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RH_RF69.cpp
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RH_RF69.cpp
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// RH_RF69.cpp
//
// Copyright (C) 2011 Mike McCauley
// $Id: RH_RF69.cpp,v 1.31 2019/09/02 05:21:52 mikem Exp $
#include <RH_RF69.h>
// Interrupt vectors for the 3 Arduino interrupt pins
// Each interrupt can be handled by a different instance of RH_RF69, allowing you to have
// 2 or more RF69s per Arduino
RH_RF69* RH_RF69::_deviceForInterrupt[RH_RF69_NUM_INTERRUPTS] = {0, 0, 0};
uint8_t RH_RF69::_interruptCount = 0; // Index into _deviceForInterrupt for next device
// These are indexed by the values of ModemConfigChoice
// Stored in flash (program) memory to save SRAM
// It is important to keep the modulation index for FSK between 0.5 and 10
// modulation index = 2 * Fdev / BR
// Note that I have not had much success with FSK with Fd > ~5
// You have to construct these by hand, using the data from the RF69 Datasheet :-(
// or use the SX1231 starter kit software (Ctl-Alt-N to use that without a connected radio)
#define CONFIG_FSK (RH_RF69_DATAMODUL_DATAMODE_PACKET | RH_RF69_DATAMODUL_MODULATIONTYPE_FSK | RH_RF69_DATAMODUL_MODULATIONSHAPING_FSK_NONE)
#define CONFIG_GFSK (RH_RF69_DATAMODUL_DATAMODE_PACKET | RH_RF69_DATAMODUL_MODULATIONTYPE_FSK | RH_RF69_DATAMODUL_MODULATIONSHAPING_FSK_BT1_0)
#define CONFIG_OOK (RH_RF69_DATAMODUL_DATAMODE_PACKET | RH_RF69_DATAMODUL_MODULATIONTYPE_OOK | RH_RF69_DATAMODUL_MODULATIONSHAPING_OOK_NONE)
// Choices for RH_RF69_REG_37_PACKETCONFIG1:
#define CONFIG_NOWHITE (RH_RF69_PACKETCONFIG1_PACKETFORMAT_VARIABLE | RH_RF69_PACKETCONFIG1_DCFREE_NONE | RH_RF69_PACKETCONFIG1_CRC_ON | RH_RF69_PACKETCONFIG1_ADDRESSFILTERING_NONE)
#define CONFIG_WHITE (RH_RF69_PACKETCONFIG1_PACKETFORMAT_VARIABLE | RH_RF69_PACKETCONFIG1_DCFREE_WHITENING | RH_RF69_PACKETCONFIG1_CRC_ON | RH_RF69_PACKETCONFIG1_ADDRESSFILTERING_NONE)
#define CONFIG_MANCHESTER (RH_RF69_PACKETCONFIG1_PACKETFORMAT_VARIABLE | RH_RF69_PACKETCONFIG1_DCFREE_MANCHESTER | RH_RF69_PACKETCONFIG1_CRC_ON | RH_RF69_PACKETCONFIG1_ADDRESSFILTERING_NONE)
PROGMEM static const RH_RF69::ModemConfig MODEM_CONFIG_TABLE[] =
{
// 02, 03, 04, 05, 06, 19, 1a, 37
// FSK, No Manchester, no shaping, whitening, CRC, no address filtering
// AFC BW == RX BW == 2 x bit rate
// Low modulation indexes of ~ 1 at slow speeds do not seem to work very well. Choose MI of 2.
