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///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2019 Edouard Griffiths, F4EXB //
// Copyright (C) 2020 Jon Beniston, M7RCE //
// //
// 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 as version 3 of the License, 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 V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see <http://www.gnu.org/licenses/>. //
///////////////////////////////////////////////////////////////////////////////////
# include <cctype>
# include <QDebug>
# include "dsp/basebandsamplesink.h"
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# include "dsp/datafifo.h"
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# include "packetmodsource.h"
# include "util/crc.h"
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# include "util/messagequeue.h"
# include "maincore.h"
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# include "channel/channelapi.h"
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PacketModSource : : PacketModSource ( ) :
m_channelSampleRate ( 48000 ) ,
m_channelFrequencyOffset ( 0 ) ,
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m_spectrumRate ( 0 ) ,
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m_audioPhase ( 0.0f ) ,
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m_fmPhase ( 0.0 ) ,
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m_preemphasisFilter ( 48000 , FMPREEMPHASIS_TAU_US ) ,
m_spectrumSink ( nullptr ) ,
m_magsq ( 0.0 ) ,
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m_levelCalcCount ( 0 ) ,
m_peakLevel ( 0.0f ) ,
m_levelSum ( 0.0f ) ,
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m_state ( idle ) ,
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m_byteIdx ( 0 ) ,
m_bitIdx ( 0 ) ,
m_last5Bits ( 0 ) ,
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m_bitCount ( 0 ) ,
m_scrambler ( 0x10800 , 0x0 )
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{
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m_lowpass . create ( 301 , m_channelSampleRate , 22000.0 / 2.0 ) ;
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qDebug ( ) < < " PacketModSource::PacketModSource creating BPF : " < < m_channelSampleRate ;
m_bandpass . create ( 301 , m_channelSampleRate , 800.0 , 2600.0 ) ;
m_pulseShape . create ( 0.5 , 6 , m_channelSampleRate / 9600 ) ;
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m_demodBuffer . resize ( 1 < < 12 ) ;
m_demodBufferFill = 0 ;
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applySettings ( m_settings , true ) ;
applyChannelSettings ( m_channelSampleRate , m_channelFrequencyOffset , true ) ;
}
PacketModSource : : ~ PacketModSource ( )
{
}
void PacketModSource : : pull ( SampleVector : : iterator begin , unsigned int nbSamples )
{
std : : for_each (
begin ,
begin + nbSamples ,
[ this ] ( Sample & s ) {
pullOne ( s ) ;
}
) ;
}
void PacketModSource : : pullOne ( Sample & sample )
{
if ( m_settings . m_channelMute )
{
sample . m_real = 0.0f ;
sample . m_imag = 0.0f ;
return ;
}
// Calculate next sample
modulateSample ( ) ;
// Shift to carrier frequency
Complex ci = m_modSample ;
ci * = m_carrierNco . nextIQ ( ) ;
// Calculate power
double magsq = ci . real ( ) * ci . real ( ) + ci . imag ( ) * ci . imag ( ) ;
m_movingAverage ( magsq ) ;
m_magsq = m_movingAverage . asDouble ( ) ;
// Convert from float to fixed point
sample . m_real = ( FixReal ) ( ci . real ( ) * SDR_TX_SCALEF ) ;
sample . m_imag = ( FixReal ) ( ci . imag ( ) * SDR_TX_SCALEF ) ;
}
void PacketModSource : : sampleToSpectrum ( Real sample )
{
if ( m_spectrumSink )
{
Complex out ;
Complex in ;
in . real ( sample ) ;
in . imag ( 0.0f ) ;
if ( m_interpolator . decimate ( & m_interpolatorDistanceRemain , in , & out ) )
{
sample = std : : real ( out ) ;
m_sampleBuffer . push_back ( Sample ( sample * 0.891235351562f * SDR_TX_SCALEF , 0.0f ) ) ;
m_spectrumSink - > feed ( m_sampleBuffer . begin ( ) , m_sampleBuffer . end ( ) , true ) ;
m_sampleBuffer . clear ( ) ;
m_interpolatorDistanceRemain + = m_interpolatorDistance ;
}
}
}
void PacketModSource : : modulateSample ( )
{
Real audioMod ;
Real linearRampGain ;
if ( ( m_state = = idle ) | | ( m_state = = wait ) )
{
audioMod = 0.0f ;
m_modSample . real ( audioMod ) ;
m_modSample . imag ( 0 ) ;
calculateLevel ( audioMod ) ;
sampleToSpectrum ( audioMod ) ;
if ( m_state = = wait )
{
m_waitCounter - - ;
if ( m_waitCounter = = 0 )
initTX ( ) ;
}
}
else
{
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if ( m_sampleIdx = = 0 )
{
if ( bitsValid ( ) )
{
// NRZI encoding - encode 0 as change of freq, 1 no change
if ( getBit ( ) = = 0 )
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m_nrziBit = m_nrziBit = = 1 ? 0 : 1 ;
// Scramble to ensure lots of transitions
if ( m_settings . m_scramble )
m_scrambledBit = m_scrambler . scramble ( m_nrziBit ) ;
else
m_scrambledBit = m_nrziBit ;
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}
// Should we start ramping down power?
