B3M38SPD seminar project - beehive monitor with LoRa reporting
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/*
/ _____) _ | |
( (____ _____ ____ _| |_ _____ ____| |__
\____ \| ___ | (_ _) ___ |/ ___) _ \
_____) ) ____| | | || |_| ____( (___| | | |
(______/|_____)_|_|_| \__)_____)\____)_| |_|
(C)2013 Semtech
___ _____ _ ___ _ _____ ___ ___ ___ ___
/ __|_ _/_\ / __| |/ / __/ _ \| _ \/ __| __|
\__ \ | |/ _ \ (__| ' <| _| (_) | / (__| _|
|___/ |_/_/ \_\___|_|\_\_| \___/|_|_\\___|___|
embedded.connectivity.solutions===============
Description: LoRa MAC region AU915 implementation
License: Revised BSD License, see LICENSE.TXT file include in the project
Maintainer: Miguel Luis ( Semtech ), Gregory Cristian ( Semtech ) and Daniel Jaeckle ( STACKFORCE )
*/
#include <stdbool.h>
#include <string.h>
#include <stdint.h>
#include <math.h>
#include "radio.h"
#include "timer.h"
#include "LoRaMac.h"
#include "utilities.h"
#include "Region.h"
#include "RegionCommon.h"
#include "RegionAU915.h"
#include "debug.h"
// Definitions
#define CHANNELS_MASK_SIZE 6
// Global attributes
/*!
* LoRaMAC channels
*/
static ChannelParams_t Channels[AU915_MAX_NB_CHANNELS];
/*!
* LoRaMac bands
*/
static Band_t Bands[AU915_MAX_NB_BANDS] =
{
AU915_BAND0
};
/*!
* LoRaMac channels mask
*/
static uint16_t ChannelsMask[CHANNELS_MASK_SIZE];
/*!
* LoRaMac channels remaining
*/
static uint16_t ChannelsMaskRemaining[CHANNELS_MASK_SIZE];
/*!
* LoRaMac channels default mask
*/
static uint16_t ChannelsDefaultMask[CHANNELS_MASK_SIZE];
// Static functions
static int8_t GetNextLowerTxDr( int8_t dr, int8_t minDr )
{
uint8_t nextLowerDr = 0;
if( dr == minDr )
{
nextLowerDr = minDr;
}
else
{
nextLowerDr = dr - 1;
}
return nextLowerDr;
}
static uint32_t GetBandwidth( uint32_t drIndex )
{
switch( BandwidthsAU915[drIndex] )
{
default:
case 125000:
return 0;
case 250000:
return 1;
case 500000:
return 2;
}
}
static int8_t LimitTxPower( int8_t txPower, int8_t maxBandTxPower, int8_t datarate, uint16_t* channelsMask )
{
int8_t txPowerResult = txPower;
// Limit tx power to the band max
txPowerResult = MAX( txPower, maxBandTxPower );
return txPowerResult;
}
static uint8_t CountNbOfEnabledChannels( uint8_t datarate, uint16_t* channelsMask, ChannelParams_t* channels, Band_t* bands, uint8_t* enabledChannels, uint8_t* delayTx )
{
uint8_t nbEnabledChannels = 0;
uint8_t delayTransmission = 0;
for( uint8_t i = 0, k = 0; i < AU915_MAX_NB_CHANNELS; i += 16, k++ )
{
for( uint8_t j = 0; j < 16; j++ )
{
if( ( channelsMask[k] & ( 1 << j ) ) != 0 )
{
if( channels[i + j].Frequency == 0 )
{ // Check if the channel is enabled
continue;
}
