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RH_E32.cpp
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RH_E32.cpp
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// RH_E32.cpp
//
// Copyright (C) 2017 Mike McCauley
// $Id: RH_E32.cpp,v 1.6 2020/01/07 23:35:02 mikem Exp $
#include <RadioHead.h>
#ifdef RH_HAVE_SERIAL // No serial
#include <RH_E32.h>
RH_E32::RH_E32(Stream *s, uint8_t m0_pin, uint8_t m1_pin, uint8_t aux_pin)
:
_s(s),
_m0_pin(m0_pin),
_m1_pin(m1_pin),
_aux_pin(aux_pin)
{
// Prevent glitches at startup
pinMode(_aux_pin, INPUT);
digitalWrite(_m0_pin, HIGH);
digitalWrite(_m1_pin, HIGH);
pinMode(_m0_pin, OUTPUT);
pinMode(_m1_pin, OUTPUT);
}
bool RH_E32::init()
{
// When a message is available, Aux will go low 5 msec before the first character is output
// So if we ever wait more than this period of time after Aux low, can conclude there will be no data
_s->setTimeout(10);
// Wait until the module is connected
waitAuxHigh();
if (!getVersion())
return false; // Could not communicate with module or wrong type of module
setMode(RHModeRx);
clearRxBuf();
if (!setDataRate(DataRate5kbps))
return false;
if (!setPower(Power21dBm))
return false;
// if (!setBaudRate(BaudRate9600, Parity8N1))
// return false;
if (!setFrequency(433))
return false;
return true;
}
bool RH_E32::reset()
{
setOperatingMode(ModeSleep);
uint8_t resetCommand[] = { RH_E32_COMMAND_RESET, RH_E32_COMMAND_RESET, RH_E32_COMMAND_RESET };
size_t result = _s->write(resetCommand, sizeof(resetCommand));
setOperatingMode(ModeNormal);
return (result == sizeof(resetCommand));
}
bool RH_E32::readParameters(Parameters& params)
{
setOperatingMode(ModeSleep);
uint8_t readParamsCommand[] = { RH_E32_COMMAND_READ_PARAMS, RH_E32_COMMAND_READ_PARAMS, RH_E32_COMMAND_READ_PARAMS };
_s->write(readParamsCommand, sizeof(readParamsCommand));
size_t result = _s->readBytes((char*)¶ms, sizeof(params)); // default 1 sec timeout
setOperatingMode(ModeNormal);
return (result == sizeof(Parameters));
}
bool RH_E32::writeParameters(Parameters& params, bool save)
{
setOperatingMode(ModeSleep);
params.head = save ? RH_E32_COMMAND_WRITE_PARAMS_SAVE : RH_E32_COMMAND_WRITE_PARAMS_NOSAVE;
// printBuffer("writing now", (uint8_t*)¶ms, sizeof(params));
size_t result = _s->write((uint8_t*)¶ms, sizeof(params));
if (result != sizeof(params))
return false;
// Now we expect to get the same data back
result = _s->readBytes((char*)¶ms, sizeof(params));
if (result != sizeof(params))
return false;
// printBuffer("additional read", (uint8_t*)¶ms, sizeof(params));
// Without a little delay here, writing params often fails
delay(20);
setOperatingMode(ModeNormal);
return result == sizeof(params);
}
void RH_E32::setOperatingMode(OperatingMode mode)
{
waitAuxHigh();
switch (mode)
{
case ModeNormal:
digitalWrite(_m0_pin, LOW);
digitalWrite(_m1_pin, LOW);
break;
case ModeWakeUp:
digitalWrite(_m0_pin, HIGH);
digitalWrite(_m1_pin, LOW);
break;
case ModePowerSaving:
digitalWrite(_m0_pin, LOW);
digitalWrite(_m1_pin, HIGH);
break;
case ModeSleep:
digitalWrite(_m0_pin, HIGH);
digitalWrite(_m1_pin, HIGH);
break;
}
delay(10); // Takes a little while to start its response
waitAuxHigh();
}
bool RH_E32::getVersion()
{
setOperatingMode(ModeSleep);
uint8_t readVersionCommand[] = { RH_E32_COMMAND_READ_VERSION, RH_E32_COMMAND_READ_VERSION, RH_E32_COMMAND_READ_VERSION };
_s->write(readVersionCommand, sizeof(readVersionCommand));
uint8_t version[4];
size_t result = _s->readBytes((char *)version, sizeof(version)); // default 1 sec timeout
setOperatingMode(ModeNormal);
if (result == 4)
{
// Successful read
// printBuffer("read version", version, sizeof(version));
if (version[0] != 0xc3 || version [1] != 0x32)
{
// Not an E32
return false;
}
else
{
// REVISIT: do something with it?
