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MultiChannelDevice.h
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MultiChannelDevice.h
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//- -----------------------------------------------------------------------------------------------------------------------
// AskSin++
// 2016-10-31 papa Creative Commons - http://creativecommons.org/licenses/by-nc-sa/3.0/de/
//- -----------------------------------------------------------------------------------------------------------------------
#ifndef __MULTICHANNELDEVICE_H__
#define __MULTICHANNELDEVICE_H__
#include <Device.h>
#include <Defines.h>
#include <cm.h>
#include <Led.h>
#include <Activity.h>
#if ARDUINO_ARCH_AVR
#include <avr/wdt.h>
#endif
namespace as {
extern void(* resetFunc) (void);
#define REPLAY_NO 0
#define REPLAY_ACK 1
#define REPLAY_NACK 2
template <class HalType,class ChannelType,int ChannelCount,class List0Type=List0>
class ChannelDevice : public Device<HalType,List0Type> {
List0Type list0;
ChannelType* devchannels[ChannelCount];
uint8_t cfgChannel;
GenericList cfgList;
HMID lastdev; // store last fromID to evaluate a repeated message or a repeated broadcast message
uint8_t lastcnt;
public:
typedef Device<HalType,List0Type> DeviceType;
ChannelDevice (const DeviceInfo& i,uint16_t addr) : DeviceType(i,addr,list0,ChannelCount), list0(addr + this->keystore().size()), cfgChannel(0xff) {}
virtual ~ChannelDevice () {}
void registerChannel(ChannelType& ch,uint8_t num) {
if( num >= 1 && num <= ChannelCount) {
devchannels[num-1] = &ch;
}
}
void layoutChannels () {
uint16_t addr = list0.address() + list0.size();
for( uint8_t i=0; i<this->channels(); ++i ) {
devchannels[i]->setup(this,i+1,addr);
addr += devchannels[i]->size();
}
}
void channels (uint8_t num) {
DeviceType::channels(min(num,(uint8_t)ChannelCount));
}
uint8_t channels () const {
return DeviceType::channels();
}
void dumpSize () {
DPRINT(F("Address Space: "));DDEC(this->keystore().address());DPRINT(F(" - "));DDECLN(getUserStorage().getAddress());
}
// get object to access free EEPROM after device data
UserStorage getUserStorage () {
ChannelType& ch = channel(this->channels());
return UserStorage(ch.address() + ch.size());
}
uint16_t checksum () {
uint16_t crc = 0;
#ifndef NOCRC
// size of keystore data
crc = HalType::crc16(crc,DeviceType::keystore().size());
// add register of list0
for( uint8_t i=0; i<list0.size(); ++i ) {
crc = HalType::crc16(crc,list0.getRegister(i));
}
// add number of channels
for( uint8_t c=1; c<=this->channels(); ++c ) {
ChannelType& ch = channel(c);
// add register list 1
GenericList l = ch.getList1();
for( uint8_t i=0; i<l.getSize(); ++i ) {
crc = HalType::crc16(crc,l.getRegister(i));
}
// add register list 3
l = ch.getList3((uint8_t)0);
for( uint8_t i=0; i<l.getSize(); ++i ) {
crc = HalType::crc16(crc,l.getRegister(i));
}
// add register list 4
l = ch.getList4((uint8_t)0);
for( uint8_t i=0; i<l.getSize(); ++i ) {
crc = HalType::crc16(crc,l.getRegister(i));
}
// add number of peers
crc = HalType::crc16(crc,ch.peers());
}
#endif
return crc;
}
List0Type& getList0 () {
return list0;
}
bool init (HalType& hal) {
layoutChannels();
dumpSize();
// first initialize EEProm if needed
bool first = storage().setup(checksum());
if( first == true ) {
firstinit();
storage().store();
}
this->keystore().init();
this->setHal(hal);
HMID id;
this->getDeviceID(id);
hal.init(id);
hal.config(this->getConfigArea());
return first;
}
void initDone () {
// trigger initial config changed - to allow scan/caching of list data
this->hasConfigChanged(true);
this->configChanged();
for( uint8_t cdx=1; cdx<=channels(); ++cdx ) {
channel(cdx).configChanged();
}
// trigger save of storage
storage().store();
}
void firstinit () {
this->keystore().defaults(); // init aes key infrastructure
list0.defaults();
for( uint8_t i=0; i<this->channels(); ++i ) {
devchannels[i]->firstinit();
}
}
void reset () {
if( getList0().localResetDisable() == false ) {
DPRINTLN(F("RESET"));
storage().reset();
storage().store();
#if ARDUINO_ARCH_AVR
resetFunc();
#elif ARDUINO_ARCH_STM32F1
nvic_sys_reset();
#elif defined (ARDUINO_ARCH_STM32) && defined (STM32L1xx)
NVIC_SystemReset();
#elif ARDUINO_ARCH_ESP32
ESP.restart();
#elif ARDUINO_ARCH_EFM32
delay(250);
NVIC_SystemReset();
#endif
}
}
void bootloader () {
DPRINTLN(F("BOOTLOADER"));
#if ARDUINO_ARCH_AVR
wdt_enable(WDTO_250MS);
while(1);
#endif
}
void startPairing () {
this->sendDeviceInfo();
this->led().set(LedStates::pairing);
this->activity().stayAwake( seconds2ticks(20) ); // 20 seconds
}
ChannelType& channel(uint8_t ch) {
return *devchannels[ch-1];
}
bool pollRadio () {
bool worked = DeviceType::pollRadio();
for( uint8_t i=1; i<=this->channels(); ++i ) {
ChannelType& ch = channel(i);
if( ch.changed() == true ) {
bool ledEnableState = DeviceType::led().enable(); //save current enable state
DeviceType::led().enable(false); //deactivate LED when sending info message (cyclic, sabotage, ...)
