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Working inital version

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This commit is contained in:
Gregor Baues 2021-05-19 09:49:18 +02:00
parent 981453d399
commit c3abb0018d
14 changed files with 1053 additions and 845 deletions
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19
CommandDistributor.cpp
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@ -19,18 +19,21 @@
#include <Arduino.h>
#include "CommandDistributor.h"
#include "WiThrottle.h"
#include "DIAG.h"
DCCEXParser * CommandDistributor::parser=0;
DCCEXParser *CommandDistributor::parser = 0;
void CommandDistributor::parse(byte clientId,byte * buffer, RingStream * streamer) {
DIAG(F("CDS %d : %s : %x"), clientId, (char *) buffer, streamer);
if (buffer[0] == '<') {
if (!parser) parser = new DCCEXParser();
void CommandDistributor::parse(byte clientId, byte *buffer, RingStream *streamer)
{
if (buffer[0] == '<')
{
if (!parser)
{
parser = new DCCEXParser();
}
parser->parse(streamer, buffer, streamer);
}
else {
DIAG(F("CDS WiThrottle"));
else
{
WiThrottle::getThrottle(clientId)->parse(streamer, buffer);
}
}

60
CommandStation-EX.ino
View File

@ -16,14 +16,13 @@
// If config.h is not found, config.example.h will be used with all defaults.
////////////////////////////////////////////////////////////////////////////////////
#if __has_include ( "config.h")
#include "config.h"
#if __has_include("config.h")
#include "config.h"
#else
#warning config.h not found. Using defaults from config.example.h
#include "config.example.h"
#warning config.h not found. Using defaults from config.example.h
#include "config.example.h"
#endif
/*
* © 2020,2021 Chris Harlow, Harald Barth, David Cutting,
* Fred Decker, Gregor Baues, Anthony W - Dayton All rights reserved.
@ -43,7 +42,6 @@
* along with CommandStation. If not, see <https://www.gnu.org/licenses/>.
*/
#include "DCCEX.h"
// Create a serial command parser for the USB connection,
@ -59,13 +57,14 @@ void setup()
// This is normally Serial but uses SerialUSB on a SAMD processor
Serial.begin(115200);
CONDITIONAL_LCD_START {
CONDITIONAL_LCD_START
{
// This block is still executed for DIAGS if LCD not in use
LCD(0,F("DCC++ EX v%S"),F(VERSION));
LCD(1,F("Starting"));
LCD(0, F("DCC++ EX v%S"), F(VERSION));
LCD(1, F("Starting"));
}
// Start the WiFi interface on a MEGA, Uno cannot currently handle WiFi
// Start the WiFi interface on a MEGA, Uno cannot currently handle WiFi
#if WIFI_ON
WifiInterface::setup(WIFI_SERIAL_LINK_SPEED, F(WIFI_SSID), F(WIFI_PASSWORD), F(WIFI_HOSTNAME), IP_PORT, WIFI_CHANNEL);
@ -76,12 +75,9 @@ void setup()
#endif // ETHERNET_ON
#if MQTT_ON
DccMQTT::get()->setup();
MQTTInterface::setup();
#endif
// Responsibility 3: Start the DCC engine.
// Note: this provides DCC with two motor drivers, main and prog, which handle the motor shield(s)
// Standard supported devices have pre-configured macros but custome hardware installations require
@ -89,25 +85,26 @@ void setup()
// STANDARD_MOTOR_SHIELD, POLOLU_MOTOR_SHIELD, FIREBOX_MK1, FIREBOX_MK1S are pre defined in MotorShields.h
DCC::begin(MOTOR_SHIELD_TYPE);
#if defined(RMFT_ACTIVE)
#if defined(RMFT_ACTIVE)
RMFT::begin();
#endif
#endif
#if __has_include ( "mySetup.h")
#define SETUP(cmd) serialParser.parse(F(cmd))
#include "mySetup.h"
#undef SETUP
#endif
#if __has_include("mySetup.h")
#define SETUP(cmd) serialParser.parse(F(cmd))
#include "mySetup.h"
#undef SETUP
#endif
#if defined(LCN_SERIAL)
#if defined(LCN_SERIAL)
LCN_SERIAL.begin(115200);
LCN::init(LCN_SERIAL);
#endif
#endif
LCD(1,F("Ready"));
LCD(1, F("Ready"));
}
void loop()
@ -125,21 +122,22 @@ void loop()
#if WIFI_ON
WifiInterface::loop();
#endif
#if ETHERNET_ON
EthernetInterface::loop();
#endif
#if MQTT_ON
DccMQTT::get()->loop();
#endif
#if MQTT_ON
MQTTInterface::loop();
#endif
#if defined(RMFT_ACTIVE)
RMFT::loop();
#endif
#if defined(LCN_SERIAL)
#if defined(LCN_SERIAL)
LCN::loop();
#endif
#endif
LCDDisplay::loop(); // ignored if LCD not in use
@ -150,6 +148,6 @@ void loop()
if (freeNow < ramLowWatermark)
{
ramLowWatermark = freeNow;
LCD(2,F("Free RAM=%5db"), ramLowWatermark);
LCD(2, F("Free RAM=%5db"), ramLowWatermark);
}
}

2
DCCEX.h
View File

@ -16,7 +16,7 @@
#endif
#if MQTT_ON == true
#include "DccMQTT.h"
#include "MQTTInterface.h"
#endif
#include "LCD_Implementation.h"

6
DCCEXParser.cpp
View File

@ -499,17 +499,11 @@ void DCCEXParser::parse(Print *stream, byte *com, RingStream * ringStream)
return;
case 's': // <s>
// DIAG(F("s1"));
StringFormatter::send(stream, F("<p%d>\n"), DCCWaveform::mainTrack.getPowerMode() == POWERMODE::ON);
// DIAG(F("s2"));
StringFormatter::send(stream, F("<iDCC-EX V-%S / %S / %S G-%S>\n"), F(VERSION), F(ARDUINO_TYPE), DCC::getMotorShieldName(), F(GITHUB_SHA));
// DIAG(F("s3"));
Turnout::printAll(stream); //send all Turnout states
// DIAG(F("s4"));
Output::printAll(stream); //send all Output states
// DIAG(F("s5"));
Sensor::printAll(stream); //send all Sensor states
//DIAG(F("s6"));
// TODO Send stats of speed reminders table
return;

