi16(tmp_result,1); tmp_result2 = _mm_mulhi_epi16(a_i,a_i); tmp_result2 = _mm_slli_epi16(tmp_result2,1); tmp_result2 = _mm_mulhi_epi16(tmp_result2,scale_factor); tmp_result2 = _mm_slli_epi16(tmp_result2,3); tmp_result2 = _mm_mulhi_epi16(tmp_result2,int_ch_mag); tmp_result2 = _mm_slli_epi16(tmp_result2,1); a_sq = _mm_adds_epi16(tmp_result,tmp_result2);

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#elif defined(__arm__)

#endif

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//==============================================================================================
// SINGLE-STREAM
//==============================================================================================

//----------------------------------------------------------------------------------------------
// QPSK
//----------------------------------------------------------------------------------------------

int dlsch_qpsk_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                   int32_t **rxdataF_comp,
                   int16_t *dlsch_llr,
                   uint8_t symbol,
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                   uint8_t first_symbol_flag,
                   uint16_t nb_rb,
                   uint16_t pbch_pss_sss_adjust,
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                   int16_t **llr32p)
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{
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  uint32_t *rxF = (uint32_t*)&rxdataF_comp[0][((int32_t)symbol*frame_parms->N_RB_DL*12)];
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  uint32_t *llr32;
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  int i,len;
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  uint8_t symbol_mod = (symbol >= (7-frame_parms->Ncp))? (symbol-(7-frame_parms->Ncp)) : symbol;
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  if (first_symbol_flag==1) {
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    llr32 = (uint32_t*)dlsch_llr;
  } else {
    llr32 = (uint32_t*)(*llr32p);
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  }
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  if (!llr32) {
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    msg("dlsch_qpsk_llr: llr is null, symbol %d, llr32=%p\n",symbol, llr32);
    return(-1);
  }
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  if ((symbol_mod==0) || (symbol_mod==(4-frame_parms->Ncp))) {
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    if (frame_parms->mode1_flag==0)
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      len = (nb_rb*8) - (2*pbch_pss_sss_adjust/3);
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    else
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      len = (nb_rb*10) - (5*pbch_pss_sss_adjust/6);
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  } else {
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    len = (nb_rb*12) - pbch_pss_sss_adjust;
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  }
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  //  printf("dlsch_qpsk_llr: symbol %d,nb_rb %d, len %d,pbch_pss_sss_adjust %d\n",symbol,nb_rb,len,pbch_pss_sss_adjust);
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  for (i=0; i<len; i++) {
    *llr32 = *rxF;
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    //    printf("llr %d : (%d,%d)\n",i,((int16_t*)llr32)[0],((int16_t*)llr32)[1]);
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    rxF++;
    llr32++;
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  }

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  *llr32p = (int16_t *)llr32;
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  return(0);
}

//----------------------------------------------------------------------------------------------
// 16-QAM
//----------------------------------------------------------------------------------------------

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,
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                     uint8_t first_symbol_flag,
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                     uint16_t nb_rb,
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                     uint16_t pbch_pss_sss_adjust,
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                     int16_t **llr32p)
{

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#if defined(__x86_64__) || defined(__i386__)
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  __m128i *rxF = (__m128i*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  __m128i *ch_mag;
  __m128i llr128[2];
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  uint32_t *llr32;
#elif defined(__arm__)
  int16x8_t *rxF = (int16x8_t*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  int16x8_t *ch_mag;
  int16x8_t xmm0;
  int16_t *llr16;
#endif


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  int i,len;
  unsigned char symbol_mod,len_mod4=0;


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  if (first_symbol_flag==1) {
    llr32 = (uint32_t*)dlsch_llr;
  } else {
    llr32 = (uint32_t*)*llr32p;
  }
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#elif defined(__arm__)
  if (first_symbol_flag==1) {
    llr16 = (int16_t*)dlsch_llr;
  } else {
    llr16 = (int16_t*)*llr32p;
  }
#endif
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  symbol_mod = (symbol>=(7-frame_parms->Ncp)) ? symbol-(7-frame_parms->Ncp) : symbol;

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  ch_mag = (__m128i*)&dl_ch_mag[0][(symbol*frame_parms->N_RB_DL*12)];
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#elif defined(__arm__)
  ch_mag = (int16x8_t*)&dl_ch_mag[0][(symbol*frame_parms->N_RB_DL*12)];
#endif
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  if ((symbol_mod==0) || (symbol_mod==(4-frame_parms->Ncp))) {
    if (frame_parms->mode1_flag==0)
      len = nb_rb*8 - (2*pbch_pss_sss_adjust/3);
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    else
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      len = nb_rb*10 - (5*pbch_pss_sss_adjust/6);
  } else {
    len = nb_rb*12 - pbch_pss_sss_adjust;
  }

  // update output pointer according to number of REs in this symbol (<<2 because 4 bits per RE)
  if (first_symbol_flag == 1)
    *llr32p = dlsch_llr + (len<<2);
  else
    *llr32p += (len<<2);

  len_mod4 = len&3;
  len>>=2;  // length in quad words (4 REs)
  len+=(len_mod4==0 ? 0 : 1);

  for (i=0; i<len; i++) {

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    xmm0 = _mm_abs_epi16(rxF[i]);
    xmm0 = _mm_subs_epi16(ch_mag[i],xmm0);