if ( ( m_bitCount < m_settings . m_rampDownBits ) | | ( ( m_bitCount = = 0 ) & & ! m_settings . m_rampDownBits ) )
{
m_state = ramp_down ;
if ( m_settings . m_rampDownBits > 0 )
m_powRamp = - m_settings . m_rampRange / ( m_settings . m_rampDownBits * ( Real ) m_samplesPerSymbol ) ;
}
}
m_sampleIdx + + ;
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if ( m_sampleIdx > = m_samplesPerSymbol )
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m_sampleIdx = 0 ;
if ( ! m_settings . m_bbNoise )
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{
if ( m_settings . m_modulation = = PacketModSettings : : AFSK )
{
// Bell 202 AFSK
audioMod = sin ( m_audioPhase ) ;
if ( ( m_state = = tx ) | | m_settings . m_modulateWhileRamping )
m_audioPhase + = ( M_PI * 2.0f * ( m_scrambledBit ? m_settings . m_markFrequency : m_settings . m_spaceFrequency ) ) / ( m_channelSampleRate ) ;
if ( m_audioPhase > M_PI )
m_audioPhase - = ( 2.0f * M_PI ) ;
}
else
{
// FSK
if ( m_settings . m_pulseShaping )
{
if ( ( m_sampleIdx = = 1 ) & & ( m_state ! = ramp_down ) )
audioMod = m_pulseShape . filter ( m_scrambledBit ? 1.0f : - 1.0f ) ;
else
audioMod = m_pulseShape . filter ( 0.0f ) ;
}
else
audioMod = m_scrambledBit ? 1.0f : - 1.0f ;
}
}
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else
audioMod = ( Real ) rand ( ) / ( ( Real ) RAND_MAX ) - 0.5 ; // Noise to test filter frequency response
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// Baseband bandpass filter
if ( m_settings . m_bpf )
audioMod = m_bandpass . filter ( audioMod ) ;
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// Preemphasis filter
if ( m_settings . m_preEmphasis )
audioMod = m_preemphasisFilter . filter ( audioMod ) ;
if ( m_audioFile . is_open ( ) )
m_audioFile < < audioMod < < " \n " ;
// Display baseband audio in spectrum analyser
sampleToSpectrum ( audioMod ) ;
// FM
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m_fmPhase + = m_phaseSensitivity * audioMod ;
// Keep phase in range -pi,pi
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if ( m_fmPhase > M_PI )
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m_fmPhase - = 2.0f * M_PI ;
else if ( m_fmPhase < - M_PI )
m_fmPhase + = 2.0f * M_PI ;
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linearRampGain = powf ( 10.0f , m_pow / 20.0f ) ;
if ( ! m_settings . m_rfNoise )
{
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m_modSample . real ( m_linearGain * linearRampGain * cos ( m_fmPhase ) ) ;
m_modSample . imag ( m_linearGain * linearRampGain * sin ( m_fmPhase ) ) ;
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}
else
{
// Noise to test filter frequency response
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m_modSample . real ( m_linearGain * ( ( Real ) rand ( ) / ( ( Real ) RAND_MAX ) - 0.5f ) ) ;
m_modSample . imag ( m_linearGain * ( ( Real ) rand ( ) / ( ( Real ) RAND_MAX ) - 0.5f ) ) ;
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}
// Apply low pass filter to limit RF BW
m_modSample = m_lowpass . filter ( m_modSample ) ;
// Ramp up/down power at start/end of packet
if ( ( m_state = = ramp_up ) | | ( m_state = = ramp_down ) )
{
m_pow + = m_powRamp ;
if ( ( m_state = = ramp_up ) & & ( m_pow > = 0.0f ) )
{
// Finished ramp up, transmit at full gain
m_state = tx ;
m_pow = 0.0f ;
}
else if ( ( m_state = = ramp_down ) & & ( ( m_settings . m_rampRange = = 0 )
| | ( m_settings . m_rampDownBits = = 0 )
| | ( m_pow < = - ( Real ) m_settings . m_rampRange )
) )
{
m_state = idle ;
// Do we need to retransmit the packet?