500
DccMQTT.cpp
View File

@ -1,500 +0,0 @@
/**
* @file DccMQTT.cpp
* @author Gregor Baues
* @brief MQTT protocol controller for DCC-EX. Sets up and maintains the connection to the MQTT broker incl setting up the topics.
* Topics are created specifically for the command station on which the code runs. Manages subsriptions as well as recieving/sending of messages on the different topics.
* @version 0.1
* @date 2020-07-08
*
* @copyright Copyright (c) 2020
*
* This is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* It is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details <https://www.gnu.org/licenses/>.
*
* Notes:
* At most 20 channels are allowed (MAXMQTTCONNECTIONS ) this can be pushed put to 255
* notwithstanding memeory consumption for maintaining the session info
*
* once the channel is open i.E the topic id has been send via MQ the CS will subscribe to
* clientid/topicid/cmd for recieveing commands and publish on
* clientid/topicid/diag
* clientid/topicid/result
* i.e. the consumer connected via MQTT to the cs has/should to subscribe to
* clientid/topicid/diag
* clientid/topicid/result
* and publish on clientid/topicid/cmd
*/
#if __has_include("config.h")
#include "config.h"
#else
#warning config.h not found. Using defaults from config.example.h
#include "config.example.h"
#endif
#include "defines.h"
#include <Arduino.h>
#include <avr/pgmspace.h>
#include <EthernetInterface.h>
#include <PubSubClient.h>
#include <DIAG.h>
#include <Ethernet.h>
#include <Dns.h>
#include <DCCTimer.h>
#include <DccMQTT.h>
#include <CommandDistributor.h>
#include <Queue.h>
#include <ObjectPool.h>
#include <errno.h>
#include <limits.h>
#include <inttypes.h>
#include <freeMemory.h>
//---------
// Variables
//---------
DccMQTT DccMQTT::singleton;
auto mqtt = DccMQTT::get();
// The RingBuffer size / no Withrottle over MQ so we don't need the huge buffer as for ethernet
#define OUT_BOUND_SIZE 256
// pairing functions used for creating a client identifier
// when a external system connects via MQ to the CS i.e. subscribes to the main channel the first message to be published
// shall be a admin message with a random number
// the cs will based on a counter use a second number to create the cantor encoding of both numbers and publish the cantor code
// this message will be seen by all throttles and they can decode the number which provides the first number they send and the
// second number to be used as tpoic for the external system from then on. The CS will recieve on all topics the commands and
// during processing then send the replies to the topic from which the command was recieved.
// Thus the main channel shall not be used for any p2p coms ev just for broadcast from the CS to the subscribed clients
long cantorEncode(long a, long b)
{
return (((a + b) * (a + b + 1)) / 2) + b;
}
void cantorDecode(int32_t c, int *a, int *b)
{
int w = floor((sqrt(8 * c + 1) - 1) / 2);
int t = (w * (w + 1)) / 2;
*b = c - t;
*a = w - *b;
}
/**
* @brief Copies an byte array to a hex representation as string; used for generating the unique Arduino ID
*
* @param array array containing bytes
* @param len length of the array
* @param buffer buffer to which the string will be written; make sure the buffer has appropriate length
*/
static void array_to_string(byte array[], unsigned int len, char buffer[])
{
for (unsigned int i = 0; i < len; i++)
{
byte nib1 = (array[i] >> 4) & 0x0F;
byte nib2 = (array[i] >> 0) & 0x0F;
buffer[i * 2 + 0] = nib1 < 0xA ? '0' + nib1 : 'A' + nib1 - 0xA;
buffer[i * 2 + 1] = nib2 < 0xA ? '0' + nib2 : 'A' + nib2 - 0xA;
}
buffer[len * 2] = '\0';
}
// callback when a message arrives from the broker; push cmd into the incommming queue
void mqttCallback(char *topic, byte *payload, unsigned int length)
{
auto clients = mqtt->getClients();
errno = 0;
payload[length] = '\0'; // make sure we have the string terminator in place
DIAG(F("MQTT Callback:[%s] [%s] [%d]"), topic, (char *)payload, length);
switch (payload[0])
{
case '<':
{
const char s[2] = "/"; // topic delimiter is /
char *token;
byte mqsocket;
/* get the first token = ClientID */
token = strtok(topic, s);
/* get the second token = topicID */
token = strtok(NULL, s);
if (token == NULL)
{
DIAG(F("Can't identify sender #1; command send on wrong topic"));
return;
// don't do anything as we wont know where to send the results
// normally the topicid shall be valid as we only have subscribed to that one and nothing else
// comes here; The only issue is when recieveing on the open csid channel ( which stays open in order to
// able to accept other connections )
}
else
{
auto topicid = atoi(token);
// verify that there is a MQTT client with that topic id connected
bool isClient = false;
// check in the array of clients if we have one with the topicid
// start at 1 as 0 is not allocated as mqsocket
for (int i = 1; i <= mqtt->getClientSize(); i++)
{
if (clients[i].topic == topicid)
{
isClient = true;
mqsocket = i;
break;
}
}
if (!isClient)
{
// no such client connected
DIAG(F("Can't identify sender #2; command send on wrong topic"));
return;
}
}
// if we make it until here we dont even need to test the last "cmd" element from the topic as there is no
// subscription for anything else
// DIAG(F("MQTT Message arrived on [%s]: [%d]"), buf, topicid);
// Prepare the DCC-EX command
auto pool = mqtt->getPool(); // message pool
auto q = mqtt->getIncomming(); // incomming queue
csmsg_t tm; // topic message
if (length + 1 > MAXPAYLOAD)
{
DIAG(F("MQTT Command too long (> %d characters)"), MAXPAYLOAD);
}
strlcpy(tm.cmd, (char *)payload, length + 1); // message payload
tm.mqsocket = mqsocket; // on which socket did we recieve the mq message
int idx = pool->setItem(tm); // Add the recieved command to the pool
if (idx == -1)
{
DIAG(F("MQTT Command pool full. Could not handle recieved command."));
return;
}
q->push(idx); // Add the index of the pool item to the incomming queue
DIAG(F("MQTT Message arrived [%s]: [%s]"), topic, tm.cmd);
break;
}
case 'm':
{
switch (payload[1])
{
case 'i':
{
char buffer[30];
char *tmp = (char *)payload + 3;
strlcpy(buffer, tmp, length);
buffer[length - 4] = '\0';
// DIAG(F("MQTT buffer %s - %s - %s - %d"), payload, tmp, buffer, length);
auto distantid = strtol(buffer, NULL, 10);
if (errno == ERANGE || distantid > UCHAR_MAX)
{
DIAG(F("Invalid Handshake ID; must be between 0 and 255"));
return;
}
if (distantid == 0)
{
DIAG(F("Invalid Handshake ID"));
return;
}
// ---------------------------
// Create a new MQTT client
// ---------------------------
// check in the clients if the distantid has been set already somewhere
// if so we either have a new one with the same id then we have a collision -> publish a collision
// or its the same i.e; the message comming back as we are subscribed -> stop here
// All is ok so set up the channel; MQTT Ctrl command
auto subscriberid = DccMQTT::get()->obtainSubscriberID(); // to be used in the parsing process for the clientid in the ringbuffer
if (subscriberid == 0)
{
DIAG(F("MQTT no more connections are available"));
return;
}
