// MIT License
//
// Copyright (c) 2022 Mark Qvist - unsigned.io/rnode
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE.
# include <Arduino.h>
# include <SPI.h>
# include "Utilities.h"
FIFOBuffer serialFIFO ;
uint8_t serialBuffer [ CONFIG_UART_BUFFER_SIZE + 1 ] ;
FIFOBuffer16 packet_starts ;
uint16_t packet_starts_buf [ CONFIG_QUEUE_MAX_LENGTH + 1 ] ;
FIFOBuffer16 packet_lengths ;
uint16_t packet_lengths_buf [ CONFIG_QUEUE_MAX_LENGTH + 1 ] ;
uint8_t packet_queue [ CONFIG_QUEUE_SIZE ] ;
volatile uint8_t queue_height = 0 ;
volatile uint16_t queued_bytes = 0 ;
volatile uint16_t queue_cursor = 0 ;
volatile uint16_t current_packet_start = 0 ;
volatile bool serial_buffering = false ;
char sbuf [ 128 ] ;
# if MCU_VARIANT == MCU_ESP32
bool packet_ready = false ;
# endif
void setup ( ) {
# if MCU_VARIANT == MCU_ESP32
delay ( 500 ) ;
EEPROM . begin ( EEPROM_SIZE ) ;
Serial . setRxBufferSize ( CONFIG_UART_BUFFER_SIZE ) ;
# endif
// Seed the PRNG
randomSeed ( analogRead ( 0 ) ) ;
// Initialise serial communication
memset ( serialBuffer , 0 , sizeof ( serialBuffer ) ) ;
fifo_init ( & serialFIFO , serialBuffer , CONFIG_UART_BUFFER_SIZE ) ;
Serial . begin ( serial_baudrate ) ;
while ( ! Serial ) ;
serial_interrupt_init ( ) ;
// Configure input and output pins
pinMode ( pin_led_rx , OUTPUT ) ;
pinMode ( pin_led_tx , OUTPUT ) ;
// Initialise buffers
memset ( pbuf , 0 , sizeof ( pbuf ) ) ;
memset ( cbuf , 0 , sizeof ( cbuf ) ) ;
memset ( packet_queue , 0 , sizeof ( packet_queue ) ) ;
memset ( packet_starts_buf , 0 , sizeof ( packet_starts_buf ) ) ;
fifo16_init ( & packet_starts , packet_starts_buf , CONFIG_QUEUE_MAX_LENGTH ) ;
memset ( packet_lengths_buf , 0 , sizeof ( packet_starts_buf ) ) ;
fifo16_init ( & packet_lengths , packet_lengths_buf , CONFIG_QUEUE_MAX_LENGTH ) ;
// Set chip select, reset and interrupt
// pins for the LoRa module
LoRa . setPins ( pin_cs , pin_reset , pin_dio ) ;
# if MCU_VARIANT == MCU_ESP32
# if HAS_PMU == true
pmu_ready = init_pmu ( ) ;
# endif
kiss_indicate_reset ( ) ;
# endif
# if HAS_DISPLAY
disp_ready = display_init ( ) ;
# endif
// Validate board health, EEPROM and config
validateStatus ( ) ;
# if HAS_BLUETOOTH
bt_ready = bt_init ( ) ;
# endif
}
void lora_receive ( ) {
if ( ! implicit ) {
LoRa . receive ( ) ;
} else {
LoRa . receive ( implicit_l ) ;
}
}
inline void kiss_write_packet ( ) {
Serial . write ( FEND ) ;
Serial . write ( CMD_DATA ) ;
for ( uint16_t i = 0 ; i < read_len ; i + + ) {
uint8_t byte = pbuf [ i ] ;
if ( byte = = FEND ) { Serial . write ( FESC ) ; byte = TFEND ; }
if ( byte = = FESC ) { Serial . write ( FESC ) ; byte = TFESC ; }
Serial . write ( byte ) ;
}
Serial . write ( FEND ) ;
read_len = 0 ;
# if MCU_VARIANT == MCU_ESP32
packet_ready = false ;
# endif
}
inline void getPacketData ( uint16_t len ) {
while ( len - - & & read_len < MTU ) {
pbuf [ read_len + + ] = LoRa . read ( ) ;
}
}
void ISR_VECT receive_callback ( int packet_size ) {
if ( ! promisc ) {
// The standard operating mode allows large
// packets with a payload up to 500 bytes,
// by combining two raw LoRa packets.
