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RH_CC110.cpp
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RH_CC110.cpp
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// RH_CC110.cpp
//
// Driver for Texas Instruments CC110L transceiver.
//
// Copyright (C) 2016 Mike McCauley
// $Id: RH_CC110.cpp,v 1.5 2017/01/12 23:58:00 mikem Exp $
#include <RH_CC110.h>
// Interrupt vectors for the 3 Arduino interrupt pins
// Each interrupt can be handled by a different instance of RH_CC110, allowing you to have
// 2 or more LORAs per Arduino
RH_CC110* RH_CC110::_deviceForInterrupt[RH_CC110_NUM_INTERRUPTS] = {0, 0, 0};
uint8_t RH_CC110::_interruptCount = 0; // Index into _deviceForInterrupt for next device
// We need 2 tables of modem configuration registers, since some values change depending on the Xtal frequency
// These are indexed by the values of ModemConfigChoice
// Canned modem configurations generated with the TI SmartRF Studio v7 version 2.3.0 on boodgie
// based on the sample 'Typical settings'
// Stored in flash (program) memory to save SRAM
// For 26MHz crystals
PROGMEM static const RH_CC110::ModemConfig MODEM_CONFIG_TABLE_26MHZ[] =
{
// 0B 0C 10 11 12 15 19 1A 1B 1C 1D 21 22 23 24 25 26 2C 2D 2E
{0x06, 0x00, 0xf5, 0x83, 0x13, 0x15, 0x16, 0x6c, 0x03, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb1_2Fd5_2
{0x06, 0x00, 0xf6, 0x83, 0x13, 0x15, 0x16, 0x6c, 0x03, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb2_4Fd5_2
{0x06, 0x00, 0xc7, 0x83, 0x13, 0x40, 0x16, 0x6c, 0x43, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb4_8Fd25_4
{0x06, 0x00, 0xc8, 0x93, 0x13, 0x34, 0x16, 0x6c, 0x43, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb10Fd19
{0x06, 0x00, 0xca, 0x83, 0x13, 0x35, 0x16, 0x6c, 0x43, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb38_4Fd20
{0x08, 0x00, 0x7b, 0x83, 0x13, 0x42, 0x1d, 0x1c, 0xc7, 0x00, 0xb2, 0xb6, 0x10, 0xea, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb76_8Fd32
{0x08, 0x00, 0x5b, 0xf8, 0x13, 0x47, 0x1d, 0x1c, 0xc7, 0x00, 0xb2, 0xb6, 0x10, 0xea, 0x2a, 0x00, 0x1f, 0x81, 0x31, 0x09}, // GFSK_Rb100Fd47
{0x0c, 0x00, 0x2d, 0x3b, 0x13, 0x62, 0x1d, 0x1c, 0xc7, 0x00, 0xb0, 0xb6, 0x10, 0xea, 0x2a, 0x00, 0x1f, 0x88, 0x31, 0x09}, // GFSK_Rb250Fd127
};
// For 27MHz crystals
PROGMEM static const RH_CC110::ModemConfig MODEM_CONFIG_TABLE_27MHZ[] =
{
// 0B 0C 10 11 12 15 19 1A 1B 1C 1D 21 22 23 24 25 26 2C 2D 2E
{0x06, 0x00, 0xf5, 0x75, 0x13, 0x14, 0x16, 0x6c, 0x03, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb1_2Fd5_2
{0x06, 0x00, 0xf6, 0x75, 0x13, 0x14, 0x16, 0x6c, 0x03, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb2_4Fd5_2
{0x06, 0x00, 0xc7, 0x75, 0x13, 0x37, 0x16, 0x6c, 0x43, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb4_8Fd25_4
{0x06, 0x00, 0xc8, 0x84, 0x13, 0x33, 0x16, 0x6c, 0x43, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb10Fd19
{0x06, 0x00, 0xca, 0x75, 0x13, 0x34, 0x16, 0x6c, 0x43, 0x40, 0x91, 0x56, 0x10, 0xe9, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb38_4Fd20
{0x08, 0x00, 0x7b, 0x75, 0x13, 0x42, 0x1d, 0x1c, 0xc7, 0x00, 0xb2, 0xb6, 0x10, 0xea, 0x2a, 0x00, 0x1f, 0x81, 0x35, 0x09}, // GFSK_Rb76_8Fd32
{0x08, 0x00, 0x5b, 0xf8, 0x13, 0x47, 0x1d, 0x1c, 0xc7, 0x00, 0xb2, 0xb6, 0x10, 0xea, 0x2a, 0x00, 0x1f, 0x81, 0x31, 0x09}, // GFSK_Rb100Fd47
{0x0c, 0x00, 0x2d, 0x2f, 0x13, 0x62, 0x1d, 0x1c, 0xc7, 0x00, 0xb0, 0xb6, 0x10, 0xea, 0x2a, 0x00, 0x1f, 0x88, 0x31, 0x09}, // GFSK_Rb250Fd127
};
// These power outputs are based on the suggested optimum values for
// multilayer inductors in the 915MHz frequency band. Per table 5-15.
