Wemos8266RelaysLedDisplay/src/main.cpp

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/* Wemos8266RelaysLedDisplay/main.cpp
*/
#define COMPDATE __DATE__ __TIME__
#define APP_VERSION "0.2.18"
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// Button pin on the esp for selecting modes. 0 for Generic devices!
#define MODEBUTTON D3
#define RELAY1_PIN D1
#define RELAY2_PIN D2
#define DISPLAY_CLK_PIN D5
#define DISPLAY_DATA_PIN D7
#define DISPLAY_CS_PIN D6
#define VERTICAL_BAR_STARTS_TOP false
#define DEBUG_RELAYS false
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#define DEBUG_DISPLAY false
#define STARTUP1_ANIMATION_DURATION_ms 2000
#define STARTUP2_ANIMATION_DURATION_ms 33000
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#include <Arduino.h>
#include <IOTAppStory.h>
#include <MD_Parola.h>
#include <MD_MAX72xx.h>
#include <SPI.h>
#include <NTPClient.h>
#include <ESP8266WiFi.h>
#include <WiFiUdp.h>
#include "MD_RobotEyes.h"
#include <FS.h>
#include <ESPAsyncTCP.h> // https://github.com/me-no-dev/AsyncTCP
#include <ESPAsyncWebServer.h>
#include "Relays.h"
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IOTAppStory IAS(COMPDATE, MODEBUTTON);
String deviceName = "wemosMatrixDisplay";
String chipId;
// Define the number of devices we have in the chain and the hardware interface
// NOTE: These pin numbers will probably not work with your hardware and may
// need to be adapted
/* Mapper result, connector to ESP is at right (backside):
Your responses produce these hardware parameters
HW_DIG_ROWS 1
HW_REV_COLS 0
HW_REV_ROWS 0
Your hardware matches the setting for FC-16 modules. Please set FC16_HW.
*/
#define HARDWARE_TYPE MD_MAX72XX::FC16_HW
#define MAX_DEVICES 4
// Hardware SPI connection
// MD_Parola P = MD_Parola(HARDWARE_TYPE, DISPLAY_CS_PIN, MAX_DEVICES);
// Arbitrary output pins
MD_Parola P = MD_Parola(HARDWARE_TYPE, DISPLAY_DATA_PIN, DISPLAY_CLK_PIN, DISPLAY_CS_PIN, MAX_DEVICES);
MD_RobotEyes E;
Relays R;
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WiFiUDP ntpUDP;
NTPClient timeClient(ntpUDP, "europe.pool.ntp.org", 3600, 60000);
AsyncWebServer server(80);
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// Field default values
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char *clockName = "FREMO";
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char *clockSpeed_modelMsPerRealSec_String = "250";
int clockSpeed_modelMsPerRealSec = 250;
char *relay1Pin_String = "D1";
char *relay2Pin_String = "D2";
int relay1Pin = D1, relay2Pin = D2;
char *relayHoldTime_ms_String = "200";
char *relayMinOffTime_ms_String = "100";
unsigned int displayRefresh_ms = 200;
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// Clock Display Config Parameter
static char * displayClockNameEvery_ms_String = "16000";
static char * displayClockNameDuration_ms_String = "1200";
static uint32_t displayClockNameEvery_ms = 16000;
static uint32_t displayClockNameDuration_ms = 1200;
static uint16_t doNotShowClockNameBeforeAndAfterMinuteChange_s = 2;
static uint16_t hours, minutes, seconds;
static char minuteProgressIndicator;
static char timeBuffer[10];
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void setupIAS(void) {
#if defined ESP8266
// creat a unique deviceName for classroom situations (deviceName-123)
chipId = String(ESP.getChipId());
chipId = "-"+chipId.substring(chipId.length()-3);
deviceName += chipId;
#endif
// preset deviceName this is also your MDNS responder: http://deviceName.local
IAS.preSetDeviceName(deviceName);
IAS.preSetAppName(F("Wemos2RelaysMatrixDisplays"));
IAS.preSetAppVersion(F(APP_VERSION));