if( RegionCommonValueInRange( datarate, channels[i + j].DrRange.Fields.Min,
channels[i + j].DrRange.Fields.Max ) == false )
{ // Check if the current channel selection supports the given datarate
continue;
}
if( bands[channels[i + j].Band].TimeOff > 0 )
{ // Check if the band is available for transmission
delayTransmission++;
continue;
}
enabledChannels[nbEnabledChannels++] = i + j;
}
}
}
*delayTx = delayTransmission;
return nbEnabledChannels;
}
PhyParam_t RegionAU915GetPhyParam( GetPhyParams_t* getPhy )
{
PhyParam_t phyParam = { 0 };
switch( getPhy->Attribute )
{
case PHY_MIN_RX_DR:
{
phyParam.Value = AU915_RX_MIN_DATARATE;
break;
}
case PHY_MIN_TX_DR:
{
phyParam.Value = AU915_TX_MIN_DATARATE;
break;
}
case PHY_DEF_TX_DR:
{
phyParam.Value = AU915_DEFAULT_DATARATE;
break;
}
case PHY_NEXT_LOWER_TX_DR:
{
phyParam.Value = GetNextLowerTxDr( getPhy->Datarate, AU915_TX_MIN_DATARATE );
break;
}
case PHY_DEF_TX_POWER:
{
phyParam.Value = AU915_DEFAULT_TX_POWER;
break;
}
case PHY_MAX_PAYLOAD:
{
phyParam.Value = MaxPayloadOfDatarateAU915[getPhy->Datarate];
break;
}
case PHY_MAX_PAYLOAD_REPEATER:
{
phyParam.Value = MaxPayloadOfDatarateRepeaterAU915[getPhy->Datarate];
break;
}
case PHY_DUTY_CYCLE:
{
phyParam.Value = AU915_DUTY_CYCLE_ENABLED;
break;
}
case PHY_MAX_RX_WINDOW:
{
phyParam.Value = AU915_MAX_RX_WINDOW;
break;
}
case PHY_RECEIVE_DELAY1:
{
phyParam.Value = AU915_RECEIVE_DELAY1;
break;
}
case PHY_RECEIVE_DELAY2:
{
phyParam.Value = AU915_RECEIVE_DELAY2;
break;
}
case PHY_JOIN_ACCEPT_DELAY1:
{
phyParam.Value = AU915_JOIN_ACCEPT_DELAY1;
break;
}
case PHY_JOIN_ACCEPT_DELAY2:
{
phyParam.Value = AU915_JOIN_ACCEPT_DELAY2;
break;
}
case PHY_MAX_FCNT_GAP:
{
phyParam.Value = AU915_MAX_FCNT_GAP;
break;
}
case PHY_ACK_TIMEOUT:
{
phyParam.Value = ( AU915_ACKTIMEOUT + randr( -AU915_ACK_TIMEOUT_RND, AU915_ACK_TIMEOUT_RND ) );
break;
}
case PHY_DEF_DR1_OFFSET:
{
phyParam.Value = AU915_DEFAULT_RX1_DR_OFFSET;
break;
}
case PHY_DEF_RX2_FREQUENCY:
{
phyParam.Value = AU915_RX_WND_2_FREQ;
break;
}
case PHY_DEF_RX2_DR:
{
phyParam.Value = AU915_RX_WND_2_DR;
break;
}
case PHY_CHANNELS_MASK:
{
phyParam.ChannelsMask = ChannelsMask;
break;
}
case PHY_CHANNELS_DEFAULT_MASK:
{
phyParam.ChannelsMask = ChannelsDefaultMask;
break;
}
case PHY_MAX_NB_CHANNELS:
{
phyParam.Value = AU915_MAX_NB_CHANNELS;
break;
}
case PHY_CHANNELS:
{
phyParam.Channels = Channels;
break;
}
case PHY_DEF_UPLINK_DWELL_TIME:
case PHY_DEF_DOWNLINK_DWELL_TIME:
{
phyParam.Value = 0;
break;
}
case PHY_DEF_MAX_EIRP:
{
phyParam.fValue = AU915_DEFAULT_MAX_EIRP;
break;
}
case PHY_DEF_ANTENNA_GAIN:
{
phyParam.fValue = AU915_DEFAULT_ANTENNA_GAIN;
break;
}
case PHY_NB_JOIN_TRIALS:
case PHY_DEF_NB_JOIN_TRIALS:
{