if ( m_settings . m_repeat )
{
if ( m_packetRepeatCount > 0 )
m_packetRepeatCount - - ;
if ( ( m_packetRepeatCount = = PacketModSettings : : infinitePackets ) | | ( m_packetRepeatCount > 0 ) )
{
if ( m_settings . m_repeatDelay > 0.0f )
{
// Wait before retransmitting
m_state = wait ;
m_waitCounter = m_settings . m_repeatDelay * m_channelSampleRate ;
}
else
{
// Retransmit immediately
initTX ( ) ;
}
}
}
}
}
Real s = std : : real ( m_modSample ) ;
calculateLevel ( s ) ;
}
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m_demodBuffer [ m_demodBufferFill ] = audioMod * std : : numeric_limits < int16_t > : : max ( ) ;
+ + m_demodBufferFill ;
if ( m_demodBufferFill > = m_demodBuffer . size ( ) )
{
QList < DataFifo * > * dataFifos = MainCore : : instance ( ) - > getDataPipes ( ) . getFifos ( m_channel , " demod " ) ;
if ( dataFifos )
{
QList < DataFifo * > : : iterator it = dataFifos - > begin ( ) ;
for ( ; it ! = dataFifos - > end ( ) ; + + it ) {
( * it ) - > write ( ( quint8 * ) & m_demodBuffer [ 0 ] , m_demodBuffer . size ( ) * sizeof ( qint16 ) ) ;
}
}
m_demodBufferFill = 0 ;
}
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}
void PacketModSource : : calculateLevel ( Real & sample )
{
if ( m_levelCalcCount < m_levelNbSamples )
{
m_peakLevel = std : : max ( std : : fabs ( m_peakLevel ) , sample ) ;
m_levelSum + = sample * sample ;
m_levelCalcCount + + ;
}
else
{
m_rmsLevel = sqrt ( m_levelSum / m_levelNbSamples ) ;
m_peakLevelOut = m_peakLevel ;
m_peakLevel = 0.0f ;
m_levelSum = 0.0f ;
m_levelCalcCount = 0 ;
}
}
void PacketModSource : : applySettings ( const PacketModSettings & settings , bool force )
{
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// Only recreate filters if settings have changed
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if ( ( settings . m_lpfTaps ! = m_settings . m_lpfTaps ) | | ( settings . m_rfBandwidth ! = m_settings . m_rfBandwidth ) | | force )
{
qDebug ( ) < < " PacketModSource::applySettings: Creating new lpf with taps " < < settings . m_lpfTaps < < " rfBW " < < settings . m_rfBandwidth ;
m_lowpass . create ( settings . m_lpfTaps , m_channelSampleRate , settings . m_rfBandwidth / 2.0 ) ;
}
if ( ( settings . m_preEmphasisTau ! = m_settings . m_preEmphasisTau ) | | ( settings . m_preEmphasisHighFreq ! = m_settings . m_preEmphasisHighFreq ) | | force )
{
qDebug ( ) < < " PacketModSource::applySettings: Creating new preemphasis filter with tau " < < settings . m_preEmphasisTau < < " highFreq " < < settings . m_preEmphasisHighFreq < < " sampleRate " < < m_channelSampleRate ;
m_preemphasisFilter . configure ( m_channelSampleRate , settings . m_preEmphasisTau , settings . m_preEmphasisHighFreq ) ;
}
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if ( ( settings . m_bpfLowCutoff ! = m_settings . m_bpfLowCutoff ) | | ( settings . m_bpfHighCutoff ! = m_settings . m_bpfHighCutoff )
| | ( settings . m_bpfTaps ! = m_settings . m_bpfTaps ) | | force )
{
qDebug ( ) < < " PacketModSource::applySettings: Recreating bandpass filter: "
< < " m_bpfTaps: " < < settings . m_bpfTaps
< < " m_channelSampleRate: " < < m_channelSampleRate
< < " m_bpfLowCutoff: " < < settings . m_bpfLowCutoff
< < " m_bpfHighCutoff: " < < settings . m_bpfHighCutoff ;
m_bandpass . create ( settings . m_bpfTaps , m_channelSampleRate , settings . m_bpfLowCutoff , settings . m_bpfHighCutoff ) ;
}
if ( ( settings . m_beta ! = m_settings . m_beta ) | | ( settings . m_symbolSpan ! = m_settings . m_symbolSpan ) | | ( settings . m_baud ! = m_settings . m_baud ) | | force )