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IAS.preSetAutoUpdate(true);
// define fields
IAS.addField(clockName, "Clock Name", 8, 'T');
IAS.addField(clockSpeed_modelMsPerRealSec_String, "Model MilliSec per Real Sec", 8, 'N');
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IAS.addField(displayClockNameEvery_ms_String, "Display clock name every (ms)", 5, 'N');
IAS.addField(displayClockNameDuration_ms_String, "Display clock name duration (ms)", 5, 'N');
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IAS.addField(relay1Pin_String, "Pin Relay 1", 2, 'P');
IAS.addField(relay2Pin_String, "Pin Relay 2", 2, 'P');
IAS.addField(relayHoldTime_ms_String, "Relay hold time (ms)", 3, 'N');
IAS.addField(relayMinOffTime_ms_String, "Relay min off time (ms)", 3, 'N');
IAS.onModeButtonShortPress([]() {
Serial.println(F(" If mode button is released, I will enter firmware update mode."));
Serial.println(F("*----------------------------------------------------------------------*"));
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P.print("|updt");
});
IAS.onModeButtonLongPress([]() {
Serial.println(F(" If mode button is released, I will enter configuration mode."));
Serial.println(F("*----------------------------------------------------------------------*"));
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P.print("|cfg");
});
IAS.onFirstBoot([]() {
Serial.println(F(" Manual reset necessary after serial upload!"));
Serial.println(F("*----------------------------------------------------------------------*"));
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P.print("|rst");
ESP.reset();
});
IAS.onConfigMode([]() {
P.print(" WiFi");
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delay(400);
P.print(":" + chipId);
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Serial.print(F("Entered config mode for Wifi, device=")); Serial.println(chipId);
});
IAS.onFirmwareUpdateCheck([]() {
// P.print("chk upd");
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Serial.println(F("Firmware update check"));
});
IAS.onFirmwareUpdateDownload([]() {
P.print("dl+instl");
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Serial.println(F("Download and install new firmware"));
});
IAS.onFirmwareUpdateError([]() {
// P.print("Err fwu");
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Serial.println(F("Firmware update error"));
});
// Optional parameter: What to do with EEPROM on First boot of the app?
// 'F' Fully erase | 'P' Partial erase(default) | 'L' Leave intact
IAS.begin('L');
delay(500);
// Set to true to enable calling home frequently (disabled by default)
IAS.setCallHome(true);
// Call home interval in seconds, use 60s only for development.
// Please change it to at least 2 hours in production
IAS.setCallHomeInterval(120);
//IAS.callHome(false /*SPIFFS-check*/);
clockSpeed_modelMsPerRealSec = atoi(clockSpeed_modelMsPerRealSec_String);
relay1Pin = IAS.dPinConv(relay1Pin_String);
relay2Pin = IAS.dPinConv(relay2Pin_String);
R.setHoldTime_ms(atoi(relayHoldTime_ms_String));
R.setMinOffTime_ms(atoi(relayMinOffTime_ms_String));
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displayClockNameEvery_ms = atoi(displayClockNameEvery_ms_String);
displayClockNameDuration_ms = atoi(displayClockNameDuration_ms_String);
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Serial.println(F("Configuration used:"));
Serial.print(F("Relay1 Pin: ")); Serial.println(relay1Pin);
Serial.print(F("Relay2 Pin: ")); Serial.println(relay2Pin);
Serial.print(F("Clock speed: ")); Serial.print(clockSpeed_modelMsPerRealSec); Serial.println(F(" model ms per real sec"));
Serial.print(F("Relay hold time (ms): ")); Serial.println(relayHoldTime_ms_String);
