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rf12.h
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rf12.h
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// -*- mode: c++; indent-tabs-mode: nil; -*-
// RFM12B driver definitions
// 2009-02-09 <[email protected]> http://opensource.org/licenses/mit-license.php
// 2011-12-28 Ben Laurie <[email protected]>
/*
* Packets look like:
*
* SYNC1 SYNC2 HDR LEN ... CRC1 CRC2
*
* SYNC1 is 2d
* SYNC2 is the group, which is d4 by default
* HDR is
* bit 7 CTL
* bit 6 DST
* bit 5 ACK
* bit 4-0 ID
* LEN is the length of the data
* ... is the data
* CRC is a CRC over SYNC2 onwards
*
* Nodes can only send to other nodes in the same group (nominally you
* can send outside the group, but the chip recognises the group code,
* so you can only receive messages with your group number on them).
*
* If DST=1, then ID is the id of the destination, otherwise it is the
* ID of the source.
*
* A packet with ACK=1 and CTL=0 wants an ack.
* An ack depends on DST in the received packet
* DST=1 -> CTL=1 DST=0 ACK=0 ID=sender ID (== destination
* ID of original packet)
* DST=0 -> CTL=1 DST=1 ACK=0 ID=source ID of original packet
*
* It is not clear how the recipient, in the first case, knows the ack
* is theirs?
*
* A packet with CTL=1 is an ack. If DST=1, then ID is the id of the
* node the ack is aimed at.
*
*/
#ifndef RF12_h
#define RF12_h
#include <stdint.h>
#include <string.h>
#include <util/crc16.h>
#include "arduino--.h"
#include "spi.h"
// version 1 did not include the group code in the crc
// version 2 does include the group code in the crc
#define RF12_VERSION 2
#define RF12_HDR_CTL 0x80
#define RF12_HDR_DST 0x40
#define RF12_HDR_ACK 0x20
#define RF12_HDR_MASK 0x1F
#define RF12_MAXDATA 66
// EEPROM address range used by the rf12_config() code
#define RF12_EEPROM_ADDR ((uint8_t*) 0x20)
#define RF12_EEPROM_SIZE 32
#define RF12_EEPROM_EKEY (RF12_EEPROM_ADDR + RF12_EEPROM_SIZE)
#define RF12_EEPROM_ELEN 16
// shorthand to simplify sending out the proper ACK when requested
#define RF12_WANTS_ACK ((rf12_hdr & RF12_HDR_ACK) && !(rf12_hdr & RF12_HDR_CTL))
#define RF12_ACK_REPLY (rf12_hdr & RF12_HDR_DST ? RF12_HDR_CTL : \
RF12_HDR_CTL | RF12_HDR_DST | (rf12_hdr & RF12_HDR_MASK))
// options for RF12_sleep()
#define RF12_SLEEP 0
#define RF12_WAKEUP -1
//#define OPTIMIZE_SPI 1 // uncomment this to write to the RFM12B @ 8 Mhz
// maximum transmit / receive buffer: 3 header + data + 2 crc bytes
#define RF_MAX (RF12_MAXDATA + 5)
// pins used for the RFM12B interface - yes, there *is* logic in this madness:
//
// - leave RFM_IRQ set to the pin which corresponds with INT0, because the
// current driver code will use attachInterrupt() to hook into that
// - use SS_DDR, SS_PORT, and SS_BIT to define the pin you will be using as
// select pin for the RFM12B (you're free to set them to anything you like)
// - please leave SPI_SS, SPI_MOSI, SPI_MISO, and SPI_SCK as is, i.e. pointing
// to the hardware-supported SPI pins on the ATmega, *including* SPI_SS !
