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c7361c66f6
11 [CQ DXcall DXgrid]. git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@6934 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
519 lines
17 KiB
C
519 lines
17 KiB
C
/*
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qra64.c
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Encoding/decoding functions for the QRA64 mode
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(c) 2016 - Nico Palermo, IV3NWV
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-------------------------------------------------------------------------------
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qracodes is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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qracodes is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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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 qracodes source distribution.
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If not, see <http://www.gnu.org/licenses/>.
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-----------------------------------------------------------------------------
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Code used in this sowftware release:
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QRA13_64_64_IRR_E: K=13 N=64 Q=64 irregular QRA code (defined in
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qra13_64_64_irr_e.h /.c)
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Codes with K=13 are designed to include a CRC as the 13th information symbol
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and improve the code UER (Undetected Error Rate).
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The CRC symbol is not sent along the channel (the codes are punctured) and the
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resulting code is a (12,63) code
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*/
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//----------------------------------------------------------------------------
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#include <stdlib.h>
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#include <math.h>
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#include <string.h>
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#include "qra64.h"
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#include "../qracodes/qracodes.h"
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#include "../qracodes/qra13_64_64_irr_e.h"
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#include "../qracodes/pdmath.h"
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// Code parameters of the QRA64 mode
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#define QRA64_CODE qra_13_64_64_irr_e
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#define QRA64_NMSG 218 // Must much value indicated in QRA64_CODE.NMSG
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#define QRA64_KC (QRA64_K+1) // Information symbols (crc included)
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#define QRA64_NC (QRA64_N+1) // Codeword length (as defined in the code)
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#define QRA64_NITER 100 // max number of iterations per decode
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// static functions declarations ----------------------------------------------
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static int calc_crc6(const int *x, int sz);
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static void ix_mask(float *dst, const float *src, const int *mask,
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const int *x);
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static int qra64_do_decode(int *x, const float *pix, const int *ap_mask,
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const int *ap_x);
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// a-priori information masks for fields in JT65-like msgs --------------------
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#define MASK_CQQRZ 0xFFFFFFC // CQ/QRZ calls common bits
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#define MASK_CALL1 0xFFFFFFF
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#define MASK_CALL2 0xFFFFFFF
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#define MASK_GRIDFULL 0xFFFF
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#define MASK_GRIDBIT 0x8000 // b[15] is 1 for free text, 0 otherwise
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// ----------------------------------------------------------------------------
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qra64codec *qra64_init(int flags)
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{
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// Eb/No value for which we optimize the decoder metric
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const float EbNodBMetric = 2.8f;
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const float EbNoMetric = (float)pow(10,EbNodBMetric/10);
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const float R = 1.0f*(QRA64_KC)/(QRA64_NC);
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qra64codec *pcodec = (qra64codec*)malloc(sizeof(qra64codec));
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if (!pcodec)
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return 0; // can't allocate memory
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pcodec->decEsNoMetric = 1.0f*QRA64_m*R*EbNoMetric;
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pcodec->apflags = flags;
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memset(pcodec->apmsg_set,0,APTYPE_SIZE*sizeof(int));
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if (flags==QRA_NOAP)
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return pcodec;
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// for QRA_USERAP and QRA_AUTOAP modes we always enable [CQ/QRZ ? ?] mgs look-up.
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// encode CQ/QRZ AP messages
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// NOTE: Here we handle only CQ and QRZ msgs.