// Yes these are not linear.
// Caution: this table is indexed by the values of enum TransmitPower
// Do not change one without changing the other.
// If you do not like these values, use setPaTable() directly.
PROGMEM static const uint8_t paPowerValues[] =
{
0x03, // -30dBm
0x0e, // -20dBm
0x1e, // -15dBm
0x27, // -10dBm
0x8e, // 0dBm
0xcd, // 5dBm
0xc7, // 7dBm
0xc0, // 10dBm
};
RH_CC110::RH_CC110(uint8_t slaveSelectPin, uint8_t interruptPin, bool is27MHz, RHGenericSPI& spi)
:
RHNRFSPIDriver(slaveSelectPin, spi),
_rxBufValid(false),
_is27MHz(is27MHz)
{
_interruptPin = interruptPin;
_myInterruptIndex = 0xff; // Not allocated yet
}
bool RH_CC110::init()
{
if (!RHNRFSPIDriver::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
// Reset the chip
// Strobe the reset
uint8_t val = spiCommand(RH_CC110_STROBE_30_SRES); // Reset
delay(100);
val = spiCommand(RH_CC110_STROBE_36_SIDLE); // IDLE
if (val != 0x0f)
return false; // No chip there or reset failed.
// 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_CC110_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
spiWriteRegister(RH_CC110_REG_02_IOCFG0, RH_CC110_GDO_CFG_CRC_OK_AUTORESET); // gdo0 interrupt on CRC_OK
spiWriteRegister(RH_CC110_REG_06_PKTLEN, RH_CC110_MAX_PAYLOAD_LEN); // max packet length
spiWriteRegister(RH_CC110_REG_07_PKTCTRL1, RH_CC110_CRC_AUTOFLUSH); // no append status, crc autoflush, no addr check
spiWriteRegister(RH_CC110_REG_08_PKTCTRL0, RH_CC110_PKT_FORMAT_NORMAL | RH_CC110_CRC_EN | RH_CC110_LENGTH_CONFIG_VARIABLE);
spiWriteRegister(RH_CC110_REG_13_MDMCFG1, RH_CC110_NUM_PREAMBLE_4); // 4 preamble bytes, chan spacing not used
spiWriteRegister(RH_CC110_REG_17_MCSM1, RH_CC110_CCA_MODE_RSSI_PACKET | RH_CC110_RXOFF_MODE_RX | RH_CC110_TXOFF_MODE_IDLE);
spiWriteRegister(RH_CC110_REG_18_MCSM0, RH_CC110_FS_AUTOCAL_FROM_IDLE | RH_CC110_PO_TIMEOUT_64); // cal when going to tx or rx
spiWriteRegister(RH_CC110_REG_20_WORCTRL, 0xfb); // from smartrf
spiWriteRegister(RH_CC110_REG_29_FSTEST, 0x59); // from smartrf
spiWriteRegister(RH_CC110_REG_2A_PTEST, 0x7f); // from smartrf
spiWriteRegister(RH_CC110_REG_2B_AGCTEST, 0x3f); // from smartrf
// Set some reasonable default values
uint8_t syncWords[] = { 0xd3, 0x91 };
setSyncWords(syncWords, sizeof(syncWords));
setTxPower(TransmitPower5dBm);
setFrequency(915.0);
setModemConfig(GFSK_Rb1_2Fd5_2);
return true;
}
void RH_CC110::setIs27MHz(bool is27MHz)
{
_is27MHz = is27MHz;
}
// C++ level interrupt handler for this instance
// We use this to get RxDone and TxDone interrupts
void RH_CC110::handleInterrupt()
{
// Serial.println("I");
if (_mode == RHModeRx)
{