{ CONFIG_FSK, 0x3e, 0x80, 0x00, 0x52, 0xf4, 0xf4, CONFIG_WHITE}, // FSK_Rb2Fd5
{ CONFIG_FSK, 0x34, 0x15, 0x00, 0x4f, 0xf4, 0xf4, CONFIG_WHITE}, // FSK_Rb2_4Fd4_8
{ CONFIG_FSK, 0x1a, 0x0b, 0x00, 0x9d, 0xf4, 0xf4, CONFIG_WHITE}, // FSK_Rb4_8Fd9_6
{ CONFIG_FSK, 0x0d, 0x05, 0x01, 0x3b, 0xf4, 0xf4, CONFIG_WHITE}, // FSK_Rb9_6Fd19_2
{ CONFIG_FSK, 0x06, 0x83, 0x02, 0x75, 0xf3, 0xf3, CONFIG_WHITE}, // FSK_Rb19_2Fd38_4
{ CONFIG_FSK, 0x03, 0x41, 0x04, 0xea, 0xf2, 0xf2, CONFIG_WHITE}, // FSK_Rb38_4Fd76_8
{ CONFIG_FSK, 0x02, 0x2c, 0x07, 0xae, 0xe2, 0xe2, CONFIG_WHITE}, // FSK_Rb57_6Fd120
{ CONFIG_FSK, 0x01, 0x00, 0x08, 0x00, 0xe1, 0xe1, CONFIG_WHITE}, // FSK_Rb125Fd125
{ CONFIG_FSK, 0x00, 0x80, 0x10, 0x00, 0xe0, 0xe0, CONFIG_WHITE}, // FSK_Rb250Fd250
{ CONFIG_FSK, 0x02, 0x40, 0x03, 0x33, 0x42, 0x42, CONFIG_WHITE}, // FSK_Rb55555Fd50
// 02, 03, 04, 05, 06, 19, 1a, 37
// GFSK (BT=1.0), No Manchester, whitening, CRC, no address filtering
// AFC BW == RX BW == 2 x bit rate
{ CONFIG_GFSK, 0x3e, 0x80, 0x00, 0x52, 0xf4, 0xf5, CONFIG_WHITE}, // GFSK_Rb2Fd5
{ CONFIG_GFSK, 0x34, 0x15, 0x00, 0x4f, 0xf4, 0xf4, CONFIG_WHITE}, // GFSK_Rb2_4Fd4_8
{ CONFIG_GFSK, 0x1a, 0x0b, 0x00, 0x9d, 0xf4, 0xf4, CONFIG_WHITE}, // GFSK_Rb4_8Fd9_6
{ CONFIG_GFSK, 0x0d, 0x05, 0x01, 0x3b, 0xf4, 0xf4, CONFIG_WHITE}, // GFSK_Rb9_6Fd19_2
{ CONFIG_GFSK, 0x06, 0x83, 0x02, 0x75, 0xf3, 0xf3, CONFIG_WHITE}, // GFSK_Rb19_2Fd38_4
{ CONFIG_GFSK, 0x03, 0x41, 0x04, 0xea, 0xf2, 0xf2, CONFIG_WHITE}, // GFSK_Rb38_4Fd76_8
{ CONFIG_GFSK, 0x02, 0x2c, 0x07, 0xae, 0xe2, 0xe2, CONFIG_WHITE}, // GFSK_Rb57_6Fd120
{ CONFIG_GFSK, 0x01, 0x00, 0x08, 0x00, 0xe1, 0xe1, CONFIG_WHITE}, // GFSK_Rb125Fd125
{ CONFIG_GFSK, 0x00, 0x80, 0x10, 0x00, 0xe0, 0xe0, CONFIG_WHITE}, // GFSK_Rb250Fd250
{ CONFIG_GFSK, 0x02, 0x40, 0x03, 0x33, 0x42, 0x42, CONFIG_WHITE}, // GFSK_Rb55555Fd50
// 02, 03, 04, 05, 06, 19, 1a, 37
// OOK, No Manchester, no shaping, whitening, CRC, no address filtering
// with the help of the SX1231 configuration program
// AFC BW == RX BW
// All OOK configs have the default:
// Threshold Type: Peak
// Peak Threshold Step: 0.5dB
// Peak threshiold dec: ONce per chip
// Fixed threshold: 6dB
{ CONFIG_OOK, 0x7d, 0x00, 0x00, 0x10, 0x88, 0x88, CONFIG_WHITE}, // OOK_Rb1Bw1
{ CONFIG_OOK, 0x68, 0x2b, 0x00, 0x10, 0xf1, 0xf1, CONFIG_WHITE}, // OOK_Rb1_2Bw75