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// 'CQ nnn', 'CQ DX' and 'DE' msgs will be handled by the decoder
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// as messages with no a-priori knowledge
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qra64_apset(pcodec, CALL_CQ, 0, GRID_BLANK, APTYPE_CQQRZ);
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// initialize masks for decoding with a-priori information
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encodemsg_jt65(pcodec->apmask_cqqrz, MASK_CQQRZ, 0, MASK_GRIDBIT);
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encodemsg_jt65(pcodec->apmask_cqqrz_ooo, MASK_CQQRZ, 0, MASK_GRIDFULL);
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encodemsg_jt65(pcodec->apmask_call1, MASK_CALL1, 0, MASK_GRIDBIT);
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encodemsg_jt65(pcodec->apmask_call1_ooo, MASK_CALL1, 0, MASK_GRIDFULL);
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encodemsg_jt65(pcodec->apmask_call2, 0, MASK_CALL2, MASK_GRIDBIT);
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encodemsg_jt65(pcodec->apmask_call2_ooo, 0, MASK_CALL2, MASK_GRIDFULL);
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encodemsg_jt65(pcodec->apmask_call1_call2, MASK_CALL1,MASK_CALL2, MASK_GRIDBIT);
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encodemsg_jt65(pcodec->apmask_call1_call2_grid,MASK_CALL1,MASK_CALL2, MASK_GRIDFULL);
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encodemsg_jt65(pcodec->apmask_cq_call2, MASK_CQQRZ, MASK_CALL2, MASK_GRIDBIT);
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encodemsg_jt65(pcodec->apmask_cq_call2_ooo, MASK_CQQRZ, MASK_CALL2, MASK_GRIDFULL);
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return pcodec;
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}
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void qra64_close(qra64codec *pcodec)
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{
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free(pcodec);
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}
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int qra64_apset(qra64codec *pcodec, const int mycall, const int hiscall, const int grid, const int aptype)
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{
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// Set decoder a-priori knowledge accordingly to the type of the message to look up for
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// arguments:
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// pcodec = pointer to a qra64codec data structure as returned by qra64_init
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// mycall = mycall to look for
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// hiscall = hiscall to look for
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// grid = grid to look for
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// aptype = define and masks the type of AP to be set accordingly to the following:
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// APTYPE_CQQRZ set [cq/qrz ? ?/blank]
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// APTYPE_MYCALL set [mycall ? ?/blank]
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// APTYPE_HISCALL set [? hiscall ?/blank]
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// APTYPE_BOTHCALLS set [mycall hiscall ?]
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// APTYPE_FULL set [mycall hiscall grid]
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// APTYPE_CQHISCALL set [cq/qrz hiscall ?/blank] and [cq/qrz hiscall grid]
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// returns:
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// 0 on success
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// -1 when qra64_init was called with the QRA_NOAP flag
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// -2 invalid apytpe
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if (pcodec->apflags==QRA_NOAP)
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return -1;
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switch (aptype) {
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case APTYPE_CQQRZ:
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encodemsg_jt65(pcodec->apmsg_cqqrz, CALL_CQ, 0, GRID_BLANK);
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break;
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case APTYPE_MYCALL:
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encodemsg_jt65(pcodec->apmsg_call1, mycall, 0, GRID_BLANK);
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break;
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case APTYPE_HISCALL:
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encodemsg_jt65(pcodec->apmsg_call2, 0, hiscall, GRID_BLANK);
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break;
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case APTYPE_BOTHCALLS:
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encodemsg_jt65(pcodec->apmsg_call1_call2, mycall, hiscall, GRID_BLANK);
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break;
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case APTYPE_FULL:
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encodemsg_jt65(pcodec->apmsg_call1_call2_grid, mycall, hiscall, grid);
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break;
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case APTYPE_CQHISCALL:
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encodemsg_jt65(pcodec->apmsg_cq_call2, CALL_CQ, hiscall, GRID_BLANK);
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encodemsg_jt65(pcodec->apmsg_cq_call2_grid, CALL_CQ, hiscall, grid);
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break;
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default:
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return -2; // invalid ap type
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}
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pcodec->apmsg_set[aptype]=1; // signal the decoder to look-up for the specified type
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return 0;
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}
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void qra64_apdisable(qra64codec *pcodec, const int aptype)
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{
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if (pcodec->apflags==QRA_NOAP)
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return;
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if (aptype<APTYPE_CQQRZ || aptype>=APTYPE_SIZE)
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return;
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pcodec->apmsg_set[aptype] = 0; // signal the decoder not to look-up to the specified type
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}
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void qra64_encode(qra64codec *pcodec, int *y, const int *x)
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{
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int encx[QRA64_KC]; // encoder input buffer
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int ency[QRA64_NC]; // encoder output buffer
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int hiscall,mycall,grid;
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memcpy(encx,x,QRA64_K*sizeof(int)); // Copy input to encoder buffer
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encx[QRA64_K]=calc_crc6(encx,QRA64_K); // Compute and add crc symbol
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qra_encode(&QRA64_CODE, ency, encx); // encode msg+crc using given QRA code
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// copy codeword to output puncturing the crc symbol
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memcpy(y,ency,QRA64_K*sizeof(int)); // copy information symbols
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memcpy(y+QRA64_K,ency+QRA64_KC,QRA64_C*sizeof(int)); // copy parity symbols
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if (pcodec->apflags!=QRA_AUTOAP)
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return;
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// Here we handle the QRA_AUTOAP mode --------------------------------------------
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// When a [hiscall mycall ?] msg is detected we instruct the decoder
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// to look for [mycall hiscall ?] msgs
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// otherwise when a [cq mycall ?] msg is sent we reset the APTYPE_BOTHCALLS
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// look if the msg sent is a std type message (bit15 of grid field = 0)
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if ((x[9]&0x80)==1)
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return; // no, it's a text message, nothing to do
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// It's a [hiscall mycall grid] message
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// We assume that mycall is our call (but we don't check it)
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// hiscall the station we are calling or a general call (CQ/QRZ/etc..)