Serial.print(F("Relay min off time (ms): ")); Serial.println(relayMinOffTime_ms_String);
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Serial.print(F("Clock speed (model ms per real time s): ")); Serial.println(clockSpeed_modelMsPerRealSec);
Serial.print(F("Show clock name every (ms): ")); Serial.println(displayClockNameEvery_ms);
Serial.print(F("Show clock name for (ms): ")); Serial.println(displayClockNameDuration_ms);
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}
static MD_MAX72XX *graphicDisplay = NULL;
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void setupDisplay() {
int charCode;
#if VERTICAL_BAR_STARTS_TOP
static uint8_t verticalBarFont[] = {
1, 0x00, /* blank */
1, 0x01, /* 1 dot */
1, 0x03, /* 2 dots */
1, 0x07,
1, 0x0f,
1, 0x1f,
1, 0x3f,
1, 0x7f,
1, 0xff, /* vertical bar completely set */
}; // columns from right to left, each byte is a single column
#else
static uint8_t verticalBarFont[] = {
1, 0x00, /* blank */
1, 0x80, /* 1 dot */
1, 0xc0, /* 2 dots */
1, 0xe0,
1, 0xf0,
1, 0xf8,
1, 0xfc,
1, 0xfe,
1, 0xff, /* vertical bar completely set */
}; // columns from right to left, each byte is a single column
#endif
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static uint8_t newZero[] = {0x05, 0x3e, 0x41, 0x41, 0x41, 0x3e, 0x00};
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P.begin();
// P.setZoneEffect(0, true, PA_FLIP_LR);
graphicDisplay = P.getGraphicObject();
E.begin(graphicDisplay);
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P.setIntensity(1);
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for (charCode=1; charCode<=9; ++charCode) {
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P.addChar(charCode, verticalBarFont+2*(charCode-1));
}
char intro[] = {':', '-', ')', ' ', 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x00};
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// replace the 0 characters, we do not like the "slash"
P.addChar('0', newZero);
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P.print(intro);
}
//called when the url is not defined here return 404
void onRequest(AsyncWebServerRequest *request){
//Handle Unknown Request
request->send(404);
}
void setupFS() {
if(!SPIFFS.begin()){
Serial.println(F(" SPIFFS Mount Failed"));
return;
}
}
void setupWebServer() {
server.on("/fwd", HTTP_GET, [](AsyncWebServerRequest *request){
Serial.println(F("\n WebApp button pressed -- move clock forward"));
R.toggle();
// create json return
String json = "{";
json += "\"result\":\"OK\",";
json += "\"clockName\":\"" + String(clockName) + "\",";
json += "\"hours\":\"" + String(hours) + "\",";
json += "\"minutes\":\"" + String(minutes) + "\",";
json += "\"seconds\":\"" + String(seconds) + "\"";
json += "}";
// return json to WebApp
request->send(200, F("text/json"), json);
json = String();
});
server.on("/clock", HTTP_GET, [](AsyncWebServerRequest *request){
// create json return
String json = "{";
json += "\"clockName\":\""+String(clockName)+"\",";
json += "\"clockSpeed\":\""+String(clockSpeed_modelMsPerRealSec)+"\",";
json += "\"relayHoldTime_ms\":\""+String(R.getHoldTime_ms())+"\",";
json += "\"relayMinOffTime_ms\":\""+String(R.getMinOffTime_ms())+"\",";
json += "\"displayRefresh_ms\":\""+String(displayRefresh_ms)+"\",";
json += "\"displayClockNameEvery_ms\":\""+String(displayClockNameEvery_ms)+"\",";
json += "\"displayClockNameDuration_ms\":\""+String(displayClockNameDuration_ms)+"\",";
json += "\"doNotShowClockNameBeforeAndAfterMinuteChange_s\":\""+String(doNotShowClockNameBeforeAndAfterMinuteChange_s)+"\",";
json += "\"real_hours\":\""+String(hours)+"\",";