    // lambda_1=y_R, lambda_2=|y_R|-|h|^2, lamda_3=y_I, lambda_4=|y_I|-|h|^2
    llr128[0] = _mm_unpacklo_epi32(rxF[i],xmm0);
    llr128[1] = _mm_unpackhi_epi32(rxF[i],xmm0);
    llr32[0] = _mm_extract_epi32(llr128[0],0); //((uint32_t *)&llr128[0])[0];
    llr32[1] = _mm_extract_epi32(llr128[0],1); //((uint32_t *)&llr128[0])[1];
    llr32[2] = _mm_extract_epi32(llr128[0],2); //((uint32_t *)&llr128[0])[2];
    llr32[3] = _mm_extract_epi32(llr128[0],3); //((uint32_t *)&llr128[0])[3];
    llr32[4] = _mm_extract_epi32(llr128[1],0); //((uint32_t *)&llr128[1])[0];
    llr32[5] = _mm_extract_epi32(llr128[1],1); //((uint32_t *)&llr128[1])[1];
    llr32[6] = _mm_extract_epi32(llr128[1],2); //((uint32_t *)&llr128[1])[2];
    llr32[7] = _mm_extract_epi32(llr128[1],3); //((uint32_t *)&llr128[1])[3];
    llr32+=8;
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#elif defined(__arm__)
    xmm0 = vabsq_s16(rxF[i]);
    xmm0 = vqsubq_s16(ch_mag[i],xmm0);
    // lambda_1=y_R, lambda_2=|y_R|-|h|^2, lamda_3=y_I, lambda_4=|y_I|-|h|^2

    llr16[0] = vgetq_lane_s16(rxF[i],0);
    llr16[1] = vgetq_lane_s16(rxF[i],1);
    llr16[2] = vgetq_lane_s16(xmm0,0);
    llr16[3] = vgetq_lane_s16(xmm0,1);
    llr16[4] = vgetq_lane_s16(rxF[i],2);
    llr16[5] = vgetq_lane_s16(rxF[i],3);
    llr16[6] = vgetq_lane_s16(xmm0,2);
    llr16[7] = vgetq_lane_s16(xmm0,3);
    llr16[8] = vgetq_lane_s16(rxF[i],4);
    llr16[9] = vgetq_lane_s16(rxF[i],5);
    llr16[10] = vgetq_lane_s16(xmm0,4);
    llr16[11] = vgetq_lane_s16(xmm0,5);
    llr16[12] = vgetq_lane_s16(rxF[i],6);
    llr16[13] = vgetq_lane_s16(rxF[i],6);
    llr16[14] = vgetq_lane_s16(xmm0,7);
    llr16[15] = vgetq_lane_s16(xmm0,7);
    llr16+=16;
#endif

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  }
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  _mm_empty();
  _m_empty();
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#endif
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}

//----------------------------------------------------------------------------------------------
// 64-QAM
//----------------------------------------------------------------------------------------------

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,
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                     uint8_t first_symbol_flag,
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                     uint16_t nb_rb,
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                     uint16_t pbch_pss_sss_adjust,
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                     int16_t **llr_save)
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{
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#if defined(__x86_64__) || defined(__i386__)
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  __m128i *rxF = (__m128i*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  __m128i *ch_mag,*ch_magb;
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#elif defined(__arm__)
  int16x8_t *rxF = (int16x8_t*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  int16x8_t *ch_mag,*ch_magb,xmm1,xmm2;
#endif
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  int i,len,len2;
  unsigned char symbol_mod,len_mod4;
  short *llr;
  int16_t *llr2;

  if (first_symbol_flag==1)
    llr = dlsch_llr;
  else
    llr = *llr_save;

  symbol_mod = (symbol>=(7-frame_parms->Ncp)) ? symbol-(7-frame_parms->Ncp) : symbol;

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#if defined(__x86_64__) || defined(__i386__)
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  ch_mag = (__m128i*)&dl_ch_mag[0][(symbol*frame_parms->N_RB_DL*12)];
  ch_magb = (__m128i*)&dl_ch_magb[0][(symbol*frame_parms->N_RB_DL*12)];
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#elif defined(__arm__)
  ch_mag = (int16x8_t*)&dl_ch_mag[0][(symbol*frame_parms->N_RB_DL*12)];
  ch_magb = (int16x8_t*)&dl_ch_magb[0][(symbol*frame_parms->N_RB_DL*12)];
#endif
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  if ((symbol_mod==0) || (symbol_mod==(4-frame_parms->Ncp))) {
    if (frame_parms->mode1_flag==0)
      len = nb_rb*8 - (2*pbch_pss_sss_adjust/3);
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    else
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      len = nb_rb*10 - (5*pbch_pss_sss_adjust/6);
  } else {
    len = nb_rb*12 - pbch_pss_sss_adjust;
  }

  llr2 = llr;
  llr += (len*6);

  len_mod4 =len&3;
  len2=len>>2;  // length in quad words (4 REs)
  len2+=(len_mod4?0:1);

  for (i=0; i<len2; i++) {

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    xmm1 = _mm_abs_epi16(rxF[i]);
    xmm1 = _mm_subs_epi16(ch_mag[i],xmm1);
    xmm2 = _mm_abs_epi16(xmm1);
    xmm2 = _mm_subs_epi16(ch_magb[i],xmm2);
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#elif defined(__arm__)
    xmm1 = vabsq_s16(rxF[i]);
    xmm1 = vsubq_s16(ch_mag[i],xmm1);
    xmm2 = vabsq_s16(xmm1);
    xmm2 = vsubq_s16(ch_magb[i],xmm2);
#endif
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    // loop over all LLRs in quad word (24 coded bits)
    /*
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      for (j=0;j<8;j+=2) {
      llr2[0] = ((short *)&rxF[i])[j];
      llr2[1] = ((short *)&rxF[i])[j+1];
      llr2[2] = ((short *)&xmm1)[j];
      llr2[3] = ((short *)&xmm1)[j+1];
      llr2[4] = ((short *)&xmm2)[j];
      llr2[5] = ((short *)&xmm2)[j+1];