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decodemsg_jt65(&hiscall,&mycall,&grid,x);
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if ((hiscall>=CALL_CQ && hiscall<=CALL_CQ999) || hiscall==CALL_CQDX ||
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hiscall==CALL_DE) {
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// tell the decoder to look for msgs directed to us
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qra64_apset(pcodec,mycall,0,0,APTYPE_MYCALL);
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// We are making a general call and don't know who might reply
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// Reset APTYPE_BOTHCALLS so decoder won't look for [mycall hiscall ?] msgs
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qra64_apdisable(pcodec,APTYPE_BOTHCALLS);
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} else {
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// We are replying to someone named hiscall
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// Set APTYPE_BOTHCALLS so decoder will try for [mycall hiscall ?] msgs
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qra64_apset(pcodec,mycall, hiscall, GRID_BLANK, APTYPE_BOTHCALLS);
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}
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}
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#define EBNO_MIN -10.0f // minimum Eb/No value returned by the decoder (in dB)
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int qra64_decode(qra64codec *pcodec, float *ebno, int *x, const float *rxen)
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{
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int k;
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float *srctmp, *dsttmp;
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float ix[QRA64_NC*QRA64_M]; // (depunctured) intrisic information
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int xdec[QRA64_KC]; // decoded message (with crc)
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int ydec[QRA64_NC]; // re-encoded message (for snr calculations)
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float noisestd; // estimated noise variance
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float msge; // estimated message energy
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float ebnoval; // estimated Eb/No
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int rc;
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if (QRA64_NMSG!=QRA64_CODE.NMSG) // sanity check
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return -16; // QRA64_NMSG define is wrong
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// compute symbols intrinsic probabilities from received energy observations
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noisestd = qra_mfskbesselmetric(ix, rxen, QRA64_m, QRA64_N,pcodec->decEsNoMetric);
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// de-puncture observations adding a uniform distribution for the crc symbol
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// move check symbols distributions one symbol towards the end
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dsttmp = PD_ROWADDR(ix,QRA64_M, QRA64_NC-1); //Point to last symbol prob dist
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srctmp = dsttmp-QRA64_M; // source is the previous pd
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for (k=0;k<QRA64_C;k++) {
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pd_init(dsttmp,srctmp,QRA64_M);
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dsttmp -=QRA64_M;
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srctmp -=QRA64_M;
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}
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// Initialize crc prob to a uniform distribution
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pd_init(dsttmp,pd_uniform(QRA64_m),QRA64_M);
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// Attempt to decode without a-priori info --------------------------------
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rc = qra64_do_decode(xdec, ix, NULL, NULL);
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if (rc>=0) {
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rc = 0; // successfull decode with AP0
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goto decode_end;
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}
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else
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if (pcodec->apflags==QRA_NOAP)
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// nothing more to do
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return rc; // rc<0 = unsuccessful decode
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// Here we handle decoding with AP knowledge
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// Attempt to decode CQ calls
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rc = qra64_do_decode(xdec,ix,pcodec->apmask_cqqrz, pcodec->apmsg_cqqrz);
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if (rc>=0) { rc = 1; goto decode_end; }; // decoded [cq/qrz ? ?]
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_cqqrz_ooo,
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pcodec->apmsg_cqqrz);
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if (rc>=0) { rc = 2; goto decode_end; }; // decoded [cq ? ooo]
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// attempt to decode calls directed to us
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if (pcodec->apmsg_set[APTYPE_MYCALL]) {
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_call1,
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pcodec->apmsg_call1);
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if (rc>=0) { rc = 3; goto decode_end; }; // decoded [mycall ? ?]
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_call1_ooo,
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pcodec->apmsg_call1);
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if (rc>=0) { rc = 4; goto decode_end; }; // decoded [mycall ? ooo]
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}
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// attempt to decode [mycall srccall ?] msgs
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if (pcodec->apmsg_set[APTYPE_BOTHCALLS]) {
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_call1_call2,
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pcodec->apmsg_call1_call2);
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if (rc>=0) { rc = 5; goto decode_end; }; // decoded [mycall srccall ?]