// We read the 1-byte header and extract
// packet sequence number and split flags
uint8_t header = LoRa . read ( ) ; packet_size - - ;
uint8_t sequence = packetSequence ( header ) ;
bool ready = false ;
if ( isSplitPacket ( header ) & & seq = = SEQ_UNSET ) {
// This is the first part of a split
// packet, so we set the seq variable
// and add the data to the buffer
read_len = 0 ;
seq = sequence ;
# if MCU_VARIANT != MCU_ESP32
last_rssi = LoRa . packetRssi ( ) ;
last_snr_raw = LoRa . packetSnrRaw ( ) ;
# endif
getPacketData ( packet_size ) ;
} else if ( isSplitPacket ( header ) & & seq = = sequence ) {
// This is the second part of a split
// packet, so we add it to the buffer
// and set the ready flag.
# if MCU_VARIANT != MCU_ESP32
last_rssi = ( last_rssi + LoRa . packetRssi ( ) ) / 2 ;
last_snr_raw = ( last_snr_raw + LoRa . packetSnrRaw ( ) ) / 2 ;
# endif
getPacketData ( packet_size ) ;
seq = SEQ_UNSET ;
ready = true ;
} else if ( isSplitPacket ( header ) & & seq ! = sequence ) {
// This split packet does not carry the
// same sequence id, so we must assume
// that we are seeing the first part of
// a new split packet.
read_len = 0 ;
seq = sequence ;
# if MCU_VARIANT != MCU_ESP32
last_rssi = LoRa . packetRssi ( ) ;
last_snr_raw = LoRa . packetSnrRaw ( ) ;
# endif
getPacketData ( packet_size ) ;
} else if ( ! isSplitPacket ( header ) ) {
// This is not a split packet, so we
// just read it and set the ready
// flag to true.
if ( seq ! = SEQ_UNSET ) {
// If we already had part of a split
// packet in the buffer, we clear it.
read_len = 0 ;
seq = SEQ_UNSET ;
}
# if MCU_VARIANT != MCU_ESP32
last_rssi = LoRa . packetRssi ( ) ;
last_snr_raw = LoRa . packetSnrRaw ( ) ;
# endif
getPacketData ( packet_size ) ;
ready = true ;
}
if ( ready ) {
# if MCU_VARIANT != MCU_ESP32
// We first signal the RSSI of the
// recieved packet to the host.
kiss_indicate_stat_rssi ( ) ;
kiss_indicate_stat_snr ( ) ;
// And then write the entire packet
kiss_write_packet ( ) ;
# else
packet_ready = true ;
# endif
}
} else {
// In promiscuous mode, raw packets are
// output directly to the host
read_len = 0 ;
# if MCU_VARIANT != MCU_ESP32
last_rssi = LoRa . packetRssi ( ) ;
last_snr_raw = LoRa . packetSnrRaw ( ) ;
getPacketData ( packet_size ) ;
// We first signal the RSSI of the
// recieved packet to the host.
kiss_indicate_stat_rssi ( ) ;
kiss_indicate_stat_snr ( ) ;
// And then write the entire packet
kiss_write_packet ( ) ;
# else
getPacketData ( packet_size ) ;
packet_ready = true ;
# endif
}
}
bool startRadio ( ) {
update_radio_lock ( ) ;
if ( ! radio_online ) {
if ( ! radio_locked & & hw_ready ) {
if ( ! LoRa . begin ( lora_freq ) ) {
// The radio could not be started.
// Indicate this failure over both the
// serial port and with the onboard LEDs
radio_error = true ;
kiss_indicate_error ( ERROR_INITRADIO ) ;
led_indicate_error ( 0 ) ;
return false ;
} else {
radio_online = true ;
setTXPower ( ) ;
setBandwidth ( ) ;
setSpreadingFactor ( ) ;
setCodingRate ( ) ;
getFrequency ( ) ;
LoRa . enableCrc ( ) ;
LoRa . onReceive ( receive_callback ) ;
lora_receive ( ) ;
// Flash an info pattern to indicate
// that the radio is now on
kiss_indicate_radiostate ( ) ;
led_indicate_info ( 3 ) ;
return true ;
}
} else {
// Flash a warning pattern to indicate
// that the radio was locked, and thus
// not started
radio_online = false ;
kiss_indicate_radiostate ( ) ;
led_indicate_warning ( 3 ) ;
return false ;
}
} else {
// If radio is already on, we silently
// ignore the request.