auto topicid = cantorEncode((long)subscriberid, (long)distantid);
DIAG(F("MQTT Ctrl Message arrived [%s] : subscriber [%d] : distant [%d] : topic: [%d]"), buffer, subscriberid, (int)distantid, topicid);
// extract the number delivered from
// we need to check if the id we got from the client has been used allready and if yes reject and ask for a different one
// initalize the new mqtt client object
clients[subscriberid] = {(int)distantid, subscriberid, topicid, true};
// add/subcribe to the topic for listening on cmds recieved via the channel for the client with
// subscriberid as identifier
char tbuffer[(CLIENTIDSIZE * 2) + 1 + MAXTOPICLENGTH];
mqtt->getSubscriberTopic(subscriberid, tbuffer);
auto ok = mqtt->subscribe(tbuffer);
DIAG(F("MQTT new subscriber topic: %s %s"), tbuffer, ok ? "OK" : "NOK");
// send the topicid on which the CS will listen for commands to the MQTT client on the root topic
memset(buffer, 0, 30);
sprintf(buffer, "mc(%d,%ld)", (int)distantid, topicid);
DIAG(F("Publishing: [%s] to [%s]"), buffer, mqtt->getClientID());
mqtt->publish(mqtt->getClientID(), buffer);
// on the cs side all is set and we declare that the cs is open for business
clients[subscriberid].open = true;
// we now need to subscribe to the ../clientid/topicid/cmd topic as we shall recieve the cmds from there
// in the < case we should test that we got the command on the right topic ...
DIAG(F("MQTT CS is listening for commands on [%s]"), tbuffer);
memset(buffer, 0, 30);
sprintf(buffer, "%s/%ld/result", mqtt->getClientID(), topicid);
DIAG(F("MQTT CS is publishing return information to [%s]"), buffer);
memset(buffer, 0, 30);
sprintf(buffer, "%s/%ld/diag", mqtt->getClientID(), topicid);
DIAG(F("MQTT CS is publishing diagnostic information to [%s]"), buffer);
return;
}
default:
{
// ignore
return;
}
}
}
default:
{
// invalid command
DIAG(F("MQTT Invalid DCC-EX command: %s"), (char *)payload);
break;
}
}
}
/**
* @brief MQTT broker connection / reconnection
*
*/
void DccMQTT::connect()
{
int reconnectCount = 0;
connectID[0] = '\0';
// Build the connect ID : Prefix + clientID
if (broker->prefix != nullptr)
{
strcpy_P(connectID, (const char *)broker->prefix);
}
strcat(connectID, clientID);
// Connect to the broker
DIAG(F("MQTT %s (re)connecting ..."), connectID);
while (!mqttClient.connected() && reconnectCount < MAXRECONNECT)
{
DIAG(F("Attempting MQTT Broker connection[%d]..."), broker->cType);
switch (broker->cType)
{
// no uid no pwd
case 6:
case 1:
{ // port(p), ip(i), domain(d),
if (mqttClient.connect(connectID))
{
DIAG(F("MQTT Broker connected ..."));
mqState = CONNECTED;
}
else
{
DIAG(F("MQTT broker connection failed, rc=%d, trying to reconnect"), mqttClient.state());
reconnectCount++;
}
break;
}
// with uid passwd
case 5:
case 2:
{ // port(p), ip(i), domain(d), user(uid), pwd(pass),
break;
}
// with uid, passwd & prefix
case 4:
case 3:
{ // port(p), ip(i), domain(d), user(uid), pwd(pass), prefix(pfix)
// port(p), domain(d), user(uid), pwd(pass), prefix(pfix)
// mqttClient.connect(connectID, MQTT_BROKER_USER, MQTT_BROKER_PASSWD, "$connected", 0, true, "0", 0))
break;
}
}
if (reconnectCount == MAXRECONNECT)
{
DIAG(F("MQTT Connection aborted after %d tries"), MAXRECONNECT);
mqState = CONNECTION_FAILED;
}
}
}
// for the time being only one topic at the root which os the unique clientID from the MCU
// QoS is 0 by default
boolean DccMQTT::subscribe(char *topic)
{
return mqttClient.subscribe(topic);
}
void DccMQTT::publish(char *topic, char *payload)
{
mqttClient.publish(topic, payload);
}
/**
* @brief Public part of the MQTT setup function. Will call the secondary private setup function following the broker
* configuration from config.h
*
*/
void DccMQTT::setup()
{
// setup Ethnet connection first
byte mac[6];
DCCTimer::getSimulatedMacAddress(mac);
#ifdef IP_ADDRESS
Ethernet.begin(mac, IP_ADDRESS);
#else
if (Ethernet.begin(mac) == 0)
{
DIAG(F("Ethernet.begin FAILED"));
return;
}
#endif
DIAG(F("Ethernet.begin OK."));
if (Ethernet.hardwareStatus() == EthernetNoHardware)
{
DIAG(F("Ethernet shield not found"));
return;
}
if (Ethernet.linkStatus() == LinkOFF)
{
DIAG(F("Ethernet cable not connected"));
return;
}
IPAddress ip = Ethernet.localIP(); // reassign the obtained ip address
DIAG(F("IP: %d.%d.%d.%d"), ip[0], ip[1], ip[2], ip[3]);
DIAG(F("Port:%d"), IP_PORT);
// setup the MQBroker
setup(CSMQTTBROKER);
}
/**
* @brief Private part of the MQTT setup function. Realizes all required actions for establishing the MQTT connection.
*
* @param id Name provided to the broker configuration
* @param b MQTT broker object containing the main configuration parameters
*/
void DccMQTT::setup(const FSH *id, MQTTBroker *b)
{
//Create the MQTT environment and establish inital connection to the Broker
broker = b;
DIAG(F("MQTT Connect to %S at %S/%d.%d.%d.%d:%d"), id, broker->domain, broker->ip[0], broker->ip[1], broker->ip[2], broker->ip[3], broker->port);
byte mqbid[CLIENTIDSIZE] = {0};
DCCTimer::getSimulatedMacAddress(mqbid);
// initalize MQ Broker
mqttClient = PubSubClient(broker->ip, broker->port, mqttCallback, ethClient);
DIAG(F("MQTT Client created ok..."));
array_to_string(mqbid, CLIENTIDSIZE, clientID);
DIAG(F("MQTT Client ID : %s"), clientID);
connect(); // inital connection as well as reconnects
auto sub = DccMQTT::subscribe(clientID); // set up all subscriptions
DIAG(F("MQTT subscriptons %s..."), sub ? "ok" : "failed");
outboundRing = new RingStream(OUT_BOUND_SIZE);
}
void DccMQTT::loop()
{
// Connection impossible so just don't do anything
if (mqState == CONNECTION_FAILED)
{
return;
}
if (!mqttClient.connected())
{
connect();
}
if (!mqttClient.loop())
{
DIAG(F("mqttClient returned with error; state: %d"), mqttClient.state());
};
// read incomming queue for processing; one per loop
bool state;
DIAG(F("in.count: %d"), in.count());
if (in.count() > 0)
{
auto idx = in.peek();
auto c = pool.getItem(in.pop(), &state);
DIAG(F("MQTT Processing pool: %d with command: %s from client %d"), idx, c->cmd, c->mqsocket);
DIAG(F("Ring free space1: %d"), outboundRing->freeSpace());
outboundRing->mark((uint8_t)c->mqsocket);
CommandDistributor::parse(c->mqsocket, (byte *)c->cmd, outboundRing);
// StringFormatter::send(outboundRing, F("Test result message"));
outboundRing->commit();
DIAG(F("Ring free space2: %d"), outboundRing->freeSpace());
pool.returnItem(idx);
}
// handle at most 1 outbound transmission
int socketOut = outboundRing->read();
DIAG(F("socketOut: %d"), socketOut);
if (socketOut > 0) // mqsocket / clientid can't be 0 ....
{
int count = outboundRing->count();
buffer[0] = '\0';
sprintf(buffer, "%s/%d/result", clientID, (int)clients[socketOut].topic);
DIAG(F("MQTT publish to mqsocket=%d, count=:%d on topic %s"), socketOut, count, buffer);
// construct the payload
char payload[count];
payload[count] = '\0';
char *tmp = payload;
for (; count > 0; count--)
{
*tmp = (char)outboundRing->read();
tmp++;
}
// DIAG(F("Ring free space4: %d"),outboundRing->freeSpace());
DIAG(F("MQTT publish with payload:\n%s"), payload);
// mqtt->publish(buffer, payload);
}
}