{ CONFIG_OOK, 0x34, 0x15, 0x00, 0x10, 0xf5, 0xf5, CONFIG_WHITE}, // OOK_Rb2_4Bw4_8
{ CONFIG_OOK, 0x1a, 0x0b, 0x00, 0x10, 0xf4, 0xf4, CONFIG_WHITE}, // OOK_Rb4_8Bw9_6
{ CONFIG_OOK, 0x0d, 0x05, 0x00, 0x10, 0xf3, 0xf3, CONFIG_WHITE}, // OOK_Rb9_6Bw19_2
{ CONFIG_OOK, 0x06, 0x83, 0x00, 0x10, 0xf2, 0xf2, CONFIG_WHITE}, // OOK_Rb19_2Bw38_4
{ CONFIG_OOK, 0x03, 0xe8, 0x00, 0x10, 0xe2, 0xe2, CONFIG_WHITE}, // OOK_Rb32Bw64
// { CONFIG_FSK, 0x68, 0x2b, 0x00, 0x52, 0x55, 0x55, CONFIG_WHITE}, // works: Rb1200 Fd 5000 bw10000, DCC 400
// { CONFIG_FSK, 0x0c, 0x80, 0x02, 0x8f, 0x52, 0x52, CONFIG_WHITE}, // works 10/40/80
// { CONFIG_FSK, 0x0c, 0x80, 0x02, 0x8f, 0x53, 0x53, CONFIG_WHITE}, // works 10/40/40
};
RH_RF69::RH_RF69(uint8_t slaveSelectPin, uint8_t interruptPin, RHGenericSPI& spi)
:
RHSPIDriver(slaveSelectPin, spi)
{
_interruptPin = interruptPin;
_idleMode = RH_RF69_OPMODE_MODE_STDBY;
_myInterruptIndex = 0xff; // Not allocated yet
}
void RH_RF69::setIdleMode(uint8_t idleMode)
{
_idleMode = idleMode;
}
bool RH_RF69::init()
{
if (!RHSPIDriver::init())
return false;
// Determine the interrupt number that corresponds to the interruptPin
int interruptNumber = digitalPinToInterrupt(_interruptPin);
if (interruptNumber == NOT_AN_INTERRUPT)
return false;
#ifdef RH_ATTACHINTERRUPT_TAKES_PIN_NUMBER
interruptNumber = _interruptPin;
#endif
// Tell the low level SPI interface we will use SPI within this interrupt
spiUsingInterrupt(interruptNumber);
// Get the device type and check it
// This also tests whether we are really connected to a device
// My test devices return 0x24
_deviceType = spiRead(RH_RF69_REG_10_VERSION);
if (_deviceType == 00 ||
_deviceType == 0xff)
return false;
// Add by Adrien van den Bossche <[email protected]> for Teensy
// ARM M4 requires the below. else pin interrupt doesn't work properly.
// On all other platforms, its innocuous, belt and braces
pinMode(_interruptPin, INPUT);
// Set up interrupt handler
// Since there are a limited number of interrupt glue functions isr*() available,
// we can only support a limited number of devices simultaneously
// ON some devices, notably most Arduinos, the interrupt pin passed in is actuallt the
// interrupt number. You have to figure out the interruptnumber-to-interruptpin mapping
// yourself based on knwledge of what Arduino board you are running on.