kiss_indicate_radiostate ( ) ;
return true ;
}
}
void stopRadio ( ) {
LoRa . end ( ) ;
radio_online = false ;
}
void update_radio_lock ( ) {
if ( lora_freq ! = 0 & & lora_bw ! = 0 & & lora_txp ! = 0xFF & & lora_sf ! = 0 ) {
radio_locked = false ;
} else {
radio_locked = true ;
}
}
bool queueFull ( ) {
return ( queue_height > = CONFIG_QUEUE_MAX_LENGTH | | queued_bytes > = CONFIG_QUEUE_SIZE ) ;
}
volatile bool queue_flushing = false ;
void flushQueue ( void ) {
if ( ! queue_flushing ) {
queue_flushing = true ;
uint16_t processed = 0 ;
# if MCU_VARIANT == MCU_ESP32
while ( ! fifo16_isempty ( & packet_starts ) ) {
# else
while ( ! fifo16_isempty_locked ( & packet_starts ) ) {
# endif
uint16_t start = fifo16_pop ( & packet_starts ) ;
uint16_t length = fifo16_pop ( & packet_lengths ) ;
if ( length > = MIN_L & & length < = MTU ) {
for ( uint16_t i = 0 ; i < length ; i + + ) {
uint16_t pos = ( start + i ) % CONFIG_QUEUE_SIZE ;
tbuf [ i ] = packet_queue [ pos ] ;
}
transmit ( length ) ;
processed + + ;
}
}
}
queue_height = 0 ;
queued_bytes = 0 ;
queue_flushing = false ;
}
void transmit ( uint16_t size ) {
if ( radio_online ) {
if ( ! promisc ) {
led_tx_on ( ) ;
uint16_t written = 0 ;
uint8_t header = random ( 256 ) & 0xF0 ;
if ( size > SINGLE_MTU - HEADER_L ) {
header = header | FLAG_SPLIT ;
}
LoRa . beginPacket ( ) ;
LoRa . write ( header ) ; written + + ;
for ( uint16_t i = 0 ; i < size ; i + + ) {
LoRa . write ( tbuf [ i ] ) ;
written + + ;
if ( written = = 255 ) {
LoRa . endPacket ( ) ;
LoRa . beginPacket ( ) ;
LoRa . write ( header ) ;
written = 1 ;
}
}
LoRa . endPacket ( ) ;
led_tx_off ( ) ;
lora_receive ( ) ;
} else {
// In promiscuous mode, we only send out
// plain raw LoRa packets with a maximum
// payload of 255 bytes
led_tx_on ( ) ;
uint16_t written = 0 ;
// Cap packets at 255 bytes
if ( size > SINGLE_MTU ) {
size = SINGLE_MTU ;
}
// If implicit header mode has been set,
// set packet length to payload data length
if ( ! implicit ) {
LoRa . beginPacket ( ) ;
} else {
LoRa . beginPacket ( size ) ;
}
for ( uint16_t i = 0 ; i < size ; i + + ) {
LoRa . write ( tbuf [ i ] ) ;
written + + ;
}
LoRa . endPacket ( ) ;
led_tx_off ( ) ;
lora_receive ( ) ;
}
} else {
kiss_indicate_error ( ERROR_TXFAILED ) ;
led_indicate_error ( 5 ) ;
}
}
void serialCallback ( uint8_t sbyte ) {
if ( IN_FRAME & & sbyte = = FEND & & command = = CMD_DATA ) {
IN_FRAME = false ;
if ( ! fifo16_isfull ( & packet_starts ) & & queued_bytes < CONFIG_QUEUE_SIZE ) {
uint16_t s = current_packet_start ;
int16_t e = queue_cursor - 1 ; if ( e = = - 1 ) e = CONFIG_QUEUE_SIZE - 1 ;
uint16_t l ;
if ( s ! = e ) {
l = ( s < e ) ? e - s + 1 : CONFIG_QUEUE_SIZE - s + e + 1 ;
} else {
l = 1 ;
}
if ( l > = MIN_L ) {
queue_height + + ;
fifo16_push ( & packet_starts , s ) ;
