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esphome-ratgdo
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This commit is contained in:
J. Nick Koston 2023-06-05 12:13:01 -05:00
parent 1d04b22eb2
commit 4af7a079d8
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5 changed files with 543 additions and 501 deletions
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15
components/ratgdo/__init__.py
View File

@ -1,16 +1,7 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.core import coroutine_with_priority
import esphome.codegen as cg import esphome.config_validation as cv from esphome.core import coroutine_with_priority
ratgdo_ns = cg.esphome_ns.namespace("ratgdo")
CONFIG_SCHEMA = cv.All(
cv.Schema({}),
)
CONFIG_SCHEMA = cv.All(cv.Schema({}), )
@coroutine_with_priority(1.0)
async def to_code(config):
cg.add_library("bblanchon/ArduinoJson", "6.18.5")
cg.add_define("USE_JSON")
cg.add_global(ratgdo_ns.using)
@coroutine_with_priority(1.0) async def to_code(config) :cg.add_library("bblanchon/ArduinoJson", "6.18.5") cg.add_define("USE_JSON") cg.add_global(ratgdo_ns.using)

153
components/ratgdo/ratgdo.cpp
View File

@ -11,27 +11,27 @@
* GNU GENERAL PUBLIC LICENSE
************************************/
#include "common.h"
#include "ratgdo.h"
#include "common.h"
#include "esphome/core/log.h"
namespace esphome
{
namespace ratgdo
{
namespace esphome {
namespace ratgdo {
static const char *const TAG = "ratgdo";
void RATGDOComponent::setup()
{
void RATGDOComponent::setup() {
pinMode(TRIGGER_OPEN, INPUT_PULLUP);
pinMode(TRIGGER_CLOSE, INPUT_PULLUP);
pinMode(TRIGGER_LIGHT, INPUT_PULLUP);
pinMode(STATUS_DOOR, OUTPUT);
pinMode(STATUS_OBST, OUTPUT);
pinMode(INPUT_RPM1, INPUT_PULLUP); // set to pullup to add support for reed switches
pinMode(INPUT_RPM2, INPUT_PULLUP); // make sure pin doesn't float when using reed switch and fire interrupt by mistake
pinMode(INPUT_RPM1,
INPUT_PULLUP); // set to pullup to add support for reed switches
pinMode(INPUT_RPM2,
INPUT_PULLUP); // make sure pin doesn't float when using reed switch
// and fire interrupt by mistake
pinMode(INPUT_OBST, INPUT);
attachInterrupt(TRIGGER_OPEN, isrDoorOpen, CHANGE);
@ -49,7 +49,8 @@ namespace esphome
// if(rollingCodeCounter == 0) rollingCodeCounter = 1;
ESP_LOGD(TAG, "Syncing rolling code counter after reboot...");
sync(); // if rolling codes are being used (rolling code counter > 0), send reboot/sync to the opener on startup
sync(); // if rolling codes are being used (rolling code counter > 0), send
// reboot/sync to the opener on startup
} else {
ESP_LOGD(TAG, "Rolling codes are disabled.");
}
@ -61,13 +62,11 @@ namespace esphome
dryContactLoop();
}
} // namespace ratgdo
} // namespace esphome
/*************************** DETECTING THE DOOR STATE ***************************/
/*************************** DETECTING THE DOOR STATE
* ***************************/
void doorStateLoop() {
static bool rotaryEncoderDetected = false;
static int lastDoorPositionCounter = 0;
@ -75,15 +74,18 @@ void doorStateLoop(){
static int lastCounterMillis = 0;
// Handle reed switch
// This may need to be debounced, but so far in testing I haven't detected any bounces
// This may need to be debounced, but so far in testing I haven't detected any
// bounces
if (!rotaryEncoderDetected) {
if (digitalRead(INPUT_RPM1) == LOW) {
if (doorState != "reed_closed") {
ESP_LOGD(TAG, "Reed switch closed");
doorState = "reed_closed";
if (isConfigFileOk) {
bootstrapManager.publish(overallStatusTopic.c_str(), "reed_closed", true);
bootstrapManager.publish(doorStatusTopic.c_str(), "reed_closed", true);
bootstrapManager.publish(overallStatusTopic.c_str(), "reed_closed",
true);
bootstrapManager.publish(doorStatusTopic.c_str(), "reed_closed",
true);
}
digitalWrite(STATUS_DOOR, HIGH);
}
@ -99,7 +101,8 @@ void doorStateLoop(){
