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/*
* Copyright ( C ) 2014 Jared Boone , ShareBrained Technology , Inc .
* Copyright ( C ) 2017 Furrtek
*
* This file is part of PortaPack .
*
* This program is free software ; you can redistribute it and / or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation ; either version 2 , or ( at your option )
* any later version .
*
* This program is distributed in the hope that it will be useful ,
* but WITHOUT ANY WARRANTY ; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
* GNU General Public License for more details .
*
* You should have received a copy of the GNU General Public License
* along with this program ; see the file COPYING . If not , write to
* the Free Software Foundation , Inc . , 51 Franklin Street ,
* Boston , MA 02110 - 1301 , USA .
*/
# include "proc_siggen.hpp"
# include "portapack_shared_memory.hpp"
# include "sine_table_int8.hpp"
# include "event_m4.hpp"
# include <cstdint>
void SigGenProcessor : : execute ( const buffer_c8_t & buffer ) {
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if ( ! configured ) return ;
for ( size_t i = 0 ; i < buffer . count ; i + + ) {
if ( ! sample_count & & auto_off ) {
configured = false ;
txprogress_message . done = true ;
shared_memory . application_queue . push ( txprogress_message ) ;
} else
sample_count - - ;
if ( tone_shape = = 0 ) {
// CW
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re = 127 ; // max. signed 8 bits value . (-128 ...+127), max. amplitude , static phasor at 0º
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im = 0 ;
} else {
if ( tone_shape = = 1 ) {
// Sine
sample = ( sine_table_i8 [ ( tone_phase & 0xFF000000 ) > > 24 ] ) ;
} else if ( tone_shape = = 2 ) {
// Triangle
int8_t a = ( tone_phase & 0xFF000000 ) > > 24 ;
sample = ( a & 0x80 ) ? ( ( a < < 1 ) ^ 0xFF ) - 0x80 : ( a < < 1 ) + 0x80 ;
} else if ( tone_shape = = 3 ) {
// Saw up
sample = ( ( tone_phase & 0xFF000000 ) > > 24 ) ;
} else if ( tone_shape = = 4 ) {
// Saw down
sample = ( ( tone_phase & 0xFF000000 ) > > 24 ) ^ 0xFF ;
} else if ( tone_shape = = 5 ) {
// Square
sample = ( ( ( tone_phase & 0xFF000000 ) > > 24 ) & 0x80 ) ? 127 : - 128 ;
} else if ( tone_shape = = 6 ) {
// Noise generator, pseudo random noise generator, 16 bits linear-feedback shift register (LFSR) algorithm, variant Fibonacci.
// https://en.wikipedia.org/wiki/Linear-feedback_shift_register
// 16 bits LFSR .taps: 16, 15, 13, 4 ;feedback polynomial: x^16 + x^15 + x^13 + x^4 + 1
// Periode 65535= 2^n-1, quite continuous .
if ( counter = = 0 ) { // we slow down the shift register, because the pseudo random noise clock freq was too high for modulator.
bit_16 = ( ( lfsr_16 > > 0 ) ^ ( lfsr_16 > > 1 ) ^ ( lfsr_16 > > 3 ) ^ ( lfsr_16 > > 4 ) ^ ( ( lfsr_16 > > 12 ) & 1 ) ) ;
lfsr_16 = ( lfsr_16 > > 1 ) | ( bit_16 < < 15 ) ;
sample = ( lfsr_16 & 0x00FF ) ; // main pseudo random noise generator.
}
if ( counter = = 5 ) { // after many empiric test, that combination mix of >>4 and >>5, gives a reasonable trade off white noise / good rf power level .
sample = ( ( lfsr_16 & 0b0000111111110000 ) > > 4 ) ; // just changing the spectrum shape .
}
if ( counter = = 10 ) {
sample = ( ( lfsr_16 & 0b0001111111100000 ) > > 5 ) ; // just changing the spectrum shape .