#if defined(__AVR_ATmega2560__) || defined(__AVR_ATmega1280__)
#define RFM_IRQ 2
#define SS_DDR DDRB
#define SS_PORT PORTB
#define SS_BIT 0
#define SPI_SS 53 // PB0, pin 19
#define SPI_MOSI 51 // PB2, pin 21
#define SPI_MISO 50 // PB3, pin 22
#define SPI_SCK 52 // PB1, pin 20
#elif defined(__AVR_ATmega644P__)
#define RFM_IRQ 10
#define SS_DDR DDRB
#define SS_PORT PORTB
#define SS_BIT 4
#define SPI_SS 4
#define SPI_MOSI 5
#define SPI_MISO 6
#define SPI_SCK 7
#elif defined(__AVR_ATtiny84__)
#define RFM_IRQ 2
#define SS_DDR DDRB
#define SS_PORT PORTB
#define SS_BIT 1
#define SPI_SS 1 // PB1, pin 3
#define SPI_MISO 4 // PA6, pin 7
#define SPI_MOSI 5 // PA5, pin 8
#define SPI_SCK 6 // PA4, pin 9
#else
// ATmega168, ATmega328, etc.
//#define RFM_IRQ 2
#define SS_DDR DDRB
#define SS_PORT PORTB
#define SS_BIT 2 // for PORTB: 2 = d.10, 1 = d.9, 0 = d.8
//#define SPI_SS 10 // PB2, pin 16
#define SPI_MOSI 11 // PB3, pin 17
#define SPI_MISO 12 // PB4, pin 18
#define SPI_SCK 13 // PB5, pin 19
#endif
// RF12 command codes
#define RF_RECEIVER_ON 0x82DD
#define RF_XMITTER_ON 0x823D
#define RF_IDLE_MODE 0x820D
#define RF_SLEEP_MODE 0x8205
#define RF_WAKEUP_MODE 0x8207
#define RF_TXREG_WRITE 0xB800
#define RF_RX_FIFO_READ 0xB000
#define RF_WAKEUP_TIMER 0xE000
// RF12 status bits
#define RF_LBD_BIT 0x0400
#define RF_RSSI_BIT 0x0100
// bits in the node id configuration byte
#define NODE_BAND 0xC0 // frequency band
#define NODE_ACKANY 0x20 // ack on broadcast packets if set
#define NODE_ID 0x1F // id of this node, as A..Z or 1..31
template <class RFM_IRQ> class _RF12
{
static volatile uint16_t _crc; // running crc value, should be
// zero at end
enum BufferOffset
{
GROUP = 0,
HEADER = 1,
LENGTH = 2,
DATA = 3
};
static volatile byte _buf[]; // recv/xmit buf including hdr &
// crc bytes
static long _seq; // seq number of encrypted packet (or -1)
// transceiver states, these determine what to do with each interrupt
enum TransceiverState
{
TXCRC1,
TXCRC2,
TXTAIL,
TXDONE,
TXIDLE,
TXRECV,
TXPRE1,
TXPRE2,
TXPRE3,
TXSYN1,
TXSYN2,
};
static uint8_t _nodeid; // address of this node
static uint8_t _group; // network group
static volatile byte _rxfill; // number of data bytes in rf12_buf
static volatile int8_t _rxstate; // current transceiver state
#define RETRIES 8 // stop retrying after 8 times
#define RETRY_MS 1000 // resend packet every second until ack'ed
static uint8_t _ezInterval; // number of seconds between transmits
static uint8_t _ezSendBuf[RF12_MAXDATA]; // data to send
static char _ezSendLen; // number of bytes to send
static uint8_t _ezPending; // remaining number of retries
static long _ezNextSend[2]; // when was last retry [0] or
// data [1] sent
static uint32_t _seqNum; // encrypted send sequence number
static uint32_t _cryptKey[4]; // encryption key to use
static void (*_crypter)(uint8_t); // does en-/decryption (null
// if disabled)
public:
// only needed if you want to init the SPI bus before
// rf12_initialize does it
static void spiInit(void)