      llr2+=6;
      }
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    */
    llr2[0] = ((short *)&rxF[i])[0];
    llr2[1] = ((short *)&rxF[i])[1];
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    llr2[2] = _mm_extract_epi16(xmm1,0);
    llr2[3] = _mm_extract_epi16(xmm1,1);//((short *)&xmm1)[j+1];
    llr2[4] = _mm_extract_epi16(xmm2,0);//((short *)&xmm2)[j];
    llr2[5] = _mm_extract_epi16(xmm2,1);//((short *)&xmm2)[j+1];
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#elif defined(__arm__)
    llr2[2] = vgetq_lane_s16(xmm1,0);
    llr2[3] = vgetq_lane_s16(xmm1,1);//((short *)&xmm1)[j+1];
    llr2[4] = vgetq_lane_s16(xmm2,0);//((short *)&xmm2)[j];
    llr2[5] = vgetq_lane_s16(xmm2,1);//((short *)&xmm2)[j+1];
#endif
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    llr2+=6;
    llr2[0] = ((short *)&rxF[i])[2];
    llr2[1] = ((short *)&rxF[i])[3];
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    llr2[2] = _mm_extract_epi16(xmm1,2);
    llr2[3] = _mm_extract_epi16(xmm1,3);//((short *)&xmm1)[j+1];
    llr2[4] = _mm_extract_epi16(xmm2,2);//((short *)&xmm2)[j];
    llr2[5] = _mm_extract_epi16(xmm2,3);//((short *)&xmm2)[j+1];
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#elif defined(__arm__)
    llr2[2] = vgetq_lane_s16(xmm1,2);
    llr2[3] = vgetq_lane_s16(xmm1,3);//((short *)&xmm1)[j+1];
    llr2[4] = vgetq_lane_s16(xmm2,2);//((short *)&xmm2)[j];
    llr2[5] = vgetq_lane_s16(xmm2,3);//((short *)&xmm2)[j+1];
#endif
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    llr2+=6;
    llr2[0] = ((short *)&rxF[i])[4];
    llr2[1] = ((short *)&rxF[i])[5];
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    llr2[2] = _mm_extract_epi16(xmm1,4);
    llr2[3] = _mm_extract_epi16(xmm1,5);//((short *)&xmm1)[j+1];
    llr2[4] = _mm_extract_epi16(xmm2,4);//((short *)&xmm2)[j];
    llr2[5] = _mm_extract_epi16(xmm2,5);//((short *)&xmm2)[j+1];
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#elif defined(__arm__)
    llr2[2] = vgetq_lane_s16(xmm1,4);
    llr2[3] = vgetq_lane_s16(xmm1,5);//((short *)&xmm1)[j+1];
    llr2[4] = vgetq_lane_s16(xmm2,4);//((short *)&xmm2)[j];
    llr2[5] = vgetq_lane_s16(xmm2,5);//((short *)&xmm2)[j+1];
#endif
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    llr2+=6;
    llr2[0] = ((short *)&rxF[i])[6];
    llr2[1] = ((short *)&rxF[i])[7];
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    llr2[2] = _mm_extract_epi16(xmm1,6);
    llr2[3] = _mm_extract_epi16(xmm1,7);//((short *)&xmm1)[j+1];
    llr2[4] = _mm_extract_epi16(xmm2,6);//((short *)&xmm2)[j];
    llr2[5] = _mm_extract_epi16(xmm2,7);//((short *)&xmm2)[j+1];
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#elif defined(__arm__)
    llr2[2] = vgetq_lane_s16(xmm1,6);
    llr2[3] = vgetq_lane_s16(xmm1,7);//((short *)&xmm1)[j+1];
    llr2[4] = vgetq_lane_s16(xmm2,6);//((short *)&xmm2)[j];
    llr2[5] = vgetq_lane_s16(xmm2,7);//((short *)&xmm2)[j+1];
#endif
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    llr2+=6;

  }

  *llr_save = llr;
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  _mm_empty();
  _m_empty();
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#endif
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}


//==============================================================================================
// DUAL-STREAM
//==============================================================================================

//----------------------------------------------------------------------------------------------
// QPSK
//----------------------------------------------------------------------------------------------

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#if defined(__x86_64__) || defined(__i386)
__m128i  y0r_over2 __attribute__ ((aligned(16)));
__m128i  y0i_over2 __attribute__ ((aligned(16)));
__m128i  y1r_over2 __attribute__ ((aligned(16)));
__m128i  y1i_over2 __attribute__ ((aligned(16)));

__m128i  A __attribute__ ((aligned(16)));
__m128i  B __attribute__ ((aligned(16)));
__m128i  C __attribute__ ((aligned(16)));
__m128i  D __attribute__ ((aligned(16)));
__m128i  E __attribute__ ((aligned(16)));
__m128i  F __attribute__ ((aligned(16)));
__m128i  G __attribute__ ((aligned(16)));
__m128i  H __attribute__ ((aligned(16)));
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int dlsch_qpsk_qpsk_llr(LTE_DL_FRAME_PARMS *frame_parms,
                        int **rxdataF_comp,
                        int **rxdataF_comp_i,
                        int **rho_i,
                        short *dlsch_llr,
                        unsigned char symbol,
                        unsigned char first_symbol_flag,
                        unsigned short nb_rb,
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                        uint16_t pbch_pss_sss_adjust,
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                        short **llr16p)
{

  int16_t *rxF=(int16_t*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *rxF_i=(int16_t*)&rxdataF_comp_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *rho=(int16_t*)&rho_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *llr16;
  int len;
  uint8_t symbol_mod = (symbol >= (7-frame_parms->Ncp))? (symbol-(7-frame_parms->Ncp)) : symbol;

  if (first_symbol_flag == 1) {
    llr16 = (int16_t*)dlsch_llr;
  } else {
    llr16 = (int16_t*)(*llr16p);
  }

  if (!llr16) {
    msg("dlsch_qpsk_qpsk_llr: llr is null, symbol %d\n",symbol);
    return -1;
  }

  if ((symbol_mod==0) || (symbol_mod==(4-frame_parms->Ncp))) {
    // if symbol has pilots
    if (frame_parms->mode1_flag==0)
      // in 2 antenna ports we have 8 REs per symbol per RB
      len = (nb_rb*8) - (2*pbch_pss_sss_adjust/3);
    else
      // for 1 antenna port we have 10 REs per symbol per RB
      len = (nb_rb*10) - (5*pbch_pss_sss_adjust/6);
  } else {
    // symbol has no pilots
    len = (nb_rb*12) - pbch_pss_sss_adjust;
  }

  //    printf("qpsk_qpsk: len %d, llr16 %p\n",len,llr16);
  qpsk_qpsk((short *)rxF,
            (short *)rxF_i,
            (short *)llr16,
            (short *)rho,
            len);

  llr16 += (len<<1);
  *llr16p = (short *)llr16;

  return(0);
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//__m128i ONE_OVER_SQRT_8 __attribute__((aligned(16)));
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void qpsk_qpsk(short *stream0_in,
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               short *stream1_in,
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               short *stream0_out,
               short *rho01,
               int length
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	       )
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{
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  /*
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    This function computes the LLRs of stream 0 (s_0) in presence of the interfering stream 1 (s_1) assuming that both symbols are QPSK. It can be used for both MU-MIMO interference-aware receiver or for SU-MIMO receivers.

