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mirror of https://github.com/kidoman/embd synced 2024-12-23 05:10:05 +01:00
embd/radio/rfm69/rfm69.go
2016-09-06 21:07:29 -07:00

258 lines
6.6 KiB
Go

// Copyright 2016 by Thorsten von Eicken, see LICENSE file
// The RFM69 package interfaces with a HopeRF RFM69 radio connected to an SPI bus. In addition,
// an interrupt capable GPIO pin may be used to avoid having to poll the radio.
package rfm69
import (
"fmt"
"log"
"github.com/kidoman/embd"
)
// rfm69 represents a HopeRF RFM69 radio
type rfm69 struct {
// configuration
spi embd.SPIBus // bus where the radio is connected
intrPin embd.InterruptPin // interrupt pin for RX and TX interrupts
id byte // my RF ID/address
group byte // RF address of group
freq int // center frequency
parity byte // ???
// state
mode byte // current operation mode
// info about current RX packet
rxInfo *RxInfo
}
type Packet struct {
Length uint8 // number of message bytes plus 1 for the address byte
Address uint8 // destination address
Message []byte
}
type RxInfo struct {
rssi int // rssi value for current packet
lna int // low noise amp gain for current packet
fei int // frequency error for current packet
afc int // frequency correction applied for current packet
}
// New creates a connection to an rfm69 radio connected to the provided SPI bus and interrupt pin.
// the bufCount determines how many transmit buffers are allocated to allow for the queueing of
// transmit packets.
// For the RFM69 the SPI bus must be set to 10Mhz and mode 0.
func New(bus embd.SPIBus, intr embd.InterruptPin, id, group byte, freq int) *rfm69 {
// bit 7 = b7^b5^b3^b1; bit 6 = b6^b4^b2^b0
parity := group ^ (group << 4)
parity = (parity ^ (parity << 2)) & 0xc0
return &rfm69{spi: bus, intrPin: intr, id: id, group: group, freq: freq, parity: parity,
mode: 255}
}
func (rf *rfm69) writeReg(addr, data byte) error {
buf := []byte{addr | 0x80, data}
return rf.spi.TransferAndReceiveData(buf)
}
func (rf *rfm69) readReg(addr byte) (byte, error) {
buf := []byte{addr & 0x7f, 0}
err := rf.spi.TransferAndReceiveData(buf)
return buf[1], err
}
func (rf *rfm69) Init() error {
// try to establish communication with the rfm69
sync := func(pattern byte) error {
n := 10
for {
rf.writeReg(REG_SYNCVALUE1, pattern)
v, err := rf.readReg(REG_SYNCVALUE1)
if err != nil {
return err
}
if v == pattern {
return nil
}
if n == 0 {
return fmt.Errorf("Cannot sync with rfm69 chip")
}
n--
}
}
if err := sync(0xaa); err != nil {
return err
}
if err := sync(0x55); err != nil {
return err
}
// write the configuration into the registers
for i := 0; i < len(configRegs)-1; i += 2 {
if err := rf.writeReg(configRegs[i], configRegs[i+1]); err != nil {
return err
}
}
rf.setFrequency(rf.freq)
rf.writeReg(REG_SYNCVALUE2, rf.group)
if gpio, ok := rf.intrPin.(embd.DigitalPin); ok {
log.Printf("Set intr direction")
gpio.SetDirection(embd.In)
}
if err := rf.intrPin.Watch(embd.EdgeRising, rf.intrHandler); err != nil {
return err
}
return nil
}
func (rf *rfm69) setFrequency(freq int) {
// accept any frequency scale as input, including KHz and MHz
// multiply by 10 until freq >= 100 MHz
for freq > 0 && freq < 100000000 {
freq = freq * 10
}
// Frequency steps are in units of (32,000,000 >> 19) = 61.03515625 Hz
// use multiples of 64 to avoid multi-precision arithmetic, i.e. 3906.25 Hz