{
// maybe use clk/2 (2x 1/4th) for sending (and clk/8 for recv,
// see rf12_xferSlow)
SPISS::init(0, F_CPU > 10000000);
RFM_IRQ::modeInput();
// pullup (apparently)
RFM_IRQ::set();
}
enum Band
{
MHZ433 = 1,
MHZ868 = 2,
MHZ915 = 3,
};
// call this once with the node ID, frequency band, and optional group
static void init(uint8_t id, uint8_t band, uint8_t group = 0xD4)
{
_nodeid = id;
_group = group;
spiInit();
xfer(0x0000); // intitial SPI transfer added to avoid power-up problem
xfer(RF_SLEEP_MODE); // DC (disable clk pin), enable lbd
// wait until RFM12B is out of power-up reset, this takes
// several *seconds*
xfer(RF_TXREG_WRITE); // in case we're still in OOK mode
while (RFM_IRQ::read() == 0)
xfer(0x0000);
xfer(0x80C7 | (band << 4)); // EL (ena TX), EF (ena RX
// FIFO), 12.0pF
xfer(0xA640); // 868MHz
xfer(0xC606); // approx 49.2 Kbps, i.e. 10000/29/(1+6) Kbps
xfer(0x94A2); // VDI,FAST,134kHz,0dBm,-91dBm
xfer(0xC2AC); // AL,!ml,DIG,DQD4
if (group != 0)
{
xfer(0xCA83); // FIFO8,2-SYNC,!ff,DR
xfer(0xCE00 | group); // SYNC=2DXX;
}
else
{
xfer(0xCA8B); // FIFO8,1-SYNC,!ff,DR
xfer(0xCE2D); // SYNC=2D;
}
xfer(0xC483); // @PWR,NO RSTRIC,!st,!fi,OE,EN
xfer(0x9850); // !mp,90kHz,MAX OUT
xfer(0xCC77); // OB1,OB0, LPX,!ddy,DDIT,BW0
xfer(0xE000); // NOT USE
xfer(0xC800); // NOT USE
xfer(0xC049); // 1.66MHz,3.1V
_rxstate = TXIDLE;
if ((_nodeid & NODE_ID) != 0)
Interrupt0::enable(Interrupt0::LOW);
else
Interrupt0::disable();
}
// call this frequently, returns true if a packet has been received
static bool recvDone(void)
{
if (_rxstate == TXRECV && (_rxfill >= _buf[LENGTH] + 5
|| _rxfill >= RF_MAX))
{
_rxstate = TXIDLE;
if (_buf[LENGTH] > RF12_MAXDATA)
_crc = 1; // force bad crc if packet length is invalid
if (!(_buf[HEADER] & RF12_HDR_DST) || (_nodeid & NODE_ID) == 31 ||
(_buf[HEADER] & RF12_HDR_MASK) == (_nodeid & NODE_ID))
{
if (_crc == 0 && _crypter != 0)
_crypter(0);
else
_seq = -1;
return true; // it's a broadcast packet or it's addressed
// to this node
}
}
if (_rxstate == TXIDLE)
recvStart();
return false;
}
static bool goodCRC() { return _crc == 0; }
static byte header() { return _buf[HEADER]; }
static byte length() { return _buf[LENGTH]; }
static const volatile byte *data() { return &_buf[DATA]; }
// call this to check whether a new transmission can be started
// returns true when a new transmission may be started with
// rf12_sendStart()
static bool canSend(void)
{
// no need to test with interrupts disabled: state TXRECV is
// only reached outside of ISR and we don't care if rxfill
// jumps from 0 to 1 here
if (_rxstate == TXRECV && _rxfill == 0 &&
(xferByte(0x00) & (RF_RSSI_BIT >> 8)) == 0)
{
xfer(RF_IDLE_MODE); // stop receiver
//XXX just in case, don't know whether these RF12 reads are needed!
// rf12_xfer(0x0000); // status register
// rf12_xfer(RF_RX_FIFO_READ); // fifo read
_rxstate = TXIDLE;
_buf[GROUP] = _group;
return true;
}
return false;
}
// returns true if the buffer currently contains a packet that
// needs ACKing.
