xnode/lib-ext/rfm-69.git/Examples/Struct_receive/Struct_receive.ino

#include <RFM69.h>
#include <SPI.h>
#include <SPIFlash.h>

#define NODEID      1
#define NETWORKID   100
#define FREQUENCY   RF69_433MHZ //Match this with the version of your Moteino! (others: RF69_433MHZ, RF69_868MHZ)
#define KEY         "thisIsEncryptKey" //has to be same 16 characters/bytes on all nodes, not more not less!
#define LED         9
#define SERIAL_BAUD 115200
#define ACK_TIME    30  // # of ms to wait for an ack

RFM69 radio;
SPIFlash flash(8, 0xEF30); //EF40 for 16mbit windbond chip
bool promiscuousMode = false; //set to 'true' to sniff all packets on the same network

typedef struct {
  int           nodeId; //store this nodeId
  unsigned long uptime; //uptime in ms
  float         temp;   //temperature maybe?
} Payload;
Payload theData;

void setup() {
  Serial.begin(SERIAL_BAUD);
  delay(10);
  radio.initialize(FREQUENCY,NODEID,NETWORKID);
  //radio.setHighPower(); //uncomment only for RFM69HW!
  radio.encrypt(KEY);
  radio.promiscuous(promiscuousMode);
  char buff[50];
  sprintf(buff, "\nListening at %d Mhz...", FREQUENCY==RF69_433MHZ ? 433 : FREQUENCY==RF69_868MHZ ? 868 : 915);
  Serial.println(buff);
  if (flash.initialize())
    Serial.println("SPI Flash Init OK!");
  else
    Serial.println("SPI Flash Init FAIL! (is chip present?)");
}

byte ackCount=0;
void loop() {
  //process any serial input
  if (Serial.available() > 0)
  {
    char input = Serial.read();
    if (input == 'r') //d=dump all register values
      radio.readAllRegs();
    if (input == 'E') //E=enable encryption
      radio.encrypt(KEY);
    if (input == 'e') //e=disable encryption
      radio.encrypt(null);
    if (input == 'p')
    {
      promiscuousMode = !promiscuousMode;
      radio.promiscuous(promiscuousMode);
      Serial.print("Promiscuous mode ");Serial.println(promiscuousMode ? "on" : "off");
    }
    
    if (input == 'd') //d=dump flash area
    {
      Serial.println("Flash content:");
      int counter = 0;

      while(counter<=256){
        Serial.print(flash.readByte(counter++), HEX);
        Serial.print('.');
      }
      while(flash.busy());
      Serial.println();
    }
    if (input == 'D')
    {
      Serial.print("Deleting Flash chip content... ");
      flash.chipErase();
      while(flash.busy());
      Serial.println("DONE");
    }
    if (input == 'i')
    {
      Serial.print("DeviceID: ");
      word jedecid = flash.readDeviceId();
      Serial.println(jedecid, HEX);
    }
  }

  if (radio.receiveDone())
  {
    Serial.print('[');Serial.print(radio.SENDERID, DEC);Serial.print("] ");
    Serial.print(" [RX_RSSI:");Serial.print(radio.readRSSI());Serial.print("]");
    if (promiscuousMode)
    {
      Serial.print("to [");Serial.print(radio.TARGETID, DEC);Serial.print("] ");
    }

    if (radio.DATALEN != sizeof(Payload))
      Serial.print("Invalid payload received, not matching Payload struct!");
    else
    {
      theData = *(Payload*)radio.DATA; //assume radio.DATA actually contains our struct and not something else
      Serial.print(" nodeId=");
      Serial.print(theData.nodeId);
      Serial.print(" uptime=");
      Serial.print(theData.uptime);
      Serial.print(" temp=");
      Serial.print(theData.temp);
    }
    
    if (radio.ACKRequested())
    {
      byte theNodeID = radio.SENDERID;
      radio.sendACK();
      Serial.print(" - ACK sent.");

      // When a node requests an ACK, respond to the ACK
      // and also send a packet requesting an ACK (every 3rd one only)
      // This way both TX/RX NODE functions are tested on 1 end at the GATEWAY
      if (ackCount++%3==0)
      {
        Serial.print(" Pinging node ");
        Serial.print(theNodeID);
        Serial.print(" - ACK...");
        delay(3); //need this when sending right after reception .. ?
        if (radio.sendWithRetry(theNodeID, "ACK TEST", 8, 0))  // 0 = only 1 attempt, no retries
          Serial.print("ok!");
        else Serial.print("nothing");
      }
    }
    Serial.println();
    Blink(LED,3);
  }
}

void Blink(byte PIN, int DELAY_MS)
{
  pinMode(PIN, OUTPUT);
  digitalWrite(PIN,HIGH);
  delay(DELAY_MS);
  digitalWrite(PIN,LOW);
}
Added project 2022-11-13 00:46:38 +00:00			`#include <RFM69.h>`
			`#include <SPI.h>`
			`#include <SPIFlash.h>`

