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mirror of https://github.com/DCC-EX/CommandStation-EX.git synced 2024-12-24 13:21:23 +01:00
CommandStation-EX/CVReader.ino

107 lines
4.0 KiB
C++

#include "DCC.h"
#include "DIAG.h"
#include "DCCEXParser.h"
#include "WifiInterface.h"
// this code is here to demonstrate use of the DCC API and other techniques
// myFilter is an example of an OPTIONAL command filter used to intercept < > commands from
// the usb or wifi streamm. It demonstrates how a command may be intercepted
// or even a new command created without having to break open the API library code.
// The filter is permitted to use or modify the parameter list before passing it on to
// the standard parser. By setting the opcode to 0, the standard parser will
// just ignore the command on the assumption that you have already handled it.
//
// The filter must be enabled by calling the DCC EXParser::setFilter method, see use in setup().
void myFilter(Print & stream, byte & opcode, byte & paramCount, int p[]) {
(void)stream; // avoid compiler warning if we don't access this parameter
switch (opcode) {
case 'F': // Invent new command to call the new Loco Function API <F cab func 1|0>
DIAG(F("Setting loco %d F%d %S"),p[0],p[1],p[2]?F("ON"):F("OFF"));
DCC::setFn(p[0],p[1],p[2]==1);
opcode=0; // tell parser to ignore this command
break;
case '#': // Diagnose parser <#....>
DIAG(F("# paramCount=%d\n"),paramCount);
for (int i=0;i<paramCount;i++) DIAG(F("p[%d]=%d (0x%x)\n"),i,p[i],p[i]);
opcode=0; // Normal parser wont understand #,
break;
default: // drop through and parser will use the command unaltered.
break;
}
}
// Callback functions are necessary if you call any API that must wait for a response from the
// programming track. The API must return immediately otherwise other loop() functions would be blocked.
// Your callback function will be invoked when the data arrives from the prog track.
// See the DCC:getLocoId example in the setup function.
void myCallback(int result) {
DIAG(F("\n getting Loco Id callback result=%d"),result);
}
// Create a serial command parser... This is OPTIONAL if you don't need to handle JMRI type commands
// from the Serial port.
DCCEXParser serialParser;
// Try monitoring the memory
#include "freeMemory.h"
int minMemory=32767;
void setup() {
// The main sketch has responsibilities during setup()
// Responsibility 1: Start the usb connection for diagnostics and possible JMRI input
Serial.begin(115200);
// Responsibility 2: Start the DCC engine.
DCC::begin();
// Responsibility 3: Optionally Start the WiFi interface if required.
// NOTE: On a Uno you will have to provide a SoftwareSerial
// configured for the pins connected to the Wifi card
// and a 9600 baud rate.
// setup(serial, F(router name), F(password) , port)
//
Serial1.begin(115200);
WifiInterface::setup(Serial1, F("BTHub5-M6PT"), F("49de8d4862"),3532); // (3532 is 0xDCC decimal... )
// This is just for demonstration purposes
DIAG(F("\n===== CVReader demonstrating DCC::getLocoId() call ==========\n"));
DCC::getLocoId(myCallback); // myCallback will be called with the result
DIAG(F("\n===== DCC::getLocoId has returned, but the callback wont be executed until we are in loop() ======\n"));
// Optionally tell the command parser to use my example filter.
// This will intercept JMRI commands from both USB and Wifi
DCCEXParser::setFilter(myFilter);
DIAG(F("\nReady for JMRI commands\n"));
}
void loop() {
// The main sketch has responsibilities during loop()
// Responsibility 1: Handle DCC background processes
// (loco reminders and power checks)
DCC::loop();
// Responsibility 2: handle any incoming commands on USB connection
serialParser.loop(Serial);
// Responsibility 3: Optionally handle any incoming WiFi traffic
WifiInterface::loop(Serial1);
// Your additional code e.g. Report any decrease in memory
int freeNow=freeMemory();
if (freeNow<minMemory) {
minMemory=freeNow;
DIAG(F("\nFree memory=%d"),minMemory);
}
}