275
DccMQTT.h
View File

@ -1,275 +0,0 @@
#ifndef _DccMQTT_h_
#define _DccMQTT_h_
#if __has_include("config.h")
#include "config.h"
#else
#warning config.h not found. Using defaults from config.example.h
#include "config.example.h"
#endif
#include "defines.h"
#include <PubSubClient.h>
#include <DCCEXParser.h>
#include <Queue.h>
#include <Ethernet.h>
#include <Dns.h>
#include <ObjectPool.h>
#include <limits.h>
#define MAXPAYLOAD 64
#define MAXDOMAINLENGTH 32
#define MAXTBUF 50 //!< max length of the buffer for building the topic name ;to be checked
#define MAXTMSG 120 //!< max length of the messages for a topic ;to be checked PROGMEM ?
#define MAXTSTR 30 //!< max length of a topic string
#define MAXCONNECTID 40 // Broker connection id length incl possible prefixes
#define CLIENTIDSIZE 6 //
#define MAXRECONNECT 5 // reconnection tries before final failure
#define MAXMQTTCONNECTIONS 20 // maximum number of unique tpoics available for subscribers
#define MAXTOPICLENGTH 20
// Define Broker configurations; Values are provided in the following order
// MQTT_BROKER_PORT 9883
// MQTT_BROKER_DOMAIN "dcclms.modelrailroad.ovh"
// MQTT_BROKER_ADDRESS 51, 210, 151, 143
// MQTT_BROKER_USER "dcccs"
// MQTT_BROKER_PASSWD "dcccs$3020"
// MQTT_BROKER_CLIENTID_PREFIX "dcc$lms-"
struct MQTTBroker
{
int port;
IPAddress ip;
const FSH *domain = nullptr;
const FSH *user = nullptr;
const FSH *pwd = nullptr;
const FSH *prefix = nullptr;
byte cType; // connection type to identify valid params
IPAddress resovleBroker(const FSH *d){
DNSClient dns;
IPAddress bip;
char domain[MAXDOMAINLENGTH];
strcpy_P(domain, (const char *)d);
dns.begin(Ethernet.dnsServerIP());
if (dns.getHostByName(domain, bip) == 1)
{
DIAG(F("MQTT Broker/ %s = %d.%d.%d.%d"), domain, bip[0], bip[1],bip[2],bip[3]);
}
else
{
DIAG(F("MQTT Dns lookup for %s failed"), domain);
}
return bip;
}
MQTTBroker(int p, IPAddress i, const FSH *d) : port(p), ip(i), domain(d), cType(1) {};
MQTTBroker(int p, IPAddress i, const FSH *d, const FSH *uid, const FSH *pass) : port(p), ip(i), domain(d), user(uid), pwd(pass), cType(2){};
MQTTBroker(int p, IPAddress i, const FSH *d, const FSH *uid, const FSH *pass, const FSH *pfix) : port(p), ip(i), domain(d), user(uid), pwd(pass), prefix(pfix), cType(3){};
MQTTBroker(int p, const FSH *d, const FSH *uid, const FSH *pass, const FSH *pfix) : port(p), domain(d), user(uid), pwd(pass), prefix(pfix), cType(4)
{
ip = resovleBroker(d);
};
MQTTBroker(int p, const FSH *d, const FSH *uid, const FSH *pass) : port(p), domain(d), user(uid), pwd(pass), cType(5)
{
ip = resovleBroker(d);
};
MQTTBroker(int p, const FSH *d) : port(p), domain(d), cType(6)
{
ip = resovleBroker(d);
};
};
/**
* @brief dcc-ex command as recieved via MQ
*
*/
typedef struct csmsg_t {
char cmd[MAXPAYLOAD]; // recieved command message
byte mqsocket; // from which mqsocket / subscriberid
} csmsg_t;
typedef struct csmqttclient_t {
int distant; // random int number recieved from the subscriber
byte mqsocket; // mqtt socket = subscriberid provided by the cs
long topic; // cantor(subscriber,cs) encoded tpoic used to send / recieve commands
bool open; // true as soon as we have send the id to the mq broker for the client to pickup
} csmqttclient_t;
enum DccMQTTState
{
INIT,
CONFIGURED, // server/client objects set
CONNECTED, // mqtt broker is connected
CONNECTION_FAILED // Impossible to get the connection set after MAXRECONNECT tries
};
class DccMQTT
{
private:
// Methods
DccMQTT() = default;
DccMQTT(const DccMQTT &); // non construction-copyable
DccMQTT &operator=(const DccMQTT &); // non copyable
void setup(const FSH *id, MQTTBroker *broker);
void connect(); // (re)connects to the broker
// Members
static DccMQTT singleton;
EthernetClient ethClient; // TCP Client object for the MQ Connection
IPAddress server; // MQTT server object
PubSubClient mqttClient; // PubSub Endpoint for data exchange
MQTTBroker *broker; // Broker configuration object as set in config.h
ObjectPool<csmsg_t,MAXPOOLSIZE> pool; // Pool of commands recieved for the CS
Queue<int> in; // Queue of indexes into the pool according to incomming cmds
char clientID[(CLIENTIDSIZE*2)+1]; // unique ID of the commandstation; not to confused with the connectionID
csmqttclient_t clients[MAXMQTTCONNECTIONS]; // array of connected mqtt clients
char connectID[MAXCONNECTID]; // clientId plus possible prefix if required by the broker
uint8_t subscriberid = 0; // id assigned to a mqtt client when recieving the inital handshake; +1 at each connection
DccMQTTState mqState = INIT;
RingStream *outboundRing;
char buffer[MAXTMSG]; // temp buffer for manipulating strings / messages
public:
static DccMQTT *get() noexcept
{
return &singleton;
}
boolean subscribe(char *topic);
void publish(char *topic, char* payload);
bool isConfigured() { return mqState == CONFIGURED; };
bool isConnected() { return mqState == CONNECTED; };
void setState(DccMQTTState s) { mqState = s; };
ObjectPool<csmsg_t,MAXPOOLSIZE> *getPool() { return &pool; };
Queue<int> *getIncomming() { return &in; };
char *getClientID() { return clientID; };
uint8_t getClientSize() { return subscriberid; }
// initalized to 0 so that the first id comming back is 1
// index 0 in the clients array is not used therefore
//! improvement here to be done to save some bytes
uint8_t obtainSubscriberID(){
if ( subscriberid == MAXMQTTCONNECTIONS) {
return 0; // no more subscriber id available
}
return (++subscriberid);
}
// this could be calculated once forever at each new connect and be stored
// but to save space we calculate it at each publish
void getSubscriberTopic( uint8_t subscriberid, char *tbuffer ){
sprintf(tbuffer, "%s/%ld/cmd", clientID, (long) clients[subscriberid].topic);
}
csmqttclient_t *getClients() { return clients; };
void setup(); // called at setup in the main ino file
void loop();
~DccMQTT() = default;
};
// /**
// * @brief MQTT broker configuration done in config.h
// */
// // Class for setting up the MQTT connection / topics / queues for processing commands and sendig back results
// #define MAXDEVICEID 20 // maximum length of the unique id / device id
// #define MAXTOPICS 8 // command L,T,S,A plus response plus admin for inital handshake
// #define TCMDROOT "command/" // root of command topics
// #define TCMRESROOT "result/" // root of the result topic
// #define ADMROOT "admin/" // root of the admin topic where whe can do hanshakes for the inital setup
// ; // esp for sec reasons i.e. making sure we are talking to the right device and
// ; // not some one elses
// #define TELEMETRYROOT "telemetry/" // telemetry topic
// #define DIAGROOT "diag/" // diagnostics
// #define JRMIROOT "jrmi/"
// #define NOOFDCCTOPICS 11
// enum DccTopics {
// CMD_L, // L is Loco or Layout(power on/off)
// CMD_T,
// CMD_S,
// CMD_A,
// RESULT,
// ADMIN,
// TELEMETRY,
// DIAGNOSTIC,
// JRMI,
// INVALID_T
// };
// /**
// * @brief List of keywords used in the command protocol
// *
// */
// #define MAX_KEYWORD_LENGTH 11
// PROGMEM const char _kRead[] = {"read"};
// PROGMEM const char _kWrite[] = {"write"};
// PROGMEM const char _kPower[] = {"power"};
// PROGMEM const char _kThrottle[] = {"throttle"};
// PROGMEM const char _kFunction[] = {"function"};
// PROGMEM const char _kCv[] = {"cv"};
// PROGMEM const char _kSpeed[] = {"speed"};
// PROGMEM const char _kLocomotive[] = {"locomotive"};
// PROGMEM const char _kValue[] = {"value"};
// PROGMEM const char _kDirection[] = {"direction"};
// PROGMEM const char _kState[] = {"state"};
// PROGMEM const char _kFn[] = {"fn"};
// PROGMEM const char _kTrack[] = {"track"};
// PROGMEM const char _kBit[] = {"bit"};
// /**
// * @brief The ingoin and outgoing queues can hold 20 messages each; this should be bigger than the number
// * of statically allocated pool items whose pointers are getting pushed into the queues.
// *
// */
// #define MAXQUEUE 20 // MAX message queue length
// class DccMQTT
// {
// private:
// static char *deviceID; // Unique Device Identifier; based on the chip
// static Queue<int> inComming; // incomming messages queue; the queue only contains indexes to the message pool
// static Queue<int> outGoing; // outgoing messages queue; the queue only contains indexes to the message pool
// public:
// static char **topics; // list of pub/sub topics
// static PubSubClient *mqClient;
// static void setup(DCCEXParser p); // main entry to get things going
// static void loop(); // recieveing commands / processing commands / publish results
// static bool connected(); // true if the MQ client is connected
// static char *getDeviceID();
// static void setDeviceID();
// static void subscribe(); // subscribes to all relevant topics
// static void subscribeT(char *topic);// subscribe to a particular topic for other than the std ones in subscribe (e.g. telemetry)
// static void publish(); // publishes a JSON message constructed from the outgoing queue (cid and result)
// static void printTopics(); // prints the list of subscribed topics - debug use
// static bool inIsEmpty(); // test if the incomming queue is empty
// static bool outIsEmpty(); // test if the outgoing queue is empty
// static void pushIn(uint8_t midx); // push a command struct into the incomming queue for processing
// static void pushOut(uint8_t midx); // push a command struct into the incomming queue for processing
// static uint8_t popOut(); // pop a command struct with the result to be published
// static uint8_t popIn(); // pop a command struct from the in comming queue for processing
// static void pub_free_memory(int fm);
// DccMQTT();
// ~DccMQTT();
// };
#endif