phyParam.Value = 2;
break;
}
default:
{
break;
}
}
return phyParam;
}
void RegionAU915SetBandTxDone( SetBandTxDoneParams_t* txDone )
{
RegionCommonSetBandTxDone( txDone->Joined, &Bands[Channels[txDone->Channel].Band], txDone->LastTxDoneTime );
}
void RegionAU915InitDefaults( InitType_t type )
{
switch( type )
{
case INIT_TYPE_INIT:
{
// Channels
// 125 kHz channels
for( uint8_t i = 0; i < AU915_MAX_NB_CHANNELS - 8; i++ )
{
Channels[i].Frequency = 915200000 + i * 200000;
Channels[i].DrRange.Value = ( DR_5 << 4 ) | DR_0;
Channels[i].Band = 0;
}
// 500 kHz channels
for( uint8_t i = AU915_MAX_NB_CHANNELS - 8; i < AU915_MAX_NB_CHANNELS; i++ )
{
Channels[i].Frequency = 915900000 + ( i - ( AU915_MAX_NB_CHANNELS - 8 ) ) * 1600000;
Channels[i].DrRange.Value = ( DR_6 << 4 ) | DR_6;
Channels[i].Band = 0;
}
// Initialize channels default mask
ChannelsDefaultMask[0] = 0xFFFF;
ChannelsDefaultMask[1] = 0xFFFF;
ChannelsDefaultMask[2] = 0xFFFF;
ChannelsDefaultMask[3] = 0xFFFF;
ChannelsDefaultMask[4] = 0x00FF;
ChannelsDefaultMask[5] = 0x0000;
// Copy channels default mask
RegionCommonChanMaskCopy( ChannelsMask, ChannelsDefaultMask, 6 );
// Copy into channels mask remaining
RegionCommonChanMaskCopy( ChannelsMaskRemaining, ChannelsMask, 6 );
break;
}
case INIT_TYPE_RESTORE:
{
// Copy channels default mask
RegionCommonChanMaskCopy( ChannelsMask, ChannelsDefaultMask, 6 );
for( uint8_t i = 0; i < 6; i++ )
{ // Copy-And the channels mask
ChannelsMaskRemaining[i] &= ChannelsMask[i];
}
break;
}
default:
{
break;
}
}
}
bool RegionAU915Verify( VerifyParams_t* verify, PhyAttribute_t phyAttribute )
{
switch( phyAttribute )
{
case PHY_TX_DR:
case PHY_DEF_TX_DR:
{
return RegionCommonValueInRange( verify->DatarateParams.Datarate, AU915_TX_MIN_DATARATE, AU915_TX_MAX_DATARATE );
}
case PHY_RX_DR:
{
return RegionCommonValueInRange( verify->DatarateParams.Datarate, AU915_RX_MIN_DATARATE, AU915_RX_MAX_DATARATE );
}
case PHY_DEF_TX_POWER:
case PHY_TX_POWER:
{
// Remark: switched min and max!
return RegionCommonValueInRange( verify->TxPower, AU915_MAX_TX_POWER, AU915_MIN_TX_POWER );
}
case PHY_DUTY_CYCLE:
{
return AU915_DUTY_CYCLE_ENABLED;
}
case PHY_NB_JOIN_TRIALS:
{
if( verify->NbJoinTrials < 2 )
{
return false;
}
break;
}
default:
return false;
}
return true;
}
void RegionAU915ApplyCFList( ApplyCFListParams_t* applyCFList )
{
return;
}
bool RegionAU915ChanMaskSet( ChanMaskSetParams_t* chanMaskSet )
{
uint8_t nbChannels = RegionCommonCountChannels( chanMaskSet->ChannelsMaskIn, 0, 4 );
// Check the number of active channels
// According to ACMA regulation, we require at least 20 125KHz channels, if
// the node shall utilize 125KHz channels.