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}
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// attempt to decode [? hiscall ?/b] msgs
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if (pcodec->apmsg_set[APTYPE_HISCALL]) {
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_call2,
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pcodec->apmsg_call2);
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if (rc>=0) { rc = 6; goto decode_end; }; // decoded [? hiscall ?]
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_call2_ooo,
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pcodec->apmsg_call2);
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if (rc>=0) { rc = 7; goto decode_end; }; // decoded [? hiscall ooo]
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}
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// attempt to decode [cq/qrz hiscall ?/b/grid] msgs
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if (pcodec->apmsg_set[APTYPE_CQHISCALL]) {
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_cq_call2,
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pcodec->apmsg_cq_call2);
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if (rc>=0) { rc = 9; goto decode_end; }; // decoded [cq/qrz hiscall ?]
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_cq_call2_ooo,
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pcodec->apmsg_cq_call2_grid);
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if (rc>=0) { rc = 11; goto decode_end; }; // decoded [cq/qrz hiscall grid]
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_cq_call2_ooo,
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pcodec->apmsg_cq_call2);
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if (rc>=0) { rc = 10; goto decode_end; }; // decoded [cq/qrz hiscall ]
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}
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// attempt to decode [mycall hiscall grid]
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if (pcodec->apmsg_set[APTYPE_FULL]) {
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rc = qra64_do_decode(xdec, ix, pcodec->apmask_call1_call2_grid,
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pcodec->apmsg_call1_call2_grid);
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if (rc>=0) { rc = 8; goto decode_end; }; // decoded [mycall hiscall grid]
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}
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// all decoding attempts failed
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return rc;
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decode_end: // successfull decode
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// copy decoded message (without crc) to output buffer
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memcpy(x,xdec,QRA64_K*sizeof(int));
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if (ebno==0) // null pointer indicates we are not interested in the Eb/No estimate
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return rc;
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// reencode message and estimate Eb/No
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qra_encode(&QRA64_CODE, ydec, xdec);
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// puncture crc
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memmove(ydec+QRA64_K,ydec+QRA64_KC,QRA64_C*sizeof(int));
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// compute total power of decoded message
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msge = 0;
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for (k=0;k<QRA64_N;k++) {
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msge +=rxen[ydec[k]]; // add energy of current symbol
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rxen+=QRA64_M; // ptr to next symbol
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}
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// NOTE:
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// To make a more accurate Eb/No estimation we should compute the noise variance
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// on all the rxen values but the transmitted symbols.
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// Noisestd is compute by qra_mfskbesselmetric assuming that
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// the signal power is much less than the total noise power in the QRA64_M tones
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// but this is true only if the Eb/No is low.
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// Here, in order to improve accuracy, we linearize the estimated Eb/No value empirically
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// (it gets compressed when it is very high as in this case the noise variance
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// is overestimated)
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// this would be the exact value if the noisestd were not overestimated at high Eb/No
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ebnoval = (0.5f/(QRA64_K*QRA64_m))*msge/(noisestd*noisestd)-1.0f;
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// Empirical linearization (to remove the noise variance overestimation)
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// the resulting SNR is accurate up to +20 dB (51 dB Eb/No)
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if (ebnoval>57.004f)
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ebnoval=57.004f;