this->sendInfoActuatorStatus(this->getMasterID(),this->nextcount(),ch);
DeviceType::led().enable(ledEnableState); //restore enable state
worked = true;
}
}
return worked;
}
bool aesActive () {
if( getList0().aesActive() == true ) {
return true;
}
for( uint8_t i=1; i<=this->channels(); ++i) {
if( channel(i).aesActive() == true ) {
return true;
}
}
return false;
}
bool validSignature(__attribute__((unused)) Message& msg) {
#ifdef USE_AES
if( aesActive() == true ) {
return this->requestSignature(msg);
}
#endif
return true;
}
bool validSignature(__attribute__((unused)) uint8_t ch, __attribute__((unused)) Message& msg) {
#ifdef USE_AES
if( (ch==0 && aesActive()) || (this->hasChannel(ch)==true && channel(ch).aesActive()==true) ) {
return this->requestSignature(msg);
}
#endif
return true;
}
bool process(Message& msg) {
uint8_t answer = REPLAY_NO;
ChannelType* ch = 0;
HMID devid;
this->getDeviceID(devid);
if( msg.to() == devid || this->isBroadcastMsg(msg) ) {
// we got a message - we do not answer before 100ms
this->radio().setSendTimeout(); // use default value from radio
DPRINT(F("-> "));
msg.dump();
// ignore repeated messages and store info if the last message came from same device
uint8_t samefromID = (lastdev == msg.from());
if (samefromID && lastcnt == msg.count()) {
return false;
}
lastdev = msg.from();
lastcnt = msg.count();
//is Device already paired to a master / CCU ?
bool isPaired = HMID::broadcast != this->getMasterID();
//received message is from our paired master / CCU ?
bool msgIsFromMaster = msg.from() == this->getMasterID();
// start processing the message
uint8_t mtype = msg.type();
uint8_t mcomm = msg.command();
uint8_t msubc = msg.subcommand();
if( mtype == AS_MESSAGE_CONFIG ) {
//we are already paired, but the CONFIG message does not come from master / CCU
if( isPaired == true && msgIsFromMaster == false ) {
//DPRINTLN(F("-> message for us, but from wrong master address."));
return false;
}
// PAIR_SERIAL
if( msubc == AS_CONFIG_PAIR_SERIAL && this->isDeviceSerial(msg.data())==true ) {
this->led().set(LedStates::pairing);
this->activity().stayAwake( seconds2ticks(20) ); // 20 seconds
this->sendDeviceInfo(msg.from(),msg.length());
}
// CONFIG_PEER_ADD
else if ( msubc == AS_CONFIG_PEER_ADD ) {
const ConfigPeerAddMsg& pm = msg.configPeerAdd();
bool success = false;
if( this->hasChannel(pm.channel()) == true ) {
if( validSignature(pm.channel(),msg) == true ) {
ch = &channel(pm.channel());
if( pm.peers() == 1 ) {
success = ch->peer(pm.peer1());
}
else {
success = ch->peer(pm.peer1(),pm.peer2());
}
}
}
if( success == true ) {
this->hasConfigChanged(true);
ch->configChanged();
storage().store();
answer = REPLAY_ACK;
}
else {
answer = REPLAY_NACK;
}
}
// CONFIG_PEER_REMOVE
else if ( msubc == AS_CONFIG_PEER_REMOVE ) {
const ConfigPeerRemoveMsg& pm = msg.configPeerRemove();
bool success = false;
if( this->hasChannel(pm.channel()) == true ) {
if( validSignature(pm.channel(),msg) == true ) {
ch = &channel(pm.channel());
success = ch->deletepeer(pm.peer1());
if( pm.peers() == 2 ) {
success &= ch->deletepeer(pm.peer2());
}
}
}
if( success == true ) {
this->hasConfigChanged(true);
ch->configChanged();
storage().store();
answer = REPLAY_ACK;
}
else {
answer = REPLAY_NACK;
}
}