// Radio is confgigured to stay in RX until we move it to IDLE after a CRC_OK message for us
// We only get interrupts in RX mode, on CRC_OK
// CRC OK
_lastRssi = spiBurstReadRegister(RH_CC110_REG_34_RSSI); // Was set when sync word was detected
_bufLen = spiReadRegister(RH_CC110_REG_3F_FIFO);
if (_bufLen < 4)
{
// Something wrong there, flush the FIFO
spiCommand(RH_CC110_STROBE_3A_SFRX);
clearRxBuf();
return;
}
spiBurstRead(RH_CC110_REG_3F_FIFO | RH_CC110_SPI_BURST_MASK | RH_CC110_SPI_READ_MASK, _buf, _bufLen);
// All good so far. See if its for us
validateRxBuf();
if (_rxBufValid)
setModeIdle(); // Done
}
}
// These are low level functions that call the interrupt handler for the correct
// instance of RH_CC110.
// 3 interrupts allows us to have 3 different devices
void RH_CC110::isr0()
{
if (_deviceForInterrupt[0])
_deviceForInterrupt[0]->handleInterrupt();
}
void RH_CC110::isr1()
{
if (_deviceForInterrupt[1])
_deviceForInterrupt[1]->handleInterrupt();
}
void RH_CC110::isr2()
{
if (_deviceForInterrupt[2])
_deviceForInterrupt[2]->handleInterrupt();
}
uint8_t RH_CC110::spiReadRegister(uint8_t reg)
{
return spiRead((reg & 0x3f) | RH_CC110_SPI_READ_MASK);
}
uint8_t RH_CC110::spiBurstReadRegister(uint8_t reg)
{
return spiRead((reg & 0x3f) | RH_CC110_SPI_READ_MASK | RH_CC110_SPI_BURST_MASK);
}
uint8_t RH_CC110::spiWriteRegister(uint8_t reg, uint8_t val)
{
return spiWrite((reg & 0x3f), val);
}
uint8_t RH_CC110::spiBurstWriteRegister(uint8_t reg, const uint8_t* src, uint8_t len)
{
return spiBurstWrite((reg & 0x3f) | RH_CC110_SPI_BURST_MASK, src, len);
}
bool RH_CC110::printRegisters()
{
#ifdef RH_HAVE_SERIAL
uint8_t i;
for (i = 0; i <= 0x2f; i++)
{
Serial.print(i, HEX);
Serial.print(": ");
Serial.println(spiReadRegister(i), HEX);
}
// Burst registers
for (i = 0x30; i <= 0x3e; i++)
{
Serial.print(i, HEX);
Serial.print(": ");
Serial.println(spiBurstReadRegister(i), HEX);
}
#endif
return true;
}
// Check whether the latest received message is complete and uncorrupted
void RH_CC110::validateRxBuf()
{
if (_bufLen < 4)
return; // Too short to be a real message
// Extract the 4 headers
_rxHeaderTo = _buf[0];
_rxHeaderFrom = _buf[1];
_rxHeaderId = _buf[2];
_rxHeaderFlags = _buf[3];
if (_promiscuous ||
_rxHeaderTo == _thisAddress ||
_rxHeaderTo == RH_BROADCAST_ADDRESS)
{
_rxGood++;
_rxBufValid = true;
}
}
bool RH_CC110::available()
{
if (_mode == RHModeTx)
return false;
if (_rxBufValid) // Will be set by the interrupt handler when a good message is received
return true;
setModeRx(); // Make sure we are receiving
return false; // Nothing yet
}
void RH_CC110::clearRxBuf()
{
ATOMIC_BLOCK_START;