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ebnoval = ebnoval*57.03f/(57.03f-ebnoval);
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// compute value in dB
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if (ebnoval<=0)
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ebnoval = EBNO_MIN; // assume a minimum, positive value
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else
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ebnoval = 10.0f*(float)log10(ebnoval);
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if (ebnoval<EBNO_MIN)
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ebnoval = EBNO_MIN;
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*ebno = ebnoval;
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return rc;
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}
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// Static functions definitions ----------------------------------------------
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// Decode with given a-priori information
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static int qra64_do_decode(int *xdec, const float *pix, const int *ap_mask,
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const int *ap_x)
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{
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int rc;
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const float *ixsrc;
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float ix_masked[QRA64_NC*QRA64_M]; // Masked intrinsic information
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float ex[QRA64_NC*QRA64_M]; // Extrinsic information from the decoder
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float v2cmsg[QRA64_NMSG*QRA64_M]; // buffers for the decoder messages
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float c2vmsg[QRA64_NMSG*QRA64_M];
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if (ap_mask==NULL) { // no a-priori information
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ixsrc = pix; // intrinsic source is what passed as argument
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} else {
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// a-priori information provided
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// mask channel observations with a-priori
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ix_mask(ix_masked,pix,ap_mask,ap_x);
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ixsrc = ix_masked; // intrinsic source is the masked version
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}
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// run the decoding algorithm
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rc = qra_extrinsic(&QRA64_CODE,ex,ixsrc,QRA64_NITER,v2cmsg,c2vmsg);
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if (rc<0)
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return -1; // no convergence in given iterations
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// decode
|
|
qra_mapdecode(&QRA64_CODE,xdec,ex,ixsrc);
|
|
|
|
// verify crc
|
|
if (calc_crc6(xdec,QRA64_K)!=xdec[QRA64_K]) // crc doesn't match (detected error)
|
|
return -2; // decoding was succesfull but crc doesn't match
|
|
|
|
return 0;
|
|
}
|
|
// crc functions --------------------------------------------------------------
|
|
// crc-6 generator polynomial
|
|
// g(x) = x^6 + a5*x^5 + ... + a1*x + a0
|
|
|
|
// g(x) = x^6 + x + 1
|
|
#define CRC6_GEN_POL 0x30 // MSB=a0 LSB=a5
|
|
|
|
// g(x) = x^6 + x^2 + x + 1 (See: https://users.ece.cmu.edu/~koopman/crc/)
|
|
// #define CRC6_GEN_POL 0x38 // MSB=a0 LSB=a5. Simulation results are similar
|
|
|
|
static int calc_crc6(const int *x, int sz)
|
|
{
|
|
// todo: compute it faster using a look up table
|
|
int k,j,t,sr = 0;
|
|
for (k=0;k<sz;k++) {
|
|
t = x[k];
|
|
for (j=0;j<6;j++) {
|
|
if ((t^sr)&0x01)
|
|
sr = (sr>>1) ^ CRC6_GEN_POL;
|
|
else
|
|
sr = (sr>>1);
|
|
t>>=1;
|
|
}
|
|
}
|
|
return sr;
|
|
}
|
|
|
|
static void ix_mask(float *dst, const float *src, const int *mask,
|
|
const int *x)
|
|
{
|
|
// mask intrinsic information (channel observations) with a priori knowledge
|
|
|
|
int k,kk, smask;
|
|
float *row;
|
|
|
|
memcpy(dst,src,(QRA64_NC*QRA64_M)*sizeof(float));
|
|
|
|
for (k=0;k<QRA64_K;k++) { // we can mask only information symbols distrib
|
|
smask = mask[k];
|
|
row = PD_ROWADDR(dst,QRA64_M,k);
|
|
if (smask) {
|
|
for (kk=0;kk<QRA64_M;kk++)
|
|
if (((kk^x[k])&smask)!=0)
|
|
*(row+kk) = 0.f;
|
|
|
|
pd_norm(row,QRA64_m);
|
|
}
|
|
}
|
|
}
|
|
|
|
// encode/decode msgs as done in JT65
|
|
void encodemsg_jt65(int *y, const int call1, const int call2, const int grid)
|
|
{
|
|
y[0]= (call1>>22)&0x3F;
|
|
y[1]= (call1>>16)&0x3F;
|
|
y[2]= (call1>>10)&0x3F;
|
|
y[3]= (call1>>4)&0x3F;
|
|
y[4]= (call1<<2)&0x3F;
|
|
|
|
y[4] |= (call2>>26)&0x3F;
|
|
y[5]= (call2>>20)&0x3F;
|
|
y[6]= (call2>>14)&0x3F;
|
|
y[7]= (call2>>8)&0x3F;
|
|
y[8]= (call2>>2)&0x3F;
|
|
y[9]= (call2<<4)&0x3F;
|
|
|
|
y[9] |= (grid>>12)&0x3F;
|
|
y[10]= (grid>>6)&0x3F;
|
|
y[11]= (grid)&0x3F;
|
|
|
|
}
|
|
void decodemsg_jt65(int *call1, int *call2, int *grid, const int *x)
|
|
{
|
|
int nc1, nc2, ng;
|
|
|
|
nc1 = x[4]>>2;
|
|
nc1 |= x[3]<<4;
|
|
nc1 |= x[2]<<10;
|
|
nc1 |= x[1]<<16;
|
|
nc1 |= x[0]<<22;
|
|
|
|
nc2 = x[9]>>4;
|
|
nc2 |= x[8]<<2;
|
|
nc2 |= x[7]<<8;
|
|
nc2 |= x[6]<<14;
|
|
nc2 |= x[5]<<20;
|
|
nc2 |= (x[4]&0x03)<<26;
|
|
|
|
ng = x[11];
|
|
ng |= x[10]<<6;
|
|
ng |= (x[9]&0x0F)<<12;
|
|
|
|
*call1 = nc1;
|
|
*call2 = nc2;
|
|
*grid = ng;
|
|
}
|