json += "\"real_minutes\":\""+String(minutes)+"\",";
json += "\"real_seconds\":\""+String(seconds)+"\",";
json += "\"model_hours\":\""+String(hours)+"\",";
json += "\"model_minutes\":\""+String(minutes)+"\",";
json += "\"model_seconds\":\""+String(seconds)+"\"";
json += "}";
// return json to WebApp
request->send(200, F("text/json"), json);
json = String();
});
server.on("/setDT", HTTP_GET, [](AsyncWebServerRequest *request){
String h, m, message;
Serial.println(F("\n Setting displayed time of clock"));
message = "";
if (request->hasParam("h")) {
h = request->getParam("h")->value();
} else {
message += "Parameter h for hours missing. ";
}
if (request->hasParam("m")) {
m = request->getParam("m")->value();
} else {
message += "Parameter m for minutes missing. ";
}
R.setDisplayedTime(h.toInt(), m.toInt());
h = String();
m = String();
// create json return
String json = "{";
if (message.length() > 0) {
json += "\"result\":\"Error\",";
json += "\"message\": \"" + message + "\"";
} else {
json += "\"result\":\"OK\"";
}
json += "}";
// return json to WebApp
request->send(200, F("text/json"), json);
json = String();
});
server.serveStatic("/", SPIFFS, "/");
server.onNotFound(onRequest);
// start the HTTP server
server.begin();
Serial.print(F("HTTP server started at: "));
Serial.println(WiFi.localIP());
Serial.println("");
}
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void setup(void)
{
Serial.println(F("setup():"));
setupDisplay();
setupIAS();
setupFS();
setupWebServer();
delay(200);
R.begin(relay1Pin, relay2Pin);
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timeClient.begin();
Serial.println(F("setup() finished"));
}
static bool timeClientInitialized = false;
static unsigned long lastTimeOutput_ms = 0;
#define TIME_BETWEEN_REALTIME_UPDATE_ms 60000
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typedef struct
{
char name[7];
MD_RobotEyes::emotion_t e;
uint16_t timePause; // in milliseconds
} sampleItem_t;
static const sampleItem_t eSeq[] =
{
{ "Nutral", MD_RobotEyes::E_NEUTRAL, 1000 },
{ "Blink" , MD_RobotEyes::E_BLINK, 1000 },
{ "Wink" , MD_RobotEyes::E_WINK, 1000 },
{ "Left" , MD_RobotEyes::E_LOOK_L, 1000 },
{ "Right" , MD_RobotEyes::E_LOOK_R, 1000 },
{ "Up" , MD_RobotEyes::E_LOOK_U, 1000 },
{ "Down" , MD_RobotEyes::E_LOOK_D, 1000 },
{ "Angry" , MD_RobotEyes::E_ANGRY, 1000 },
{ "Sad" , MD_RobotEyes::E_SAD, 1000 },
{ "Evil" , MD_RobotEyes::E_EVIL, 1000 },
{ "Evil2" , MD_RobotEyes::E_EVIL2, 1000 },
{ "Squint", MD_RobotEyes::E_SQUINT, 1000 },
{ "Dead" , MD_RobotEyes::E_DEAD, 1000 },
{ "ScanV" , MD_RobotEyes::E_SCAN_UD, 1000 },
{ "ScanH" , MD_RobotEyes::E_SCAN_LR, 1000 },
};
#define DISPLAY_ANIM_NAME false
void loopStartupAnimation() {
// show startup animation
boolean animationFinished = false;
static uint32_t timeStartDelay;
static uint8_t index = ARRAY_SIZE(eSeq);
static enum { S_IDLE, S_TEXT, S_ANIM, S_PAUSE } state = S_IDLE;
animationFinished = E.runAnimation();
switch (state)
{
case S_IDLE:
index++;
if (index >= ARRAY_SIZE(eSeq))
index = 0;
P.displayClear();
#if DISPLAY_ANIM_NAME
E.setText(eSeq[index].name);
#endif
state = S_TEXT;
break;
case S_TEXT: // wait for the text to finish
if (animationFinished) // text animation is finished
{
E.setAnimation(eSeq[index].e, true);
state = S_ANIM;
}
break;
case S_ANIM: // checking animation is completed
if (animationFinished) // animation is finished
{
timeStartDelay = millis();
state = S_PAUSE;
}
break;
case S_PAUSE: // non blocking waiting for a period between animations
if (millis() - timeStartDelay >= eSeq[index].timePause)
state = S_IDLE;
break;
default:
state = S_IDLE;
break;
}
}
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void reInitializeDisplay() {