    Parameters:
    stream0_in = Matched filter output y0' = (h0*g0)*y0
    stream1_in = Matched filter output y1' = (h0*g1)*y0
    stream0_out = LLRs
    rho01 = Correlation between the two effective channels \rho_{10} = (h1*g1)*(h0*g0)
    length = number of resource elements
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  */
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#if defined(__x86_64__) || defined(__i386__)
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  __m128i *rho01_128i = (__m128i *)rho01;
  __m128i *stream0_128i_in = (__m128i *)stream0_in;
  __m128i *stream1_128i_in = (__m128i *)stream1_in;
  __m128i *stream0_128i_out = (__m128i *)stream0_out;
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  __m128i ONE_OVER_SQRT_8 = _mm_set1_epi16(23170); //round(2^16/sqrt(8))
#elif defined(__arm__)
  int16x8_t *rho01_128i = (int16x8_t *)rho01;
  int16x8_t *stream0_128i_in = (int16x8_t *)stream0_in;
  int16x8_t *stream1_128i_in = (int16x8_t *)stream1_in;
  int16x8_t *stream0_128i_out = (int16x8_t *)stream0_out;
  int16x8_t ONE_OVER_SQRT_8 = vdupq_n_s16(23170); //round(2^16/sqrt(8))
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  for (i=0; i<length>>2; i+=2) {
    // in each iteration, we take 8 complex samples
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    xmm0 = rho01_128i[i]; // 4 symbols
    xmm1 = rho01_128i[i+1];

    // put (rho_r + rho_i)/2sqrt2 in rho_rpi
    // put (rho_r - rho_i)/2sqrt2 in rho_rmi
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    xmm0 = _mm_shufflelo_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shufflehi_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shuffle_epi32(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflelo_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflehi_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shuffle_epi32(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    //xmm0 = [Re(0,1) Re(2,3) Im(0,1) Im(2,3)]
    //xmm1 = [Re(4,5) Re(6,7) Im(4,5) Im(6,7)]
    xmm2 = _mm_unpacklo_epi64(xmm0,xmm1); // Re(rho)
    xmm3 = _mm_unpackhi_epi64(xmm0,xmm1); // Im(rho)
    rho_rpi = _mm_adds_epi16(xmm2,xmm3); // rho = Re(rho) + Im(rho)
    rho_rmi = _mm_subs_epi16(xmm2,xmm3); // rho* = Re(rho) - Im(rho)

    // divide by sqrt(8), no shift needed ONE_OVER_SQRT_8 = Q1.16
    rho_rpi = _mm_mulhi_epi16(rho_rpi,ONE_OVER_SQRT_8);
    rho_rmi = _mm_mulhi_epi16(rho_rmi,ONE_OVER_SQRT_8);
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#endif
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    // Compute LLR for first bit of stream 0

    // Compute real and imaginary parts of MF output for stream 0
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#if defined(__x86_64__) || defined(__i386__)
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    xmm0 = stream0_128i_in[i];
    xmm1 = stream0_128i_in[i+1];

    xmm0 = _mm_shufflelo_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shufflehi_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shuffle_epi32(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflelo_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflehi_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shuffle_epi32(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    //xmm0 = [Re(0,1) Re(2,3) Im(0,1) Im(2,3)]
    //xmm1 = [Re(4,5) Re(6,7) Im(4,5) Im(6,7)]
    y0r = _mm_unpacklo_epi64(xmm0,xmm1); // = [y0r(1),y0r(2),y0r(3),y0r(4)]
    y0i = _mm_unpackhi_epi64(xmm0,xmm1);

    y0r_over2  = _mm_srai_epi16(y0r,1);   // divide by 2
    y0i_over2  = _mm_srai_epi16(y0i,1);   // divide by 2
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    // Compute real and imaginary parts of MF output for stream 1
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    xmm0 = stream1_128i_in[i];
    xmm1 = stream1_128i_in[i+1];

    xmm0 = _mm_shufflelo_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shufflehi_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shuffle_epi32(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflelo_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflehi_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shuffle_epi32(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    //xmm0 = [Re(0,1) Re(2,3) Im(0,1) Im(2,3)]
    //xmm1 = [Re(4,5) Re(6,7) Im(4,5) Im(6,7)]
    y1r = _mm_unpacklo_epi64(xmm0,xmm1); //[y1r(1),y1r(2),y1r(3),y1r(4)]
    y1i = _mm_unpackhi_epi64(xmm0,xmm1); //[y1i(1),y1i(2),y1i(3),y1i(4)]

    y1r_over2  = _mm_srai_epi16(y1r,1);   // divide by 2
    y1i_over2  = _mm_srai_epi16(y1i,1);   // divide by 2

    // Compute the terms for the LLR of first bit

    xmm0 = _mm_setzero_si128(); // ZERO

    // 1 term for numerator of LLR
    xmm3 = _mm_subs_epi16(y1r_over2,rho_rpi);
    A = _mm_abs_epi16(xmm3); // A = |y1r/2 - rho/sqrt(8)|
    xmm2 = _mm_adds_epi16(A,y0i_over2); // = |y1r/2 - rho/sqrt(8)| + y0i/2
    xmm3 = _mm_subs_epi16(y1i_over2,rho_rmi);
    B = _mm_abs_epi16(xmm3); // B = |y1i/2 - rho*/sqrt(8)|
    logmax_num_re0 = _mm_adds_epi16(B,xmm2); // = |y1r/2 - rho/sqrt(8)|+|y1i/2 - rho*/sqrt(8)| + y0i/2