if (_myInterruptIndex == 0xff)
{
// First run, no interrupt allocated yet
if (_interruptCount <= RH_RF69_NUM_INTERRUPTS)
_myInterruptIndex = _interruptCount++;
else
return false; // Too many devices, not enough interrupt vectors
}
_deviceForInterrupt[_myInterruptIndex] = this;
if (_myInterruptIndex == 0)
attachInterrupt(interruptNumber, isr0, RISING);
else if (_myInterruptIndex == 1)
attachInterrupt(interruptNumber, isr1, RISING);
else if (_myInterruptIndex == 2)
attachInterrupt(interruptNumber, isr2, RISING);
else
return false; // Too many devices, not enough interrupt vectors
setModeIdle();
// Configure important RH_RF69 registers
// Here we set up the standard packet format for use by the RH_RF69 library:
// 4 bytes preamble
// 2 SYNC words 2d, d4
// 2 CRC CCITT octets computed on the header, length and data (this in the modem config data)
// 0 to 60 bytes data
// RSSI Threshold -114dBm
// We dont use the RH_RF69s address filtering: instead we prepend our own headers to the beginning
// of the RH_RF69 payload
spiWrite(RH_RF69_REG_3C_FIFOTHRESH, RH_RF69_FIFOTHRESH_TXSTARTCONDITION_NOTEMPTY | 0x0f); // thresh 15 is default
// RSSITHRESH is default
// spiWrite(RH_RF69_REG_29_RSSITHRESH, 220); // -110 dbM
// SYNCCONFIG is default. SyncSize is set later by setSyncWords()
// spiWrite(RH_RF69_REG_2E_SYNCCONFIG, RH_RF69_SYNCCONFIG_SYNCON); // auto, tolerance 0
// PAYLOADLENGTH is default
// spiWrite(RH_RF69_REG_38_PAYLOADLENGTH, RH_RF69_FIFO_SIZE); // max size only for RX
// PACKETCONFIG 2 is default
spiWrite(RH_RF69_REG_6F_TESTDAGC, RH_RF69_TESTDAGC_CONTINUOUSDAGC_IMPROVED_LOWBETAOFF);
// If high power boost set previously, disable it
spiWrite(RH_RF69_REG_5A_TESTPA1, RH_RF69_TESTPA1_NORMAL);
spiWrite(RH_RF69_REG_5C_TESTPA2, RH_RF69_TESTPA2_NORMAL);
// The following can be changed later by the user if necessary.
// Set up default configuration
uint8_t syncwords[] = { 0x2d, 0xd4 };
setSyncWords(syncwords, sizeof(syncwords)); // Same as RF22's
// Reasonably fast and reliable default speed and modulation
setModemConfig(GFSK_Rb250Fd250);
// 3 would be sufficient, but this is the same as RF22's
setPreambleLength(4);
// An innocuous ISM frequency, same as RF22's
setFrequency(434.0);
// No encryption
setEncryptionKey(NULL);
// +13dBm, same as power-on default
setTxPower(13);
return true;
}
// C++ level interrupt handler for this instance
// RH_RF69 is unusual in Mthat it has several interrupt lines, and not a single, combined one.
// On Moteino, only one of the several interrupt lines (DI0) from the RH_RF69 is connnected to the processor.
// We use this to get PACKETSDENT and PAYLOADRADY interrupts.
void RH_RF69::handleInterrupt()
{
// Get the interrupt cause
uint8_t irqflags2 = spiRead(RH_RF69_REG_28_IRQFLAGS2);
if (_mode == RHModeTx && (irqflags2 & RH_RF69_IRQFLAGS2_PACKETSENT))
{
// A transmitter message has been fully sent
setModeIdle(); // Clears FIFO
_txGood++;
// Serial.println("PACKETSENT");
}
// Must look for PAYLOADREADY, not CRCOK, since only PAYLOADREADY occurs _after_ AES decryption
// has been done
if (_mode == RHModeRx && (irqflags2 & RH_RF69_IRQFLAGS2_PAYLOADREADY))
{
// A complete message has been received with good CRC
_lastRssi = -((int8_t)(spiRead(RH_RF69_REG_24_RSSIVALUE) >> 1));
_lastPreambleTime = millis();
setModeIdle();
// Save it in our buffer
readFifo();
// Serial.println("PAYLOADREADY");
}
}
// Low level function reads the FIFO and checks the address
// Caution: since we put our headers in what the RH_RF69 considers to be the payload, if encryption is enabled
// we have to suffer the cost of decryption before we can determine whether the address is acceptable.