static unsigned long last_reinit_ts = 0;
#define REINIT_AFTER_ms 5000
#define AVOID_REINIT_BEFORE_AND_AFTER_FULLMINUTE_FOR_s 3
if (last_reinit_ts == 0) last_reinit_ts = millis();
if (millis() - last_reinit_ts > REINIT_AFTER_ms
&& seconds < 60 - AVOID_REINIT_BEFORE_AND_AFTER_FULLMINUTE_FOR_s
&& seconds > AVOID_REINIT_BEFORE_AND_AFTER_FULLMINUTE_FOR_s) {
P.begin();
last_reinit_ts = millis();
}
}
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void loop(void)
{
int currentDisplayState;
static int lastMinutes = 0;
static int lastSeconds = 0;
#define MsgSize 10
static char debugMsg[MsgSize+1];
static int recentDisplayState = -1;
static unsigned long firstLoop_ts = 0;
if (firstLoop_ts == 0) firstLoop_ts = millis();
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if (!timeClientInitialized && WiFi.status() == WL_CONNECTED) {
timeClient.begin();
timeClientInitialized = true;
timeClient.update();
Serial.println(timeClient.getFormattedTime());
lastTimeOutput_ms = millis();
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}
IAS.loop();
if (timeClientInitialized && millis()-lastTimeOutput_ms > TIME_BETWEEN_REALTIME_UPDATE_ms) {
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timeClient.update();
Serial.println(timeClient.getFormattedTime());
lastTimeOutput_ms = millis();
}
if (millis() < firstLoop_ts + STARTUP1_ANIMATION_DURATION_ms) {
// Startup phase 1: Constant display of content, created during setup()
return;
}
if (millis() < firstLoop_ts + STARTUP1_ANIMATION_DURATION_ms + STARTUP2_ANIMATION_DURATION_ms) {
loopStartupAnimation();
return;
}
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if (timeClientInitialized) {
hours = timeClient.getHours();
minutes = timeClient.getMinutes();
seconds = timeClient.getSeconds();
} else {
hours = (millis() / 60 * 60 * 1000) % 24;
minutes = (millis() / 60 * 1000) % 60;
seconds = (millis() / 1000) % 60;
}
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minuteProgressIndicator = seconds/6.7 + 1; // char code 1-8 show vertical bar
if (minuteProgressIndicator > 9) minuteProgressIndicator = 9;
snprintf(timeBuffer, 10, "%c %2d:%02d", minuteProgressIndicator, hours, minutes);
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// standard procedure to display
static uint32_t last_clock_refresh = 0;
static uint32_t lastTimeClockNameShown = 0;
static boolean showingClockName = false;
if (showingClockName) {
if (millis() - lastTimeClockNameShown > displayClockNameDuration_ms) {
// stop showingClockName
showingClockName = false;
}
} else {
if ((millis() - lastTimeClockNameShown > displayClockNameEvery_ms)
&& (seconds < 60-doNotShowClockNameBeforeAndAfterMinuteChange_s)
&& (seconds > doNotShowClockNameBeforeAndAfterMinuteChange_s)) {
//P.begin(); // re-initialize, that fixes display problems due to electrical relais feedbacks
reInitializeDisplay();
P.setIntensity(2);
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P.print(clockName);
lastTimeClockNameShown = millis();
showingClockName = true;
} else {
// showing clock
if (millis() - last_clock_refresh > displayRefresh_ms) {
// P.begin(); // re-initialize, that fixes display problems due to electrical relais feedbacks
reInitializeDisplay();
P.setIntensity(1);
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P.print(timeBuffer);
last_clock_refresh = millis();
}
}
}
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// toggle relays
if (lastMinutes != minutes) {
R.toggle();
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lastMinutes = minutes;
}
lastSeconds = seconds;
R.loop();
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}