    // 2 term for numerator of LLR
    xmm3 = _mm_subs_epi16(y1r_over2,rho_rmi);
    C = _mm_abs_epi16(xmm3); // C = |y1r/2 - rho*/4|
    xmm2 = _mm_subs_epi16(C,y0i_over2); // = |y1r/2 - rho*/4| - y0i/2
    xmm3 = _mm_adds_epi16(y1i_over2,rho_rpi);
    D = _mm_abs_epi16(xmm3); // D = |y1i/2 + rho/4|
    xmm2 = _mm_adds_epi16(xmm2,D); // |y1r/2 - rho*/4| + |y1i/2 + rho/4| - y0i/2
    logmax_num_re0 = _mm_max_epi16(logmax_num_re0,xmm2); // max, numerator done

    // 1 term for denominator of LLR
    xmm3 = _mm_adds_epi16(y1r_over2,rho_rmi);
    E = _mm_abs_epi16(xmm3); // E = |y1r/2 + rho*/4|
    xmm2 = _mm_adds_epi16(E,y0i_over2); // = |y1r/2 + rho*/4| + y0i/2
    xmm3 = _mm_subs_epi16(y1i_over2,rho_rpi);
    F = _mm_abs_epi16(xmm3); // F = |y1i/2 - rho/4|
    logmax_den_re0 = _mm_adds_epi16(F,xmm2); // = |y1r/2 + rho*/4| + |y1i/2 - rho/4| + y0i/2

    // 2 term for denominator of LLR
    xmm3 = _mm_adds_epi16(y1r_over2,rho_rpi);
    G = _mm_abs_epi16(xmm3); // G = |y1r/2 + rho/4|
    xmm2 = _mm_subs_epi16(G,y0i_over2); // = |y1r/2 + rho/4| - y0i/2
    xmm3 = _mm_adds_epi16(y1i_over2,rho_rmi);
    H = _mm_abs_epi16(xmm3); // H = |y1i/2 + rho*/4|
    xmm2 = _mm_adds_epi16(xmm2,H); // = |y1r/2 + rho/4| + |y1i/2 + rho*/4| - y0i/2
    logmax_den_re0 = _mm_max_epi16(logmax_den_re0,xmm2); // max, denominator done

    // Compute the terms for the LLR of first bit

    // 1 term for nominator of LLR
    xmm2 = _mm_adds_epi16(A,y0r_over2);
    logmax_num_im0 = _mm_adds_epi16(B,xmm2); // = |y1r/2 - rho/4| + |y1i/2 - rho*/4| + y0r/2

    // 2 term for nominator of LLR
    xmm2 = _mm_subs_epi16(E,y0r_over2);
    xmm2 = _mm_adds_epi16(xmm2,F); // = |y1r/2 + rho*/4| + |y1i/2 - rho/4| - y0r/2

    logmax_num_im0 = _mm_max_epi16(logmax_num_im0,xmm2); // max, nominator done

    // 1 term for denominator of LLR
    xmm2 = _mm_adds_epi16(C,y0r_over2);
    logmax_den_im0 = _mm_adds_epi16(D,xmm2); // = |y1r/2 - rho*/4| + |y1i/2 + rho/4| - y0r/2

    xmm2 = _mm_subs_epi16(G,y0r_over2);
    xmm2 = _mm_adds_epi16(xmm2,H); // = |y1r/2 + rho/4| + |y1i/2 + rho*/4| - y0r/2

    logmax_den_im0 = _mm_max_epi16(logmax_den_im0,xmm2); // max, denominator done

    // LLR of first bit [L1(1), L1(2), L1(3), L1(4)]
    y0r = _mm_adds_epi16(y0r,logmax_num_re0);
    y0r = _mm_subs_epi16(y0r,logmax_den_re0);

    // LLR of second bit [L2(1), L2(2), L2(3), L2(4)]
    y0i = _mm_adds_epi16(y0i,logmax_num_im0);
    y0i = _mm_subs_epi16(y0i,logmax_den_im0);

    _mm_storeu_si128(&stream0_128i_out[i],_mm_unpacklo_epi16(y0r,y0i)); // = [L1(1), L2(1), L1(2), L2(2)]

    if (i<((length>>1) - 1)) // false if only 2 REs remain
      _mm_storeu_si128(&stream0_128i_out[i+1],_mm_unpackhi_epi16(y0r,y0i));

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#elif defined(__x86_64__)

#endif
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  }

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#if defined(__x86_64__) || defined(__i386__)
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  _mm_empty();
  _m_empty();
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#endif
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}

int dlsch_qpsk_16qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                         int32_t **rxdataF_comp,
                         int32_t **rxdataF_comp_i,
                         int32_t **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,
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                         uint16_t pbch_pss_sss_adjust,
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                         int16_t **llr16p)
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{

  int16_t *rxF=(int16_t*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *rxF_i=(int16_t*)&rxdataF_comp_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *ch_mag_i = (int16_t*)&dl_ch_mag_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *rho=(int16_t*)&rho_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *llr16;
  int len;
  uint8_t symbol_mod = (symbol >= (7-frame_parms->Ncp))? (symbol-(7-frame_parms->Ncp)) : symbol;

  if (first_symbol_flag == 1) {
    llr16 = (int16_t*)dlsch_llr;
  } else {
    llr16 = (int16_t*)(*llr16p);
  }

  if (!llr16) {
    msg("dlsch_qpsk_qpsk_llr: llr is null, symbol %d\n",symbol);
    return -1;
  }

  if ((symbol_mod==0) || (symbol_mod==(4-frame_parms->Ncp))) {
    // if symbol has pilots
    if (frame_parms->mode1_flag==0)
      // in 2 antenna ports we have 8 REs per symbol per RB
      len = (nb_rb*8) - (2*pbch_pss_sss_adjust/3);
    else
      // for 1 antenna port we have 10 REs per symbol per RB
      len = (nb_rb*10) - (5*pbch_pss_sss_adjust/6);
  } else {
    // symbol has no pilots
    len = (nb_rb*12) - pbch_pss_sss_adjust;
  }

  qpsk_qam16((short *)rxF,
             (short *)rxF_i,
             (short *)ch_mag_i,
             (short *)llr16,
             (short *)rho,
             len);