			`#define NODEID 1`
			`#define NETWORKID 100`
			`#define FREQUENCY RF69_433MHZ //Match this with the version of your Moteino! (others: RF69_433MHZ, RF69_868MHZ)`
			`#define KEY "thisIsEncryptKey" //has to be same 16 characters/bytes on all nodes, not more not less!`
			`#define LED 9`
			`#define SERIAL_BAUD 115200`
			`#define ACK_TIME 30 // # of ms to wait for an ack`

			`RFM69 radio;`
			`SPIFlash flash(8, 0xEF30); //EF40 for 16mbit windbond chip`
			`bool promiscuousMode = false; //set to 'true' to sniff all packets on the same network`

			`typedef struct {`
			`int nodeId; //store this nodeId`
			`unsigned long uptime; //uptime in ms`
			`float temp; //temperature maybe?`
			`} Payload;`
			`Payload theData;`

			`void setup() {`
			`Serial.begin(SERIAL_BAUD);`
			`delay(10);`
			`radio.initialize(FREQUENCY,NODEID,NETWORKID);`
			`//radio.setHighPower(); //uncomment only for RFM69HW!`
			`radio.encrypt(KEY);`
			`radio.promiscuous(promiscuousMode);`
			`char buff[50];`
			`sprintf(buff, "\nListening at %d Mhz...", FREQUENCY==RF69_433MHZ ? 433 : FREQUENCY==RF69_868MHZ ? 868 : 915);`
			`Serial.println(buff);`
			`if (flash.initialize())`
			`Serial.println("SPI Flash Init OK!");`
			`else`
			`Serial.println("SPI Flash Init FAIL! (is chip present?)");`
			`}`

			`byte ackCount=0;`
			`void loop() {`
			`//process any serial input`
			`if (Serial.available() > 0)`
			`{`
			`char input = Serial.read();`
			`if (input == 'r') //d=dump all register values`
			`radio.readAllRegs();`
			`if (input == 'E') //E=enable encryption`
			`radio.encrypt(KEY);`
			`if (input == 'e') //e=disable encryption`
			`radio.encrypt(null);`
			`if (input == 'p')`
			`{`
			`promiscuousMode = !promiscuousMode;`
			`radio.promiscuous(promiscuousMode);`
			`Serial.print("Promiscuous mode ");Serial.println(promiscuousMode ? "on" : "off");`
			`}`

			`if (input == 'd') //d=dump flash area`
			`{`
			`Serial.println("Flash content:");`
			`int counter = 0;`

			`while(counter<=256){`
			`Serial.print(flash.readByte(counter++), HEX);`
			`Serial.print('.');`
			`}`
			`while(flash.busy());`
			`Serial.println();`
			`}`
			`if (input == 'D')`
			`{`
			`Serial.print("Deleting Flash chip content... ");`
			`flash.chipErase();`
			`while(flash.busy());`
			`Serial.println("DONE");`
			`}`
			`if (input == 'i')`
			`{`
			`Serial.print("DeviceID: ");`
			`word jedecid = flash.readDeviceId();`
			`Serial.println(jedecid, HEX);`
			`}`
			`}`

			`if (radio.receiveDone())`
			`{`
			`Serial.print('[');Serial.print(radio.SENDERID, DEC);Serial.print("] ");`
			`Serial.print(" [RX_RSSI:");Serial.print(radio.readRSSI());Serial.print("]");`
			`if (promiscuousMode)`
			`{`
			`Serial.print("to [");Serial.print(radio.TARGETID, DEC);Serial.print("] ");`
			`}`

			`if (radio.DATALEN != sizeof(Payload))`
			`Serial.print("Invalid payload received, not matching Payload struct!");`
			`else`
			`{`
			`theData = (Payload)radio.DATA; //assume radio.DATA actually contains our struct and not something else`
			`Serial.print(" nodeId=");`
			`Serial.print(theData.nodeId);`
			`Serial.print(" uptime=");`
			`Serial.print(theData.uptime);`
			`Serial.print(" temp=");`
			`Serial.print(theData.temp);`
			`}`

			`if (radio.ACKRequested())`
			`{`
			`byte theNodeID = radio.SENDERID;`
			`radio.sendACK();`
			`Serial.print(" - ACK sent.");`

			`// When a node requests an ACK, respond to the ACK`
			`// and also send a packet requesting an ACK (every 3rd one only)`
			`// This way both TX/RX NODE functions are tested on 1 end at the GATEWAY`
			`if (ackCount++%3==0)`
			`{`
			`Serial.print(" Pinging node ");`
			`Serial.print(theNodeID);`
			`Serial.print(" - ACK...");`
			`delay(3); //need this when sending right after reception .. ?`
			`if (radio.sendWithRetry(theNodeID, "ACK TEST", 8, 0)) // 0 = only 1 attempt, no retries`
			`Serial.print("ok!");`
			`else Serial.print("nothing");`
			`}`
			`}`
			`Serial.println();`
			`Blink(LED,3);`
			`}`
			`}`

			`void Blink(byte PIN, int DELAY_MS)`
			`{`
			`pinMode(PIN, OUTPUT);`
			`digitalWrite(PIN,HIGH);`
			`delay(DELAY_MS);`
			`digitalWrite(PIN,LOW);`
			`}`