if( ( nbChannels < 20 ) &&
( nbChannels > 0 ) )
{
return false;
}
switch( chanMaskSet->ChannelsMaskType )
{
case CHANNELS_MASK:
{
RegionCommonChanMaskCopy( ChannelsMask, chanMaskSet->ChannelsMaskIn, 6 );
for( uint8_t i = 0; i < 6; i++ )
{ // Copy-And the channels mask
ChannelsMaskRemaining[i] &= ChannelsMask[i];
}
break;
}
case CHANNELS_DEFAULT_MASK:
{
RegionCommonChanMaskCopy( ChannelsDefaultMask, chanMaskSet->ChannelsMaskIn, 6 );
break;
}
default:
return false;
}
return true;
}
bool RegionAU915AdrNext( AdrNextParams_t* adrNext, int8_t* drOut, int8_t* txPowOut, uint32_t* adrAckCounter )
{
bool adrAckReq = false;
int8_t datarate = adrNext->Datarate;
int8_t txPower = adrNext->TxPower;
GetPhyParams_t getPhy;
PhyParam_t phyParam;
// Report back the adr ack counter
*adrAckCounter = adrNext->AdrAckCounter;
if( adrNext->AdrEnabled == true )
{
if( datarate == AU915_TX_MIN_DATARATE )
{
*adrAckCounter = 0;
adrAckReq = false;
}
else
{
if( adrNext->AdrAckCounter >= AU915_ADR_ACK_LIMIT )
{
adrAckReq = true;
txPower = AU915_MAX_TX_POWER;
}
else
{
adrAckReq = false;
}
if( adrNext->AdrAckCounter >= ( AU915_ADR_ACK_LIMIT + AU915_ADR_ACK_DELAY ) )
{
if( ( adrNext->AdrAckCounter % AU915_ADR_ACK_DELAY ) == 1 )
{
// Decrease the datarate
getPhy.Attribute = PHY_NEXT_LOWER_TX_DR;
getPhy.Datarate = datarate;
getPhy.UplinkDwellTime = adrNext->UplinkDwellTime;
phyParam = RegionAU915GetPhyParam( &getPhy );
datarate = phyParam.Value;
if( datarate == AU915_TX_MIN_DATARATE )
{
// We must set adrAckReq to false as soon as we reach the lowest datarate
adrAckReq = false;
if( adrNext->UpdateChanMask == true )
{
// Re-enable default channels
ChannelsMask[0] = 0xFFFF;
ChannelsMask[1] = 0xFFFF;
ChannelsMask[2] = 0xFFFF;
ChannelsMask[3] = 0xFFFF;
ChannelsMask[4] = 0x00FF;
ChannelsMask[5] = 0x0000;
}
}
}
}
}
}
*drOut = datarate;
*txPowOut = txPower;
return adrAckReq;
}
void RegionAU915ComputeRxWindowParameters( int8_t datarate, uint8_t minRxSymbols, uint32_t rxError, RxConfigParams_t *rxConfigParams )
{
double tSymbol = 0.0;
uint32_t radioWakeUpTime;
// Get the datarate, perform a boundary check
rxConfigParams->Datarate = MIN( datarate, AU915_RX_MAX_DATARATE );
rxConfigParams->Bandwidth = GetBandwidth( rxConfigParams->Datarate );
tSymbol = RegionCommonComputeSymbolTimeLoRa( DataratesAU915[rxConfigParams->Datarate], BandwidthsAU915[rxConfigParams->Datarate] );
radioWakeUpTime = Radio.GetRadioWakeUpTime( );
RegionCommonComputeRxWindowParameters( tSymbol, minRxSymbols, rxError, radioWakeUpTime, &rxConfigParams->WindowTimeout, &rxConfigParams->WindowOffset );
}
bool RegionAU915RxConfig( RxConfigParams_t* rxConfig, int8_t* datarate )
{
int8_t dr = rxConfig->Datarate;
uint8_t maxPayload = 0;
int8_t phyDr = 0;
uint32_t frequency = rxConfig->Frequency;
if( Radio.GetStatus( ) != RF_IDLE )
{
return false;
}
if( rxConfig->Window == 0 )
{
// Apply window 1 frequency
frequency = AU915_FIRST_RX1_CHANNEL + ( rxConfig->Channel % 8 ) * AU915_STEPWIDTH_RX1_CHANNEL;
}
// Read the physical datarate from the datarates table
phyDr = DataratesAU915[dr];
Radio.SetChannel( frequency );
// Radio configuration
Radio.SetRxConfig( MODEM_LORA, rxConfig->Bandwidth, phyDr, 1, 0, 8, rxConfig->WindowTimeout, false, 0, false, 0, 0, true, rxConfig->RxContinuous );