// CONFIG_PEER_LIST_REQ
else if( msubc == AS_CONFIG_PEER_LIST_REQ ) {
const ConfigPeerListReqMsg& pm = msg.configPeerListReq();
if( this->hasChannel(pm.channel()) == true ) {
this->sendInfoPeerList(msg.from(),msg.count(),channel(pm.channel()));
}
}
// CONFIG_PARAM_REQ
else if (msubc == AS_CONFIG_PARAM_REQ ) {
const ConfigParamReqMsg& pm = msg.configParamReq();
GenericList gl = findList(pm.channel(),pm.peer(),pm.list());
if( gl.valid() == true ) {
this->sendInfoParamResponsePairs(msg.from(),msg.count(),gl);
}
else {
answer = REPLAY_NACK;
}
}
// CONFIG_STATUS_REQUEST
else if (msubc == AS_CONFIG_STATUS_REQUEST ) {
// this is an answer to a request - so we need no ack
this->sendInfoActuatorStatus(msg.from(),msg.count(),channel(msg.command()),false);
}
// CONFIG_START
else if( msubc == AS_CONFIG_START ) {
const ConfigStartMsg& pm = msg.configStart();
if( validSignature(pm.channel(),msg) == true ) {
cfgChannel = pm.channel();
cfgList = findList(cfgChannel,pm.peer(),pm.list());
// TODO setup alarm to disable after 2000ms
answer = REPLAY_ACK;
}
else {
answer = REPLAY_NACK;
}
}
// CONFIG_END
else if( msubc == AS_CONFIG_END ) {
this->hasConfigChanged(true);
if( cfgList.address() == list0.address() ) {
this->led().set(LedStates::nothing);
this->configChanged();
}
else {
// signal list update to channel
channel(cfgChannel).configChanged();
}
cfgChannel = 0xff;
storage().store();
// TODO cancel alarm
this->sendAck(msg,Message::WKMEUP);
}
else if( msubc == AS_CONFIG_WRITE_INDEX ) {
const ConfigWriteIndexMsg& pm = msg.configWriteIndex();
if( validSignature(pm.channel(),msg)==true ) {
if( cfgChannel == pm.channel() && cfgList.valid() == true ) {
this->writeList(cfgList,pm.data(),pm.datasize());
}
answer = REPLAY_ACK;
}
else {
answer = REPLAY_NACK;
}
}
else if( msubc == AS_CONFIG_SERIAL_REQ ) {
this->sendSerialInfo(msg.from(),msg.count());
}
else {
answer = REPLAY_NACK;
}
}
else if( mtype == AS_MESSAGE_ACTION ) {
//we are paired to a master / CCU, but the ACTION message does not come from master / CCU
if( isPaired==true && msgIsFromMaster==false ) {
//DPRINTLN(F("-> message for us, but from wrong master address."));
return false;
}
if ( mcomm == AS_ACTION_RESET || mcomm == AS_ACTION_ENTER_BOOTLOADER ) {
if( validSignature(msg) == true ) {
this->sendAck(msg);
if( mcomm == AS_ACTION_ENTER_BOOTLOADER ) {
bootloader();
}
else {
reset();
}
}
}
#ifndef SENSOR_ONLY
else {
const ActionMsg& pm = msg.action();
if( this->hasChannel(pm.channel())==true ) {
ch = &channel(pm.channel());
if( validSignature(pm.channel(),msg)==true ) {
switch( mcomm ) {
case AS_ACTION_INHIBIT_OFF:
ch->inhibit(false);
answer = REPLAY_ACK;
break;
case AS_ACTION_INHIBIT_ON:
ch->inhibit(true);
answer = REPLAY_ACK;
break;
case AS_ACTION_STOP_CHANGE:
ch->stop();
answer = REPLAY_ACK;
break;
case AS_ACTION_SET:
if( ch->inhibit() == false ) {
answer = ch->process(msg.actionSet()) ? REPLAY_ACK : REPLAY_NACK;
}
break;
case AS_ACTION_COMMAND:
if( ch->inhibit() == false ) {
answer = ch->process(msg.actionCommand()) ? REPLAY_ACK : REPLAY_NACK;
}
break;
}
}
}
}
#endif
}
else if( mtype == AS_MESSAGE_HAVE_DATA ) {
DPRINTLN(F("HAVE DATA"));
answer = REPLAY_ACK;
}
#ifndef SENSOR_ONLY
else if (mtype == AS_MESSAGE_SWITCH_EVENT) {