}
// end reed switch handling
// If the previous and the current state of the RPM2 Signal are different, that means there is a rotary encoder detected and the door is moving
// If the previous and the current state of the RPM2 Signal are different,
// that means there is a rotary encoder detected and the door is moving
if (doorPositionCounter != lastDoorPositionCounter) {
rotaryEncoderDetected = true; // this disables the reed switch handler
lastCounterMillis = millis();
@ -139,8 +142,10 @@ void doorStateLoop(){
doorState = "closed";
ESP_LOGD(TAG, "Closed");
if (isConfigFileOk) {
bootstrapManager.publish(overallStatusTopic.c_str(), doorState.c_str(), true);
bootstrapManager.publish(doorStatusTopic.c_str(), doorState.c_str(), true);
bootstrapManager.publish(overallStatusTopic.c_str(), doorState.c_str(),
true);
bootstrapManager.publish(doorStatusTopic.c_str(), doorState.c_str(),
true);
}
digitalWrite(STATUS_DOOR, LOW);
}
@ -150,8 +155,10 @@ void doorStateLoop(){
doorState = "open";
ESP_LOGD(TAG, "Open");
if (isConfigFileOk) {
bootstrapManager.publish(overallStatusTopic.c_str(), doorState.c_str(), true);
bootstrapManager.publish(doorStatusTopic.c_str(), doorState.c_str(), true);
bootstrapManager.publish(overallStatusTopic.c_str(), doorState.c_str(),
true);
bootstrapManager.publish(doorStatusTopic.c_str(), doorState.c_str(),
true);
}
digitalWrite(STATUS_DOOR, HIGH);
}
@ -160,7 +167,8 @@ void doorStateLoop(){
lastDoorPositionCounter = doorPositionCounter;
}
/*************************** DRY CONTACT CONTROL OF LIGHT & DOOR ***************************/
/*************************** DRY CONTACT CONTROL OF LIGHT & DOOR
* ***************************/
void IRAM_ATTR isrDebounce(const char *type) {
static unsigned long lastOpenDoorTime = 0;
static unsigned long lastCloseDoorTime = 0;
@ -168,14 +176,17 @@ void IRAM_ATTR isrDebounce(const char *type){
unsigned long currentMillis = millis();
// Prevent ISR during the first 2 seconds after reboot
if(currentMillis < 2000) return;
if (currentMillis < 2000)
return;
if (strcmp(type, "openDoor") == 0) {
if (digitalRead(TRIGGER_OPEN) == LOW) {
// save the time of the falling edge
lastOpenDoorTime = currentMillis;
}else if(currentMillis - lastOpenDoorTime > 500 && currentMillis - lastOpenDoorTime < 10000){
// now see if the rising edge was between 500ms and 10 seconds after the falling edge
} else if (currentMillis - lastOpenDoorTime > 500 &&
currentMillis - lastOpenDoorTime < 10000) {
// now see if the rising edge was between 500ms and 10 seconds after the
// falling edge
dryContactDoorOpen = true;
}
}
@ -184,8 +195,10 @@ void IRAM_ATTR isrDebounce(const char *type){
if (digitalRead(TRIGGER_CLOSE) == LOW) {
// save the time of the falling edge
lastCloseDoorTime = currentMillis;
}else if(currentMillis - lastCloseDoorTime > 500 && currentMillis - lastCloseDoorTime < 10000){
// now see if the rising edge was between 500ms and 10 seconds after the falling edge
} else if (currentMillis - lastCloseDoorTime > 500 &&
currentMillis - lastCloseDoorTime < 10000) {
// now see if the rising edge was between 500ms and 10 seconds after the
// falling edge
dryContactDoorClose = true;
}
}
@ -194,29 +207,23 @@ void IRAM_ATTR isrDebounce(const char *type){
if (digitalRead(TRIGGER_LIGHT) == LOW) {
// save the time of the falling edge
lastToggleLightTime = currentMillis;
}else if(currentMillis - lastToggleLightTime > 500 && currentMillis - lastToggleLightTime < 10000){
// now see if the rising edge was between 500ms and 10 seconds after the falling edge
} else if (currentMillis - lastToggleLightTime > 500 &&
currentMillis - lastToggleLightTime < 10000) {
// now see if the rising edge was between 500ms and 10 seconds after the
// falling edge
dryContactToggleLight = true;
}
}
}
void IRAM_ATTR isrDoorOpen(){