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#ifndef _MQTTBrokers_h_
#define _MQTTBrokers_h_
// Define Broker configurations; Values are provided in the following order
// MQTT_BROKER_PORT 9883
// MQTT_BROKER_DOMAIN "dcclms.modelrailroad.ovh"
// MQTT_BROKER_ADDRESS 51, 210, 151, 143
// MQTT_BROKER_USER "dcccs"
// MQTT_BROKER_PASSWD "dcccs$3020"
// MQTT_BROKER_CLIENTID_PREFIX "dcc$lms-"
// Local server no user / pwd / prefix required
// EthernetShields / Arduino do not support securte transport i.e. on either port 443 or 8883 for MQTTS on most broker installations
// Once we support the ESP / Wifi as Transport medium we may get TLS capabilities for data in transit i.e. can use the 443/8883 ports
#define LOCAL_MQTT_BROKER F("LOCALMQ"), new MQTTBroker( 1883, {192, 168, 0, 51}, F("my.local.server"))
// Local server with user / pwd and no prefix
#define LOCAL_MQTT_USER_BROKER F("LOCALMQ"), new MQTTBroker( 1883, {192, 168, 0, 51}, F("my.local.server"), F("myuser"), F("mypassword"))
// Cloud server
#define DCCEX_MQTT_BROKER F("DCCEXMQ"), new MQTTBroker( 9883, {51, 210, 151, 143}, F("dcclms.modelrailroad.ovh"), F("dcccs"), F("dcccs$3020"), F("dcc$lms-"))
// Cloud server
#define DCCEX_MQTT_DOMAIN_BROKER F("DCCEXMQ"), new MQTTBroker( 9883, F("dcclms.modelrailroad.ovh"), F("dcccs"), F("dcccs$3020"), F("dcc$lms-"))
// Mosquitto test server
#define DCCEX_MOSQUITTO F("Mosquitto"), new MQTTBroker(1883, F("test.mosquitto.org"))
// HiveMQ test server
#define DCCEX_HIVEMQ F("HiveMQ"), new MQTTBroker(1883, F("broker.hivemq.com"))
#endif