}
counter + + ;
if ( counter = = 15 ) {
counter = 0 ;
}
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} else if ( tone_shape = = 7 ) {
// Digital BPSK consecutive 0,1,0,...continuous cycle, 1 bit/symbol, at rate of 2 symbols / Freq Tone Periode... without any Pulse shape at the moment .
re = ( ( ( tone_phase & 0xFF000000 ) > > 24 ) & 0x80 ) ? 127 : - 128 ; // Sending 2 bits by Periode T of the GUI tone, alternative static phasor to 0, -180º , 0º
im = 0 ;
} else if ( tone_shape = = 8 ) {
// Digital QPSK consecutive 00, 01, 10, 11,00, ...continuous cycle ,2 bits/symbol, at rate of 4 symbols / Freq Tone Periode. not random., without any Pulse shape at the moment .
switch ( ( ( tone_phase & 0xFF000000 ) > > 24 ) ) {
case 0 . . . 63 : // equivalent to 1/4 of total 360º degrees.
/* "00" */
re = ( sine_table_i8 [ 32 ] ) ; // we are sending symbol-phasor 45º during 1/4 of the total periode
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im = ( sine_table_i8 [ 32 + 64 ] ) ; // 32 index = rounded (45º/360º * 255 total sin table steps) = 31,875
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break ;
case 64 . . . 127 :
/* "01" */
re = ( sine_table_i8 [ 96 ] ) ; // symbol-phasor 135º
im = ( sine_table_i8 [ 96 + 64 ] ) ; // 96 index = 32 + 256/4
break ;
break ;
case 128 . . . 191 :
/* "10" */
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re = ( sine_table_i8 [ 159 ] ) ; // symbol-phasor 225º
im = ( sine_table_i8 [ 159 + 64 ] ) ; // 159 rounded index = 96 + 256/4 = 159.3
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break ;
case 192 . . . 255 :
/* "11" */
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re = ( sine_table_i8 [ 223 ] ) ; // symbol-phasor 315º ; 223 rounded index = (315/360) * 255 =223.125
im = ( sine_table_i8 [ ( ( 223 + 64 ) & 0xFF ) ] ) ; // Max index 255, circular periodic conversion.
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break ;
default :
break ;
}
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}
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if ( tone_shape ! = 6 ) { //(all except Pseudo Random White Noise). We are in (1):periodic signals or (2):BPSK/QPSK , in both cases ,we need Tone updated acum sum phases to modulate in FM / or control phasor phase (BPSK & QPSK.)
tone_phase + = tone_delta ; // In periodic signals(Sine/triangle/square) we are using to FM mod. in BPSK-QSPK we are using to calculate each 1/4 of the periode.
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}
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if ( tone_shape < 7 ) { // All Option shape signals except BPSK(7) & QPSK(8) we are modulating in FM. (Those two has phase shift modulation XPSK , not FM )
// Do FM modulation
delta = sample * fm_delta ;
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phase + = delta ;
sphase = phase + ( 64 < < 24 ) ;
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re = ( sine_table_i8 [ ( sphase & 0xFF000000 ) > > 24 ] ) ; // sin LUT is not dealing with decimals , output range [-128 ,...127]
im = ( sine_table_i8 [ ( phase & 0xFF000000 ) > > 24 ] ) ;
}
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}
buffer . p [ i ] = { re , im } ;
}
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} ;
void SigGenProcessor : : on_message ( const Message * const msg ) {
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const auto message = * reinterpret_cast < const SigGenConfigMessage * > ( msg ) ;
switch ( msg - > id ) {
case Message : : ID : : SigGenConfig :
if ( ! message . bw ) {
configured = false ;
return ;
}
if ( message . duration ) {
sample_count = message . duration ;
auto_off = true ;
} else
auto_off = false ;
fm_delta = message . bw * ( 0xFFFFFFULL / 1536000 ) ;
tone_shape = message . shape ;
// lfsr = seed_value ; // Finally not used , init lfsr 8 bits.
lfsr_16 = seed_value_16 ; // init lfsr 16 bits.
configured = true ;
break ;
case Message : : ID : : SigGenTone :
tone_delta = reinterpret_cast < const SigGenToneMessage * > ( msg ) - > tone_delta ;
break ;
default :
break ;
}
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}
int main ( ) {
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EventDispatcher event_dispatcher { std : : make_unique < SigGenProcessor > ( ) } ;
event_dispatcher . run ( ) ;
return 0 ;
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}