  llr16 += (len<<1);
  *llr16p = (short *)llr16;

  return(0);
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}

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/*
#if defined(__x86_64__) || defined(__i386__)
__m128i ONE_OVER_SQRT_2 __attribute__((aligned(16)));
__m128i ONE_OVER_SQRT_10 __attribute__((aligned(16)));
__m128i THREE_OVER_SQRT_10 __attribute__((aligned(16)));
__m128i ONE_OVER_SQRT_10_Q15 __attribute__((aligned(16)));
__m128i SQRT_10_OVER_FOUR __attribute__((aligned(16)));
__m128i ch_mag_int;
#endif
*/
void qpsk_qam16(int16_t *stream0_in,
                int16_t *stream1_in,
                int16_t *ch_mag_i,
                int16_t *stream0_out,
                int16_t *rho01,
                int32_t length
		)
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{
  /*
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    This function computes the LLRs of stream 0 (s_0) in presence of the interfering stream 1 (s_1) assuming that both symbols are QPSK. It can be used for both MU-MIMO interference-aware receiver or for SU-MIMO receivers.

    Parameters:
    stream0_in = Matched filter output y0' = (h0*g0)*y0
    stream1_in = Matched filter output y1' = (h0*g1)*y0
    stream0_out = LLRs
    rho01 = Correlation between the two effective channels \rho_{10} = (h1*g1)*(h0*g0)
    length = number of resource elements
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  */

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#if defined(__x86_64__) || defined(__i386__)
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  __m128i *rho01_128i = (__m128i *)rho01;
  __m128i *stream0_128i_in = (__m128i *)stream0_in;
  __m128i *stream1_128i_in = (__m128i *)stream1_in;
  __m128i *stream0_128i_out = (__m128i *)stream0_out;
  __m128i *ch_mag_128i_i    = (__m128i *)ch_mag_i;
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  __m128i ONE_OVER_SQRT_2 = _mm_set1_epi16(23170); // round(1/sqrt(2)*2^15)
  __m128i ONE_OVER_SQRT_10_Q15 = _mm_set1_epi16(10362); // round(1/sqrt(10)*2^15)
  __m128i THREE_OVER_SQRT_10 = _mm_set1_epi16(31086); // round(3/sqrt(10)*2^15)
  __m128i SQRT_10_OVER_FOUR = _mm_set1_epi16(25905); // round(sqrt(10)/4*2^15)
  __m128i ch_mag_int __attribute__((aligned(16)));
#elif defined(__arm__)
  int16x8_t *rho01_128i = (int16x8_t *)rho01;
  int16x8_t *stream0_128i_in = (int16x8_t *)stream0_in;
  int16x8_t *stream1_128i_in = (int16x8_t *)stream1_in;
  int16x8_t *stream0_128i_out = (int16x8_t *)stream0_out;
  int16x8_t *ch_mag_128i_i    = (int16x8_t *)ch_mag_i;
  int16x8_t ONE_OVER_SQRT_2 = vdupq_n_s16(23170); // round(1/sqrt(2)*2^15)
  int16x8_t ONE_OVER_SQRT_10_Q15 = vdupq_n_s16(10362); // round(1/sqrt(10)*2^15)
  int16x8_t THREE_OVER_SQRT_10 = vdupq_n_s16(31086); // round(3/sqrt(10)*2^15)
  int16x8_t SQRT_10_OVER_FOUR = vdupq_n_s16(25905); // round(sqrt(10)/4*2^15)
  int16x8_t ch_mag_int __attribute__((aligned(16)));
#endif
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#ifdef DEBUG_LLR
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  print_shorts2("rho01_128i:\n",rho01_128i);
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#endif

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  int i;


  for (i=0; i<length>>2; i+=2) {
    // in each iteration, we take 8 complex samples

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#if defined(__x86_64__) || defined(__i386__)

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    xmm0 = rho01_128i[i]; // 4 symbols
    xmm1 = rho01_128i[i+1];

    // put (rho_r + rho_i)/2sqrt2 in rho_rpi
    // put (rho_r - rho_i)/2sqrt2 in rho_rmi
    xmm0 = _mm_shufflelo_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shufflehi_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shuffle_epi32(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflelo_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflehi_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shuffle_epi32(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    //xmm0 = [Re(0,1) Re(2,3) Im(0,1) Im(2,3)]
    //xmm1 = [Re(4,5) Re(6,7) Im(4,5) Im(6,7)]
    xmm2 = _mm_unpacklo_epi64(xmm0,xmm1); // Re(rho)
    xmm3 = _mm_unpackhi_epi64(xmm0,xmm1); // Im(rho)
    rho_rpi = _mm_adds_epi16(xmm2,xmm3); // rho = Re(rho) + Im(rho)
    rho_rmi = _mm_subs_epi16(xmm2,xmm3); // rho* = Re(rho) - Im(rho)

    // divide by sqrt(2)
    rho_rpi = _mm_mulhi_epi16(rho_rpi, ONE_OVER_SQRT_2);
    rho_rmi = _mm_mulhi_epi16(rho_rmi, ONE_OVER_SQRT_2);
    rho_rpi = _mm_slli_epi16(rho_rpi,1);
    rho_rmi = _mm_slli_epi16(rho_rmi,1);

    // Compute LLR for first bit of stream 0

    // Compute real and imaginary parts of MF output for stream 0
    xmm0 = stream0_128i_in[i];
    xmm1 = stream0_128i_in[i+1];

    xmm0 = _mm_shufflelo_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shufflehi_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shuffle_epi32(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflelo_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflehi_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shuffle_epi32(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    //xmm0 = [Re(0,1) Re(2,3) Im(0,1) Im(2,3)]
    //xmm1 = [Re(4,5) Re(6,7) Im(4,5) Im(6,7)]
    y0r = _mm_unpacklo_epi64(xmm0,xmm1); // = [y0r(1),y0r(2),y0r(3),y0r(4)]
    y0i = _mm_unpackhi_epi64(xmm0,xmm1);