fifo16_push ( & packet_lengths , l ) ;
current_packet_start = queue_cursor ;
}
}
} else if ( sbyte = = FEND ) {
IN_FRAME = true ;
command = CMD_UNKNOWN ;
frame_len = 0 ;
} else if ( IN_FRAME & & frame_len < MTU ) {
// Have a look at the command byte first
if ( frame_len = = 0 & & command = = CMD_UNKNOWN ) {
command = sbyte ;
} else if ( command = = CMD_DATA ) {
cable_state = CABLE_STATE_CONNECTED ;
if ( sbyte = = FESC ) {
ESCAPE = true ;
} else {
if ( ESCAPE ) {
if ( sbyte = = TFEND ) sbyte = FEND ;
if ( sbyte = = TFESC ) sbyte = FESC ;
ESCAPE = false ;
}
if ( queue_height < CONFIG_QUEUE_MAX_LENGTH & & queued_bytes < CONFIG_QUEUE_SIZE ) {
queued_bytes + + ;
packet_queue [ queue_cursor + + ] = sbyte ;
if ( queue_cursor = = CONFIG_QUEUE_SIZE ) queue_cursor = 0 ;
}
}
} else if ( command = = CMD_FREQUENCY ) {
if ( sbyte = = FESC ) {
ESCAPE = true ;
} else {
if ( ESCAPE ) {
if ( sbyte = = TFEND ) sbyte = FEND ;
if ( sbyte = = TFESC ) sbyte = FESC ;
ESCAPE = false ;
}
cbuf [ frame_len + + ] = sbyte ;
}
if ( frame_len = = 4 ) {
uint32_t freq = ( uint32_t ) cbuf [ 0 ] < < 24 | ( uint32_t ) cbuf [ 1 ] < < 16 | ( uint32_t ) cbuf [ 2 ] < < 8 | ( uint32_t ) cbuf [ 3 ] ;
if ( freq = = 0 ) {
kiss_indicate_frequency ( ) ;
} else {
lora_freq = freq ;
if ( op_mode = = MODE_HOST ) setFrequency ( ) ;
kiss_indicate_frequency ( ) ;
}
}
} else if ( command = = CMD_BANDWIDTH ) {
if ( sbyte = = FESC ) {
ESCAPE = true ;
} else {
if ( ESCAPE ) {
if ( sbyte = = TFEND ) sbyte = FEND ;
if ( sbyte = = TFESC ) sbyte = FESC ;
ESCAPE = false ;
}
cbuf [ frame_len + + ] = sbyte ;
}
if ( frame_len = = 4 ) {
uint32_t bw = ( uint32_t ) cbuf [ 0 ] < < 24 | ( uint32_t ) cbuf [ 1 ] < < 16 | ( uint32_t ) cbuf [ 2 ] < < 8 | ( uint32_t ) cbuf [ 3 ] ;
if ( bw = = 0 ) {
kiss_indicate_bandwidth ( ) ;
} else {
lora_bw = bw ;
if ( op_mode = = MODE_HOST ) setBandwidth ( ) ;
kiss_indicate_bandwidth ( ) ;
}
}
} else if ( command = = CMD_TXPOWER ) {
if ( sbyte = = 0xFF ) {
kiss_indicate_txpower ( ) ;
} else {
int txp = sbyte ;
if ( txp > 17 ) txp = 17 ;
lora_txp = txp ;
if ( op_mode = = MODE_HOST ) setTXPower ( ) ;
kiss_indicate_txpower ( ) ;
}
} else if ( command = = CMD_SF ) {
if ( sbyte = = 0xFF ) {
kiss_indicate_spreadingfactor ( ) ;
} else {
int sf = sbyte ;
if ( sf < 6 ) sf = 6 ;
if ( sf > 12 ) sf = 12 ;
lora_sf = sf ;
if ( op_mode = = MODE_HOST ) setSpreadingFactor ( ) ;
kiss_indicate_spreadingfactor ( ) ;
}
} else if ( command = = CMD_CR ) {
if ( sbyte = = 0xFF ) {
kiss_indicate_codingrate ( ) ;
} else {
int cr = sbyte ;
if ( cr < 5 ) cr = 5 ;
if ( cr > 8 ) cr = 8 ;
lora_cr = cr ;
if ( op_mode = = MODE_HOST ) setCodingRate ( ) ;
kiss_indicate_codingrate ( ) ;
}
} else if ( command = = CMD_IMPLICIT ) {
set_implicit_length ( sbyte ) ;
kiss_indicate_implicit_length ( ) ;
} else if ( command = = CMD_LEAVE ) {