isrDebounce("openDoor");
}
void IRAM_ATTR isrDoorOpen() { isrDebounce("openDoor"); }
void IRAM_ATTR isrDoorClose(){
isrDebounce("closeDoor");
}
void IRAM_ATTR isrDoorClose() { isrDebounce("closeDoor"); }
void IRAM_ATTR isrLight(){
isrDebounce("toggleLight");
}
void IRAM_ATTR isrLight() { isrDebounce("toggleLight"); }
// Fire on RISING edge of RPM1
void IRAM_ATTR isrRPM1(){
rpm1Pulsed = true;
}
void IRAM_ATTR isrRPM1() { rpm1Pulsed = true; }
// Fire on RISING edge of RPM2
// When RPM1 HIGH on RPM2 rising edge, door closing:
@ -227,9 +234,10 @@ void IRAM_ATTR isrRPM1(){
// RPM1: ___|--|__
// RPM2: __|--|___
void IRAM_ATTR isrRPM2() {
// The encoder updates faster than the ESP wants to process, so by sampling every 5ms we get a more reliable curve
// The counter is behind the actual pulse counter, but it doesn't matter since we only need a reliable linear counter
// to determine the door direction
// The encoder updates faster than the ESP wants to process, so by sampling
// every 5ms we get a more reliable curve The counter is behind the actual
// pulse counter, but it doesn't matter since we only need a reliable linear
// counter to determine the door direction
static unsigned long lastPulse = 0;
unsigned long currentMillis = millis();
@ -237,9 +245,10 @@ void IRAM_ATTR isrRPM2(){
return;
}
// In rare situations, the rotary encoder can be parked so that RPM2 continuously fires this ISR.
// This causes the door counter to change value even though the door isn't moving
// To solve this, check to see if RPM1 pulsed. If not, do nothing. If yes, reset the pulsed flag
// In rare situations, the rotary encoder can be parked so that RPM2
// continuously fires this ISR. This causes the door counter to change value
// even though the door isn't moving To solve this, check to see if RPM1
// pulsed. If not, do nothing. If yes, reset the pulsed flag
if (rpm1Pulsed) {
rpm1Pulsed = false;
} else {
@ -248,7 +257,8 @@ void IRAM_ATTR isrRPM2(){
lastPulse = millis();
// If the RPM1 state is different from the RPM2 state, then the door is opening
// If the RPM1 state is different from the RPM2 state, then the door is
// opening
if (digitalRead(INPUT_RPM1)) {
doorPositionCounter--;
} else {
@ -284,18 +294,19 @@ void IRAM_ATTR isrObstruction(){
} else {
obstructionLowCount++;
}
}
void obstructionLoop() {
long currentMillis = millis();
static unsigned long lastMillis = 0;
// the obstruction sensor has 3 states: clear (HIGH with LOW pulse every 7ms), obstructed (HIGH), asleep (LOW)
// the transitions between awake and asleep are tricky because the voltage drops slowly when falling asleep
// and is high without pulses when waking up
// the obstruction sensor has 3 states: clear (HIGH with LOW pulse every 7ms),
// obstructed (HIGH), asleep (LOW) the transitions between awake and asleep
// are tricky because the voltage drops slowly when falling asleep and is high
// without pulses when waking up
// If at least 3 low pulses are counted within 50ms, the door is awake, not obstructed and we don't have to check anything else
// If at least 3 low pulses are counted within 50ms, the door is awake, not
// obstructed and we don't have to check anything else
// Every 50ms
if (currentMillis - lastMillis > 50) {
@ -305,7 +316,8 @@ void obstructionLoop(){
// if there have been no pulses the line is steady high or low
} else if (obstructionLowCount == 0) {
// if the line is high and the last high pulse was more than 70ms ago, then there is an obstruction present
// if the line is high and the last high pulse was more than 70ms ago,
// then there is an obstruction present
if (digitalRead(INPUT_OBST) && currentMillis - lastObstructionHigh > 70) {
obstructionDetected();
} else {
@ -330,7 +342,8 @@ void obstructionDetected(){
if (isConfigFileOk) {
bootstrapManager.publish(overallStatusTopic.c_str(), "obstructed", true);