{
qDebug ( ) < < " PacketModSource::applySettings: Recreating pulse shaping filter: "
< < " beta: " < < settings . m_beta
< < " symbolSpan: " < < settings . m_symbolSpan
< < " channelSampleRate: " < < m_channelSampleRate
< < " baud: " < < settings . m_baud ;
m_pulseShape . create ( settings . m_beta , m_settings . m_symbolSpan , m_channelSampleRate / settings . m_baud ) ;
}
if ( ( settings . m_polynomial ! = m_settings . m_polynomial ) | | force )
m_scrambler . setPolynomial ( settings . m_polynomial ) ;
if ( ( settings . m_spectrumRate ! = m_settings . m_spectrumRate ) | | force )
{
m_interpolatorDistanceRemain = 0 ;
m_interpolatorConsumed = false ;
m_interpolatorDistance = ( Real ) m_channelSampleRate / ( Real ) settings . m_spectrumRate ;
m_interpolator . create ( 48 , settings . m_spectrumRate , settings . m_spectrumRate / 2.2 , 3.0 ) ;
}
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m_settings = settings ;
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// Precalculate FM sensensity and linear gain to save doing it in the loop
m_phaseSensitivity = 2.0f * M_PI * m_settings . m_fmDeviation / ( double ) m_channelSampleRate ;
m_linearGain = powf ( 10.0f , m_settings . m_gain / 20.0f ) ;
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}
void PacketModSource : : applyChannelSettings ( int channelSampleRate , int channelFrequencyOffset , bool force )
{
qDebug ( ) < < " PacketModSource::applyChannelSettings: "
< < " channelSampleRate: " < < channelSampleRate
< < " channelFrequencyOffset: " < < channelFrequencyOffset
< < " rfBandwidth: " < < m_settings . m_rfBandwidth
< < " spectrumRate: " < < m_settings . m_spectrumRate ;
if ( ( channelFrequencyOffset ! = m_channelFrequencyOffset )
| | ( channelSampleRate ! = m_channelSampleRate ) | | force )
{
m_carrierNco . setFreq ( channelFrequencyOffset , channelSampleRate ) ;
}
if ( ( m_channelSampleRate ! = channelSampleRate ) | | force )
{
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qDebug ( ) < < " PacketModSource::applyChannelSettings: Recreating filters " ;
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m_lowpass . create ( m_settings . m_lpfTaps , channelSampleRate , m_settings . m_rfBandwidth / 2.0 ) ;
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qDebug ( ) < < " PacketModSource::applyChannelSettings: Recreating bandpass filter: "
< < " bpfTaps: " < < m_settings . m_bpfTaps
< < " channelSampleRate: " < < channelSampleRate
< < " bpfLowCutoff: " < < m_settings . m_bpfLowCutoff
< < " bpfHighCutoff: " < < m_settings . m_bpfHighCutoff ;
m_bandpass . create ( m_settings . m_bpfTaps , channelSampleRate , m_settings . m_bpfLowCutoff , m_settings . m_bpfHighCutoff ) ;
m_preemphasisFilter . configure ( channelSampleRate , m_settings . m_preEmphasisTau ) ;
qDebug ( ) < < " PacketModSource::applyChannelSettings: Recreating pulse shaping filter: "
< < " beta: " < < m_settings . m_beta
< < " symbolSpan: " < < m_settings . m_symbolSpan
< < " channelSampleRate: " < < m_channelSampleRate
< < " baud: " < < m_settings . m_baud ;
m_pulseShape . create ( m_settings . m_beta , m_settings . m_symbolSpan , channelSampleRate / m_settings . m_baud ) ;
}
if ( ( m_channelSampleRate ! = channelSampleRate ) | | ( m_spectrumRate ! = m_settings . m_spectrumRate ) | | force )
{
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m_interpolatorDistanceRemain = 0 ;
m_interpolatorConsumed = false ;