// Performance issue?
void RH_RF69::readFifo()
{
ATOMIC_BLOCK_START;
digitalWrite(_slaveSelectPin, LOW);
_spi.beginTransaction();
_spi.transfer(RH_RF69_REG_00_FIFO); // Send the start address with the write mask off
uint8_t payloadlen = _spi.transfer(0); // First byte is payload len (counting the headers)
if (payloadlen <= RH_RF69_MAX_ENCRYPTABLE_PAYLOAD_LEN &&
payloadlen >= RH_RF69_HEADER_LEN)
{
_rxHeaderTo = _spi.transfer(0);
// Check addressing
if (_promiscuous ||
_rxHeaderTo == _thisAddress ||
_rxHeaderTo == RH_BROADCAST_ADDRESS)
{
// Get the rest of the headers
_rxHeaderFrom = _spi.transfer(0);
_rxHeaderId = _spi.transfer(0);
_rxHeaderFlags = _spi.transfer(0);
// And now the real payload
for (_bufLen = 0; _bufLen < (payloadlen - RH_RF69_HEADER_LEN); _bufLen++)
_buf[_bufLen] = _spi.transfer(0);
_rxGood++;
_rxBufValid = true;
}
}
digitalWrite(_slaveSelectPin, HIGH);
_spi.endTransaction();
ATOMIC_BLOCK_END;
// Any junk remaining in the FIFO will be cleared next time we go to receive mode.
}
// These are low level functions that call the interrupt handler for the correct
// instance of RH_RF69.
// 3 interrupts allows us to have 3 different devices
void RH_INTERRUPT_ATTR RH_RF69::isr0()
{
if (_deviceForInterrupt[0])
_deviceForInterrupt[0]->handleInterrupt();
}
void RH_INTERRUPT_ATTR RH_RF69::isr1()
{
if (_deviceForInterrupt[1])
_deviceForInterrupt[1]->handleInterrupt();
}
void RH_INTERRUPT_ATTR RH_RF69::isr2()
{
if (_deviceForInterrupt[2])
_deviceForInterrupt[2]->handleInterrupt();
}
int8_t RH_RF69::temperatureRead()
{
// Caution: must be ins standby.
// setModeIdle();
spiWrite(RH_RF69_REG_4E_TEMP1, RH_RF69_TEMP1_TEMPMEASSTART); // Start the measurement
while (spiRead(RH_RF69_REG_4E_TEMP1) & RH_RF69_TEMP1_TEMPMEASRUNNING)
; // Wait for the measurement to complete
return 166 - spiRead(RH_RF69_REG_4F_TEMP2); // Very approximate, based on observation
}
bool RH_RF69::setFrequency(float centre, float afcPullInRange)
{
// Frf = FRF / FSTEP
uint32_t frf = (uint32_t)((centre * 1000000.0) / RH_RF69_FSTEP);
spiWrite(RH_RF69_REG_07_FRFMSB, (frf >> 16) & 0xff);
spiWrite(RH_RF69_REG_08_FRFMID, (frf >> 8) & 0xff);
spiWrite(RH_RF69_REG_09_FRFLSB, frf & 0xff);
// afcPullInRange is not used
(void)afcPullInRange;
return true;
}
int8_t RH_RF69::rssiRead()
{
// Force a new value to be measured
// Hmmm, this hangs forever!
#if 0
spiWrite(RH_RF69_REG_23_RSSICONFIG, RH_RF69_RSSICONFIG_RSSISTART);
while (!(spiRead(RH_RF69_REG_23_RSSICONFIG) & RH_RF69_RSSICONFIG_RSSIDONE))
;
#endif
return -((int8_t)(spiRead(RH_RF69_REG_24_RSSIVALUE) >> 1));
}
void RH_RF69::setOpMode(uint8_t mode)
{
uint8_t opmode = spiRead(RH_RF69_REG_01_OPMODE);
opmode &= ~RH_RF69_OPMODE_MODE;
opmode |= (mode & RH_RF69_OPMODE_MODE);
spiWrite(RH_RF69_REG_01_OPMODE, opmode);
// Wait for mode to change.