bootstrapManager.publish(obstructionStatusTopic.c_str(), "obstructed", true);
bootstrapManager.publish(obstructionStatusTopic.c_str(), "obstructed",
true);
}
}
lastInterruptTime = interruptTime;
@ -354,7 +367,8 @@ void sendDoorStatus(){
ESP_LOGD(TAG, "Door state %s", doorState);
if (isConfigFileOk) {
bootstrapManager.publish(overallStatusTopic.c_str(), doorState.c_str(), true);
bootstrapManager.publish(overallStatusTopic.c_str(), doorState.c_str(),
true);
bootstrapManager.publish(doorStatusTopic.c_str(), doorState.c_str(), true);
}
}
@ -367,10 +381,9 @@ void sendCurrentCounter(){
}
}
/********************************** MANAGE HARDWARE BUTTON *****************************************/
void manageHardwareButton(){
}
/********************************** MANAGE HARDWARE BUTTON
* *****************************************/
void manageHardwareButton() {}
/************************* DOOR COMMUNICATION *************************/
/*
@ -378,10 +391,12 @@ void manageHardwareButton(){
* The TX1 pin is controlling a transistor, so the logic is inverted
* A HIGH state on TX1 will pull the 12v line LOW
*
* The opener requires a specific duration low/high pulse before it will accept a message
* The opener requires a specific duration low/high pulse before it will accept
* a message
*/
void transmit(byte *payload, unsigned int length) {
digitalWrite(OUTPUT_GDO, HIGH); // pull the line high for 1305 micros so the door opener responds to the message
digitalWrite(OUTPUT_GDO, HIGH); // pull the line high for 1305 micros so the
// door opener responds to the message
delayMicroseconds(1305);
digitalWrite(OUTPUT_GDO, LOW); // bring the line low
@ -390,7 +405,8 @@ void transmit(byte* payload, unsigned int length){
}
void sync() {
if(!useRollingCodes) return;
if (!useRollingCodes)
return;
getRollingCode("reboot1");
transmit(rollingCode, CODE_LENGTH);
@ -425,7 +441,9 @@ void openDoor(){
return;
}
doorState = "opening"; // It takes a couple of pulses to detect opening/closing. by setting here, we can avoid bouncing from rapidly repeated commands
doorState = "opening"; // It takes a couple of pulses to detect
// opening/closing. by setting here, we can avoid
// bouncing from rapidly repeated commands
if (useRollingCodes) {
getRollingCode("door1");
@ -455,7 +473,9 @@ void closeDoor(){
return;
}
doorState = "closing"; // It takes a couple of pulses to detect opening/closing. by setting here, we can avoid bouncing from rapidly repeated commands
doorState = "closing"; // It takes a couple of pulses to detect
// opening/closing. by setting here, we can avoid
// bouncing from rapidly repeated commands
if (useRollingCodes) {
getRollingCode("door1");
@ -471,7 +491,6 @@ void closeDoor(){
for (int i = 0; i < 4; i++) {
ESP_LOGD(TAG, "sync_code[%d]", i);
transmit(SYNC_CODE[i], CODE_LENGTH);
delay(45);
}

80
components/ratgdo/ratgdo.h
View File

@ -14,57 +14,76 @@
#ifndef _RATGDO_H
#define _RATGDO_H
#include "BootstrapManager.h" // Must use the https://github.com/PaulWieland/arduinoImprovBootstrapper fork, ratgdo branch
#include "SoftwareSerial.h" // Using espsoftwareserial https://github.com/plerup/espsoftwareserial
#include "rolling_code.h"
#include "home_assistant.h"
#include "rolling_code.h"
SoftwareSerial swSerial;
/********************************** BOOTSTRAP MANAGER *****************************************/
/********************************** BOOTSTRAP MANAGER
* *****************************************/
BootstrapManager bootstrapManager;
/********************************** PIN DEFINITIONS *****************************************/
#define OUTPUT_GDO D4 // red control terminal / GarageDoorOpener (UART1 TX) pin is D4 on D1 Mini
/********************************** PIN DEFINITIONS
* *****************************************/
#define OUTPUT_GDO \