if ( sbyte = = 0xFF ) {
cable_state = CABLE_STATE_DISCONNECTED ;
current_rssi = - 292 ;
last_rssi = - 292 ;
last_rssi_raw = 0x00 ;
last_snr_raw = 0x80 ;
}
} else if ( command = = CMD_RADIO_STATE ) {
cable_state = CABLE_STATE_CONNECTED ;
if ( sbyte = = 0xFF ) {
kiss_indicate_radiostate ( ) ;
} else if ( sbyte = = 0x00 ) {
stopRadio ( ) ;
kiss_indicate_radiostate ( ) ;
} else if ( sbyte = = 0x01 ) {
startRadio ( ) ;
kiss_indicate_radiostate ( ) ;
}
} else if ( command = = CMD_STAT_RX ) {
kiss_indicate_stat_rx ( ) ;
} else if ( command = = CMD_STAT_TX ) {
kiss_indicate_stat_tx ( ) ;
} else if ( command = = CMD_STAT_RSSI ) {
kiss_indicate_stat_rssi ( ) ;
} else if ( command = = CMD_RADIO_LOCK ) {
update_radio_lock ( ) ;
kiss_indicate_radio_lock ( ) ;
} else if ( command = = CMD_BLINK ) {
led_indicate_info ( sbyte ) ;
} else if ( command = = CMD_RANDOM ) {
kiss_indicate_random ( getRandom ( ) ) ;
} else if ( command = = CMD_DETECT ) {
if ( sbyte = = DETECT_REQ ) {
cable_state = CABLE_STATE_CONNECTED ;
kiss_indicate_detect ( ) ;
}
} else if ( command = = CMD_PROMISC ) {
if ( sbyte = = 0x01 ) {
promisc_enable ( ) ;
} else if ( sbyte = = 0x00 ) {
promisc_disable ( ) ;
}
kiss_indicate_promisc ( ) ;
} else if ( command = = CMD_READY ) {
if ( ! queueFull ( ) ) {
kiss_indicate_ready ( ) ;
} else {
kiss_indicate_not_ready ( ) ;
}
} else if ( command = = CMD_UNLOCK_ROM ) {
if ( sbyte = = ROM_UNLOCK_BYTE ) {
unlock_rom ( ) ;
}
} else if ( command = = CMD_RESET ) {
if ( sbyte = = CMD_RESET_BYTE ) {
hard_reset ( ) ;
}
} else if ( command = = CMD_ROM_READ ) {
kiss_dump_eeprom ( ) ;
} else if ( command = = CMD_ROM_WRITE ) {
if ( sbyte = = FESC ) {
ESCAPE = true ;
} else {
if ( ESCAPE ) {
if ( sbyte = = TFEND ) sbyte = FEND ;
if ( sbyte = = TFESC ) sbyte = FESC ;
ESCAPE = false ;
}
cbuf [ frame_len + + ] = sbyte ;
}
if ( frame_len = = 2 ) {
eeprom_write ( cbuf [ 0 ] , cbuf [ 1 ] ) ;
}
} else if ( command = = CMD_FW_VERSION ) {
kiss_indicate_version ( ) ;
} else if ( command = = CMD_PLATFORM ) {
kiss_indicate_platform ( ) ;
} else if ( command = = CMD_MCU ) {
kiss_indicate_mcu ( ) ;
} else if ( command = = CMD_BOARD ) {
kiss_indicate_board ( ) ;
} else if ( command = = CMD_CONF_SAVE ) {
eeprom_conf_save ( ) ;
} else if ( command = = CMD_CONF_DELETE ) {
eeprom_conf_delete ( ) ;
} else if ( command = = CMD_FB_EXT ) {
# if HAS_DISPLAY == true
if ( sbyte = = 0xFF ) {
kiss_indicate_fbstate ( ) ;
} else if ( sbyte = = 0x00 ) {
ext_fb_disable ( ) ;
kiss_indicate_fbstate ( ) ;
} else if ( sbyte = = 0x01 ) {
ext_fb_enable ( ) ;
kiss_indicate_fbstate ( ) ;
}
# endif
} else if ( command = = CMD_FB_WRITE ) {
if ( sbyte = = FESC ) {
ESCAPE = true ;
} else {
if ( ESCAPE ) {
if ( sbyte = = TFEND ) sbyte = FEND ;
if ( sbyte = = TFESC ) sbyte = FESC ;
ESCAPE = false ;