static bool wantsAck()
{
return (_buf[HEADER] & RF12_HDR_ACK) && !(_buf[HEADER] & RF12_HDR_CTL);
}
// Send an ack reply to the packet in the buffer (wantsAck() must be true)
static void sendAckReply()
{
byte hdr;
if (_buf[HEADER] & RF12_HDR_DST)
hdr = RF12_HDR_CTL;
else
hdr = RF12_HDR_CTL | RF12_HDR_DST | (_buf[HEADER] & RF12_HDR_MASK);
sendStart(hdr, 0, 0);
}
static bool isAckReply() { return (header() & RF12_HDR_CTL) != 0; }
// call this only when rf12_recvDone() or rf12_canSend() return true
static void sendStart(uint8_t hdr)
{
_buf[HEADER] = hdr & RF12_HDR_DST ? hdr :
(hdr & ~RF12_HDR_MASK) + (_nodeid & NODE_ID);
if (_crypter != 0)
_crypter(1);
_crc = ~0;
#if RF12_VERSION >= 2
_crc = _crc16_update(_crc, _buf[GROUP]);
#endif
_rxstate = TXPRE1;
xfer(RF_XMITTER_ON); // bytes will be fed via interrupts
}
static void sendStart(uint8_t hdr, const void* ptr, uint8_t len)
{
_buf[LENGTH] = len;
memcpy((void *)&_buf[DATA], ptr, len);
sendStart(hdr);
}
// wait for send to finish, sleep mode: 0=none, 1=idle, 2=standby, 3=powerdown
void rf12_sendWait(uint8_t mode);
// this simulates OOK by turning the transmitter on and off via SPI commands
// use this only when the radio was initialized with a fake zero node ID
void rf12_onOff(uint8_t value);
// power off the RF12, ms > 0 sets watchdog to wake up again after N * 32 ms
// note: once off, calling this with -1 can be used to bring the RF12 back up
void rf12_sleep(char n);
// returns true of the supply voltage is below 3.1V
char rf12_lowbat(void);
// set up the easy tranmission mode, arg is number of seconds between packets
void rf12_easyInit(uint8_t secs);
// call this often to keep the easy transmission mode going
char rf12_easyPoll(void);
// send new data using the easy transmission mode, buffer gets copied to driver
char rf12_easySend(const void* data, uint8_t size);
// enable encryption (null arg disables it again)
void rf12_encrypt(const uint8_t*);
// low-level control of the RFM12B via direct register access
// http://tools.jeelabs.org/rfm12b is useful for calculating these
uint16_t rf12_control(uint16_t cmd);
// See http://blog.strobotics.com.au/2009/07/27/rfm12-tutorial-part-3a/
// Transmissions are packetized, don't assume you can sustain these speeds!
//
// Note - data rates are approximate. For higher data rates you may need to
// alter receiver radio bandwidth and transmitter modulator bandwidth.
// Note that bit 7 is a prescaler - don't just interpolate rates between
// RF12_DATA_RATE_3 and RF12_DATA_RATE_2.
enum rf12DataRates {
RF12_DATA_RATE_CMD = 0xC600,
RF12_DATA_RATE_9 = RF12_DATA_RATE_CMD | 0x02, // Approx 115200 bps
RF12_DATA_RATE_8 = RF12_DATA_RATE_CMD | 0x05, // Approx 57600 bps
RF12_DATA_RATE_7 = RF12_DATA_RATE_CMD | 0x06, // Approx 49200 bps
RF12_DATA_RATE_6 = RF12_DATA_RATE_CMD | 0x08, // Approx 38400 bps
RF12_DATA_RATE_5 = RF12_DATA_RATE_CMD | 0x11, // Approx 19200 bps
RF12_DATA_RATE_4 = RF12_DATA_RATE_CMD | 0x23, // Approx 9600 bps
RF12_DATA_RATE_3 = RF12_DATA_RATE_CMD | 0x47, // Approx 4800 bps
RF12_DATA_RATE_2 = RF12_DATA_RATE_CMD | 0x91, // Approx 2400 bps
RF12_DATA_RATE_1 = RF12_DATA_RATE_CMD | 0x9E, // Approx 1200 bps
RF12_DATA_RATE_DEFAULT = RF12_DATA_RATE_7,
};
static void interrupt()
{
// a transfer of 2x 16 bits @ 2 MHz over SPI takes 2x 8 us
// inside this ISR correction: now takes 2 + 8 µs, since
// sending can be done at 8 MHz
xfer(0x0000);
if (_rxstate == TXRECV)
{
uint8_t in = xferSlow(RF_RX_FIFO_READ);
// Shouldn't happen?