if( rxConfig->RepeaterSupport == true )
{
maxPayload = MaxPayloadOfDatarateRepeaterAU915[dr];
}
else
{
maxPayload = MaxPayloadOfDatarateAU915[dr];
}
Radio.SetMaxPayloadLength( MODEM_LORA, maxPayload + LORA_MAC_FRMPAYLOAD_OVERHEAD );
DBG_PRINTF( "RX on freq %d Hz at DR %d\n\r", frequency, dr );
*datarate = (uint8_t) dr;
return true;
}
bool RegionAU915TxConfig( TxConfigParams_t* txConfig, int8_t* txPower, TimerTime_t* txTimeOnAir )
{
int8_t phyDr = DataratesAU915[txConfig->Datarate];
int8_t txPowerLimited = LimitTxPower( txConfig->TxPower, Bands[Channels[txConfig->Channel].Band].TxMaxPower, txConfig->Datarate, ChannelsMask );
uint32_t bandwidth = GetBandwidth( txConfig->Datarate );
int8_t phyTxPower = 0;
// Calculate physical TX power
phyTxPower = RegionCommonComputeTxPower( txPowerLimited, txConfig->MaxEirp, txConfig->AntennaGain );
// Setup the radio frequency
Radio.SetChannel( Channels[txConfig->Channel].Frequency );
Radio.SetTxConfig( MODEM_LORA, phyTxPower, 0, bandwidth, phyDr, 1, 8, false, true, 0, 0, false, 3000 );
DBG_PRINTF( "TX on freq %d Hz at DR %d\n\r", Channels[txConfig->Channel].Frequency, txConfig->Datarate );
// Setup maximum payload lenght of the radio driver
Radio.SetMaxPayloadLength( MODEM_LORA, txConfig->PktLen );
*txTimeOnAir = Radio.TimeOnAir( MODEM_LORA, txConfig->PktLen );
*txPower = txPowerLimited;
return true;
}
uint8_t RegionAU915LinkAdrReq( LinkAdrReqParams_t* linkAdrReq, int8_t* drOut, int8_t* txPowOut, uint8_t* nbRepOut, uint8_t* nbBytesParsed )
{
uint8_t status = 0x07;
RegionCommonLinkAdrParams_t linkAdrParams;
uint8_t nextIndex = 0;
uint8_t bytesProcessed = 0;
uint16_t channelsMask[6] = { 0, 0, 0, 0, 0, 0 };
GetPhyParams_t getPhy;
PhyParam_t phyParam;
RegionCommonLinkAdrReqVerifyParams_t linkAdrVerifyParams;
// Initialize local copy of channels mask
RegionCommonChanMaskCopy( channelsMask, ChannelsMask, 6 );
while( bytesProcessed < linkAdrReq->PayloadSize )
{
nextIndex = RegionCommonParseLinkAdrReq( &( linkAdrReq->Payload[bytesProcessed] ), &linkAdrParams );
if( nextIndex == 0 )
break; // break loop, since no more request has been found
// Update bytes processed
bytesProcessed += nextIndex;
// Revert status, as we only check the last ADR request for the channel mask KO
status = 0x07;
if( linkAdrParams.ChMaskCtrl == 6 )
{
// Enable all 125 kHz channels
channelsMask[0] = 0xFFFF;
channelsMask[1] = 0xFFFF;
channelsMask[2] = 0xFFFF;
channelsMask[3] = 0xFFFF;
// Apply chMask to channels 64 to 71
channelsMask[4] = linkAdrParams.ChMask;
}
else if( linkAdrParams.ChMaskCtrl == 7 )
{
// Disable all 125 kHz channels
channelsMask[0] = 0x0000;
channelsMask[1] = 0x0000;
channelsMask[2] = 0x0000;
channelsMask[3] = 0x0000;
// Apply chMask to channels 64 to 71
channelsMask[4] = linkAdrParams.ChMask;
}
else if( linkAdrParams.ChMaskCtrl == 5 )
{
// RFU
status &= 0xFE; // Channel mask KO
}
else
{
channelsMask[linkAdrParams.ChMaskCtrl] = linkAdrParams.ChMask;
}
}
// FCC 15.247 paragraph F mandates to hop on at least 2 125 kHz channels
if( ( linkAdrParams.Datarate < DR_6 ) && ( RegionCommonCountChannels( channelsMask, 0, 4 ) < 2 ) )
{
status &= 0xFE; // Channel mask KO
}
// Get the minimum possible datarate
getPhy.Attribute = PHY_MIN_TX_DR;