}
cbuf [ frame_len + + ] = sbyte ;
}
if ( frame_len = = 9 ) {
uint8_t line = cbuf [ 0 ] ;
if ( line > 63 ) line = 63 ;
int fb_o = line * 8 ;
memcpy ( fb + fb_o , cbuf + 1 , 8 ) ;
}
} else if ( command = = CMD_FB_READ ) {
if ( sbyte ! = 0x00 ) {
kiss_indicate_fb ( ) ;
}
}
}
}
# if MCU_VARIANT == MCU_ESP32
portMUX_TYPE update_lock = portMUX_INITIALIZER_UNLOCKED ;
# endif
void updateModemStatus ( ) {
# if MCU_VARIANT == MCU_ESP32
portENTER_CRITICAL ( & update_lock ) ;
# endif
uint8_t status = LoRa . modemStatus ( ) ;
current_rssi = LoRa . currentRssi ( ) ;
last_status_update = millis ( ) ;
# if MCU_VARIANT == MCU_ESP32
portEXIT_CRITICAL ( & update_lock ) ;
# endif
if ( status & SIG_DETECT = = SIG_DETECT ) { stat_signal_detected = true ; } else { stat_signal_detected = false ; }
if ( status & SIG_SYNCED = = SIG_SYNCED ) { stat_signal_synced = true ; } else { stat_signal_synced = false ; }
if ( status & RX_ONGOING = = RX_ONGOING ) { stat_rx_ongoing = true ; } else { stat_rx_ongoing = false ; }
if ( stat_signal_detected | | stat_signal_synced | | stat_rx_ongoing ) {
if ( dcd_count < dcd_threshold ) {
dcd_count + + ;
dcd = true ;
} else {
dcd = true ;
dcd_led = true ;
}
} else {
if ( dcd_count > 0 ) {
dcd_count - - ;
} else {
dcd_led = false ;
}
dcd = false ;
}
if ( dcd_led ) {
led_rx_on ( ) ;
} else {
led_rx_off ( ) ;
}
}
void checkModemStatus ( ) {
if ( millis ( ) - last_status_update > = status_interval_ms ) {
updateModemStatus ( ) ;
}
}
void validateStatus ( ) {
# if MCU_VARIANT == MCU_1284P
uint8_t boot_flags = OPTIBOOT_MCUSR ;
uint8_t F_POR = PORF ;
uint8_t F_BOR = BORF ;
uint8_t F_WDR = WDRF ;
# elif MCU_VARIANT == MCU_2560
uint8_t boot_flags = OPTIBOOT_MCUSR ;
if ( boot_flags = = 0x00 ) boot_flags = 0x03 ;
uint8_t F_POR = PORF ;
uint8_t F_BOR = BORF ;
uint8_t F_WDR = WDRF ;
# elif MCU_VARIANT == MCU_ESP32
// TODO: Get ESP32 boot flags
uint8_t boot_flags = 0x02 ;
uint8_t F_POR = 0x00 ;
uint8_t F_BOR = 0x00 ;
uint8_t F_WDR = 0x01 ;
# endif
if ( boot_flags & ( 1 < < F_POR ) ) {
boot_vector = START_FROM_POWERON ;
} else if ( boot_flags & ( 1 < < F_BOR ) ) {
boot_vector = START_FROM_BROWNOUT ;
} else if ( boot_flags & ( 1 < < F_WDR ) ) {
boot_vector = START_FROM_BOOTLOADER ;
} else {
Serial . write ( " Error, indeterminate boot vector \r \n " ) ;
# if HAS_DISPLAY
if ( disp_ready ) update_display ( ) ;
# endif
led_indicate_boot_error ( ) ;
}
if ( boot_vector = = START_FROM_BOOTLOADER | | boot_vector = = START_FROM_POWERON ) {
if ( eeprom_lock_set ( ) ) {
if ( eeprom_product_valid ( ) & & eeprom_model_valid ( ) & & eeprom_hwrev_valid ( ) ) {
if ( eeprom_checksum_valid ( ) ) {
hw_ready = true ;
if ( eeprom_have_conf ( ) ) {
eeprom_conf_load ( ) ;
op_mode = MODE_TNC ;
startRadio ( ) ;
}
}
} else {
hw_ready = false ;
}
} else {