_rxBufValid = false;
_bufLen = 0;
ATOMIC_BLOCK_END;
}
bool RH_CC110::recv(uint8_t* buf, uint8_t* len)
{
if (!available())
return false;
if (buf && len)
{
ATOMIC_BLOCK_START;
// Skip the 4 headers that are at the beginning of the rxBuf
if (*len > _bufLen - RH_CC110_HEADER_LEN)
*len = _bufLen - RH_CC110_HEADER_LEN;
memcpy(buf, _buf + RH_CC110_HEADER_LEN, *len);
ATOMIC_BLOCK_END;
}
clearRxBuf(); // This message accepted and cleared
return true;
}
bool RH_CC110::send(const uint8_t* data, uint8_t len)
{
if (len > RH_CC110_MAX_MESSAGE_LEN)
return false;
waitPacketSent(); // Make sure we dont interrupt an outgoing message
setModeIdle();
if (!waitCAD())
return false; // Check channel activity
spiWriteRegister(RH_CC110_REG_3F_FIFO, len + RH_CC110_HEADER_LEN);
spiWriteRegister(RH_CC110_REG_3F_FIFO,_txHeaderTo);
spiWriteRegister(RH_CC110_REG_3F_FIFO,_txHeaderFrom);
spiWriteRegister(RH_CC110_REG_3F_FIFO,_txHeaderId);
spiWriteRegister(RH_CC110_REG_3F_FIFO,_txHeaderFlags);
spiBurstWriteRegister(RH_CC110_REG_3F_FIFO, data, len);
// Radio returns to Idle when TX is finished
// need waitPacketSent() to detect change of _mode and TX completion
setModeTx();
return true;
}
uint8_t RH_CC110::maxMessageLength()
{
return RH_CC110_MAX_MESSAGE_LEN;
}
void RH_CC110::setModeIdle()
{
if (_mode != RHModeIdle)
{
spiCommand(RH_CC110_STROBE_36_SIDLE);
_mode = RHModeIdle;
}
}
bool RH_CC110::sleep()
{
if (_mode != RHModeSleep)
{
spiCommand(RH_CC110_STROBE_39_SPWD);
_mode = RHModeSleep;
}
return true;
}
void RH_CC110::setModeRx()
{
if (_mode != RHModeRx)
{
// Radio is configuewd to stay in RX mode
// only receipt of a CRC_OK wil cause us to return it to IDLE
spiCommand(RH_CC110_STROBE_34_SRX);
_mode = RHModeRx;
}
}
void RH_CC110::setModeTx()
{
if (_mode != RHModeTx)
{
spiCommand(RH_CC110_STROBE_35_STX);
_mode = RHModeTx;
}
}
uint8_t RH_CC110::statusRead()
{
return spiCommand(RH_CC110_STROBE_3D_SNOP);
}
// Sigh, this chip has no TXDONE type interrupt, so we have to poll
bool RH_CC110::waitPacketSent()
{
// If we are not currently in transmit mode, there is no packet to wait for
if (_mode != RHModeTx)
return false;
// Caution: may transition through CALIBRATE
while ((statusRead() & RH_CC110_STATUS_STATE) != RH_CC110_STATUS_IDLE)
YIELD;
_mode = RHModeIdle;
return true;
}
bool RH_CC110::setTxPower(TransmitPower power)
{
if (power > sizeof(paPowerValues))
return false;
uint8_t patable[2];
memcpy_P(&patable[0], (void*)&paPowerValues[power], sizeof(uint8_t));
patable[1] = 0x00;
setPaTable(patable, sizeof(patable));
return true;
}
void RH_CC110::setPaTable(uint8_t* patable, uint8_t patablesize)
{