    // divide by sqrt(2)
    y0r_over2 = _mm_mulhi_epi16(y0r, ONE_OVER_SQRT_2);
    y0i_over2 = _mm_mulhi_epi16(y0i, ONE_OVER_SQRT_2);
    y0r_over2  = _mm_slli_epi16(y0r,1);
    y0i_over2  = _mm_slli_epi16(y0i,1);

    y0_p_1_1 = _mm_adds_epi16(y0r_over2, y0i_over2);
    y0_m_1_1 = _mm_subs_epi16(y0r_over2, y0i_over2);

    // Compute real and imaginary parts of MF output for stream 1
    xmm0 = stream1_128i_in[i];
    xmm1 = stream1_128i_in[i+1];

    xmm0 = _mm_shufflelo_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shufflehi_epi16(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm0 = _mm_shuffle_epi32(xmm0,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflelo_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shufflehi_epi16(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm1 = _mm_shuffle_epi32(xmm1,0xd8); //_MM_SHUFFLE(0,2,1,3));
    //xmm0 = [Re(0,1) Re(2,3) Im(0,1) Im(2,3)]
    //xmm1 = [Re(4,5) Re(6,7) Im(4,5) Im(6,7)]
    y1r = _mm_unpacklo_epi64(xmm0,xmm1); //[y1r(1),y1r(2),y1r(3),y1r(4)]
    y1i = _mm_unpackhi_epi64(xmm0,xmm1); //[y1i(1),y1i(2),y1i(3),y1i(4)]

    xmm0 = _mm_setzero_si128(); // ZERO

    // compute psi
    xmm3 = _mm_subs_epi16(y1r,rho_rpi);
    psi_r_p1_p1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_subs_epi16(y1i,rho_rmi);
    psi_i_p1_p1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_subs_epi16(y1r,rho_rmi);
    psi_r_p1_m1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_adds_epi16(y1i,rho_rpi);
    psi_i_p1_m1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_adds_epi16(y1r,rho_rmi);
    psi_r_m1_p1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_subs_epi16(y1i,rho_rpi);
    psi_i_m1_p1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_adds_epi16(y1r,rho_rpi);
    psi_r_m1_m1 = _mm_abs_epi16(xmm3);
    xmm3 = _mm_adds_epi16(y1i,rho_rmi);
    psi_i_m1_m1 = _mm_abs_epi16(xmm3);

    // Rearrange interfering channel magnitudes
    xmm2 = ch_mag_128i_i[i];
    xmm3 = ch_mag_128i_i[i+1];

    xmm2 = _mm_shufflelo_epi16(xmm2,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm2 = _mm_shufflehi_epi16(xmm2,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm2 = _mm_shuffle_epi32(xmm2,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm3 = _mm_shufflelo_epi16(xmm3,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm3 = _mm_shufflehi_epi16(xmm3,0xd8); //_MM_SHUFFLE(0,2,1,3));
    xmm3 = _mm_shuffle_epi32(xmm3,0xd8); //_MM_SHUFFLE(0,2,1,3));

    ch_mag_int = _mm_unpacklo_epi64(xmm2,xmm3);

    // calculate optimal interference amplitudes
    interference_abs_epi16(psi_r_p1_p1 , ch_mag_int, a_r_p1_p1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_i_p1_p1 , ch_mag_int, a_i_p1_p1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_r_p1_m1 , ch_mag_int, a_r_p1_m1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_i_p1_m1 , ch_mag_int, a_i_p1_m1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_r_m1_p1 , ch_mag_int, a_r_m1_p1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_i_m1_p1 , ch_mag_int, a_i_m1_p1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_r_m1_m1 , ch_mag_int, a_r_m1_m1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);
    interference_abs_epi16(psi_i_m1_m1 , ch_mag_int, a_i_m1_m1 , ONE_OVER_SQRT_10_Q15, THREE_OVER_SQRT_10);

    // prodsum
    prodsum_psi_a_epi16(psi_r_p1_p1, a_r_p1_p1, psi_i_p1_p1, a_i_p1_p1, psi_a_p1_p1);
    prodsum_psi_a_epi16(psi_r_p1_m1, a_r_p1_m1, psi_i_p1_m1, a_i_p1_m1, psi_a_p1_m1);
    prodsum_psi_a_epi16(psi_r_m1_p1, a_r_m1_p1, psi_i_m1_p1, a_i_m1_p1, psi_a_m1_p1);
    prodsum_psi_a_epi16(psi_r_m1_m1, a_r_m1_m1, psi_i_m1_m1, a_i_m1_m1, psi_a_m1_m1);

    // squares
    square_a_epi16(a_r_p1_p1, a_i_p1_p1, ch_mag_int, SQRT_10_OVER_FOUR, a_sq_p1_p1);
    square_a_epi16(a_r_p1_m1, a_i_p1_m1, ch_mag_int, SQRT_10_OVER_FOUR, a_sq_p1_m1);
    square_a_epi16(a_r_m1_p1, a_i_m1_p1, ch_mag_int, SQRT_10_OVER_FOUR, a_sq_m1_p1);
    square_a_epi16(a_r_m1_m1, a_i_m1_m1, ch_mag_int, SQRT_10_OVER_FOUR, a_sq_m1_m1);

    // Computing Metrics
    xmm0 = _mm_subs_epi16(psi_a_p1_p1, a_sq_p1_p1);
    bit_met_p1_p1 = _mm_adds_epi16(xmm0, y0_p_1_1);

    xmm0 = _mm_subs_epi16(psi_a_p1_m1, a_sq_p1_m1);
    bit_met_p1_m1 = _mm_adds_epi16(xmm0, y0_m_1_1);

    xmm0 = _mm_subs_epi16(psi_a_m1_p1, a_sq_m1_p1);
    bit_met_m1_p1 = _mm_subs_epi16(xmm0, y0_m_1_1);

    xmm0 = _mm_subs_epi16(psi_a_m1_m1, a_sq_m1_m1);
    bit_met_m1_m1 = _mm_subs_epi16(xmm0, y0_p_1_1);

    // MSB
    logmax_num_re0 = _mm_max_epi16(bit_met_p1_p1,bit_met_p1_m1); // bit=0
    logmax_den_re0 = _mm_max_epi16(bit_met_m1_p1,bit_met_m1_m1); // bit=1

    y0r = _mm_subs_epi16(logmax_num_re0,logmax_den_re0);