D4 // red control terminal / GarageDoorOpener (UART1 TX) pin is D4 on D1 Mini
#define TRIGGER_OPEN D5 // dry contact for opening door
#define TRIGGER_CLOSE D6 // dry contact for closing door
#define TRIGGER_LIGHT D3 // dry contact for triggering light (no discrete light commands, so toggle only)
#define TRIGGER_LIGHT \
D3 // dry contact for triggering light (no discrete light commands, so toggle
// only)
#define STATUS_DOOR D0 // output door status, HIGH for open, LOW for closed
#define STATUS_OBST D8 // output for obstruction status, HIGH for obstructed, LOW for clear
#define INPUT_RPM1 D1 // RPM1 rotary encoder input OR reed switch if not soldering to the door opener logic board
#define INPUT_RPM2 D2 // RPM2 rotary encoder input OR not used if using reed switch
#define STATUS_OBST \
D8 // output for obstruction status, HIGH for obstructed, LOW for clear
#define INPUT_RPM1 \
D1 // RPM1 rotary encoder input OR reed switch if not soldering to the door
// opener logic board
#define INPUT_RPM2 \
D2 // RPM2 rotary encoder input OR not used if using reed switch
#define INPUT_OBST D7 // black obstruction sensor terminal
/********************************** MQTT TOPICS *****************************************/
/********************************** MQTT TOPICS
* *****************************************/
String doorCommandTopic = ""; // will be mqttTopicPrefix/deviceName/command
String setCounterTopic = ""; // will be mqttTopicPrefix/deviceName/set_code_counter
String setCounterTopic =
""; // will be mqttTopicPrefix/deviceName/set_code_counter
String doorCommand = ""; // will be [open|close|light]
String overallStatusTopic = ""; // legacy from 1.0. Will be mqttTopicPrefix/deviceName/status
String overallStatusTopic =
""; // legacy from 1.0. Will be mqttTopicPrefix/deviceName/status
String availabilityStatusTopic = ""; // online|offline
String obstructionStatusTopic = ""; // obstructed|clear
String doorStatusTopic = ""; // open|opening|closing|closed|reed_open|reed_closed
String rollingCodeTopic = ""; // broadcast the current rolling code count for debugging purposes
String doorStatusTopic =
""; // open|opening|closing|closed|reed_open|reed_closed
String rollingCodeTopic =
""; // broadcast the current rolling code count for debugging purposes
/********************************** GLOBAL VARS *****************************************/
/********************************** GLOBAL VARS
* *****************************************/
bool setupComplete = false;
unsigned int rollingCodeCounter;
byte rollingCode[CODE_LENGTH];
String doorState = "unknown"; // will be [online|offline|opening|open|closing|closed|obstructed|clear|reed_open|reed_closed]
String doorState =
"unknown"; // will be
// [online|offline|opening|open|closing|closed|obstructed|clear|reed_open|reed_closed]
unsigned int obstructionLowCount = 0; // count obstruction low pulses
unsigned long lastObstructionHigh = 0; // count time between high pulses from the obst ISR
unsigned long lastObstructionHigh =
0; // count time between high pulses from the obst ISR
bool doorIsObstructed = false;
bool dryContactDoorOpen = false;
bool dryContactDoorClose = false;
bool dryContactToggleLight = false;
int doorPositionCounter = 0; // calculate the door's movement and position
bool rpm1Pulsed = false; // did rpm1 get a pulse or not - eliminates an issue when the sensor is parked on a high pulse which fires rpm2 isr
bool rpm1Pulsed =
false; // did rpm1 get a pulse or not - eliminates an issue when the sensor
// is parked on a high pulse which fires rpm2 isr
/********************************** FUNCTION DECLARATION *****************************************/
/********************************** FUNCTION DECLARATION
* *****************************************/
void callback(char *topic, byte *payload, unsigned int length);