while (!(spiRead(RH_RF69_REG_27_IRQFLAGS1) & RH_RF69_IRQFLAGS1_MODEREADY))
;
}
void RH_RF69::setModeIdle()
{
if (_mode != RHModeIdle)
{
if (_power >= 18)
{
// If high power boost, return power amp to receive mode
spiWrite(RH_RF69_REG_5A_TESTPA1, RH_RF69_TESTPA1_NORMAL);
spiWrite(RH_RF69_REG_5C_TESTPA2, RH_RF69_TESTPA2_NORMAL);
}
setOpMode(_idleMode);
_mode = RHModeIdle;
}
}
bool RH_RF69::sleep()
{
if (_mode != RHModeSleep)
{
spiWrite(RH_RF69_REG_01_OPMODE, RH_RF69_OPMODE_MODE_SLEEP);
_mode = RHModeSleep;
}
return true;
}
void RH_RF69::setModeRx()
{
if (_mode != RHModeRx)
{
if (_power >= 18)
{
// If high power boost, return power amp to receive mode
spiWrite(RH_RF69_REG_5A_TESTPA1, RH_RF69_TESTPA1_NORMAL);
spiWrite(RH_RF69_REG_5C_TESTPA2, RH_RF69_TESTPA2_NORMAL);
}
spiWrite(RH_RF69_REG_25_DIOMAPPING1, RH_RF69_DIOMAPPING1_DIO0MAPPING_01); // Set interrupt line 0 PayloadReady
setOpMode(RH_RF69_OPMODE_MODE_RX); // Clears FIFO
_mode = RHModeRx;
}
}
void RH_RF69::setModeTx()
{
if (_mode != RHModeTx)
{
if (_power >= 18)
{
// Set high power boost mode
// Note that OCP defaults to ON so no need to change that.
spiWrite(RH_RF69_REG_5A_TESTPA1, RH_RF69_TESTPA1_BOOST);
spiWrite(RH_RF69_REG_5C_TESTPA2, RH_RF69_TESTPA2_BOOST);
}
spiWrite(RH_RF69_REG_25_DIOMAPPING1, RH_RF69_DIOMAPPING1_DIO0MAPPING_00); // Set interrupt line 0 PacketSent
setOpMode(RH_RF69_OPMODE_MODE_TX); // Clears FIFO
_mode = RHModeTx;
}
}
void RH_RF69::setTxPower(int8_t power, bool ishighpowermodule)
{
_power = power;
uint8_t palevel;
if (ishighpowermodule)
{
if (_power < -2)
_power = -2; //RFM69HW only works down to -2.
if (_power <= 13)
{
// -2dBm to +13dBm
//Need PA1 exclusivelly on RFM69HW
palevel = RH_RF69_PALEVEL_PA1ON | ((_power + 18) &
RH_RF69_PALEVEL_OUTPUTPOWER);
}
else if (_power >= 18)
{
// +18dBm to +20dBm
// Need PA1+PA2
// Also need PA boost settings change when tx is turned on and off, see setModeTx()
palevel = RH_RF69_PALEVEL_PA1ON
| RH_RF69_PALEVEL_PA2ON
| ((_power + 11) & RH_RF69_PALEVEL_OUTPUTPOWER);
}
else
{
// +14dBm to +17dBm
// Need PA1+PA2
palevel = RH_RF69_PALEVEL_PA1ON
| RH_RF69_PALEVEL_PA2ON
| ((_power + 14) & RH_RF69_PALEVEL_OUTPUTPOWER);
}
}
else
{
if (_power < -18) _power = -18;
if (_power > 13) _power = 13; //limit for RFM69W
palevel = RH_RF69_PALEVEL_PA0ON
| ((_power + 18) & RH_RF69_PALEVEL_OUTPUTPOWER);
}
spiWrite(RH_RF69_REG_11_PALEVEL, palevel);
}
// Sets registers from a canned modem configuration structure
void RH_RF69::setModemRegisters(const ModemConfig* config)
{
spiBurstWrite(RH_RF69_REG_02_DATAMODUL, &config->reg_02, 5);
spiBurstWrite(RH_RF69_REG_19_RXBW, &config->reg_19, 2);
spiWrite(RH_RF69_REG_37_PACKETCONFIG1, config->reg_37);
}
// Set one of the canned FSK Modem configs
// Returns true if its a valid choice
bool RH_RF69::setModemConfig(ModemConfigChoice index)
{