RemoteEventMsg& pm = msg.switchSim().toEventMsg();
//DPRINT(F("X> ")); pm.dump();
for (uint8_t cdx = 1; cdx <= this->channels(); ++cdx) {
ChannelType* c = &channel(cdx);
if (c->inhibit() == false && c->has(pm.peer()) == true) {
c->process(pm);
}
}
answer = REPLAY_ACK;
}
else if (mtype == AS_MESSAGE_REMOTE_EVENT || mtype == AS_MESSAGE_SENSOR_EVENT) {
static uint8_t lastcntr, lastbcst;
uint8_t cntr;
answer = REPLAY_NACK;
const RemoteEventMsg& pm = msg.remoteEvent();
uint8_t processed = 0;
for( uint8_t cdx=1; cdx<=this->channels(); ++cdx ) {
ChannelType* c = &channel(cdx);
if( c->inhibit() == false && c->has(pm.peer()) == true ) {
if( processed > 0 || validSignature(cdx,msg) == true ) {
++processed;
ch = c;
switch( mtype ) {
case AS_MESSAGE_REMOTE_EVENT:
// check if it is a repeated broadcast message addressed now to us
cntr = msg.remoteEvent().counter();
if (lastbcst && samefromID && cntr == lastcntr && !msg.remoteEvent().isLong()) {
//DPRINTLN(F("repeat broadcast"));
}
else {
ch->process(pm);
}
lastcntr = cntr;
lastbcst = msg.isBroadcast();
break;
case AS_MESSAGE_SENSOR_EVENT:
ch->process(msg.sensorEvent());
break;
}
answer = REPLAY_ACK;
}
}
}
if( processed > 1 ) {
// we had more than one channel processed
// clear channel, so we only send an ACK
ch = 0;
}
}
#endif
#ifdef USE_AES
else if (mtype == AS_MESSAGE_KEY_EXCHANGE ) {
if( isPaired==false || msgIsFromMaster==false ) { return false; }
if( validSignature(msg) == true ) {
if( this->keystore().exchange(msg.aesExchange())==true ) answer = REPLAY_ACK;
else answer = REPLAY_NACK;
}
}
#endif
// default - send Nack if answer is requested
else {
answer = REPLAY_NACK;
}
}
else {
#ifndef HIDE_IGNORE_MSG
DPRINT(F("ignore "));
msg.dump();
#endif
return false;
}
// send ack/nack
if( msg.ackRequired() == true && msg.to() == devid ) {
if( answer == REPLAY_ACK ) {
if( ch != 0 ) this->sendAck(msg, *ch);
else this->sendAck(msg);
}
else if( answer == REPLAY_NACK ) {
this->sendNack(msg);
}
}
// we always stay awake after valid communication
this->activity().stayAwake(millis2ticks(500));
return true;
}
GenericList findList(uint8_t ch,const Peer& peer,uint8_t numlist) {
if (numlist == 0) {
return list0;
} else if (this->hasChannel(ch) == true) {
ChannelType& c = channel(ch);
if (numlist == 1) {
return c.getList1();
} else if (c.hasList2() && numlist == 2) {
return c.getList2();
} else if (c.hasList3() && numlist == 3) {
return c.getList3(peer);
} else if (c.hasList4() && numlist == 4) {
return c.getList4(peer);
}
}
return GenericList();
}
void sendPeerEvent (Message& msg,const ChannelType& ch) {
// we send only to peers if there is no config message pending
if( cfgChannel != 0xff ) {
DeviceType::sendPeerEvent(msg,ch);
}
}
};
template <class HalType,class ChannelType,int ChannelCount,class List0Type=List0>
class MultiChannelDevice : public ChannelDevice<HalType,ChannelType,ChannelCount,List0Type> {
ChannelType cdata[ChannelCount];
public:
typedef ChannelDevice<HalType,ChannelType,ChannelCount,List0Type> DeviceType;
MultiChannelDevice (const DeviceInfo& i,uint16_t addr) : ChannelDevice<HalType,ChannelType,ChannelCount,List0Type>(i,addr) {
for( uint8_t i=0; i<ChannelCount; ++i ) {
this->registerChannel(cdata[i], i+1);
}
}
virtual ~MultiChannelDevice () {}
};
}
#endif