getPhy.UplinkDwellTime = linkAdrReq->UplinkDwellTime;
phyParam = RegionAU915GetPhyParam( &getPhy );
linkAdrVerifyParams.Status = status;
linkAdrVerifyParams.AdrEnabled = linkAdrReq->AdrEnabled;
linkAdrVerifyParams.Datarate = linkAdrParams.Datarate;
linkAdrVerifyParams.TxPower = linkAdrParams.TxPower;
linkAdrVerifyParams.NbRep = linkAdrParams.NbRep;
linkAdrVerifyParams.CurrentDatarate = linkAdrReq->CurrentDatarate;
linkAdrVerifyParams.CurrentTxPower = linkAdrReq->CurrentTxPower;
linkAdrVerifyParams.CurrentNbRep = linkAdrReq->CurrentNbRep;
linkAdrVerifyParams.NbChannels = AU915_MAX_NB_CHANNELS;
linkAdrVerifyParams.ChannelsMask = channelsMask;
linkAdrVerifyParams.MinDatarate = ( int8_t )phyParam.Value;
linkAdrVerifyParams.MaxDatarate = AU915_TX_MAX_DATARATE;
linkAdrVerifyParams.Channels = Channels;
linkAdrVerifyParams.MinTxPower = AU915_MIN_TX_POWER;
linkAdrVerifyParams.MaxTxPower = AU915_MAX_TX_POWER;
// Verify the parameters and update, if necessary
status = RegionCommonLinkAdrReqVerifyParams( &linkAdrVerifyParams, &linkAdrParams.Datarate, &linkAdrParams.TxPower, &linkAdrParams.NbRep );
// Update channelsMask if everything is correct
if( status == 0x07 )
{
// Copy Mask
RegionCommonChanMaskCopy( ChannelsMask, channelsMask, 6 );
ChannelsMaskRemaining[0] &= ChannelsMask[0];
ChannelsMaskRemaining[1] &= ChannelsMask[1];
ChannelsMaskRemaining[2] &= ChannelsMask[2];
ChannelsMaskRemaining[3] &= ChannelsMask[3];
ChannelsMaskRemaining[4] = ChannelsMask[4];
ChannelsMaskRemaining[5] = ChannelsMask[5];
}
// Update status variables
*drOut = linkAdrParams.Datarate;
*txPowOut = linkAdrParams.TxPower;
*nbRepOut = linkAdrParams.NbRep;
*nbBytesParsed = bytesProcessed;
return status;
}
uint8_t RegionAU915RxParamSetupReq( RxParamSetupReqParams_t* rxParamSetupReq )
{
uint8_t status = 0x07;
uint32_t freq = rxParamSetupReq->Frequency;
// Verify radio frequency
if( ( Radio.CheckRfFrequency( freq ) == false ) ||
( freq < AU915_FIRST_RX1_CHANNEL ) ||
( freq > AU915_LAST_RX1_CHANNEL ) ||
( ( ( freq - ( uint32_t ) AU915_FIRST_RX1_CHANNEL ) % ( uint32_t ) AU915_STEPWIDTH_RX1_CHANNEL ) != 0 ) )
{
status &= 0xFE; // Channel frequency KO
}
// Verify datarate
if( RegionCommonValueInRange( rxParamSetupReq->Datarate, AU915_RX_MIN_DATARATE, AU915_RX_MAX_DATARATE ) == false )
{
status &= 0xFD; // Datarate KO
}
if( ( rxParamSetupReq->Datarate == DR_7 ) ||
( rxParamSetupReq->Datarate > DR_13 ) )
{
status &= 0xFD; // Datarate KO
}
// Verify datarate offset
if( RegionCommonValueInRange( rxParamSetupReq->DrOffset, AU915_MIN_RX1_DR_OFFSET, AU915_MAX_RX1_DR_OFFSET ) == false )
{
status &= 0xFB; // Rx1DrOffset range KO
}
return status;
}
uint8_t RegionAU915NewChannelReq( NewChannelReqParams_t* newChannelReq )
{
// Datarate and frequency KO
return 0;
}
int8_t RegionAU915TxParamSetupReq( TxParamSetupReqParams_t* txParamSetupReq )
{
return -1;
}
uint8_t RegionAU915DlChannelReq( DlChannelReqParams_t* dlChannelReq )
{
return 0;
}
int8_t RegionAU915AlternateDr( AlternateDrParams_t* alternateDr )
{
int8_t datarate = 0;
// Re-enable 500 kHz default channels
ChannelsMask[4] = 0x00FF;
if( ( alternateDr->NbTrials & 0x01 ) == 0x01 )
{
datarate = DR_6;
}
else
{
datarate = DR_0;
}
return datarate;
}
void RegionAU915CalcBackOff( CalcBackOffParams_t* calcBackOff )