if (index > (signed int)(sizeof(MODEM_CONFIG_TABLE) / sizeof(ModemConfig)))
return false;
ModemConfig cfg;
memcpy_P(&cfg, &MODEM_CONFIG_TABLE[index], sizeof(RH_RF69::ModemConfig));
setModemRegisters(&cfg);
return true;
}
void RH_RF69::setPreambleLength(uint16_t bytes)
{
spiWrite(RH_RF69_REG_2C_PREAMBLEMSB, bytes >> 8);
spiWrite(RH_RF69_REG_2D_PREAMBLELSB, bytes & 0xff);
}
void RH_RF69::setSyncWords(const uint8_t* syncWords, uint8_t len)
{
uint8_t syncconfig = spiRead(RH_RF69_REG_2E_SYNCCONFIG);
if (syncWords && len && len <= 4)
{
spiBurstWrite(RH_RF69_REG_2F_SYNCVALUE1, syncWords, len);
syncconfig |= RH_RF69_SYNCCONFIG_SYNCON;
}
else
syncconfig &= ~RH_RF69_SYNCCONFIG_SYNCON;
syncconfig &= ~RH_RF69_SYNCCONFIG_SYNCSIZE;
syncconfig |= (len-1) << 3;
spiWrite(RH_RF69_REG_2E_SYNCCONFIG, syncconfig);
}
void RH_RF69::setEncryptionKey(uint8_t* key)
{
if (key)
{
spiBurstWrite(RH_RF69_REG_3E_AESKEY1, key, 16);
spiWrite(RH_RF69_REG_3D_PACKETCONFIG2, spiRead(RH_RF69_REG_3D_PACKETCONFIG2) | RH_RF69_PACKETCONFIG2_AESON);
}
else
{
spiWrite(RH_RF69_REG_3D_PACKETCONFIG2, spiRead(RH_RF69_REG_3D_PACKETCONFIG2) & ~RH_RF69_PACKETCONFIG2_AESON);
}
}
bool RH_RF69::available()
{
if (_mode == RHModeTx)
return false;
setModeRx(); // Make sure we are receiving
return _rxBufValid;
}
bool RH_RF69::recv(uint8_t* buf, uint8_t* len)
{
if (!available())
return false;
if (buf && len)
{
ATOMIC_BLOCK_START;
if (*len > _bufLen)
*len = _bufLen;
memcpy(buf, _buf, *len);
ATOMIC_BLOCK_END;
}
_rxBufValid = false; // Got the most recent message
// printBuffer("recv:", buf, *len);
return true;
}
bool RH_RF69::send(const uint8_t* data, uint8_t len)
{
if (len > RH_RF69_MAX_MESSAGE_LEN)
return false;
waitPacketSent(); // Make sure we dont interrupt an outgoing message
setModeIdle(); // Prevent RX while filling the fifo
if (!waitCAD())
return false; // Check channel activity
ATOMIC_BLOCK_START;
digitalWrite(_slaveSelectPin, LOW);
_spi.transfer(RH_RF69_REG_00_FIFO | RH_RF69_SPI_WRITE_MASK); // Send the start address with the write mask on
_spi.transfer(len + RH_RF69_HEADER_LEN); // Include length of headers
// First the 4 headers
_spi.transfer(_txHeaderTo);
_spi.transfer(_txHeaderFrom);
_spi.transfer(_txHeaderId);
_spi.transfer(_txHeaderFlags);
// Now the payload
while (len--)
_spi.transfer(*data++);
digitalWrite(_slaveSelectPin, HIGH);
ATOMIC_BLOCK_END;
setModeTx(); // Start the transmitter
return true;
}
uint8_t RH_RF69::maxMessageLength()
{
return RH_RF69_MAX_MESSAGE_LEN;
}
bool RH_RF69::printRegister(uint8_t reg)
{
#ifdef RH_HAVE_SERIAL
Serial.print(reg, HEX);
Serial.print(" ");
Serial.println(spiRead(reg), HEX);
#endif
return true;
}
bool RH_RF69::printRegisters()
{
uint8_t i;
for (i = 0; i < 0x50; i++)
printRegister(i);
// Non-contiguous registers
printRegister(RH_RF69_REG_58_TESTLNA);
printRegister(RH_RF69_REG_6F_TESTDAGC);
printRegister(RH_RF69_REG_71_TESTAFC);
return true;
}