m_interpolatorDistance = ( Real ) channelSampleRate / ( Real ) m_settings . m_spectrumRate ;
m_interpolator . create ( 48 , m_settings . m_spectrumRate , m_settings . m_spectrumRate / 2.2 , 3.0 ) ;
}
m_channelSampleRate = channelSampleRate ;
m_channelFrequencyOffset = channelFrequencyOffset ;
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m_spectrumRate = m_settings . m_spectrumRate ;
m_samplesPerSymbol = m_channelSampleRate / m_settings . m_baud ;
qDebug ( ) < < " m_samplesPerSymbol: " < < m_samplesPerSymbol < < " ( " < < m_channelSampleRate < < " / " < < m_settings . m_baud < < " ) " ;
// Precalculate FM sensensity to save doing it in the loop
m_phaseSensitivity = 2.0f * M_PI * m_settings . m_fmDeviation / ( double ) m_channelSampleRate ;
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QList < MessageQueue * > * messageQueues = MainCore : : instance ( ) - > getMessagePipes ( ) . getMessageQueues ( m_channel , " reportdemod " ) ;
if ( messageQueues )
{
QList < MessageQueue * > : : iterator it = messageQueues - > begin ( ) ;
for ( ; it ! = messageQueues - > end ( ) ; + + it )
{
MainCore : : MsgChannelDemodReport * msg = MainCore : : MsgChannelDemodReport : : create ( m_channel , m_channelSampleRate ) ;
( * it ) - > push ( msg ) ;
}
}
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}
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static bool ax25_ssid ( QByteArray & b , int i , int len , uint8_t & ssid )
{
if ( b [ i ] = = ' - ' )
{
if ( len > i + 1 )
{
ssid = b [ i + 1 ] - ' 0 ' ;
if ( ( len > i + 2 ) & & isdigit ( b [ i + 2 ] ) ) {
ssid = ( ssid * 10 ) + ( b [ i + 2 ] - ' 0 ' ) ;
}
if ( ssid > = 16 )
{
qDebug ( ) < < " ax25_address: SSID greater than 15 not supported " ;
ssid = ssid & 0xf ;
return false ;
}
else
{
return true ;
}
}
else
{
qDebug ( ) < < " ax25_address: SSID number missing " ;
return false ;
}
}
else
return false ;
}
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static uint8_t * ax25_address ( uint8_t * p , QString address , uint8_t crrl )
{
int len ;
int i ;
QByteArray b ;
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uint8_t ssid = 0 ;
bool hyphenSeen = false ;
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len = address . length ( ) ;
b = address . toUtf8 ( ) ;
ssid = 0 ;
for ( i = 0 ; i < 6 ; i + + )
{
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if ( ( i < len ) & & ! hyphenSeen )
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{
if ( b [ i ] = = ' - ' )
{
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ax25_ssid ( b , i , len , ssid ) ;
hyphenSeen = true ;
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* p + + = ' ' < < 1 ;
}
else
{
* p + + = b [ i ] < < 1 ;
}
}
else
{
* p + + = ' ' < < 1 ;
}
}
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if ( b [ i ] = = ' - ' )
{
ax25_ssid ( b , i , len , ssid ) ;
}
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* p + + = crrl | ( ssid < < 1 ) ;
return p ;
}
bool PacketModSource : : bitsValid ( )
{
return m_bitCount > 0 ;
}
int PacketModSource : : getBit ( )
{
int bit ;
if ( m_bitCount > 0 )
{
bit = ( m_bits [ m_byteIdx ] > > m_bitIdx ) & 1 ;
m_bitIdx + + ;
m_bitCount - - ;
if ( m_bitIdx = = 8 )
{
m_byteIdx + + ;
m_bitIdx = 0 ;
}
}
else
bit = 0 ;
return bit ;
}
void PacketModSource : : addBit ( int bit )
{
// Transmit LSB first
m_bits [ m_byteIdx ] | = bit < < m_bitIdx ;
m_bitIdx + + ;
m_bitCount + + ;
m_bitCountTotal + + ;
if ( m_bitIdx = = 8 )
{
m_byteIdx + + ;