    // LSB
    logmax_num_im0 = _mm_max_epi16(bit_met_p1_p1,bit_met_m1_p1); // bit=0
    logmax_den_im0 = _mm_max_epi16(bit_met_p1_m1,bit_met_m1_m1); // bit=1

    y0i = _mm_subs_epi16(logmax_num_im0,logmax_den_im0);

    stream0_128i_out[i] = _mm_unpacklo_epi16(y0r,y0i); // = [L1(1), L2(1), L1(2), L2(2)]

    if (i<((length>>1) - 1)) // false if only 2 REs remain
      stream0_128i_out[i+1] = _mm_unpackhi_epi16(y0r,y0i);

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#elif defined(__arm__)

#endif
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  }

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#if defined(__x86_64__) || defined(__i386__)
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  _mm_empty();
  _m_empty();
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#endif
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}

int dlsch_qpsk_64qam_llr(LTE_DL_FRAME_PARMS *frame_parms,
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                         int32_t **rxdataF_comp,
                         int32_t **rxdataF_comp_i,
                         int32_t **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,
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                         uint16_t pbch_pss_sss_adjust,
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                         int16_t **llr16p)
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{

  int16_t *rxF=(int16_t*)&rxdataF_comp[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *rxF_i=(int16_t*)&rxdataF_comp_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *ch_mag_i = (int16_t*)&dl_ch_mag_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *rho=(int16_t*)&rho_i[0][(symbol*frame_parms->N_RB_DL*12)];
  int16_t *llr16;
  int len;
  uint8_t symbol_mod = (symbol >= (7-frame_parms->Ncp))? (symbol-(7-frame_parms->Ncp)) : symbol;

  if (first_symbol_flag == 1) {
    llr16 = (int16_t*)dlsch_llr;
  } else {
    llr16 = (int16_t*)(*llr16p);
  }

  if (!llr16) {
    msg("dlsch_qpsk_qam64_llr: llr is null, symbol %d\n",symbol);
    return -1;
  }

  if ((symbol_mod==0) || (symbol_mod==(4-frame_parms->Ncp))) {
    // if symbol has pilots
    if (frame_parms->mode1_flag==0)
      // in 2 antenna ports we have 8 REs per symbol per RB
      len = (nb_rb*8) - (2*pbch_pss_sss_adjust/3);
    else
      // for 1 antenna port we have 10 REs per symbol per RB
      len = (nb_rb*10) - (5*pbch_pss_sss_adjust/6);
  } else {
    // symbol has no pilots
    len = (nb_rb*12) - pbch_pss_sss_adjust;
  }

  qpsk_qam64((short *)rxF,
             (short *)rxF_i,
             (short *)ch_mag_i,
             (short *)llr16,
             (short *)rho,
             len);

  llr16 += (len<<1);
  *llr16p = (short *)llr16;

  return(0);
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}
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/*
__m128i ONE_OVER_SQRT_2_42 __attribute__((aligned(16)));
__m128i THREE_OVER_SQRT_2_42 __attribute__((aligned(16)));
__m128i FIVE_OVER_SQRT_2_42 __attribute__((aligned(16)));
__m128i SEVEN_OVER_SQRT_2_42 __attribute__((aligned(16)));

__m128i ch_mag_int_with_sigma2 __attribute__((aligned(16)));
__m128i two_ch_mag_int_with_sigma2 __attribute__((aligned(16)));
__m128i three_ch_mag_int_with_sigma2 __attribute__((aligned(16)));
__m128i SQRT_42_OVER_FOUR __attribute__((aligned(16)));
*/
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void qpsk_qam64(short *stream0_in,
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                short *stream1_in,
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                short *ch_mag_i,
                short *stream0_out,
                short *rho01,
                int length
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		)
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{

  /*
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    This function computes the LLRs of stream 0 (s_0) in presence of the interfering stream 1 (s_1) assuming that both symbols are QPSK. It can be used for both MU-MIMO interference-aware receiver or for SU-MIMO receivers.

    Parameters:
    stream0_in = Matched filter output y0' = (h0*g0)*y0
    stream1_in = Matched filter output y1' = (h0*g1)*y0
    stream0_out = LLRs
    rho01 = Correlation between the two effective channels \rho_{10} = (h1*g1)*(h0*g0)
    length = number of resource elements
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  */

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#if defined(__x86_64__) || defined(__i386__)
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  __m128i *rho01_128i = (__m128i *)rho01;
  __m128i *stream0_128i_in = (__m128i *)stream0_in;
  __m128i *stream1_128i_in = (__m128i *)stream1_in;
  __m128i *stream0_128i_out = (__m128i *)stream0_out;
  __m128i *ch_mag_128i_i    = (__m128i *)ch_mag_i;
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  __m128i ONE_OVER_SQRT_2 = _mm_set1_epi16(23170); // round(1/sqrt(2)*2^15)
  __m128i ONE_OVER_SQRT_2_42 = _mm_set1_epi16(3575); // round(1/sqrt(2*42)*2^15)
  __m128i THREE_OVER_SQRT_2_42 = _mm_set1_epi16(10726); // round(3/sqrt(2*42)*2^15)
  __m128i FIVE_OVER_SQRT_2_42 = _mm_set1_epi16(17876); // round(5/sqrt(2*42)*2^15)
  __m128i SEVEN_OVER_SQRT_2_42 = _mm_set1_epi16(25027); // round(7/sqrt(2*42)*2^15)
  __m128i SQRT_42_OVER_FOUR = _mm_set1_epi16(13272); // round(sqrt(42)/4*2^13), Q3.1
  __m128i ch_mag_int;
  __m128i ch_mag_int_with_sigma2;
  __m128i two_ch_mag_int_with_sigma2;
  __m128i three_ch_mag_int_with_sigma2;
#elif defined(__arm__)

#endif
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#ifdef DEBUG_LLR
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  print_shorts2("rho01_128i:\n",rho01_128i);
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#endif

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  int i;


  for (i=0; i<length>>2;</