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#if __has_include("config.h")
#include "config.h"
#else
#warning config.h not found. Using defaults from config.example.h
#include "config.example.h"
#endif
#include "defines.h"
#include "MQTTInterface.h"
#include "MQTTBrokers.h"
#include "DCCTimer.h"
#include <CommandDistributor.h>
#include <errno.h>
#include <limits.h>
MQTTInterface *MQTTInterface::singleton = NULL;
long cantorEncode(long a, long b)
{
return (((a + b) * (a + b + 1)) / 2) + b;
}
void cantorDecode(int32_t c, int *a, int *b)
{
int w = floor((sqrt(8 * c + 1) - 1) / 2);
int t = (w * (w + 1)) / 2;
*b = c - t;
*a = w - *b;
}
void MQTTInterface::setup()
{
singleton = new MQTTInterface();
if (!singleton->connected)
{
singleton = NULL;
}
if (Diag::MQTT)
DIAG(F("MQTT Interface instance: [%x] - Setup done"), singleton);
};
MQTTInterface::MQTTInterface()
{
this->connected = this->setupNetwork();
if (!this->connected)
{
DIAG(F("Network setup failed"));
}
else
{
this->setup(CSMQTTBROKER);
}
this->outboundRing = new RingStream(OUT_BOUND_SIZE);
};
/**
* @brief MQTT Interface callback recieving all incomming messages from the PubSubClient
*
* @param topic
* @param payload
* @param length
*/
void mqttCallback(char *topic, byte *payload, unsigned int length)
{
MQTTInterface *mqtt = MQTTInterface::get();
auto clients = mqtt->getClients();
errno = 0;
payload[length] = '\0'; // make sure we have the string terminator in place
if (Diag::MQTT)
DIAG(F("MQTT Callback:[%s] [%s] [%d] on interface [%x]"), topic, (char *)payload, length, mqtt);
switch (payload[0])
{
case '<':
{
const char s[2] = "/"; // topic delimiter is /
char *token;
byte mqsocket;
/* get the first token = ClientID */
token = strtok(topic, s);
/* get the second token = topicID */
token = strtok(NULL, s);
if (token == NULL)
{
DIAG(F("MQTT Can't identify sender #1; command send on wrong topic"));
return;
// don't do anything as we wont know where to send the results
// normally the topicid shall be valid as we only have subscribed to that one and nothing else
// comes here; The only issue is when recieveing on the open csid channel ( which stays open in order to
// able to accept other connections )
}
else
{
auto topicid = atoi(token);
// verify that there is a MQTT client with that topic id connected
bool isClient = false;
// check in the array of clients if we have one with the topicid
// start at 1 as 0 is not allocated as mqsocket
for (int i = 1; i <= mqtt->getClientSize(); i++)
// for (int i = 1; i <= subscriberid; i++)
{
if (clients[i].topic == topicid)
{
isClient = true;
mqsocket = i;
break;
}
}
if (!isClient)
{
// no such client connected
DIAG(F("MQTT Can't identify sender #2; command send on wrong topic"));
return;
}
}
// if we make it until here we dont even need to test the last "cmd" element from the topic as there is no
// subscription for anything else
// DIAG(F("MQTT Message arrived on [%s]: [%d]"), buf, topicid);
// Prepare the DCC-EX command
csmsg_t tm; // topic message
if (length >= MAXPAYLOAD)
{
DIAG(F("MQTT Command too long (> [%d] characters)"), MAXPAYLOAD);
}
memset(tm.cmd, 0, MAXPAYLOAD); // Clean up the cmd buffer - should not be necessary
strlcpy(tm.cmd, (char *)payload, length + 1); // Message payload
tm.mqsocket = mqsocket; // On which socket did we recieve the mq message
int idx = mqtt->getPool()->setItem(tm); // Add the recieved command to the pool
if (idx == -1)
{
DIAG(F("MQTT Command pool full. Could not handle recieved command."));
return;
}
mqtt->getIncomming()->push(idx); // Add the index of the pool item to the incomming queue
if (Diag::MQTT)
DIAG(F("MQTT Message arrived [%s]: [%s]"), topic, tm.cmd);
break;
}
case 'm':
{
switch (payload[1])
{
case 'i':
{
char buffer[MAXPAYLOAD];
char *tmp = (char *)payload + 3;
strlcpy(buffer, tmp, length);
buffer[length - 4] = '\0';
// DIAG(F("MQTT buffer %s - %s - %s - %d"), payload, tmp, buffer, length);
auto distantid = strtol(buffer, NULL, 10);
if (errno == ERANGE || distantid > UCHAR_MAX)
{
DIAG(F("MQTT Invalid Handshake ID; must be between 0 and 255"));
return;
}
if (distantid == 0)
{
DIAG(F("MQTT Invalid Handshake ID"));
return;
}
// ---------------------------
// Create a new MQTT client
// ---------------------------
// check in the clients if the distantid has been set already somewhere
// if so we either have a new one with the same id then we have a collision -> publish a collision
// or its the same i.e; the message comming back as we are subscribed -> stop here
// All is ok so set up the channel; MQTT Ctrl command
auto subscriberid = mqtt->obtainSubscriberID(); // to be used in the parsing process for the clientid in the ringbuffer
if (subscriberid == 0)
{
DIAG(F("MQTT no more connections are available"));
return;
}
auto topicid = cantorEncode((long)subscriberid, (long)distantid);
DIAG(F("MQTT Client connected : subscriber [%d] : distant [%d] : topic: [%d]"), subscriberid, (int)distantid, topicid);
// extract the number delivered from
// we need to check if the id we got from the client has been used allready and if yes reject and ask for a different one
// initalize the new mqtt client object
clients[subscriberid] = {(int)distantid, subscriberid, topicid, false}; // set to true once the channels are available
auto sq = mqtt->getSubscriptionQueue();
sq->push(subscriberid);
return;
}
default:
{
// ignore
return;
}
}
}
default:
{
// invalid command
DIAG(F("MQTT Invalid DCC-EX command: %s"), (char *)payload);
break;
}
}
}
/**
* @brief Copies an byte array to a hex representation as string; used for generating the unique Arduino ID
*
* @param array array containing bytes
* @param len length of the array
* @param buffer buffer to which the string will be written; make sure the buffer has appropriate length
*/
static void array_to_string(byte array[], unsigned int len, char buffer[])
{
for (unsigned int i = 0; i < len; i++)
{
byte nib1 = (array[i] >> 4) & 0x0F;
byte nib2 = (array[i] >> 0) & 0x0F;
buffer[i * 2 + 0] = nib1 < 0xA ? '0' + nib1 : 'A' + nib1 - 0xA;
buffer[i * 2 + 1] = nib2 < 0xA ? '0' + nib2 : 'A' + nib2 - 0xA;
}
buffer[len * 2] = '\0';
}
/**
* @brief Connect to the MQTT broker; Parameters for this function are defined in
* like the motoshield configurations there are mqtt broker configurations in config.h
*
* @param id Name provided to the broker configuration
* @param b MQTT broker object containing the main configuration parameters
*/
void MQTTInterface::setup(const FSH *id, MQTTBroker *b)
{
//Create the MQTT environment and establish inital connection to the Broker
broker = b;
DIAG(F("MQTT Connect to %S at %S/%d.%d.%d.%d:%d"), id, broker->domain, broker->ip[0], broker->ip[1], broker->ip[2], broker->ip[3], broker->port);
// initalize MQ Broker
mqttClient = new PubSubClient(broker->ip, broker->port, mqttCallback, ethClient);
if (Diag::MQTT)
DIAG(F("MQTT Client created ok..."));
array_to_string(mac, CLIENTIDSIZE, clientID);
DIAG(F("MQTT Client ID : %s"), clientID);
connect(); // inital connection as well as reconnects
}
/**
* @brief MQTT broker connection / reconnection
*
*/
void MQTTInterface::connect()
{
int reconnectCount = 0;
connectID[0] = '\0';
// Build the connect ID : Prefix + clientID
if (broker->prefix != nullptr)
{
strcpy_P(connectID, (const char *)broker->prefix);
}
strcat(connectID, clientID);
// Connect to the broker
DIAG(F("MQTT %s (re)connecting ..."), connectID);
while (!mqttClient->connected() && reconnectCount < MAXRECONNECT)
{
switch (broker->cType)
{
// no uid no pwd
case 6:
case 1:
{ // port(p), ip(i), domain(d),
if (mqttClient->connect(connectID))
{
DIAG(F("MQTT Broker connected ..."));
auto sub = subscribe(clientID); // set up the main subscription on which we will recieve the intal mi message from a subscriber
if (Diag::MQTT)
DIAG(F("MQTT subscriptons %s..."), sub ? "ok" : "failed");
mqState = CONNECTED;
}
else
{
DIAG(F("MQTT broker connection failed, rc=%d, trying to reconnect"), mqttClient->state());
mqState = CONNECTION_FAILED;
reconnectCount++;
}
break;
}
// with uid passwd
case 5:
case 2:
{ // port(p), ip(i), domain(d), user(uid), pwd(pass),
break;
}
// with uid, passwd & prefix
case 4:
case 3:
{ // port(p), ip(i), domain(d), user(uid), pwd(pass), prefix(pfix)
// port(p), domain(d), user(uid), pwd(pass), prefix(pfix)
// mqttClient.connect(connectID, MQTT_BROKER_USER, MQTT_BROKER_PASSWD, "$connected", 0, true, "0", 0))
break;
}
}
if (reconnectCount == MAXRECONNECT)
{
DIAG(F("MQTT Connection aborted after %d tries"), MAXRECONNECT);
mqState = CONNECTION_FAILED;
}
}
}
/**
* @brief for the time being only one topic at the root
* which is the unique clientID from the MCU
* QoS is 0 by default
*
* @param topic to subsribe to
* @return boolean true if successful false otherwise
*/
boolean MQTTInterface::subscribe(const char *topic)
{
auto res = mqttClient->subscribe(topic);
return res;
}
void MQTTInterface::publish(const char *topic, const char *payload)
{
mqttClient->publish(topic, payload);
}
/**
* @brief Connect the Ethernet network;
*
* @return true if connections was successful
*/
bool MQTTInterface::setupNetwork()
{
// setup Ethernet connection first
DCCTimer::getSimulatedMacAddress(mac);
#ifdef IP_ADDRESS
Ethernet.begin(mac, IP_ADDRESS);
#else
if (Ethernet.begin(mac) == 0)
{
DIAG(F("Ethernet.begin FAILED"));
return false;
}
#endif
DIAG(F("Ethernet.begin OK."));
if (Ethernet.hardwareStatus() == EthernetNoHardware)
{
DIAG(F("Ethernet shield not found"));
return false;
}
if (Ethernet.linkStatus() == LinkOFF)
{
DIAG(F("Ethernet cable not connected"));
return false;
}
IPAddress ip = Ethernet.localIP(); // reassign the obtained ip address
DIAG(F("IP: %d.%d.%d.%d"), ip[0], ip[1], ip[2], ip[3]);
DIAG(F("Port:%d"), IP_PORT);
return true;
}
/**
* @brief handle the incomming queue in the loop
*
*/
void inLoop(Queue<int> &in, ObjectPool<csmsg_t, MAXPOOLSIZE> &pool, RingStream *outboundRing)
{
bool state;
if (in.count() > 0)
{
// pop a command index from the incomming queue and get the command from the pool
int idx = in.pop();
csmsg_t *c = pool.getItem(idx, &state);
// execute the command and collect results
outboundRing->mark((uint8_t)c->mqsocket);
CommandDistributor::parse(c->mqsocket, (byte *)c->cmd, outboundRing);
outboundRing->commit();
// free the slot in the command pool
pool.returnItem(idx);
}
}
/**
* @brief handle the outgoing messages in the loop
*
*/
void outLoop(PubSubClient *mq)
{
// handle at most 1 outbound transmission
MQTTInterface *mqtt = MQTTInterface::get();
auto clients = mqtt->getClients();
auto outboundRing = mqtt->getRingStream();
int mqSocket = outboundRing->read();
if (mqSocket >= 0) // mqsocket / clientid can't be 0 ....
{
int count = outboundRing->count();
char buffer[MAXTSTR];
buffer[0] = '\0';
sprintf(buffer, "%s/%d/result", mqtt->getClientID(), (int)clients[mqSocket].topic);
if (Diag::MQTT)
DIAG(F("MQTT publish to mqSocket=%d, count=:%d on topic %s"), mqSocket, count, buffer);
if (mq->beginPublish(buffer, count, false))
{
for (; count > 0; count--)
{
mq->write(outboundRing->read());
}
}
else
{
DIAG(F("MQTT error start publishing result)"));
};
if (!mq->endPublish())
{
DIAG(F("MQTT error finalizing published result)"));
};
}
}
/**
* @brief check if there are new subscribers connected and create the channels
*
* @param sq if the callback captured a client there will be an entry in the sq with the subscriber number
* @param clients the clients array where we find the info to setup the subsciptions and print out the publish topics for info
*/
void checkSubscribers(Queue<int> &sq, csmqttclient_t *clients)
{
MQTTInterface *mqtt = MQTTInterface::get();
if (sq.count() > 0)
{
// new subscriber
auto s = sq.pop();
char tbuffer[(CLIENTIDSIZE * 2) + 1 + MAXTSTR];
sprintf(tbuffer, "%s/%ld/cmd", mqtt->getClientID(), clients[s].topic);
auto ok = mqtt->subscribe(tbuffer);
if (Diag::MQTT)
DIAG(F("MQTT new subscriber topic: %s %s"), tbuffer, ok ? "OK" : "NOK");
// send the topicid on which the CS will listen for commands to the MQTT client on the root topic
char buffer[30];
memset(buffer, 0, 30);
sprintf(buffer, "mc(%d,%ld)", (int)clients[s].distant, clients[s].topic);
if (Diag::MQTT)
DIAG(F("MQTT Publishing: [%s] to [%s]"), buffer, mqtt->getClientID());
mqtt->publish(mqtt->getClientID(), buffer);
// on the cs side all is set and we declare that the cs is open for business
clients[s].open = true;
// we now need to subscribe to the ../clientid/topicid/cmd topic as we shall recieve the cmds from there
// in the < case we should test that we got the command on the right topic ...
DIAG(F("MQTT CS is listening for commands on [%s]"), tbuffer);
memset(buffer, 0, 30);
sprintf(buffer, "%s/%ld/result", mqtt->getClientID(), clients[s].topic);
DIAG(F("MQTT CS is publishing return information to [%s]"), buffer);
memset(buffer, 0, 30);
sprintf(buffer, "%s/%ld/diag", mqtt->getClientID(), clients[s].topic);
DIAG(F("MQTT CS is publishing diagnostic information to [%s]"), buffer);
}
}
void MQTTInterface::loop()
{
if (!singleton)
return;
singleton->loop2();
}
void MQTTInterface::loop2()
{
// Connection impossible so just don't do anything
if (singleton->mqState == CONNECTION_FAILED)
{
DIAG(F("MQTT connection failed..."));
return;
}
if (!mqttClient->connected())
{
DIAG(F("MQTT no connection trying to reconnect ..."));
connect();
}
if (!mqttClient->loop())
{
DIAG(F("mqttClient returned with error; state: %d"), mqttClient->state());
return;
};
checkSubscribers(subscriberQueue, clients);
inLoop(in, pool, outboundRing);
outLoop(mqttClient);
}