hw_ready = false ;
}
} else {
hw_ready = false ;
Serial . write ( " Error, incorrect boot vector \r \n " ) ;
# if HAS_DISPLAY
if ( disp_ready ) update_display ( ) ;
# endif
led_indicate_boot_error ( ) ;
}
}
void loop ( ) {
if ( radio_online ) {
checkModemStatus ( ) ;
# if MCU_VARIANT == MCU_ESP32
if ( packet_ready ) {
portENTER_CRITICAL ( & update_lock ) ;
last_rssi = LoRa . packetRssi ( ) ;
last_snr_raw = LoRa . packetSnrRaw ( ) ;
portEXIT_CRITICAL ( & update_lock ) ;
kiss_indicate_stat_rssi ( ) ;
kiss_indicate_stat_snr ( ) ;
kiss_write_packet ( ) ;
}
# endif
if ( queue_height > 0 ) {
if ( ! dcd_waiting ) updateModemStatus ( ) ;
if ( ! dcd & & ! dcd_led ) {
if ( dcd_waiting ) delay ( lora_rx_turnaround_ms ) ;
updateModemStatus ( ) ;
if ( ! dcd ) {
dcd_waiting = false ;
flushQueue ( ) ;
}
} else {
dcd_waiting = true ;
}
}
} else {
if ( hw_ready ) {
led_indicate_standby ( ) ;
} else {
led_indicate_not_ready ( ) ;
stopRadio ( ) ;
}
}
# if MCU_VARIANT == MCU_ESP32
buffer_serial ( ) ;
if ( ! fifo_isempty ( & serialFIFO ) ) serial_poll ( ) ;
# else
if ( ! fifo_isempty_locked ( & serialFIFO ) ) serial_poll ( ) ;
# endif
# if HAS_DISPLAY
if ( disp_ready ) update_display ( ) ;
# endif
# if HAS_PMU
if ( pmu_ready ) update_pmu ( ) ;
# endif
}
volatile bool serial_polling = false ;
void serial_poll ( ) {
serial_polling = true ;
# if MCU_VARIANT != MCU_ESP32
while ( ! fifo_isempty_locked ( & serialFIFO ) ) {
# else
while ( ! fifo_isempty ( & serialFIFO ) ) {
# endif
char sbyte = fifo_pop ( & serialFIFO ) ;
serialCallback ( sbyte ) ;
}
serial_polling = false ;
}
# if MCU_VARIANT != MCU_ESP32
# define MAX_CYCLES 20
# else
# define MAX_CYCLES 10
# endif
void buffer_serial ( ) {
if ( ! serial_buffering ) {
serial_buffering = true ;
uint8_t c = 0 ;
while ( c < MAX_CYCLES & & Serial . available ( ) ) {
c + + ;
# if MCU_VARIANT != MCU_ESP32
if ( ! fifo_isfull_locked ( & serialFIFO ) ) {
fifo_push_locked ( & serialFIFO , Serial . read ( ) ) ;
}
# else
if ( ! fifo_isfull ( & serialFIFO ) ) {
fifo_push ( & serialFIFO , Serial . read ( ) ) ;
}
# endif
}
serial_buffering = false ;
}
}
void serial_interrupt_init ( ) {
# if MCU_VARIANT == MCU_1284P
TCCR3A = 0 ;
TCCR3B = _BV ( CS10 ) |
_BV ( WGM33 ) |
_BV ( WGM32 ) ;
// Buffer incoming frames every 1ms
ICR3 = 16000 ;
TIMSK3 = _BV ( ICIE3 ) ;
# elif MCU_VARIANT == MCU_2560
// TODO: This should probably be updated for
// atmega2560 support. Might be source of
// reported issues from snh.
TCCR3A = 0 ;
TCCR3B = _BV ( CS10 ) |
_BV ( WGM33 ) |
_BV ( WGM32 ) ;
// Buffer incoming frames every 1ms
ICR3 = 16000 ;
TIMSK3 = _BV ( ICIE3 ) ;
# elif MCU_VARIANT == MCU_ESP32
// No interrupt-based polling on ESP32
# endif
}
# if MCU_VARIANT == MCU_1284P || MCU_VARIANT == MCU_2560
ISR ( TIMER3_CAPT_vect ) {
buffer_serial ( ) ;
}
# endif