{
RegionCommonCalcBackOffParams_t calcBackOffParams;
calcBackOffParams.Channels = Channels;
calcBackOffParams.Bands = Bands;
calcBackOffParams.LastTxIsJoinRequest = calcBackOff->LastTxIsJoinRequest;
calcBackOffParams.Joined = calcBackOff->Joined;
calcBackOffParams.DutyCycleEnabled = calcBackOff->DutyCycleEnabled;
calcBackOffParams.Channel = calcBackOff->Channel;
calcBackOffParams.ElapsedTime = calcBackOff->ElapsedTime;
calcBackOffParams.TxTimeOnAir = calcBackOff->TxTimeOnAir;
RegionCommonCalcBackOff( &calcBackOffParams );
}
bool RegionAU915NextChannel( NextChanParams_t* nextChanParams, uint8_t* channel, TimerTime_t* time, TimerTime_t* aggregatedTimeOff )
{
uint8_t nbEnabledChannels = 0;
uint8_t delayTx = 0;
uint8_t enabledChannels[AU915_MAX_NB_CHANNELS] = { 0 };
TimerTime_t nextTxDelay = 0;
// Count 125kHz channels
if( RegionCommonCountChannels( ChannelsMaskRemaining, 0, 4 ) == 0 )
{ // Reactivate default channels
RegionCommonChanMaskCopy( ChannelsMaskRemaining, ChannelsMask, 4 );
}
// Check other channels
if( nextChanParams->Datarate >= DR_6 )
{
if( ( ChannelsMaskRemaining[4] & 0x00FF ) == 0 )
{
ChannelsMaskRemaining[4] = ChannelsMask[4];
}
}
if( nextChanParams->AggrTimeOff <= TimerGetElapsedTime( nextChanParams->LastAggrTx ) )
{
// Reset Aggregated time off
*aggregatedTimeOff = 0;
// Update bands Time OFF
nextTxDelay = RegionCommonUpdateBandTimeOff( nextChanParams->Joined, nextChanParams->DutyCycleEnabled, Bands, AU915_MAX_NB_BANDS );
// Search how many channels are enabled
nbEnabledChannels = CountNbOfEnabledChannels( nextChanParams->Datarate,
ChannelsMaskRemaining, Channels,
Bands, enabledChannels, &delayTx );
}
else
{
delayTx++;
nextTxDelay = nextChanParams->AggrTimeOff - TimerGetElapsedTime( nextChanParams->LastAggrTx );
}
if( nbEnabledChannels > 0 )
{
// We found a valid channel
*channel = enabledChannels[randr( 0, nbEnabledChannels - 1 )];
// Disable the channel in the mask
RegionCommonChanDisable( ChannelsMaskRemaining, *channel, AU915_MAX_NB_CHANNELS - 8 );
*time = 0;
return true;
}
else
{
if( delayTx > 0 )
{
// Delay transmission due to AggregatedTimeOff or to a band time off
*time = nextTxDelay;
return true;
}
// Datarate not supported by any channel
*time = 0;
return false;
}
}
LoRaMacStatus_t RegionAU915ChannelAdd( ChannelAddParams_t* channelAdd )
{
return LORAMAC_STATUS_PARAMETER_INVALID;
}
bool RegionAU915ChannelsRemove( ChannelRemoveParams_t* channelRemove )
{
return LORAMAC_STATUS_PARAMETER_INVALID;
}
void RegionAU915SetContinuousWave( ContinuousWaveParams_t* continuousWave )
{
int8_t txPowerLimited = LimitTxPower( continuousWave->TxPower, Bands[Channels[continuousWave->Channel].Band].TxMaxPower, continuousWave->Datarate, ChannelsMask );
int8_t phyTxPower = 0;
uint32_t frequency = Channels[continuousWave->Channel].Frequency;
// Calculate physical TX power
phyTxPower = RegionCommonComputeTxPower( txPowerLimited, continuousWave->MaxEirp, continuousWave->AntennaGain );
Radio.SetTxContinuousWave( frequency, phyTxPower, continuousWave->Timeout );
}
uint8_t RegionAU915ApplyDrOffset( uint8_t downlinkDwellTime, int8_t dr, int8_t drOffset )
{
int8_t datarate = DatarateOffsetsAU915[dr][drOffset];
if( datarate < 0 )
{
datarate = DR_0;
}
return datarate;
}