186
MQTTInterface.h Normal file
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@ -0,0 +1,186 @@
#ifndef _MQTTInterface_h_
#define _MQTTInterface_h_
#if __has_include("config.h")
#include "config.h"
#else
#warning config.h not found. Using defaults from config.example.h
#include "config.example.h"
#endif
#include "defines.h"
#include <PubSubClient.h>
#include <DCCEXParser.h>
#include <Queue.h>
#include <Arduino.h>
#include <Ethernet.h>
#include <Dns.h>
#include <ObjectPool.h>
#define MAXPAYLOAD 64 // max length of a payload recieved
#define MAXDOMAINLENGTH 32 // domain name length for the broker e.g. test.mosquitto.org
#define MAXTBUF 50 //!< max length of the buffer for building the topic name ;to be checked
#define MAXTMSG 120 //!< max length of the messages for a topic ;to be checked PROGMEM ?
#define MAXTSTR 30 //!< max length of a topic string
#define MAXCONNECTID 40 // broker connection id length incl possible prefixes
#define CLIENTIDSIZE 6 // max length of the clientid used for connection to the broker
#define MAXRECONNECT 5 // reconnection tries before final failure
#define MAXMQTTCONNECTIONS 20 // maximum number of unique tpoics available for subscribers
#define OUT_BOUND_SIZE 256 // Size of the RingStream used to provide results from the parser and publish
#define MAX_POOL_SIZE 32 // recieved command store size
// Define Broker configurations; Values are provided in the following order
// MQTT_BROKER_PORT 9883
// MQTT_BROKER_DOMAIN "dcclms.modelrailroad.ovh"
// MQTT_BROKER_ADDRESS 51, 210, 151, 143
// MQTT_BROKER_USER "dcccs"
// MQTT_BROKER_PASSWD "dcccs$3020"
// MQTT_BROKER_CLIENTID_PREFIX "dcc$lms-"
struct MQTTBroker
{
int port;
IPAddress ip;
const FSH *domain = nullptr;
const FSH *user = nullptr;
const FSH *pwd = nullptr;
const FSH *prefix = nullptr;
byte cType; // connection type to identify valid params
IPAddress resovleBroker(const FSH *d)
{
DNSClient dns;
IPAddress bip;
char domain[MAXDOMAINLENGTH];
strcpy_P(domain, (const char *)d);
dns.begin(Ethernet.dnsServerIP());
if (dns.getHostByName(domain, bip) == 1)
{
DIAG(F("MQTT Broker/ %s = %d.%d.%d.%d"), domain, bip[0], bip[1], bip[2], bip[3]);
}
else
{
DIAG(F("MQTT Dns lookup for %s failed"), domain);
}
return bip;
}
MQTTBroker(int p, IPAddress i, const FSH *d) : port(p), ip(i), domain(d), cType(1){};
MQTTBroker(int p, IPAddress i, const FSH *d, const FSH *uid, const FSH *pass) : port(p), ip(i), domain(d), user(uid), pwd(pass), cType(2){};
MQTTBroker(int p, IPAddress i, const FSH *d, const FSH *uid, const FSH *pass, const FSH *pfix) : port(p), ip(i), domain(d), user(uid), pwd(pass), prefix(pfix), cType(3){};
MQTTBroker(int p, const FSH *d, const FSH *uid, const FSH *pass, const FSH *pfix) : port(p), domain(d), user(uid), pwd(pass), prefix(pfix), cType(4)
{
ip = resovleBroker(d);
};
MQTTBroker(int p, const FSH *d, const FSH *uid, const FSH *pass) : port(p), domain(d), user(uid), pwd(pass), cType(5)
{
ip = resovleBroker(d);
};
MQTTBroker(int p, const FSH *d) : port(p), domain(d), cType(6)
{
ip = resovleBroker(d);
};
};
/**
* @brief dcc-ex command as recieved via MQ
*
*/
typedef struct csmsg_t
{
char cmd[MAXPAYLOAD]; // recieved command message
byte mqsocket; // from which mqsocket / subscriberid
} csmsg_t;
typedef struct csmqttclient_t
{
int distant; // random int number recieved from the subscriber
byte mqsocket; // mqtt socket = subscriberid provided by the cs
long topic; // cantor(subscriber,cs) encoded tpoic used to send / recieve commands
bool open; // true as soon as we have send the id to the mq broker for the client to pickup
} csmqttclient_t;
enum MQTTInterfaceState
{
INIT,
CONFIGURED, // server/client objects set
CONNECTED, // mqtt broker is connected
CONNECTION_FAILED // Impossible to get the connection set after MAXRECONNECT tries
};
class MQTTInterface
{
private:
// Methods
MQTTInterface();
MQTTInterface(const MQTTInterface &); // non construction-copyable
MQTTInterface &operator=(const MQTTInterface &); // non copyable
void setup(const FSH *id, MQTTBroker *broker); // instantiates the broker
void connect(); // (re)connects to the broker
bool setupNetwork(); // sets up the network connection for the PubSub system
void loop2();
// Members
static MQTTInterface *singleton; // unique instance of the MQTTInterface object
EthernetClient ethClient; // TCP Client object for the MQ Connection
byte mac[6]; // simulated mac address
IPAddress server; // MQTT server object
MQTTBroker *broker; // Broker configuration object as set in config.h
ObjectPool<csmsg_t, MAXPOOLSIZE> pool; // Pool of commands recieved for the CS
Queue<int> in; // Queue of indexes into the pool according to incomming cmds
Queue<int> subscriberQueue; // Queue for incomming subscribers; push the subscriber into the queue for setup in a loop cycle
char clientID[(CLIENTIDSIZE * 2) + 1]; // unique ID of the commandstation; not to confused with the connectionID
csmqttclient_t clients[MAXMQTTCONNECTIONS]; // array of connected mqtt clients
char connectID[MAXCONNECTID]; // clientId plus possible prefix if required by the broker
uint8_t subscriberid = 0; // id assigned to a mqtt client when recieving the inital handshake; +1 at each connection
bool connected = false; // set to true if the ethernet connection is available
MQTTInterfaceState mqState = INIT; // Status of the MQBroker connection
RingStream *outboundRing; // Buffer for collecting the results from the command parser
PubSubClient *mqttClient; // PubSub Endpoint for data exchange
public:
static MQTTInterface *get() noexcept
{
return singleton;
}
boolean subscribe(const char *topic);
void publish(const char *topic, const char *payload);
ObjectPool<csmsg_t, MAXPOOLSIZE> *getPool() { return &pool; };
Queue<int> *getIncomming() { return &in; };
Queue<int> *getSubscriptionQueue() { return &subscriberQueue; };
char *getClientID() { return clientID; };
uint8_t getClientSize() { return subscriberid; }
// initalized to 0 so that the first id comming back is 1
// index 0 in the clients array is not used therefore
//! improvement here to be done to save some bytes
uint8_t obtainSubscriberID()
{
if (subscriberid == MAXMQTTCONNECTIONS)
{
return 0; // no more subscriber id available
}
return (++subscriberid);
}
csmqttclient_t *getClients() { return clients; };
RingStream *getRingStream() { return outboundRing; }; // debug only
static void setup();
static void loop();
~MQTTInterface() = default;
};
#endif