// due to this, the lower 6 bits of the calculated factor will always be 0
// this is still 4 ppm, i.e. well below the radio's 32 MHz crystal accuracy
// 868.0 MHz = 0xD90000, 868.3 MHz = 0xD91300, 915.0 MHz = 0xE4C000
frf := (freq << 2) / (32000000 >> 11)
rf.writeReg(REG_FRFMSB, byte(frf>>10))
rf.writeReg(REG_FRFMSB+1, byte(frf>>2))
rf.writeReg(REG_FRFMSB+2, byte(frf<<6))
}
func (rf *rfm69) setMode(mode byte) error {
reg, err := rf.readReg(REG_OPMODE)
if err != nil {
return err
}
reg = (reg & 0xE3) | mode
err = rf.writeReg(REG_OPMODE, reg)
if err != nil {
return err
}
for {
val, err := rf.readReg(REG_IRQFLAGS1)
if err != nil {
rf.mode = 255
return err
}
if val&IRQ1_MODEREADY != 0 {
rf.mode = mode
return nil
}
}
}
func (rf *rfm69) Send(header byte, message []byte) error {
if len(message) > 62 {
return fmt.Errorf("message too long")
}
rf.setMode(MODE_SLEEP)
buf := make([]byte, len(message)+4)
buf[0] = REG_FIFO | 0x80
buf[1] = byte(len(message) + 2)
buf[2] = (header & 0x3f) | rf.parity
buf[3] = (header & 0xC0) | rf.id
copy(buf[4:], message)
err := rf.spi.TransferAndReceiveData(buf)
if err != nil {
return err
}
rf.setMode(MODE_TRANSMIT)
for {
val, err := rf.readReg(REG_IRQFLAGS2)
if err != nil {
return err
}
if val&IRQ2_PACKETSENT != 0 {
break
}
}
rf.setMode(MODE_STANDBY)
return nil
}
func (rf *rfm69) readInfo() *RxInfo {
// collect rxinfo, start with rssi
rxInfo := &RxInfo{}
rssi, _ := rf.readReg(REG_RSSIVALUE)
rxInfo.rssi = 0 - int(rssi)/2
// low noise amp gain
lna, _ := rf.readReg(REG_LNAVALUE)
rxInfo.lna = int((lna >> 3) & 0x7)
// auto freq correction applied, caution: signed value
buf := []byte{REG_AFCMSB, 0, 0}
rf.spi.TransferAndReceiveData(buf)
rxInfo.afc = int(int8(buf[1]))<<8 | int(buf[2])
// freq error detected, caution: signed value
buf = []byte{REG_FEIMSB, 0, 0}
rf.spi.TransferAndReceiveData(buf)
rxInfo.fei = int(int8(buf[1]))<<8 | int(buf[2])
return rxInfo
}
func (rf *rfm69) Receive() (header byte, message []byte, info *RxInfo, err error) {
// if we're not in receive mode, then switch, this also flushes the FIFO
if rf.mode != MODE_RECEIVE {
rf.setMode(MODE_RECEIVE)
return
}
// if we don't have rxinfo check whether we have RX_READY, which means that we've
// started receiving a packet so we can collect info
if rf.rxInfo == nil {
irq1, err := rf.readReg(REG_IRQFLAGS1)
if err != nil {
return 0, nil, nil, err
}
if irq1&IRQ1_RXREADY != 0 {
rf.rxInfo = rf.readInfo()
}
}
// see whether we have a full packet
irq2, err := rf.readReg(REG_IRQFLAGS2)
if err != nil {
return 0, nil, nil, err
}
if irq2&IRQ2_PAYLOADREADY == 0 {
return
}
i2 := rf.readInfo()
if rf.rxInfo != nil && i2 != nil &&
(rf.rxInfo.rssi != i2.rssi || rf.rxInfo.lna != i2.lna ||
rf.rxInfo.afc != i2.afc || rf.rxInfo.fei != i2.fei) {
fmt.Printf("\nrxInfo mismatch: %+v vs %+v\n", *rf.rxInfo, *i2)
}
// got packet, read it by fetching the entire FIFO, should be faster than first
// looking at the length
buf := make([]byte, 67)
buf[0] = REG_FIFO
err = rf.spi.TransferAndReceiveData(buf)
if err != nil {
return 0, nil, nil, err
}
// return the packet
info = rf.rxInfo
rf.rxInfo = nil
l := buf[1]
if l > 66 {
l = 66 // or error?
}
header = buf[2]
message = buf[3 : 2+l]
return
}
func (rf *rfm69) intrHandler(pin embd.DigitalPin) {
log.Printf("Interrupt called!")
}