}
}
else
{
// Read failed: no module? Wrong baud?
return false;
}
return true;
}
void RH_E32::waitAuxHigh()
{
// REVISIT: timeout needed?
while (digitalRead(_aux_pin) == false)
;
}
void RH_E32::waitAuxLow()
{
while (digitalRead(_aux_pin) == true)
;
}
// Check whether the latest received message is complete and uncorrupted
void RH_E32::validateRxBuf()
{
if (_bufLen < RH_E32_HEADER_LEN)
return; // Too short to be a real message
if (_bufLen != _buf[0])
return; // Do we have all the message?
// Extract the 4 headers
_rxHeaderTo = _buf[1];
_rxHeaderFrom = _buf[2];
_rxHeaderId = _buf[3];
_rxHeaderFlags = _buf[4];
if (_promiscuous ||
_rxHeaderTo == _thisAddress ||
_rxHeaderTo == RH_BROADCAST_ADDRESS)
{
_rxGood++;
_rxBufValid = true;
}
}
void RH_E32::clearRxBuf()
{
_rxBufValid = false;
_bufLen = 0;
}
bool RH_E32::available()
{
// Caution: long packets could be sent in several bursts
if (!_rxBufValid)
{
if (_mode == RHModeTx)
return false;
if (!_s->available())
return false;
// Suck up all the characters we can
uint8_t data;
while (_s->readBytes((char *)&data, 1) == 1) // Not read timeout
{
_buf[_bufLen++] = data;
}
// Now assess what we have
if (_bufLen < RH_E32_HEADER_LEN)
{
// Serial.println("Incomplete header");
return false;
}
else if (_bufLen < _buf[0])
{
// Serial.println("Incomplete message");
return false;
}
else if ( _bufLen > _buf[0]
|| _bufLen > RH_E32_MAX_PAYLOAD_LEN)
{
// Serial.println("Overrun");
clearRxBuf();
_rxBad++;
return false;
}
// Else it a partial or complete message, test it
// printBuffer("read success", _buf, _bufLen);
validateRxBuf();
}
return _rxBufValid;
}
bool RH_E32::recv(uint8_t* buf, uint8_t* len)
{
if (!available())
return false;
if (buf && len)
{
// Skip the 4 headers that are at the beginning of the rxBuf
if (*len > _bufLen - RH_E32_HEADER_LEN)
*len = _bufLen - RH_E32_HEADER_LEN;
memcpy(buf, _buf + RH_E32_HEADER_LEN, *len);
}
clearRxBuf(); // This message accepted and cleared
return true;
}
bool RH_E32::send(const uint8_t* data, uint8_t len)
{
if (len > RH_E32_MAX_MESSAGE_LEN)
return false;
waitPacketSent(); // Make sure we dont collide with previous message
// Set up the headers
_buf[0] = len + RH_E32_HEADER_LEN; // Number of octets in teh whole message
_buf[1] = _txHeaderTo;
_buf[2] = _txHeaderFrom;
_buf[3] = _txHeaderId;
_buf[4] = _txHeaderFlags;
// REVISIT: do we really have to do this? perhaps just write it after writing the header?
memcpy(_buf+RH_E32_HEADER_LEN, data, len);
_s->write(_buf, len + RH_E32_HEADER_LEN);
setMode(RHModeTx);
_txGood++;
// Aux will return high when the TX buffer is empty
return true;
}
uint8_t RH_E32::maxMessageLength()
{
return RH_E32_MAX_MESSAGE_LEN;
}
bool RH_E32::waitPacketSent()
{
if (_mode == RHModeTx)
waitAuxHigh();
setMode(RHModeRx);
return true;
}
bool RH_E32::setDataRate(DataRate rate)
{
Parameters params;
if (!readParameters(params))
return false;
// The DataRate enums are the same values as the register bitmasks
params.sped &= ~RH_E32_PARAM_SPED_DATARATE_MASK;
params.sped |= (rate & RH_E32_PARAM_SPED_DATARATE_MASK);
return writeParameters(params);
}
bool RH_E32::setPower(PowerLevel level)
{
Parameters params;
if (!readParameters(params))
return false;
// The DataRate enums are the same values as the register bitmasks
params.option &= ~RH_E32_PARAM_OPTION_POWER_MASK;
params.option |= (level & RH_E32_PARAM_OPTION_POWER_MASK);
return writeParameters(params);
}
bool RH_E32::setBaudRate(BaudRate rate, Parity parity)
{
Parameters params;
if (!readParameters(params))
return false;
// The DataRate enums are the same values as the register bitmasks
params.sped &= ~RH_E32_PARAM_SPED_UART_BAUD_MASK;
params.sped |= (rate & RH_E32_PARAM_SPED_UART_BAUD_MASK);
// Also set the parity
params.sped &= ~RH_E32_PARAM_SPED_UART_MODE_MASK;
params.sped |= (parity & RH_E32_PARAM_SPED_UART_MODE_MASK);
return writeParameters(params);
}
bool RH_E32::setFrequency(uint16_t frequency)
{
if (frequency < 410 || frequency > 441)
return false;
Parameters params;
if (!readParameters(params))
return false;
params.chan = frequency - 410;
return writeParameters(params);
}
#endif // RH_HAVE_SERIAL