void manageDisconnections();
void manageQueueSubscription();
@ -85,7 +104,8 @@ void sendDoorStatus();
void doorStateLoop();
void dryContactLoop();
/********************************** INTERRUPT SERVICE ROUTINES ***********************************/
/********************************** INTERRUPT SERVICE ROUTINES
* ***********************************/
void IRAM_ATTR isrDebounce(const char *type);
void IRAM_ATTR isrDoorOpen();
void IRAM_ATTR isrDoorClose();
@ -95,14 +115,20 @@ void IRAM_ATTR isrRPM1();
void IRAM_ATTR isrRPM2();
/*** Static Codes ***/
byte SYNC1[] = {0x55,0x01,0x00,0x61,0x12,0x49,0x2c,0x92,0x5b,0x24,0x96,0x86,0x0b,0x65,0x96,0xd9,0x8f,0x26,0x4a};
byte SYNC2[] = {0x55,0x01,0x00,0x08,0x34,0x93,0x49,0xb4,0x92,0x4d,0x20,0x26,0x1b,0x4d,0xb4,0xdb,0xad,0x76,0x93};
byte SYNC3[] = {0x55,0x01,0x00,0x06,0x1b,0x2c,0xbf,0x4b,0x6d,0xb6,0x4b,0x18,0x20,0x92,0x09,0x20,0xf2,0x11,0x2c};
byte SYNC4[] = {0x55,0x01,0x00,0x95,0x29,0x36,0x91,0x29,0x36,0x9a,0x69,0x05,0x2f,0xbe,0xdf,0x6d,0x16,0xcb,0xe7};
byte SYNC1[] = {0x55, 0x01, 0x00, 0x61, 0x12, 0x49, 0x2c, 0x92, 0x5b, 0x24,
0x96, 0x86, 0x0b, 0x65, 0x96, 0xd9, 0x8f, 0x26, 0x4a};
byte SYNC2[] = {0x55, 0x01, 0x00, 0x08, 0x34, 0x93, 0x49, 0xb4, 0x92, 0x4d,
0x20, 0x26, 0x1b, 0x4d, 0xb4, 0xdb, 0xad, 0x76, 0x93};
byte SYNC3[] = {0x55, 0x01, 0x00, 0x06, 0x1b, 0x2c, 0xbf, 0x4b, 0x6d, 0xb6,
0x4b, 0x18, 0x20, 0x92, 0x09, 0x20, 0xf2, 0x11, 0x2c};
byte SYNC4[] = {0x55, 0x01, 0x00, 0x95, 0x29, 0x36, 0x91, 0x29, 0x36, 0x9a,
0x69, 0x05, 0x2f, 0xbe, 0xdf, 0x6d, 0x16, 0xcb, 0xe7};
byte *SYNC_CODE[] = {SYNC1, SYNC2, SYNC3, SYNC4};
byte DOOR_CODE[] = {0x55,0x01,0x00,0x94,0x3f,0xef,0xbc,0xfb,0x7f,0xbe,0xfc,0xa6,0x1a,0x4d,0xa6,0xda,0x8d,0x36,0xb3};
byte DOOR_CODE[] = {0x55, 0x01, 0x00, 0x94, 0x3f, 0xef, 0xbc, 0xfb, 0x7f, 0xbe,
0xfc, 0xa6, 0x1a, 0x4d, 0xa6, 0xda, 0x8d, 0x36, 0xb3};
byte LIGHT_CODE[] = {0x55,0x01,0x00,0x94,0x3f,0xef,0xbc,0xfb,0x7f,0xbe,0xff,0xa6,0x1a,0x4d,0xa6,0xda,0x8d,0x76,0xb1};
byte LIGHT_CODE[] = {0x55, 0x01, 0x00, 0x94, 0x3f, 0xef, 0xbc, 0xfb, 0x7f, 0xbe,
0xff, 0xa6, 0x1a, 0x4d, 0xa6, 0xda, 0x8d, 0x76, 0xb1};
#endif

8
components/ratgdo/rolling_code.cpp
View File

@ -1,5 +1,5 @@
#include "common.h"
#include "rolling_code.h"
#include "common.h"
#include "secplus.h"
void readCounterFromFlash() {
@ -82,7 +82,8 @@ void getRollingCode(const char *command){
printRollingCode();
if(strcmp(command,"door1") != 0){ // door2 is created with same counter and should always be called after door1
if (strcmp(command, "door1") != 0) { // door2 is created with same counter and
// should always be called after door1
rollingCodeCounter = (rollingCodeCounter + 1) & 0xfffffff;
}
return;
@ -90,7 +91,8 @@ void getRollingCode(const char *command){
void printRollingCode() {
for (int i = 0; i < CODE_LENGTH; i++) {
if(rollingCode[i] <= 0x0f) Serial.print("0");
if (rollingCode[i] <= 0x0f)
Serial.print("0");
Serial.print(rollingCode[i], HEX);
}
Serial.println("");

14
components/ratgdo/rolling_code.h
View File

@ -1,18 +1,22 @@
#ifndef _RATGDO_ROLLING_CODE_H
#define _RATGDO_ROLLING_CODE_H
#include <Arduino.h>
#include <LittleFS.h>
#include <ArduinoJson.h>
#include "BootstrapManager.h"
#include <Arduino.h>
#include <ArduinoJson.h>
#include <LittleFS.h>
extern "C" {
#include "secplus.h"
}
void readCounterFromFlash(); // get the rolling code counter from setup.json & return it
void readCounterFromFlash(); // get the rolling code counter from setup.json &
// return it
void writeCounterToFlash(); // write the counter back to setup.json
void getRollingCode(const char *command); // get the next rolling code for type [reboot1,reboot2,reboot3,reboot4,reboot5,door1,light]
void getRollingCode(
const char
*command); // get the next rolling code for type
// [reboot1,reboot2,reboot3,reboot4,reboot5,door1,light]
void printRollingCode();
#endif