98
MemStream.cpp Normal file
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@ -0,0 +1,98 @@
/*
(c) 2015 Ingo Fischer
buffer serial device
based on Arduino SoftwareSerial
Constructor warning messages fixed by Chris Harlow.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include "MemStream.h"
MemStream::MemStream(uint8_t *buffer, const uint16_t len, uint16_t content_len, bool allowWrite)
:_buffer(buffer),_len(len), _buffer_overflow(false), _pos_read(0), _allowWrite(allowWrite)
{
if (content_len==0) memset(_buffer, 0, _len);
_pos_write=(content_len>len)? len: content_len;
}
size_t MemStream::write(uint8_t byte) {
if (! _allowWrite) return -1;
if (_pos_write >= _len) {
_buffer_overflow = true;
return 0;
}
_buffer[_pos_write] = byte;
++_pos_write;
return 1;
}
void MemStream::flush() {
memset(_buffer, 0, _len);
_pos_write = 0;
_pos_read = 0;
}
int MemStream::read() {
if (_pos_read >= _len) {
_buffer_overflow = true;
return -1;
}
if (_pos_read >= _pos_write) {
return -1;
}
return _buffer[_pos_read++];
}
int MemStream::peek() {
if (_pos_read >= _len) {
_buffer_overflow = true;
return -1;
}
if (_pos_read >= _pos_write) {
return -1;
}
return _buffer[_pos_read+1];
}
int MemStream::available() {
int ret=_pos_write-_pos_read;
if (ret<0) ret=0;
return ret;
}
void MemStream::setBufferContent(uint8_t *buffer, uint16_t content_len) {
memset(_buffer, 0, _len);
memcpy(_buffer, buffer, content_len);
_buffer_overflow=false;
_pos_write=content_len;
_pos_read=0;
}
void MemStream::setBufferContentFromProgmem(uint8_t *buffer, uint16_t content_len) {
memset(_buffer, 0, _len);
memcpy_P(_buffer, buffer, content_len);
_buffer_overflow=false;
_pos_write=content_len;
_pos_read=0;
}
void MemStream::setBufferContentPosition(uint16_t read_pos, uint16_t write_pos) {
_pos_write=write_pos;
_pos_read=read_pos;
}

78
MemStream.h Normal file
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@ -0,0 +1,78 @@
/*
(c) 2015 Ingo FIscher
buffer serial device
based on Arduino SoftwareSerial
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#ifndef MemStream_h
#define MemStream_h
#include <inttypes.h>
#if defined(ARDUINO_ARCH_MEGAAVR)
#include <Arduino.h>
#else
#include <Stream.h>
#endif
#include <avr/pgmspace.h>
class MemStream : public Stream
{
private:
uint8_t *_buffer;
const uint16_t _len;
bool _buffer_overflow;
uint16_t _pos_read;
uint16_t _pos_write;
bool _allowWrite;
public:
// public methods
MemStream(uint8_t *buffer, const uint16_t len, uint16_t content_len = 0, bool allowWrite = true);
~MemStream() {}
operator const uint8_t *() const { return _buffer; }
operator const char *() const { return (const char *)_buffer; }
uint16_t current_length() const { return _pos_write; }
bool listen() { return true; }
void end() {}
bool isListening() { return true; }
bool overflow()
{
bool ret = _buffer_overflow;
_buffer_overflow = false;
return ret;
}
int peek();
virtual size_t write(uint8_t byte);
virtual int read();
virtual int available();
virtual void flush();
void setBufferContent(uint8_t *buffer, uint16_t content_len);
void setBufferContentFromProgmem(uint8_t *buffer, uint16_t content_len);
void setBufferContentPosition(uint16_t read_pos, uint16_t write_pos);
using Print::write;
};
#endif

40
RingStream.cpp
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@ -103,3 +103,43 @@ bool RingStream::commit() {
_buffer[_mark]=lowByte(_count);
return true; // commit worked
}
// grbba to be removed
// print the buffer one line for 10 chars in the array
// void RingStream::printBuffer() {
// int j = 0;
// for ( int k = 0; k < _len; k++ ) {
// if ( j == 10) {
// j = 0;
// Serial.println();
// }
// j++;
// Serial.print((char) _buffer[k]);
// Serial.print(" ");
// }
// }
// void RingStream::printInfo() {
// Serial.print("_len: "); Serial.println(_len);
// Serial.print("_pos_write: "); Serial.println(_pos_write);
// Serial.print("_pos_read: "); Serial.println(_pos_read);
// Serial.print("_overflow: "); Serial.println(_overflow);
// Serial.print("_mark: "); Serial.println(_mark);
// Serial.print("_count: ");Serial.println(_count);
// }
// void RingStream::reset(const uint16_t len)
// {
// _len=len;
// memset(_buffer,0,len);
// // _buffer=new byte[len];
// _pos_write=0;
// _pos_read=0;
// _buffer[0]=0;
// _overflow=false;
// _mark=0;
// _count=0;
// }
// grbba to be removed

18
RingStream.h
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@ -21,10 +21,12 @@
#include <Arduino.h>
// template <size_t S>
class RingStream : public Print {
public:
RingStream( const uint16_t len);
~RingStream() = default;
virtual size_t write(uint8_t b);
using Print::write;
@ -35,14 +37,26 @@ class RingStream : public Print {
bool commit();
uint8_t peekTargetMark();
int size() {return _len;}
byte *getBuffer() { return _buffer; }
// grbba to be removed
// void printBuffer();
// void printInfo();
// void reset(const uint16_t len);
// grbba to be removed
int getLen() { return _len; };
private:
int _len;
int _pos_write;
// int _len = S;
int _pos_write ;
int _pos_read;
bool _overflow;
int _mark;
int _count;
byte * _buffer;
// byte _buffer[S];
byte *_buffer;
};
#endif

16
config.example.h
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@ -92,6 +92,22 @@ The configuration file for DCC-EX Command Station
//
//#define IP_ADDRESS { 192, 168, 1, 200 }
//
// ENABLE_MQTT: if set to true you have to have an Arduino Ethernet card (wired). This
// is not for Wifi. You will need the Arduino Ethernet library as well as the PubSub
// library from <add link here> or get via the libray manager either from the IDE
// or PIO
// #define ENABLE_MQTT true
// Set the used broker to one of the configurations from MQTTBrokers.h where some
// public freely avaiable brokers are configured
#define CSMQTTBROKER DCCEX_MOSQUITTO
// Example for configuring your own MQTT broker
/////////////////////////////////////////////////////////////////////////////////////
//