if (_rxfill >= RF_MAX)
return;
if (_rxfill == 0 && _group != 0)
_buf[_rxfill++] = _group;
_buf[_rxfill++] = in;
_crc = _crc16_update(_crc, in);
if (_rxfill >= _buf[LENGTH] + 5 || _rxfill >= RF_MAX)
xfer(RF_IDLE_MODE);
}
else
{
uint8_t out;
if (_rxstate < 0)
{
uint8_t pos = 3 + _buf[LENGTH] + _rxstate++;
out = _buf[pos];
_crc = _crc16_update(_crc, out);
}
else
switch (_rxstate++)
{
case TXSYN1: out = 0x2D; break;
case TXSYN2:
out = _buf[GROUP];
_rxstate = - (2 + _buf[LENGTH]);
break;
case TXCRC1: out = _crc; break;
case TXCRC2: out = _crc >> 8; break;
case TXDONE: xfer(RF_IDLE_MODE); // fall through
default: out = 0xAA;
}
xfer(RF_TXREG_WRITE + out);
}
}
private:
// FIXME: unify with arduino++.h
static uint8_t xferByte(uint8_t out)
{
#ifdef SPDR
SPDR = out;
// this loop spins 4 usec with a 2 MHz SPI clock
while (!(SPSR & _BV(SPIF)))
;
return SPDR;
#else
// ATtiny
USIDR = out;
byte v1 = bit(USIWM0) | bit(USITC);
byte v2 = bit(USIWM0) | bit(USITC) | bit(USICLK);
#if F_CPU <= 5000000
// only unroll if resulting clock stays under 2.5 MHz
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
USICR = v1; USICR = v2;
#else
for (uint8_t i = 0; i < 8; ++i)
{
USICR = v1;
USICR = v2;
}
#endif
return USIDR;
#endif
}
static uint16_t xferSlow(uint16_t cmd)
{
// slow down to under 2.5 MHz
#if F_CPU > 10000000
//bitSet(SPCR, SPR0);
//SPCR |= (1 << SPR0);
Register::SPCR.set(SPR0);
#endif
//bitClear(SS_PORT, SS_BIT);
Pin::SPI_SS::clear();
uint16_t reply = xferByte(cmd >> 8) << 8;
reply |= xferByte(cmd);
//bitSet(SS_PORT, SS_BIT);
Pin::SPI_SS::set();
#if F_CPU > 10000000
//bitClear(SPCR, SPR0);
//SPCR &= ~(1 << SPR0);
Register::SPCR.clear(SPR0);
#endif
return reply;
}
static void xfer(uint16_t cmd)
{
#if OPTIMIZE_SPI
// writing can take place at full speed, even 8 MHz works
//bitClear(SS_PORT, SS_BIT);
Pin::SPI_SS::clear();
xferByte(cmd >> 8);
xferByte(cmd);
//bitSet(SS_PORT, SS_BIT);
Pin::SPI_SS::set();
#else
xferSlow(cmd);
#endif
}
static void recvStart ()
{
_rxfill = _buf[LENGTH] = 0;
_crc = ~0;
#if RF12_VERSION >= 2
if (_group != 0)
_crc = _crc16_update(~0, _group);
#endif
_rxstate = TXRECV;
xfer(RF_RECEIVER_ON);
}
};
template <class RFM_IRQ> volatile byte _RF12<RFM_IRQ>::_buf[RF_MAX];
template <class RFM_IRQ> volatile byte _RF12<RFM_IRQ>::_rxfill;
template <class RFM_IRQ> volatile uint16_t _RF12<RFM_IRQ>::_crc;
template <class RFM_IRQ> byte _RF12<RFM_IRQ>::_group;
template <class RFM_IRQ> volatile int8_t _RF12<RFM_IRQ>::_rxstate;
template <class RFM_IRQ> byte _RF12<RFM_IRQ>::_nodeid;
template <class RFM_IRQ> void (*_RF12<RFM_IRQ>::_crypter)(byte);
template <class RFM_IRQ> long _RF12<RFM_IRQ>::_seq;
// Setup for Jeenodes and Wi/Nanodes.
typedef _RF12<Pin::D2> RF12B;
SIGNAL(INT0_vect)
{
RF12B::interrupt();
}
#endif