m_bits [ m_byteIdx ] = 0 ;
m_bitIdx = 0 ;
}
m_last5Bits = ( ( m_last5Bits < < 1 ) | bit ) & 0x1f ;
}
void PacketModSource : : initTX ( )
{
m_byteIdx = 0 ;
m_bitIdx = 0 ;
m_bitCount = m_bitCountTotal ; // Reset to allow retransmission
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m_nrziBit = 0 ;
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if ( m_settings . m_rampUpBits = = 0 )
{
m_state = tx ;
m_pow = 0.0f ;
}
else
{
m_state = ramp_up ;
m_pow = - ( Real ) m_settings . m_rampRange ;
m_powRamp = m_settings . m_rampRange / ( m_settings . m_rampUpBits * ( Real ) m_samplesPerSymbol ) ;
}
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m_scrambler . init ( ) ;
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}
void PacketModSource : : addTXPacket ( QString callsign , QString to , QString via , QString data )
{
uint8_t packet [ AX25_MAX_BYTES ] ;
uint8_t * crc_start ;
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uint8_t * packet_end ;
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uint8_t * p ;
crc16x25 crc ;
uint16_t crcValue ;
int len ;
int packet_length ;
// Create AX.25 packet
p = packet ;
// Flag
for ( int i = 0 ; i < std : : min ( m_settings . m_ax25PreFlags , AX25_MAX_FLAGS ) ; i + + )
* p + + = AX25_FLAG ;
crc_start = p ;
// Dest
p = ax25_address ( p , to , 0xe0 ) ;
// From
p = ax25_address ( p , callsign , 0x60 ) ;
// Via
p = ax25_address ( p , via , 0x61 ) ;
// Control
* p + + = m_settings . m_ax25Control ;
// PID
* p + + = m_settings . m_ax25PID ;
// Data
len = data . length ( ) ;
memcpy ( p , data . toUtf8 ( ) , len ) ;
p + = len ;
// CRC (do not include flags)
crc . calculate ( crc_start , p - crc_start ) ;
crcValue = crc . get ( ) ;
* p + + = crcValue & 0xff ;
* p + + = ( crcValue > > 8 ) ;
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packet_end = p ;
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// Flag
for ( int i = 0 ; i < std : : min ( m_settings . m_ax25PostFlags , AX25_MAX_FLAGS ) ; i + + )
* p + + = AX25_FLAG ;
packet_length = p - & packet [ 0 ] ;
// HDLC bit stuffing
m_byteIdx = 0 ;
m_bitIdx = 0 ;
m_last5Bits = 0 ;
m_bitCount = 0 ;
m_bitCountTotal = 0 ;
for ( int i = 0 ; i < packet_length ; i + + )
{
for ( int j = 0 ; j < 8 ; j + + )
{
int tx_bit = ( packet [ i ] > > j ) & 1 ;
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// Stuff 0 if last 5 bits are 1s, unless transmitting flag
// Except for special case of when last 5 bits of CRC are 1s
if ( ( ( packet [ i ] ! = AX25_FLAG )
| | ( ( & packet [ i ] > = crc_start )
& & ( ( & packet [ i ] < packet_end )
| | ( ( & packet [ i ] = = packet_end ) & & ( j = = 0 ) )
)
)
)
& & ( m_last5Bits = = 0x1f )
)
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addBit ( 0 ) ;
addBit ( tx_bit ) ;
}
}
m_samplesPerSymbol = m_channelSampleRate / m_settings . m_baud ;
m_packetRepeatCount = m_settings . m_repeatCount ;
initTX ( ) ;
// Only reset phases at start of new packet TX, not in initTX(), so that
// there isn't a discontinuity in phase when repeatedly transmitting a
// single tone
m_sampleIdx = 0 ;
m_audioPhase = 0.0f ;
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m_fmPhase = 0.0 ;
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if ( m_settings . m_writeToFile )
m_audioFile . open ( " packetmod.csv " , std : : ofstream : : out ) ;
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else if ( m_audioFile . is_open ( ) )
m_audioFile . close ( ) ;
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}