spiBurstWriteRegister(RH_CC110_REG_3E_PATABLE, patable, patablesize);
}
bool RH_CC110::setFrequency(float centre)
{
// From section 5.21: fcarrier = fxosc / 2^16 * FREQ
uint32_t FREQ;
float fxosc = _is27MHz ? 27.0 : 26.0;
FREQ = (uint32_t)(centre * 65536 / fxosc);
// Some trivial checks
if (FREQ & 0xff000000)
return false;
spiWriteRegister(RH_CC110_REG_0D_FREQ2, (FREQ >> 16) & 0xff);
spiWriteRegister(RH_CC110_REG_0E_FREQ1, (FREQ >> 8) & 0xff);
spiWriteRegister(RH_CC110_REG_0F_FREQ0, FREQ & 0xff);
// Radio is configured to calibrate automatically whenever it enters RX or TX mode
// so no need to check for PLL lock here
return true;
}
// Sets registers from a canned modem configuration structure
void RH_CC110::setModemRegisters(const ModemConfig* config)
{
spiWriteRegister(RH_CC110_REG_0B_FSCTRL1, config->reg_0b);
spiWriteRegister(RH_CC110_REG_0C_FSCTRL0, config->reg_0c);
spiWriteRegister(RH_CC110_REG_10_MDMCFG4, config->reg_10);
spiWriteRegister(RH_CC110_REG_11_MDMCFG3, config->reg_11);
spiWriteRegister(RH_CC110_REG_12_MDMCFG2, config->reg_12);
spiWriteRegister(RH_CC110_REG_15_DEVIATN, config->reg_15);
spiWriteRegister(RH_CC110_REG_19_FOCCFG, config->reg_19);
spiWriteRegister(RH_CC110_REG_1A_BSCFG, config->reg_1a);
spiWriteRegister(RH_CC110_REG_1B_AGCCTRL2, config->reg_1b);
spiWriteRegister(RH_CC110_REG_1C_AGCCTRL1, config->reg_1c);
spiWriteRegister(RH_CC110_REG_1D_AGCCTRL0, config->reg_1d);
spiWriteRegister(RH_CC110_REG_21_FREND1, config->reg_21);
spiWriteRegister(RH_CC110_REG_22_FREND0, config->reg_22);
spiWriteRegister(RH_CC110_REG_23_FSCAL3, config->reg_23);
spiWriteRegister(RH_CC110_REG_24_FSCAL2, config->reg_24);
spiWriteRegister(RH_CC110_REG_25_FSCAL1, config->reg_25);
spiWriteRegister(RH_CC110_REG_26_FSCAL0, config->reg_26);
spiWriteRegister(RH_CC110_REG_2C_TEST2, config->reg_2c);
spiWriteRegister(RH_CC110_REG_2D_TEST1, config->reg_2d);
spiWriteRegister(RH_CC110_REG_2E_TEST0, config->reg_2e);
}
// Set one of the canned Modem configs
// Returns true if its a valid choice
bool RH_CC110::setModemConfig(ModemConfigChoice index)
{
if (index > (signed int)(sizeof(MODEM_CONFIG_TABLE_27MHZ) / sizeof(ModemConfig)))
return false;
const RH_CC110::ModemConfig *p = _is27MHz ? MODEM_CONFIG_TABLE_27MHZ : MODEM_CONFIG_TABLE_26MHZ ;
RH_CC110::ModemConfig cfg;
memcpy_P(&cfg, p + index, sizeof(RH_CC110::ModemConfig));
setModemRegisters(&cfg);
return true;
}
void RH_CC110::setSyncWords(const uint8_t* syncWords, uint8_t len)
{
if (!syncWords || len != 2)
return; // Only 2 byte sync words are supported
spiWriteRegister(RH_CC110_REG_04_SYNC1, syncWords[0]);
spiWriteRegister(RH_CC110_REG_05_SYNC0, syncWords[1]);
}